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text data bss dec hex filename 1021988 559 5052 1027599 fae0f busybox_old 1021236 559 5052 1026847 fab1f busybox_unstripped Signed-off-by: Denys Vlasenko <vda.linux@googlemail.com>
1469 lines
39 KiB
C
1469 lines
39 KiB
C
/* vi: set sw=4 ts=4: */
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/*
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* Utility routines.
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*
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* Copyright (C) 2010 Denys Vlasenko
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*
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* Licensed under GPLv2 or later, see file LICENSE in this source tree.
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*/
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#include "libbb.h"
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#define NEED_SHA512 (ENABLE_SHA512SUM || ENABLE_USE_BB_CRYPT_SHA)
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/* gcc 4.2.1 optimizes rotr64 better with inline than with macro
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* (for rotX32, there is no difference). Why? My guess is that
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* macro requires clever common subexpression elimination heuristics
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* in gcc, while inline basically forces it to happen.
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*/
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//#define rotl32(x,n) (((x) << (n)) | ((x) >> (32 - (n))))
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static ALWAYS_INLINE uint32_t rotl32(uint32_t x, unsigned n)
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{
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return (x << n) | (x >> (32 - n));
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}
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//#define rotr32(x,n) (((x) >> (n)) | ((x) << (32 - (n))))
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static ALWAYS_INLINE uint32_t rotr32(uint32_t x, unsigned n)
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{
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return (x >> n) | (x << (32 - n));
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}
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/* rotr64 in needed for sha512 only: */
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//#define rotr64(x,n) (((x) >> (n)) | ((x) << (64 - (n))))
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static ALWAYS_INLINE uint64_t rotr64(uint64_t x, unsigned n)
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{
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return (x >> n) | (x << (64 - n));
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}
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/* rotl64 only used for sha3 currently */
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static ALWAYS_INLINE uint64_t rotl64(uint64_t x, unsigned n)
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{
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return (x << n) | (x >> (64 - n));
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}
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/* Process the remaining bytes in the buffer */
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static void FAST_FUNC common64_end(md5_ctx_t *ctx, int swap_needed)
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{
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unsigned bufpos = ctx->total64 & 63;
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/* Pad the buffer to the next 64-byte boundary with 0x80,0,0,0... */
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ctx->wbuffer[bufpos++] = 0x80;
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/* This loop iterates either once or twice, no more, no less */
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while (1) {
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unsigned remaining = 64 - bufpos;
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memset(ctx->wbuffer + bufpos, 0, remaining);
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/* Do we have enough space for the length count? */
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if (remaining >= 8) {
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/* Store the 64-bit counter of bits in the buffer */
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uint64_t t = ctx->total64 << 3;
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if (swap_needed)
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t = bb_bswap_64(t);
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/* wbuffer is suitably aligned for this */
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*(bb__aliased_uint64_t *) (&ctx->wbuffer[64 - 8]) = t;
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}
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ctx->process_block(ctx);
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if (remaining >= 8)
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break;
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bufpos = 0;
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}
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}
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/*
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* Compute MD5 checksum of strings according to the
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* definition of MD5 in RFC 1321 from April 1992.
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*
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* Written by Ulrich Drepper <drepper@gnu.ai.mit.edu>, 1995.
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*
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* Copyright (C) 1995-1999 Free Software Foundation, Inc.
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* Copyright (C) 2001 Manuel Novoa III
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* Copyright (C) 2003 Glenn L. McGrath
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* Copyright (C) 2003 Erik Andersen
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*
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* Licensed under GPLv2 or later, see file LICENSE in this source tree.
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*/
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/* 0: fastest, 3: smallest */
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#if CONFIG_MD5_SMALL < 0
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# define MD5_SMALL 0
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#elif CONFIG_MD5_SMALL > 3
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# define MD5_SMALL 3
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#else
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# define MD5_SMALL CONFIG_MD5_SMALL
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#endif
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/* These are the four functions used in the four steps of the MD5 algorithm
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* and defined in the RFC 1321. The first function is a little bit optimized
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* (as found in Colin Plumbs public domain implementation).
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* #define FF(b, c, d) ((b & c) | (~b & d))
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*/
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#undef FF
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#undef FG
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#undef FH
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#undef FI
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#define FF(b, c, d) (d ^ (b & (c ^ d)))
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#define FG(b, c, d) FF(d, b, c)
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#define FH(b, c, d) (b ^ c ^ d)
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#define FI(b, c, d) (c ^ (b | ~d))
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/* Hash a single block, 64 bytes long and 4-byte aligned */
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static void FAST_FUNC md5_process_block64(md5_ctx_t *ctx)
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{
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#if MD5_SMALL > 0
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/* Before we start, one word to the strange constants.
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They are defined in RFC 1321 as
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T[i] = (int)(2^32 * fabs(sin(i))), i=1..64
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*/
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static const uint32_t C_array[] ALIGN4 = {
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/* round 1 */
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0xd76aa478, 0xe8c7b756, 0x242070db, 0xc1bdceee,
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0xf57c0faf, 0x4787c62a, 0xa8304613, 0xfd469501,
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0x698098d8, 0x8b44f7af, 0xffff5bb1, 0x895cd7be,
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0x6b901122, 0xfd987193, 0xa679438e, 0x49b40821,
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/* round 2 */
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0xf61e2562, 0xc040b340, 0x265e5a51, 0xe9b6c7aa,
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0xd62f105d, 0x02441453, 0xd8a1e681, 0xe7d3fbc8,
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0x21e1cde6, 0xc33707d6, 0xf4d50d87, 0x455a14ed,
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0xa9e3e905, 0xfcefa3f8, 0x676f02d9, 0x8d2a4c8a,
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/* round 3 */
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0xfffa3942, 0x8771f681, 0x6d9d6122, 0xfde5380c,
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0xa4beea44, 0x4bdecfa9, 0xf6bb4b60, 0xbebfbc70,
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0x289b7ec6, 0xeaa127fa, 0xd4ef3085, 0x4881d05,
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0xd9d4d039, 0xe6db99e5, 0x1fa27cf8, 0xc4ac5665,
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/* round 4 */
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0xf4292244, 0x432aff97, 0xab9423a7, 0xfc93a039,
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0x655b59c3, 0x8f0ccc92, 0xffeff47d, 0x85845dd1,
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0x6fa87e4f, 0xfe2ce6e0, 0xa3014314, 0x4e0811a1,
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0xf7537e82, 0xbd3af235, 0x2ad7d2bb, 0xeb86d391
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};
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static const char P_array[] ALIGN1 = {
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# if MD5_SMALL > 1
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0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, /* 1 */
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# endif
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1, 6, 11, 0, 5, 10, 15, 4, 9, 14, 3, 8, 13, 2, 7, 12, /* 2 */
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5, 8, 11, 14, 1, 4, 7, 10, 13, 0, 3, 6, 9, 12, 15, 2, /* 3 */
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0, 7, 14, 5, 12, 3, 10, 1, 8, 15, 6, 13, 4, 11, 2, 9 /* 4 */
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};
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#endif
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uint32_t *words = (void*) ctx->wbuffer;
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uint32_t A = ctx->hash[0];
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uint32_t B = ctx->hash[1];
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uint32_t C = ctx->hash[2];
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uint32_t D = ctx->hash[3];
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#if MD5_SMALL >= 2 /* 2 or 3 */
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static const char S_array[] ALIGN1 = {
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7, 12, 17, 22,
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5, 9, 14, 20,
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4, 11, 16, 23,
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6, 10, 15, 21
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};
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const uint32_t *pc;
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const char *pp;
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const char *ps;
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int i;
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uint32_t temp;
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if (BB_BIG_ENDIAN)
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for (i = 0; i < 16; i++)
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words[i] = SWAP_LE32(words[i]);
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# if MD5_SMALL == 3
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pc = C_array;
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pp = P_array;
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ps = S_array - 4;
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for (i = 0; i < 64; i++) {
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if ((i & 0x0f) == 0)
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ps += 4;
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temp = A;
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switch (i >> 4) {
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case 0:
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temp += FF(B, C, D);
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break;
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case 1:
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temp += FG(B, C, D);
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break;
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case 2:
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temp += FH(B, C, D);
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break;
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default: /* case 3 */
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temp += FI(B, C, D);
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}
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temp += words[(int) (*pp++)] + *pc++;
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temp = rotl32(temp, ps[i & 3]);
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temp += B;
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A = D;
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D = C;
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C = B;
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B = temp;
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}
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# else /* MD5_SMALL == 2 */
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pc = C_array;
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pp = P_array;
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ps = S_array;
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for (i = 0; i < 16; i++) {
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temp = A + FF(B, C, D) + words[(int) (*pp++)] + *pc++;
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temp = rotl32(temp, ps[i & 3]);
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temp += B;
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A = D;
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D = C;
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C = B;
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B = temp;
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}
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ps += 4;
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for (i = 0; i < 16; i++) {
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temp = A + FG(B, C, D) + words[(int) (*pp++)] + *pc++;
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temp = rotl32(temp, ps[i & 3]);
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temp += B;
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A = D;
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D = C;
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C = B;
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B = temp;
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}
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ps += 4;
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for (i = 0; i < 16; i++) {
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temp = A + FH(B, C, D) + words[(int) (*pp++)] + *pc++;
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temp = rotl32(temp, ps[i & 3]);
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temp += B;
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A = D;
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D = C;
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C = B;
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B = temp;
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}
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ps += 4;
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for (i = 0; i < 16; i++) {
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temp = A + FI(B, C, D) + words[(int) (*pp++)] + *pc++;
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temp = rotl32(temp, ps[i & 3]);
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temp += B;
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A = D;
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D = C;
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C = B;
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B = temp;
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}
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# endif
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/* Add checksum to the starting values */
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ctx->hash[0] += A;
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ctx->hash[1] += B;
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ctx->hash[2] += C;
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ctx->hash[3] += D;
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#else /* MD5_SMALL == 0 or 1 */
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# if MD5_SMALL == 1
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const uint32_t *pc;
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const char *pp;
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int i;
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# endif
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/* First round: using the given function, the context and a constant
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the next context is computed. Because the algorithm's processing
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unit is a 32-bit word and it is determined to work on words in
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little endian byte order we perhaps have to change the byte order
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before the computation. To reduce the work for the next steps
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we save swapped words in WORDS array. */
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# undef OP
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# define OP(a, b, c, d, s, T) \
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do { \
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a += FF(b, c, d) + (*words IF_BIG_ENDIAN(= SWAP_LE32(*words))) + T; \
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words++; \
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a = rotl32(a, s); \
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a += b; \
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} while (0)
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/* Round 1 */
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# if MD5_SMALL == 1
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pc = C_array;
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for (i = 0; i < 4; i++) {
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OP(A, B, C, D, 7, *pc++);
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OP(D, A, B, C, 12, *pc++);
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OP(C, D, A, B, 17, *pc++);
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OP(B, C, D, A, 22, *pc++);
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}
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# else
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OP(A, B, C, D, 7, 0xd76aa478);
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OP(D, A, B, C, 12, 0xe8c7b756);
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OP(C, D, A, B, 17, 0x242070db);
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OP(B, C, D, A, 22, 0xc1bdceee);
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OP(A, B, C, D, 7, 0xf57c0faf);
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OP(D, A, B, C, 12, 0x4787c62a);
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OP(C, D, A, B, 17, 0xa8304613);
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OP(B, C, D, A, 22, 0xfd469501);
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OP(A, B, C, D, 7, 0x698098d8);
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OP(D, A, B, C, 12, 0x8b44f7af);
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OP(C, D, A, B, 17, 0xffff5bb1);
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OP(B, C, D, A, 22, 0x895cd7be);
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OP(A, B, C, D, 7, 0x6b901122);
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OP(D, A, B, C, 12, 0xfd987193);
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OP(C, D, A, B, 17, 0xa679438e);
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OP(B, C, D, A, 22, 0x49b40821);
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# endif
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words -= 16;
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/* For the second to fourth round we have the possibly swapped words
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in WORDS. Redefine the macro to take an additional first
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argument specifying the function to use. */
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# undef OP
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# define OP(f, a, b, c, d, k, s, T) \
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do { \
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a += f(b, c, d) + words[k] + T; \
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a = rotl32(a, s); \
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a += b; \
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} while (0)
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/* Round 2 */
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# if MD5_SMALL == 1
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pp = P_array;
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for (i = 0; i < 4; i++) {
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OP(FG, A, B, C, D, (int) (*pp++), 5, *pc++);
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OP(FG, D, A, B, C, (int) (*pp++), 9, *pc++);
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OP(FG, C, D, A, B, (int) (*pp++), 14, *pc++);
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OP(FG, B, C, D, A, (int) (*pp++), 20, *pc++);
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}
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# else
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OP(FG, A, B, C, D, 1, 5, 0xf61e2562);
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OP(FG, D, A, B, C, 6, 9, 0xc040b340);
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OP(FG, C, D, A, B, 11, 14, 0x265e5a51);
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OP(FG, B, C, D, A, 0, 20, 0xe9b6c7aa);
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OP(FG, A, B, C, D, 5, 5, 0xd62f105d);
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OP(FG, D, A, B, C, 10, 9, 0x02441453);
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OP(FG, C, D, A, B, 15, 14, 0xd8a1e681);
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OP(FG, B, C, D, A, 4, 20, 0xe7d3fbc8);
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OP(FG, A, B, C, D, 9, 5, 0x21e1cde6);
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OP(FG, D, A, B, C, 14, 9, 0xc33707d6);
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OP(FG, C, D, A, B, 3, 14, 0xf4d50d87);
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OP(FG, B, C, D, A, 8, 20, 0x455a14ed);
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OP(FG, A, B, C, D, 13, 5, 0xa9e3e905);
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OP(FG, D, A, B, C, 2, 9, 0xfcefa3f8);
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OP(FG, C, D, A, B, 7, 14, 0x676f02d9);
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OP(FG, B, C, D, A, 12, 20, 0x8d2a4c8a);
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# endif
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/* Round 3 */
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# if MD5_SMALL == 1
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for (i = 0; i < 4; i++) {
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OP(FH, A, B, C, D, (int) (*pp++), 4, *pc++);
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OP(FH, D, A, B, C, (int) (*pp++), 11, *pc++);
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OP(FH, C, D, A, B, (int) (*pp++), 16, *pc++);
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OP(FH, B, C, D, A, (int) (*pp++), 23, *pc++);
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}
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# else
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OP(FH, A, B, C, D, 5, 4, 0xfffa3942);
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OP(FH, D, A, B, C, 8, 11, 0x8771f681);
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OP(FH, C, D, A, B, 11, 16, 0x6d9d6122);
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OP(FH, B, C, D, A, 14, 23, 0xfde5380c);
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OP(FH, A, B, C, D, 1, 4, 0xa4beea44);
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OP(FH, D, A, B, C, 4, 11, 0x4bdecfa9);
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OP(FH, C, D, A, B, 7, 16, 0xf6bb4b60);
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OP(FH, B, C, D, A, 10, 23, 0xbebfbc70);
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OP(FH, A, B, C, D, 13, 4, 0x289b7ec6);
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OP(FH, D, A, B, C, 0, 11, 0xeaa127fa);
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OP(FH, C, D, A, B, 3, 16, 0xd4ef3085);
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OP(FH, B, C, D, A, 6, 23, 0x04881d05);
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OP(FH, A, B, C, D, 9, 4, 0xd9d4d039);
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OP(FH, D, A, B, C, 12, 11, 0xe6db99e5);
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OP(FH, C, D, A, B, 15, 16, 0x1fa27cf8);
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OP(FH, B, C, D, A, 2, 23, 0xc4ac5665);
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# endif
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|
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/* Round 4 */
|
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# if MD5_SMALL == 1
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for (i = 0; i < 4; i++) {
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OP(FI, A, B, C, D, (int) (*pp++), 6, *pc++);
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OP(FI, D, A, B, C, (int) (*pp++), 10, *pc++);
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OP(FI, C, D, A, B, (int) (*pp++), 15, *pc++);
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OP(FI, B, C, D, A, (int) (*pp++), 21, *pc++);
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}
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# else
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OP(FI, A, B, C, D, 0, 6, 0xf4292244);
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OP(FI, D, A, B, C, 7, 10, 0x432aff97);
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OP(FI, C, D, A, B, 14, 15, 0xab9423a7);
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OP(FI, B, C, D, A, 5, 21, 0xfc93a039);
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OP(FI, A, B, C, D, 12, 6, 0x655b59c3);
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OP(FI, D, A, B, C, 3, 10, 0x8f0ccc92);
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OP(FI, C, D, A, B, 10, 15, 0xffeff47d);
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OP(FI, B, C, D, A, 1, 21, 0x85845dd1);
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OP(FI, A, B, C, D, 8, 6, 0x6fa87e4f);
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OP(FI, D, A, B, C, 15, 10, 0xfe2ce6e0);
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OP(FI, C, D, A, B, 6, 15, 0xa3014314);
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OP(FI, B, C, D, A, 13, 21, 0x4e0811a1);
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OP(FI, A, B, C, D, 4, 6, 0xf7537e82);
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OP(FI, D, A, B, C, 11, 10, 0xbd3af235);
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OP(FI, C, D, A, B, 2, 15, 0x2ad7d2bb);
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OP(FI, B, C, D, A, 9, 21, 0xeb86d391);
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# undef OP
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# endif
|
|
/* Add checksum to the starting values */
|
|
ctx->hash[0] += A;
|
|
ctx->hash[1] += B;
|
|
ctx->hash[2] += C;
|
|
ctx->hash[3] += D;
|
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#endif
|
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}
|
|
#undef FF
|
|
#undef FG
|
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#undef FH
|
|
#undef FI
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|
|
|
/* Initialize structure containing state of computation.
|
|
* (RFC 1321, 3.3: Step 3)
|
|
*/
|
|
void FAST_FUNC md5_begin(md5_ctx_t *ctx)
|
|
{
|
|
ctx->hash[0] = 0x67452301;
|
|
ctx->hash[1] = 0xefcdab89;
|
|
ctx->hash[2] = 0x98badcfe;
|
|
ctx->hash[3] = 0x10325476;
|
|
ctx->total64 = 0;
|
|
ctx->process_block = md5_process_block64;
|
|
}
|
|
|
|
/* Used also for sha1 and sha256 */
|
|
void FAST_FUNC md5_hash(md5_ctx_t *ctx, const void *buffer, size_t len)
|
|
{
|
|
unsigned bufpos = ctx->total64 & 63;
|
|
|
|
ctx->total64 += len;
|
|
|
|
while (1) {
|
|
unsigned remaining = 64 - bufpos;
|
|
if (remaining > len)
|
|
remaining = len;
|
|
/* Copy data into aligned buffer */
|
|
memcpy(ctx->wbuffer + bufpos, buffer, remaining);
|
|
len -= remaining;
|
|
buffer = (const char *)buffer + remaining;
|
|
bufpos += remaining;
|
|
|
|
/* Clever way to do "if (bufpos != N) break; ... ; bufpos = 0;" */
|
|
bufpos -= 64;
|
|
if (bufpos != 0)
|
|
break;
|
|
|
|
/* Buffer is filled up, process it */
|
|
ctx->process_block(ctx);
|
|
/*bufpos = 0; - already is */
|
|
}
|
|
}
|
|
|
|
/* Process the remaining bytes in the buffer and put result from CTX
|
|
* in first 16 bytes following RESBUF. The result is always in little
|
|
* endian byte order, so that a byte-wise output yields to the wanted
|
|
* ASCII representation of the message digest.
|
|
*/
|
|
unsigned FAST_FUNC md5_end(md5_ctx_t *ctx, void *resbuf)
|
|
{
|
|
/* MD5 stores total in LE, need to swap on BE arches: */
|
|
common64_end(ctx, /*swap_needed:*/ BB_BIG_ENDIAN);
|
|
|
|
/* The MD5 result is in little endian byte order */
|
|
if (BB_BIG_ENDIAN) {
|
|
ctx->hash[0] = SWAP_LE32(ctx->hash[0]);
|
|
ctx->hash[1] = SWAP_LE32(ctx->hash[1]);
|
|
ctx->hash[2] = SWAP_LE32(ctx->hash[2]);
|
|
ctx->hash[3] = SWAP_LE32(ctx->hash[3]);
|
|
}
|
|
|
|
memcpy(resbuf, ctx->hash, sizeof(ctx->hash[0]) * 4);
|
|
return sizeof(ctx->hash[0]) * 4;
|
|
}
|
|
|
|
|
|
/*
|
|
* SHA1 part is:
|
|
* Copyright 2007 Rob Landley <rob@landley.net>
|
|
*
|
|
* Based on the public domain SHA-1 in C by Steve Reid <steve@edmweb.com>
|
|
* from http://www.mirrors.wiretapped.net/security/cryptography/hashes/sha1/
|
|
*
|
|
* Licensed under GPLv2, see file LICENSE in this source tree.
|
|
*
|
|
* ---------------------------------------------------------------------------
|
|
*
|
|
* SHA256 and SHA512 parts are:
|
|
* Released into the Public Domain by Ulrich Drepper <drepper@redhat.com>.
|
|
* Shrank by Denys Vlasenko.
|
|
*
|
|
* ---------------------------------------------------------------------------
|
|
*
|
|
* The best way to test random blocksizes is to go to coreutils/md5_sha1_sum.c
|
|
* and replace "4096" with something like "2000 + time(NULL) % 2097",
|
|
* then rebuild and compare "shaNNNsum bigfile" results.
|
|
*/
|
|
|
|
static void FAST_FUNC sha1_process_block64(sha1_ctx_t *ctx)
|
|
{
|
|
static const uint32_t rconsts[] ALIGN4 = {
|
|
0x5A827999, 0x6ED9EBA1, 0x8F1BBCDC, 0xCA62C1D6
|
|
};
|
|
int i, j;
|
|
int cnt;
|
|
uint32_t W[16+16];
|
|
uint32_t a, b, c, d, e;
|
|
|
|
/* On-stack work buffer frees up one register in the main loop
|
|
* which otherwise will be needed to hold ctx pointer */
|
|
for (i = 0; i < 16; i++)
|
|
W[i] = W[i+16] = SWAP_BE32(((uint32_t*)ctx->wbuffer)[i]);
|
|
|
|
a = ctx->hash[0];
|
|
b = ctx->hash[1];
|
|
c = ctx->hash[2];
|
|
d = ctx->hash[3];
|
|
e = ctx->hash[4];
|
|
|
|
/* 4 rounds of 20 operations each */
|
|
cnt = 0;
|
|
for (i = 0; i < 4; i++) {
|
|
j = 19;
|
|
do {
|
|
uint32_t work;
|
|
|
|
work = c ^ d;
|
|
if (i == 0) {
|
|
work = (work & b) ^ d;
|
|
if (j <= 3)
|
|
goto ge16;
|
|
/* Used to do SWAP_BE32 here, but this
|
|
* requires ctx (see comment above) */
|
|
work += W[cnt];
|
|
} else {
|
|
if (i == 2)
|
|
work = ((b | c) & d) | (b & c);
|
|
else /* i = 1 or 3 */
|
|
work ^= b;
|
|
ge16:
|
|
W[cnt] = W[cnt+16] = rotl32(W[cnt+13] ^ W[cnt+8] ^ W[cnt+2] ^ W[cnt], 1);
|
|
work += W[cnt];
|
|
}
|
|
work += e + rotl32(a, 5) + rconsts[i];
|
|
|
|
/* Rotate by one for next time */
|
|
e = d;
|
|
d = c;
|
|
c = /* b = */ rotl32(b, 30);
|
|
b = a;
|
|
a = work;
|
|
cnt = (cnt + 1) & 15;
|
|
} while (--j >= 0);
|
|
}
|
|
|
|
ctx->hash[0] += a;
|
|
ctx->hash[1] += b;
|
|
ctx->hash[2] += c;
|
|
ctx->hash[3] += d;
|
|
ctx->hash[4] += e;
|
|
}
|
|
|
|
/* Constants for SHA512 from FIPS 180-2:4.2.3.
|
|
* SHA256 constants from FIPS 180-2:4.2.2
|
|
* are the most significant half of first 64 elements
|
|
* of the same array.
|
|
*/
|
|
#undef K
|
|
#if NEED_SHA512
|
|
typedef uint64_t sha_K_int;
|
|
# define K(v) v
|
|
#else
|
|
typedef uint32_t sha_K_int;
|
|
# define K(v) (uint32_t)(v >> 32)
|
|
#endif
|
|
static const sha_K_int sha_K[] ALIGN8 = {
|
|
K(0x428a2f98d728ae22ULL), K(0x7137449123ef65cdULL),
|
|
K(0xb5c0fbcfec4d3b2fULL), K(0xe9b5dba58189dbbcULL),
|
|
K(0x3956c25bf348b538ULL), K(0x59f111f1b605d019ULL),
|
|
K(0x923f82a4af194f9bULL), K(0xab1c5ed5da6d8118ULL),
|
|
K(0xd807aa98a3030242ULL), K(0x12835b0145706fbeULL),
|
|
K(0x243185be4ee4b28cULL), K(0x550c7dc3d5ffb4e2ULL),
|
|
K(0x72be5d74f27b896fULL), K(0x80deb1fe3b1696b1ULL),
|
|
K(0x9bdc06a725c71235ULL), K(0xc19bf174cf692694ULL),
|
|
K(0xe49b69c19ef14ad2ULL), K(0xefbe4786384f25e3ULL),
|
|
K(0x0fc19dc68b8cd5b5ULL), K(0x240ca1cc77ac9c65ULL),
|
|
K(0x2de92c6f592b0275ULL), K(0x4a7484aa6ea6e483ULL),
|
|
K(0x5cb0a9dcbd41fbd4ULL), K(0x76f988da831153b5ULL),
|
|
K(0x983e5152ee66dfabULL), K(0xa831c66d2db43210ULL),
|
|
K(0xb00327c898fb213fULL), K(0xbf597fc7beef0ee4ULL),
|
|
K(0xc6e00bf33da88fc2ULL), K(0xd5a79147930aa725ULL),
|
|
K(0x06ca6351e003826fULL), K(0x142929670a0e6e70ULL),
|
|
K(0x27b70a8546d22ffcULL), K(0x2e1b21385c26c926ULL),
|
|
K(0x4d2c6dfc5ac42aedULL), K(0x53380d139d95b3dfULL),
|
|
K(0x650a73548baf63deULL), K(0x766a0abb3c77b2a8ULL),
|
|
K(0x81c2c92e47edaee6ULL), K(0x92722c851482353bULL),
|
|
K(0xa2bfe8a14cf10364ULL), K(0xa81a664bbc423001ULL),
|
|
K(0xc24b8b70d0f89791ULL), K(0xc76c51a30654be30ULL),
|
|
K(0xd192e819d6ef5218ULL), K(0xd69906245565a910ULL),
|
|
K(0xf40e35855771202aULL), K(0x106aa07032bbd1b8ULL),
|
|
K(0x19a4c116b8d2d0c8ULL), K(0x1e376c085141ab53ULL),
|
|
K(0x2748774cdf8eeb99ULL), K(0x34b0bcb5e19b48a8ULL),
|
|
K(0x391c0cb3c5c95a63ULL), K(0x4ed8aa4ae3418acbULL),
|
|
K(0x5b9cca4f7763e373ULL), K(0x682e6ff3d6b2b8a3ULL),
|
|
K(0x748f82ee5defb2fcULL), K(0x78a5636f43172f60ULL),
|
|
K(0x84c87814a1f0ab72ULL), K(0x8cc702081a6439ecULL),
|
|
K(0x90befffa23631e28ULL), K(0xa4506cebde82bde9ULL),
|
|
K(0xbef9a3f7b2c67915ULL), K(0xc67178f2e372532bULL),
|
|
#if NEED_SHA512 /* [64]+ are used for sha512 only */
|
|
K(0xca273eceea26619cULL), K(0xd186b8c721c0c207ULL),
|
|
K(0xeada7dd6cde0eb1eULL), K(0xf57d4f7fee6ed178ULL),
|
|
K(0x06f067aa72176fbaULL), K(0x0a637dc5a2c898a6ULL),
|
|
K(0x113f9804bef90daeULL), K(0x1b710b35131c471bULL),
|
|
K(0x28db77f523047d84ULL), K(0x32caab7b40c72493ULL),
|
|
K(0x3c9ebe0a15c9bebcULL), K(0x431d67c49c100d4cULL),
|
|
K(0x4cc5d4becb3e42b6ULL), K(0x597f299cfc657e2aULL),
|
|
K(0x5fcb6fab3ad6faecULL), K(0x6c44198c4a475817ULL),
|
|
#endif
|
|
};
|
|
#undef K
|
|
|
|
#undef Ch
|
|
#undef Maj
|
|
#undef S0
|
|
#undef S1
|
|
#undef R0
|
|
#undef R1
|
|
|
|
static void FAST_FUNC sha256_process_block64(sha256_ctx_t *ctx)
|
|
{
|
|
unsigned t;
|
|
uint32_t W[64], a, b, c, d, e, f, g, h;
|
|
const uint32_t *words = (uint32_t*) ctx->wbuffer;
|
|
|
|
/* Operators defined in FIPS 180-2:4.1.2. */
|
|
#define Ch(x, y, z) ((x & y) ^ (~x & z))
|
|
#define Maj(x, y, z) ((x & y) ^ (x & z) ^ (y & z))
|
|
#define S0(x) (rotr32(x, 2) ^ rotr32(x, 13) ^ rotr32(x, 22))
|
|
#define S1(x) (rotr32(x, 6) ^ rotr32(x, 11) ^ rotr32(x, 25))
|
|
#define R0(x) (rotr32(x, 7) ^ rotr32(x, 18) ^ (x >> 3))
|
|
#define R1(x) (rotr32(x, 17) ^ rotr32(x, 19) ^ (x >> 10))
|
|
|
|
/* Compute the message schedule according to FIPS 180-2:6.2.2 step 2. */
|
|
for (t = 0; t < 16; ++t)
|
|
W[t] = SWAP_BE32(words[t]);
|
|
for (/*t = 16*/; t < 64; ++t)
|
|
W[t] = R1(W[t - 2]) + W[t - 7] + R0(W[t - 15]) + W[t - 16];
|
|
|
|
a = ctx->hash[0];
|
|
b = ctx->hash[1];
|
|
c = ctx->hash[2];
|
|
d = ctx->hash[3];
|
|
e = ctx->hash[4];
|
|
f = ctx->hash[5];
|
|
g = ctx->hash[6];
|
|
h = ctx->hash[7];
|
|
|
|
/* The actual computation according to FIPS 180-2:6.2.2 step 3. */
|
|
for (t = 0; t < 64; ++t) {
|
|
/* Need to fetch upper half of sha_K[t]
|
|
* (I hope compiler is clever enough to just fetch
|
|
* upper half)
|
|
*/
|
|
uint32_t K_t = NEED_SHA512 ? (sha_K[t] >> 32) : sha_K[t];
|
|
uint32_t T1 = h + S1(e) + Ch(e, f, g) + K_t + W[t];
|
|
uint32_t T2 = S0(a) + Maj(a, b, c);
|
|
h = g;
|
|
g = f;
|
|
f = e;
|
|
e = d + T1;
|
|
d = c;
|
|
c = b;
|
|
b = a;
|
|
a = T1 + T2;
|
|
}
|
|
#undef Ch
|
|
#undef Maj
|
|
#undef S0
|
|
#undef S1
|
|
#undef R0
|
|
#undef R1
|
|
/* Add the starting values of the context according to FIPS 180-2:6.2.2
|
|
step 4. */
|
|
ctx->hash[0] += a;
|
|
ctx->hash[1] += b;
|
|
ctx->hash[2] += c;
|
|
ctx->hash[3] += d;
|
|
ctx->hash[4] += e;
|
|
ctx->hash[5] += f;
|
|
ctx->hash[6] += g;
|
|
ctx->hash[7] += h;
|
|
}
|
|
|
|
#if NEED_SHA512
|
|
static void FAST_FUNC sha512_process_block128(sha512_ctx_t *ctx)
|
|
{
|
|
unsigned t;
|
|
uint64_t W[80];
|
|
/* On i386, having assignments here (not later as sha256 does)
|
|
* produces 99 bytes smaller code with gcc 4.3.1
|
|
*/
|
|
uint64_t a = ctx->hash[0];
|
|
uint64_t b = ctx->hash[1];
|
|
uint64_t c = ctx->hash[2];
|
|
uint64_t d = ctx->hash[3];
|
|
uint64_t e = ctx->hash[4];
|
|
uint64_t f = ctx->hash[5];
|
|
uint64_t g = ctx->hash[6];
|
|
uint64_t h = ctx->hash[7];
|
|
const uint64_t *words = (uint64_t*) ctx->wbuffer;
|
|
|
|
/* Operators defined in FIPS 180-2:4.1.2. */
|
|
#define Ch(x, y, z) ((x & y) ^ (~x & z))
|
|
#define Maj(x, y, z) ((x & y) ^ (x & z) ^ (y & z))
|
|
#define S0(x) (rotr64(x, 28) ^ rotr64(x, 34) ^ rotr64(x, 39))
|
|
#define S1(x) (rotr64(x, 14) ^ rotr64(x, 18) ^ rotr64(x, 41))
|
|
#define R0(x) (rotr64(x, 1) ^ rotr64(x, 8) ^ (x >> 7))
|
|
#define R1(x) (rotr64(x, 19) ^ rotr64(x, 61) ^ (x >> 6))
|
|
|
|
/* Compute the message schedule according to FIPS 180-2:6.3.2 step 2. */
|
|
for (t = 0; t < 16; ++t)
|
|
W[t] = SWAP_BE64(words[t]);
|
|
for (/*t = 16*/; t < 80; ++t)
|
|
W[t] = R1(W[t - 2]) + W[t - 7] + R0(W[t - 15]) + W[t - 16];
|
|
|
|
/* The actual computation according to FIPS 180-2:6.3.2 step 3. */
|
|
for (t = 0; t < 80; ++t) {
|
|
uint64_t T1 = h + S1(e) + Ch(e, f, g) + sha_K[t] + W[t];
|
|
uint64_t T2 = S0(a) + Maj(a, b, c);
|
|
h = g;
|
|
g = f;
|
|
f = e;
|
|
e = d + T1;
|
|
d = c;
|
|
c = b;
|
|
b = a;
|
|
a = T1 + T2;
|
|
}
|
|
#undef Ch
|
|
#undef Maj
|
|
#undef S0
|
|
#undef S1
|
|
#undef R0
|
|
#undef R1
|
|
/* Add the starting values of the context according to FIPS 180-2:6.3.2
|
|
step 4. */
|
|
ctx->hash[0] += a;
|
|
ctx->hash[1] += b;
|
|
ctx->hash[2] += c;
|
|
ctx->hash[3] += d;
|
|
ctx->hash[4] += e;
|
|
ctx->hash[5] += f;
|
|
ctx->hash[6] += g;
|
|
ctx->hash[7] += h;
|
|
}
|
|
#endif /* NEED_SHA512 */
|
|
|
|
void FAST_FUNC sha1_begin(sha1_ctx_t *ctx)
|
|
{
|
|
ctx->hash[0] = 0x67452301;
|
|
ctx->hash[1] = 0xefcdab89;
|
|
ctx->hash[2] = 0x98badcfe;
|
|
ctx->hash[3] = 0x10325476;
|
|
ctx->hash[4] = 0xc3d2e1f0;
|
|
ctx->total64 = 0;
|
|
ctx->process_block = sha1_process_block64;
|
|
}
|
|
|
|
static const uint32_t init256[] ALIGN4 = {
|
|
0,
|
|
0,
|
|
0x6a09e667,
|
|
0xbb67ae85,
|
|
0x3c6ef372,
|
|
0xa54ff53a,
|
|
0x510e527f,
|
|
0x9b05688c,
|
|
0x1f83d9ab,
|
|
0x5be0cd19,
|
|
};
|
|
#if NEED_SHA512
|
|
static const uint32_t init512_lo[] ALIGN4 = {
|
|
0,
|
|
0,
|
|
0xf3bcc908,
|
|
0x84caa73b,
|
|
0xfe94f82b,
|
|
0x5f1d36f1,
|
|
0xade682d1,
|
|
0x2b3e6c1f,
|
|
0xfb41bd6b,
|
|
0x137e2179,
|
|
};
|
|
#endif /* NEED_SHA512 */
|
|
|
|
// Note: SHA-384 is identical to SHA-512, except that initial hash values are
|
|
// 0xcbbb9d5dc1059ed8, 0x629a292a367cd507, 0x9159015a3070dd17, 0x152fecd8f70e5939,
|
|
// 0x67332667ffc00b31, 0x8eb44a8768581511, 0xdb0c2e0d64f98fa7, 0x47b5481dbefa4fa4,
|
|
// and the output is constructed by omitting last two 64-bit words of it.
|
|
|
|
/* Initialize structure containing state of computation.
|
|
(FIPS 180-2:5.3.2) */
|
|
void FAST_FUNC sha256_begin(sha256_ctx_t *ctx)
|
|
{
|
|
memcpy(&ctx->total64, init256, sizeof(init256));
|
|
/*ctx->total64 = 0; - done by prepending two 32-bit zeros to init256 */
|
|
ctx->process_block = sha256_process_block64;
|
|
}
|
|
|
|
#if NEED_SHA512
|
|
/* Initialize structure containing state of computation.
|
|
(FIPS 180-2:5.3.3) */
|
|
void FAST_FUNC sha512_begin(sha512_ctx_t *ctx)
|
|
{
|
|
int i;
|
|
/* Two extra iterations zero out ctx->total64[2] */
|
|
uint64_t *tp = ctx->total64;
|
|
for (i = 0; i < 8 + 2; i++)
|
|
tp[i] = ((uint64_t)(init256[i]) << 32) + init512_lo[i];
|
|
/*ctx->total64[0] = ctx->total64[1] = 0; - already done */
|
|
}
|
|
|
|
void FAST_FUNC sha512_hash(sha512_ctx_t *ctx, const void *buffer, size_t len)
|
|
{
|
|
unsigned bufpos = ctx->total64[0] & 127;
|
|
unsigned remaining;
|
|
|
|
/* First increment the byte count. FIPS 180-2 specifies the possible
|
|
length of the file up to 2^128 _bits_.
|
|
We compute the number of _bytes_ and convert to bits later. */
|
|
ctx->total64[0] += len;
|
|
if (ctx->total64[0] < len)
|
|
ctx->total64[1]++;
|
|
|
|
while (1) {
|
|
remaining = 128 - bufpos;
|
|
if (remaining > len)
|
|
remaining = len;
|
|
/* Copy data into aligned buffer */
|
|
memcpy(ctx->wbuffer + bufpos, buffer, remaining);
|
|
len -= remaining;
|
|
buffer = (const char *)buffer + remaining;
|
|
bufpos += remaining;
|
|
|
|
/* Clever way to do "if (bufpos != N) break; ... ; bufpos = 0;" */
|
|
bufpos -= 128;
|
|
if (bufpos != 0)
|
|
break;
|
|
|
|
/* Buffer is filled up, process it */
|
|
sha512_process_block128(ctx);
|
|
/*bufpos = 0; - already is */
|
|
}
|
|
}
|
|
#endif /* NEED_SHA512 */
|
|
|
|
/* Used also for sha256 */
|
|
unsigned FAST_FUNC sha1_end(sha1_ctx_t *ctx, void *resbuf)
|
|
{
|
|
unsigned hash_size;
|
|
|
|
/* SHA stores total in BE, need to swap on LE arches: */
|
|
common64_end(ctx, /*swap_needed:*/ BB_LITTLE_ENDIAN);
|
|
|
|
hash_size = (ctx->process_block == sha1_process_block64) ? 5 : 8;
|
|
/* This way we do not impose alignment constraints on resbuf: */
|
|
if (BB_LITTLE_ENDIAN) {
|
|
unsigned i;
|
|
for (i = 0; i < hash_size; ++i)
|
|
ctx->hash[i] = SWAP_BE32(ctx->hash[i]);
|
|
}
|
|
hash_size *= sizeof(ctx->hash[0]);
|
|
memcpy(resbuf, ctx->hash, hash_size);
|
|
return hash_size;
|
|
}
|
|
|
|
#if NEED_SHA512
|
|
unsigned FAST_FUNC sha512_end(sha512_ctx_t *ctx, void *resbuf)
|
|
{
|
|
unsigned bufpos = ctx->total64[0] & 127;
|
|
|
|
/* Pad the buffer to the next 128-byte boundary with 0x80,0,0,0... */
|
|
ctx->wbuffer[bufpos++] = 0x80;
|
|
|
|
while (1) {
|
|
unsigned remaining = 128 - bufpos;
|
|
memset(ctx->wbuffer + bufpos, 0, remaining);
|
|
if (remaining >= 16) {
|
|
/* Store the 128-bit counter of bits in the buffer in BE format */
|
|
uint64_t t;
|
|
t = ctx->total64[0] << 3;
|
|
t = SWAP_BE64(t);
|
|
*(bb__aliased_uint64_t *) (&ctx->wbuffer[128 - 8]) = t;
|
|
t = (ctx->total64[1] << 3) | (ctx->total64[0] >> 61);
|
|
t = SWAP_BE64(t);
|
|
*(bb__aliased_uint64_t *) (&ctx->wbuffer[128 - 16]) = t;
|
|
}
|
|
sha512_process_block128(ctx);
|
|
if (remaining >= 16)
|
|
break;
|
|
bufpos = 0;
|
|
}
|
|
|
|
if (BB_LITTLE_ENDIAN) {
|
|
unsigned i;
|
|
for (i = 0; i < ARRAY_SIZE(ctx->hash); ++i)
|
|
ctx->hash[i] = SWAP_BE64(ctx->hash[i]);
|
|
}
|
|
memcpy(resbuf, ctx->hash, sizeof(ctx->hash));
|
|
return sizeof(ctx->hash);
|
|
}
|
|
#endif /* NEED_SHA512 */
|
|
|
|
|
|
/*
|
|
* The Keccak sponge function, designed by Guido Bertoni, Joan Daemen,
|
|
* Michael Peeters and Gilles Van Assche. For more information, feedback or
|
|
* questions, please refer to our website: http://keccak.noekeon.org/
|
|
*
|
|
* Implementation by Ronny Van Keer,
|
|
* hereby denoted as "the implementer".
|
|
*
|
|
* To the extent possible under law, the implementer has waived all copyright
|
|
* and related or neighboring rights to the source code in this file.
|
|
* http://creativecommons.org/publicdomain/zero/1.0/
|
|
*
|
|
* Busybox modifications (C) Lauri Kasanen, under the GPLv2.
|
|
*/
|
|
|
|
#if CONFIG_SHA3_SMALL < 0
|
|
# define SHA3_SMALL 0
|
|
#elif CONFIG_SHA3_SMALL > 1
|
|
# define SHA3_SMALL 1
|
|
#else
|
|
# define SHA3_SMALL CONFIG_SHA3_SMALL
|
|
#endif
|
|
|
|
#define OPTIMIZE_SHA3_FOR_32 0
|
|
/*
|
|
* SHA3 can be optimized for 32-bit CPUs with bit-slicing:
|
|
* every 64-bit word of state[] can be split into two 32-bit words
|
|
* by even/odd bits. In this form, all rotations of sha3 round
|
|
* are 32-bit - and there are lots of them.
|
|
* However, it requires either splitting/combining state words
|
|
* before/after sha3 round (code does this now)
|
|
* or shuffling bits before xor'ing them into state and in sha3_end.
|
|
* Without shuffling, bit-slicing results in -130 bytes of code
|
|
* and marginal speedup (but of course it gives wrong result).
|
|
* With shuffling it works, but +260 code bytes, and slower.
|
|
* Disabled for now:
|
|
*/
|
|
#if 0 /* LONG_MAX == 0x7fffffff */
|
|
# undef OPTIMIZE_SHA3_FOR_32
|
|
# define OPTIMIZE_SHA3_FOR_32 1
|
|
#endif
|
|
|
|
#if OPTIMIZE_SHA3_FOR_32
|
|
/* This splits every 64-bit word into a pair of 32-bit words,
|
|
* even bits go into first word, odd bits go to second one.
|
|
* The conversion is done in-place.
|
|
*/
|
|
static void split_halves(uint64_t *state)
|
|
{
|
|
/* Credit: Henry S. Warren, Hacker's Delight, Addison-Wesley, 2002 */
|
|
uint32_t *s32 = (uint32_t*)state;
|
|
uint32_t t, x0, x1;
|
|
int i;
|
|
for (i = 24; i >= 0; --i) {
|
|
x0 = s32[0];
|
|
t = (x0 ^ (x0 >> 1)) & 0x22222222; x0 = x0 ^ t ^ (t << 1);
|
|
t = (x0 ^ (x0 >> 2)) & 0x0C0C0C0C; x0 = x0 ^ t ^ (t << 2);
|
|
t = (x0 ^ (x0 >> 4)) & 0x00F000F0; x0 = x0 ^ t ^ (t << 4);
|
|
t = (x0 ^ (x0 >> 8)) & 0x0000FF00; x0 = x0 ^ t ^ (t << 8);
|
|
x1 = s32[1];
|
|
t = (x1 ^ (x1 >> 1)) & 0x22222222; x1 = x1 ^ t ^ (t << 1);
|
|
t = (x1 ^ (x1 >> 2)) & 0x0C0C0C0C; x1 = x1 ^ t ^ (t << 2);
|
|
t = (x1 ^ (x1 >> 4)) & 0x00F000F0; x1 = x1 ^ t ^ (t << 4);
|
|
t = (x1 ^ (x1 >> 8)) & 0x0000FF00; x1 = x1 ^ t ^ (t << 8);
|
|
*s32++ = (x0 & 0x0000FFFF) | (x1 << 16);
|
|
*s32++ = (x0 >> 16) | (x1 & 0xFFFF0000);
|
|
}
|
|
}
|
|
/* The reverse operation */
|
|
static void combine_halves(uint64_t *state)
|
|
{
|
|
uint32_t *s32 = (uint32_t*)state;
|
|
uint32_t t, x0, x1;
|
|
int i;
|
|
for (i = 24; i >= 0; --i) {
|
|
x0 = s32[0];
|
|
x1 = s32[1];
|
|
t = (x0 & 0x0000FFFF) | (x1 << 16);
|
|
x1 = (x0 >> 16) | (x1 & 0xFFFF0000);
|
|
x0 = t;
|
|
t = (x0 ^ (x0 >> 8)) & 0x0000FF00; x0 = x0 ^ t ^ (t << 8);
|
|
t = (x0 ^ (x0 >> 4)) & 0x00F000F0; x0 = x0 ^ t ^ (t << 4);
|
|
t = (x0 ^ (x0 >> 2)) & 0x0C0C0C0C; x0 = x0 ^ t ^ (t << 2);
|
|
t = (x0 ^ (x0 >> 1)) & 0x22222222; x0 = x0 ^ t ^ (t << 1);
|
|
*s32++ = x0;
|
|
t = (x1 ^ (x1 >> 8)) & 0x0000FF00; x1 = x1 ^ t ^ (t << 8);
|
|
t = (x1 ^ (x1 >> 4)) & 0x00F000F0; x1 = x1 ^ t ^ (t << 4);
|
|
t = (x1 ^ (x1 >> 2)) & 0x0C0C0C0C; x1 = x1 ^ t ^ (t << 2);
|
|
t = (x1 ^ (x1 >> 1)) & 0x22222222; x1 = x1 ^ t ^ (t << 1);
|
|
*s32++ = x1;
|
|
}
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
* In the crypto literature this function is usually called Keccak-f().
|
|
*/
|
|
static void sha3_process_block72(uint64_t *state)
|
|
{
|
|
enum { NROUNDS = 24 };
|
|
|
|
#if OPTIMIZE_SHA3_FOR_32
|
|
/*
|
|
static const uint32_t IOTA_CONST_0[NROUNDS] ALIGN4 = {
|
|
0x00000001UL,
|
|
0x00000000UL,
|
|
0x00000000UL,
|
|
0x00000000UL,
|
|
0x00000001UL,
|
|
0x00000001UL,
|
|
0x00000001UL,
|
|
0x00000001UL,
|
|
0x00000000UL,
|
|
0x00000000UL,
|
|
0x00000001UL,
|
|
0x00000000UL,
|
|
0x00000001UL,
|
|
0x00000001UL,
|
|
0x00000001UL,
|
|
0x00000001UL,
|
|
0x00000000UL,
|
|
0x00000000UL,
|
|
0x00000000UL,
|
|
0x00000000UL,
|
|
0x00000001UL,
|
|
0x00000000UL,
|
|
0x00000001UL,
|
|
0x00000000UL,
|
|
};
|
|
** bits are in lsb: 0101 0000 1111 0100 1111 0001
|
|
*/
|
|
uint32_t IOTA_CONST_0bits = (uint32_t)(0x0050f4f1);
|
|
static const uint32_t IOTA_CONST_1[NROUNDS] ALIGN4 = {
|
|
0x00000000UL,
|
|
0x00000089UL,
|
|
0x8000008bUL,
|
|
0x80008080UL,
|
|
0x0000008bUL,
|
|
0x00008000UL,
|
|
0x80008088UL,
|
|
0x80000082UL,
|
|
0x0000000bUL,
|
|
0x0000000aUL,
|
|
0x00008082UL,
|
|
0x00008003UL,
|
|
0x0000808bUL,
|
|
0x8000000bUL,
|
|
0x8000008aUL,
|
|
0x80000081UL,
|
|
0x80000081UL,
|
|
0x80000008UL,
|
|
0x00000083UL,
|
|
0x80008003UL,
|
|
0x80008088UL,
|
|
0x80000088UL,
|
|
0x00008000UL,
|
|
0x80008082UL,
|
|
};
|
|
|
|
uint32_t *const s32 = (uint32_t*)state;
|
|
unsigned round;
|
|
|
|
split_halves(state);
|
|
|
|
for (round = 0; round < NROUNDS; round++) {
|
|
unsigned x;
|
|
|
|
/* Theta */
|
|
{
|
|
uint32_t BC[20];
|
|
for (x = 0; x < 10; ++x) {
|
|
BC[x+10] = BC[x] = s32[x]^s32[x+10]^s32[x+20]^s32[x+30]^s32[x+40];
|
|
}
|
|
for (x = 0; x < 10; x += 2) {
|
|
uint32_t ta, tb;
|
|
ta = BC[x+8] ^ rotl32(BC[x+3], 1);
|
|
tb = BC[x+9] ^ BC[x+2];
|
|
s32[x+0] ^= ta;
|
|
s32[x+1] ^= tb;
|
|
s32[x+10] ^= ta;
|
|
s32[x+11] ^= tb;
|
|
s32[x+20] ^= ta;
|
|
s32[x+21] ^= tb;
|
|
s32[x+30] ^= ta;
|
|
s32[x+31] ^= tb;
|
|
s32[x+40] ^= ta;
|
|
s32[x+41] ^= tb;
|
|
}
|
|
}
|
|
/* RhoPi */
|
|
{
|
|
uint32_t t0a,t0b, t1a,t1b;
|
|
t1a = s32[1*2+0];
|
|
t1b = s32[1*2+1];
|
|
|
|
#define RhoPi(PI_LANE, ROT_CONST) \
|
|
t0a = s32[PI_LANE*2+0];\
|
|
t0b = s32[PI_LANE*2+1];\
|
|
if (ROT_CONST & 1) {\
|
|
s32[PI_LANE*2+0] = rotl32(t1b, ROT_CONST/2+1);\
|
|
s32[PI_LANE*2+1] = ROT_CONST == 1 ? t1a : rotl32(t1a, ROT_CONST/2+0);\
|
|
} else {\
|
|
s32[PI_LANE*2+0] = rotl32(t1a, ROT_CONST/2);\
|
|
s32[PI_LANE*2+1] = rotl32(t1b, ROT_CONST/2);\
|
|
}\
|
|
t1a = t0a; t1b = t0b;
|
|
|
|
RhoPi(10, 1)
|
|
RhoPi( 7, 3)
|
|
RhoPi(11, 6)
|
|
RhoPi(17,10)
|
|
RhoPi(18,15)
|
|
RhoPi( 3,21)
|
|
RhoPi( 5,28)
|
|
RhoPi(16,36)
|
|
RhoPi( 8,45)
|
|
RhoPi(21,55)
|
|
RhoPi(24, 2)
|
|
RhoPi( 4,14)
|
|
RhoPi(15,27)
|
|
RhoPi(23,41)
|
|
RhoPi(19,56)
|
|
RhoPi(13, 8)
|
|
RhoPi(12,25)
|
|
RhoPi( 2,43)
|
|
RhoPi(20,62)
|
|
RhoPi(14,18)
|
|
RhoPi(22,39)
|
|
RhoPi( 9,61)
|
|
RhoPi( 6,20)
|
|
RhoPi( 1,44)
|
|
#undef RhoPi
|
|
}
|
|
/* Chi */
|
|
for (x = 0; x <= 40;) {
|
|
uint32_t BC0, BC1, BC2, BC3, BC4;
|
|
BC0 = s32[x + 0*2];
|
|
BC1 = s32[x + 1*2];
|
|
BC2 = s32[x + 2*2];
|
|
s32[x + 0*2] = BC0 ^ ((~BC1) & BC2);
|
|
BC3 = s32[x + 3*2];
|
|
s32[x + 1*2] = BC1 ^ ((~BC2) & BC3);
|
|
BC4 = s32[x + 4*2];
|
|
s32[x + 2*2] = BC2 ^ ((~BC3) & BC4);
|
|
s32[x + 3*2] = BC3 ^ ((~BC4) & BC0);
|
|
s32[x + 4*2] = BC4 ^ ((~BC0) & BC1);
|
|
x++;
|
|
BC0 = s32[x + 0*2];
|
|
BC1 = s32[x + 1*2];
|
|
BC2 = s32[x + 2*2];
|
|
s32[x + 0*2] = BC0 ^ ((~BC1) & BC2);
|
|
BC3 = s32[x + 3*2];
|
|
s32[x + 1*2] = BC1 ^ ((~BC2) & BC3);
|
|
BC4 = s32[x + 4*2];
|
|
s32[x + 2*2] = BC2 ^ ((~BC3) & BC4);
|
|
s32[x + 3*2] = BC3 ^ ((~BC4) & BC0);
|
|
s32[x + 4*2] = BC4 ^ ((~BC0) & BC1);
|
|
x += 9;
|
|
}
|
|
/* Iota */
|
|
s32[0] ^= IOTA_CONST_0bits & 1;
|
|
IOTA_CONST_0bits >>= 1;
|
|
s32[1] ^= IOTA_CONST_1[round];
|
|
}
|
|
|
|
combine_halves(state);
|
|
#else
|
|
/* Native 64-bit algorithm */
|
|
static const uint16_t IOTA_CONST[NROUNDS] ALIGN2 = {
|
|
/* Elements should be 64-bit, but top half is always zero
|
|
* or 0x80000000. We encode 63rd bits in a separate word below.
|
|
* Same is true for 31th bits, which lets us use 16-bit table
|
|
* instead of 64-bit. The speed penalty is lost in the noise.
|
|
*/
|
|
0x0001,
|
|
0x8082,
|
|
0x808a,
|
|
0x8000,
|
|
0x808b,
|
|
0x0001,
|
|
0x8081,
|
|
0x8009,
|
|
0x008a,
|
|
0x0088,
|
|
0x8009,
|
|
0x000a,
|
|
0x808b,
|
|
0x008b,
|
|
0x8089,
|
|
0x8003,
|
|
0x8002,
|
|
0x0080,
|
|
0x800a,
|
|
0x000a,
|
|
0x8081,
|
|
0x8080,
|
|
0x0001,
|
|
0x8008,
|
|
};
|
|
/* bit for CONST[0] is in msb: 0011 0011 0000 0111 1101 1101 */
|
|
const uint32_t IOTA_CONST_bit63 = (uint32_t)(0x3307dd00);
|
|
/* bit for CONST[0] is in msb: 0001 0110 0011 1000 0001 1011 */
|
|
const uint32_t IOTA_CONST_bit31 = (uint32_t)(0x16381b00);
|
|
|
|
static const uint8_t ROT_CONST[24] ALIGN1 = {
|
|
1, 3, 6, 10, 15, 21, 28, 36, 45, 55, 2, 14,
|
|
27, 41, 56, 8, 25, 43, 62, 18, 39, 61, 20, 44,
|
|
};
|
|
static const uint8_t PI_LANE[24] ALIGN1 = {
|
|
10, 7, 11, 17, 18, 3, 5, 16, 8, 21, 24, 4,
|
|
15, 23, 19, 13, 12, 2, 20, 14, 22, 9, 6, 1,
|
|
};
|
|
/*static const uint8_t MOD5[10] ALIGN1 = { 0, 1, 2, 3, 4, 0, 1, 2, 3, 4, };*/
|
|
|
|
unsigned x;
|
|
unsigned round;
|
|
|
|
if (BB_BIG_ENDIAN) {
|
|
for (x = 0; x < 25; x++) {
|
|
state[x] = SWAP_LE64(state[x]);
|
|
}
|
|
}
|
|
|
|
for (round = 0; round < NROUNDS; ++round) {
|
|
/* Theta */
|
|
{
|
|
uint64_t BC[10];
|
|
for (x = 0; x < 5; ++x) {
|
|
BC[x + 5] = BC[x] = state[x]
|
|
^ state[x + 5] ^ state[x + 10]
|
|
^ state[x + 15] ^ state[x + 20];
|
|
}
|
|
/* Using 2x5 vector above eliminates the need to use
|
|
* BC[MOD5[x+N]] trick below to fetch BC[(x+N) % 5],
|
|
* and the code is a bit _smaller_.
|
|
*/
|
|
for (x = 0; x < 5; ++x) {
|
|
uint64_t temp = BC[x + 4] ^ rotl64(BC[x + 1], 1);
|
|
state[x] ^= temp;
|
|
state[x + 5] ^= temp;
|
|
state[x + 10] ^= temp;
|
|
state[x + 15] ^= temp;
|
|
state[x + 20] ^= temp;
|
|
}
|
|
}
|
|
|
|
/* Rho Pi */
|
|
if (SHA3_SMALL) {
|
|
uint64_t t1 = state[1];
|
|
for (x = 0; x < 24; ++x) {
|
|
uint64_t t0 = state[PI_LANE[x]];
|
|
state[PI_LANE[x]] = rotl64(t1, ROT_CONST[x]);
|
|
t1 = t0;
|
|
}
|
|
} else {
|
|
/* Especially large benefit for 32-bit arch (75% faster):
|
|
* 64-bit rotations by non-constant usually are SLOW on those.
|
|
* We resort to unrolling here.
|
|
* This optimizes out PI_LANE[] and ROT_CONST[],
|
|
* but generates 300-500 more bytes of code.
|
|
*/
|
|
uint64_t t0;
|
|
uint64_t t1 = state[1];
|
|
#define RhoPi_twice(x) \
|
|
t0 = state[PI_LANE[x ]]; \
|
|
state[PI_LANE[x ]] = rotl64(t1, ROT_CONST[x ]); \
|
|
t1 = state[PI_LANE[x+1]]; \
|
|
state[PI_LANE[x+1]] = rotl64(t0, ROT_CONST[x+1]);
|
|
RhoPi_twice(0); RhoPi_twice(2);
|
|
RhoPi_twice(4); RhoPi_twice(6);
|
|
RhoPi_twice(8); RhoPi_twice(10);
|
|
RhoPi_twice(12); RhoPi_twice(14);
|
|
RhoPi_twice(16); RhoPi_twice(18);
|
|
RhoPi_twice(20); RhoPi_twice(22);
|
|
#undef RhoPi_twice
|
|
}
|
|
/* Chi */
|
|
# if LONG_MAX > 0x7fffffff
|
|
for (x = 0; x <= 20; x += 5) {
|
|
uint64_t BC0, BC1, BC2, BC3, BC4;
|
|
BC0 = state[x + 0];
|
|
BC1 = state[x + 1];
|
|
BC2 = state[x + 2];
|
|
state[x + 0] = BC0 ^ ((~BC1) & BC2);
|
|
BC3 = state[x + 3];
|
|
state[x + 1] = BC1 ^ ((~BC2) & BC3);
|
|
BC4 = state[x + 4];
|
|
state[x + 2] = BC2 ^ ((~BC3) & BC4);
|
|
state[x + 3] = BC3 ^ ((~BC4) & BC0);
|
|
state[x + 4] = BC4 ^ ((~BC0) & BC1);
|
|
}
|
|
# else
|
|
/* Reduced register pressure version
|
|
* for register-starved 32-bit arches
|
|
* (i386: -95 bytes, and it is _faster_)
|
|
*/
|
|
for (x = 0; x <= 40;) {
|
|
uint32_t BC0, BC1, BC2, BC3, BC4;
|
|
uint32_t *const s32 = (uint32_t*)state;
|
|
# if SHA3_SMALL
|
|
do_half:
|
|
# endif
|
|
BC0 = s32[x + 0*2];
|
|
BC1 = s32[x + 1*2];
|
|
BC2 = s32[x + 2*2];
|
|
s32[x + 0*2] = BC0 ^ ((~BC1) & BC2);
|
|
BC3 = s32[x + 3*2];
|
|
s32[x + 1*2] = BC1 ^ ((~BC2) & BC3);
|
|
BC4 = s32[x + 4*2];
|
|
s32[x + 2*2] = BC2 ^ ((~BC3) & BC4);
|
|
s32[x + 3*2] = BC3 ^ ((~BC4) & BC0);
|
|
s32[x + 4*2] = BC4 ^ ((~BC0) & BC1);
|
|
x++;
|
|
# if SHA3_SMALL
|
|
if (x & 1)
|
|
goto do_half;
|
|
x += 8;
|
|
# else
|
|
BC0 = s32[x + 0*2];
|
|
BC1 = s32[x + 1*2];
|
|
BC2 = s32[x + 2*2];
|
|
s32[x + 0*2] = BC0 ^ ((~BC1) & BC2);
|
|
BC3 = s32[x + 3*2];
|
|
s32[x + 1*2] = BC1 ^ ((~BC2) & BC3);
|
|
BC4 = s32[x + 4*2];
|
|
s32[x + 2*2] = BC2 ^ ((~BC3) & BC4);
|
|
s32[x + 3*2] = BC3 ^ ((~BC4) & BC0);
|
|
s32[x + 4*2] = BC4 ^ ((~BC0) & BC1);
|
|
x += 9;
|
|
# endif
|
|
}
|
|
# endif /* long is 32-bit */
|
|
/* Iota */
|
|
state[0] ^= IOTA_CONST[round]
|
|
| (uint32_t)((IOTA_CONST_bit31 << round) & 0x80000000)
|
|
| (uint64_t)((IOTA_CONST_bit63 << round) & 0x80000000) << 32;
|
|
}
|
|
|
|
if (BB_BIG_ENDIAN) {
|
|
for (x = 0; x < 25; x++) {
|
|
state[x] = SWAP_LE64(state[x]);
|
|
}
|
|
}
|
|
#endif
|
|
}
|
|
|
|
void FAST_FUNC sha3_begin(sha3_ctx_t *ctx)
|
|
{
|
|
memset(ctx, 0, sizeof(*ctx));
|
|
/* SHA3-512, user can override */
|
|
ctx->input_block_bytes = (1600 - 512*2) / 8; /* 72 bytes */
|
|
}
|
|
|
|
void FAST_FUNC sha3_hash(sha3_ctx_t *ctx, const void *buffer, size_t len)
|
|
{
|
|
#if SHA3_SMALL
|
|
const uint8_t *data = buffer;
|
|
unsigned bufpos = ctx->bytes_queued;
|
|
|
|
while (1) {
|
|
unsigned remaining = ctx->input_block_bytes - bufpos;
|
|
if (remaining > len)
|
|
remaining = len;
|
|
len -= remaining;
|
|
/* XOR data into buffer */
|
|
while (remaining != 0) {
|
|
uint8_t *buf = (uint8_t*)ctx->state;
|
|
buf[bufpos] ^= *data++;
|
|
bufpos++;
|
|
remaining--;
|
|
}
|
|
|
|
/* Clever way to do "if (bufpos != N) break; ... ; bufpos = 0;" */
|
|
bufpos -= ctx->input_block_bytes;
|
|
if (bufpos != 0)
|
|
break;
|
|
|
|
/* Buffer is filled up, process it */
|
|
sha3_process_block72(ctx->state);
|
|
/*bufpos = 0; - already is */
|
|
}
|
|
ctx->bytes_queued = bufpos + ctx->input_block_bytes;
|
|
#else
|
|
/* +50 bytes code size, but a bit faster because of long-sized XORs */
|
|
const uint8_t *data = buffer;
|
|
unsigned bufpos = ctx->bytes_queued;
|
|
unsigned iblk_bytes = ctx->input_block_bytes;
|
|
|
|
/* If already data in queue, continue queuing first */
|
|
if (bufpos != 0) {
|
|
while (len != 0) {
|
|
uint8_t *buf = (uint8_t*)ctx->state;
|
|
buf[bufpos] ^= *data++;
|
|
len--;
|
|
bufpos++;
|
|
if (bufpos == iblk_bytes) {
|
|
bufpos = 0;
|
|
goto do_block;
|
|
}
|
|
}
|
|
}
|
|
|
|
/* Absorb complete blocks */
|
|
while (len >= iblk_bytes) {
|
|
/* XOR data onto beginning of state[].
|
|
* We try to be efficient - operate one word at a time, not byte.
|
|
* Careful wrt unaligned access: can't just use "*(long*)data"!
|
|
*/
|
|
unsigned count = iblk_bytes / sizeof(long);
|
|
long *buf = (long*)ctx->state;
|
|
do {
|
|
long v;
|
|
move_from_unaligned_long(v, (long*)data);
|
|
*buf++ ^= v;
|
|
data += sizeof(long);
|
|
} while (--count);
|
|
len -= iblk_bytes;
|
|
do_block:
|
|
sha3_process_block72(ctx->state);
|
|
}
|
|
|
|
/* Queue remaining data bytes */
|
|
while (len != 0) {
|
|
uint8_t *buf = (uint8_t*)ctx->state;
|
|
buf[bufpos] ^= *data++;
|
|
bufpos++;
|
|
len--;
|
|
}
|
|
|
|
ctx->bytes_queued = bufpos;
|
|
#endif
|
|
}
|
|
|
|
unsigned FAST_FUNC sha3_end(sha3_ctx_t *ctx, void *resbuf)
|
|
{
|
|
/* Padding */
|
|
uint8_t *buf = (uint8_t*)ctx->state;
|
|
/*
|
|
* Keccak block padding is: add 1 bit after last bit of input,
|
|
* then add zero bits until the end of block, and add the last 1 bit
|
|
* (the last bit in the block) - the "10*1" pattern.
|
|
* SHA3 standard appends additional two bits, 01, before that padding:
|
|
*
|
|
* SHA3-224(M) = KECCAK[448](M||01, 224)
|
|
* SHA3-256(M) = KECCAK[512](M||01, 256)
|
|
* SHA3-384(M) = KECCAK[768](M||01, 384)
|
|
* SHA3-512(M) = KECCAK[1024](M||01, 512)
|
|
* (M is the input, || is bit concatenation)
|
|
*
|
|
* The 6 below contains 01 "SHA3" bits and the first 1 "Keccak" bit:
|
|
*/
|
|
buf[ctx->bytes_queued] ^= 6; /* bit pattern 00000110 */
|
|
buf[ctx->input_block_bytes - 1] ^= 0x80;
|
|
|
|
sha3_process_block72(ctx->state);
|
|
|
|
/* Output */
|
|
memcpy(resbuf, ctx->state, 64);
|
|
return 64;
|
|
}
|