// Copyright (c) Facebook, Inc. and its affiliates. 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). #pragma once #ifndef ROCKSDB_LITE #include #include "file/random_access_file_reader.h" #include "file/writable_file_writer.h" #include "rocksdb/utilities/cache_dump_load.h" #include "table/block_based/block.h" #include "table/block_based/block_type.h" #include "table/block_based/cachable_entry.h" #include "table/block_based/parsed_full_filter_block.h" #include "table/block_based/reader_common.h" #include "util/hash_containers.h" namespace ROCKSDB_NAMESPACE { // the read buffer size of for the default CacheDumpReader const unsigned int kDumpReaderBufferSize = 1024; // 1KB static const unsigned int kSizePrefixLen = 4; enum CacheDumpUnitType : unsigned char { kHeader = 1, kFooter = 2, kData = 3, kFilter = 4, kProperties = 5, kCompressionDictionary = 6, kRangeDeletion = 7, kHashIndexPrefixes = 8, kHashIndexMetadata = 9, kMetaIndex = 10, kIndex = 11, kDeprecatedFilterBlock = 12, // OBSOLETE / DEPRECATED kFilterMetaBlock = 13, kBlockTypeMax, }; // The metadata of a dump unit. After it is serilized, its size is fixed 16 // bytes. struct DumpUnitMeta { // sequence number is a monotonically increasing number to indicate the order // of the blocks being written. Header is 0. uint32_t sequence_num; // The Crc32c checksum of its dump unit. uint32_t dump_unit_checksum; // The dump unit size after the dump unit is serilized to a string. uint64_t dump_unit_size; void reset() { sequence_num = 0; dump_unit_checksum = 0; dump_unit_size = 0; } }; // The data structure to hold a block and its information. struct DumpUnit { // The timestamp when the block is identified, copied, and dumped from block // cache uint64_t timestamp; // The type of the block CacheDumpUnitType type; // The key of this block when the block is referenced by this Cache Slice key; // The block size size_t value_len; // The Crc32c checksum of the block uint32_t value_checksum; // Pointer to the block. Note that, in the dump process, it points to a memory // buffer copied from cache block. The buffer is freed when we process the // next block. In the load process, we use an std::string to store the // serialized dump_unit read from the reader. So it points to the memory // address of the begin of the block in this string. void* value; DumpUnit() { reset(); } void reset() { timestamp = 0; type = CacheDumpUnitType::kBlockTypeMax; key.clear(); value_len = 0; value_checksum = 0; value = nullptr; } }; // The default implementation of the Cache Dumper class CacheDumperImpl : public CacheDumper { public: CacheDumperImpl(const CacheDumpOptions& dump_options, const std::shared_ptr& cache, std::unique_ptr&& writer) : options_(dump_options), cache_(cache), writer_(std::move(writer)) {} ~CacheDumperImpl() { writer_.reset(); } Status SetDumpFilter(std::vector db_list) override; IOStatus DumpCacheEntriesToWriter() override; private: IOStatus WriteBlock(CacheDumpUnitType type, const Slice& key, const Slice& value); IOStatus WriteHeader(); IOStatus WriteFooter(); bool ShouldFilterOut(const Slice& key); std::function DumpOneBlockCallBack(std::string& buf); CacheDumpOptions options_; std::shared_ptr cache_; std::unique_ptr writer_; SystemClock* clock_; uint32_t sequence_num_; // The cache key prefix filter. Currently, we use db_session_id as the prefix, // so using std::set to store the prefixes as filter is enough. Further // improvement can be applied like BloomFilter or others to speedup the // filtering. std::set prefix_filter_; }; // The default implementation of CacheDumpedLoader class CacheDumpedLoaderImpl : public CacheDumpedLoader { public: CacheDumpedLoaderImpl(const CacheDumpOptions& dump_options, const BlockBasedTableOptions& /*toptions*/, const std::shared_ptr& secondary_cache, std::unique_ptr&& reader) : options_(dump_options), secondary_cache_(secondary_cache), reader_(std::move(reader)) {} ~CacheDumpedLoaderImpl() {} IOStatus RestoreCacheEntriesToSecondaryCache() override; private: IOStatus ReadDumpUnitMeta(std::string* data, DumpUnitMeta* unit_meta); IOStatus ReadDumpUnit(size_t len, std::string* data, DumpUnit* unit); IOStatus ReadHeader(std::string* data, DumpUnit* dump_unit); IOStatus ReadCacheBlock(std::string* data, DumpUnit* dump_unit); CacheDumpOptions options_; std::shared_ptr secondary_cache_; std::unique_ptr reader_; }; // The default implementation of CacheDumpWriter. We write the blocks to a file // sequentially. class ToFileCacheDumpWriter : public CacheDumpWriter { public: explicit ToFileCacheDumpWriter( std::unique_ptr&& file_writer) : file_writer_(std::move(file_writer)) {} ~ToFileCacheDumpWriter() { Close().PermitUncheckedError(); } // Write the serialized metadata to the file virtual IOStatus WriteMetadata(const Slice& metadata) override { assert(file_writer_ != nullptr); std::string prefix; PutFixed32(&prefix, static_cast(metadata.size())); IOStatus io_s = file_writer_->Append(Slice(prefix)); if (!io_s.ok()) { return io_s; } io_s = file_writer_->Append(metadata); return io_s; } // Write the serialized data to the file virtual IOStatus WritePacket(const Slice& data) override { assert(file_writer_ != nullptr); std::string prefix; PutFixed32(&prefix, static_cast(data.size())); IOStatus io_s = file_writer_->Append(Slice(prefix)); if (!io_s.ok()) { return io_s; } io_s = file_writer_->Append(data); return io_s; } // Reset the writer virtual IOStatus Close() override { file_writer_.reset(); return IOStatus::OK(); } private: std::unique_ptr file_writer_; }; // The default implementation of CacheDumpReader. It is implemented based on // RandomAccessFileReader. Note that, we keep an internal variable to remember // the current offset. class FromFileCacheDumpReader : public CacheDumpReader { public: explicit FromFileCacheDumpReader( std::unique_ptr&& reader) : file_reader_(std::move(reader)), offset_(0), buffer_(new char[kDumpReaderBufferSize]) {} ~FromFileCacheDumpReader() { delete[] buffer_; } virtual IOStatus ReadMetadata(std::string* metadata) override { uint32_t metadata_len = 0; IOStatus io_s = ReadSizePrefix(&metadata_len); if (!io_s.ok()) { return io_s; } return Read(metadata_len, metadata); } virtual IOStatus ReadPacket(std::string* data) override { uint32_t data_len = 0; IOStatus io_s = ReadSizePrefix(&data_len); if (!io_s.ok()) { return io_s; } return Read(data_len, data); } private: IOStatus ReadSizePrefix(uint32_t* len) { std::string prefix; IOStatus io_s = Read(kSizePrefixLen, &prefix); if (!io_s.ok()) { return io_s; } Slice encoded_slice(prefix); if (!GetFixed32(&encoded_slice, len)) { return IOStatus::Corruption("Decode size prefix string failed"); } return IOStatus::OK(); } IOStatus Read(size_t len, std::string* data) { assert(file_reader_ != nullptr); IOStatus io_s; unsigned int bytes_to_read = static_cast(len); unsigned int to_read = bytes_to_read > kDumpReaderBufferSize ? kDumpReaderBufferSize : bytes_to_read; while (to_read > 0) { io_s = file_reader_->Read(IOOptions(), offset_, to_read, &result_, buffer_, nullptr, Env::IO_TOTAL /* rate_limiter_priority */); if (!io_s.ok()) { return io_s; } if (result_.size() < to_read) { return IOStatus::Corruption("Corrupted cache dump file."); } data->append(result_.data(), result_.size()); offset_ += to_read; bytes_to_read -= to_read; to_read = bytes_to_read > kDumpReaderBufferSize ? kDumpReaderBufferSize : bytes_to_read; } return io_s; } std::unique_ptr file_reader_; Slice result_; size_t offset_; char* buffer_; }; // The cache dump and load helper class class CacheDumperHelper { public: // serialize the dump_unit_meta to a string, it is fixed 16 bytes size. static void EncodeDumpUnitMeta(const DumpUnitMeta& meta, std::string* data) { assert(data); PutFixed32(data, static_cast(meta.sequence_num)); PutFixed32(data, static_cast(meta.dump_unit_checksum)); PutFixed64(data, meta.dump_unit_size); } // Serialize the dump_unit to a string. static void EncodeDumpUnit(const DumpUnit& dump_unit, std::string* data) { assert(data); PutFixed64(data, dump_unit.timestamp); data->push_back(dump_unit.type); PutLengthPrefixedSlice(data, dump_unit.key); PutFixed32(data, static_cast(dump_unit.value_len)); PutFixed32(data, dump_unit.value_checksum); PutLengthPrefixedSlice(data, Slice((char*)dump_unit.value, dump_unit.value_len)); } // Deserialize the dump_unit_meta from a string static Status DecodeDumpUnitMeta(const std::string& encoded_data, DumpUnitMeta* unit_meta) { assert(unit_meta != nullptr); Slice encoded_slice = Slice(encoded_data); if (!GetFixed32(&encoded_slice, &(unit_meta->sequence_num))) { return Status::Incomplete("Decode dumped unit meta sequence_num failed"); } if (!GetFixed32(&encoded_slice, &(unit_meta->dump_unit_checksum))) { return Status::Incomplete( "Decode dumped unit meta dump_unit_checksum failed"); } if (!GetFixed64(&encoded_slice, &(unit_meta->dump_unit_size))) { return Status::Incomplete( "Decode dumped unit meta dump_unit_size failed"); } return Status::OK(); } // Deserialize the dump_unit from a string. static Status DecodeDumpUnit(const std::string& encoded_data, DumpUnit* dump_unit) { assert(dump_unit != nullptr); Slice encoded_slice = Slice(encoded_data); // Decode timestamp if (!GetFixed64(&encoded_slice, &dump_unit->timestamp)) { return Status::Incomplete("Decode dumped unit string failed"); } // Decode the block type dump_unit->type = static_cast(encoded_slice[0]); encoded_slice.remove_prefix(1); // Decode the key if (!GetLengthPrefixedSlice(&encoded_slice, &(dump_unit->key))) { return Status::Incomplete("Decode dumped unit string failed"); } // Decode the value size uint32_t value_len; if (!GetFixed32(&encoded_slice, &value_len)) { return Status::Incomplete("Decode dumped unit string failed"); } dump_unit->value_len = static_cast(value_len); // Decode the value checksum if (!GetFixed32(&encoded_slice, &(dump_unit->value_checksum))) { return Status::Incomplete("Decode dumped unit string failed"); } // Decode the block content and copy to the memory space whose pointer // will be managed by the cache finally. Slice block; if (!GetLengthPrefixedSlice(&encoded_slice, &block)) { return Status::Incomplete("Decode dumped unit string failed"); } dump_unit->value = (void*)block.data(); assert(block.size() == dump_unit->value_len); return Status::OK(); } }; } // namespace ROCKSDB_NAMESPACE #endif // ROCKSDB_LITE