// Copyright 2015 The Crashpad Authors. All rights reserved. // // 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 "util/file/file_io.h" #include #include #include #include #include "base/atomicops.h" #include "base/files/file_path.h" #include "build/build_config.h" #include "gmock/gmock.h" #include "gtest/gtest.h" #include "test/errors.h" #include "test/file.h" #include "test/scoped_temp_dir.h" #include "util/misc/implicit_cast.h" #include "util/thread/thread.h" namespace crashpad { namespace test { namespace { using testing::_; using testing::InSequence; using testing::Return; class MockReadExactly : public internal::ReadExactlyInternal { public: MockReadExactly() : ReadExactlyInternal() {} MockReadExactly(const MockReadExactly&) = delete; MockReadExactly& operator=(const MockReadExactly&) = delete; ~MockReadExactly() {} // Since it’s more convenient for the test to use uintptr_t than void*, // ReadExactlyInt() and ReadInt() adapt the types. bool ReadExactlyInt(uintptr_t data, size_t size, bool can_log) { return ReadExactly(reinterpret_cast(data), size, can_log); } MOCK_METHOD(FileOperationResult, ReadInt, (uintptr_t, size_t, bool)); // ReadExactlyInternal: FileOperationResult Read(void* data, size_t size, bool can_log) { return ReadInt(reinterpret_cast(data), size, can_log); } }; TEST(FileIO, ReadExactly_Zero) { MockReadExactly read_exactly; InSequence in_sequence; EXPECT_CALL(read_exactly, ReadInt(_, _, false)).Times(0); EXPECT_TRUE(read_exactly.ReadExactlyInt(100, 0, false)); } TEST(FileIO, ReadExactly_SingleSmallSuccess) { MockReadExactly read_exactly; InSequence in_sequence; EXPECT_CALL(read_exactly, ReadInt(1000, 1, false)).WillOnce(Return(1)); EXPECT_TRUE(read_exactly.ReadExactlyInt(1000, 1, false)); } TEST(FileIO, ReadExactly_SingleSmallSuccessCanLog) { MockReadExactly read_exactly; InSequence in_sequence; EXPECT_CALL(read_exactly, ReadInt(1000, 1, true)).WillOnce(Return(1)); EXPECT_TRUE(read_exactly.ReadExactlyInt(1000, 1, true)); } TEST(FileIO, ReadExactly_SingleSmallFailure) { MockReadExactly read_exactly; InSequence in_sequence; EXPECT_CALL(read_exactly, ReadInt(1000, 1, false)).WillOnce(Return(-1)); EXPECT_FALSE(read_exactly.ReadExactlyInt(1000, 1, false)); } TEST(FileIO, ReadExactly_SingleSmallFailureCanLog) { MockReadExactly read_exactly; InSequence in_sequence; EXPECT_CALL(read_exactly, ReadInt(1000, 1, true)).WillOnce(Return(-1)); EXPECT_FALSE(read_exactly.ReadExactlyInt(1000, 1, true)); } TEST(FileIO, ReadExactly_DoubleSmallSuccess) { MockReadExactly read_exactly; InSequence in_sequence; EXPECT_CALL(read_exactly, ReadInt(0x1000, 2, false)).WillOnce(Return(1)); EXPECT_CALL(read_exactly, ReadInt(0x1001, 1, false)).WillOnce(Return(1)); EXPECT_TRUE(read_exactly.ReadExactlyInt(0x1000, 2, false)); } TEST(FileIO, ReadExactly_DoubleSmallShort) { MockReadExactly read_exactly; InSequence in_sequence; EXPECT_CALL(read_exactly, ReadInt(0x20000, 2, false)).WillOnce(Return(1)); EXPECT_CALL(read_exactly, ReadInt(0x20001, 1, false)).WillOnce(Return(0)); EXPECT_FALSE(read_exactly.ReadExactlyInt(0x20000, 2, false)); } TEST(FileIO, ReadExactly_DoubleSmallShortCanLog) { MockReadExactly read_exactly; InSequence in_sequence; EXPECT_CALL(read_exactly, ReadInt(0x20000, 2, true)).WillOnce(Return(1)); EXPECT_CALL(read_exactly, ReadInt(0x20001, 1, true)).WillOnce(Return(0)); EXPECT_FALSE(read_exactly.ReadExactlyInt(0x20000, 2, true)); } TEST(FileIO, ReadExactly_Medium) { MockReadExactly read_exactly; InSequence in_sequence; EXPECT_CALL(read_exactly, ReadInt(0x80000000, 0x20000000, false)) .WillOnce(Return(0x10000000)); EXPECT_CALL(read_exactly, ReadInt(0x90000000, 0x10000000, false)) .WillOnce(Return(0x8000000)); EXPECT_CALL(read_exactly, ReadInt(0x98000000, 0x8000000, false)) .WillOnce(Return(0x4000000)); EXPECT_CALL(read_exactly, ReadInt(0x9c000000, 0x4000000, false)) .WillOnce(Return(0x2000000)); EXPECT_CALL(read_exactly, ReadInt(0x9e000000, 0x2000000, false)) .WillOnce(Return(0x1000000)); EXPECT_CALL(read_exactly, ReadInt(0x9f000000, 0x1000000, false)) .WillOnce(Return(0x800000)); EXPECT_CALL(read_exactly, ReadInt(0x9f800000, 0x800000, false)) .WillOnce(Return(0x400000)); EXPECT_CALL(read_exactly, ReadInt(0x9fc00000, 0x400000, false)) .WillOnce(Return(0x200000)); EXPECT_CALL(read_exactly, ReadInt(0x9fe00000, 0x200000, false)) .WillOnce(Return(0x100000)); EXPECT_CALL(read_exactly, ReadInt(0x9ff00000, 0x100000, false)) .WillOnce(Return(0x80000)); EXPECT_CALL(read_exactly, ReadInt(0x9ff80000, 0x80000, false)) .WillOnce(Return(0x40000)); EXPECT_CALL(read_exactly, ReadInt(0x9ffc0000, 0x40000, false)) .WillOnce(Return(0x20000)); EXPECT_CALL(read_exactly, ReadInt(0x9ffe0000, 0x20000, false)) .WillOnce(Return(0x10000)); EXPECT_CALL(read_exactly, ReadInt(0x9fff0000, 0x10000, false)) .WillOnce(Return(0x8000)); EXPECT_CALL(read_exactly, ReadInt(0x9fff8000, 0x8000, false)) .WillOnce(Return(0x4000)); EXPECT_CALL(read_exactly, ReadInt(0x9fffc000, 0x4000, false)) .WillOnce(Return(0x2000)); EXPECT_CALL(read_exactly, ReadInt(0x9fffe000, 0x2000, false)) .WillOnce(Return(0x1000)); EXPECT_CALL(read_exactly, ReadInt(0x9ffff000, 0x1000, false)) .WillOnce(Return(0x800)); EXPECT_CALL(read_exactly, ReadInt(0x9ffff800, 0x800, false)) .WillOnce(Return(0x400)); EXPECT_CALL(read_exactly, ReadInt(0x9ffffc00, 0x400, false)) .WillOnce(Return(0x200)); EXPECT_CALL(read_exactly, ReadInt(0x9ffffe00, 0x200, false)) .WillOnce(Return(0x100)); EXPECT_CALL(read_exactly, ReadInt(0x9fffff00, 0x100, false)) .WillOnce(Return(0x80)); EXPECT_CALL(read_exactly, ReadInt(0x9fffff80, 0x80, false)) .WillOnce(Return(0x40)); EXPECT_CALL(read_exactly, ReadInt(0x9fffffc0, 0x40, false)) .WillOnce(Return(0x20)); EXPECT_CALL(read_exactly, ReadInt(0x9fffffe0, 0x20, false)) .WillOnce(Return(0x10)); EXPECT_CALL(read_exactly, ReadInt(0x9ffffff0, 0x10, false)) .WillOnce(Return(0x8)); EXPECT_CALL(read_exactly, ReadInt(0x9ffffff8, 0x8, false)) .WillOnce(Return(0x4)); EXPECT_CALL(read_exactly, ReadInt(0x9ffffffc, 0x4, false)) .WillOnce(Return(0x2)); EXPECT_CALL(read_exactly, ReadInt(0x9ffffffe, 0x2, false)) .WillOnce(Return(0x1)); EXPECT_CALL(read_exactly, ReadInt(0x9fffffff, 0x1, false)) .WillOnce(Return(0x1)); EXPECT_TRUE(read_exactly.ReadExactlyInt(0x80000000, 0x20000000, false)); } TEST(FileIO, ReadExactly_LargeSuccess) { MockReadExactly read_exactly; InSequence in_sequence; constexpr size_t max = std::numeric_limits::max(); constexpr size_t increment = std::numeric_limits::max(); EXPECT_CALL(read_exactly, ReadInt(0, max, false)).WillOnce(Return(increment)); EXPECT_CALL(read_exactly, ReadInt(increment, max - increment, false)) .WillOnce(Return(increment)); EXPECT_CALL(read_exactly, ReadInt(2 * increment, 1, false)) .WillOnce(Return(1)); EXPECT_TRUE(read_exactly.ReadExactlyInt(0, max, false)); } TEST(FileIO, ReadExactly_LargeShort) { MockReadExactly read_exactly; InSequence in_sequence; EXPECT_CALL(read_exactly, ReadInt(0, 0xffffffff, false)) .WillOnce(Return(0x7fffffff)); EXPECT_CALL(read_exactly, ReadInt(0x7fffffff, 0x80000000, false)) .WillOnce(Return(0x10000000)); EXPECT_CALL(read_exactly, ReadInt(0x8fffffff, 0x70000000, false)) .WillOnce(Return(0)); EXPECT_FALSE(read_exactly.ReadExactlyInt(0, 0xffffffff, false)); } TEST(FileIO, ReadExactly_LargeFailure) { MockReadExactly read_exactly; InSequence in_sequence; EXPECT_CALL(read_exactly, ReadInt(0, 0xffffffff, false)) .WillOnce(Return(0x7fffffff)); EXPECT_CALL(read_exactly, ReadInt(0x7fffffff, 0x80000000, false)) .WillOnce(Return(-1)); EXPECT_FALSE(read_exactly.ReadExactlyInt(0, 0xffffffff, false)); } TEST(FileIO, ReadExactly_TripleMax) { MockReadExactly read_exactly; InSequence in_sequence; constexpr size_t max = std::numeric_limits::max(); constexpr size_t increment = std::numeric_limits::type>::max(); EXPECT_CALL(read_exactly, ReadInt(0, max, false)).WillOnce(Return(increment)); EXPECT_CALL(read_exactly, ReadInt(increment, max - increment, false)) .WillOnce(Return(increment)); EXPECT_CALL(read_exactly, ReadInt(2 * increment, 1, false)) .WillOnce(Return(1)); EXPECT_TRUE(read_exactly.ReadExactlyInt(0, max, false)); } class MockWriteAll : public internal::WriteAllInternal { public: MockWriteAll() : WriteAllInternal() {} MockWriteAll(const MockWriteAll&) = delete; MockWriteAll& operator=(const MockWriteAll&) = delete; ~MockWriteAll() {} // Since it’s more convenient for the test to use uintptr_t than const void*, // WriteAllInt() and WriteInt() adapt the types. bool WriteAllInt(uintptr_t data, size_t size) { return WriteAll(reinterpret_cast(data), size); } MOCK_METHOD(FileOperationResult, WriteInt, (uintptr_t, size_t)); // WriteAllInternal: FileOperationResult Write(const void* data, size_t size) { return WriteInt(reinterpret_cast(data), size); } }; TEST(FileIO, WriteAll_Zero) { MockWriteAll write_all; InSequence in_sequence; EXPECT_CALL(write_all, WriteInt(_, _)).Times(0); EXPECT_TRUE(write_all.WriteAllInt(100, 0)); } TEST(FileIO, WriteAll_SingleSmallSuccess) { MockWriteAll write_all; InSequence in_sequence; EXPECT_CALL(write_all, WriteInt(1000, 1)).WillOnce(Return(1)); EXPECT_TRUE(write_all.WriteAllInt(1000, 1)); } TEST(FileIO, WriteAll_SingleSmallFailure) { MockWriteAll write_all; InSequence in_sequence; EXPECT_CALL(write_all, WriteInt(1000, 1)).WillOnce(Return(-1)); EXPECT_FALSE(write_all.WriteAllInt(1000, 1)); } TEST(FileIO, WriteAll_DoubleSmall) { MockWriteAll write_all; InSequence in_sequence; EXPECT_CALL(write_all, WriteInt(0x1000, 2)).WillOnce(Return(1)); EXPECT_CALL(write_all, WriteInt(0x1001, 1)).WillOnce(Return(1)); EXPECT_TRUE(write_all.WriteAllInt(0x1000, 2)); } TEST(FileIO, WriteAll_Medium) { MockWriteAll write_all; InSequence in_sequence; EXPECT_CALL(write_all, WriteInt(0x80000000, 0x20000000)) .WillOnce(Return(0x10000000)); EXPECT_CALL(write_all, WriteInt(0x90000000, 0x10000000)) .WillOnce(Return(0x8000000)); EXPECT_CALL(write_all, WriteInt(0x98000000, 0x8000000)) .WillOnce(Return(0x4000000)); EXPECT_CALL(write_all, WriteInt(0x9c000000, 0x4000000)) .WillOnce(Return(0x2000000)); EXPECT_CALL(write_all, WriteInt(0x9e000000, 0x2000000)) .WillOnce(Return(0x1000000)); EXPECT_CALL(write_all, WriteInt(0x9f000000, 0x1000000)) .WillOnce(Return(0x800000)); EXPECT_CALL(write_all, WriteInt(0x9f800000, 0x800000)) .WillOnce(Return(0x400000)); EXPECT_CALL(write_all, WriteInt(0x9fc00000, 0x400000)) .WillOnce(Return(0x200000)); EXPECT_CALL(write_all, WriteInt(0x9fe00000, 0x200000)) .WillOnce(Return(0x100000)); EXPECT_CALL(write_all, WriteInt(0x9ff00000, 0x100000)) .WillOnce(Return(0x80000)); EXPECT_CALL(write_all, WriteInt(0x9ff80000, 0x80000)) .WillOnce(Return(0x40000)); EXPECT_CALL(write_all, WriteInt(0x9ffc0000, 0x40000)) .WillOnce(Return(0x20000)); EXPECT_CALL(write_all, WriteInt(0x9ffe0000, 0x20000)) .WillOnce(Return(0x10000)); EXPECT_CALL(write_all, WriteInt(0x9fff0000, 0x10000)) .WillOnce(Return(0x8000)); EXPECT_CALL(write_all, WriteInt(0x9fff8000, 0x8000)).WillOnce(Return(0x4000)); EXPECT_CALL(write_all, WriteInt(0x9fffc000, 0x4000)).WillOnce(Return(0x2000)); EXPECT_CALL(write_all, WriteInt(0x9fffe000, 0x2000)).WillOnce(Return(0x1000)); EXPECT_CALL(write_all, WriteInt(0x9ffff000, 0x1000)).WillOnce(Return(0x800)); EXPECT_CALL(write_all, WriteInt(0x9ffff800, 0x800)).WillOnce(Return(0x400)); EXPECT_CALL(write_all, WriteInt(0x9ffffc00, 0x400)).WillOnce(Return(0x200)); EXPECT_CALL(write_all, WriteInt(0x9ffffe00, 0x200)).WillOnce(Return(0x100)); EXPECT_CALL(write_all, WriteInt(0x9fffff00, 0x100)).WillOnce(Return(0x80)); EXPECT_CALL(write_all, WriteInt(0x9fffff80, 0x80)).WillOnce(Return(0x40)); EXPECT_CALL(write_all, WriteInt(0x9fffffc0, 0x40)).WillOnce(Return(0x20)); EXPECT_CALL(write_all, WriteInt(0x9fffffe0, 0x20)).WillOnce(Return(0x10)); EXPECT_CALL(write_all, WriteInt(0x9ffffff0, 0x10)).WillOnce(Return(0x8)); EXPECT_CALL(write_all, WriteInt(0x9ffffff8, 0x8)).WillOnce(Return(0x4)); EXPECT_CALL(write_all, WriteInt(0x9ffffffc, 0x4)).WillOnce(Return(0x2)); EXPECT_CALL(write_all, WriteInt(0x9ffffffe, 0x2)).WillOnce(Return(0x1)); EXPECT_CALL(write_all, WriteInt(0x9fffffff, 0x1)).WillOnce(Return(0x1)); EXPECT_TRUE(write_all.WriteAllInt(0x80000000, 0x20000000)); } TEST(FileIO, WriteAll_LargeSuccess) { MockWriteAll write_all; InSequence in_sequence; constexpr size_t max = std::numeric_limits::max(); constexpr size_t increment = std::numeric_limits::max(); EXPECT_CALL(write_all, WriteInt(0, max)).WillOnce(Return(increment)); EXPECT_CALL(write_all, WriteInt(increment, max - increment)) .WillOnce(Return(increment)); EXPECT_CALL(write_all, WriteInt(2 * increment, 1)).WillOnce(Return(1)); EXPECT_TRUE(write_all.WriteAllInt(0, max)); } TEST(FileIO, WriteAll_LargeFailure) { MockWriteAll write_all; InSequence in_sequence; EXPECT_CALL(write_all, WriteInt(0, 0xffffffff)).WillOnce(Return(0x7fffffff)); EXPECT_CALL(write_all, WriteInt(0x7fffffff, 0x80000000)).WillOnce(Return(-1)); EXPECT_FALSE(write_all.WriteAllInt(0, 0xffffffff)); } TEST(FileIO, WriteAll_TripleMax) { MockWriteAll write_all; InSequence in_sequence; constexpr size_t max = std::numeric_limits::max(); constexpr size_t increment = std::numeric_limits::type>::max(); EXPECT_CALL(write_all, WriteInt(0, max)).WillOnce(Return(increment)); EXPECT_CALL(write_all, WriteInt(increment, max - increment)) .WillOnce(Return(increment)); EXPECT_CALL(write_all, WriteInt(2 * increment, 1)).WillOnce(Return(1)); EXPECT_TRUE(write_all.WriteAllInt(0, max)); } void TestOpenFileForWrite(FileHandle (*opener)(const base::FilePath&, FileWriteMode, FilePermissions)) { ScopedTempDir temp_dir; base::FilePath file_path_1 = temp_dir.path().Append(FILE_PATH_LITERAL("file_1")); ASSERT_FALSE(FileExists(file_path_1)); ScopedFileHandle file_handle(opener(file_path_1, FileWriteMode::kReuseOrFail, FilePermissions::kWorldReadable)); EXPECT_EQ(file_handle, kInvalidFileHandle); EXPECT_FALSE(FileExists(file_path_1)); file_handle.reset(opener(file_path_1, FileWriteMode::kCreateOrFail, FilePermissions::kWorldReadable)); EXPECT_NE(file_handle, kInvalidFileHandle); EXPECT_TRUE(FileExists(file_path_1)); EXPECT_EQ(FileSize(file_path_1), 0); file_handle.reset(opener(file_path_1, FileWriteMode::kReuseOrCreate, FilePermissions::kWorldReadable)); EXPECT_NE(file_handle, kInvalidFileHandle); EXPECT_TRUE(FileExists(file_path_1)); EXPECT_EQ(FileSize(file_path_1), 0); constexpr char data = '%'; EXPECT_TRUE(LoggingWriteFile(file_handle.get(), &data, sizeof(data))); // Close file_handle to ensure that the write is flushed to disk. file_handle.reset(); EXPECT_EQ(FileSize(file_path_1), implicit_cast(sizeof(data))); file_handle.reset(opener(file_path_1, FileWriteMode::kReuseOrCreate, FilePermissions::kWorldReadable)); EXPECT_NE(file_handle, kInvalidFileHandle); EXPECT_TRUE(FileExists(file_path_1)); EXPECT_EQ(FileSize(file_path_1), implicit_cast(sizeof(data))); file_handle.reset(opener(file_path_1, FileWriteMode::kCreateOrFail, FilePermissions::kWorldReadable)); EXPECT_EQ(file_handle, kInvalidFileHandle); EXPECT_TRUE(FileExists(file_path_1)); EXPECT_EQ(FileSize(file_path_1), implicit_cast(sizeof(data))); file_handle.reset(opener(file_path_1, FileWriteMode::kReuseOrFail, FilePermissions::kWorldReadable)); EXPECT_NE(file_handle, kInvalidFileHandle); EXPECT_TRUE(FileExists(file_path_1)); EXPECT_EQ(FileSize(file_path_1), implicit_cast(sizeof(data))); file_handle.reset(opener(file_path_1, FileWriteMode::kTruncateOrCreate, FilePermissions::kWorldReadable)); EXPECT_NE(file_handle, kInvalidFileHandle); EXPECT_TRUE(FileExists(file_path_1)); EXPECT_EQ(FileSize(file_path_1), 0); base::FilePath file_path_2 = temp_dir.path().Append(FILE_PATH_LITERAL("file_2")); ASSERT_FALSE(FileExists(file_path_2)); file_handle.reset(opener(file_path_2, FileWriteMode::kTruncateOrCreate, FilePermissions::kWorldReadable)); EXPECT_NE(file_handle, kInvalidFileHandle); EXPECT_TRUE(FileExists(file_path_2)); EXPECT_EQ(FileSize(file_path_2), 0); base::FilePath file_path_3 = temp_dir.path().Append(FILE_PATH_LITERAL("file_3")); ASSERT_FALSE(FileExists(file_path_3)); file_handle.reset(opener(file_path_3, FileWriteMode::kReuseOrCreate, FilePermissions::kWorldReadable)); EXPECT_NE(file_handle, kInvalidFileHandle); EXPECT_TRUE(FileExists(file_path_3)); EXPECT_EQ(FileSize(file_path_3), 0); } TEST(FileIO, OpenFileForWrite) { TestOpenFileForWrite(OpenFileForWrite); } TEST(FileIO, OpenFileForReadAndWrite) { TestOpenFileForWrite(OpenFileForReadAndWrite); } TEST(FileIO, LoggingOpenFileForWrite) { TestOpenFileForWrite(LoggingOpenFileForWrite); } TEST(FileIO, LoggingOpenFileForReadAndWrite) { TestOpenFileForWrite(LoggingOpenFileForReadAndWrite); } #if BUILDFLAG(IS_LINUX) || BUILDFLAG(IS_CHROMEOS) TEST(FileIO, LoggingOpenMemoryFileForReadAndWrite) { ScopedFileHandle handle( LoggingOpenMemoryFileForReadAndWrite(base::FilePath("memfile"))); ASSERT_TRUE(handle.is_valid()); static constexpr char kTestData[] = "somedata"; ASSERT_TRUE(LoggingWriteFile(handle.get(), kTestData, sizeof(kTestData))); ASSERT_EQ(LoggingSeekFile(handle.get(), 0, SEEK_SET), 0); char buffer[sizeof(kTestData)]; ASSERT_TRUE(LoggingReadFileExactly(handle.get(), buffer, sizeof(buffer))); EXPECT_EQ(memcmp(buffer, kTestData, sizeof(buffer)), 0); } #endif // BUILDFLAG(IS_LINUX) || BUILDFLAG(IS_CHROMEOS) enum class ReadOrWrite : bool { kRead, kWrite, }; void FileShareModeTest(ReadOrWrite first, ReadOrWrite second) { ScopedTempDir temp_dir; base::FilePath shared_file = temp_dir.path().Append(FILE_PATH_LITERAL("shared_file")); { // Create an empty file to work on. ScopedFileHandle create( LoggingOpenFileForWrite(shared_file, FileWriteMode::kCreateOrFail, FilePermissions::kOwnerOnly)); } auto handle1 = ScopedFileHandle( (first == ReadOrWrite::kRead) ? LoggingOpenFileForRead(shared_file) : LoggingOpenFileForWrite(shared_file, FileWriteMode::kReuseOrCreate, FilePermissions::kOwnerOnly)); ASSERT_NE(handle1, kInvalidFileHandle); auto handle2 = ScopedFileHandle( (second == ReadOrWrite::kRead) ? LoggingOpenFileForRead(shared_file) : LoggingOpenFileForWrite(shared_file, FileWriteMode::kReuseOrCreate, FilePermissions::kOwnerOnly)); EXPECT_NE(handle2, kInvalidFileHandle); EXPECT_NE(handle1.get(), handle2.get()); } TEST(FileIO, FileShareMode_Read_Read) { FileShareModeTest(ReadOrWrite::kRead, ReadOrWrite::kRead); } TEST(FileIO, FileShareMode_Read_Write) { FileShareModeTest(ReadOrWrite::kRead, ReadOrWrite::kWrite); } TEST(FileIO, FileShareMode_Write_Read) { FileShareModeTest(ReadOrWrite::kWrite, ReadOrWrite::kRead); } TEST(FileIO, FileShareMode_Write_Write) { FileShareModeTest(ReadOrWrite::kWrite, ReadOrWrite::kWrite); } // Fuchsia does not currently support any sort of file locking. See // https://crashpad.chromium.org/bug/196 and // https://crashpad.chromium.org/bug/217. #if !BUILDFLAG(IS_FUCHSIA) TEST(FileIO, MultipleSharedLocks) { ScopedTempDir temp_dir; base::FilePath shared_file = temp_dir.path().Append(FILE_PATH_LITERAL("file_to_lock")); { // Create an empty file to lock. ScopedFileHandle create( LoggingOpenFileForWrite(shared_file, FileWriteMode::kCreateOrFail, FilePermissions::kOwnerOnly)); } auto handle1 = ScopedFileHandle(LoggingOpenFileForRead(shared_file)); ASSERT_NE(handle1, kInvalidFileHandle); EXPECT_EQ( LoggingLockFile( handle1.get(), FileLocking::kShared, FileLockingBlocking::kBlocking), FileLockingResult::kSuccess); auto handle2 = ScopedFileHandle(LoggingOpenFileForRead(shared_file)); ASSERT_NE(handle1, kInvalidFileHandle); EXPECT_EQ( LoggingLockFile( handle2.get(), FileLocking::kShared, FileLockingBlocking::kBlocking), FileLockingResult::kSuccess); EXPECT_TRUE(LoggingUnlockFile(handle1.get())); EXPECT_TRUE(LoggingUnlockFile(handle2.get())); } class LockingTestThread : public Thread { public: LockingTestThread() : file_(), lock_type_(), iterations_(), actual_iterations_() {} LockingTestThread(const LockingTestThread&) = delete; LockingTestThread& operator=(const LockingTestThread&) = delete; void Init(FileHandle file, FileLocking lock_type, int iterations, base::subtle::Atomic32* actual_iterations) { ASSERT_NE(file, kInvalidFileHandle); file_ = ScopedFileHandle(file); lock_type_ = lock_type; iterations_ = iterations; actual_iterations_ = actual_iterations; } private: void ThreadMain() override { for (int i = 0; i < iterations_; ++i) { EXPECT_EQ(LoggingLockFile( file_.get(), lock_type_, FileLockingBlocking::kBlocking), FileLockingResult::kSuccess); base::subtle::NoBarrier_AtomicIncrement(actual_iterations_, 1); EXPECT_TRUE(LoggingUnlockFile(file_.get())); } } ScopedFileHandle file_; FileLocking lock_type_; int iterations_; base::subtle::Atomic32* actual_iterations_; }; void LockingTest(FileLocking main_lock, FileLocking other_locks) { ScopedTempDir temp_dir; base::FilePath shared_file = temp_dir.path().Append(FILE_PATH_LITERAL("file_to_lock")); { // Create an empty file to lock. ScopedFileHandle create( LoggingOpenFileForWrite(shared_file, FileWriteMode::kCreateOrFail, FilePermissions::kOwnerOnly)); } auto initial = ScopedFileHandle( (main_lock == FileLocking::kShared) ? LoggingOpenFileForRead(shared_file) : LoggingOpenFileForWrite(shared_file, FileWriteMode::kReuseOrCreate, FilePermissions::kOwnerOnly)); ASSERT_NE(initial, kInvalidFileHandle); EXPECT_EQ( LoggingLockFile(initial.get(), main_lock, FileLockingBlocking::kBlocking), FileLockingResult::kSuccess); base::subtle::Atomic32 actual_iterations = 0; LockingTestThread threads[20]; int expected_iterations = 0; for (size_t index = 0; index < std::size(threads); ++index) { int iterations_for_this_thread = static_cast(index * 10); threads[index].Init( (other_locks == FileLocking::kShared) ? LoggingOpenFileForRead(shared_file) : LoggingOpenFileForWrite(shared_file, FileWriteMode::kReuseOrCreate, FilePermissions::kOwnerOnly), other_locks, iterations_for_this_thread, &actual_iterations); expected_iterations += iterations_for_this_thread; ASSERT_NO_FATAL_FAILURE(threads[index].Start()); } base::subtle::Atomic32 result = base::subtle::NoBarrier_Load(&actual_iterations); EXPECT_EQ(result, 0); ASSERT_TRUE(LoggingUnlockFile(initial.get())); for (auto& t : threads) t.Join(); result = base::subtle::NoBarrier_Load(&actual_iterations); EXPECT_EQ(result, expected_iterations); } TEST(FileIO, ExclusiveVsExclusives) { LockingTest(FileLocking::kExclusive, FileLocking::kExclusive); } TEST(FileIO, ExclusiveVsShareds) { LockingTest(FileLocking::kExclusive, FileLocking::kShared); } TEST(FileIO, SharedVsExclusives) { LockingTest(FileLocking::kShared, FileLocking::kExclusive); } TEST(FileIO, ExclusiveVsExclusivesNonBlocking) { ScopedTempDir temp_dir; base::FilePath exclusive_file = temp_dir.path().Append(FILE_PATH_LITERAL("file_to_lock")); { // Create an empty file to lock. ScopedFileHandle create( LoggingOpenFileForWrite(exclusive_file, FileWriteMode::kCreateOrFail, FilePermissions::kOwnerOnly)); } auto handle1 = ScopedFileHandle(LoggingOpenFileForRead(exclusive_file)); ASSERT_NE(handle1, kInvalidFileHandle); EXPECT_EQ(LoggingLockFile(handle1.get(), FileLocking::kExclusive, FileLockingBlocking::kBlocking), FileLockingResult::kSuccess); // Non-blocking lock should fail. auto handle2 = ScopedFileHandle(LoggingOpenFileForRead(exclusive_file)); ASSERT_NE(handle2, kInvalidFileHandle); EXPECT_EQ(LoggingLockFile(handle2.get(), FileLocking::kExclusive, FileLockingBlocking::kNonBlocking), FileLockingResult::kWouldBlock); // After unlocking, non-blocking lock should succeed. EXPECT_TRUE(LoggingUnlockFile(handle1.get())); EXPECT_EQ(LoggingLockFile(handle2.get(), FileLocking::kExclusive, FileLockingBlocking::kNonBlocking), FileLockingResult::kSuccess); EXPECT_TRUE(LoggingUnlockFile(handle2.get())); } #endif // !BUILDFLAG(IS_FUCHSIA) TEST(FileIO, FileSizeByHandle) { EXPECT_EQ(LoggingFileSizeByHandle(kInvalidFileHandle), -1); ScopedTempDir temp_dir; base::FilePath file_path = temp_dir.path().Append(FILE_PATH_LITERAL("file_size")); ScopedFileHandle file_handle(LoggingOpenFileForWrite( file_path, FileWriteMode::kCreateOrFail, FilePermissions::kOwnerOnly)); ASSERT_NE(file_handle.get(), kInvalidFileHandle); EXPECT_EQ(LoggingFileSizeByHandle(file_handle.get()), 0); static constexpr char data[] = "zippyzap"; ASSERT_TRUE(LoggingWriteFile(file_handle.get(), &data, sizeof(data))); EXPECT_EQ(LoggingFileSizeByHandle(file_handle.get()), 9); } FileHandle FileHandleForFILE(FILE* file) { int fd = fileno(file); #if BUILDFLAG(IS_POSIX) return fd; #elif BUILDFLAG(IS_WIN) return reinterpret_cast(_get_osfhandle(fd)); #else #error Port #endif } TEST(FileIO, StdioFileHandle) { EXPECT_EQ(StdioFileHandle(StdioStream::kStandardInput), FileHandleForFILE(stdin)); EXPECT_EQ(StdioFileHandle(StdioStream::kStandardOutput), FileHandleForFILE(stdout)); EXPECT_EQ(StdioFileHandle(StdioStream::kStandardError), FileHandleForFILE(stderr)); } } // namespace } // namespace test } // namespace crashpad