ChrisTheCoolHut/Firmware_Slap: Discovering vulnerabilities in firmware through concolic analysis and function clustering.
2019-08-18 16:58:51 Author: github.com(查看原文) 阅读量:209 收藏

Firmware slap combines concolic analysis with function clustering for vulnerability discovery and function similarity in firmware. Firmware slap is built as a series of libraries and exports most information as either pickles or JSON for integration with other tools.

Firmware Slap

Slides from the talk can be found here

Setup

Firmware slap should be run in a virtual environment. It has been tested on Python3.6

You will need rabbitmq and (radare2 or Ghidra)

# Ubuntu
sudo apt install rabbitmq-server
# OSX
brew install rabbitmq

# Radare2
git clone https://github.com/radare/radare2.git
sudo ./radare2/sys/install.sh
# Ghidra
wget https://ghidra-sre.org/ghidra_9.0.4_PUBLIC_20190516.zip
unzip ghidra_9.0.4_PUBLIC_20190516.zip -d ghidra
echo "export PATH=\$PATH:$PWD/ghidra/ghidra_9.0.4/support" >> ~/.bashrc

Ghidra requires JDK 11.

sudo apt install default-jdk
java --version

If you want to use the Elastic search stuff run the Elasticsearch_and_kibana.sh script

Quickstart

Ensure rabbitmq-server is running.

# In a Separate terminal, run this in the top level "Firmware_Slap" directory
celery -A firmware_slap.celery_tasks worker --loglevel=info
# Basic buffer overflow
Discover_And_Dump.py examples/iwconfig -D iwconfig_results
# Command injection
tar -xvf examples/Almond_libs.tar.gz
Vuln_Discover_Celery.py examples/upload.cgi -L Almond_Root/lib/

Usage

# Get the firmware used for examples
wget https://firmware.securifi.com/AL3_64MB/AL3-R024-64MB
binwalk -Mre AL3-R024-64MB

Start a celery work from the project root directory:

# In a separate terminal
celery -A firmware_slap.celery_tasks worker --loglevel=info

In a different terminal window, run a vulnerability discovery job.

$ Vuln_Discover_Celery.py Almond_Root/etc_ro/lighttpd/www/cgi-bin/upload_bootloader.cgi -L Almond_Root/lib/
[+] Getting argument functions
[+] Analyzing 1 functions
  0%|                                                                                                                                                                                                                                   | 0/1 [00:01<?, ?it/s]
{   'Injected_Location': {   'base': '0x7ffefde8',
........................ SNIP ......................
    'type': 'Command Injection'}
Python 3.5.2 (default, Nov 12 2018, 13:43:14) 
Type 'copyright', 'credits' or 'license' for more information
IPython 7.3.0 -- An enhanced Interactive Python. Type '?' for help.

In [1]: 

The returned vulnerability object

The above command will return an object in the result variable. This is a dictionary will all sorts of awesome information about the vulnerability. There are three major keys in the object: The function arguments, The memory, and the injected location.

In [3]: result.keys()                                                                                 
Out[3]: dict_keys(['args', 'file_name', 'type', 'mem', 'Injected_Location'])

args

The args key will detail information about the recovered argument and what the argument values must be to recreate the vulnerability. In the below example, one argument is recovered, and to trigger the command injection that argument must be a char* that contains "`reboot`" to trigger a reboot.

In [1]: result['args']                                                           
Out[1]: 
[{'base': 'a1',
  'type': 'int',
  'value': "0x0 -> b'`reboot`\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x00'"}]

Memory

The memory component of the object keeps track of the required memory values set to trigger the vulnerability. It also offers stack addresses and .text addresses with the offending commands for setting the required memory constraints. The first memory event required is at mtd_write_firmware+0x0 and the second is at mtd_write_firmware+0x38. Assembly is provided to help prettify future display work.

In [2]: result['mem']                                                                   
Out[2]: 
[{'BBL_ADDR': '0x401138',
  'BBL_DESC': {'DESCRIPTION': 'mtd_write_firmware+0x0 in upload_bootloader.cgi (0x401138)',
   'DISASSEMBLY': ['0x401138:\tlui\t$gp, 0x42',
    '0x40113c:\taddiu\t$sp, $sp, -0x228',
    '0x401140:\taddiu\t$gp, $gp, -0x5e90',
    '0x401144:\tlw\t$t9, -0x7f84($gp)',
    '0x401148:\tsw\t$a2, 0x10($sp)',
    '0x40114c:\tlui\t$a2, 0x40',
    '0x401150:\tmove\t$a3, $a1',
    '0x401154:\tsw\t$ra, 0x224($sp)',
    '0x401158:\tsw\t$gp, 0x18($sp)',
    '0x40115c:\tsw\t$a0, 0x14($sp)',
    '0x401160:\taddiu\t$a1, $zero, 0x200',
    '0x401164:\taddiu\t$a0, $sp, 0x20',
    '0x401168:\tjalr\t$t9',
    '0x40116c:\taddiu\t$a2, $a2, 0x196c']},
  'DATA': "b'`reboot`\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x01\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00'",
  'DATA_ADDRS': ['0x0']},
 {'BBL_ADDR': '0x401170',
  'BBL_DESC': {'DESCRIPTION': 'mtd_write_firmware+0x38 in upload_bootloader.cgi (0x401170)',
   'DISASSEMBLY': ['0x401170:\tlw\t$gp, 0x18($sp)',
    '0x401174:\tnop\t',
    '0x401178:\tlw\t$t9, -0x7f68($gp)',
    '0x40117c:\tnop\t',
    '0x401180:\tjalr\t$t9',
    '0x401184:\taddiu\t$a0, $sp, 0x20']},
  'DATA': "b'/bin/mtd_write -o 0 -l 0 write `reboot`'",
  'DATA_ADDRS': ['0x7ffefe07']}]

Command Injection Specific

Since command injections are the easiest to demo, I've created a convenience dictionary key to demonstrate the location of the command injection easily.

In [4]: result['Injected_Location']                                                                      
Out[4]: {'base': '0x7ffefde8', 'type': 'char *', 'value': '/bin/mtd_write -o 0 -l 0 write `reboot`'}

Sample Vulnerability Cluster Script

The vulnerability cluster script will attempt to discover vulnerabilities using the method in the Sample Vulnerability Discovery script and then build k-means clusters of a set of given functions across an extracted firmware to find similar functions to vulnerable ones.

$ Vuln_Cluster_Celery.py -h
usage: Vuln_Cluster_Celery.py [-h] [-L LD_PATH] [-F FUNCTION] [-V VULN_PICKLE]
                              Directory

positional arguments:
  Directory

optional arguments:
  -h, --help            show this help message and exit
  -L LD_PATH, --LD_PATH LD_PATH
                        Path to libraries to load
  -F FUNCTION, --Function FUNCTION
  -V VULN_PICKLE, --Vuln_Pickle VULN_PICKLE

The below command takes -F as a known vulnerable function. -V as a dumped pickle from a previous run to not need to discover new vulnerabilites and -L for the library path. A sample usage:

$ python Vuln_Cluster_Celery.py -F mtd_write_firmware -L Almond_Root/lib/ Almond_Root/etc_ro/lighttpd/www/cgi-bin/
[+] Reading Files
100%|███████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████| 1/1 [00:00<00:00,  2.80it/s]
Getting functions from executables
Starting main
... Snip ...

文章来源: https://github.com/ChrisTheCoolHut/Firmware_Slap
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