347 lines
9.3 KiB
Go
347 lines
9.3 KiB
Go
// Go implementation of http://www.hashids.org under MIT license
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// Generates hashes from an array of integers, eg. for YouTube like hashes
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// Setup: go get github.com/speps/go-hashids
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// Original implementations by Ivan Akimov at https://github.com/ivanakimov
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// Thanks to Rémy Oudompheng and Peter Hellberg for code review and fixes
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package hashids
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import (
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"errors"
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"math"
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)
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const (
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// Version is the version number of the library
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Version string = "1.0.0"
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// DefaultAlphabet is the default alphabet used by go-hashids
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DefaultAlphabet string = "abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ1234567890"
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minAlphabetLength int = 16
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sepDiv float64 = 3.5
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guardDiv float64 = 12.0
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)
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var sepsOriginal = []rune("cfhistuCFHISTU")
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// HashID contains everything needed to encode/decode hashids
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type HashID struct {
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alphabet []rune
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minLength int
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salt []rune
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seps []rune
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guards []rune
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}
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// HashIDData contains the information needed to generate hashids
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type HashIDData struct {
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// Alphabet is the alphabet used to generate new ids
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Alphabet string
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// MinLength is the minimum length of a generated id
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MinLength int
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// Salt is the secret used to make the generated id harder to guess
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Salt string
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}
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// NewData creates a new HashIDData with the DefaultAlphabet already set.
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func NewData() *HashIDData {
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return &HashIDData{Alphabet: DefaultAlphabet}
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}
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// New creates a new HashID
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func New() *HashID {
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return NewWithData(NewData())
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}
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// NewWithData creates a new HashID with the provided HashIDData
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func NewWithData(data *HashIDData) *HashID {
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if len(data.Alphabet) < minAlphabetLength {
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panic(errors.New("alphabet must contain at least 16 characters"))
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}
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// Check if all characters are unique in Alphabet
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uniqueCheck := make(map[rune]bool, len(data.Alphabet))
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for _, a := range data.Alphabet {
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if _, found := uniqueCheck[a]; found {
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panic(errors.New("duplicate character in alphabet"))
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}
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uniqueCheck[a] = true
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}
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alphabet := []rune(data.Alphabet)
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salt := []rune(data.Salt)
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seps := make([]rune, len(sepsOriginal))
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copy(seps, sepsOriginal)
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// seps should contain only characters present in alphabet; alphabet should not contains seps
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for i := 0; i < len(seps); i++ {
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foundIndex := -1
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for j, a := range alphabet {
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if a == seps[i] {
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foundIndex = j
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break
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}
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}
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if foundIndex == -1 {
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seps = append(seps[:i], seps[i+1:]...)
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i--
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} else {
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alphabet = append(alphabet[:foundIndex], alphabet[foundIndex+1:]...)
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}
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}
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seps = consistentShuffle(seps, salt)
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if len(seps) == 0 || float64(len(alphabet))/float64(len(seps)) > sepDiv {
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sepsLength := int(math.Ceil(float64(len(alphabet)) / sepDiv))
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if sepsLength == 1 {
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sepsLength++
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}
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if sepsLength > len(seps) {
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diff := sepsLength - len(seps)
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seps = append(seps, alphabet[:diff]...)
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alphabet = alphabet[diff:]
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} else {
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seps = seps[:sepsLength]
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}
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}
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alphabet = consistentShuffle(alphabet, salt)
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guardCount := int(math.Ceil(float64(len(alphabet)) / guardDiv))
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var guards []rune
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if len(alphabet) < 3 {
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guards = seps[:guardCount]
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seps = seps[guardCount:]
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} else {
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guards = alphabet[:guardCount]
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alphabet = alphabet[guardCount:]
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}
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return &HashID{
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alphabet: alphabet,
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minLength: data.MinLength,
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salt: salt,
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seps: seps,
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guards: guards,
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}
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}
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// Encode hashes an array of int to a string containing at least MinLength characters taken from the Alphabet.
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// Use Decode using the same Alphabet and Salt to get back the array of int.
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func (h *HashID) Encode(numbers []int) (string, error) {
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numbers64 := make([]int64, 0, len(numbers))
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for _, id := range numbers {
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numbers64 = append(numbers64, int64(id))
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}
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return h.EncodeInt64(numbers64)
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}
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// EncodeInt64 hashes an array of int64 to a string containing at least MinLength characters taken from the Alphabet.
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// Use DecodeInt64 using the same Alphabet and Salt to get back the array of int64.
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func (h *HashID) EncodeInt64(numbers []int64) (string, error) {
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if len(numbers) == 0 {
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return "", errors.New("encoding empty array of numbers makes no sense")
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}
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for _, n := range numbers {
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if n < 0 {
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return "", errors.New("negative number not supported")
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}
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}
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alphabet := make([]rune, len(h.alphabet))
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copy(alphabet, h.alphabet)
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numbersHash := int64(0)
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for i, n := range numbers {
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numbersHash += (n % int64(i+100))
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}
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result := make([]rune, 0, h.minLength)
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lottery := alphabet[numbersHash%int64(len(alphabet))]
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result = append(result, lottery)
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for i, n := range numbers {
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buffer := append([]rune{lottery}, append(h.salt, alphabet...)...)
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alphabet = consistentShuffle(alphabet, buffer[:len(alphabet)])
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hash := hash(n, alphabet)
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result = append(result, hash...)
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if i+1 < len(numbers) {
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n %= int64(hash[0]) + int64(i)
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result = append(result, h.seps[n%int64(len(h.seps))])
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}
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}
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if len(result) < h.minLength {
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guardIndex := (numbersHash + int64(result[0])) % int64(len(h.guards))
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result = append([]rune{h.guards[guardIndex]}, result...)
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if len(result) < h.minLength {
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guardIndex = (numbersHash + int64(result[2])) % int64(len(h.guards))
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result = append(result, h.guards[guardIndex])
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}
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}
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halfLength := len(alphabet) / 2
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for len(result) < h.minLength {
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alphabet = consistentShuffle(alphabet, alphabet)
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result = append(alphabet[halfLength:], append(result, alphabet[:halfLength]...)...)
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excess := len(result) - h.minLength
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if excess > 0 {
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result = result[excess/2 : excess/2+h.minLength]
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}
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}
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return string(result), nil
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}
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// DEPRECATED: Use DecryptWithError instead
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// Decode unhashes the string passed to an array of int.
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// It is symmetric with Encode if the Alphabet and Salt are the same ones which were used to hash.
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// MinLength has no effect on Decode.
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func (h *HashID) Decode(hash string) []int {
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result, err := h.DecodeWithError(hash)
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if err != nil {
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panic(err)
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}
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return result
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}
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// Decode unhashes the string passed to an array of int.
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// It is symmetric with Encode if the Alphabet and Salt are the same ones which were used to hash.
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// MinLength has no effect on Decode.
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func (h *HashID) DecodeWithError(hash string) ([]int, error) {
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result64, err := h.DecodeInt64WithError(hash)
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if err != nil {
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return nil, err
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}
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result := make([]int, 0, len(result64))
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for _, id := range result64 {
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result = append(result, int(id))
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}
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return result, nil
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}
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// DEPRECATED: Use DecryptInt64WithError instead
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// DecodeInt64 unhashes the string passed to an array of int64.
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// It is symmetric with EncodeInt64 if the Alphabet and Salt are the same ones which were used to hash.
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// MinLength has no effect on DecodeInt64.
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func (h *HashID) DecodeInt64(hash string) []int64 {
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result, err := h.DecodeInt64WithError(hash)
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if err != nil {
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panic(err)
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}
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return result
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}
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// DecodeInt64 unhashes the string passed to an array of int64.
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// It is symmetric with EncodeInt64 if the Alphabet and Salt are the same ones which were used to hash.
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// MinLength has no effect on DecodeInt64.
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func (h *HashID) DecodeInt64WithError(hash string) ([]int64, error) {
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hashes := splitRunes([]rune(hash), h.guards)
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hashIndex := 0
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if len(hashes) == 2 || len(hashes) == 3 {
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hashIndex = 1
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}
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result := make([]int64, 0)
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hashBreakdown := hashes[hashIndex]
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if len(hashBreakdown) > 0 {
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lottery := hashBreakdown[0]
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hashBreakdown = hashBreakdown[1:]
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hashes = splitRunes(hashBreakdown, h.seps)
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alphabet := []rune(h.alphabet)
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for _, subHash := range hashes {
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buffer := append([]rune{lottery}, append(h.salt, alphabet...)...)
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alphabet = consistentShuffle(alphabet, buffer[:len(alphabet)])
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number, err := unhash(subHash, alphabet)
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if err != nil {
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return nil, err
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}
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result = append(result, number)
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}
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}
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return result, nil
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}
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func splitRunes(input, seps []rune) [][]rune {
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splitIndices := make([]int, 0)
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for i, inputRune := range input {
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for _, sepsRune := range seps {
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if inputRune == sepsRune {
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splitIndices = append(splitIndices, i)
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}
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}
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}
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result := make([][]rune, 0, len(splitIndices)+1)
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inputLeft := input[:]
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for _, splitIndex := range splitIndices {
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splitIndex -= len(input) - len(inputLeft)
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subInput := make([]rune, splitIndex)
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copy(subInput, inputLeft[:splitIndex])
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result = append(result, subInput)
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inputLeft = inputLeft[splitIndex+1:]
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}
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result = append(result, inputLeft)
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return result
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}
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func hash(input int64, alphabet []rune) []rune {
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result := make([]rune, 0)
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for {
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r := alphabet[input%int64(len(alphabet))]
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result = append(result, r)
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input /= int64(len(alphabet))
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if input == 0 {
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break
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}
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}
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reversed := make([]rune, len(result))
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for i, r := range result {
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reversed[len(result)-i-1] = r
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}
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return reversed
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}
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func unhash(input, alphabet []rune) (int64, error) {
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result := int64(0)
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for i, inputRune := range input {
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alphabetPos := -1
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for pos, alphabetRune := range alphabet {
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if inputRune == alphabetRune {
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alphabetPos = pos
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break
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}
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}
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if alphabetPos == -1 {
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return 0, errors.New("alphabet used for hash was different")
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}
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result += int64(alphabetPos) * int64(math.Pow(float64(len(alphabet)), float64(len(input)-i-1)))
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}
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return result, nil
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}
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func consistentShuffle(alphabet, salt []rune) []rune {
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if len(salt) == 0 {
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return alphabet
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}
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result := make([]rune, len(alphabet))
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copy(result, alphabet)
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for i, v, p := len(result)-1, 0, 0; i > 0; i-- {
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p += int(salt[v])
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j := (int(salt[v]) + v + p) % i
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result[i], result[j] = result[j], result[i]
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v = (v + 1) % len(salt)
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}
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return result
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}
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