| // Protocol Buffers - Google's data interchange format |
| // Copyright 2008 Google Inc. All rights reserved. |
| // https://developers.google.com/protocol-buffers/ |
| // |
| // Redistribution and use in source and binary forms, with or without |
| // modification, are permitted provided that the following conditions are |
| // met: |
| // |
| // * Redistributions of source code must retain the above copyright |
| // notice, this list of conditions and the following disclaimer. |
| // * Redistributions in binary form must reproduce the above |
| // copyright notice, this list of conditions and the following disclaimer |
| // in the documentation and/or other materials provided with the |
| // distribution. |
| // * Neither the name of Google Inc. nor the names of its |
| // contributors may be used to endorse or promote products derived from |
| // this software without specific prior written permission. |
| // |
| // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS |
| // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT |
| // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR |
| // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT |
| // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, |
| // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT |
| // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, |
| // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY |
| // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT |
| // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE |
| // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
| |
| // Author: kenton@google.com (Kenton Varda) |
| // Based on original Protocol Buffers design by |
| // Sanjay Ghemawat, Jeff Dean, and others. |
| // |
| // This file contains tests and benchmarks. |
| |
| #include <memory> |
| #ifndef _SHARED_PTR_H |
| #include <google/protobuf/stubs/shared_ptr.h> |
| #endif |
| #include <vector> |
| |
| #include <google/protobuf/io/coded_stream.h> |
| |
| #include <limits.h> |
| |
| #include <google/protobuf/stubs/common.h> |
| #include <google/protobuf/stubs/logging.h> |
| #include <google/protobuf/stubs/logging.h> |
| #include <google/protobuf/testing/googletest.h> |
| #include <gtest/gtest.h> |
| #include <google/protobuf/io/zero_copy_stream_impl.h> |
| |
| |
| // This declares an unsigned long long integer literal in a portable way. |
| // (The original macro is way too big and ruins my formatting.) |
| #undef ULL |
| #define ULL(x) GOOGLE_ULONGLONG(x) |
| |
| namespace google { |
| namespace protobuf { |
| namespace io { |
| namespace { |
| |
| // =================================================================== |
| // Data-Driven Test Infrastructure |
| |
| // TEST_1D and TEST_2D are macros I'd eventually like to see added to |
| // gTest. These macros can be used to declare tests which should be |
| // run multiple times, once for each item in some input array. TEST_1D |
| // tests all cases in a single input array. TEST_2D tests all |
| // combinations of cases from two arrays. The arrays must be statically |
| // defined such that the GOOGLE_ARRAYSIZE() macro works on them. Example: |
| // |
| // int kCases[] = {1, 2, 3, 4} |
| // TEST_1D(MyFixture, MyTest, kCases) { |
| // EXPECT_GT(kCases_case, 0); |
| // } |
| // |
| // This test iterates through the numbers 1, 2, 3, and 4 and tests that |
| // they are all grater than zero. In case of failure, the exact case |
| // which failed will be printed. The case type must be printable using |
| // ostream::operator<<. |
| |
| // TODO(kenton): gTest now supports "parameterized tests" which would be |
| // a better way to accomplish this. Rewrite when time permits. |
| |
| #define TEST_1D(FIXTURE, NAME, CASES) \ |
| class FIXTURE##_##NAME##_DD : public FIXTURE { \ |
| protected: \ |
| template <typename CaseType> \ |
| void DoSingleCase(const CaseType& CASES##_case); \ |
| }; \ |
| \ |
| TEST_F(FIXTURE##_##NAME##_DD, NAME) { \ |
| for (int i = 0; i < GOOGLE_ARRAYSIZE(CASES); i++) { \ |
| SCOPED_TRACE(testing::Message() \ |
| << #CASES " case #" << i << ": " << CASES[i]); \ |
| DoSingleCase(CASES[i]); \ |
| } \ |
| } \ |
| \ |
| template <typename CaseType> \ |
| void FIXTURE##_##NAME##_DD::DoSingleCase(const CaseType& CASES##_case) |
| |
| #define TEST_2D(FIXTURE, NAME, CASES1, CASES2) \ |
| class FIXTURE##_##NAME##_DD : public FIXTURE { \ |
| protected: \ |
| template <typename CaseType1, typename CaseType2> \ |
| void DoSingleCase(const CaseType1& CASES1##_case, \ |
| const CaseType2& CASES2##_case); \ |
| }; \ |
| \ |
| TEST_F(FIXTURE##_##NAME##_DD, NAME) { \ |
| for (int i = 0; i < GOOGLE_ARRAYSIZE(CASES1); i++) { \ |
| for (int j = 0; j < GOOGLE_ARRAYSIZE(CASES2); j++) { \ |
| SCOPED_TRACE(testing::Message() \ |
| << #CASES1 " case #" << i << ": " << CASES1[i] << ", " \ |
| << #CASES2 " case #" << j << ": " << CASES2[j]); \ |
| DoSingleCase(CASES1[i], CASES2[j]); \ |
| } \ |
| } \ |
| } \ |
| \ |
| template <typename CaseType1, typename CaseType2> \ |
| void FIXTURE##_##NAME##_DD::DoSingleCase(const CaseType1& CASES1##_case, \ |
| const CaseType2& CASES2##_case) |
| |
| // =================================================================== |
| |
| class CodedStreamTest : public testing::Test { |
| protected: |
| // Helper method used by tests for bytes warning. See implementation comment |
| // for further information. |
| static void SetupTotalBytesLimitWarningTest( |
| int total_bytes_limit, int warning_threshold, |
| vector<string>* out_errors, vector<string>* out_warnings); |
| |
| // Buffer used during most of the tests. This assumes tests run sequentially. |
| static const int kBufferSize = 1024 * 64; |
| static uint8 buffer_[kBufferSize]; |
| }; |
| |
| uint8 CodedStreamTest::buffer_[CodedStreamTest::kBufferSize]; |
| |
| // We test each operation over a variety of block sizes to insure that |
| // we test cases where reads or writes cross buffer boundaries, cases |
| // where they don't, and cases where there is so much buffer left that |
| // we can use special optimized paths that don't worry about bounds |
| // checks. |
| const int kBlockSizes[] = {1, 2, 3, 5, 7, 13, 32, 1024}; |
| |
| |
| // ------------------------------------------------------------------- |
| // Varint tests. |
| |
| struct VarintCase { |
| uint8 bytes[10]; // Encoded bytes. |
| int size; // Encoded size, in bytes. |
| uint64 value; // Parsed value. |
| }; |
| |
| inline std::ostream& operator<<(std::ostream& os, const VarintCase& c) { |
| return os << c.value; |
| } |
| |
| VarintCase kVarintCases[] = { |
| // 32-bit values |
| {{0x00} , 1, 0}, |
| {{0x01} , 1, 1}, |
| {{0x7f} , 1, 127}, |
| {{0xa2, 0x74}, 2, (0x22 << 0) | (0x74 << 7)}, // 14882 |
| {{0xbe, 0xf7, 0x92, 0x84, 0x0b}, 5, // 2961488830 |
| (0x3e << 0) | (0x77 << 7) | (0x12 << 14) | (0x04 << 21) | |
| (ULL(0x0b) << 28)}, |
| |
| // 64-bit |
| {{0xbe, 0xf7, 0x92, 0x84, 0x1b}, 5, // 7256456126 |
| (0x3e << 0) | (0x77 << 7) | (0x12 << 14) | (0x04 << 21) | |
| (ULL(0x1b) << 28)}, |
| {{0x80, 0xe6, 0xeb, 0x9c, 0xc3, 0xc9, 0xa4, 0x49}, 8, // 41256202580718336 |
| (0x00 << 0) | (0x66 << 7) | (0x6b << 14) | (0x1c << 21) | |
| (ULL(0x43) << 28) | (ULL(0x49) << 35) | (ULL(0x24) << 42) | |
| (ULL(0x49) << 49)}, |
| // 11964378330978735131 |
| {{0x9b, 0xa8, 0xf9, 0xc2, 0xbb, 0xd6, 0x80, 0x85, 0xa6, 0x01}, 10, |
| (0x1b << 0) | (0x28 << 7) | (0x79 << 14) | (0x42 << 21) | |
| (ULL(0x3b) << 28) | (ULL(0x56) << 35) | (ULL(0x00) << 42) | |
| (ULL(0x05) << 49) | (ULL(0x26) << 56) | (ULL(0x01) << 63)}, |
| }; |
| |
| TEST_2D(CodedStreamTest, ReadVarint32, kVarintCases, kBlockSizes) { |
| memcpy(buffer_, kVarintCases_case.bytes, kVarintCases_case.size); |
| ArrayInputStream input(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| uint32 value; |
| EXPECT_TRUE(coded_input.ReadVarint32(&value)); |
| EXPECT_EQ(static_cast<uint32>(kVarintCases_case.value), value); |
| } |
| |
| EXPECT_EQ(kVarintCases_case.size, input.ByteCount()); |
| } |
| |
| TEST_2D(CodedStreamTest, ReadTag, kVarintCases, kBlockSizes) { |
| memcpy(buffer_, kVarintCases_case.bytes, kVarintCases_case.size); |
| ArrayInputStream input(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| uint32 expected_value = static_cast<uint32>(kVarintCases_case.value); |
| EXPECT_EQ(expected_value, coded_input.ReadTag()); |
| |
| EXPECT_TRUE(coded_input.LastTagWas(expected_value)); |
| EXPECT_FALSE(coded_input.LastTagWas(expected_value + 1)); |
| } |
| |
| EXPECT_EQ(kVarintCases_case.size, input.ByteCount()); |
| } |
| |
| // This is the regression test that verifies that there is no issues |
| // with the empty input buffers handling. |
| TEST_F(CodedStreamTest, EmptyInputBeforeEos) { |
| class In : public ZeroCopyInputStream { |
| public: |
| In() : count_(0) {} |
| private: |
| virtual bool Next(const void** data, int* size) { |
| *data = NULL; |
| *size = 0; |
| return count_++ < 2; |
| } |
| virtual void BackUp(int count) { |
| GOOGLE_LOG(FATAL) << "Tests never call this."; |
| } |
| virtual bool Skip(int count) { |
| GOOGLE_LOG(FATAL) << "Tests never call this."; |
| return false; |
| } |
| virtual int64 ByteCount() const { return 0; } |
| int count_; |
| } in; |
| CodedInputStream input(&in); |
| input.ReadTag(); |
| EXPECT_TRUE(input.ConsumedEntireMessage()); |
| } |
| |
| TEST_1D(CodedStreamTest, ExpectTag, kVarintCases) { |
| // Leave one byte at the beginning of the buffer so we can read it |
| // to force the first buffer to be loaded. |
| buffer_[0] = '\0'; |
| memcpy(buffer_ + 1, kVarintCases_case.bytes, kVarintCases_case.size); |
| ArrayInputStream input(buffer_, sizeof(buffer_)); |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| // Read one byte to force coded_input.Refill() to be called. Otherwise, |
| // ExpectTag() will return a false negative. |
| uint8 dummy; |
| coded_input.ReadRaw(&dummy, 1); |
| EXPECT_EQ((uint)'\0', (uint)dummy); |
| |
| uint32 expected_value = static_cast<uint32>(kVarintCases_case.value); |
| |
| // ExpectTag() produces false negatives for large values. |
| if (kVarintCases_case.size <= 2) { |
| EXPECT_FALSE(coded_input.ExpectTag(expected_value + 1)); |
| EXPECT_TRUE(coded_input.ExpectTag(expected_value)); |
| } else { |
| EXPECT_FALSE(coded_input.ExpectTag(expected_value)); |
| } |
| } |
| |
| if (kVarintCases_case.size <= 2) { |
| EXPECT_EQ(kVarintCases_case.size + 1, input.ByteCount()); |
| } else { |
| EXPECT_EQ(1, input.ByteCount()); |
| } |
| } |
| |
| TEST_1D(CodedStreamTest, ExpectTagFromArray, kVarintCases) { |
| memcpy(buffer_, kVarintCases_case.bytes, kVarintCases_case.size); |
| |
| const uint32 expected_value = static_cast<uint32>(kVarintCases_case.value); |
| |
| // If the expectation succeeds, it should return a pointer past the tag. |
| if (kVarintCases_case.size <= 2) { |
| EXPECT_TRUE(NULL == |
| CodedInputStream::ExpectTagFromArray(buffer_, |
| expected_value + 1)); |
| EXPECT_TRUE(buffer_ + kVarintCases_case.size == |
| CodedInputStream::ExpectTagFromArray(buffer_, expected_value)); |
| } else { |
| EXPECT_TRUE(NULL == |
| CodedInputStream::ExpectTagFromArray(buffer_, expected_value)); |
| } |
| } |
| |
| TEST_2D(CodedStreamTest, ReadVarint64, kVarintCases, kBlockSizes) { |
| memcpy(buffer_, kVarintCases_case.bytes, kVarintCases_case.size); |
| ArrayInputStream input(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| uint64 value; |
| EXPECT_TRUE(coded_input.ReadVarint64(&value)); |
| EXPECT_EQ(kVarintCases_case.value, value); |
| } |
| |
| EXPECT_EQ(kVarintCases_case.size, input.ByteCount()); |
| } |
| |
| TEST_2D(CodedStreamTest, WriteVarint32, kVarintCases, kBlockSizes) { |
| if (kVarintCases_case.value > ULL(0x00000000FFFFFFFF)) { |
| // Skip this test for the 64-bit values. |
| return; |
| } |
| |
| ArrayOutputStream output(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedOutputStream coded_output(&output); |
| |
| coded_output.WriteVarint32(static_cast<uint32>(kVarintCases_case.value)); |
| EXPECT_FALSE(coded_output.HadError()); |
| |
| EXPECT_EQ(kVarintCases_case.size, coded_output.ByteCount()); |
| } |
| |
| EXPECT_EQ(kVarintCases_case.size, output.ByteCount()); |
| EXPECT_EQ(0, |
| memcmp(buffer_, kVarintCases_case.bytes, kVarintCases_case.size)); |
| } |
| |
| TEST_2D(CodedStreamTest, WriteVarint64, kVarintCases, kBlockSizes) { |
| ArrayOutputStream output(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedOutputStream coded_output(&output); |
| |
| coded_output.WriteVarint64(kVarintCases_case.value); |
| EXPECT_FALSE(coded_output.HadError()); |
| |
| EXPECT_EQ(kVarintCases_case.size, coded_output.ByteCount()); |
| } |
| |
| EXPECT_EQ(kVarintCases_case.size, output.ByteCount()); |
| EXPECT_EQ(0, |
| memcmp(buffer_, kVarintCases_case.bytes, kVarintCases_case.size)); |
| } |
| |
| // This test causes gcc 3.3.5 (and earlier?) to give the cryptic error: |
| // "sorry, unimplemented: `method_call_expr' not supported by dump_expr" |
| #if !defined(__GNUC__) || __GNUC__ > 3 || (__GNUC__ == 3 && __GNUC_MINOR__ > 3) |
| |
| int32 kSignExtendedVarintCases[] = { |
| 0, 1, -1, 1237894, -37895138 |
| }; |
| |
| TEST_2D(CodedStreamTest, WriteVarint32SignExtended, |
| kSignExtendedVarintCases, kBlockSizes) { |
| ArrayOutputStream output(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedOutputStream coded_output(&output); |
| |
| coded_output.WriteVarint32SignExtended(kSignExtendedVarintCases_case); |
| EXPECT_FALSE(coded_output.HadError()); |
| |
| if (kSignExtendedVarintCases_case < 0) { |
| EXPECT_EQ(10, coded_output.ByteCount()); |
| } else { |
| EXPECT_LE(coded_output.ByteCount(), 5); |
| } |
| } |
| |
| if (kSignExtendedVarintCases_case < 0) { |
| EXPECT_EQ(10, output.ByteCount()); |
| } else { |
| EXPECT_LE(output.ByteCount(), 5); |
| } |
| |
| // Read value back in as a varint64 and insure it matches. |
| ArrayInputStream input(buffer_, sizeof(buffer_)); |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| uint64 value; |
| EXPECT_TRUE(coded_input.ReadVarint64(&value)); |
| |
| EXPECT_EQ(kSignExtendedVarintCases_case, static_cast<int64>(value)); |
| } |
| |
| EXPECT_EQ(output.ByteCount(), input.ByteCount()); |
| } |
| |
| #endif |
| |
| |
| // ------------------------------------------------------------------- |
| // Varint failure test. |
| |
| struct VarintErrorCase { |
| uint8 bytes[12]; |
| int size; |
| bool can_parse; |
| }; |
| |
| inline std::ostream& operator<<(std::ostream& os, const VarintErrorCase& c) { |
| return os << "size " << c.size; |
| } |
| |
| const VarintErrorCase kVarintErrorCases[] = { |
| // Control case. (Insures that there isn't something else wrong that |
| // makes parsing always fail.) |
| {{0x00}, 1, true}, |
| |
| // No input data. |
| {{}, 0, false}, |
| |
| // Input ends unexpectedly. |
| {{0xf0, 0xab}, 2, false}, |
| |
| // Input ends unexpectedly after 32 bits. |
| {{0xf0, 0xab, 0xc9, 0x9a, 0xf8, 0xb2}, 6, false}, |
| |
| // Longer than 10 bytes. |
| {{0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0x01}, |
| 11, false}, |
| }; |
| |
| TEST_2D(CodedStreamTest, ReadVarint32Error, kVarintErrorCases, kBlockSizes) { |
| memcpy(buffer_, kVarintErrorCases_case.bytes, kVarintErrorCases_case.size); |
| ArrayInputStream input(buffer_, kVarintErrorCases_case.size, |
| kBlockSizes_case); |
| CodedInputStream coded_input(&input); |
| |
| uint32 value; |
| EXPECT_EQ(kVarintErrorCases_case.can_parse, coded_input.ReadVarint32(&value)); |
| } |
| |
| TEST_2D(CodedStreamTest, ReadVarint64Error, kVarintErrorCases, kBlockSizes) { |
| memcpy(buffer_, kVarintErrorCases_case.bytes, kVarintErrorCases_case.size); |
| ArrayInputStream input(buffer_, kVarintErrorCases_case.size, |
| kBlockSizes_case); |
| CodedInputStream coded_input(&input); |
| |
| uint64 value; |
| EXPECT_EQ(kVarintErrorCases_case.can_parse, coded_input.ReadVarint64(&value)); |
| } |
| |
| // ------------------------------------------------------------------- |
| // VarintSize |
| |
| struct VarintSizeCase { |
| uint64 value; |
| int size; |
| }; |
| |
| inline std::ostream& operator<<(std::ostream& os, const VarintSizeCase& c) { |
| return os << c.value; |
| } |
| |
| VarintSizeCase kVarintSizeCases[] = { |
| {0u, 1}, |
| {1u, 1}, |
| {127u, 1}, |
| {128u, 2}, |
| {758923u, 3}, |
| {4000000000u, 5}, |
| {ULL(41256202580718336), 8}, |
| {ULL(11964378330978735131), 10}, |
| }; |
| |
| TEST_1D(CodedStreamTest, VarintSize32, kVarintSizeCases) { |
| if (kVarintSizeCases_case.value > 0xffffffffu) { |
| // Skip 64-bit values. |
| return; |
| } |
| |
| EXPECT_EQ(kVarintSizeCases_case.size, |
| CodedOutputStream::VarintSize32( |
| static_cast<uint32>(kVarintSizeCases_case.value))); |
| } |
| |
| TEST_1D(CodedStreamTest, VarintSize64, kVarintSizeCases) { |
| EXPECT_EQ(kVarintSizeCases_case.size, |
| CodedOutputStream::VarintSize64(kVarintSizeCases_case.value)); |
| } |
| |
| // ------------------------------------------------------------------- |
| // Fixed-size int tests |
| |
| struct Fixed32Case { |
| uint8 bytes[sizeof(uint32)]; // Encoded bytes. |
| uint32 value; // Parsed value. |
| }; |
| |
| struct Fixed64Case { |
| uint8 bytes[sizeof(uint64)]; // Encoded bytes. |
| uint64 value; // Parsed value. |
| }; |
| |
| inline std::ostream& operator<<(std::ostream& os, const Fixed32Case& c) { |
| return os << "0x" << std::hex << c.value << std::dec; |
| } |
| |
| inline std::ostream& operator<<(std::ostream& os, const Fixed64Case& c) { |
| return os << "0x" << std::hex << c.value << std::dec; |
| } |
| |
| Fixed32Case kFixed32Cases[] = { |
| {{0xef, 0xcd, 0xab, 0x90}, 0x90abcdefu}, |
| {{0x12, 0x34, 0x56, 0x78}, 0x78563412u}, |
| }; |
| |
| Fixed64Case kFixed64Cases[] = { |
| {{0xef, 0xcd, 0xab, 0x90, 0x12, 0x34, 0x56, 0x78}, ULL(0x7856341290abcdef)}, |
| {{0x11, 0x22, 0x33, 0x44, 0x55, 0x66, 0x77, 0x88}, ULL(0x8877665544332211)}, |
| }; |
| |
| TEST_2D(CodedStreamTest, ReadLittleEndian32, kFixed32Cases, kBlockSizes) { |
| memcpy(buffer_, kFixed32Cases_case.bytes, sizeof(kFixed32Cases_case.bytes)); |
| ArrayInputStream input(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| uint32 value; |
| EXPECT_TRUE(coded_input.ReadLittleEndian32(&value)); |
| EXPECT_EQ(kFixed32Cases_case.value, value); |
| } |
| |
| EXPECT_EQ(sizeof(uint32), input.ByteCount()); |
| } |
| |
| TEST_2D(CodedStreamTest, ReadLittleEndian64, kFixed64Cases, kBlockSizes) { |
| memcpy(buffer_, kFixed64Cases_case.bytes, sizeof(kFixed64Cases_case.bytes)); |
| ArrayInputStream input(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| uint64 value; |
| EXPECT_TRUE(coded_input.ReadLittleEndian64(&value)); |
| EXPECT_EQ(kFixed64Cases_case.value, value); |
| } |
| |
| EXPECT_EQ(sizeof(uint64), input.ByteCount()); |
| } |
| |
| TEST_2D(CodedStreamTest, WriteLittleEndian32, kFixed32Cases, kBlockSizes) { |
| ArrayOutputStream output(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedOutputStream coded_output(&output); |
| |
| coded_output.WriteLittleEndian32(kFixed32Cases_case.value); |
| EXPECT_FALSE(coded_output.HadError()); |
| |
| EXPECT_EQ(sizeof(uint32), coded_output.ByteCount()); |
| } |
| |
| EXPECT_EQ(sizeof(uint32), output.ByteCount()); |
| EXPECT_EQ(0, memcmp(buffer_, kFixed32Cases_case.bytes, sizeof(uint32))); |
| } |
| |
| TEST_2D(CodedStreamTest, WriteLittleEndian64, kFixed64Cases, kBlockSizes) { |
| ArrayOutputStream output(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedOutputStream coded_output(&output); |
| |
| coded_output.WriteLittleEndian64(kFixed64Cases_case.value); |
| EXPECT_FALSE(coded_output.HadError()); |
| |
| EXPECT_EQ(sizeof(uint64), coded_output.ByteCount()); |
| } |
| |
| EXPECT_EQ(sizeof(uint64), output.ByteCount()); |
| EXPECT_EQ(0, memcmp(buffer_, kFixed64Cases_case.bytes, sizeof(uint64))); |
| } |
| |
| // Tests using the static methods to read fixed-size values from raw arrays. |
| |
| TEST_1D(CodedStreamTest, ReadLittleEndian32FromArray, kFixed32Cases) { |
| memcpy(buffer_, kFixed32Cases_case.bytes, sizeof(kFixed32Cases_case.bytes)); |
| |
| uint32 value; |
| const uint8* end = CodedInputStream::ReadLittleEndian32FromArray( |
| buffer_, &value); |
| EXPECT_EQ(kFixed32Cases_case.value, value); |
| EXPECT_TRUE(end == buffer_ + sizeof(value)); |
| } |
| |
| TEST_1D(CodedStreamTest, ReadLittleEndian64FromArray, kFixed64Cases) { |
| memcpy(buffer_, kFixed64Cases_case.bytes, sizeof(kFixed64Cases_case.bytes)); |
| |
| uint64 value; |
| const uint8* end = CodedInputStream::ReadLittleEndian64FromArray( |
| buffer_, &value); |
| EXPECT_EQ(kFixed64Cases_case.value, value); |
| EXPECT_TRUE(end == buffer_ + sizeof(value)); |
| } |
| |
| // ------------------------------------------------------------------- |
| // Raw reads and writes |
| |
| const char kRawBytes[] = "Some bytes which will be written and read raw."; |
| |
| TEST_1D(CodedStreamTest, ReadRaw, kBlockSizes) { |
| memcpy(buffer_, kRawBytes, sizeof(kRawBytes)); |
| ArrayInputStream input(buffer_, sizeof(buffer_), kBlockSizes_case); |
| char read_buffer[sizeof(kRawBytes)]; |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| EXPECT_TRUE(coded_input.ReadRaw(read_buffer, sizeof(kRawBytes))); |
| EXPECT_EQ(0, memcmp(kRawBytes, read_buffer, sizeof(kRawBytes))); |
| } |
| |
| EXPECT_EQ(sizeof(kRawBytes), input.ByteCount()); |
| } |
| |
| TEST_1D(CodedStreamTest, WriteRaw, kBlockSizes) { |
| ArrayOutputStream output(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedOutputStream coded_output(&output); |
| |
| coded_output.WriteRaw(kRawBytes, sizeof(kRawBytes)); |
| EXPECT_FALSE(coded_output.HadError()); |
| |
| EXPECT_EQ(sizeof(kRawBytes), coded_output.ByteCount()); |
| } |
| |
| EXPECT_EQ(sizeof(kRawBytes), output.ByteCount()); |
| EXPECT_EQ(0, memcmp(buffer_, kRawBytes, sizeof(kRawBytes))); |
| } |
| |
| TEST_1D(CodedStreamTest, ReadString, kBlockSizes) { |
| memcpy(buffer_, kRawBytes, sizeof(kRawBytes)); |
| ArrayInputStream input(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| string str; |
| EXPECT_TRUE(coded_input.ReadString(&str, strlen(kRawBytes))); |
| EXPECT_EQ(kRawBytes, str); |
| } |
| |
| EXPECT_EQ(strlen(kRawBytes), input.ByteCount()); |
| } |
| |
| // Check to make sure ReadString doesn't crash on impossibly large strings. |
| TEST_1D(CodedStreamTest, ReadStringImpossiblyLarge, kBlockSizes) { |
| ArrayInputStream input(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| string str; |
| // Try to read a gigabyte. |
| EXPECT_FALSE(coded_input.ReadString(&str, 1 << 30)); |
| } |
| } |
| |
| TEST_F(CodedStreamTest, ReadStringImpossiblyLargeFromStringOnStack) { |
| // Same test as above, except directly use a buffer. This used to cause |
| // crashes while the above did not. |
| uint8 buffer[8]; |
| CodedInputStream coded_input(buffer, 8); |
| string str; |
| EXPECT_FALSE(coded_input.ReadString(&str, 1 << 30)); |
| } |
| |
| TEST_F(CodedStreamTest, ReadStringImpossiblyLargeFromStringOnHeap) { |
| google::protobuf::scoped_array<uint8> buffer(new uint8[8]); |
| CodedInputStream coded_input(buffer.get(), 8); |
| string str; |
| EXPECT_FALSE(coded_input.ReadString(&str, 1 << 30)); |
| } |
| |
| TEST_1D(CodedStreamTest, ReadStringReservesMemoryOnTotalLimit, kBlockSizes) { |
| memcpy(buffer_, kRawBytes, sizeof(kRawBytes)); |
| ArrayInputStream input(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedInputStream coded_input(&input); |
| coded_input.SetTotalBytesLimit(sizeof(kRawBytes), sizeof(kRawBytes)); |
| EXPECT_EQ(sizeof(kRawBytes), coded_input.BytesUntilTotalBytesLimit()); |
| |
| string str; |
| EXPECT_TRUE(coded_input.ReadString(&str, strlen(kRawBytes))); |
| EXPECT_EQ(sizeof(kRawBytes) - strlen(kRawBytes), |
| coded_input.BytesUntilTotalBytesLimit()); |
| EXPECT_EQ(kRawBytes, str); |
| // TODO(liujisi): Replace with a more meaningful test (see cl/60966023). |
| EXPECT_GE(str.capacity(), strlen(kRawBytes)); |
| } |
| |
| EXPECT_EQ(strlen(kRawBytes), input.ByteCount()); |
| } |
| |
| TEST_1D(CodedStreamTest, ReadStringReservesMemoryOnPushedLimit, kBlockSizes) { |
| memcpy(buffer_, kRawBytes, sizeof(kRawBytes)); |
| ArrayInputStream input(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedInputStream coded_input(&input); |
| coded_input.PushLimit(sizeof(buffer_)); |
| |
| string str; |
| EXPECT_TRUE(coded_input.ReadString(&str, strlen(kRawBytes))); |
| EXPECT_EQ(kRawBytes, str); |
| // TODO(liujisi): Replace with a more meaningful test (see cl/60966023). |
| EXPECT_GE(str.capacity(), strlen(kRawBytes)); |
| } |
| |
| EXPECT_EQ(strlen(kRawBytes), input.ByteCount()); |
| } |
| |
| TEST_F(CodedStreamTest, ReadStringNoReservationIfLimitsNotSet) { |
| memcpy(buffer_, kRawBytes, sizeof(kRawBytes)); |
| // Buffer size in the input must be smaller than sizeof(kRawBytes), |
| // otherwise check against capacity will fail as ReadStringInline() |
| // will handle the reading and will reserve the memory as needed. |
| ArrayInputStream input(buffer_, sizeof(buffer_), 32); |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| string str; |
| EXPECT_TRUE(coded_input.ReadString(&str, strlen(kRawBytes))); |
| EXPECT_EQ(kRawBytes, str); |
| // Note: this check depends on string class implementation. It |
| // expects that string will allocate more than strlen(kRawBytes) |
| // if the content of kRawBytes is appended to string in small |
| // chunks. |
| // TODO(liujisi): Replace with a more meaningful test (see cl/60966023). |
| EXPECT_GE(str.capacity(), strlen(kRawBytes)); |
| } |
| |
| EXPECT_EQ(strlen(kRawBytes), input.ByteCount()); |
| } |
| |
| TEST_F(CodedStreamTest, ReadStringNoReservationSizeIsNegative) { |
| memcpy(buffer_, kRawBytes, sizeof(kRawBytes)); |
| // Buffer size in the input must be smaller than sizeof(kRawBytes), |
| // otherwise check against capacity will fail as ReadStringInline() |
| // will handle the reading and will reserve the memory as needed. |
| ArrayInputStream input(buffer_, sizeof(buffer_), 32); |
| |
| { |
| CodedInputStream coded_input(&input); |
| coded_input.PushLimit(sizeof(buffer_)); |
| |
| string str; |
| EXPECT_FALSE(coded_input.ReadString(&str, -1)); |
| // Note: this check depends on string class implementation. It |
| // expects that string will always allocate the same amount of |
| // memory for an empty string. |
| EXPECT_EQ(string().capacity(), str.capacity()); |
| } |
| } |
| |
| TEST_F(CodedStreamTest, ReadStringNoReservationSizeIsLarge) { |
| memcpy(buffer_, kRawBytes, sizeof(kRawBytes)); |
| // Buffer size in the input must be smaller than sizeof(kRawBytes), |
| // otherwise check against capacity will fail as ReadStringInline() |
| // will handle the reading and will reserve the memory as needed. |
| ArrayInputStream input(buffer_, sizeof(buffer_), 32); |
| |
| { |
| CodedInputStream coded_input(&input); |
| coded_input.PushLimit(sizeof(buffer_)); |
| |
| string str; |
| EXPECT_FALSE(coded_input.ReadString(&str, 1 << 30)); |
| EXPECT_GT(1 << 30, str.capacity()); |
| } |
| } |
| |
| TEST_F(CodedStreamTest, ReadStringNoReservationSizeIsOverTheLimit) { |
| memcpy(buffer_, kRawBytes, sizeof(kRawBytes)); |
| // Buffer size in the input must be smaller than sizeof(kRawBytes), |
| // otherwise check against capacity will fail as ReadStringInline() |
| // will handle the reading and will reserve the memory as needed. |
| ArrayInputStream input(buffer_, sizeof(buffer_), 32); |
| |
| { |
| CodedInputStream coded_input(&input); |
| coded_input.PushLimit(16); |
| |
| string str; |
| EXPECT_FALSE(coded_input.ReadString(&str, strlen(kRawBytes))); |
| // Note: this check depends on string class implementation. It |
| // expects that string will allocate less than strlen(kRawBytes) |
| // for an empty string. |
| EXPECT_GT(strlen(kRawBytes), str.capacity()); |
| } |
| } |
| |
| TEST_F(CodedStreamTest, ReadStringNoReservationSizeIsOverTheTotalBytesLimit) { |
| memcpy(buffer_, kRawBytes, sizeof(kRawBytes)); |
| // Buffer size in the input must be smaller than sizeof(kRawBytes), |
| // otherwise check against capacity will fail as ReadStringInline() |
| // will handle the reading and will reserve the memory as needed. |
| ArrayInputStream input(buffer_, sizeof(buffer_), 32); |
| |
| { |
| CodedInputStream coded_input(&input); |
| coded_input.SetTotalBytesLimit(16, 16); |
| |
| string str; |
| EXPECT_FALSE(coded_input.ReadString(&str, strlen(kRawBytes))); |
| // Note: this check depends on string class implementation. It |
| // expects that string will allocate less than strlen(kRawBytes) |
| // for an empty string. |
| EXPECT_GT(strlen(kRawBytes), str.capacity()); |
| } |
| } |
| |
| TEST_F(CodedStreamTest, |
| ReadStringNoReservationSizeIsOverTheClosestLimit_GlobalLimitIsCloser) { |
| memcpy(buffer_, kRawBytes, sizeof(kRawBytes)); |
| // Buffer size in the input must be smaller than sizeof(kRawBytes), |
| // otherwise check against capacity will fail as ReadStringInline() |
| // will handle the reading and will reserve the memory as needed. |
| ArrayInputStream input(buffer_, sizeof(buffer_), 32); |
| |
| { |
| CodedInputStream coded_input(&input); |
| coded_input.PushLimit(sizeof(buffer_)); |
| coded_input.SetTotalBytesLimit(16, 16); |
| |
| string str; |
| EXPECT_FALSE(coded_input.ReadString(&str, strlen(kRawBytes))); |
| // Note: this check depends on string class implementation. It |
| // expects that string will allocate less than strlen(kRawBytes) |
| // for an empty string. |
| EXPECT_GT(strlen(kRawBytes), str.capacity()); |
| } |
| } |
| |
| TEST_F(CodedStreamTest, |
| ReadStringNoReservationSizeIsOverTheClosestLimit_LocalLimitIsCloser) { |
| memcpy(buffer_, kRawBytes, sizeof(kRawBytes)); |
| // Buffer size in the input must be smaller than sizeof(kRawBytes), |
| // otherwise check against capacity will fail as ReadStringInline() |
| // will handle the reading and will reserve the memory as needed. |
| ArrayInputStream input(buffer_, sizeof(buffer_), 32); |
| |
| { |
| CodedInputStream coded_input(&input); |
| coded_input.PushLimit(16); |
| coded_input.SetTotalBytesLimit(sizeof(buffer_), sizeof(buffer_)); |
| EXPECT_EQ(sizeof(buffer_), coded_input.BytesUntilTotalBytesLimit()); |
| |
| string str; |
| EXPECT_FALSE(coded_input.ReadString(&str, strlen(kRawBytes))); |
| // Note: this check depends on string class implementation. It |
| // expects that string will allocate less than strlen(kRawBytes) |
| // for an empty string. |
| EXPECT_GT(strlen(kRawBytes), str.capacity()); |
| } |
| } |
| |
| |
| // ------------------------------------------------------------------- |
| // Skip |
| |
| const char kSkipTestBytes[] = |
| "<Before skipping><To be skipped><After skipping>"; |
| |
| TEST_1D(CodedStreamTest, SkipInput, kBlockSizes) { |
| memcpy(buffer_, kSkipTestBytes, sizeof(kSkipTestBytes)); |
| ArrayInputStream input(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| string str; |
| EXPECT_TRUE(coded_input.ReadString(&str, strlen("<Before skipping>"))); |
| EXPECT_EQ("<Before skipping>", str); |
| EXPECT_TRUE(coded_input.Skip(strlen("<To be skipped>"))); |
| EXPECT_TRUE(coded_input.ReadString(&str, strlen("<After skipping>"))); |
| EXPECT_EQ("<After skipping>", str); |
| } |
| |
| EXPECT_EQ(strlen(kSkipTestBytes), input.ByteCount()); |
| } |
| |
| // ------------------------------------------------------------------- |
| // GetDirectBufferPointer |
| |
| TEST_F(CodedStreamTest, GetDirectBufferPointerInput) { |
| ArrayInputStream input(buffer_, sizeof(buffer_), 8); |
| CodedInputStream coded_input(&input); |
| |
| const void* ptr; |
| int size; |
| |
| EXPECT_TRUE(coded_input.GetDirectBufferPointer(&ptr, &size)); |
| EXPECT_EQ(buffer_, ptr); |
| EXPECT_EQ(8, size); |
| |
| // Peeking again should return the same pointer. |
| EXPECT_TRUE(coded_input.GetDirectBufferPointer(&ptr, &size)); |
| EXPECT_EQ(buffer_, ptr); |
| EXPECT_EQ(8, size); |
| |
| // Skip forward in the same buffer then peek again. |
| EXPECT_TRUE(coded_input.Skip(3)); |
| EXPECT_TRUE(coded_input.GetDirectBufferPointer(&ptr, &size)); |
| EXPECT_EQ(buffer_ + 3, ptr); |
| EXPECT_EQ(5, size); |
| |
| // Skip to end of buffer and peek -- should get next buffer. |
| EXPECT_TRUE(coded_input.Skip(5)); |
| EXPECT_TRUE(coded_input.GetDirectBufferPointer(&ptr, &size)); |
| EXPECT_EQ(buffer_ + 8, ptr); |
| EXPECT_EQ(8, size); |
| } |
| |
| TEST_F(CodedStreamTest, GetDirectBufferPointerInlineInput) { |
| ArrayInputStream input(buffer_, sizeof(buffer_), 8); |
| CodedInputStream coded_input(&input); |
| |
| const void* ptr; |
| int size; |
| |
| coded_input.GetDirectBufferPointerInline(&ptr, &size); |
| EXPECT_EQ(buffer_, ptr); |
| EXPECT_EQ(8, size); |
| |
| // Peeking again should return the same pointer. |
| coded_input.GetDirectBufferPointerInline(&ptr, &size); |
| EXPECT_EQ(buffer_, ptr); |
| EXPECT_EQ(8, size); |
| |
| // Skip forward in the same buffer then peek again. |
| EXPECT_TRUE(coded_input.Skip(3)); |
| coded_input.GetDirectBufferPointerInline(&ptr, &size); |
| EXPECT_EQ(buffer_ + 3, ptr); |
| EXPECT_EQ(5, size); |
| |
| // Skip to end of buffer and peek -- should return false and provide an empty |
| // buffer. It does not try to Refresh(). |
| EXPECT_TRUE(coded_input.Skip(5)); |
| coded_input.GetDirectBufferPointerInline(&ptr, &size); |
| EXPECT_EQ(buffer_ + 8, ptr); |
| EXPECT_EQ(0, size); |
| } |
| |
| TEST_F(CodedStreamTest, GetDirectBufferPointerOutput) { |
| ArrayOutputStream output(buffer_, sizeof(buffer_), 8); |
| CodedOutputStream coded_output(&output); |
| |
| void* ptr; |
| int size; |
| |
| EXPECT_TRUE(coded_output.GetDirectBufferPointer(&ptr, &size)); |
| EXPECT_EQ(buffer_, ptr); |
| EXPECT_EQ(8, size); |
| |
| // Peeking again should return the same pointer. |
| EXPECT_TRUE(coded_output.GetDirectBufferPointer(&ptr, &size)); |
| EXPECT_EQ(buffer_, ptr); |
| EXPECT_EQ(8, size); |
| |
| // Skip forward in the same buffer then peek again. |
| EXPECT_TRUE(coded_output.Skip(3)); |
| EXPECT_TRUE(coded_output.GetDirectBufferPointer(&ptr, &size)); |
| EXPECT_EQ(buffer_ + 3, ptr); |
| EXPECT_EQ(5, size); |
| |
| // Skip to end of buffer and peek -- should get next buffer. |
| EXPECT_TRUE(coded_output.Skip(5)); |
| EXPECT_TRUE(coded_output.GetDirectBufferPointer(&ptr, &size)); |
| EXPECT_EQ(buffer_ + 8, ptr); |
| EXPECT_EQ(8, size); |
| |
| // Skip over multiple buffers. |
| EXPECT_TRUE(coded_output.Skip(22)); |
| EXPECT_TRUE(coded_output.GetDirectBufferPointer(&ptr, &size)); |
| EXPECT_EQ(buffer_ + 30, ptr); |
| EXPECT_EQ(2, size); |
| } |
| |
| // ------------------------------------------------------------------- |
| // Limits |
| |
| TEST_1D(CodedStreamTest, BasicLimit, kBlockSizes) { |
| ArrayInputStream input(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| EXPECT_EQ(-1, coded_input.BytesUntilLimit()); |
| CodedInputStream::Limit limit = coded_input.PushLimit(8); |
| |
| // Read until we hit the limit. |
| uint32 value; |
| EXPECT_EQ(8, coded_input.BytesUntilLimit()); |
| EXPECT_TRUE(coded_input.ReadLittleEndian32(&value)); |
| EXPECT_EQ(4, coded_input.BytesUntilLimit()); |
| EXPECT_TRUE(coded_input.ReadLittleEndian32(&value)); |
| EXPECT_EQ(0, coded_input.BytesUntilLimit()); |
| EXPECT_FALSE(coded_input.ReadLittleEndian32(&value)); |
| EXPECT_EQ(0, coded_input.BytesUntilLimit()); |
| |
| coded_input.PopLimit(limit); |
| |
| EXPECT_EQ(-1, coded_input.BytesUntilLimit()); |
| EXPECT_TRUE(coded_input.ReadLittleEndian32(&value)); |
| } |
| |
| EXPECT_EQ(12, input.ByteCount()); |
| } |
| |
| // Test what happens when we push two limits where the second (top) one is |
| // shorter. |
| TEST_1D(CodedStreamTest, SmallLimitOnTopOfBigLimit, kBlockSizes) { |
| ArrayInputStream input(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| EXPECT_EQ(-1, coded_input.BytesUntilLimit()); |
| CodedInputStream::Limit limit1 = coded_input.PushLimit(8); |
| EXPECT_EQ(8, coded_input.BytesUntilLimit()); |
| CodedInputStream::Limit limit2 = coded_input.PushLimit(4); |
| |
| uint32 value; |
| |
| // Read until we hit limit2, the top and shortest limit. |
| EXPECT_EQ(4, coded_input.BytesUntilLimit()); |
| EXPECT_TRUE(coded_input.ReadLittleEndian32(&value)); |
| EXPECT_EQ(0, coded_input.BytesUntilLimit()); |
| EXPECT_FALSE(coded_input.ReadLittleEndian32(&value)); |
| EXPECT_EQ(0, coded_input.BytesUntilLimit()); |
| |
| coded_input.PopLimit(limit2); |
| |
| // Read until we hit limit1. |
| EXPECT_EQ(4, coded_input.BytesUntilLimit()); |
| EXPECT_TRUE(coded_input.ReadLittleEndian32(&value)); |
| EXPECT_EQ(0, coded_input.BytesUntilLimit()); |
| EXPECT_FALSE(coded_input.ReadLittleEndian32(&value)); |
| EXPECT_EQ(0, coded_input.BytesUntilLimit()); |
| |
| coded_input.PopLimit(limit1); |
| |
| // No more limits. |
| EXPECT_EQ(-1, coded_input.BytesUntilLimit()); |
| EXPECT_TRUE(coded_input.ReadLittleEndian32(&value)); |
| } |
| |
| EXPECT_EQ(12, input.ByteCount()); |
| } |
| |
| // Test what happens when we push two limits where the second (top) one is |
| // longer. In this case, the top limit is shortened to match the previous |
| // limit. |
| TEST_1D(CodedStreamTest, BigLimitOnTopOfSmallLimit, kBlockSizes) { |
| ArrayInputStream input(buffer_, sizeof(buffer_), kBlockSizes_case); |
| |
| { |
| CodedInputStream coded_input(&input); |
| |
| EXPECT_EQ(-1, coded_input.BytesUntilLimit()); |
| CodedInputStream::Limit limit1 = coded_input.PushLimit(4); |
| EXPECT_EQ(4, coded_input.BytesUntilLimit()); |
| CodedInputStream::Limit limit2 = coded_input.PushLimit(8); |
| |
| uint32 value; |
| |
| // Read until we hit limit2. Except, wait! limit1 is shorter, so |
| // we end up hitting that first, despite having 4 bytes to go on |
| // limit2. |
| EXPECT_EQ(4, coded_input.BytesUntilLimit()); |
| EXPECT_TRUE(coded_input.ReadLittleEndian32(&value)); |
| EXPECT_EQ(0, coded_input.BytesUntilLimit()); |
| EXPECT_FALSE(coded_input.ReadLittleEndian32(&value)); |
| EXPECT_EQ(0, coded_input.BytesUntilLimit()); |
| |
| coded_input.PopLimit(limit2); |
| |
| // OK, popped limit2, now limit1 is on top, which we've already hit. |
| EXPECT_EQ(0, coded_input.BytesUntilLimit()); |
| EXPECT_FALSE(coded_input.ReadLittleEndian32(&value)); |
| EXPECT_EQ(0, coded_input.BytesUntilLimit()); |
| |
| coded_input.PopLimit(limit1); |
| |
| // No more limits. |
| EXPECT_EQ(-1, coded_input.BytesUntilLimit()); |
| EXPECT_TRUE(coded_input.ReadLittleEndian32(&value)); |
| } |
| |
| EXPECT_EQ(8, input.ByteCount()); |
| } |
| |
| TEST_F(CodedStreamTest, ExpectAtEnd) { |
| // Test ExpectAtEnd(), which is based on limits. |
| ArrayInputStream input(buffer_, sizeof(buffer_)); |
| CodedInputStream coded_input(&input); |
| |
| EXPECT_FALSE(coded_input.ExpectAtEnd()); |
| |
| CodedInputStream::Limit limit = coded_input.PushLimit(4); |
| |
| uint32 value; |
| EXPECT_TRUE(coded_input.ReadLittleEndian32(&value)); |
| EXPECT_TRUE(coded_input.ExpectAtEnd()); |
| |
| coded_input.PopLimit(limit); |
| EXPECT_FALSE(coded_input.ExpectAtEnd()); |
| } |
| |
| TEST_F(CodedStreamTest, NegativeLimit) { |
| // Check what happens when we push a negative limit. |
| ArrayInputStream input(buffer_, sizeof(buffer_)); |
| CodedInputStream coded_input(&input); |
| |
| CodedInputStream::Limit limit = coded_input.PushLimit(-1234); |
| // BytesUntilLimit() returns -1 to mean "no limit", which actually means |
| // "the limit is INT_MAX relative to the beginning of the stream". |
| EXPECT_EQ(-1, coded_input.BytesUntilLimit()); |
| coded_input.PopLimit(limit); |
| } |
| |
| TEST_F(CodedStreamTest, NegativeLimitAfterReading) { |
| // Check what happens when we push a negative limit. |
| ArrayInputStream input(buffer_, sizeof(buffer_)); |
| CodedInputStream coded_input(&input); |
| ASSERT_TRUE(coded_input.Skip(128)); |
| |
| CodedInputStream::Limit limit = coded_input.PushLimit(-64); |
| // BytesUntilLimit() returns -1 to mean "no limit", which actually means |
| // "the limit is INT_MAX relative to the beginning of the stream". |
| EXPECT_EQ(-1, coded_input.BytesUntilLimit()); |
| coded_input.PopLimit(limit); |
| } |
| |
| TEST_F(CodedStreamTest, OverflowLimit) { |
| // Check what happens when we push a limit large enough that its absolute |
| // position is more than 2GB into the stream. |
| ArrayInputStream input(buffer_, sizeof(buffer_)); |
| CodedInputStream coded_input(&input); |
| ASSERT_TRUE(coded_input.Skip(128)); |
| |
| CodedInputStream::Limit limit = coded_input.PushLimit(INT_MAX); |
| // BytesUntilLimit() returns -1 to mean "no limit", which actually means |
| // "the limit is INT_MAX relative to the beginning of the stream". |
| EXPECT_EQ(-1, coded_input.BytesUntilLimit()); |
| coded_input.PopLimit(limit); |
| } |
| |
| TEST_F(CodedStreamTest, TotalBytesLimit) { |
| ArrayInputStream input(buffer_, sizeof(buffer_)); |
| CodedInputStream coded_input(&input); |
| coded_input.SetTotalBytesLimit(16, -1); |
| EXPECT_EQ(16, coded_input.BytesUntilTotalBytesLimit()); |
| |
| string str; |
| EXPECT_TRUE(coded_input.ReadString(&str, 16)); |
| EXPECT_EQ(0, coded_input.BytesUntilTotalBytesLimit()); |
| |
| vector<string> errors; |
| |
| { |
| ScopedMemoryLog error_log; |
| EXPECT_FALSE(coded_input.ReadString(&str, 1)); |
| errors = error_log.GetMessages(ERROR); |
| } |
| |
| ASSERT_EQ(1, errors.size()); |
| EXPECT_PRED_FORMAT2(testing::IsSubstring, |
| "A protocol message was rejected because it was too big", errors[0]); |
| |
| coded_input.SetTotalBytesLimit(32, -1); |
| EXPECT_EQ(16, coded_input.BytesUntilTotalBytesLimit()); |
| EXPECT_TRUE(coded_input.ReadString(&str, 16)); |
| EXPECT_EQ(0, coded_input.BytesUntilTotalBytesLimit()); |
| } |
| |
| TEST_F(CodedStreamTest, TotalBytesLimitNotValidMessageEnd) { |
| // total_bytes_limit_ is not a valid place for a message to end. |
| |
| ArrayInputStream input(buffer_, sizeof(buffer_)); |
| CodedInputStream coded_input(&input); |
| |
| // Set both total_bytes_limit and a regular limit at 16 bytes. |
| coded_input.SetTotalBytesLimit(16, -1); |
| CodedInputStream::Limit limit = coded_input.PushLimit(16); |
| |
| // Read 16 bytes. |
| string str; |
| EXPECT_TRUE(coded_input.ReadString(&str, 16)); |
| |
| // Read a tag. Should fail, but report being a valid endpoint since it's |
| // a regular limit. |
| EXPECT_EQ(0, coded_input.ReadTag()); |
| EXPECT_TRUE(coded_input.ConsumedEntireMessage()); |
| |
| // Pop the limit. |
| coded_input.PopLimit(limit); |
| |
| // Read a tag. Should fail, and report *not* being a valid endpoint, since |
| // this time we're hitting the total bytes limit. |
| EXPECT_EQ(0, coded_input.ReadTag()); |
| EXPECT_FALSE(coded_input.ConsumedEntireMessage()); |
| } |
| |
| // This method is used by the tests below. |
| // It constructs a CodedInputStream with the given limits and tries to read 2KiB |
| // of data from it. Then it returns the logged errors and warnings in the given |
| // vectors. |
| void CodedStreamTest::SetupTotalBytesLimitWarningTest( |
| int total_bytes_limit, int warning_threshold, |
| vector<string>* out_errors, vector<string>* out_warnings) { |
| ArrayInputStream raw_input(buffer_, sizeof(buffer_), 128); |
| |
| ScopedMemoryLog scoped_log; |
| { |
| CodedInputStream input(&raw_input); |
| input.SetTotalBytesLimit(total_bytes_limit, warning_threshold); |
| string str; |
| EXPECT_TRUE(input.ReadString(&str, 2048)); |
| } |
| |
| *out_errors = scoped_log.GetMessages(ERROR); |
| *out_warnings = scoped_log.GetMessages(WARNING); |
| } |
| |
| TEST_F(CodedStreamTest, TotalBytesLimitWarning) { |
| vector<string> errors; |
| vector<string> warnings; |
| SetupTotalBytesLimitWarningTest(10240, 1024, &errors, &warnings); |
| |
| EXPECT_EQ(0, errors.size()); |
| |
| ASSERT_EQ(2, warnings.size()); |
| EXPECT_PRED_FORMAT2(testing::IsSubstring, |
| "Reading dangerously large protocol message. If the message turns out to " |
| "be larger than 10240 bytes, parsing will be halted for security reasons.", |
| warnings[0]); |
| EXPECT_PRED_FORMAT2(testing::IsSubstring, |
| "The total number of bytes read was 2048", |
| warnings[1]); |
| } |
| |
| TEST_F(CodedStreamTest, TotalBytesLimitWarningDisabled) { |
| vector<string> errors; |
| vector<string> warnings; |
| |
| // Test with -1 |
| SetupTotalBytesLimitWarningTest(10240, -1, &errors, &warnings); |
| EXPECT_EQ(0, errors.size()); |
| EXPECT_EQ(0, warnings.size()); |
| |
| // Test again with -2, expecting the same result |
| SetupTotalBytesLimitWarningTest(10240, -2, &errors, &warnings); |
| EXPECT_EQ(0, errors.size()); |
| EXPECT_EQ(0, warnings.size()); |
| } |
| |
| |
| TEST_F(CodedStreamTest, RecursionLimit) { |
| ArrayInputStream input(buffer_, sizeof(buffer_)); |
| CodedInputStream coded_input(&input); |
| coded_input.SetRecursionLimit(4); |
| |
| // This is way too much testing for a counter. |
| EXPECT_TRUE(coded_input.IncrementRecursionDepth()); // 1 |
| EXPECT_TRUE(coded_input.IncrementRecursionDepth()); // 2 |
| EXPECT_TRUE(coded_input.IncrementRecursionDepth()); // 3 |
| EXPECT_TRUE(coded_input.IncrementRecursionDepth()); // 4 |
| EXPECT_FALSE(coded_input.IncrementRecursionDepth()); // 5 |
| EXPECT_FALSE(coded_input.IncrementRecursionDepth()); // 6 |
| coded_input.DecrementRecursionDepth(); // 5 |
| EXPECT_FALSE(coded_input.IncrementRecursionDepth()); // 6 |
| coded_input.DecrementRecursionDepth(); // 5 |
| coded_input.DecrementRecursionDepth(); // 4 |
| coded_input.DecrementRecursionDepth(); // 3 |
| EXPECT_TRUE(coded_input.IncrementRecursionDepth()); // 4 |
| EXPECT_FALSE(coded_input.IncrementRecursionDepth()); // 5 |
| coded_input.DecrementRecursionDepth(); // 4 |
| coded_input.DecrementRecursionDepth(); // 3 |
| coded_input.DecrementRecursionDepth(); // 2 |
| coded_input.DecrementRecursionDepth(); // 1 |
| coded_input.DecrementRecursionDepth(); // 0 |
| coded_input.DecrementRecursionDepth(); // 0 |
| coded_input.DecrementRecursionDepth(); // 0 |
| EXPECT_TRUE(coded_input.IncrementRecursionDepth()); // 1 |
| EXPECT_TRUE(coded_input.IncrementRecursionDepth()); // 2 |
| EXPECT_TRUE(coded_input.IncrementRecursionDepth()); // 3 |
| EXPECT_TRUE(coded_input.IncrementRecursionDepth()); // 4 |
| EXPECT_FALSE(coded_input.IncrementRecursionDepth()); // 5 |
| |
| coded_input.SetRecursionLimit(6); |
| EXPECT_TRUE(coded_input.IncrementRecursionDepth()); // 6 |
| EXPECT_FALSE(coded_input.IncrementRecursionDepth()); // 7 |
| } |
| |
| |
| class ReallyBigInputStream : public ZeroCopyInputStream { |
| public: |
| ReallyBigInputStream() : backup_amount_(0), buffer_count_(0) {} |
| ~ReallyBigInputStream() {} |
| |
| // implements ZeroCopyInputStream ---------------------------------- |
| bool Next(const void** data, int* size) { |
| // We only expect BackUp() to be called at the end. |
| EXPECT_EQ(0, backup_amount_); |
| |
| switch (buffer_count_++) { |
| case 0: |
| *data = buffer_; |
| *size = sizeof(buffer_); |
| return true; |
| case 1: |
| // Return an enormously large buffer that, when combined with the 1k |
| // returned already, should overflow the total_bytes_read_ counter in |
| // CodedInputStream. Note that we'll only read the first 1024 bytes |
| // of this buffer so it's OK that we have it point at buffer_. |
| *data = buffer_; |
| *size = INT_MAX; |
| return true; |
| default: |
| return false; |
| } |
| } |
| |
| void BackUp(int count) { |
| backup_amount_ = count; |
| } |
| |
| bool Skip(int count) { GOOGLE_LOG(FATAL) << "Not implemented."; return false; } |
| int64 ByteCount() const { GOOGLE_LOG(FATAL) << "Not implemented."; return 0; } |
| |
| int backup_amount_; |
| |
| private: |
| char buffer_[1024]; |
| int64 buffer_count_; |
| }; |
| |
| TEST_F(CodedStreamTest, InputOver2G) { |
| // CodedInputStream should gracefully handle input over 2G and call |
| // input.BackUp() with the correct number of bytes on destruction. |
| ReallyBigInputStream input; |
| |
| vector<string> errors; |
| |
| { |
| ScopedMemoryLog error_log; |
| CodedInputStream coded_input(&input); |
| string str; |
| EXPECT_TRUE(coded_input.ReadString(&str, 512)); |
| EXPECT_TRUE(coded_input.ReadString(&str, 1024)); |
| errors = error_log.GetMessages(ERROR); |
| } |
| |
| EXPECT_EQ(INT_MAX - 512, input.backup_amount_); |
| EXPECT_EQ(0, errors.size()); |
| } |
| |
| // =================================================================== |
| |
| |
| } // namespace |
| } // namespace io |
| } // namespace protobuf |
| } // namespace google |