gcc_plugin/README.md - platform/external/AFLplusplus - Git at Google

 # GCC-based instrumentation for afl-fuzz

   (See [../README.md](../README.md) for the general instruction manual.)
   (See [../llvm_mode/README.md](../llvm_mode/README.md) for the LLVM-based instrumentation.)

 !!! TODO items are:
 !!!  => inline instrumentation has to work!
 !!!


 ## 1) Introduction

 The code in this directory allows you to instrument programs for AFL using
 true compiler-level instrumentation, instead of the more crude
 assembly-level rewriting approach taken by afl-gcc and afl-clang. This has
 several interesting properties:

   - The compiler can make many optimizations that are hard to pull off when
     manually inserting assembly. As a result, some slow, CPU-bound programs will
     run up to around faster.

     The gains are less pronounced for fast binaries, where the speed is limited
     chiefly by the cost of creating new processes. In such cases, the gain will
     probably stay within 10%.

   - The instrumentation is CPU-independent. At least in principle, you should
     be able to rely on it to fuzz programs on non-x86 architectures (after
     building afl-fuzz with AFL_NOX86=1).

   - Because the feature relies on the internals of GCC, it is gcc-specific
     and will *not* work with LLVM (see ../llvm_mode for an alternative).

 Once this implementation is shown to be sufficiently robust and portable, it
 will probably replace afl-gcc. For now, it can be built separately and
 co-exists with the original code.

 The idea and much of the implementation comes from Laszlo Szekeres.

 ## 2) How to use

 In order to leverage this mechanism, you need to have modern enough GCC
 (>= version 4.5.0) and the plugin headers installed on your system. That
 should be all you need. On Debian machines, these headers can be acquired by
 installing the `gcc-<VERSION>-plugin-dev` packages.

 To build the instrumentation itself, type 'make'. This will generate binaries
 called afl-gcc-fast and afl-g++-fast in the parent directory.
 If the CC/CXX have been overridden, those compilers will be used from
 those wrappers without using AFL_CXX/AFL_CC settings.
 Once this is done, you can instrument third-party code in a way similar to the
 standard operating mode of AFL, e.g.:

   CC=/path/to/afl/afl-gcc-fast ./configure [...options...]
   make

 Be sure to also include CXX set to afl-g++-fast for C++ code.

 The tool honors roughly the same environmental variables as afl-gcc (see
 [env_variables.md](../docs/env_variables.md). This includes AFL_INST_RATIO, AFL_USE_ASAN,
 AFL_HARDEN, and AFL_DONT_OPTIMIZE.

 Note: if you want the GCC plugin to be installed on your system for all
 users, you need to build it before issuing 'make install' in the parent
 directory.

 ## 3) Gotchas, feedback, bugs

 This is an early-stage mechanism, so field reports are welcome. You can send bug
 reports to <hexcoder-@github.com>.

 ## 4) Bonus feature #1: deferred initialization

 AFL tries to optimize performance by executing the targeted binary just once,
 stopping it just before main(), and then cloning this "master" process to get
 a steady supply of targets to fuzz.

 Although this approach eliminates much of the OS-, linker- and libc-level
 costs of executing the program, it does not always help with binaries that
 perform other time-consuming initialization steps - say, parsing a large config
 file before getting to the fuzzed data.

 In such cases, it's beneficial to initialize the forkserver a bit later, once
 most of the initialization work is already done, but before the binary attempts
 to read the fuzzed input and parse it; in some cases, this can offer a 10x+
 performance gain. You can implement delayed initialization in LLVM mode in a
 fairly simple way.

 First, locate a suitable location in the code where the delayed cloning can
 take place. This needs to be done with *extreme* care to avoid breaking the
 binary. In particular, the program will probably malfunction if you select
 a location after:

   - The creation of any vital threads or child processes - since the forkserver
     can't clone them easily.

   - The initialization of timers via setitimer() or equivalent calls.

   - The creation of temporary files, network sockets, offset-sensitive file
     descriptors, and similar shared-state resources - but only provided that
     their state meaningfully influences the behavior of the program later on.

   - Any access to the fuzzed input, including reading the metadata about its
     size.

 With the location selected, add this code in the appropriate spot:

 ```
 #ifdef __AFL_HAVE_MANUAL_CONTROL
   __AFL_INIT();
 #endif
 ```

 You don't need the #ifdef guards, but they will make the program still work as
 usual when compiled with a tool other than afl-gcc-fast/afl-clang-fast.

 Finally, recompile the program with afl-gcc-fast (afl-gcc or afl-clang will
 *not* generate a deferred-initialization binary) - and you should be all set!

 ## 5) Bonus feature #2: persistent mode

 Some libraries provide APIs that are stateless, or whose state can be reset in
 between processing different input files. When such a reset is performed, a
 single long-lived process can be reused to try out multiple test cases,
 eliminating the need for repeated fork() calls and the associated OS overhead.

 The basic structure of the program that does this would be:

 ```
   while (__AFL_LOOP(1000)) {

     /* Read input data. */
     /* Call library code to be fuzzed. */
     /* Reset state. */

   }

   /* Exit normally */
 ```

 The numerical value specified within the loop controls the maximum number
 of iterations before AFL will restart the process from scratch. This minimizes
 the impact of memory leaks and similar glitches; 1000 is a good starting point.

 A more detailed template is shown in ../examples/persistent_demo/.
 Similarly to the previous mode, the feature works only with afl-gcc-fast or
 afl-clang-fast; #ifdef guards can be used to suppress it when using other
 compilers.

 Note that as with the previous mode, the feature is easy to misuse; if you
 do not reset the critical state fully, you may end up with false positives or
 waste a whole lot of CPU power doing nothing useful at all. Be particularly
 wary of memory leaks and the state of file descriptors.

 When running in this mode, the execution paths will inherently vary a bit
 depending on whether the input loop is being entered for the first time or
 executed again. To avoid spurious warnings, the feature implies
 AFL_NO_VAR_CHECK and hides the "variable path" warnings in the UI.
	# GCC-based instrumentation for afl-fuzz

	(See [../README.md](../README.md) for the general instruction manual.)
	(See [../llvm_mode/README.md](../llvm_mode/README.md) for the LLVM-based instrumentation.)

	!!! TODO items are:
	!!! => inline instrumentation has to work!
	!!!


	## 1) Introduction

	The code in this directory allows you to instrument programs for AFL using
	true compiler-level instrumentation, instead of the more crude
	assembly-level rewriting approach taken by afl-gcc and afl-clang. This has
	several interesting properties:

	- The compiler can make many optimizations that are hard to pull off when
	manually inserting assembly. As a result, some slow, CPU-bound programs will
	run up to around faster.

	The gains are less pronounced for fast binaries, where the speed is limited
	chiefly by the cost of creating new processes. In such cases, the gain will
	probably stay within 10%.

	- The instrumentation is CPU-independent. At least in principle, you should
	be able to rely on it to fuzz programs on non-x86 architectures (after
	building afl-fuzz with AFL_NOX86=1).

	- Because the feature relies on the internals of GCC, it is gcc-specific
	and will not work with LLVM (see ../llvm_mode for an alternative).

	Once this implementation is shown to be sufficiently robust and portable, it
	will probably replace afl-gcc. For now, it can be built separately and
	co-exists with the original code.

	The idea and much of the implementation comes from Laszlo Szekeres.

	## 2) How to use

	In order to leverage this mechanism, you need to have modern enough GCC
	(>= version 4.5.0) and the plugin headers installed on your system. That
	should be all you need. On Debian machines, these headers can be acquired by
	installing the `gcc-<VERSION>-plugin-dev` packages.

	To build the instrumentation itself, type 'make'. This will generate binaries
	called afl-gcc-fast and afl-g++-fast in the parent directory.
	If the CC/CXX have been overridden, those compilers will be used from
	those wrappers without using AFL_CXX/AFL_CC settings.
	Once this is done, you can instrument third-party code in a way similar to the
	standard operating mode of AFL, e.g.:

	CC=/path/to/afl/afl-gcc-fast ./configure [...options...]
	make

	Be sure to also include CXX set to afl-g++-fast for C++ code.

	The tool honors roughly the same environmental variables as afl-gcc (see
	[env_variables.md](../docs/env_variables.md). This includes AFL_INST_RATIO, AFL_USE_ASAN,
	AFL_HARDEN, and AFL_DONT_OPTIMIZE.

	Note: if you want the GCC plugin to be installed on your system for all
	users, you need to build it before issuing 'make install' in the parent
	directory.

	## 3) Gotchas, feedback, bugs

	This is an early-stage mechanism, so field reports are welcome. You can send bug
	reports to <hexcoder-@github.com>.

	## 4) Bonus feature #1: deferred initialization

	AFL tries to optimize performance by executing the targeted binary just once,
	stopping it just before main(), and then cloning this "master" process to get
	a steady supply of targets to fuzz.

	Although this approach eliminates much of the OS-, linker- and libc-level
	costs of executing the program, it does not always help with binaries that
	perform other time-consuming initialization steps - say, parsing a large config
	file before getting to the fuzzed data.

	In such cases, it's beneficial to initialize the forkserver a bit later, once
	most of the initialization work is already done, but before the binary attempts
	to read the fuzzed input and parse it; in some cases, this can offer a 10x+
	performance gain. You can implement delayed initialization in LLVM mode in a
	fairly simple way.

	First, locate a suitable location in the code where the delayed cloning can
	take place. This needs to be done with extreme care to avoid breaking the
	binary. In particular, the program will probably malfunction if you select
	a location after:

	- The creation of any vital threads or child processes - since the forkserver
	can't clone them easily.

	- The initialization of timers via setitimer() or equivalent calls.

	- The creation of temporary files, network sockets, offset-sensitive file
	descriptors, and similar shared-state resources - but only provided that
	their state meaningfully influences the behavior of the program later on.

	- Any access to the fuzzed input, including reading the metadata about its
	size.

	With the location selected, add this code in the appropriate spot:

	```
	#ifdef __AFL_HAVE_MANUAL_CONTROL
	__AFL_INIT();
	#endif
	```

	You don't need the #ifdef guards, but they will make the program still work as
	usual when compiled with a tool other than afl-gcc-fast/afl-clang-fast.

	Finally, recompile the program with afl-gcc-fast (afl-gcc or afl-clang will
	not generate a deferred-initialization binary) - and you should be all set!

	## 5) Bonus feature #2: persistent mode

	Some libraries provide APIs that are stateless, or whose state can be reset in
	between processing different input files. When such a reset is performed, a
	single long-lived process can be reused to try out multiple test cases,
	eliminating the need for repeated fork() calls and the associated OS overhead.

	The basic structure of the program that does this would be:

	```
	while (__AFL_LOOP(1000)) {

	/* Read input data. */
	/* Call library code to be fuzzed. */
	/* Reset state. */

	}

	/* Exit normally */
	```

	The numerical value specified within the loop controls the maximum number
	of iterations before AFL will restart the process from scratch. This minimizes
	the impact of memory leaks and similar glitches; 1000 is a good starting point.

	A more detailed template is shown in ../examples/persistent_demo/.
	Similarly to the previous mode, the feature works only with afl-gcc-fast or
	afl-clang-fast; #ifdef guards can be used to suppress it when using other
	compilers.

	Note that as with the previous mode, the feature is easy to misuse; if you
	do not reset the critical state fully, you may end up with false positives or
	waste a whole lot of CPU power doing nothing useful at all. Be particularly
	wary of memory leaks and the state of file descriptors.

	When running in this mode, the execution paths will inherently vary a bit
	depending on whether the input loop is being entered for the first time or
	executed again. To avoid spurious warnings, the feature implies
	AFL_NO_VAR_CHECK and hides the "variable path" warnings in the UI.