mirror of https://github.com/facebook/rocksdb.git
712 lines
32 KiB
C++
712 lines
32 KiB
C++
// Copyright (c) Facebook, Inc. and its affiliates. All Rights Reserved.
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// Copyright (c) 2011 The LevelDB Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file. See the AUTHORS file for names of contributors.
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//
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// Currently we support two types of tables: plain table and block-based table.
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// 1. Block-based table: this is the default table type that we inherited from
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// LevelDB, which was designed for storing data in hard disk or flash
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// device.
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// 2. Plain table: it is one of RocksDB's SST file format optimized
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// for low query latency on pure-memory or really low-latency media.
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//
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// A tutorial of rocksdb table formats is available here:
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// https://github.com/facebook/rocksdb/wiki/A-Tutorial-of-RocksDB-SST-formats
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//
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// Example code is also available
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// https://github.com/facebook/rocksdb/wiki/A-Tutorial-of-RocksDB-SST-formats#wiki-examples
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#pragma once
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#include <memory>
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#include <string>
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#include <unordered_map>
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#include "rocksdb/customizable.h"
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#include "rocksdb/env.h"
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#include "rocksdb/options.h"
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#include "rocksdb/status.h"
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namespace ROCKSDB_NAMESPACE {
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// -- Block-based Table
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class Cache;
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class FilterPolicy;
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class FlushBlockPolicyFactory;
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class PersistentCache;
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class RandomAccessFile;
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struct TableReaderOptions;
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struct TableBuilderOptions;
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class TableBuilder;
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class TableFactory;
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class TableReader;
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class WritableFileWriter;
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struct ConfigOptions;
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struct EnvOptions;
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enum ChecksumType : char {
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kNoChecksum = 0x0,
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kCRC32c = 0x1,
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kxxHash = 0x2,
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kxxHash64 = 0x3,
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};
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// `PinningTier` is used to specify which tier of block-based tables should
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// be affected by a block cache pinning setting (see
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// `MetadataCacheOptions` below).
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enum class PinningTier {
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// For compatibility, this value specifies to fallback to the behavior
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// indicated by the deprecated options,
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// `pin_l0_filter_and_index_blocks_in_cache` and
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// `pin_top_level_index_and_filter`.
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kFallback,
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// This tier contains no block-based tables.
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kNone,
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// This tier contains block-based tables that may have originated from a
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// memtable flush. In particular, it includes tables from L0 that are smaller
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// than 1.5 times the current `write_buffer_size`. Note these criteria imply
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// it can include intra-L0 compaction outputs and ingested files, as long as
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// they are not abnormally large compared to flushed files in L0.
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kFlushedAndSimilar,
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// This tier contains all block-based tables.
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kAll,
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};
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// `MetadataCacheOptions` contains members indicating the desired caching
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// behavior for the different categories of metadata blocks.
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struct MetadataCacheOptions {
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// The tier of block-based tables whose top-level index into metadata
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// partitions will be pinned. Currently indexes and filters may be
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// partitioned.
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//
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// Note `cache_index_and_filter_blocks` must be true for this option to have
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// any effect. Otherwise any top-level index into metadata partitions would be
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// held in table reader memory, outside the block cache.
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PinningTier top_level_index_pinning = PinningTier::kFallback;
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// The tier of block-based tables whose metadata partitions will be pinned.
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// Currently indexes and filters may be partitioned.
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PinningTier partition_pinning = PinningTier::kFallback;
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// The tier of block-based tables whose unpartitioned metadata blocks will be
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// pinned.
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//
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// Note `cache_index_and_filter_blocks` must be true for this option to have
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// any effect. Otherwise the unpartitioned meta-blocks would be held in table
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// reader memory, outside the block cache.
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PinningTier unpartitioned_pinning = PinningTier::kFallback;
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};
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// For advanced user only
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struct BlockBasedTableOptions {
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static const char* kName() { return "BlockTableOptions"; };
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// @flush_block_policy_factory creates the instances of flush block policy.
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// which provides a configurable way to determine when to flush a block in
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// the block based tables. If not set, table builder will use the default
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// block flush policy, which cut blocks by block size (please refer to
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// `FlushBlockBySizePolicy`).
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std::shared_ptr<FlushBlockPolicyFactory> flush_block_policy_factory;
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// TODO(kailiu) Temporarily disable this feature by making the default value
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// to be false.
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//
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// TODO(ajkr) we need to update names of variables controlling meta-block
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// caching as they should now apply to range tombstone and compression
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// dictionary meta-blocks, in addition to index and filter meta-blocks.
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//
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// Indicating if we'd put index/filter blocks to the block cache.
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// If not specified, each "table reader" object will pre-load index/filter
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// block during table initialization.
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bool cache_index_and_filter_blocks = false;
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// If cache_index_and_filter_blocks is enabled, cache index and filter
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// blocks with high priority. If set to true, depending on implementation of
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// block cache, index and filter blocks may be less likely to be evicted
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// than data blocks.
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bool cache_index_and_filter_blocks_with_high_priority = true;
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// DEPRECATED: This option will be removed in a future version. For now, this
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// option still takes effect by updating each of the following variables that
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// has the default value, `PinningTier::kFallback`:
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//
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// - `MetadataCacheOptions::partition_pinning`
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// - `MetadataCacheOptions::unpartitioned_pinning`
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//
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// The updated value is chosen as follows:
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//
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// - `pin_l0_filter_and_index_blocks_in_cache == false` ->
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// `PinningTier::kNone`
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// - `pin_l0_filter_and_index_blocks_in_cache == true` ->
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// `PinningTier::kFlushedAndSimilar`
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//
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// To migrate away from this flag, explicitly configure
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// `MetadataCacheOptions` as described above.
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//
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// if cache_index_and_filter_blocks is true and the below is true, then
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// filter and index blocks are stored in the cache, but a reference is
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// held in the "table reader" object so the blocks are pinned and only
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// evicted from cache when the table reader is freed.
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bool pin_l0_filter_and_index_blocks_in_cache = false;
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// DEPRECATED: This option will be removed in a future version. For now, this
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// option still takes effect by updating
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// `MetadataCacheOptions::top_level_index_pinning` when it has the
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// default value, `PinningTier::kFallback`.
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//
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// The updated value is chosen as follows:
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//
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// - `pin_top_level_index_and_filter == false` ->
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// `PinningTier::kNone`
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// - `pin_top_level_index_and_filter == true` ->
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// `PinningTier::kAll`
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//
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// To migrate away from this flag, explicitly configure
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// `MetadataCacheOptions` as described above.
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//
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// If cache_index_and_filter_blocks is true and the below is true, then
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// the top-level index of partitioned filter and index blocks are stored in
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// the cache, but a reference is held in the "table reader" object so the
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// blocks are pinned and only evicted from cache when the table reader is
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// freed. This is not limited to l0 in LSM tree.
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bool pin_top_level_index_and_filter = true;
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// The desired block cache pinning behavior for the different categories of
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// metadata blocks. While pinning can reduce block cache contention, users
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// must take care not to pin excessive amounts of data, which risks
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// overflowing block cache.
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MetadataCacheOptions metadata_cache_options;
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// The index type that will be used for this table.
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enum IndexType : char {
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// A space efficient index block that is optimized for
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// binary-search-based index.
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kBinarySearch = 0x00,
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// The hash index, if enabled, will do the hash lookup when
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// `Options.prefix_extractor` is provided.
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kHashSearch = 0x01,
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// A two-level index implementation. Both levels are binary search indexes.
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kTwoLevelIndexSearch = 0x02,
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// Like kBinarySearch, but index also contains first key of each block.
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// This allows iterators to defer reading the block until it's actually
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// needed. May significantly reduce read amplification of short range scans.
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// Without it, iterator seek usually reads one block from each level-0 file
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// and from each level, which may be expensive.
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// Works best in combination with:
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// - IndexShorteningMode::kNoShortening,
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// - custom FlushBlockPolicy to cut blocks at some meaningful boundaries,
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// e.g. when prefix changes.
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// Makes the index significantly bigger (2x or more), especially when keys
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// are long.
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kBinarySearchWithFirstKey = 0x03,
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};
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IndexType index_type = kBinarySearch;
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// The index type that will be used for the data block.
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enum DataBlockIndexType : char {
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kDataBlockBinarySearch = 0, // traditional block type
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kDataBlockBinaryAndHash = 1, // additional hash index
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};
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DataBlockIndexType data_block_index_type = kDataBlockBinarySearch;
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// #entries/#buckets. It is valid only when data_block_hash_index_type is
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// kDataBlockBinaryAndHash.
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double data_block_hash_table_util_ratio = 0.75;
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// This option is now deprecated. No matter what value it is set to,
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// it will behave as if hash_index_allow_collision=true.
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bool hash_index_allow_collision = true;
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// Use the specified checksum type. Newly created table files will be
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// protected with this checksum type. Old table files will still be readable,
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// even though they have different checksum type.
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ChecksumType checksum = kCRC32c;
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// Disable block cache. If this is set to true,
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// then no block cache should be used, and the block_cache should
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// point to a nullptr object.
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bool no_block_cache = false;
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// If non-NULL use the specified cache for blocks.
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// If NULL, rocksdb will automatically create and use an 8MB internal cache.
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std::shared_ptr<Cache> block_cache = nullptr;
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// If non-NULL use the specified cache for pages read from device
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// IF NULL, no page cache is used
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std::shared_ptr<PersistentCache> persistent_cache = nullptr;
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// If non-NULL use the specified cache for compressed blocks.
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// If NULL, rocksdb will not use a compressed block cache.
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// Note: though it looks similar to `block_cache`, RocksDB doesn't put the
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// same type of object there.
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std::shared_ptr<Cache> block_cache_compressed = nullptr;
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// Approximate size of user data packed per block. Note that the
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// block size specified here corresponds to uncompressed data. The
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// actual size of the unit read from disk may be smaller if
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// compression is enabled. This parameter can be changed dynamically.
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size_t block_size = 4 * 1024;
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// This is used to close a block before it reaches the configured
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// 'block_size'. If the percentage of free space in the current block is less
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// than this specified number and adding a new record to the block will
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// exceed the configured block size, then this block will be closed and the
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// new record will be written to the next block.
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int block_size_deviation = 10;
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// Number of keys between restart points for delta encoding of keys.
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// This parameter can be changed dynamically. Most clients should
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// leave this parameter alone. The minimum value allowed is 1. Any smaller
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// value will be silently overwritten with 1.
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int block_restart_interval = 16;
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// Same as block_restart_interval but used for the index block.
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int index_block_restart_interval = 1;
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// Block size for partitioned metadata. Currently applied to indexes when
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// kTwoLevelIndexSearch is used and to filters when partition_filters is used.
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// Note: Since in the current implementation the filters and index partitions
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// are aligned, an index/filter block is created when either index or filter
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// block size reaches the specified limit.
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// Note: this limit is currently applied to only index blocks; a filter
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// partition is cut right after an index block is cut
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// TODO(myabandeh): remove the note above when filter partitions are cut
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// separately
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uint64_t metadata_block_size = 4096;
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// Note: currently this option requires kTwoLevelIndexSearch to be set as
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// well.
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// TODO(myabandeh): remove the note above once the limitation is lifted
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// Use partitioned full filters for each SST file. This option is
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// incompatible with block-based filters.
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bool partition_filters = false;
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// EXPERIMENTAL Option to generate Bloom filters that minimize memory
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// internal fragmentation.
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//
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// When false, malloc_usable_size is not available, or format_version < 5,
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// filters are generated without regard to internal fragmentation when
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// loaded into memory (historical behavior). When true (and
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// malloc_usable_size is available and format_version >= 5), then Bloom
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// filters are generated to "round up" and "round down" their sizes to
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// minimize internal fragmentation when loaded into memory, assuming the
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// reading DB has the same memory allocation characteristics as the
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// generating DB. This option does not break forward or backward
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// compatibility.
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//
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// While individual filters will vary in bits/key and false positive rate
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// when setting is true, the implementation attempts to maintain a weighted
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// average FP rate for filters consistent with this option set to false.
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//
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// With Jemalloc for example, this setting is expected to save about 10% of
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// the memory footprint and block cache charge of filters, while increasing
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// disk usage of filters by about 1-2% due to encoding efficiency losses
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// with variance in bits/key.
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//
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// NOTE: Because some memory counted by block cache might be unmapped pages
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// within internal fragmentation, this option can increase observed RSS
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// memory usage. With cache_index_and_filter_blocks=true, this option makes
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// the block cache better at using space it is allowed.
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//
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// NOTE: Do not set to true if you do not trust malloc_usable_size. With
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// this option, RocksDB might access an allocated memory object beyond its
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// original size if malloc_usable_size says it is safe to do so. While this
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// can be considered bad practice, it should not produce undefined behavior
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// unless malloc_usable_size is buggy or broken.
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bool optimize_filters_for_memory = false;
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// Use delta encoding to compress keys in blocks.
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// ReadOptions::pin_data requires this option to be disabled.
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//
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// Default: true
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bool use_delta_encoding = true;
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// If non-nullptr, use the specified filter policy to reduce disk reads.
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// Many applications will benefit from passing the result of
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// NewBloomFilterPolicy() here.
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std::shared_ptr<const FilterPolicy> filter_policy = nullptr;
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// If true, place whole keys in the filter (not just prefixes).
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// This must generally be true for gets to be efficient.
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bool whole_key_filtering = true;
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// Verify that decompressing the compressed block gives back the input. This
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// is a verification mode that we use to detect bugs in compression
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// algorithms.
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bool verify_compression = false;
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// If used, For every data block we load into memory, we will create a bitmap
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// of size ((block_size / `read_amp_bytes_per_bit`) / 8) bytes. This bitmap
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// will be used to figure out the percentage we actually read of the blocks.
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//
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// When this feature is used Tickers::READ_AMP_ESTIMATE_USEFUL_BYTES and
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// Tickers::READ_AMP_TOTAL_READ_BYTES can be used to calculate the
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// read amplification using this formula
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// (READ_AMP_TOTAL_READ_BYTES / READ_AMP_ESTIMATE_USEFUL_BYTES)
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//
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// value => memory usage (percentage of loaded blocks memory)
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// 1 => 12.50 %
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// 2 => 06.25 %
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// 4 => 03.12 %
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// 8 => 01.56 %
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// 16 => 00.78 %
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//
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// Note: This number must be a power of 2, if not it will be sanitized
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// to be the next lowest power of 2, for example a value of 7 will be
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// treated as 4, a value of 19 will be treated as 16.
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//
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// Default: 0 (disabled)
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uint32_t read_amp_bytes_per_bit = 0;
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// We currently have five versions:
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// 0 -- This version is currently written out by all RocksDB's versions by
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// default. Can be read by really old RocksDB's. Doesn't support changing
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// checksum (default is CRC32).
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// 1 -- Can be read by RocksDB's versions since 3.0. Supports non-default
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// checksum, like xxHash. It is written by RocksDB when
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// BlockBasedTableOptions::checksum is something other than kCRC32c. (version
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// 0 is silently upconverted)
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// 2 -- Can be read by RocksDB's versions since 3.10. Changes the way we
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// encode compressed blocks with LZ4, BZip2 and Zlib compression. If you
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// don't plan to run RocksDB before version 3.10, you should probably use
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// this.
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// 3 -- Can be read by RocksDB's versions since 5.15. Changes the way we
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// encode the keys in index blocks. If you don't plan to run RocksDB before
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// version 5.15, you should probably use this.
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// This option only affects newly written tables. When reading existing
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// tables, the information about version is read from the footer.
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// 4 -- Can be read by RocksDB's versions since 5.16. Changes the way we
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// encode the values in index blocks. If you don't plan to run RocksDB before
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// version 5.16 and you are using index_block_restart_interval > 1, you should
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// probably use this as it would reduce the index size.
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// This option only affects newly written tables. When reading existing
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// tables, the information about version is read from the footer.
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// 5 -- Can be read by RocksDB's versions since 6.6.0. Full and partitioned
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// filters use a generally faster and more accurate Bloom filter
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// implementation, with a different schema.
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uint32_t format_version = 4;
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// Store index blocks on disk in compressed format. Changing this option to
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// false will avoid the overhead of decompression if index blocks are evicted
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// and read back
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bool enable_index_compression = true;
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// Align data blocks on lesser of page size and block size
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bool block_align = false;
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// This enum allows trading off increased index size for improved iterator
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// seek performance in some situations, particularly when block cache is
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// disabled (ReadOptions::fill_cache = false) and direct IO is
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// enabled (DBOptions::use_direct_reads = true).
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// The default mode is the best tradeoff for most use cases.
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// This option only affects newly written tables.
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//
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// The index contains a key separating each pair of consecutive blocks.
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// Let A be the highest key in one block, B the lowest key in the next block,
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// and I the index entry separating these two blocks:
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// [ ... A] I [B ...]
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// I is allowed to be anywhere in [A, B).
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// If an iterator is seeked to a key in (A, I], we'll unnecessarily read the
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// first block, then immediately fall through to the second block.
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// However, if I=A, this can't happen, and we'll read only the second block.
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// In kNoShortening mode, we use I=A. In other modes, we use the shortest
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// key in [A, B), which usually significantly reduces index size.
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//
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// There's a similar story for the last index entry, which is an upper bound
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// of the highest key in the file. If it's shortened and therefore
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// overestimated, iterator is likely to unnecessarily read the last data block
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// from each file on each seek.
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enum class IndexShorteningMode : char {
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// Use full keys.
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kNoShortening,
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// Shorten index keys between blocks, but use full key for the last index
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// key, which is the upper bound of the whole file.
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kShortenSeparators,
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// Shorten both keys between blocks and key after last block.
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kShortenSeparatorsAndSuccessor,
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};
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IndexShorteningMode index_shortening =
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IndexShorteningMode::kShortenSeparators;
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};
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// Table Properties that are specific to block-based table properties.
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struct BlockBasedTablePropertyNames {
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// value of this properties is a fixed int32 number.
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static const std::string kIndexType;
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// value is "1" for true and "0" for false.
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static const std::string kWholeKeyFiltering;
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// value is "1" for true and "0" for false.
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static const std::string kPrefixFiltering;
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};
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// Create default block based table factory.
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extern TableFactory* NewBlockBasedTableFactory(
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const BlockBasedTableOptions& table_options = BlockBasedTableOptions());
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#ifndef ROCKSDB_LITE
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enum EncodingType : char {
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// Always write full keys without any special encoding.
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kPlain,
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// Find opportunity to write the same prefix once for multiple rows.
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// In some cases, when a key follows a previous key with the same prefix,
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// instead of writing out the full key, it just writes out the size of the
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// shared prefix, as well as other bytes, to save some bytes.
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//
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// When using this option, the user is required to use the same prefix
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// extractor to make sure the same prefix will be extracted from the same key.
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// The Name() value of the prefix extractor will be stored in the file. When
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// reopening the file, the name of the options.prefix_extractor given will be
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// bitwise compared to the prefix extractors stored in the file. An error
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// will be returned if the two don't match.
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kPrefix,
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};
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// Table Properties that are specific to plain table properties.
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struct PlainTablePropertyNames {
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static const std::string kEncodingType;
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static const std::string kBloomVersion;
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static const std::string kNumBloomBlocks;
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};
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const uint32_t kPlainTableVariableLength = 0;
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struct PlainTableOptions {
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static const char* kName() { return "PlainTableOptions"; };
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// @user_key_len: plain table has optimization for fix-sized keys, which can
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// be specified via user_key_len. Alternatively, you can pass
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// `kPlainTableVariableLength` if your keys have variable
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// lengths.
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uint32_t user_key_len = kPlainTableVariableLength;
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// @bloom_bits_per_key: the number of bits used for bloom filer per prefix.
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// You may disable it by passing a zero.
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int bloom_bits_per_key = 10;
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// @hash_table_ratio: the desired utilization of the hash table used for
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// prefix hashing.
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// hash_table_ratio = number of prefixes / #buckets in the
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// hash table
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double hash_table_ratio = 0.75;
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// @index_sparseness: inside each prefix, need to build one index record for
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// how many keys for binary search inside each hash bucket.
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// For encoding type kPrefix, the value will be used when
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// writing to determine an interval to rewrite the full
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// key. It will also be used as a suggestion and satisfied
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// when possible.
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size_t index_sparseness = 16;
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// @huge_page_tlb_size: if <=0, allocate hash indexes and blooms from malloc.
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// Otherwise from huge page TLB. The user needs to
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// reserve huge pages for it to be allocated, like:
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// sysctl -w vm.nr_hugepages=20
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// See linux doc Documentation/vm/hugetlbpage.txt
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size_t huge_page_tlb_size = 0;
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// @encoding_type: how to encode the keys. See enum EncodingType above for
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// the choices. The value will determine how to encode keys
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// when writing to a new SST file. This value will be stored
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// inside the SST file which will be used when reading from
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// the file, which makes it possible for users to choose
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// different encoding type when reopening a DB. Files with
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// different encoding types can co-exist in the same DB and
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// can be read.
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EncodingType encoding_type = kPlain;
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// @full_scan_mode: mode for reading the whole file one record by one without
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// using the index.
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bool full_scan_mode = false;
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// @store_index_in_file: compute plain table index and bloom filter during
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// file building and store it in file. When reading
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// file, index will be mmaped instead of recomputation.
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bool store_index_in_file = false;
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};
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// -- Plain Table with prefix-only seek
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// For this factory, you need to set Options.prefix_extractor properly to make
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// it work. Look-up will starts with prefix hash lookup for key prefix. Inside
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// the hash bucket found, a binary search is executed for hash conflicts.
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// Finally, a linear search is used.
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extern TableFactory* NewPlainTableFactory(
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const PlainTableOptions& options = PlainTableOptions());
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struct CuckooTablePropertyNames {
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// The key that is used to fill empty buckets.
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static const std::string kEmptyKey;
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// Fixed length of value.
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static const std::string kValueLength;
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// Number of hash functions used in Cuckoo Hash.
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static const std::string kNumHashFunc;
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// It denotes the number of buckets in a Cuckoo Block. Given a key and a
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// particular hash function, a Cuckoo Block is a set of consecutive buckets,
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// where starting bucket id is given by the hash function on the key. In case
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// of a collision during inserting the key, the builder tries to insert the
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// key in other locations of the cuckoo block before using the next hash
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// function. This reduces cache miss during read operation in case of
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// collision.
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static const std::string kCuckooBlockSize;
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// Size of the hash table. Use this number to compute the modulo of hash
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// function. The actual number of buckets will be kMaxHashTableSize +
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// kCuckooBlockSize - 1. The last kCuckooBlockSize-1 buckets are used to
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// accommodate the Cuckoo Block from end of hash table, due to cache friendly
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// implementation.
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static const std::string kHashTableSize;
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// Denotes if the key sorted in the file is Internal Key (if false)
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// or User Key only (if true).
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static const std::string kIsLastLevel;
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// Indicate if using identity function for the first hash function.
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static const std::string kIdentityAsFirstHash;
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// Indicate if using module or bit and to calculate hash value
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static const std::string kUseModuleHash;
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// Fixed user key length
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static const std::string kUserKeyLength;
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};
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struct CuckooTableOptions {
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static const char* kName() { return "CuckooTableOptions"; };
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// Determines the utilization of hash tables. Smaller values
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// result in larger hash tables with fewer collisions.
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double hash_table_ratio = 0.9;
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// A property used by builder to determine the depth to go to
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// to search for a path to displace elements in case of
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// collision. See Builder.MakeSpaceForKey method. Higher
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// values result in more efficient hash tables with fewer
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// lookups but take more time to build.
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uint32_t max_search_depth = 100;
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// In case of collision while inserting, the builder
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// attempts to insert in the next cuckoo_block_size
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// locations before skipping over to the next Cuckoo hash
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// function. This makes lookups more cache friendly in case
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// of collisions.
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uint32_t cuckoo_block_size = 5;
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// If this option is enabled, user key is treated as uint64_t and its value
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// is used as hash value directly. This option changes builder's behavior.
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// Reader ignore this option and behave according to what specified in table
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// property.
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bool identity_as_first_hash = false;
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// If this option is set to true, module is used during hash calculation.
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// This often yields better space efficiency at the cost of performance.
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// If this option is set to false, # of entries in table is constrained to be
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// power of two, and bit and is used to calculate hash, which is faster in
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// general.
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bool use_module_hash = true;
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};
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// Cuckoo Table Factory for SST table format using Cache Friendly Cuckoo Hashing
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extern TableFactory* NewCuckooTableFactory(
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const CuckooTableOptions& table_options = CuckooTableOptions());
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#endif // ROCKSDB_LITE
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class RandomAccessFileReader;
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// A base class for table factories.
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class TableFactory : public Customizable {
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public:
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virtual ~TableFactory() override {}
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static const char* kBlockCacheOpts() { return "BlockCache"; };
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static const char* kBlockBasedTableName() { return "BlockBasedTable"; };
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static const char* kPlainTableName() { return "PlainTable"; }
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static const char* kCuckooTableName() { return "CuckooTable"; };
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// Creates and configures a new TableFactory from the input options and id.
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static Status CreateFromString(const ConfigOptions& config_options,
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const std::string& id,
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std::shared_ptr<TableFactory>* factory);
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static const char* Type() { return "TableFactory"; }
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// Returns a Table object table that can fetch data from file specified
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// in parameter file. It's the caller's responsibility to make sure
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// file is in the correct format.
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//
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// NewTableReader() is called in three places:
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// (1) TableCache::FindTable() calls the function when table cache miss
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// and cache the table object returned.
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// (2) SstFileDumper (for SST Dump) opens the table and dump the table
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// contents using the iterator of the table.
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// (3) DBImpl::IngestExternalFile() calls this function to read the contents
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// of the sst file it's attempting to add
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//
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// table_reader_options is a TableReaderOptions which contain all the
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// needed parameters and configuration to open the table.
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// file is a file handler to handle the file for the table.
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// file_size is the physical file size of the file.
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// table_reader is the output table reader.
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virtual Status NewTableReader(
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const TableReaderOptions& table_reader_options,
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std::unique_ptr<RandomAccessFileReader>&& file, uint64_t file_size,
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std::unique_ptr<TableReader>* table_reader,
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bool prefetch_index_and_filter_in_cache = true) const {
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ReadOptions ro;
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return NewTableReader(ro, table_reader_options, std::move(file), file_size,
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table_reader, prefetch_index_and_filter_in_cache);
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}
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// Overload of the above function that allows the caller to pass in a
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// ReadOptions
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virtual Status NewTableReader(
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const ReadOptions& ro, const TableReaderOptions& table_reader_options,
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std::unique_ptr<RandomAccessFileReader>&& file, uint64_t file_size,
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std::unique_ptr<TableReader>* table_reader,
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bool prefetch_index_and_filter_in_cache) const = 0;
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// Return a table builder to write to a file for this table type.
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//
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// It is called in several places:
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// (1) When flushing memtable to a level-0 output file, it creates a table
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// builder (In DBImpl::WriteLevel0Table(), by calling BuildTable())
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// (2) During compaction, it gets the builder for writing compaction output
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// files in DBImpl::OpenCompactionOutputFile().
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// (3) When recovering from transaction logs, it creates a table builder to
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// write to a level-0 output file (In DBImpl::WriteLevel0TableForRecovery,
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// by calling BuildTable())
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// (4) When running Repairer, it creates a table builder to convert logs to
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// SST files (In Repairer::ConvertLogToTable() by calling BuildTable())
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//
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// Multiple configured can be accessed from there, including and not limited
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// to compression options. file is a handle of a writable file.
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// It is the caller's responsibility to keep the file open and close the file
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// after closing the table builder. compression_type is the compression type
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// to use in this table.
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virtual TableBuilder* NewTableBuilder(
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const TableBuilderOptions& table_builder_options,
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uint32_t column_family_id, WritableFileWriter* file) const = 0;
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// Return is delete range supported
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virtual bool IsDeleteRangeSupported() const { return false; }
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};
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#ifndef ROCKSDB_LITE
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// Create a special table factory that can open either of the supported
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// table formats, based on setting inside the SST files. It should be used to
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// convert a DB from one table format to another.
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// @table_factory_to_write: the table factory used when writing to new files.
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// @block_based_table_factory: block based table factory to use. If NULL, use
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// a default one.
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// @plain_table_factory: plain table factory to use. If NULL, use a default one.
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// @cuckoo_table_factory: cuckoo table factory to use. If NULL, use a default
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// one.
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extern TableFactory* NewAdaptiveTableFactory(
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std::shared_ptr<TableFactory> table_factory_to_write = nullptr,
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std::shared_ptr<TableFactory> block_based_table_factory = nullptr,
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std::shared_ptr<TableFactory> plain_table_factory = nullptr,
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std::shared_ptr<TableFactory> cuckoo_table_factory = nullptr);
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#endif // ROCKSDB_LITE
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} // namespace ROCKSDB_NAMESPACE
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