// Copyright (c) 2011-present, Facebook, Inc. All rights reserved. // This source code is licensed under the BSD-style license found in the // LICENSE file in the root directory of this source tree. An additional grant // of patent rights can be found in the PATENTS file in the same directory. // // Copyright (c) 2011 The LevelDB Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. See the AUTHORS file for names of contributors. #include "port/win/io_win.h" #include "util/sync_point.h" #include "util/coding.h" #include "util/iostats_context_imp.h" #include "util/aligned_buffer.h" namespace rocksdb { namespace port { /* * DirectIOHelper */ namespace { const size_t kSectorSize = 512; inline bool IsPowerOfTwo(const size_t alignment) { return ((alignment) & (alignment - 1)) == 0; } inline bool IsSectorAligned(const size_t off) { return (off & (kSectorSize - 1)) == 0; } inline bool IsAligned(size_t alignment, const void* ptr) { return ((uintptr_t(ptr)) & (alignment - 1)) == 0; } } std::string GetWindowsErrSz(DWORD err) { LPSTR lpMsgBuf; FormatMessageA(FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS, NULL, err, 0, // Default language reinterpret_cast(&lpMsgBuf), 0, NULL); std::string Err = lpMsgBuf; LocalFree(lpMsgBuf); return Err; } // We preserve the original name of this interface to denote the original idea // behind it. // All reads happen by a specified offset and pwrite interface does not change // the position of the file pointer. Judging from the man page and errno it does // execute // lseek atomically to return the position of the file back where it was. // WriteFile() does not // have this capability. Therefore, for both pread and pwrite the pointer is // advanced to the next position // which is fine for writes because they are (should be) sequential. // Because all the reads/writes happen by the specified offset, the caller in // theory should not // rely on the current file offset. SSIZE_T pwrite(HANDLE hFile, const char* src, size_t numBytes, uint64_t offset) { assert(numBytes <= std::numeric_limits::max()); OVERLAPPED overlapped = { 0 }; ULARGE_INTEGER offsetUnion; offsetUnion.QuadPart = offset; overlapped.Offset = offsetUnion.LowPart; overlapped.OffsetHigh = offsetUnion.HighPart; SSIZE_T result = 0; unsigned long bytesWritten = 0; if (FALSE == WriteFile(hFile, src, static_cast(numBytes), &bytesWritten, &overlapped)) { result = -1; } else { result = bytesWritten; } return result; } // See comments for pwrite above SSIZE_T pread(HANDLE hFile, char* src, size_t numBytes, uint64_t offset) { assert(numBytes <= std::numeric_limits::max()); OVERLAPPED overlapped = { 0 }; ULARGE_INTEGER offsetUnion; offsetUnion.QuadPart = offset; overlapped.Offset = offsetUnion.LowPart; overlapped.OffsetHigh = offsetUnion.HighPart; SSIZE_T result = 0; unsigned long bytesRead = 0; if (FALSE == ReadFile(hFile, src, static_cast(numBytes), &bytesRead, &overlapped)) { return -1; } else { result = bytesRead; } return result; } // SetFileInformationByHandle() is capable of fast pre-allocates. // However, this does not change the file end position unless the file is // truncated and the pre-allocated space is not considered filled with zeros. Status fallocate(const std::string& filename, HANDLE hFile, uint64_t to_size) { Status status; FILE_ALLOCATION_INFO alloc_info; alloc_info.AllocationSize.QuadPart = to_size; if (!SetFileInformationByHandle(hFile, FileAllocationInfo, &alloc_info, sizeof(FILE_ALLOCATION_INFO))) { auto lastError = GetLastError(); status = IOErrorFromWindowsError( "Failed to pre-allocate space: " + filename, lastError); } return status; } Status ftruncate(const std::string& filename, HANDLE hFile, uint64_t toSize) { Status status; FILE_END_OF_FILE_INFO end_of_file; end_of_file.EndOfFile.QuadPart = toSize; if (!SetFileInformationByHandle(hFile, FileEndOfFileInfo, &end_of_file, sizeof(FILE_END_OF_FILE_INFO))) { auto lastError = GetLastError(); status = IOErrorFromWindowsError("Failed to Set end of file: " + filename, lastError); } return status; } size_t GetUniqueIdFromFile(HANDLE hFile, char* id, size_t max_size) { if (max_size < kMaxVarint64Length * 3) { return 0; } // This function has to be re-worked for cases when // ReFS file system introduced on Windows Server 2012 is used BY_HANDLE_FILE_INFORMATION FileInfo; BOOL result = GetFileInformationByHandle(hFile, &FileInfo); TEST_SYNC_POINT_CALLBACK("GetUniqueIdFromFile:FS_IOC_GETVERSION", &result); if (!result) { return 0; } char* rid = id; rid = EncodeVarint64(rid, uint64_t(FileInfo.dwVolumeSerialNumber)); rid = EncodeVarint64(rid, uint64_t(FileInfo.nFileIndexHigh)); rid = EncodeVarint64(rid, uint64_t(FileInfo.nFileIndexLow)); assert(rid >= id); return static_cast(rid - id); } //////////////////////////////////////////////////////////////////////////////////////////////////// // WinMmapReadableFile WinMmapReadableFile::WinMmapReadableFile(const std::string& fileName, HANDLE hFile, HANDLE hMap, const void* mapped_region, size_t length) : WinFileData(fileName, hFile, false /* use_direct_io */), hMap_(hMap), mapped_region_(mapped_region), length_(length) {} WinMmapReadableFile::~WinMmapReadableFile() { BOOL ret = ::UnmapViewOfFile(mapped_region_); assert(ret); ret = ::CloseHandle(hMap_); assert(ret); } Status WinMmapReadableFile::Read(uint64_t offset, size_t n, Slice* result, char* scratch) const { Status s; if (offset > length_) { *result = Slice(); return IOError(filename_, EINVAL); } else if (offset + n > length_) { n = length_ - offset; } *result = Slice(reinterpret_cast(mapped_region_)+offset, n); return s; } Status WinMmapReadableFile::InvalidateCache(size_t offset, size_t length) { return Status::OK(); } size_t WinMmapReadableFile::GetUniqueId(char* id, size_t max_size) const { return GetUniqueIdFromFile(hFile_, id, max_size); } /////////////////////////////////////////////////////////////////////////////// /// WinMmapFile // Can only truncate or reserve to a sector size aligned if // used on files that are opened with Unbuffered I/O Status WinMmapFile::TruncateFile(uint64_t toSize) { return ftruncate(filename_, hFile_, toSize); } Status WinMmapFile::UnmapCurrentRegion() { Status status; if (mapped_begin_ != nullptr) { if (!::UnmapViewOfFile(mapped_begin_)) { status = IOErrorFromWindowsError( "Failed to unmap file view: " + filename_, GetLastError()); } // Move on to the next portion of the file file_offset_ += view_size_; // UnmapView automatically sends data to disk but not the metadata // which is good and provides some equivalent of fdatasync() on Linux // therefore, we donot need separate flag for metadata mapped_begin_ = nullptr; mapped_end_ = nullptr; dst_ = nullptr; last_sync_ = nullptr; pending_sync_ = false; } return status; } Status WinMmapFile::MapNewRegion() { Status status; assert(mapped_begin_ == nullptr); size_t minDiskSize = file_offset_ + view_size_; if (minDiskSize > reserved_size_) { status = Allocate(file_offset_, view_size_); if (!status.ok()) { return status; } } // Need to remap if (hMap_ == NULL || reserved_size_ > mapping_size_) { if (hMap_ != NULL) { // Unmap the previous one BOOL ret = ::CloseHandle(hMap_); assert(ret); hMap_ = NULL; } ULARGE_INTEGER mappingSize; mappingSize.QuadPart = reserved_size_; hMap_ = CreateFileMappingA( hFile_, NULL, // Security attributes PAGE_READWRITE, // There is not a write only mode for mapping mappingSize.HighPart, // Enable mapping the whole file but the actual // amount mapped is determined by MapViewOfFile mappingSize.LowPart, NULL); // Mapping name if (NULL == hMap_) { return IOErrorFromWindowsError( "WindowsMmapFile failed to create file mapping for: " + filename_, GetLastError()); } mapping_size_ = reserved_size_; } ULARGE_INTEGER offset; offset.QuadPart = file_offset_; // View must begin at the granularity aligned offset mapped_begin_ = reinterpret_cast( MapViewOfFileEx(hMap_, FILE_MAP_WRITE, offset.HighPart, offset.LowPart, view_size_, NULL)); if (!mapped_begin_) { status = IOErrorFromWindowsError( "WindowsMmapFile failed to map file view: " + filename_, GetLastError()); } else { mapped_end_ = mapped_begin_ + view_size_; dst_ = mapped_begin_; last_sync_ = mapped_begin_; pending_sync_ = false; } return status; } Status WinMmapFile::PreallocateInternal(uint64_t spaceToReserve) { return fallocate(filename_, hFile_, spaceToReserve); } WinMmapFile::WinMmapFile(const std::string& fname, HANDLE hFile, size_t page_size, size_t allocation_granularity, const EnvOptions& options) : WinFileData(fname, hFile, false), hMap_(NULL), page_size_(page_size), allocation_granularity_(allocation_granularity), reserved_size_(0), mapping_size_(0), view_size_(0), mapped_begin_(nullptr), mapped_end_(nullptr), dst_(nullptr), last_sync_(nullptr), file_offset_(0), pending_sync_(false) { // Allocation granularity must be obtained from GetSystemInfo() and must be // a power of two. assert(allocation_granularity > 0); assert((allocation_granularity & (allocation_granularity - 1)) == 0); assert(page_size > 0); assert((page_size & (page_size - 1)) == 0); // Only for memory mapped writes assert(options.use_mmap_writes); // View size must be both the multiple of allocation_granularity AND the // page size and the granularity is usually a multiple of a page size. const size_t viewSize = 32 * 1024; // 32Kb similar to the Windows File Cache in buffered mode view_size_ = Roundup(viewSize, allocation_granularity_); } WinMmapFile::~WinMmapFile() { if (hFile_) { this->Close(); } } Status WinMmapFile::Append(const Slice& data) { const char* src = data.data(); size_t left = data.size(); while (left > 0) { assert(mapped_begin_ <= dst_); size_t avail = mapped_end_ - dst_; if (avail == 0) { Status s = UnmapCurrentRegion(); if (s.ok()) { s = MapNewRegion(); } if (!s.ok()) { return s; } } else { size_t n = std::min(left, avail); memcpy(dst_, src, n); dst_ += n; src += n; left -= n; pending_sync_ = true; } } // Now make sure that the last partial page is padded with zeros if needed size_t bytesToPad = Roundup(size_t(dst_), page_size_) - size_t(dst_); if (bytesToPad > 0) { memset(dst_, 0, bytesToPad); } return Status::OK(); } // Means Close() will properly take care of truncate // and it does not need any additional information Status WinMmapFile::Truncate(uint64_t size) { return Status::OK(); } Status WinMmapFile::Close() { Status s; assert(NULL != hFile_); // We truncate to the precise size so no // uninitialized data at the end. SetEndOfFile // which we use does not write zeros and it is good. uint64_t targetSize = GetFileSize(); if (mapped_begin_ != nullptr) { // Sync before unmapping to make sure everything // is on disk and there is not a lazy writing // so we are deterministic with the tests Sync(); s = UnmapCurrentRegion(); } if (NULL != hMap_) { BOOL ret = ::CloseHandle(hMap_); if (!ret && s.ok()) { auto lastError = GetLastError(); s = IOErrorFromWindowsError( "Failed to Close mapping for file: " + filename_, lastError); } hMap_ = NULL; } if (hFile_ != NULL) { TruncateFile(targetSize); BOOL ret = ::CloseHandle(hFile_); hFile_ = NULL; if (!ret && s.ok()) { auto lastError = GetLastError(); s = IOErrorFromWindowsError( "Failed to close file map handle: " + filename_, lastError); } } return s; } Status WinMmapFile::Flush() { return Status::OK(); } // Flush only data Status WinMmapFile::Sync() { Status s; // Some writes occurred since last sync if (dst_ > last_sync_) { assert(mapped_begin_); assert(dst_); assert(dst_ > mapped_begin_); assert(dst_ < mapped_end_); size_t page_begin = TruncateToPageBoundary(page_size_, last_sync_ - mapped_begin_); size_t page_end = TruncateToPageBoundary(page_size_, dst_ - mapped_begin_ - 1); // Flush only the amount of that is a multiple of pages if (!::FlushViewOfFile(mapped_begin_ + page_begin, (page_end - page_begin) + page_size_)) { s = IOErrorFromWindowsError("Failed to FlushViewOfFile: " + filename_, GetLastError()); } else { last_sync_ = dst_; } } return s; } /** * Flush data as well as metadata to stable storage. */ Status WinMmapFile::Fsync() { Status s = Sync(); // Flush metadata if (s.ok() && pending_sync_) { if (!::FlushFileBuffers(hFile_)) { s = IOErrorFromWindowsError("Failed to FlushFileBuffers: " + filename_, GetLastError()); } pending_sync_ = false; } return s; } /** * Get the size of valid data in the file. This will not match the * size that is returned from the filesystem because we use mmap * to extend file by map_size every time. */ uint64_t WinMmapFile::GetFileSize() { size_t used = dst_ - mapped_begin_; return file_offset_ + used; } Status WinMmapFile::InvalidateCache(size_t offset, size_t length) { return Status::OK(); } Status WinMmapFile::Allocate(uint64_t offset, uint64_t len) { Status status; TEST_KILL_RANDOM("WinMmapFile::Allocate", rocksdb_kill_odds); // Make sure that we reserve an aligned amount of space // since the reservation block size is driven outside so we want // to check if we are ok with reservation here size_t spaceToReserve = Roundup(offset + len, view_size_); // Nothing to do if (spaceToReserve <= reserved_size_) { return status; } IOSTATS_TIMER_GUARD(allocate_nanos); status = PreallocateInternal(spaceToReserve); if (status.ok()) { reserved_size_ = spaceToReserve; } return status; } size_t WinMmapFile::GetUniqueId(char* id, size_t max_size) const { return GetUniqueIdFromFile(hFile_, id, max_size); } ////////////////////////////////////////////////////////////////////////////////// // WinSequentialFile WinSequentialFile::WinSequentialFile(const std::string& fname, HANDLE f, const EnvOptions& options) : WinFileData(fname, f, options.use_direct_reads) {} WinSequentialFile::~WinSequentialFile() { assert(hFile_ != INVALID_HANDLE_VALUE); } Status WinSequentialFile::Read(size_t n, Slice* result, char* scratch) { Status s; size_t r = 0; // Windows ReadFile API accepts a DWORD. // While it is possible to read in a loop if n is > UINT_MAX // it is a highly unlikely case. if (n > UINT_MAX) { return IOErrorFromWindowsError(filename_, ERROR_INVALID_PARAMETER); } DWORD bytesToRead = static_cast(n); //cast is safe due to the check above DWORD bytesRead = 0; BOOL ret = ReadFile(hFile_, scratch, bytesToRead, &bytesRead, NULL); if (ret == TRUE) { r = bytesRead; } else { return IOErrorFromWindowsError(filename_, GetLastError()); } *result = Slice(scratch, r); return s; } Status WinSequentialFile::Skip(uint64_t n) { // Can't handle more than signed max as SetFilePointerEx accepts a signed 64-bit // integer. As such it is a highly unlikley case to have n so large. if (n > _I64_MAX) { return IOErrorFromWindowsError(filename_, ERROR_INVALID_PARAMETER); } LARGE_INTEGER li; li.QuadPart = static_cast(n); //cast is safe due to the check above BOOL ret = SetFilePointerEx(hFile_, li, NULL, FILE_CURRENT); if (ret == FALSE) { return IOErrorFromWindowsError(filename_, GetLastError()); } return Status::OK(); } Status WinSequentialFile::InvalidateCache(size_t offset, size_t length) { return Status::OK(); } ////////////////////////////////////////////////////////////////////////////////////////////////// /// WinRandomAccessBase // Helper void CalculateReadParameters(size_t alignment, uint64_t offset, size_t bytes_requested, size_t& actual_bytes_toread, uint64_t& first_page_start) { first_page_start = TruncateToPageBoundary(alignment, offset); const uint64_t last_page_start = TruncateToPageBoundary(alignment, offset + bytes_requested - 1); actual_bytes_toread = (last_page_start - first_page_start) + alignment; } SSIZE_T WinRandomAccessImpl::ReadIntoBuffer(uint64_t user_offset, uint64_t first_page_start, size_t bytes_to_read, size_t& left, AlignedBuffer& buffer, char* dest) const { assert(buffer.CurrentSize() == 0); assert(buffer.Capacity() >= bytes_to_read); SSIZE_T read = PositionedReadInternal(buffer.Destination(), bytes_to_read, first_page_start); if (read > 0) { buffer.Size(read); // Let's figure out how much we read from the users standpoint if ((first_page_start + buffer.CurrentSize()) > user_offset) { assert(first_page_start <= user_offset); size_t buffer_offset = user_offset - first_page_start; read = buffer.Read(dest, buffer_offset, left); } else { read = 0; } left -= read; } return read; } SSIZE_T WinRandomAccessImpl::ReadIntoOneShotBuffer(uint64_t user_offset, uint64_t first_page_start, size_t bytes_to_read, size_t& left, char* dest) const { AlignedBuffer bigBuffer; bigBuffer.Alignment(buffer_.Alignment()); bigBuffer.AllocateNewBuffer(bytes_to_read); return ReadIntoBuffer(user_offset, first_page_start, bytes_to_read, left, bigBuffer, dest); } SSIZE_T WinRandomAccessImpl::ReadIntoInstanceBuffer(uint64_t user_offset, uint64_t first_page_start, size_t bytes_to_read, size_t& left, char* dest) const { SSIZE_T read = ReadIntoBuffer(user_offset, first_page_start, bytes_to_read, left, buffer_, dest); if (read > 0) { buffered_start_ = first_page_start; } return read; } SSIZE_T WinRandomAccessImpl::PositionedReadInternal(char* src, size_t numBytes, uint64_t offset) const { return pread(file_base_->GetFileHandle(), src, numBytes, offset); } inline WinRandomAccessImpl::WinRandomAccessImpl(WinFileData* file_base, size_t alignment, const EnvOptions& options) : file_base_(file_base), read_ahead_(false), compaction_readahead_size_(options.compaction_readahead_size), random_access_max_buffer_size_(options.random_access_max_buffer_size), buffer_(), buffered_start_(0) { assert(!options.use_mmap_reads); // Direct access, use internal buffer for reads if (file_base_->UseDirectIO()) { // Do not allocate the buffer either until the first request or // until there is a call to allocate a read-ahead buffer buffer_.Alignment(alignment); } } inline Status WinRandomAccessImpl::ReadImpl(uint64_t offset, size_t n, Slice* result, char* scratch) const { Status s; SSIZE_T r = -1; size_t left = n; char* dest = scratch; if (n == 0) { *result = Slice(scratch, 0); return s; } // When in direct I/O mode we need to do the following changes: // - use our own aligned buffer // - always read at the offset of that is a multiple of alignment if (file_base_->UseDirectIO()) { uint64_t first_page_start = 0; size_t actual_bytes_toread = 0; size_t bytes_requested = left; if (!read_ahead_ && random_access_max_buffer_size_ == 0) { CalculateReadParameters(buffer_.Alignment(), offset, bytes_requested, actual_bytes_toread, first_page_start); assert(actual_bytes_toread > 0); r = ReadIntoOneShotBuffer(offset, first_page_start, actual_bytes_toread, left, dest); } else { std::unique_lock lock(buffer_mut_); // Let's see if at least some of the requested data is already // in the buffer if (offset >= buffered_start_ && offset < (buffered_start_ + buffer_.CurrentSize())) { size_t buffer_offset = offset - buffered_start_; r = buffer_.Read(dest, buffer_offset, left); assert(r >= 0); left -= size_t(r); offset += r; dest += r; } // Still some left or none was buffered if (left > 0) { // Figure out the start/end offset for reading and amount to read bytes_requested = left; if (read_ahead_ && bytes_requested < compaction_readahead_size_) { bytes_requested = compaction_readahead_size_; } CalculateReadParameters(buffer_.Alignment(), offset, bytes_requested, actual_bytes_toread, first_page_start); assert(actual_bytes_toread > 0); if (buffer_.Capacity() < actual_bytes_toread) { // If we are in read-ahead mode or the requested size // exceeds max buffer size then use one-shot // big buffer otherwise reallocate main buffer if (read_ahead_ || (actual_bytes_toread > random_access_max_buffer_size_)) { // Unlock the mutex since we are not using instance buffer lock.unlock(); r = ReadIntoOneShotBuffer(offset, first_page_start, actual_bytes_toread, left, dest); } else { buffer_.AllocateNewBuffer(actual_bytes_toread); r = ReadIntoInstanceBuffer(offset, first_page_start, actual_bytes_toread, left, dest); } } else { buffer_.Clear(); r = ReadIntoInstanceBuffer(offset, first_page_start, actual_bytes_toread, left, dest); } } } } else { r = PositionedReadInternal(scratch, left, offset); if (r > 0) { left -= r; } } if (r < 0) { auto lastError = GetLastError(); // Posix impl wants to treat reads from beyond // of the file as OK. if(lastError != ERROR_HANDLE_EOF) { s = IOErrorFromWindowsError(file_base_->GetName(), lastError); } } *result = Slice(scratch, (r < 0) ? 0 : n - left); return s; } inline void WinRandomAccessImpl::HintImpl(RandomAccessFile::AccessPattern pattern) { if (pattern == RandomAccessFile::SEQUENTIAL && file_base_->UseDirectIO() && compaction_readahead_size_ > 0) { std::lock_guard lg(buffer_mut_); if (!read_ahead_) { read_ahead_ = true; // This would allocate read-ahead size + 2 alignments // - one for memory alignment which added implicitly by AlignedBuffer // - We add one more alignment because we will read one alignment more // from disk buffer_.AllocateNewBuffer(compaction_readahead_size_ + buffer_.Alignment()); } } } /////////////////////////////////////////////////////////////////////////////////////////////////// /// WinRandomAccessFile WinRandomAccessFile::WinRandomAccessFile(const std::string& fname, HANDLE hFile, size_t alignment, const EnvOptions& options) : WinFileData(fname, hFile, options.use_direct_reads), WinRandomAccessImpl(this, alignment, options) {} WinRandomAccessFile::~WinRandomAccessFile() { } Status WinRandomAccessFile::Read(uint64_t offset, size_t n, Slice* result, char* scratch) const { return ReadImpl(offset, n, result, scratch); } void WinRandomAccessFile::EnableReadAhead() { HintImpl(SEQUENTIAL); } bool WinRandomAccessFile::ShouldForwardRawRequest() const { return true; } void WinRandomAccessFile::Hint(AccessPattern pattern) { HintImpl(pattern); } Status WinRandomAccessFile::InvalidateCache(size_t offset, size_t length) { return Status::OK(); } size_t WinRandomAccessFile::GetUniqueId(char* id, size_t max_size) const { return GetUniqueIdFromFile(GetFileHandle(), id, max_size); } ///////////////////////////////////////////////////////////////////////////// // WinWritableImpl // inline Status WinWritableImpl::PreallocateInternal(uint64_t spaceToReserve) { return fallocate(file_data_->GetName(), file_data_->GetFileHandle(), spaceToReserve); } WinWritableImpl::WinWritableImpl(WinFileData* file_data, size_t alignment) : file_data_(file_data), alignment_(alignment), filesize_(0), reservedsize_(0) { } Status WinWritableImpl::AppendImpl(const Slice& data) { Status s; assert(data.size() < std::numeric_limits::max()); uint64_t written = 0; if (file_data_->UseDirectIO()) { // With no offset specified we are appending // to the end of the file assert(IsSectorAligned(filesize_)); assert(IsSectorAligned(data.size())); assert(IsAligned(GetAlignement(), data.data())); SSIZE_T ret = pwrite(file_data_->GetFileHandle(), data.data(), data.size(), filesize_); if (ret < 0) { auto lastError = GetLastError(); s = IOErrorFromWindowsError( "Failed to pwrite for: " + file_data_->GetName(), lastError); } else { written = ret; } } else { DWORD bytesWritten = 0; if (!WriteFile(file_data_->GetFileHandle(), data.data(), static_cast(data.size()), &bytesWritten, NULL)) { auto lastError = GetLastError(); s = IOErrorFromWindowsError( "Failed to WriteFile: " + file_data_->GetName(), lastError); } else { written = bytesWritten; } } if(s.ok()) { assert(written == data.size()); filesize_ += data.size(); } return s; } Status WinWritableImpl::PositionedAppendImpl(const Slice& data, uint64_t offset) { if(file_data_->UseDirectIO()) { assert(IsSectorAligned(offset)); assert(IsSectorAligned(data.size())); assert(IsAligned(GetAlignement(), data.data())); } Status s; SSIZE_T ret = pwrite(file_data_->GetFileHandle(), data.data(), data.size(), offset); // Error break if (ret < 0) { auto lastError = GetLastError(); s = IOErrorFromWindowsError( "Failed to pwrite for: " + file_data_->GetName(), lastError); } else { assert(size_t(ret) == data.size()); // For sequential write this would be simple // size extension by data.size() uint64_t write_end = offset + data.size(); if (write_end >= filesize_) { filesize_ = write_end; } } return s; } // Need to implement this so the file is truncated correctly // when buffered and unbuffered mode inline Status WinWritableImpl::TruncateImpl(uint64_t size) { Status s = ftruncate(file_data_->GetName(), file_data_->GetFileHandle(), size); if (s.ok()) { filesize_ = size; } return s; } Status WinWritableImpl::CloseImpl() { Status s; auto hFile = file_data_->GetFileHandle(); assert(INVALID_HANDLE_VALUE != hFile); if (fsync(hFile) < 0) { auto lastError = GetLastError(); s = IOErrorFromWindowsError("fsync failed at Close() for: " + file_data_->GetName(), lastError); } if(!file_data_->CloseFile()) { auto lastError = GetLastError(); s = IOErrorFromWindowsError("CloseHandle failed for: " + file_data_->GetName(), lastError); } return s; } Status WinWritableImpl::SyncImpl() { Status s; // Calls flush buffers if (fsync(file_data_->GetFileHandle()) < 0) { auto lastError = GetLastError(); s = IOErrorFromWindowsError( "fsync failed at Sync() for: " + file_data_->GetName(), lastError); } return s; } Status WinWritableImpl::AllocateImpl(uint64_t offset, uint64_t len) { Status status; TEST_KILL_RANDOM("WinWritableFile::Allocate", rocksdb_kill_odds); // Make sure that we reserve an aligned amount of space // since the reservation block size is driven outside so we want // to check if we are ok with reservation here size_t spaceToReserve = Roundup(offset + len, alignment_); // Nothing to do if (spaceToReserve <= reservedsize_) { return status; } IOSTATS_TIMER_GUARD(allocate_nanos); status = PreallocateInternal(spaceToReserve); if (status.ok()) { reservedsize_ = spaceToReserve; } return status; } //////////////////////////////////////////////////////////////////////////////// /// WinWritableFile WinWritableFile::WinWritableFile(const std::string& fname, HANDLE hFile, size_t alignment, size_t /* capacity */, const EnvOptions& options) : WinFileData(fname, hFile, options.use_direct_writes), WinWritableImpl(this, alignment) { assert(!options.use_mmap_writes); } WinWritableFile::~WinWritableFile() { } // Indicates if the class makes use of direct I/O bool WinWritableFile::UseDirectIO() const { return WinFileData::UseDirectIO(); } size_t WinWritableFile::GetRequiredBufferAlignment() const { return GetAlignement(); } Status WinWritableFile::Append(const Slice& data) { return AppendImpl(data); } Status WinWritableFile::PositionedAppend(const Slice& data, uint64_t offset) { return PositionedAppendImpl(data, offset); } // Need to implement this so the file is truncated correctly // when buffered and unbuffered mode Status WinWritableFile::Truncate(uint64_t size) { return TruncateImpl(size); } Status WinWritableFile::Close() { return CloseImpl(); } // write out the cached data to the OS cache // This is now taken care of the WritableFileWriter Status WinWritableFile::Flush() { return Status::OK(); } Status WinWritableFile::Sync() { return SyncImpl(); } Status WinWritableFile::Fsync() { return SyncImpl(); } uint64_t WinWritableFile::GetFileSize() { return GetFileSizeImpl(); } Status WinWritableFile::Allocate(uint64_t offset, uint64_t len) { return AllocateImpl(offset, len); } size_t WinWritableFile::GetUniqueId(char* id, size_t max_size) const { return GetUniqueIdFromFile(GetFileHandle(), id, max_size); } ///////////////////////////////////////////////////////////////////////// /// WinRandomRWFile WinRandomRWFile::WinRandomRWFile(const std::string& fname, HANDLE hFile, size_t alignment, const EnvOptions& options) : WinFileData(fname, hFile, options.use_direct_reads && options.use_direct_writes), WinRandomAccessImpl(this, alignment, options), WinWritableImpl(this, alignment) {} bool WinRandomRWFile::UseDirectIO() const { return WinFileData::UseDirectIO(); } size_t WinRandomRWFile::GetRequiredBufferAlignment() const { return GetAlignement(); } bool WinRandomRWFile::ShouldForwardRawRequest() const { return true; } void WinRandomRWFile::EnableReadAhead() { HintImpl(RandomAccessFile::SEQUENTIAL); } Status WinRandomRWFile::Write(uint64_t offset, const Slice & data) { return PositionedAppendImpl(data, offset); } Status WinRandomRWFile::Read(uint64_t offset, size_t n, Slice* result, char* scratch) const { return ReadImpl(offset, n, result, scratch); } Status WinRandomRWFile::Flush() { return Status::OK(); } Status WinRandomRWFile::Sync() { return SyncImpl(); } Status WinRandomRWFile::Close() { return CloseImpl(); } ////////////////////////////////////////////////////////////////////////// /// WinDirectory Status WinDirectory::Fsync() { return Status::OK(); } ////////////////////////////////////////////////////////////////////////// /// WinFileLock WinFileLock::~WinFileLock() { BOOL ret = ::CloseHandle(hFile_); assert(ret); } } }