// Copyright (c) 2012 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 "content/browser/download/base_file.h" #include #include #include #include "base/files/file.h" #include "base/files/file_util.h" #include "base/files/scoped_temp_dir.h" #include "base/logging.h" #include "base/macros.h" #include "base/strings/string_number_conversions.h" #include "base/test/test_file_util.h" #include "build/build_config.h" #include "content/public/browser/download_interrupt_reasons.h" #include "content/public/test/test_browser_thread_bundle.h" #include "crypto/secure_hash.h" #include "crypto/sha2.h" #include "testing/gtest/include/gtest/gtest.h" namespace content { namespace { const char kTestData1[] = "Let's write some data to the file!\n"; const char kTestData2[] = "Writing more data.\n"; const char kTestData3[] = "Final line."; const char kTestData4[] = "supercalifragilisticexpialidocious"; const int kTestDataLength1 = arraysize(kTestData1) - 1; const int kTestDataLength2 = arraysize(kTestData2) - 1; const int kTestDataLength4 = arraysize(kTestData4) - 1; // SHA-256 hash of kTestData1 (excluding terminating NUL). const uint8_t kHashOfTestData1[] = { 0x0b, 0x2d, 0x3f, 0x3f, 0x79, 0x43, 0xad, 0x64, 0xb8, 0x60, 0xdf, 0x94, 0xd0, 0x5c, 0xb5, 0x6a, 0x8a, 0x97, 0xc6, 0xec, 0x57, 0x68, 0xb5, 0xb7, 0x0b, 0x93, 0x0c, 0x5a, 0xa7, 0xfa, 0x9a, 0xde}; // SHA-256 hash of kTestData1 ++ kTestData2 ++ kTestData3 (excluding terminating // NUL). const uint8_t kHashOfTestData1To3[] = { 0xcb, 0xf6, 0x8b, 0xf1, 0x0f, 0x80, 0x03, 0xdb, 0x86, 0xb3, 0x13, 0x43, 0xaf, 0xac, 0x8c, 0x71, 0x75, 0xbd, 0x03, 0xfb, 0x5f, 0xc9, 0x05, 0x65, 0x0f, 0x8c, 0x80, 0xaf, 0x08, 0x74, 0x43, 0xa8}; } // namespace class BaseFileTest : public testing::Test { public: static const unsigned char kEmptySha256Hash[crypto::kSHA256Length]; BaseFileTest() : expect_file_survives_(false), expect_in_progress_(true), expected_error_(DOWNLOAD_INTERRUPT_REASON_NONE) {} void SetUp() override { ASSERT_TRUE(temp_dir_.CreateUniqueTempDir()); base_file_.reset(new BaseFile(net::NetLogWithSource())); } void TearDown() override { EXPECT_FALSE(base_file_->in_progress()); if (!expected_error_) { EXPECT_EQ(static_cast(expected_data_.size()), base_file_->bytes_so_far()); } base::FilePath full_path = base_file_->full_path(); if (!expected_data_.empty() && !expected_error_) { // Make sure the data has been properly written to disk. std::string disk_data; EXPECT_TRUE(base::ReadFileToString(full_path, &disk_data)); EXPECT_EQ(expected_data_, disk_data); } // Make sure the mock BrowserThread outlives the BaseFile to satisfy // thread checks inside it. base_file_.reset(); EXPECT_EQ(expect_file_survives_, base::PathExists(full_path)); } bool InitializeFile() { DownloadInterruptReason result = base_file_->Initialize( base::FilePath(), temp_dir_.GetPath(), base::File(), 0, std::string(), std::unique_ptr()); EXPECT_EQ(expected_error_, result); return result == DOWNLOAD_INTERRUPT_REASON_NONE; } bool AppendDataToFile(const std::string& data) { EXPECT_EQ(expect_in_progress_, base_file_->in_progress()); DownloadInterruptReason result = base_file_->AppendDataToFile(data.data(), data.size()); if (result == DOWNLOAD_INTERRUPT_REASON_NONE) EXPECT_TRUE(expect_in_progress_) << " result = " << result; EXPECT_EQ(expected_error_, result); if (base_file_->in_progress()) { expected_data_ += data; if (expected_error_ == DOWNLOAD_INTERRUPT_REASON_NONE) { EXPECT_EQ(static_cast(expected_data_.size()), base_file_->bytes_so_far()); } } return result == DOWNLOAD_INTERRUPT_REASON_NONE; } void set_expected_data(const std::string& data) { expected_data_ = data; } // Helper functions. // Create a file. Returns the complete file path. base::FilePath CreateTestFile() { base::FilePath file_name; BaseFile file((net::NetLogWithSource())); EXPECT_EQ( DOWNLOAD_INTERRUPT_REASON_NONE, file.Initialize(base::FilePath(), temp_dir_.GetPath(), base::File(), 0, std::string(), std::unique_ptr())); file_name = file.full_path(); EXPECT_NE(base::FilePath::StringType(), file_name.value()); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, file.AppendDataToFile(kTestData4, kTestDataLength4)); // Keep the file from getting deleted when existing_file_name is deleted. file.Detach(); return file_name; } // Create a file with the specified file name. void CreateFileWithName(const base::FilePath& file_name) { EXPECT_NE(base::FilePath::StringType(), file_name.value()); BaseFile duplicate_file((net::NetLogWithSource())); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, duplicate_file.Initialize(file_name, temp_dir_.GetPath(), base::File(), 0, std::string(), std::unique_ptr())); // Write something into it. duplicate_file.AppendDataToFile(kTestData4, kTestDataLength4); // Detach the file so it isn't deleted on destruction of |duplicate_file|. duplicate_file.Detach(); } int64_t CurrentSpeedAtTime(base::TimeTicks current_time) { EXPECT_TRUE(base_file_.get()); return base_file_->CurrentSpeedAtTime(current_time); } base::TimeTicks StartTick() { EXPECT_TRUE(base_file_.get()); return base_file_->start_tick_; } void set_expected_error(DownloadInterruptReason err) { expected_error_ = err; } void ExpectPermissionError(DownloadInterruptReason err) { EXPECT_TRUE(err == DOWNLOAD_INTERRUPT_REASON_FILE_TRANSIENT_ERROR || err == DOWNLOAD_INTERRUPT_REASON_FILE_ACCESS_DENIED) << "Interrupt reason = " << err; } template static void ExpectHashValue(const uint8_t (&expected_hash)[SZ], std::unique_ptr hash_state) { std::vector hash_value(hash_state->GetHashLength()); hash_state->Finish(&hash_value.front(), hash_value.size()); ASSERT_EQ(SZ, hash_value.size()); EXPECT_EQ(0, memcmp(expected_hash, &hash_value.front(), hash_value.size())); } protected: // BaseClass instance we are testing. std::unique_ptr base_file_; // Temporary directory for renamed downloads. base::ScopedTempDir temp_dir_; // Expect the file to survive deletion of the BaseFile instance. bool expect_file_survives_; // Expect the file to be in progress. bool expect_in_progress_; private: // Keep track of what data should be saved to the disk file. std::string expected_data_; DownloadInterruptReason expected_error_; TestBrowserThreadBundle thread_bundle_; }; // This will initialize the entire array to zero. const unsigned char BaseFileTest::kEmptySha256Hash[] = { 0 }; // Test the most basic scenario: just create the object and do a sanity check // on all its accessors. This is actually a case that rarely happens // in production, where we would at least Initialize it. TEST_F(BaseFileTest, CreateDestroy) { EXPECT_EQ(base::FilePath().value(), base_file_->full_path().value()); } // Cancel the download explicitly. TEST_F(BaseFileTest, Cancel) { ASSERT_TRUE(InitializeFile()); EXPECT_TRUE(base::PathExists(base_file_->full_path())); base_file_->Cancel(); EXPECT_FALSE(base::PathExists(base_file_->full_path())); EXPECT_NE(base::FilePath().value(), base_file_->full_path().value()); } // Write data to the file and detach it, so it doesn't get deleted // automatically when base_file_ is destructed. TEST_F(BaseFileTest, WriteAndDetach) { ASSERT_TRUE(InitializeFile()); ASSERT_TRUE(AppendDataToFile(kTestData1)); base_file_->Finish(); base_file_->Detach(); expect_file_survives_ = true; } // Write data to the file and detach it, and calculate its sha256 hash. TEST_F(BaseFileTest, WriteWithHashAndDetach) { ASSERT_TRUE(InitializeFile()); ASSERT_TRUE(AppendDataToFile(kTestData1)); ExpectHashValue(kHashOfTestData1, base_file_->Finish()); base_file_->Detach(); expect_file_survives_ = true; } // Rename the file after writing to it, then detach. TEST_F(BaseFileTest, WriteThenRenameAndDetach) { ASSERT_TRUE(InitializeFile()); base::FilePath initial_path(base_file_->full_path()); EXPECT_TRUE(base::PathExists(initial_path)); base::FilePath new_path(temp_dir_.GetPath().AppendASCII("NewFile")); EXPECT_FALSE(base::PathExists(new_path)); ASSERT_TRUE(AppendDataToFile(kTestData1)); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, base_file_->Rename(new_path)); EXPECT_FALSE(base::PathExists(initial_path)); EXPECT_TRUE(base::PathExists(new_path)); ExpectHashValue(kHashOfTestData1, base_file_->Finish()); base_file_->Detach(); expect_file_survives_ = true; } // Write data to the file once. TEST_F(BaseFileTest, SingleWrite) { ASSERT_TRUE(InitializeFile()); ASSERT_TRUE(AppendDataToFile(kTestData1)); ExpectHashValue(kHashOfTestData1, base_file_->Finish()); } // Write data to the file multiple times. TEST_F(BaseFileTest, MultipleWrites) { ASSERT_TRUE(InitializeFile()); ASSERT_TRUE(AppendDataToFile(kTestData1)); ASSERT_TRUE(AppendDataToFile(kTestData2)); ASSERT_TRUE(AppendDataToFile(kTestData3)); ExpectHashValue(kHashOfTestData1To3, base_file_->Finish()); } // Write data to the file multiple times, interrupt it, and continue using // another file. Calculate the resulting combined sha256 hash. TEST_F(BaseFileTest, MultipleWritesInterruptedWithHash) { ASSERT_TRUE(InitializeFile()); // Write some data ASSERT_TRUE(AppendDataToFile(kTestData1)); ASSERT_TRUE(AppendDataToFile(kTestData2)); // Get the hash state and file name. std::unique_ptr hash_state = base_file_->Finish(); base::FilePath new_file_path(temp_dir_.GetPath().Append( base::FilePath(FILE_PATH_LITERAL("second_file")))); ASSERT_TRUE(base::CopyFile(base_file_->full_path(), new_file_path)); // Create another file BaseFile second_file((net::NetLogWithSource())); ASSERT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, second_file.Initialize(new_file_path, base::FilePath(), base::File(), base_file_->bytes_so_far(), std::string(), std::move(hash_state))); std::string data(kTestData3); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, second_file.AppendDataToFile(data.data(), data.size())); ExpectHashValue(kHashOfTestData1To3, second_file.Finish()); } // Rename the file after all writes to it. TEST_F(BaseFileTest, WriteThenRename) { ASSERT_TRUE(InitializeFile()); base::FilePath initial_path(base_file_->full_path()); EXPECT_TRUE(base::PathExists(initial_path)); base::FilePath new_path(temp_dir_.GetPath().AppendASCII("NewFile")); EXPECT_FALSE(base::PathExists(new_path)); ASSERT_TRUE(AppendDataToFile(kTestData1)); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, base_file_->Rename(new_path)); EXPECT_FALSE(base::PathExists(initial_path)); EXPECT_TRUE(base::PathExists(new_path)); ExpectHashValue(kHashOfTestData1, base_file_->Finish()); } // Rename the file while the download is still in progress. TEST_F(BaseFileTest, RenameWhileInProgress) { ASSERT_TRUE(InitializeFile()); base::FilePath initial_path(base_file_->full_path()); EXPECT_TRUE(base::PathExists(initial_path)); base::FilePath new_path(temp_dir_.GetPath().AppendASCII("NewFile")); EXPECT_FALSE(base::PathExists(new_path)); ASSERT_TRUE(AppendDataToFile(kTestData1)); EXPECT_TRUE(base_file_->in_progress()); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, base_file_->Rename(new_path)); EXPECT_FALSE(base::PathExists(initial_path)); EXPECT_TRUE(base::PathExists(new_path)); ASSERT_TRUE(AppendDataToFile(kTestData2)); ASSERT_TRUE(AppendDataToFile(kTestData3)); ExpectHashValue(kHashOfTestData1To3, base_file_->Finish()); } // Test that a failed rename reports the correct error. TEST_F(BaseFileTest, RenameWithError) { ASSERT_TRUE(InitializeFile()); // TestDir is a subdirectory in |temp_dir_| that we will make read-only so // that the rename will fail. base::FilePath test_dir(temp_dir_.GetPath().AppendASCII("TestDir")); ASSERT_TRUE(base::CreateDirectory(test_dir)); base::FilePath new_path(test_dir.AppendASCII("TestFile")); EXPECT_FALSE(base::PathExists(new_path)); { base::FilePermissionRestorer restore_permissions_for(test_dir); ASSERT_TRUE(base::MakeFileUnwritable(test_dir)); ExpectPermissionError(base_file_->Rename(new_path)); } base_file_->Finish(); } // Test that if a rename fails for an in-progress BaseFile, it remains writeable // and renameable. TEST_F(BaseFileTest, RenameWithErrorInProgress) { ASSERT_TRUE(InitializeFile()); base::FilePath test_dir(temp_dir_.GetPath().AppendASCII("TestDir")); ASSERT_TRUE(base::CreateDirectory(test_dir)); base::FilePath new_path(test_dir.AppendASCII("TestFile")); EXPECT_FALSE(base::PathExists(new_path)); // Write some data to start with. ASSERT_TRUE(AppendDataToFile(kTestData1)); ASSERT_TRUE(base_file_->in_progress()); base::FilePath old_path = base_file_->full_path(); { base::FilePermissionRestorer restore_permissions_for(test_dir); ASSERT_TRUE(base::MakeFileUnwritable(test_dir)); ExpectPermissionError(base_file_->Rename(new_path)); // The file should still be open and we should be able to continue writing // to it. ASSERT_TRUE(base_file_->in_progress()); ASSERT_TRUE(AppendDataToFile(kTestData2)); ASSERT_EQ(old_path.value(), base_file_->full_path().value()); // Try to rename again, just for kicks. It should still fail. ExpectPermissionError(base_file_->Rename(new_path)); } // Now that TestDir is writeable again, we should be able to successfully // rename the file. EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, base_file_->Rename(new_path)); ASSERT_EQ(new_path.value(), base_file_->full_path().value()); ASSERT_TRUE(AppendDataToFile(kTestData3)); ExpectHashValue(kHashOfTestData1To3, base_file_->Finish()); } // Test that a failed write reports an error. TEST_F(BaseFileTest, WriteWithError) { base::FilePath path; ASSERT_TRUE(base::CreateTemporaryFile(&path)); // Pass a file handle which was opened without the WRITE flag. // This should result in an error when writing. base::File file(path, base::File::FLAG_OPEN_ALWAYS | base::File::FLAG_READ); base_file_.reset(new BaseFile(net::NetLogWithSource())); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, base_file_->Initialize(path, base::FilePath(), std::move(file), 0, std::string(), std::unique_ptr())); #if defined(OS_WIN) set_expected_error(DOWNLOAD_INTERRUPT_REASON_FILE_ACCESS_DENIED); #elif defined (OS_POSIX) set_expected_error(DOWNLOAD_INTERRUPT_REASON_FILE_FAILED); #endif ASSERT_FALSE(AppendDataToFile(kTestData1)); base_file_->Finish(); } // Try to write to uninitialized file. TEST_F(BaseFileTest, UninitializedFile) { expect_in_progress_ = false; set_expected_error(DOWNLOAD_INTERRUPT_REASON_FILE_FAILED); EXPECT_FALSE(AppendDataToFile(kTestData1)); } // Create two |BaseFile|s with the same file, and attempt to write to both. // Overwrite base_file_ with another file with the same name and // non-zero contents, and make sure the last file to close 'wins'. TEST_F(BaseFileTest, DuplicateBaseFile) { ASSERT_TRUE(InitializeFile()); // Create another |BaseFile| referring to the file that |base_file_| owns. CreateFileWithName(base_file_->full_path()); ASSERT_TRUE(AppendDataToFile(kTestData1)); base_file_->Finish(); } // Create a file and append to it. TEST_F(BaseFileTest, AppendToBaseFile) { // Create a new file. base::FilePath existing_file_name = CreateTestFile(); set_expected_data(kTestData4); // Use the file we've just created. base_file_.reset(new BaseFile(net::NetLogWithSource())); ASSERT_EQ( DOWNLOAD_INTERRUPT_REASON_NONE, base_file_->Initialize(existing_file_name, base::FilePath(), base::File(), kTestDataLength4, std::string(), std::unique_ptr())); const base::FilePath file_name = base_file_->full_path(); EXPECT_NE(base::FilePath::StringType(), file_name.value()); // Write into the file. EXPECT_TRUE(AppendDataToFile(kTestData1)); base_file_->Finish(); base_file_->Detach(); expect_file_survives_ = true; } // Create a read-only file and attempt to write to it. TEST_F(BaseFileTest, ReadonlyBaseFile) { // Create a new file. base::FilePath readonly_file_name = CreateTestFile(); // Restore permissions to the file when we are done with this test. base::FilePermissionRestorer restore_permissions(readonly_file_name); // Make it read-only. EXPECT_TRUE(base::MakeFileUnwritable(readonly_file_name)); // Try to overwrite it. base_file_.reset(new BaseFile(net::NetLogWithSource())); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_FILE_ACCESS_DENIED, base_file_->Initialize(readonly_file_name, base::FilePath(), base::File(), 0, std::string(), std::unique_ptr())); expect_in_progress_ = false; const base::FilePath file_name = base_file_->full_path(); EXPECT_NE(base::FilePath::StringType(), file_name.value()); // Write into the file. set_expected_error(DOWNLOAD_INTERRUPT_REASON_FILE_FAILED); EXPECT_FALSE(AppendDataToFile(kTestData1)); base_file_->Finish(); base_file_->Detach(); expect_file_survives_ = true; } // Open an existing file and continue writing to it. The hash of the partial // file is known and matches the existing contents. TEST_F(BaseFileTest, ExistingBaseFileKnownHash) { base::FilePath file_path = temp_dir_.GetPath().AppendASCII("existing"); ASSERT_EQ(kTestDataLength1, base::WriteFile(file_path, kTestData1, kTestDataLength1)); std::string hash_so_far(std::begin(kHashOfTestData1), std::end(kHashOfTestData1)); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, base_file_->Initialize(file_path, base::FilePath(), base::File(), kTestDataLength1, hash_so_far, std::unique_ptr())); set_expected_data(kTestData1); ASSERT_TRUE(AppendDataToFile(kTestData2)); ASSERT_TRUE(AppendDataToFile(kTestData3)); ExpectHashValue(kHashOfTestData1To3, base_file_->Finish()); } // Open an existing file and continue writing to it. The hash of the partial // file is unknown. TEST_F(BaseFileTest, ExistingBaseFileUnknownHash) { base::FilePath file_path = temp_dir_.GetPath().AppendASCII("existing"); ASSERT_EQ(kTestDataLength1, base::WriteFile(file_path, kTestData1, kTestDataLength1)); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, base_file_->Initialize(file_path, base::FilePath(), base::File(), kTestDataLength1, std::string(), std::unique_ptr())); set_expected_data(kTestData1); ASSERT_TRUE(AppendDataToFile(kTestData2)); ASSERT_TRUE(AppendDataToFile(kTestData3)); ExpectHashValue(kHashOfTestData1To3, base_file_->Finish()); } // Open an existing file. The contentsof the file doesn't match the known hash. TEST_F(BaseFileTest, ExistingBaseFileIncorrectHash) { base::FilePath file_path = temp_dir_.GetPath().AppendASCII("existing"); ASSERT_EQ(kTestDataLength2, base::WriteFile(file_path, kTestData2, kTestDataLength2)); std::string hash_so_far(std::begin(kHashOfTestData1), std::end(kHashOfTestData1)); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_FILE_HASH_MISMATCH, base_file_->Initialize(file_path, base::FilePath(), base::File(), kTestDataLength2, hash_so_far, std::unique_ptr())); set_expected_error(DOWNLOAD_INTERRUPT_REASON_FILE_HASH_MISMATCH); } // Open a large existing file with a known hash and continue writing to it. TEST_F(BaseFileTest, ExistingBaseFileLargeSizeKnownHash) { base::FilePath file_path = temp_dir_.GetPath().AppendASCII("existing"); std::string big_buffer(1024 * 200, 'a'); ASSERT_EQ(static_cast(big_buffer.size()), base::WriteFile(file_path, big_buffer.data(), big_buffer.size())); // Hash of partial file (1024*200 * 'a') const uint8_t kExpectedPartialHash[] = { 0x4b, 0x4f, 0x0f, 0x46, 0xac, 0x02, 0xd1, 0x77, 0xde, 0xa0, 0xab, 0x36, 0xa6, 0x6a, 0x65, 0x78, 0x40, 0xe2, 0xfb, 0x98, 0xb2, 0x0b, 0xb2, 0x7a, 0x68, 0x8d, 0xb4, 0xd8, 0xea, 0x9c, 0xd2, 0x2c}; // Hash of entire file (1024*400 * 'a') const uint8_t kExpectedFullHash[] = { 0x0c, 0xe9, 0xf6, 0x78, 0x6b, 0x0f, 0x58, 0x49, 0x36, 0xe8, 0x83, 0xc5, 0x09, 0x16, 0xbc, 0x5e, 0x2d, 0x07, 0x95, 0xb9, 0x42, 0x20, 0x41, 0x7c, 0xb3, 0x38, 0xd3, 0xf4, 0xe0, 0x78, 0x89, 0x46}; ASSERT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, base_file_->Initialize(file_path, base::FilePath(), base::File(), big_buffer.size(), std::string(std::begin(kExpectedPartialHash), std::end(kExpectedPartialHash)), std::unique_ptr())); set_expected_data(big_buffer); // Contents of the file on Open. ASSERT_TRUE(AppendDataToFile(big_buffer)); ExpectHashValue(kExpectedFullHash, base_file_->Finish()); } // Open a large existing file. The contents doesn't match the known hash. TEST_F(BaseFileTest, ExistingBaseFileLargeSizeIncorrectHash) { base::FilePath file_path = temp_dir_.GetPath().AppendASCII("existing"); std::string big_buffer(1024 * 200, 'a'); ASSERT_EQ(static_cast(big_buffer.size()), base::WriteFile(file_path, big_buffer.data(), big_buffer.size())); // Incorrect hash of partial file (1024*200 * 'a') const uint8_t kExpectedPartialHash[] = { 0xc2, 0xa9, 0x08, 0xd9, 0x8f, 0x5d, 0xf9, 0x87, 0xad, 0xe4, 0x1b, 0x5f, 0xce, 0x21, 0x30, 0x67, 0xef, 0x6c, 0xc2, 0x1e, 0xf2, 0x24, 0x02, 0x12, 0xa4, 0x1e, 0x54, 0xb5, 0xe7, 0xc2, 0x8a, 0xe5}; EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_FILE_HASH_MISMATCH, base_file_->Initialize(file_path, base::FilePath(), base::File(), big_buffer.size(), std::string(std::begin(kExpectedPartialHash), std::end(kExpectedPartialHash)), std::unique_ptr())); set_expected_error(DOWNLOAD_INTERRUPT_REASON_FILE_HASH_MISMATCH); } // Open an existing file. The size of the file is too short. TEST_F(BaseFileTest, ExistingBaseFileTooShort) { base::FilePath file_path = temp_dir_.GetPath().AppendASCII("existing"); ASSERT_EQ(kTestDataLength1, base::WriteFile(file_path, kTestData1, kTestDataLength1)); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_FILE_TOO_SHORT, base_file_->Initialize(file_path, base::FilePath(), base::File(), kTestDataLength1 + 1, std::string(), std::unique_ptr())); set_expected_error(DOWNLOAD_INTERRUPT_REASON_FILE_TOO_SHORT); } // Open an existing file. The size is larger than expected. TEST_F(BaseFileTest, ExistingBaseFileKnownHashTooLong) { base::FilePath file_path = temp_dir_.GetPath().AppendASCII("existing"); std::string contents; contents.append(kTestData1); contents.append("Something extra"); ASSERT_EQ(static_cast(contents.size()), base::WriteFile(file_path, contents.data(), contents.size())); std::string hash_so_far(std::begin(kHashOfTestData1), std::end(kHashOfTestData1)); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, base_file_->Initialize(file_path, base::FilePath(), base::File(), kTestDataLength1, hash_so_far, std::unique_ptr())); set_expected_data(kTestData1); // Our starting position. ASSERT_TRUE(AppendDataToFile(kTestData2)); ASSERT_TRUE(AppendDataToFile(kTestData3)); ExpectHashValue(kHashOfTestData1To3, base_file_->Finish()); } // Open an existing file. The size is large than expected and the hash is // unknown. TEST_F(BaseFileTest, ExistingBaseFileUnknownHashTooLong) { base::FilePath file_path = temp_dir_.GetPath().AppendASCII("existing"); std::string contents; contents.append(kTestData1); contents.append("Something extra"); ASSERT_EQ(static_cast(contents.size()), base::WriteFile(file_path, contents.data(), contents.size())); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, base_file_->Initialize(file_path, base::FilePath(), base::File(), kTestDataLength1, std::string(), std::unique_ptr())); set_expected_data(kTestData1); ASSERT_TRUE(AppendDataToFile(kTestData2)); ASSERT_TRUE(AppendDataToFile(kTestData3)); ExpectHashValue(kHashOfTestData1To3, base_file_->Finish()); } // Similar to ExistingBaseFileKnownHashTooLong test, but with a file large // enough to requre multiple Read()s to complete. This provides additional code // coverage for the CalculatePartialHash() logic. TEST_F(BaseFileTest, ExistingBaseFileUnknownHashTooLongForLargeFile) { base::FilePath file_path = temp_dir_.GetPath().AppendASCII("existing"); const size_t kFileSize = 1024 * 1024; const size_t kIntermediateSize = kFileSize / 2 + 111; // |contents| is 100 bytes longer than kIntermediateSize. The latter is the // expected size. std::string contents(kIntermediateSize + 100, 'a'); ASSERT_EQ(static_cast(contents.size()), base::WriteFile(file_path, contents.data(), contents.size())); EXPECT_EQ(DOWNLOAD_INTERRUPT_REASON_NONE, base_file_->Initialize(file_path, base::FilePath(), base::File(), kIntermediateSize, std::string(), std::unique_ptr())); // The extra bytes should be stripped during Initialize(). contents.resize(kIntermediateSize, 'a'); set_expected_data(contents); std::string new_data(kFileSize - kIntermediateSize, 'a'); ASSERT_TRUE(AppendDataToFile(new_data)); const uint8_t kExpectedHash[] = { 0x9b, 0xc1, 0xb2, 0xa2, 0x88, 0xb2, 0x6a, 0xf7, 0x25, 0x7a, 0x36, 0x27, 0x7a, 0xe3, 0x81, 0x6a, 0x7d, 0x4f, 0x16, 0xe8, 0x9c, 0x1e, 0x7e, 0x77, 0xd0, 0xa5, 0xc4, 0x8b, 0xad, 0x62, 0xb3, 0x60, }; ExpectHashValue(kExpectedHash, base_file_->Finish()); } // Test that a temporary file is created in the default download directory. TEST_F(BaseFileTest, CreatedInDefaultDirectory) { ASSERT_TRUE(base_file_->full_path().empty()); ASSERT_TRUE(InitializeFile()); EXPECT_FALSE(base_file_->full_path().empty()); // On Windows, CreateTemporaryFileInDir() will cause a path with short names // to be expanded into a path with long names. Thus temp_dir.GetPath() might // not // be a string-wise match to base_file_->full_path().DirName() even though // they are in the same directory. base::FilePath temp_file; ASSERT_TRUE(base::CreateTemporaryFileInDir(temp_dir_.GetPath(), &temp_file)); ASSERT_FALSE(temp_file.empty()); EXPECT_STREQ(temp_file.DirName().value().c_str(), base_file_->full_path().DirName().value().c_str()); base_file_->Finish(); } TEST_F(BaseFileTest, NoDoubleDeleteAfterCancel) { ASSERT_TRUE(InitializeFile()); base::FilePath full_path = base_file_->full_path(); ASSERT_FALSE(full_path.empty()); ASSERT_TRUE(base::PathExists(full_path)); base_file_->Cancel(); ASSERT_FALSE(base::PathExists(full_path)); const char kData[] = "hello"; const int kDataLength = static_cast(arraysize(kData) - 1); ASSERT_EQ(kDataLength, base::WriteFile(full_path, kData, kDataLength)); // The file that we created here should stick around when the BaseFile is // destroyed during TearDown. expect_file_survives_ = true; } } // namespace content