/* * Copyright © 2017 Intel Corporation * * 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. */ /** * @file iris_query.c * * ============================= GENXML CODE ============================= * [This file is compiled once per generation.] * ======================================================================= * * Query object support. This allows measuring various simple statistics * via counters on the GPU. We use GenX code for MI_MATH calculations. */ #include #include #include "perf/gen_perf.h" #include "pipe/p_defines.h" #include "pipe/p_state.h" #include "pipe/p_context.h" #include "pipe/p_screen.h" #include "util/u_inlines.h" #include "util/u_upload_mgr.h" #include "iris_context.h" #include "iris_defines.h" #include "iris_fence.h" #include "iris_monitor.h" #include "iris_resource.h" #include "iris_screen.h" #include "iris_genx_macros.h" #define SO_PRIM_STORAGE_NEEDED(n) (GENX(SO_PRIM_STORAGE_NEEDED0_num) + (n) * 8) #define SO_NUM_PRIMS_WRITTEN(n) (GENX(SO_NUM_PRIMS_WRITTEN0_num) + (n) * 8) struct iris_query { enum pipe_query_type type; int index; bool ready; bool stalled; uint64_t result; struct iris_state_ref query_state_ref; struct iris_query_snapshots *map; struct iris_syncpt *syncpt; int batch_idx; struct iris_monitor_object *monitor; }; struct iris_query_snapshots { /** iris_render_condition's saved MI_PREDICATE_RESULT value. */ uint64_t predicate_result; /** Have the start/end snapshots landed? */ uint64_t snapshots_landed; /** Starting and ending counter snapshots */ uint64_t start; uint64_t end; }; struct iris_query_so_overflow { uint64_t predicate_result; uint64_t snapshots_landed; struct { uint64_t prim_storage_needed[2]; uint64_t num_prims[2]; } stream[4]; }; static struct gen_mi_value query_mem64(struct iris_query *q, uint32_t offset) { struct iris_address addr = { .bo = iris_resource_bo(q->query_state_ref.res), .offset = q->query_state_ref.offset + offset, .write = true }; return gen_mi_mem64(addr); } /** * Is this type of query written by PIPE_CONTROL? */ static bool iris_is_query_pipelined(struct iris_query *q) { switch (q->type) { case PIPE_QUERY_OCCLUSION_COUNTER: case PIPE_QUERY_OCCLUSION_PREDICATE: case PIPE_QUERY_OCCLUSION_PREDICATE_CONSERVATIVE: case PIPE_QUERY_TIMESTAMP: case PIPE_QUERY_TIMESTAMP_DISJOINT: case PIPE_QUERY_TIME_ELAPSED: return true; default: return false; } } static void mark_available(struct iris_context *ice, struct iris_query *q) { struct iris_batch *batch = &ice->batches[q->batch_idx]; unsigned flags = PIPE_CONTROL_WRITE_IMMEDIATE; unsigned offset = offsetof(struct iris_query_snapshots, snapshots_landed); struct iris_bo *bo = iris_resource_bo(q->query_state_ref.res); offset += q->query_state_ref.offset; if (!iris_is_query_pipelined(q)) { ice->vtbl.store_data_imm64(batch, bo, offset, true); } else { /* Order available *after* the query results. */ flags |= PIPE_CONTROL_FLUSH_ENABLE; iris_emit_pipe_control_write(batch, "query: mark available", flags, bo, offset, true); } } /** * Write PS_DEPTH_COUNT to q->(dest) via a PIPE_CONTROL. */ static void iris_pipelined_write(struct iris_batch *batch, struct iris_query *q, enum pipe_control_flags flags, unsigned offset) { const struct gen_device_info *devinfo = &batch->screen->devinfo; const unsigned optional_cs_stall = GEN_GEN == 9 && devinfo->gt == 4 ? PIPE_CONTROL_CS_STALL : 0; struct iris_bo *bo = iris_resource_bo(q->query_state_ref.res); iris_emit_pipe_control_write(batch, "query: pipelined snapshot write", flags | optional_cs_stall, bo, offset, 0ull); } static void write_value(struct iris_context *ice, struct iris_query *q, unsigned offset) { struct iris_batch *batch = &ice->batches[q->batch_idx]; struct iris_bo *bo = iris_resource_bo(q->query_state_ref.res); if (!iris_is_query_pipelined(q)) { iris_emit_pipe_control_flush(batch, "query: non-pipelined snapshot write", PIPE_CONTROL_CS_STALL | PIPE_CONTROL_STALL_AT_SCOREBOARD); q->stalled = true; } switch (q->type) { case PIPE_QUERY_OCCLUSION_COUNTER: case PIPE_QUERY_OCCLUSION_PREDICATE: case PIPE_QUERY_OCCLUSION_PREDICATE_CONSERVATIVE: if (GEN_GEN >= 10) { /* "Driver must program PIPE_CONTROL with only Depth Stall Enable * bit set prior to programming a PIPE_CONTROL with Write PS Depth * Count sync operation." */ iris_emit_pipe_control_flush(batch, "workaround: depth stall before writing " "PS_DEPTH_COUNT", PIPE_CONTROL_DEPTH_STALL); } iris_pipelined_write(&ice->batches[IRIS_BATCH_RENDER], q, PIPE_CONTROL_WRITE_DEPTH_COUNT | PIPE_CONTROL_DEPTH_STALL, offset); break; case PIPE_QUERY_TIME_ELAPSED: case PIPE_QUERY_TIMESTAMP: case PIPE_QUERY_TIMESTAMP_DISJOINT: iris_pipelined_write(&ice->batches[IRIS_BATCH_RENDER], q, PIPE_CONTROL_WRITE_TIMESTAMP, offset); break; case PIPE_QUERY_PRIMITIVES_GENERATED: ice->vtbl.store_register_mem64(batch, q->index == 0 ? GENX(CL_INVOCATION_COUNT_num) : SO_PRIM_STORAGE_NEEDED(q->index), bo, offset, false); break; case PIPE_QUERY_PRIMITIVES_EMITTED: ice->vtbl.store_register_mem64(batch, SO_NUM_PRIMS_WRITTEN(q->index), bo, offset, false); break; case PIPE_QUERY_PIPELINE_STATISTICS_SINGLE: { static const uint32_t index_to_reg[] = { GENX(IA_VERTICES_COUNT_num), GENX(IA_PRIMITIVES_COUNT_num), GENX(VS_INVOCATION_COUNT_num), GENX(GS_INVOCATION_COUNT_num), GENX(GS_PRIMITIVES_COUNT_num), GENX(CL_INVOCATION_COUNT_num), GENX(CL_PRIMITIVES_COUNT_num), GENX(PS_INVOCATION_COUNT_num), GENX(HS_INVOCATION_COUNT_num), GENX(DS_INVOCATION_COUNT_num), GENX(CS_INVOCATION_COUNT_num), }; const uint32_t reg = index_to_reg[q->index]; ice->vtbl.store_register_mem64(batch, reg, bo, offset, false); break; } default: assert(false); } } static void write_overflow_values(struct iris_context *ice, struct iris_query *q, bool end) { struct iris_batch *batch = &ice->batches[IRIS_BATCH_RENDER]; uint32_t count = q->type == PIPE_QUERY_SO_OVERFLOW_PREDICATE ? 1 : 4; struct iris_bo *bo = iris_resource_bo(q->query_state_ref.res); uint32_t offset = q->query_state_ref.offset; iris_emit_pipe_control_flush(batch, "query: write SO overflow snapshots", PIPE_CONTROL_CS_STALL | PIPE_CONTROL_STALL_AT_SCOREBOARD); for (uint32_t i = 0; i < count; i++) { int s = q->index + i; int g_idx = offset + offsetof(struct iris_query_so_overflow, stream[s].num_prims[end]); int w_idx = offset + offsetof(struct iris_query_so_overflow, stream[s].prim_storage_needed[end]); ice->vtbl.store_register_mem64(batch, SO_NUM_PRIMS_WRITTEN(s), bo, g_idx, false); ice->vtbl.store_register_mem64(batch, SO_PRIM_STORAGE_NEEDED(s), bo, w_idx, false); } } static uint64_t iris_raw_timestamp_delta(uint64_t time0, uint64_t time1) { if (time0 > time1) { return (1ULL << TIMESTAMP_BITS) + time1 - time0; } else { return time1 - time0; } } static bool stream_overflowed(struct iris_query_so_overflow *so, int s) { return (so->stream[s].prim_storage_needed[1] - so->stream[s].prim_storage_needed[0]) != (so->stream[s].num_prims[1] - so->stream[s].num_prims[0]); } static void calculate_result_on_cpu(const struct gen_device_info *devinfo, struct iris_query *q) { switch (q->type) { case PIPE_QUERY_OCCLUSION_PREDICATE: case PIPE_QUERY_OCCLUSION_PREDICATE_CONSERVATIVE: q->result = q->map->end != q->map->start; break; case PIPE_QUERY_TIMESTAMP: case PIPE_QUERY_TIMESTAMP_DISJOINT: /* The timestamp is the single starting snapshot. */ q->result = gen_device_info_timebase_scale(devinfo, q->map->start); q->result &= (1ull << TIMESTAMP_BITS) - 1; break; case PIPE_QUERY_TIME_ELAPSED: q->result = iris_raw_timestamp_delta(q->map->start, q->map->end); q->result = gen_device_info_timebase_scale(devinfo, q->result); q->result &= (1ull << TIMESTAMP_BITS) - 1; break; case PIPE_QUERY_SO_OVERFLOW_PREDICATE: q->result = stream_overflowed((void *) q->map, q->index); break; case PIPE_QUERY_SO_OVERFLOW_ANY_PREDICATE: q->result = false; for (int i = 0; i < MAX_VERTEX_STREAMS; i++) q->result |= stream_overflowed((void *) q->map, i); break; case PIPE_QUERY_PIPELINE_STATISTICS_SINGLE: q->result = q->map->end - q->map->start; /* WaDividePSInvocationCountBy4:HSW,BDW */ if (GEN_GEN == 8 && q->index == PIPE_STAT_QUERY_PS_INVOCATIONS) q->result /= 4; break; case PIPE_QUERY_OCCLUSION_COUNTER: case PIPE_QUERY_PRIMITIVES_GENERATED: case PIPE_QUERY_PRIMITIVES_EMITTED: default: q->result = q->map->end - q->map->start; break; } q->ready = true; } /** * Calculate the streamout overflow for stream \p idx: * * (num_prims[1] - num_prims[0]) - (storage_needed[1] - storage_needed[0]) */ static struct gen_mi_value calc_overflow_for_stream(struct gen_mi_builder *b, struct iris_query *q, int idx) { #define C(counter, i) query_mem64(q, \ offsetof(struct iris_query_so_overflow, stream[idx].counter[i])) return gen_mi_isub(b, gen_mi_isub(b, C(num_prims, 1), C(num_prims, 0)), gen_mi_isub(b, C(prim_storage_needed, 1), C(prim_storage_needed, 0))); #undef C } /** * Calculate whether any stream has overflowed. */ static struct gen_mi_value calc_overflow_any_stream(struct gen_mi_builder *b, struct iris_query *q) { struct gen_mi_value stream_result[MAX_VERTEX_STREAMS]; for (int i = 0; i < MAX_VERTEX_STREAMS; i++) stream_result[i] = calc_overflow_for_stream(b, q, i); struct gen_mi_value result = stream_result[0]; for (int i = 1; i < MAX_VERTEX_STREAMS; i++) result = gen_mi_ior(b, result, stream_result[i]); return result; } static bool query_is_boolean(enum pipe_query_type type) { switch (type) { case PIPE_QUERY_OCCLUSION_PREDICATE: case PIPE_QUERY_OCCLUSION_PREDICATE_CONSERVATIVE: case PIPE_QUERY_SO_OVERFLOW_PREDICATE: case PIPE_QUERY_SO_OVERFLOW_ANY_PREDICATE: return true; default: return false; } } /** * Calculate the result using MI_MATH. */ static struct gen_mi_value calculate_result_on_gpu(const struct gen_device_info *devinfo, struct gen_mi_builder *b, struct iris_query *q) { struct gen_mi_value result; struct gen_mi_value start_val = query_mem64(q, offsetof(struct iris_query_snapshots, start)); struct gen_mi_value end_val = query_mem64(q, offsetof(struct iris_query_snapshots, end)); switch (q->type) { case PIPE_QUERY_SO_OVERFLOW_PREDICATE: result = calc_overflow_for_stream(b, q, q->index); break; case PIPE_QUERY_SO_OVERFLOW_ANY_PREDICATE: result = calc_overflow_any_stream(b, q); break; case PIPE_QUERY_TIMESTAMP: { /* TODO: This discards any fractional bits of the timebase scale. * We would need to do a bit of fixed point math on the CS ALU, or * launch an actual shader to calculate this with full precision. */ uint32_t scale = 1000000000ull / devinfo->timestamp_frequency; result = gen_mi_iand(b, gen_mi_imm((1ull << 36) - 1), gen_mi_imul_imm(b, start_val, scale)); break; } case PIPE_QUERY_TIME_ELAPSED: { /* TODO: This discards fractional bits (see above). */ uint32_t scale = 1000000000ull / devinfo->timestamp_frequency; result = gen_mi_imul_imm(b, gen_mi_isub(b, end_val, start_val), scale); break; } default: result = gen_mi_isub(b, end_val, start_val); break; } /* WaDividePSInvocationCountBy4:HSW,BDW */ if (GEN_GEN == 8 && q->type == PIPE_QUERY_PIPELINE_STATISTICS_SINGLE && q->index == PIPE_STAT_QUERY_PS_INVOCATIONS) result = gen_mi_ushr32_imm(b, result, 2); if (query_is_boolean(q->type)) result = gen_mi_iand(b, gen_mi_nz(b, result), gen_mi_imm(1)); return result; } static struct pipe_query * iris_create_query(struct pipe_context *ctx, unsigned query_type, unsigned index) { struct iris_query *q = calloc(1, sizeof(struct iris_query)); q->type = query_type; q->index = index; q->monitor = NULL; if (q->type == PIPE_QUERY_PIPELINE_STATISTICS_SINGLE && q->index == PIPE_STAT_QUERY_CS_INVOCATIONS) q->batch_idx = IRIS_BATCH_COMPUTE; else q->batch_idx = IRIS_BATCH_RENDER; return (struct pipe_query *) q; } static struct pipe_query * iris_create_batch_query(struct pipe_context *ctx, unsigned num_queries, unsigned *query_types) { struct iris_context *ice = (void *) ctx; struct iris_query *q = calloc(1, sizeof(struct iris_query)); if (unlikely(!q)) return NULL; q->type = PIPE_QUERY_DRIVER_SPECIFIC; q->index = -1; q->monitor = iris_create_monitor_object(ice, num_queries, query_types); if (unlikely(!q->monitor)) { free(q); return NULL; } return (struct pipe_query *) q; } static void iris_destroy_query(struct pipe_context *ctx, struct pipe_query *p_query) { struct iris_query *query = (void *) p_query; struct iris_screen *screen = (void *) ctx->screen; if (query->monitor) { iris_destroy_monitor_object(ctx, query->monitor); query->monitor = NULL; } else { iris_syncpt_reference(screen, &query->syncpt, NULL); } free(query); } static bool iris_begin_query(struct pipe_context *ctx, struct pipe_query *query) { struct iris_context *ice = (void *) ctx; struct iris_query *q = (void *) query; if (q->monitor) return iris_begin_monitor(ctx, q->monitor); void *ptr = NULL; uint32_t size; if (q->type == PIPE_QUERY_SO_OVERFLOW_PREDICATE || q->type == PIPE_QUERY_SO_OVERFLOW_ANY_PREDICATE) size = sizeof(struct iris_query_so_overflow); else size = sizeof(struct iris_query_snapshots); u_upload_alloc(ice->query_buffer_uploader, 0, size, size, &q->query_state_ref.offset, &q->query_state_ref.res, &ptr); if (!iris_resource_bo(q->query_state_ref.res)) return false; q->map = ptr; if (!q->map) return false; q->result = 0ull; q->ready = false; WRITE_ONCE(q->map->snapshots_landed, false); if (q->type == PIPE_QUERY_PRIMITIVES_GENERATED && q->index == 0) { ice->state.prims_generated_query_active = true; ice->state.dirty |= IRIS_DIRTY_STREAMOUT | IRIS_DIRTY_CLIP; } if (q->type == PIPE_QUERY_SO_OVERFLOW_PREDICATE || q->type == PIPE_QUERY_SO_OVERFLOW_ANY_PREDICATE) write_overflow_values(ice, q, false); else write_value(ice, q, q->query_state_ref.offset + offsetof(struct iris_query_snapshots, start)); return true; } static bool iris_end_query(struct pipe_context *ctx, struct pipe_query *query) { struct iris_context *ice = (void *) ctx; struct iris_query *q = (void *) query; if (q->monitor) return iris_end_monitor(ctx, q->monitor); struct iris_batch *batch = &ice->batches[q->batch_idx]; if (q->type == PIPE_QUERY_TIMESTAMP) { iris_begin_query(ctx, query); iris_batch_reference_signal_syncpt(batch, &q->syncpt); mark_available(ice, q); return true; } if (q->type == PIPE_QUERY_PRIMITIVES_GENERATED && q->index == 0) { ice->state.prims_generated_query_active = false; ice->state.dirty |= IRIS_DIRTY_STREAMOUT | IRIS_DIRTY_CLIP; } if (q->type == PIPE_QUERY_SO_OVERFLOW_PREDICATE || q->type == PIPE_QUERY_SO_OVERFLOW_ANY_PREDICATE) write_overflow_values(ice, q, true); else write_value(ice, q, q->query_state_ref.offset + offsetof(struct iris_query_snapshots, end)); iris_batch_reference_signal_syncpt(batch, &q->syncpt); mark_available(ice, q); return true; } /** * See if the snapshots have landed for a query, and if so, compute the * result and mark it ready. Does not flush (unlike iris_get_query_result). */ static void iris_check_query_no_flush(struct iris_context *ice, struct iris_query *q) { struct iris_screen *screen = (void *) ice->ctx.screen; const struct gen_device_info *devinfo = &screen->devinfo; if (!q->ready && READ_ONCE(q->map->snapshots_landed)) { calculate_result_on_cpu(devinfo, q); } } static bool iris_get_query_result(struct pipe_context *ctx, struct pipe_query *query, bool wait, union pipe_query_result *result) { struct iris_context *ice = (void *) ctx; struct iris_query *q = (void *) query; if (q->monitor) return iris_get_monitor_result(ctx, q->monitor, wait, result->batch); struct iris_screen *screen = (void *) ctx->screen; const struct gen_device_info *devinfo = &screen->devinfo; if (unlikely(screen->no_hw)) { result->u64 = 0; return true; } if (!q->ready) { struct iris_batch *batch = &ice->batches[q->batch_idx]; if (q->syncpt == iris_batch_get_signal_syncpt(batch)) iris_batch_flush(batch); while (!READ_ONCE(q->map->snapshots_landed)) { if (wait) iris_wait_syncpt(ctx->screen, q->syncpt, INT64_MAX); else return false; } assert(READ_ONCE(q->map->snapshots_landed)); calculate_result_on_cpu(devinfo, q); } assert(q->ready); result->u64 = q->result; return true; } static void iris_get_query_result_resource(struct pipe_context *ctx, struct pipe_query *query, bool wait, enum pipe_query_value_type result_type, int index, struct pipe_resource *p_res, unsigned offset) { struct iris_context *ice = (void *) ctx; struct iris_query *q = (void *) query; struct iris_batch *batch = &ice->batches[q->batch_idx]; const struct gen_device_info *devinfo = &batch->screen->devinfo; struct iris_resource *res = (void *) p_res; struct iris_bo *query_bo = iris_resource_bo(q->query_state_ref.res); struct iris_bo *dst_bo = iris_resource_bo(p_res); unsigned snapshots_landed_offset = offsetof(struct iris_query_snapshots, snapshots_landed); res->bind_history |= PIPE_BIND_QUERY_BUFFER; if (index == -1) { /* They're asking for the availability of the result. If we still * have commands queued up which produce the result, submit them * now so that progress happens. Either way, copy the snapshots * landed field to the destination resource. */ if (q->syncpt == iris_batch_get_signal_syncpt(batch)) iris_batch_flush(batch); ice->vtbl.copy_mem_mem(batch, dst_bo, offset, query_bo, snapshots_landed_offset, result_type <= PIPE_QUERY_TYPE_U32 ? 4 : 8); return; } if (!q->ready && READ_ONCE(q->map->snapshots_landed)) { /* The final snapshots happen to have landed, so let's just compute * the result on the CPU now... */ calculate_result_on_cpu(devinfo, q); } if (q->ready) { /* We happen to have the result on the CPU, so just copy it. */ if (result_type <= PIPE_QUERY_TYPE_U32) { ice->vtbl.store_data_imm32(batch, dst_bo, offset, q->result); } else { ice->vtbl.store_data_imm64(batch, dst_bo, offset, q->result); } /* Make sure the result lands before they use bind the QBO elsewhere * and use the result. */ // XXX: Why? i965 doesn't do this. iris_emit_pipe_control_flush(batch, "query: unknown QBO flushing hack", PIPE_CONTROL_CS_STALL); return; } bool predicated = !wait && !q->stalled; struct gen_mi_builder b; gen_mi_builder_init(&b, batch); struct gen_mi_value result = calculate_result_on_gpu(devinfo, &b, q); struct gen_mi_value dst = result_type <= PIPE_QUERY_TYPE_U32 ? gen_mi_mem32(rw_bo(dst_bo, offset)) : gen_mi_mem64(rw_bo(dst_bo, offset)); if (predicated) { gen_mi_store(&b, gen_mi_reg32(MI_PREDICATE_RESULT), gen_mi_mem64(ro_bo(query_bo, snapshots_landed_offset))); gen_mi_store_if(&b, dst, result); } else { gen_mi_store(&b, dst, result); } } static void iris_set_active_query_state(struct pipe_context *ctx, bool enable) { struct iris_context *ice = (void *) ctx; if (ice->state.statistics_counters_enabled == enable) return; // XXX: most packets aren't paying attention to this yet, because it'd // have to be done dynamically at draw time, which is a pain ice->state.statistics_counters_enabled = enable; ice->state.dirty |= IRIS_DIRTY_CLIP | IRIS_DIRTY_GS | IRIS_DIRTY_RASTER | IRIS_DIRTY_STREAMOUT | IRIS_DIRTY_TCS | IRIS_DIRTY_TES | IRIS_DIRTY_VS | IRIS_DIRTY_WM; } static void set_predicate_enable(struct iris_context *ice, bool value) { if (value) ice->state.predicate = IRIS_PREDICATE_STATE_RENDER; else ice->state.predicate = IRIS_PREDICATE_STATE_DONT_RENDER; } static void set_predicate_for_result(struct iris_context *ice, struct iris_query *q, bool inverted) { struct iris_batch *batch = &ice->batches[IRIS_BATCH_RENDER]; struct iris_bo *bo = iris_resource_bo(q->query_state_ref.res); /* The CPU doesn't have the query result yet; use hardware predication */ ice->state.predicate = IRIS_PREDICATE_STATE_USE_BIT; /* Ensure the memory is coherent for MI_LOAD_REGISTER_* commands. */ iris_emit_pipe_control_flush(batch, "conditional rendering: set predicate", PIPE_CONTROL_FLUSH_ENABLE); q->stalled = true; struct gen_mi_builder b; gen_mi_builder_init(&b, batch); struct gen_mi_value result; switch (q->type) { case PIPE_QUERY_SO_OVERFLOW_PREDICATE: result = calc_overflow_for_stream(&b, q, q->index); break; case PIPE_QUERY_SO_OVERFLOW_ANY_PREDICATE: result = calc_overflow_any_stream(&b, q); break; default: { /* PIPE_QUERY_OCCLUSION_* */ struct gen_mi_value start = query_mem64(q, offsetof(struct iris_query_snapshots, start)); struct gen_mi_value end = query_mem64(q, offsetof(struct iris_query_snapshots, end)); result = gen_mi_isub(&b, end, start); break; } } result = inverted ? gen_mi_z(&b, result) : gen_mi_nz(&b, result); result = gen_mi_iand(&b, result, gen_mi_imm(1)); /* We immediately set the predicate on the render batch, as all the * counters come from 3D operations. However, we may need to predicate * a compute dispatch, which executes in a different GEM context and has * a different MI_PREDICATE_RESULT register. So, we save the result to * memory and reload it in iris_launch_grid. */ gen_mi_value_ref(&b, result); gen_mi_store(&b, gen_mi_reg32(MI_PREDICATE_RESULT), result); gen_mi_store(&b, query_mem64(q, offsetof(struct iris_query_snapshots, predicate_result)), result); ice->state.compute_predicate = bo; } static void iris_render_condition(struct pipe_context *ctx, struct pipe_query *query, bool condition, enum pipe_render_cond_flag mode) { struct iris_context *ice = (void *) ctx; struct iris_query *q = (void *) query; /* The old condition isn't relevant; we'll update it if necessary */ ice->state.compute_predicate = NULL; ice->condition.query = q; ice->condition.condition = condition; if (!q) { ice->state.predicate = IRIS_PREDICATE_STATE_RENDER; return; } iris_check_query_no_flush(ice, q); if (q->result || q->ready) { set_predicate_enable(ice, (q->result != 0) ^ condition); } else { if (mode == PIPE_RENDER_COND_NO_WAIT || mode == PIPE_RENDER_COND_BY_REGION_NO_WAIT) { perf_debug(&ice->dbg, "Conditional rendering demoted from " "\"no wait\" to \"wait\"."); } set_predicate_for_result(ice, q, condition); } } static void iris_resolve_conditional_render(struct iris_context *ice) { struct pipe_context *ctx = (void *) ice; struct iris_query *q = ice->condition.query; struct pipe_query *query = (void *) q; union pipe_query_result result; if (ice->state.predicate != IRIS_PREDICATE_STATE_USE_BIT) return; assert(q); iris_get_query_result(ctx, query, true, &result); set_predicate_enable(ice, (q->result != 0) ^ ice->condition.condition); } void genX(init_query)(struct iris_context *ice) { struct pipe_context *ctx = &ice->ctx; ctx->create_query = iris_create_query; ctx->create_batch_query = iris_create_batch_query; ctx->destroy_query = iris_destroy_query; ctx->begin_query = iris_begin_query; ctx->end_query = iris_end_query; ctx->get_query_result = iris_get_query_result; ctx->get_query_result_resource = iris_get_query_result_resource; ctx->set_active_query_state = iris_set_active_query_state; ctx->render_condition = iris_render_condition; ice->vtbl.resolve_conditional_render = iris_resolve_conditional_render; }