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df79080e5f
2002-02-06 Adam Megacz <adam@xwt.org> * shs.h, shs.cc, natSimpleSHSStream.cc: use uint<n>_t instead of LONG and BYTE From-SVN: r49565
285 lines
8.5 KiB
C++
285 lines
8.5 KiB
C++
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/* --------------------------------- SHS.CC ------------------------------- */
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/*
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* NIST proposed Secure Hash Standard.
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*
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* Written 2 September 1992, Peter C. Gutmann.
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* This implementation placed in the public domain.
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*
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* Comments to pgut1@cs.aukuni.ac.nz
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*/
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// Force C++ compiler to use Java-style EH, so we don't have to link with
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// libstdc++.
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#pragma GCC java_exceptions
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#include <string.h>
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#include "shs.h"
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/* The SHS f()-functions */
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#define f1(x,y,z) ( ( x & y ) | ( ~x & 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 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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/* 32-bit rotate - kludged with shifts */
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#define S(n,X) ((X << n) | (X >> (32 - n)))
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/* The initial expanding function */
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#define expand(count) W [count] = W [count - 3] ^ W [count - 8] ^ W [count - 14] ^ W [count - 16]
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/* The four SHS sub-rounds */
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#define subRound1(count) \
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{ \
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temp = S (5, A) + f1 (B, C, D) + E + W [count] + K1; \
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E = D; \
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D = C; \
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C = S (30, B); \
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B = A; \
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A = temp; \
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}
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#define subRound2(count) \
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{ \
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temp = S (5, A) + f2 (B, C, D) + E + W [count] + K2; \
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E = D; \
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D = C; \
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C = S (30, B); \
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B = A; \
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A = temp; \
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}
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#define subRound3(count) \
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{ \
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temp = S (5, A) + f3 (B, C, D) + E + W [count] + K3; \
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E = D; \
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D = C; \
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C = S (30, B); \
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B = A; \
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A = temp; \
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}
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#define subRound4(count) \
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{ \
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temp = S (5, A) + f4 (B, C, D) + E + W [count] + K4; \
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E = D; \
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D = C; \
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C = S (30, B); \
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B = A; \
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A = temp; \
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}
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/* The two buffers of 5 32-bit words */
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uint32_t h0, h1, h2, h3, h4;
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uint32_t A, B, C, D, E;
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local void byteReverse OF((uint32_t *buffer, int byteCount));
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void shsTransform OF((SHS_INFO *shsInfo));
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/* Initialize the SHS values */
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void shsInit (SHS_INFO *shsInfo)
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{
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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 = 0L;
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}
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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 - it may be necessary to split it into
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* sections, eg based on the four subrounds
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*/
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void shsTransform (SHS_INFO *shsInfo)
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{
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uint32_t W [80], temp;
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int i;
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/* Step A. Copy the data buffer into the local work buffer */
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for (i = 0; i < 16; i++)
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W [i] = shsInfo->data [i];
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/* Step B. Expand the 16 words into 64 temporary data words */
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expand (16); expand (17); expand (18); expand (19); expand (20);
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expand (21); expand (22); expand (23); expand (24); expand (25);
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expand (26); expand (27); expand (28); expand (29); expand (30);
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expand (31); expand (32); expand (33); expand (34); expand (35);
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expand (36); expand (37); expand (38); expand (39); expand (40);
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expand (41); expand (42); expand (43); expand (44); expand (45);
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expand (46); expand (47); expand (48); expand (49); expand (50);
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expand (51); expand (52); expand (53); expand (54); expand (55);
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expand (56); expand (57); expand (58); expand (59); expand (60);
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expand (61); expand (62); expand (63); expand (64); expand (65);
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expand (66); expand (67); expand (68); expand (69); expand (70);
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expand (71); expand (72); expand (73); expand (74); expand (75);
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expand (76); expand (77); expand (78); expand (79);
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/* Step C. Set up first buffer */
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A = shsInfo->digest [0];
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B = shsInfo->digest [1];
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C = shsInfo->digest [2];
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D = shsInfo->digest [3];
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E = shsInfo->digest [4];
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/* Step D. Serious mangling, divided into four sub-rounds */
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subRound1 (0); subRound1 (1); subRound1 (2); subRound1 (3);
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subRound1 (4); subRound1 (5); subRound1 (6); subRound1 (7);
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subRound1 (8); subRound1 (9); subRound1 (10); subRound1 (11);
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subRound1 (12); subRound1 (13); subRound1 (14); subRound1 (15);
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subRound1 (16); subRound1 (17); subRound1 (18); subRound1 (19);
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subRound2 (20); subRound2 (21); subRound2 (22); subRound2 (23);
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subRound2 (24); subRound2 (25); subRound2 (26); subRound2 (27);
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subRound2 (28); subRound2 (29); subRound2 (30); subRound2 (31);
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subRound2 (32); subRound2 (33); subRound2 (34); subRound2 (35);
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subRound2 (36); subRound2 (37); subRound2 (38); subRound2 (39);
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subRound3 (40); subRound3 (41); subRound3 (42); subRound3 (43);
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subRound3 (44); subRound3 (45); subRound3 (46); subRound3 (47);
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subRound3 (48); subRound3 (49); subRound3 (50); subRound3 (51);
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subRound3 (52); subRound3 (53); subRound3 (54); subRound3 (55);
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subRound3 (56); subRound3 (57); subRound3 (58); subRound3 (59);
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subRound4 (60); subRound4 (61); subRound4 (62); subRound4 (63);
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subRound4 (64); subRound4 (65); subRound4 (66); subRound4 (67);
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subRound4 (68); subRound4 (69); subRound4 (70); subRound4 (71);
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subRound4 (72); subRound4 (73); subRound4 (74); subRound4 (75);
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subRound4 (76); subRound4 (77); subRound4 (78); subRound4 (79);
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/* Step E. Build message digest */
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shsInfo->digest [0] += A;
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shsInfo->digest [1] += B;
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shsInfo->digest [2] += C;
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shsInfo->digest [3] += D;
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shsInfo->digest [4] += E;
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}
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local void byteReverse (uint32_t *buffer, int byteCount)
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{
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uint32_t value;
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int count;
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/*
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* Find out what the byte order is on this machine.
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* Big endian is for machines that place the most significant byte
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* first (eg. Sun SPARC). Little endian is for machines that place
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* the least significant byte first (eg. VAX).
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*
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* We figure out the byte order by stuffing a 2 byte string into a
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* short and examining the left byte. '@' = 0x40 and 'P' = 0x50
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* If the left byte is the 'high' byte, then it is 'big endian'.
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* If the left byte is the 'low' byte, then the machine is 'little
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* endian'.
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*
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* -- Shawn A. Clifford (sac@eng.ufl.edu)
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*/
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/*
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* Several bugs fixed -- Pat Myrto (pat@rwing.uucp)
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*/
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if ((*(unsigned short *) ("@P") >> 8) == '@')
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return;
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byteCount /= sizeof (uint32_t);
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for (count = 0; count < byteCount; count++) {
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value = (buffer [count] << 16) | (buffer [count] >> 16);
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buffer [count] = ((value & 0xFF00FF00L) >> 8) | ((value & 0x00FF00FFL) << 8);
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}
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}
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/*
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* Update SHS for a block of data. This code assumes that the buffer size is
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* a multiple of SHS_BLOCKSIZE bytes long, which makes the code a lot more
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* efficient since it does away with the need to handle partial blocks
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* between calls to shsUpdate()
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*/
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void shsUpdate (SHS_INFO *shsInfo, uint8_t *buffer, int count)
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{
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/* Update bitcount */
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if ((shsInfo->countLo + ((uint32_t) count << 3)) < shsInfo->countLo)
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shsInfo->countHi++; /* Carry from low to high bitCount */
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shsInfo->countLo += ((uint32_t) count << 3);
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shsInfo->countHi += ((uint32_t) count >> 29);
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/* Process data in SHS_BLOCKSIZE chunks */
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while (count >= SHS_BLOCKSIZE) {
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memcpy (shsInfo->data, buffer, SHS_BLOCKSIZE);
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byteReverse (shsInfo->data, SHS_BLOCKSIZE);
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shsTransform (shsInfo);
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buffer += SHS_BLOCKSIZE;
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count -= SHS_BLOCKSIZE;
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}
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/*
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* Handle any remaining bytes of data.
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* This should only happen once on the final lot of data
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*/
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memcpy (shsInfo->data, buffer, count);
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}
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void shsFinal (SHS_INFO *shsInfo)
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{
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int count;
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uint32_t lowBitcount = shsInfo->countLo, highBitcount = shsInfo->countHi;
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/* Compute number of bytes mod 64 */
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count = (int) ((shsInfo->countLo >> 3) & 0x3F);
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/*
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* Set the first char of padding to 0x80.
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* This is safe since there is always at least one byte free
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*/
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((uint8_t *) shsInfo->data) [count++] = 0x80;
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/* Pad out to 56 mod 64 */
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if (count > 56) {
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/* Two lots of padding: Pad the first block to 64 bytes */
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memset ((uint8_t *) shsInfo->data + count, 0, 64 - count);
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byteReverse (shsInfo->data, SHS_BLOCKSIZE);
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shsTransform (shsInfo);
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/* Now fill the next block with 56 bytes */
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memset (shsInfo->data, 0, 56);
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} else
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/* Pad block to 56 bytes */
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memset ((uint8_t *) shsInfo->data + count, 0, 56 - count);
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byteReverse (shsInfo->data, SHS_BLOCKSIZE);
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/* Append length in bits and transform */
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shsInfo->data [14] = highBitcount;
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shsInfo->data [15] = lowBitcount;
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shsTransform (shsInfo);
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byteReverse (shsInfo->data, SHS_DIGESTSIZE);
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}
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