vendor/github.com/docker/distribution/digestset/set.go - cloudstack-kubernetes-provider - Git at Google

 package digestset

 import (
 	"errors"
 	"sort"
 	"strings"
 	"sync"

 	digest "github.com/opencontainers/go-digest"
 )

 var (
 	// ErrDigestNotFound is used when a matching digest
 	// could not be found in a set.
 	ErrDigestNotFound = errors.New("digest not found")

 	// ErrDigestAmbiguous is used when multiple digests
 	// are found in a set. None of the matching digests
 	// should be considered valid matches.
 	ErrDigestAmbiguous = errors.New("ambiguous digest string")
 )

 // Set is used to hold a unique set of digests which
 // may be easily referenced by easily  referenced by a string
 // representation of the digest as well as short representation.
 // The uniqueness of the short representation is based on other
 // digests in the set. If digests are omitted from this set,
 // collisions in a larger set may not be detected, therefore it
 // is important to always do short representation lookups on
 // the complete set of digests. To mitigate collisions, an
 // appropriately long short code should be used.
 type Set struct {
 	mutex   sync.RWMutex
 	entries digestEntries
 }

 // NewSet creates an empty set of digests
 // which may have digests added.
 func NewSet() *Set {
 	return &Set{
 		entries: digestEntries{},
 	}
 }

 // checkShortMatch checks whether two digests match as either whole
 // values or short values. This function does not test equality,
 // rather whether the second value could match against the first
 // value.
 func checkShortMatch(alg digest.Algorithm, hex, shortAlg, shortHex string) bool {
 	if len(hex) == len(shortHex) {
 		if hex != shortHex {
 			return false
 		}
 		if len(shortAlg) > 0 && string(alg) != shortAlg {
 			return false
 		}
 	} else if !strings.HasPrefix(hex, shortHex) {
 		return false
 	} else if len(shortAlg) > 0 && string(alg) != shortAlg {
 		return false
 	}
 	return true
 }

 // Lookup looks for a digest matching the given string representation.
 // If no digests could be found ErrDigestNotFound will be returned
 // with an empty digest value. If multiple matches are found
 // ErrDigestAmbiguous will be returned with an empty digest value.
 func (dst *Set) Lookup(d string) (digest.Digest, error) {
 	dst.mutex.RLock()
 	defer dst.mutex.RUnlock()
 	if len(dst.entries) == 0 {
 		return "", ErrDigestNotFound
 	}
 	var (
 		searchFunc func(int) bool
 		alg        digest.Algorithm
 		hex        string
 	)
 	dgst, err := digest.Parse(d)
 	if err == digest.ErrDigestInvalidFormat {
 		hex = d
 		searchFunc = func(i int) bool {
 			return dst.entries[i].val >= d
 		}
 	} else {
 		hex = dgst.Hex()
 		alg = dgst.Algorithm()
 		searchFunc = func(i int) bool {
 			if dst.entries[i].val == hex {
 				return dst.entries[i].alg >= alg
 			}
 			return dst.entries[i].val >= hex
 		}
 	}
 	idx := sort.Search(len(dst.entries), searchFunc)
 	if idx == len(dst.entries) || !checkShortMatch(dst.entries[idx].alg, dst.entries[idx].val, string(alg), hex) {
 		return "", ErrDigestNotFound
 	}
 	if dst.entries[idx].alg == alg && dst.entries[idx].val == hex {
 		return dst.entries[idx].digest, nil
 	}
 	if idx+1 < len(dst.entries) && checkShortMatch(dst.entries[idx+1].alg, dst.entries[idx+1].val, string(alg), hex) {
 		return "", ErrDigestAmbiguous
 	}

 	return dst.entries[idx].digest, nil
 }

 // Add adds the given digest to the set. An error will be returned
 // if the given digest is invalid. If the digest already exists in the
 // set, this operation will be a no-op.
 func (dst *Set) Add(d digest.Digest) error {
 	if err := d.Validate(); err != nil {
 		return err
 	}
 	dst.mutex.Lock()
 	defer dst.mutex.Unlock()
 	entry := &digestEntry{alg: d.Algorithm(), val: d.Hex(), digest: d}
 	searchFunc := func(i int) bool {
 		if dst.entries[i].val == entry.val {
 			return dst.entries[i].alg >= entry.alg
 		}
 		return dst.entries[i].val >= entry.val
 	}
 	idx := sort.Search(len(dst.entries), searchFunc)
 	if idx == len(dst.entries) {
 		dst.entries = append(dst.entries, entry)
 		return nil
 	} else if dst.entries[idx].digest == d {
 		return nil
 	}

 	entries := append(dst.entries, nil)
 	copy(entries[idx+1:], entries[idx:len(entries)-1])
 	entries[idx] = entry
 	dst.entries = entries
 	return nil
 }

 // Remove removes the given digest from the set. An err will be
 // returned if the given digest is invalid. If the digest does
 // not exist in the set, this operation will be a no-op.
 func (dst *Set) Remove(d digest.Digest) error {
 	if err := d.Validate(); err != nil {
 		return err
 	}
 	dst.mutex.Lock()
 	defer dst.mutex.Unlock()
 	entry := &digestEntry{alg: d.Algorithm(), val: d.Hex(), digest: d}
 	searchFunc := func(i int) bool {
 		if dst.entries[i].val == entry.val {
 			return dst.entries[i].alg >= entry.alg
 		}
 		return dst.entries[i].val >= entry.val
 	}
 	idx := sort.Search(len(dst.entries), searchFunc)
 	// Not found if idx is after or value at idx is not digest
 	if idx == len(dst.entries) || dst.entries[idx].digest != d {
 		return nil
 	}

 	entries := dst.entries
 	copy(entries[idx:], entries[idx+1:])
 	entries = entries[:len(entries)-1]
 	dst.entries = entries

 	return nil
 }

 // All returns all the digests in the set
 func (dst *Set) All() []digest.Digest {
 	dst.mutex.RLock()
 	defer dst.mutex.RUnlock()
 	retValues := make([]digest.Digest, len(dst.entries))
 	for i := range dst.entries {
 		retValues[i] = dst.entries[i].digest
 	}

 	return retValues
 }

 // ShortCodeTable returns a map of Digest to unique short codes. The
 // length represents the minimum value, the maximum length may be the
 // entire value of digest if uniqueness cannot be achieved without the
 // full value. This function will attempt to make short codes as short
 // as possible to be unique.
 func ShortCodeTable(dst *Set, length int) map[digest.Digest]string {
 	dst.mutex.RLock()
 	defer dst.mutex.RUnlock()
 	m := make(map[digest.Digest]string, len(dst.entries))
 	l := length
 	resetIdx := 0
 	for i := 0; i < len(dst.entries); i++ {
 		var short string
 		extended := true
 		for extended {
 			extended = false
 			if len(dst.entries[i].val) <= l {
 				short = dst.entries[i].digest.String()
 			} else {
 				short = dst.entries[i].val[:l]
 				for j := i + 1; j < len(dst.entries); j++ {
 					if checkShortMatch(dst.entries[j].alg, dst.entries[j].val, "", short) {
 						if j > resetIdx {
 							resetIdx = j
 						}
 						extended = true
 					} else {
 						break
 					}
 				}
 				if extended {
 					l++
 				}
 			}
 		}
 		m[dst.entries[i].digest] = short
 		if i >= resetIdx {
 			l = length
 		}
 	}
 	return m
 }

 type digestEntry struct {
 	alg    digest.Algorithm
 	val    string
 	digest digest.Digest
 }

 type digestEntries []*digestEntry

 func (d digestEntries) Len() int {
 	return len(d)
 }

 func (d digestEntries) Less(i, j int) bool {
 	if d[i].val != d[j].val {
 		return d[i].val < d[j].val
 	}
 	return d[i].alg < d[j].alg
 }

 func (d digestEntries) Swap(i, j int) {
 	d[i], d[j] = d[j], d[i]
 }
	package digestset

	import (
	"errors"
	"sort"
	"strings"
	"sync"

	digest "github.com/opencontainers/go-digest"
	)

	var (
	// ErrDigestNotFound is used when a matching digest
	// could not be found in a set.
	ErrDigestNotFound = errors.New("digest not found")

	// ErrDigestAmbiguous is used when multiple digests
	// are found in a set. None of the matching digests
	// should be considered valid matches.
	ErrDigestAmbiguous = errors.New("ambiguous digest string")
	)

	// Set is used to hold a unique set of digests which
	// may be easily referenced by easily referenced by a string
	// representation of the digest as well as short representation.
	// The uniqueness of the short representation is based on other
	// digests in the set. If digests are omitted from this set,
	// collisions in a larger set may not be detected, therefore it
	// is important to always do short representation lookups on
	// the complete set of digests. To mitigate collisions, an
	// appropriately long short code should be used.
	type Set struct {
	mutex sync.RWMutex
	entries digestEntries
	}

	// NewSet creates an empty set of digests
	// which may have digests added.
	func NewSet() *Set {
	return &Set{
	entries: digestEntries{},
	}
	}

	// checkShortMatch checks whether two digests match as either whole
	// values or short values. This function does not test equality,
	// rather whether the second value could match against the first
	// value.
	func checkShortMatch(alg digest.Algorithm, hex, shortAlg, shortHex string) bool {
	if len(hex) == len(shortHex) {
	if hex != shortHex {
	return false
	}
	if len(shortAlg) > 0 && string(alg) != shortAlg {
	return false
	}
	} else if !strings.HasPrefix(hex, shortHex) {
	return false
	} else if len(shortAlg) > 0 && string(alg) != shortAlg {
	return false
	}
	return true
	}

	// Lookup looks for a digest matching the given string representation.
	// If no digests could be found ErrDigestNotFound will be returned
	// with an empty digest value. If multiple matches are found
	// ErrDigestAmbiguous will be returned with an empty digest value.
	func (dst *Set) Lookup(d string) (digest.Digest, error) {
	dst.mutex.RLock()
	defer dst.mutex.RUnlock()
	if len(dst.entries) == 0 {
	return "", ErrDigestNotFound
	}
	var (
	searchFunc func(int) bool
	alg digest.Algorithm
	hex string
	)
	dgst, err := digest.Parse(d)
	if err == digest.ErrDigestInvalidFormat {
	hex = d
	searchFunc = func(i int) bool {
	return dst.entries[i].val >= d
	}
	} else {
	hex = dgst.Hex()
	alg = dgst.Algorithm()
	searchFunc = func(i int) bool {
	if dst.entries[i].val == hex {
	return dst.entries[i].alg >= alg
	}
	return dst.entries[i].val >= hex
	}
	}
	idx := sort.Search(len(dst.entries), searchFunc)
	if idx == len(dst.entries) \|\| !checkShortMatch(dst.entries[idx].alg, dst.entries[idx].val, string(alg), hex) {
	return "", ErrDigestNotFound
	}
	if dst.entries[idx].alg == alg && dst.entries[idx].val == hex {
	return dst.entries[idx].digest, nil
	}
	if idx+1 < len(dst.entries) && checkShortMatch(dst.entries[idx+1].alg, dst.entries[idx+1].val, string(alg), hex) {
	return "", ErrDigestAmbiguous
	}

	return dst.entries[idx].digest, nil
	}

	// Add adds the given digest to the set. An error will be returned
	// if the given digest is invalid. If the digest already exists in the
	// set, this operation will be a no-op.
	func (dst *Set) Add(d digest.Digest) error {
	if err := d.Validate(); err != nil {
	return err
	}
	dst.mutex.Lock()
	defer dst.mutex.Unlock()
	entry := &digestEntry{alg: d.Algorithm(), val: d.Hex(), digest: d}
	searchFunc := func(i int) bool {
	if dst.entries[i].val == entry.val {
	return dst.entries[i].alg >= entry.alg
	}
	return dst.entries[i].val >= entry.val
	}
	idx := sort.Search(len(dst.entries), searchFunc)
	if idx == len(dst.entries) {
	dst.entries = append(dst.entries, entry)
	return nil
	} else if dst.entries[idx].digest == d {
	return nil
	}

	entries := append(dst.entries, nil)
	copy(entries[idx+1:], entries[idx:len(entries)-1])
	entries[idx] = entry
	dst.entries = entries
	return nil
	}

	// Remove removes the given digest from the set. An err will be
	// returned if the given digest is invalid. If the digest does
	// not exist in the set, this operation will be a no-op.
	func (dst *Set) Remove(d digest.Digest) error {
	if err := d.Validate(); err != nil {
	return err
	}
	dst.mutex.Lock()
	defer dst.mutex.Unlock()
	entry := &digestEntry{alg: d.Algorithm(), val: d.Hex(), digest: d}
	searchFunc := func(i int) bool {
	if dst.entries[i].val == entry.val {
	return dst.entries[i].alg >= entry.alg
	}
	return dst.entries[i].val >= entry.val
	}
	idx := sort.Search(len(dst.entries), searchFunc)
	// Not found if idx is after or value at idx is not digest
	if idx == len(dst.entries) \|\| dst.entries[idx].digest != d {
	return nil
	}

	entries := dst.entries
	copy(entries[idx:], entries[idx+1:])
	entries = entries[:len(entries)-1]
	dst.entries = entries

	return nil
	}

	// All returns all the digests in the set
	func (dst *Set) All() []digest.Digest {
	dst.mutex.RLock()
	defer dst.mutex.RUnlock()
	retValues := make([]digest.Digest, len(dst.entries))
	for i := range dst.entries {
	retValues[i] = dst.entries[i].digest
	}

	return retValues
	}

	// ShortCodeTable returns a map of Digest to unique short codes. The
	// length represents the minimum value, the maximum length may be the
	// entire value of digest if uniqueness cannot be achieved without the
	// full value. This function will attempt to make short codes as short
	// as possible to be unique.
	func ShortCodeTable(dst *Set, length int) map[digest.Digest]string {
	dst.mutex.RLock()
	defer dst.mutex.RUnlock()
	m := make(map[digest.Digest]string, len(dst.entries))
	l := length
	resetIdx := 0
	for i := 0; i < len(dst.entries); i++ {
	var short string
	extended := true
	for extended {
	extended = false
	if len(dst.entries[i].val) <= l {
	short = dst.entries[i].digest.String()
	} else {
	short = dst.entries[i].val[:l]
	for j := i + 1; j < len(dst.entries); j++ {
	if checkShortMatch(dst.entries[j].alg, dst.entries[j].val, "", short) {
	if j > resetIdx {
	resetIdx = j
	}
	extended = true
	} else {
	break
	}
	}
	if extended {
	l++
	}
	}
	}
	m[dst.entries[i].digest] = short
	if i >= resetIdx {
	l = length
	}
	}
	return m
	}

	type digestEntry struct {
	alg digest.Algorithm
	val string
	digest digest.Digest
	}

	type digestEntries []*digestEntry

	func (d digestEntries) Len() int {
	return len(d)
	}

	func (d digestEntries) Less(i, j int) bool {
	if d[i].val != d[j].val {
	return d[i].val < d[j].val
	}
	return d[i].alg < d[j].alg
	}

	func (d digestEntries) Swap(i, j int) {
	d[i], d[j] = d[j], d[i]
	}