llvm-project/compiler-rt/lib/fuzzer/FuzzerMutate.cpp
Aaron Green 6708186c91 [crt][fuzzer] Fix up various numeric conversions
Attempting to build a standalone libFuzzer in Fuchsia's default toolchain for the purpose of cross-compiling the unit tests  revealed a number of not-quite-proper type conversions. Fuchsia's toolchain include `-std=c++17` and `-Werror`, among others, leading to many errors like `-Wshorten-64-to-32`, `-Wimplicit-float-conversion`, etc.

Most of these have been addressed by simply making the conversion explicit with a `static_cast`. These typically fell into one of two categories: 1) conversions between types where high precision isn't critical, e.g. the "energy" calculations for `InputInfo`, and 2) conversions where the values will never reach the bits being truncated, e.g. `DftTimeInSeconds` is not going to exceed 136 years.

The major exception to this is the number of features: there are several places that treat features as `size_t`, and others as `uint32_t`. This change makes the decision to cap the features at 32 bits. The maximum value of a feature as produced by `TracePC::CollectFeatures` is roughly:
  (NumPCsInPCTables + ValueBitMap::kMapSizeInBits + ExtraCountersBegin() - ExtraCountersEnd() + log2(SIZE_MAX)) * 8

It's conceivable for extremely large targets and/or extra counters that this limit could be reached. This shouldn't break fuzzing, but it will cause certain features to collide and lower the fuzzers overall precision. To address this, this change adds a warning to TracePC::PrintModuleInfo about excessive feature size if it is detected, and recommends refactoring the fuzzer into several smaller ones.

Reviewed By: morehouse

Differential Revision: https://reviews.llvm.org/D97992
2021-03-11 16:01:28 -08:00

583 lines
21 KiB
C++

//===- FuzzerMutate.cpp - Mutate a test input -----------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
// Mutate a test input.
//===----------------------------------------------------------------------===//
#include "FuzzerDefs.h"
#include "FuzzerExtFunctions.h"
#include "FuzzerIO.h"
#include "FuzzerMutate.h"
#include "FuzzerOptions.h"
#include "FuzzerTracePC.h"
namespace fuzzer {
const size_t Dictionary::kMaxDictSize;
static const size_t kMaxMutationsToPrint = 10;
static void PrintASCII(const Word &W, const char *PrintAfter) {
PrintASCII(W.data(), W.size(), PrintAfter);
}
MutationDispatcher::MutationDispatcher(Random &Rand,
const FuzzingOptions &Options)
: Rand(Rand), Options(Options) {
DefaultMutators.insert(
DefaultMutators.begin(),
{
{&MutationDispatcher::Mutate_EraseBytes, "EraseBytes"},
{&MutationDispatcher::Mutate_InsertByte, "InsertByte"},
{&MutationDispatcher::Mutate_InsertRepeatedBytes,
"InsertRepeatedBytes"},
{&MutationDispatcher::Mutate_ChangeByte, "ChangeByte"},
{&MutationDispatcher::Mutate_ChangeBit, "ChangeBit"},
{&MutationDispatcher::Mutate_ShuffleBytes, "ShuffleBytes"},
{&MutationDispatcher::Mutate_ChangeASCIIInteger, "ChangeASCIIInt"},
{&MutationDispatcher::Mutate_ChangeBinaryInteger, "ChangeBinInt"},
{&MutationDispatcher::Mutate_CopyPart, "CopyPart"},
{&MutationDispatcher::Mutate_CrossOver, "CrossOver"},
{&MutationDispatcher::Mutate_AddWordFromManualDictionary,
"ManualDict"},
{&MutationDispatcher::Mutate_AddWordFromPersistentAutoDictionary,
"PersAutoDict"},
});
if(Options.UseCmp)
DefaultMutators.push_back(
{&MutationDispatcher::Mutate_AddWordFromTORC, "CMP"});
if (EF->LLVMFuzzerCustomMutator)
Mutators.push_back({&MutationDispatcher::Mutate_Custom, "Custom"});
else
Mutators = DefaultMutators;
if (EF->LLVMFuzzerCustomCrossOver)
Mutators.push_back(
{&MutationDispatcher::Mutate_CustomCrossOver, "CustomCrossOver"});
}
static char RandCh(Random &Rand) {
if (Rand.RandBool())
return static_cast<char>(Rand(256));
const char Special[] = "!*'();:@&=+$,/?%#[]012Az-`~.\xff\x00";
return Special[Rand(sizeof(Special) - 1)];
}
size_t MutationDispatcher::Mutate_Custom(uint8_t *Data, size_t Size,
size_t MaxSize) {
return EF->LLVMFuzzerCustomMutator(Data, Size, MaxSize,
Rand.Rand<unsigned int>());
}
size_t MutationDispatcher::Mutate_CustomCrossOver(uint8_t *Data, size_t Size,
size_t MaxSize) {
if (Size == 0)
return 0;
if (!CrossOverWith) return 0;
const Unit &Other = *CrossOverWith;
if (Other.empty())
return 0;
CustomCrossOverInPlaceHere.resize(MaxSize);
auto &U = CustomCrossOverInPlaceHere;
size_t NewSize = EF->LLVMFuzzerCustomCrossOver(
Data, Size, Other.data(), Other.size(), U.data(), U.size(),
Rand.Rand<unsigned int>());
if (!NewSize)
return 0;
assert(NewSize <= MaxSize && "CustomCrossOver returned overisized unit");
memcpy(Data, U.data(), NewSize);
return NewSize;
}
size_t MutationDispatcher::Mutate_ShuffleBytes(uint8_t *Data, size_t Size,
size_t MaxSize) {
if (Size > MaxSize || Size == 0) return 0;
size_t ShuffleAmount =
Rand(std::min(Size, (size_t)8)) + 1; // [1,8] and <= Size.
size_t ShuffleStart = Rand(Size - ShuffleAmount);
assert(ShuffleStart + ShuffleAmount <= Size);
std::shuffle(Data + ShuffleStart, Data + ShuffleStart + ShuffleAmount, Rand);
return Size;
}
size_t MutationDispatcher::Mutate_EraseBytes(uint8_t *Data, size_t Size,
size_t MaxSize) {
if (Size <= 1) return 0;
size_t N = Rand(Size / 2) + 1;
assert(N < Size);
size_t Idx = Rand(Size - N + 1);
// Erase Data[Idx:Idx+N].
memmove(Data + Idx, Data + Idx + N, Size - Idx - N);
// Printf("Erase: %zd %zd => %zd; Idx %zd\n", N, Size, Size - N, Idx);
return Size - N;
}
size_t MutationDispatcher::Mutate_InsertByte(uint8_t *Data, size_t Size,
size_t MaxSize) {
if (Size >= MaxSize) return 0;
size_t Idx = Rand(Size + 1);
// Insert new value at Data[Idx].
memmove(Data + Idx + 1, Data + Idx, Size - Idx);
Data[Idx] = RandCh(Rand);
return Size + 1;
}
size_t MutationDispatcher::Mutate_InsertRepeatedBytes(uint8_t *Data,
size_t Size,
size_t MaxSize) {
const size_t kMinBytesToInsert = 3;
if (Size + kMinBytesToInsert >= MaxSize) return 0;
size_t MaxBytesToInsert = std::min(MaxSize - Size, (size_t)128);
size_t N = Rand(MaxBytesToInsert - kMinBytesToInsert + 1) + kMinBytesToInsert;
assert(Size + N <= MaxSize && N);
size_t Idx = Rand(Size + 1);
// Insert new values at Data[Idx].
memmove(Data + Idx + N, Data + Idx, Size - Idx);
// Give preference to 0x00 and 0xff.
uint8_t Byte = static_cast<uint8_t>(
Rand.RandBool() ? Rand(256) : (Rand.RandBool() ? 0 : 255));
for (size_t i = 0; i < N; i++)
Data[Idx + i] = Byte;
return Size + N;
}
size_t MutationDispatcher::Mutate_ChangeByte(uint8_t *Data, size_t Size,
size_t MaxSize) {
if (Size > MaxSize) return 0;
size_t Idx = Rand(Size);
Data[Idx] = RandCh(Rand);
return Size;
}
size_t MutationDispatcher::Mutate_ChangeBit(uint8_t *Data, size_t Size,
size_t MaxSize) {
if (Size > MaxSize) return 0;
size_t Idx = Rand(Size);
Data[Idx] ^= 1 << Rand(8);
return Size;
}
size_t MutationDispatcher::Mutate_AddWordFromManualDictionary(uint8_t *Data,
size_t Size,
size_t MaxSize) {
return AddWordFromDictionary(ManualDictionary, Data, Size, MaxSize);
}
size_t MutationDispatcher::ApplyDictionaryEntry(uint8_t *Data, size_t Size,
size_t MaxSize,
DictionaryEntry &DE) {
const Word &W = DE.GetW();
bool UsePositionHint = DE.HasPositionHint() &&
DE.GetPositionHint() + W.size() < Size &&
Rand.RandBool();
if (Rand.RandBool()) { // Insert W.
if (Size + W.size() > MaxSize) return 0;
size_t Idx = UsePositionHint ? DE.GetPositionHint() : Rand(Size + 1);
memmove(Data + Idx + W.size(), Data + Idx, Size - Idx);
memcpy(Data + Idx, W.data(), W.size());
Size += W.size();
} else { // Overwrite some bytes with W.
if (W.size() > Size) return 0;
size_t Idx = UsePositionHint ? DE.GetPositionHint() : Rand(Size - W.size());
memcpy(Data + Idx, W.data(), W.size());
}
return Size;
}
// Somewhere in the past we have observed a comparison instructions
// with arguments Arg1 Arg2. This function tries to guess a dictionary
// entry that will satisfy that comparison.
// It first tries to find one of the arguments (possibly swapped) in the
// input and if it succeeds it creates a DE with a position hint.
// Otherwise it creates a DE with one of the arguments w/o a position hint.
DictionaryEntry MutationDispatcher::MakeDictionaryEntryFromCMP(
const void *Arg1, const void *Arg2,
const void *Arg1Mutation, const void *Arg2Mutation,
size_t ArgSize, const uint8_t *Data,
size_t Size) {
bool HandleFirst = Rand.RandBool();
const void *ExistingBytes, *DesiredBytes;
Word W;
const uint8_t *End = Data + Size;
for (int Arg = 0; Arg < 2; Arg++) {
ExistingBytes = HandleFirst ? Arg1 : Arg2;
DesiredBytes = HandleFirst ? Arg2Mutation : Arg1Mutation;
HandleFirst = !HandleFirst;
W.Set(reinterpret_cast<const uint8_t*>(DesiredBytes), ArgSize);
const size_t kMaxNumPositions = 8;
size_t Positions[kMaxNumPositions];
size_t NumPositions = 0;
for (const uint8_t *Cur = Data;
Cur < End && NumPositions < kMaxNumPositions; Cur++) {
Cur =
(const uint8_t *)SearchMemory(Cur, End - Cur, ExistingBytes, ArgSize);
if (!Cur) break;
Positions[NumPositions++] = Cur - Data;
}
if (!NumPositions) continue;
return DictionaryEntry(W, Positions[Rand(NumPositions)]);
}
DictionaryEntry DE(W);
return DE;
}
template <class T>
DictionaryEntry MutationDispatcher::MakeDictionaryEntryFromCMP(
T Arg1, T Arg2, const uint8_t *Data, size_t Size) {
if (Rand.RandBool()) Arg1 = Bswap(Arg1);
if (Rand.RandBool()) Arg2 = Bswap(Arg2);
T Arg1Mutation = static_cast<T>(Arg1 + Rand(-1, 1));
T Arg2Mutation = static_cast<T>(Arg2 + Rand(-1, 1));
return MakeDictionaryEntryFromCMP(&Arg1, &Arg2, &Arg1Mutation, &Arg2Mutation,
sizeof(Arg1), Data, Size);
}
DictionaryEntry MutationDispatcher::MakeDictionaryEntryFromCMP(
const Word &Arg1, const Word &Arg2, const uint8_t *Data, size_t Size) {
return MakeDictionaryEntryFromCMP(Arg1.data(), Arg2.data(), Arg1.data(),
Arg2.data(), Arg1.size(), Data, Size);
}
size_t MutationDispatcher::Mutate_AddWordFromTORC(
uint8_t *Data, size_t Size, size_t MaxSize) {
Word W;
DictionaryEntry DE;
switch (Rand(4)) {
case 0: {
auto X = TPC.TORC8.Get(Rand.Rand<size_t>());
DE = MakeDictionaryEntryFromCMP(X.A, X.B, Data, Size);
} break;
case 1: {
auto X = TPC.TORC4.Get(Rand.Rand<size_t>());
if ((X.A >> 16) == 0 && (X.B >> 16) == 0 && Rand.RandBool())
DE = MakeDictionaryEntryFromCMP((uint16_t)X.A, (uint16_t)X.B, Data, Size);
else
DE = MakeDictionaryEntryFromCMP(X.A, X.B, Data, Size);
} break;
case 2: {
auto X = TPC.TORCW.Get(Rand.Rand<size_t>());
DE = MakeDictionaryEntryFromCMP(X.A, X.B, Data, Size);
} break;
case 3: if (Options.UseMemmem) {
auto X = TPC.MMT.Get(Rand.Rand<size_t>());
DE = DictionaryEntry(X);
} break;
default:
assert(0);
}
if (!DE.GetW().size()) return 0;
Size = ApplyDictionaryEntry(Data, Size, MaxSize, DE);
if (!Size) return 0;
DictionaryEntry &DERef =
CmpDictionaryEntriesDeque[CmpDictionaryEntriesDequeIdx++ %
kCmpDictionaryEntriesDequeSize];
DERef = DE;
CurrentDictionaryEntrySequence.push_back(&DERef);
return Size;
}
size_t MutationDispatcher::Mutate_AddWordFromPersistentAutoDictionary(
uint8_t *Data, size_t Size, size_t MaxSize) {
return AddWordFromDictionary(PersistentAutoDictionary, Data, Size, MaxSize);
}
size_t MutationDispatcher::AddWordFromDictionary(Dictionary &D, uint8_t *Data,
size_t Size, size_t MaxSize) {
if (Size > MaxSize) return 0;
if (D.empty()) return 0;
DictionaryEntry &DE = D[Rand(D.size())];
Size = ApplyDictionaryEntry(Data, Size, MaxSize, DE);
if (!Size) return 0;
DE.IncUseCount();
CurrentDictionaryEntrySequence.push_back(&DE);
return Size;
}
// Overwrites part of To[0,ToSize) with a part of From[0,FromSize).
// Returns ToSize.
size_t MutationDispatcher::CopyPartOf(const uint8_t *From, size_t FromSize,
uint8_t *To, size_t ToSize) {
// Copy From[FromBeg, FromBeg + CopySize) into To[ToBeg, ToBeg + CopySize).
size_t ToBeg = Rand(ToSize);
size_t CopySize = Rand(ToSize - ToBeg) + 1;
assert(ToBeg + CopySize <= ToSize);
CopySize = std::min(CopySize, FromSize);
size_t FromBeg = Rand(FromSize - CopySize + 1);
assert(FromBeg + CopySize <= FromSize);
memmove(To + ToBeg, From + FromBeg, CopySize);
return ToSize;
}
// Inserts part of From[0,ToSize) into To.
// Returns new size of To on success or 0 on failure.
size_t MutationDispatcher::InsertPartOf(const uint8_t *From, size_t FromSize,
uint8_t *To, size_t ToSize,
size_t MaxToSize) {
if (ToSize >= MaxToSize) return 0;
size_t AvailableSpace = MaxToSize - ToSize;
size_t MaxCopySize = std::min(AvailableSpace, FromSize);
size_t CopySize = Rand(MaxCopySize) + 1;
size_t FromBeg = Rand(FromSize - CopySize + 1);
assert(FromBeg + CopySize <= FromSize);
size_t ToInsertPos = Rand(ToSize + 1);
assert(ToInsertPos + CopySize <= MaxToSize);
size_t TailSize = ToSize - ToInsertPos;
if (To == From) {
MutateInPlaceHere.resize(MaxToSize);
memcpy(MutateInPlaceHere.data(), From + FromBeg, CopySize);
memmove(To + ToInsertPos + CopySize, To + ToInsertPos, TailSize);
memmove(To + ToInsertPos, MutateInPlaceHere.data(), CopySize);
} else {
memmove(To + ToInsertPos + CopySize, To + ToInsertPos, TailSize);
memmove(To + ToInsertPos, From + FromBeg, CopySize);
}
return ToSize + CopySize;
}
size_t MutationDispatcher::Mutate_CopyPart(uint8_t *Data, size_t Size,
size_t MaxSize) {
if (Size > MaxSize || Size == 0) return 0;
// If Size == MaxSize, `InsertPartOf(...)` will
// fail so there's no point using it in this case.
if (Size == MaxSize || Rand.RandBool())
return CopyPartOf(Data, Size, Data, Size);
else
return InsertPartOf(Data, Size, Data, Size, MaxSize);
}
size_t MutationDispatcher::Mutate_ChangeASCIIInteger(uint8_t *Data, size_t Size,
size_t MaxSize) {
if (Size > MaxSize) return 0;
size_t B = Rand(Size);
while (B < Size && !isdigit(Data[B])) B++;
if (B == Size) return 0;
size_t E = B;
while (E < Size && isdigit(Data[E])) E++;
assert(B < E);
// now we have digits in [B, E).
// strtol and friends don't accept non-zero-teminated data, parse it manually.
uint64_t Val = Data[B] - '0';
for (size_t i = B + 1; i < E; i++)
Val = Val * 10 + Data[i] - '0';
// Mutate the integer value.
switch(Rand(5)) {
case 0: Val++; break;
case 1: Val--; break;
case 2: Val /= 2; break;
case 3: Val *= 2; break;
case 4: Val = Rand(Val * Val); break;
default: assert(0);
}
// Just replace the bytes with the new ones, don't bother moving bytes.
for (size_t i = B; i < E; i++) {
size_t Idx = E + B - i - 1;
assert(Idx >= B && Idx < E);
Data[Idx] = (Val % 10) + '0';
Val /= 10;
}
return Size;
}
template<class T>
size_t ChangeBinaryInteger(uint8_t *Data, size_t Size, Random &Rand) {
if (Size < sizeof(T)) return 0;
size_t Off = Rand(Size - sizeof(T) + 1);
assert(Off + sizeof(T) <= Size);
T Val;
if (Off < 64 && !Rand(4)) {
Val = static_cast<T>(Size);
if (Rand.RandBool())
Val = Bswap(Val);
} else {
memcpy(&Val, Data + Off, sizeof(Val));
T Add = static_cast<T>(Rand(21));
Add -= 10;
if (Rand.RandBool())
Val = Bswap(T(Bswap(Val) + Add)); // Add assuming different endiannes.
else
Val = Val + Add; // Add assuming current endiannes.
if (Add == 0 || Rand.RandBool()) // Maybe negate.
Val = -Val;
}
memcpy(Data + Off, &Val, sizeof(Val));
return Size;
}
size_t MutationDispatcher::Mutate_ChangeBinaryInteger(uint8_t *Data,
size_t Size,
size_t MaxSize) {
if (Size > MaxSize) return 0;
switch (Rand(4)) {
case 3: return ChangeBinaryInteger<uint64_t>(Data, Size, Rand);
case 2: return ChangeBinaryInteger<uint32_t>(Data, Size, Rand);
case 1: return ChangeBinaryInteger<uint16_t>(Data, Size, Rand);
case 0: return ChangeBinaryInteger<uint8_t>(Data, Size, Rand);
default: assert(0);
}
return 0;
}
size_t MutationDispatcher::Mutate_CrossOver(uint8_t *Data, size_t Size,
size_t MaxSize) {
if (Size > MaxSize) return 0;
if (Size == 0) return 0;
if (!CrossOverWith) return 0;
const Unit &O = *CrossOverWith;
if (O.empty()) return 0;
size_t NewSize = 0;
switch(Rand(3)) {
case 0:
MutateInPlaceHere.resize(MaxSize);
NewSize = CrossOver(Data, Size, O.data(), O.size(),
MutateInPlaceHere.data(), MaxSize);
memcpy(Data, MutateInPlaceHere.data(), NewSize);
break;
case 1:
NewSize = InsertPartOf(O.data(), O.size(), Data, Size, MaxSize);
if (!NewSize)
NewSize = CopyPartOf(O.data(), O.size(), Data, Size);
break;
case 2:
NewSize = CopyPartOf(O.data(), O.size(), Data, Size);
break;
default: assert(0);
}
assert(NewSize > 0 && "CrossOver returned empty unit");
assert(NewSize <= MaxSize && "CrossOver returned overisized unit");
return NewSize;
}
void MutationDispatcher::StartMutationSequence() {
CurrentMutatorSequence.clear();
CurrentDictionaryEntrySequence.clear();
}
// Copy successful dictionary entries to PersistentAutoDictionary.
void MutationDispatcher::RecordSuccessfulMutationSequence() {
for (auto DE : CurrentDictionaryEntrySequence) {
// PersistentAutoDictionary.AddWithSuccessCountOne(DE);
DE->IncSuccessCount();
assert(DE->GetW().size());
// Linear search is fine here as this happens seldom.
if (!PersistentAutoDictionary.ContainsWord(DE->GetW()))
PersistentAutoDictionary.push_back({DE->GetW(), 1});
}
}
void MutationDispatcher::PrintRecommendedDictionary() {
Vector<DictionaryEntry> V;
for (auto &DE : PersistentAutoDictionary)
if (!ManualDictionary.ContainsWord(DE.GetW()))
V.push_back(DE);
if (V.empty()) return;
Printf("###### Recommended dictionary. ######\n");
for (auto &DE: V) {
assert(DE.GetW().size());
Printf("\"");
PrintASCII(DE.GetW(), "\"");
Printf(" # Uses: %zd\n", DE.GetUseCount());
}
Printf("###### End of recommended dictionary. ######\n");
}
void MutationDispatcher::PrintMutationSequence(bool Verbose) {
Printf("MS: %zd ", CurrentMutatorSequence.size());
size_t EntriesToPrint =
Verbose ? CurrentMutatorSequence.size()
: std::min(kMaxMutationsToPrint, CurrentMutatorSequence.size());
for (size_t i = 0; i < EntriesToPrint; i++)
Printf("%s-", CurrentMutatorSequence[i].Name);
if (!CurrentDictionaryEntrySequence.empty()) {
Printf(" DE: ");
EntriesToPrint = Verbose ? CurrentDictionaryEntrySequence.size()
: std::min(kMaxMutationsToPrint,
CurrentDictionaryEntrySequence.size());
for (size_t i = 0; i < EntriesToPrint; i++) {
Printf("\"");
PrintASCII(CurrentDictionaryEntrySequence[i]->GetW(), "\"-");
}
}
}
std::string MutationDispatcher::MutationSequence() {
std::string MS;
for (auto M : CurrentMutatorSequence) {
MS += M.Name;
MS += "-";
}
return MS;
}
size_t MutationDispatcher::Mutate(uint8_t *Data, size_t Size, size_t MaxSize) {
return MutateImpl(Data, Size, MaxSize, Mutators);
}
size_t MutationDispatcher::DefaultMutate(uint8_t *Data, size_t Size,
size_t MaxSize) {
return MutateImpl(Data, Size, MaxSize, DefaultMutators);
}
// Mutates Data in place, returns new size.
size_t MutationDispatcher::MutateImpl(uint8_t *Data, size_t Size,
size_t MaxSize,
Vector<Mutator> &Mutators) {
assert(MaxSize > 0);
// Some mutations may fail (e.g. can't insert more bytes if Size == MaxSize),
// in which case they will return 0.
// Try several times before returning un-mutated data.
for (int Iter = 0; Iter < 100; Iter++) {
auto M = Mutators[Rand(Mutators.size())];
size_t NewSize = (this->*(M.Fn))(Data, Size, MaxSize);
if (NewSize && NewSize <= MaxSize) {
if (Options.OnlyASCII)
ToASCII(Data, NewSize);
CurrentMutatorSequence.push_back(M);
return NewSize;
}
}
*Data = ' ';
return 1; // Fallback, should not happen frequently.
}
// Mask represents the set of Data bytes that are worth mutating.
size_t MutationDispatcher::MutateWithMask(uint8_t *Data, size_t Size,
size_t MaxSize,
const Vector<uint8_t> &Mask) {
size_t MaskedSize = std::min(Size, Mask.size());
// * Copy the worthy bytes into a temporary array T
// * Mutate T
// * Copy T back.
// This is totally unoptimized.
auto &T = MutateWithMaskTemp;
if (T.size() < Size)
T.resize(Size);
size_t OneBits = 0;
for (size_t I = 0; I < MaskedSize; I++)
if (Mask[I])
T[OneBits++] = Data[I];
if (!OneBits) return 0;
assert(!T.empty());
size_t NewSize = Mutate(T.data(), OneBits, OneBits);
assert(NewSize <= OneBits);
(void)NewSize;
// Even if NewSize < OneBits we still use all OneBits bytes.
for (size_t I = 0, J = 0; I < MaskedSize; I++)
if (Mask[I])
Data[I] = T[J++];
return Size;
}
void MutationDispatcher::AddWordToManualDictionary(const Word &W) {
ManualDictionary.push_back(
{W, std::numeric_limits<size_t>::max()});
}
} // namespace fuzzer