/* * Copyright 2015 Samuel Pitoiset * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. */ #include "nvc0/nvc0_context.h" #include "nvc0/nvc0_query_hw_metric.h" #include "nvc0/nvc0_query_hw_sm.h" #define _Q(i,n,t,d) { NVC0_HW_METRIC_QUERY_##i, n, PIPE_DRIVER_QUERY_TYPE_##t, d } static const struct nvc0_hw_metric_cfg { unsigned id; const char *name; enum pipe_driver_query_type type; const char *desc; } nvc0_hw_metric_queries[] = { _Q(ACHIEVED_OCCUPANCY, "metric-achieved_occupancy", PERCENTAGE, "Ratio of the average active warps per active cycle to the maximum " "number of warps supported on a multiprocessor"), _Q(BRANCH_EFFICIENCY, "metric-branch_efficiency", PERCENTAGE, "Ratio of non-divergent branches to total branches"), _Q(INST_ISSUED, "metric-inst_issued", UINT64, "The number of instructions issued"), _Q(INST_PER_WRAP, "metric-inst_per_wrap", UINT64, "Average number of instructions executed by each warp"), _Q(INST_REPLAY_OVERHEAD, "metric-inst_replay_overhead", UINT64, "Average number of replays for each instruction executed"), _Q(ISSUED_IPC, "metric-issued_ipc", UINT64, "Instructions issued per cycle"), _Q(ISSUE_SLOTS, "metric-issue_slots", UINT64, "The number of issue slots used"), _Q(ISSUE_SLOT_UTILIZATION, "metric-issue_slot_utilization", PERCENTAGE, "Percentage of issue slots that issued at least one instruction, " "averaged across all cycles"), _Q(IPC, "metric-ipc", UINT64, "Instructions executed per cycle"), _Q(SHARED_REPLAY_OVERHEAD, "metric-shared_replay_overhead", UINT64, "Average number of replays due to shared memory conflicts for each " "instruction executed"), _Q(WARP_EXECUTION_EFFICIENCY, "metric-warp_execution_efficiency", PERCENTAGE, "Ratio of the average active threads per warp to the maximum number of " "threads per warp supported on a multiprocessor"), _Q(WARP_NONPRED_EXECUTION_EFFICIENCY, "metric-warp_nonpred_execution_efficiency", PERCENTAGE, "Ratio of the average active threads per warp executing non-predicated " "instructions to the maximum number of threads per warp supported on a " "multiprocessor"), }; #undef _Q static inline const struct nvc0_hw_metric_cfg * nvc0_hw_metric_get_cfg(unsigned metric_id) { unsigned i; for (i = 0; i < ARRAY_SIZE(nvc0_hw_metric_queries); i++) { if (nvc0_hw_metric_queries[i].id == metric_id) return &nvc0_hw_metric_queries[i]; } assert(0); return NULL; } struct nvc0_hw_metric_query_cfg { unsigned type; uint32_t queries[8]; uint32_t num_queries; }; #define _SM(n) NVC0_HW_SM_QUERY(NVC0_HW_SM_QUERY_ ##n) /* ==== Compute capability 2.0 (GF100/GF110) ==== */ static const struct nvc0_hw_metric_query_cfg sm20_achieved_occupancy = { .type = NVC0_HW_METRIC_QUERY_ACHIEVED_OCCUPANCY, .queries[0] = _SM(ACTIVE_WARPS), .queries[1] = _SM(ACTIVE_CYCLES), .num_queries = 2, }; static const struct nvc0_hw_metric_query_cfg sm20_branch_efficiency = { .type = NVC0_HW_METRIC_QUERY_BRANCH_EFFICIENCY, .queries[0] = _SM(BRANCH), .queries[1] = _SM(DIVERGENT_BRANCH), .num_queries = 2, }; static const struct nvc0_hw_metric_query_cfg sm20_inst_per_wrap = { .type = NVC0_HW_METRIC_QUERY_INST_PER_WRAP, .queries[0] = _SM(INST_EXECUTED), .queries[1] = _SM(WARPS_LAUNCHED), .num_queries = 2, }; static const struct nvc0_hw_metric_query_cfg sm20_inst_replay_overhead = { .type = NVC0_HW_METRIC_QUERY_INST_REPLAY_OVERHEAD, .queries[0] = _SM(INST_ISSUED), .queries[1] = _SM(INST_EXECUTED), .num_queries = 2, }; static const struct nvc0_hw_metric_query_cfg sm20_issued_ipc = { .type = NVC0_HW_METRIC_QUERY_ISSUED_IPC, .queries[0] = _SM(INST_ISSUED), .queries[1] = _SM(ACTIVE_CYCLES), .num_queries = 2, }; static const struct nvc0_hw_metric_query_cfg sm20_issue_slot_utilization = { .type = NVC0_HW_METRIC_QUERY_ISSUE_SLOT_UTILIZATION, .queries[0] = _SM(INST_ISSUED), .queries[1] = _SM(ACTIVE_CYCLES), .num_queries = 2, }; static const struct nvc0_hw_metric_query_cfg sm20_ipc = { .type = NVC0_HW_METRIC_QUERY_IPC, .queries[0] = _SM(INST_EXECUTED), .queries[1] = _SM(ACTIVE_CYCLES), .num_queries = 2, }; static const struct nvc0_hw_metric_query_cfg *sm20_hw_metric_queries[] = { &sm20_achieved_occupancy, &sm20_branch_efficiency, &sm20_inst_per_wrap, &sm20_inst_replay_overhead, &sm20_ipc, &sm20_issued_ipc, &sm20_issue_slot_utilization, }; /* ==== Compute capability 2.1 (GF108+ except GF110) ==== */ static const struct nvc0_hw_metric_query_cfg sm21_inst_issued = { .type = NVC0_HW_METRIC_QUERY_INST_ISSUED, .queries[0] = _SM(INST_ISSUED1_0), .queries[1] = _SM(INST_ISSUED1_1), .queries[2] = _SM(INST_ISSUED2_0), .queries[3] = _SM(INST_ISSUED2_1), .num_queries = 4, }; static const struct nvc0_hw_metric_query_cfg sm21_inst_replay_overhead = { .type = NVC0_HW_METRIC_QUERY_INST_REPLAY_OVERHEAD, .queries[0] = _SM(INST_ISSUED1_0), .queries[1] = _SM(INST_ISSUED1_1), .queries[2] = _SM(INST_ISSUED2_0), .queries[3] = _SM(INST_ISSUED2_1), .queries[4] = _SM(INST_EXECUTED), .num_queries = 5, }; static const struct nvc0_hw_metric_query_cfg sm21_issued_ipc = { .type = NVC0_HW_METRIC_QUERY_ISSUED_IPC, .queries[0] = _SM(INST_ISSUED1_0), .queries[1] = _SM(INST_ISSUED1_1), .queries[2] = _SM(INST_ISSUED2_0), .queries[3] = _SM(INST_ISSUED2_1), .queries[4] = _SM(ACTIVE_CYCLES), .num_queries = 5, }; static const struct nvc0_hw_metric_query_cfg sm21_issue_slots = { .type = NVC0_HW_METRIC_QUERY_ISSUE_SLOTS, .queries[0] = _SM(INST_ISSUED1_0), .queries[1] = _SM(INST_ISSUED1_1), .queries[2] = _SM(INST_ISSUED2_0), .queries[3] = _SM(INST_ISSUED2_1), .num_queries = 4, }; static const struct nvc0_hw_metric_query_cfg sm21_issue_slot_utilization = { .type = NVC0_HW_METRIC_QUERY_ISSUE_SLOT_UTILIZATION, .queries[0] = _SM(INST_ISSUED1_0), .queries[1] = _SM(INST_ISSUED1_1), .queries[2] = _SM(INST_ISSUED2_0), .queries[3] = _SM(INST_ISSUED2_1), .queries[4] = _SM(ACTIVE_CYCLES), .num_queries = 5, }; static const struct nvc0_hw_metric_query_cfg *sm21_hw_metric_queries[] = { &sm20_achieved_occupancy, &sm20_branch_efficiency, &sm21_inst_issued, &sm20_inst_per_wrap, &sm21_inst_replay_overhead, &sm20_ipc, &sm21_issued_ipc, &sm21_issue_slots, &sm21_issue_slot_utilization, }; /* ==== Compute capability 3.0 (GK104/GK106/GK107) ==== */ static const struct nvc0_hw_metric_query_cfg sm30_inst_issued = { .type = NVC0_HW_METRIC_QUERY_INST_ISSUED, .queries[0] = _SM(INST_ISSUED1), .queries[1] = _SM(INST_ISSUED2), .num_queries = 2, }; static const struct nvc0_hw_metric_query_cfg sm30_inst_replay_overhead = { .type = NVC0_HW_METRIC_QUERY_INST_REPLAY_OVERHEAD, .queries[0] = _SM(INST_ISSUED1), .queries[1] = _SM(INST_ISSUED2), .queries[2] = _SM(INST_EXECUTED), .num_queries = 3, }; static const struct nvc0_hw_metric_query_cfg sm30_issued_ipc = { .type = NVC0_HW_METRIC_QUERY_ISSUED_IPC, .queries[0] = _SM(INST_ISSUED1), .queries[1] = _SM(INST_ISSUED2), .queries[2] = _SM(ACTIVE_CYCLES), .num_queries = 3, }; static const struct nvc0_hw_metric_query_cfg sm30_issue_slots = { .type = NVC0_HW_METRIC_QUERY_ISSUE_SLOTS, .queries[0] = _SM(INST_ISSUED1), .queries[1] = _SM(INST_ISSUED2), .num_queries = 2, }; static const struct nvc0_hw_metric_query_cfg sm30_issue_slot_utilization = { .type = NVC0_HW_METRIC_QUERY_ISSUE_SLOT_UTILIZATION, .queries[0] = _SM(INST_ISSUED1), .queries[1] = _SM(INST_ISSUED2), .queries[2] = _SM(ACTIVE_CYCLES), .num_queries = 3, }; static const struct nvc0_hw_metric_query_cfg sm30_shared_replay_overhead = { .type = NVC0_HW_METRIC_QUERY_SHARED_REPLAY_OVERHEAD, .queries[0] = _SM(SHARED_LD_REPLAY), .queries[1] = _SM(SHARED_ST_REPLAY), .queries[2] = _SM(INST_EXECUTED), .num_queries = 3, }; static const struct nvc0_hw_metric_query_cfg sm30_warp_execution_efficiency = { .type = NVC0_HW_METRIC_QUERY_WARP_EXECUTION_EFFICIENCY, .queries[0] = _SM(INST_EXECUTED), .queries[1] = _SM(TH_INST_EXECUTED), .num_queries = 2, }; static const struct nvc0_hw_metric_query_cfg *sm30_hw_metric_queries[] = { &sm20_achieved_occupancy, &sm20_branch_efficiency, &sm30_inst_issued, &sm20_inst_per_wrap, &sm30_inst_replay_overhead, &sm20_ipc, &sm30_issued_ipc, &sm30_issue_slots, &sm30_issue_slot_utilization, &sm30_shared_replay_overhead, &sm30_warp_execution_efficiency, }; /* ==== Compute capability 3.5 (GK110/GK208) ==== */ static const struct nvc0_hw_metric_query_cfg sm35_warp_nonpred_execution_efficiency = { .type = NVC0_HW_METRIC_QUERY_WARP_NONPRED_EXECUTION_EFFICIENCY, .queries[0] = _SM(INST_EXECUTED), .queries[1] = _SM(NOT_PRED_OFF_INST_EXECUTED), .num_queries = 2, }; static const struct nvc0_hw_metric_query_cfg *sm35_hw_metric_queries[] = { &sm20_achieved_occupancy, &sm30_inst_issued, &sm20_inst_per_wrap, &sm30_inst_replay_overhead, &sm20_ipc, &sm30_issued_ipc, &sm30_issue_slots, &sm30_issue_slot_utilization, &sm30_shared_replay_overhead, &sm30_warp_execution_efficiency, &sm35_warp_nonpred_execution_efficiency, }; /* ==== Compute capability 5.0 (GM107/GM108) ==== */ static const struct nvc0_hw_metric_query_cfg *sm50_hw_metric_queries[] = { &sm20_achieved_occupancy, &sm20_branch_efficiency, &sm30_inst_issued, &sm20_inst_per_wrap, &sm30_inst_replay_overhead, &sm20_ipc, &sm30_issued_ipc, &sm30_issue_slots, &sm30_issue_slot_utilization, &sm30_warp_execution_efficiency, &sm35_warp_nonpred_execution_efficiency, }; #undef _SM static inline const struct nvc0_hw_metric_query_cfg ** nvc0_hw_metric_get_queries(struct nvc0_screen *screen) { struct nouveau_device *dev = screen->base.device; switch (screen->base.class_3d) { case GM200_3D_CLASS: case GM107_3D_CLASS: return sm50_hw_metric_queries; case NVF0_3D_CLASS: return sm35_hw_metric_queries; case NVE4_3D_CLASS: return sm30_hw_metric_queries; default: if (dev->chipset == 0xc0 || dev->chipset == 0xc8) return sm20_hw_metric_queries; return sm21_hw_metric_queries; } assert(0); return NULL; } unsigned nvc0_hw_metric_get_num_queries(struct nvc0_screen *screen) { struct nouveau_device *dev = screen->base.device; switch (screen->base.class_3d) { case GM200_3D_CLASS: case GM107_3D_CLASS: return ARRAY_SIZE(sm50_hw_metric_queries); case NVF0_3D_CLASS: return ARRAY_SIZE(sm35_hw_metric_queries); case NVE4_3D_CLASS: return ARRAY_SIZE(sm30_hw_metric_queries); default: if (dev->chipset == 0xc0 || dev->chipset == 0xc8) return ARRAY_SIZE(sm20_hw_metric_queries); return ARRAY_SIZE(sm21_hw_metric_queries); } return 0; } static const struct nvc0_hw_metric_query_cfg * nvc0_hw_metric_query_get_cfg(struct nvc0_context *nvc0, struct nvc0_hw_query *hq) { const struct nvc0_hw_metric_query_cfg **queries; struct nvc0_screen *screen = nvc0->screen; struct nvc0_query *q = &hq->base; unsigned num_queries; unsigned i; num_queries = nvc0_hw_metric_get_num_queries(screen); queries = nvc0_hw_metric_get_queries(screen); for (i = 0; i < num_queries; i++) { if (NVC0_HW_METRIC_QUERY(queries[i]->type) == q->type) return queries[i]; } assert(0); return NULL; } static void nvc0_hw_metric_destroy_query(struct nvc0_context *nvc0, struct nvc0_hw_query *hq) { struct nvc0_hw_metric_query *hmq = nvc0_hw_metric_query(hq); unsigned i; for (i = 0; i < hmq->num_queries; i++) if (hmq->queries[i]->funcs->destroy_query) hmq->queries[i]->funcs->destroy_query(nvc0, hmq->queries[i]); FREE(hmq); } static bool nvc0_hw_metric_begin_query(struct nvc0_context *nvc0, struct nvc0_hw_query *hq) { struct nvc0_hw_metric_query *hmq = nvc0_hw_metric_query(hq); bool ret = false; unsigned i; for (i = 0; i < hmq->num_queries; i++) { ret = hmq->queries[i]->funcs->begin_query(nvc0, hmq->queries[i]); if (!ret) return ret; } return ret; } static void nvc0_hw_metric_end_query(struct nvc0_context *nvc0, struct nvc0_hw_query *hq) { struct nvc0_hw_metric_query *hmq = nvc0_hw_metric_query(hq); unsigned i; for (i = 0; i < hmq->num_queries; i++) hmq->queries[i]->funcs->end_query(nvc0, hmq->queries[i]); } static uint64_t sm20_hw_metric_calc_result(struct nvc0_hw_query *hq, uint64_t res64[8]) { switch (hq->base.type - NVC0_HW_METRIC_QUERY(0)) { case NVC0_HW_METRIC_QUERY_ACHIEVED_OCCUPANCY: /* ((active_warps / active_cycles) / max. number of warps on a MP) * 100 */ if (res64[1]) return ((res64[0] / (double)res64[1]) / 48) * 100; break; case NVC0_HW_METRIC_QUERY_BRANCH_EFFICIENCY: /* (branch / (branch + divergent_branch)) * 100 */ if (res64[0] + res64[1]) return (res64[0] / (double)(res64[0] + res64[1])) * 100; break; case NVC0_HW_METRIC_QUERY_INST_PER_WRAP: /* inst_executed / warps_launched */ if (res64[1]) return res64[0] / (double)res64[1]; break; case NVC0_HW_METRIC_QUERY_INST_REPLAY_OVERHEAD: /* (inst_issued - inst_executed) / inst_executed */ if (res64[1]) return (res64[0] - res64[1]) / (double)res64[1]; break; case NVC0_HW_METRIC_QUERY_ISSUED_IPC: /* inst_issued / active_cycles */ if (res64[1]) return res64[0] / (double)res64[1]; break; case NVC0_HW_METRIC_QUERY_ISSUE_SLOT_UTILIZATION: /* ((inst_issued / 2) / active_cycles) * 100 */ if (res64[1]) return ((res64[0] / 2) / (double)res64[1]) * 100; break; case NVC0_HW_METRIC_QUERY_IPC: /* inst_executed / active_cycles */ if (res64[1]) return res64[0] / (double)res64[1]; break; default: debug_printf("invalid metric type: %d\n", hq->base.type - NVC0_HW_METRIC_QUERY(0)); break; } return 0; } static uint64_t sm21_hw_metric_calc_result(struct nvc0_hw_query *hq, uint64_t res64[8]) { switch (hq->base.type - NVC0_HW_METRIC_QUERY(0)) { case NVC0_HW_METRIC_QUERY_ACHIEVED_OCCUPANCY: return sm20_hw_metric_calc_result(hq, res64); case NVC0_HW_METRIC_QUERY_BRANCH_EFFICIENCY: return sm20_hw_metric_calc_result(hq, res64); case NVC0_HW_METRIC_QUERY_INST_ISSUED: /* issued1_0 + issued1_1 + (issued2_0 + issued2_1) * 2 */ return res64[0] + res64[1] + (res64[2] + res64[3]) * 2; break; case NVC0_HW_METRIC_QUERY_INST_PER_WRAP: return sm20_hw_metric_calc_result(hq, res64); case NVC0_HW_METRIC_QUERY_INST_REPLAY_OVERHEAD: /* (metric-inst_issued - inst_executed) / inst_executed */ if (res64[4]) return (((res64[0] + res64[1] + (res64[2] + res64[3]) * 2) - res64[4]) / (double)res64[4]); break; case NVC0_HW_METRIC_QUERY_ISSUED_IPC: /* metric-inst_issued / active_cycles */ if (res64[4]) return (res64[0] + res64[1] + (res64[2] + res64[3]) * 2) / (double)res64[4]; break; case NVC0_HW_METRIC_QUERY_ISSUE_SLOTS: /* issued1_0 + issued1_1 + issued2_0 + issued2_1 */ return res64[0] + res64[1] + res64[2] + res64[3]; break; case NVC0_HW_METRIC_QUERY_ISSUE_SLOT_UTILIZATION: /* ((metric-issue_slots / 2) / active_cycles) * 100 */ if (res64[4]) return (((res64[0] + res64[1] + res64[2] + res64[3]) / 2) / (double)res64[4]) * 100; break; case NVC0_HW_METRIC_QUERY_IPC: return sm20_hw_metric_calc_result(hq, res64); default: debug_printf("invalid metric type: %d\n", hq->base.type - NVC0_HW_METRIC_QUERY(0)); break; } return 0; } static uint64_t sm30_hw_metric_calc_result(struct nvc0_hw_query *hq, uint64_t res64[8]) { switch (hq->base.type - NVC0_HW_METRIC_QUERY(0)) { case NVC0_HW_METRIC_QUERY_ACHIEVED_OCCUPANCY: /* ((active_warps / active_cycles) / max. number of warps on a MP) * 100 */ if (res64[1]) return ((res64[0] / (double)res64[1]) / 64) * 100; break; case NVC0_HW_METRIC_QUERY_BRANCH_EFFICIENCY: return sm20_hw_metric_calc_result(hq, res64); case NVC0_HW_METRIC_QUERY_INST_ISSUED: /* inst_issued1 + inst_issued2 * 2 */ return res64[0] + res64[1] * 2; case NVC0_HW_METRIC_QUERY_INST_PER_WRAP: return sm20_hw_metric_calc_result(hq, res64); case NVC0_HW_METRIC_QUERY_INST_REPLAY_OVERHEAD: /* (metric-inst_issued - inst_executed) / inst_executed */ if (res64[2]) return (((res64[0] + res64[1] * 2) - res64[2]) / (double)res64[2]); break; case NVC0_HW_METRIC_QUERY_ISSUED_IPC: /* metric-inst_issued / active_cycles */ if (res64[2]) return (res64[0] + res64[1] * 2) / (double)res64[2]; break; case NVC0_HW_METRIC_QUERY_ISSUE_SLOTS: /* inst_issued1 + inst_issued2 */ return res64[0] + res64[1]; case NVC0_HW_METRIC_QUERY_ISSUE_SLOT_UTILIZATION: /* ((metric-issue_slots / 2) / active_cycles) * 100 */ if (res64[2]) return (((res64[0] + res64[1]) / 2) / (double)res64[2]) * 100; break; case NVC0_HW_METRIC_QUERY_IPC: return sm20_hw_metric_calc_result(hq, res64); case NVC0_HW_METRIC_QUERY_SHARED_REPLAY_OVERHEAD: /* (shared_load_replay + shared_store_replay) / inst_executed */ if (res64[2]) return (res64[0] + res64[1]) / (double)res64[2]; break; case NVC0_HW_METRIC_QUERY_WARP_EXECUTION_EFFICIENCY: /* thread_inst_executed / (inst_executed * max. number of threads per * wrap) * 100 */ if (res64[0]) return (res64[1] / ((double)res64[0] * 32)) * 100; break; default: debug_printf("invalid metric type: %d\n", hq->base.type - NVC0_HW_METRIC_QUERY(0)); break; } return 0; } static uint64_t sm35_hw_metric_calc_result(struct nvc0_hw_query *hq, uint64_t res64[8]) { switch (hq->base.type - NVC0_HW_METRIC_QUERY(0)) { case NVC0_HW_METRIC_QUERY_WARP_NONPRED_EXECUTION_EFFICIENCY: /* not_predicated_off_thread_inst_executed / (inst_executed * max. number * of threads per wrap) * 100 */ if (res64[0]) return (res64[1] / ((double)res64[0] * 32)) * 100; break; default: return sm30_hw_metric_calc_result(hq, res64); } return 0; } static bool nvc0_hw_metric_get_query_result(struct nvc0_context *nvc0, struct nvc0_hw_query *hq, bool wait, union pipe_query_result *result) { struct nvc0_hw_metric_query *hmq = nvc0_hw_metric_query(hq); struct nvc0_screen *screen = nvc0->screen; struct nouveau_device *dev = screen->base.device; union pipe_query_result results[8] = {}; uint64_t res64[8] = {}; uint64_t value = 0; bool ret = false; unsigned i; for (i = 0; i < hmq->num_queries; i++) { ret = hmq->queries[i]->funcs->get_query_result(nvc0, hmq->queries[i], wait, &results[i]); if (!ret) return ret; res64[i] = *(uint64_t *)&results[i]; } switch (screen->base.class_3d) { case GM200_3D_CLASS: case GM107_3D_CLASS: case NVF0_3D_CLASS: value = sm35_hw_metric_calc_result(hq, res64); break; case NVE4_3D_CLASS: value = sm30_hw_metric_calc_result(hq, res64); break; default: if (dev->chipset == 0xc0 || dev->chipset == 0xc8) value = sm20_hw_metric_calc_result(hq, res64); else value = sm21_hw_metric_calc_result(hq, res64); break; } *(uint64_t *)result = value; return ret; } static const struct nvc0_hw_query_funcs hw_metric_query_funcs = { .destroy_query = nvc0_hw_metric_destroy_query, .begin_query = nvc0_hw_metric_begin_query, .end_query = nvc0_hw_metric_end_query, .get_query_result = nvc0_hw_metric_get_query_result, }; struct nvc0_hw_query * nvc0_hw_metric_create_query(struct nvc0_context *nvc0, unsigned type) { const struct nvc0_hw_metric_query_cfg *cfg; struct nvc0_hw_metric_query *hmq; struct nvc0_hw_query *hq; unsigned i; if (type < NVC0_HW_METRIC_QUERY(0) || type > NVC0_HW_METRIC_QUERY_LAST) return NULL; hmq = CALLOC_STRUCT(nvc0_hw_metric_query); if (!hmq) return NULL; hq = &hmq->base; hq->funcs = &hw_metric_query_funcs; hq->base.type = type; cfg = nvc0_hw_metric_query_get_cfg(nvc0, hq); for (i = 0; i < cfg->num_queries; i++) { hmq->queries[i] = nvc0_hw_sm_create_query(nvc0, cfg->queries[i]); if (!hmq->queries[i]) { nvc0_hw_metric_destroy_query(nvc0, hq); return NULL; } hmq->num_queries++; } return hq; } int nvc0_hw_metric_get_driver_query_info(struct nvc0_screen *screen, unsigned id, struct pipe_driver_query_info *info) { int count = 0; if (screen->base.drm->version >= 0x01000101) { if (screen->compute) count = nvc0_hw_metric_get_num_queries(screen); } if (!info) return count; if (id < count) { if (screen->compute) { if (screen->base.class_3d <= GM200_3D_CLASS) { const struct nvc0_hw_metric_query_cfg **queries = nvc0_hw_metric_get_queries(screen); const struct nvc0_hw_metric_cfg *cfg = nvc0_hw_metric_get_cfg(queries[id]->type); info->name = cfg->name; info->query_type = NVC0_HW_METRIC_QUERY(queries[id]->type); info->type = cfg->type; info->group_id = NVC0_HW_METRIC_QUERY_GROUP; return 1; } } } return 0; }