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241 lines
6.3 KiB
Go
241 lines
6.3 KiB
Go
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// Copyright 2012 Jimmy Zelinskie. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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// Package whirlpool implements the ISO/IEC 10118-3:2004 whirlpool
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// cryptographic hash. Whirlpool is defined in
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// http://www.larc.usp.br/~pbarreto/WhirlpoolPage.html
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package whirlpool
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import (
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"encoding/binary"
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"hash"
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)
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// whirlpool represents the partial evaluation of a checksum.
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type whirlpool struct {
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bitLength [lengthBytes]byte // Number of hashed bits.
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buffer [wblockBytes]byte // Buffer of data to be hashed.
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bufferBits int // Current number of bits on the buffer.
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bufferPos int // Current byte location on buffer.
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hash [digestBytes / 8]uint64 // Hash state.
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}
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// New returns a new hash.Hash computing the whirlpool checksum.
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func New() hash.Hash {
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return new(whirlpool)
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}
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func (w *whirlpool) Reset() {
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// Cleanup the buffer.
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w.buffer = [wblockBytes]byte{}
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w.bufferBits = 0
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w.bufferPos = 0
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// Cleanup the digest.
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w.hash = [digestBytes / 8]uint64{}
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// Clean up the number of hashed bits.
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w.bitLength = [lengthBytes]byte{}
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}
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func (w *whirlpool) Size() int {
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return digestBytes
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}
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func (w *whirlpool) BlockSize() int {
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return wblockBytes
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}
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func (w *whirlpool) transform() {
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var (
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K [8]uint64 // Round key.
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block [8]uint64 // μ(buffer).
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state [8]uint64 // Cipher state.
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L [8]uint64
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)
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// Map the buffer to a block.
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for i := 0; i < 8; i++ {
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b := 8 * i
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block[i] = binary.BigEndian.Uint64(w.buffer[b:])
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}
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// Compute & apply K^0 to the cipher state.
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for i := 0; i < 8; i++ {
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K[i] = w.hash[i]
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state[i] = block[i] ^ K[i]
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}
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// Iterate over all the rounds.
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for r := 1; r <= rounds; r++ {
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// Compute K^rounds from K^(rounds-1).
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for i := 0; i < 8; i++ {
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L[i] = _C0[byte(K[i%8]>>56)] ^
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_C1[byte(K[(i+7)%8]>>48)] ^
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_C2[byte(K[(i+6)%8]>>40)] ^
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_C3[byte(K[(i+5)%8]>>32)] ^
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_C4[byte(K[(i+4)%8]>>24)] ^
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_C5[byte(K[(i+3)%8]>>16)] ^
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_C6[byte(K[(i+2)%8]>>8)] ^
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_C7[byte(K[(i+1)%8])]
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}
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L[0] ^= rc[r]
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for i := 0; i < 8; i++ {
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K[i] = L[i]
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}
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// Apply r-th round transformation.
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for i := 0; i < 8; i++ {
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L[i] = _C0[byte(state[i%8]>>56)] ^
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_C1[byte(state[(i+7)%8]>>48)] ^
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_C2[byte(state[(i+6)%8]>>40)] ^
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_C3[byte(state[(i+5)%8]>>32)] ^
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_C4[byte(state[(i+4)%8]>>24)] ^
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_C5[byte(state[(i+3)%8]>>16)] ^
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_C6[byte(state[(i+2)%8]>>8)] ^
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_C7[byte(state[(i+1)%8])] ^
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K[i%8]
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}
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for i := 0; i < 8; i++ {
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state[i] = L[i]
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}
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}
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// Apply the Miyaguchi-Preneel compression function.
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for i := 0; i < 8; i++ {
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w.hash[i] ^= state[i] ^ block[i]
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}
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}
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func (w *whirlpool) Write(source []byte) (int, error) {
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var (
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sourcePos int // Index of the leftmost source.
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nn int = len(source) // Num of bytes to process.
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sourceBits uint64 = uint64(nn * 8) // Num of bits to process.
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sourceGap uint = uint((8 - (int(sourceBits & 7))) & 7) // Space on source[sourcePos].
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bufferRem uint = uint(w.bufferBits & 7) // Occupied bits on buffer[bufferPos].
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b uint32 // Current byte.
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)
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// Tally the length of the data added.
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for i, carry, value := 31, uint32(0), uint64(sourceBits); i >= 0 && (carry != 0 || value != 0); i-- {
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carry += uint32(w.bitLength[i]) + (uint32(value & 0xff))
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w.bitLength[i] = byte(carry)
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carry >>= 8
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value >>= 8
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}
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// Process data in chunks of 8 bits.
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for sourceBits > 8 {
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// Take a byte form the source.
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b = uint32(((source[sourcePos] << sourceGap) & 0xff) |
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((source[sourcePos+1] & 0xff) >> (8 - sourceGap)))
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// Process this byte.
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w.buffer[w.bufferPos] |= uint8(b >> bufferRem)
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w.bufferPos++
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w.bufferBits += int(8 - bufferRem)
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if w.bufferBits == digestBits {
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// Process this block.
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w.transform()
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// Reset the buffer.
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w.bufferBits = 0
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w.bufferPos = 0
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}
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w.buffer[w.bufferPos] = byte(b << (8 - bufferRem))
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w.bufferBits += int(bufferRem)
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// Proceed to remaining data.
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sourceBits -= 8
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sourcePos++
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}
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// 0 <= sourceBits <= 8; All data leftover is in source[sourcePos].
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if sourceBits > 0 {
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b = uint32((source[sourcePos] << sourceGap) & 0xff) // The bits are left-justified.
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// Process the remaining bits.
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w.buffer[w.bufferPos] |= byte(b) >> bufferRem
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} else {
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b = 0
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}
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if uint64(bufferRem)+sourceBits < 8 {
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// The remaining data fits on the buffer[bufferPos].
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w.bufferBits += int(sourceBits)
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} else {
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// The buffer[bufferPos] is full.
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w.bufferPos++
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w.bufferBits += 8 - int(bufferRem) // bufferBits = 8*bufferPos
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sourceBits -= uint64(8 - bufferRem)
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// Now, 0 <= sourceBits <= 8; all data leftover is in source[sourcePos].
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if w.bufferBits == digestBits {
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// Process this data block.
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w.transform()
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// Reset buffer.
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w.bufferBits = 0
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w.bufferPos = 0
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}
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w.buffer[w.bufferPos] = byte(b << (8 - bufferRem))
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w.bufferBits += int(sourceBits)
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}
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return nn, nil
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}
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func (w *whirlpool) Sum(in []byte) []byte {
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// Copy the whirlpool so that the caller can keep summing.
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n := *w
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// Append a 1-bit.
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n.buffer[n.bufferPos] |= 0x80 >> (uint(n.bufferBits) & 7)
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n.bufferPos++
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// The remaining bits should be 0. Pad with 0s to be complete.
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if n.bufferPos > wblockBytes-lengthBytes {
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if n.bufferPos < wblockBytes {
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for i := 0; i < wblockBytes-n.bufferPos; i++ {
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n.buffer[n.bufferPos+i] = 0
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}
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}
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// Process this data block.
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n.transform()
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// Reset the buffer.
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n.bufferPos = 0
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}
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if n.bufferPos < wblockBytes-lengthBytes {
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for i := 0; i < (wblockBytes-lengthBytes)-n.bufferPos; i++ {
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n.buffer[n.bufferPos+i] = 0
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}
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}
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n.bufferPos = wblockBytes - lengthBytes
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// Append the bit length of the hashed data.
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for i := 0; i < lengthBytes; i++ {
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n.buffer[n.bufferPos+i] = n.bitLength[i]
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}
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// Process this data block.
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n.transform()
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// Return the final digest as []byte.
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var digest [digestBytes]byte
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for i := 0; i < digestBytes/8; i++ {
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digest[i*8] = byte(n.hash[i] >> 56)
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digest[i*8+1] = byte(n.hash[i] >> 48)
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digest[i*8+2] = byte(n.hash[i] >> 40)
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digest[i*8+3] = byte(n.hash[i] >> 32)
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digest[i*8+4] = byte(n.hash[i] >> 24)
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digest[i*8+5] = byte(n.hash[i] >> 16)
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digest[i*8+6] = byte(n.hash[i] >> 8)
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digest[i*8+7] = byte(n.hash[i])
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}
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return append(in, digest[:digestBytes]...)
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}
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