mirror of
https://source.quilibrium.com/quilibrium/ceremonyclient.git
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749 lines
21 KiB
Go
749 lines
21 KiB
Go
// Copyright 2020 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 manifest
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import (
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"bytes"
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"fmt"
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"github.com/cockroachdb/pebble/internal/base"
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"github.com/cockroachdb/pebble/internal/invariants"
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)
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// LevelMetadata contains metadata for all of the files within
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// a level of the LSM.
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type LevelMetadata struct {
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level int
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totalSize uint64
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// NumVirtual is the number of virtual sstables in the level.
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NumVirtual uint64
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// VirtualSize is the size of the virtual sstables in the level.
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VirtualSize uint64
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tree btree
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}
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// clone makes a copy of the level metadata, implicitly increasing the ref
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// count of every file contained within lm.
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func (lm *LevelMetadata) clone() LevelMetadata {
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return LevelMetadata{
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level: lm.level,
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totalSize: lm.totalSize,
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NumVirtual: lm.NumVirtual,
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VirtualSize: lm.VirtualSize,
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tree: lm.tree.Clone(),
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}
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}
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func (lm *LevelMetadata) release() (obsolete []*FileBacking) {
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return lm.tree.Release()
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}
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func makeLevelMetadata(cmp Compare, level int, files []*FileMetadata) LevelMetadata {
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bcmp := btreeCmpSeqNum
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if level > 0 {
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bcmp = btreeCmpSmallestKey(cmp)
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}
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var lm LevelMetadata
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lm.level = level
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lm.tree, _ = makeBTree(bcmp, files)
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for _, f := range files {
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lm.totalSize += f.Size
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if f.Virtual {
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lm.NumVirtual++
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lm.VirtualSize += f.Size
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}
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}
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return lm
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}
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func makeBTree(cmp btreeCmp, files []*FileMetadata) (btree, LevelSlice) {
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var t btree
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t.cmp = cmp
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for _, f := range files {
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t.Insert(f)
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}
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return t, newLevelSlice(t.Iter())
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}
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func (lm *LevelMetadata) insert(f *FileMetadata) error {
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if err := lm.tree.Insert(f); err != nil {
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return err
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}
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lm.totalSize += f.Size
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if f.Virtual {
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lm.NumVirtual++
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lm.VirtualSize += f.Size
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}
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return nil
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}
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func (lm *LevelMetadata) remove(f *FileMetadata) bool {
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lm.totalSize -= f.Size
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if f.Virtual {
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lm.NumVirtual--
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lm.VirtualSize -= f.Size
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}
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return lm.tree.Delete(f)
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}
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// Empty indicates whether there are any files in the level.
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func (lm *LevelMetadata) Empty() bool {
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return lm.tree.Count() == 0
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}
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// Len returns the number of files within the level.
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func (lm *LevelMetadata) Len() int {
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return lm.tree.Count()
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}
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// Size returns the cumulative size of all the files within the level.
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func (lm *LevelMetadata) Size() uint64 {
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return lm.totalSize
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}
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// Iter constructs a LevelIterator over the entire level.
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func (lm *LevelMetadata) Iter() LevelIterator {
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return LevelIterator{iter: lm.tree.Iter()}
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}
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// Slice constructs a slice containing the entire level.
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func (lm *LevelMetadata) Slice() LevelSlice {
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return newLevelSlice(lm.tree.Iter())
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}
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// Find finds the provided file in the level if it exists.
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func (lm *LevelMetadata) Find(cmp base.Compare, m *FileMetadata) *LevelFile {
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iter := lm.Iter()
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if lm.level != 0 {
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// If lm holds files for levels >0, we can narrow our search by binary
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// searching by bounds.
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o := overlaps(iter, cmp, m.Smallest.UserKey,
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m.Largest.UserKey, m.Largest.IsExclusiveSentinel())
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iter = o.Iter()
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}
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for f := iter.First(); f != nil; f = iter.Next() {
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if f == m {
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lf := iter.Take()
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return &lf
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}
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}
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return nil
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}
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// Annotation lazily calculates and returns the annotation defined by
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// Annotator. The Annotator is used as the key for pre-calculated
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// values, so equal Annotators must be used to avoid duplicate computations
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// and cached annotations. Annotation must not be called concurrently, and in
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// practice this is achieved by requiring callers to hold DB.mu.
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func (lm *LevelMetadata) Annotation(annotator Annotator) interface{} {
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if lm.Empty() {
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return annotator.Zero(nil)
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}
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v, _ := lm.tree.root.Annotation(annotator)
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return v
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}
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// InvalidateAnnotation clears any cached annotations defined by Annotator. The
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// Annotator is used as the key for pre-calculated values, so equal Annotators
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// must be used to clear the appropriate cached annotation. InvalidateAnnotation
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// must not be called concurrently, and in practice this is achieved by
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// requiring callers to hold DB.mu.
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func (lm *LevelMetadata) InvalidateAnnotation(annotator Annotator) {
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if lm.Empty() {
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return
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}
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lm.tree.root.InvalidateAnnotation(annotator)
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}
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// LevelFile holds a file's metadata along with its position
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// within a level of the LSM.
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type LevelFile struct {
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*FileMetadata
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slice LevelSlice
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}
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// Slice constructs a LevelSlice containing only this file.
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func (lf LevelFile) Slice() LevelSlice {
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return lf.slice
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}
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// NewLevelSliceSeqSorted constructs a LevelSlice over the provided files,
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// sorted by the L0 sequence number sort order.
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// TODO(jackson): Can we improve this interface or avoid needing to export
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// a slice constructor like this?
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func NewLevelSliceSeqSorted(files []*FileMetadata) LevelSlice {
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tr, slice := makeBTree(btreeCmpSeqNum, files)
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tr.Release()
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slice.verifyInvariants()
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return slice
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}
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// NewLevelSliceKeySorted constructs a LevelSlice over the provided files,
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// sorted by the files smallest keys.
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// TODO(jackson): Can we improve this interface or avoid needing to export
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// a slice constructor like this?
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func NewLevelSliceKeySorted(cmp base.Compare, files []*FileMetadata) LevelSlice {
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tr, slice := makeBTree(btreeCmpSmallestKey(cmp), files)
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tr.Release()
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slice.verifyInvariants()
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return slice
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}
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// NewLevelSliceSpecificOrder constructs a LevelSlice over the provided files,
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// ordering the files by their order in the provided slice. It's used in
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// tests.
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// TODO(jackson): Update tests to avoid requiring this and remove it.
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func NewLevelSliceSpecificOrder(files []*FileMetadata) LevelSlice {
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tr, slice := makeBTree(btreeCmpSpecificOrder(files), files)
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tr.Release()
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slice.verifyInvariants()
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return slice
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}
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// newLevelSlice constructs a new LevelSlice backed by iter.
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func newLevelSlice(iter iterator) LevelSlice {
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s := LevelSlice{iter: iter}
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if iter.r != nil {
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s.length = iter.r.subtreeCount
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}
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s.verifyInvariants()
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return s
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}
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// newBoundedLevelSlice constructs a new LevelSlice backed by iter and bounded
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// by the provided start and end bounds. The provided startBound and endBound
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// iterators must be iterators over the same B-Tree. Both start and end bounds
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// are inclusive.
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func newBoundedLevelSlice(iter iterator, startBound, endBound *iterator) LevelSlice {
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s := LevelSlice{
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iter: iter,
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start: startBound,
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end: endBound,
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}
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if iter.valid() {
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s.length = endBound.countLeft() - startBound.countLeft()
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// NB: The +1 is a consequence of the end bound being inclusive.
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if endBound.valid() {
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s.length++
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}
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// NB: A slice that's empty due to its bounds may have an endBound
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// positioned before the startBound due to the inclusive bounds.
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// TODO(jackson): Consider refactoring the end boundary to be exclusive;
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// it would simplify some areas (eg, here) and complicate others (eg,
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// Reslice-ing to grow compactions).
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if s.length < 0 {
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s.length = 0
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}
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}
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s.verifyInvariants()
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return s
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}
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// LevelSlice contains a slice of the files within a level of the LSM.
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// A LevelSlice is immutable once created, but may be used to construct a
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// mutable LevelIterator over the slice's files.
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//
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// LevelSlices should be constructed through one of the existing constructors,
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// not manually initialized.
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type LevelSlice struct {
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iter iterator
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length int
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// start and end form the inclusive bounds of a slice of files within a
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// level of the LSM. They may be nil if the entire B-Tree backing iter is
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// accessible.
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start *iterator
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end *iterator
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}
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func (ls LevelSlice) verifyInvariants() {
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if invariants.Enabled {
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i := ls.Iter()
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var length int
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for f := i.First(); f != nil; f = i.Next() {
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length++
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}
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if ls.length != length {
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panic(fmt.Sprintf("LevelSlice %s has length %d value; actual length is %d", ls, ls.length, length))
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}
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}
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}
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// Each invokes fn for each element in the slice.
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func (ls LevelSlice) Each(fn func(*FileMetadata)) {
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iter := ls.Iter()
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for f := iter.First(); f != nil; f = iter.Next() {
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fn(f)
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}
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}
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// String implements fmt.Stringer.
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func (ls LevelSlice) String() string {
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var buf bytes.Buffer
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fmt.Fprintf(&buf, "%d files: ", ls.length)
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ls.Each(func(f *FileMetadata) {
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if buf.Len() > 0 {
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fmt.Fprintf(&buf, " ")
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}
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fmt.Fprint(&buf, f)
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})
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return buf.String()
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}
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// Empty indicates whether the slice contains any files.
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func (ls *LevelSlice) Empty() bool {
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return emptyWithBounds(ls.iter, ls.start, ls.end)
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}
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// Iter constructs a LevelIterator that iterates over the slice.
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func (ls *LevelSlice) Iter() LevelIterator {
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return LevelIterator{
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start: ls.start,
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end: ls.end,
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iter: ls.iter.clone(),
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}
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}
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// Len returns the number of files in the slice. Its runtime is constant.
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func (ls *LevelSlice) Len() int {
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return ls.length
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}
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// SizeSum sums the size of all files in the slice. Its runtime is linear in
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// the length of the slice.
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func (ls *LevelSlice) SizeSum() uint64 {
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var sum uint64
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iter := ls.Iter()
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for f := iter.First(); f != nil; f = iter.Next() {
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sum += f.Size
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}
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return sum
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}
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// NumVirtual returns the number of virtual sstables in the level. Its runtime is
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// linear in the length of the slice.
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func (ls *LevelSlice) NumVirtual() uint64 {
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var n uint64
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iter := ls.Iter()
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for f := iter.First(); f != nil; f = iter.Next() {
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if f.Virtual {
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n++
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}
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}
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return n
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}
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// VirtualSizeSum returns the sum of the sizes of the virtual sstables in the
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// level.
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func (ls *LevelSlice) VirtualSizeSum() uint64 {
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var sum uint64
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iter := ls.Iter()
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for f := iter.First(); f != nil; f = iter.Next() {
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if f.Virtual {
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sum += f.Size
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}
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}
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return sum
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}
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// Reslice constructs a new slice backed by the same underlying level, with
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// new start and end positions. Reslice invokes the provided function, passing
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// two LevelIterators: one positioned to i's inclusive start and one
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// positioned to i's inclusive end. The resliceFunc may move either iterator
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// forward or backwards, including beyond the callee's original bounds to
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// capture additional files from the underlying level. Reslice constructs and
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// returns a new LevelSlice with the final bounds of the iterators after
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// calling resliceFunc.
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func (ls LevelSlice) Reslice(resliceFunc func(start, end *LevelIterator)) LevelSlice {
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if ls.iter.r == nil {
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return ls
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}
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var start, end LevelIterator
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if ls.start == nil {
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start.iter = ls.iter.clone()
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start.iter.first()
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} else {
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start.iter = ls.start.clone()
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}
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if ls.end == nil {
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end.iter = ls.iter.clone()
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end.iter.last()
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} else {
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end.iter = ls.end.clone()
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}
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resliceFunc(&start, &end)
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return newBoundedLevelSlice(start.iter.clone(), &start.iter, &end.iter)
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}
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// KeyType is used to specify the type of keys we're looking for in
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// LevelIterator positioning operations. Files not containing any keys of the
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// desired type are skipped.
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type KeyType int8
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const (
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// KeyTypePointAndRange denotes a search among the entire keyspace, including
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// both point keys and range keys. No sstables are skipped.
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KeyTypePointAndRange KeyType = iota
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// KeyTypePoint denotes a search among the point keyspace. SSTables with no
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// point keys will be skipped. Note that the point keyspace includes rangedels.
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KeyTypePoint
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// KeyTypeRange denotes a search among the range keyspace. SSTables with no
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// range keys will be skipped.
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KeyTypeRange
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)
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type keyTypeAnnotator struct{}
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var _ Annotator = keyTypeAnnotator{}
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func (k keyTypeAnnotator) Zero(dst interface{}) interface{} {
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var val *KeyType
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if dst != nil {
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val = dst.(*KeyType)
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} else {
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val = new(KeyType)
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}
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*val = KeyTypePoint
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return val
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}
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func (k keyTypeAnnotator) Accumulate(m *FileMetadata, dst interface{}) (interface{}, bool) {
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v := dst.(*KeyType)
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switch *v {
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case KeyTypePoint:
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if m.HasRangeKeys {
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*v = KeyTypePointAndRange
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}
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case KeyTypePointAndRange:
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// Do nothing.
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default:
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panic("unexpected key type")
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}
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return v, true
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}
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func (k keyTypeAnnotator) Merge(src interface{}, dst interface{}) interface{} {
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v := dst.(*KeyType)
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srcVal := src.(*KeyType)
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switch *v {
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case KeyTypePoint:
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if *srcVal == KeyTypePointAndRange {
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*v = KeyTypePointAndRange
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}
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case KeyTypePointAndRange:
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// Do nothing.
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default:
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panic("unexpected key type")
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}
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return v
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}
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// LevelIterator iterates over a set of files' metadata. Its zero value is an
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// empty iterator.
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type LevelIterator struct {
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iter iterator
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start *iterator
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end *iterator
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filter KeyType
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}
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func (i LevelIterator) String() string {
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var buf bytes.Buffer
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iter := i.iter.clone()
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iter.first()
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iter.prev()
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if i.iter.pos == -1 {
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fmt.Fprint(&buf, "(<start>)*")
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}
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iter.next()
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for ; iter.valid(); iter.next() {
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if buf.Len() > 0 {
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fmt.Fprint(&buf, " ")
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}
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if i.start != nil && cmpIter(iter, *i.start) == 0 {
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fmt.Fprintf(&buf, " [ ")
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}
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isCurrentPos := cmpIter(iter, i.iter) == 0
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if isCurrentPos {
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fmt.Fprint(&buf, " ( ")
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}
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fmt.Fprint(&buf, iter.cur().String())
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if isCurrentPos {
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fmt.Fprint(&buf, " )*")
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}
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if i.end != nil && cmpIter(iter, *i.end) == 0 {
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fmt.Fprintf(&buf, " ]")
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}
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}
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if i.iter.n != nil && i.iter.pos >= i.iter.n.count {
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if buf.Len() > 0 {
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fmt.Fprint(&buf, " ")
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}
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fmt.Fprint(&buf, "(<end>)*")
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}
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return buf.String()
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}
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// Clone copies the iterator, returning an independent iterator at the same
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// position.
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func (i *LevelIterator) Clone() LevelIterator {
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if i.iter.r == nil {
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return *i
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}
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// The start and end iterators are not cloned and are treated as
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// immutable.
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return LevelIterator{
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iter: i.iter.clone(),
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start: i.start,
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end: i.end,
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filter: i.filter,
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}
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}
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|
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// Current returns the item at the current iterator position.
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//
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// Current is deprecated. Callers should instead use the return value of a
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// positioning operation.
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func (i *LevelIterator) Current() *FileMetadata {
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if !i.iter.valid() ||
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(i.end != nil && cmpIter(i.iter, *i.end) > 0) ||
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(i.start != nil && cmpIter(i.iter, *i.start) < 0) {
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return nil
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}
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return i.iter.cur()
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}
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|
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func (i *LevelIterator) empty() bool {
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return emptyWithBounds(i.iter, i.start, i.end)
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}
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|
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// Filter clones the iterator and sets the desired KeyType as the key to filter
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// files on.
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func (i *LevelIterator) Filter(keyType KeyType) LevelIterator {
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l := i.Clone()
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l.filter = keyType
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return l
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}
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|
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func emptyWithBounds(i iterator, start, end *iterator) bool {
|
|
// If i.r is nil, the iterator was constructed from an empty btree.
|
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// If the end bound is before the start bound, the bounds represent an
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// empty slice of the B-Tree.
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return i.r == nil || (start != nil && end != nil && cmpIter(*end, *start) < 0)
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}
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|
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// First seeks to the first file in the iterator and returns it.
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|
func (i *LevelIterator) First() *FileMetadata {
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if i.empty() {
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|
return nil
|
|
}
|
|
if i.start != nil {
|
|
i.iter = i.start.clone()
|
|
} else {
|
|
i.iter.first()
|
|
}
|
|
if !i.iter.valid() {
|
|
return nil
|
|
}
|
|
return i.skipFilteredForward(i.iter.cur())
|
|
}
|
|
|
|
// Last seeks to the last file in the iterator and returns it.
|
|
func (i *LevelIterator) Last() *FileMetadata {
|
|
if i.empty() {
|
|
return nil
|
|
}
|
|
if i.end != nil {
|
|
i.iter = i.end.clone()
|
|
} else {
|
|
i.iter.last()
|
|
}
|
|
if !i.iter.valid() {
|
|
return nil
|
|
}
|
|
return i.skipFilteredBackward(i.iter.cur())
|
|
}
|
|
|
|
// Next advances the iterator to the next file and returns it.
|
|
func (i *LevelIterator) Next() *FileMetadata {
|
|
if i.iter.r == nil {
|
|
return nil
|
|
}
|
|
if invariants.Enabled && (i.iter.pos >= i.iter.n.count || (i.end != nil && cmpIter(i.iter, *i.end) > 0)) {
|
|
panic("pebble: cannot next forward-exhausted iterator")
|
|
}
|
|
i.iter.next()
|
|
if !i.iter.valid() {
|
|
return nil
|
|
}
|
|
return i.skipFilteredForward(i.iter.cur())
|
|
}
|
|
|
|
// Prev moves the iterator the previous file and returns it.
|
|
func (i *LevelIterator) Prev() *FileMetadata {
|
|
if i.iter.r == nil {
|
|
return nil
|
|
}
|
|
if invariants.Enabled && (i.iter.pos < 0 || (i.start != nil && cmpIter(i.iter, *i.start) < 0)) {
|
|
panic("pebble: cannot prev backward-exhausted iterator")
|
|
}
|
|
i.iter.prev()
|
|
if !i.iter.valid() {
|
|
return nil
|
|
}
|
|
return i.skipFilteredBackward(i.iter.cur())
|
|
}
|
|
|
|
// SeekGE seeks to the first file in the iterator's file set with a largest
|
|
// user key greater than or equal to the provided user key. The iterator must
|
|
// have been constructed from L1+, because it requires the underlying files to
|
|
// be sorted by user keys and non-overlapping.
|
|
func (i *LevelIterator) SeekGE(cmp Compare, userKey []byte) *FileMetadata {
|
|
// TODO(jackson): Assert that i.iter.cmp == btreeCmpSmallestKey.
|
|
if i.iter.r == nil {
|
|
return nil
|
|
}
|
|
m := i.seek(func(m *FileMetadata) bool {
|
|
return cmp(m.Largest.UserKey, userKey) >= 0
|
|
})
|
|
if i.filter != KeyTypePointAndRange && m != nil {
|
|
b, ok := m.LargestBound(i.filter)
|
|
if !ok {
|
|
m = i.Next()
|
|
} else if c := cmp(b.UserKey, userKey); c < 0 || c == 0 && b.IsExclusiveSentinel() {
|
|
// This file does not contain any keys of the type ≥ lower. It
|
|
// should be filtered, even though it does contain point keys.
|
|
m = i.Next()
|
|
}
|
|
}
|
|
return i.skipFilteredForward(m)
|
|
}
|
|
|
|
// SeekLT seeks to the last file in the iterator's file set with a smallest
|
|
// user key less than the provided user key. The iterator must have been
|
|
// constructed from L1+, because it requires the underlying files to be sorted
|
|
// by user keys and non-overlapping.
|
|
func (i *LevelIterator) SeekLT(cmp Compare, userKey []byte) *FileMetadata {
|
|
// TODO(jackson): Assert that i.iter.cmp == btreeCmpSmallestKey.
|
|
if i.iter.r == nil {
|
|
return nil
|
|
}
|
|
i.seek(func(m *FileMetadata) bool {
|
|
return cmp(m.Smallest.UserKey, userKey) >= 0
|
|
})
|
|
m := i.Prev()
|
|
// Although i.Prev() guarantees that the current file contains keys of the
|
|
// relevant type, it doesn't guarantee that the keys of the relevant type
|
|
// are < userKey.
|
|
if i.filter != KeyTypePointAndRange && m != nil {
|
|
b, ok := m.SmallestBound(i.filter)
|
|
if !ok {
|
|
panic("unreachable")
|
|
}
|
|
if c := cmp(b.UserKey, userKey); c >= 0 {
|
|
// This file does not contain any keys of the type ≥ lower. It
|
|
// should be filtered, even though it does contain point keys.
|
|
m = i.Prev()
|
|
}
|
|
}
|
|
return i.skipFilteredBackward(m)
|
|
}
|
|
|
|
// skipFilteredForward takes the file metadata at the iterator's current
|
|
// position, and skips forward if the current key-type filter (i.filter)
|
|
// excludes the file. It skips until it finds an unfiltered file or exhausts the
|
|
// level. If lower is != nil, skipFilteredForward skips any files that do not
|
|
// contain keys with the provided key-type ≥ lower.
|
|
//
|
|
// skipFilteredForward also enforces the upper bound, returning nil if at any
|
|
// point the upper bound is exceeded.
|
|
func (i *LevelIterator) skipFilteredForward(meta *FileMetadata) *FileMetadata {
|
|
for meta != nil && !meta.ContainsKeyType(i.filter) {
|
|
i.iter.next()
|
|
if !i.iter.valid() {
|
|
meta = nil
|
|
} else {
|
|
meta = i.iter.cur()
|
|
}
|
|
}
|
|
if meta != nil && i.end != nil && cmpIter(i.iter, *i.end) > 0 {
|
|
// Exceeded upper bound.
|
|
meta = nil
|
|
}
|
|
return meta
|
|
}
|
|
|
|
// skipFilteredBackward takes the file metadata at the iterator's current
|
|
// position, and skips backward if the current key-type filter (i.filter)
|
|
// excludes the file. It skips until it finds an unfiltered file or exhausts the
|
|
// level. If upper is != nil, skipFilteredBackward skips any files that do not
|
|
// contain keys with the provided key-type < upper.
|
|
//
|
|
// skipFilteredBackward also enforces the lower bound, returning nil if at any
|
|
// point the lower bound is exceeded.
|
|
func (i *LevelIterator) skipFilteredBackward(meta *FileMetadata) *FileMetadata {
|
|
for meta != nil && !meta.ContainsKeyType(i.filter) {
|
|
i.iter.prev()
|
|
if !i.iter.valid() {
|
|
meta = nil
|
|
} else {
|
|
meta = i.iter.cur()
|
|
}
|
|
}
|
|
if meta != nil && i.start != nil && cmpIter(i.iter, *i.start) < 0 {
|
|
// Exceeded lower bound.
|
|
meta = nil
|
|
}
|
|
return meta
|
|
}
|
|
|
|
func (i *LevelIterator) seek(fn func(*FileMetadata) bool) *FileMetadata {
|
|
i.iter.seek(fn)
|
|
|
|
// i.iter.seek seeked in the unbounded underlying B-Tree. If the iterator
|
|
// has start or end bounds, we may have exceeded them. Reset to the bounds
|
|
// if necessary.
|
|
//
|
|
// NB: The LevelIterator and LevelSlice semantics require that a bounded
|
|
// LevelIterator/LevelSlice containing files x0, x1, ..., xn behave
|
|
// identically to an unbounded LevelIterator/LevelSlice of a B-Tree
|
|
// containing x0, x1, ..., xn. In other words, any files outside the
|
|
// LevelIterator's bounds should not influence the iterator's behavior.
|
|
// When seeking, this means a SeekGE that seeks beyond the end bound,
|
|
// followed by a Prev should return the last element within bounds.
|
|
if i.end != nil && cmpIter(i.iter, *i.end) > 0 {
|
|
i.iter = i.end.clone()
|
|
// Since seek(fn) positioned beyond i.end, we know there is nothing to
|
|
// return within bounds.
|
|
i.iter.next()
|
|
return nil
|
|
} else if i.start != nil && cmpIter(i.iter, *i.start) < 0 {
|
|
i.iter = i.start.clone()
|
|
}
|
|
if !i.iter.valid() {
|
|
return nil
|
|
}
|
|
return i.iter.cur()
|
|
}
|
|
|
|
// Take constructs a LevelFile containing the file at the iterator's current
|
|
// position. Take panics if the iterator is not currently positioned over a
|
|
// file.
|
|
func (i *LevelIterator) Take() LevelFile {
|
|
m := i.Current()
|
|
if m == nil {
|
|
panic("Take called on invalid LevelIterator")
|
|
}
|
|
// LevelSlice's start and end fields are immutable and are positioned to
|
|
// the same position for a LevelFile because they're inclusive, so we can
|
|
// share one iterator stack between the two bounds.
|
|
boundsIter := i.iter.clone()
|
|
s := newBoundedLevelSlice(i.iter.clone(), &boundsIter, &boundsIter)
|
|
return LevelFile{
|
|
FileMetadata: m,
|
|
slice: s,
|
|
}
|
|
}
|