well-goknown/vendor/github.com/btcsuite/btcd/chaincfg/chainhash/hash.go

// Copyright (c) 2013-2016 The btcsuite developers
// Copyright (c) 2015 The Decred developers
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.

package chainhash

import (
	"crypto/sha256"
	"encoding/hex"
	"encoding/json"
	"fmt"
)

// HashSize of array used to store hashes.  See Hash.
const HashSize = 32

// MaxHashStringSize is the maximum length of a Hash hash string.
const MaxHashStringSize = HashSize * 2

var (
	// TagBIP0340Challenge is the BIP-0340 tag for challenges.
	TagBIP0340Challenge = []byte("BIP0340/challenge")

	// TagBIP0340Aux is the BIP-0340 tag for aux data.
	TagBIP0340Aux = []byte("BIP0340/aux")

	// TagBIP0340Nonce is the BIP-0340 tag for nonces.
	TagBIP0340Nonce = []byte("BIP0340/nonce")

	// TagTapSighash is the tag used by BIP 341 to generate the sighash
	// flags.
	TagTapSighash = []byte("TapSighash")

	// TagTagTapLeaf is the message tag prefix used to compute the hash
	// digest of a tapscript leaf.
	TagTapLeaf = []byte("TapLeaf")

	// TagTapBranch is the message tag prefix used to compute the
	// hash digest of two tap leaves into a taproot branch node.
	TagTapBranch = []byte("TapBranch")

	// TagTapTweak is the message tag prefix used to compute the hash tweak
	// used to enable a public key to commit to the taproot branch root
	// for the witness program.
	TagTapTweak = []byte("TapTweak")

	// precomputedTags is a map containing the SHA-256 hash of the BIP-0340
	// tags.
	precomputedTags = map[string]Hash{
		string(TagBIP0340Challenge): sha256.Sum256(TagBIP0340Challenge),
		string(TagBIP0340Aux):       sha256.Sum256(TagBIP0340Aux),
		string(TagBIP0340Nonce):     sha256.Sum256(TagBIP0340Nonce),
		string(TagTapSighash):       sha256.Sum256(TagTapSighash),
		string(TagTapLeaf):          sha256.Sum256(TagTapLeaf),
		string(TagTapBranch):        sha256.Sum256(TagTapBranch),
		string(TagTapTweak):         sha256.Sum256(TagTapTweak),
	}
)

// ErrHashStrSize describes an error that indicates the caller specified a hash
// string that has too many characters.
var ErrHashStrSize = fmt.Errorf("max hash string length is %v bytes", MaxHashStringSize)

// Hash is used in several of the bitcoin messages and common structures.  It
// typically represents the double sha256 of data.
type Hash [HashSize]byte

// String returns the Hash as the hexadecimal string of the byte-reversed
// hash.
func (hash Hash) String() string {
	for i := 0; i < HashSize/2; i++ {
		hash[i], hash[HashSize-1-i] = hash[HashSize-1-i], hash[i]
	}
	return hex.EncodeToString(hash[:])
}

// CloneBytes returns a copy of the bytes which represent the hash as a byte
// slice.
//
// NOTE: It is generally cheaper to just slice the hash directly thereby reusing
// the same bytes rather than calling this method.
func (hash *Hash) CloneBytes() []byte {
	newHash := make([]byte, HashSize)
	copy(newHash, hash[:])

	return newHash
}

// SetBytes sets the bytes which represent the hash.  An error is returned if
// the number of bytes passed in is not HashSize.
func (hash *Hash) SetBytes(newHash []byte) error {
	nhlen := len(newHash)
	if nhlen != HashSize {
		return fmt.Errorf("invalid hash length of %v, want %v", nhlen,
			HashSize)
	}
	copy(hash[:], newHash)

	return nil
}

// IsEqual returns true if target is the same as hash.
func (hash *Hash) IsEqual(target *Hash) bool {
	if hash == nil && target == nil {
		return true
	}
	if hash == nil || target == nil {
		return false
	}
	return *hash == *target
}

// MarshalJSON serialises the hash as a JSON appropriate string value.
func (hash Hash) MarshalJSON() ([]byte, error) {
	return json.Marshal(hash.String())
}

// UnmarshalJSON parses the hash with JSON appropriate string value.
func (hash *Hash) UnmarshalJSON(input []byte) error {
	// If the first byte indicates an array, the hash could have been marshalled
	// using the legacy method and e.g. persisted.
	if len(input) > 0 && input[0] == '[' {
		return decodeLegacy(hash, input)
	}

	var sh string
	err := json.Unmarshal(input, &sh)
	if err != nil {
		return err
	}
	newHash, err := NewHashFromStr(sh)
	if err != nil {
		return err
	}

	return hash.SetBytes(newHash[:])
}

// NewHash returns a new Hash from a byte slice.  An error is returned if
// the number of bytes passed in is not HashSize.
func NewHash(newHash []byte) (*Hash, error) {
	var sh Hash
	err := sh.SetBytes(newHash)
	if err != nil {
		return nil, err
	}
	return &sh, err
}

// TaggedHash implements the tagged hash scheme described in BIP-340. We use
// sha-256 to bind a message hash to a specific context using a tag:
// sha256(sha256(tag) || sha256(tag) || msg).
func TaggedHash(tag []byte, msgs ...[]byte) *Hash {
	// Check to see if we've already pre-computed the hash of the tag. If
	// so then this'll save us an extra sha256 hash.
	shaTag, ok := precomputedTags[string(tag)]
	if !ok {
		shaTag = sha256.Sum256(tag)
	}

	// h = sha256(sha256(tag) || sha256(tag) || msg)
	h := sha256.New()
	h.Write(shaTag[:])
	h.Write(shaTag[:])

	for _, msg := range msgs {
		h.Write(msg)
	}

	taggedHash := h.Sum(nil)

	// The function can't error out since the above hash is guaranteed to
	// be 32 bytes.
	hash, _ := NewHash(taggedHash)

	return hash
}

// NewHashFromStr creates a Hash from a hash string.  The string should be
// the hexadecimal string of a byte-reversed hash, but any missing characters
// result in zero padding at the end of the Hash.
func NewHashFromStr(hash string) (*Hash, error) {
	ret := new(Hash)
	err := Decode(ret, hash)
	if err != nil {
		return nil, err
	}
	return ret, nil
}

// Decode decodes the byte-reversed hexadecimal string encoding of a Hash to a
// destination.
func Decode(dst *Hash, src string) error {
	// Return error if hash string is too long.
	if len(src) > MaxHashStringSize {
		return ErrHashStrSize
	}

	// Hex decoder expects the hash to be a multiple of two.  When not, pad
	// with a leading zero.
	var srcBytes []byte
	if len(src)%2 == 0 {
		srcBytes = []byte(src)
	} else {
		srcBytes = make([]byte, 1+len(src))
		srcBytes[0] = '0'
		copy(srcBytes[1:], src)
	}

	// Hex decode the source bytes to a temporary destination.
	var reversedHash Hash
	_, err := hex.Decode(reversedHash[HashSize-hex.DecodedLen(len(srcBytes)):], srcBytes)
	if err != nil {
		return err
	}

	// Reverse copy from the temporary hash to destination.  Because the
	// temporary was zeroed, the written result will be correctly padded.
	for i, b := range reversedHash[:HashSize/2] {
		dst[i], dst[HashSize-1-i] = reversedHash[HashSize-1-i], b
	}

	return nil
}

// decodeLegacy decodes an Hash that has been encoded with the legacy method
// (i.e. represented as a bytes array) to a destination.
func decodeLegacy(dst *Hash, src []byte) error {
	var hashBytes []byte
	err := json.Unmarshal(src, &hashBytes)
	if err != nil {
		return err
	}
	if len(hashBytes) != HashSize {
		return ErrHashStrSize
	}
	return dst.SetBytes(hashBytes)
}
replace context with caller for zerolog, add vendor 2024-09-17 01:01:42 +00:00			`// Copyright (c) 2013-2016 The btcsuite developers`
			`// Copyright (c) 2015 The Decred developers`
			`// Use of this source code is governed by an ISC`
			`// license that can be found in the LICENSE file.`

			`package chainhash`

			`import (`
			`"crypto/sha256"`
			`"encoding/hex"`
			`"encoding/json"`
			`"fmt"`
			`)`

			`// HashSize of array used to store hashes. See Hash.`
			`const HashSize = 32`

			`// MaxHashStringSize is the maximum length of a Hash hash string.`
			`const MaxHashStringSize = HashSize * 2`

			`var (`
			`// TagBIP0340Challenge is the BIP-0340 tag for challenges.`
			`TagBIP0340Challenge = []byte("BIP0340/challenge")`

			`// TagBIP0340Aux is the BIP-0340 tag for aux data.`
			`TagBIP0340Aux = []byte("BIP0340/aux")`

			`// TagBIP0340Nonce is the BIP-0340 tag for nonces.`
			`TagBIP0340Nonce = []byte("BIP0340/nonce")`

			`// TagTapSighash is the tag used by BIP 341 to generate the sighash`
			`// flags.`
			`TagTapSighash = []byte("TapSighash")`

			`// TagTagTapLeaf is the message tag prefix used to compute the hash`
			`// digest of a tapscript leaf.`
			`TagTapLeaf = []byte("TapLeaf")`

			`// TagTapBranch is the message tag prefix used to compute the`
			`// hash digest of two tap leaves into a taproot branch node.`
			`TagTapBranch = []byte("TapBranch")`

			`// TagTapTweak is the message tag prefix used to compute the hash tweak`
			`// used to enable a public key to commit to the taproot branch root`
			`// for the witness program.`
			`TagTapTweak = []byte("TapTweak")`

			`// precomputedTags is a map containing the SHA-256 hash of the BIP-0340`
			`// tags.`
			`precomputedTags = map[string]Hash{`
			`string(TagBIP0340Challenge): sha256.Sum256(TagBIP0340Challenge),`
			`string(TagBIP0340Aux): sha256.Sum256(TagBIP0340Aux),`
			`string(TagBIP0340Nonce): sha256.Sum256(TagBIP0340Nonce),`
			`string(TagTapSighash): sha256.Sum256(TagTapSighash),`
			`string(TagTapLeaf): sha256.Sum256(TagTapLeaf),`
			`string(TagTapBranch): sha256.Sum256(TagTapBranch),`
			`string(TagTapTweak): sha256.Sum256(TagTapTweak),`
			`}`
			`)`

			`// ErrHashStrSize describes an error that indicates the caller specified a hash`
			`// string that has too many characters.`
			`var ErrHashStrSize = fmt.Errorf("max hash string length is %v bytes", MaxHashStringSize)`

			`// Hash is used in several of the bitcoin messages and common structures. It`
			`// typically represents the double sha256 of data.`
			`type Hash [HashSize]byte`

			`// String returns the Hash as the hexadecimal string of the byte-reversed`
			`// hash.`
			`func (hash Hash) String() string {`
			`for i := 0; i < HashSize/2; i++ {`
			`hash[i], hash[HashSize-1-i] = hash[HashSize-1-i], hash[i]`
			`}`
			`return hex.EncodeToString(hash[:])`
			`}`

			`// CloneBytes returns a copy of the bytes which represent the hash as a byte`
			`// slice.`
			`//`
			`// NOTE: It is generally cheaper to just slice the hash directly thereby reusing`
			`// the same bytes rather than calling this method.`
			`func (hash *Hash) CloneBytes() []byte {`
			`newHash := make([]byte, HashSize)`
			`copy(newHash, hash[:])`

			`return newHash`
			`}`

			`// SetBytes sets the bytes which represent the hash. An error is returned if`
			`// the number of bytes passed in is not HashSize.`
			`func (hash *Hash) SetBytes(newHash []byte) error {`
			`nhlen := len(newHash)`
			`if nhlen != HashSize {`
			`return fmt.Errorf("invalid hash length of %v, want %v", nhlen,`
			`HashSize)`
			`}`
			`copy(hash[:], newHash)`

			`return nil`
			`}`

			`// IsEqual returns true if target is the same as hash.`
			`func (hash Hash) IsEqual(target Hash) bool {`
			`if hash == nil && target == nil {`
			`return true`
			`}`
			`if hash == nil \|\| target == nil {`
			`return false`
			`}`
			`return hash == target`
			`}`

			`// MarshalJSON serialises the hash as a JSON appropriate string value.`
			`func (hash Hash) MarshalJSON() ([]byte, error) {`
			`return json.Marshal(hash.String())`
			`}`

			`// UnmarshalJSON parses the hash with JSON appropriate string value.`
			`func (hash *Hash) UnmarshalJSON(input []byte) error {`
			`// If the first byte indicates an array, the hash could have been marshalled`
			`// using the legacy method and e.g. persisted.`
			`if len(input) > 0 && input[0] == '[' {`
			`return decodeLegacy(hash, input)`
			`}`

			`var sh string`
			`err := json.Unmarshal(input, &sh)`
			`if err != nil {`
			`return err`
			`}`
			`newHash, err := NewHashFromStr(sh)`
			`if err != nil {`
			`return err`
			`}`

			`return hash.SetBytes(newHash[:])`
			`}`

			`// NewHash returns a new Hash from a byte slice. An error is returned if`
			`// the number of bytes passed in is not HashSize.`
			`func NewHash(newHash []byte) (*Hash, error) {`
			`var sh Hash`
			`err := sh.SetBytes(newHash)`
			`if err != nil {`
			`return nil, err`
			`}`
			`return &sh, err`
			`}`

			`// TaggedHash implements the tagged hash scheme described in BIP-340. We use`
			`// sha-256 to bind a message hash to a specific context using a tag:`
			`// sha256(sha256(tag) \|\| sha256(tag) \|\| msg).`
			`func TaggedHash(tag []byte, msgs ...[]byte) *Hash {`
			`// Check to see if we've already pre-computed the hash of the tag. If`
			`// so then this'll save us an extra sha256 hash.`
			`shaTag, ok := precomputedTags[string(tag)]`
			`if !ok {`
			`shaTag = sha256.Sum256(tag)`
			`}`

			`// h = sha256(sha256(tag) \|\| sha256(tag) \|\| msg)`
			`h := sha256.New()`
			`h.Write(shaTag[:])`
			`h.Write(shaTag[:])`

			`for _, msg := range msgs {`
			`h.Write(msg)`
			`}`

			`taggedHash := h.Sum(nil)`

			`// The function can't error out since the above hash is guaranteed to`
			`// be 32 bytes.`
			`hash, _ := NewHash(taggedHash)`

			`return hash`
			`}`

			`// NewHashFromStr creates a Hash from a hash string. The string should be`
			`// the hexadecimal string of a byte-reversed hash, but any missing characters`
			`// result in zero padding at the end of the Hash.`
			`func NewHashFromStr(hash string) (*Hash, error) {`
			`ret := new(Hash)`
			`err := Decode(ret, hash)`
			`if err != nil {`
			`return nil, err`
			`}`
			`return ret, nil`
			`}`

			`// Decode decodes the byte-reversed hexadecimal string encoding of a Hash to a`
			`// destination.`
			`func Decode(dst *Hash, src string) error {`
			`// Return error if hash string is too long.`
			`if len(src) > MaxHashStringSize {`
			`return ErrHashStrSize`
			`}`

			`// Hex decoder expects the hash to be a multiple of two. When not, pad`
			`// with a leading zero.`
			`var srcBytes []byte`
			`if len(src)%2 == 0 {`
			`srcBytes = []byte(src)`
			`} else {`
			`srcBytes = make([]byte, 1+len(src))`
			`srcBytes[0] = '0'`
			`copy(srcBytes[1:], src)`
			`}`

			`// Hex decode the source bytes to a temporary destination.`
			`var reversedHash Hash`
			`_, err := hex.Decode(reversedHash[HashSize-hex.DecodedLen(len(srcBytes)):], srcBytes)`
			`if err != nil {`
			`return err`
			`}`

			`// Reverse copy from the temporary hash to destination. Because the`
			`// temporary was zeroed, the written result will be correctly padded.`
			`for i, b := range reversedHash[:HashSize/2] {`
			`dst[i], dst[HashSize-1-i] = reversedHash[HashSize-1-i], b`
			`}`

			`return nil`
			`}`

			`// decodeLegacy decodes an Hash that has been encoded with the legacy method`
			`// (i.e. represented as a bytes array) to a destination.`
			`func decodeLegacy(dst *Hash, src []byte) error {`
			`var hashBytes []byte`
			`err := json.Unmarshal(src, &hashBytes)`
			`if err != nil {`
			`return err`
			`}`
			`if len(hashBytes) != HashSize {`
			`return ErrHashStrSize`
			`}`
			`return dst.SetBytes(hashBytes)`
			`}`