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blis/kernels/knc/3/bli_sgemm_knc_asm_30x16.c
Field G. Van Zee 0645f239fb Remove UT-Austin from copyright headers' clause 3. 
Details:
- Removed explicit reference to The University of Texas at Austin in the
  third clause of the license comment blocks of all relevant files and
  replaced it with a more all-encompassing "copyright holder(s)".
- Removed duplicate words ("derived") from a few kernels' license
  comment blocks.
- Homogenized license comment block in kernels/zen/3/bli_gemm_small.c
  with format of all other comment blocks.
2018-12-04 14:31:06 -06:00

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/*
BLIS
An object-based framework for developing high-performance BLAS-like
libraries.
Copyright (C) 2014, The University of Texas at Austin
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
- Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
- 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.
- Neither the name(s) of the copyright holder(s) nor the names of its
contributors may be used to endorse or promote products derived
from this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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 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.
*/
#include "blis.h"
#include <assert.h>
#define A_L1_PREFETCH_DIST 4
#define B_L1_PREFETCH_DIST 2
#define L2_PREFETCH_DIST 16 // Must be greater than 10, because of the way the loop is constructed.
//Alternate code path uused if C is not row-major
#define UPDATE_C_ROW_SCATTERED(REG1, NUM, BASE_DEST) \
{ \
__asm kmov k3, ebx \
__asm GATHER##NUM: \
__asm vgatherdps zmm31{k3}, [BASE_DEST + zmm30 * 4] \
__asm jknzd k3, GATHER##NUM \
\
__asm vmulps REG1, REG1, 0[r12]{1to16} /*scale by alpha*/ \
__asm vfmadd132ps zmm31, REG1, 0[r13]{1to16} /*scale by beta, add in result*/\
__asm kmov k3, ebx \
\
__asm SCATTER##NUM: \
__asm vscatterdps [BASE_DEST + zmm30 * 4]{k3}, zmm31 \
__asm jknzd k3, SCATTER##NUM \
__asm add BASE_DEST, r11 \
}
//One iteration of the k_r loop.
//Each iteration, we prefetch A into L1 and into L2
#define ONE_ITER_MAIN_LOOP(C_ADDR, COUNTER) \
{\
__asm vbroadcastf32x4 zmm30, 0[r15] \
__asm vmovaps zmm31, 0[rbx] \
\
__asm vfmadd231ps zmm0, zmm31, zmm30{aaaa} \
__asm vfmadd231ps zmm4, zmm31, 4*4[r15]{1to16} \
__asm vprefetch0 A_L1_PREFETCH_DIST*256[r15] \
__asm vfmadd231ps zmm5, zmm31, 5*4[r15]{1to16} \
__asm vprefetch0 A_L1_PREFETCH_DIST*256+64[r15] \
__asm vfmadd231ps zmm6, zmm31, 6*4[r15]{1to16} \
__asm vprefetch0 A_L1_PREFETCH_DIST*256+128[r15]\
__asm vfmadd231ps zmm7, zmm31, 7*4[r15]{1to16} \
__asm vprefetch0 A_L1_PREFETCH_DIST*256+192[r15]\
__asm vfmadd231ps zmm8, zmm31, 8*4[r15]{1to16} \
\
__asm vprefetch1 0[r15 + r14] \
__asm vfmadd231ps zmm9, zmm31, 9*4[r15]{1to16} \
__asm vfmadd231ps zmm1, zmm31, zmm30{bbbb} \
__asm vfmadd231ps zmm2, zmm31, zmm30{cccc} \
__asm vfmadd231ps zmm3, zmm31, zmm30{dddd} \
__asm vfmadd231ps zmm10, zmm31, 10*4[r15]{1to16} \
\
__asm vprefetch1 64[r15 + r14] \
__asm vfmadd231ps zmm11, zmm31, 11*4[r15]{1to16} \
__asm vfmadd231ps zmm12, zmm31, 12*4[r15]{1to16} \
__asm vfmadd231ps zmm13, zmm31, 13*4[r15]{1to16} \
__asm vfmadd231ps zmm14, zmm31, 14*4[r15]{1to16} \
__asm vfmadd231ps zmm15, zmm31, 15*4[r15]{1to16} \
\
__asm vprefetch1 2*64[r15 + r14] \
__asm vfmadd231ps zmm16, zmm31, 16*4[r15]{1to16} \
__asm vfmadd231ps zmm17, zmm31, 17*4[r15]{1to16} \
__asm vfmadd231ps zmm18, zmm31, 18*4[r15]{1to16} \
__asm vfmadd231ps zmm19, zmm31, 19*4[r15]{1to16} \
__asm vfmadd231ps zmm20, zmm31, 20*4[r15]{1to16} \
\
__asm vprefetch1 3*64[r15 + r14] \
__asm vfmadd231ps zmm21, zmm31, 21*4[r15]{1to16} \
__asm add r15, r12 \
__asm vfmadd231ps zmm22, zmm31, -10*4[r15]{1to16}\
__asm vfmadd231ps zmm23, zmm31, -9*4[r15]{1to16} \
__asm vfmadd231ps zmm24, zmm31, -8*4[r15]{1to16} \
__asm dec COUNTER \
__asm vfmadd231ps zmm25, zmm31, -7*4[r15]{1to16} \
\
\
__asm vprefetch1 0[rbx + r13] \
__asm vfmadd231ps zmm26, zmm31, -6*4[r15]{1to16} \
__asm vprefetch0 B_L1_PREFETCH_DIST*16*4[rbx] \
__asm vfmadd231ps zmm27, zmm31, -5*4[r15]{1to16} \
__asm add rbx, r9 \
__asm vfmadd231ps zmm28, zmm31, -4*4[r15]{1to16} \
__asm cmp COUNTER, 0 \
__asm vfmadd231ps zmm29, zmm31, -3*4[r15]{1to16} \
}
//One iteration of the k_r loop.
//Same as ONE_ITER_MAIN_LOOP, but additionally, we prefetch one line of C into the L2 cache
//Current placement of this prefetch instruction is somewhat arbitrary.
#define ONE_ITER_PC_L2(C_ADDR) \
{\
__asm vbroadcastf32x4 zmm30, 0[r15] \
__asm vmovaps zmm31, 0[rbx] \
\
__asm vfmadd231ps zmm0, zmm31, zmm30{aaaa} \
__asm vfmadd231ps zmm4, zmm31, 4*4[r15]{1to16} \
__asm vprefetch0 A_L1_PREFETCH_DIST*256[r15] \
__asm vfmadd231ps zmm5, zmm31, 5*4[r15]{1to16} \
__asm vprefetch0 A_L1_PREFETCH_DIST*256+64[r15] \
__asm vfmadd231ps zmm6, zmm31, 6*4[r15]{1to16} \
__asm vprefetch0 A_L1_PREFETCH_DIST*256+128[r15]\
__asm vfmadd231ps zmm7, zmm31, 7*4[r15]{1to16} \
__asm vprefetch0 A_L1_PREFETCH_DIST*256+192[r15]\
__asm vfmadd231ps zmm8, zmm31, 8*4[r15]{1to16} \
\
__asm vprefetch1 0[r15 + r14] \
__asm vfmadd231ps zmm9, zmm31, 9*4[r15]{1to16} \
__asm vfmadd231ps zmm1, zmm31, zmm30{bbbb} \
__asm vfmadd231ps zmm2, zmm31, zmm30{cccc} \
__asm vfmadd231ps zmm3, zmm31, zmm30{dddd} \
__asm vfmadd231ps zmm10, zmm31, 10*4[r15]{1to16} \
\
__asm vprefetch1 64[r15 + r14] \
__asm vfmadd231ps zmm11, zmm31, 11*4[r15]{1to16} \
__asm vprefetch1 0[C_ADDR] \
__asm vfmadd231ps zmm12, zmm31, 12*4[r15]{1to16} \
__asm vfmadd231ps zmm13, zmm31, 13*4[r15]{1to16} \
__asm vfmadd231ps zmm14, zmm31, 14*4[r15]{1to16} \
__asm vfmadd231ps zmm15, zmm31, 15*4[r15]{1to16} \
\
__asm vprefetch1 2*64[r15 + r14] \
__asm vfmadd231ps zmm16, zmm31, 16*4[r15]{1to16} \
__asm vfmadd231ps zmm17, zmm31, 17*4[r15]{1to16} \
__asm vfmadd231ps zmm18, zmm31, 18*4[r15]{1to16} \
__asm vfmadd231ps zmm19, zmm31, 19*4[r15]{1to16} \
__asm vfmadd231ps zmm20, zmm31, 20*4[r15]{1to16} \
\
__asm vprefetch1 3*64[r15 + r14] \
__asm vfmadd231ps zmm21, zmm31, 21*4[r15]{1to16} \
__asm add r15, r12 \
__asm vfmadd231ps zmm22, zmm31, -10*4[r15]{1to16}\
__asm vfmadd231ps zmm23, zmm31, -9*4[r15]{1to16} \
__asm add C_ADDR, r11 \
__asm vfmadd231ps zmm24, zmm31, -8*4[r15]{1to16} \
__asm dec r8 \
__asm vfmadd231ps zmm25, zmm31, -7*4[r15]{1to16} \
\
\
__asm vprefetch1 0[rbx + r13] \
__asm vfmadd231ps zmm26, zmm31, -6*4[r15]{1to16} \
__asm vprefetch0 B_L1_PREFETCH_DIST*16*4[rbx] \
__asm vfmadd231ps zmm27, zmm31, -5*4[r15]{1to16} \
__asm add rbx, r9 \
__asm vfmadd231ps zmm28, zmm31, -4*4[r15]{1to16} \
__asm cmp r8, 0 \
__asm vfmadd231ps zmm29, zmm31, -3*4[r15]{1to16} \
\
}
//One iteration of the k_r loop.
//Same as ONE_ITER_MAIN_LOOP, but additionally, we prefetch 3 cache lines of C into the L1 cache
//Current placement of these prefetch instructions is somewhat arbitrary.
#define ONE_ITER_PC_L1(C_ADDR) \
{\
__asm vbroadcastf32x4 zmm30, 0[r15] \
__asm vmovaps zmm31, 0[rbx] \
\
__asm vfmadd231ps zmm0, zmm31, zmm30{aaaa} \
__asm vfmadd231ps zmm4, zmm31, 4*4[r15]{1to16} \
__asm vprefetch0 A_L1_PREFETCH_DIST*256[r15] \
__asm vfmadd231ps zmm5, zmm31, 5*4[r15]{1to16} \
__asm vprefetch0 A_L1_PREFETCH_DIST*256+64[r15] \
__asm vfmadd231ps zmm6, zmm31, 6*4[r15]{1to16} \
__asm vprefetch0 A_L1_PREFETCH_DIST*256+128[r15]\
__asm vfmadd231ps zmm7, zmm31, 7*4[r15]{1to16} \
__asm vprefetch0 A_L1_PREFETCH_DIST*256+192[r15]\
__asm vfmadd231ps zmm8, zmm31, 8*4[r15]{1to16} \
\
__asm vprefetch1 0[r15 + r14] \
__asm vfmadd231ps zmm9, zmm31, 9*4[r15]{1to16} \
__asm vprefetch0 0[C_ADDR] \
__asm vfmadd231ps zmm1, zmm31, zmm30{bbbb} \
__asm add C_ADDR, r11 \
__asm vfmadd231ps zmm2, zmm31, zmm30{cccc} \
__asm vfmadd231ps zmm3, zmm31, zmm30{dddd} \
__asm vfmadd231ps zmm10, zmm31, 10*4[r15]{1to16} \
\
__asm vprefetch1 64[r15 + r14] \
__asm vfmadd231ps zmm11, zmm31, 11*4[r15]{1to16} \
__asm vprefetch0 0[C_ADDR] \
__asm vfmadd231ps zmm12, zmm31, 12*4[r15]{1to16} \
__asm add C_ADDR, r11 \
__asm vfmadd231ps zmm13, zmm31, 13*4[r15]{1to16} \
__asm vfmadd231ps zmm14, zmm31, 14*4[r15]{1to16} \
__asm vfmadd231ps zmm15, zmm31, 15*4[r15]{1to16} \
\
__asm vprefetch1 2*64[r15 + r14] \
__asm vfmadd231ps zmm16, zmm31, 16*4[r15]{1to16} \
__asm vprefetch0 0[C_ADDR] \
__asm vfmadd231ps zmm17, zmm31, 17*4[r15]{1to16} \
__asm add C_ADDR, r11 \
__asm vfmadd231ps zmm18, zmm31, 18*4[r15]{1to16} \
__asm vfmadd231ps zmm19, zmm31, 19*4[r15]{1to16} \
__asm vfmadd231ps zmm20, zmm31, 20*4[r15]{1to16} \
\
__asm vprefetch1 3*64[r15 + r14] \
__asm vfmadd231ps zmm21, zmm31, 21*4[r15]{1to16} \
__asm add r15, r12 \
__asm vfmadd231ps zmm22, zmm31, -10*4[r15]{1to16}\
__asm vfmadd231ps zmm23, zmm31, -9*4[r15]{1to16} \
__asm vfmadd231ps zmm24, zmm31, -8*4[r15]{1to16} \
__asm dec r8 \
__asm vfmadd231ps zmm25, zmm31, -7*4[r15]{1to16} \
\
\
__asm vprefetch1 0[rbx + r13] \
__asm vfmadd231ps zmm26, zmm31, -6*4[r15]{1to16} \
__asm vprefetch0 B_L1_PREFETCH_DIST*16*4[rbx] \
__asm vfmadd231ps zmm27, zmm31, -5*4[r15]{1to16} \
__asm add rbx, r9 \
__asm vfmadd231ps zmm28, zmm31, -4*4[r15]{1to16} \
__asm cmp r8, 0 \
__asm vfmadd231ps zmm29, zmm31, -3*4[r15]{1to16} \
\
}
//This is an array used for the scattter/gather instructions.
int offsets[16] __attribute__((aligned(0x1000))) = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15};
//#define MONITORS
//#define LOOPMON
void bli_sgemm_knc_asm_30x16
(
dim_t k,
float* restrict alpha,
float* restrict a,
float* restrict b,
float* restrict beta,
float* restrict c, inc_t rs_c, inc_t cs_c,
auxinfo_t* restrict data,
cntx_t* restrict cntx
)
{
float * a_next = bli_auxinfo_next_a( data );
float * b_next = bli_auxinfo_next_b( data );
int * offsetPtr = &offsets[0];
uint64_t k64 = k;
#ifdef MONITORS
int toph, topl, both, botl, midl, midh, mid2l, mid2h;
#endif
#ifdef LOOPMON
int tlooph, tloopl, blooph, bloopl;
#endif
__asm
{
#ifdef MONITORS
rdtsc
mov topl, eax
mov toph, edx
#endif
vpxord zmm0, zmm0, zmm0
vmovaps zmm1, zmm0 //clear out registers
vmovaps zmm2, zmm0
mov rsi, k64 //loop index
vmovaps zmm3, zmm0
mov r11, rs_c //load row stride
vmovaps zmm4, zmm0
sal r11, 2 //scale row stride
vmovaps zmm5, zmm0
mov r15, a //load address of a
vmovaps zmm6, zmm0
mov rbx, b //load address of b
vmovaps zmm7, zmm0
vmovaps zmm8, zmm0
lea r10, [r11 + 2*r11 + 0] //r10 has 3 * r11
vmovaps zmm9, zmm0
vmovaps zmm10, zmm0
mov rdi, r11
vmovaps zmm11, zmm0
sal rdi, 2 //rdi has 4*r11
vmovaps zmm12, zmm0
mov rcx, c //load address of c for prefetching
vmovaps zmm13, zmm0
vmovaps zmm14, zmm0
mov r8, k64
vmovaps zmm15, zmm0
vmovaps zmm16, zmm0
vmovaps zmm17, zmm0
mov r13, L2_PREFETCH_DIST*4*16
vmovaps zmm18, zmm0
mov r14, L2_PREFETCH_DIST*4*32
vmovaps zmm19, zmm0
vmovaps zmm20, zmm0
vmovaps zmm21, zmm0
vmovaps zmm22, zmm0
vmovaps zmm23, zmm0
sub r8, 30 + L2_PREFETCH_DIST //Check if we have over 40 operations to do.
vmovaps zmm24, zmm0
mov r8, 30
vmovaps zmm25, zmm0
mov r9, 16*4 //amount to increment b* by each iteration
vmovaps zmm26, zmm0
mov r12, 32*4 //amount to increment a* by each iteration
vmovaps zmm27, zmm0
vmovaps zmm28, zmm0
vmovaps zmm29, zmm0
#ifdef MONITORS
rdtsc
mov midl, eax
mov midh, edx
#endif
jle CONSIDER_UNDER_40
sub rsi, 30 + L2_PREFETCH_DIST
//First 30 iterations
LOOPREFECHCL2:
ONE_ITER_PC_L2(rcx)
jne LOOPREFECHCL2
mov rcx, c
//Main Loop.
LOOPMAIN:
ONE_ITER_MAIN_LOOP(rcx, rsi)
jne LOOPMAIN
//Penultimate 22 iterations.
//Break these off from the main loop to avoid prefetching extra shit.
mov r14, a_next
mov r13, b_next
sub r14, r15
sub r13, rbx
mov rsi, L2_PREFETCH_DIST-10
LOOPMAIN2:
ONE_ITER_MAIN_LOOP(rcx, rsi)
jne LOOPMAIN2
//Last 10 iterations
mov r8, 10
LOOPREFETCHCL1:
ONE_ITER_PC_L1(rcx)
jne LOOPREFETCHCL1
jmp POSTACCUM
//Alternate main loop, with no prefetching of C
//Used when <= 40 iterations
CONSIDER_UNDER_40:
mov rsi, k64
test rsi, rsi
je POSTACCUM
LOOP_UNDER_40:
ONE_ITER_MAIN_LOOP(rcx, rsi)
jne LOOP_UNDER_40
POSTACCUM:
#ifdef MONITORS
rdtsc
mov mid2l, eax
mov mid2h, edx
#endif
mov r9, c //load address of c for update
mov r12, alpha //load address of alpha
// Check if C is row stride. If not, jump to the slow scattered update
mov r14, cs_c
dec r14
jne SCATTEREDUPDATE
mov r14, beta
vbroadcastss zmm31, 0[r14]
vmulps zmm0, zmm0, 0[r12]{1to16}
vmulps zmm1, zmm1, 0[r12]{1to16}
vmulps zmm2, zmm2, 0[r12]{1to16}
vmulps zmm3, zmm3, 0[r12]{1to16}
vfmadd231ps zmm0, zmm31, [r9+0]
vfmadd231ps zmm1, zmm31, [r9+r11+0]
vfmadd231ps zmm2, zmm31, [r9+2*r11+0]
vfmadd231ps zmm3, zmm31, [r9+r10+0]
vmovaps [r9+0], zmm0
vmovaps [r9+r11+0], zmm1
vmovaps [r9+2*r11+0], zmm2
vmovaps [r9+r10+0], zmm3
add r9, rdi
vmulps zmm4, zmm4, 0[r12]{1to16}
vmulps zmm5, zmm5, 0[r12]{1to16}
vmulps zmm6, zmm6, 0[r12]{1to16}
vmulps zmm7, zmm7, 0[r12]{1to16}
vfmadd231ps zmm4, zmm31, [r9+0]
vfmadd231ps zmm5, zmm31, [r9+r11+0]
vfmadd231ps zmm6, zmm31, [r9+2*r11+0]
vfmadd231ps zmm7, zmm31, [r9+r10+0]
vmovaps [r9+0], zmm4
vmovaps [r9+r11+0], zmm5
vmovaps [r9+2*r11+0], zmm6
vmovaps [r9+r10+0], zmm7
add r9, rdi
vmulps zmm8, zmm8, 0[r12]{1to16}
vmulps zmm9, zmm9, 0[r12]{1to16}
vmulps zmm10, zmm10, 0[r12]{1to16}
vmulps zmm11, zmm11, 0[r12]{1to16}
vfmadd231ps zmm8, zmm31, [r9+0]
vfmadd231ps zmm9, zmm31, [r9+r11+0]
vfmadd231ps zmm10, zmm31, [r9+2*r11+0]
vfmadd231ps zmm11, zmm31, [r9+r10+0]
vmovaps [r9+0], zmm8
vmovaps [r9+r11+0], zmm9
vmovaps [r9+2*r11+0], zmm10
vmovaps [r9+r10+0], zmm11
add r9, rdi
vmulps zmm12, zmm12, 0[r12]{1to16}
vmulps zmm13, zmm13, 0[r12]{1to16}
vmulps zmm14, zmm14, 0[r12]{1to16}
vmulps zmm15, zmm15, 0[r12]{1to16}
vfmadd231ps zmm12, zmm31, [r9+0]
vfmadd231ps zmm13, zmm31, [r9+r11+0]
vfmadd231ps zmm14, zmm31, [r9+2*r11+0]
vfmadd231ps zmm15, zmm31, [r9+r10+0]
vmovaps [r9+0], zmm12
vmovaps [r9+r11+0], zmm13
vmovaps [r9+2*r11+0], zmm14
vmovaps [r9+r10+0], zmm15
add r9, rdi
vmulps zmm16, zmm16, 0[r12]{1to16}
vmulps zmm17, zmm17, 0[r12]{1to16}
vmulps zmm18, zmm18, 0[r12]{1to16}
vmulps zmm19, zmm19, 0[r12]{1to16}
vfmadd231ps zmm16, zmm31, [r9+0]
vfmadd231ps zmm17, zmm31, [r9+r11+0]
vfmadd231ps zmm18, zmm31, [r9+2*r11+0]
vfmadd231ps zmm19, zmm31, [r9+r10+0]
vmovaps [r9+0], zmm16
vmovaps [r9+r11+0], zmm17
vmovaps [r9+2*r11+0], zmm18
vmovaps [r9+r10+0], zmm19
add r9, rdi
vmulps zmm20, zmm20, 0[r12]{1to16}
vmulps zmm21, zmm21, 0[r12]{1to16}
vmulps zmm22, zmm22, 0[r12]{1to16}
vmulps zmm23, zmm23, 0[r12]{1to16}
vfmadd231ps zmm20, zmm31, [r9+0]
vfmadd231ps zmm21, zmm31, [r9+r11+0]
vfmadd231ps zmm22, zmm31, [r9+2*r11+0]
vfmadd231ps zmm23, zmm31, [r9+r10+0]
vmovaps [r9+0], zmm20
vmovaps [r9+r11+0], zmm21
vmovaps [r9+2*r11+0], zmm22
vmovaps [r9+r10+0], zmm23
add r9, rdi
vmulps zmm24, zmm24, 0[r12]{1to16}
vmulps zmm25, zmm25, 0[r12]{1to16}
vmulps zmm26, zmm26, 0[r12]{1to16}
vmulps zmm27, zmm27, 0[r12]{1to16}
vfmadd231ps zmm24, zmm31, [r9+0]
vfmadd231ps zmm25, zmm31, [r9+r11+0]
vfmadd231ps zmm26, zmm31, [r9+2*r11+0]
vfmadd231ps zmm27, zmm31, [r9+r10+0]
vmovaps [r9+0], zmm24
vmovaps [r9+r11+0], zmm25
vmovaps [r9+2*r11+0], zmm26
vmovaps [r9+r10+0], zmm27
add r9, rdi
vmulps zmm28, zmm28, 0[r12]{1to16}
vmulps zmm29, zmm29, 0[r12]{1to16}
vfmadd231ps zmm28, zmm31, [r9+0]
vfmadd231ps zmm29, zmm31, [r9+r11+0]
vmovaps [r9+0], zmm28
vmovaps [r9+r11+0], zmm29
jmp END
SCATTEREDUPDATE:
mov r10, offsetPtr
vmovaps zmm31, 0[r10]
vpbroadcastd zmm30, cs_c
mov r13, beta
vpmulld zmm30, zmm31, zmm30
mov ebx, 0xFFFF
UPDATE_C_ROW_SCATTERED(zmm0, 0, r9)
UPDATE_C_ROW_SCATTERED(zmm1, 1, r9)
UPDATE_C_ROW_SCATTERED(zmm2, 2, r9)
UPDATE_C_ROW_SCATTERED(zmm3, 3, r9)
UPDATE_C_ROW_SCATTERED(zmm4, 4, r9)
UPDATE_C_ROW_SCATTERED(zmm5, 5, r9)
UPDATE_C_ROW_SCATTERED(zmm6, 6, r9)
UPDATE_C_ROW_SCATTERED(zmm7, 7, r9)
UPDATE_C_ROW_SCATTERED(zmm8, 8, r9)
UPDATE_C_ROW_SCATTERED(zmm9, 9, r9)
UPDATE_C_ROW_SCATTERED(zmm10, 10, r9)
UPDATE_C_ROW_SCATTERED(zmm11, 11, r9)
UPDATE_C_ROW_SCATTERED(zmm12, 12, r9)
UPDATE_C_ROW_SCATTERED(zmm13, 13, r9)
UPDATE_C_ROW_SCATTERED(zmm14, 14, r9)
UPDATE_C_ROW_SCATTERED(zmm15, 15, r9)
UPDATE_C_ROW_SCATTERED(zmm16, 16, r9)
UPDATE_C_ROW_SCATTERED(zmm17, 17, r9)
UPDATE_C_ROW_SCATTERED(zmm18, 18, r9)
UPDATE_C_ROW_SCATTERED(zmm19, 19, r9)
UPDATE_C_ROW_SCATTERED(zmm20, 20, r9)
UPDATE_C_ROW_SCATTERED(zmm21, 21, r9)
UPDATE_C_ROW_SCATTERED(zmm22, 22, r9)
UPDATE_C_ROW_SCATTERED(zmm23, 23, r9)
UPDATE_C_ROW_SCATTERED(zmm24, 24, r9)
UPDATE_C_ROW_SCATTERED(zmm25, 25, r9)
UPDATE_C_ROW_SCATTERED(zmm26, 26, r9)
UPDATE_C_ROW_SCATTERED(zmm27, 27, r9)
UPDATE_C_ROW_SCATTERED(zmm28, 28, r9)
UPDATE_C_ROW_SCATTERED(zmm29, 29, r9)
END:
#ifdef MONITORS
rdtsc
mov botl, eax
mov both, edx
#endif
}
#ifdef LOOPMON
printf("looptime = \t%d\n", bloopl - tloopl);
#endif
#ifdef MONITORS
dim_t top = ((dim_t)toph << 32) | topl;
dim_t mid = ((dim_t)midh << 32) | midl;
dim_t mid2 = ((dim_t)mid2h << 32) | mid2l;
dim_t bot = ((dim_t)both << 32) | botl;
printf("setup =\t%u\tmain loop =\t%u\tcleanup=\t%u\ttotal=\t%u\n", mid - top, mid2 - mid, bot - mid2, bot - top);
#endif
}
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