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258 lines
11 KiB
Go
258 lines
11 KiB
Go
// Copyright 2022 The LevelDB-Go and Pebble Authors. All rights reserved. Use
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// of this source code is governed by a BSD-style license that can be found in
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// the LICENSE file.
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package sstable
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import (
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"github.com/cockroachdb/errors"
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"github.com/cockroachdb/pebble/internal/base"
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)
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// TableFormat specifies the format version for sstables. The legacy LevelDB
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// format is format version 1.
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type TableFormat uint32
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// The available table formats, representing the tuple (magic number, version
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// number). Note that these values are not (and should not) be serialized to
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// disk. The ordering should follow the order the versions were introduced to
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// Pebble (i.e. the history is linear).
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const (
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TableFormatUnspecified TableFormat = iota
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TableFormatLevelDB
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TableFormatRocksDBv2
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TableFormatPebblev1 // Block properties.
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TableFormatPebblev2 // Range keys.
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TableFormatPebblev3 // Value blocks.
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TableFormatPebblev4 // DELSIZED tombstones.
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NumTableFormats
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TableFormatMax = NumTableFormats - 1
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)
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// TableFormatPebblev4, in addition to DELSIZED, introduces the use of
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// InternalKeyKindSSTableInternalObsoleteBit.
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//
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// 1. Motivation
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//
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// We have various related problems caused by Pebble snapshots:
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//
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// - P1: RANGEDELs that delete points in the same sstable, but the points
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// happen to not get deleted during compactions because of an open snapshot.
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// This causes very expensive iteration, that has been observed in
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// production deployments
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//
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// - P2: When iterating over a foreign sstable (in disaggregated storage), we
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// need to do (a) point collapsing to expose at most one point per user key,
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// (b) apply RANGEDELs in the sstable to hide deleted points in the same
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// sstable. This per-sstable point collapsing iteration needs to be very
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// efficient (ideally as efficient from a CPU perspective as iteration over
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// regular sstables) since foreign sstables can be very long-lived -- one of
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// the goals of disaggregated storage is to scale compute and disk bandwidth
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// resources as a function of the hot (from a write perspective) data and
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// not the whole data, so we don't want to have to rewrite foreign sstables
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// solely to improve read performance.
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//
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// The ideal solution for P2 would allow user-facing reads to utilize the
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// existing SST iterators (with slight modifications) and with no loss of
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// efficiency. And for P1 and P2 we would like to skip whole blocks of
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// overwritten/deleted points. Even when we can't skip whole blocks, avoiding
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// key comparisons at iteration time to discover what points are deleted is
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// very desirable, since keys can be long.
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//
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// We observe that:
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//
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// - Reads:
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// - All user-facing reads in CockroachDB use iterators over the DB, hence
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// have a higher read seqnum than all sstables (there are some rare cases
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// that can violate this, but those are not important from a performance
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// optimization perspective).
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//
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// - Certain internal-facing reads in CockroachDB use snapshots, but the
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// snapshots are shortlived enough that most L5 and L6 sstables will have
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// all seqnums lower than the snapshot seqnum.
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//
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// - Writes:
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// - We already do key comparisons between points when writing the sstable
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// to ensure that the sstable invariant (monotonically increasing internal
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// keys) is not violated. So we know which points share the same userkey,
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// and thereby which points are obsolete because there is a more recent
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// point in the same sstable.
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//
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// - The compactionIter knows which point id deleted by a RANGEDEL even if
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// the point does need to be written because of a snapshot.
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//
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// So this known information can be encoded in the sstable at write time and
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// utilized for optimized reading.
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//
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// 2. Solution
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//
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// We primarily scope the solution to the following point kinds: SET,
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// SETWITHDEL, DEL, DELSIZED, SINGLEDEL. These are the ones marked locally
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// obsolete, i.e., obsolete within the sstable, and we can guarantee that at
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// most one point will be exposed per user key. MERGE keys create more
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// complexity: MERGE followed by MERGE causes multiple keys to not be
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// obsolete. Same applies for MERGE followed by SET/SETWITHDEL/DEL*. Note
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// that:
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//
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// - For regular sst iteration, the obsolete marking is a performance
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// optimization, and multiple keys for the same userkey can be handled by
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// higher layers in the iterator tree (specifically pebble.Iterator).
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//
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// - For foreign sst iteration, we disallow MERGEs to be written to such
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// shared ssts (details below).
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//
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// The key kinds are marked with an obsolete bit
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// (InternalKeyKindSSTableInternalObsoleteBit) when the key-value pair is
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// obsolete. This marking is done within blockWriter, based on information
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// passed to it by Writer. In turn, Writer uses a combination of key
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// comparisons, and information provided by compactionIter to decide whether a
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// key-value pair is obsolete. Additionally, a Pebble-internal
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// BlockPropertyCollector (obsoleteKeyBlockPropertyCollector) is used to mark
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// blocks where all key-value pairs are obsolete. Since the common case is
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// non-obsolete blocks, this block property collector uses the empty byte
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// slice to represent a non-obsolete block, which consumes no space in
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// BlockHandleWithProperties.Props.
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//
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// At read time, the obsolete bit is only visible to the blockIter, which can
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// be optionally configured to hide obsolete points. This hiding is only
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// configured for data block iterators for sstables being read by user-facing
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// iterators at a seqnum greater than the max seqnum in the sstable.
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// Additionally, when this hiding is configured, a Pebble-internal block
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// property filter (obsoleteKeyBlockPropertyFilter), is used to skip whole
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// blocks that are obsolete.
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//
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// 2.1 Correctness
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//
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// Due to the level invariant, the sequence of seqnums for a user key in a
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// sstable represents a contiguous subsequence of the seqnums for the userkey
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// across the whole LSM, and is more recent than the seqnums in a sstable in a
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// lower level. So exposing exactly one point from a sstable for a userkey
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// will also mask the points for the userkey in lower levels. If we expose no
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// point, because of RANGEDELs, that RANGEDEL will also mask the points in
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// lower levels.
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//
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// Note that we do not need to do anything special at write time for
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// SETWITHDEL and SINGLEDEL. This is because these key kinds are treated
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// specially only by compactions, which do not hide obsolete points. For
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// regular reads, SETWITHDEL behaves the same as SET and SINGLEDEL behaves the
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// same as DEL.
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//
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// 2.2 Strictness and MERGE
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//
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// Setting the obsolete bit on point keys is advanced usage, so we support two
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// modes, both of which must be truthful when setting the obsolete bit, but
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// vary in when they don't set the obsolete bit.
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//
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// - Non-strict: In this mode, the bit does not need to be set for keys that
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// are obsolete. Additionally, any sstable containing MERGE keys can only
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// use this mode. An iterator over such an sstable, when configured to
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// hideObsoletePoints, can expose multiple internal keys per user key, and
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// can expose keys that are deleted by rangedels in the same sstable. This
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// is the mode that non-advanced users should use. Pebble without
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// disaggregated storage will also use this mode and will best-effort set
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// the obsolete bit, to optimize iteration when snapshots have retained many
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// obsolete keys.
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//
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// - Strict: In this mode, every obsolete key must have the obsolete bit set,
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// and no MERGE keys are permitted. An iterator over such an sstable, when
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// configured to hideObsoletePoints satisfies two properties:
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// - S1: will expose at most one internal key per user key, which is the
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// most recent one.
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// - S2: will never expose keys that are deleted by rangedels in the same
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// sstable.
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//
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// This is the mode for two use cases in disaggregated storage (which will
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// exclude parts of the key space that has MERGEs), for levels that contain
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// sstables that can become foreign sstables:
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// - Pebble compaction output to these levels that can become foreign
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// sstables.
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//
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// - CockroachDB ingest operations that can ingest into the levels that can
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// become foreign sstables. Note, these are not sstables corresponding to
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// copied data for CockroachDB range snapshots. This case occurs for
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// operations like index backfills: these trivially satisfy the strictness
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// criteria since they only write one key per userkey.
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//
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// TODO(sumeer): this latter case is not currently supported, since only
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// Writer.AddWithForceObsolete calls are permitted for writing strict
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// obsolete sstables. This is done to reduce the likelihood of bugs. One
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// simple way to lift this limitation would be to disallow adding any
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// RANGEDELs when a Pebble-external writer is trying to construct a strict
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// obsolete sstable.
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// ParseTableFormat parses the given magic bytes and version into its
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// corresponding internal TableFormat.
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func ParseTableFormat(magic []byte, version uint32) (TableFormat, error) {
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switch string(magic) {
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case levelDBMagic:
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return TableFormatLevelDB, nil
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case rocksDBMagic:
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if version != rocksDBFormatVersion2 {
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return TableFormatUnspecified, base.CorruptionErrorf(
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"pebble/table: unsupported rocksdb format version %d", errors.Safe(version),
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)
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}
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return TableFormatRocksDBv2, nil
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case pebbleDBMagic:
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switch version {
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case 1:
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return TableFormatPebblev1, nil
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case 2:
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return TableFormatPebblev2, nil
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case 3:
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return TableFormatPebblev3, nil
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case 4:
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return TableFormatPebblev4, nil
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default:
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return TableFormatUnspecified, base.CorruptionErrorf(
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"pebble/table: unsupported pebble format version %d", errors.Safe(version),
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)
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}
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default:
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return TableFormatUnspecified, base.CorruptionErrorf(
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"pebble/table: invalid table (bad magic number: 0x%x)", magic,
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)
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}
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}
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// AsTuple returns the TableFormat's (Magic String, Version) tuple.
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func (f TableFormat) AsTuple() (string, uint32) {
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switch f {
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case TableFormatLevelDB:
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return levelDBMagic, 0
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case TableFormatRocksDBv2:
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return rocksDBMagic, 2
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case TableFormatPebblev1:
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return pebbleDBMagic, 1
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case TableFormatPebblev2:
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return pebbleDBMagic, 2
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case TableFormatPebblev3:
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return pebbleDBMagic, 3
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case TableFormatPebblev4:
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return pebbleDBMagic, 4
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default:
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panic("sstable: unknown table format version tuple")
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}
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}
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// String returns the TableFormat (Magic String,Version) tuple.
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func (f TableFormat) String() string {
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switch f {
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case TableFormatLevelDB:
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return "(LevelDB)"
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case TableFormatRocksDBv2:
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return "(RocksDB,v2)"
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case TableFormatPebblev1:
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return "(Pebble,v1)"
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case TableFormatPebblev2:
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return "(Pebble,v2)"
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case TableFormatPebblev3:
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return "(Pebble,v3)"
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case TableFormatPebblev4:
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return "(Pebble,v4)"
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default:
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panic("sstable: unknown table format version tuple")
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}
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}
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