src/third_party/openssl/openssl/engines/ccgost/gosthash.c - cobalt - Git at Google

 /**********************************************************************
  *                          gosthash.c                                *
  *             Copyright (c) 2005-2006 Cryptocom LTD                  *
  *         This file is distributed under the same license as OpenSSL *
  *                                                                    *
  *    Implementation of GOST R 34.11-94 hash function                 *
  *       uses on gost89.c and gost89.h Doesn't need OpenSSL           *
  **********************************************************************/
 #include <string.h>

 #include "gost89.h"
 #include "gosthash.h"

 /*
  * Use OPENSSL_malloc for memory allocation if compiled with
  * -DOPENSSL_BUILD, and libc malloc otherwise
  */
 #ifndef MYALLOC
 # ifdef OPENSSL_BUILD
 #  include <openssl/crypto.h>
 #  define MYALLOC(size) OPENSSL_malloc(size)
 #  define MYFREE(ptr) OPENSSL_free(ptr)
 # else
 #  define MYALLOC(size) malloc(size)
 #  define MYFREE(ptr) free(ptr)
 # endif
 #endif
 /*
  * Following functions are various bit meshing routines used in GOST R
  * 34.11-94 algorithms
  */
 static void swap_bytes(byte * w, byte * k)
 {
     int i, j;
     for (i = 0; i < 4; i++)
         for (j = 0; j < 8; j++)
             k[i + 4 * j] = w[8 * i + j];

 }

 /* was A_A */
 static void circle_xor8(const byte * w, byte * k)
 {
     byte buf[8];
     int i;
     memcpy(buf, w, 8);
     memmove(k, w + 8, 24);
     for (i = 0; i < 8; i++)
         k[i + 24] = buf[i] ^ k[i];
 }

 /* was R_R */
 static void transform_3(byte * data)
 {
     unsigned short int acc;
     acc = (data[0] ^ data[2] ^ data[4] ^ data[6] ^ data[24] ^ data[30]) |
         ((data[1] ^ data[3] ^ data[5] ^ data[7] ^ data[25] ^ data[31]) << 8);
     memmove(data, data + 2, 30);
     data[30] = acc & 0xff;
     data[31] = acc >> 8;
 }

 /* Adds blocks of N bytes modulo 2**(8*n). Returns carry*/
 static int add_blocks(int n, byte * left, const byte * right)
 {
     int i;
     int carry = 0;
     int sum;
     for (i = 0; i < n; i++) {
         sum = (int)left[i] + (int)right[i] + carry;
         left[i] = sum & 0xff;
         carry = sum >> 8;
     }
     return carry;
 }

 /* Xor two sequences of bytes */
 static void xor_blocks(byte * result, const byte * a, const byte * b,
                        size_t len)
 {
     size_t i;
     for (i = 0; i < len; i++)
         result[i] = a[i] ^ b[i];
 }

 /*
  *      Calculate H(i+1) = Hash(Hi,Mi)
  *      Where H and M are 32 bytes long
  */
 static int hash_step(gost_ctx * c, byte * H, const byte * M)
 {
     byte U[32], W[32], V[32], S[32], Key[32];
     int i;
     /* Compute first key */
     xor_blocks(W, H, M, 32);
     swap_bytes(W, Key);
     /* Encrypt first 8 bytes of H with first key */
     gost_enc_with_key(c, Key, H, S);
     /* Compute second key */
     circle_xor8(H, U);
     circle_xor8(M, V);
     circle_xor8(V, V);
     xor_blocks(W, U, V, 32);
     swap_bytes(W, Key);
     /* encrypt second 8 bytes of H with second key */
     gost_enc_with_key(c, Key, H + 8, S + 8);
     /* compute third key */
     circle_xor8(U, U);
     U[31] = ~U[31];
     U[29] = ~U[29];
     U[28] = ~U[28];
     U[24] = ~U[24];
     U[23] = ~U[23];
     U[20] = ~U[20];
     U[18] = ~U[18];
     U[17] = ~U[17];
     U[14] = ~U[14];
     U[12] = ~U[12];
     U[10] = ~U[10];
     U[8] = ~U[8];
     U[7] = ~U[7];
     U[5] = ~U[5];
     U[3] = ~U[3];
     U[1] = ~U[1];
     circle_xor8(V, V);
     circle_xor8(V, V);
     xor_blocks(W, U, V, 32);
     swap_bytes(W, Key);
     /* encrypt third 8 bytes of H with third key */
     gost_enc_with_key(c, Key, H + 16, S + 16);
     /* Compute fourth key */
     circle_xor8(U, U);
     circle_xor8(V, V);
     circle_xor8(V, V);
     xor_blocks(W, U, V, 32);
     swap_bytes(W, Key);
     /* Encrypt last 8 bytes with fourth key */
     gost_enc_with_key(c, Key, H + 24, S + 24);
     for (i = 0; i < 12; i++)
         transform_3(S);
     xor_blocks(S, S, M, 32);
     transform_3(S);
     xor_blocks(S, S, H, 32);
     for (i = 0; i < 61; i++)
         transform_3(S);
     memcpy(H, S, 32);
     return 1;
 }

 /*
  * Initialize gost_hash ctx - cleans up temporary structures and set up
  * substitution blocks
  */
 int init_gost_hash_ctx(gost_hash_ctx * ctx,
                        const gost_subst_block * subst_block)
 {
     memset(ctx, 0, sizeof(gost_hash_ctx));
     ctx->cipher_ctx = (gost_ctx *) MYALLOC(sizeof(gost_ctx));
     if (!ctx->cipher_ctx) {
         return 0;
     }
     gost_init(ctx->cipher_ctx, subst_block);
     return 1;
 }

 /*
  * Free cipher CTX if it is dynamically allocated. Do not use
  * if cipher ctx is statically allocated as in OpenSSL implementation of
  * GOST hash algroritm
  *
  */
 void done_gost_hash_ctx(gost_hash_ctx * ctx)
 {
     /*
      * No need to use gost_destroy, because cipher keys are not really secret
      * when hashing
      */
     MYFREE(ctx->cipher_ctx);
 }

 /*
  * reset state of hash context to begin hashing new message
  */
 int start_hash(gost_hash_ctx * ctx)
 {
     if (!ctx->cipher_ctx)
         return 0;
     memset(&(ctx->H), 0, 32);
     memset(&(ctx->S), 0, 32);
     ctx->len = 0L;
     ctx->left = 0;
     return 1;
 }

 /*
  * Hash block of arbitrary length
  *
  *
  */
 int hash_block(gost_hash_ctx * ctx, const byte * block, size_t length)
 {
     if (ctx->left) {
         /*
          * There are some bytes from previous step
          */
         unsigned int add_bytes = 32 - ctx->left;
         if (add_bytes > length) {
             add_bytes = length;
         }
         memcpy(&(ctx->remainder[ctx->left]), block, add_bytes);
         ctx->left += add_bytes;
         if (ctx->left < 32) {
             return 1;
         }
         block += add_bytes;
         length -= add_bytes;
         hash_step(ctx->cipher_ctx, ctx->H, ctx->remainder);
         add_blocks(32, ctx->S, ctx->remainder);
         ctx->len += 32;
         ctx->left = 0;
     }
     while (length >= 32) {
         hash_step(ctx->cipher_ctx, ctx->H, block);

         add_blocks(32, ctx->S, block);
         ctx->len += 32;
         block += 32;
         length -= 32;
     }
     if (length) {
         memcpy(ctx->remainder, block, ctx->left = length);
     }
     return 1;
 }

 /*
  * Compute hash value from current state of ctx
  * state of hash ctx becomes invalid and cannot be used for further
  * hashing.
  */
 int finish_hash(gost_hash_ctx * ctx, byte * hashval)
 {
     byte buf[32];
     byte H[32];
     byte S[32];
     ghosthash_len fin_len = ctx->len;
     byte *bptr;
     memcpy(H, ctx->H, 32);
     memcpy(S, ctx->S, 32);
     if (ctx->left) {
         memset(buf, 0, 32);
         memcpy(buf, ctx->remainder, ctx->left);
         hash_step(ctx->cipher_ctx, H, buf);
         add_blocks(32, S, buf);
         fin_len += ctx->left;
     }
     memset(buf, 0, 32);
     bptr = buf;
     fin_len <<= 3;              /* Hash length in BITS!! */
     while (fin_len > 0) {
         *(bptr++) = (byte) (fin_len & 0xFF);
         fin_len >>= 8;
     };
     hash_step(ctx->cipher_ctx, H, buf);
     hash_step(ctx->cipher_ctx, H, S);
     memcpy(hashval, H, 32);
     return 1;
 }
	/**********************************************************************
	* gosthash.c *
	* Copyright (c) 2005-2006 Cryptocom LTD *
	* This file is distributed under the same license as OpenSSL *
	* *
	* Implementation of GOST R 34.11-94 hash function *
	* uses on gost89.c and gost89.h Doesn't need OpenSSL *
	**********************************************************************/
	#include <string.h>

	#include "gost89.h"
	#include "gosthash.h"

	/*
	* Use OPENSSL_malloc for memory allocation if compiled with
	* -DOPENSSL_BUILD, and libc malloc otherwise
	*/
	#ifndef MYALLOC
	# ifdef OPENSSL_BUILD
	# include <openssl/crypto.h>
	# define MYALLOC(size) OPENSSL_malloc(size)
	# define MYFREE(ptr) OPENSSL_free(ptr)
	# else
	# define MYALLOC(size) malloc(size)
	# define MYFREE(ptr) free(ptr)
	# endif
	#endif
	/*
	* Following functions are various bit meshing routines used in GOST R
	* 34.11-94 algorithms
	*/
	static void swap_bytes(byte * w, byte * k)
	{
	int i, j;
	for (i = 0; i < 4; i++)
	for (j = 0; j < 8; j++)
	k[i + 4 * j] = w[8 * i + j];

	}

	/* was A_A */
	static void circle_xor8(const byte * w, byte * k)
	{
	byte buf[8];
	int i;
	memcpy(buf, w, 8);
	memmove(k, w + 8, 24);
	for (i = 0; i < 8; i++)
	k[i + 24] = buf[i] ^ k[i];
	}

	/* was R_R */
	static void transform_3(byte * data)
	{
	unsigned short int acc;
	acc = (data[0] ^ data[2] ^ data[4] ^ data[6] ^ data[24] ^ data[30]) \|
	((data[1] ^ data[3] ^ data[5] ^ data[7] ^ data[25] ^ data[31]) << 8);
	memmove(data, data + 2, 30);
	data[30] = acc & 0xff;
	data[31] = acc >> 8;
	}

	/* Adds blocks of N bytes modulo 2*(8n). Returns carry*/
	static int add_blocks(int n, byte * left, const byte * right)
	{
	int i;
	int carry = 0;
	int sum;
	for (i = 0; i < n; i++) {
	sum = (int)left[i] + (int)right[i] + carry;
	left[i] = sum & 0xff;
	carry = sum >> 8;
	}
	return carry;
	}

	/* Xor two sequences of bytes */
	static void xor_blocks(byte * result, const byte * a, const byte * b,
	size_t len)
	{
	size_t i;
	for (i = 0; i < len; i++)
	result[i] = a[i] ^ b[i];
	}

	/*
	* Calculate H(i+1) = Hash(Hi,Mi)
	* Where H and M are 32 bytes long
	*/
	static int hash_step(gost_ctx * c, byte * H, const byte * M)
	{
	byte U[32], W[32], V[32], S[32], Key[32];
	int i;
	/* Compute first key */
	xor_blocks(W, H, M, 32);
	swap_bytes(W, Key);
	/* Encrypt first 8 bytes of H with first key */
	gost_enc_with_key(c, Key, H, S);
	/* Compute second key */
	circle_xor8(H, U);
	circle_xor8(M, V);
	circle_xor8(V, V);
	xor_blocks(W, U, V, 32);
	swap_bytes(W, Key);
	/* encrypt second 8 bytes of H with second key */
	gost_enc_with_key(c, Key, H + 8, S + 8);
	/* compute third key */
	circle_xor8(U, U);
	U[31] = ~U[31];
	U[29] = ~U[29];
	U[28] = ~U[28];
	U[24] = ~U[24];
	U[23] = ~U[23];
	U[20] = ~U[20];
	U[18] = ~U[18];
	U[17] = ~U[17];
	U[14] = ~U[14];
	U[12] = ~U[12];
	U[10] = ~U[10];
	U[8] = ~U[8];
	U[7] = ~U[7];
	U[5] = ~U[5];
	U[3] = ~U[3];
	U[1] = ~U[1];
	circle_xor8(V, V);
	circle_xor8(V, V);
	xor_blocks(W, U, V, 32);
	swap_bytes(W, Key);
	/* encrypt third 8 bytes of H with third key */
	gost_enc_with_key(c, Key, H + 16, S + 16);
	/* Compute fourth key */
	circle_xor8(U, U);
	circle_xor8(V, V);
	circle_xor8(V, V);
	xor_blocks(W, U, V, 32);
	swap_bytes(W, Key);
	/* Encrypt last 8 bytes with fourth key */
	gost_enc_with_key(c, Key, H + 24, S + 24);
	for (i = 0; i < 12; i++)
	transform_3(S);
	xor_blocks(S, S, M, 32);
	transform_3(S);
	xor_blocks(S, S, H, 32);
	for (i = 0; i < 61; i++)
	transform_3(S);
	memcpy(H, S, 32);
	return 1;
	}

	/*
	* Initialize gost_hash ctx - cleans up temporary structures and set up
	* substitution blocks
	*/
	int init_gost_hash_ctx(gost_hash_ctx * ctx,
	const gost_subst_block * subst_block)
	{
	memset(ctx, 0, sizeof(gost_hash_ctx));
	ctx->cipher_ctx = (gost_ctx *) MYALLOC(sizeof(gost_ctx));
	if (!ctx->cipher_ctx) {
	return 0;
	}
	gost_init(ctx->cipher_ctx, subst_block);
	return 1;
	}

	/*
	* Free cipher CTX if it is dynamically allocated. Do not use
	* if cipher ctx is statically allocated as in OpenSSL implementation of
	* GOST hash algroritm
	*
	*/
	void done_gost_hash_ctx(gost_hash_ctx * ctx)
	{
	/*
	* No need to use gost_destroy, because cipher keys are not really secret
	* when hashing
	*/
	MYFREE(ctx->cipher_ctx);
	}

	/*
	* reset state of hash context to begin hashing new message
	*/
	int start_hash(gost_hash_ctx * ctx)
	{
	if (!ctx->cipher_ctx)
	return 0;
	memset(&(ctx->H), 0, 32);
	memset(&(ctx->S), 0, 32);
	ctx->len = 0L;
	ctx->left = 0;
	return 1;
	}

	/*
	* Hash block of arbitrary length
	*
	*
	*/
	int hash_block(gost_hash_ctx * ctx, const byte * block, size_t length)
	{
	if (ctx->left) {
	/*
	* There are some bytes from previous step
	*/
	unsigned int add_bytes = 32 - ctx->left;
	if (add_bytes > length) {
	add_bytes = length;
	}
	memcpy(&(ctx->remainder[ctx->left]), block, add_bytes);
	ctx->left += add_bytes;
	if (ctx->left < 32) {
	return 1;
	}
	block += add_bytes;
	length -= add_bytes;
	hash_step(ctx->cipher_ctx, ctx->H, ctx->remainder);
	add_blocks(32, ctx->S, ctx->remainder);
	ctx->len += 32;
	ctx->left = 0;
	}
	while (length >= 32) {
	hash_step(ctx->cipher_ctx, ctx->H, block);

	add_blocks(32, ctx->S, block);
	ctx->len += 32;
	block += 32;
	length -= 32;
	}
	if (length) {
	memcpy(ctx->remainder, block, ctx->left = length);
	}
	return 1;
	}

	/*
	* Compute hash value from current state of ctx
	* state of hash ctx becomes invalid and cannot be used for further
	* hashing.
	*/
	int finish_hash(gost_hash_ctx * ctx, byte * hashval)
	{
	byte buf[32];
	byte H[32];
	byte S[32];
	ghosthash_len fin_len = ctx->len;
	byte *bptr;
	memcpy(H, ctx->H, 32);
	memcpy(S, ctx->S, 32);
	if (ctx->left) {
	memset(buf, 0, 32);
	memcpy(buf, ctx->remainder, ctx->left);
	hash_step(ctx->cipher_ctx, H, buf);
	add_blocks(32, S, buf);
	fin_len += ctx->left;
	}
	memset(buf, 0, 32);
	bptr = buf;
	fin_len <<= 3; /* Hash length in BITS!! */
	while (fin_len > 0) {
	*(bptr++) = (byte) (fin_len & 0xFF);
	fin_len >>= 8;
	};
	hash_step(ctx->cipher_ctx, H, buf);
	hash_step(ctx->cipher_ctx, H, S);
	memcpy(hashval, H, 32);
	return 1;
	}