neoneo-go/pkg/encoding/bigint/bigint.go

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package bigint
import (
"encoding/binary"
"math/big"
"math/bits"
)
const (
// MaxBytesLen is the maximum length of serialized integer suitable for Neo VM.
MaxBytesLen = 33 // 32 bytes for 256-bit integer plus 1 if padding needed
// wordSizeBytes is a size of a big.Word (uint) in bytes.`
wordSizeBytes = bits.UintSize / 8
)
// FromBytes converts data in little-endian format to
// an integer.
func FromBytes(data []byte) *big.Int {
n := new(big.Int)
size := len(data)
if size == 0 {
return big.NewInt(0)
}
isNeg := data[size-1]&0x80 != 0
size = getEffectiveSize(data, isNeg)
if size == 0 {
if isNeg {
return big.NewInt(-1)
}
return big.NewInt(0)
}
lw := size / wordSizeBytes
ws := make([]big.Word, lw+1)
for i := 0; i < lw; i++ {
base := i * wordSizeBytes
for j := base + 7; j >= base; j-- {
ws[i] <<= 8
ws[i] ^= big.Word(data[j])
}
}
for i := size - 1; i >= lw*wordSizeBytes; i-- {
ws[lw] <<= 8
ws[lw] ^= big.Word(data[i])
}
if isNeg {
for i := 0; i <= lw; i++ {
ws[i] = ^ws[i]
}
shift := byte(wordSizeBytes-size%wordSizeBytes) * 8
ws[lw] = ws[lw] & (^big.Word(0) >> shift)
n.SetBits(ws)
n.Neg(n)
return n.Sub(n, big.NewInt(1))
}
return n.SetBits(ws)
}
// getEffectiveSize returns minimal number of bytes required
// to represent a number (two's complement for negatives).
func getEffectiveSize(buf []byte, isNeg bool) int {
var b byte
if isNeg {
b = 0xFF
}
size := len(buf)
for ; size > 0; size-- {
if buf[size-1] != b {
break
}
}
return size
}
// ToBytes converts integer to a slice in little-endian format.
// Note: NEO3 serialization differs from default C# BigInteger.ToByteArray()
// when n == 0. For zero is equal to empty slice in NEO3.
// https://github.com/neo-project/neo-vm/blob/master/src/neo-vm/Types/Integer.cs#L16
func ToBytes(n *big.Int) []byte {
return ToPreallocatedBytes(n, []byte{})
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}
// ToPreallocatedBytes converts integer to a slice in little-endian format using given
// byte array for conversion result.
func ToPreallocatedBytes(n *big.Int, data []byte) []byte {
sign := n.Sign()
if sign == 0 {
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return data
}
var ws []big.Word
if sign == 1 {
ws = n.Bits()
} else {
n1 := new(big.Int).Add(n, big.NewInt(1))
if n1.Sign() == 0 { // n == -1
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return append(data, 0xFF)
}
ws = n1.Bits()
}
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lb := len(ws) * wordSizeBytes
if c := cap(data); c < lb {
data = make([]byte, lb, lb+1)
} else {
data = data[:lb]
}
data = wordsToBytes(ws, data)
size := len(data)
for ; data[size-1] == 0; size-- {
}
data = data[:size]
if data[size-1]&0x80 != 0 {
data = append(data, 0)
}
if sign == -1 {
for i := range data {
data[i] = ^data[i]
}
}
return data
}
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func wordsToBytes(ws []big.Word, bs []byte) []byte {
if wordSizeBytes == 8 {
for i := range ws {
binary.LittleEndian.PutUint64(bs[i*wordSizeBytes:], uint64(ws[i]))
}
} else {
for i := range ws {
binary.LittleEndian.PutUint32(bs[i*wordSizeBytes:], uint32(ws[i]))
}
}
return bs
}