2019-04-06 22:48:14 -07:00
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## Instrumenting URDE with MemorySanitizer
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*For Linux and OpenGL only.*
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To enable checking for uninitialized memory accesses with
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[MemorySanitizer](https://clang.llvm.org/docs/MemorySanitizer.html), pass
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2019-04-06 22:49:21 -07:00
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`-DURDE_MSAN=On` to the CMake command line.
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2019-04-06 22:48:14 -07:00
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URDE and boo will conditionally disable certain features when MemorySanitizer
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is enabled. Audio will not be processed in order to avoid the significant
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CPU expense required for mixing. Disabling audio also avoids the need to
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track allocations made by PulseAudio. Additionally, DBus functionality is
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disabled to avoid tracking its allocations.
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MemorySanitizer ideally requires all code in the process be compiled for
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instrumentation. In practice this is not easy since several system and
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multimedia libraries are dynamically linked by URDE.
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Two key system additions/modifications are required to successfully instrument.
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### libc++
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The C++ runtime has numerous instances of memory allocation. The easiest way
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to ensure these are instrumented is to build libc++ and libc++abi with
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MemorySanitizer enabled. Follow
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[these instructions](https://github.com/google/sanitizers/wiki/MemorySanitizerBootstrappingClang)
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up to the "Build libc++ and libc++abi with MemorySanitizer" step.
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Once built, install them onto your system.
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### Mesa
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*Tested with Radeon SI only. Might work with Intel and Nouveau as well.*
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There is not much to do with URDE in the absence of a graphics acceleration
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library. Unfortunately, Mesa is a beast of a library that does not handle
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MemorySanitizer instrumentation well. As an alternative, boo uses MSan's
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API to contextually disable memory tracking when frequently-used OpenGL
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functions are called.
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Unfortunately, the Radeon SI driver (and probably others) spin up a work
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queue thread that URDE has no visibility of. Memory allocations in this
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thread will generate an unmanageable quantity of reports. Mesa has a convenient
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thread entry implementing a generic work queue for drivers to make use of.
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`#include <dlfcn.h>` and add the following code to the beginning of
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`util_queue_thread_func` in `src/util/u_queue.c`:
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```cpp
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typedef void (*msan_function)(void);
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msan_function func = dlsym(RTLD_NEXT, "__msan_scoped_disable_interceptor_checks");
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if (!func)
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func = dlsym(RTLD_DEFAULT, "__msan_scoped_disable_interceptor_checks");
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if (func)
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func();
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```
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Graphics driver processing should now be totally silent. There will likely
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still be a large quantity of reports during application launch and exit,
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but once the actual URDE mainloop begins processing, reports should be mostly
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limited to the game code itself.
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