Dieser Inhalt ist in der von Ihnen ausgewählten Sprache nicht verfügbar.

Chapter 11. Auditing the system


Audit does not provide additional security to your system; rather, it can be used to discover violations of security policies used on your system. These violations can further be prevented by additional security measures such as SELinux.

11.1. Linux Audit

The Linux Audit system provides a way to track security-relevant information about your system. Based on pre-configured rules, Audit generates log entries to record as much information about the events that are happening on your system as possible. This information is crucial for mission-critical environments to determine the violator of the security policy and the actions they performed.

The following list summarizes some of the information that Audit is capable of recording in its log files:

  • Date and time, type, and outcome of an event
  • Sensitivity labels of subjects and objects
  • Association of an event with the identity of the user who triggered the event
  • All modifications to Audit configuration and attempts to access Audit log files
  • All uses of authentication mechanisms, such as SSH, Kerberos, and others
  • Changes to any trusted database, such as /etc/passwd
  • Attempts to import or export information into or from the system
  • Include or exclude events based on user identity, subject and object labels, and other attributes

The use of the Audit system is also a requirement for a number of security-related certifications. Audit is designed to meet or exceed the requirements of the following certifications or compliance guides:

  • Controlled Access Protection Profile (CAPP)
  • Labeled Security Protection Profile (LSPP)
  • Rule Set Base Access Control (RSBAC)
  • National Industrial Security Program Operating Manual (NISPOM)
  • Federal Information Security Management Act (FISMA)
  • Payment Card Industry — Data Security Standard (PCI-DSS)
  • Security Technical Implementation Guides (STIG)

Audit has also been:

  • Evaluated by National Information Assurance Partnership (NIAP) and Best Security Industries (BSI)
  • Certified to LSPP/CAPP/RSBAC/EAL4+ on Red Hat Enterprise Linux 5
  • Certified to Operating System Protection Profile / Evaluation Assurance Level 4+ (OSPP/EAL4+) on Red Hat Enterprise Linux 6

Use Cases

Watching file access
Audit can track whether a file or a directory has been accessed, modified, executed, or the file’s attributes have been changed. This is useful, for example, to detect access to important files and have an Audit trail available in case one of these files is corrupted.
Monitoring system calls
Audit can be configured to generate a log entry every time a particular system call is used. This can be used, for example, to track changes to the system time by monitoring the settimeofday, clock_adjtime, and other time-related system calls.
Recording commands run by a user
Audit can track whether a file has been executed, so rules can be defined to record every execution of a particular command. For example, a rule can be defined for every executable in the /bin directory. The resulting log entries can then be searched by user ID to generate an audit trail of executed commands per user.
Recording execution of system pathnames
Aside from watching file access which translates a path to an inode at rule invocation, Audit can now watch the execution of a path even if it does not exist at rule invocation, or if the file is replaced after rule invocation. This allows rules to continue to work after upgrading a program executable or before it is even installed.
Recording security events
The pam_faillock authentication module is capable of recording failed login attempts. Audit can be set up to record failed login attempts as well and provides additional information about the user who attempted to log in.
Searching for events
Audit provides the ausearch utility, which can be used to filter the log entries and provide a complete audit trail based on several conditions.
Running summary reports
The aureport utility can be used to generate, among other things, daily reports of recorded events. A system administrator can then analyze these reports and investigate suspicious activity further.
Monitoring network access
The nftables, iptables, and ebtables utilities can be configured to trigger Audit events, allowing system administrators to monitor network access.
Note

System performance may be affected depending on the amount of information that is collected by Audit.

11.2. Audit system architecture

The Audit system consists of two main parts: the user-space applications and utilities, and the kernel-side system call processing. The kernel component receives system calls from user-space applications and filters them through one of the following filters: user, task, fstype, or exit.

After a system call passes the exclude filter, it is sent through one of the aforementioned filters, which, based on the Audit rule configuration, sends it to the Audit daemon for further processing.

The user-space Audit daemon collects the information from the kernel and creates entries in a log file. Other Audit user-space utilities interact with the Audit daemon, the kernel Audit component, or the Audit log files:

  • The auditctl Audit control utility interacts with the kernel Audit component to manage rules and to control many settings and parameters of the event generation process.
  • The remaining Audit utilities take the contents of the Audit log files as input and generate output based on user’s requirements. For example, the aureport utility generates a report of all recorded events.

In RHEL 9, the Audit dispatcher daemon (audisp) functionality is integrated in the Audit daemon (auditd). Configuration files of plugins for the interaction of real-time analytical programs with Audit events are located in the /etc/audit/plugins.d/ directory by default.

11.3. Configuring auditd for a secure environment

The default auditd configuration should be suitable for most environments. However, if your environment must meet strict security policies, you can change the following settings for the Audit daemon configuration in the /etc/audit/auditd.conf file:

log_file
The directory that holds the Audit log files (usually /var/log/audit/) should reside on a separate mount point. This prevents other processes from consuming space in this directory and provides accurate detection of the remaining space for the Audit daemon.
max_log_file
Specifies the maximum size of a single Audit log file, must be set to make full use of the available space on the partition that holds the Audit log files. The max_log_file` parameter specifies the maximum file size in megabytes. The value given must be numeric.
max_log_file_action
Decides what action is taken once the limit set in max_log_file is reached, should be set to keep_logs to prevent Audit log files from being overwritten.
space_left
Specifies the amount of free space left on the disk for which an action that is set in the space_left_action parameter is triggered. Must be set to a number that gives the administrator enough time to respond and free up disk space. The space_left value depends on the rate at which the Audit log files are generated. If the value of space_left is specified as a whole number, it is interpreted as an absolute size in megabytes (MiB). If the value is specified as a number between 1 and 99 followed by a percentage sign (for example, 5%), the Audit daemon calculates the absolute size in megabytes based on the size of the file system containing log_file.
space_left_action
It is recommended to set the space_left_action parameter to email or exec with an appropriate notification method.
admin_space_left
Specifies the absolute minimum amount of free space for which an action that is set in the admin_space_left_action parameter is triggered, must be set to a value that leaves enough space to log actions performed by the administrator. The numeric value for this parameter should be lower than the number for space_left. You can also append a percent sign (for example, 1%) to the number to have the audit daemon calculate the number based on the disk partition size.
admin_space_left_action
Should be set to single to put the system into single-user mode and allow the administrator to free up some disk space.
disk_full_action
Specifies an action that is triggered when no free space is available on the partition that holds the Audit log files, must be set to halt or single. This ensures that the system is either shut down or operating in single-user mode when Audit can no longer log events.
disk_error_action
Specifies an action that is triggered in case an error is detected on the partition that holds the Audit log files, must be set to syslog, single, or halt, depending on your local security policies regarding the handling of hardware malfunctions.
flush
Should be set to incremental_async. It works in combination with the freq parameter, which determines how many records can be sent to the disk before forcing a hard synchronization with the hard drive. The freq parameter should be set to 100. These parameters assure that Audit event data is synchronized with the log files on the disk while keeping good performance for bursts of activity.

The remaining configuration options should be set according to your local security policy.

11.4. Starting and controlling auditd

After auditd is configured, start the service to collect Audit information and store it in the log files. Use the following command as the root user to start auditd:

service auditd start

To configure auditd to start at boot time:

systemctl enable auditd

You can temporarily disable auditd with the # auditctl -e 0 command and re-enable it with # auditctl -e 1.

You can perform other actions on auditd by using the service auditd <action> command, where <action> can be one of the following:

stop
Stops auditd.
restart
Restarts auditd.
reload or force-reload
Reloads the configuration of auditd from the /etc/audit/auditd.conf file.
rotate
Rotates the log files in the /var/log/audit/ directory.
resume
Resumes logging of Audit events after it has been previously suspended, for example, when there is not enough free space on the disk partition that holds the Audit log files.
condrestart or try-restart
Restarts auditd only if it is already running.
status
Displays the running status of auditd.
Note

The service command is the only way to correctly interact with the auditd daemon. You need to use the service command so that the auid value is properly recorded. You can use the systemctl command only for two actions: enable and status.

11.5. Understanding Audit log files

By default, the Audit system stores log entries in the /var/log/audit/audit.log file; if log rotation is enabled, rotated audit.log files are stored in the same directory.

Add the following Audit rule to log every attempt to read or modify the /etc/ssh/sshd_config file:

# auditctl -w /etc/ssh/sshd_config -p warx -k sshd_config

If the auditd daemon is running, for example, using the following command creates a new event in the Audit log file:

cat /etc/ssh/sshd_config

This event in the audit.log file looks as follows:

type=SYSCALL msg=audit(1364481363.243:24287): arch=c000003e syscall=2 success=no exit=-13 a0=7fffd19c5592 a1=0 a2=7fffd19c4b50 a3=a items=1 ppid=2686 pid=3538 auid=1000 uid=1000 gid=1000 euid=1000 suid=1000 fsuid=1000 egid=1000 sgid=1000 fsgid=1000 tty=pts0 ses=1 comm="cat" exe="/bin/cat" subj=unconfined_u:unconfined_r:unconfined_t:s0-s0:c0.c1023 key="sshd_config"
type=CWD msg=audit(1364481363.243:24287):  cwd="/home/shadowman"
type=PATH msg=audit(1364481363.243:24287): item=0 name="/etc/ssh/sshd_config" inode=409248 dev=fd:00 mode=0100600 ouid=0 ogid=0 rdev=00:00 obj=system_u:object_r:etc_t:s0  nametype=NORMAL cap_fp=none cap_fi=none cap_fe=0 cap_fver=0
type=PROCTITLE msg=audit(1364481363.243:24287) : proctitle=636174002F6574632F7373682F737368645F636F6E666967

The above event consists of four records, which share the same time stamp and serial number. Records always start with the type= keyword. Each record consists of several name=value pairs separated by a white space or a comma. A detailed analysis of the above event follows:

First Record

type=SYSCALL
The type field contains the type of the record. In this example, the SYSCALL value specifies that this record was triggered by a system call to the kernel.
msg=audit(1364481363.243:24287):

The msg field records:

  • A time stamp and a unique ID of the record in the form audit(time_stamp:ID). Multiple records can share the same time stamp and ID if they were generated as part of the same Audit event. The time stamp is using the Unix time format - seconds since 00:00:00 UTC on 1 January 1970.
  • Various event-specific name=value pairs provided by the kernel or user-space applications.
arch=c000003e
The arch field contains information about the CPU architecture of the system. The value, c000003e, is encoded in hexadecimal notation. When searching Audit records with the ausearch command, use the -i or --interpret option to automatically convert hexadecimal values into their human-readable equivalents. The c000003e value is interpreted as x86_64.
syscall=2
The syscall field records the type of the system call that was sent to the kernel. The value, 2, can be matched with its human-readable equivalent in the /usr/include/asm/unistd_64.h file. In this case, 2 is the open system call. Note that the ausyscall utility allows you to convert system call numbers to their human-readable equivalents. Use the ausyscall --dump command to display a listing of all system calls along with their numbers. For more information, see the ausyscall(8) man page.
success=no
The success field records whether the system call recorded in that particular event succeeded or failed. In this case, the call did not succeed.
exit=-13

The exit field contains a value that specifies the exit code returned by the system call. This value varies for a different system call. You can interpret the value to its human-readable equivalent with the following command:

ausearch --interpret --exit -13

Note that the previous example assumes that your Audit log contains an event that failed with exit code -13.

a0=7fffd19c5592, a1=0, a2=7fffd19c5592, a3=a
The a0 to a3 fields record the first four arguments, encoded in hexadecimal notation, of the system call in this event. These arguments depend on the system call that is used; they can be interpreted by the ausearch utility.
items=1
The items field contains the number of PATH auxiliary records that follow the syscall record.
ppid=2686
The ppid field records the Parent Process ID (PPID). In this case, 2686 was the PPID of the parent process such as bash.
pid=3538
The pid field records the Process ID (PID). In this case, 3538 was the PID of the cat process.
auid=1000
The auid field records the Audit user ID, that is the loginuid. This ID is assigned to a user upon login and is inherited by every process even when the user’s identity changes, for example, by switching user accounts with the su - john command.
uid=1000
The uid field records the user ID of the user who started the analyzed process. The user ID can be interpreted into user names with the following command: ausearch -i --uid UID.
gid=1000
The gid field records the group ID of the user who started the analyzed process.
euid=1000
The euid field records the effective user ID of the user who started the analyzed process.
suid=1000
The suid field records the set user ID of the user who started the analyzed process.
fsuid=1000
The fsuid field records the file system user ID of the user who started the analyzed process.
egid=1000
The egid field records the effective group ID of the user who started the analyzed process.
sgid=1000
The sgid field records the set group ID of the user who started the analyzed process.
fsgid=1000
The fsgid field records the file system group ID of the user who started the analyzed process.
tty=pts0
The tty field records the terminal from which the analyzed process was invoked.
ses=1
The ses field records the session ID of the session from which the analyzed process was invoked.
comm="cat"
The comm field records the command-line name of the command that was used to invoke the analyzed process. In this case, the cat command was used to trigger this Audit event.
exe="/bin/cat"
The exe field records the path to the executable that was used to invoke the analyzed process.
subj=unconfined_u:unconfined_r:unconfined_t:s0-s0:c0.c1023
The subj field records the SELinux context with which the analyzed process was labeled at the time of execution.
key="sshd_config"
The key field records the administrator-defined string associated with the rule that generated this event in the Audit log.

Second Record

type=CWD

In the second record, the type field value is CWD — current working directory. This type is used to record the working directory from which the process that invoked the system call specified in the first record was executed.

The purpose of this record is to record the current process’s location in case a relative path winds up being captured in the associated PATH record. This way the absolute path can be reconstructed.

msg=audit(1364481363.243:24287)
The msg field holds the same time stamp and ID value as the value in the first record. The time stamp is using the Unix time format - seconds since 00:00:00 UTC on 1 January 1970.
cwd="/home/user_name"
The cwd field contains the path to the directory in which the system call was invoked.

Third Record

type=PATH
In the third record, the type field value is PATH. An Audit event contains a PATH-type record for every path that is passed to the system call as an argument. In this Audit event, only one path (/etc/ssh/sshd_config) was used as an argument.
msg=audit(1364481363.243:24287):
The msg field holds the same time stamp and ID value as the value in the first and second record.
item=0
The item field indicates which item, of the total number of items referenced in the SYSCALL type record, the current record is. This number is zero-based; a value of 0 means it is the first item.
name="/etc/ssh/sshd_config"
The name field records the path of the file or directory that was passed to the system call as an argument. In this case, it was the /etc/ssh/sshd_config file.
inode=409248

The inode field contains the inode number associated with the file or directory recorded in this event. The following command displays the file or directory that is associated with the 409248 inode number:

find / -inum 409248 -print
/etc/ssh/sshd_config
dev=fd:00
The dev field specifies the minor and major ID of the device that contains the file or directory recorded in this event. In this case, the value represents the /dev/fd/0 device.
mode=0100600
The mode field records the file or directory permissions, encoded in numerical notation as returned by the stat command in the st_mode field. See the stat(2) man page for more information. In this case, 0100600 can be interpreted as -rw-------, meaning that only the root user has read and write permissions to the /etc/ssh/sshd_config file.
ouid=0
The ouid field records the object owner’s user ID.
ogid=0
The ogid field records the object owner’s group ID.
rdev=00:00
The rdev field contains a recorded device identifier for special files only. In this case, it is not used as the recorded file is a regular file.
obj=system_u:object_r:etc_t:s0
The obj field records the SELinux context with which the recorded file or directory was labeled at the time of execution.
nametype=NORMAL
The nametype field records the intent of each path record’s operation in the context of a given syscall.
cap_fp=none
The cap_fp field records data related to the setting of a permitted file system-based capability of the file or directory object.
cap_fi=none
The cap_fi field records data related to the setting of an inherited file system-based capability of the file or directory object.
cap_fe=0
The cap_fe field records the setting of the effective bit of the file system-based capability of the file or directory object.
cap_fver=0
The cap_fver field records the version of the file system-based capability of the file or directory object.

Fourth Record

type=PROCTITLE
The type field contains the type of the record. In this example, the PROCTITLE value specifies that this record gives the full command-line that triggered this Audit event, triggered by a system call to the kernel.
proctitle=636174002F6574632F7373682F737368645F636F6E666967
The proctitle field records the full command-line of the command that was used to invoke the analyzed process. The field is encoded in hexadecimal notation to not allow the user to influence the Audit log parser. The text decodes to the command that triggered this Audit event. When searching Audit records with the ausearch command, use the -i or --interpret option to automatically convert hexadecimal values into their human-readable equivalents. The 636174002F6574632F7373682F737368645F636F6E666967 value is interpreted as cat /etc/ssh/sshd_config.

11.6. Using auditctl for defining and executing Audit rules

The Audit system operates on a set of rules that define what is captured in the log files. Audit rules can be set either on the command line using the auditctl utility or in the /etc/audit/rules.d/ directory.

The auditctl command enables you to control the basic functionality of the Audit system and to define rules that decide which Audit events are logged.

File-system rules examples

  1. To define a rule that logs all write access to, and every attribute change of, the /etc/passwd file:

    # auditctl -w /etc/passwd -p wa -k passwd_changes
  2. To define a rule that logs all write access to, and every attribute change of, all the files in the /etc/selinux/ directory:

    # auditctl -w /etc/selinux/ -p wa -k selinux_changes

System-call rules examples

  1. To define a rule that creates a log entry every time the adjtimex or settimeofday system calls are used by a program, and the system uses the 64-bit architecture:

    # auditctl -a always,exit -F arch=b64 -S adjtimex -S settimeofday -k time_change
  2. To define a rule that creates a log entry every time a file is deleted or renamed by a system user whose ID is 1000 or larger:

    # auditctl -a always,exit -S unlink -S unlinkat -S rename -S renameat -F auid>=1000 -F auid!=4294967295 -k delete

    Note that the -F auid!=4294967295 option is used to exclude users whose login UID is not set.

Executable-file rules

To define a rule that logs all execution of the /bin/id program, execute the following command:

# auditctl -a always,exit -F exe=/bin/id -F arch=b64 -S execve -k execution_bin_id

Additional resources

  • auditctl(8) man page on your system

11.7. Defining persistent Audit rules

To define Audit rules that are persistent across reboots, you must either directly include them in the /etc/audit/rules.d/audit.rules file or use the augenrules program that reads rules located in the /etc/audit/rules.d/ directory.

Note that the /etc/audit/audit.rules file is generated whenever the auditd service starts. Files in /etc/audit/rules.d/ use the same auditctl command-line syntax to specify the rules. Empty lines and text following a hash sign (#) are ignored.

Furthermore, you can use the auditctl command to read rules from a specified file using the -R option, for example:

# auditctl -R /usr/share/audit/sample-rules/30-stig.rules

11.8. Pre-configured Audit rules files for compliance with standards

To configure Audit for compliance with a specific certification standard, such as OSPP, PCI DSS, or STIG, you can use the set of pre-configured rules files installed with the audit package as a starting point. The sample rules are located in the /usr/share/audit/sample-rules directory.

Warning

The Audit sample rules in the sample-rules directory are not exhaustive nor up to date because security standards are dynamic and subject to change. These rules are provided only to demonstrate how Audit rules can be structured and written. They do not ensure immediate compliance with the latest security standards. To bring your system into compliance with the latest security standards according to specific security guidelines, use the SCAP-based security compliance tools.

30-nispom.rules
Audit rule configuration that meets the requirements specified in the Information System Security chapter of the National Industrial Security Program Operating Manual.
30-ospp-v42*.rules
Audit rule configuration that meets the requirements defined in the OSPP (Protection Profile for General Purpose Operating Systems) profile version 4.2.
30-pci-dss-v31.rules
Audit rule configuration that meets the requirements set by Payment Card Industry Data Security Standard (PCI DSS) v3.1.
30-stig.rules
Audit rule configuration that meets the requirements set by Security Technical Implementation Guides (STIG).

To use these configuration files, copy them to the /etc/audit/rules.d/ directory and use the augenrules --load command, for example:

# cd /usr/share/audit/sample-rules/
# cp 10-base-config.rules 30-stig.rules 31-privileged.rules 99-finalize.rules /etc/audit/rules.d/
# augenrules --load

You can order Audit rules using a numbering scheme. See the /usr/share/audit/sample-rules/README-rules file for more information.

Additional resources

  • audit.rules(7) man page on your system

11.9. Using augenrules to define persistent rules

The augenrules script reads rules located in the /etc/audit/rules.d/ directory and compiles them into an audit.rules file. This script processes all files that end with .rules in a specific order based on their natural sort order. The files in this directory are organized into groups with the following meanings:

10
Kernel and auditctl configuration
20
Rules that could match general rules but you want a different match
30
Main rules
40
Optional rules
50
Server-specific rules
70
System local rules
90
Finalize (immutable)

The rules are not meant to be used all at once. They are pieces of a policy that should be thought out and individual files copied to /etc/audit/rules.d/. For example, to set a system up in the STIG configuration, copy rules 10-base-config, 30-stig, 31-privileged, and 99-finalize.

Once you have the rules in the /etc/audit/rules.d/ directory, load them by running the augenrules script with the --load directive:

# augenrules --load
/sbin/augenrules: No change
No rules
enabled 1
failure 1
pid 742
rate_limit 0
...

Additional resources

  • audit.rules(8) and augenrules(8) man pages.

11.10. Disabling augenrules

Use the following steps to disable the augenrules utility. This switches Audit to use rules defined in the /etc/audit/audit.rules file.

Procedure

  1. Copy the /usr/lib/systemd/system/auditd.service file to the /etc/systemd/system/ directory:

    # cp -f /usr/lib/systemd/system/auditd.service /etc/systemd/system/
  2. Edit the /etc/systemd/system/auditd.service file in a text editor of your choice, for example:

    # vi /etc/systemd/system/auditd.service
  3. Comment out the line containing augenrules, and uncomment the line containing the auditctl -R command:

    #ExecStartPost=-/sbin/augenrules --load
    ExecStartPost=-/sbin/auditctl -R /etc/audit/audit.rules
  4. Reload the systemd daemon to fetch changes in the auditd.service file:

    # systemctl daemon-reload
  5. Restart the auditd service:

    # service auditd restart

Additional resources

11.11. Setting up Audit to monitor software updates

You can use the pre-configured rule 44-installers.rules to configure Audit to monitor the following utilities that install software:

  • dnf [2]
  • yum
  • pip
  • npm
  • cpan
  • gem
  • luarocks

To monitor the rpm utility, install the rpm-plugin-audit package. Audit will then generate SOFTWARE_UPDATE events when it installs or updates a package. You can list these events by entering ausearch -m SOFTWARE_UPDATE on the command line.

Note

Pre-configured rule files cannot be used on systems with the ppc64le and aarch64 architectures.

Prerequisites

Procedure

  1. Copy the pre-configured rule file 44-installers.rules from the /usr/share/audit/sample-rules/ directory to the /etc/audit/rules.d/ directory:

    # cp /usr/share/audit/sample-rules/44-installers.rules /etc/audit/rules.d/
  2. Load the audit rules:

    # augenrules --load

Verification

  1. List the loaded rules:

    # auditctl -l
    -p x-w /usr/bin/dnf-3 -k software-installer
    -p x-w /usr/bin/yum -k software-installer
    -p x-w /usr/bin/pip -k software-installer
    -p x-w /usr/bin/npm -k software-installer
    -p x-w /usr/bin/cpan -k software-installer
    -p x-w /usr/bin/gem -k software-installer
    -p x-w /usr/bin/luarocks -k software-installer
  2. Perform an installation, for example:

    # dnf reinstall -y vim-enhanced
  3. Search the Audit log for recent installation events, for example:

    # ausearch -ts recent -k software-installer
    ––––
    time->Thu Dec 16 10:33:46 2021
    type=PROCTITLE msg=audit(1639668826.074:298): proctitle=2F7573722F6C6962657865632F706C6174666F726D2D707974686F6E002F7573722F62696E2F646E66007265696E7374616C6C002D790076696D2D656E68616E636564
    type=PATH msg=audit(1639668826.074:298): item=2 name="/lib64/ld-linux-x86-64.so.2" inode=10092 dev=fd:01 mode=0100755 ouid=0 ogid=0 rdev=00:00 obj=system_u:object_r:ld_so_t:s0 nametype=NORMAL cap_fp=0 cap_fi=0 cap_fe=0 cap_fver=0 cap_frootid=0
    type=PATH msg=audit(1639668826.074:298): item=1 name="/usr/libexec/platform-python" inode=4618433 dev=fd:01 mode=0100755 ouid=0 ogid=0 rdev=00:00 obj=system_u:object_r:bin_t:s0 nametype=NORMAL cap_fp=0 cap_fi=0 cap_fe=0 cap_fver=0 cap_frootid=0
    type=PATH msg=audit(1639668826.074:298): item=0 name="/usr/bin/dnf" inode=6886099 dev=fd:01 mode=0100755 ouid=0 ogid=0 rdev=00:00 obj=system_u:object_r:rpm_exec_t:s0 nametype=NORMAL cap_fp=0 cap_fi=0 cap_fe=0 cap_fver=0 cap_frootid=0
    type=CWD msg=audit(1639668826.074:298): cwd="/root"
    type=EXECVE msg=audit(1639668826.074:298): argc=5 a0="/usr/libexec/platform-python" a1="/usr/bin/dnf" a2="reinstall" a3="-y" a4="vim-enhanced"
    type=SYSCALL msg=audit(1639668826.074:298): arch=c000003e syscall=59 success=yes exit=0 a0=55c437f22b20 a1=55c437f2c9d0 a2=55c437f2aeb0 a3=8 items=3 ppid=5256 pid=5375 auid=0 uid=0 gid=0 euid=0 suid=0 fsuid=0 egid=0 sgid=0 fsgid=0 tty=pts0 ses=3 comm="dnf" exe="/usr/libexec/platform-python3.6" subj=unconfined_u:unconfined_r:unconfined_t:s0-s0:c0.c1023 key="software-installer"

11.12. Monitoring user login times with Audit

To monitor which users logged in at specific times, you do not need to configure Audit in any special way. You can use the ausearch or aureport tools, which provide different ways of presenting the same information.

Prerequisites

Procedure

To display user log in times, use any one of the following commands:

  • Search the audit log for the USER_LOGIN message type:

    # ausearch -m USER_LOGIN -ts '12/02/2020' '18:00:00' -sv no
    time->Mon Nov 22 07:33:22 2021
    type=USER_LOGIN msg=audit(1637584402.416:92): pid=1939 uid=0 auid=4294967295 ses=4294967295 subj=system_u:system_r:sshd_t:s0-s0:c0.c1023 msg='op=login acct="(unknown)" exe="/usr/sbin/sshd" hostname=? addr=10.37.128.108 terminal=ssh res=failed'
    • You can specify the date and time with the -ts option. If you do not use this option, ausearch provides results from today, and if you omit time, ausearch provides results from midnight.
    • You can use the -sv yes option to filter out successful login attempts and -sv no for unsuccessful login attempts.
  • Pipe the raw output of the ausearch command into the aulast utility, which displays the output in a format similar to the output of the last command. For example:

    # ausearch --raw | aulast --stdin
    root     ssh          10.37.128.108    Mon Nov 22 07:33 - 07:33  (00:00)
    root     ssh          10.37.128.108    Mon Nov 22 07:33 - 07:33  (00:00)
    root     ssh          10.22.16.106     Mon Nov 22 07:40 - 07:40  (00:00)
    reboot   system boot  4.18.0-348.6.el8 Mon Nov 22 07:33
  • Display the list of login events by using the aureport command with the --login -i options.

    # aureport --login -i
    
    Login Report
    ============================================
    # date time auid host term exe success event
    ============================================
    1. 11/16/2021 13:11:30 root 10.40.192.190 ssh /usr/sbin/sshd yes 6920
    2. 11/16/2021 13:11:31 root 10.40.192.190 ssh /usr/sbin/sshd yes 6925
    3. 11/16/2021 13:11:31 root 10.40.192.190 ssh /usr/sbin/sshd yes 6930
    4. 11/16/2021 13:11:31 root 10.40.192.190 ssh /usr/sbin/sshd yes 6935
    5. 11/16/2021 13:11:33 root 10.40.192.190 ssh /usr/sbin/sshd yes 6940
    6. 11/16/2021 13:11:33 root 10.40.192.190 /dev/pts/0 /usr/sbin/sshd yes 6945

Additional resources

  • ausearch(8), aulast(8), and aureport(8) man pages on your system


[2] Because dnf is a symlink in RHEL, the path in the dnf Audit rule must include the target of the symlink. To receive correct Audit events, modify the 44-installers.rules file by changing the path=/usr/bin/dnf path to /usr/bin/dnf-3.
Red Hat logoGithubRedditYoutubeTwitter

Lernen

Testen, kaufen und verkaufen

Communitys

Über Red Hat Dokumentation

Wir helfen Red Hat Benutzern, mit unseren Produkten und Diensten innovativ zu sein und ihre Ziele zu erreichen – mit Inhalten, denen sie vertrauen können.

Mehr Inklusion in Open Source

Red Hat hat sich verpflichtet, problematische Sprache in unserem Code, unserer Dokumentation und unseren Web-Eigenschaften zu ersetzen. Weitere Einzelheiten finden Sie in Red Hat Blog.

Über Red Hat

Wir liefern gehärtete Lösungen, die es Unternehmen leichter machen, plattform- und umgebungsübergreifend zu arbeiten, vom zentralen Rechenzentrum bis zum Netzwerkrand.

© 2024 Red Hat, Inc.