Original AFL code written by Michal Zalewski <lcamtuf@google.com>
Windows fork written and maintained by Ivan Fratric <ifratric@google.com>
Copyright 2016 Google Inc. All Rights Reserved.
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
AFL is a popular fuzzing tool for coverage-guided fuzzing. The tool combines fast target execution with clever heuristics to find new execution paths in the target binary. It has been successfully used to find a large number of vulnerabilities in real products. For more info about the original project, please refer to the original documentation at:
http://lcamtuf.coredump.cx/afl/
Unfortunately, the original AFL does not work on Windows due to very *nix-specific design (e.g. instrumentation, forkserver etc). This project is a fork of AFL that uses different instrumentation approach which works on Windows even for black box binary fuzzing.
Instead of instrumenting the code at compilation time, WinAFL supports the following instrumentation modes:
- Dynamic instrumentation using DynamoRIO (http://dynamorio.org/)
- Hardware tracing using Intel PT
- Static instrumentation via Syzygy
These instrumentation modes are described in more detail in the separate documents.
To improve the process startup time, WinAFL relies heavily on persistent fuzzing mode, that is, executing multiple input samples without restarting the target process. This is accomplished by selecting a target function (that the user wants to fuzz) and instrumenting it so that it runs in a loop.
WinAFL has been successfully used to identify bugs in Windows software, such as
- [Adobe] CVE-2018-4985, CVE-2018-5063, CVE-2018-5064, CVE-2018-5065, CVE-2018-5068, CVE-2018-5069, CVE-2018-5070, CVE-2018-12754, CVE-2018-12755, CVE-2018-12764, CVE-2018-12765, CVE-2018-12766, CVE-2018-12767, CVE-2018-12768, CVE-2018-12848, CVE-2018-12849, CVE-2018-12850, CVE-2018-12840, CVE-2018-15956, CVE-2018-15955, CVE-2018-15954,CVE-2018-15953, CVE-2018-15952, CVE-2018-15938, CVE-2018-15937, CVE-2018-15936, CVE-2018-15935, CVE-2018-15934, CVE-2018-15933, CVE-2018-15932 , CVE-2018-15931, CVE-2018-15930 , CVE-2018-15929, CVE-2018-15928, CVE-2018-15927, CVE-2018-12875, CVE-2018-12874 , CVE-2018-12873, CVE-2018-12872,CVE-2018-12871, CVE-2018-12870, CVE-2018-12869, CVE-2018-12867 , CVE-2018-12866, CVE-2018-12865 , CVE-2018-12864 , CVE-2018-12863, CVE-2018-12862, CVE-2018-12861, CVE-2018-12860, CVE-2018-12859, CVE-2018-12857, CVE-2018-12839 - found by Yoav Alon and Netanel Ben-Simon from Check Point Software Technologies
- [Adobe] CVE-2018-12853, CVE-2018-16024, CVE-2018-16023, CVE-2018-15995 - found by Guy Inbar (guyio)
- [Adobe] CVE-2018-16004, CVE-2018-16005, CVE-2018-16007, CVE-2018-16009, CVE-2018-16010, CVE-2018-16043, CVE-2018-16045, CVE-2018-16046, CVE-2018-19719, CVE-2018-19720, CVE-2019-7045 - found by Sebastian Apelt (@bitshifter123)
- [Microsoft] CVE-2016-7212 - found by Aral Yaman of Noser Engineering AG
- [Microsoft] CVE-2017-0073, CVE-2017-0190, CVE-2017-11816, CVE-2018-8472, CVE-2019-1311 - found by Symeon Paraschoudis
- [Microsoft] CVE-2018-8494 - found by Guy Inbar (guyio)
- [Microsoft] CVE-2018-8464 - found by Yoav Alon and Netanel Ben-Simon from Check Point Research
- [Microsoft] CVE-2019-0576, CVE-2019-0577, CVE-2019-0579, CVE-2019-0538, CVE-2019-0580, CVE-2019-0879, CVE-2019-0889, CVE-2019-0891, CVE-2019-0899, CVE-2019-0902, CVE-2019-1243, CVE-2019-1250, CVE-2020-0687, CVE-2020-0964, CVE-2020-0995, CVE-2020-0879, CVE-2020-0744, CVE-2020-1141, CVE-2020-1145, CVE-2020-1179, CVE-2020-1160 - found by Hardik Shah of McAfee
- [Kollective Kontiki 10.0.1] CVE-2018-11672 - found by Maksim Shudrak from Salesforce
- [Mozilla] CVE-2018-5177 - found by Guy Inbar (guyio)
- [libxml2] CVE-2018-14404 - found by Guy Inbar (guyio)
- [WinRAR] CVE-2018-20250, CVE-2018-20251, CVE-2018-20252, CVE-2018-20253 - found by Nadav Grossman of Check Point Software Technologies
- [Various image viewers] CVE-2019-13083, CVE-2019-13084, CVE-2019-13085, CVE-2019-13242, CVE-2019-13243, CVE-2019-13244, CVE-2019-13245, CVE-2019-13246, CVE-2019-13247, CVE-2019-13248, CVE-2019-13249, CVE-2019-13250, CVE-2019-13251, CVE-2019-13252, CVE-2019-13253, CVE-2019-13254, CVE-2019-13255, CVE-2019-13256, CVE-2019-13257, CVE-2019-13258, CVE-2019-13259, CVE-2019-13260, CVE-2019-13261, CVE-2019-13262 - found by @expend20 and Anton Kukoba of Apriorit
- [Foxit] CVE-2019-13330, CVE-2019-13331, CVE-2020-8844 - found by Natnael Samson (@NattiSamson)
- [Rockwell Automation] CVE-2020-12034, CVE-2020-12038 - found by Sharon Brizinov and Amir Preminger of Claroty
(Let me know if you know of any others and I'll include them in the list)
-
If you are building with DynamoRIO support, download and build DynamoRIO sources or download DynamoRIO Windows binary package from https://github.com/DynamoRIO/dynamorio/releases
-
If you are building with Intel PT support, pull third party dependencies by running
git submodule update --init --recursive
from the WinAFL source directory -
Open Visual Studio Command Prompt (or Visual Studio x64 Win64 Command Prompt if you want a 64-bit build). Note that you need a 64-bit winafl.dll build if you are fuzzing 64-bit targets and vice versa.
-
Go to the directory containing the source
-
Type the following commands. Modify the -DDynamoRIO_DIR flag to point to the location of your DynamoRIO cmake files (either full path or relative to the source directory).
mkdir build32
cd build32
cmake -G"Visual Studio 16 2019" -A Win32 .. -DDynamoRIO_DIR=..\path\to\DynamoRIO\cmake -DINTELPT=1
cmake --build . --config Release
mkdir build64
cd build64
cmake -G"Visual Studio 16 2019" -A x64 .. -DDynamoRIO_DIR=..\path\to\DynamoRIO\cmake -DINTELPT=1
cmake --build . --config Release
The following cmake configuration options are supported:
-
-DDynamoRIO_DIR=..\path\to\DynamoRIO\cmake
- Needed to build the winafl.dll DynamoRIO client -
-DINTELPT=1
- Enable Intel PT mode. For more information see https://github.com/googleprojectzero/winafl/blob/master/readme_pt.md -
-DUSE_COLOR=1
- color support (Windows 10 Anniversary edition or higher) -
-DUSE_DRSYMS=1
- Drsyms support (use symbols when available to obtain -target_offset from -target_method). Enabling this has been known to cause issues on Windows 10 v1809, though there are workarounds, see googleprojectzero#145
The command line for afl-fuzz on Windows is different than on Linux. Instead of:
%s [ afl options ] -- target_cmd_line
it now looks like this:
afl-fuzz [afl options] -- [instrumentation options] -- target_cmd_line
The following afl-fuzz options are supported:
-i dir - input directory with test cases
-o dir - output directory for fuzzer findings
-t msec - timeout for each run
-D dir - directory containing DynamoRIO binaries (drrun, drconfig)
-P - use Intel PT tracing mode
-Y - enable the static instrumentation mode
-f file - location read by the fuzzed program
-m limit - memory limit for the target process
-p - persist DynamoRIO cache across target process restarts
-c cpu - the CPU to run the fuzzed program
-d - quick & dirty mode (skips deterministic steps)
-n - fuzz without instrumentation (dumb mode)
-x dir - optional fuzzer dictionary
-I msec - timeout for process initialization and first run
-T text - text banner to show on the screen
-M \\ -S id - distributed mode
-C - crash exploration mode (the peruvian rabbit thing)
-l path - a path to user-defined DLL for custom test cases processing
Please refer to the original AFL documentation for more info on these flags.
To see the supported instrumentation flags, please refer to the documentation on the specific instrumentation mode you are interested in.
When you select a target function and fuzz an application the following happens:
- Your target runs normally until your target function is reached.
- WinAFL starts recording coverage
- Your target function runs until return
- WinAFL reports coverage, rewrites the input file and patches EIP so that the execution jumps back to step 2
- After your target function runs for the specified number of iterations, the target process is killed and restarted. Note that anything that runs after the target function returns is never reached.
The target function should do these things during its lifetime:
- Open the input file. This needs to happen withing the target function so that you can read a new input file for each iteration as the input file is rewritten between target function runs).
- Parse it (so that you can measure coverage of file parsing)
- Close the input file. This is important because if the input file is not closed WinAFL won't be able to rewrite it.
- Return normally (So that WinAFL can "catch" this return and redirect execution. "returning" via ExitProcess() and such won't work)
The following documents provide information on using different insrumentation modes with WinAFL:
- Dynamic instrumentation using DynamoRIO
- Hardware tracing using Intel PT
- Static instrumentation via Syzygy
Before using WinAFL for the first time, you should read the documentation for the specific instrumentation mode you are interested in. These also contain usage examples.
WinAFL includes the windows port of afl-cmin in winafl-cmin.py. Please run the below command to see the options and usage examples:
D:\Codes\winafl>python winafl-cmin.py -h
[...]
Examples of use:
* Typical use
winafl-cmin.py -D D:\DRIO\bin32 -t 100000 -i in -o minset -covtype edge -coverage_module m.dll -target_module test.exe -target_method fuzz -nargs 2 -- test.exe @@
* Dry-run, keep crashes only with 4 workers with a working directory:
winafl-cmin.py -C --dry-run -w 4 --working-dir D:\dir -D D:\DRIO\bin32 -t 10000 -i in -i C:\fuzz\in -o out_mini -covtype edge -coverage_module m.dll -target_module test.exe -target_method fuzz -nargs 2 -- test.exe @@
* Read from specific file
winafl-cmin.py -D D:\DRIO\bin32 -t 100000 -i in -o minset -f foo.ext -covtype edge -coverage_module m.dll -target_module test.exe -target_method fuzz -nargs 2 -- test.exe @@
* Read from specific file with pattern
winafl-cmin.py -D D:\DRIO\bin32 -t 100000 -i in -o minset -f prefix-@@-foo.ext -covtype edge -coverage_module m.dll -target_module test.exe -target_method fuzz -nargs 2 -- test.exe @@
* Typical use with static instrumentation
winafl-cmin.py -Y -t 100000 -i in -o minset -- test.exe @@
WinAFL supports third party DLLs that can be used to define custom test-cases processing (e.g. to send test cases over network). To enable this option, you need to specify -l <path>
argument.
The DLL should export the following two functions:
dll_init()
dll_run(char *data, long size, int fuzz_iterations)
data - content of test case
size - size of test case
fuzz_iterations - defines a current fuzzing iteration number
We have implemented two sample DLLs for network-based applications fuzzing that you can customize for your own purposes.
WinAFL's custom_net_fuzzer.dll
allows winAFL to perform network-based applications fuzzing that receive and parse network data. There are several options supported by this DLL that should be provided via the environment variable AFL_CUSTOM_DLL_ARGS
:
-a IP address - IP address to send data in
-U - use UDP protocol instead of TCP to send data (default TCP)
-p port - port to send data in
-w msec - delay in milliseconds before actually start fuzzing
For example, if your application receives network packets via UDP protocol at port 7714 you should setup environment variable in the following way: set AFL_CUSTOM_DLL_ARGS=-U -p 7714 -a 127.0.0.1 -w 1000
You still need to find target function and make sure that this function receives data from the network, parses it, and returns normally. Also, you can use In App Persistence mode described above if your application runs the target function in a loop by its own.
Additionally, this mode is considered as experimental since we have experienced some problems with stability and performance. However, we found this option very usefull and managed to find several vulnerabilities in network-based applications (e.g. in Kollective Kontiki listed above).
There is a second DLL custom_winafl_server.dll
that allows winAFL to act as a server and perform fuzzing of client-based applications. All you need is to setup port to listen on for incoming connections from your target application. The environment variable AFL_CUSTOM_DLL_ARGS=<port_id>
should be used for this purpose.
In case of server fuzzing, if the server socket has the SO_REUSEADDR
option set like the following code, then this may case 10055
error after some time fuzzing due to the accumulation of TIME_WAIT
sockets when WinAFL restart the fuzzing process.
setsockopt(s, SOL_SOCKET, SO_REUSEADDR, (char*)&opt, sizeof(int));
To avoid this replace the SO_REUSEADDR
option by SO_LINGER
option in the server source code if availabe.
setsockopt(s, SOL_SOCKET, SO_LINGER, (char*)&opt, sizeof(int));
WinAFL supports loading a custom mutator from a third-party DLL. You need to implement dll_mutate_testcase
in your DLL and provide the DLL path to WinAFL via -l <path>
argument. WinAFL invokes the custom mutator before all the built-in mutations, and the custom mutator can skip all the built-in mutations by returning a non-zero value. The custom mutator should invoke common_fuzz_stuff
to run and make WinAFL aware of each new test case. Below is an example mutator that increments every byte by one:
u8 dll_mutate_testcase(char **argv, u8 *buf, u32 len, u8 (*common_fuzz_stuff)(char**, u8*, u32))
{
u8 bailout = 0;
u8 *newbuf;
u32 i;
// duplicate the input buffer
newbuf = malloc(len);
if (!newbuf) return bailout;
memcpy(newbuf, buf, len);
// increment every byte by one and call common_fuzz_stuff for every new test case
for (i = 0; i < len; i++) {
newbuf[i] += 1;
if (common_fuzz_stuff(argv, newbuf, len)) {
bailout = 1; // skip the rest of the mutation per common_fuzz_stuff
break;
}
}
free(newbuf);
return bailout;
}
Q: WinAFL reports timeouts while processing initial testcases.
A: You should run your target in debug mode first (-debug flag) and only
run WinAFL once you get a message in the debug log that everything
appears to be running normally.
Q: WinAFL runs slower than expected
A: This can commonly happen for several reasons
- Your target function loads a dll for every iteration. This causes
DynamoRIO to translate the same code for every iteration which causes
slowdowns. You will be able to see this in the debug log. To
resolve, select (or write) your target function differently.
- Your target function does not close the input file properly, which
causes WinAFL to kill the process in order to rewrite it. Please refer
to 6) for what a target function should look like.
Q: Can I fuzz DLLs with WinAFL
A: Yes, if you can write a harness that loads a library and runs some
function within. Write your target function according to "How to select
a target function" and for best performance, load the dll outside of
your target function (see the previous question).
Q: Can I fuzz GUI apps with WinAFL
A: Yes, provided that
- There is a target function that behaves as explained in "How to select
a target function"
- The target function is reachable without user interaction
- The target function runs and returns without user interaction
If these conditions are not satisfied, you might need to make custom changes
to WinAFL and/or your target.
Special thanks to Axel "0vercl0k" Souchet of MSRC Vulnerabilities and Mitigations Team for his contributions!