syncthing/vendor/github.com/syndtr/goleveldb/leveldb/table.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

530 lines
12 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 (
"fmt"
"sort"
"sync/atomic"
"github.com/syndtr/goleveldb/leveldb/cache"
"github.com/syndtr/goleveldb/leveldb/iterator"
"github.com/syndtr/goleveldb/leveldb/opt"
"github.com/syndtr/goleveldb/leveldb/storage"
"github.com/syndtr/goleveldb/leveldb/table"
"github.com/syndtr/goleveldb/leveldb/util"
)
// tFile holds basic information about a table.
type tFile struct {
fd storage.FileDesc
seekLeft int32
size int64
imin, imax internalKey
}
// Returns true if given key is after largest key of this table.
func (t *tFile) after(icmp *iComparer, ukey []byte) bool {
return ukey != nil && icmp.uCompare(ukey, t.imax.ukey()) > 0
}
// Returns true if given key is before smallest key of this table.
func (t *tFile) before(icmp *iComparer, ukey []byte) bool {
return ukey != nil && icmp.uCompare(ukey, t.imin.ukey()) < 0
}
// Returns true if given key range overlaps with this table key range.
func (t *tFile) overlaps(icmp *iComparer, umin, umax []byte) bool {
return !t.after(icmp, umin) && !t.before(icmp, umax)
}
// Cosumes one seek and return current seeks left.
func (t *tFile) consumeSeek() int32 {
return atomic.AddInt32(&t.seekLeft, -1)
}
// Creates new tFile.
func newTableFile(fd storage.FileDesc, size int64, imin, imax internalKey) *tFile {
f := &tFile{
fd: fd,
size: size,
imin: imin,
imax: imax,
}
// We arrange to automatically compact this file after
// a certain number of seeks. Let's assume:
// (1) One seek costs 10ms
// (2) Writing or reading 1MB costs 10ms (100MB/s)
// (3) A compaction of 1MB does 25MB of IO:
// 1MB read from this level
// 10-12MB read from next level (boundaries may be misaligned)
// 10-12MB written to next level
// This implies that 25 seeks cost the same as the compaction
// of 1MB of data. I.e., one seek costs approximately the
// same as the compaction of 40KB of data. We are a little
// conservative and allow approximately one seek for every 16KB
// of data before triggering a compaction.
f.seekLeft = int32(size / 16384)
if f.seekLeft < 100 {
f.seekLeft = 100
}
return f
}
func tableFileFromRecord(r atRecord) *tFile {
return newTableFile(storage.FileDesc{storage.TypeTable, r.num}, r.size, r.imin, r.imax)
}
// tFiles hold multiple tFile.
type tFiles []*tFile
func (tf tFiles) Len() int { return len(tf) }
func (tf tFiles) Swap(i, j int) { tf[i], tf[j] = tf[j], tf[i] }
func (tf tFiles) nums() string {
x := "[ "
for i, f := range tf {
if i != 0 {
x += ", "
}
x += fmt.Sprint(f.fd.Num)
}
x += " ]"
return x
}
// Returns true if i smallest key is less than j.
// This used for sort by key in ascending order.
func (tf tFiles) lessByKey(icmp *iComparer, i, j int) bool {
a, b := tf[i], tf[j]
n := icmp.Compare(a.imin, b.imin)
if n == 0 {
return a.fd.Num < b.fd.Num
}
return n < 0
}
// Returns true if i file number is greater than j.
// This used for sort by file number in descending order.
func (tf tFiles) lessByNum(i, j int) bool {
return tf[i].fd.Num > tf[j].fd.Num
}
// Sorts tables by key in ascending order.
func (tf tFiles) sortByKey(icmp *iComparer) {
sort.Sort(&tFilesSortByKey{tFiles: tf, icmp: icmp})
}
// Sorts tables by file number in descending order.
func (tf tFiles) sortByNum() {
sort.Sort(&tFilesSortByNum{tFiles: tf})
}
// Returns sum of all tables size.
func (tf tFiles) size() (sum int64) {
for _, t := range tf {
sum += t.size
}
return sum
}
// Searches smallest index of tables whose its smallest
// key is after or equal with given key.
func (tf tFiles) searchMin(icmp *iComparer, ikey internalKey) int {
return sort.Search(len(tf), func(i int) bool {
return icmp.Compare(tf[i].imin, ikey) >= 0
})
}
// Searches smallest index of tables whose its largest
// key is after or equal with given key.
func (tf tFiles) searchMax(icmp *iComparer, ikey internalKey) int {
return sort.Search(len(tf), func(i int) bool {
return icmp.Compare(tf[i].imax, ikey) >= 0
})
}
// Returns true if given key range overlaps with one or more
// tables key range. If unsorted is true then binary search will not be used.
func (tf tFiles) overlaps(icmp *iComparer, umin, umax []byte, unsorted bool) bool {
if unsorted {
// Check against all files.
for _, t := range tf {
if t.overlaps(icmp, umin, umax) {
return true
}
}
return false
}
i := 0
if len(umin) > 0 {
// Find the earliest possible internal key for min.
i = tf.searchMax(icmp, makeInternalKey(nil, umin, keyMaxSeq, keyTypeSeek))
}
if i >= len(tf) {
// Beginning of range is after all files, so no overlap.
return false
}
return !tf[i].before(icmp, umax)
}
// Returns tables whose its key range overlaps with given key range.
// Range will be expanded if ukey found hop across tables.
// If overlapped is true then the search will be restarted if umax
// expanded.
// The dst content will be overwritten.
func (tf tFiles) getOverlaps(dst tFiles, icmp *iComparer, umin, umax []byte, overlapped bool) tFiles {
dst = dst[:0]
for i := 0; i < len(tf); {
t := tf[i]
if t.overlaps(icmp, umin, umax) {
if umin != nil && icmp.uCompare(t.imin.ukey(), umin) < 0 {
umin = t.imin.ukey()
dst = dst[:0]
i = 0
continue
} else if umax != nil && icmp.uCompare(t.imax.ukey(), umax) > 0 {
umax = t.imax.ukey()
// Restart search if it is overlapped.
if overlapped {
dst = dst[:0]
i = 0
continue
}
}
dst = append(dst, t)
}
i++
}
return dst
}
// Returns tables key range.
func (tf tFiles) getRange(icmp *iComparer) (imin, imax internalKey) {
for i, t := range tf {
if i == 0 {
imin, imax = t.imin, t.imax
continue
}
if icmp.Compare(t.imin, imin) < 0 {
imin = t.imin
}
if icmp.Compare(t.imax, imax) > 0 {
imax = t.imax
}
}
return
}
// Creates iterator index from tables.
func (tf tFiles) newIndexIterator(tops *tOps, icmp *iComparer, slice *util.Range, ro *opt.ReadOptions) iterator.IteratorIndexer {
if slice != nil {
var start, limit int
if slice.Start != nil {
start = tf.searchMax(icmp, internalKey(slice.Start))
}
if slice.Limit != nil {
limit = tf.searchMin(icmp, internalKey(slice.Limit))
} else {
limit = tf.Len()
}
tf = tf[start:limit]
}
return iterator.NewArrayIndexer(&tFilesArrayIndexer{
tFiles: tf,
tops: tops,
icmp: icmp,
slice: slice,
ro: ro,
})
}
// Tables iterator index.
type tFilesArrayIndexer struct {
tFiles
tops *tOps
icmp *iComparer
slice *util.Range
ro *opt.ReadOptions
}
func (a *tFilesArrayIndexer) Search(key []byte) int {
return a.searchMax(a.icmp, internalKey(key))
}
func (a *tFilesArrayIndexer) Get(i int) iterator.Iterator {
if i == 0 || i == a.Len()-1 {
return a.tops.newIterator(a.tFiles[i], a.slice, a.ro)
}
return a.tops.newIterator(a.tFiles[i], nil, a.ro)
}
// Helper type for sortByKey.
type tFilesSortByKey struct {
tFiles
icmp *iComparer
}
func (x *tFilesSortByKey) Less(i, j int) bool {
return x.lessByKey(x.icmp, i, j)
}
// Helper type for sortByNum.
type tFilesSortByNum struct {
tFiles
}
func (x *tFilesSortByNum) Less(i, j int) bool {
return x.lessByNum(i, j)
}
// Table operations.
type tOps struct {
s *session
noSync bool
cache *cache.Cache
bcache *cache.Cache
bpool *util.BufferPool
}
// Creates an empty table and returns table writer.
func (t *tOps) create() (*tWriter, error) {
fd := storage.FileDesc{storage.TypeTable, t.s.allocFileNum()}
fw, err := t.s.stor.Create(fd)
if err != nil {
return nil, err
}
return &tWriter{
t: t,
fd: fd,
w: fw,
tw: table.NewWriter(fw, t.s.o.Options),
}, nil
}
// Builds table from src iterator.
func (t *tOps) createFrom(src iterator.Iterator) (f *tFile, n int, err error) {
w, err := t.create()
if err != nil {
return
}
defer func() {
if err != nil {
w.drop()
}
}()
for src.Next() {
err = w.append(src.Key(), src.Value())
if err != nil {
return
}
}
err = src.Error()
if err != nil {
return
}
n = w.tw.EntriesLen()
f, err = w.finish()
return
}
// Opens table. It returns a cache handle, which should
// be released after use.
func (t *tOps) open(f *tFile) (ch *cache.Handle, err error) {
ch = t.cache.Get(0, uint64(f.fd.Num), func() (size int, value cache.Value) {
var r storage.Reader
r, err = t.s.stor.Open(f.fd)
if err != nil {
return 0, nil
}
var bcache *cache.NamespaceGetter
if t.bcache != nil {
bcache = &cache.NamespaceGetter{Cache: t.bcache, NS: uint64(f.fd.Num)}
}
var tr *table.Reader
tr, err = table.NewReader(r, f.size, f.fd, bcache, t.bpool, t.s.o.Options)
if err != nil {
r.Close()
return 0, nil
}
return 1, tr
})
if ch == nil && err == nil {
err = ErrClosed
}
return
}
// Finds key/value pair whose key is greater than or equal to the
// given key.
func (t *tOps) find(f *tFile, key []byte, ro *opt.ReadOptions) (rkey, rvalue []byte, err error) {
ch, err := t.open(f)
if err != nil {
return nil, nil, err
}
defer ch.Release()
return ch.Value().(*table.Reader).Find(key, true, ro)
}
// Finds key that is greater than or equal to the given key.
func (t *tOps) findKey(f *tFile, key []byte, ro *opt.ReadOptions) (rkey []byte, err error) {
ch, err := t.open(f)
if err != nil {
return nil, err
}
defer ch.Release()
return ch.Value().(*table.Reader).FindKey(key, true, ro)
}
// Returns approximate offset of the given key.
func (t *tOps) offsetOf(f *tFile, key []byte) (offset int64, err error) {
ch, err := t.open(f)
if err != nil {
return
}
defer ch.Release()
return ch.Value().(*table.Reader).OffsetOf(key)
}
// Creates an iterator from the given table.
func (t *tOps) newIterator(f *tFile, slice *util.Range, ro *opt.ReadOptions) iterator.Iterator {
ch, err := t.open(f)
if err != nil {
return iterator.NewEmptyIterator(err)
}
iter := ch.Value().(*table.Reader).NewIterator(slice, ro)
iter.SetReleaser(ch)
return iter
}
// Removes table from persistent storage. It waits until
// no one use the the table.
func (t *tOps) remove(f *tFile) {
t.cache.Delete(0, uint64(f.fd.Num), func() {
if err := t.s.stor.Remove(f.fd); err != nil {
t.s.logf("table@remove removing @%d %q", f.fd.Num, err)
} else {
t.s.logf("table@remove removed @%d", f.fd.Num)
}
if t.bcache != nil {
t.bcache.EvictNS(uint64(f.fd.Num))
}
})
}
// Closes the table ops instance. It will close all tables,
// regadless still used or not.
func (t *tOps) close() {
t.bpool.Close()
t.cache.Close()
if t.bcache != nil {
t.bcache.Close()
}
}
// Creates new initialized table ops instance.
func newTableOps(s *session) *tOps {
var (
cacher cache.Cacher
bcache *cache.Cache
bpool *util.BufferPool
)
if s.o.GetOpenFilesCacheCapacity() > 0 {
cacher = cache.NewLRU(s.o.GetOpenFilesCacheCapacity())
}
if !s.o.GetDisableBlockCache() {
var bcacher cache.Cacher
if s.o.GetBlockCacheCapacity() > 0 {
bcacher = cache.NewLRU(s.o.GetBlockCacheCapacity())
}
bcache = cache.NewCache(bcacher)
}
if !s.o.GetDisableBufferPool() {
bpool = util.NewBufferPool(s.o.GetBlockSize() + 5)
}
return &tOps{
s: s,
noSync: s.o.GetNoSync(),
cache: cache.NewCache(cacher),
bcache: bcache,
bpool: bpool,
}
}
// tWriter wraps the table writer. It keep track of file descriptor
// and added key range.
type tWriter struct {
t *tOps
fd storage.FileDesc
w storage.Writer
tw *table.Writer
first, last []byte
}
// Append key/value pair to the table.
func (w *tWriter) append(key, value []byte) error {
if w.first == nil {
w.first = append([]byte{}, key...)
}
w.last = append(w.last[:0], key...)
return w.tw.Append(key, value)
}
// Returns true if the table is empty.
func (w *tWriter) empty() bool {
return w.first == nil
}
// Closes the storage.Writer.
func (w *tWriter) close() {
if w.w != nil {
w.w.Close()
w.w = nil
}
}
// Finalizes the table and returns table file.
func (w *tWriter) finish() (f *tFile, err error) {
defer w.close()
err = w.tw.Close()
if err != nil {
return
}
if !w.t.noSync {
err = w.w.Sync()
if err != nil {
return
}
}
f = newTableFile(w.fd, int64(w.tw.BytesLen()), internalKey(w.first), internalKey(w.last))
return
}
// Drops the table.
func (w *tWriter) drop() {
w.close()
w.t.s.stor.Remove(w.fd)
w.t.s.reuseFileNum(w.fd.Num)
w.tw = nil
w.first = nil
w.last = nil
}