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Initial Information Gathering
Basic Information
First of all, it's recommended to have some USB with good known binaries and libraries on it (you can just get a ubuntu and copy the folders /bin, /sbin, /lib, and /lib64), then mount the USN, and modify the env variables to use those binaries:
export PATH=/mnt/usb/bin:/mnt/usb/sbin
export LD_LIBRARY_PATH=/mnt/usb/lib:/mnt/usb/lib64
Once you have configured the system to use good and known binaries you can start extracting some basic information:
date #Date and time (Clock my be skewed, Might be in different timezone)
uname -a #OS info
ifconfig -a || ip a #Network interfaces (promiscuosu mode?)
ps -ef #Running processes
netstat -anp #Proccess and ports
lsof -V #Open files
netstat -rn; route #Routing table
df; mount #Free space and mounted devices
free #Meam and swap space
w #Who is connected
last -Faiwx #Logins
lsmod #What is loaded
cat /etc/passwd #Unexpected data?
cat /etc/shadow #Unexpected data?
find /directory -type f -mtime -1 -print #Find modified files during the last minute in the directory
Suspicious information
While obtaining the basic information you should check for weird things like:
- root processes usually run with low PIDS, so if you find a root process with a big PID you may suspect
- Check registered logins of users without a shell inside
/etc/passwd
- Check for password hashes inside
/etc/shadow
for users without a shell
Memory Dump
In order to obtain the memory of the running system it's recommended to use LiME.
In order to compile it you need to use the exact same kernel the victim machine is using.
{% hint style="info" %} Remember that you cannot install LiME or any other thing in the victim machine it will make several changes to it {% endhint %}
So, if you have an identical version of Ubuntu you can use apt-get install lime-forensics-dkms
In other cases you need to download LiME from github can compile it with correct kernel headers. In order to obtain the exact kernel headers of the victim machine, you can just copy the directory /lib/modules/<kernel version>
to your machine, and then compile LiME using them:
make -C /lib/modules/<kernel version>/build M=$PWD
sudo insmod lime.ko "path=/home/sansforensics/Desktop/mem_dump.bin format=lime"
LiME supports 3 formats:
- Raw (every segment concatenated together)
- Padded (same as raw, but with zeroes in right bits)
- Lime (recommended format with metadata
LiME can also be use to send the dump via network instead of storing it on the system using something like: path=tcp:4444
Disk Imaging
Shutting down
First of all you will need to shutdown the system. This isn't always an option as some times system will be a production server that the company cannot afford to shutdown.
There are 2 ways of shutting down the system, a normal shutdown and a "plug the plug" shutdown. The first one will allow the processes to terminate as usual and the filesystem to be synchronized, but I will also allow the possible malware to destroy evidences. The "pull the plug" approach may carry some information loss (as we have already took an image of the memory not much info is going to be lost) and the malware won't have any opportunity to do anything about it. Therefore, if you suspect that there may be a malware, just execute the sync
command on the system and pull the plug.
Taking an image of the disk
It's important to note that before connecting to your computer anything related to the case, you need to be sure that it's going to be mounted as read only to avoid modifying the any information.
#Create a raw copy of the disk
dd if=<subject device> of=<image file> bs=512
#Raw copy with hashes along the way (more secur s it checks hashes while it's copying the data)
dcfldd if=<subject device> of=<image file> bs=512 hash=<algorithm> hashwindow=<chunk size> hashlog=<hash file>
dcfldd if=/dev/sdc of=/media/usb/pc.image hash=sha256 hashwindow=1M hashlog=/media/usb/pc.hashes
Disk Image pre-analysis
Imaging that you receive a disk image with no more data.
#Find that it's actually a disk imageusing "file" command
file disk.img
disk.img: Linux rev 1.0 ext4 filesystem data, UUID=59e7a736-9c90-4fab-ae35-1d6a28e5de27 (extents) (64bit) (large files) (huge files)
#Check which type of disk image it's
img_stat -t evidence.img
raw
#You can list supported types with
img_stat -i list
Supported image format types:
raw (Single or split raw file (dd))
aff (Advanced Forensic Format)
afd (AFF Multiple File)
afm (AFF with external metadata)
afflib (All AFFLIB image formats (including beta ones))
ewf (Expert Witness Format (EnCase))
#Data of the image
fsstat -i raw -f ext4 disk.img
FILE SYSTEM INFORMATION
--------------------------------------------
File System Type: Ext4
Volume Name:
Volume ID: 162850f203fd75afab4f1e4736a7e776
Last Written at: 2020-02-06 06:22:48 (UTC)
Last Checked at: 2020-02-06 06:15:09 (UTC)
Last Mounted at: 2020-02-06 06:15:18 (UTC)
Unmounted properly
Last mounted on: /mnt/disk0
Source OS: Linux
[...]
#ls inside the image
fls -i raw -f ext4 disk.img
d/d 11: lost+found
d/d 12: Documents
d/d 8193: folder1
d/d 8194: folder2
V/V 65537: $OrphanFiles
#ls inside folder
fls -i raw -f ext4 disk.img 12
r/r 16: secret.txt
#cat file inside image
icat -i raw -f ext4 disk.img 16
ThisisTheMasterSecret
Search for known Malware
Modified System Files
Some Linux systems have a feature to verify the integrity of many installed components, providing an effective way to identify unusual or out of place files. For instance, rpm -Va
on Linux is designed to verify all packages that were installed using RedHat Package Manager.
#RedHat
rpm -Va
#Debian
dpkg --verify
debsums | grep -v "OK$" #apt-get install debsums
Malware/Rootkit Detectors
Read the following page to learn about tools that can be useful to find malware:
{% content-ref url="malware-analysis.md" %} malware-analysis.md {% endcontent-ref %}
Search installed programs
Package Manager
On Debian-based systems, the /var/ lib/dpkg/status file contains details about installed packages and the /var/log/dpkg.log file records information when a package is installed.
On RedHat and related Linux distributions the rpm -qa --root=/ mntpath/var/lib/rpm
command will list the contents of an RPM database on a subject systems.
#Debian
cat /var/lib/dpkg/status | grep -E "Package:|Status:"
cat /var/log/dpkg.log | grep installed
#RedHat
rpm -qa --root=/ mntpath/var/lib/rpm
Other
Not all installed programs will be listed by the above commands because some applications are not available as packages for certain systems and must be installed from source. Therefore, a review of locations such as /usr/local and /opt may reveal other applications that have been compiled and installed from source code.
ls /opt /usr/local
Another good idea is to check the common folders inside $PATH for binaries not related to installed packages:
#Both lines are going to print the executables in /sbin non related to installed packages
#Debian
find /sbin/ -exec dpkg -S {} \; | grep "no path found"
#RedHat
find /sbin/ –exec rpm -qf {} \; | grep "is not"
Recover Deleted Running Binaries
Inspect AutoStart locations
Scheduled Tasks
cat /var/spool/cron/crontabs/* \
/var/spool/cron/atjobs \
/var/spool/anacron \
/etc/cron* \
/etc/at* \
/etc/anacrontab \
/etc/incron.d/* \
/var/spool/incron/* \
#MacOS
ls -l /usr/lib/cron/tabs/ /Library/LaunchAgents/ /Library/LaunchDaemons/ ~/Library/LaunchAgents/
Services
It is extremely common for malware to entrench itself as a new, unauthorized service. Linux has a number of scripts that are used to start services as the computer boots. The initialization startup script /etc/inittab calls other scripts such as rc.sysinit and various startup scripts under the /etc/rc.d/ directory, or /etc/rc.boot/ in some older versions. On other versions of Linux, such as Debian, startup scripts are stored in the /etc/init.d/ directory. In addition, some common services are enabled in /etc/inetd.conf or /etc/xinetd/ depending on the version of Linux. Digital investigators should inspect each of these startup scripts for anomalous entries.
- /etc/inittab
- /etc/rc.d/
- /etc/rc.boot/
- /etc/init.d/
- /etc/inetd.conf
- /etc/xinetd/
- /etc/systemd/system
- /etc/systemd/system/multi-user.target.wants/
Kernel Modules
On Linux systems, kernel modules are commonly used as rootkit components to malware packages. Kernel modules are loaded when the system boots up based on the configuration information in the /lib/modules/'uname -r'
and /etc/modprobe.d
directories, and the /etc/modprobe
or /etc/modprobe.conf
file. These areas should be inspected for items that are related to malware.
Other AutoStart Locations
There are several configuration files that Linux uses to automatically launch an executable when a user logs into the system that may contain traces of malware.
- /etc/profile.d/* , /etc/profile , /etc/bash.bashrc are executed when any user account logs in.
- ∼/.bashrc , ∼/.bash_profile , ~/.profile , ∼/.config/autostart are executed when the specific user logs in.
- /etc/rc.local It is traditionally executed after all the normal system services are started, at the end of the process of switching to a multiuser runlevel.
Examine Logs
Look in all available log files on the compromised system for traces of malicious execution and associated activities such as creation of a new service.
Pure Logs
Logon events recorded in the system and security logs, including logons via the network, can reveal that malware or an intruder gained access to a compromised system via a given account at a specific time. Other events around the time of a malware infection can be captured in system logs, including the creation of a new service or new accounts around the time of an incident.
Interesting system logons:
- /var/log/syslog (debian) or /var/log/messages (Redhat)
- Shows general messages and info regarding the system. Basically a data log of all activity throughout the global system.
- /var/log/auth.log (debian) or /var/log/secure (Redhat)
- Keep authentication logs for both successful or failed logins, and authentication processes. Storage depends on system type.
cat /var/log/auth.log | grep -iE "session opened for|accepted password|new session|not in sudoers"
- /var/log/boot.log: start-up messages and boot info.
- /var/log/maillog or var/log/mail.log: is for mail server logs, handy for postfix, smtpd, or email-related services info running on your server.
- /var/log/kern.log: keeps in Kernel logs and warning info. Kernel activity logs (e.g., dmesg, kern.log, klog) can show that a particular service crashed repeatedly, potentially indicating that an unstable trojanized version was installed.
- /var/log/dmesg: a repository for device driver messages. Use dmesg to see messages in this file.
- /var/log/faillog: records info on failed logins. Hence, handy for examining potential security breaches like login credential hacks and brute-force attacks.
- /var/log/cron: keeps a record of Crond-related messages (cron jobs). Like when the cron daemon started a job.
- /var/log/daemon.log: keeps track of running background services but doesn’t represent them graphically.
- /var/log/btmp: keeps a note of all failed login attempts.
- /var/log/httpd/: a directory containing error_log and access_log files of the Apache httpd daemon. Every error that httpd comes across is kept in the error_log file. Think of memory problems and other system-related errors. access_log logs all requests which come in via HTTP.
- /var/log/mysqld.log or /var/log/mysql.log : MySQL log file that records every debug, failure and success message, including starting, stopping and restarting of MySQL daemon mysqld. The system decides on the directory. RedHat, CentOS, Fedora, and other RedHat-based systems use /var/log/mariadb/mariadb.log. However, Debian/Ubuntu use /var/log/mysql/error.log directory.
- /var/log/xferlog: keeps FTP file transfer sessions. Includes info like file names and user-initiated FTP transfers.
- /var/log/* : You should always check for unexpected logs in this directory
{% hint style="info" %} Linux system logs and audit subsystems may be disabled or deleted in an intrusion or malware incident. In fact, because logs on Linux systems generally contain some of the most useful information about malicious activities, intruders routinely delete them. Therefore, when examining available log files, it is important to look for gaps or out of order entries that might be an indication of deletion or tampering. {% endhint %}
Command History
Many Linux systems are configured to maintain a command history for each user account:
- ~/.bash_history
- ~/.history
- ~/.sh_history
- ~/.*_history
Logins
Using the command last -Faiwx
it's possible to get the list of users that have logged in.
It's recommended to check if those logins make sense:
- Any unknown user?
- Any user that shouldn't have a shell has logged in?
This is important as attackers some times may copy /bin/bash
inside /bin/false
so users like lightdm may be able to login.
Note that you can also take a look to this information reading the logs.
Application Traces
- SSH: Connections to systems made using SSH to and from a compromised system result in entries being made in files for each user account (∼/.ssh/authorized_keys and ∼/.ssh/known_keys). These entries can reveal the hostname or IP address of the remote hosts.
- Gnome Desktop: User accounts may have a ∼/.recently-used.xbel file that contains information about files that were recently accessed using applications running in the Gnome desktop.
- VIM: User accounts may have a ∼/.viminfo file that contains details about the use of VIM, including search string history and paths to files that were opened using vim.
- Open Office: Recent files.
- MySQL: User accounts may have a ∼/.mysql_history file that contains queries executed using MySQL.
- Less: User accounts may have a ∼/.lesshst file that contains details about the use of less, including search string history and shell commands executed via less
USB Logs
usbrip is a small piece of software written in pure Python 3 which parses Linux log files (/var/log/syslog*
or /var/log/messages*
depending on the distro) for constructing USB event history tables.
It is interesting to know all the USBs that have been used and it will be more useful if you have an authorized list of USB to find "violation events" (the use of USBs that aren't inside that list).
Installation
pip3 install usbrip
usbrip ids download #Downloal USB ID database
Examples
usbrip events history #Get USB history of your curent linux machine
usbrip events history --pid 0002 --vid 0e0f --user kali #Search by pid OR vid OR user
#Search for vid and/or pid
usbrip ids download #Downlaod database
usbrip ids search --pid 0002 --vid 0e0f #Search for pid AND vid
More examples and info inside the github: https://github.com/snovvcrash/usbrip
Review User Accounts and Logon Activities
Examine the /etc/passwd, /etc/shadow and security logs for unusual names or accounts created and/or used in close proximity to known unauthorized events. Also check possible sudo brute-force attacks.
Moreover, check files like /etc/sudoers and /etc/groups for unexpected privileges given to users.
Finally look for accounts with no passwords or easily guessed passwords.
Examine File System
File system data structures can provide substantial amounts of information related to a malware incident, including the timing of events and the actual content of malware.
Malware is increasingly being designed to thwart file system analysis. Some malware alter date-time stamps on malicious files to make it more difficult to find them with time line analysis. Other malicious code is designed to only store certain information in memory to minimize the amount of data stored in the file system.
To deal with such anti-forensic techniques, it is necessary to pay careful attention to time line analysis of file system date-time stamps and to files stored in common locations where malware might be found.
- Using autopsy you can see the timeline of events that may be useful to discover suspicions activity. You can also use the
mactime
feature from Sleuth Kit directly. - Check for unexpected scripts inside $PATH (maybe some sh or php scripts?)
- Files in
/dev
use to be special files, you may find non-special files here related to malware. - Look for unusual or hidden files and directories, such as “.. ” (dot dot space) or “..^G ” (dot dot control-G)
- setuid copies of /bin/bash on the system
find / -user root -perm -04000 –print
- Review date-time stamps of deleted inodes for large numbers of files being deleted around the same time, which might indicate malicious activity such as installation of a rootkit or trojanized service.
- Because inodes are allocated on a next available basis, malicious files placed on the system at around the same time may be assigned consecutive inodes. Therefore, after one component of malware is located, it can be productive to inspect neighbouring inodes.
- Also check directories like /bin or /sbin as the modified and/or changed time of new or modified files me be interesting.
- It's interesting to see the files and folders of a directory sorted by creation date instead alphabetically to see which files/folders are more recent (last ones usually).
You can check the most recent files of a folder using ls -laR --sort=time /bin
You can check the inodes of the files inside a folder using ls -lai /bin |sort -n
{% hint style="info" %} Note that an attacker can modify the time to make files appear legitimate, but he cannot modify the inode. If you find that a file indicates that it was created and modify at the same time of the rest of the files in the same folder, but the inode is unexpectedly bigger, then the timestamps of that file were modified. {% endhint %}
Compare files of different filesystem versions
Find added files
git diff --no-index --diff-filter=A _openwrt1.extracted/squashfs-root/ _openwrt2.extracted/squashfs-root/
Find Modified content
git diff --no-index --diff-filter=M _openwrt1.extracted/squashfs-root/ _openwrt2.extracted/squashfs-root/ | grep -E "^\+" | grep -v "Installed-Time"
Find deleted files
git diff --no-index --diff-filter=A _openwrt1.extracted/squashfs-root/ _openwrt2.extracted/squashfs-root/
Other filters
-diff-filter=[(A|C|D|M|R|T|U|X|B)…[*]]
Select only files that are Added (A
), Copied (C
), Deleted (D
), Modified (M
), Renamed (R
), have their type (i.e. regular file, symlink, submodule, …) changed (T
), are Unmerged (U
), are Unknown (X
), or have had their pairing Broken (B
). Any combination of the filter characters (including none) can be used. When *
(All-or-none) is added to the combination, all paths are selected if there is any file that matches other criteria in the comparison; if there is no file that matches other criteria, nothing is selected.
Also, these upper-case letters can be downcased to exclude. E.g. --diff-filter=ad
excludes added and deleted paths.
Note that not all diffs can feature all types. For instance, diffs from the index to the working tree can never have Added entries (because the set of paths included in the diff is limited by what is in the index). Similarly, copied and renamed entries cannot appear if detection for those types is disabled.
References
- https://cdn.ttgtmedia.com/rms/security/Malware%20Forensics%20Field%20Guide%20for%20Linux%20Systems_Ch3.pdf
- https://www.plesk.com/blog/featured/linux-logs-explained/
Support HackTricks and get benefits!
Do you work in a cybersecurity company? Do you want to see your company advertised in HackTricks? or do you want to have access the latest version of the PEASS or download HackTricks in PDF? Check the SUBSCRIPTION PLANS!
Discover The PEASS Family, our collection of exclusive NFTs
Get the official PEASS & HackTricks swag
Join the 💬 Discord group or the telegram group or follow me on Twitter 🐦@carlospolopm.
Share your hacking tricks submitting PRs to the hacktricks github repo.