#ifndef CACHE_LINE_SIZE
#define CACHE_LINE_SIZE 8
#endif
#ifndef DIVIDE_RATE
#define DIVIDE_RATE 2
#endif
#ifndef GEMM_PREFERED_SIZE
#define GEMM_PREFERED_SIZE 1
#endif
#if MAX_CPU_NUMBER > BLAS3_MEM_ALLOC_THRESHOLD
#define USE_ALLOC_HEAP
#endif
#ifndef GEMM_LOCAL
#if defined(NN)
#define GEMM_LOCAL GEMM_NN
#elif defined(NT)
#define GEMM_LOCAL GEMM_NT
#elif defined(NR)
#define GEMM_LOCAL GEMM_NR
#elif defined(NC)
#define GEMM_LOCAL GEMM_NC
#elif defined(TN)
#define GEMM_LOCAL GEMM_TN
#elif defined(TT)
#define GEMM_LOCAL GEMM_TT
#elif defined(TR)
#define GEMM_LOCAL GEMM_TR
#elif defined(TC)
#define GEMM_LOCAL GEMM_TC
#elif defined(RN)
#define GEMM_LOCAL GEMM_RN
#elif defined(RT)
#define GEMM_LOCAL GEMM_RT
#elif defined(RR)
#define GEMM_LOCAL GEMM_RR
#elif defined(RC)
#define GEMM_LOCAL GEMM_RC
#elif defined(CN)
#define GEMM_LOCAL GEMM_CN
#elif defined(CT)
#define GEMM_LOCAL GEMM_CT
#elif defined(CR)
#define GEMM_LOCAL GEMM_CR
#elif defined(CC)
#define GEMM_LOCAL GEMM_CC
#endif
#endif
typedef struct {
volatile
BLASLONG working[MAX_CPU_NUMBER][CACHE_LINE_SIZE * DIVIDE_RATE];
} job_t;
#ifndef BETA_OPERATION
#ifndef COMPLEX
#define BETA_OPERATION(M_FROM, M_TO, N_FROM, N_TO, BETA, C, LDC) \
GEMM_BETA((M_TO) - (M_FROM), (N_TO - N_FROM), 0, \
BETA[0], NULL, 0, NULL, 0, \
(FLOAT *)(C) + ((M_FROM) + (N_FROM) * (LDC)) * COMPSIZE, LDC)
#else
#define BETA_OPERATION(M_FROM, M_TO, N_FROM, N_TO, BETA, C, LDC) \
GEMM_BETA((M_TO) - (M_FROM), (N_TO - N_FROM), 0, \
BETA[0], BETA[1], NULL, 0, NULL, 0, \
(FLOAT *)(C) + ((M_FROM) + (N_FROM) * (LDC)) * COMPSIZE, LDC)
#endif
#endif
#ifndef ICOPY_OPERATION
#if defined(NN) || defined(NT) || defined(NC) || defined(NR) || \
defined(RN) || defined(RT) || defined(RC) || defined(RR)
#define ICOPY_OPERATION(M, N, A, LDA, X, Y, BUFFER) GEMM_ITCOPY(M, N, (IFLOAT *)(A) + ((Y) + (X) * (LDA)) * COMPSIZE, LDA, BUFFER);
#else
#define ICOPY_OPERATION(M, N, A, LDA, X, Y, BUFFER) GEMM_INCOPY(M, N, (IFLOAT *)(A) + ((X) + (Y) * (LDA)) * COMPSIZE, LDA, BUFFER);
#endif
#endif
#ifndef OCOPY_OPERATION
#if defined(NN) || defined(TN) || defined(CN) || defined(RN) || \
defined(NR) || defined(TR) || defined(CR) || defined(RR)
#define OCOPY_OPERATION(M, N, A, LDA, X, Y, BUFFER) GEMM_ONCOPY(M, N, (IFLOAT *)(A) + ((X) + (Y) * (LDA)) * COMPSIZE, LDA, BUFFER);
#else
#define OCOPY_OPERATION(M, N, A, LDA, X, Y, BUFFER) GEMM_OTCOPY(M, N, (IFLOAT *)(A) + ((Y) + (X) * (LDA)) * COMPSIZE, LDA, BUFFER);
#endif
#endif
#ifndef KERNEL_FUNC
#if defined(NN) || defined(NT) || defined(TN) || defined(TT)
#define KERNEL_FUNC GEMM_KERNEL_N
#endif
#if defined(CN) || defined(CT) || defined(RN) || defined(RT)
#define KERNEL_FUNC GEMM_KERNEL_L
#endif
#if defined(NC) || defined(TC) || defined(NR) || defined(TR)
#define KERNEL_FUNC GEMM_KERNEL_R
#endif
#if defined(CC) || defined(CR) || defined(RC) || defined(RR)
#define KERNEL_FUNC GEMM_KERNEL_B
#endif
#endif
#ifndef KERNEL_OPERATION
#ifndef COMPLEX
#define KERNEL_OPERATION(M, N, K, ALPHA, SA, SB, C, LDC, X, Y) \
KERNEL_FUNC(M, N, K, ALPHA[0], SA, SB, (FLOAT *)(C) + ((X) + (Y) * LDC) * COMPSIZE, LDC)
#else
#define KERNEL_OPERATION(M, N, K, ALPHA, SA, SB, C, LDC, X, Y) \
KERNEL_FUNC(M, N, K, ALPHA[0], ALPHA[1], SA, SB, (FLOAT *)(C) + ((X) + (Y) * LDC) * COMPSIZE, LDC)
#endif
#endif
#ifndef FUSED_KERNEL_OPERATION
#if defined(NN) || defined(TN) || defined(CN) || defined(RN) || \
defined(NR) || defined(TR) || defined(CR) || defined(RR)
#ifndef COMPLEX
#define FUSED_KERNEL_OPERATION(M, N, K, ALPHA, SA, SB, B, LDB, C, LDC, I, J, L) \
FUSED_GEMM_KERNEL_N(M, N, K, ALPHA[0], SA, SB, \
(FLOAT *)(B) + ((L) + (J) * LDB) * COMPSIZE, LDB, (FLOAT *)(C) + ((I) + (J) * LDC) * COMPSIZE, LDC)
#else
#define FUSED_KERNEL_OPERATION(M, N, K, ALPHA, SA, SB, B, LDB, C, LDC, I, J, L) \
FUSED_GEMM_KERNEL_N(M, N, K, ALPHA[0], ALPHA[1], SA, SB, \
(FLOAT *)(B) + ((L) + (J) * LDB) * COMPSIZE, LDB, (FLOAT *)(C) + ((I) + (J) * LDC) * COMPSIZE, LDC)
#endif
#else
#ifndef COMPLEX
#define FUSED_KERNEL_OPERATION(M, N, K, ALPHA, SA, SB, B, LDB, C, LDC, I, J, L) \
FUSED_GEMM_KERNEL_T(M, N, K, ALPHA[0], SA, SB, \
(FLOAT *)(B) + ((J) + (L) * LDB) * COMPSIZE, LDB, (FLOAT *)(C) + ((I) + (J) * LDC) * COMPSIZE, LDC)
#else
#define FUSED_KERNEL_OPERATION(M, N, K, ALPHA, SA, SB, B, LDB, C, LDC, I, J, L) \
FUSED_GEMM_KERNEL_T(M, N, K, ALPHA[0], ALPHA[1], SA, SB, \
(FLOAT *)(B) + ((J) + (L) * LDB) * COMPSIZE, LDB, (FLOAT *)(C) + ((I) + (J) * LDC) * COMPSIZE, LDC)
#endif
#endif
#endif
#ifndef A
#define A args -> a
#endif
#ifndef LDA
#define LDA args -> lda
#endif
#ifndef B
#define B args -> b
#endif
#ifndef LDB
#define LDB args -> ldb
#endif
#ifndef C
#define C args -> c
#endif
#ifndef LDC
#define LDC args -> ldc
#endif
#ifndef M
#define M args -> m
#endif
#ifndef N
#define N args -> n
#endif
#ifndef K
#define K args -> k
#endif
#ifdef TIMING
#define START_RPCC() rpcc_counter = rpcc()
#define STOP_RPCC(COUNTER) COUNTER += rpcc() - rpcc_counter
#else
#define START_RPCC()
#define STOP_RPCC(COUNTER)
#endif
static int inner_thread(blas_arg_t *args, BLASLONG *range_m, BLASLONG *range_n, IFLOAT *sa, IFLOAT *sb, BLASLONG mypos){
IFLOAT *buffer[DIVIDE_RATE];
BLASLONG k, lda, ldb, ldc;
BLASLONG m_from, m_to, n_from, n_to;
FLOAT *alpha, *beta;
IFLOAT *a, *b;
FLOAT *c;
job_t *job = (job_t *)args -> common;
BLASLONG nthreads_m;
BLASLONG mypos_m, mypos_n;
BLASLONG is, js, ls, bufferside, jjs;
BLASLONG min_i, min_l, div_n, min_jj;
BLASLONG i, current;
BLASLONG l1stride;
#ifdef TIMING
BLASULONG rpcc_counter;
BLASULONG copy_A = 0;
BLASULONG copy_B = 0;
BLASULONG kernel = 0;
BLASULONG waiting1 = 0;
BLASULONG waiting2 = 0;
BLASULONG waiting3 = 0;
BLASULONG waiting6[MAX_CPU_NUMBER];
BLASULONG ops = 0;
for (i = 0; i < args -> nthreads; i++) waiting6[i] = 0;
#endif
k = K;
a = (IFLOAT *)A;
b = (IFLOAT *)B;
c = (FLOAT *)C;
lda = LDA;
ldb = LDB;
ldc = LDC;
alpha = (FLOAT *)args -> alpha;
beta = (FLOAT *)args -> beta;
nthreads_m = args -> nthreads;
if (range_m) {
nthreads_m = range_m[-1];
}
mypos_n = blas_quickdivide(mypos, nthreads_m);
mypos_m = mypos - mypos_n * nthreads_m;
m_from = 0;
m_to = M;
if (range_m) {
m_from = range_m[mypos_m + 0];
m_to = range_m[mypos_m + 1];
}
n_from = 0;
n_to = N;
if (range_n) {
n_from = range_n[mypos + 0];
n_to = range_n[mypos + 1];
}
if (beta) {
#ifndef COMPLEX
if (beta[0] != ONE)
#else
if ((beta[0] != ONE) || (beta[1] != ZERO))
#endif
BETA_OPERATION(m_from, m_to, range_n[mypos_n * nthreads_m], range_n[(mypos_n + 1) * nthreads_m], beta, c, ldc);
}
if ((k == 0) || (alpha == NULL)) return 0;
if (alpha[0] == ZERO
#ifdef COMPLEX
&& alpha[1] == ZERO
#endif
) return 0;
div_n = (n_to - n_from + DIVIDE_RATE - 1) / DIVIDE_RATE;
buffer[0] = sb;
for (i = 1; i < DIVIDE_RATE; i++) {
buffer[i] = buffer[i - 1] + GEMM_Q * ((div_n + GEMM_UNROLL_N - 1)/GEMM_UNROLL_N) * GEMM_UNROLL_N * COMPSIZE;
}
for(ls = 0; ls < k; ls += min_l){
min_l = k - ls;
if (min_l >= GEMM_Q * 2) {
min_l = GEMM_Q;
} else {
if (min_l > GEMM_Q) min_l = (min_l + 1) / 2;
}
BLASLONG pad_min_l = min_l;
#if defined(HALF)
#if defined(DYNAMIC_ARCH)
pad_min_l = (min_l + gotoblas->sbgemm_align_k - 1) & ~(gotoblas->sbgemm_align_k-1);
#else
pad_min_l = (min_l + SBGEMM_ALIGN_K - 1) & ~(SBGEMM_ALIGN_K - 1);;
#endif
#endif
* Note: We are currently on the first step in m
*/
l1stride = 1;
min_i = m_to - m_from;
if (min_i >= GEMM_P * 2) {
min_i = GEMM_P;
} else {
if (min_i > GEMM_P) {
min_i = ((min_i / 2 + GEMM_UNROLL_M - 1)/GEMM_UNROLL_M) * GEMM_UNROLL_M;
} else {
if (args -> nthreads == 1) l1stride = 0;
}
}
START_RPCC();
ICOPY_OPERATION(min_l, min_i, a, lda, ls, m_from, sa);
STOP_RPCC(copy_A);
div_n = (n_to - n_from + DIVIDE_RATE - 1) / DIVIDE_RATE;
for (js = n_from, bufferside = 0; js < n_to; js += div_n, bufferside ++) {
START_RPCC();
for (i = 0; i < args -> nthreads; i++)
while (job[mypos].working[i][CACHE_LINE_SIZE * bufferside]) {YIELDING;};
STOP_RPCC(waiting1);
MB;
#if defined(FUSED_GEMM) && !defined(TIMING)
FUSED_KERNEL_OPERATION(min_i, MIN(n_to, js + div_n) - js, min_l, alpha,
sa, buffer[bufferside], b, ldb, c, ldc, m_from, js, ls);
#else
for(jjs = js; jjs < MIN(n_to, js + div_n); jjs += min_jj){
min_jj = MIN(n_to, js + div_n) - jjs;
#if defined(SKYLAKEX) || defined(COOPERLAKE) || defined(SAPPHIRERAPIDS)
if (min_jj >= 6*GEMM_UNROLL_N) min_jj = 6*GEMM_UNROLL_N;
#else
if (min_jj >= 3*GEMM_UNROLL_N) min_jj = 3*GEMM_UNROLL_N;
else
if (min_jj >= 2*GEMM_UNROLL_N) min_jj = 2*GEMM_UNROLL_N;
else
*/
if (min_jj > GEMM_UNROLL_N) min_jj = GEMM_UNROLL_N;
#endif
START_RPCC();
OCOPY_OPERATION(min_l, min_jj, b, ldb, ls, jjs,
buffer[bufferside] + pad_min_l * (jjs - js) * COMPSIZE * l1stride);
STOP_RPCC(copy_B);
START_RPCC();
KERNEL_OPERATION(min_i, min_jj, min_l, alpha,
sa, buffer[bufferside] + pad_min_l * (jjs - js) * COMPSIZE * l1stride,
c, ldc, m_from, jjs);
STOP_RPCC(kernel);
#ifdef TIMING
ops += 2 * min_i * min_jj * min_l;
#endif
}
#endif
WMB;
for (i = mypos_n * nthreads_m; i < (mypos_n + 1) * nthreads_m; i++)
job[mypos].working[i][CACHE_LINE_SIZE * bufferside] = (BLASLONG)buffer[bufferside];
}
current = mypos;
do {
* [ mypos_n * nthreads_m, (mypos_n+1) * nthreads_m ) */
current ++;
if (current >= (mypos_n + 1) * nthreads_m) current = mypos_n * nthreads_m;
div_n = (range_n[current + 1] - range_n[current] + DIVIDE_RATE - 1) / DIVIDE_RATE;
for (js = range_n[current], bufferside = 0; js < range_n[current + 1]; js += div_n, bufferside ++) {
if (current != mypos) {
START_RPCC();
while(job[current].working[mypos][CACHE_LINE_SIZE * bufferside] == 0) {YIELDING;};
STOP_RPCC(waiting2);
MB;
START_RPCC();
KERNEL_OPERATION(min_i, MIN(range_n[current + 1] - js, div_n), min_l, alpha,
sa, (IFLOAT *)job[current].working[mypos][CACHE_LINE_SIZE * bufferside],
c, ldc, m_from, js);
STOP_RPCC(kernel);
#ifdef TIMING
ops += 2 * min_i * MIN(range_n[current + 1] - js, div_n) * min_l;
#endif
}
if (m_to - m_from == min_i) {
WMB;
job[current].working[mypos][CACHE_LINE_SIZE * bufferside] &= 0;
}
}
} while (current != mypos);
* Note: First step has already been finished */
for(is = m_from + min_i; is < m_to; is += min_i){
min_i = m_to - is;
if (min_i >= GEMM_P * 2) {
min_i = GEMM_P;
} else
if (min_i > GEMM_P) {
min_i = (((min_i + 1) / 2 + GEMM_UNROLL_M - 1)/GEMM_UNROLL_M) * GEMM_UNROLL_M;
}
START_RPCC();
ICOPY_OPERATION(min_l, min_i, a, lda, ls, is, sa);
STOP_RPCC(copy_A);
current = mypos;
do {
div_n = (range_n[current + 1] - range_n[current] + DIVIDE_RATE - 1) / DIVIDE_RATE;
for (js = range_n[current], bufferside = 0; js < range_n[current + 1]; js += div_n, bufferside ++) {
START_RPCC();
KERNEL_OPERATION(min_i, MIN(range_n[current + 1] - js, div_n), min_l, alpha,
sa, (IFLOAT *)job[current].working[mypos][CACHE_LINE_SIZE * bufferside],
c, ldc, is, js);
STOP_RPCC(kernel);
#ifdef TIMING
ops += 2 * min_i * MIN(range_n[current + 1] - js, div_n) * min_l;
#endif
if (is + min_i >= m_to) {
WMB;
job[current].working[mypos][CACHE_LINE_SIZE * bufferside] &= 0;
}
}
* [ mypos_n * nthreads_m, (mypos_n+1) * nthreads_m ) */
current ++;
if (current >= (mypos_n + 1) * nthreads_m) current = mypos_n * nthreads_m;
} while (current != mypos);
}
}
START_RPCC();
for (i = 0; i < args -> nthreads; i++) {
for (js = 0; js < DIVIDE_RATE; js++) {
while (job[mypos].working[i][CACHE_LINE_SIZE * js] ) {YIELDING;};
}
}
STOP_RPCC(waiting3);
MB;
#ifdef TIMING
BLASLONG waiting = waiting1 + waiting2 + waiting3;
BLASLONG total = copy_A + copy_B + kernel + waiting;
fprintf(stderr, "GEMM [%2ld] Copy_A : %6.2f Copy_B : %6.2f Wait1 : %6.2f Wait2 : %6.2f Wait3 : %6.2f Kernel : %6.2f",
mypos, (double)copy_A /(double)total * 100., (double)copy_B /(double)total * 100.,
(double)waiting1 /(double)total * 100.,
(double)waiting2 /(double)total * 100.,
(double)waiting3 /(double)total * 100.,
(double)ops/(double)kernel / 4. * 100.);
fprintf(stderr, "\n");
#endif
return 0;
}
static int round_up(int remainder, int width, int multiple)
{
if (multiple > remainder || width <= multiple)
return width;
width = (width + multiple - 1) / multiple;
width = width * multiple;
return width;
}
static int gemm_driver(blas_arg_t *args, BLASLONG *range_m, BLASLONG
*range_n, IFLOAT *sa, IFLOAT *sb,
BLASLONG nthreads_m, BLASLONG nthreads_n) {
#ifdef USE_OPENMP
static omp_lock_t level3_lock, critical_section_lock;
static volatile BLASULONG init_lock = 0, omp_lock_initialized = 0,
parallel_section_left = MAX_PARALLEL_NUMBER;
while(omp_lock_initialized == 0)
{
blas_lock(&init_lock);
{
if(omp_lock_initialized == 0)
{
omp_init_lock(&level3_lock);
omp_init_lock(&critical_section_lock);
omp_lock_initialized = 1;
WMB;
}
blas_unlock(&init_lock);
}
}
#elif defined(OS_WINDOWS)
CRITICAL_SECTION level3_lock;
InitializeCriticalSection((PCRITICAL_SECTION)&level3_lock);
#else
static pthread_mutex_t level3_lock = PTHREAD_MUTEX_INITIALIZER;
static pthread_cond_t level3_wakeup = PTHREAD_COND_INITIALIZER;
volatile static BLASLONG CPU_AVAILABLE = MAX_CPU_NUMBER;
#endif
blas_arg_t newarg;
#ifndef USE_ALLOC_HEAP
job_t job[MAX_CPU_NUMBER];
#else
job_t * job = NULL;
#endif
blas_queue_t queue[MAX_CPU_NUMBER];
BLASLONG range_M_buffer[MAX_CPU_NUMBER + 2];
BLASLONG range_N_buffer[MAX_CPU_NUMBER + 2];
BLASLONG *range_M, *range_N;
BLASLONG num_parts;
BLASLONG nthreads = args -> nthreads;
BLASLONG width, width_n, i, j, k, js;
BLASLONG m, n, n_from, n_to;
int mode;
#if defined(DYNAMIC_ARCH)
int switch_ratio = gotoblas->switch_ratio;
#else
int switch_ratio = SWITCH_RATIO;
#endif
#ifndef COMPLEX
#ifdef XDOUBLE
mode = BLAS_XDOUBLE | BLAS_REAL | BLAS_NODE;
#elif defined(DOUBLE)
mode = BLAS_DOUBLE | BLAS_REAL | BLAS_NODE;
#else
mode = BLAS_SINGLE | BLAS_REAL | BLAS_NODE;
#endif
#else
#ifdef XDOUBLE
mode = BLAS_XDOUBLE | BLAS_COMPLEX | BLAS_NODE;
#elif defined(DOUBLE)
mode = BLAS_DOUBLE | BLAS_COMPLEX | BLAS_NODE;
#else
mode = BLAS_SINGLE | BLAS_COMPLEX | BLAS_NODE;
#endif
#endif
#ifdef USE_OPENMP
omp_set_lock(&level3_lock);
omp_set_lock(&critical_section_lock);
parallel_section_left--;
How OpenMP locks works with NUM_PARALLEL
1) parallel_section_left = Number of available concurrent executions of OpenBLAS - Number of currently executing OpenBLAS executions
2) level3_lock is acting like a master lock or barrier which stops OpenBLAS calls when all the parallel_section are currently busy executing other OpenBLAS calls
3) critical_section_lock is used for updating variables shared between threads executing OpenBLAS calls concurrently and for unlocking of master lock whenever required
4) Unlock master lock only when we have not already exhausted all the parallel_sections and allow another thread with a OpenBLAS call to enter
*/
if(parallel_section_left != 0)
omp_unset_lock(&level3_lock);
omp_unset_lock(&critical_section_lock);
#elif defined(OS_WINDOWS)
EnterCriticalSection((PCRITICAL_SECTION)&level3_lock);
#else
pthread_mutex_lock(&level3_lock);
while(CPU_AVAILABLE < nthreads) {
pthread_cond_wait(&level3_wakeup, &level3_lock);
}
CPU_AVAILABLE -= nthreads;
WMB;
pthread_mutex_unlock(&level3_lock);
#endif
#ifdef USE_ALLOC_HEAP
job = (job_t*)malloc(MAX_CPU_NUMBER * sizeof(job_t));
if(job==NULL){
fprintf(stderr, "OpenBLAS: malloc failed in %s\n", __func__);
exit(1);
}
#endif
newarg.m = args -> m;
newarg.n = args -> n;
newarg.k = args -> k;
newarg.a = args -> a;
newarg.b = args -> b;
newarg.c = args -> c;
newarg.lda = args -> lda;
newarg.ldb = args -> ldb;
newarg.ldc = args -> ldc;
newarg.alpha = args -> alpha;
newarg.beta = args -> beta;
newarg.nthreads = args -> nthreads;
newarg.common = (void *)job;
#ifdef PARAMTEST
newarg.gemm_p = args -> gemm_p;
newarg.gemm_q = args -> gemm_q;
newarg.gemm_r = args -> gemm_r;
#endif
* Note: The number of CPU partitions is stored in the -1 entry */
range_M = &range_M_buffer[1];
range_N = &range_N_buffer[1];
range_M[-1] = nthreads_m;
range_N[-1] = nthreads_n;
if (!range_m) {
range_M[0] = 0;
m = args -> m;
} else {
range_M[0] = range_m[0];
m = range_m[1] - range_m[0];
}
num_parts = 0;
while (m > 0){
width = blas_quickdivide(m + nthreads_m - num_parts - 1, nthreads_m - num_parts);
width = round_up(m, width, GEMM_PREFERED_SIZE);
m -= width;
if (m < 0) width = width + m;
range_M[num_parts + 1] = range_M[num_parts] + width;
num_parts ++;
}
for (i = num_parts; i < MAX_CPU_NUMBER; i++) {
range_M[i + 1] = range_M[num_parts];
}
for (i = 0; i < nthreads; i++) {
queue[i].mode = mode;
queue[i].routine = inner_thread;
queue[i].args = &newarg;
queue[i].range_m = range_M;
queue[i].range_n = range_N;
queue[i].sa = NULL;
queue[i].sb = NULL;
queue[i].next = &queue[i + 1];
}
queue[0].sa = sa;
queue[0].sb = sb;
queue[nthreads - 1].next = NULL;
if (!range_n) {
n_from = 0;
n_to = args -> n;
} else {
n_from = range_n[0];
n_to = range_n[1];
}
for(js = n_from; js < n_to; js += GEMM_R * nthreads){
n = n_to - js;
if (n > GEMM_R * nthreads) n = GEMM_R * nthreads;
range_N[0] = js;
num_parts = 0;
for(j = 0; j < nthreads_n; j++){
width_n = blas_quickdivide(n + nthreads_n - j - 1, nthreads_n - j);
n -= width_n;
for(i = 0; i < nthreads_m; i++){
width = blas_quickdivide(width_n + nthreads_m - i - 1, nthreads_m - i);
if (width < switch_ratio) {
width = switch_ratio;
}
width = round_up(width_n, width, GEMM_PREFERED_SIZE);
width_n -= width;
if (width_n < 0) {
width = width + width_n;
width_n = 0;
}
range_N[num_parts + 1] = range_N[num_parts] + width;
num_parts ++;
}
}
for (j = num_parts; j < MAX_CPU_NUMBER; j++) {
range_N[j + 1] = range_N[num_parts];
}
for (i = 0; i < nthreads; i++) {
for (j = 0; j < nthreads; j++) {
for (k = 0; k < DIVIDE_RATE; k++) {
job[i].working[j][CACHE_LINE_SIZE * k] = 0;
}
}
}
WMB;
exec_blas(nthreads, queue);
}
#ifdef USE_ALLOC_HEAP
free(job);
#endif
#ifdef USE_OPENMP
omp_set_lock(&critical_section_lock);
parallel_section_left++;
Unlock master lock only when all the parallel_sections are already exhausted and one of the thread has completed its OpenBLAS call
otherwise just increment the parallel_section_left
The master lock is only locked when we have exhausted all the parallel_sections, So only unlock it then and otherwise just increment the count
*/
if(parallel_section_left == 1)
omp_unset_lock(&level3_lock);
omp_unset_lock(&critical_section_lock);
#elif defined(OS_WINDOWS)
LeaveCriticalSection((PCRITICAL_SECTION)&level3_lock);
#else
pthread_mutex_lock(&level3_lock);
CPU_AVAILABLE += nthreads;
WMB;
pthread_cond_signal(&level3_wakeup);
pthread_mutex_unlock(&level3_lock);
#endif
return 0;
}
int CNAME(blas_arg_t *args, BLASLONG *range_m, BLASLONG *range_n, IFLOAT *sa, IFLOAT *sb, BLASLONG mypos){
BLASLONG m = args -> m;
BLASLONG n = args -> n;
BLASLONG nthreads_m, nthreads_n;
#if defined(DYNAMIC_ARCH)
int switch_ratio = gotoblas->switch_ratio;
#else
int switch_ratio = SWITCH_RATIO;
#endif
if (range_m) {
m = range_m[1] - range_m[0];
}
if (range_n) {
n = range_n[1] - range_n[0];
}
if (m < 2 * switch_ratio) {
nthreads_m = 1;
} else {
nthreads_m = args -> nthreads;
while (m < nthreads_m * switch_ratio) {
nthreads_m = nthreads_m / 2;
}
}
if (n < switch_ratio * nthreads_m) {
nthreads_n = 1;
} else {
nthreads_n = (n + switch_ratio * nthreads_m - 1) / (switch_ratio * nthreads_m);
if (nthreads_m * nthreads_n > args -> nthreads) {
nthreads_n = blas_quickdivide(args -> nthreads, nthreads_m);
}
while (nthreads_m % 2 == 0 && n * nthreads_m + m * nthreads_n > n * (nthreads_m / 2) + m * (nthreads_n * 2)) {
nthreads_m /= 2;
nthreads_n *= 2;
}
}
if (nthreads_m * nthreads_n <= 1) {
GEMM_LOCAL(args, range_m, range_n, sa, sb, 0);
} else {
args -> nthreads = nthreads_m * nthreads_n;
gemm_driver(args, range_m, range_n, sa, sb, nthreads_m, nthreads_n);
}
return 0;
}