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ReStructuredText
454 lines
17 KiB
ReStructuredText
=================
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SanitizerCoverage
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=================
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.. contents::
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:local:
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Introduction
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============
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Sanitizer tools have a very simple code coverage tool built in. It allows to
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get function-level, basic-block-level, and edge-level coverage at a very low
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cost.
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How to build and run
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====================
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SanitizerCoverage can be used with :doc:`AddressSanitizer`,
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:doc:`LeakSanitizer`, :doc:`MemorySanitizer`, and UndefinedBehaviorSanitizer.
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In addition to ``-fsanitize=``, pass one of the following compile-time flags:
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* ``-fsanitize-coverage=func`` for function-level coverage (very fast).
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* ``-fsanitize-coverage=bb`` for basic-block-level coverage (may add up to 30%
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**extra** slowdown).
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* ``-fsanitize-coverage=edge`` for edge-level coverage (up to 40% slowdown).
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You may also specify ``-fsanitize-coverage=indirect-calls`` for
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additional `caller-callee coverage`_.
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At run time, pass ``coverage=1`` in ``ASAN_OPTIONS``, ``LSAN_OPTIONS``,
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``MSAN_OPTIONS`` or ``UBSAN_OPTIONS``, as appropriate.
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To get `Coverage counters`_, add ``-fsanitize-coverage=8bit-counters``
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to one of the above compile-time flags. At runtime, use
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``*SAN_OPTIONS=coverage=1:coverage_counters=1``.
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Example:
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.. code-block:: console
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% cat -n cov.cc
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1 #include <stdio.h>
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2 __attribute__((noinline))
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3 void foo() { printf("foo\n"); }
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4
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5 int main(int argc, char **argv) {
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6 if (argc == 2)
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7 foo();
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8 printf("main\n");
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9 }
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% clang++ -g cov.cc -fsanitize=address -fsanitize-coverage=func
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% ASAN_OPTIONS=coverage=1 ./a.out; ls -l *sancov
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main
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-rw-r----- 1 kcc eng 4 Nov 27 12:21 a.out.22673.sancov
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% ASAN_OPTIONS=coverage=1 ./a.out foo ; ls -l *sancov
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foo
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main
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-rw-r----- 1 kcc eng 4 Nov 27 12:21 a.out.22673.sancov
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-rw-r----- 1 kcc eng 8 Nov 27 12:21 a.out.22679.sancov
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Every time you run an executable instrumented with SanitizerCoverage
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one ``*.sancov`` file is created during the process shutdown.
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If the executable is dynamically linked against instrumented DSOs,
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one ``*.sancov`` file will be also created for every DSO.
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Postprocessing
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==============
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The format of ``*.sancov`` files is very simple: the first 8 bytes is the magic,
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one of ``0xC0BFFFFFFFFFFF64`` and ``0xC0BFFFFFFFFFFF32``. The last byte of the
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magic defines the size of the following offsets. The rest of the data is the
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offsets in the corresponding binary/DSO that were executed during the run.
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A simple script
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``$LLVM/projects/compiler-rt/lib/sanitizer_common/scripts/sancov.py`` is
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provided to dump these offsets.
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.. code-block:: console
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% sancov.py print a.out.22679.sancov a.out.22673.sancov
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sancov.py: read 2 PCs from a.out.22679.sancov
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sancov.py: read 1 PCs from a.out.22673.sancov
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sancov.py: 2 files merged; 2 PCs total
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0x465250
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0x4652a0
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You can then filter the output of ``sancov.py`` through ``addr2line --exe
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ObjectFile`` or ``llvm-symbolizer --obj ObjectFile`` to get file names and line
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numbers:
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.. code-block:: console
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% sancov.py print a.out.22679.sancov a.out.22673.sancov 2> /dev/null | llvm-symbolizer --obj a.out
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cov.cc:3
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cov.cc:5
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Sancov Tool
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===========
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A new experimental ``sancov`` tool is developed to process coverage files.
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The tool is part of LLVM project and is currently supported only on Linux.
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It can handle symbolization tasks autonomously without any extra support
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from the environment. You need to pass .sancov files (named
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``<module_name>.<pid>.sancov`` and paths to all corresponding binary elf files.
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Sancov matches these files using module names and binaries file names.
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.. code-block:: console
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USAGE: sancov [options] <action> (<binary file>|<.sancov file>)...
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Action (required)
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-print - Print coverage addresses
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-covered-functions - Print all covered functions.
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-not-covered-functions - Print all not covered functions.
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-html-report - Print HTML coverage report.
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Options
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-blacklist=<string> - Blacklist file (sanitizer blacklist format).
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-demangle - Print demangled function name.
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-strip_path_prefix=<string> - Strip this prefix from file paths in reports
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Automatic HTML Report Generation
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================================
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If ``*SAN_OPTIONS`` contains ``html_cov_report=1`` option set, then html
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coverage report would be automatically generated alongside the coverage files.
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The ``sancov`` binary should be present in ``PATH`` or
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``sancov_path=<path_to_sancov`` option can be used to specify tool location.
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How good is the coverage?
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=========================
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It is possible to find out which PCs are not covered, by subtracting the covered
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set from the set of all instrumented PCs. The latter can be obtained by listing
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all callsites of ``__sanitizer_cov()`` in the binary. On Linux, ``sancov.py``
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can do this for you. Just supply the path to binary and a list of covered PCs:
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.. code-block:: console
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% sancov.py print a.out.12345.sancov > covered.txt
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sancov.py: read 2 64-bit PCs from a.out.12345.sancov
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sancov.py: 1 file merged; 2 PCs total
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% sancov.py missing a.out < covered.txt
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sancov.py: found 3 instrumented PCs in a.out
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sancov.py: read 2 PCs from stdin
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sancov.py: 1 PCs missing from coverage
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0x4cc61c
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Edge coverage
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=============
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Consider this code:
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.. code-block:: c++
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void foo(int *a) {
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if (a)
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*a = 0;
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}
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It contains 3 basic blocks, let's name them A, B, C:
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.. code-block:: none
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A
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C
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If blocks A, B, and C are all covered we know for certain that the edges A=>B
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and B=>C were executed, but we still don't know if the edge A=>C was executed.
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Such edges of control flow graph are called
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`critical <http://en.wikipedia.org/wiki/Control_flow_graph#Special_edges>`_. The
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edge-level coverage (``-fsanitize-coverage=edge``) simply splits all critical
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edges by introducing new dummy blocks and then instruments those blocks:
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.. code-block:: none
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A
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D B
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C
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Bitset
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======
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When ``coverage_bitset=1`` run-time flag is given, the coverage will also be
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dumped as a bitset (text file with 1 for blocks that have been executed and 0
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for blocks that were not).
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.. code-block:: console
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% clang++ -fsanitize=address -fsanitize-coverage=edge cov.cc
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% ASAN_OPTIONS="coverage=1:coverage_bitset=1" ./a.out
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main
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% ASAN_OPTIONS="coverage=1:coverage_bitset=1" ./a.out 1
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foo
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main
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% head *bitset*
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==> a.out.38214.bitset-sancov <==
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01101
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==> a.out.6128.bitset-sancov <==
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11011%
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For a given executable the length of the bitset is always the same (well,
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unless dlopen/dlclose come into play), so the bitset coverage can be
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easily used for bitset-based corpus distillation.
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Caller-callee coverage
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======================
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(Experimental!)
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Every indirect function call is instrumented with a run-time function call that
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captures caller and callee. At the shutdown time the process dumps a separate
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file called ``caller-callee.PID.sancov`` which contains caller/callee pairs as
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pairs of lines (odd lines are callers, even lines are callees)
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.. code-block:: console
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a.out 0x4a2e0c
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a.out 0x4a6510
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a.out 0x4a2e0c
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a.out 0x4a87f0
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Current limitations:
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* Only the first 14 callees for every caller are recorded, the rest are silently
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ignored.
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* The output format is not very compact since caller and callee may reside in
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different modules and we need to spell out the module names.
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* The routine that dumps the output is not optimized for speed
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* Only Linux x86_64 is tested so far.
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* Sandboxes are not supported.
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Coverage counters
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=================
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This experimental feature is inspired by
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`AFL <http://lcamtuf.coredump.cx/afl/technical_details.txt>`__'s coverage
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instrumentation. With additional compile-time and run-time flags you can get
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more sensitive coverage information. In addition to boolean values assigned to
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every basic block (edge) the instrumentation will collect imprecise counters.
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On exit, every counter will be mapped to a 8-bit bitset representing counter
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ranges: ``1, 2, 3, 4-7, 8-15, 16-31, 32-127, 128+`` and those 8-bit bitsets will
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be dumped to disk.
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.. code-block:: console
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% clang++ -g cov.cc -fsanitize=address -fsanitize-coverage=edge,8bit-counters
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% ASAN_OPTIONS="coverage=1:coverage_counters=1" ./a.out
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% ls -l *counters-sancov
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... a.out.17110.counters-sancov
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% xxd *counters-sancov
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0000000: 0001 0100 01
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These counters may also be used for in-process coverage-guided fuzzers. See
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``include/sanitizer/coverage_interface.h``:
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.. code-block:: c++
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// The coverage instrumentation may optionally provide imprecise counters.
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// Rather than exposing the counter values to the user we instead map
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// the counters to a bitset.
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// Every counter is associated with 8 bits in the bitset.
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// We define 8 value ranges: 1, 2, 3, 4-7, 8-15, 16-31, 32-127, 128+
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// The i-th bit is set to 1 if the counter value is in the i-th range.
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// This counter-based coverage implementation is *not* thread-safe.
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// Returns the number of registered coverage counters.
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uintptr_t __sanitizer_get_number_of_counters();
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// Updates the counter 'bitset', clears the counters and returns the number of
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// new bits in 'bitset'.
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// If 'bitset' is nullptr, only clears the counters.
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// Otherwise 'bitset' should be at least
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// __sanitizer_get_number_of_counters bytes long and 8-aligned.
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uintptr_t
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__sanitizer_update_counter_bitset_and_clear_counters(uint8_t *bitset);
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Tracing basic blocks
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====================
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Experimental support for basic block (or edge) tracing.
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With ``-fsanitize-coverage=trace-bb`` the compiler will insert
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``__sanitizer_cov_trace_basic_block(s32 *id)`` before every function, basic block, or edge
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(depending on the value of ``-fsanitize-coverage=[func,bb,edge]``).
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Example:
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.. code-block:: console
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% clang -g -fsanitize=address -fsanitize-coverage=edge,trace-bb foo.cc
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% ASAN_OPTIONS=coverage=1 ./a.out
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This will produce two files after the process exit:
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`trace-points.PID.sancov` and `trace-events.PID.sancov`.
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The first file will contain a textual description of all the instrumented points in the program
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in the form that you can feed into llvm-symbolizer (e.g. `a.out 0x4dca89`), one per line.
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The second file will contain the actual execution trace as a sequence of 4-byte integers
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-- these integers are the indices into the array of instrumented points (the first file).
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Basic block tracing is currently supported only for single-threaded applications.
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Tracing PCs
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===========
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*Experimental* feature similar to tracing basic blocks, but with a different API.
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With ``-fsanitize-coverage=trace-pc`` the compiler will insert
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``__sanitizer_cov_trace_pc()`` on every edge.
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With an additional ``...=trace-pc,indirect-calls`` flag
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``__sanitizer_cov_trace_pc_indirect(void *callee)`` will be inserted on every indirect call.
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These callbacks are not implemented in the Sanitizer run-time and should be defined
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by the user. So, these flags do not require the other sanitizer to be used.
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This mechanism is used for fuzzing the Linux kernel (https://github.com/google/syzkaller)
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and can be used with `AFL <http://lcamtuf.coredump.cx/afl>`__.
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Tracing data flow
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=================
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An *experimental* feature to support data-flow-guided fuzzing.
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With ``-fsanitize-coverage=trace-cmp`` the compiler will insert extra instrumentation
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around comparison instructions and switch statements.
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The fuzzer will need to define the following functions,
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they will be called by the instrumented code.
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.. code-block:: c++
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// Called before a comparison instruction.
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// SizeAndType is a packed value containing
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// - [63:32] the Size of the operands of comparison in bits
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// - [31:0] the Type of comparison (one of ICMP_EQ, ... ICMP_SLE)
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// Arg1 and Arg2 are arguments of the comparison.
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void __sanitizer_cov_trace_cmp(uint64_t SizeAndType, uint64_t Arg1, uint64_t Arg2);
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// Called before a switch statement.
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// Val is the switch operand.
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// Cases[0] is the number of case constants.
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// Cases[1] is the size of Val in bits.
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// Cases[2:] are the case constants.
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void __sanitizer_cov_trace_switch(uint64_t Val, uint64_t *Cases);
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This interface is a subject to change.
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The current implementation is not thread-safe and thus can be safely used only for single-threaded targets.
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Output directory
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================
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By default, .sancov files are created in the current working directory.
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This can be changed with ``ASAN_OPTIONS=coverage_dir=/path``:
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.. code-block:: console
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% ASAN_OPTIONS="coverage=1:coverage_dir=/tmp/cov" ./a.out foo
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% ls -l /tmp/cov/*sancov
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-rw-r----- 1 kcc eng 4 Nov 27 12:21 a.out.22673.sancov
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-rw-r----- 1 kcc eng 8 Nov 27 12:21 a.out.22679.sancov
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Sudden death
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============
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Normally, coverage data is collected in memory and saved to disk when the
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program exits (with an ``atexit()`` handler), when a SIGSEGV is caught, or when
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``__sanitizer_cov_dump()`` is called.
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If the program ends with a signal that ASan does not handle (or can not handle
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at all, like SIGKILL), coverage data will be lost. This is a big problem on
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Android, where SIGKILL is a normal way of evicting applications from memory.
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With ``ASAN_OPTIONS=coverage=1:coverage_direct=1`` coverage data is written to a
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memory-mapped file as soon as it collected.
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.. code-block:: console
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% ASAN_OPTIONS="coverage=1:coverage_direct=1" ./a.out
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main
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% ls
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7036.sancov.map 7036.sancov.raw a.out
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% sancov.py rawunpack 7036.sancov.raw
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sancov.py: reading map 7036.sancov.map
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sancov.py: unpacking 7036.sancov.raw
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writing 1 PCs to a.out.7036.sancov
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% sancov.py print a.out.7036.sancov
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sancov.py: read 1 PCs from a.out.7036.sancov
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sancov.py: 1 files merged; 1 PCs total
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0x4b2bae
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Note that on 64-bit platforms, this method writes 2x more data than the default,
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because it stores full PC values instead of 32-bit offsets.
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In-process fuzzing
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==================
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Coverage data could be useful for fuzzers and sometimes it is preferable to run
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a fuzzer in the same process as the code being fuzzed (in-process fuzzer).
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You can use ``__sanitizer_get_total_unique_coverage()`` from
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``<sanitizer/coverage_interface.h>`` which returns the number of currently
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covered entities in the program. This will tell the fuzzer if the coverage has
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increased after testing every new input.
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If a fuzzer finds a bug in the ASan run, you will need to save the reproducer
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before exiting the process. Use ``__asan_set_death_callback`` from
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``<sanitizer/asan_interface.h>`` to do that.
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An example of such fuzzer can be found in `the LLVM tree
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<http://llvm.org/viewvc/llvm-project/llvm/trunk/lib/Fuzzer/README.txt?view=markup>`_.
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Performance
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===========
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This coverage implementation is **fast**. With function-level coverage
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(``-fsanitize-coverage=func``) the overhead is not measurable. With
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basic-block-level coverage (``-fsanitize-coverage=bb``) the overhead varies
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between 0 and 25%.
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============== ========= ========= ========= ========= ========= =========
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benchmark cov0 cov1 diff 0-1 cov2 diff 0-2 diff 1-2
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============== ========= ========= ========= ========= ========= =========
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400.perlbench 1296.00 1307.00 1.01 1465.00 1.13 1.12
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401.bzip2 858.00 854.00 1.00 1010.00 1.18 1.18
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403.gcc 613.00 617.00 1.01 683.00 1.11 1.11
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429.mcf 605.00 582.00 0.96 610.00 1.01 1.05
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445.gobmk 896.00 880.00 0.98 1050.00 1.17 1.19
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456.hmmer 892.00 892.00 1.00 918.00 1.03 1.03
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458.sjeng 995.00 1009.00 1.01 1217.00 1.22 1.21
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462.libquantum 497.00 492.00 0.99 534.00 1.07 1.09
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464.h264ref 1461.00 1467.00 1.00 1543.00 1.06 1.05
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471.omnetpp 575.00 590.00 1.03 660.00 1.15 1.12
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473.astar 658.00 652.00 0.99 715.00 1.09 1.10
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483.xalancbmk 471.00 491.00 1.04 582.00 1.24 1.19
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433.milc 616.00 627.00 1.02 627.00 1.02 1.00
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444.namd 602.00 601.00 1.00 654.00 1.09 1.09
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447.dealII 630.00 634.00 1.01 653.00 1.04 1.03
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450.soplex 365.00 368.00 1.01 395.00 1.08 1.07
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453.povray 427.00 434.00 1.02 495.00 1.16 1.14
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470.lbm 357.00 375.00 1.05 370.00 1.04 0.99
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482.sphinx3 927.00 928.00 1.00 1000.00 1.08 1.08
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============== ========= ========= ========= ========= ========= =========
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Why another coverage?
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=====================
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Why did we implement yet another code coverage?
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* We needed something that is lightning fast, plays well with
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AddressSanitizer, and does not significantly increase the binary size.
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* Traditional coverage implementations based in global counters
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`suffer from contention on counters
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<https://groups.google.com/forum/#!topic/llvm-dev/cDqYgnxNEhY>`_.
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