Utilities/cmlibrhash/librhash/sha3.c - third_party/cmake - Git at Google

 /* sha3.c - an implementation of Secure Hash Algorithm 3 (Keccak).
  * based on the
  * The Keccak SHA-3 submission. Submission to NIST (Round 3), 2011
  * by Guido Bertoni, Joan Daemen, Michaël Peeters and Gilles Van Assche
  *
  * Copyright: 2013 Aleksey Kravchenko <rhash.admin@gmail.com>
  *
  * Permission is hereby granted,  free of charge,  to any person  obtaining a
  * copy of this software and associated documentation files (the "Software"),
  * to deal in the Software without restriction,  including without limitation
  * the rights to  use, copy, modify,  merge, publish, distribute, sublicense,
  * and/or sell copies  of  the Software,  and to permit  persons  to whom the
  * Software is furnished to do so.
  *
  * This program  is  distributed  in  the  hope  that it will be useful,  but
  * WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
  * or FITNESS FOR A PARTICULAR PURPOSE.  Use this program  at  your own risk!
  */

 #include <assert.h>
 #include <string.h>
 #include "byte_order.h"
 #include "sha3.h"

 /* constants */
 #define NumberOfRounds 24

 /* SHA3 (Keccak) constants for 24 rounds */
 static uint64_t keccak_round_constants[NumberOfRounds] = {
 	I64(0x0000000000000001), I64(0x0000000000008082), I64(0x800000000000808A), I64(0x8000000080008000),
 	I64(0x000000000000808B), I64(0x0000000080000001), I64(0x8000000080008081), I64(0x8000000000008009),
 	I64(0x000000000000008A), I64(0x0000000000000088), I64(0x0000000080008009), I64(0x000000008000000A),
 	I64(0x000000008000808B), I64(0x800000000000008B), I64(0x8000000000008089), I64(0x8000000000008003),
 	I64(0x8000000000008002), I64(0x8000000000000080), I64(0x000000000000800A), I64(0x800000008000000A),
 	I64(0x8000000080008081), I64(0x8000000000008080), I64(0x0000000080000001), I64(0x8000000080008008)
 };

 /* Initializing a sha3 context for given number of output bits */
 static void rhash_keccak_init(sha3_ctx *ctx, unsigned bits)
 {
 	/* NB: The Keccak capacity parameter = bits * 2 */
 	unsigned rate = 1600 - bits * 2;

 	memset(ctx, 0, sizeof(sha3_ctx));
 	ctx->block_size = rate / 8;
 	assert(rate <= 1600 && (rate % 64) == 0);
 }

 /**
  * Initialize context before calculating hash.
  *
  * @param ctx context to initialize
  */
 void rhash_sha3_224_init(sha3_ctx *ctx)
 {
 	rhash_keccak_init(ctx, 224);
 }

 /**
  * Initialize context before calculating hash.
  *
  * @param ctx context to initialize
  */
 void rhash_sha3_256_init(sha3_ctx *ctx)
 {
 	rhash_keccak_init(ctx, 256);
 }

 /**
  * Initialize context before calculating hash.
  *
  * @param ctx context to initialize
  */
 void rhash_sha3_384_init(sha3_ctx *ctx)
 {
 	rhash_keccak_init(ctx, 384);
 }

 /**
  * Initialize context before calculating hash.
  *
  * @param ctx context to initialize
  */
 void rhash_sha3_512_init(sha3_ctx *ctx)
 {
 	rhash_keccak_init(ctx, 512);
 }

 /* Keccak theta() transformation */
 static void keccak_theta(uint64_t *A)
 {
 	unsigned int x;
 	uint64_t C[5], D[5];

 	for (x = 0; x < 5; x++) {
 		C[x] = A[x] ^ A[x + 5] ^ A[x + 10] ^ A[x + 15] ^ A[x + 20];
 	}
 	D[0] = ROTL64(C[1], 1) ^ C[4];
 	D[1] = ROTL64(C[2], 1) ^ C[0];
 	D[2] = ROTL64(C[3], 1) ^ C[1];
 	D[3] = ROTL64(C[4], 1) ^ C[2];
 	D[4] = ROTL64(C[0], 1) ^ C[3];

 	for (x = 0; x < 5; x++) {
 		A[x]      ^= D[x];
 		A[x + 5]  ^= D[x];
 		A[x + 10] ^= D[x];
 		A[x + 15] ^= D[x];
 		A[x + 20] ^= D[x];
 	}
 }

 /* Keccak pi() transformation */
 static void keccak_pi(uint64_t *A)
 {
 	uint64_t A1;
 	A1 = A[1];
 	A[ 1] = A[ 6];
 	A[ 6] = A[ 9];
 	A[ 9] = A[22];
 	A[22] = A[14];
 	A[14] = A[20];
 	A[20] = A[ 2];
 	A[ 2] = A[12];
 	A[12] = A[13];
 	A[13] = A[19];
 	A[19] = A[23];
 	A[23] = A[15];
 	A[15] = A[ 4];
 	A[ 4] = A[24];
 	A[24] = A[21];
 	A[21] = A[ 8];
 	A[ 8] = A[16];
 	A[16] = A[ 5];
 	A[ 5] = A[ 3];
 	A[ 3] = A[18];
 	A[18] = A[17];
 	A[17] = A[11];
 	A[11] = A[ 7];
 	A[ 7] = A[10];
 	A[10] = A1;
 	/* note: A[ 0] is left as is */
 }

 /* Keccak chi() transformation */
 static void keccak_chi(uint64_t *A)
 {
 	int i;
 	for (i = 0; i < 25; i += 5) {
 		uint64_t A0 = A[0 + i], A1 = A[1 + i];
 		A[0 + i] ^= ~A1 & A[2 + i];
 		A[1 + i] ^= ~A[2 + i] & A[3 + i];
 		A[2 + i] ^= ~A[3 + i] & A[4 + i];
 		A[3 + i] ^= ~A[4 + i] & A0;
 		A[4 + i] ^= ~A0 & A1;
 	}
 }

 static void rhash_sha3_permutation(uint64_t *state)
 {
 	int round;
 	for (round = 0; round < NumberOfRounds; round++)
 	{
 		keccak_theta(state);

 		/* apply Keccak rho() transformation */
 		state[ 1] = ROTL64(state[ 1],  1);
 		state[ 2] = ROTL64(state[ 2], 62);
 		state[ 3] = ROTL64(state[ 3], 28);
 		state[ 4] = ROTL64(state[ 4], 27);
 		state[ 5] = ROTL64(state[ 5], 36);
 		state[ 6] = ROTL64(state[ 6], 44);
 		state[ 7] = ROTL64(state[ 7],  6);
 		state[ 8] = ROTL64(state[ 8], 55);
 		state[ 9] = ROTL64(state[ 9], 20);
 		state[10] = ROTL64(state[10],  3);
 		state[11] = ROTL64(state[11], 10);
 		state[12] = ROTL64(state[12], 43);
 		state[13] = ROTL64(state[13], 25);
 		state[14] = ROTL64(state[14], 39);
 		state[15] = ROTL64(state[15], 41);
 		state[16] = ROTL64(state[16], 45);
 		state[17] = ROTL64(state[17], 15);
 		state[18] = ROTL64(state[18], 21);
 		state[19] = ROTL64(state[19],  8);
 		state[20] = ROTL64(state[20], 18);
 		state[21] = ROTL64(state[21],  2);
 		state[22] = ROTL64(state[22], 61);
 		state[23] = ROTL64(state[23], 56);
 		state[24] = ROTL64(state[24], 14);

 		keccak_pi(state);
 		keccak_chi(state);

 		/* apply iota(state, round) */
 		*state ^= keccak_round_constants[round];
 	}
 }

 /**
  * The core transformation. Process the specified block of data.
  *
  * @param hash the algorithm state
  * @param block the message block to process
  * @param block_size the size of the processed block in bytes
  */
 static void rhash_sha3_process_block(uint64_t hash[25], const uint64_t *block, size_t block_size)
 {
 	/* expanded loop */
 	hash[ 0] ^= le2me_64(block[ 0]);
 	hash[ 1] ^= le2me_64(block[ 1]);
 	hash[ 2] ^= le2me_64(block[ 2]);
 	hash[ 3] ^= le2me_64(block[ 3]);
 	hash[ 4] ^= le2me_64(block[ 4]);
 	hash[ 5] ^= le2me_64(block[ 5]);
 	hash[ 6] ^= le2me_64(block[ 6]);
 	hash[ 7] ^= le2me_64(block[ 7]);
 	hash[ 8] ^= le2me_64(block[ 8]);
 	/* if not sha3-512 */
 	if (block_size > 72) {
 		hash[ 9] ^= le2me_64(block[ 9]);
 		hash[10] ^= le2me_64(block[10]);
 		hash[11] ^= le2me_64(block[11]);
 		hash[12] ^= le2me_64(block[12]);
 		/* if not sha3-384 */
 		if (block_size > 104) {
 			hash[13] ^= le2me_64(block[13]);
 			hash[14] ^= le2me_64(block[14]);
 			hash[15] ^= le2me_64(block[15]);
 			hash[16] ^= le2me_64(block[16]);
 			/* if not sha3-256 */
 			if (block_size > 136) {
 				hash[17] ^= le2me_64(block[17]);
 #ifdef FULL_SHA3_FAMILY_SUPPORT
 				/* if not sha3-224 */
 				if (block_size > 144) {
 					hash[18] ^= le2me_64(block[18]);
 					hash[19] ^= le2me_64(block[19]);
 					hash[20] ^= le2me_64(block[20]);
 					hash[21] ^= le2me_64(block[21]);
 					hash[22] ^= le2me_64(block[22]);
 					hash[23] ^= le2me_64(block[23]);
 					hash[24] ^= le2me_64(block[24]);
 				}
 #endif
 			}
 		}
 	}
 	/* make a permutation of the hash */
 	rhash_sha3_permutation(hash);
 }

 #define SHA3_FINALIZED 0x80000000

 /**
  * Calculate message hash.
  * Can be called repeatedly with chunks of the message to be hashed.
  *
  * @param ctx the algorithm context containing current hashing state
  * @param msg message chunk
  * @param size length of the message chunk
  */
 void rhash_sha3_update(sha3_ctx *ctx, const unsigned char *msg, size_t size)
 {
 	size_t index = (size_t)ctx->rest;
 	size_t block_size = (size_t)ctx->block_size;

 	if (ctx->rest & SHA3_FINALIZED) return; /* too late for additional input */
 	ctx->rest = (unsigned)((ctx->rest + size) % block_size);

 	/* fill partial block */
 	if (index) {
 		size_t left = block_size - index;
 		memcpy((char*)ctx->message + index, msg, (size < left ? size : left));
 		if (size < left) return;

 		/* process partial block */
 		rhash_sha3_process_block(ctx->hash, ctx->message, block_size);
 		msg  += left;
 		size -= left;
 	}
 	while (size >= block_size) {
 		uint64_t* aligned_message_block;
 		if (IS_ALIGNED_64(msg)) {
 			/* the most common case is processing of an already aligned message
 			without copying it */
 			aligned_message_block = (uint64_t*)msg;
 		} else {
 			memcpy(ctx->message, msg, block_size);
 			aligned_message_block = ctx->message;
 		}

 		rhash_sha3_process_block(ctx->hash, aligned_message_block, block_size);
 		msg  += block_size;
 		size -= block_size;
 	}
 	if (size) {
 		memcpy(ctx->message, msg, size); /* save leftovers */
 	}
 }

 /**
  * Store calculated hash into the given array.
  *
  * @param ctx the algorithm context containing current hashing state
  * @param result calculated hash in binary form
  */
 void rhash_sha3_final(sha3_ctx *ctx, unsigned char* result)
 {
 	size_t digest_length = 100 - ctx->block_size / 2;
 	const size_t block_size = ctx->block_size;

 	if (!(ctx->rest & SHA3_FINALIZED))
 	{
 		/* clear the rest of the data queue */
 		memset((char*)ctx->message + ctx->rest, 0, block_size - ctx->rest);
 		((char*)ctx->message)[ctx->rest] |= 0x06;
 		((char*)ctx->message)[block_size - 1] |= 0x80;

 		/* process final block */
 		rhash_sha3_process_block(ctx->hash, ctx->message, block_size);
 		ctx->rest = SHA3_FINALIZED; /* mark context as finalized */
 	}

 	assert(block_size > digest_length);
 	if (result) me64_to_le_str(result, ctx->hash, digest_length);
 }

 #ifdef USE_KECCAK
 /**
 * Store calculated hash into the given array.
 *
 * @param ctx the algorithm context containing current hashing state
 * @param result calculated hash in binary form
 */
 void rhash_keccak_final(sha3_ctx *ctx, unsigned char* result)
 {
 	size_t digest_length = 100 - ctx->block_size / 2;
 	const size_t block_size = ctx->block_size;

 	if (!(ctx->rest & SHA3_FINALIZED))
 	{
 		/* clear the rest of the data queue */
 		memset((char*)ctx->message + ctx->rest, 0, block_size - ctx->rest);
 		((char*)ctx->message)[ctx->rest] |= 0x01;
 		((char*)ctx->message)[block_size - 1] |= 0x80;

 		/* process final block */
 		rhash_sha3_process_block(ctx->hash, ctx->message, block_size);
 		ctx->rest = SHA3_FINALIZED; /* mark context as finalized */
 	}

 	assert(block_size > digest_length);
 	if (result) me64_to_le_str(result, ctx->hash, digest_length);
 }
 #endif /* USE_KECCAK */
	/* sha3.c - an implementation of Secure Hash Algorithm 3 (Keccak).
	* based on the
	* The Keccak SHA-3 submission. Submission to NIST (Round 3), 2011
	* by Guido Bertoni, Joan Daemen, Michaël Peeters and Gilles Van Assche
	*
	* Copyright: 2013 Aleksey Kravchenko <rhash.admin@gmail.com>
	*
	* Permission is hereby granted, free of charge, to any person obtaining a
	* copy of this software and associated documentation files (the "Software"),
	* to deal in the Software without restriction, including without limitation
	* the rights to use, copy, modify, merge, publish, distribute, sublicense,
	* and/or sell copies of the Software, and to permit persons to whom the
	* Software is furnished to do so.
	*
	* This program is distributed in the hope that it will be useful, but
	* WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
	* or FITNESS FOR A PARTICULAR PURPOSE. Use this program at your own risk!
	*/

	#include <assert.h>
	#include <string.h>
	#include "byte_order.h"
	#include "sha3.h"

	/* constants */
	#define NumberOfRounds 24

	/* SHA3 (Keccak) constants for 24 rounds */
	static uint64_t keccak_round_constants[NumberOfRounds] = {
	I64(0x0000000000000001), I64(0x0000000000008082), I64(0x800000000000808A), I64(0x8000000080008000),
	I64(0x000000000000808B), I64(0x0000000080000001), I64(0x8000000080008081), I64(0x8000000000008009),
	I64(0x000000000000008A), I64(0x0000000000000088), I64(0x0000000080008009), I64(0x000000008000000A),
	I64(0x000000008000808B), I64(0x800000000000008B), I64(0x8000000000008089), I64(0x8000000000008003),
	I64(0x8000000000008002), I64(0x8000000000000080), I64(0x000000000000800A), I64(0x800000008000000A),
	I64(0x8000000080008081), I64(0x8000000000008080), I64(0x0000000080000001), I64(0x8000000080008008)
	};

	/* Initializing a sha3 context for given number of output bits */
	static void rhash_keccak_init(sha3_ctx *ctx, unsigned bits)
	{
	/* NB: The Keccak capacity parameter = bits * 2 */
	unsigned rate = 1600 - bits * 2;

	memset(ctx, 0, sizeof(sha3_ctx));
	ctx->block_size = rate / 8;
	assert(rate <= 1600 && (rate % 64) == 0);
	}

	/**
	* Initialize context before calculating hash.
	*
	* @param ctx context to initialize
	*/
	void rhash_sha3_224_init(sha3_ctx *ctx)
	{
	rhash_keccak_init(ctx, 224);
	}

	/**
	* Initialize context before calculating hash.
	*
	* @param ctx context to initialize
	*/
	void rhash_sha3_256_init(sha3_ctx *ctx)
	{
	rhash_keccak_init(ctx, 256);
	}

	/**
	* Initialize context before calculating hash.
	*
	* @param ctx context to initialize
	*/
	void rhash_sha3_384_init(sha3_ctx *ctx)
	{
	rhash_keccak_init(ctx, 384);
	}

	/**
	* Initialize context before calculating hash.
	*
	* @param ctx context to initialize
	*/
	void rhash_sha3_512_init(sha3_ctx *ctx)
	{
	rhash_keccak_init(ctx, 512);
	}

	/* Keccak theta() transformation */
	static void keccak_theta(uint64_t *A)
	{
	unsigned int x;
	uint64_t C[5], D[5];

	for (x = 0; x < 5; x++) {
	C[x] = A[x] ^ A[x + 5] ^ A[x + 10] ^ A[x + 15] ^ A[x + 20];
	}
	D[0] = ROTL64(C[1], 1) ^ C[4];
	D[1] = ROTL64(C[2], 1) ^ C[0];
	D[2] = ROTL64(C[3], 1) ^ C[1];
	D[3] = ROTL64(C[4], 1) ^ C[2];
	D[4] = ROTL64(C[0], 1) ^ C[3];

	for (x = 0; x < 5; x++) {
	A[x] ^= D[x];
	A[x + 5] ^= D[x];
	A[x + 10] ^= D[x];
	A[x + 15] ^= D[x];
	A[x + 20] ^= D[x];
	}
	}

	/* Keccak pi() transformation */
	static void keccak_pi(uint64_t *A)
	{
	uint64_t A1;
	A1 = A[1];
	A[ 1] = A[ 6];
	A[ 6] = A[ 9];
	A[ 9] = A[22];
	A[22] = A[14];
	A[14] = A[20];
	A[20] = A[ 2];
	A[ 2] = A[12];
	A[12] = A[13];
	A[13] = A[19];
	A[19] = A[23];
	A[23] = A[15];
	A[15] = A[ 4];
	A[ 4] = A[24];
	A[24] = A[21];
	A[21] = A[ 8];
	A[ 8] = A[16];
	A[16] = A[ 5];
	A[ 5] = A[ 3];
	A[ 3] = A[18];
	A[18] = A[17];
	A[17] = A[11];
	A[11] = A[ 7];
	A[ 7] = A[10];
	A[10] = A1;
	/* note: A[ 0] is left as is */
	}

	/* Keccak chi() transformation */
	static void keccak_chi(uint64_t *A)
	{
	int i;
	for (i = 0; i < 25; i += 5) {
	uint64_t A0 = A[0 + i], A1 = A[1 + i];
	A[0 + i] ^= ~A1 & A[2 + i];
	A[1 + i] ^= ~A[2 + i] & A[3 + i];
	A[2 + i] ^= ~A[3 + i] & A[4 + i];
	A[3 + i] ^= ~A[4 + i] & A0;
	A[4 + i] ^= ~A0 & A1;
	}
	}

	static void rhash_sha3_permutation(uint64_t *state)
	{
	int round;
	for (round = 0; round < NumberOfRounds; round++)
	{
	keccak_theta(state);

	/* apply Keccak rho() transformation */
	state[ 1] = ROTL64(state[ 1], 1);
	state[ 2] = ROTL64(state[ 2], 62);
	state[ 3] = ROTL64(state[ 3], 28);
	state[ 4] = ROTL64(state[ 4], 27);
	state[ 5] = ROTL64(state[ 5], 36);
	state[ 6] = ROTL64(state[ 6], 44);
	state[ 7] = ROTL64(state[ 7], 6);
	state[ 8] = ROTL64(state[ 8], 55);
	state[ 9] = ROTL64(state[ 9], 20);
	state[10] = ROTL64(state[10], 3);
	state[11] = ROTL64(state[11], 10);
	state[12] = ROTL64(state[12], 43);
	state[13] = ROTL64(state[13], 25);
	state[14] = ROTL64(state[14], 39);
	state[15] = ROTL64(state[15], 41);
	state[16] = ROTL64(state[16], 45);
	state[17] = ROTL64(state[17], 15);
	state[18] = ROTL64(state[18], 21);
	state[19] = ROTL64(state[19], 8);
	state[20] = ROTL64(state[20], 18);
	state[21] = ROTL64(state[21], 2);
	state[22] = ROTL64(state[22], 61);
	state[23] = ROTL64(state[23], 56);
	state[24] = ROTL64(state[24], 14);

	keccak_pi(state);
	keccak_chi(state);

	/* apply iota(state, round) */
	*state ^= keccak_round_constants[round];
	}
	}

	/**
	* The core transformation. Process the specified block of data.
	*
	* @param hash the algorithm state
	* @param block the message block to process
	* @param block_size the size of the processed block in bytes
	*/
	static void rhash_sha3_process_block(uint64_t hash[25], const uint64_t *block, size_t block_size)
	{
	/* expanded loop */
	hash[ 0] ^= le2me_64(block[ 0]);
	hash[ 1] ^= le2me_64(block[ 1]);
	hash[ 2] ^= le2me_64(block[ 2]);
	hash[ 3] ^= le2me_64(block[ 3]);
	hash[ 4] ^= le2me_64(block[ 4]);
	hash[ 5] ^= le2me_64(block[ 5]);
	hash[ 6] ^= le2me_64(block[ 6]);
	hash[ 7] ^= le2me_64(block[ 7]);
	hash[ 8] ^= le2me_64(block[ 8]);
	/* if not sha3-512 */
	if (block_size > 72) {
	hash[ 9] ^= le2me_64(block[ 9]);
	hash[10] ^= le2me_64(block[10]);
	hash[11] ^= le2me_64(block[11]);
	hash[12] ^= le2me_64(block[12]);
	/* if not sha3-384 */
	if (block_size > 104) {
	hash[13] ^= le2me_64(block[13]);
	hash[14] ^= le2me_64(block[14]);
	hash[15] ^= le2me_64(block[15]);
	hash[16] ^= le2me_64(block[16]);
	/* if not sha3-256 */
	if (block_size > 136) {
	hash[17] ^= le2me_64(block[17]);
	#ifdef FULL_SHA3_FAMILY_SUPPORT
	/* if not sha3-224 */
	if (block_size > 144) {
	hash[18] ^= le2me_64(block[18]);
	hash[19] ^= le2me_64(block[19]);
	hash[20] ^= le2me_64(block[20]);
	hash[21] ^= le2me_64(block[21]);
	hash[22] ^= le2me_64(block[22]);
	hash[23] ^= le2me_64(block[23]);
	hash[24] ^= le2me_64(block[24]);
	}
	#endif
	}
	}
	}
	/* make a permutation of the hash */
	rhash_sha3_permutation(hash);
	}

	#define SHA3_FINALIZED 0x80000000

	/**
	* Calculate message hash.
	* Can be called repeatedly with chunks of the message to be hashed.
	*
	* @param ctx the algorithm context containing current hashing state
	* @param msg message chunk
	* @param size length of the message chunk
	*/
	void rhash_sha3_update(sha3_ctx ctx, const unsigned char msg, size_t size)
	{
	size_t index = (size_t)ctx->rest;
	size_t block_size = (size_t)ctx->block_size;

	if (ctx->rest & SHA3_FINALIZED) return; /* too late for additional input */
	ctx->rest = (unsigned)((ctx->rest + size) % block_size);

	/* fill partial block */
	if (index) {
	size_t left = block_size - index;
	memcpy((char*)ctx->message + index, msg, (size < left ? size : left));
	if (size < left) return;

	/* process partial block */
	rhash_sha3_process_block(ctx->hash, ctx->message, block_size);
	msg += left;
	size -= left;
	}
	while (size >= block_size) {
	uint64_t* aligned_message_block;
	if (IS_ALIGNED_64(msg)) {
	/* the most common case is processing of an already aligned message
	without copying it */
	aligned_message_block = (uint64_t*)msg;
	} else {
	memcpy(ctx->message, msg, block_size);
	aligned_message_block = ctx->message;
	}

	rhash_sha3_process_block(ctx->hash, aligned_message_block, block_size);
	msg += block_size;
	size -= block_size;
	}
	if (size) {
	memcpy(ctx->message, msg, size); /* save leftovers */
	}
	}

	/**
	* Store calculated hash into the given array.
	*
	* @param ctx the algorithm context containing current hashing state
	* @param result calculated hash in binary form
	*/
	void rhash_sha3_final(sha3_ctx ctx, unsigned char result)
	{
	size_t digest_length = 100 - ctx->block_size / 2;
	const size_t block_size = ctx->block_size;

	if (!(ctx->rest & SHA3_FINALIZED))
	{
	/* clear the rest of the data queue */
	memset((char*)ctx->message + ctx->rest, 0, block_size - ctx->rest);
	((char*)ctx->message)[ctx->rest] \|= 0x06;
	((char*)ctx->message)[block_size - 1] \|= 0x80;

	/* process final block */
	rhash_sha3_process_block(ctx->hash, ctx->message, block_size);
	ctx->rest = SHA3_FINALIZED; /* mark context as finalized */
	}

	assert(block_size > digest_length);
	if (result) me64_to_le_str(result, ctx->hash, digest_length);
	}

	#ifdef USE_KECCAK
	/**
	* Store calculated hash into the given array.
	*
	* @param ctx the algorithm context containing current hashing state
	* @param result calculated hash in binary form
	*/
	void rhash_keccak_final(sha3_ctx ctx, unsigned char result)
	{
	size_t digest_length = 100 - ctx->block_size / 2;
	const size_t block_size = ctx->block_size;

	if (!(ctx->rest & SHA3_FINALIZED))
	{
	/* clear the rest of the data queue */
	memset((char*)ctx->message + ctx->rest, 0, block_size - ctx->rest);
	((char*)ctx->message)[ctx->rest] \|= 0x01;
	((char*)ctx->message)[block_size - 1] \|= 0x80;

	/* process final block */
	rhash_sha3_process_block(ctx->hash, ctx->message, block_size);
	ctx->rest = SHA3_FINALIZED; /* mark context as finalized */
	}

	assert(block_size > digest_length);
	if (result) me64_to_le_str(result, ctx->hash, digest_length);
	}
	#endif /* USE_KECCAK */