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syncthing/vendor/github.com/syndtr/goleveldb/leveldb/session_compaction.go
Jakob Borg 65aaa607ab Use Go 1.5 vendoring instead of Godeps 
Change made by:

- running "gvt fetch" on each of the packages mentioned in
  Godeps/Godeps.json
- `rm -rf Godeps`
- tweaking the build scripts to not mention Godeps
- tweaking the build scripts to test `./lib/...`, `./cmd/...` explicitly
  (to avoid testing vendor)
- tweaking the build scripts to not juggle GOPATH for Godeps and instead
  set GO15VENDOREXPERIMENT.

This also results in some updated packages at the same time I bet.

Building with Go 1.3 and 1.4 still *works* but won't use our vendored
dependencies - the user needs to have the actual packages in their
GOPATH then, which they'll get with a normal "go get". Building with Go
1.6+ will get our vendored dependencies by default even when not using
our build script, which is nice.

By doing this we gain some freedom in that we can pick and choose
manually what to include in vendor, as it's not based on just dependency
analysis of our own code. This is also a risk as we might pick up
dependencies we are unaware of, as the build may work locally with those
packages present in GOPATH. On the other hand the build server will
detect this as it has no packages in it's GOPATH beyond what is included
in the repo.

Recommended tool to manage dependencies is github.com/FiloSottile/gvt.
2016-03-05 21:21:24 +01:00

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// 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)
}
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