floraachy/OpenBLAS
1
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity
Files
f6b50057e259761f8b2662e64272861cabb66607
OpenBLAS/kernel/x86_64/cgemm_kernel_8x2_haswell.S
wernsaar f6b50057e2 corrected and testet FMA3 Code
2013-10-19 10:52:20 +02:00

2324 lines
55 KiB
ArmAsm
Raw Blame History

/*********************************************************************/
/* 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. */
/*********************************************************************/
/*********************************************************************
* 2013/10/19 Saar
* BLASTEST :
* CTEST : OK
* TEST : OK
*
* 2013/08/16 Saar
* Parameter:
* CGEMM_DEFAULT_UNROLL_N 2
* CGEMM_DEFAULT_UNROLL_M 8
* CGEMM_DEFAULT_P 224
* CGEMM_DEFAULT_Q 224
*
* BLASTEST: OK
*
* Performance:
* 1 thread: 2.04 times faster than sandybridge
* 4 threads: 1.96 times faster than sandybridge
*
* Compile for FMA3: OK
*
*********************************************************************/
#define ASSEMBLER
#include "common.h"
#define OLD_M %rdi
#define OLD_N %rsi
#define M %r13
#define J %r14
#define OLD_K %rdx
#define A %rcx
#define B %r8
#define C %r9
#define LDC %r10
#define I %r11
#define AO %rdi
#define BO %rsi
#define CO1 %r15
#define K %r12
#define BI %rbp
#define SP %rbx
#define BO1 %rdi
#define BO2 %r15
#ifndef WINDOWS_ABI
#define STACKSIZE 96
#else
#define STACKSIZE 320
#define OLD_ALPHA_I 40 + STACKSIZE(%rsp)
#define OLD_A 48 + STACKSIZE(%rsp)
#define OLD_B 56 + STACKSIZE(%rsp)
#define OLD_C 64 + STACKSIZE(%rsp)
#define OLD_LDC 72 + STACKSIZE(%rsp)
#define OLD_OFFSET 80 + STACKSIZE(%rsp)
#endif
#define L_BUFFER_SIZE 512*8*4
#define LB2_OFFSET 512*8*2
#define Ndiv6 24(%rsp)
#define Nmod6 32(%rsp)
#define N 40(%rsp)
#define ALPHA_R 48(%rsp)
#define ALPHA_I 56(%rsp)
#define OFFSET 64(%rsp)
#define KK 72(%rsp)
#define KKK 80(%rsp)
#define BUFFER1 128(%rsp)
#define BUFFER2 LB2_OFFSET+128(%rsp)
#if defined(OS_WINDOWS)
#if L_BUFFER_SIZE > 16384
#define STACK_TOUCH \
movl $0, 4096 * 4(%rsp);\
movl $0, 4096 * 3(%rsp);\
movl $0, 4096 * 2(%rsp);\
movl $0, 4096 * 1(%rsp);
#elif L_BUFFER_SIZE > 12288
#define STACK_TOUCH \
movl $0, 4096 * 3(%rsp);\
movl $0, 4096 * 2(%rsp);\
movl $0, 4096 * 1(%rsp);
#elif L_BUFFER_SIZE > 8192
#define STACK_TOUCH \
movl $0, 4096 * 2(%rsp);\
movl $0, 4096 * 1(%rsp);
#elif L_BUFFER_SIZE > 4096
#define STACK_TOUCH \
movl $0, 4096 * 1(%rsp);
#else
#define STACK_TOUCH
#endif
#else
#define STACK_TOUCH
#endif
#if defined(BULLDOZER)
#if defined(NN) || defined(NT) || defined(TN) || defined(TT)
.macro VFMADDPS_R y0,y1,y2
vfmaddps \y0,\y1,\y2,\y0
.endm
.macro VFMADDPS_I y0,y1,y2
vfmaddps \y0,\y1,\y2,\y0
.endm
#elif defined(RN) || defined(RT) || defined(CN) || defined(CT)
.macro VFMADDPS_R y0,y1,y2
vfnmaddps \y0,\y1,\y2,\y0
.endm
.macro VFMADDPS_I y0,y1,y2
vfmaddps \y0,\y1,\y2,\y0
.endm
#elif defined(NR) || defined(NC) || defined(TR) || defined(TC)
.macro VFMADDPS_R y0,y1,y2
vfmaddps \y0,\y1,\y2,\y0
.endm
.macro VFMADDPS_I y0,y1,y2
vfnmaddps \y0,\y1,\y2,\y0
.endm
#else
.macro VFMADDPS_R y0,y1,y2
vfnmaddps \y0,\y1,\y2,\y0
.endm
.macro VFMADDPS_I y0,y1,y2
vfnmaddps \y0,\y1,\y2,\y0
.endm
#endif
#else
#if defined(NN) || defined(NT) || defined(TN) || defined(TT)
.macro VFMADDPS_R y0,y1,y2
vfmadd231ps \y1,\y2,\y0
.endm
.macro VFMADDPS_I y0,y1,y2
vfmadd231ps \y1,\y2,\y0
.endm
#elif defined(RN) || defined(RT) || defined(CN) || defined(CT)
.macro VFMADDPS_R y0,y1,y2
vfnmadd231ps \y1,\y2,\y0
.endm
.macro VFMADDPS_I y0,y1,y2
vfmadd231ps \y1,\y2,\y0
.endm
#elif defined(NR) || defined(NC) || defined(TR) || defined(TC)
.macro VFMADDPS_R y0,y1,y2
vfmadd231ps \y1,\y2,\y0
.endm
.macro VFMADDPS_I y0,y1,y2
vfnmadd231ps \y1,\y2,\y0
.endm
#else
.macro VFMADDPS_R y0,y1,y2
vfnmadd231ps \y1,\y2,\y0
.endm
.macro VFMADDPS_I y0,y1,y2
vfnmadd231ps \y1,\y2,\y0
.endm
#endif
#endif
#define A_PR1 384
#define B_PR1 192
/***************************************************************************************************************************/
.macro KERNEL8x2_SUB
vmovups -16 * SIZE(AO, %rax, SIZE), %ymm0
vbroadcastss -8 * SIZE(BO, BI, SIZE), %ymm4
VFMADDPS_R %ymm8,%ymm4,%ymm0
vmovups -8 * SIZE(AO, %rax, SIZE), %ymm1
VFMADDPS_R %ymm12,%ymm4,%ymm1
vbroadcastss -7 * SIZE(BO, BI, SIZE), %ymm5
VFMADDPS_I %ymm9,%ymm5,%ymm0
VFMADDPS_I %ymm13,%ymm5,%ymm1
vbroadcastss -6 * SIZE(BO, BI, SIZE), %ymm6
VFMADDPS_R %ymm10,%ymm6,%ymm0
VFMADDPS_R %ymm14,%ymm6,%ymm1
vbroadcastss -5 * SIZE(BO, BI, SIZE), %ymm7
VFMADDPS_I %ymm11,%ymm7,%ymm0
VFMADDPS_I %ymm15,%ymm7,%ymm1
addq $4 , BI
addq $16, %rax
.endm
.macro SAVE8x2
vbroadcastss ALPHA_R, %ymm0
vbroadcastss ALPHA_I, %ymm1
// swap high and low 64 bytes
vshufps $0xb1, %ymm9 , %ymm9, %ymm9
vshufps $0xb1, %ymm11, %ymm11, %ymm11
vshufps $0xb1, %ymm13, %ymm13, %ymm13
vshufps $0xb1, %ymm15, %ymm15, %ymm15
#if defined(NN) || defined(NT) || defined(TN) || defined(TT) || \
defined(NR) || defined(NC) || defined(TR) || defined(TC)
vaddsubps %ymm9, %ymm8 , %ymm8
vaddsubps %ymm11,%ymm10, %ymm10
vaddsubps %ymm13,%ymm12, %ymm12
vaddsubps %ymm15,%ymm14, %ymm14
vshufps $0xb1, %ymm8 , %ymm8, %ymm9
vshufps $0xb1, %ymm10, %ymm10, %ymm11
vshufps $0xb1, %ymm12, %ymm12, %ymm13
vshufps $0xb1, %ymm14, %ymm14, %ymm15
#else
vaddsubps %ymm8, %ymm9 ,%ymm9
vaddsubps %ymm10, %ymm11,%ymm11
vaddsubps %ymm12, %ymm13,%ymm13
vaddsubps %ymm14, %ymm15,%ymm15
vmovaps %ymm9, %ymm8
vmovaps %ymm11, %ymm10
vmovaps %ymm13, %ymm12
vmovaps %ymm15, %ymm14
// swap high and low 64 bytes
vshufps $0xb1, %ymm9 , %ymm9, %ymm9
vshufps $0xb1, %ymm11, %ymm11, %ymm11
vshufps $0xb1, %ymm13, %ymm13, %ymm13
vshufps $0xb1, %ymm15, %ymm15, %ymm15
#endif
// multiply with ALPHA_R
vmulps %ymm8 , %ymm0, %ymm8
vmulps %ymm10, %ymm0, %ymm10
vmulps %ymm12, %ymm0, %ymm12
vmulps %ymm14, %ymm0, %ymm14
// multiply with ALPHA_I
vmulps %ymm9 , %ymm1, %ymm9
vmulps %ymm11, %ymm1, %ymm11
vmulps %ymm13, %ymm1, %ymm13
vmulps %ymm15, %ymm1, %ymm15
vaddsubps %ymm9, %ymm8 , %ymm8
vaddsubps %ymm11,%ymm10, %ymm10
vaddsubps %ymm13,%ymm12, %ymm12
vaddsubps %ymm15,%ymm14, %ymm14
#ifndef TRMMKERNEL
vaddps (CO1), %ymm8 , %ymm8
vaddps 8 * SIZE(CO1), %ymm12, %ymm12
vaddps (CO1, LDC), %ymm10, %ymm10
vaddps 8 * SIZE(CO1, LDC), %ymm14, %ymm14
#endif
vmovups %ymm8 , (CO1)
vmovups %ymm12 , 8 * SIZE(CO1)
vmovups %ymm10 , (CO1, LDC)
vmovups %ymm14 , 8 * SIZE(CO1, LDC)
.endm
/***************************************************************************************************************************/
.macro KERNEL4x2_SUB
vmovups -16 * SIZE(AO, %rax, SIZE), %xmm0
vbroadcastss -8 * SIZE(BO, BI, SIZE), %xmm4
VFMADDPS_R %xmm8,%xmm4,%xmm0
vmovups -12 * SIZE(AO, %rax, SIZE), %xmm1
VFMADDPS_R %xmm12,%xmm4,%xmm1
vbroadcastss -7 * SIZE(BO, BI, SIZE), %xmm5
VFMADDPS_I %xmm9,%xmm5,%xmm0
VFMADDPS_I %xmm13,%xmm5,%xmm1
vbroadcastss -6 * SIZE(BO, BI, SIZE), %xmm6
VFMADDPS_R %xmm10,%xmm6,%xmm0
VFMADDPS_R %xmm14,%xmm6,%xmm1
vbroadcastss -5 * SIZE(BO, BI, SIZE), %xmm7
VFMADDPS_I %xmm11,%xmm7,%xmm0
VFMADDPS_I %xmm15,%xmm7,%xmm1
addq $4, BI
addq $8, %rax
.endm
.macro SAVE4x2
vbroadcastss ALPHA_R, %xmm0
vbroadcastss ALPHA_I, %xmm1
// swap high and low 64 bytes
vshufps $0xb1, %xmm9 , %xmm9, %xmm9
vshufps $0xb1, %xmm11, %xmm11, %xmm11
vshufps $0xb1, %xmm13, %xmm13, %xmm13
vshufps $0xb1, %xmm15, %xmm15, %xmm15
#if defined(NN) || defined(NT) || defined(TN) || defined(TT) || \
defined(NR) || defined(NC) || defined(TR) || defined(TC)
vaddsubps %xmm9, %xmm8 , %xmm8
vaddsubps %xmm11,%xmm10, %xmm10
vaddsubps %xmm13,%xmm12, %xmm12
vaddsubps %xmm15,%xmm14, %xmm14
vshufps $0xb1, %xmm8 , %xmm8, %xmm9
vshufps $0xb1, %xmm10, %xmm10, %xmm11
vshufps $0xb1, %xmm12, %xmm12, %xmm13
vshufps $0xb1, %xmm14, %xmm14, %xmm15
#else
vaddsubps %xmm8, %xmm9 ,%xmm9
vaddsubps %xmm10, %xmm11,%xmm11
vaddsubps %xmm12, %xmm13,%xmm13
vaddsubps %xmm14, %xmm15,%xmm15
vmovaps %xmm9, %xmm8
vmovaps %xmm11, %xmm10
vmovaps %xmm13, %xmm12
vmovaps %xmm15, %xmm14
// swap high and low 64 bytes
vshufps $0xb1, %xmm9 , %xmm9, %xmm9
vshufps $0xb1, %xmm11, %xmm11, %xmm11
vshufps $0xb1, %xmm13, %xmm13, %xmm13
vshufps $0xb1, %xmm15, %xmm15, %xmm15
#endif
// multiply with ALPHA_R
vmulps %xmm8 , %xmm0, %xmm8
vmulps %xmm10, %xmm0, %xmm10
vmulps %xmm12, %xmm0, %xmm12
vmulps %xmm14, %xmm0, %xmm14
// multiply with ALPHA_I
vmulps %xmm9 , %xmm1, %xmm9
vmulps %xmm11, %xmm1, %xmm11
vmulps %xmm13, %xmm1, %xmm13
vmulps %xmm15, %xmm1, %xmm15
vaddsubps %xmm9, %xmm8 , %xmm8
vaddsubps %xmm11,%xmm10, %xmm10
vaddsubps %xmm13,%xmm12, %xmm12
vaddsubps %xmm15,%xmm14, %xmm14
#ifndef TRMMKERNEL
vaddps (CO1), %xmm8 , %xmm8
vaddps 4 * SIZE(CO1), %xmm12, %xmm12
vaddps (CO1, LDC), %xmm10, %xmm10
vaddps 4 * SIZE(CO1, LDC), %xmm14, %xmm14
#endif
vmovups %xmm8 , (CO1)
vmovups %xmm12 , 4 * SIZE(CO1)
vmovups %xmm10 , (CO1, LDC)
vmovups %xmm14 , 4 * SIZE(CO1, LDC)
.endm
/************************************************************************************************/
.macro KERNEL2x2_SUB
vmovups -16 * SIZE(AO, %rax, SIZE), %xmm0
vbroadcastss -8 * SIZE(BO, BI, SIZE), %xmm4
VFMADDPS_R %xmm8,%xmm4,%xmm0
vbroadcastss -7 * SIZE(BO, BI, SIZE), %xmm5
VFMADDPS_I %xmm9,%xmm5,%xmm0
vbroadcastss -6 * SIZE(BO, BI, SIZE), %xmm6
VFMADDPS_R %xmm10,%xmm6,%xmm0
vbroadcastss -5 * SIZE(BO, BI, SIZE), %xmm7
VFMADDPS_I %xmm11,%xmm7,%xmm0
addq $4, BI
addq $4, %rax
.endm
.macro SAVE2x2
vbroadcastss ALPHA_R, %xmm0
vbroadcastss ALPHA_I, %xmm1
// swap high and low 4 bytes
vshufps $0xb1, %xmm9 , %xmm9, %xmm9
vshufps $0xb1, %xmm11, %xmm11, %xmm11
#if defined(NN) || defined(NT) || defined(TN) || defined(TT) || \
defined(NR) || defined(NC) || defined(TR) || defined(TC)
vaddsubps %xmm9, %xmm8 , %xmm8
vaddsubps %xmm11,%xmm10, %xmm10
vshufps $0xb1, %xmm8 , %xmm8, %xmm9
vshufps $0xb1, %xmm10, %xmm10, %xmm11
#else
vaddsubps %xmm8, %xmm9 ,%xmm9
vaddsubps %xmm10, %xmm11,%xmm11
vmovaps %xmm9, %xmm8
vmovaps %xmm11, %xmm10
// swap high and low 4 bytes
vshufps $0xb1, %xmm9 , %xmm9, %xmm9
vshufps $0xb1, %xmm11, %xmm11, %xmm11
#endif
// multiply with ALPHA_R
vmulps %xmm8 , %xmm0, %xmm8
vmulps %xmm10, %xmm0, %xmm10
// multiply with ALPHA_I
vmulps %xmm9 , %xmm1, %xmm9
vmulps %xmm11, %xmm1, %xmm11
vaddsubps %xmm9, %xmm8 , %xmm8
vaddsubps %xmm11,%xmm10, %xmm10
#ifndef TRMMKERNEL
vaddps (CO1), %xmm8 , %xmm8
vaddps (CO1, LDC), %xmm10, %xmm10
#endif
vmovups %xmm8 , (CO1)
vmovups %xmm10 , (CO1, LDC)
.endm
/************************************************************************************************/
.macro KERNEL1x2_SUB
vmovsd -16 * SIZE(AO, %rax, SIZE), %xmm0
vbroadcastss -8 * SIZE(BO, BI, SIZE), %xmm4
VFMADDPS_R %xmm8,%xmm4,%xmm0
vbroadcastss -7 * SIZE(BO, BI, SIZE), %xmm5
VFMADDPS_I %xmm9,%xmm5,%xmm0
vbroadcastss -6 * SIZE(BO, BI, SIZE), %xmm6
VFMADDPS_R %xmm10,%xmm6,%xmm0
vbroadcastss -5 * SIZE(BO, BI, SIZE), %xmm7
VFMADDPS_I %xmm11,%xmm7,%xmm0
addq $4, BI
addq $2, %rax
.endm
.macro SAVE1x2
vbroadcastss ALPHA_R, %xmm0
vbroadcastss ALPHA_I, %xmm1
// swap high and low 64 bytes
vshufps $0xb1, %xmm9 , %xmm9, %xmm9
vshufps $0xb1, %xmm11, %xmm11, %xmm11
#if defined(NN) || defined(NT) || defined(TN) || defined(TT) || \
defined(NR) || defined(NC) || defined(TR) || defined(TC)
vaddsubps %xmm9, %xmm8 , %xmm8
vaddsubps %xmm11,%xmm10, %xmm10
vshufps $0xb1, %xmm8 , %xmm8, %xmm9
vshufps $0xb1, %xmm10, %xmm10, %xmm11
#else
vaddsubps %xmm8, %xmm9 ,%xmm9
vaddsubps %xmm10, %xmm11,%xmm11
vmovaps %xmm9, %xmm8
vmovaps %xmm11, %xmm10
// swap high and low 64 bytes
vshufps $0xb1, %xmm9 , %xmm9, %xmm9
vshufps $0xb1, %xmm11, %xmm11, %xmm11
#endif
// multiply with ALPHA_R
vmulps %xmm8 , %xmm0, %xmm8
vmulps %xmm10, %xmm0, %xmm10
// multiply with ALPHA_I
vmulps %xmm9 , %xmm1, %xmm9
vmulps %xmm11, %xmm1, %xmm11
vaddsubps %xmm9, %xmm8 , %xmm8
vaddsubps %xmm11,%xmm10, %xmm10
#ifndef TRMMKERNEL
vmovsd (CO1), %xmm14
vaddps %xmm14, %xmm8 , %xmm8
vmovsd (CO1, LDC), %xmm15
vaddps %xmm15, %xmm10, %xmm10
#endif
vmovsd %xmm8 , (CO1)
vmovsd %xmm10 , (CO1, LDC)
.endm
/************************************************************************************************/
.macro KERNEL8x1_SUB
vmovups -16 * SIZE(AO, %rax, SIZE), %ymm0
vmovups -8 * SIZE(AO, %rax, SIZE), %ymm1
vbroadcastss -4 * SIZE(BO, BI, SIZE), %ymm4
VFMADDPS_R %ymm8,%ymm4,%ymm0
VFMADDPS_R %ymm12,%ymm4,%ymm1
vbroadcastss -3 * SIZE(BO, BI, SIZE), %ymm5
VFMADDPS_I %ymm9,%ymm5,%ymm0
VFMADDPS_I %ymm13,%ymm5,%ymm1
addq $2 , BI
addq $16, %rax
.endm
.macro SAVE8x1
vbroadcastss ALPHA_R, %ymm0
vbroadcastss ALPHA_I, %ymm1
// swap high and low 64 bytes
vshufps $0xb1, %ymm9 , %ymm9, %ymm9
vshufps $0xb1, %ymm13, %ymm13, %ymm13
#if defined(NN) || defined(NT) || defined(TN) || defined(TT) || \
defined(NR) || defined(NC) || defined(TR) || defined(TC)
vaddsubps %ymm9, %ymm8 , %ymm8
vaddsubps %ymm13,%ymm12, %ymm12
vshufps $0xb1, %ymm8 , %ymm8, %ymm9
vshufps $0xb1, %ymm12, %ymm12, %ymm13
#else
vaddsubps %ymm8, %ymm9 ,%ymm9
vaddsubps %ymm12, %ymm13,%ymm13
vmovaps %ymm9, %ymm8
vmovaps %ymm13, %ymm12
// swap high and low 64 bytes
vshufps $0xb1, %ymm9 , %ymm9, %ymm9
vshufps $0xb1, %ymm13, %ymm13, %ymm13
#endif
// multiply with ALPHA_R
vmulps %ymm8 , %ymm0, %ymm8
vmulps %ymm12, %ymm0, %ymm12
// multiply with ALPHA_I
vmulps %ymm9 , %ymm1, %ymm9
vmulps %ymm13, %ymm1, %ymm13
vaddsubps %ymm9, %ymm8 , %ymm8
vaddsubps %ymm13,%ymm12, %ymm12
#ifndef TRMMKERNEL
vaddps (CO1), %ymm8 , %ymm8
vaddps 8 * SIZE(CO1), %ymm12, %ymm12
#endif
vmovups %ymm8 , (CO1)
vmovups %ymm12 , 8 * SIZE(CO1)
.endm
/************************************************************************************************/
.macro KERNEL4x1_SUB
vmovups -16 * SIZE(AO, %rax, SIZE), %xmm0
vbroadcastss -4 * SIZE(BO, BI, SIZE), %xmm4
VFMADDPS_R %xmm8,%xmm4,%xmm0
vmovups -12 * SIZE(AO, %rax, SIZE), %xmm1
VFMADDPS_R %xmm12,%xmm4,%xmm1
vbroadcastss -3 * SIZE(BO, BI, SIZE), %xmm5
VFMADDPS_I %xmm9,%xmm5,%xmm0
VFMADDPS_I %xmm13,%xmm5,%xmm1
addq $2, BI
addq $8, %rax
.endm
.macro SAVE4x1
vbroadcastss ALPHA_R, %xmm0
vbroadcastss ALPHA_I, %xmm1
// swap high and low 4 bytes
vshufps $0xb1, %xmm9 , %xmm9, %xmm9
vshufps $0xb1, %xmm13, %xmm13, %xmm13
#if defined(NN) || defined(NT) || defined(TN) || defined(TT) || \
defined(NR) || defined(NC) || defined(TR) || defined(TC)
vaddsubps %xmm9, %xmm8 , %xmm8
vaddsubps %xmm13,%xmm12, %xmm12
vshufps $0xb1, %xmm8 , %xmm8, %xmm9
vshufps $0xb1, %xmm12, %xmm12, %xmm13
#else
vaddsubps %xmm8, %xmm9 ,%xmm9
vaddsubps %xmm12, %xmm13,%xmm13
vmovaps %xmm9, %xmm8
vmovaps %xmm13, %xmm12
// swap high and low 4 bytes
vshufps $0xb1, %xmm9 , %xmm9, %xmm9
vshufps $0xb1, %xmm13, %xmm13, %xmm13
#endif
// multiply with ALPHA_R
vmulps %xmm8 , %xmm0, %xmm8
vmulps %xmm12, %xmm0, %xmm12
// multiply with ALPHA_I
vmulps %xmm9 , %xmm1, %xmm9
vmulps %xmm13, %xmm1, %xmm13
vaddsubps %xmm9, %xmm8 , %xmm8
vaddsubps %xmm13,%xmm12, %xmm12
#ifndef TRMMKERNEL
vaddps (CO1), %xmm8 , %xmm8
vaddps 4 * SIZE(CO1), %xmm12, %xmm12
#endif
vmovups %xmm8 , (CO1)
vmovups %xmm12 , 4 * SIZE(CO1)
.endm
/************************************************************************************************/
.macro KERNEL2x1_SUB
vmovups -16 * SIZE(AO, %rax, SIZE), %xmm0
vbroadcastss -4 * SIZE(BO, BI, SIZE), %xmm4
VFMADDPS_R %xmm8,%xmm4,%xmm0
vbroadcastss -3 * SIZE(BO, BI, SIZE), %xmm5
VFMADDPS_I %xmm9,%xmm5,%xmm0
addq $2, BI
addq $4, %rax
.endm
.macro SAVE2x1
vbroadcastss ALPHA_R, %xmm0
vbroadcastss ALPHA_I, %xmm1
// swap high and low 64 bytes
vshufps $0xb1, %xmm9 , %xmm9, %xmm9
#if defined(NN) || defined(NT) || defined(TN) || defined(TT) || \
defined(NR) || defined(NC) || defined(TR) || defined(TC)
vaddsubps %xmm9, %xmm8 , %xmm8
vshufps $0xb1, %xmm8 , %xmm8, %xmm9
#else
vaddsubps %xmm8, %xmm9 ,%xmm9
vmovaps %xmm9, %xmm8
// swap high and low 64 bytes
vshufps $0xb1, %xmm9 , %xmm9, %xmm9
#endif
// multiply with ALPHA_R
vmulps %xmm8 , %xmm0, %xmm8
// multiply with ALPHA_I
vmulps %xmm9 , %xmm1, %xmm9
vaddsubps %xmm9, %xmm8 , %xmm8
#ifndef TRMMKERNEL
vaddps (CO1), %xmm8 , %xmm8
#endif
vmovups %xmm8 , (CO1)
.endm
/************************************************************************************************/
.macro KERNEL1x1_SUB
vmovsd -16 * SIZE(AO, %rax, SIZE), %xmm0
vbroadcastss -4 * SIZE(BO, BI, SIZE), %xmm4
VFMADDPS_R %xmm8,%xmm4,%xmm0
vbroadcastss -3 * SIZE(BO, BI, SIZE), %xmm5
VFMADDPS_I %xmm9,%xmm5,%xmm0
addq $2, BI
addq $2, %rax
.endm
.macro SAVE1x1
vbroadcastss ALPHA_R, %xmm0
vbroadcastss ALPHA_I, %xmm1
// swap high and low 64 bytes
vshufps $0xb1, %xmm9 , %xmm9, %xmm9
#if defined(NN) || defined(NT) || defined(TN) || defined(TT) || \
defined(NR) || defined(NC) || defined(TR) || defined(TC)
vaddsubps %xmm9, %xmm8 , %xmm8
vshufps $0xb1, %xmm8 , %xmm8, %xmm9
#else
vaddsubps %xmm8, %xmm9 ,%xmm9
vmovaps %xmm9, %xmm8
// swap high and low 64 bytes
vshufps $0xb1, %xmm9 , %xmm9, %xmm9
#endif
// multiply with ALPHA_R
vmulps %xmm8 , %xmm0, %xmm8
// multiply with ALPHA_I
vmulps %xmm9 , %xmm1, %xmm9
vaddsubps %xmm9, %xmm8 , %xmm8
#ifndef TRMMKERNEL
vmovsd (CO1), %xmm14
vaddps %xmm14, %xmm8 , %xmm8
#endif
vmovsd %xmm8 , (CO1)
.endm
/************************************************************************************************/
PROLOGUE
PROFCODE
subq $STACKSIZE, %rsp
movq %rbx, (%rsp)
movq %rbp, 8(%rsp)
movq %r12, 16(%rsp)
movq %r13, 24(%rsp)
movq %r14, 32(%rsp)
movq %r15, 40(%rsp)
vzeroupper
#ifdef WINDOWS_ABI
movq %rdi, 48(%rsp)
movq %rsi, 56(%rsp)
movups %xmm6, 64(%rsp)
movups %xmm7, 80(%rsp)
movups %xmm8, 96(%rsp)
movups %xmm9, 112(%rsp)
movups %xmm10, 128(%rsp)
movups %xmm11, 144(%rsp)
movups %xmm12, 160(%rsp)
movups %xmm13, 176(%rsp)
movups %xmm14, 192(%rsp)
movups %xmm15, 208(%rsp)
movq ARG1, OLD_M
movq ARG2, OLD_N
movq ARG3, OLD_K
movq OLD_A, A
movq OLD_B, B
movq OLD_C, C
movq OLD_LDC, LDC
#ifdef TRMMKERNEL
movsd OLD_OFFSET, %xmm12
#endif
vmovaps %xmm3, %xmm0
#else
movq STACKSIZE + 8(%rsp), LDC
#ifdef TRMMKERNEL
movsd STACKSIZE + 16(%rsp), %xmm12
#endif
#endif
movq %rsp, SP # save old stack
subq $128 + L_BUFFER_SIZE, %rsp
andq $-4096, %rsp # align stack
STACK_TOUCH
cmpq $0, OLD_M
je .L999
cmpq $0, OLD_N
je .L999
cmpq $0, OLD_K
je .L999
movq OLD_M, M
movq OLD_N, N
movq OLD_K, K
vmovss %xmm0, ALPHA_R
vmovss %xmm1, ALPHA_I
salq $ZBASE_SHIFT, LDC
movq N, %rax
xorq %rdx, %rdx
movq $2, %rdi
divq %rdi // N / 2
movq %rax, Ndiv6 // N / 2
movq %rdx, Nmod6 // N % 2
#ifdef TRMMKERNEL
vmovsd %xmm12, OFFSET
vmovsd %xmm12, KK
#ifndef LEFT
negq KK
#endif
#endif
.L2_0:
movq Ndiv6, J
cmpq $0, J
je .L1_0
ALIGN_4
.L2_01:
// copy to sub buffer
movq B, BO1
leaq BUFFER1, BO // first buffer to BO
movq K, %rax
ALIGN_4
.L2_02b:
vmovups (BO1), %xmm0
vmovups %xmm0, (BO)
addq $4*SIZE,BO1
addq $4*SIZE,BO
decq %rax
jnz .L2_02b
.L2_02c:
movq BO1, B // next offset of B
.L2_10:
movq C, CO1
leaq (C, LDC, 2), C // c += 2 * ldc
#if defined(TRMMKERNEL) && defined(LEFT)
movq OFFSET, %rax
movq %rax, KK
#endif
movq A, AO // aoffset = a
addq $16 * SIZE, AO
movq M, I
sarq $3, I // i = (m >> 3)
je .L2_4_10
ALIGN_4
/**********************************************************************************************************/
.L2_8_11:
#if !defined(TRMMKERNEL) || \
(defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
leaq BUFFER1, BO // first buffer to BO
addq $8 * SIZE, BO
#else
movq KK, %rax
leaq BUFFER1, BO // first buffer to BO
addq $8 * SIZE, BO
movq %rax, BI // Index for BO
leaq (,BI,4), BI // BI = BI * 4 ; number of values
leaq (BO, BI, SIZE), BO
salq $4, %rax // rax = rax *16 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
vzeroall
#ifndef TRMMKERNEL
movq K, %rax
#elif (defined(LEFT) && !defined(TRANSA)) || (!defined(LEFT) && defined(TRANSA))
movq K, %rax
subq KK, %rax
movq %rax, KKK
#else
movq KK, %rax
#ifdef LEFT
addq $8, %rax // number of values in AO
#else
addq $2, %rax // number of values in BO
#endif
movq %rax, KKK
#endif
andq $-8, %rax // K = K - ( K % 8 )
je .L2_8_16
movq %rax, BI // Index for BO
leaq ( ,BI,4), BI // BI = BI * 4 ; number of values
salq $4, %rax // rax = rax *16 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L2_8_12:
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL8x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL8x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x2_SUB
je .L2_8_16
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL8x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL8x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x2_SUB
je .L2_8_16
jmp .L2_8_12
ALIGN_4
.L2_8_16:
#ifndef TRMMKERNEL
movq K, %rax
#else
movq KKK, %rax
#endif
andq $7, %rax # if (k & 1)
je .L2_8_19
movq %rax, BI // Index for BO
leaq ( ,BI,4), BI // BI = BI * 4 ; number of values
salq $4, %rax // rax = rax *16 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L2_8_17:
KERNEL8x2_SUB
jl .L2_8_17
ALIGN_4
.L2_8_19:
SAVE8x2
#if (defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
movq K, %rax
subq KKK, %rax
movq %rax, BI // Index for BO
leaq ( ,BI,4), BI // BI = BI * 4 ; number of values
leaq (BO, BI, SIZE), BO
salq $4, %rax // rax = rax *16 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
#if defined(TRMMKERNEL) && defined(LEFT)
addq $8, KK
#endif
addq $16 * SIZE, CO1 # coffset += 16
decq I # i --
jg .L2_8_11
ALIGN_4
/**********************************************************************************************************/
.L2_4_10:
testq $7, M
jz .L2_4_60 // to next 2 lines of N
testq $4, M
jz .L2_4_20
ALIGN_4
.L2_4_11:
#if !defined(TRMMKERNEL) || \
(defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
leaq BUFFER1, BO // first buffer to BO
addq $8 * SIZE, BO
#else
movq KK, %rax
leaq BUFFER1, BO // first buffer to BO
addq $8 * SIZE, BO
movq %rax, BI // Index for BO
leaq (,BI,4), BI // BI = BI * 4 ; number of values
leaq (BO, BI, SIZE), BO
salq $3, %rax // rax = rax * 8 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
vzeroall
#ifndef TRMMKERNEL
movq K, %rax
#elif (defined(LEFT) && !defined(TRANSA)) || (!defined(LEFT) && defined(TRANSA))
movq K, %rax
subq KK, %rax
movq %rax, KKK
#else
movq KK, %rax
#ifdef LEFT
addq $4, %rax // number of values in AO
#else
addq $2, %rax // number of values in BO
#endif
movq %rax, KKK
#endif
andq $-8, %rax // K = K - ( K % 8 )
je .L2_4_16
movq %rax, BI // Index for BO
leaq ( ,BI,4), BI // BI = BI * 4 ; number of values
salq $3, %rax // rax = rax * 8 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L2_4_12:
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL4x2_SUB
KERNEL4x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL4x2_SUB
KERNEL4x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL4x2_SUB
KERNEL4x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL4x2_SUB
KERNEL4x2_SUB
je .L2_4_16
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL4x2_SUB
KERNEL4x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL4x2_SUB
KERNEL4x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL4x2_SUB
KERNEL4x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL4x2_SUB
KERNEL4x2_SUB
je .L2_4_16
jmp .L2_4_12
ALIGN_4
.L2_4_16:
#ifndef TRMMKERNEL
movq K, %rax
#else
movq KKK, %rax
#endif
andq $7, %rax # if (k & 1)
je .L2_4_19
movq %rax, BI // Index for BO
leaq ( ,BI,4), BI // BI = BI * 4 ; number of values
salq $3, %rax // rax = rax * 8 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L2_4_17:
KERNEL4x2_SUB
jl .L2_4_17
ALIGN_4
.L2_4_19:
SAVE4x2
#if (defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
movq K, %rax
subq KKK, %rax
movq %rax, BI // Index for BO
leaq ( ,BI,4), BI // BI = BI * 4 ; number of values
leaq (BO, BI, SIZE), BO
salq $3, %rax // rax = rax * 8 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
#if defined(TRMMKERNEL) && defined(LEFT)
addq $4, KK
#endif
addq $8 * SIZE, CO1 # coffset += 8
ALIGN_4
/**************************************************************************
* Rest of M
***************************************************************************/
.L2_4_20:
testq $2, M
jz .L2_4_40
ALIGN_4
.L2_4_21:
#if !defined(TRMMKERNEL) || \
(defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
leaq BUFFER1, BO // first buffer to BO
addq $8 * SIZE, BO
#else
movq KK, %rax
leaq BUFFER1, BO // first buffer to BO
addq $8 * SIZE, BO
movq %rax, BI // Index for BO
leaq (,BI,4), BI // BI = BI * 4 ; number of values
leaq (BO, BI, SIZE), BO
salq $2, %rax // rax = rax * 4 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
vzeroall
#ifndef TRMMKERNEL
movq K, %rax
#elif (defined(LEFT) && !defined(TRANSA)) || (!defined(LEFT) && defined(TRANSA))
movq K, %rax
subq KK, %rax
movq %rax, KKK
#else
movq KK, %rax
#ifdef LEFT
addq $2, %rax // number of values in AO
#else
addq $2, %rax // number of values in BO
#endif
movq %rax, KKK
#endif
andq $-8, %rax // K = K - ( K % 8 )
je .L2_4_26
movq %rax, BI // Index for BO
leaq ( ,BI,4), BI // BI = BI * 4 ; number of values
salq $2, %rax // rax = rax * 4 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L2_4_22:
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL2x2_SUB
KERNEL2x2_SUB
KERNEL2x2_SUB
KERNEL2x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL2x2_SUB
KERNEL2x2_SUB
KERNEL2x2_SUB
KERNEL2x2_SUB
je .L2_4_26
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL2x2_SUB
KERNEL2x2_SUB
KERNEL2x2_SUB
KERNEL2x2_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL2x2_SUB
KERNEL2x2_SUB
KERNEL2x2_SUB
KERNEL2x2_SUB
je .L2_4_26
jmp .L2_4_22
ALIGN_4
.L2_4_26:
#ifndef TRMMKERNEL
movq K, %rax
#else
movq KKK, %rax
#endif
andq $7, %rax # if (k & 1)
je .L2_4_29
movq %rax, BI // Index for BO
leaq ( ,BI,4), BI // BI = BI * 4 ; number of values
salq $2, %rax // rax = rax * 4 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L2_4_27:
KERNEL2x2_SUB
jl .L2_4_27
ALIGN_4
.L2_4_29:
vbroadcastss ALPHA_R, %xmm0
vbroadcastss ALPHA_I, %xmm1
// swap high and low 64 bytes
vshufps $0xb1, %xmm9 , %xmm9, %xmm9
vshufps $0xb1, %xmm11, %xmm11, %xmm11
#if defined(NN) || defined(NT) || defined(TN) || defined(TT) || \
defined(NR) || defined(NC) || defined(TR) || defined(TC)
vaddsubps %xmm9, %xmm8 , %xmm8
vaddsubps %xmm11,%xmm10, %xmm10
vshufps $0xb1, %xmm8 , %xmm8, %xmm9
vshufps $0xb1, %xmm10, %xmm10, %xmm11
#else
vaddsubps %xmm8, %xmm9 ,%xmm9
vaddsubps %xmm10, %xmm11,%xmm11
vmovaps %xmm9, %xmm8
vmovaps %xmm11, %xmm10
// swap high and low 64 bytes
vshufps $0xb1, %xmm9 , %xmm9, %xmm9
vshufps $0xb1, %xmm11, %xmm11, %xmm11
#endif
// multiply with ALPHA_R
vmulps %xmm8 , %xmm0, %xmm8
vmulps %xmm10, %xmm0, %xmm10
// multiply with ALPHA_I
vmulps %xmm9 , %xmm1, %xmm9
vmulps %xmm11, %xmm1, %xmm11
vaddsubps %xmm9, %xmm8 , %xmm8
vaddsubps %xmm11,%xmm10, %xmm10
#ifndef TRMMKERNEL
vaddps (CO1), %xmm8 , %xmm8
vaddps (CO1, LDC), %xmm10, %xmm10
#endif
vmovups %xmm8 , (CO1)
vmovups %xmm10 , (CO1, LDC)
#if (defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
movq K, %rax
subq KKK, %rax
movq %rax, BI // Index for BO
leaq ( ,BI,4), BI // BI = BI * 4 ; number of values
leaq (BO, BI, SIZE), BO
salq $2, %rax // rax = rax * 4 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
#if defined(TRMMKERNEL) && defined(LEFT)
addq $2, KK
#endif
addq $4 * SIZE, CO1 # coffset += 4
decq I # i --
jg .L2_4_21
ALIGN_4
/**************************************************************************/
.L2_4_40:
testq $1, M
jz .L2_4_60 // to next 2 lines of N
ALIGN_4
.L2_4_41:
#if !defined(TRMMKERNEL) || \
(defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
leaq BUFFER1, BO // first buffer to BO
addq $8 * SIZE, BO
#else
movq KK, %rax
leaq BUFFER1, BO // first buffer to BO
addq $8 * SIZE, BO
movq %rax, BI // Index for BO
leaq (,BI,4), BI // BI = BI * 4 ; number of values
leaq (BO, BI, SIZE), BO
salq $1, %rax // rax = rax * 2 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
vzeroall
#ifndef TRMMKERNEL
movq K, %rax
#elif (defined(LEFT) && !defined(TRANSA)) || (!defined(LEFT) && defined(TRANSA))
movq K, %rax
subq KK, %rax
movq %rax, KKK
#else
movq KK, %rax
#ifdef LEFT
addq $1, %rax // number of values in AO
#else
addq $2, %rax // number of values in BO
#endif
movq %rax, KKK
#endif
andq $-8, %rax // K = K - ( K % 8 )
je .L2_4_46
movq %rax, BI // Index for BO
leaq ( ,BI,4), BI // BI = BI * 4 ; number of values
salq $1, %rax // rax = rax * 2 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L2_4_42:
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL1x2_SUB
KERNEL1x2_SUB
KERNEL1x2_SUB
KERNEL1x2_SUB
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL1x2_SUB
KERNEL1x2_SUB
KERNEL1x2_SUB
KERNEL1x2_SUB
je .L2_4_46
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL1x2_SUB
KERNEL1x2_SUB
KERNEL1x2_SUB
KERNEL1x2_SUB
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL1x2_SUB
KERNEL1x2_SUB
KERNEL1x2_SUB
KERNEL1x2_SUB
je .L2_4_46
jmp .L2_4_42
ALIGN_4
.L2_4_46:
#ifndef TRMMKERNEL
movq K, %rax
#else
movq KKK, %rax
#endif
andq $7, %rax # if (k & 1)
je .L2_4_49
movq %rax, BI // Index for BO
leaq ( ,BI,4), BI // BI = BI * 4 ; number of values
salq $1, %rax // rax = rax * 2 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L2_4_47:
KERNEL1x2_SUB
jl .L2_4_47
ALIGN_4
.L2_4_49:
SAVE1x2
#if (defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
movq K, %rax
subq KKK, %rax
movq %rax, BI // Index for BO
leaq ( ,BI,4), BI // BI = BI * 4 ; number of values
leaq (BO, BI, SIZE), BO
salq $1, %rax // rax = rax * 2 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
#if defined(TRMMKERNEL) && defined(LEFT)
addq $1, KK
#endif
addq $2 * SIZE, CO1 # coffset += 2
decq I # i --
jg .L2_4_41
ALIGN_4
.L2_4_60:
#if defined(TRMMKERNEL) && !defined(LEFT)
addq $2, KK
#endif
decq J // j --
jg .L2_01 // next 2 lines of N
.L1_0:
/************************************************************************************************
* Loop for Nmod6 % 2 > 0
*************************************************************************************************/
movq Nmod6, J
andq $1, J // j % 2
je .L999
ALIGN_4
.L1_01:
// copy to sub buffer
movq B, BO1
leaq BUFFER1, BO // first buffer to BO
movq K, %rax
ALIGN_4
.L1_02b:
vmovsd (BO1), %xmm0
vmovsd %xmm0, (BO)
addq $2*SIZE,BO1
addq $2*SIZE,BO
decq %rax
jnz .L1_02b
.L1_02c:
movq BO1, B // next offset of B
.L1_10:
movq C, CO1
leaq (C, LDC, 1), C // c += 1 * ldc
#if defined(TRMMKERNEL) && defined(LEFT)
movq OFFSET, %rax
movq %rax, KK
#endif
movq A, AO // aoffset = a
addq $16 * SIZE, AO
movq M, I
sarq $3, I // i = (m >> 3)
je .L1_4_10
ALIGN_4
/**************************************************************************************************/
.L1_8_11:
#if !defined(TRMMKERNEL) || \
(defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
leaq BUFFER1, BO // first buffer to BO
addq $4 * SIZE, BO
#else
movq KK, %rax
leaq BUFFER1, BO // first buffer to BO
addq $4 * SIZE, BO
movq %rax, BI // Index for BO
leaq (,BI,2), BI // BI = BI * 2 ; number of values
leaq (BO, BI, SIZE), BO
salq $4, %rax // rax = rax *16 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
vzeroall
#ifndef TRMMKERNEL
movq K, %rax
#elif (defined(LEFT) && !defined(TRANSA)) || (!defined(LEFT) && defined(TRANSA))
movq K, %rax
subq KK, %rax
movq %rax, KKK
#else
movq KK, %rax
#ifdef LEFT
addq $8, %rax // number of values in AO
#else
addq $1, %rax // number of values in BO
#endif
movq %rax, KKK
#endif
andq $-8, %rax // K = K - ( K % 8 )
je .L1_8_16
movq %rax, BI // Index for BO
leaq ( ,BI,2), BI // BI = BI * 2 ; number of values
salq $4, %rax // rax = rax *16 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L1_8_12:
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL8x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x1_SUB
je .L1_8_16
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL8x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL8x1_SUB
je .L1_8_16
jmp .L1_8_12
ALIGN_4
.L1_8_16:
#ifndef TRMMKERNEL
movq K, %rax
#else
movq KKK, %rax
#endif
andq $7, %rax # if (k & 1)
je .L1_8_19
movq %rax, BI // Index for BO
leaq ( ,BI,2), BI // BI = BI * 4 ; number of values
salq $4, %rax // rax = rax *16 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L1_8_17:
KERNEL8x1_SUB
jl .L1_8_17
ALIGN_4
.L1_8_19:
SAVE8x1
#if (defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
movq K, %rax
subq KKK, %rax
movq %rax, BI // Index for BO
leaq ( ,BI,2), BI // BI = BI * 2 ; number of values
leaq (BO, BI, SIZE), BO
salq $4, %rax // rax = rax *16 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
#if defined(TRMMKERNEL) && defined(LEFT)
addq $8, KK
#endif
addq $16 * SIZE, CO1 # coffset += 16
decq I # i --
jg .L1_8_11
ALIGN_4
/**************************************************************************************************/
.L1_4_10:
testq $7, M
jz .L999
testq $4, M
jz .L1_4_20
.L1_4_11:
#if !defined(TRMMKERNEL) || \
(defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
leaq BUFFER1, BO // first buffer to BO
addq $4 * SIZE, BO
#else
movq KK, %rax
leaq BUFFER1, BO // first buffer to BO
addq $4 * SIZE, BO
movq %rax, BI // Index for BO
leaq (,BI,2), BI // BI = BI * 2 ; number of values
leaq (BO, BI, SIZE), BO
salq $3, %rax // rax = rax * 8 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
vzeroall
#ifndef TRMMKERNEL
movq K, %rax
#elif (defined(LEFT) && !defined(TRANSA)) || (!defined(LEFT) && defined(TRANSA))
movq K, %rax
subq KK, %rax
movq %rax, KKK
#else
movq KK, %rax
#ifdef LEFT
addq $4, %rax // number of values in AO
#else
addq $1, %rax // number of values in BO
#endif
movq %rax, KKK
#endif
andq $-8, %rax // K = K - ( K % 8 )
je .L1_4_16
movq %rax, BI // Index for BO
leaq ( ,BI,2), BI // BI = BI * 2 ; number of values
salq $3, %rax // rax = rax * 8 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L1_4_12:
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL4x1_SUB
KERNEL4x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL4x1_SUB
KERNEL4x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL4x1_SUB
KERNEL4x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL4x1_SUB
KERNEL4x1_SUB
je .L1_4_16
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL4x1_SUB
KERNEL4x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL4x1_SUB
KERNEL4x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL4x1_SUB
KERNEL4x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL4x1_SUB
KERNEL4x1_SUB
je .L1_4_16
jmp .L1_4_12
ALIGN_4
.L1_4_16:
#ifndef TRMMKERNEL
movq K, %rax
#else
movq KKK, %rax
#endif
andq $7, %rax # if (k & 1)
je .L1_4_19
movq %rax, BI // Index for BO
leaq ( ,BI,2), BI // BI = BI * 4 ; number of values
salq $3, %rax // rax = rax * 8 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L1_4_17:
KERNEL4x1_SUB
jl .L1_4_17
ALIGN_4
.L1_4_19:
SAVE4x1
#if (defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
movq K, %rax
subq KKK, %rax
movq %rax, BI // Index for BO
leaq ( ,BI,2), BI // BI = BI * 2 ; number of values
leaq (BO, BI, SIZE), BO
salq $3, %rax // rax = rax * 8 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
#if defined(TRMMKERNEL) && defined(LEFT)
addq $4, KK
#endif
addq $8 * SIZE, CO1 # coffset += 8
ALIGN_4
/**************************************************************************
* Rest of M
***************************************************************************/
.L1_4_20:
testq $2, M
jz .L1_4_40
ALIGN_4
.L1_4_21:
#if !defined(TRMMKERNEL) || \
(defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
leaq BUFFER1, BO // first buffer to BO
addq $4 * SIZE, BO
#else
movq KK, %rax
leaq BUFFER1, BO // first buffer to BO
addq $4 * SIZE, BO
movq %rax, BI // Index for BO
leaq (,BI,2), BI // BI = BI * 2 ; number of values
leaq (BO, BI, SIZE), BO
salq $2, %rax // rax = rax * 4 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
vzeroall
#ifndef TRMMKERNEL
movq K, %rax
#elif (defined(LEFT) && !defined(TRANSA)) || (!defined(LEFT) && defined(TRANSA))
movq K, %rax
subq KK, %rax
movq %rax, KKK
#else
movq KK, %rax
#ifdef LEFT
addq $2, %rax // number of values in AO
#else
addq $1, %rax // number of values in BO
#endif
movq %rax, KKK
#endif
andq $-8, %rax // K = K - ( K % 8 )
je .L1_4_26
movq %rax, BI // Index for BO
leaq ( ,BI,2), BI // BI = BI * 2 ; number of values
salq $2, %rax // rax = rax * 4 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L1_4_22:
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL2x1_SUB
KERNEL2x1_SUB
KERNEL2x1_SUB
KERNEL2x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL2x1_SUB
KERNEL2x1_SUB
KERNEL2x1_SUB
KERNEL2x1_SUB
je .L1_4_26
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL2x1_SUB
KERNEL2x1_SUB
KERNEL2x1_SUB
KERNEL2x1_SUB
prefetcht0 A_PR1(AO,%rax,SIZE)
KERNEL2x1_SUB
KERNEL2x1_SUB
KERNEL2x1_SUB
KERNEL2x1_SUB
je .L1_4_26
jmp .L1_4_22
ALIGN_4
.L1_4_26:
#ifndef TRMMKERNEL
movq K, %rax
#else
movq KKK, %rax
#endif
andq $7, %rax # if (k & 1)
je .L1_4_29
movq %rax, BI // Index for BO
leaq ( ,BI,2), BI // BI = BI * 2; number of values
salq $2, %rax // rax = rax * 4 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L1_4_27:
KERNEL2x1_SUB
jl .L1_4_27
ALIGN_4
.L1_4_29:
SAVE2x1
#if (defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
movq K, %rax
subq KKK, %rax
movq %rax, BI // Index for BO
leaq ( ,BI,2), BI // BI = BI * 2 ; number of values
leaq (BO, BI, SIZE), BO
salq $2, %rax // rax = rax * 4 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
#if defined(TRMMKERNEL) && defined(LEFT)
addq $2, KK
#endif
addq $4 * SIZE, CO1 # coffset += 4
ALIGN_4
/**************************************************************************/
.L1_4_40:
testq $1, M
jz .L999 // to next 2 lines of N
ALIGN_4
.L1_4_41:
#if !defined(TRMMKERNEL) || \
(defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
leaq BUFFER1, BO // first buffer to BO
addq $4 * SIZE, BO
#else
movq KK, %rax
leaq BUFFER1, BO // first buffer to BO
addq $4 * SIZE, BO
movq %rax, BI // Index for BO
leaq (,BI,2), BI // BI = BI * 2 ; number of values
leaq (BO, BI, SIZE), BO
salq $1, %rax // rax = rax * 2 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
vzeroall
#ifndef TRMMKERNEL
movq K, %rax
#elif (defined(LEFT) && !defined(TRANSA)) || (!defined(LEFT) && defined(TRANSA))
movq K, %rax
subq KK, %rax
movq %rax, KKK
#else
movq KK, %rax
#ifdef LEFT
addq $1, %rax // number of values in AO
#else
addq $1, %rax // number of values in BO
#endif
movq %rax, KKK
#endif
andq $-8, %rax // K = K - ( K % 8 )
je .L1_4_46
movq %rax, BI // Index for BO
leaq ( ,BI,2), BI // BI = BI * 2 ; number of values
salq $1, %rax // rax = rax * 2 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L1_4_42:
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL1x1_SUB
KERNEL1x1_SUB
KERNEL1x1_SUB
KERNEL1x1_SUB
KERNEL1x1_SUB
KERNEL1x1_SUB
KERNEL1x1_SUB
KERNEL1x1_SUB
je .L1_4_46
prefetcht0 A_PR1(AO,%rax,SIZE)
prefetcht0 B_PR1(BO,BI,SIZE)
KERNEL1x1_SUB
KERNEL1x1_SUB
KERNEL1x1_SUB
KERNEL1x1_SUB
KERNEL1x1_SUB
KERNEL1x1_SUB
KERNEL1x1_SUB
KERNEL1x1_SUB
je .L1_4_46
jmp .L1_4_42
ALIGN_4
.L1_4_46:
#ifndef TRMMKERNEL
movq K, %rax
#else
movq KKK, %rax
#endif
andq $7, %rax # if (k & 1)
je .L1_4_49
movq %rax, BI // Index for BO
leaq ( ,BI,2), BI // BI = BI * 2 ; number of values
salq $1, %rax // rax = rax * 2 ; number of values
leaq (AO, %rax, SIZE), AO
leaq (BO, BI, SIZE), BO
negq BI
negq %rax
ALIGN_4
.L1_4_47:
KERNEL1x1_SUB
jl .L1_4_47
ALIGN_4
.L1_4_49:
SAVE1x1
#if (defined(TRMMKERNEL) && defined(LEFT) && defined(TRANSA)) || \
(defined(TRMMKERNEL) && !defined(LEFT) && !defined(TRANSA))
movq K, %rax
subq KKK, %rax
movq %rax, BI // Index for BO
leaq ( ,BI,2), BI // BI = BI * 2 ; number of values
leaq (BO, BI, SIZE), BO
salq $1, %rax // rax = rax * 2 ; number of values
leaq (AO, %rax, SIZE), AO
#endif
#if defined(TRMMKERNEL) && defined(LEFT)
addq $1, KK
#endif
addq $2 * SIZE, CO1 # coffset += 2
ALIGN_4
.L999:
movq SP, %rsp
movq (%rsp), %rbx
movq 8(%rsp), %rbp
movq 16(%rsp), %r12
movq 24(%rsp), %r13
movq 32(%rsp), %r14
movq 40(%rsp), %r15
#ifdef WINDOWS_ABI
movq 48(%rsp), %rdi
movq 56(%rsp), %rsi
movups 64(%rsp), %xmm6
movups 80(%rsp), %xmm7
movups 96(%rsp), %xmm8
movups 112(%rsp), %xmm9
movups 128(%rsp), %xmm10
movups 144(%rsp), %xmm11
movups 160(%rsp), %xmm12
movups 176(%rsp), %xmm13
movups 192(%rsp), %xmm14
movups 208(%rsp), %xmm15
#endif
addq $STACKSIZE, %rsp
ret
EPILOGUE
Reference in New Issue View Git Blame Copy Permalink