12 GWP-ASan is a sampled allocator framework that assists in finding use-after-free
13 and heap-buffer-overflow bugs in production environments. It informally is a
14 recursive acronym, "**G**\WP-ASan **W**\ill **P**\rovide **A**\llocation
17 GWP-ASan is based on the classic
18 `Electric Fence Malloc Debugger <https://linux.die.net/man/3/efence>`_, with a
19 key adaptation. Notably, we only choose a very small percentage of allocations
20 to sample, and apply guard pages to these sampled allocations only. The sampling
21 is small enough to allow us to have very low performance overhead.
23 There is a small, tunable memory overhead that is fixed for the lifetime of the
24 process. This is approximately ~40KiB per process using the default settings,
25 depending on the average size of your allocations.
30 Unlike `AddressSanitizer <https://clang.llvm.org/docs/AddressSanitizer.html>`_,
31 GWP-ASan does not induce a significant performance overhead. ASan often requires
32 the use of dedicated canaries to be viable in production environments, and as
33 such is often impractical.
35 GWP-ASan is only capable of finding a subset of the memory issues detected by
36 ASan. Furthermore, GWP-ASan's bug detection capabilities are only probabilistic.
37 As such, we recommend using ASan over GWP-ASan in testing, as well as anywhere
38 else that guaranteed error detection is more valuable than the 2x execution
39 slowdown/binary size bloat. For the majority of production environments, this
40 impact is too high, and GWP-ASan proves extremely useful.
45 **Please note:** The implementation of GWP-ASan is largely in-flux, and these
46 details are subject to change. There are currently other implementations of
47 GWP-ASan, such as the implementation featured in
48 `Chromium <https://cs.chromium.org/chromium/src/components/gwp_asan/>`_. The
49 long-term support goal is to ensure feature-parity where reasonable, and to
50 support compiler-rt as the reference implementation.
55 GWP-ASan is not a replacement for a traditional allocator. Instead, it works by
56 inserting stubs into a supporting allocator to redirect allocations to GWP-ASan
57 when they're chosen to be sampled. These stubs are generally implemented in the
58 implementaion of ``malloc()``, ``free()`` and ``realloc()``. The stubs are
59 extremely small, which makes using GWP-ASan in most allocators fairly trivial.
60 The stubs follow the same general pattern (example ``malloc()`` pseudocode
65 #ifdef INSTALL_GWP_ASAN_STUBS
66 gwp_asan::GuardedPoolAllocator GWPASanAllocator;
69 void* YourAllocator::malloc(..) {
70 #ifdef INSTALL_GWP_ASAN_STUBS
71 if (GWPASanAllocator.shouldSample(..))
72 return GWPASanAllocator.allocate(..);
75 // ... the rest of your allocator code here.
78 Then, all the supporting allocator needs to do is compile with
79 ``-DINSTALL_GWP_ASAN_STUBS`` and link against the GWP-ASan library! For
80 performance reasons, we strongly recommend static linkage of the GWP-ASan
83 Guarded Allocation Pool
84 -----------------------
86 The core of GWP-ASan is the guarded allocation pool. Each sampled allocation is
87 backed using its own *guarded* slot, which may consist of one or more accessible
88 pages. Each guarded slot is surrounded by two *guard* pages, which are mapped as
89 inaccessible. The collection of all guarded slots makes up the *guarded
92 Buffer Underflow/Overflow Detection
93 -----------------------------------
95 We gain buffer-overflow and buffer-underflow detection through these guard
96 pages. When a memory access overruns the allocated buffer, it will touch the
97 inaccessible guard page, causing memory exception. This exception is caught and
98 handled by the internal crash handler. Because each allocation is recorded with
99 metadata about where (and by what thread) it was allocated and deallocated, we
100 can provide information that will help identify the root cause of the bug.
102 Allocations are randomly selected to be either left- or right-aligned to provide
103 equal detection of both underflows and overflows.
105 Use after Free Detection
106 ------------------------
108 The guarded allocation pool also provides use-after-free detection. Whenever a
109 sampled allocation is deallocated, we map its guarded slot as inaccessible. Any
110 memory accesses after deallocation will thus trigger the crash handler, and we
111 can provide useful information about the source of the error.
113 Please note that the use-after-free detection for a sampled allocation is
114 transient. To keep memory overhead fixed while still detecting bugs, deallocated
115 slots are randomly reused to guard future allocations.
120 GWP-ASan already ships by default in the
121 `Scudo Hardened Allocator <https://llvm.org/docs/ScudoHardenedAllocator.html>`_,
122 so building with ``-fsanitize=scudo`` is the quickest and easiest way to try out
128 GWP-ASan's configuration is managed by the supporting allocator. We provide a
129 generic configuration management library that is used by Scudo. It allows
130 several aspects of GWP-ASan to be configured through the following methods:
132 - When the GWP-ASan library is compiled, by setting
133 ``-DGWP_ASAN_DEFAULT_OPTIONS`` to the options string you want set by default.
134 If you're building GWP-ASan as part of a compiler-rt/LLVM build, add it during
135 cmake configure time (e.g. ``cmake ... -DGWP_ASAN_DEFAULT_OPTIONS="..."``). If
136 you're building GWP-ASan outside of compiler-rt, simply ensure that you
137 specify ``-DGWP_ASAN_DEFAULT_OPTIONS="..."`` when building
138 ``optional/options_parser.cpp``).
140 - By defining a ``__gwp_asan_default_options`` function in one's program that
141 returns the options string to be parsed. Said function must have the following
142 prototype: ``extern "C" const char* __gwp_asan_default_options(void)``, with a
143 default visibility. This will override the compile time define;
145 - Depending on allocator support (Scudo has support for this mechanism): Through
146 the environment variable ``GWP_ASAN_OPTIONS``, containing the options string
147 to be parsed. Options defined this way will override any definition made
148 through ``__gwp_asan_default_options``.
150 The options string follows a syntax similar to ASan, where distinct options
151 can be assigned in the same string, separated by colons.
153 For example, using the environment variable:
157 GWP_ASAN_OPTIONS="MaxSimultaneousAllocations=16:SampleRate=5000" ./a.out
159 Or using the function:
163 extern "C" const char *__gwp_asan_default_options() {
164 return "MaxSimultaneousAllocations=16:SampleRate=5000";
167 The following options are available:
169 +----------------------------+---------+--------------------------------------------------------------------------------+
170 | Option | Default | Description |
171 +----------------------------+---------+--------------------------------------------------------------------------------+
172 | Enabled | true | Is GWP-ASan enabled? |
173 +----------------------------+---------+--------------------------------------------------------------------------------+
174 | PerfectlyRightAlign | false | When allocations are right-aligned, should we perfectly align them up to the |
175 | | | page boundary? By default (false), we round up allocation size to the nearest |
176 | | | power of two (2, 4, 8, 16) up to a maximum of 16-byte alignment for |
177 | | | performance reasons. Setting this to true can find single byte |
178 | | | buffer-overflows at the cost of performance, and may be incompatible with |
179 | | | some architectures. |
180 +----------------------------+---------+--------------------------------------------------------------------------------+
181 | MaxSimultaneousAllocations | 16 | Number of simultaneously-guarded allocations available in the pool. |
182 +----------------------------+---------+--------------------------------------------------------------------------------+
183 | SampleRate | 5000 | The probability (1 / SampleRate) that a page is selected for GWP-ASan |
184 | | | sampling. Sample rates up to (2^31 - 1) are supported. |
185 +----------------------------+---------+--------------------------------------------------------------------------------+
186 | InstallSignalHandlers | true | Install GWP-ASan signal handlers for SIGSEGV during dynamic loading. This |
187 | | | allows better error reports by providing stack traces for allocation and |
188 | | | deallocation when reporting a memory error. GWP-ASan's signal handler will |
189 | | | forward the signal to any previously-installed handler, and user programs |
190 | | | that install further signal handlers should make sure they do the same. Note, |
191 | | | if the previously installed SIGSEGV handler is SIG_IGN, we terminate the |
192 | | | process after dumping the error report. |
193 +----------------------------+---------+--------------------------------------------------------------------------------+
198 The below code has a use-after-free bug, where the ``string_view`` is created as
199 a reference to the temporary result of the ``string+`` operator. The
200 use-after-free occurs when ``sv`` is dereferenced on line 8.
204 1: #include <iostream>
206 3: #include <string_view>
209 6: std::string s = "Hellooooooooooooooo ";
210 7: std::string_view sv = s + "World\n";
214 Compiling this code with Scudo+GWP-ASan will probabilistically catch this bug
215 and provide us a detailed error report:
219 $ clang++ -fsanitize=scudo -std=c++17 -g buggy_code.cpp
220 $ for i in `seq 1 200`; do
221 GWP_ASAN_OPTIONS="SampleRate=100" ./a.out > /dev/null;
224 | *** GWP-ASan detected a memory error ***
225 | Use after free at 0x7feccab26000 (0 bytes into a 41-byte allocation at 0x7feccab26000) by thread 31027 here:
227 | #9 ./a.out(_ZStlsIcSt11char_traitsIcEERSt13basic_ostreamIT_T0_ES6_St17basic_string_viewIS3_S4_E+0x45) [0x55585c0afa55]
228 | #10 ./a.out(main+0x9f) [0x55585c0af7cf]
229 | #11 /lib/x86_64-linux-gnu/libc.so.6(__libc_start_main+0xeb) [0x7fecc966952b]
230 | #12 ./a.out(_start+0x2a) [0x55585c0867ba]
232 | 0x7feccab26000 was deallocated by thread 31027 here:
234 | #7 ./a.out(main+0x83) [0x55585c0af7b3]
235 | #8 /lib/x86_64-linux-gnu/libc.so.6(__libc_start_main+0xeb) [0x7fecc966952b]
236 | #9 ./a.out(_start+0x2a) [0x55585c0867ba]
238 | 0x7feccab26000 was allocated by thread 31027 here:
240 | #12 ./a.out(main+0x57) [0x55585c0af787]
241 | #13 /lib/x86_64-linux-gnu/libc.so.6(__libc_start_main+0xeb) [0x7fecc966952b]
242 | #14 ./a.out(_start+0x2a) [0x55585c0867ba]
244 | *** End GWP-ASan report ***
247 To symbolize these stack traces, some care has to be taken. Scudo currently uses
248 GNU's ``backtrace_symbols()`` from ``<execinfo.h>`` to unwind. The unwinder
249 provides human-readable stack traces in ``function+offset`` form, rather than
250 the normal ``binary+offset`` form. In order to use addr2line or similar tools to
251 recover the exact line number, we must convert the ``function+offset`` to
252 ``binary+offset``. A helper script is available at
253 ``compiler-rt/lib/gwp_asan/scripts/symbolize.sh``. Using this script will
254 attempt to symbolize each possible line, falling back to the previous output if
255 anything fails. This results in the following output:
259 $ cat my_gwp_asan_error.txt | symbolize.sh
261 | *** GWP-ASan detected a memory error ***
262 | Use after free at 0x7feccab26000 (0 bytes into a 41-byte allocation at 0x7feccab26000) by thread 31027 here:
264 | #9 /usr/lib/gcc/x86_64-linux-gnu/8.0.1/../../../../include/c++/8.0.1/string_view:547
265 | #10 /tmp/buggy_code.cpp:8
267 | 0x7feccab26000 was deallocated by thread 31027 here:
269 | #7 /tmp/buggy_code.cpp:8
270 | #8 /lib/x86_64-linux-gnu/libc.so.6(__libc_start_main+0xeb) [0x7fecc966952b]
271 | #9 ./a.out(_start+0x2a) [0x55585c0867ba]
273 | 0x7feccab26000 was allocated by thread 31027 here:
275 | #12 /tmp/buggy_code.cpp:7
276 | #13 /lib/x86_64-linux-gnu/libc.so.6(__libc_start_main+0xeb) [0x7fecc966952b]
277 | #14 ./a.out(_start+0x2a) [0x55585c0867ba]
279 | *** End GWP-ASan report ***