| // Copyright 2013 The Chromium Authors. All rights reserved. |
| // Use of this source code is governed by a BSD-style license that can be |
| // found in the LICENSE file. |
| |
| #include "net/websockets/websocket_frame.h" |
| |
| #include <stdint.h> |
| #include <algorithm> |
| #include <vector> |
| |
| #include "base/macros.h" |
| #include "base/memory/aligned_memory.h" |
| #include "net/base/net_errors.h" |
| #include "testing/gtest/include/gtest/gtest.h" |
| |
| namespace net { |
| |
| namespace { |
| |
| TEST(WebSocketFrameHeaderTest, FrameLengths) { |
| struct TestCase { |
| const char* frame_header; |
| size_t frame_header_length; |
| uint64_t frame_length; |
| }; |
| static const TestCase kTests[] = { |
| { "\x81\x00", 2, UINT64_C(0) }, |
| { "\x81\x7D", 2, UINT64_C(125) }, |
| { "\x81\x7E\x00\x7E", 4, UINT64_C(126) }, |
| { "\x81\x7E\xFF\xFF", 4, UINT64_C(0xFFFF) }, |
| { "\x81\x7F\x00\x00\x00\x00\x00\x01\x00\x00", 10, UINT64_C(0x10000) }, |
| { "\x81\x7F\x7F\xFF\xFF\xFF\xFF\xFF\xFF\xFF", 10, |
| UINT64_C(0x7FFFFFFFFFFFFFFF) } |
| }; |
| static const int kNumTests = arraysize(kTests); |
| |
| for (int i = 0; i < kNumTests; ++i) { |
| WebSocketFrameHeader header(WebSocketFrameHeader::kOpCodeText); |
| header.final = true; |
| header.payload_length = kTests[i].frame_length; |
| |
| std::vector<char> expected_output( |
| kTests[i].frame_header, |
| kTests[i].frame_header + kTests[i].frame_header_length); |
| std::vector<char> output(expected_output.size()); |
| EXPECT_EQ(static_cast<int>(expected_output.size()), |
| WriteWebSocketFrameHeader( |
| header, NULL, &output.front(), output.size())); |
| EXPECT_EQ(expected_output, output); |
| } |
| } |
| |
| TEST(WebSocketFrameHeaderTest, FrameLengthsWithMasking) { |
| static const char kMaskingKey[] = "\xDE\xAD\xBE\xEF"; |
| static_assert( |
| arraysize(kMaskingKey) - 1 == WebSocketFrameHeader::kMaskingKeyLength, |
| "incorrect masking key size"); |
| |
| struct TestCase { |
| const char* frame_header; |
| size_t frame_header_length; |
| uint64_t frame_length; |
| }; |
| static const TestCase kTests[] = { |
| { "\x81\x80\xDE\xAD\xBE\xEF", 6, UINT64_C(0) }, |
| { "\x81\xFD\xDE\xAD\xBE\xEF", 6, UINT64_C(125) }, |
| { "\x81\xFE\x00\x7E\xDE\xAD\xBE\xEF", 8, UINT64_C(126) }, |
| { "\x81\xFE\xFF\xFF\xDE\xAD\xBE\xEF", 8, UINT64_C(0xFFFF) }, |
| { "\x81\xFF\x00\x00\x00\x00\x00\x01\x00\x00\xDE\xAD\xBE\xEF", 14, |
| UINT64_C(0x10000) }, |
| { "\x81\xFF\x7F\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xDE\xAD\xBE\xEF", 14, |
| UINT64_C(0x7FFFFFFFFFFFFFFF) } |
| }; |
| static const int kNumTests = arraysize(kTests); |
| |
| WebSocketMaskingKey masking_key; |
| std::copy(kMaskingKey, |
| kMaskingKey + WebSocketFrameHeader::kMaskingKeyLength, |
| masking_key.key); |
| |
| for (int i = 0; i < kNumTests; ++i) { |
| WebSocketFrameHeader header(WebSocketFrameHeader::kOpCodeText); |
| header.final = true; |
| header.masked = true; |
| header.payload_length = kTests[i].frame_length; |
| |
| std::vector<char> expected_output( |
| kTests[i].frame_header, |
| kTests[i].frame_header + kTests[i].frame_header_length); |
| std::vector<char> output(expected_output.size()); |
| EXPECT_EQ(static_cast<int>(expected_output.size()), |
| WriteWebSocketFrameHeader( |
| header, &masking_key, &output.front(), output.size())); |
| EXPECT_EQ(expected_output, output); |
| } |
| } |
| |
| TEST(WebSocketFrameHeaderTest, FrameOpCodes) { |
| struct TestCase { |
| const char* frame_header; |
| size_t frame_header_length; |
| WebSocketFrameHeader::OpCode opcode; |
| }; |
| static const TestCase kTests[] = { |
| { "\x80\x00", 2, WebSocketFrameHeader::kOpCodeContinuation }, |
| { "\x81\x00", 2, WebSocketFrameHeader::kOpCodeText }, |
| { "\x82\x00", 2, WebSocketFrameHeader::kOpCodeBinary }, |
| { "\x88\x00", 2, WebSocketFrameHeader::kOpCodeClose }, |
| { "\x89\x00", 2, WebSocketFrameHeader::kOpCodePing }, |
| { "\x8A\x00", 2, WebSocketFrameHeader::kOpCodePong }, |
| // These are undefined opcodes, but the builder should accept them anyway. |
| { "\x83\x00", 2, 0x3 }, |
| { "\x84\x00", 2, 0x4 }, |
| { "\x85\x00", 2, 0x5 }, |
| { "\x86\x00", 2, 0x6 }, |
| { "\x87\x00", 2, 0x7 }, |
| { "\x8B\x00", 2, 0xB }, |
| { "\x8C\x00", 2, 0xC }, |
| { "\x8D\x00", 2, 0xD }, |
| { "\x8E\x00", 2, 0xE }, |
| { "\x8F\x00", 2, 0xF } |
| }; |
| static const int kNumTests = arraysize(kTests); |
| |
| for (int i = 0; i < kNumTests; ++i) { |
| WebSocketFrameHeader header(kTests[i].opcode); |
| header.final = true; |
| header.payload_length = 0; |
| |
| std::vector<char> expected_output( |
| kTests[i].frame_header, |
| kTests[i].frame_header + kTests[i].frame_header_length); |
| std::vector<char> output(expected_output.size()); |
| EXPECT_EQ(static_cast<int>(expected_output.size()), |
| WriteWebSocketFrameHeader( |
| header, NULL, &output.front(), output.size())); |
| EXPECT_EQ(expected_output, output); |
| } |
| } |
| |
| TEST(WebSocketFrameHeaderTest, FinalBitAndReservedBits) { |
| struct TestCase { |
| const char* frame_header; |
| size_t frame_header_length; |
| bool final; |
| bool reserved1; |
| bool reserved2; |
| bool reserved3; |
| }; |
| static const TestCase kTests[] = { |
| { "\x81\x00", 2, true, false, false, false }, |
| { "\x01\x00", 2, false, false, false, false }, |
| { "\xC1\x00", 2, true, true, false, false }, |
| { "\xA1\x00", 2, true, false, true, false }, |
| { "\x91\x00", 2, true, false, false, true }, |
| { "\x71\x00", 2, false, true, true, true }, |
| { "\xF1\x00", 2, true, true, true, true } |
| }; |
| static const int kNumTests = arraysize(kTests); |
| |
| for (int i = 0; i < kNumTests; ++i) { |
| WebSocketFrameHeader header(WebSocketFrameHeader::kOpCodeText); |
| header.final = kTests[i].final; |
| header.reserved1 = kTests[i].reserved1; |
| header.reserved2 = kTests[i].reserved2; |
| header.reserved3 = kTests[i].reserved3; |
| header.payload_length = 0; |
| |
| std::vector<char> expected_output( |
| kTests[i].frame_header, |
| kTests[i].frame_header + kTests[i].frame_header_length); |
| std::vector<char> output(expected_output.size()); |
| EXPECT_EQ(static_cast<int>(expected_output.size()), |
| WriteWebSocketFrameHeader( |
| header, NULL, &output.front(), output.size())); |
| EXPECT_EQ(expected_output, output); |
| } |
| } |
| |
| TEST(WebSocketFrameHeaderTest, InsufficientBufferSize) { |
| struct TestCase { |
| uint64_t payload_length; |
| bool masked; |
| size_t expected_header_size; |
| }; |
| static const TestCase kTests[] = { |
| { UINT64_C(0), false, 2u }, |
| { UINT64_C(125), false, 2u }, |
| { UINT64_C(126), false, 4u }, |
| { UINT64_C(0xFFFF), false, 4u }, |
| { UINT64_C(0x10000), false, 10u }, |
| { UINT64_C(0x7FFFFFFFFFFFFFFF), false, 10u }, |
| { UINT64_C(0), true, 6u }, |
| { UINT64_C(125), true, 6u }, |
| { UINT64_C(126), true, 8u }, |
| { UINT64_C(0xFFFF), true, 8u }, |
| { UINT64_C(0x10000), true, 14u }, |
| { UINT64_C(0x7FFFFFFFFFFFFFFF), true, 14u } |
| }; |
| static const int kNumTests = arraysize(kTests); |
| |
| for (int i = 0; i < kNumTests; ++i) { |
| WebSocketFrameHeader header(WebSocketFrameHeader::kOpCodeText); |
| header.final = true; |
| header.opcode = WebSocketFrameHeader::kOpCodeText; |
| header.masked = kTests[i].masked; |
| header.payload_length = kTests[i].payload_length; |
| |
| char dummy_buffer[14]; |
| // Set an insufficient size to |buffer_size|. |
| EXPECT_EQ( |
| ERR_INVALID_ARGUMENT, |
| WriteWebSocketFrameHeader( |
| header, NULL, dummy_buffer, kTests[i].expected_header_size - 1)); |
| } |
| } |
| |
| TEST(WebSocketFrameTest, MaskPayload) { |
| struct TestCase { |
| const char* masking_key; |
| uint64_t frame_offset; |
| const char* input; |
| const char* output; |
| size_t data_length; |
| }; |
| static const TestCase kTests[] = { |
| { "\xDE\xAD\xBE\xEF", 0, "FooBar", "\x98\xC2\xD1\xAD\xBF\xDF", 6 }, |
| { "\xDE\xAD\xBE\xEF", 1, "FooBar", "\xEB\xD1\x80\x9C\xCC\xCC", 6 }, |
| { "\xDE\xAD\xBE\xEF", 2, "FooBar", "\xF8\x80\xB1\xEF\xDF\x9D", 6 }, |
| { "\xDE\xAD\xBE\xEF", 3, "FooBar", "\xA9\xB1\xC2\xFC\x8E\xAC", 6 }, |
| { "\xDE\xAD\xBE\xEF", 4, "FooBar", "\x98\xC2\xD1\xAD\xBF\xDF", 6 }, |
| { "\xDE\xAD\xBE\xEF", 42, "FooBar", "\xF8\x80\xB1\xEF\xDF\x9D", 6 }, |
| { "\xDE\xAD\xBE\xEF", 0, "", "", 0 }, |
| { "\xDE\xAD\xBE\xEF", 0, "\xDE\xAD\xBE\xEF", "\x00\x00\x00\x00", 4 }, |
| { "\xDE\xAD\xBE\xEF", 0, "\x00\x00\x00\x00", "\xDE\xAD\xBE\xEF", 4 }, |
| { "\x00\x00\x00\x00", 0, "FooBar", "FooBar", 6 }, |
| { "\xFF\xFF\xFF\xFF", 0, "FooBar", "\xB9\x90\x90\xBD\x9E\x8D", 6 }, |
| }; |
| static const int kNumTests = arraysize(kTests); |
| |
| for (int i = 0; i < kNumTests; ++i) { |
| WebSocketMaskingKey masking_key; |
| std::copy(kTests[i].masking_key, |
| kTests[i].masking_key + WebSocketFrameHeader::kMaskingKeyLength, |
| masking_key.key); |
| std::vector<char> frame_data(kTests[i].input, |
| kTests[i].input + kTests[i].data_length); |
| std::vector<char> expected_output(kTests[i].output, |
| kTests[i].output + kTests[i].data_length); |
| MaskWebSocketFramePayload(masking_key, |
| kTests[i].frame_offset, |
| frame_data.empty() ? NULL : &frame_data.front(), |
| frame_data.size()); |
| EXPECT_EQ(expected_output, frame_data); |
| } |
| } |
| |
| // Check that all combinations of alignment, frame offset and chunk size work |
| // correctly for MaskWebSocketFramePayload(). This is mainly used to ensure that |
| // vectorisation optimisations don't break anything. We could take a "white box" |
| // approach and only test the edge cases, but since the exhaustive "black box" |
| // approach runs in acceptable time, we don't have to take the risk of being |
| // clever. |
| // |
| // This brute-force approach runs in O(N^3) time where N is the size of the |
| // maximum vector size we want to test again. This might need reconsidering if |
| // MaskWebSocketFramePayload() is ever optimised for a dedicated vector |
| // architecture. |
| TEST(WebSocketFrameTest, MaskPayloadAlignment) { |
| // This reflects what might be implemented in the future, rather than |
| // the current implementation. FMA3 and FMA4 support 256-bit vector ops. |
| static const size_t kMaxVectorSizeInBits = 256; |
| static const size_t kMaxVectorSize = kMaxVectorSizeInBits / 8; |
| static const size_t kMaxVectorAlignment = kMaxVectorSize; |
| static const size_t kMaskingKeyLength = |
| WebSocketFrameHeader::kMaskingKeyLength; |
| static const size_t kScratchBufferSize = |
| kMaxVectorAlignment + kMaxVectorSize * 2; |
| static const char kTestMask[] = "\xd2\xba\x5a\xbe"; |
| // We use 786 bits of random input to reduce the risk of correlated errors. |
| static const char kTestInput[] = { |
| "\x3d\x77\x1d\x1b\x19\x8c\x48\xa3\x19\x6d\xf7\xcc\x39\xe7\x57\x0b" |
| "\x69\x8c\xda\x4b\xfc\xac\x2c\xd3\x49\x96\x6e\x8a\x7b\x5a\x32\x76" |
| "\xd0\x11\x43\xa0\x89\xfc\x76\x2b\x10\x2f\x4c\x7b\x4f\xa6\xdd\xe4" |
| "\xfc\x8e\xd8\x72\xcf\x7e\x37\xcd\x31\xcd\xc1\xc0\x89\x0c\xa7\x4c" |
| "\xda\xa8\x4b\x75\xa1\xcb\xa9\x77\x19\x4d\x6e\xdf\xc8\x08\x1c\xb6" |
| "\x6d\xfb\x38\x04\x44\xd5\xba\x57\x9f\x76\xb0\x2e\x07\x91\xe6\xa8" |
| }; |
| static const size_t kTestInputSize = arraysize(kTestInput) - 1; |
| static const char kTestOutput[] = { |
| "\xef\xcd\x47\xa5\xcb\x36\x12\x1d\xcb\xd7\xad\x72\xeb\x5d\x0d\xb5" |
| "\xbb\x36\x80\xf5\x2e\x16\x76\x6d\x9b\x2c\x34\x34\xa9\xe0\x68\xc8" |
| "\x02\xab\x19\x1e\x5b\x46\x2c\x95\xc2\x95\x16\xc5\x9d\x1c\x87\x5a" |
| "\x2e\x34\x82\xcc\x1d\xc4\x6d\x73\xe3\x77\x9b\x7e\x5b\xb6\xfd\xf2" |
| "\x08\x12\x11\xcb\x73\x71\xf3\xc9\xcb\xf7\x34\x61\x1a\xb2\x46\x08" |
| "\xbf\x41\x62\xba\x96\x6f\xe0\xe9\x4d\xcc\xea\x90\xd5\x2b\xbc\x16" |
| }; |
| static_assert(arraysize(kTestInput) == arraysize(kTestOutput), |
| "output and input arrays should have the same length"); |
| std::unique_ptr<char, base::AlignedFreeDeleter> scratch(static_cast<char*>( |
| base::AlignedAlloc(kScratchBufferSize, kMaxVectorAlignment))); |
| WebSocketMaskingKey masking_key; |
| std::copy(kTestMask, kTestMask + kMaskingKeyLength, masking_key.key); |
| for (size_t frame_offset = 0; frame_offset < kMaskingKeyLength; |
| ++frame_offset) { |
| for (size_t alignment = 0; alignment < kMaxVectorAlignment; ++alignment) { |
| char* const aligned_scratch = scratch.get() + alignment; |
| const size_t aligned_len = std::min(kScratchBufferSize - alignment, |
| kTestInputSize - frame_offset); |
| for (size_t chunk_size = 1; chunk_size < kMaxVectorSize; ++chunk_size) { |
| memcpy(aligned_scratch, kTestInput + frame_offset, aligned_len); |
| for (size_t chunk_start = 0; chunk_start < aligned_len; |
| chunk_start += chunk_size) { |
| const size_t this_chunk_size = |
| std::min(chunk_size, aligned_len - chunk_start); |
| MaskWebSocketFramePayload(masking_key, |
| frame_offset + chunk_start, |
| aligned_scratch + chunk_start, |
| this_chunk_size); |
| } |
| // Stop the test if it fails, since we don't want to spew thousands of |
| // failures. |
| ASSERT_TRUE(std::equal(aligned_scratch, |
| aligned_scratch + aligned_len, |
| kTestOutput + frame_offset)) |
| << "Output failed to match for frame_offset=" << frame_offset |
| << ", alignment=" << alignment << ", chunk_size=" << chunk_size; |
| } |
| } |
| } |
| } |
| |
| // "IsKnownDataOpCode" is currently implemented in an "obviously correct" |
| // manner, but we test is anyway in case it changes to a more complex |
| // implementation in future. |
| TEST(WebSocketFrameHeaderTest, IsKnownDataOpCode) { |
| // Make the test less verbose. |
| typedef WebSocketFrameHeader Frame; |
| |
| // Known opcode, is used for data frames |
| EXPECT_TRUE(Frame::IsKnownDataOpCode(Frame::kOpCodeContinuation)); |
| EXPECT_TRUE(Frame::IsKnownDataOpCode(Frame::kOpCodeText)); |
| EXPECT_TRUE(Frame::IsKnownDataOpCode(Frame::kOpCodeBinary)); |
| |
| // Known opcode, is used for control frames |
| EXPECT_FALSE(Frame::IsKnownDataOpCode(Frame::kOpCodeClose)); |
| EXPECT_FALSE(Frame::IsKnownDataOpCode(Frame::kOpCodePing)); |
| EXPECT_FALSE(Frame::IsKnownDataOpCode(Frame::kOpCodePong)); |
| |
| // Check that unused opcodes return false |
| EXPECT_FALSE(Frame::IsKnownDataOpCode(Frame::kOpCodeDataUnused)); |
| EXPECT_FALSE(Frame::IsKnownDataOpCode(Frame::kOpCodeControlUnused)); |
| |
| // Check that opcodes with the 4 bit set return false |
| EXPECT_FALSE(Frame::IsKnownDataOpCode(0x6)); |
| EXPECT_FALSE(Frame::IsKnownDataOpCode(0xF)); |
| |
| // Check that out-of-range opcodes return false |
| EXPECT_FALSE(Frame::IsKnownDataOpCode(-1)); |
| EXPECT_FALSE(Frame::IsKnownDataOpCode(0xFF)); |
| } |
| |
| // "IsKnownControlOpCode" is implemented in an "obviously correct" manner but |
| // might be optimised in future. |
| TEST(WebSocketFrameHeaderTest, IsKnownControlOpCode) { |
| // Make the test less verbose. |
| typedef WebSocketFrameHeader Frame; |
| |
| // Known opcode, is used for data frames |
| EXPECT_FALSE(Frame::IsKnownControlOpCode(Frame::kOpCodeContinuation)); |
| EXPECT_FALSE(Frame::IsKnownControlOpCode(Frame::kOpCodeText)); |
| EXPECT_FALSE(Frame::IsKnownControlOpCode(Frame::kOpCodeBinary)); |
| |
| // Known opcode, is used for control frames |
| EXPECT_TRUE(Frame::IsKnownControlOpCode(Frame::kOpCodeClose)); |
| EXPECT_TRUE(Frame::IsKnownControlOpCode(Frame::kOpCodePing)); |
| EXPECT_TRUE(Frame::IsKnownControlOpCode(Frame::kOpCodePong)); |
| |
| // Check that unused opcodes return false |
| EXPECT_FALSE(Frame::IsKnownControlOpCode(Frame::kOpCodeDataUnused)); |
| EXPECT_FALSE(Frame::IsKnownControlOpCode(Frame::kOpCodeControlUnused)); |
| |
| // Check that opcodes with the 4 bit set return false |
| EXPECT_FALSE(Frame::IsKnownControlOpCode(0x6)); |
| EXPECT_FALSE(Frame::IsKnownControlOpCode(0xF)); |
| |
| // Check that out-of-range opcodes return false |
| EXPECT_FALSE(Frame::IsKnownControlOpCode(-1)); |
| EXPECT_FALSE(Frame::IsKnownControlOpCode(0xFF)); |
| } |
| |
| } // namespace |
| |
| } // namespace net |