GCC Code Coverage Report
Directory: ./ Exec Total Coverage
File: lib/libcrypto/crypto/../../libssl/src/crypto/whrlpool/wp_dgst.c Lines: 0 105 0.0 %
Date: 2016-12-06 Branches: 0 56 0.0 %

Line Branch Exec Source
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/* $OpenBSD: wp_dgst.c,v 1.4 2014/07/12 11:25:25 miod Exp $ */
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/**
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 * The Whirlpool hashing function.
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 *
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 * <P>
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 * <b>References</b>
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 *
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 * <P>
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 * The Whirlpool algorithm was developed by
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 * <a href="mailto:pbarreto@scopus.com.br">Paulo S. L. M. Barreto</a> and
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 * <a href="mailto:vincent.rijmen@cryptomathic.com">Vincent Rijmen</a>.
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 *
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 * See
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 *      P.S.L.M. Barreto, V. Rijmen,
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 *      ``The Whirlpool hashing function,''
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 *      NESSIE submission, 2000 (tweaked version, 2001),
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 *      <https://www.cosic.esat.kuleuven.ac.be/nessie/workshop/submissions/whirlpool.zip>
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 *
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 * Based on "@version 3.0 (2003.03.12)" by Paulo S.L.M. Barreto and
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 * Vincent Rijmen. Lookup "reference implementations" on
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 * <http://planeta.terra.com.br/informatica/paulobarreto/>
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 *
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 * =============================================================================
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 *
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 * THIS SOFTWARE IS PROVIDED BY THE AUTHORS ''AS IS'' AND ANY EXPRESS
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 * OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
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 * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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 * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHORS OR CONTRIBUTORS BE
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 * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
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 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
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 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
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 * BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
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 * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
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 * OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
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 * EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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 *
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 */
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/*
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 * OpenSSL-specific implementation notes.
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 *
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 * WHIRLPOOL_Update as well as one-stroke WHIRLPOOL both expect
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 * number of *bytes* as input length argument. Bit-oriented routine
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 * as specified by authors is called WHIRLPOOL_BitUpdate[!] and
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 * does not have one-stroke counterpart.
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 *
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 * WHIRLPOOL_BitUpdate implements byte-oriented loop, essentially
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 * to serve WHIRLPOOL_Update. This is done for performance.
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 *
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 * Unlike authors' reference implementation, block processing
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 * routine whirlpool_block is designed to operate on multi-block
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 * input. This is done for performance.
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 */
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#include "wp_locl.h"
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#include <openssl/crypto.h>
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#include <string.h>
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int WHIRLPOOL_Init(WHIRLPOOL_CTX *c)
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	{
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	memset (c,0,sizeof(*c));
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	return(1);
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	}
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int WHIRLPOOL_Update	(WHIRLPOOL_CTX *c,const void *_inp,size_t bytes)
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	{
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	/* Well, largest suitable chunk size actually is
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	 * (1<<(sizeof(size_t)*8-3))-64, but below number
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	 * is large enough for not to care about excessive
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	 * calls to WHIRLPOOL_BitUpdate... */
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	size_t chunk = ((size_t)1)<<(sizeof(size_t)*8-4);
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	const unsigned char *inp = _inp;
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	while (bytes>=chunk)
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		{
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		WHIRLPOOL_BitUpdate(c,inp,chunk*8);
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		bytes -= chunk;
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		inp   += chunk;
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		}
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	if (bytes)
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		WHIRLPOOL_BitUpdate(c,inp,bytes*8);
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	return(1);
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	}
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void WHIRLPOOL_BitUpdate(WHIRLPOOL_CTX *c,const void *_inp,size_t bits)
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	{
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	size_t		n;
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	unsigned int	bitoff = c->bitoff,
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			bitrem = bitoff%8,
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			inpgap = (8-(unsigned int)bits%8)&7;
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	const unsigned char *inp=_inp;
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	/* This 256-bit increment procedure relies on the size_t
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	 * being natural size of CPU register, so that we don't
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	 * have to mask the value in order to detect overflows. */
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	c->bitlen[0] += bits;
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	if (c->bitlen[0] < bits)	/* overflow */
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		{
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		n = 1;
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		do  { 	c->bitlen[n]++;
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		    } while(c->bitlen[n]==0
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		   	    && ++n<(WHIRLPOOL_COUNTER/sizeof(size_t)));
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		}
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#ifndef OPENSSL_SMALL_FOOTPRINT
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	reconsider:
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	if (inpgap==0 && bitrem==0)	/* byte-oriented loop */
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		{
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		while (bits)
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			{
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			if (bitoff==0 && (n=bits/WHIRLPOOL_BBLOCK))
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				{
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				whirlpool_block(c,inp,n);
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				inp  += n*WHIRLPOOL_BBLOCK/8;
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				bits %= WHIRLPOOL_BBLOCK;
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				}
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			else
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				{
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				unsigned int byteoff = bitoff/8;
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				bitrem = WHIRLPOOL_BBLOCK - bitoff;/* re-use bitrem */
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				if (bits >= bitrem)
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					{
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					bits -= bitrem;
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					bitrem /= 8;
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					memcpy(c->data+byteoff,inp,bitrem);
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					inp  += bitrem;
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					whirlpool_block(c,c->data,1);
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					bitoff = 0;
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					}
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				else
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					{
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					memcpy(c->data+byteoff,inp,bits/8);
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					bitoff += (unsigned int)bits;
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					bits = 0;
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					}
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				c->bitoff = bitoff;
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				}
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			}
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		}
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	else				/* bit-oriented loop */
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#endif
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		{
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		/*
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			   inp
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			   |
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			   +-------+-------+-------
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			      |||||||||||||||||||||
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			   +-------+-------+-------
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		+-------+-------+-------+-------+-------
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		||||||||||||||				c->data
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		+-------+-------+-------+-------+-------
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			|
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			c->bitoff/8
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		*/
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		while (bits)
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			{
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			unsigned int	byteoff	= bitoff/8;
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			unsigned char	b;
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#ifndef OPENSSL_SMALL_FOOTPRINT
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			if (bitrem==inpgap)
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				{
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				c->data[byteoff++] |= inp[0] & (0xff>>inpgap);
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				inpgap = 8-inpgap;
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				bitoff += inpgap;  bitrem = 0;	/* bitoff%8 */
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				bits   -= inpgap;  inpgap = 0;	/* bits%8   */
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				inp++;
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				if (bitoff==WHIRLPOOL_BBLOCK)
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					{
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					whirlpool_block(c,c->data,1);
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					bitoff = 0;
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					}
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				c->bitoff = bitoff;
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				goto reconsider;
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				}
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			else
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#endif
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			if (bits>=8)
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				{
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				b  = ((inp[0]<<inpgap) | (inp[1]>>(8-inpgap)));
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				b &= 0xff;
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				if (bitrem)	c->data[byteoff++] |= b>>bitrem;
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				else		c->data[byteoff++]  = b;
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				bitoff += 8;
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				bits   -= 8;
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				inp++;
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				if (bitoff>=WHIRLPOOL_BBLOCK)
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					{
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					whirlpool_block(c,c->data,1);
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					byteoff  = 0;
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					bitoff  %= WHIRLPOOL_BBLOCK;
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					}
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				if (bitrem)	c->data[byteoff] = b<<(8-bitrem);
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				}
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			else	/* remaining less than 8 bits */
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				{
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				b = (inp[0]<<inpgap)&0xff;
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				if (bitrem)	c->data[byteoff++] |= b>>bitrem;
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				else		c->data[byteoff++]  = b;
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				bitoff += (unsigned int)bits;
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				if (bitoff==WHIRLPOOL_BBLOCK)
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					{
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					whirlpool_block(c,c->data,1);
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					byteoff  = 0;
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			        	bitoff  %= WHIRLPOOL_BBLOCK;
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					}
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				if (bitrem)	c->data[byteoff] = b<<(8-bitrem);
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				bits = 0;
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				}
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			c->bitoff = bitoff;
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			}
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		}
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	}
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int WHIRLPOOL_Final	(unsigned char *md,WHIRLPOOL_CTX *c)
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	{
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	unsigned int	bitoff  = c->bitoff,
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			byteoff = bitoff/8;
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	size_t		i,j,v;
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	unsigned char  *p;
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	bitoff %= 8;
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	if (bitoff)	c->data[byteoff] |= 0x80>>bitoff;
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	else		c->data[byteoff]  = 0x80;
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	byteoff++;
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	/* pad with zeros */
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	if (byteoff > (WHIRLPOOL_BBLOCK/8-WHIRLPOOL_COUNTER))
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		{
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		if (byteoff<WHIRLPOOL_BBLOCK/8)
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			memset(&c->data[byteoff],0,WHIRLPOOL_BBLOCK/8-byteoff);
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		whirlpool_block(c,c->data,1);
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		byteoff = 0;
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		}
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	if (byteoff < (WHIRLPOOL_BBLOCK/8-WHIRLPOOL_COUNTER))
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		memset(&c->data[byteoff],0,
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			(WHIRLPOOL_BBLOCK/8-WHIRLPOOL_COUNTER)-byteoff);
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	/* smash 256-bit c->bitlen in big-endian order */
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	p = &c->data[WHIRLPOOL_BBLOCK/8-1];	/* last byte in c->data */
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	for(i=0;i<WHIRLPOOL_COUNTER/sizeof(size_t);i++)
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		for(v=c->bitlen[i],j=0;j<sizeof(size_t);j++,v>>=8)
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			*p-- = (unsigned char)(v&0xff);
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	whirlpool_block(c,c->data,1);
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	if (md)	{
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		memcpy(md,c->H.c,WHIRLPOOL_DIGEST_LENGTH);
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		memset(c,0,sizeof(*c));
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		return(1);
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		}
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	return(0);
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	}
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unsigned char *WHIRLPOOL(const void *inp, size_t bytes,unsigned char *md)
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	{
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	WHIRLPOOL_CTX ctx;
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	static unsigned char m[WHIRLPOOL_DIGEST_LENGTH];
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	if (md == NULL) md=m;
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	WHIRLPOOL_Init(&ctx);
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	WHIRLPOOL_Update(&ctx,inp,bytes);
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	WHIRLPOOL_Final(md,&ctx);
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	return(md);
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	}