Implement SSE2 32 bit assembly algorithm as well.

13 years ago · 7dc3db2340
7 changed files with 479 additions and 7 deletions
--- a/Makefile.am
+++ b/Makefile.am
@ -22,7 +22,7 @@ cgminer_SOURCES	= elist.h miner.h compat.h bench_block.h	\
 		  ocl.c ocl.h findnonce.c findnonce.h 		\
 		  sha256_generic.c sha256_4way.c sha256_via.c	\
 		  sha256_cryptopp.c sha256_sse2_amd64.c		\
-		  sha256_sse4_amd64.c \
+		  sha256_sse4_amd64.c sha256_sse2_i386.c		\
 		  phatk110817.cl poclbm110817.cl
 cgminer_LDFLAGS	= $(PTHREAD_FLAGS)
@ -35,4 +35,10 @@ SUBDIRS		+= x86_64
 cgminer_LDADD	+= x86_64/libx8664.a
 AM_CFLAGS	= -DHAS_YASM
 endif
 else
 if HAS_YASM
 SUBDIRS		+= x86_32
 cgminer_LDADD	+= x86_32/libx8632.a
 AM_CFLAGS	= -DHAS_YASM
 endif
 endif
--- a/configure.ac
+++ b/configure.ac
@ -119,7 +119,7 @@ if test "x$YASM" != "xfalse" ; then
  fi
 fi
 if test "x$has_yasm" = "xfalse" ; then
-  AC_MSG_NOTICE([yasm is required for the sse2_64 algorithm. It will be skipped.])
+  AC_MSG_NOTICE([yasm is required for the assembly algorithms. They will be skipped.])
 fi
 AM_CONDITIONAL([HAS_YASM], [test x$has_yasm = xtrue])
@ -176,6 +176,7 @@ AC_CONFIG_FILES([
 	compat/Makefile
 	compat/jansson/Makefile
 	x86_64/Makefile
 	x86_32/Makefile
 	ccan/Makefile
 	lib/Makefile
 	])
--- a/main.c
+++ b/main.c
@ -106,6 +106,7 @@ enum sha256_algos {
 	ALGO_VIA,		/* VIA padlock */
 	ALGO_CRYPTOPP,		/* Crypto++ (C) */
 	ALGO_CRYPTOPP_ASM32,	/* Crypto++ 32-bit assembly */
 	ALGO_SSE2_32,		/* SSE2 for x86_32 */
 	ALGO_SSE2_64,		/* SSE2 for x86_64 */
 	ALGO_SSE4_64,		/* SSE4 for x86_64 */
 };
@ -142,6 +143,9 @@ static const char *algo_names[] = {
 #ifdef WANT_CRYPTOPP_ASM32
 	[ALGO_CRYPTOPP_ASM32]	= "cryptopp_asm32",
 #endif
 #ifdef WANT_X8632_SSE2
 	[ALGO_SSE2_32]		= "sse2_32",
 #endif
 #ifdef WANT_X8664_SSE2
 	[ALGO_SSE2_64]		= "sse2_64",
 #endif
@ -163,6 +167,9 @@ static const sha256_func sha256_funcs[] = {
 #ifdef WANT_CRYPTOPP_ASM32
 	[ALGO_CRYPTOPP_ASM32]	= (sha256_func)scanhash_asm32,
 #endif
 #ifdef WANT_X8632_SSE2
 	[ALGO_SSE2_32]		= (sha256_func)scanhash_sse2_32,
 #endif
 #ifdef WANT_X8664_SSE2
 	[ALGO_SSE2_64]		= (sha256_func)scanhash_sse2_64,
 #endif
@ -193,10 +200,10 @@ int opt_scantime = 60;
 int opt_bench_algo = -1;
 static const bool opt_time = true;
 static bool opt_restart = true;
-#if defined(WANT_X8664_SSE4) && defined(__SSE4_1__)
+#if defined(WANT_X8664_SSE2) && defined(__SSE2__)
 static enum sha256_algos opt_algo = ALGO_SSE4_64;
 #elif defined(WANT_X8664_SSE2) && defined(__SSE2__)
 static enum sha256_algos opt_algo = ALGO_SSE2_64;
 #elif defined(WANT_X8632_SSE2) && defined(__SSE2__)
 static enum sha256_algos opt_algo = ALGO_SSE2_32;
 #else
 static enum sha256_algos opt_algo = ALGO_C;
 #endif
@ -818,6 +825,10 @@ static enum sha256_algos pick_fastest_algo()
 		bench_algo(&best_rate, &best_algo, ALGO_CRYPTOPP_ASM32);
 	#endif
 	#if defined(WANT_X8632_SSE2)
 		bench_algo(&best_rate, &best_algo, ALGO_SSE2_32);
 	#endif
 	#if defined(WANT_X8664_SSE2)
 		bench_algo(&best_rate, &best_algo, ALGO_SSE2_64);
 	#endif
@ -1042,11 +1053,14 @@ static struct opt_table opt_config_table[] = {
 #ifdef WANT_CRYPTOPP_ASM32
 		     "\n\tcryptopp_asm32\tCrypto++ 32-bit assembler implementation"
 #endif
 #ifdef WANT_X8632_SSE2
 		     "\n\tsse2_32\t\tSSE2 32 bit implementation for i386 machines"
 #endif
 #ifdef WANT_X8664_SSE2
-		     "\n\tsse2_64\t\tSSE2 implementation for x86_64 machines"
+		     "\n\tsse2_64\t\tSSE2 64 bit implementation for x86_64 machines"
 #endif
 #ifdef WANT_X8664_SSE4
-		     "\n\tsse4_64\t\tSSE4 implementation for x86_64 machines"
+		     "\n\tsse4_64\t\tSSE4.1 64 bit implementation for x86_64 machines"
 #endif
 		),
 	OPT_WITH_ARG("--bench-algo|-b",
@ -3305,6 +3319,19 @@ static void *miner_thread(void *userdata)
 					work->blk.nonce);
 			break;
 #ifdef WANT_X8632_SSE2
 		case ALGO_SSE2_32: {
 			unsigned int rc5 =
 			        scanhash_sse2_32(thr_id, work->midstate, work->data + 64,
 						 work->hash1, work->hash,
 						 work->target,
 					         max_nonce, &hashes_done,
 						 work->blk.nonce);
 			rc = (rc5 == -1) ? false : true;
 			}
 			break;
 #endif
 #ifdef WANT_X8664_SSE2
 		case ALGO_SSE2_64: {
 			unsigned int rc5 =
--- a/miner.h
+++ b/miner.h
@ -55,6 +55,10 @@ void *alloca (size_t);
 #define WANT_SSE2_4WAY 1
 #endif
 #if defined(__i386__) && defined(HAS_YASM)
 #define WANT_X8632_SSE2 1
 #endif
 #if defined(__i386__) || defined(__x86_64__)
 #define WANT_VIA_PADLOCK 1
 #endif
@ -297,6 +301,12 @@ extern int scanhash_sse4_64(int, const unsigned char *pmidstate, unsigned char *
 	uint32_t max_nonce, unsigned long *nHashesDone,
 	uint32_t nonce);
 extern int scanhash_sse2_32(int, const unsigned char *pmidstate, unsigned char *pdata,
 	unsigned char *phash1, unsigned char *phash,
 	const unsigned char *ptarget,
 	uint32_t max_nonce, unsigned long *nHashesDone,
 	uint32_t nonce);
 extern int
 timeval_subtract (struct timeval *result, struct timeval *x, struct timeval *y);
--- a/sha256_sse2_i386.c
+++ b/sha256_sse2_i386.c
@ -0,0 +1,136 @@
 /*
 * SHA-256 driver for ASM routine for x86_64 on Linux
 * Copyright (c) Mark Crichton <crichton@gimp.org>
 *
 * This program is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License as published by the Free
 * Software Foundation; either version 2 of the License, or (at your option)
 * any later version.
 *
 */
 #include "config.h"
 #include "miner.h"
 #ifdef WANT_X8632_SSE2
 #include <string.h>
 #include <assert.h>
 #include <xmmintrin.h>
 #include <stdint.h>
 #include <stdio.h>
 extern void CalcSha256_x86 (__m128i *res, __m128i *data, const uint32_t init[8])__attribute__((fastcall));
 static uint32_t g_sha256_k[]__attribute__((aligned(0x100))) = {
    0x428a2f98, 0x71374491, 0xb5c0fbcf, 0xe9b5dba5, /*  0 */
    0x3956c25b, 0x59f111f1, 0x923f82a4, 0xab1c5ed5,
    0xd807aa98, 0x12835b01, 0x243185be, 0x550c7dc3, /*  8 */
    0x72be5d74, 0x80deb1fe, 0x9bdc06a7, 0xc19bf174,
    0xe49b69c1, 0xefbe4786, 0x0fc19dc6, 0x240ca1cc, /* 16 */
    0x2de92c6f, 0x4a7484aa, 0x5cb0a9dc, 0x76f988da,
    0x983e5152, 0xa831c66d, 0xb00327c8, 0xbf597fc7, /* 24 */
    0xc6e00bf3, 0xd5a79147, 0x06ca6351, 0x14292967,
    0x27b70a85, 0x2e1b2138, 0x4d2c6dfc, 0x53380d13, /* 32 */
    0x650a7354, 0x766a0abb, 0x81c2c92e, 0x92722c85,
    0xa2bfe8a1, 0xa81a664b, 0xc24b8b70, 0xc76c51a3, /* 40 */
    0xd192e819, 0xd6990624, 0xf40e3585, 0x106aa070,
    0x19a4c116, 0x1e376c08, 0x2748774c, 0x34b0bcb5, /* 48 */
    0x391c0cb3, 0x4ed8aa4a, 0x5b9cca4f, 0x682e6ff3,
    0x748f82ee, 0x78a5636f, 0x84c87814, 0x8cc70208, /* 56 */
    0x90befffa, 0xa4506ceb, 0xbef9a3f7, 0xc67178f2
 };
 const uint32_t sha256_32init[8]__attribute__((aligned(0x100))) =
 {0x6a09e667, 0xbb67ae85, 0x3c6ef372, 0xa54ff53a, 0x510e527f, 0x9b05688c, 0x1f83d9ab, 0x5be0cd19};
 __m128i g_4sha256_k[64];
 __m128i sha256_consts_m128i[64]__attribute__((aligned(0x1000)));
 int scanhash_sse2_32(int thr_id, const unsigned char *pmidstate,
 	unsigned char *pdata,
 	unsigned char *phash1, unsigned char *phash,
 	const unsigned char *ptarget,
 	uint32_t max_nonce, unsigned long *nHashesDone,
 	uint32_t nonce)
 {
    uint32_t *nNonce_p = (uint32_t *)(pdata + 12);
    uint32_t m_midstate[8], m_w[16], m_w1[16];
    __m128i m_4w[64] __attribute__ ((aligned (0x100)));
    __m128i m_4hash[64] __attribute__ ((aligned (0x100)));
    __m128i m_4hash1[64] __attribute__ ((aligned (0x100)));
    __m128i offset;
    int i;
    work_restart[thr_id].restart = 0;
    /* For debugging */
    union {
        __m128i m;
        uint32_t i[4];
    } mi;
    /* Message expansion */
    memcpy(m_midstate, pmidstate, sizeof(m_midstate));
    memcpy(m_w, pdata, sizeof(m_w)); /* The 2nd half of the data */
    memcpy(m_w1, phash1, sizeof(m_w1));
    memset(m_4hash, 0, sizeof(m_4hash));
    /* Transmongrify */
    for (i = 0; i < 16; i++)
        m_4w[i] = _mm_set1_epi32(m_w[i]);
    for (i = 0; i < 16; i++)
        m_4hash1[i] = _mm_set1_epi32(m_w1[i]);
    for (i = 0; i < 64; i++)
 	sha256_consts_m128i[i] = _mm_set1_epi32(g_sha256_k[i]);
    offset = _mm_set_epi32(0x3, 0x2, 0x1, 0x0);
    for (;;)
    {
 	int j;
 	m_4w[3] = _mm_add_epi32(offset, _mm_set1_epi32(nonce));
 	/* Some optimization can be done here W.R.T. precalculating some hash */
 	CalcSha256_x86 (m_4hash1, m_4w, m_midstate);
 	CalcSha256_x86 (m_4hash, m_4hash1, sha256_32init);
 	for (j = 0; j < 4; j++) {
 	    mi.m = m_4hash[7];
 	    if (unlikely(mi.i[j] == 0))
 		break;
        }
 	/* If j = true, we found a hit...so check it */
 	/* Use the C version for a check... */
 	if (unlikely(j != 4)) {
 		for (i = 0; i < 8; i++) {
 		    mi.m = m_4hash[i];
 		    *(uint32_t *)&(phash)[i*4] = mi.i[j];
 		}
 		if (fulltest(phash, ptarget)) {
 		     *nHashesDone = nonce;
 		     *nNonce_p = nonce + j;
 		     return nonce + j;
 		}
 	}
 	nonce += 4;
        if (unlikely((nonce >= max_nonce) || work_restart[thr_id].restart))
        {
            *nHashesDone = nonce;
            return -1;
 	}
   }
 }
 #endif /* WANT_X8632_SSE2 */
--- a/x86_32/Makefile.am
+++ b/x86_32/Makefile.am
@ -0,0 +1,8 @@
 noinst_LIBRARIES	= libx8632.a
 SUFFIXES = .asm
 libx8632_a_SOURCES	= sha256_xmm.asm
 .asm.o:
 	$(YASM) -f elf32 $<
--- a/x86_32/sha256_xmm.asm
+++ b/x86_32/sha256_xmm.asm
@ -0,0 +1,284 @@
 ;; SHA-256 for X86 for Linux, based off of:
 ; (c) Ufasoft 2011 http://ufasoft.com mailto:support@ufasoft.com
 ; Version 2011
 ; This software is Public Domain
 ; SHA-256 CPU SSE cruncher for Bitcoin Miner
 ALIGN 32
 BITS 32
 %define hash ecx
 %define data edx
 %define init esi
 ; 0 = (1024 - 256) (mod (LAB_CALC_UNROLL*LAB_CALC_PARA*16))
 %define LAB_CALC_PARA	2
 %define LAB_CALC_UNROLL	8
 %define LAB_LOOP_UNROLL 8
 extern sha256_consts_m128i
 global CalcSha256_x86
 ;	CalcSha256	hash(ecx), data(edx), init([esp+4])
 CalcSha256_x86:
                push	esi
                push	edi
                mov	init, [esp+12]
 	push	ebx
 LAB_NEXT_NONCE:
 	mov	eax, 64*4					; 256 - rcx is # of SHA-2 rounds
 	mov	ebx, 16*4					; 64 - rax is where we expand to
 LAB_SHA:
 	push	eax
 	lea	eax, qword [data+eax*4]				; + 1024
 	lea	edi, qword [data+ebx*4]				; + 256
 LAB_CALC:
 %macro	lab_calc_blk 1
 	movdqa	xmm0, [edi-(15-%1)*16]				; xmm0 = W[I-15]
 	movdqa	xmm4, [edi-(15-(%1+1))*16]			; xmm4 = W[I-15+1]
 	movdqa	xmm2, xmm0					; xmm2 = W[I-15]
 	movdqa	xmm6, xmm4					; xmm6 = W[I-15+1]
 	psrld	xmm0, 3						; xmm0 = W[I-15] >> 3
 	psrld	xmm4, 3						; xmm4 = W[I-15+1] >> 3
 	movdqa	xmm1, xmm0					; xmm1 = W[I-15] >> 3
 	movdqa	xmm5, xmm4					; xmm5 = W[I-15+1] >> 3
 	pslld	xmm2, 14					; xmm2 = W[I-15] << 14
 	pslld	xmm6, 14					; xmm6 = W[I-15+1] << 14
 	psrld	xmm1, 4						; xmm1 = W[I-15] >> 7
 	psrld	xmm5, 4						; xmm5 = W[I-15+1] >> 7
 	pxor	xmm0, xmm1					; xmm0 = (W[I-15] >> 3) ^ (W[I-15] >> 7)
 	pxor	xmm4, xmm5					; xmm4 = (W[I-15+1] >> 3) ^ (W[I-15+1] >> 7)
 	psrld	xmm1, 11					; xmm1 = W[I-15] >> 18
 	psrld	xmm5, 11					; xmm5 = W[I-15+1] >> 18
 	pxor	xmm0, xmm2					; xmm0 = (W[I-15] >> 3) ^ (W[I-15] >> 7) ^ (W[I-15] << 14)
 	pxor	xmm4, xmm6					; xmm4 = (W[I-15+1] >> 3) ^ (W[I-15+1] >> 7) ^ (W[I-15+1] << 14)
 	pslld	xmm2, 11					; xmm2 = W[I-15] << 25
 	pslld	xmm6, 11					; xmm6 = W[I-15+1] << 25
 	pxor	xmm0, xmm1					; xmm0 = (W[I-15] >> 3) ^ (W[I-15] >> 7) ^ (W[I-15] << 14) ^ (W[I-15] >> 18)
 	pxor	xmm4, xmm5					; xmm4 = (W[I-15+1] >> 3) ^ (W[I-15+1] >> 7) ^ (W[I-15+1] << 14) ^ (W[I-15+1] >> 18)
 	pxor	xmm0, xmm2					; xmm0 = (W[I-15] >> 3) ^ (W[I-15] >> 7) ^ (W[I-15] << 14) ^ (W[I-15] >> 18) ^ (W[I-15] << 25)
 	pxor	xmm4, xmm6					; xmm4 = (W[I-15+1] >> 3) ^ (W[I-15+1] >> 7) ^ (W[I-15+1] << 14) ^ (W[I-15+1] >> 18) ^ (W[I-15+1] << 25)
 	movdqa	xmm3, [edi-(2-%1)*16]				; xmm3 = W[I-2]
 	movdqa	xmm7, [edi-(2-(%1+1))*16]			; xmm7 = W[I-2+1]
 	paddd	xmm0, [edi-(16-%1)*16]				; xmm0 = s0(W[I-15]) + W[I-16]
 	paddd	xmm4, [edi-(16-(%1+1))*16]			; xmm4 = s0(W[I-15+1]) + W[I-16+1]
 ;;;;;;;;;;;;;;;;;;
 	movdqa	xmm2, xmm3					; xmm2 = W[I-2]
 	movdqa	xmm6, xmm7					; xmm6 = W[I-2+1]
 	psrld	xmm3, 10					; xmm3 = W[I-2] >> 10
 	psrld	xmm7, 10					; xmm7 = W[I-2+1] >> 10
 	movdqa	xmm1, xmm3					; xmm1 = W[I-2] >> 10
 	movdqa	xmm5, xmm7					; xmm5 = W[I-2+1] >> 10
 	paddd	xmm0, [edi-(7-%1)*16]				; xmm0 = s0(W[I-15]) + W[I-16] + W[I-7]
 	pslld	xmm2, 13					; xmm2 = W[I-2] << 13
 	pslld	xmm6, 13					; xmm6 = W[I-2+1] << 13
 	psrld	xmm1, 7						; xmm1 = W[I-2] >> 17
 	psrld	xmm5, 7						; xmm5 = W[I-2+1] >> 17
 	paddd	xmm4, [edi-(7-(%1+1))*16]			; xmm4 = s0(W[I-15+1]) + W[I-16+1] + W[I-7+1]
 	pxor	xmm3, xmm1					; xmm3 = (W[I-2] >> 10) ^ (W[I-2] >> 17)
 	pxor	xmm7, xmm5					; xmm7 = (W[I-2+1] >> 10) ^ (W[I-2+1] >> 17)
 	psrld	xmm1, 2						; xmm1 = W[I-2] >> 19
 	psrld	xmm5, 2						; xmm5 = W[I-2+1] >> 19
 	pxor	xmm3, xmm2					; xmm3 = (W[I-2] >> 10) ^ (W[I-2] >> 17) ^ (W[I-2] << 13)
 	pxor	xmm7, xmm6					; xmm7 = (W[I-2+1] >> 10) ^ (W[I-2+1] >> 17) ^ (W[I-2+1] << 13)
 	pslld	xmm2, 2						; xmm2 = W[I-2] << 15
 	pslld	xmm6, 2						; xmm6 = W[I-2+1] << 15
 	pxor	xmm3, xmm1					; xmm3 = (W[I-2] >> 10) ^ (W[I-2] >> 17) ^ (W[I-2] << 13) ^ (W[I-2] >> 19)
 	pxor	xmm7, xmm5					; xmm7 = (W[I-2+1] >> 10) ^ (W[I-2+1] >> 17) ^ (W[I-2+1] << 13) ^ (W[I-2+1] >> 19)
 	pxor	xmm3, xmm2					; xmm3 = (W[I-2] >> 10) ^ (W[I-2] >> 17) ^ (W[I-2] << 13) ^ (W[I-2] >> 19) ^ (W[I-2] << 15)
 	pxor	xmm7, xmm6					; xmm7 = (W[I-2+1] >> 10) ^ (W[I-2+1] >> 17) ^ (W[I-2+1] << 13) ^ (W[I-2+1] >> 19) ^ (W[I-2+1] << 15)
 	paddd	xmm0, xmm3					; xmm0 = s0(W[I-15]) + W[I-16] + s1(W[I-2]) + W[I-7]
 	paddd	xmm4, xmm7					; xmm4 = s0(W[I-15+1]) + W[I-16+1] + s1(W[I-2+1]) + W[I-7+1]
 	movdqa	[edi+(%1*16)], xmm0
 	movdqa	[edi+((%1+1)*16)], xmm4
 %endmacro
 %assign i 0
 %rep    LAB_CALC_UNROLL
        lab_calc_blk i
 %assign i i+LAB_CALC_PARA
 %endrep
 	add	edi, LAB_CALC_UNROLL*LAB_CALC_PARA*16
 	cmp	edi, eax
 	jb	LAB_CALC
 	pop	eax
 	mov	ebx, 0
 ; Load the init values of the message into the hash.
 	movdqa	xmm7, [init]
 	pshufd	xmm5, xmm7, 0x55		; xmm5 == b
 	pshufd	xmm4, xmm7, 0xAA		; xmm4 == c
 	pshufd	xmm3, xmm7, 0xFF		; xmm3 == d
 	pshufd	xmm7, xmm7, 0			; xmm7 == a
 	movdqa	xmm0, [init+4*4]
 	pshufd	xmm1, xmm0, 0x55		; [hash+0*16] == f
 	movdqa	[hash+0*16], xmm1
 	pshufd	xmm1, xmm0, 0xAA		; [hash+1*16] == g
 	movdqa	[hash+1*16], xmm1
 	pshufd	xmm1, xmm0, 0xFF		; [hash+2*16] == h
 	movdqa	[hash+2*16], xmm1
 	pshufd	xmm0, xmm0, 0			; xmm0 == e
 LAB_LOOP:
 ;; T t1 = h + (Rotr32(e, 6) ^ Rotr32(e, 11) ^ Rotr32(e, 25)) + ((e & f) ^ AndNot(e, g)) + Expand32<T>(g_sha256_k[j]) + w[j]
 %macro	lab_loop_blk 0
 	movdqa	xmm6, [data+ebx*4]
 	paddd	xmm6, sha256_consts_m128i[ebx*4]
 	add	ebx, 4
 	paddd	xmm6, [hash+2*16]		; +h
 	movdqa	xmm1, xmm0
 	movdqa	xmm2, [hash+1*16]
 	pandn	xmm1, xmm2	; ~e & g
 	movdqa	[hash+2*16], xmm2		; h = g
 	movdqa	xmm2, [hash+0*16]		; f
 	movdqa	[hash+1*16], xmm2		; g = f
 	pand	xmm2, xmm0	; e & f
 	pxor	xmm1, xmm2	; (e & f) ^ (~e & g)
 	movdqa	[hash+0*16], xmm0		; f = e
 	paddd	xmm6, xmm1	; Ch + h + w[i] + k[i]
 	movdqa	xmm1, xmm0
 	psrld	xmm0, 6
 	movdqa	xmm2, xmm0
 	pslld	xmm1, 7
 	psrld	xmm2, 5
 	pxor	xmm0, xmm1
 	pxor	xmm0, xmm2
 	pslld	xmm1, 14
 	psrld	xmm2, 14
 	pxor	xmm0, xmm1
 	pxor	xmm0, xmm2
 	pslld	xmm1, 5
 	pxor	xmm0, xmm1	; Rotr32(e, 6) ^ Rotr32(e, 11) ^ Rotr32(e, 25)
 	paddd	xmm6, xmm0	; xmm6 = t1
 	movdqa	xmm0, xmm3	; d
 	paddd	xmm0, xmm6	; e = d+t1
 	movdqa	xmm1, xmm5	; =b
 	movdqa	xmm3, xmm4	; d = c
 	movdqa	xmm2, xmm4	; c
 	pand	xmm2, xmm5	; b & c
 	pand	xmm4, xmm7	; a & c
 	pand	xmm1, xmm7	; a & b
 	pxor	xmm1, xmm4
 	movdqa	xmm4, xmm5	; c = b
 	movdqa	xmm5, xmm7	; b = a
 	pxor	xmm1, xmm2	; (a & c) ^ (a & d) ^ (c & d)
 	paddd	xmm6, xmm1	; t1 + ((a & c) ^ (a & d) ^ (c & d))
 	movdqa	xmm2, xmm7
 	psrld	xmm7, 2
 	movdqa	xmm1, xmm7
 	pslld	xmm2, 10
 	psrld	xmm1, 11
 	pxor	xmm7, xmm2
 	pxor	xmm7, xmm1
 	pslld	xmm2, 9
 	psrld	xmm1, 9
 	pxor	xmm7, xmm2
 	pxor	xmm7, xmm1
 	pslld	xmm2, 11
 	pxor	xmm7, xmm2
 	paddd	xmm7, xmm6	; a = t1 + (Rotr32(a, 2) ^ Rotr32(a, 13) ^ Rotr32(a, 22)) + ((a & c) ^ (a & d) ^ (c & d));
 %endmacro
 %assign i 0
 %rep    LAB_LOOP_UNROLL
        lab_loop_blk
 %assign i i+1
 %endrep
 	cmp	ebx, eax
 	jb	LAB_LOOP
 ; Finished the 64 rounds, calculate hash and save
 	movdqa	xmm1, [init]
 	pshufd	xmm2, xmm1, 0x55
 	pshufd	xmm6, xmm1, 0xAA
 	movdqa	[hash+3*16], xmm6
 	pshufd	xmm6, xmm1, 0xFF
 	movdqa	[hash+4*16], xmm6
 	pshufd	xmm1, xmm1, 0
 	paddd	xmm5, xmm2
 	paddd	xmm4, [hash+3*16]
 	paddd	xmm3, [hash+4*16]
 	paddd	xmm7, xmm1
 	movdqa	xmm1, [init+4*4]
 	pshufd	xmm2, xmm1, 0x55
 	pshufd	xmm6, xmm1, 0xAA
 	movdqa	[hash+3*16], xmm6
 	pshufd	xmm6, xmm1, 0xFF
 	movdqa	[hash+4*16], xmm6
 	pshufd	xmm1, xmm1, 0
 	movdqa	xmm6, [hash+0*16]
 	paddd	xmm2, xmm6
 	movdqa	[hash+0*16], xmm2
 	movdqa	xmm2, [hash+3*16]
 	movdqa	xmm6, [hash+1*16]
 	paddd	xmm2, xmm6
 	movdqa	[hash+1*16], xmm2
 	movdqa	xmm2, [hash+4*16]
 	movdqa	xmm6, [hash+2*16]
 	paddd	xmm2, xmm6
 	movdqa	[hash+2*16], xmm2
 	paddd	xmm0, xmm1
 	movdqa	xmm1, [hash+0*16]
 	movdqa	xmm2, [hash+1*16]
 	movdqa	xmm6, [hash+2*16]
 	movdqa	[hash+0*16], xmm7
 	movdqa	[hash+1*16], xmm5
 	movdqa	[hash+2*16], xmm4
 	movdqa	[hash+3*16], xmm3
 	movdqa	[hash+4*16], xmm0
 	movdqa	[hash+5*16], xmm1
 	movdqa	[hash+6*16], xmm2
 	movdqa	[hash+7*16], xmm6
 LAB_RET:
 	pop	ebx
                pop	edi
                pop	esi
                retn	4