// Copyright (c) 2011-present, Facebook, Inc. All rights reserved. // This source code is licensed under both the GPLv2 (found in the // COPYING file in the root directory) and Apache 2.0 License // (found in the LICENSE.Apache file in the root 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 "table/block_fetcher.h" #include #include #include #include "logging/logging.h" #include "memory/memory_allocator_impl.h" #include "monitoring/perf_context_imp.h" #include "rocksdb/compression_type.h" #include "rocksdb/env.h" #include "table/block_based/block.h" #include "table/block_based/block_based_table_reader.h" #include "table/block_based/block_type.h" #include "table/block_based/reader_common.h" #include "table/format.h" #include "table/persistent_cache_helper.h" #include "util/compression.h" #include "util/stop_watch.h" namespace ROCKSDB_NAMESPACE { inline void BlockFetcher::ProcessTrailerIfPresent() { if (footer_.GetBlockTrailerSize() > 0) { assert(footer_.GetBlockTrailerSize() == BlockBasedTable::kBlockTrailerSize); if (read_options_.verify_checksums) { io_status_ = status_to_io_status( VerifyBlockChecksum(footer_, slice_.data(), block_size_, file_->file_name(), handle_.offset())); RecordTick(ioptions_.stats, BLOCK_CHECKSUM_COMPUTE_COUNT); if (!io_status_.ok()) { assert(io_status_.IsCorruption()); RecordTick(ioptions_.stats, BLOCK_CHECKSUM_MISMATCH_COUNT); } } compression_type_ = BlockBasedTable::GetBlockCompressionType(slice_.data(), block_size_); } else { // E.g. plain table or cuckoo table compression_type_ = kNoCompression; } } inline bool BlockFetcher::TryGetUncompressBlockFromPersistentCache() { if (cache_options_.persistent_cache && !cache_options_.persistent_cache->IsCompressed()) { Status status = PersistentCacheHelper::LookupUncompressed( cache_options_, handle_, contents_); if (status.ok()) { // uncompressed page is found for the block handle return true; } else { // uncompressed page is not found if (ioptions_.logger && !status.IsNotFound()) { assert(!status.ok()); ROCKS_LOG_INFO(ioptions_.logger, "Error reading from persistent cache. %s", status.ToString().c_str()); } } } return false; } inline bool BlockFetcher::TryGetFromPrefetchBuffer() { if (prefetch_buffer_ != nullptr) { IOOptions opts; IOStatus io_s = file_->PrepareIOOptions(read_options_, opts); if (io_s.ok()) { bool read_from_prefetch_buffer = prefetch_buffer_->TryReadFromCache( opts, file_, handle_.offset(), block_size_with_trailer_, &slice_, &io_s, for_compaction_); if (read_from_prefetch_buffer) { ProcessTrailerIfPresent(); if (io_status_.ok()) { got_from_prefetch_buffer_ = true; used_buf_ = const_cast(slice_.data()); } else if (!(io_status_.IsCorruption() && retry_corrupt_read_)) { return true; } } } if (!io_s.ok()) { io_status_ = io_s; return true; } } return got_from_prefetch_buffer_; } inline bool BlockFetcher::TryGetSerializedBlockFromPersistentCache() { if (cache_options_.persistent_cache && cache_options_.persistent_cache->IsCompressed()) { std::unique_ptr buf; io_status_ = status_to_io_status(PersistentCacheHelper::LookupSerialized( cache_options_, handle_, &buf, block_size_with_trailer_)); if (io_status_.ok()) { heap_buf_ = CacheAllocationPtr(buf.release()); used_buf_ = heap_buf_.get(); slice_ = Slice(heap_buf_.get(), block_size_); ProcessTrailerIfPresent(); return true; } else if (!io_status_.IsNotFound() && ioptions_.logger) { assert(!io_status_.ok()); ROCKS_LOG_INFO(ioptions_.logger, "Error reading from persistent cache. %s", io_status_.ToString().c_str()); } } return false; } inline void BlockFetcher::PrepareBufferForBlockFromFile() { // cache miss read from device if ((do_uncompress_ || ioptions_.allow_mmap_reads) && block_size_with_trailer_ < kDefaultStackBufferSize) { // If we've got a small enough chunk of data, read it in to the // trivially allocated stack buffer instead of needing a full malloc() // // `GetBlockContents()` cannot return this data as its lifetime is tied to // this `BlockFetcher`'s lifetime. That is fine because this is only used // in cases where we do not expect the `GetBlockContents()` result to be the // same buffer we are assigning here. If we guess incorrectly, there will be // a heap allocation and memcpy in `GetBlockContents()` to obtain the final // result. Considering we are eliding a heap allocation here by using the // stack buffer, the cost of guessing incorrectly here is one extra memcpy. // // When `do_uncompress_` is true, we expect the uncompression step will // allocate heap memory for the final result. However this expectation will // be wrong if the block turns out to already be uncompressed, which we // won't know for sure until after reading it. // // When `ioptions_.allow_mmap_reads` is true, we do not expect the file // reader to use the scratch buffer at all, but instead return a pointer // into the mapped memory. This expectation will be wrong when using a // file reader that does not implement mmap reads properly. used_buf_ = &stack_buf_[0]; } else if (maybe_compressed_ && !do_uncompress_) { compressed_buf_ = AllocateBlock(block_size_with_trailer_, memory_allocator_compressed_); used_buf_ = compressed_buf_.get(); } else { heap_buf_ = AllocateBlock(block_size_with_trailer_, memory_allocator_); used_buf_ = heap_buf_.get(); } } inline void BlockFetcher::InsertCompressedBlockToPersistentCacheIfNeeded() { if (io_status_.ok() && read_options_.fill_cache && cache_options_.persistent_cache && cache_options_.persistent_cache->IsCompressed()) { PersistentCacheHelper::InsertSerialized(cache_options_, handle_, used_buf_, block_size_with_trailer_); } } inline void BlockFetcher::InsertUncompressedBlockToPersistentCacheIfNeeded() { if (io_status_.ok() && !got_from_prefetch_buffer_ && read_options_.fill_cache && cache_options_.persistent_cache && !cache_options_.persistent_cache->IsCompressed()) { // insert to uncompressed cache PersistentCacheHelper::InsertUncompressed(cache_options_, handle_, *contents_); } } inline void BlockFetcher::CopyBufferToHeapBuf() { assert(used_buf_ != heap_buf_.get()); heap_buf_ = AllocateBlock(block_size_with_trailer_, memory_allocator_); memcpy(heap_buf_.get(), used_buf_, block_size_with_trailer_); #ifndef NDEBUG num_heap_buf_memcpy_++; #endif } inline void BlockFetcher::CopyBufferToCompressedBuf() { assert(used_buf_ != compressed_buf_.get()); compressed_buf_ = AllocateBlock(block_size_with_trailer_, memory_allocator_compressed_); memcpy(compressed_buf_.get(), used_buf_, block_size_with_trailer_); #ifndef NDEBUG num_compressed_buf_memcpy_++; #endif } // Before - Entering this method means the block is uncompressed or do not need // to be uncompressed. // // The block can be in one of the following buffers: // 1. prefetch buffer if prefetch is enabled and the block is prefetched before // 2. stack_buf_ if block size is smaller than the stack_buf_ size and block // is not compressed // 3. heap_buf_ if the block is not compressed // 4. compressed_buf_ if the block is compressed // 5. direct_io_buf_ if direct IO is enabled or // 6. underlying file_system scratch is used (FSReadRequest.fs_scratch). // // After - After this method, if the block is compressed, it should be in // compressed_buf_ and heap_buf_ points to compressed_buf_, otherwise should be // in heap_buf_. inline void BlockFetcher::GetBlockContents() { if (slice_.data() != used_buf_) { // the slice content is not the buffer provided *contents_ = BlockContents(Slice(slice_.data(), block_size_)); } else { // page can be either uncompressed or compressed, the buffer either stack // or heap provided. Refer to https://github.com/facebook/rocksdb/pull/4096 if (got_from_prefetch_buffer_ || used_buf_ == &stack_buf_[0]) { CopyBufferToHeapBuf(); } else if (used_buf_ == compressed_buf_.get()) { if (compression_type_ == kNoCompression && memory_allocator_ != memory_allocator_compressed_) { CopyBufferToHeapBuf(); } else { heap_buf_ = std::move(compressed_buf_); } } else if (direct_io_buf_.get() != nullptr || use_fs_scratch_) { if (compression_type_ == kNoCompression) { CopyBufferToHeapBuf(); } else { CopyBufferToCompressedBuf(); heap_buf_ = std::move(compressed_buf_); } } *contents_ = BlockContents(std::move(heap_buf_), block_size_); } #ifndef NDEBUG contents_->has_trailer = footer_.GetBlockTrailerSize() > 0; #endif } // Read a block from the file and verify its checksum. Upon return, io_status_ // will be updated with the status of the read, and slice_ will be updated // with a pointer to the data. void BlockFetcher::ReadBlock(bool retry) { FSReadRequest read_req; IOOptions opts; io_status_ = file_->PrepareIOOptions(read_options_, opts); opts.verify_and_reconstruct_read = retry; read_req.status.PermitUncheckedError(); // Actual file read if (io_status_.ok()) { if (file_->use_direct_io()) { PERF_TIMER_GUARD(block_read_time); PERF_CPU_TIMER_GUARD( block_read_cpu_time, ioptions_.env ? ioptions_.env->GetSystemClock().get() : nullptr); io_status_ = file_->Read(opts, handle_.offset(), block_size_with_trailer_, &slice_, /*scratch=*/nullptr, &direct_io_buf_); PERF_COUNTER_ADD(block_read_count, 1); used_buf_ = const_cast(slice_.data()); } else if (use_fs_scratch_) { PERF_TIMER_GUARD(block_read_time); PERF_CPU_TIMER_GUARD( block_read_cpu_time, ioptions_.env ? ioptions_.env->GetSystemClock().get() : nullptr); read_req.offset = handle_.offset(); read_req.len = block_size_with_trailer_; read_req.scratch = nullptr; io_status_ = file_->MultiRead(opts, &read_req, /*num_reqs=*/1, /*AlignedBuf* =*/nullptr); PERF_COUNTER_ADD(block_read_count, 1); slice_ = Slice(read_req.result.data(), read_req.result.size()); used_buf_ = const_cast(slice_.data()); } else { // It allocates/assign used_buf_ PrepareBufferForBlockFromFile(); PERF_TIMER_GUARD(block_read_time); PERF_CPU_TIMER_GUARD( block_read_cpu_time, ioptions_.env ? ioptions_.env->GetSystemClock().get() : nullptr); io_status_ = file_->Read( opts, handle_.offset(), /*size*/ block_size_with_trailer_, /*result*/ &slice_, /*scratch*/ used_buf_, /*aligned_buf=*/nullptr); PERF_COUNTER_ADD(block_read_count, 1); #ifndef NDEBUG if (slice_.data() == &stack_buf_[0]) { num_stack_buf_memcpy_++; } else if (slice_.data() == heap_buf_.get()) { num_heap_buf_memcpy_++; } else if (slice_.data() == compressed_buf_.get()) { num_compressed_buf_memcpy_++; } #endif } } // TODO: introduce dedicated perf counter for range tombstones switch (block_type_) { case BlockType::kFilter: case BlockType::kFilterPartitionIndex: PERF_COUNTER_ADD(filter_block_read_count, 1); break; case BlockType::kCompressionDictionary: PERF_COUNTER_ADD(compression_dict_block_read_count, 1); break; case BlockType::kIndex: PERF_COUNTER_ADD(index_block_read_count, 1); break; // Nothing to do here as we don't have counters for the other types. default: break; } PERF_COUNTER_ADD(block_read_byte, block_size_with_trailer_); if (io_status_.ok()) { if (use_fs_scratch_ && !read_req.status.ok()) { io_status_ = read_req.status; } else if (slice_.size() != block_size_with_trailer_) { io_status_ = IOStatus::Corruption( "truncated block read from " + file_->file_name() + " offset " + std::to_string(handle_.offset()) + ", expected " + std::to_string(block_size_with_trailer_) + " bytes, got " + std::to_string(slice_.size())); } } if (io_status_.ok()) { ProcessTrailerIfPresent(); } if (io_status_.ok()) { InsertCompressedBlockToPersistentCacheIfNeeded(); fs_buf_ = std::move(read_req.fs_scratch); } else { ReleaseFileSystemProvidedBuffer(&read_req); direct_io_buf_.reset(); compressed_buf_.reset(); heap_buf_.reset(); used_buf_ = nullptr; } } IOStatus BlockFetcher::ReadBlockContents() { if (TryGetUncompressBlockFromPersistentCache()) { compression_type_ = kNoCompression; #ifndef NDEBUG contents_->has_trailer = footer_.GetBlockTrailerSize() > 0; #endif // NDEBUG return IOStatus::OK(); } if (TryGetFromPrefetchBuffer()) { if (!io_status_.ok()) { return io_status_; } } else if (!TryGetSerializedBlockFromPersistentCache()) { ReadBlock(/*retry =*/false); // If the file system supports retry after corruption, then try to // re-read the block and see if it succeeds. if (io_status_.IsCorruption() && retry_corrupt_read_) { assert(!fs_buf_); ReadBlock(/*retry=*/true); } if (!io_status_.ok()) { assert(!fs_buf_); return io_status_; } } if (do_uncompress_ && compression_type_ != kNoCompression) { PERF_TIMER_GUARD(block_decompress_time); // compressed page, uncompress, update cache UncompressionContext context(compression_type_); UncompressionInfo info(context, uncompression_dict_, compression_type_); io_status_ = status_to_io_status(UncompressSerializedBlock( info, slice_.data(), block_size_, contents_, footer_.format_version(), ioptions_, memory_allocator_)); #ifndef NDEBUG num_heap_buf_memcpy_++; #endif // Save the compressed block without trailer slice_ = Slice(slice_.data(), block_size_); } else { GetBlockContents(); slice_ = Slice(); } InsertUncompressedBlockToPersistentCacheIfNeeded(); return io_status_; } IOStatus BlockFetcher::ReadAsyncBlockContents() { if (TryGetUncompressBlockFromPersistentCache()) { compression_type_ = kNoCompression; #ifndef NDEBUG contents_->has_trailer = footer_.GetBlockTrailerSize() > 0; #endif // NDEBUG return IOStatus::OK(); } else if (!TryGetSerializedBlockFromPersistentCache()) { assert(prefetch_buffer_ != nullptr); if (!for_compaction_) { IOOptions opts; IOStatus io_s = file_->PrepareIOOptions(read_options_, opts); if (!io_s.ok()) { return io_s; } io_s = status_to_io_status(prefetch_buffer_->PrefetchAsync( opts, file_, handle_.offset(), block_size_with_trailer_, &slice_)); if (io_s.IsTryAgain()) { return io_s; } if (io_s.ok()) { // Data Block is already in prefetch. got_from_prefetch_buffer_ = true; ProcessTrailerIfPresent(); if (io_status_.IsCorruption() && retry_corrupt_read_) { got_from_prefetch_buffer_ = false; ReadBlock(/*retry = */ true); } if (!io_status_.ok()) { assert(!fs_buf_); return io_status_; } used_buf_ = const_cast(slice_.data()); if (do_uncompress_ && compression_type_ != kNoCompression) { PERF_TIMER_GUARD(block_decompress_time); // compressed page, uncompress, update cache UncompressionContext context(compression_type_); UncompressionInfo info(context, uncompression_dict_, compression_type_); io_status_ = status_to_io_status(UncompressSerializedBlock( info, slice_.data(), block_size_, contents_, footer_.format_version(), ioptions_, memory_allocator_)); #ifndef NDEBUG num_heap_buf_memcpy_++; #endif } else { GetBlockContents(); } InsertUncompressedBlockToPersistentCacheIfNeeded(); return io_status_; } } // Fallback to sequential reading of data blocks in case of io_s returns // error or for_compaction_is true. return ReadBlockContents(); } return io_status_; } } // namespace ROCKSDB_NAMESPACE