func TestBase58(t *testing.T) {
// Encode tests
for x, test := range stringTests {
tmp := []byte(test.in)
if res := base58.Encode(tmp); res != test.out {
t.Errorf("Encode test #%d failed: got: %s want: %s",
x, res, test.out)
continue
}
}
// Decode tests
for x, test := range hexTests {
b, err := hex.DecodeString(test.in)
if err != nil {
t.Errorf("hex.DecodeString failed failed #%d: got: %s", x, test.in)
continue
}
if res := base58.Decode(test.out); bytes.Equal(res, b) != true {
t.Errorf("Decode test #%d failed: got: %q want: %q",
x, res, test.in)
continue
}
}
// Decode with invalid input
for x, test := range invalidStringTests {
if res := base58.Decode(test.in); string(res) != test.out {
t.Errorf("Decode invalidString test #%d failed: got: %q want: %q",
x, res, test.out)
continue
}
}
}
// String returns the extended key as a human-readable base58-encoded string.
func (k *ExtendedKey) String() string {
if len(k.key) == 0 {
return "zeroed extended key"
}
var childNumBytes [4]byte
depthByte := byte(k.depth % 256)
binary.BigEndian.PutUint32(childNumBytes[:], k.childNum)
// The serialized format is:
// version (4) || depth (1) || parent fingerprint (4)) ||
// child num (4) || chain code (32) || key data (33) || checksum (4)
serializedBytes := make([]byte, 0, serializedKeyLen+4)
serializedBytes = append(serializedBytes, k.version...)
serializedBytes = append(serializedBytes, depthByte)
serializedBytes = append(serializedBytes, k.parentFP...)
serializedBytes = append(serializedBytes, childNumBytes[:]...)
serializedBytes = append(serializedBytes, k.chainCode...)
if k.isPrivate {
serializedBytes = append(serializedBytes, 0x00)
serializedBytes = append(serializedBytes, k.key...)
} else {
serializedBytes = append(serializedBytes, k.pubKeyBytes()...)
}
checkSum := wire.DoubleSha256(serializedBytes)[:4]
serializedBytes = append(serializedBytes, checkSum...)
return base58.Encode(serializedBytes)
}
func BenchmarkBase58Encode(b *testing.B) {
b.StopTimer()
data := bytes.Repeat([]byte{0xff}, 5000)
b.SetBytes(int64(len(data)))
b.StartTimer()
for i := 0; i < b.N; i++ {
base58.Encode(data)
}
}
// This example demonstrates how to encode data using the modified base58
// encoding scheme.
func ExampleEncode() {
// Encode example data with the modified base58 encoding scheme.
data := []byte("Test data")
encoded := base58.Encode(data)
// Show the encoded data.
fmt.Println("Encoded Data:", encoded)
// Output:
// Encoded Data: 25JnwSn7XKfNQ
}
// String creates the Wallet Import Format string encoding of a WIF structure.
// See DecodeWIF for a detailed breakdown of the format and requirements of
// a valid WIF string.
func (w *WIF) String() string {
// Precalculate size. Maximum number of bytes before base58 encoding
// is one byte for the network, 32 bytes of private key, possibly one
// extra byte if the pubkey is to be compressed, and finally four
// bytes of checksum.
encodeLen := 1 + btcec.PrivKeyBytesLen + 4
if w.CompressPubKey {
encodeLen++
}
a := make([]byte, 0, encodeLen)
a = append(a, w.netID)
// Pad and append bytes manually, instead of using Serialize, to
// avoid another call to make.
a = paddedAppend(btcec.PrivKeyBytesLen, a, w.PrivKey.D.Bytes())
if w.CompressPubKey {
a = append(a, compressMagic)
}
cksum := wire.DoubleSha256(a)[:4]
a = append(a, cksum...)
return base58.Encode(a)
}