zolfa
/
tendermint


								package hd


								import (

									"crypto/ecdsa"

									"crypto/hmac"

									"crypto/sha256"

									"crypto/sha512"

									"encoding/base64"

									"encoding/binary"

									"encoding/hex"

									"errors"

									"fmt"

									"hash"

									"log"

									"math/big"

									"strconv"

									"strings"


									"github.com/btcsuite/btcd/btcec"

									"github.com/btcsuite/btcutil/base58"

									"github.com/tendermint/go-crypto"

									"golang.org/x/crypto/ripemd160"

								)


								func ComputeAddress(pubKeyHex string, chainHex string, path string, index int32) string {

									pubKeyBytes := DerivePublicKeyForPath(

										HexDecode(pubKeyHex),

										HexDecode(chainHex),

										fmt.Sprintf("%v/%v", path, index),

									)

									return AddrFromPubKeyBytes(pubKeyBytes)

								}


								func ComputePrivateKey(mprivHex string, chainHex string, path string, index int32) string {

									privKeyBytes := DerivePrivateKeyForPath(

										HexDecode(mprivHex),

										HexDecode(chainHex),

										fmt.Sprintf("%v/%v", path, index),

									)

									return HexEncode(privKeyBytes)

								}


								func ComputeAddressForPrivKey(privKey string) string {

									pubKeyBytes := PubKeyBytesFromPrivKeyBytes(HexDecode(privKey), true)

									return AddrFromPubKeyBytes(pubKeyBytes)

								}


								func SignMessage(privKey string, message string, compress bool) string {

									prefixBytes := []byte("Bitcoin Signed Message:\n")

									messageBytes := []byte(message)

									bytes := []byte{}

									bytes = append(bytes, byte(len(prefixBytes)))

									bytes = append(bytes, prefixBytes...)

									bytes = append(bytes, byte(len(messageBytes)))

									bytes = append(bytes, messageBytes...)

									privKeyBytes := HexDecode(privKey)

									x, y := btcec.S256().ScalarBaseMult(privKeyBytes)

									ecdsaPubKey := ecdsa.PublicKey{

										Curve: btcec.S256(),

										X:     x,

										Y:     y,

									}

									ecdsaPrivKey := &btcec.PrivateKey{

										PublicKey: ecdsaPubKey,

										D:         new(big.Int).SetBytes(privKeyBytes),

									}

									sigbytes, err := btcec.SignCompact(btcec.S256(), ecdsaPrivKey, crypto.Sha256(crypto.Sha256(bytes)), compress)

									if err != nil {

										panic(err)

									}

									return base64.StdEncoding.EncodeToString(sigbytes)

								}


								// returns MPK, Chain, and master secret in hex.

								func ComputeMastersFromSeed(seed string) (string, string, string, string) {

									secret, chain := I64([]byte("Bitcoin seed"), []byte(seed))

									pubKeyBytes := PubKeyBytesFromPrivKeyBytes(secret, true)

									return HexEncode(pubKeyBytes), HexEncode(secret), HexEncode(chain), HexEncode(secret)

								}


								func ComputeWIF(privKey string, compress bool) string {

									return WIFFromPrivKeyBytes(HexDecode(privKey), compress)

								}


								func ComputeTxId(rawTxHex string) string {

									return HexEncode(ReverseBytes(CalcHash256(HexDecode(rawTxHex))))

								}


								// Private methods...


								func printKeyInfo(privKeyBytes []byte, pubKeyBytes []byte, chain []byte) {

									if pubKeyBytes == nil {

										pubKeyBytes = PubKeyBytesFromPrivKeyBytes(privKeyBytes, true)

									}

									addr := AddrFromPubKeyBytes(pubKeyBytes)

									log.Println("\nprikey:\t%v\npubKeyBytes:\t%v\naddr:\t%v\nchain:\t%v",

										HexEncode(privKeyBytes),

										HexEncode(pubKeyBytes),

										addr,

										HexEncode(chain))

								}


								func DerivePrivateKeyForPath(privKeyBytes []byte, chain []byte, path string) []byte {

									data := privKeyBytes

									parts := strings.Split(path, "/")

									for _, part := range parts {

										prime := part[len(part)-1:] == "'"

										// prime == private derivation. Otherwise public.

										if prime {

											part = part[:len(part)-1]

										}

										i, err := strconv.Atoi(part)

										if err != nil {

											panic(err)

										}

										if i < 0 {

											panic(errors.New("index too large."))

										}

										data, chain = DerivePrivateKey(data, chain, uint32(i), prime)

										//printKeyInfo(data, nil, chain)

									}

									return data

								}


								func DerivePublicKeyForPath(pubKeyBytes []byte, chain []byte, path string) []byte {

									data := pubKeyBytes

									parts := strings.Split(path, "/")

									for _, part := range parts {

										prime := part[len(part)-1:] == "'"

										if prime {

											panic(errors.New("cannot do a prime derivation from public key"))

										}

										i, err := strconv.Atoi(part)

										if err != nil {

											panic(err)

										}

										if i < 0 {

											panic(errors.New("index too large."))

										}

										data, chain = DerivePublicKey(data, chain, uint32(i))

										//printKeyInfo(nil, data, chain)

									}

									return data

								}


								func DerivePrivateKey(privKeyBytes []byte, chain []byte, i uint32, prime bool) ([]byte, []byte) {

									data := []byte{}

									if prime {

										i = i | 0x80000000

										data = append([]byte{byte(0)}, privKeyBytes...)

									} else {

										public := PubKeyBytesFromPrivKeyBytes(privKeyBytes, true)

										data = public

									}

									data = append(data, uint32ToBytes(i)...)

									data2, chain2 := I64(chain, data)

									x := addScalars(privKeyBytes, data2)

									return x, chain2

								}


								func DerivePublicKey(pubKeyBytes []byte, chain []byte, i uint32) ([]byte, []byte) {

									data := []byte{}

									data = append(data, pubKeyBytes...)

									data = append(data, uint32ToBytes(i)...)

									data2, chain2 := I64(chain, data)

									data2p := PubKeyBytesFromPrivKeyBytes(data2, true)

									return addPoints(pubKeyBytes, data2p), chain2

								}


								func addPoints(a []byte, b []byte) []byte {

									ap, err := btcec.ParsePubKey(a, btcec.S256())

									if err != nil {

										panic(err)

									}

									bp, err := btcec.ParsePubKey(b, btcec.S256())

									if err != nil {

										panic(err)

									}

									sumX, sumY := btcec.S256().Add(ap.X, ap.Y, bp.X, bp.Y)

									sum := (*btcec.PublicKey)(&btcec.PublicKey{

										Curve: btcec.S256(),

										X:     sumX,

										Y:     sumY,

									})

									return sum.SerializeCompressed()

								}


								func addScalars(a []byte, b []byte) []byte {

									aInt := new(big.Int).SetBytes(a)

									bInt := new(big.Int).SetBytes(b)

									sInt := new(big.Int).Add(aInt, bInt)

									x := sInt.Mod(sInt, btcec.S256().N).Bytes()

									x2 := [32]byte{}

									copy(x2[32-len(x):], x)

									return x2[:]

								}


								func uint32ToBytes(i uint32) []byte {

									b := [4]byte{}

									binary.BigEndian.PutUint32(b[:], i)

									return b[:]

								}


								func HexEncode(b []byte) string {

									return hex.EncodeToString(b)

								}


								func HexDecode(str string) []byte {

									b, _ := hex.DecodeString(str)

									return b

								}


								func I64(key []byte, data []byte) ([]byte, []byte) {

									mac := hmac.New(sha512.New, key)

									mac.Write(data)

									I := mac.Sum(nil)

									return I[:32], I[32:]

								}


								// This returns a Bitcoin-like address.

								func AddrFromPubKeyBytes(pubKeyBytes []byte) string {

									prefix := byte(0x00) // TODO Make const or configurable

									h160 := CalcHash160(pubKeyBytes)

									h160 = append([]byte{prefix}, h160...)

									checksum := CalcHash256(h160)

									b := append(h160, checksum[:4]...)

									return base58.Encode(b)

								}


								func AddrBytesFromPubKeyBytes(pubKeyBytes []byte) (addrBytes []byte, checksum []byte) {

									prefix := byte(0x00) // TODO Make const or configurable

									h160 := CalcHash160(pubKeyBytes)

									_h160 := append([]byte{prefix}, h160...)

									checksum = CalcHash256(_h160)[:4]

									return h160, checksum

								}


								func WIFFromPrivKeyBytes(privKeyBytes []byte, compress bool) string {

									prefix := byte(0x80) // TODO Make const or configurable

									bytes := append([]byte{prefix}, privKeyBytes...)

									if compress {

										bytes = append(bytes, byte(1))

									}

									checksum := CalcHash256(bytes)

									bytes = append(bytes, checksum[:4]...)

									return base58.Encode(bytes)

								}


								func PubKeyBytesFromPrivKeyBytes(privKeyBytes []byte, compress bool) (pubKeyBytes []byte) {

									x, y := btcec.S256().ScalarBaseMult(privKeyBytes)

									pub := (*btcec.PublicKey)(&btcec.PublicKey{

										Curve: btcec.S256(),

										X:     x,

										Y:     y,

									})


									if compress {

										return pub.SerializeCompressed()

									}

									return pub.SerializeUncompressed()

								}


								// Calculate the hash of hasher over buf.

								func CalcHash(buf []byte, hasher hash.Hash) []byte {

									hasher.Write(buf)

									return hasher.Sum(nil)

								}


								// calculate hash160 which is ripemd160(sha256(data))

								func CalcHash160(buf []byte) []byte {

									return CalcHash(CalcHash(buf, sha256.New()), ripemd160.New())

								}


								// calculate hash256 which is sha256(sha256(data))

								func CalcHash256(buf []byte) []byte {

									return CalcHash(CalcHash(buf, sha256.New()), sha256.New())

								}


								// calculate sha512(data)

								func CalcSha512(buf []byte) []byte {

									return CalcHash(buf, sha512.New())

								}


								func ReverseBytes(buf []byte) []byte {

									res := []byte{}

									for i := len(buf) - 1; i >= 0; i-- {

										res = append(res, buf[i])

									}

									return res

								}