third_party/perfetto/src/protozero/proto_decoder_unittest.cc - cobalt - Git at Google

 /*
  * Copyright (C) 2018 The Android Open Source Project
  *
  * 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
  *
  *      http://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 "perfetto/protozero/proto_decoder.h"

 #include "perfetto/ext/base/utils.h"
 #include "perfetto/protozero/message.h"
 #include "perfetto/protozero/proto_utils.h"
 #include "perfetto/protozero/scattered_heap_buffer.h"
 #include "perfetto/protozero/static_buffer.h"
 #include "test/gtest_and_gmock.h"

 #include "src/protozero/test/example_proto/test_messages.pb.h"
 #include "src/protozero/test/example_proto/test_messages.pbzero.h"

 // Generated by the protozero plugin.
 namespace pbtest = protozero::test::protos::pbzero;

 // Generated by the official protobuf compiler.
 namespace pbgold = protozero::test::protos;

 namespace protozero {
 namespace {

 using ::testing::_;
 using ::testing::InSequence;
 using ::testing::Invoke;
 using namespace proto_utils;

 TEST(ProtoDecoderTest, ReadString) {
   HeapBuffered<Message> message;

   static constexpr char kTestString[] = "test";
   message->AppendString(1, kTestString);
   std::vector<uint8_t> proto = message.SerializeAsArray();
   TypedProtoDecoder<32, false> decoder(proto.data(), proto.size());

   const auto& field = decoder.Get(1);
   ASSERT_EQ(field.type(), ProtoWireType::kLengthDelimited);
   ASSERT_EQ(field.size(), sizeof(kTestString) - 1);
   for (size_t i = 0; i < sizeof(kTestString) - 1; i++) {
     ASSERT_EQ(field.data()[i], kTestString[i]);
   }
 }

 TEST(ProtoDecoderTest, SkipVeryLargeFields) {
   const size_t kPayloadSize = 257 * 1024 * 1024;
   const uint64_t data_size = 4096 + kPayloadSize;
   std::unique_ptr<uint8_t, perfetto::base::FreeDeleter> data(
       static_cast<uint8_t*>(malloc(data_size)));
   StaticBuffered<Message> message(data.get(), data_size);

   // Append a valid field.
   message->AppendVarInt(/*field_id=*/1, 11);

   // Append a very large field that will be skipped.
   uint8_t raw[10];
   uint8_t* wptr = raw;
   wptr = WriteVarInt(MakeTagLengthDelimited(2), wptr);
   wptr = WriteVarInt(kPayloadSize, wptr);
   message->AppendRawProtoBytes(raw, static_cast<size_t>(wptr - raw));
   const size_t kPaddingSize = 1024 * 128;
   std::unique_ptr<uint8_t[]> padding(new uint8_t[kPaddingSize]());
   for (size_t i = 0; i < kPayloadSize / kPaddingSize; i++)
     message->AppendRawProtoBytes(padding.get(), kPaddingSize);

   // Append another valid field.
   message->AppendVarInt(/*field_id=*/3, 13);

   ProtoDecoder decoder(data.get(), message.Finalize());
   Field field = decoder.ReadField();
   ASSERT_EQ(1u, field.id());
   ASSERT_EQ(11, field.as_int32());

   field = decoder.ReadField();
   ASSERT_EQ(3u, field.id());
   ASSERT_EQ(13, field.as_int32());

   field = decoder.ReadField();
   ASSERT_FALSE(field.valid());
 }

 TEST(ProtoDecoderTest, SingleRepeatedField) {
   HeapBuffered<Message> message;
   message->AppendVarInt(/*field_id=*/2, 10);
   auto data = message.SerializeAsArray();
   TypedProtoDecoder<2, true> tpd(data.data(), data.size());
   auto it = tpd.GetRepeated<int32_t>(/*field_id=*/2);
   EXPECT_TRUE(it);
   EXPECT_EQ(it.field().as_int32(), 10);
   EXPECT_EQ(*it, 10);
   EXPECT_FALSE(++it);
 }

 TEST(ProtoDecoderTest, RepeatedVariableLengthField) {
   HeapBuffered<Message> message;

   static constexpr char kTestString[] = "test";
   static constexpr char kTestString2[] = "honk honk";
   message->AppendString(1, kTestString);
   message->AppendString(1, kTestString2);
   std::vector<uint8_t> proto = message.SerializeAsArray();
   TypedProtoDecoder<32, false> decoder(proto.data(), proto.size());

   auto it = decoder.GetRepeated<ConstChars>(1);
   ASSERT_EQ(it->type(), ProtoWireType::kLengthDelimited);
   ASSERT_EQ(it->size(), sizeof(kTestString) - 1);
   ASSERT_EQ(it->as_std_string(), std::string(kTestString));
   ASSERT_EQ((*it).ToStdString(), std::string(kTestString));
   ++it;
   ASSERT_EQ(it->type(), ProtoWireType::kLengthDelimited);
   ASSERT_EQ(it->size(), sizeof(kTestString2) - 1);
   ASSERT_EQ(it->as_std_string(), std::string(kTestString2));
   ASSERT_EQ((*it).ToStdString(), std::string(kTestString2));
 }

 TEST(ProtoDecoderTest, SingleRepeatedFieldWithExpansion) {
   HeapBuffered<Message> message;
   for (int i = 0; i < 2000; i++) {
     message->AppendVarInt(/*field_id=*/2, i);
   }
   auto data = message.SerializeAsArray();
   TypedProtoDecoder<2, true> tpd(data.data(), data.size());
   auto it = tpd.GetRepeated<int32_t>(/*field_id=*/2);
   for (int i = 0; i < 2000; i++) {
     EXPECT_TRUE(it);
     EXPECT_EQ(*it, i);
     ++it;
   }
   EXPECT_FALSE(it);
 }

 TEST(ProtoDecoderTest, NoRepeatedField) {
   uint8_t buf[] = {0x01};
   TypedProtoDecoder<2, true> tpd(buf, 1);
   auto it = tpd.GetRepeated<int32_t>(/*field_id=*/1);
   EXPECT_FALSE(it);
   EXPECT_FALSE(tpd.Get(2).valid());
 }

 TEST(ProtoDecoderTest, RepeatedFields) {
   HeapBuffered<Message> message;

   message->AppendVarInt(1, 10);
   message->AppendVarInt(2, 20);
   message->AppendVarInt(3, 30);

   message->AppendVarInt(1, 11);
   message->AppendVarInt(2, 21);
   message->AppendVarInt(2, 22);

   // When iterating with the simple decoder we should just see fields in parsing
   // order.
   auto data = message.SerializeAsArray();
   ProtoDecoder decoder(data.data(), data.size());
   std::string fields_seen;
   for (auto fld = decoder.ReadField(); fld.valid(); fld = decoder.ReadField()) {
     fields_seen +=
         std::to_string(fld.id()) + ":" + std::to_string(fld.as_int32()) + ";";
   }
   EXPECT_EQ(fields_seen, "1:10;2:20;3:30;1:11;2:21;2:22;");

   TypedProtoDecoder<4, true> tpd(data.data(), data.size());

   // When parsing with the one-shot decoder and querying the single field id, we
   // should see the last value for each of them, not the first one. This is the
   // current behavior of Google protobuf's parser.
   EXPECT_EQ(tpd.Get(1).as_int32(), 11);
   EXPECT_EQ(tpd.Get(2).as_int32(), 22);
   EXPECT_EQ(tpd.Get(3).as_int32(), 30);

   // But when iterating we should see values in the original order.
   auto it = tpd.GetRepeated<int32_t>(1);
   EXPECT_EQ(*it, 10);
   EXPECT_EQ(*++it, 11);
   EXPECT_FALSE(++it);

   it = tpd.GetRepeated<int32_t>(2);
   EXPECT_EQ(*it++, 20);
   EXPECT_EQ(*it++, 21);
   EXPECT_EQ(*it++, 22);
   EXPECT_FALSE(it);

   it = tpd.GetRepeated<int32_t>(3);
   EXPECT_EQ(*it, 30);
   EXPECT_FALSE(++it);
 }

 TEST(ProtoDecoderTest, FixedData) {
   struct FieldExpectation {
     const char* encoded;
     size_t encoded_size;
     uint32_t id;
     ProtoWireType type;
     uint64_t int_value;
   };

   const FieldExpectation kFieldExpectations[] = {
       {"\x08\x00", 2, 1, ProtoWireType::kVarInt, 0},
       {"\x08\x01", 2, 1, ProtoWireType::kVarInt, 1},
       {"\x08\x42", 2, 1, ProtoWireType::kVarInt, 0x42},
       {"\xF8\x07\x42", 3, 127, ProtoWireType::kVarInt, 0x42},
       {"\xB8\x3E\xFF\xFF\xFF\xFF\x0F", 7, 999, ProtoWireType::kVarInt,
        0xFFFFFFFF},
       {"\x7D\x42\x00\x00\x00", 5, 15, ProtoWireType::kFixed32, 0x42},
       {"\xBD\x3E\x78\x56\x34\x12", 6, 999, ProtoWireType::kFixed32, 0x12345678},
       {"\x79\x42\x00\x00\x00\x00\x00\x00\x00", 9, 15, ProtoWireType::kFixed64,
        0x42},
       {"\xB9\x3E\x08\x07\x06\x05\x04\x03\x02\x01", 10, 999,
        ProtoWireType::kFixed64, 0x0102030405060708},
       {"\x0A\x00", 2, 1, ProtoWireType::kLengthDelimited, 0},
       {"\x0A\x04|abc", 6, 1, ProtoWireType::kLengthDelimited, 4},
       {"\xBA\x3E\x04|abc", 7, 999, ProtoWireType::kLengthDelimited, 4},
       {"\xBA\x3E\x83\x01|abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzab"
        "cdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstu"
        "vwx",
        135, 999, ProtoWireType::kLengthDelimited, 131},
   };

   for (size_t i = 0; i < perfetto::base::ArraySize(kFieldExpectations); ++i) {
     const FieldExpectation& exp = kFieldExpectations[i];
     TypedProtoDecoder<999, 0> decoder(
         reinterpret_cast<const uint8_t*>(exp.encoded), exp.encoded_size);

     auto& field = decoder.Get(exp.id);
     ASSERT_EQ(exp.type, field.type());

     if (field.type() == ProtoWireType::kLengthDelimited) {
       ASSERT_EQ(exp.int_value, field.size());
     } else {
       ASSERT_EQ(int64_t(exp.int_value), field.as_int64());
       // Proto encodes booleans as varints of 0 or 1.
       if (exp.int_value == 0 || exp.int_value == 1) {
         ASSERT_EQ(int64_t(exp.int_value), field.as_bool());
       }
     }
   }

   // Test float and doubles decoding.
   const char buf[] = "\x0d\x00\x00\xa0\x3f\x11\x00\x00\x00\x00\x00\x42\x8f\xc0";
   TypedProtoDecoder<2, false> decoder(reinterpret_cast<const uint8_t*>(buf),
                                       sizeof(buf));
   EXPECT_FLOAT_EQ(decoder.Get(1).as_float(), 1.25f);
   EXPECT_DOUBLE_EQ(decoder.Get(2).as_double(), -1000.25);
 }

 TEST(ProtoDecoderTest, FindField) {
   uint8_t buf[] = {0x08, 0x00};  // field_id 1, varint value 0.
   ProtoDecoder pd(buf, 2);

   auto field = pd.FindField(1);
   ASSERT_TRUE(field);
   EXPECT_EQ(field.as_int64(), 0);

   auto field2 = pd.FindField(2);
   EXPECT_FALSE(field2);
 }

 TEST(ProtoDecoderTest, MoveTypedDecoder) {
   HeapBuffered<Message> message;
   message->AppendVarInt(/*field_id=*/1, 10);
   std::vector<uint8_t> proto = message.SerializeAsArray();

   // Construct a decoder that uses inline storage (i.e., the fields are stored
   // within the object itself).
   using Decoder = TypedProtoDecoder<32, false>;
   std::unique_ptr<Decoder> decoder(new Decoder(proto.data(), proto.size()));
   ASSERT_GE(reinterpret_cast<uintptr_t>(&decoder->at<1>()),
             reinterpret_cast<uintptr_t>(decoder.get()));
   ASSERT_LT(reinterpret_cast<uintptr_t>(&decoder->at<1>()),
             reinterpret_cast<uintptr_t>(decoder.get()) + sizeof(Decoder));

   // Move the decoder into another object and deallocate the original object.
   Decoder decoder2(std::move(*decoder));
   decoder.reset();

   // Check that the contents got moved correctly.
   EXPECT_EQ(decoder2.Get(1).as_int32(), 10);
   ASSERT_GE(reinterpret_cast<uintptr_t>(&decoder2.at<1>()),
             reinterpret_cast<uintptr_t>(&decoder2));
   ASSERT_LT(reinterpret_cast<uintptr_t>(&decoder2.at<1>()),
             reinterpret_cast<uintptr_t>(&decoder2) + sizeof(Decoder));
 }

 TEST(ProtoDecoderTest, PackedRepeatedVarint) {
   std::vector<int32_t> values = {42, 255, 0, -1};

   // serialize using protobuf library
   pbgold::PackedRepeatedFields msg;
   for (auto v : values)
     msg.add_field_int32(v);
   std::string serialized = msg.SerializeAsString();

   // decode using TypedProtoDecoder directly
   {
     constexpr int kFieldId =
         pbtest::PackedRepeatedFields::kFieldInt32FieldNumber;
     TypedProtoDecoder<kFieldId, false> decoder(
         reinterpret_cast<const uint8_t*>(serialized.data()), serialized.size());
     ASSERT_TRUE(decoder.at<kFieldId>().valid());
     bool parse_error = false;
     auto packed_it =
         decoder.GetPackedRepeated<proto_utils::ProtoWireType::kVarInt, int32_t>(
             kFieldId, &parse_error);

     std::vector<int32_t> decoded_values;
     for (; packed_it; ++packed_it) {
       auto v = *packed_it;
       decoded_values.push_back(v);
     }
     ASSERT_EQ(values, decoded_values);
     ASSERT_FALSE(parse_error);
   }

   // decode using plugin-generated accessor
   {
     auto decoder = pbtest::PackedRepeatedFields::Decoder(serialized);
     ASSERT_TRUE(decoder.has_field_int32());

     bool parse_error = false;
     std::vector<int32_t> decoded_values;
     for (auto packed_it = decoder.field_int32(&parse_error); packed_it;
          ++packed_it) {
       auto v = *packed_it;
       decoded_values.push_back(v);
     }
     ASSERT_EQ(values, decoded_values);
     ASSERT_FALSE(parse_error);
   }

   // unset field case
   pbgold::PackedRepeatedFields empty_msg;
   std::string empty_serialized = empty_msg.SerializeAsString();
   auto decoder = pbtest::PackedRepeatedFields::Decoder(empty_serialized);
   ASSERT_FALSE(decoder.has_field_int32());
   bool parse_error = false;
   auto packed_it = decoder.field_int32(&parse_error);
   ASSERT_FALSE(bool(packed_it));
   ASSERT_FALSE(parse_error);
 }

 TEST(ProtoDecoderTest, PackedRepeatedFixed32) {
   std::vector<uint32_t> values = {42, 255, 0, 1};

   // serialize using protobuf library
   pbgold::PackedRepeatedFields msg;
   for (auto v : values)
     msg.add_field_fixed32(v);
   std::string serialized = msg.SerializeAsString();

   // decode using TypedProtoDecoder directly
   {
     constexpr int kFieldId =
         pbtest::PackedRepeatedFields::kFieldFixed32FieldNumber;
     TypedProtoDecoder<kFieldId, false> decoder(
         reinterpret_cast<const uint8_t*>(serialized.data()), serialized.size());
     bool parse_error = false;
     auto packed_it =
         decoder
             .GetPackedRepeated<proto_utils::ProtoWireType::kFixed32, uint32_t>(
                 kFieldId, &parse_error);

     std::vector<uint32_t> decoded_values;
     for (; packed_it; ++packed_it) {
       auto v = *packed_it;
       decoded_values.push_back(v);
     }
     ASSERT_EQ(values, decoded_values);
     ASSERT_FALSE(parse_error);
   }

   // decode using plugin-generated accessor
   {
     auto decoder = pbtest::PackedRepeatedFields::Decoder(serialized);
     ASSERT_TRUE(decoder.has_field_fixed32());

     bool parse_error = false;
     std::vector<uint32_t> decoded_values;
     for (auto packed_it = decoder.field_fixed32(&parse_error); packed_it;
          packed_it++) {
       auto v = *packed_it;
       decoded_values.push_back(v);
     }
     ASSERT_EQ(values, decoded_values);
     ASSERT_FALSE(parse_error);
   }

   // unset field case
   pbgold::PackedRepeatedFields empty_msg;
   std::string empty_serialized = empty_msg.SerializeAsString();
   auto decoder = pbtest::PackedRepeatedFields::Decoder(empty_serialized);
   ASSERT_FALSE(decoder.has_field_fixed32());
   bool parse_error = false;
   auto packed_it = decoder.field_fixed32(&parse_error);
   ASSERT_FALSE(bool(packed_it));
   ASSERT_FALSE(parse_error);
 }

 TEST(ProtoDecoderTest, PackedRepeatedFixed64) {
   std::vector<int64_t> values = {42, 255, 0, -1};

   // serialize using protobuf library
   pbgold::PackedRepeatedFields msg;
   for (auto v : values)
     msg.add_field_sfixed64(v);
   std::string serialized = msg.SerializeAsString();

   // decode using TypedProtoDecoder directly
   {
     constexpr int kFieldId =
         pbtest::PackedRepeatedFields::kFieldSfixed64FieldNumber;
     TypedProtoDecoder<kFieldId, false> decoder(
         reinterpret_cast<const uint8_t*>(serialized.data()), serialized.size());
     bool parse_error = false;
     auto packed_it =
         decoder
             .GetPackedRepeated<proto_utils::ProtoWireType::kFixed64, int64_t>(
                 kFieldId, &parse_error);

     std::vector<int64_t> decoded_values;
     for (; packed_it; ++packed_it) {
       auto v = *packed_it;
       decoded_values.push_back(v);
     }
     ASSERT_EQ(values, decoded_values);
     ASSERT_FALSE(parse_error);
   }

   // decode using plugin-generated accessor
   {
     auto decoder = pbtest::PackedRepeatedFields::Decoder(serialized);
     ASSERT_TRUE(decoder.has_field_sfixed64());

     bool parse_error = false;
     std::vector<int64_t> decoded_values;
     for (auto packed_it = decoder.field_sfixed64(&parse_error); packed_it;
          packed_it++) {
       auto v = *packed_it;
       decoded_values.push_back(v);
     }
     ASSERT_EQ(values, decoded_values);
     ASSERT_FALSE(parse_error);
   }

   // unset field case
   pbgold::PackedRepeatedFields empty_msg;
   std::string empty_serialized = empty_msg.SerializeAsString();
   auto decoder = pbtest::PackedRepeatedFields::Decoder(empty_serialized);
   ASSERT_FALSE(decoder.has_field_sfixed64());
   bool parse_error = false;
   auto packed_it = decoder.field_sfixed64(&parse_error);
   ASSERT_FALSE(bool(packed_it));
   ASSERT_FALSE(parse_error);
 }

 TEST(ProtoDecoderTest, ZeroLengthPackedRepeatedField) {
   HeapBuffered<pbtest::PackedRepeatedFields> msg;
   PackedVarInt buf;
   msg->set_field_int32(buf);
   std::string serialized = msg.SerializeAsString();

   // Encoded as 2 bytes: tag/field, and a length of zero.
   EXPECT_EQ(2u, serialized.size());

   // Appears empty when decoded.
   auto decoder = pbtest::PackedRepeatedFields::Decoder(serialized);
   ASSERT_TRUE(decoder.has_field_int32());
   bool parse_error = false;
   auto packed_it = decoder.field_int32(&parse_error);
   ASSERT_FALSE(bool(packed_it));
   ASSERT_FALSE(parse_error);
 }

 TEST(ProtoDecoderTest, MalformedPackedFixedBuffer) {
   // Encode a fixed32 field where the length is not a multiple of 4 bytes.
   HeapBuffered<pbtest::PackedRepeatedFields> msg;
   PackedFixedSizeInt<uint32_t> buf;
   buf.Append(1);
   buf.Append(2);
   buf.Append(3);
   const uint8_t* data = buf.data();
   size_t size = buf.size();
   size_t invalid_size = size - 2;
   constexpr int kFieldId =
       pbtest::PackedRepeatedFields::kFieldFixed32FieldNumber;
   msg->AppendBytes(kFieldId, data, invalid_size);
   std::string serialized = msg.SerializeAsString();

   // Iterator indicates parse error.
   auto decoder = pbtest::PackedRepeatedFields::Decoder(serialized);
   ASSERT_TRUE(decoder.has_field_fixed32());
   bool parse_error = false;
   for (auto packed_it = decoder.field_fixed32(&parse_error); packed_it;
        packed_it++) {
   }
   ASSERT_TRUE(parse_error);
 }

 TEST(ProtoDecoderTest, MalformedPackedVarIntBuffer) {
   // Encode a varint field with the last varint chopped off partway.
   HeapBuffered<pbtest::PackedRepeatedFields> msg;
   PackedVarInt buf;
   buf.Append(1024);
   buf.Append(2048);
   buf.Append(4096);
   const uint8_t* data = buf.data();
   size_t size = buf.size();
   size_t invalid_size = size - 1;
   constexpr int kFieldId = pbtest::PackedRepeatedFields::kFieldInt32FieldNumber;
   msg->AppendBytes(kFieldId, data, invalid_size);
   std::string serialized = msg.SerializeAsString();

   // Iterator indicates parse error.
   auto decoder = pbtest::PackedRepeatedFields::Decoder(serialized);
   ASSERT_TRUE(decoder.has_field_int32());
   bool parse_error = false;
   for (auto packed_it = decoder.field_int32(&parse_error); packed_it;
        packed_it++) {
   }
   ASSERT_TRUE(parse_error);
 }

 // Tests that big field ids (> 0xffff) are just skipped but don't fail parsing.
 // This is a regression test for b/145339282 (DataSourceConfig.for_testing
 // having a very large ID == 268435455 until Android R).
 TEST(ProtoDecoderTest, SkipBigFieldIds) {
   HeapBuffered<Message> message;
   message->AppendVarInt(/*field_id=*/1, 11);
   message->AppendVarInt(/*field_id=*/1000000, 0);  // Will be skipped
   message->AppendVarInt(/*field_id=*/65535, 99);
   message->AppendVarInt(/*field_id=*/268435455, 0);  // Will be skipped
   message->AppendVarInt(/*field_id=*/2, 12);
   message->AppendVarInt(/*field_id=*/2000000, 0);  // Will be skipped
   auto data = message.SerializeAsArray();

   // Check the iterator-based ProtoDecoder.
   {
     ProtoDecoder decoder(data.data(), data.size());
     Field field = decoder.ReadField();
     ASSERT_TRUE(field.valid());
     ASSERT_EQ(field.id(), 1u);
     ASSERT_EQ(field.as_int32(), 11);

     field = decoder.ReadField();
     ASSERT_TRUE(field.valid());
     ASSERT_EQ(field.id(), 65535u);
     ASSERT_EQ(field.as_int32(), 99);

     field = decoder.ReadField();
     ASSERT_TRUE(field.valid());
     ASSERT_EQ(field.id(), 2u);
     ASSERT_EQ(field.as_int32(), 12);

     field = decoder.ReadField();
     ASSERT_FALSE(field.valid());
   }

   // Test the one-shot-read TypedProtoDecoder.
   // Note: field 65535 will be also skipped because this TypedProtoDecoder has
   // a cap on MAX_FIELD_ID = 3.
   {
     TypedProtoDecoder<3, true> tpd(data.data(), data.size());
     EXPECT_EQ(tpd.Get(1).as_int32(), 11);
     EXPECT_EQ(tpd.Get(2).as_int32(), 12);
   }
 }

 // Edge case for SkipBigFieldIds, the message contains only one field with a
 // very big id. Test that we skip it and return an invalid field, instead of
 // geetting stuck in some loop.
 TEST(ProtoDecoderTest, OneBigFieldIdOnly) {
   HeapBuffered<Message> message;
   message->AppendVarInt(/*field_id=*/268435455, 0);
   auto data = message.SerializeAsArray();

   // Check the iterator-based ProtoDecoder.
   ProtoDecoder decoder(data.data(), data.size());
   Field field = decoder.ReadField();
   ASSERT_FALSE(field.valid());
 }

 }  // namespace
 }  // namespace protozero
	/*
	* Copyright (C) 2018 The Android Open Source Project
	*
	* 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
	*
	* http://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 "perfetto/protozero/proto_decoder.h"

	#include "perfetto/ext/base/utils.h"
	#include "perfetto/protozero/message.h"
	#include "perfetto/protozero/proto_utils.h"
	#include "perfetto/protozero/scattered_heap_buffer.h"
	#include "perfetto/protozero/static_buffer.h"
	#include "test/gtest_and_gmock.h"

	#include "src/protozero/test/example_proto/test_messages.pb.h"
	#include "src/protozero/test/example_proto/test_messages.pbzero.h"

	// Generated by the protozero plugin.
	namespace pbtest = protozero::test::protos::pbzero;

	// Generated by the official protobuf compiler.
	namespace pbgold = protozero::test::protos;

	namespace protozero {
	namespace {

	using ::testing::_;
	using ::testing::InSequence;
	using ::testing::Invoke;
	using namespace proto_utils;

	TEST(ProtoDecoderTest, ReadString) {
	HeapBuffered<Message> message;

	static constexpr char kTestString[] = "test";
	message->AppendString(1, kTestString);
	std::vector<uint8_t> proto = message.SerializeAsArray();
	TypedProtoDecoder<32, false> decoder(proto.data(), proto.size());

	const auto& field = decoder.Get(1);
	ASSERT_EQ(field.type(), ProtoWireType::kLengthDelimited);
	ASSERT_EQ(field.size(), sizeof(kTestString) - 1);
	for (size_t i = 0; i < sizeof(kTestString) - 1; i++) {
	ASSERT_EQ(field.data()[i], kTestString[i]);
	}
	}

	TEST(ProtoDecoderTest, SkipVeryLargeFields) {
	const size_t kPayloadSize = 257 * 1024 * 1024;
	const uint64_t data_size = 4096 + kPayloadSize;
	std::unique_ptr<uint8_t, perfetto::base::FreeDeleter> data(
	static_cast<uint8_t*>(malloc(data_size)));
	StaticBuffered<Message> message(data.get(), data_size);

	// Append a valid field.
	message->AppendVarInt(/field_id=/1, 11);

	// Append a very large field that will be skipped.
	uint8_t raw[10];
	uint8_t* wptr = raw;
	wptr = WriteVarInt(MakeTagLengthDelimited(2), wptr);
	wptr = WriteVarInt(kPayloadSize, wptr);
	message->AppendRawProtoBytes(raw, static_cast<size_t>(wptr - raw));
	const size_t kPaddingSize = 1024 * 128;
	std::unique_ptr<uint8_t[]> padding(new uint8_t[kPaddingSize]());
	for (size_t i = 0; i < kPayloadSize / kPaddingSize; i++)
	message->AppendRawProtoBytes(padding.get(), kPaddingSize);

	// Append another valid field.
	message->AppendVarInt(/field_id=/3, 13);

	ProtoDecoder decoder(data.get(), message.Finalize());
	Field field = decoder.ReadField();
	ASSERT_EQ(1u, field.id());
	ASSERT_EQ(11, field.as_int32());

	field = decoder.ReadField();
	ASSERT_EQ(3u, field.id());
	ASSERT_EQ(13, field.as_int32());

	field = decoder.ReadField();
	ASSERT_FALSE(field.valid());
	}

	TEST(ProtoDecoderTest, SingleRepeatedField) {
	HeapBuffered<Message> message;
	message->AppendVarInt(/field_id=/2, 10);
	auto data = message.SerializeAsArray();
	TypedProtoDecoder<2, true> tpd(data.data(), data.size());
	auto it = tpd.GetRepeated<int32_t>(/field_id=/2);
	EXPECT_TRUE(it);
	EXPECT_EQ(it.field().as_int32(), 10);
	EXPECT_EQ(*it, 10);
	EXPECT_FALSE(++it);
	}

	TEST(ProtoDecoderTest, RepeatedVariableLengthField) {
	HeapBuffered<Message> message;

	static constexpr char kTestString[] = "test";
	static constexpr char kTestString2[] = "honk honk";
	message->AppendString(1, kTestString);
	message->AppendString(1, kTestString2);
	std::vector<uint8_t> proto = message.SerializeAsArray();
	TypedProtoDecoder<32, false> decoder(proto.data(), proto.size());

	auto it = decoder.GetRepeated<ConstChars>(1);
	ASSERT_EQ(it->type(), ProtoWireType::kLengthDelimited);
	ASSERT_EQ(it->size(), sizeof(kTestString) - 1);
	ASSERT_EQ(it->as_std_string(), std::string(kTestString));
	ASSERT_EQ((*it).ToStdString(), std::string(kTestString));
	++it;
	ASSERT_EQ(it->type(), ProtoWireType::kLengthDelimited);
	ASSERT_EQ(it->size(), sizeof(kTestString2) - 1);
	ASSERT_EQ(it->as_std_string(), std::string(kTestString2));
	ASSERT_EQ((*it).ToStdString(), std::string(kTestString2));
	}

	TEST(ProtoDecoderTest, SingleRepeatedFieldWithExpansion) {
	HeapBuffered<Message> message;
	for (int i = 0; i < 2000; i++) {
	message->AppendVarInt(/field_id=/2, i);
	}
	auto data = message.SerializeAsArray();
	TypedProtoDecoder<2, true> tpd(data.data(), data.size());
	auto it = tpd.GetRepeated<int32_t>(/field_id=/2);
	for (int i = 0; i < 2000; i++) {
	EXPECT_TRUE(it);
	EXPECT_EQ(*it, i);
	++it;
	}
	EXPECT_FALSE(it);
	}

	TEST(ProtoDecoderTest, NoRepeatedField) {
	uint8_t buf[] = {0x01};
	TypedProtoDecoder<2, true> tpd(buf, 1);
	auto it = tpd.GetRepeated<int32_t>(/field_id=/1);
	EXPECT_FALSE(it);
	EXPECT_FALSE(tpd.Get(2).valid());
	}

	TEST(ProtoDecoderTest, RepeatedFields) {
	HeapBuffered<Message> message;

	message->AppendVarInt(1, 10);
	message->AppendVarInt(2, 20);
	message->AppendVarInt(3, 30);

	message->AppendVarInt(1, 11);
	message->AppendVarInt(2, 21);
	message->AppendVarInt(2, 22);

	// When iterating with the simple decoder we should just see fields in parsing
	// order.
	auto data = message.SerializeAsArray();
	ProtoDecoder decoder(data.data(), data.size());
	std::string fields_seen;
	for (auto fld = decoder.ReadField(); fld.valid(); fld = decoder.ReadField()) {
	fields_seen +=
	std::to_string(fld.id()) + ":" + std::to_string(fld.as_int32()) + ";";
	}
	EXPECT_EQ(fields_seen, "1:10;2:20;3:30;1:11;2:21;2:22;");

	TypedProtoDecoder<4, true> tpd(data.data(), data.size());

	// When parsing with the one-shot decoder and querying the single field id, we
	// should see the last value for each of them, not the first one. This is the
	// current behavior of Google protobuf's parser.
	EXPECT_EQ(tpd.Get(1).as_int32(), 11);
	EXPECT_EQ(tpd.Get(2).as_int32(), 22);
	EXPECT_EQ(tpd.Get(3).as_int32(), 30);

	// But when iterating we should see values in the original order.
	auto it = tpd.GetRepeated<int32_t>(1);
	EXPECT_EQ(*it, 10);
	EXPECT_EQ(*++it, 11);
	EXPECT_FALSE(++it);

	it = tpd.GetRepeated<int32_t>(2);
	EXPECT_EQ(*it++, 20);
	EXPECT_EQ(*it++, 21);
	EXPECT_EQ(*it++, 22);
	EXPECT_FALSE(it);

	it = tpd.GetRepeated<int32_t>(3);
	EXPECT_EQ(*it, 30);
	EXPECT_FALSE(++it);
	}

	TEST(ProtoDecoderTest, FixedData) {
	struct FieldExpectation {
	const char* encoded;
	size_t encoded_size;
	uint32_t id;
	ProtoWireType type;
	uint64_t int_value;
	};

	const FieldExpectation kFieldExpectations[] = {
	{"\x08\x00", 2, 1, ProtoWireType::kVarInt, 0},
	{"\x08\x01", 2, 1, ProtoWireType::kVarInt, 1},
	{"\x08\x42", 2, 1, ProtoWireType::kVarInt, 0x42},
	{"\xF8\x07\x42", 3, 127, ProtoWireType::kVarInt, 0x42},
	{"\xB8\x3E\xFF\xFF\xFF\xFF\x0F", 7, 999, ProtoWireType::kVarInt,
	0xFFFFFFFF},
	{"\x7D\x42\x00\x00\x00", 5, 15, ProtoWireType::kFixed32, 0x42},
	{"\xBD\x3E\x78\x56\x34\x12", 6, 999, ProtoWireType::kFixed32, 0x12345678},
	{"\x79\x42\x00\x00\x00\x00\x00\x00\x00", 9, 15, ProtoWireType::kFixed64,
	0x42},
	{"\xB9\x3E\x08\x07\x06\x05\x04\x03\x02\x01", 10, 999,
	ProtoWireType::kFixed64, 0x0102030405060708},
	{"\x0A\x00", 2, 1, ProtoWireType::kLengthDelimited, 0},
	{"\x0A\x04\|abc", 6, 1, ProtoWireType::kLengthDelimited, 4},
	{"\xBA\x3E\x04\|abc", 7, 999, ProtoWireType::kLengthDelimited, 4},
	{"\xBA\x3E\x83\x01\|abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzab"
	"cdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstu"
	"vwx",
	135, 999, ProtoWireType::kLengthDelimited, 131},
	};

	for (size_t i = 0; i < perfetto::base::ArraySize(kFieldExpectations); ++i) {
	const FieldExpectation& exp = kFieldExpectations[i];
	TypedProtoDecoder<999, 0> decoder(
	reinterpret_cast<const uint8_t*>(exp.encoded), exp.encoded_size);

	auto& field = decoder.Get(exp.id);
	ASSERT_EQ(exp.type, field.type());

	if (field.type() == ProtoWireType::kLengthDelimited) {
	ASSERT_EQ(exp.int_value, field.size());
	} else {
	ASSERT_EQ(int64_t(exp.int_value), field.as_int64());
	// Proto encodes booleans as varints of 0 or 1.
	if (exp.int_value == 0 \|\| exp.int_value == 1) {
	ASSERT_EQ(int64_t(exp.int_value), field.as_bool());
	}
	}
	}

	// Test float and doubles decoding.
	const char buf[] = "\x0d\x00\x00\xa0\x3f\x11\x00\x00\x00\x00\x00\x42\x8f\xc0";
	TypedProtoDecoder<2, false> decoder(reinterpret_cast<const uint8_t*>(buf),
	sizeof(buf));
	EXPECT_FLOAT_EQ(decoder.Get(1).as_float(), 1.25f);
	EXPECT_DOUBLE_EQ(decoder.Get(2).as_double(), -1000.25);
	}

	TEST(ProtoDecoderTest, FindField) {
	uint8_t buf[] = {0x08, 0x00}; // field_id 1, varint value 0.
	ProtoDecoder pd(buf, 2);

	auto field = pd.FindField(1);
	ASSERT_TRUE(field);
	EXPECT_EQ(field.as_int64(), 0);

	auto field2 = pd.FindField(2);
	EXPECT_FALSE(field2);
	}

	TEST(ProtoDecoderTest, MoveTypedDecoder) {
	HeapBuffered<Message> message;
	message->AppendVarInt(/field_id=/1, 10);
	std::vector<uint8_t> proto = message.SerializeAsArray();

	// Construct a decoder that uses inline storage (i.e., the fields are stored
	// within the object itself).
	using Decoder = TypedProtoDecoder<32, false>;
	std::unique_ptr<Decoder> decoder(new Decoder(proto.data(), proto.size()));
	ASSERT_GE(reinterpret_cast<uintptr_t>(&decoder->at<1>()),
	reinterpret_cast<uintptr_t>(decoder.get()));
	ASSERT_LT(reinterpret_cast<uintptr_t>(&decoder->at<1>()),
	reinterpret_cast<uintptr_t>(decoder.get()) + sizeof(Decoder));

	// Move the decoder into another object and deallocate the original object.
	Decoder decoder2(std::move(*decoder));
	decoder.reset();

	// Check that the contents got moved correctly.
	EXPECT_EQ(decoder2.Get(1).as_int32(), 10);
	ASSERT_GE(reinterpret_cast<uintptr_t>(&decoder2.at<1>()),
	reinterpret_cast<uintptr_t>(&decoder2));
	ASSERT_LT(reinterpret_cast<uintptr_t>(&decoder2.at<1>()),
	reinterpret_cast<uintptr_t>(&decoder2) + sizeof(Decoder));
	}

	TEST(ProtoDecoderTest, PackedRepeatedVarint) {
	std::vector<int32_t> values = {42, 255, 0, -1};

	// serialize using protobuf library
	pbgold::PackedRepeatedFields msg;
	for (auto v : values)
	msg.add_field_int32(v);
	std::string serialized = msg.SerializeAsString();

	// decode using TypedProtoDecoder directly
	{
	constexpr int kFieldId =
	pbtest::PackedRepeatedFields::kFieldInt32FieldNumber;
	TypedProtoDecoder<kFieldId, false> decoder(
	reinterpret_cast<const uint8_t*>(serialized.data()), serialized.size());
	ASSERT_TRUE(decoder.at<kFieldId>().valid());
	bool parse_error = false;
	auto packed_it =
	decoder.GetPackedRepeated<proto_utils::ProtoWireType::kVarInt, int32_t>(
	kFieldId, &parse_error);

	std::vector<int32_t> decoded_values;
	for (; packed_it; ++packed_it) {
	auto v = *packed_it;
	decoded_values.push_back(v);
	}
	ASSERT_EQ(values, decoded_values);
	ASSERT_FALSE(parse_error);
	}

	// decode using plugin-generated accessor
	{
	auto decoder = pbtest::PackedRepeatedFields::Decoder(serialized);
	ASSERT_TRUE(decoder.has_field_int32());

	bool parse_error = false;
	std::vector<int32_t> decoded_values;
	for (auto packed_it = decoder.field_int32(&parse_error); packed_it;
	++packed_it) {
	auto v = *packed_it;
	decoded_values.push_back(v);
	}
	ASSERT_EQ(values, decoded_values);
	ASSERT_FALSE(parse_error);
	}

	// unset field case
	pbgold::PackedRepeatedFields empty_msg;
	std::string empty_serialized = empty_msg.SerializeAsString();
	auto decoder = pbtest::PackedRepeatedFields::Decoder(empty_serialized);
	ASSERT_FALSE(decoder.has_field_int32());
	bool parse_error = false;
	auto packed_it = decoder.field_int32(&parse_error);
	ASSERT_FALSE(bool(packed_it));
	ASSERT_FALSE(parse_error);
	}

	TEST(ProtoDecoderTest, PackedRepeatedFixed32) {
	std::vector<uint32_t> values = {42, 255, 0, 1};

	// serialize using protobuf library
	pbgold::PackedRepeatedFields msg;
	for (auto v : values)
	msg.add_field_fixed32(v);
	std::string serialized = msg.SerializeAsString();

	// decode using TypedProtoDecoder directly
	{
	constexpr int kFieldId =
	pbtest::PackedRepeatedFields::kFieldFixed32FieldNumber;
	TypedProtoDecoder<kFieldId, false> decoder(
	reinterpret_cast<const uint8_t*>(serialized.data()), serialized.size());
	bool parse_error = false;
	auto packed_it =
	decoder
	.GetPackedRepeated<proto_utils::ProtoWireType::kFixed32, uint32_t>(
	kFieldId, &parse_error);

	std::vector<uint32_t> decoded_values;
	for (; packed_it; ++packed_it) {
	auto v = *packed_it;
	decoded_values.push_back(v);
	}
	ASSERT_EQ(values, decoded_values);
	ASSERT_FALSE(parse_error);
	}

	// decode using plugin-generated accessor
	{
	auto decoder = pbtest::PackedRepeatedFields::Decoder(serialized);
	ASSERT_TRUE(decoder.has_field_fixed32());

	bool parse_error = false;
	std::vector<uint32_t> decoded_values;
	for (auto packed_it = decoder.field_fixed32(&parse_error); packed_it;
	packed_it++) {
	auto v = *packed_it;
	decoded_values.push_back(v);
	}
	ASSERT_EQ(values, decoded_values);
	ASSERT_FALSE(parse_error);
	}

	// unset field case
	pbgold::PackedRepeatedFields empty_msg;
	std::string empty_serialized = empty_msg.SerializeAsString();
	auto decoder = pbtest::PackedRepeatedFields::Decoder(empty_serialized);
	ASSERT_FALSE(decoder.has_field_fixed32());
	bool parse_error = false;
	auto packed_it = decoder.field_fixed32(&parse_error);
	ASSERT_FALSE(bool(packed_it));
	ASSERT_FALSE(parse_error);
	}

	TEST(ProtoDecoderTest, PackedRepeatedFixed64) {
	std::vector<int64_t> values = {42, 255, 0, -1};

	// serialize using protobuf library
	pbgold::PackedRepeatedFields msg;
	for (auto v : values)
	msg.add_field_sfixed64(v);
	std::string serialized = msg.SerializeAsString();

	// decode using TypedProtoDecoder directly
	{
	constexpr int kFieldId =
	pbtest::PackedRepeatedFields::kFieldSfixed64FieldNumber;
	TypedProtoDecoder<kFieldId, false> decoder(
	reinterpret_cast<const uint8_t*>(serialized.data()), serialized.size());
	bool parse_error = false;
	auto packed_it =
	decoder
	.GetPackedRepeated<proto_utils::ProtoWireType::kFixed64, int64_t>(
	kFieldId, &parse_error);

	std::vector<int64_t> decoded_values;
	for (; packed_it; ++packed_it) {
	auto v = *packed_it;
	decoded_values.push_back(v);
	}
	ASSERT_EQ(values, decoded_values);
	ASSERT_FALSE(parse_error);
	}

	// decode using plugin-generated accessor
	{
	auto decoder = pbtest::PackedRepeatedFields::Decoder(serialized);
	ASSERT_TRUE(decoder.has_field_sfixed64());

	bool parse_error = false;
	std::vector<int64_t> decoded_values;
	for (auto packed_it = decoder.field_sfixed64(&parse_error); packed_it;
	packed_it++) {
	auto v = *packed_it;
	decoded_values.push_back(v);
	}
	ASSERT_EQ(values, decoded_values);
	ASSERT_FALSE(parse_error);
	}

	// unset field case
	pbgold::PackedRepeatedFields empty_msg;
	std::string empty_serialized = empty_msg.SerializeAsString();
	auto decoder = pbtest::PackedRepeatedFields::Decoder(empty_serialized);
	ASSERT_FALSE(decoder.has_field_sfixed64());
	bool parse_error = false;
	auto packed_it = decoder.field_sfixed64(&parse_error);
	ASSERT_FALSE(bool(packed_it));
	ASSERT_FALSE(parse_error);
	}

	TEST(ProtoDecoderTest, ZeroLengthPackedRepeatedField) {
	HeapBuffered<pbtest::PackedRepeatedFields> msg;
	PackedVarInt buf;
	msg->set_field_int32(buf);
	std::string serialized = msg.SerializeAsString();

	// Encoded as 2 bytes: tag/field, and a length of zero.
	EXPECT_EQ(2u, serialized.size());

	// Appears empty when decoded.
	auto decoder = pbtest::PackedRepeatedFields::Decoder(serialized);
	ASSERT_TRUE(decoder.has_field_int32());
	bool parse_error = false;
	auto packed_it = decoder.field_int32(&parse_error);
	ASSERT_FALSE(bool(packed_it));
	ASSERT_FALSE(parse_error);
	}

	TEST(ProtoDecoderTest, MalformedPackedFixedBuffer) {
	// Encode a fixed32 field where the length is not a multiple of 4 bytes.
	HeapBuffered<pbtest::PackedRepeatedFields> msg;
	PackedFixedSizeInt<uint32_t> buf;
	buf.Append(1);
	buf.Append(2);
	buf.Append(3);
	const uint8_t* data = buf.data();
	size_t size = buf.size();
	size_t invalid_size = size - 2;
	constexpr int kFieldId =
	pbtest::PackedRepeatedFields::kFieldFixed32FieldNumber;
	msg->AppendBytes(kFieldId, data, invalid_size);
	std::string serialized = msg.SerializeAsString();

	// Iterator indicates parse error.
	auto decoder = pbtest::PackedRepeatedFields::Decoder(serialized);
	ASSERT_TRUE(decoder.has_field_fixed32());
	bool parse_error = false;
	for (auto packed_it = decoder.field_fixed32(&parse_error); packed_it;
	packed_it++) {
	}
	ASSERT_TRUE(parse_error);
	}

	TEST(ProtoDecoderTest, MalformedPackedVarIntBuffer) {
	// Encode a varint field with the last varint chopped off partway.
	HeapBuffered<pbtest::PackedRepeatedFields> msg;
	PackedVarInt buf;
	buf.Append(1024);
	buf.Append(2048);
	buf.Append(4096);
	const uint8_t* data = buf.data();
	size_t size = buf.size();
	size_t invalid_size = size - 1;
	constexpr int kFieldId = pbtest::PackedRepeatedFields::kFieldInt32FieldNumber;
	msg->AppendBytes(kFieldId, data, invalid_size);
	std::string serialized = msg.SerializeAsString();

	// Iterator indicates parse error.
	auto decoder = pbtest::PackedRepeatedFields::Decoder(serialized);
	ASSERT_TRUE(decoder.has_field_int32());
	bool parse_error = false;
	for (auto packed_it = decoder.field_int32(&parse_error); packed_it;
	packed_it++) {
	}
	ASSERT_TRUE(parse_error);
	}

	// Tests that big field ids (> 0xffff) are just skipped but don't fail parsing.
	// This is a regression test for b/145339282 (DataSourceConfig.for_testing
	// having a very large ID == 268435455 until Android R).
	TEST(ProtoDecoderTest, SkipBigFieldIds) {
	HeapBuffered<Message> message;
	message->AppendVarInt(/field_id=/1, 11);
	message->AppendVarInt(/field_id=/1000000, 0); // Will be skipped
	message->AppendVarInt(/field_id=/65535, 99);
	message->AppendVarInt(/field_id=/268435455, 0); // Will be skipped
	message->AppendVarInt(/field_id=/2, 12);
	message->AppendVarInt(/field_id=/2000000, 0); // Will be skipped
	auto data = message.SerializeAsArray();

	// Check the iterator-based ProtoDecoder.
	{
	ProtoDecoder decoder(data.data(), data.size());
	Field field = decoder.ReadField();
	ASSERT_TRUE(field.valid());
	ASSERT_EQ(field.id(), 1u);
	ASSERT_EQ(field.as_int32(), 11);

	field = decoder.ReadField();
	ASSERT_TRUE(field.valid());
	ASSERT_EQ(field.id(), 65535u);
	ASSERT_EQ(field.as_int32(), 99);

	field = decoder.ReadField();
	ASSERT_TRUE(field.valid());
	ASSERT_EQ(field.id(), 2u);
	ASSERT_EQ(field.as_int32(), 12);

	field = decoder.ReadField();
	ASSERT_FALSE(field.valid());
	}

	// Test the one-shot-read TypedProtoDecoder.
	// Note: field 65535 will be also skipped because this TypedProtoDecoder has
	// a cap on MAX_FIELD_ID = 3.
	{
	TypedProtoDecoder<3, true> tpd(data.data(), data.size());
	EXPECT_EQ(tpd.Get(1).as_int32(), 11);
	EXPECT_EQ(tpd.Get(2).as_int32(), 12);
	}
	}

	// Edge case for SkipBigFieldIds, the message contains only one field with a
	// very big id. Test that we skip it and return an invalid field, instead of
	// geetting stuck in some loop.
	TEST(ProtoDecoderTest, OneBigFieldIdOnly) {
	HeapBuffered<Message> message;
	message->AppendVarInt(/field_id=/268435455, 0);
	auto data = message.SerializeAsArray();

	// Check the iterator-based ProtoDecoder.
	ProtoDecoder decoder(data.data(), data.size());
	Field field = decoder.ReadField();
	ASSERT_FALSE(field.valid());
	}

	} // namespace
	} // namespace protozero