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381 lines
15 KiB
Go
381 lines
15 KiB
Go
// Copyright 2021 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 rangekey
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import (
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"bytes"
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"math"
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"sort"
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"github.com/cockroachdb/pebble/internal/base"
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"github.com/cockroachdb/pebble/internal/invariants"
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"github.com/cockroachdb/pebble/internal/keyspan"
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"github.com/cockroachdb/pebble/internal/manifest"
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)
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// UserIteratorConfig holds state for constructing the range key iterator stack
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// for user iteration. The range key iterator must merge range key spans across
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// the levels of the LSM. This merging is performed by a keyspan.MergingIter
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// on-the-fly. The UserIteratorConfig implements keyspan.Transformer, evaluating
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// range-key semantics and shadowing, so the spans returned by a MergingIter are
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// fully resolved.
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//
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// The MergingIter is wrapped by a BoundedIter, which elides spans that are
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// outside the iterator bounds (or the current prefix's bounds, during prefix
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// iteration mode).
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//
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// To provide determinisim during iteration, the BoundedIter is wrapped by a
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// DefragmentingIter that defragments abutting spans with identical
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// user-observable state.
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//
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// At the top-level an InterleavingIter interleaves range keys with point keys
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// and performs truncation to iterator bounds.
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//
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// Below is an abbreviated diagram illustrating the mechanics of a SeekGE.
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//
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// InterleavingIter.SeekGE
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// │
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// DefragmentingIter.SeekGE
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// │
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// BoundedIter.SeekGE
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// │
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// ╭────────────────┴───────────────╮
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// │ ├── defragmentBwd*
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// MergingIter.SeekGE │
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// │ ╰── defragmentFwd
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// ╰─╶╶ per level╶╶ ─╮
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// │
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// │
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// ├── <?>.SeekLT
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// │
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// ╰── <?>.Next
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type UserIteratorConfig struct {
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snapshot uint64
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comparer *base.Comparer
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miter keyspan.MergingIter
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biter keyspan.BoundedIter
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diter keyspan.DefragmentingIter
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liters [manifest.NumLevels]keyspan.LevelIter
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litersUsed int
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internalKeys bool
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bufs *Buffers
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}
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// Buffers holds various buffers used for range key iteration. They're exposed
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// so that they may be pooled and reused between iterators.
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type Buffers struct {
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merging keyspan.MergingBuffers
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defragmenting keyspan.DefragmentingBuffers
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sortBuf keyspan.KeysBySuffix
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}
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// PrepareForReuse discards any excessively large buffers.
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func (bufs *Buffers) PrepareForReuse() {
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bufs.merging.PrepareForReuse()
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bufs.defragmenting.PrepareForReuse()
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}
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// Init initializes the range key iterator stack for user iteration. The
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// resulting fragment iterator applies range key semantics, defragments spans
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// according to their user-observable state and, if !internalKeys, removes all
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// Keys other than RangeKeySets describing the current state of range keys. The
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// resulting spans contain Keys sorted by suffix (unless internalKeys is true,
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// in which case they remain sorted by trailer descending).
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//
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// The snapshot sequence number parameter determines which keys are visible. Any
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// keys not visible at the provided snapshot are ignored.
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func (ui *UserIteratorConfig) Init(
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comparer *base.Comparer,
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snapshot uint64,
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lower, upper []byte,
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hasPrefix *bool,
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prefix *[]byte,
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internalKeys bool,
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bufs *Buffers,
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iters ...keyspan.FragmentIterator,
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) keyspan.FragmentIterator {
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ui.snapshot = snapshot
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ui.comparer = comparer
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ui.internalKeys = internalKeys
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ui.miter.Init(comparer.Compare, ui, &bufs.merging, iters...)
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ui.biter.Init(comparer.Compare, comparer.Split, &ui.miter, lower, upper, hasPrefix, prefix)
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if internalKeys {
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ui.diter.Init(comparer, &ui.biter, keyspan.DefragmentInternal, keyspan.StaticDefragmentReducer, &bufs.defragmenting)
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} else {
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ui.diter.Init(comparer, &ui.biter, ui, keyspan.StaticDefragmentReducer, &bufs.defragmenting)
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}
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ui.litersUsed = 0
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ui.bufs = bufs
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return &ui.diter
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}
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// AddLevel adds a new level to the bottom of the iterator stack. AddLevel
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// must be called after Init and before any other method on the iterator.
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func (ui *UserIteratorConfig) AddLevel(iter keyspan.FragmentIterator) {
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ui.miter.AddLevel(iter)
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}
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// NewLevelIter returns a pointer to a newly allocated or reused
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// keyspan.LevelIter. The caller is responsible for calling Init() on this
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// instance.
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func (ui *UserIteratorConfig) NewLevelIter() *keyspan.LevelIter {
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if ui.litersUsed >= len(ui.liters) {
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return &keyspan.LevelIter{}
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}
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ui.litersUsed++
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return &ui.liters[ui.litersUsed-1]
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}
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// SetBounds propagates bounds to the iterator stack. The fragment iterator
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// interface ordinarily doesn't enforce bounds, so this is exposed as an
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// explicit method on the user iterator config.
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func (ui *UserIteratorConfig) SetBounds(lower, upper []byte) {
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ui.biter.SetBounds(lower, upper)
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}
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// Transform implements the keyspan.Transformer interface for use with a
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// keyspan.MergingIter. It transforms spans by resolving range keys at the
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// provided snapshot sequence number. Shadowing of keys is resolved (eg, removal
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// of unset keys, removal of keys overwritten by a set at the same suffix, etc)
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// and then non-RangeKeySet keys are removed. The resulting transformed spans
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// only contain RangeKeySets describing the state visible at the provided
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// sequence number, and hold their Keys sorted by Suffix (except if internalKeys
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// is true, then keys remain sorted by trailer.
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func (ui *UserIteratorConfig) Transform(cmp base.Compare, s keyspan.Span, dst *keyspan.Span) error {
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// Apply shadowing of keys.
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dst.Start = s.Start
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dst.End = s.End
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ui.bufs.sortBuf = keyspan.KeysBySuffix{
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Cmp: cmp,
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Keys: ui.bufs.sortBuf.Keys[:0],
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}
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if err := coalesce(ui.comparer.Equal, &ui.bufs.sortBuf, ui.snapshot, s.Keys); err != nil {
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return err
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}
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if ui.internalKeys {
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if s.KeysOrder != keyspan.ByTrailerDesc {
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panic("unexpected key ordering in UserIteratorTransform with internalKeys = true")
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}
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dst.Keys = ui.bufs.sortBuf.Keys
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keyspan.SortKeysByTrailer(&dst.Keys)
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return nil
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}
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// During user iteration over range keys, unsets and deletes don't matter. This
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// step helps logical defragmentation during iteration.
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keys := ui.bufs.sortBuf.Keys
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dst.Keys = dst.Keys[:0]
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for i := range keys {
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switch keys[i].Kind() {
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case base.InternalKeyKindRangeKeySet:
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if invariants.Enabled && len(dst.Keys) > 0 && cmp(dst.Keys[len(dst.Keys)-1].Suffix, keys[i].Suffix) > 0 {
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panic("pebble: keys unexpectedly not in ascending suffix order")
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}
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dst.Keys = append(dst.Keys, keys[i])
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case base.InternalKeyKindRangeKeyUnset:
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if invariants.Enabled && len(dst.Keys) > 0 && cmp(dst.Keys[len(dst.Keys)-1].Suffix, keys[i].Suffix) > 0 {
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panic("pebble: keys unexpectedly not in ascending suffix order")
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}
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// Skip.
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continue
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case base.InternalKeyKindRangeKeyDelete:
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// Skip.
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continue
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default:
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return base.CorruptionErrorf("pebble: unrecognized range key kind %s", keys[i].Kind())
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}
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}
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// coalesce results in dst.Keys being sorted by Suffix.
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dst.KeysOrder = keyspan.BySuffixAsc
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return nil
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}
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// ShouldDefragment implements the DefragmentMethod interface and configures a
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// DefragmentingIter to defragment spans of range keys if their user-visible
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// state is identical. This defragmenting method assumes the provided spans have
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// already been transformed through (UserIterationConfig).Transform, so all
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// RangeKeySets are user-visible sets and are already in Suffix order. This
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// defragmenter checks for equality between set suffixes and values (ignoring
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// sequence numbers). It's intended for use during user iteration, when the
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// wrapped keyspan iterator is merging spans across all levels of the LSM.
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func (ui *UserIteratorConfig) ShouldDefragment(equal base.Equal, a, b *keyspan.Span) bool {
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// This method is not called with internalKeys = true.
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if ui.internalKeys {
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panic("unexpected call to ShouldDefragment with internalKeys = true")
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}
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// This implementation must only be used on spans that have transformed by
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// ui.Transform. The transform applies shadowing, removes all keys besides
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// the resulting Sets and sorts the keys by suffix. Since shadowing has been
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// applied, each Set must set a unique suffix. If the two spans are
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// equivalent, they must have the same number of range key sets.
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if len(a.Keys) != len(b.Keys) || len(a.Keys) == 0 {
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return false
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}
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if a.KeysOrder != keyspan.BySuffixAsc || b.KeysOrder != keyspan.BySuffixAsc {
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panic("pebble: range key span's keys unexpectedly not in ascending suffix order")
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}
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ret := true
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for i := range a.Keys {
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if invariants.Enabled {
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if a.Keys[i].Kind() != base.InternalKeyKindRangeKeySet ||
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b.Keys[i].Kind() != base.InternalKeyKindRangeKeySet {
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panic("pebble: unexpected non-RangeKeySet during defragmentation")
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}
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if i > 0 && (ui.comparer.Compare(a.Keys[i].Suffix, a.Keys[i-1].Suffix) < 0 ||
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ui.comparer.Compare(b.Keys[i].Suffix, b.Keys[i-1].Suffix) < 0) {
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panic("pebble: range keys not ordered by suffix during defragmentation")
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}
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}
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if !equal(a.Keys[i].Suffix, b.Keys[i].Suffix) {
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ret = false
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break
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}
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if !bytes.Equal(a.Keys[i].Value, b.Keys[i].Value) {
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ret = false
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break
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}
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}
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return ret
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}
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// Coalesce imposes range key semantics and coalesces range keys with the same
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// bounds. Coalesce drops any keys shadowed by more recent sets, unsets or
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// deletes. Coalesce modifies the provided span's Keys slice, reslicing the
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// slice to remove dropped keys.
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//
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// Coalescence has subtle behavior with respect to sequence numbers. Coalesce
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// depends on a keyspan.Span's Keys being sorted in sequence number descending
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// order. The first key has the largest sequence number. The returned coalesced
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// span includes only the largest sequence number. All other sequence numbers
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// are forgotten. When a compaction constructs output range keys from a
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// coalesced span, it produces at most one RANGEKEYSET, one RANGEKEYUNSET and
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// one RANGEKEYDEL. Each one of these keys adopt the largest sequence number.
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//
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// This has the potentially surprising effect of 'promoting' a key to a higher
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// sequence number. This is okay, because:
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// - There are no other overlapping keys within the coalesced span of
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// sequence numbers (otherwise they would be in the compaction, due to
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// the LSM invariant).
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// - Range key sequence numbers are never compared to point key sequence
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// numbers. Range keys and point keys have parallel existences.
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// - Compactions only coalesce within snapshot stripes.
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//
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// Additionally, internal range keys at the same sequence number have subtle
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// mechanics:
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// - RANGEKEYSETs shadow RANGEKEYUNSETs of the same suffix.
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// - RANGEKEYDELs only apply to keys at lower sequence numbers.
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//
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// This is required for ingestion. Ingested sstables are assigned a single
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// sequence number for the file, at which all of the file's keys are visible.
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// The RANGEKEYSET, RANGEKEYUNSET and RANGEKEYDEL key kinds are ordered such
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// that among keys with equal sequence numbers (thus ordered by their kinds) the
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// keys do not affect one another. Ingested sstables are expected to be
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// consistent with respect to the set/unset suffixes: A given suffix should be
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// set or unset but not both.
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//
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// The resulting dst Keys slice is sorted by Trailer.
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func Coalesce(cmp base.Compare, eq base.Equal, keys []keyspan.Key, dst *[]keyspan.Key) error {
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// TODO(jackson): Currently, Coalesce doesn't actually perform the sequence
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// number promotion described in the comment above.
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keysBySuffix := keyspan.KeysBySuffix{
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Cmp: cmp,
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Keys: (*dst)[:0],
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}
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if err := coalesce(eq, &keysBySuffix, math.MaxUint64, keys); err != nil {
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return err
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}
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// Update the span with the (potentially reduced) keys slice. coalesce left
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// the keys in *dst sorted by suffix. Re-sort them by trailer.
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*dst = keysBySuffix.Keys
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keyspan.SortKeysByTrailer(dst)
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return nil
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}
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func coalesce(
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equal base.Equal, keysBySuffix *keyspan.KeysBySuffix, snapshot uint64, keys []keyspan.Key,
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) error {
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// First, enforce visibility and RangeKeyDelete mechanics. We only need to
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// consider the prefix of keys before and including the first
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// RangeKeyDelete. We also must skip any keys that aren't visible at the
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// provided snapshot sequence number.
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//
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// NB: Within a given sequence number, keys are ordered as:
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// RangeKeySet > RangeKeyUnset > RangeKeyDelete
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// This is significant, because this ensures that a Set or Unset sharing a
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// sequence number with a Delete do not shadow each other.
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deleteIdx := -1
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for i := range keys {
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if invariants.Enabled && i > 0 && keys[i].Trailer > keys[i-1].Trailer {
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panic("pebble: invariant violation: span keys unordered")
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}
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if !keys[i].VisibleAt(snapshot) {
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continue
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}
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// Once a RangeKeyDelete is observed, we know it shadows all subsequent
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// keys and we can break early. We don't add the RangeKeyDelete key to
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// keysBySuffix.keys yet, because we don't want a suffix-less key
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// that appeared earlier in the slice to elide it. It'll be added back
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// in at the end.
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if keys[i].Kind() == base.InternalKeyKindRangeKeyDelete {
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deleteIdx = i
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break
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}
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keysBySuffix.Keys = append(keysBySuffix.Keys, keys[i])
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}
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// Sort the accumulated keys by suffix. There may be duplicates within a
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// suffix, in which case the one with a larger trailer survives.
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//
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// We use a stable sort so that the first key with a given suffix is the one
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// that with the highest Trailer (because the input `keys` was sorted by
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// trailer descending).
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sort.Stable(keysBySuffix)
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// Grab a handle of the full sorted slice, before reslicing
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// keysBySuffix.keys to accumulate the final coalesced keys.
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sorted := keysBySuffix.Keys
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keysBySuffix.Keys = keysBySuffix.Keys[:0]
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var (
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// prevSuffix is updated on each iteration of the below loop, and
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// compared by the subsequent iteration to determine whether adjacent
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// keys are defined at the same suffix.
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prevSuffix []byte
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// shadowing is set to true once any Key is shadowed by another key.
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// When it's set to true—or after the loop if no keys are shadowed—the
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// keysBySuffix.keys slice is resliced to contain the prefix of
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// unshadowed keys. This avoids copying them incrementally in the common
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// case of no shadowing.
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shadowing bool
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)
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for i := range sorted {
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if i > 0 && equal(prevSuffix, sorted[i].Suffix) {
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// Skip; this key is shadowed by the predecessor that had a larger
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// Trailer. If this is the first shadowed key, set shadowing=true
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// and reslice keysBySuffix.keys to hold the entire unshadowed
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// prefix.
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if !shadowing {
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keysBySuffix.Keys = keysBySuffix.Keys[:i]
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shadowing = true
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}
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continue
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}
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prevSuffix = sorted[i].Suffix
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if shadowing {
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keysBySuffix.Keys = append(keysBySuffix.Keys, sorted[i])
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}
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}
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// If there was no shadowing, keysBySuffix.keys is untouched. We can simply
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// set it to the existing `sorted` slice (also backed by keysBySuffix.keys).
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if !shadowing {
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keysBySuffix.Keys = sorted
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}
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// If the original input `keys` slice contained a RangeKeyDelete, add it.
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if deleteIdx >= 0 {
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keysBySuffix.Keys = append(keysBySuffix.Keys, keys[deleteIdx])
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}
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return nil
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}
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