/* * Copyright © 2015 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 #include #include #include #include #include "anv_private.h" #include "anv_timestamp.h" #include "util/strtod.h" #include "util/debug.h" #include "genxml/gen7_pack.h" struct anv_dispatch_table dtable; static void compiler_debug_log(void *data, const char *fmt, ...) { } static void compiler_perf_log(void *data, const char *fmt, ...) { va_list args; va_start(args, fmt); if (unlikely(INTEL_DEBUG & DEBUG_PERF)) vfprintf(stderr, fmt, args); va_end(args); } static VkResult anv_physical_device_init(struct anv_physical_device *device, struct anv_instance *instance, const char *path) { VkResult result; int fd; fd = open(path, O_RDWR | O_CLOEXEC); if (fd < 0) return vk_error(VK_ERROR_INCOMPATIBLE_DRIVER); device->_loader_data.loaderMagic = ICD_LOADER_MAGIC; device->instance = instance; assert(strlen(path) < ARRAY_SIZE(device->path)); strncpy(device->path, path, ARRAY_SIZE(device->path)); device->chipset_id = anv_gem_get_param(fd, I915_PARAM_CHIPSET_ID); if (!device->chipset_id) { result = vk_error(VK_ERROR_INCOMPATIBLE_DRIVER); goto fail; } device->name = gen_get_device_name(device->chipset_id); if (!gen_get_device_info(device->chipset_id, &device->info)) { result = vk_error(VK_ERROR_INCOMPATIBLE_DRIVER); goto fail; } if (device->info.is_haswell) { fprintf(stderr, "WARNING: Haswell Vulkan support is incomplete\n"); } else if (device->info.gen == 7 && !device->info.is_baytrail) { fprintf(stderr, "WARNING: Ivy Bridge Vulkan support is incomplete\n"); } else if (device->info.gen == 7 && device->info.is_baytrail) { fprintf(stderr, "WARNING: Bay Trail Vulkan support is incomplete\n"); } else if (device->info.gen >= 8) { /* Broadwell, Cherryview, Skylake, Broxton, Kabylake is as fully * supported as anything */ } else { result = vk_errorf(VK_ERROR_INCOMPATIBLE_DRIVER, "Vulkan not yet supported on %s", device->name); goto fail; } device->cmd_parser_version = -1; if (device->info.gen == 7) { device->cmd_parser_version = anv_gem_get_param(fd, I915_PARAM_CMD_PARSER_VERSION); if (device->cmd_parser_version == -1) { result = vk_errorf(VK_ERROR_INITIALIZATION_FAILED, "failed to get command parser version"); goto fail; } } if (anv_gem_get_aperture(fd, &device->aperture_size) == -1) { result = vk_errorf(VK_ERROR_INITIALIZATION_FAILED, "failed to get aperture size: %m"); goto fail; } if (!anv_gem_get_param(fd, I915_PARAM_HAS_WAIT_TIMEOUT)) { result = vk_errorf(VK_ERROR_INITIALIZATION_FAILED, "kernel missing gem wait"); goto fail; } if (!anv_gem_get_param(fd, I915_PARAM_HAS_EXECBUF2)) { result = vk_errorf(VK_ERROR_INITIALIZATION_FAILED, "kernel missing execbuf2"); goto fail; } if (!device->info.has_llc && anv_gem_get_param(fd, I915_PARAM_MMAP_VERSION) < 1) { result = vk_errorf(VK_ERROR_INITIALIZATION_FAILED, "kernel missing wc mmap"); goto fail; } bool swizzled = anv_gem_get_bit6_swizzle(fd, I915_TILING_X); /* GENs prior to 8 do not support EU/Subslice info */ if (device->info.gen >= 8) { device->subslice_total = anv_gem_get_param(fd, I915_PARAM_SUBSLICE_TOTAL); device->eu_total = anv_gem_get_param(fd, I915_PARAM_EU_TOTAL); /* Without this information, we cannot get the right Braswell * brandstrings, and we have to use conservative numbers for GPGPU on * many platforms, but otherwise, things will just work. */ if (device->subslice_total < 1 || device->eu_total < 1) { fprintf(stderr, "WARNING: Kernel 4.1 required to properly" " query GPU properties.\n"); } } else if (device->info.gen == 7) { device->subslice_total = 1 << (device->info.gt - 1); } if (device->info.is_cherryview && device->subslice_total > 0 && device->eu_total > 0) { /* Logical CS threads = EUs per subslice * 7 threads per EU */ uint32_t max_cs_threads = device->eu_total / device->subslice_total * 7; /* Fuse configurations may give more threads than expected, never less. */ if (max_cs_threads > device->info.max_cs_threads) device->info.max_cs_threads = max_cs_threads; } close(fd); brw_process_intel_debug_variable(); device->compiler = brw_compiler_create(NULL, &device->info); if (device->compiler == NULL) { result = vk_error(VK_ERROR_OUT_OF_HOST_MEMORY); goto fail; } device->compiler->shader_debug_log = compiler_debug_log; device->compiler->shader_perf_log = compiler_perf_log; result = anv_init_wsi(device); if (result != VK_SUCCESS) goto fail; /* XXX: Actually detect bit6 swizzling */ isl_device_init(&device->isl_dev, &device->info, swizzled); return VK_SUCCESS; fail: close(fd); return result; } static void anv_physical_device_finish(struct anv_physical_device *device) { anv_finish_wsi(device); ralloc_free(device->compiler); } static const VkExtensionProperties global_extensions[] = { { .extensionName = VK_KHR_SURFACE_EXTENSION_NAME, .specVersion = 25, }, #ifdef VK_USE_PLATFORM_XCB_KHR { .extensionName = VK_KHR_XCB_SURFACE_EXTENSION_NAME, .specVersion = 5, }, #endif #ifdef VK_USE_PLATFORM_XLIB_KHR { .extensionName = VK_KHR_XLIB_SURFACE_EXTENSION_NAME, .specVersion = 5, }, #endif #ifdef VK_USE_PLATFORM_WAYLAND_KHR { .extensionName = VK_KHR_WAYLAND_SURFACE_EXTENSION_NAME, .specVersion = 4, }, #endif }; static const VkExtensionProperties device_extensions[] = { { .extensionName = VK_KHR_SWAPCHAIN_EXTENSION_NAME, .specVersion = 67, }, }; static void * default_alloc_func(void *pUserData, size_t size, size_t align, VkSystemAllocationScope allocationScope) { return malloc(size); } static void * default_realloc_func(void *pUserData, void *pOriginal, size_t size, size_t align, VkSystemAllocationScope allocationScope) { return realloc(pOriginal, size); } static void default_free_func(void *pUserData, void *pMemory) { free(pMemory); } static const VkAllocationCallbacks default_alloc = { .pUserData = NULL, .pfnAllocation = default_alloc_func, .pfnReallocation = default_realloc_func, .pfnFree = default_free_func, }; VkResult anv_CreateInstance( const VkInstanceCreateInfo* pCreateInfo, const VkAllocationCallbacks* pAllocator, VkInstance* pInstance) { struct anv_instance *instance; assert(pCreateInfo->sType == VK_STRUCTURE_TYPE_INSTANCE_CREATE_INFO); uint32_t client_version; if (pCreateInfo->pApplicationInfo && pCreateInfo->pApplicationInfo->apiVersion != 0) { client_version = pCreateInfo->pApplicationInfo->apiVersion; } else { client_version = VK_MAKE_VERSION(1, 0, 0); } if (VK_MAKE_VERSION(1, 0, 0) > client_version || client_version > VK_MAKE_VERSION(1, 0, 0xfff)) { return vk_errorf(VK_ERROR_INCOMPATIBLE_DRIVER, "Client requested version %d.%d.%d", VK_VERSION_MAJOR(client_version), VK_VERSION_MINOR(client_version), VK_VERSION_PATCH(client_version)); } for (uint32_t i = 0; i < pCreateInfo->enabledExtensionCount; i++) { bool found = false; for (uint32_t j = 0; j < ARRAY_SIZE(global_extensions); j++) { if (strcmp(pCreateInfo->ppEnabledExtensionNames[i], global_extensions[j].extensionName) == 0) { found = true; break; } } if (!found) return vk_error(VK_ERROR_EXTENSION_NOT_PRESENT); } instance = vk_alloc2(&default_alloc, pAllocator, sizeof(*instance), 8, VK_SYSTEM_ALLOCATION_SCOPE_INSTANCE); if (!instance) return vk_error(VK_ERROR_OUT_OF_HOST_MEMORY); instance->_loader_data.loaderMagic = ICD_LOADER_MAGIC; if (pAllocator) instance->alloc = *pAllocator; else instance->alloc = default_alloc; instance->apiVersion = client_version; instance->physicalDeviceCount = -1; _mesa_locale_init(); VG(VALGRIND_CREATE_MEMPOOL(instance, 0, false)); *pInstance = anv_instance_to_handle(instance); return VK_SUCCESS; } void anv_DestroyInstance( VkInstance _instance, const VkAllocationCallbacks* pAllocator) { ANV_FROM_HANDLE(anv_instance, instance, _instance); if (instance->physicalDeviceCount > 0) { /* We support at most one physical device. */ assert(instance->physicalDeviceCount == 1); anv_physical_device_finish(&instance->physicalDevice); } VG(VALGRIND_DESTROY_MEMPOOL(instance)); _mesa_locale_fini(); vk_free(&instance->alloc, instance); } VkResult anv_EnumeratePhysicalDevices( VkInstance _instance, uint32_t* pPhysicalDeviceCount, VkPhysicalDevice* pPhysicalDevices) { ANV_FROM_HANDLE(anv_instance, instance, _instance); VkResult result; if (instance->physicalDeviceCount < 0) { char path[20]; for (unsigned i = 0; i < 8; i++) { snprintf(path, sizeof(path), "/dev/dri/renderD%d", 128 + i); result = anv_physical_device_init(&instance->physicalDevice, instance, path); if (result != VK_ERROR_INCOMPATIBLE_DRIVER) break; } if (result == VK_ERROR_INCOMPATIBLE_DRIVER) { instance->physicalDeviceCount = 0; } else if (result == VK_SUCCESS) { instance->physicalDeviceCount = 1; } else { return result; } } /* pPhysicalDeviceCount is an out parameter if pPhysicalDevices is NULL; * otherwise it's an inout parameter. * * The Vulkan spec (git aaed022) says: * * pPhysicalDeviceCount is a pointer to an unsigned integer variable * that is initialized with the number of devices the application is * prepared to receive handles to. pname:pPhysicalDevices is pointer to * an array of at least this many VkPhysicalDevice handles [...]. * * Upon success, if pPhysicalDevices is NULL, vkEnumeratePhysicalDevices * overwrites the contents of the variable pointed to by * pPhysicalDeviceCount with the number of physical devices in in the * instance; otherwise, vkEnumeratePhysicalDevices overwrites * pPhysicalDeviceCount with the number of physical handles written to * pPhysicalDevices. */ if (!pPhysicalDevices) { *pPhysicalDeviceCount = instance->physicalDeviceCount; } else if (*pPhysicalDeviceCount >= 1) { pPhysicalDevices[0] = anv_physical_device_to_handle(&instance->physicalDevice); *pPhysicalDeviceCount = 1; } else if (*pPhysicalDeviceCount < instance->physicalDeviceCount) { return VK_INCOMPLETE; } else { *pPhysicalDeviceCount = 0; } return VK_SUCCESS; } void anv_GetPhysicalDeviceFeatures( VkPhysicalDevice physicalDevice, VkPhysicalDeviceFeatures* pFeatures) { ANV_FROM_HANDLE(anv_physical_device, pdevice, physicalDevice); *pFeatures = (VkPhysicalDeviceFeatures) { .robustBufferAccess = true, .fullDrawIndexUint32 = true, .imageCubeArray = false, .independentBlend = true, .geometryShader = true, .tessellationShader = false, .sampleRateShading = true, .dualSrcBlend = true, .logicOp = true, .multiDrawIndirect = false, .drawIndirectFirstInstance = false, .depthClamp = true, .depthBiasClamp = false, .fillModeNonSolid = true, .depthBounds = false, .wideLines = true, .largePoints = true, .alphaToOne = true, .multiViewport = true, .samplerAnisotropy = true, .textureCompressionETC2 = pdevice->info.gen >= 8 || pdevice->info.is_baytrail, .textureCompressionASTC_LDR = pdevice->info.gen >= 9, /* FINISHME CHV */ .textureCompressionBC = true, .occlusionQueryPrecise = true, .pipelineStatisticsQuery = false, .fragmentStoresAndAtomics = true, .shaderTessellationAndGeometryPointSize = true, .shaderImageGatherExtended = false, .shaderStorageImageExtendedFormats = false, .shaderStorageImageMultisample = false, .shaderUniformBufferArrayDynamicIndexing = true, .shaderSampledImageArrayDynamicIndexing = true, .shaderStorageBufferArrayDynamicIndexing = true, .shaderStorageImageArrayDynamicIndexing = true, .shaderStorageImageReadWithoutFormat = false, .shaderStorageImageWriteWithoutFormat = true, .shaderClipDistance = false, .shaderCullDistance = false, .shaderFloat64 = false, .shaderInt64 = false, .shaderInt16 = false, .alphaToOne = true, .variableMultisampleRate = false, .inheritedQueries = false, }; /* We can't do image stores in vec4 shaders */ pFeatures->vertexPipelineStoresAndAtomics = pdevice->compiler->scalar_stage[MESA_SHADER_VERTEX] && pdevice->compiler->scalar_stage[MESA_SHADER_GEOMETRY]; } void anv_device_get_cache_uuid(void *uuid) { memset(uuid, 0, VK_UUID_SIZE); snprintf(uuid, VK_UUID_SIZE, "anv-%s", ANV_TIMESTAMP); } void anv_GetPhysicalDeviceProperties( VkPhysicalDevice physicalDevice, VkPhysicalDeviceProperties* pProperties) { ANV_FROM_HANDLE(anv_physical_device, pdevice, physicalDevice); const struct gen_device_info *devinfo = &pdevice->info; const float time_stamp_base = devinfo->gen >= 9 ? 83.333 : 80.0; /* See assertions made when programming the buffer surface state. */ const uint32_t max_raw_buffer_sz = devinfo->gen >= 7 ? (1ul << 30) : (1ul << 27); VkSampleCountFlags sample_counts = isl_device_get_sample_counts(&pdevice->isl_dev); VkPhysicalDeviceLimits limits = { .maxImageDimension1D = (1 << 14), .maxImageDimension2D = (1 << 14), .maxImageDimension3D = (1 << 11), .maxImageDimensionCube = (1 << 14), .maxImageArrayLayers = (1 << 11), .maxTexelBufferElements = 128 * 1024 * 1024, .maxUniformBufferRange = (1ul << 27), .maxStorageBufferRange = max_raw_buffer_sz, .maxPushConstantsSize = MAX_PUSH_CONSTANTS_SIZE, .maxMemoryAllocationCount = UINT32_MAX, .maxSamplerAllocationCount = 64 * 1024, .bufferImageGranularity = 64, /* A cache line */ .sparseAddressSpaceSize = 0, .maxBoundDescriptorSets = MAX_SETS, .maxPerStageDescriptorSamplers = 64, .maxPerStageDescriptorUniformBuffers = 64, .maxPerStageDescriptorStorageBuffers = 64, .maxPerStageDescriptorSampledImages = 64, .maxPerStageDescriptorStorageImages = 64, .maxPerStageDescriptorInputAttachments = 64, .maxPerStageResources = 128, .maxDescriptorSetSamplers = 256, .maxDescriptorSetUniformBuffers = 256, .maxDescriptorSetUniformBuffersDynamic = 256, .maxDescriptorSetStorageBuffers = 256, .maxDescriptorSetStorageBuffersDynamic = 256, .maxDescriptorSetSampledImages = 256, .maxDescriptorSetStorageImages = 256, .maxDescriptorSetInputAttachments = 256, .maxVertexInputAttributes = 32, .maxVertexInputBindings = 32, .maxVertexInputAttributeOffset = 2047, .maxVertexInputBindingStride = 2048, .maxVertexOutputComponents = 128, .maxTessellationGenerationLevel = 0, .maxTessellationPatchSize = 0, .maxTessellationControlPerVertexInputComponents = 0, .maxTessellationControlPerVertexOutputComponents = 0, .maxTessellationControlPerPatchOutputComponents = 0, .maxTessellationControlTotalOutputComponents = 0, .maxTessellationEvaluationInputComponents = 0, .maxTessellationEvaluationOutputComponents = 0, .maxGeometryShaderInvocations = 32, .maxGeometryInputComponents = 64, .maxGeometryOutputComponents = 128, .maxGeometryOutputVertices = 256, .maxGeometryTotalOutputComponents = 1024, .maxFragmentInputComponents = 128, .maxFragmentOutputAttachments = 8, .maxFragmentDualSrcAttachments = 2, .maxFragmentCombinedOutputResources = 8, .maxComputeSharedMemorySize = 32768, .maxComputeWorkGroupCount = { 65535, 65535, 65535 }, .maxComputeWorkGroupInvocations = 16 * devinfo->max_cs_threads, .maxComputeWorkGroupSize = { 16 * devinfo->max_cs_threads, 16 * devinfo->max_cs_threads, 16 * devinfo->max_cs_threads, }, .subPixelPrecisionBits = 4 /* FIXME */, .subTexelPrecisionBits = 4 /* FIXME */, .mipmapPrecisionBits = 4 /* FIXME */, .maxDrawIndexedIndexValue = UINT32_MAX, .maxDrawIndirectCount = UINT32_MAX, .maxSamplerLodBias = 16, .maxSamplerAnisotropy = 16, .maxViewports = MAX_VIEWPORTS, .maxViewportDimensions = { (1 << 14), (1 << 14) }, .viewportBoundsRange = { INT16_MIN, INT16_MAX }, .viewportSubPixelBits = 13, /* We take a float? */ .minMemoryMapAlignment = 4096, /* A page */ .minTexelBufferOffsetAlignment = 1, .minUniformBufferOffsetAlignment = 1, .minStorageBufferOffsetAlignment = 1, .minTexelOffset = -8, .maxTexelOffset = 7, .minTexelGatherOffset = -8, .maxTexelGatherOffset = 7, .minInterpolationOffset = -0.5, .maxInterpolationOffset = 0.4375, .subPixelInterpolationOffsetBits = 4, .maxFramebufferWidth = (1 << 14), .maxFramebufferHeight = (1 << 14), .maxFramebufferLayers = (1 << 10), .framebufferColorSampleCounts = sample_counts, .framebufferDepthSampleCounts = sample_counts, .framebufferStencilSampleCounts = sample_counts, .framebufferNoAttachmentsSampleCounts = sample_counts, .maxColorAttachments = MAX_RTS, .sampledImageColorSampleCounts = sample_counts, .sampledImageIntegerSampleCounts = VK_SAMPLE_COUNT_1_BIT, .sampledImageDepthSampleCounts = sample_counts, .sampledImageStencilSampleCounts = sample_counts, .storageImageSampleCounts = VK_SAMPLE_COUNT_1_BIT, .maxSampleMaskWords = 1, .timestampComputeAndGraphics = false, .timestampPeriod = time_stamp_base, .maxClipDistances = 0 /* FIXME */, .maxCullDistances = 0 /* FIXME */, .maxCombinedClipAndCullDistances = 0 /* FIXME */, .discreteQueuePriorities = 1, .pointSizeRange = { 0.125, 255.875 }, .lineWidthRange = { 0.0, 7.9921875 }, .pointSizeGranularity = (1.0 / 8.0), .lineWidthGranularity = (1.0 / 128.0), .strictLines = false, /* FINISHME */ .standardSampleLocations = true, .optimalBufferCopyOffsetAlignment = 128, .optimalBufferCopyRowPitchAlignment = 128, .nonCoherentAtomSize = 64, }; *pProperties = (VkPhysicalDeviceProperties) { .apiVersion = VK_MAKE_VERSION(1, 0, 5), .driverVersion = 1, .vendorID = 0x8086, .deviceID = pdevice->chipset_id, .deviceType = VK_PHYSICAL_DEVICE_TYPE_INTEGRATED_GPU, .limits = limits, .sparseProperties = {0}, /* Broadwell doesn't do sparse. */ }; strcpy(pProperties->deviceName, pdevice->name); anv_device_get_cache_uuid(pProperties->pipelineCacheUUID); } void anv_GetPhysicalDeviceQueueFamilyProperties( VkPhysicalDevice physicalDevice, uint32_t* pCount, VkQueueFamilyProperties* pQueueFamilyProperties) { if (pQueueFamilyProperties == NULL) { *pCount = 1; return; } assert(*pCount >= 1); *pQueueFamilyProperties = (VkQueueFamilyProperties) { .queueFlags = VK_QUEUE_GRAPHICS_BIT | VK_QUEUE_COMPUTE_BIT | VK_QUEUE_TRANSFER_BIT, .queueCount = 1, .timestampValidBits = 36, /* XXX: Real value here */ .minImageTransferGranularity = (VkExtent3D) { 1, 1, 1 }, }; } void anv_GetPhysicalDeviceMemoryProperties( VkPhysicalDevice physicalDevice, VkPhysicalDeviceMemoryProperties* pMemoryProperties) { ANV_FROM_HANDLE(anv_physical_device, physical_device, physicalDevice); VkDeviceSize heap_size; /* Reserve some wiggle room for the driver by exposing only 75% of the * aperture to the heap. */ heap_size = 3 * physical_device->aperture_size / 4; if (physical_device->info.has_llc) { /* Big core GPUs share LLC with the CPU and thus one memory type can be * both cached and coherent at the same time. */ pMemoryProperties->memoryTypeCount = 1; pMemoryProperties->memoryTypes[0] = (VkMemoryType) { .propertyFlags = VK_MEMORY_PROPERTY_DEVICE_LOCAL_BIT | VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT | VK_MEMORY_PROPERTY_HOST_COHERENT_BIT | VK_MEMORY_PROPERTY_HOST_CACHED_BIT, .heapIndex = 0, }; } else { /* The spec requires that we expose a host-visible, coherent memory * type, but Atom GPUs don't share LLC. Thus we offer two memory types * to give the application a choice between cached, but not coherent and * coherent but uncached (WC though). */ pMemoryProperties->memoryTypeCount = 2; pMemoryProperties->memoryTypes[0] = (VkMemoryType) { .propertyFlags = VK_MEMORY_PROPERTY_DEVICE_LOCAL_BIT | VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT | VK_MEMORY_PROPERTY_HOST_COHERENT_BIT, .heapIndex = 0, }; pMemoryProperties->memoryTypes[1] = (VkMemoryType) { .propertyFlags = VK_MEMORY_PROPERTY_DEVICE_LOCAL_BIT | VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT | VK_MEMORY_PROPERTY_HOST_CACHED_BIT, .heapIndex = 0, }; } pMemoryProperties->memoryHeapCount = 1; pMemoryProperties->memoryHeaps[0] = (VkMemoryHeap) { .size = heap_size, .flags = VK_MEMORY_HEAP_DEVICE_LOCAL_BIT, }; } PFN_vkVoidFunction anv_GetInstanceProcAddr( VkInstance instance, const char* pName) { return anv_lookup_entrypoint(NULL, pName); } /* With version 1+ of the loader interface the ICD should expose * vk_icdGetInstanceProcAddr to work around certain LD_PRELOAD issues seen in apps. */ PUBLIC VKAPI_ATTR PFN_vkVoidFunction VKAPI_CALL vk_icdGetInstanceProcAddr( VkInstance instance, const char* pName); PUBLIC VKAPI_ATTR PFN_vkVoidFunction VKAPI_CALL vk_icdGetInstanceProcAddr( VkInstance instance, const char* pName) { return anv_GetInstanceProcAddr(instance, pName); } PFN_vkVoidFunction anv_GetDeviceProcAddr( VkDevice _device, const char* pName) { ANV_FROM_HANDLE(anv_device, device, _device); return anv_lookup_entrypoint(&device->info, pName); } static VkResult anv_queue_init(struct anv_device *device, struct anv_queue *queue) { queue->_loader_data.loaderMagic = ICD_LOADER_MAGIC; queue->device = device; queue->pool = &device->surface_state_pool; return VK_SUCCESS; } static void anv_queue_finish(struct anv_queue *queue) { } static struct anv_state anv_state_pool_emit_data(struct anv_state_pool *pool, size_t size, size_t align, const void *p) { struct anv_state state; state = anv_state_pool_alloc(pool, size, align); memcpy(state.map, p, size); if (!pool->block_pool->device->info.has_llc) anv_state_clflush(state); return state; } struct gen8_border_color { union { float float32[4]; uint32_t uint32[4]; }; /* Pad out to 64 bytes */ uint32_t _pad[12]; }; static void anv_device_init_border_colors(struct anv_device *device) { static const struct gen8_border_color border_colors[] = { [VK_BORDER_COLOR_FLOAT_TRANSPARENT_BLACK] = { .float32 = { 0.0, 0.0, 0.0, 0.0 } }, [VK_BORDER_COLOR_FLOAT_OPAQUE_BLACK] = { .float32 = { 0.0, 0.0, 0.0, 1.0 } }, [VK_BORDER_COLOR_FLOAT_OPAQUE_WHITE] = { .float32 = { 1.0, 1.0, 1.0, 1.0 } }, [VK_BORDER_COLOR_INT_TRANSPARENT_BLACK] = { .uint32 = { 0, 0, 0, 0 } }, [VK_BORDER_COLOR_INT_OPAQUE_BLACK] = { .uint32 = { 0, 0, 0, 1 } }, [VK_BORDER_COLOR_INT_OPAQUE_WHITE] = { .uint32 = { 1, 1, 1, 1 } }, }; device->border_colors = anv_state_pool_emit_data(&device->dynamic_state_pool, sizeof(border_colors), 64, border_colors); } VkResult anv_device_submit_simple_batch(struct anv_device *device, struct anv_batch *batch) { struct drm_i915_gem_execbuffer2 execbuf; struct drm_i915_gem_exec_object2 exec2_objects[1]; struct anv_bo bo, *exec_bos[1]; VkResult result = VK_SUCCESS; uint32_t size; int64_t timeout; int ret; /* Kernel driver requires 8 byte aligned batch length */ size = align_u32(batch->next - batch->start, 8); result = anv_bo_pool_alloc(&device->batch_bo_pool, &bo, size); if (result != VK_SUCCESS) return result; memcpy(bo.map, batch->start, size); if (!device->info.has_llc) anv_clflush_range(bo.map, size); exec_bos[0] = &bo; exec2_objects[0].handle = bo.gem_handle; exec2_objects[0].relocation_count = 0; exec2_objects[0].relocs_ptr = 0; exec2_objects[0].alignment = 0; exec2_objects[0].offset = bo.offset; exec2_objects[0].flags = 0; exec2_objects[0].rsvd1 = 0; exec2_objects[0].rsvd2 = 0; execbuf.buffers_ptr = (uintptr_t) exec2_objects; execbuf.buffer_count = 1; execbuf.batch_start_offset = 0; execbuf.batch_len = size; execbuf.cliprects_ptr = 0; execbuf.num_cliprects = 0; execbuf.DR1 = 0; execbuf.DR4 = 0; execbuf.flags = I915_EXEC_HANDLE_LUT | I915_EXEC_NO_RELOC | I915_EXEC_RENDER; execbuf.rsvd1 = device->context_id; execbuf.rsvd2 = 0; result = anv_device_execbuf(device, &execbuf, exec_bos); if (result != VK_SUCCESS) goto fail; timeout = INT64_MAX; ret = anv_gem_wait(device, bo.gem_handle, &timeout); if (ret != 0) { /* We don't know the real error. */ result = vk_errorf(VK_ERROR_DEVICE_LOST, "execbuf2 failed: %m"); goto fail; } fail: anv_bo_pool_free(&device->batch_bo_pool, &bo); return result; } VkResult anv_CreateDevice( VkPhysicalDevice physicalDevice, const VkDeviceCreateInfo* pCreateInfo, const VkAllocationCallbacks* pAllocator, VkDevice* pDevice) { ANV_FROM_HANDLE(anv_physical_device, physical_device, physicalDevice); VkResult result; struct anv_device *device; assert(pCreateInfo->sType == VK_STRUCTURE_TYPE_DEVICE_CREATE_INFO); for (uint32_t i = 0; i < pCreateInfo->enabledExtensionCount; i++) { bool found = false; for (uint32_t j = 0; j < ARRAY_SIZE(device_extensions); j++) { if (strcmp(pCreateInfo->ppEnabledExtensionNames[i], device_extensions[j].extensionName) == 0) { found = true; break; } } if (!found) return vk_error(VK_ERROR_EXTENSION_NOT_PRESENT); } device = vk_alloc2(&physical_device->instance->alloc, pAllocator, sizeof(*device), 8, VK_SYSTEM_ALLOCATION_SCOPE_DEVICE); if (!device) return vk_error(VK_ERROR_OUT_OF_HOST_MEMORY); device->_loader_data.loaderMagic = ICD_LOADER_MAGIC; device->instance = physical_device->instance; device->chipset_id = physical_device->chipset_id; if (pAllocator) device->alloc = *pAllocator; else device->alloc = physical_device->instance->alloc; /* XXX(chadv): Can we dup() physicalDevice->fd here? */ device->fd = open(physical_device->path, O_RDWR | O_CLOEXEC); if (device->fd == -1) { result = vk_error(VK_ERROR_INITIALIZATION_FAILED); goto fail_device; } device->context_id = anv_gem_create_context(device); if (device->context_id == -1) { result = vk_error(VK_ERROR_INITIALIZATION_FAILED); goto fail_fd; } device->info = physical_device->info; device->isl_dev = physical_device->isl_dev; /* On Broadwell and later, we can use batch chaining to more efficiently * implement growing command buffers. Prior to Haswell, the kernel * command parser gets in the way and we have to fall back to growing * the batch. */ device->can_chain_batches = device->info.gen >= 8; device->robust_buffer_access = pCreateInfo->pEnabledFeatures && pCreateInfo->pEnabledFeatures->robustBufferAccess; pthread_mutex_init(&device->mutex, NULL); anv_bo_pool_init(&device->batch_bo_pool, device); anv_block_pool_init(&device->dynamic_state_block_pool, device, 16384); anv_state_pool_init(&device->dynamic_state_pool, &device->dynamic_state_block_pool); anv_block_pool_init(&device->instruction_block_pool, device, 128 * 1024); anv_state_pool_init(&device->instruction_state_pool, &device->instruction_block_pool); anv_block_pool_init(&device->surface_state_block_pool, device, 4096); anv_state_pool_init(&device->surface_state_pool, &device->surface_state_block_pool); anv_bo_init_new(&device->workaround_bo, device, 1024); anv_scratch_pool_init(device, &device->scratch_pool); anv_queue_init(device, &device->queue); switch (device->info.gen) { case 7: if (!device->info.is_haswell) result = gen7_init_device_state(device); else result = gen75_init_device_state(device); break; case 8: result = gen8_init_device_state(device); break; case 9: result = gen9_init_device_state(device); break; default: /* Shouldn't get here as we don't create physical devices for any other * gens. */ unreachable("unhandled gen"); } if (result != VK_SUCCESS) goto fail_fd; anv_device_init_blorp(device); anv_device_init_border_colors(device); *pDevice = anv_device_to_handle(device); return VK_SUCCESS; fail_fd: close(device->fd); fail_device: vk_free(&device->alloc, device); return result; } void anv_DestroyDevice( VkDevice _device, const VkAllocationCallbacks* pAllocator) { ANV_FROM_HANDLE(anv_device, device, _device); anv_queue_finish(&device->queue); anv_device_finish_blorp(device); #ifdef HAVE_VALGRIND /* We only need to free these to prevent valgrind errors. The backing * BO will go away in a couple of lines so we don't actually leak. */ anv_state_pool_free(&device->dynamic_state_pool, device->border_colors); #endif anv_gem_munmap(device->workaround_bo.map, device->workaround_bo.size); anv_gem_close(device, device->workaround_bo.gem_handle); anv_bo_pool_finish(&device->batch_bo_pool); anv_state_pool_finish(&device->dynamic_state_pool); anv_block_pool_finish(&device->dynamic_state_block_pool); anv_state_pool_finish(&device->instruction_state_pool); anv_block_pool_finish(&device->instruction_block_pool); anv_state_pool_finish(&device->surface_state_pool); anv_block_pool_finish(&device->surface_state_block_pool); anv_scratch_pool_finish(device, &device->scratch_pool); close(device->fd); pthread_mutex_destroy(&device->mutex); vk_free(&device->alloc, device); } VkResult anv_EnumerateInstanceExtensionProperties( const char* pLayerName, uint32_t* pPropertyCount, VkExtensionProperties* pProperties) { if (pProperties == NULL) { *pPropertyCount = ARRAY_SIZE(global_extensions); return VK_SUCCESS; } assert(*pPropertyCount >= ARRAY_SIZE(global_extensions)); *pPropertyCount = ARRAY_SIZE(global_extensions); memcpy(pProperties, global_extensions, sizeof(global_extensions)); return VK_SUCCESS; } VkResult anv_EnumerateDeviceExtensionProperties( VkPhysicalDevice physicalDevice, const char* pLayerName, uint32_t* pPropertyCount, VkExtensionProperties* pProperties) { if (pProperties == NULL) { *pPropertyCount = ARRAY_SIZE(device_extensions); return VK_SUCCESS; } assert(*pPropertyCount >= ARRAY_SIZE(device_extensions)); *pPropertyCount = ARRAY_SIZE(device_extensions); memcpy(pProperties, device_extensions, sizeof(device_extensions)); return VK_SUCCESS; } VkResult anv_EnumerateInstanceLayerProperties( uint32_t* pPropertyCount, VkLayerProperties* pProperties) { if (pProperties == NULL) { *pPropertyCount = 0; return VK_SUCCESS; } /* None supported at this time */ return vk_error(VK_ERROR_LAYER_NOT_PRESENT); } VkResult anv_EnumerateDeviceLayerProperties( VkPhysicalDevice physicalDevice, uint32_t* pPropertyCount, VkLayerProperties* pProperties) { if (pProperties == NULL) { *pPropertyCount = 0; return VK_SUCCESS; } /* None supported at this time */ return vk_error(VK_ERROR_LAYER_NOT_PRESENT); } void anv_GetDeviceQueue( VkDevice _device, uint32_t queueNodeIndex, uint32_t queueIndex, VkQueue* pQueue) { ANV_FROM_HANDLE(anv_device, device, _device); assert(queueIndex == 0); *pQueue = anv_queue_to_handle(&device->queue); } VkResult anv_device_execbuf(struct anv_device *device, struct drm_i915_gem_execbuffer2 *execbuf, struct anv_bo **execbuf_bos) { int ret = anv_gem_execbuffer(device, execbuf); if (ret != 0) { /* We don't know the real error. */ return vk_errorf(VK_ERROR_DEVICE_LOST, "execbuf2 failed: %m"); } struct drm_i915_gem_exec_object2 *objects = (void *)execbuf->buffers_ptr; for (uint32_t k = 0; k < execbuf->buffer_count; k++) execbuf_bos[k]->offset = objects[k].offset; return VK_SUCCESS; } VkResult anv_QueueSubmit( VkQueue _queue, uint32_t submitCount, const VkSubmitInfo* pSubmits, VkFence _fence) { ANV_FROM_HANDLE(anv_queue, queue, _queue); ANV_FROM_HANDLE(anv_fence, fence, _fence); struct anv_device *device = queue->device; VkResult result = VK_SUCCESS; /* We lock around QueueSubmit for two main reasons: * * 1) When a block pool is resized, we create a new gem handle with a * different size and, in the case of surface states, possibly a * different center offset but we re-use the same anv_bo struct when * we do so. If this happens in the middle of setting up an execbuf, * we could end up with our list of BOs out of sync with our list of * gem handles. * * 2) The algorithm we use for building the list of unique buffers isn't * thread-safe. While the client is supposed to syncronize around * QueueSubmit, this would be extremely difficult to debug if it ever * came up in the wild due to a broken app. It's better to play it * safe and just lock around QueueSubmit. * * Since the only other things that ever take the device lock such as block * pool resize only rarely happen, this will almost never be contended so * taking a lock isn't really an expensive operation in this case. */ pthread_mutex_lock(&device->mutex); for (uint32_t i = 0; i < submitCount; i++) { for (uint32_t j = 0; j < pSubmits[i].commandBufferCount; j++) { ANV_FROM_HANDLE(anv_cmd_buffer, cmd_buffer, pSubmits[i].pCommandBuffers[j]); assert(cmd_buffer->level == VK_COMMAND_BUFFER_LEVEL_PRIMARY); result = anv_cmd_buffer_execbuf(device, cmd_buffer); if (result != VK_SUCCESS) goto out; } } if (fence) { struct anv_bo *fence_bo = &fence->bo; result = anv_device_execbuf(device, &fence->execbuf, &fence_bo); if (result != VK_SUCCESS) goto out; } out: pthread_mutex_unlock(&device->mutex); return result; } VkResult anv_QueueWaitIdle( VkQueue _queue) { ANV_FROM_HANDLE(anv_queue, queue, _queue); return anv_DeviceWaitIdle(anv_device_to_handle(queue->device)); } VkResult anv_DeviceWaitIdle( VkDevice _device) { ANV_FROM_HANDLE(anv_device, device, _device); struct anv_batch batch; uint32_t cmds[8]; batch.start = batch.next = cmds; batch.end = (void *) cmds + sizeof(cmds); anv_batch_emit(&batch, GEN7_MI_BATCH_BUFFER_END, bbe); anv_batch_emit(&batch, GEN7_MI_NOOP, noop); return anv_device_submit_simple_batch(device, &batch); } VkResult anv_bo_init_new(struct anv_bo *bo, struct anv_device *device, uint64_t size) { uint32_t gem_handle = anv_gem_create(device, size); if (!gem_handle) return vk_error(VK_ERROR_OUT_OF_DEVICE_MEMORY); anv_bo_init(bo, gem_handle, size); return VK_SUCCESS; } VkResult anv_AllocateMemory( VkDevice _device, const VkMemoryAllocateInfo* pAllocateInfo, const VkAllocationCallbacks* pAllocator, VkDeviceMemory* pMem) { ANV_FROM_HANDLE(anv_device, device, _device); struct anv_device_memory *mem; VkResult result; assert(pAllocateInfo->sType == VK_STRUCTURE_TYPE_MEMORY_ALLOCATE_INFO); if (pAllocateInfo->allocationSize == 0) { /* Apparently, this is allowed */ *pMem = VK_NULL_HANDLE; return VK_SUCCESS; } /* We support exactly one memory heap. */ assert(pAllocateInfo->memoryTypeIndex == 0 || (!device->info.has_llc && pAllocateInfo->memoryTypeIndex < 2)); /* FINISHME: Fail if allocation request exceeds heap size. */ mem = vk_alloc2(&device->alloc, pAllocator, sizeof(*mem), 8, VK_SYSTEM_ALLOCATION_SCOPE_OBJECT); if (mem == NULL) return vk_error(VK_ERROR_OUT_OF_HOST_MEMORY); /* The kernel is going to give us whole pages anyway */ uint64_t alloc_size = align_u64(pAllocateInfo->allocationSize, 4096); result = anv_bo_init_new(&mem->bo, device, alloc_size); if (result != VK_SUCCESS) goto fail; mem->type_index = pAllocateInfo->memoryTypeIndex; *pMem = anv_device_memory_to_handle(mem); return VK_SUCCESS; fail: vk_free2(&device->alloc, pAllocator, mem); return result; } void anv_FreeMemory( VkDevice _device, VkDeviceMemory _mem, const VkAllocationCallbacks* pAllocator) { ANV_FROM_HANDLE(anv_device, device, _device); ANV_FROM_HANDLE(anv_device_memory, mem, _mem); if (mem == NULL) return; if (mem->bo.map) anv_gem_munmap(mem->bo.map, mem->bo.size); if (mem->bo.gem_handle != 0) anv_gem_close(device, mem->bo.gem_handle); vk_free2(&device->alloc, pAllocator, mem); } VkResult anv_MapMemory( VkDevice _device, VkDeviceMemory _memory, VkDeviceSize offset, VkDeviceSize size, VkMemoryMapFlags flags, void** ppData) { ANV_FROM_HANDLE(anv_device, device, _device); ANV_FROM_HANDLE(anv_device_memory, mem, _memory); if (mem == NULL) { *ppData = NULL; return VK_SUCCESS; } if (size == VK_WHOLE_SIZE) size = mem->bo.size - offset; /* FIXME: Is this supposed to be thread safe? Since vkUnmapMemory() only * takes a VkDeviceMemory pointer, it seems like only one map of the memory * at a time is valid. We could just mmap up front and return an offset * pointer here, but that may exhaust virtual memory on 32 bit * userspace. */ uint32_t gem_flags = 0; if (!device->info.has_llc && mem->type_index == 0) gem_flags |= I915_MMAP_WC; /* GEM will fail to map if the offset isn't 4k-aligned. Round down. */ uint64_t map_offset = offset & ~4095ull; assert(offset >= map_offset); uint64_t map_size = (offset + size) - map_offset; /* Let's map whole pages */ map_size = align_u64(map_size, 4096); mem->map = anv_gem_mmap(device, mem->bo.gem_handle, map_offset, map_size, gem_flags); mem->map_size = map_size; *ppData = mem->map + (offset - map_offset); return VK_SUCCESS; } void anv_UnmapMemory( VkDevice _device, VkDeviceMemory _memory) { ANV_FROM_HANDLE(anv_device_memory, mem, _memory); if (mem == NULL) return; anv_gem_munmap(mem->map, mem->map_size); } static void clflush_mapped_ranges(struct anv_device *device, uint32_t count, const VkMappedMemoryRange *ranges) { for (uint32_t i = 0; i < count; i++) { ANV_FROM_HANDLE(anv_device_memory, mem, ranges[i].memory); void *p = mem->map + (ranges[i].offset & ~CACHELINE_MASK); void *end; if (ranges[i].offset + ranges[i].size > mem->map_size) end = mem->map + mem->map_size; else end = mem->map + ranges[i].offset + ranges[i].size; while (p < end) { __builtin_ia32_clflush(p); p += CACHELINE_SIZE; } } } VkResult anv_FlushMappedMemoryRanges( VkDevice _device, uint32_t memoryRangeCount, const VkMappedMemoryRange* pMemoryRanges) { ANV_FROM_HANDLE(anv_device, device, _device); if (device->info.has_llc) return VK_SUCCESS; /* Make sure the writes we're flushing have landed. */ __builtin_ia32_mfence(); clflush_mapped_ranges(device, memoryRangeCount, pMemoryRanges); return VK_SUCCESS; } VkResult anv_InvalidateMappedMemoryRanges( VkDevice _device, uint32_t memoryRangeCount, const VkMappedMemoryRange* pMemoryRanges) { ANV_FROM_HANDLE(anv_device, device, _device); if (device->info.has_llc) return VK_SUCCESS; clflush_mapped_ranges(device, memoryRangeCount, pMemoryRanges); /* Make sure no reads get moved up above the invalidate. */ __builtin_ia32_mfence(); return VK_SUCCESS; } void anv_GetBufferMemoryRequirements( VkDevice device, VkBuffer _buffer, VkMemoryRequirements* pMemoryRequirements) { ANV_FROM_HANDLE(anv_buffer, buffer, _buffer); /* The Vulkan spec (git aaed022) says: * * memoryTypeBits is a bitfield and contains one bit set for every * supported memory type for the resource. The bit `1<memoryTypeBits = 1; pMemoryRequirements->size = buffer->size; pMemoryRequirements->alignment = 16; } void anv_GetImageMemoryRequirements( VkDevice device, VkImage _image, VkMemoryRequirements* pMemoryRequirements) { ANV_FROM_HANDLE(anv_image, image, _image); /* The Vulkan spec (git aaed022) says: * * memoryTypeBits is a bitfield and contains one bit set for every * supported memory type for the resource. The bit `1<memoryTypeBits = 1; pMemoryRequirements->size = image->size; pMemoryRequirements->alignment = image->alignment; } void anv_GetImageSparseMemoryRequirements( VkDevice device, VkImage image, uint32_t* pSparseMemoryRequirementCount, VkSparseImageMemoryRequirements* pSparseMemoryRequirements) { stub(); } void anv_GetDeviceMemoryCommitment( VkDevice device, VkDeviceMemory memory, VkDeviceSize* pCommittedMemoryInBytes) { *pCommittedMemoryInBytes = 0; } VkResult anv_BindBufferMemory( VkDevice device, VkBuffer _buffer, VkDeviceMemory _memory, VkDeviceSize memoryOffset) { ANV_FROM_HANDLE(anv_device_memory, mem, _memory); ANV_FROM_HANDLE(anv_buffer, buffer, _buffer); if (mem) { buffer->bo = &mem->bo; buffer->offset = memoryOffset; } else { buffer->bo = NULL; buffer->offset = 0; } return VK_SUCCESS; } VkResult anv_QueueBindSparse( VkQueue queue, uint32_t bindInfoCount, const VkBindSparseInfo* pBindInfo, VkFence fence) { stub_return(VK_ERROR_INCOMPATIBLE_DRIVER); } VkResult anv_CreateFence( VkDevice _device, const VkFenceCreateInfo* pCreateInfo, const VkAllocationCallbacks* pAllocator, VkFence* pFence) { ANV_FROM_HANDLE(anv_device, device, _device); struct anv_bo fence_bo; struct anv_fence *fence; struct anv_batch batch; VkResult result; assert(pCreateInfo->sType == VK_STRUCTURE_TYPE_FENCE_CREATE_INFO); result = anv_bo_pool_alloc(&device->batch_bo_pool, &fence_bo, 4096); if (result != VK_SUCCESS) return result; /* Fences are small. Just store the CPU data structure in the BO. */ fence = fence_bo.map; fence->bo = fence_bo; /* Place the batch after the CPU data but on its own cache line. */ const uint32_t batch_offset = align_u32(sizeof(*fence), CACHELINE_SIZE); batch.next = batch.start = fence->bo.map + batch_offset; batch.end = fence->bo.map + fence->bo.size; anv_batch_emit(&batch, GEN7_MI_BATCH_BUFFER_END, bbe); anv_batch_emit(&batch, GEN7_MI_NOOP, noop); if (!device->info.has_llc) { assert(((uintptr_t) batch.start & CACHELINE_MASK) == 0); assert(batch.next - batch.start <= CACHELINE_SIZE); __builtin_ia32_mfence(); __builtin_ia32_clflush(batch.start); } fence->exec2_objects[0].handle = fence->bo.gem_handle; fence->exec2_objects[0].relocation_count = 0; fence->exec2_objects[0].relocs_ptr = 0; fence->exec2_objects[0].alignment = 0; fence->exec2_objects[0].offset = fence->bo.offset; fence->exec2_objects[0].flags = 0; fence->exec2_objects[0].rsvd1 = 0; fence->exec2_objects[0].rsvd2 = 0; fence->execbuf.buffers_ptr = (uintptr_t) fence->exec2_objects; fence->execbuf.buffer_count = 1; fence->execbuf.batch_start_offset = batch.start - fence->bo.map; fence->execbuf.batch_len = batch.next - batch.start; fence->execbuf.cliprects_ptr = 0; fence->execbuf.num_cliprects = 0; fence->execbuf.DR1 = 0; fence->execbuf.DR4 = 0; fence->execbuf.flags = I915_EXEC_HANDLE_LUT | I915_EXEC_NO_RELOC | I915_EXEC_RENDER; fence->execbuf.rsvd1 = device->context_id; fence->execbuf.rsvd2 = 0; fence->ready = false; *pFence = anv_fence_to_handle(fence); return VK_SUCCESS; } void anv_DestroyFence( VkDevice _device, VkFence _fence, const VkAllocationCallbacks* pAllocator) { ANV_FROM_HANDLE(anv_device, device, _device); ANV_FROM_HANDLE(anv_fence, fence, _fence); assert(fence->bo.map == fence); anv_bo_pool_free(&device->batch_bo_pool, &fence->bo); } VkResult anv_ResetFences( VkDevice _device, uint32_t fenceCount, const VkFence* pFences) { for (uint32_t i = 0; i < fenceCount; i++) { ANV_FROM_HANDLE(anv_fence, fence, pFences[i]); fence->ready = false; } return VK_SUCCESS; } VkResult anv_GetFenceStatus( VkDevice _device, VkFence _fence) { ANV_FROM_HANDLE(anv_device, device, _device); ANV_FROM_HANDLE(anv_fence, fence, _fence); int64_t t = 0; int ret; if (fence->ready) return VK_SUCCESS; ret = anv_gem_wait(device, fence->bo.gem_handle, &t); if (ret == 0) { fence->ready = true; return VK_SUCCESS; } return VK_NOT_READY; } VkResult anv_WaitForFences( VkDevice _device, uint32_t fenceCount, const VkFence* pFences, VkBool32 waitAll, uint64_t timeout) { ANV_FROM_HANDLE(anv_device, device, _device); /* DRM_IOCTL_I915_GEM_WAIT uses a signed 64 bit timeout and is supposed * to block indefinitely timeouts <= 0. Unfortunately, this was broken * for a couple of kernel releases. Since there's no way to know * whether or not the kernel we're using is one of the broken ones, the * best we can do is to clamp the timeout to INT64_MAX. This limits the * maximum timeout from 584 years to 292 years - likely not a big deal. */ if (timeout > INT64_MAX) timeout = INT64_MAX; int64_t t = timeout; /* FIXME: handle !waitAll */ for (uint32_t i = 0; i < fenceCount; i++) { ANV_FROM_HANDLE(anv_fence, fence, pFences[i]); int ret = anv_gem_wait(device, fence->bo.gem_handle, &t); if (ret == -1 && errno == ETIME) { return VK_TIMEOUT; } else if (ret == -1) { /* We don't know the real error. */ return vk_errorf(VK_ERROR_OUT_OF_DEVICE_MEMORY, "gem wait failed: %m"); } } return VK_SUCCESS; } // Queue semaphore functions VkResult anv_CreateSemaphore( VkDevice device, const VkSemaphoreCreateInfo* pCreateInfo, const VkAllocationCallbacks* pAllocator, VkSemaphore* pSemaphore) { /* The DRM execbuffer ioctl always execute in-oder, even between different * rings. As such, there's nothing to do for the user space semaphore. */ *pSemaphore = (VkSemaphore)1; return VK_SUCCESS; } void anv_DestroySemaphore( VkDevice device, VkSemaphore semaphore, const VkAllocationCallbacks* pAllocator) { } // Event functions VkResult anv_CreateEvent( VkDevice _device, const VkEventCreateInfo* pCreateInfo, const VkAllocationCallbacks* pAllocator, VkEvent* pEvent) { ANV_FROM_HANDLE(anv_device, device, _device); struct anv_state state; struct anv_event *event; assert(pCreateInfo->sType == VK_STRUCTURE_TYPE_EVENT_CREATE_INFO); state = anv_state_pool_alloc(&device->dynamic_state_pool, sizeof(*event), 8); event = state.map; event->state = state; event->semaphore = VK_EVENT_RESET; if (!device->info.has_llc) { /* Make sure the writes we're flushing have landed. */ __builtin_ia32_mfence(); __builtin_ia32_clflush(event); } *pEvent = anv_event_to_handle(event); return VK_SUCCESS; } void anv_DestroyEvent( VkDevice _device, VkEvent _event, const VkAllocationCallbacks* pAllocator) { ANV_FROM_HANDLE(anv_device, device, _device); ANV_FROM_HANDLE(anv_event, event, _event); anv_state_pool_free(&device->dynamic_state_pool, event->state); } VkResult anv_GetEventStatus( VkDevice _device, VkEvent _event) { ANV_FROM_HANDLE(anv_device, device, _device); ANV_FROM_HANDLE(anv_event, event, _event); if (!device->info.has_llc) { /* Invalidate read cache before reading event written by GPU. */ __builtin_ia32_clflush(event); __builtin_ia32_mfence(); } return event->semaphore; } VkResult anv_SetEvent( VkDevice _device, VkEvent _event) { ANV_FROM_HANDLE(anv_device, device, _device); ANV_FROM_HANDLE(anv_event, event, _event); event->semaphore = VK_EVENT_SET; if (!device->info.has_llc) { /* Make sure the writes we're flushing have landed. */ __builtin_ia32_mfence(); __builtin_ia32_clflush(event); } return VK_SUCCESS; } VkResult anv_ResetEvent( VkDevice _device, VkEvent _event) { ANV_FROM_HANDLE(anv_device, device, _device); ANV_FROM_HANDLE(anv_event, event, _event); event->semaphore = VK_EVENT_RESET; if (!device->info.has_llc) { /* Make sure the writes we're flushing have landed. */ __builtin_ia32_mfence(); __builtin_ia32_clflush(event); } return VK_SUCCESS; } // Buffer functions VkResult anv_CreateBuffer( VkDevice _device, const VkBufferCreateInfo* pCreateInfo, const VkAllocationCallbacks* pAllocator, VkBuffer* pBuffer) { ANV_FROM_HANDLE(anv_device, device, _device); struct anv_buffer *buffer; assert(pCreateInfo->sType == VK_STRUCTURE_TYPE_BUFFER_CREATE_INFO); buffer = vk_alloc2(&device->alloc, pAllocator, sizeof(*buffer), 8, VK_SYSTEM_ALLOCATION_SCOPE_OBJECT); if (buffer == NULL) return vk_error(VK_ERROR_OUT_OF_HOST_MEMORY); buffer->size = pCreateInfo->size; buffer->usage = pCreateInfo->usage; buffer->bo = NULL; buffer->offset = 0; *pBuffer = anv_buffer_to_handle(buffer); return VK_SUCCESS; } void anv_DestroyBuffer( VkDevice _device, VkBuffer _buffer, const VkAllocationCallbacks* pAllocator) { ANV_FROM_HANDLE(anv_device, device, _device); ANV_FROM_HANDLE(anv_buffer, buffer, _buffer); vk_free2(&device->alloc, pAllocator, buffer); } void anv_fill_buffer_surface_state(struct anv_device *device, struct anv_state state, enum isl_format format, uint32_t offset, uint32_t range, uint32_t stride) { isl_buffer_fill_state(&device->isl_dev, state.map, .address = offset, .mocs = device->default_mocs, .size = range, .format = format, .stride = stride); if (!device->info.has_llc) anv_state_clflush(state); } void anv_DestroySampler( VkDevice _device, VkSampler _sampler, const VkAllocationCallbacks* pAllocator) { ANV_FROM_HANDLE(anv_device, device, _device); ANV_FROM_HANDLE(anv_sampler, sampler, _sampler); vk_free2(&device->alloc, pAllocator, sampler); } VkResult anv_CreateFramebuffer( VkDevice _device, const VkFramebufferCreateInfo* pCreateInfo, const VkAllocationCallbacks* pAllocator, VkFramebuffer* pFramebuffer) { ANV_FROM_HANDLE(anv_device, device, _device); struct anv_framebuffer *framebuffer; assert(pCreateInfo->sType == VK_STRUCTURE_TYPE_FRAMEBUFFER_CREATE_INFO); size_t size = sizeof(*framebuffer) + sizeof(struct anv_image_view *) * pCreateInfo->attachmentCount; framebuffer = vk_alloc2(&device->alloc, pAllocator, size, 8, VK_SYSTEM_ALLOCATION_SCOPE_OBJECT); if (framebuffer == NULL) return vk_error(VK_ERROR_OUT_OF_HOST_MEMORY); framebuffer->attachment_count = pCreateInfo->attachmentCount; for (uint32_t i = 0; i < pCreateInfo->attachmentCount; i++) { VkImageView _iview = pCreateInfo->pAttachments[i]; framebuffer->attachments[i] = anv_image_view_from_handle(_iview); } framebuffer->width = pCreateInfo->width; framebuffer->height = pCreateInfo->height; framebuffer->layers = pCreateInfo->layers; *pFramebuffer = anv_framebuffer_to_handle(framebuffer); return VK_SUCCESS; } void anv_DestroyFramebuffer( VkDevice _device, VkFramebuffer _fb, const VkAllocationCallbacks* pAllocator) { ANV_FROM_HANDLE(anv_device, device, _device); ANV_FROM_HANDLE(anv_framebuffer, fb, _fb); vk_free2(&device->alloc, pAllocator, fb); }