// Copyright 2008 Google Inc. // Author: Lincoln Smith // // 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 <config.h> #include "google/vcdecoder.h" #include <stdlib.h> // free, posix_memalign #include <string.h> // memcpy #include <string> #include "testing.h" #include "varint_bigendian.h" #include "vcdecoder_test.h" #include "vcdiff_defs.h" // VCD_SOURCE #ifdef HAVE_MALLOC_H #include <malloc.h> #endif // HAVE_MALLOC_H #ifdef HAVE_SYS_MMAN_H #define _XOPEN_SOURCE 600 // posix_memalign #include <sys/mman.h> // mprotect #endif // HAVE_SYS_MMAN_H #ifdef HAVE_UNISTD_H #include <unistd.h> // getpagesize #endif // HAVE_UNISTD_H namespace open_vcdiff { // Test headers, valid and invalid. TEST_F(VCDiffInterleavedDecoderTest, DecodeHeaderOnly) { decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_TRUE(decoder_.DecodeChunk(delta_file_header_.data(), delta_file_header_.size(), &output_)); EXPECT_TRUE(decoder_.FinishDecoding()); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, PartialHeaderNotEnough) { decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_TRUE(decoder_.DecodeChunk(delta_file_header_.data(), delta_file_header_.size() - 2, &output_)); EXPECT_FALSE(decoder_.FinishDecoding()); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, BadMagicNumber) { delta_file_[1] = 'Q' | 0x80; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, BadVersionNumber) { delta_file_[3] = 0x01; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, SecondaryCompressionNotSupported) { delta_file_[4] = 0x01; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, Decode) { decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_TRUE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_TRUE(decoder_.FinishDecoding()); EXPECT_EQ(expected_target_, output_); } TEST_F(VCDiffInterleavedDecoderTest, DecodeWithChecksum) { ComputeAndAddChecksum(); InitializeDeltaFile(); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_TRUE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_TRUE(decoder_.FinishDecoding()); EXPECT_EQ(expected_target_, output_); } TEST_F(VCDiffInterleavedDecoderTest, ChecksumDoesNotMatch) { AddChecksum(0xBADBAD); InitializeDeltaFile(); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, ChecksumIsInvalid64BitVarint) { static const char kInvalidVarint[] = { 0x81, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x00 }; delta_window_header_[0] |= VCD_CHECKSUM; delta_window_header_.append(kInvalidVarint, sizeof(kInvalidVarint)); // Adjust delta window size to include size of invalid Varint. string size_of_invalid_varint; VarintBE<int32_t>::AppendToString( static_cast<int32_t>(delta_window_header_[4] + sizeof(kInvalidVarint)), &size_of_invalid_varint); delta_window_header_.replace(4, 1, size_of_invalid_varint); InitializeDeltaFile(); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } // Remove one byte from the length of the chunk to process, and // verify that an error is returned for FinishDecoding(). TEST_F(VCDiffInterleavedDecoderTest, FinishAfterDecodingPartialWindow) { decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_TRUE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size() - 1, &output_)); EXPECT_FALSE(decoder_.FinishDecoding()); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTest, FinishAfterDecodingPartialWindowHeader) { decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_TRUE(decoder_.DecodeChunk(delta_file_.data(), delta_file_header_.size() + delta_window_header_.size() - 1, &output_)); EXPECT_FALSE(decoder_.FinishDecoding()); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTest, TargetMatchesWindowSizeLimit) { decoder_.SetMaximumTargetWindowSize(expected_target_.size()); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_TRUE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_TRUE(decoder_.FinishDecoding()); EXPECT_EQ(expected_target_, output_); } TEST_F(VCDiffInterleavedDecoderTest, TargetMatchesFileSizeLimit) { decoder_.SetMaximumTargetFileSize(expected_target_.size()); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_TRUE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_TRUE(decoder_.FinishDecoding()); EXPECT_EQ(expected_target_, output_); } TEST_F(VCDiffInterleavedDecoderTest, TargetExceedsWindowSizeLimit) { decoder_.SetMaximumTargetWindowSize(expected_target_.size() - 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, TargetExceedsFileSizeLimit) { decoder_.SetMaximumTargetFileSize(expected_target_.size() - 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } // Fuzz bits to make sure decoder does not violently crash. // This test has no expected behavior except that no crashes should occur. // In some cases, changing bits will still decode to the correct target; // for example, changing unused bits within a bitfield. TEST_F(VCDiffInterleavedDecoderTest, FuzzBits) { while (FuzzOneByteInDeltaFile()) { decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); if (decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)) { decoder_.FinishDecoding(); } InitializeDeltaFile(); output_.clear(); } } // If a checksum is present, then fuzzing any of the bits may produce an error, // but it should not result in an incorrect target being produced without // an error. TEST_F(VCDiffInterleavedDecoderTest, FuzzBitsWithChecksum) { ComputeAndAddChecksum(); InitializeDeltaFile(); while (FuzzOneByteInDeltaFile()) { decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); if (decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)) { if (decoder_.FinishDecoding()) { // Decoding succeeded. Make sure the correct target was produced. EXPECT_EQ(expected_target_, output_); } } else { EXPECT_EQ("", output_); } InitializeDeltaFile(); output_.clear(); } } TEST_F(VCDiffInterleavedDecoderTest, CopyMoreThanExpectedTarget) { delta_file_[delta_file_header_.size() + 0x0C] = FirstByteOfStringLength(kExpectedTarget); delta_file_[delta_file_header_.size() + 0x0D] = SecondByteOfStringLength(kExpectedTarget) + 1; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, CopySizeZero) { delta_file_[delta_file_header_.size() + 0x0C] = 0; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, CopySizeTooLargeByOne) { ++delta_file_[delta_file_header_.size() + 0x0C]; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, CopySizeTooSmallByOne) { --delta_file_[delta_file_header_.size() + 0x0C]; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, CopySizeMaxInt) { WriteMaxVarintAtOffset(0x0C, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, CopySizeNegative) { WriteNegativeVarintAtOffset(0x0C, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, CopySizeInvalid) { WriteInvalidVarintAtOffset(0x0C, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, CopyAddressBeyondHereAddress) { delta_file_[delta_file_header_.size() + 0x0D] = FirstByteOfStringLength(kDictionary); delta_file_[delta_file_header_.size() + 0x0E] = SecondByteOfStringLength(kDictionary); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, CopyAddressMaxInt) { WriteMaxVarintAtOffset(0x0D, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, CopyAddressNegative) { WriteNegativeVarintAtOffset(0x0D, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, CopyAddressInvalid) { WriteInvalidVarintAtOffset(0x0D, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, AddMoreThanExpectedTarget) { delta_file_[delta_file_header_.size() + 0x0F] = FirstByteOfStringLength(kExpectedTarget); delta_file_[delta_file_header_.size() + 0x10] = SecondByteOfStringLength(kExpectedTarget) + 1; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, AddSizeZero) { delta_file_[delta_file_header_.size() + 0x0F] = 0; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, AddSizeTooLargeByOne) { ++delta_file_[delta_file_header_.size() + 0x0F]; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, AddSizeTooSmallByOne) { --delta_file_[delta_file_header_.size() + 0x0F]; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, AddSizeMaxInt) { WriteMaxVarintAtOffset(0x0F, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, AddSizeNegative) { WriteNegativeVarintAtOffset(0x0F, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, AddSizeInvalid) { WriteInvalidVarintAtOffset(0x0F, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, RunMoreThanExpectedTarget) { delta_file_[delta_file_header_.size() + 0x5F] = FirstByteOfStringLength(kExpectedTarget); delta_file_[delta_file_header_.size() + 0x60] = SecondByteOfStringLength(kExpectedTarget) + 1; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, RunSizeZero) { delta_file_[delta_file_header_.size() + 0x5F] = 0; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, RunSizeTooLargeByOne) { ++delta_file_[delta_file_header_.size() + 0x5F]; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, RunSizeTooSmallByOne) { --delta_file_[delta_file_header_.size() + 0x5F]; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, RunSizeMaxInt) { WriteMaxVarintAtOffset(0x5F, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, RunSizeNegative) { WriteNegativeVarintAtOffset(0x5F, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTest, RunSizeInvalid) { WriteInvalidVarintAtOffset(0x5F, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_FALSE(decoder_.DecodeChunk(delta_file_.data(), delta_file_.size(), &output_)); EXPECT_EQ("", output_); } #if defined(HAVE_MPROTECT) && \ (defined(HAVE_MEMALIGN) || defined(HAVE_POSIX_MEMALIGN)) TEST_F(VCDiffInterleavedDecoderTest, ShouldNotReadPastEndOfBuffer) { // Allocate two memory pages. const int page_size = getpagesize(); void* two_pages = NULL; #ifdef HAVE_POSIX_MEMALIGN posix_memalign(&two_pages, page_size, 2 * page_size); #else // !HAVE_POSIX_MEMALIGN two_pages = memalign(page_size, 2 * page_size); #endif // HAVE_POSIX_MEMALIGN char* const first_page = reinterpret_cast<char*>(two_pages); char* const second_page = first_page + page_size; // Place the delta string at the end of the first page. char* delta_with_guard = second_page - delta_file_.size(); memcpy(delta_with_guard, delta_file_.data(), delta_file_.size()); // Make the second page unreadable. mprotect(second_page, page_size, PROT_NONE); // Now perform the decode operation, which will cause a segmentation fault // if it reads past the end of the buffer. decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_TRUE(decoder_.DecodeChunk(delta_with_guard, delta_file_.size(), &output_)); EXPECT_TRUE(decoder_.FinishDecoding()); EXPECT_EQ(expected_target_, output_); // Undo the mprotect. mprotect(second_page, page_size, PROT_READ|PROT_WRITE); free(two_pages); } TEST_F(VCDiffInterleavedDecoderTest, ShouldNotReadPastBeginningOfBuffer) { // Allocate two memory pages. const int page_size = getpagesize(); void* two_pages = NULL; #ifdef HAVE_POSIX_MEMALIGN posix_memalign(&two_pages, page_size, 2 * page_size); #else // !HAVE_POSIX_MEMALIGN two_pages = memalign(page_size, 2 * page_size); #endif // HAVE_POSIX_MEMALIGN char* const first_page = reinterpret_cast<char*>(two_pages); char* const second_page = first_page + page_size; // Make the first page unreadable. mprotect(first_page, page_size, PROT_NONE); // Place the delta string at the beginning of the second page. char* delta_with_guard = second_page; memcpy(delta_with_guard, delta_file_.data(), delta_file_.size()); // Now perform the decode operation, which will cause a segmentation fault // if it reads past the beginning of the buffer. decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); EXPECT_TRUE(decoder_.DecodeChunk(delta_with_guard, delta_file_.size(), &output_)); EXPECT_TRUE(decoder_.FinishDecoding()); EXPECT_EQ(expected_target_, output_); // Undo the mprotect. mprotect(first_page, page_size, PROT_READ|PROT_WRITE); free(two_pages); } #endif // HAVE_MPROTECT && (HAVE_MEMALIGN || HAVE_POSIX_MEMALIGN) // These are the same tests as for VCDiffInterleavedDecoderTest, with the added // complication that instead of calling DecodeChunk() once with the entire data // set, DecodeChunk() is called once for each byte of input. This is intended // to shake out any bugs with rewind and resume while parsing chunked data. typedef VCDiffInterleavedDecoderTest VCDiffInterleavedDecoderTestByteByByte; // Test headers, valid and invalid. TEST_F(VCDiffInterleavedDecoderTestByteByByte, DecodeHeaderOnly) { decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); for (size_t i = 0; i < delta_file_header_.size(); ++i) { EXPECT_TRUE(decoder_.DecodeChunk(&delta_file_header_[i], 1, &output_)); } EXPECT_TRUE(decoder_.FinishDecoding()); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, PartialHeaderNotEnough) { delta_file_.resize(delta_file_header_.size() - 2); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); for (size_t i = 0; i < delta_file_.size(); ++i) { EXPECT_TRUE(decoder_.DecodeChunk(&delta_file_[i], 1, &output_)); } EXPECT_FALSE(decoder_.FinishDecoding()); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, BadMagicNumber) { delta_file_[1] = 'Q' | 0x80; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { // It should fail at the position that was altered EXPECT_EQ(1U, i); failed = true; break; } } EXPECT_TRUE(failed); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, BadVersionNumber) { delta_file_[3] = 0x01; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(3U, i); break; } } EXPECT_TRUE(failed); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, SecondaryCompressionNotSupported) { delta_file_[4] = 0x01; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(4U, i); break; } } EXPECT_TRUE(failed); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, Decode) { decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); for (size_t i = 0; i < delta_file_.size(); ++i) { EXPECT_TRUE(decoder_.DecodeChunk(&delta_file_[i], 1, &output_)); } EXPECT_TRUE(decoder_.FinishDecoding()); EXPECT_EQ(expected_target_, output_); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, DecodeWithChecksum) { ComputeAndAddChecksum(); InitializeDeltaFile(); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); for (size_t i = 0; i < delta_file_.size(); ++i) { EXPECT_TRUE(decoder_.DecodeChunk(&delta_file_[i], 1, &output_)); } EXPECT_TRUE(decoder_.FinishDecoding()); EXPECT_EQ(expected_target_, output_); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, ChecksumDoesNotMatch) { AddChecksum(0xBADBAD); InitializeDeltaFile(); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail after decoding the entire delta file EXPECT_EQ(delta_file_.size() - 1, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, ChecksumIsInvalid64BitVarint) { static const char kInvalidVarint[] = { 0x81, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x00 }; delta_window_header_[0] |= VCD_CHECKSUM; delta_window_header_.append(kInvalidVarint, sizeof(kInvalidVarint)); // Adjust delta window size to include size of invalid Varint. string size_of_invalid_varint; VarintBE<int32_t>::AppendToString( static_cast<int32_t>(delta_window_header_[4] + sizeof(kInvalidVarint)), &size_of_invalid_varint); delta_window_header_.replace(4, 1, size_of_invalid_varint); InitializeDeltaFile(); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail while trying to interpret the checksum. EXPECT_EQ(delta_file_header_.size() + delta_window_header_.size() - 2, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, TargetMatchesWindowSizeLimit) { decoder_.SetMaximumTargetWindowSize(expected_target_.size()); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); for (size_t i = 0; i < delta_file_.size(); ++i) { EXPECT_TRUE(decoder_.DecodeChunk(&delta_file_[i], 1, &output_)); } EXPECT_TRUE(decoder_.FinishDecoding()); EXPECT_EQ(expected_target_, output_); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, TargetMatchesFileSizeLimit) { decoder_.SetMaximumTargetFileSize(expected_target_.size()); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); for (size_t i = 0; i < delta_file_.size(); ++i) { EXPECT_TRUE(decoder_.DecodeChunk(&delta_file_[i], 1, &output_)); } EXPECT_TRUE(decoder_.FinishDecoding()); EXPECT_EQ(expected_target_, output_); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, TargetExceedsWindowSizeLimit) { decoder_.SetMaximumTargetWindowSize(expected_target_.size() - 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; break; } } EXPECT_TRUE(failed); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, TargetExceedsFileSizeLimit) { decoder_.SetMaximumTargetFileSize(expected_target_.size() - 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; break; } } EXPECT_TRUE(failed); EXPECT_EQ("", output_); } // Fuzz bits to make sure decoder does not violently crash. // This test has no expected behavior except that no crashes should occur. // In some cases, changing bits will still decode to the correct target; // for example, changing unused bits within a bitfield. TEST_F(VCDiffInterleavedDecoderTestByteByByte, FuzzBits) { while (FuzzOneByteInDeltaFile()) { decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; break; } } if (!failed) { decoder_.FinishDecoding(); } InitializeDeltaFile(); output_.clear(); } } // If a checksum is present, then fuzzing any of the bits may produce an error, // but it should not result in an incorrect target being produced without // an error. TEST_F(VCDiffInterleavedDecoderTestByteByByte, FuzzBitsWithChecksum) { ComputeAndAddChecksum(); InitializeDeltaFile(); while (FuzzOneByteInDeltaFile()) { decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; break; } } if (!failed) { if (decoder_.FinishDecoding()) { // Decoding succeeded. Make sure the correct target was produced. EXPECT_EQ(expected_target_, output_); } } // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); InitializeDeltaFile(); output_.clear(); } } TEST_F(VCDiffInterleavedDecoderTestByteByByte, CopyInstructionsShouldFailIfNoSourceSegment) { // Replace the Win_Indicator and the source size and source offset with a // single 0 byte (a Win_Indicator for a window with no source segment.) delta_window_header_.replace(0, 4, "\0", 1); InitializeDeltaFile(); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // The first COPY instruction should fail. EXPECT_EQ(delta_file_header_.size() + delta_window_header_.size() + 2, i); break; } } EXPECT_TRUE(failed); EXPECT_EQ("", output_); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, CopyMoreThanExpectedTarget) { delta_file_[delta_file_header_.size() + 0x0C] = FirstByteOfStringLength(kExpectedTarget); delta_file_[delta_file_header_.size() + 0x0D] = SecondByteOfStringLength(kExpectedTarget) + 1; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x0D, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } // A COPY instruction with an explicit size of 0 is not illegal according to the // standard, although it is inefficient and should not be generated by any // reasonable encoder. Changing the size of a COPY instruction to zero will // cause a failure because the generated target window size will not match the // expected target size. TEST_F(VCDiffInterleavedDecoderTestByteByByte, CopySizeZero) { delta_file_[delta_file_header_.size() + 0x0C] = 0; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, CopySizeTooLargeByOne) { ++delta_file_[delta_file_header_.size() + 0x0C]; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, CopySizeTooSmallByOne) { --delta_file_[delta_file_header_.size() + 0x0C]; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, CopySizeMaxInt) { WriteMaxVarintAtOffset(0x0C, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x10, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, CopySizeNegative) { WriteNegativeVarintAtOffset(0x0C, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x0F, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, CopySizeInvalid) { WriteInvalidVarintAtOffset(0x0C, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x10, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, CopyAddressBeyondHereAddress) { delta_file_[delta_file_header_.size() + 0x0D] = FirstByteOfStringLength(kDictionary); delta_file_[delta_file_header_.size() + 0x0E] = SecondByteOfStringLength(kDictionary); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x0E, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, CopyAddressMaxInt) { WriteMaxVarintAtOffset(0x0D, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x11, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, CopyAddressNegative) { WriteNegativeVarintAtOffset(0x0D, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x10, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, CopyAddressInvalid) { WriteInvalidVarintAtOffset(0x0D, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x11, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, AddMoreThanExpectedTarget) { delta_file_[delta_file_header_.size() + 0x0F] = FirstByteOfStringLength(kExpectedTarget); delta_file_[delta_file_header_.size() + 0x10] = SecondByteOfStringLength(kExpectedTarget) + 1; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x10, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } // An ADD instruction with an explicit size of 0 is not illegal according to the // standard, although it is inefficient and should not be generated by any // reasonable encoder. Changing the size of an ADD instruction to zero will // cause a failure because the generated target window size will not match the // expected target size. TEST_F(VCDiffInterleavedDecoderTestByteByByte, AddSizeZero) { delta_file_[delta_file_header_.size() + 0x0F] = 0; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, AddSizeTooLargeByOne) { ++delta_file_[delta_file_header_.size() + 0x0F]; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, AddSizeTooSmallByOne) { --delta_file_[delta_file_header_.size() + 0x0F]; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, AddSizeMaxInt) { WriteMaxVarintAtOffset(0x0F, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x13, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, AddSizeNegative) { WriteNegativeVarintAtOffset(0x0F, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x12, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, AddSizeInvalid) { WriteInvalidVarintAtOffset(0x0F, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x13, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, RunMoreThanExpectedTarget) { delta_file_[delta_file_header_.size() + 0x5F] = FirstByteOfStringLength(kExpectedTarget); delta_file_[delta_file_header_.size() + 0x60] = SecondByteOfStringLength(kExpectedTarget) + 1; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x60, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } // A RUN instruction with an explicit size of 0 is not illegal according to the // standard, although it is inefficient and should not be generated by any // reasonable encoder. Changing the size of a RUN instruction to zero will // cause a failure because the generated target window size will not match the // expected target size. TEST_F(VCDiffInterleavedDecoderTestByteByByte, RunSizeZero) { delta_file_[delta_file_header_.size() + 0x5F] = 0; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, RunSizeTooLargeByOne) { ++delta_file_[delta_file_header_.size() + 0x5F]; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, RunSizeTooSmallByOne) { --delta_file_[delta_file_header_.size() + 0x5F]; decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, RunSizeMaxInt) { WriteMaxVarintAtOffset(0x5F, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x63, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, RunSizeNegative) { WriteNegativeVarintAtOffset(0x5F, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x62, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } TEST_F(VCDiffInterleavedDecoderTestByteByByte, RunSizeInvalid) { WriteInvalidVarintAtOffset(0x5F, 1); decoder_.StartDecoding(dictionary_.data(), dictionary_.size()); bool failed = false; for (size_t i = 0; i < delta_file_.size(); ++i) { if (!decoder_.DecodeChunk(&delta_file_[i], 1, &output_)) { failed = true; // It should fail at the position that was altered EXPECT_EQ(delta_file_header_.size() + 0x63, i); break; } } EXPECT_TRUE(failed); // The decoder should not create more target bytes than were expected. EXPECT_GE(expected_target_.size(), output_.size()); } } // namespace open_vcdiff