neo-go/pkg/crypto/keys/publickey.go

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package keys
import (
"crypto/ecdsa"
"crypto/elliptic"
"crypto/x509"
"encoding/hex"
"encoding/json"
"errors"
"fmt"
"math/big"
"github.com/btcsuite/btcd/btcec"
lru "github.com/hashicorp/golang-lru"
"github.com/nspcc-dev/neo-go/pkg/core/interop/interopnames"
"github.com/nspcc-dev/neo-go/pkg/crypto/hash"
"github.com/nspcc-dev/neo-go/pkg/encoding/address"
"github.com/nspcc-dev/neo-go/pkg/io"
"github.com/nspcc-dev/neo-go/pkg/util"
"github.com/nspcc-dev/neo-go/pkg/vm/emit"
)
// coordLen is the number of bytes in serialized X or Y coordinate.
const coordLen = 32
// SignatureLen is the length of standard signature for 256-bit EC key.
const SignatureLen = 64
// PublicKeys is a list of public keys.
type PublicKeys []*PublicKey
func (keys PublicKeys) Len() int { return len(keys) }
func (keys PublicKeys) Swap(i, j int) { keys[i], keys[j] = keys[j], keys[i] }
func (keys PublicKeys) Less(i, j int) bool {
return keys[i].Cmp(keys[j]) == -1
}
// DecodeBytes decodes a PublicKeys from the given slice of bytes.
func (keys *PublicKeys) DecodeBytes(data []byte) error {
b := io.NewBinReaderFromBuf(data)
b.ReadArray(keys)
return b.Err
}
// Bytes encodes PublicKeys to the new slice of bytes.
func (keys *PublicKeys) Bytes() []byte {
buf := io.NewBufBinWriter()
buf.WriteArray(*keys)
if buf.Err != nil {
panic(buf.Err)
}
return buf.Bytes()
}
// Contains checks whether passed param contained in PublicKeys.
func (keys PublicKeys) Contains(pKey *PublicKey) bool {
for _, key := range keys {
if key.Equal(pKey) {
return true
}
}
return false
}
// Copy returns copy of keys.
func (keys PublicKeys) Copy() PublicKeys {
res := make(PublicKeys, len(keys))
copy(res, keys)
return res
}
// Unique returns set of public keys.
func (keys PublicKeys) Unique() PublicKeys {
unique := PublicKeys{}
for _, publicKey := range keys {
if !unique.Contains(publicKey) {
unique = append(unique, publicKey)
}
}
return unique
}
// PublicKey represents a public key and provides a high level
// API around ecdsa.PublicKey.
type PublicKey ecdsa.PublicKey
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// Equal returns true in case public keys are equal.
func (p *PublicKey) Equal(key *PublicKey) bool {
return p.X.Cmp(key.X) == 0 && p.Y.Cmp(key.Y) == 0
}
// Cmp compares two keys.
func (p *PublicKey) Cmp(key *PublicKey) int {
xCmp := p.X.Cmp(key.X)
if xCmp != 0 {
return xCmp
}
return p.Y.Cmp(key.Y)
}
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// NewPublicKeyFromString returns a public key created from the
// given hex string.
func NewPublicKeyFromString(s string) (*PublicKey, error) {
b, err := hex.DecodeString(s)
if err != nil {
return nil, err
}
return NewPublicKeyFromBytes(b, elliptic.P256())
}
// keycache is a simple lru cache for P256 keys that avoids Y calculation overhead
// for known keys.
var keycache *lru.Cache
func init() {
// Less than 100K, probably enough for our purposes.
keycache, _ = lru.New(1024)
}
// NewPublicKeyFromBytes returns public key created from b using given EC.
func NewPublicKeyFromBytes(b []byte, curve elliptic.Curve) (*PublicKey, error) {
var pubKey *PublicKey
cachedKey, ok := keycache.Get(string(b))
if ok {
pubKey = cachedKey.(*PublicKey)
if pubKey.Curve == curve {
return pubKey, nil
}
}
pubKey = new(PublicKey)
pubKey.Curve = curve
if err := pubKey.DecodeBytes(b); err != nil {
return nil, err
}
keycache.Add(string(b), pubKey)
return pubKey, nil
}
// getBytes serializes X and Y using compressed or uncompressed format.
func (p *PublicKey) getBytes(compressed bool) []byte {
if p.IsInfinity() {
return []byte{0x00}
}
if compressed {
return elliptic.MarshalCompressed(p.Curve, p.X, p.Y)
}
return elliptic.Marshal(p.Curve, p.X, p.Y)
}
// Bytes returns byte array representation of the public key in compressed
// form (33 bytes with 0x02 or 0x03 prefix, except infinity which is always 0).
func (p *PublicKey) Bytes() []byte {
return p.getBytes(true)
}
// UncompressedBytes returns byte array representation of the public key in
// uncompressed form (65 bytes with 0x04 prefix, except infinity which is
// always 0).
func (p *PublicKey) UncompressedBytes() []byte {
return p.getBytes(false)
}
// NewPublicKeyFromASN1 returns a NEO PublicKey from the ASN.1 serialized key.
func NewPublicKeyFromASN1(data []byte) (*PublicKey, error) {
var (
err error
pubkey interface{}
)
if pubkey, err = x509.ParsePKIXPublicKey(data); err != nil {
return nil, err
}
pk, ok := pubkey.(*ecdsa.PublicKey)
if !ok {
return nil, errors.New("given bytes aren't ECDSA public key")
}
result := PublicKey(*pk)
return &result, nil
}
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// decodeCompressedY performs decompression of Y coordinate for given X and Y's least significant bit.
// We use here a short-form Weierstrass curve (https://www.hyperelliptic.org/EFD/g1p/auto-shortw.html)
// y² = x³ + ax + b. Two types of elliptic curves are supported:
// 1. Secp256k1 (Koblitz curve): y² = x³ + b,
// 2. Secp256r1 (Random curve): y² = x³ - 3x + b.
// To decode compressed curve point we perform the following operation: y = sqrt(x³ + ax + b mod p)
// where `p` denotes the order of the underlying curve field.
func decodeCompressedY(x *big.Int, ylsb uint, curve elliptic.Curve) (*big.Int, error) {
var a *big.Int
switch curve.(type) {
case *btcec.KoblitzCurve:
a = big.NewInt(0)
default:
a = big.NewInt(3)
}
cp := curve.Params()
xCubed := new(big.Int).Exp(x, big.NewInt(3), cp.P)
aX := new(big.Int).Mul(x, a)
aX.Mod(aX, cp.P)
ySquared := new(big.Int).Sub(xCubed, aX)
ySquared.Add(ySquared, cp.B)
ySquared.Mod(ySquared, cp.P)
y := new(big.Int).ModSqrt(ySquared, cp.P)
if y == nil {
return nil, errors.New("error computing Y for compressed point")
}
if y.Bit(0) != ylsb {
y.Neg(y)
y.Mod(y, cp.P)
}
return y, nil
}
// DecodeBytes decodes a PublicKey from the given slice of bytes.
func (p *PublicKey) DecodeBytes(data []byte) error {
b := io.NewBinReaderFromBuf(data)
p.DecodeBinary(b)
if b.Err != nil {
return b.Err
}
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if b.Len() != 0 {
return errors.New("extra data")
}
return nil
}
// DecodeBinary decodes a PublicKey from the given BinReader using information
// about the EC curve to decompress Y point. Secp256r1 is a default value for EC curve.
func (p *PublicKey) DecodeBinary(r *io.BinReader) {
var prefix uint8
var x, y *big.Int
var err error
prefix = uint8(r.ReadB())
if r.Err != nil {
return
}
if p.Curve == nil {
p.Curve = elliptic.P256()
}
curve := p.Curve
curveParams := p.Params()
// Infinity
switch prefix {
case 0x00:
// noop, initialized to nil
return
case 0x02, 0x03:
// Compressed public keys
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xbytes := make([]byte, coordLen)
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r.ReadBytes(xbytes)
if r.Err != nil {
return
}
x = new(big.Int).SetBytes(xbytes)
ylsb := uint(prefix & 0x1)
y, err = decodeCompressedY(x, ylsb, curve)
if err != nil {
r.Err = err
return
}
case 0x04:
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xbytes := make([]byte, coordLen)
ybytes := make([]byte, coordLen)
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r.ReadBytes(xbytes)
r.ReadBytes(ybytes)
if r.Err != nil {
return
}
x = new(big.Int).SetBytes(xbytes)
y = new(big.Int).SetBytes(ybytes)
if !curve.IsOnCurve(x, y) {
r.Err = errors.New("encoded point is not on the P256 curve")
return
}
default:
r.Err = fmt.Errorf("invalid prefix %d", prefix)
return
}
if x.Cmp(curveParams.P) >= 0 || y.Cmp(curveParams.P) >= 0 {
r.Err = errors.New("enccoded point is not correct (X or Y is bigger than P")
return
}
p.X, p.Y = x, y
}
// EncodeBinary encodes a PublicKey to the given BinWriter.
func (p *PublicKey) EncodeBinary(w *io.BinWriter) {
w.WriteBytes(p.Bytes())
}
// GetVerificationScript returns NEO VM bytecode with CHECKSIG command for the
// public key.
func (p *PublicKey) GetVerificationScript() []byte {
b := p.Bytes()
buf := io.NewBufBinWriter()
if address.Prefix == address.NEO2Prefix {
buf.WriteB(0x21) // PUSHBYTES33
buf.WriteBytes(p.Bytes())
buf.WriteB(0xAC) // CHECKSIG
return buf.Bytes()
}
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emit.Bytes(buf.BinWriter, b)
emit.Syscall(buf.BinWriter, interopnames.SystemCryptoCheckSig)
return buf.Bytes()
}
// GetScriptHash returns a Hash160 of verification script for the key.
func (p *PublicKey) GetScriptHash() util.Uint160 {
return hash.Hash160(p.GetVerificationScript())
}
// Address returns a base58-encoded NEO-specific address based on the key hash.
func (p *PublicKey) Address() string {
return address.Uint160ToString(p.GetScriptHash())
}
// Verify returns true if the signature is valid and corresponds
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// to the hash and public key.
func (p *PublicKey) Verify(signature []byte, hash []byte) bool {
if p.X == nil || p.Y == nil || len(signature) != SignatureLen {
return false
}
rBytes := new(big.Int).SetBytes(signature[0:32])
sBytes := new(big.Int).SetBytes(signature[32:64])
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return ecdsa.Verify((*ecdsa.PublicKey)(p), hash, rBytes, sBytes)
}
// VerifyHashable returns true if the signature is valid and corresponds
// to the hash and public key.
func (p *PublicKey) VerifyHashable(signature []byte, net uint32, hh hash.Hashable) bool {
var digest = hash.NetSha256(net, hh)
return p.Verify(signature, digest[:])
}
// IsInfinity checks if the key is infinite (null, basically).
func (p *PublicKey) IsInfinity() bool {
return p.X == nil && p.Y == nil
}
// String implements the Stringer interface.
func (p *PublicKey) String() string {
if p.IsInfinity() {
return "00"
}
bx := hex.EncodeToString(p.X.Bytes())
by := hex.EncodeToString(p.Y.Bytes())
return fmt.Sprintf("%s%s", bx, by)
}
// MarshalJSON implements the json.Marshaler interface.
func (p PublicKey) MarshalJSON() ([]byte, error) {
return json.Marshal(hex.EncodeToString(p.Bytes()))
}
// UnmarshalJSON implements json.Unmarshaler interface.
func (p *PublicKey) UnmarshalJSON(data []byte) error {
l := len(data)
if l < 2 || data[0] != '"' || data[l-1] != '"' {
return errors.New("wrong format")
}
bytes := make([]byte, hex.DecodedLen(l-2))
_, err := hex.Decode(bytes, data[1:l-1])
if err != nil {
return err
}
err = p.DecodeBytes(bytes)
if err != nil {
return err
}
return nil
}