// Copyright 2019 The Pigweed Authors

//

// Licensed under the Apache License, Version 2.0 (the "License"); you may not

// use this file except in compliance with the License. You may obtain a copy of

// the License at

//

//     https://www.apache.org/licenses/LICENSE-2.0

//

// Unless required by applicable law or agreed to in writing, software

// distributed under the License is distributed on an "AS IS" BASIS, WITHOUT

// WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the

// License for the specific language governing permissions and limitations under

// the License.

#include <cstddef>

#include <cstdint>

#include <cstring>

#include <vector>

#include "fuzz.h"

#include "pw_fuzzer/asan_interface.h"

#include "pw_fuzzer/fuzzed_data_provider.h"

#include "pw_protobuf/encoder.h"

#include "pw_span/span.h"

namespace pw::protobuf::fuzz {

namespace {

// TODO: b/235289495 - Move this to pw_fuzzer/fuzzed_data_provider.h

// Uses the given |provider| to pick and return a number between 0 and the

// maximum numbers of T that can be generated from the remaining input data.

template <typename T>

size_t ConsumeSize(FuzzedDataProvider& provider) {

  size_t max = provider.remaining_bytes() / sizeof(T);

  return provider.ConsumeIntegralInRange<size_t>(0, max);

}

encoder_fuzzer.cc:unsigned long pw::protobuf::fuzz::(anonymous namespace)::ConsumeSize<unsigned int>(FuzzedDataProvider&)

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size_t ConsumeSize(FuzzedDataProvider& provider) {

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  size_t max = provider.remaining_bytes() / sizeof(T);

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3.54k

  return provider.ConsumeIntegralInRange<size_t>(0, max);

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3.54k

}

encoder_fuzzer.cc:unsigned long pw::protobuf::fuzz::(anonymous namespace)::ConsumeSize<unsigned long>(FuzzedDataProvider&)

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4.53k

size_t ConsumeSize(FuzzedDataProvider& provider) {

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4.53k

  size_t max = provider.remaining_bytes() / sizeof(T);

36

4.53k

  return provider.ConsumeIntegralInRange<size_t>(0, max);

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4.53k

}

encoder_fuzzer.cc:unsigned long pw::protobuf::fuzz::(anonymous namespace)::ConsumeSize<int>(FuzzedDataProvider&)

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4.10k

size_t ConsumeSize(FuzzedDataProvider& provider) {

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4.10k

  size_t max = provider.remaining_bytes() / sizeof(T);

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4.10k

  return provider.ConsumeIntegralInRange<size_t>(0, max);

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4.10k

}

encoder_fuzzer.cc:unsigned long pw::protobuf::fuzz::(anonymous namespace)::ConsumeSize<long>(FuzzedDataProvider&)

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4.23k

size_t ConsumeSize(FuzzedDataProvider& provider) {

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4.23k

  size_t max = provider.remaining_bytes() / sizeof(T);

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4.23k

  return provider.ConsumeIntegralInRange<size_t>(0, max);

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4.23k

}

encoder_fuzzer.cc:unsigned long pw::protobuf::fuzz::(anonymous namespace)::ConsumeSize<float>(FuzzedDataProvider&)

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2.02k

size_t ConsumeSize(FuzzedDataProvider& provider) {

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2.02k

  size_t max = provider.remaining_bytes() / sizeof(T);

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2.02k

  return provider.ConsumeIntegralInRange<size_t>(0, max);

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2.02k

}

encoder_fuzzer.cc:unsigned long pw::protobuf::fuzz::(anonymous namespace)::ConsumeSize<double>(FuzzedDataProvider&)

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2.64k

size_t ConsumeSize(FuzzedDataProvider& provider) {

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2.64k

  size_t max = provider.remaining_bytes() / sizeof(T);

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2.64k

  return provider.ConsumeIntegralInRange<size_t>(0, max);

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2.64k

}

encoder_fuzzer.cc:unsigned long pw::protobuf::fuzz::(anonymous namespace)::ConsumeSize<std::byte>(FuzzedDataProvider&)

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30.0k

size_t ConsumeSize(FuzzedDataProvider& provider) {

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30.0k

  size_t max = provider.remaining_bytes() / sizeof(T);

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30.0k

  return provider.ConsumeIntegralInRange<size_t>(0, max);

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30.0k

}

// Uses the given |provider| to generate several instances of T, store them in

// |data|, and then return a span to them. It is the caller's responsbility

// to ensure |data| remains in scope as long as the returned span.

template <typename T>

span<const T> ConsumeSpan(FuzzedDataProvider& provider, std::vector<T>* data) {

  size_t num = ConsumeSize<T>(provider);

  size_t off = data->size();

  if (num == 0) {

    return span<const T>();

  }

  data->reserve(off + num);

  for (size_t i = 0; i < num; ++i) {

    if constexpr (std::is_floating_point<T>::value) {

      data->push_back(provider.ConsumeFloatingPoint<T>());

    } else {

      data->push_back(provider.ConsumeIntegral<T>());

    }

  }

  return span(&((*data)[off]), num);

}

encoder_fuzzer.cc:pw::span<unsigned int const, 18446744073709551615ul> pw::protobuf::fuzz::(anonymous namespace)::ConsumeSpan<unsigned int>(FuzzedDataProvider&, std::__1::vector<unsigned int, std::__1::allocator<unsigned int> >*)

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3.54k

span<const T> ConsumeSpan(FuzzedDataProvider& provider, std::vector<T>* data) {

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3.54k

  size_t num = ConsumeSize<T>(provider);

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  size_t off = data->size();

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  if (num == 0) {

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1.83k

    return span<const T>();

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1.83k

  }

49

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  data->reserve(off + num);

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6.17M

  for (size_t i = 0; i < num; ++i) {

52

    if constexpr (std::is_floating_point<T>::value) {

53

      data->push_back(provider.ConsumeFloatingPoint<T>());

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6.16M

    } else {

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6.16M

      data->push_back(provider.ConsumeIntegral<T>());

56

6.16M

    }

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6.16M

  }

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  return span(&((*data)[off]), num);

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3.54k

}

encoder_fuzzer.cc:pw::span<unsigned long const, 18446744073709551615ul> pw::protobuf::fuzz::(anonymous namespace)::ConsumeSpan<unsigned long>(FuzzedDataProvider&, std::__1::vector<unsigned long, std::__1::allocator<unsigned long> >*)

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4.53k

span<const T> ConsumeSpan(FuzzedDataProvider& provider, std::vector<T>* data) {

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4.53k

  size_t num = ConsumeSize<T>(provider);

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4.53k

  size_t off = data->size();

46

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  if (num == 0) {

47

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    return span<const T>();

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2.47k

  }

49

50

2.06k

  data->reserve(off + num);

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4.87M

  for (size_t i = 0; i < num; ++i) {

52

    if constexpr (std::is_floating_point<T>::value) {

53

      data->push_back(provider.ConsumeFloatingPoint<T>());

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4.87M

    } else {

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4.87M

      data->push_back(provider.ConsumeIntegral<T>());

56

4.87M

    }

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4.87M

  }

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  return span(&((*data)[off]), num);

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4.53k

}

encoder_fuzzer.cc:pw::span<int const, 18446744073709551615ul> pw::protobuf::fuzz::(anonymous namespace)::ConsumeSpan<int>(FuzzedDataProvider&, std::__1::vector<int, std::__1::allocator<int> >*)

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4.10k

span<const T> ConsumeSpan(FuzzedDataProvider& provider, std::vector<T>* data) {

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  size_t num = ConsumeSize<T>(provider);

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  size_t off = data->size();

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  if (num == 0) {

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    return span<const T>();

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2.65k

  }

49

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1.45k

  data->reserve(off + num);

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5.25M

  for (size_t i = 0; i < num; ++i) {

52

    if constexpr (std::is_floating_point<T>::value) {

53

      data->push_back(provider.ConsumeFloatingPoint<T>());

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5.25M

    } else {

55

5.25M

      data->push_back(provider.ConsumeIntegral<T>());

56

5.25M

    }

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5.25M

  }

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  return span(&((*data)[off]), num);

59

4.10k

}

encoder_fuzzer.cc:pw::span<long const, 18446744073709551615ul> pw::protobuf::fuzz::(anonymous namespace)::ConsumeSpan<long>(FuzzedDataProvider&, std::__1::vector<long, std::__1::allocator<long> >*)

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4.23k

span<const T> ConsumeSpan(FuzzedDataProvider& provider, std::vector<T>* data) {

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4.23k

  size_t num = ConsumeSize<T>(provider);

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  size_t off = data->size();

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  if (num == 0) {

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    return span<const T>();

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  }

49

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  data->reserve(off + num);

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  for (size_t i = 0; i < num; ++i) {

52

    if constexpr (std::is_floating_point<T>::value) {

53

      data->push_back(provider.ConsumeFloatingPoint<T>());

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2.96M

    } else {

55

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      data->push_back(provider.ConsumeIntegral<T>());

56

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    }

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  }

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  return span(&((*data)[off]), num);

59

4.23k

}

encoder_fuzzer.cc:pw::span<float const, 18446744073709551615ul> pw::protobuf::fuzz::(anonymous namespace)::ConsumeSpan<float>(FuzzedDataProvider&, std::__1::vector<float, std::__1::allocator<float> >*)

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2.02k

span<const T> ConsumeSpan(FuzzedDataProvider& provider, std::vector<T>* data) {

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2.02k

  size_t num = ConsumeSize<T>(provider);

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2.02k

  size_t off = data->size();

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  if (num == 0) {

47

949

    return span<const T>();

48

949

  }

49

50

1.07k

  data->reserve(off + num);

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2.46M

  for (size_t i = 0; i < num; ++i) {

52

2.46M

    if constexpr (std::is_floating_point<T>::value) {

53

2.46M

      data->push_back(provider.ConsumeFloatingPoint<T>());

54

    } else {

55

      data->push_back(provider.ConsumeIntegral<T>());

56

    }

57

2.46M

  }

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1.07k

  return span(&((*data)[off]), num);

59

2.02k

}

encoder_fuzzer.cc:pw::span<double const, 18446744073709551615ul> pw::protobuf::fuzz::(anonymous namespace)::ConsumeSpan<double>(FuzzedDataProvider&, std::__1::vector<double, std::__1::allocator<double> >*)

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2.64k

span<const T> ConsumeSpan(FuzzedDataProvider& provider, std::vector<T>* data) {

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2.64k

  size_t num = ConsumeSize<T>(provider);

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  size_t off = data->size();

46

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  if (num == 0) {

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    return span<const T>();

48

1.19k

  }

49

50

1.45k

  data->reserve(off + num);

51

2.10M

  for (size_t i = 0; i < num; ++i) {

52

2.10M

    if constexpr (std::is_floating_point<T>::value) {

53

2.10M

      data->push_back(provider.ConsumeFloatingPoint<T>());

54

    } else {

55

      data->push_back(provider.ConsumeIntegral<T>());

56

    }

57

2.10M

  }

58

1.45k

  return span(&((*data)[off]), num);

59

2.64k

}

// Uses the given |provider| to generate a string, store it in |data|, and

// return a C-style representation. It is the caller's responsbility to

// ensure |data| remains in scope as long as the returned char*.

const char* ConsumeString(FuzzedDataProvider& provider,

                          std::vector<std::string>* data) {

  size_t off = data->size();

  // OSS-Fuzz's clang doesn't have the zero-parameter version of

  // ConsumeRandomLengthString yet.

  size_t max_length = std::numeric_limits<size_t>::max();

  data->push_back(provider.ConsumeRandomLengthString(max_length));

  return (*data)[off].c_str();

}

// Uses the given |provider| to generate non-arithmetic bytes, store them in

// |data|, and return a span to them. It is the caller's responsbility to

// ensure |data| remains in scope as long as the returned span.

span<const std::byte> ConsumeBytes(FuzzedDataProvider& provider,

                                   std::vector<std::byte>* data) {

  size_t num = ConsumeSize<std::byte>(provider);

  auto added = provider.ConsumeBytes<std::byte>(num);

  size_t off = data->size();

  num = added.size();

  data->insert(data->end(), added.begin(), added.end());

  // It's possible nothing was added, and the vector was empty to begin with.

  if (data->empty()) {

    return span<const std::byte>();

  }

  return span(&((*data)[off]), num);

}

void RecursiveFuzzedEncode(FuzzedDataProvider& provider,

                           StreamEncoder& encoder,

                           uint32_t depth = 0) {

  constexpr size_t kMaxDepth = 256;

  if (depth > kMaxDepth) {

    return;

  }

  // Storage for generated spans

  std::vector<uint32_t> u32s;

  std::vector<uint64_t> u64s;

  std::vector<int32_t> s32s;

  std::vector<int64_t> s64s;

  std::vector<float> floats;

  std::vector<double> doubles;

  std::vector<std::string> strings;

  std::vector<std::byte> bytes;

  // Consume the fuzzing input, using it to generate a sequence of fields to

  // encode. Both the uint32_t field IDs and the fields values are generated.

  // Don't try to detect errors, ensures pushes and pops are balanced, or

  // otherwise hold the interface correctly. Instead, fuzz the widest possbile

  // set of inputs to the encoder to ensure it doesn't misbehave.

  while (provider.remaining_bytes() != 0) {

    switch (provider.ConsumeEnum<FieldType>()) {

      case kUint32:

        encoder

            .WriteUint32(provider.ConsumeIntegral<uint32_t>(),

                         provider.ConsumeIntegral<uint32_t>())

            .IgnoreError();

        break;

      case kPackedUint32:

        encoder

            .WritePackedUint32(provider.ConsumeIntegral<uint32_t>(),

                               ConsumeSpan<uint32_t>(provider, &u32s))

            .IgnoreError();

        break;

      case kUint64:

        encoder

            .WriteUint64(provider.ConsumeIntegral<uint32_t>(),

                         provider.ConsumeIntegral<uint64_t>())

            .IgnoreError();

        break;

      case kPackedUint64:

        encoder

            .WritePackedUint64(provider.ConsumeIntegral<uint32_t>(),

                               ConsumeSpan<uint64_t>(provider, &u64s))

            .IgnoreError();

        break;

      case kInt32:

        encoder

            .WriteInt32(provider.ConsumeIntegral<uint32_t>(),

                        provider.ConsumeIntegral<int32_t>())

            .IgnoreError();

        break;

      case kPackedInt32:

        encoder

            .WritePackedInt32(provider.ConsumeIntegral<uint32_t>(),

                              ConsumeSpan<int32_t>(provider, &s32s))

            .IgnoreError();

        break;

      case kInt64:

        encoder

            .WriteInt64(provider.ConsumeIntegral<uint32_t>(),

                        provider.ConsumeIntegral<int64_t>())

            .IgnoreError();

        break;

      case kPackedInt64:

        encoder

            .WritePackedInt64(provider.ConsumeIntegral<uint32_t>(),

                              ConsumeSpan<int64_t>(provider, &s64s))

            .IgnoreError();

        break;

      case kSint32:

        encoder

            .WriteSint32(provider.ConsumeIntegral<uint32_t>(),

                         provider.ConsumeIntegral<int32_t>())

            .IgnoreError();

        break;

      case kPackedSint32:

        encoder

            .WritePackedSint32(provider.ConsumeIntegral<uint32_t>(),

                               ConsumeSpan<int32_t>(provider, &s32s))

            .IgnoreError();

        break;

      case kSint64:

        encoder

            .WriteSint64(provider.ConsumeIntegral<uint32_t>(),

                         provider.ConsumeIntegral<int64_t>())

            .IgnoreError();

        break;

      case kPackedSint64:

        encoder

            .WritePackedSint64(provider.ConsumeIntegral<uint32_t>(),

                               ConsumeSpan<int64_t>(provider, &s64s))

            .IgnoreError();

        break;

      case kBool:

        encoder

            .WriteBool(provider.ConsumeIntegral<uint32_t>(),

                       provider.ConsumeBool())

            .IgnoreError();

        break;

      case kFixed32:

        encoder

            .WriteFixed32(provider.ConsumeIntegral<uint32_t>(),

                          provider.ConsumeIntegral<uint32_t>())

            .IgnoreError();

        break;

      case kPackedFixed32:

        encoder

            .WritePackedFixed32(provider.ConsumeIntegral<uint32_t>(),

                                ConsumeSpan<uint32_t>(provider, &u32s))

            .IgnoreError();

        break;

      case kFixed64:

        encoder

            .WriteFixed64(provider.ConsumeIntegral<uint32_t>(),

                          provider.ConsumeIntegral<uint64_t>())

            .IgnoreError();

        break;

      case kPackedFixed64:

        encoder

            .WritePackedFixed64(provider.ConsumeIntegral<uint32_t>(),

                                ConsumeSpan<uint64_t>(provider, &u64s))

            .IgnoreError();

        break;

      case kSfixed32:

        encoder

            .WriteSfixed32(provider.ConsumeIntegral<uint32_t>(),

                           provider.ConsumeIntegral<int32_t>())

            .IgnoreError();

        break;

      case kPackedSfixed32:

        encoder

            .WritePackedSfixed32(provider.ConsumeIntegral<uint32_t>(),

                                 ConsumeSpan<int32_t>(provider, &s32s))

            .IgnoreError();

        break;

      case kSfixed64:

        encoder

            .WriteSfixed64(provider.ConsumeIntegral<uint32_t>(),

                           provider.ConsumeIntegral<int64_t>())

            .IgnoreError();

        break;

      case kPackedSfixed64:

        encoder

            .WritePackedSfixed64(provider.ConsumeIntegral<uint32_t>(),

                                 ConsumeSpan<int64_t>(provider, &s64s))

            .IgnoreError();

        break;

      case kFloat:

        encoder

            .WriteFloat(provider.ConsumeIntegral<uint32_t>(),

                        provider.ConsumeFloatingPoint<float>())

            .IgnoreError();

        break;

      case kPackedFloat:

        encoder

            .WritePackedFloat(provider.ConsumeIntegral<uint32_t>(),

                              ConsumeSpan<float>(provider, &floats))

            .IgnoreError();

        break;

      case kDouble:

        encoder

            .WriteDouble(provider.ConsumeIntegral<uint32_t>(),

                         provider.ConsumeFloatingPoint<double>())

            .IgnoreError();

        break;

      case kPackedDouble:

        encoder

            .WritePackedDouble(provider.ConsumeIntegral<uint32_t>(),

                               ConsumeSpan<double>(provider, &doubles))

            .IgnoreError();

        break;

      case kBytes:

        encoder

            .WriteBytes(provider.ConsumeIntegral<uint32_t>(),

                        ConsumeBytes(provider, &bytes))

            .IgnoreError();

        break;

      case kString:

        encoder

            .WriteString(provider.ConsumeIntegral<uint32_t>(),

                         ConsumeString(provider, &strings))

            .IgnoreError();

        break;

      case kPush: {

        // Special "field". The marks the start of a nested message.

        StreamEncoder nested_encoder =

            encoder.GetNestedEncoder(provider.ConsumeIntegral<uint32_t>());

        RecursiveFuzzedEncode(provider, nested_encoder, depth + 1);

        break;

      }

      case kPop:

        if (depth > 0) {

          // Special "field". The marks the end of a nested message.

          return;

        }

    }

  }

}

void TestOneInput(FuzzedDataProvider& provider) {

  static std::byte buffer[65536];

  // Pick a subset of the buffer that the fuzzer is allowed to use, and poison

  // the rest.

  size_t unpoisoned_length =

      provider.ConsumeIntegralInRange<size_t>(0, sizeof(buffer));

  ByteSpan unpoisoned(buffer, unpoisoned_length);

  void* poisoned = &buffer[unpoisoned_length];

  size_t poisoned_length = sizeof(buffer) - unpoisoned_length;

  ASAN_POISON_MEMORY_REGION(poisoned, poisoned_length);

  pw::protobuf::MemoryEncoder encoder(unpoisoned);

  RecursiveFuzzedEncode(provider, encoder);

  // Don't forget to unpoison for the next iteration!

  ASAN_UNPOISON_MEMORY_REGION(poisoned, poisoned_length);

}

}  // namespace

}  // namespace pw::protobuf::fuzz

extern "C" int LLVMFuzzerTestOneInput(const uint8_t* data, size_t size) {

  FuzzedDataProvider provider(data, size);

  pw::protobuf::fuzz::TestOneInput(provider);

  return 0;

}