vendor/go.etcd.io/etcd/mvcc/key_index.go - voltha-go - Gitiles

 // Copyright 2015 The etcd Authors
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 package mvcc

 import (
 	"bytes"
 	"errors"
 	"fmt"

 	"github.com/google/btree"
 	"go.uber.org/zap"
 )

 var (
 	ErrRevisionNotFound = errors.New("mvcc: revision not found")
 )

 // keyIndex stores the revisions of a key in the backend.
 // Each keyIndex has at least one key generation.
 // Each generation might have several key versions.
 // Tombstone on a key appends an tombstone version at the end
 // of the current generation and creates a new empty generation.
 // Each version of a key has an index pointing to the backend.
 //
 // For example: put(1.0);put(2.0);tombstone(3.0);put(4.0);tombstone(5.0) on key "foo"
 // generate a keyIndex:
 // key:     "foo"
 // rev: 5
 // generations:
 //    {empty}
 //    {4.0, 5.0(t)}
 //    {1.0, 2.0, 3.0(t)}
 //
 // Compact a keyIndex removes the versions with smaller or equal to
 // rev except the largest one. If the generation becomes empty
 // during compaction, it will be removed. if all the generations get
 // removed, the keyIndex should be removed.
 //
 // For example:
 // compact(2) on the previous example
 // generations:
 //    {empty}
 //    {4.0, 5.0(t)}
 //    {2.0, 3.0(t)}
 //
 // compact(4)
 // generations:
 //    {empty}
 //    {4.0, 5.0(t)}
 //
 // compact(5):
 // generations:
 //    {empty} -> key SHOULD be removed.
 //
 // compact(6):
 // generations:
 //    {empty} -> key SHOULD be removed.
 type keyIndex struct {
 	key         []byte
 	modified    revision // the main rev of the last modification
 	generations []generation
 }

 // put puts a revision to the keyIndex.
 func (ki *keyIndex) put(lg *zap.Logger, main int64, sub int64) {
 	rev := revision{main: main, sub: sub}

 	if !rev.GreaterThan(ki.modified) {
 		if lg != nil {
 			lg.Panic(
 				"'put' with an unexpected smaller revision",
 				zap.Int64("given-revision-main", rev.main),
 				zap.Int64("given-revision-sub", rev.sub),
 				zap.Int64("modified-revision-main", ki.modified.main),
 				zap.Int64("modified-revision-sub", ki.modified.sub),
 			)
 		} else {
 			plog.Panicf("store.keyindex: put with unexpected smaller revision [%v / %v]", rev, ki.modified)
 		}
 	}
 	if len(ki.generations) == 0 {
 		ki.generations = append(ki.generations, generation{})
 	}
 	g := &ki.generations[len(ki.generations)-1]
 	if len(g.revs) == 0 { // create a new key
 		keysGauge.Inc()
 		g.created = rev
 	}
 	g.revs = append(g.revs, rev)
 	g.ver++
 	ki.modified = rev
 }

 func (ki *keyIndex) restore(lg *zap.Logger, created, modified revision, ver int64) {
 	if len(ki.generations) != 0 {
 		if lg != nil {
 			lg.Panic(
 				"'restore' got an unexpected non-empty generations",
 				zap.Int("generations-size", len(ki.generations)),
 			)
 		} else {
 			plog.Panicf("store.keyindex: cannot restore non-empty keyIndex")
 		}
 	}

 	ki.modified = modified
 	g := generation{created: created, ver: ver, revs: []revision{modified}}
 	ki.generations = append(ki.generations, g)
 	keysGauge.Inc()
 }

 // tombstone puts a revision, pointing to a tombstone, to the keyIndex.
 // It also creates a new empty generation in the keyIndex.
 // It returns ErrRevisionNotFound when tombstone on an empty generation.
 func (ki *keyIndex) tombstone(lg *zap.Logger, main int64, sub int64) error {
 	if ki.isEmpty() {
 		if lg != nil {
 			lg.Panic(
 				"'tombstone' got an unexpected empty keyIndex",
 				zap.String("key", string(ki.key)),
 			)
 		} else {
 			plog.Panicf("store.keyindex: unexpected tombstone on empty keyIndex %s", string(ki.key))
 		}
 	}
 	if ki.generations[len(ki.generations)-1].isEmpty() {
 		return ErrRevisionNotFound
 	}
 	ki.put(lg, main, sub)
 	ki.generations = append(ki.generations, generation{})
 	keysGauge.Dec()
 	return nil
 }

 // get gets the modified, created revision and version of the key that satisfies the given atRev.
 // Rev must be higher than or equal to the given atRev.
 func (ki *keyIndex) get(lg *zap.Logger, atRev int64) (modified, created revision, ver int64, err error) {
 	if ki.isEmpty() {
 		if lg != nil {
 			lg.Panic(
 				"'get' got an unexpected empty keyIndex",
 				zap.String("key", string(ki.key)),
 			)
 		} else {
 			plog.Panicf("store.keyindex: unexpected get on empty keyIndex %s", string(ki.key))
 		}
 	}
 	g := ki.findGeneration(atRev)
 	if g.isEmpty() {
 		return revision{}, revision{}, 0, ErrRevisionNotFound
 	}

 	n := g.walk(func(rev revision) bool { return rev.main > atRev })
 	if n != -1 {
 		return g.revs[n], g.created, g.ver - int64(len(g.revs)-n-1), nil
 	}

 	return revision{}, revision{}, 0, ErrRevisionNotFound
 }

 // since returns revisions since the given rev. Only the revision with the
 // largest sub revision will be returned if multiple revisions have the same
 // main revision.
 func (ki *keyIndex) since(lg *zap.Logger, rev int64) []revision {
 	if ki.isEmpty() {
 		if lg != nil {
 			lg.Panic(
 				"'since' got an unexpected empty keyIndex",
 				zap.String("key", string(ki.key)),
 			)
 		} else {
 			plog.Panicf("store.keyindex: unexpected get on empty keyIndex %s", string(ki.key))
 		}
 	}
 	since := revision{rev, 0}
 	var gi int
 	// find the generations to start checking
 	for gi = len(ki.generations) - 1; gi > 0; gi-- {
 		g := ki.generations[gi]
 		if g.isEmpty() {
 			continue
 		}
 		if since.GreaterThan(g.created) {
 			break
 		}
 	}

 	var revs []revision
 	var last int64
 	for ; gi < len(ki.generations); gi++ {
 		for _, r := range ki.generations[gi].revs {
 			if since.GreaterThan(r) {
 				continue
 			}
 			if r.main == last {
 				// replace the revision with a new one that has higher sub value,
 				// because the original one should not be seen by external
 				revs[len(revs)-1] = r
 				continue
 			}
 			revs = append(revs, r)
 			last = r.main
 		}
 	}
 	return revs
 }

 // compact compacts a keyIndex by removing the versions with smaller or equal
 // revision than the given atRev except the largest one (If the largest one is
 // a tombstone, it will not be kept).
 // If a generation becomes empty during compaction, it will be removed.
 func (ki *keyIndex) compact(lg *zap.Logger, atRev int64, available map[revision]struct{}) {
 	if ki.isEmpty() {
 		if lg != nil {
 			lg.Panic(
 				"'compact' got an unexpected empty keyIndex",
 				zap.String("key", string(ki.key)),
 			)
 		} else {
 			plog.Panicf("store.keyindex: unexpected compact on empty keyIndex %s", string(ki.key))
 		}
 	}

 	genIdx, revIndex := ki.doCompact(atRev, available)

 	g := &ki.generations[genIdx]
 	if !g.isEmpty() {
 		// remove the previous contents.
 		if revIndex != -1 {
 			g.revs = g.revs[revIndex:]
 		}
 		// remove any tombstone
 		if len(g.revs) == 1 && genIdx != len(ki.generations)-1 {
 			delete(available, g.revs[0])
 			genIdx++
 		}
 	}

 	// remove the previous generations.
 	ki.generations = ki.generations[genIdx:]
 }

 // keep finds the revision to be kept if compact is called at given atRev.
 func (ki *keyIndex) keep(atRev int64, available map[revision]struct{}) {
 	if ki.isEmpty() {
 		return
 	}

 	genIdx, revIndex := ki.doCompact(atRev, available)
 	g := &ki.generations[genIdx]
 	if !g.isEmpty() {
 		// remove any tombstone
 		if revIndex == len(g.revs)-1 && genIdx != len(ki.generations)-1 {
 			delete(available, g.revs[revIndex])
 		}
 	}
 }

 func (ki *keyIndex) doCompact(atRev int64, available map[revision]struct{}) (genIdx int, revIndex int) {
 	// walk until reaching the first revision smaller or equal to "atRev",
 	// and add the revision to the available map
 	f := func(rev revision) bool {
 		if rev.main <= atRev {
 			available[rev] = struct{}{}
 			return false
 		}
 		return true
 	}

 	genIdx, g := 0, &ki.generations[0]
 	// find first generation includes atRev or created after atRev
 	for genIdx < len(ki.generations)-1 {
 		if tomb := g.revs[len(g.revs)-1].main; tomb > atRev {
 			break
 		}
 		genIdx++
 		g = &ki.generations[genIdx]
 	}

 	revIndex = g.walk(f)

 	return genIdx, revIndex
 }

 func (ki *keyIndex) isEmpty() bool {
 	return len(ki.generations) == 1 && ki.generations[0].isEmpty()
 }

 // findGeneration finds out the generation of the keyIndex that the
 // given rev belongs to. If the given rev is at the gap of two generations,
 // which means that the key does not exist at the given rev, it returns nil.
 func (ki *keyIndex) findGeneration(rev int64) *generation {
 	lastg := len(ki.generations) - 1
 	cg := lastg

 	for cg >= 0 {
 		if len(ki.generations[cg].revs) == 0 {
 			cg--
 			continue
 		}
 		g := ki.generations[cg]
 		if cg != lastg {
 			if tomb := g.revs[len(g.revs)-1].main; tomb <= rev {
 				return nil
 			}
 		}
 		if g.revs[0].main <= rev {
 			return &ki.generations[cg]
 		}
 		cg--
 	}
 	return nil
 }

 func (ki *keyIndex) Less(b btree.Item) bool {
 	return bytes.Compare(ki.key, b.(*keyIndex).key) == -1
 }

 func (ki *keyIndex) equal(b *keyIndex) bool {
 	if !bytes.Equal(ki.key, b.key) {
 		return false
 	}
 	if ki.modified != b.modified {
 		return false
 	}
 	if len(ki.generations) != len(b.generations) {
 		return false
 	}
 	for i := range ki.generations {
 		ag, bg := ki.generations[i], b.generations[i]
 		if !ag.equal(bg) {
 			return false
 		}
 	}
 	return true
 }

 func (ki *keyIndex) String() string {
 	var s string
 	for _, g := range ki.generations {
 		s += g.String()
 	}
 	return s
 }

 // generation contains multiple revisions of a key.
 type generation struct {
 	ver     int64
 	created revision // when the generation is created (put in first revision).
 	revs    []revision
 }

 func (g *generation) isEmpty() bool { return g == nil || len(g.revs) == 0 }

 // walk walks through the revisions in the generation in descending order.
 // It passes the revision to the given function.
 // walk returns until: 1. it finishes walking all pairs 2. the function returns false.
 // walk returns the position at where it stopped. If it stopped after
 // finishing walking, -1 will be returned.
 func (g *generation) walk(f func(rev revision) bool) int {
 	l := len(g.revs)
 	for i := range g.revs {
 		ok := f(g.revs[l-i-1])
 		if !ok {
 			return l - i - 1
 		}
 	}
 	return -1
 }

 func (g *generation) String() string {
 	return fmt.Sprintf("g: created[%d] ver[%d], revs %#v\n", g.created, g.ver, g.revs)
 }

 func (g generation) equal(b generation) bool {
 	if g.ver != b.ver {
 		return false
 	}
 	if len(g.revs) != len(b.revs) {
 		return false
 	}

 	for i := range g.revs {
 		ar, br := g.revs[i], b.revs[i]
 		if ar != br {
 			return false
 		}
 	}
 	return true
 }
	// Copyright 2015 The etcd Authors
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	package mvcc

	import (
	"bytes"
	"errors"
	"fmt"

	"github.com/google/btree"
	"go.uber.org/zap"
	)

	var (
	ErrRevisionNotFound = errors.New("mvcc: revision not found")
	)

	// keyIndex stores the revisions of a key in the backend.
	// Each keyIndex has at least one key generation.
	// Each generation might have several key versions.
	// Tombstone on a key appends an tombstone version at the end
	// of the current generation and creates a new empty generation.
	// Each version of a key has an index pointing to the backend.
	//
	// For example: put(1.0);put(2.0);tombstone(3.0);put(4.0);tombstone(5.0) on key "foo"
	// generate a keyIndex:
	// key: "foo"
	// rev: 5
	// generations:
	// {empty}
	// {4.0, 5.0(t)}
	// {1.0, 2.0, 3.0(t)}
	//
	// Compact a keyIndex removes the versions with smaller or equal to
	// rev except the largest one. If the generation becomes empty
	// during compaction, it will be removed. if all the generations get
	// removed, the keyIndex should be removed.
	//
	// For example:
	// compact(2) on the previous example
	// generations:
	// {empty}
	// {4.0, 5.0(t)}
	// {2.0, 3.0(t)}
	//
	// compact(4)
	// generations:
	// {empty}
	// {4.0, 5.0(t)}
	//
	// compact(5):
	// generations:
	// {empty} -> key SHOULD be removed.
	//
	// compact(6):
	// generations:
	// {empty} -> key SHOULD be removed.
	type keyIndex struct {
	key []byte
	modified revision // the main rev of the last modification
	generations []generation
	}

	// put puts a revision to the keyIndex.
	func (ki keyIndex) put(lg zap.Logger, main int64, sub int64) {
	rev := revision{main: main, sub: sub}

	if !rev.GreaterThan(ki.modified) {
	if lg != nil {
	lg.Panic(
	"'put' with an unexpected smaller revision",
	zap.Int64("given-revision-main", rev.main),
	zap.Int64("given-revision-sub", rev.sub),
	zap.Int64("modified-revision-main", ki.modified.main),
	zap.Int64("modified-revision-sub", ki.modified.sub),
	)
	} else {
	plog.Panicf("store.keyindex: put with unexpected smaller revision [%v / %v]", rev, ki.modified)
	}
	}
	if len(ki.generations) == 0 {
	ki.generations = append(ki.generations, generation{})
	}
	g := &ki.generations[len(ki.generations)-1]
	if len(g.revs) == 0 { // create a new key
	keysGauge.Inc()
	g.created = rev
	}
	g.revs = append(g.revs, rev)
	g.ver++
	ki.modified = rev
	}

	func (ki keyIndex) restore(lg zap.Logger, created, modified revision, ver int64) {
	if len(ki.generations) != 0 {
	if lg != nil {
	lg.Panic(
	"'restore' got an unexpected non-empty generations",
	zap.Int("generations-size", len(ki.generations)),
	)
	} else {
	plog.Panicf("store.keyindex: cannot restore non-empty keyIndex")
	}
	}

	ki.modified = modified
	g := generation{created: created, ver: ver, revs: []revision{modified}}
	ki.generations = append(ki.generations, g)
	keysGauge.Inc()
	}

	// tombstone puts a revision, pointing to a tombstone, to the keyIndex.
	// It also creates a new empty generation in the keyIndex.
	// It returns ErrRevisionNotFound when tombstone on an empty generation.
	func (ki keyIndex) tombstone(lg zap.Logger, main int64, sub int64) error {
	if ki.isEmpty() {
	if lg != nil {
	lg.Panic(
	"'tombstone' got an unexpected empty keyIndex",
	zap.String("key", string(ki.key)),
	)
	} else {
	plog.Panicf("store.keyindex: unexpected tombstone on empty keyIndex %s", string(ki.key))
	}
	}
	if ki.generations[len(ki.generations)-1].isEmpty() {
	return ErrRevisionNotFound
	}
	ki.put(lg, main, sub)
	ki.generations = append(ki.generations, generation{})
	keysGauge.Dec()
	return nil
	}

	// get gets the modified, created revision and version of the key that satisfies the given atRev.
	// Rev must be higher than or equal to the given atRev.
	func (ki keyIndex) get(lg zap.Logger, atRev int64) (modified, created revision, ver int64, err error) {
	if ki.isEmpty() {
	if lg != nil {
	lg.Panic(
	"'get' got an unexpected empty keyIndex",
	zap.String("key", string(ki.key)),
	)
	} else {
	plog.Panicf("store.keyindex: unexpected get on empty keyIndex %s", string(ki.key))
	}
	}
	g := ki.findGeneration(atRev)
	if g.isEmpty() {
	return revision{}, revision{}, 0, ErrRevisionNotFound
	}

	n := g.walk(func(rev revision) bool { return rev.main > atRev })
	if n != -1 {
	return g.revs[n], g.created, g.ver - int64(len(g.revs)-n-1), nil
	}

	return revision{}, revision{}, 0, ErrRevisionNotFound
	}

	// since returns revisions since the given rev. Only the revision with the
	// largest sub revision will be returned if multiple revisions have the same
	// main revision.
	func (ki keyIndex) since(lg zap.Logger, rev int64) []revision {
	if ki.isEmpty() {
	if lg != nil {
	lg.Panic(
	"'since' got an unexpected empty keyIndex",
	zap.String("key", string(ki.key)),
	)
	} else {
	plog.Panicf("store.keyindex: unexpected get on empty keyIndex %s", string(ki.key))
	}
	}
	since := revision{rev, 0}
	var gi int
	// find the generations to start checking
	for gi = len(ki.generations) - 1; gi > 0; gi-- {
	g := ki.generations[gi]
	if g.isEmpty() {
	continue
	}
	if since.GreaterThan(g.created) {
	break
	}
	}

	var revs []revision
	var last int64
	for ; gi < len(ki.generations); gi++ {
	for _, r := range ki.generations[gi].revs {
	if since.GreaterThan(r) {
	continue
	}
	if r.main == last {
	// replace the revision with a new one that has higher sub value,
	// because the original one should not be seen by external
	revs[len(revs)-1] = r
	continue
	}
	revs = append(revs, r)
	last = r.main
	}
	}
	return revs
	}

	// compact compacts a keyIndex by removing the versions with smaller or equal
	// revision than the given atRev except the largest one (If the largest one is
	// a tombstone, it will not be kept).
	// If a generation becomes empty during compaction, it will be removed.
	func (ki keyIndex) compact(lg zap.Logger, atRev int64, available map[revision]struct{}) {
	if ki.isEmpty() {
	if lg != nil {
	lg.Panic(
	"'compact' got an unexpected empty keyIndex",
	zap.String("key", string(ki.key)),
	)
	} else {
	plog.Panicf("store.keyindex: unexpected compact on empty keyIndex %s", string(ki.key))
	}
	}

	genIdx, revIndex := ki.doCompact(atRev, available)

	g := &ki.generations[genIdx]
	if !g.isEmpty() {
	// remove the previous contents.
	if revIndex != -1 {
	g.revs = g.revs[revIndex:]
	}
	// remove any tombstone
	if len(g.revs) == 1 && genIdx != len(ki.generations)-1 {
	delete(available, g.revs[0])
	genIdx++
	}
	}

	// remove the previous generations.
	ki.generations = ki.generations[genIdx:]
	}

	// keep finds the revision to be kept if compact is called at given atRev.
	func (ki *keyIndex) keep(atRev int64, available map[revision]struct{}) {
	if ki.isEmpty() {
	return
	}

	genIdx, revIndex := ki.doCompact(atRev, available)
	g := &ki.generations[genIdx]
	if !g.isEmpty() {
	// remove any tombstone
	if revIndex == len(g.revs)-1 && genIdx != len(ki.generations)-1 {
	delete(available, g.revs[revIndex])
	}
	}
	}

	func (ki *keyIndex) doCompact(atRev int64, available map[revision]struct{}) (genIdx int, revIndex int) {
	// walk until reaching the first revision smaller or equal to "atRev",
	// and add the revision to the available map
	f := func(rev revision) bool {
	if rev.main <= atRev {
	available[rev] = struct{}{}
	return false
	}
	return true
	}

	genIdx, g := 0, &ki.generations[0]
	// find first generation includes atRev or created after atRev
	for genIdx < len(ki.generations)-1 {
	if tomb := g.revs[len(g.revs)-1].main; tomb > atRev {
	break
	}
	genIdx++
	g = &ki.generations[genIdx]
	}

	revIndex = g.walk(f)

	return genIdx, revIndex
	}

	func (ki *keyIndex) isEmpty() bool {
	return len(ki.generations) == 1 && ki.generations[0].isEmpty()
	}

	// findGeneration finds out the generation of the keyIndex that the
	// given rev belongs to. If the given rev is at the gap of two generations,
	// which means that the key does not exist at the given rev, it returns nil.
	func (ki keyIndex) findGeneration(rev int64) generation {
	lastg := len(ki.generations) - 1
	cg := lastg

	for cg >= 0 {
	if len(ki.generations[cg].revs) == 0 {
	cg--
	continue
	}
	g := ki.generations[cg]
	if cg != lastg {
	if tomb := g.revs[len(g.revs)-1].main; tomb <= rev {
	return nil
	}
	}
	if g.revs[0].main <= rev {
	return &ki.generations[cg]
	}
	cg--
	}
	return nil
	}

	func (ki *keyIndex) Less(b btree.Item) bool {
	return bytes.Compare(ki.key, b.(*keyIndex).key) == -1
	}

	func (ki keyIndex) equal(b keyIndex) bool {
	if !bytes.Equal(ki.key, b.key) {
	return false
	}
	if ki.modified != b.modified {
	return false
	}
	if len(ki.generations) != len(b.generations) {
	return false
	}
	for i := range ki.generations {
	ag, bg := ki.generations[i], b.generations[i]
	if !ag.equal(bg) {
	return false
	}
	}
	return true
	}

	func (ki *keyIndex) String() string {
	var s string
	for _, g := range ki.generations {
	s += g.String()
	}
	return s
	}

	// generation contains multiple revisions of a key.
	type generation struct {
	ver int64
	created revision // when the generation is created (put in first revision).
	revs []revision
	}

	func (g *generation) isEmpty() bool { return g == nil \|\| len(g.revs) == 0 }

	// walk walks through the revisions in the generation in descending order.
	// It passes the revision to the given function.
	// walk returns until: 1. it finishes walking all pairs 2. the function returns false.
	// walk returns the position at where it stopped. If it stopped after
	// finishing walking, -1 will be returned.
	func (g *generation) walk(f func(rev revision) bool) int {
	l := len(g.revs)
	for i := range g.revs {
	ok := f(g.revs[l-i-1])
	if !ok {
	return l - i - 1
	}
	}
	return -1
	}

	func (g *generation) String() string {
	return fmt.Sprintf("g: created[%d] ver[%d], revs %#v\n", g.created, g.ver, g.revs)
	}

	func (g generation) equal(b generation) bool {
	if g.ver != b.ver {
	return false
	}
	if len(g.revs) != len(b.revs) {
	return false
	}

	for i := range g.revs {
	ar, br := g.revs[i], b.revs[i]
	if ar != br {
	return false
	}
	}
	return true
	}