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/* sha1.c : Implementation of the Secure Hash Algorithm */
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/* SHA: NIST's Secure Hash Algorithm */
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/*	This version written November 2000 by David Ireland of 
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	DI Management Services Pty Limited <[email protected]>
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	Adapted from code in the Python Cryptography Toolkit, 
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	version 1.0.0 by A.M. Kuchling 1995.
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*/
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/* AM Kuchling's posting:- 
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   Based on SHA code originally posted to sci.crypt by Peter Gutmann
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   in message <[email protected]>.
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   Modified to test for endianness on creation of SHA objects by AMK.
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   Also, the original specification of SHA was found to have a weakness
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   by NSA/NIST.  This code implements the fixed version of SHA.
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*/
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/* Here's the first paragraph of Peter Gutmann's posting:
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The following is my SHA (FIPS 180) code updated to allow use of the "fixed"
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SHA, thanks to Jim Gillogly and an anonymous contributor for the information on
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what's changed in the new version.  The fix is a simple change which involves
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adding a single rotate in the initial expansion function.  It is unknown
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whether this is an optimal solution to the problem which was discovered in the
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SHA or whether it's simply a bandaid which fixes the problem with a minimum of
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effort (for example the reengineering of a great many Capstone chips).
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*/
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/* h files included here to make this just one file ... */
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/* global.h */
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/* sha.c */
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#include "SHA1.h"
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#include <stdio.h>
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#include <string.h>
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static void SHAtoByte(BYTE *output, const UINT4 *input, unsigned int len);
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/* The SHS block size and message digest sizes, in bytes */
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#define SHS_DATASIZE    64
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#define SHS_DIGESTSIZE  20
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/* The SHS f()-functions.  The f1 and f3 functions can be optimized to
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   save one boolean operation each - thanks to Rich Schroeppel,
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   [email protected] for discovering this */
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/*#define f1(x,y,z) ( ( x & y ) | ( ~x & z ) )          // Rounds  0-19 */
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#define f1(x,y,z)   ( z ^ ( x & ( y ^ z ) ) )           /* Rounds  0-19 */
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#define f2(x,y,z)   ( x ^ y ^ z )                       /* Rounds 20-39 */
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/*#define f3(x,y,z) ( ( x & y ) | ( x & z ) | ( y & z ) )   // Rounds 40-59 */
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#define f3(x,y,z)   ( ( x & y ) | ( z & ( x | y ) ) )   /* Rounds 40-59 */
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#define f4(x,y,z)   ( x ^ y ^ z )                       /* Rounds 60-79 */
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/* The SHS Mysterious Constants */
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#define K1  0x5A827999L                                 /* Rounds  0-19 */
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#define K2  0x6ED9EBA1L                                 /* Rounds 20-39 */
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#define K3  0x8F1BBCDCL                                 /* Rounds 40-59 */
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#define K4  0xCA62C1D6L                                 /* Rounds 60-79 */
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/* SHS initial values */
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#define h0init  0x67452301L
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#define h1init  0xEFCDAB89L
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#define h2init  0x98BADCFEL
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#define h3init  0x10325476L
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#define h4init  0xC3D2E1F0L
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/* Note that it may be necessary to add parentheses to these macros if they
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   are to be called with expressions as arguments */
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/* 32-bit rotate left - kludged with shifts */
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#define ROTL(n,X)  ( ( ( X ) << n ) | ( ( X ) >> ( 32 - n ) ) )
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/* The initial expanding function.  The hash function is defined over an
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   80-UINT2 expanded input array W, where the first 16 are copies of the input
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   data, and the remaining 64 are defined by
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        W[ i ] = W[ i - 16 ] ^ W[ i - 14 ] ^ W[ i - 8 ] ^ W[ i - 3 ]
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   This implementation generates these values on the fly in a circular
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   buffer - thanks to Colin Plumb, [email protected] for this
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   optimization.
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   The updated SHS changes the expanding function by adding a rotate of 1
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   bit.  Thanks to Jim Gillogly, [email protected], and an anonymous contributor
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   for this information */
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#define expand(W,i) ( W[ i & 15 ] = ROTL( 1, ( W[ i & 15 ] ^ W[ (i - 14) & 15 ] ^ \
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                                                 W[ (i - 8) & 15 ] ^ W[ (i - 3) & 15 ] ) ) )
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/* The prototype SHS sub-round.  The fundamental sub-round is:
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        a' = e + ROTL( 5, a ) + f( b, c, d ) + k + data;
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        b' = a;
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        c' = ROTL( 30, b );
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        d' = c;
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        e' = d;
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   but this is implemented by unrolling the loop 5 times and renaming the
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   variables ( e, a, b, c, d ) = ( a', b', c', d', e' ) each iteration.
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   This code is then replicated 20 times for each of the 4 functions, using
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   the next 20 values from the W[] array each time */
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#define subRound(a, b, c, d, e, f, k, data) \
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    ( e += ROTL( 5, a ) + f( b, c, d ) + k + data, b = ROTL( 30, b ) )
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/* Initialize the SHS values */
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void SHAInit(SHA_CTX *shsInfo)
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{
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    endianTest(&shsInfo->Endianness);
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    /* Set the h-vars to their initial values */
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    shsInfo->digest[ 0 ] = h0init;
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    shsInfo->digest[ 1 ] = h1init;
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    shsInfo->digest[ 2 ] = h2init;
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    shsInfo->digest[ 3 ] = h3init;
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    shsInfo->digest[ 4 ] = h4init;
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    /* Initialise bit count */
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    shsInfo->countLo = shsInfo->countHi = 0;
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}
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/* Perform the SHS transformation.  Note that this code, like MD5, seems to
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   break some optimizing compilers due to the complexity of the expressions
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   and the size of the basic block.  It may be necessary to split it into
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   sections, e.g. based on the four subrounds
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   Note that this corrupts the shsInfo->data area */
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static void SHSTransform( UINT4 *digest, UINT4 *data )
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{
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    UINT4 A, B, C, D, E;     /* Local vars */
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    UINT4 eData[ 16 ];       /* Expanded data */
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    /* Set up first buffer and local data buffer */
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    A = digest[ 0 ];
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    B = digest[ 1 ];
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    C = digest[ 2 ];
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    D = digest[ 3 ];
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    E = digest[ 4 ];
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    memcpy( (POINTER)eData, (POINTER)data, SHS_DATASIZE );
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    /* Heavy mangling, in 4 sub-rounds of 20 interations each. */
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    subRound( A, B, C, D, E, f1, K1, eData[  0 ] );
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    subRound( E, A, B, C, D, f1, K1, eData[  1 ] );
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    subRound( D, E, A, B, C, f1, K1, eData[  2 ] );
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    subRound( C, D, E, A, B, f1, K1, eData[  3 ] );
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    subRound( B, C, D, E, A, f1, K1, eData[  4 ] );
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    subRound( A, B, C, D, E, f1, K1, eData[  5 ] );
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    subRound( E, A, B, C, D, f1, K1, eData[  6 ] );
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    subRound( D, E, A, B, C, f1, K1, eData[  7 ] );
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    subRound( C, D, E, A, B, f1, K1, eData[  8 ] );
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    subRound( B, C, D, E, A, f1, K1, eData[  9 ] );
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    subRound( A, B, C, D, E, f1, K1, eData[ 10 ] );
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    subRound( E, A, B, C, D, f1, K1, eData[ 11 ] );
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    subRound( D, E, A, B, C, f1, K1, eData[ 12 ] );
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    subRound( C, D, E, A, B, f1, K1, eData[ 13 ] );
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    subRound( B, C, D, E, A, f1, K1, eData[ 14 ] );
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    subRound( A, B, C, D, E, f1, K1, eData[ 15 ] );
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    subRound( E, A, B, C, D, f1, K1, expand( eData, 16 ) );
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    subRound( D, E, A, B, C, f1, K1, expand( eData, 17 ) );
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    subRound( C, D, E, A, B, f1, K1, expand( eData, 18 ) );
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    subRound( B, C, D, E, A, f1, K1, expand( eData, 19 ) );
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    subRound( A, B, C, D, E, f2, K2, expand( eData, 20 ) );
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    subRound( E, A, B, C, D, f2, K2, expand( eData, 21 ) );
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    subRound( D, E, A, B, C, f2, K2, expand( eData, 22 ) );
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    subRound( C, D, E, A, B, f2, K2, expand( eData, 23 ) );
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    subRound( B, C, D, E, A, f2, K2, expand( eData, 24 ) );
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    subRound( A, B, C, D, E, f2, K2, expand( eData, 25 ) );
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    subRound( E, A, B, C, D, f2, K2, expand( eData, 26 ) );
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    subRound( D, E, A, B, C, f2, K2, expand( eData, 27 ) );
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    subRound( C, D, E, A, B, f2, K2, expand( eData, 28 ) );
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    subRound( B, C, D, E, A, f2, K2, expand( eData, 29 ) );
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    subRound( A, B, C, D, E, f2, K2, expand( eData, 30 ) );
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    subRound( E, A, B, C, D, f2, K2, expand( eData, 31 ) );
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    subRound( D, E, A, B, C, f2, K2, expand( eData, 32 ) );
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    subRound( C, D, E, A, B, f2, K2, expand( eData, 33 ) );
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    subRound( B, C, D, E, A, f2, K2, expand( eData, 34 ) );
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    subRound( A, B, C, D, E, f2, K2, expand( eData, 35 ) );
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    subRound( E, A, B, C, D, f2, K2, expand( eData, 36 ) );
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    subRound( D, E, A, B, C, f2, K2, expand( eData, 37 ) );
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    subRound( C, D, E, A, B, f2, K2, expand( eData, 38 ) );
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    subRound( B, C, D, E, A, f2, K2, expand( eData, 39 ) );
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    subRound( A, B, C, D, E, f3, K3, expand( eData, 40 ) );
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    subRound( E, A, B, C, D, f3, K3, expand( eData, 41 ) );
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    subRound( D, E, A, B, C, f3, K3, expand( eData, 42 ) );
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    subRound( C, D, E, A, B, f3, K3, expand( eData, 43 ) );
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    subRound( B, C, D, E, A, f3, K3, expand( eData, 44 ) );
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    subRound( A, B, C, D, E, f3, K3, expand( eData, 45 ) );
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    subRound( E, A, B, C, D, f3, K3, expand( eData, 46 ) );
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    subRound( D, E, A, B, C, f3, K3, expand( eData, 47 ) );
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    subRound( C, D, E, A, B, f3, K3, expand( eData, 48 ) );
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    subRound( B, C, D, E, A, f3, K3, expand( eData, 49 ) );
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    subRound( A, B, C, D, E, f3, K3, expand( eData, 50 ) );
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    subRound( E, A, B, C, D, f3, K3, expand( eData, 51 ) );
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    subRound( D, E, A, B, C, f3, K3, expand( eData, 52 ) );
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    subRound( C, D, E, A, B, f3, K3, expand( eData, 53 ) );
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    subRound( B, C, D, E, A, f3, K3, expand( eData, 54 ) );
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    subRound( A, B, C, D, E, f3, K3, expand( eData, 55 ) );
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    subRound( E, A, B, C, D, f3, K3, expand( eData, 56 ) );
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    subRound( D, E, A, B, C, f3, K3, expand( eData, 57 ) );
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    subRound( C, D, E, A, B, f3, K3, expand( eData, 58 ) );
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    subRound( B, C, D, E, A, f3, K3, expand( eData, 59 ) );
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    subRound( A, B, C, D, E, f4, K4, expand( eData, 60 ) );
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    subRound( E, A, B, C, D, f4, K4, expand( eData, 61 ) );
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    subRound( D, E, A, B, C, f4, K4, expand( eData, 62 ) );
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    subRound( C, D, E, A, B, f4, K4, expand( eData, 63 ) );
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    subRound( B, C, D, E, A, f4, K4, expand( eData, 64 ) );
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    subRound( A, B, C, D, E, f4, K4, expand( eData, 65 ) );
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    subRound( E, A, B, C, D, f4, K4, expand( eData, 66 ) );
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    subRound( D, E, A, B, C, f4, K4, expand( eData, 67 ) );
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    subRound( C, D, E, A, B, f4, K4, expand( eData, 68 ) );
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    subRound( B, C, D, E, A, f4, K4, expand( eData, 69 ) );
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    subRound( A, B, C, D, E, f4, K4, expand( eData, 70 ) );
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    subRound( E, A, B, C, D, f4, K4, expand( eData, 71 ) );
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    subRound( D, E, A, B, C, f4, K4, expand( eData, 72 ) );
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    subRound( C, D, E, A, B, f4, K4, expand( eData, 73 ) );
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    subRound( B, C, D, E, A, f4, K4, expand( eData, 74 ) );
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    subRound( A, B, C, D, E, f4, K4, expand( eData, 75 ) );
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    subRound( E, A, B, C, D, f4, K4, expand( eData, 76 ) );
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    subRound( D, E, A, B, C, f4, K4, expand( eData, 77 ) );
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    subRound( C, D, E, A, B, f4, K4, expand( eData, 78 ) );
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    subRound( B, C, D, E, A, f4, K4, expand( eData, 79 ) );
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    /* Build message digest */
240
    digest[ 0 ] += A;
241
    digest[ 1 ] += B;
242
    digest[ 2 ] += C;
243
    digest[ 3 ] += D;
244
    digest[ 4 ] += E;
245
    }
246

247
/* When run on a little-endian CPU we need to perform byte reversal on an
248
   array of long words. */
249

250
static void longReverse(UINT4 *buffer, int byteCount, int Endianness )
251
{
252
    UINT4 value;
253

254
    if (Endianness==TRUE) return;
255
    byteCount /= sizeof( UINT4 );
256
    while( byteCount-- )
257
        {
258
        value = *buffer;
259
        value = ( ( value & 0xFF00FF00L ) >> 8  ) | \
260
                ( ( value & 0x00FF00FFL ) << 8 );
261
        *buffer++ = ( value << 16 ) | ( value >> 16 );
262
        }
263
}
264

265
/* Update SHS for a block of data */
266

267
void SHAUpdate(SHA_CTX *shsInfo, const BYTE *buffer, int count)
268
{
269
    UINT4 tmp;
270
    int dataCount;
271

272
    /* Update bitcount */
273
    tmp = shsInfo->countLo;
274
    if ( ( shsInfo->countLo = tmp + ( ( UINT4 ) count << 3 ) ) < tmp )
275
        shsInfo->countHi++;             /* Carry from low to high */
276
    shsInfo->countHi += count >> 29;
277

278
    /* Get count of bytes already in data */
279
    dataCount = ( int ) ( tmp >> 3 ) & 0x3F;
280

281
    /* Handle any leading odd-sized chunks */
282
    if( dataCount )
283
        {
284
        BYTE *p = ( BYTE * ) shsInfo->data + dataCount;
285

286
        dataCount = SHS_DATASIZE - dataCount;
287
        if( count < dataCount )
288
            {
289
            memcpy( p, buffer, count );
290
            return;
291
            }
292
        memcpy( p, buffer, dataCount );
293
        longReverse( shsInfo->data, SHS_DATASIZE, shsInfo->Endianness);
294
        SHSTransform( shsInfo->digest, shsInfo->data );
295
        buffer += dataCount;
296
        count -= dataCount;
297
        }
298

299
    /* Process data in SHS_DATASIZE chunks */
300
    while( count >= SHS_DATASIZE )
301
        {
302
        memcpy( (POINTER)shsInfo->data, (CONST_POINTER)buffer, SHS_DATASIZE );
303
        longReverse( shsInfo->data, SHS_DATASIZE, shsInfo->Endianness );
304
        SHSTransform( shsInfo->digest, shsInfo->data );
305
        buffer += SHS_DATASIZE;
306
        count -= SHS_DATASIZE;
307
        }
308

309
    /* Handle any remaining bytes of data. */
310
    memcpy( (POINTER)shsInfo->data, (CONST_POINTER)buffer, count );
311
    }
312

313
/* Final wrapup - pad to SHS_DATASIZE-byte boundary with the bit pattern
314
   1 0* (64-bit count of bits processed, MSB-first) */
315

316
void SHAFinal(BYTE *output, SHA_CTX *shsInfo)
317
{
318
    int count;
319
    BYTE *dataPtr;
320

321
    /* Compute number of bytes mod 64 */
322
    count = ( int ) shsInfo->countLo;
323
    count = ( count >> 3 ) & 0x3F;
324

325
    /* Set the first char of padding to 0x80.  This is safe since there is
326
       always at least one byte free */
327
    dataPtr = ( BYTE * ) shsInfo->data + count;
328
    *dataPtr++ = 0x80;
329

330
    /* Bytes of padding needed to make 64 bytes */
331
    count = SHS_DATASIZE - 1 - count;
332

333
    /* Pad out to 56 mod 64 */
334
    if( count < 8 )
335
        {
336
        /* Two lots of padding:  Pad the first block to 64 bytes */
337
        memset( dataPtr, 0, count );
338
        longReverse( shsInfo->data, SHS_DATASIZE, shsInfo->Endianness );
339
        SHSTransform( shsInfo->digest, shsInfo->data );
340

341
        /* Now fill the next block with 56 bytes */
342
        memset( (POINTER)shsInfo->data, 0, SHS_DATASIZE - 8 );
343
        }
344
    else
345
        /* Pad block to 56 bytes */
346
        memset( dataPtr, 0, count - 8 );
347

348
    /* Append length in bits and transform */
349
    shsInfo->data[ 14 ] = shsInfo->countHi;
350
    shsInfo->data[ 15 ] = shsInfo->countLo;
351

352
    longReverse( shsInfo->data, SHS_DATASIZE - 8, shsInfo->Endianness );
353
    SHSTransform( shsInfo->digest, shsInfo->data );
354

355
	/* Output to an array of bytes */
356
	SHAtoByte(output, shsInfo->digest, SHS_DIGESTSIZE);
357

358
	/* Zeroise sensitive stuff */
359
	memset((POINTER)shsInfo, 0, sizeof(*shsInfo));
360
}
361

362
static void SHAtoByte(BYTE *output, const UINT4 *input, unsigned int len)
363
{	/* Output SHA digest in byte array */
364
	unsigned int i, j;
365

366
	for(i = 0, j = 0; j < len; i++, j += 4) 
367
	{
368
        output[j+3] = (BYTE)( input[i]        & 0xff);
369
        output[j+2] = (BYTE)((input[i] >> 8 ) & 0xff);
370
        output[j+1] = (BYTE)((input[i] >> 16) & 0xff);
371
        output[j  ] = (BYTE)((input[i] >> 24) & 0xff);
372
	}
373
}
374

375

376

377

378
/* endian.c */
379

380
void endianTest(int *endian_ness)
381
{
382
	if((*(unsigned short *) ("#S") >> 8) == '#')
383
	{
384
		/* printf("Big endian = no change\n"); */
385
		*endian_ness = !(0);
386
	}
387
	else
388
	{
389
		/* printf("Little endian = swap\n"); */
390
		*endian_ness = 0;
391
	}
392
}
393

394