/* * Copyright © 2021 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 (including the next * paragraph) 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 "anv_private.h" #include "anv_internal_kernels.h" #include "common/intel_debug_identifier.h" #include "ds/intel_tracepoints.h" #include "genxml/gen9_pack.h" #include "perf/intel_perf.h" #include "util/perf/cpu_trace.h" #include "vk_common_entrypoints.h" /** Timestamp structure format */ union anv_utrace_timestamp { /* Timestamp writtem by either 2 * MI_STORE_REGISTER_MEM or * PIPE_CONTROL. */ uint64_t timestamp; /* Timestamp written by COMPUTE_WALKER::PostSync * * Layout is described in PRMs. * ATSM PRMs, Volume 2d: Command Reference: Structures, POSTSYNC_DATA: * * "The timestamp layout : * [0] = 32b Context Timestamp Start * [1] = 32b Global Timestamp Start * [2] = 32b Context Timestamp End * [3] = 32b Global Timestamp End" */ uint32_t gfx125_postsync_data[4]; /* Timestamp written by COMPUTE_WALKER::PostSync * * BSpec 56591: * * "The timestamp layout : * [0] = 64b Context Timestamp Start * [1] = 64b Global Timestamp Start * [2] = 64b Context Timestamp End * [3] = 64b Global Timestamp End" */ uint64_t gfx20_postsync_data[4]; }; static uint32_t command_buffers_count_utraces(struct anv_device *device, uint32_t cmd_buffer_count, struct anv_cmd_buffer **cmd_buffers, uint32_t *utrace_copies) { if (!u_trace_should_process(&device->ds.trace_context)) return 0; uint32_t utraces = 0; for (uint32_t i = 0; i < cmd_buffer_count; i++) { if (u_trace_has_points(&cmd_buffers[i]->trace)) { utraces++; if (!(cmd_buffers[i]->usage_flags & VK_COMMAND_BUFFER_USAGE_ONE_TIME_SUBMIT_BIT)) *utrace_copies += list_length(&cmd_buffers[i]->trace.trace_chunks); } } return utraces; } static void anv_utrace_delete_submit(struct u_trace_context *utctx, void *submit_data) { struct anv_device *device = container_of(utctx, struct anv_device, ds.trace_context); struct anv_utrace_submit *submit = container_of(submit_data, struct anv_utrace_submit, ds); intel_ds_flush_data_fini(&submit->ds); anv_state_stream_finish(&submit->dynamic_state_stream); anv_state_stream_finish(&submit->general_state_stream); anv_async_submit_fini(&submit->base); vk_free(&device->vk.alloc, submit); } void anv_device_utrace_emit_gfx_copy_buffer(struct u_trace_context *utctx, void *cmdstream, void *ts_from, uint64_t from_offset_B, void *ts_to, uint64_t to_offset_B, uint64_t size_B) { struct anv_device *device = container_of(utctx, struct anv_device, ds.trace_context); struct anv_memcpy_state *memcpy_state = cmdstream; struct anv_address from_addr = (struct anv_address) { .bo = ts_from, .offset = from_offset_B }; struct anv_address to_addr = (struct anv_address) { .bo = ts_to, .offset = to_offset_B }; anv_genX(device->info, emit_so_memcpy)(memcpy_state, to_addr, from_addr, size_B); } static void anv_device_utrace_emit_cs_copy_buffer(struct u_trace_context *utctx, void *cmdstream, void *ts_from, uint64_t from_offset_B, void *ts_to, uint64_t to_offset_B, uint64_t size_B) { struct anv_device *device = container_of(utctx, struct anv_device, ds.trace_context); struct anv_simple_shader *simple_state = cmdstream; struct anv_address from_addr = (struct anv_address) { .bo = ts_from, .offset = from_offset_B }; struct anv_address to_addr = (struct anv_address) { .bo = ts_to, .offset = to_offset_B }; struct anv_state push_data_state = anv_genX(device->info, simple_shader_alloc_push)( simple_state, sizeof(struct anv_memcpy_params)); struct anv_memcpy_params *params = push_data_state.map; *params = (struct anv_memcpy_params) { .num_dwords = size_B / 4, .src_addr = anv_address_physical(from_addr), .dst_addr = anv_address_physical(to_addr), }; anv_genX(device->info, emit_simple_shader_dispatch)( simple_state, DIV_ROUND_UP(params->num_dwords, 4), push_data_state); } VkResult anv_device_utrace_flush_cmd_buffers(struct anv_queue *queue, uint32_t cmd_buffer_count, struct anv_cmd_buffer **cmd_buffers, struct anv_utrace_submit **out_submit) { struct anv_device *device = queue->device; uint32_t utrace_copies = 0; uint32_t utraces = command_buffers_count_utraces(device, cmd_buffer_count, cmd_buffers, &utrace_copies); if (!utraces) { *out_submit = NULL; return VK_SUCCESS; } VkResult result; struct anv_utrace_submit *submit = vk_zalloc(&device->vk.alloc, sizeof(struct anv_utrace_submit), 8, VK_SYSTEM_ALLOCATION_SCOPE_DEVICE); if (!submit) return vk_error(device, VK_ERROR_OUT_OF_HOST_MEMORY); result = anv_async_submit_init(&submit->base, queue, &device->batch_bo_pool, false, true); if (result != VK_SUCCESS) goto error_async; intel_ds_flush_data_init(&submit->ds, &queue->ds, queue->ds.submission_id); struct anv_batch *batch = &submit->base.batch; if (utrace_copies > 0) { anv_state_stream_init(&submit->dynamic_state_stream, &device->dynamic_state_pool, 16384); anv_state_stream_init(&submit->general_state_stream, &device->general_state_pool, 16384); /* Only engine class where we support timestamp copies * * TODO: add INTEL_ENGINE_CLASS_COPY support (should be trivial ;) */ assert(queue->family->engine_class == INTEL_ENGINE_CLASS_RENDER || queue->family->engine_class == INTEL_ENGINE_CLASS_COMPUTE); if (queue->family->engine_class == INTEL_ENGINE_CLASS_RENDER) { trace_intel_begin_trace_copy_cb(&submit->ds.trace, batch); anv_genX(device->info, emit_so_memcpy_init)(&submit->memcpy_state, device, NULL, batch); uint32_t num_traces = 0; for (uint32_t i = 0; i < cmd_buffer_count; i++) { if (cmd_buffers[i]->usage_flags & VK_COMMAND_BUFFER_USAGE_ONE_TIME_SUBMIT_BIT) { intel_ds_queue_flush_data(&queue->ds, &cmd_buffers[i]->trace, &submit->ds, device->vk.current_frame, false); } else { num_traces += cmd_buffers[i]->trace.num_traces; u_trace_clone_append(u_trace_begin_iterator(&cmd_buffers[i]->trace), u_trace_end_iterator(&cmd_buffers[i]->trace), &submit->ds.trace, &submit->memcpy_state, anv_device_utrace_emit_gfx_copy_buffer); } } anv_genX(device->info, emit_so_memcpy_fini)(&submit->memcpy_state); trace_intel_end_trace_copy_cb(&submit->ds.trace, batch, num_traces); anv_genX(device->info, emit_so_memcpy_end)(&submit->memcpy_state); } else { struct anv_shader_bin *copy_kernel; VkResult ret = anv_device_get_internal_shader(device, ANV_INTERNAL_KERNEL_MEMCPY_COMPUTE, ©_kernel); if (ret != VK_SUCCESS) goto error_sync; trace_intel_begin_trace_copy_cb(&submit->ds.trace, batch); submit->simple_state = (struct anv_simple_shader) { .device = device, .dynamic_state_stream = &submit->dynamic_state_stream, .general_state_stream = &submit->general_state_stream, .batch = batch, .kernel = copy_kernel, .l3_config = device->internal_kernels_l3_config, }; anv_genX(device->info, emit_simple_shader_init)(&submit->simple_state); uint32_t num_traces = 0; for (uint32_t i = 0; i < cmd_buffer_count; i++) { num_traces += cmd_buffers[i]->trace.num_traces; if (cmd_buffers[i]->usage_flags & VK_COMMAND_BUFFER_USAGE_ONE_TIME_SUBMIT_BIT) { intel_ds_queue_flush_data(&queue->ds, &cmd_buffers[i]->trace, &submit->ds, device->vk.current_frame, false); } else { num_traces += cmd_buffers[i]->trace.num_traces; u_trace_clone_append(u_trace_begin_iterator(&cmd_buffers[i]->trace), u_trace_end_iterator(&cmd_buffers[i]->trace), &submit->ds.trace, &submit->simple_state, anv_device_utrace_emit_cs_copy_buffer); } } trace_intel_end_trace_copy_cb(&submit->ds.trace, batch, num_traces); anv_genX(device->info, emit_simple_shader_end)(&submit->simple_state); } if (batch->status != VK_SUCCESS) { result = batch->status; goto error_sync; } intel_ds_queue_flush_data(&queue->ds, &submit->ds.trace, &submit->ds, device->vk.current_frame, true); } else { for (uint32_t i = 0; i < cmd_buffer_count; i++) { assert(cmd_buffers[i]->usage_flags & VK_COMMAND_BUFFER_USAGE_ONE_TIME_SUBMIT_BIT); intel_ds_queue_flush_data(&queue->ds, &cmd_buffers[i]->trace, &submit->ds, device->vk.current_frame, i == (cmd_buffer_count - 1)); } } *out_submit = submit; return VK_SUCCESS; error_sync: intel_ds_flush_data_fini(&submit->ds); anv_async_submit_fini(&submit->base); error_async: vk_free(&device->vk.alloc, submit); return result; } static void * anv_utrace_create_buffer(struct u_trace_context *utctx, uint64_t size_B) { struct anv_device *device = container_of(utctx, struct anv_device, ds.trace_context); struct anv_bo *bo = NULL; UNUSED VkResult result = anv_bo_pool_alloc(&device->utrace_bo_pool, align(size_B, 4096), &bo); assert(result == VK_SUCCESS); memset(bo->map, 0, bo->size); #ifdef SUPPORT_INTEL_INTEGRATED_GPUS if (device->physical->memory.need_flush && anv_bo_needs_host_cache_flush(bo->alloc_flags)) intel_flush_range(bo->map, bo->size); #endif return bo; } static void anv_utrace_destroy_buffer(struct u_trace_context *utctx, void *timestamps) { struct anv_device *device = container_of(utctx, struct anv_device, ds.trace_context); struct anv_bo *bo = timestamps; anv_bo_pool_free(&device->utrace_bo_pool, bo); } static void anv_utrace_record_ts(struct u_trace *ut, void *cs, void *timestamps, uint64_t offset_B, uint32_t flags) { struct anv_device *device = container_of(ut->utctx, struct anv_device, ds.trace_context); struct anv_cmd_buffer *cmd_buffer = container_of(ut, struct anv_cmd_buffer, trace); /* cmd_buffer is only valid if cs == NULL */ struct anv_batch *batch = cs != NULL ? cs : &cmd_buffer->batch; struct anv_bo *bo = timestamps; assert(offset_B % sizeof(union anv_utrace_timestamp) == 0); struct anv_address ts_address = (struct anv_address) { .bo = bo, .offset = offset_B, }; /* Is this a end of compute trace point? */ const bool is_end_compute = cs == NULL && (flags & INTEL_DS_TRACEPOINT_FLAG_END_OF_PIPE_CS); assert(device->info->verx10 < 125 || !is_end_compute || cmd_buffer->state.last_indirect_dispatch != NULL || cmd_buffer->state.last_compute_walker != NULL); enum anv_timestamp_capture_type capture_type = (device->info->verx10 >= 125 && is_end_compute) ? (cmd_buffer->state.last_indirect_dispatch != NULL ? ANV_TIMESTAMP_REWRITE_INDIRECT_DISPATCH : ANV_TIMESTAMP_REWRITE_COMPUTE_WALKER) : (flags & (INTEL_DS_TRACEPOINT_FLAG_END_OF_PIPE | INTEL_DS_TRACEPOINT_FLAG_END_OF_PIPE_CS)) ? ANV_TIMESTAMP_CAPTURE_END_OF_PIPE : ANV_TIMESTAMP_CAPTURE_TOP_OF_PIPE; void *addr = capture_type == ANV_TIMESTAMP_REWRITE_INDIRECT_DISPATCH ? cmd_buffer->state.last_indirect_dispatch : capture_type == ANV_TIMESTAMP_REWRITE_COMPUTE_WALKER ? cmd_buffer->state.last_compute_walker : NULL; device->physical->cmd_emit_timestamp(batch, device, ts_address, capture_type, addr); if (is_end_compute) { cmd_buffer->state.last_compute_walker = NULL; cmd_buffer->state.last_indirect_dispatch = NULL; } } static uint64_t anv_utrace_read_ts(struct u_trace_context *utctx, void *timestamps, uint64_t offset_B, void *flush_data) { struct anv_device *device = container_of(utctx, struct anv_device, ds.trace_context); struct anv_bo *bo = timestamps; struct anv_utrace_submit *submit = container_of(flush_data, struct anv_utrace_submit, ds); /* Only need to stall on results for the first entry: */ if (offset_B == 0) { MESA_TRACE_SCOPE("anv utrace wait timestamps"); UNUSED VkResult result = vk_sync_wait(&device->vk, submit->base.signal.sync, submit->base.signal.signal_value, VK_SYNC_WAIT_COMPLETE, os_time_get_absolute_timeout(OS_TIMEOUT_INFINITE)); assert(result == VK_SUCCESS); } assert(offset_B % sizeof(union anv_utrace_timestamp) == 0); union anv_utrace_timestamp *ts = (union anv_utrace_timestamp *)(bo->map + offset_B); /* Don't translate the no-timestamp marker: */ if (ts->timestamp == U_TRACE_NO_TIMESTAMP) return U_TRACE_NO_TIMESTAMP; /* Detect a 16/32 bytes timestamp write */ if (ts->gfx20_postsync_data[1] != 0 || ts->gfx20_postsync_data[2] != 0 || ts->gfx20_postsync_data[3] != 0) { if (device->info->ver >= 20) { return intel_device_info_timebase_scale(device->info, ts->gfx20_postsync_data[3]); } /* The timestamp written by COMPUTE_WALKER::PostSync only as 32bits. We * need to rebuild the full 64bits using the previous timestamp. We * assume that utrace is reading the timestamp in order. Anyway * timestamp rollover on 32bits in a few minutes so in most cases that * should be correct. */ uint64_t timestamp = (submit->last_full_timestamp & 0xffffffff00000000) | (uint64_t) ts->gfx125_postsync_data[3]; return intel_device_info_timebase_scale(device->info, timestamp); } submit->last_full_timestamp = ts->timestamp; return intel_device_info_timebase_scale(device->info, ts->timestamp); } static void anv_utrace_capture_data(struct u_trace *ut, void *cs, void *dst_buffer, uint64_t dst_offset_B, void *src_buffer, uint64_t src_offset_B, uint32_t size_B) { struct anv_device *device = container_of(ut->utctx, struct anv_device, ds.trace_context); struct anv_cmd_buffer *cmd_buffer = container_of(ut, struct anv_cmd_buffer, trace); /* cmd_buffer is only valid if cs == NULL */ struct anv_batch *batch = cs != NULL ? cs : &cmd_buffer->batch; struct anv_address dst_addr = { .bo = dst_buffer, .offset = dst_offset_B, }; struct anv_address src_addr = { .bo = src_buffer, .offset = src_offset_B, }; device->physical->cmd_capture_data(batch, device, dst_addr, src_addr, size_B); } static const void * anv_utrace_get_data(struct u_trace_context *utctx, void *buffer, uint64_t offset_B, uint32_t size_B) { struct anv_bo *bo = buffer; return bo->map + offset_B; } void anv_device_utrace_init(struct anv_device *device) { device->utrace_timestamp_size = sizeof(union anv_utrace_timestamp); anv_bo_pool_init(&device->utrace_bo_pool, device, "utrace", ANV_BO_ALLOC_MAPPED | ANV_BO_ALLOC_HOST_CACHED_COHERENT); intel_ds_device_init(&device->ds, device->info, device->fd, device->physical->local_minor, INTEL_DS_API_VULKAN); u_trace_context_init(&device->ds.trace_context, &device->ds, device->utrace_timestamp_size, 12, anv_utrace_create_buffer, anv_utrace_destroy_buffer, anv_utrace_record_ts, anv_utrace_read_ts, anv_utrace_capture_data, anv_utrace_get_data, anv_utrace_delete_submit); for (uint32_t q = 0; q < device->queue_count; q++) { struct anv_queue *queue = &device->queues[q]; intel_ds_device_init_queue(&device->ds, &queue->ds, "%s%u", intel_engines_class_to_string(queue->family->engine_class), queue->vk.index_in_family); } } void anv_device_utrace_finish(struct anv_device *device) { intel_ds_device_process(&device->ds, true); intel_ds_device_fini(&device->ds); anv_bo_pool_finish(&device->utrace_bo_pool); } enum intel_ds_stall_flag anv_pipe_flush_bit_to_ds_stall_flag(enum anv_pipe_bits bits) { static const struct { enum anv_pipe_bits anv; enum intel_ds_stall_flag ds; } anv_to_ds_flags[] = { { .anv = ANV_PIPE_DEPTH_CACHE_FLUSH_BIT, .ds = INTEL_DS_DEPTH_CACHE_FLUSH_BIT, }, { .anv = ANV_PIPE_DATA_CACHE_FLUSH_BIT, .ds = INTEL_DS_DATA_CACHE_FLUSH_BIT, }, { .anv = ANV_PIPE_TILE_CACHE_FLUSH_BIT, .ds = INTEL_DS_TILE_CACHE_FLUSH_BIT, }, { .anv = ANV_PIPE_RENDER_TARGET_CACHE_FLUSH_BIT, .ds = INTEL_DS_RENDER_TARGET_CACHE_FLUSH_BIT, }, { .anv = ANV_PIPE_STATE_CACHE_INVALIDATE_BIT, .ds = INTEL_DS_STATE_CACHE_INVALIDATE_BIT, }, { .anv = ANV_PIPE_CONSTANT_CACHE_INVALIDATE_BIT, .ds = INTEL_DS_CONST_CACHE_INVALIDATE_BIT, }, { .anv = ANV_PIPE_VF_CACHE_INVALIDATE_BIT, .ds = INTEL_DS_VF_CACHE_INVALIDATE_BIT, }, { .anv = ANV_PIPE_TEXTURE_CACHE_INVALIDATE_BIT, .ds = INTEL_DS_TEXTURE_CACHE_INVALIDATE_BIT, }, { .anv = ANV_PIPE_INSTRUCTION_CACHE_INVALIDATE_BIT, .ds = INTEL_DS_INST_CACHE_INVALIDATE_BIT, }, { .anv = ANV_PIPE_DEPTH_STALL_BIT, .ds = INTEL_DS_DEPTH_STALL_BIT, }, { .anv = ANV_PIPE_CS_STALL_BIT, .ds = INTEL_DS_CS_STALL_BIT, }, { .anv = ANV_PIPE_HDC_PIPELINE_FLUSH_BIT, .ds = INTEL_DS_HDC_PIPELINE_FLUSH_BIT, }, { .anv = ANV_PIPE_STALL_AT_SCOREBOARD_BIT, .ds = INTEL_DS_STALL_AT_SCOREBOARD_BIT, }, { .anv = ANV_PIPE_UNTYPED_DATAPORT_CACHE_FLUSH_BIT, .ds = INTEL_DS_UNTYPED_DATAPORT_CACHE_FLUSH_BIT, }, { .anv = ANV_PIPE_PSS_STALL_SYNC_BIT, .ds = INTEL_DS_PSS_STALL_SYNC_BIT, }, { .anv = ANV_PIPE_END_OF_PIPE_SYNC_BIT, .ds = INTEL_DS_END_OF_PIPE_BIT, }, { .anv = ANV_PIPE_CCS_CACHE_FLUSH_BIT, .ds = INTEL_DS_CCS_CACHE_FLUSH_BIT, }, }; enum intel_ds_stall_flag ret = 0; for (uint32_t i = 0; i < ARRAY_SIZE(anv_to_ds_flags); i++) { if (anv_to_ds_flags[i].anv & bits) ret |= anv_to_ds_flags[i].ds; } return ret; } void anv_CmdBeginDebugUtilsLabelEXT( VkCommandBuffer _commandBuffer, const VkDebugUtilsLabelEXT *pLabelInfo) { VK_FROM_HANDLE(anv_cmd_buffer, cmd_buffer, _commandBuffer); vk_common_CmdBeginDebugUtilsLabelEXT(_commandBuffer, pLabelInfo); trace_intel_begin_cmd_buffer_annotation(&cmd_buffer->trace); } void anv_CmdEndDebugUtilsLabelEXT(VkCommandBuffer _commandBuffer) { VK_FROM_HANDLE(anv_cmd_buffer, cmd_buffer, _commandBuffer); if (cmd_buffer->vk.labels.size > 0) { const VkDebugUtilsLabelEXT *label = util_dynarray_top_ptr(&cmd_buffer->vk.labels, VkDebugUtilsLabelEXT); trace_intel_end_cmd_buffer_annotation(&cmd_buffer->trace, strlen(label->pLabelName), label->pLabelName); } vk_common_CmdEndDebugUtilsLabelEXT(_commandBuffer); } void anv_queue_trace(struct anv_queue *queue, const char *label, bool frame, bool begin) { struct anv_device *device = queue->device; VkResult result; struct anv_utrace_submit *submit = vk_zalloc(&device->vk.alloc, sizeof(struct anv_utrace_submit), 8, VK_SYSTEM_ALLOCATION_SCOPE_DEVICE); if (!submit) return; result = anv_async_submit_init(&submit->base, queue, &device->batch_bo_pool, false, true); if (result != VK_SUCCESS) goto error_async; intel_ds_flush_data_init(&submit->ds, &queue->ds, queue->ds.submission_id); struct anv_batch *batch = &submit->base.batch; if (frame) { if (begin) trace_intel_begin_frame(&submit->ds.trace, batch); else trace_intel_end_frame(&submit->ds.trace, batch, device->debug_frame_desc->frame_id); } else { if (begin) { trace_intel_begin_queue_annotation(&submit->ds.trace, batch); } else { trace_intel_end_queue_annotation(&submit->ds.trace, batch, strlen(label), label); } } anv_batch_emit(batch, GFX9_MI_BATCH_BUFFER_END, bbs); anv_batch_emit(batch, GFX9_MI_NOOP, noop); if (batch->status != VK_SUCCESS) { result = batch->status; goto error_batch; } intel_ds_queue_flush_data(&queue->ds, &submit->ds.trace, &submit->ds, device->vk.current_frame, true); result = device->kmd_backend->queue_exec_async(&submit->base, 0, NULL, 0, NULL); if (result != VK_SUCCESS) goto error_batch; if (frame && !begin) intel_ds_device_process(&device->ds, true); return; error_batch: intel_ds_flush_data_fini(&submit->ds); anv_async_submit_fini(&submit->base); error_async: vk_free(&device->vk.alloc, submit); } void anv_QueueBeginDebugUtilsLabelEXT( VkQueue _queue, const VkDebugUtilsLabelEXT *pLabelInfo) { VK_FROM_HANDLE(anv_queue, queue, _queue); vk_common_QueueBeginDebugUtilsLabelEXT(_queue, pLabelInfo); anv_queue_trace(queue, pLabelInfo->pLabelName, false /* frame */, true /* begin */); } void anv_QueueEndDebugUtilsLabelEXT(VkQueue _queue) { VK_FROM_HANDLE(anv_queue, queue, _queue); if (queue->vk.labels.size > 0) { const VkDebugUtilsLabelEXT *label = util_dynarray_top_ptr(&queue->vk.labels, VkDebugUtilsLabelEXT); anv_queue_trace(queue, label->pLabelName, false /* frame */, false /* begin */); intel_ds_device_process(&queue->device->ds, true); } vk_common_QueueEndDebugUtilsLabelEXT(_queue); }