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gitea/vendor/github.com/syndtr/goleveldb/leveldb/session_compaction.go

303 lines
8.3 KiB
Go

// Copyright (c) 2012, Suryandaru Triandana <syndtr@gmail.com>
// All rights reserved.
//
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
package leveldb
import (
"sync/atomic"
"github.com/syndtr/goleveldb/leveldb/iterator"
"github.com/syndtr/goleveldb/leveldb/memdb"
"github.com/syndtr/goleveldb/leveldb/opt"
)
func (s *session) pickMemdbLevel(umin, umax []byte, maxLevel int) int {
v := s.version()
defer v.release()
return v.pickMemdbLevel(umin, umax, maxLevel)
}
func (s *session) flushMemdb(rec *sessionRecord, mdb *memdb.DB, maxLevel int) (int, error) {
// Create sorted table.
iter := mdb.NewIterator(nil)
defer iter.Release()
t, n, err := s.tops.createFrom(iter)
if err != nil {
return 0, err
}
// Pick level other than zero can cause compaction issue with large
// bulk insert and delete on strictly incrementing key-space. The
// problem is that the small deletion markers trapped at lower level,
// while key/value entries keep growing at higher level. Since the
// key-space is strictly incrementing it will not overlaps with
// higher level, thus maximum possible level is always picked, while
// overlapping deletion marker pushed into lower level.
// See: https://github.com/syndtr/goleveldb/issues/127.
flushLevel := s.pickMemdbLevel(t.imin.ukey(), t.imax.ukey(), maxLevel)
rec.addTableFile(flushLevel, t)
s.logf("memdb@flush created L%d@%d N·%d S·%s %q:%q", flushLevel, t.fd.Num, n, shortenb(int(t.size)), t.imin, t.imax)
return flushLevel, nil
}
// Pick a compaction based on current state; need external synchronization.
func (s *session) pickCompaction() *compaction {
v := s.version()
var sourceLevel int
var t0 tFiles
if v.cScore >= 1 {
sourceLevel = v.cLevel
cptr := s.getCompPtr(sourceLevel)
tables := v.levels[sourceLevel]
for _, t := range tables {
if cptr == nil || s.icmp.Compare(t.imax, cptr) > 0 {
t0 = append(t0, t)
break
}
}
if len(t0) == 0 {
t0 = append(t0, tables[0])
}
} else {
if p := atomic.LoadPointer(&v.cSeek); p != nil {
ts := (*tSet)(p)
sourceLevel = ts.level
t0 = append(t0, ts.table)
} else {
v.release()
return nil
}
}
return newCompaction(s, v, sourceLevel, t0)
}
// Create compaction from given level and range; need external synchronization.
func (s *session) getCompactionRange(sourceLevel int, umin, umax []byte, noLimit bool) *compaction {
v := s.version()
if sourceLevel >= len(v.levels) {
v.release()
return nil
}
t0 := v.levels[sourceLevel].getOverlaps(nil, s.icmp, umin, umax, sourceLevel == 0)
if len(t0) == 0 {
v.release()
return nil
}
// Avoid compacting too much in one shot in case the range is large.
// But we cannot do this for level-0 since level-0 files can overlap
// and we must not pick one file and drop another older file if the
// two files overlap.
if !noLimit && sourceLevel > 0 {
limit := int64(v.s.o.GetCompactionSourceLimit(sourceLevel))
total := int64(0)
for i, t := range t0 {
total += t.size
if total >= limit {
s.logf("table@compaction limiting F·%d -> F·%d", len(t0), i+1)
t0 = t0[:i+1]
break
}
}
}
return newCompaction(s, v, sourceLevel, t0)
}
func newCompaction(s *session, v *version, sourceLevel int, t0 tFiles) *compaction {
c := &compaction{
s: s,
v: v,
sourceLevel: sourceLevel,
levels: [2]tFiles{t0, nil},
maxGPOverlaps: int64(s.o.GetCompactionGPOverlaps(sourceLevel)),
tPtrs: make([]int, len(v.levels)),
}
c.expand()
c.save()
return c
}
// compaction represent a compaction state.
type compaction struct {
s *session
v *version
sourceLevel int
levels [2]tFiles
maxGPOverlaps int64
gp tFiles
gpi int
seenKey bool
gpOverlappedBytes int64
imin, imax internalKey
tPtrs []int
released bool
snapGPI int
snapSeenKey bool
snapGPOverlappedBytes int64
snapTPtrs []int
}
func (c *compaction) save() {
c.snapGPI = c.gpi
c.snapSeenKey = c.seenKey
c.snapGPOverlappedBytes = c.gpOverlappedBytes
c.snapTPtrs = append(c.snapTPtrs[:0], c.tPtrs...)
}
func (c *compaction) restore() {
c.gpi = c.snapGPI
c.seenKey = c.snapSeenKey
c.gpOverlappedBytes = c.snapGPOverlappedBytes
c.tPtrs = append(c.tPtrs[:0], c.snapTPtrs...)
}
func (c *compaction) release() {
if !c.released {
c.released = true
c.v.release()
}
}
// Expand compacted tables; need external synchronization.
func (c *compaction) expand() {
limit := int64(c.s.o.GetCompactionExpandLimit(c.sourceLevel))
vt0 := c.v.levels[c.sourceLevel]
vt1 := tFiles{}
if level := c.sourceLevel + 1; level < len(c.v.levels) {
vt1 = c.v.levels[level]
}
t0, t1 := c.levels[0], c.levels[1]
imin, imax := t0.getRange(c.s.icmp)
// We expand t0 here just incase ukey hop across tables.
t0 = vt0.getOverlaps(t0, c.s.icmp, imin.ukey(), imax.ukey(), c.sourceLevel == 0)
if len(t0) != len(c.levels[0]) {
imin, imax = t0.getRange(c.s.icmp)
}
t1 = vt1.getOverlaps(t1, c.s.icmp, imin.ukey(), imax.ukey(), false)
// Get entire range covered by compaction.
amin, amax := append(t0, t1...).getRange(c.s.icmp)
// See if we can grow the number of inputs in "sourceLevel" without
// changing the number of "sourceLevel+1" files we pick up.
if len(t1) > 0 {
exp0 := vt0.getOverlaps(nil, c.s.icmp, amin.ukey(), amax.ukey(), c.sourceLevel == 0)
if len(exp0) > len(t0) && t1.size()+exp0.size() < limit {
xmin, xmax := exp0.getRange(c.s.icmp)
exp1 := vt1.getOverlaps(nil, c.s.icmp, xmin.ukey(), xmax.ukey(), false)
if len(exp1) == len(t1) {
c.s.logf("table@compaction expanding L%d+L%d (F·%d S·%s)+(F·%d S·%s) -> (F·%d S·%s)+(F·%d S·%s)",
c.sourceLevel, c.sourceLevel+1, len(t0), shortenb(int(t0.size())), len(t1), shortenb(int(t1.size())),
len(exp0), shortenb(int(exp0.size())), len(exp1), shortenb(int(exp1.size())))
imin, imax = xmin, xmax
t0, t1 = exp0, exp1
amin, amax = append(t0, t1...).getRange(c.s.icmp)
}
}
}
// Compute the set of grandparent files that overlap this compaction
// (parent == sourceLevel+1; grandparent == sourceLevel+2)
if level := c.sourceLevel + 2; level < len(c.v.levels) {
c.gp = c.v.levels[level].getOverlaps(c.gp, c.s.icmp, amin.ukey(), amax.ukey(), false)
}
c.levels[0], c.levels[1] = t0, t1
c.imin, c.imax = imin, imax
}
// Check whether compaction is trivial.
func (c *compaction) trivial() bool {
return len(c.levels[0]) == 1 && len(c.levels[1]) == 0 && c.gp.size() <= c.maxGPOverlaps
}
func (c *compaction) baseLevelForKey(ukey []byte) bool {
for level := c.sourceLevel + 2; level < len(c.v.levels); level++ {
tables := c.v.levels[level]
for c.tPtrs[level] < len(tables) {
t := tables[c.tPtrs[level]]
if c.s.icmp.uCompare(ukey, t.imax.ukey()) <= 0 {
// We've advanced far enough.
if c.s.icmp.uCompare(ukey, t.imin.ukey()) >= 0 {
// Key falls in this file's range, so definitely not base level.
return false
}
break
}
c.tPtrs[level]++
}
}
return true
}
func (c *compaction) shouldStopBefore(ikey internalKey) bool {
for ; c.gpi < len(c.gp); c.gpi++ {
gp := c.gp[c.gpi]
if c.s.icmp.Compare(ikey, gp.imax) <= 0 {
break
}
if c.seenKey {
c.gpOverlappedBytes += gp.size
}
}
c.seenKey = true
if c.gpOverlappedBytes > c.maxGPOverlaps {
// Too much overlap for current output; start new output.
c.gpOverlappedBytes = 0
return true
}
return false
}
// Creates an iterator.
func (c *compaction) newIterator() iterator.Iterator {
// Creates iterator slice.
icap := len(c.levels)
if c.sourceLevel == 0 {
// Special case for level-0.
icap = len(c.levels[0]) + 1
}
its := make([]iterator.Iterator, 0, icap)
// Options.
ro := &opt.ReadOptions{
DontFillCache: true,
Strict: opt.StrictOverride,
}
strict := c.s.o.GetStrict(opt.StrictCompaction)
if strict {
ro.Strict |= opt.StrictReader
}
for i, tables := range c.levels {
if len(tables) == 0 {
continue
}
// Level-0 is not sorted and may overlaps each other.
if c.sourceLevel+i == 0 {
for _, t := range tables {
its = append(its, c.s.tops.newIterator(t, nil, ro))
}
} else {
it := iterator.NewIndexedIterator(tables.newIndexIterator(c.s.tops, c.s.icmp, nil, ro), strict)
its = append(its, it)
}
}
return iterator.NewMergedIterator(its, c.s.icmp, strict)
}