2015-04-10 00:13:35 +02:00
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// Copyright (c) 2015 The btcsuite developers
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// Use of this source code is governed by an ISC
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// license that can be found in the LICENSE file.
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package btcec
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import (
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"bytes"
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"crypto/aes"
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"crypto/cipher"
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"crypto/hmac"
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"crypto/rand"
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"crypto/sha256"
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"crypto/sha512"
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"errors"
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"io"
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)
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var (
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// ErrInvalidMAC occurs when Message Authentication Check (MAC) fails
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// during decryption. This happens because of either invalid private key or
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// corrupt ciphertext.
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ErrInvalidMAC = errors.New("invalid mac hash")
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// errInputTooShort occurs when the input ciphertext to the Decrypt
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// function is less than 134 bytes long.
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errInputTooShort = errors.New("ciphertext too short")
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// errUnsupportedCurve occurs when the first two bytes of the encrypted
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// text aren't 0x02CA (= 712 = secp256k1, from OpenSSL).
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errUnsupportedCurve = errors.New("unsupported curve")
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errInvalidXLength = errors.New("invalid X length, must be 32")
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errInvalidYLength = errors.New("invalid Y length, must be 32")
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errInvalidPadding = errors.New("invalid PKCS#7 padding")
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// 0x02CA = 714
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ciphCurveBytes = [2]byte{0x02, 0xCA}
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// 0x20 = 32
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ciphCoordLength = [2]byte{0x00, 0x20}
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)
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// GenerateSharedSecret generates a shared secret based on a private key and a
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// private key using Diffie-Hellman key exchange (ECDH) (RFC 4753).
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// RFC5903 Section 9 states we should only return x.
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func GenerateSharedSecret(privkey *PrivateKey, pubkey *PublicKey) []byte {
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x, _ := pubkey.Curve.ScalarMult(pubkey.X, pubkey.Y, privkey.D.Bytes())
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return x.Bytes()
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}
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// Encrypt encrypts data for the target public key using AES-256-CBC. It also
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// generates a private key (the pubkey of which is also in the output). The only
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// supported curve is secp256k1. The `structure' that it encodes everything into
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// is:
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//
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// struct {
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// // Initialization Vector used for AES-256-CBC
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// IV [16]byte
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// // Public Key: curve(2) + len_of_pubkeyX(2) + pubkeyX +
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// // len_of_pubkeyY(2) + pubkeyY (curve = 714)
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// PublicKey [70]byte
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// // Cipher text
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// Data []byte
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// // HMAC-SHA-256 Message Authentication Code
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// HMAC [32]byte
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// }
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//
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// The primary aim is to ensure byte compatibility with Pyelliptic. Additionaly,
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// refer to section 5.8.1 of ANSI X9.63 for rationale on this format.
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func Encrypt(pubkey *PublicKey, in []byte) ([]byte, error) {
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ephemeral, err := NewPrivateKey(S256())
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if err != nil {
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return nil, err
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}
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ecdhKey := GenerateSharedSecret(ephemeral, pubkey)
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derivedKey := sha512.Sum512(ecdhKey)
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keyE := derivedKey[:32]
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keyM := derivedKey[32:]
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paddedIn := addPKCSPadding(in)
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// IV + Curve params/X/Y + padded plaintext/ciphertext + HMAC-256
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out := make([]byte, aes.BlockSize+70+len(paddedIn)+sha256.Size)
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iv := out[:aes.BlockSize]
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if _, err = io.ReadFull(rand.Reader, iv); err != nil {
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return nil, err
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}
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// start writing public key
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pb := ephemeral.PubKey().SerializeUncompressed()
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offset := aes.BlockSize
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// curve and X length
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copy(out[offset:offset+4], append(ciphCurveBytes[:], ciphCoordLength[:]...))
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offset += 4
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// X
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copy(out[offset:offset+32], pb[1:33])
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offset += 32
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// Y length
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copy(out[offset:offset+2], ciphCoordLength[:])
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offset += 2
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// Y
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copy(out[offset:offset+32], pb[33:])
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offset += 32
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// start encryption
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block, err := aes.NewCipher(keyE)
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if err != nil {
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return nil, err
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}
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mode := cipher.NewCBCEncrypter(block, iv)
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mode.CryptBlocks(out[offset:len(out)-sha256.Size], paddedIn)
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// start HMAC-SHA-256
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hm := hmac.New(sha256.New, keyM)
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hm.Write(out[:len(out)-sha256.Size]) // everything is hashed
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copy(out[len(out)-sha256.Size:], hm.Sum(nil)) // write checksum
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return out, nil
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}
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// Decrypt decrypts data that was encrypted using the Encrypt function.
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func Decrypt(priv *PrivateKey, in []byte) ([]byte, error) {
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// IV + Curve params/X/Y + 1 block + HMAC-256
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if len(in) < aes.BlockSize+70+aes.BlockSize+sha256.Size {
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return nil, errInputTooShort
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}
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// read iv
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iv := in[:aes.BlockSize]
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offset := aes.BlockSize
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// start reading pubkey
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if !bytes.Equal(in[offset:offset+2], ciphCurveBytes[:]) {
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return nil, errUnsupportedCurve
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}
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offset += 2
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if !bytes.Equal(in[offset:offset+2], ciphCoordLength[:]) {
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return nil, errInvalidXLength
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}
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offset += 2
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xBytes := in[offset : offset+32]
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offset += 32
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if !bytes.Equal(in[offset:offset+2], ciphCoordLength[:]) {
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return nil, errInvalidYLength
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}
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offset += 2
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yBytes := in[offset : offset+32]
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offset += 32
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pb := make([]byte, 65)
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pb[0] = byte(0x04) // uncompressed
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copy(pb[1:33], xBytes)
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copy(pb[33:], yBytes)
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// check if (X, Y) lies on the curve and create a Pubkey if it does
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pubkey, err := ParsePubKey(pb, S256())
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if err != nil {
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return nil, err
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}
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// check for cipher text length
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if (len(in)-aes.BlockSize-offset-sha256.Size)%aes.BlockSize != 0 {
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return nil, errInvalidPadding // not padded to 16 bytes
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}
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// read hmac
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messageMAC := in[len(in)-sha256.Size:]
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// generate shared secret
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ecdhKey := GenerateSharedSecret(priv, pubkey)
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derivedKey := sha512.Sum512(ecdhKey)
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keyE := derivedKey[:32]
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keyM := derivedKey[32:]
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// verify mac
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hm := hmac.New(sha256.New, keyM)
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hm.Write(in[:len(in)-sha256.Size]) // everything is hashed
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expectedMAC := hm.Sum(nil)
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2015-05-25 13:12:43 +02:00
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if !hmac.Equal(messageMAC, expectedMAC) {
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2015-04-10 00:13:35 +02:00
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return nil, ErrInvalidMAC
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}
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// start decryption
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block, err := aes.NewCipher(keyE)
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if err != nil {
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return nil, err
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}
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mode := cipher.NewCBCDecrypter(block, iv)
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// same length as ciphertext
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plaintext := make([]byte, len(in)-offset-sha256.Size)
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mode.CryptBlocks(plaintext, in[offset:len(in)-sha256.Size])
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return removePKCSPadding(plaintext)
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}
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// Implement PKCS#7 padding with block size of 16 (AES block size).
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// addPKCSPadding adds padding to a block of data
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func addPKCSPadding(src []byte) []byte {
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padding := aes.BlockSize - len(src)%aes.BlockSize
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padtext := bytes.Repeat([]byte{byte(padding)}, padding)
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return append(src, padtext...)
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}
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// removePKCSPadding removes padding from data that was added with addPKCSPadding
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func removePKCSPadding(src []byte) ([]byte, error) {
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length := len(src)
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padLength := int(src[length-1])
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if padLength > aes.BlockSize || length < aes.BlockSize {
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return nil, errInvalidPadding
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}
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return src[:length-padLength], nil
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}
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