vendor/go.etcd.io/bbolt/tx_check.go - third_party/github.com/moby/moby - Git at Google

 package bbolt

 import (
 	"encoding/hex"
 	"fmt"
 )

 // Check performs several consistency checks on the database for this transaction.
 // An error is returned if any inconsistency is found.
 //
 // It can be safely run concurrently on a writable transaction. However, this
 // incurs a high cost for large databases and databases with a lot of subbuckets
 // because of caching. This overhead can be removed if running on a read-only
 // transaction, however, it is not safe to execute other writer transactions at
 // the same time.
 func (tx *Tx) Check() <-chan error {
 	return tx.CheckWithOptions()
 }

 // CheckWithOptions allows users to provide a customized `KVStringer` implementation,
 // so that bolt can generate human-readable diagnostic messages.
 func (tx *Tx) CheckWithOptions(options ...CheckOption) <-chan error {
 	chkConfig := checkConfig{
 		kvStringer: HexKVStringer(),
 	}
 	for _, op := range options {
 		op(&chkConfig)
 	}

 	ch := make(chan error)
 	go tx.check(chkConfig.kvStringer, ch)
 	return ch
 }

 func (tx *Tx) check(kvStringer KVStringer, ch chan error) {
 	// Force loading free list if opened in ReadOnly mode.
 	tx.db.loadFreelist()

 	// Check if any pages are double freed.
 	freed := make(map[pgid]bool)
 	all := make([]pgid, tx.db.freelist.count())
 	tx.db.freelist.copyall(all)
 	for _, id := range all {
 		if freed[id] {
 			ch <- fmt.Errorf("page %d: already freed", id)
 		}
 		freed[id] = true
 	}

 	// Track every reachable page.
 	reachable := make(map[pgid]*page)
 	reachable[0] = tx.page(0) // meta0
 	reachable[1] = tx.page(1) // meta1
 	if tx.meta.freelist != pgidNoFreelist {
 		for i := uint32(0); i <= tx.page(tx.meta.freelist).overflow; i++ {
 			reachable[tx.meta.freelist+pgid(i)] = tx.page(tx.meta.freelist)
 		}
 	}

 	// Recursively check buckets.
 	tx.checkBucket(&tx.root, reachable, freed, kvStringer, ch)

 	// Ensure all pages below high water mark are either reachable or freed.
 	for i := pgid(0); i < tx.meta.pgid; i++ {
 		_, isReachable := reachable[i]
 		if !isReachable && !freed[i] {
 			ch <- fmt.Errorf("page %d: unreachable unfreed", int(i))
 		}
 	}

 	// Close the channel to signal completion.
 	close(ch)
 }

 func (tx *Tx) checkBucket(b *Bucket, reachable map[pgid]*page, freed map[pgid]bool,
 	kvStringer KVStringer, ch chan error) {
 	// Ignore inline buckets.
 	if b.root == 0 {
 		return
 	}

 	// Check every page used by this bucket.
 	b.tx.forEachPage(b.root, func(p *page, _ int, stack []pgid) {
 		if p.id > tx.meta.pgid {
 			ch <- fmt.Errorf("page %d: out of bounds: %d (stack: %v)", int(p.id), int(b.tx.meta.pgid), stack)
 		}

 		// Ensure each page is only referenced once.
 		for i := pgid(0); i <= pgid(p.overflow); i++ {
 			var id = p.id + i
 			if _, ok := reachable[id]; ok {
 				ch <- fmt.Errorf("page %d: multiple references (stack: %v)", int(id), stack)
 			}
 			reachable[id] = p
 		}

 		// We should only encounter un-freed leaf and branch pages.
 		if freed[p.id] {
 			ch <- fmt.Errorf("page %d: reachable freed", int(p.id))
 		} else if (p.flags&branchPageFlag) == 0 && (p.flags&leafPageFlag) == 0 {
 			ch <- fmt.Errorf("page %d: invalid type: %s (stack: %v)", int(p.id), p.typ(), stack)
 		}
 	})

 	tx.recursivelyCheckPages(b.root, kvStringer.KeyToString, ch)

 	// Check each bucket within this bucket.
 	_ = b.ForEachBucket(func(k []byte) error {
 		if child := b.Bucket(k); child != nil {
 			tx.checkBucket(child, reachable, freed, kvStringer, ch)
 		}
 		return nil
 	})
 }

 // recursivelyCheckPages confirms database consistency with respect to b-tree
 // key order constraints:
 //   - keys on pages must be sorted
 //   - keys on children pages are between 2 consecutive keys on the parent's branch page).
 func (tx *Tx) recursivelyCheckPages(pgId pgid, keyToString func([]byte) string, ch chan error) {
 	tx.recursivelyCheckPagesInternal(pgId, nil, nil, nil, keyToString, ch)
 }

 // recursivelyCheckPagesInternal verifies that all keys in the subtree rooted at `pgid` are:
 //   - >=`minKeyClosed` (can be nil)
 //   - <`maxKeyOpen` (can be nil)
 //   - Are in right ordering relationship to their parents.
 //     `pagesStack` is expected to contain IDs of pages from the tree root to `pgid` for the clean debugging message.
 func (tx *Tx) recursivelyCheckPagesInternal(
 	pgId pgid, minKeyClosed, maxKeyOpen []byte, pagesStack []pgid,
 	keyToString func([]byte) string, ch chan error) (maxKeyInSubtree []byte) {

 	p := tx.page(pgId)
 	pagesStack = append(pagesStack, pgId)
 	switch {
 	case p.flags&branchPageFlag != 0:
 		// For branch page we navigate ranges of all subpages.
 		runningMin := minKeyClosed
 		for i := range p.branchPageElements() {
 			elem := p.branchPageElement(uint16(i))
 			verifyKeyOrder(elem.pgid, "branch", i, elem.key(), runningMin, maxKeyOpen, ch, keyToString, pagesStack)

 			maxKey := maxKeyOpen
 			if i < len(p.branchPageElements())-1 {
 				maxKey = p.branchPageElement(uint16(i + 1)).key()
 			}
 			maxKeyInSubtree = tx.recursivelyCheckPagesInternal(elem.pgid, elem.key(), maxKey, pagesStack, keyToString, ch)
 			runningMin = maxKeyInSubtree
 		}
 		return maxKeyInSubtree
 	case p.flags&leafPageFlag != 0:
 		runningMin := minKeyClosed
 		for i := range p.leafPageElements() {
 			elem := p.leafPageElement(uint16(i))
 			verifyKeyOrder(pgId, "leaf", i, elem.key(), runningMin, maxKeyOpen, ch, keyToString, pagesStack)
 			runningMin = elem.key()
 		}
 		if p.count > 0 {
 			return p.leafPageElement(p.count - 1).key()
 		}
 	default:
 		ch <- fmt.Errorf("unexpected page type for pgId:%d", pgId)
 	}
 	return maxKeyInSubtree
 }

 /***
  * verifyKeyOrder checks whether an entry with given #index on pgId (pageType: "branch|leaf") that has given "key",
  * is within range determined by (previousKey..maxKeyOpen) and reports found violations to the channel (ch).
  */
 func verifyKeyOrder(pgId pgid, pageType string, index int, key []byte, previousKey []byte, maxKeyOpen []byte, ch chan error, keyToString func([]byte) string, pagesStack []pgid) {
 	if index == 0 && previousKey != nil && compareKeys(previousKey, key) > 0 {
 		ch <- fmt.Errorf("the first key[%d]=(hex)%s on %s page(%d) needs to be >= the key in the ancestor (%s). Stack: %v",
 			index, keyToString(key), pageType, pgId, keyToString(previousKey), pagesStack)
 	}
 	if index > 0 {
 		cmpRet := compareKeys(previousKey, key)
 		if cmpRet > 0 {
 			ch <- fmt.Errorf("key[%d]=(hex)%s on %s page(%d) needs to be > (found <) than previous element (hex)%s. Stack: %v",
 				index, keyToString(key), pageType, pgId, keyToString(previousKey), pagesStack)
 		}
 		if cmpRet == 0 {
 			ch <- fmt.Errorf("key[%d]=(hex)%s on %s page(%d) needs to be > (found =) than previous element (hex)%s. Stack: %v",
 				index, keyToString(key), pageType, pgId, keyToString(previousKey), pagesStack)
 		}
 	}
 	if maxKeyOpen != nil && compareKeys(key, maxKeyOpen) >= 0 {
 		ch <- fmt.Errorf("key[%d]=(hex)%s on %s page(%d) needs to be < than key of the next element in ancestor (hex)%s. Pages stack: %v",
 			index, keyToString(key), pageType, pgId, keyToString(previousKey), pagesStack)
 	}
 }

 // ===========================================================================================

 type checkConfig struct {
 	kvStringer KVStringer
 }

 type CheckOption func(options *checkConfig)

 func WithKVStringer(kvStringer KVStringer) CheckOption {
 	return func(c *checkConfig) {
 		c.kvStringer = kvStringer
 	}
 }

 // KVStringer allows to prepare human-readable diagnostic messages.
 type KVStringer interface {
 	KeyToString([]byte) string
 	ValueToString([]byte) string
 }

 // HexKVStringer serializes both key & value to hex representation.
 func HexKVStringer() KVStringer {
 	return hexKvStringer{}
 }

 type hexKvStringer struct{}

 func (_ hexKvStringer) KeyToString(key []byte) string {
 	return hex.EncodeToString(key)
 }

 func (_ hexKvStringer) ValueToString(value []byte) string {
 	return hex.EncodeToString(value)
 }
	package bbolt

	import (
	"encoding/hex"
	"fmt"
	)

	// Check performs several consistency checks on the database for this transaction.
	// An error is returned if any inconsistency is found.
	//
	// It can be safely run concurrently on a writable transaction. However, this
	// incurs a high cost for large databases and databases with a lot of subbuckets
	// because of caching. This overhead can be removed if running on a read-only
	// transaction, however, it is not safe to execute other writer transactions at
	// the same time.
	func (tx *Tx) Check() <-chan error {
	return tx.CheckWithOptions()
	}

	// CheckWithOptions allows users to provide a customized `KVStringer` implementation,
	// so that bolt can generate human-readable diagnostic messages.
	func (tx *Tx) CheckWithOptions(options ...CheckOption) <-chan error {
	chkConfig := checkConfig{
	kvStringer: HexKVStringer(),
	}
	for _, op := range options {
	op(&chkConfig)
	}

	ch := make(chan error)
	go tx.check(chkConfig.kvStringer, ch)
	return ch
	}

	func (tx *Tx) check(kvStringer KVStringer, ch chan error) {
	// Force loading free list if opened in ReadOnly mode.
	tx.db.loadFreelist()

	// Check if any pages are double freed.
	freed := make(map[pgid]bool)
	all := make([]pgid, tx.db.freelist.count())
	tx.db.freelist.copyall(all)
	for _, id := range all {
	if freed[id] {
	ch <- fmt.Errorf("page %d: already freed", id)
	}
	freed[id] = true
	}

	// Track every reachable page.
	reachable := make(map[pgid]*page)
	reachable[0] = tx.page(0) // meta0
	reachable[1] = tx.page(1) // meta1
	if tx.meta.freelist != pgidNoFreelist {
	for i := uint32(0); i <= tx.page(tx.meta.freelist).overflow; i++ {
	reachable[tx.meta.freelist+pgid(i)] = tx.page(tx.meta.freelist)
	}
	}

	// Recursively check buckets.
	tx.checkBucket(&tx.root, reachable, freed, kvStringer, ch)

	// Ensure all pages below high water mark are either reachable or freed.
	for i := pgid(0); i < tx.meta.pgid; i++ {
	_, isReachable := reachable[i]
	if !isReachable && !freed[i] {
	ch <- fmt.Errorf("page %d: unreachable unfreed", int(i))
	}
	}

	// Close the channel to signal completion.
	close(ch)
	}

	func (tx Tx) checkBucket(b Bucket, reachable map[pgid]*page, freed map[pgid]bool,
	kvStringer KVStringer, ch chan error) {
	// Ignore inline buckets.
	if b.root == 0 {
	return
	}

	// Check every page used by this bucket.
	b.tx.forEachPage(b.root, func(p *page, _ int, stack []pgid) {
	if p.id > tx.meta.pgid {
	ch <- fmt.Errorf("page %d: out of bounds: %d (stack: %v)", int(p.id), int(b.tx.meta.pgid), stack)
	}

	// Ensure each page is only referenced once.
	for i := pgid(0); i <= pgid(p.overflow); i++ {
	var id = p.id + i
	if _, ok := reachable[id]; ok {
	ch <- fmt.Errorf("page %d: multiple references (stack: %v)", int(id), stack)
	}
	reachable[id] = p
	}

	// We should only encounter un-freed leaf and branch pages.
	if freed[p.id] {
	ch <- fmt.Errorf("page %d: reachable freed", int(p.id))
	} else if (p.flags&branchPageFlag) == 0 && (p.flags&leafPageFlag) == 0 {
	ch <- fmt.Errorf("page %d: invalid type: %s (stack: %v)", int(p.id), p.typ(), stack)
	}
	})

	tx.recursivelyCheckPages(b.root, kvStringer.KeyToString, ch)

	// Check each bucket within this bucket.
	_ = b.ForEachBucket(func(k []byte) error {
	if child := b.Bucket(k); child != nil {
	tx.checkBucket(child, reachable, freed, kvStringer, ch)
	}
	return nil
	})
	}

	// recursivelyCheckPages confirms database consistency with respect to b-tree
	// key order constraints:
	// - keys on pages must be sorted
	// - keys on children pages are between 2 consecutive keys on the parent's branch page).
	func (tx *Tx) recursivelyCheckPages(pgId pgid, keyToString func([]byte) string, ch chan error) {
	tx.recursivelyCheckPagesInternal(pgId, nil, nil, nil, keyToString, ch)
	}

	// recursivelyCheckPagesInternal verifies that all keys in the subtree rooted at `pgid` are:
	// - >=`minKeyClosed` (can be nil)
	// - <`maxKeyOpen` (can be nil)
	// - Are in right ordering relationship to their parents.
	// `pagesStack` is expected to contain IDs of pages from the tree root to `pgid` for the clean debugging message.
	func (tx *Tx) recursivelyCheckPagesInternal(
	pgId pgid, minKeyClosed, maxKeyOpen []byte, pagesStack []pgid,
	keyToString func([]byte) string, ch chan error) (maxKeyInSubtree []byte) {

	p := tx.page(pgId)
	pagesStack = append(pagesStack, pgId)
	switch {
	case p.flags&branchPageFlag != 0:
	// For branch page we navigate ranges of all subpages.
	runningMin := minKeyClosed
	for i := range p.branchPageElements() {
	elem := p.branchPageElement(uint16(i))
	verifyKeyOrder(elem.pgid, "branch", i, elem.key(), runningMin, maxKeyOpen, ch, keyToString, pagesStack)

	maxKey := maxKeyOpen
	if i < len(p.branchPageElements())-1 {
	maxKey = p.branchPageElement(uint16(i + 1)).key()
	}
	maxKeyInSubtree = tx.recursivelyCheckPagesInternal(elem.pgid, elem.key(), maxKey, pagesStack, keyToString, ch)
	runningMin = maxKeyInSubtree
	}
	return maxKeyInSubtree
	case p.flags&leafPageFlag != 0:
	runningMin := minKeyClosed
	for i := range p.leafPageElements() {
	elem := p.leafPageElement(uint16(i))
	verifyKeyOrder(pgId, "leaf", i, elem.key(), runningMin, maxKeyOpen, ch, keyToString, pagesStack)
	runningMin = elem.key()
	}
	if p.count > 0 {
	return p.leafPageElement(p.count - 1).key()
	}
	default:
	ch <- fmt.Errorf("unexpected page type for pgId:%d", pgId)
	}
	return maxKeyInSubtree
	}

	/***
	* verifyKeyOrder checks whether an entry with given #index on pgId (pageType: "branch\|leaf") that has given "key",
	* is within range determined by (previousKey..maxKeyOpen) and reports found violations to the channel (ch).
	*/
	func verifyKeyOrder(pgId pgid, pageType string, index int, key []byte, previousKey []byte, maxKeyOpen []byte, ch chan error, keyToString func([]byte) string, pagesStack []pgid) {
	if index == 0 && previousKey != nil && compareKeys(previousKey, key) > 0 {
	ch <- fmt.Errorf("the first key[%d]=(hex)%s on %s page(%d) needs to be >= the key in the ancestor (%s). Stack: %v",
	index, keyToString(key), pageType, pgId, keyToString(previousKey), pagesStack)
	}
	if index > 0 {
	cmpRet := compareKeys(previousKey, key)
	if cmpRet > 0 {
	ch <- fmt.Errorf("key[%d]=(hex)%s on %s page(%d) needs to be > (found <) than previous element (hex)%s. Stack: %v",
	index, keyToString(key), pageType, pgId, keyToString(previousKey), pagesStack)
	}
	if cmpRet == 0 {
	ch <- fmt.Errorf("key[%d]=(hex)%s on %s page(%d) needs to be > (found =) than previous element (hex)%s. Stack: %v",
	index, keyToString(key), pageType, pgId, keyToString(previousKey), pagesStack)
	}
	}
	if maxKeyOpen != nil && compareKeys(key, maxKeyOpen) >= 0 {
	ch <- fmt.Errorf("key[%d]=(hex)%s on %s page(%d) needs to be < than key of the next element in ancestor (hex)%s. Pages stack: %v",
	index, keyToString(key), pageType, pgId, keyToString(previousKey), pagesStack)
	}
	}

	// ===========================================================================================

	type checkConfig struct {
	kvStringer KVStringer
	}

	type CheckOption func(options *checkConfig)

	func WithKVStringer(kvStringer KVStringer) CheckOption {
	return func(c *checkConfig) {
	c.kvStringer = kvStringer
	}
	}

	// KVStringer allows to prepare human-readable diagnostic messages.
	type KVStringer interface {
	KeyToString([]byte) string
	ValueToString([]byte) string
	}

	// HexKVStringer serializes both key & value to hex representation.
	func HexKVStringer() KVStringer {
	return hexKvStringer{}
	}

	type hexKvStringer struct{}

	func (_ hexKvStringer) KeyToString(key []byte) string {
	return hex.EncodeToString(key)
	}

	func (_ hexKvStringer) ValueToString(value []byte) string {
	return hex.EncodeToString(value)
	}