Securing and Optimizing Linux RedHat Edition -A Hands on Guide Gerhard Mourani Open Network Architecture www.openna.com                                           Madhu "Maddy" Complete port of the Book to DocBook/XML source and Editing  Copyright © 2000 Gerhard Mourani and OpenDocs, LLC. Copyright © 2000 Madhusudan (Madhu "Maddy") XML Source This version and its subsequent outputs whether be it HTML, PDF or any other derivatives can be distributed under the same licensing terms and conditions as the orginal Securing_and_Optimizing_Linux i.e. as set forth in the Open Publication License; V1.0 or later, the latest version is presently available at www.opencontent.org/openpub/. Please note even if i madhusudan (Madhu "Maddy"), hold the copyright for the XML source(Markup), you still need to get permission from Gerhard Mourani the orginal author of Securing_and Optmising_Linux, to make any changes to the content of this book. Please do read the licensing terms and conditions detailed below for additional information This material may be distributed only subject to the terms and conditions set forth in the Open Publication License; V1.0 or later, the latest version is presently available at www.opencontent.org/openpub/. Distribution of substantively modified versions of this document is prohibited without the explicit permission of the copyright holder. Distribution of the work or derivative of the work in any standard (paper) book form for commercial purposes is prohibited unless prior permission is obtained from the copyright holder. Please note even if I, Gerhard Mourani have the copyright, I don't control commercial printing of the book. Please contact OpenDocs @www.opendocspublishing.com/ if you have questions concerning such matters. The logos, trademarks, symbols used in this book are properties of their respective compan(y)ies. ------------------------------------------------------------------------------- Table of Contents Preface 1._Why_did_i_write_this_book? 2._Why_fiddle? 3._DocBook_! 4._DocBook/XML 4.1._Bouquets_Brickbats_Etc. 1._Getting_Started 1._Introduction 1._Audience 2._Organization_of_This_Book 3._Pre-requisites 4._Obtaining_the_book_and_example_configuration_files 4.1._Example_Configuration_files 5._Acknowledgements_from_Gerhard 5.1._Acknowledgements_from_"Maddy" 2._Installation 2._Overview_of_OS_Linux 1._What_is_Linux? 2._A_Few_good_reasons_to_use_Linux 3._Fears,_Uncertainity_and_Doubts 3._Installation_of_your_Linux_Server 1._Know_your_Hardware! 2._Creating_the_Boot_Disk_and_Booting 3._Installation_Class_and_Method_(Install_Type) 4._Disk_Setup-_Disk_Druid 5._Disk_Druid 6._An_example 7._Post-Partitioning 8._Components_to_Install-_Package_Group_Selection 9._Select_Individual_Package_-_Part_'A' 10._Select_Individual_Package_-Part_'B' 11._How_to_use_RPM_Commands 12._Starting_and_stopping_daemon_services 4._Post-Install 1._Software_that_must_be_uninstalled 2._Use_RPM_command_to_uninstall. 3._Software_that_must_be_installed 4._Check,Re-confirm 5._Verify,Cross-check 6._some_colors_for_a_change 7._Update_of_the_latest_software 3._Security,_Optimization_and_Upgrade 5._General_System_Security 1._BIOS 2._Security_as_a_Policy 3._Choose_a_right_Password 4._The_root_account 5._The_/etc/exports_file 6._Disable_console_program_access 7._Disable_all_console_access 8._The_inetd_-_/etc/inetd.conf_file 9._TCP_WRAPPERS 9.1._Don't_display_system_issue_file 10._The_/etc/host.conf_file 11._The_/etc/services_file 12._The_/etc/securetty_file 13._Special_accounts 14._Blocking;_su_to_root,_by_one_and_sundry 15._Put_limits_on_resource 16._Control_mounting_a_file_system 17._Conceal_binary_RPM 18._Shell_logging 19._The_LILO_and_lilo.conf_file 20._Disable_Ctrl-Alt-Delete_keyboard_shutdown_command 21._Physical_hard_copies_of_all-important_logs 22._Tighten_scripts_under_/etc/rc.d/ 22.1._The_/etc/rc.d/rc.local_file 23._Bits_from_root-owned_programs 24._The_kernel_tunable_parameters 24.1._Prevent_your_system_responding_to_Ping 25._Refuse_responding_to_broadcasts_request 26._Routing_Protocols 27._Enable_TCP_SYN_Cookie_Protection 28._Disable_ICMP_Redirect_Acceptance 29._Enable_always-defragging_Protection 30._Enable_bad_error_message_Protection 31._Enable_IP_spoofing_protection 32._Log_Spoofed,_Source_Routed_and_Redirect_Packets 33._Unusual_or_hidden_files 34._System_is_compromised_! 6._Linux_General_Optimization 1._The_/etc/profile_file 2._Benchmark_Results 3._Benchmark_results-i586 4._Benchmark_results_-i486 5._The_bdflush_parameters 6._The_buffermem_parameters 7._The_ip_local_port_range_parameters 8._The_/etc/nsswitch.conf_file 9._The_file-max_parameter 10._The_ulimit_parameter 11._The_atime_and_noatime_attribute 12._Tuning_IDE_Hard_Disk_Performance 13._Better_manage_your_TCP/IP_resources 7._Configuring_and_Building_a_Secure,_Optimized_Kernel 1._Pre-Install 1.1._Make_an_emergency_boot_floppy 2._Uninstallation_and_Optimization 3._Securing_the_kernel 4._Compilation 5._Kernel_configuration_-Part_"A" 6._Kernel_configuration_-Part_"B" 7._Kernel_configuration_-Part_"C" 8._Kernel_configuration_-Part_"D" 9._Kernel_configuration_-Part_"E" 10._Installing_the_new_kernel 11._Delete_programs,_Edit_files_pertaining_to_modules 12._Create_a_emergency_Rescue_and_Boot_floppy_disk 4._Networking_-Management,_Firewall,_Masquerading_and_Forwarding 8._TCP/IP_-Network_Management 1._Multiple_Ethernet_Card_per_Machine 9._Files_-Networking_Functionality 1._The_/etc/HOSTNAME_file 2._The_/etc/sysconfig/network-scripts/ifcfg-ethN_files 3._The_/etc/resolv.conf_file 4._The_/etc/host.conf_file 5._The_/etc/sysconfig/network_file 6._The_/etc/sysctl.conf_file 7._The_/etc/hosts_file 8._Config_TCP/IP_Networking_manually_-command_line 10._Networking_-Firewall 1._Policy,_Guidelines_etc. 2._The_topology 3._Build_a_kernel_with_IPCHAINS_Firewall_support 4._Rules_used_in_the_Firewall_script_files 5._Source_Address_Filtering 11._The_firewall_scripts_files 1._Config_/etc/rc.d/init.d/firewall_script_file_-Web_Server 2._Config_/etc/rc.d/init.d/firewall_script_file_-_Mail_Server 12._Networking_Firewall_-Masquerading_and_Forwarding 1._Build_a_kernel_with_Firewall_Masquerading_and_Forwarding support 2._Config_/etc/rc.d/init.d/firewall_script_file_-Gateway_Server 3._Configure_script_for_Example_Gateway_Server 4._Deny_access_to_some_address 5._IPCHAINS_Administrative_Tools 5._Software_-Security 13._Linux_-The_Compiler_functionality 1._The_necessary_packages 2._Why_choose_tarballs? 2.1._Compiling_software_on_your_system 3._Build,_Install_software_on_your_system 3.1._Edit_files_with_the_vi_editor 14._Software_-Security/Monitoring 1._sXid 2._Configure_and_Optimize_sXid 2.1._Configure_the_/etc/sxid.conf_file 3._Logcheck 4._Configure_and_Optimize_Logcheck 5._PortSentry 6._Configure_and_Optimise_Portsentry 7._Test_fire_your_PortSentry 6._Software_-Networking 15._Software_-Securities 1._OpenSSH 2._Configure_and_optimise_Openssh 3._Configure_the_/etc/ssh/ssh_config_file 4._Configure_the_/etc/ssh/sshd_config_file 5._Configure_OpenSSH_to_use_TCP-Wrappers/inetd_super_server 6._OpenSSH_Per-User_Configuration 7._OpenSSH_Users_Tools 7.1._scp 8._Installed_files 8.1._Free_SSH_clients_for_Windows 16._Software_-Securties(commercial) 1._Linux_SSH2_Client/Server 2._Configure_and_Optimise_SSH2 3._Configure_the_/etc/ssh2/ssh2_config_file 4._Configure_the_/etc/ssh2/sshd2_config_file 5._Configure_sshd2_to_use_tcp-wrappers/inetd_super_server 6._Configuration_of_the_/etc/pam.d/ssh_file 7._Ssh2_Per-User_Configuration 8._SSH2_Users_Tools 9._Installed_files 17._Software_-Securities/System_Integrity 1._Linux_Tripwire_2.2.1 2._Configure_the_/var/tmp/install.cfg_file 3._Configuration_files 4._Configure_the_/usr/TSS/policy/twpol.txt_file 5._Securing_Tripwire_for_Linux 5.1._Often_used_Commands 6._Integrity_or_Interactive_Check_Mode 7._Installed_files 18._Linux_Tripwire_ASR_1.3.1 1._Install,_Compile_and_Optimize 2._Configurations 3._Configure_the_/etc/tw.config_file 4._Configure_the_/etc/cron.daily/tripwire.verify_script 4.1._Security_Issue 5._Tripwire_in_Interactive_Checking_Mode 6._Run_Tripwire_in_Database_Update_Mode 6.1._Installed_Files 19._Software_-Securities/Management_&_Limitation 1._Linux_GnuPG 2._Often_used_Commands 3._Importing_keys 3.1._Key_signing 4._Encrypt_and_decrypt 4.1._Exporting_your_public_key 20._Set_Limits_using_Qouta 1._Qouta 1.1._Modify_the_/etc/fstab_file 2._Create_of_the_quota.user_and_quota.group 3._edquota 3.1._The_grace_period_parameter 4._Assign_quota_for_a_particular_group 4.1._Assign_quota_for_groups_of_users_with_the_same_value 5._Often_used_Commands 21._Software_-Networking 1._Linux_DNS_and_BIND_Server 2._Configure 3._Caching-only_name_Server 4._Primary_master_name_Server 5._Secondary_slave_name_Server 5.1._/etc/rc.d/init.d/named_script 6._Run_ISC_BIND/DNS_in_a_chroot_jail 7._The_syslog_daemon 8._Clean-up_and_Test_the_new_chrooted_jail 9._DNS_Administrative_Tools 10._DNS_Users_Tools 11._Installed_files 22._Software_-Server/Mail_Network 1._Linux_Sendmail_Server 2._Compile_and_optimize 3._Configurations 4._The_/etc/sendmail.mc_file_/Central_Mail_Hub 5._Build_and_Tweak_Sendmail 5.1._The_null.mc_file 6._The_/etc/mail/access_and_access.db_files 7._The_/etc/mail/aliases_and_aliases.db_files 7.1._The_/etc/mail/_Directory 8._The_/etc/mail/local-host-names_file 8.1._Configure_the_/etc/sysconfig/sendmail_file 9._The_/etc/rc.d/init.d/sendmail_script_file 10._Secure_Sendmail_using_smrsh 11._The_/etc/mail/aliases_file 12._Limit_queue_processing_to_root 12.1._The_SMTP_greeting_message 13._Sendmail_Administrative_Tools 13.1._Sendmail_Users_Tools 14._Installed_files:_Sendmail_-Central_Mail_Hub 15._Installed_files:_Sendmail_-Local_server/client 23._Linux_IMAP_&_POP_Server 1._Configure_and_Compile 2._Configure_to_tweak 2.1._The_/etc/pam.d/imap_file 3._Enable_IMAP_or_POP_via_the_tcp-wrappers_inetd_super_server 3.1._Securing_IMAP/POP 4._Installed_files 24._Software_-Networking/Encryption 1._Linux_OPENSSL_Server 2._Compile_and_Optimize 3._Configure_OpenSSL_to_optimise 4._The_/etc/ssl/openssl.cnf_file 5._Create_the_/usr/bin/sign.sh_program_file 6._Commands_-often_used 7._Securing_OpenSSL 8._Installed_files 25._Linux_FreeS/WAN_VPN 1._IPSEC/VPN_-FreeS/WAN 2._Compile,_insert_FreeS/WAN_into_the_kernel 3._Reconfigure_and_install_the_kernel_with_FreeS/WAN_VPN_support 4._Configure_to_optimise 5._Automatic_or_Manual_Key_connections 6._The_/etc/ipsec.conf_file 7._The_/etc/ipsec.secrets_file 8._Configure_RSA_private_keys_secrets 9._Required_network_setup_for_IPSec 10._Testing_the_installation 11._Further_documentation 12._Installed_files 26._Linux_OpenLDAP_Server 1._Compile_ans_Install 2._Compile_and_Optimize 3._Configurations 4._Configure_the_/etc/ldap/slapd.conf_file 5._Configure_the_/etc/rc.d/init.d/ldap_script_file 6._Securing_OpenLDAP 7._OpenLDAP_Creation_and_Maintenance_Tools 7.1._LDMB_backend_database_off-line 8._Create_the_LDMB_backend_database_on-line 8.1._ldapmodify 9._OpenLDAP_Users_Tools 9.1._The_Netscape_Address_Book_client_for_LDAP 10._Installed_files 27._Linux_PostgreSQL_Database_Server 1._Install_PostgreSQL 2._Compile_and_Optimize 3._Database_installation_using_superuser_account 4._Configuration_files 5._Configure_the_/etc/rc.d/init.d/postgresql_script_file 6._Commands_often_used 7._Installed_files 28._Software_-Server/Proxy_Network 1._Linux_Squid_Proxy_Server 2._Configure_and_Optimize 3._Improve_performance_Using_GNU_malloc_library 4._Compile_and_Optimize 5._Configurations 6._Configure_the_/etc/squid/squid.conf_file_-in_httpd-accelerator mode 7._Configure_of_the_/etc/squid/squid.conf_file_-/proxy-caching mode 8._Configure_the_/etc/rc.d/init.d/squid_script_file_-/all configurations 9._Configure_the_/etc/logrotate.d/squid_file 9.1._Securing_and_Immunize_Squid 10._Optimizing_Squid 10.1._The_cachemgr.cgi 11._Netscape_Proxies_Configuration 12._Installed_files 29._Software_-Network_Server,_web/Apache 1._Linux_MM_Shared_Memory_Library 2._Compile 2.1._Installed_files 3._Linux_Apache_Web_Server 4._Compile_and_Optimize 5._Configure_and_apply_PHP4_to_Apache_source 6._Apply_mod_perl_to_Apache_source_tree 7._Install_Apache 8._Post_install_Configuration 9._Configure_the_/etc/httpd/conf/httpd.conf_file 10._Configure_the_/etc/logrotate.d/apache_file 11._Configure_the_/etc/rc.d/init.d/httpd_script_file 12._PHP4_server-side_scripting 13._Perl_module_Devel::Symdump 13.1._Installed_files 14._CGI.pm_Perl_library 14.1._Installed_files 15._Securing_Apache 16._users_authentication_with_.dbmpasswd_password_file 16.1._Immunize_configuration_files_like_httpd.conf 17._Apache_in_a_chroot_jail 18._Apache_to_use_shared_libraries 19._The_/chroot/etc_directory 20._Test_the_new_chrooted_jail 21._Configure_the_new_/etc/logrotate.d/apache_file 22._Optimizing_Apache 23._Installed_files_for_Apache_Web_Server 24._Installed_files_/PHP4 25._Installed_files_by_mod_perl 30._Optional_component_to_install_with_Apache 1._Linux_Webalizer 2._Compile 2.1._Configurations 3._Configure_the_/etc/webalizer.conf_file 4._Make_Apache_aware_of_Webalizer_output_directory 4.1._Running_Webalizer_manually_first_time 5._Run_Webalizer_automatically_with_a_cron_job 5.1._Installed_files 6._Linux_FAQ-O-Matic 7._Compile_and_install_FAQ-O-Matic 8._Make_Apache_aware_Faq-O-Matic_file's_location 9._Configure_your_FAQ-O-Matic 10._Installed_files 11._Linux_Webmail_IMP 12._Set_up_PHPLib 13._Compile_to_install_Webmail_IMP 14._Configure_and_create_Webmail_IMP_SQL_database 15._Configure_your_php.ini_from_PHP4 15.1._Configure_Apache_to_recognize_Webmail_IMP 16._Configure_Webmail_IMP_via_your_web_browser 31._Software_-Server/File_Sharing-Network 1._Linux_Samba_Server 2._Configure_Samba 3._Compile_and_optimize 4._Configurations 5._Configuration_of_the_/etc/smb.conf_file 6._Configure_the_/etc/lmhosts_file 6.1._Configure_the_/etc/pam.d/samba_file 7._Encrypted_Samba_password_file_for_clients 8._Optimizing_Samba 8.1._Tuning_the_buffer_cache 9._Tuning_the_buffermem 10._Further_documentation 11._Samba_Administrative_Tools 11.1._Samba_Users_Tools 12._The_/etc/rc.d/init.d/smb_script_file 12.1._Securing_Samba 13._Installed_files 32._Linux_FTP_Server 1._chroot'd_Guest_FTP_access 2._Setup_an_FTP_user_account_minus_shells 3._Setup_a_chroot_user_environment 4._Configurations 5._Configure_the_/etc/ftphosts_file 5.1._Configure_the_/etc/ftpusers_file 6._Configure_the_/etc/ftpconversions_file 6.1._Configure_the_/etc/pam.d/ftp_file 7._Configure_the_/etc/logrotate.d/ftpd_file 7.1._Configure_ftpd_to_use_tcp-wrappers_inetd 8._FTP_Administrative_Tools 9._Securing_FTP 10._The_special_file_.notar 11._Installed_files 7._Backup_and_Restore 33._Why's_and_When's_of_Backup_and_Restore 1._What_to_backup 2._The_tar_backup_program 3._Automating_backups_with_tar 4._Restore_files_with_tar 5._The_dump_backup_program 6._Making_backups_with_dump 7._Restoring_files_with_dump 8._Backing_up_and_restoring_over_the_network 8.1._Using_the_scp_SSH_command I._Appendixes A._Resources B._Tweaks,_Tips_and_Administration_tasks C._Obtaining_Requests_for_Comments_(RFCs) List of Tables 3.1. Sample_representaion_of_partitions 33.1. Dump_scheme List of Examples 3.1. Starting_and_Stopping_various_Daemon's 5.1. Export_file_systems_using_NFS 5.2. Disable_console-equivalent_access 5.3. Print_log_reports 5.4. Use_man_pages 5.5. Use_find_to_find 6.1. For_128_MB_of_RAM 7.1. SMP_support 8.1. Two_ISA_ethernet_cards 12.1. rc.firewall.blocked 13.1. Using_tar 15.1. Remote_login_using_ssh 15.2. scp_Secure_Copy_utility 15.3. local_to_remote 16.1. login_to_a_remote_using_ssh2 16.2. sftp2,_Secure_File_Transfer 18.1. Usage_of_Tripwire 19.1. Importing_using_gpg 19.2. Signing_key 19.3. Encrypting 19.4. Decrypting 20.1. usrquota 20.2. grpquota 21.1. dnsquery 21.2. Look_up_host_names 21.3. Using_host 21.4. List_a_complete_domain 22.1. Overriding_RBL 22.2. Alternative_names 22.3. sendmail.cf 26.1. my-data-file 26.2. LDMB_backend 26.3. modifyentry 26.4. Address_Book 30.1. Using_Netscape_browser 33.1. Backup_directory_of_a_week 33.2. scp_SSH_command 33.3. scp_SSH_command Preface Table of Contents 1._Why_did_i_write_this_book? 2._Why_fiddle? 3._DocBook_! 4._DocBook/XML 4.1._Bouquets_Brickbats_Etc. 1. Why did i write this book? When I began writing this book, the first question I asked myself was how to install Linux on a server, and be sure that no one from the outside, or inside, could access it without authorization. Then I wondered if any method similar to the one on Windows® exists to improve the computers performance. Subsequently, I began a search on the Internet and read several books to get the most information on security and performance for my server. After many years of research and studies I had finally found the answer to my questions. These answers were found, all scattered throughout different documents, books, articles, and Internet sites. I created documentation based on my research that could help me through my daily activities. Through the years, my documentation grew and started to look more like a book and less like simple, scattered notes. I decide to publish it on the Internet so that anyone could take advantage of it. By sharing this information, I felt that I was doing my part for the community who answered so many of my computing needs with one magical, reliable, strong, powerful, fast and free operating system named Linux. I had received a lot of feedback and comments about my documentation, which helped to improve it over time. 2. Why fiddle? Madhu "Maddy" Abstract Is there a need to fiddle with what apparently is perfectly working and is serving the need. Well for one the i have choosen a format, XML, unlike the original manuscript which was written in word, in this case has the advantage of source being one and output can be in various format. That is if the source is in XML, it is easier now to convert into HTML, PDF, RTF etc. Also to prove to the sceptics that DocBook is very much suitable for large production quality projects, not that this is the first effort, in this case an entire book has been marked up in XML. Infact why XML indeed? XML -eXtensible Markup Language has been able to do justice to a large extent to the hype. Maybe having a watch body like w3.org to monitor has been advantageous; unlike HTML which lacked a formal monitoring, ability to extend, a weak structure and no support for validation, XML has all these and more. It is a system-independant, vendor-independant and has behind it the proven experience of SGML implementation, XML being a subset of SGML. I concur with Tim Bray's reported comment that it is ridiculous to use an application like MS Word, Quark Express etc.for writing text which will be stored as a binary and proprietory format therby bloating it considerably. And unlike HTML which has about aprox. 50-60 pre-cooked tags, with XML one can make up one's own. Infact this facility of having one's own tag will make it very, very useful in the long run. And the inherent factor that XML is all about content and nothing to do with presentation will be its greatest strength for years to come. The presentation part is taken care of by Stylesheet or FO or some such thing. 3. DocBook ! DocBook is a DTD - Document Type Definition. now what is this? well say for example having said XML is in itself a rule set , suppose i use an markup element tag in my document and another author uses element tag in his document, isn't it true we are trying to convey the same meaning .Imagine thousands of pages are being written for the web, for the publishing industry and what a waste of enormous time if people would like to convey similar meaning but use different elements with the core language being same, this is where an DTD comes into picture.     Docbook DTD is a very popular set of tags for describing books, articles and other prose documents, particularly technical documentation. Docbook is defined using the native DTD syntax of SGML and XML. Like HTML, DocBook is an example of a markup language defined in SGML/XML.  ---From the book DocBook - The Definitive Guide by Norman Walsh and Leonard Muellner. 4. DocBook/XML With the sole intent of making this book future proof, I have ported ( i am not sure this is the right term) this entire book into DocBook/XML.That the source being Markedup in XML, this ensures: * It will become platform independant and the source is not in any proprietory format like word. * It will be easy to have different outputs like HTML, PDF, RTF etc. With the never version of browsers supporting Raw XML as input with stylesheet being a seperate component, that this remains ready for that day when it becomes possible to have it converted on the fly. * That in the eventuality of me not being involved in the project at a later date, with the advent of professionals, there will be enough warm bodies to do this job. My fond hope is that this should not turn out be just a futile excersize and it proves usefull to everybody; atleast to some people even they are a small minority, the least of all to Gerhard Mourani, who is the author of this splendid book. 4.1. Bouquets Brickbats Etc. The idea behind this exercize primarily has been : * To give back something to the Linux community which has been instrumental in spearheading the spirit of sharing. * To create awareness about possibilities existing with the available tools set. But in the process some mistakes might have creeped in but there can be no excuse. Since this book has been looked at twice over; but still, i think the mistakes are entirely mine, if at all and not Gerhard's. So if you spot some glaring mistakes whether be it in the form of wrong or mis-information, typos or grammatical mistakes please do inform me at or you can even inform gerhard at . I am sure he will give a wallop on my backside( it is quite fragile!) so that such mistakes don't happen next time. Also welcome are the suggestions on how we could improve on this, so that next time round it will much be better. Here is hoping that this proves useful despite those already mentioned, creeped in mistakes, errors etc. and it kindles in you the same spirit which has embodied the growth of Linux as a powerful environement to work in. And if that happens i would consider myself highly obliged and this will prove to be a satisfying endevour for me personally. I have a feeling that the orginal author of this book Gerhard Mourani shares this thought of mine and probably agrees with me. Part 1. Getting Started Owl Table of Contents 1._Introduction 1._Audience 2._Organization_of_This_Book 3._Pre-requisites 4._Obtaining_the_book_and_example_configuration_files 4.1._Example_Configuration_files 5._Acknowledgements_from_Gerhard 5.1._Acknowledgements_from_"Maddy" Chapter 1. Introduction Table of Contents 1._Audience 2._Organization_of_This_Book 3._Pre-requisites 4._Obtaining_the_book_and_example_configuration_files 4.1._Example_Configuration_files 5._Acknowledgements_from_Gerhard 5.1._Acknowledgements_from_"Maddy" Abstract I realized that a lot of people wanted to see it published for its contents, to get advantages out of it and see the power of this beautiful Linux system in action. A lot of time and effort went into the making of this book, and to ensure that the results were as accurate as possible. If you find any abnormalities, inconsistent results, errors, omissions or anything else that doesn't look right, please let me know so I that can investigate the problem or correct the error. Suggestions for future versions are also welcome and appreciated. 1. Audience This book is intended for a target audience of technical and system administrators who manage Linux servers, but it also includes enough material for home users and others. It discusses how to install and setup a Red Hat Linux Server with all the necessary security and optimization for a high performance Linux specific machine. Since we speak of optimization and security configuration, we have used only source distribution (tar.gz) programs; the most available type for critical server software, like Apache, BIND/DNS, Samba, Squid, OpenSSL etc. Source packages give us fast upgrades, security updates when necessary, and a better compilation, customization, and optimization option for our specific machines that often we can't have with RPM packages. 2. Organization of This Book Depending of your level of knowledge in Linux, you can read this book from the start to finish or each chapter which may be of interest to you. Each chapter and section of this book appears in a manner that let you read only the relevant parts of your interest without the need to schedule a couple of day's reading. Too many books available as of now take two pages to explain something that can be explained in two lines, I'm sure that many of you agree with my opinion. This book attempts a different path, in the sense, only the essential and important information that the readers are interested in knowing are explained in detail thereby eliminating all the nonsense. Though the fact that you can read this book in any order you want, there is a particular order that you could follow if something seem to be confusing for you. The steps shown below is what I recommend to facilitate a smooth reading. Chapter_2 through Chapter_4 will guide you to do these steps: i. Setup Linux in your computer ii. Remove all the unnecessary RPM package(s) during setup iii. Install the necessary RPM package(s) for compilation Chapter_5 through Chapter_7 will guide you with these additional steps: i. Secure the system in general ii. Optimize the system in general iii. Install, recompile and customize the Kernel * Chapter_24 will guide you through this: i. Install OpenSSL to be able to use encryption with the Linux server * Chapter_15 will guide you through this: i. Install OpenSSH to be able to make remote administration tasks * Chapter_21 will guide you through this: i. Install BIND/DNS as client or server depending of your needs * Chapter_22 will guide you through this: i. Install Sendmail as client or server depending of your needs * Chapter_10 through Chapter_12 will guide you through these steps: i. Install & Configure the firewall script according to which services are installed in your system * Chapter_17 and Chapter_18 should guide you through this step: i. Install Tripwire Now for this step you will need to go through the book section wise to choose what you want. i. Install any software you need later. 3. Pre-requisites These installation instructions assume that: You have a CD-ROM drive on your computer and the Official Red Hat Linux CD-ROM. Installations were tested on the Official Red Hat Linux version 6.1 and 6.2. You should understand the hardware system on which the operating system will be installed. After examining the hardware, the rest of this document guides you, step-by-step, though the installation process. About products mentioned in this book: Many products, mentioned in this book; some commercial, but most are not commercial, cost nothing and can be freely used or distributed. It is also important to say that I'm not affiliated with any of them and if I mention a tool, because it is useful. You will find that a lot of big companies in their daily use, use most of them. 4. Obtaining the book and example configuration files Securing and Optimizing Linux: RedHat Edition is now also available to download around the most popular Linux web sites. Free formatted versions of this book can be found on the Internet via the following addresses listed below. From the original web site Open Network Architecturewww.openna.com The Linux Documentation Project homepage: www.linuxdoc.org O'Reilly Network: oreilly.linu.com/pub/d/25 Linux Security portal linuxsecurity.com/docs On the other hand you like the nice feel of paper and would like to browse through the pages at your convenience, you will have to purchase it. By_clicking_here! You can Buy here! It also comes with an accompanying CD filled with some nice goodies and all the example configuration files. Other related web sites may exist without my knowledge. If you host this book Securing and Optimizing Linux: RedHat Edition and want to be included in the list of the next release, please send me a message with your intentions. If you receive this as part of a printed distribution or on a CD-ROM, please check out the Linux Documentation home page www.linuxdoc.org/ or the original website at www.openna.com to see if there is a more recent version. This could potentially save you a lot of trouble. If you want to translate this book, please notify me so I can keep track of what languages I have been published in. 4.1. Example Configuration files The example configuration files in this book are available electronically via http from this website www.openna.com/books/floppy.tgz. In either case, be it from CDROM or if you have downloaded from the website extract the files from the archive by typing: [root@deep ]/tmp#tar xzpf floppy.tgz this is assuming you have stored the floppy.tgz in a directory called tmp/ . Errata Important As i was giving the final look over on this book, Gerhard Mourani has released an errata for all firewall scripts and it is available here http:// www.openna.com/books/errata.htm If you cannot get the examples directly over the Internet, please contact the author at these email addresses: 5. Acknowledgements from Gerhard I would like to thank Michel Méral who has drawn all the beautiful animal drawing in my book, Robert L. Ziegler for allowing me to include his Firewall software and all Linux users around the world for their comments and suggestions. 5.1. Acknowledgements from "Maddy" The book has been orginally written by Gerhard Mourani www.openna.com but i would like to thank him for collaborating with me in porting ( for the want of a better word).To say he was co-operative will be an under statement he was always there with a helping hand to answer my innumerable queries etc. Also i would like to thank the following people,but not in any particular order; Norman Walsh, http://nwalsh.com/~ndw/ for his phenominal and brilliant contribution to DocBook. To me at times looks like only one man contributing to its growth, popularity and in the process as well making it a mature product. Add to that he is a wonderful human being. My many many thanks to him. Peter Graves, http://armedbear.org for his Brilliant editor j, i do all my work using it and there are no words to describe it. i am indebted to him. I doubt very much if i could have worked for long stretches without it. Bryan Henderson, http://netpbm.sourceforge.net/ for his netpbm package and more than any thing for having the patience in dealing with my often persistent and idiotic queries. His software was mainly responsible for converting and manupilating all the orginal images which were in some esoteric format. Additionally i would also like to thank the following for releasing the right software at the right time: James clark, http://www.jclark.com/ for his xt and xp Michael Kay, http://users.iclway.co.uk/mhkay/saxon/ for Saxon To each and everyone at OASIS, http://www.oasis-open.org/docbook/ To each and everyone at Docbook.org, http://docbook.org/ To Sebestain Rahtz, http://users.ox.ac.uk/~rahtz/passivetex/ for his contribution to DocBook Mark Galassi for his brilliant Docbook Tutorial http://nis-www.lanl.gov/ ~rosalia/mydocs/ , My starting point!. The list would probably go on endlessly, and may be require a book for acknowledgements i guess. Part 2. Installation Turtle! Table of Contents 2._Overview_of_OS_Linux 1._What_is_Linux? 2._A_Few_good_reasons_to_use_Linux 3._Fears,_Uncertainity_and_Doubts 3._Installation_of_your_Linux_Server 1._Know_your_Hardware! 2._Creating_the_Boot_Disk_and_Booting 3._Installation_Class_and_Method_(Install_Type) 4._Disk_Setup-_Disk_Druid 5._Disk_Druid 6._An_example 7._Post-Partitioning 8._Components_to_Install-_Package_Group_Selection 9._Select_Individual_Package_-_Part_'A' 10._Select_Individual_Package_-Part_'B' 11._How_to_use_RPM_Commands 12._Starting_and_stopping_daemon_services 4._Post-Install 1._Software_that_must_be_uninstalled 2._Use_RPM_command_to_uninstall. 3._Software_that_must_be_installed 4._Check,Re-confirm 5._Verify,Cross-check 6._some_colors_for_a_change 7._Update_of_the_latest_software Chapter 2. Overview of OS Linux Table of Contents 1._What_is_Linux? 2._A_Few_good_reasons_to_use_Linux 3._Fears,_Uncertainity_and_Doubts This part of the book deals with all the basic knowledge required to properly install a Linux OS, in our case a Redhat Linux on your system. Introduction to Linux Steps to be taken prior to install Steps to be taken post install 1. What is Linux? Linux is an Operating System that was first created at the University of Helsinki in Finland by a young student named Linus Torvalds. At this time the student was working on a UNIX system that was running on an expensive platform. Because of his low budget, and his need to work at home, he decided to create a copy of the UNIX system in order to run it on a less expensive platform, such as an IBM PC. He began his work in 1991 when he released version 0.02 and worked steadily until 1994 when version 1.0 of the Linux Kernel was released. The current full-featured version at this time is 2.2.X; released January 25, 1999, and development continues. GNU GPL and Linux The Linux operating system is developed under the GNU General Public License (also known as GNU GPL) and its source code is freely available to everyone who downloads it via the Internet. The CD-ROM version of Linux is also available in many stores, and companies that provide it will charge you for the cost of the media and support. Linux may be used for a wide variety of purposes including networking, software development, and as an end-user platform. Linux is often considered an excellent, low-cost alternative to other more expensive operating systems because you can install it on multiple computers without paying more. 2.  A Few good reasons to use Linux There are no royalty or licensing fees for using Linux, and the source code can be modified to fit your needs. The results can be sold for profit, but original authors retain copyright and you must provide the source to your modifications. Because it comes with source code to the kernel, it is quite portable. Linux runs on more CPUs and platforms than any other computer operating system. The recent direction of the software and hardware industry is to push consumers to purchase faster computers with more system memory and hard drive storage. Linux systems are not affected by those industries orientation because of it capacity to run on any kind of computers, even aging x486-based computers with limited amounts of RAM. Linux is a true multi-tasking operating system similar to its brother UNIX. It uses sophisticated, state-of-the-art memory management to control all system processes. That means that if a program crashes you can kill it and continue working with confidence. Another benefit is that Linux is practically immunized against all kinds of viruses that we find in other operating systems. To date we have found only two viruses that were effective on Linux systems. 3. Fears, Uncertainity and Doubts Let's dispel some of the fear, uncertainty, and doubt about Linux: It's a toy operating system.  Fortune 500 companies, governments, and consumers; more and more use, Linux as a cost-effective computing solution. It has been used and is still used by big companies like IBM, Amtrak, NASA, and others. There's no support.  Every Linux distribution comes with more than 12,000 pages of documentation. Commercial Linux distributions such as Red Hat Linux, Caldera, SuSE, and OpenLinux offer initial support for registered users, and small business and corporate accounts can get 24/7 supports through a number of commercial support companies. As an Open Source operating system, there's no six-months to wait for a service release, and the online Linux community fixes many serious bugs within hours. Chapter 3. Installation of your Linux Server Table of Contents 1._Know_your_Hardware! 2._Creating_the_Boot_Disk_and_Booting 3._Installation_Class_and_Method_(Install_Type) 4._Disk_Setup-_Disk_Druid 5._Disk_Druid 6._An_example 7._Post-Partitioning 8._Components_to_Install-_Package_Group_Selection 9._Select_Individual_Package_-_Part_'A' 10._Select_Individual_Package_-Part_'B' 11._How_to_use_RPM_Commands 12._Starting_and_stopping_daemon_services The next two chapters is structured in a manner that follows the original installation of the Red Hat Linux CD-ROM. Each section below refers to, and will guide you through, different screens that will appear during the setup of your system after the insertion of the Red Hat boot diskette in your computer. We promise that it will be interesting to have the machine you want to install Linux on, ready and near to you when you follow the steps described below. From time to time Red Hat Linux updates its operating system to a new version and adds, changes or removes some packages as well as changes some locations, content or features of files in its distribution. Red Hat Recently has updated their version of operating system to 6.2 called Zoot, which is a minor upgrade of 6.1, so to be as accurate as possible about all information contained in these early chapters, we'll comment upon installation of version 6.1 as well as version 6.2 for those who will upgrade or install to it. Any sections in this chapter that refer to version 6.1 will be for the Red Hat Linux 6.1 (Cartman) distribution, and any section where we talk about version 6.2 will be for the Red Hat Linux 6.2 (Zoot) distribution, respectively. The following conventions will simplify the interpretations in these chapter: All versions This icon applies to Red Hat Linux version 6.1 and 6.2 respectively. Version 6.1 only This icon applies to Red Hat Linux version 6.1 only. Version 6.2 only This icon applies to Red Hat Linux version 6.2 only. We know that many organizations and companies handle different versions of this operating system, and run a number of services on them. Sometimes it may be difficult to upgrade to the latest version since clients use services on the server 24 hours a day. With this simple convention, people who maintain and use version 6.1 of Red Hat Linux will always find exact information related to their needs. 1. Know your Hardware! Understanding the hardware of your computer is essential for a successful installation of Red Hat Linux. Therefore, you should take a moment now and familiarize yourself with your computer hardware. Be prepared to answer the following questions: * How many hard drives do you have? * What size is each hard drive? e.g. 3.2GB. * If you have more than one hard drive, which is the primary one? * What kind of hard drive do you have? e.g. IDE, SCSI. * How much RAM do you have e.g. 256MB RAM. * Do you have a SCSI adapter? If so, who is the manufacturer and what model is it? * Do you have a RAID system? If so, who is the manufacturer and what model is it? * What type of mouse do you have e.g. PS/2, Microsoft, Logitech. * How many buttons does your mouse have? 2/3 buttons. * If you have a serial mouse, what COM port is it connected to? e.g. COM1. * What is the make and model of your video card? How much video RAM do you have? e.g. 4MB. * What kind of monitor do you have? Make and Model. * Will you be connected to a network? If so, what will be the following: * a. Your IP address? b. Your netmask? c. Your gateway address? d. Your domain name server's IP address? e. Your domain name? f. Your hostname? g. Your types of network(s) card(s)? Make and Model. h. Your number of card(s)? Make and Model. 2. Creating the Boot Disk and Booting The first thing to do is to create an installation diskette also known as a boot disk. If you have purchased the official Red Hat Linux CD-ROM, you will find this floppy disk named Boot Diskette in the Red Hat Linux box and you don't need to create it. From time to time, you may find that the installation will fail with the standard diskette image that comes with the official Red Hat Linux CD-ROM. If this happens, a revised diskette is required in order for the installation to work properly. In these cases, special images are available via the Red Hat Linux Errata web page to solve the problem www.redhat.com/errata. Since this, is a relatively rare occurrence, you will save time if you try to use the standard diskette images first, and then review the Errata only if you experience any problem completing the installation. Step 1.  Before you make the boot disk, insert the Official Red Hat Linux™ CD- ROM Part 1 in your computer that runs the Windows© operating system. When the program asks for the filename, enter boot.img for the boot disk. To make the floppies under MS-DOS©, you need to use these commands assuming your CD-ROM is drive D: and contain the Official Red Hat Linux© CD-ROM. Open the Command Prompt under Windows: Start | Programs | Command Prompt C:\> d: D:\> cd \dosutils D:\dosutils> rawrite Enter disk image source file name: ..\images\boot.img Enter target diskette drive: a: Please insert a formatted diskette into drive A: and press -- ENTER-- : D:\dosutils> The rawrite.exe program asks for the filename of the disk image: Enter boot.img and insert a floppy into drive A. It will then ask for a disk to write to: Enter a:, and when complete, label the disk; for example, Red Hat boot disk. Step 2.  Since we'd start the installation directly off the CD-ROM, boot with the boot disk. Insert the boot diskette you create into the drive A: on the computer where you want to install Linux and reboot the computer. At the boot:, press Enter to continue booting and follow the three simple steps below: Choose your language You can choose your prefferd language for the Linux OS from a list. For example, English, Danish etc Choose your keyboard type You can choose your Keyboard type. For example US pc104, norwegian etc Select your mouse type You can choose your mouse type. For example Logitech two button, Microsoft three button mouse etc 3. Installation Class and Method (Install Type) Red Hat Linux 6.1 and 6.2 include four different classes, or type of installation. They are: GNOME Workstation KDE Workstation Server Custom The first three classes GNOME Workstation, KDE Workstation, and Server give you the option of simplifying the installation process with a significant loss of configuration flexibility that we don't want to lose. For this reason we highly recommend Custom installation, as this allows you to choose what services are added and how the system is partitioned.The idea is to load the minimum number of packages, while maintaining maximum efficiency. The less software that resides on the box, the fewer potential security exploits or holes may appear.Select Custom and click Next 4. Disk Setup- Disk Druid Versian All We assume that you are installing your new Linux server to a new hard drive, with no other existing file system or operating system previously installed. A good partition strategy is to create a separate partition for each major file system. This enhances security and prevents accidental denial of service or exploit of SUID programs. Creating multiple partitions offers you the following advantages: Protection against denial of service attack. Protection against SUID programs. Faster booting. Easy backup and upgrade management. Ability for better control of mounted file system. Limit each file system's ability to grow. Warning If previous file system or operating system exist on the hard drive and computer where you want to install your Linux system, we highly recommend, that you make a backup of your current system before proceeding with the disk partitioning. Step 1.  For performance, stability and security reasons you must create something like the following partitions listed below on your computer. We suppose for this partition configuration the fact that you have a SCSI hard drive of 3.2 GB. Of course you will need to adjust partition sizes according to your own needs and disk size. Partitions that must be created on your system: /boot 5MB 1 /usr 512MB 2 /home 1146MB 3 /chroot 256MB 4 /cache 256MB 5 /var 256MB 6 128MB 7 /tmp 256MB 8 / 256MB 9 _1_ All Kernel images are kept here. _2_ Must be large, since all Linux binaries programs are installed here. _3_ Proportional to the number of users you intend to host i.e. 10MB per users multiplied by the number of users 114 = 1140MB. _4_ If you want to install programs in chroot jail environment i.e. DNS. _5_ This is the cache partition of a proxy server i.e. Squid. _6_ Contains files that change when the system run normally i.e. Log files. _6_ Our swap partition. The virtual memory of the Linux operating system. _8_ Our temporary files partition. _9_ Our root partition. We have made two more special partitions: /chroot The /chroot partition can be used for DNS server chrooted, Apache server chrooted and other chrooted future programs. /cache The /cache partition can be used for a Squid Proxy server. If you are not intending to install Squid Proxy server you don't need to create the /cache partition. Keeping /tmp and /home on separate partitions is pretty much mandatory if users have shell access to the server- protection against SUID programs; splitting these off into separate partitions also prevent users from filling up any critical file system -denial of service attack. The same applies to /var, and / usr on separate partitions is also a very good idea. By isolating the /var partition, you protect your root partition from overfilling -denial of service attack. In our partition configuration we'll reserve 256 MB of disk space for chrooted programs like Apache, DNS and other software. This is necessary because Apache DocumentRoot files and other binaries, programs related to Apache will be installed in this partition if you decide to run Apache web server in a chrooted jail. Take note that the size of the Apache chrooted directory on the chrooted partition is proportional to the size of your DocumentRoot files. If you're not intending to install and use Apache on your server, you can reduce the size of this partition to something like 10 MB for DNS server that you always need in a chrooted jail environment for security reasons. Minimum size of partitions Note For information purposes only, this is the minimum size in megabytes, which a Linux installation must have to function properly. The sizes of partitions listed below are really small. This configuration can fit into a very old hard disk of 512MB in size that you might find in old x486 computers. We show you this partition just to get an idea of the minimum requirements. / 35MB /boot 5MB /chroot 10MB /home 100MB /tmp 30MB /usr 232MB /var 25MB 5. Disk Druid Disk Druid Partitions is a program that partitions your hard drive for you. Choose Add to add a new partition, Edit to edit a partition, Delete to delete a partition and Reset to reset the partitions to the original state. When you add a new partition, a new window appears on your screen and gives you parameters to choose. Different parameters are: Mount Point: for where you want to mount your new partition in the filesystem. Size (Megs): for the size of your new partition in megabytes. Partition Type: Linux native for Linux filesystem and Swap for Linux Swap Partition. Note If you have a SCSI disk the device name will be /dev/sda and if you have an IDE disk it will be /dev/hda. If you're looking for high performance and stability, a SCSI disk is highly recommended. Linux refers to disk partitions using a combination of letters and numbers. It uses a naming scheme that is more flexible and conveys more information than the approach used by other operating systems. Here is a summary: Disk naming convention First Two Letters The first two letters of the partition name indicate the type of device on which the partition resides. You'll normally see either hd (for IDE disks), or sd (for SCSI disks). The Next Letter This letter indicates which device the partition is on. For example: / dev/hda (the first IDE hard disk) and /dev/hdb (the second IDE disk). Keep this information in mind, it will make things easier to understand when you're setting up the partitions Linux requires. Swap partitions are used to support virtual memory. If your computer has 16 MB of RAM or less, you must create a swap partition. Even if you have more memory, a swap partition is still recommended. The minimum size of your swap partition should be equal to your computer's RAM or 16 MB (whichever is larger). The largest useable swap partition is roughly 1 GB, since 2.2 kernel, 1 GB swap file are supported so making a swap partition larger than that will result in wasted space. Note, however, that you can create and use more than one swap partition although this is usually only necessary for very large server installations. Try to put your swap partitions near the beginning of your drive. The beginning of the drive is physically located on the outer portion of the cylinder, so the read/write head can cover much more ground per revolution. Linux Partitions representation of linux partition 6. An example To make the partitions listed below on your system; this is the partition we'll need for our server installation example; the command will be under Disk Druid: Add Mount Point: /boot our /boot directory. Size (Megs): 5 Partition Type: Linux Native Ok Add Mount Point: /usr our /usr directory. Size (Megs): 512 Partition Type: Linux Native Ok Add Mount Point: /home our /home directory. Size (Megs): 1146 Partition Type: Linux Native Ok Add Mount Point: /chroot our /chroot directory. Size (Megs): 256 Partition Type: Linux Native Ok Add Mount Point: /cache our /cache directory. Size (Megs): 256 Partition Type: Linux Native Ok Add Mount Point: /var our /var directory. Size (Megs): 256 Partition Type: Linux Native Ok Add Mount Point: our /Swap partition leave the Mount Point Blank. Size (Megs): 128 Partition Type: Linux Swap Ok Add Mount Point: /tmp our /tmp directory. Size (Megs): 256 Partition Type: Linux Native Ok Add Mount Point: / our / directory. Size (Megs): 256 Partition Type: Linux Native Ok After the partitions of your hard disk has been completed, you must see something like the following information on your screen. Our mount points will look like this: Table 3.1. Sample representaion of partitions Mount Point Device Requested Actual Type /boot sda1 5M 5M Linux Native /usr sda5 512M 1146M Linux Native /home sda6 256M 256M Linux Native /chroot sda7 256M 256M Linux Native /cache sda8 256M 256M Linux Native /var sda9 256M 256M Linux Native sda10 128M 128M Linux Swap /tmp sda11 256M 256M Linux Native / sda12 256M 256M Linux Native _______________________________________________________ |Drive|Geom_[C/H/S]|Total_(M)|Free_(M)|Used_(M)|Used_(%)| |sda__|[3079/64/32]|3079M____|1M______|3078M___|99%_____| Note We are using a SCSI hard disk hence the first two letters of the device are sd. 7. Post-Partitioning Now that you are partitioning and choosing the mount point of your directories, select Next to continue. After your partitions are created, the installation program will ask you to choose partitions to format. Choose the partitions you want to initialize, check the (Check for bad blocks during format) box, and press Next. This formats the partitions and makes them active so Linux can use them. On the next screen you will see the LILO Configuration where you have the choice to install LILO boot record on: Master Boot Record (MBR) Or First Sector of Boot Partition Usually if Linux is the only OS on your machine you should choose the Master Boot Record (MBR) option. After that, you need to configure your Network and Clock. After you finish configuring the clock, you need to give your system a root password and authentication configuration. For Authentication Configuration don't forget to select: Enable MD5 passwords Enable Shadow passwords Enable NIS doesn't need to be selected since we are not configuring NIS services on this server. 8.  Components to Install- Package Group Selection After your partitions have been configured and selected for formatting, you are ready to select packages for installation. By default, Linux is a powerful operating system that executes many useful services. However, many of these services are unneeded and pose potential security risks. Ideally, each network service should be on a dedicated, single-purpose host. Many Linux operating systems are configured by default to provide a wider set of services and applications than are required to provide a particular network service, so you may need to configure the server to eliminate unneeded services. Offering only essential services on a particular host can enhance your network security in several ways: * Other services cannot be used to attack the host and impair or remove desired network services. * Different individuals may administer different services. By isolating services so each host and service has a single administrator you will minimize the possibility of conflicts between administrators. * The host can be configured to better suit the requirements of the particular service. Different services might require different hardware and software configurations, which could lead to needless vulnerabilities or service restrictions. By reducing services, the number of logs and log entries is reduced so detecting unexpected behavior becomes easier. A proper installation of your Linux server is the first step to a stable, secure system. You first have to choose which system components you want to install. Choose the components, and then you can go through and select or deselect each individual package of each component by selecting Select individual packages option on your Red Hat setup screen. Since we are configuring a Linux Server, we don't need to install a graphical interface XFree86 on our system, a graphical interface on a server means less processes, less CPU availability, less memory, security risks, and so on. Graphical interfaces are usually used on workstations only. Select the following packages for installation: Networked Workstation Network Management Workstation Utilities After selecting the components you wish to install, you may select or deselect packages. Important Select the Select individual packages options before continuing to have the option to select and deselect packages. 9. Select Individual Package - Part 'A' The installation program presents a list of the package groups available. Select a group to examine. The components listed below must be deselected from the Menu Group for security; optimization and other reasons described below: All versions Applications/File:  git The GIT package provides an extensible file system browser, an ASCII/ hexadecimal file viewer, a process viewer/killer and other related utilities and shell scripts. Unnecessary. All versions Applications/Internet:  finger The finger package is a client utility, which allows users to see information about system users. Security risks. ftp The ftp package provides the standard UNIX command-line FTP client. Security risks. fwhois The fwhois client program allows for querying whois databases. Security risks. ncftp The Ncftp package is an improved FTP client. [Security risks, Unnecessary. rsh The rsh package provides client programs, which allows users to run commands on remote machines, login to other machines and copy files between machines (rsh, rlogin and rcp). Security risks. rsync rsync is very powerfull mirroring program, which brings very quickly remote and host files into sync. Unnecessary talk The ntalk package provides client and daemon programs for the Internet talk protocol, which allows you to chat with other users on different UNIX systems. Security risks. telnet Telnet is a popular protocol for logging into remote systems over the network but it is insecure (transfer password in plain text). Security risks. All versions Applications/Publishing:  ghostscript The GhostScript package is a set of software that provides a PostScript interpreter, and an interpreter for Portable Document Format PDF files. Unnecessary ghostscript-fonts The GhostScript interpreter can use the Ghostscript-fonts package during text rendering. Unnecessary. Version 6.2 only groff-perl The groff-perl package is a set of commands and print filter used in printer environment. Unnecessary, no printer installed on the server. Version 6.2 only mpage The mpage package utility takes plain text files or PostScript documents as input, reduces the size of the text, and prints the files on a PostScript printer with several pages on each sheet of paper. Unnecessary, no printer installed on the server Version 6.2 only pnm2ppa The pnm2ppa package is a color driver for printing to HP PPA printers. Unnecessary, no printer installed on the server. rhs-printfilters The rhs-printfilters package contains a set of print filters, which is primarily meant to be use with the Red Hat printtool. Unnecessary, no printer installed on the server Version all Applications/System:  arpwatch The arpwatch package contains utilities to monitor Ethernet or FDDI network traffic and build databases of Ethernet/IP address pairs. Unnecessary bind-utils The bind-utils package contains a collection of utilities to find out information about Internet hosts. We will compile it later on this book. Version 6.1 only knfsd-clients The knfsd-clients package contains the showmount program that queries the mount daemon on a remote host for information about the NFS server on the remote host. Security risks, and NFS services are not installed on this server. Version 6.1 only procinfo The procinfo package acquires information about your system from the kernel as it is running. Unnecessary, other methods exist. rdate The rdate package utility can retrieve the date and time from another machine on your network. Security risks. rdist The rdist package is a program that maintains identical copies of files on multiple hosts. Security risks. screen This screen package is a useful utility for users who telnet into a machine or are connected via a dumb terminal, but want to use more than just one login. Unnecessary ucd-snmp-utils The ucd-snmp-utils package contains various utilities for use with the ucd-snmp network management project. Unnecessary, Security risks Version All Documentation:  indexhtml The indexhtml package contains the HTML page and graphics for a welcome page shown by your Web browser into X Window Systems. Unnecessary,we don't use graphical interface. 10. Select Individual Package -Part 'B' Version All System Environment/Base:  chkfontpath The chkfontpath package is a simple program for adding, removing and listing the directories contained in the X font server's path. Unnecessary, we don't use graphical interface yp-tools The Network Information Service NIS is a system, which provides and centralizes network information; login names, passwords, home directories, and group information, to all of the machines on a network. Security risks, we don't use it on our server Version All System Environment/Daemons: .  XFree86-xfs The XFree86-xfs package is a font server for XFree86 that can also serve fonts to other X servers remotely. Unnecessary, we don't use graphical interface Version 6.2 only finger-server The finger-server package contain the finger daemon that runs from the / etc/inetd.conf, file and allows users to see information about system users on the server. Security risks. lpr The lpr package provides the basic system utility for managing printing services. Unnecessary and no printer installed on the server Version 6.2 only nfs-utils The nfs-utils package provides the tools and daemon for the kernel NFS server. This package must be installed if you want to provide NFS services on your server. Security risks, and NFS services are not installed on this server. pidentd The pidentd package contains the identd, which looks up specific TCP/IP connections and returns either the user name or other information about the process that owns the connection. Unnecessary, very few things on the net require the sender to be running identd, because many machines don't have it and because many people turn it off. portmap The portmapper package manages RPC connections, which are used by protocols like NFS and NIS. Unnecessary, Security risks, and NIS/NFS services are not installed on this server. Version 6.2 only rsh-server The rsh-server package provides the servers needed for (rsh, rlogin, rcp) which allow users to run remote access commands on remote machines. Security risks rusers The routed package routing daemon maintains current routing tables by handling incoming RIP traffic and broadcasts outgoing RIP traffic about network traffic routes. Unnecessary, Security risks, and limited. Version 6.2 only rusers-server The rusers package program allows users to find out who is logged into various machines on the local network. Security risks. Version 6.2 only rwall-server The rwall-server package contains the daemon which allows receiving remote messages from users in remote hosts. Security risks rwho The rwho package shows who is logged in for all machines on the local network running the rwho daemon. Security risks. Version 6.2 only talk-server The talk-server package provides the daemon program, which allows you to chat via terminal with other users on remote UNIX systems.™ Security risks. Version 6.2 only telnet-server The telnet-server package provides the daemon, which allows telnet remote logins protocol to your server. Security risks, replace by SSH Version 6.1 only tftp The tftp package or Trivial File Transfer Protocol TFTP allows users to transfer files to and from a remote machine. It is normally used only for booting diskless workstations. Security risks, Unnecessary. Version 6.2.only tftp-server The tftp-server package provides the server for (TFTP), which allows users to transfer files to and from a remote machine. Security risks, Unnecessary. ucd-snmp The ucd-snmp package or SNMP -Simple Network Management Protocol is a protocol used for network management. Unnecessary, Security risks Version All ypbind The ypbind package is a daemon which binds NIS -Network Information Service server client to NIS server. Security risks, we don't use it on our server. Version 6.2 only ypserv The ypserv package is the NIS -Network Information Service server, which provides network information (NIS) to all of the machines on a network. Security risks, we don't use it on our server Version All System Environment/Libraries:  XFree86-libs The XFree86-libs package contains the shared libraries that most X programs need to run properly. Unnecessary, we dont use graphical interface. libpng The libpng package contains a library of functions for creating and manipulating GIF image format files. GIF is a bit-mapped graphics format similar to the GIF format. Unnecessary. User Interface/X:  Version 6.1 only XFree86-75dpi-fonts The XFree86-75dpi-fonts package contains the 75 dpi fonts (the standard fonts) used on most X Window Systems. Unnecessary, we don't use graphical interface. Version 6.2 only urw-fonts The urw-fonts package contain free versions of the 35 standard Type 1 PostScript fonts. Unnecessary, we don't use graphical interface. 11. How to use RPM Commands This section contains an overview of principal modes using with RPM for installing, uninstalling, upgrading, querying, listing, and checking RPM packages on your Linux system. You must be familiar with these RPM commands now because we'll use them often in the continuation of this book. To install a RPM package, use the command: [root@deep] /#rpm -ivh foo-1.0-2.i386.rpm Take a note that RPM packages have a file of names like foo-1.0-2.i386.rpm, which include the package name (foo), version (1.0), release (2), and architecture (i386). To uninstall a RPM package, use the command: [root@deep] /#rpm -e foo Notice that we used the package name foo, not the name of the original package file foo-1.0-2.i386.rpm. To upgrade a RPM package, use the command: [root@deep] /#rpm -Uvh foo-1.0-2.i386.rpm With this command, RPM automatically uninstall the old version of foo package and install the new one. Always use rpm -Uvh to install packages, since it works fine even when there are no previous versions of the package installed. To query a RPM package, use the command: [root@deep] /#rpm -q foo This command will print the package name, version, and release number of installed package foo. Use this command to verify that a package is or is not installed on your system. To display package information, use the command: [root@deep] /#rpm -qi foo This command display package information; includes name, version, and description of the installed program. Use this command to get information about the installed package. To list files in package, use the command: [root@deep] /#rpm -qlfoo This command will list all files in a installed RPM package. It works only when the package is already installed on your system. To check a RPM signature package, use the command: [root@deep] /#rpm --checksig foo This command checks the PGP signature of specified package to ensure its integrity and origin. Always use this command first before installing new RPM package on your system. Also, GnuPG or Pgp software must be already installed on your system before you can use this command. 12. Starting and stopping daemon services The init program of Linux -also known as process control initialization, is in charge of starting all the normal and authorized processes that need to run at boot time on your system. These may include the APACHE daemons, NETWORK daemons, and anything else that must be running when your machine boots. Each of these processes has a script under /etc/rc.d/init.d/ directory written to accept an argument, which can be start, stop and restart. You can execute those scripts by hand in fact with a command: Example 3.1. Starting and Stopping various Daemon's To start the httpd Web Server manually under Linux. [root@deep] /# /etc/rc.d/init.d/httpd start          Starting httpd:                        [OK]           To stop the httpd Web Server manually under Linux. [root@deep] /# /etc/rc.d/init.d/httpd stop          Shutting down http:             [OK]           To restart the httpd Web Server manually under Linux. [root@deep] /# /etc/rc.d/init.d/httpd restart          Shutting down http:              [OK]          Starting httpd:                 [OK]           Check inside your /etc/rc.d/init.d/ directory for services available and use command start | stop | restart to work around. Chapter 4. Post-Install Table of Contents 1._Software_that_must_be_uninstalled 2._Use_RPM_command_to_uninstall. 3._Software_that_must_be_installed 4._Check,Re-confirm 5._Verify,Cross-check 6._some_colors_for_a_change 7._Update_of_the_latest_software This entire chapter deals with the steps to be taken after the installation of your server, for example, uninstallation of certain programs which are going to compiled on your server using source tarballs, installation of certain programs required to compile these source tarballs etc 1. Software that must be uninstalled Red Hat Linux installs other pre-compiled binaries of programs on your system by default and doesn't give you the choice to uninstall them during the install setup. For this reason, you must uninstall the following software on your system after the installation of your server.We must uninstall them for better security and to make space in our server. For more information and explanation of their capabilities and uses, please see your Red Hat manual or install the package and make an rpm -qi foo command to query and get a detailed description of the program, and then uninstall it again. Below is the list of programs and a short description of their utilizations. Version All pump The Pump DHCP package allows individual diskless clients on a network to get their own IP network configuration information from network servers. Unnecessary. Version All mt-st The mt -for magnetic tape drives and st -for SCSI tape devices tape drive management programs can control rewinding, ejecting, skipping files, blocks and more. Necessary only if you have a tape backup on this server. Version All eject The eject package contains an eject program that allows the user to eject removable media typically CD-ROMs, floppy disks, Iomega Jaz or Zip disks using software control. Necessary only if you have a tape backup on this server. Version All Metamail Metamail is a program that uses the mailcap file to determine how it should display non-text or multimedia material. Unnecessary. Version All apmd The apmd package, or advanced Power Management daemon utilities, can watch your notebook's battery and warn all users when the battery is low. Unnecessary for a server. Version All kernel-pcmcia-cs The kernel-pcmcia-cs package is for laptop machines and some non-laptops that support PCMCIA cards for expansion. Unnecessary for a server. Version All linuxconf The linuxconf package is a system configuration tool. Unnecessary, buggy program. Version All getty_ps The getty_ps package contains programs that are used to accept logins on the console or a terminal on your system. Unnecessary. Version 6.1 only setconsole The setconsole package is a basic system utility for setting up the /etc/ inittab, /dev/systty and /dev/console files to handle a new console. Unnecessary. Version All isapnptools The isapnptools package contains utilities for configuring ISA Plug-and- Play (PnP) cards/boards. Unnecessary. Version All setserial The setserial package is a basic system utility for displaying or setting serial port information. Unnecessary. Version All kudzu The kudzu package is a hardware-probing tool run at system boot time to determine what hardware has been added or removed from the system. Unnecessary. version All raidtools The raidtools package includes the tools you need to set up and maintain a software RAID device on a Linux system. Depending if you use Raid or not. Version All gnuPG The GnuPG package is a tool for secure communication and data storage. It is a replacement for the PGP software. It can also be used to encrypt data and to create digital signatures. We will compile it later on our book. Version All redhat-logos The redhat-logos package contains files of the Red Hat "Shadow Man" logo and the RPM logo. Unnecessary on a server. Version All redhat-release The redhat-release package contains the Red Hat Linux release file. Unnecessary. Version All gd The gd package allows your code to quickly draw images and write out the result as a .gif file. Unnecessary. Version All pciutils The pciutils package contains various utilities for inspecting and setting devices connected to the PCI bus. We use other methods. Version All rmt The rmt utility provides remote network access to make backup. Security risks since rmt depends on rsh to work. 2. Use RPM command to uninstall. The command to uninstall software is: [root@deep] /#rpm -e Where is the name of the software you want to uninstall e.g. (foo). Since Programs like apmd, kudzu, and sendmail are daemons that run as process. It is better to stop those processes before uninstalling them from the system.To stop those processes, use the following commands: [root@deep] /# /etc/rc.d/init.d/apmd stop [root@deep] /# /etc/rc.d/init.d/sendmail stop [root@deep] /# /etc/rc.d/init.d/kudzu stop 1. Version 6.1 only Now you can uninstall them safely, and all other packages, as shown below: Remove the specified packages for Red Hat Linux version 6.1 (Cartman). [root@deep] /# rpm -e --nodeps pump mt-st eject mailcap apmd kernel-pcmcia-cs linuxconf getty_ps setconsole isapnptools setserial kudzu raidtools gnupg redhat-logos redhat-release gd pciutils rmt Version 6.2. only Remove the specified packages for Red Hat Linux version 6.2 (Zoot). [root@deep] /# rpm -e --nodeps pump mt-st eject mailcap apmd kernel-pcmcia-cs linuxconf getty_ps isapnptools setserial kudzu raidtools gnupg redhat-logos redhat-release gd pciutils rmt 2. Version All Remove the linux.conf-installed file manually. [root@deep] /# rm -f /etc/conf.linuxconf-installed Note This is a configuration file related to linuxconf software that must be removed manually. The program hdparm is needed by IDE hard disk but not SCSI hard disks. If you have an IDE disk on your system you must keep this program (hdparm), but if you don't have an IDE hard disk you can remove it safely from your system. To remove hdparm from your system, use the following command: [root@deep] /# rpm -e hdparm Use the programs kbdconfig, mouseconfig, timeconfig, authconfig, ntsysv, and setuptool in order to set your keyboard language and type, your mouse type, your default time zone, your NIS and shadow passwords, your numerous symbolic links in /etc/rc.d directory, and text mode menu utility which allow you to access all of these features. After those configurations have been set during the installation stage of your Linux server it's rare that you would need to change them again. So, you can uninstall them, and if in future you need to change your keyboard, mouse, default time, etc again via test mode menu, all you have to do is to install the program with the RPM from your original CD- ROM. To remove all the above programs from your system, use the following command: [root@deep] /# rpm -e kbdconfig mouseconfig timeconfig authconfig ntsysv setuptool Even if you are not intending to install a mail server on your Linux system, the program Sendmail is always needed on your servers for potential messages sent to the root user by different software services installed on your machine. Sendmail is a Mail Transport Agent -MTA program that sends mail from one machine to another. It can be configured in different manners; it can serve as an internal delivery mail system to a Mail Hub Server, or can be configured to be a Central Mail Hub Server for all Sendmail machines on your network. So depending on what you want to do with Sendmail, you must configure it to respond to your specific needs. For this reason you must uninstall Sendmail and see the relevant sections in this book that is related to Sendmail configuration and installation. To remove Sendmail from your system, use the following command: [root@deep] /# rpm -e sendmail 3. Software that must be installed There are certain programs required to be able to compile programs on your server, hence you must install the following RPM packages. This part of the installation is very important and requires that you install all related packages described below. These are on your Red Hat Part 1 CD-ROM under RedHat/ RPMS directory and represent the base necessary software needed on Linux to compile and install programs. 1. First, we mount the CD-ROM drive and move to the RPMS subdirectory of the CD-ROM. To mount the CD-ROM drive and move to RPM directory, use the following commands: [root@deep] /# mount /dev/cdrom /mnt/cdrom/ [root@deep] /# cd /mnt/cdrom/RedHat/RPMS/ In the process of customizing our linux server, we will be using, most of the time source tarballs rather than pre-compiled RPMs hence these are the packages that we need to be able to compile and install programs. Remember, this is the minimum package that will allow you to compile most of the tarballs available for Linux. Other compiled binary packages exist on the Red Hat CD-ROM, so verify with the README file that came with the tarballs program you want to install if you receive an error messages during compilation of the specific software. Version 6.1 only m4-1.4-12.i386.rpm egcs-1.1.2-24.i386.rpm dev86-0.14.9-1.i386.rpm ElectricFence-2.1-1.i386.rpm bison-1.28-1.i386.rpm flex-2.5.4a-7.i386.rpm byacc-1.9-11.i386.rpm gdb-4.18-4.i386.rpm cdecl-2.5-9.i386.rpm kernel-headers-2.2.12-20.i386.rpm cpp-1.1.2-24.i386.rpm glibc-devel-2.1.2-11.i386.rpm cproto-4.6-2.i386.rpm make-3.77-6.i386.rpm ctags-3.2-1.i386.rpm patch-2.5-9.i386.rpm Version 6.2 only m4-1.4-12.i386.rpm egcs-1.1.2-30.i386.rpm dev86-0.15.0-2.i386.rpm ElectricFence-2.1-3.i386.rpm bison-1.28-2.i386.rpm flex-2.5.4a-9.i386.rpm byacc-1.9-12.i386.rpm gdb-4.18-11.i386.rpm cdecl-2.5-10.i386.rpm kernel-headers-2.2.14-5.0.i386.rpm cpp-1.1.2-30.i386.rpm glibc-devel-2.1.3-15.i386.rpm cproto-4.6-3.i386.rpm make-3.78.1-4.i386.rpm ctags-3.4-1.i386.rpm patch-2.5-10.i386.rpm Note It is better to install software mentioned above in one shot, if you don't want to receive error message regarding dependencies during RPM install. 2. Version 6.1 only Install all the needed software above with one RPM command. The RPM command to install all software together is: [root@deep ] /RPMS#rpm -Uvh m4-1.4-12.i386.rpm dev86-0.14.9-1.i386.rpm bison-1.28-1.i386.rpm byacc-1.9-11.i386.rpm cdecl-2.5-9.i386.rpm cpp-1.1.2-24.i386.rpm cproto-4.6-2.i386.rpm ctags-3.2-1.i386.rpm egcs- 1.1.2-24.i386.rpm ElectricFence-2.1-1.i386.rpm flex-2.5.4a-7.i386.rpm gdb-4.18-4.i386.rpm kernel-headers-2.2.12-20.i386.rpm glibc-devel-2.1.2- 11.i386.rpm make-3.77-6.i386.rpm patch-2.5-9.i386.rpm Version 6.2 only Install all the needed software above with one RPM command. The RPM command to install all software together is: [root@deep ] /RPMS#rpm -Uvh m4-1.4-12.i386.rpm dev86- 0.15.0-2.i386.rpm bison-1.28-2.i386.rpm byacc-1.9-12.i386.rpm cdecl-2.5- 10.i386.rpm cpp-1.1.2-30.i386.rpm cproto-4.6-3.i386.rpm ctags-3.4-1.i386.rpm egcs- 1.1.2-30.i386.rpm ElectricFence-2.1-3.i386.rpm flex-2.5.4a-9.i386.rpm gdb-4.18-11.i386.rpm kernel-headers-2.2.14-5.0.i386.rpm glibc-devel- 2.1.3-15.i386.rpm make-3.78.1-4.i386.rpm patch-2.5-10.i386.rpm The RPM package has many options, for example we have used the following sytax: rpm [-Uvh] [file] you might be curious to know what these arguments -Uvh means, why should it be given at all etc.Here is a brief description: -U -stands for Upgrade which will uninstall an older version of the package you are installing and install the new one, which will eliminate the error likely to occur if in case the package being uninstalled has dependencies. It is generally recomded to use this argument even while you are obsolutely sure that there is no earlier version of the package you are trying to install is existing on your machine. v -stands for verbose, which is quite self explanatory. This argument ensures all messages are written to the stdout/console so you get to know what is happening. h -this generates the hash mark # in a series, this will give a sense of visual progress with the install process . So, when you use rpm -Uvh, whether it is Redhat ver 6.1 or ver 6.2, what you see on your console is shown below,Notice in the display that the name of the package is seen but not the version number. Infact we have mentioned this earlier in this book that when you install or upgrade you have to enter the package name with version name, for example rpm -ivh mnt-1.0.4.rpm but while querying the same package using rpm command the syntax is as follows: rpm -qi mnt, Please do keep this mind. Given below is a graphical representation of your screen when you install the above mentioned rpm's : version all m4 ################################################## dev86 ################################################## bison ################################################## byacc ################################################## cdecl ################################################## cpp ################################################## cproto ################################################## ctags ################################################## egcs ################################################## ElectricFence ################################################## flex ################################################## gdb ################################################## kernel-headers ################################################## glibc-devel ################################################## make ################################################## patch ################################################## You must exit and re-login for all the change to take effect. To exit from your console, use the command: [root@deep] /# exit 4. Check,Re-confirm After installation and compilation of all programs you need on your server, it's a good idea to remove all unnecessary programs (compilers, etc) described above unless needed it is obsolutely needed by the system. Few reasons are: * If a cracker gains access to your server he or she cannot compile or modify binary programs. Also, this will free a lot of space and will help to improve regular scanning of files on your server for integrity checking. * When you run a server you will give it a special task to accomplish. You will never put all services you want to offer in one machine or you will lose speed - resources available divided by the number of process running on the server. * Decrease your security with a lot of services running on the same machine, if a cracker accesses this server, he or she can attack directly all the others available. * Having different servers doing different tasks will simplify the administration, management you know what task each server is supposed to do, what services should be available, which ports are open to clients access and which one are closed, you know what you are supposed to see in the log files, etc, and give you more control and flexibility on each server dedicated for mail, web pages, database, development, backup, etc. * For example, having one server specialized just for development and testing will permit you to not be compelled to install compiler programs on a server each time you want to compile and install new software on it, and be obliged afterwards to uninstall the compilers, or other sharp objects. If you have followed each step exactly as described till now, Since we have chosen to customize the installation of our Linux system, this is the list of all installed programs that you must have on your server after the complete installation of the Linux Server. This list must match exactly the install.log file located in your /tmp directory or you could run into a problem. Don't forget to install all programs listed above in Software_that_must_be_installed after installation of the Server to be able to compile programd properly on your Server. Version 6.1 only Installing setup. Installing gawk. Installing netkit-base. Installing filesystem. Installing gd. Installing newt. Installing basesystem. Installing gdbm. Installing ntsysv. Installing ldconfig. Installing getty_ps. Installing passwd. Installing glibc. Installing glib. Installing pciutils. Installing shadow-utils. Installing gmp. Installing perl. Installing mktemp. Installing gnupg. Installing procmail. Installing termcap. Installing gpm. Installing procps. Installing libtermcap. Installing groff. Installing psmisc. Installing bash. Installing gzip. Installing pump. Installing MAKEDEV. Installing hdparm. Installing python. Installing SysVinit. Installing initscripts. Installing quota. Installing XFree86-Mach64. Installing ipchains. Installing raidtools. Installing chkconfig. Installing isapnptools. Installing readline. Installing apmd. Installing kbdconfig. Installing redhat-logos. Installing ncurses. Installing kernel. Installing rootfiles. Installing info. Installing kernel-pcmcia- Installing rpm. cs. Installing fileutils. Installing kudzu. Installing sash. Installing grep. Installing ld.so. Installing sendmail. Installing ash. Installing less. Installing setconsole. Installing at. Installing libc. Installing setserial. Installing authconfig. Installing libstdc++. Installing setuptool. Installing bc. Installing lilo. Installing shapecfg. Installing bdflush. Installing pwdb. Installing slang. Installing binutils. Installing pam. Installing slocate. Installing bzip2. Installing sh-utils. Installing stat. Installing sed. Installing redhat-release. Installing sysklogd. Installing console-tools. Installing linuxconf. Installing tar. Installing e2fsprogs. Installing logrotate. Installing tcp_wrappers. Installing rmt. Installing losetup. Installing tcpdump. Installing cpio. Installing lsof. Installing tcsh. Installing cracklib. Installing mailcap. Installing time. Installing cracklib-dicts. Installing mailx. Installing timeconfig. Installing crontabs. Installing man. Installing timed. Installing textutils. Installing mingetty. Installing tmpwatch. Installing dev. Installing mkbootdisk. Installing traceroute. Installing diffutils. Installing mkinitrd. Installing utempter. Installing dump. Installing modutils. Installing util-linux. Installing ed. Installing mount. Installing vim-common. Installing eject. Installing mouseconfig. Installing vim-minimal. Installing etcskel. Installing mt-st. Installing vixie-cron. Installing file. Installing ncompress. Installing which. Installing findutils. Installing net-tools. Installing zlib. Version 6.2 only Installing setup. Installing gawk. Installing ncompress. Installing filesystem. Installing gd. Installing net-tools. Installing basesystem. Installing gdbm. Installing newt. Installing ldconfig. Installing getty_ps. Installing ntsysv. Installing glibc. Installing glib. Installing passwd. Installing shadow-utils. Installing gmp. Installing pciutils. Installing mktemp. Installing gnupg. Installing perl. Installing termcap. Installing gpm. Installing popt. Installing libtermcap. Installing groff. Installing procmail. Installing bash. Installing gzip. Installing procps. Installing MAKEDEV. Installing hdparm. Installing psmisc. Installing SysVinit. Installing inetd. Installing pump. Installing XFree86-Mach64. Installing initscripts. Installing quota. Installing anacron. Installing ipchains. Installing raidtools. Installing chkconfig. Installing iputils. Installing readline. Installing apmd. Installing isapnptools. Installing redhat-logos. Installing ncurses. Installing kbdconfig. Installing rootfiles. Installing info. Installing kernel. Installing rpm. Installing fileutils. Installing kernel-pcmcia- Installing sash. cs. Installing grep. Installing kernel-utils. Installing sendmail. Installing ash. Installing kudzu. Installing setserial. Installing at. Installing ld.so. Installing setuptool. Installing authconfig. Installing less. Installing shapecfg. Installing bc. Installing libc. Installing slang. Installing bdflush. Installing libstdc++. Installing slocate. Installing binutils. Installing lilo. Installing stat. Installing bzip2. Installing pwdb. Installing sysklogd. Installing sed. Installing pam. Installing tar. Installing console-tools. Installing sh-utils. Installing tcp_wrappers. Installing e2fsprogs. Installing redhat-release. Installing tcpdump. Installing rmt. Installing linuxconf. Installing tcsh. Installing cpio. Installing logrotate. Installing time. Installing cracklib. Installing losetup. Installing timeconfig. Installing cracklib-dicts. Installing lsof. Installing tmpwatch. Installing crontabs. Installing mailcap. Installing traceroute. Installing textutils. Installing mailx. Installing utempter. Installing dev. Installing man. Installing util-linux. Installing diffutils. Installing mingetty. Installing vim-common. Installing dump. Installing mkbootdisk. Installing vim-minimal. Installing ed. Installing mkinitrd. Installing vixie-cron. Installing eject. Installing modutils. Installing which. Installing etcskel. Installing mount. Installing zlib. Installing file. Installing mouseconfig.   Installing findutils. Installing mt-st.   5. Verify,Cross-check After we have uninstalled all the software that must be uninstalled after the installation of our Linux server see Software_that_must_be_uninstalled after installation of the Server and after the addition of the necessary RPM packages, so that we will able to compile programs on our server, we must verify the list of all installed RPM programs again but this time with the following command: To verify the list of all installed RPM package on your system, use the command: [root@deep] /#rpm -qa > installed_rpm The -qa option will query all installed RPM packages on your system and the symbol > will redirect the output to the file named installed_rpm. Version 6.1 only The content of the installed_rpm file must match exactly this: setup-2.0.5-1 findutils-4.1-32 passwd-0.63-1 filesystem-1.3.5-1 gawk-3.0.4-1 perl-5.00503-6 basesystem-6.0-4 cdecl-2.5-9 flex-2.5.4a-7 ldconfig-1.9.5-15 gdbm-1.8.0-2 procps-2.0.4-2 glibc-2.1.2-11 glib-1.2.5-1 psmisc-18-3 shadow-utils-19990827-2 gmp-2.0.2-10 python-1.5.2-7 mktemp-1.5-1 cpp-1.1.2-24 quota-1.66-8 termcap-9.12.6-15 gpm-1.17.9-3 gdb-4.18-4 libtermcap-2.0.8-18 groff-1.11a-9 readline-2.2.1-5 bash-1.14.7-16 gzip-1.2.4-14 glibc-devel-2.1.2-11 MAKEDEV-2.5-2 initscripts-4.48-1 rootfiles-5.2-5 SysVinit-2.77-2 ipchains-1.3.9-3 rpm-3.0.3-2 chkconfig-1.0.7-2 cproto-4.6-2 sash-3.3-1 ncurses-4.2-25 ElectricFence-2.1-1 make-3.77-6 info-3.12h-2 kernel-2.2.12-20 shapecfg-2.2.12-2 fileutils-4.0-8 patch-2.5-9 slang-1.2.2-4 grep-2.3-2 ld.so-1.9.5-11 slocate-2.0-3 ash-0.2-18 less-340-1 stat-1.5-11 at-3.1.7-11 libc-5.3.12-31 sysklogd-1.3.31-12 m4-1.4-12 libstdc++-2.9.0-24 tar-1.13.11-1 bdflush-1.5-10 lilo-0.21-10 tcp_wrappers-7.6-9 binutils-2.9.1.0.23-6 pwdb-0.60-1 tcpdump-3.4-16 bzip2-0.9.5c-1 pam-0.68-7 tcsh-6.08.00-6 sed-3.02-4 sh-utils-2.0-1 time-1.7-9 console-tools-19990302-17 logrotate-3.3-1 timed-0.10-23 e2fsprogs-1.15-3 losetup-2.9u-4 tmpwatch-2.0-1 byacc-1.9-11 lsof-4.45-1 traceroute-1.4a5-16 cpio-2.4.2-13 mailx-8.1.1-9 utempter-0.5.1-2 cracklib-2.7-5 man-1.5g-6 util-linux-2.9w-24 cracklib-dicts-2.7-5 mingetty-0.9.4-10 vim-common-5.4-2 crontabs-1.7-7 mkbootdisk-1.2.2-1 vim-minimal-5.4-2 textutils-2.0-2 mkinitrd-2.3-1 vixie-cron-3.0.1-39 dev-2.7.10-2 modutils-2.1.121-14 which-2.8-1 diffutils-2.7-16 mount-2.9u-4 zlib-1.1.3-5 dump-0.4b4-11 ctags-3.2-1 dev86-0.14.9-1 ed-0.2-12 ncompress-4.2.4-14 egcs-1.1.2-24 bison-1.28-1 net-tools-1.53-1 kernel-headers-2.2.12-20 etcskel-2.0-1 netkit-base-0.10-37   file-3.27-3 newt-0.50-13   Version 6.2 only The content of the installed_rpm file must look exactly like this: setup-2.1.8-1 file-3.28-2 ncompress-4.2.4-15 filesystem-1.3.5-1 findutils-4.1-34 net-tools-1.54-4 basesystem-6.0-4 gawk-3.0.4-2 newt-0.50.8-2 ldconfig-1.9.5-16 patch-2.5-10 passwd-0.64.1-1 glibc-2.1.3-15 gdbm-1.8.0-3 perl-5.00503-10 shadow-utils-19990827-10 bison-1.28-2 popt-1.5-0.48 mktemp-1.5-2 glib-1.2.6-3 procmail-3.14-2 termcap-10.2.7-9 gmp-2.0.2-13 procps-2.0.6-5 libtermcap-2.0.8-20 gpm-1.18.1-7 psmisc-19-2 bash-1.14.7-22 groff-1.15-8 quota-2.00pre3-2 MAKEDEV-2.5.2-1 gzip-1.2.4a-2 gdb-4.18-11 SysVinit-2.78-5 inetd-0.16-4 readline-2.2.1-6 anacron-2.1-6 initscripts-5.00-1 make-3.78.1-4 chkconfig-1.1.2-1 ipchains-1.3.9-5 rootfiles-5.2-5 m4-1.4-12 iputils-20000121-2 rpm-3.0.4-0.48 ncurses-5.0-11 cpp-1.1.2-30 sash-3.4-2 info-4.0-5 cproto-4.6-3 shapecfg-2.2.12-2 fileutils-4.0-21 kernel-2.2.14-5.0 slang-1.2.2-5 grep-2.4-3 ctags-3.4-1 slocate-2.1-2 ash-0.2-20 kernel-utils-2.2.14-5.0 stat-1.5-12 at-3.1.7-14 ElectricFence-2.1-3 sysklogd-1.3.31-16 byacc-1.9-12 ld.so-1.9.5-13 tar-1.13.17-3 bc-1.05a-5 less-346-2 tcp_wrappers-7.6-10 bdflush-1.5-11 libc-5.3.12-31 tcpdump-3.4-19 binutils-2.9.5.0.22-6 libstdc++-2.9.0-30 tcsh-6.09-4 bzip2-0.9.5d-2 lilo-0.21-15 time-1.7-9 sed-3.02-6 pwdb-0.61-0 tmpwatch-2.2-1 console-tools-19990829-10 pam-0.72-6 traceroute-1.4a5-18 e2fsprogs-1.18-5 sh-utils-2.0-5 utempter-0.5.2-2 cpio-2.4.2-16 logrotate-3.3.2-1 util-linux-2.10f-7 cracklib-2.7-5 losetup-2.10f-1 vim-common-5.6-11 cracklib-dicts-2.7-5 lsof-4.47-2 vim-minimal-5.6-11 crontabs-1.7-7 mailx-8.1.1-10 vixie-cron-3.0.1-40 textutils-2.0a-2 man-1.5h1-1 which-2.9-2 dev-2.7.18-3 mingetty-0.9.4-11 zlib-1.1.3-6 diffutils-2.7-17 mkbootdisk-1.2.5-3 dev86-0.15.0-2 dump-0.4b15-1 mkinitrd-2.4.1-2 egcs-1.1.2-30 ed-0.2-13 modutils-2.3.9-6 kernel-headers-2.2.14-5.0 cdecl-2.5-10 mount-2.10f-1 glibc-devel-2.1.3-15 etcskel-2.3-1 flex-2.5.4a-9   This step is required to make sure we have not forgotten to remove some unnecessary RPM or to add some important packages that permit us to compile programs on the system. If the result looks as our installed_rpm file above, we are ready to play with our new Linux server. 6. some colors for a change Putting some colors on your terminal can help you to distinguish folders, files, archives, devices, symbolic links and executable file from others. My opinion is that colors help to make less errors and fast navigation on your system. It's important to note that this hack is necessary only for Red Hat Linux version 6.1 (Cartman) and older, since the new Red Hat Linux version 6.2 (Zoot) now enables and includes this feature by default. Edit the profile file vi /etc/profile and add the following lines: # Enable Colour ls eval `dircolors /etc/DIR_COLORS -b` export LS_OPTIONS='-s -F -T 0 --color=yes' Edit the bashrc file vi /etc/bashrc and add the line: alias ls='ls --color=auto' Then log in and out. The new COLORS-environment variable should now be set, and your system will recognize that. Note Remember that this feature is only required for Red Hat Linux version 6.1 and older. 7. Update of the latest software Keep and update all software especially network software up to date with the latest versions. Check the errata pages for the Red Hat Linux distribution, available at www.redhat.com/corp/support/errata/index.html. The errata pages are perhaps the best resource for fixing 90% of the common problems with Red Hat Linux. In addition, security holes for which a solution exists are generally on the errata page 24 hours after Red Hat has been notified. You should always check there first. Software that must be updated at this time for your Red Hat Linux server are: groff-1_15-1_i386.rpm pam-0_68-10_i386.rpm sysklogd-1_3_31-14_i386.rpm gpm-1.19.1-1.i386.rpm initscripts-4_70-1_i386.rpm Linux kernel 2.2.14 -linux-2_2_14_tar.gz e2fsprogs-1.17-1.i386.rpm gpm-1.19.1-1.i386.rpm Note The Linux kernel is the most important, and always must be updated. See below for more information on building a custom kernel for your specific system. You can verify that the RPM software above is installed on your system before make an update with the following command: [root@deep] /#rpm -q Where is the name of the software you want to verify like groff, sysklogd, etc. Part 3. Security, Optimization and Upgrade Bat Abstract Now that we have installed a base system, the next three chapters will concentrate on * How to tighten the security of our configured system. * Optimise our sytem to perform at its peak. * Upgrade our machine for the latest kernel. Please note when we talk of tightening the security we are referring to the features available within the base installed system and not to any new additional software. We will talk about that later in this book. Table of Contents 5._General_System_Security 1._BIOS 2._Security_as_a_Policy 3._Choose_a_right_Password 4._The_root_account 5._The_/etc/exports_file 6._Disable_console_program_access 7._Disable_all_console_access 8._The_inetd_-_/etc/inetd.conf_file 9._TCP_WRAPPERS 9.1._Don't_display_system_issue_file 10._The_/etc/host.conf_file 11._The_/etc/services_file 12._The_/etc/securetty_file 13._Special_accounts 14._Blocking;_su_to_root,_by_one_and_sundry 15._Put_limits_on_resource 16._Control_mounting_a_file_system 17._Conceal_binary_RPM 18._Shell_logging 19._The_LILO_and_lilo.conf_file 20._Disable_Ctrl-Alt-Delete_keyboard_shutdown_command 21._Physical_hard_copies_of_all-important_logs 22._Tighten_scripts_under_/etc/rc.d/ 22.1._The_/etc/rc.d/rc.local_file 23._Bits_from_root-owned_programs 24._The_kernel_tunable_parameters 24.1._Prevent_your_system_responding_to_Ping 25._Refuse_responding_to_broadcasts_request 26._Routing_Protocols 27._Enable_TCP_SYN_Cookie_Protection 28._Disable_ICMP_Redirect_Acceptance 29._Enable_always-defragging_Protection 30._Enable_bad_error_message_Protection 31._Enable_IP_spoofing_protection 32._Log_Spoofed,_Source_Routed_and_Redirect_Packets 33._Unusual_or_hidden_files 34._System_is_compromised_! 6._Linux_General_Optimization 1._The_/etc/profile_file 2._Benchmark_Results 3._Benchmark_results-i586 4._Benchmark_results_-i486 5._The_bdflush_parameters 6._The_buffermem_parameters 7._The_ip_local_port_range_parameters 8._The_/etc/nsswitch.conf_file 9._The_file-max_parameter 10._The_ulimit_parameter 11._The_atime_and_noatime_attribute 12._Tuning_IDE_Hard_Disk_Performance 13._Better_manage_your_TCP/IP_resources 7._Configuring_and_Building_a_Secure,_Optimized_Kernel 1._Pre-Install 1.1._Make_an_emergency_boot_floppy 2._Uninstallation_and_Optimization 3._Securing_the_kernel 4._Compilation 5._Kernel_configuration_-Part_"A" 6._Kernel_configuration_-Part_"B" 7._Kernel_configuration_-Part_"C" 8._Kernel_configuration_-Part_"D" 9._Kernel_configuration_-Part_"E" 10._Installing_the_new_kernel 11._Delete_programs,_Edit_files_pertaining_to_modules 12._Create_a_emergency_Rescue_and_Boot_floppy_disk Chapter 5. General System Security Table of Contents 1._BIOS 2._Security_as_a_Policy 3._Choose_a_right_Password 4._The_root_account 5._The_/etc/exports_file 6._Disable_console_program_access 7._Disable_all_console_access 8._The_inetd_-_/etc/inetd.conf_file 9._TCP_WRAPPERS 9.1._Don't_display_system_issue_file 10._The_/etc/host.conf_file 11._The_/etc/services_file 12._The_/etc/securetty_file 13._Special_accounts 14._Blocking;_su_to_root,_by_one_and_sundry 15._Put_limits_on_resource 16._Control_mounting_a_file_system 17._Conceal_binary_RPM 18._Shell_logging 19._The_LILO_and_lilo.conf_file 20._Disable_Ctrl-Alt-Delete_keyboard_shutdown_command 21._Physical_hard_copies_of_all-important_logs 22._Tighten_scripts_under_/etc/rc.d/ 22.1._The_/etc/rc.d/rc.local_file 23._Bits_from_root-owned_programs 24._The_kernel_tunable_parameters 24.1._Prevent_your_system_responding_to_Ping 25._Refuse_responding_to_broadcasts_request 26._Routing_Protocols 27._Enable_TCP_SYN_Cookie_Protection 28._Disable_ICMP_Redirect_Acceptance 29._Enable_always-defragging_Protection 30._Enable_bad_error_message_Protection 31._Enable_IP_spoofing_protection 32._Log_Spoofed,_Source_Routed_and_Redirect_Packets 33._Unusual_or_hidden_files 34._System_is_compromised_! A secure Linux server depends on how the administrator configures it to be. Once we have eliminated the potential securities risk by removing RPM services not needed, we can start to secure our existing services and software on our server. In this chapter we will discuss some of the more general, basic techniques used to secure your system. The following is a list of features that can be used to help prevent attacks from external and internal sources. 1. BIOS It is recommended that you set a Boot password to disallow booting from floppy drives and set passwords on BIOS features. You can check your BIOS manual or look it over thoroughly the next time you boot up your system to know how to do this. Disallowing the possibility to boot from floppy drives and being able to set a password to access the BIOS features will improve the security of your system. This will block undesired people from trying to boot your Linux system with a special boot disk and will protect you from people trying to change BIOS feature like allowing boot from floppy drive or booting the server without prompt password. 2. Security as a Policy It is important to point out that you cannot implement security if you have not decided what needs to be protected, and from whom. You need a security policy; a kind of list of what you consider allowable and not allowable, upon which to base any decisions regarding security. The policy should also determine your response to security violations. What you should consider while compiling a security policy will depend entirely on your definition of security. The answers to the following questions should provide some general guidelines: * How do you classify confidential or sensitive information? * Does the system contain confidential or sensitive information? * Exactly whom do you want to guard against? * Do remote users really need access to your system? * Do passwords or encryption provide enough protection? * Do you need access to the Internet? * How much access do you want to allow to your system from the Internet? * What action will you take if you discover a breach in your security? This list is not very comprehensive, and your policy will probably encompass a lot more before it is completed. Any security policy must be based on some degree of paranoia; deciding how much you trust people, both inside and outside your organization. The policy must, however, provide a balance between allowing your users reasonable access to the information they require to do their work and totally disallowing access to your information. The point where this line is drawn will determine your policy. 3. Choose a right Password The starting point of our Linux General Security tour is the password. Many people keep their valuable information and files on a computer, and the only thing preventing others from seeing it is the eight-character string called a password. An unbreakable password, contrary to popular belief, does not exist. Given time and resources all passwords can be guessed either by social engineering or by brute force. Social engineering of server passwords and other access methods are still the easiest and most popular way to gain access to accounts and servers. Often, something as simple as acting as a superior or executive in a company and yelling at the right person at the right time of the day yields terrific results. Running a password cracker on a weekly basis on your system is a good idea. This helps to find and replace passwords that are easily guessed or weak. Also, a password checking mechanism should be present to reject a weak password when first choosing a password or changing an old one. Character strings that are plain dictionary words, or are all in the same case, or do not contain numbers or special characters should not be accepted as a new password. We recommend the following rules to make passwords effective: * They should be at least six characters in length, preferably eight characters including at least one numeral or special character. * They must not be trivial; a trivial password is one that is easy to guess and is usually based on the user's name, family, occupation or some other personal characteristic. * They should have an aging period, requiring a new password to be chosen within a specific time frame. * They should be revoked and reset after a limited number of concurrent incorrect retries. The minimum acceptable password length by default when you install your Linux system is 5. This mean that when a new user is allowed to have a access on the server, his/her password length will be at minimum 5 mixes of character strings, letter, number, special character etc. This is not enough and must be 8. To prevent non-security-minded people or administrators from being able to enter just 5 characters for the valuable password, edit the rather important / etc/login.defs file and change the value of 5 to 8. Edit the login.defs file vi /etc/login.defs and change the line that read: PASS_MIN_LEN 5 To read: PASS_MIN_LEN 8 The login.defs is the configuration file for the login program. You should review or make changes to this file for your particular system. This is where you set other security policy settings like password expiration defaults or minimum acceptable password length. 4. The root account The root account is the most privileged account on a Unix system. The root account has no security restrictions imposed upon it. This means the system assumes you know what you are doing, and will do exactly what you request -- no questions asked. Therefore it is easy, with a mistyped command, to wipe out crucial system files. When using this account it is important to be as careful as possible. For security reasons, never log in on your server as root unless it is absolutely an instance that necessitates root access. Also, if you are not on your server, never sign in and leave yourself on as root --this is Very, Very, Very BAD practice. Set login time out for the root account. Despite the notice to never, if they are not on the server sign in as root and leave it unattended, administrators still stay on as root or forget to logout after finishing their work and leave their terminals unattended. The answer to solve this problem is to make the bash shell automatically logout after not being used for a period of time. To do that, you must set the special variable of Linux named TMOUT to the time in seconds of no input before logout. Edit your profile file /etc/profile and add the following line somewhere after the line that read HISTFILESIZE= on this file: TMOUT=7200 The value we enter for the variable TMOUT= is in second and represent 2 hours (60 * 60 = 3600 * 2 = 7200 seconds). It is important to note that if you decide to put the above line in your /etc/profile file, then the automatic logout after two hours of inactivity will apply for all users on the system. So, instead, if your prefer to control which users will be automatically logged out and which ones not, you can set this variable in their individual .bashrc file. After this parameter has been set on your system, you must logout and login again as root for the change to take effect. 5. The /etc/exports file If you are exporting file systems using NFS service, be sure to configure the / etc/exports file with the most restrictive access possible. This means not using wildcards, not allowing root write access, and mounting read-only wherever possible. Example 5.1. Export file systems using NFS Edit the exports file vi /etc/exports and add: /dir/to/export host1.mydomain.com(ro,root_squash) /dir/to/export host2.mydomain.com(ro,root_squash) Where: * /dir/to/export is the directory you want to export. * host#.mydomain.com is the machine allowed to log in this directory. * The ro option mean mounting read-only. * The root_squash option for not allowing root write access in this directory. For this change to take effect you will need to run the following command on your terminal: [root@deep]# /usr/sbin/exportfs -a Note Please be aware that having an NFS service available on your system can be a security risk. Personally, I don't recommend using it. 6. Disable console program access In a safe environment where we are sure that console is secured because passwords for BIOS and LILO are set and all physical power and reset switches on the system are disabled it may be advantageous to entirely disable all console-equivalent access to programs like shutdown, reboot, and halt for regular users on your server. To do this, run the following command: [root@deep] /#rm -f /etc/security/console.apps/ Where is the name of the program to which you wish to disable console-equivalent access. Unless you use xdm, however, be careful not to remove the xserver file or no one but root will be able to start the X server. If you always use xdm to start the X server, root is the only user that needs to start X, in which case you might actually want to remove the xserver file. Example 5.2. Disable console-equivalent access [root@deep] /# rm -f /etc/security/console.apps/halt [root@deep] /# rm -f /etc/security/console.apps/poweroff [root@deep] /# rm -f /etc/security/console.apps/reboot [root@deep] /# rm -f /etc/security/console.apps/shutdown [root@deep] /# rm -f /etc/security/console.apps/xserver 1 _1_ if removed, root will be the only user able to start X. This will disable console-equivalent access to programs halt, poweroff, reboot, and shutdown. Once again, the program xserver apply only is you are installed the Xwindow interface on your system. Note If you are following our setup installation, the Xwindow interface is not installed on your server and all the files described above will not appear in the /etc/security directory, so can safely ignore the above steps. 7. Disable all console access The Linux-PAM library installed by default on your system allows the system administrator to choose how applications authenticate users, such as for console access, program and file access. In order to disable all these accesses for the users, you must comment out all lines that refer to pam_console.so in the /etc/pam.d/ directory. This step is a continuation of the above hack Disable_console_program_access. The following script will do the trick automatically for you. As root creates the disabling.sh script file, touch disabling.sh and add the following lines inside: # !/bin/sh cd /etc/pam.d for i in * ; do sed '/[^#].*pam_console.so/s/^/#/' < $i > foo && mv foo $i done Make this script executable with the following command and execute it: [root@deep] /# chmod 700 disabling.sh [root@deep] /# ./disabling.sh This will comment out all lines that refer to pam_console.so for all files located under /etc/pam.d directory. Once the script has been executed, you can remove it from your system. 8. The inetd - /etc/inetd.conf file inetd, called also the super server, will load a network program based upon a request from the network. The inetd.conf file tells inetd which ports to listen to and what server to start for each port. The first thing to look at as soon as you put your Linux system on ANY network is what services you need to offer. Services that you do not need to offer should be disabled and uninstalled so that you have one less thing to worry about, and attackers have one less place to look for a hole. Look at your /etc/ inetd.conf file to see what services are being offered by your inetd program. Disable what you do not need by commenting them out by adding a # at the beginning of the line, and then sending your inetd process a SIGHUP command to update it to the current inetd.conf file. 1. Change the permissions on this file to 600. [root@deep] /#chmod 600 /etc/inetd.conf 2. Ensure that the owner is root. [root@deep] /# stat /etc/inetd.conf File: "/etc/inetd.conf" Size: 2869 Filetype: Regular File Mode: (0600/-rw-------) Uid: ( 0/ root) Gid: ( 0/ root) Device: 8,6 Inode: 18219 Links: 1 Access: Wed Sep 22 16:24:16 1999(00000.00:10:44) Modify: Mon Sep 20 10:22:44 1999(00002.06:12:16) Change: Mon Sep 20 10:22:44 1999(00002.06:12:16) 3. Edit the inetd.conf file vi /etc/inetd.conf and disable services like: ftp, telnet, shell, login, exec, talk, ntalk, imap, pop-2, pop-3, finger, auth, etc. unless you plan to use it. If it's turned off, it's much less of a risk. # To re-read this file after changes, just do a 'killall - HUP inetd' # #echo stream tcp nowait root internal #echo dgram udp wait root internal #discard stream tcp nowait root internal #discard dgram udp wait root internal #daytime stream tcp nowait root internal #daytime dgram udp wait root internal #chargen stream tcp nowait root internal #chargen dgram udp wait root internal #time stream tcp nowait root internal #time dgram udp wait root internal # # These are standard services. # #ftp stream tcp nowait root /usr/sbin/tcpd in.ftpd -l -a #telnet stream tcp nowait root /usr/sbin/tcpd in.telnetd # # Shell, login, exec, comsat and talk are BSD protocols. # #shell stream tcp nowait root /usr/sbin/tcpd in.rshd #login stream tcp nowait root /usr/sbin/tcpd in.rlogind #exec stream tcp nowait root /usr/sbin/tcpd in.rexecd #comsat dgram udp wait root /usr/sbin/tcpd in.comsat #talk dgram udp wait root /usr/sbin/tcpd in.talkd #ntalk dgram udp wait root /usr/sbin/tcpd in.ntalkd #dtalk stream tcp wait nobody /usr/sbin/tcpd in.dtalkd # # Pop and imap mail services et al # #pop-2 stream tcp nowait root /usr/sbin/tcpd ipop2d #pop-3 stream tcp nowait root /usr/sbin/tcpd ipop3d #imap stream tcp nowait root /usr/sbin/tcpd imapd # # The Internet UUCP service. # #uucp stream tcp nowait uucp /usr/sbin/tcpd /usr/lib/uucp/ uucico -l # # Tftp service is provided primarily for booting. Most sites # run this only on machines acting as "boot servers." Do not uncomment # this unless you *need* it. # #tftp dgram udp wait root /usr/sbin/tcpd in.tftpd #bootps dgram udp wait root /usr/sbin/tcpd bootpd # # Finger, systat and netstat give out user information which may be # valuable to potential "system crackers." Many sites choose to disable # some or all of these services to improve security. # #finger stream tcp nowait root /usr/sbin/tcpd in.fingerd #cfinger stream tcp nowait root /usr/sbin/tcpd in.cfingerd #systat stream tcp nowait guest /usr/sbin/tcpd /bin/ps - auwwx #netstat stream tcp nowait guest /usr/sbin/tcpd /bin/ netstat -f inet # # Authentication # #auth stream tcp nowait nobody /usr/sbin/in.identd in.identd -l -e -o # # End of inetd.conf 4. [root@deep] /# killall -HUP inetd 5. One more security measure you can take to secure the inetd.conf file is to set it immutable, using the chattr command. To set the file immutable simply, execute the following command: [root@deep] /# chattr +i /etc/inetd.conf This will prevent any changes accidental or otherwise to the inetd.conf file. A file with the immutable attribute set i cannot be modified, deleted or renamed, no link can be created to this file and no data can be written to it. The only person that can set or clear this attribute is the super-user root. If you wish later to modify the inetd.conf file you will need to unset the immutable flag: To unset the immutable flag, simply execute the following command: [root@deep] /# chattr -i /etc/inetd.conf Note Don't forget to send your inetd process a SIGHUP signal killall -HUP inetd after making change to your inetd.conf file. The services you enable on a selected host depend on the functions you want the host to provide. Functions could support the selected network service, other services hosted on this computer, or development and maintenance of the operating system and applications. 9. TCP_WRAPPERS By default Red Hat Linux allows all service requests. Using TCP_WRAPPERS makes securing your servers against outside intrusion is a lot simpler and painless then you would expect. Deny all hosts by putting ALL: ALL@ALL, PARANOID in the /etc/hosts.deny file and explicitly list trusted hosts who are allowed to your machine in the /etc/hosts.allow file. This is the safest and the best configuration. TCP_WRAPPERS is controlled from two files and the search stops at the first match. /etc/hosts.allow /etc/hosts.deny Access will be granted when a daemon, client pair matches an entry in the /etc/ hosts.allow file. Otherwise, access will be denied when a daemon, client pair matches an entry in the /etc/hosts.deny file. Otherwise, access will be granted. 1. Edit the hosts.deny file vi /etc/hosts.deny and add the following lines: Access is denied by default. # Deny access to everyone. ALL: ALL@ALL, PARANOID # Matches any host whose name does not match its address, see below. Which means all services, all locations, so any service not explicitly allowed is then blocked, unless they are permitted access by entries in the allow file. Note With the parameter PARANOID; If you intend to run telnet or ftp services on your server, dont forget to add the client's machine name and IP address in your /etc/hosts file on the server or you can expect to wait several minutes for the DNS lookup to time out, before you get a login: prompt. 2. Edit the hosts.allow file vi /etc/hosts.allow and add for example, the following line: The explicitly authorized host are listed in the allow file. As an example:sshd: 208.164.186.1 gate.openna.com, For your client machine: 208.164.186.1 is the IP address and gate.openna.com the host name of one of your client allowed using sshd. 3. The tcpdchk program is the tcpd wrapper configuration checker. It examines your tcp wrapper configuration and reports all potential and real problems it can find. After your configuration is done, run the program tcpdchk. [root@deep] /# tcpdchk Note Error messages may look like this: warning: /etc/hosts.allow, line 6: can't verify hostname: gethostbyname(win.openna.com) failed. If you receive this kind of error message, check in your DNS configuration file for the existence of this hostname. 9.1. Don't display system issue file If you don't want your systems issue file to be displayed when people log in remotely, you can change the telnet option in your /etc/inetd.conf file to look like: telnet stream tcp nowait root /usr/sbin/tcpd in.telnetd -h Adding the -h flag on the end will cause the daemon to not display any system information and just hit the user with a login: prompt. This hack is only necessary if you are using a telnet daemon on your server instead I recommend you use SSH. 10. The /etc/host.conf file Linux uses a resolver library to obtain the IP address corresponding to a host name. The /etc/host.conf file specifies how names are resolved. The entries in the etc/host.conf file tell the resolver library what services to use, and in what order, to resolve names. Edit the host.conf file vi /etc/host.conf and add the following lines: # Lookup names via DNS first then fall back to /etc/hosts. order bind,hosts # We have machines with multiple IP addresses. multi on # Check for IP address spoofing. nospoof on The order option indicates the order of services. The sample entry specifies that the resolver library should first consult the name server to resolve a name and then check the /etc/hosts file. It is recommended to set the resolver library to first check the name server, bind and then the hosts file (hosts) for better performance and security on all your servers. Of course you must have the DNS/BIND software installed or this configuration will not work. The multi option determines whether a host in the /etc/hosts file can have multiple IP addresses i.e.multiple interface ethN. Hosts that have more than one IP address are said to be multiomed, because the presence of multiple IP addresses implies that host has several network interfaces. As an example, a Gateway Server will always have multiple IP address and must have this option set to ON. The nospoof option indicates to take care of not permitting spoofing on this machine. IP-Spoofing is a security exploit that works by tricking computers in a trust relationship that you are someone that you really aren't. In this type of attack, a machine is set up to look like a legitimate server and then issue connections and other types of network activities to legitimate end systems, other servers or large data repository systems. This option must be set ON for all types of servers. 11. The /etc/services file The port numbers on which certain standard services are offered are defined in the RFC 1700 Assigned Numbers. The /etc/services file enables server and client programs to convert service names to these numbers -ports. The list is kept on each host and it is stored in the file /etc/services. Only the "root" user is allowed to make modification in this file and it is rare to edit the /etc/ services file to make change since it already contains the more common service names to port numbers. To improve security, we can immunize this file to prevent unauthorized deletion or addition of services. To immunize the /etc/ services file, use the command: [root@deep] /#chattr +i /etc/services 12. The /etc/securetty file The /etc/securetty file allows you to specify which TTY devices the root user is allowed to login on. The /etc/securetty file is read by the login program usually /bin/login. Its format is a list of the tty devices names allowed, and for all others that are commented out or do not appear in this file, root login is disallowed. Disable any tty that you do not need by commenting them out # at the beginning of the line. Edit the securetty file vi, /etc/securetty and comment out the following lines: tty1 #tty2 #tty3 #tty4 #tty5 #tty6 #tty7 #tty8 Which means only root is allowed to login on tty1. This is my recommendation, allowing root to log in only on one tty device and use the su command to switch to root if you need more. devices to log in as root. 13. Special accounts It is important to DISABLE ALL default vendor accounts that you don't use on your system, some accounts exist by default even if you have not installed the related services on your server. This should be checked after each upgrade or new software installation. Linux provides these accounts for various system activities, which you may not need if the services are not installed on your server. If you do not need the accounts, remove them. The more accounts you have, the easier it is to access your system. We assume you are using the Shadow password suite on your Linux system. If you are not, you should consider doing so, as it helps to tighten up security somewhat. This must already be set if you've followed our instructions till now and selected under the Authentication_Configuration the option to Enable Shadow Passwords see Post_Partitioning for more information. To delete user on your system, use the command: [root@deep] /# userdel username To delete group on your system, use the command: [root@deep] /# groupdel username 1. Type the following commands on your terminal to delete users listed below: [root@deep] /# userdel adm [root@deep] /# userdel lp [root@deep] /# userdel sync [root@deep] /# userdel shutdown [root@deep] /# userdel halt [root@deep] /# userdel news [root@deep] /# userdel uucp [root@deep] /# userdel operator [root@deep] /# userdel games 1 [root@deep] /# userdel gopher [root@deep] /# userdel ftp 2 _1_ Delete this user if you don't use X Window Server. _2_ Delete this user if you don't use ftp anonymous server. By default, the userdel command will not delete a user's home directory. If you want the home directories of accounts to be deleted too, then add the -r option to the userdel command. 2. Type the following commands on your terminal to delete the usersgroups listed below: [root@deep] /# groupdel adm [root@deep] /# groupdel lp [root@deep] /# groupdel news [root@deep] /# groupdel uucp [root@deep] /# groupdel games 1 [root@deep] /# groupdel dip [root@deep] /# groupdel pppusers [root@deep] /# groupdel popusers 2 [root@deep] /# groupdel slipusers _1_ Delete this group if you don't use X Window Server. _2_ Delete this group if you don't use pop server for email. 3. Add the necessary user to the system, to add a new user on your system, use the command: [root@deep] /# useradd username To add or change password for user on your system, use the command: [root@deep] /# passwd username For example: [root@deep] /# useradd admin [root@deep] /# passwd admin The output should look something like this. Changing password for user admin New UNIX password: somepasswd passwd: all authentication tokens updated successfully 4. The immutable bit can be used to prevent accidentally deleting or overwriting a file that must be protected. It also prevents someone from creating a symbolic link to this file, which has been the source of attacks involving the deletion of /etc/passwd, /etc/shadow, /etc/group or /etc/gshadow. To set the immutable bit on the passwords and groups files, use the command: [root@deep] /# chattr +i /etc/passwd [root@deep] /# chattr +i /etc/shadow [root@deep] /# chattr +i /etc/group [root@deep] /# chattr +i /etc/gshadow Note In future, if you intend to add or delete users, passwords, usergroups, or group files, you must unset the immutable bit on all those files or you will not be able to make your changes. Also if you intend to install an RPM program that will automatically add a new user to the different immunized passwd and group files, then you will receive an error message during the install if you have not unset the immutable bit from those files. 14. Blocking; su to root, by one and sundry The su Substitute User command allows you to become other existing users on the system. For example you can temporarily become root and execute commands as the super-user root. If you don't want anyone to su to root or restrict su command to certain users then add the following two lines to the top of your su configuration file in the /etc/pam.d/ directory. We highly recommend that you limit the person allowed to su to the root account. 1. Edit the su file vi /etc/pam.d/su and add the following two lines to the top of the file: auth sufficient /lib/security/pam_rootok.so debug auth required /lib/security/pam_wheel.so group=wheel After adding the two lines above, the /etc/pam.d/su file should look like this: #%PAM-1.0 auth sufficient /lib/security/pam_rootok.so debug auth required /lib/security/pam_wheel.so group=wheel auth required /lib/security/pam_pwdb.so shadow nullok account required /lib/security/pam_pwdb.so password required /lib/security/pam_cracklib.so password required /lib/security/pam_pwdb.so shadow use_authtok nullok session required /lib/security/pam_pwdb.so session optional /lib/security/pam_xauth.so Which mean only those who are a member of the wheel group can su to root; it also includes logging. Note that the wheel group is a special account on your system that can be used for this purpose. You cannot use any group name you want to make this hack. This hack combined with specifying which TTY devices root is allowed to login on will improve your security a lot on the system. 2. Now that we have defined the wheel group in our /etc/pam.d/su file configuration, it is time to add some users allowed to su to root account. If you want to make, for example, the user admin a member of the wheel group, and thus be able to su to root, use the following command: [root@deep] /# usermod -G10 admin o Which means G is a list of supplementary groups, o Where the user is also a member of, 10 is the numeric value of the user's ID wheel, o admin is the user we want to add to wheel group. Use the same command above for all users on your system you want to be able to su to root account. If you can't su in a GNOME terminal, it's because you've used the wrong terminal. So don't think that this advice simply doesn't work because of a terminal problem!. 15. Put limits on resource The limits.conf file located under the /etc/security directory can be used to control and limit resources for the users on your system. It is important to set resource limits on all your users so they can't perform denial of service attacks number of processes, amount of memory, etc). These limits will have to be set up for the user when he or she logs in. For example, limits for all users on your system might look like this. 1. Edit the limits.conf file vi /etc/security/limits.conf and add or change the lines to read: * hard core 0 * hard rss 5000 * hard nproc 20 This says to prohibit the creation of core files - core 0, restrict the number of processes to 20 - nproc 20, and restrict memory usage to 5M - rss 5000 for everyone except the super user root. All of the above only concern users who have entered through the login prompt on your system. With this kind of quota, you have more control on the processes, core files, and memory usage that users may have on your system. The asterisk * mean: all users that logs in on the server. 2. You must also edit the /etc/pam.d/login file and add the following line to the bottom of the file: session required /lib/security/pam_limits.so After adding the line above, the /etc/pam.d/login file should look like this: #%PAM-1.0 auth required /lib/security/pam_securetty.so auth required /lib/security/pam_pwdb.so shadow nullok auth required /lib/security/pam_nologin.so account required /lib/security/pam_pwdb.so password required /lib/security/pam_cracklib.so password required /lib/security/pam_pwdb.so nullok use_authtok md5 shadow session required /lib/security/pam_pwdb.so session required /lib/security/pam_limits.so #session optional /lib/security/pam_console.so 3. Finally edit the /etc/profile file and change the following line: ulimit -c 1000000 to read: ulimit -S -c 1000000 > /dev/null 2<&1 This modification is required so as to avoid getting error messages like this Unable to reach limit during login:. 16. Control mounting a file system You can have more control on mounting a file system like /home and /tmp partitions with some nifty options like noexec, nodev, and nosuid. This can be setup in the /etc/fstab text file. The fstab file contains descriptive information about the various file systems mount options; each line addresses one file system. Details regarding to security options in the fstab text file are: defaults:Allow everything quota, read-write, and suid on this partition. noquota:Do not set users quotas on this partition. nosuid:Do not set SUID/SGID access on this partition. nodev:Do not set character or special devices access on this partition. noexec:Do not set execution of any binaries on this partition. quota:Allow users quotas on this partition. ro:Allow read-only on this partition. rw:Allow read-write on this partition. suid:Allow SUID/SGID access on this partition. For more information on options that you can set in this file fstab, see the man pages about mount(8). Edit the fstab file vi /etc/fstab and change it depending on your needs. For example: /dev/sda11 /tmp ext2 defaults 1 2 /dev/sda6 /home ext2 defaults 1 2 To read: /dev/sda11 /tmp ext2 defaults,rw,nosuid,nodev,noexec 1 2 /dev/sda6 /home ext2 defaults,rw,nosuid,nodev 1 2 nosuid, Meaning do not allow set-user-identifier or set-group-identifier bits to take effect, nodev, do not interpret character or block special devices on this file system partition, noexec, do not allow execution of any binaries on the mounted file system. Take a note that we have added the rw option to the modified lines above. This is because the default options for these lines are defaults, which means to set quota, read-write, and suid, so we must add the rw option to continue having read-write access on these modified file systems. For our example above, the / dev/sda11 represent our /tmp directory partition on the system, and /dev/sda6 the /home directory partition. Of course this will be not the same for you, depending on how you have partitioned your hard disk and what kind of disks are installed on your system, IDE -hda, hdb, etc or SCSI -sda, sdb, etc. Once you have made the necessary adjustments to the /etc/fstab file, it is time to makethe Linux system aware about the modification. This can be accomplished with the following commands: [root@deep] /#mount -oremount /home/ [root@deep] /#mount -oremount /tmp/ Each file system that has been modified must be remounted with the command show above. In our example we have modified the /home/, and /tmp/ file system and it is for this reason that we remount these file system with the above commands. 17. Conceal binary RPM Once you have installed all the software that you need on yo42ur Linux server with the RPM command, it's a good idea for better security to move it to a safe place like a floppy disk or other safe place of your choice. With this method if some one accesses your server and has the intention to install software like trojan horses, password thieves etc. with RPM command, he shouldn't be able to do so. Of course, if in the future you want to install or upgrade new software via RPM, all you have to do is to replace the RPM binary to its original directory again. To move the RPM binary on the floppy disk, use the command: [root@deep] /# mount /dev/fd0 /mnt/floppy/ [root@deep] /# mv /bin/rpm /mnt/floppy/ [root@deep] /# umount /mnt/floppy Never uninstall the RPM program completely from your system or you will be unable to reinstall it again later, since to install RPM or other software you need to have RPM commands available. Another thing you can do is change the default permission of the rpm command from 755 to 700. With this modification, non-root users can't use the rpm program to query, install etc; in case you forget to move it to a safe place after installation of new programs. To change the default permission of /bin/rpm, use the command: [root@deep] /# chmod 700 /bin/rpm 18. Shell logging To make it easy for you to repeat long commands, the bash shell stores up to 500 old commands in the ~/.bash_history file where ~/ is your home directory. Each user that has an account on the system will have this file .bash_history in their home directory. Reducing the number of old commands the .bash_history files can hold may protect users on the server who enter by mistake their password on the screen in plain text and have their password stored for a long time in the .bash_history file. 1. The HISTFILESIZE and HISTSIZE lines in the /etc/profile file determine the size of old commands the .bash_history file for all users on your system can hold. For all accounts I would highly recommend setting the HISTFILESIZE and HISTSIZE in /etc/profile file to a low value such as 20. Edit the profile file vi /etc/profile and change the lines to: HISTFILESIZE=20 HISTSIZE=20 Which mean, the .bash_history file in each users home directory can store 20 old commands and no more. Now, if a cracker tries to see the ~/.bash_history file of users on your server to find some password typed by mistake in plain text, he or she has less chance to find one. 2. The administrator should also add into the /etc/skel/.bash_logout file the rm -f $HOME/.bash_history line, so that each time a user logs out, its .bash_history file will be deleted so crackers will not be able to use .bash_history file of users who are not presently logged into the system. Edit the .bash_logout file vi /etc/skel/.bash_logout and add the following line: rm -f $HOME/.bash_history The above hack will only work for future users you'll add in the server. If you already have existing users in the /etc/passwd file, you must edit and add the above line into their .bash_logout files manually. 19. The LILO and lilo.conf file LILO is the most commonly used boot loader for Linux. It manages the boot process and can boot Linux kernel images from floppy disks, hard disks or can even act as a boot manager for other operating systems. LILO is very important in the Linux system and for this reason, we must protect it the best we can. The most important configuration file of LILO is the lilo.conf file, which resides under the /etc directory. It is with this file that we can configure and improve the security of our LILO program and Linux system. Following are three important options that will improve the security of our valuable LILO program. Adding: timeout=00 This option controls how long in seconds LILO waits for user input before booting to the default selection. One of the requirements of C2 security is that this interval be set to 0 unless the system dual boots something else. Adding: restricted This option asks for a password only, if parameters are specified on the command line (e.g. linux single). The option restricted can only be used together with the password option. Make sure you use this one on each image. Adding: password= This option asks the user for a password when trying to load the Linux system in single mode. Passwords are always case-sensitive, also make sure the /etc/lilo.conf file is no longer world readable, or any user will be able to read the password. Procedure 5.1. An example of protected lilo.conf file. 1. Edit the lilo.conf file vi /etc/lilo.conf and add or change the above three options as show: boot=/dev/sda map=/boot/map install=/boot/boot.b prompt timeout=00 ß change this line to 00. Default=linux restricted ß add this line. password= 1 image=/boot/vmlinuz-2.2.12-20 label=linux initrd=/boot/initrd-2.2.12-10.img root=/dev/sda6 read-only _1_ add this line and put your password. 2. Because the configuration file /etc/lilo.conf now contains unencrypted passwords, it should only be readable for the super-user root. [root@deep] /# chmod 600 /etc/lilo.conf will be no longer world readable. 3. Now we must update our configuration file /etc/lilo.conf for the change to take effect. [root@deep] /# /sbin/lilo -v to update the lilo.conf file. 4. One more security measure you can take to secure the lilo.conf file is to set it immutable, using the chattr command. To set the file immutable simply, use the command: [root@deep] /# chattr +i /etc/lilo.conf And this will prevent any changes accidental or otherwise to the lilo.conf file. If you wish to modify the lilo.conf file you will need to unset the immutable flag: To unset the immutable flag, use the command: [root@deep] /# chattr -i /etc/lilo.conf 20. Disable Ctrl-Alt-Delete keyboard shutdown command Commenting out the line with a # listed below in your /etc/inittab file will disable the possibility of using the Ctrl-Alt-Delete command to shutdown your computer. This is pretty important if you don't have the best physical security on the box. To do this, edit the inittab file vi /etc/inittab and change the line: ca::ctrlaltdel:/sbin/shutdown -t3 -r now To read: #ca::ctrlaltdel:/sbin/shutdown -t3 -r now Now, for the change to take effect type in the following at a prompt: [root@deep] /#/sbin/init q 21.  Physical hard copies of all-important logs One of the most important security considerations is the integrity of the different log files under the /var/log directory on your server. If despite each of the security functions put in place on our server a cracker can gain access to it, our last defense is the log file system, so it is very important to consider a method of being sure of the integrity of our log files. If you have a printer installed on your server, or on a machine on your network, a good idea would be to have actual physical hard copies of all- important logs. This can be easily accomplished by using a continuous feed printer and having the syslog program sending all logs you seem important out to /dev/lp0 the printer device. Cracker can change the files, programs, etc on your server, but can do nothing when you have a printer that prints a real paper copy of all of your important logs. Example 5.3. Print log reports For logging of all telnet, mail, boot messages and ssh connections from your server to the printer attached to this server, you would want to add the following line to the "/etc/syslog.conf" file: Edit the syslog.conf file vi / etc/syslog.conf and add at the end of this file the following line: authpriv.*;mail.*;local7.*;auth.*;daemon.info /dev/lp0 Now restart your syslog daemon for the change to take effect: [root@deep] /# /etc/rc.d/init.d/syslog restart For logging of all telnet, mail, boot messages and ssh connections from your server to the printer attached to a remote server in your local network, then you would want to add the following line to /etc/syslog.conf file on the remote server. If you don't have a printer in your network, you can also copy all the log files to another machine; simply omit the first step below of adding /dev/ lp0 to your syslog.conf file on remote and go directly to the -r option step on remote. Using the feature of copying all the log files to another machine will give you the possibility to control all syslog messages on one host and will tear down administration needs. Edit the syslog.conf file vi /etc/syslog.conf on the remote server for example: mail.openna.com and add at the end of this file the following line: authpriv.*;mail.*;local7.*;auth.*;daemon.info /dev/lp0 Since the default configuration of the syslog daemon is to not receive any messages from the network, we must enable on the remote server the facility to receive messages from the network. To enable the facility to receive messages from the network on the remote server, add the following option -r to your syslog daemon script file only on the remote host: Edit the syslog daemon vi +24 /etc/rc.d/init.d/syslog and change: daemon syslogd -m 0 To read: daemon syslogd -r -m 0 Now restart your syslog daemon on the remote host for the change to take effect: [root@mail /]# /etc/rc.d/init.d/syslog restart Now, if we have a firewall on the remote server you are supposed to have one), we must add or verify the existence of the following lines: ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ 1 -s $SYSLOG_CLIENT \ 2 -d $IPADDR 514 -j ACCEPT 3 _1_ Where EXTERNAL_INTERFACE="eth0" in the firewall file. _2_ Where IPADDR="208.164.186.2" in the firewall file. _3_ Where SYSLOG_CLIENT="208.164.168.0/24" in the firewall file. Now restart your firewall on the remote host for the change to take effect: [root@mail /]# /etc/rc.d/init.d/firewall restart This firewall rule will allow incoming UDP packet on port 514 (syslog port) on the remote server that come from our internal client to be accepted. For more information on Firewall see Chapter 7 Networking firewall. Finally, edit the syslog.conf file vi /etc/syslog.conf on the local server, and add at the end of this file the following line: authpriv.*;mail.*;local7.*;auth.*;daemon.info @mail Where mail is the hostname of the remote server. Now if anyone ever hacks your box and menaces to erase vital system logs, you still have a hard copy of everything. It should then be fairly simple to trace where they came from and deal with it accordingly. Now restart your syslog daemon for the change to take effect: [root@deep] /# /etc/rc.d/init.d/syslog restart Same as on the remote host, we must add or verify the existence of the following lines in our firewall script file on the local host: ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ 1 -s $IPADDR 514 \ 2 -d $SYSLOG_SERVER 514 -j ACCEPT 3 _1_ Where EXTERNAL_INTERFACE="eth0" in the firewall file. _2_ Where IPADDR="208.164.186.1" in the firewall file. _3_ Where SYSLOG_SERVER="mail.openna.com" in the firewall file. Now restart your firewall for the change to take effect: [root@deep] /# /etc/rc.d/init.d/firewall restart This firewall rule will allow outgoing UDP packet on port 514 syslog port on the local server destined to the remote syslog server to be accepted. For more information on Firewall see chapter 7 Networking firewall. Important Never use your Gateway Server as a host to control all syslog messages; this is a very bad idea. More options and strategies exist with the sysklogd program, see the man pages about sysklogd(8), syslog(2), and syslog.conf(5) for more information. 22. Tighten scripts under /etc/rc.d/ Fix the permissions of the script files that are responsible for starting and stopping all your normal processes that need to run at boot time. [root@deep] /# chmod -R 700 /etc/rc.d/init.d/* Which means just root is allowed to Read, Write, and Execute scripts files on this directory. I don't think regular users need to know what is inside those script files. Important If you install a new program or update a program that use the init system V script located under /etc/rc.d/init.d/ directory, don't forget to change or verify the permission of this script file again. 22.1. The /etc/rc.d/rc.local file By default, when you login to a Linux box, it tells you the Linux distribution name, version, kernel version, and the name of the server. This is giving away too much info. We'd rather just prompt users with a Login: 1. To do this, Edit the /etc/rc.d/rc.local file and Place # in front of the following lines as shown: # This will overwrite /etc/issue at every boot. So, make any changes you # want to make to /etc/issue here or you will lose them when you reboot. #echo "" > /etc/issue #echo "$R" >> /etc/issue #echo "Kernel $(uname -r) on $a $(uname -m)" >> /etc/issue # #cp -f /etc/issue /etc/issue.net #echo >> /etc/issue 2. Then, remove the following files: issue.net and issue under /etc directory: [root@deep] /# rm -f /etc/issue [root@deep] /# rm -f /etc/issue.net The /etc/issue.net file is the login banner that users will see when they make a networked i.e. telnet, SSH connection to your machine. You will find it in the /etc directory, along with a similar file called issue, which is the login banner that gets displayed to local users. It is simply a text file and can be customized to your own taste, but be aware that as noted above, if you do change it or remove it like we do, you'll also need to modify the /etc/rc.d/ rc.local shell script, which re-creates both the issue and issue.net files every time the system boots. 23.  Bits from root-owned programs A regular user will be able to run a program as root if it is set to SUID root. All programs and files on your computer with the s bits appearing on its mode, have the SUID -rwsr-xr-x or SGID -r-xr-sr-x bit enabled. Because these programs grant special privileges to the user who is executing them, it is important to remove the s bits from root-owned programs that won't absolutely require such privilege. This can be accomplished by executing the command chmod a-s with the name(s) of the SUID/SGID files as its arguments. Such programs include, but aren't limited to: * Programs you never use. * Programs that you don't want any non-root users to run. * Programs you use occasionally, and don't mind having to su to root to run. We've placed an asterisk * next to each program we personally might disable and consider to be not absolutely required for the working of our server. Remember that your system needs some suid root programs to work properly, so be careful. make your choices based on your requirements. To find all files with the s bits from root-owned programs, use the command: [root@deep]#find / -type f \( -perm -04000 -o -perm -02000 \) \- exec ls 'lg {} \; *-rwsr-xr-x 1 root root 35168 Sep 22 23:35 /usr/bin/chage *-rwsr-xr-x 1 root root 36756 Sep 22 23:35 /usr/bin/gpasswd *-r-xr-sr-x 1 root tty 6788 Sep 6 18:17 /usr/bin/wall -rwsr-xr-x 1 root root 33152 Aug 16 16:35 /usr/bin/at -rwxr-sr-x 1 root man 34656 Sep 13 20:26 /usr/bin/man -r-s--x--x 1 root root 22312 Sep 25 11:52 /usr/bin/passwd -rws--x--x 2 root root 518140 Aug 30 23:12 /usr/bin/suidperl -rws--x--x 2 root root 518140 Aug 30 23:12 /usr/bin/ sperl5.00503 -rwxr-sr-x 1 root slocate 24744 Sep 20 10:29 /usr/bin/slocate *-rws--x--x 1 root root 14024 Sep 9 01:01 /usr/bin/chfn *-rws--x--x 1 root root 13768 Sep 9 01:01 /usr/bin/chsh *-rws--x--x 1 root root 5576 Sep 9 01:01 /usr/bin/newgrp *-rwxr-sr-x 1 root tty 8328 Sep 9 01:01 /usr/bin/write -rwsr-xr-x 1 root root 21816 Sep 10 16:03 /usr/bin/crontab *-rwsr-xr-x 1 root root 5896 Nov 23 21:59 /usr/sbin/ usernetctl *-rwsr-xr-x 1 root bin 16488 Jul 2 10:21 /usr/sbin/traceroute -rwxr-sr-x 1 root utmp 6096 Sep 13 20:11 /usr/sbin/utempter -rwsr-xr-x 1 root root 14124 Aug 17 22:31 /bin/su *-rwsr-xr-x 1 root root 53620 Sep 13 20:26 /bin/mount *-rwsr-xr-x 1 root root 26700 Sep 13 20:26 /bin/umount *-rwsr-xr-x 1 root root 18228 Sep 10 16:04 /bin/ping *-rwxr-sr-x 1 root root 3860 Nov 23 21:59 /sbin/netreport -r-sr-xr-x 1 root root 26309 Oct 11 20:48 /sbin/pwdb_chkpwd To disable the suid bits on selected programs above, type the following commands: [root@deep] /# chmod a-s /usr/bin/chage [root@deep] /# chmod a-s /usr/bin/gpasswd [root@deep] /# chmod a-s /usr/bin/wall [root@deep] /# chmod a-s /usr/bin/chfn [root@deep] /# chmod a-s /usr/bin/chsh [root@deep] /# chmod a-s /usr/bin/newgrp [root@deep] /# chmod a-s /usr/bin/write [root@deep] /# chmod a-s /usr/sbin/usernetctl [root@deep] /# chmod a-s /usr/sbin/traceroute [root@deep] /# chmod a-s /bin/mount [root@deep] /# chmod a-s /bin/umount [root@deep] /# chmod a-s /bin/ping [root@deep] /# chmod a-s /sbin/netreport Example 5.4. Use man pages If you want to know what those programs do, type man program-name and read the man page. [root@deep] /# man netreport 24.  The kernel tunable parameters With the new version of Red Hat Linux 6.2 all kernel parameters available under the /proc/sys subdirectory of Linux can be configured at runtime. You can now use the new /etc/sysctl.conf file under Red Hat Linux 6.2 to modify and set kernel parameters at runtime. The sysctl.conf file is read and loaded each time the system reboots. All settings are now stored in the /etc/sysctl.conf file. All modifications to /proc/sys should be made through /etc/sysctl.conf, because they offer better for control, and are executed before rc.local or any other users scripts. We have shown you the networking security options that you must configure on your server for both Red Hat Linux version 6.1 and 6.2 below. 24.1. Prevent your system responding to Ping Version 6.1 only Preventing your system for responding to ping request can be a big improvement in your network security since no one can ping on your server and receive an answer. The TCP/IP protocol suite has a number of loopholes that allows an attacker to leverage techniques in the form of covert channels to surreptitiously pass data in otherwise benign packets. Preventing your server from responding to ping requests can help to minimize this problem. An... [root@deep] /#echo 1 > /proc/sys/net/ipv4/icmp_echo_ignore_all ... should do the job such that your system won't respond to ping on any interface. You can add this line in your /etc/rc.d/rc.local file so the command will be automatically set if your system reboots. Not responding to pings would at least keep most "crackers" out because they would never even know it's there. To turn it backs on, simply do this: [root@deep] /#echo 0 > /proc/sys/net/ipv4/icmp_echo_ignore_all You can add this line in your /etc/rc.d/rc.local file so the command will be automatically set if your system reboots. Version 6.2 only Edit the /etc/sysctl.conf file and add the following line: # Enable ignoring ping request net.ipv4.icmp_echo_ignore_all = 1 You must restart your network for the change to take effect. The command to restart the network is the following: To restart all network devices manually on your system, use the following command: [root@deep] /# /etc/rc.d/init.d/network restart             Setting network parameters [  OK  ]             Bringing up interface lo [  OK  ]             Bringing up interface eth0         [  OK  ]             Bringing up interface eth1         [  OK  ]              25. Refuse responding to broadcasts request As for the ping request, it's also important to disable broadcast request. When a packet is sent to an IP broadcast address (i.e. 192.168.1.255) from a machine on the local network, that packet is delivered to all machines on that network. Then all the machines on a network respond to this ICMP echo request and the result can be severe network congestion or outages -denial-of-service attacks. See the RFC 2644 for more information. Version 6.1 only [root@deep] /# echo 1 > /proc/sys/net/ipv4/ icmp_echo_ignore_broadcasts You can add this line in your /etc/rc.d/rc.local file so the command will be automatically set if your system reboots. Version 6.2 only Edit the /etc/sysctl.conf file and add the following line: # Enable ignoring broadcasts request net.ipv4.icmp_echo_ignore_broadcasts = 1 You must restart your network for the change to take effect. The command to restart the network is the following: To restart all networks devices manually on your system, use the following command: [root@deep] /# /etc/rc.d/init.d/network restart               Setting network parameters   [  OK  ]               Bringing up interface lo   [  OK  ]               Bringing up interface eth0   [  OK  ]               Bringing up interface eth1   [  OK  ]                26. Routing Protocols Routing and routing protocols can create several problems. The IP source routing, where an IP packet contains details of the path to its intended destination, is dangerous because according to RFC 1122 the destination host must respond along the same path. If an attacker was able to send a source routed packet into your network, then he would be able to intercept the replies and fool your host into thinking it is communicating with a trusted host. I strongly recommend that you disable IP source routing to protect your server from this hole. To disable IP source routing on your server, type the following command in your terminal: Version 6.1 only [root@deep] /# for f in /proc/sys/net/ipv4/conf/*/ accept_source_route; do > echo 0 > $f > done [root@deep] /# Add the above commands to the /etc/rc.d/rc.local script file and you'll not have to type it again the next time you reboot your system. Version 6.2 only Edit the /etc/sysctl.conf file and add the following line: # Disables IP source routing net.ipv4.conf.all.accept_source_route = 0 You must restart your network for the change to take effect. The command to restart the network is the following: [root@deep] /# /etc/rc.d/init.d/network restart               Setting network parameters [  OK  ]               Bringing up interface lo [  OK  ]               Bringing up interface eth0 [  OK  ]               Bringing up interface eth1 [  OK  ]                Take Note that the above command for Red Hat Linux 6.1 or 6.2 will disable Source Routed Packets on all your interfaces lo, ethN, pppN etc. 27. Enable TCP SYN Cookie Protection A SYN Attack is a denial of service DoS attack that consumes all the resources on your machine, forcing you to reboot. Denial of service attacks -attacks which incapacitate a server due to high traffic volume or ones that tie-up system resources enough that the server cannot respond to a legitimate connection request from a remote system) are easily achievable from internal resources or external connections via extranets and Internet. To enable it, you have to do: Version 6.1.only [root@deep] /# echo 1 > /proc/sys/net/ipv4/tcp_syncookies Add the above commands to the /etc/rc.d/rc.local script file and you'll not have to type it again the next time you reboot your system. Version 6.2 only Edit the /etc/sysctl.conf file and add the following line: # Enable TCP SYN Cookie Protection net.ipv4.tcp_syncookies = 1 You must restart your network for the change to take effect. The command to restart the network is the following: [root@deep] /# /etc/rc.d/init.d/network restart Setting network parameters [ OK ] Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Bringing up interface eth1 [ OK ] If you receive an error message during execution of the above command, check that you have enabled the TCP syncookies option in your kernel configuration: IP: TCP syncookie support not enabled per default CONFIG_SYN_COOKIES Y/n/?. 28. Disable ICMP Redirect Acceptance When hosts use a non-optimal or defunct route to a particular destination, an ICMP redirect packet is used by routers to inform the hosts what the correct route should be. If an attacker is able to forge ICMP redirect packets, he or she can alter the routing tables on the host and possibly subvert the security of the host by causing traffic to flow via a path you didn't intend. It's strongly recommended to disable ICMP Redirect Acceptance to protect your server from this hole. version 6.1 only [root@deep] /# for f in /proc/sys/net/ipv4/conf/*/ accept_redirects; do > echo 0 > $f > done [root@deep] /# Add the above commands to the /etc/rc.d/rc.local script file and you'll not have to type it again the next time you reboot your system. Version 6.2 only Edit the /etc/sysctl.conf file and add the following line: # Disable ICMP Redirect Acceptance net.ipv4.conf.all.accept_redirects = 0 You must restart your network for the change to take effect. The command to restart manually the network is the following: [root@deep] /# /etc/rc.d/init.d/network restart Setting network parameters [ OK ] Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Bringing up interface eth1 [ OK ] Take Note that the above command for Red Hat Linux 6.1 or 6.2 will disable Redirect Acceptance Packets on all your interfaces lo, ethN, pppN etc. 29. Enable always-defragging Protection Version 6.1 only This protection must be enabled if you use your Linux server as a gateway to masquerade internal traffic to the Internet IP Masquerading. [root@deep] /#echo 1 > /proc/sys/net/ipv4/ip_always_defrag Add the above commands to the /etc/rc.d/rc.local script file and you'll not have to type it again the next time you reboot your system. Version 6.2 only Edit the /etc/sysctl.conf file and add the following line: # Enable always defragging Protection net.ipv4.ip_always_defrag = 1 You must restart your network for the change to take effect. The command to manually restart the network is the following: [root@deep] /# /etc/rc.d/init.d/network restart Setting network parameters [ OK ] Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Bringing up interface eth1 [ OK ] 30. Enable bad error message Protection Version 6.1 only This option will alert you to all bad error messages in your network. [root@deep] /#echo 1 > /proc/sys/net/ipv4/ icmp_ignore_bogus_error_responses Add the above commands to the /etc/rc.d/rc.local script file and you'll not have to type it again the next time you reboot your system. Edit the /etc/sysctl.conf file and add the following line: Version 6.2 only # Enable bad error message Protection net.ipv4.icmp_ignore_bogus_error_responses = 1 You must restart your network for the change to take effect. The command to manually restart the network is the following: [root@deep] /# /etc/rc.d/init.d/network restart Setting network parameters [ OK ] Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Bringing up interface eth1 [ OK ] 31. Enable IP spoofing protection The spoofing protection prevents your network from being the source of spoofed i.e. forged communications that are often used in DoS attacks. Version 6.1 only [root@deep] /# for f in /proc/sys/net/ipv4/conf/*/rp_filter; do > echo 1 > $f > done [root@deep] /# Add the above commands to the /etc/rc.d/rc.local script file and you'll not have to type it again the next time you reboot your system. Version 6.2 only Edit the /etc/sysctl.conf file and add the following line: # Enable IP spoofing protection, turn on Source Address Verification net.ipv4.conf.all.rp_filter = 1 You must restart your network for the change to take effect. The command to manually restart the network is the following: [root@deep] /# /etc/rc.d/init.d/network restart Setting network parameters [ OK ] Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Bringing up interface eth1 [ OK ] 32. Log Spoofed, Source Routed and Redirect Packets This protection will log all Spoofed Packets, Source Routed Packets, and Redirect Packets to your log files. Version 6.1 only [root@deep] /# for f in /proc/sys/net/ipv4/conf/*/log_martians; do > echo 1 > $f > done [root@deep] /# Add the above commands to the /etc/rc.d/rc.local script file and you'll not have to type it again the next time you reboot your system. Version 6.2 only Edit the /etc/sysctl.conf file and add the following line: # Log Spoofed Packets, Source Routed Packets, Redirect Packets net.ipv4.conf.all.log_martians = 1 You must restart your network for the change to take effect. The command to manually restart the network is the following: [root@deep] /# /etc/rc.d/init.d/network restart Setting network parameters [ OK ] Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Bringing up interface eth1 [ OK ] 33. Unusual or hidden files It is important to not forget to look everywhere on the system for unusual or hidden files -files that start with a period and are normally not shown by the ls command, as these can be used to hide tools and information password cracking programs, password files from other systems, etc.. A common technique on UNIX systems is to put a hidden directory or file in a user's account with an unusual name, something like '...' or '.. ' -dot dot space or ..+^G -dot dot ctrl-G. The find program can be used to look for hidden files. Example 5.5. Use find to find [root@deep] /# find / -name ".. " -print -xdev [root@deep] /# find / -name ".*" -print -xdev | cat -v Note Files with names such as .xx and .mail have been used that is, files that might appear to be normal. All SUID and SGID files that still exist on your system after we have removed those that won't absolutely require such privilege are a potential security risk, and should be monitored closely. Because these programs grant special privileges to the user who is executing them, it is necessary to ensure that insecure programs are not installed. A favorite trick of crackers is to exploit SUID root programs, and leave a SUID program as a backdoor to get in the next time. Find all SUID and SGID programs on your system, and keep track of what they are so that you are aware of any changes, which could indicate a potential intruder. Use the following command to find all SUID/SGID programs on your system: [root@deep] /# find / -type f \( -perm -04000 -o -perm -02000 \) \-exec ls -lg {} \; Tip See in this book under Securities_Software/Monitoring_Tools for more information about the software sXidthat will do the job for you automatically each day and report the results via mail. Group and world writable files and directories particularly system files partitions, can be a security hole if a cracker gains access to your system and modifies them. Additionally, world-writable directories are dangerous, since they allow a cracker to add or delete files as he or she wishes in these directories. In the normal course of operation, several files will be writable, including some from the /dev, /var/catman directories, and all symbolic links on your system. To locate all group & world-writable files on your system, use the command: [root@deep] /# find / -type f \( -perm -2 -o -perm -20 \) -exec ls -lg {} \; To locate all group & world-writable directories on your system, use the command: [root@deep] /# find / -type d \( -perm -2 -o -perm -20 \) -exec ls -ldg {} \; Tip A file and directory integrity checker like Tripwire software can be used regularly to scan, manage and find modified group or world writable files and directories easily. See in this book under Securities_Software/Monitoring_Tools for more information about Tripwire. Don't permit any unowned file. Unowned files may also be an indication that an intruder has accessed your system. If you find unowned file or directory on your system, verify its integrity, and if all looks fine, give it an owner name. Some time you may uninstall a program and get an unowned file or directory related to this software; in this case you can remove the file or directory safely. To locate files on your system that do not have an owner, use the following command: [root@deep] /#find / -nouser -o -nogroup Please Note Once again, files reported under /dev directory don't count. Finding all the .rhosts files that could exist on your server should be a part of your regular system administration duties, as these files should not be permitted on your system. Remember that a cracker only needs one insecure account to potentially gain access to your entire network. You can locate all .rhosts files on your system with the following command: [root@deep] /#find /home -name .rhosts You can also use a cron job to periodically check for, report the contents of, and delete $HOME/.rhosts files. Also, users should be made aware that you regularly perform this type of audit, as directed by policy. To use a cron job to periodically check and report via mail all .rhosts files, do the following: Create as root the find_rhosts_files script file under /etc/ cron.daily directory touch /etc/cron.daily/find_rhosts_files and add the following lines in this script file: #!/bin/sh /usr/bin/find /home -name .rhosts | (cat <               CERT Hotline:(+1) 412-268-7090               Facsimile:    (+1) 412-268-6989                CERT/CC personnel answer 8:00 a.m. to 8:00 p.m. EST (GMT 5)/EDT (GMT 4)) on working days; they are on call for emergencies during other hours and on weekends and holidays. Chapter 6. Linux General Optimization Table of Contents 1._The_/etc/profile_file 2._Benchmark_Results 3._Benchmark_results-i586 4._Benchmark_results_-i486 5._The_bdflush_parameters 6._The_buffermem_parameters 7._The_ip_local_port_range_parameters 8._The_/etc/nsswitch.conf_file 9._The_file-max_parameter 10._The_ulimit_parameter 11._The_atime_and_noatime_attribute 12._Tuning_IDE_Hard_Disk_Performance 13._Better_manage_your_TCP/IP_resources At this stage of your configuration, you should now have a Linux server optimally configured and secured. Our server contains the most essential package and programs installed to be able to work properly and the most essential general security configuration. Before we continue and begin to install the services we want to share with our clients/users, it is important to now tune our Linux server. The tuning we will perform in the following chapter will be applied to the whole system. It also applies to present as well as future programs, such as services that we will later install. Generally, if you don't use a x386 Intel processor, Red Hat Linux out of the box is not optimized for your specific CPU architecture, most people now run Linux on a Pentium processor. The sections below will guide you through different steps to optimize your Linux server for your specific processor, memory, and network, as well as your file system. 1. The /etc/profile file The /etc/profile file contains system wide environment stuff and startup programs. All customizations that you put in this file will apply for the entire environment variable on your system, so putting optimization flags in this file is a good choice. To squeeze the most performance from your x86 programs, you can use full optimization when compiling with the -O9 flag. Many programs contain -O2 in the Makefile. -O9 is the highest level of optimization. It will increase the size of what it produces, but it runs faster. Please Note it is not always true that the -O9 flag will make the best performance for your processor. If you have an x686 and above processor, surely, but below x686, not necessarily. When compiling, use the -fomit-frame-pointer switch for any kind of processor you may have. This will use the stack for accessing variables. Unfortunately, debugging is almost impossible with this option. You can also use the - mcpu=cpu_type and -march=cpu_type switch to optimize the program for the CPU listed to the best of GCC's ability. However, the resulting code will only be run able on the indicated CPU or higher. The optimization options apply only when we compile and install a new program in our server. These optimizations don't play any role in our Linux base system; it just tells our compiler to optimize the new programs that we will install with the optimization flags we have specified in the /etc/profile file. Below are the optimization flags that we recommend you put in your /etc/profile file depending on your CPU architecture. Procedure 6.1. Recommended optimization flags 1. For CPU i686 or PentiumPro, Pentium II, Pentium III In the /etc/profile file, put this line for a PentiumPro, Pentium II and III Pro Processor family: CFLAGS=-O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions For CPU i586 or Pentium: In the /etc/profile file, put this line for a Pentium Processor family: CFLAGS=-O3 -march=pentium -mcpu=pentium -ffast-math - funroll-loops -fomit-frame-pointer -fforce-mem -fforce-addr -malign- double -fno-exceptions For CPU i486: In the /etc/profile file, put this line for a i486 Processor family: CFLAGS=-O3 -funroll-all-loops -malign-double -mcpu=i486 -march=i486 -fomit-frame-pointer -fno-exceptions 2. Now after the selection of your CPU settings -i686, i586, or i486 a bit further down in the /etc/profile file, add CFLAGS LANG LESSCHARSET to the export line: export PATH PS1 HOSTNAME HISTSIZE HISTFILESIZE USER LOGNAME MAIL INPUTRC CFLAGS LANG LESSCHARSET 3. Log out and log back in; after this, the new CFLAGS environment variable is set, and software and other configure tool will recognize that. Pentium Pro/II/III optimizations will only work with egcs or pgcc compilers. The egcs compiler is already installed on your Server by default so you don't need to worry about it. Below is the explanation of the different optimization options we use: -funroll-loops The -funroll-loops optimization option will perform the optimization of loop unrolling and will do it only for loops whose number of iterations can be determined at compile time or run time. -funroll-all-loops The -funroll-all-loops optimization option will also perform the optimization of loop unrolling and is done for all loops. -ffast-math The -ffast-math optimization option will allow the GCC compiler, in the interest of optimizing code for speed, to violate some ANSI or IEEE rules/specifications. -malign-double The -malign-double optimization option will control whether the GCC compiler aligns double, long double, and long long variables on a two- word boundary or a one-word boundary. This will produce code that runs somewhat faster on a Pentium at the expense of more memory. -mcpu=cpu_type The -mcpu=cpu_type optimization option will set the default CPU to use for the machine type when scheduling instructions. -fforce-mem The -fforce-mem optimization option will produce better code by forcing memory operands to be copied into registers before doing arithmetic on them and by making all memory references potential common subexpressions. -fforce-addr The -fforce-addr optimization option will produce better code by forcing memory address constants to be copied into registers before doing arithmetic on them. -fomit-frame-pointer The -fomit-frame-pointer optimization option, one of the most interesting, will allow the program to not keep the frame pointer in a register for functions that don't need one. This avoids the instructions to save, set up and restores frame pointers; it also makes an extra register available in many functions and makes debugging impossible on most machines. Important All future optimizations that we will describe in this book refer by default to a Pentium II/III CPU family. So you must, if required, adjust the compilation flags for your specific CPU processor type in the /etc/profile file and also during your compilation time. 2. Benchmark Results Summaries by Architecture: Depending on your processor architecture and the version of your compiler GCC/EGCS, optimization results may vary. The charts below will help you to choose the best compilation flags for your compiler/CPU architecture. The compiler version installed on your Red Hat Linux version 6.1 and 6.2 is egcs 2.91.66, but be sure to check it even so before choosing your compiler optimization options. To verify the compiler version installed on your system, use the command: [root@deep] /# egcs --version egcs-2.91.66 All benchmark results, and future results, can be retrieved from the GCC home page at the following address: http://egcs.cygnus.com/ For a Pentium II/III CPU i686 with compiler version egcs-2.91.66, the best optimization options would be: CFLAGS=-O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions Otimization chart for i686 Comparitive analysis chart with the above mentioned flags 3. Benchmark results-i586 For a Pentium CPU i586 with compiler version egcs-2.91.66, the best optimization options would be: CFLAGS=-O3 -march=pentium -mcpu=pentium -ffast-math -funroll- loops -fomit-frame-pointer -fforce-mem -fforce-addr -malign-double -fno- exceptions Otimization chart for i586 Comparitive analysis chart with the above mentioned flags 4. Benchmark results -i486 For a i486 CPU with compiler version egcs-2.91.66, the best optimization options would be: CFLAGS=-O3 -funroll-all-loops -malign-double -mcpu=i486 - march=i486 -fomit-frame-pointer -fno-exceptions Otimization chart for i486 Comparitive analysis chart with the above mentioned flags 5. The bdflush parameters The bdflush file is closely related to the operation of the virtual memory VM subsystem of the Linux kernel and has a little influence on disk usage. This file /proc/sys/vm/bdflush controls the operation of the bdflush kernel daemon. We generally tune this file to improve file system performance. By changing some values from the default as shown below, the system seems more responsive; e.g. it waits a little more to write to disk and thus avoids some disk access contention. The default setup for the bdflush parameters under Red Hat Linux is: "40 500 64 256 500 3000 500 1884 2" To change the values of bdflush, type the following command on your terminal: Version 6.1 only [root@deep] /# echo "100 1200 128 512 15 5000 500 1884 2">/proc/ sys/vm/bdflush You may add the above commands to the /etc/rc.d/rc.local script file and you'll not have to type it again the next time you reboot your system. Version 6.2 only Edit the /etc/sysctl.conf file and add the following line: # Improve file system performance vm.bdflush = 100 1200 128 512 15 5000 500 1884 2 You must restart your network for the change to take effect. The command to manually restart the network is the following: [root@deep] /# /etc/rc.d/init.d/network restart           Setting network parameters  [  OK  ]           Bringing up interface lo  [  OK  ]           Bringing up interface eth0  [  OK  ]           Bringing up interface eth1  [  OK  ]            In our example above, according to the/usr/src/linux/Documentation/sysctl/ vm.txt file- The first parameter 100 % governs the maximum number of dirty buffers in the buffer cache. Dirty means that the contents of the buffer still have to be written to disk as opposed to a clean buffer, which can just be forgotten about. Setting this to a high value means that Linux can delay disk writes for a long time, but it also means that it will have to do a lot of I/O at once when memory becomes short. A low value will spread out disk I/O more evenly. The second parameter 1200 ndirty This gives the maximum number of dirty buffers that bdflush can write to the disk in one time. A high value will mean delayed, bursty I/O, while a small value can lead to memory shortage when bdflush isn't woken up often enough. The third parameter 128 nrefill This is the number of buffers that bdflush will add to the list of free buffers when refill_freelist() is called. It is necessary to allocate free buffers beforehand, since the buffers often are of a different size than memory pages and some bookkeeping needs to be done beforehand. The higher the number, the more memory will be wasted and the less often refill_freelist() will need to run. refill_freelist() 512 When this comes across more than nref_dirt dirty buffers, it will wake up bdflush. age_buffer 50*HZ, age_super parameters 5*HZ Finally, the age_buffer 50*HZ and age_super parameters 5*HZ govern the maximum time Linux waits before writing out a dirty buffer to disk. The value is expressed in jiffies (clockticks); the number of jiffies per second is 100. Age_buffer is the maximum age for data blocks, while age_super is for file system metadata. The fifth 15 and the last two parameters 1884 and 2 These are unused by the system so we don't need to change the default ones. Tip Look at /usr/src/linux/Documentation/sysctl/vm.txt for more information on how to improve kernel parameters related to virtual memory. 6. The buffermem parameters The buffermem file is also closely related to the operation of the virtual memory VM subsystem of the Linux kernel. The value in this file /proc/sys/vm/ buffermem controls how much memory should be used for buffer memory in percentage. It is important to note that the percentage is calculated as a percentage of total system memory. The default setup for the buffermem parameters under Red Hat Linux is: "2 10 60" Version 6.1 only To change the values of buffermem, type the following command on your terminal: [root@deep] /# echo "70 10 60" >/proc/sys/vm/buffermem You may add the above commands to the /etc/rc.d/rc.local script file and you'll not have to type it again the next time you reboot your system. Version 6.2 only Edit the /etc/sysctl.conf file and add the following line: # Improve virtual memory performance vm.buffermem = 70 10 60 You must restart your network for the change to take effect. The command to manually restart the network is the following: [root@deep] /# /etc/rc.d/init.d/network restart             Setting network parameters      [  OK  ]             Bringing up interface lo      [  OK  ]             Bringing up interface eth0      [  OK  ]             Bringing up interface eth1      [  OK  ]              According to the /usr/src/linux/Documentation/sysctl/vm.txt file, the first parameter 80 % means to use a minimum of 80 percent of memory for the buffer cache; the minimum percentage of memory that should be spent on buffer memory.The last two parameters 10 and 60 are unused by the system so we dont need to change the defaults. Depending of the amount of RAM you have in the server the value of 80% may vary. When your server is highly loaded and when all application are used, you can know in detail how much memory are required and used by the system. 80 % for the buffermem parameters seem to be too much for systems under 256 MB of RAM. Doing a free -m command on the prompt your system will display amount of free and used memory in the system. Once you have executed this command free - m, check for -/+ buffers/cache:values and get the one related to the minimal (- ) to set your value for buffermem. Example 6.1. For 128 MB of RAM 128 * 80% = 102.4 MB 128 - 102.4 = 25.6 MB [root@deep] /#free -m total used free shared buffers cached Mem: 124 121 3 30 43 48 -/+ buffers/cache: 29 95 Swap: 128 2 126 The result shows us that the -/+ buffers/cache: need 29 MB at minimum to run the system properly and with 128 MB of RAM set at 80% we have only 25.6 MB available. Hmmm! problem, i guess. so we go back to the calculator again and do this: 128 * 70% = 89.6 128 - 89.6 = 38.4 MB well solved good!. Tip Look at /usr/src/linux/Documentation/sysctl/vm.txt for more information on how to improve kernel parameters related to virtual memory. 7. The ip_local_port_range parameters The /proc/sys/net/ipv4/ip_local_port_range defines the local port range that is used by TCP and UDP traffic to choose the local port. You will see in the parameters of this file two numbers: The first number is the first local port allowed for TCP and UDP traffic on the server, the second is the last local port number. For high-usage systems you may change its default parameters to 32768-61000 -first-last. The default setup for the ip_local_port_range parameters under Red Hat Linux is: "1024 4999" Version 6.1 only To change the values of ip_local_port_range, type the following command on your terminal: [root@deep] /# echo "32768 61000" >/proc/sys/net/ipv4/ ip_local_port_range Add the above commands to the /etc/rc.d/rc.local script file and you'll not have to type it again the next time you reboot your system. Version 6.2 only Edit the /etc/sysctl.conf file and add the following line: # Allowed local port range net.ipv4.ip_local_port_range = 32768 61000 You must restart your network for the change to take effect. The command to manually restart the network is the following: [root@deep] /# /etc/rc.d/init.d/network restart             Setting network parameters     [  OK  ]             Bringing up interface lo     [  OK  ]             Bringing up interface eth0     [  OK  ]             Bringing up interface eth1     [  OK  ]              8. The /etc/nsswitch.conf file The /etc/nsswitch.conf file is used to configure which services are to be used to determine information such as hostnames, password files, and group files. The last two ones, password files, and group files in our case are not used, since we don't use NIS services on our server. Thus, we will focus on the hosts line in this file. Edit the nsswitch.conf file vi /etc/nsswitch.conf and change the hosts line to read: "hosts: dns files" Which means, for programs that want to resolve an address. They should use the dns feature first, and the /etc/hosts file if the DNS servers are not available or can't resolve the address. Also, we would recommend deleting all instances of NIS services from each line of this file unless you are using NIS! The result should look like this: passwd:files shadow:files group:files hosts:dns files bootparams:files ethers:files netmasks:files networks:files protocols:files rpc:files services:files automount:files aliases:files 9.  The file-max parameter The file-max file /proc/sys/fs/file-max sets the maximum number of file-handles that the Linux kernel will allocate. We generally tune this file to improve the number of open files by increasing the value of /proc/sys/fs/file-max to something reasonable like 256 for every 4M of RAM we have: i.e. for a machine with 128 MB of RAM, set it to 8192 - 128/4=32 32*256=8192. The default setup for the file-max parameter under Red Hat Linux is: "4096" To adjust the value of file-max to 128 MB of RAM, type the following on your terminal: Version 6.1 only [root@deep] /# echo "8192" >/proc/sys/fs/file-max Add the above commands to the /etc/rc.d/rc.local script file and you'll not have to type it again the next time your server reboots. Version 6.2 only Edit the /etc/sysctl.conf file and add the following line: # Improve the number of open files fs.file-max = 8192 You must restart your network for the change to take effect. The command to manually restart the network is the following: [root@deep] /# /etc/rc.d/init.d/network restart           Setting network parameters   [  OK  ]           Bringing up interface lo   [  OK  ]           Bringing up interface eth0   [  OK  ]           Bringing up interface eth1   [  OK  ]            Tip When you regularly receive from your server a lot of messages with errors about running out of open files, you might want to raise this limit. The default value is 4096. A file server or web server needs a lot of open files. 10. The ulimit parameter Linux itself has a Max Processes per user limit. This feature allows us to control the number of processes an existing user on the server may be authorized to have. To improve performance, we can safely set the limit of processes for the super-user root to be unlimited. Edit the .bashrc file vi / root/.bashrc and add the following line: ulimit -u unlimited You must exit and re-login from your terminal for the change to take effect. [root@deep] /# ulimit -a core file size (blocks) 1000000 data seg size (kbytes) unlimited file size (blocks) unlimited max memory size (kbytes) unlimited stack size (kbytes) 8192 cpu time (seconds) unlimited max user processes unlimited 1 pipe size (512 bytes) 8 open files 1024 virtual memory (kbytes) 2105343 _1_ Make sure that when you type as root the command ulimit -a on your terminal, it shows unlimited next to max user processes. Tip You may also do ulimit -u unlimited at the command prompt instead of adding it to the /root/.bashrc file. Increases the system limit on open files for instance a process on Red Hat 6.0 with kernel 2.2.5 could open at least 31000 file descriptors this way and a process on kernel 2.2.12 can open at least 90000 file descriptors this way. The upper bound seems to be available memory. To increases the number of open files to 90000 for the root account do the following: Edit the .bashrc file vi / root/.bashrc and add the following line: ulimit -n 90000 You must exit from your terminal and re-login for the change to take effect. [root@deep] /# ulimit -a core file size (blocks) 1000000 data seg size (kbytes) unlimited file size (blocks) unlimited max memory size (kbytes) unlimited stack size (kbytes) 8192 cpu time (seconds) unlimited max user processes unlimited pipe size (512 bytes) 8 open files 90000 1 virtual memory (kbytes) 2105343 _1_ Make sure that when you type as root the command ulimit -a on your terminal, it shows 90000 next to open files. Note In older 2.2 kernels, though, the number of open files per process is still limited to 1024, even with the above changes. 11. The atime and noatime attribute Linux records information about when files were created and last modified as well as when it was last accessed. There is a cost associated with recording the last access time. The ext2 file system of Linux has an attribute that allows the super-user to mark individual files such that their last access time is not recorded. This may lead to significant performance improvements on often accessed frequently changing files such as the contents of the /var/spool/news directory. To set the attribute to a file, use: [root@deep] /#chattr +A filename 1 _1_ For a specific file For a whole directory tree, do something like: [root@deep /root]#chattr -R +A /var/spool/ 1 [root@deep /root]#chattr -R +A /cache/ 2 [root@deep /root]#chattr -R +A /home/httpd/ona/ 3 _1_ For a news and mail _2_ For a proxy caches _3_ For a web pages Linux has a special mount option for file systems called noatime that can be added to each line that addresses one file system in the /etc/fstab file. If a file system has been mounted with this option, reading accesses to the file system will no longer result in an update to the atime information associated with the file like we have explained above. The importance of the noatime setting is that it eliminates the need by the system to make writes to the file system for files which are simply being read. Since writes can be somewhat expensive, this can result in measurable performance gains. Note that the write time information to a file will continue to be updated anytime the file is written to. In our example below, we will set the noatime option to our /chroot file system. Edit the fstab file vi /etc/fstab and add in the line that refer to /chrootfile system the noatime option after the defaults option as show below: /dev/sda7 /chroot ext2 defaults,noatime 1 2 You need not reboot your system for the change to take effect, just make the Linux system aware about the modification you have made to the /etc/fstab file. This can be accomplished with the following commands: [root@deep] /#mount -oremount /chroot/ Then test your results with the flowing command: [root@deep]# cat /proc/mounts            /dev/root /             ext2         rw 0 0            /proc      /proc        proc         rw 0 0            /dev/sda1  /boot        ext2         rw 0 0            /dev/sda8  /cache       ext2         rw 0 0            /dev/sda7  /chroot      ext2 rw,noatime 0 0            /dev/sda6  /home        ext2         rw 0 0            /dev/sda11 /tmp         ext2         rw 0 0            /dev/sda5  /usr         ext2         rw 0 0            /dev/sda9  /var         ext2         rw 0 0            none       /dev/pts   devpts         rw 0 0             If you see something like:/dev/sda7 /chroot ext2 rw,noatime 0 0, congratulations! 12. Tuning IDE Hard Disk Performance Putting your swap partitions near the beginning of your drive, see This_chart to_get_a_better_idea, may give you some acceptable improvement. The beginning of the drive is physically located on the outer portion of the cylinder, and the read/write head can cover much more ground per revolution. We typically see partitions placed at the end of the drive work 3MB/s slower using the hdparm - t command. Performance increases have been reported on massive disk I/O operations by setting the IDE drivers to use DMA, 32-bit transfers and multiple sector modes. The kernel seems to use more conservative settings unless told otherwise. The magic command to change the setting of your drive is hdparm. To enable 32-bit I/O over the PCI buses, use the command: [root@deep] /# /sbin/hdparm -c1 /dev/hda or hdb, hdc etc. This will usually, depending on your IDE Disk Drive model, cut the timing buffered disk reads time by 2. The hdparm(8) manpage says that you may need to use -c 3 for some chipsets. All (E)IDE drives still have only a 16-bit connection over the ribbon cable from the interface card. To enable DMA, use the command: [root@deep] /# /sbin/hdparm -d1 /dev/hda or hdb, hdc etc. This may depend on support for your motherboard chipset being compiled into your kernel. Also, this command will enable DMA support for your hard drive, it will cut the timing buffered disk reads time and will improve the performance by 2. To enable multiword DMA mode 2 transfers, use the command: [root@deep] /#/sbin/hdparm -d1 -X34 /dev/hda or hdb, hdc etc. This sets the IDE transfer mode for newer (E)IDE/ATA2 drives. check your hardware manual to see if you have it. To enable UltraDMA mode2 transfers, use the command: [root@deep] /# /sbin/hdparm -d1 -X66 /dev/hda or hdb, hdc etc. You'll need to prepare the chipset for UltraDMA beforehand. Also, see your manual page about hdparm for more information. Use this with extreme caution! To set multiple sector mode I/O, use the command: [root@deep] /#/sbin/hdparm -m XX /dev/hda or hdb, hdc etc. Where XX is the maximum setting supported by your drive. The -i flag can be used to find the maximum setting supported by an installed drive: look for MaxMultSect in the output. [root@deep] /#/sbin/hdparm -i /dev/hda or hdb, hdc etc. /dev/hda: Model=Maxtor 7540 AV, FwRev=GA7X4647, SerialNo=L1007YZS Config={ HardSect NotMFM HdSw>15uSec Fixed DTR>5Mbs FmtGapReq } RawCHS=1046/16/63, TrkSize=0, SectSize=0, ECCbytes=11 BuffType=3(DualPortCache), BuffSize=32kB, MaxMultSect=8, MultSect=8 DblWordIO=yes, maxPIO=2(fast), DMA=yes, maxDMA=1(medium) CurCHS=523/32/63, CurSects=379584528, LBA=yes, LBA=yes, LBAsects=1054368 tDMA={min:150,rec:150}, DMA modes: sword0 sword1 *sword2 *mword0 IORDY=on/off, tPIO={min:240,w/IORDY:180}, PIO modes: mode3 Multiple sector mode aka IDE Block Mode, is a feature of most modern IDE hard drives, permitting the transfer of multiple sectors per I/O interrupt, rather than the usual one sector per interrupt. When this feature is enabled, it typically reduces operating system overhead for disk I/O by 30-50%. On many systems it also provides increased data throughput of anywhere from 5% to 50%. You can test the results of your changes by running hdparm in performance test mode: [root@deep] /#/sbin/hdparm -t /dev/hda or hdb, hdc etc. Tip Once you have a set of hdparm options, you can put the commands in your /etc/ rc.d/rc.local file to run it every time you reboot the machine. 13. Better manage your TCP/IP resources This hack just make the time default values for TCP/IP connection lower so that more connections can be handled by time on your TCP/IP protocol. The following will decrease the amount of time your Linux box will try take to finish closing a connection and the amount of time before it will kill a stale connection. This will also turn off some IP extensions that aren't needed. The default setup for the TCP/IP parameters we'll change under Red Hat Linux are: * For the tcp_fin_timeout 180 * For the tcp_keepalive_time 7200 * For the tcp_window_scaling 1 * For the tcp_sack 1 * For the tcp_timestamps 1 To adjust the new TCP/IP values, type the following commands on your terminal: [root@deep] /#echo 30 >/proc/sys/net/ipv4/tcp_fin_timeout [root@deep] /#echo 1800 >/proc/sys/net/ipv4/tcp_keepalive_time [root@deep] /#echo 0 >/proc/sys/net/ipv4/tcp_window_scaling [root@deep] /#echo 0 >/proc/sys/net/ipv4/tcp_sack [root@deep] /#echo 0 >/proc/sys/net/ipv4/tcp_timestamps Execute the above commands and put them in your /etc/rc.d/rc.local file so you don't need to type them again each time your system reboots. Version 6.2 only Edit the /etc/sysctl.conf file and add the following lines: # Decrease the time default value for tcp_fin_timeout connection net.ipv4.tcp_fin_timeout = 30 # Decrease the time default value for tcp_keepalive_time connection net.ipv4.tcp_keepalive_time = 1800 # Turn off the tcp_window_scaling net.ipv4.tcp_window_scaling = 0 # Turn off the tcp_sack net.ipv4.tcp_sack = 0 # Turn off the tcp_timestamps net.ipv4.tcp_timestamps = 0 You must restart your network for the change to take effect. The command to manually restart the network is the following: [root@deep] /# /etc/rc.d/init.d/network restart              Setting network parameters     [  OK  ]              Bringing up interface lo     [  OK  ]              Bringing up interface eth0     [  OK  ]              Bringing up interface eth1     [  OK  ]               Chapter 7. Configuring and Building a Secure, Optimized Kernel Table of Contents 1._Pre-Install 1.1._Make_an_emergency_boot_floppy 2._Uninstallation_and_Optimization 3._Securing_the_kernel 4._Compilation 5._Kernel_configuration_-Part_"A" 6._Kernel_configuration_-Part_"B" 7._Kernel_configuration_-Part_"C" 8._Kernel_configuration_-Part_"D" 9._Kernel_configuration_-Part_"E" 10._Installing_the_new_kernel 11._Delete_programs,_Edit_files_pertaining_to_modules 12._Create_a_emergency_Rescue_and_Boot_floppy_disk Well, our Linux server seems to be getting in shape now! But wait, what is the most important part of our server? Yes, it's the kernel. The Linux kernel is the core of our operating system, and without it there is no Linux at all. So we must take care of our kernel and configure it to fit our needs and compile just features we really need. The first thing to do next is to build a kernel that best suits your system. It's very simple to do but, in any case, refer to the README file in the /usr/src/linux/ directory. When configuring your kernel only compile in code that you need and use. Few main reasons that come to mind are; * The Kernel will be faster less code to run, * You will have more memory, Kernel parts are NEVER swapped to the virtual memory, * More stable. Try probing for a non-existent card?, * Unnecessary parts can be used by an attacker to gain access to the machine or other machines on the network. * Modules are also slower than support compiled directly in the kernel. 1. Pre-Install In our configuration and compilation we will build a monolithic kernel. Monolithic kernel means to only answer Yes or No to the questions, don't make anything modular and omit the steps: * make_modules * make_modules_install. Also, we will patch our new kernel with the buffer overflow protection from kernel patches. Patches for the Linux kernel exist, like Solar Designer's non- executable stack patch, which disallows the execution of code on the stack, making a number of buffer overflow attacks harder - and defeating completely a number of current exploits used by "script kiddies" worldwide. Important Remember to only answer Yes or No to the questions when configuring your new kernel if you're intending to build a monolithic kernel. If you intend to use firewall masquerading functions or a dial-up ppp connection, you cannot build a monolithic kernel, since these function require the build of some modules, by default. Build, instead, a modularized kernel. A new kernel is very specific to your computer hardware, in the kernel configuration part; we are using the following hardware for our example. Of course you must change them to fit your system components. 1 Pentium II 400 MHz (i686) processor 1 Motherboard SCSI 1 Hard Disk SCSI 1 SCSI Controler Adaptec AIC 7xxx 1 CD-ROM ATAPI IDE 1 Floppy Disk 2 Ethernet Cards Intel EtherExpressPro 10/100 1 Mouse PS/2 These installation instructions assume Commands are Unix-compatible. The source path is /usr/src. Installations were tested on Red Hat Linux 6.1 and 6.2. All steps in the installation will happen in super-user account root. Latest Kernel version number is 2.2.14 Latest Secure Linux Kernel Patches version number is 2_2_14-ow2 All these below mentioned Packages were available in the following sites as of this writing but we suggest you can get additional information regarding mirror sites by searching on their respective home pages. * Kernel Homepage:http://www.kernelnotes.org/ Be sure to download: linux-2_2_14_tar.gz Kernel FTP Site: 139.142.90.113 * Secure Linux Kernel Patches Homepage:http://www.openwall.com/linux/ You must be sure to download: linux-2_2_14-ow2_tar.gz Secure Linux Kernel Patches FTP Site: 195.42.162.180 1.1. Make an emergency boot floppy The first of the pre-install step is to make an emergency boot floppy. Linux has a small utility named mkbootdisk to simply do this. The first step is to find out what kernel version, you are currently using. Check out your /etc/ lilo.conf file and see which image was booted from and from this image, we can find the kernel version we need to make our emergency boot floppy. [root@deep] /#cat /etc/lilo.conf In my example, I have the following in the lilo.conf file: boot=/dev/sda map=/boot/map install=/boot/boot.b prompt timeout=50 image=/boot/vmlinuz-2.2.12-20 1 label=linux 2 root=/dev/sda6 initrd=/boot/initrd-2.2.12-20.img read-only _1_ the kernel version _2_ the image we booted from Now you'll need to find the image that you booted from. On a standard new first install, it will be the one-labeled linux. In the above example we show that the machine booted using the /boot/vmlinuz-2.2.12-20 original kernel version of the system. Now we simply need to put a formatted 1.44 floppy in our system and execute the following command as root: [root@deep] /#mkbootdisk --device /dev/fd0 2.2.12-20                                      Insert a disk in /dev/ fd0. Any information on the disk will be lost.                  Press  to continue or ^C to abort:                                     Following these guidelines, you will now have a boot floppy with a known working kernel in case of problems with the upgrade. I recommend rebooting the system with the floppy to make sure that the floppy works correctly. 2.  Uninstallation and Optimization 1. We must copy the archive file of the Kernel to the /usr/src directory and move to this directory. [root@deep] /#cp linux-version_tar.gz /usr/src/ [root@deep] /#cd /usr/src/ These steps are required only if you already have installed a Linux kernel with a tar archive before. If it is a first, fresh install of Linux kernel, then instead uninstall the kernel-headers-version.i386.rpm, kernel-version.i386.rpm package that are on your system. Remove the Linux symbolic link with the following command: [root@deep ] /src#rm -rf linux Remove the Linux kernel headers directory with the following command: [root@deep ] /src#rm -rf linux-2.2.xx Remove the Linux kernel modules directory with the following command: [root@deep ] /src#rm -rf /lib/modules/2.2.xx Important Removing the old kernel modules is required only if you have installed a modularized kernel version before. If the modules directory doesn't exist under the /lib directory it's because your old kernel version is not a modularized kernel. If the original kernels RPM package are installed on your system instead of the Linux kernel tar archive, because you have just finished installing your new Linux system, or have used an RPM package before to upgrade your Linux system, then use the following command to uninstall the Linux kernel: You can verify that a kernel RPM package is installed on your system with the following command: [root@deep ] /src#rpm -qa |grep kernel                kernel-headers-2.2.xx.i386.rpm                kernel-2.2.xx.i386.rpm                                 To uninstall the linux kernel RPM, use the following command: [root@deep ] /src#rpm -e --nodeps kernel-headers kernel                                cannot remove /usr/src/linux-2.2.xx - directory not empty                cannot remove /lib/modules/2.2.xx - directory not empty                                 [root@deep ] /src#rm -rf /usr/src/linux-2.2.xx/ [root@deep ] /src#rm -rf /lib/modules/2.2.xx/ In the steps below, we remove manually the empty /usr/src/linux-2.2.xx and /lib/modules/2.2.xx directories after the uninstallation of the kernels RPM, the RPM uninstall program will not completely remove those directories. 2. Now, we must decompress the tar archive of the kernel and remove the Linux tar archive from the system. [root@deep ] /src#tar xzpf linux-version_tar.gz [root@deep ] /src#rm -f linux-version_tar.gz 3. To increase the number of tasks allowed the maximum number of processes per user, you may need to edit the /usr/src/linux/include/linux/tasks.h file and change the following parameters. Edit the tasks.h file, vi +14 / usr/src/linux/include/linux/tasks.h and change the following parameters: NR_TASKS from 512 to 3072 and MIN_TASKS_LEFT_FOR_ROOT from 4 to 24 Important The value in the NR_TASKS line denotes the maximum number of tasks (processes) handles that the Linux kernel will allocate per users. Increasing this number will allow you to handle more connections from clients on your server, example: an HTTP web server will be able to serve more client connections. Please don't forget, Linux is protected from allocation of all process slots for normal users. There is a special parameter line MIN_TASKS_LEFT_FOR_ROOT reserved especially for the super- user root that you may set for the number of process reserved to root -24 is a good value. 4. To optimize the Linux kernel to fit your specific CPU architecture and optimization flags you may need to edit the /usr/src/linux/Makefile file and change the following parameters. a. Edit the Makefile file (vi +18 /usr/src/linux/Makefile) and change the line: HOSTCC =gcc to read: HOSTCC =egcs. b. Edit the Makefile file, vi +25 /usr/src/linux/Makefile and change the line: CC =$(CROSS_COMPILE)gcc D__KERNEL__ -I$(HPATH) to read: CC =$(CROSS_COMPILE)egcs D__KERNEL__ -I$(HPATH). c. Edit the Makefile file vi +90 /usr/src/linux/Makefile and change the line: CFLAGS = -Wall -Wstrict-prototypes -O2 -fomit-frame-pointer to read: CFLAGS = -Wall -Wstrict-prototypes -O9 -funroll- loops -ffast-math -malign-double -mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions d. Edit the Makefile file vi +19 /usr/src/linux/Makefile and change the line: HOSTCFLAGS =-Wall -Wstrict-prototypes -O2 -fomit-frame-pointer to read: HOSTCFLAGS =-Wall -Wstrict-prototypes -O9 -funroll- loops -ffast-math -malign-double -mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions Important These changes turn on aggressive optimization tricks that may or may not work with all kernels. Please, if the optimization flags above, or the ones you have chosen for your CPU architecture do not work for you, don't try to absolutely force it to work. I wouldn't want to make your system unstable like Microsoft Windows. 3. Securing the kernel The secure Linux kernel patches from the Openwall Project are a great way to prevent attacks like Stack Buffer Overflows, and others. The Openwall patch is a collection of security-related features for the Linux kernel, all configurable via the new Security options configuration section that will be added to your new Linux kernel. This patch may change from version to version, and some may contain various other security fixes. New features of patch version linux-2_2_14-ow2_tar.gz are: * Non-executable user stack area * Restricted links in /tmp * Restricted FIFOs in /tmp * Restricted /proc * Special handling of fd 0, 1, and 2 * Enforce RLIMIT_NPROC on execve(2) * Destroy shared memory segments not in use Important When applying the linux-2_2_14-ow2 patch, a new Security options section will be added at the end of your kernel configuration. For more information and description of the different features available with this patch, see the README file that come with the source code of the patch. Applying the patch [root@deep] /#cp linux-2_2_14-ow2_tar.gz /usr/src/ 1 [root@deep] /#cd /usr/src/ 2 [root@deep ]/src#tar xzpf linux.2_2_14-ow2_tar.gz 3 [root@deep ]/src#cd linux-2.2.14-ow2/ 4 [root@deep ] /linux-2.2.14-ow2#mv linux-2.2.14-ow2.diff /usr/ src/ 5 [root@deep ] /linux-2.2.14-ow2#cd .. 6 [root@deep ]/src#patch -p0 16Mb of memory) (CONFIG_SKB_LARGE) Y/n/? The IPX protocol (CONFIG_IPX) N/y/? Appletalk DDP (CONFIG_ATALK) N/y/? Telephony support.  Linux telephony support (CONFIG_PHONE) N/y/? (NEW) SCSI support.  SCSI support (CONFIG_SCSI) Y/n/? SCSI disk support (CONFIG_BLK_DEV_SD) Y/n/? SCSI tape support (CONFIG_CHR_DEV_ST) N/y/? SCSI CD-ROM support (CONFIG_BLK_DEV_SR) N/y/? SCSI generic support (CONFIG_CHR_DEV_SG) N/y/? Probe all LUNs on each SCSI device (CONFIG_SCSI_MULTI_LUN) Y/n/? N Verbose SCSI error reporting (kernel size +=12K) (CONFIG_SCSI_CONSTANTS) Y/n/? N SCSI logging facility (CONFIG_SCSI_LOGGING) N/y/? SCSI low-level drivers.  7000FASST SCSI support (CONFIG_SCSI_7000FASST) N/y/? ACARD SCSI support (CONFIG_SCSI_ACARD) N/y/? Adaptec AHA152X/2825 support (CONFIG_SCSI_AHA152X) N/y/? Adaptec AHA1542 support (CONFIG_SCSI_AHA1542) N/y/? Adaptec AHA1740 support (CONFIG_SCSI_AHA1740) N/y/? Adaptec AIC7xxx support (CONFIG_SCSI_AIC7XXX) N/y/? Y Enable Tagged Command Queueing TCQ by default N/y/? (NEW) Y Maximum number of TCQ commands per device (CONFIG_AIC7XXX_CMDS_PER_DEVICE) [8] (NEW) Collect statistics to report in /proc (CONFIG_AIC7XXX_PROC_STATS) N/y/? (NEW) Delay in seconds after SCSI bus reset (CONFIG_AIC7XXX_RESET_DELAY) [5] (NEW) IBM ServeRAID support (CONFIG_SCSI_IPS) N/y/? (NEW) AdvanSys SCSI support (CONFIG_SCSI_ADVANSYS) N/y/? Always IN2000 SCSI support (CONFIG_SCSI_IN2000) N/y/? AM53/79C974 PCI SCSI support (CONFIG_SCSI_AM53C974) N/y/? AMI MegaRAID support (CONFIG_SCSI_MEGARAID) N/y/? BusLogic SCSI support (CONFIG_SCSI_BUSLOGIC) N/y/? DTC3180/3280 SCSI support (CONFIG_SCSI_DTC3280) N/y/? EATA ISA/EISA/PCI (DPT and generic EATA/DMA) support (CONFIG_SCSI_EATA) N/y/? EATA-DMA [Obsolete] (DPT, NEC, AT&T, SNI, AST, Olivetti, Alphatronix) support (CONFIG_SCSI_EATA_DMA) N/y/? EATA-PIO (old DPT PM2001, PM2012A) support (CONFIG_SCSI_EATA_PIO) N/y/? Future Domain 16xx SCSI/AHA-2920A support (CONFIG_SCSI_FUTURE_DOMAIN) N/y/? GDT SCSI Disk Array Controller support (CONFIG_SCSI_GDTH) N/ y/? Generic NCR5380/53c400 SCSI support (CONFIG_SCSI_GENERIC_NCR5380) N/y/? Initio 9100U(W) support (CONFIG_SCSI_INITIO) N/y/? Initio INI-A100U2W support (CONFIG_SCSI_INIA100) N/y/? NCR53c406a SCSI support (CONFIG_SCSI_NCR53C406A) N/y/? symbios 53c416 SCSI support (CONFIG_SCSI_SYM53C416) N/y/? Simple 53c710 SCSI support (Compaq, NCR machines) (CONFIG_SCSI_SIM710) N/y/? (NEW) NCR53c7,8xx SCSI support (CONFIG_SCSI_NCR53C7xx) N/y/? NCR53C8XX SCSI support (CONFIG_SCSI_NCR53C8XX) N/y/? SYM53C8XX SCSI support (CONFIG_SCSI_SYM53C8XX) Y/n/? N PAS16 SCSI support (CONFIG_SCSI_PAS16) N/y/? PCI2000 support (CONFIG_SCSI_PCI2000) N/y/? PCI2220i support (CONFIG_SCSI_PCI2220I) N/y/? PSI240i support (CONFIG_SCSI_PSI240I) N/y/? Qlogic FAS SCSI support (CONFIG_SCSI_QLOGIC_FAS) N/y/? Qlogic ISP SCSI support (CONFIG_SCSI_QLOGIC_ISP) N/y/? Qlogic ISP FC SCSI support (CONFIG_SCSI_QLOGIC_FC) N/y/? Seagate ST-02 and Future Domain TMC-8xx SCSI support (CONFIG_SCSI_SEAGATE) N/y/? Tekram DC390(T) and Am53/79C974 SCSI support (CONFIG_SCSI_DC390T) N/y/? Trantor T128/T128F/T228 SCSI support (CONFIG_SCSI_T128) N/y/ ? UltraStor 14F/34F support (CONFIG_SCSI_U14_34F) N/y/? UltraStor SCSI support (CONFIG_SCSI_ULTRASTOR) N/y/? 7. Kernel configuration -Part "C" Network device support.  Network device support (CONFIG_NETDEVICES) Y/n/? ARCnet devices.  ARCnet support (CONFIG_ARCNET) N/y/? Dummy net driver support (CONFIG_DUMMY) Y/n/? EQL -serial line load balancing support (CONFIG_EQUALIZER) N/ y/? General Instruments Surfboard 1000 (CONFIG_NET_SB1000) N/y/? (NEW) Ethernet (10 or 100Mbit).  Ethernet (10 or 100Mbit) (CONFIG_NET_ETHERNET) Y/n/? 3COM cards (CONFIG_NET_VENDOR_3COM) N/y/? AMD LANCE and PCnet (AT1500 and NE2100) support (CONFIG_LANCE) N/y/? Western Digital/SMC cards (CONFIG_NET_VENDOR_SMC) N/y/? Racal-Interlan (Micom) NI cards (CONFIG_NET_VENDOR_RACAL) N/y/ ? Other ISA cards (CONFIG_NET_ISA) N/y/? EISA, VLB, PCI and on board controllers (CONFIG_NET_EISA) Y/n/ ? AMD PCnet32 (VLB and PCI) support (CONFIG_PCNET32) N/y/? Apricot Xen-II on board Ethernet (CONFIG_APRICOT) N/y/? CS89x0 support (CONFIG_CS89x0) N/y/? DM9102 PCI Fast Ethernet Adapter support (EXPERIMENTAL) (CONFIG_DM9102) N/y/? (NEW) Generic DECchip & DIGITAL EtherWORKS PCI/EISA (CONFIG_DE4X5) N/y/? DECchip Tulip (dc21x4x) PCI support (CONFIG_DEC_ELCP) N/y/? Old DECchip Tulip (dc21x4x) PCI support (CONFIG_DEC_ELCP_OLD) N/y/? (NEW) Digi Intl. RightSwitch SE-X support (CONFIG_DGRS) N/y/? EtherExpressPro/100 support (CONFIG_EEXPRESS_PRO100) Y/n/? PCI NE2000 support (CONFIG_NE2K_PCI) N/y/? TI ThunderLAN support (CONFIG_TLAN) N/y/? VIA Rhine support (CONFIG_VIA_RHINE) N/y/? SiS 900/7016 PCI Fast Ethernet Adapter support (CONFIG_SIS900) N/y/? (NEW) Pocket and portable adaptors (CONFIG_NET_POCKET) N/y/? Ethernet (1000 Mbit).  SysKonnect SK-98xx support (CONFIG_SK98LIN) N/y/? (NEW) FDDI driver support (CONFIG_FDDI) N/y/? PPP (point-to-point) support (CONFIG_PPP) N/y/? SLIP (serial line) support (CONFIG_SLIP) N/y/? Wireless LAN (non-hamradio) (CONFIG_NET_RADIO) N/y/? Token ring devices.  Token Ring driver support (CONFIG_TR) N/y/? Fibre Channel driver support (CONFIG_NET_FC) N/y/? (NEW) Wan interfaces.  MultiGate (COMX) synchronous serial boards support (CONFIG_COMX) N/y/? (NEW) Frame relay DLCI support (CONFIG_DLCI) N/y/? WAN drivers (CONFIG_WAN_DRIVERS) N/y/? SBNI12-xx support (CONFIG_SBNI) N/y/? (NEW) Amateur Radio support.  Amateur Radio support (CONFIG_HAMRADIO) N/y/? IrDA subsystem support.  IrDA subsystem support (CONFIG_IRDA) N/y/? ISDN subsystem.  ISDN support (CONFIG_ISDN) N/y/? Old CD-ROM drivers (not SCSI, not IDE).  Support non-SCSI/IDE/ATAPI CDROM drives (CONFIG_CD_NO_IDESCSI) N/ y/? Character devices.  Virtual terminal (CONFIG_VT) Y/n/? Support for console on virtual terminal (CONFIG_VT_CONSOLE) Y/ n/? Standard/generic (dumb) serial support (CONFIG_SERIAL) Y/n/? Support for console on serial port (CONFIG_SERIAL_CONSOLE) N/ y/? Extended dumb serial driver options (CONFIG_SERIAL_EXTENDED) N/y/? Non-standard serial port support (CONFIG_SERIAL_NONSTANDARD) N/y/? Unix98 PTY support (CONFIG_UNIX98_PTYS) Y/n/? Maximum number of Unix98 PTYs in use (0-2048) (CONFIG_UNIX98_PTY_COUNT) [256] 128 Mouse Support (not serial mice) (CONFIG_MOUSE) Y/n/? 8. Kernel configuration -Part "D" Mice.  ATIXL busmouse support (CONFIG_ATIXL_BUSMOUSE) N/y/? Logitech busmouse support (CONFIG_BUSMOUSE) N/y/? Microsoft busmouse support (CONFIG_MS_BUSMOUSE) N/y/? PS/2 mouse (aka "auxiliary device") support (CONFIG_PSMOUSE) N/y/? C&T 82C710 mouse port support (as on TI Travelmate) (CONFIG_82C710_MOUSE) Y/n/? N PC110 digitizer pad support (CONFIG_PC110_PAD) N/y/? Joystick support.  Joystick support (CONFIG_JOYSTICK) N/y/? QIC-02 tape support (CONFIG_QIC02_TAPE) N/y/? Watchdog Timer Support (CONFIG_WATCHDOG) N/y/? /dev/nvram support (CONFIG_NVRAM) N/y/? Enhanced Real Time Clock Support (CONFIG_RTC) N/y/? Video for Linux.  Video For Linux (CONFIG_VIDEO_DEV) N/y/? Double Talk PC internal speech card support (CONFIG_DTLK) N/y/? Ftape, the floppy tape device driver.  Ftape (QIC-80/Travan) support (CONFIG_FTAPE) N/y/? Filesystems.  Quota support (CONFIG_QUOTA) N/y/? Y Kernel automounter support (CONFIG_AUTOFS_FS) Y/n/? N Amiga FFS filesystem support (CONFIG_AFFS_FS) N/y/? Apple Macintosh filesystem support (experimental) (CONFIG_HFS_FS) N/y/? DOS FAT fs support (CONFIG_FAT_FS) N/y/? ISO 9660 CDROM filesystem support (CONFIG_ISO9660_FS) Y/n/? Microsoft Joliet CDROM extensions (CONFIG_JOLIET) N/y/? Minix fs support (CONFIG_MINIX_FS) N/y/? NTFS filesystem support (read only) (CONFIG_NTFS_FS) N/y/? OS/2 HPFS filesystem support (read only) (CONFIG_HPFS_FS) N/y/ ? /proc filesystem support (CONFIG_PROC_FS) Y/n/? /dev/pts filesystem for Unix98 PTYs (CONFIG_DEVPTS_FS) Y/n/? ROM filesystem support (CONFIG_ROMFS_FS) N/y/? Second extended fs support (CONFIG_EXT2_FS) Y/n/? System V and Coherent filesystem support (CONFIG_SYSV_FS) N/y/ ? UFS filesystem support (CONFIG_UFS_FS) N/y/? Network File Systems.  Coda filesystem support (advanced network fs) (CONFIG_CODA_FS) N/y/? NFS filesystem support (CONFIG_NFS_FS) Y/n/? N SMB filesystem support (to mount WfW shares etc.) (CONFIG_SMB_FS) N/y/? NCP filesystem support (to mount NetWare volumes) (CONFIG_NCP_FS) N/y/? Partition Types.  BSD disklabel (BSD partition tables) support (CONFIG_BSD_DISKLABEL) N/y/? Macintosh partition map support (CONFIG_MAC_PARTITION) N/y/? SMD disklabel (Sun partition tables) support (CONFIG_SMD_DISKLABEL) N/y/? Solaris (x86) partition table support (CONFIG_SOLARIS_X86_PARTITION) N/y/? Console drivers.  VGA text console (CONFIG_VGA_CONSOLE) Y/n/? Video mode selection support (CONFIG_VIDEO_SELECT) N/y/? Sound .  Sound card support (CONFIG_SOUND) N/y/? 9. Kernel configuration -Part "E" Security options. Security options will appear only if you have patched your kernel with the Openwall Project patch. Non-executable user stack area (CONFIG_SECURE_STACK) Y Autodetect and emulate GCC trampolines (CONFIG_SECURE_STACK_SMART) Y Restricted links in /tmp (CONFIG_SECURE_LINK) Y Restricted FIFOs in /tmp (CONFIG_SECURE_FIFO) Y Restricted /proc (CONFIG_SECURE_PROC) N Y Special handling of fd 0, 1, and 2 (CONFIG_SECURE_FD_0_1_2) Y Enforce RLIMIT_NPROC on execve(2) (CONFIG_SECURE_RLIMIT_NPROC) Y Destroy shared memory segments not in use (CONFIG_SECURE_SHM) N Y Kernel hacking.  Magic SysRq key (CONFIG_MAGIC_SYSRQ) N/y/? Now, return to the /usr/src/linux/ directory, if you are not already in it. You need to compile the new kernel. You do so by using the following command: [root@deep ] /linux# make dep; make clean; make bzImage This line contains three commands in one. * The first one, make dep, actually takes your configuration and builds the corresponding dependency tree. This process determines what gets compiled and what doesn't. * The next step, make clean, erase all previous traces of a compilation so as to avoid any mistakes in which version of a feature gets tied into the kernel. * Finally, make bzImage does the full compilation of the kernel. After the process is complete, the kernel is compressed and ready to be installed on your system. Before we can install the new kernel, we must know if we need to compile the corresponding modules. This is required only if you said Yes to Enable loadable module support CONFIG_MODULES and have compiled some options in the kernel configuration above as a module. In this case, you must execute the following commands: [root@deep ] /linux#make modules [root@deep ] /linux#make modules_install Note The make modules and make modules_install commands are required only if you say Yes to Enable loadable module support CONFIG_MODULES in your kernel configuration above. 10. Installing the new kernel 1. Copy the file /usr/src/linux/arch/i386/boot/bzImage from the kernel source tree to the /boot directory, and give it an appropriate new name. [root@deep ] /linux#cp /usr/src/linux/arch/i386/boot/ bzImage /boot/vmlinuz-kernel.version.number An appropriated or recommended new name is something like vmlinuz-2.2.14, this is important if you want a new rescue floppy or emergency boot floppy using the mkbootdisk program that require some specific needs like for example: vmlinuz-2.2.14 instead of vmlinuz-2.2.14.a 2. Copy the file /usr/src/linux/System.map from the kernel source tree to the /boot directory, and give it an appropriate new name. [root@deep ] /linux#cp /usr/src/linux/System.map /boot/ System.map-kernel.version.number 3. Move into the /boot directory and rebuild the links to vmlinuz and System.map with the following commands: [root@deep ] /linux#cd /boot [root@deep ] /boot#ln -fs vmlinuz-kernel.version.number vmlinuz [root@deep ] /boot#ln -fs System.map-kernel.version.number System.map We must rebuild the links of vmlinuz and System.map to point them to the new kernel version installed. Without the new links LILO program will look by default for the old version of your Linux kernel. 4. Remove obsolete and unnecessary files under the /boot directory to make space: [root@deep ] /boot#rm -f module-info [root@deep ] /boot#rm -f initrd-2.2.xx.img The module-info link point to the old modules directory of your original kernel. Since we have installed a brand new kernel, we don't need to keep this broken link. The initrd-2.2.xx is a file that contains an initial RAM disk image that serves as a system before the disk is available. This file is only available and is installed from the Linux setup installation if your system has a SCSI adapter present. If we use and have a SCSI system, the driver now will be incorporated into our new Linux kernel since we have build a monolithic kernel, so we can remove this file initrd- 2.2.xx.img safely. 5. Create a new Linux kernel directory that will handle all header files related to Linux kernel for future compilation of other programs on your system. Recall, we had created two symlinks under the /usr/include directory that point to the Linux kernel to be able to compile it without receiving error and also be able to compile future programs. The /usr/ include directory is where all header files of your Linux system are kept for reference and dependencies when you compile and install new programs. The asm, and linux links are used when program need to know some functions from compile-time specific to the kernel installed on your system. Programs call other headers in the include directory when they must know specific information, dependencies, etc. of your system. [root@deep] /#mkdir -p /usr/src/linux-2.2.14/include [root@deep] /#cp -r /usr/src/linux/include/asm-generic / usr/src/linux-2.2.14/include [root@deep] /#cp -r /usr/src/linux/include/asm-i386 /usr/ src/linux-2.2.14/include [root@deep] /#cp -r /usr/src/linux/include/linux /usr/ src/linux-2.2.14/include [root@deep] /#cp -r /usr/src/linux/include/net /usr/src/ linux-2.2.14/include [root@deep] /#cp -r /usr/src/linux/include/video /usr/ src/linux-2.2.14/include [root@deep] /#cp -r /usr/src/linux/include/scsi /usr/src/ linux-2.2.14/include [root@deep] /#rm -rf /usr/src/linux [root@deep] /#cd /usr/src [root@deep ] /src#ln -s /usr/src/linux-2.2.14 linux First we create a new directory named linux-2.2.14 based on the version of the kernel we have installed for easy interpretation, then we copy directories asm-generic, asm-i386, linux, net, video, and scsi from /usr/ linux/include to our new place /usr/src/linux-2.2.14/include. After We remove the entire source directory where we had compiled the new kernel, create a new symbolic link named linux under /usr/src that points to our new /usr/src/linux-2.2.14/include directory. With these steps, future compiled programs will know where to look for headers related to the kernel on your server. Note This step will allow us to gain space on our hard drive and will reduce the risk of security. The Linux kernel source directory handles a of lot files and is about 75 MB in size when uncompressed. With the procedure described above, our Linux kernel directory began approximately 3 MB in size so we save 72 MB for the same functionalities. 6. Finally, you need to edit the /etc/lilo.conf file to make your new kernel one of the boot time options: a. Edit the lilo.conf file - vi /etc/lilo.conf and make the appropriated change on the line that read image=/boot/. [root@deep] /#vi /etc/lilo.conf                                boot=/dev/sda              map=/boot/map              install=/boot/boot.b              prompt              timeout=00              restricted              password=somepasswd              image=/boot/vmlinuz- kernel.version.number  #add your new kernel name file here.              label=linux              root=/dev/sda6              read-only                             Important Don't forget to remove the line that read initrd=/boot/initrd-2.2.12- 20.img in the lilo.conf file, since this line is not necessary now monolithic kernel doesn't need an initrd file. b. Once the name of the new kernel version has been put in the lilo.conf file as shown above, we update our lilo.conf file for the change to take effect with the following command: [root@deep] /#/sbin/lilo -v                              LILO version 21, [Copyright 1992-1998 Werner Almesberger              Reading boot sector from /dev/sda              Merging with /boot/boot.b              Boot image: /boot/vmlinuz-2.2.14              Added linux *              /boot/boot.0800 exits  no backup copy made.              Writing boot sector.                             Important If you say NO to the configuration option Unix98 PTY support CONFIG_UNIX98_PTYS during your kernel configuration, you must edit the /etc/fstab file and remove the line that read: none /dev/pts devpts gid=5,mode=620 0 0 11. Delete programs, Edit files pertaining to modules By default when you install Red Hat Linux for the first time like we do, the kernel is built as a modularized kernel. This means that each device or function we need exists as modules and is controlled by the Kernel Daemon program named kmod, which automatically loads some modules and functions support into memory as it is needed, and unloads it when it's no longer being used. 1. kmod and other module management programs included in the modutils RPM package use the conf.modules file located in the /etc directory to know, for example which Ethernet card you have, if your Ethernet card requires special configuration and so on. Since we are not using any modules in our new compiled kernel, we can remove the conf.modules file and uninstall completely the modutils package program. To remove the conf.modules file, use the command: [root@deep] /#rm -f /etc/conf.modules To uninstall the modutils package, use the following command: [root@deep] /#rpm -e --nodeps modutils 2. One last thing to do is to edit the file rc.sysinit and comment out all the lines related to depmod -a by inserting a # at the beginning of the lines. This is needed since at boot time the system read the rc.sysinit script to find module dependencies in the kernel by default. Version 6.2 only Comment out the line 260 in the rc.sysinit file vi +260 /etc/rc.d/ rc.sysinit: if [ -x /sbin/depmod -a -n "$USEMODULES" ]; then, To read: #if [ -x /sbin/depmod -a -n "$USEMODULES" ]; then Comment out the lines 272 to 277 in the rc.sysinit file vi +272 /etc/rc.d/ rc.sysinit: if [ -L /lib/modules/default ]; then INITLOG_ARGS= action "Finding module dependencies" depmod - a default else INITLOG_ARGS= action "Finding module dependencies" depmod -a fi fi To read: # if [ -L /lib/modules/default ]; then # INITLOG_ARGS= action "Finding module dependencies" depmod -a default # else # INITLOG_ARGS= action "Finding module dependencies" depmod -a # fi #fi Important The procedure described above relates to initscripts-4_70-1 package under Red Hat Linux version 6.1. Version 6.2 only Comment out the line 243 in the rc.sysinit file vi +243 /etc/rc.d/ rc.sysinit: if [ -x /sbin/depmod -a -n "$USEMODULES" ]; then, To read: #if [ -x /sbin/depmod -a -n "$USEMODULES" ]; then Comment out the lines 255 to 260 in the rc.sysinit file vi +255 /etc/rc.d/ rc.sysinit: if [ -L /lib/modules/default ]; then INITLOG_ARGS= action "Finding module dependencies" depmod - a default else INITLOG_ARGS= action "Finding module dependencies" depmod -a fi fi To read: # if [ -L /lib/modules/default ]; then # INITLOG_ARGS= action "Finding module dependencies" depmod -a default # else # INITLOG_ARGS= action "Finding module dependencies" depmod -a # fi #fi Once again, all of this part Delete program, file and lines related to modules is required only if you said No to Enable loadable module support CONFIG_MODULES in your kernel configuration above. 3. Now you must Reboot your system and test your results. [root@deep] /#reboot When the system is rebooted and you are logged in, verify the new version of your kernel with the following command: To verify the version of your new kernel, use the following command: [root@deep] /#uname -a                          Linux deep.openna.com 2.2.14 #1 Mon Jan 10 10:40: 35 EDT 2000 i686 unknown            [root@deep]#                         Congratulation !. 12. Create a emergency Rescue and Boot floppy disk After the reboot of your Linux server, you should have now a system with an upgraded kernel. Therefore, it's time is to make a new rescue image with the new kernel in case of future emergencies. To do this, follow the simple step below; Login as root, and insert a new floppy, then execute the following command: [root@deep] /#mkbootdisk --device /dev/fd0 2.2.14                              Insert a disk in /dev/ fd0. Any information on the disk will be lost.              Press  --device ^C to abort:                             Important The mkbootdisk program runs only on modularized kernel. So you can't use it on a monolithic kernel; instead create an emergency boot floppy as shown below if you have a problem with your system in the future. Because it is possible to create a rescue floppy only on modularized kernel, we must find another way to boot our Linux system if the Linux kernel on the hard disk is damaged. This is possible with a Linux emergency boot floppy disk. You should immediately create it after you successfully start your system and log in as root. 1. To create the emergency boot floppy disk, follow these steps: a. Insert a floppy disk and format it with the following command: [root@deep] /#fdformat /dev/fd0H1440                              Double-sided, 80 tracks, 18 sec/ track. Total capacity 1440 kB.              Formatting ... done              Verifying ... done                             b. Copy the file vmlinuz from the /boot directory to the floppy disk: [root@deep] /#cp /boot/vmlinuz /dev/fd0                              cp: overwrite '/dev/fd0'? y                             The vmlinuz file is a symbolic link that point to the real Linux kernel. c. Determine the kernel's root device with the following command: [root@deep] /#rdev /dev/sda12 / The kernel's root device is the disk partition where the root file system is located. In this example, the root device is dev/sda12; the device name may be different on your system. d. Set the kernel's root device with the following command: [root@deep] /#rdev /dev/fd0 /dev/sda12 To set the kernel's root device, use the device reported by the rdev command utility in the previous step. e. 5.Mark the root device as read-only with the following command: [root@deep] /#rdev -R /dev/fd0 1 This causes Linux initially to mount the root file system as read- only. By setting the root device as read-only, you avoid several warning and error messages. f. Now put the boot floppy in the drive A: and reboot your system with the following command: [root@deep] /#reboot 2. Update your /dev entries:If you have added new devices to your system or have done recently a major kernel upgrade (a major kernel upgrade is for example when you pass from kernel version 2.2.9 to 2.2.15 directly), it may be important to update your /dev entries to avoid problems related to missing devices. We can accomplish this task with the MAKEDEV script utility that scan the /dev directory where all devices that interfaces with drivers in the kernel are kept. A special option named update allow the MAKEDEV utility to create new devices that you have configured in your kernel and delete those which are no longer configured.To update your /dev entries, execute the following commands: [root@deep] /#cd /dev [root@deep ] /dev#./MAKEDEV update Part 4. Networking -Management, Firewall, Masquerading and Forwarding PIG Abstract Until now, we have not tinkered with the networking capabilities of Linux. Linux is one of the best existing operating systems in the world for networking features. Most Internet sites around the world already know this, and have used it for quite some time. Understanding your hardware network and all files related to it is very important if you want to have a full control of what happens on your server. Good knowledge of primary networking commands is vital. Network management covers a wide variety of topics. In general, it includes gathering statistical data and status of parts of your network, and taking action as necessary to deal with failures and other changes. Table of Contents 8._TCP/IP_-Network_Management 1._Multiple_Ethernet_Card_per_Machine 9._Files_-Networking_Functionality 1._The_/etc/HOSTNAME_file 2._The_/etc/sysconfig/network-scripts/ifcfg-ethN_files 3._The_/etc/resolv.conf_file 4._The_/etc/host.conf_file 5._The_/etc/sysconfig/network_file 6._The_/etc/sysctl.conf_file 7._The_/etc/hosts_file 8._Config_TCP/IP_Networking_manually_-command_line 10._Networking_-Firewall 1._Policy,_Guidelines_etc. 2._The_topology 3._Build_a_kernel_with_IPCHAINS_Firewall_support 4._Rules_used_in_the_Firewall_script_files 5._Source_Address_Filtering 11._The_firewall_scripts_files 1._Config_/etc/rc.d/init.d/firewall_script_file_-Web_Server 2._Config_/etc/rc.d/init.d/firewall_script_file_-_Mail_Server 12._Networking_Firewall_-Masquerading_and_Forwarding 1._Build_a_kernel_with_Firewall_Masquerading_and_Forwarding_support 2._Config_/etc/rc.d/init.d/firewall_script_file_-Gateway_Server 3._Configure_script_for_Example_Gateway_Server 4._Deny_access_to_some_address 5._IPCHAINS_Administrative_Tools Chapter 8. TCP/IP -Network Management Table of Contents 1._Multiple_Ethernet_Card_per_Machine The most primitive technique for network monitoring is periodic pinging of critical hosts. More sophisticated network monitoring requires the ability to get specific status and statistical information from various devices on the network. These should include various sorts of data gram counts, as well as counts of errors of various kinds. For these reasons, in this part we will try to answer fundamental questions about networking devices, files related to networking functionality, and essential networking commands. 1. Multiple Ethernet Card per Machine You can use Linux as a gateway between two Ethernet networks. In that case, you might have two Ethernet cards on your server. To eliminate problems at boot time, the Linux kernel doesn't detect multiple cards automatically. If you happen to have two or more cards, you should specify the parameters of the cards in the lilo.conf file for a monolithic kernel or in the conf.modules file for a modularized kernel. The following are problems you may encounter with your network cards. Problem 1.  If the driver(s) of the card(s) is/are being used as a loadable module modularized kernel, in the case of PCI drivers, the module will typically detect all of the installed cards automatically. For ISA cards, you need to supply the I/O base address of the card so the module knows where to look. This information is stored in the file /etc/conf.modules. Example 8.1. Two ISA ethernet cards Consider we have two ISA 3c509 cards, one at I/O 0x300 and one at I/O 0x320. For ISA cards, edit the conf.modules file, vi /etc/conf.modules and add: alias eth0 3c509 alias eth1 3c509 options 3c509 io=0x300,0x320 This says that the 3c509 driver should be loaded for either eth0 or eth1 alias eth0, eth1 and it should be loaded with the options io=0x300,0x320 so that the drivers knows where to look for the cards. Note that 0x is important, things like 300h as commonly used in the DOS world wont work. For PCI cards, you typically only need the alias lines to correlate the ethN interfaces with the appropriate driver name, since the I/O base of a PCI card can be safely detected. For PCI cards, edit the conf.modules file vi /etc/ conf.modules and add: alias eth0 3c509 alias eth1 3c509 Problem 2.  If the drivers(s) of the card(s) is/are compiled into the kernel - monolithic kernel, the PCI probes will find all related cards automatically. ISA cards will also find all related cards automatically, but in some circumstance ISA cards still need to do the following. This information is stored in the file /etc/lilo.conf. The method is to pass boot-time arguments to the kernel, which is usually done by LILO. For ISA cards, edit the lilo.conf file, vi /etc/lilo.conf and add: append=ether=0,0,eth1 Important First test your ISA cards without the boot-time arguments in the lilo.conf file, and if this fails, use the boot-time arguments. In this case eth0 and eth1 will be assigned in the order that the cards are found at boot. Since we have recompiled the kernel, we must use the second method. If the drivers(s) is/are compiled into the kernel to install our second Ethernet card on the system. Remember that this is required only in some circumstance for ISA cards, PCI cards will be found automatically. Chapter 9. Files -Networking Functionality Table of Contents 1._The_/etc/HOSTNAME_file 2._The_/etc/sysconfig/network-scripts/ifcfg-ethN_files 3._The_/etc/resolv.conf_file 4._The_/etc/host.conf_file 5._The_/etc/sysconfig/network_file 6._The_/etc/sysctl.conf_file 7._The_/etc/hosts_file 8._Config_TCP/IP_Networking_manually_-command_line This chapter deals with all the basic files usually text files related to TCP/ IP networking.It's very important to know the configurations files related to TCP/IP networking, so that you can edit and configure the files if necessary. Remember that our server doesn't have an Xwindow interface to configure files via graphical interface. Even if you use a GUI in your daily activities it is important to know how to configure network in text mode. The following sections describe the basic TCP/IP configuration files. 1. The /etc/HOSTNAME file This file stores your system's host name, your system's fully qualified domain name -FQDN, such as deep.openna.com. Following is a sample /etc/HOSTNAME file: deep.openna.com 2. The /etc/sysconfig/network-scripts/ifcfg-ethN files File configurations for each network device you may have or want to add on your system are located in the /etc/sysconfig/network-scripts/ directory with Red Hat Linux 6.1 or 6.2 and are named ifcfg-eth0 for the first interface and ifcfg-eth1 for the second, etc. Following is a example /etc/sysconfig/network- scripts/ifcfg-eth0 file: DEVICE=eth0 IPADDR=208.164.186.1 NETMASK=255.255.255.0 NETWORK=208.164.186.0 BROADCAST=208.164.186.255 ONBOOT=yes BOOTPROTO=none USERCTL=no If you want to modify your network address manually, or add a new network on a new interface, edit this file -ifcfg-ethN, or create a new one and make the appropriate changes. * DEVICE=devicename, where devicename is the name of the physical network device. * IPADDR=ipaddr, where ipaddr is the IP address. * NETMASK=netmask, where netmask is the netmask IP value. * NETWORK=network, where network is the network IP address. * BROADCAST=broadcast, where broadcast is the broadcast IP address. * ONBOOT=answer, where answer is yes or no. Do the interface need to be active or inactive at boot time. * BOOTPROTO=proto, where proto is one of the following : i. none - No boot-time protocol should be used. ii. bootp - The bootp now pump protocol should be used. iii. dhcp - The dhcp protocol should be used. * USERCTL=answer, where answer is one of the following: 1. yes - Non-root users are allowed to control this device. 2. no - Only the super-user root is allowed to control this device. 3. The /etc/resolv.conf file This file is another text file, used by the resolver a library that determines the IP address for a host name. Following is a sample /etc/resolv.conf file: search openna.com nameserver 208.164.186.1 nameserver 208.164.186.2 Note Name servers are queried in the order they appear in the file primary, secondary. 4. The /etc/host.conf file This file specifies how names are resolved. Linux uses a resolver library to obtain the IP address corresponding to a host name. Following is a sample /etc/ host.conf file: # Lookup names via DNS first then fall back to /etc/hosts. order bind,hosts 1 # We have machines with multiple addresses. multi on 2 # Check for IP address spoofing. nospoof on 3 _1_ The order option indicates the order of services. The sample entry specifies that the resolver library should first consult the name server (DNS) to resolve a name and then check the /etc/hosts file. _2_ The multi option determines whether a host in the /etc/hosts file can have multiple IP addresses multiple interface ethN. Hosts that have more than one IP address are said to be multiomed, because the presence of multiple IP addresses implies that host has several network interfaces. _3_ The nospoof option indicates to take care of not permitting spoofing on this machine. IP-Spoofing is a security exploit that works by tricking computers in a trust relationship that you are someone that you really aren't. 5. The /etc/sysconfig/network file The /etc/sysconfig/network file is used to specify information about the desired network configuration on your server. Following is a example /etc/ sysconfig/network file: NETWORKING=yes FORWARD_IPV4=yes HOSTNAME=deep. openna.com GATEWAY=0.0.0.0 GATEWAYDEV= The following values may be used: * NETWORKING=answer, where answer is yes or no -Configure networking or not to configure networking. * FORWARD_IPV4=answer, where answer is yes or no -Perform IP forwarding or not to perform IP forwarding. * HOSTNAME=hostname, where hostname is the hostname of your server. * GATEWAY=gwip, where gwip is the IP address of the remote network gateway -if available. * GATEWAYDEV=gwdev, where gwdev is the device name eth# you use to access the remote gateway. Important For compatibility with older software, the /etc/HOSTNAME file should contain the same value as HOSTNAME= hostname above. With the new version of Red Hat Linux 6.2 the FORWARD_IPV4= parameter is now specified in the /etc/sysctl.conf file instead of the /etc/sysconfig/network file. 6. The /etc/sysctl.conf file In Red Hat Linux 6.2, many kernel options related to networking security such as dropping packets that come in over interfaces they shouldn't or ignoring ping/broadcasts request, etc. can be set in the new /etc/sysctl.conf file instead of the /etc/rc.d/rc.local file. One important consideration is the IPv4 forwarding parameter which is now done via the sysctl program, as opposed to being controlled by the contents of the file in /etc/sysconfig/network. The sysctl settings are stored in /etc/sysctl.conf, and are loaded at each boot before the /etc/rc.d/rc.local file is loaded. We've already talked about all networking security parameters that we must set into the server in General System_Security, and for this reason we'll focus only on the kernel option for IPv4 forwarding. To enable IPv4 forwarding on your RH 6.2 system, use the following command: Edit the /etc/sysctl.conf file and add the following line: # Enable packet forwarding net.ipv4.ip_forward = 1 You must restart your network for the change to take effect. The command to restart the network is the following: [root@deep] /# /etc/rc.d/init.d/network restart Setting network parameters [ OK ] Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Bringing up interface eth1 [ OK ] Tip Enabling IPv4 forwarding via the sysctl.conf file is only valid for Red Hat Linux 6.2 users. Users with version 6.1 of Red Hat must set this parameter into the /etc/sysconfig/network file as explained above. 7. The /etc/hosts file As your machine gets started, it will need to know the mapping of some hostnames to IP addresses before DNS can be referenced. This mapping is kept in the /etc/hosts file. In the absence of a name server, any network program on your system consults this file to determine the IP address that corresponds to a host name. Following is a sample /etc/hosts file: IPAddress Hostname Alias 127.0.0.1 localhost deep.openna.com 208.164.186.1 deep.openna.com deep 208.164.186.2 mail.openna.com mail 208.164.186.3 web.openna.com web The leftmost column is the IP address to be resolved. The next column is that host's name. Any subsequent columns are alias for that host. In the second line, for example, the IP address 208.164.186.1 is for the host deep.openna.com. Another name for deep.openna.com is deep. After you are finished configuring your networking files, don't forget to restart your network for the changes to take effect. [root@deep] /# /etc/rc.d/init.d/network restart Setting network parameters [ OK ] Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Bringing up interface eth1 [ OK ] Important Time out problems for telnet or ftp connection are often caused by the server trying to resolve the client IP address to a DNS name. Either DNS isn't configured properly on your server or the client machines aren't known to DNS. If you intend to run telnet or ftp services on your server, and aren't using DNS, don't forget to add the client machine name and IP in your /etc/hosts file on the server or you can expect to wait several minutes for the DNS lookup to time out, before you get a login: prompt. 8. Config TCP/IP Networking manually -command line The ifconfig utility is the tool used to set up and configure your network card. You should understand this command in the event you need to configure the network by hand. An important note to take care with is when using ifconfig to configure your network devices; the settings will not survive a reboot. To assign the eth0 interface the IP-address of 208.164.186.2 use the command: [root@deep] /#ifconfig eth0 208.164.186.2 netmask 255.255.255.0 Tip Usually, the pratice is to configure or change the TCP/IP networking manually only to make some test on the server. If you want to keep your TCP/IP values, it's preferable to set them in the files related to networking functionality. To display all the interfaces you have on your server, use the command: [root@deep] /#ifconfig The output should look something like this: eth0 Link encap:Ethernet HWaddr 00:E0:18:90:1B:56 inet addr:208.164.186.2 Bcast:208.164.186.255 Mask:255.255.255.0 UP BROADCAST RUNNING MULTICAST MTU:1500 Metric:1 RX packets:1295 errors:0 dropped:0 overruns:0 frame:0 TX packets:1163 errors:0 dropped:0 overruns:0 carrier:0 collisions:0 txqueuelen:100 Interrupt:11 Base address:0xa800 lo Link encap:Local Loopback inet addr:127.0.0.1 Mask:255.0.0.0 UP LOOPBACK RUNNING MTU:3924 Metric:1 RX packets:139 errors:0 dropped:0 overruns:0 frame:0 TX packets:139 errors:0 dropped:0 overruns:0 carrier:0 collisions:0 txqueuelen:0 If the ifconfig tool is invoked without any parameters, it displays all interfaces you have configured. An option of -a shows the inactive one as well. To display all interfaces as well as inactive interfaces you may have, use the command: [root@deep] /#ifconfig -a The output should look something like this: eth0 Link encap:Ethernet HWaddr 00:E0:18:90:1B:56 inet addr:208.164.186.2 Bcast:208.164.186.255 Mask:255.255.255.0 UP BROADCAST RUNNING MULTICAST MTU:1500 Metric:1 RX packets:1295 errors:0 dropped:0 overruns:0 frame:0 TX packets:1163 errors:0 dropped:0 overruns:0 carrier:0 collisions:0 txqueuelen:100 Interrupt:11 Base address:0xa800 eth1 Link encap:Ethernet HWaddr 00:E0:18:90:1B:56 inet addr:192.168.1.1 Bcast:192.168.1.255 Mask:255.255.255.0 UP BROADCAST RUNNING MULTICAST MTU:1500 Metric:1 RX packets:1295 errors:0 dropped:0 overruns:0 frame:0 TX packets:1163 errors:0 dropped:0 overruns:0 carrier:0 collisions:0 txqueuelen:100 Interrupt:5 Base address:0xa320 lo Link encap:Local Loopback inet addr:127.0.0.1 Mask:255.0.0.0 UP LOOPBACK RUNNING MTU:3924 Metric:1 RX packets:139 errors:0 dropped:0 overruns:0 frame:0 TX packets:139 errors:0 dropped:0 overruns:0 carrier:0 collisions:0 txqueuelen:0 It is important to note that the settings configured with the ifconfig toll for your network devices will not survive a reboot. To assign the default gateway for 208.164.186.12 use the command: [root@deep] /#route add default gw 208.164.186.1 In this example, the default route is set up to go to 208.164.186.12, your router. Once again, if you want to keep your default gateway value, it's preferable to set in it the files related to networking functionality -/etc/ sysconfig/network. Verify that you can reach your hosts. Choose a host from your network, for instance 208.164.186.1. Use the command: [root@deep] /#ping 208.164.186.1 The output should look something like this: [root@deep networking]# ping 208.164.186.1 PING 208.164.186.1 (208.164.186.1) from 208.164.186.2 : 56 data bytes 64 bytes from 208.164.186.2: icmp_seq=0 ttl=128 time=1.0 ms 64 bytes from 208.164.186.2: icmp_seq=1 ttl=128 time=1.0 ms 64 bytes from 208.164.186.2: icmp_seq=2 ttl=128 time=1.0 ms 64 bytes from 208.164.186.2: icmp_seq=3 ttl=128 time=1.0 ms --- 208.164.186.1 ping statistics --- 4 packets transmitted, 4 packets received, 0% packet loss round-trip min/avg/max = 1.0/1.0/1.0 ms You should now display the routing information with the command route to see if both hosts have the correct routing entry. Use the command: [root@deep] /#route -n The output should look something like this: Kernel IP routing table Destination Gateway Genmask Flags Metric Ref Use Iface 208.164.186.2 0.0.0.0 255.255.255.255 UH 0 0 0 eth0 208.164.186.0 208.164.186.2 255.255.255.0 UG 0 0 0 eth0 208.164.186.0 0.0.0.0 255.255.255.0 U 0 0 0 eth0 127.0.0.0 0.0.0.0 255.0.0.0 U 0 0 0 lo To check the status of the interfaces quickly, use the netstat -i command, as follows: [root@deep] /#netstat -i The output should look something like this: Kernel Interface table Iface MTU Met RX-OK RX-ERR RX-DRP RX-OVR TX-OK TX-ERR TX-DRP TX-OVR Flg eth0 1500 0 4236 0 0 0 3700 0 0 0 BRU lo 3924 0 13300 0 0 0 13300 0 0 0 LRU ppp0 1500 0 14 1 0 0 16 0 0 0 PRU Another useful netstat option is -t, which shows all active TCP connections. Following is a typical result of netstat -t: [root@deep] /#netstat -t The output should look something like this: Active Internet connections (w/o servers) Proto Recv-Q Send-Q Local Address Foreign Address State Tcp 0 0 deep.openar:netbios-ssn gate.openna.com:1045 ESTABLISHED Tcp 0 0 localhost:1032 localhost:1033 ESTABLISHED Tcp 0 0 localhost:1033 localhost:1032 ESTABLISHED Tcp 0 0 localhost:1030 localhost:1034 ESTABLISHED Tcp 0 0 localhost:1031 localhost:1030 ESTABLISHED Tcp 0 0 localhost:1028 localhost:1029 ESTABLISHED Tcp 0 0 localhost:1029 localhost:1028 ESTABLISHED Tcp 0 0 localhost:1026 localhost:1027 ESTABLISHED Tcp 0 0 localhost:1027 localhost:1026 ESTABLISHED Tcp 0 0 localhost:1024 localhost:1025 ESTABLISHED Tcp 0 0 localhost:1025 localhost:1024 ESTABLISHED To shows all active and listen TCP connections, use the command: [root@deep] /#netstat -vat The output should look something like this: Active Internet connections (servers and established) Proto Recv-Q Send-Q Local Address Foreign Address State tcp 0 0 deep.openna.co:domain *: * LISTEN tcp 0 0 localhost:domain *: * LISTEN tcp 0 0 deep.openna.com:ssh gate.openna.com: 1682 ESTABLISHED tcp 0 0 *:webcache *: * LISTEN tcp 0 0 deep.openar:netbios-ssn *: * LISTEN tcp 0 0 localhost:netbios-ssn *: * LISTEN tcp 0 0 localhost:1032 localhost:1033 ESTABLISHED tcp 0 0 localhost:1033 localhost:1032 ESTABLISHED tcp 0 0 localhost:1030 localhost:1031 ESTABLISHED tcp 0 0 localhost:1031 localhost:1030 ESTABLISHED tcp 0 0 localhost:1028 localhost:1029 ESTABLISHED tcp 0 0 localhost:1029 localhost:1028 ESTABLISHED tcp 0 0 localhost:1026 localhost:1027 ESTABLISHED tcp 0 0 localhost:1027 localhost:1026 ESTABLISHED tcp 0 0 localhost:1024 localhost:1025 ESTABLISHED tcp 0 0 localhost:1025 localhost:1024 ESTABLISHED tcp 0 0 deep.openna.com:www *: * LISTEN tcp 0 0 deep.openna.com:https *: * LISTEN tcp 0 0 *:389 *: * LISTEN tcp 0 0 *:ssh *: * LISTEN To stop all network devices manually on your system, use the following command: [root@deep] /# /etc/rc.d/init.d/network stop Shutting down interface eth0 [ OK ] Disabling IPv4 packet forwarding [ OK ] To start all network devices manually on your system, use the following command: [root@deep] /# /etc/rc.d/init.d/network start Enabling IPv4 packet forwarding [ OK ] Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Chapter 10. Networking -Firewall Table of Contents 1._Policy,_Guidelines_etc. 2._The_topology 3._Build_a_kernel_with_IPCHAINS_Firewall_support 4._Rules_used_in_the_Firewall_script_files 5._Source_Address_Filtering Can someone tell me why I might want something like a commercial firewall product rather than simply using Ipchains and restricting certain packets? What am I losing by using Ipchains? Now, there is undoubtedly room for debate on this- Ipchains is as good, and most of the time better, than commercial firewall packages from a functionality and support standpoint. You will probably have more insight into what's going on in your network using Ipchains than a commercial solution. That said, a lot of corporate types want to tell their shareholders, CEO,CTO etc. that they have the backing of reputable security Software Company. The firewall could be doing nothing more than passing through all traffic, and still the corporate type would be more comfortable than having to rely on the geeky guy in the corner cube who gets grumpy if you turn the light on before noon. In the end, a lot of companies want to be able to turn around and demand some sort of restitution from a vendor if the network is breached, whether or not they'd actually get anything or even try. All they can typically do with an open source solution is fire the guy that implemented it. At least some of the commercial firewalls are based on Linux or something similar. It's quite probable that Ipchains is secure enough for you but not those engaging in serious amounts of high stakes bond trading. Doing a cost/benefit analysis and asking a lot of pertinent questions is recommended before spending serious money on a commercial firewall---otherwise you may end up with something inferior to your Ipchains tool. Quite a few of the NT firewalls are likely to be no better than Ipchains and the general consensus on bugtraq and NT bugtraq are that NT is far too insecure to run a serious firewall. 1. Policy, Guidelines etc. What is a Network Firewall Security Policy? Network firewall security policy defines those services that will be explicitly allowed or denied, how these services will be used and the exceptions to these rules. An organization's overall security policy must be determined according to security and business- need analysis. Since a firewall relates to network security alone, a firewall has little value unless the overall security policy is properly defined. Every rule in the network firewall security policy should be implemented on a firewall. Generally, a firewall uses one of the following methods. Everything not specifically permitted is denied. This approach blocks all traffic between two networks except for those services and applications that are permitted. Therefore, each desired service and application should be implemented one by one. No service or application that might be a potential hole on the firewall should be permitted. This is the most secure method, denying services and applications unless explicitly allowed by the administrator. On the other hand, from the point of users, it might be more restrictive and less convenient. This is the method we will use in our Firewall configuration files in this book. Everything not specifically denied is permitted This approach allows all traffic between two networks except for those services and applications that are denied. Therefore, each untrusted or potentially harmful service or application should be denied one by one. Although this is a flexible and convenient method for the users, it could potentially cause some serious security problems. What is Packet Filtering? Packet Filtering is the type of firewall built into the Linux kernel. A filtering firewall works at the network level. Data is only allowed to leave the system if the firewall rules allow it. As packets arrive they are filtered by their type, source address, destination address, and port information contained in each packet. Most of the time, packet filtering is accomplished by using a router that can forward packets according to filtering rules. When a packet arrives at the packet-filtering router, the router extracts certain information from the packet header and makes decisions according to the filter rules as to whether the packet will pass through or be discarded. The following information can be extracted from the packet header: Source IP address Destination IP address TCP/UDP source port TCP/UDP destination port ICMP message type Encapsulated protocol information (TCP, UDP, ICMP or IP tunnel) Because very little data is analyzed and logged, filtering firewalls take less CPU power and create less latency in your network. There are lots of ways to structure your network to protect your systems using a firewall. 2. The topology All servers should be configured to block at least the unused ports, even if there are not a firewall server. This is required for more security. Imagine someone gains access to your firewall gateway server: if your neighborhoods servers are not configured to block unused ports, this is a serious network risk. The same is true for local connections; unauthorized employees can gain access from the inside to your other servers in this manner. In our configuration we will give you three different examples that can help you to configure your firewall rules depending on the type of the server you want to protect and the placement of these servers on your network architecture. The first example firewall rules file will be for a Web Server. The second for a Mail Server. The last for a Gateway Server that acts as proxy for the inside Wins, Workstations and Servers machines. See the graph below to get an idea: Firewall schematic representaion The graph above shows you the ports that I enable on the different servers by default in my firewall scripts file in this book www.openna.com Caching Only DNS 208.164.186.3 .  i. Unlimited traffic on the loopback interface allowed ii. ICMP traffic allowed iii. DNS Caching and Client Server on port 53 allowed iv. SSH Server on port 22 allowed v. HTTP Server on port 80 allowed vi. HTTPS Server on port 443 allowed vii. SMTP Client on port 25 allowed viii. FTP Server on ports 20, 21 allowed ix. Outgoing traceroute request allowed deep.openna.com Master DNS Server 208.164.186.1 .  i. Unlimited traffic on the loopback interface allowed ii. ICMP traffic allowed iii. DNS Server and Client on port 53 allowed iv. SSH Server and Client on port 22 allowed v. HTTP Server and Client on port 80 allowed vi. HTTPS Server and Client on port 443 allowed vii. WWW-CACHE Client on port 8080 allowed viii. External POP Client on port 110 allowed ix. External NNTP NEWS Client on port 119 allowed x. SMTP Server and Client on port 25 allowed xi. IMAP Server on port 143 allowed xii. IRC Client on port 6667 allowed xiii. ICQ Client on port 4000 allowed xiv. FTP Client on port 20, 21 allowed xv. RealAudio / QuickTime Client allowed xvi. Outgoing traceroute request allowed mail.openna.com Slave DNS Server 208.164.186.2 .  i. Unlimited traffic on the loopback interface allowed ii. ICMP traffic allowed iii. DNS Server and Client on port 53 allowed iv. SSH Server on port 22 allowed v. SMTP Server and Client on port 25 allowed vi. IMAP Server on port 143 allowed vii. Outgoing traceroute request allowed The list above shows you the ports that I enable on the different servers by default in my firewall scripts file in this book. Depending on what services must be available in the server for the outside, you must configure your firewall script file to allow the traffic on the specified ports. * www.openna.com is our Web Server, * mail.openna.com is our Mail Hub Server for all the internal network, * deep.openna.com is our Gateway Server for all the examples explained later in this chapter. 3. Build a kernel with IPCHAINS Firewall support The first thing you need to do is ensure that your kernel has been built with Network Firewall support enabled and Firewalling. Remember, all servers should be configured to block unused ports, even if there are no firewall server. In the 2.2.14 kernel version you need to be sure that you have answered Y to the following questions: Networking options: Network firewalls (CONFIG_FIREFALL) [N] Y IP:Firewalling (CONFIG_IP_FIREWALL) [N] Y IP:TCP syncookie support (CONFIG_SYN_COOKIES) [N] Y If you have followed the Linux Kernel section and have recompiled your kernel, the options Network firewalls, IP:Firewalling, and IP:TCP syncookie support shown above are already set. 4. Rules used in the Firewall script files The following is an explanation of a few of the rules that will be used in the Firewalling examples below. This is shown just as a reference, the firewall scripts are well commented and very easy to modify. Constants are used, in the firewall scripts files for most values. The most basic constants are: EXTERNAL_INTERFACE This is the name of the external network interface to the Internet. It's defined as eth0 in the examples. LOCAL_INTERFACE_1 This is the name of the internal network interface to the LAN, if any. It's defined as eth1 in the examples. LOOPBACK_INTERFACE This is the name of the loopback interface. It's defined as lo in the examples. IPADDR This is the IP address of your external interface. It's either a static IP address registered with InterNIC, or else a dynamically assigned address from your ISP (usually via DHCP). LOCALNET_1 This is your LAN network address, if any - the entire range of IP addresses used by the machines on your LAN. These may be statically assigned, or you might run a local DHCP server to assign them. In these examples, the range is 192.168.1.0/24, part of the Class C private address range. ANYWHERE Anywhere is a label for an address used by ipchains to match any (non- broadcast) address. Both programs provide any/0 as a label for this address, which is 0.0.0.0/0. NAMESERVER_1 This is the IP address of your Primary DNS Server from your network or your ISP. NAMESERVER_2 This is the IP address of your Secondary DNS Server from your network or your ISP. MY_ISP This is your ISP & NOC address range. The value you specify here is used by the firewall to allow ICMP ping request and traceroute. If you don't specify an IP address range, then you will not be able to ping the Internet from your internal network. LOOPBACK The loopback address range is 127.0.0.0/8. The interface itself is addressed as 127.0.0.1 in /etc/hosts. PRIVPORTS The privileged ports, 0 through 1023, are usually referenced in total. UNPRIVPORTS The unprivileged ports, 1024 through 65535, are usually referenced in total. They are addresses dynamically assigned to the client side of a connection. Please Note a firewall has a default policy and a collection of actions to take in response to specific message types. This means that if a given packet has not been selected by any other rule, then the default policy rule will be applied. Tip People with dynamically assigned IPs from an ISP may include the following two lines in their declarations for the firewall. The lines will determine the ppp0 IP address, and the network of the remote ppp server. IPADDR=`/sbin/ifconfig | grep -A 4 ppp0 | awk '/inet/ { print $2 } ' | sed -e s/addr://` MY_ISP=`/sbin/ifconfig | grep -A 4 ppp0 | awk '/P-t-P/ { print $3 } ' | sed -e s/P-t-P:// | cut -d '.' -f 1-3`.0/24 You need to Enable Local Traffic since the default policies for all example firewall rule script files in this book are to deny everything, some of these rules must be unset. Local network services do not go through the external network interface. They go through a special, private interface called the loopback interface. None of your local network programs will work until loopback traffic is allowed. # Unlimited traffic on the loopback interface. ipchains -A input -i $LOOPBACK_INTERFACE -j ACCEPT ipchains -A output -i $LOOPBACK_INTERFACE -j ACCEPT 5. Source Address Filtering All IP packet headers contain the source and destination IP addresses and the type of IP protocol message; ICMP, UDP or TCP this packet contains. The only means of identification under the Internet Protocol - IP) is the source address in the IP packet header. This is a problem that opens the door to source address spoofing, where the sender may replaces its address with either a nonexistent address, or the address of some other site. # Refuse spoofed packets pretending to be from the external address. ipchains -A input -i $EXTERNAL_INTERFACE -s $IPADDR -l -j DENY Also, there are at least seven sets of source addresses you should refuse on your external interface in all cases. These are incoming packets claiming to be from: i. Your external IP address ii. Class A private IP addresses iii. Class B private IP addresses iv. Class C private IP addresses v. Class D multicast addresses vi. Class E reserved addresses vii. The loopback interface With the exception of your own IP address, blocking outgoing packets containing these source addresses protects you from possible configuration errors on your part. Important Don't forget to exclude your own IP address from outgoing packets blocked. By default I choose to exclude the Class C private IP addresses since it's the most used by the majority of people at this time. If you used another class instead of the Class C, then you must comment out the lines that refer to your class under the SPOOFING & BAD ADDRESSES section of the firewall. script file. The rest of the rules used in the firewall scripts files are: * Accessing a Service from the Outside World * Offering a Service to the Outside World * Masquerading the Internal Machines Chapter 11. The firewall scripts files Table of Contents 1._Config_/etc/rc.d/init.d/firewall_script_file_-Web_Server 2._Config_/etc/rc.d/init.d/firewall_script_file_-_Mail_Server The tool ipchains allows you to set up firewalls, IP masquerading, etc. Ipchains talks to the kernel and tells it what packets to filter. Therefore all your firewall setups are stored in the kernel, and thus will be lost on reboot. To avoid this, we recommend using the System V init scripts to make your rules permanent. To do this, create a firewall script file like shown over the next three sections in your /etc/rc.d/init.d/ directory for each servers you have. Of course, each server has different services to offer and needs a different firewall setup. For this reason, we provide you three different firewall settings, which you can play with, and examine to fit your needs. Also I assume that you have a minimum knowledge on how filtering firewalls and firewall rules works. 1.  Config /etc/rc.d/init.d/firewall script file -Web Server Errata Important As i was giving the final look over on this book, Gerhard Mourani has released an errata for all firewall scripts and it is available here http:// www.openna.com/books/errata.htm This is the configuration script file for our Web Server. This configuration allows unlimited traffic on the Loopback interface, ICMP, DNS Caching and Client Server (53), SSH Server (22), HTTP Server (80), HTTPS Server (443), SMTP Client (25), FTP Server (20, 21), and OUTGOING TRACEROUTE requests by default. If you don't want some services listed in the firewall rules files for the Web Server that I make ON by default, comment them out with a "#" at the beginning of the line. If you want some other services that I commented out with a "#", then remove the "#" at the beginning of those lines. Create the firewall script file, touch /etc/rc.d/init.d/firewall on your Web Server and add: #!/bin/sh # # ----------------------------------------------------------------- ----------- # Last modified by Gerhard Mourani: 04-25-2000 # ----------------------------------------------------------------- ----------- # Copyright (C) 1997, 1998, 1999 Robert L. Ziegler # # Permission to use, copy, modify, and distribute this software and its # documentation for educational, research, private and non-profit purposes, # without fee, and without a written agreement is hereby granted. # This software is provided as an example and basis for individual firewall # development. This software is provided without warranty. # # Any material furnished by Robert L. Ziegler is furnished on an # "as is" basis. He makes no warranties of any kind, either expressed # or implied as to any matter including, but not limited to, warranty # of fitness for a particular purpose, exclusivity or results obtained # from use of the material. # ----------------------------------------------------------------- ----------- # # Invoked from /etc/rc.d/init.d/firewall. # chkconfig: - 60 95 # description: Starts and stops the IPCHAINS Firewall \ # used to provide Firewall network services. # Source function library. . /etc/rc.d/init.d/functions # Source networking configuration. . /etc/sysconfig/network # Check that networking is up. if [ ${NETWORKING} = "no" ] then exit 0 fi if [ ! -x /sbin/ipchains ]; then exit 0 fi # See how we were called. case "$1" in start) echo -n "Starting Firewalling Services: " # Some definitions for easy maintenance. # ----------------------------------------------------------------- ----------- # EDIT THESE TO SUIT YOUR SYSTEM AND ISP. EXTERNAL_INTERFACE="eth0" # Internet connected interface LOOPBACK_INTERFACE="lo" # Your local naming convention IPADDR="my.ip.address" # Your IP address ANYWHERE="any/0" # Match any IP address NAMESERVER_1="my.name.server.1" # Everyone must have at least one NAMESERVER_2="my.name.server.2" # Your secondary name server MY_ISP="my.isp.address.range/24" # ISP & NOC address range SMTP_SERVER="my.smtp.server" # Your Mail Hub Server. SYSLOG_SERVER="syslog.internal.server" # Your syslog internal server SYSLOG_CLIENT="sys.int.client.range/24" # Your syslog internal client range LOOPBACK="127.0.0.0/8" # Reserved loopback address range CLASS_A="10.0.0.0/8" # Class A private networks CLASS_B="172.16.0.0/12" # Class B private networks CLASS_C="192.168.0.0/16" # Class C private networks CLASS_D_MULTICAST="224.0.0.0/4" # Class D multicast addresses CLASS_E_RESERVED_NET="240.0.0.0/5" # Class E reserved addresses BROADCAST_SRC="0.0.0.0" # Broadcast source address BROADCAST_DEST="255.255.255.255" # Broadcast destination address PRIVPORTS="0:1023" # Well known, privileged port range UNPRIVPORTS="1024:65535" # Unprivileged port range # ----------------------------------------------------------------- ----------- # SSH starts at 1023 and works down to 513 for # each additional simultaneous incoming connection. SSH_PORTS="1022:1023" # range for SSH privileged ports # traceroute usually uses -S 32769:65535 -D 33434:33523 TRACEROUTE_SRC_PORTS="32769:65535" TRACEROUTE_DEST_PORTS="33434:33523" # ----------------------------------------------------------------- ----------- # Default policy is DENY # Explicitly accept desired INCOMING & OUTGOING connections # Remove all existing rules belonging to this filter ipchains -F # Clearing all current rules and user defined chains ipchains -X # Set the default policy of the filter to deny. # Don't even bother sending an error message back. ipchains -P input DENY ipchains -P output DENY ipchains -P forward DENY # ----------------------------------------------------------------- ----------- # LOOPBACK # Unlimited traffic on the loopback interface. ipchains -A input -i $LOOPBACK_INTERFACE -j ACCEPT ipchains -A output -i $LOOPBACK_INTERFACE -j ACCEPT # ----------------------------------------------------------------- ----------- # Network Ghouls # Deny access to jerks # /etc/rc.d/rc.firewall.blocked contains a list of # ipchains -A input -i $EXTERNAL_INTERFACE -s address -j DENY # rules to block from any access. # Refuse any connection from problem sites #if [ -f /etc/rc.d/rc.firewall.blocked ]; then # . /etc/rc.d/rc.firewall.blocked #fi # ----------------------------------------------------------------- ----------- # SPOOFING & BAD ADDRESSES # Refuse spoofed packets. # Ignore blatantly illegal source addresses. # Protect yourself from sending to bad addresses. # Refuse spoofed packets pretending to be from the external address. ipchains -A input -i $EXTERNAL_INTERFACE -s $IPADDR -j DENY -l # Refuse packets claiming to be to or from a Class A private network ipchains -A input -i $EXTERNAL_INTERFACE -s $CLASS_A -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -d $CLASS_A -j DENY -l ipchains -A output -i $EXTERNAL_INTERFACE -s $CLASS_A -j REJECT -l ipchains -A output -i $EXTERNAL_INTERFACE -d $CLASS_A -j REJECT -l # Refuse packets claiming to be to or from a Class B private network ipchains -A input -i $EXTERNAL_INTERFACE -s $CLASS_B -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -d $CLASS_B -j DENY -l ipchains -A output -i $EXTERNAL_INTERFACE -s $CLASS_B -j REJECT -l ipchains -A output -i $EXTERNAL_INTERFACE -d $CLASS_B -j REJECT -l # Refuse packets claiming to be to or from a Class C private network # ipchains -A input -i $EXTERNAL_INTERFACE -s $CLASS_C -j DENY -l # ipchains -A input -i $EXTERNAL_INTERFACE -d $CLASS_C -j DENY -l # ipchains -A output -i $EXTERNAL_INTERFACE -s $CLASS_C - j REJECT -l # ipchains -A output -i $EXTERNAL_INTERFACE -d $CLASS_C - j REJECT -l # Refuse packets claiming to be from the loopback interface ipchains -A input -i $EXTERNAL_INTERFACE -s $LOOPBACK -j DENY -l ipchains -A output -i $EXTERNAL_INTERFACE -s $LOOPBACK -j REJECT -l # Refuse broadcast address SOURCE packets ipchains -A input -i $EXTERNAL_INTERFACE -s $BROADCAST_DEST - j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -d $BROADCAST_SRC -j DENY -l # Refuse Class D multicast addresses (in.h) (NET-3-HOWTO) # Multicast is illegal as a source address. # Multicast uses UDP. ipchains -A input -i $EXTERNAL_INTERFACE -s $CLASS_D_MULTICAST - j DENY -l # Refuse Class E reserved IP addresses ipchains -A input -i $EXTERNAL_INTERFACE -s $CLASS_E_RESERVED_NET -j DENY -l # refuse addresses defined as reserved by the IANA # 0.*.*.*, 1.*.*.*, 2.*.*.*, 5.*.*.*, 7.*.*.*, 23.*.*.*, 27.*.*.* # 31.*.*.*, 37.*.*.*, 39.*.*.*, 41.*.*.*, 42.*.*.*, 58-60.*.*.* # 65-95.*.*.*, 96-126.*.*.*, 197.*.*.*, 201.*.*.* (?), 217- 223.*.*.* ipchains -A input -i $EXTERNAL_INTERFACE -s 1.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 2.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 5.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 7.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 23.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 27.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 31.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 37.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 39.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 41.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 42.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 58.0.0.0/7 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 60.0.0.0/8 -j DENY -l #65: 01000001 - /3 includes 64 - need 65-79 spelled out ipchains -A input -i $EXTERNAL_INTERFACE -s 65.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 66.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 67.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 68.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 69.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 70.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 71.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 72.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 73.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 74.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 75.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 76.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 77.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 78.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 79.0.0.0/8 -j DENY -l #80: 01010000 - /4 masks 80-95 ipchains -A input -i $EXTERNAL_INTERFACE -s 80.0.0.0/4 -j DENY -l # 96: 01100000 - /4 makses 96-111 ipchains -A input -i $EXTERNAL_INTERFACE -s 96.0.0.0/4 -j DENY -l #126: 01111110 - /3 includes 127 - need 112-126 spelled out ipchains -A input -i $EXTERNAL_INTERFACE -s 112.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 113.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 114.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 115.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 116.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 117.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 118.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 119.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 120.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 121.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 122.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 123.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 124.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 125.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 126.0.0.0/8 -j DENY -l #217: 11011001 - /5 includes 216 - need 217-219 spelled out ipchains -A input -i $EXTERNAL_INTERFACE -s 217.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 218.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 219.0.0.0/8 -j DENY -l #223: 11011111 - /6 masks 220-223 ipchains -A input -i $EXTERNAL_INTERFACE -s 220.0.0.0/6 -j DENY -l # ----------------------------------------------------------------- ----------- # ICMP # To prevent denial of service attacks based on ICMP bombs, filter # incoming Redirect (5) and outgoing Destination Unreachable (3). # Note, however, disabling Destination Unreachable (3) is not # advisable, as it is used to negotiate packet fragment size. # For bi-directional ping. # Message Types: Echo_Reply (0), Echo_Request (8) # To prevent attacks, limit the src addresses to your ISP range. # # For outgoing traceroute. # Message Types: INCOMING Dest_Unreachable (3), Time_Exceeded (11) # default UDP base: 33434 to base+nhops-1 # # For incoming traceroute. # Message Types: OUTGOING Dest_Unreachable (3), Time_Exceeded (11) # To block this, deny OUTGOING 3 and 11 # 0: echo-reply (pong) # 3: destination-unreachable, port-unreachable, fragmentation- needed, etc. # 4: source-quench # 5: redirect # 8: echo-request (ping) # 11: time-exceeded # 12: parameter-problem ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 0 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 3 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 4 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 11 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 12 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $MY_ISP 8 -d $IPADDR -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 0 -d $MY_ISP -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 3 -d $MY_ISP -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 4 -d $ANYWHERE -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 8 -d $ANYWHERE -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 12 -d $ANYWHERE -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 11 -d $MY_ISP -j ACCEPT # ----------------------------------------------------------------- ----------- # UDP INCOMING TRACEROUTE # traceroute usually uses -S 32769:65535 -D 33434:33523 ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $MY_ISP $TRACEROUTE_SRC_PORTS \ -d $IPADDR $TRACEROUTE_DEST_PORTS -j ACCEPT -l ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $ANYWHERE $TRACEROUTE_SRC_PORTS \ -d $IPADDR $TRACEROUTE_DEST_PORTS -j DENY -l # ----------------------------------------------------------------- ----------- # DNS forwarding, caching only nameserver (53) # -------------------------------------------- # server to server query or response # Caching only name server only requires UDP, not TCP ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $NAMESERVER_1 53 \ -d $IPADDR 53 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -s $IPADDR 53 \ -d $NAMESERVER_1 53 -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $NAMESERVER_2 53 \ -d $IPADDR 53 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -s $IPADDR 53 \ -d $NAMESERVER_2 53 -j ACCEPT # DNS client (53) # --------------- ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $NAMESERVER_1 53 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -s $IPADDR $UNPRIVPORTS \ -d $NAMESERVER_1 53 -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $NAMESERVER_2 53 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -s $IPADDR $UNPRIVPORTS \ -d $NAMESERVER_2 53 -j ACCEPT # TCP client to server requests are allowed by the protocol # if UDP requests fail. This is rarely seen. Usually, clients # use TCP as a secondary nameserver for zone transfers from # their primary nameservers, and as hackers. ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $NAMESERVER_1 53 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $NAMESERVER_1 53 -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $NAMESERVER_2 53 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $NAMESERVER_2 53 -j ACCEPT # ----------------------------------------------------------------- ----------- # TCP accept only on selected ports # --------------------------------- # ----------------------------------------------------------------- - # SSH server (22) # --------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE $UNPRIVPORTS \ -d $IPADDR 22 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $IPADDR 22 \ -d $ANYWHERE $UNPRIVPORTS -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE $SSH_PORTS \ -d $IPADDR 22 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $IPADDR 22 \ -d $ANYWHERE $SSH_PORTS -j ACCEPT # ----------------------------------------------------------------- - # HTTP server (80) # ---------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE $UNPRIVPORTS \ -d $IPADDR 80 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $IPADDR 80 \ -d $ANYWHERE $UNPRIVPORTS -j ACCEPT # ----------------------------------------------------------------- - # HTTPS server (443) # ------------------ ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE $UNPRIVPORTS \ -d $IPADDR 443 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $IPADDR 443 \ -d $ANYWHERE $UNPRIVPORTS -j ACCEPT # ----------------------------------------------------------------- - # SYSLOG server (514) # ----------------- # Provides full remote logging. Using this feature you're able to # control all syslog messages on one host. # ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ # -s $SYSLOG_CLIENT \ # -d $IPADDR 514 -j ACCEPT # SYSLOG client (514) # ----------------- # ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ # -s $IPADDR 514 \ # -d $SYSLOG_SERVER 514 -j ACCEPT # ----------------------------------------------------------------- - # AUTH server (113) # ----------------- # Reject, rather than deny, the incoming auth port. (NET-3-HOWTO) ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE \ -d $IPADDR 113 -j REJECT # ----------------------------------------------------------------- - # SMTP client (25) # ---------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $SMTP_SERVER 25 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $SMTP_SERVER 25 -j ACCEPT # ----------------------------------------------------------------- - # FTP server (20, 21) # ------------------- # incoming request ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE $UNPRIVPORTS \ -d $IPADDR 21 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $IPADDR 21 \ -d $ANYWHERE $UNPRIVPORTS -j ACCEPT # PORT MODE data channel responses # ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $ANYWHERE $UNPRIVPORTS \ -d $IPADDR 20 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR 20 \ -d $ANYWHERE $UNPRIVPORTS -j ACCEPT # PASSIVE MODE data channel responses ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE $UNPRIVPORTS \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE $UNPRIVPORTS -j ACCEPT # ----------------------------------------------------------------- - # OUTGOING TRACEROUTE # ------------------- ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -s $IPADDR $TRACEROUTE_SRC_PORTS \ -d $ANYWHERE $TRACEROUTE_DEST_PORTS -j ACCEPT # ----------------------------------------------------------------- ----------- # Enable logging for selected denied packets ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -d $IPADDR -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -d $IPADDR $PRIVPORTS -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -d $IPADDR $UNPRIVPORTS -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 5 -d $IPADDR -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 13:255 -d $IPADDR -j DENY -l # ----------------------------------------------------------------- ----------- ;; stop) echo -n "Shutting Firewalling Services: " # Remove all existing rules belonging to this filter ipchains -F # Delete all user-defined chain to this filter ipchains -X # Reset the default policy of the filter to accept. ipchains -P input ACCEPT ipchains -P output ACCEPT ipchains -P forward ACCEPT ;; status) status firewall ;; restart|reload) $0 stop $0 start ;; *) echo "Usage: firewall {start|stop|status|restart|reload}" exit 1 esac exit 0 Now, make this script executable and change its default permissions: [root@deep] /# chmod 700 /etc/rc.d/init.d/firewall [root@deep] /# chown 0.0 /etc/rc.d/init.d/firewall Create the symbolic rc.d links for your Firewall with the following command: [root@deep] /# chkconfig --add firewall [root@deep] /# chkconfig --level 345 firewall on Now, your firewall rules are configured to use System V init (System V init is in charge of starting all the normal processes that need to run at boot time) and it will be automatically started each time your server reboots. To manually stop the firewall on your system, use the following command: [root@deep] /# /etc/rc.d/init.d/firewall stop Shutting Firewalling Services: [ OK ] To manually start the firewall on your system, use the following command: [root@deep] /# /etc/rc.d/init.d/firewall start Starting Firewalling Services: [ OK ] 2. Config /etc/rc.d/init.d/firewall script file - Mail Server This is the configuration script file for our Mail Server. This is configured to allows unlimited traffic on the Loopback interface, ICMP, DNS Server and Client (53), SSH Server (22), SMTP Server and Client (25), IMAP server (143), and OUTGOING TRACEROUTE requests by default. If you don't want some services listed in the firewall rules files for the Mail Server that I make ON by default, comment them out with a "#" at the beginning of the line. If you want some other services that I commented out with a "#", then remove the "#" at the beginning of their lines. Create the firewall script file, touch /etc/rc.d/ init.d/firewall on your Mail Server and add: #!/bin/sh # # --------------------------------------------------------------- ------------- # Last modified by Gerhard Mourani: 04-25-2000 # --------------------------------------------------------------- ------------- # Copyright (C) 1997, 1998, 1999 Robert L. Ziegler # # Permission to use, copy, modify, and distribute this software and its # documentation for educational, research, private and non-profit purposes, # without fee, and without a written agreement is hereby granted. # This software is provided as an example and basis for individual firewall # development. This software is provided without warranty. # # Any material furnished by Robert L. Ziegler is furnished on an # "as is" basis. He makes no warranties of any kind, either expressed # or implied as to any matter including, but not limited to, warranty # of fitness for a particular purpose, exclusivity or results obtained # from use of the material. # --------------------------------------------------------------- ------------- # # Invoked from /etc/rc.d/init.d/firewall. # chkconfig: - 60 95 # description: Starts and stops the IPCHAINS Firewall \ # used to provide Firewall network services. # Source function library. . /etc/rc.d/init.d/functions # Source networking configuration. . /etc/sysconfig/network # Check that networking is up. if [ ${NETWORKING} = "no" ] then exit 0 fi if [ ! -x /sbin/ipchains ]; then exit 0 fi # See how we were called. case "$1" in start) echo -n "Starting Firewalling Services: " # Some definitions for easy maintenance. # --------------------------------------------------------------- ------------- # EDIT THESE TO SUIT YOUR SYSTEM AND ISP. EXTERNAL_INTERFACE="eth0" # Internet connected interface LOOPBACK_INTERFACE="lo" # Your local naming convention IPADDR="my.ip.address" # Your IP address ANYWHERE="any/0" # Match any IP address NAMESERVER_1="my.name.server.1" # Everyone must have at least one NAMESERVER_2="my.name.server.2" # Your secondary name server MY_ISP="my.isp.address.range/24" # ISP & NOC address range SMTP_SERVER="my.smtp.server" # Your Mail Hub Server. SYSLOG_SERVER="syslog.internal.server" # Your syslog internal server SYSLOG_CLIENT="sys.int.client.range/24" # Your syslog internal client range LOOPBACK="127.0.0.0/8" # Reserved loopback address range CLASS_A="10.0.0.0/8" # Class A private networks CLASS_B="172.16.0.0/12" # Class B private networks CLASS_C="192.168.0.0/16" # Class C private networks CLASS_D_MULTICAST="224.0.0.0/4" # Class D multicast addresses CLASS_E_RESERVED_NET="240.0.0.0/5" # Class E reserved addresses BROADCAST_SRC="0.0.0.0" # Broadcast source address BROADCAST_DEST="255.255.255.255" # Broadcast destination address PRIVPORTS="0:1023" # Well known, privileged port range UNPRIVPORTS="1024:65535" # Unprivileged port range # --------------------------------------------------------------- ------------- # SSH starts at 1023 and works down to 513 for # each additional simultaneous incoming connection. SSH_PORTS="1022:1023" # range for SSH privileged ports # traceroute usually uses -S 32769:65535 -D 33434:33523 TRACEROUTE_SRC_PORTS="32769:65535" TRACEROUTE_DEST_PORTS="33434:33523" # --------------------------------------------------------------- ------------- # Default policy is DENY # Explicitly accept desired INCOMING & OUTGOING connections # Remove all existing rules belonging to this filter ipchains -F # Clearing all current rules and user defined chains ipchains -X # Set the default policy of the filter to deny. # Don't even bother sending an error message back. ipchains -P input DENY ipchains -P output DENY ipchains -P forward DENY # --------------------------------------------------------------- ------------- # LOOPBACK # Unlimited traffic on the loopback interface. ipchains -A input -i $LOOPBACK_INTERFACE -j ACCEPT ipchains -A output -i $LOOPBACK_INTERFACE -j ACCEPT # --------------------------------------------------------------- ------------- # Network Ghouls # Deny access to jerks # /etc/rc.d/rc.firewall.blocked contains a list of # ipchains -A input -i $EXTERNAL_INTERFACE -s address -j DENY # rules to block from any access. # Refuse any connection from problem sites #if [ -f /etc/rc.d/rc.firewall.blocked ]; then # . /etc/rc.d/rc.firewall.blocked #fi # --------------------------------------------------------------- ------------- # SPOOFING & BAD ADDRESSES # Refuse spoofed packets. # Ignore blatantly illegal source addresses. # Protect yourself from sending to bad addresses. # Refuse spoofed packets pretending to be from the external address. ipchains -A input -i $EXTERNAL_INTERFACE -s $IPADDR -j DENY -l # Refuse packets claiming to be to or from a Class A private network ipchains -A input -i $EXTERNAL_INTERFACE -s $CLASS_A -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -d $CLASS_A -j DENY -l ipchains -A output -i $EXTERNAL_INTERFACE -s $CLASS_A -j REJECT - l ipchains -A output -i $EXTERNAL_INTERFACE -d $CLASS_A -j REJECT - l # Refuse packets claiming to be to or from a Class B private network ipchains -A input -i $EXTERNAL_INTERFACE -s $CLASS_B -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -d $CLASS_B -j DENY -l ipchains -A output -i $EXTERNAL_INTERFACE -s $CLASS_B -j REJECT - l ipchains -A output -i $EXTERNAL_INTERFACE -d $CLASS_B -j REJECT - l # Refuse packets claiming to be to or from a Class C private network # ipchains -A input -i $EXTERNAL_INTERFACE -s $CLASS_C - j DENY -l # ipchains -A input -i $EXTERNAL_INTERFACE -d $CLASS_C - j DENY -l # ipchains -A output -i $EXTERNAL_INTERFACE -s $CLASS_C - j REJECT -l # ipchains -A output -i $EXTERNAL_INTERFACE -d $CLASS_C - j REJECT -l # Refuse packets claiming to be from the loopback interface ipchains -A input -i $EXTERNAL_INTERFACE -s $LOOPBACK -j DENY -l ipchains -A output -i $EXTERNAL_INTERFACE -s $LOOPBACK -j REJECT -l # Refuse broadcast address SOURCE packets ipchains -A input -i $EXTERNAL_INTERFACE -s $BROADCAST_DEST - j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -d $BROADCAST_SRC - j DENY -l # Refuse Class D multicast addresses (in.h) (NET-3-HOWTO) # Multicast is illegal as a source address. # Multicast uses UDP. ipchains -A input -i $EXTERNAL_INTERFACE -s $CLASS_D_MULTICAST - j DENY -l # Refuse Class E reserved IP addresses ipchains -A input -i $EXTERNAL_INTERFACE - s $CLASS_E_RESERVED_NET -j DENY -l # refuse addresses defined as reserved by the IANA # 0.*.*.*, 1.*.*.*, 2.*.*.*, 5.*.*.*, 7.*.*.*, 23.*.*.*, 27.*.*.* # 31.*.*.*, 37.*.*.*, 39.*.*.*, 41.*.*.*, 42.*.*.*, 58-60.*.*.* # 65-95.*.*.*, 96-126.*.*.*, 197.*.*.*, 201.*.*.* (?), 217- 223.*.*.* ipchains -A input -i $EXTERNAL_INTERFACE -s 1.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 2.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 5.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 7.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 23.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 27.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 31.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 37.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 39.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 41.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 42.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 58.0.0.0/7 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 60.0.0.0/8 -j DENY - l #65: 01000001 - /3 includes 64 - need 65-79 spelled out ipchains -A input -i $EXTERNAL_INTERFACE -s 65.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 66.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 67.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 68.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 69.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 70.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 71.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 72.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 73.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 74.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 75.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 76.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 77.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 78.0.0.0/8 -j DENY - l ipchains -A input -i $EXTERNAL_INTERFACE -s 79.0.0.0/8 -j DENY - l #80: 01010000 - /4 masks 80-95 ipchains -A input -i $EXTERNAL_INTERFACE -s 80.0.0.0/4 -j DENY - l # 96: 01100000 - /4 makses 96-111 ipchains -A input -i $EXTERNAL_INTERFACE -s 96.0.0.0/4 -j DENY - l #126: 01111110 - /3 includes 127 - need 112-126 spelled out ipchains -A input -i $EXTERNAL_INTERFACE -s 112.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 113.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 114.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 115.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 116.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 117.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 118.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 119.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 120.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 121.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 122.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 123.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 124.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 125.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 126.0.0.0/8 -j DENY -l #217: 11011001 - /5 includes 216 - need 217-219 spelled out ipchains -A input -i $EXTERNAL_INTERFACE -s 217.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 218.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 219.0.0.0/8 -j DENY -l #223: 11011111 - /6 masks 220-223 ipchains -A input -i $EXTERNAL_INTERFACE -s 220.0.0.0/6 -j DENY -l # --------------------------------------------------------------- ------------- # ICMP # To prevent denial of service attacks based on ICMP bombs, filter # incoming Redirect (5) and outgoing Destination Unreachable (3). # Note, however, disabling Destination Unreachable (3) is not # advisable, as it is used to negotiate packet fragment size. # For bi-directional ping. # Message Types: Echo_Reply (0), Echo_Request (8) # To prevent attacks, limit the src addresses to your ISP range. # # For outgoing traceroute. # Message Types: INCOMING Dest_Unreachable (3), Time_Exceeded (11) # default UDP base: 33434 to base+nhops-1 # # For incoming traceroute. # Message Types: OUTGOING Dest_Unreachable (3), Time_Exceeded (11) # To block this, deny OUTGOING 3 and 11 # 0: echo-reply (pong) # 3: destination-unreachable, port-unreachable, fragmentation- needed, etc. # 4: source-quench # 5: redirect # 8: echo-request (ping) # 11: time-exceeded # 12: parameter-problem ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 0 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 3 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 4 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 11 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 12 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $MY_ISP 8 -d $IPADDR -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 0 -d $MY_ISP -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 3 -d $MY_ISP -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 4 -d $ANYWHERE -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 8 -d $ANYWHERE -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 12 -d $ANYWHERE -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 11 -d $MY_ISP -j ACCEPT # --------------------------------------------------------------- ------------- # UDP INCOMING TRACEROUTE # traceroute usually uses -S 32769:65535 -D 33434:33523 ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $MY_ISP $TRACEROUTE_SRC_PORTS \ -d $IPADDR $TRACEROUTE_DEST_PORTS -j ACCEPT -l ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $ANYWHERE $TRACEROUTE_SRC_PORTS \ -d $IPADDR $TRACEROUTE_DEST_PORTS -j DENY -l # --------------------------------------------------------------- ------------- # DNS server # ---------- # DNS: full server # server/client to server query or response ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $ANYWHERE $UNPRIVPORTS \ -d $IPADDR 53 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -s $IPADDR 53 \ -d $ANYWHERE $UNPRIVPORTS -j ACCEPT # DNS client & Zone Transfers (53) # --------------- ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $NAMESERVER_1 53 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -s $IPADDR $UNPRIVPORTS \ -d $NAMESERVER_1 53 -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $NAMESERVER_1 53 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $NAMESERVER_1 53 -j ACCEPT # --------------------------------------------------------------- ------------- # TCP accept only on selected ports # --------------------------------- # --------------------------------------------------------------- --- # SSH server (22) # --------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE $UNPRIVPORTS \ -d $IPADDR 22 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $IPADDR 22 \ -d $ANYWHERE $UNPRIVPORTS -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE $SSH_PORTS \ -d $IPADDR 22 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $IPADDR 22 \ -d $ANYWHERE $SSH_PORTS -j ACCEPT # --------------------------------------------------------------- --- # AUTH server (113) # ----------------- # Reject, rather than deny, the incoming auth port. (NET-3-HOWTO) ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE \ -d $IPADDR 113 -j REJECT # --------------------------------------------------------------- --- # SYSLOG server (514) # ----------------- # Provides full remote logging. Using this feature you're able to # control all syslog messages on one host. # ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ # -s $SYSLOG_CLIENT \ # -d $IPADDR 514 -j ACCEPT # SYSLOG client (514) # ----------------- # ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ # -s $IPADDR 514 \ # -d $SYSLOG_SERVER 514 -j ACCEPT # --------------------------------------------------------------- --- # SMTP server (25) # ---------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE $UNPRIVPORTS \ -d $IPADDR 25 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $IPADDR 25 \ -d $ANYWHERE $UNPRIVPORTS -j ACCEPT # SMTP client (25) # ---------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $ANYWHERE 25 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE 25 -j ACCEPT # --------------------------------------------------------------- --- # IMAP server (143) # ----------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE $UNPRIVPORTS \ -d $IPADDR 143 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $IPADDR 143 \ -d $ANYWHERE $UNPRIVPORTS -j ACCEPT # POP server (110) # ----------------- # ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ # -s $ANYWHERE $UNPRIVPORTS \ # -d $IPADDR 110 -j ACCEPT # ipchains -A output -i $EXTERNAL_INTERFACE -p tcp ! -y \ # -s $IPADDR 110 \ # -d $ANYWHERE $UNPRIVPORTS -j ACCEPT # --------------------------------------------------------------- --- # OUTGOING TRACEROUTE # ------------------- ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -s $IPADDR $TRACEROUTE_SRC_PORTS \ -d $ANYWHERE $TRACEROUTE_DEST_PORTS -j ACCEPT # --------------------------------------------------------------- ------------- # Enable logging for selected denied packets ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -d $IPADDR -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -d $IPADDR $PRIVPORTS -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -d $IPADDR $UNPRIVPORTS -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 5 -d $IPADDR -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 13:255 -d $IPADDR -j DENY -l # --------------------------------------------------------------- ------------- ;; stop) echo -n "Shutting Firewalling Services: " # Remove all existing rules belonging to this filter ipchains -F # Delete all user-defined chain to this filter ipchains -X # Reset the default policy of the filter to accept. ipchains -P input ACCEPT ipchains -P output ACCEPT ipchains -P forward ACCEPT ;; status) status firewall ;; restart|reload) $0 stop $0 start ;; *) echo "Usage: firewall {start|stop|status|restart|reload}" exit 1 esac exit 0 Now, make this script executable and change its default permissions: [root@deep] /#chmod 700 /etc/rc.d/init.d/firewall [root@deep] /#chown 0.0 /etc/rc.d/init.d/firewall Create the symbolic rc.d links for your Firewall with the command: [root@deep] /#chkconfig --add firewall [root@deep] /#chkconfig --level 345 firewall on Now, your firewall rules are configured to use System V init (System V init is in charge of starting all the normal processes that need to run at boot time) and it will be automatically started each time if your server reboot. To manually stop the firewall on your system, use the following command: [root@deep] /# /etc/rc.d/init.d/firewall stop Shutting Firewalling Services: [ OK ] To manually start the firewall on your system, use the following command: [root@deep] /# /etc/rc.d/init.d/firewall start Starting Firewalling Services: [ OK ] Chapter 12. Networking Firewall -Masquerading and Forwarding Table of Contents 1._Build_a_kernel_with_Firewall_Masquerading_and_Forwarding_support 2._Config_/etc/rc.d/init.d/firewall_script_file_-Gateway_Server 3._Configure_script_for_Example_Gateway_Server 4._Deny_access_to_some_address 5._IPCHAINS_Administrative_Tools Unlike the example configurations in The_firewall_scripts_files, configuring a Linux Server to masquerade and forward traffic generally from the inside private network that has unregistered IP addresses i.e. 192.168.1.0/24 to the outside network i.e. the Internet require a special setup of your kernel and of your firewall configuration scripts file. This kind of setting is also known as a Gateway Server, a machine that serves as a gateway for internal traffic to external traffic. This configuration must only be set if you have the intentions and the needs for this kind of service and it's for this reason that the configuration of the script file for the Gateway Server is in its own chapter. 1. Build a kernel with Firewall Masquerading and Forwarding support Once again, the first thing you need to do is ensuring that your kernel has been built with Network Firewall support enabled and Firewalling. In the 2.2.14 kernel version you need to ensure that you have answered Y to the following questions: Networking options: Network firewalls (CONFIG_FIREFALL) [N] Y IP:Firewalling (CONFIG_IP_FIREWALL) [N] Y IP:TCP syncookie support (CONFIG_SYN_COOKIES) [N] Y Note If you followed the Linux Kernel section and have recompiled your kernel, the options Network firewalls, IP:Firewalling, and IP:TCP syncookies supports shown above are already set. IP Masquerading and IP ICMP Masquerading are requiring only for a Gateway Server. IP:Masquerading (CONFIG_IP_MASQUERADE) [N] Y IP:ICMP Masquerading (CONFIG_IP_MASQUERADE_ICMP) [N] Y Important Only your Gateway Server needs to have IP:Masquerading and IP:ICMP Masquerading kernel options enabled. This is required to masquerade your Internal Network to the outside. Masquerade means that if one of the computers on your local network for which your Linux box (or gateway) acts as a firewall wants to send something to the outside, your box can masquerade as that computer. In other words it forwards the traffic to the intended outside destination, but makes it look like it came from the firewall box itself. It works both ways: if the outside host replies, the Linux firewall will silently forward the traffic to the corresponding local computer. This way, the computers on your local net are completely invisible to the outside world, even though they can reach the outside and can receive replies. This makes it possible to have the computers on the local network participate on the Internet even if they don't have officially registered IP addresses. The IP masquerading code will only work if IP forwarding is enabled on your system. This feature is by default disabled and you can enable it with the following command: Under Version 6.1 only To enable IP forwarding feature on your server, execute the following command: [root@deep] /#echo 1 > /proc/sys/net/ipv4/ip_forward You can add the above line in your /etc/rc.d/rc.local script file so IP forwarding is enabled automatically for you even if your server is rebooted. In Red Hat Linux 6.1 this can also be accomplished by changing the line in /etc/ sysconfig/network file from: FORWARD_IPV4="false" To read: FORWARD_IPV4="yes" You must restart your network for the change to take effect: [root@deep] /# /etc/rc.d/init.d/network restart Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Bringing up interface eth1 [ OK ] So you can either add the echo 1 > /proc/sys/net/ipv4/ip_forward command line to your rc.local script file or you change the value of the line FORWARD_IPV4=false to yes in the network file to set this feature to ON. Personally I prefer the second choice. Under Version 6.2 only To enable IPv4 forwarding on your RH 6.2 system, Edit the /etc/sysctl.conf file and add the following line: # Enable packet forwarding net.ipv4.ip_forward = 1 You must restart your network for the change to take effect. The command to restart the network is the following: To restart all network devices manually on your system, use the following command: [root@deep] /# /etc/rc.d/init.d/network restart Setting network parameters [ OK ] Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Bringing up interface eth1 [ OK ] Important The IP forwarding line above is only required if you answered Yes to the kernel option IP:Masquerading (CONFIG_IP_MASQUERADE) and choose to have a server act as a Gateway and masquerade for your inside network. If you enabled IP Masquerading, then the modules ip_masq_ftp.o for ftp file transfers, ip_masq_irc.o for irc chats, ip_masq_quake.o you guessed it!, ip_masq_vdolive.o for VDOLive video connections, ip_masq_cuseeme.o for CU-SeeMe broadcasts and ip_masq_raudio.o for RealAudio downloads will automatically be compiled. They are needed to make masquerading for these protocols work. Also, don't forget that you'll need to build a modularized kernel and answer Yes to the Enable loadable module support (CONFIG_MODULES) option instead of a monolithic kernel to be able to use masquerading functions and modules like ip_masq_ftp.o on your Gateway server see the Linux_Kernel_section above in this book for more information. The basic masquerade code described for IP: masquerading above only handles TCP or UDP packets and ICMP errors for existing connections. The IP:ICMP Masquerading option adds additional support for masquerading ICMP packets, such as ping or the probes used by the Windows 95™ tracer program. Remember that other servers like the Web_Server and Mail_Server examples don't need to have these options enabled since they either have a real IP address assigned or don't act as a Gateway for the inside network. 2. Config /etc/rc.d/init.d/firewall script file -Gateway Server Some Points to Consider You can safely assume that you are potentially at risk if you connect your system to the Internet. Your gateway to the Internet is your greatest exposure, so we recommend the following: * The gateway should not run any more applications than are absolutely necessary. * The gateway should strictly limit the type and number of protocols allowed to flow through it (protocols potentially provide security holes, such as FTP and telnet). * Any system containing confidential or sensitive information should not be directly accessible from the Internet. 3. Configure script for Example Gateway Server This is the configuration script file for our Gateway Server. This configuration allows unlimited traffic on the Loopback interface, ICMP, DNS Server and Client (53), SSH Server and Client (22), HTTP Server and Client (80), HTTPS Server and Client (443), POP Client (110), NNTP NEWS Client (119), SMTP Server and Client (25), IMAP Server (143), IRC Client (6667), ICQ Client (4000), FTP Client (20, 21), RealAudio / QuickTime Client, and OUTGOING TRACEROUTE requests by default. If you don't want some services listed in the firewall rules files for the Gateway Server that I make ON by default, comment them out with a "#" at the beginning of the line. If you want some other services that I commented out with a "#", then remove the "#" at the beginning of their lines. If you have configured Masquerading on your server, don't forget to uncomment the modules necessary to masquerade their respective services that you need like ip_masq_irc.o, ip_masq_raudio.o, etc under the MODULES MASQUERADING section of the firewall script file. Create the firewall script file touch /etc/rc.d/init.d/firewall, on your Gateway Server and add: #!/bin/sh # # ------------------------------------------------------------------ ---------- # Last modified by Gerhard Mourani: 04-25-2000 # ------------------------------------------------------------------ ---------- # Copyright (C) 1997, 1998, 1999 Robert L. Ziegler # # Permission to use, copy, modify, and distribute this software and its # documentation for educational, research, private and non-profit purposes, # without fee, and without a written agreement is hereby granted. # This software is provided as an example and basis for individual firewall # development. This software is provided without warranty. # # Any material furnished by Robert L. Ziegler is furnished on an # "as is" basis. He makes no warranties of any kind, either expressed # or implied as to any matter including, but not limited to, warranty # of fitness for a particular purpose, exclusivity or results obtained # from use of the material. # ------------------------------------------------------------------ ---------- # # Invoked from /etc/rc.d/init.d/firewall. # chkconfig: - 60 95 # description: Starts and stops the IPCHAINS Firewall \ # used to provide Firewall network services. # Source function library. . /etc/rc.d/init.d/functions # Source networking configuration. . /etc/sysconfig/network # Check that networking is up. if [ ${NETWORKING} = "no" ] then exit 0 fi if [ ! -x /sbin/ipchains ]; then exit 0 fi # See how we were called. case "$1" in start) echo -n "Starting Firewalling Services: " # Some definitions for easy maintenance. # ------------------------------------------------------------------ ---------- # EDIT THESE TO SUIT YOUR SYSTEM AND ISP. EXTERNAL_INTERFACE="eth0" # Internet connected interface LOCAL_INTERFACE_1="eth1" # Internal LAN interface LOOPBACK_INTERFACE="lo" # Your local naming convention IPADDR="my.ip.address" # Your IP address LOCALNET_1="192.168.1.0/24" # Whatever private range you use IPSECSG="my.ipsecsg.address" # Space separated list of remote VPN gateways FREESWANVI="ipsec0" # Space separated list of virtual interfaces ANYWHERE="any/0" # Match any IP address NAMESERVER_1="my.name.server.1" # Everyone must have at least one NAMESERVER_2="my.name.server.2" # Your secondary name server MY_ISP="my.isp.address.range/24" # ISP & NOC address range SMTP_SERVER="my.smtp.server" # Your Mail Hub Server. POP_SERVER="my.pop.server" # External pop server, if any NEWS_SERVER="my.news.server" # External news server, if any SYSLOG_SERVER="syslog.internal.server" # Your syslog internal server LOOPBACK="127.0.0.0/8" # Reserved loopback address range CLASS_A="10.0.0.0/8" # Class A private networks CLASS_B="172.16.0.0/12" # Class B private networks CLASS_C="192.168.0.0/16" # Class C private networks CLASS_D_MULTICAST="224.0.0.0/4" # Class D multicast addresses CLASS_E_RESERVED_NET="240.0.0.0/5" # Class E reserved addresses BROADCAST_SRC="0.0.0.0" # Broadcast source address BROADCAST_DEST="255.255.255.255" # Broadcast destination address PRIVPORTS="0:1023" # Well known, privileged port range UNPRIVPORTS="1024:65535" # Unprivileged port range # ------------------------------------------------------------------ ---------- # SSH starts at 1023 and works down to 513 for # each additional simultaneous incoming connection. SSH_PORTS="1022:1023" # range for SSH privileged ports # traceroute usually uses -S 32769:65535 -D 33434:33523 TRACEROUTE_SRC_PORTS="32769:65535" TRACEROUTE_DEST_PORTS="33434:33523" # ------------------------------------------------------------------ ---------- # Default policy is DENY # Explicitly accept desired INCOMING & OUTGOING connections # Remove all existing rules belonging to this filter ipchains -F # Clearing all current rules and user defined chains ipchains -X # Set the default policy of the filter to deny. # Don't even bother sending an error message back. ipchains -P input DENY ipchains -P output DENY ipchains -P forward DENY # set masquerade timeout to 10 hours for tcp connections ipchains -M -S 36000 0 0 # Don't forward fragments. Assemble before forwarding. ipchains -A output -f -i $LOCAL_INTERFACE_1 -j DENY # ------------------------------------------------------------------ ---------- # MODULES MASQUERADING # Uncomment bellow all modules lines that you need # These modules are necessary to masquerade their respective services. /sbin/modprobe ip_masq_ftp /sbin/modprobe ip_masq_raudio ports=554,7070,7071,6970,6971 /sbin/modprobe ip_masq_irc #/sbin/modprobe ip_masq_vdolive #/sbin/modprobe ip_masq_cuseeme #/sbin/modprobe ip_masq_quake # ------------------------------------------------------------------ ---------- # LOOPBACK # Unlimited traffic on the loopback interface. ipchains -A input -i $LOOPBACK_INTERFACE -j ACCEPT ipchains -A output -i $LOOPBACK_INTERFACE -j ACCEPT # ------------------------------------------------------------------ ---------- # Network Ghouls # Deny access to jerks # /etc/rc.d/rc.firewall.blocked contains a list of # ipchains -A input -i $EXTERNAL_INTERFACE -s address -j DENY # rules to block from any access. # Refuse any connection from problem sites #if [ -f /etc/rc.d/rc.firewall.blocked ]; then # . /etc/rc.d/rc.firewall.blocked #fi # ------------------------------------------------------------------ ---------- # SPOOFING & BAD ADDRESSES # Refuse spoofed packets. # Ignore blatantly illegal source addresses. # Protect yourself from sending to bad addresses. # Refuse spoofed packets pretending to be from the external address. ipchains -A input -i $EXTERNAL_INTERFACE -s $IPADDR -j DENY -l # Refuse packets claiming to be to or from a Class A private network ipchains -A input -i $EXTERNAL_INTERFACE -s $CLASS_A -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -d $CLASS_A -j DENY -l ipchains -A output -i $EXTERNAL_INTERFACE -s $CLASS_A -j REJECT -l ipchains -A output -i $EXTERNAL_INTERFACE -d $CLASS_A -j REJECT -l # Refuse packets claiming to be to or from a Class B private network ipchains -A input -i $EXTERNAL_INTERFACE -s $CLASS_B -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -d $CLASS_B -j DENY -l ipchains -A output -i $EXTERNAL_INTERFACE -s $CLASS_B -j REJECT -l ipchains -A output -i $EXTERNAL_INTERFACE -d $CLASS_B -j REJECT -l # Refuse packets claiming to be to or from a Class C private network # ipchains -A input -i $EXTERNAL_INTERFACE -s $CLASS_C -j DENY - l # ipchains -A input -i $EXTERNAL_INTERFACE -d $CLASS_C -j DENY - l # ipchains -A output -i $EXTERNAL_INTERFACE -s $CLASS_C -j REJECT -l # ipchains -A output -i $EXTERNAL_INTERFACE -d $CLASS_C -j REJECT -l # Refuse packets claiming to be from the loopback interface ipchains -A input -i $EXTERNAL_INTERFACE -s $LOOPBACK -j DENY -l ipchains -A output -i $EXTERNAL_INTERFACE -s $LOOPBACK -j REJECT -l # Refuse broadcast address SOURCE packets ipchains -A input -i $EXTERNAL_INTERFACE -s $BROADCAST_DEST -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -d $BROADCAST_SRC -j DENY -l # Refuse Class D multicast addresses (in.h) (NET-3-HOWTO) # Multicast is illegal as a source address. # Multicast uses UDP. ipchains -A input -i $EXTERNAL_INTERFACE -s $CLASS_D_MULTICAST - j DENY -l # Refuse Class E reserved IP addresses ipchains -A input -i $EXTERNAL_INTERFACE -s $CLASS_E_RESERVED_NET - j DENY -l # refuse addresses defined as reserved by the IANA # 0.*.*.*, 1.*.*.*, 2.*.*.*, 5.*.*.*, 7.*.*.*, 23.*.*.*, 27.*.*.* # 31.*.*.*, 37.*.*.*, 39.*.*.*, 41.*.*.*, 42.*.*.*, 58-60.*.*.* # 65-95.*.*.*, 96-126.*.*.*, 197.*.*.*, 201.*.*.* (?), 217-223.*.*.* ipchains -A input -i $EXTERNAL_INTERFACE -s 1.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 2.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 5.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 7.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 23.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 27.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 31.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 37.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 39.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 41.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 42.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 58.0.0.0/7 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 60.0.0.0/8 -j DENY -l #65: 01000001 - /3 includes 64 - need 65-79 spelled out ipchains -A input -i $EXTERNAL_INTERFACE -s 65.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 66.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 67.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 68.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 69.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 70.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 71.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 72.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 73.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 74.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 75.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 76.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 77.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 78.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 79.0.0.0/8 -j DENY -l #80: 01010000 - /4 masks 80-95 ipchains -A input -i $EXTERNAL_INTERFACE -s 80.0.0.0/4 -j DENY -l # 96: 01100000 - /4 makses 96-111 ipchains -A input -i $EXTERNAL_INTERFACE -s 96.0.0.0/4 -j DENY -l #126: 01111110 - /3 includes 127 - need 112-126 spelled out ipchains -A input -i $EXTERNAL_INTERFACE -s 112.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 113.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 114.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 115.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 116.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 117.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 118.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 119.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 120.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 121.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 122.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 123.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 124.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 125.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 126.0.0.0/8 -j DENY -l #217: 11011001 - /5 includes 216 - need 217-219 spelled out ipchains -A input -i $EXTERNAL_INTERFACE -s 217.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 218.0.0.0/8 -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -s 219.0.0.0/8 -j DENY -l #223: 11011111 - /6 masks 220-223 ipchains -A input -i $EXTERNAL_INTERFACE -s 220.0.0.0/6 -j DENY -l # ------------------------------------------------------------------ ---------- # ICMP # To prevent denial of service attacks based on ICMP bombs, filter # incoming Redirect (5) and outgoing Destination Unreachable (3). # Note, however, disabling Destination Unreachable (3) is not # advisable, as it is used to negotiate packet fragment size. # For bi-directional ping. # Message Types: Echo_Reply (0), Echo_Request (8) # To prevent attacks, limit the src addresses to your ISP range. # # For outgoing traceroute. # Message Types: INCOMING Dest_Unreachable (3), Time_Exceeded (11) # default UDP base: 33434 to base+nhops-1 # # For incoming traceroute. # Message Types: OUTGOING Dest_Unreachable (3), Time_Exceeded (11) # To block this, deny OUTGOING 3 and 11 # 0: echo-reply (pong) # 3: destination-unreachable, port-unreachable, fragmentation- needed, etc. # 4: source-quench # 5: redirect # 8: echo-request (ping) # 11: time-exceeded # 12: parameter-problem ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 0 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 3 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 4 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 11 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 12 -d $IPADDR -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $MY_ISP 8 -d $IPADDR -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 0 -d $MY_ISP -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 3 -d $MY_ISP -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 4 -d $ANYWHERE -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 8 -d $ANYWHERE -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 12 -d $ANYWHERE -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p icmp \ -s $IPADDR 11 -d $MY_ISP -j ACCEPT # ------------------------------------------------------------------ ---------- # UDP INCOMING TRACEROUTE # traceroute usually uses -S 32769:65535 -D 33434:33523 ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $MY_ISP $TRACEROUTE_SRC_PORTS \ -d $IPADDR $TRACEROUTE_DEST_PORTS -j ACCEPT -l ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $ANYWHERE $TRACEROUTE_SRC_PORTS \ -d $IPADDR $TRACEROUTE_DEST_PORTS -j DENY -l # ------------------------------------------------------------------ ---------- # DNS server # ---------- # DNS: full server # server/client to server query or response ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $ANYWHERE $UNPRIVPORTS \ -d $IPADDR 53 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -s $IPADDR 53 \ -d $ANYWHERE $UNPRIVPORTS -j ACCEPT # DNS client (53) # --------------- ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $NAMESERVER_1 53 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -s $IPADDR $UNPRIVPORTS \ -d $NAMESERVER_1 53 -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $NAMESERVER_2 53 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -s $IPADDR $UNPRIVPORTS \ -d $NAMESERVER_2 53 -j ACCEPT # TCP client to server requests are allowed by the protocol # if UDP requests fail. This is rarely seen. Usually, clients # use TCP as a secondary nameserver for zone transfers from # their primary nameservers, and as hackers. ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $NAMESERVER_1 53 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $NAMESERVER_1 53 -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $NAMESERVER_2 53 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $NAMESERVER_2 53 -j ACCEPT # ------------------------------------------------------------------ ---------- # TCP accept only on selected ports # --------------------------------- # ------------------------------------------------------------------ # SSH server (22) # --------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE $UNPRIVPORTS \ -d $IPADDR 22 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $IPADDR 22 \ -d $ANYWHERE $UNPRIVPORTS -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE $SSH_PORTS \ -d $IPADDR 22 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $IPADDR 22 \ -d $ANYWHERE $SSH_PORTS -j ACCEPT # SSH client (22) # --------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $ANYWHERE 22 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE 22 -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $ANYWHERE 22 \ -d $IPADDR $SSH_PORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $SSH_PORTS \ -d $ANYWHERE 22 -j ACCEPT # ------------------------------------------------------------------ # HTTP client (80) # ---------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $ANYWHERE 80 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE 80 -j ACCEPT # ------------------------------------------------------------------ # HTTPS client (443) # ------------------ ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $ANYWHERE 443 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE 443 -j ACCEPT # ------------------------------------------------------------------ # POP client (110) # ---------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $POP_SERVER 110 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $POP_SERVER 110 -j ACCEPT # ------------------------------------------------------------------ # NNTP NEWS client (119) # ---------------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $NEWS_SERVER 119 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $NEWS_SERVER 119 -j ACCEPT # ------------------------------------------------------------------ # FINGER client (79) # ------------------ # ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ # -s $ANYWHERE 79 \ # -d $IPADDR $UNPRIVPORTS -j ACCEPT # ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ # -s $IPADDR $UNPRIVPORTS \ # -d $ANYWHERE 79 -j ACCEPT # ------------------------------------------------------------------ # SYSLOG client (514) # ----------------- # ipchains -A output -i $LOCAL_INTERFACE_1 -p udp \ # -s $IPADDR 514 \ # -d $SYSLOG_SERVER 514 -j ACCEPT # ------------------------------------------------------------------ # AUTH server (113) # ----------------- # Reject, rather than deny, the incoming auth port. (NET-3-HOWTO) ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE \ -d $IPADDR 113 -j REJECT # AUTH client (113) # ----------------- # ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ # -s $ANYWHERE 113 \ # -d $IPADDR $UNPRIVPORTS -j ACCEPT # ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ # -s $IPADDR $UNPRIVPORTS \ # -d $ANYWHERE 113 -j ACCEPT # ------------------------------------------------------------------ # SMTP client (25) # ---------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $ANYWHERE 25 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE 25 -j ACCEPT # ------------------------------------------------------------------ # IRC client (6667) # ----------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $ANYWHERE 6667 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE 6667 -j ACCEPT # ------------------------------------------------------------------ # ICQ client (4000) # ----------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $ANYWHERE 2000:4000 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE 2000:4000 -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $ANYWHERE 4000 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE 4000 -j ACCEPT # ------------------------------------------------------------------ # FTP client (20, 21) # ------------------- # outgoing request ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $ANYWHERE 21 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE 21 -j ACCEPT # NORMAL mode data channel ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -s $ANYWHERE 20 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT # NORMAL mode data channel responses ipchains -A output -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE 20 -j ACCEPT # PASSIVE mode data channel creation ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE $UNPRIVPORTS -j ACCEPT # PASSIVE mode data channel responses ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $ANYWHERE $UNPRIVPORTS \ -d $IPADDR $UNPRIVPORTS -j ACCEPT # ------------------------------------------------------------------ # RealAudio / QuickTime client # ---------------------------- ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $ANYWHERE 554 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE 554 -j ACCEPT # TCP is a more secure method: 7070:7071 ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ -s $ANYWHERE 7070:7071 \ -d $IPADDR $UNPRIVPORTS -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE 7070:7071 -j ACCEPT # UDP is the preferred method: 6970:6999 # For LAN machines, UDP requires the RealAudio masquerading module and # the ipmasqadm third-party software. ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $ANYWHERE $UNPRIVPORTS \ -d $IPADDR 6970:6999 -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -s $IPADDR $UNPRIVPORTS \ -d $ANYWHERE $UNPRIVPORTS -j ACCEPT # ------------------------------------------------------------------ # WHOIS client (43) # ----------------- # ipchains -A input -i $EXTERNAL_INTERFACE -p tcp ! -y \ # -s $ANYWHERE 43 \ # -d $IPADDR $UNPRIVPORTS -j ACCEPT # ipchains -A output -i $EXTERNAL_INTERFACE -p tcp \ # -s $IPADDR $UNPRIVPORTS \ # -d $ANYWHERE 43 -j ACCEPT # ------------------------------------------------------------------ # OUTGOING TRACEROUTE # ------------------- ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -s $IPADDR $TRACEROUTE_SRC_PORTS \ -d $ANYWHERE $TRACEROUTE_DEST_PORTS -j ACCEPT # ------------------------------------------------------------------ ---------- # Unlimited traffic within the local network. # All internal machines have access to the firewall machine. ipchains -A input -i $LOCAL_INTERFACE_1 -s $LOCALNET_1 -j ACCEPT ipchains -A output -i $LOCAL_INTERFACE_1 -d $LOCALNET_1 -j ACCEPT # ------------------------------------------------------------------ ---------- # FreeS/WAN IPSec VPN # ------------------- # If you are using the FreeSWAN IPSec VPN, you will need to fill in the # addresses of the gateways in the IPSECSG and the virtual interfaces for # FreeS/Wan IPSEC in the FREESWANVI parameters. Look at the beginning of # this firewall script rules file to set the parameters. # IPSECSG is a Space separated list of remote gateways. FREESWANVI is a # Space separated list of virtual interfaces for FreeS/Wan IPSEC # implementation. Only include those that are actually used. # Allow IPSEC protocol from remote gateways on external interface # IPSEC uses three main types of packet: # IKE uses the UDP protocol and port 500, # ESP use the protocol number 50, and # AH use the protocol number 51 # ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ # -s $IPSECSG -j ACCEPT # ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ # -d $IPSECSG -j ACCEPT # ipchains -A input -i $EXTERNAL_INTERFACE -p 50 \ # -s $IPSECSG -j ACCEPT # ipchains -A output -i $EXTERNAL_INTERFACE -p 50 \ # -d $IPSECSG -j ACCEPT # ipchains -A input -i $EXTERNAL_INTERFACE -p 51 \ # -s $IPSECSG -j ACCEPT # ipchains -A output -i $EXTERNAL_INTERFACE -p 51 \ # -d $IPSECSG -j ACCEPT # Allow all traffic to FreeS/WAN Virtual Interface # ipchains -A input -i $FREESWANVI \ # -s $ANYWHERE \ # -d $ANYWHERE -j ACCEPT # ipchains -A output -i $FREESWANVI \ # -s $ANYWHERE \ # -d $ANYWHERE -j ACCEPT # Forward anything from the FreeS/WAN virtual interface IPSEC tunnel # ipchains -A forward -i $FREESWANVI \ # -s $ANYWHERE \ # -d $ANYWHERE -j ACCEPT # Disable IP spoofing protection to allow IPSEC to work properly # echo 0 > /proc/sys/net/ipv4/conf/ipsec0/rp_filter # echo 0 > /proc/sys/net/ipv4/conf/eth0/rp_filter # ------------------------------------------------------------------ ---------- # Masquerade internal traffic. # All internal traffic is masqueraded externally. ipchains -A forward -i $EXTERNAL_INTERFACE -s $LOCALNET_1 -j MASQ # ------------------------------------------------------------------ ---------- # Enable logging for selected denied packets ipchains -A input -i $EXTERNAL_INTERFACE -p tcp \ -d $IPADDR -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -d $IPADDR $PRIVPORTS -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -d $IPADDR $UNPRIVPORTS -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 5 -d $IPADDR -j DENY -l ipchains -A input -i $EXTERNAL_INTERFACE -p icmp \ -s $ANYWHERE 13:255 -d $IPADDR -j DENY -l # ------------------------------------------------------------------ ---------- ;; stop) echo -n "Shutting Firewalling Services: " # Remove all existing rules belonging to this filter ipchains -F # Delete all user-defined chain to this filter ipchains -X # Reset the default policy of the filter to accept. ipchains -P input ACCEPT ipchains -P output ACCEPT ipchains -P forward ACCEPT ;; status) status firewall ;; restart|reload) $0 stop $0 start ;; *) echo "Usage: firewall {start|stop|status|restart|reload}" exit 1 esac exit 0 Now, make this script executable and change its default permissions: [root@deep] /#chmod 700 /etc/rc.d/init.d/firewall [root@deep] /#chown 0.0 /etc/rc.d/init.d/firewall Create the symbolic rc.d links for your Firewall with the command: [root@deep] /#chkconfig --add firewall [root@deep] /#chkconfig --level 345 firewall on Now, your firewall rules are configured to use System V init -System V init is in charge of starting all the normal processes that need to run at boot time and it will be automatically started each time your server reboots. To manually stop the firewall on your system, use the following command: [root@deep] /# /etc/rc.d/init.d/firewall stop Shutting Firewalling Services: [ OK ] To manually start the firewall on your system, use the following command: [root@deep] /# /etc/rc.d/init.d/firewall start Starting Firewalling Services: [ OK ] 4. Deny access to some address Sometimes you'll know an address that you would like to block from having any access at all to your server. You can do that by creating the rc.firewall.blocked file under /etc/rc.d/ directory and uncomment the following lines in your firewall rules scripts file: Edit your firewall scripts file vi /etc/rc.d/init.d/firewall and uncomment the following lines: if [ -f /etc/rc.d/rc.firewall.blocked ]; then . /etc/rc.d/rc.firewall.blocked fi Create the rc.firewall.blocked file touch /etc/rc.d/rc.firewall.blocked and add inside this file all the IP addresses that you want to block from having any access to your server at all: For example, I put the following IP addresses in this file: Example 12.1. rc.firewall.blocked 204.254.45.9 187.231.11.5 Further documentation, more details, there are several man pages you can read: * ipchains(8)- IP firewall administration * ipchains-restore(8)- restore IP firewall chains from stdin * ipchains-save(8)- save IP firewall chains to stdout 5. IPCHAINS Administrative Tools The commands listed below are some tools that we use often, but many more exist, and you should check the man page and documentation for more details and information. The ipchains tool is used for the firewall administration of the Linux system. We can use it to set up a firewall rules file, as we are doing in this book. Once firewall rules have been created we can play with its many commands to maintain, and inspect its rules in the Linux kernel. To list all rules in the selected chain, use the command: [root@deep] /# ipchains -L This command will list all rules in the selected chain. If no chain is selected, all chains are listed. To list all input rules in the selected chain, use the command: [root@deep] /# ipchains -L input This command will list all input rules we have configured in the selected chain. To list all output rules in the selected chain, use the command: [root@deep] /# ipchains -L output This command will list all output rules we have configured in the selected chain. To list all forward rules in the selected chain, use the command: [root@deep] /# ipchains -L forward This command will list all forward rules in the selected chain. This of course works only if you have configured Masquerading on your server. for gateway servers in general. To list all masquerades rules in the selected chain, use the command: [root@deep] /# ipchains -ML This option allows viewing of the currently masqueraded connections. You must have configured Masquerading on your server for this command to work, once again, only for gateway servers. To list all rules in numeric output in the selected chain, use the command: [root@deep] /# ipchains -nL This command will list all rules in numeric output. All the IP addresses and port numbers will be printed in numeric format. Part 5. Software -Security Spoonbill Abstract The next Two parts will exclusively deal with the Software other than the one's which the Linux distribution, in our case Redhat Linux, may or may not provide as a part of its core distribution. In some cases it may be provided as an extra but may come as pre-compiled binary which may not exactly suit your purpose. Hence we have in most cases used source packages usually packed as tar gzipped -*.tar.gz or in some recent case in tar bzipped -*.tar.bz2 format. This gives us the maximum available choices to tweak, choose and delete the options within these Softwares. Just a word about the *.tar.gz and *.tar.bz2, the contents are same except that the compression used is different and the bz2 extention is smaller in size as compressed format. Table of Contents 13._Linux_-The_Compiler_functionality 1._The_necessary_packages 2._Why_choose_tarballs? 2.1._Compiling_software_on_your_system 3._Build,_Install_software_on_your_system 3.1._Edit_files_with_the_vi_editor 14._Software_-Security/Monitoring 1._sXid 2._Configure_and_Optimize_sXid 2.1._Configure_the_/etc/sxid.conf_file 3._Logcheck 4._Configure_and_Optimize_Logcheck 5._PortSentry 6._Configure_and_Optimise_Portsentry 7._Test_fire_your_PortSentry Chapter 13. Linux -The Compiler functionality Table of Contents 1._The_necessary_packages 2._Why_choose_tarballs? 2.1._Compiling_software_on_your_system 3._Build,_Install_software_on_your_system 3.1._Edit_files_with_the_vi_editor We are, now at one of the most interesting point, here we will compile and install all the services that we wish to offer in our Linux server. Before we begin to explain how to compile and install server software with all the necessary securities and optimizations that we will need on our server, it is important to know the commands and programs we'll use often to do the job. First of all, we must ensure that we have the necessary packages needed to make compilations on our system. These packages must be installed on your server or you'll not be able to compile programs. 1. The necessary packages The following are the necessary packages needed to be able to compile the other software programs on your system after recompilation of your kernel. This software is on your Red Hat Linux 6.1 or 6.2 Part 1 CD-ROM under RedHat/RPMS directory if they are not already installed. [root@deep] /#mount /dev/cdrom /mnt/cdrom/ [root@deep] /#cd /mnt/cdrom/RedHat/RPMS/ Version 6.1 only autoconf-2.13-5.noarch.rpm ctags-3.2-1.i386.rpm m4-1.4-12.i386.rpm egcs-1.1.2-24.i386.rpm automake-1.4-5.noarch.rpm ElectricFence-2.1-1.i386.rpm dev86-0.14.9-1.i386.rpm flex-2.5.4a-7.i386.rpm bison-1.28-1.i386.rpm gdb-4.18-4.i386.rpm byacc-1.9-11.i386.rpm kernel-headers-2.2.12-20.i386.rpm cdecl-2.5-9.i386.rpm glibc-devel-2.1.2-11.i386.rpm cpp-1.1.2-24.i386.rpm make-3.77-6.i386.rpm cproto-4.6-2.i386.rpm patch-2.5-9.i386.rpm Version 6.2 only autoconf-2.13-5.noarch.rpm ctags-3.4-1.i386.rpm m4-1.4-12.i386.rpm egcs-1.1.2-30.i386.rpm automake-1.4-6.noarch.rpm ElectricFence-2.1-3.i386.rpm dev86-0.15.0-2.i386.rpm flex-2.5.4a-9.i386.rpm bison-1.28-2.i386.rpm gdb-4.18-11.i386.rpm byacc-1.9-12.i386.rpm kernel-headers-2.2.14-5.0.i386.rpm cdecl-2.5-10.i386.rpm glibc-devel-2.1.3-15.i386.rpm cpp-1.1.2-30.i386.rpm make-3.78.1-4.i386.rpm cproto-4.6-3.i386.rpm patch-2.5-10.i386.rpm Important It is better to install the software described above all together if you don't want to receive dependency error messages during RPM install. If you have followed all the steps in Installation_of_your_Linux_Server, then all of these packages are already installed on your system and you don't need to reinstall them again. The RPM command to install a RPM package on your system is: [root@deep] /#rpm -Uvh foo-1.0-2.i386.rpm The RPM command to verify that a package is or is not installed on your system is: [root@deep] /#rpm -q foo Once again, after installation and compilation of all programs that you need on your server, its important to uninstall all sharp objects compilers, etc. describe above. This will protect your system from unauthorized users trying to compile programs on your server without authorization. Another thing to do is to move the rpm binary program to a safe place like a floppy disk for the same reasons listed above. Imagine somebody with dark intentions trying to compile programs on your server and realizing that compilers are not available. They will switch to import programs RPM on the server and install it with the RPM commands. Whoops, Heh! Heh! surprised! RPM commands are not available either. Of course, in future if you need to install new software on your server, all you have to do is to replace it from the floppy disk. To move the RPM binary in the floppy disk, use the command: [root@deep] /#mount /dev/fd0 /mnt/floppy/ [root@deep] /#mv /bin/rpm /mnt/floppy [root@deep] /#umount /mnt/floppy/ To put the RPM binary to its original directory, use the command: [root@deep] /#mount /dev/fd0 /mnt/floppy/ [root@deep] /#cp /mnt/floppy/rpm /bin/ [root@deep] /#umount /mnt/floppy/ Warning Never uninstall the RPM program completely from your system or you will be unable to reinstall it again later since to install RPM or other software you need to have RPM commands available. 2. Why choose tarballs? All the programs in Red Hat distributions of Linux are provided as RPM files. An RPM file, also known, as a package, is a way of distributing software so that it can be easily installed, upgraded, queried, and deleted. However, in Unix world, the defacto-standard for package distribution continues to be by way of so-called tarballs. Tarballs are simply compressed files that can be readable and uncompressed with the tar utility. Installing from tar is usually significantly more tedious than using RPM. So why would we choose to do so? 1. Unfortunately, it takes a few weeks for developers and coders to get the latest version of a package converted to RPMs because many developers first release them as tarballs. 2. When developers and vendors release a new RPM, they include a lot of options that often are not necessary. Those organization and companies don't know what options you will need and what you will not, so they include the most used to fit the needs of everyone. 3. Often RPMs are not optimized for your specific processors; companies like Red Hat Linux build RPMs based on a standard PC. This permit their RPM packages to be installed on all sorts of computers since compiling programs for an i386 machine can fit on all systems. 4. Sometimes you download and install RPM, which other people around the world are building and make available for your purposes. This can pose conflicts in certain cases depending how this individual built the package, such as errors, security and all the other problems described above. 2.1. Compiling software on your system A program is something a computer can execute. Originally, somebody wrote the source code in a programming language he/she could understand e.g., C, C++. The program source code also makes sense to a compiler that converts the instructions into a binary file suited to whatever processor is wanted e.g. a 386 or similar. A modern file format for these executable programs is Elf. The programmer compiles his source using the compiler and gets a result of some sort. It's not at all uncommon that early attempts fail to compile, or having compiled, fail to act as expected. Half of programming is tracking down and fixing these problems debugging. For the beginners there are more aspect and new words relating to compilation of a source code that you must know, these includes but are not limited to: The Multiple Files One-file programs are quite rare. Usually there are a number of files say *.c, *.cpp, etc. that are each compiled into object files *.o and then linked into an executable. The compiler is usually used to perform the linking and calls the ld program behind the scenes. The Makefiles The Makefiles are intended to aid you in building your program the same way each time. They also often help with speed. The make program uses dependencies in the Makefile to decide what parts of the program need to be recompiled. If you change one source file out of fifty you hope to get away with one compile and one link step, instead of starting from scratch. The Libraries Programs can be linked not only to object files *.o but also to libraries that are collections of object files. There are two forms of linking to libraries: static, where the code goes in the executable file, and dynamic, where the code is collected when the program starts to run. The Patches It was common before for executable files to be given corrections without recompiling them. Now this practice has died out; in modern days, people changes a small proportion of the whole source code, putting a change into a file called a patch. Where different versions of a program are required, small changes to code can be released this way, saving the trouble of having two large distributions. The Errors in Compilation and Linking Errors in compilation and linking are often typos, omissions, and misuse of the language. Check that the right includes files are used for the functions you are calling. Unreferenced symbols are the sign of an incomplete link step. Also checks if the necessary development libraries GLIBC or tools GCC, DEV86, AUTOMAKE, etc. are installed on your system. The Debugging Debugging is a large topic. It usually helps to have statements in the code that inform you of what is happening. To avoid drowning in output you might sometimes get them to print out only the first 3 passes in a loop. Checking that variables have passed correctly between modules often helps. Get familiar with your debugging tools. 3. Build, Install software on your system You will see from the next chapter right through Part 6 that we use many different compile commands to build and install programs on the server. These commands are UNIX compatible and are used on all variant off *nix machines to compile and install software. The procedures to compile and install software tarballs on your server follow: 1. First of all, you must download the tarball from your trusted software archive site. Usually from the main site of the software you hope to install. 2. After downloading the tarball change to the /var/tmp/ directory, note that other paths are possible, as personal discretion and untar the archive by typing the commands as root as in the following example: Example 13.1. Using tar [root@deep] /#tar xzpf foo.tar.gz The above command will extract all files from the example foo.tar.gz compressed archive and will create a new directory for them with the name of this software from the path where you are executing the command. The x option tells tar to extract all files from the archive. The z option tells tar that the archive is compressed with gzip. The p option maintains the original and permissions the files had as the archive was created. The f option tells tar that the very next argument is the file name. Once the tarball has been decompressed into the appropriate directory, you will almost certainly find a README and/or an INSTALL file included with the newly decompressed files, with further instructions on how to build and compile the software package for use. You will need to enter commands similar to the following example: ./configure make make install The above commands; ./configure will configure the software to ensure your system has the necessary functionality and libraries to successfully compile the package make will compile all the source files into executable binaries. Finally, make install will install the binaries and any supporting files into the appropriate locations. Other specifics commands that you'll see in our book for compilation and installation procedure will be: make depend strip chown make depend command will build and make the necessary dependencies for different files. strip command will discard all symbols from the object files. This means that our binary file will be smaller in size, will improve a bit the performance hit to the program since there will be fewer lines to read by the system when it executes the binary. chown command will set the correct files owner and group permission for the binaries. Note More commands when necessary will be explained in the concerned installation procedure. 3.1. Edit files with the vi editor The vi program is a text editor that you can use to edit any text and particularly programs. During installation of software, the user will often have to edit text files like Makefiles or configuration files to make and fit they changes. The following are some of the most important keystroke commands to get around in vi. i To insert text before the cursor. a To append text after the cursor. dd To delete the current line. x To delete the current character. Esc To end the insert or append mode. u To undo the last command. Ctrl+f Scroll up one page. Ctrl+b Scroll down one page. /string Search forward for string. :f Display filename and current line nmber. :q Quit editor. :q! Quit editor without saving changes. :wq Save changes and exit editor. Warning Before proceeding to read the rest of this book, it should be noted that the text assumes that certain files are placed in certain directories. Where they have been specified, the conventions we adopt here for locating these files are those of the Red Hat Linux distribution. If you are using a distribution of Linux or some other operating system that chooses to distribute these files in a different way, you should be careful when copying examples directly from the text. Chapter 14. Software -Security/Monitoring Table of Contents 1._sXid 2._Configure_and_Optimize_sXid 2.1._Configure_the_/etc/sxid.conf_file 3._Logcheck 4._Configure_and_Optimize_Logcheck 5._PortSentry 6._Configure_and_Optimise_Portsentry 7._Test_fire_your_PortSentry At this part of our book, all software-listed on chapter 14 through chapter 32 are optional and depends on what you want to install or do on your server. e.g., What kind of tasks will your server do, and for which part of your network Intranet/Internet? In other parts it may be important for you to replace the Telnet program with SSH for secure remote administration. Another interesting program is Tripwire that aids system administrators and users in monitoring a designated set of files for any changes. 1. sXid SUID/SGID files can be a security hazard. To reduce the risks, we have previously already removed the s bits from root-owned programs that won't absolutely require such privilege, but future and existing files may be set with these s bits enabled without your notification. sXid is an all in one suid/sgid monitoring program designed to be run from cron on a regular basis. Basically it tracks any changes in your s[ug]id files and folders. If there are any new ones, ones that aren't set any more, or they have changed bits or other modes then it reports the changes in an easy to read format via email or on the command line. sXid will automate the task to find all SUID/SGID on your server and report them to you. Once installed you can forget it and it will do the job for you. These installation instructions assume the following: * Commands are Unix-compatible. * The source path is /var/tmp other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * sXid version number as of this writing is 4.0.1 Packages can be dowloaded from the sXid FTP Site:ftp://marcus.seva.net/pub/ sxid/ and You must be sure to download: sxid_4.0.1.tar.gz or whatever the latest version is. Warning The instructions explained here in this book are applicable to the version number mentioned and you need to consult the README and/or INSTALL with in the tarball of the version you have downloaded for any changes, additions and deletions etc.. Important It is a good idea to make a list of files on the system before you install sXid, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > sXid1 before and find /* > sXid2 after you install the software, and use diff sXid1 sXid2 > sXid-Installed to get a list of what changed. Decompress the tarball tar.gz. [root@deep] /#cp sxid_version.tar.gz /var/tmp/ [root@deep] /#cd /var/tmp [root@deep ] /tmp#tar xzpf sxid_version.tar.gz To Compile and Optimize move into the new sXid directory and type the following commands on your terminal: [root@deep tmp]#cd sxid-4.0.1 [root@deep ] /sxid-4.0.1#make install The above commands will configure the software to ensure your system has the necessary functionality and libraries to successfully compile the package, compile all source files into executable binaries, and then install the binaries and any supporting files into the appropriate locations. Please do a cleanup later: [root@deep] /#cd /var/tmp [root@deep ] /tmp#rm -rf sxid-version/ sxid_version_tar.gz The rm command as used above will remove all the source files we have used to compile and install sXid. It will also remove the sXid compressed archive from the /var/tmp directory. 2. Configure and Optimize sXid Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example sXid configuration file are organised like this: total 4 -rw-r--r-- 1 harrypotter harrypotter 1586 Jun 8 13:00 sxid.conf You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. Tip To run sXid, the following file from the floppy.tgz archive is required and must be created or copied to the appropriate directory on your server. Copy the sxid.conf file to the /etc/ directory. or alternatively you can copy and paste directly from this book to the concerned file. 2.1. Configure the /etc/sxid.conf file The configuration file for sXid /etc/sxid.conf allows you to set options that modify the operation of the program. It is well commented and very basic. 1. Edit the sxid.conf file vi /etc/sxid.conf and set your needs: # Configuration file for sXid # Note that all directories must be absolute with no trailing / 's # Where to begin our file search SEARCH = "/" # Which subdirectories to exclude from searching EXCLUDE = "/proc /mnt /cdrom /floppy" # Who to send reports to EMAIL = "root" # Always send reports, even when there are no changes? ALWAYS_NOTIFY = "no" # Where to keep interim logs. This will rotate 'x' number of # times based on KEEP_LOGS below LOG_FILE = "/var/log/sxid.log" # How many logs to keep KEEP_LOGS = "5" # Rotate the logs even when there are no changes? ALWAYS_ROTATE = "no" # Directories where +s is forbidden (these are searched # even if not explicitly in SEARCH), EXCLUDE rules apply FORBIDDEN = "/home /tmp" # Remove (-s) files found in forbidden directories? ENFORCE = "yes" # This implies ALWAYS_NOTIFY. It will send a full list of # entries along with the changes LISTALL = "no" # Ignore entries for directories in these paths # (this means that only files will be recorded, you # can effectively ignore all directory entries by # setting this to "/"). The default is /home since # some systems have /home g+s. IGNORE_DIRS = "/home" # File that contains a list of (each on it's own line) # of other files that sxid should monitor. This is useful # for files that aren't +s, but relate to system # integrity (tcpd, inetd, apache...). # EXTRA_LIST = "/etc/sxid.list" # Mail program. This changes the default compiled in # mailer for reports. You only need this if you have changed # it's location and don't want to recompile sxid. # MAIL_PROG = "/usr/bin/mail" 2. Place an entry into root's crontabs to make sXid run as a cronjob. sXid will run from crond; basically it tracks any changes in your s[ug]id files and folders. If there are any new ones, ones that aren't set any more, or they have changed bits or other modes then it reports the changes. To add sxid in your cronjob you must edit the crontab and add the following line: To edit the crontab, use the command as root: [root@deep] /#crontab -e # Sample crontab entry to run every day at 4am 0 4 * * * /usr/bin/sxid Further documentation for more details, there are some man pages you can read sxid.conf(5) -configuration settings for sxid and sxid(1) - check for changes in s[ug]id files and directories sXid as administrative tool is meant to run as a cronjob. It must run once a day, but busy shell boxes may want to run it twice a day. You can also run this manually for spot-checking. To run sxid manually, use the command: [root@deep] /#sxid -k          sXid Vers  : 4.0.1          Check run  : Wed Dec 29 12:40:32 1999          This host  : mail.openna.com          Spotcheck  : /home/admin          Excluding  : /proc /mnt /cdrom /floppy          Ignore Dirs: /home          Forbidden  : /home /tmp                     No changes found! This checks for changes by recursing the current working directory. Log files will not be rotated and no email sent. All output will go to stdout. These are the Installed files on your system by the program sXid. /etc/sxid.conf /usr/bin/sxid /usr/man/man1/sxid.1 /usr/man/man5/sxid.conf.5 3. Logcheck One important task in the security world is to regularly check the log files. Often the daily activities of an administrator don't allow him the time to do this task and this can bring about problems. Extracted from [Logcheck abstract]: Auditing and logging system events is important! What is more important is that system administrators be aware of these events so they can prevent problems that will inevitably occur if you have a system connected to the Internet. Unfortunately for most Unices it doesn't matter how much you log activity if nobody ever checks the logs, which is often the case. This is where logcheck will help. Logcheck automates the auditing process and weeds out normal log information to give you a condensed look at problems and potential troublemakers mailed to wherever you please. Logcheck is a software package that is designed to automatically run and check system log files for security violations and unusual activity. Logcheck utilizes a program called logtail that remembers the last position it read from in a log file and uses this position on subsequent runs to process new information. These installation instructions assume * Commands are Unix-compatible. * The source path is /var/tmp other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * Logcheck version number is 1.1.1 These are the packages available at Logcheck Homepage Site: http:// www.psionic.com/abacus/logcheck/, and you must be sure to download: logcheck- 1.1.1.tar.gz available as of this writing. Important Please do not forget to read the README and/or INSTALL with in the tarball you have downloaded if the version number is not the same as we have suggested and follow the instructions since there are chances of some changes either bythe way of additions or deletions are likely to be there. Before you uncompress and install from the tarballs it is a good idea to make a list of files on the system before you install Logcheck, and one afterwards, and then compare them using diff to find out what files were placed where. Simply run find /* > Logcheck1 before and find /* > Logcheck2 after you install the software, and use diff Logcheck1 Logcheck2 > Logcheck-Installed to get a list of what changed. To compile, you need to decompress the tarball (tar.gz). [root@deep] /#cp logcheck-version.tar.gz /var/tmp/ [root@deep] /#cd /var/tmp [root@deep ]/tmp#tar xzpf logcheck-version.tar.gz To Compile and Optimize you must modify the Makefile file of Logcheck to specify installation paths, compilation flags, and optimizations for your system. We must modify this file to be compliant with Red Hat's file system structure and install Logcheck script files under our PATH Environment variable. 1. Move into the new Logcheck directory and edit the Makefile, vi Makefile and change the following lines by type the following commands on your terminal: a. CC = cc To read: CC = egcs b. CFLAGS = -O To read: CFLAGS = -O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno- exceptions c. INSTALLDIR = /usr/local/etc To read: INSTALLDIR = /etc/logcheck d. INSTALLDIR_BIN = /usr/local/bin To read: INSTALLDIR_BIN = /usr/bin e. INSTALLDIR_SH = /usr/local/etc To read: INSTALLDIR_SH = /usr/bin f. TMPDIR = /usr/local/etc/tmp To read: TMPDIR = /etc/logcheck/tmp g. The above changes will configure the software to use egcs compiler, optimization flags specific to our system, and locate all files related to Logcheck software to the destination target directories we have chosen to be compliant with the Red Hat file system structure. 2. Edit the Makefile file vi +67 Makefile and change the following line: @if [ ! -d $(TMPDIR) ]; then /bin/mkdir $(TMPDIR); fi To read: @if [ ! -d $(TMPDIR) ]; then /bin/mkdir -p $(TMPDIR); fi The above change -p will allow the installation program to create parent directories as needed. 3. Install Logcheck on your system. [root@deep ]/logcheck-1.1.1#make linux The above command will configure the software for the Linux operating system, compile all source files into executable binaries, and then install the binaries and any supporting files into the appropriate locations. Please don't forget to cleanup later: [root@deep] /#cd /var/tmp [root@deep ]/tmp#rm -rf logcheck-version/ logcheck- version_tar.gz The rm command as used above will remove all the source files we have used to compile and install Logcheck. It will also remove the Logcheck compressed archive from the /var/tmp directory. 4. Configure and Optimize Logcheck You need to configure the /usr/bin/logcheck.sh script file, Since we are using an alternate path for the files i.e. not /usr/local/etc, we need to change the path entries for logcheck.hacking, logcheck.violations, logcheck.ignore, logcheck.violations.ignore, and logtail in the main logcheck.sh script. The script file for Logcheck /usr/bin/logcheck.sh allows you to set these options that modify the path entries and operation of the program. It is well commented and very basic. 1. Edit the logcheck.sh file vi /usr/bin/logcheck.sh and change the following: a. LOGTAIL=/usr/local/bin/logtail To read: LOGTAIL=/usr/bin/logtail b. TMPDIR=/usr/local/etc/tmp To read: TMPDIR=/etc/logcheck/tmp c. HACKING_FILE=/usr/local/etc/logcheck.hacking To read: HACKING_FILE=/etc/logcheck/logcheck.hacking d. VIOLATIONS_FILE=/usr/local/etc/logcheck.violations To read: VIOLATIONS_FILE=/etc/logcheck/logcheck.violations e. VIOLATIONS_IGNORE_FILE=/usr/local/etc/ logcheck.violations.ignore To read: VIOLATIONS_IGNORE_FILE=/etc/logcheck/ logcheck.violations.ignore f. IGNORE_FILE=/usr/local/etc/logcheck.ignore To read: IGNORE_FILE=/etc/logcheck/logcheck.ignore 2. After installing Logcheck, place an entry into root's crontabs to make Logcheck run as a cronjob, you should edit your local crontab file for root and set Logcheck to run once per hour recommended, although you can do it more frequently, or less frequently. To add Logcheck in your cronjob you must edit the crontab and add the following line as root: [root@deep] /#crontab -e # Hourly check Log files for security violations and unusual activity. 00 * * * * /usr/bin/logcheck.sh Note Remember, Logcheck does not report anything via email if it has nothing useful to say. These are the files Installed by the program Logcheck on your sytem, for your future referance. /etc/logcheck /usr/bin/logcheck.sh /etc/logcheck/tmp /usr/bin/logtail /etc/logcheck/logcheck.hacking /var/log/messages.offset /etc/logcheck/logcheck.violations /var/log/secure.offset /etc/logcheck/logcheck.violations.ignore /var/log/maillog.offset /etc/logcheck/logcheck.ignore   5. PortSentry Firewalls help us to protect our network from unsolicited intrusions. Using them we can choose which ports we want to be open and which one's we dont. Information is kept private by your organization and responsibility of individuals asociated. Nobody from the outside implicitly knows this information, but attackers know as well as spammers, that for some kind of attacks you can use a special program to scan all the ports on a server to glean this valuable information i.e. what is open and what is not. From the [PortSentry introduction]: A port scan is a symptom of a larger problem coming your way. It is often the pre-cursor for an attack and is a critical piece of information for properly defending your information resources. PortSentry is a program designed to detect and respond to port scans against a target host in real-time and has a number of options to detect port scans. When it finds one it can react in the following ways: A log indicating the incident is made via syslog(). The target host is automatically dropped into /etc/hosts.deny for TCP Wrappers. The local host is automatically re-configured to route all traffic to the target to a dead host to make the target system disappear. The local host is automatically re-configured to drop all packets from the target via a local packet filter. The purpose of this is to give an admin a heads up that their host is being probed. These installation instructions assume: * Commands are Unix-compatible. * The source path is /var/tmp other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * Portsentry version number is 1.0 These are the Package(s) you have to download and Portsentry Homepage:http:// www.psionic.com/abacus/portsentry/ You must be sure to download: portsentry- 1.0.tar.gz Important Please do not forget to read the README and/or INSTALL with in the tarball you have downloaded if the version number is not the same as we have suggested and follow the instructions since there are chances of some changes either by the way of additions or deletions are likely to be there. When you install from Tarball(s), it is always better to make a list of files on the system before you install Portsentry, and one afterwards, and then compare them using diff to find out what file is placed where.A Simple step find /* > Portsentry1 before and find /* > Portsentry2 after you install the software, and use diff Portsentry1 Portsentry2 > PortSentry-Installed to get a list of what changed. You need to Compile so Decompress the tarball *.tar.gz. [root@deep] /#cp portsentry-version.tar.gz /var/tmp/ [root@deep] /#cd /var/tmp [root@deep ]/tmp#tar xzpf portsentry-version.tar.gz Procedure 14.1. Optimize to compile 1. You must modify the Makefile file for Portsentry to specify installation paths, compilation flags, and optimizations for your system. We must also modify this file to be compliant with Red Hat file's system structure. Move into the new Portsentry directory and with the following commands on your terminal edit the Makefile file vi Makefile and change the following lines: a. CC = cc To read: CC = egcs b. CFLAGS = -O -Wall To read: CFLAGS = -O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno- exceptions -Wall c. INSTALLDIR = /usr/local/psionic To read: INSTALLDIR = /usr/psionic d. The above changes will configure the software to use egcs compiler, optimization flags specific to our system, and locate all files related to Portsentry software to the target directories we have chosen. 2. Since we are using an alternate path for the files i.e. not /usr/local/ psionic, we need to change the path to the PortSentry configuration file in the main portsentry_config.h header file. Move into the new PortSentry directory and edit the portsentry_config.h file vi portsentry_config.h and change the following line: #define CONFIG_FILE "/usr/local/psionic/portsentry/ portsentry.conf" To read: #define CONFIG_FILE "/usr/psionic/portsentry/portsentry.conf" 3. Step 3 Install Portsentry on your system. [root@deep ]/portsentry-1.0#make linux [root@deep ]/portsentry-1.0#make install The above commands will configure the software to the Linux operating system, compile, build, and then finally install files into the appropriate locations. Please do a cleanup later: [root@deep] /# cd /var/tmp [root@deep ]/tmp#rm -rf portsentry-version/ portsentry- version_tar.gz The rm command will remove all the source files we have used to compile and install PortSentry. It will also remove the PortSentry compressed archive from the /var/tmp directory. 6. Configure and Optimise Portsentry You have to configure the the /usr/psionic/portsentry/portsentry.conf file which is the main configuration file for the PortSentry Software; you can specify which ports you want to listen to, which IP addresses are denied, monitor, ignore, disable automatic responses, and so on. For more information read the README.install file under the PortSentry source directory. Edit the portsentry.conf file, vi /usr/psionic/portsentry.conf and check/change the following options to fit your needs: # PortSentry Configuration # # $Id$ # # IMPORTANT NOTE: You CAN NOT put spaces between your port arguments. # # The default ports will catch a large number of common probes # # All entries must be in quotes. ####################### # Port Configurations # ####################### # # # Some example port configs for classic and basic Stealth modes # # I like to always keep some ports at the "low" end of the spectrum. # This will detect a sequential port sweep really quickly and usually # these ports are not in use (i.e. tcpmux port 1) # # ** X-Windows Users **: If you are running X on your box, you need to be sure # you are not binding PortSentry to port 6000 (or port 2000 for OpenWindows users). # Doing so will prevent the X-client from starting properly. # # These port bindings are *ignored* for Advanced Stealth Scan Detection Mode. # # Un-comment these if you are really anal: #TCP_PORTS="1,7,9,11,15,70,79,80,109,110,111,119,138,139,143,512,513,514,515,540,635,1080,1524,2000,2001,4000,4001,5742,6000,6001,6667,12345,12346,20034,30303,32771,32772,32773,32774,31337,40421,40425,49724,54320" #UDP_PORTS="1,7,9,66,67,68,69,111,137,138,161,162,474,513,517,518,635,640,641,666,700,2049,32770,32771,32772,32773,32774,31337,54321" # # Use these if you just want to be aware: TCP_PORTS="1,11,15,79,111,119,143,540,635,1080,1524,2000,5742,6667,12345,12346,20034,31337,32771,32772,32773,32774,40421,49724,54320" UDP_PORTS="1,7,9,69,161,162,513,635,640,641,700,32770,32771,32772,32773,32774,31337,54321" # # Use these for just bare-bones #TCP_PORTS="1,11,15,110,111,143,540,635,1080,524,2000,12345,12346,20034,32771,32772,32773,32774,49724,54320" #UDP_PORTS="1,7,9,69,161,162,513,640,700,32770,32771,32772,32773,32774,31337,54321" ########################################### # Advanced Stealth Scan Detection Options # ########################################### # # This is the number of ports you want PortSentry to monitor in Advanced mode. # Any port *below* this number will be monitored. Right now it watches # everything below 1023. # # On many Linux systems you cannot bind above port 61000. This is because # these ports are used as part of IP masquerading. I don't recommend you # bind over this number of ports. Realistically: I DON'T RECOMMEND YOU MONITOR # OVER 1023 PORTS AS YOUR FALSE ALARM RATE WILL ALMOST CERTAINLY RISE. You've been # warned! Don't write me if you have have a problem because I'll only tell # you to RTFM and don't run above the first 1023 ports. # # ADVANCED_PORTS_TCP="1023" ADVANCED_PORTS_UDP="1023" # # This field tells PortSentry what ports (besides listening daemons) to # ignore. This is helpful for services like ident that services such # as FTP, SMTP, and wrappers look for but you may not run (and probably # *shouldn't* IMHO). # # By specifying ports here PortSentry will simply not respond to # incoming requests, in effect PortSentry treats them as if they are # actual bound daemons. The default ports are ones reported as # problematic false alarms and should probably be left alone for # all but the most isolated systems/networks. # # Default TCP ident and NetBIOS service ADVANCED_EXCLUDE_TCP="113,139" # Default UDP route (RIP), NetBIOS, bootp broadcasts. ADVANCED_EXCLUDE_UDP="520,138,137,67" ###################### # Configuration Files# ###################### # # Hosts to ignore IGNORE_FILE="/usr/psionic/portsentry/portsentry.ignore" # Hosts that have been denied (running history) HISTORY_FILE="/usr/psionic/portsentry/portsentry.history" # Hosts that have been denied this session only (temporary until next restart) BLOCKED_FILE="/usr/psionic/portsentry/portsentry.blocked" ################### # Response Options# ################### # Options to dispose of attacker. Each is an action that will # be run if an attack is detected. If you don't want a particular # option then comment it out and it will be skipped. # # The variable $TARGET$ will be substituted with the target attacking # host when an attack is detected. The variable $PORT$ will be substituted # with the port that was scanned. # ################## # Ignore Options # ################## # These options allow you to enable automatic response # options for UDP/TCP. This is useful if you just want # warnings for connections, but don't want to react for # a particular protocol (i.e. you want to block TCP, but # not UDP). To prevent a possible Denial of service attack # against UDP and stealth scan detection for TCP, you may # want to disable blocking, but leave the warning enabled. # I personally would wait for this to become a problem before # doing though as most attackers really aren't doing this. # The third option allows you to run just the external command # in case of a scan to have a pager script or such execute # but not drop the route. This may be useful for some admins # who want to block TCP, but only want pager/e-mail warnings # on UDP, etc. # # # 0 = Do not block UDP/TCP scans. # 1 = Block UDP/TCP scans. # 2 = Run external command only (KILL_RUN_CMD) BLOCK_UDP="1" BLOCK_TCP="1" ################### # Dropping Routes:# ################### # This command is used to drop the route or add the host into # a local filter table. # # The gateway (333.444.555.666) should ideally be a dead host on # the *local* subnet. On some hosts you can also point this at # localhost (127.0.0.1) and get the same effect. NOTE THAT # 333.444.555.66 WILL *NOT* WORK. YOU NEED TO CHANGE IT!! # # All KILL ROUTE OPTIONS ARE COMMENTED OUT INITIALLY. Make sure you # uncomment the correct line for your OS. If you OS is not listed # here and you have a route drop command that works then please # mail it to me so I can include it. ONLY ONE KILL_ROUTE OPTION # CAN BE USED AT A TIME SO DON'T UNCOMMENT MULTIPLE LINES. # # NOTE: The route commands are the least optimal way of blocking # and do not provide complete protection against UDP attacks and # will still generate alarms for both UDP and stealth scans. I # always recommend you use a packet filter because they are made # for this purpose. # # Generic #KILL_ROUTE="/sbin/route add $TARGET$ 333.444.555.666" # Generic Linux #KILL_ROUTE="/sbin/route add -host $TARGET$ gw 333.444.555.666" # Newer versions of Linux support the reject flag now. This # is cleaner than the above option. KILL_ROUTE="/sbin/route add -host $TARGET$ reject" # Generic BSD (BSDI, OpenBSD, NetBSD, FreeBSD) #KILL_ROUTE="/sbin/route add $TARGET$ 333.444.555.666" # Generic Sun #KILL_ROUTE="/usr/sbin/route add $TARGET$ 333.444.555.666 1" # NEXTSTEP #KILL_ROUTE="/usr/etc/route add $TARGET$ 127.0.0.1 1" # FreeBSD (Not well tested.) #KILL_ROUTE="route add -net $TARGET$ -netmask 255.255.255.255 127.0.0.1 -blackhole" # Digital UNIX 4.0D (OSF/1 / Compaq Tru64 UNIX) #KILL_ROUTE="/sbin/route add -host -blackhole $TARGET$ 127.0.0.1" # Generic HP-UX #KILL_ROUTE="/usr/sbin/route add net $TARGET$ netmask 255.255.255.0 127.0.0.1" ## # Using a packet filter is the preferred method. The below lines # work well on many OS's. Remember, you can only uncomment *one* # KILL_ROUTE option. ## ############### # TCP Wrappers# ############### # This text will be dropped into the hosts.deny file for wrappers # to use. There are two formats for TCP wrappers: # # Format One: Old Style - The default when extended host processing # options are not enabled. # KILL_HOSTS_DENY="ALL: $TARGET$" # # Format Two: New Style - The format used when extended option # processing is enabled. You can drop in extended processing # options, but be sure you escape all '%' symbols with a backslash # to prevent problems writing out (i.e. \%c \%h ) # #KILL_HOSTS_DENY="ALL: $TARGET$ : DENY" ################### # External Command# ################### # This is a command that is run when a host connects, it can be whatever # you want it to be (pager, etc.). This command is executed before the # route is dropped. I NEVER RECOMMEND YOU PUT IN RETALIATORY ACTIONS # AGAINST THE HOST SCANNING YOU. TCP/IP is an *unauthenticated protocol* # and people can make scans appear out of thin air. The only time it # is reasonably safe (and I *never* think it is reasonable) to run # reverse probe scripts is when using the "classic" -tcp mode. This # mode requires a full connect and is very hard to spoof. # #KILL_RUN_CMD="/some/path/here/script $TARGET$ $PORT$" ##################### # Scan trigger value# ##################### # Enter in the number of port connects you will allow before an # alarm is given. The default is 0 which will react immediately. # A value of 1 or 2 will reduce false alarms. Anything higher is # probably not necessary. This value must always be specified, but # generally can be left at 0. # # NOTE: If you are using the advanced detection option you need to # be careful that you don't make a hair trigger situation. Because # Advanced mode will react for *any* host connecting to a non-used # below your specified range, you have the opportunity to really # break things. (i.e someone innocently tries to connect to you via # SSL [TCP port 443] and you immediately block them). Some of you # may even want this though. Just be careful. # SCAN_TRIGGER="0" ###################### # Port Banner Section# ###################### # # Enter text in here you want displayed to a person tripping the PortSentry. # I *don't* recommend taunting the person as this will aggravate them. # Leave this commented out to disable the feature # # Stealth scan detection modes don't use this feature # PORT_BANNER="** UNAUTHORIZED ACCESS PROHIBITED *** YOUR CONNECTION ATTEMPT HAS BEEN LOGGED. GO AWAY." # EOF Now, we must check/change its default permission for security reasons: [root@deep] /#chmod 600 /usr/psionic/portsentry/portsentry.conf You need to configure the /usr/psionic/portsentry/portsentry.ignore file, where you add in any host you want to have ignored if it connects to a tripwired port. This should always contain at least the localhost 127.0.0.1 and the IP's of the local interfaces lo. It is not recommend that you put in every IP on your network. Edit the portsentry.ignore file, vi /usr/psionic/ portsentry.ignore and add in any host you want to have ignored if it connects to a tripwired port: # Put hosts in here you never want blocked. This includes the IP addresses # of all local interfaces on the protected host (i.e virtual host, mult-home) # Keep 127.0.0.1 and 0.0.0.0 to keep people from playing games. 127.0.0.1 0.0.0.0 Now, we must check/change its default permission for security reasons: [root@deep] /#chmod 600 /usr/psionic/portsentry/portsentry.ignore 7. Test fire your PortSentry The PortSentry program can be configured in six different modes of operation, but be aware that only one protocol mode type can be started at a time. To be more accurate, you can start one TCP mode and one UDP mode, so two TCP modes and one UDP modes, for example, doesn't work. The available modes are: portsentry -tcp basic port-bound TCP mode portsentry -udp basic port-bound UDP mode portsentry -stcp Stealth TCP scan detection portsentry -atcp Advanced TCP stealth scan detection portsentry -sudp Stealth UDP scan detection portsentry -audp Advanced Stealth UDP scan detection In my case I prefer to start TCP in Advanced TCP stealth scan detection protocol mode and UDP in Stealth UDP scan detection protocol mode. For information about the other protocol modes, please refer to the README.install and README.stealth file under the PortSentry source directory. For TCP mode I choose: -atcp Advanced TCP stealth scan detection mode With the Advanced TCP stealth scan detection mode -atcp protocol mode type, PortSentry will first check to see what ports you have running on your server, then remove these ports from monitoring and will begin watching the remaining ports. This is very powerful and reacts exceedingly quickly for port scanners. It also uses very little CPU time. For UDP mode I choose: -sudp Stealth UDP scan detection mode With the Stealth UDP scan detection mode -sudp protocol mode type, the UDP ports will be listed and then monitored. To start PortSentry in the two modes selected above, use the commands: [root@deep] /# /usr/psionic/portsentry/portsentry -atcp [root@deep] /# /usr/psionic/portsentry/portsentry -sudp Tip You can add the above lines to your /etc/rc.d/rc.local script file and PortSentry software will be automatically started if you reboot your system. These are the files Installed by Portsentry on your system: /usr/psionic /usr/psionic/portsentry /usr/psionic/portsentry/portsentry.conf /usr/psionic/portsentry/portsentry.ignore /usr/psionic/portsentry/portsentry Part 6. Software -Networking Two ducks! Abstract Linux being a product of the net revolution is a natural choice for a web server, mail server, a file and print server; if it is a part of your intranet environement, among various other roles it can perform superbly well. In this part we take a look at various avatars it can assume and serve your organisation for a long time to come. All distributions of linux whether be it RedHat or SuSe do provide in binary format tools/software for your linux to act as a Web server or a Mail server to mention a few, but the amount of advancements which happen in linux world are beyond the grasp of these companies for it to catch up. The situation is if something can be achieved, it will be done in shortest possible time hence we have used always source tarballs downloaded from the respective websites of the software(s) used as example in this book. This affords us the capability to configure, choose and optimise according to our needs. This part attempts to highlight the capablities of linux to act as a full fledged Web server, Mail server, a file and print server, as a B2B e-commerce point where the need of the hour is secure environement, etc. Enjoy! Table of Contents 15._Software_-Securities 1._OpenSSH 2._Configure_and_optimise_Openssh 3._Configure_the_/etc/ssh/ssh_config_file 4._Configure_the_/etc/ssh/sshd_config_file 5._Configure_OpenSSH_to_use_TCP-Wrappers/inetd_super_server 6._OpenSSH_Per-User_Configuration 7._OpenSSH_Users_Tools 7.1._scp 8._Installed_files 8.1._Free_SSH_clients_for_Windows 16._Software_-Securties(commercial) 1._Linux_SSH2_Client/Server 2._Configure_and_Optimise_SSH2 3._Configure_the_/etc/ssh2/ssh2_config_file 4._Configure_the_/etc/ssh2/sshd2_config_file 5._Configure_sshd2_to_use_tcp-wrappers/inetd_super_server 6._Configuration_of_the_/etc/pam.d/ssh_file 7._Ssh2_Per-User_Configuration 8._SSH2_Users_Tools 9._Installed_files 17._Software_-Securities/System_Integrity 1._Linux_Tripwire_2.2.1 2._Configure_the_/var/tmp/install.cfg_file 3._Configuration_files 4._Configure_the_/usr/TSS/policy/twpol.txt_file 5._Securing_Tripwire_for_Linux 5.1._Often_used_Commands 6._Integrity_or_Interactive_Check_Mode 7._Installed_files 18._Linux_Tripwire_ASR_1.3.1 1._Install,_Compile_and_Optimize 2._Configurations 3._Configure_the_/etc/tw.config_file 4._Configure_the_/etc/cron.daily/tripwire.verify_script 4.1._Security_Issue 5._Tripwire_in_Interactive_Checking_Mode 6._Run_Tripwire_in_Database_Update_Mode 6.1._Installed_Files 19._Software_-Securities/Management_&_Limitation 1._Linux_GnuPG 2._Often_used_Commands 3._Importing_keys 3.1._Key_signing 4._Encrypt_and_decrypt 4.1._Exporting_your_public_key 20._Set_Limits_using_Qouta 1._Qouta 1.1._Modify_the_/etc/fstab_file 2._Create_of_the_quota.user_and_quota.group 3._edquota 3.1._The_grace_period_parameter 4._Assign_quota_for_a_particular_group 4.1._Assign_quota_for_groups_of_users_with_the_same_value 5._Often_used_Commands 21._Software_-Networking 1._Linux_DNS_and_BIND_Server 2._Configure 3._Caching-only_name_Server 4._Primary_master_name_Server 5._Secondary_slave_name_Server 5.1._/etc/rc.d/init.d/named_script 6._Run_ISC_BIND/DNS_in_a_chroot_jail 7._The_syslog_daemon 8._Clean-up_and_Test_the_new_chrooted_jail 9._DNS_Administrative_Tools 10._DNS_Users_Tools 11._Installed_files 22._Software_-Server/Mail_Network 1._Linux_Sendmail_Server 2._Compile_and_optimize 3._Configurations 4._The_/etc/sendmail.mc_file_/Central_Mail_Hub 5._Build_and_Tweak_Sendmail 5.1._The_null.mc_file 6._The_/etc/mail/access_and_access.db_files 7._The_/etc/mail/aliases_and_aliases.db_files 7.1._The_/etc/mail/_Directory 8._The_/etc/mail/local-host-names_file 8.1._Configure_the_/etc/sysconfig/sendmail_file 9._The_/etc/rc.d/init.d/sendmail_script_file 10._Secure_Sendmail_using_smrsh 11._The_/etc/mail/aliases_file 12._Limit_queue_processing_to_root 12.1._The_SMTP_greeting_message 13._Sendmail_Administrative_Tools 13.1._Sendmail_Users_Tools 14._Installed_files:_Sendmail_-Central_Mail_Hub 15._Installed_files:_Sendmail_-Local_server/client 23._Linux_IMAP_&_POP_Server 1._Configure_and_Compile 2._Configure_to_tweak 2.1._The_/etc/pam.d/imap_file 3._Enable_IMAP_or_POP_via_the_tcp-wrappers_inetd_super_server 3.1._Securing_IMAP/POP 4._Installed_files 24._Software_-Networking/Encryption 1._Linux_OPENSSL_Server 2._Compile_and_Optimize 3._Configure_OpenSSL_to_optimise 4._The_/etc/ssl/openssl.cnf_file 5._Create_the_/usr/bin/sign.sh_program_file 6._Commands_-often_used 7._Securing_OpenSSL 8._Installed_files 25._Linux_FreeS/WAN_VPN 1._IPSEC/VPN_-FreeS/WAN 2._Compile,_insert_FreeS/WAN_into_the_kernel 3._Reconfigure_and_install_the_kernel_with_FreeS/WAN_VPN_support 4._Configure_to_optimise 5._Automatic_or_Manual_Key_connections 6._The_/etc/ipsec.conf_file 7._The_/etc/ipsec.secrets_file 8._Configure_RSA_private_keys_secrets 9._Required_network_setup_for_IPSec 10._Testing_the_installation 11._Further_documentation 12._Installed_files 26._Linux_OpenLDAP_Server 1._Compile_ans_Install 2._Compile_and_Optimize 3._Configurations 4._Configure_the_/etc/ldap/slapd.conf_file 5._Configure_the_/etc/rc.d/init.d/ldap_script_file 6._Securing_OpenLDAP 7._OpenLDAP_Creation_and_Maintenance_Tools 7.1._LDMB_backend_database_off-line 8._Create_the_LDMB_backend_database_on-line 8.1._ldapmodify 9._OpenLDAP_Users_Tools 9.1._The_Netscape_Address_Book_client_for_LDAP 10._Installed_files 27._Linux_PostgreSQL_Database_Server 1._Install_PostgreSQL 2._Compile_and_Optimize 3._Database_installation_using_superuser_account 4._Configuration_files 5._Configure_the_/etc/rc.d/init.d/postgresql_script_file 6._Commands_often_used 7._Installed_files 28._Software_-Server/Proxy_Network 1._Linux_Squid_Proxy_Server 2._Configure_and_Optimize 3._Improve_performance_Using_GNU_malloc_library 4._Compile_and_Optimize 5._Configurations 6._Configure_the_/etc/squid/squid.conf_file_-in_httpd-accelerator_mode 7._Configure_of_the_/etc/squid/squid.conf_file_-/proxy-caching_mode 8._Configure_the_/etc/rc.d/init.d/squid_script_file_-/all configurations 9._Configure_the_/etc/logrotate.d/squid_file 9.1._Securing_and_Immunize_Squid 10._Optimizing_Squid 10.1._The_cachemgr.cgi 11._Netscape_Proxies_Configuration 12._Installed_files 29._Software_-Network_Server,_web/Apache 1._Linux_MM_Shared_Memory_Library 2._Compile 2.1._Installed_files 3._Linux_Apache_Web_Server 4._Compile_and_Optimize 5._Configure_and_apply_PHP4_to_Apache_source 6._Apply_mod_perl_to_Apache_source_tree 7._Install_Apache 8._Post_install_Configuration 9._Configure_the_/etc/httpd/conf/httpd.conf_file 10._Configure_the_/etc/logrotate.d/apache_file 11._Configure_the_/etc/rc.d/init.d/httpd_script_file 12._PHP4_server-side_scripting 13._Perl_module_Devel::Symdump 13.1._Installed_files 14._CGI.pm_Perl_library 14.1._Installed_files 15._Securing_Apache 16._users_authentication_with_.dbmpasswd_password_file 16.1._Immunize_configuration_files_like_httpd.conf 17._Apache_in_a_chroot_jail 18._Apache_to_use_shared_libraries 19._The_/chroot/etc_directory 20._Test_the_new_chrooted_jail 21._Configure_the_new_/etc/logrotate.d/apache_file 22._Optimizing_Apache 23._Installed_files_for_Apache_Web_Server 24._Installed_files_/PHP4 25._Installed_files_by_mod_perl 30._Optional_component_to_install_with_Apache 1._Linux_Webalizer 2._Compile 2.1._Configurations 3._Configure_the_/etc/webalizer.conf_file 4._Make_Apache_aware_of_Webalizer_output_directory 4.1._Running_Webalizer_manually_first_time 5._Run_Webalizer_automatically_with_a_cron_job 5.1._Installed_files 6._Linux_FAQ-O-Matic 7._Compile_and_install_FAQ-O-Matic 8._Make_Apache_aware_Faq-O-Matic_file's_location 9._Configure_your_FAQ-O-Matic 10._Installed_files 11._Linux_Webmail_IMP 12._Set_up_PHPLib 13._Compile_to_install_Webmail_IMP 14._Configure_and_create_Webmail_IMP_SQL_database 15._Configure_your_php.ini_from_PHP4 15.1._Configure_Apache_to_recognize_Webmail_IMP 16._Configure_Webmail_IMP_via_your_web_browser 31._Software_-Server/File_Sharing-Network 1._Linux_Samba_Server 2._Configure_Samba 3._Compile_and_optimize 4._Configurations 5._Configuration_of_the_/etc/smb.conf_file 6._Configure_the_/etc/lmhosts_file 6.1._Configure_the_/etc/pam.d/samba_file 7._Encrypted_Samba_password_file_for_clients 8._Optimizing_Samba 8.1._Tuning_the_buffer_cache 9._Tuning_the_buffermem 10._Further_documentation 11._Samba_Administrative_Tools 11.1._Samba_Users_Tools 12._The_/etc/rc.d/init.d/smb_script_file 12.1._Securing_Samba 13._Installed_files 32._Linux_FTP_Server 1._chroot'd_Guest_FTP_access 2._Setup_an_FTP_user_account_minus_shells 3._Setup_a_chroot_user_environment 4._Configurations 5._Configure_the_/etc/ftphosts_file 5.1._Configure_the_/etc/ftpusers_file 6._Configure_the_/etc/ftpconversions_file 6.1._Configure_the_/etc/pam.d/ftp_file 7._Configure_the_/etc/logrotate.d/ftpd_file 7.1._Configure_ftpd_to_use_tcp-wrappers_inetd 8._FTP_Administrative_Tools 9._Securing_FTP 10._The_special_file_.notar 11._Installed_files Chapter 15. Software -Securities Table of Contents 1._OpenSSH 2._Configure_and_optimise_Openssh 3._Configure_the_/etc/ssh/ssh_config_file 4._Configure_the_/etc/ssh/sshd_config_file 5._Configure_OpenSSH_to_use_TCP-Wrappers/inetd_super_server 6._OpenSSH_Per-User_Configuration 7._OpenSSH_Users_Tools 7.1._scp 8._Installed_files 8.1._Free_SSH_clients_for_Windows As illustrated in Installation_of_your_Linux_Server, many network services including, but not limited, to telnet, rsh, rlogin, or rexec are vulnerable to electronic eavesdropping. As a consequence, anyone who has access to any machine connected to the network can listen in on their communication and get your password, as well as any other private information that goes over the network in plain text. Currently the Telnet program is indispensable for daily administration task, but is insecure since it transmits your password in plain text over the network and allows any listener to thereby use your account to do anything he likes. To solve this problem we must find another way, or program, to replace it. Fortunately OpenSSH is a truly seamless and secure replacement of old, insecure and obsolete remote login programs such as telnet, rlogin, rsh, rdist, or rcp. 1. OpenSSH The official [OpenSSH README] file says: Ssh Secure Shell is a program to log into another computer over a network, to execute commands in a remote machine, and to move files from one machine to another. It provides strong authentication and secure communications over insecure channels. It is intended as a replacement for rlogin, rsh, rcp, and rdist. In our configuration we have configured OpenSSH to support tcp-wrappers; the inetd super server, to improve the security of this already secure program and to avoid always running its daemon in the background of the server. This way, the program will run only when client connections arrive and will redirect them through the TCP-WRAPPERS daemon for authentication and authorization before allowing the connection in the server. OpenSSH is a free replacement and improvement of SSH1 with all patent- encumbered algorithms removed to external libraries, all known security bugs fixed, new features reintroduced and many other clean-ups. It is recommended that you use OpenSSH free and security bug fixed instead of SSH1 free, buggy, and old or SSH2 that was originally free but now under a commercial license. For peoples that use SSH2 from Datafellows Company, we'll provide in this book both versions, beginning with OpenSSH, since it is the new SSH program which everyone, we suggest, must move to in the future. These installation instructions assume: * Commands are Unix-compatible. * The source path is /var/tmp -other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * OpenSSH version number is 1.2.3 These are the Packages you can download from OpenSSH Homepage:http:// www.openssh.com and be sure to download: openssh-1.2.3.tar.gz as of this writing There are some Prerequisites you need to take care of before installing OpenSSH since it requires that the zlib-devel package, which contains the header files and libraries needed to develop programs that use the zlib compression and decompression library, be already installed on your system. If this is not the case, you must install it from your Red Hat Linux 6.1 or 6.2 CD-ROM. To verify that the zlib-devel package is installed on your Linux system, use the following command: [root@deep] /#rpm -qi zlib-devel          package zlib-devel is not installed           To install the zlib-devel package on your Linux system, use the following command: [root@deep] /#mount /dev/cdrom /mnt/cdrom/ [root@deep] /#cd /mnt/cdrom/RedHat/RPMS/ [root@deep ]/RPMS#rpm -Uvh zlib-devel-version.i386.rpm          gd                          ##################################################           [root@deep ]/RPMS#rpm -Uvh gd-devel-version.i386.rpm          zlib- devel                  ##################################################           [root@deep ]/RPMS# cd /; umount /mnt/cdrom/ Important OpenSSL, which enables support for SSL functionality, must already be installed on your system to be able to use the OpenSSH software.For more information on OpenSSL server, see its related chapter in this book. Even if you don't need to use OpenSSL software to create or hold encrypted key files, it's important to note that OpenSSH program require its libraries files to be able to work properly on your system. you need to decompress and unpack the Tarballs but it is a good idea to make a list of files on the system before you install OpenSSH, and one afterwards, and then compare them using diff to find out what files it placed where. Simply run find/* > OpenSSH1 before and find/* > OpenSSH2 after you install the software, and use diff OpenSSH1 OpenSSH2 > OpenSSH-Installed to get a list of what changed. To Compile,Decompress the tarball tar.gz and: [root@deep] /#cp openssh-version.tar.gz /var/tmp [root@deep] /#cd /var/tmp [root@deep ]/tmp#tar xzpf openssh-version.tar.gz You need to Compile and Optimize: 1. Move into the new OpenSSH directory and type the following commands on your terminal: CC="egcs" \ CFLAGS="-O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions" \ ./configure \ --prefix=/usr \ --sysconfdir=/etc/ssh \ --with-tcp-wrappers \ --with-ipv4-default \ --with-ssl-dir=/usr/include/openssl This tells OpenSSH to set itself up for this particular hardware setup with: - Compiled-in libwrap and enabled TCP Wrappers /etc/hosts.allow|deny support. - Disabled long delays in name resolution under Linux/glibc-2.1.2 to improve connection time. - Specified locations of OpenSSL libraries required by OpenSSH program to work. 2. Now, we must compile and install OpenSSH on the Server: [root@deep ]/openssh-1.2.3#make [root@deep ]/openssh-1.2.3#make install [root@deep ]/openssh-1.2.3#make host-key [root@deep ]/openssh-1.2.3#install -m644 contrib/redhat/ sshd.pam /etc/pam.d/sshd make command will compile all source files into executable binaries, make install will install the binaries and any supporting files into the appropriate locations. make host-key command will generate a host key. install command will install the PAM support for Red Hat Linux, which is now more functional than the popular packages of commercial ssh-1.2.x. 3. please do a Cleanup later: [root@deep] /#cd /var/tmp [root@deep ]/tmp#rm -rf openssh-version/ openssh-version.tar.gz The rm command as used above will remove all the source files we have used to compile and install OpenSSH. It will also remove the OpenSSH compressed archive from the /var/tmp directory. 2. Configure and optimise Openssh Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example Openssh configuration file are organised like this: total 16 -rw-r--r-- 1 harrypotter harrypotter 275 Jun 8 13:00 Compile-OpenSSH drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 pam.d/ -rw-r--r-- 1 harrypotter harrypotter 372 Jun 8 13:00 ssh_config -rw-r--r-- 1 harrypotter harrypotter 467 Jun 8 13:00 sshd_config You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run OpenSSH Client/Server, the following files are required and must be created or copied to the appropriate directories on your server. * Copy the ssh_config file to the /etc/ssh/ directory. * Copy the sshd_config file to the /etc/ssh/ directory. * Copy the sshd file to the /etc/pam.d/ directory. Tip You can obtain the configuration files listed in the next sections on our floppy.tgz archive. Copy the following files from the decompressed floppy.tgz archive to the appropriate places, or copy them directly from this book to the concerned file. 3. Configure the /etc/ssh/ssh_config file The /etc/ssh/ssh_config file is the system-wide configuration file for OpenSSH which allows you to set options that modify the operation of the client programs. The file contains keyword-value pairs, one per line, with keywords being case insensitive. Here are the most important keywords to configure your ssh for top security; a complete listing and/or special requirements are available in the man page for ssh(1). Edit the ssh_config file, vi /etc/ssh/ssh_config and add/or change, if necessary the following parameters: # Site-wide defaults for various options Host * ForwardAgent no ForwardX11 no RhostsAuthentication no RhostsRSAAuthentication no RSAAuthentication yes PasswordAuthentication yes FallBackToRsh no UseRsh no BatchMode no CheckHostIP yes StrictHostKeyChecking no IdentityFile ~/.ssh/identity Port 22 Cipher blowfish EscapeChar ~ This tells ssh_config file to set itself up for this particular configuration setup with: Host * The option Host restricts all forwarded declarations and options in the configuration file to be only for those hosts that match one of the patterns given after the keyword. The pattern * means for all hosts up to the next Host keyword. With this option you can set different declarations for different hosts in the same ssh_config file. ForwardAgent no The option ForwardAgent specifies which connection authentication agent if any should be forwarded to the remote machine. ForwardX11 no The option ForwardX11 is for people that use the Xwindow GUI and want to automatically redirect X11 sessions to the remote machine. Since we setup a server and don't have GUI installed on it, we can safely turn this option off. RhostsAuthentication no The option RhostsAuthentication specifies whether we can try to use rhosts based authentication. Because rhosts authentication is insecure you shouldn't use this option. RhostsRSAAuthentication no The option RhostsRSAAuthentication specifies whether or not to try rhosts authentication in concert with RSA host authentication. RSAAuthentication yes The option RSAAuthentication specifies whether to try RSA authentication. This option must be set to yes for better security on your sessions. RSA uses public and private keys pair created with the ssh-keygen1utility for authentication purposes. PasswordAuthentication yes The option PasswordAuthentication specifies whether we should use password-based authentication. For strong security, this option must always be set to yes. FallBackToRsh no The option FallBackToRsh specifies that if a connection with ssh daemon fails rsh should automatically be used instead. Recalling that rsh service is insecure, this option must always be set to no. UseRsh no The option UseRsh specifies that rlogin/rsh services should be used on this host. As with the FallBackToRsh option, it must be set to no for obvious reasons. BatchMode no The option BatchMode specifies whether a username and password querying on connect will be disabled. This option is useful when you create scripts and dont want to supply the password. e.g. Scripts that use the scp command to make backups over the network. CheckHostIP yes The option CheckHostIP specifies whether or not ssh will additionally check the host IP address that connect to the server to detect DNS spoofing. It's recommended that you set this option to yes. StrictHostKeyChecking no The option StrictHostKeyChecking specifies whether or not ssh will automatically add new host keys to the $HOME/.ssh/known_hosts file, or never automatically add new host keys to the host file. This option, when set to yes, provides maximum protection against Trojan horse attacks. One interesting procedure with this option is to set it to no at the beginning, allow ssh to add automatically all common hosts to the host file as they are connected to, and then return to set it to yes to take advantage of this feature. IdentityFile ~/.ssh/identity The option IdentityFile specifies an alternate RSA authentication identity file to read. Also, multiple identity files may be specified in the configuration file ssh_config. Port 22 The option Port specifies on which port number ssh connects to on the remote host. The default port is 22. Cipher blowfish The option Cipher specifies what cipher should be used for encrypting sessios. The blowfish use 64-bit blocks and keys of up to 448 bits. EscapeChar ~ The option EscapeChar specifies the session escape character for suspension. 4. Configure the /etc/ssh/sshd_config file The /etc/ssh/sshd_config file is the system-wide configuration file for OpenSSH which allows you to set options that modify the operation of the daemon. This file contains keyword-value pairs, one per line, with keywords being case insensitive. Here are the most important keywords to configure your sshd for top security; a complete listing and/or special requirements are available in the man page for sshd(8). Edit the sshd_config file, vi /etc/ssh/sshd_config and add/or change, if necessary, the following parameters: # This is ssh server systemwide configuration file. Port 22 ListenAddress 192.168.1.1 HostKey /etc/ssh/ssh_host_key ServerKeyBits 1024 LoginGraceTime 600 KeyRegenerationInterval 3600 PermitRootLogin no IgnoreRhosts yes IgnoreUserKnownHosts yes StrictModes yes X11Forwarding no PrintMotd yes SyslogFacility AUTH LogLevel INFO RhostsAuthentication no RhostsRSAAuthentication no RSAAuthentication yes PasswordAuthentication yes PermitEmptyPasswords no AllowUsers admin This tells sshd_config file to set itself up for this particular configuration setup with: Port 22 The option Port specifies on which port number ssh daemon listens for incoming connections. The default port is 22. ListenAddress 192.168.1.1 The option ListenAddress specifies the IP address of the interface network on which the ssh daemon server socket is bind. The default is 0.0.0.0; to improve security you may specify only the required ones to limit possible addresses. HostKey /etc/ssh/ssh_host_key The option HostKey specifies the location containing the private host key. ServerKeyBits 1024 The option ServerKeyBits specifies how many bits to use in the server key. These bits are used when the daemon starts to generate its RSA key. LoginGraceTime 600 The option LoginGraceTime specifies how long in seconds after a connection request the server will wait before disconnecting if the user has not successfully logged in. KeyRegenerationInterval 3600 The option KeyRegenerationInterval specifies how long in seconds the server should wait before automatically regenerated its key. This is a security feature to prevent decrypting captured sessions. PermitRootLogin no The option PermitRootLogin specifies whether root can log in using ssh. Never say yes to this option. IgnoreRhosts yes The option IgnoreRhosts specifies whether rhosts or shosts files should not be used in authentication. For security reasons it is recommended to no use rhosts or shosts files for authentication. IgnoreUserKnownHosts yes The option IgnoreUserKnownHosts specifies whether the ssh daemon should ignore the user's $HOME/.ssh/known_hosts during RhostsRSAAuthentication. StrictModes yes The option StrictModes specifies whether ssh should check user's permissions in their home directory and rhosts files before accepting login. This option must always be set to yes because sometimes users may accidentally leave their directory or files world-writable. X11Forwarding no The option X11Forwarding specifies whether X11 forwarding should be enabled or not on this server. Since we setup a server without GUI installed on it, we can safely turn this option off. PrintMotd yes The option PrintMotd specifies whether the ssh daemon should print the contents of the /etc/motd file when a user logs in interactively. The / etc/motd file is also known as the message of the day. SyslogFacility AUTH The option SyslogFacility specifies the facility code used when logging messages from sshd. The facility specifies the subsystem that produced the message--in our case, AUTH. LogLevel INFO The option LogLevel specifies the level that is used when logging messages from sshd. INFO is a good choice. See the man page for sshd for more information on other possibilities. RhostsAuthentication no The option RhostsAuthentication specifies whether sshd can try to use rhosts based authentication. Because rhosts authentication is insecure you shouldn't use this option. RhostsRSAAuthentication no The option RhostsRSAAuthentication specifies whether to try rhosts authentication in concert with RSA host authentication. RSAAuthentication yes The option RSAAuthentication specifies whether to try RSA authentication. This option must be set to yes for better security in your sessions. RSA use public and private key pairs created with the ssh-keygen1utility for authentication purposes. PasswordAuthentication yes The option PasswordAuthentication specifies whether we should use password-based authentication. For strong security, this option must always be set to yes. PermitEmptyPasswords no The option PermitEmptyPasswords specifies whether the server allows logging in to accounts with a null password. If you intend to use the scp utility to make automatic backups over the network, you must set this option to yes. AllowUsers admin The option AllowUsers specifies and controls which users can access ssh services. Multiple users can be specified, separated by spaces. 5. Configure OpenSSH to use TCP-Wrappers/inetd super server Tcp-Wrappers should be enabled to start and stop our OpenSSH server. Upon execution, inetd reads its configuration information from a configuration file which, by default, is /etc/inetd.conf. There must be an entry for each field of the configuration file, with entries for each field separated by a tab or a space. 1. Edit the inetd.conf file vi /etc/inetd.conf and add the line: ssh stream tcp nowait root /usr/sbin/tcpd sshd -i Important The -i parameter is important since it's specifies that sshd is being run from inetd. Also, update your inetd.conf file by sending a SIGHUP signal killall-HUP inetd after adding the above line to the file. To update your inetd.conf file, use the following command: [root@deep] /#killall -HUP inetd 2. Edit the hosts.allow file, vi /etc/hosts.allow and add the line: sshd: 192.168.1.4 win.openna.com Which mean client IP 192.168.1.4 with host name win.openna.com is allowed to ssh in to the server. These daemon strings for tcp-wrappers are in use by sshd: sshdfwd-X11 if you want to allow/deny X11-forwarding sshdfwd- for tcp-forwarding sshdfwd- port-name defined in /etc/services. Used in tcp-forwarding Tip If you do decide to switch to using ssh, make sure you install and use it on all your servers. Having ten secure servers and one insecure is a waste of time. For more details, there are several man pages you can read: ssh(1) OpenSSH secure shell client remote login program ssh [slogin](1) OpenSSH secure shell client remote login program ssh-add(1) adds identities for the authentication agent ssh-agent(1) authentication agent ssh-keygen(1) authentication key generation sshd(8) secure shell daemon 6. OpenSSH Per-User Configuration 1. Create your private & public keys of local, by executing: [root@deep] /#su admin [admin@deep /]$ssh-keygen The result should look like the following example: Initializing random number generator... Generating p: ............................++ (distance 430) Generating q: ......................++ (distance 456) Computing the keys... Testing the keys... Key generation complete. Enter file in which to save the key (/home/admin/.ssh/ identity): [Press Enter] Enter passphrase: Enter the same passphrase again: Your identification has been saved in /home/admin/.ssh/ identity. Your public key is: 1024 37 14937757511251955533691120318477293862290049394715136511145806108870001764378494676831297577843158532 2723612061006231460440536487184367748423324091941848098890786099717524446977589647127757030728779973708569993 017043141563536333068888944038178461608592483844590202154102756903055846534063365635584899765402181 admin@deep.openna.com Your public key has been saved in /home/admin/.ssh/ identity.pub Note If you have multiple accounts you might want to create a separate key on each of them. You may want to have separate keys for: o Your Mail server o Your Web server o Your GW server This allows you to limit access between these servers, e.g. not allowing the Mail account to access your Web account or the machines in the GW. This enhances the overall security in the case any of your authentication keys are compromised for any reason. 2. Copy your local public keys identity.pub to the /home/admin/.ssh directory remotely under the name, say, authorized_keys. Tip One way to copy the file is to use the ftp command or you might need to send your public key in electronic mail to the administrator of the system. Just include the contents of the ~/.ssh/identity.pub file in the message. You might feel the need to Change your pass-phrase for various reason and can do so at any time by using the -p option of ssh-keygen. To change the pass- phrase, use the command: [root@deep] /#su admin [admin@deep /]$ssh-keygen -p Enter file key is in /home/admin/.ssh/identity: [Press ENTER] Enter old passphrase: Key has comment 'admin@deep.openna.com' Enter new passphrase: Enter the same passphrase again: Your identification has been saved with the new passphrase. 7. OpenSSH Users Tools The commands listed belows are some that we use often in our regular use, but many more exist, and you should check the man page and documentation for more details. The ssh Secure Shell command provides secure encrypted communications between two untrusted hosts over an insecure network. It is a program for logging securely into a remote machine and executing commands from there. It is a suitable replacement for insecure programs like telnet, rlogin, rcp, rdist, and rsh. To login to a remote machine, use the command: [root@deep] /#ssh -l Example 15.1. Remote login using ssh [root@deep] /#ssh -l admin www.openna.com admin@deep.openna.coms password: Last login: Tue Oct 19 1999 18:13:00 -0400 from deep.openna.com No mail. [admin@www ]/admin$ Where is the name you use to connect to the ssh server and is the remote address of your ssh server. 7.1. scp The scp Secure Copy utility copies files from the local system to a remote system or vice versa, or even between two remote systems using the scp command. To copy files from remote to local system, use the following command: [root@deep] /#su admin [admin@deep /]$scp -p :/dir/for/file localdir/ to/filelocation Example 15.2. scp Secure Copy utility [admin@deep /]$ scp1 -p admin@mail:/etc/test1 /tmp           Enter passphrase for RSA key 'admin@mail.openna.com':           test1                       |          2 KB |   2.0 kB/s | ETA: 00: 00:00 | 100%            To copy files from local to remote system, use the following command: [root@deep] /#su admin [admin@deep /]$scp -p localdir/to/filelocation : /dir/for/file Example 15.3. local to remote [admin@deep /]$scp1 -p /usr/bin/test2 admin@mail:/var/tmp           admin@mail's password:           test2                     |          7 KB |   7.9 kB/s | ETA: 00:00: 00 | 100%            Tip The -p option indicates that the modification and access times, as well as modes of the source file, should be preserved on the copy. This is usually desirable. Some possible uses of OpenSSH softwareare: 1. Replace telnet, rlogin, rsh, rdist, and rcp. 2. Make secure backups over the network. 3. Execute remote commands. 4. Access to corporate resources over the Internet. 8. Installed files These are files Installed by the software program Openssh: /etc/ssh /usr/bin/slogin /etc/ssh/ssh_config /usr/man/man1/ssh.1 /etc/ssh/sshd_config /usr/man/man1/scp.1 /etc/ssh_host_key /usr/man/man1/ssh-add.1 /etc/ssh_host_key.pub /usr/man/man1/ssh-agent.1 /usr/bin/ssh /usr/man/man1/ssh-keygen.1 /usr/bin/scp /usr/man/man1/slogin.1 /usr/bin/ssh-add /usr/man/man8/sshd.8 /usr/bin/ssh-agent /usr/sbin/sshd /usr/bin/ssh-keygen   8.1. Free SSH clients for Windows Check out this free SSH clients for windows; so that you can provide the same services on your windows machine, if your networked environement is likely to have windows indtalled machines. Putty.  And this is Putty Homepage:http://www.chiark.greenend.org.uk/~sgtatham/ putty.html Tera Term Pro and TTSSH.  The Tera Term Pro can be found here on its Homepage: http://hp.vector.co.jp/authors/VA002416/teraterm.html, and TTSSH Homepage is: http://www.zip.com.au/~roca/download.html. Chapter 16. Software -Securties(commercial) Table of Contents 1._Linux_SSH2_Client/Server 2._Configure_and_Optimise_SSH2 3._Configure_the_/etc/ssh2/ssh2_config_file 4._Configure_the_/etc/ssh2/sshd2_config_file 5._Configure_sshd2_to_use_tcp-wrappers/inetd_super_server 6._Configuration_of_the_/etc/pam.d/ssh_file 7._Ssh2_Per-User_Configuration 8._SSH2_Users_Tools 9._Installed_files Its now clear that all Linux users must use OpenSSH instead of SSH2 from Datafellows Company. However, for the users or organizations that want to use the non-free version of this software, we provide here steps to follow. This is the SSH2 commercial version of SSH software. In our configuration we have also configured sshd2 to support tcp-wrappers the inetd super server for security reason. 1. Linux SSH2 Client/Server Since Linux is all about choices we have provided as an alternative the commercial verion of OpenSSH, The SSH2 and these installation instructions assume * Commands are Unix-compatible. * The source path is /var/tmp, other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * SSH2 version number is 2.0.13 Packages that you need can be downloaded from: SSH2 Homepage:http://www.ssh.org/ You must be sure to download: ssh-2.0.13.tar.gz once you have got the Tarballs, It is a good idea to make a list of files on the system before you install ssh2, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > SSH1 before and find /* > SSH2 after you install the software, and use diff SSH1 SSH2 > SSH-Installed to get a list of what changed. Before you Compile, you need to decompress the tarball tar.gz. [root@deep] /#cp ssh-version.tar.gz /var/tmp [root@deep] /#cd /var/tmp [root@deep ]/tmp#tar xzpf ssh-version.tar.gz You need to Compile and Optimize so move into the new SSH2 directory and type the following commands on your terminal: CC="egcs" \ CFLAGS="-O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions" \ ./configure \ --prefix=/usr \ --without-ssh-agent1-compat \ --disable-suid-ssh-signer \ --disable-tcp-port-forwarding \ --disable-X11-forwarding \ --enable-tcp-nodelay \ --with-libwrap This tells SSH2 to set itself up for this particular hardware setup as follows: * Leave out ssh-agent1 compatibility. * Install ssh-signer without suid bit. * Disable port forwarding support. * Disable X11 forwarding support. * Enable TCP_NODELAY socket option. * Compile in libwrap tcp_wrappers support. [root@deep ]/ssh-2.0.13#make clean [root@deep ]/ssh-2.0.13# make [root@deep ]/ssh-2.0.13# make install [root@deep ]/ssh-2.0.13#rm -f /usr/bin/ssh-askpass The make clean, command erase all previous traces of a compilation so as to avoid any mistakes, The make command compiles all source files into executable binaries, The make install command installs the binaries and any supporting files into the appropriate locations. Please don't forget to cleanup after work: [root@deep] /#cd /var/tmp [root@deep ]/tmp#rm -rf ssh-version/ ssh-version.tar.gz The rm command as used above will remove all the source files we have used to compile and install SSH2. It will also remove the SSH2 compressed archive from the /var/tmp directory. 2. Configure and Optimise SSH2 Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example SSH2 configuration file are organised like this: total 16 -rw-r--r-- 1 harrypotter harrypotter 326 Jun 8 13:00 Compile-SSH2 drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 pam.d/ -rw-r--r-- 1 harrypotter harrypotter 462 Jun 8 13:00 ssh2_config -rw-r--r-- 1 harrypotter harrypotter 799 Jun 8 13:00 sshd2_config You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run the SSH2 Client/Server, the following files are required, and must be created or copied to the appropriate directories on your server. * Copy the sshd2_config file to the /etc/ssh2/ directory. * Copy the ssh2_config file to the /etc/ssh2/ directory. * Copy the ssh file to the /etc/pam.d/ directory. Tip You can obtain the configuration files listed in the following section on our floppy.tgz archive. Copy the following files from the decompressed floppy.tgz archive to the appropriate places, or copy them directly from this book to the concerned file. 3. Configure the /etc/ssh2/ssh2_config file The configuration file for ssh2 /etc/ssh2/ssh2_config allows you to set options that modify the operation of the client programs. The files contain keyword- value pairs, one per line, with keywords being case insensitive. Here are the more important keywords; a complete listing is available in the man page for ssh2(1). Edit the ssh2_config file, vi /etc/ssh2/ssh2_config and add or change, if necessary: # ssh2_config # SSH 2.0 Client Configuration File *:Port 22 Ciphers blowfish Compression yes IdentityFile identification AuthorizationFile authorization RandomSeedFile random_seed VerboseMode no ForwardAgent no ForwardX11 no PasswordPrompt "%U's password: " Ssh1Compatibility no Ssh1AgentCompatibility none NoDelay yes KeepAlive yes QuietMode no This tells ssh2_config file to set itself up for this particular configuration setup with: Port 22 The option Port specifies on which port number ssh connects to on the remote host. The default port is 22. Ciphers blowfish The option Ciphers specifies what cipher should be used for encrypting sessions. The blowfish uses 64-bit blocks and keys of up to 448 bits. Compression yes The option Compression specifies whether to use compression during sessions. Compression will improve communication speed and files transfers. IdentityFile identification The option IdentityFile specifies an alternate name for the user's identification file. AuthorizationFile authorization The option AuthorizationFile specifies an alternate name for the user's authorization file. RandomSeedFile random_seed The option RandomSeedFile specifies an alternate name for the user's random seed file. VerboseMode no The option VerboseMode instructs ssh2 to print debugging messages about its progress. This option is helpful in debugging connection, authentication, and configuration problems. ForwardAgent no The option ForwardAgent specifies which connection authentication agent if any should be forwarded to the remote machine. ForwardX11 no The option ForwardX11 is for people that use the Xwindow GUI and want to automatically redirect X11 sessions to the remote machine. Since we've set up a server and do not have a GUI installed on it, we can safely turn this option off. PasswordPrompt "%U's password: " The option PasswordPrompt specifies the password prompt that will be displayed for the user when connecting to a host. Variables %U and %H give the user's login name and host, respectively. Ssh1Compatibility no The option Ssh1Compatibility specifies whether or not to use SSH1 compatibility code with SSH2 for ssh1 users. Ssh1AgentCompatibility none The option Ssh1AgentCompatibility specifies whether or not to also forward SSH1 agent connections with SSH2 for ssh1 users. NoDelay yes The option NoDelay specifies if the socket option TCP_NODELAY should be enabled. It is recommended that you set this option to yes to improve network performance. KeepAlive yes The option KeepAlive specifies whether the system should send keep alive messages to the remote server. If set to yes then the death of the connection or crash of remote machines will be properly noticed. QuietMode no The option QuietMode specifies whether the system runs in quiet mode. This option must be set to no because in quiet mode, nothing is logged in the system log except for fatal errors. Since we want to have information about users sessions it is preferable to disable this option. 4. Configure the /etc/ssh2/sshd2_config file The configuration file for sshd2 /etc/ssh2/sshd2_config allows you to set options that modify the operation of the daemon. The files contain keyword- value pairs, one per line, with keywords being case insensitive. Here are the more important keywords; a complete listing is available in the man page for sshd2(8). Edit the sshd2_config file (vi /etc/ssh2/sshs2_config and add or change, if necessary: # sshd2_config # SSH 2.0 Server Configuration File *:Port 22 ListenAddress 192.168.1.1 Ciphers blowfish IdentityFile identification AuthorizationFile authorization HostKeyFile hostkey PublicHostKeyFile hostkey.pub RandomSeedFile random_seed ForwardAgent no ForwardX11 no PasswordGuesses 3 MaxConnections 5 PermitRootLogin no AllowedAuthentications publickey,password RequiredAuthentications publickey,password VerboseMode no PrintMotd yes CheckMail yes UserConfigDirectory "%D/.ssh2" SyslogFacility DAEMON Ssh1Compatibility no NoDelay yes KeepAlive yes UserKnownHosts yes AllowHosts 192.168.1.4 DenyHosts * QuietMode no # subsystem definitions subsystem-sftp sftp-server This tells sshd2_config file to set itself up for this particular configuration setup with: Port 22 The option Port specifies which port number the ssh2 daemon listens to for ssh incoming connection. The default port is 22. ListenAddress 192.168.1.1 The option ListenAddress specifies the IP address of the interface network on which the ssh2 daemon server socket is bound. The default is 0.0.0.0; to improve security you may specify only the required ones to limit possible addresses. Ciphers blowfish The option Ciphers specifies what cipher should be used for encrypting sessions. The blowfish uses 64-bit blocks and keys of up to 448 bits. IdentityFile identification The option IdentityFile specifies an alternate name for the user's identification file. AuthorizationFile authorization The option AuthorizationFile specifies an alternate name for the user's authorization file. HostKeyFile hostkey The option HostKeyFile specifies an alternate file containing the private host key. The default is /etc/ssh2/hostkey. PublicHostKeyFile hostkey.pub The option PublicHostKeyFile specifies an alternate file containing the public host key. The default is /etc/ssh2/hostkey.pub. RandomSeedFile random_seed The option RandomSeedFile specifies an alternate name for the user's random seed file. ForwardAgent no The option ForwardAgent specifies which connection authentication agent if any should be forwarded to the remote machine. ForwardX11 no The option ForwardX11 is for people that use the Xwindow GUI and want to automatically redirect X11 sessions to the remote machine. Since we set up a server and don't have a GUI installed on it, we can safely turn this option off. PasswordGuesses 3 The option PasswordGuesses specifies how many tries the user has when using password authentication. MaxConnections 5 The option MaxConnections specifies what the maximum number of connections that ssh2 daemon will handle simultaneously is. PermitRootLogin no The option PermitRootLogin specifies whether root can log in using ssh. Never say, yes to this option. AllowedAuthentications publickey,password The option AllowedAuthentications specifies which authentication methods are allowed to be used. With this option the administrator can force users to complete several authentications before they are considered authenticated. RequiredAuthentications publickey,password The option RequiredAuthentications related to AllowedAuthentications, specifies which authentication methods the users must complete before continuing. This parameter must be the same as for the AllowedAuthentications option or the server will denies connection every time. VerboseMode no The option VerboseMode instructs the ssh2 daemon to print debugging messages about its progress. This option is helpful in debugging connection, authentication, and configuration problems. PrintMotd yes The option PrintMotd specifies whether the ssh2 daemon should print the content of the /etc/motd file when a user logs in interactively. The / etc/motd file is also know as the message of the day. CheckMail yes The option CheckMail specifies whether the ssh2 daemon should print information about new mail you may have. UserConfigDirectory "%D/.ssh2" The option UserConfigDirectory specifies the default location for user- specific configuration data. SyslogFacility DAEMON The option SyslogFacility specifies the facility code used when logging messages from the ssh2 daemon. The facility specifies the subsystem that produced the message, in our case DAEMON. Ssh1Compatibility no The option Ssh1Compatibility specifies whether or not to use SSH1 compatibility code with SSH2 for ssh1 users. NoDelay yes The option NoDelay specifies if the socket option TCP_NODELAY should be enabled. It is recommended that you set this option to yes to improve network performance. KeepAlive yes The option KeepAlive specifies whether the system should send keep alive messages to the remote server. If set to yes then the death of the connection or crash of remote machines will be properly noticed. UserKnownHosts yes The option UserKnownHosts specifies whether the default user's home directory $HOME/.ssh2/knownhosts/ can be used to get hosts public keys when using hostbased-authentication. AllowHosts 192.168.1.4 The option AllowHosts specifies and control which hosts can access ssh2 services. Multiple hosts can be specified separated by spaces. DenyHosts * The option DenyHosts specifies and controls which hosts cannot access ssh2 services. Multiple hosts can be specified separated by spaces. The default pattern * mean all hosts. QuietMode no The option QuietMode specifies whether the system runs in quiet mode. This option must be set to no, because in quiet mode nothing is logged in the system log except for fatal errors. Since we want to have information about user sessions it is preferable to disable this option. 5. Configure sshd2 to use tcp-wrappers/inetd super server Tcp-wrappers shoud be enabled to start and stop the sshd2 server. Upon execution, inetd reads its configuration information from a configuration file which, by default, is /etc/inetd.conf. There must be an entry for each field of the configuration file, with entries for each field separated by a tab or a space. 1. Edit the inetd.conf file, vi /etc/inetd.conf and add the line: ssh stream tcp nowait root /usr/sbin/tcpd sshd -i Important The -i parameter is important since it specifies that sshd is being run from inetd. Also, update your inetd.conf file by sending a SIGHUP signal, killall -HUP inetd after adding the above line into the file. To update your inetd.conf file, use the following command: [root@deep] /#killall -HUP inetd 2. Edit the hosts.allow file, vi /etc/hosts.allow and add the line: sshd: 192.168.1.4 win.openna.com Which means client 192.168.1.4 with host name win.openna.com is allowed to ssh on the server. Note These daemon strings for tcp-wrappers are in use by sshd2: sshd, sshd2 The name sshd2 was called with usually sshd. sshdfwd-X11 if you want to allow/deny X11-forwarding. sshdfwd- for tcp-forwarding. sshdfwd- port-name defined in /etc/services. Used in tcp-forwarding. Tip If you do decide to switch to using ssh, make sure you install and use it on all your servers. Having ten secure servers and one insecure is a waste of time. 6. Configuration of the /etc/pam.d/ssh file For better security of your ssh2 server, you can configure it to use pam authentication. To do that, you must create the /etc/pam.d/ssh file. Create the ssh file touch /etc/pam.d/ssh and add or change, if necessary: #%PAM-1.0 auth required /lib/security/pam_pwdb.so shadow auth required /lib/security/pam_nologin.so account required /lib/security/pam_pwdb.so password required /lib/security/pam_cracklib.so password required /lib/security/pam_pwdb.so use_authtok nullok md5 shadow session required /lib/security/pam_pwdb.so For Further documentation and more details, there are several man pages you can read: ssh-add2(1) - adds identities for the authentication agent ssh-agent2(1) - authentication agent ssh-keygen2(1) - authentication key pair generation ssh2(1) - secure shell client remote login program sshd2(8) - secure shell daemon 7. Ssh2 Per-User Configuration 1. Create your private & public keys of local, by executing: [root@deep] /#su admin [admin@deep /]$ ssh-keygen2 Generating 1024-bit dsa key pair 6 Oo..oOo.oOo. Key generated. 1024-bit dsa, admin@deep.openna.com, Sun Feb 13 2000 05:33:38 - 0500 Passphrase : Again : Private key saved to /home/admin/.ssh2/id_dsa_1024_a Public key saved to /home/admin/.ssh2/id_dsa_1024_a.pub 2. Create an identification file in your ~/.ssh2 home directory on local: [admin@deep]$cd ~/.ssh2 [admin@deep ]/.ssh2$echo "IdKey id_dsa_1024_a" > identification Note It's optional to create an identification file on Remote. The identification file contains the name of the private key that is to be used in authentication. 3. Copy your public key of Local id_dsa_1024_a.pub to ~/.ssh2 home directory of remote under the name, say, Local.pub. 4. Create an authorization file in your ~/.ssh2 home directory on remote: [admin@remote ]/.ssh2$touch authorization Note The ~/ means the user home directory. 5. Add the following one line to the authorization file on the remote host: [admin@remote ]/.ssh2$vi authorization key Local.pub 8. SSH2 Users Tools The commands listed below are some that we use often in our regular use, but many more exist, and you should check the man page and documentation for more details. ssh2.  Ssh2, Secure Shell provides secure encrypted communications between two untrusted hosts over an insecure network. It is a program for logging securely into a remote machine and executing commands from there. It is a suitable replacement for insecure program like telnet, rlogin, rcp, rdist, and rsh. To login to a remote machine, use the command: [root@deep] /#ssh2 -l Example 16.1. login to a remote using ssh2 [root@deep] /#ssh2 -l admin www.openna.com Passphrase for key "/home/admin/.ssh2/id_dsa_1024_a" with comment "1024-bit dsa, admin@deep.openna.com, Tue Oct 19 1999 14:31:40 -0400": admin's password: Last login: Tue Oct 19 1999 18:13:00 -0400 from deep.openna.com No mail. [admin@www ]/admin$ Where is the name you use to connect to the ssh2 remote server and is the address of your ssh2 remote server. sftp2.  The sftp2, Secure File Transfer utility is an ftp-like client that provides file transfers over the network. You must already be connected with ssh2 before using the sftp2 utility. To ftp over ssh2, use the following command: [admin@deep /]$sftp2 Example 16.2. sftp2, Secure File Transfer [admin@deep /]$sftp2 www.openna.com local path : /home/admin Passphrase for key "/home/admin/.ssh2/id_dsa_1024_a" with comment "1024-bit dsa, admin@deep.openna.com, Tue Oct 19 1999 14:31:40 -0400": admin's password: admin's password: remote path : /home/admin sftp> Where is the name of the remote server you want to sftp. 9. Installed files These are the files Installed by Ssh2 software on your machine: /etc/pam.d/ssh /usr/man/man1/sftp2.1 /usr/bin/ssh-keygen2 /etc/ssh2 /usr/man/man1/ssh.1 /usr/bin/ssh-signer2 /etc/ssh2/hostkey /usr/man/man1/ssh-add.1 /usr/bin/ssh-add2 /etc/ssh2/hostkey.pub /usr/man/man1/ssh-agent.1 /usr/bin/ssh /etc/ssh2/sshd2_config /usr/man/man1/ssh-keygen.1 /usr/bin/ssh-agent /etc/ssh2/ssh2_config /usr/man/man1/scp.1 /usr/bin/ssh-add /root/.ssh2 /usr/man/man1/sftp.1 /usr/bin/ssh-askpass /root/.ssh2/random_seed /usr/man/man8/sshd2.8 /usr/bin/ssh-keygen /root/ssh2 /usr/man/man8/sshd.8 /usr/bin/scp /usr/man/man1/ssh2.1 /usr/bin/ssh2 /usr/bin/sftp /usr/man/man1/ssh-keygen2.1 /usr/bin/scp2 /usr/bin/sftp-server /usr/man/man1/ssh-add2.1 /usr/bin/sftp2 /usr/bin/ssh-signer /usr/man/man1/ssh-agent2.1 /usr/bin/sftp-server2 /usr/sbin/sshd2 /usr/man/man1/scp2.1 /usr/bin/ssh-agent2 /usr/sbin/sshd Chapter 17. Software -Securities/System Integrity Table of Contents 1._Linux_Tripwire_2.2.1 2._Configure_the_/var/tmp/install.cfg_file 3._Configuration_files 4._Configure_the_/usr/TSS/policy/twpol.txt_file 5._Securing_Tripwire_for_Linux 5.1._Often_used_Commands 6._Integrity_or_Interactive_Check_Mode 7._Installed_files A typical Red Hat Linux server installation handles approximately 30,400 files. At their busiest times, administrators can't check the integrity of all system files, and if a cracker has accessed your server, he or she can install or modify files without your knowledge with some effort. Since such a possibility exists a few programs have been created to respond to this kind of activity. 1. Linux Tripwire 2.2.1 According to the official [Tripwire site]: Tripwire works at the most fundamental layer, protecting the servers and workstations that make up the corporate network. Tripwire works by first scanning a computer and creating a database of system files, a compact digital snapshot of the system in a known secure state. The user can configure Tripwire very precisely, specifying individual files and directories on each machine to monitor, or creating a standard template that can be used on all machines in an enterprisewide environement. Once this baseline database is created, a system administrator can use Tripwire to check the integrity of a system at any time. By scanning the current system and comparing that information with the data stored in the database, Tripwire detects and reports any additions, deletions, or changes to the system outside of the specified boundaries. If these changes are valid, the administrator can update the baseline database with the new information. If malicious changes are found, the system administrator will instantly know exactly which part, which component etc. of the network have been affected. This version of Tripwire has significant product enhancements over previous versions of Tripwire. Some of the enhancements include: * Multiple levels of reporting allow you to choose different levels of report detail. * Syslog option sends information about database initialization, database update, policy update and integrity check to the syslog. * Database performance has been optimized to increase the efficiency of integrity checks. * Individual email recipients can be sent certain sections of a report. * SMTP email reporting support. * Email test mode enables you to verify that the email settings are correct. * Ability to create multiple sections within a policy file to be executed separately. These installation instructions assume: * Commands are Unix-compatible. * The source path is /var/tmp -other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * Tripwire version number is 2.2.1 These are the Package(s) you need to install: Tripwire Homepage: http://www.tripwiresecurity.com/ You must be sure to download: Tripwire_221_for_Linux_x86_tar.gz To Compile Tripwire-2.2.1, you do need to Decompress the tarball tar.gz.: [root@deep] /#cp Tripwire_version_for_Linux_x86_tar.gz /var/tmp [root@deep] /#cd /var/tmp [root@deep ]/tmp# tar xzpf Tripwire_version_for_Linux_x86_tar.gz Note After the decompression of Tripwire you will see the following files in your / var/tmp directory related to Tripwire software: License.txt README Release_Notes install.cfg install.sh package directory Tripwire tar.gz file Tripwire_version_for_Linux_x86_tar.gz. 2. Configure the /var/tmp/install.cfg file Recall that Tripwire version 2.2.1 is not open source, so you cannot compile and install it like other archives source files, instead you must modify the install.cfg file of tripwire that will install automatically Tripwire software for you to specify installation paths for your system. We must modify this file to be compliant with Red Hats file system structure and install Tripwire binaries under our PATH Environment Variable. 1. Edit the install.cfg file, vi install.cfg and change this file to look like: # # install.cfg # # default install.cfg for: # Tripwire(R) 2.2.1 for Unix # # NOTE: This is a Bourne shell script that stores installation # parameters for your installation. The installer will # execute this file to generate your config file and also to # locate any special configuration needs for your install. # Protect this file, because it is possible for # malicious code to be inserted here # # To set your Root directory for install, set TWROOT= to something # other than /usr/TSS as necessary. # #======================================================= # If CLOBBER is true, then existing files are overwritten. # If CLOBBER is false, existing files are not overwritten. CLOBBER=false # The root of the TSS directory tree. TWROOT="/usr" # Tripwire binaries are stored in TWBIN. TWBIN="${TWROOT}/bin" # Tripwire policy files are stored in TWPOLICY. TWPOLICY="${TWROOT}/TSS/policy" # Tripwire manual pages are stored in TWMAN. TWMAN="${TWROOT}/man" # Tripwire database files are stored in TWDB. TWDB="${TWROOT}/TSS/db" # The Tripwire site key files are stored in TWSITEKEYDIR. TWSITEKEYDIR="${TWROOT}/TSS/key" # The Tripwire local key files are stored in TWLOCALKEYDIR. TWLOCALKEYDIR="${TWROOT}/TSS/key" # Tripwire report files are stored in TWREPORT. TWREPORT="${TWROOT}/TSS/report" # This sets the default text editor for Tripwire. TWEDITOR="/bin/vi" # TWLATEPROMTING controls the point when tripwire asks for a password. TWLATEPROMPTING=false # TWLOOSEDIRCHK selects whether the directory should be monitored for # properties that change when files in the directory are monitored. TWLOOSEDIRCHK=false # TWMAILNOVIOLATIONS determines whether Tripwire sends a no violation # report when integrity check is run with --email-report but no rule # violations are found. This lets the admin know that the integrity # was run, as opposed to having failed for some reason. TWMAILNOVIOLATIONS=true # TWEMAILREPORTLEVEL determines the verbosity of e-mail reports. TWEMAILREPORTLEVEL=3 # TWREPORTLEVEL determines the verbosity of report printouts. TWREPORTLEVEL=3 # TWSYSLOG determines whether Tripwire will log events to the system log TWSYSLOG=false ##################################### # Mail Options - Choose the appropriate # method and comment the other section ##################################### ##################################### # SENDMAIL options - DEFAULT # # Either SENDMAIL or SMTP can be used to send reports via TWMAILMETHOD. # Specifies which sendmail program to use. ##################################### TWMAILMETHOD=SENDMAIL TWMAILPROGRAM="/usr/lib/sendmail -oi -t" ##################################### # SMTP options # # TWSMTPHOST selects the SMTP host to be used to send reports. # SMTPPORT selects the SMTP port for the SMTP mail program to use. ##################################### # TWMAILMETHOD=SMTP # TWSMTPHOST="mail.domain.com" # TWSMTPPORT=25 ################################################################################ # Copyright (C) 1998-2000 Tripwire (R) Security Systems, Inc. Tripwire (R) is a # registered trademark of the Purdue Research Foundation and is licensed # exclusively to Tripwire (R) Security Systems, Inc. ################################################################################ Note The file install.cfg is a Bourne shell script used by the installer to set configuration variables. These variables specify the target directories where the installer will copy files and what the installer should do if the installation process would overwrite existing Tripwire software files. 2. Now we must run the installation script to install Tripwire binaries and related files on to our system according to whether you are using default or custom configuration values. To run the installation script and install Tripwire, use the following command: [root@deep ]/tmp#./install.sh Important The install.sh file is the installation script which you run to begin installation of Tripwire. During the installation procedure, you will: 1. Answer some questions related to the installation. 2. Specify two pass phrases to be assigned for your site and local keys. 3. When Tripwire is installed in our system it will copy License.txt, README, and Release_Notes files under /usr directory. Of course after finishing reading those files you can safely remove them from your /usr directory with the following command: To remove these files from your system, use the following command: [root@deep ]/usr# rm -f /usr/License.txt README Release_Notes Dont forget to clean up later: [root@deep] /#cd /var/tmp [root@deep ]/tmp# rm -rf License.txt README Release-Notes install.cfg install.sh pkg/ Tripwire_version_for_Linux_x86_tar.gz The rm command as used above will remove all related files and directories we have used to install Tripwire for Linux. It will also remove the Tripwire for Linux compressed archive from the /var/tmp directory. 3. Configuration files Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example Tripwire-2.2.1 configuration file are organised like this: total 16 -rw-r--r-- 1 harrypotter harrypotter 3312 Jun 8 13:00 install.cfg -rw-r--r-- 1 harrypotter harrypotter 10152 Jun 8 13:00 twpol.txt You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run Tripwire for Linux, the following file is required and must be created or copied to the appropriate directory on your server. Copy the twpol.txt file to the /usr/TSS/policy directory. Tip You can obtain the configuration file listed below on our floppy.tgz archive. Copy the following file from the decompressed floppy.tgz archive to the appropriate place, or copy and paste it directly from this book to the concerned file. 4. Configure the /usr/TSS/policy/twpol.txt file The /usr/TSS/policy/twpol.txt is the text policy file of Tripwire where you specify what files and directories, to check. Note that extensive testing and experience are necessary when editing this policy file before you get a working file report. The following is a working example from where you can start your own customization. 1. You must modify the default policy file, or create your own. The policyguide.txt file under /usr/TSS/policy directory can help you. Open the policy file twpol.txt with a text editor, vi /usr/TSS/policy/twpol.txt and change it to fit your needs: @@section GLOBAL TWROOT="/usr"; TWBIN="/usr/bin"; TWPOL="/usr/TSS/policy"; TWDB="/usr/TSS/db"; TWSKEY="/usr/TSS/key"; TWLKEY="/usr/TSS/key"; TWREPORT="/usr/TSS/report"; HOSTNAME=deep.openna.com; @@section FS SEC_CRIT = $(IgnoreNone)-SHa; # Critical files - we can't afford to miss any changes. SEC_SUID = $(IgnoreNone)-SHa; # Binaries with the SUID or SGID flags set. SEC_TCB = $(ReadOnly); # Members of the Trusted Computing Base. SEC_BIN = $(ReadOnly); # Binaries that shouldn't change SEC_CONFIG = $(Dynamic); # Config files that are changed infrequently but accessed often. SEC_LOG = $(Growing); # Files that grow, but that should never change ownership. SEC_INVARIANT = +pug; # Directories that should never change permission or ownership. SIG_LOW = 33; # Non-critical files that are of minimal security impact SIG_MED = 66; # Non-critical files that are of significant security impact SIG_HI = 100; # Critical files that are significant points of vulnerability # Tripwire Binaries (emailto = admin@openna.com, rulename = "Tripwire Binaries", severity = $(SIG_HI)) { $(TWBIN)/siggen -> $(ReadOnly); $(TWBIN)/tripwire -> $(ReadOnly); $(TWBIN)/twadmin -> $(ReadOnly); $(TWBIN)/twprint -> $(ReadOnly); } # Tripwire Data Files - Configuration Files, Policy Files, Keys, Reports, Databases (emailto = admin@openna.com, rulename = "Tripwire Data Files", severity = $(SIG_HI)) { # NOTE: Removing the inode attribute because when Tripwire creates a backup # it does so by renaming the old file and creating a new one (which will # have a new inode number). Leaving inode turned on for keys, which shouldn't # ever change. # NOTE: this rule will trigger on the first integrity check after database # initialization, and each integrity check afterward until a database update # is run, since the database file will not exist before that point. $(TWDB) -> $(Dynamic) -i; $(TWPOL)/tw.pol -> $(SEC_BIN) -i; $(TWBIN)/tw.cfg -> $(SEC_BIN) -i; $(TWLKEY)/$(HOSTNAME)-local.key -> $(SEC_BIN) ; $(TWSKEY)/site.key -> $(SEC_BIN) ; #don't scan the individual reports $(TWREPORT) -> $(Dynamic) (recurse=0); } # These files are critical to a correct system boot. (emailto = admin@openna.com, rulename = "Critical system boot files", severity = 100) { /boot -> $(SEC_CRIT) ; !/boot/System.map ; !/boot/module-info ; } # These files change the behavior of the root account (emailto = admin@openna.com, rulename = "Root config files", severity = 100) { /root -> $(SEC_CRIT) ; /root/.bash_history -> $(SEC_LOG) ; } # Commonly accessed directories that should remain static with regards to owner and group (emailto = admin@openna.com, rulename = "Invariant Directories", severity = $(SIG_MED)) { / -> $(SEC_INVARIANT) (recurse = 0); /home -> $(SEC_INVARIANT) (recurse = 0); /etc -> $(SEC_INVARIANT) (recurse = 0); /chroot -> $(SEC_INVARIANT) (recurse = 0); /cache -> $(SEC_INVARIANT) (recurse = 0); } (emailto = admin@openna.com, rulename = "Shell Binaries") { /bin/bsh -> $(SEC_BIN); /bin/csh -> $(SEC_BIN); /bin/sh -> $(SEC_BIN); } # Rest of critical system binaries (emailto = admin@openna.com, rulename = "OS executables and libraries", severity = $(SIG_HI)) { /bin -> $(ReadOnly) ; /lib -> $(ReadOnly) ; } # Local files (emailto = admin@openna.com, rulename = "User binaries", severity = $(SIG_MED)) { /sbin -> $(SEC_BIN) (recurse = 1); /usr/sbin -> $(SEC_BIN) (recurse = 1); /usr/bin -> $(SEC_BIN) (recurse = 1); } # Temporary directories (emailto = admin@openna.com, rulename = "Temporary directories", recurse = false, severity = $(SIG_LOW)) { /usr/tmp -> $(SEC_INVARIANT); /var/tmp -> $(SEC_INVARIANT); /tmp -> $(SEC_INVARIANT); } # Libraries (emailto = admin@openna.com, rulename = "Libraries", severity = $(SIG_MED)) { /usr/lib -> $(SEC_BIN); } # Include (emailto = admin@openna.com, rulename = "OS Development Files", severity = $(SIG_MED)) { /usr/include -> $(SEC_BIN); } # Shared (emailto = admin@openna.com, rulename = "OS Shared Files", severity = $(SIG_MED)) { /usr/share -> $(SEC_BIN); } # Kernel headers files (emailto = admin@openna.com, rulename = "Kernel Headers Files", severity = $( SIG_HI)) { /usr/src/linux-2.2.14 -> $(SEC_BIN); } # setuid/setgid root programs (emailto = admin@openna.com, rulename = "setuid/setgid", severity = $(SIG_HI)) { /bin/su -> $(SEC_SUID); /sbin/pwdb_chkpwd -> $(SEC_SUID); /sbin/dump -> $(SEC_SUID); /sbin/restore -> $(SEC_SUID); /usr/bin/at -> $(SEC_SUID); /usr/bin/passwd -> $(SEC_SUID); /usr/bin/suidperl -> $(SEC_SUID); /usr/bin/crontab -> $(SEC_SUID); /usr/sbin/sendmail -> $(SEC_SUID); /usr/bin/man -> $(SEC_SUID); /usr/bin/sperl5.00503 -> $(SEC_SUID); /usr/bin/slocate -> $(SEC_SUID); /usr/sbin/utempter -> $(SEC_SUID); /sbin/netreport -> $(SEC_SUID); } (emailto = admin@openna.com, rulename = "Configuration Files") { /etc/hosts -> $(SEC_CONFIG); /etc/inetd.conf -> $(SEC_CONFIG); /etc/initlog.conf -> $(SEC_CONFIG); /etc/inittab -> $(SEC_CONFIG); /etc/resolv.conf -> $(SEC_CONFIG); /etc/syslog.conf -> $(SEC_CONFIG); } (emailto = admin@openna.com, rulename = "Security Control") { /etc/group -> $(SEC_CRIT); /etc/security/ -> $(SEC_CRIT); /lib/security/ -> $(SEC_CRIT); /var/spool/cron -> $(SEC_CRIT); } (emailto = admin@openna.com, rulename = "Login Scripts") { /etc/csh.login -> $(SEC_CONFIG); /etc/profile -> $(SEC_CONFIG); } # These files change every time the system boots (emailto = admin@openna.com, rulename = "System boot changes", severity = $(SIG_HI)) { /dev/log -> $(Dynamic) ; /dev/cua0 -> $(Dynamic) ; /dev/console -> $(Dynamic) ; /dev/tty2 -> $(Dynamic) ; # tty devices /dev/tty3 -> $(Dynamic) ; # are extremely /dev/tty4 -> $(Dynamic) ; # variable /dev/tty5 -> $(Dynamic) ; /dev/tty6 -> $(Dynamic) ; /dev/urandom -> $(Dynamic) ; /dev/initctl -> $(Dynamic) ; /var/lock/subsys -> $(Dynamic) ; /var/run -> $(Dynamic) ; # daemon PIDs /var/log -> $(Dynamic) ; /etc/ioctl.save -> $(Dynamic) ; /etc/.pwd.lock -> $(Dynamic) ; /etc/mtab -> $(Dynamic) ; /lib/modules -> $(Dynamic) ; } # Critical configuration files (emailto = admin@openna.com, rulename = "Critical configuration files", severity = $(SIG_HI)) { /etc/conf.modules -> $(ReadOnly) ; /etc/crontab -> $(ReadOnly) ; /etc/cron.hourly -> $(ReadOnly) ; /etc/cron.daily -> $(ReadOnly) ; /etc/cron.weekly -> $(ReadOnly) ; /etc/cron.monthly -> $(ReadOnly) ; /etc/default -> $(ReadOnly) ; /etc/fstab -> $(ReadOnly) ; /etc/group- -> $(ReadOnly) ; # changes should be infrequent /etc/host.conf -> $(ReadOnly) ; /etc/hosts.allow -> $(ReadOnly) ; /etc/hosts.deny -> $(ReadOnly) ; /etc/lilo.conf -> $(ReadOnly) ; /etc/logrotate.conf -> $(ReadOnly) ; /etc/pwdb.conf -> $(ReadOnly) ; /etc/securetty -> $(ReadOnly) ; /etc/sendmail.cf -> $(ReadOnly) ; /etc/protocols -> $(ReadOnly) ; /etc/services -> $(ReadOnly) ; /etc/rc.d/init.d -> $(ReadOnly) ; /etc/rc.d -> $(ReadOnly) ; /etc/motd -> $(ReadOnly) ; /etc/passwd -> $(ReadOnly) ; /etc/passwd- -> $(ReadOnly) ; /etc/profile.d -> $(ReadOnly) ; /etc/rpc -> $(ReadOnly) ; /etc/sysconfig -> $(ReadOnly) ; /etc/shells -> $(ReadOnly) ; /etc/nsswitch.conf -> $(ReadOnly) ; } # Critical devices (emailto = admin@openna.com, rulename = "Critical devices", severity = $(SIG_HI), recurse = false) { /dev/kmem -> $(Device) ; /dev/mem -> $(Device) ; /dev/null -> $(Device) ; /dev/zero -> $(Device) ; /proc/devices -> $(Device) ; /proc/net -> $(Device) ; /proc/tty -> $(Device) ; /proc/sys -> $(Device) ; /proc/cpuinfo -> $(Device) ; /proc/modules -> $(Device) ; /proc/mounts -> $(Device) ; /proc/dma -> $(Device) ; /proc/filesystems -> $(Device) ; /proc/ide -> $(Device) ; /proc/interrupts -> $(Device) ; /proc/ioports -> $(Device) ; /proc/scsi -> $(Device) ; /proc/kcore -> $(Device) ; /proc/self -> $(Device) ; /proc/kmsg -> $(Device) ; /proc/stat -> $(Device) ; /proc/ksyms -> $(Device) ; /proc/loadavg -> $(Device) ; /proc/uptime -> $(Device) ; /proc/locks -> $(Device) ; /proc/version -> $(Device) ; /proc/meminfo -> $(Device) ; /proc/cmdline -> $(Device) ; /proc/misc -> $(Device) ; } Tip This is an example policy file we provide you; of course, you must modify this file to fit your system files and specific needs. 2. Once you are ready to use your policy file for the first time, install it with the following command: [root@deep] /#twadmin --create-polfile /usr/TSS/policy/ twpol.txt Please enter your site passphrase: Wrote policy file: /usr/TSS/policy/tw.pol 5. Securing Tripwire for Linux It is important to make sure that the integrity of the system you are running has not been already compromised. For maximum confidence in your baseline database, you should generate operating system and application files from a clean installation and original media. Also, it is recommended that you delete the plain text copy of the Tripwire configuration file named twcfg.txt located under the /usr/bin directory to hide the location of Tripwire's files and prevent anyone from creating a second, or alternate, configuration file. To delete the plain text copy of the tripwire configuration file, use the following command: [root@deep] /#rm -f /usr/bin/twcfg.txt Further documentation for more details, there are several man pages you can read: siggen(8) - signature gathering routine for Tripwire tripwire(8) - a file integrity checker for UNIX systems twadmin(8) - Tripwire administrative and utility tool twconfig(4) - Tripwire configuration file reference twfiles(5) - overview of files used by Tripwire and file backup process twintro(8) - introduction to Tripwire software twpolicy(4) - Tripwire policy file reference twprint(8) - Tripwire database and report printer 5.1. Often used Commands The commands listed below are some that we use often in our regular use, but many more exist. Check the man page for more details. Creating the database for the first time; once your policy file has been installed, it is time to build and initialize your database of file system objects, based on the rules from your policy file. This database will serve as the baseline for later integrity checks. The syntax for Database Initialization mode is: [root@deep] /#tripwire --init To initialize your database file, use the following command: [root@deep] /#tripwire --init Please enter your local passphrase: Parsing policy file: /usr/TSS/policy/tw.pol Generating the database... *** Processing Unix File System *** Wrote database file: /usr/TSS/db/deep.openna.com.twd The database was successfully generated. Tip When this command has executed, the database is ready and you can check system integrity and review the report file. 6. Integrity or Interactive Check Mode Tripwire has a feature called Integrity Check Mode. Now that our database has been built, we can run this feature to compare the current file system objects with their properties as recorded in the Tripwire database. All violations of files will be printed to stdout, the report-generated file will be saved and can later be accessed by the twprint utility. The syntax for integrity check mode is: [root@deep] /#tripwire --check To run the integrity check mode, use the command: [root@deep] /#tripwire --check Tripwire can also be run in Interactive Check Mode. In this mode you can automatically update your changes via the terminal. To run in interactive check mode, use the command: [root@deep] /#tripwire --check --interactive An email option exists with Tripwire and allows you to send email. This option will specify that reports be emailed to the recipients designated in the policy file. To run in integrity check mode and send email to the recipient, use the command: [root@deep] /#tripwire --check --email-report Updating the database after an integrity check If you have decided to use the Integrity Check Mode of Tripwire instead of the Interactive Check Mode, you must update the Tripwire database with the Database Update Mode feature. This update process allows you to save time by updating the database without having to regenerate it, and it also enables selective updating, which cannot be done through regeneration. The syntax for database update mode is: [root@deep] /# tripwire --update -r To update the database, use the command: [root@deep] /#tripwire --update -r /usr/TSS/report/ deep.openna.com-200001-021854.twr Where -r read the specified report file deep.openna.com-200001-021854.twr. This option is required since the REPORTFILE variable in the current configuration file uses $(DATE). Important In Database Update Mode or Interactive Check Mode, Tripwire software displays the report in your terminal with a ballot box next to each policy violation. You can approve a change to the file system by leaving the x next to each policy violation or remove the x from the ballot box and the database will not be updated with the new value(s) for that object. After you exit the editor and provide the local pass phrase, Tripwire software will update and save your changes. Updating the policy file Some times you want to change the rules in your policy file to reflect new file locations or policy rules. A special command exists to do the work and update the database without requiring a complete re- initialization of the policy file. This can save a significant amount of time and preserves security by keeping the policy file synchronized with the database it uses. The syntax for policy update mode is: [root@deep] /#tripwire --update-policy /path/to/new/policy/file To update the policy file, use the command: [root@deep] /#tripwire --update-policy /usr/TSS/policy/ newtwpol.txt The policy Update mode runs with the --secure-mode high option by default. You may encounter errors when running with this option if the file system has changed since the last database update, and if the changes cause a violation in the new policy. After determining that all of the violations reported in high security mode are authorized, you can update the policy file in low security mode to solve this situation: To update the policy file in low security mode, use the command: [root@deep] /#tripwire --update-policy --secure-mode low /usr/TSS/ policy/newtwpol.txt 7. Installed files These are the files Installed by Tripwire: /usr/TSS /usr/TSS/policy/tw.pol /usr/man/man5 /usr/bin /usr/TSS/policy/ /usr/man/man5/twfiles.5 twpol.txt.bak /usr/bin/siggen /usr/TSS/report /usr/man/man8 /usr/bin/twprint /usr/TSS/db /usr/man/man8/siggen.8 /usr/bin/twadmin /usr/TSS/key /usr/man/man8/tripwire.8 /usr/bin/tripwire /usr/TSS/key/site.key /usr/man/man8/twadmin.8 /usr/bin/twcfg.txt /usr/TSS/key/ /usr/man/man8/twintro.8 deep.openna.com-local.key /usr/bin/tw.cfg /usr/man /usr/man/man8/twprint.8 /usr/TSS/policy /usr/man/man4 /usr/README /usr/TSS/policy/ /usr/man/man4/twconfig.4 /usr/Release_Notes policyguide.txt /usr/TSS/policy/twpol.txt /usr/man/man4/twpolicy.4 /usr/License.txt Chapter 18. Linux Tripwire ASR 1.3.1 Table of Contents 1._Install,_Compile_and_Optimize 2._Configurations 3._Configure_the_/etc/tw.config_file 4._Configure_the_/etc/cron.daily/tripwire.verify_script 4.1._Security_Issue 5._Tripwire_in_Interactive_Checking_Mode 6._Run_Tripwire_in_Database_Update_Mode 6.1._Installed_Files Tripwire ASR 1.3.1 is the Academic Source Release (ASR) of Tripwire software. Personally, I prefer the 1.3.1 version of the software rather than the 2.2.1 version because it can compile and be installed without any compatibility problems on all versions of Linux systems. 1. Install, Compile and Optimize As explained in the [Tripwire ASR goals]: With the advent of increasingly sophisticated and subtle account break-ins on Unix systems, the need for tools to aid in the detection of unauthorized modification of files becomes clear. Tripwire is a tool that aids system administrators and users in monitoring a designated set of files for any changes. Used with system files on a regular (e.g., daily) basis, Tripwire can notify system administrators of corrupted or tampered files, so damage control measures can be taken in a timely manner. Tripwire is a file and directory integrity checker, a utility that compares a designated set of files and directories against information stored in a previously generated database. Any differences are flagged and logged, including added or deleted entries. When run against system files on a regular basis, any changes in critical system files will be spotted -- and appropriate damage control measures can be taken immediately. With Tripwire, system administrators can conclude with a high degree of certainty that a given set of files remain free of unauthorized modifications if Tripwire reports no changes. These installation instructions assume: * Commands are Unix-compatible. * The source path is /var/tmp -other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * Tripwire version number is 1.3.1-1 These are the package(s) required and Tripwire Homepage: http://www.tripwiresecurity.com/ You must be sure to download: Tripwire-1.3.1-1.tar.gz You need to decompress the Tarballs, It is a good idea to make a list of files on the system before you install it, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > Tripwire1 before and find /* > Tripwire2 after you install the tarball, and use diff Tripwire1 Tripwire2 > Tripwire-Installed to get a list of what changed. [root@deep] /# cp Tripwire-version.tar.gz /var/tmp [root@deep] /# cd /var/tmp [root@deep ]/tmp# tar xzpf Tripwire-version.tar.gz Move into the new Tripwire directory and Edit the utils.c file (vi +462 src/ utils.c) and change the line: else if (iscntrl(*pcin)) { To read: else if (!(*pcin & 0x80) && iscntrl(*pcin)) { Edit the config.parse.c file, vi +356 src/config.parse.c and change the line: rewind(fpout); To read: else { rewind(fpin); } Edit the config.h file, vi +106 include/config.h and change the line: #define CONFIG_PATH "/usr/local/bin/tw" #define DATABASE_PATH "/var/tripwire" To read: #define CONFIG_PATH "/etc" #define DATABASE_PATH "/var/spool/tripwire" Edit the config.h file, vi +165 include/config.h and change the line: #define TEMPFILE_TEMPLATE "/tmp/twzXXXXXX" To read: #define TEMPFILE_TEMPLATE "/var/tmp/.twzXXXXXX" Edit the config.pre.y file vi +66 src/config.pre.y and change the line: #ifdef TW_LINUX To read: #ifdef TW_LINUX_UNDEF Edit the Makefile, vi +13 Makefile and change the line: DESTDIR = /usr/local/bin/tw To read: DESTDIR = /usr/sbin DATADIR = /var/tripwire To read: DATADIR = /var/spool/tripwire LEX = lex To read: LEX = flex CC=gcc To read: CC=egcs CFLAGS = -O To read: CFLAGS = -O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions [root@deep ]/tw_ASR_1.3.1_src# make [root@deep ]/tw_ASR_1.3.1_src# make install [root@deep ]/tw_ASR_1.3.1_src# chmod 700 /var/spool/tripwire/ [root@deep ]/tw_ASR_1.3.1_src# chmod 500 /usr/sbin/tripwire [root@deep ]/tw_ASR_1.3.1_src# chmod 500 /usr/sbin/siggen [root@deep ]/tw_ASR_1.3.1_src# rm -f /usr/sbin/tw.config * The above commands make and make install will configure the software to ensure your system has the necessary functionality and libraries to successfully compile the package, compile all source files into executable binaries, and then install the binaries and any supporting files into the appropriate locations. * The chmod command will change the default mode of tripwire directory to be 700 drwx------ only readable, writable, and executable by the super-user root. It will make the binary /usr/sbin/tripwire only readable, and executable by the super-user root -r-x------ and finally make the siggen program under /usr/sbin directory only executable and readable by root. * The rm command as used above will remove the file tw.config under /usr/sbin. We don't need this file since we will create a new one under /etc directory later. Do Cleanup later: [root@deep] /# cd /var/tmp [root@deep ]/tmp# rm -rf tw_ASR_version/ Tripwire-version.tar.gz The rm command as used above will remove all the source files we have used to compile and install Tripwire. It will also remove the Tripwire compressed archive from the /var/tmp directory. 2. Configurations Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example Tripwire-1.3.1. configuration file are organised like this: total 8 -rwx------ 1 harrypotter harrypotter 504 Jun 8 13:00 tripwire.verify* -rw------- 1 harrypotter harrypotter 611 Jun 8 13:00 tw.config You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run Tripwire, the following files are required and must be created or copied to their appropriate directories on your server. 1. Copy the tw.config file to the /etc directory. 2. Copy the tripwire.verify script to the /etc/cron.daily directory. 3. Configure the /etc/tw.config file The /etc/tw.config file is the Tripwire configuration file where you decide and set which system files and directories that you want monitored. Note that extensive testing and experience are necessary when editing this file before you get working file reports. The following is a working example from where you can start you own customization. 1. Create the tw.config file, touch /etc/tw.config and add in this file all files and directories that you want monitored. The format of the configuration file is described in its header and in the man page tw.config(5): # Gerhard Mourani: gmourani@videotron.ca # last updated: 1999/11/12 # First, root's "home" /root R !/root/.bash_history / R # OS itself /boot/vmlinuz R # critical boot resources /boot R # Critical directories and files /chroot R /etc R /etc/inetd.conf R /etc/nsswitch.conf R /etc/rc.d R /etc/mtab L /etc/motd L /etc/group R /etc/passwd L # other popular filesystems /usr R /usr/local R /dev L-am /usr/etc R # truncate home =/home R # var tree =/var/spool L /var/log L /var/lib L /var/spool/cron L !/var/lock # unusual directories =/proc E =/tmp =/mnt/cdrom =/mnt/floppy 2. Now, for security reasons, change the mode of this file to be 0600 with the following command: [root@deep] /# chmod 600 /etc/tw.config 4. Configure the /etc/cron.daily/tripwire.verify script The tripwire.verify file is a small script executed by the crond program of your server each day to scan your hard disk for possible changed files or directories and mail the results to the system administrator. This script will automate the procedure of integrity checking for you. If you intend to automate this task, follow the simple steps below. 1. Create the tripwire.verify script file, touch /etc/cron.daily/ tripwire.verify and add in this script: #!/bin/sh /usr/sbin/tripwire -loosedir -q | (cat < File: '/root/tmp/firewall' ---> Update entry? [YN(y)nh?] Note In interactive mode, Tripwire first reports all added, deleted, and changed files, then allows the user to update the entry in the database. 6. Run Tripwire in Database Update Mode Running Tripwire in Database Update Mode mixed with the tripwire.verify script file that mails the results to the system administrator, will reduce the time of scanning the system. Instead of running Tripwire in Interactive Checking Mode and waiting for the long scan to finish, the script file tripwire.verify will scan the system and report via mail the result, then you run Tripwire in Database Update Mode and update only single files or directories that has changed. Example 18.1. Usage of Tripwire If a single file has changed, you can: [root@deep] /# tripwire -update /etc/newly.installed.file Or, if an entire set of files or directories has changed, you can run: [root@deep] /# tripwire -update /usr/lib/Package_Dir In either case, Tripwire regenerates the database entries for every specified file. A backup of the old database is created in the ./databases directory. These are Some possible uses of Tripwire software 1. Check the integrity of your files system. 2. Get a list of new installed or removed files on your system. 6.1. Installed Files These are the files Installed by the software TripWire ASR on your system: /etc/cron.daily/tripwire.verify /etc/tw.config /usr/man/man5/tw.config.5 /usr/man/man8/siggen.8 /usr/man/man8/tripwire.8 /usr/sbin/tripwire /usr/sbin/siggen /var/spool/tripwire /var/spool/tripwire/tw.db_TEST 6.1.1. Alternatives to Tripwire These are some of the alternatives to Tripwire: ViperDB ViperDB Homepage: http://www.resentment.org/projects/viperdb/ FCHECK FCHECK Homepage:http://sites.netscape.net/fcheck/fcheck.html Sentinel Sentinel Homepage:http://zurk.netpedia.net/zfile.html Chapter 19. Software -Securities/Management & Limitation Table of Contents 1._Linux_GnuPG 2._Often_used_Commands 3._Importing_keys 3.1._Key_signing 4._Encrypt_and_decrypt 4.1._Exporting_your_public_key Encryption of data sources is an invaluable feature that gives us a high degree of confidentiality for our work. A tool like GnuPG does much more than just encryption of mail messages. It can be used for all kinds of data encryptions, and its utilization can only be stopped by the imagination. GnuPG RPM package comes already installed on you computer, but this version is not up to date and it is recommended to install the latest release available to fit our needs and CPU architecture. 1. Linux GnuPG According to the [official GnuPG README] file: GnuPG is GNU's tool for secure communication and data storage. It can be used to encrypt data and to create digital signatures. It includes an advanced key management facility and is compliant with the proposed OpenPGP Internet standard as described in RFC2440. Because GnuPG does not use any patented algorithm it cannot be compatible with PGP2 versions. PGP 2.x uses only IDEA (which is patented worldwide) and RSA (which is patented in the United States until Sep 20, 2000). These installation instructions assume: * Commands are Unix-compatible. * The source path is /var/tmp -other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * GnuPG version number is 1.0.1 These are the Package(s) you must be sure to download: GnuPG Homepage:http://www.gnupg.org/ Package to download: gnupg-1.0.1.tar.gz You must decompress the tarball to compile, it is a good idea to make a list of files on the system before you install it, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > GnuPG1 before and find /* > GnuPG2 after you install the tarball, and use diff GnuPG1 GnuPG2 > GnuPG-Installed to get a list of what changed. Decompress the tarball (tar.gz): [root@deep] /# cp gnupg-version.tar.gz /var/tmp [root@deep] /# cd /var/tmp [root@deep ]/tmp# tar xzpf gnupg-version.tar.gz You need to Compile and Optimize, move into the new GnuPG dir and type the following on your terminal: CC="egcs" \ CFLAGS="-O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions" \ ./configure \ --prefix=/usr \ --enable-shared [root@deep ]/gnupg-1.0.1# make [root@deep ]/gnupg-1.0.1# make check [root@deep ]/gnupg-1.0.1# make install [root@deep ]/gnupg-1.0.1# strip /usr/bin/gpg The make command compiles all source files into executable binaries, The make check will run any self-tests that come with the package finally, the make install command installs the binaries and any supporting files into the appropriate locations. The strip command will reduce the size of the gpg binary for better performance. Cleanup after work [root@deep] /# cd /var/tmp [root@deep ]/tmp# rm -rf gnupg-version/ gnupg-version.tar.gz The rm command as used above will remove all the source files we have used to compile and install GnuPG. It will also remove the GnuPG compressed archive from the /var/tmp directory. 2. Often used Commands The commands listed below are some that we use often, but many more exist. Check the man page for more details and information. First of all, we must create a new key-pair (public and private) if this is a first use of the GnuPG software to be able to use its encryption features. 1. To create a new key-pair, use the following command: [root@deep] /# gpg --gen-key gpg (GnuPG) 1.0.1; Copyright (C) 1999 Free Software Foundation, Inc. This program comes with ABSOLUTELY NO WARRANTY. This is free software, and you are welcome to redistribute it under certain conditions. See the file COPYING for details. gpg: /root/.gnupg: directory created gpg: /root/.gnupg/options: new options file created gpg: you have to start GnuPG again, so it can read the new options file This asks some questions and then starts key generation. 2. We start GnuPG again with the following command: [root@deep] /# gpg --gen-key gpg (GnuPG) 1.0.1; Copyright (C) 1999 Free Software Foundation, Inc. This program comes with ABSOLUTELY NO WARRANTY. This is free software, and you are welcome to redistribute it under certain conditions. See the file COPYING for details. gpg: /root/.gnupg/secring.gpg: keyring created gpg: /root/.gnupg/pubring.gpg: keyring created Please select what kind of key you want: (1) DSA and ElGamal (default) (2) DSA (sign only) (4) ElGamal (sign and encrypt) Your selection? 1 DSA keypair will have 1024 bits. About to generate a new ELG-E keypair. minimum keysize is 768 bits default keysize is 1024 bits highest suggested keysize is 2048 bits What keysize do you want? (1024) 2048 Do you really need such a large keysize? y Requested keysize is 2048 bits Please specify how long the key should be valid. 0 = key does not expire = key expires in n days w = key expires in n weeks m = key expires in n months y = key expires in n years Key is valid for? (0) 0 correct (y/n)? y You need a User-ID to identify your key; the software constructs the user id from Real Name, Comment and Email Address in this form: "Heinrich Heine (Der Dichter) " Real name: Gerhard Mourani Email address: gmourani@videotron.ca Comment: [Press Enter] You selected this USER-ID: "Gerhard Mourani " Change (N)ame, (C)omment, (E)mail or (O)kay/(Q)uit? o You need a Passphrase to protect your secret key. We need to generate a lot of random bytes. It is a good idea to perform some other action (type on the keyboard, move the mouse, utilize the disks) during the prime generation; this gives the random number generator a better chance to gain enough entropy. +++++..+++++++++++++++..+++++.++++++++++++++++++++++++++++++++++++++++..+++++++ +++.+++++++++++++++++++++++++.+++++++++++++++...+++++++++++++++++++++++++.+++++ ..+++++>+++++...+++++++++++++++>+++++.......>+++++.......>+++++................ ..........+++++^^^^ public and secret key created and signed. A new key-pair is created (secret and public key) in the root home directory ~/ root. 3. Importing keys Once our own key-pair is created, we can begin to put into our public keyring database of all keys we have from some trusted third partly in order to be able to use his/her keys for future encryption and authentication communication. To import Public Keys to your keyring, use the following command: [root@deep] /# gpg --import Example 19.1. Importing using gpg [root@deep] /# gpg --import redhat2.asc gpg: key DB42A60E: public key imported gpg: /root/.gnupg/trustdb.gpg: trustdb created gpg: Total number processed: 1 gpg: imported: 1 The above command will append all new keys to our keyring database and will update all already existing keys. It is important to note that GnuPG does not import keys that are not self-signed. In the above example we import the Public Key file redhat2.asc from the company Red Hat Linux, downloadable from the Red Hat Internet site, into our keyring. 3.1. Key signing When you import keys into your public keyring database and are sure that trusted third party is really the person they claim, you can start signing his/ her keys. Signing a key certifies that you know the owner of the keys. To sign a key for the company RedHat that we have added on our keyring above, use the following command: [root@deep] /# gpg --sign-key Example 19.2. Signing key [root@deep] /# gpg --sign-key RedHat pub 1024D/DB42A60E created: 1999-09-23 expires: never trust: -/q sub 2048g/961630A2 created: 1999-09-23 expires: never (1) Red Hat, Inc pub 1024D/DB42A60E created: 1999-09-23 expires: never trust: -/q Fingerprint: CA20 8686 2BD6 9DFC 65F6 ECC4 2191 80CD DB42 A60E Red Hat, Inc Are you really sure that you want to sign this key with your key: "Gerhard Mourani " Really sign? y You need a passphrase to unlock the secret key for user: "Gerhard Mourani " 1024-bit DSA key, ID E92D6C97, created 1999-12-30 Enter passphrase: Note You should only sign a key as being authentic when you are Absolutely sure that the key is really authentic! You should never sign a key based on any assumption. 4. Encrypt and decrypt After installing, importing, signing and configuring everything in the way that we want, we can start on encrypting and decrypting our work. To encrypt and sign data for the user RedHat that we have added on our keyring above, use the following command: [root@deep] /# gpg -sear RedHat Example 19.3. Encrypting [root@deep] /# gpg -sear RedHat message-to-RedHat.txt You need a passphrase to unlock the secret key for user: "Gerhard Mourani (Open Network Architecture) " 1024-bit DSA key, ID BBB4BA9B, created 1999-10-26 Enter passphrase: Of the arguments passed, The s is for signing To avoid the risk that somebody else claims to be you, it is very useful to sign everything you encrypt, * e for encrypting, * a to create ASCII armored output .asc ready for sending by mail, * r to encrypt the user id name * is the message you want to encrypt. To decrypt data, use the following command: [root@deep] /# gpg -d Example 19.4. Decrypting [root@deep] /# gpg -d message-to-Gerhard.asc You need a passphrase to unlock the secret key for user: "Gerhard Mourani (Open Network Architecture) " 2048-bit ELG-E key, ID 71D4CC44, created 1999-10-26 (main key ID BBB4BA9B) Enter passphrase: Where * -d is for decrypting * is the message you want to decrypt. It is important that the public key of the sender of the message we want to decrypt be in our public keyring database. or of course nothing will work. 4.1. Exporting your public key You can spread your wings by exporting and distributing your public key to the world. This can be done by publishing it on your homepage, through an available key server on the Internet, or any other available method. GnuPG has some useful options to help you publish your public keys. To extract your public key in ASCII armored output, use the following command: [root@deep] /# gpg --export --armor > Public-key.asc where * --export is for extracting your Public-key from your pubring encrypted file, * --armor is to create ASCII armored output that you can mail, publish or put it on a web page * > Public-key.asc is to put the result in a file that you've named Public- key.asc. You need to Check the signature, once you have extracted your public key and exported it, everyone who knows or gets your public key should be able to check whether encrypted data from you is also really signed by you. To check the signature of encrypted data, use the following command: [root@deep] /# gpg --verify The --verify option will check the signature where is the encrypted data/file you want to verify. Some possible uses of GnuPG software 1. Send encrypted mail massage. 2. Encrypt backup files before transmission over the network. 3. Encrypt individual sensitive files i.e. a file that handle all your passwords. Installed files /usr/bin/gpg /usr/lib/gnupg /usr/lib/gnupg/rndunix /usr/lib/gnupg/rndegd /usr/lib/gnupg/tiger /usr/man/man1/gpg.1 /usr/share/gnupg /usr/share/gnupg/options.skel Chapter 20. Set Limits using Qouta Table of Contents 1._Qouta 1.1._Modify_the_/etc/fstab_file 2._Create_of_the_quota.user_and_quota.group 3._edquota 3.1._The_grace_period_parameter 4._Assign_quota_for_a_particular_group 4.1._Assign_quota_for_groups_of_users_with_the_same_value 5._Often_used_Commands 1. Qouta Quota is a system administration tools for monitoring and limiting users and/or groups disk usage, per file system. Two features of disk storage with quota are available to set limits: * The first is the number of inodes number of files a user or a group of users may possess. * The second is the number of disk blocks amount of space in kilobytes that may be allocated to a user or a group of users. With quota, the users are forced by the system administrator to not consume unlimited disk space on a system. This program is handled on per user, per file system basis and must be set for each file system separately. The first thing you need to do is ensure that your kernel has been built with Quota support enabled. In the 2.2.14 kernel version you need ensure that you have answered Y to the following questions: Filesystems Quota support (CONFIG_QUOTA) [N/y/?] Y Tip If you have followed the Linux Kernel chapter in this book and have recompiled your kernel, the option Quota support shown above is already set. 1.1. Modify the /etc/fstab file The /etc/fstab file contains information about the various file systems installed on your Linux server. Quota must be enabled in the fstab file before you can use it. Since Quota must be set for each file system separately, and because in the fstab file, each file system is described on a separate line, quota must be set on each of the separate lines in the fstab for which you want to enable quota support. With the program quota, depending on your intentions, needs, etc, you can enable quota only for users, groups or both users and groups. For all examples below, we'll use the /home directory on the /dev/sda6 partition and shows you the three possibilities. Possibility 1 To enable user quota support on a specific file system, edit your fstab file vi /etc/fstab and add the usrquota option to the fourth field after the word defaults or any other options you may have set for this specific file system. Example 20.1. usrquota change: /dev/sda6 /home ext2 defaults 1 2 1 /dev/sda6 /home ext2 nosuid,nodev 1 2 2 _1_ as an example: the word defaults _2_ as an example: any other options you have set To read: /dev/sda6 /home ext2 defaults,usrquota 1 2 /dev/sda6 /home ext2 nosuid,nodev,usrquota 1 2 Possibility 2 To enable group quota support on a file system, edit your fstab file vi /etc/ fstab and add grpquota to the fourth field after the word defaults or any other options you may have set for this specific file system. Example 20.2. grpquota change: /dev/sda6 /home ext2 defaults 1 2 1 /dev/sda6 /home ext2 nosuid,nodev 1 2 2 _1_ as an example: the word defaults _2_ as an example: any other options you have set To read: /dev/sda6 /home ext2 defaults,grpquota 1 2 /dev/sda6 /home ext2 nosuid,nodev,grpquota 1 2 Possibility 3 To enable both users quota and group quota support on a file system, edit your fstab file vi /etc/fstab and add usrquota,grpquota to the fourth field after the word defaults or any other options you may have set for this specific file system. Change: /dev/sda6 /home ext2 defaults 1 2 1 /dev/sda6 /home ext2 nosuid,nodev 1 2 2 _1_ as an example: the word defaults _2_ as an example: any other options you have set To read: /dev/sda6 /home ext2 defaults,usrquota,grpquota 1 2 /dev/sda6 /home ext2 nosuid,nodev,usrquota,grpquota 1 2 2. Create of the quota.user and quota.group After the modification of your /etc/fstab file, in order for quotas to be established on a file system, the root directory of the file system i.e. /home in our example must contain a file, owned by root, called quota.user if you want to use user quota, quota.group if you want to use group quota, or both if you want to use users and group quota. 1. Create the quota.user and/or quota.group files, as root go to the root of the partition you wish to enable quota i.e. /home doing: [root@deep] /# touch /home/quota.user [root@deep] /# touch /home/quota.group [root@deep] /# chmod 600 /home/quota.user [root@deep] /# chmod 600 /home/quota.group The touch command will create new empty files under the home directory named quota.user and quota.group. The chmod command will set the mode of these files to be read-write only by the super-user root. Important Both quota record files, quota.user and quota.group, should be owned by root, with read-write permission for root and none for anybody else. 2. Now we must initialize the files quota.user and quota.group in the root directory of the file system in order to not receive an error messages about quota during the reboot of our server. To initialize quota.user and/ or quota.group files, use the following commands: [root@deep] /# edquota -u wahib [root@deep] /# edquota -g wahib The steps above are necessary just to initialize the files quota.user and/ or quota.group; the command edquota -u will edit the quota for the user wahib and -g will edit the quota for the group wahib. Note that you must edit an existing UID/GID on your system to initialize the files successfully. 3. After you have finished setting the appropriate options for your quota program in the /etc/fstab file, and created and initialized the quota.users, and/or quota.group files, you must reboot the system for the changes you have made in the /etc/fstab file and/or the files quota.user, quota.group to take effect. To reboot your system, use the following command: [root@deep] /# reboot After your system has been rebooted you can assign quotas to users or groups of users on your system. This operation is performed with the edquota command. See man page edquota(8) 3. edquota The edquota program is a quota editor that creates a temporary file of the current disk quotas used by the super-user root to set quotas for users or group of users in the system. The example below shows you how to setup quotas for users or groups on your system. Consider, for example, that you have a user with the login id wahib on your system. The following command opens the editor vi to edit and set quotas for user wahib on each partition that has quotas enabled: 1. To edit and modify quota for user wahib, use the following command: [root@deep] /# edquota -u wahib Quotas for user wahib: /dev/sda6: blocks in use: 6, limits (soft = 0, hard = 0) inodes in use: 5, limits (soft = 0, hard = 0) After the execution of the above command, you will see the following lines related to the user wahib appear on the screen. The blocks in use: display the total number of blocks in kilobytes the user has consumed on a partition. The inodes in use: display the total number of files the user has on a partition. These parameters blocks in use, and inodes in use are controlled and set automatically by the system and you don't need to set or change them. 2. To assign 5MB of quota for user wahib, change the following parameters in the vi editor: Quotas for user wahib: /dev/sda6: blocks in use: 6, limits (soft = 0, hard = 0) inodes in use: 5, limits (soft = 0, hard = 0) To read: Quotas for user wahib: /dev/sda6: blocks in use: 6, limits (soft = 5000, hard = 0) inodes in use: 5, limits (soft = 0, hard = 0) The soft limit (soft =) specifies the maximum amount of disk usage a quota user is allowed to have. The hard limit (hard =) specifies the absolute limit on the disk usage a quota user can't go beyond it. Tip Take a note that the hard limit value works only when the grace period parameter is set. 3.1. The grace period parameter The grace period parameter allow you to set a time limit before the soft limit value is enforced on a file system with quota enabled, see the soft limit above for more information. For example this parameter can be used to warn your users about a new policy that will set a quota of 5MB of disk space in their home directory in 7 days. You can set the 0 days default part of this parameter to any length of time you feel reasonable. The changes of this setting require two steps as follows, in my example I assume 7 days. 1. Edit the default grace period parameter, by using the following command: [root@deep] /# edquota -t Time units may be: days, hours, minutes, or seconds Grace period before enforcing soft limits for users: /dev/sda6: block grace period: 0 days, file grace period: 0 days 2. Modify the grace period to 7 days. Change or set the following parameters in the vi editor: Time units may be: days, hours, minutes, or seconds Grace period before enforcing soft limits for users: /dev/sda6: block grace period: 0 days, file grace period: 0 days To read: Time units may be: days, hours, minutes, or seconds Grace period before enforcing soft limits for users: /dev/sda6: block grace period: 7 days, file grace period: 7 days The command edquota -t edits the soft time limits for each file system with quotas enabled. 4. Assign quota for a particular group Consider, for example, you have a group with the group id webusers on your system. The following command takes you into the vi editor to edit quotas for the group webusers on each partition that has quotas enabled: To edit and modify quota for group webusers, use the following command: [root@deep] /# edquota -g webusers Quotas for group webusers: /dev/sda6: blocks in use: 6, limits (soft = 0, hard = 0) inodes in use: 6, limits (soft = 0, hard = 0) The procedure is the same as for assigning quotas for a particular user; as described above, you must modify the parameter of soft = and save your change. 4.1. Assign quota for groups of users with the same value The edquota program has a special option -p that assign quotas for groups of users with the same value assigned to an initial user. Assuming that you want to assign users starting at UID 500 on the system the same value as the user wahib, we would first edit and set wahib's quota information, then execute: To assign quota for group of users with the same value, use the following command: [root@deep] /# edquota -p wahib `awk -F: '$3 > 499 {print $1}' /etc/passwd` The edquota program will duplicate the quota that we have set for the user wahib to all users in the /etc/passwd file that begin after UID 499. Further documentation for more details, please consult man pages: edquota(8) - edit user quotas quota(1) - display disk usage and limits quotacheck(8) - scan a file system for disk usages quotactl(2) - manipulate disk quotas quotaon, quotaoff(8) - turn file system quotas on and off repquota(8) - summarize quotas for a file system rquota(3) - implement quotas on remote machines 5. Often used Commands The commands listed below are some that we use often, but many more exist. Check the man page for more details and information. Quota.  Quota displays users' disk usage and limits on a file system. To display user disk usage and limits, use the command: [root@deep] /# quota -u wahib Disk quotas for user wahib (uid 501): Filesystem blocks quota limit grace files quota limit grace /dev/sda6 6001* 6000 0 none 7 0 0 To display group quotas for the group of which the user is a member, use the command: [root@deep] /# quota -g wahib Disk quotas for group wahib (gid 501): Filesystem blocks quota limit grace files quota limit grace /dev/sda6 5995* 5000 0 none 1 0 0 If the group quota is not set for the user specified, you will receive the following message: Disk quotas for group wahib (gid 501): none Repquota .  Repquota produces summarized quota information of the disk usage and quotas for the specified file systems. Also, it prints for each user the current number of files and amount of space used (in kilobytes). Here is a sample output repquota gives you results may vary: [root@deep] /# repquota -a Block limits File limits User used soft hard grace used soft hard grace Roo -- 21 0 0 4 0 0 Named -- 6 0 0 5 0 0 Admin -- 388657 0 0 21 21 0 0 Wahib -- 6001 0 0 7 0 0 Block limits File limits User used soft hard grace used soft hard grace root -- 21 0 0 4 0 0 named -- 6 0 0 5 0 0 admin -- 388657 0 0 2121 0 0 wahib -- 6001 6000 0 none 7 0 0 Chapter 21. Software -Networking Table of Contents 1._Linux_DNS_and_BIND_Server 2._Configure 3._Caching-only_name_Server 4._Primary_master_name_Server 5._Secondary_slave_name_Server 5.1._/etc/rc.d/init.d/named_script 6._Run_ISC_BIND/DNS_in_a_chroot_jail 7._The_syslog_daemon 8._Clean-up_and_Test_the_new_chrooted_jail 9._DNS_Administrative_Tools 10._DNS_Users_Tools 11._Installed_files Once we have installed all the necessary security software in our Linux server, it's time to finetune the network part of our server. DNS is the MOST important network service for IP networks communication, and for this reason, all Linux client machines should be configured to perform caching functions as a minimum. 1. Linux DNS and BIND Server Setting up a caching server for client local machines will reduce the load on the site's primary server. A caching only name server will find the answer to name queries and remember the answer the next time we need it. This will shorten the waiting time the next time significantly. For security reasons, it is very important that DNS doesn't exist between hosts on the corporate network and external hosts; it is far safer to simply use IP addresses to connect to external machines from the corporate network and vice-versa. In our configuration and installation we'll run BIND/DNS as non root-user and in a chrooted environment. We also provide you three different configurations; * one for a simple caching name server only client * one for a slave secondary server * one for a master name server primary server. The simple caching name server configuration will be used for your servers that don't act as a master or slave name server, and the slave and master configurations will be used for your servers that act as a master name server and slave name server. Usually one of your servers acts as master, another one acts as slave and the rest act as simple caching client name server. This is a graphical representation of the DNS configuration we use in this book. We try to show you different settings DNS caching name server * Caching Only DNS * Master DNS * Slave DNS on different servers. A lot of possibilities exist, and depend on your needs, and network architecture. These installation instructions assume * Commands are Unix-compatible. * The source path is /var/tmp. other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * ISC BIND version number is 8.2.2-patchlevel5 These are the Package(s) required: ISC BIND Homepage:http://www.isc.org/ ISC BIND FTP Site: 204.152.184.27 You must be sure to download: bind-contrib.tar.gz, bind-doc.tar.gz, bind- src.tar.gz Before you decompress Tarballs and install, it is a good idea to make a list of files on the system before you install BIND, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > DNS1 before and find /* > DNS2 after you install the software, and use diff DNS1 DNS2 > DNS-Installed to get a list of what changed. Compile and Decompress the tarball (tar.gz). [root@deep] /# mkdir /var/tmp/bind [root@deep] /# cp bind-contrib.tar.gz /var/tmp/bind/ [root@deep] /# cp bind-doc.tar.gz /var/tmp/bind/ [root@deep] /# cp bind-src.tar.gz /var/tmp/bind/ We create a directory named bind to handle the tar archives and copy them to this new directory. Move into the new bind directory cd /var/tmp/bind and decompress the tar files: [root@deep ]/bind# tar xzpf bind-contrib.tar.gz [root@deep ]/bind# tar xzpf bind-doc.tar.gz [root@deep ]/bind# tar xzpf bind-src.tar.gz 2. Configure Configuration files for different services are very specific depending on your needs and your network architecture. People can install DNS Servers at home as a caching-only server, though companies may install it with primary, secondary and caching DNS servers. Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example BIND-DNS configuration file are organised like this: total 24 drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 Caching- Only-DNS/ -rw-r--r-- 1 harrypotter harrypotter 484 Jun 8 13:00 Compile- BIND drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 Primary- Master-DNS/ drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 Secondary-Slave-DNS/ -rwx------ 1 harrypotter harrypotter 300 Jun 8 13:00 bind.sh* drwxr-xr-x 3 harrypotter harrypotter 4096 Jun 8 13:00 init.d/ You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run a caching-only name server, the following files are required and must be created or copied to the appropriate directories on your server. i. Copy the named.conf file to the /etc/ directory. ii. Copy the db.127.0.0 file to the /var/named/ directory. iii. Copy the db.cache file to the /var/named/ directory. iv. Copy the named script file to the /etc/rc.d/init.d/ directory. To run a master name server, the following files are required and must be created or copied to the appropriate directories on your server. i. Copy the named.conf file to the /etc/ directory. ii. Copy the db.127.0.0 file to the /var/named/ directory. iii. Copy the db.cache file to the /var/named/ directory. iv. Copy the db.208.164.186 file to the /var/named/ directory. v. Copy the db.openna file to the /var/named/ directory. vi. Copy the named script file to the /etc/rc.d/init.d/ directory. To run a slave name server, the following files are required and must be created or copied to the appropriate directories on your server. i. Copy the named.conf file to the /etc/ directory. ii. Copy the db.127.0.0 file to the /var/named/ directory. iii. Copy the db.cache file to the /var/named/ directory. iv. Copy the named script file to the /etc/rc.d/init.d/ directory. Tip You can obtain the configuration files listed over the next few sections on the floppy.tgz archive. Copy the following files from the decompressed floppy.tgz archive to the appropriate places, or copy them directly from this book to the concerned file. 3. Caching-only name Server Caching-only name servers are servers not authoritative for any domains except 0.0.127.in-addr.arpa, the localhost. A caching-only name server can look up names inside and outside your zone, as can primary and slave name servers. The difference is that when a caching-only name server initially looks up a name within your zone, it ends up asking one of the primary or slave names servers for your zone for the answer. The necessary files to setup a simple caching name server are: 1. named.conf 2. db.127.0.0 3. db.cache 4. named script To configure the /etc/named.conf file for a simple caching name server, use this for all servers that dont act as a master or slave name server. Setting up a simple caching server for local client machines will reduce the load on the network's primary server. Many users on dialup connections may use this configuration along with bind for such a purpose. Create the named.conf file, touch /etc/named.conf and add the following lines to the file: options { directory "/var/named"; forwarders { 208.164.186.1; 208.164.186.2; }; 1 forward only; }; // // a caching only nameserver config zone "." in { type hint; file "db.cache"; }; zone "0.0.127.in-addr.arpa" in { type master; file "db.127.0.0"; }; _1_ In the forwarders line, 208.164.186.1 and 208.164.186.2 are the IP addresses of your Primary Master and Secondary Slave DNS server. They can also be the IP addresses of your ISPs DNS server and another DNS server, respectively. Tip To improve the security of your BIND/DNS server you can stop it from even trying to contact an off-site server if their forwarder is down or doesn't respond. With the forward only option set in your named.conf file, the name server doesn't try to contact other servers to find out information if the forwarder doesn't give it an answer. To configure the /var/named/db.127.0.0 file for a simple caching name server,you can use this configuration for all machines on your network that don't act as a master or slave name server. The db.127.0.0 file covers the loopback network. Create the following files in /var/named/, touch /var/named/ db.127.0.0 and add the following lines in the file: $TTL 345600 @ IN SOA localhost. root.localhost. ( 00 ; Serial 86400 ; Refresh 7200 ; Retry 2592000 ; Expire 345600 ) ; Minimum IN NS localhost. 1 IN PTR localhost. Configure the /var/named/db.cache file for a simple caching name server before starting your DNS server. You must take a copy of db.cache file and copy this file to the /var/named/ directory. The db.cache tells your server where the servers for the root zone are. Use the following commands on another Unix computer in your organization to query a new db.cache file for your DNS Server or pick one from your Red Hat Linux CD-ROM source distribution: [root@deep]# dig @.aroot-servers.net . ns > db.cache Don't forget to copy the db.cache file to the /var/named/ directory on your server where you're installing DNS server after retrieving it over the Internet. Tip Internal addresses like 192.168.1/24 are not included in the DNS configuration files for security reasons. It is very important that DNS doesn't exist between hosts on the corporate network and external hosts. 4. Primary master name Server A primary master name server for a zone reads the data for the zone from a file on it's host and are authoritative for that zone.The necessary files to setup a primary master name server are: a. named.conf b. db.127.0.0 c. db.208.164.186 d. db.openna e. db.cache f. named script To configure the /etc/named.conf file for a master name server, use this configuration for the server on your network that acts as a master name server. After compiling DNS, you need to set up a primary domain name for your server. We'll use openna.com as an example domain, and assume you are using IP network address of 208.164.186.0. To do this, add the following lines to your /etc/ named.conf. Create the named.conf file touch /etc/named.conf and add: options { directory "/var/named"; fetch-glue no; 1 recursion no; 2 allow-query { 208.164.186/24; 127.0.0/8; }; 3 allow-transfer { 208.164.186.2; }; 4 transfer-format many-answers; }; // These files are not specific to any zone zone "." in { type hint; file "db.cache"; }; zone "0.0.127.in-addr.arpa" in { type master; file "db.127.0.0"; }; // These are our primary zone files zone "openna.com" in { type master; file "db.openna "; }; zone "186.164.208.in-addr.arpa" in { type master; file "db.208.164.186"; }; _1_ _2_ The fetch-glue no option can be used in conjunction with the option recursion no to prevent the server's cache from growing or becoming corrupted. Also, disabling recursion puts your name servers into a passive mode, telling it never to send queries on behalf of other name servers or resolvers. A non-recursive name server is very difficult to spoof, since it doesn't send queries, and hence doesn't cache any data. _3_ In the allow-query line, 208.164.186/24 and 127.0.0/8 are the IP addresses allowed to ask ordinary questions to the server. _4_ In the allow-transfer line, 208.164.186.2 is the IP address allowed to receive zone transfers from the server. You must ensure that only your real slave name servers can transfer zones from your name serve, as the information provided is often used by spammers and IP spoofers. Note The options recursion no, allow-query, and allow-transfer in the named.conf file above are security features. To configure the /var/named/db.127.0.0 file for a master and slave name server, you can use this configuration file by both a master name server and a slave name server. The db.127.0.0 file covers the loopback network. Create the following files in /var/named/. Create the db.127.0.0 file, touch /var/named/db.127.0.0 and add: ; Revision History: April 22, 1999 - admin@mail.openna.com ; Start of Authority (SOA) records. $TTL 345600 @ IN SOA deep.openna.com. admin.mail.openna.com. ( 00 ; Serial 86400 ; Refresh 7200 ; Retry 2592000 ; Expire 345600 ) ; Minimum ; Name Server (NS) records. NS deep.openna.com. NS mail.openna.com. ; only One PTR record. 1 PTR localhost. To configure the /var/named/db.208.164.186 file for a master name server, Use this configuration for the server on your network that acts as a master name server. The file db.208.164.186 maps host names to addresses. Create the following files in /var/named/. Create the db.208.164.186 file, touch /var/named/db.208.164.186 and add: ; Revision History: April 22, 1999 - admin@mail.openna.com ; Start of Authority (SOA) records. $TTL 345600 @ IN SOA deep.openna.com. admin.mail.openna.com. ( 00 ; Serial 86400 ; Refresh 7200 ; Retry 2592000 ; Expire 345600 ) ; Minimum ; Name Server (NS) records. NS deep.openna.com. NS mail.openna.com. ; Addresses Point to Canonical Names (PTR) for Reverse lookups 1 PTR deep.openna.com. 2 PTR mail.openna.com. 3 PTR www.openna.com. To configure of the /var/named/db.openna file for a master name server, use this configuration for the server on your network that acts as a master name server. The file db.openna maps addresses to host names. Create the following file in /var/named/. Create the db.openna file touch /var/named/db.openna and add: ; Revision History: April 22, 1999 - admin@mail.openna.com ; Start of Authority (SOA) records. $TTL 345600 @ IN SOA deep.openna.com. admin.mail.openna.com. ( 00 ; Serial 86400 ; Refresh 7200 ; Retry 2592000 ; Expire 345600 ) ; Minimum ; Name Server (NS) records. NS deep.openna.com. NS mail.openna.com. ; Mail Exchange (MX) records. MX 0 mail.openna.com. ; Address (A) records. localhost A 127.0.0.1 deep A 208.164.186.1 mail A 208.164.186.2 www A 208.164.186.3 ; Aliases in Canonical Name (CNAME) records. ;www CNAME deep.openna.com. To configure the /var/named/db.cache file for a master and slave name servers Before starting your DNS server you must take a copy of the db.cache file and copy it into the /var/named/ directory. The db.cache tells your server where the servers for the root zone are. Use the following command on another Unix computer in your organization to query a new db.cache file for your DNS Server or pick one from your Red Hat Linux CD-ROM source distribution: [root@deep] /# dig @.aroot-servers.net . ns > db.cache Don't forget to copy the db.cache file to the /var/named/ directory on your server where you're installing DNS server after retrieving it over the Internet. 5. Secondary slave name Server The purpose of a slave name server is to share the load with the master server, or handle the entire load if the master server is down. A slave name server loads its data over the network from another name server usually the master name server, but it can load from another slave name server too. This process is called a zone transfer. Necessary files to setup a secondary slave name server are: i. named.conf ii. db.127.0.0 iii. db.cache iv. named script To configure the /etc/named.conf file for a slave name server, use this configuration for the server on your network that acts as a slave name server. You must modify the named.conf file on the slave name server host. Change every occurrence of primary to secondary except for 0.0.127.in-addr.arpa and add a masters line with the IP address of the master server as shown below. Create the named.conf file (touch /etc/named.conf) and add: options { directory "/var/named"; fetch-glue no; recursion no; allow-query { 208.164.186/24; 127.0.0/8; }; allow-transfer { 208.164.186.1; }; transfer-format many-answers; }; // These files are not specific to any zone zone "." in { type hint; file "db.cache"; }; zone "0.0.127.in-addr.arpa" in { type master; file "db.127.0.0"; }; // These are our slave zone files zone "openna.com" in { type slave; file "db.openna"; masters { 208.164.186.1; }; }; zone "186.164.208.in-addr.arpa" in { type slave; file "db.208.164.186"; masters { 208.164.186.1; }; }; This tells the name server that it is a slave for the zone openna.com and should track the version of this zone that is being kept on the host 208.164.186.1. A slave name server doesn't need to retrieve all of its database (db) files over the network because these db files db.127.0.0 and db.cache are the same as on a primary master, so you can keep a local copy of these files on the slave name server. i. Copy the db.127.0.0file from master name server to slave name server. ii. Copy the db.cache file from master name server to slave name server. 5.1. /etc/rc.d/init.d/named script Configure your /etc/rc.d/init.d/named script file to start and stop the BIND/ DNS daemon on your Server. This configuration script file can by used for all type of name server caching, master or slave. Create the named script file touch /etc/rc.d/init.d/named and add: #!/bin/sh # # named This shell script takes care of starting and stopping # named (BIND DNS server). # # chkconfig: - 55 45 # description: named (BIND) is a Domain Name Server (DNS) \ # that is used to resolve host names to IP addresses. # probe: true # Source function library. . /etc/rc.d/init.d/functions # Source networking configuration. . /etc/sysconfig/network # Check that networking is up. [ ${NETWORKING} = "no" ] && exit 0 [ -f /usr/sbin/named ] || exit 0 [ -f /etc/named.conf ] || exit 0 RETVAL=0 # See how we were called. case "$1" in start) # Start daemons. echo -n "Starting named: " daemon named RETVAL=$? [ $RETVAL -eq 0 ] && touch /var/lock/subsys/named echo ;; stop) # Stop daemons. echo -n "Shutting down named: " killproc named RETVAL=$? [ $RETVAL -eq 0 ] && rm -f /var/lock/subsys/named echo ;; status) /usr/sbin/ndc status exit $? ;; restart) $0 stop $0 start ;; reload) /usr/sbin/ndc reload exit $? ;; probe) # named knows how to reload intelligently; we don't want linuxconf # to offer to restart every time /usr/sbin/ndc reload >/dev/null 2>&1 || echo start exit 0 ;; *) echo "Usage: named {start|stop|status|restart}" exit 1 esac exit $RETVAL Now, make this script executable and change its default permissions: [root@deep]# chmod 700 /etc/rc.d/init.d/named Create the symbolic rc.d links for BIND/DNS with the command: [root@deep]# chkconfig --add named The BIND/DNS script will not automatically start the named daemon when you reboot the server. You can change its default by executing the following command: [root@deep]# chkconfig --level 345 named on Start your DNS Server manually with the following command: [root@deep]# /etc/rc.d/init.d/named start Starting named: [ OK ] 6. Run ISC BIND/DNS in a chroot jail The main benefit of a chroot jail is that the jail will limit the portion of the file system the DNS daemon program can see to the root directory of the jail. Additionally, since the jail only needs to support DNS, the programs related to ISC BIND/DNS available in the jail can be extremely limited. Most importantly, there is no need for setuid-root programs, which can be used to gain root access and break out of the jail. Securing ISC BIND/DNS This part focuses on preventing ISC BIND/DNS from being used as a point of break-in to the system hosting it. Since ISC BIND/DNS performs a relatively large and complex function, the potential for bugs that affect security is rather high with this software. In fact, there have been exploitable bugs in the past that allowed a remote attacker to obtain root access to hosts running ISC BIND/DNS. To minimize this risk, ISC BIND/DNS can be run as a non-root user, which will limit any damage to what can be done as a normal user with a local shell. Of course, this is not enough for the security requirements of most DNS servers, so an additional step can be taken - that is, running ISC BIND in a chroot jail. DNS in chroot Important The named binary program must be in a directory listed within your PATH environment variable for this to work. For the rest of the documentation, I'll assume the path of your original named program is /usr/sbin/named. The following are the necessary steps to run ISC BIND/DNS software in a chroot jail: We must find the shared library dependencies of named, named is the DNS daemon. These will need to be copied into the chroot jail later. 1. To find the shared library dependencies of named, execute the following command: [root@deep] /# ldd /usr/sbin/named libc.so.6 => /lib/libc.so.6 (0x40017000) /lib/ld-linux.so.2 => /lib/ld-linux.so.2 (0x40000000) 2. Make a note of the files listed above; you will need these later in our steps. Now we must set up the chroot environment, and create the root directory of the jail. We've chosen /chroot/named because we want to put this on its own separate file system to prevent file system attacks. Early in our Linux installation procedure we created a special partition /chroot for this purpose. 1. [root@deep] /# /etc/rc.d/init.d/named stop 1 _1_ Require only if an existing named daemon is running. Shutting down named: [ OK ] [root@deep] /# mkdir -p /chroot/named 2. Next, create the rest of directories as follows: [root@deep] /# mkdir /chroot/named/dev [root@deep] /# mkdir /chroot/named/lib [root@deep] /# mkdir /chroot/named/etc [root@deep] /# mkdir -p /chroot/named/usr/sbin [root@deep] /# mkdir -p /chroot/named/var/run [root@deep] /# mkdir /chroot/named/var/named 3. Now copy the main configuration file, the zone files, the named and the named-xfer programs into the appropriate places in the chroot jail directory: [root@deep] /# cp /etc/named.conf /chroot/named/etc/ [root@deep] /# cd /var/named ; cp -a . /chroot/named/var/named/ [root@deep] /# mknod /chroot/named/dev/null c 1 3 [root@deep] /# chmod 666 /chroot/named/dev/null [root@deep] /# cp /usr/sbin/named /chroot/named/usr/sbin/ [root@deep] /# cp /usr/sbin/named-xfer /chroot/named/usr/sbin/ Important The owner of the /chroot/named/var/named directory and all files in this directory must be the process name named under the slave server and only the slave server or you wouldn't be able to make a zone transfer. 4. To make the named directory and all its files own by the named process name under the slave server, use the command: [root@deep] /# chown -R named.named /chroot/named/var/named/ Copy the shared libraries identified above to the chrooted lib directory: [root@deep] /# cp /lib/libc.so.6 /chroot/named/lib/ [root@deep] /# cp /lib/ld-linux.so.2 /chroot/named/lib/ Copy the localtime and nsswitch.conf files to the chrooted etc directory so that log entries are adjusted for your local timezone properly: [root@deep] /# cp /etc/localtime /chroot/named/etc/ [root@deep] /# cp /etc/nsswitch.conf /chroot/named/etc/ We must set some files under the /chroot/named/etc directory with the immutable bit enabled for better security: 1. Set the immutable bit on nsswitch.conf file: [root@deep] /# cd /chroot/named/etc/ [root@deep etc]# chattr +i nsswitch.conf 2. Set the immutable bit on named.conf file: [root@deep] /# cd /chroot/named/etc/ [root@deep etc]# chattr +i named.conf A file with the +i attribute cannot be modified, deleted or renamed; no link can be created to this file and no data can be written to it. Only the superuser can set or clear this attribute. Add a new UID and a new GID for running the daemon named if this is not already set. This is important because running it as root defeats the purpose of the jail, and using a different user id that already exists on the system can allow your services to access each others' resources. Check the /etc/passwd and /etc/ group files for a free UID/GID number available. In our example we'll use the number 53 and the name named. [root@deep] /#useradd -c DNS Server -u 53 -s /bin/false -r -d /chroot/named named 2>/dev/null || : 7. The syslog daemon We must tell syslogd the syslog daemon program about the new chrooted service, since normally, processes talk to syslogd through /dev/log. As a result of the chroot jail, this won't be possible, so syslogd needs to be told to listen to / chroot/named/dev/log instead of the default dev/log. To do this, edit the syslog startup script file to specify additional places to listen. Edit the syslog script file vi +24 /etc/rc.d/init.d/syslog and change the line: daemon syslogd -m 0 To read: daemon syslogd -m 0 -a /chroot/named/dev/log The default named script file of ISC BIND/DNS starts the daemon named outside the chroot jail. We must change it to start named from the chroot jail. Edit the named script file vi /etc/rc.d/init.d/named and change the lines: 1. [ -f /usr/sbin/named ] || exit 0 To read: [ -f /chroot/named/usr/sbin/named ] || exit 0 2. [ -f /etc/named.conf ] || exit 0 To read: [ -f /chroot/named/etc/named.conf ] || exit 0 3. daemon named To read: daemon /chroot/named/usr/sbin/named -t /chroot/named/ -unamed -gnamed The -t option tells named to start up using the new chroot environment. The -u option specifies the user to run as. The -g option specifies the group to run as. In BIND 8.2 version, the ndc command of ISC BIND/DNS software became a binary file; before, it was a script file, which renders the shipped ndc useless in this setting. To fix it, the ISC BIND/DNS package must be compiled again from source. To do this, in the top level of ISC BIND/DNS source directory. 1. For ndc utility: [root@deep] /# cp bind-src.tar.gz /vat/tmp [root@deep] /# cd /var/tmp/ [root@deep ]/tmp# tar xzpf bind-src.tar.gz [root@deep ]/tmp# cd src [root@deep ]/src# cp port/linux/Makefile.set port/linux/Makefile.set- orig 2. Edit the Makefile.set file, vi port/linux/Makefile.set to make the changes listed below: 'CC=egcs -D_GNU_SOURCE' 'CDEBUG=-O9 -funroll-loops -ffast-math -malign-double -mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions -g 'DESTBIN=/usr/bin' 'DESTSBIN=/chroot/named/usr/sbin' 'DESTEXEC=/chroot/named/usr/sbin' 'DESTMAN=/usr/man' 'DESTHELP=/usr/lib' 'DESTETC=/etc' 'DESTRUN=/chroot/named/var/run' 'DESTLIB=/usr/lib/bind/lib' 'DESTINC=/usr/lib/bind/include' 'LEX=flex -8 -I' 'YACC=yacc -d' 'SYSLIBS=-lfl' 'INSTALL=install' 'MANDIR=man' 'MANROFF=cat' 'CATEXT=$$N' 'PS=ps p' 'AR=ar crus' 'RANLIB=:' 3. The difference between the Makefile we used before and this one is that we modify the DESTSBIN=, DESTEXEC=, and DESTRUN= lines to point to the chrooted directory of BIND/DNS. With this modification, the ndc program knows where to find named. [root@deep ]/src# make clean [root@deep ]/src# make [root@deep ]/src# cp bin/ndc/ndc /usr/sbin/ [root@deep ]/src# cp: overwrite `/usr/sbin/ndc'? y [root@deep ]/src# strip /usr/sbin/ndc We build the binary file, then copy the result of ndc program to /usr/sbin and overwrite the old one. We dont forget to strip our new ndc binary for better performance. 8. Clean-up and Test the new chrooted jail Remove the unnecessary files and directory. [root@deep] /# rm -f /usr/sbin/named [root@deep] /# rm -f /usr/sbin/named-xfer [root@deep] /# rm -f /etc/named.conf [root@deep] /# rm -rf /var/named/ We remove the named and named-xfer binaries from the /usr/sbin directory, since the ones we'll work with now on a daily basis are located under the chroot directory. The same applies for the named.conf file and /var/named directory. We must test the new chrooted jail configuration of our ISC BIND/DNS software. 1. The first thing to do is to restart our syslogd daemon with the following command: [root@deep] /# /etc/rc.d/init.d/syslog restart Shutting down kernel logger: [ OK ] Shutting down system logger: [ OK ] Starting system logger: [ OK ] Starting kernel logger: [ OK ] 2. Now, start the new chrooted jail ISC BIND/DNS with the following command: [root@deep] /# /etc/rc.d/init.d/named start Starting named: [ OK ] 3. Make sure it's running as user named and with the new arguments. To verify that ISC BIND/DNS is running as user named with the new arguments, use the following command: [root@deep] /# ps auxw | grep named named 11446 0.0 1.2 2444 1580 ? S 23:09 0:00 /chroot/named/usr/sbin/ named -t /chroot/named/ -unamed -gnamed The first column should be named, which is the UID named daemon is running under. The end of the line should be named -t /chroot/named/ -unamed - gnamed, which are the new arguments. 4. Please dont forget to cleanup: [root@deep] /# rm -rf /var/tmp/src bind-src.tar.gz This will remove the source file and tar archive we used to compile and install ISC BIND/DNS. Further documentation, for more details there are several man pages you can read: dnsdomainname(1) - show the system's DNS domain name dnskeygen(1) - generate public, private, and shared secret keys for DNS Security dnsquery(1) - query domain name servers using resolver named(8) - Internet domain name server DNS hesiod_to_bind [hesiod](3) - Hesiod name server interface library ldconfig(8) - determine run-time link bindings lesskey(1) - specify key bindings for less raw(8) - bind a Linux raw character device mkfifo(1) - make FIFOs named pipes named-bootconf(8) - convert name server configuration files named-xfer(8) - ancillary agent for inbound zone transfers named.conf [named](5) - configuration file for Opcode(3) - Disable named opcodes when compiling perl code dig(1) - send domain name query packets to name servers nslookup(8) - query Internet name servers interactively ndc(8) - name daemon control program 9. DNS Administrative Tools The commands listed belows are some that we use often, but many more exist. Check the man pages and documentation for more details and information. dig.  The dig command utility domain information groper can be used to update your db.cache file by telling your server where the servers for the root zone are. When the server knows about the location of these zones, it queries a new db.cache from it. The root name servers do not change very often, but they do change. A good practice is to update your db.cache file every month or two. Use the following command to query a new db.cache file for your DNS Server: [root@deep] /# dig @.aroot-servers.net . ns > db.cache Copy the db.cache file to /var/named/ after retrieving it. [root@deep] /# cp db.cache /var/named/ Where @a.root-servers.net is the address of the root server for querying the new db.cache file and db.cache file is the name of your new db.cache file. ndc.  The ndc command utility of ISC BIND/DNS allows the system administrator to control interactively via a terminal the operation of a name server. Type ndc on your terminal and then help to see help on different command. [root@deep] /# ndc Type help -or- /h if you need help. ndc> help getpid status stop exec reload [zone] ... reconfig (just sees new/gone zones) dumpdb stats trace [level] notrace querylog qrylog help quit ndc> /e 10. DNS Users Tools The commands listed belows are some that we use often, but many more exist. Check the man pages and documentation for more details and information. nslookup.  The nslookup program allows the user to query Internet domain name servers interactively or non-interactively. In interactive mode the user can query name servers for information about various hosts and domains, and print a list of hosts in a domain. In non-interactive mode the user can just print the name and request information for a host or domain. Interactive mode has a lot of options and commands; it is recommended that you see the man page for nslookup, or the help under nslookup Interactive mode. To enter under nslookup Interactive mode, use the command: [root@deep] /# nslookup Default Server: deep.openna.com Address: 208.164.186.1 > help $Id$ Commands: (identifiers are shown in uppercase, [] means optional) NAME - print info about the host/domain NAME using default server NAME1 NAME2 - as above, but use NAME2 as server help or ? - print info on common commands; see nslookup(1) for details set OPTION - set an option all - print options, current server and host [no]debug - print debugging information [no]d2 - print exhaustive debugging information To run in non-interactive mode, use the command: [root@deep] /# nslookup www.redhat.com Server: deep.openna.com Address: 208.164.186.1 Non-authoritative answer: Name: www.portal.redhat.com Addresses: 206.132.41.202, 206.132.41.203 Aliases: www.redhat.com Where www.redhat.com is the host name or Internet address of the name server to be looked up. dnsquery.  The dnsquery program queries domain name servers via the resolver library calls /etc/resolv.conf. To query domain name servers using resolver, use the command: [root@deep] /# dnsquery Example 21.1. dnsquery [root@deep] /# dnsquery www.redhat.com ;; ->>HEADER<<- opcode: QUERY, status: NOERROR, id: 40803 ;; flags: qr rd ra; QUERY: 1, ANSWER: 1, AUTHORITY: 4, ADDITIONAL: 4 ;; www.redhat.com, type = ANY, class = IN www.redhat.com. 2h19m46s IN CNAME www.portal.redhat.com. redhat.com. 2h18m13s IN NS ns.redhat.com. redhat.com. 2h18m13s IN NS ns2.redhat.com. redhat.com. 2h18m13s IN NS ns3.redhat.com. redhat.com. 2h18m13s IN NS speedy.redhat.com. ns.redhat.com. 1d2h18m8s IN A 207.175.42.153 ns2.redhat.com. 1d2h18m8s IN A 208.178.165.229 ns3.redhat.com. 1d2h18m8s IN A 206.132.41.213 speedy.redhat.com. 2h18m13s IN A 199.183.24.251 Where is the name of the host you want to query. host.  The host program looks up host names using DNS. To look up host names using domain server, use the command: [root@deep] /# host Example 21.2. Look up host names [root@deep] /# host redhat.com redhat.com has address 207.175.42.154 Where is either FDQN www.redhat.com, domain names redhat.com, host names www or host numbers 207.175.42.154. To find all of the information about a host maintained by the DNS, use the command: [root@deep] /# host -a Example 21.3. Using host [root@deep] /# host -a redhat.com Trying null domain rcode = 0 (Success), ancount=6 The following answer is not authoritative: The following answer is not verified as authentic by the server: redhat.com 8112 IN NS ns.redhat.com redhat.com 8112 IN NS ns2.redhat.com redhat.com 8112 IN NS ns3.redhat.com redhat.com 8112 IN NS speedy.redhat.com redhat.com 8112 IN A 207.175.42.154 redhat.com 11891 IN SOA ns.redhat.com noc.redhat.com( 2000021402 ;serial (version) 3600 ;refresh period 1800 ;retry refresh this often 604800 ;expiration period 86400 ;minimum TTL ) For authoritative answers, see: redhat.com 8112 IN NS ns.redhat.com redhat.com 8112 IN NS ns2.redhat.com redhat.com 8112 IN NS ns3.redhat.com redhat.com 8112 IN NS speedy.redhat.com Additional information: ns.redhat.com 94507 IN A 207.175.42.153 ns2.redhat.com 94507 IN A 208.178.165.229 ns3.redhat.com 94507 IN A 206.132.41.213 speedy.redhat.com 8112 IN A 199.183.24.251 This option can be used to find all of the information that is maintained by the domain server about this host, in our example redhat.com. To list a complete domain, use the command: [root@deep] /# host -l Example 21.4. List a complete domain [root@deep] /# host -l openna.com openna.com name server deep.openna.com openna.com name server mail.openna.com localhost.openna.com has address 127.0.0.1 deep.openna.com has address 208.164.186.1 mail.openna.com has address 208.164.186.2 www.openna.com has address 208.164.186.3 This option, in the official master file format, will give a complete download of the zone data for the domain name openna.com. This command should be used only if it is absolutely necessary. 11. Installed files /etc/rc.d/init.d/named /usr/lib/bind/include/hesiod.h /etc/rc.d/rc0.d/K45named /usr/lib/bind/include/sys /etc/rc.d/rc1.d/K45named /usr/lib/bind/include/net /etc/rc.d/rc2.d/K45named /usr/lib/bind/lib /etc/rc.d/rc3.d/K45named /usr/lib/bind/lib/libbind.a /etc/rc.d/rc4.d/K45named /usr/lib/bind/lib/libbind_r.a /etc/rc.d/rc5.d/K45named /usr/lib/nslookup.help /etc/rc.d/rc6.d/K45named /usr/man/man1/dig.1 /etc/named.conf /usr/man/man1/host.1 /usr/bin/addr /usr/man/man1/dnsquery.1 /usr/bin/nslookup /usr/man/man1/dnskeygen.1 /usr/bin/dig /usr/man/man3/hesiod.3 /usr/bin/dnsquery /usr/man/man3/gethostbyname.3 /usr/bin/host /usr/man/man3/inet_cidr.3 /usr/bin/nsupdate /usr/man/man3/resolver.3 /usr/bin/mkservdb /usr/man/man3/getnetent.3 /usr/lib/bind /usr/man/man3/tsig.3 /usr/lib/bind/include /usr/man/man3/getaddrinfo.3 /usr/lib/bind/include/arpa /usr/man/man3/getipnodebyname.3 /usr/lib/bind/include/arpa/inet.h /usr/man/man5/resolver.5 /usr/lib/bind/include/arpa/nameser.h /usr/man/man5/irs.conf.5 /usr/lib/bind/include/arpa/nameser_compat.h /usr/man/man5/named.conf.5 /usr/lib/bind/include/isc /usr/man/man7/hostname.7 /usr/lib/bind/include/isc/eventlib.h /usr/man/man7/mailaddr.7 /usr/lib/bind/include/isc/misc.h /usr/man/man8/named.8 /usr/lib/bind/include/isc/tree.h /usr/man/man8/ndc.8 /usr/lib/bind/include/isc/logging.h /usr/man/man8/named-xfer.8 /usr/lib/bind/include/isc/heap.h /usr/man/man8/named-bootconf.8 /usr/lib/bind/include/isc/memcluster.h /usr/man/man8/nslookup.8 /usr/lib/bind/include/isc/assertions.h /usr/man/man8/nsupdate.8 /usr/lib/bind/include/isc/list.h /usr/sbin/ndc /usr/lib/bind/include/isc/dst.h /usr/sbin/named /usr/lib/bind/include/isc/irpmarshall.h /usr/sbin/named-xfer /usr/lib/bind/include/netdb.h /usr/sbin/irpd /usr/lib/bind/include/resolv.h /usr/sbin/dnskeygen /usr/lib/bind/include/res_update.h /usr/sbin/named-bootconf /usr/lib/bind/include/irs.h /var/named /usr/lib/bind/include/irp.h   Chapter 22. Software -Server/Mail Network Table of Contents 1._Linux_Sendmail_Server 2._Compile_and_optimize 3._Configurations 4._The_/etc/sendmail.mc_file_/Central_Mail_Hub 5._Build_and_Tweak_Sendmail 5.1._The_null.mc_file 6._The_/etc/mail/access_and_access.db_files 7._The_/etc/mail/aliases_and_aliases.db_files 7.1._The_/etc/mail/_Directory 8._The_/etc/mail/local-host-names_file 8.1._Configure_the_/etc/sysconfig/sendmail_file 9._The_/etc/rc.d/init.d/sendmail_script_file 10._Secure_Sendmail_using_smrsh 11._The_/etc/mail/aliases_file 12._Limit_queue_processing_to_root 12.1._The_SMTP_greeting_message 13._Sendmail_Administrative_Tools 13.1._Sendmail_Users_Tools 14._Installed_files:_Sendmail_-Central_Mail_Hub 15._Installed_files:_Sendmail_-Local_server/client The Sendmail program is one of the most widely used Internet Mail Transport Agents -MTAs in the world. The purpose of an MTA is to send mail from one machine to another, and nothing else. Sendmail is not a client program, which you use to read your e-mail. Instead, it actually moves your email over networks, or the Internet, to where you want it to go. Sendmail has been an easy target for system crackers to exploit in the past, but with the advent of Sendmail version 8, this has become much more difficult. 1. Linux Sendmail Server In our configuration and installation we'll provide you two different configurations that you can set up for Sendmail; Central Mail Hub Relay, The Central Mail Hub Relay Server configuration will be used for your server where the assigned task is to send, receive and relay all mail for all local or neighbor client and server mail machines you may have on your network. local or neighbor clients and servers. A local or neighbor client and server refer to all other local server or client machines on your network that run Sendmail and send all outgoing mail to the Central Mail Hub for future delivery. This kind of internal client never receives mail directly via the Internet; Instead, all mail from the Internet for those computers is kept on the Mail Hub server. It is a good idea to run one Central Mail Hub Server for all computers on your network; this architecture will limit the task managements on the server and client machines, and improve the security of your site. You can configure the neighbor Sendmail so that it accepts only mail that is generated locally, thus insulating neighbor machines for easier security. The Gateway server outside the firewall, or part of it acts as a proxy and accepts external mail via its Firewall rules file that is destined for internal delivery from the outside, and forwards it to the Central Mail Hub Server. Also note that the Gateway server is configured like a neighbor Sendmail server to never accept incoming mail from the outside the Internet. Here is a graphical representation of the Sendmail configuration used in this book, with different settings: * Central Mail Hub Relay, * local or neighbor client and servers on different servers. Lots of possibilities exist, and depends on your need and network architecture. Sendmail configuration examples These installation instructions assume * Commands are Unix-compatible. * The source path is /var/tmp, other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * Sendmail version number is 8.10.1 These are the package(s) you need to download and they are available here Sendmail Homepage: http://www.sendmail.org/ Sendmail FTP Sire: 204.152.184.34 You must be sure to download: sendmail.8.10.1.tar.gz Before you decompress the tarballs, it is a good idea to make a list of files on the system before you install Sendmail, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > Sendmail1 before and find /* > Sendmail2 after you install the software, and use diff Sendmail1 Sendmail2 > Sendmail-Installed to get a list of what changed. You need to compile, so decompress the tarball (tar.gz). which you have downloaded:d [root@deep] /# cp sendmail.version.tar.gz /var/tmp [root@deep] /# cd /var/tmp [root@deep ]/tmp# tar xzpf sendmail.version.tar.gz Before you compile it is always better to configure to your needs, move into the new Sendmail directory and edit the smrsh.c file vi +77 smrsh/smrsh.c and change the line: # define CMDDIR "/usr/adm/sm.bin" To read: # define CMDDIR "/etc/smrsh" This modification specifies the default search path for commands runs by smrsh program. It allows us to limit the location where these programs may reside. 2. Compile and optimize The Build script of Sendmail uses by default a site configuration file that correspond to your operating system type to get information about definitions for system installation and various compilation values. This file is located under the subdirectory named devtools/OS and if you're running a Linux system, it'll be named Linux. We'll rebuild this site configuration file to suit our Linux system installation and put it in the default devtools/OS sub-directory of the Sendmail source distribution since the Build script will look for the default site configuration file in this directory during compile time of Sendmail. Move into the new Sendmail directory, edit the Linux file, vi devtools/OS/ Linux, and remove all predefined lines then add the following lines inside the file: define(`confENVDEF', `-DPICKY_QF_NAME_CHECK -DXDEBUG=0') define(`confCC', `egcs') define(`confOPTIMIZE', `-O9 -funroll-loops -mcpu=pentiumpro - march=pentiumpro -fomit-frame-pointer -fno-exceptions') define(`confLIBS', `-lnsl') define(`confLDOPTS', `-s') define(`confMANROOT', `/usr/man/man') define(`confMANOWN', `root') define(`confMANGRP', `root') define(`confMANMODE', `644') define(`confMAN1SRC', `1') define(`confMAN5SRC', `5') define(`confMAN8SRC', `8') define(`confDEPEND_TYPE', `CC-M') define(`confNO_HELPFILE_INSTALL) define(`confSBINGRP', `root') define(`confSBINMODE', `6755') define(`confUBINOWN', `root') define(`confUBINGRP', `root') define(`confEBINDIR', `/usr/sbin') This tells Linux file to set itself up for this particular configuration setup with: define(`confENVDEF', `-DPICKY_QF_NAME_CHECK -DXDEBUG=0') This macro option is used primarily to specify code that should either be specially included or excluded. With -DPICKY_QF_NAME_CHECK defined, Sendmail will log an error if the name of the qf file is incorrectly formed and will rename the qf file into a Qf file. The -DXDEBUG=0 argument disables the step of additional internal checking during compile time. define(`confCC', `egcs') This macro option defines the C compiler to use for compilation of Sendmail. In our case we use the egcs C compiler for better optimization. define(`confOPTIMIZE', `-O9 -funroll-loops -mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions') This macro option defines the flags passed to CC for optimization related to our specific CPU architecture. define(`confLIBS', `-lnsl') This macro option defines the -l flags passed to ld. define(`confLDOPTS', `-s') This macro option defines the linker options passed to ld. define(`confMANROOT', `/usr/man/man') This macro option defines the location to install the Sendmail man pages. define(`confMANOWN', `root') This macro option defines the owner for all Sendmail installed man pages. define(`confMANGRP', `root') This macro option defines the group for all Sendmail installed man pages. define(`confMANMODE', `644') This macro option defines the mode for all Sendmail installed man pages. define(`confMAN1SRC', `1') This macro option defines the source for man pages installed in confMAN1. define(`confMAN5SRC', `5') This macro option defines the source for man pages installed in confMAN5. define(`confMAN8SRC', `8') This macro option defines the source for man pages installed in confMAN8. define(`confDEPEND_TYPE', `CC-M') This macro option specifies how to build dependencies with Sendmail. define(`confNO_HELPFILE_INSTALL') This macro option specifies to not install the Sendmail help file by default. Some experienced administrators recommend it, for better security. define(`confSBINGRP', `root') This macro option defines the group for all Sendmail setuid binaries. define(`confSBINMODE', `6755') This macro option defines the mode for all Sendmail setuid binaries. define(`confUBINOWN', `root') This macro option defines the owner for Sendmail binaries. define(`confUBINGRP', `root') This macro option defines the group for Sendmail binaries. define(`confEBINDIR', `/usr/sbin') This macro option defines where to install binaries executed from other binaries. On Red Hat Linux the path must be set to the /usr/sbin directory. Now we must compile and install Sendmail in the server: [root@deep ]/sendmail-8.10.1# cd sendmail [root@deep ]/sendmail# sh Build [root@deep ]/sendmail# sh Build install [root@deep ]/sendmail# cd .. [root@deep ]/sendmail-8.10.1# cd mailstats [root@deep ]/mailstats# sh Build install [root@deep ]/mailstats# cd .. [root@deep ]/sendmail-8.10.1# cd smrsh [root@deep ]/smrsh# sh Build install [root@deep ]/smrsh# cd .. [root@deep ]/sendmail-8.10.1# cd makemap 1 [root@deep ]/makemap# sh Build install 2 [root@deep ]/makemap# cd .. [root@deep ]/sendmail-8.10.1# cd praliases 3 [root@deep ]/praliases# sh Build install 4 [root@deep ]/praliases# cd .. [root@deep ]/sendmail-8.10.1# ln -fs /usr/sbin/sendmail /usr/lib/ sendmail [root@deep ]/sendmail-8.10.1# chmod 511 /usr/sbin/smrsh [root@deep ]/sendmail-8.10.1# install -d -m 755 /var/spool/mqueue [root@deep ]/sendmail-8.10.1# chown root.mail /var/spool/mqueue [root@deep ]/sendmail-8.10.1# mkdir /etc/smrsh _1_ Required only for Mail Hub configuration _2_ Required only for Mail Hub configuration _3_ Required only for Mail Hub configuration _4_ Required only for Mail Hub configuration * The sh Build command would build and make the necessary dependencies for the different binary files required by Sendmail before installation on your system. * The sh Build install command would install sendmail, mailstats, makemap, praliases, smrsh binaries as well as the corresponding man pages on your system if compiled with this command. * The ln -fs command would make a symbolic link of the sendmail binary to the / usr/lib directory. This is required, since some programs hope to find the sendmail binary in this directory /usr/lib. * The install command would create the directory mqueue with permission 755 under /var/spool. A mail message can be temporarily undeliverable for a wide variety of reasons. To ensure that such messages are eventually delivered, Sendmail stores them in its queue directory until they can be delivered successfully. * The chown command would set UID root and GID mail for the mqueue directory. * The mkdir command would create the /etc/smrsh directory on your system. This directory is where we'll put all program mailers that we allow Sendmail to be able to run. Note The programs makemap, and praliases must only be installed on the Central Mail Hub Server. makemap permits you to create a database map like the /etc/mail/ aliases.db or /etc/mail/access.db files, for Sendmail. The praliases display the system mail aliases, the content of /etc/mail/aliases file. Since it is better to only have one place like our Central Mail Hub to handle and manage all the db files in our network, then it is not necessary to use the makemap, and praliases programs and build db files on your other hosts in the network. 3. Configurations Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example Sendmail configuration file are organised like this: total 32 -rw-r--r-- 1 harrypotter harrypotter 684 Jun 8 13:00 Linux -rw-r--r-- 1 harrypotter harrypotter 3648 Jun 8 13:00 access -rw-r--r-- 1 harrypotter harrypotter 547 Jun 8 13:00 aliases drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 init.d/ -rw-r--r-- 1 harrypotter harrypotter 137 Jun 8 13:00 local- host-names -rw-r--r-- 1 harrypotter harrypotter 109 Jun 8 13:00 null.mc -rw-r--r-- 1 harrypotter harrypotter 685 Jun 8 13:00 sendmail.mc drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 sysconfig/ You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run a Central Mail Hub Server, the following files are required and must be created or copied to the appropriate directories on your server. * Copy the sendmail file in the /etc/sysconfig directory. * Copy the sendmail script file in the /etc/rc.d/init.d/ directory. * Copy the local-host-names file in the /etc/mail directory. * Copy the access file in the /etc/mail directory. * Copy the aliases file in the /etc/mail directory. Create the virtusertable, domaintable, mailertable and .db files in /etc/mail directory. To run a Local or Neighbor Client, Server, the following files are required and must be created or copied to the appropriate directories on your server. * Copy the sendmail file in the /etc/sysconfig directory. * Copy the sendmail script file in the /etc/rc.d/init.d/ directory. * Copy the local-host-names file in the /etc/mail directory. Tip You can obtain the configuration files listed below on our floppy.tgz archive. Copy the following files from the decompressed floppy.tgz archive to the appropriate places or copy and paste them directly from this book to the concerned file. 4. The /etc/sendmail.mc file /Central Mail Hub The /etc/sendmail.mc file for the Central Mail Hub, instead of having each individual server or workstation in a network handle its own mail, it can be advantageous to have powerful central server that handles all mail. Such a server is called a Mail Hub. The advantage of a Central Mail Hub is: i. All incoming mail is sent to the hub, and no mail is sent directly to a client machine. ii. All outgoing mail from clients is sent to the Hub, and the Hub then forwards that mail to its ultimate destination. iii. All outgoing mail appears to come from a single server and no client's name needs to be known to the outside world. iv. No client needs to run a sendmail daemon to listen for mail. The sendmail.cf is the first file reading by Sendmail when it runs and one of the most important for Sendmail. Among the many items contained in that file are the locations of all the other files, the default permissions for those files and directories that Sendmail needs. The m4 macro preprocessor program of Linux is used by Sendmail V8 to produce a Sendmail configuration file. This macro program will produce the /etc/mail/sendmail.cf configuration file by processing a file whose name ends in .mc. For this reason, we'll create this file sendmail.mc and put the necessary macro values in it to allow the m4 program to process, read its input and gathers definitions of macros, and then replaces those macros with their values and output the result to create our sendmail.cf file. Please refer to the Sendmail documentation and README file under the cf subdirectory of the V8 Sendmail source distribution for more information. Create the sendmail.mc file, touch /var/tmp/sendmail-version/cf/cf/sendmail.mc and add the following lines: define(`confDEF_USER_ID',``8:12'')dnl OSTYPE(`linux')dnl DOMAIN(`generic')dnl define(`confTRY_NULL_MX_LIST',true)dnl define(`confDONT_PROBE_INTERFACES',true)dnl define(`PROCMAIL_MAILER_PATH',`/usr/bin/procmail')dnl define(`LOCAL_MAILER_FLAGS', `ShPfn')dnl define(`LOCAL_MAILER_ARGS', `procmail -a $h -d $u')dnl FEATURE(`smrsh',`/usr/sbin/smrsh')dnl FEATURE(`mailertable')dnl FEATURE(`virtusertable',`hash -o /etc/mail/virtusertable')dnl FEATURE(`redirect')dnl FEATURE(`always_add_domain')dnl FEATURE(`use_cw_file')dnl FEATURE(`local_procmail')dnl FEATURE(`access_db')dnl FEATURE(`blacklist_recipients')dnl FEATURE(`dnsbl')dnl MAILER(`local')dnl MAILER(`smtp')dnl MAILER(`procmail')dnl This tells the sendmail.mc file to set itself up for this particular configuration with: define(`confDEF_USER_ID',``8:12'')dnl This configuration option specifies the default user id. In our case the user mail and group mail, which correspond to ID number 8:12 see the / etc/passwd and /etc/group file. OSTYPE(`linux')dnl This configuration option specifies the default operating system Sendmail wil bel running on; in our case the linux system. This item is one of the minimal pieces of information required by the mc file. DOMAIN(`generic')dnl This configuration option will specify and describe a particular domain appropriated for your environment. define(`confTRY_NULL_MX_LIST',true)dnl This configuration option specifies whether the receiving server is the best MX for a host and if so, try connecting to that host directly. define(`confDONT_PROBE_INTERFACES',true)dnl This configuration option, if set to true, means Sendmail will _not_insert the names and addresses of any local interfaces into the $=w class, list of known equivalent addresses. define(`PROCMAIL_MAILER_PATH',`/usr/bin/procmail')dnl This configuration option sets the path to the procmail program installed in your server. Since the path in Red Hat Linux differs from other Linux versions, we must specify the new path with this macro. It's important to note that this macro is also used by FEATURE(`local_procmail') as defined later in this file. define(`LOCAL_MAILER_FLAGS', `ShPfn')dnl This configuration option defines the flags that must be used by the local mailer (procmail). See your Sendmail documentation for more information of each one. define(`LOCAL_MAILER_ARGS', `procmail -a $h -d $u')dnl This configuration option defines the arguments that must be passed to the local mailer (procmail). See your Sendmail documentation for more information on each one. FEATURE(`smrsh',`/usr/sbin/smrsh')dnl This m4 macro enables the use of smrsh, the sendmail restricted shell, instead of the default /bin/sh for mailing programs. With this feature you can control what program gets run via e-mail through the /etc/mail/ aliases and ~/.forward files. The default location for the smrsh program is /usr/libexec/smrsh. Since we have installed smrsh in another location, we need to add an argument to the smrsh feature to indicate the new placement /usr/sbin/smrsh. The use of smrsh is recommended by CERT, so you are encouraged to use this feature as often as possible. FEATURE(`mailertable')dnl This m4 macro enables the use of mailertable database selects new delivery agents. A mailertable is a database that maps host.domain names to special delivery agent and new domain name pairs. With this feature, mail can be delivered through the use of a specified or particular delivery agent to a new domain name. Usually, this feature must be available only on a Central Mail Hub server. FEATURE(`virtusertable',`hash -o /etc/mail/virtusertable')dnl This m4 macro enables the use of virtusertable, support for virtual domains, which allow multiple virtual domains to be hosted on one machine. A virtusertable is a database that maps virtual domains into new addresses. With this feature, mail for virtual domains can be delivered to a local, remote, or single user address. Usually this feature must be available only on a Central Mail Hub server. FEATURE(`redirect')dnl This m4 macro enables the use of redirect support for address.REDIRECT. With this feature, mail addressed to a retired user account wahib, for example, will be bounced with an indication of the new forwarding address. The retired accounts must be set up in the aliases file on the mail server. Usually this feature must be available only on a Central Mail Hub server. FEATURE(`always_add_domain')dnl This m4 macro enables the use of always_add_domain, add the local domain even on local mail. With this feature, all addresses that are locally delivered will be fully qualified. It is safe and recommended to set this feature for security reasons. FEATURE(`use_cw_file')dnl This m4 macro enables the use of use_cw_file, use /etc/mail/local-host- names file for local hostnames. With this feature you can declare a list of hosts in the /etc/mail/local-host-names file for which the local host is acting as the MX recipient. In other word this feature causes the file /etc/mail/local-host-names to be read to obtain alternative names for the local host. FEATURE(`local_procmail')dnl This m4 macro enables the use of local_procmail use procmail as local delivery agent. With this feature you can use procmail as a Sendmail delivery agent. FEATURE(`access_db')dnl This m4 macro enables the access database feature. With this feature you have the ability through the access db to allow or refuse to accept mail from specified domains. Usually this feature must be available only in a Central Mail Hub server. FEATURE(`blacklist_recipients')dnl This m4 macro enables the ability to block incoming mail for certain recipient usernames, hostnames, or addresses. With this feature you can, for example, block incoming mail to user nobody, host foo.mydomain.com, or guest@bar.mydomain.com. FEATURE(`dnsbl')dnl This m4 macro enables Sendmail to reject mail from any site in the Realtime Blackhole List database rbl.maps.vix.com. The DNS based rejection is a database maintained in DNS of spammers. For details, see http://maps.vix.com/rbl/. MAILER(`local'), MAILER(`smtp'), and MAILER(`procmail')dnl This m4 macro enables the use of local, smtp, and procmail as delivery agents in Sendmail by default, delivery agents are not automatically declared. With this feature, you can specify which ones you want to support and which ones to ignore. The MAILER(`local'), MAILER(`smtp'), and MAILER(`procmail') options cause support for local, smtp, esmtp, smtp8, relay delivery agents and procmail to be included. It's important to note that MAILER(`smtp') should always precede MAILER(`procmail'). Note Sometimes, a domain with which you wish to continue communications may end up in the RBL list. In this case, Sendmail allows you to override these domains to allow their e-mail to be received. To do this, simply edit the /etc/mail/access file and add the appropriate domain information. Example 22.1. Overriding RBL blacklisted.domain OK 5. Build and Tweak Sendmail Now that our macro configuration file sendmail.mc is created, we can build the sendmail configuration file sendmail.cf from these statements with the following commands: [root@deep] /# cd /var/tmp/sendmail-version/cf/cf/ [root@deep ]/cf# m4 ../m4/cf.m4 sendmail.mc > /etc/mail/ sendmail.cf Note Here, the ../m4/cf.m4 tells m4 program where to look for its default configuration file information. 5.1. The null.mc file Since our local clients machines never receive mail directly from the outside world, and relay, send all their mail through the Mail Hub server, we will create a special file called null.mc which, when later processed, will create a customized sendmail.cf configuration file that responds to this special setup for our neighbour or local server client machines. This m4 macro file is simple to create and configure because it doesn't need a lot of features, as the configuration file -sendmail.mc, for the Central Mail Hub server did. Caution The null.mc file is for the local or neighbour client and server machines only 1. Create the null.mc file, touch /var/tmp/sendmail-version/cf/cf/null.mc and add the following lines: OSTYPE(`linux')dnl 1 DOMAIN(`generic')dnl 2 FEATURE(`nullclient',`mail.openna.com')dnl 3 undefine(`ALIAS_FILE')dnl 4 _1_ This configuration option specifies the default operating system Sendmail will be running on, in our case, the linux system. This item is one of the minimal pieces of information required by the mc file. _2_ This configuration option will specify and describe a particular domain appropriated for your environment. _3_ This m4 macro sets your clients machines to never receive mail directly, to send their mail to a Central Mail Hub, and relay all mail through that server rather than sending directly. This feature creates a stripped down configuration file containing nothing but support for forwarding all mail to a Mail Hub via a local SMTP-based network. The argument `mail.openna.com' included in this feature is the canonical name of that Mail Hub. You should, of course, change this canonical name to reflect your Mail Hub Server for example: FEATURE (`nullclient',` my.mailhub.com'). _4_ This configuration option prevents the nullclient version of Sendmail from trying to access /etc/mail/aliases and /etc/mail/aliases.db files. With the adding of this line in the .mc file, you don't need to have an aliases file on all your internal neighbor client Sendmail machines. Aliases files are required only on the Mail Hub Server for all server and client aliases on the network. Tip We advice that with this kind of configuration, no mailers should be defined, and no aliasing or forwarding is done. 2. Now that our macro configuration file null.mc is created, we can build the Sendmail configuration file sendmail.cf from these statements in all our neighbor servers, and client machines with the following commands: [root@deep] /# cd /var/tmp/sendmail-version/cf/cf/ [root@deep ]/cf# m4 ../m4/cf.m4 null.mc > /etc/mail/ sendmail.cf 3. No mail should ever again be delivered to your local machine. Since there will be no incoming mail connections, you no longer needed to run a Sendmail daemon on your neighbor or local server, client machines. To stop the Sendmail daemon from running on your neighbor or local server, or client machines, edit or create the /etc/sysconfig/sendmail file and change/add the lines that read: DAEMON=yes To read: DAEMON=no And: QUEUE=1h Note The QUEUE=1h under /etc/sysconfig/sendmail file causes Sendmail to process the queue once every 1 hour. We leave that line in place because Sendmail still needs to process the queue periodically in case the Mail Hub is down. 4. Remove the following files from your system, use the following command: [root@client /]# rm -f /usr/bin/newaliases [root@client /]# rm -f /usr/man/man1/newaliases.1 [root@client /]# rm -f /usr/man/man5/aliases.5 Note Local machines never use aliases, access, or other maps database. Since all map file databases are located and used on the Central Mail Hub Server for all local machines we may have on the network, we can safety remove the following commands and man pages from all our local machines. o /usr/bin/newaliases o /usr/man/man1/newaliases.1 o /usr/man/man5/aliases.5 5. Remove the unnecessary Procmail program from your entire local Sendmail server or client. Since local machines send all internal and outgoing mail to the mail Hub Server for future delivery, we don't need to use a complex local delivery agent program like Procmail to do the job. Instead we can use the default /bin/mail program. To remove Procmail from your system, use the following command: [root@client ]# rpm -e procmail 6. The /etc/mail/access and access.db files The access database file can be created to accept or reject mail from selected domains. For example, you may choose to reject all mail originating from known spammers, or to accept to relay all mail from your local network since now relaying is denied by default with Sendmail -this is an Anti-Spam feature. In the access file example below, we'll allow relaying from localhost and all local network addresses beginning with the IP address 192.168.1. The files access and access.db are not required for Local or Neighbor Client setups. It is required only if you decide to set up a Central Mail Hub to handle all your mail. Also note that the use of a Central Mail Hub will improve the security and the management of other servers and clients on your network that run Sendmail. 1. Create the access file touch /etc/mail/access and add the following lines: # Description showing bellow for the format of this file comes from # the Sendmail source distribution under "cf/README" file. # # The table itself uses e-mail addresses, domain names, and network # numbers as keys. For example, # # spammer@aol.com REJECT # cyberspammer.com REJECT # 192.168.212 REJECT # # would refuse mail from spammer@aol.com, any user from cyberspammer.com # (or any host within the cyberspammer.com domain), and any host on the # 192.168.212.* network. # # The value part of the map can contain: # # OK Accept mail even if other rules in the # running ruleset would reject it, for example, # if the domain name is unresolvable. # RELAY Accept mail addressed to the indicated domain or # received from the indicated domain for relaying # through your SMTP server. RELAY also serves as # an implicit OK for the other checks. # REJECT Reject the sender or recipient with a general # purpose message. # DISCARD Discard the message completely using the # $#discard mailer. This only works for sender # addresses (i.e., it indicates that you should # discard anything received from the indicated # domain). # ### any text where ### is an RFC 821 compliant error code # and "any text" is a message to return for # the command. # # For example: # # cyberspammer.com 550 We don't accept mail from spammers # okay.cyberspammer.com OK # sendmail.org OK # 128.32 RELAY # # would accept mail from okay.cyberspammer.com, but would reject mail # from all other hosts at cyberspammer.com with the indicated message. # It would allow accept mail from any hosts in the sendmail.org domain, # and allow relaying for the 128.32.*.* network. # # You can also use the access database to block sender addresses based on # the username portion of the address. For example: # # FREE.STEALTH.MAILER@ 550 Spam not accepted # # Note that you must include the @ after the username to signify that # this database entry is for checking only the username portion of the # sender address. # # If you use like we do in our "sendmail.mc macro configuration: # # FEATURE(`blacklist_recipients') # # then you can add entries to the map for local users, hosts in your # domains, or addresses in your domain which should not receive mail: # # badlocaluser 550 Mailbox disabled for this username # host.mydomain.com 550 That host does not accept mail # user@otherhost.mydomain.com 550 Mailbox disabled for this recipient # # This would prevent a recipient of badlocaluser@mydomain.com, any # user at host.mydomain.com, and the single address # user@otherhost.mydomain.com from receiving mail. Enabling this # feature will keep you from sending mails to all addresses that # have an error message or REJECT as value part in the access map. # Taking the example from above: # # spammer@aol.com REJECT # cyberspammer.com REJECT # # Mail can't be sent to spammer@aol.com or anyone at cyberspammer.com. # # Now our configuration of access file, # by default we allow relaying from localhost... localhost.localdomain RELAY localhost RELAY 127.0.0.1 RELAY 192.168.1 RELAY Note Don't forget to specify in this file access your private IP address range you want to relay or you'll be unable to send mail from your internal network. 2. Create the access.db file, remember, since /etc/mail/access is a database, after creating the text file as described above, you must use the makemap utility program to create the database map. To create the access database map, use the following command: [root@deep] /# makemap hash /etc/mail/access.db < /etc/mail/ access 7. The /etc/mail/aliases and aliases.db files Aliasing is the process of converting one local recipient name on the system into another -aliasing occurs only on local names. Example uses are to convert a generic name -such as root, into a real username on the system, or to convert one name into a list of many names -for mailing lists. For every envelope that lists a local user as a recipient, Sendmail looks up that recipient's name in the aliases file. Because Sendmail may have to search through thousands of names in the aliases file, a copy of the file is stored in a separate db database format file to significantly improve lookup speed. If you configure your Sendmail to use a Central Server Mail Hub to handles all mail, you don't need to install the aliases and aliases.db files on the neighbor server or client machines. 1. Create the aliases file touch /etc/mail/aliases and add the following lines by default: # # @(#)aliases 8.2 (Berkeley) 3/5/94 # # Aliases in this file will NOT be expanded in the header from # Mail, but WILL be visible over networks or from /bin/mail. # # >>>>>>>>>> The program "newaliases" must be run after # >> NOTE >> this file is updated for any changes to # >>>>>>>>>> show through to sendmail. # # Basic system aliases -- these MUST be present. MAILER-DAEMON: postmaster postmaster: root # General redirections for pseudo accounts. bin: root daemon: root nobody: root # Person who should get root's mail #root: admin Note Your aliases file will be probably far more complex, but even so, note how the example shows the minimum form of aliases. 2. Since /etc/mail/aliases is a database, after creating the text file as described above, you must use the makemap program to create the database map. To create the aliases database map, use the following command: [root@deep] /# makemap hash /etc/mail/aliases.db < /etc/mail/ aliases 7.1. The /etc/mail/ Directory The * /etc/mail/virtusertable, * domaintable * mailertable and * virtusertable.db, * domaintable.db, * mailertable.db All of these files relate to particular features of Sendmail that can be tuned by the system administrator. Once again, these features are usually required only in the Central Mail Hub server. The following is the explanation of each one. The virtusertable & virtusertable.db files A virtusertable is a database that maps virtual domains into news addresses. With this feature, mail for virtual domain on your network can be delivered to local, remote, or a single user address. The domaintable & domaintable.db files A domaintable is a database that maps old domain to a new one. With this feature, multiple domain names on your network can be rewritten from the old domain to the new. The mailertable & mailertable.db files A mailertable is a database that maps host.domain names to special delivery agent and new domain name pairs. With this feature mail on your network can be delivered through the use of a particular delivery agent to a new local or remote domain name. To create the virtusertable, domaintable, mailertable, and their corresponding .db files into /etc/mail directory, use the following commands: [root@deep] /# for map in virtusertable domaintable mailertable > do > touch /etc/mail/${map} > chmod 0644 /etc/mail/${map} > makemap hash /etc/mail/${map}.db < /etc/mail/${map} > chmod 0644 /etc/mail/${map}.db > done 8. The /etc/mail/local-host-names file Note Please note that the /etc/mail/local-host-names file is for all type of configuration. The /etc/mail/local-host-names file is read to obtain alternative names for the local host. One use for such a file might be to declare a list of hosts in your network for which the local host is acting as the MX recipient. On that machine we simply need to add the names of machines for which it i.e. mail.openna.com, will handle mail to /etc/mail/local-host-names. Here is an example: Example 22.2. Alternative names Create the local-host-names file, touch /etc/mail/local-host-names and add the following line: # local-host-names - include all aliases for your machine here. openna.com deep.openna.com www.openna.com win.openna.com mail.openna.com With this type of configuration, all mail sent will appear as if it were sent from openna.com, and any mail sent to www.openna.com or the other hosts will be delivered to mail.openna.com our mail Hub. Caution Please be aware that if you configure your system to masquerade as another, any e-mail sent from your system to your system will be sent to the machine you are masquerading as. For example, in the above illustration, log files that are periodically sent to by the cron daemon of Linux would be sent to our Mail Hub. 8.1. Configure the /etc/sysconfig/sendmail file The /etc/sysconfig/sendmail file is used to specify SENDMAIL configuration information, such as if sendmail should run as a daemon, if it should listen for mail or not, and how much time to wait before sending a warning if messages in the queue directory have not been delivered. Create the sendmail file touch /etc/sysconfig/sendmail and add in this file: DAEMON=yes 1 QUEUE=1h 2 _1_ The DAEMON=yes option instructs Sendmail to run as a daemon. This line is useful when Sendmail client machines are configured to not accept mail directly from outside in favor of forwarding all local mail to a Central Hub, not running a daemon also improves security. If you have configured your server or client machines in this way, all you have to do is to replace the DAEMON=yes to DAEMON=no. _2_ Mail is usually placed into the queue because it could not be transmitted immediately. The QUEUE=1h sets the time interval before sends a warning to the sender if the messages has not been delivered. 9. The /etc/rc.d/init.d/sendmail script file Note Please note that the /etc/rc.d/init.d/sendmail file is for all type of configuration. To configure your /etc/rc.d/init.d/sendmail script file to start and stop the Sendmail daemon, You have to create the sendmail script file, touch /etc/rc.d/ init.d/sendmail and add: #!/bin/sh # # sendmail This shell script takes care of starting and stopping # sendmail. # # chkconfig: 2345 80 30 # description: Sendmail is a Mail Transport Agent, which is the program \ # that moves mail from one machine to another. # processname: sendmail # config: /etc/sendmail.cf # pidfile: /var/run/sendmail.pid # Source function library. . /etc/rc.d/init.d/functions # Source networking configuration. . /etc/sysconfig/network # Source sendmail configuration. if [ -f /etc/sysconfig/sendmail ] ; then . /etc/sysconfig/sendmail else DAEMON=yes QUEUE=1h fi # Check that networking is up. [ ${NETWORKING} = "no" ] && exit 0 [ -f /usr/sbin/sendmail ] || exit 0 RETVAL=0 # See how we were called. case "$1" in start) # Start daemons. echo -n "Starting sendmail: " /usr/bin/newaliases > /dev/null 2>&1 for i in virtusertable access domaintable mailertable ; do if [ -f /etc/mail/$i ] ; then makemap hash /etc/mail/$i < /etc/mail/$i fi done daemon /usr/sbin/sendmail $([ "$DAEMON" = yes ] && echo -bd) \ $([ -n "$QUEUE" ] && echo -q$QUEUE) RETVAL=$? echo [ $RETVAL -eq 0 ] && touch /var/lock/subsys/sendmail ;; stop) # Stop daemons. echo -n "Shutting down sendmail: " killproc sendmail RETVAL=$? echo [ $RETVAL -eq 0 ] && rm -f /var/lock/subsys/sendmail ;; restart|reload) $0 stop $0 start RETVAL=$? ;; status) status sendmail RETVAL=$? ;; *) echo "Usage: sendmail {start|stop|restart|status}" exit 1 esac exit $RETVAL Now, make this script executable and change its default permissions: [root@deep] /# chmod 700 /etc/rc.d/init.d/sendmail Create the symbolic rc.d links for Sendmail with the command: [root@deep] /# chkconfig --add sendmail Start your Sendmail Server manually with the following command: [root@deep] /# /etc/rc.d/init.d/sendmail start Starting sendmail: [ OK ] Please do a cleanup as always later: [root@deep] /# cd /var/tmp [root@deep ]/tmp# rm -rf sendmail-version/ sendmail.version.tar.gz The rm command as used above will remove all the source files we have used to compile and install Sendmail. It will also remove the Sendmail compressed archive from the /var/tmp directory. 10. Secure Sendmail using smrsh The smrsh program is intended as a replacement for /bin/sh in the program mailer definition of Sendmail. It's a restricted shell utility that provides the ability to specify, through the /etc/smrsh directory, an explicit list of executable programs available to Sendmail. To be more accurate, even if somebody with malicious intentions can get Sendmail to run a program without going through an aliases or forward file, smrsh limits the set of programs that he or she can execute. When used in conjunction with Sendmail, smrsh effectively limits Sendmail's scope of program execution to only those programs specified in smrsh's directory. If you have followed what we did above, smrsh program is already compiled and installed on your computer under /usr/sbin/ smrsh. 1. The first thing we need to do is to determine the list of commands that smrsh should allow Sendmail to run. By default we include, but are not limited to: o /bin/mail -if you have it installed on your system o /usr/bin/procmail -if you have it installed on your system Warning You should not include interpreter programs such as sh(1), csh(1), perl (1), uudecode(1) or sed(1) -the stream editor, in your list of acceptable commands. 2. You will next need to populate the /etc/smrsh directory with the programs that are allowable for Sendmail to execute. To prevent duplicate programs, and do a nice job, it is better to establish links to the allowable programs from /etc/smrsh rather than copy programs to this directory. To allow the mail program /bin/mail, use the following commands: [root@deep] /# cd /etc/smrsh [root@deep ]/smrsh# ln -s /bin/mail mail To allow the procmail program /usr/bin/procmail, use the following commands: [root@deep] /# cd /etc/smrsh [root@deep ]/smrsh# ln -s /usr/bin/procmail procmail This will allow the mail and procmail programs to be run from a user's .forward file or an aliases file which uses the program syntax. Important Procmail is required only in Mail Hub Server and not in Local Client Mail Server. If you've configured your system like a Mail Hub Server then make the link with procmail as explained above, if you've configured your system as a Local Client Server then skip the procmail step above. 3. We can now configure Sendmail to use the restricted shell. The program mailer is defined by a single line in the Sendmail configuration file, / etc/mail/sendmail.cf. You must modify this single line Mprog definition in the sendmail.cf file, by replacing the /bin/sh specification with /usr/ sbin/smrsh. Edit the sendmail.cf file, vi /etc/mail/sendmail.cf and change the line: Example 22.3. sendmail.cf Mprog, P=/bin/sh, F=lsDFMoqeu9, S=10/30, R=20/40, D=$z:/, T=X- Unix, A=sh -c $u Which should be changed to: Mprog, P=/usr/sbin/smrsh, F=lsDFMoqeu9, S=10/30, R=20/40, D=$z:/, T=X-Unix, A=sh -c $u 4. Now re-start the sendmail process manually with the following command: [root@deep] /# /etc/rc.d/init.d/sendmail restart Note In our sendmail.mc configuration file for the Mail Hub Server above, we have already configured this line Mprog to use the restricted shell /usr/sbin/smrsh with the m4 macro FEATURE(`smrsh',`/usr/sbin/smrsh'), so don't be surprised if the /usr/sbin/smrshspecification is already set in your /etc/mail/sendmail.cf file for the Mail Hub relay. Instead, use the technique shown above for other /etc/mail/sendmail.cf files in your network like the one for the nullclient local or neighbor client and servers that use the null.mc macro configuration file to generate the /etc/ mail/sendmail.cf file. 11. The /etc/mail/aliases file A poorly or carelessly administered aliases file can easily be used to gain privileged status. For example, many vendors ship systems with a decode alias in the /etc/mail/aliases file. The intention is to provide an easy way for users to transfer binary files using mail. At the sending site the user converts the binary to ASCII with uuencode, then mails the result to the decode alias at the receiving site. That alias pipes the mail message through the / usr/bin/uuencode program, which converts the ASCII back into the original binary file. Remove the decode alias line from your /etc/mail/aliases file. Similarly, every alias that executes a program that you did not place there yourself and check completely should be questioned and probably removed. Edit the aliases file vi /etc/mail/aliases and remove the following lines: # Basic system aliases -- these MUST be present. MAILER-DAEMON: postmaster postmaster: root # General redirections for pseudo accounts. bin: root daemon: root games: root 1 ingres: root 2 nobody: root system: root 3 toor: root 4 uucp: root 5 # Well-known aliases. manager: root 6 dumper: root 7 operator: root 8 # trap decode to catch security attacks decode: root 9 # Person who should get root's mail #root: marc _1_ _2_ _3_ _4_ _5_ _6_ _7_ _8_ _9_ Remove all these lines For the changes to take effect you will need to run: [root@deep] /# /usr/bin/newaliases You need to prevent your Sendmail being abused by unauthorized users, Sendmail now includes powerful Anti-Spam features, which can help prevent your mail server from being abused by unauthorized users. To do this, make a change to the configuration file to block off spammers. Edit the sendmail.cf file, vi / etc/mail/sendmail.cf and change the line: O PrivacyOptions=authwarnings To read: O PrivacyOptions=authwarnings,goaway Setting the goaway option causes Sendmail to disallow all SMTP EXPN commands, it also causes it to reject all SMTP VERB commands and to disallow all SMTP VRFY commands. These changes prevent spammers from using the EXPN and VRFY commands in Sendmail. You have to restrict who can examine the queues contents, ordinarily, anyone may examine the mail queue's contents by using the mailq command. To restrict who may examine the queues contents, you must specify the restrictmailq option in the /etc/mail/sendmail.cf file. With this option, Sendmail allows only users who are in the same group as the group ownership of the queue directory root to examine the contents. This allows the queue directory to be fully protected with mode 0700, while selected users are still able to see the contents. Edit the sendmail.cf file, vi /etc/mail/sendmail.cf and change the line: O PrivacyOptions=authwarnings,goaway To read: O PrivacyOptions=authwarnings,goaway,restrictmailq Now we change the mode of our queue directory to be fully protected: [root@deep] /# chmod 0700 /var/spool/mqueue Now re-start the sendmail process manually for the change to take effect: [root@deep] /# /etc/rc.d/init.d/sendmail restart Shutting down sendmail: [ OK ] Starting sendmail: [ OK ] Tip We have already added the goaway option to the line PrivacyOptions= in sendmail.cf file. Now we can just add the restrictmailq option to this line. Any non-privileged user who attempts to examine the mail queue content will get this message: [user@deep /]$ /usr/bin/mailq You are not permitted to see the queue 12. Limit queue processing to root Ordinarily, anyone may process the queue with the -q switch. To limit queue processing to root and the owner of the queue directory, you must specify the restrictqrun option in the /etc/mail/sendmail.cf file. Edit the sendmail.cf file, vi /etc/mail/sendmail.cf and change the line: O PrivacyOptions=authwarnings,goaway,restrictmailq To read: O PrivacyOptions=authwarnings,goaway,restrictmailq,restrictqrun Now re-start the sendmail process manually for the change to take effect: [root@deep] /# /etc/rc.d/init.d/sendmail restart Shutting down sendmail: [ OK ] Starting sendmail: [ OK ] Any non-privileged user who attempts to process the queue will get this message: [user@deep /]$ /usr/sbin/sendmail -q You do not have permission to process the queue 12.1. The SMTP greeting message When Sendmail accepts an incoming SMTP connection it sends a greeting message to the other host. This message identifies the local machine and is the first thing it sends to say it is ready. Edit the sendmail.cf file, vi /etc/mail/sendmail.cf and change the line: O SmtpGreetingMessage=$j Sendmail $v/$Z; $b To read: O SmtpGreetingMessage=$j Now re-start the sendmail process manually for the change to take effect: [root@deep] /# /etc/rc.d/init.d/sendmail restart Shutting down sendmail: [ OK ] Starting sendmail: [ OK ] Tip This change doesn't actually affect anything, but was recommended by folks in the news.admin.net-abuse.email newsgroup as a legal precaution. It modifies the banner, which Sendmail displays upon receiving a connection. Do set the immutable bit on important Sendmail files, important Sendmail files can be set immutable for better security with the chattr command of Linux. A file with the +i attribute cannot be modified, deleted or renamed. No link can be created to this file, and no data can be written to the file. Only the super-user can set or clear this attribute. 1. Set the immutable bit on the sendmail.cf file: [root@deep] /# chattr +i /etc/mail/sendmail.cf 2. Set the immutable bit on the local-host-names file: [root@deep] /# chattr +i /etc/mail/local-host-names 3. Set the immutable bit on the aliases file: [root@deep] /# chattr +i /etc/mail/aliases 4. Set the immutable bit on the access file: [root@deep] /# chattr +i /etc/mail/access Further documentation and for more details, there are several man pages you can read: aliases(5) - aliases file for sendmail makemap(8) - create database maps for sendmail sendmail(8) - an electronic mail transport agent mailq(1) - print the mail queue newaliases(1) - rebuild the data base for the mail aliases file mailstats(8) - display mail statistics praliases(8) - display system mail aliases 13. Sendmail Administrative Tools The commands listed below are some that we use often, but many more exist. Check the man page and documentation for more details and information. newaliases.  The purpose of the newaliases program utility of Sendmail is to rebuild and update the random access database for the mail aliases file /etc/ mail/aliases. It must be run each time you change the contents of this file in order for the changes to take effect. To update the aliases file with the newaliases utility, use the following command: [root@deep] /# /usr/bin/newaliases makemap.  The purpose of the makemap program utility is to create the database maps in Sendmail. The makemap command must be used only when you need to create a new database for file like aliases, access, or domaintable, mailertable, and virtusertable. To run makemap to create a new database for access, use the following command: [root@deep] /# makemap hash /etc/mail/access.db < /etc/mail/access * Where is the database format, makemap can handles up to three different database formats; they may be hash, btree or dbm. * The /etc/mail/access.db is the location and the name of the new database that will be created. * The /etc/mail/access is the location of the file from where makemap will read from the standard input file. In our example, we have created a new access.db file with the makemap command above. To create a database for other files like aliases, domaintable, mailertable, and virtusertable, you must indicate the location and name of the corresponding file in the makemap command. mailq.  The purpose of the mailq program utility is to print a summary of the mail messages queued for future delivery. To print a summary of the mail messages queued, use the following command: [root@deep] /# mailq Mail queue is empty 13.1. Sendmail Users Tools The commands listed below are some that we use often, but many more exist. Check the man page and documentation for more details and information. mailstats.  The purpose of the mailstats program utility is to displays contents of the current mail statistics. To displays the current mail statistics, use the following command: [root@deep] /# mailstats Statistics from Tue Dec 14 20:31:48 1999 M msgsfr bytes_from msgsto bytes_to msgsrej msgsdis Mailer 5 0 0K 1 3K 0 0 esmtp 8 1259 19618K 1259 19278K 0 0 local ============================================================= T 1259 19618K 1260 19281K 0 0 praliases.  The purpose of the praliases program utility is to display one per line, in no particular order the contents of the current system mail aliases. To displays the current system aliases, use the following command: [root@deep] /# praliases postmaster:root daemon:root root:admin @:@ mailer-daemon:postmaster bin:root nobody:root webadmin:admin www:root 14. Installed files: Sendmail -Central Mail Hub Files Installed for Sendmail Central Mail Hub configuration are: /etc/rc.d/init.d/sendmail /etc/mail/local-host-names /etc/rc.d/rc0.d/K30sendmail /etc/smrsh /etc/rc.d/rc1.d/K30sendmail /usr/bin/newaliases /etc/rc.d/rc2.d/S80sendmail /usr/bin/mailq /etc/rc.d/rc3.d/S80sendmail /usr/bin/hoststat /etc/rc.d/rc4.d/S80sendmail /usr/bin/purgestat /etc/rc.d/rc5.d/S80sendmail /usr/lib/sendmail /etc/rc.d/rc6.d/K30sendmail /usr/man/man1/mailq.1 /etc/sysconfig/sendmail /usr/man/man1/newaliases.1 /etc/mail /usr/man/man5/aliases.5 /etc/mail/statistics /usr/man/man8/sendmail.8 /etc/mail/sendmail.cf /usr/man/man8/mailstats.8 /etc/mail/access /usr/man/man8/makemap.8 /etc/mail/access.db /usr/man/man8/praliases.8 /etc/mail/aliases /usr/man/man8/smrsh.8 /etc/mail/aliases.db /usr/sbin/sendmail /etc/mail/virtusertable /usr/sbin/mailstats /etc/mail/virtusertable.db /usr/sbin/makemap /etc/mail/domaintable /usr/sbin/praliases /etc/mail/domaintable.db /usr/sbin/smrsh /etc/mail/mailertable /var/spool/mqueue /etc/mail/mailertable.db   15. Installed files: Sendmail -Local server/client Files installed for Sendmail local server or client configuration: /etc/rc.d/init.d/sendmail /etc/smrsh /etc/rc.d/rc0.d/K30sendmail /usr/bin/mailq /etc/rc.d/rc1.d/K30sendmail /usr/bin/hoststat /etc/rc.d/rc2.d/S80sendmail /usr/bin/purgestat /etc/rc.d/rc3.d/S80sendmail /usr/lib/sendmail /etc/rc.d/rc4.d/S80sendmail /usr/man/man1/mailq.1 /etc/rc.d/rc5.d/S80sendmail /usr/man/man8/sendmail.8 /etc/rc.d/rc6.d/K30sendmail /usr/man/man8/mailstats.8 /etc/sysconfig/sendmail /usr/man/man8/smrsh.8 /etc/mail /usr/sbin/sendmail /etc/mail/statistics /usr/sbin/mailstats /etc/mail/sendmail.cf /usr/sbin/smrsh /etc/mail/local-host-names /var/spool/mqueue Chapter 23. Linux IMAP & POP Server Table of Contents 1._Configure_and_Compile 2._Configure_to_tweak 2.1._The_/etc/pam.d/imap_file 3._Enable_IMAP_or_POP_via_the_tcp-wrappers_inetd_super_server 3.1._Securing_IMAP/POP 4._Installed_files If you have configured Sendmail as a Central Mail Hub Server, you must install IMAP/POP software or you'll not be able to take advantage of your Linux Mail server since Sendmail is just software that sends mail from one machine to another, and nothing else. A mail server is a server that is running one or more of the following: An IMAP server A POP3 server A POP2 server or an SMTP server. An example of SMTP server is Sendmail that must be already installed on your Linux server as a Central Mail Hub before you continue reading this part of the book. For now, we are going to cover installing IMAP4, POP3, and POP2, which all come in a single package. 1. Configure and Compile With IMAP & POP software, a remote client email program can access message stores on the Linux mail server as if they were local. For example, email received and stored on an IMAP server for a user can be manipulated from his/ her computer at home, office, etc, without the need to transfer messages or files back and forth between these computers. POP stands for Post Office Protocol and simply allows you to list messages, retrieve them, and delete them. IMAP is POP on steroids. It allows you to easily maintain multiple accounts, have multiple people access one account, leave mail on the server, just download the headers, or bodies, no attachments, and so on. IMAP is ideal for anyone on the go, or with serious email needs. The default POP and IMAP servers that most distributions ship fulfill most needs. IMAP client These installation instructions assume: * Commands are Unix-compatible. * The source path is /var/tmp -other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * IMAP version number is 4.7c These are the Package(s) needed and should be available here: IMAP/POP Homepage: http://www.washington.edu/imap/ IMAP/POP FTP Site: 140.142.3.227 or 140.142.4.227 You must be sure to download: imap.tar.Z Note These are a few Prerequisites you have to keep in mind, sendmail server should be already installed on your system to be able to use IMAP & POP software. For more information on the required software, see the related chapters in this book. You need to decompress the tarballs to compile, so it is a good idea to make a list of files on the system before you install Imap, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > Imap1 before and find /* > Imap2 after you install the software, and use diff Imap1 Imap2 > Imap-Installed to get a list of what changed. Before Compilation you need to decompress the tarball (tar.Z).: [root@deep] /# cp imap.tar.Z /var/tmp [root@deep] /# cd /var/tmp [root@deep ]/tmp# tar xzpf imap.tar.Z Optimize before you Compile, move into the new IMAP/POP directory and edit the Makefile file vi src/osdep/unix/Makefile and change these lines: 1. sh -c '(test -f /usr/include/sys/statvfs.h -a $(OS) != sc5 -a $ (OS) != sco) && $(LN) flocksun.c flockbsd.c || $(LN) flocksv4.c flockbsd.c' To read: sh -c '(test -f /usr/include/sys/statvfs.h -a $(OS) != sc5 -a $ (OS) != sco -a $(OS) != lnx) && $(LN) flocksun.c flockbsd.c || $ (LN) flocksv4.c flockbsd.c' This modification will change the sys/stavfs file. This file, with the new glibc 2.1 of Linux, is different from what is available on Sun. 2. BASECFLAGS="-g -fno-omit-frame-pointer -O6 -DNFSKLUDGE" \ To read: BASECFLAGS="-g -fno-omit-frame-pointer -O9 -funroll-loops - ffast-math -malign-double -mcpu=pentiumpro -march=pentiumpro -fomit- frame-pointer -fno-exceptions -DNFSKLUDGE" \ These are our optimization flags for the compilation of IMAP/POP software on the server. 3. ACTIVEFILE=/usr/lib/news/active To read: ACTIVEFILE=/var/lib/news/active SPOOLDIR=/usr/spool To read: SPOOLDIR=/var/spool RSHPATH=/usr/ucb/rsh To read: RSHPATH=/usr/bin/rsh LOCKPGM=/etc/mlock To read: #LOCKPGM=/etc/mlock The ACTIVEFILE= line specifies the path of the active directory for IMAP/ POP, the SPOOLDIR= is where we put the spool directory of Linux IMAP/POP, and the RSHPATH= specify the path of rsh directory on our system. It's important to note that we don't use rsh services on our server, but even so, we specify the right directory to rsh. 4. CC=cc To read: CC=egcs This line represents the name of our GCC compiler we will use to compile IMAP/POP software, in our case, egcs). Now, we must compile and install IMAP & POP on the Mail Server: [root@deep ]/imap-4.7c# make lnp [root@deep ]/imap-4.7c# install -m 644 ./src/ipopd/ipopd.8c /usr/ man/man8/ipopd.8c [root@deep ]/imap-4.7c# install -m 644 ./src/imapd/imapd.8c /usr/ man/man8/imapd.8c [root@deep ]/imap-4.7c# install -s -m 755 ./ipopd/ipop2d /usr/sbin [root@deep ]/imap-4.7c# install -s -m 755 ./ipopd/ipop3d /usr/sbin [root@deep ]/imap-4.7c# install -s -m 755 ./imapd/imapd /usr/sbin [root@deep ]/imap-4.7c# install -m 644 ./c-client/c-client.a /usr/ lib [root@deep ]/imap-4.7c# ln -fs /usr/lib/c-client.a /usr/lib/ libimap.a [root@deep ]/imap-4.7c# mkdir -p /usr/include/imap [root@deep ]/imap-4.7c# install -m 644 ./c-client/*.h /usr/include/ imap [root@deep ]/imap-4.7c# install -m 644 ./src/osdep/tops-20/ shortsym.h /usr/include/imap [root@deep ]/imap-4.7c# chown root.mail /usr/sbin/ipop2d [root@deep ]/imap-4.7c# chown root.mail /usr/sbin/ipop3d [root@deep ]/imap-4.7c# chown root.mail /usr/sbin/imapd The above commands will configure the software to ensure your system has the necessary functionality and libraries to successfully compile the package, compile all source files into executable binaries, and then install the binaries and any supporting files into the appropriate locations. * Note that the make lnp command above will configure your Linux system with Pluggable Authentication Modules -PAM capability for better security. * The mkdir command will create a new directory named imap under /usr/include. This new directory imap will keep all header files related to the imapd program c-client/*, and shortsym.h files. * The chown command will change the ownership of the binary programs ipop2d, ipop3d, and imapd to be owned by the super-user root, be group owner by the user mail. * The ln -fs command would create a symbolic link from c-client.a file to libimap.a link which may be require by some third party program you may install in the future. Important For security reasons, if you use only imapd services, remove the ipop2d and ipop3d binaries from your mail server. The same applies for ipopd; if you use only ipopd services, remove the imapd binary from your mail server. If you intend to use imapd and ipopd services then keep both binaries. Please do cleanup later: [root@deep] /# cd /var/tmp [root@deep ]/tmp# rm -rf imap-version/ imap.tar.Z The rm command as used above will remove all the source files we have used to compile and install IMAP/POP. It will also remove the IMAP/POP compressed archive from the /var/tmp directory. 2. Configure to tweak Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example IMAP/POP configuration file are organised like this: total 8 -rwx------ 1 harrypotter harrypotter 685 Jun 8 13:00 imap.sh* drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 pam.d/ You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run the IMAP/POP server, the following files are required and must be created or copied to the appropriate directories on your server. * Copy the imap file to the /etc/pam.d/ directory if you intend to use imapd service. * Copy the pop file to the /etc/pam.d/ directory if you intend to use popd service. Tip You can obtain the configuration files listed below on our floppy.tgz archive. Copy the following files from the decompressed floppy.tgz archive to the appropriate places or copy and paste them directly from this book to the concerned file. 2.1. The /etc/pam.d/imap file Configure your /etc/pam.d/imap file to use pam authentication, create the imap file touch /etc/pam.d/imap and add: #%PAM-1.0 auth required /lib/security/pam_pwdb.so shadow nullok account required /lib/security/pam_pwdb.so Note This file is only required if you intend to use IMAP services. 2.1.1. The /etc/pam.d/pop file Configure your /etc/pam.d/pop file to use pam authentication, create the pop file touch /etc/pam.d/pop and add: #%PAM-1.0 auth required /lib/security/pam_pwdb.so shadow nullok account required /lib/security/pam_pwdb.so Note This file is only required if you intend to use POP services. 3. Enable IMAP or POP via the tcp-wrappers inetd super server Tcp-wrappers take cares to start and stop IMAP or POP server. Upon execution, inetd reads its configuration information from a configuration file which, by default, is /etc/inetd.conf. There must be an entry for each field of the configuration file, with entries for each field separated by a tab or a space. 1. Edit the inetd.conf file, vi /etc/inetd.conf and add or uncomment the line related to the service you want to enable. If you want to use IMAP then uncomment the line related to it, if is POP that you want to use in your server, then uncomment it instead of IMAP. In our example below we'll use IMAP service. #pop-2 stream tcp nowait root /usr/sbin/tcpd ipop2d #pop-3 stream tcp nowait root /usr/sbin/tcpd ipop3d imap stream tcp nowait root /usr/sbin/tcpd imapd 2. Don't forget to update your inetd.conf file by sending a SIGHUP signal killall -HUP inetd after adding or uncommenting the corresponding line. [root@deep /root]# killall -HUP inetd 3. If the IMAP/POP server you want to install is a private and limited server for wheel knows real IP address clients, you can use the security feature of tcp-wrappers to control, which can connect, to your server and from where. If you intended to offer mail service to a dial-up clients or a Webmail service for example, then you cannot use this feature. Edit the hosts.deny file, vi /etc/hosts.deny and add the line: ALL: ALL@ALL, PARANOID Which means all services, all locations, so any service not explicitly allowed is then blocked, unless they are permitted access by entries in the hosts.allow file. 4. Edit the hosts.allow file, vi /etc/hosts.allow and add the line: imapd: 216.209.228.34 my.domain.com Which mean only client IP 216.209.228.34 with host name my.domain.com is allowed to connect and use IMAP service on the server. 3.1. Securing IMAP/POP 3.1.1. Do_you_really_need_IMAP/POP_service? 3.1.1. Do you really need IMAP/POP service? Be aware that IMAP/POP programs use plain text passwords by default. Anyone running a sniffer program along your network path can grab your username/password and use them to log in as you. It's not because you use an IMAP/POP mail reader on your LINUX system that you need to run an IMAP/POP server locally. Check your configuration, and if you use a remote/external IMAP/POP server then uninstall IMAP/POP on your system. Sniffer attack? Using SSL capabilities over IMAP/POP Unfortunately, due to US government export restrictions, the IMAP toolkit with SSL capability is currently not available. There are packages available from third parties that allow IMAP and POP3 sessions through SSL. One of these packages is WebMail IMP, a web interface that permits you to read your mail via the Internet with a web browser. WebMail IMP uses the SSL protocol to encrypt the communication with the IMAP/POP server. See part IV, Software's-Related Reference, in Chapter 19, Servers Software (Web Network Services) for more information on the topic. Webmail-IMP web browser interface With WebMail IMP, communications from the mail server through to the client machine are encrypted with the SSL protocol using a web browser. Further documentation, for more details, there are several man pages you can read: imapd(8C) - Internet Message Access Protocol server ipopd(8C) - Post Office Protocol server 4. Installed files These are the files installed by IMAP/POP software: /etc/pam.d/imap /etc/pam.d/pop /usr/include/imap /usr/include/imap/dummy.h /usr/include/imap/env.h /usr/include/imap/ env_unix.h /usr/include/imap/ /usr/include/imap/ /usr/include/imap/fs.h fdstring.h flstring.h /usr/include/imap/ftl.h /usr/include/imap/ /usr/include/imap/ imap4r1.h linkage.h /usr/include/imap/ /usr/include/imap/mail.h /usr/include/imap/mbox.h lockfix.h /usr/include/imap/mbx.h /usr/include/imap/mh.h /usr/include/imap/misc.h /usr/include/imap/mmdf.h /usr/include/imap/mtx.h /usr/include/imap/mx.h /usr/include/imap/ /usr/include/imap/news.h /usr/include/imap/newsrc.h netmsg.h /usr/include/imap/nl.h /usr/include/imap/nntp.h /usr/include/imap/os_a32.h /usr/include/imap/ /usr/include/imap/os_aix.h /usr/include/imap/os_aos.h os_a41.h /usr/include/imap/ /usr/include/imap/os_asv.h /usr/include/imap/os_aux.h os_art.h /usr/include/imap/ /usr/include/imap/os_bsi.h /usr/include/imap/os_cvx.h os_bsd.h /usr/include/imap/os_d- /usr/include/imap/os_do4.h /usr/include/imap/os_drs.h g.h /usr/include/imap/ /usr/include/imap/os_hpp.h /usr/include/imap/os_isc.h os_dyn.h /usr/include/imap/ /usr/include/imap/os_lyn.h /usr/include/imap/os_mct.h os_lnx.h /usr/include/imap/ /usr/include/imap/os_nxt.h /usr/include/imap/os_os4.h os_mnt.h /usr/include/imap/ /usr/include/imap/os_ptx.h /usr/include/imap/os_pyr.h os_osf.h /usr/include/imap/ /usr/include/imap/os_s40.h /usr/include/imap/os_sc5.h os_qnx.h /usr/include/imap/ /usr/include/imap/os_sgi.h /usr/include/imap/os_shp.h os_sco.h /usr/include/imap/ /usr/include/imap/os_sol.h /usr/include/imap/os_sos.h os_slx.h /usr/include/imap/ /usr/include/imap/os_sv2.h /usr/include/imap/os_sv4.h os_sun.h /usr/include/imap/ /usr/include/imap/os_vu2.h /usr/include/imap/osdep.h os_ult.h /usr/include/imap/phile.h /usr/include/imap/pop3.h /usr/include/imap/pseudo.h /usr/include/imap/ /usr/include/imap/smtp.h /usr/include/imap/tcp.h rfc822.h /usr/include/imap/ /usr/include/imap/tenex.h /usr/include/imap/unix.h tcp_unix.h /usr/include/imap/utf8.h /usr/include/imap/ /usr/lib/c-client.a shortsym.h /usr/lib/libimap.a /usr/man/man8/ipopd.8c /usr/man/man8/imapd.8c /usr/sbin/ipop2d /usr/sbin/ipop3d /usr/sbin/imapd Chapter 24. Software -Networking/Encryption Table of Contents 1._Linux_OPENSSL_Server 2._Compile_and_Optimize 3._Configure_OpenSSL_to_optimise 4._The_/etc/ssl/openssl.cnf_file 5._Create_the_/usr/bin/sign.sh_program_file 6._Commands_-often_used 7._Securing_OpenSSL 8._Installed_files Most server software like IMAP & POP, Samba, OpenLDAP, FTP, Apache, and others that ask for users authentication before allowing services, by default transmit the user's identification and password in plain text. Alternatively, encryption mechanisms like SSL ensure safe and secure transactions. With this technology, data going over the network is point-to-point encrypted. Once OpenSSL has been installed on your Linux server you can use it as a third party tool to enable other applications with SSL functionality. 1. Linux OPENSSL Server The OpenSSL Project is a collaborative effort to develop a robust, commercial- grade, fully featured, and Open Source toolkit implementing the Secure Sockets Layer; SSL v2/v3, and Transport Layer Security -TLS v1 protocols with full- strength cryptography. The project is managed by a worldwide community of volunteers that use the Internet to communicate, plan, and develop the OpenSSL toolkit and its related documentation. Cryptographic Technology —From the [OpenSSL web site] The main advantages gained by using encryption technology follow: Cryptography Advantages Data Confidentiality When a message is encrypted, the input plain text is transformed by an algorithm into enciphered text that hides the meaning of the message and can be sent via any public mechanism. This process involves a secret key that is used to encrypt and later decrypt the data. Without the secret key, the encrypted data is meaningless. Data Integrity A cryptographic checksum, called a message authentication code -MAC, can be calculated on arbitrarily user-supplied text to protect the integrity of data. The result, text and MAC are then sent to the receiver which can verify the trial MAC appended to a message by recalculating the MAC for the message, using the appropriate secret key and verifying that it exactly equals the trial MAC. Authentication Personal identification is another use of cryptography, where the user/ sender knows a secret, which can serve to authenticate his/her identity. Electronic Signature A digital signature assures the sender and receiver that the message is authentic and that only the owner of the key could have generated the digital signature. Patents Warning Several legal issues exist for SSL technology. If you intend to use OpenSSL for commercial purpose, you may need to obtain a license from RSA regarding use of RSA libraries. Here's an excerpt from the README file of OpenSSL: Various companies hold various patents for various algorithms in various locations around the world. _YOU_ are responsible for ensuring that your use of any algorithms is legal by checking if there are any patents in your country. This file contains some of the patents that we know about or are rumored to exist. This is not a definitive list. * RSA Data Security holds software patents on the RSA and RC5 algorithms. If their ciphers are used inside the USA and Japan?, you must contact RSA Data Security for licensing conditions. Their web page is http://www.rsa.com/. * RC4 is a trademark of RSA Data Security, so use of this label should perhaps only be used with RSA Data Security's permission. * The IDEA algorithm is patented by Ascom in Austria, France, Germany, Italy, Japan, Netherlands, Spain, Sweden, Switzerland, UK and the USA. They should be contacted if that algorithm is to be used; their web page is http:// www.ascom.ch/ These installation instructions assume: * Commands are Unix-compatible. * The source path is /var/tmp -other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * OpenSSL version number is 0.9.5a Before you decompress the tarballs, it is a good idea to make a list of files on the system before you install Openssl, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > OpenSSL1 before and find /* > OpenSSL2 after you install the software, and use diff OpenSSL1 OpenSSL2 > OpenSSL-Installed to get a list of what changed. These are the Package(s) required: OpenSSL Homepage: http://www.openssl.org/ You must be sure to download: openssl-0.9.5a.tar.gz To Compile, you need to decompress the tarball (tar.gz). [root@deep] /# cp openssl-version.tar.gz /var/tmp [root@deep] /# cd /var/tmp [root@deep ]/tmp# tar xzpf openssl-version.tar.gz 2. Compile and Optimize Move into the new Openssl directory and type the following commands on your terminal: 1. Edit the c_rehash file, vi +11 tools/c_rehash and change the line: DIR=/usr/local/ssl To read: DIR=/usr The changed line above will build and install OpenSSL in the default location /usr. 2. By default, OpenSSL source files suppose that your Perl program directory is located under the /usr/local/bin/perl directory. We must modify the #!/ usr/local/bin/perl line in all scripts that rely on perl to reflect our Perl directory under Red Hat Linux to be /usr/bin. [root@deep ]/openssl-0.9.5a# perl util/perlpath.pl /usr/bin 1 _1_ where your perl program reside. 3. OpenSSL must know where to find the necessary OpenSSL source libraries to compile successfully its required files. With the command below, we set the PATH environment variable to the default directory where we have uncompressed the OpenSSL source files. [root@deep ]/openssl-0.9.5a# export LD_LIBRARY_PATH=`pwd` 4. Now, we must configure OpenSSL for our system: CC="egcs" \ ./Configure linux-elf -DSSL_FORBID_ENULL \ 1 --prefix=/usr \ --openssldir=/etc/ssl _1_ The -DSSL_FORBID_ENULL option is required for not allowing null encryption for security reasons. 5. Edit the Makefile.ssl file and change the following line: a. vi +50 Makefile.ssl CC= gcc To read: CC= egcs b. Edit with vi +52 Makefile.ssl and add/change the following line: CFLAG= -DTHREADS -D_REENTRANT -DSSL_FORBID_ENULL - DL_ENDIAN -DTERMIO -O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno- exceptions -Wall -DSHA1_ASM -DMD5_ASM -DRMD160_ASM c. Edit with vi +79 Makefile.ssl and add the following value for a Pentium Pro processor: PROCESSOR= 686 Note The three modifications we made above will set the optimization flag for compilation of OpenSSL software on the server. For the last modification PROCESSOR= above, if you use 586 to denote a Pentium, use 686 to denote Pro/II/III, use 486 to denote a 486, depending on the type of processor you have. d. Edit with vi +161 Makefile.ssl and change the following line: MANDIR=$(OPENSSLDIR)/man To read: MANDIR=/usr/man This step is necessary to set the directory for where the man pages of OpenSSL will be installed. With this modification, we install them under /usr/man directory. Now we must compile and install OpenSSL on the server: [root@deep ]/openssl-0.9.5a# make -f Makefile [root@deep ]/openssl-0.9.5a# make test [root@deep ]/openssl-0.9.5a# make install [root@deep ]/openssl-0.9.5a# mv /etc/ssl/misc/* /usr/bin/ [root@deep ]/openssl-0.9.5a# rm -rf /etc/ssl/misc/ [root@deep ]/openssl-0.9.5a# rm -rf /etc/ssl/lib/ [root@deep ]/openssl-0.9.5a# rm -f /usr/bin/CA.pl [root@deep ]/openssl-0.9.5a# rm -f /usr/bin/CA.sh [root@deep ]/openssl-0.9.5a# install -m 644 libRSAglue.a /usr/ lib/ [root@deep ]/openssl-0.9.5a# install -m 644 rsaref/rsaref.h / usr/include/openssl/ [root@deep ]/openssl-0.9.5a# strip /usr/bin/openssl [root@deep ]/openssl-0.9.5a# mkdir -p /etc/ssl/crl * The make -f command will build the OpenSSL libraries, libcrypto.a and libssl.a and the OpenSSL binary openssl. The libraries will be built in the top-level directory, and the binary will be in the apps directory. * After a successful build, the make test will test the libraries and finally the make install will create the installation directory and install OpenSSL. * The mv command will move all files under the /etc/ssl/misc/ directory to the /usr/bin/ directory. These files are binary and must be located under /usr/ bin/ since in our system, all binary files are keep in this directory. Also putting these files in the /usr/bin/ directory will keep them in our PATH environment variable. * The rm command will remove the /etc/ssl/misc/ and /etc/ssl/lib/ directories from our system, since files that were in these directories are now located in other places. Also, it will remove the CA.pl and CA.sh files, that are small scripts used to create your own CA certificates. Those scripts related to openssl ca commands has some strange requirements, and the default OpenSSL config doesn't allow one easily to use openssl ca directly. So we'll create the sign.sh script program later to replace them. Caution The bc-1.05a-4.i386.rpm package or higher must be already installed on your Linux server or you'll receive an error message during the library test of OpenSSL. Please don't forget to cleanup later: [root@deep] /# cd /var/tmp [root@deep tmp]# rm -rf openssl-version/ openssl-version.tar.gz The rm command will remove all the source files we have used to compile and install OpenSSL. It will also remove the OpenSSL compressed archive from th/ var/tmp directory. 3. Configure OpenSSL to optimise Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example OpenSSL configuration file are organised like this: total 16 -rw-r--r-- 1 harrypotter harrypotter 7002 Jun 8 13:00 openssl.cnf -rwxr-xr-x 1 harrypotter harrypotter 1847 Jun 8 13:00 sign.sh* -rwx------ 1 harrypotter harrypotter 362 Jun 8 13:00 ssl.sh* You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run OpenSSL Server, the following files are required and must be created or copied to the appropriate directories on your server. i. Copy the openssl.cnf file to the /etc/ssl/ directory. ii. Copy the sign.sh script file to the /usr/bin/ directory. Tip You can obtain the configuration files listed below on our floppy.tgz archive. Copy the following files from the decompressed floppy.tgz archive to the appropriate places or copy and paste them directly from this book to the concerned file. 4. The /etc/ssl/openssl.cnf file This is the general configuration file for OpenSSL program where you can configure expiration date of your keys, the name of your organization, the address etc. The parameters you may change will be in the [ CA_default ] and especially the [ req_distinguished_name ] sections. Edit the openssl.cnf file, vi /etc/ssl/openssl.cnf and add or modify: # OpenSSL example configuration file. # This is mostly being used for generation of certificate requests. # RANDFILE = $ENV::HOME/.rnd oid_file = $ENV::HOME/.oid oid_section = new_oids # To use this configuration file with the "-extfile" option of the # "openssl x509" utility, name here the section containing the # X.509v3 extensions to use: # extensions = # (Alternatively, use a configuration file that has only # X.509v3 extensions in its main [= default] section.) [ new_oids ] # We can add new OIDs in here for use by 'ca' and 'req'. # Add a simple OID like this: # testoid1=1.2.3.4 # Or use config file substitution like this: # testoid2=${testoid1}.5.6 #################################################################### [ ca ] default_ca = CA_default # The default ca section #################################################################### [ CA_default ] dir = /etc/ssl # Where everything is kept certs = $dir/certs # Where the issued certs are kept crl_dir = $dir/crl # Where the issued crl are kept database = $dir/ca.db.index # database index file. new_certs_dir = $dir/ca.db.certs # default place for new certs. certificate = $dir/certs/ca.crt # The CA certificate serial = $dir/ca.db.serial # The current serial number crl = $dir/crl.pem # The current CRL private_key = $dir/private/ca.key # The private key RANDFILE = $dir/ca.db.rand # private random number file x509_extensions = usr_cert # The extentions to add to the cert # Extensions to add to a CRL. Note: Netscape communicator chokes on V2 CRLs # so this is commented out by default to leave a V1 CRL. # crl_extensions = crl_ext default_days = 365 # how long to certify for default_crl_days = 30 # how long before next CRL default_md = md5 # which md to use. Preserve = no # keep passed DN ordering # A few difference way of specifying how similar the request should look # For type CA, the listed attributes must be the same, and the optional # and supplied fields are just that :-) policy = policy_match # For the CA policy [ policy_match ] countryName = match stateOrProvinceName = match organizationName = match organizationalUnitName = optional commonName = supplied emailAddress = optional # For the 'anything' policy # At this point in time, you must list all acceptable 'object' # types. [ policy_anything ] countryName = optional stateOrProvinceName = optional localityName = optional organizationName = optional organizationalUnitName = optional commonName = supplied emailAddress = optional #################################################################### [ req ] default_bits = 1024 default_keyfile = privkey.pem distinguished_name = req_distinguished_name attributes = req_attributes x509_extensions = v3_ca # The extentions to add to the self signed cert [ req_distinguished_name ] countryName = Country Name (2 letter code) countryName_default = CA countryName_min = 2 countryName_max = 2 stateOrProvinceName = State or Province Name (full name) stateOrProvinceName_default = Quebec localityName = Locality Name (eg, city) localityName_default = Montreal 0.organizationName = Organization Name (eg, company) 0.organizationName_default = Open Network Architecture # we can do this but it is not needed normally :-) #1.organizationName = Second Organization Name (eg, company) #1.organizationName_default = World Wide Web Pty Ltd organizationalUnitName = Organizational Unit Name (eg, section) organizationalUnitName_default = Internet Department commonName = Common Name (eg, YOUR name) commonName_default = www.openna.com commonName_max = 64 emailAddress = Email Address emailAddress_default = admin@openna.com emailAddress_max = 40 # SET-ex3 = SET extension number 3 [ req_attributes ] challengePassword = A challenge password challengePassword_min = 4 challengePassword_max = 20 unstructuredName = An optional company name [ usr_cert ] # These extensions are added when 'ca' signs a request. # This goes against PKIX guidelines but some CAs do it and some software # requires this to avoid interpreting an end user certificate as a CA. basicConstraints=CA:FALSE # Here are some examples of the usage of nsCertType. If it is omitted # the certificate can be used for anything *except* object signing. # This is OK for an SSL server. # nsCertType = server # For an object signing certificate this would be used. # nsCertType = objsign # For normal client use this is typical # nsCertType = client, email # and for everything including object signing: # nsCertType = client, email, objsign # This is typical in keyUsage for a client certificate. # keyUsage = nonRepudiation, digitalSignature, keyEncipherment # This will be displayed in Netscape's comment listbox. nsComment = "OpenSSL Generated Certificate" # PKIX recommendations harmless if included in all certificates. subjectKeyIdentifier=hash authorityKeyIdentifier=keyid,issuer:always # This stuff is for subjectAltName and issuerAltname. # Import the email address. # subjectAltName=email:copy # Copy subject details # issuerAltName=issuer:copy #nsCaRevocationUrl = http://www.domain.dom/ca-crl.pem #nsBaseUrl #nsRevocationUrl #nsRenewalUrl #nsCaPolicyUrl #nsSslServerName [ v3_ca] # Extensions for a typical CA # PKIX recommendation. subjectKeyIdentifier=hash authorityKeyIdentifier=keyid:always,issuer:always # This is what PKIX recommends but some broken software chokes on critical # extensions. #basicConstraints = critical,CA:true # So we do this instead. basicConstraints = CA:true # Key usage: this is typical for a CA certificate. However since it will # prevent it being used as an test self-signed certificate it is best # left out by default. # keyUsage = cRLSign, keyCertSign # Some might want this also # nsCertType = sslCA, emailCA # Include email address in subject alt name: another PKIX recommendation # subjectAltName=email:copy # Copy issuer details # issuerAltName=issuer:copy # RAW DER hex encoding of an extension: beware experts only! # 1.2.3.5=RAW:02:03 # You can even override a supported extension: # basicConstraints= critical, RAW:30:03:01:01:FF [ crl_ext ] # CRL extensions. # Only issuerAltName and authorityKeyIdentifier make any sense in a CRL. # issuerAltName=issuer:copy authorityKeyIdentifier=keyid:always,issuer:always Tip The file openssl.cnf already exists on your server when you compile and install the OpenSSL program, and can be found under the /etc/ssl/ directory. You don't need to change all the default options set in this file; The configurations you may usually change will be in the [ CA_default ] and [ req_distinguished_name ] sections only. 5. Create the /usr/bin/sign.sh program file The openssl ca commands has some strange requirements and the default OpenSSL config doesn't allow one easily to use openssl ca directly. Therefore, well create this sign.sh program to replace it. Create the sign.sh program file, touch /usr/bin/sign.sh and add to this file: #!/bin/sh ## ## sign.sh -- Sign a SSL Certificate Request (CSR) ## Copyright (c) 1998-1999 Ralf S. Engelschall, All Rights Reserved. ## # argument line handling CSR=$1 if [ $# -ne 1 ]; then echo "Usage: sign.sign .csr"; exit 1 fi if [ ! -f $CSR ]; then echo "CSR not found: $CSR"; exit 1 fi case $CSR in *.csr ) CERT="`echo $CSR | sed -e 's/\.csr/.crt/'`" ;; * ) CERT="$CSR.crt" ;; esac # make sure environment exists if [ ! -d ca.db.certs ]; then mkdir ca.db.certs fi if [ ! -f ca.db.serial ]; then echo '01' >ca.db.serial fi if [ ! -f ca.db.index ]; then cp /dev/null ca.db.index fi # create an own SSLeay config cat >ca.config < $CERT:" openssl ca -config ca.config -out $CERT -infiles $CSR echo "CA verifying: $CERT <-> CA cert" openssl verify -CAfile /etc/ssl/certs/ca.crt $CERT # cleanup after SSLeay rm -f ca.config rm -f ca.db.serial.old rm -f ca.db.index.old # die gracefully exit 0 Now, make this program executable, and change its default permissions: [root@deep] /# chmod 755 /usr/bin/sign.sh Tip You can also find this program sign.sh in the mod_ssl distribution under the mod_ssl-version/pkg.contrib/ subdirectory, or on our floppy.tgz archive file. Also note that the section [ CA_own ] must be changed to refect your own environment and don't forget to change the openssl verify -CAfile /etc/ssl/ certs/ca.crt $CERT line too. 6. Commands -often used The commands listed below are some that we use often, but many more exist. Check the man pages and documentation for more details and information. As an example, we'll show you how to create certificates for your Apache Web Server and/or your own CA Certifying Authority to sign your Certificate Signing Request yourself. Important All commands listed below are assumed to be made in the /etc/ssl/ directory. Create a RSA private key protected with a passphrase for your Apache Server. [root@deep ]/ssl#openssl genrsa -des3 -out server.key 1024 Generating RSA private key, 1024 bit long modulus ......................+++++ .....+++++ e is 65537 (0x10001) Enter PEM pass phrase: Verifying password - Enter PEM pass phrase: Please backup this server.key file and remember the pass-phrase you had to enter at a secure location. Generate a Certificate Signing Request CSR with the server RSA private key. [root@deep ]/ssl# openssl req -new -key server.key -out server.csr Using configuration from /etc/ssl/openssl.cnf Enter PEM pass phrase: You are about to be asked to enter information that will be incorporated into your certificate request. What you are about to enter is what is called a Distinguished Name or a DN. There are quite a few fields but you can leave some blank For some fields there will be a default value, If you enter '.', the field will be left blank. ----- Country Name (2 letter code) [CA]: State or Province Name (full name) [Quebec]: Locality Name (eg, city) [Montreal]: Organization Name (eg, company) [Open Network Architecture]: Organizational Unit Name (eg, section) [Internet Department]: Common Name (eg, YOUR name) [www.openna.com]: Email Address [admin@openna.com]: Please enter the following 'extra' attributes to be sent with your certificate request A challenge password []:. An optional company name []:. Note Make sure you enter the FQDN, Fully Qualified Domain Name of the server when OpenSSL prompts you for the CommonName, i.e. when you generate a CSR for a website which will be later accessed via https://www.mydomain.com/, enter www.mydomain.com here. After generation of your Certificate Signing Request; CSR, you have two choices: i. the first is to send this certificate to a commercial Certifying Authority (CA) like Verisign or Thawte for signing. You usually have to post the CSR into a web form, pay for the signing, await the signed Certificate and store it into a server.crt file. The result is then a real Certificate, which can be used for Apache. ii. Second, you can use your own CA and now have to sign the CSR yourself by this CA. This solution is economical, and allows an organization to host their own CA server and generate as many certificates as they need for internal use without paying any cent to a commercial CA. Unfortunately. using your own CA to generate certificates cause problems in electronic commerce, because customers need to have some trust in your organization by the use of recognized commercial CA. See below on how to sign a CSR with your CA yourself. Create a RSA private key for your CA. [root@deep ]/ssl# openssl genrsa -des3 -out ca.key 1024 Generating RSA private key, 1024 bit long modulus ...........................+++++ ............................................+++++ e is 65537 (0x10001) Enter PEM pass phrase: Verifying password - Enter PEM pass phrase: Please backup this ca.key file and remember the pass-phrase you had to enter at a secure location. Create a self-signed CA certificate x509 structure with the RSA key of the CA. [root@deep ]/ssl# openssl req -new -x509 -days 365 -key ca.key -out ca.crt Using configuration from /etc/ssl/openssl.cnf Enter PEM pass phrase: You are about to be asked to enter information that will be incorporated into your certificate request. What you are about to enter is what is called a Distinguished Name or a DN. There are quite a few fields but you can leave some blank For some fields there will be a default value, If you enter '.', the field will be left blank. ----- Country Name (2 letter code) [CA]: State or Province Name (full name) [Quebec]: Locality Name (eg, city) [Montreal]: Organization Name (eg, company) [Open Network Architecture]: Organizational Unit Name (eg, section) [Internet Department]:CA Marketing Common Name (eg, YOUR name) [www.openna.com]: Email Address [admin@openna.com]: [root@deep ]/ssl# mv server.key private/ [root@deep ]/ssl# mv ca.key private/ [root@deep ]/ssl# mv ca.crt certs/ Note The req command creates a self-signed certificate when the -x509 switch is used. Signing a certificate request. We create and use our own Certificate Authority -CA, Prepare the script for signing which is needed because the openssl ca command has some strange requirements, and the default OpenSSL config doesn't allow one easily to use openssl ca directly. The script named sign.sh is distributed with the floppy disk under the openssl directory. Use this script for signing. Now you can use this CA to sign server CSR's in order to create real SSL Certificates for use inside an Apache Webserver assuming you already have a server.csr at hand: [root@deep ]/ssl# /usr/bin/sign.sh server.csr CA signing: server.csr -> server.crt: Using configuration from ca.config Enter PEM pass phrase: Check that the request matches the signature Signature ok The Subjects Distinguished Name is as follows countryName :PRINTABLE:'CA' stateOrProvinceName :PRINTABLE:'Quebec' localityName :PRINTABLE:'Montreal' organizationName :PRINTABLE:'Open Network Architecture' organizationalUnitName :PRINTABLE:'Internet Department' commonName :PRINTABLE:'www.openna.com' emailAddress :IA5STRING:'admin@openna.com' Certificate is to be certified until Dec 1 14:59:29 2000 GMT (365 days) Sign the certificate? [y/n]:y 1 out of 1 certificate requests certified, commit? [y/n]y Write out database with 1 new entries Data Base Updated CA verifying: server.crt <-> CA cert server.crt: OK This signs the CSR and results in a server.crt file. [root@deep ]/ssl# mv server.crt certs/ Now you have two files: server.key and server.crt. These can now, for example, be used as follows, inside your Apache server's httpd.conf file: SSLCertificateFile /etc/ssl/certs/server.crt 1 SSLCertificateKeyFile /etc/ssl/private/server.key 2 _1_ Our web server public key _2_ Our web server private key The server.csr file is no longer needed. [root@deep ]/ssl# rm -f server.csr Tip If you receive error message during signature of the certificate, it's probably because you've entered the wrong FQDN, Fully Qualified Domain Name for the server when OpenSSL prompted you for the CommonName; the CommonName must be something like my.domain.com and not domain.com. Also, since you generate both the certificate and the CA certificate, it's important that at least one piece of information differs between both files, or you may encounter problems during the signature of the certificate request. 7. Securing OpenSSL Make your keys Read and Write only by the super-user root. This is important because no one needs to touch these files. use the following commands: [root@deep] /# chmod 600 /etc/ssl/certs/ca.crt [root@deep] /# chmod 600 /etc/ssl/certs/server.crt [root@deep] /# chmod 600 /etc/ssl/private/ca.key [root@deep] /# chmod 600 /etc/ssl/private/server.key Some possible uses of OpenSSL software, for example OpenSSL can be used to: i. Create your own Certificate Server. ii. Provide data confidentiality, integrity, authentication, and electronic signature in transmission for the users. iii. Secure electronic commerce transactions. 8. Installed files These are the files installed by OpenSSL software on your harddisk: /etc/ssl /etc/ssl/crl /etc/ssl/certs /etc/ssl/private /etc/ssl/openssl.cnf /usr/bin/openssl /usr/bin/c_rehash /usr/bin/sign.sh /usr/bin/c_hash /usr/bin/c_info /usr/bin/c_issuer /usr/bin/c_name /usr/bin/der_chop /usr/include/openssl /usr/include/openssl/ e_os.h /usr/include/openssl/ /usr/include/openssl/crypto.h /usr/include/openssl/ e_os2.h tmdiff.h /usr/include/openssl/ /usr/include/openssl/ /usr/include/openssl/ opensslv.h opensslconf.h ebcdic.h /usr/include/openssl/ /usr/include/openssl/md5.h /usr/include/openssl/ md2.h sha.h /usr/include/openssl/ /usr/include/openssl/hmac.h /usr/include/openssl/ mdc2.h ripemd.h /usr/include/openssl/ /usr/include/openssl/rc2.h /usr/include/openssl/ des.h rc4.h /usr/include/openssl/ /usr/include/openssl/idea.h /usr/include/openssl/ rc5.h blowfish.h /usr/include/openssl/ /usr/include/openssl/bn.h /usr/include/openssl/ cast.h rsa.h /usr/include/openssl/ /usr/include/openssl/dh.h /usr/include/openssl/ dsa.h buffer.h /usr/include/openssl/ /usr/include/openssl/stack.h /usr/include/openssl/ bio.h safestack.h /usr/include/openssl/ /usr/include/openssl/rand.h /usr/include/openssl/ lhash.h err.h /usr/include/openssl/ /usr/include/openssl/evp.h /usr/include/openssl/ objects.h asn1.h /usr/include/openssl/ /usr/include/openssl/pem.h /usr/include/openssl/ asn1_mac.h pem2.h /usr/include/openssl/ /usr/include/openssl/ /usr/include/openssl/ x509.h x509_vfy.h x509v3.h /usr/include/openssl/ /usr/include/openssl/txt_db.h /usr/include/openssl/ conf.h pkcs7.h /usr/include/openssl/ /usr/include/openssl/comp.h /usr/include/openssl/ pkcs12.h ssl.h /usr/include/openssl/ /usr/include/openssl/ssl3.h /usr/include/openssl/ ssl2.h ssl23.h /usr/include/openssl/ /usr/include/openssl/rsaref.h /usr/lib/libcrypto.a tls1.h /usr/lib/libssl.a /usr/lib/libRSAglue.a /usr/man/man1/CA.pl.1 /usr/man/man1/ /usr/man/man1/ca.1 /usr/man/man1/ciphers.1 asn1parse.1 /usr/man/man1/crl.1 /usr/man/man1/crl2pkcs7.1 /usr/man/man1/dgst.1 /usr/man/man1/dhparam.1 /usr/man/man1/dsa.1 /usr/man/man1/dsaparam.1 /usr/man/man1/enc.1 /usr/man/man1/gendsa.1 /usr/man/man1/genrsa.1 /usr/man/man1/nseq.1 /usr/man/man1/openssl.1 /usr/man/man1/pkcs12.1 /usr/man/man1/pkcs7.1 /usr/man/man1/pkcs8.1 /usr/man/man1/req.1 /usr/man/man1/rsa.1 /usr/man/man1/s_client.1 /usr/man/man1/s_server.1 /usr/man/man1/sess_id.1 /usr/man/man1/smime.1 /usr/man/man1/speed.1 /usr/man/man1/spkac.1 /usr/man/man1/verify.1 /usr/man/man1/version.1 /usr/man/man1/x509.1 /usr/man/man3/BN_CTX_new.3 /usr/man/man3/ BN_CTX_start.3 /usr/man/man3/BN_add.3 /usr/man/man3/BN_add_word.3 /usr/man/man3/BN_bn2bin.3 /usr/man/man3/BN_cmp.3 /usr/man/man3/BN_copy.3 /usr/man/man3/ BN_generate_prime.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man3/ BN_mod_inverse.3 BN_mod_mul_montgomery.3 BN_mod_mul_reciprocal.3 /usr/man/man3/BN_new.3 /usr/man/man3/BN_num_bytes.3 /usr/man/man3/BN_rand.3 /usr/man/man3/ /usr/man/man3/BN_zero.3 /usr/man/man3/ BN_set_bit.3 CRYPTO_set_ex_data.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man3/ DH_generate_key.3 DH_generate_parameters.3 DH_get_ex_new_index.3 /usr/man/man3/DH_new.3 /usr/man/man3/DH_set_method.3 /usr/man/man3/DH_size.3 /usr/man/man3/ /usr/man/man3/DSA_do_sign.3 /usr/man/man3/ DSA_SIG_new.3 DSA_dup_DH.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man3/ DSA_generate_key.3 DSA_generate_parameters.3 DSA_get_ex_new_index.3 /usr/man/man3/DSA_new.3 /usr/man/man3/DSA_set_method.3 /usr/man/man3/DSA_sign.3 /usr/man/man3/DSA_size.3 /usr/man/man3/ERR_GET_LIB.3 /usr/man/man3/ ERR_clear_error.3 /usr/man/man3/ /usr/man/man3/ERR_get_error.3 /usr/man/man3/ ERR_error_string.3 ERR_load_crypto_strings.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man3/ ERR_load_strings.3 ERR_print_errors.3 ERR_put_error.3 /usr/man/man3/ /usr/man/man3/EVP_DigestInit.3 /usr/man/man3/ ERR_remove_state.3 EVP_EncryptInit.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man3/RAND_add.3 OPENSSL_VERSION_NUMBER.3 OpenSSL_add_all_algorithms.3 /usr/man/man3/ /usr/man/man3/RAND_cleanup.3 /usr/man/man3/RAND_egd.3 RAND_bytes.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man3/ RAND_load_file.3 RAND_set_rand_method.3 RSA_blinding_on.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man3/ RSA_check_key.3 RSA_generate_key.3 RSA_get_ex_new_index.3 /usr/man/man3/RSA_new.3 /usr/man/man3/ /usr/man/man3/RSA_print.3 RSA_padding_add_PKCS1_type_1.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man3/ RSA_private_encrypt.3 RSA_public_encrypt.3 RSA_set_method.3 /usr/man/man3/RSA_sign.3 /usr/man/man3/ /usr/man/man3/RSA_size.3 RSA_sign_ASN1_OCTET_STRING.3 /usr/man/man3/blowfish.3 /usr/man/man3/bn.3 /usr/man/man3/ bn_internal.3 /usr/man/man3/buffer.3 /usr/man/man3/crypto.3 /usr/man/man3/ d2i_DHparams.3 /usr/man/man3/ /usr/man/man3/dh.3 /usr/man/man3/dsa.3 d2i_RSAPublicKey.3 /usr/man/man3/err.3 /usr/man/man3/hmac.3 /usr/man/man3/lh_stats.3 /usr/man/man3/lhash.3 /usr/man/man3/md5.3 /usr/man/man3/mdc2.3 /usr/man/man3/rand.3 /usr/man/man3/rc4.3 /usr/man/man3/ripemd.3 /usr/man/man3/rsa.3 /usr/man/man3/sha.3 /usr/man/man3/threads.3 /usr/man/man3/ /usr/man/man3/ssl.3 /usr/man/man5/config.5 SSL_get_error.3 /usr/man/man7/     des_modes.7 Chapter 25. Linux FreeS/WAN VPN Table of Contents 1._IPSEC/VPN_-FreeS/WAN 2._Compile,_insert_FreeS/WAN_into_the_kernel 3._Reconfigure_and_install_the_kernel_with_FreeS/WAN_VPN_support 4._Configure_to_optimise 5._Automatic_or_Manual_Key_connections 6._The_/etc/ipsec.conf_file 7._The_/etc/ipsec.secrets_file 8._Configure_RSA_private_keys_secrets 9._Required_network_setup_for_IPSec 10._Testing_the_installation 11._Further_documentation 12._Installed_files Protection of client-to-server with SSL solutions is an excellent choice but sometime for enterprise environments establishing secure communication channels, assuring full privacy, authenticity and data integrity in between two firewalls over the Internet are vital. For this, IPSEC has been created. 1. IPSEC/VPN -FreeS/WAN IPSEC is Internet Protocol SECurity. It uses strong cryptography to provide both authentication and encryption services. Authentication ensures that packets are from the right sender and have not been altered in transit. Encryption prevents unauthorized reading of packet contents. IPSEC can protect any protocol running above IP and any medium used below IP. IPSEC can also provide some security services in the background, with no visible impact on users. More to the point, it can protect a mixture of protocols running over a complex combination of media i.e. IMAP/POP etc. without having to change them in any ways, since the encryption occurs at the IP level. IPSEC services allow you to build secure tunnels through untrusted networks. Everything passing through the untrusted net is encrypted by the IPSEC gateway machine and decrypted by the gateway at the other end. The result is Virtual Private Network or VPN. This is a network, which is effectively private even though it includes machines at several different sites connected by the insecure Internet. FreeSWAN VPN These installation instructions assume * Commands are Unix-compatible. * The source path is /usr/src * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root * Kernel version number is 2.2.14 * FreeS/WAN VPN version number is 1.3 These are the Package(s) and available here Kernel Homepage: http://www.kernelnotes.org/ You must be sure to download: linux-2_2_14_tar.gz FreeS/WAN VPN Homepage Site: http://www.freeswan.org/ FreeS/WAN VPN FTP Site: 194.109.6.26 You must be sure to download: freeswan-1.3.tar.gz Before you decompress the tarballs, it is a good idea to make a list of files on the system before you install FreeS/WAN, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > Freeswan1 before and find /* > Freeswan2 after you install the software, and use diff Freeswan1 Freeswan2 > Freeswan-Installed to get a list of what changed. Some of the Prerequisites; the installation of IPSEC FreeS/WAN Virtual Private Network software requires some modification of your original kernel since FreeS/WAN must be included and incorporated in your kernel before you can use it. For this reason the first step in installing FreeS/WAN software is to go to the Linux_Kernel section in this book and follow the instructions on how to install the Linux Kernel on your system, even if you have already done this before and come back to Linux FreeS/WAN VPN (this section) after you have executed the make dep; make clean commands, but before the make bzImage command in the Linux Kernel section. Caution It is highly recommended that you not compile anything in the kernel with optimization flags if you intend to install the FreeSWAN software on your system. Any optimization flags added to the Linux kernel will produce errors messages in the FreeSWAN IPSEC software when it tries to run; this is an important warning you must note, or else nothing will work with FreeSWAN. The optimization flags documented in Configuring_and_Building_a_Secure,_Optimized kernel apply without any problems to all sections and chapters of this book with the single exception of the FreeSWAN IPSEC software. Once again, I repeat, don't use or add any optimization options or flags into your Linux kernel when compiling and patching it to support FreeSWAN. To Compile FreeS/WAN you need to decompress the tarball (tar.gz). [root@deep] /# cp freeswan-version.tar.gz /usr/src/ [root@deep] /# cd /usr/src [root@deep ]/src# tar xzpf freeswan-version.tar.gz [root@deep ]src# chown -R 0.0 /usr/src/freeswan-version 2. Compile, insert FreeS/WAN into the kernel You must modify the Makefile under the FreeS/WAN source directory and subdirectories named utils, klips/utils, Pluto, and lib to specify installation paths. We must modify these files to be compliant with Red Hat's file system structure and install FreeS/WAN files under our PATH environment variable. 1. Move to the top-level directory of the new FreeS/WAN distribution and type the following commands on your terminal: Edit the Makefile file, vi Makefile and change the following lines: a. PUBDIR=/usr/local/sbin To read: PUBDIR=/usr/sbin b. PRIVDIR=/usr/local/lib/ipsec To read: PRIVDIR=/usr/lib/ipsec c. FINALPRIVDIR=/usr/local/lib/ipsec To read: FINALPRIVDIR=/usr/lib/ipsec d. MANTREE=/usr/local/man To read: MANTREE=/usr/man 2. Edit the Makefile file of the subdirectory utils, vi utils/Makefile and change the following lines: a. PUBDIR=/usr/local/sbin To read: PUBDIR=/usr/sbin b. PRIVDIR=/usr/local/lib/ipsec To read: PRIVDIR=/usr/lib/ipsec c. FINALPRIVDIR=/usr/local/lib/ipsec To read: FINALPRIVDIR=/usr/lib/ipsec d. MANTREE=/usr/local/man To read: MANTREE=/usr/man 3. Edit the Makefile file of the subdirectory klips/utils, vi klips/utils/ Makefile and change the following lines: a. BINDIR=/usr/local/lib/ipsec To read: BINDIR=/usr/lib/ipsec b. MANTREE=/usr/local/man To read: MANTREE=/usr/man 4. Edit the Makefile file of the subdirectory pluto, vi pluto/Makefile and change the following lines: a. BINDIR=/usr/local/lib/ipsec To read: BINDIR=/usr/lib/ipsec b. MANTREE=/usr/local/man To read: MANTREE=/usr/man 5. Edit the Makefile file of the subdirectory lib, vi lib/Makefile and change the following lines: MANTREE=/usr/local/man To read: MANTREE=/usr/man 6. Edit the Makefile file of the subdirectory libdes, vi libdes/Makefile and change the following lines: a. LIBDIR=/usr/local/lib To read: LIBDIR=/usr/lib b. BINDIR=/usr/local/bin To read: BINDIR=/usr/bin c. INCDIR=/usr/local/include To read: INCDIR=/usr/include d. MANDIR=/usr/local/man To read: MANDIR=/usr/man The above changes, from step1 to step 6, will locate all files related to the FreeS/WAN software to the destination target directories we have chosen in order to be compliant with the Red Hat file system structure. Now, we must compile and install FreeSWAN on the server: [root@deep ]/freeswan-1.3# make insert [root@deep ]/freeswan-1.3# make programs [root@deep ]/freeswan-1.3# make install * The make insert command creates a symbolic link /usr/src/linux/net/ipsec, pointing to the KLIPS source directory. It patches some kernel files, where necessary, to know about KLIPS and/or to fix bugs. It also adds its default configuration to the kernel configuration file, and finally, it makes the KLIPS communication file, /dev/ipsec, if it's not already there. * The make programs command builds the libraries, Pluto, and various user-level utilities. * The make install will install the Pluto daemon and user-level utilities, and set things up for boot-time startup. 3. Reconfigure and install the kernel with FreeS/WAN VPN support Now, we must return to the /usr/src/linux directory and execute the following commands to reconfigure the kernel with FreeS/WAN support enable: [root@deep ]/freeswan-1.3# cd /usr/src/linux [root@deep ]/linux# make config Important The difference with the make config command we used before is that now a new section related to FreeS/WAN has been included in our kernel configuration, and for this reason we must reconfigure the kernel to customize the IPSec options to be part of your kernel. The first thing you need to do is ensure that your kernel has been built with FreeS/WAN support enabled. In the 2.2.14 kernel version, a new section related to frees/WAN VPN support named IPSec options (FreeS/WAN) should appear in your kernel configuration after you have patched the kernel with the FreeS/WAN program as descibed above. You need ensure that you have answered Y to the following questions under the new section: IPSec options (FreeS/WAN). IPSec options (FreeS/WAN) IP Security Protocol (FreeS/WAN IPSEC) (CONFIG_IPSEC) [Y/n/?] IPSEC: IP-in-IP encapsulation (CONFIG_IPSEC_IPIP) [Y/n/?] IPSEC: PF_KEYv2 kernel/user interface (CONFIG_IPSEC_PFKEYv2) [Y/n/?] IPSEC: Enable ICMP PMTU messages (CONFIG_IPSEC_ICMP) [Y/n/?] IPSEC: Authentication Header (CONFIG_IPSEC_AH) [Y/n/?] HMAC-MD5 authentication algorithm (CONFIG_IPSEC_AUTH_HMAC_MD5) [Y/n/?] HMAC-SHA1 authentication algorithm (CONFIG_IPSEC_AUTH_HMAC_SHA1) [Y/n/?] IPSEC: Encapsulating Security Payload (CONFIG_IPSEC_ESP) [Y/n/?] 3DES encryption algorithm (CONFIG_IPSEC_ENC_3DES) [Y/n/?] IPSEC Debugging Option (DEBUG_IPSEC) [Y/n/?] Tip All the customizations you made to your kernel the first time you ran the make config, make dep, and make clean commands will be preserved, so you don't need to reconfigure every part of your kernel; Just the new section added by FreeS/ WAN named IPSec options (FreeS/WAN) is required, as shown above. Some networking options will get turned on automatically, even if you previously turned them off, this is because IPSEC needs them. Whichever configuration program you are using, you should pay careful attention to a few issues. In particular, do not disable any of the following under the Networking Options of your kernel configuration: Kernel/User netlink socket (CONFIG_NETLINK) [Y/n/?] Netlink device emulation (CONFIG_NETLINK_DEV) [Y/n/?] You need to Compile and install the new kernel with FreeS/WAN, now that we have included in the kernel the support for FreeS/WAN VPN, Return to the /usr/src/ linux directory and run the following commands again: [root@deep ]/linux# make dep; make clean; make bzImage After execution of the commands above, follow the rest of the instructions in the Linux Kernel section of this book Configuring_and_Building_a_secure, optimized_Kernel as normal to install the kernel. At this point, after you have copied and installed your new kernel image, system.map, or modules, if necessary and set the lilo.conf file to load the new kernel, you must edit and customize the configuration files related to FreeS/WAN ipsec.conf and ipsec.secrets before rebooting your system. Please don't forget to cleanup later: [root@deep] /# cd /usr/src [root@deep ]/src# rm -rf freeswan-version/ freeswan-version.tar.gz The rm command will remove all the source files we have used to compile and install FreeS/WAN. It will also remove the FreeS/WAN compressed archive from the /usr/src directory. 4. Configure to optimise Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example FreeSWAN configuration file are organised like this: total 8 -rw-r--r-- 1 harrypotter harrypotter 998 Jun 8 13:00 ipsec.conf -rw------- 1 harrypotter harrypotter 1838 Jun 8 13:00 ipsec.secrets You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run FreeSWAN, the following files are required and must be created or copied to the appropriate directories on your server. i. Copy the ipsec.conf file to the /etc/ directory. ii. Copy the ipsec.secrets file to the /etc/ directory. Tip You can obtain the configuration files listed below on our floppy.tgz archive. Copy the following files from the decompressed floppy.tgz archive to the appropriate places or copy and paste them directly from this book to the concerned file. 5. Automatic or Manual Key connections The configuration file for FreeS/WAN /etc/ipsec.conf allows you to configure your IPSEC configurations, control information and connections types. IPSEC currently supports two types of connections: Manually keyed Manually keyed connections use keys stored in the /etc/ipsec.conf file. This type of connection is less secure then automatically keyed. Automatically keyed. Automatically keyed connections use keys automatically generated by the Pluto key negotiation daemon. The key negotiation protocol, used by default and named IKE, authenticates the other system using shared secrets stored in /etc/ipsec.secrets file. The difference is strictly in how they are keyed. For these reasons, we will use and show you the automatically keyed connection that is more secure then the manually keyed connection. Once again, it is highly recommended that you use the automatically keyed connection. In our example configuration below, we configure a sample tunnel with a firewall-penetrating tunnel, and we assume that firewalling is being done on the left and right side. We choose to show you this configuration since we assume it is what most users and companies will use. Also, it allows us to play with more options in the configuration file ipsec.conf for automatically keyed connections. Different configurations exist and you may consult the doc/ examples file under the subdirectory doc of the frees/WAN source directory for more information and other possible configurations. SubnetDeep======Deep------Deepgate..........Mailgate------- Mail======SubnetMail Untrusted net leftsubnet = SubnetDeep (192.168.1.0/24) left = Deep (deep.openna.com) leftnexthop = Deepgate (the first router in the direction or ISP router for deep.openna.com) Internet = Untrusted net rightnexthop = Mailgate (the first router in the direction or ISP router for mail.openna.com) right = Mail (mail.openna.com) rightsubnet = SubnetMail (192.168.1.0/24) *        SubnetDeep   \ 192.168.1.0/24 /   +--------------------+                 | SubnetDeep is the IP network address of your private internal network on the first gateway. eth1 is attached to the internal network. *             Deep    \ 208.164.186.1 /    +-------------------+                 | Deep is the IP address of your first Gateway. eth0 is attached to the Internet. *          Deepgate  \ 205.151.222.250 /  +----------------------+                 | Deepgate is the IP address of the first router in the direction of your second gateway mail.openna.com or your ISP router. *  I  N  T  E  R  N  E  T                 | INTERNET is the untrusted network. *           Mailgate  / 205.151.222.251 \ +------------------------+                 | Mailgate is the IP address of the first router in the direction of your first gateway deep.openna.com or your ISP router. *              Mail    / 208.164.186.2 \   +---------------------+                 | Mail is the IP address of your second Gateway. eth0 is attached to the Internet. *        SubnetMail   / 192.168.1.0/24 \  +----------------------+ SubnetMail is the IP network address of your private internal network on the second gateway. eth1 is attached to the internal network. 6. The /etc/ipsec.conf file We must edit the ipsec.conf file vi /etc/ipsec.conf and change the default values to fit our specifications for IPSEC configuration and communication. Currently there are two types of section in this file /etc/ipsec.conf: 1. A config section which specifies general configuration information for IPSEC, 2. A conn section which specifies an IPSEC connection. Its contents are not security-sensitive unless manual keying is being done, recall, manual keying is not recommended for security reasons. * The first section type, called config setup, is the only config section known to the IPSEC software containing overall setup parameters for IPSEC that apply to all connections, and information used when the software is being started. * The second type, called conn, contains a connection specification defining a network connection to be made using IPSEC. The name it is given is arbitrary, and is simply used to identify the connection to ipsec_auto(8) and ipsec_manual(8). # /etc/ipsec.conf - FreeS/WAN IPSEC configuration file # More elaborate and more varied sample configurations can be found # in doc/examples. # basic configuration config setup interfaces="ipsec0=eth0" klipsdebug=none plutodebug=none plutoload=%search plutostart=%search # sample connection conn deep-mail left=208.164.186.1 leftsubnet=192.168.1.0/24 leftnexthop=205.151.222.250 right=208.164.186.2 rightsubnet=192.168.1.0/24 rightnexthop=205.151.222.251 keyingtries=0 auth=ah auto=start This tells ipsec.conf file to set itself up for this particular configuration setup with: interfaces="ipsec0=eth0" This option specifies which appropriate virtual and physical interfaces for IPSEC to use. The default setting, interfaces=%defaultroute, will look for your default connection to the Internet, or your corporate network. Also, you can name one or more specific interfaces to be used by FreeS/WAN. For example: interfaces="ipsec0=eth0" interfaces="ipsec0=eth0 ipsec1=ppp0" Both set the eth0 interface as ipsec0. The second one, however, also supports IPSEC over a PPP interface. If the default setting interfaces=%defaultroute is not used, then the specified interfaces will be the only ones this gateway machine can use to communicate with other IPSEC gateways. klipsdebug=none This option specifies the debugging output for KLIPS -the kernel IPSEC code. The default value none, means no debugging output and the value all means full output. plutodebug=none This option specifies the debugging output for the Pluto key. The default value, none, means no debugging output, and the value all means full output. plutoload=%search This option specifies which connections (by name) to load automatically into memory when Pluto starts. The default is none and the value %search loads all connections with auto=add or auto=start. plutostart=%search This option specifies which connections (by name) to automatically negotiate when Pluto starts. The default is none and the value %search starts all connections with auto=start. conn deep-mail This option specifies the name given to identify the connection specification to be made using IPSEC. It's a good convention to name connections by their ends to avoid mistakes. For example, the link between deep.openna.com and mail.openna.com gateways server can be named deep-mail, or the link between your Montreal and Paris offices, montreal- paris. Note Note that the names deep-mail or whatever you have chosen should be the same in the ipsec.conf file on both gateways. In other words, the only change you should make in the /etc/ipsec.conf file on the second gateway is changing the interfaces= line to match the interface the second gateway uses for IPSEC connection, if, of course, it's different from the first gateway. For example, if the interface eth0 is used on the both gateways for IPSEC communication, you don't need to change the line interfaces= on the second gateway. On the other hand, if the first gateway use eth0 and the second use eth1, you must change the line interfaces= on the second gateway to match the interface eth1. left=208.164.186.1 This option specifies the IP address of the gateway's external interface used to talk to the other gateway. leftsubnet=192.168.1.0/24 This option specifies the IP network or address of the private subnet behind the gateway. leftnexthop=205.151.222.250 This option specifies the IP address of the first router in the appropriate direction or ISP router. right=208.164.186.2 This is the same explanation as left= but for the right destination. rightsubnet=192.168.1.0/24 This is the same explanation as leftsubnet= but for the right destination. rightnexthop=205.151.222.251 This is the same explanation as leftnexthop= but for the right destination. keyingtries=0 This option specifies how many attempts (an integer) should be made in (re)keying negotiations. The default value 0 (retry forever) is recommended. auth=ah This option specifies whether authentication should be done separately using AH (Authentication Header), or be included as part of the ESP - Encapsulated Security Payload service. This is preferable when the IP headers are exposed to prevent man-in-the-middle attacks. auto=start This option specifies whether automatic startup operations should be done at IPSEC startup. Caution A data mismatch anywhere in this configuration ipsec.conf will cause FreeS/WAN to fail and to log various error messages. 7. The /etc/ipsec.secrets file The file ipsec.secrets stores the secrets used by the pluto daemon to authenticate communication between both gateways. Two different kinds of secrets can be configured in this file, which are preshared secrets and RSA private keys. You must check the modes and permissions of this file to be sure that the super-user root owns the file, and its permissions are set to block all access by others. 1. An example secret is supplied in the ipsec.secrets file by default. You should change it by creating your own. With automatic keying you may have a shared secret up to 256 bits, which is then used during the key exchanges to make sure a man in the middle attack does not occur. To create a new shared secret, use the following commands: [root@deep] /# ipsec ranbits 256 > temp New, random keys are created with the ranbits(8) utility in the file named temp. The ranbits utility may pause for a few seconds if not enough entropy is available immediately. Caution Dont forget to delete the temporary file as soon as you are done with it. 2. Now that our new shared secret key has been created in the temp file, we must put it in the /etc/ipsec.secrets file. When editing the ipsec.secrets file, you should see something like the following appearing in your text editor. Each line has the IP addresses of the two gateways plus the secret. It should look something like this: # This file holds shared secrets which are currently the only inter- Pluto # authentication mechanism. See ipsec_pluto(8) manpage. Each secret is # (oversimplifying slightly) for one pair of negotiating hosts. # The shared secrets are arbitrary character strings and should be both # long and hard to guess. # Note that all secrets must now be enclosed in quotes, even if they have # no white space inside them. 10.0.0.1 11.0.0.1 "jxVS1kVUTTulkVRRTnTujSm444jRuU1mlkklku2nkW3nnVu V2WjjRRnulmlkmU1Run5VSnnRT" a. Edit the ipsec.secrets file, vi /etc/ipsec.secrets and change the default secrets keys: 10.0.0.1 11.0.0.1 " jxVS1kVUTTulkVRRTnTujSm444jRuU1mlkklku2nkW3nnVu V2WjjRRnulmlkmU1Run5VSnnRT " To read: 208.164.186.1 208.164.186.2 "0x9748cc31_2e99194f_d230589b_cd846b57_dc070b01_74b66f34_19c40a1a_804906ed" Where 208.164.186.1 and 208.164.186.2 are the IP addresses of the two gateways and "0x9748cc31_2e99194f_d230589b_cd846b57_dc070b01_74b66f34_19c40a1a_804906ed" note that the quotes are required is the shared secret we have generated above with the command ipsec ranbits 256 > temp in the temp file. 3. The files ipsec.conf and ipsec.secrets must be copied to the second gateway machine so as to be identical on both ends. The only exception to this is the ipsec.conf file, which must have in it a section labeled by the line config setup with the correct interface settings for the second gateway, if they differ from the first. The ipsec.secrets file, contrary to the RSA private key, should absolutely have the same-shared secrets on the two gateways. Important The file /etc/ipsec.secrets should have permissions rw-------(600) and be owned by the super-user root. The file /etc/ipsec.conf is installed with permissions rw-r--r (644) and must be owned also by root. 8. Configure RSA private keys secrets Recall that currently with FreeSWAN software there are two kinds of secrets: i. preshared secrets ii. RSA private keys. The preshared secrets are what we have configured in our ipsec.conf and ipsec.secrets example, above. Some people may prefer to use RSA private keys for authentication by the Pluto daemon of the other hosts. If you are in this situation, you will have to make some minor modifications to your ipsec.conf and ipsec.secrets files as described in the following steps: You need to create a separate RSA key for *each* gateway. Each one gets its private key in its own ipsec.secrets file, and the public keys go in leftrsasigkey and rightrsasigkey parameters in the conn description of ipsec.conf file, which goes to both. 1. Create a separate RSA key for *each* gateway: a. On the first gateway i.e. deep, use the following commands: [root@deep] /# cd / [root@deep] /# ipsec rsasigkey --verbose 1024 > deep-keys computing primes and modulus... getting 64 random bytes from /dev/random looking for a prime starting there found it after 30 tries getting 64 random bytes from /dev/random looking for a prime starting there found it after 230 tries swapping primes so p is the larger computing (p-1)*(q-1)... computing d... computing exp1, exp1, coeff... output... b. On the second gateway i.e. mail, use the following commands: [root@mail /]# cd / [root@mail /]# ipsec rsasigkey --verbose 1024 > mail-keys computing primes and modulus... getting 64 random bytes from /dev/random looking for a prime starting there found it after 30 tries getting 64 random bytes from /dev/random looking for a prime starting there found it after 230 tries swapping primes so p is the larger computing (p-1)*(q-1)... computing d... computing exp1, exp1, coeff... output... The rsasigkey utility generates an RSA public and private key pair of a 1024-bit signature, and puts it in the file deep-keys. mail-keys for the second command on the second gateway. The private key can be inserted verbatim into the ipsec.secrets file, and the public key into the ipsec.conf file. 2. Tip The rsasigkey utility may pause for a few seconds if not enough entropy is available immediately. You may want to give it some bogus activity such as random mouse movements. The temporary RSA. deep-keys and mail-keys files should be deleted as soon as you are done with it. Don't forget to delete the deep-keys and mail-keys RSA files. 3. Modify your /etc/ipsec.conf files to use RSA public keys in *each* gateway: a. Edit you original ipsec.conf file, vi /etc/ipsec.conf and add the following parameters related to RSA in the conn desciption of your ipsec.conf file on both gateway: # sample connection conn deep-mail left=208.164.186.1 leftsubnet=192.168.1.0/24 leftnexthop=205.151.222.250 right=208.164.186.2 rightsubnet=192.168.1.0/24 rightnexthop=205.151.222.251 keyingtries=0 auth=ah authby=rsasig 1 leftrsasigkey= 2 rightrsasigkey= 3 auto=start _1_ This parameter specifies how the two security gateways should authenticate each other. The default value is secret for shared secrets. We must specify rsasig for RSA since we have decided to use RSA digital signatures. _2_ This parameter specifies the left participant's public key for RSA signature authentication. In our example, left is 208.164.186.1, and represents deep.openna.com, so we must put the RSA public key for deep on this line. _3_ This parameter specifies the right participant's public key for RSA signature authentication. In our example, right is 208.164.186.2, and represents mail.openna.com, so we must put the RSA public key of mail on this line. b. You can retrieve the public key of deep in the RSA key file called deep-keys, and the public key of mail in the RSA key file named mail- keys, that we have created in above step. These files will look like this: RSA keys for gateway deep (deep-keys): [root@deep] /# cd / [root@deep] /# vi deep-keys # 1024 bits, Fri Feb 4 05:05:19 2000 # for signatures only, UNSAFE FOR ENCRYPTION #pubkey=0x010395daee1be05f3038ae529ef2668afd79f5ff1b16203c9ceaef801cea9cb74bcfb51a6ecc08890d3eb4b5470c0fc35465c8ba2ce9d1145ff07b5427e04cf4a38ef98a7f29edcb4d7689f2da7a69199e4318b4c8d0ea25d33e4f084186a2a54f4b4cec12cca1a5deac3b19d561c16a76bab772888f1fd71aa08f08502a141b611f Modulus: 0x95daee1be05f3038ae529ef2668afd79f5ff1b16203c9ceaef801cea9cb74bcfb51a6ecc08890d3eb4b5470c0fc35465c8ba2ce9d1145ff07b5427e04cf4a38ef98a7f29edcb4d7689f2da7a69199e4318b4c8d0ea25d33e4f084186a2a54f4b4cec12cca1a5deac3b19d561c16a76bab772888f1fd71aa08f08502a141b611f PublicExponent: 0x03 # everything after this point is secret PrivateExponent: 0x63e74967eaea2025c98c69f6ef0753a6a3ff6764157dbdf1f50013471324dd352366f48805b0b37f232384b2b52ce2ee85d173468b62eaa052381a9588a317b3a1324d01a531a41fa7add6c5efbdd88f4718feed2bc0246be924e81bb90f03e49ceedf7af0dd48f06f265b519600bd082c6e6bd27eaa71cc0288df1ecc3b062b Prime1: 0xc5b471a88b025dd09d4bd7b61840f20d182d9b75bb7c11eb4bd78312209e3aee7ebfe632304db6df5e211d21af7fee79c5d45546bea3ccc7b744254f6f0b847f Prime2: 0xc20a99feeafe79767122409b693be75f15e1aef76d098ab12579624aec708e85e2c5dd62080c3a64363f2f45b0e96cb4aef8918ca333a326d3f6dc2c72b75361 Exponent1: 0x83cda11b0756e935be328fcebad5f6b36573bcf927a80bf2328facb6c0697c9eff2a9976cade79ea3ec0be1674fff4512e8d8e2f29c2888524d818df9f5d02ff Exponent2: 0x815c66a9f1fefba44b6c2b124627ef94b9411f4f9e065c7618fb96dc9da05f03ec83e8ec055d7c42ced4ca2e75f0f3231f5061086ccd176f37f9e81da1cf8ceb Coefficient: 0x10d954c9e2b8d11f4db1b233ef37ff0a3cecfffad89ba5d515449b007803f577e3bd7f0183ceddfd805466d62f767f3f5a5731a73875d30186520f1753a7e325 c. RSA keys for gateway mail -mail-keys: [root@mail /]# cd / [root@mail /]# vi mail-keys # 1024 bits, Fri Feb 4 04:46:59 2000 # for signatures only, UNSAFE FOR ENCRYPTION #pubkey=0x01037631b81f00d5e6f888c542d44dbb784cd3646f084ed96f942d341c7c4686cbd405b805dc728f8697475f11e8b1dd797550153a3f0d4ff0f2b274b70a2ebc88f073748d1c1c8821dc6be6a2f0064f3be7f8e4549f8ab9af64944f829b014788dd202cf7d2e320cab666f5e7a197e64efe0bfee94e92ce4dad82d5230c57b89edf Modulus: 0x7631b81f00d5e6f888c542d44dbb784cd3646f084ed96f942d341c7c4686cbd405b805dc728f8697475f11e8b1dd797550153a3f0d4ff0f2b274b70a2ebc88f073748d1c1c8821dc6be6a2f0064f3be7f8e4549f8ab9af64944f829b014788dd202cf7d2e320cab666f5e7a197e64efe0bfee94e92ce4dad82d5230c57b89edf PublicExponent: 0x03 # everything after this point is secret PrivateExponent: 0x4ecbd014ab3944a5b08381e2de7cfadde242f4b03490f50d737812fd8459dd3803d003e84c5faf0f84ea0bf07693a64e35637c2a08dff5f721a324b1747db09f62c871d5e11711251b845ae76753d4ef967c494b0def4f5d0762f65da603bc04c41b4c6cab4c413a72c633b608267ae2889c162a3d5bc07ee083b1c6e038400b Prime1: 0xc7f7cc8feaaac65039c39333b878bffd8f95b0dc22995c553402a5b287f341012253e9f25b83983c936f6ca512926bebee3d5403bf9f4557206c6bbfd9aac899 Prime2: 0x975015cb603ac1d488dc876132d8bc83079435d2d3395c03d5386b5c004eadd4d7b01b3d86aad0a2275d2d6b791a2abe50d7740b7725679811a32ca22db97637 Exponent1: 0x854fddb5471c84357bd7b777d0507ffe5fb92092c1bb92e37801c3cc5aa22b5616e29bf6e7ad1028624a486e0c619d47f428e2ad2a6a2e3a159d9d2a911c85bb Exponent2: 0x64e00e87957c81385b3daf9621e5d302050d7937377b92ad38d04792aadf1e8de52012290471e06c1a3e1e47a61171d435e4f807a4c39a6561177316c9264ecf Coefficient: 0x6f087591becddc210c2ee0480e30beeb25615a3615203cd3cef65e5a1d476fd9602ca0ef10d9b858edb22db42c975fb71883a470b43433a7be57df7ace4a0a3f d. Extract and copy the public RSA key files of deep and mail to your ipsec.conf files as shown below. You can locate the line related to the public key by a sentence beginning with the commented-out: #pubkey= line. # sample connection conn deep-mail left=208.164.186.1 leftsubnet=192.168.1.0/24 leftnexthop=205.151.222.250 right=208.164.186.2 rightsubnet=192.168.1.0/24 rightnexthop=205.151.222.251 keyingtries=0 auth=ah authby=rsasig leftrsasigkey=0x010395daee1be05f3038ae529ef2668afd79f5ff1b16203c9ceaef801cea9cb74bcfb51a6ecc08890d3eb4b5470c0fc35465c8ba2ce9d1145ff07b5427e04cf4a38ef98a7f29edcb4d7689f2da7a69199e4318b4c8d0ea25d33e4f084186a2a54f4b4cec12cca1a5deac3b19d561c16a76bab772888f1fd71aa08f08502a141b611f rightrsasigkey=0x01037631b81f00d5e6f888c542d44dbb784cd3646f084ed96f942d341c7c4686cbd405b805dc728f8697475f11e8b1dd797550153a3f0d4ff0f2b274b70a2ebc88f073748d1c1c8821dc6be6a2f0064f3be7f8e4549f8ab9af64944f829b014788dd202cf7d2e320cab666f5e7a197e64efe0bfee94e92ce4dad82d5230c57b89edf auto=start 4. Note Don't forget that, in this example, o The leftrsasigkey= parameter contains the public key of deep o The rightrsasigkey= parameter contains the public key of mail. 5. Modify your /etc/ipsec.secrets files to use RSA private keys in *each* gateway: Edit your original ipsec.secrets file, vi /etc/ipsec.secrets and add the RSA private key for authentication on both gateways: The ipsec.secrets file for gateway deep: [root@deep] /# vi /etc/ipsec.secrets 208.164.186.1 208.164.186.2 "0x9748cc31_2e99194f_d230589b_cd846b57_dc070b01_74b66f34_19c40a1a_804906ed" You must change your original ipsec.secrets file as shown above to look like the following on both gateways. It is important to note that the private keys are not the same on both gateways, deep and mail. The private key for deep comes from the RSA key file deep-keys, while the private key for mail comes from the RSA key file mail-keys: a. 208.164.186.1 208.164.186.2: RSA { Modulus: 0x95daee1be05f3038ae529ef2668afd79f5ff1b16203c9ceaef801cea9cb74bcfb51a6ecc08890d3eb4b5470c0fc35465c8ba2ce9d1145ff07b5427e04cf4a38ef98a7f29edcb4d7689f2da7a69199e4318b4c8d0ea25d33e4f084186a2a54f4b4cec12cca1a5deac3b19d561c16a76bab772888f1fd71aa08f08502a141b611f PublicExponent: 0x03 # everything after this point is secret PrivateExponent: 0x63e74967eaea2025c98c69f6ef0753a6a3ff6764157dbdf1f50013471324dd352366f48805b0b37f232384b2b52ce2ee85d173468b62eaa052381a9588a317b3a1324d01a531a41fa7add6c5efbdd88f4718feed2bc0246be924e81bb90f03e49ceedf7af0dd48f06f265b519600bd082c6e6bd27eaa71cc0288df1ecc3b062b Prime1: 0xc5b471a88b025dd09d4bd7b61840f20d182d9b75bb7c11eb4bd78312209e3aee7ebfe632304db6df5e211d21af7fee79c5d45546bea3ccc7b744254f6f0b847f Prime2: 0xc20a99feeafe79767122409b693be75f15e1aef76d098ab12579624aec708e85e2c5dd62080c3a64363f2f45b0e96cb4aef8918ca333a326d3f6dc2c72b75361 Exponent1: 0x83cda11b0756e935be328fcebad5f6b36573bcf927a80bf2328facb6c0697c9eff2a9976cade79ea3ec0be1674fff4512e8d8e2f29c2888524d818df9f5d02ff Exponent2: 0x815c66a9f1fefba44b6c2b124627ef94b9411f4f9e065c7618fb96dc9da05f03ec83e8ec055d7c42ced4ca2e75f0f3231f5061086ccd176f37f9e81da1cf8ceb Coefficient: 0x10d954c9e2b8d11f4db1b233ef37ff0a3cecfffad89ba5d515449b007803f577e3bd7f0183ceddfd805466d62f767f3f5a5731a73875d30186520f1753a7e325 } b. The ipsec.secrets file for gateway mail: [root@mail ]/# vi /etc/ipsec.secrets 208.164.186.1 208.164.186.2: RSA { Modulus: 0x95daee1be05f3038ae529ef2668afd79f5ff1b16203c9ceaef801cea9cb74bcfb51a6ecc08890d3eb4b5470c0fc35465c8ba2ce9d1145ff07b5427e04cf4a38ef98a7f29edcb4d7689f2da7a69199e4318b4c8d0ea25d33e4f084186a2a54f4b4cec12cca1a5deac3b19d561c16a76bab772888f1fd71aa08f08502a141b611f PublicExponent: 0x03 # everything after this point is secret PrivateExponent: 0x63e74967eaea2025c98c69f6ef0753a6a3ff6764157dbdf1f50013471324dd352366f48805b0b37f232384b2b52ce2ee85d173468b62eaa052381a9588a317b3a1324d01a531a41fa7add6c5efbdd88f4718feed2bc0246be924e81bb90f03e49ceedf7af0dd48f06f265b519600bd082c6e6bd27eaa71cc0288df1ecc3b062b Prime1: 0xc5b471a88b025dd09d4bd7b61840f20d182d9b75bb7c11eb4bd78312209e3aee7ebfe632304db6df5e211d21af7fee79c5d45546bea3ccc7b744254f6f0b847f Prime2: 0xc20a99feeafe79767122409b693be75f15e1aef76d098ab12579624aec708e85e2c5dd62080c3a64363f2f45b0e96cb4aef8918ca333a326d3f6dc2c72b75361 Exponent1: 0x83cda11b0756e935be328fcebad5f6b36573bcf927a80bf2328facb6c0697c9eff2a9976cade79ea3ec0be1674fff4512e8d8e2f29c2888524d818df9f5d02ff Exponent2: 0x815c66a9f1fefba44b6c2b124627ef94b9411f4f9e065c7618fb96dc9da05f03ec83e8ec055d7c42ced4ca2e75f0f3231f5061086ccd176f37f9e81da1cf8ceb Coefficient: 0x10d954c9e2b8d11f4db1b233ef37ff0a3cecfffad89ba5d515449b007803f577e3bd7f0183ceddfd805466d62f767f3f5a5731a73875d30186520f1753a7e325 } Authentication by RSA Signatures requires that each host have its own private key. The key part of an entry may start with a token indicating the kind of key. RSA signifies RSA private key and PSK - which is the default signifies PreShared Key. Since PSK is the default, we must specify RSA, so that we'll be able to use RSA private keys in this file ipsec.secrets. The super-user root should own the file ipsec.secrets, and its permissions should be set to block all access by others. 9. Required network setup for IPSec There are some considerations you must ensure are correct before running FreeS/ WAN software. These considerations are important if you don't want to receive error messages during start up of your VPN. The following are required: You will need to enable TCP/IP forwarding on the both gateway servers. In Red Hat Linux, this is accomplished by changing or adding the following line, depending on the Red Hat version you use: Version 6.1 only Edit the network file, vi /etc/sysconfig/network, and change the following line: FORWARD_IPV4="false" To read: FORWARD_IPV4="yes" You must restart your network for the change to take effect: [root@deep] /# /etc/rc.d/init.d/network restart Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Bringing up interface eth1 [ OK ] Version 6.2 only To enable IPv4 forwarding on your RH 6.2 system, use the following command: Edit the /etc/sysctl.conf file and add the following line: # Enable packet forwarding net.ipv4.ip_forward = 1 You must restart your network for the change to take effect. The command to restart the network is the following: [root@deep] /# /etc/rc.d/init.d/network restart Setting network parameters [ OK ] Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Bringing up interface eth1 [ OK ] Recall that automatically keyed connections use keys automatically generated by the Pluto key negotiation daemon. The pluto daemon will start up, try to connect to the Pluto daemon at the other end of the tunnel, and establish a connection. For this reason, an IPSEC gateway should have packet filters rules in the firewall script file permitting the following protocols to traverse the gateway when talking to other IPSEC gateway: i. UDP port 500 for IKE implemented by the Pluto daemon ii. Protocol 50 for ESP encryption and/or authentication iii. Protocol 51 for AH packet-level authentication 1. Edit the firewall script file, vi /etc/rc.d/init.d/firewall on both gateway machines, and add/check the following lines to allow IPSEC packets to traverse the remote network gateway to your network gateway and vice versa: # FreeS/WAN IPSec VPN # ------------------- # If you are using the FreeSWAN IPSec VPN, you will need to fill in the # addresses of the gateways in the IPSECSG and the virtual interfaces for # FreeS/Wan IPSEC in the FREESWANVI parameters. Look at the beginning of # this firewall script rules file to set the parameters. # IPSECSG is a Space separated list of remote gateways. FREESWANVI is a # Space separated list of virtual interfaces for FreeS/Wan IPSEC # implementation. Only include those that are actually used. # Allow IPSEC protocol from remote gateways on external interface # IPSEC uses three main types of packet: # IKE uses the UDP protocol and port 500, # ESP use the protocol number 50, and # AH use the protocol number 51 ipchains -A input -i $EXTERNAL_INTERFACE -p udp \ -s $IPSECSG -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p udp \ -d $IPSECSG -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p 50 \ -s $IPSECSG -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p 50 \ -d $IPSECSG -j ACCEPT ipchains -A input -i $EXTERNAL_INTERFACE -p 51 \ -s $IPSECSG -j ACCEPT ipchains -A output -i $EXTERNAL_INTERFACE -p 51 \ -d $IPSECSG -j ACCEPT # Allow all traffic to FreeS/WAN Virtual Interface ipchains -A input -i $FREESWANVI \ -s $ANYWHERE \ -d $ANYWHERE -j ACCEPT ipchains -A output -i $FREESWANVI \ -s $ANYWHERE \ -d $ANYWHERE -j ACCEPT # Forward anything from the FreeS/WAN virtual interface IPSEC tunnel ipchains -A forward -i $FREESWANVI \ -s $ANYWHERE \ -d $ANYWHERE -j ACCEPT where EXTERNAL_INTERFACE="eth0" You external interface to the Internet. ANYWHERE="any/0" Mean everywhere 0.0.0.0/0. IPSECSG=208.164.186.2 Space separated list of remote VPN gateways. FREESWANVI=ipsec0 Space separated list of virtual interfaces for FreeS/Wan. Important See Networking_Firewall, for more information. Dont forget to add/check these firewall rules in the other gateway as well. 2. The rp_filter subsystem related to IP spoofing protection must be turned off on both gateways for IPSEC to work properly. This is accomplished by checking if the value 0 (off) is set in the /proc/sys/net/ipv4/conf/ ipsec0/rp_filter and /proc/sys/net/ipv4/conf/eth0/rp_filter files respectively: a. To check if the value 0 (off) is set in the rp_filter files, use the commands: [root@deep] /# cat /proc/sys/net/ipv4/conf/ipsec0/rp_filter 0 [root@deep] /# cat /proc/sys/net/ipv4/conf/eth0/rp_filter 0 Important The subdirectory ipsec0 in our example will be created only after the reboot of your system. So you may check the value of the rp_filter file in the ipsec0 directory after your system has been restarted. b. To set the value 0 (off) in the both rp_filter files manually, use the command: [root@deep] /# echo 0 > /proc/sys/net/ipv4/conf/ipsec0/rp_filter [root@deep] /# echo 0 > /proc/sys/net/ipv4/conf/eth0/rp_filter Tip Also you can put lines like the following in your firewall script files /etc/rc.d/init.d/firewall on the both gateways to automatically set these values to 0 (off) and avoid making them manually: # Disable IP spoofing protection to allow IPSEC to work properly echo 0 > /proc/sys/net/ipv4/conf/ipsec0/rp_filter echo 0 > /proc/sys/net/ipv4/conf/eth0/rp_filter 3. Note In the example of the firewall script file above, we assume that eth0 is the interface you use for your connection. Of course if you use eth1 you must change eth0 to eth1, and so on. If you forget this step you will receive error messages on your terminal such as the following during the start up of FreeSWAN IPSEC: ipsec_setup: WARNING: ipsec0 has route filtering turned on, KLIPS may not work ipsec_setup: (/proc/sys/net/ipv4/conf/ipsec0/rp_filter = `1', should be 0) ipsec_setup: WARNING: eth0 has route filtering turned on, KLIPS may not work ipsec_setup: (/proc/sys/net/ipv4/conf/eth0/rp_filter = `1', should be 0) 4. It's important to note that any masquerading rules for internal networks that use IPSEC must come after the rules allowing IPSEC related traffic (The step 2 and 3 above), or the machine will try to masquerade the packets, instead of them being passed over to IPSEC. Edit the firewall script file, vi /etc/rc.d/init.d/firewall on both gateway machines and add/check the following lines to allow masqueraded packets to traverse the remote network gateway to your network gateway and vice versa: # Masquerade internal traffic. # All internal traffic is masqueraded externally. ipchains -A forward -i $EXTERNAL_INTERFACE -s $LOCALNET_1 -j MASQ Where EXTERNAL_INTERFACE="eth0" You external interface to the Internet. LOCALNET_1=" 192.168.1.0/24" whatever private range you use. Note See Networking_Firewall_with_Masquerading_and_Forwarding support for more information. Now, you can reboot your system, and the machines on Gateway A should be able to talk to the machines on Gateway B with no problems. 10. Testing the installation Reboot the both gateways to get FreeS/WAN started. Examine the /var/log/ messages file for any signs of trouble. If all goes well you should see something like this in the /var/log/messages file: Feb 2 05:22:35 deep ipsec_setup: Starting FreeS/WAN IPSEC snap2000jan31b... Feb 2 05:22:35 deep ipsec_setup: KLIPS debug `none' Feb 2 05:22:35 deep ipsec_setup: KLIPS ipsec0 on eth0 192.168.1.1/ 255.255.255.0 broadcast 192.168.1.255 Feb 2 05:22:36 deep ipsec_setup: Disabling core dumps: Feb 2 05:22:36 deep ipsec_setup: Starting Pluto (debug `none'): Feb 2 05:22:37 deep ipsec_setup: Loading Pluto database `deep-mail': Feb 2 05:22:37 deep ipsec_setup: Enabling Pluto negotiation: Feb 2 05:22:37 deep ipsec_setup: Routing for Pluto conns `deep-mail': Feb 2 05:22:37 deep ipsec_setup: Initiating Pluto tunnel `deep-mail': Feb 2 05:22:39 deep ipsec_setup: 102 "deep-mail" #1: STATE_MAIN_I1: initiate Feb 2 05:22:39 deep ipsec_setup: 104 "deep-mail" #1: STATE_MAIN_I2: from STATE_MAIN_I1; sent MI2, expecting MR2 Feb 2 05:22:39 deep ipsec_setup: 106 "deep-mail" #1: STATE_MAIN_I3: from STATE_MAIN_I2; sent MI3, expecting MR3 Feb 2 05:22:39 deep ipsec_setup: 004 "deep-mail" #1: STATE_MAIN_I4: SA established Feb 2 05:22:39 deep ipsec_setup: 110 "deep-mail" #2: STATE_QUICK_I1: initiate Feb 2 05:22:39 deep ipsec_setup: 004 "deep-mail" #2: STATE_QUICK_I2: SA established Feb 2 05:22:39 deep ipsec_setup: ...FreeS/WAN IPSEC started Examine the /var/log/secure file for any signs of trouble. If all goes well you should see something like the following: Feb 21 14:45:42 deep Pluto[432]: Starting Pluto (FreeS/WAN Version 1.3) Feb 21 14:45:43 deep Pluto[432]: added connection description "deep-mail" Feb 21 14:45:43 deep Pluto[432]: listening for IKE messages Feb 21 14:45:43 deep Pluto[432]: adding interface ipsec0/eth0 192.168.1.1 Feb 21 14:45:43 deep Pluto[432]: loading secrets from "/etc/ipsec.secrets" Feb 21 14:45:43 deep Pluto[432]: "deep-mail" #1: initiating Main Mode Feb 21 14:45:44 deep Pluto[432]: "deep-mail" #1: ISAKMP SA established Feb 21 14:45:44 deep Pluto[432]: "deep-mail" #2: initiating Quick Mode POLICY_RSASIG+POLICY_ENCRYPT+POLICY_AUTHENTICATE+POLICY_TUNNEL+POLICY_PFS Feb 21 14:45:46 deep Pluto[432]: "deep-mail" #2: sent QI2, IPsec SA established Feb 21 14:45:47 deep Pluto[432]: "deep-mail" #3: responding to Main Mode Feb 21 14:45:49 deep Pluto[432]: "deep-mail" #3: sent MR3, ISAKMP SA established Feb 21 14:45:49 deep Pluto[432]: "deep-mail" #4: responding to Quick Mode Feb 21 14:45:50 deep Pluto[432]: "deep-mail" #4: IPsec SA established On both gateways, the following entries should now exist in the /proc/net/ directory: [root@deep] /# ls -l /proc/net/ipsec_* -r--r--r-- 1 root root 0 Feb 2 05:30 /proc/net/ipsec_eroute -r--r--r-- 1 root root 0 Feb 2 05:30 /proc/net/ ipsec_klipsdebug -r--r--r-- 1 root root 0 Feb 2 05:30 /proc/net/ipsec_spi -r--r--r-- 1 root root 0 Feb 2 05:30 /proc/net/ipsec_spigrp -r--r--r-- 1 root root 0 Feb 2 05:30 /proc/net/ipsec_spinew -r--r--r-- 1 root root 0 Feb 2 05:30 /proc/net/ipsec_tncfg -r--r--r-- 1 root root 0 Feb 2 05:30 /proc/net/ ipsec_version The IPSEC interfaces should be attached on top of the specified physical interfaces. Confirm that with: [root@deep] /# cat /proc/net/ipsec_tncfg ipsec0 -> eth0 mtu=16260 -> 1500 ipsec1 -> NULL mtu=0 -> 0 ipsec2 -> NULL mtu=0 -> 0 ipsec3 -> NULL mtu=0 -> 0 Now execute the following command to show minimal debugging information and see if the output looks something like this: [root@deep] /# ipsec look deep.openna.com Fri Feb 4 17:25:17 EST 2000 ============-============ 192.168.1.1/32 -> 192.168.1.2/32 => tun0x106@192.168.1.2 esp0x4450894d@192.168.1.2 ah0x4450894c@192.168.1.2 ------------=------------ ah0x3350f551@192.168.1.1 AH_HMAC_MD5: dir=in ooowin=32 seq=115 bit=0xffffffff alen=128 aklen=16 life(c,s,h)=bytes(16140,0,0)add(51656,0,0)use (54068,0,0)packets(115,0,0) idle=499 ah0x4450894c@192.168.1.2 AH_HMAC_MD5: dir=out ooowin=32 seq=2828 alen=128 aklen=16 life(c,s,h)=bytes(449488,0,0)add(51656,0,0)use(51656,0,0)packets (2828,0,0) idle=6 esp0x3350f552@192.168.1.1 ESP_3DES: dir=in ooowin=32 seq=115 bit=0xffffffff eklen=24 life(c,s,h)=bytes(13380,0,0)add(51656,0,0)use(54068,0,0)packets (115,0,0) idle=499 esp0x4450894d@192.168.1.2 ESP_3DES: dir=out ooowin=32 seq=2828 eklen=24 life (c,s,h)=bytes(381616,0,0)add(51656,0,0)use(51656,0,0)packets(2828,0,0) idle=6 tun0x105@192.168.1.1 IPIP: dir=in 192.168.1.2 -> 192.168.1.1 life(c,s,h)=add (51656,0,0) tun0x106@192.168.1.2 IPIP: dir=out 192.168.1.1 -> 192.168.1.2 life (c,s,h)=bytes(327581,0,0)add(51656,0,0)use(51656,0,0)packets(2828,0,0) idle=6 192.168.1.0 0.0.0.0 255.255.255.0 U 0 0 0 eth0 192.168.1.0 0.0.0.0 255.255.255.0 U 0 0 0 ipsec0 192.168.1.1 0.0.0.0 255.255.255.255 UH 0 0 0 eth0 192.168.1.2 192.168.1.2 255.255.255.255 UGH 0 0 0 ipsec0 Destination Gateway Genmask Flags MSS Window irtt Iface Try pinging 192.168.1.2 from the 192.168.1.1 client. If this works then you have set it up correctly. If it does not work check your network to make sure 208.164.186.1 can reach 208.164.186.2, and that TCP-IP forwarding is enabled, and make sure that no firewall rules are blocking the packets, or trying to masquerade them before the rules allowing IPSec related traffic. For this test to work, it is important to use pings that go from one subnet to the other. 208.164.186.1 ---- 205.151.222.250 ---- 205.151.222.251 ---- 208.164.186.2 | | 192.168.1.0/24 192.168.1.0/24 | | 192.168.1.1 192.168.1.2 A last note about testing the installation of FreeSWAN IPSEC, if you encounter a problem that you are unable to resolve, you can use the following command to view a collection of debugging information, contents of files, selections from logs, etc. Anything related to the IPSEC encryption/authentication system that you should send to the Linux-IPSEC Mailing List to help you. Use the following command to make an output of a collection of debugging information: [root@deep] /# ipsec barf > result This command is primarily provided as a convenience for remote debugging; A single command which packages up -and labels all information that might be relevant to diagnosing a problem in IPSEC. 11. Further documentation For more details, there are several man pages you can read: ipsec(8) - invoke IPSEC utilities ipsec atoasr(3) - convert ASCII to Internet address, subnet, or range ipsec atobytes, bytestoa(3) - convert binary data bytes from and to ASCII formats ipsec atodata, datatoa (3) - convert binary data from and to ASCII formats ipsec atosa, satoa (3) - convert IPSEC Security Association IDs to and from ASCII ipsec atosubnet, subnettoa (3) - convert subnet/mask ASCII form to and from addresses ipsec atoul, ultoa (3) - convert unsigned-long numbers to and from ASCII ipsec auto (8) - control automatically-keyed IPSEC connections ipsec barf (8) - spew out collected IPSEC debugging information ipsec bitstomask (3) - convert bit count to Internet subnet mask ipsec eroute (8) - manipulate IPSEC extended routing tables ipsec goodmask (3) - is this Internet subnet mask a valid one? ipsec hostof (3) - given Internet address and subnet mask, return host part ipsec klipsdebug (8) - set Klips -kernel IPSEC support, debug features and level ipsec look (8) - show minimal debugging information ipsec manual (8) - take manually-keyed IPSEC connections up and down ipsec masktobits (3) - convert Internet subnet mask to bit count ipsec optionsfrom (3) - read additional command-line options from file ipsec pluto (8) - IPsec IKE keying daemon ipsec ranbits (8) - generate random bits in ASCII form ipsec rangetoa (3) - convert Internet address range to ASCII ipsec rsasigkey (8) - generate RSA signature key ipsec setup (8) - control IPSEC subsystem ipsec spi (8) - manage IPSEC Security Associations ipsec spigrp (8) - group/ungroup IPSEC Security Associations ipsec subnetof (3) - given Internet address and subnet mask, return subnet number ipsec tncfg (8) - associate IPSEC virtual interface with real interface ipsec whack (8) - control interface for IPSEC keying daemon ipsec.conf (5) - IPSEC configuration and connections ipsec.secrets (5) - secrets for IKE/IPsec authentication ipsec (8) - invoke IPSEC utilities ipsec atoaddr, addrtoa (3) - convert Internet addresses to and from ASCII ipsec atoasr (3) - convert ASCII to Internet address, subnet, or range ipsec atobytes, bytestoa (3) - convert binary data bytes from and to ASCII formats ipsec atodata, datatoa (3) - convert binary data from and to ASCII formats ipsec atosa, satoa (3) - convert IPSEC Security Association IDs to and from ASCII ipsec atosubnet, subnettoa (3) - convert subnet/mask ASCII form to and from addresses ipsec atoul, ultoa (3) - convert unsigned-long numbers to and from ASCII ipsec auto (8) - control automatically-keyed IPSEC connections ipsec barf (8) - spew out collected IPSEC debugging information ipsec bitstomask (3) - convert bit count to Internet subnet mask ipsec eroute (8) - manipulate IPSEC extended routing tables ipsec goodmask (3) - is this Internet subnet mask a valid one? ipsec hostof (3) - given Internet address and subnet mask, return host part ipsec klipsdebug (8) - set Klips (kernel IPSEC support) debug features and level ipsec look (8) - show minimal debugging information ipsec manual (8) - take manually-keyed IPSEC connections up and down ipsec masktobits (3) - convert Internet subnet mask to bit count ipsec optionsfrom (3) - read additional command-line options from file ipsec pluto (8) - IPsec IKE keying daemon ipsec ranbits (8) - generate random bits in ASCII form ipsec rangetoa (3) - convert Internet address range to ASCII ipsec rsasigkey (8) - generate RSA signature key ipsec setup (8) - control IPSEC subsystem ipsec spi (8) - manage IPSEC Security Associations ipsec spigrp (8) - group/ungroup IPSEC Security Associations ipsec subnetof (3) - given Internet address and subnet mask, return subnet number ipsec tncfg (8) - associate IPSEC virtual interface with real interface ipsec whack (8) - control interface for IPSEC keying daemon ipsec.conf (5) - IPSEC configuration and connections ipsec.secrets (5) - secrets for IKE/IPsec authentication 12. Installed files These are the files installed on your system by the software program FreeS/WAN /etc/rc.d/init.d/ipsec /etc/rc.d/rc0.d/K68ipsec /etc/rc.d/rc1.d/K68ipsec /etc/rc.d/rc2.d/S47ipsec /etc/rc.d/rc3.d/S47ipsec /etc/rc.d/rc4.d/S47ipsec /etc/rc.d/rc5.d/S47ipsec /etc/rc.d/rc6.d/K68ipsec /etc/ipsec.conf /etc/ipsec.secrets /usr/lib/ipsec /usr/lib/ipsec/spi /usr/lib/ipsec/eroute /usr/lib/ipsec/spigrp /usr/lib/ipsec/tncfg /usr/lib/ipsec/klipsdebug /usr/lib/ipsec/pluto /usr/lib/ipsec/whack /usr/lib/ipsec/ipsec /usr/lib/ipsec/barf /usr/lib/ipsec/manual /usr/lib/ipsec/auto /usr/lib/ipsec/look /usr/lib/ipsec/ showdefaults /usr/lib/ipsec/_include /usr/lib/ipsec/_confread /usr/lib/ipsec/_keycensor /usr/lib/ipsec/ /usr/lib/ipsec/_updown /usr/lib/ipsec/ranbits _secretcensor /usr/lib/ipsec/rsasigkey /usr/lib/ipsec/setup /usr/man/man3/ ipsec_atoaddr.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man3/ ipsec_addrtoa.3 ipsec_atosubnet.3 ipsec_subnettoa.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man3/ ipsec_atoasr.3 ipsec_rangetoa.3 ipsec_atodata.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man3/ ipsec_atobytes.3 ipsec_bytestoa.3 ipsec_datatoa.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man3/ ipsec_atosa.3 ipsec_satoa.3 ipsec_atoul.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man3/ ipsec_ultoa.3 ipsec_goodmask.3 ipsec_masktobits.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man3/ ipsec_bitstomask.3 ipsec_optionsfrom.3 ipsec_subnetof.3 /usr/man/man3/ /usr/man/man3/ /usr/man/man5/ ipsec_hostof.3 ipsec_broadcastof.3 ipsec.secrets.5 /usr/man/man5/ipsec.conf.5 /usr/man/man8/ipsec_spi.8 /usr/man/man8/ipsec.8 /usr/man/man8/ /usr/man/man8/ /usr/man/man8/ ipsec_eroute.8 ipsec_spigrp.8 ipsec_tncfg.8 /usr/man/man8/ /usr/man/man8/ /usr/man/man8/ ipsec_klipsdebug.8 ipsec_pluto.8 ipsec_whack.8 /usr/man/man8/ipsec_barf.8 /usr/man/man8/ipsec_look.8 /usr/man/man8/ ipsec_manual.8 /usr/man/man8/ipsec_auto.8 /usr/man/man8/ /usr/man/man8/ ipsec_setup.8 ipsec_ranbits.8 /usr/man/man8/ /usr/sbin/ipsec   ipsec_rsasigkey.8 Chapter 26. Linux OpenLDAP Server Table of Contents 1._Compile_ans_Install 2._Compile_and_Optimize 3._Configurations 4._Configure_the_/etc/ldap/slapd.conf_file 5._Configure_the_/etc/rc.d/init.d/ldap_script_file 6._Securing_OpenLDAP 7._OpenLDAP_Creation_and_Maintenance_Tools 7.1._LDMB_backend_database_off-line 8._Create_the_LDMB_backend_database_on-line 8.1._ldapmodify 9._OpenLDAP_Users_Tools 9.1._The_Netscape_Address_Book_client_for_LDAP 10._Installed_files Until now, we have been talking about security and optimization in this book, so why would we talk about OpenLDAP? Well, the OpenLDAP directory server will expand our horizons through its many possibilities. We can use its replication capability to centralize and consolidate different information on one server for all the others in our network. Imagine having the possibility of adding or disabling a Unix or NT account, setting access to a restricted Web server, and adding a mail address or alias, all with a single operation available as an NIS service, with the added security of SSL encryption, and the speed of object- oriented hierarchies. Another interesting use is to create an authoritative list of employees on one or more LDAP servers that can be accessible from your private network, or over the Internet. 1. Compile ans Install As per in the [OpenLDAP web site]: LDAP -Lightweight Directory Access Protocol is an open-standard protocol for accessing information services. The protocol runs over Internet transport protocols, such as TCP, and can be used to access stand-alone directory servers or X.500 directories. LDAP These installation instructions assume * Commands are Unix-compatible. * The source path is /var/tmp, other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * OpenLDAP version number is 1.2.10 The Package(s) required are and available at: OpenLDAP Homepage:http://www.openldap.org/ OpenLDAP FTP Site: 204.152.186.57 You must be sure to download: openldap-1.2.10.tgz Before you decompress tarballs, it is a good idea to make a list of files on the system before you install OpenLDAP, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > OpenLDAP1 before and find /* > OpenLDAP2 after you install the software, and use diff OpenLDAP1 OpenLDAP2 > OpenLDAP-Installed to get a list of what changed. Compile and decompress the tarball, tar.gz. [root@deep] /# cp openldap-version.tgz /var/tmp [root@deep] /# cd /var/tmp/ [root@deep ]/tmp# tar xzpf openldap-version.tgz 2. Compile and Optimize Move into the new OpenLDAP directory and type the following commands on your terminal: It is important to note that you can configure three different kinds of backend databases with LDAP. i. A high-performance, disk-based database called LDBM ii. A database interface to arbitrary UNIX commands or shell scripts calledd SHELL iii. A simple password file database named PASSWD * The default installation of OpenLDAP assumes an LDBM backend database, so if you want to configure another type of backend database, you must specify it during the configuration and compile time. For a SHELL backend database you must add the --enable-shell option and for a PASSWD backend database used as replacement for NIS service you must add the --enable-passwd option in your configuration lines. CC="egcs" \ CFLAGS="-O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions - D_REENTRANT" \ ./configure \ --prefix=/usr \ --libexecdir=/usr/sbin \ --localstatedir=/var/run \ --sysconfdir=/etc \ --enable-dns \ --enable-shared \ --with-gnu-ld \ --disable-debug This tells OpenLDAP to set itself up for this particular hardware setup as follows: o Enable dns support. o Build shared libraries. o Assume the C compiler uses GNU ld. Important The compile options above assume that you want to set up an LDBM backend database. For the other type of backend database, you must add the required option in your configuration lines above. Now, we must compile and install OpenLDAP in the server: [root@deep openldap-1.2.10]# make depend [root@deep openldap-1.2.10]# make [root@deep openldap-1.2.10]# cd tests/ [root@deep tests]# make [root@deep tests]# cd .. [root@deep openldap-1.2.10]# make install * The make depend command will build and make the necessary dependencies for different files, * make compiles all source files into executable binaries, * make install installs the binaries and any supporting files into the appropriate locations. The make command under /test subdirectory will do some important tests to verify the functionality of your LDAP server before the installation. If some tests fails, you'll need to fixes the problems before continuing the installation. [root@deep openldap-1.2.10]# install -d -m 700 /var/ldap [root@deep openldap-1.2.10]# echo localhost > /etc/openldap/ ldapserver [root@deep openldap-1.2.10]# strip /usr/lib/liblber.so.1.0.0 [root@deep openldap-1.2.10]# strip /usr/lib/libldap.so.1.0.0 [root@deep openldap-1.2.10]# strip /usr/lib/libldap.a [root@deep openldap-1.2.10]# strip /usr/lib/liblber.a [root@deep openldap-1.2.10]# strip /usr/sbin/in.xfingerd [root@deep openldap-1.2.10]# strip /usr/sbin/go500 [root@deep openldap-1.2.10]# strip /usr/sbin/go500gw [root@deep openldap-1.2.10]# strip /usr/sbin/mail500 [root@deep openldap-1.2.10]# strip /usr/sbin/rp500 [root@deep openldap-1.2.10]# strip /usr/sbin/rcpt500 [root@deep openldap-1.2.10]# strip /usr/sbin/fax500 [root@deep openldap-1.2.10]# strip /usr/sbin/slapd [root@deep openldap-1.2.10]# strip /usr/sbin/slurpd [root@deep openldap-1.2.10]# strip /usr/sbin/ldif [root@deep openldap-1.2.10]# strip /usr/sbin/ldif2ldbm [root@deep openldap-1.2.10]# strip /usr/sbin/ldif2index [root@deep openldap-1.2.10]# strip /usr/sbin/ldif2id2entry [root@deep openldap-1.2.10]# strip /usr/sbin/ldif2id2children [root@deep openldap-1.2.10]# strip /usr/sbin/ldbmcat [root@deep openldap-1.2.10]# strip /usr/sbin/ldbmtest [root@deep openldap-1.2.10]# strip /usr/sbin/centipede [root@deep openldap-1.2.10]# strip /usr/bin/ud [root@deep openldap-1.2.10]# strip /usr/bin/ldapadd [root@deep openldap-1.2.10]# strip /usr/bin/ldapsearch [root@deep openldap-1.2.10]# strip /usr/bin/ldapmodify [root@deep openldap-1.2.10]# strip /usr/bin/ldapmodrdn [root@deep openldap-1.2.10]# strip /usr/bin/ldappasswd [root@deep openldap-1.2.10]# strip /usr/bin/ldapdelete * The install command above will create a new directory named ldap under /var directory and will set its mode to be readable, writable, and executable only by the super-user root, 700 for security reasons. * The strip command will discard all symbols from the object files. This means that our binary files will be smaller in size. This will improve the performance hit to the program since there will be fewer lines to be read by the system when it executes the binary. Please don't forget to cleanup later: [root@deep] /# cd /var/tmp [root@deep ]/tmp# rm -rf openldap-version/ openldap- version.tgz The rm command will remove all the source files we have used to compile and install OpenLDAP. It will also remove the OpenLDAP compressed archive from the /var/tmp directory. 3. Configurations Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example OpenLDAP configuration file are organised like this: total 16 -rw-r--r-- 1 harrypotter harrypotter 321 Jun 8 13:00 Compile-OpenLDAP drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 init.d/ -rwx------ 1 harrypotter harrypotter 893 Jun 8 13:00 ldap.sh* -rw------- 1 harrypotter harrypotter 922 Jun 8 13:00 slapd.conf You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run OpenLDAP server, the following files are required and must be created or copied to the appropriate directories on your server. i. Copy the slapd.conf file in the /etc/openldap/ directory. ii. Copy the ldap script file in the /etc/rc.d/init.d/ directory. Tip You can obtain the configuration files listed in the next few sections on our floppy.tgz archive. Copy the following files from the decompressed floppy.tgz archive to the appropriate places or copy and paste them directly from this book to the concerned file. 4. Configure the /etc/ldap/slapd.conf file The /etc/openldap/slapd.conf file is the main configuration file for the stand- alone LDAP daemon. Options like: permission, password, database type, database location and so on can be configured in this file and will apply to the slapd daemon as a whole. In the example below we configure the slapd.conf file for an LDBM backend database. Edit the slapd.conf file, vi /etc/openldap/slapd.conf and add/adjust the following information: # # See slapd.conf(5) for details on configuration options. # This file should NOT be world readable. # include /etc/openldap/slapd.at.conf include /etc/openldap/slapd.oc.conf schemacheck off #referral ldap://ldap.itd.umich.edu pidfile /var/run/slapd.pid argsfile /var/run/slapd.args ####################################################################### # ldbm database definitions ####################################################################### database ldbm suffix "o=openna, c=com" directory /var/ldap rootdn "cn=admin, o=openna, c=com" rootpw secret # cleartext passwords, especially for the rootdn, should # be avoid. See slapd.conf(5) for details. # ldbm indexed attribute definitions index cn,sn,uid index objectclass pres,eq index default none # ldbm access control definitions defaultaccess read access to attr=userpassword by self write by dn="cn=admin, o=openna, c=com" write by * compare You should be sure to set the following options in your slapd.conf file above before starting the slapd daemon program: suffix o=openna, c=com This option specifies the DN of the root of the sub tree you are trying to create. In other words, it indicates what entries are to be held by this database. directory /var/ldap This option specifies the directory where the database and associated indexes files of LDAP should reside. We must set this to /var/ldap because we created this directory earlier in the installation stage specifically to handle the backend database of LDAP. rootdn cn=admin, o=openna, c=com This option specifies the DN of an entry allowed to do anything on the LDAP directory. The name entered here can be one that doesn't actually exist in your password file /etc/passwd. rootpw secret This option specifies the password that can be used to authenticate the super-user entry of the database. This is the password for the rootdn option above. Its important to not use clear text passwords here and to use a crypto password instead. index cn,sn,uid | index objectclass pres,eq | index default none These options specify the index definitions you want to build and maintain in the database definition. The options we specifies in our slapd.conf file example above, cause all indexes to be maintained for the cn, sn, and uid attributes; -index cn,sn,uid, presence and an equality indexes for the objectclass attribute -index objectclass pres,eq, and no indexes for all remaining attributes -index default none. See your user manual for more information. The last options in the file slapd.conf relate to access control in LDAP directory. defaultaccess read access to attr=userpassword by self write by dn="cn=admin, o=openna, c=com" write by * compare This example applies to entries in the o=openna, c=com sub tree. Read access is granted to everyone, and the entry itself can write all attributes, except for userpassword. The userpassword attribute is writable only by the specified cn entry; admin, and comparable by everybody else. See your user manual for more information. 5. Configure the /etc/rc.d/init.d/ldap script file Configure your /etc/rc.d/init.d/ldap script file to start and stop LDAP Server. Create the ldap script file, touch /etc/rc.d/init.d/ldap and add: #!/bin/sh # # ldap This shell script takes care of starting and stopping # ldap servers (slapd and slurpd). # # chkconfig: - 70 40 # description: LDAP stands for Lightweight Directory Access Protocol, used \ # for implementing the industry standard directory services. # processname: slapd # config: /etc/openldap/slapd.conf # pidfile: /var/run/slapd.pid # Source function library. . /etc/rc.d/init.d/functions # Source networking configuration. . /etc/sysconfig/network # Check that networking is up. [ ${NETWORKING} = "no" ] && exit 0 [ -f /usr/sbin/slapd ] || exit 0 [ -f /usr/sbin/slurpd ] || exit 0 RETVAL=0 # See how we were called. case "$1" in start) # Start daemons. echo -n "Starting ldap: " daemon slapd RETVAL=$? if [ $RETVAL -eq 0 ]; then if grep -q "^replogfile" /etc/openldap/slapd.conf; then daemon slurpd RETVAL=$? [ $RETVAL -eq 0 ] && pidof slurpd | cut -f 1 -d " " > /var/run/slurpd fi fi echo [ $RETVAL -eq 0 ] && touch /var/lock/subsys/ldap ;; stop) # Stop daemons. echo -n "Shutting down ldap: " killproc slapd RETVAL=$? if [ $RETVAL -eq 0 ]; then if grep -q "^replogfile" /etc/openldap/slapd.conf; then killproc slurpd RETVAL=$? fi fi echo if [ $RETVAL -eq 0 ]; then rm -f /var/lock/subsys/ldap rm -f /var/run/slapd.args fi ;; status) status slapd RETVAL=$? if [ $RETVAL -eq 0 ]; then if grep -q "^replogfile" /etc/openldap/slapd.conf; then status slurpd RETVAL=$? fi fi ;; restart) $0 stop $0 start RETVAL=$? ;; reload) killproc -HUP slapd RETVAL=$? if [ $RETVAL -eq 0 ]; then if grep -q "^replogfile" /etc/openldap/slapd.conf; then killproc -HUP slurpd RETVAL=$? fi fi ;; *) echo "Usage: $0 start|stop|restart|status}" exit 1 esac exit $RETVAL Now, make this script executable and change its default permissions: [root@deep] /# chmod 700 /etc/rc.d/init.d/ldap Create the symbolic rc.d links for OpenLDAP with the command: [root@deep] /# chkconfig --add ldap The OpenLDAP script will not automatically start the slapd daemon when you reboot the server. You can change its defaults by executing the following command: [root@deep] /# chkconfig --level 345 ldap on Start your OpenLDAP Server manually with the following command: [root@deep] /# /etc/rc.d/init.d/ldap start Starting ldap: [ OK ] 6. Securing OpenLDAP Don't forget to immunize important configuration files. The immutable bit can be used to prevent one from accidentally deleting or overwriting a file that must be protected. It also prevents someone from creating a symbolic link to this file. Once your slapd.conf file has been configured, it's a good idea to immunize it with command like: [root@deep] /# chattr +i /etc/openldap/slapd.conf Further documentation, for more details there are several man pages you can read: ldapd(8) LDAP X.500 Protocol Daemon ldapdelete(1) ldap delete entry tool ldapfilter.conf(5) configuration file for LDAP get filter routines ldapfriendly(5) data file for LDAP friendly routines ldapmodify, ldapadd(1) ldap modify entry and ldap add entry tools ldapmodrdn(1) ldap modify entry RDN tool ldappasswd(1) change the password of an LDAP entry ldapsearch(1) ldap search tool ldapsearchprefs.conf(5) configuration file for LDAP search preference routines ldaptemplates.conf(5) configuration file for LDAP display template routines ldif(5) LDAP Data Interchange Format slapd(8) Stand-alone LDAP Daemon slapd.conf(5) configuration file for slapd, the stand-alone LDAP daemon slurpd(8) Standalone LDAP Update Replication Daemon ud(1) interactive LDAP Directory Server query program 7. OpenLDAP Creation and Maintenance Tools To Create of the LDMB backend database, there are two methods to create a database for LDAP, 1. The first is off-line with the ldif2ldbm command utility 2. The other is on-line with the ldapadd command utility. Usually you use the off-line method when you have many thousands of entries to insert into your database and the on-line method when you have only a small number of entries to put into your database. It is also important to note that * The off-line method requires that your slapd daemon is not running * The on-line method requires that your slapd daemon of LDAP is running. 7.1. LDMB backend database off-line The first thing to do is to create an LDIF input file containing a text representation of your entries. The text file named my-data-file below can be used as an example file. Of course, your real LDIF input file will handle much more information than this example. When you install OpenLDAP for the first time and have big entries to put in your backend database, it's always a good idea to put all this information into a text file and add them into your backend database with the ldif2ldbm command utility. Example 26.1. my-data-file Create the file, touch /tmp/my-data-file and add as an example in this file the following lines: 1. dn: o=openna, c=com o: openna objectclass: organization dn: cn=Gerhard Mourani, o=openna, c=com cn: Gerhard Mourani sn: Mourani mail: gmourani@videotron.ca title: Author objectclass: person dn: cn=Anthony Bay, o=openna, c=com cn: Anthony Bay sn: Bay homephone: (444) 111-2233 mobile: (444) 555-6677 mail: abay@openna.com objectclass: person dn: cn=George Parker, o=openna, c=com cn: George Parker sn: Parker telephonenumber: (555) 234-5678 fax: (543) 987-6543 mobile: (543) 321-4354 description: E-Commerce objectclass: person The above example shows you how to convert your information into LDIF files before adding them to your new backend directory. Consult your OpenLDAP documentation or book for more information. 2. Once the LDIF input file containing our entries has been created, we must insert it in the LDAP directory server. To insert the LDIF input file and create the database off-line, use the following command: [root@deep ]/tmp# ldif2ldbm -i - f [root@deep ]/tmp# ldif2ldbm -i my-data-file - f /etc/openldap/slapd.conf The -i option with the option specifies the location of the LDIF input file containing the entries in text form to add. The option specifies the location of the slapd configuration file, which specifies where to create the indexes, what indexes to create, etc. Important It is important to note that the slapd daemon of LDAP is not started in this mode of creation. 8. Create the LDMB backend database on-line If the entries in your directory server are already created or if you have only a small amount of information to insert into your backend database, you'll prefer to use the ldapadd command utility to do your job on-line. For example, to add the Europe Mourani entry using the ldapadd tool, you could create a file called newentry in your /tmp directory. Example 26.2. LDMB backend Create the newentry file, touch /tmp/newentry and add in this file the following contents: 1. cn=Europe Mourani, o=openna, c=com cn=Europe Mourani sn=Mourani mail=emourani@old.com description=Marketing relation objectClass=person 2. Once the file newentry has been created, we must add the entry into the LDAP directory server. To actually create the entry on-line in the backend database, use the following command: [root@deep] /# ldapadd -f /tmp/newentry - D "cn=admin, o=openna, c=com" -W Enter LDAP Password : The above command assumes that you have set rootdn to cn=admin, o=openna, c=com and rootpw to secret. You will be prompted to enter the password. Important It is important to note that the slapd daemon of LDAP is started in this mode of creation. 8.1. ldapmodify Contrary to relational databases where data is constantly changed, the directory server contains information that is rarely modified once inserted. But, some times you need to modify information, and the ldapmodify tool will help you in your tasks. The ldapmodify command allows you to add or modify entries on the backend directory server. Example 26.3. modifyentry Assuming that we want to replace the contents of the Europe Mourani entry's mail attribute with the new value emourani@new.com, the following steps will be require: 1. Create the modifyentry file, touch /tmp/modifyentry and add in this file the contents: cn=Europe Mourani, o=openna, c=com - mail=emourani@old.com # will delete the old mail address for Europe Mourani in the database. +mail=emourani@new.com # will add the new mail address for Europe Mourani in the database. 2. Once the modifyentry file has been created, we must replace the entry in the LDAP directory server with the one contained in this file - modifyentry. To modify the contents of backend database, use the following command: [root@deep] /# ladpmodify -D cn=Admin, o=openna, c=com -W -f [root@deep] /# ladpmodify -D cn=Admin, o=openna, c=com -W -f modifyentry Where is the name of the file modifyentry we created in step 1 above. 9. OpenLDAP Users Tools To Search on LDAP directory server for entries, the ldapsearch utility searches through the backend database of LDAP directory for information you have requested. You can use the following command: [root@deep] /# ldapsearch -b dn attrs [root@deep] /# ldapsearch -b o=openna, c=com cn=europe* cn=Europe Mourani, o=openna, c=com cn=Europe Mourani sn=Mourani mail=emourani@old.com description=Marketing relation objectClass=person This command will retrieve all entries and values for the name europe and will print the result to standard output in your terminal. Some possible uses of OpenLDAP software, for instance OpenLDAP can be used as: i. Web Catalogue Server. ii. White Pages Server. iii. Certificate Server. iv. An Access Control Server. v. Network Name Server. 9.1. The Netscape Address Book client for LDAP If you have Netscape installed on a Linux workstation, or even another kind of operating system, you can use its Address Book features to access the LDAP Directory Server you have just installed on Linux and query your directory server for information like you do with the ldapsearch command tool on Linux. If you are interested in doing that, follow the simple steps below: 1. Open Netscape Communicator 2. Go to Communicator menu 3. Open the Address Book 4. Go to File menu 5. Click on New Directory 6. Fill the boxes with your server information Example 26.4. Address Book Description: Open Network Architecture LDAP Server: 208.164.186.3 Server Root: o=openna, c=com Now all you have to do is to make some queries to your LDAP Directory Server on Linux, by using the box named Show names Containing: to start your search, and clicking on the button Search For: to get the results. Address Book The Netscape Address Book Client Program. 10. Installed files These are the files installed by the program OpenLDAP on your sytem. /etc/openldap /etc/openldap/ldap.conf /etc/openldap/ldap.conf.default /etc/openldap/ldapfilter.conf /etc/openldap/ldapfilter.conf.default /etc/openldap/ldaptemplates.conf /etc/openldap/ /etc/openldap/ldapsearchprefs.conf ldaptemplates.conf.default /etc/openldap/ /etc/openldap/slapd.conf ldapsearchprefs.conf.default /etc/openldap/slapd.conf.default /etc/openldap/slapd.at.conf /etc/openldap/slapd.at.conf.default /etc/openldap/slapd.oc.conf /etc/openldap/slapd.oc.conf.default /etc/openldap/ldapserver /etc/rc.d/init.d/ldap /etc/rc.d/rc0.d/K40ldap /etc/rc.d/rc1.d/K40ldap /etc/rc.d/rc2.d/K40ldap /etc/rc.d/rc3.d/S70ldap /etc/rc.d/rc4.d/S70ldap /etc/rc.d/rc5.d/S70ldap /etc/rc.d/rc6.d/K40ldap /usr/bin/ud /usr/bin/ldapsearch /usr/bin/ldapmodify /usr/bin/ldapdelete /usr/bin/ldapmodrdn /usr/bin/ldappasswd /usr/bin/ldapadd /usr/include/ldap.h /usr/include/lber.h /usr/include/ldap_cdefs.h /usr/include/disptmpl.h /usr/include/srchpref.h /usr/lib/liblber.so.1.0.0 /usr/lib/liblber.so.1 /usr/lib/liblber.so /usr/lib/liblber.la /usr/lib/liblber.a /usr/lib/libldap.so.1.0.0 /usr/lib/libldap.so.1 /usr/lib/libldap.so /usr/lib/libldap.la /usr/lib/libldap.a /usr/man/man1/ud.1 /usr/man/man1/ldapdelete.1 /usr/man/man1/ldapmodify.1 /usr/man/man1/ldapadd.1 /usr/man/man1/ldapmodrdn.1 /usr/man/man1/ldappasswd.1 /usr/man/man1/ldapsearch.1 /usr/man/man3/cldap_close.3 /usr/man/man3/cldap_open.3 /usr/man/man3/cldap_search_s.3 /usr/man/man3/cldap_setretryinfo.3 /usr/man/man3/lber-decode.3 /usr/man/man3/lber-encode.3 /usr/man/man3/ldap.3 /usr/man/man3/cldap.3 /usr/man/man3/ldap_abandon.3 /usr/man/man3/ldap_add.3 /usr/man/man3/ldap_add_s.3 /usr/man/man3/ldap_bind.3 /usr/man/man3/ldap_bind_s.3 /usr/man/man3/ldap_simple_bind.3 /usr/man/man3/ldap_simple_bind_s.3 /usr/man/man3/ldap_kerberos_bind_s.3 /usr/man/man3/ldap_kerberos_bind1.3 /usr/man/man3/ldap_kerberos_bind1_s.3 /usr/man/man3/ldap_kerberos_bind2.3 /usr/man/man3/ldap_kerberos_bind2_s.3 /usr/man/man3/ldap_unbind.3 /usr/man/man3/ldap_unbind_s.3 /usr/man/man3/ldap_set_rebind_proc.3 /usr/man/man3/ldap_cache.3 /usr/man/man3/ldap_enable_cache.3 /usr/man/man3/ldap_disable_cache.3 /usr/man/man3/ldap_destroy_cache.3 /usr/man/man3/ldap_flush_cache.3 /usr/man/man3/ldap_uncache_entry.3 /usr/man/man3/ldap_uncache_request.3 /usr/man/man3/ldap_set_cache_options.3 /usr/man/man3/ldap_charset.3 /usr/man/man3/ ldap_set_string_translators.3 /usr/man/man3/ldap_enable_translation.3 /usr/man/man3/ldap_translate_from_t61.3 /usr/man/man3/ldap_translate_to_t61.3 /usr/man/man3/ldap_t61_to_8859.3 /usr/man/man3/ldap_8859_to_t61.3 /usr/man/man3/ldap_compare.3 /usr/man/man3/ldap_compare_s.3 /usr/man/man3/ldap_delete.3 /usr/man/man3/ldap_delete_s.3 /usr/man/man3/ldap_disptmpl.3 /usr/man/man3/ldap_init_templates.3 /usr/man/man3/ldap_init_templates_buf.3 /usr/man/man3/ldap_free_templates.3 /usr/man/man3/ldap_first_disptmpl.3 /usr/man/man3/ldap_next_disptmpl.3 /usr/man/man3/ldap_oc2template.3 /usr/man/man3/ldap_tmplattrs.3 /usr/man/man3/ldap_first_tmplrow.3 /usr/man/man3/ldap_next_tmplrow.3 /usr/man/man3/ldap_first_tmplcol.3 /usr/man/man3/ldap_next_tmplcol.3 /usr/man/man3/ldap_entry2text.3 /usr/man/man3/ldap_entry2text_search.3 /usr/man/man3/ldap_vals2text.3 /usr/man/man3/ldap_entry2html.3 /usr/man/man3/ldap_entry2html_search.3 /usr/man/man3/ldap_vals2html.3 /usr/man/man3/ldap_error.3 /usr/man/man3/ldap_perror.3 /usr/man/man3/ld_errno.3 /usr/man/man3/ldap_result2error.3 /usr/man/man3/ldap_open.3 /usr/man/man3/ldap_errlist.3 /usr/man/man3/ldap_err2string.3 /usr/man/man3/ldap_first_attribute.3 /usr/man/man3/ldap_next_attribute.3 /usr/man/man3/ldap_first_entry.3 /usr/man/man3/ldap_next_entry.3 /usr/man/man3/ldap_count_entries.3 /usr/man/man3/ldap_friendly.3 /usr/man/man3/ldap_friendly_name.3 /usr/man/man3/ldap_free_friendlymap.3 /usr/man/man3/ldap_get_dn.3 /usr/man/man3/ldap_explode_dn.3 /usr/man/man3/ldap_explode_dns.3 /usr/man/man3/ldap_dn2ufn.3 /usr/man/man3/ldap_is_dns_dn.3 /usr/man/man3/ldap_get_values.3 /usr/man/man3/ldap_get_values_len.3 /usr/man/man3/ldap_value_free.3 /usr/man/man3/ldap_value_free_len.3 /usr/man/man3/ldap_count_values.3 /usr/man/man3/ldap_count_values_len.3 /usr/man/man3/ldap_getfilter.3 /usr/man/man3/ldap_init_getfilter.3 /usr/man/man3/ldap_init_getfilter_buf.3 /usr/man/man3/ldap_getfilter_free.3 /usr/man/man3/ldap_getfirstfilter.3 /usr/man/man3/ldap_getnextfilter.3 /usr/man/man3/ldap_setfilteraffixes.3 /usr/man/man3/ldap_build_filter.3 /usr/man/man3/ldap_modify.3 /usr/man/man3/ldap_modify_s.3 usr/man/man3/ldap_mods_free.3 /usr/man/man3/ldap_modrdn.3 /usr/man/man3/ldap_modrdn_s.3 /usr/man/man3/ldap_modrdn2.3 /usr/man/man3/ldap_modrdn2_s.3 /usr/man/man3/ldap_init.3 /usr/man/man3/ldap_result.3 /usr/man/man3/ldap_msgfree.3 /usr/man/man3/ldap_search.3 /usr/man/man3/ldap_search_s.3 /usr/man/man3/ldap_search_st.3 /usr/man/man3/ldap_searchprefs.3 /usr/man/man3/ldap_init_searchprefs.3 /usr/man/man3/ /usr/man/man3/ldap_free_searchprefs.3 ldap_init_searchprefs_buf.3 /usr/man/man3/ldap_first_searchobj.3 /usr/man/man3/ldap_next_searchobj.3 /usr/man/man3/ldap_sort.3 /usr/man/man3/ldap_sort_entries.3 /usr/man/man3/ldap_sort_values.3 /usr/man/man3/ldap_sort_strcasecmp.3 /usr/man/man3/ldap_ufn.3 /usr/man/man3/ldap_ufn_search_s.3 /usr/man/man3/ldap_ufn_search_c.3 /usr/man/man3/ldap_ufn_search_ct.3 /usr/man/man3/ldap_ufn_setprefix.3 /usr/man/man3/ldap_ufn_setfilter.3 /usr/man/man3/ldap_ufn_timeout.3 /usr/man/man3/ldap_url.3 /usr/man/man3/ldap_is_ldap_url.3 /usr/man/man3/ldap_url_parse.3 /usr/man/man3/ldap_free_urldesc.3 /usr/man/man3/ldap_url_search.3 /usr/man/man3/ldap_url_search_s.3 /usr/man/man3/ldap_url_search_st.3 /usr/man/man5/ldap.conf.5 /usr/man/man5/ldapfilter.conf.5 /usr/man/man5/ldapfriendly.5 /usr/man/man5/ldapsearchprefs.conf.5 /usr/man/man5/ldaptemplates.conf.5 /usr/man/man5/ldif.5 /usr/man/man5/slapd.conf.5 /usr/man/man5/slapd.replog.5 /usr/man/man5/ud.conf.5 /usr/man/man8/centipede.8 /usr/man/man8/chlog2replog.8 /usr/man/man8/edb2ldif.8 /usr/man/man8/go500.8 /usr/man/man8/go500gw.8 /usr/man/man8/in.xfingerd.8 /usr/man/man8/ldapd.8 /usr/man/man8/ldbmcat.8 /usr/man/man8/ldif.8 /usr/man/man8/ldif2ldbm.8 /usr/man/man8/ldif2index.8 /usr/man/man8/ldif2id2entry.8 /usr/man/man8/ldif2id2children.8 /usr/man/man8/mail500.8 /usr/man/man8/fax500.8 /usr/man/man8/rcpt500.8 /usr/man/man8/slapd.8 /usr/man/man8/slurpd.8 /usr/sbin/ldif /usr/sbin/in.xfingerd /usr/sbin/go500 /usr/sbin/go500gw /usr/sbin/mail500 /usr/sbin/rp500 /usr/sbin/fax500 /usr/sbin/xrpcomp /usr/sbin/rcpt500 /usr/sbin/slapd /usr/sbin/ldif2ldbm /usr/sbin/ldif2index /usr/sbin/ldif2id2entry /usr/sbin/ldif2id2children /usr/sbin/ldbmcat /usr/sbin/centipede /usr/sbin/ldbmtest /usr/sbin/slurpd /usr/share/openldap /usr/share/openldap/ldapfriendly /usr/share/openldap/go500gw.help /usr/share/openldap/rcpt500.help /var/ldap Chapter 27. Linux PostgreSQL Database Server Table of Contents 1._Install_PostgreSQL 2._Compile_and_Optimize 3._Database_installation_using_superuser_account 4._Configuration_files 5._Configure_the_/etc/rc.d/init.d/postgresql_script_file 6._Commands_often_used 7._Installed_files Once you begin to serve, and supply services to your customers, you'll inevitably find that you need to keep information about them in an archive to be accessible and modifiable at any time, should you want it. These tasks can be accomplished with the use of a database. Many databases are available on Linux; Choosing one can be complicated, as it must be able to support a number of programming languages, standards and features. PostgreSQL, developed originally in the UC Berkeley Computer Science Department, pioneered many of the object-relational concepts now becoming available in commercial databases. It provides SQL92/SQL3 language support, transaction integrity, and type extensibility. 1. Install PostgreSQL As per the [PostgreSQL web site]: PostgreSQL is a sophisticated Object-Relational DBMS, supporting almost all SQL constructs, including subselects, transactions, and user-defined types and functions. It is the most advanced open-source database available anywhere. PostgresSQL These installation instructions assume * Commands are Unix-compatible. * The source path is /var/tmp, other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * PostgreSQL version number is 6.5.3 These are the Package(s) and available here: PostgreSQL Homepage: http://www.postgresql.org/ PostgreSQL FTP Site:216.126.84.28 You must be sure to download: postgresql-6.5.3.tar.gz There are certain prerequisites before compiling the PostgreSQL program, you must verify that egcs-c++-version.i386.rpm package is installed on your system. The egcs-c++-version.i386.rpm package is located in you Red Hat Linux CD-ROM under RedHat/RPMS subdirectory. After compilation and installation of PostgreSQL you can remove this package from your system. To verify that egcs- c++-version.i386.rpm is already installed, use the following command: [root@deep] /# rpm -q egcs-c++ To install egcs-c++-version.i386.rpm, use the following command: [root@deep] /# mount /dev/cdrom /mnt/cdrom [root@deep] /# cd /mnt/cdrom/RedHat/RPMS [root@deep ]/RPMS# rpm -Uvh egcs-c++-version.i386.rpm egcs-c++ ################################################## Before you decompress the tarballs, it is a good idea to make a list of files on the system before you install it, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > PostgreSQL1 before and find /* > PostgreSQL2 after you install the tarball, and use diff PostgreSQL1 PostgreSQL2 > PostgreSQL-Installed to get a list of what changed. To Compile you need to decompress the tarball -tar.gz: [root@deep] /# cp postgresql-version.tar.gz /var/tmp [root@deep] /# cd /var/tmp [root@deep ]/tmp# tar xzpf postgresql-version.tar.gz 2. Compile and Optimize First of all, to avoid security risks, we'll create an unprivileged user account named postgres to be the owner of the Postgres files. 1. To create the Postgres account, use the following command: [root@deep] /# useradd -M -o -r -d /var/lib/pgsql - s /bin/bash -c "PostgreSQL Server" -u 40 postgres >/dev/null 2>&1 || : 2. Move into the new PosgreSQL directory we have untarred earlier, and then move to its subdirectory named src. Type the following commands on your terminal: [root@deep] /# cd /var/tmp/postgresql-6.5.3 [root@deep ]/postgresql-6.5.3# cd src CC="egcs" \ ./configure \ --prefix=/usr \ --enable-locale This tells PostgreSQL to set itself up for this particular hardware setup with: - Enable locale support. 3. Edit the Makefile.global file, vi +210 Makefile.global and change the line: CFLAGS= -I$(SRCDIR)/include -I$(SRCDIR)/backend To read: CFLAGS= -I$(SRCDIR)/include -I$(SRCDIR)/backend -O9 - funroll-loops -ffast-math -malign-double -mcpu=pentiumpro - march=pentiumpro -fomit-frame-pointer -fno-exceptions These are our optimization flags for the PostgreSQL Server. Of course, you must tailor them to fit your system and CPU architecture. Now, we must compile and install PosgreSQL on to the server: [root@deep ]/src# make all [root@deep ]/src# cd .. [root@deep ]/postgresql-6.5.3# make -C src install [root@deep ]/postgresql-6.5.3# make -C src/man install [root@deep ]/postgresql-6.5.3# mkdir -p /usr/include/pgsql [root@deep ]/postgresql-6.5.3# mv /usr/include/access /usr/ include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/commands / usr/include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/executor / usr/include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/lib /usr/ include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/libpq /usr/ include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/libpq++ / usr/include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/port /usr/ include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/utils /usr/ include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/fmgr.h /usr/ include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/os.h /usr/ include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/config.h / usr/include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/c.h /usr/ include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/postgres.h / usr/include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/ postgres_ext.h /usr/include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/libpq-fe.h / usr/include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/libpq-int.h / usr/include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/ecpgerrno.h / usr/include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/ecpglib.h / usr/include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/ecpgtype.h / usr/include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/sqlca.h /usr/ include/pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/include/libpq++.H / usr/include/pgsql/ [root@deep ]/postgresql-6.5.3# mkdir -p /usr/lib/pgsql [root@deep ]/postgresql-6.5.3# mv /usr/lib/*source /usr/lib/ pgsql/ [root@deep ]/postgresql-6.5.3# mv /usr/lib/*sample /usr/lib/ pgsql/ [root@deep ]/postgresql-6.5.3# mkdir -p /var/lib/pgsql [root@deep ]/postgresql-6.5.3# chown -R postgres.postgres / var/lib/pgsql/ [root@deep ]/postgresql-6.5.3# chmod 755 /usr/lib/ libpq.so.2.0 [root@deep ]/postgresql-6.5.3# chmod 755 /usr/lib/ libecpg.so.3.0.0 [root@deep ]/postgresql-6.5.3# chmod 755 /usr/lib/ libpq++.so.3.0 [root@deep ]/postgresql-6.5.3# strip /usr/bin/postgres [root@deep ]/postgresql-6.5.3# strip /usr/bin/postmaster [root@deep ]/postgresql-6.5.3# strip /usr/bin/ecpg [root@deep ]/postgresql-6.5.3# strip /usr/bin/pg_id [root@deep ]/postgresql-6.5.3# strip /usr/bin/pg_version [root@deep ]/postgresql-6.5.3# strip /usr/bin/pg_dump [root@deep ]/postgresql-6.5.3# strip /usr/bin/pg_passwd [root@deep ]/postgresql-6.5.3# strip /usr/bin/psql [root@deep ]/postgresql-6.5.3# rm -f /usr/lib/ global1.description [root@deep ]/postgresql-6.5.3# rm -f /usr/lib/ local1_template1.description * The make command compiles all source files into executable binaries. * The make install command installs the binaries and any supporting files into the appropriate locations. * The mkdir will create a new directory named pgsql under the /usr/include and /usr/lib directories, * and then we move all subdirectories and files related to PostgreSQL under / usr/include and /usr/lib directories to the /usr/include/pgsql and /usr/lib/ pgsql directories respectively with the command mv. * The chown command will set the correct owner and group permission for the / var/lib/pgsql directory. * The strip command will discard all symbols from the object files. This means that our binary file will be smaller in size. This will improve the performance hit to the program since there will be fewer lines to read by the system when it executes the binary. * The rm command will remove the global1.description and local1_template1.description files that are not needed by our PosgreSQL program. 3. Database installation using superuser account Once PostgreSQL is installed on your Linux server, it's important to create the database installation before starting your PostgreSQL server. To create the database installation, use the following command: [root@deep] /# su postgres [postgres@deep /]$ initdb --pglib=/usr/lib/pgsql --pgdata=/ var/lib/pgsql We are initializing the database system with username postgres uid=40. This user will own all the files and must also own the server process. Creating Postgres database system directory /var/lib/pgsql/ base Creating template database in /var/lib/pgsql/base/template1 Creating global classes in /var/lib/pgsql/base Adding template1 database to pg_database... Vacuuming template1 Creating public pg_user view Creating view pg_rules Creating view pg_views Creating view pg_tables Creating view pg_indexes Loading pg_description [postgres@deep /]$ chmod 640 /var/lib/pgsql/pg_pwd [postgres@deep /]$ exit exit [root@deep] /# The --pglib command will specify where the library directory of PostgreSQL resides in the system, and the --pgdata command will specify where the database files must reside for this installation on Linux. Tip Do not create the database installation as root! This would be a major security hole. Please don't foreget to Cleanup later: [root@deep] /# cd /var/tmp [root@deep ]/tmp# rm -rf postgresql-version/ postgresql- version.tar.gz Remove the egcs-c++-version.i386.rpm package to save space. [root@deep] /# rpm -e egcs-c++ * The rm command will remove all the source files we have used to compile and install PostgreSQL. It will also remove the PostgreSQL compressed archive from the /var/tmp directory. * The rpm -e command will remove the egcs-c++ package we installed to compile the PosgreSQL Server. Note that the egcs-c++ package is required only for compiling programs like PostgreSQL and can be uninstalled safely after successful compilation of PostgreSQL. 4. Configuration files Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example PostgreSQL configuration file are organised like this: total 12 -rw-r--r-- 1 harrypotter harrypotter 58 Jun 8 13:00 Compile-PostgreSQL drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 init.d/ -rwx------ 1 harrypotter harrypotter 1504 Jun 8 13:00 postgres.sh* You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run PostgreSQL Database server, the following file is required and must be created or copied to the appropriate directory on your server. i. Copy the postgresql script file to the /etc/rc.d/init.d/ directory. Tip You can obtain the configuration files listed below on our floppy.tgz archive. Copy the following files from the decompressed floppy.tgz archive to the appropriate places, or copy and paste them directly from this book to the concerned file. 5. Configure the /etc/rc.d/init.d/postgresql script file To start and stop PostgreSQL Server, create the postgresql script file, touch / etc/rc.d/init.d/postgresql and add: #! /bin/sh # postgresql This is the init script for starting up the PostgreSQL # server # chkconfig: 345 85 15 # description: Starts and stops the PostgreSQL backend daemon that handles \ # all database requests. # processname: postmaster # pidfile: /var/run/postmaster.pid # # Source function library. . /etc/rc.d/init.d/functions # Get config. . /etc/sysconfig/network # Check that networking is up. # Pretty much need it for postmaster. [ ${NETWORKING} = "no" ] && exit 0 [ -f /usr/bin/postmaster ] || exit 0 # This script is slightly unusual in that the name of the daemon (postmaster) # is not the same as the name of the subsystem (postgresql) # See how we were called. case "$1" in start) echo -n "Checking postgresql installation: " # Check for the PGDATA structure if [ -f /var/lib/pgsql/PG_VERSION ] && [ -d /var/lib/ pgsql/base/template1 ] then # Check version of existing PGDATA if [ `cat /var/lib/pgsql/PG_VERSION` != '6.5' ] then echo "old version. Need to Upgrade." echo "See /usr/doc/postgresql-6.5.2/README.rpm for more information." exit 1 else echo "looks good!" fi # No existing PGDATA! Initdb it. else echo "no database files found." if [ ! -d /var/lib/pgsql ] then mkdir -p /var/lib/pgsql chown postgres.postgres /var/lib/pgsql fi su -l postgres -c '/usr/bin/initdb --pglib=/usr/lib/pgsql -- pgdata=/var/lib/pgsql' fi # Check for postmaster already running... pid=`pidof postmaster` if [ $pid ] then echo "Postmaster already running." else #all systems go -- remove any stale lock files rm -f /tmp/.s.PGSQL.* > /dev/null echo -n "Starting postgresql service: " su -l postgres -c '/usr/bin/postmaster -i -S -D/var/lib/pgsql' sleep 1 pid=`pidof postmaster` if [ $pid ] then echo -n "postmaster [$pid]" touch /var/lock/subsys/postgresql echo $pid > /var/run/postmaster.pid echo else echo "failed." fi fi ;; stop) echo -n "Stopping postgresql service: " killproc postmaster sleep 2 rm -f /var/run/postmaster.pid rm -f /var/lock/subsys/postgresql echo ;; status) status postmaster ;; restart) $0 stop $0 start ;; *) echo "Usage: postgresql {start|stop|status|restart}" exit 1 esac exit 0 Now, make this script executable and change its default permissions: [root@deep] /# chmod 700 /etc/rc.d/init.d/postgresql Create the symbolic rc.d links for PostgreSQL with the command: [root@deep] /# chkconfig --add postgresql Start your new PostgreSQL server manually with the following command: [root@deep] /# /etc/rc.d/init.d/postgresql start Checking postgresql installation: looks good! Starting postgresql service: postmaster [22401] 6. Commands often used The commands listed below are some that we use often, but many more exist. Check the man page for more details and information. To define a new user in your database, run the createuser utility program: [root@deep] /# su postgres [postgres@deep /]$ createuser Enter name of user to add ---> admin Enter user's postgres ID or RETURN to use unix user ID: 500 -> Is user "admin" allowed to create databases (y/n) y Is user "admin" a superuser? (y/n) y createuser: admin was successfully added To remove a user in your database, run the destroyuser utility program: [root@deep] /# su postgres [postgres@deep /]$ destroyuser Enter name of user to delete ---> admin destroyuser: delete of user admin was successful. To create a new database, run the createdb utility program: [root@deep] /# su postgres [postgres@deep /]$ createdb dbname 1 _1_ dbname is the name of the database. or with the Postgres terminal monitor program (psql) [root@deep] /# su admin [admin@deep /]$ psql template1 Welcome to the POSTGRESQL interactive sql monitor: Please read the file COPYRIGHT for copyright terms of POSTGRESQL [PostgreSQL 6.5.3 on i686-pc-linux-gnu, compiled by egcs ] type \? for help on slash commands type \q to quit type \g or terminate with semicolon to execute query You are currently connected to the database: template1 template1-> create database foo; CREATEDB Note Client connections can be restricted by IP address and/or user name via the pg_hba.conf file in PG_DATA. Other useful Postgres terminal monitor program commands (psql) are: To connect to the new database, use the command: template1-> \c foo connecting to new database: foo foo-> To create a table, use the command: foo-> create table bar (i int4, c char(16)); CREATE foo-> To inspect the new table, use the command: foo-> \d bar foo-> Table = bar +----------------------------------+------------------------ ----------+------------+ | Field | Type | Length | +----------------------------------+------------------------ ----------+------------+ | I | int4 | 4 | | c | char() | 16 | +----------------------------------+------------------------ ----------+------------+ To drop a table, index, view, use the command: foo-> drop table table_name; foo-> drop index index_name; foo-> drop view view_name; To insert into: once a table is created, it can be filled using the command. foo-> insert into table_name (name_of_attr1, name_of_attr2, name_of_attr3) foo-> values (value1, value2, value3); 7. Installed files /etc/rc.d/init.d/postgresql /etc/rc.d/rc0.d/K15postgresql /etc/rc.d/rc1.d/K15postgresql /etc/rc.d/rc2.d/K15postgresql /etc/rc.d/rc3.d/S85postgresql /etc/rc.d/rc4.d/S85postgresql /etc/rc.d/rc5.d/S85postgresql /etc/rc.d/rc6.d/K15postgresql /usr/bin/postgres /usr/bin/postmaster /usr/bin/ecpg /usr/bin/pg_id /usr/bin/pg_version /usr/bin/psql /usr/bin/pg_dump /usr/bin/pg_dumpall /usr/bin/pg_upgrade /usr/bin/pg_passwd /usr/bin/cleardbdir /usr/bin/createdb /usr/bin/createlang /usr/bin/createuser /usr/bin/destroydb /usr/bin/destroylang /usr/bin/destroyuser /usr/bin/initdb /usr/bin/vacuumdb /usr/bin/initlocation /usr/bin/ipcclean /usr/include/lib /usr/include/lib/dllist.h /usr/include/pgsql /usr/include/pgsql/access /usr/include/pgsql/access/attnum.h /usr/include/pgsql/commands /usr/include/pgsql/commands/trigger.h /usr/include/pgsql/executor /usr/include/pgsql/executor/spi.h /usr/include/pgsql/libpq /usr/include/pgsql/libpq/pqcomm.h /usr/include/pgsql/libpq/libpq-fs.h /usr/include/pgsql/libpq++ /usr/include/pgsql/libpq++/ /usr/include/pgsql/libpq++/pgdatabase.h pgconnection.h /usr/include/pgsql/libpq++/pgtransdb.h /usr/include/pgsql/libpq++/pgcursordb.h /usr/include/pgsql/libpq++/pglobject.h /usr/include/pgsql/port /usr/include/pgsql/port/linux /usr/include/pgsql/utils /usr/include/pgsql/utils/geo_decls.h /usr/include/pgsql/utils/elog.h /usr/include/pgsql/utils/palloc.h /usr/include/pgsql/utils/mcxt.h /usr/include/pgsql/fmgr.h /usr/include/pgsql/os.h /usr/include/pgsql/config.h /usr/include/pgsql/c.h /usr/include/pgsql/postgres.h /usr/include/pgsql/postgres_ext.h /usr/include/pgsql/libpq-fe.h /usr/include/pgsql/libpq-int.h /usr/include/pgsql/ecpgerrno.h /usr/include/pgsql/ecpglib.h /usr/include/pgsql/ecpgtype.h /usr/include/pgsql/sqlca.h /usr/include/pgsql/libpq++.H /usr/lib/libpq.a /usr/lib/libpq.so.2.0 /usr/lib/libpq.so.2 /usr/lib/libpq.so /usr/lib/libecpg.a /usr/lib/libecpg.so.3.0.0 /usr/lib/libecpg.so.3 /usr/lib/libecpg.so /usr/lib/libpq++.a /usr/lib/libpq++.so.3.0 /usr/lib/libpq++.so.3 /usr/lib/libpq++.so /usr/lib/plpgsql.so /usr/lib/pgsql /usr/lib/pgsql/global1.bki.source /usr/lib/pgsql/ /usr/lib/pgsql/pg_geqo.sample local1_template1.bki.source /usr/lib/pgsql/pg_hba.conf.sample /usr/man/man1/cleardbdir.1 /usr/man/man1/createdb.1 /usr/man/man1/createuser.1 /usr/man/man1/destroydb.1 /usr/man/man1/destroyuser.1 /usr/man/man1/ecpg.1 /usr/man/man1/initdb.1 /usr/man/man1/initlocation.1 /usr/man/man1/ipcclean.1 /usr/man/man1/pg_dump.1 /usr/man/man1/pg_dumpall.1 /usr/man/man1/pg_passwd.1 /usr/man/man1/pg_upgrade.1 /usr/man/man1/postgres.1 /usr/man/man1/postmaster.1 /usr/man/man1/psql.1 /usr/man/man3/catalogs.3 /usr/man/man3/libpq.3 /usr/man/man5/pg_hba.conf.5 /usr/man/manl /usr/man/manl/abort.l /usr/man/manl/alter_table.l /usr/man/manl/alter_user.l /usr/man/manl/begin.l /usr/man/manl/close.l /usr/man/manl/cluster.l /usr/man/manl/commit.l /usr/man/manl/copy.l /usr/man/manl/create_aggregate.l /usr/man/manl/create_database.l /usr/man/manl/create_function.l /usr/man/manl/create_index.l /usr/man/manl/create_language.l /usr/man/manl/create_operator.l /usr/man/manl/create_rule.l /usr/man/manl/create_sequence.l /usr/man/manl/create_table.l /usr/man/manl/create_trigger.l /usr/man/manl/create_type.l /usr/man/manl/create_user.l /usr/man/manl/create_version.l /usr/man/manl/create_view.l /usr/man/manl/declare.l /usr/man/manl/delete.l /usr/man/manl/drop.l /usr/man/manl/drop_aggregate.l /usr/man/manl/drop_database.l /usr/man/manl/drop_function.l /usr/man/manl/drop_index.l /usr/man/manl/drop_language.l /usr/man/manl/drop_operator.l /usr/man/manl/drop_rule.l /usr/man/manl/drop_sequence.l /usr/man/manl/drop_table.l /usr/man/manl/drop_trigger.l /usr/man/manl/drop_type.l /usr/man/manl/drop_user.l /usr/man/manl/drop_view.l /usr/man/manl/end.l /usr/man/manl/explain.l /usr/man/manl/fetch.l /usr/man/manl/grant.l /usr/man/manl/insert.l /usr/man/manl/listen.l /usr/man/manl/load.l /usr/man/manl/lock.l /usr/man/manl/move.l /usr/man/manl/notify.l /usr/man/manl/reset.l /usr/man/manl/revoke.l /usr/man/manl/rollback.l /usr/man/manl/select.l /usr/man/manl/set.l /usr/man/manl/show.l /usr/man/manl/sql.l /usr/man/manl/update.l /usr/man/manl/vacuum.l /var/lib/pgsql /var/lib/pgsql/base /var/lib/pgsql/base/template1 /var/lib/pgsql/base/template1/pg_proc /var/lib/pgsql/base/template1/pg_type /var/lib/pgsql/base/template1/ pg_attribute /var/lib/pgsql/base/template1/pg_class /var/lib/pgsql/base/template1/ pg_inherits /var/lib/pgsql/base/template1/pg_index /var/lib/pgsql/base/template1/ pg_statistic /var/lib/pgsql/base/template1/ /var/lib/pgsql/base/template1/ pg_operator pg_opclass /var/lib/pgsql/base/template1/pg_am /var/lib/pgsql/base/template1/pg_amop /var/lib/pgsql/base/template1/pg_amproc /var/lib/pgsql/base/template1/ pg_language /var/lib/pgsql/base/template1/ /var/lib/pgsql/base/template1/pg_ipl pg_aggregate /var/lib/pgsql/base/template1/ /var/lib/pgsql/base/template1/ pg_inheritproc pg_rewrite /var/lib/pgsql/base/template1/ /var/lib/pgsql/base/template1/ pg_listener pg_description /var/lib/pgsql/base/template1/ /var/lib/pgsql/base/template1/ pg_attribute_relid_attnam_index pg_attribute_relid_attnum_index /var/lib/pgsql/base/template1/ /var/lib/pgsql/base/template1/ pg_attribute_attrelid_index pg_proc_oid_index /var/lib/pgsql/base/template1/ /var/lib/pgsql/base/template1/ pg_proc_proname_narg_type_index pg_proc_prosrc_index /var/lib/pgsql/base/template1/ /var/lib/pgsql/base/template1/ pg_type_oid_index pg_type_typname_index /var/lib/pgsql/base/template1/ /var/lib/pgsql/base/template1/ pg_class_oid_index pg_class_relname_index /var/lib/pgsql/base/template1/ /var/lib/pgsql/base/template1/ pg_attrdef pg_attrdef_adrelid_index /var/lib/pgsql/base/template1/ /var/lib/pgsql/base/template1/ pg_relcheck pg_relcheck_rcrelid_index /var/lib/pgsql/base/template1/ /var/lib/pgsql/base/template1/ pg_trigger pg_trigger_tgrelid_index /var/lib/pgsql/base/template1/ /var/lib/pgsql/base/template1/ pg_description_objoid_index PG_VERSION /var/lib/pgsql/base/template1/pg_user /var/lib/pgsql/base/template1/pg_rules /var/lib/pgsql/base/template1/pg_views /var/lib/pgsql/base/template1/pg_tables /var/lib/pgsql/base/template1/ /var/lib/pgsql/pg_variable pg_indexes /var/lib/pgsql/pg_database /var/lib/pgsql/pg_shadow /var/lib/pgsql/pg_group /var/lib/pgsql/pg_log /var/lib/pgsql/PG_VERSION /var/lib/pgsql/pg_hba.conf /var/lib/pgsql/pg_geqo.sample /var/lib/pgsql/pg_pwd Chapter 28. Software -Server/Proxy Network Table of Contents 1._Linux_Squid_Proxy_Server 2._Configure_and_Optimize 3._Improve_performance_Using_GNU_malloc_library 4._Compile_and_Optimize 5._Configurations 6._Configure_the_/etc/squid/squid.conf_file_-in_httpd-accelerator_mode 7._Configure_of_the_/etc/squid/squid.conf_file_-/proxy-caching_mode 8._Configure_the_/etc/rc.d/init.d/squid_script_file_-/all_configurations 9._Configure_the_/etc/logrotate.d/squid_file 9.1._Securing_and_Immunize_Squid 10._Optimizing_Squid 10.1._The_cachemgr.cgi 11._Netscape_Proxies_Configuration 12._Installed_files Proxy-servers, with their capability to save bandwidth, improve security, and increase web-surfing speed are becoming more popular than ever. At this time only a few proxy-server programs are available. These proxy-servers have two main drawbacks: They are commercial. They don't support ICP, ICP is used to exchange hints about the existence of URLs in neighbor caches . Squid is the best choice for a proxy-cache server since it is robust, free, and can use ICP features. Derived from the cached software from the ARPA-funded Harvest research project, developed at the National Laboratory for Applied Network Research and funded by the National Science Foundation, Squid offers high-performance caching of web clients, and also supports FTP, Gopher, and HTTP data objects. It stores hot objects in RAM, maintains a robust database of objects on disk, has a complex access control mechanism, and supports the SSL protocol for proxying secure connections. In addition, it can be hierarchically linked to other Squid-based proxy servers for streamlined caching of pages. 1. Linux Squid Proxy Server In our compilation and configuration we'll configure Squid to run as an httpd- accelerator to get more performance out of our web server. In accelerator mode, the Squid server acts as a reverse proxy cache: it accepts client requests, serves them out of cache, if possible, or requests them from the original server for which it is the reverse proxy. Also we'll show you how to configure Squid as a proxy-caching server to be able to let all users in your corporate network use Squid to access the Internet. These installation instructions assume * Commands are Unix-compatible. * The source path is /var/tmp, other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * Squid version number is 2.3.STABLE2 These are Package(s) and are available here: Squid Homepage:http://www.squid-cache.org/ Squid FTP Site: 204.144.128.89 You must be sure to download: squid-2.3.STABLE2-src.tar.gz Before you decompress tarballs, it is a good idea to make a list of files on the system before you install Squid, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > Squid1 before and find /* > Squid2 after you install the software, and use diff Squid1 Squid2 > Squid-Installed to get a list of what changed. To Compile, you need to decompress the tarball, tar.gz.: [root@deep] /# cp squid-version.STABLEz-src.tar.gz /var/tmp [root@deep] /# cd /var/tmp [root@deep ]/tmp# tar xzpf squid-version.STABLEz-src.tar.gz 2. Configure and Optimize Squid Proxy Server can't run as super-user root, and for this reason we must create a special user with no shell for running Squid Proxy Server. [root@deep] /# useradd -d /cache/ -r -s /dev/null squid >/ dev/null 2>&1 [root@deep] /# mkdir /cache/ [root@deep] /# chown -R squid.squid /cache/ First of all, we add the user squid to the /etc/passwd file. Then, we create the /cache directory if this directory doesn't exist, we repeat only if it doesn't exist. Finally, we change the owner of the directory cache to be the user squid. Tip Usually we don't need to perform the command, mkdir /cache/, because we have already created this directory when we partitioned our hard drive during the installation of Linux. If this partition doesn't exist, you must execute this command to create the directory. 1. Move into the new Squid directory and type the following commands on your terminal: Edit the Makefile.in file, vi +18 icons/Makefile.in and change the line: DEFAULT_ICON_DIR = $(sysconfdir)/icons To read: DEFAULT_ICON_DIR = $(libexecdir)/icons 2. We change the variable, sysconfdir to be libexecdir. With this modification, the icons directory of Squid will be located under the /usr/ lib/squid directory. a. Edit the Makefile.in file, vi +34 src/Makefile.in and change the lines: DEFAULT_CACHE_LOG = $(localstatedir)/logs/ cache.log To read: DEFAULT_CACHE_LOG = $(localstatedir)/log/ squid/cache.log b. DEFAULT_ACCESS_LOG = $(localstatedir)/logs/ access.log To read: DEFAULT_ACCESS_LOG = $(localstatedir)/log/ squid/access.log c. DEFAULT_STORE_LOG = $(localstatedir)/logs/ store.log To read: DEFAULT_STORE_LOG = $(localstatedir)/log/ squid/store.log d. DEFAULT_PID_FILE = $(localstatedir)/logs/ squid.pid To read: DEFAULT_PID_FILE = $(localstatedir)/run/ squid.pid e. DEFAULT_SWAP_DIR = $(localstatedir)/cache To read: DEFAULT_SWAP_DIR = /cache f. DEFAULT_ICON_DIR = $(sysconfdir)/icons To read: DEFAULT_ICON_DIR = $(libexecdir)/icons We change the default location of cache.log, access.log, and store.log files to be located under /var/log/squid directory. Then, we put the pid file of Squid under /var/run directory, and finally, locate the icons directory of Squid under /usr/lib/squid/icons with the variable libexecdir above. 3. Improve performance Using GNU malloc library If you're suffering from memory limitations on your system, the cache performance of Squid will be affected. To reduce this problem, you can link Squid with an external malloc library such as GNU malloc. To make Squid use GNU malloc as an external library, follows these simple steps: These are the Package(s) required: GNU malloc Homepage:http://www.gnu.org/order/ftp.html You must be sure to download: malloc.tar.gz [root@deep] /# cp malloc.tar.gz /var/tmp [root@deep] /# cd /var/tmp [root@deep ]/tmp# tar xzpf malloc.tar.gz 1. Compile and install GNU malloc on your system by executing the following commands: [root@deep ]/tmp# cd malloc [root@deep ]/malloc# export CC=egcs [root@deep ]/malloc# make 2. Copy the libmalloc.a file to your system library directory and be sure to name it libgnumalloc.a [root@deep ]/malloc# cp libmalloc.a /usr/lib/ libgnumalloc.a 3. Copy the malloc.h file to your system's include directory and be sure to name it gnumalloc.h [root@deep ]/malloc# cp malloc.h /usr/include/ gnumalloc.h With the files libgnumalloc.a and gnumalloc.h installed on your system, Squid will detect them automatically during its compile time, and will use them to improve its cache performance. 4. Compile and Optimize Return into the new Squid directory and type the following commands on your terminal: CC="egcs" \ CFLAGS="-O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions" \ ./configure \ --prefix=/usr \ --exec-prefix=/usr \ --bindir=/usr/sbin \ --libexecdir=/usr/lib/squid \ --localstatedir=/var \ --sysconfdir=/etc/squid \ --enable-delay-pools \ --enable-cache-digests \ --enable-poll \ --disable-ident-lookups \ --enable-truncate \ --enable-heap-replacement This tells Squid to set itself up for this particular hardware setup with these options: * Use the delay pools feature of Squid to limit and control bandwidth usage for users. * Use Cache Digests to improve client response time and network utilization. * Enable poll() instead of select() since its preferred over select. * Disable ident-lookups to remove code that performs Ident, RFC 931, lookups and reduce possible denial-of-service. * Enable truncate to glean some performance improvements when removing cached files. * Use the heap-replacement feature of Squid to have the choice of various cache replacement algorithms, instead of the standard LRU algorithm for better performance. See below for a more detailed explanation. Now, we must compile and install Squid on the server: [root@deep ]/squid-2.3.STABLE2# make -f makefile [root@deep ]/squid-2.3.STABLE2# make install [root@deep ]/squid-2.3.STABLE2# mkdir -p /var/log/squid [root@deep ]/squid-2.3.STABLE2# rm -rf /var/logs/ [root@deep ]/squid-2.3.STABLE2# chown squid.squid /var/log/ squid/ [root@deep ]/squid-2.3.STABLE2# chmod 750 /var/log/squid/ [root@deep ]/squid-2.3.STABLE2# chmod 750 /cache/ [root@deep ]/squid-2.3.STABLE2# rm -f /usr/sbin/RunCache [root@deep ]/squid-2.3.STABLE2# rm -f /usr/sbin/RunAccel [root@deep ]/squid-2.3.STABLE2# strip /usr/sbin/squid [root@deep ]/squid-2.3.STABLE2# strip /usr/sbin/client [root@deep ]/squid-2.3.STABLE2# strip /usr/lib/squid/ dnsserver [root@deep ]/squid-2.3.STABLE2# strip /usr/lib/squid/unlinkd [root@deep ]/squid-2.3.STABLE2# strip /usr/lib/squid/ cachemgr.cgi * The make -f command will compile all source files into executable binaries * The make install will install the binaries and any supporting files into the appropriate locations. * The mkdir command will create a new directory named squid under /var/log. * The rm -rf command will remove the /var/logs directory since this directory has been created to handle the log files related to Squid that we have moved to the /var/log/squid location. * The chown will change the owner of /var/log/squid to be the user squid * The chmod command will make the mode of squid and cache directories; 0750/ drwxr-x---, for security reasons. Take note that we remove the small scripts named RunCache and RunAccel which start Squid in either caching mode or accelerator mode, since we use a better script named squid located under the /etc/rc.d/init.d/ directory that takes advantage of Linux system V. The strip command will reduce the size of binaries for optimum performance. Please do cleanup later: [root@deep] /# cd /var/tmp [root@deep ]/tmp# rm -rf squid-version/ squid- version.STABLEz-src.tar.gz [root@deep ]/tmp# rm -rf malloc/ malloc.tar.gz (if you used the GNU malloc external library) The rm command will remove all the source files we have used to compile and install Squid and GNU malloc. It will also remove the Squid and GNU malloc compressed archive from the /var/tmp directory. 5. Configurations Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example Squid configuration file are organised like this: total 20 -rw-r--r-- 1 harrypotter harrypotter 428 Jun 8 13:00 Compile-Squid drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 init.d/ drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 logrotate.d/ -rw-r--r-- 1 harrypotter harrypotter 461 Jun 8 13:00 squid.conf -rwx------ 1 harrypotter harrypotter 319 Jun 8 13:00 squid.sh* You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run Squid server in httpd-accelerator mode, the following files are required and must be created or copied to the appropriate directories on your server. i. Copy the squid.conf file in the /etc/squid/ directory. ii. Copy the squid script file in the /etc/rc.d/init.d/ directory. iii. Copy the squid file in the /etc/logrotate.d/ directory. To run Squid server in proxy-caching mode, the following files are required and must be created or copied to the appropriate directories on your server. i. Copy the squid.conf file in the /etc/squid/ directory. ii. Copy the squid script file in the /etc/rc.d/init.d/ directory. iii. Copy the squid file in the /etc/logrotate.d/ directory. Tip You can obtain the configuration files listed below on our floppy.tgz archive. Copy the following files from the decompressed floppy.tgz archive to the appropriate places, or copy and paste them directly from this book to the concerned file. 6. Configure the /etc/squid/squid.conf file -in httpd-accelerator mode The squid.conf file is used to set and configure all the different options for your Squid proxy server. In the configuration file below, we'll configure the / etc/squid/squid.conf file to be in httpd-accelerator mode. In this acceleration mode, if the Web Server runs on the same server where Squid is installed, you must set its daemon to run on port 81. With the Apache web server, you can do it by assigning the line Port 80 to Port 81 in its httpd.conf file. If the Web Server runs on other servers in your network like we do, you can keep the same port number (80) for Apache, since Squid will bind on a different IP number where port (80) is not already in use. Squid/Accelerator Edit the squid.conf file, vi /etc/squid/squid.conf and add/change the following options: http_port 80 icp_port 0 acl QUERY urlpath_regex cgi-bin \? no_cache deny QUERY cache_mem 16 MB cache_dir ufs /cache 200 16 256 emulate_httpd_log on redirect_rewrites_host_header off replacement_policy GDSF acl all src 0.0.0.0/0.0.0.0 http_access allow all cache_mgr admin@openna.com cache_effective_user squid cache_effective_group squid httpd_accel_host 208.164.186.3 httpd_accel_port 80 log_icp_queries off cachemgr_passwd my-secret-pass all buffered_logs on This tells the squid.conf file to set itself up for this particular configuration setup with: http_port 80 The option http_port specifies the port number where Squid will listen for HTTP client requests. If you set this option to port 80, the client will have the illusion of being connected to the Apache Web Server. Since we are running Squid in accelerator mode, we must listen on port 80. icp_port 0 The option icp_port specifies the port number where Squid will sends and receive ICP requests from neighboring caches. We must set the value of this option to 0 to disable it, since we are configuring Squid to be in accelerator mode for the Web Server. The ICP feature is needed only in a multi-level cache environment with multiple siblings and parent caches. Using ICP in an accelerator mode configuration would add unwanted overhead to Squid. acl QUERY urlpath_regex cgi-bin \? and no_cache deny QUERY The options acl QUERY urlpath_regex cgi-bin \? and no_cache deny QUERY are used to force certain objects to never be cached, like files under cgi-bin directory. This is a security feature. cache_mem 16 MB The option cache_mem specifies the amount of memory; RAM, to be used for caching the so called: In-Transit objects, Hot Objects, Negative-Cached objects. This is an optimization feature. It's important to note that Squid can uses much more memory than the value you specify in this parameter, and for this reason if you have 48 MB free for Squid, you must put 48/3 = 16 MB here. cache_dir ufs /cache 200 16 256 The option cache_dir specifies in this order: which kind of storage system to use; ufs, the name of the cache directory; /cache for Squid, the disk space in megabytes to use under this directory 200 Mbytes, the number of first-level subdirectories to be created under the cache directory; 16 Level-1, and the number of second-level subdirectories to be created under each first-level cache directory; 256 Level-2. In accelerator mode, this option is directly related to the size and number of files that you want to serve with your Apache web server. emulate_httpd_log on The option emulate_httpd_log, if set to ON, specifies that Squid should emulate the log file format of the Apache web server. This is very useful if you want to use a third party program like Webalizer to analyze the Web Server httpd log file. redirect_rewrites_host_header off The option redirect_rewrites_host_header, if set to OFF, tells Squid to not rewrites any Host: header in redirected requests. It's recommended to set this option to OFF if you are running Squid in accelerator mode. replacement_policy GDSF The option replacement_policy specifies the cache policy Squid will use to determine which objects in the cache must be replaced when the proxy need to make disk space. The Squid LRU policy is used by default if you have not specified the --enable-heap-replacement option during compile time. In our configuration, we choose the GDSF -Greedy-Dual Size Frequency policy as our default policy. See http://www.hpl.hp.com/ techreports/1999/HPL-1999-69.html and http://fog.hpl.external.hp.com/ techreports/98/HPL-98-173.html for more information. acl all src 0.0.0.0/0.0.0.0 and http_access allow all The options acl and http_access specify and define an access control list to be applied on the proxy server Squid. Our acl and http_access options are not restricted, and allow every one to connect on the proxy server since we use this proxy to accelerate the public Apache Web Server. See your Squid documentation for more information when using Squid in non- accelerator mode. cache_mgr admin The option cache_mgr specify the email-address of the administrator responsible for the Squid proxy server. This person is the one who will receive mail if Squid encounter problems. You can specify the name or the complete email address in this option. cache_effective_user squid and cache_effective_group squid The options cache_effective_user and cache_effective_group specify the UID/GID that the cache will run on. Don't forget to never run Squid as root. In our configuration we use the UID squid and the GID squid. httpd_accel_host 208.164.186.3 and httpd_accel_port 80 The options httpd_accel_host and httpd_accel_port specify to Squid the IP address and port number where the real HTTP Server i.e. Apache is. In our configuration, the real HTTP Web Server is on the IP address 208.164.186.3, www.openna.com and on port (80). www.openna.com is another host name on our network, and since the Squid Proxy Server doesn't reside on the same host of Apache HTTP Web Server, we can use port (80) for our Squid Proxy Server, and port (80) for our Apache Web Server, and the illusion is perfect. log_icp_queries off The option log_icp_queries specifies if you want ICP; ICP is used to exchange hints about the existence of URLs in neighbor caches queries to be logged to the access.log file or not. Since we don't use the ICP feature in Squid accelerator mode, we can safely set this option to OFF. cachemgr_passwd my-secret-pass all The option cachemgr_passwd specifies a password that will be required for accessing the operations of the cachemgr.cgi program utility. This CGI utility program is designed to run through a web interface and outputs statistics about the Squid configuration and performance. The my-secret- pass is the password that you have chosen, and the keyword all specifies to set this password to be the same for all actions you can perform with this program. See The cachemgr.cgi program utility of Squid, below in this chapter for more information. buffered_logs on The option buffered_logs, if turned ON, can speed up the writing of some log files slightly. This is an optimization feature. 7. Configure of the /etc/squid/squid.conf file -/proxy-caching mode With some minor modification to the squid.conf file we have defined above to run in httpd-accelerator mode, we can run Squid as a proxy-caching server. With a proxy cache server, all users in your corporate network use Squid to access the Internet. With this configuration, you can have complete control, and apply special policies on what can be viewed, accessed, and downloaded. You can also control bandwidth usage, connection time, and so on. A proxy cache server can be configured to run as stand-alone server for your corporation, or to use and share caches hierarchically with other proxy servers around the Internet. Squid-StandAlone With the first example below we show you how to configure Squid as a stand- alone server, and then speak a little bit about a cache hierarchy configuration, where two or more proxy-cache servers cooperate by serving documents to each other. Edit the squid.conf file, vi /etc/squid/squid.conf and add/change the following options for proxy cache that run as a stand-alone server: http_port 8080 icp_port 0 acl QUERY urlpath_regex cgi-bin \? no_cache deny QUERY cache_mem 16 MB cache_dir ufs /cache 200 16 256 redirect_rewrites_host_header off replacement_policy GDSF acl localnet src 192.168.1.0/255.255.255.0 acl localhost src 127.0.0.1/255.255.255.255 acl Safe_ports port 80 443 210 119 70 21 1025-65535 acl CONNECT method CONNECT acl all src 0.0.0.0/0.0.0.0 http_access allow localnet http_access allow localhost http_access deny !Safe_ports http_access deny CONNECT http_access deny all cache_mgr admin@openna.com cache_effective_user squid cache_effective_group squid log_icp_queries off cachemgr_passwd my-secret-pass all buffered_logs on The big difference with the httpd-accellerator mode configuration is the use of access control lists (ACL). This feature allows you to restrict access based on source IP address (src), destination IP address (dst), source domain, destination domain, time, and so on. Many types exist with this feature, and you should consult the Squid.conf file for a complete list. The four most used types are as follows:                    acl  name   type    data                    |     |    |    |                    acl some-name src a.b.c.d/e.f.g.h  # ACL restrict access based on source IP address                     acl some-name dst a.b.c.d/e.f.g.h  # ACL restrict access based on destination IP address                     acl some-name srcdomain foo.com  # ACL restrict access based on source domain                     acl some-name dstdomain foo.com  # ACL restrict access based on destination domain                   As an example, to restrict access to your Squid proxy server to only your internal clients, and to a specific range of designated ports, something like the following will make the job: acl localnet src 192.168.1.0/255.255.255.0 acl localhost src 127.0.0.1/255.255.255.255 acl Safe_ports port 80 443 210 119 70 21 1025-65535 acl CONNECT method CONNECT acl all src 0.0.0.0/0.0.0.0 http_access allow localnet http_access allow localhost http_access deny !Safe_ports http_access deny CONNECT http_access deny all This acl configuration will allow all internal clients from the private class C 192.168.1.0 to access the proxy server; it's also recommended that you allow the localhost IP (a special IP address used by your own server) to access the proxy. After we choose a range of ports (80=http, 443=https, 210=wais, 119=nntp, 70=gopher, and 21=ftp) which our internal clients can use to access the Internet, we deny the CONNECT method to prevent outside people from trying to connect to the proxy server, and finally, we deny all source IP address and ports on the proxy server. Multi-level Web Caching The second method of proxy cache is the so-called Multi-level Web Caching where you choose to share and cooperate with more proxy-cache servers on the Internet. With this method, your organization uses the cache of many others proxy cache servers, and to compensate, the other cache server can use yours. It's important to note that in this situation, the proxy cache can play two different roles in the hierarchy. It can be configured to be a sibling cache, and be able to only serve documents it already has, or it can be configured as a parent cache, and be able to get documents from another cache or from the source directly. Squid-Hierarchy Tip A good strategy to avoid generating more network traffic than without web caching is to choose to have several sibling caches and only a small number of parent caches. 8. Configure the /etc/rc.d/init.d/squid script file -/all configurations Configure your /etc/rc.d/init.d/squid script file to start and stop the Squid Internet Object Cache. This script has been modified to setup swap cache for Squid in /cache instead of /var/spool/squid. Create the squid script file, touch /etc/rc.d/init.d/squid and add: #!/bin/bash # squid This shell script takes care of starting and stopping # Squid Internet Object Cache # # chkconfig: - 90 25 # description: Squid - Internet Object Cache. Internet object caching is \ # a way to store requested Internet objects (i.e., data available \ # via the HTTP, FTP, and gopher protocols) on a system closer to the \ # requesting site than to the source. Web browsers can then use the \ # local Squid cache as a proxy HTTP server, reducing access time as \ # well as bandwidth consumption. # pidfile: /var/run/squid.pid # config: /etc/squid/squid.conf PATH=/usr/bin:/sbin:/bin:/usr/sbin export PATH # Source function library. . /etc/rc.d/init.d/functions # Source networking configuration. . /etc/sysconfig/network # Check that networking is up. [ ${NETWORKING} = "no" ] && exit 0 # check if the squid conf file is present [ -f /etc/squid/squid.conf ] || exit 0 # determine the name of the squid binary [ -f /usr/sbin/squid ] && SQUID=squid [ -z "$SQUID" ] && exit 0 # determine which one is the cache_swap directory CACHE_SWAP=`sed -e 's/#.*//g' /etc/squid/squid.conf | \ grep cache_dir | sed -e 's/cache_dir//' | \ cut -d ' ' -f 2` [ -z "$CACHE_SWAP" ] && CACHE_SWAP=/cache # default squid options # -D disables initial dns checks. If you most likely will not to have an # internet connection when you start squid, uncomment this #SQUID_OPTS="-D" RETVAL=0 case "$1" in start) echo -n "Starting $SQUID: " for adir in $CACHE_SWAP; do if [ ! -d $adir/00 ]; then echo -n "init_cache_dir $adir... " $SQUID -z -F 2>/dev/null fi done $SQUID $SQUID_OPTS & RETVAL=$? echo $SQUID [ $RETVAL -eq 0 ] && touch /var/lock/subsys/$SQUID ;; stop) echo -n "Stopping $SQUID: " $SQUID -k shutdown & RETVAL=$? if [ $RETVAL -eq 0 ] ; then rm -f /var/lock/subsys/$SQUID while : ; do [ -f /var/run/squid.pid ] || break sleep 2 && echo -n "." done echo "done" else echo fi ;; reload) $SQUID $SQUID_OPTS -k reconfigure exit $? ;; restart) $0 stop $0 start ;; status) status $SQUID $SQUID -k check exit $? ;; probe) exit 0; ;; *) echo "Usage: $0 {start|stop|status|reload|restart}" exit 1 esac exit $RETVAL Now, make this script executable and change its default permissions: [root@deep /]# chmod 700 /etc/rc.d/init.d/squid Create the symbolic rc.d links for Squid with the command: [root@deep /]# chkconfig --add squid By default the squid script will not automatically start the proxy server on Red Hat Linux when you reboot the server. You can change it's default by executing the following command: [root@deep /]# chkconfig --level 345 squid on Start your new Squid Proxy Server manually with the following command: [root@deep /]# /etc/rc.d/init.d/squid start Starting squid: init_cache_dir ufs... squid 9. Configure the /etc/logrotate.d/squid file Configure your /etc/logrotate.d/squid file to rotate your log files automatically each week. Create the squid file, touch /etc/logrotate.d/squid and add: /var/log/squid/access.log { weekly rotate 5 copytruncate compress notifempty missingok } /var/log/squid/cache.log { weekly rotate 5 copytruncate compress notifempty missingok } /var/log/squid/store.log { weekly rotate 5 copytruncate compress notifempty missingok # This script asks squid to rotate its logs on its own. # Restarting squid is a long process and it is not worth # doing it just to rotate logs postrotate /usr/sbin/squid -k rotate endscript } 9.1. Securing and Immunize Squid By having more control on mounting the cache directory of Squid, if you have created the cache directory of Squid in a separate partition of your Linux system i.e. /cache, like we have done during the install setup, then you can use the noexec, nodev, and nosuid features to improve and consolidate the cache security. These features can be set up in the /etc/fstab file to tell the system to not allow execution of any binaries; noexec to not interpret character or block special devices; nodev and to not allow set-user-identifier or set-group-identifier bits to take effect, nosuid on the mounted file system /cache in our example. Applying this procedure on the partition where the Squid Cache resides will help to eliminate the possibility of DEV, SUID/SGID, and execution of any binaries. As an example, assuming /dev/sda8 is the partition in the system where the / cache directory of Squid lives, you must edit the fstab file, vi /etc/fstab and change the line related to /dev/sda8: /dev/sda8 /cache ext2 defaults 1 2 To read: /dev/sda8 /cache ext2 noexec,nodev,nosuid 1 2 Dont you forget to reboot your system for the changes to take effect. You should immunize important configuration file like squid.conf. As we already know, the immutable bit can be used to prevent deletion, overwriting, or creation of a symbolic link to a file. Once your squid.conf file has been configured, it's a good idea to immunize it with the following command: [root@deep /]# chattr +i /etc/squid/squid.conf 10. Optimizing Squid The atime and noatime attributes can be used to get a measurable performance gain in the Squid cache directory. See General_System_Optimization in this book, for more information on the subject. The most important resource for Squid is physical memory. Your processor does not need to be ultra-fast. Your disk system will be the major bottleneck, so fast disks are important for high-volume caches. Do not use IDE disks if you can help it. 10.1. The cachemgr.cgi The cachemgr.cgi utility program, which is available by default when you compile and install Squid into your system, is designed to run through a web interface, and outputs various statistics about Squid configuration and performance. This program is located under the /usr/lib/squid directory, and you must put it in your cgi-bin directory (eg, /home/httpd/cgi-bin) to be able to use it. Follow the simple steps below to use this program. 1. Move the cachemgr.cgi program to your cgi-bin directory: [root@deep /]# mv /usr/lib/squid/cachemgr.cgi / home/httpd/cgi-bin I assume your cgi-bin directory is located under /home/httpd/cgi-bin, other paths are possible. Also, this cgi-bin will exist only if you've installed the Apache Web Server on your system. 2. Once you've put the cachemgr.cgi program in your cgi-bin directory, you can point your web browser to the following address http://my-web-server/ cgi-bin/cachemgr.cgi to be able to use the various features of this program. The my-web-server is the address where your Apache web server lives, and cachemgr.cgi is the utility program we have just placed in our cgi-bin directory to display information and the configuration of our Squid Linux server. Squid cache password If you have configured the squid.conf file to use password authentication for cachemgr.cgi, you'll be asked to enter the Cache Host, Cache Port, Manager name, and Password information before you are able to access the cachemgr.cgi program. See the configuration of the /etc/squid/squid.conf file above for more information. Squid cache Manager Once you have been authenticated by the server, you'll see in your web browser interface the Cache Manager menu where you can examine and analyze the different options related to your Squid Proxy server. 11. Netscape Proxies Configuration If you decide to use Squid as proxy-caching server, and allow all users in your corporate network to use Squid to access the Internet only in this mode, you must instruct your users browsers to fetch objects from your Squid proxy server instead of retrieving them directly from the Internet. With Netscape Communicator, follow these simple steps below: 1. Open Netscape Communicator 2. Go to Edit menu 3. Click on Preferences 4. Double click Advanced category on the left side 5. Click on Proxies subcategory option 6. Select on the right side Manual proxy configuration radio button 7. Click on the View button 8. Fill the boxes with your proxy server information For example: HTTP: 208.164.186.1 Port: 8080 Security: 208.164.186.1 Port: 8080 FTP: 208.164.186.1 Port: 8080 Gopher: 208.164.186.1 Port: 8080 WAIS: 208.164.186.1 Port: 8080 Proxy Netscape Configuration 12. Installed files /etc/squid /etc/squid/mib.txt /etc/squid/squid.conf.default /etc/squid/squid.conf /etc/squid/mime.conf.default /etc/squid/mime.conf /etc/squid/errors /etc/squid/errors/ERR_ACCESS_DENIED /etc/squid/errors/ /etc/squid/errors/ ERR_CACHE_ACCESS_DENIED ERR_CACHE_MGR_ACCESS_DENIED /etc/squid/errors/ERR_CANNOT_FORWARD /etc/squid/errors/ERR_CONNECT_FAIL /etc/squid/errors/ERR_DNS_FAIL /etc/squid/errors/ERR_FORWARDING_DENIED /etc/squid/errors/ERR_FTP_DISABLED /etc/squid/errors/ERR_FTP_FAILURE /etc/squid/errors/ERR_FTP_FORBIDDEN /etc/squid/errors/ERR_FTP_NOT_FOUND /etc/squid/errors/ERR_FTP_PUT_CREATED /etc/squid/errors/ERR_FTP_PUT_ERROR /etc/squid/errors/ERR_FTP_PUT_MODIFIED /etc/squid/errors/ERR_FTP_UNAVAILABLE /etc/squid/errors/ERR_INVALID_REQ /etc/squid/errors/ERR_INVALID_URL /etc/squid/errors/ERR_LIFETIME_EXP /etc/squid/errors/ERR_NO_RELAY /etc/squid/errors/ /etc/squid/errors/ERR_READ_ERROR ERR_ONLY_IF_CACHED_MISS etc/squid/errors/ERR_READ_TIMEOUT /etc/squid/errors/ERR_SHUTTING_DOWN /etc/squid/errors/ERR_SOCKET_FAILURE /etc/squid/errors/ERR_TOO_BIG /etc/squid/errors/ERR_UNSUP_REQ /etc/squid/errors/ERR_URN_RESOLVE /etc/squid/errors/ERR_WRITE_ERROR /etc/squid/errors/ERR_ZERO_SIZE_OBJECT /etc/rc.d/init.d/squid /etc/rc.d/rc0.d/K25squid /etc/rc.d/rc1.d/K25squid /etc/rc.d/rc2.d/K25squid /etc/rc.d/rc3.d/S90squid /etc/rc.d/rc4.d/S90squid /etc/rc.d/rc5.d/S90squid /etc/rc.d/rc6.d/K25squid /etc/logrotate.d/squid /usr/lib/squid /usr/lib/squid/dnsserver /usr/lib/squid/unlinkd /usr/lib/squid/cachemgr.cgi /usr/lib/squid/icons /usr/lib/squid/icons/anthony-binhex.gif /usr/lib/squid/icons/anthony-bomb.gif /usr/lib/squid/icons/anthony-box.gif /usr/lib/squid/icons/anthony-box2.gif /usr/lib/squid/icons/anthony-c.gif /usr/lib/squid/icons/anthony- compressed.gif /usr/lib/squid/icons/anthony-dir.gif /usr/lib/squid/icons/anthony-dirup.gif /usr/lib/squid/icons/anthony-dvi.gif /usr/lib/squid/icons/anthony-f.gif /usr/lib/squid/icons/anthony-image.gif /usr/lib/squid/icons/anthony-image2.gif /usr/lib/squid/icons/anthony-layout.gif /usr/lib/squid/icons/anthony-link.gif /usr/lib/squid/icons/anthony-movie.gif /usr/lib/squid/icons/anthony-pdf.gif /usr/lib/squid/icons/anthony-portal.gif /usr/lib/squid/icons/anthony-ps.gif /usr/lib/squid/icons/anthony-quill.gif /usr/lib/squid/icons/anthony-script.gif /usr/lib/squid/icons/anthony-sound.gif /usr/lib/squid/icons/anthony-tar.gif /usr/lib/squid/icons/anthony-tex.gif /usr/lib/squid/icons/anthony-text.gif /usr/lib/squid/icons/anthony- /usr/lib/squid/icons/anthony-xbm.gif unknown.gif /usr/lib/squid/icons/anthony-xpm.gif /usr/sbin/RunCache /usr/sbin/RunAccel /usr/sbin/squid /usr/sbin/client /var/log/squid Chapter 29. Software -Network Server, web/Apache Table of Contents 1._Linux_MM_Shared_Memory_Library 2._Compile 2.1._Installed_files 3._Linux_Apache_Web_Server 4._Compile_and_Optimize 5._Configure_and_apply_PHP4_to_Apache_source 6._Apply_mod_perl_to_Apache_source_tree 7._Install_Apache 8._Post_install_Configuration 9._Configure_the_/etc/httpd/conf/httpd.conf_file 10._Configure_the_/etc/logrotate.d/apache_file 11._Configure_the_/etc/rc.d/init.d/httpd_script_file 12._PHP4_server-side_scripting 13._Perl_module_Devel::Symdump 13.1._Installed_files 14._CGI.pm_Perl_library 14.1._Installed_files 15._Securing_Apache 16._users_authentication_with_.dbmpasswd_password_file 16.1._Immunize_configuration_files_like_httpd.conf 17._Apache_in_a_chroot_jail 18._Apache_to_use_shared_libraries 19._The_/chroot/etc_directory 20._Test_the_new_chrooted_jail 21._Configure_the_new_/etc/logrotate.d/apache_file 22._Optimizing_Apache 23._Installed_files_for_Apache_Web_Server 24._Installed_files_/PHP4 25._Installed_files_by_mod_perl It is recommended that you compile and install this small program only if you intend to install and use the Apache web server with third party modules like: mod_ssl for encrypted data mod_perl for the Perl programming language mod_php for the PHP server-side scripting language. This program will provide a significant performance to Apache modules. For instance if you need to install Apache with SSL support for your electronic commerce on the Internet, this will allows the SSL protocol to use a high- performance RAM-based session cache instead of a disk-based one. 1. Linux MM Shared Memory Library As per the [MM Shared Memory Library web site]: The MM library is a 2-layer abstraction library, which simplifies the usage of shared memory between forked and, in this example, strongly related processes under Unix platforms. On the first layer it hides all platform dependent implementation details; allocation and locking, when dealing with shared memory segments, and on the second layer it provides a high-level malloc(3)-style API for a convenient and well known way to work with data-structures inside those shared memory segments. The library is released under the term of an open-source, BSD-style license, because it was originally written as a proposal for use inside the next version of the Apache web server as a base library for providing shared memory pools to Apache modules, Currently Apache modules can only use heap-allocated memory, which isn't shared across the pre-forked server processes. The requirement actually comes from comprehensive modules like mod_ssl, mod_perl and mod_php, which would benefit a lot from easy to use shared memory pools. These installation instructions assume * Commands are Unix-compatible. * The source path is /var/tmp, other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * Mm version number is 1.1.2 These are the package(s): MM Homepage:http://www.engelschall.com/sw/mm/ You must be sure to download: mm-1.1.2.tar.gz Before you decompress the tarballs, it is a good idea to make a list of files on the system before you install MM, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > MM1 before and find /* > MM2 after you install the software, and use diff MM1 MM2 > MM-Installed to get a list of what changed. To compile you need to decompress the tarball (tar.gz) first. [root@deep /]# cp mm-version.tar.gz /var/tmp [root@deep /]# cd /var/tmp [root@deep ]/tmp# tar xzpf mm-version.tar.gz 2. Compile Move into the new mm directory and type the following commands on your terminal: ./configure \ --disable-shared \ --prefix=/usr This tells MM to set itself up for this particular hardware setup with: * Disable shared libraries. Now, we must compile and install MM Shared Memory Library in the server: [root@deep ]/mm-1.1.2# make [root@deep ]/mm-1.1.2# make test [root@deep ]/mm-1.1.2# make install The make test command will make some important tests on the program to verify that it works, and respond properly before the installation. Please do Cleanup later: [root@deep /]# cd /var/tmp [root@deep ]/tmp# rm -rf mm-version/ mm-version.tar.gz The rm command will remove all the source files we have used to compile and install mm. It will also remove the mm compressed archive from the /var/tmp directory. Further documentation, for more details there are several man pages you can read: MM(3) Shared Memory Library mm-config(1) MM library configuration/build utility 2.1. Installed files These are the files installed by the program MM on your system. /usr/bin/mm-config /usr/include/mm.h /usr/lib/libmm.la /usr/lib/libmm.a /usr/man/man1/mm-config.1 /usr/man/man3/mm.3 3. Linux Apache Web Server Apache is the most widely used HTTP-server in the world today. It surpasses all free and commercial competitors on the market, and provides a myriad of features; more than the nearest cmpetitor could give you on a UNIX variant. It is also the most used web server for a Linux system. A web server like Apache, in its simplest function, is software that displays and serves HTML pages hosted on a server to a client browser that understands the HTML code. Mixed with third party modules and programs, it can become powerful software, which will provide strong and useful services to a client browser. I expect that most of the users that read this book will be especially interested in knowing how to install the Apache web server in the most secure, and optimized, way. In its base install, Apache is no more difficult to install then the other software we have installed on our Linux server. The process can become tricky when we want to add some third party modules or programs. There are a lot of possibilities, variants and options for installing Apache. we have provided some step-by-step examples where you can see how to build Apache with other third-party modules and programs like mod_ssl, mod_perl, PHP4, LDAP connectivity, etc. Of course, the building of these programs is optional, and you are free to compile only what you want, i.e. you may want to compile Apache with support for PHP4, but without SSL or PostgreSQL database connectivity etc. To simplify matters we assume some prerequisites for each example. If these don't fit your needs, simply modify the steps to suit your needs. In this section, we explain and cover some of the basic ways in which you can adjust the configuration to improve the server's performance. Also, for the interested, we'll provide a procedure to be able to run Apache as a non root- user and in a chrooted environment for optimal security. Apache web server These installation instructions assume * Commands are Unix-compatible. * The source path is /var/tmp, other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * Apache version number is 1.3.12 * Mod_SSL version number is 2.6.4-1.3.12 * Mod_Perl version number is 1.24 * Mod_PHP version number is 4.0.0 Packages Apache Homepage: http://www.apache.org/ Mod_Perl Homepage: http:// perl.apache.org/ Apache FTP Site: 63.211.145.10 Mod_Perl FTP Site: 63.211.145.10 You must be sure to download: You must be sure to download: mod_perl- apache_1.3.12.tar.gz 1.24.tar.gz Mod_SSL Homepage: http:// Mod_PHP Homepage: http://www.php.net/ www.modssl.org/ Mod_SSL FTP Site: 129.132.7.171 You must be sure to download: php- 4.0.0.tar.gz You must be sure to download: mod_ssl-   2.6.4-1.3.12.tar.gz And don't forget that these are the prerequisites if you are following the steps described by us exactly. i. OpenSSL should be already installed on your system if you want Apache and SSL encryption support. ii. PosgreSQL should be already installed on your system if you want Apache and PostgreSQL database connectivity support. iii. MM should be already installed on your system if you want Apache and MM high-performance RAM-based session cache support. iv. OpenLDAP should be already installed on your system if you want Apache and LDAP directory connectivity support. v. IMAP & POP should be already installed on your system if you want Apache and IMAP & POP capability. Tip For more information on the required software, see the related chapter(s) in this book. Before you decompress the tarballs, It is a good idea to make a list of files on the system before you install Apache, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > Apache1 before and find /* > Apache2 after you install the software, and use diff Apache1 Apache2 > Apache-Installed to get a list of what changed. To compile, decompress the tarballs (tar.gz). [root@deep ]/# cp apache_version.tar.gz /var/tmp [root@deep ]/# cp mod_ssl-version-version.tar.gz /var/tmp [root@deep ]/# cp mod_perl-version.tar.gz /var/tmp [root@deep ]/# cp php-version.tar.gz /var/tmp [root@deep ]/# cd /var/tmp/ [root@deep ]/tmp# tar xzpf apache_version.tar.gz [root@deep ]/tmp# tar xzpf mod_ssl-version-version.tar.gz [root@deep ]/tmp# tar xzpf mod_perl-version.tar.gz [root@deep ]/tmp# tar xzpf php-version.tar.gz 4. Compile and Optimize Apache Web Server, like many applications we'll install, cannot run as super- user root. For this reason we must create a special user that has minimal access to the system, and still function enougn to run the Apache web Server. It is best to choose and create a new user just for the purpose of running the web server daemon. 1. [root@deep ]/# useradd -c "Apache Server" -u 80 -s /bin/false -r -d /home/httpd www 2>/dev/null || : 2. You have to apply mod-ssl to Apache source tree, if you want to use and include the SSL data encryption support in your Apache web server, then move into the new mod_ssl source directory cd mod_ssl-version-version/ and type the following commands on your terminal: CC="egcs" \ CFLAGS="-O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions" \ ./configure \ --with-apache=../apache_1.3.12 \ --with-crt=/etc/ssl/certs/server.crt \ --with-key=/etc/ssl/private/server.key o The --with-apache option specifies the location of the Apache source directory, it's important to note that we suppose your Apache version in this example is 1.3.12, o The --with-crt option specifies the location of your existing public key for SSL encryption o The --with-key option specifies the location of your existing private key for SSL encryption. Important OpenSSL software must already be installed on your server, and your public and private keys must already be existent or be created on your server, or you'll receive an error message during the configuration time of mod_ssl. See Software_-Networking/Encryption, in this book, for more information. 3. Improve the MaxClients Parameter of Apache, by default in the Apache configuration file; httpd.conf, the maximum number you can set for the MaxClients Parameter is 256. For a busy site, and for better performance, its recommended that you increase the limit of this parameter. You can do it by editing the src/include/httpd.h file in the source directory of Apache and changing the default value. Move into the new Apache source directory, cd ../apache_1.3.12/ and edit the httpd.h file: #define HARD_SERVER_LIMIT 256 To read: #define HARD_SERVER_LIMIT 1024 4. Pre-configure Apache for PHP4 configure step if you want to use and include the PHP4 server-side scripting language support on your Apache web server, then move into the new Apache source directory cd apache_1.3.12/ if you are not already in it and type the following commands on your terminal: CC="egcs" \ OPTIM="-O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions" \ CFLAGS="-DDYNAMIC_MODULE_LIMIT=0" \ ./configure \ --prefix=/home/httpd \ --bindir=/usr/bin \ --sbindir=/usr/sbin \ --libexecdir=/usr/lib/apache \ --includedir=/usr/include/apache \ --sysconfdir=/etc/httpd/conf \ --localstatedir=/var \ --runtimedir=/var/run \ --logfiledir=/var/log/httpd \ --datadir=/home/httpd \ --proxycachedir=/var/cache/httpd \ --mandir=/usr/man Tip This step is necessary only if you want to include PHP4 support in your Apache source code, since it'll pre-configure Apache for PHP4s configure step below. Take a note that the -DDYNAMIC_MODULE_LIMIT=0 option will disable the use of dynamically loaded modules in our compilation of Apache, and will improve its performance. 5. Configure and apply PHP4 to Apache source Now, move into the new php4 directory cd ../php-4.0 and type the following commands on your terminal: 1. Edit the php_pgsql.h file, vi ext/pgsql/php_pgsql.h and change the lines: #include libpq-fe.h #include libpq/libpq-fs.h To read: #include /usr/include/pgsql/libpq-fe.h #include /usr/include/pgsql/libpq/libpq-fs.h These modifications in the php_pgsql.h file are necessary to indicate the location of our libpq-fe.h, and libpq-fs.h header files of PostgreSQL database during configure of PHP4. In Red Hat Linux, the libraries of PostgreSQL are located under /usr/include/pgsql. 2. Now, we must configure and install PHP4 in the Linux server: CC="egcs" \ CFLAGS="-O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions - I/usr/include/openssl" \ ./configure \ --prefix=/usr \ --with-exec-dir=/usr/bin \ --with-apache=../apache_1.3.12 \ --with-config-file-path=/etc/httpd \ --disable-debug \ --enable-safe-mode \ --with-imap \ 1 --with-ldap \ 2 --with-pgsql \ 3 --with-mm \ --enable-inline-optimization \ --with-gnu-ld \ --enable-memory-limit _1_ If you want IMAP & POP support. _2_ If you want LDAP database light directory support. _3_ if you want PostgreSQL database support. This tells PHP4 to set itself up for this particular hardware setup with: o Compile without debugging symbols. o Enable safe mode by default. o Include IMAP & POP support. o Include LDAP directory support. o Include PostgresSQL database support. o Include mm support to improve performance of Memory Library. o Enable inline-optimization for better performance. o Compile with memory limit support. o Assume the C compiler uses GNU ld. 3. [root@deep ]/php-4.0# make [root@deep ]/php-4.0# make install 6. Apply mod_perl to Apache source tree You need to build/install the Perl-side of mod_perl, if you want to use and include Perl programming language support in your Apache web server. Move into the new mod_perl source directory cd ../mod_perl-1.24/ and type the following commands on your terminal: 1. perl Makefile.PL \ EVERYTHING=1 \ APACHE_SRC=../apache_1.3.12/src \ USE_APACI=1 \ PREP_HTTPD=1 \ DO_HTTPD=1 2. [root@deep ]/mod_perl-1.24# make [root@deep ]/mod_perl-1.24# make install 3. Once you have included in your Apache source the third party modules that you want to support and use, it is time to compile and install it into your Linux system. The last step is to move into the new Apache source directory cd ../apache_1.3.12/ and type the following commands on your terminal depending on what you want to install with Apache for example it could you want to Build/Install Apache with/without mod_ssl +- PHP4 and/or mod_perl etc. SSL_BASE=SYSTEM \ 1 EAPI_MM=SYSTEM \ 2 CC="egcs" \ OPTIM="-O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions" \ CFLAGS="-DDYNAMIC_MODULE_LIMIT=0" \ ./configure \ --prefix=/home/httpd \ --bindir=/usr/bin \ --sbindir=/usr/sbin \ --libexecdir=/usr/lib/apache \ --includedir=/usr/include/apache \ --sysconfdir=/etc/httpd/conf \ --localstatedir=/var \ --runtimedir=/var/run \ --logfiledir=/var/log/httpd \ --datadir=/home/httpd \ --proxycachedir=/var/cache/httpd \ --mandir=/usr/man \ --add-module=src/modules/experimental/mod_mmap_static.c \ 3 --add-module=src/modules/standard/mod_auth_db.c \ 4 --enable-module=ssl \ 5 --enable-rule=SSL_SDBM \ 6 --disable-rule=SSL_COMPAT \ 7 --activate-module=src/modules/php4/libphp4.a \ 8 --enable-module=php4 \ 9 --activate-module=src/modules/perl/libperl.a \ 10 --enable-module=perl \ 11 --disable-module=status \ --disable-module=userdir \ --disable-module=negotiation \ --disable-module=autoindex \ --disable-module=asis \ --disable-module=imap \ --disable-module=env \ --disable-module=actions _1_ require only if you have included support for mod_ssl to your Apache source. _2_ require only if you use the mm Shared Memory Library for Apache. _3_ required only if you have the intention to use mod_mmap, see the section Optimizing_Apache in this chapter for more information. _4_ required only if you have the intention to use mod_auth_db, see the section Securing_Apache in this chapter for more information. _5_ required only if you have included support for mod_ssl data encryption to your Apache source. _6_ _7_ require only if you have included support for mod_ssl data encryption to your Apache source. _8_ _9_ require only if you have included support for PHP4 server-side scripting language to your Apache source. _10_ _11_ require only if you have included support for mod_perl programming language to your Apache source. This tells Apache to set itself up for this particular hardware setup with: * module mod_mmap to improve performance. * module mod_auth_db for users password authentication security. * module mod_ssl for data encryptions and secure communication. * module mod_php4 for php server-side scripting language and improve the load of web pages build in PHP. * module mod_perl for better security and performance than the default cgi scripts. * disable module status * disable module userdir * disable module negotiation * disable module autoindex * disable module asis * disable module imap * disable module env * disable module actions Important It's important to note that removing all unrequired modules during the configure time will improve the performance of your Apache Web Server. In our configuration above, we've removed the most unused modules both to lower the load operation, and limit the security risks in our Apache web server. See your Apache documentation for information on each one. 7. Install Apache Now, we must install Apache in the Linux server: [root@deep ]/apache_1.3.12# make [root@deep ]/apache_1.3.12# make install [root@deep ]/apache_1.3.12# rm -f /usr/sbin/apachectl [root@deep ]/apache_1.3.12# rm -f /usr/man/man8/apachectl.8 [root@deep ]/apache_1.3.12# rm -rf /home/httpd/icons/ [root@deep ]/apache_1.3.12# rm -rf /home/httpd/htdocs/ [root@deep ]/apache_1.3.12# cd /var/tmp/php-4.0 [root@deep ]/php-4.0.0# install -m 644 php.ini.dist /usr/lib/php.ini [root@deep ]/php-4.0.0# rm -rf /etc/httpd/conf/ssl.crl/ [root@deep ]/php-4.0.0# rm -rf /etc/httpd/conf/ssl.crt/ [root@deep ]/php-4.0.0# rm -rf /etc/httpd/conf/ssl.csr/ [root@deep ]/php-4.0.0# rm -rf /etc/httpd/conf/ssl.key/ [root@deep ]/php-4.0.0# rm -rf /etc/httpd/conf/ssl.prm/ [root@deep ]/php-4.0.0# rm -f /etc/httpd/conf/srm.conf srm.conf.default access.conf access.conf.default * The make command will compile all source files into executable binaries * The make install will install the binaries and any supporting files into the appropriate locations. * The rm -f command will remove the small script apachectl responsible to start and stop the Apache daemon since we use a better script named httpd located under the /etc/rc.d/init.d/ directory that takes advantage of Linux system V. * We also remove the /home/httpd/icons directory used under Apache when you use its automatic indexing feature. This feature can bring about a security risk, and for this reason we've disabled it in the configuration file. Therefore, we can safely remove the directory to make space on the Linux server. The / home/httpd/htdocs directory handles all documentation files related to Apache, so after we have finished reading the documentation we can remove it to make space. * The install -m command will install the php.ini.dist file under the /etc/ httpd/ directory, and will rename it php.ini; This file controls many aspects of PHP's behavior. * The ssl.crl, ssl.crt, ssl.csr, ssl.key and ssl.prm directories under /etc/ httpd/conf are all of the directories related to SSL, and handle private and public keys. Since we use another location, /etc/ssl/, we can remove them safely. * Finally, we remove the unused srm.conf, srm.conf.default, access.conf and access.conf.default files, whose purposes are now handled by the httpd.conf Apache file. Please as usual do cleanup later: [root@deep ]/# cd /var/tmp [root@deep ]/tmp# rm -rf apache-version/ apache-version.tar.gz mod_ssl-version-version/ mod_ssl-version-version.tar.gz php-version/ php- version.tar.gz mod_perl-version/ mod_perl-version.tar.gz The rm command will remove all the source files we have used to compile and install Apache, mod_ssl, mod_perl, and php. It will also remove the Apache, mod_ssl, mod_perl, and php compressed archives from the /var/tmp directory. 8. Post install Configuration Configuration files for different services are very specific depending on your needs, and your network architecture. Someone might install Apache Server for showing web pages only; another might install it with database connectivity and e-commerce with SSL support, etc. In this book, we provide you with an httpd.conf file, with PHP, Perl, SSL, LDAP, and password authentication settings, to show you different possibilities. We'll focus on optimization and security of these files, and leave all specific adjustments to your tastes. You will need to read the documentation that comes with these programs, and hopefully understand them. Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example Apache configuration file are organised like this: total 16 -rw-r--r-- 1 harrypotter harrypotter 2417 Jun 8 13:00 Compile-Apache -rw-r--r-- 1 harrypotter harrypotter 3426 Jun 8 13:00 httpd.conf drwxr-xr-x 3 harrypotter harrypotter 4096 Jun 8 13:00 init.d/ drwxr-xr-x 3 harrypotter harrypotter 4096 Jun 8 13:00 logrotate.d/ You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run Apache server, the following files are required and must be created or copied to the appropriate directories on your server. i. Copy the httpd.conf file to the /etc/httpd/conf/ directory. ii. Copy the apache file to the /etc/logrotate.d/ directory. iii. Copy the httpd script file to the /etc/rc.d/init.d/ directory. Tip You can obtain the configuration files listed in the following section on our floppy.tgz archive. Copy the following files from the decompressed floppy.tgz archive to the appropriate places, or copy them directly from this book to the concerned file. 9. Configure the /etc/httpd/conf/httpd.conf file The httpd.conf file is the main configuration file for the Apache web server. A lot options exist, and it's important to read the documentation that comes with Apache for more information on different settings and parameters. The following configuration example is a minimal working configuration file for Apache, with SSL support. Also, it's important to note that we only comment the parameters that relate to security and optimization, and leave all the others to your own research. Edit the httpd.conf file, vi /etc/httpd/conf/httpd.conf and add/change: ### Section 1: Global Environment # ServerType standalone ServerRoot "/etc/httpd" PidFile /var/run/httpd.pid ResourceConfig /dev/null AccessConfig /dev/null Timeout 300 KeepAlive On MaxKeepAliveRequests 0 KeepAliveTimeout 15 MinSpareServers 16 MaxSpareServers 64 StartServers 16 MaxClients 512 MaxRequestsPerChild 100000 ### Section 2: 'Main' server configuration # Port 80 Listen 80 Listen 443 User www Group www ServerAdmin admin@openna.com ServerName www.openna.com DocumentRoot "/home/httpd/ona" Options None AllowOverride None Order deny,allow Deny from all Options None AllowOverride None Order allow,deny Allow from all Options None AllowOverride None Order deny,allow Deny from all DirectoryIndex index.htm index.html index.php index.php3 default.html index.cgi # #Include conf/mmap.conf # UseCanonicalName On TypesConfig /etc/httpd/conf/mime.types DefaultType text/plain HostnameLookups Off ErrorLog /var/log/httpd/error_log LogLevel warn LogFormat "%h %l %u %t \"%r\" %>s %b \"%{Referer}i\" \"%{User- Agent}i\"" combined SetEnvIf Request_URI \.gif$ gif-image CustomLog /var/log/httpd/access_log combined env=!gif-image ServerSignature Off ScriptAlias /cgi-bin/ "/home/httpd/cgi-bin/" AllowOverride None Options None Order allow,deny Allow from all AddEncoding x-compress Z AddEncoding x-gzip gz tgz AddType application/x-tar .tgz ErrorDocument 500 "The server made a boo boo. ErrorDocument 404 http://192.168.1.1/error.htm ErrorDocument 403 "Access Forbidden -- Go away. BrowserMatch "Mozilla/2" nokeepalive BrowserMatch "MSIE 4\.0b2;" nokeepalive downgrade-1.0 force-response- 1.0 BrowserMatch "RealPlayer 4\.0" force-response-1.0 BrowserMatch "Java/1\.0" force-response-1.0 BrowserMatch "JDK/1\.0" force-response-1.0 ### Section 3: Virtual Hosts # AddType application/x-x509-ca-cert .crt AddType application/x-pkcs7-crl .crl SSLPassPhraseDialog builtin SSLSessionCache dbm:/var/run/ssl_scache SSLSessionCacheTimeout 300 SSLMutex file:/var/run/ssl_mutex SSLRandomSeed startup builtin SSLRandomSeed connect builtin SSLLog /var/log/httpd/ssl_engine_log SSLLogLevel warn DocumentRoot "/home/httpd/ona" ServerName www.openna.com ServerAdmin admin@openna.com ErrorLog /var/log/httpd/error_log SSLEngine on SSLCipherSuite ALL:!ADH:RC4+RSA:+HIGH:+MEDIUM:+LOW:+SSLv2:+EXP:+eNULL SSLCertificateFile /etc/ssl/certs/server.crt SSLCertificateKeyFile /etc/ssl/private/server.key SSLCACertificatePath /etc/ssl/certs SSLCACertificateFile /etc/ssl/certs/ca.crt SSLCARevocationPath /etc/ssl/crl SSLVerifyClient none SSLVerifyDepth 10 SSLOptions +ExportCertData +StrictRequire SetEnvIf User-Agent ".*MSIE.*" nokeepalive ssl-unclean-shutdown SetEnvIf Request_URI \.gif$ gif-image CustomLog /var/log/httpd/ssl_request_log \ "%t %h %{SSL_PROTOCOL}x %{SSL_CIPHER}x \"%r\" %b" env=!gif-image This tells httpd.conf file to set itself up for this particular configuration setup with: ServerType standalone The option ServerType specifies how Apache should run on the system. You can run it from the super-server inetd, or as standalone daemon. It's highly recommended to run Apache in standalone type for better performance and speed. ServerRoot "/etc/httpd" The option ServerRoot specifies the directory in which the configuration files of the Apache server lives. It allows Apache to know where it can find its configuration files when it starts. PidFile /var/run/httpd.pid The option PidFile specifies the location where the server will record the process id of the daemon when it starts. This option is only required when you configure Apache in standalone mode. ResourceConfig /dev/null The option ResourceConfig specifies the location of the old srm.conf file that Apache read after it finished reading the httpd.conf file. When you set the location to /dev/null, Apache allows you to include the content of this file in httpd.conf file, and in this manner, you have just one file that handles all your configuration parameters for simplicity. AccessConfig /dev/null The option AccessConfig specifies the location of the old access.conf file that Apache read after it finished reading the srm.conf file. When you set the location to /dev/null, Apache allows you to include the content of this file in httpd.conf file, and in this manner, you have just one file that handles all your configuration parameters for simplicity. Timeout 300 The option Timeout specifies the amount of time Apache will wait for a GET, POST, PUT request and ACKs on transmissions. You can safely leave this option on its default values. KeepAlive On The option KeepAlive, if set to On, specifies enabling persistent connections on this web server. For better performance, it's recommended to set this option to On, and allow more than one request per connection. MaxKeepAliveRequests 0 The option MaxKeepAliveRequests specifies the number of requests allowed per connection when the KeepAlive option above is set to On. When the value of this option is set to 0 then unlimited requests are allowed on the server. For server performance, it's recommended to allow unlimited requests. KeepAliveTimeout 15 The option KeepAliveTimeout specifies how much time, in seconds, Apache will wait for a subsequent request before closing the connection. The value of 15 seconds is a good average for server performance. MinSpareServers 16 The option MinSpareServers specifies the minimum number of idle child server processes for Apache, which is not handling a request. This is an important tuning parameter regarding the performance of the Apache web server. For high load operation, a value of 16 is recommended by various benchmarks on the Internet. MaxSpareServers 64 The option MaxSpareServers specifies the maximum number of idle child server processes for Apache, which is not handling a request. This is also an important tuning parameter regarding the performance of the Apache web server. For high load operation, a value of 64 is recommended by various benchmarks on the Internet. StartServers 16 The option StartServers specifies the number of child server processes that will be created by Apache on start-up. This is, again, an important tuning parameter regarding the performance of the Apache web server. For high load operation, a value of 16 is recommended by various benchmarks on the Internet. MaxClients 512 The option MaxClients specifies the number of simultaneous requests that can be supported by Apache. This too is an important tuning parameter regarding the performance of the Apache web server. For high load operation, a value of 512 is recommended by various benchmarks on the Internet. MaxRequestsPerChild 100000 The option MaxRequestsPerChild specifies the number of requests that an individual child server process will handle. This too is an important tuning parameter regarding the performance of the Apache web server. User www The option User specifies the UID that Apache server will run as. It's important to create a new user that has minimal access to the system, and functions just for the purpose of running the web server daemon. Group www The option Group specifies the GID the Apache server will run as. It's important to create a new group that has minimal access to the system and functions just for the purpose of running the web server daemon. DirectoryIndex index.htm index.html index.php index.php3 default.html index.cgi The option DirectoryIndex specifies the files to use by Apache as a pre- written HTML directory index. In other words, if Apache can't find the default index page to display, it'll try the next entry in this parameter, if available. To improve performance of your web server it's recommended to list the most used default index pages of your web site first. Include conf/mmap.conf The option Include specifies the location of other files that you can include from within the server configuration files httpd.conf. In our case, we include the mmap.conf file located under /etc/httpd/conf directory. This file mmap.conf maps files into memory for faster serving. See the section on Optimizing_Apache for more information. HostnameLookups Off The option HostnameLookups, if set to Off, specifies the disabling of DNS lookups. It's recommended to set this option to Off in order to save the network traffic time, and to improve the performance of your Apache web server. 10. Configure the /etc/logrotate.d/apache file Configure your /etc/logrotate.d/apache file to rotate each week your Apache log files automatically. Create the apache file, touch /etc/logrotate.d/apache and add: /var/log/httpd/access_log { missingok postrotate /usr/bin/killall -HUP httpd endscript } /var/log/httpd/error_log { missingok postrotate /usr/bin/killall -HUP httpd endscript } /var/log/httpd/ssl_request_log { missingok postrotate /usr/bin/killall -HUP httpd endscript } /var/log/httpd/ssl_engine_log { missingok postrotate /usr/bin/killall -HUP httpd endscript } CAution Lines to automatically rotate the SSL log files named ssl_request_log and ssl_engine_log are included in this file. If you intend to run Apache without SSL support, you must remove the lines related to SSL. 11. Configure the /etc/rc.d/init.d/httpd script file Configure your /etc/rc.d/init.d/httpd script file to start and stop Apache Web Server. Create the httpd script file, touch /etc/rc.d/init.d/httpd and add: #!/bin/sh # # Startup script for the Apache Web Server # # chkconfig: 345 85 15 # description: Apache is a World Wide Web server. It is used to serve \ # HTML files and CGI. # processname: httpd # pidfile: /var/run/httpd.pid # config: /etc/httpd/conf/httpd.conf # Source function library. . /etc/rc.d/init.d/functions # See how we were called. case "$1" in start) echo -n "Starting httpd: " daemon httpd -DSSL echo touch /var/lock/subsys/httpd ;; stop) echo -n "Shutting down http: " killproc httpd echo rm -f /var/lock/subsys/httpd rm -f /var/run/httpd.pid ;; status) status httpd ;; restart) $0 stop $0 start ;; reload) echo -n "Reloading httpd: " killproc httpd -HUP echo ;; *) echo "Usage: $0 {start|stop|restart|reload|status}" exit 1 esac exit 0 Now, make this script executable and change its default permissions: [root@deep ]/# chmod 700 /etc/rc.d/init.d/httpd Create the symbolic rc.d links for Apache with the command: [root@deep ]/# chkconfig --add httpd Start your new Apache server manually with the following command: [root@deep ]/# /etc/rc.d/init.d/httpd start Starting httpd: [ OK ] The -DSSL option will start Apache in SSL mode. If you want to start Apache in regular mode, remove the -DSSL option near the line that reads daemon httpd. 12. PHP4 server-side scripting If you intend to use PHP4 server-side scripting language support with your Apache web server don't forget to include in your /etc/httpd/conf/httpd.conf file the following lines to enable this feature: 1. Edit the httpd.conf file, vi /etc/httpd/conf/httpd.conf, and add the following lines between the section tags and : AddType application/x-httpd-php .php AddType application/x-httpd-php .php3 AddType application/x-httpd-php-source .phps 2. You must restart the Apache web server for the changes to take effect, using the following commands: [root@deep ]/# /etc/rc.d/init.d/httpd restart Shutting down http: [ OK ] Starting httpd: [ OK ] 3. Once the above lines have been included in our httpd.conf file, we must test the new PHP4 feature to be sure it's working. We'll create a small PHP file named php.php in our DocumentRoot, and then point our web broswer to this PHP document to see if PHP4 work on the server. Create the php.php file in your DocumentRoot, touch /home/httpd/ona/php.php and add the following lines in the PHP file: These lines will inform PHP4 program to display various pieces of information about the configuration of our Linux server. 4. Now, point your web browser to the following address:http://my-web-server/ php.php The is the address where your Apache web server resides, and is the PHP document we have created above to display the information and configuration of our Linux server. PHP info If you see something like the above page appearing in your web browser congratulations! Your PHP module is working. 13. Perl module Devel::Symdump If you intend to use the mod_perl programming language support with your Apache web server, it can be interesting to install the small perl module program named Devel::Symdump. This third party module will allow you to inspect perl's symbol table and the class hierarchies within a running program. To build and install it, follow these steps. These are the package(s) Devel-Symdump Homepage:http://www.perl.com/CPAN/modules/by-module/Devel/ You must be sure to download: Devel-Symdump-2_00_tar.gz Devel-Symdump version number is 2.00 [root@deep ]/# cp Devel-Symdump-version.tar.gz /var/tmp/ [root@deep ]/# cd /var/tmp/ [root@deep ]/tmp# tar xzpf Devel-Symdump-version.tar.gz Move into the new Devel-Symdump directory and type the following commands on your terminal to compile and install the module on your Linux server: [root@deep ]/Devel-Symdump-2.00# perl Makefile.PL [root@deep ]/Devel-Symdump-2.00# make [root@deep ]/Devel-Symdump-2.00# make test [root@deep ]/Devel-Symdump-2.00# make install Once the module has been installed on your system, you must include in your / etc/httpd/conf/httpd.conf file the following lines to be able to see the status of different Perl modules on the server: Edit the httpd.conf file, vi /etc/ httpd/conf/httpd.conf and add the following lines: 1. SetHandler perl-script PerlHandler Apache::Status Order deny,allow Deny from all Allow from 192.168.1.0/24 2. You must restart the Apache web server for the changes to take effect: To restart Apache, use the following commands: [root@deep ]/# /etc/rc.d/init.d/httpd restart Shutting down http: [ OK ] Starting httpd: [ OK ] 3. Finally, we must test the new Devel-Symdump module to be sure that we can see status of different Perl modules on the server. To verify that it works, points your web browser to the following address: http://my-web-server/perl-status/. The is the address where your Apache web server resides. Mod perl Please as always Cleanup : [root@deep ]/# cd /var/tmp [root@deep ]/tmp# rm -rf Devel-Symdump.version/ Devel-Symdump- version.tar.gz 13.1. Installed files /usr/lib/perl5/man/man3/Devel::Symdump.3 /usr/lib/perl5/site_perl/5.005/i386-linux/auto/Devel /usr/lib/perl5/site_perl/5.005/i386-linux/auto/Devel/Symdump /usr/lib/perl5/site_perl/5.005/i386-linux/auto/Devel/Symdump/.packlist /usr/lib/perl5/site_perl/5.005/Devel /usr/lib/perl5/site_perl/5.005/Devel/Symdump /usr/lib/perl5/site_perl/5.005/Devel/Symdump/Export.pm /usr/lib/perl5/site_perl/5.005/Devel/Symdump.pm 14. CGI.pm Perl library The CGI.pm is a Perl5 library for writing World Wide Web CGI scripts. Older versions of this software exist by default on your system, but they are buggy. It's recommended that you update your copy to version 2.56, at least. To update this module, please follow these steps. These are the package(s) CGI.pm Homepage: http://stein.cshl.org/WWW/software/CGI/cgi_docs.html You must be sure to download: CGI_pm_tar.gz CGI.pm version number is 2.56 [root@deep ]/# cp CGI_pm_tar.gz /var/tmp/ [root@deep ]/# cd /var/tmp/ [root@deep ]/tmp# tar xzpf CGI_pm_tar.gz First of all, well check the version of CGI.pm installed in our system with the following command: [root@deep ]/# perl -e 'use CGI; print $CGI::VERSION."\n";' 2.46 Move into the new CGI.pm directory and type the following commands on your terminal to compile and install the updated libraries on your Linux server: [root@deep ]/CGI.pm-2.56# perl Makefile.PL [root@deep ]/CGI.pm-2.56# make [root@deep ]/CGI.pm-2.56# make test [root@deep ]/CGI.pm-2.56# make install Please do cleanup later: [root@deep ]/# cd /var/tmp [root@deep ]/tmp# rm -rf CGI.pm-version/ CGI_pm_tar.gz 14.1. Installed files /usr/lib/perl5/5.00503/CGI/Pretty.pm /usr/lib/perl5/5.00503/i386-linux/auto/CGI /usr/lib/perl5/5.00503/i386-linux/auto/CGI/.packlist /usr/lib/perl5/man/man3/CGI::Pretty.3 15. Securing Apache Change some important permissions on files and directories for your Web Server. When you install Apache on your server, there are some files and directories that have too many permissions set by default. The binary program httpd can be set to be read-only by the super-user root, and executable by the owner, group, and others for better security. The /etc/httpd/conf and /var/log/httpd directories don't need to by readable, writable or executable by other people. [root@deep ]/# chmod 511 /usr/sbin/httpd [root@deep ]/# chmod 750 /etc/httpd/conf/ [root@deep ]/# chmod 750 /var/log/httpd/ If you have enabled the automatic indexing of directories in your Apache configuration file; IndexOptions in httpd.conf, then you'll have a security issue since any requests for a directory that don't find an index file will build an index of what is in the directory. In many cases, you may only want people seeing files that you specifically link to. To turn this off, you need to remove read permissions from the DocumentRoot directory but not the files inside it. [root@deep ]/# cd /home/httpd/ [root@deep ]/httpd# chmod 311 ona [root@deep ]/httpd# ls -la d-wx--x--x 13 webadmin webadmin 1024 Jul 28 08:12 ona Now, with this modification, any requests for this protected directory should return an error message like: Forbidden You don't have permission to access /ona/ on this server. Tip ona is the DocumentRoot, the directory out of which you will serve your documents, in our example. 16. users authentication with .dbmpasswd password file This step is necessary only if you think that you'll use an access file authentication system for your web site. Access file authentication is used when you have the need to protect some part of your web site with a user password. With Apache, a lot of options exist to protect your site with usernames and passwords. 1. The dbmmanage program utility of Apache can be used to create and update usernames and passwords of HTTP users. This method use a DBM format files that is the fastest mechanism when you have thousands users to manage in your password file. First of all, it's important to change the permission of this program to be 0750/-rwxr-x---, writable only by the super-user root, readable and executable by group and nothing for the others. a. To change the permissions on the dbmmanage program, use the following command: [root@deep ]/# chmod 750 /usr/bin/dbmmanage b. To create a username and password, use the following command: [root@deep ]/# /usr/bin/dbmmanage /etc/ httpd/.dbmpasswd adduser username New password: Re-type new password: User username added with password encrypted to l4jrdAL9MH0K. Where is the location of the password file, <.dbmpasswd> is the name of the password file, and is the name of the user you want to add in your .dbmpasswd file. 2. If you use the dbmmanage utility with your Apache web server to create passwords and usernames, don't forget to include in your /etc/httpd/conf/ httpd.conf configuration file the part of your web site you need to protect with user password authentication: Edit the httpd.conf file vi / etc/httpd/conf/httpd.conf and add the following lines to protect the private directory of your web site ona with user password authentication: Options None AllowOverride AuthConfig AuthName "restricted stuff" AuthType Basic AuthDBUserFile /etc/httpd/.dbmpasswd require valid-user The path specifies the directory we want to protect with a password and username, the specifies the location of the password file. To add the DB password authentication module to your Apache Web Server, you must be sure to include it during the configuration time of Apache with the following parameter --add-module=src/modules/standard/mod_auth_db.c. See your Apache documentation for more information. 3. You must restart Apache web server for the changes to take effect: To restart Apache, use the following commands: [root@deep ]/# /etc/rc.d/init.d/httpd restart Shutting down http: [ OK ] Starting httpd: [ OK ] 4. Finally, we must test the new protected directory named private. To verify that it works, point your web browser to the following address: http://my- web-server/private/. The is the address where your Apache web server lives. The is the directory we want to protect with user password authentication. Apache password 16.1. Immunize configuration files like httpd.conf As we already know, the immutable bit can be used to prevent deletion, overwriting or creation of a symbolic link to a file. Once your httpd.conf file has been configured, it's a good idea to immunize it with the following command: [root@deep ]/# chattr +i /etc/httpd/conf/httpd.conf 17. Apache in a chroot jail This part focuses on preventing Apache from being used as a point of break-in to the system hosting it. Apache by default runs as a non-root user, which will limit any damage to what can be done as a normal user with a local shell. Of course, allowing what amounts to an anonymous guest account falls rather short of the security requirements for most Apache servers, so an additional step can be taken - that is, running Apache in a chroot jail. The main benefit of a chroot jail is that the jail will limit the portion of the file system the daemon can see to the root directory of the jail. Additionally, since the jail only needs to support Apache, the programs available in the jail can be extremely limited. Most importantly, there is no need for setuid-root programs, which can be used to gain root access and break out of the jail. Proxy Netscape Configuration Chrooting apache is no easy task and has a tendency to break things. Before we embark on this, we need to first decide whether it is beneficial for you to do so. Some pros and cons are there, but most certainly not limited to, the following: Pros and Cons i. If apache is ever compromised, the attacker will not have access to the entire file system. ii. Poorly written CGI scripts that may allow someone to access your server will not work. i. There are extra libraries you'll need to have in the chroot jail for Apache to work. ii. If you use any Perl/CGI features with Apache, you will need to copy the needed binaries, Perl libraries and files to the appropriate spot within the chroot space. The same applies for SSL, PHP, LDAP, PostgresSQL and other third-party programs. The chrooted configuration listed below supposes that you've compiled your Apache server with the external program mod_ssl. The differences in what you've compiled with your Apache web server reside in which libraries and binaries you'll need to copy to the chrooted directory. Important Remember that if you've compiled Apache to use mod_perl, you must copy all the related binaries and Perl libraries to the chrooted directory. Perl resides in /usr/lib/perl5 and in case you use Perl features, copy the Perl directories to /chroot/httpd/usr/lib/perl5/. Don't forget to create the directory /chroot/ httpd/usr/lib/perl5 in your chrooted structure before copying. The following are the necessary steps to run Apache Web Server in a chroot jail: We must find the shared library dependencies of httpd. These will need to be copied into the chroot jail later. To find the shared library dependencies of httpd, execute the following command: [root@deep ]/# ldd /usr/sbin/httpd libpam.so.0 =>/lib/libpam.so.0 (0x40016000) libm.so.6 =>/lib/libm.so.6 (0x4001f000) libdl.so.2 =>/lib/libdl.so.2 (0x4003b000) libcrypt.so.1 =>/lib/libcrypt.so.1 (0x4003e000) libnsl.so.1 =>/lib/libnsl.so.1 (0x4006b000) libresolv.so.2 =>/lib/libresolv.so.2 (0x40081000) libdb.so.3 =>/lib/libdb.so.3 (0x40090000) libc.so.6 =>/lib/libc.so.6 (0x400cb000) /lib/ld-linux.so.2 =>/lib/ld-linux.so.2 (0x40000000) Make a note of the files listed above, you will need these later in our steps. Add a new UID and a new GID if this is not already done for running Apache httpd. This is important because running it as root defeats the purpose of the jail, and using a different UID that already exists on the system i.e. nobody can allow your services to access each others' resources. Consider the scenario where a web server is running as nobody, or any other overly used UID/GID and compromised. The cracker can now access any other processes running as nobody from within the chroot. 1. These are sample UID/GIDs. Check the /etc/passwd and /etc/group files for a free UID/GID number. In our configuration we'll use the numeric value 80 and UID/GID www. [root@deep ]/# useradd -c "Apache Server" -u 80 -s /bin/ false -r -d /home/httpd www 2>/dev/null || : The above commands will create the group www with the numerical GID value 80, and the user www with the numerical UID value 80. 2. Set up the chroot environment. First we need to create the chrooted Apache structure. We use /chroot/httpd for the chrooted Apache. The /chroot/httpd is just a directory on a different partition where we've decided to put apache for more security. [root@deep ]/# /etc/rc.d/init.d/httpd stop 1 _1_ Only if Apache is already installed and run on your system. Shutting down http: [ OK ] [root@deep ]/# mkdir /chroot/httpd 3. Next, create the rest of directories as follows: [root@deep ]/# mkdir /chroot/httpd/dev [root@deep ]/# mkdir /chroot/httpd/lib [root@deep ]/# mkdir /chroot/httpd/etc [root@deep ]/# mkdir -p /chroot/httpd/usr/sbin [root@deep ]/# mkdir -p /chroot/httpd/var/run [root@deep ]/# mkdir -p /chroot/httpd/var/log/httpd [root@deep ]/# chmod 750 /chroot/httpd/var/log/httpd/ [root@deep ]/# mkdir -p /chroot/httpd/home/httpd 4. Copy the main configuration directory, the configuration files, the cgi- bin directory, the root directory and the httpd program to the chroot jail: [root@deep ]/# cp -r /etc/httpd /chroot/httpd/etc/ [root@deep ]/# cp -r /home/httpd/cgi-bin /chroot/httpd/home/httpd/ [root@deep ]/# cp -r / home/httpd/your-DocumentRoot /chroot/httpd/home/httpd/ [root@deep ]/ # mknod /chroot/httpd/dev/null c 1 3 [root@deep ]/# chmod 666 /chroot/ httpd/dev/null [root@deep ]/# cp /usr/sbin/httpd /chroot/httpd/usr/sbin/ We need the /chroot/httpd/etc, /chroot/httpd/dev, /chroot/httpd/lib, / chroot/httpd/usr/sbin /chroot/httpd/var/run, /chroot/httpd/home/httpd and /chroot/httpd/var/log/httpd directories because, from the point of the chroot, we're sitting at /. 5. If you have compiled your Apache web server with SSL support, you must copy the entire /etc/ssl directory that handles all private and public keys to the chroot jail. [root@deep ]/# cp -r /etc/ssl /chroot/httpd/etc/ ß require only if you use mod_ssl feature. [root@deep ]/# chmod 600 /chroot/httpd/etc/ssl/certs/ca.crt ß require only if you use mod_ssl feature. [root@deep ]/# chmod 600 /chroot/httpd//etc/ssl/certs/ server.crt ß require only if you use mod_ssl feature. [root@deep ]/# chmod 600 /chroot/httpd/etc/ssl/private/ ca.key ß require only if you use mod_ssl feature. [root@deep ]/# chmod 600 /chroot/httpd/etc/ssl/private/ server.key ß require only if you use mod_ssl feature. 18. Apache to use shared libraries Since we have compiled apache to use shared libraries, we need to install them into the chroot directory structure. Use ldd /chroot/httpd/usr/sbin/httpd to find out which libraries are needed. The output, depending on what you've compiled with Apache will be something similar to: libpam.so.0 =>/lib/libpam.so.0 (0x40016000) libm.so.6 =>/lib/libm.so.6 (0x4001f000) libdl.so.2 =>/lib/libdl.so.2 (0x4003b000) libcrypt.so.1 =>/lib/libcrypt.so.1 (0x4003e000) libnsl.so.1 =>/lib/libnsl.so.1 (0x4006b000) libresolv.so.2 =>/lib/libresolv.so.2 (0x40081000) libdb.so.3 =>/lib/libdb.so.3 (0x40090000) libc.so.6 =>/lib/libc.so.6 (0x400cb000) /lib/ld-linux.so.2 =>/lib/ld-linux.so.2 (0x40000000) Copy the shared libraries identified above: [root@deep ]/# cp /lib/libpam.so.0 /chroot/httpd/lib/ [root@deep ]/# cp /lib/libm.so.6 /chroot/httpd/lib/ [root@deep ]/# cp /lib/libdl.so.2 /chroot/httpd/lib/ [root@deep ]/# cp /lib/libcrypt.so.1 /chroot/httpd/lib/ [root@deep ]/# cp /lib/libnsl* /chroot/httpd/lib/ [root@deep ]/# cp /lib/libresolv* /chroot/httpd/lib/ [root@deep ]/# cp /lib/libdb.so.3 /chroot/httpd/lib/ [root@deep ]/# cp /lib/libc.so.6 /chroot/httpd/lib/ [root@deep ]/# cp /lib/ld-linux.so.2 /chroot/httpd/lib/ You'll also need the following extra libraries for some network functions, like resolving: [root@deep ]/# cp /lib/libnss_compat* /chroot/httpd/lib/ [root@deep ]/# cp /lib/libnss_dns* /chroot/httpd/lib/ [root@deep ]/# cp /lib/libnss_files* /chroot/httpd/lib/ * We now need to copy the passwd and group files inside the /chroot/httpd/etc chrooted directory. The concept here is the same as how ftpd uses passwd and group files. Next, we'll remove all entries except for the user that apache runs as in both files passwd and group. a. [root@deep ]/# cp /etc/passwd /chroot/httpd/etc/ [root@deep ]/# cp /etc/group /chroot/httpd/etc/ b. Edit the passwd file, vi /chroot/httpd/etc/passwd and delete all entries except for the user apache run as in our configuration, it's www: www:x:80:80::/home/www:/bin/bash c. Edit the group file, vi /chroot/httpd/etc/group and delete all entries except the group apache run as, in our configuration it,s www: www:x:80: 19. The /chroot/etc directory You will also need /etc/resolv.conf, /etc/nsswitch.conf and /etc/hosts files in your chroot jail. [root@deep ]/# cp /etc/resolv.conf /chroot/httpd/etc/ [root@deep ]/# cp /etc/hosts /chroot/httpd/etc/ [root@deep ]/# cp /etc/ nsswitch.conf /chroot/httpd/etc/ 1. Now we must set some files in the chroot jail directory immutable for better security. a. Set the immutable bit on passwd file: [root@deep ]/# cd /chroot/httpd/etc/ [root@deep ]/# chattr +i passwd b. Set the immutable bit on group file: [root@deep ]/# cd /chroot/httpd/etc/ [root@deep ]/# chattr +i group c. Set the immutable bit on httpd.conf file: [root@deep ]/# cd /chroot/httpd/etc/httpd/conf/ [root@deep ]/# chattr +i httpd.conf d. Set the immutable bit on resolv.conf file: [root@deep ]/# cd /chroot/httpd/etc/ [root@deep ]/# chattr +i resolv.conf e. Set the immutable bit on hosts file: [root@deep ]/# cd /chroot/httpd/etc/ [root@deep ]/# chattr +i hosts Set the immutable bit on nsswitch.conf file: [root@deep ]/# cd /chroot/httpd/etc/ [root@deep ]/# chattr +i nsswitch.conf 2. Copy the localtime file to the jail so that log entries are adjusted for your local timezone properly: [root@deep ]/# cp /etc/localtime /chroot/httpd/etc/ 3. Remove unnecessary Apache files and directories: [root@deep ]/# rm -rf /var/log/httpd/ [root@deep ]/# rm -rf /etc/httpd/ [root@deep ]/# rm -rf /home/httpd/ [root@deep ]/# rm -f /usr/sbin/httpd We can remove safely all of the above files and directories since they are now located under our chroot jail directory. 4. Normally, processes talk to syslogd through /dev/log. As a result of the chroot jail, this won't be possible, so syslogd needs to be told to listen to /chroot/httpd/dev/log. To do this, edit the syslog startup script, vi / etc/rc.d/init.d/syslog to specify additional places to listen. daemon syslogd -m 0 To read: daemon syslogd -m 0 -a /chroot/httpd/dev/log 5. The default httpd script file of Apache starts the daemon httpd outside the chroot jail. We must change it to now start httpd from the chroot jail. a. Edit the httpd script file, vi /etc/rc.d/init.d/httpd and change the line: daemon httpd To read: /usr/sbin/chroot /chroot/httpd/ /usr/sbin/httpd -DSSL b. rm -f /var/run/httpd.pid To read: rm -f /chroot/httpd/var/run/httpd.pid 20. Test the new chrooted jail Finally, we must test the new chrooted jail configuration of our Apache Web Server. The first thing to do is to restart our syslogd daemon with the following command: [root@deep ]/# /etc/rc.d/init.d/syslog restart Shutting down kernel logger: [ OK ] Shutting down system logger: [ OK ] Starting system logger: [ OK ] Starting kernel logger: [ OK ] Now, start the new chrooted jail Apache with the following command: [root@deep ]/# /etc/rc.d/init.d/httpd start Starting httpd: [ OK ] If you don't get any errors, do a ps ax | grep httpd and see if we're running: [root@deep ]/# ps ax | grep httpd 14373 ? S 0:00 httpd -DSSL 14376 ? S 0:00 httpd -DSSL 14377 ? S 0:00 httpd -DSSL 14378 ? S 0:00 httpd -DSSL 14379 ? S 0:00 httpd -DSSL 14380 ? S 0:00 httpd -DSSL 14381 ? S 0:00 httpd -DSSL 14382 ? S 0:00 httpd -DSSL 14383 ? S 0:00 httpd -DSSL 14384 ? S 0:00 httpd -DSSL 14385 ? S 0:00 httpd -DSSL 14386 ? S 0:00 httpd -DSSL 14387 ? S 0:00 httpd -DSSL 14388 ? S 0:00 httpd -DSSL 14389 ? S 0:00 httpd -DSSL 14390 ? S 0:00 httpd -DSSL 14391 ? S 0:00 httpd -DSSL 14397 ? S 0:00 httpd -DSSL 14476 ? S 0:00 httpd -DSSL 14477 ? S 0:00 httpd -DSSL 14478 ? S 0:00 httpd -DSSL If so, lets check to make sure it's chrooted by picking out one of its process numbers and doing ls -la /proc/that_process_number/root/. [root@deep ]/# ls -la /proc/14373/root/ If you see: dev etc home lib usr var congratulations! As mentioned above, if you use Perl, you'll need to copy or hardlink any system libraries, perl libraries /usr/lib/perl5, and binaries into the chroot area. The same applies for SSL, PHP, LDAP, PostgreSQL and other programs. 21. Configure the new /etc/logrotate.d/apache file Now Apache logs files residing in the /chroot/var/log/httpd directory instead of /var/log/httpd and for this reason we need to modify the /etc/logrotate.d/ httpd file to point to the new chrooted directory. Also, we've compiled Apache with mod_ssl, so we'll add one more line to permit the logrotate program to rotate the ssl_request_log and ssl_engine_log files. Configure your /etc/ logrotate.d/apache file to rotate your log files each week automatically. Create the apache file, touch /etc/logrotate.d/apache and add: /chroot/httpd/var/log/httpd/access_log { missingok postrotate /usr/bin/killall -HUP /chroot/httpd/usr/sbin/httpd endscript } /chroot/httpd/var/log/httpd/error_log { missingok postrotate /usr/bin/killall -HUP /chroot/httpd/usr/sbin/httpd endscript } /chroot/httpd/var/log/httpd/ssl_request_log { missingok postrotate /usr/bin/killall -HUP /chroot/httpd/usr/sbin/httpd endscript } /chroot/httpd/var/log/httpd/ssl_engine_log { missingok postrotate /usr/bin/killall -HUP /chroot/httpd/usr/sbin/httpd endscript } 22. Optimizing Apache The mod_mmap_static module of Apache, is a special module with the Apache distribution named mod_mmap_static that can be used to improve the performance of your Web Server. This module works by providing mappings of a statically configured list of frequently requested, but not changed, files in your RootDirectory. So, if files displayed by Apache don't change often, you can use this module to memory-map the static documents and increase the speed of your Apache web server. It's important to note that the mod_mmap_static module of Apache must be enabled during the configuration and compilation time of Apache before you can use it. If you have followed our steps described in the configuration and compilation time section above, this is already in Apache --add-module-../ mod_mmap_static.c. 1. To memory-map static documents, use the following command: [root@deep ]/# find /home/httpd/ona -type f -print | sed - e 's/.*/mmapfile &/' /etc/httpd/conf/mmap.conf The /home/httpd/ona is the RootDirectory, or to be more precise, the directory out of which you will serve your documents, and the /etc/httpd/ conf/mmap.conf is the location where we want to create this file, mmap.conf, that contains a static memory-map of all documents under our RootDirectory. 2. Once the mmap.conf file has been created under the location where we have chosen to keep this file, we must include it in the httpd.conf file of Apache to be able to use its features on our web server. Edit the httpd.conf file, vi /etc/httpd/conf/httpd.conf and add the line: Include conf/mmap.conf Proxy Netscape Configuration See your Apache documentation for more information about the use of mod_mmap_static. Remember that this feature must be only used when you serve documents that don't change often on your web site. You must restart the Apache web server for the changes to take effect: [root@deep ]/# /etc/rc.d/init.d/httpd restart Shutting down http: [ OK ] Starting httpd: [ OK ] The atime and noatime attributes Tip The atime and noatime attributes of Linux can be used to get measurable performance gains in Apache. See in this book, General_System_Optimization, for more information on the subject. 23. Installed files for Apache Web Server These are the files installed by the software program Apache on your server. /etc/rc.d/init.d/httpd /etc/rc.d/rc0.d/K15httpd /etc/rc.d/rc1.d/K15httpd /etc/rc.d/rc2.d/K15httpd /etc/rc.d/rc3.d/S85httpd /etc/rc.d/rc4.d/S85httpd /etc/rc.d/rc5.d/S85httpd /etc/rc.d/rc6.d/K15httpd /etc/logrotate.d/apache /etc/httpd /etc/httpd/conf /etc/httpd/conf/ httpd.conf.default /etc/httpd/conf/ /etc/httpd/conf/ /etc/httpd/conf/mime.types httpd.conf mime.types.default /etc/httpd/conf/ /etc/httpd/conf/magic /etc/httpd/php.ini magic.default /home/httpd /home/httpd/cgi-bin /home/httpd/cgi-bin/ printenv /home/httpd/cgi-bin/test- /usr/bin/htpasswd /usr/bin/htdigest cgi /usr/bin/dbmmanage /usr/include/apache /usr/include/apache/xml /usr/include/apache/xml/ /usr/include/apache/xml/ /usr/include/apache/xml/ asciitab.h hashtable.h iasciitab.h /usr/include/apache/xml/ /usr/include/apache/xml/ /usr/include/apache/xml/ latin1tab.h nametab.h utf8tab.h /usr/include/apache/xml/ /usr/include/apache/xml/ /usr/include/apache/xml/ xmldef.h xmlparse.h xmlrole.h /usr/include/apache/xml/ /usr/include/apache/xml/ /usr/include/apache/ xmltok.h xmltok_impl.h alloc.h /usr/include/apache/ap.h /usr/include/apache/ /usr/include/apache/ ap_compat.h ap_config.h /usr/include/apache/ /usr/include/apache/ /usr/include/apache/ ap_config_auto.h ap_ctx.h ap_ctype.h /usr/include/apache/ /usr/include/apache/ /usr/include/apache/ ap_hook.h ap_md5.h ap_mm.h /usr/include/apache/ /usr/include/apache/ /usr/include/apache/buff.h ap_mmn.h ap_sha1.h /usr/include/apache/ /usr/include/apache/conf.h /usr/include/apache/ compat.h explain.h /usr/include/apache/ /usr/include/apache/ /usr/include/apache/ fnmatch.h hsregex.h http_conf_globals.h /usr/include/apache/ /usr/include/apache/ /usr/include/apache/ http_config.h http_core.h http_log.h /usr/include/apache/ /usr/include/apache/ /usr/include/apache/ http_main.h http_protocol.h http_request.h /usr/include/apache/ /usr/include/apache/ /usr/include/apache/ http_vhost.h httpd.h multithread.h /usr/include/apache/ /usr/include/apache/ /usr/include/apache/ rfc1413.h scoreboard.h util_date.h /usr/include/apache/ /usr/include/apache/ /usr/include/apache/ util_md5.h util_script.h util_uri.h /usr/include/apache/os.h /usr/include/apache/os- /usr/lib/apache inline.c /usr/man/man1/htpasswd.1 /usr/man/man1/htdigest.1 /usr/man/man1/dbmmanage.1 /usr/man/man8/ab.8 /usr/man/man8/httpd.8 /usr/man/man8/logresolve.8 /usr/man/man8/ /usr/man/man8/apxs.8 /usr/sbin/httpd rotatelogs.8 /usr/sbin/ab /usr/sbin/logresolve /usr/sbin/rotatelogs /usr/sbin/apxs /var/log/httpd /var/cache /var/cache/httpd     24. Installed files /PHP4 These are the tnstalled files by PHP4 server-side scripting language with Apache Web Server: /usr/bin/phpize /usr/bin/php-config /usr/include/php /usr/include/php/Zend /usr/include/php/Zend/FlexLexer.h /usr/include/php/Zend/acconfig.h /usr/include/php/Zend/modules.h /usr/include/php/Zend/zend-parser.h /usr/include/php/Zend/zend-scanner.h /usr/include/php/Zend/zend.h /usr/include/php/Zend/zend_API.h /usr/include/php/Zend/zend_alloc.h /usr/include/php/Zend/ /usr/include/php/Zend/zend_compile.h zend_builtin_functions.h /usr/include/php/Zend/zend_config.h /usr/include/php/Zend/zend_config.w32.h /usr/include/php/Zend/zend_constants.h /usr/include/php/Zend/ zend_dynamic_array.h /usr/include/php/Zend/zend_errors.h /usr/include/php/Zend/zend_execute.h /usr/include/php/Zend/ /usr/include/php/Zend/zend_extensions.h zend_execute_locks.h /usr/include/php/Zend/zend_fast_cache.h /usr/include/php/Zend/zend_globals.h /usr/include/php/Zend/ /usr/include/php/Zend/zend_hash.h zend_globals_macros.h /usr/include/php/Zend/zend_highlight.h /usr/include/php/Zend/zend_indent.h /usr/include/php/Zend/zend_list.h /usr/include/php/Zend/zend_llist.h /usr/include/php/Zend/zend_operators.h /usr/include/php/Zend/zend_ptr_stack.h /usr/include/php/Zend/zend_stack.h /usr/include/php/Zend/zend_variables.h /usr/include/php/TSRM /usr/include/php/TSRM/TSRM.h /usr/include/php/ext /usr/include/php/ext/standard /usr/include/php/ext/standard/base64.h /usr/include/php/ext/standard/ basic_functions.h /usr/include/php/ext/standard/ /usr/include/php/ext/standard/ cyr_convert.h datetime.h /usr/include/php/ext/standard/dl.h /usr/include/php/ext/standard/dns.h /usr/include/php/ext/standard/exec.h /usr/include/php/ext/standard/file.h /usr/include/php/ext/standard/ /usr/include/php/ext/standard/fsock.h flock_compat.h /usr/include/php/ext/standard/global.h /usr/include/php/ext/standard/head.h /usr/include/php/ext/standard/html.h /usr/include/php/ext/standard/info.h /usr/include/php/ext/standard/md5.h /usr/include/php/ext/standard/ microtime.h /usr/include/php/ext/standard/pack.h /usr/include/php/ext/standard/ pageinfo.h /usr/include/php/ext/standard/ /usr/include/php/ext/standard/ php_array.h php_assert.h /usr/include/php/ext/standard/ /usr/include/php/ext/standard/ php_browscap.h php_crypt.h /usr/include/php/ext/standard/php_dir.h /usr/include/php/ext/standard/ php_filestat.h /usr/include/php/ext/standard/ /usr/include/php/ext/standard/ php_image.h php_iptc.h /usr/include/php/ext/standard/php_lcg.h /usr/include/php/ext/standard/ php_link.h /usr/include/php/ext/standard/ /usr/include/php/ext/standard/ php_mail.h php_metaphone.h /usr/include/php/ext/standard/ /usr/include/php/ext/standard/ php_output.h php_rand.h /usr/include/php/ext/standard/ /usr/include/php/ext/standard/ php_standard.h php_string.h /usr/include/php/ext/standard/ /usr/include/php/ext/standard/php_var.h php_syslog.h /usr/include/php/ext/standard/phpdir.h /usr/include/php/ext/standard/phpmath.h /usr/include/php/ext/standard/ /usr/include/php/ext/standard/reg.h quot_print.h /usr/include/php/ext/standard/type.h /usr/include/php/ext/standard/uniqid.h /usr/include/php/ext/standard/url.h /usr/include/php/ext/standard/ url_scanner.h /usr/include/php/regex /usr/include/php/regex/regex.h /usr/include/php/regex/regex_extra.h /usr/include/php/php.h /usr/include/php/php_regex.h /usr/include/php/php3_compat.h /usr/include/php/safe_mode.h /usr/include/php/fopen-wrappers.h /usr/include/php/php_version.h /usr/include/php/php_globals.h /usr/include/php/php_reentrancy.h /usr/include/php/php_ini.h /usr/include/php/SAPI.h /usr/include/php/php_config.h /usr/include/php/zend_config.h /usr/include/php/build-defs.h /usr/lib/php /usr/lib/php/DB /usr/lib/php/DB/common.php /usr/lib/php/DB/odbc.php /usr/lib/php/DB/mysql.php /usr/lib/php/DB/pgsql.php /usr/lib/php/DB/storage.php /usr/lib/php/build /usr/lib/php/build/pear.m4 /usr/lib/php/build/fastgen.sh /usr/lib/php/build/library.mk /usr/lib/php/build/ltlib.mk /usr/lib/php/build/program.mk /usr/lib/php/build/rules.mk /usr/lib/php/build/rules_pear.mk /usr/lib/php/build/shtool /usr/lib/php/build/acinclude.m4 /usr/lib/php/DB.php 25. Installed files by mod_perl Installed files by mod_perl programming language with Apache Web Server on your machine. /usr/lib/perl5/5.00503/i386-linux/ /usr/lib/perl5/man/man3/Apache.3 perllocal.pod /usr/lib/perl5/man/man3/Apache:: /usr/lib/perl5/man/man3/Apache::Leak.3 Constants.3 /usr/lib/perl5/man/man3/Apache::Log.3 /usr/lib/perl5/man/man3/Apache:: PerlRunXS.3 /usr/lib/perl5/man/man3/Apache:: /usr/lib/perl5/man/man3/Apache::Table.3 Symbol.3 /usr/lib/perl5/man/man3/Apache::URI.3 /usr/lib/perl5/man/man3/Apache::Util.3 /usr/lib/perl5/man/man3/Apache:: /usr/lib/perl5/man/man3/mod_perl.3 FakeRequest.3 /usr/lib/perl5/man/man3/Apache:: /usr/lib/perl5/man/man3/Apache::SIG.3 ExtUtils.3 /usr/lib/perl5/man/man3/Apache:: /usr/lib/perl5/man/man3/Apache:: Status.3 Include.3 /usr/lib/perl5/man/man3/Apache::Debug.3 /usr/lib/perl5/man/man3/Apache:: Resource.3 /usr/lib/perl5/man/man3/Apache::src.3 /usr/lib/perl5/man/man3/Apache:: PerlRun.3 /usr/lib/perl5/man/man3/Apache:: /usr/lib/perl5/man/man3/ httpd_conf.3 mod_perl_traps.3 /usr/lib/perl5/man/man3/Apache:: /usr/lib/perl5/man/man3/mod_perl_cvs.3 Options.3 /usr/lib/perl5/man/man3/Apache:: /usr/lib/perl5/man/man3/Apache:: Symdump.3 RegistryLoader.3 /usr/lib/perl5/man/man3/ /usr/lib/perl5/man/man3/ mod_perl_method_handlers.3 mod_perl_tuning.3 /usr/lib/perl5/man/man3/ /usr/lib/perl5/man/man3/Apache:: cgi_to_mod_perl.3 StatINC.3 /usr/lib/perl5/man/man3/Apache:: /usr/lib/perl5/man/man3/Bundle:: Registry.3 Apache.3 /usr/lib/perl5/man/man3/Apache:: /usr/lib/perl5/man/man3/Apache:: SizeLimit.3 PerlSections.3 /usr/lib/perl5/man/man3/Apache:: /usr/lib/perl5/site_perl/5.005/i386- RedirectLogFix.3 linux/auto /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache linux/auto/Apache/include /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include linux/auto/Apache/include/include/ buff.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ multithread.h httpd.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ ap_config.h alloc.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ap.h linux/auto/Apache/include/include/ ap_md5.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ ap_ctx.h util_md5.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ rfc1413.h conf.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ util_uri.h explain.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ ap_compat.h http_config.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ ap_sha1.h scoreboard.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ compat.h http_request.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ http_core.h ap_mm.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ http_protocol.h util_date.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ ap_hook.h http_main.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ http_conf_globals.h util_script.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ http_vhost.h ap_ctype.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ hsregex.h ap_mmn.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/include/ ap_config_auto.h http_log.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/include/ linux/auto/Apache/include/os fnmatch.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/netware linux/auto/Apache/include/os/netware/ os.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/netware/ linux/auto/Apache/include/os/netware/ getopt.h test_char.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/netware/ linux/auto/Apache/include/os/netware/ uri_delims.h precomp.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/bs2000 linux/auto/Apache/include/os/bs2000/os- inline.c /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/bs2000/ linux/auto/Apache/include/os/bs2000/ ebcdic.h os.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/tpf linux/auto/Apache/include/os/tpf/ ebcdic.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/tpf/os.h linux/auto/Apache/include/os/tpf/os- inline.c /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/win32 linux/auto/Apache/include/os/win32/ service.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/win32/ linux/auto/Apache/include/os/win32/ getopt.h registry.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/win32/ linux/auto/Apache/include/os/win32/ resource.h installer /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/win32/ linux/auto/Apache/include/os/win32/ installer/installdll installer/installdll/test /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/win32/ linux/auto/Apache/include/os/win32/ installer/installdll/test/test.h installer/installdll/test/resource.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/win32/os.h linux/auto/Apache/include/os/win32/ passwd.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/win32/ linux/auto/Apache/include/os/unix readdir.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/unix/os.h linux/auto/Apache/include/os/unix/os- inline.c /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/os390 linux/auto/Apache/include/os/os390/os- inline.c /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/os390/ linux/auto/Apache/include/os/os390/os.h ebcdic.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/mpeix linux/auto/Apache/include/os/mpeix/os- inline.c /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/mpeix/os.h linux/auto/Apache/include/os/os2 /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/os/os2/os.h linux/auto/Apache/include/os/os2/os- inline.c /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/modules linux/auto/Apache/include/modules/ssl /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/modules/ssl/ linux/auto/Apache/include/modules/ssl/ ssl_expr.h ssl_util_table.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/modules/ssl/ linux/auto/Apache/include/modules/ssl/ ssl_util_ssl.h ssl_expr_parse.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/modules/ssl/ linux/auto/Apache/include/modules/ssl/ mod_ssl.h ssl_util_sdbm.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/modules/perl linux/auto/Apache/include/modules/perl/ mod_perl.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/modules/perl/ linux/auto/Apache/include/modules/perl/ mod_perl_version.h perl_PL.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/modules/perl/ linux/auto/Apache/include/modules/php4 mod_perl_xs.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/modules/php4/ linux/auto/Apache/include/modules/proxy mod_php4.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/modules/ linux/auto/Apache/include/modules/ proxy/mod_proxy.h standard /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/modules/ linux/auto/Apache/include/support standard/mod_rewrite.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/support/ linux/auto/Apache/include/lib suexec.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/lib/expat- linux/auto/Apache/include/lib/expat- lite lite/iasciitab.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/lib/expat- linux/auto/Apache/include/lib/expat- lite/latin1tab.h lite/xmldef.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/lib/expat- linux/auto/Apache/include/lib/expat- lite/xmlparse.h lite/xmltok.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/lib/expat- linux/auto/Apache/include/lib/expat- lite/xmlrole.h lite/hashtable.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/lib/expat- linux/auto/Apache/include/lib/expat- lite/nametab.h lite/xmltok_impl.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/lib/expat- linux/auto/Apache/include/lib/expat- lite/utf8tab.h lite/asciitab.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/regex linux/auto/Apache/include/regex/utils.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/regex/ linux/auto/Apache/include/regex/ regex2.h cclass.h /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/include/regex/cname.h linux/auto/Apache/typemap /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/Leak linux/auto/Apache/Leak/Leak.so /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/Leak/Leak.bs linux/auto/Apache/Symbol /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/Apache/Symbol/Symbol.so linux/auto/Apache/Symbol/Symbol.bs /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/mod_perl linux/auto/mod_perl/.packlist /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/mod_perl.pod linux/Bundle /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Bundle/Apache.pm linux/Apache /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/test.pm linux/Apache/Debug.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/Resource.pm linux/Apache/src.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/httpd_conf.pm linux/Apache/Symdump.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/RegistryLoader.pm linux/Apache/Registry.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/SizeLimit.pm linux/Apache/RedirectLogFix.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/MyConfig.pm linux/Apache/Constants /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/Constants/Exports.pm linux/Apache/SIG.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/StatINC.pm linux/Apache/Opcode.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/PerlSections.pm linux/Apache/FakeRequest.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/ExtUtils.pm linux/Apache/Include.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/Status.pm linux/Apache/PerlRun.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/Options.pm linux/Apache/RegistryNG.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/RegistryBB.pm linux/Apache/Connection.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/Constants.pm linux/Apache/File.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/Leak.pm linux/Apache/Log.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/ModuleConfig.pm linux/Apache/PerlRunXS.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/Server.pm linux/Apache/Symbol.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/Table.pm linux/Apache/URI.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/Apache/Util.pm linux/mod_perl_hooks.pm /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/mod_perl_hooks.pm.PL linux/mod_perl_tuning.pod /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/mod_perl_cvs.pod linux/mod_perl_method_handlers.pod /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/mod_perl.pm linux/mod_perl_traps.pod /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/cgi_to_mod_perl.pod linux/Apache.pm Chapter 30. Optional component to install with Apache Table of Contents 1._Linux_Webalizer 2._Compile 2.1._Configurations 3._Configure_the_/etc/webalizer.conf_file 4._Make_Apache_aware_of_Webalizer_output_directory 4.1._Running_Webalizer_manually_first_time 5._Run_Webalizer_automatically_with_a_cron_job 5.1._Installed_files 6._Linux_FAQ-O-Matic 7._Compile_and_install_FAQ-O-Matic 8._Make_Apache_aware_Faq-O-Matic_file's_location 9._Configure_your_FAQ-O-Matic 10._Installed_files 11._Linux_Webmail_IMP 12._Set_up_PHPLib 13._Compile_to_install_Webmail_IMP 14._Configure_and_create_Webmail_IMP_SQL_database 15._Configure_your_php.ini_from_PHP4 15.1._Configure_Apache_to_recognize_Webmail_IMP 16._Configure_Webmail_IMP_via_your_web_browser In this chapter, Three-useful external programs that you may install on your Linux server are explained. These programs have been made for use with the Apache Web Server, and are useful only if you intend to use Apache in your organization. If this is not the case, you can skip this chapter and continue through the rest of this book. To begin, we'll talk about: i. Webalizer, which is a web server log file analysis program. ii. Then we'll discuss FAQ-O-Matic, which can be used when you want a FAQ list, bug-tracing database, documentation and much more on your server. iii. Finally, we'll talk about a very sophisticated and interesting program called Webmail, which allows you to offer free mail accounts to your clients, or access and read your mail, in a secure manner. 1. Linux Webalizer A web server like Apache logs all predefined log entry information into a text file that can be viewed and analyzed by the web administrator. This file can also be evaluated by a special program which can produce the information in a graphical presentation, making interpretation easier for the administrator. As per in the [README] file of Webalizer: The Webalizer is a web server log file analysis program, which produces usage statistics in HTML format for viewing with a browser. The results are presented in both columnar and graphical format, which facilitates interpretation. Yearly, monthly, daily and hourly usage statistics are presented, along with the ability to display usage by site, URL, referrer, user agent, browser and country, user agent and referrer are only available if your web server produces Combined log format files. These installation instructions assume * Commands are Unix-compatible. * The source path is /var/tmp, other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * Webalizer version number is 1_30-04 These are the Package(s): Webalizer Homepage: http://www.mrunix.net/webalizer/ Webalizer FTP Site: 207.153.121.6 You must be sure to download: webalizer-1_30-04-src.tgz Before you compile, decompress the tarball (tar.gz). [root@deep /]# cp webalizer-version-src.tgz /var/tmp/ [root@deep /]# cd /var/tmp/ [root@deep ]/tmp# tar xzpf webalizer-version-src.tgz Important There are a few prerequisites; the Webalizer requires that the GD Graphics Library, which is required for generating inline graphics for the Webalizer program, be already installed on your system. If this is not the case, you must install it from your Red Hat Linux CD-ROM. To verify that the GD package is installed on your Linux system, use the following command: [root@deep /]# rpm -qi gd package gd is not installed To install the GD packages on your Linux system, use the following command: [root@deep /]# mount /dev/cdrom /mnt/cdrom/ [root@deep /]# cd /mnt/cdrom/RedHat/RPMS/ [root@deep ]/RPMS# rpm -Uvh gd-version.i386.rpm gd ################################################## [root@deep ]/RPMS# rpm -Uvh gd-devel-version.i386.rpm gd-devel ################################################## [root@deep ]/RPMS# cd /; umount /mnt/cdrom/ Important The Apache web server should be already installed on your system to be able to use Webalizer software, of course. For more information on Apache_web_server, see its related chapter in this book. 2. Compile Move into the new Webalizer directory and type the following commands on your terminal: CC="egcs" \ CFLAGS="-O9 -funroll-loops -ffast-math -malign-double - mcpu=pentiumpro -march=pentiumpro -fomit-frame-pointer -fno-exceptions" \ ./configure \ --prefix=/usr [root@deep ]/webalizer-1.30-04# make [root@deep ]/webalizer-1.30-04# make install [root@deep ]/webalizer-1.30-04# mkdir /home/httpd/usage * The make command will compile all source files into executable binaries, * The make install will install the binaries and any supporting files into the appropriate locations. * The mkdir will create a new directory named usage under the /home/httpd/ directory where we'll handle all related Webalizer files. Please do cleanup later: [root@deep /]# cd /var/tmp [root@deep ]/tmp# rm -rf webalizer-version/ webalizer-version-src.tgz The rm command will remove all the source files we have used to compile and install Webalizer. It will also remove the Webalizer compressed archive from the /var/tmp directory. 2.1. Configurations Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example Webalizer configuration file are organised like this: total 8 -rw-r--r-- 1 harrypotter harrypotter 208 Jul 26 18:04 webalizer.conf You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run Webalizer, the following file is required, and must be created or copied to the appropriate directory on your server. i. Copy the webalizer.conf file to the /etc/ directory. Tip To run Webalizer, the following file from the floppy.tgz archive is required and must be created or copied to the appropriate directory on your server. Copy the sxid.conf file to the /etc/ directory. or alternatively you can copy and paste directly from this book to the concerned file. 3. Configure the /etc/webalizer.conf file The /etc/webalizer.conf is the default configuration file for Webalizer. With it, you can specify which directories or pages in your web site to analyze, which URLs to hide, and so on. By default, the Webalizer program will install a sample configuration file named webalizer.conf.sample under the /etc/ directory of Linux. You can use this file to configure your choices and then rename it webalizer.conf, and the Webalizer program will be able to find and use it. A lot of options exist and it's important to read the documentation that comes with Webalizer for more information on all of the different setting and parameters. Also, it's important to note that we comment in this Webalizer configuration file only the most common and used parameters. Edit the webalizer.conf.sample file, vi /etc/webalizer.conf.sample or create the webalizer.conf file, touch /etc/webalizer.conf and add/change in this file: LogFile /var/log/httpd/access_log OutputDir /home/httpd/usage Incremental yes PageType htm* PageType cgi PageType php HideURL *.gif HideURL *.GIF HideURL *.jpg HideURL *.JPG HideURL *.ra IgnoreURL /taskbar* This tells the webalizer.conf file to set itself up for this particular configuration setup with: LogFile/var/log/httpd/access_log The option LogFile specifies the logfile to use with Webalizer. The default log file is supposed to be the access_log of Apache Web Server, but you can specifies a different one, like the one Squid Proxy Server makes named access.log if you use it in httpd-accelerator mode. See, Software_-Server/Proxy_Network, for more information. OutputDir /home/httpd/usage The option OutputDir specifies the location of the output directory to use for the reports of Webalizer. All present and future report files generated by the Webalizer program will be hosted in this directory. It is recommended that you create this directory where your Apache web site resides. Incremental yes The option Incremental if set to Yes tells the program only to process partial logs file, and allows you to rotate your log files as much as you want without the loss of access information. It's recommended to set this option to Yes. PageType htm* cgi php The option PageType specifies what file extensions you want Webalizer to consider as a page to count. Each added file extensions must be specified on its own line as shown in the Webalizer configuration file above. HideURL *.gif *.GIF *.jpg *.JPG *.ra The option HideURL specifies what kind of items such as graphic files, audio files or other non-html files to hide from the reports page. Each added item must be specified on its own line as shown in the Webalizer configuration file above. IgnoreURL /taskbar* The option IgnoreURL specifies URLs to be completely ignored from the generated statistics reports. This option can be used to ignore directories that are not important in our statistics reports. It's also useful when you want to manage and class which URLs should be monitored and which should be ignored. Caution If you decide to use the existent /etc/webalizer.conf.sample file to configure your parameters for Webalizer, don't forget to rename it webalizer.conf or the program will be unable to use it. 4. Make Apache aware of Webalizer output directory Once Webalizer has been installed in the system we must add the following lines into the httpd.conf file of Apache to be able to locate and use it features. 1. Edit the httpd.conf file, vi /etc/httpd/conf/httpd.conf and add the following lines between the section tags and : Alias /usage/ "/home/httpd/usage/" Options None AllowOverride None Order deny,allow Deny from all Allow from 192.168.1.0/24 2. Don't forget to restart your Apache web server once you have added the above lines to its httpd.conf file: [root@deep ] /# /etc/rc.d/init.d/httpd restart Shutting down http: [ OK ] Starting httpd: [ OK ] 4.1. Running Webalizer manually first time Now it's time to run the program to generate reports, html and graphics in the default Webalizer directory so that we can see them in our web browser interface. This step is required just the first time you install and use Webalizer, since it's preferable to use a cron job to automate this task in the future. To run Webalizer manually, to generate reports, use the following command: [root@deep ] /# /usr/bin/webalizer Webalizer V1.30-04 (Linux 2.2.14) English Using logfile /var/log/httpd/access_log Creating output in /home/httpd/usage Hostname for reports is 'deep.openna.com' History file not found... Previous run data not found... Saving current run data... [03/06/2000 04:42:03] Generating report for March 2000 Generating summary report Saving history information... 81 records (2 ignored) in 0.31 seconds At this stage, we should verify that Webalizer is working on the system. To do that, point your web browser to the following address: http://my-web-server/ usage/. The my-web-server is the address where your Apache web server lives, and usage is the directory that host all the Webalizer reports files. Webalizer 5. Run Webalizer automatically with a cron job The last thing you can do now is automate the task of generating a new log file to update your Webalizer reports. Place an entry into root's crontabs to make Webalizer run as a cron job. To add Webalizer in your cron job you must edit the crontab and add the following line as root to run it, for example, every 28 minutes for busy sites: [root@deep ] /# crontab -e # Run Webalizer to update Apache Log files every 28 minutes. 28 * * * * /usr/bin/webalizer 5.1. Installed files These are the following files installed by Webalizer. /etc/webalizer.conf.sample /usr/bin/webalizer /usr/man/man1/webalizer.1 6. Linux FAQ-O-Matic As per the [Faq-O-Matic] web site: A mailing list archive is good, because it lets thoughtful people with Frequently Asked Questions search for an immediate answer, and avoids bothering the people who have answers. Unfortunately, the answers in a mailing list archive become stale over time, are disorganized, and are hard to sift from the conversational noise of the mailing list. A Frequently Asked Questions, list FAQ is even better, because the people with questions can be a little lazier and still find their answer right away. Unfortunately, maintaining a FAQ list requires effort; if people with the answers become lazy, the FAQ list becomes stale. The Faq-O-Matic is a CGI-based system that automates the process of maintaining a FAQ or Frequently Asked Questions list. It allows visitors to your FAQ to take part in keeping it up-to-date. A permission system also makes it useful as a help-desk application, bug-tracking database, or documentation system. These installation instructions assume * Commands are Unix-compatible. * The source path is /var/tmp, other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * FAQ-O-Matic version number is 2.709 These are the Package(s) required: FAQ-O-Matic Homepage: http://www.dartmouth.edu/~jonh/ff-serve/cache/1.html The most recent version of the FAQ-O-Matic is always available at: ftp:// ftp.cs.dartmouth.edu/pub/jonh. You must be sure to download: FAQ-OMatic-2.709.tar.gz There are some prerequisites which you need to keep in mind before can install FAQ-O-Matic, i. Apache web server should be already installed on your system in order to be able to use FAQ-O-Matic software. ii. Revision Control System, RCS file version management tools should also already be installed on your system to be able to use FAQ-O-Matic software. To verify that the RCS package is installed on your system, use the following command: [root@deep ] /# rpm -qi rcs package rcs is not installed To install the RCS package on your Linux system, use the following command: [root@deep ] /# mount /dev/cdrom /mnt/cdrom/ [root@deep ] /# cd /mnt/cdrom/RedHat/RPMS/ [root@deep ]/RPMS# rpm -Uvh rcs-version.i386.rpm rcs ################################################## [root@deep ]/RPMS# cd /; umount /mnt/cdrom/ For more information on the required software, see the related chapters in this book. 7. Compile and install FAQ-O-Matic Before you Compile, Decompress the tarball (tar.gz). [root@deep ] /# cp FAQ-O-Matic-version.tar.gz /var/tmp/ [root@deep ] /# cd /var/tmp/ [root@deep ]/tmp# tar xzpf FAQ-O-Matic-version.tar.gz You need to compile, to install the Faq-O-Matic program on your computer, move into the new FAQ-O-Matic directory and type the following commands on your terminal: [root@deep ] /FAQ-OMatic-2.709# perl Makefile.PL [root@deep ] /FAQ-OMatic-2.709# make [root@deep ] /FAQ-OMatic-2.709# make install [root@deep ] /FAQ-OMatic-2.709# mv fom /home/httpd/cgi-bin/ 1 [root@deep ] /FAQ-OMatic-2.709# mkdir -p /home/httpd/cgi-bin/fom- meta [root@deep ] /FAQ-OMatic-2.709# mkdir -p /home/httpd/faqomatic [root@deep ] /FAQ-OMatic-2.709# chown root.www /home/httpd/cgi-bin/ fom [root@deep ] /FAQ-OMatic-2.709# chown -R www.www /home/httpd/cgi- bin/fom-meta/ [root@deep ] /FAQ-OMatic-2.709# chown -R www.www /home/httpd/ faqomatic/ _1_ Or wherever your CGIs live. * The make command will compile all source files into executable binaries * The make install will install the Perl programs and any supporting files into the appropriate locations * The mv command will move the main fom CGI program of Faq-O-Matic to the cgi- bin directory of your Apache web server. * The mkdir will create new directories named fom-meta and faqomatic under the /home/httpd/ directory where we'll handle all related FAQ-O-Matic files. * Finally, the chown command will set the owner of the fom CGI program to be the super-user root and the group to be the user Apache run as www and will set the directories fom-meta and faqomatic to be owned by www and group by www. Note You'll receive a temporary password via mail during the compilation of the software. This password will be necessary to complete later the installation of Faq-O-Matic through the web interface. 8. Make Apache aware Faq-O-Matic file's location Once Faq-O-Matic has been installed in the system, we must add the following lines to the httpd.conf file of Apache to be able to locate and use it's features. 1. Edit the httpd.conf file, vi /etc/httpd/conf/httpd.conf and add the following lines between the section tags and : Alias /faqomatic/ "/home/httpd/faqomatic/" Options None AllowOverride None Order allow,deny Allow from all Alias /bags/ "/home/httpd/faqomatic/bags/" Options None AllowOverride None Order allow,deny Allow from all Alias /cache/ "/home/httpd/faqomatic/cache/" Options None AllowOverride None Order allow,deny Allow from all Alias /item/ "/home/httpd/faqomatic/item/" Options None AllowOverride None Order allow,deny Allow from all 2. Don't forget to restart your Apache web server once you have added the above lines to its httpd.conf file: [root@deep ] /# /etc/rc.d/init.d/httpd restart Shutting down http: [ OK ] Starting httpd: [ OK ] 9. Configure your FAQ-O-Matic The rest of this installation will be made through the use of your web browser. With Netscape Communicator, follow the simple steps below: 1. The first step is to load your web browser and use it to configure Faq-O- Matic. a. Point your Netscape browser to the following location:http://my-web- server/cgi-bin/fom b. Enter your temporary password c. Create the /home/httpd/cgi-bin/fom-meta/ directory first d. Configure the Define configuration parameters in the configuration main menu 2. Example 30.1. Using Netscape browser Fill under the sections marked Mandatory the following information: $adminAuth= admin@openna.com $serverBase= http://www.openna.com $cgiURL= /cgi-bin/fom $serveDir= /home/httpd/faqomatic/ $serveURL= /faqomatic/ FAQ-O-Matic-Configuration Configure the rest of the Define configuration parameters as you need. Once you have finished setting your parameters, click on the Define button to validate your choices. Tip The my-web-server is the address where your Apache web server resides, and the temporary password is the one you should have received by mail during the install stage of this software. 3. Once you have finished configuring the Define configuration parameters, you must perform the rest of the FAQ-O-Matic configuration in order to be able to use it as described in the configuration main menu of the FAQ-O- Matic software. Test FAQ-O-Matic 4. Please do cleanup later: [root@deep ] /# cd /var/tmp [root@deep ]/tmp# rm -rf FAQ-OMatic-version/ FAQ-O-Matic- version.tar.gz The rm command will remove all the source files we have used to compile and install FAQ-O-Matic. It will also remove the FAQ-O-Matic compressed archive from the /var/tmp directory. 10. Installed files These are the files installed by FAQ-O-Matic software on your system: /usr/lib/perl5/man/man3/FAQ::OMatic:: /usr/lib/perl5/site_perl/5.005/i386- API.3 linux/auto/FAQ /usr/lib/perl5/site_perl/5.005/i386- /usr/lib/perl5/site_perl/5.005/i386- linux/auto/FAQ/OMatic linux/auto/FAQ/OMatic/.packlist /usr/lib/perl5/site_perl/5.005/FAQ /usr/lib/perl5/site_perl/5.005/FAQ/OMatic /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/Bags.pm OMatic/authenticate.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/ImageRef.pm OMatic/Groups.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/submitGroup.pm OMatic/recent.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/submitItem.pm OMatic/maintenance.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/Language_de_iso8859_1.pm OMatic/Slow.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/help.pm OMatic/selectBag.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/submitPart.pm OMatic/delPart.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/buildSearchDB.pm OMatic/mirrorServer.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/editItem.pm OMatic/search.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/SearchMod.pm OMatic/addItem.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/Versions.pm OMatic/displaySlow.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/Language_fr.pm OMatic/img.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/editPart.pm OMatic/AuthLocal.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/ColorPicker.pm OMatic/ImageData.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/changePass.pm OMatic/submitBag.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/submitModOptions.pm OMatic/I18N.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/Log.pm OMatic/appearanceForm.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/moveItem.pm OMatic/editGroups.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/HelpMod.pm OMatic/searchForm.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/submitPass.pm OMatic/submitMove.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/Set.pm OMatic/statgraph.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/stats.pm OMatic/Item.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/Words.pm OMatic/Appearance.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/dispatch.pm OMatic/editBag.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/submitCatToAns.pm OMatic/submitAnsToCat.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/editModOptions.pm OMatic/Auth.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/install.pm OMatic/Part.pm /usr/lib/perl5/site_perl/5.005/FAQ/ /usr/lib/perl5/site_perl/5.005/FAQ/ OMatic/faq.pm OMatic/API.pm /usr/lib/perl5/site_perl/5.005/FAQ/   OMatic.pm 11. Linux Webmail IMP Webmail IMP allows universal, web-based access to IMAP/POP3 servers and provides an address book, LDAP directory searches, full support for sending and receiving attachments, and many other features normally only found in desktop mail clients. If you have installed Apache with SSL support, clients can access and read mail through a secure manner by way of SSL encryption. By default in this section, we have configured Webmail IMP to use PostgreSQL database and IMAP connections. There is, though, much support for other databases within Webmail IMP. If you prefer, you can use MySQL, Oracle, Sybase, or other well know SQL databases. You may also choose to use POP3 instead of IMAP connection to your clients. These installation instructions assume * Commands are Unix-compatible. * The source path is /home/httpd. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * Horde version number is 1.2.0 * Webmail IMP version number is 2.2.0 * PHPLib version number is 7.2b These are the Package(s): Webmail IMP Homepage:http://www.horde.org/imp/ You must be sure to download: horde-1.2.0-pre11.tar.gz You must be sure to download: imp-2.2.0-pre11.tar.gz PHPLib Homepage:http://phplib.netuse.de/index.php3 You must be sure to download: phplib-7.2b.tar.gz there are some prerequisites youi need to take care of: 1. Apache web server should be already installed on your system to be able to use the Webmail IMP software. 2. The PHP4 server-side scripting language support should be already installed on your system to be able to use the Webmail IMP software. 3. Postgresql, or another database server, should be already installed on your system if you intend to use the Webmail IMP software with SQL support. 4. The OpenLDAP directory server should be already installed on your system if you intend to use the Webmail IMP software with LDAP support. 5. The IMAP/POP server should be already installed on your system to be able to use the Webmail IMP software. 6. The PHPLIB files, 7.2 or greater, should be already installed on your system to be able to use the Webmail IMP software. Note For more information on the required software, see the related chapter in this book. 12. Set up PHPLib To be able to run Webmail IMP on your Linux server; PHPLib, a toolkit development of Web applications for PHP developers software must be installed. To install PHPLib, follow the simple steps below: These are the package(s) PHPLib Homepage: http://phplib.netuse.de/index.php3, http://phplib.netuse.de/ index.php3 You must be sure to download: phplib-7.2b.tar.gz [root@deep ] /# cp phplib-7.2b.tar.gz /home/httpd/ [root@deep ] /# cd /home/httpd/ [root@deep ] /httpd# tar xzpf phplib-7.2b.tar.gz Move to your web server's DocumentRoot, and create a /home/httpd/php directory by executing the following commands: [root@deep ] /# cd /home/httpd/ [root@deep ] /httpd# mkdir php Copy the contents of the PHPLib distributions php directory into the php directory that you created in your DocumentRoot: [root@deep ] /# cd /home/httpd/phplib-7.2b/php/ [root@deep ] /php# cp * /home/httpd/php/ [root@deep ] /php# cd /home/httpd/ [root@deep ] /httpd# rm -f phplib-7.2b.tar.gz [root@deep ] /httpd# rm -rf phplib-7.2b/ Important We remove the tar archive and phplib-version directory of PHPLib once we are finished copying its php directory into the new php directory we created in our DocumentRoot. 13. Compile to install Webmail IMP To install the Webmail IMP program on your server, please follow the simple steps below. 1. Copy horde-1.2.0-pre11.tar.gz to your web servers DocumentRoot, /home/ httpd/, untar it and move the directory from horde-version to horde by executing the following commands: [root@deep ] /# cp horde-version.tar.gz /home/httpd/ [root@deep ] /# cd /home/httpd/ [root@deep ] /httpd# tar xzpf horde-version.tar.gz [root@deep ] /httpd# mv horde-version horde [root@deep ] /httpd# rm -f horde-version.tar.gz We remove the tar archive of Horde once we have finished moving the horde- version directory of Horde to its new name horde. 2. Copy imp-2.2.0-pre11.tar.gz to your new horde directory, /home/httpd/ horde/, untar it and move the directory from imp-version to imp by executing the following commands: [root@deep ] /# cp imp-version.tar.gz /home/httpd/horde/ [root@deep ] /# cd /home/httpd/horde/ [root@deep ] /horde# tar xzpf imp-version.tar.gz [root@deep ] /horde# mv imp-version imp [root@deep ] /horde# rm -f imp-version.tar.gz Important It's important that the directory imp reside inside horde directory, or Webmail will not work. We remove the tar archive of IMP once we have finished moving the imp-version directory of IMP to its new name imp. 3. Change the horde directory and all its subdirectories and files to be owned by the super-user root for security reasons. [root@deep ] /# chown -R 0.0 /home/httpd/horde/ 4. Copy the /home/httpd/horde/phplib/*.ihtml files to your new php directory, /home/httpd/php/ by executing the following commands: [root@deep ] /# cp /home/httpd/horde/phplib/*.ihtml /home/ httpd/php/ 14. Configure and create Webmail IMP SQL database We must now configure our database to be able to use Webmail IMP with the SQL database. The easier method is to use the predefined scripts located under the /home/httpd/horde/imp/config/scripts/ subdirectory. For PostgreSQL support, follow the simple steps below. 1. First of all, we must edit the script file pgsql_create.sql related to PostgreSQL located under the /home/httpd/horde/imp/config/scripts subdirectory, and change its default value for the username to run as from httpd to www. GRANT SELECT, INSERT, UPDATE ON imp_pref, imp_addr TO nobody; To read: GRANT SELECT, INSERT, UPDATE ON imp_pref, imp_addr TO www; 2. Now, we must define the username for Apache named www in our PostgreSQL database, to be able to create the Webmail IMP database with this username. To define the httpd username named www in your database, run the createuser utility program of PostgreSQL: [root@deep ] /# su postgres [postgres@deep /]$ createuser Enter name of user to add ---> www Enter user's postgres ID or RETURN to use unix user ID: 80 - [Press Enter] Is user "www" allowed to create databases (y/n) y Is user "www" a superuser? (y/n) n createuser: www was successfully added 3. Once the httpd user www has been included in PostgreSQL, log in as the user your PostgreSQL database runs as, in our case postgres and insert the small script related to PostgreSQL to automatically create the Webmail IMP database in PostgreSQL. To automatically create Webmail IMP database in PostgreSQL, use the following commands: [root@deep ] /# cd /home/httpd/horde/imp/config/scripts/ [root@deep scripts]# su postgres [postgres@deep ] /scripts$ psql template1 < pgsql_create.sql // IMP database creation script for postgreSQL // Author: barce@lines.edu // Date: Aug-29-1998 // Notes: replace "nobody" with yours httpd username // Run using: psql template1 < pgsql_create.sql CREATE DATABASE horde; CREATEDB \connect horde connecting to new database: horde CREATE TABLE imp_pref ( username text, sig text, fullname text, replyto text, lang varchar(30) ); CREATE CREATE TABLE imp_addr ( username text, address text, nickname text, fullname text ); CREATE GRANT SELECT, INSERT, UPDATE ON imp_pref, imp_addr TO www; CHANGE EOF 4. We must restart the PostgreSQL server for the changes to take effect: [root@deep ] /# /etc/rc.d/init.d/postgresql restart Stopping postgresql service: [ OK ] Checking postgresql installation: looks good! Starting postgresql service: postmaster [13474] 5. Copy and rename the file /home/httpd/horde/phplib/horde_phplib.inc to / home/httpd/php/local.inc, then edit the new local.inc file which is your phplib configuration file containing settings that will define the behavior of phplib, and follow its instruction to define the storage container you'll want to uncomment. a. [root@deep ] /# cp /home/httpd/horde/phplib/ horde_phplib.inc /home/httpd/php/local.inc cp: overwrite `/home/httpd/php/local.inc'? y b. Edit the local.inc file, vi /home/httpd/php/local.inc, then uncomment and set the following lines to define SQL as your default database: /* To use an SQL database, uncomment and edit the following: */ class HordeDB extends DB_Sql { var $Host = 'localhost'; var $Database = 'horde'; var $User = 'www'; var $Password = 'some-password'; var $Port = '5432'; function halt($msg) { printf("Database error (HordeDB): %s
\n", $msg); } } class HordeCT extends CT_Sql { var $database_class = 'HordeDB'; // Which database class to use... var $database_table = 'active_sessions'; // and find our data in this table. } Don't forget to uncomment in this file the type of storage container you want to use for Webmail IMP. Remember to uncomment only one type. In our case we chose to use SQL. Also the parameters you must set for SQL database are the var $User =, var $Password =, and var $Port =. The var $User = corresponds to your httpd username, in our case www, var $Password = corresponds to the password for the user www you have defined in PostgreSQL, and var $Port = is the IP port number used to connect to your SQL database. 6. Finally edit the /home/httpd/php/prepend.php3 file and specifies your default database type. Edit the prepend.php3 file, vi /home/httpd/php/ prepend.php3 then change the following line to define PostgreSQL as your database type: require($_PHPLIB["libdir"] . "db_mysql.inc"); To read: require($_PHPLIB["libdir"] . "db_pgsql.inc"); 15. Configure your php.ini from PHP4 Another setting you need to configure is in your PHP4 configuration file /etc/ httpd/php.ini. This modification is required in order to define which features, such as IMAP, PostgreSQL and others, are to be loaded automatically by PHP4. Since we decided to use PostgreSQL as our database, and need to use IMAP features in our Webmail software, we must define them in the php.ini configuration file of PHP4. Edit the php.ini file, vi /etc/httpd/php.ini, and add under the Dynamic Extensions section your desired choices. In our case, as you can see, we chose IMAP and PostgreSQL support: extension=imap.so ; Added for IMAP support extension=pgsql.so ; Added for PostgreSql support extension=mysql.so ; Added for MySql support extension=ldap.so ; Added for LDAP support You must tell where to look when including files that don't have absolute paths as well, to automatically prepend the contents of phplib's prepend.php3 to each file, and turns off magic quotes. Edit the php.ini file, vi /etc/httpd/php.ini and add the following parameters to the related lines: magic_quotes_gpc = Off auto_prepend_file = "/home/httpd/php/prepend.php3" include_path = "/home/httpd/horde:/home/httpd/php" 15.1. Configure Apache to recognize Webmail IMP Once Webmail IMP has been installed in the system, we must add the following lines in the httpd.conf file of Apache to be able to locate and use its features. Edit the httpd.conf file, vi /etc/httpd/conf/httpd.conf and add the following lines between the section tags and : Alias /horde/ "/home/httpd/horde/" Options None AllowOverride None Order allow,deny Allow from all Alias /imp/ "/home/httpd/horde/imp/" Options None AllowOverride None Order allow,deny Allow from all You must restart the Apache web server for the changes to take effect, use the following commands: [root@deep ] /# /etc/rc.d/init.d/httpd restart Shutting down http: [ OK ] Starting httpd: [ OK ] 16. Configure Webmail IMP via your web browser Several ways exist to configure Webmail IMP, and the one we've chosen is the new setup engine named setup.php3, which gives people the ability to configure IMP via a web browser. 1. For security reasons, it is disabled by default, but you can enable it with the following commands: To enable setup.php, use the following command: [root@deep ] /# cd /home/httpd/horde/ [root@deep ] /horde# sh ./install.sh Your blank configuration files have been created, please go to the configuration utitlity at : your install path url/setup.php3 2. Once the new setup engine of Webmail IMP has been enabled, point your browser to the following URL: http://my-web-server/horde/setup.php. At this point, you can walk through the graphical setup program and configure all aspects of IMP. my-web-server is the address where your Apache web server lives, and the /horde/ directory is where the setup.php file resides. 3. When you are done with the new setup engine of Webmail IMP, be sure to disable it again for security reasons. To disable setup.php, use the following command: [root@deep ] /# cd /home/httpd/horde/ [root@deep ] /horde# sh ./secure.sh I have made your configuration files, and libraries mode 0555 which is read / execute for everyone. And the setup.php is mode 0000 which is no access period. At this stage, we must verify that Webmail IMP is working on your system. To do this, point your web browser to the following address: http://my-web-server/ horde/. my-web-server is the address where your Apache web server lives, and / horde is the directory that host Webmail IMP program. Webmail through browser Chapter 31. Software -Server/File Sharing-Network Table of Contents 1._Linux_Samba_Server 2._Configure_Samba 3._Compile_and_optimize 4._Configurations 5._Configuration_of_the_/etc/smb.conf_file 6._Configure_the_/etc/lmhosts_file 6.1._Configure_the_/etc/pam.d/samba_file 7._Encrypted_Samba_password_file_for_clients 8._Optimizing_Samba 8.1._Tuning_the_buffer_cache 9._Tuning_the_buffermem 10._Further_documentation 11._Samba_Administrative_Tools 11.1._Samba_Users_Tools 12._The_/etc/rc.d/init.d/smb_script_file 12.1._Securing_Samba 13._Installed_files Enterprise-level organizations often use different operating systems for handling many kind of jobs and have the need to keep them in a networked environment for files sharing and printers. Employees may work on workstations like Linux, Microsoft Windows 95/98/NT, OS/2 or Novel and still need to access the server in their daily work. A Linux server with Samba support can be used for these activities. 1. Linux Samba Server Samba is a strong network service for file and print sharing that works on the majority of operating systems available today. When well implemented by the administrator, it's faster and more secure than the native file sharing services available on Microsoft Windows machines. As per the [README file of Samba]: Samba is the protocol by which a lot of PC-related machines share files and printers, and other information, such as lists of available files and printers. Operating systems that support this natively include Windows 95/98/NT, OS/2, and Linux, and add on packages that achieve the similar thing are available for DOS, Windows, VMS, Unix of all kinds, MVS, and more. Apple Macs and some Web Browsers can speak this protocol as well. Alternatives to SMB include Netware, NFS, AppleTalk, Banyan Vines, Decnet etc. Many of these have advantages but none are public specifications and widely implemented in desktop machines by default. Samba software includes an SMB server, to provide Windows NT and LAN Manager-style file and print services to SMB clients such as Windows 95, Warp Server, smbfs and others, a NetBIOS, rfc1001/1002 name server, which amongst other things gives browsing support, an ftp-like SMB client so that you can access PC resources; disks and printers from Unix, Netware and other operating systems, and finally, a tar extension to the client for backing up PCs. Samba These installation instructions assume * Commands are Unix-compatible. * The source path is /var/tmp, other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * Samba version number is 2.0.7 These are the Package(s) required: Samba Homepage: http://us1.samba.org/samba/samba.html Samba FTP Site: 63.238.153.11 You must be sure to download: samba-2.0.7.tar.gz Before you decompress the tarballs, It is a good idea to make a list of files on the system before you install Samba, and one afterwards, and then compare them using diff to find out what file it placed where. Simply run find /* > Samba1 before and find /* > Samba2 after you install the software, and use diff Samba1 Samba2 > Samba-Installed to get a list of what changed. To compile, decompress the tarball (tar.gz): [root@deep ] /# cp samba-version.tar.gz /var/tmp [root@deep ] /# cd /var/tmp [root@deep ]/tmp# tar xzpf samba-version.tar.gz 2. Configure Samba Move into the new Samba directory, and move into its source subdirectory. 1. Edit the smbsh.in file, vi smbwrapper/smbsh.in and change the line: SMBW_LIBDIR=${SMBW_LIBDIR-@builddir@/smbwrapper} To read: SMBW_LIBDIR=${SMBW_LIBDIR-/usr/bin} This change will relocate the lib directory of Samba to be under the /usr/ bin directory. 2. Edit the Makefile.in file, vi Makefile.in and change the line: a. SBINDIR = @bindir@ To read: SBINDIR = @sbindir@ b. VARDIR = @localstadir@ To read: VARDIR = /var/log/samba This will specify that our sbin directory for the Samba binaries files will be located in the /usr/sbin directory, and that the /var directory for Samba log files will be under the /var/log/samba subdirectory. 3. Edit the convert_smbpasswd file, vi script/convert_smbpasswd and change the line: nawk 'BEGIN {FS=":"} To: gawk 'BEGIN {FS=":"} This will specify to use the GNU Linux version of the awk text processing utility instated of the Bell Labs research version of awk program for the smbpasswd file. 4. Edit the smbmount.c file, vi client/smbmount.c and change the lines: static void close_our_files(int client_fd) { int i; for (i = 0; i < 256; i++) { if (i == client_fd) continue; close(i); } To read: static void close_our_files(int client_fd) { struct rlimit limits; int i; getrlimit(RLIMIT_NOFILE,&limits); for (i = 0; i < limits.rlim_max; i++) { if (i == client_fd) continue; close(i); } This step will make the smbmount.c file compatible with Red Hat's glibc 2.1 library. 3. Compile and optimize Type the following commands on your terminal: CC="egcs" \ ./configure \ --prefix=/usr \ --libdir=/etc \ --with-lockdir=/var/lock/samba \ --with-privatedir=/etc \ --with-swatdir=/usr/share/swat \ --with-pam \ --with-mmap \ --without-sambabook Caution The option --with-mmap can give a large performance boost on some machines, while on others it makes no difference at all, and on some it may reduce performance. This tells Samba to set itself up for this particular hardware setup with: i. Include PAM password database support for better security. ii. Include experimental MMAP support to improve Samba performance. iii. Don't install the book help that come with Samba distribution. Now, we must install Samba in the Linux server: [root@deep ] /source# make all [root@deep ] /source# make install [root@deep ] /source# install -m 755 script/mksmbpasswd.sh /usr/bin/ [root@deep ] /source# rm -rf /usr/share/swat/ 1 [root@deep ] /source# rm -f /usr/sbin/swat [root@deep ] /source# rm -f /usr/man/man8/swat.8 [root@deep ] /source# mkdir -p /var/lock/samba [root@deep ] /source# mkdir -p /var/spool/samba 2 [root@deep ] /source# chmod 1777 /var/spool/samba/ 3 _1_ If like me, you don't like to configure Samba in HTML. _2_ Only require if you are the intention to use printer sharing. _3_ Only require if you are the intention to use printer sharing. * The install command will install the script mksmbpasswd.sh under /usr/bin/ directory. This script is needed to setup Samba users allowed to connect on our server via the smbpasswd file. See later in this documentation for how to setup and use Samba password. * The rm command will remove the /usr/share/swat directory and all the files under it, and it will also remove the swat binary program under /usr/sbin/. The SWAT program is a web-based configuration utility that permits you to configure the smb.conf file of Samba via a web browser interface. Of course, in order to use the SWAT utility you will need to have a web server running, such as Apache. The SWAT utility can open a security breach on your server and for this reason I recommend that you remove and not use it. * The mkdir command will create a /var/spool/samba/ directory on your system for all print sharing jobs you may have. Of course this directory is only necessary if you intend to use Samba print sharing over your LAN. Since we have not configured our Samba server to use print sharing, we do not need to create this directory, /var/spool/samba/ on our server, and we do not need to use the command chmod to change the sticky bit in /var/spool/samba so only the file's owner can delete a given file in this directory. Please do cleanup later: [root@deep ] /# cd /var/tmp [root@deep ]/tmp# rm -rf samba-version/ samba-version.tar.gz The rm command will remove all the source files we have used to compile and install Samba. It will also remove the Samba compressed archive from the /var/ tmp directory. 4. Configurations Configuration files for different services are very specific, depending on your need and your network architecture. Someone could install Samba Server and have just one client connection, and another could install it with 1000 connections. Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example Samba configuration file are organised like this: total 28 -rw-r--r-- 1 harrypotter harrypotter 196 Jun 8 13:00 Compile-Samba drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 init.d/ -rw-r--r-- 1 harrypotter harrypotter 94 Jun 8 13:00 lmhosts drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 logrotate.d/ drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 pam.d/ -rwx------ 1 harrypotter harrypotter 282 Jun 8 13:00 samba.sh* -rw-r--r-- 1 harrypotter harrypotter 1157 Jun 8 13:00 smb.conf You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run a Samba server, the following files are required and must be created or copied to the appropriate directories on your server. i. Copy the smb.conf and lmhosts files in the /etc/ directory. ii. Copy the smb script file in the /etc/rc.d/init.d/ directory. iii. Copy the samba file in the /etc/logrotate.d/ directory. iv. Copy the samba file in the /etc/pam.d/ directory. Tip To run Samba, the following file from the floppy.tgz archive is required and must be created or copied to the appropriate directory on your server. Copy the *.conf file to the /etc/ directory. or alternatively you can copy and paste directly from this book to the concerned file. 5. Configuration of the /etc/smb.conf file The /etc/smb.conf file is the main configuration file for the Samba server, in which you can specify which directory you want to access from Windows machines, which IP addresses are authorized, and so on. The first few lines of the file under the [global] line contain global configuration directives, which are common to all shares, unless they are over-ridden on a per-share basis, followed by share sections. A lot of options exist, and it's important to read the documentation that comes with Samba for more information on each of the different settings and parameters. The following configuration example is a minimal working configuration file for Samba with encrypted password support. Also, it's important to note that we comment in this Samba configuration only parameters that relate to security and optimization, and left other posiblities for you to explore. In our example we have created just one directory, [tmp] and have allowed only class C machine IP address ranges to connect on the Samba server. Also, we don't use print-sharing capability between Samba and Windows on this server. Edit the smb.conf file, vi /etc/smb.conf and add/change the following parameters: [global] workgroup = OPENNA server string = R&D of Open Network Architecture Samba Server encrypt passwords = True security = user smb passwd file = /etc/smbpasswd log file = /var/log/samba/log.%m socket options = IPTOS_LOWDELAY TCP_NODELAY domain master = Yes local master = Yes preferred master = Yes os level = 65 dns proxy = No name resolve order = lmhosts host bcast bind interfaces only = True interfaces = eth0 192.168.1.1 hosts deny = ALL hosts allow = 192.168.1.4 127.0.0.1 debug level = 1 create mask = 0644 directory mask = 0755 level2 oplocks = True read raw = no write cache size = 262144 [homes] comment = Home Directories browseable = no read only = no invalid users = root bin daemon nobody named sys tty disk mem kmem users [tmp] comment = Temporary File Space path = /tmp read only = No valid users = admin invalid users = root bin daemon nobody named sys tty disk mem kmem users This tells the smb.conf file to set itself up for this particular configuration setup with: [global].  workgroup = OPENNA The option workgroup specifies the workgroup your server will appear to be in when queried by clients. It's important to have the same workgroup name on both clients and servers. server string = R&D of Open Network Architecture Samba Server The option server string specifies the string that you wish to show to your users in the printer comment box in print manager, or to the IPC connection in the net view command under Windows machines. encrypt passwords = True The option encrypt passwords if set to True instructs Samba to use encrypted passwords instead of plain text password when negotiating with the client. Sniffer program will not be able to detect your password when it is encrypted. This option always must be set to True for security reasons. security = user The option security, if set to user, specifies that a client must first log-on with a valid username and password, or the connection will be refused. This means that a valid username and password for the client must exit in your /etc/passwd file on the Linux server and in the /etc/ smbpasswd file of the Samba server, or the connection from the client will fail. See Securing_samba in this chapter for more information about the smbpasswd file. smb passwd file = /etc/smbpasswd The option smb passwd file specifies the path to the encrypted smbpasswd file. The smbpasswd file is a copy of the /etc/passwd file of the Linux system containing valid usernames and passwords of clients allowed to connect to the Samba server. The Samba software reads this file, smbpasswd when a connection is requested. log file = /var/log/samba/log.%m The option log file specifies the locations and names of Samba log files. With the name extension %m, it allows you to have separate log files for each user or machine that logs on your Samba server i.e. log.machine1. socket options = IPTOS_LOWDELAY TCP_NODELAY The option socket options specifies parameters that you can include in your Samba configuration to tune and improve your samba server for optimal performance. By default we chose to tune the connection for a local network, and improve the performance of the Samba server for transferring files. domain master = Yes The option domain master specifies to set nmbd, the Samba server daemon, as a domain master browser for its given workgroup. This option usually must be set to Yes only on one Samba server for all other Samba servers on the same network and workgroup. local master = Yes The option local master allows nmbd, the Samba server daemon, to try to become a local master browser on a subnet. Like the above, usually this option must be set to Yes only on one Samba server that acts as a local master on a subnet for all the other Samba servers on your network. preferred master = Yes The option preferred master specifies and controls if nmbd the Samba server daemon, is a preferred master browser for its workgroup. Once again, this must usually be set to Yes on one server for all the others on your network. os level = 65 The option os level specifies by its value whether nmbd, the Samba server daemon, has a chance of becoming a local master browser for the Workgroup in the local broadcast area. The number 65 will win against any NT Server. If you have an NT Server on your network, and want to set your Linux Samba server to be a local master browser for the Workgroup in the local broadcast area then you must set the os level option to 65. Also, this option must be set only on one Linux Samba server, and must be disabled on all other Linux Samba servers you may have on your network. dns proxy = No The option dns proxy if set to Yes specifies that nmbd, the Samba server daemon, when acting as a WINS server and finding that a Net BIOS name has not been registered, should treat the Net BIOS name word-for-word as a DNS name and do a lookup with the DNS server for that name on behalf of the name-querying client. Since we have not configured the Samba server to act as a WINS server, we don't need to set this option to Yes. Also, setting this option to Yes will degrade your Samba performance. name resolve order = lmhosts host bcast The option name resolve order specifies what naming services to use in order to resolve host names to IP addresses, and in what order. The parameters we chose cause the local lmhosts file of samba to be examined first, followed by the rest. bind interfaces only = True The option bind interfaces only if set to True, allows you to limit what interfaces will serve smb requests. This is a security feature. The configuration option interfaces = eth0 192.168.1.1 below completes this option. interfaces = eth0 192.168.1.1 The option interfaces allows you to override the default network interface list that Samba will use for browsing, name registration and other NBT traffic. By default, Samba will query the kernel for the list of all active interfaces and use any interface, except 127.0.0.1, that is broadcast capable. With this option, Samba will only listen on interface eth0 on the IP address 192.168.1.1. This is a security feature, and completes the above configuration option bind interfaces only = True. hosts deny = ALL The option hosts deny specifies the list of hosts that are not permitted access to Samba services unless the specific services have their own lists to override this one. For simplicity, we deny access to all hosts by default, and allow specific hosts in the hosts allow = option below. hosts allow = 192.168.1.4 127.0.0.1 The option hosts allow specifies which hosts are permitted to access a Samba service. By default, we allow hosts from IP class C 192.168.1.4 and our localhost 127.0.0.1 to access the Samba server. Note that the localhost must always be set or you will receive some error messages. debug level = 1 The option debug level allows the logging level to be specified in the smb.conf file. If you set the debug level higher than 2 then you may suffer a large drop in performance. This is because the server flushes the log file after each operation, which can be very expensive. create mask = 0644 The option create mask specifies and sets the necessary permissions according to the mapping from DOS modes to UNIX permissions. With this option set to 0644, all file copying or creating from a Windows system to the Unix system will have a permission of 0644 by default. directory mask = 0755 The option directory mask specifies and set the octal modes, which are used when converting DOS modes to UNIX modes when creating UNIX directories. With this option set to 0755, all directory copying or creating from a Windows system to the Unix system will have a permission of 0755 by default. level2 oplocks = True The option level2 oplocks, if set to True, will increase the performance for many accesses of files that are not commonly written, such as .EXE application files. read raw = no The option read raw controls whether or not the server will support the raw read SMB requests when transferring data to clients. Note that memory mapping is not used by the read raw operation. Thus, you may find memory mapping is more effective if you disable read raw using read raw = no, like we do. write cache size = 262144 The option write cache size allows Samba to improve performance on systems where the disk subsystem is a bottleneck. The value of this option is specified in bytes, and a size of 262,144 represent a 256k cache size per file. [tmp].  comment = Temporary File Space The option comment allows you to specify a comment that will appear next to a share when a client does queries to the server. path = /tmp The option path specifies a directory to which the user of the service is to be given access. In our example this is the tmp directory of the Linux server. read only = No The option read only specifies if users should be allowed to only read files or not. In our example, since this is a configuration for the tmp directory of the Linux server, users can do more than just read files. valid users = admin The option valid users specifies a list of users that should be allowed to login to this service. In our example only the user admin is allowed to access the service. invalid users = root bin daemon nobody named sys tty disk mem kmem users The option invalid users specifies a list of users that should not be allowed to login to this service. This is really a paranoid check to absolutely ensure an improper setting does not breach your security. It is recommended that you include all default users that run daemons on the server. 6. Configure the /etc/lmhosts file Configure your /etc/lmhosts file. The lmhosts file is the Samba Net BIOS name to IP address mapping file. It is very similar to the /etc/hosts file format, except that the hostname component must correspond to the Net BIOS naming format. Create the lmhosts file, touch /etc/lmhosts and add your client hosts: # Sample Samba lmhosts file. # 127.0.0.1 localhost 192.168.1.1 deep 192.168.1.4 win In our example, this file contains three IP to Net BIOS name mappings. The localhost, 127.0.0.1, client named deep, 192.168.1.1 and client named win, 192.168.1.4. 6.1. Configure the /etc/pam.d/samba file Configure your /etc/pam.d/samba file to use pam authentication by creating the samba file, touch /etc/pam.d/samba and add the following lines: Auth required /lib/security/pam_pwdb.so nullok shadow Account required /lib/security/pam_pwdb.so 6.1.1. Configure the /etc/logrotate.d/samba file Configure your /etc/logrotate.d/samba file to rotate each week your log files automatically. Create the samba file, touch /etc/logrotate.d/samba and add the following lines: /var/log/samba/log.nmb { notifempty missingok postrotate /usr/bin/killall -HUP nmbd endrotate } /var/log/samba/log.smb { notifempty missingok postrotate /usr/bin/killall -HUP smbd endrotate } 7. Encrypted Samba password file for clients The /etc/smbpasswd file is the Samba encrypted password file. It contains the username; Unix UID and SMB hashed passwords of the allowed users to your Samba server, as well as account flag information and the time the password was last changed. It's important to create this password file and include all allowed users to it before your clients try to connect to your Samba server. Without this step, no one will be able to connect to your Samba server. 1. To create a Samba account you must first have a valid Linux account for them, so create in your etc/passwd file all the users you want to connect to your Samba server first before generating the smbpasswd file of Samba. a. To add a new users to your /etc/passwd file, use the following commands: [root@deep ] /# useradd smbclient b. To add password for users in your /etc/passwd file, use the following commands: [root@deep ] /# passwd smbclient Changing password for user smbclient New UNIX password: Retype new UNIX password: passwd: all authentication tokens updated successfully 2. Once we have added all Samba clients in our /etc/passwd file on the Linux server, we can now generate the smbpasswd file from the /etc/passwd file. To generate smbpasswd file from the /etc/passwd file, use the following commands: [root@deep ] /# cat /etc/passwd | mksmbpasswd.sh > /etc/ smbpasswd 3. Finally, the last step we must perform is to create the Samba user account in our /etc/smbpasswd file before we are able to use it. To create the Samba user account, use the following commands: [root@deep ] /# smbpasswd -a smbclient 1 _1_ Remember that smbclient must be a valid Linux account. New SMB password: Retype new SMB password: Added user smbclient. Password changed for user smbclient. 4. Don't forget to change the permission of your new smbpasswd file to be readable and writable only by the super-user root, and nothing for group and other 0600/-rw------- This is a security measure. [root@deep ] /# chmod 600 /etc/smbpasswd [root@deep ] /# testparm 1 _1_ This will verify the smb.conf file for error. See ENCRYPTION.txt in samba/doc/texts/ for more information. 8. Optimizing Samba It is a big mistake to set the wide links Samba parameter to no in the Samba configuration file /etc/smb.conf. This option, if set to no, tells Samba not to follow symbolic links outside of an area designated as being exported as a share point. In order to determine if a link points outside the shared area, Samba has to follow the link and then do a directory path lookup to determine where on the file system the link ended up. This ends up adding a total of six extra system calls per filename lookup, and Samba looks up filenames a lot. A test done was published that showed that setting this parameter will cause a 25 to 30 -percent slowdown in Samba performance. 8.1. Tuning the buffer cache The modification of the filesystem cache-tuning parameters can significantly improve Linux's file-serving performance up to a factor of two. Linux will attempt to use memory not being used for any other purpose for filesystem caching. A special daemon, called bdflush, will periodically flush dirty buffers, buffers that contain modified filesystem data or metadata to the disk. The secret to good performance is to keep as much of the data in memory for as long as is possible. Writing to the disk is the slowest part of any filesystem. If you know that the filesystem will be heavily used, then you can tune this process for Linux Samba. As with many kernel tuneable options, this can be done on the fly by writing to special files in the /proc filesystem. The trick is, you have to tell Linux you want it to do that. You do so by executing the following command for a Linux 2.2 kernel. The default setup for the bdflush parameters under Red Hat Linux is: "40 500 64 256 500 3000 500 1884 2" To change the values of bdflush, type the following command on your terminal: Under Version 6.1 [root@deep ] /# echo "80 500 64 64 15 6000 6000 1884 2" >/proc/sys/ vm/bdflush You may add the above commands to the /etc/rc.d/rc.local script file and you'll not have to type it again the next time you reboot your system. Under Version 6.2 Edit the /etc/sysctl.conf file and add the following line: # Improve file system performance vm.bdflush = 80 500 64 64 15 6000 6000 1884 2 You must restart your network for the change to take effect. The command to restart the network is the following: [root@deep ] /# /etc/rc.d/init.d/network restart Setting network parameters [ OK ] Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Bringing up interface eth1 [ OK ] This line tells bdflush not to worry about writing out dirty blocks to the disk until the filesystem buffer cache is 80 percent full (80). The other values tune such things as the number of buffers to write out in one disk operation (500), how long to allow dirty buffers to age in the kernel (60*HZ), etc. You can find full details in the 2.2 kernel documentation in the file linux/ Documentation/sysctl/vm.txt, and also, you can check General_System Optimization, for more information. 9. Tuning the buffermem Another helpful tuning hint is to tell Linux the following: Use a minimum of 60 percent of memory for the buffer cache; only prune when the percentage of memory used for the buffer cache gets over 10 percent (this parameter is now unused); and allow the buffer cache to grow to 60 percent of all memory (this parameter is also unused now). The default setup for the buffermem parameters under Red Hat Linux is: "2 10 60" Under Version 6.1 To change the values of buffermem, type the following command on your terminal: [root@deep ] /# echo "60 10 60" >/proc/sys/vm/buffermem You can put the above command in the /etc/rc.d/rc.local script file and avoid typing it again the next time your system reboots. You can find full details in the 2.2 kernel documentation in the file linux/Documentation/sysctl/vm.txt a nd also, you can check General_System_Optimization, for more information. Under Version 6.2 Edit the /etc/sysctl.conf file and add the following line: # Improve virtual memory performance vm.buffermem = 60 10 60 You must restart your network for the change to take effect. The command to restart the network is the following: [root@deep ] /# /etc/rc.d/init.d/network restart Setting network parameters [ OK ] Bringing up interface lo [ OK ] Bringing up interface eth0 [ OK ] Bringing up interface eth1 [ OK ] Recall that the last two parameters, 10 and 60 are unused by the system so we don't need to change the default ones. 10. Further documentation For more details, there are several man pages you can read: Samba(7) A Windows SMB/CIFS fileserver for UNIX smb.conf(5) The configuration file for the Samba suite smbclient(1) ftp-like client to access SMB/CIFS resources on servers smbd(8) server to provide SMB/CIFS services to clients smbmnt(8) mount smb file system smbmount(8) mount smb file system smbpasswd(5) The Samba encrypted password file smbpasswd(8) change a users SMB password smbrun(1) interface program between smbd and external programs smbsh(1) Allows access to Windows NT filesystem using UNIX commands smbstatus(1) report on current Samba connections smbtar(1) shell script for backing up SMB shares directly to UNIX tape drives smbumount(8) umount for normal users testparm(1) check an smb.conf configuration file for internal correctness testprns(1) check printer name for validity with smbd 11. Samba Administrative Tools The commands listed below are some that we use often, but many more exist. Check the man pages and documentation for more details and information. smbstatus.  The smbstatus utility is a very simple program to list the current Samba connections. To report current Samba connections, use the following command: [root@deep ] /# smbstatus Samba version 2.0.7 Service uid gid pid machine ---------------------------------------------- tmp webmaster webmaster 3995 gate (192.168.1.3) Sat Sep 25 19:40:54 1999 No locked files Share mode memory usage (bytes): 1048464(99%) free + 56(0%) used + 56(0%) overhead = 1048576(100%) total 11.1. Samba Users Tools The commands listed below are some that we use often, but many more exist. Check the man pages and documentation for more details and information. smbclient.  The smbclient program utility for Samba works much like the interface of the FTP program. This small program allow you to get files from the server to the local machine, put files from the local machine to the server, retrieve directory information from the server, and so on. To connect to a Windows machine with smbclient utility, use the following command: [root@deep ] /# smbclient //sbmserver/sharename -U smbclient [root@deep ] /# smbclient //gate/tmp -U smbclient Password: Domain=[OPENNA] OS=[Windows NT 4.0] Server=[NT LAN Manager 4.0] smb: \> ls . D 0 Tue Mar 14 15:31:50 2000 .. D 0 Tue Mar 14 15:31: 50 2000 PostgreSQL D 0 Tue Mar 14 15:32: 22 2000 Squid D 0 Tue Mar 14 15:32: 28 2000 E_comm D 0 Tue Mar 14 15:32: 42 2000 StackGuard.pdf A 61440 Tue Dec 21 20: 41:34 1999 installation-without-XFree86 A 448 Tue Dec 21 20:41:28 1999 lcap-0_0_3-2_src.rpm A 13481 Thu Jan 13 01: 50:12 2000 mirc561t.exe A 948224 Tue Dec 21 20:41: 54 1999 65510 blocks of size 32768. 5295 blocks available smb: \> Where //sbmserver is the name of the server you want to connect to. /sharename is the directory on this server you want to connect to, and smbclient is your username on this machine. 12. The /etc/rc.d/init.d/smb script file Configure your /etc/rc.d/init.d/smb script file to start and stop Samba smbd and nmbd daemons Server automaticaly. Create the smb script file, touch /etc/ rc.d/init.d/smb and add the following lines: #!/bin/sh # # chkconfig: - 91 35 # description: Starts and stops the Samba smbd and nmbd daemons \ # used to provide SMB network services. # Source function library. . /etc/rc.d/init.d/functions # Source networking configuration. . /etc/sysconfig/network # Check that networking is up. [ ${NETWORKING} = "no" ] && exit 0 # Check that smb.conf exists. [ -f /etc/smb.conf ] || exit 0 RETVAL=0 # See how we were called. case "$1" in start) echo -n "Starting SMB services: " daemon smbd -D RETVAL=$? echo echo -n "Starting NMB services: " daemon nmbd -D RETVAL2=$? echo [ $RETVAL -eq 0 -a $RETVAL2 -eq 0 ] && touch /var/lock/subsys/ smb || \ RETVAL=1 ;; stop) echo -n "Shutting down SMB services: " killproc smbd RETVAL=$? echo echo -n "Shutting down NMB services: " killproc nmbd RETVAL2=$? [ $RETVAL -eq 0 -a $RETVAL2 -eq 0 ] && rm -f /var/lock/subsys/ smb echo "" ;; restart) $0 stop $0 start RETVAL=$? ;; reload) echo -n "Reloading smb.conf file: " killproc -HUP smbd RETVAL=$? echo ;; status) status smbd status nmbd RETVAL=$? ;; *) echo "Usage: $0 {start|stop|restart|status}" exit 1 esac exit $RETVAL Now, make this script executable and change its default permissions: [root@deep ] /# chmod 700 /etc/rc.d/init.d/smb Create the symbolic rc.d links for Samba with the command: [root@deep ] /# chkconfig --add smb Samba script will not automatically start the smbd and nmbd daemon when you reboot the server. You can change it to do this by default by executing the following command: [root@deep ] /# chkconfig --level 345 smb on Start your Samba Server manually with the following command: [root@deep ] /# /etc/rc.d/init.d/smb start Starting SMB services: [ OK ] Starting NMB services: [ OK ] 12.1. Securing Samba Immunize important configuration files, the immutable bit can be used to prevent accidentally deleting or overwriting a file that must be protected. It also prevents someone from creating a symbolic link to this file. Once your smb.conf and lmhosts files have been configured, it's a good idea to immunize them with a command like: [root@deep ] /# chattr +i /etc/smb.conf [root@deep ] /# chattr +i /etc/lmhosts 13. Installed files These are the files installed by Samba software on your sytem. /etc/rc.d/init.d/smb /etc/rc.d/rc0.d/K35smb /etc/rc.d/rc1.d/K35smb /etc/rc.d/rc2.d/K35smb /etc/rc.d/rc3.d/S91smb /etc/rc.d/rc4.d/S91smb /etc/rc.d/rc5.d/S91smb /etc/rc.d/rc6.d/K35smb /etc/pam.d/samba /etc/logrotate.d/samba /etc/codepages /etc/codepages/ codepage.437 /etc/codepages/ /etc/codepages/ /etc/codepages/ unicode_map.437 codepage.737 unicode_map.737 /etc/codepages/ /etc/codepages/ /etc/codepages/ codepage.775 codepage.850 unicode_map.850 /etc/codepages/ /etc/codepages/ /etc/codepages/ codepage.852 unicode_map.852 codepage.861 /etc/codepages/ /etc/codepages/ /etc/codepages/ unicode_map.861 codepage.932 unicode_map.932 /etc/codepages/ /etc/codepages/ /etc/codepages/ codepage.866 unicode_map.866 codepage.949 /etc/codepages/ /etc/codepages/ /etc/codepages/ unicode_map.949 codepage.950 unicode_map.950 /etc/codepages/ /etc/codepages/ /etc/codepages/ codepage.936 unicode_map.936 codepage.1251 /etc/codepages/ /etc/codepages/ /etc/codepages/ unicode_map.ISO8859-1 unicode_map.ISO8859-2 unicode_map.ISO8859-5 /etc/codepages/ /etc/codepages/ /etc/lmhosts unicode_map.ISO8859-7 unicode_map.KOI8-R /etc/smb.conf /etc/smbpasswd /etc/gshadow- /usr/bin/smbclient /usr/bin/smbspool /usr/bin/testparm /usr/bin/testprns /usr/bin/smbstatus /usr/bin/rpcclient /usr/bin/smbpasswd /usr/bin/make_smbcodepage /usr/bin/make_unicodemap /usr/bin/nmblookup /usr/bin/make_printerdef /usr/bin/smbtar /usr/bin/addtosmbpass /usr/bin/convert_smbpasswd /usr/bin/mksmbpasswd.sh /usr/man/man1/ /usr/man/man1/ /usr/man/man1/nmblookup.1 make_smbcodepage.1 make_unicodemap.1 /usr/man/man1/smbclient.1 /usr/man/man1/smbrun.1 /usr/man/man1/smbsh.1 /usr/man/man1/smbstatus.1 /usr/man/man1/smbtar.1 /usr/man/man1/testparm.1 /usr/man/man1/testprns.1 /usr/man/man5/lmhosts.5 /usr/man/man5/smb.conf.5 /usr/man/man5/smbpasswd.5 /usr/man/man7/samba.7 /usr/man/man8/nmbd.8 /usr/man/man8/smbd.8 /usr/man/man8/smbmnt.8 /usr/man/man8/smbmount.8 /usr/man/man8/smbpasswd.8 /usr/man/man8/smbspool.8 /usr/man/man8/smbumount.8 /usr/sbin/smbd /usr/sbin/nmbd /var/log/samba /var/lock/samba     Chapter 32. Linux FTP Server Table of Contents 1._chroot'd_Guest_FTP_access 2._Setup_an_FTP_user_account_minus_shells 3._Setup_a_chroot_user_environment 4._Configurations 5._Configure_the_/etc/ftphosts_file 5.1._Configure_the_/etc/ftpusers_file 6._Configure_the_/etc/ftpconversions_file 6.1._Configure_the_/etc/pam.d/ftp_file 7._Configure_the_/etc/logrotate.d/ftpd_file 7.1._Configure_ftpd_to_use_tcp-wrappers_inetd 8._FTP_Administrative_Tools 9._Securing_FTP 10._The_special_file_.notar 11._Installed_files Despite its age, using the File Transfer Protocol, FTP is one of the most popular way to transfer files from machine to machine across a network. Clients and servers have been written for almost all popular platforms in the market, thereby making FTP the most convenient way to perform file transfers. 1. chroot'd Guest FTP access Various methods exist to configure your FTP servers. One is as a private user- only site, which is the default configuration for an FTP server; a private FTP server allows users on the Linux system only to be able to connect via FTP and access their files. Anohter method is to configure as an anonymous FTP server. An anonymous FTP server allows anyone on the network to connect to it and transfer files without having an account. Due to the potential security risk involved with this setup, precautions should be taken to allow access only to certain directories on the system. The configuration we will cover here is an FTP server that allows FTP to semi- secure areas of a Unix file system, chroot'd Guest FTP access. This configuration allows users to have access to the FTP server directories without allowing them to get into higher levels. This is the most secure setup for an FTP server. FTP These installation instructions assume * Commands are Unix-compatible. * The source path is /var/tmp, other paths are possible. * Installations were tested on Red Hat Linux 6.1 and 6.2. * All steps in the installation will happen in super-user account root. * wu-ftpd version number is 2.6.0 These are the Package(s): Wu-ftpd Homepage:http://www.wu-ftpd.org/ Wu-ftpd FTP Site:205.133.13.68 You must be sure to download: wu-ftpd-2.6.0.tar.gz To compile, you need to decompress the tarball, tar.gz. [root@deep ] /# cp wu-ftpd-version.tar.gz /var/tmp [root@deep ] /# cd /var/tmp [root@deep ]/tmp# tar xzpf wu-ftpd-version.tar.gz 2. Setup an FTP user account minus shells It's important to give to your strictly FTP users no real shell account on the Linux system. In this manner, if for any reasons someone could successfully get out of the FTP chrooted environment, it would not have the possibility of executing any user tasks since it doesn't have a bash shell. First, create new users for this purpose; These users will be the users allowed to connect to your FTP server. This has to be separate from a regular user account with unlimited access because of how the chroot environment works. Chroot makes it appear from the user's perspective as if the level of the file system you've placed them in is the top level of the file system. Use the following command to create users in the /etc/passwd file. This step must be done for each additional new user you allow to access your FTP server. [root@deep ] /# mkdir /home/ftp [root@deep ] /# useradd -d /home/ftp/ftpadmin/ -s /dev/null ftpadmin > /dev/null 2>&1 [root@deep ] /# passwd ftpadmin Changing password for user ftpadmin New UNIX password: Retype new UNIX password: passwd: all authentication tokens updated successfully * The mkdir command will create the ftp directory under the /home directory to handle all FTP users' home directories we'll have on the server. * The useradd command will add the new user named ftpadmin to our Linux server. * Finally, the passwd command will set the password for this user ftpadmin. Once the home/ftp/ directory has been created you don't have to use this command again for additional FTP users. 1. Edit the /etc/shells file, vi /etc/shells and add a non-existent shell name like null, for example. This fake shell will limit access on the system for FTP users. [root@deep ] /# vi /etc/shells /bin/bash /bin/sh /bin/ash /bin/bsh /bin/tcsh /bin/csh /dev/null /dev/null, This is our added no-existent shell. With Red Hat Linux, a special device name /dev/null exists for purposes such as these. 2. Now, edit your /etc/passwd file and add manually the /./ line to divide the /home/ftp directory with the /ftpadmin directory where the user ftpadmin should be automatically chdir'd to. This step must be done for each FTP user you add to your passwd file. ftpadmin:x:502:502::/home/ftp/ftpadmin/:/dev/null To read: ftpadmin:x:502:502::/home/ftp/./ftpadmin/:/dev/null ^^ The account is ftpadmin, but you'll notice the path to the home directory is a bit odd. The first part /home/ftp/ indicates the filesystem that should be considered their new root directory. The dot . divides that from the directory they should be automatically chdir'd. change directory'd into, /ftpadmin/. Once again, the /dev/null part disables their login as a regular user. With this modification, the user ftpadmin now has a fake shell instead of a real shell resulting in properly limited access on the system. 3. Setup a chroot user environment What you're essentially doing is creating a skeleton root file system with enough components necessary, binaries, password files, etc. to allow Unix to do a chroot when the user logs in. Note that if you use the --enable-ls option during compilation as seen above, the /home/ftp/bin, and /home/ftp/lib directories are not required since this new option allows Wu-ftpd to use its own ls function. We still continue to demonstrate the old method for people that prefer to copy /bin/ls to the chroot'd FTP directory, /home/ftp/bin and create the appropriated library related to ls. FTP chrooted The following are the necessary steps to run Wu-ftpd software in a chroot jail: First create all the necessary chrooted environment directories as shown below: [root@deep ] /# mkdir /home/ftp/dev [root@deep ] /# mkdir /home/ftp/etc [root@deep ] /# mkdir /home/ftp/bin 1 [root@deep ] /# mkdir /home/ftp/lib 2 _1_ Require only if you are not using the --enable-ls option. _2_ Require only if you are not using the --enable-ls option Change the new directories permission to 0511 for security reasons: The chmod command will make our chrooted dev, etc, bin, and lib directories readable and executable by the super-user root and executable by the user-group and all users. [root@deep ] /# chmod 0511 /home/ftp/dev/ [root@deep ] /# chmod 0511 /home/ftp/etc/ [root@deep ] /# chmod 0511 /home/ftp/bin 1 [root@deep ] /# chmod 0511 /home/ftp/lib 2 _1_ Require only if you are not using the --enable-ls option. _2_ Require only if you are not using the --enable-ls option. 1. Copy the /bin/ls binary to /home/ftp/bin directory and change the permission of the ls program to 0111. You don't want users to be able to modify the binaries: [root@deep ] /# cp /bin/ls /home/ftp/bin 1 [root@deep ] /# chmod 0111 /bin/ls /home/ftp/bin/ls 2 _1_ Require only if you are not using the --enable-ls option. _2_ Require only if you are not using the --enable-ls option. This step is necessary only if you're not using the --enable-ls option during the configure time of Wu-ftpd. See the Compile_and_Optimize section in this chapter for more information. 2. Find the shared library dependencies of the ls Linux binary program: a. [root@deep ] /# ldd /bin/ls 1 _1_ Require only if you are not using the --enable-ls option. libc.so.6 => /lib/libc.so.6 (0x00125000) /lib/ld-linux.so.2 =7gt; /lib/ld-linux.so.2 (0x00110000) b. Copy the shared libraries identified above to your new lib directory under /home/ftp directory: [root@deep ] /# cp /lib/libc.so.6 /home/ftp/lib/ 1 [root@deep ] /# cp /lib/ld-linux.so.2 /home/ftp/ lib/ 2 _1_ Require only if you are not using the --enable-ls option _2_ Require only if you are not using the --enable-ls option c. Caution These library are needed to make ls work. Also, steps 3 and 4 above are required only if you want to use the ls Linux binary program instead of the --enable-ls option that uses the new internal ls capability of Wu-ftpd. 3. Create your /home/ftp/dev/null file: [root@deep ] /# mknod /home/ftp/dev/null c 1 3 [root@deep ] /# chmod 666 /home/ftp/dev/null 4. Copy the group and passwd files in /home/ftp/etc directory. This should not be the same as your real ones. For this reason, we'll remove all non FTP users except for the super-user root in both of these files, passwd and group. a. [root@deep ] /# cp /etc/passwd /home/ftp/etc/ [root@deep ] /# cp /etc/group /home/ftp/etc/ b. Edit the passwd file, vi /home/ftp/etc/passwd and delete all entries except for the super-user root and your allowed FTP users. It is very important that the passwd file in the chroot environment has entries like: root:x:0:0:root:/:/dev/null ftpadmin:x:502:502::/ftpadmin/:/dev/null c. Note We can notice two things here: first, the home directory for all users inside this modified passwd file are now changed to reflect the new chrooted FTP directory i.e. /home/ftp/./ftpadmin/ begins / ftpadmin/, and also, the name of the user's login shell for the root account has been changed to /dev/null. d. Edit the group file, vi /home/ftp/etc/group and delete all entries except for the super-user root and all your allowed FTP users. The group file should correspond to your normal group file: root:x:0:root ftpadmin:x:502: 5. Now we must set passwd, and group files in the chroot jail directory immutable for better security. a. [root@deep ] /# cd /home/ftp/etc/ [root@deep ] /# chattr +i passwd b. Set the immutable bit on group file: [root@deep ] /# cd /home/ftp/etc/ [root@deep ] /# chattr +i group 4. Configurations Note All the configuration files required for each software described in this book has been provided by us as a gzipped file, floppy.tgz for your convenience. This can be downloaded from this web address: http://www.openna.com/books/ floppy.tgz You can unpack this to any location on your local machine, say for example /tmp, assuming you have done this your directory structure will be / tmp/floppy. Within this floppy directory each configuration file has its own directory for respective software. For example FTP configuration file are organised like this: total 32 -rw-r--r-- 1 harrypotter harrypotter 419 Jun 8 13:00 Compile-Wuftpd -rw------- 1 harrypotter harrypotter 1036 Jun 8 13:00 ftpaccess -rw------- 1 harrypotter harrypotter 538 Jun 8 13:00 ftpconversions -rw------- 1 harrypotter harrypotter 39 Jun 8 13:00 ftpgroups -rw------- 1 harrypotter harrypotter 188 Jun 8 13:00 ftphosts -rw------- 1 harrypotter harrypotter 79 Jun 8 13:00 ftpusers drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 logrotate.d/ drwxr-xr-x 2 harrypotter harrypotter 4096 Jun 8 13:00 pam.d/ You can either cut and paste this directly if you are faithfully following our instructions from the begining or manually edit these to modify to your needs. This facility is there though as a convenience but please don't forget ultimately it will be your responsibility to check, verify, etc. before you use them whether modified or as it is. To run an FTP server, the following files are required and must be created or copied to the appropriate directories on your server. i. Copy the ftpaccess file in the /etc/ directory. ii. Copy the ftpusers file in the /etc/ directory. iii. Copy the ftphosts file in the /etc/ directory. iv. Copy the ftpgroups file in the /etc/ directory. v. Copy the ftpconversion file in the /etc/ directory. vi. Copy the ftp file in the /etc/pam.d/ directory. vii. Copy the ftpd file in the /etc/logrotate.d/ directory. Tip You can obtain the configuration files listed in the next sections on our floppy.tgz archive. Copy the following files from the decompressed floppy.tgz archive to the appropriate places, or copy them directly from this book to the concerned file. 5. Configure the /etc/ftphosts file The /etc/ftphosts file is used to define whether users are allowed to log in from certain hosts or whether there are denied access. 1. Create the ftphosts file, touch /etc/ftphosts and add for example in this file the following lines: # Example host access file # # Everything after a '#' is treated as comment, # empty lines are ignored allow ftpadmin 208.164.186.1 208.164.186.2 208.164.186.4 deny ftpadmin 208.164.186.5 In the example below, we allow the user ftpadmin to connect via FTP from the explicitly listed addresses 208.164.186.1 208.164.186.2208.164.186.4, and deny the specified ftpadmin user to connect from the site 208.164.186.5. 2. Now, change its default permission to be 600: [root@deep ] /# chmod 600 /etc/ftphosts 5.1. Configure the /etc/ftpusers file The /etc/ftpusers/ file specifies those users that are NOT allowed to connect to your FTP server. 1. Create the ftpusers file, touch /etc/ftpusers and add in this file the following users for security reasons: root bin daemon adm lp sync shutdown halt mail news uucp operator games nobody 2. Now, change its default permission to be 600: [root@deep ] /# chmod 600 /etc/ftpusers 6. Configure the /etc/ftpconversions file The /etc/ftpconversions file contains instructions that permit you to compress files on demand before the transfer. 1. Edit the ftpconversions file, vi /etc/ftpconversions and add in this file the following lines: :.Z: : :/bin/compress -d -c %s:T_REG|T_ASCII:O_UNCOMPRESS: UNCOMPRESS : : :.Z:/bin/compress -c %s:T_REG:O_COMPRESS:COMPRESS :.gz: : :/bin/gzip -cd %s:T_REG|T_ASCII:O_UNCOMPRESS:GUNZIP : : :.gz:/bin/gzip -9 -c %s:T_REG:O_COMPRESS:GZIP : : :.tar:/bin/tar -c -f - %s:T_REG|T_DIR:O_TAR:TAR : : :.tar.Z:/bin/tar -c -Z -f - %s:T_REG|T_DIR: O_COMPRESS|O_TAR:TAR+COMPRESS : : :.tar.gz:/bin/tar -c -z -f - %s:T_REG|T_DIR: O_COMPRESS|O_TAR:TAR+GZIP : : :.crc:/bin/cksum %s:T_REG::CKSUM : : :.md5:/bin/md5sum %s:T_REG::MD5SUM 2. Now, change its default permissions to be 600: [root@deep ] /# chmod 600 /etc/ftpconversions 6.1. Configure the /etc/pam.d/ftp file Configure your /etc/pam.d/ftp file to use pam authentication by creating the / etc/pam.d/ftp file and add the following lines: #%PAM-1.0 auth required /lib/security/pam_listfile.so item=user sense=deny file=/etc/ftpusers onerr=succeed auth required /lib/security/pam_pwdb.so shadow nullok auth required /lib/security/pam_shells.so account required /lib/security/pam_pwdb.so session required /lib/security/pam_pwdb.so 7. Configure the /etc/logrotate.d/ftpd file Configure your /etc/logrotate.d/ftpd file to automatically rotate your log files each week by creating the /etc/logrotate.d/ftpd file and add the following lines: /var/log/xferlog { # ftpd doesn't handle SIGHUP properly nocompress } 7.1. Configure ftpd to use tcp-wrappers inetd Tcp-wrappers should be enabled to start and stop the ftpd server. Upon execution, inetd reads its configuration information from a configuration file which, by default, is /etc/inetd.conf. There must be an entry for each field of the configuration file, with entries for each field separated by a tab or a space. Edit the inetd.conf file, vi /etc/inetd.conf and add or verify the existence of the following line: ftp stream tcp nowait root /usr/sbin/tcpd in.ftpd -l -a Update your inetd.conf file by sending a SIGHUP signal, killall -HUP inetd, after adding the above line in the file. [root@deep ] /# killall -HUP inetd Edit the hosts.allow file, vi /etc/hosts.allow and add, for example, the following line: in.ftpd: 192.168.1.4 win.openna.com Which means client IP 192.168.1.4 with host name win.openna.com is allowed to FTP on to the server. 8. FTP Administrative Tools ftpwho.  The ftpwho program utility displays all active ftp users, and their current process information on the system. The output of the command is in the format of the /bin/ps command. The format of this command is: To displays all active ftp users and their current process, use the following command: [root@deep ] /# ftpwho Service class openna: 5443 ? S 0:00 ftpd: win.openna.com: ftpadmin: IDLE - 1 users ( 20 maximum) Here, you can see that one user is logged in, 20 users are allowed to be connected, and this user has the username ftpadmin who claims to be from win.openna.com. ftpcount.  The ftpcount program utility, which is a simplified version of ftpwho, shows only the current number of users logged in to the system, and the maximum number of users allowed. To shows only the current number of users logged in to the system and the maximum number of users allowed, use the following command: [root@deep ] /# ftpcount Service class openna - 1 users ( 20 maximum) 9. Securing FTP The ftpusers file.  It's important to ensure that you have set up the file / etc/ftpusers which specifies those users that are NOT allowed to connect to your FTP server. This should include, as a MINIMUM, the following entries: root, bin, daemon, adm, lp, sync, shutdown, halt, mail, news, uucp, operator, games, nobody and ALL other default vendor supplied accounts available in your /etc/passwd file. The anonymous FTP program.  To disable anonymous FTP, remove the anonymous user ftp from your password file and verify that anonftp-version.i386.rpm package is not installed on your system. To remove the user ftp from your password file, use the following command: [root@deep ] /# userdel ftp To verify that the RPM package of anonymous FTP program is not installed on your Linux system, use the following command: [root@deep ] /# rpm -q anonftp package anonftp is not installed The upload command.  By default, the Wu-ftpd server will grant upload privileges to all users. The upload parameter allow remote clients to load and place files on the FTP server. For optimal security, we don't want users being able to upload into bin, etc, dev, and lib subdirectories in the /home/ftp directory. In our /etc/ftpaccess file we have already chroot'd users to /home/ ftp and they cannot access any area of the filesystem outside that directory structure, but in case something happens to the permissions on them you should deny upload privileges in your /etc/ftpaccess file into these areas; /home/ ftp/, /home/ftp/bin, /home/ftp/etc, /home/ftp/dev, and /home/ftp/lib. Edit the ftpaccess file, vi /etc/ftpaccess and add the following lines to deny upload privileges into these areas. # We don't want users being able to upload into these areas. upload /home/ftp/* / no upload /home/ftp/* /etc no upload /home/ftp/* /dev no upload /home/ftp/* /bin no 1 upload /home/ftp/* /lib no 2 _1_ Require only if you are not using the --enable-ls option. _2_ Require only if you are not using the --enable-ls option. The above lines specify to deny upload into the /, /etc, /dev, /bin and /lib directories of the chroot'd /home/ftp directory structure. 10. The special file .notar Whether you allow on-the-fly tarring of directories or not, you should make sure an end-run cannot be made using tar command in all areas where the upload parameter is not permit. To do so, create the special file .notar in each directory and in the FTP directory. [root@deep ] /# touch /home/ftp/.notar [root@deep ] /# touch /home/ftp/etc/.notar [root@deep ] /# touch /home/ftp/dev/.notar [root@deep ] /# touch /home/ftp/bin/.notar 1 [root@deep ] /# touch /home/ftp/lib/.notar 2 [root@deep ] /# chmod 0 /home/ftp/.notar [root@deep ] /# chmod 0 /home/ftp/etc/.notar [root@deep ] /# chmod 0 /home/ftp/dev/.notar [root@deep ] /# chmod 0 /home/ftp/bin/.notar 3 [root@deep ] /# chmod 0 /home/ftp/lib/.notar 4 _1_ Require only if you are not using the --enable-ls option. _2_ Require only if you are not using the --enable-ls option. _3_ Require only if you are not using the --enable-ls option. _4_ Require only if you are not using the --enable-ls option. The zero-length .notar file can confuse some web clients and FTP proxies, so let's mark it irretrievable to solve the problem. Add the following lines to your /etc/ftpaccess file. noretrieve .notar The noretrieve command.  The noretrieve parameter of Wu-ftpd server allow you to deny transfer of the sectected directories or files. It is also a good idea to prevent downloads of those subdirectories bin, etc, dev, and lib in the / home/ftp directory with the command noretrieve in your /etc/ftpaccess file. # We'll prevent downloads with noretrieve. noretrieve /home/ftp/etc noretrieve /home/ftp/dev noretrieve /home/ftp/bin 1 noretrieve /home/ftp/lib 2 _1_ Require only if you are not using the --enable-ls option. _2_ Require only if you are not using the --enable-ls option. 11. Installed files These are the files installed on your system: /etc/pam.d/ftp /etc/logrotate.d/ftpd /etc/ftpaccess /etc/ftpconversions /etc/ftpgroups /etc/ftphosts /etc/ftpusers /home/ftp/ /usr/bin/ftpcount /usr/bin/ftpwho /usr/man/man1/ftpcount.1 /usr/man/man1/ftpwho.1 /usr/man/man5/ftpaccess.5 /usr/man/man5/ftphosts.5 /usr/man/man5/ftpconversions.5 /usr/man/man5/xferlog.5 /usr/man/man8/ftpd.8 /usr/man/man8/ftpshut.8 /usr/man/man8/ftprestart.8 /usr/sbin/in.ftpd /usr/sbin/ftpshut /usr/sbin/ckconfig /usr/sbin/ftprestart /usr/sbin/xferstats /usr/sbin/wu.ftpd /usr/sbin/in.wuftpd /var/log/xferlog   Part 7. Backup and Restore hen, cock! Abstract A secure and reliable server is closely related to performing regular backups. Failures will probably occur sometimes. They may be caused by attacks, hardware failure, human error, power outages, etc. The safest method of doing backups is to record them in a location separate from your Linux system like over a network, from tape, removable drive, writable CD-ROM, etc. Table of Contents 33._Why's_and_When's_of_Backup_and_Restore 1._What_to_backup 2._The_tar_backup_program 3._Automating_backups_with_tar 4._Restore_files_with_tar 5._The_dump_backup_program 6._Making_backups_with_dump 7._Restoring_files_with_dump 8._Backing_up_and_restoring_over_the_network 8.1._Using_the_scp_SSH_command Chapter 33. Why's and When's of Backup and Restore Table of Contents 1._What_to_backup 2._The_tar_backup_program 3._Automating_backups_with_tar 4._Restore_files_with_tar 5._The_dump_backup_program 6._Making_backups_with_dump 7._Restoring_files_with_dump 8._Backing_up_and_restoring_over_the_network 8.1._Using_the_scp_SSH_command Many methods of performing backups with Linux exist, such as dump, tar, cpio, as well as dd that are each available by default on your Linux system. Also available are text-based utilities, such as Amanda, which is designed to add a friendlier user interface to the backup and restore procedures. Finally, commercial backup utilities are also available, such as BRU. The procedures for performing a backup and restore will differ depending on your choice of a backup solution. For this reason we will discuss methods for performing backups with the traditional UNIX tools: i. tar ii. dump which is a command-line backup tool. 1. What to backup The idea of making a backup is to back up as much as possible on your system, but some exceptions do exist as shown below. It is not logical to include these in your backup at the cost of time and space in your media for nothing. The major exceptions to not include in your backup are: * The /proc file system: since it only contains data that the kernel generates automatically, it is never a good idea to back it up. * The /mnt file system, because it is where you mount your removable media like CD-ROM, floppy disk and other. The backup directory or media where you have placed your backup files, such as a tape, CD-ROM, NFS mounted file system, remote/local directory or other kind of media. Software that can be easily reinstalled, though they may have configuration files that are important to back up, lest you do all the work to configure them all over again. I will recommend putting them. the configuration files for software on the floppy disk. 2. The tar backup program The tar backup program is an archiving program designed to store and extract files from an archive file known as a tarfile. A tarfile may be made on a tape drive; however, it is also common to write a tarfile to a normal file. A simple backup is when you decide to make a backup of files on your system you must choose a backup scheme before the beginning of your backup procedure. A lot of strategic backup schemes exist, and depend on the backup policies you want to use. In the following, We have shown you one backup scheme that you may use which takes advantage of the tar program's capabilities. This scheme is to first back up everything once, then back up everything that has been modified since the previous backup. i. The first backup is called a full backup ii. The subsequent ones are incremental backups. With six tapes you can make backups every day; The procedure is to use tape 1 for the first full backup Friday 1, and tapes 2 to 5 for the incremental backups Monday through Thursday. Then, you make a new full backup on tape 6 second Friday, and start doing incremental ones with tapes 2 to 5 again. It's important to keep tape 1 at its state until you've got a new full backup with tape 6. In the following example below, we assume that we write the backup to a SCSI tape drive named /dev/st0, and we backup the home directory /home of our system. First of all, we must to move to the file system / partition. When creating an archive file, tar will strip leading / slash characters from file path names. This means that restored files may not end up in the same locations they were backed up from. Therefore, to solve the problem, the solution is to change to the / root directory before making all backups and restorations. To move to the / root directory, use the command: [root@deep]# cd / It is important to always start with a full backup; say on a Friday, for example: Friday 1.  use tape 1 for the first full backup. [root@deep] /# cd / [root@deep] /# tar cpf /dev/st0 --label=" full-backup created on `date '+%d- %B-%Y'`." \ --directory / home Monday.  use tapes 2 for the incremental backups. [root@deep] /# cd / [root@deep] /# tar cpNf /dev/st0 --label=" full-backup created on `date '+%d- %B-%Y'`." \ --directory / home Tuesday.  use tapes 3 for the incremental backups. [root@deep] /# cd / [root@deep] /# tar cpNf /dev/st0 --label=" full-backup created on `date '+%d- %B-%Y'`." \ --directory / home Wednesday.  use tapes 4 for the incremental backups. [root@deep] /# cd / [root@deep] /# tar cpNf /dev/st0 --label=" full-backup created on `date '+%d- %B-%Y'`." \ --directory / home Thursday.  use tapes 5 for the incremental backups. [root@deep] /# cd / [root@deep] /# tar cpNf /dev/st0 --label=" full-backup created on `date '+%d- %B-%Y'`." \ --directory / home Friday 2.  use tape 6 for the new full backups. [root@deep] /# cd / [root@deep] /# tar cpf /dev/st0 --label=" full-backup created on `date '+%d- %B-%Y'`." \ --directory / home Now, start doing incremental ones with tapes 2 to 5 again and so on. * The c option specifies that an archive file is begin created. * The p option preserves permissions; file protection information will be remembered. * The N option does an incremental backup and only stores files newer than DATE. * The f option states that the very next argument will be the name of the archive file or device being written. Notice how a filename, which contains the current date, is derived, simply by enclosing the date command between two back-quote characters. A common naming convention is to add a tar suffix for non-compressed archives, and a tar.gz suffix for compressed ones. Since we aren't able to specify a filename for the backup set, the --label option can be used to write some information about the backup set into the archive file itself. Finally, only the files contained in the /home are written to the tape. Because the tape drive is a character device, it is not possible to specify an actual file name. Therefore, the file name used as an argument to tar is simply the name of the device, /dev/st0, the first tape device. The /dev/st0 device does not rewind after the backup set is written. Therefore it is possible to write multiple sets on one tape. You may also refer to the device as /dev/st0, in which case the tape is automatically rewound after the backup set is written. When working with tapes you can use the following commands to rewind and eject your tape: [root@deep] /# mt -f /dev/st0 rewind [root@deep] /# mt -f /dev/st0 offline Caution To reduce the space needed on a tar archive, the backups can be compressed with the z option of tar program. Unfortunately, using this option to compress backups can cause trouble. Due to the nature of how compression works, if a single bit in the compressed backup is wrong, all the rest of the compressed data will be lost. It's recommended to NOT using compression, the z option to make backups with the tar command. If your backup doesn't fit on one tape, you'll need to use the --multi-volume - M option: [root@deep] /# cd / [root@deep] /# tar cMpf /dev/st0 /home Prepare volume #2 for /dev/st0 and hit return: After you have made a backup, you should check that it is OK, using the -- compare -d option as shown below: [root@deep] /# cd / [root@deep] /# tar dvf /dev/st0 To perform a backup of your entire system, use the following command: [root@deep] /# cd / [root@deep] /# tar cpf /archive/full-backup-`date '+%d-%B-%Y'`.tar \ --directory / --exclude=proc --exclude=mnt --exclude=archive \ --exclude=cache --exclude=*/lost+found . * The --directory option tells tar to first switch to the following directory path, the / directory in this example, prior to starting the backup. * The --exclude options tells tar not to bother backing up the specified directories or files. * The . character at the end of the command tells tar that it should back up everything in the current directory. Caution When backing up your file systems, do not include the /proc pseudo-file-system! The files in /proc are not actually files but are simply file-like links which describe and point to kernel data structures. Also, do not include the /mnt, / archive, and all lost+found directories. 3. Automating backups with tar It is always interesting to automate the tasks of a backup. Automation offers enormous opportunities for using your Linux server to achieve the goals you set. The following example below is our backup script, called backup.cron. This script is designed to run on any computer by changing only the four variables: i. COMPUTER ii. DIRECTORIES iii. BACKUPDIR iv. TIMEDIR We suggest that you set this script up and run it at the beginning of the month for the first time, and then run it for a month before making major changes. In our example below we do the backup to a directory on the local server BACKUPDIR, but you could modify this script to do it to a tape on the local server or via an NFS mounted file system. 1. Create the backup script backup.cron file, touch /etc/cron.daily/ backup.cron and add the following lines to this backup file: #!/bin/sh # full and incremental backup script # created 07 February 2000 # Based on a script by Daniel O'Callaghan # and modified by Gerhard Mourani #Change the 5 variables below to fit your computer/backup COMPUTER=deep # name of this computer DIRECTORIES="/home" # directoris to backup BACKUPDIR=/backups # where to store the backups TIMEDIR=/backups/last-full # where to store time of full backup TAR=/bin/tar # name and locaction of tar #You should not have to change anything below here PATH=/usr/local/bin:/usr/bin:/bin DOW=`date +%a` # Day of the week e.g. Mon DOM=`date +%d` # Date of the Month e.g. 27 DM=`date +%d%b` # Date and Month e.g. 27Sep # On the 1st of the month a permanet full backup is made # Every Sunday a full backup is made - overwriting last Sundays backup # The rest of the time an incremental backup is made. Each incremental # backup overwrites last weeks incremental backup of the same name. # # if NEWER = "", then tar backs up all files in the directories # otherwise it backs up files newer than the NEWER date. NEWER # gets it date from the file written every Sunday. # Monthly full backup if [ $DOM = "01" ]; then NEWER="" $TAR $NEWER -cf $BACKUPDIR/$COMPUTER-$DM.tar $DIRECTORIES fi # Weekly full backup if [ $DOW = "Sun" ]; then NEWER="" NOW=`date +%d-%b` # Update full backup date echo $NOW > $TIMEDIR/$COMPUTER-full-date $TAR $NEWER -cf $BACKUPDIR/$COMPUTER-$DOW.tar $DIRECTORIES # Make incremental backup - overwrite last weeks else # Get date of last full backup NEWER="--newer `cat $TIMEDIR/$COMPUTER-full-date`" $TAR $NEWER -cf $BACKUPDIR/$COMPUTER-$DOW.tar $DIRECTORIES fi Example 33.1. Backup directory of a week Here is an abbreviated look of the backup directory after one week: [root@deep] /# ls -l /backups/ total 22217 -rw-r--r-- 1 root root 10731288 Feb 7 11:24 deep- 01Feb.tar -rw-r--r-- 1 root root 6879 Feb 7 11:24 deep- Fri.tar -rw-r--r-- 1 root root 2831 Feb 7 11:24 deep-Mon.tar -rw-r--r-- 1 root root 7924 Feb 7 11:25 deep- Sat.tar -rw-r--r-- 1 root root 11923013 Feb 7 11:24 deep-Sun.tar -rw-r--r-- 1 root root 5643 Feb 7 11:25 deep- Thu.tar -rw-r--r-- 1 root root 3152 Feb 7 11:25 deep- Tue.tar -rw-r--r-- 1 root root 4567 Feb 7 11:25 deep- Wed.tar drwxr-xr-x 2 root root 1024 Feb 7 11:20 last-full Important The directory where to store the backups BACKUPDIR, and the directory where to store time of full backup TIMEDIR must exist or be created before the use of the backup-script, or you will receive an error message. 2. If you are not running this backup script from the beginning of the month 01-month-year, the incremental backups will need the time of the Sunday backup to be able to work properly. If you start in the middle of the week, you will need to create the time file in the TIMEDIR. To create the time file in the TIMEDIR directory, use the following command: [root@deep] /# date +%d%b < /backups/last-full/myserver-full-date Where /backups/last-full is our variable TIMEDIR wherein we want to store the time of the full backup, and myserver-full-date is the name of our server e.g. deep, and our time file consists of a single line with the present date i.e. 15-Feb. 3. Make this script executable and change its default permissions to be writable only by the super-user root 755. [root@deep] /# chmod 755 /etc/cron.daily/backup.cron Note Because this script is in the /etc/cron.daily directory, it will be automatically run as a cron job at one o'clock in the morning every day. 4. Restore files with tar More important than performing regular backups is having them available when we need to recover important files! In this section, we will discuss methods for restoring files, which have been backed up with tar command. The following command will restore all files from the full-backup-Day-Month- Year.tar archive, which is an example backup of our home directory created from the example tar commands shown above. [root@deep] /# cd / [root@deep] /# tar xpf /dev/st0/full-backup-Day-Month-Year.tar The above command extracts all files contained in the compressed archive, preserving original file ownership and permissions. * The x option stands for extract. * The p option preserve permissions; file protection information will be remembered. * The f option states that the very next argument will be the name of the archive file or device. If you do not need to restore all the files contained in the archive, you can specify one or more files that you wish to restore: To specify one or more files that you wish to restore, use the following command: [root@deep]# cd / [root@deep]# tar xpf /dev/st0/full-backup-Day-Month-Year.tar \ home/wahib/Personal/Contents.doc home/quota.user The above command restores the /home/wahib/Personal/Contents.doc and /home/ quota.user files from the archive. If you just want to see what files are in the backup volume, Use the --list or -t option: [root@deep] /# tar tf /dev/st0 Caution If you have files on your system set with the immutable bit, using the chattr command, these files will not be remembered with the immutable bit from your restored backup. You must reset it immutable with the command chattr +i after the backup is completed. Test the ability to recover Note Dont forget to test the ability to recover from backups, for many system administrators, recovering a file from a backup is an uncommon activity. This step assures that if you need to recover a file, the tools and processes will work. Performing this test periodically will help you to discover problems with the backup procedures so you can correct them before losing data. Some backup restoration software does not accurately recover the correct file protection and file ownership controls. Check the attributes of restored files to ensure they are being set correctly. Periodically test to ensure that you can perform a full system recovery from your backups. Further documentation, for more details, there is man page you can read: tar(1) - The GNU version of the tar archiving utility 5. The dump backup program Dump is completely different from tar, it is a program for backing up and restoring file system. It backups up the entire file system - not the files. Dump does not care what file system is on the hard drive, or even if there are files in the file system. It examines files on an ext2 file system, determines which ones need to be backed up, and copies those files to a specified disk, tape, file or other storage medium. It dumps one file system at a time quickly and efficiently. Unfortunately, it does not do individual directories, and so it eats up a great deal more storage space than tar. It is also written specifically for backups. The restore command performs the inverse function of dump, It can restore a full backup of a file system. Subsequent incremental backups can then be layered on top of the full backup. Single files and directory sub trees may also be restored from full or partial backups. You can use dump if you need a procedure for both backing up file systems and restoring file systems after backups. Dump has several levels of backup procedures. The levels range from 0 to 9, where level number 0 means a full backup and guarantees the entire file system is copied. A level number above 0, incremental backup, tells dump to copy all files new or modified since the last dump of the same or lower level. To be more precise, at each incremental backup level you back up everything that has changed since the previous backup at the same or a previous level. What are the advantages and the reasons to create and use several levels to make a backup? I try to explain it with the following schemas: 0 3 2 5 4 7 6 9 8 9 | | | | | | | | | | 0 means a full backup. | | | | | | | | | | | | 3 means copy all files new or modified since level 0, and 3. | | | | | | | | 2 means copy all files new or modified since level 0, and 2. | | | | | | | 5 means copy all files new or modified since level 0, 3, and 5. | | | | | | 4 means copy all files new or modified since level 0, 3, and 4. | | | | | 7 means copy all files new or modified since level 0, 3, 4, and 7. | | | | 6 means copy all files new or modified since level 0, 3, 4, and 6. | | | 9 means copy all files new or modified since level 0, 3, 4, 6, and 9. | | 8 means copy all files new or modified since level 0, 3, 4, 6, and 8. | 9 means copy all files new or modified since level 0, 3, 4, 6, 8, and 9. The advantages and reasons for doing this are that with multiple levels, the backup history can be extended more cheaply. A longer backup history is useful, since deleted or corrupted files are often not noticed for a long time. Even a version of a file that is not very up to date is better than no file at all. Also, backup levels are used to keep both the backup and restore times to a minimum -low. The dump manual page suggests a good scheme to take the full advantage of backup levels: 3, 2, 5, 4, 7, 6, 9, 8, 9, etc as described by the table below. The most you have to backup is two day's worth of work. The number of tapes for a restore depends on how long you keep between full backups. Table 33.1. Dump scheme ________________________________________ |Tape|Level|Backup_days|___Restore_tapes_| |__1_|___0_|_____N.A.__|____________1____| |__2_|___3_|_______1___|_________1,_2____| |__3_|___2_|_______2___|_________1,_3____| |__4_|___5_|_______1___|_______1,_2,_4___| |__5_|___4_|_______2___|_______1,_2,_5___| |__6_|___7_|_______1___|_____1,_2,_5,_6__| |__7_|___6_|_______2___|_____1,_2,_5,_7__| |__8_|___9_|_______1___|___1,_2,_5,_7,_8_| |__9_|___8_|_______2___|___1,_2,_5,_7,_9_| |_10_|___9_|_______1___|1,_2,_5,_7,_9,_10| 6. Making backups with dump It's interesting to use the dump backup program if you want to take advantage of its several levels of backup procedures. Given below is a procedure to have a longer backup history and to keep both the backup and restore times to a minimum. In the following example, we assume that the backup is written to a tape drive named /dev/st0 and we backup the home directory /home of our system. It is important to always start with a level 0 backup, for example: Friday 1.  use tape 1 for the first full backup. [root@deep] /# dump -0u -f /dev/st0 /home DUMP: Date of this level 0 dump: Fri Jan 28 21:25:12 2000 DUMP: Date of last level 0 dump: the epoch DUMP: Dumping /dev/sda6 (/home) to /dev/st0 DUMP: mapping (Pass I) [regular files] DUMP: mapping (Pass II) [directories] DUMP: estimated 18582 tape blocks on 0.48 tape(s). DUMP: Volume 1 started at: Fri Jan 28 21:25:14 2000 DUMP: dumping (Pass III) [directories] DUMP: dumping (Pass IV) [regular files] DUMP: DUMP: 18580 tape blocks on 1 volumes(s) DUMP: finished in 4 seconds, throughput 4645 KBytes/sec DUMP: Volume 1 completed at: Fri Jan 28 21:25:18 2000 DUMP: Volume 1 took 0:00:04 DUMP: Volume 1 transfer rate: 4645 KB/s DUMP: level 0 dump on Fri Jan 28 21:25:12 2000 DUMP: DUMP: Date of this level 0 dump: Fri Jan 28 21:25:12 2000 DUMP: DUMP: Date this dump completed: Fri Jan 28 21:25:18 2000 DUMP: DUMP: Average transfer rate: 4645 KB/s DUMP: Closing /dev/st0 DUMP: DUMP IS DONE Monday.  use tape 2 for the incremental backups. [root@deep] /# dump -3u -f /dev/st0 /home Tuesday.  use tape 3 for the incremental backups. [root@deep] /# dump -2u -f /dev/st0 /home Wednesday.  use tape 4 for the incremental backups. [root@deep] /# dump -5u -f /dev/st0 /home Thursday.  use tape 5 for the incremental backups. [root@deep] /# dump -4u -f /dev/st0 /home Friday 2.  use tape 6 for the incremental backups. [root@deep] /# dump -7u -f /dev/st0 /home Monday.  use tape 2 for the incremental backups. [root@deep] /# dump -3u -f /dev/st0 /home Tuesday.  use tape 3 for the incremental backups. [root@deep] /# dump -2u -f /dev/st0 /home Wednesday.  use tape 4 for the incremental backups. [root@deep] /# dump -5u -f /dev/st0 /home Thursday.  use tape 5 for the incremental backups. [root@deep] /# dump -4u -f /dev/st0 /home Friday 3.  use tape 7 for the incremental backups. [root@deep] /# dump -6u -f /dev/st0 /home Monday.  use tape 2 for the incremental backups. [root@deep] /# dump -3u -f /dev/st0 /home Tuesday.  use tape 3 for the incremental backups. [root@deep] /# dump -2u -f /dev/st0 /home Wednesday.  use tape 4 for the incremental backups. [root@deep] /# dump -5u -f /dev/st0 /home Thursday.  use tape 5 for the incremental backups. [root@deep] /# dump -4u -f /dev/st0 /home Friday 4.  use tape 8 for the incremental backups only if there have five Fridays in one month. [root@deep] /# dump -9u -f /dev/st0 /home Monday.  use tape 2 for the incremental backups only if there have five Fridays in one month. [root@deep] /# dump -3u -f /dev/st0 /home Tuesday.  use tape 3 for the incremental backups only if there have five Fridays in one month. [root@deep] /# dump -2u -f /dev/st0 /home Wednesday.  use tape 4 for the incremental backups only if there have five Fridays in one month. [root@deep] /# dump -5u -f /dev/st0 /home Thursday.  use tape 5 for the incremental backups only if there have five Fridays in one month. [root@deep] /# dump -4u -f /dev/st0 /home Month.  use another tape for a new full backup when the month change. [root@deep] /# dump -0u -f /dev/st0 /home Where * -0 to -9 is the backup level option you want to use, * the u option means to update the file /etc/dumpdates after a successful dump, * The -f option to write the backup to file The file may be a i. special device file like /dev/st0, a tape drive, ii. /dev/rsd1c, a disk drive, iii. An ordinary file iv. the standard output. Finally, you must specify what you want to backup. In our example, it is the / home directory /home. You can see that we use the same tapes 2 to 5 for daily backups -Monday to Thursday = 4 tapes, tapes 6, 7, and 8 for weekly backups -other Fridays, 6 + 7 + 8 = 3 tapes. note that there can be five Fridays in one month and tapes 1 and any subsequent new one for monthly backups -first Friday each month, 1 + any subsequent 11 months = 12 tapes. In conclusion, if we use 8 tapes 4 + 3 + 1 = 8, we can have a full backup for one month and repeat the procedure with the 8 tapes to get our subsequent 11 months to come for a total of 1-year individual full backups. The full backup should be done at set intervals, say once a month, and on a set of fresh tapes that are saved forever. With this kind of procedure, you will have 12 tapes for 12 months that handle histories and changes of your system for one year. Later, you can copy the 12 tape backups onto a different computer designated to keep all yearly backups for a long time and be able to reuse them, 12 tapes, to repeat the procedure for a new year. 7. Restoring files with dump The restore command performs the inverse function of dump(8). It restores files or file systems from backups made with dump. A full backup of a file system may be restored, and subsequent incremental backups layered on top of it. Single files and directory sub-trees may be restored from full, or partial backups. You have a number of possibile commands and options to restore backed up data with the dump program. Below, detailed is a procedure that uses the full potential of the restore program with the most options possible. It is also done in interactive mode. In an interactive restoration of files from a dump, the restore program provides a shell like interface that allows the user to move around the directory tree selecting files to be extracted, after reading in the directory information from the dump. The following is what we will see if we try to restore our /home directory: First of all, with the following command we must move to the partition file system where we want to restore our backup. This is required, since the interactive mode of the restore program will restore our backups from the current partition file system where we have executed the restore command from. [root@deep] /# cd /home To restore files from a dump in interactive mode, use the following command: [root@deep /home]# restore -i -f /dev/st0 restore > A prompt will appear in your terminal, to list the current, or specified, directory. Use the ls command as shown below: restore > ls .: admin/ lost+found/ named/ quota.group quota.user wahib/ restore > To change the current working directory to the specified one, use the cd commands. In our example, we change to wahib directory, as shown below: restore > cd wahib restore > ls ./wahib: .Xdefaults .bash_logout .bashrc .bash_history .bash_profile Personal/ restore > To add the current directory or file to the list of files to be extracted, use the add command. If a directory is specified, then it and all its descendents are added to the extraction list as shown below: restore > add Personal/ restore > Files that are on the extraction list are prepended with a * when they are listed by the ls command: restore > ls ./wahib: .Xdefaults .bash_logout .bashrc .bash_history .bash_profile *Personal/ To delete the current directory or specified argument from the list of files to be extracted, use the delete command. If a directory is specified, then all its descendents including itself are deleted from the extraction list, as shown below: restore > cd Personal/ restore > ls ./wahib/Personal: *Ad?le_Nakad.doc *Overview.doc *BIMCOR/ *Resume/ *My Webs/ *SAMS/ *Contents.doc *Templates/ *Divers.doc *bruno universite.doc *Linux/ *My Pictures/ restore > delete Resume/ restore > ls ./wahib/Personal: *Ad?le_Nakad.doc *Overview.doc *BIMCOR/ Resume/ *My Webs/ *SAMS/ *Contents.doc *Templates/ *Divers.doc *bruno universite.doc *Linux/ *My Pictures/ Tip The most expedient way to extract most of the files from a directory is to add the directory to the extraction list and then delete those files that are not needed. To extract all files in the extraction list from the dump, use the extract command. Restore will ask which volume the user wishes to mount. The fastest way to extract a few files is to start with the last volume and work towards the first volume, as shown below: restore > extract You have not read any tapes yet. Unless you know which volume your file(s) are on you should start with the last volume and work towards the first. Specify next volume #: 1 set owner/mode for '.'? [yn] y To exit from the interactive restore mode after you have finished extracting your directories or files, use the quit command as shown below. /sbin/restore > quit Tip Other methods of restoration exist with the dump program, consult the man page of dump for more information. Further documentation, for more details, there are man pages you can read: dump(8) ext2 filesystem backup restore(8) restore files or file systems from backups made with dump 8. Backing up and restoring over the network Backups allow you to restore the availability and integrity of information resources following security breaches and accidents. Without a backup, you may be unable to restore a computer's data after system failures and security breaches. It is important to develop a plan that is broad enough to cover all the servers you plan to deploy. We must determine what categories of files will be backed up. For example, you may choose to back up only user data files i.e. /home because damaged system files should be reloaded from the original distribution media. There are common technological approaches to file backups. For network servers, an authoritative version of the informational content of the server is created and maintained on a secure machine that is backed up. If the server is compromised and its content damaged, it can be reloaded from the secure system maintaining the authoritative version. This approach is typically used for public servers, such as Web servers, because the content changes at more predictable intervals. It is important to ensure that backups are performed in a secure manner and that the contents of the backups remain secure. We recommend that the plan specify that: * The source data is encrypted before being transmitted to the storage medium. * The data remains encrypted on the backup storage media. * The storage media are kept in a physically secure facility that is protected from man-made and natural disasters. You should make sure that transfer of your backup happens in a secure manner over the network. In the previous sections, we have shown you how to make a backup onto both a tape and files from the same system where you execute the backup procedure, with utilities like tar and dump. These programs tar and dump are capable of making backups over the network as well. To be able to backup over the network you must ensure that the packages named rmt and rsh are installed on your system. The rmt utility provides remote access to tape devices for programs like dump, and tar. To complement this, the rsh package contains a set of programs which allow users to run commands on remote machines, login to other machines and copy files between machines, rsh, rlogin and rcp are this set of programs. Since rsh can be easily hacked, and rmt depends on rsh to be able to work, we have chosen to not install them in our setup installation, see Installation_of your_Linux_Server for more information, due to security reasons. Therefore, we must find another way to make backups over the network in a secure manner. SSH technology is the solution for our problem Software_-Securities, because it also has the ability to copy data across the network with its scp command, through encryption. The following is a method that permits us to use the potential of SSH software to transfer our backups made with tar or dump in a secure manner via the scp SSH utility. 8.1. Using the scp SSH command The scp command copies files between hosts on a network. It uses SSH for data transfer, and uses the same authentication, and provides the same security, as SSH. Unlike the rcp utility that comes with the package rsh, scp will ask for passwords or passphrases. In our example below, we transfer a backup file made with the tar archive program. The procedure to transfer a backup file or tape made with dump program is the same. To use scp to copy a backup tape or file to a remote secure system, use the command: [admin@deep /]# scp Where is the directory where your backup file resides on your local server, and represents, in this order: i. The username, user of the person on the remote site that will hold the backup file, ii. The hostname, host of the remote host where you want to send the backup file, iii. The remote directory of this host where you want to place the transferred backup file. Example 33.2. scp SSH command A real example will look like this: [admin@deep /]# scp -Cp /backups/deep-01Feb.tar admin@backupserver:/archive/ deep/deep-01Feb.tar admin@backupserver's password: deep-01Feb.tgz | 10479 KB | 154.1 kB/s | ETA: 00:00:00 | 100% Important The C option enables compression for fast data transfer over the encrypted session, the p option indicates that the modification and access times as well as modes of the source file should be preserved on the copy. This is usually desirable. It is important to note that the dir/for/file directory on the remote host, /archive/deep in our example, must be owned by the username you specify in your scp command admin is this username in our example, or you may receive error message like: scp: /archive/deep/deep-01Feb.tar: Permission denied. To use scp to copy a remote tape or file to the local system, use the command: [admin@deep /]# scp Where represents, in this order; i. The username user of the person on the remote site that holds the backup file, ii. The hostname host of the remote host where you want to get the backup file, iii. The remote directory of this host where the backup file is kept, iv. is the local directory on your system where your want to place the backup file that you get from the remote host. Example 33.3. scp SSH command A real example would look like this: [admin@deep /]# scp -Cp admin@backupserver:/archive/deep/deep-01Feb.tar / backups admin@backupserver's password: deep-01Feb.tgz | 10479 KB | 154.1 kB/s | ETA: 00:00:00 | 100% Important It is important to note that the localdir/to/filelocation directory on the local host, /backups in our example, must be owned by the username you specify in your scp command, admin is this username in our example or you may receive an error message like: /backups/deep-01Feb.tar: Permission denied. 8.1.1. Alternatives to tar and dump backups AMANDA Homepage: http://www.cs.umd.edu/projects/amanda/ BRU Homepage: http://www.bru.com/ Part I. Appendixes Elephant Table of Contents A._Resources B._Tweaks,_Tips_and_Administration_tasks C._Obtaining_Requests_for_Comments_(RFCs) Appendix A. Resources Surprised!, Don't be, what we have attempted is to duplicate a server-side redirect here. The idea is, supposingly you are viewing this book online from a website, this will give enough time to think about leaving this environement which is what would have happened if you had clicked on any link, or save this page and go back to the page you were browsing. this will leave with the option of checking out the later at your convenience. To us when and if, a misnomer the link needs to be updated or changed or edited etc. we have to tinker with this page rather than hunt and peck at the links by searching them from different pages I have strived hard to make it as easy as possible for all to traverse here for finding the links . As a thumb rule all the links have as title the name of the chapter you clicked on the link. Open Network Architecture.  The official website of Securing and Optimizing Linux Redhat Edition www.openna.com Legalnotice.  For the latest version of Open Publication License: www.opencontent.org/ openpub/. For the commercial printing license please contact: OpenDocs @www.opendocspublishing.com/ Obtaining_the_book_and_example_configuration_files.  From the original web site Open Network Architecturewww.openna.com The Linux Documentation Project homepage: www.linuxdoc.org O'Reilly Network: oreilly.linu.com/pub/d/25 _You_can_Buy_here!__By_clicking_here! Linux Security portal www.linuxsecurity.com/docs For the latest version of this book keep checking here: www.linuxdoc.org/ The example_configuration_files can obtained from here: www.openna.com/books/ floppy.tgz. Creating_the_Boot_Disk_and_Booting.  Redhat boot images are available here: www.redhat.com/errata Update_of_the_latest_software.  The errata page for RedHat Linux distro: www.redhat.com/corp/support/errata/index.html Openna Errata.  The Firewall Scripts Errata page is here http://www.openna.com/ books/errata.htm Benchmark_Results.  The benchmarking results can be retrieved from GCC homepage: http://egcs.cygnus.com/ Pre-install.  For the latest Linux kernel check out the Kernel homepage here: http://www.kernelnotes.org/ Secure Linux Kernel.  For the latest the place to check for the latest Secure Linux Kernel Patches Homepage: http://www.openwall.com/linux/ Chapter 14,_Software_-Security/Monitoring .  The sXid packages can be found here: ftp://marcus.seva.net/pub/sxid/ Logcheck.  The Logcheck homepage is: http://www.psionic.com/abacus/logcheck/ PortSentry.  The Portsentry Homepage is: http://www.psionic.com/abacus/portsentry/ OpenSSh.  The OpenSSh package can be downloaded from: http://www.openssh.com Putty.  http://www.chiark.greenend.org.uk/~sgtatham/putty.html Tera_Term_Pro_and_TTSSH.  http://hp.vector.co.jp/authors/VA002416/teraterm.html, http://www.zip.com.au/~roca/download.html. Linux_SSH2_Client/Server.  The SSH2 (commercial) homepage is: http://www.ssh.org/ Linux_Tripwire_2.2.1.  http://www.tripwiresecurity.com/ Linux_Tripwire_ASR_1.3.1.  http://www.tripwiresecurity.com/ Alternatives_to_Tripwire:  ViperDB ViperDB Homepage: http://www.resentment.org/projects/viperdb/ FCHECK FCHECK Homepage:http://sites.netscape.net/fcheck/fcheck.html Sentinel Sentinel Homepage:http://zurk.netpedia.net/zfile.html Linux_GnuPG.  These are the Package(s) you must be sure to download: GnuPG Homepage:http://www.gnupg.org/ Linux_DNS_and_BIND_Server.  The required packages of DNS/BIND can be got here: ISC BIND Homepage:http://www.isc.org/ ISC BIND FTP Site:204.152.184.27 Sendmail.  Sendmail Homepage: http://www.sendmail.org/ Sendmail FTP Sire: 204.152.184.34 You must be sure to download: sendmail.8.10.1.tar.gz For details, regarding Realtime_Blackhole_List_database see: http://maps.vix.com/rbl/ Linux_IMAP_&_POP_Server.  These are the Package(s) needed and should be available here: IMAP/POP Homepage: http://www.washington.edu/imap/ IMAP/POP FTP Site: 140.142.3.227 or 140.142.4.227 You must be sure to download: imap.tar.Z Patents.  RSA Data Security:Their web page is http://www.rsa.com/ Ascom in Austria:Their web page is http://www.ascom.ch/ OPENSSL.  OpenSSL Homepage: http://www.openssl.org/ IPSEC/VPN_-FreeS/WAN.  Kernel Homepage: http://www.kernelnotes.org/ FreeS/WAN VPN Homepage Site: http://www.freeswan.org/ FreeS/WAN VPN FTP Site: 194.109.6.26 Compile_and_Install.  OpenLDAP Homepage:http://www.openldap.org/ OpenLDAP FTP Site: 204.152.186.57 Alternatives_to_tar_and_dump_backups.  AMANDA Homepage: http://www.cs.umd.edu/projects/amanda/ BRU Homepage: http://www.bru.com/ Install_PostgreSQL.  PostgreSQL packages are found here: PostgreSQL Homepage: http://www.postgresql.org/ PostgreSQL FTP Site:216.126.84.28 Linux_Squid_Proxy_Server.  These are Package(s) and are available here: Squid Homepage:http://www.squid-cache.org/ Squid FTP Site: 204.144.128.89 GNU malloc Homepage:http://www.gnu.org/order/ftp.html Configure_the_/etc/squid/squid.conf_file_-in_httpd-accelerator_mode.  http://www.hpl.hp.com/techreports/1999/HPL-1999-69.html http://fog.hpl.external.hp.com/techreports/98/HPL-98-173.html Linux_MM_Shared_Memory_Library.  MM Homepage:http://www.engelschall.com/sw/mm/ Linux_Apache_Web_Server.  Apache Homepage: http://www.apache.org/ Mod_Perl Homepage: http:// perl.apache.org/ Apache FTP Site: 63.211.145.10 Mod_Perl FTP Site: 63.211.145.10 Mod_SSL Homepage: http://www.modssl.org/ Mod_PHP Homepage: http://www.php.net/ Mod_SSL FTP Site: 129.132.7.171   Perl_module_Devel::Symdump.  Devel-Symdump Homepage:http://www.perl.com/CPAN/modules/by-module/Devel/ CGI.pm_Perl_library.  CGI.pm Homepage: http://stein.cshl.org/WWW/software/CGI/cgi_docs.html Linux_Webalizer.  These are the Package(s): Webalizer Homepage: http://www.mrunix.net/webalizer/ Webalizer FTP Site: 207.153.121.6 Linux_FAQ-O-Matic.  These are the Package(s) required: FAQ-O-Matic Homepage: http://www.dartmouth.edu/~jonh/ff-serve/cache/1.html The most recent version of the FAQ-O-Matic is always available at: ftp:// ftp.cs.dartmouth.edu/pub/jonh. Linux_Webmail_IMP.  These are the Package(s): Webmail IMP Homepage:http://www.horde.org/imp/ PHPLib Homepage:http://phplib.netuse.de/index.php3 phplib.  These are the package(s) PHPLib Homepage: http://phplib.netuse.de/index.php3, http://phplib.netuse.de/ index.php3 Linux_Samba_Server.  The Package(s) required are and available at: Samba Homepage: http://us1.samba.org/samba/samba.html Samba FTP Site: 63.238.153.11 Linux_FTP_Server.  These are the Package(s): Wu-ftpd Homepage:http://www.wu-ftpd.org/ Wu-ftpd FTP Site:205.133.13.68 Appendix_-RFC.  http://www.cis.ohio-state.edu/rfc/ Docbook_and_Additional_resources.  Norman walsh, http://nwalsh.com/~ndw/ Peter Graves, http://armedbear.org Bryan henderson, http://netpbm.sourceforge.net/ James clark, http://www.jclark.com/ for his xt and xp Michael Kay, http://users.iclway.co.uk/mhkay/saxon/ for Saxon To each and everyone at OASIS, http://www.oasis-open.org/docbook/ To each and everyone at Docbook.org, http://docbook.org/ Sebestain Rahtz, http://users.ox.ac.uk/~rahtz/passivetex/ for his contribution to DocBook Mark Gallasihttp://nis-www.lanl.gov/~rosalia/mydocs/ Appendix B. Tweaks, Tips and Administration tasks Some of the tips in this section are specific to Linux systems. Most are applicable to UNIX system in general. The du utility command Tip You can use the du utility to estimate file space usage. For example, to determine in megabyte the sizes of the /var/log/ and /home/ directory trees, type the following command: [root@deep] /# du -sh /var/log /home 3.5M /var/log 350M /home Keep in mind that the above command will report the actual size of your data. Now that you know for example that /home is using 350M you can move into it and du -sh * to locate where the largest files are. [root@deep] /# cd /home/ [root@deep ]/home# du -sh * 343M admin 11k ftp 6.8M httpd 12k lost+found 6.0k named 6.0k smbclient 6.0k test 8.0k www Tip You can add this command to your crontab so that every day you get emailed the desired disk space list, and you'll be able to monitor it without logging in constantly. Find the route Tip If you want to find out the route that the packets sent from your machine to a remote host, simply issue the following command: [root@deep] /# traceroute www.redhat.com traceroute to www.portal.redhat.com (206.132.41.202), 30 hops max, 38 byte packets 1 ppp005.108-253-207.mtl.mt.videotron.net (207.253.108.5) 98.584 ms 1519.806 ms 109.911 ms 2 fa5-1-0.rb02-piex.videotron.net (207.96.135.1) 149.888 ms 89.830 ms 109.914 ms 3 ia-tlpt-bb01-fec1.videotron.net (207.253.253.53) 149.896 ms 99.873 ms 139.930 ms 4 ia-cduc-bb02-ge2-0.videotron.net (207.253.253.61) 99.897 ms 169.863 ms 329.926 ms 5 if-4-1.core1.Montreal.Teleglobe.net (207.45.204.5) 409.895 ms 1469.882 ms 109.902 ms 6 if-1-1.core1.NewYork.Teleglobe.net (207.45.223.109) 189.920 ms 139.852 ms 109.939 ms 7 206.132.150.133 (206.132.150.133) 99.902 ms 99.724 ms 119.914 ms 8 pos1-0-2488M.wr2.CLE1.gblx.net (206.132.111.89) 189.899 ms 129.873 ms 129.934 ms 9 pos8-0-2488m.wr2.kcy1.globalcenter.net (206.132.111.82) 169.890 ms 179.884 ms 169.933 ms 10 206.132.114.77 (206.132.114.77) 199.890 ms 179.771 ms 169.928 ms 11 pos8-0-2488M.wr2.SFO1.gblx.net (206.132.110.110) 159.909 ms 199.959 ms 179.837 ms 12 pos1-0-2488M.cr1.SNV2.gblx.net (208.48.118.118) 179.885 ms 309.855 ms 299.937 ms 13 pos0-0-0-155M.hr2.SNV2.gblx.net (206.132.151.46) 329.905 ms 179.843 ms 169.936 ms 14 206.132.41.202 (206.132.41.202) 2229.906 ms 199.752 ms 309.927 ms Where is the name or ip address of the host that you want to trace. Display Web pages access Tip To display quickly the number of times your web page has been accessed use this command: [root@deep] /# grep "GET / HTTP" /var/log/httpd/access_log | wc -l 467 Shut down most services altogether Tip As root, you can shut down most services altogether with the following command: [root@deep] /# killall httpd smbd nmbd slapd named The above command will shut down the Apache server, Samba services, LDAP server, and DNS server respectively. clock on the top of your terminal Tip Edit the profile file, vi /etc/profile and add the following line: PROMPT_COMMAND='echo -ne "\0337\033[2;999r\033[1;1H\033[00;44m\033 [K"`date`"\033[00m\0338"' The result will look like: Clock on terminal window lsof installed on your server? Tip If not, install it and execute lsof-i. This should list which ports you have open on your machine. The lsof program is a great tool as it will tell you which processes are listening on a given port. [root@deep] /# lsof -i COMMAND PID USER FD TYPE DEVICE SIZE NODE NAME Inetd 344 root 4u IPv4 327 TCP *:ssh (LISTEN) sendmail 389 root 4u IPv4 387 TCP *:smtp (LISTEN) smbd 450 root 5u IPv4 452 TCP deep.openna.com: netbios-ssn (LISTEN) nmbd 461 root 5u IPv4 463 UDP *:netbios-ns nmbd 461 root 6u IPv4 465 UDP *:netbios-dgm nmbd 461 root 8u IPv4 468 UDP deep.openna.com: netbios-ns nmbd 461 root 9u IPv4 470 UDP deep.openna.com: netbios-dgm named 2599 root 4u IPv4 3095 UDP *:32771 named 2599 root 20u IPv4 3091 UDP localhost.localdomain:domain named 2599 root 21u IPv4 3092 TCP localhost.localdomain:domain (LISTEN) named 2599 root 22u IPv4 3093 UDP deep.openna.com: domain named 2599 root 23u IPv4 3094 TCP deep.openna.com: domain (LISTEN) commands on remote servers via ssh protocol Tip The ssh command can also be used to run commands on remote systems without logging in. The output of the command is displayed, and control returns to the local system. Here is an example which will display all the users logged in on the remote system. [admin@deep /]$ ssh mail.openna.com who admin@mail.openna.com's password: root tty1 Dec 2 14:45 admin tty2 Dec 2 14:45 wahib pts/0 Dec 2 11:38 Filename Completion Tip Tab filename completion allows you to type in portions of a filename or program, and then press TAB, and it will complete the filename for you. If there's more than one file or program that starts with what you already typed in, it will beep, and then when you press TAB again it will list all the files that start with what you initially typed. Special Characters Tip You can quickly accomplish tasks that you perform frequently by using shortcut keys one or more keys you press on the keyboard to complete a task. For example, special characters can be used on the Linux shell like the following: * Control+d: If you are in the shell and hit Control+d you get logged off. * Control+l: If you are in the shell and hit Control+l you clear the screen. * ?: This is a wildcard. This can represent a single character. If you specified something at the command line like "m?b" Linux would look for mob, mib, mub, and every other letter/number between a-z, 0-9. * *: This can represent any number of characters. If you specified a "mi*" it would use "mit", mim, miiii, miya, and ANYTHING that starts with mi. "m*l" could by mill, mull, ml, and anything that starts with an m and ends with an l. * [] - Specifies a range. if I did m[o,u,i]m Linux would think: mim, mum, mom if I did: m[a-d]m Linux would think: mam, mbm, mcm, mdm. Get the idea? The [], ?, and * are usually used with copying, deleting, and directory listings. Important Everything in Linux is CASE sensitive. This means "Bill" and "bill" are not the same thing. This allows for many files to be able to be stored, since "Bill" "bill" "bIll" "biLl", etc. can be different files. So, when using the [] stuff, you have to specify capital letters if any files you are dealing with have capital letters. Much of everything is lower case in UNIX, though. Appendix C. Obtaining Requests for Comments (RFCs) Requests for Comments -RFCs is an ongoing set of documents issued by the Internet Engineering Task Force -IETF at the Network Information Center -NIC that presents new protocols and establishes standards for the Internet protocol suite. Each such document defines an aspect of protocol regarding the Internet. We have listed below all the RFCs that pertain to this book, and various software described in this book. RFCs are available from the following site: http://www.cis.ohio-state.edu/rfc/ RFC706 On the Junk Mail Problem. RFC733 Standard for the Format of ARPA Network Text Messages. RFC768 User Datagram Protocol -UDP. RFC791 Internet Protocol -IP. RFC792 Internet Control Message Protocol -ICMP. RFC793 Transmission Control Protocol (TCP). RFC805 Computer Mail Meting Notes. RFC821 Simple Mail Transfert Protocol -SMTP. RFC822 Standard for the Format of ARPA Internet Text Massages. RFC934 Proposed Standard for Message Encapsulation. RFC950 IP Subnet Extention. RFC959 File Transfer Protocol (FTP). RFC976 UUCP Mail Interchange Format Standard. RFC1034 Domain Names: Concepts and Facilities. RFC1036 Standard for Interchange of USENET Message. RFC1058 Routing Information Protocol -RIP. RFC1112 Internet Group Multicast Protocol IGMP. RFC1122 Requirement for Internet Host Communication Layers. RFC1123 Requirements for Internet Host Application and Support. RFC1137 Mapping Between Full RFC 822 and RFC 822 with Restricted Encoding. RFC1153 Digest Message Format. RFC1155 Structure of Management Information SMI. RFC1157 Simple Network Management Protocol SNMP. RFC1176 Interactive Mail Access Protocol: Version 2. RFC1274 The COSINE and Internet X.500 Schema. RFC1275 Replication Requirements to provide an Internet Directory using X.500. RFC1279 X.500 and Domains. RFC1308 Executive Introduction to Directory Services Using the X.500 Protocol. RFC1309 Technical Overview of Directory Services Using the X.500 Protocol. RFC1310 The Internet Standards Process. RFC1319 MD2 Message-Digest Algorithm. RFC1320 MD4 Message-Digest Algorithm. RFC1321 MD5 Message-Digest Algorithm. RFC1343 User Agent Configuration Mechanism for Multimedia Mail Format Information. RFC1344 Implications of MIME for Internet Mail Gateways. RFC1345 Character Mnemonics and Character Sets. RFC1421 Privacy Enhancement for Internet Electronic Mail: Part IMessage Encipherment and authentication Procedures. RFC1422 Privacy Enhancement for Internet Electronic Mail: Part IICertificate- based key Management. RFC1423 Privacy Enhancement for Internet Electronic Mail: Part IIIAlgorithms, modes, and identifiers [Draft]. RFC1428 Transmition of Internet Mail from Just-Send-8 to 8bit-SMTP/MIME. RFC1430 A Strategic Plan for Deploying an Internet X.500 Directory Service. RFC1492 An Access Control Protocol, Sometimes Called TACACS. RFC1495 Mapping Between X.400(1988)/ISO 10021 and RFC 822. RFC1496 X.400 1988 to 1984 Downgrading. RFC1505 Encoding Header Field for Internet Messages. RFC1510 The Kerberos Network Authentication Service (V5). RFC1519 Classless Inter-Domain Routing, -CIDR Assignment and Aggregation Strategy. RFC1521 MIME -Multipurpose Internet Mail Extensions: Mechanisms for Specifying and Describing the Format of Internet Message Bodies (MIME). RFC1522 Representation of Non-ASCII Text in Internet Message Headers. RFC1558 A String Representation of LDAP Search Filters. RFC1566 Mail Monitoring MIB. RFC1579 Firewall-Friendly FTP. RFC1583 Open Shortest Path First Routing V2 (OSPF2). RFC1617 Naming and Structuring Guidelines for X.500 Directory Pilots. RFC1625 WAIS over Z39.50-1988. RFC1631 The IP Network Address Translator -NAT. RFC1652 SMTP Service Extentions for 8bit-MIMEtransport. RFC1661 Point-to-Point Protocol -PPP. RFC1711 Classifications in E-mail Routing. RFC1725 Post Office Protocol, Version 3 -POP3. RFC1738 Uniform Resource Locators -URL. RFC1739 A Primer on Internet and TCP/IP Tools. RFC1777 Lightweight Directory Access Protocol. RFC1778 The String Representation of Standard Attribute Syntaxes. RFC1779 A String Representation of Distinguished Names. RFC1781 Using the OSI Directory to Achieve User Friendly Naming. RFC1796 Not All RFCs are Standards. RFC1798 Connection-less Lightweight Directory Access Protocol. RFC1823 The LDAP Application Program Interface. RFC1830 SMTP Services Extentions for Transmission of Large and Binary MIME Messages. RFC1844 Multimedia E-mail -MIME, User Agent checklist. RFC1845 SMTP Service Extension for Checkpoint/Restart. RFC1846 SMTP 521 Reply Code. RFC1854 SMTP Service Extention for command pipelining. RFC1855 Netiquette Guidelines. RFC1864 The content-MD5 Header. RFC1866 Hypertext Markup Language - 2.0. RFC1869 SMTP Service Extensions. RFC1870 SMTP Service Extension for Message Size Declaration. RFC1872 The MIME Multipart/Related Content-type. RFC1873 Message/External-Body Content-ID Access-type. RFC1883 Internet Protocol, Version 6 (Ipv6) Specification. RFC1884 IP Version 6 Addressing Atchitecture. RFC1886 DNS Extentions to support IP version 6. RFC1891 SMTP Service Extension for Delivery Status Notifications. RFC1892 The Multipart/Report Content Type for the Reporting of Mail System Administrative Messages. RFC1893 Enhanced Mail System Status Codes. RFC1894 An Extensible Message Format for Delivery Status Notifications. RFC1918 Address Allocation for Private Internets. RFC1928 SOCKS Protocol Version 5. RFC1929 Username/Password Authentication for SOCKS V5. RFC1959 An LDAP URL Format. RFC1960 A String Representation of LDAP Search Filters. RFC1961 GSS-API Authentication Method for SOCKS Version 5. RFC2003 IP Encapsulation within IP. RFC2028 The Organizations Involved in the IETF Standards Process. RFC2044 UTF-8, a transformation format of Unicode and ISO 10646. RFC2060 Internet Message Access Protocol Version 4rev1 -IMAP4. RFC2104 HMAC: Keyed-Hashing for Message Authentication. RFC2138 Remote Authentication Dial In User Service (RADIUS). RFC2164 Use of an X.500/LDAP directory to support MIXER address mapping. RFC2200 Internet Official Protocol Standards. RFC2218 A Common Schema for the Internet White Pages Service. RFC2247 Using Domains in LDAP/X.500 Distinguished Names. RFC2251 Lightweight Directory Access Protocol (v3). RFC2252 Lightweight Directory Access Protocol (v3): Attribute Syntax Definitions. RFC2253 Lightweight Directory Access Protocol (v3): UTF-8 String Representation of Distinguished Names RFC2254 The String Representation of LDAP Search Filters. RFC2255 The LDAP URL Format. RFC2256 A Summary of the X.500(96) User Schema for use with LDAPv3. RFC2279 UTF-8, a transformation format of ISO 10646. RFC2293 Representing Tables and Subtrees in the X.500 Directory. RFC2294 Representing the O/R Address hierarchy in the X.500 Directory Information Tree. RFC2305 A Simple Mode of Facsimile Using Internet Mail. RFC2307 An Approach for Using LDAP as a Network Information Service. RFC2313 PKCS 1: RSA Encryption Version 1-5. RFC2314 PKCS 10: Certification Request Syntax Version 1-5. RFC2315 PKCS 7: Cryptographic Message Syntax Version 1-5. RFC2377 Naming Plan for Internet Directory-Enabled Applications.