265 lines
6.9 KiB
C
265 lines
6.9 KiB
C
#include <vx_spawn.h>
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#include <vx_intrinsics.h>
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#include <inttypes.h>
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#ifdef __cplusplus
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extern "C" {
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#endif
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#define NUM_CORES_MAX 32
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#define MIN(a, b) ((a) < (b) ? (a) : (b))
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typedef struct {
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vx_spawn_tasks_cb callback;
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void * arg;
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int offset;
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int N;
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int R;
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} wspawn_tasks_args_t;
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typedef struct {
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struct context_t * ctx;
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vx_spawn_kernel_cb callback;
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void * arg;
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int offset;
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int N;
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int R;
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char isXYpow2;
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char isXpow2;
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char log2XY;
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char log2X;
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} wspawn_kernel_args_t;
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void* g_wspawn_args[NUM_CORES_MAX];
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inline char is_log2(int x) {
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return ((x & (x-1)) == 0);
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}
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inline int fast_log2(int x) {
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float f = x;
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return (*(int*)(&f)>>23) - 127;
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}
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static void spawn_tasks_callback() {
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vx_tmc(vx_num_threads());
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int core_id = vx_core_id();
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int wid = vx_warp_id();
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int tid = vx_thread_id();
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int NT = vx_num_threads();
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wspawn_tasks_args_t* p_wspawn_args = (wspawn_tasks_args_t*)g_wspawn_args[core_id];
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int wK = (p_wspawn_args->N * wid) + MIN(p_wspawn_args->R, wid);
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int tK = p_wspawn_args->N + (wid < p_wspawn_args->R);
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int offset = p_wspawn_args->offset + (wK * NT) + (tid * tK);
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for (int task_id = offset, N = task_id + tK; task_id < N; ++task_id) {
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(p_wspawn_args->callback)(task_id, p_wspawn_args->arg);
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}
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vx_tmc(0 == wid);
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}
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void spawn_remaining_tasks_callback(int nthreads) {
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vx_tmc(nthreads);
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int core_id = vx_core_id();
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int tid = vx_thread_gid();
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wspawn_tasks_args_t* p_wspawn_args = (wspawn_tasks_args_t*)g_wspawn_args[core_id];
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int task_id = p_wspawn_args->offset + tid;
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(p_wspawn_args->callback)(task_id, p_wspawn_args->arg);
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vx_tmc(1);
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}
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void vx_spawn_tasks(int num_tasks, vx_spawn_tasks_cb callback , void * arg) {
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// device specs
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int NC = vx_num_cores();
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int NW = vx_num_warps();
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int NT = vx_num_threads();
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// current core id
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int core_id = vx_core_id();
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if (core_id >= NUM_CORES_MAX)
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return;
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// calculate necessary active cores
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int WT = NW * NT;
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int nC = (num_tasks > WT) ? (num_tasks / WT) : 1;
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int nc = MIN(nC, NC);
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if (core_id >= nc)
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return; // terminate extra cores
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// number of tasks per core
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int tasks_per_core = num_tasks / nc;
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int tasks_per_core0 = tasks_per_core;
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if (core_id == (NC-1)) {
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int QC_r = num_tasks - (nc * tasks_per_core0);
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tasks_per_core0 += QC_r; // last core executes remaining tasks
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}
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// number of tasks per warp
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int nW = tasks_per_core0 / NT; // total warps per core
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int rT = tasks_per_core0 - (nW * NT); // remaining threads
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int fW = (nW >= NW) ? (nW / NW) : 0; // full warps iterations
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int rW = (fW != 0) ? (nW - fW * NW) : 0; // remaining warps
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if (0 == fW)
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fW = 1;
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//--
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wspawn_tasks_args_t wspawn_args = { callback, arg, core_id * tasks_per_core, fW, rW };
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g_wspawn_args[core_id] = &wspawn_args;
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//--
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if (nW >= 1) {
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int nw = MIN(nW, NW);
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vx_wspawn(nw, spawn_tasks_callback);
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spawn_tasks_callback();
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}
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//--
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if (rT != 0) {
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wspawn_args.offset = tasks_per_core0 - rT;
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spawn_remaining_tasks_callback(rT);
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}
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}
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///////////////////////////////////////////////////////////////////////////////
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static void spawn_kernel_callback() {
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vx_tmc(vx_num_threads());
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int core_id = vx_core_id();
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int wid = vx_warp_id();
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int tid = vx_thread_id();
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int NT = vx_num_threads();
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wspawn_kernel_args_t* p_wspawn_args = (wspawn_kernel_args_t*)g_wspawn_args[core_id];
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int wK = (p_wspawn_args->N * wid) + MIN(p_wspawn_args->R, wid);
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int tK = p_wspawn_args->N + (wid < p_wspawn_args->R);
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int offset = p_wspawn_args->offset + (wK * NT) + (tid * tK);
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int X = p_wspawn_args->ctx->num_groups[0];
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int Y = p_wspawn_args->ctx->num_groups[1];
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int XY = X * Y;
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for (int wg_id = offset, N = wg_id + tK; wg_id < N; ++wg_id) {
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int k = p_wspawn_args->isXYpow2 ? (wg_id >> p_wspawn_args->log2XY) : (wg_id / XY);
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int wg_2d = wg_id - k * XY;
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int j = p_wspawn_args->isXpow2 ? (wg_2d >> p_wspawn_args->log2X) : (wg_2d / X);
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int i = wg_2d - j * X;
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int gid0 = p_wspawn_args->ctx->global_offset[0] + i;
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int gid1 = p_wspawn_args->ctx->global_offset[1] + j;
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int gid2 = p_wspawn_args->ctx->global_offset[2] + k;
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(p_wspawn_args->callback)(p_wspawn_args->arg, p_wspawn_args->ctx, gid0, gid1, gid2);
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}
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vx_tmc(0 == wid);
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}
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static void spawn_kernel_remaining_callback(int nthreads) {
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vx_tmc(nthreads);
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int core_id = vx_core_id();
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int tid = vx_thread_gid();
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wspawn_kernel_args_t* p_wspawn_args = (wspawn_kernel_args_t*)g_wspawn_args[core_id];
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int wg_id = p_wspawn_args->offset + tid;
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int X = p_wspawn_args->ctx->num_groups[0];
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int Y = p_wspawn_args->ctx->num_groups[1];
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int XY = X * Y;
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int k = p_wspawn_args->isXYpow2 ? (wg_id >> p_wspawn_args->log2XY) : (wg_id / XY);
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int wg_2d = wg_id - k * XY;
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int j = p_wspawn_args->isXpow2 ? (wg_2d >> p_wspawn_args->log2X) : (wg_2d / X);
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int i = wg_2d - j * X;
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int gid0 = p_wspawn_args->ctx->global_offset[0] + i;
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int gid1 = p_wspawn_args->ctx->global_offset[1] + j;
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int gid2 = p_wspawn_args->ctx->global_offset[2] + k;
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(p_wspawn_args->callback)(p_wspawn_args->arg, p_wspawn_args->ctx, gid0, gid1, gid2);
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vx_tmc(1);
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}
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void vx_spawn_kernel(struct context_t * ctx, vx_spawn_kernel_cb callback, void * arg) {
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// total number of WGs
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int X = ctx->num_groups[0];
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int Y = ctx->num_groups[1];
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int Z = ctx->num_groups[2];
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int XY = X * Y;
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int Q = XY * Z;
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// device specs
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int NC = vx_num_cores();
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int NW = vx_num_warps();
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int NT = vx_num_threads();
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// current core id
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int core_id = vx_core_id();
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if (core_id >= NUM_CORES_MAX)
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return;
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// calculate necessary active cores
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int WT = NW * NT;
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int nC = (Q > WT) ? (Q / WT) : 1;
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int nc = MIN(nC, NC);
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if (core_id >= nc)
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return; // terminate extra cores
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// number of workgroups per core
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int wgs_per_core = Q / nc;
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int wgs_per_core0 = wgs_per_core;
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if (core_id == (NC-1)) {
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int QC_r = Q - (nc * wgs_per_core0);
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wgs_per_core0 += QC_r; // last core executes remaining WGs
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}
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// number of workgroups per warp
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int nW = wgs_per_core0 / NT; // total warps per core
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int rT = wgs_per_core0 - (nW * NT); // remaining threads
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int fW = (nW >= NW) ? (nW / NW) : 0; // full warps iterations
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int rW = (fW != 0) ? (nW - fW * NW) : 0; // reamining full warps
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if (0 == fW)
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fW = 1;
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// fast path handling
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char isXYpow2 = is_log2(XY);
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char isXpow2 = is_log2(X);
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char log2XY = fast_log2(XY);
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char log2X = fast_log2(X);
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//--
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wspawn_kernel_args_t wspawn_args = {
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ctx, callback, arg, core_id * wgs_per_core, fW, rW, isXYpow2, isXpow2, log2XY, log2X
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};
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g_wspawn_args[core_id] = &wspawn_args;
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//--
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if (nW >= 1) {
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int nw = MIN(nW, NW);
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vx_wspawn(nw, spawn_kernel_callback);
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spawn_kernel_callback();
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}
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//--
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if (rT != 0) {
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wspawn_args.offset = wgs_per_core0 - rT;
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spawn_kernel_remaining_callback(rT);
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}
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}
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#ifdef __cplusplus
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}
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#endif |