/* * Copyright 2016 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #ifndef Fuzz_DEFINED #define Fuzz_DEFINED #include "include/core/SkData.h" #include "include/core/SkImageFilter.h" #include "include/core/SkRegion.h" #include "include/core/SkTypes.h" #include "include/private/base/SkMalloc.h" #include "include/private/base/SkTFitsIn.h" #include "tools/Registry.h" #include #include #include #include class Fuzz { public: explicit Fuzz(const uint8_t* data, size_t size) : fData(data), fSize(size), fNextByte(0) {} Fuzz() = delete; // Make noncopyable Fuzz(Fuzz&) = delete; Fuzz& operator=(Fuzz&) = delete; // Returns the total number of "random" bytes available. size_t size() const { return fSize; } // Returns if there are no bytes remaining for fuzzing. bool exhausted() const { return fSize == fNextByte; } void deplete() { fNextByte = fSize; } size_t remainingSize() const { return fSize - fNextByte; } const uint8_t *remainingData() const { return fData + fNextByte; } // next() loads fuzzed bytes into the variable passed in by pointer. // We use this approach instead of T next() because different compilers // evaluate function parameters in different orders. If fuzz->next() // returned 5 and then 7, foo(fuzz->next(), fuzz->next()) would be // foo(5, 7) when compiled on GCC and foo(7, 5) when compiled on Clang. // By requiring params to be passed in, we avoid the temptation to call // next() in a way that does not consume fuzzed bytes in a single // platform-independent order. template void next(T* t) { this->nextBytes(t, sizeof(T)); } // This is a convenient way to initialize more than one argument at a time. template void next(Arg* first, Args... rest); // nextRange returns values only in [min, max]. template void nextRange(T*, Min, Max); // nextEnum is a wrapper around nextRange for enums. template void nextEnum(T* ptr, T max); // nextN loads n * sizeof(T) bytes into ptr template void nextN(T* ptr, int n); void signalBug() { // Tell the fuzzer that these inputs found a bug. SkDebugf("Signal bug\n"); raise(SIGSEGV); } // Specialized versions for when true random doesn't quite make sense void next(bool* b); void next(SkRegion* region); bool nextBool() { bool b; this->next(&b); return b; } void nextRange(float* f, float min, float max); private: template T nextT(); const uint8_t *fData; size_t fSize; size_t fNextByte; friend void fuzz__MakeEncoderCorpus(Fuzz*); void nextBytes(void* ptr, size_t size); }; template inline void Fuzz::next(Arg* first, Args... rest) { this->next(first); this->next(rest...); } template inline void Fuzz::nextRange(T* value, Min min, Max max) { // UBSAN worries if we make an enum with out of range values, even temporarily. using Raw = typename sk_strip_enum::type; Raw raw; this->next(&raw); if (raw < (Raw)min) { raw = (Raw)min; } if (raw > (Raw)max) { raw = (Raw)max; } *value = (T)raw; } template inline void Fuzz::nextEnum(T* value, T max) { // This works around the fact that UBSAN will assert if we put an invalid // value into an enum. We might see issues with enums being represented // on Windows differently than Linux, but that's not a thing we can fix here. using U = typename std::underlying_type::type; U v; this->next(&v); if (v < (U)0) { *value = (T)0; return;} if (v > (U)max) { *value = (T)max; return;} *value = (T)v; } template inline void Fuzz::nextN(T* ptr, int n) { for (int i = 0; i < n; i++) { this->next(ptr+i); } } struct Fuzzable { const char* name; void (*fn)(Fuzz*); }; // Not static so that we can link these into oss-fuzz harnesses if we like. #define DEF_FUZZ(name, f) \ void fuzz_##name(Fuzz*); \ sk_tools::Registry register_##name({#name, fuzz_##name}); \ void fuzz_##name(Fuzz* f) #endif // Fuzz_DEFINED