/*********************************************************************/ /* Copyright 2009, 2010 The University of Texas at Austin. */ /* All rights reserved. */ /* */ /* Redistribution and use in source and binary forms, with or */ /* without modification, are permitted provided that the following */ /* conditions are met: */ /* */ /* 1. Redistributions of source code must retain the above */ /* copyright notice, this list of conditions and the following */ /* disclaimer. */ /* */ /* 2. Redistributions in binary form must reproduce the above */ /* copyright notice, this list of conditions and the following */ /* disclaimer in the documentation and/or other materials */ /* provided with the distribution. */ /* */ /* THIS SOFTWARE IS PROVIDED BY THE UNIVERSITY OF TEXAS AT */ /* AUSTIN ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, */ /* INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF */ /* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE */ /* DISCLAIMED. IN NO EVENT SHALL THE UNIVERSITY OF TEXAS AT */ /* AUSTIN OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, */ /* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES */ /* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE */ /* GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR */ /* BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF */ /* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT */ /* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT */ /* OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE */ /* POSSIBILITY OF SUCH DAMAGE. */ /* */ /* The views and conclusions contained in the software and */ /* documentation are those of the authors and should not be */ /* interpreted as representing official policies, either expressed */ /* or implied, of The University of Texas at Austin. */ /*********************************************************************/ #define ASSEMBLER #include "common.h" #ifdef OPTERON #define PREFETCH prefetch #define PREFETCHW prefetchw #else #define PREFETCH prefetcht0 #define PREFETCHW prefetcht0 #endif #define PREFETCHSIZE (5 + 4 * 10) #define STACK 16 #define ARGS 16 #define J 0 + STACK(%esp) #define KK 4 + STACK(%esp) #define KKK 8 + STACK(%esp) #define AORIG 12 + STACK(%esp) #define M 4 + STACK + ARGS(%esp) #define N 8 + STACK + ARGS(%esp) #define K 12 + STACK + ARGS(%esp) #define ALPHA 16 + STACK + ARGS(%esp) #define A 32 + STACK + ARGS(%esp) #define ARG_B 36 + STACK + ARGS(%esp) #define C 40 + STACK + ARGS(%esp) #define ARG_LDC 44 + STACK + ARGS(%esp) #define OFFSET 48 + STACK + ARGS(%esp) #define I %esi #define B %ebx #define CO %edi #define AO %edx #define BO %ecx #define LDC %ebp #define PREFETCH_OFFSET 48 PROLOGUE subl $ARGS, %esp # Generate Stack Frame pushl %ebp pushl %edi pushl %esi pushl %ebx PROFCODE movl ARG_LDC, LDC movl ARG_B, B sall $BASE_SHIFT, LDC addl $8 * SIZE, A addl $8 * SIZE, B #ifdef LN movl M, %eax sall $BASE_SHIFT, %eax addl %eax, C imull K, %eax addl %eax, A #endif #ifdef RT movl N, %eax sall $BASE_SHIFT, %eax imull K, %eax addl %eax, B movl N, %eax imull %ebp, %eax addl %eax, C #endif #ifdef RN movl OFFSET, %eax negl %eax movl %eax, KK #endif #ifdef RT movl N, %eax subl OFFSET, %eax movl %eax, KK #endif movl N, %eax sarl $1, %eax movl %eax, J je .L30 ALIGN_4 .L01: #if defined(LT) || defined(RN) movl A, AO #else movl A, %eax movl %eax, AORIG #endif #ifdef RT movl K, %eax sall $1 + BASE_SHIFT, %eax subl %eax, B #endif lea (, LDC, 2), %eax #ifdef RT subl %eax, C #endif movl C, CO #ifndef RT addl %eax, C #endif #ifdef LN movl OFFSET, %eax addl M, %eax movl %eax, KK #endif #ifdef LT movl OFFSET, %eax movl %eax, KK #endif movl M, %eax andl $1, %eax je .L20 ALIGN_4 .L21: #ifdef LN movl K, %eax sall $0 + BASE_SHIFT, %eax subl %eax, AORIG #endif #if defined(LN) || defined(RT) movl KK, %eax sall $BASE_SHIFT, %eax movl AORIG, AO leal (AO, %eax, 1), AO leal (B, %eax, 2), BO #else movl B, BO #endif fldz fldz #if defined(LT) || defined(RN) movl KK, %eax #else movl K, %eax subl KK, %eax #endif sarl $2, %eax je .L25 ALIGN_4 .L22: PREFETCH (PREFETCHSIZE + 0) * SIZE(AO) FLD -8 * SIZE(AO) FLD -8 * SIZE(BO) fmul %st(1), %st faddp %st, %st(2) FLD -7 * SIZE(BO) fmulp %st, %st(1) faddp %st, %st(2) FLD -7 * SIZE(AO) FLD -6 * SIZE(BO) fmul %st(1), %st faddp %st, %st(2) FLD -5 * SIZE(BO) fmulp %st, %st(1) faddp %st, %st(2) FLD -6 * SIZE(AO) FLD -4 * SIZE(BO) fmul %st(1), %st faddp %st, %st(2) FLD -3 * SIZE(BO) fmulp %st, %st(1) faddp %st, %st(2) FLD -5 * SIZE(AO) FLD -2 * SIZE(BO) fmul %st(1), %st faddp %st, %st(2) FLD -1 * SIZE(BO) fmulp %st, %st(1) faddp %st, %st(2) addl $4 * SIZE,AO addl $8 * SIZE,BO decl %eax jne .L22 ALIGN_4 .L25: #if defined(LT) || defined(RN) movl KK, %eax #else movl K, %eax subl KK, %eax #endif and $3, %eax je .L28 ALIGN_4 .L26: FLD -8 * SIZE(AO) FLD -8 * SIZE(BO) fmul %st(1), %st faddp %st, %st(2) FLD -7 * SIZE(BO) fmulp %st, %st(1) faddp %st, %st(2) addl $1 * SIZE,AO addl $2 * SIZE,BO decl %eax jne .L26 ALIGN_4 .L28: #if defined(LN) || defined(RT) movl KK, %eax #ifdef LN subl $1, %eax #else subl $2, %eax #endif sall $BASE_SHIFT, %eax movl AORIG, AO leal (AO, %eax, 1), AO leal (B, %eax, 2), BO #endif #if defined(LN) || defined(LT) FLD -8 * SIZE(BO) fsubp %st, %st(1) FLD -7 * SIZE(BO) fsubp %st, %st(2) #else FLD -8 * SIZE(AO) fsubp %st, %st(1) FLD -7 * SIZE(AO) fsubp %st, %st(3) #endif #if defined(LN) || defined(LT) FLD -8 * SIZE(AO) fmul %st, %st(1) fmulp %st, %st(2) #endif #ifdef RN FLD -8 * SIZE(BO) fmulp %st, %st(1) FLD -7 * SIZE(BO) fmul %st(1), %st fsubrp %st, %st(2) FLD -5 * SIZE(BO) fmulp %st, %st(2) #endif #ifdef RT FLD -5 * SIZE(BO) fmulp %st, %st(2) FLD -6 * SIZE(BO) fmul %st(2), %st fsubrp %st, %st(1) FLD -8 * SIZE(BO) fmulp %st, %st(1) #endif #ifdef LN subl $1 * SIZE, CO #endif #if defined(LN) || defined(LT) fld %st FST -8 * SIZE(BO) fxch %st(1) fld %st FST -7 * SIZE(BO) #else fld %st FST -8 * SIZE(AO) fxch %st(1) fld %st FST -7 * SIZE(AO) #endif FST 0 * SIZE(CO, LDC) FST 0 * SIZE(CO) #ifndef LN addl $1 * SIZE, CO #endif #if defined(LT) || defined(RN) movl K, %eax subl KK, %eax sall $BASE_SHIFT, %eax leal (AO, %eax, 1), AO leal (BO, %eax, 2), BO #endif #ifdef LN subl $1, KK #endif #ifdef LT addl $1, KK #endif #ifdef RT movl K, %eax sall $0 + BASE_SHIFT, %eax addl %eax, AORIG #endif ALIGN_4 .L20: movl M, I sarl $1, I je .L29 ALIGN_4 .L11: #ifdef LN movl K, %eax sall $1 + BASE_SHIFT, %eax subl %eax, AORIG #endif #if defined(LN) || defined(RT) movl KK, %eax sall $BASE_SHIFT, %eax movl AORIG, AO leal (AO, %eax, 2), AO leal (B, %eax, 2), BO #else movl B, BO #endif fldz fldz fldz fldz #if defined(HAVE_3DNOW) prefetchw 2 * SIZE(CO) prefetchw 2 * SIZE(CO, LDC, 1) #elif defined(HAVE_SSE) prefetchnta 2 * SIZE(CO) prefetchnta 2 * SIZE(CO, LDC, 1) #endif #if defined(LT) || defined(RN) movl KK, %eax #else movl K, %eax subl KK, %eax #endif sarl $2, %eax je .L15 ALIGN_4 .L12: PREFETCH (PREFETCHSIZE + 0) * SIZE(AO) FLD -8 * SIZE(AO) FLD -8 * SIZE(BO) fld %st(1) fmul %st(1), %st faddp %st, %st(3) FLD -7 * SIZE(BO) fmul %st, %st(2) FLD -7 * SIZE(AO) fmul %st, %st(2) fmulp %st, %st(1) faddp %st, %st(6) faddp %st, %st(4) faddp %st, %st(2) FLD -6 * SIZE(AO) FLD -6 * SIZE(BO) fld %st(1) fmul %st(1), %st faddp %st, %st(3) FLD -5 * SIZE(BO) fmul %st, %st(2) FLD -5 * SIZE(AO) fmul %st, %st(2) fmulp %st, %st(1) faddp %st, %st(6) faddp %st, %st(4) faddp %st, %st(2) PREFETCH (PREFETCHSIZE + 4) * SIZE(AO) FLD -4 * SIZE(AO) FLD -4 * SIZE(BO) fld %st(1) fmul %st(1), %st faddp %st, %st(3) FLD -3 * SIZE(BO) fmul %st, %st(2) FLD -3 * SIZE(AO) fmul %st, %st(2) fmulp %st, %st(1) faddp %st, %st(6) faddp %st, %st(4) faddp %st, %st(2) FLD -2 * SIZE(AO) FLD -2 * SIZE(BO) fld %st(1) fmul %st(1), %st faddp %st, %st(3) FLD -1 * SIZE(BO) fmul %st, %st(2) FLD -1 * SIZE(AO) fmul %st, %st(2) fmulp %st, %st(1) faddp %st, %st(6) faddp %st, %st(4) faddp %st, %st(2) addl $8 * SIZE,AO addl $8 * SIZE,BO decl %eax jne .L12 ALIGN_4 .L15: #if defined(LT) || defined(RN) movl KK, %eax #else movl K, %eax subl KK, %eax #endif and $3, %eax je .L18 ALIGN_4 .L16: FLD -8 * SIZE(AO) FLD -8 * SIZE(BO) fld %st(1) fmul %st(1), %st faddp %st, %st(3) FLD -7 * SIZE(BO) fmul %st, %st(2) FLD -7 * SIZE(AO) fmul %st, %st(2) fmulp %st, %st(1) faddp %st, %st(6) faddp %st, %st(4) faddp %st, %st(2) addl $2 * SIZE,AO addl $2 * SIZE,BO decl %eax jne .L16 ALIGN_4 .L18: #if defined(LN) || defined(RT) movl KK, %eax #ifdef LN subl $2, %eax #else subl $2, %eax #endif sall $BASE_SHIFT, %eax movl AORIG, AO leal (AO, %eax, 2), AO leal (B, %eax, 2), BO #endif #if defined(LN) || defined(LT) FLD -8 * SIZE(BO) fsubp %st, %st(1) FLD -7 * SIZE(BO) fsubp %st, %st(2) FLD -6 * SIZE(BO) fsubp %st, %st(3) FLD -5 * SIZE(BO) fsubp %st, %st(4) #else FLD -8 * SIZE(AO) fsubp %st, %st(1) FLD -7 * SIZE(AO) fsubp %st, %st(3) FLD -6 * SIZE(AO) fsubp %st, %st(2) FLD -5 * SIZE(AO) fsubp %st, %st(4) #endif #ifdef LN FLD -5 * SIZE(AO) fmul %st, %st(3) fmulp %st, %st(4) FLD -6 * SIZE(AO) fmul %st(3), %st FLD -6 * SIZE(AO) fmul %st(5), %st fsubrp %st, %st(3) fsubrp %st, %st(1) FLD -8 * SIZE(AO) fmul %st, %st(1) fmulp %st, %st(2) #endif #ifdef LT FLD -8 * SIZE(AO) fmul %st, %st(1) fmulp %st, %st(2) FLD -7 * SIZE(AO) fmul %st(1), %st FLD -7 * SIZE(AO) fmul %st(3), %st fsubrp %st, %st(5) fsubrp %st, %st(3) FLD -5 * SIZE(AO) fmul %st, %st(3) fmulp %st, %st(4) #endif #ifdef RN FLD -8 * SIZE(BO) fmul %st, %st(1) fmulp %st, %st(3) FLD -7 * SIZE(BO) fmul %st(1), %st FLD -7 * SIZE(BO) fmul %st(4), %st fsubrp %st, %st(5) fsubrp %st, %st(2) FLD -5 * SIZE(BO) fmul %st, %st(2) fmulp %st, %st(4) #endif #ifdef RT FLD -5 * SIZE(BO) fmul %st, %st(2) fmulp %st, %st(4) FLD -6 * SIZE(BO) fmul %st(2), %st FLD -6 * SIZE(BO) fmul %st(5), %st fsubrp %st, %st(4) fsubrp %st, %st(1) FLD -8 * SIZE(BO) fmul %st, %st(1) fmulp %st, %st(3) #endif #ifdef LN subl $2 * SIZE, CO #endif #if defined(LN) || defined(LT) fld %st FST -8 * SIZE(BO) fxch %st(1) fld %st FST -7 * SIZE(BO) fxch %st(2) fld %st FST -6 * SIZE(BO) fxch %st(3) fld %st FST -5 * SIZE(BO) FST 1 * SIZE(CO, LDC) FST 0 * SIZE(CO) FST 0 * SIZE(CO, LDC) FST 1 * SIZE(CO) #else fld %st FST -8 * SIZE(AO) fxch %st(2) fld %st FST -7 * SIZE(AO) fxch %st(1) fld %st FST -6 * SIZE(AO) fxch %st(3) fld %st FST -5 * SIZE(AO) FST 1 * SIZE(CO, LDC) FST 1 * SIZE(CO) FST 0 * SIZE(CO) FST 0 * SIZE(CO, LDC) #endif #ifndef LN addl $2 * SIZE, CO #endif #if defined(LT) || defined(RN) movl K, %eax subl KK, %eax sall $BASE_SHIFT, %eax leal (AO, %eax, 2), AO leal (BO, %eax, 2), BO #endif #ifdef LN subl $2, KK #endif #ifdef LT addl $2, KK #endif #ifdef RT movl K, %eax sall $1 + BASE_SHIFT, %eax addl %eax, AORIG #endif decl I jne .L11 ALIGN_4 .L29: #ifdef LN movl K, %eax sall $BASE_SHIFT, %eax leal (B, %eax, 2), B #endif #if defined(LT) || defined(RN) movl BO, B #endif #ifdef RN addl $2, KK #endif #ifdef RT subl $2, KK #endif decl J jne .L01 ALIGN_4 .L30: movl N, %eax testl $1, %eax je .L999 #if defined(LT) || defined(RN) movl A, AO #else movl A, %eax movl %eax, AORIG #endif #ifdef RT movl K, %eax sall $0 + BASE_SHIFT, %eax subl %eax, B #endif #ifdef RT subl LDC, C #endif movl C, CO #ifndef RT addl %eax, C #endif #ifdef LN movl OFFSET, %eax addl M, %eax movl %eax, KK #endif #ifdef LT movl OFFSET, %eax movl %eax, KK #endif movl M, %eax andl $1, %eax je .L40 ALIGN_4 .L41: #ifdef LN movl K, %eax sall $0 + BASE_SHIFT, %eax subl %eax, AORIG #endif #if defined(LN) || defined(RT) movl KK, %eax sall $BASE_SHIFT, %eax movl AORIG, AO leal (AO, %eax, 1), AO leal (B, %eax, 1), BO #else movl B, BO #endif fldz #if defined(LT) || defined(RN) movl KK, %eax #else movl K, %eax subl KK, %eax #endif sarl $2, %eax je .L45 ALIGN_4 .L42: PREFETCH (PREFETCHSIZE + 0) * SIZE(AO) FLD -8 * SIZE(AO) FLD -8 * SIZE(BO) fmulp %st, %st(1) faddp %st, %st(1) FLD -7 * SIZE(AO) FLD -7 * SIZE(BO) fmulp %st, %st(1) faddp %st, %st(1) FLD -6 * SIZE(AO) FLD -6 * SIZE(BO) fmulp %st, %st(1) faddp %st, %st(1) FLD -5 * SIZE(AO) FLD -5 * SIZE(BO) fmulp %st, %st(1) faddp %st, %st(1) addl $4 * SIZE,AO addl $4 * SIZE,BO decl %eax jne .L42 ALIGN_4 .L45: #if defined(LT) || defined(RN) movl KK, %eax #else movl K, %eax subl KK, %eax #endif and $3, %eax je .L48 ALIGN_4 .L46: FLD -8 * SIZE(AO) FLD -8 * SIZE(BO) fmulp %st, %st(1) faddp %st, %st(1) addl $1 * SIZE,AO addl $1 * SIZE,BO decl %eax jne .L46 ALIGN_4 .L48: #if defined(LN) || defined(RT) movl KK, %eax #ifdef LN subl $1, %eax #else subl $1, %eax #endif sall $BASE_SHIFT, %eax movl AORIG, AO leal (AO, %eax, 1), AO leal (B, %eax, 1), BO #endif #if defined(LN) || defined(LT) FLD -8 * SIZE(BO) fsubp %st, %st(1) #else FLD -8 * SIZE(AO) fsubp %st, %st(1) #endif #ifdef LN FLD -8 * SIZE(AO) fmulp %st, %st(1) #endif #ifdef LT FLD -8 * SIZE(AO) fmulp %st, %st(1) #endif #ifdef RN FLD -8 * SIZE(BO) fmulp %st, %st(1) #endif #ifdef RT FLD -8 * SIZE(BO) fmulp %st, %st(1) #endif #ifdef LN subl $1 * SIZE, CO #endif #if defined(LN) || defined(LT) fld %st FST -8 * SIZE(BO) #else fld %st FST -8 * SIZE(AO) #endif FST 0 * SIZE(CO) #ifndef LN addl $1 * SIZE, CO #endif #if defined(LT) || defined(RN) movl K, %eax subl KK, %eax sall $BASE_SHIFT, %eax leal (AO, %eax, 1), AO leal (BO, %eax, 1), BO #endif #ifdef LN subl $1, KK #endif #ifdef LT addl $1, KK #endif #ifdef RT movl K, %eax sall $0 + BASE_SHIFT, %eax addl %eax, AORIG #endif ALIGN_4 .L40: movl M, I sarl $1, I je .L49 ALIGN_4 .L31: #ifdef LN movl K, %eax sall $1 + BASE_SHIFT, %eax subl %eax, AORIG #endif #if defined(LN) || defined(RT) movl KK, %eax sall $BASE_SHIFT, %eax movl AORIG, AO leal (AO, %eax, 2), AO leal (B, %eax, 1), BO #else movl B, BO #endif fldz fldz #if defined(HAVE_3DNOW) prefetchw 2 * SIZE(CO) #elif defined(HAVE_SSE) prefetchnta 2 * SIZE(CO) #endif #if defined(LT) || defined(RN) movl KK, %eax #else movl K, %eax subl KK, %eax #endif sarl $2, %eax je .L35 ALIGN_4 .L32: PREFETCH (PREFETCHSIZE + 0) * SIZE(AO) FLD -8 * SIZE(BO) FLD -8 * SIZE(AO) fmul %st(1), %st faddp %st, %st(2) FLD -7 * SIZE(AO) fmulp %st, %st(1) faddp %st, %st(2) FLD -7 * SIZE(BO) FLD -6 * SIZE(AO) fmul %st(1), %st faddp %st, %st(2) FLD -5 * SIZE(AO) fmulp %st, %st(1) faddp %st, %st(2) FLD -6 * SIZE(BO) FLD -4 * SIZE(AO) fmul %st(1), %st faddp %st, %st(2) FLD -3 * SIZE(AO) fmulp %st, %st(1) faddp %st, %st(2) FLD -5 * SIZE(BO) FLD -2 * SIZE(AO) fmul %st(1), %st faddp %st, %st(2) FLD -1 * SIZE(AO) fmulp %st, %st(1) faddp %st, %st(2) addl $8 * SIZE,AO addl $4 * SIZE,BO decl %eax jne .L32 ALIGN_4 .L35: #if defined(LT) || defined(RN) movl KK, %eax #else movl K, %eax subl KK, %eax #endif and $3, %eax je .L38 ALIGN_4 .L36: FLD -8 * SIZE(BO) FLD -8 * SIZE(AO) fmul %st(1), %st faddp %st, %st(2) FLD -7 * SIZE(AO) fmulp %st, %st(1) faddp %st, %st(2) addl $2 * SIZE,AO addl $1 * SIZE,BO decl %eax jne .L36 ALIGN_4 .L38: #if defined(LN) || defined(RT) movl KK, %eax #ifdef LN subl $2, %eax #else subl $1, %eax #endif sall $BASE_SHIFT, %eax movl AORIG, AO leal (AO, %eax, 2), AO leal (B, %eax, 1), BO #endif #if defined(LN) || defined(LT) FLD -8 * SIZE(BO) fsubp %st, %st(1) FLD -7 * SIZE(BO) fsubp %st, %st(2) #else FLD -8 * SIZE(AO) fsubp %st, %st(1) FLD -7 * SIZE(AO) fsubp %st, %st(3) #endif #ifdef LN FLD -5 * SIZE(AO) fmulp %st, %st(2) FLD -6 * SIZE(AO) fmul %st(2), %st fsubrp %st, %st(1) FLD -8 * SIZE(AO) fmulp %st, %st(1) #endif #ifdef LT FLD -8 * SIZE(AO) fmulp %st, %st(1) FLD -7 * SIZE(AO) fmul %st(1), %st fsubrp %st, %st(2) FLD -5 * SIZE(AO) fmulp %st, %st(2) #endif #ifdef RN FLD -8 * SIZE(BO) fmul %st, %st(1) fmulp %st, %st(2) #endif #ifdef RT FLD -8 * SIZE(BO) fmul %st, %st(1) fmulp %st, %st(2) #endif #ifdef LN subl $2 * SIZE, CO #endif #if defined(LN) || defined(LT) fld %st FST -8 * SIZE(BO) fxch %st(1) fld %st FST -7 * SIZE(BO) #else fld %st FST -8 * SIZE(AO) fxch %st(1) fld %st FST -7 * SIZE(AO) #endif FST 1 * SIZE(CO) FST 0 * SIZE(CO) #ifndef LN addl $2 * SIZE, CO #endif #if defined(LT) || defined(RN) movl K, %eax subl KK, %eax sall $BASE_SHIFT, %eax leal (AO, %eax, 2), AO leal (BO, %eax, 1), BO #endif #ifdef LN subl $2, KK #endif #ifdef LT addl $2, KK #endif #ifdef RT movl K, %eax sall $1 + BASE_SHIFT, %eax addl %eax, AORIG #endif decl I jne .L31 ALIGN_4 .L49: #ifdef LN movl K, %eax sall $BASE_SHIFT, %eax leal (B, %eax, 1), B #endif #if defined(LT) || defined(RN) movl BO, B #endif #ifdef RN addl $1, KK #endif #ifdef RT subl $1, KK #endif ALIGN_4 .L999: popl %ebx popl %esi popl %edi popl %ebp addl $ARGS, %esp ret EPILOGUE