44 Understanding Linux audit #
The Linux audit framework as shipped with this version of SUSE Linux Enterprise Server provides a CAPP-compliant (Controlled Access Protection Profiles) auditing system that reliably collects information about any security-relevant event. The audit records can be examined to determine whether any violation of the security policies has been committed, and by whom.
Providing an audit framework is an important requirement for a CC-CAPP/EAL (Common Criteria-Controlled Access Protection Profiles/Evaluation Assurance Level) certification. Common Criteria (CC) for Information Technology Security Information is an international standard for independent security evaluations. Common Criteria helps customers judge the security level of any IT product they intend to deploy in mission-critical setups.
Common Criteria security evaluations have two sets of evaluation requirements, functional and assurance requirements. Functional requirements describe the security attributes of the product under evaluation and are summarized under the Controlled Access Protection Profiles (CAPP). Assurance requirements are summarized under the Evaluation Assurance Level (EAL). EAL describes any activities that must take place for the evaluators to be confident that security attributes are present, effective, and implemented. Examples for activities of this kind include documenting the developers' search for security vulnerabilities, the patch process, and testing.
This guide provides a basic understanding of how audit works and how it can be set up. For more information about Common Criteria itself, refer to the Common Criteria Web site.
Linux audit helps make your system more secure by providing you with a means to analyze what is happening on your system in great detail. It does not, however, provide additional security itself—it does not protect your system from code malfunctions or any kind of exploits. Instead, audit is useful for tracking these issues and helps you take additional security measures, like AppArmor, to prevent them.
Audit consists of several components, each contributing crucial
functionality to the overall framework. The audit kernel module intercepts
the system calls and records the relevant events. The
auditd
daemon writes the audit
reports to disk. Various command line utilities take care of displaying,
querying, and archiving the audit trail.
Audit enables you to do the following:
- Associate users with processes
Audit maps processes to the user ID that started them. This makes it possible for the administrator or security officer to exactly trace which user owns which process and is potentially doing malicious operations on the system.
Important: Renaming user IDsAudit does not handle the renaming of UIDs. Therefore avoid renaming UIDs (for example, changing
tux
fromuid=1001
touid=2000
) and obsolete UIDs rather than renaming them. Otherwise you would need to changeauditctl
data (audit rules) and would have problems retrieving old data correctly.- Review the audit trail
Linux audit provides tools that write the audit reports to disk and translate them into human readable format.
- Review particular audit events
Audit provides a utility that allows you to filter the audit reports for certain events of interest. You can filter for:
User
Group
Audit ID
Remote Host Name
Remote Host Address
System Call
System Call Arguments
File
File Operations
Success or Failure
- Apply a selective audit
Audit provides the means to filter the audit reports for events of interest and to tune audit to record only selected events. You can create your own set of rules and have the audit daemon record only those of interest to you.
- Guarantee the availability of the report data
Audit reports are owned by
root
and therefore only removable byroot
. Unauthorized users cannot remove the audit logs.- Prevent audit data loss
If the kernel runs out of memory, the audit daemon's backlog is exceeded, or its rate limit is exceeded, audit can trigger a shutdown of the system to keep events from escaping audit's control. This shutdown would be an immediate halt of the system triggered by the audit kernel component without synchronizing the latest logs to disk. The default configuration is to log a warning to syslog rather than to halt the system.
If the system runs out of disk space when logging, the audit system can be configured to perform clean shutdown. The default configuration tells the audit daemon to stop logging when it runs out of disk space.
44.1 Introducing the components of Linux audit #
In SUSE Linux Enterprise Server 15 SP4 the code for
audispd
has
been merged into auditd
.
All audispd
configurations
are now in /etc/audit/auditd.conf
and
/etc/audit/plugins.d
.
The following figure illustrates how the various components of audit interact with each other:
Straight arrows represent the data flow between components while dashed arrows represent lines of control between components.
- auditd
The audit daemon is responsible for writing the audit messages that were generated through the audit kernel interface and triggered by application and system activity to disk. The way the audit daemon is started is controlled by
systemd
. The audit system functions (when started) are controlled by/etc/audit/auditd.conf
. For more information aboutauditd
and its configuration, refer to Section 44.2, “Configuring the audit daemon”.auditctl
The
auditctl
utility controls the audit system. It controls the log generation parameters and kernel settings of the audit interface and the rule sets that determine which events are tracked. For more information aboutauditctl
, refer to Section 44.3, “Controlling the audit system usingauditctl
”.- audit rules
The file
/etc/audit/audit.rules
contains a sequence ofauditctl
commands that are loaded at system boot time immediately after the audit daemon is started. For more information about audit rules, refer to Section 44.4, “Passing parameters to the audit system”.- aureport
The
aureport
utility allows you to create custom reports from the audit event log. This report generation can easily be scripted, and the output can be used by various other applications, for example, to plot these results. For more information aboutaureport
, refer to Section 44.5, “Understanding the audit logs and generating reports”.- ausearch
The
ausearch
utility can search the audit log file for certain events using various keys or other characteristics of the logged format. For more information aboutausearch
, refer to Section 44.6, “Querying the audit daemon logs withausearch
”.- autrace
The
autrace
utility traces individual processes in a fashion similar tostrace
. The output ofautrace
is logged to the audit log. For more information aboutautrace
, refer to Section 44.7, “Analyzing processes withautrace
”.- aulast
Prints a list of the last logged-in users, similarly to
last
.aulast
searches back through the audit logs (or the given audit log file) and displays a list of all users logged in and out based on the range of time in the audit logs.- aulastlog
Prints the last login for all users of a machine similar to the way
lastlog
does. The login name, port, and last login time will be printed.
44.2 Configuring the audit daemon #
Before you can start generating audit logs and processing them,
configure the audit daemon itself.
The /etc/audit/auditd.conf
configuration file
determines how the audit system functions when the daemon has been
started. For most use cases, the default settings shipped with
SUSE Linux Enterprise Server should suffice. For CAPP environments, most of these
parameters need tweaking. The following example is the default
configuration:
local_events = yes write_logs = yes log_file = /var/log/audit/audit.log log_group = audit log_format = RAW flush = INCREMENTAL_ASYNC freq = 50 max_log_file = 8 num_logs = 5 priority_boost = 4 name_format = NONE ##name = mydomain max_log_file_action = ROTATE space_left = 75 space_left_action = SYSLOG verify_email = yes action_mail_acct = root admin_space_left = 50 admin_space_left_action = SUSPEND disk_full_action = SUSPEND disk_error_action = SUSPEND use_libwrap = yes ##tcp_listen_port = 60 tcp_listen_queue = 5 tcp_max_per_addr = 1 ##tcp_client_ports = 1024-65535 tcp_client_max_idle = 0 transport = TCP distribute_network = no q_depth = 1200 overflow_action = SYSLOG max_restarts = 10 plugin_dir = /etc/audit/plugins.d end_of_event_timeout = 2
Refer to man 5 auditd.conf
for an explanation of these
options.
Depending on whether you want your environment to satisfy the requirements of CAPP, you need to be extra restrictive when configuring the audit daemon. Where you need to use particular settings to meet the CAPP requirements, a “CAPP Environment” note tells you how to adjust the configuration.
When the daemon configuration in
/etc/audit/auditd.conf
is complete, the next step is
to focus on controlling the amount of auditing the daemon does, and to
assign sufficient resources and limits to the daemon so it can operate
smoothly.
44.3 Controlling the audit system using auditctl
#
auditctl
is responsible for controlling the status and
some basic system parameters of the audit daemon. It controls the amount
of auditing performed on the system. Using audit rules,
auditctl
controls which components of your system are
subjected to the audit and to what extent they are audited. Audit rules
can be passed to the audit daemon on the auditctl
command line or by composing a rule set and instructing the audit
daemon to process this file. By default, the
auditd
daemon is configured to
check for audit rules under /etc/audit/audit.rules
.
For more details on audit rules, refer to
Section 44.4, “Passing parameters to the audit system”.
The main auditctl
commands to control basic audit
system parameters are:
auditctl
-e
to enable or disable auditauditctl
-f
to control the failure flagauditctl
-r
to control the rate limit for audit messagesauditctl
-b
to control the backlog limitauditctl
-s
to query the current status of the audit daemonauditctl
-S
specifies which system call to audit. Before runningauditctl -S
on your system, add-F arch=b64
to prevent the architecture mismatch warning.
The -e
, -f
, -r
, and
-b
options can also be specified in the
audit.rules
file to avoid having to enter them each
time the audit daemon is started.
Any time you query the status of the audit daemon with
auditctl
-s
or change the status flag
with auditctl
-eFLAG
, a status message
(including information on each of the above-mentioned parameters) is
printed. The following example highlights the typical audit status
message.
auditctl
-s
#enabled 1 failure 1 pid 790 rate_limit 0 backlog_limit 64 lost 0 backlog 0 backlog_wait_time 15000 loginuid_immutable 0 unlocked
Flag |
Meaning [Possible Values] |
Command |
---|---|---|
|
Set the enable flag. [0..2] 0=disable, 1=enable, 2=enable and lock
down the configuration. Note that this only disables logging syscalls,
and other events may still be logged. (See
|
|
|
Set the failure flag. [0..2] 0=silent, 1=printk, 2=panic (immediate halt without synchronizing pending data to disk) |
|
|
Process ID under which
|
— |
|
Set a limit in messages per second. If the rate is not zero and is exceeded, the action specified in the failure flag is triggered. |
|
|
Specify the maximum number of outstanding audit buffers allowed. If all buffers are full, the action specified in the failure flag is triggered. |
|
|
Count the current number of lost audit messages. |
— |
|
Count the current number of outstanding audit buffers. |
— |
44.4 Passing parameters to the audit system #
Commands to control the audit system can be invoked individually from the
shell using auditctl
or batch read from a file using
auditctl -
R
. This latter method is
used by the init scripts to load rules from the file
/etc/audit/audit.rules
after the audit daemon has
been started. The rules are executed in order from top to bottom. Each of
these rules would expand to a separate auditctl
command. The syntax used in the rules file is the same as that used for
the auditctl
command.
Changes made to the running audit system by executing
auditctl
on the command line are not persistent across
system restarts. For changes to persist, add them to the
/etc/audit/audit.rules
file and, if they are not
currently loaded into audit, restart the audit system to load the
modified rule set by using the systemctl restart
auditd
command.
-b 10001 -f 12 -r 103 -e 14
Specify the maximum number of outstanding audit buffers. Depending on the level of logging activity, you might need to adjust the number of buffers to avoid causing too heavy an audit load on your system. | |
Specify the failure flag to use. See Table 44.1, “Audit status flags” for possible values. | |
Specify the maximum number of messages per second that may be issued by the kernel. See Table 44.1, “Audit status flags” for details. | |
Enable or disable the audit subsystem. |
Using audit, you can track any kind of file system access to important files, configurations or resources. You can add watches on these and assign keys to each kind of watch for better identification in the logs.
-w /etc/shadow1 -w /etc -p rx2 -w /etc/passwd -k fk_passwd -p rwxa3
The | |
This rule adds a watch to the | |
This rule adds a file watch to |
System call auditing lets you track your system's behavior on a level even below the application level. When designing these rules, consider that auditing a great many system calls may increase your system load and cause you to run out of disk space. Consider carefully which events need tracking and how they can be filtered to be even more specific.
-a exit,always -S mkdir1 -a exit,always -S access -F a1=42 -a exit,always -S ipc -F a0=23 -a exit,always -S open -F success!=04 -a task,always -F auid=05 -a task,always -F uid=0 -F auid=501 -F gid=wheel6
This rule activates auditing for the | |
This rule adds auditing to the access system call, but only if the
second argument of the system call ( | |
This rule adds an audit context to the IPC multiplexed system call. The
specific | |
This rule audits failed attempts to call open. | |
This rule is an example of a task rule (keyword:
| |
This last rule makes heavy use of filters. All filter options are
combined with a logical AND operator, meaning that this rule applies to
all tasks that carry the audit ID of |
For more details on filtering system call arguments, refer to Section 46.6, “Filtering system call arguments”.
You cannot only add rules to the audit system, but also remove them. There are different methods for deleting the entire rule set at once or for deleting system call rules or file and directory watches:
-D1 -d exit,always -S mkdir2 -W /etc3
Clear the queue of audit rules and delete any preexisting rules. This
rule is used as the first rule in
| |
This rule deletes a system call rule. The | |
This rule tells audit to discard the rule with the directory watch on
|
To get an overview of which rules are currently in use in your audit
setup, run auditctl
-l
. This command
displays all rules with one rule per line.
auditctl
-l
#exit,always watch=/etc perm=rx exit,always watch=/etc/passwd perm=rwxa key=fk_passwd exit,always watch=/etc/shadow perm=rwxa exit,always syscall=mkdir exit,always a1=4 (0x4) syscall=access exit,always a0=2 (0x2) syscall=ipc exit,always success!=0 syscall=open
You can build very sophisticated audit rules by using the various filter
options. Refer to the auditctl(8)
man page for more
information about the options available for building audit filter rules,
and audit rules in general.
44.5 Understanding the audit logs and generating reports #
To understand what the aureport
utility does, it is
vital to know how the logs generated by the audit daemon are structured,
and what exactly is recorded for an event. Only then can you decide which
report types are most appropriate for your needs.
44.5.1 Understanding the audit logs #
The following examples highlight two typical events that are logged by
audit and how their trails in the audit log are read. The audit log or
logs (if log rotation is enabled) are stored in the
/var/log/audit
directory.
The logs record two types of information: record types and event
fields. The record types are identified by type=
in
each log entry. Event fields are all other items on the left side of
the equals signs. In the following examples,
type=SYSCALL
and type=CWD
are
record types, and arch=c000003e
and
syscall=2
are event fields, followed by their values.
Refer to the /usr/include/libaudit.h
file (from the
audit-devel package) to see
a complete list of record types and their definitions.
Run the ausyscall --dump
command to see a table of
syscall numbers, and what they represent:
>
ausyscall --dump
Using x86_64 syscall table:
0 read
1 write
2 open
3 close
4 stat
5 fstat
[...]
The first example is a simple less
command. The second
example covers a great deal of PAM activity in the logs when a user tries
to remotely log in to a machine running audit.
type=SYSCALL msg=audit(1234874638.599:5207): arch=c000003e syscall=2 success=yes exit=4 a0=62fb60 a1=0 a2=31 a3=0 items=1 ppid=25400 pid =25616 auid=0 uid=0 gid=0 euid=0 suid=0 fsuid=0 egid=0 sgid=0 fsgid=0 tty=pts1 ses=1164 comm="less" exe="/usr/bin/less" key="doc_log" type=CWD msg=audit(1234874638.599:5207): cwd="/root" type=PATH msg=audit(1234874638.599:5207): item=0 name="/var/log/audit/ audit.log" inode=1219041 dev=08:06 mode=0100644 ouid=0 ogid=0 rdev=00:00
The above event, a simple less
/var/log/audit/audit.log
, wrote three messages to the log. All
of them are closely linked together and you would not be able to make
sense of one of them without the others. The first message reveals the
following information:
type
The type of event recorded. In this case, it assigns the
SYSCALL
type to an event triggered by a system call. TheCWD
event was recorded to record the current working directory at the time of the syscall. APATH
event is generated for each path passed to the system call. The open system call takes only one path argument, so only generates onePATH
event. It is important to understand that thePATH
event reports the path name string argument without any further interpretation, so a relative path requires manual combination with the path reported by theCWD
event to determine the object accessed.msg
A message ID enclosed in brackets. The ID splits into two parts. All characters before the
:
represent a Unix epoch time stamp. The number after the colon represents the actual event ID. All events that are logged from one application's system call have the same event ID. If the application makes a second system call, it gets another event ID.arch
References the CPU architecture of the system call. Decode this information using the
-i
option on any of yourausearch
commands when searching the logs.syscall
The type of system call as it would have been printed by an
strace
on this particular system call. This data is taken from the list of system calls under/usr/include/asm/unistd.h
and may vary depending on the architecture. In this case,syscall=2
refers to the open system call (seeman open(2)
) invoked by the less application.success
Whether the system call succeeded or failed.
exit
The exit value returned by the system call. For the
open
system call used in this example, this is the file descriptor number. This varies by system call.a0
toa3
The first four arguments to the system call in numeric form. The values of these are system call dependent. In this example (an
open
system call), the following are used:a0=62fb60 a1=8000 a2=31 a3=0
a0
is the start address of the passed path name.a1
is the flags.8000
in hex notation translates to100000
in octal notation, which in turn translates toO_LARGEFILE
.a2
is the mode, which, becauseO_CREAT
was not specified, is unused.a3
is not passed by theopen
system call. Check the manual page of the relevant system call to find out which arguments are used with it.items
The number of strings passed to the application.
ppid
The process ID of the parent of the process analyzed.
pid
The process ID of the process analyzed.
auid
The audit ID. A process is given an audit ID on user login. This ID is then handed down to any child process started by the initial process of the user. Even if the user changes their identity (for example, becomes
root
), the audit ID stays the same. Thus you can always trace actions to the original user who logged in.uid
The user ID of the user who started the process. In this case,
0
forroot
.gid
The group ID of the user who started the process. In this case,
0
forroot
.euid
,suid
,fsuid
Effective user ID, set user ID, and file system user ID of the user that started the process.
egid
,sgid
,fsgid
Effective group ID, set group ID, and file system group ID of the user that started the process.
tty
The terminal from which the application was started. In this case, a pseudo-terminal used in an SSH session.
ses
The login session ID. This process attribute is set when a user logs in and can tie any process to a particular user login.
comm
The application name under which it appears in the task list.
exe
The resolved path name to the binary program.
subj
auditd
records whether the process is subject to any security context, such as AppArmor.unconstrained
, as in this case, means that the process is not confined with AppArmor. If the process had been confined, the binary path name plus the AppArmor profile mode would have been logged.key
If you are auditing many directories or files, assign key strings to each of these watches. You can use these keys with
ausearch
to search the logs for events of this type only.
The second message triggered by the example less
call
does not reveal anything apart from the current working directory when
the less
command was executed.
The third message reveals the following (the type
and
message
flags have already been introduced):
item
In this example,
item
references thea0
argument—a path—that is associated with the originalSYSCALL
message. Had the original call had more than one path argument (such as acp
ormv
command), an additionalPATH
event would have been logged for the second path argument.name
Refers to the path name passed as an argument to the open system call.
inode
Refers to the inode number corresponding to
name
.dev
Specifies the device on which the file is stored. In this case,
08:06
, which stands for/dev/sda1
or “first partition on the first IDE device.”mode
Numerical representation of the file's access permissions. In this case,
root
has read and write permissions and their group (root
) has read access while the entire rest of the world cannot access the file.ouid
andogid
Refer to the UID and GID of the inode itself.
rdev
Not applicable for this example. The
rdev
entry only applies to block or character devices, not to files.
Example 44.9, “An advanced audit event—login via SSH” highlights the audit events triggered by an incoming SSH connection. Most of the messages are related to the PAM stack and reflect the different stages of the SSH PAM process. Several of the audit messages carry nested PAM messages in them that signify that a particular stage of the PAM process has been reached. Although the PAM messages are logged by audit, audit assigns its own message type to each event:
type=USER_AUTH msg=audit(1234877011.791:7731): user pid=26127 uid=0 1 auid=4294967295 ses=4294967295 msg='op=PAM:authentication acct="root" exe="/usr/sbin/sshd" (hostname=jupiter.example.com, addr=192.168.2.100, terminal=ssh res=success)' type=USER_ACCT msg=audit(1234877011.795:7732): user pid=26127 uid=0 2 auid=4294967295 ses=4294967295 msg='op=PAM:accounting acct="root" exe="/usr/sbin/sshd" (hostname=jupiter.example.com, addr=192.168.2.100, terminal=ssh res=success)' type=CRED_ACQ msg=audit(1234877011.799:7733): user pid=26125 uid=0 3 auid=4294967295 ses=4294967295 msg='op=PAM:setcred acct="root" exe="/usr/sbin/sshd" (hostname=jupiter.example.com, addr=192.168.2.100, terminal=/dev/pts/0 res=success)' type=LOGIN msg=audit(1234877011.799:7734): login pid=26125 uid=0 old auid=4294967295 new auid=0 old ses=4294967295 new ses=1172 type=USER_START msg=audit(1234877011.799:7735): user pid=26125 uid=0 4 auid=0 ses=1172 msg='op=PAM:session_open acct="root" exe="/usr/sbin/sshd" (hostname=jupiter.example.com, addr=192.168.2.100, terminal=/dev/pts/0 res=success)' type=USER_LOGIN msg=audit(1234877011.823:7736): user pid=26128 uid=0 5 auid=0 ses=1172 msg='uid=0: exe="/usr/sbin/sshd" (hostname=jupiter.example.com, addr=192.168.2.100, terminal=/dev/pts/0 res=success)' type=CRED_REFR msg=audit(1234877011.828:7737): user pid=26128 uid=0 6 auid=0 ses=1172 msg='op=PAM:setcred acct="root" exe="/usr/sbin/sshd" (hostname=jupiter.example.com, addr=192.168.2.100, terminal=/dev/pts/0 res=success)'
PAM reports that is has successfully requested user authentication for
| |
PAM reports that it has successfully determined whether the user is authorized to log in. | |
PAM reports that the appropriate credentials to log in have been
acquired and that the terminal changed to a normal terminal
( | |
PAM reports that it has successfully opened a session for
| |
The user has successfully logged in. This event is the one used by
| |
PAM reports that the credentials have been successfully reacquired. |
44.5.2 Generating custom audit reports #
The raw audit reports stored in the /var/log/audit
directory tend to become very bulky and hard to understand. To more
easily find relevant messages, use the aureport
utility and create custom reports.
The following use cases highlight a few of the possible report types
that you can generate with aureport
:
- Read audit logs from another file
When the audit logs have moved to another machine or when you want to analyze the logs of several machines on your local machine without wanting to connect to each of these individually, move the logs to a local file and have
aureport
analyze them locally:>
sudo
aureport -if myfile
Summary Report ====================== Range of time in logs: 03/02/09 14:13:38.225 - 17/02/09 14:52:27.971 Selected time for report: 03/02/09 14:13:38 - 17/02/09 14:52:27.971 Number of changes in configuration: 13 Number of changes to accounts, groups, or roles: 0 Number of logins: 6 Number of failed logins: 13 Number of authentications: 7 Number of failed authentications: 573 Number of users: 1 Number of terminals: 9 Number of host names: 4 Number of executables: 17 Number of files: 279 Number of AVC's: 0 Number of MAC events: 0 Number of failed syscalls: 994 Number of anomaly events: 0 Number of responses to anomaly events: 0 Number of crypto events: 0 Number of keys: 2 Number of process IDs: 1211 Number of events: 5320The above command,
aureport
without any arguments, provides only the standard general summary report generated from the logs contained inmyfile
. To create more detailed reports, combine the-if
option with any of the options below. For example, generate a login report that is limited to a certain time frame:>
sudo
aureport -l -ts 14:00 -te 15:00 -if myfile
Login Report ============================================ # date time auid host term exe success event ============================================ 1. 17/02/09 14:21:09 root: 192.168.2.100 sshd /usr/sbin/sshd no 7718 2. 17/02/09 14:21:15 0 jupiter /dev/pts/3 /usr/sbin/sshd yes 7724- Convert numeric entities to text
Some information, such as user IDs, are printed in numeric form. To convert these into a human-readable text format, add the
-i
option to youraureport
command.- Create a rough summary report
If you are interested in the current audit statistics (events, logins, processes, etc.), run
aureport
without any other option.- Create a summary report of failed events
If you want to break down the overall statistics of plain
aureport
to the statistics of failed events, useaureport
--failed
:>
sudo
aureport --failed
Failed Summary Report ====================== Range of time in logs: 03/02/09 14:13:38.225 - 17/02/09 14:57:35.183 Selected time for report: 03/02/09 14:13:38 - 17/02/09 14:57:35.183 Number of changes in configuration: 0 Number of changes to accounts, groups, or roles: 0 Number of logins: 0 Number of failed logins: 13 Number of authentications: 0 Number of failed authentications: 574 Number of users: 1 Number of terminals: 5 Number of host names: 4 Number of executables: 11 Number of files: 77 Number of AVC's: 0 Number of MAC events: 0 Number of failed syscalls: 994 Number of anomaly events: 0 Number of responses to anomaly events: 0 Number of crypto events: 0 Number of keys: 2 Number of process IDs: 708 Number of events: 1583- Create a summary report of successful events
If you want to break down the overall statistics of a plain
aureport
to the statistics of successful events, useaureport
--success
:>
sudo
aureport --success
Success Summary Report ====================== Range of time in logs: 03/02/09 14:13:38.225 - 17/02/09 15:00:01.535 Selected time for report: 03/02/09 14:13:38 - 17/02/09 15:00:01.535 Number of changes in configuration: 13 Number of changes to accounts, groups, or roles: 0 Number of logins: 6 Number of failed logins: 0 Number of authentications: 7 Number of failed authentications: 0 Number of users: 1 Number of terminals: 7 Number of host names: 3 Number of executables: 16 Number of files: 215 Number of AVC's: 0 Number of MAC events: 0 Number of failed syscalls: 0 Number of anomaly events: 0 Number of responses to anomaly events: 0 Number of crypto events: 0 Number of keys: 2 Number of process IDs: 558 Number of events: 3739- Create summary reports
In addition to the dedicated summary reports (main summary and failed and success summary), use the
--summary
option with most of the other options to create summary reports for a particular area of interest only. Not all reports support this option, however. This example creates a summary report for user login events:>
sudo
aureport -u -i --summary
User Summary Report =========================== total auid =========================== 5640 root 13 tux 3 wilber- Create a report of events
To get an overview of the events logged by audit, use the
aureport
-e
command. This command generates a numbered list of all events including date, time, event number, event type, and audit ID.>
sudo
aureport -e -ts 14:00 -te 14:21 Event Report =================================== # date time event type auid success =================================== 1. 17/02/09 14:20:27 7462 DAEMON_START 0 yes 2. 17/02/09 14:20:27 7715 CONFIG_CHANGE 0 yes 3. 17/02/09 14:20:57 7716 USER_END 0 yes 4. 17/02/09 14:20:57 7717 CRED_DISP 0 yes 5. 17/02/09 14:21:09 7718 USER_LOGIN -1 no 6. 17/02/09 14:21:15 7719 USER_AUTH -1 yes 7. 17/02/09 14:21:15 7720 USER_ACCT -1 yes 8. 17/02/09 14:21:15 7721 CRED_ACQ -1 yes 9. 17/02/09 14:21:15 7722 LOGIN 0 yes 10. 17/02/09 14:21:15 7723 USER_START 0 yes 11. 17/02/09 14:21:15 7724 USER_LOGIN 0 yes 12. 17/02/09 14:21:15 7725 CRED_REFR 0 yes- Create a report from all process events
To analyze the log from a process's point of view, use the
aureport
-p
command. This command generates a numbered list of all process events including date, time, process ID, name of the executable, system call, audit ID, and event number.aureport -p
Process ID Report ====================================== # date time pid exe syscall auid event ====================================== 1. 13/02/09 15:30:01 32742 /usr/sbin/cron 0 0 35 2. 13/02/09 15:30:01 32742 /usr/sbin/cron 0 0 36 3. 13/02/09 15:38:34 32734 /usr/lib/gdm/gdm-session-worker 0 -1 37- Create a report from all system call events
To analyze the audit log from a system call's point of view, use the
aureport
-s
command. This command generates a numbered list of all system call events including date, time, number of the system call, process ID, name of the command that used this call, audit ID, and event number.>
sudo
aureport -s
Syscall Report ======================================= # date time syscall pid comm auid event ======================================= 1. 16/02/09 17:45:01 2 20343 cron -1 2279 2. 16/02/09 17:45:02 83 20350 mktemp 0 2284 3. 16/02/09 17:45:02 83 20351 mkdir 0 2285- Create a report from all executable events
To analyze the audit log from an executable's point of view, use the
aureport
-x
command. This command generates a numbered list of all executable events including date, time, name of the executable, the terminal it is run in, the host executing it, the audit ID, and event number.aureport -x
Executable Report ==================================== # date time exe term host auid event ==================================== 1. 13/02/09 15:08:26 /usr/sbin/sshd sshd 192.168.2.100 -1 12 2. 13/02/09 15:08:28 /usr/lib/gdm/gdm-session-worker :0 ? -1 13 3. 13/02/09 15:08:28 /usr/sbin/sshd ssh 192.168.2.100 -1 14- Create a report about files
To generate a report from the audit log that focuses on file access, use the
aureport
-f
command. This command generates a numbered list of all file-related events including date, time, name of the accessed file, number of the system call accessing it, success or failure of the command, the executable accessing the file, audit ID, and event number.>
sudo
aureport -f
File Report =============================================== # date time file syscall success exe auid event =============================================== 1. 16/02/09 17:45:01 /etc/shadow 2 yes /usr/sbin/cron -1 2279 2. 16/02/09 17:45:02 /tmp/ 83 yes /bin/mktemp 0 2284 3. 16/02/09 17:45:02 /var 83 no /bin/mkdir 0 2285- Create a report about users
To generate a report from the audit log that illustrates which users are running what executables on your system, use the
aureport
-u
command. This command generates a numbered list of all user-related events including date, time, audit ID, terminal used, host, name of the executable, and an event ID.aureport -u
User ID Report ==================================== # date time auid term host exe event ==================================== 1. 13/02/09 15:08:26 -1 sshd 192.168.2.100 /usr/sbin/sshd 12 2. 13/02/09 15:08:28 -1 :0 ? /usr/lib/gdm/gdm-session-worker 13 3. 14/02/09 08:25:39 -1 ssh 192.168.2.101 /usr/sbin/sshd 14- Create a report about logins
To create a report that focuses on login attempts to your machine, run the
aureport
-l
command. This command generates a numbered list of all login-related events including date, time, audit ID, host and terminal used, name of the executable, success or failure of the attempt, and an event ID.>
sudo
aureport -l -i
Login Report ============================================ # date time auid host term exe success event ============================================ 1. 13/02/09 15:08:31 tux: 192.168.2.100 sshd /usr/sbin/sshd no 19 2. 16/02/09 12:39:05 root: 192.168.2.101 sshd /usr/sbin/sshd no 2108 3. 17/02/09 15:29:07 geeko: ? tty3 /bin/login yes 7809- Limit a report to a certain time frame
To analyze the logs for a particular time frame, such as only the working hours of Feb 16, 2009, first find out whether this data is contained in the current
audit.log
or whether the logs have been rotated in by runningaureport
-t
:aureport -t
Log Time Range Report ===================== /var/log/audit/audit.log: 03/02/09 14:13:38.225 - 17/02/09 15:30:01.636The current
audit.log
contains all the desired data. Otherwise, use the-if
option to point theaureport
commands to the log file that contains the needed data.Then, specify the start date and time and the end date and time of the desired time frame and combine it with the report option needed. This example focuses on login attempts:
>
sudo
aureport -ts 02/16/09 8:00 -te 02/16/09 18:00 -l
Login Report ============================================ # date time auid host term exe success event ============================================ 1. 16/02/09 12:39:05 root: 192.168.2.100 sshd /usr/sbin/sshd no 2108 2. 16/02/09 12:39:12 0 192.168.2.100 /dev/pts/1 /usr/sbin/sshd yes 2114 3. 16/02/09 13:09:28 root: 192.168.2.100 sshd /usr/sbin/sshd no 2131 4. 16/02/09 13:09:32 root: 192.168.2.100 sshd /usr/sbin/sshd no 2133 5. 16/02/09 13:09:37 0 192.168.2.100 /dev/pts/2 /usr/sbin/sshd yes 2139The start date and time are specified with the
-ts
option. Any event that has a time stamp equal to or after your given start time appears in the report. If you omit the date,aureport
assumes that you meant today. If you omit the time, it assumes that the start time should be midnight of the date specified.Specify the end date and time with the
-te
option. Any event that has a time stamp equal to or before your given event time appears in the report. If you omit the date,aureport
assumes that you meant today. If you omit the time, it assumes that the end time should be now. Use the same format for the date and time as for-ts
.
All reports except the summary ones are printed in column format and sent to STDOUT, which means that this data can be written to other commands very easily. The visualization scripts introduced in Section 44.8, “Visualizing audit data” are examples of how to further process the data generated by audit.
44.6 Querying the audit daemon logs with ausearch
#
The aureport
tool helps you to create overall
summaries of what is happening on the system, but if you are interested
in the details of a particular event, ausearch
is the
tool to use.
ausearch
allows you to search the audit logs using
special keys and search phrases that relate to most of the flags that
appear in event messages in
/var/log/audit/audit.log
. Not all record types
contain the same search phrases. There are no hostname
or uid
entries in a PATH
record,
for example.
When searching, make sure that you choose appropriate search criteria to
catch all records you need. On the other hand, you could be searching for
a specific type of record and still get various other related records
along with it. This is caused by different parts of the kernel
contributing additional records for events that are related to the one to
find. For example, you would always get a PATH
record
along with the SYSCALL
record for an
open
system call.
Any of the command line options can be combined with logical AND operators to narrow down your search.
- Read audit logs from another file
When the audit logs have moved to another machine or when you want to analyze the logs of several machines on your local machine without wanting to connect to each of these individually, move the logs to a local file and have
ausearch
search them locally:>
sudo
ausearch -
option -if myfile- Convert numeric results into text
Some information, such as user IDs are printed in numeric form. To convert these into human readable text format, add the
-i
option to yourausearch
command.- Search by audit event ID
If you have previously run an audit report or done an
autrace
, you should analyze the trail of a particular event in the log. Most of the report types described in Section 44.5, “Understanding the audit logs and generating reports” include audit event IDs in their output. An audit event ID is the second part of an audit message ID, which consists of a Unix epoch time stamp and the audit event ID separated by a colon. All events that are logged from one application's system call have the same event ID. Use this event ID withausearch
to retrieve this event's trail from the log.Use a command similar to the following:
>
sudo
ausearch -a 5207
---- time->Tue Feb 17 13:43:58 2009 type=PATH msg=audit(1234874638.599:5207): item=0 name="/var/log/audit/audit.log" inode=1219041 dev=08:06 mode=0100644 ouid=0 ogid=0 rdev=00:00 type=CWD msg=audit(1234874638.599:5207): cwd="/root" type=SYSCALL msg=audit(1234874638.599:5207): arch=c000003e syscall=2 success=yes exit=4 a0=62fb60 a1=0 a2=31 a3=0 items=1 ppid=25400 pid=25616 auid=0 uid=0 gid=0 euid=0 suid=0 fsuid=0 egid=0 sgid=0 fsgid=0 tty=pts1 ses=1164 comm="less" exe="/usr/bin/less" key="doc_log"The
ausearch
-a
command grabs all records in the logs that are related to the audit event ID provided and displays them. This option can be combined with any other option.- Search by message type
To search for audit records of a particular message type, use the
ausearch
-m MESSAGE_TYPE
command. Examples of valid message types includePATH
,SYSCALL
, andUSER_LOGIN
. Runningausearch
-m
without a message type displays a list of all message types.- Search by login ID
To view records associated with a particular login user ID, use the
ausearch
-ul
command. It displays any records related to the user login ID specified provided that user had been able to log in successfully.- Search by user ID
View records related to any of the user IDs (both user ID and effective user ID) with
ausearch
-ua
. View reports related to a particular user ID withausearch
-ui UID
. Search for records related to a particular effective user ID, use theausearch
-ue EUID
. Searching for a user ID means the user ID of the user creating a process. Searching for an effective user ID means the user ID and privileges that are required to run this process.- Search by group ID
View records related to any of the group IDs (both group ID and effective group ID) with the
ausearch
-ga
command. View reports related to a particular user ID withausearch
-gi GID
. Search for records related to a particular effective group ID, useausearch
-ge EGID
.- Search by command line name
View records related to a certain command, using the
ausearch
-c COMM_NAME
command, for example,ausearch
-c less
for all records related to theless
command.- Search by executable name
View records related to a certain executable with the
ausearch
-x EXE
command, for exampleausearch
-x /usr/bin/less
for all records related to the/usr/bin/less
executable.- Search by system call name
View records related to a certain system call with the
ausearch
-sc SYSCALL
command, for example,ausearch -sc open
for all records related to theopen
system call.- Search by process ID
View records related to a certain process ID with the
ausearch
-p PID
command, for exampleausearch
-p 13368
for all records related to this process ID.- Search by event or system call success value
View records containing a certain system call success value with
ausearch
-sv SUCCESS_VALUE
, for example,ausearch
-sv yes
for all successful system calls.- Search by file name
View records containing a certain file name with
ausearch
-f FILE_NAME
, for example,ausearch
-f /foo/bar
for all records related to the/foo/bar
file. Using the file name alone would work as well, but using relative paths does not work.- Search by terminal
View records of events related to a certain terminal only with
ausearch
-tm TERM
, for example,ausearch
-tm ssh
to view all records related to events on the SSH terminal andausearch
-tm tty
to view all events related to the console.- Search by host name
View records related to a certain remote host name with
ausearch
-hn HOSTNAME
, for example,ausearch
-hn jupiter.example.com
. You can use a host name, fully qualified domain name, or numeric network address.- Search by key field
View records that contain a certain key assigned in the audit rule set to identify events of a particular type. Use the
ausearch
-k KEY_FIELD
, for example,ausearch
-k CFG_etc
to display any records containing theCFG_etc
key.- Search by word
View records that contain a certain string assigned in the audit rule set to identify events of a particular type. The whole string will be matched on file name, host name, and terminal. Use the
ausearch
-w WORD
.- Limit a search to a certain time frame
Use
-ts
and-te
to limit the scope of your searches to a certain time frame. The-ts
option is used to specify the start date and time and the-te
option is used to specify the end date and time. These options can be combined with any of the above. The use of these options is similar to use withaureport
.
44.7 Analyzing processes with autrace
#
In addition to monitoring your system using the rules you set up, you can
also perform dedicated audits of individual processes using the
autrace
command. autrace
works
similarly to the strace
command, but gathers slightly
different information. The output of autrace
is
written to /var/log/audit/audit.log
and does not
look any different from the standard audit log entries.
When performing an autrace
on a process, make sure
that any audit rules are purged from the queue to avoid these rules
clashing with the ones autrace
adds itself. Delete the
audit rules with the auditctl
-D
command. This stops all normal auditing.
>
sudo
auditctl -D
No rulesautrace /usr/bin/less
Waiting to execute: /usr/bin/less Cleaning up... No rules Trace complete. You can locate the records with 'ausearch -i -p 7642'
Always use the full path to the executable to track with
autrace
. After the trace is complete,
autrace
provides the event ID of the trace, so you can
analyze the entire data trail with ausearch
. To
restore the audit system to use the audit rule set again, restart the
audit daemon with systemctl restart auditd
.
44.8 Visualizing audit data #
Neither the data trail in /var/log/audit/audit.log
nor the different report types generated by aureport
,
described in Section 44.5.2, “Generating custom audit reports”, provide an
intuitive reading experience to the user. The aureport
output is formatted in columns and thus easily available to any sed,
Perl, or awk scripts that users might connect to the audit framework to
visualize the audit data.
The visualization scripts (see Section 45.6, “Configuring log visualization”) are one example of how to use standard Linux tools available with SUSE Linux Enterprise Server or any other Linux distribution to create easy-to-read audit output. The following examples help you understand how the plain audit reports can be transformed into human readable graphics.
The first example illustrates the relationship of programs and system
calls. To get to this kind of data, you need to determine the appropriate
aureport
command that delivers the source data from
which to generate the final graphic:
>
sudo
aureport -s -i
Syscall Report ======================================= # date time syscall pid comm auid event ======================================= 1. 16/02/09 17:45:01 open 20343 cron unset 2279 2. 16/02/09 17:45:02 mkdir 20350 mktemp root 2284 3. 16/02/09 17:45:02 mkdir 20351 mkdir root 2285 ...
The first thing that the visualization script needs to do on this report
is to extract only those columns that are of interest, in this example,
the syscall
and the comm
columns.
The output is sorted and duplicates removed then the final output is
written into the visualization program itself:
LC_ALL=C aureport -s -i | awk '/^[0-9]/ { print $6" "$4 }' | sort | uniq | mkgraph
The second example illustrates the different types of events and how many
of each type have been logged. The appropriate
aureport
command to extract this kind of information
is aureport -e
:
>
sudo
aureport -e -i --summary Event Summary Report ====================== total type ====================== 2434 SYSCALL 816 USER_START 816 USER_ACCT 814 CRED_ACQ 810 LOGIN 806 CRED_DISP 779 USER_END 99 CONFIG_CHANGE 52 USER_LOGIN
Because this type of report already contains a two column output, it is only fed into the visualization script and transformed into a bar chart.
>
sudo
aureport -e -i --summary | mkbar events
For background information about the visualization of audit data, refer to the Web site of the audit project at http://people.redhat.com/sgrubb/audit/visualize/index.html.
44.9 Relaying audit event notifications #
The auditing system also allows external applications to access and
use the auditd
daemon in real
time. This feature is provided by so called audit
dispatcher which allows, for example, intrusion detection
systems to use auditd
to receive
enhanced detection information.
The configuration of auditd
is
stored in /etc/audit/auditd.conf
. The file includes
the following options:
q_depth
Specifies the size of the event dispatcher internal queue. If syslog complains about audit events getting dropped, increase this value. Default is 250.
overflow_action
Specifies the way the audit daemon will react to the internal queue overflow. Possible values are
ignore
(nothing happens),syslog
(issues a warning to syslog),suspend
(stop processing events),single
(the computer system will be put in single user mode), orhalt
(shuts the system down).priority_boost
Specifies the priority for the audit event dispatcher (in addition to the audit daemon priority itself). Default is 4 which means no change in priority.
name_format
Specifies the way the computer node name is inserted into the audit event. Possible values are
none
(no computer name is inserted),hostname
(name returned by thegethostname
system call),fqd
(fully qualified domain name of the machine),numeric
(IP address of the machine), oruser
(user defined string from thename
option). Default isnone
.name
Specifies a user-defined string which identifies the machine. The
name_format
option must be set touser
, otherwise this option is ignored.max_restarts
A non-negative number that tells the audit event dispatcher how many times it can try to restart a crashed plug-in. The default is 10.
q_depth = 250 overflow_action = SYSLOG priority_boost = 4 name_format = HOSTNAME #name = mydomain
The plug-in programs install their configuration files in a special
directory, /etc/audit/plugins.d
.
The plug-in configuration files have the following options:
active
Specifies if the program will use
auditd
. Possible values areyes
orno
.direction
Specifies the way the plug-in was designed to communicate with audit. It informs the event dispatcher in which directions the events flow. Possible values are
in
orout
.path
Specifies the absolute path to the plug-in executable. In case of internal plug-ins, this option specifies the plug-in name.
type
Specifies the way the plug-in is to be run. Possible values are
builtin
oralways
. Usebuiltin
for internal plug-ins (af_unix
andsyslog
) andalways
for most (if not all) other plug-ins. Default isalways
.args
Specifies the argument that is passed to the plug-in program. Normally, plug-in programs read their arguments from their configuration file and do not need to receive any arguments. There is a limit of two arguments.
format
Specifies the format of data that the audit dispatcher passes to the plug-in program. Valid options are
binary
orstring
.binary
passes the data exactly as the event dispatcher receives them from the audit daemon.string
instructs the dispatcher to change the event into a string that is parseable by the audit parsing library. Default isstring
.
active = no direction = out path = /sbin/audisp-syslog type = builtin args = LOG_INFO format = string