$ mkdir in_dir
$ echo 'hello' >in_dir/hello
$ ./afl-fuzz -i in_dir -o out_dir ./jpeg-9a/djpeg
In essence, I created a text file containing just "hello" and asked the fuzzer to keep feeding it to a program that expects a JPEG image (djpeg is a simple utility bundled with the ubiquitous IJG jpeg image library; libjpeg-turbo should also work). Of course, my input file does not resemble a valid picture, so it gets immediately rejected by the utility:
$ ./djpeg '../out_dir/queue/id:000000,orig:hello'
Not a JPEG file: starts with 0x68 0x65
Such a fuzzing run would be normally completely pointless: there is essentially no chance that a "hello" could be ever turned into a valid JPEG by a traditional, format-agnostic fuzzer, since the probability that dozens of random tweaks would align just right is astronomically low.
Luckily, afl-fuzz can leverage lightweight assembly-level instrumentation to its advantage - and within a millisecond or so, it notices that although setting the first byte to 0xff does not change the externally observable output, it triggers a slightly different internal code path in the tested app. Equipped with this information, it decides to use that test case as a seed for future fuzzing rounds:
$ ./djpeg '../out_dir/queue/id:000001,src:000000,op:int8,pos:0,val:-1,+cov'
Not a JPEG file: starts with 0xff 0x65
When later working with that second-generation test case, the fuzzer almost immediately notices that setting the second byte to 0xd8 does something even more interesting:
$ ./djpeg '../out_dir/queue/id:000004,src:000001,op:havoc,rep:16,+cov'
Premature end of JPEG file
JPEG datastream contains no image
At this point, the fuzzer managed to synthesize the valid file header - and actually realized its significance. Using this output as the seed for the next round of fuzzing, it quickly starts getting deeper and deeper into the woods. Within several hundred generations and several hundred million execve() calls, it figures out more and more of the essential control structures that make a valid JPEG file - SOFs, Huffman tables, quantization tables, SOS markers, and so on:
$ ./djpeg '../out_dir/queue/id:000008,src:000004,op:havoc,rep:2,+cov'
Invalid JPEG file structure: two SOI markers
...
$ ./djpeg '../out_dir/queue/id:001005,src:000262+000979,op:splice,rep:2'
Quantization table 0x0e was not defined
...
$ ./djpeg '../out_dir/queue/id:001282,src:001005+001270,op:splice,rep:2,+cov' >.tmp; ls -l .tmp
-rw-r--r-- 1 lcamtuf lcamtuf 7069 Nov 7 09:29 .tmp
The first image, hit after about six hours on an 8-core system, looks very unassuming: it's a blank grayscale image, 3 pixels wide and 784 pixels tall. But the moment it is discovered, the fuzzer starts using the image as a seed - rapidly producing a wide array of more interesting pics for every new execution path:
Of course, synthesizing a complete image out of thin air is an extreme example, and not necessarily a very practical one. But more prosaically, fuzzers are meant to stress-test every feature of the targeted program. With instrumented, generational fuzzing, lesser-known features (e.g., progressive, black-and-white, or arithmetic-coded JPEGs) can be discovered and locked onto without requiring a giant, high-quality corpus of diverse test cases to seed the fuzzer with.
The cool part of the libjpeg demo is that it works without any special preparation: there is nothing special about the "hello" string, the fuzzer knows nothing about image parsing, and is not designed or fine-tuned to work with this particular library. There aren't even any command-line knobs to turn. You can throw afl-fuzz at many other types of parsers with similar results: with bash, it will write valid scripts; with giflib, it will make GIFs; with fileutils, it will create and flag ELF files, Atari 68xxx executables, x86 boot sectors, and UTF-8 with BOM. In almost all cases, the performance impact of instrumentation is minimal, too.
Of course, not all is roses; at its core, afl-fuzz is still a brute-force tool. This makes it simple, fast, and robust, but also means that certain types of atomically executed checks with a large search space may pose an insurmountable obstacle to the fuzzer; a good example of this may be:
if (strcmp(header.magic_password, "h4ck3d by p1gZ")) goto terminate_now;
In practical terms, this means that afl-fuzz won't have as much luck "inventing" PNG files or non-trivial HTML documents from scratch - and will need a starting point better than just "hello". To consistently deal with code constructs similar to the one shown above, a general-purpose fuzzer would need to understand the operation of the targeted binary on a wholly different level. There is some progress on this in the academia, but frameworks that can pull this off across diverse and complex codebases in a quick, easy, and reliable way are probably still years away.
PS. Several folks asked me about symbolic execution and other inspirations for afl-fuzz; I put together some notes in this doc.
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