AUDIT.RULES(category12-datenbank-server.html) - phpMan

AUDIT.RULES(7)          System Administration Utilities         AUDIT.RULES(7)
NAME
       audit.rules - a set of rules loaded in the kernel audit system
DESCRIPTION
       audit.rules is a file containing audit rules that will be loaded by the
       audit daemon's init script whenever the daemon is started. The auditctl
       program  is used by the initscripts to perform this operation. The syn-
       tax for the rules is essentially the same as when typing in an auditctl
       command  at  a shell prompt except you do not need to type the auditctl
       command name since that is implied. The audit rules  come  in  3  vari-
       eties: control, file, and syscall.
   Control
       Control  commands generally involve configuring the audit system rather
       than telling it what to watch for.  These  commands  typically  include
       deleting  all  rules,  setting  the size of the kernel's backlog queue,
       setting the failure mode, setting the event  rate  limit,  or  to  tell
       auditctl  to  ignore  syntax  errors in the rules and continue loading.
       Generally, these rules are at the top of the rules file.
   File System
       File System rules are sometimes called watches. These rules are used to
       audit  access to particular files or directories that you may be inter-
       ested in. If the path given in a watch rule is a  directory,  then  the
       rule  used  is  recursive to the bottom of the directory tree excluding
       any directories that may be mount points. The  syntax  of  these  watch
       rules generally follow this format:
       -w path-to-file -p permissions -k keyname
       where the permission are any one of the following:
              r - read of the file
              w - write to the file
              x - execute the file
              a - change in the file's attribute
       Watches  can  also  be created using the syscall format described below
       which allow for greater flexibility and options.  Using  syscall  rules
       you  can  choose between path and dir which is against a specific inode
       or directory tree respectively. It should also be noted that the recur-
       sive directory watch will stop if there is a mount point below the par-
       ent directory. There is an option  to  make  the  mounted  subdirectory
       equivalent by using a -q rule.
   System Call
       The system call rules are loaded into a matching engine that intercepts
       each syscall that all programs on the system  makes.  Therefore  it  is
       very  important  to only use syscall rules when you have to since these
       affect performance. The more rules, the bigger the performance hit. You
       can  help  the performance, though, by combining syscalls into one rule
       whenever possible.
       The Linux kernel has 6 rule matching lists or filters as they are some-
       times  called.  They  are:  task,  exit, user, exclude, filesystem, and
       io_uring. The task list is  checked  only  during  the  fork  or  clone
       syscalls. It is rarely used in practice.
       The  exit  filter  is the place where all syscall and file system audit
       requests are evaluated.
       The user filter is used to filter (remove) some events  that  originate
       in  user  space.   By  default,  any event originating in user space is
       allowed. So, if there are some events that you do not want to see, then
       this  is  a place where some can be removed. See auditctl(8) for fields
       that are valid.
       The exclude filter is used to exclude certain events from  being  emit-
       ted.  The  msgtype and a number of subject attribute fields can be used
       to tell the kernel which message types you do not want to record.  This
       filter  can  remove the event as a whole and is not selective about any
       other attribute. The user and exit filters are better suited to  selec-
       tively  auditing  events.   The  action  is  ignored  for  this filter,
       defaulting to "never".
       The io_uring filter is used to watch underlying syscalls  performed  by
       io_uring operations.
       Syscall rules take the general form of:
       -a action,list -S syscall -F field=value -k keyname
       The  -a  option tells the kernel's rule matching engine that we want to
       append a rule at the end of the rule list. But we need to specify which
       rule  list  it  goes on and what action to take when it triggers. Valid
       actions are:
              always - always create an event
              never  - never create an event
       The action and list are separated by a comma but no space  in  between.
       Valid  lists  are: task, exit, user, exclude, filesystem, and io_uring.
       Their meaning was explained earlier.
       Next in the rule would normally be the -S option. This field can either
       be  the  syscall  name  or  number. For readability, the name is almost
       always used. You may give more than one syscall in a rule by specifying
       another  -S  option.  When sent into the kernel, all syscall fields are
       put into a mask so that one compare can determine if the syscall is  of
       interest.  So,  adding multiple syscalls in one rule is very efficient.
       When you specify a syscall name, auditctl will look up the name and get
       its  syscall  number.  This leads to some problems on bi-arch machines.
       The 32 and 64 bit syscall numbers sometimes, but not always,  line  up.
       So,  to  solve this problem, you would generally need to break the rule
       into 2 with one specifying -F arch=b32  and  the  other  specifying  -F
       arch=b64.  This  needs to go in front of the -S option so that auditctl
       looks at the right lookup table when returning the number.
       After the syscall is specified, you would normally have one or more  -F
       options  that fine tune what to match against. Rather than list all the
       valid field types here, the reader should look at the auditctl man page
       which  has  a  full  listing  of each field and what it means. But it's
       worth mentioning a couple things.
       The audit system considers uids to be unsigned numbers. The audit  sys-
       tem  uses  the  number  -1 to indicate that a loginuid is not set. This
       means that when it's printed out, it looks like  4294967295.  But  when
       you  write rules, you can use either "unset" which is easy to remember,
       or -1, or 4294967295. They are all equivalent. If you write a rule that
       you  wanted  try to get the valid users of the system, you need to look
       in /etc/login.defs to see where user accounts start.  For  example,  if
       UID_MIN is 1000, then you would also need to take into account that the
       unsigned representation of -1 is higher than 500. So you would  address
       this with the following piece of a rule:
       -F auid>=1000 -F auid!=unset
       These individual checks are "anded" and both have to be true.
       The  last  thing  to know about syscall rules is that you can add a key
       field which is a free form text string that you want inserted into  the
       event to help identify its meaning. This is discussed in more detail in
       the NOTES section.
NOTES
       The purpose of auditing is to be able to do an  investigation  periodi-
       cally or whenever an incident occurs. A few simple steps in planning up
       front will make this job easier. The best advice is to use keys in both
       the  watches and system call rules to give the rule a meaning. If rules
       are related or together meet a specific requirement, then give  them  a
       common  key  name. You can use this during your investigation to select
       only results with a specific meaning.
       When doing an investigation, you would normally start off with the main
       aureport output to just get an idea about what is happening on the sys-
       tem. This report mostly tells you about events that are hard  coded  by
       the  audit  system  such  as  login/out, uses of authentication, system
       anomalies, how many users have been on the machine, and if SE Linux has
       detected any AVCs.
       aureport --start this-week
       After  looking  at  the  report, you probably want to get a second view
       about what rules you loaded that have been triggering.  This  is  where
       keys  become  important. You would generally run the key summary report
       like this:
       aureport --start this-week --key --summary
       This will give an ordered listing of the  keys  associated  with  rules
       that  have  been  triggering.  If, for example, you had a syscall audit
       rule that triggered on the failure to open files with EPERM that had  a
       key field of access like this:
       -a always,exit -F arch=b64 -S open -S openat -S openat2 -F exit=-EPERM -k access
       Then  you can isolate these failures with ausearch and pipe the results
       to aureport for display. Suppose your investigation noticed  a  lot  of
       the  access denied events. If you wanted to see the files that unautho-
       rized access has been attempted, you could run the following command:
       ausearch --start this-week -k access --raw | aureport --file --summary
       This will give an ordered list showing which files are  being  accessed
       with  the EPERM failure. Suppose you wanted to see which users might be
       having failed access, you would run the following command:
       ausearch --start this-week -k access --raw | aureport --user --summary
       If your investigation showed a lot of failed accesses to  a  particular
       file, you could run the following report to see who is doing it:
       ausearch  --start this-week -k access -f /path-to/file --raw | aureport
       --user -i
       This report will give you the individual access attempts by person.  If
       you  needed  to  see the actual audit event that is being reported, you
       would look at the date, time, and event columns. Assuming the event was
       822  and  it  occurred at 2:30 on 09/01/2009 and you use the en_US.utf8
       locale, the command would look something like this:
       ausearch --start 09/01/2009 02:30 -a 822 -i --just-one
       This will select the first event from that day and time with the match-
       ing  event id and interpret the numeric values into human readable val-
       ues.
       The most important step in being able to do this kind  of  analysis  is
       setting up key fields when the rules were originally written. It should
       also be pointed out that you can have more than one key  field  associ-
       ated with any given rule.
TROUBLESHOOTING
       If  you  are  not  getting  events  on syscall rules that you think you
       should, try running a test program under strace so that you can see the
       syscalls.  There  is  a chance that you might have identified the wrong
       syscall.
       If you get a warning from auditctl saying, "32/64 bit syscall  mismatch
       in  line XX, you should specify an arch". This means that you specified
       a syscall rule on a bi-arch system where the syscall  has  a  different
       syscall number for the 32 and 64 bit interfaces. This means that on one
       of those interfaces you are likely auditing the wrong syscall. To solve
       the  problem,  re-write  the  rule as two rules specifying the intended
       arch for each rule. For example,
       -a always,exit -S openat -k access
       would be rewritten as
       -a always,exit -F arch=b32 -S openat -k access
       -a always,exit -F arch=b64 -S openat -k access
       If you get a warning that says, "entry rules  deprecated,  changing  to
       exit rule". This means that you have a rule intended for the entry fil-
       ter, but that filter is no longer available. Auditctl moved  your  rule
       to the exit filter so that it's not lost. But to solve this so that you
       do not get the warning any more, you need to change the offending  rule
       from entry to exit.
EXAMPLES
       The  following  rule  shows  how to audit failed access to files due to
       permission problems. Note that it takes two rules for each arch ABI  to
       audit  this since file access can fail with two different failure codes
       indicating permission problems.
       -a always,exit -F arch=b32 -S open -S openat -S openat2 -F exit=-EACCES -k access
       -a always,exit -F arch=b32 -S open -S openat -S openat2 -F exit=-EPERM -k access
       -a always,exit -F arch=b64 -S open -S openat -S openat2 -F exit=-EACCES -k access
       -a always,exit -F arch=b64 -S open -S openat -S openat2 -F exit=-EPERM -k access
IO_URING RULES
       Io_uring rules do not take an arch field. It is implicit in the  speci-
       fication  of  the  filter.  The following example rule watches for file
       opens through the io_uring subsystem:
       -a always,io_uring -S openat -S openat2 -F key=access
HARD WIRED EVENTS
       If auditing is enabled, then you can get any event that is  not  caused
       by  syscall  or  file  watch  rules  (because  you don't have any rules
       loaded). So, that means, any event from 1100-1299, 1326, 1328, 1331 and
       higher  can  be  emitted.  The reason that there are a number of events
       that are hardwired is because they are required by  regulatory  compli-
       ance  and  are  sent  automatically  as  a  convenience.  (For example,
       logon/logoff is a mandatory event in all  security  guidance.)  If  you
       don't want this, you can use the exclude filter to drop events that you
       do not want.
       -a always,exclude -F msgtype=CRED_REFR
SEE ALSO
       auditctl(8), auditd(8).
AUTHOR
       Steve Grubb
Red Hat                            Feb 2023                     AUDIT.RULES(7)