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c35cbd3461
This partially fixes the compilation of the LibFuzzer unit test on OSX using AppleClang. llvm-svn: 270926
188 lines
5.5 KiB
C++
188 lines
5.5 KiB
C++
//===- FuzzerAdapter.h - Arbitrary function Fuzzer adapter -------*- C++ -*===//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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//
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// W A R N I N G : E X P E R I M E N T A L.
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//
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// Defines an adapter to fuzz functions with (almost) arbitrary signatures.
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//===----------------------------------------------------------------------===//
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#ifndef LLVM_FUZZER_ADAPTER_H
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#define LLVM_FUZZER_ADAPTER_H
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#include <stddef.h>
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#include <stdint.h>
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#include <algorithm>
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#include <string>
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#include <tuple>
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#include <vector>
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namespace fuzzer {
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/// Unpacks bytes from \p Data according to \p F argument types
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/// and calls the function.
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/// Use to automatically adapt LLVMFuzzerTestOneInput interface to
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/// a specific function.
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/// Supported argument types: primitive types, std::vector<uint8_t>.
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template <typename Fn> bool Adapt(Fn F, const uint8_t *Data, size_t Size);
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// The implementation performs several steps:
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// - function argument types are obtained (Args...)
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// - data is unpacked into std::tuple<Args...> one by one
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// - function is called with std::tuple<Args...> containing arguments.
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namespace impl {
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// Single argument unpacking.
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template <typename T>
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size_t UnpackPrimitive(const uint8_t *Data, size_t Size, T *Value) {
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if (Size < sizeof(T))
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return Size;
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*Value = *reinterpret_cast<const T *>(Data);
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return Size - sizeof(T);
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}
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/// Unpacks into a given Value and returns the Size - num_consumed_bytes.
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/// Return value equal to Size signals inability to unpack the data (typically
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/// because there are not enough bytes).
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template <typename T>
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size_t UnpackSingle(const uint8_t *Data, size_t Size, T *Value);
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#define UNPACK_SINGLE_PRIMITIVE(Type) \
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template <> \
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size_t UnpackSingle<Type>(const uint8_t *Data, size_t Size, Type *Value) { \
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return UnpackPrimitive(Data, Size, Value); \
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}
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UNPACK_SINGLE_PRIMITIVE(char)
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UNPACK_SINGLE_PRIMITIVE(signed char)
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UNPACK_SINGLE_PRIMITIVE(unsigned char)
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UNPACK_SINGLE_PRIMITIVE(short int)
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UNPACK_SINGLE_PRIMITIVE(unsigned short int)
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UNPACK_SINGLE_PRIMITIVE(int)
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UNPACK_SINGLE_PRIMITIVE(unsigned int)
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UNPACK_SINGLE_PRIMITIVE(long int)
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UNPACK_SINGLE_PRIMITIVE(unsigned long int)
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UNPACK_SINGLE_PRIMITIVE(bool)
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UNPACK_SINGLE_PRIMITIVE(wchar_t)
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UNPACK_SINGLE_PRIMITIVE(float)
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UNPACK_SINGLE_PRIMITIVE(double)
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UNPACK_SINGLE_PRIMITIVE(long double)
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#undef UNPACK_SINGLE_PRIMITIVE
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template <>
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size_t UnpackSingle<std::vector<uint8_t>>(const uint8_t *Data, size_t Size,
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std::vector<uint8_t> *Value) {
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if (Size < 1)
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return Size;
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size_t Len = std::min(static_cast<size_t>(*Data), Size - 1);
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std::vector<uint8_t> V(Data + 1, Data + 1 + Len);
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Value->swap(V);
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return Size - Len - 1;
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}
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template <>
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size_t UnpackSingle<std::string>(const uint8_t *Data, size_t Size,
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std::string *Value) {
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if (Size < 1)
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return Size;
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size_t Len = std::min(static_cast<size_t>(*Data), Size - 1);
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std::string S(Data + 1, Data + 1 + Len);
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Value->swap(S);
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return Size - Len - 1;
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}
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// Unpacking into arbitrary tuple.
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// Recursion guard.
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template <int N, typename TupleT>
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typename std::enable_if<N == std::tuple_size<TupleT>::value, bool>::type
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UnpackImpl(const uint8_t *Data, size_t Size, TupleT *Tuple) {
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return true;
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}
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// Unpack tuple elements starting from Nth.
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template <int N, typename TupleT>
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typename std::enable_if<N < std::tuple_size<TupleT>::value, bool>::type
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UnpackImpl(const uint8_t *Data, size_t Size, TupleT *Tuple) {
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size_t NewSize = UnpackSingle(Data, Size, &std::get<N>(*Tuple));
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if (NewSize == Size) {
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return false;
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}
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return UnpackImpl<N + 1, TupleT>(Data + (Size - NewSize), NewSize, Tuple);
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}
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// Unpacks into arbitrary tuple and returns true if successful.
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template <typename... Args>
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bool Unpack(const uint8_t *Data, size_t Size, std::tuple<Args...> *Tuple) {
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return UnpackImpl<0, std::tuple<Args...>>(Data, Size, Tuple);
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}
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// Helper integer sequence templates.
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template <int...> struct Seq {};
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template <int N, int... S> struct GenSeq : GenSeq<N - 1, N - 1, S...> {};
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// GenSeq<N>::type is Seq<0, 1, ..., N-1>
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template <int... S> struct GenSeq<0, S...> { typedef Seq<S...> type; };
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// Function signature introspection.
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template <typename T> struct FnTraits {};
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template <typename ReturnType, typename... Args>
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struct FnTraits<ReturnType (*)(Args...)> {
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enum { Arity = sizeof...(Args) };
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typedef std::tuple<Args...> ArgsTupleT;
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};
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// Calling a function with arguments in a tuple.
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template <typename Fn, int... S>
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void ApplyImpl(Fn F, const typename FnTraits<Fn>::ArgsTupleT &Params,
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Seq<S...>) {
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F(std::get<S>(Params)...);
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}
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template <typename Fn>
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void Apply(Fn F, const typename FnTraits<Fn>::ArgsTupleT &Params) {
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// S is Seq<0, ..., Arity-1>
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auto S = typename GenSeq<FnTraits<Fn>::Arity>::type();
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ApplyImpl(F, Params, S);
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}
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// Unpacking data into arguments tuple of correct type and calling the function.
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template <typename Fn>
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bool UnpackAndApply(Fn F, const uint8_t *Data, size_t Size) {
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typename FnTraits<Fn>::ArgsTupleT Tuple;
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if (!Unpack(Data, Size, &Tuple))
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return false;
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Apply(F, Tuple);
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return true;
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}
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} // namespace impl
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template <typename Fn> bool Adapt(Fn F, const uint8_t *Data, size_t Size) {
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return impl::UnpackAndApply(F, Data, Size);
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}
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} // namespace fuzzer
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#endif
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