// 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_parser.h" #include #include #include #include "net/base/io_buffer.h" #include "testing/gtest/include/gtest/gtest.h" namespace net { namespace { const char kHello[] = "Hello, world!"; const uint64_t kHelloLength = arraysize(kHello) - 1; const char kHelloFrame[] = "\x81\x0DHello, world!"; const uint64_t kHelloFrameLength = arraysize(kHelloFrame) - 1; const char kMaskedHelloFrame[] = "\x81\x8D\xDE\xAD\xBE\xEF" "\x96\xC8\xD2\x83\xB1\x81\x9E\x98\xB1\xDF\xD2\x8B\xFF"; const uint64_t kMaskedHelloFrameLength = arraysize(kMaskedHelloFrame) - 1; struct FrameHeaderTestCase { const char* frame_header; size_t frame_header_length; uint64_t frame_length; WebSocketError error_code; }; const FrameHeaderTestCase kFrameHeaderTests[] = { { "\x81\x00", 2, UINT64_C(0), kWebSocketNormalClosure }, { "\x81\x7D", 2, UINT64_C(125), kWebSocketNormalClosure }, { "\x81\x7E\x00\x7E", 4, UINT64_C(126), kWebSocketNormalClosure }, { "\x81\x7E\xFF\xFF", 4, UINT64_C(0xFFFF), kWebSocketNormalClosure }, { "\x81\x7F\x00\x00\x00\x00\x00\x01\x00\x00", 10, UINT64_C(0x10000), kWebSocketNormalClosure }, { "\x81\x7F\x00\x00\x00\x00\x7F\xFF\xFF\xFF", 10, UINT64_C(0x7FFFFFFF), kWebSocketNormalClosure }, { "\x81\x7F\x00\x00\x00\x00\x80\x00\x00\x00", 10, UINT64_C(0x80000000), kWebSocketErrorMessageTooBig }, { "\x81\x7F\x7F\xFF\xFF\xFF\xFF\xFF\xFF\xFF", 10, UINT64_C(0x7FFFFFFFFFFFFFFF), kWebSocketErrorMessageTooBig } }; const int kNumFrameHeaderTests = arraysize(kFrameHeaderTests); TEST(WebSocketFrameParserTest, DecodeNormalFrame) { WebSocketFrameParser parser; std::vector> frames; EXPECT_TRUE(parser.Decode(kHelloFrame, kHelloFrameLength, &frames)); EXPECT_EQ(kWebSocketNormalClosure, parser.websocket_error()); ASSERT_EQ(1u, frames.size()); WebSocketFrameChunk* frame = frames[0].get(); ASSERT_TRUE(frame != NULL); const WebSocketFrameHeader* header = frame->header.get(); EXPECT_TRUE(header != NULL); if (header) { EXPECT_TRUE(header->final); EXPECT_FALSE(header->reserved1); EXPECT_FALSE(header->reserved2); EXPECT_FALSE(header->reserved3); EXPECT_EQ(WebSocketFrameHeader::kOpCodeText, header->opcode); EXPECT_FALSE(header->masked); EXPECT_EQ(kHelloLength, header->payload_length); } EXPECT_TRUE(frame->final_chunk); ASSERT_EQ(static_cast(kHelloLength), frame->data->size()); EXPECT_TRUE(std::equal(kHello, kHello + kHelloLength, frame->data->data())); } TEST(WebSocketFrameParserTest, DecodeMaskedFrame) { WebSocketFrameParser parser; std::vector> frames; EXPECT_TRUE( parser.Decode(kMaskedHelloFrame, kMaskedHelloFrameLength, &frames)); EXPECT_EQ(kWebSocketNormalClosure, parser.websocket_error()); ASSERT_EQ(1u, frames.size()); WebSocketFrameChunk* frame = frames[0].get(); ASSERT_TRUE(frame != NULL); const WebSocketFrameHeader* header = frame->header.get(); EXPECT_TRUE(header != NULL); if (header) { EXPECT_TRUE(header->final); EXPECT_FALSE(header->reserved1); EXPECT_FALSE(header->reserved2); EXPECT_FALSE(header->reserved3); EXPECT_EQ(WebSocketFrameHeader::kOpCodeText, header->opcode); EXPECT_TRUE(header->masked); EXPECT_EQ(kHelloLength, header->payload_length); } EXPECT_TRUE(frame->final_chunk); ASSERT_EQ(static_cast(kHelloLength), frame->data->size()); EXPECT_TRUE(std::equal(kHello, kHello + kHelloLength, frame->data->data())); } TEST(WebSocketFrameParserTest, DecodeManyFrames) { struct Input { const char* frame; size_t frame_length; const char* expected_payload; size_t expected_payload_length; }; static const Input kInputs[] = { // Each |frame| data is split into two string literals because C++ lexers // consume unlimited number of hex characters in a hex character escape // (e.g. "\x05F" is not treated as { '\x5', 'F', '\0' } but as // { '\x5F', '\0' }). { "\x81\x05" "First", 7, "First", 5 }, { "\x81\x06" "Second", 8, "Second", 6 }, { "\x81\x05" "Third", 7, "Third", 5 }, { "\x81\x06" "Fourth", 8, "Fourth", 6 }, { "\x81\x05" "Fifth", 7, "Fifth", 5 }, { "\x81\x05" "Sixth", 7, "Sixth", 5 }, { "\x81\x07" "Seventh", 9, "Seventh", 7 }, { "\x81\x06" "Eighth", 8, "Eighth", 6 }, { "\x81\x05" "Ninth", 7, "Ninth", 5 }, { "\x81\x05" "Tenth", 7, "Tenth", 5 } }; static const int kNumInputs = arraysize(kInputs); std::vector input; // Concatenate all frames. for (int i = 0; i < kNumInputs; ++i) { input.insert(input.end(), kInputs[i].frame, kInputs[i].frame + kInputs[i].frame_length); } WebSocketFrameParser parser; std::vector> frames; EXPECT_TRUE(parser.Decode(&input.front(), input.size(), &frames)); EXPECT_EQ(kWebSocketNormalClosure, parser.websocket_error()); ASSERT_EQ(static_cast(kNumInputs), frames.size()); for (int i = 0; i < kNumInputs; ++i) { WebSocketFrameChunk* frame = frames[i].get(); EXPECT_TRUE(frame != NULL); if (!frame) continue; EXPECT_TRUE(frame->final_chunk); ASSERT_EQ(kInputs[i].expected_payload_length, static_cast(frame->data->size())); EXPECT_TRUE(std::equal( kInputs[i].expected_payload, kInputs[i].expected_payload + kInputs[i].expected_payload_length, frame->data->data())); const WebSocketFrameHeader* header = frame->header.get(); EXPECT_TRUE(header != NULL); if (!header) continue; EXPECT_TRUE(header->final); EXPECT_FALSE(header->reserved1); EXPECT_FALSE(header->reserved2); EXPECT_FALSE(header->reserved3); EXPECT_EQ(WebSocketFrameHeader::kOpCodeText, header->opcode); EXPECT_FALSE(header->masked); EXPECT_EQ(kInputs[i].expected_payload_length, header->payload_length); } } TEST(WebSocketFrameParserTest, DecodePartialFrame) { static const size_t kFrameHeaderSize = 2; for (size_t cutting_pos = 0; cutting_pos < kHelloLength; ++cutting_pos) { std::vector input1(kHelloFrame, kHelloFrame + kFrameHeaderSize + cutting_pos); std::vector input2(kHelloFrame + input1.size(), kHelloFrame + kHelloFrameLength); std::vector expected1(kHello, kHello + cutting_pos); std::vector expected2(kHello + cutting_pos, kHello + kHelloLength); WebSocketFrameParser parser; std::vector> frames1; EXPECT_TRUE(parser.Decode(&input1.front(), input1.size(), &frames1)); EXPECT_EQ(kWebSocketNormalClosure, parser.websocket_error()); EXPECT_EQ(1u, frames1.size()); if (frames1.size() != 1u) continue; WebSocketFrameChunk* frame1 = frames1[0].get(); EXPECT_TRUE(frame1 != NULL); if (!frame1) continue; EXPECT_FALSE(frame1->final_chunk); if (expected1.size() == 0) { EXPECT_EQ(NULL, frame1->data.get()); } else { ASSERT_EQ(cutting_pos, static_cast(frame1->data->size())); EXPECT_TRUE( std::equal(expected1.begin(), expected1.end(), frame1->data->data())); } const WebSocketFrameHeader* header1 = frame1->header.get(); EXPECT_TRUE(header1 != NULL); if (!header1) continue; EXPECT_TRUE(header1->final); EXPECT_FALSE(header1->reserved1); EXPECT_FALSE(header1->reserved2); EXPECT_FALSE(header1->reserved3); EXPECT_EQ(WebSocketFrameHeader::kOpCodeText, header1->opcode); EXPECT_FALSE(header1->masked); EXPECT_EQ(kHelloLength, header1->payload_length); std::vector> frames2; EXPECT_TRUE(parser.Decode(&input2.front(), input2.size(), &frames2)); EXPECT_EQ(kWebSocketNormalClosure, parser.websocket_error()); EXPECT_EQ(1u, frames2.size()); if (frames2.size() != 1u) continue; WebSocketFrameChunk* frame2 = frames2[0].get(); EXPECT_TRUE(frame2 != NULL); if (!frame2) continue; EXPECT_TRUE(frame2->final_chunk); if (expected2.size() == 0) { EXPECT_EQ(NULL, frame2->data.get()); } else { ASSERT_EQ(expected2.size(), static_cast(frame2->data->size())); EXPECT_TRUE( std::equal(expected2.begin(), expected2.end(), frame2->data->data())); } const WebSocketFrameHeader* header2 = frame2->header.get(); EXPECT_TRUE(header2 == NULL); } } TEST(WebSocketFrameParserTest, DecodePartialMaskedFrame) { static const size_t kFrameHeaderSize = 6; for (size_t cutting_pos = 0; cutting_pos < kHelloLength; ++cutting_pos) { std::vector input1( kMaskedHelloFrame, kMaskedHelloFrame + kFrameHeaderSize + cutting_pos); std::vector input2(kMaskedHelloFrame + input1.size(), kMaskedHelloFrame + kMaskedHelloFrameLength); std::vector expected1(kHello, kHello + cutting_pos); std::vector expected2(kHello + cutting_pos, kHello + kHelloLength); WebSocketFrameParser parser; std::vector> frames1; EXPECT_TRUE(parser.Decode(&input1.front(), input1.size(), &frames1)); EXPECT_EQ(kWebSocketNormalClosure, parser.websocket_error()); EXPECT_EQ(1u, frames1.size()); if (frames1.size() != 1u) continue; WebSocketFrameChunk* frame1 = frames1[0].get(); EXPECT_TRUE(frame1 != NULL); if (!frame1) continue; EXPECT_FALSE(frame1->final_chunk); if (expected1.size() == 0) { EXPECT_EQ(NULL, frame1->data.get()); } else { ASSERT_EQ(expected1.size(), static_cast(frame1->data->size())); EXPECT_TRUE( std::equal(expected1.begin(), expected1.end(), frame1->data->data())); } const WebSocketFrameHeader* header1 = frame1->header.get(); EXPECT_TRUE(header1 != NULL); if (!header1) continue; EXPECT_TRUE(header1->final); EXPECT_FALSE(header1->reserved1); EXPECT_FALSE(header1->reserved2); EXPECT_FALSE(header1->reserved3); EXPECT_EQ(WebSocketFrameHeader::kOpCodeText, header1->opcode); EXPECT_TRUE(header1->masked); EXPECT_EQ(kHelloLength, header1->payload_length); std::vector> frames2; EXPECT_TRUE(parser.Decode(&input2.front(), input2.size(), &frames2)); EXPECT_EQ(kWebSocketNormalClosure, parser.websocket_error()); EXPECT_EQ(1u, frames2.size()); if (frames2.size() != 1u) continue; WebSocketFrameChunk* frame2 = frames2[0].get(); EXPECT_TRUE(frame2 != NULL); if (!frame2) continue; EXPECT_TRUE(frame2->final_chunk); if (expected2.size() == 0) { EXPECT_EQ(NULL, frame2->data.get()); } else { ASSERT_EQ(expected2.size(), static_cast(frame2->data->size())); EXPECT_TRUE( std::equal(expected2.begin(), expected2.end(), frame2->data->data())); } const WebSocketFrameHeader* header2 = frame2->header.get(); EXPECT_TRUE(header2 == NULL); } } TEST(WebSocketFrameParserTest, DecodeFramesOfVariousLengths) { for (int i = 0; i < kNumFrameHeaderTests; ++i) { const char* frame_header = kFrameHeaderTests[i].frame_header; size_t frame_header_length = kFrameHeaderTests[i].frame_header_length; uint64_t frame_length = kFrameHeaderTests[i].frame_length; std::vector input(frame_header, frame_header + frame_header_length); // Limit the payload size not to flood the console on failure. static const uint64_t kMaxPayloadSize = 200; uint64_t input_payload_size = std::min(frame_length, kMaxPayloadSize); input.insert(input.end(), input_payload_size, 'a'); WebSocketFrameParser parser; std::vector> frames; EXPECT_EQ(kFrameHeaderTests[i].error_code == kWebSocketNormalClosure, parser.Decode(&input.front(), input.size(), &frames)); EXPECT_EQ(kFrameHeaderTests[i].error_code, parser.websocket_error()); if (kFrameHeaderTests[i].error_code != kWebSocketNormalClosure) { EXPECT_EQ(0u, frames.size()); } else { EXPECT_EQ(1u, frames.size()); } if (frames.size() != 1u) continue; WebSocketFrameChunk* frame = frames[0].get(); EXPECT_TRUE(frame != NULL); if (!frame) continue; if (frame_length == input_payload_size) { EXPECT_TRUE(frame->final_chunk); } else { EXPECT_FALSE(frame->final_chunk); } std::vector expected_payload(input_payload_size, 'a'); if (expected_payload.size() == 0) { EXPECT_EQ(NULL, frame->data.get()); } else { ASSERT_EQ(expected_payload.size(), static_cast(frame->data->size())); EXPECT_TRUE(std::equal(expected_payload.begin(), expected_payload.end(), frame->data->data())); } const WebSocketFrameHeader* header = frame->header.get(); EXPECT_TRUE(header != NULL); if (!header) continue; EXPECT_TRUE(header->final); EXPECT_FALSE(header->reserved1); EXPECT_FALSE(header->reserved2); EXPECT_FALSE(header->reserved3); EXPECT_EQ(WebSocketFrameHeader::kOpCodeText, header->opcode); EXPECT_FALSE(header->masked); EXPECT_EQ(frame_length, header->payload_length); } } TEST(WebSocketFrameParserTest, DecodePartialHeader) { for (int i = 0; i < kNumFrameHeaderTests; ++i) { const char* frame_header = kFrameHeaderTests[i].frame_header; size_t frame_header_length = kFrameHeaderTests[i].frame_header_length; uint64_t frame_length = kFrameHeaderTests[i].frame_length; WebSocketFrameParser parser; std::vector> frames; // Feed each byte to the parser to see if the parser behaves correctly // when it receives partial frame header. size_t last_byte_offset = frame_header_length - 1; for (size_t j = 0; j < frame_header_length; ++j) { bool failed = kFrameHeaderTests[i].error_code != kWebSocketNormalClosure && j == last_byte_offset; EXPECT_EQ(!failed, parser.Decode(frame_header + j, 1, &frames)); if (failed) { EXPECT_EQ(kFrameHeaderTests[i].error_code, parser.websocket_error()); } else { EXPECT_EQ(kWebSocketNormalClosure, parser.websocket_error()); } if (kFrameHeaderTests[i].error_code == kWebSocketNormalClosure && j == last_byte_offset) { EXPECT_EQ(1u, frames.size()); } else { EXPECT_EQ(0u, frames.size()); } } if (frames.size() != 1u) continue; WebSocketFrameChunk* frame = frames[0].get(); EXPECT_TRUE(frame != NULL); if (!frame) continue; if (frame_length == 0u) { EXPECT_TRUE(frame->final_chunk); } else { EXPECT_FALSE(frame->final_chunk); } EXPECT_EQ(NULL, frame->data.get()); const WebSocketFrameHeader* header = frame->header.get(); EXPECT_TRUE(header != NULL); if (!header) continue; EXPECT_TRUE(header->final); EXPECT_FALSE(header->reserved1); EXPECT_FALSE(header->reserved2); EXPECT_FALSE(header->reserved3); EXPECT_EQ(WebSocketFrameHeader::kOpCodeText, header->opcode); EXPECT_FALSE(header->masked); EXPECT_EQ(frame_length, header->payload_length); } } TEST(WebSocketFrameParserTest, InvalidLengthEncoding) { struct TestCase { const char* frame_header; size_t frame_header_length; }; static const TestCase kTests[] = { // For frames with two-byte extended length field, the payload length // should be 126 (0x7E) bytes or more. { "\x81\x7E\x00\x00", 4 }, { "\x81\x7E\x00\x7D", 4 }, // For frames with eight-byte extended length field, the payload length // should be 0x10000 bytes or more. { "\x81\x7F\x00\x00\x00\x00\x00\x00\x00\x00", 10 }, { "\x81\x7E\x00\x00\x00\x00\x00\x00\xFF\xFF", 10 }, }; static const int kNumTests = arraysize(kTests); for (int i = 0; i < kNumTests; ++i) { const char* frame_header = kTests[i].frame_header; size_t frame_header_length = kTests[i].frame_header_length; WebSocketFrameParser parser; std::vector> frames; EXPECT_EQ(kWebSocketNormalClosure, parser.websocket_error()); EXPECT_FALSE(parser.Decode(frame_header, frame_header_length, &frames)); EXPECT_EQ(kWebSocketErrorProtocolError, parser.websocket_error()); EXPECT_EQ(0u, frames.size()); // Once the parser has failed, it no longer accepts any input (even if // the input is empty). EXPECT_FALSE(parser.Decode("", 0, &frames)); EXPECT_EQ(kWebSocketErrorProtocolError, parser.websocket_error()); EXPECT_EQ(0u, frames.size()); } } TEST(WebSocketFrameParserTest, FrameTypes) { 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 parser needs to be able to parse // 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) { const char* frame_header = kTests[i].frame_header; size_t frame_header_length = kTests[i].frame_header_length; WebSocketFrameHeader::OpCode opcode = kTests[i].opcode; WebSocketFrameParser parser; std::vector> frames; EXPECT_TRUE(parser.Decode(frame_header, frame_header_length, &frames)); EXPECT_EQ(kWebSocketNormalClosure, parser.websocket_error()); EXPECT_EQ(1u, frames.size()); if (frames.size() != 1u) continue; WebSocketFrameChunk* frame = frames[0].get(); EXPECT_TRUE(frame != NULL); if (!frame) continue; EXPECT_TRUE(frame->final_chunk); EXPECT_EQ(NULL, frame->data.get()); const WebSocketFrameHeader* header = frame->header.get(); EXPECT_TRUE(header != NULL); if (!header) continue; EXPECT_TRUE(header->final); EXPECT_FALSE(header->reserved1); EXPECT_FALSE(header->reserved2); EXPECT_FALSE(header->reserved3); EXPECT_EQ(opcode, header->opcode); EXPECT_FALSE(header->masked); EXPECT_EQ(0u, header->payload_length); } } TEST(WebSocketFrameParserTest, 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) { const char* frame_header = kTests[i].frame_header; size_t frame_header_length = kTests[i].frame_header_length; bool final = kTests[i].final; bool reserved1 = kTests[i].reserved1; bool reserved2 = kTests[i].reserved2; bool reserved3 = kTests[i].reserved3; WebSocketFrameParser parser; std::vector> frames; EXPECT_TRUE(parser.Decode(frame_header, frame_header_length, &frames)); EXPECT_EQ(kWebSocketNormalClosure, parser.websocket_error()); EXPECT_EQ(1u, frames.size()); if (frames.size() != 1u) continue; WebSocketFrameChunk* frame = frames[0].get(); EXPECT_TRUE(frame != NULL); if (!frame) continue; EXPECT_TRUE(frame->final_chunk); EXPECT_EQ(NULL, frame->data.get()); const WebSocketFrameHeader* header = frame->header.get(); EXPECT_TRUE(header != NULL); if (!header) continue; EXPECT_EQ(final, header->final); EXPECT_EQ(reserved1, header->reserved1); EXPECT_EQ(reserved2, header->reserved2); EXPECT_EQ(reserved3, header->reserved3); EXPECT_EQ(WebSocketFrameHeader::kOpCodeText, header->opcode); EXPECT_FALSE(header->masked); EXPECT_EQ(0u, header->payload_length); } } } // Unnamed namespace } // namespace net