/* Copyright (c) 2015-2016 The Khronos Group Inc. * Copyright (c) 2015-2016 Valve Corporation * Copyright (c) 2015-2016 LunarG, Inc. * Copyright (C) 2015-2016 Google Inc. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * Author: Cody Northrop * Author: Michael Lentine * Author: Tobin Ehlis * Author: Chia-I Wu * Author: Chris Forbes * Author: Mark Lobodzinski * Author: Ian Elliott */ // Allow use of STL min and max functions in Windows #define NOMINMAX #include #include #include #include #include #include #include #include //#include #include #include #include #include #include #include "vk_loader_platform.h" #include "vk_dispatch_table_helper.h" #include "vk_struct_string_helper_cpp.h" #if defined(__GNUC__) #pragma GCC diagnostic ignored "-Wwrite-strings" #endif #if defined(__GNUC__) #pragma GCC diagnostic warning "-Wwrite-strings" #endif #include "vk_struct_size_helper.h" #include "core_validation.h" #include "vk_layer_table.h" #include "vk_layer_data.h" #include "vk_layer_extension_utils.h" #include "vk_layer_utils.h" #include "spirv-tools/libspirv.h" #if defined __ANDROID__ #include #define LOGCONSOLE(...) ((void)__android_log_print(ANDROID_LOG_INFO, "DS", __VA_ARGS__)) #else #define LOGCONSOLE(...) \ { \ printf(__VA_ARGS__); \ printf("\n"); \ } #endif // This intentionally includes a cpp file #include "vk_safe_struct.cpp" using namespace std; namespace core_validation { using std::unordered_map; using std::unordered_set; // WSI Image Objects bypass usual Image Object creation methods. A special Memory // Object value will be used to identify them internally. static const VkDeviceMemory MEMTRACKER_SWAP_CHAIN_IMAGE_KEY = (VkDeviceMemory)(-1); // 2nd special memory handle used to flag object as unbound from memory static const VkDeviceMemory MEMORY_UNBOUND = VkDeviceMemory(~((uint64_t)(0)) - 1); struct devExts { bool wsi_enabled; bool wsi_display_swapchain_enabled; unordered_map> swapchainMap; unordered_map imageToSwapchainMap; }; // fwd decls struct shader_module; struct instance_layer_data { VkInstance instance = VK_NULL_HANDLE; debug_report_data *report_data = nullptr; std::vector logging_callback; VkLayerInstanceDispatchTable dispatch_table; CALL_STATE vkEnumeratePhysicalDevicesState = UNCALLED; uint32_t physical_devices_count = 0; CHECK_DISABLED disabled = {}; unordered_map physical_device_map; unordered_map surface_map; bool surfaceExtensionEnabled = false; bool displayExtensionEnabled = false; #ifdef VK_USE_PLATFORM_ANDROID_KHR bool androidSurfaceExtensionEnabled = false; #endif #ifdef VK_USE_PLATFORM_MIR_KHR bool mirSurfaceExtensionEnabled = false; #endif #ifdef VK_USE_PLATFORM_WAYLAND_KHR bool waylandSurfaceExtensionEnabled = false; #endif #ifdef VK_USE_PLATFORM_WIN32_KHR bool win32SurfaceExtensionEnabled = false; #endif #ifdef VK_USE_PLATFORM_XCB_KHR bool xcbSurfaceExtensionEnabled = false; #endif #ifdef VK_USE_PLATFORM_XLIB_KHR bool xlibSurfaceExtensionEnabled = false; #endif }; struct layer_data { debug_report_data *report_data = nullptr; VkLayerDispatchTable dispatch_table; devExts device_extensions = {}; unordered_set queues; // All queues under given device // Global set of all cmdBuffers that are inFlight on this device unordered_set globalInFlightCmdBuffers; // Layer specific data unordered_map> samplerMap; unordered_map> imageViewMap; unordered_map> imageMap; unordered_map> bufferViewMap; unordered_map> bufferMap; unordered_map pipelineMap; unordered_map commandPoolMap; unordered_map descriptorPoolMap; unordered_map setMap; unordered_map descriptorSetLayoutMap; unordered_map pipelineLayoutMap; unordered_map> memObjMap; unordered_map fenceMap; unordered_map queueMap; unordered_map eventMap; unordered_map queryToStateMap; unordered_map queryPoolMap; unordered_map semaphoreMap; unordered_map commandBufferMap; unordered_map> frameBufferMap; unordered_map> imageSubresourceMap; unordered_map imageLayoutMap; unordered_map> renderPassMap; unordered_map> shaderModuleMap; VkDevice device = VK_NULL_HANDLE; VkPhysicalDevice physical_device = VK_NULL_HANDLE; instance_layer_data *instance_data = nullptr; // from device to enclosing instance VkPhysicalDeviceFeatures enabled_features = {}; // Device specific data PHYS_DEV_PROPERTIES_NODE phys_dev_properties = {}; VkPhysicalDeviceMemoryProperties phys_dev_mem_props = {}; }; // TODO : Do we need to guard access to layer_data_map w/ lock? static unordered_map layer_data_map; static unordered_map instance_layer_data_map; static const VkLayerProperties global_layer = { "VK_LAYER_LUNARG_core_validation", VK_LAYER_API_VERSION, 1, "LunarG Validation Layer", }; template void ValidateLayerOrdering(const TCreateInfo &createInfo) { bool foundLayer = false; for (uint32_t i = 0; i < createInfo.enabledLayerCount; ++i) { if (!strcmp(createInfo.ppEnabledLayerNames[i], global_layer.layerName)) { foundLayer = true; } // This has to be logged to console as we don't have a callback at this point. if (!foundLayer && !strcmp(createInfo.ppEnabledLayerNames[0], "VK_LAYER_GOOGLE_unique_objects")) { LOGCONSOLE("Cannot activate layer VK_LAYER_GOOGLE_unique_objects prior to activating %s.", global_layer.layerName); } } } // Code imported from shader_checker static void build_def_index(shader_module *); // A forward iterator over spirv instructions. Provides easy access to len, opcode, and content words // without the caller needing to care too much about the physical SPIRV module layout. struct spirv_inst_iter { std::vector::const_iterator zero; std::vector::const_iterator it; uint32_t len() { auto result = *it >> 16; assert(result > 0); return result; } uint32_t opcode() { return *it & 0x0ffffu; } uint32_t const &word(unsigned n) { assert(n < len()); return it[n]; } uint32_t offset() { return (uint32_t)(it - zero); } spirv_inst_iter() {} spirv_inst_iter(std::vector::const_iterator zero, std::vector::const_iterator it) : zero(zero), it(it) {} bool operator==(spirv_inst_iter const &other) { return it == other.it; } bool operator!=(spirv_inst_iter const &other) { return it != other.it; } spirv_inst_iter operator++(int) { /* x++ */ spirv_inst_iter ii = *this; it += len(); return ii; } spirv_inst_iter operator++() { /* ++x; */ it += len(); return *this; } /* The iterator and the value are the same thing. */ spirv_inst_iter &operator*() { return *this; } spirv_inst_iter const &operator*() const { return *this; } }; struct shader_module { /* the spirv image itself */ vector words; /* a mapping of to the first word of its def. this is useful because walking type * trees, constant expressions, etc requires jumping all over the instruction stream. */ unordered_map def_index; shader_module(VkShaderModuleCreateInfo const *pCreateInfo) : words((uint32_t *)pCreateInfo->pCode, (uint32_t *)pCreateInfo->pCode + pCreateInfo->codeSize / sizeof(uint32_t)), def_index() { build_def_index(this); } /* expose begin() / end() to enable range-based for */ spirv_inst_iter begin() const { return spirv_inst_iter(words.begin(), words.begin() + 5); } /* first insn */ spirv_inst_iter end() const { return spirv_inst_iter(words.begin(), words.end()); } /* just past last insn */ /* given an offset into the module, produce an iterator there. */ spirv_inst_iter at(unsigned offset) const { return spirv_inst_iter(words.begin(), words.begin() + offset); } /* gets an iterator to the definition of an id */ spirv_inst_iter get_def(unsigned id) const { auto it = def_index.find(id); if (it == def_index.end()) { return end(); } return at(it->second); } }; // TODO : This can be much smarter, using separate locks for separate global data static std::mutex global_lock; // Return IMAGE_VIEW_STATE ptr for specified imageView or else NULL IMAGE_VIEW_STATE *getImageViewState(const layer_data *dev_data, VkImageView image_view) { auto iv_it = dev_data->imageViewMap.find(image_view); if (iv_it == dev_data->imageViewMap.end()) { return nullptr; } return iv_it->second.get(); } // Return sampler node ptr for specified sampler or else NULL SAMPLER_STATE *getSamplerState(const layer_data *dev_data, VkSampler sampler) { auto sampler_it = dev_data->samplerMap.find(sampler); if (sampler_it == dev_data->samplerMap.end()) { return nullptr; } return sampler_it->second.get(); } // Return image state ptr for specified image or else NULL IMAGE_STATE *getImageState(const layer_data *dev_data, VkImage image) { auto img_it = dev_data->imageMap.find(image); if (img_it == dev_data->imageMap.end()) { return nullptr; } return img_it->second.get(); } // Return buffer state ptr for specified buffer or else NULL BUFFER_STATE *getBufferState(const layer_data *dev_data, VkBuffer buffer) { auto buff_it = dev_data->bufferMap.find(buffer); if (buff_it == dev_data->bufferMap.end()) { return nullptr; } return buff_it->second.get(); } // Return swapchain node for specified swapchain or else NULL SWAPCHAIN_NODE *getSwapchainNode(const layer_data *dev_data, VkSwapchainKHR swapchain) { auto swp_it = dev_data->device_extensions.swapchainMap.find(swapchain); if (swp_it == dev_data->device_extensions.swapchainMap.end()) { return nullptr; } return swp_it->second.get(); } // Return swapchain for specified image or else NULL VkSwapchainKHR getSwapchainFromImage(const layer_data *dev_data, VkImage image) { auto img_it = dev_data->device_extensions.imageToSwapchainMap.find(image); if (img_it == dev_data->device_extensions.imageToSwapchainMap.end()) { return VK_NULL_HANDLE; } return img_it->second; } // Return buffer node ptr for specified buffer or else NULL BUFFER_VIEW_STATE *getBufferViewState(const layer_data *my_data, VkBufferView buffer_view) { auto bv_it = my_data->bufferViewMap.find(buffer_view); if (bv_it == my_data->bufferViewMap.end()) { return nullptr; } return bv_it->second.get(); } FENCE_NODE *getFenceNode(layer_data *dev_data, VkFence fence) { auto it = dev_data->fenceMap.find(fence); if (it == dev_data->fenceMap.end()) { return nullptr; } return &it->second; } EVENT_STATE *getEventNode(layer_data *dev_data, VkEvent event) { auto it = dev_data->eventMap.find(event); if (it == dev_data->eventMap.end()) { return nullptr; } return &it->second; } QUERY_POOL_NODE *getQueryPoolNode(layer_data *dev_data, VkQueryPool query_pool) { auto it = dev_data->queryPoolMap.find(query_pool); if (it == dev_data->queryPoolMap.end()) { return nullptr; } return &it->second; } QUEUE_NODE *getQueueNode(layer_data *dev_data, VkQueue queue) { auto it = dev_data->queueMap.find(queue); if (it == dev_data->queueMap.end()) { return nullptr; } return &it->second; } SEMAPHORE_NODE *getSemaphoreNode(layer_data *dev_data, VkSemaphore semaphore) { auto it = dev_data->semaphoreMap.find(semaphore); if (it == dev_data->semaphoreMap.end()) { return nullptr; } return &it->second; } COMMAND_POOL_NODE *getCommandPoolNode(layer_data *dev_data, VkCommandPool pool) { auto it = dev_data->commandPoolMap.find(pool); if (it == dev_data->commandPoolMap.end()) { return nullptr; } return &it->second; } PHYSICAL_DEVICE_STATE *getPhysicalDeviceState(instance_layer_data *instance_data, VkPhysicalDevice phys) { auto it = instance_data->physical_device_map.find(phys); if (it == instance_data->physical_device_map.end()) { return nullptr; } return &it->second; } SURFACE_STATE *getSurfaceState(instance_layer_data *instance_data, VkSurfaceKHR surface) { auto it = instance_data->surface_map.find(surface); if (it == instance_data->surface_map.end()) { return nullptr; } return &it->second; } // Return ptr to memory binding for given handle of specified type static BINDABLE *GetObjectMemBinding(layer_data *my_data, uint64_t handle, VkDebugReportObjectTypeEXT type) { switch (type) { case VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT: return getImageState(my_data, VkImage(handle)); case VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT: return getBufferState(my_data, VkBuffer(handle)); default: break; } return nullptr; } // prototype static GLOBAL_CB_NODE *getCBNode(layer_data const *, const VkCommandBuffer); // Helper function to validate correct usage bits set for buffers or images // Verify that (actual & desired) flags != 0 or, // if strict is true, verify that (actual & desired) flags == desired // In case of error, report it via dbg callbacks static bool validate_usage_flags(layer_data *my_data, VkFlags actual, VkFlags desired, VkBool32 strict, uint64_t obj_handle, VkDebugReportObjectTypeEXT obj_type, int32_t const msgCode, char const *ty_str, char const *func_name, char const *usage_str) { bool correct_usage = false; bool skip_call = false; if (strict) correct_usage = ((actual & desired) == desired); else correct_usage = ((actual & desired) != 0); if (!correct_usage) { if (msgCode == -1) { // TODO: Fix callers with msgCode == -1 to use correct validation checks. skip_call = log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, obj_type, obj_handle, __LINE__, MEMTRACK_INVALID_USAGE_FLAG, "MEM", "Invalid usage flag for %s 0x%" PRIxLEAST64 " used by %s. In this case, %s should have %s set during creation.", ty_str, obj_handle, func_name, ty_str, usage_str); } else { const char *valid_usage = (msgCode == -1) ? "" : validation_error_map[msgCode]; skip_call = log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, obj_type, obj_handle, __LINE__, msgCode, "MEM", "Invalid usage flag for %s 0x%" PRIxLEAST64 " used by %s. In this case, %s should have %s set during creation. %s", ty_str, obj_handle, func_name, ty_str, usage_str, valid_usage); } } return skip_call; } // Helper function to validate usage flags for buffers // For given buffer_state send actual vs. desired usage off to helper above where // an error will be flagged if usage is not correct static bool ValidateImageUsageFlags(layer_data *dev_data, IMAGE_STATE const *image_state, VkFlags desired, VkBool32 strict, int32_t const msgCode, char const *func_name, char const *usage_string) { return validate_usage_flags(dev_data, image_state->createInfo.usage, desired, strict, reinterpret_cast(image_state->image), VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, msgCode, "image", func_name, usage_string); } // Helper function to validate usage flags for buffers // For given buffer_state send actual vs. desired usage off to helper above where // an error will be flagged if usage is not correct static bool ValidateBufferUsageFlags(layer_data *dev_data, BUFFER_STATE const *buffer_state, VkFlags desired, VkBool32 strict, int32_t const msgCode, char const *func_name, char const *usage_string) { return validate_usage_flags(dev_data, buffer_state->createInfo.usage, desired, strict, reinterpret_cast(buffer_state->buffer), VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT, msgCode, "buffer", func_name, usage_string); } // Return ptr to info in map container containing mem, or NULL if not found // Calls to this function should be wrapped in mutex DEVICE_MEM_INFO *getMemObjInfo(const layer_data *dev_data, const VkDeviceMemory mem) { auto mem_it = dev_data->memObjMap.find(mem); if (mem_it == dev_data->memObjMap.end()) { return NULL; } return mem_it->second.get(); } static void add_mem_obj_info(layer_data *my_data, void *object, const VkDeviceMemory mem, const VkMemoryAllocateInfo *pAllocateInfo) { assert(object != NULL); my_data->memObjMap[mem] = unique_ptr(new DEVICE_MEM_INFO(object, mem, pAllocateInfo)); } // Helper function to print lowercase string of object type // TODO: Unify string helper functions, this should really come out of a string helper if not there already static const char *object_type_to_string(VkDebugReportObjectTypeEXT type) { switch (type) { case VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT: return "image"; case VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT: return "buffer"; case VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_VIEW_EXT: return "image view"; case VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_VIEW_EXT: return "buffer view"; case VK_DEBUG_REPORT_OBJECT_TYPE_SWAPCHAIN_KHR_EXT: return "swapchain"; case VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT: return "descriptor set"; case VK_DEBUG_REPORT_OBJECT_TYPE_FRAMEBUFFER_EXT: return "framebuffer"; case VK_DEBUG_REPORT_OBJECT_TYPE_EVENT_EXT: return "event"; case VK_DEBUG_REPORT_OBJECT_TYPE_QUERY_POOL_EXT: return "query pool"; case VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_POOL_EXT: return "descriptor pool"; case VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_POOL_EXT: return "command pool"; case VK_DEBUG_REPORT_OBJECT_TYPE_PIPELINE_EXT: return "pipeline"; case VK_DEBUG_REPORT_OBJECT_TYPE_SAMPLER_EXT: return "sampler"; case VK_DEBUG_REPORT_OBJECT_TYPE_RENDER_PASS_EXT: return "renderpass"; case VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT: return "device memory"; case VK_DEBUG_REPORT_OBJECT_TYPE_SEMAPHORE_EXT: return "semaphore"; default: return "unknown"; } } // For given bound_object_handle, bound to given mem allocation, verify that the range for the bound object is valid static bool ValidateMemoryIsValid(layer_data *dev_data, VkDeviceMemory mem, uint64_t bound_object_handle, VkDebugReportObjectTypeEXT type, const char *functionName) { DEVICE_MEM_INFO *mem_info = getMemObjInfo(dev_data, mem); if (mem_info) { if (!mem_info->bound_ranges[bound_object_handle].valid) { return log_msg(dev_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, reinterpret_cast(mem), __LINE__, MEMTRACK_INVALID_MEM_REGION, "MEM", "%s: Cannot read invalid region of memory allocation 0x%" PRIx64 " for bound %s object 0x%" PRIx64 ", please fill the memory before using.", functionName, reinterpret_cast(mem), object_type_to_string(type), bound_object_handle); } } return false; } // For given image_state // If mem is special swapchain key, then verify that image_state valid member is true // Else verify that the image's bound memory range is valid static bool ValidateImageMemoryIsValid(layer_data *dev_data, IMAGE_STATE *image_state, const char *functionName) { if (image_state->binding.mem == MEMTRACKER_SWAP_CHAIN_IMAGE_KEY) { if (!image_state->valid) { return log_msg(dev_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, reinterpret_cast(image_state->binding.mem), __LINE__, MEMTRACK_INVALID_MEM_REGION, "MEM", "%s: Cannot read invalid swapchain image 0x%" PRIx64 ", please fill the memory before using.", functionName, reinterpret_cast(image_state->image)); } } else { return ValidateMemoryIsValid(dev_data, image_state->binding.mem, reinterpret_cast(image_state->image), VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, functionName); } return false; } // For given buffer_state, verify that the range it's bound to is valid static bool ValidateBufferMemoryIsValid(layer_data *dev_data, BUFFER_STATE *buffer_state, const char *functionName) { return ValidateMemoryIsValid(dev_data, buffer_state->binding.mem, reinterpret_cast(buffer_state->buffer), VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT, functionName); } // For the given memory allocation, set the range bound by the given handle object to the valid param value static void SetMemoryValid(layer_data *dev_data, VkDeviceMemory mem, uint64_t handle, bool valid) { DEVICE_MEM_INFO *mem_info = getMemObjInfo(dev_data, mem); if (mem_info) { mem_info->bound_ranges[handle].valid = valid; } } // For given image node // If mem is special swapchain key, then set entire image_state to valid param value // Else set the image's bound memory range to valid param value static void SetImageMemoryValid(layer_data *dev_data, IMAGE_STATE *image_state, bool valid) { if (image_state->binding.mem == MEMTRACKER_SWAP_CHAIN_IMAGE_KEY) { image_state->valid = valid; } else { SetMemoryValid(dev_data, image_state->binding.mem, reinterpret_cast(image_state->image), valid); } } // For given buffer node set the buffer's bound memory range to valid param value static void SetBufferMemoryValid(layer_data *dev_data, BUFFER_STATE *buffer_state, bool valid) { SetMemoryValid(dev_data, buffer_state->binding.mem, reinterpret_cast(buffer_state->buffer), valid); } // Find CB Info and add mem reference to list container // Find Mem Obj Info and add CB reference to list container static bool update_cmd_buf_and_mem_references(layer_data *dev_data, const VkCommandBuffer cb, const VkDeviceMemory mem, const char *apiName) { bool skip_call = false; // Skip validation if this image was created through WSI if (mem != MEMTRACKER_SWAP_CHAIN_IMAGE_KEY) { // First update CB binding in MemObj mini CB list DEVICE_MEM_INFO *pMemInfo = getMemObjInfo(dev_data, mem); if (pMemInfo) { // Now update CBInfo's Mem reference list GLOBAL_CB_NODE *cb_node = getCBNode(dev_data, cb); pMemInfo->cb_bindings.insert(cb_node); // TODO: keep track of all destroyed CBs so we know if this is a stale or simply invalid object if (cb_node) { cb_node->memObjs.insert(mem); } } } return skip_call; } // Create binding link between given sampler and command buffer node void AddCommandBufferBindingSampler(GLOBAL_CB_NODE *cb_node, SAMPLER_STATE *sampler_state) { sampler_state->cb_bindings.insert(cb_node); cb_node->object_bindings.insert( {reinterpret_cast(sampler_state->sampler), VK_DEBUG_REPORT_OBJECT_TYPE_SAMPLER_EXT}); } // Create binding link between given image node and command buffer node void AddCommandBufferBindingImage(const layer_data *dev_data, GLOBAL_CB_NODE *cb_node, IMAGE_STATE *image_state) { // Skip validation if this image was created through WSI if (image_state->binding.mem != MEMTRACKER_SWAP_CHAIN_IMAGE_KEY) { // First update CB binding in MemObj mini CB list for (auto mem_binding : image_state->GetBoundMemory()) { DEVICE_MEM_INFO *pMemInfo = getMemObjInfo(dev_data, mem_binding); if (pMemInfo) { pMemInfo->cb_bindings.insert(cb_node); // Now update CBInfo's Mem reference list cb_node->memObjs.insert(mem_binding); } } // Now update cb binding for image cb_node->object_bindings.insert({reinterpret_cast(image_state->image), VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT}); image_state->cb_bindings.insert(cb_node); } } // Create binding link between given image view node and its image with command buffer node void AddCommandBufferBindingImageView(const layer_data *dev_data, GLOBAL_CB_NODE *cb_node, IMAGE_VIEW_STATE *view_state) { // First add bindings for imageView view_state->cb_bindings.insert(cb_node); cb_node->object_bindings.insert( {reinterpret_cast(view_state->image_view), VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_VIEW_EXT}); auto image_state = getImageState(dev_data, view_state->create_info.image); // Add bindings for image within imageView if (image_state) { AddCommandBufferBindingImage(dev_data, cb_node, image_state); } } // Create binding link between given buffer node and command buffer node void AddCommandBufferBindingBuffer(const layer_data *dev_data, GLOBAL_CB_NODE *cb_node, BUFFER_STATE *buffer_state) { // First update CB binding in MemObj mini CB list for (auto mem_binding : buffer_state->GetBoundMemory()) { DEVICE_MEM_INFO *pMemInfo = getMemObjInfo(dev_data, mem_binding); if (pMemInfo) { pMemInfo->cb_bindings.insert(cb_node); // Now update CBInfo's Mem reference list cb_node->memObjs.insert(mem_binding); } } // Now update cb binding for buffer cb_node->object_bindings.insert({reinterpret_cast(buffer_state->buffer), VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT}); buffer_state->cb_bindings.insert(cb_node); } // Create binding link between given buffer view node and its buffer with command buffer node void AddCommandBufferBindingBufferView(const layer_data *dev_data, GLOBAL_CB_NODE *cb_node, BUFFER_VIEW_STATE *view_state) { // First add bindings for bufferView view_state->cb_bindings.insert(cb_node); cb_node->object_bindings.insert( {reinterpret_cast(view_state->buffer_view), VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_VIEW_EXT}); auto buffer_state = getBufferState(dev_data, view_state->create_info.buffer); // Add bindings for buffer within bufferView if (buffer_state) { AddCommandBufferBindingBuffer(dev_data, cb_node, buffer_state); } } // For every mem obj bound to particular CB, free bindings related to that CB static void clear_cmd_buf_and_mem_references(layer_data *dev_data, GLOBAL_CB_NODE *cb_node) { if (cb_node) { if (cb_node->memObjs.size() > 0) { for (auto mem : cb_node->memObjs) { DEVICE_MEM_INFO *pInfo = getMemObjInfo(dev_data, mem); if (pInfo) { pInfo->cb_bindings.erase(cb_node); } } cb_node->memObjs.clear(); } cb_node->validate_functions.clear(); } } // Overloaded call to above function when GLOBAL_CB_NODE has not already been looked-up static void clear_cmd_buf_and_mem_references(layer_data *dev_data, const VkCommandBuffer cb) { clear_cmd_buf_and_mem_references(dev_data, getCBNode(dev_data, cb)); } // Clear a single object binding from given memory object, or report error if binding is missing static bool ClearMemoryObjectBinding(layer_data *dev_data, uint64_t handle, VkDebugReportObjectTypeEXT type, VkDeviceMemory mem) { DEVICE_MEM_INFO *mem_info = getMemObjInfo(dev_data, mem); // This obj is bound to a memory object. Remove the reference to this object in that memory object's list if (mem_info && !mem_info->obj_bindings.erase({handle, type})) { return log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, type, handle, __LINE__, MEMTRACK_INVALID_OBJECT, "MEM", "While trying to clear mem binding for %s obj 0x%" PRIxLEAST64 ", unable to find that object referenced by mem obj 0x%" PRIxLEAST64, object_type_to_string(type), handle, (uint64_t)mem); } return false; } // ClearMemoryObjectBindings clears the binding of objects to memory // For the given object it pulls the memory bindings and makes sure that the bindings // no longer refer to the object being cleared. This occurs when objects are destroyed. static bool ClearMemoryObjectBindings(layer_data *dev_data, uint64_t handle, VkDebugReportObjectTypeEXT type) { bool skip = false; BINDABLE *mem_binding = GetObjectMemBinding(dev_data, handle, type); if (mem_binding) { if (!mem_binding->sparse) { skip = ClearMemoryObjectBinding(dev_data, handle, type, mem_binding->binding.mem); } else { // Sparse, clear all bindings for (auto& sparse_mem_binding : mem_binding->sparse_bindings) { skip |= ClearMemoryObjectBinding(dev_data, handle, type, sparse_mem_binding.mem); } } } return skip; } // For given mem object, verify that it is not null or UNBOUND, if it is, report error. Return skip value. bool VerifyBoundMemoryIsValid(const layer_data *dev_data, VkDeviceMemory mem, uint64_t handle, const char *api_name, const char *type_name) { bool result = false; if (VK_NULL_HANDLE == mem) { result = log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, handle, __LINE__, MEMTRACK_OBJECT_NOT_BOUND, "MEM", "%s: Vk%s object 0x%" PRIxLEAST64 " used with no memory bound. Memory should be bound by calling " "vkBind%sMemory().", api_name, type_name, handle, type_name); } else if (MEMORY_UNBOUND == mem) { result = log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, handle, __LINE__, MEMTRACK_OBJECT_NOT_BOUND, "MEM", "%s: Vk%s object 0x%" PRIxLEAST64 " used with no memory bound and previously bound memory was freed. " "Memory must not be freed prior to this operation.", api_name, type_name, handle); } return result; } // Check to see if memory was ever bound to this image bool ValidateMemoryIsBoundToImage(const layer_data *dev_data, const IMAGE_STATE *image_state, const char *api_name) { bool result = false; if (0 == (static_cast(image_state->createInfo.flags) & VK_IMAGE_CREATE_SPARSE_BINDING_BIT)) { result = VerifyBoundMemoryIsValid(dev_data, image_state->binding.mem, reinterpret_cast(image_state->image), api_name, "Image"); } return result; } // Check to see if memory was bound to this buffer bool ValidateMemoryIsBoundToBuffer(const layer_data *dev_data, const BUFFER_STATE *buffer_state, const char *api_name) { bool result = false; if (0 == (static_cast(buffer_state->createInfo.flags) & VK_BUFFER_CREATE_SPARSE_BINDING_BIT)) { result = VerifyBoundMemoryIsValid(dev_data, buffer_state->binding.mem, reinterpret_cast(buffer_state->buffer), api_name, "Buffer"); } return result; } // SetMemBinding is used to establish immutable, non-sparse binding between a single image/buffer object and memory object // For NULL mem case, output warning // Make sure given object is in global object map // IF a previous binding existed, output validation error // Otherwise, add reference from objectInfo to memoryInfo // Add reference off of objInfo static bool SetMemBinding(layer_data *dev_data, VkDeviceMemory mem, uint64_t handle, VkDebugReportObjectTypeEXT type, const char *apiName) { bool skip_call = false; // It's an error to bind an object to NULL memory if (mem == VK_NULL_HANDLE) { skip_call = log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, type, handle, __LINE__, MEMTRACK_INVALID_MEM_OBJ, "MEM", "In %s, attempting to Bind Obj(0x%" PRIxLEAST64 ") to NULL", apiName, handle); } else { BINDABLE *mem_binding = GetObjectMemBinding(dev_data, handle, type); assert(mem_binding); // TODO : Add check here to make sure object isn't sparse // VALIDATION_ERROR_00792 for buffers // VALIDATION_ERROR_00804 for images assert(!mem_binding->sparse); DEVICE_MEM_INFO *mem_info = getMemObjInfo(dev_data, mem); if (mem_info) { DEVICE_MEM_INFO *prev_binding = getMemObjInfo(dev_data, mem_binding->binding.mem); if (prev_binding) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, reinterpret_cast(mem), __LINE__, MEMTRACK_REBIND_OBJECT, "MEM", "In %s, attempting to bind memory (0x%" PRIxLEAST64 ") to object (0x%" PRIxLEAST64 ") which has already been bound to mem object 0x%" PRIxLEAST64, apiName, reinterpret_cast(mem), handle, reinterpret_cast(prev_binding->mem)); } else if (mem_binding->binding.mem == MEMORY_UNBOUND) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, reinterpret_cast(mem), __LINE__, MEMTRACK_REBIND_OBJECT, "MEM", "In %s, attempting to bind memory (0x%" PRIxLEAST64 ") to object (0x%" PRIxLEAST64 ") which was previous bound to memory that has since been freed. Memory bindings are immutable in " "Vulkan so this attempt to bind to new memory is not allowed.", apiName, reinterpret_cast(mem), handle); } else { mem_info->obj_bindings.insert({handle, type}); // For image objects, make sure default memory state is correctly set // TODO : What's the best/correct way to handle this? if (VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT == type) { auto const image_state = getImageState(dev_data, VkImage(handle)); if (image_state) { VkImageCreateInfo ici = image_state->createInfo; if (ici.usage & (VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT | VK_IMAGE_USAGE_DEPTH_STENCIL_ATTACHMENT_BIT)) { // TODO:: More memory state transition stuff. } } } mem_binding->binding.mem = mem; } } } return skip_call; } // For NULL mem case, clear any previous binding Else... // Make sure given object is in its object map // IF a previous binding existed, update binding // Add reference from objectInfo to memoryInfo // Add reference off of object's binding info // Return VK_TRUE if addition is successful, VK_FALSE otherwise static bool SetSparseMemBinding(layer_data *dev_data, MEM_BINDING binding, uint64_t handle, VkDebugReportObjectTypeEXT type, const char *apiName) { bool skip_call = VK_FALSE; // Handle NULL case separately, just clear previous binding & decrement reference if (binding.mem == VK_NULL_HANDLE) { // TODO : This should cause the range of the resource to be unbound according to spec } else { BINDABLE *mem_binding = GetObjectMemBinding(dev_data, handle, type); assert(mem_binding); assert(mem_binding->sparse); DEVICE_MEM_INFO *mem_info = getMemObjInfo(dev_data, binding.mem); if (mem_info) { mem_info->obj_bindings.insert({handle, type}); // Need to set mem binding for this object mem_binding->sparse_bindings.insert(binding); } } return skip_call; } // For handle of given object type, return memory binding static bool get_mem_for_type(layer_data *dev_data, uint64_t handle, VkDebugReportObjectTypeEXT type, VkDeviceMemory *mem) { bool skip_call = false; *mem = VK_NULL_HANDLE; switch (type) { case VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT: *mem = getImageState(dev_data, VkImage(handle))->binding.mem; break; case VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT: *mem = getBufferState(dev_data, VkBuffer(handle))->binding.mem; break; default: assert(0); } if (!*mem) { skip_call = log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, type, handle, __LINE__, MEMTRACK_INVALID_OBJECT, "MEM", "Trying to get mem binding for %s object 0x%" PRIxLEAST64 " but binding is NULL. Has memory been bound to this object?", object_type_to_string(type), handle); } return skip_call; } // Print details of MemObjInfo list static void print_mem_list(layer_data *dev_data) { // Early out if info is not requested if (!(dev_data->report_data->active_flags & VK_DEBUG_REPORT_INFORMATION_BIT_EXT)) { return; } // Just printing each msg individually for now, may want to package these into single large print log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", "Details of Memory Object list (of size " PRINTF_SIZE_T_SPECIFIER " elements)", dev_data->memObjMap.size()); log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", "============================="); if (dev_data->memObjMap.size() <= 0) return; for (auto ii = dev_data->memObjMap.begin(); ii != dev_data->memObjMap.end(); ++ii) { auto mem_info = (*ii).second.get(); log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", " ===MemObjInfo at 0x%p===", (void *)mem_info); log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", " Mem object: 0x%" PRIxLEAST64, (uint64_t)(mem_info->mem)); log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", " Ref Count: " PRINTF_SIZE_T_SPECIFIER, mem_info->cb_bindings.size() + mem_info->obj_bindings.size()); if (0 != mem_info->alloc_info.allocationSize) { string pAllocInfoMsg = vk_print_vkmemoryallocateinfo(&mem_info->alloc_info, "MEM(INFO): "); log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", " Mem Alloc info:\n%s", pAllocInfoMsg.c_str()); } else { log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", " Mem Alloc info is NULL (alloc done by vkCreateSwapchainKHR())"); } log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", " VK OBJECT Binding list of size " PRINTF_SIZE_T_SPECIFIER " elements:", mem_info->obj_bindings.size()); if (mem_info->obj_bindings.size() > 0) { for (auto obj : mem_info->obj_bindings) { log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", " VK OBJECT 0x%" PRIx64, obj.handle); } } log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", " VK Command Buffer (CB) binding list of size " PRINTF_SIZE_T_SPECIFIER " elements", mem_info->cb_bindings.size()); if (mem_info->cb_bindings.size() > 0) { for (auto cb : mem_info->cb_bindings) { log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", " VK command buffer 0x%p", cb); } } } } static void printCBList(layer_data *my_data) { GLOBAL_CB_NODE *pCBInfo = NULL; // Early out if info is not requested if (!(my_data->report_data->active_flags & VK_DEBUG_REPORT_INFORMATION_BIT_EXT)) { return; } log_msg(my_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", "Details of command buffer list (of size " PRINTF_SIZE_T_SPECIFIER " elements)", my_data->commandBufferMap.size()); log_msg(my_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", "=================="); if (my_data->commandBufferMap.size() <= 0) return; for (auto &cb_node : my_data->commandBufferMap) { pCBInfo = cb_node.second; log_msg(my_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", " CB Info (0x%p) has command buffer 0x%p", (void *)pCBInfo, (void *)pCBInfo->commandBuffer); if (pCBInfo->memObjs.size() <= 0) continue; for (auto obj : pCBInfo->memObjs) { log_msg(my_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, 0, __LINE__, MEMTRACK_NONE, "MEM", " Mem obj 0x%" PRIx64, (uint64_t)obj); } } } // Return a string representation of CMD_TYPE enum static string cmdTypeToString(CMD_TYPE cmd) { switch (cmd) { case CMD_BINDPIPELINE: return "CMD_BINDPIPELINE"; case CMD_BINDPIPELINEDELTA: return "CMD_BINDPIPELINEDELTA"; case CMD_SETVIEWPORTSTATE: return "CMD_SETVIEWPORTSTATE"; case CMD_SETLINEWIDTHSTATE: return "CMD_SETLINEWIDTHSTATE"; case CMD_SETDEPTHBIASSTATE: return "CMD_SETDEPTHBIASSTATE"; case CMD_SETBLENDSTATE: return "CMD_SETBLENDSTATE"; case CMD_SETDEPTHBOUNDSSTATE: return "CMD_SETDEPTHBOUNDSSTATE"; case CMD_SETSTENCILREADMASKSTATE: return "CMD_SETSTENCILREADMASKSTATE"; case CMD_SETSTENCILWRITEMASKSTATE: return "CMD_SETSTENCILWRITEMASKSTATE"; case CMD_SETSTENCILREFERENCESTATE: return "CMD_SETSTENCILREFERENCESTATE"; case CMD_BINDDESCRIPTORSETS: return "CMD_BINDDESCRIPTORSETS"; case CMD_BINDINDEXBUFFER: return "CMD_BINDINDEXBUFFER"; case CMD_BINDVERTEXBUFFER: return "CMD_BINDVERTEXBUFFER"; case CMD_DRAW: return "CMD_DRAW"; case CMD_DRAWINDEXED: return "CMD_DRAWINDEXED"; case CMD_DRAWINDIRECT: return "CMD_DRAWINDIRECT"; case CMD_DRAWINDEXEDINDIRECT: return "CMD_DRAWINDEXEDINDIRECT"; case CMD_DISPATCH: return "CMD_DISPATCH"; case CMD_DISPATCHINDIRECT: return "CMD_DISPATCHINDIRECT"; case CMD_COPYBUFFER: return "CMD_COPYBUFFER"; case CMD_COPYIMAGE: return "CMD_COPYIMAGE"; case CMD_BLITIMAGE: return "CMD_BLITIMAGE"; case CMD_COPYBUFFERTOIMAGE: return "CMD_COPYBUFFERTOIMAGE"; case CMD_COPYIMAGETOBUFFER: return "CMD_COPYIMAGETOBUFFER"; case CMD_CLONEIMAGEDATA: return "CMD_CLONEIMAGEDATA"; case CMD_UPDATEBUFFER: return "CMD_UPDATEBUFFER"; case CMD_FILLBUFFER: return "CMD_FILLBUFFER"; case CMD_CLEARCOLORIMAGE: return "CMD_CLEARCOLORIMAGE"; case CMD_CLEARATTACHMENTS: return "CMD_CLEARCOLORATTACHMENT"; case CMD_CLEARDEPTHSTENCILIMAGE: return "CMD_CLEARDEPTHSTENCILIMAGE"; case CMD_RESOLVEIMAGE: return "CMD_RESOLVEIMAGE"; case CMD_SETEVENT: return "CMD_SETEVENT"; case CMD_RESETEVENT: return "CMD_RESETEVENT"; case CMD_WAITEVENTS: return "CMD_WAITEVENTS"; case CMD_PIPELINEBARRIER: return "CMD_PIPELINEBARRIER"; case CMD_BEGINQUERY: return "CMD_BEGINQUERY"; case CMD_ENDQUERY: return "CMD_ENDQUERY"; case CMD_RESETQUERYPOOL: return "CMD_RESETQUERYPOOL"; case CMD_COPYQUERYPOOLRESULTS: return "CMD_COPYQUERYPOOLRESULTS"; case CMD_WRITETIMESTAMP: return "CMD_WRITETIMESTAMP"; case CMD_INITATOMICCOUNTERS: return "CMD_INITATOMICCOUNTERS"; case CMD_LOADATOMICCOUNTERS: return "CMD_LOADATOMICCOUNTERS"; case CMD_SAVEATOMICCOUNTERS: return "CMD_SAVEATOMICCOUNTERS"; case CMD_BEGINRENDERPASS: return "CMD_BEGINRENDERPASS"; case CMD_ENDRENDERPASS: return "CMD_ENDRENDERPASS"; default: return "UNKNOWN"; } } // SPIRV utility functions static void build_def_index(shader_module *module) { for (auto insn : *module) { switch (insn.opcode()) { /* Types */ case spv::OpTypeVoid: case spv::OpTypeBool: case spv::OpTypeInt: case spv::OpTypeFloat: case spv::OpTypeVector: case spv::OpTypeMatrix: case spv::OpTypeImage: case spv::OpTypeSampler: case spv::OpTypeSampledImage: case spv::OpTypeArray: case spv::OpTypeRuntimeArray: case spv::OpTypeStruct: case spv::OpTypeOpaque: case spv::OpTypePointer: case spv::OpTypeFunction: case spv::OpTypeEvent: case spv::OpTypeDeviceEvent: case spv::OpTypeReserveId: case spv::OpTypeQueue: case spv::OpTypePipe: module->def_index[insn.word(1)] = insn.offset(); break; /* Fixed constants */ case spv::OpConstantTrue: case spv::OpConstantFalse: case spv::OpConstant: case spv::OpConstantComposite: case spv::OpConstantSampler: case spv::OpConstantNull: module->def_index[insn.word(2)] = insn.offset(); break; /* Specialization constants */ case spv::OpSpecConstantTrue: case spv::OpSpecConstantFalse: case spv::OpSpecConstant: case spv::OpSpecConstantComposite: case spv::OpSpecConstantOp: module->def_index[insn.word(2)] = insn.offset(); break; /* Variables */ case spv::OpVariable: module->def_index[insn.word(2)] = insn.offset(); break; /* Functions */ case spv::OpFunction: module->def_index[insn.word(2)] = insn.offset(); break; default: /* We don't care about any other defs for now. */ break; } } } static spirv_inst_iter find_entrypoint(shader_module *src, char const *name, VkShaderStageFlagBits stageBits) { for (auto insn : *src) { if (insn.opcode() == spv::OpEntryPoint) { auto entrypointName = (char const *)&insn.word(3); auto entrypointStageBits = 1u << insn.word(1); if (!strcmp(entrypointName, name) && (entrypointStageBits & stageBits)) { return insn; } } } return src->end(); } static char const *storage_class_name(unsigned sc) { switch (sc) { case spv::StorageClassInput: return "input"; case spv::StorageClassOutput: return "output"; case spv::StorageClassUniformConstant: return "const uniform"; case spv::StorageClassUniform: return "uniform"; case spv::StorageClassWorkgroup: return "workgroup local"; case spv::StorageClassCrossWorkgroup: return "workgroup global"; case spv::StorageClassPrivate: return "private global"; case spv::StorageClassFunction: return "function"; case spv::StorageClassGeneric: return "generic"; case spv::StorageClassAtomicCounter: return "atomic counter"; case spv::StorageClassImage: return "image"; case spv::StorageClassPushConstant: return "push constant"; default: return "unknown"; } } /* get the value of an integral constant */ unsigned get_constant_value(shader_module const *src, unsigned id) { auto value = src->get_def(id); assert(value != src->end()); if (value.opcode() != spv::OpConstant) { /* TODO: Either ensure that the specialization transform is already performed on a module we're considering here, OR -- specialize on the fly now. */ return 1; } return value.word(3); } static void describe_type_inner(std::ostringstream &ss, shader_module const *src, unsigned type) { auto insn = src->get_def(type); assert(insn != src->end()); switch (insn.opcode()) { case spv::OpTypeBool: ss << "bool"; break; case spv::OpTypeInt: ss << (insn.word(3) ? 's' : 'u') << "int" << insn.word(2); break; case spv::OpTypeFloat: ss << "float" << insn.word(2); break; case spv::OpTypeVector: ss << "vec" << insn.word(3) << " of "; describe_type_inner(ss, src, insn.word(2)); break; case spv::OpTypeMatrix: ss << "mat" << insn.word(3) << " of "; describe_type_inner(ss, src, insn.word(2)); break; case spv::OpTypeArray: ss << "arr[" << get_constant_value(src, insn.word(3)) << "] of "; describe_type_inner(ss, src, insn.word(2)); break; case spv::OpTypePointer: ss << "ptr to " << storage_class_name(insn.word(2)) << " "; describe_type_inner(ss, src, insn.word(3)); break; case spv::OpTypeStruct: { ss << "struct of ("; for (unsigned i = 2; i < insn.len(); i++) { describe_type_inner(ss, src, insn.word(i)); if (i == insn.len() - 1) { ss << ")"; } else { ss << ", "; } } break; } case spv::OpTypeSampler: ss << "sampler"; break; case spv::OpTypeSampledImage: ss << "sampler+"; describe_type_inner(ss, src, insn.word(2)); break; case spv::OpTypeImage: ss << "image(dim=" << insn.word(3) << ", sampled=" << insn.word(7) << ")"; break; default: ss << "oddtype"; break; } } static std::string describe_type(shader_module const *src, unsigned type) { std::ostringstream ss; describe_type_inner(ss, src, type); return ss.str(); } static bool is_narrow_numeric_type(spirv_inst_iter type) { if (type.opcode() != spv::OpTypeInt && type.opcode() != spv::OpTypeFloat) return false; return type.word(2) < 64; } static bool types_match(shader_module const *a, shader_module const *b, unsigned a_type, unsigned b_type, bool a_arrayed, bool b_arrayed, bool relaxed) { /* walk two type trees together, and complain about differences */ auto a_insn = a->get_def(a_type); auto b_insn = b->get_def(b_type); assert(a_insn != a->end()); assert(b_insn != b->end()); if (a_arrayed && a_insn.opcode() == spv::OpTypeArray) { return types_match(a, b, a_insn.word(2), b_type, false, b_arrayed, relaxed); } if (b_arrayed && b_insn.opcode() == spv::OpTypeArray) { /* we probably just found the extra level of arrayness in b_type: compare the type inside it to a_type */ return types_match(a, b, a_type, b_insn.word(2), a_arrayed, false, relaxed); } if (a_insn.opcode() == spv::OpTypeVector && relaxed && is_narrow_numeric_type(b_insn)) { return types_match(a, b, a_insn.word(2), b_type, a_arrayed, b_arrayed, false); } if (a_insn.opcode() != b_insn.opcode()) { return false; } if (a_insn.opcode() == spv::OpTypePointer) { /* match on pointee type. storage class is expected to differ */ return types_match(a, b, a_insn.word(3), b_insn.word(3), a_arrayed, b_arrayed, relaxed); } if (a_arrayed || b_arrayed) { /* if we havent resolved array-of-verts by here, we're not going to. */ return false; } switch (a_insn.opcode()) { case spv::OpTypeBool: return true; case spv::OpTypeInt: /* match on width, signedness */ return a_insn.word(2) == b_insn.word(2) && a_insn.word(3) == b_insn.word(3); case spv::OpTypeFloat: /* match on width */ return a_insn.word(2) == b_insn.word(2); case spv::OpTypeVector: /* match on element type, count. */ if (!types_match(a, b, a_insn.word(2), b_insn.word(2), a_arrayed, b_arrayed, false)) return false; if (relaxed && is_narrow_numeric_type(a->get_def(a_insn.word(2)))) { return a_insn.word(3) >= b_insn.word(3); } else { return a_insn.word(3) == b_insn.word(3); } case spv::OpTypeMatrix: /* match on element type, count. */ return types_match(a, b, a_insn.word(2), b_insn.word(2), a_arrayed, b_arrayed, false) && a_insn.word(3) == b_insn.word(3); case spv::OpTypeArray: /* match on element type, count. these all have the same layout. we don't get here if * b_arrayed. This differs from vector & matrix types in that the array size is the id of a constant instruction, * not a literal within OpTypeArray */ return types_match(a, b, a_insn.word(2), b_insn.word(2), a_arrayed, b_arrayed, false) && get_constant_value(a, a_insn.word(3)) == get_constant_value(b, b_insn.word(3)); case spv::OpTypeStruct: /* match on all element types */ { if (a_insn.len() != b_insn.len()) { return false; /* structs cannot match if member counts differ */ } for (unsigned i = 2; i < a_insn.len(); i++) { if (!types_match(a, b, a_insn.word(i), b_insn.word(i), a_arrayed, b_arrayed, false)) { return false; } } return true; } default: /* remaining types are CLisms, or may not appear in the interfaces we * are interested in. Just claim no match. */ return false; } } static int value_or_default(std::unordered_map const &map, unsigned id, int def) { auto it = map.find(id); if (it == map.end()) return def; else return it->second; } static unsigned get_locations_consumed_by_type(shader_module const *src, unsigned type, bool strip_array_level) { auto insn = src->get_def(type); assert(insn != src->end()); switch (insn.opcode()) { case spv::OpTypePointer: /* see through the ptr -- this is only ever at the toplevel for graphics shaders; * we're never actually passing pointers around. */ return get_locations_consumed_by_type(src, insn.word(3), strip_array_level); case spv::OpTypeArray: if (strip_array_level) { return get_locations_consumed_by_type(src, insn.word(2), false); } else { return get_constant_value(src, insn.word(3)) * get_locations_consumed_by_type(src, insn.word(2), false); } case spv::OpTypeMatrix: /* num locations is the dimension * element size */ return insn.word(3) * get_locations_consumed_by_type(src, insn.word(2), false); case spv::OpTypeVector: { auto scalar_type = src->get_def(insn.word(2)); auto bit_width = (scalar_type.opcode() == spv::OpTypeInt || scalar_type.opcode() == spv::OpTypeFloat) ? scalar_type.word(2) : 32; /* locations are 128-bit wide; 3- and 4-component vectors of 64 bit * types require two. */ return (bit_width * insn.word(3) + 127) / 128; } default: /* everything else is just 1. */ return 1; /* TODO: extend to handle 64bit scalar types, whose vectors may need * multiple locations. */ } } static unsigned get_locations_consumed_by_format(VkFormat format) { switch (format) { case VK_FORMAT_R64G64B64A64_SFLOAT: case VK_FORMAT_R64G64B64A64_SINT: case VK_FORMAT_R64G64B64A64_UINT: case VK_FORMAT_R64G64B64_SFLOAT: case VK_FORMAT_R64G64B64_SINT: case VK_FORMAT_R64G64B64_UINT: return 2; default: return 1; } } typedef std::pair location_t; typedef std::pair descriptor_slot_t; struct interface_var { uint32_t id; uint32_t type_id; uint32_t offset; bool is_patch; bool is_block_member; /* TODO: collect the name, too? Isn't required to be present. */ }; struct shader_stage_attributes { char const *const name; bool arrayed_input; bool arrayed_output; }; static shader_stage_attributes shader_stage_attribs[] = { {"vertex shader", false, false}, {"tessellation control shader", true, true}, {"tessellation evaluation shader", true, false}, {"geometry shader", true, false}, {"fragment shader", false, false}, }; static spirv_inst_iter get_struct_type(shader_module const *src, spirv_inst_iter def, bool is_array_of_verts) { while (true) { if (def.opcode() == spv::OpTypePointer) { def = src->get_def(def.word(3)); } else if (def.opcode() == spv::OpTypeArray && is_array_of_verts) { def = src->get_def(def.word(2)); is_array_of_verts = false; } else if (def.opcode() == spv::OpTypeStruct) { return def; } else { return src->end(); } } } static void collect_interface_block_members(shader_module const *src, std::map *out, std::unordered_map const &blocks, bool is_array_of_verts, uint32_t id, uint32_t type_id, bool is_patch) { /* Walk down the type_id presented, trying to determine whether it's actually an interface block. */ auto type = get_struct_type(src, src->get_def(type_id), is_array_of_verts && !is_patch); if (type == src->end() || blocks.find(type.word(1)) == blocks.end()) { /* this isn't an interface block. */ return; } std::unordered_map member_components; /* Walk all the OpMemberDecorate for type's result id -- first pass, collect components. */ for (auto insn : *src) { if (insn.opcode() == spv::OpMemberDecorate && insn.word(1) == type.word(1)) { unsigned member_index = insn.word(2); if (insn.word(3) == spv::DecorationComponent) { unsigned component = insn.word(4); member_components[member_index] = component; } } } /* Second pass -- produce the output, from Location decorations */ for (auto insn : *src) { if (insn.opcode() == spv::OpMemberDecorate && insn.word(1) == type.word(1)) { unsigned member_index = insn.word(2); unsigned member_type_id = type.word(2 + member_index); if (insn.word(3) == spv::DecorationLocation) { unsigned location = insn.word(4); unsigned num_locations = get_locations_consumed_by_type(src, member_type_id, false); auto component_it = member_components.find(member_index); unsigned component = component_it == member_components.end() ? 0 : component_it->second; for (unsigned int offset = 0; offset < num_locations; offset++) { interface_var v; v.id = id; /* TODO: member index in interface_var too? */ v.type_id = member_type_id; v.offset = offset; v.is_patch = is_patch; v.is_block_member = true; (*out)[std::make_pair(location + offset, component)] = v; } } } } } static std::map collect_interface_by_location( shader_module const *src, spirv_inst_iter entrypoint, spv::StorageClass sinterface, bool is_array_of_verts) { std::unordered_map var_locations; std::unordered_map var_builtins; std::unordered_map var_components; std::unordered_map blocks; std::unordered_map var_patch; for (auto insn : *src) { /* We consider two interface models: SSO rendezvous-by-location, and * builtins. Complain about anything that fits neither model. */ if (insn.opcode() == spv::OpDecorate) { if (insn.word(2) == spv::DecorationLocation) { var_locations[insn.word(1)] = insn.word(3); } if (insn.word(2) == spv::DecorationBuiltIn) { var_builtins[insn.word(1)] = insn.word(3); } if (insn.word(2) == spv::DecorationComponent) { var_components[insn.word(1)] = insn.word(3); } if (insn.word(2) == spv::DecorationBlock) { blocks[insn.word(1)] = 1; } if (insn.word(2) == spv::DecorationPatch) { var_patch[insn.word(1)] = 1; } } } /* TODO: handle grouped decorations */ /* TODO: handle index=1 dual source outputs from FS -- two vars will * have the same location, and we DON'T want to clobber. */ /* find the end of the entrypoint's name string. additional zero bytes follow the actual null terminator, to fill out the rest of the word - so we only need to look at the last byte in the word to determine which word contains the terminator. */ uint32_t word = 3; while (entrypoint.word(word) & 0xff000000u) { ++word; } ++word; std::map out; for (; word < entrypoint.len(); word++) { auto insn = src->get_def(entrypoint.word(word)); assert(insn != src->end()); assert(insn.opcode() == spv::OpVariable); if (insn.word(3) == static_cast(sinterface)) { unsigned id = insn.word(2); unsigned type = insn.word(1); int location = value_or_default(var_locations, id, -1); int builtin = value_or_default(var_builtins, id, -1); unsigned component = value_or_default(var_components, id, 0); /* unspecified is OK, is 0 */ bool is_patch = var_patch.find(id) != var_patch.end(); /* All variables and interface block members in the Input or Output storage classes * must be decorated with either a builtin or an explicit location. * * TODO: integrate the interface block support here. For now, don't complain -- * a valid SPIRV module will only hit this path for the interface block case, as the * individual members of the type are decorated, rather than variable declarations. */ if (location != -1) { /* A user-defined interface variable, with a location. Where a variable * occupied multiple locations, emit one result for each. */ unsigned num_locations = get_locations_consumed_by_type(src, type, is_array_of_verts && !is_patch); for (unsigned int offset = 0; offset < num_locations; offset++) { interface_var v; v.id = id; v.type_id = type; v.offset = offset; v.is_patch = is_patch; v.is_block_member = false; out[std::make_pair(location + offset, component)] = v; } } else if (builtin == -1) { /* An interface block instance */ collect_interface_block_members(src, &out, blocks, is_array_of_verts, id, type, is_patch); } } } return out; } static std::vector> collect_interface_by_input_attachment_index( debug_report_data *report_data, shader_module const *src, std::unordered_set const &accessible_ids) { std::vector> out; for (auto insn : *src) { if (insn.opcode() == spv::OpDecorate) { if (insn.word(2) == spv::DecorationInputAttachmentIndex) { auto attachment_index = insn.word(3); auto id = insn.word(1); if (accessible_ids.count(id)) { auto def = src->get_def(id); assert(def != src->end()); if (def.opcode() == spv::OpVariable && insn.word(3) == spv::StorageClassUniformConstant) { auto num_locations = get_locations_consumed_by_type(src, def.word(1), false); for (unsigned int offset = 0; offset < num_locations; offset++) { interface_var v; v.id = id; v.type_id = def.word(1); v.offset = offset; v.is_patch = false; v.is_block_member = false; out.emplace_back(attachment_index + offset, v); } } } } } } return out; } static std::vector> collect_interface_by_descriptor_slot( debug_report_data *report_data, shader_module const *src, std::unordered_set const &accessible_ids) { std::unordered_map var_sets; std::unordered_map var_bindings; for (auto insn : *src) { /* All variables in the Uniform or UniformConstant storage classes are required to be decorated with both * DecorationDescriptorSet and DecorationBinding. */ if (insn.opcode() == spv::OpDecorate) { if (insn.word(2) == spv::DecorationDescriptorSet) { var_sets[insn.word(1)] = insn.word(3); } if (insn.word(2) == spv::DecorationBinding) { var_bindings[insn.word(1)] = insn.word(3); } } } std::vector> out; for (auto id : accessible_ids) { auto insn = src->get_def(id); assert(insn != src->end()); if (insn.opcode() == spv::OpVariable && (insn.word(3) == spv::StorageClassUniform || insn.word(3) == spv::StorageClassUniformConstant)) { unsigned set = value_or_default(var_sets, insn.word(2), 0); unsigned binding = value_or_default(var_bindings, insn.word(2), 0); interface_var v; v.id = insn.word(2); v.type_id = insn.word(1); v.offset = 0; v.is_patch = false; v.is_block_member = false; out.emplace_back(std::make_pair(set, binding), v); } } return out; } static bool validate_interface_between_stages(debug_report_data *report_data, shader_module const *producer, spirv_inst_iter producer_entrypoint, shader_stage_attributes const *producer_stage, shader_module const *consumer, spirv_inst_iter consumer_entrypoint, shader_stage_attributes const *consumer_stage) { bool pass = true; auto outputs = collect_interface_by_location(producer, producer_entrypoint, spv::StorageClassOutput, producer_stage->arrayed_output); auto inputs = collect_interface_by_location(consumer, consumer_entrypoint, spv::StorageClassInput, consumer_stage->arrayed_input); auto a_it = outputs.begin(); auto b_it = inputs.begin(); /* maps sorted by key (location); walk them together to find mismatches */ while ((outputs.size() > 0 && a_it != outputs.end()) || (inputs.size() && b_it != inputs.end())) { bool a_at_end = outputs.size() == 0 || a_it == outputs.end(); bool b_at_end = inputs.size() == 0 || b_it == inputs.end(); auto a_first = a_at_end ? std::make_pair(0u, 0u) : a_it->first; auto b_first = b_at_end ? std::make_pair(0u, 0u) : b_it->first; if (b_at_end || ((!a_at_end) && (a_first < b_first))) { if (log_msg(report_data, VK_DEBUG_REPORT_PERFORMANCE_WARNING_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_OUTPUT_NOT_CONSUMED, "SC", "%s writes to output location %u.%u which is not consumed by %s", producer_stage->name, a_first.first, a_first.second, consumer_stage->name)) { pass = false; } a_it++; } else if (a_at_end || a_first > b_first) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_INPUT_NOT_PRODUCED, "SC", "%s consumes input location %u.%u which is not written by %s", consumer_stage->name, b_first.first, b_first.second, producer_stage->name)) { pass = false; } b_it++; } else { // subtleties of arrayed interfaces: // - if is_patch, then the member is not arrayed, even though the interface may be. // - if is_block_member, then the extra array level of an arrayed interface is not // expressed in the member type -- it's expressed in the block type. if (!types_match(producer, consumer, a_it->second.type_id, b_it->second.type_id, producer_stage->arrayed_output && !a_it->second.is_patch && !a_it->second.is_block_member, consumer_stage->arrayed_input && !b_it->second.is_patch && !b_it->second.is_block_member, true)) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_INTERFACE_TYPE_MISMATCH, "SC", "Type mismatch on location %u.%u: '%s' vs '%s'", a_first.first, a_first.second, describe_type(producer, a_it->second.type_id).c_str(), describe_type(consumer, b_it->second.type_id).c_str())) { pass = false; } } if (a_it->second.is_patch != b_it->second.is_patch) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_EXT, /*dev*/ 0, __LINE__, SHADER_CHECKER_INTERFACE_TYPE_MISMATCH, "SC", "Decoration mismatch on location %u.%u: is per-%s in %s stage but " "per-%s in %s stage", a_first.first, a_first.second, a_it->second.is_patch ? "patch" : "vertex", producer_stage->name, b_it->second.is_patch ? "patch" : "vertex", consumer_stage->name)) { pass = false; } } a_it++; b_it++; } } return pass; } enum FORMAT_TYPE { FORMAT_TYPE_UNDEFINED, FORMAT_TYPE_FLOAT, /* UNORM, SNORM, FLOAT, USCALED, SSCALED, SRGB -- anything we consider float in the shader */ FORMAT_TYPE_SINT, FORMAT_TYPE_UINT, }; static unsigned get_format_type(VkFormat fmt) { switch (fmt) { case VK_FORMAT_UNDEFINED: return FORMAT_TYPE_UNDEFINED; case VK_FORMAT_R8_SINT: case VK_FORMAT_R8G8_SINT: case VK_FORMAT_R8G8B8_SINT: case VK_FORMAT_R8G8B8A8_SINT: case VK_FORMAT_R16_SINT: case VK_FORMAT_R16G16_SINT: case VK_FORMAT_R16G16B16_SINT: case VK_FORMAT_R16G16B16A16_SINT: case VK_FORMAT_R32_SINT: case VK_FORMAT_R32G32_SINT: case VK_FORMAT_R32G32B32_SINT: case VK_FORMAT_R32G32B32A32_SINT: case VK_FORMAT_R64_SINT: case VK_FORMAT_R64G64_SINT: case VK_FORMAT_R64G64B64_SINT: case VK_FORMAT_R64G64B64A64_SINT: case VK_FORMAT_B8G8R8_SINT: case VK_FORMAT_B8G8R8A8_SINT: case VK_FORMAT_A8B8G8R8_SINT_PACK32: case VK_FORMAT_A2B10G10R10_SINT_PACK32: case VK_FORMAT_A2R10G10B10_SINT_PACK32: return FORMAT_TYPE_SINT; case VK_FORMAT_R8_UINT: case VK_FORMAT_R8G8_UINT: case VK_FORMAT_R8G8B8_UINT: case VK_FORMAT_R8G8B8A8_UINT: case VK_FORMAT_R16_UINT: case VK_FORMAT_R16G16_UINT: case VK_FORMAT_R16G16B16_UINT: case VK_FORMAT_R16G16B16A16_UINT: case VK_FORMAT_R32_UINT: case VK_FORMAT_R32G32_UINT: case VK_FORMAT_R32G32B32_UINT: case VK_FORMAT_R32G32B32A32_UINT: case VK_FORMAT_R64_UINT: case VK_FORMAT_R64G64_UINT: case VK_FORMAT_R64G64B64_UINT: case VK_FORMAT_R64G64B64A64_UINT: case VK_FORMAT_B8G8R8_UINT: case VK_FORMAT_B8G8R8A8_UINT: case VK_FORMAT_A8B8G8R8_UINT_PACK32: case VK_FORMAT_A2B10G10R10_UINT_PACK32: case VK_FORMAT_A2R10G10B10_UINT_PACK32: return FORMAT_TYPE_UINT; default: return FORMAT_TYPE_FLOAT; } } /* characterizes a SPIR-V type appearing in an interface to a FF stage, * for comparison to a VkFormat's characterization above. */ static unsigned get_fundamental_type(shader_module const *src, unsigned type) { auto insn = src->get_def(type); assert(insn != src->end()); switch (insn.opcode()) { case spv::OpTypeInt: return insn.word(3) ? FORMAT_TYPE_SINT : FORMAT_TYPE_UINT; case spv::OpTypeFloat: return FORMAT_TYPE_FLOAT; case spv::OpTypeVector: return get_fundamental_type(src, insn.word(2)); case spv::OpTypeMatrix: return get_fundamental_type(src, insn.word(2)); case spv::OpTypeArray: return get_fundamental_type(src, insn.word(2)); case spv::OpTypePointer: return get_fundamental_type(src, insn.word(3)); case spv::OpTypeImage: return get_fundamental_type(src, insn.word(2)); default: return FORMAT_TYPE_UNDEFINED; } } static uint32_t get_shader_stage_id(VkShaderStageFlagBits stage) { uint32_t bit_pos = u_ffs(stage); return bit_pos - 1; } static bool validate_vi_consistency(debug_report_data *report_data, VkPipelineVertexInputStateCreateInfo const *vi) { /* walk the binding descriptions, which describe the step rate and stride of each vertex buffer. * each binding should be specified only once. */ std::unordered_map bindings; bool pass = true; for (unsigned i = 0; i < vi->vertexBindingDescriptionCount; i++) { auto desc = &vi->pVertexBindingDescriptions[i]; auto &binding = bindings[desc->binding]; if (binding) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_INCONSISTENT_VI, "SC", "Duplicate vertex input binding descriptions for binding %d", desc->binding)) { pass = false; } } else { binding = desc; } } return pass; } static bool validate_vi_against_vs_inputs(debug_report_data *report_data, VkPipelineVertexInputStateCreateInfo const *vi, shader_module const *vs, spirv_inst_iter entrypoint) { bool pass = true; auto inputs = collect_interface_by_location(vs, entrypoint, spv::StorageClassInput, false); /* Build index by location */ std::map attribs; if (vi) { for (unsigned i = 0; i < vi->vertexAttributeDescriptionCount; i++) { auto num_locations = get_locations_consumed_by_format(vi->pVertexAttributeDescriptions[i].format); for (auto j = 0u; j < num_locations; j++) { attribs[vi->pVertexAttributeDescriptions[i].location + j] = &vi->pVertexAttributeDescriptions[i]; } } } auto it_a = attribs.begin(); auto it_b = inputs.begin(); bool used = false; while ((attribs.size() > 0 && it_a != attribs.end()) || (inputs.size() > 0 && it_b != inputs.end())) { bool a_at_end = attribs.size() == 0 || it_a == attribs.end(); bool b_at_end = inputs.size() == 0 || it_b == inputs.end(); auto a_first = a_at_end ? 0 : it_a->first; auto b_first = b_at_end ? 0 : it_b->first.first; if (!a_at_end && (b_at_end || a_first < b_first)) { if (!used && log_msg(report_data, VK_DEBUG_REPORT_PERFORMANCE_WARNING_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_OUTPUT_NOT_CONSUMED, "SC", "Vertex attribute at location %d not consumed by vertex shader", a_first)) { pass = false; } used = false; it_a++; } else if (!b_at_end && (a_at_end || b_first < a_first)) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_EXT, /*dev*/ 0, __LINE__, SHADER_CHECKER_INPUT_NOT_PRODUCED, "SC", "Vertex shader consumes input at location %d but not provided", b_first)) { pass = false; } it_b++; } else { unsigned attrib_type = get_format_type(it_a->second->format); unsigned input_type = get_fundamental_type(vs, it_b->second.type_id); /* type checking */ if (attrib_type != FORMAT_TYPE_UNDEFINED && input_type != FORMAT_TYPE_UNDEFINED && attrib_type != input_type) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_INTERFACE_TYPE_MISMATCH, "SC", "Attribute type of `%s` at location %d does not match vertex shader input type of `%s`", string_VkFormat(it_a->second->format), a_first, describe_type(vs, it_b->second.type_id).c_str())) { pass = false; } } /* OK! */ used = true; it_b++; } } return pass; } static bool validate_fs_outputs_against_render_pass(debug_report_data *report_data, shader_module const *fs, spirv_inst_iter entrypoint, VkRenderPassCreateInfo const *rpci, uint32_t subpass_index) { std::map color_attachments; auto subpass = rpci->pSubpasses[subpass_index]; for (auto i = 0u; i < subpass.colorAttachmentCount; ++i) { uint32_t attachment = subpass.pColorAttachments[i].attachment; if (attachment == VK_ATTACHMENT_UNUSED) continue; if (rpci->pAttachments[attachment].format != VK_FORMAT_UNDEFINED) { color_attachments[i] = rpci->pAttachments[attachment].format; } } bool pass = true; /* TODO: dual source blend index (spv::DecIndex, zero if not provided) */ auto outputs = collect_interface_by_location(fs, entrypoint, spv::StorageClassOutput, false); auto it_a = outputs.begin(); auto it_b = color_attachments.begin(); /* Walk attachment list and outputs together */ while ((outputs.size() > 0 && it_a != outputs.end()) || (color_attachments.size() > 0 && it_b != color_attachments.end())) { bool a_at_end = outputs.size() == 0 || it_a == outputs.end(); bool b_at_end = color_attachments.size() == 0 || it_b == color_attachments.end(); if (!a_at_end && (b_at_end || it_a->first.first < it_b->first)) { if (log_msg(report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_OUTPUT_NOT_CONSUMED, "SC", "fragment shader writes to output location %d with no matching attachment", it_a->first.first)) { pass = false; } it_a++; } else if (!b_at_end && (a_at_end || it_a->first.first > it_b->first)) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_INPUT_NOT_PRODUCED, "SC", "Attachment %d not written by fragment shader", it_b->first)) { pass = false; } it_b++; } else { unsigned output_type = get_fundamental_type(fs, it_a->second.type_id); unsigned att_type = get_format_type(it_b->second); /* type checking */ if (att_type != FORMAT_TYPE_UNDEFINED && output_type != FORMAT_TYPE_UNDEFINED && att_type != output_type) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_INTERFACE_TYPE_MISMATCH, "SC", "Attachment %d of type `%s` does not match fragment shader output type of `%s`", it_b->first, string_VkFormat(it_b->second), describe_type(fs, it_a->second.type_id).c_str())) { pass = false; } } /* OK! */ it_a++; it_b++; } } return pass; } /* For some analyses, we need to know about all ids referenced by the static call tree of a particular * entrypoint. This is important for identifying the set of shader resources actually used by an entrypoint, * for example. * Note: we only explore parts of the image which might actually contain ids we care about for the above analyses. * - NOT the shader input/output interfaces. * * TODO: The set of interesting opcodes here was determined by eyeballing the SPIRV spec. It might be worth * converting parts of this to be generated from the machine-readable spec instead. */ static std::unordered_set mark_accessible_ids(shader_module const *src, spirv_inst_iter entrypoint) { std::unordered_set ids; std::unordered_set worklist; worklist.insert(entrypoint.word(2)); while (!worklist.empty()) { auto id_iter = worklist.begin(); auto id = *id_iter; worklist.erase(id_iter); auto insn = src->get_def(id); if (insn == src->end()) { /* id is something we didn't collect in build_def_index. that's OK -- we'll stumble * across all kinds of things here that we may not care about. */ continue; } /* try to add to the output set */ if (!ids.insert(id).second) { continue; /* if we already saw this id, we don't want to walk it again. */ } switch (insn.opcode()) { case spv::OpFunction: /* scan whole body of the function, enlisting anything interesting */ while (++insn, insn.opcode() != spv::OpFunctionEnd) { switch (insn.opcode()) { case spv::OpLoad: case spv::OpAtomicLoad: case spv::OpAtomicExchange: case spv::OpAtomicCompareExchange: case spv::OpAtomicCompareExchangeWeak: case spv::OpAtomicIIncrement: case spv::OpAtomicIDecrement: case spv::OpAtomicIAdd: case spv::OpAtomicISub: case spv::OpAtomicSMin: case spv::OpAtomicUMin: case spv::OpAtomicSMax: case spv::OpAtomicUMax: case spv::OpAtomicAnd: case spv::OpAtomicOr: case spv::OpAtomicXor: worklist.insert(insn.word(3)); /* ptr */ break; case spv::OpStore: case spv::OpAtomicStore: worklist.insert(insn.word(1)); /* ptr */ break; case spv::OpAccessChain: case spv::OpInBoundsAccessChain: worklist.insert(insn.word(3)); /* base ptr */ break; case spv::OpSampledImage: case spv::OpImageSampleImplicitLod: case spv::OpImageSampleExplicitLod: case spv::OpImageSampleDrefImplicitLod: case spv::OpImageSampleDrefExplicitLod: case spv::OpImageSampleProjImplicitLod: case spv::OpImageSampleProjExplicitLod: case spv::OpImageSampleProjDrefImplicitLod: case spv::OpImageSampleProjDrefExplicitLod: case spv::OpImageFetch: case spv::OpImageGather: case spv::OpImageDrefGather: case spv::OpImageRead: case spv::OpImage: case spv::OpImageQueryFormat: case spv::OpImageQueryOrder: case spv::OpImageQuerySizeLod: case spv::OpImageQuerySize: case spv::OpImageQueryLod: case spv::OpImageQueryLevels: case spv::OpImageQuerySamples: case spv::OpImageSparseSampleImplicitLod: case spv::OpImageSparseSampleExplicitLod: case spv::OpImageSparseSampleDrefImplicitLod: case spv::OpImageSparseSampleDrefExplicitLod: case spv::OpImageSparseSampleProjImplicitLod: case spv::OpImageSparseSampleProjExplicitLod: case spv::OpImageSparseSampleProjDrefImplicitLod: case spv::OpImageSparseSampleProjDrefExplicitLod: case spv::OpImageSparseFetch: case spv::OpImageSparseGather: case spv::OpImageSparseDrefGather: case spv::OpImageTexelPointer: worklist.insert(insn.word(3)); /* image or sampled image */ break; case spv::OpImageWrite: worklist.insert(insn.word(1)); /* image -- different operand order to above */ break; case spv::OpFunctionCall: for (uint32_t i = 3; i < insn.len(); i++) { worklist.insert(insn.word(i)); /* fn itself, and all args */ } break; case spv::OpExtInst: for (uint32_t i = 5; i < insn.len(); i++) { worklist.insert(insn.word(i)); /* operands to ext inst */ } break; } } break; } } return ids; } static bool validate_push_constant_block_against_pipeline(debug_report_data *report_data, std::vector const *push_constant_ranges, shader_module const *src, spirv_inst_iter type, VkShaderStageFlagBits stage) { bool pass = true; /* strip off ptrs etc */ type = get_struct_type(src, type, false); assert(type != src->end()); /* validate directly off the offsets. this isn't quite correct for arrays * and matrices, but is a good first step. TODO: arrays, matrices, weird * sizes */ for (auto insn : *src) { if (insn.opcode() == spv::OpMemberDecorate && insn.word(1) == type.word(1)) { if (insn.word(3) == spv::DecorationOffset) { unsigned offset = insn.word(4); auto size = 4; /* bytes; TODO: calculate this based on the type */ bool found_range = false; for (auto const &range : *push_constant_ranges) { if (range.offset <= offset && range.offset + range.size >= offset + size) { found_range = true; if ((range.stageFlags & stage) == 0) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_PUSH_CONSTANT_NOT_ACCESSIBLE_FROM_STAGE, "SC", "Push constant range covering variable starting at " "offset %u not accessible from stage %s", offset, string_VkShaderStageFlagBits(stage))) { pass = false; } } break; } } if (!found_range) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_PUSH_CONSTANT_OUT_OF_RANGE, "SC", "Push constant range covering variable starting at " "offset %u not declared in layout", offset)) { pass = false; } } } } } return pass; } static bool validate_push_constant_usage(debug_report_data *report_data, std::vector const *push_constant_ranges, shader_module const *src, std::unordered_set accessible_ids, VkShaderStageFlagBits stage) { bool pass = true; for (auto id : accessible_ids) { auto def_insn = src->get_def(id); if (def_insn.opcode() == spv::OpVariable && def_insn.word(3) == spv::StorageClassPushConstant) { pass &= validate_push_constant_block_against_pipeline(report_data, push_constant_ranges, src, src->get_def(def_insn.word(1)), stage); } } return pass; } // For given pipelineLayout verify that the set_layout_node at slot.first // has the requested binding at slot.second and return ptr to that binding static VkDescriptorSetLayoutBinding const * get_descriptor_binding(PIPELINE_LAYOUT_NODE const *pipelineLayout, descriptor_slot_t slot) { if (!pipelineLayout) return nullptr; if (slot.first >= pipelineLayout->set_layouts.size()) return nullptr; return pipelineLayout->set_layouts[slot.first]->GetDescriptorSetLayoutBindingPtrFromBinding(slot.second); } // Block of code at start here for managing/tracking Pipeline state that this layer cares about static uint64_t g_drawCount[NUM_DRAW_TYPES] = {0, 0, 0, 0}; // TODO : Should be tracking lastBound per commandBuffer and when draws occur, report based on that cmd buffer lastBound // Then need to synchronize the accesses based on cmd buffer so that if I'm reading state on one cmd buffer, updates // to that same cmd buffer by separate thread are not changing state from underneath us // Track the last cmd buffer touched by this thread static bool hasDrawCmd(GLOBAL_CB_NODE *pCB) { for (uint32_t i = 0; i < NUM_DRAW_TYPES; i++) { if (pCB->drawCount[i]) return true; } return false; } // Check object status for selected flag state static bool validate_status(layer_data *my_data, GLOBAL_CB_NODE *pNode, CBStatusFlags status_mask, VkFlags msg_flags, DRAW_STATE_ERROR error_code, const char *fail_msg) { if (!(pNode->status & status_mask)) { return log_msg(my_data->report_data, msg_flags, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(pNode->commandBuffer), __LINE__, error_code, "DS", "command buffer object 0x%" PRIxLEAST64 ": %s", reinterpret_cast(pNode->commandBuffer), fail_msg); } return false; } // Retrieve pipeline node ptr for given pipeline object static PIPELINE_STATE *getPipelineState(layer_data const *my_data, VkPipeline pipeline) { auto it = my_data->pipelineMap.find(pipeline); if (it == my_data->pipelineMap.end()) { return nullptr; } return it->second; } static RENDER_PASS_STATE *getRenderPassState(layer_data const *my_data, VkRenderPass renderpass) { auto it = my_data->renderPassMap.find(renderpass); if (it == my_data->renderPassMap.end()) { return nullptr; } return it->second.get(); } static FRAMEBUFFER_STATE *getFramebufferState(const layer_data *my_data, VkFramebuffer framebuffer) { auto it = my_data->frameBufferMap.find(framebuffer); if (it == my_data->frameBufferMap.end()) { return nullptr; } return it->second.get(); } cvdescriptorset::DescriptorSetLayout const *getDescriptorSetLayout(layer_data const *my_data, VkDescriptorSetLayout dsLayout) { auto it = my_data->descriptorSetLayoutMap.find(dsLayout); if (it == my_data->descriptorSetLayoutMap.end()) { return nullptr; } return it->second; } static PIPELINE_LAYOUT_NODE const *getPipelineLayout(layer_data const *my_data, VkPipelineLayout pipeLayout) { auto it = my_data->pipelineLayoutMap.find(pipeLayout); if (it == my_data->pipelineLayoutMap.end()) { return nullptr; } return &it->second; } // Return true if for a given PSO, the given state enum is dynamic, else return false static bool isDynamic(const PIPELINE_STATE *pPipeline, const VkDynamicState state) { if (pPipeline && pPipeline->graphicsPipelineCI.pDynamicState) { for (uint32_t i = 0; i < pPipeline->graphicsPipelineCI.pDynamicState->dynamicStateCount; i++) { if (state == pPipeline->graphicsPipelineCI.pDynamicState->pDynamicStates[i]) return true; } } return false; } // Validate state stored as flags at time of draw call static bool validate_draw_state_flags(layer_data *dev_data, GLOBAL_CB_NODE *pCB, const PIPELINE_STATE *pPipe, bool indexedDraw) { bool result = false; if (pPipe->graphicsPipelineCI.pInputAssemblyState && ((pPipe->graphicsPipelineCI.pInputAssemblyState->topology == VK_PRIMITIVE_TOPOLOGY_LINE_LIST) || (pPipe->graphicsPipelineCI.pInputAssemblyState->topology == VK_PRIMITIVE_TOPOLOGY_LINE_STRIP))) { result |= validate_status(dev_data, pCB, CBSTATUS_LINE_WIDTH_SET, VK_DEBUG_REPORT_ERROR_BIT_EXT, DRAWSTATE_LINE_WIDTH_NOT_BOUND, "Dynamic line width state not set for this command buffer"); } if (pPipe->graphicsPipelineCI.pRasterizationState && (pPipe->graphicsPipelineCI.pRasterizationState->depthBiasEnable == VK_TRUE)) { result |= validate_status(dev_data, pCB, CBSTATUS_DEPTH_BIAS_SET, VK_DEBUG_REPORT_ERROR_BIT_EXT, DRAWSTATE_DEPTH_BIAS_NOT_BOUND, "Dynamic depth bias state not set for this command buffer"); } if (pPipe->blendConstantsEnabled) { result |= validate_status(dev_data, pCB, CBSTATUS_BLEND_CONSTANTS_SET, VK_DEBUG_REPORT_ERROR_BIT_EXT, DRAWSTATE_BLEND_NOT_BOUND, "Dynamic blend constants state not set for this command buffer"); } if (pPipe->graphicsPipelineCI.pDepthStencilState && (pPipe->graphicsPipelineCI.pDepthStencilState->depthBoundsTestEnable == VK_TRUE)) { result |= validate_status(dev_data, pCB, CBSTATUS_DEPTH_BOUNDS_SET, VK_DEBUG_REPORT_ERROR_BIT_EXT, DRAWSTATE_DEPTH_BOUNDS_NOT_BOUND, "Dynamic depth bounds state not set for this command buffer"); } if (pPipe->graphicsPipelineCI.pDepthStencilState && (pPipe->graphicsPipelineCI.pDepthStencilState->stencilTestEnable == VK_TRUE)) { result |= validate_status(dev_data, pCB, CBSTATUS_STENCIL_READ_MASK_SET, VK_DEBUG_REPORT_ERROR_BIT_EXT, DRAWSTATE_STENCIL_NOT_BOUND, "Dynamic stencil read mask state not set for this command buffer"); result |= validate_status(dev_data, pCB, CBSTATUS_STENCIL_WRITE_MASK_SET, VK_DEBUG_REPORT_ERROR_BIT_EXT, DRAWSTATE_STENCIL_NOT_BOUND, "Dynamic stencil write mask state not set for this command buffer"); result |= validate_status(dev_data, pCB, CBSTATUS_STENCIL_REFERENCE_SET, VK_DEBUG_REPORT_ERROR_BIT_EXT, DRAWSTATE_STENCIL_NOT_BOUND, "Dynamic stencil reference state not set for this command buffer"); } if (indexedDraw) { result |= validate_status(dev_data, pCB, CBSTATUS_INDEX_BUFFER_BOUND, VK_DEBUG_REPORT_ERROR_BIT_EXT, DRAWSTATE_INDEX_BUFFER_NOT_BOUND, "Index buffer object not bound to this command buffer when Indexed Draw attempted"); } return result; } // Verify attachment reference compatibility according to spec // If one array is larger, treat missing elements of shorter array as VK_ATTACHMENT_UNUSED & other array much match this // If both AttachmentReference arrays have requested index, check their corresponding AttachmentDescriptions // to make sure that format and samples counts match. // If not, they are not compatible. static bool attachment_references_compatible(const uint32_t index, const VkAttachmentReference *pPrimary, const uint32_t primaryCount, const VkAttachmentDescription *pPrimaryAttachments, const VkAttachmentReference *pSecondary, const uint32_t secondaryCount, const VkAttachmentDescription *pSecondaryAttachments) { // Check potential NULL cases first to avoid nullptr issues later if (pPrimary == nullptr) { if (pSecondary == nullptr) { return true; } return false; } else if (pSecondary == nullptr) { return false; } if (index >= primaryCount) { // Check secondary as if primary is VK_ATTACHMENT_UNUSED if (VK_ATTACHMENT_UNUSED == pSecondary[index].attachment) return true; } else if (index >= secondaryCount) { // Check primary as if secondary is VK_ATTACHMENT_UNUSED if (VK_ATTACHMENT_UNUSED == pPrimary[index].attachment) return true; } else { // Format and sample count must match if ((pPrimary[index].attachment == VK_ATTACHMENT_UNUSED) && (pSecondary[index].attachment == VK_ATTACHMENT_UNUSED)) { return true; } else if ((pPrimary[index].attachment == VK_ATTACHMENT_UNUSED) || (pSecondary[index].attachment == VK_ATTACHMENT_UNUSED)) { return false; } if ((pPrimaryAttachments[pPrimary[index].attachment].format == pSecondaryAttachments[pSecondary[index].attachment].format) && (pPrimaryAttachments[pPrimary[index].attachment].samples == pSecondaryAttachments[pSecondary[index].attachment].samples)) return true; } // Format and sample counts didn't match return false; } // TODO : Scrub verify_renderpass_compatibility() and validateRenderPassCompatibility() and unify them and/or share code // For given primary RenderPass object and secondry RenderPassCreateInfo, verify that they're compatible static bool verify_renderpass_compatibility(const layer_data *my_data, const VkRenderPassCreateInfo *primaryRPCI, const VkRenderPassCreateInfo *secondaryRPCI, string &errorMsg) { if (primaryRPCI->subpassCount != secondaryRPCI->subpassCount) { stringstream errorStr; errorStr << "RenderPass for primary cmdBuffer has " << primaryRPCI->subpassCount << " subpasses but renderPass for secondary cmdBuffer has " << secondaryRPCI->subpassCount << " subpasses."; errorMsg = errorStr.str(); return false; } uint32_t spIndex = 0; for (spIndex = 0; spIndex < primaryRPCI->subpassCount; ++spIndex) { // For each subpass, verify that corresponding color, input, resolve & depth/stencil attachment references are compatible uint32_t primaryColorCount = primaryRPCI->pSubpasses[spIndex].colorAttachmentCount; uint32_t secondaryColorCount = secondaryRPCI->pSubpasses[spIndex].colorAttachmentCount; uint32_t colorMax = std::max(primaryColorCount, secondaryColorCount); for (uint32_t cIdx = 0; cIdx < colorMax; ++cIdx) { if (!attachment_references_compatible(cIdx, primaryRPCI->pSubpasses[spIndex].pColorAttachments, primaryColorCount, primaryRPCI->pAttachments, secondaryRPCI->pSubpasses[spIndex].pColorAttachments, secondaryColorCount, secondaryRPCI->pAttachments)) { stringstream errorStr; errorStr << "color attachments at index " << cIdx << " of subpass index " << spIndex << " are not compatible."; errorMsg = errorStr.str(); return false; } else if (!attachment_references_compatible(cIdx, primaryRPCI->pSubpasses[spIndex].pResolveAttachments, primaryColorCount, primaryRPCI->pAttachments, secondaryRPCI->pSubpasses[spIndex].pResolveAttachments, secondaryColorCount, secondaryRPCI->pAttachments)) { stringstream errorStr; errorStr << "resolve attachments at index " << cIdx << " of subpass index " << spIndex << " are not compatible."; errorMsg = errorStr.str(); return false; } } if (!attachment_references_compatible(0, primaryRPCI->pSubpasses[spIndex].pDepthStencilAttachment, 1, primaryRPCI->pAttachments, secondaryRPCI->pSubpasses[spIndex].pDepthStencilAttachment, 1, secondaryRPCI->pAttachments)) { stringstream errorStr; errorStr << "depth/stencil attachments of subpass index " << spIndex << " are not compatible."; errorMsg = errorStr.str(); return false; } uint32_t primaryInputCount = primaryRPCI->pSubpasses[spIndex].inputAttachmentCount; uint32_t secondaryInputCount = secondaryRPCI->pSubpasses[spIndex].inputAttachmentCount; uint32_t inputMax = std::max(primaryInputCount, secondaryInputCount); for (uint32_t i = 0; i < inputMax; ++i) { if (!attachment_references_compatible(i, primaryRPCI->pSubpasses[spIndex].pInputAttachments, primaryColorCount, primaryRPCI->pAttachments, secondaryRPCI->pSubpasses[spIndex].pInputAttachments, secondaryColorCount, secondaryRPCI->pAttachments)) { stringstream errorStr; errorStr << "input attachments at index " << i << " of subpass index " << spIndex << " are not compatible."; errorMsg = errorStr.str(); return false; } } } return true; } // For given cvdescriptorset::DescriptorSet, verify that its Set is compatible w/ the setLayout corresponding to // pipelineLayout[layoutIndex] static bool verify_set_layout_compatibility(layer_data *my_data, const cvdescriptorset::DescriptorSet *pSet, PIPELINE_LAYOUT_NODE const *pipeline_layout, const uint32_t layoutIndex, string &errorMsg) { auto num_sets = pipeline_layout->set_layouts.size(); if (layoutIndex >= num_sets) { stringstream errorStr; errorStr << "VkPipelineLayout (" << pipeline_layout->layout << ") only contains " << num_sets << " setLayouts corresponding to sets 0-" << num_sets - 1 << ", but you're attempting to bind set to index " << layoutIndex; errorMsg = errorStr.str(); return false; } auto layout_node = pipeline_layout->set_layouts[layoutIndex]; return pSet->IsCompatible(layout_node, &errorMsg); } // Validate that data for each specialization entry is fully contained within the buffer. static bool validate_specialization_offsets(debug_report_data *report_data, VkPipelineShaderStageCreateInfo const *info) { bool pass = true; VkSpecializationInfo const *spec = info->pSpecializationInfo; if (spec) { for (auto i = 0u; i < spec->mapEntryCount; i++) { if (spec->pMapEntries[i].offset + spec->pMapEntries[i].size > spec->dataSize) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_EXT, /*dev*/ 0, __LINE__, SHADER_CHECKER_BAD_SPECIALIZATION, "SC", "Specialization entry %u (for constant id %u) references memory outside provided " "specialization data (bytes %u.." PRINTF_SIZE_T_SPECIFIER "; " PRINTF_SIZE_T_SPECIFIER " bytes provided)", i, spec->pMapEntries[i].constantID, spec->pMapEntries[i].offset, spec->pMapEntries[i].offset + spec->pMapEntries[i].size - 1, spec->dataSize)) { pass = false; } } } } return pass; } static bool descriptor_type_match(shader_module const *module, uint32_t type_id, VkDescriptorType descriptor_type, unsigned &descriptor_count) { auto type = module->get_def(type_id); descriptor_count = 1; /* Strip off any array or ptrs. Where we remove array levels, adjust the * descriptor count for each dimension. */ while (type.opcode() == spv::OpTypeArray || type.opcode() == spv::OpTypePointer) { if (type.opcode() == spv::OpTypeArray) { descriptor_count *= get_constant_value(module, type.word(3)); type = module->get_def(type.word(2)); } else { type = module->get_def(type.word(3)); } } switch (type.opcode()) { case spv::OpTypeStruct: { for (auto insn : *module) { if (insn.opcode() == spv::OpDecorate && insn.word(1) == type.word(1)) { if (insn.word(2) == spv::DecorationBlock) { return descriptor_type == VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER || descriptor_type == VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC; } else if (insn.word(2) == spv::DecorationBufferBlock) { return descriptor_type == VK_DESCRIPTOR_TYPE_STORAGE_BUFFER || descriptor_type == VK_DESCRIPTOR_TYPE_STORAGE_BUFFER_DYNAMIC; } } } /* Invalid */ return false; } case spv::OpTypeSampler: return descriptor_type == VK_DESCRIPTOR_TYPE_SAMPLER || descriptor_type == VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER; case spv::OpTypeSampledImage: if (descriptor_type == VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER) { /* Slight relaxation for some GLSL historical madness: samplerBuffer * doesn't really have a sampler, and a texel buffer descriptor * doesn't really provide one. Allow this slight mismatch. */ auto image_type = module->get_def(type.word(2)); auto dim = image_type.word(3); auto sampled = image_type.word(7); return dim == spv::DimBuffer && sampled == 1; } return descriptor_type == VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER; case spv::OpTypeImage: { /* Many descriptor types backing image types-- depends on dimension * and whether the image will be used with a sampler. SPIRV for * Vulkan requires that sampled be 1 or 2 -- leaving the decision to * runtime is unacceptable. */ auto dim = type.word(3); auto sampled = type.word(7); if (dim == spv::DimSubpassData) { return descriptor_type == VK_DESCRIPTOR_TYPE_INPUT_ATTACHMENT; } else if (dim == spv::DimBuffer) { if (sampled == 1) { return descriptor_type == VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER; } else { return descriptor_type == VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER; } } else if (sampled == 1) { return descriptor_type == VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE || descriptor_type == VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER; } else { return descriptor_type == VK_DESCRIPTOR_TYPE_STORAGE_IMAGE; } } /* We shouldn't really see any other junk types -- but if we do, they're * a mismatch. */ default: return false; /* Mismatch */ } } static bool require_feature(debug_report_data *report_data, VkBool32 feature, char const *feature_name) { if (!feature) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_FEATURE_NOT_ENABLED, "SC", "Shader requires VkPhysicalDeviceFeatures::%s but is not " "enabled on the device", feature_name)) { return false; } } return true; } static bool validate_shader_capabilities(debug_report_data *report_data, shader_module const *src, VkPhysicalDeviceFeatures const *enabledFeatures) { bool pass = true; for (auto insn : *src) { if (insn.opcode() == spv::OpCapability) { switch (insn.word(1)) { case spv::CapabilityMatrix: case spv::CapabilityShader: case spv::CapabilityInputAttachment: case spv::CapabilitySampled1D: case spv::CapabilityImage1D: case spv::CapabilitySampledBuffer: case spv::CapabilityImageBuffer: case spv::CapabilityImageQuery: case spv::CapabilityDerivativeControl: // Always supported by a Vulkan 1.0 implementation -- no feature bits. break; case spv::CapabilityGeometry: pass &= require_feature(report_data, enabledFeatures->geometryShader, "geometryShader"); break; case spv::CapabilityTessellation: pass &= require_feature(report_data, enabledFeatures->tessellationShader, "tessellationShader"); break; case spv::CapabilityFloat64: pass &= require_feature(report_data, enabledFeatures->shaderFloat64, "shaderFloat64"); break; case spv::CapabilityInt64: pass &= require_feature(report_data, enabledFeatures->shaderInt64, "shaderInt64"); break; case spv::CapabilityTessellationPointSize: case spv::CapabilityGeometryPointSize: pass &= require_feature(report_data, enabledFeatures->shaderTessellationAndGeometryPointSize, "shaderTessellationAndGeometryPointSize"); break; case spv::CapabilityImageGatherExtended: pass &= require_feature(report_data, enabledFeatures->shaderImageGatherExtended, "shaderImageGatherExtended"); break; case spv::CapabilityStorageImageMultisample: pass &= require_feature(report_data, enabledFeatures->shaderStorageImageMultisample, "shaderStorageImageMultisample"); break; case spv::CapabilityUniformBufferArrayDynamicIndexing: pass &= require_feature(report_data, enabledFeatures->shaderUniformBufferArrayDynamicIndexing, "shaderUniformBufferArrayDynamicIndexing"); break; case spv::CapabilitySampledImageArrayDynamicIndexing: pass &= require_feature(report_data, enabledFeatures->shaderSampledImageArrayDynamicIndexing, "shaderSampledImageArrayDynamicIndexing"); break; case spv::CapabilityStorageBufferArrayDynamicIndexing: pass &= require_feature(report_data, enabledFeatures->shaderStorageBufferArrayDynamicIndexing, "shaderStorageBufferArrayDynamicIndexing"); break; case spv::CapabilityStorageImageArrayDynamicIndexing: pass &= require_feature(report_data, enabledFeatures->shaderStorageImageArrayDynamicIndexing, "shaderStorageImageArrayDynamicIndexing"); break; case spv::CapabilityClipDistance: pass &= require_feature(report_data, enabledFeatures->shaderClipDistance, "shaderClipDistance"); break; case spv::CapabilityCullDistance: pass &= require_feature(report_data, enabledFeatures->shaderCullDistance, "shaderCullDistance"); break; case spv::CapabilityImageCubeArray: pass &= require_feature(report_data, enabledFeatures->imageCubeArray, "imageCubeArray"); break; case spv::CapabilitySampleRateShading: pass &= require_feature(report_data, enabledFeatures->sampleRateShading, "sampleRateShading"); break; case spv::CapabilitySparseResidency: pass &= require_feature(report_data, enabledFeatures->shaderResourceResidency, "shaderResourceResidency"); break; case spv::CapabilityMinLod: pass &= require_feature(report_data, enabledFeatures->shaderResourceMinLod, "shaderResourceMinLod"); break; case spv::CapabilitySampledCubeArray: pass &= require_feature(report_data, enabledFeatures->imageCubeArray, "imageCubeArray"); break; case spv::CapabilityImageMSArray: pass &= require_feature(report_data, enabledFeatures->shaderStorageImageMultisample, "shaderStorageImageMultisample"); break; case spv::CapabilityStorageImageExtendedFormats: pass &= require_feature(report_data, enabledFeatures->shaderStorageImageExtendedFormats, "shaderStorageImageExtendedFormats"); break; case spv::CapabilityInterpolationFunction: pass &= require_feature(report_data, enabledFeatures->sampleRateShading, "sampleRateShading"); break; case spv::CapabilityStorageImageReadWithoutFormat: pass &= require_feature(report_data, enabledFeatures->shaderStorageImageReadWithoutFormat, "shaderStorageImageReadWithoutFormat"); break; case spv::CapabilityStorageImageWriteWithoutFormat: pass &= require_feature(report_data, enabledFeatures->shaderStorageImageWriteWithoutFormat, "shaderStorageImageWriteWithoutFormat"); break; case spv::CapabilityMultiViewport: pass &= require_feature(report_data, enabledFeatures->multiViewport, "multiViewport"); break; default: if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_BAD_CAPABILITY, "SC", "Shader declares capability %u, not supported in Vulkan.", insn.word(1))) pass = false; break; } } } return pass; } static uint32_t descriptor_type_to_reqs(shader_module const *module, uint32_t type_id) { auto type = module->get_def(type_id); while (true) { switch (type.opcode()) { case spv::OpTypeArray: case spv::OpTypeSampledImage: type = module->get_def(type.word(2)); break; case spv::OpTypePointer: type = module->get_def(type.word(3)); break; case spv::OpTypeImage: { auto dim = type.word(3); auto arrayed = type.word(5); auto msaa = type.word(6); switch (dim) { case spv::Dim1D: return arrayed ? DESCRIPTOR_REQ_VIEW_TYPE_1D_ARRAY : DESCRIPTOR_REQ_VIEW_TYPE_1D; case spv::Dim2D: return (msaa ? DESCRIPTOR_REQ_MULTI_SAMPLE : DESCRIPTOR_REQ_SINGLE_SAMPLE) | (arrayed ? DESCRIPTOR_REQ_VIEW_TYPE_2D_ARRAY : DESCRIPTOR_REQ_VIEW_TYPE_2D); case spv::Dim3D: return DESCRIPTOR_REQ_VIEW_TYPE_3D; case spv::DimCube: return arrayed ? DESCRIPTOR_REQ_VIEW_TYPE_CUBE_ARRAY : DESCRIPTOR_REQ_VIEW_TYPE_CUBE; case spv::DimSubpassData: return msaa ? DESCRIPTOR_REQ_MULTI_SAMPLE : DESCRIPTOR_REQ_SINGLE_SAMPLE; default: // buffer, etc. return 0; } } default: return 0; } } } static bool validate_pipeline_shader_stage(debug_report_data *report_data, VkPipelineShaderStageCreateInfo const *pStage, PIPELINE_STATE *pipeline, shader_module **out_module, spirv_inst_iter *out_entrypoint, VkPhysicalDeviceFeatures const *enabledFeatures, std::unordered_map> const &shaderModuleMap) { bool pass = true; auto module_it = shaderModuleMap.find(pStage->module); auto module = *out_module = module_it->second.get(); /* find the entrypoint */ auto entrypoint = *out_entrypoint = find_entrypoint(module, pStage->pName, pStage->stage); if (entrypoint == module->end()) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_MISSING_ENTRYPOINT, "SC", "No entrypoint found named `%s` for stage %s", pStage->pName, string_VkShaderStageFlagBits(pStage->stage))) { return false; // no point continuing beyond here, any analysis is just going to be garbage. } } /* validate shader capabilities against enabled device features */ pass &= validate_shader_capabilities(report_data, module, enabledFeatures); /* mark accessible ids */ auto accessible_ids = mark_accessible_ids(module, entrypoint); /* validate descriptor set layout against what the entrypoint actually uses */ auto descriptor_uses = collect_interface_by_descriptor_slot(report_data, module, accessible_ids); auto pipelineLayout = pipeline->pipeline_layout; pass &= validate_specialization_offsets(report_data, pStage); pass &= validate_push_constant_usage(report_data, &pipelineLayout.push_constant_ranges, module, accessible_ids, pStage->stage); /* validate descriptor use */ for (auto use : descriptor_uses) { // While validating shaders capture which slots are used by the pipeline auto & reqs = pipeline->active_slots[use.first.first][use.first.second]; reqs = descriptor_req(reqs | descriptor_type_to_reqs(module, use.second.type_id)); /* verify given pipelineLayout has requested setLayout with requested binding */ const auto &binding = get_descriptor_binding(&pipelineLayout, use.first); unsigned required_descriptor_count; if (!binding) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_MISSING_DESCRIPTOR, "SC", "Shader uses descriptor slot %u.%u (used as type `%s`) but not declared in pipeline layout", use.first.first, use.first.second, describe_type(module, use.second.type_id).c_str())) { pass = false; } } else if (~binding->stageFlags & pStage->stage) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_EXT, /*dev*/ 0, __LINE__, SHADER_CHECKER_DESCRIPTOR_NOT_ACCESSIBLE_FROM_STAGE, "SC", "Shader uses descriptor slot %u.%u (used " "as type `%s`) but descriptor not " "accessible from stage %s", use.first.first, use.first.second, describe_type(module, use.second.type_id).c_str(), string_VkShaderStageFlagBits(pStage->stage))) { pass = false; } } else if (!descriptor_type_match(module, use.second.type_id, binding->descriptorType, /*out*/ required_descriptor_count)) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_DESCRIPTOR_TYPE_MISMATCH, "SC", "Type mismatch on descriptor slot " "%u.%u (used as type `%s`) but " "descriptor of type %s", use.first.first, use.first.second, describe_type(module, use.second.type_id).c_str(), string_VkDescriptorType(binding->descriptorType))) { pass = false; } } else if (binding->descriptorCount < required_descriptor_count) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_DESCRIPTOR_TYPE_MISMATCH, "SC", "Shader expects at least %u descriptors for binding %u.%u (used as type `%s`) but only %u provided", required_descriptor_count, use.first.first, use.first.second, describe_type(module, use.second.type_id).c_str(), binding->descriptorCount)) { pass = false; } } } /* validate use of input attachments against subpass structure */ if (pStage->stage == VK_SHADER_STAGE_FRAGMENT_BIT) { auto input_attachment_uses = collect_interface_by_input_attachment_index(report_data, module, accessible_ids); auto rpci = pipeline->render_pass_ci.ptr(); auto subpass = pipeline->graphicsPipelineCI.subpass; for (auto use : input_attachment_uses) { auto input_attachments = rpci->pSubpasses[subpass].pInputAttachments; auto index = (input_attachments && use.first < rpci->pSubpasses[subpass].inputAttachmentCount) ? input_attachments[use.first].attachment : VK_ATTACHMENT_UNUSED; if (index == VK_ATTACHMENT_UNUSED) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_MISSING_INPUT_ATTACHMENT, "SC", "Shader consumes input attachment index %d but not provided in subpass", use.first)) { pass = false; } } else if (get_format_type(rpci->pAttachments[index].format) != get_fundamental_type(module, use.second.type_id)) { if (log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_INPUT_ATTACHMENT_TYPE_MISMATCH, "SC", "Subpass input attachment %u format of %s does not match type used in shader `%s`", use.first, string_VkFormat(rpci->pAttachments[index].format), describe_type(module, use.second.type_id).c_str())) { pass = false; } } } } return pass; } // Validate that the shaders used by the given pipeline and store the active_slots // that are actually used by the pipeline into pPipeline->active_slots static bool validate_and_capture_pipeline_shader_state(debug_report_data *report_data, PIPELINE_STATE *pPipeline, VkPhysicalDeviceFeatures const *enabledFeatures, std::unordered_map> const &shaderModuleMap) { auto pCreateInfo = pPipeline->graphicsPipelineCI.ptr(); int vertex_stage = get_shader_stage_id(VK_SHADER_STAGE_VERTEX_BIT); int fragment_stage = get_shader_stage_id(VK_SHADER_STAGE_FRAGMENT_BIT); shader_module *shaders[5]; memset(shaders, 0, sizeof(shaders)); spirv_inst_iter entrypoints[5]; memset(entrypoints, 0, sizeof(entrypoints)); VkPipelineVertexInputStateCreateInfo const *vi = 0; bool pass = true; for (uint32_t i = 0; i < pCreateInfo->stageCount; i++) { auto pStage = &pCreateInfo->pStages[i]; auto stage_id = get_shader_stage_id(pStage->stage); pass &= validate_pipeline_shader_stage(report_data, pStage, pPipeline, &shaders[stage_id], &entrypoints[stage_id], enabledFeatures, shaderModuleMap); } // if the shader stages are no good individually, cross-stage validation is pointless. if (!pass) return false; vi = pCreateInfo->pVertexInputState; if (vi) { pass &= validate_vi_consistency(report_data, vi); } if (shaders[vertex_stage]) { pass &= validate_vi_against_vs_inputs(report_data, vi, shaders[vertex_stage], entrypoints[vertex_stage]); } int producer = get_shader_stage_id(VK_SHADER_STAGE_VERTEX_BIT); int consumer = get_shader_stage_id(VK_SHADER_STAGE_TESSELLATION_CONTROL_BIT); while (!shaders[producer] && producer != fragment_stage) { producer++; consumer++; } for (; producer != fragment_stage && consumer <= fragment_stage; consumer++) { assert(shaders[producer]); if (shaders[consumer]) { pass &= validate_interface_between_stages(report_data, shaders[producer], entrypoints[producer], &shader_stage_attribs[producer], shaders[consumer], entrypoints[consumer], &shader_stage_attribs[consumer]); producer = consumer; } } if (shaders[fragment_stage]) { pass &= validate_fs_outputs_against_render_pass(report_data, shaders[fragment_stage], entrypoints[fragment_stage], pPipeline->render_pass_ci.ptr(), pCreateInfo->subpass); } return pass; } static bool validate_compute_pipeline(debug_report_data *report_data, PIPELINE_STATE *pPipeline, VkPhysicalDeviceFeatures const *enabledFeatures, std::unordered_map> const &shaderModuleMap) { auto pCreateInfo = pPipeline->computePipelineCI.ptr(); shader_module *module; spirv_inst_iter entrypoint; return validate_pipeline_shader_stage(report_data, &pCreateInfo->stage, pPipeline, &module, &entrypoint, enabledFeatures, shaderModuleMap); } // Return Set node ptr for specified set or else NULL cvdescriptorset::DescriptorSet *getSetNode(const layer_data *my_data, VkDescriptorSet set) { auto set_it = my_data->setMap.find(set); if (set_it == my_data->setMap.end()) { return NULL; } return set_it->second; } // For the given command buffer, verify and update the state for activeSetBindingsPairs // This includes: // 1. Verifying that any dynamic descriptor in that set has a valid dynamic offset bound. // To be valid, the dynamic offset combined with the offset and range from its // descriptor update must not overflow the size of its buffer being updated // 2. Grow updateImages for given pCB to include any bound STORAGE_IMAGE descriptor images // 3. Grow updateBuffers for pCB to include buffers from STORAGE*_BUFFER descriptor buffers static bool validate_and_update_drawtime_descriptor_state( layer_data *dev_data, GLOBAL_CB_NODE *pCB, const vector, std::vector const *>> &activeSetBindingsPairs, const char *function) { bool result = false; for (auto set_bindings_pair : activeSetBindingsPairs) { cvdescriptorset::DescriptorSet *set_node = std::get<0>(set_bindings_pair); std::string err_str; if (!set_node->ValidateDrawState(std::get<1>(set_bindings_pair), *std::get<2>(set_bindings_pair), &err_str)) { // Report error here auto set = set_node->GetSet(); result |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT, reinterpret_cast(set), __LINE__, DRAWSTATE_DESCRIPTOR_SET_NOT_UPDATED, "DS", "Descriptor set 0x%" PRIxLEAST64 " encountered the following validation error at %s() time: %s", reinterpret_cast(set), function, err_str.c_str()); } set_node->GetStorageUpdates(std::get<1>(set_bindings_pair), &pCB->updateBuffers, &pCB->updateImages); } return result; } // For given pipeline, return number of MSAA samples, or one if MSAA disabled static VkSampleCountFlagBits getNumSamples(PIPELINE_STATE const *pipe) { if (pipe->graphicsPipelineCI.pMultisampleState != NULL && VK_STRUCTURE_TYPE_PIPELINE_MULTISAMPLE_STATE_CREATE_INFO == pipe->graphicsPipelineCI.pMultisampleState->sType) { return pipe->graphicsPipelineCI.pMultisampleState->rasterizationSamples; } return VK_SAMPLE_COUNT_1_BIT; } static void list_bits(std::ostream& s, uint32_t bits) { for (int i = 0; i < 32 && bits; i++) { if (bits & (1 << i)) { s << i; bits &= ~(1 << i); if (bits) { s << ","; } } } } // Validate draw-time state related to the PSO static bool validatePipelineDrawtimeState(layer_data const *my_data, LAST_BOUND_STATE const &state, const GLOBAL_CB_NODE *pCB, PIPELINE_STATE const *pPipeline) { bool skip_call = false; // Verify vertex binding if (pPipeline->vertexBindingDescriptions.size() > 0) { for (size_t i = 0; i < pPipeline->vertexBindingDescriptions.size(); i++) { auto vertex_binding = pPipeline->vertexBindingDescriptions[i].binding; if ((pCB->currentDrawData.buffers.size() < (vertex_binding + 1)) || (pCB->currentDrawData.buffers[vertex_binding] == VK_NULL_HANDLE)) { skip_call |= log_msg( my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_VTX_INDEX_OUT_OF_BOUNDS, "DS", "The Pipeline State Object (0x%" PRIxLEAST64 ") expects that this Command Buffer's vertex binding Index %u " "should be set via vkCmdBindVertexBuffers. This is because VkVertexInputBindingDescription struct " "at index " PRINTF_SIZE_T_SPECIFIER " of pVertexBindingDescriptions has a binding value of %u.", (uint64_t)state.pipeline_state->pipeline, vertex_binding, i, vertex_binding); } } } else { if (!pCB->currentDrawData.buffers.empty()) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_PERFORMANCE_WARNING_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_VTX_INDEX_OUT_OF_BOUNDS, "DS", "Vertex buffers are bound to command buffer (0x%" PRIxLEAST64 ") but no vertex buffers are attached to this Pipeline State Object (0x%" PRIxLEAST64 ").", (uint64_t)pCB->commandBuffer, (uint64_t)state.pipeline_state->pipeline); } } // If Viewport or scissors are dynamic, verify that dynamic count matches PSO count. // Skip check if rasterization is disabled or there is no viewport. if ((!pPipeline->graphicsPipelineCI.pRasterizationState || (pPipeline->graphicsPipelineCI.pRasterizationState->rasterizerDiscardEnable == VK_FALSE)) && pPipeline->graphicsPipelineCI.pViewportState) { bool dynViewport = isDynamic(pPipeline, VK_DYNAMIC_STATE_VIEWPORT); bool dynScissor = isDynamic(pPipeline, VK_DYNAMIC_STATE_SCISSOR); if (dynViewport) { auto requiredViewportsMask = (1 << pPipeline->graphicsPipelineCI.pViewportState->viewportCount) - 1; auto missingViewportMask = ~pCB->viewportMask & requiredViewportsMask; if (missingViewportMask) { std::stringstream ss; ss << "Dynamic viewport(s) "; list_bits(ss, missingViewportMask); ss << " are used by pipeline state object, but were not provided via calls to vkCmdSetViewport()."; skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, DRAWSTATE_VIEWPORT_SCISSOR_MISMATCH, "DS", "%s", ss.str().c_str()); } } if (dynScissor) { auto requiredScissorMask = (1 << pPipeline->graphicsPipelineCI.pViewportState->scissorCount) - 1; auto missingScissorMask = ~pCB->scissorMask & requiredScissorMask; if (missingScissorMask) { std::stringstream ss; ss << "Dynamic scissor(s) "; list_bits(ss, missingScissorMask); ss << " are used by pipeline state object, but were not provided via calls to vkCmdSetScissor()."; skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, DRAWSTATE_VIEWPORT_SCISSOR_MISMATCH, "DS", "%s", ss.str().c_str()); } } } // Verify that any MSAA request in PSO matches sample# in bound FB // Skip the check if rasterization is disabled. if (!pPipeline->graphicsPipelineCI.pRasterizationState || (pPipeline->graphicsPipelineCI.pRasterizationState->rasterizerDiscardEnable == VK_FALSE)) { VkSampleCountFlagBits pso_num_samples = getNumSamples(pPipeline); if (pCB->activeRenderPass) { auto const render_pass_info = pCB->activeRenderPass->createInfo.ptr(); const VkSubpassDescription *subpass_desc = &render_pass_info->pSubpasses[pCB->activeSubpass]; uint32_t i; const safe_VkPipelineColorBlendStateCreateInfo *color_blend_state = pPipeline->graphicsPipelineCI.pColorBlendState; if ((color_blend_state != NULL) && (pCB->activeSubpass == pPipeline->graphicsPipelineCI.subpass) && (color_blend_state->attachmentCount != subpass_desc->colorAttachmentCount)) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PIPELINE_EXT, reinterpret_cast(pPipeline->pipeline), __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "Render pass subpass %u mismatch with blending state defined and blend state attachment " "count %u while subpass color attachment count %u in Pipeline (0x%" PRIxLEAST64 ")! These " "must be the same at draw-time.", pCB->activeSubpass, color_blend_state->attachmentCount, subpass_desc->colorAttachmentCount, reinterpret_cast(pPipeline->pipeline)); } unsigned subpass_num_samples = 0; for (i = 0; i < subpass_desc->colorAttachmentCount; i++) { auto attachment = subpass_desc->pColorAttachments[i].attachment; if (attachment != VK_ATTACHMENT_UNUSED) subpass_num_samples |= (unsigned)render_pass_info->pAttachments[attachment].samples; } if (subpass_desc->pDepthStencilAttachment && subpass_desc->pDepthStencilAttachment->attachment != VK_ATTACHMENT_UNUSED) { auto attachment = subpass_desc->pDepthStencilAttachment->attachment; subpass_num_samples |= (unsigned)render_pass_info->pAttachments[attachment].samples; } if (subpass_num_samples && static_cast(pso_num_samples) != subpass_num_samples) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PIPELINE_EXT, reinterpret_cast(pPipeline->pipeline), __LINE__, DRAWSTATE_NUM_SAMPLES_MISMATCH, "DS", "Num samples mismatch! At draw-time in Pipeline (0x%" PRIxLEAST64 ") with %u samples while current RenderPass (0x%" PRIxLEAST64 ") w/ %u samples!", reinterpret_cast(pPipeline->pipeline), pso_num_samples, reinterpret_cast(pCB->activeRenderPass->renderPass), subpass_num_samples); } } else { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PIPELINE_EXT, reinterpret_cast(pPipeline->pipeline), __LINE__, DRAWSTATE_NUM_SAMPLES_MISMATCH, "DS", "No active render pass found at draw-time in Pipeline (0x%" PRIxLEAST64 ")!", reinterpret_cast(pPipeline->pipeline)); } } // Verify that PSO creation renderPass is compatible with active renderPass if (pCB->activeRenderPass) { std::string err_string; if ((pCB->activeRenderPass->renderPass != pPipeline->graphicsPipelineCI.renderPass) && !verify_renderpass_compatibility(my_data, pCB->activeRenderPass->createInfo.ptr(), pPipeline->render_pass_ci.ptr(), err_string)) { // renderPass that PSO was created with must be compatible with active renderPass that PSO is being used with skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PIPELINE_EXT, reinterpret_cast(pPipeline->pipeline), __LINE__, DRAWSTATE_RENDERPASS_INCOMPATIBLE, "DS", "At Draw time the active render pass (0x%" PRIxLEAST64 ") is incompatible w/ gfx pipeline " "(0x%" PRIxLEAST64 ") that was created w/ render pass (0x%" PRIxLEAST64 ") due to: %s", reinterpret_cast(pCB->activeRenderPass->renderPass), reinterpret_cast(pPipeline->pipeline), reinterpret_cast(pPipeline->graphicsPipelineCI.renderPass), err_string.c_str()); } if (pPipeline->graphicsPipelineCI.subpass != pCB->activeSubpass) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PIPELINE_EXT, reinterpret_cast(pPipeline->pipeline), __LINE__, DRAWSTATE_RENDERPASS_INCOMPATIBLE, "DS", "Pipeline was built for subpass %u but used in subpass %u", pPipeline->graphicsPipelineCI.subpass, pCB->activeSubpass); } } // TODO : Add more checks here return skip_call; } // Validate overall state at the time of a draw call static bool validate_and_update_draw_state(layer_data *my_data, GLOBAL_CB_NODE *cb_node, const bool indexedDraw, const VkPipelineBindPoint bindPoint, const char *function) { bool result = false; auto const &state = cb_node->lastBound[bindPoint]; PIPELINE_STATE *pPipe = state.pipeline_state; if (nullptr == pPipe) { result |= log_msg( my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, DRAWSTATE_INVALID_PIPELINE, "DS", "At Draw/Dispatch time no valid VkPipeline is bound! This is illegal. Please bind one with vkCmdBindPipeline()."); // Early return as any further checks below will be busted w/o a pipeline if (result) return true; } // First check flag states if (VK_PIPELINE_BIND_POINT_GRAPHICS == bindPoint) result = validate_draw_state_flags(my_data, cb_node, pPipe, indexedDraw); // Now complete other state checks if (VK_NULL_HANDLE != state.pipeline_layout.layout) { string errorString; auto pipeline_layout = pPipe->pipeline_layout; // Need a vector (vs. std::set) of active Sets for dynamicOffset validation in case same set bound w/ different offsets vector, std::vector const *>> activeSetBindingsPairs; for (auto & setBindingPair : pPipe->active_slots) { uint32_t setIndex = setBindingPair.first; // If valid set is not bound throw an error if ((state.boundDescriptorSets.size() <= setIndex) || (!state.boundDescriptorSets[setIndex])) { result |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_DESCRIPTOR_SET_NOT_BOUND, "DS", "VkPipeline 0x%" PRIxLEAST64 " uses set #%u but that set is not bound.", (uint64_t)pPipe->pipeline, setIndex); } else if (!verify_set_layout_compatibility(my_data, state.boundDescriptorSets[setIndex], &pipeline_layout, setIndex, errorString)) { // Set is bound but not compatible w/ overlapping pipeline_layout from PSO VkDescriptorSet setHandle = state.boundDescriptorSets[setIndex]->GetSet(); result |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT, (uint64_t)setHandle, __LINE__, DRAWSTATE_PIPELINE_LAYOUTS_INCOMPATIBLE, "DS", "VkDescriptorSet (0x%" PRIxLEAST64 ") bound as set #%u is not compatible with overlapping VkPipelineLayout 0x%" PRIxLEAST64 " due to: %s", reinterpret_cast(setHandle), setIndex, reinterpret_cast(pipeline_layout.layout), errorString.c_str()); } else { // Valid set is bound and layout compatible, validate that it's updated // Pull the set node cvdescriptorset::DescriptorSet *pSet = state.boundDescriptorSets[setIndex]; // Gather active bindings std::unordered_set bindings; for (auto binding : setBindingPair.second) { bindings.insert(binding.first); } // Bind this set and its active descriptor resources to the command buffer pSet->BindCommandBuffer(cb_node, bindings); // Save vector of all active sets to verify dynamicOffsets below activeSetBindingsPairs.push_back(std::make_tuple(pSet, setBindingPair.second, &state.dynamicOffsets[setIndex])); // Make sure set has been updated if it has no immutable samplers // If it has immutable samplers, we'll flag error later as needed depending on binding if (!pSet->IsUpdated()) { for (auto binding : bindings) { if (!pSet->GetImmutableSamplerPtrFromBinding(binding)) { result |= log_msg( my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT, (uint64_t)pSet->GetSet(), __LINE__, DRAWSTATE_DESCRIPTOR_SET_NOT_UPDATED, "DS", "Descriptor Set 0x%" PRIxLEAST64 " bound but was never updated. It is now being used to draw so " "this will result in undefined behavior.", (uint64_t)pSet->GetSet()); } } } } } // For given active slots, verify any dynamic descriptors and record updated images & buffers result |= validate_and_update_drawtime_descriptor_state(my_data, cb_node, activeSetBindingsPairs, function); } // Check general pipeline state that needs to be validated at drawtime if (VK_PIPELINE_BIND_POINT_GRAPHICS == bindPoint) result |= validatePipelineDrawtimeState(my_data, state, cb_node, pPipe); return result; } // Validate HW line width capabilities prior to setting requested line width. static bool verifyLineWidth(layer_data *my_data, DRAW_STATE_ERROR dsError, const uint64_t &target, float lineWidth) { bool skip_call = false; // First check to see if the physical device supports wide lines. if ((VK_FALSE == my_data->enabled_features.wideLines) && (1.0f != lineWidth)) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, target, __LINE__, dsError, "DS", "Attempt to set lineWidth to %f but physical device wideLines feature " "not supported/enabled so lineWidth must be 1.0f!", lineWidth); } else { // Otherwise, make sure the width falls in the valid range. if ((my_data->phys_dev_properties.properties.limits.lineWidthRange[0] > lineWidth) || (my_data->phys_dev_properties.properties.limits.lineWidthRange[1] < lineWidth)) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, target, __LINE__, dsError, "DS", "Attempt to set lineWidth to %f but physical device limits line width " "to between [%f, %f]!", lineWidth, my_data->phys_dev_properties.properties.limits.lineWidthRange[0], my_data->phys_dev_properties.properties.limits.lineWidthRange[1]); } } return skip_call; } // Verify that create state for a pipeline is valid static bool verifyPipelineCreateState(layer_data *my_data, std::vector pPipelines, int pipelineIndex) { bool skip_call = false; PIPELINE_STATE *pPipeline = pPipelines[pipelineIndex]; // If create derivative bit is set, check that we've specified a base // pipeline correctly, and that the base pipeline was created to allow // derivatives. if (pPipeline->graphicsPipelineCI.flags & VK_PIPELINE_CREATE_DERIVATIVE_BIT) { PIPELINE_STATE *pBasePipeline = nullptr; if (!((pPipeline->graphicsPipelineCI.basePipelineHandle != VK_NULL_HANDLE) ^ (pPipeline->graphicsPipelineCI.basePipelineIndex != -1))) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_PIPELINE_CREATE_STATE, "DS", "Invalid Pipeline CreateInfo: exactly one of base pipeline index and handle must be specified"); } else if (pPipeline->graphicsPipelineCI.basePipelineIndex != -1) { if (pPipeline->graphicsPipelineCI.basePipelineIndex >= pipelineIndex) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_PIPELINE_CREATE_STATE, "DS", "Invalid Pipeline CreateInfo: base pipeline must occur earlier in array than derivative pipeline."); } else { pBasePipeline = pPipelines[pPipeline->graphicsPipelineCI.basePipelineIndex]; } } else if (pPipeline->graphicsPipelineCI.basePipelineHandle != VK_NULL_HANDLE) { pBasePipeline = getPipelineState(my_data, pPipeline->graphicsPipelineCI.basePipelineHandle); } if (pBasePipeline && !(pBasePipeline->graphicsPipelineCI.flags & VK_PIPELINE_CREATE_ALLOW_DERIVATIVES_BIT)) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_PIPELINE_CREATE_STATE, "DS", "Invalid Pipeline CreateInfo: base pipeline does not allow derivatives."); } } if (pPipeline->graphicsPipelineCI.pColorBlendState != NULL) { if (!my_data->enabled_features.independentBlend) { if (pPipeline->attachments.size() > 1) { VkPipelineColorBlendAttachmentState *pAttachments = &pPipeline->attachments[0]; for (size_t i = 1; i < pPipeline->attachments.size(); i++) { // Quoting the spec: "If [the independent blend] feature is not enabled, the VkPipelineColorBlendAttachmentState // settings for all color attachments must be identical." VkPipelineColorBlendAttachmentState contains // only attachment state, so memcmp is best suited for the comparison if (memcmp(static_cast(pAttachments), static_cast(&pAttachments[i]), sizeof(pAttachments[0]))) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INDEPENDENT_BLEND, "DS", "Invalid Pipeline CreateInfo: If independent blend feature not " "enabled, all elements of pAttachments must be identical"); break; } } } } if (!my_data->enabled_features.logicOp && (pPipeline->graphicsPipelineCI.pColorBlendState->logicOpEnable != VK_FALSE)) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_DISABLED_LOGIC_OP, "DS", "Invalid Pipeline CreateInfo: If logic operations feature not enabled, logicOpEnable must be VK_FALSE"); } } // Ensure the subpass index is valid. If not, then validate_and_capture_pipeline_shader_state // produces nonsense errors that confuse users. Other layers should already // emit errors for renderpass being invalid. auto renderPass = getRenderPassState(my_data, pPipeline->graphicsPipelineCI.renderPass); if (renderPass && pPipeline->graphicsPipelineCI.subpass >= renderPass->createInfo.subpassCount) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_PIPELINE_CREATE_STATE, "DS", "Invalid Pipeline CreateInfo State: Subpass index %u " "is out of range for this renderpass (0..%u)", pPipeline->graphicsPipelineCI.subpass, renderPass->createInfo.subpassCount - 1); } if (!validate_and_capture_pipeline_shader_state(my_data->report_data, pPipeline, &my_data->enabled_features, my_data->shaderModuleMap)) { skip_call = true; } // Each shader's stage must be unique if (pPipeline->duplicate_shaders) { for (uint32_t stage = VK_SHADER_STAGE_VERTEX_BIT; stage & VK_SHADER_STAGE_ALL_GRAPHICS; stage <<= 1) { if (pPipeline->duplicate_shaders & stage) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, DRAWSTATE_INVALID_PIPELINE_CREATE_STATE, "DS", "Invalid Pipeline CreateInfo State: Multiple shaders provided for stage %s", string_VkShaderStageFlagBits(VkShaderStageFlagBits(stage))); } } } // VS is required if (!(pPipeline->active_shaders & VK_SHADER_STAGE_VERTEX_BIT)) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_PIPELINE_CREATE_STATE, "DS", "Invalid Pipeline CreateInfo State: Vertex Shader required"); } // Either both or neither TC/TE shaders should be defined if (((pPipeline->active_shaders & VK_SHADER_STAGE_TESSELLATION_CONTROL_BIT) == 0) != ((pPipeline->active_shaders & VK_SHADER_STAGE_TESSELLATION_EVALUATION_BIT) == 0)) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_PIPELINE_CREATE_STATE, "DS", "Invalid Pipeline CreateInfo State: TE and TC shaders must be included or excluded as a pair"); } // Compute shaders should be specified independent of Gfx shaders if ((pPipeline->active_shaders & VK_SHADER_STAGE_COMPUTE_BIT) && (pPipeline->active_shaders & (VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_TESSELLATION_CONTROL_BIT | VK_SHADER_STAGE_TESSELLATION_EVALUATION_BIT | VK_SHADER_STAGE_GEOMETRY_BIT | VK_SHADER_STAGE_FRAGMENT_BIT))) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_PIPELINE_CREATE_STATE, "DS", "Invalid Pipeline CreateInfo State: Do not specify Compute Shader for Gfx Pipeline"); } // VK_PRIMITIVE_TOPOLOGY_PATCH_LIST primitive topology is only valid for tessellation pipelines. // Mismatching primitive topology and tessellation fails graphics pipeline creation. if (pPipeline->active_shaders & (VK_SHADER_STAGE_TESSELLATION_CONTROL_BIT | VK_SHADER_STAGE_TESSELLATION_EVALUATION_BIT) && (!pPipeline->graphicsPipelineCI.pInputAssemblyState || pPipeline->graphicsPipelineCI.pInputAssemblyState->topology != VK_PRIMITIVE_TOPOLOGY_PATCH_LIST)) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_PIPELINE_CREATE_STATE, "DS", "Invalid Pipeline CreateInfo State: " "VK_PRIMITIVE_TOPOLOGY_PATCH_LIST must be set as IA " "topology for tessellation pipelines"); } if (pPipeline->graphicsPipelineCI.pInputAssemblyState && pPipeline->graphicsPipelineCI.pInputAssemblyState->topology == VK_PRIMITIVE_TOPOLOGY_PATCH_LIST) { if (~pPipeline->active_shaders & VK_SHADER_STAGE_TESSELLATION_CONTROL_BIT) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_PIPELINE_CREATE_STATE, "DS", "Invalid Pipeline CreateInfo State: " "VK_PRIMITIVE_TOPOLOGY_PATCH_LIST primitive " "topology is only valid for tessellation pipelines"); } if (!pPipeline->graphicsPipelineCI.pTessellationState) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_PIPELINE_CREATE_STATE, "DS", "Invalid Pipeline CreateInfo State: " "pTessellationState is NULL when VK_PRIMITIVE_TOPOLOGY_PATCH_LIST primitive " "topology used. pTessellationState must not be NULL in this case."); } else if (!pPipeline->graphicsPipelineCI.pTessellationState->patchControlPoints || (pPipeline->graphicsPipelineCI.pTessellationState->patchControlPoints > 32)) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_PIPELINE_CREATE_STATE, "DS", "Invalid Pipeline CreateInfo State: " "VK_PRIMITIVE_TOPOLOGY_PATCH_LIST primitive " "topology used with patchControlPoints value %u." " patchControlPoints should be >0 and <=32.", pPipeline->graphicsPipelineCI.pTessellationState->patchControlPoints); } } // If a rasterization state is provided, make sure that the line width conforms to the HW. if (pPipeline->graphicsPipelineCI.pRasterizationState) { if (!isDynamic(pPipeline, VK_DYNAMIC_STATE_LINE_WIDTH)) { skip_call |= verifyLineWidth(my_data, DRAWSTATE_INVALID_PIPELINE_CREATE_STATE, reinterpret_cast(pPipeline->pipeline), pPipeline->graphicsPipelineCI.pRasterizationState->lineWidth); } } // Viewport state must be included if rasterization is enabled. // If the viewport state is included, the viewport and scissor counts should always match. // NOTE : Even if these are flagged as dynamic, counts need to be set correctly for shader compiler if (!pPipeline->graphicsPipelineCI.pRasterizationState || (pPipeline->graphicsPipelineCI.pRasterizationState->rasterizerDiscardEnable == VK_FALSE)) { if (!pPipeline->graphicsPipelineCI.pViewportState) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_VIEWPORT_SCISSOR_MISMATCH, "DS", "Gfx Pipeline pViewportState is null. Even if viewport " "and scissors are dynamic PSO must include " "viewportCount and scissorCount in pViewportState."); } else if (pPipeline->graphicsPipelineCI.pViewportState->scissorCount != pPipeline->graphicsPipelineCI.pViewportState->viewportCount) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_VIEWPORT_SCISSOR_MISMATCH, "DS", "Gfx Pipeline viewport count (%u) must match scissor count (%u).", pPipeline->graphicsPipelineCI.pViewportState->viewportCount, pPipeline->graphicsPipelineCI.pViewportState->scissorCount); } else { // If viewport or scissor are not dynamic, then verify that data is appropriate for count bool dynViewport = isDynamic(pPipeline, VK_DYNAMIC_STATE_VIEWPORT); bool dynScissor = isDynamic(pPipeline, VK_DYNAMIC_STATE_SCISSOR); if (!dynViewport) { if (pPipeline->graphicsPipelineCI.pViewportState->viewportCount && !pPipeline->graphicsPipelineCI.pViewportState->pViewports) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_VIEWPORT_SCISSOR_MISMATCH, "DS", "Gfx Pipeline viewportCount is %u, but pViewports is NULL. For non-zero viewportCount, you " "must either include pViewports data, or include viewport in pDynamicState and set it with " "vkCmdSetViewport().", pPipeline->graphicsPipelineCI.pViewportState->viewportCount); } } if (!dynScissor) { if (pPipeline->graphicsPipelineCI.pViewportState->scissorCount && !pPipeline->graphicsPipelineCI.pViewportState->pScissors) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_VIEWPORT_SCISSOR_MISMATCH, "DS", "Gfx Pipeline scissorCount is %u, but pScissors is NULL. For non-zero scissorCount, you " "must either include pScissors data, or include scissor in pDynamicState and set it with " "vkCmdSetScissor().", pPipeline->graphicsPipelineCI.pViewportState->scissorCount); } } } // If rasterization is not disabled, and subpass uses a depth/stencil // attachment, pDepthStencilState must be a pointer to a valid structure auto subpass_desc = renderPass ? &renderPass->createInfo.pSubpasses[pPipeline->graphicsPipelineCI.subpass] : nullptr; if (subpass_desc && subpass_desc->pDepthStencilAttachment && subpass_desc->pDepthStencilAttachment->attachment != VK_ATTACHMENT_UNUSED) { if (!pPipeline->graphicsPipelineCI.pDepthStencilState) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_UNKNOWN_EXT, 0, __LINE__, DRAWSTATE_INVALID_PIPELINE_CREATE_STATE, "DS", "Invalid Pipeline CreateInfo State: " "pDepthStencilState is NULL when rasterization is enabled and subpass uses a " "depth/stencil attachment"); } } } return skip_call; } // Free the Pipeline nodes static void deletePipelines(layer_data *my_data) { if (my_data->pipelineMap.size() <= 0) return; for (auto &pipe_map_pair : my_data->pipelineMap) { delete pipe_map_pair.second; } my_data->pipelineMap.clear(); } // Block of code at start here specifically for managing/tracking DSs // Return Pool node ptr for specified pool or else NULL DESCRIPTOR_POOL_STATE *getDescriptorPoolState(const layer_data *dev_data, const VkDescriptorPool pool) { auto pool_it = dev_data->descriptorPoolMap.find(pool); if (pool_it == dev_data->descriptorPoolMap.end()) { return NULL; } return pool_it->second; } // Return false if update struct is of valid type, otherwise flag error and return code from callback static bool validUpdateStruct(layer_data *my_data, const VkDevice device, const GENERIC_HEADER *pUpdateStruct) { switch (pUpdateStruct->sType) { case VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET: case VK_STRUCTURE_TYPE_COPY_DESCRIPTOR_SET: return false; default: return log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_UPDATE_STRUCT, "DS", "Unexpected UPDATE struct of type %s (value %u) in vkUpdateDescriptors() struct tree", string_VkStructureType(pUpdateStruct->sType), pUpdateStruct->sType); } } // Set count for given update struct in the last parameter static uint32_t getUpdateCount(layer_data *my_data, const VkDevice device, const GENERIC_HEADER *pUpdateStruct) { switch (pUpdateStruct->sType) { case VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET: return ((VkWriteDescriptorSet *)pUpdateStruct)->descriptorCount; case VK_STRUCTURE_TYPE_COPY_DESCRIPTOR_SET: // TODO : Need to understand this case better and make sure code is correct return ((VkCopyDescriptorSet *)pUpdateStruct)->descriptorCount; default: return 0; } } // For given layout and update, return the first overall index of the layout that is updated static uint32_t getUpdateStartIndex(layer_data *my_data, const VkDevice device, const uint32_t binding_start_index, const uint32_t arrayIndex, const GENERIC_HEADER *pUpdateStruct) { return binding_start_index + arrayIndex; } // For given layout and update, return the last overall index of the layout that is updated static uint32_t getUpdateEndIndex(layer_data *my_data, const VkDevice device, const uint32_t binding_start_index, const uint32_t arrayIndex, const GENERIC_HEADER *pUpdateStruct) { uint32_t count = getUpdateCount(my_data, device, pUpdateStruct); return binding_start_index + arrayIndex + count - 1; } // Verify that the descriptor type in the update struct matches what's expected by the layout static bool validateUpdateConsistency(layer_data *my_data, const VkDevice device, const VkDescriptorType layout_type, const GENERIC_HEADER *pUpdateStruct, uint32_t startIndex, uint32_t endIndex) { // First get actual type of update bool skip_call = false; VkDescriptorType actualType = VK_DESCRIPTOR_TYPE_MAX_ENUM; switch (pUpdateStruct->sType) { case VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET: actualType = ((VkWriteDescriptorSet *)pUpdateStruct)->descriptorType; break; case VK_STRUCTURE_TYPE_COPY_DESCRIPTOR_SET: /* no need to validate */ return false; break; default: skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_UPDATE_STRUCT, "DS", "Unexpected UPDATE struct of type %s (value %u) in vkUpdateDescriptors() struct tree", string_VkStructureType(pUpdateStruct->sType), pUpdateStruct->sType); } if (!skip_call) { if (layout_type != actualType) { skip_call |= log_msg( my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_DESCRIPTOR_TYPE_MISMATCH, "DS", "Write descriptor update has descriptor type %s that does not match overlapping binding descriptor type of %s!", string_VkDescriptorType(actualType), string_VkDescriptorType(layout_type)); } } return skip_call; } //TODO: Consolidate functions bool FindLayout(const GLOBAL_CB_NODE *pCB, ImageSubresourcePair imgpair, IMAGE_CMD_BUF_LAYOUT_NODE &node, const VkImageAspectFlags aspectMask) { layer_data *my_data = get_my_data_ptr(get_dispatch_key(pCB->commandBuffer), layer_data_map); if (!(imgpair.subresource.aspectMask & aspectMask)) { return false; } VkImageAspectFlags oldAspectMask = imgpair.subresource.aspectMask; imgpair.subresource.aspectMask = aspectMask; auto imgsubIt = pCB->imageLayoutMap.find(imgpair); if (imgsubIt == pCB->imageLayoutMap.end()) { return false; } if (node.layout != VK_IMAGE_LAYOUT_MAX_ENUM && node.layout != imgsubIt->second.layout) { log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, reinterpret_cast(imgpair.image), __LINE__, DRAWSTATE_INVALID_LAYOUT, "DS", "Cannot query for VkImage 0x%" PRIx64 " layout when combined aspect mask %d has multiple layout types: %s and %s", reinterpret_cast(imgpair.image), oldAspectMask, string_VkImageLayout(node.layout), string_VkImageLayout(imgsubIt->second.layout)); } if (node.initialLayout != VK_IMAGE_LAYOUT_MAX_ENUM && node.initialLayout != imgsubIt->second.initialLayout) { log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, reinterpret_cast(imgpair.image), __LINE__, DRAWSTATE_INVALID_LAYOUT, "DS", "Cannot query for VkImage 0x%" PRIx64 " layout when combined aspect mask %d has multiple initial layout types: %s and %s", reinterpret_cast(imgpair.image), oldAspectMask, string_VkImageLayout(node.initialLayout), string_VkImageLayout(imgsubIt->second.initialLayout)); } node = imgsubIt->second; return true; } bool FindLayout(const layer_data *my_data, ImageSubresourcePair imgpair, VkImageLayout &layout, const VkImageAspectFlags aspectMask) { if (!(imgpair.subresource.aspectMask & aspectMask)) { return false; } VkImageAspectFlags oldAspectMask = imgpair.subresource.aspectMask; imgpair.subresource.aspectMask = aspectMask; auto imgsubIt = my_data->imageLayoutMap.find(imgpair); if (imgsubIt == my_data->imageLayoutMap.end()) { return false; } if (layout != VK_IMAGE_LAYOUT_MAX_ENUM && layout != imgsubIt->second.layout) { log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, reinterpret_cast(imgpair.image), __LINE__, DRAWSTATE_INVALID_LAYOUT, "DS", "Cannot query for VkImage 0x%" PRIx64 " layout when combined aspect mask %d has multiple layout types: %s and %s", reinterpret_cast(imgpair.image), oldAspectMask, string_VkImageLayout(layout), string_VkImageLayout(imgsubIt->second.layout)); } layout = imgsubIt->second.layout; return true; } // find layout(s) on the cmd buf level bool FindLayout(const GLOBAL_CB_NODE *pCB, VkImage image, VkImageSubresource range, IMAGE_CMD_BUF_LAYOUT_NODE &node) { ImageSubresourcePair imgpair = {image, true, range}; node = IMAGE_CMD_BUF_LAYOUT_NODE(VK_IMAGE_LAYOUT_MAX_ENUM, VK_IMAGE_LAYOUT_MAX_ENUM); FindLayout(pCB, imgpair, node, VK_IMAGE_ASPECT_COLOR_BIT); FindLayout(pCB, imgpair, node, VK_IMAGE_ASPECT_DEPTH_BIT); FindLayout(pCB, imgpair, node, VK_IMAGE_ASPECT_STENCIL_BIT); FindLayout(pCB, imgpair, node, VK_IMAGE_ASPECT_METADATA_BIT); if (node.layout == VK_IMAGE_LAYOUT_MAX_ENUM) { imgpair = {image, false, VkImageSubresource()}; auto imgsubIt = pCB->imageLayoutMap.find(imgpair); if (imgsubIt == pCB->imageLayoutMap.end()) return false; node = imgsubIt->second; } return true; } // find layout(s) on the global level bool FindLayout(const layer_data *my_data, ImageSubresourcePair imgpair, VkImageLayout &layout) { layout = VK_IMAGE_LAYOUT_MAX_ENUM; FindLayout(my_data, imgpair, layout, VK_IMAGE_ASPECT_COLOR_BIT); FindLayout(my_data, imgpair, layout, VK_IMAGE_ASPECT_DEPTH_BIT); FindLayout(my_data, imgpair, layout, VK_IMAGE_ASPECT_STENCIL_BIT); FindLayout(my_data, imgpair, layout, VK_IMAGE_ASPECT_METADATA_BIT); if (layout == VK_IMAGE_LAYOUT_MAX_ENUM) { imgpair = {imgpair.image, false, VkImageSubresource()}; auto imgsubIt = my_data->imageLayoutMap.find(imgpair); if (imgsubIt == my_data->imageLayoutMap.end()) return false; layout = imgsubIt->second.layout; } return true; } bool FindLayout(const layer_data *my_data, VkImage image, VkImageSubresource range, VkImageLayout &layout) { ImageSubresourcePair imgpair = {image, true, range}; return FindLayout(my_data, imgpair, layout); } bool FindLayouts(const layer_data *my_data, VkImage image, std::vector &layouts) { auto sub_data = my_data->imageSubresourceMap.find(image); if (sub_data == my_data->imageSubresourceMap.end()) return false; auto image_state = getImageState(my_data, image); if (!image_state) return false; bool ignoreGlobal = false; // TODO: Make this robust for >1 aspect mask. Now it will just say ignore // potential errors in this case. if (sub_data->second.size() >= (image_state->createInfo.arrayLayers * image_state->createInfo.mipLevels + 1)) { ignoreGlobal = true; } for (auto imgsubpair : sub_data->second) { if (ignoreGlobal && !imgsubpair.hasSubresource) continue; auto img_data = my_data->imageLayoutMap.find(imgsubpair); if (img_data != my_data->imageLayoutMap.end()) { layouts.push_back(img_data->second.layout); } } return true; } // Set the layout on the global level void SetLayout(layer_data *my_data, ImageSubresourcePair imgpair, const VkImageLayout &layout) { VkImage &image = imgpair.image; // TODO (mlentine): Maybe set format if new? Not used atm. my_data->imageLayoutMap[imgpair].layout = layout; // TODO (mlentine): Maybe make vector a set? auto subresource = std::find(my_data->imageSubresourceMap[image].begin(), my_data->imageSubresourceMap[image].end(), imgpair); if (subresource == my_data->imageSubresourceMap[image].end()) { my_data->imageSubresourceMap[image].push_back(imgpair); } } // Set the layout on the cmdbuf level void SetLayout(GLOBAL_CB_NODE *pCB, ImageSubresourcePair imgpair, const IMAGE_CMD_BUF_LAYOUT_NODE &node) { pCB->imageLayoutMap[imgpair] = node; // TODO (mlentine): Maybe make vector a set? auto subresource = std::find(pCB->imageSubresourceMap[imgpair.image].begin(), pCB->imageSubresourceMap[imgpair.image].end(), imgpair); if (subresource == pCB->imageSubresourceMap[imgpair.image].end()) { pCB->imageSubresourceMap[imgpair.image].push_back(imgpair); } } void SetLayout(GLOBAL_CB_NODE *pCB, ImageSubresourcePair imgpair, const VkImageLayout &layout) { // TODO (mlentine): Maybe make vector a set? if (std::find(pCB->imageSubresourceMap[imgpair.image].begin(), pCB->imageSubresourceMap[imgpair.image].end(), imgpair) != pCB->imageSubresourceMap[imgpair.image].end()) { pCB->imageLayoutMap[imgpair].layout = layout; } else { // TODO (mlentine): Could be expensive and might need to be removed. assert(imgpair.hasSubresource); IMAGE_CMD_BUF_LAYOUT_NODE node; if (!FindLayout(pCB, imgpair.image, imgpair.subresource, node)) { node.initialLayout = layout; } SetLayout(pCB, imgpair, {node.initialLayout, layout}); } } template void SetLayout(OBJECT *pObject, ImageSubresourcePair imgpair, const LAYOUT &layout, VkImageAspectFlags aspectMask) { if (imgpair.subresource.aspectMask & aspectMask) { imgpair.subresource.aspectMask = aspectMask; SetLayout(pObject, imgpair, layout); } } template void SetLayout(OBJECT *pObject, VkImage image, VkImageSubresource range, const LAYOUT &layout) { ImageSubresourcePair imgpair = {image, true, range}; SetLayout(pObject, imgpair, layout, VK_IMAGE_ASPECT_COLOR_BIT); SetLayout(pObject, imgpair, layout, VK_IMAGE_ASPECT_DEPTH_BIT); SetLayout(pObject, imgpair, layout, VK_IMAGE_ASPECT_STENCIL_BIT); SetLayout(pObject, imgpair, layout, VK_IMAGE_ASPECT_METADATA_BIT); } template void SetLayout(OBJECT *pObject, VkImage image, const LAYOUT &layout) { ImageSubresourcePair imgpair = {image, false, VkImageSubresource()}; SetLayout(pObject, image, imgpair, layout); } void SetLayout(const layer_data *dev_data, GLOBAL_CB_NODE *pCB, VkImageView imageView, const VkImageLayout &layout) { auto view_state = getImageViewState(dev_data, imageView); assert(view_state); auto image = view_state->create_info.image; const VkImageSubresourceRange &subRange = view_state->create_info.subresourceRange; // TODO: Do not iterate over every possibility - consolidate where possible for (uint32_t j = 0; j < subRange.levelCount; j++) { uint32_t level = subRange.baseMipLevel + j; for (uint32_t k = 0; k < subRange.layerCount; k++) { uint32_t layer = subRange.baseArrayLayer + k; VkImageSubresource sub = {subRange.aspectMask, level, layer}; // TODO: If ImageView was created with depth or stencil, transition both layouts as // the aspectMask is ignored and both are used. Verify that the extra implicit layout // is OK for descriptor set layout validation if (subRange.aspectMask & (VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT)) { if (vk_format_is_depth_and_stencil(view_state->create_info.format)) { sub.aspectMask |= (VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT); } } SetLayout(pCB, image, sub, layout); } } } // Validate that given set is valid and that it's not being used by an in-flight CmdBuffer // func_str is the name of the calling function // Return false if no errors occur // Return true if validation error occurs and callback returns true (to skip upcoming API call down the chain) static bool validateIdleDescriptorSet(const layer_data *dev_data, VkDescriptorSet set, std::string func_str) { if (dev_data->instance_data->disabled.idle_descriptor_set) return false; bool skip_call = false; auto set_node = dev_data->setMap.find(set); if (set_node == dev_data->setMap.end()) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT, (uint64_t)(set), __LINE__, DRAWSTATE_DOUBLE_DESTROY, "DS", "Cannot call %s() on descriptor set 0x%" PRIxLEAST64 " that has not been allocated.", func_str.c_str(), (uint64_t)(set)); } else { // TODO : This covers various error cases so should pass error enum into this function and use passed in enum here if (set_node->second->in_use.load()) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT, (uint64_t)(set), __LINE__, VALIDATION_ERROR_00919, "DS", "Cannot call %s() on descriptor set 0x%" PRIxLEAST64 " that is in use by a command buffer. %s", func_str.c_str(), (uint64_t)(set), validation_error_map[VALIDATION_ERROR_00919]); } } return skip_call; } // Remove set from setMap and delete the set static void freeDescriptorSet(layer_data *dev_data, cvdescriptorset::DescriptorSet *descriptor_set) { dev_data->setMap.erase(descriptor_set->GetSet()); delete descriptor_set; } // Free all DS Pools including their Sets & related sub-structs // NOTE : Calls to this function should be wrapped in mutex static void deletePools(layer_data *my_data) { if (my_data->descriptorPoolMap.size() <= 0) return; for (auto ii = my_data->descriptorPoolMap.begin(); ii != my_data->descriptorPoolMap.end(); ++ii) { // Remove this pools' sets from setMap and delete them for (auto ds : (*ii).second->sets) { freeDescriptorSet(my_data, ds); } (*ii).second->sets.clear(); } my_data->descriptorPoolMap.clear(); } static void clearDescriptorPool(layer_data *my_data, const VkDevice device, const VkDescriptorPool pool, VkDescriptorPoolResetFlags flags) { DESCRIPTOR_POOL_STATE *pPool = getDescriptorPoolState(my_data, pool); // TODO: validate flags // For every set off of this pool, clear it, remove from setMap, and free cvdescriptorset::DescriptorSet for (auto ds : pPool->sets) { freeDescriptorSet(my_data, ds); } pPool->sets.clear(); // Reset available count for each type and available sets for this pool for (uint32_t i = 0; i < pPool->availableDescriptorTypeCount.size(); ++i) { pPool->availableDescriptorTypeCount[i] = pPool->maxDescriptorTypeCount[i]; } pPool->availableSets = pPool->maxSets; } // For given CB object, fetch associated CB Node from map static GLOBAL_CB_NODE *getCBNode(layer_data const *my_data, const VkCommandBuffer cb) { auto it = my_data->commandBufferMap.find(cb); if (it == my_data->commandBufferMap.end()) { log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(cb), __LINE__, DRAWSTATE_INVALID_COMMAND_BUFFER, "DS", "Attempt to use CommandBuffer 0x%" PRIxLEAST64 " that doesn't exist!", (uint64_t)(cb)); return NULL; } return it->second; } // Free all CB Nodes // NOTE : Calls to this function should be wrapped in mutex static void deleteCommandBuffers(layer_data *my_data) { if (my_data->commandBufferMap.empty()) { return; } for (auto ii = my_data->commandBufferMap.begin(); ii != my_data->commandBufferMap.end(); ++ii) { delete (*ii).second; } my_data->commandBufferMap.clear(); } static bool report_error_no_cb_begin(const layer_data *dev_data, const VkCommandBuffer cb, const char *caller_name) { return log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)cb, __LINE__, DRAWSTATE_NO_BEGIN_COMMAND_BUFFER, "DS", "You must call vkBeginCommandBuffer() before this call to %s", caller_name); } bool validateCmdsInCmdBuffer(const layer_data *dev_data, const GLOBAL_CB_NODE *pCB, const CMD_TYPE cmd_type) { if (!pCB->activeRenderPass) return false; bool skip_call = false; if (pCB->activeSubpassContents == VK_SUBPASS_CONTENTS_SECONDARY_COMMAND_BUFFERS && (cmd_type != CMD_EXECUTECOMMANDS && cmd_type != CMD_NEXTSUBPASS && cmd_type != CMD_ENDRENDERPASS)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_COMMAND_BUFFER, "DS", "Commands cannot be called in a subpass using secondary command buffers."); } else if (pCB->activeSubpassContents == VK_SUBPASS_CONTENTS_INLINE && cmd_type == CMD_EXECUTECOMMANDS) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_COMMAND_BUFFER, "DS", "vkCmdExecuteCommands() cannot be called in a subpass using inline commands."); } return skip_call; } static bool checkGraphicsBit(const layer_data *my_data, VkQueueFlags flags, const char *name) { if (!(flags & VK_QUEUE_GRAPHICS_BIT)) return log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_COMMAND_BUFFER, "DS", "Cannot call %s on a command buffer allocated from a pool without graphics capabilities.", name); return false; } static bool checkComputeBit(const layer_data *my_data, VkQueueFlags flags, const char *name) { if (!(flags & VK_QUEUE_COMPUTE_BIT)) return log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_COMMAND_BUFFER, "DS", "Cannot call %s on a command buffer allocated from a pool without compute capabilities.", name); return false; } static bool checkGraphicsOrComputeBit(const layer_data *my_data, VkQueueFlags flags, const char *name) { if (!((flags & VK_QUEUE_GRAPHICS_BIT) || (flags & VK_QUEUE_COMPUTE_BIT))) return log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_COMMAND_BUFFER, "DS", "Cannot call %s on a command buffer allocated from a pool without graphics capabilities.", name); return false; } // Add specified CMD to the CmdBuffer in given pCB, flagging errors if CB is not // in the recording state or if there's an issue with the Cmd ordering static bool addCmd(layer_data *my_data, GLOBAL_CB_NODE *pCB, const CMD_TYPE cmd, const char *caller_name) { bool skip_call = false; auto pPool = getCommandPoolNode(my_data, pCB->createInfo.commandPool); if (pPool) { VkQueueFlags flags = my_data->phys_dev_properties.queue_family_properties[pPool->queueFamilyIndex].queueFlags; switch (cmd) { case CMD_BINDPIPELINE: case CMD_BINDPIPELINEDELTA: case CMD_BINDDESCRIPTORSETS: case CMD_FILLBUFFER: case CMD_CLEARCOLORIMAGE: case CMD_SETEVENT: case CMD_RESETEVENT: case CMD_WAITEVENTS: case CMD_BEGINQUERY: case CMD_ENDQUERY: case CMD_RESETQUERYPOOL: case CMD_COPYQUERYPOOLRESULTS: case CMD_WRITETIMESTAMP: skip_call |= checkGraphicsOrComputeBit(my_data, flags, cmdTypeToString(cmd).c_str()); break; case CMD_SETVIEWPORTSTATE: case CMD_SETSCISSORSTATE: case CMD_SETLINEWIDTHSTATE: case CMD_SETDEPTHBIASSTATE: case CMD_SETBLENDSTATE: case CMD_SETDEPTHBOUNDSSTATE: case CMD_SETSTENCILREADMASKSTATE: case CMD_SETSTENCILWRITEMASKSTATE: case CMD_SETSTENCILREFERENCESTATE: case CMD_BINDINDEXBUFFER: case CMD_BINDVERTEXBUFFER: case CMD_DRAW: case CMD_DRAWINDEXED: case CMD_DRAWINDIRECT: case CMD_DRAWINDEXEDINDIRECT: case CMD_BLITIMAGE: case CMD_CLEARATTACHMENTS: case CMD_CLEARDEPTHSTENCILIMAGE: case CMD_RESOLVEIMAGE: case CMD_BEGINRENDERPASS: case CMD_NEXTSUBPASS: case CMD_ENDRENDERPASS: skip_call |= checkGraphicsBit(my_data, flags, cmdTypeToString(cmd).c_str()); break; case CMD_DISPATCH: case CMD_DISPATCHINDIRECT: skip_call |= checkComputeBit(my_data, flags, cmdTypeToString(cmd).c_str()); break; case CMD_COPYBUFFER: case CMD_COPYIMAGE: case CMD_COPYBUFFERTOIMAGE: case CMD_COPYIMAGETOBUFFER: case CMD_CLONEIMAGEDATA: case CMD_UPDATEBUFFER: case CMD_PIPELINEBARRIER: case CMD_EXECUTECOMMANDS: case CMD_END: break; default: break; } } if (pCB->state != CB_RECORDING) { skip_call |= report_error_no_cb_begin(my_data, pCB->commandBuffer, caller_name); } else { skip_call |= validateCmdsInCmdBuffer(my_data, pCB, cmd); CMD_NODE cmdNode = {}; // init cmd node and append to end of cmd LL cmdNode.cmdNumber = ++pCB->numCmds; cmdNode.type = cmd; pCB->cmds.push_back(cmdNode); } return skip_call; } // For given object struct return a ptr of BASE_NODE type for its wrapping struct BASE_NODE *GetStateStructPtrFromObject(layer_data *dev_data, VK_OBJECT object_struct) { BASE_NODE *base_ptr = nullptr; switch (object_struct.type) { case VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT: { base_ptr = getSetNode(dev_data, reinterpret_cast(object_struct.handle)); break; } case VK_DEBUG_REPORT_OBJECT_TYPE_SAMPLER_EXT: { base_ptr = getSamplerState(dev_data, reinterpret_cast(object_struct.handle)); break; } case VK_DEBUG_REPORT_OBJECT_TYPE_QUERY_POOL_EXT: { base_ptr = getQueryPoolNode(dev_data, reinterpret_cast(object_struct.handle)); break; } case VK_DEBUG_REPORT_OBJECT_TYPE_PIPELINE_EXT: { base_ptr = getPipelineState(dev_data, reinterpret_cast(object_struct.handle)); break; } case VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT: { base_ptr = getBufferState(dev_data, reinterpret_cast(object_struct.handle)); break; } case VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_VIEW_EXT: { base_ptr = getBufferViewState(dev_data, reinterpret_cast(object_struct.handle)); break; } case VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT: { base_ptr = getImageState(dev_data, reinterpret_cast(object_struct.handle)); break; } case VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_VIEW_EXT: { base_ptr = getImageViewState(dev_data, reinterpret_cast(object_struct.handle)); break; } case VK_DEBUG_REPORT_OBJECT_TYPE_EVENT_EXT: { base_ptr = getEventNode(dev_data, reinterpret_cast(object_struct.handle)); break; } case VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_POOL_EXT: { base_ptr = getDescriptorPoolState(dev_data, reinterpret_cast(object_struct.handle)); break; } case VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_POOL_EXT: { base_ptr = getCommandPoolNode(dev_data, reinterpret_cast(object_struct.handle)); break; } case VK_DEBUG_REPORT_OBJECT_TYPE_FRAMEBUFFER_EXT: { base_ptr = getFramebufferState(dev_data, reinterpret_cast(object_struct.handle)); break; } case VK_DEBUG_REPORT_OBJECT_TYPE_RENDER_PASS_EXT: { base_ptr = getRenderPassState(dev_data, reinterpret_cast(object_struct.handle)); break; } case VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT: { base_ptr = getMemObjInfo(dev_data, reinterpret_cast(object_struct.handle)); break; } default: // TODO : Any other objects to be handled here? assert(0); break; } return base_ptr; } // Tie the VK_OBJECT to the cmd buffer which includes: // Add object_binding to cmd buffer // Add cb_binding to object static void addCommandBufferBinding(std::unordered_set *cb_bindings, VK_OBJECT obj, GLOBAL_CB_NODE *cb_node) { cb_bindings->insert(cb_node); cb_node->object_bindings.insert(obj); } // For a given object, if cb_node is in that objects cb_bindings, remove cb_node static void removeCommandBufferBinding(layer_data *dev_data, VK_OBJECT const *object, GLOBAL_CB_NODE *cb_node) { BASE_NODE *base_obj = GetStateStructPtrFromObject(dev_data, *object); if (base_obj) base_obj->cb_bindings.erase(cb_node); } // Reset the command buffer state // Maintain the createInfo and set state to CB_NEW, but clear all other state static void resetCB(layer_data *dev_data, const VkCommandBuffer cb) { GLOBAL_CB_NODE *pCB = dev_data->commandBufferMap[cb]; if (pCB) { pCB->in_use.store(0); pCB->cmds.clear(); // Reset CB state (note that createInfo is not cleared) pCB->commandBuffer = cb; memset(&pCB->beginInfo, 0, sizeof(VkCommandBufferBeginInfo)); memset(&pCB->inheritanceInfo, 0, sizeof(VkCommandBufferInheritanceInfo)); pCB->numCmds = 0; memset(pCB->drawCount, 0, NUM_DRAW_TYPES * sizeof(uint64_t)); pCB->state = CB_NEW; pCB->submitCount = 0; pCB->status = 0; pCB->viewportMask = 0; pCB->scissorMask = 0; for (uint32_t i = 0; i < VK_PIPELINE_BIND_POINT_RANGE_SIZE; ++i) { pCB->lastBound[i].reset(); } memset(&pCB->activeRenderPassBeginInfo, 0, sizeof(pCB->activeRenderPassBeginInfo)); pCB->activeRenderPass = nullptr; pCB->activeSubpassContents = VK_SUBPASS_CONTENTS_INLINE; pCB->activeSubpass = 0; pCB->broken_bindings.clear(); pCB->waitedEvents.clear(); pCB->events.clear(); pCB->writeEventsBeforeWait.clear(); pCB->waitedEventsBeforeQueryReset.clear(); pCB->queryToStateMap.clear(); pCB->activeQueries.clear(); pCB->startedQueries.clear(); pCB->imageSubresourceMap.clear(); pCB->imageLayoutMap.clear(); pCB->eventToStageMap.clear(); pCB->drawData.clear(); pCB->currentDrawData.buffers.clear(); pCB->primaryCommandBuffer = VK_NULL_HANDLE; // Make sure any secondaryCommandBuffers are removed from globalInFlight for (auto secondary_cb : pCB->secondaryCommandBuffers) { dev_data->globalInFlightCmdBuffers.erase(secondary_cb); } pCB->secondaryCommandBuffers.clear(); pCB->updateImages.clear(); pCB->updateBuffers.clear(); clear_cmd_buf_and_mem_references(dev_data, pCB); pCB->eventUpdates.clear(); pCB->queryUpdates.clear(); // Remove object bindings for (auto obj : pCB->object_bindings) { removeCommandBufferBinding(dev_data, &obj, pCB); } pCB->object_bindings.clear(); // Remove this cmdBuffer's reference from each FrameBuffer's CB ref list for (auto framebuffer : pCB->framebuffers) { auto fb_state = getFramebufferState(dev_data, framebuffer); if (fb_state) fb_state->cb_bindings.erase(pCB); } pCB->framebuffers.clear(); pCB->activeFramebuffer = VK_NULL_HANDLE; } } // Set PSO-related status bits for CB, including dynamic state set via PSO static void set_cb_pso_status(GLOBAL_CB_NODE *pCB, const PIPELINE_STATE *pPipe) { // Account for any dynamic state not set via this PSO if (!pPipe->graphicsPipelineCI.pDynamicState || !pPipe->graphicsPipelineCI.pDynamicState->dynamicStateCount) { // All state is static pCB->status |= CBSTATUS_ALL_STATE_SET; } else { // First consider all state on // Then unset any state that's noted as dynamic in PSO // Finally OR that into CB statemask CBStatusFlags psoDynStateMask = CBSTATUS_ALL_STATE_SET; for (uint32_t i = 0; i < pPipe->graphicsPipelineCI.pDynamicState->dynamicStateCount; i++) { switch (pPipe->graphicsPipelineCI.pDynamicState->pDynamicStates[i]) { case VK_DYNAMIC_STATE_LINE_WIDTH: psoDynStateMask &= ~CBSTATUS_LINE_WIDTH_SET; break; case VK_DYNAMIC_STATE_DEPTH_BIAS: psoDynStateMask &= ~CBSTATUS_DEPTH_BIAS_SET; break; case VK_DYNAMIC_STATE_BLEND_CONSTANTS: psoDynStateMask &= ~CBSTATUS_BLEND_CONSTANTS_SET; break; case VK_DYNAMIC_STATE_DEPTH_BOUNDS: psoDynStateMask &= ~CBSTATUS_DEPTH_BOUNDS_SET; break; case VK_DYNAMIC_STATE_STENCIL_COMPARE_MASK: psoDynStateMask &= ~CBSTATUS_STENCIL_READ_MASK_SET; break; case VK_DYNAMIC_STATE_STENCIL_WRITE_MASK: psoDynStateMask &= ~CBSTATUS_STENCIL_WRITE_MASK_SET; break; case VK_DYNAMIC_STATE_STENCIL_REFERENCE: psoDynStateMask &= ~CBSTATUS_STENCIL_REFERENCE_SET; break; default: // TODO : Flag error here break; } } pCB->status |= psoDynStateMask; } } // Print the last bound Gfx Pipeline static bool printPipeline(layer_data *my_data, const VkCommandBuffer cb) { bool skip_call = false; GLOBAL_CB_NODE *pCB = getCBNode(my_data, cb); if (pCB) { PIPELINE_STATE *pPipeTrav = pCB->lastBound[VK_PIPELINE_BIND_POINT_GRAPHICS].pipeline_state; if (!pPipeTrav) { // nothing to print } else { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_NONE, "DS", "%s", vk_print_vkgraphicspipelinecreateinfo( reinterpret_cast(&pPipeTrav->graphicsPipelineCI), "{DS}") .c_str()); } } return skip_call; } static void printCB(layer_data *my_data, const VkCommandBuffer cb) { GLOBAL_CB_NODE *pCB = getCBNode(my_data, cb); if (pCB && pCB->cmds.size() > 0) { log_msg(my_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_NONE, "DS", "Cmds in command buffer 0x%p", (void *)cb); vector cmds = pCB->cmds; for (auto ii = cmds.begin(); ii != cmds.end(); ++ii) { // TODO : Need to pass cmdbuffer as srcObj here log_msg(my_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, 0, __LINE__, DRAWSTATE_NONE, "DS", " CMD 0x%" PRIx64 ": %s", (*ii).cmdNumber, cmdTypeToString((*ii).type).c_str()); } } else { // Nothing to print } } static bool synchAndPrintDSConfig(layer_data *my_data, const VkCommandBuffer cb) { bool skip_call = false; if (!(my_data->report_data->active_flags & VK_DEBUG_REPORT_INFORMATION_BIT_EXT)) { return skip_call; } skip_call |= printPipeline(my_data, cb); return skip_call; } // Flags validation error if the associated call is made inside a render pass. The apiName // routine should ONLY be called outside a render pass. static bool insideRenderPass(const layer_data *my_data, GLOBAL_CB_NODE *pCB, const char *apiName) { bool inside = false; if (pCB->activeRenderPass) { inside = log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)pCB->commandBuffer, __LINE__, DRAWSTATE_INVALID_RENDERPASS_CMD, "DS", "%s: It is invalid to issue this call inside an active render pass (0x%" PRIxLEAST64 ")", apiName, (uint64_t)pCB->activeRenderPass->renderPass); } return inside; } // Flags validation error if the associated call is made outside a render pass. The apiName // routine should ONLY be called inside a render pass. static bool outsideRenderPass(const layer_data *my_data, GLOBAL_CB_NODE *pCB, const char *apiName) { bool outside = false; if (((pCB->createInfo.level == VK_COMMAND_BUFFER_LEVEL_PRIMARY) && (!pCB->activeRenderPass)) || ((pCB->createInfo.level == VK_COMMAND_BUFFER_LEVEL_SECONDARY) && (!pCB->activeRenderPass) && !(pCB->beginInfo.flags & VK_COMMAND_BUFFER_USAGE_RENDER_PASS_CONTINUE_BIT))) { outside = log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)pCB->commandBuffer, __LINE__, DRAWSTATE_NO_ACTIVE_RENDERPASS, "DS", "%s: This call must be issued inside an active render pass.", apiName); } return outside; } static void init_core_validation(instance_layer_data *instance_data, const VkAllocationCallbacks *pAllocator) { layer_debug_actions(instance_data->report_data, instance_data->logging_callback, pAllocator, "lunarg_core_validation"); } static void checkInstanceRegisterExtensions(const VkInstanceCreateInfo *pCreateInfo, instance_layer_data *instance_data) { for (uint32_t i = 0; i < pCreateInfo->enabledExtensionCount; i++) { if (!strcmp(pCreateInfo->ppEnabledExtensionNames[i], VK_KHR_SURFACE_EXTENSION_NAME)) instance_data->surfaceExtensionEnabled = true; if (!strcmp(pCreateInfo->ppEnabledExtensionNames[i], VK_KHR_DISPLAY_EXTENSION_NAME)) instance_data->displayExtensionEnabled = true; #ifdef VK_USE_PLATFORM_ANDROID_KHR if (!strcmp(pCreateInfo->ppEnabledExtensionNames[i], VK_KHR_ANDROID_SURFACE_EXTENSION_NAME)) instance_data->androidSurfaceExtensionEnabled = true; #endif #ifdef VK_USE_PLATFORM_MIR_KHR if (!strcmp(pCreateInfo->ppEnabledExtensionNames[i], VK_KHR_MIR_SURFACE_EXTENSION_NAME)) instance_data->mirSurfaceExtensionEnabled = true; #endif #ifdef VK_USE_PLATFORM_WAYLAND_KHR if (!strcmp(pCreateInfo->ppEnabledExtensionNames[i], VK_KHR_WAYLAND_SURFACE_EXTENSION_NAME)) instance_data->waylandSurfaceExtensionEnabled = true; #endif #ifdef VK_USE_PLATFORM_WIN32_KHR if (!strcmp(pCreateInfo->ppEnabledExtensionNames[i], VK_KHR_WIN32_SURFACE_EXTENSION_NAME)) instance_data->win32SurfaceExtensionEnabled = true; #endif #ifdef VK_USE_PLATFORM_XCB_KHR if (!strcmp(pCreateInfo->ppEnabledExtensionNames[i], VK_KHR_XCB_SURFACE_EXTENSION_NAME)) instance_data->xcbSurfaceExtensionEnabled = true; #endif #ifdef VK_USE_PLATFORM_XLIB_KHR if (!strcmp(pCreateInfo->ppEnabledExtensionNames[i], VK_KHR_XLIB_SURFACE_EXTENSION_NAME)) instance_data->xlibSurfaceExtensionEnabled = true; #endif } } VKAPI_ATTR VkResult VKAPI_CALL CreateInstance(const VkInstanceCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkInstance *pInstance) { VkLayerInstanceCreateInfo *chain_info = get_chain_info(pCreateInfo, VK_LAYER_LINK_INFO); assert(chain_info->u.pLayerInfo); PFN_vkGetInstanceProcAddr fpGetInstanceProcAddr = chain_info->u.pLayerInfo->pfnNextGetInstanceProcAddr; PFN_vkCreateInstance fpCreateInstance = (PFN_vkCreateInstance)fpGetInstanceProcAddr(NULL, "vkCreateInstance"); if (fpCreateInstance == NULL) return VK_ERROR_INITIALIZATION_FAILED; // Advance the link info for the next element on the chain chain_info->u.pLayerInfo = chain_info->u.pLayerInfo->pNext; VkResult result = fpCreateInstance(pCreateInfo, pAllocator, pInstance); if (result != VK_SUCCESS) return result; instance_layer_data *instance_data = get_my_data_ptr(get_dispatch_key(*pInstance), instance_layer_data_map); instance_data->instance = *pInstance; layer_init_instance_dispatch_table(*pInstance, &instance_data->dispatch_table, fpGetInstanceProcAddr); instance_data->report_data = debug_report_create_instance( &instance_data->dispatch_table, *pInstance, pCreateInfo->enabledExtensionCount, pCreateInfo->ppEnabledExtensionNames); checkInstanceRegisterExtensions(pCreateInfo, instance_data); init_core_validation(instance_data, pAllocator); ValidateLayerOrdering(*pCreateInfo); return result; } /* hook DestroyInstance to remove tableInstanceMap entry */ VKAPI_ATTR void VKAPI_CALL DestroyInstance(VkInstance instance, const VkAllocationCallbacks *pAllocator) { // TODOSC : Shouldn't need any customization here dispatch_key key = get_dispatch_key(instance); // TBD: Need any locking this early, in case this function is called at the // same time by more than one thread? instance_layer_data *instance_data = get_my_data_ptr(key, instance_layer_data_map); instance_data->dispatch_table.DestroyInstance(instance, pAllocator); std::lock_guard lock(global_lock); // Clean up logging callback, if any while (instance_data->logging_callback.size() > 0) { VkDebugReportCallbackEXT callback = instance_data->logging_callback.back(); layer_destroy_msg_callback(instance_data->report_data, callback, pAllocator); instance_data->logging_callback.pop_back(); } layer_debug_report_destroy_instance(instance_data->report_data); layer_data_map.erase(key); } static void checkDeviceRegisterExtensions(const VkDeviceCreateInfo *pCreateInfo, VkDevice device) { uint32_t i; // TBD: Need any locking, in case this function is called at the same time // by more than one thread? layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); dev_data->device_extensions.wsi_enabled = false; dev_data->device_extensions.wsi_display_swapchain_enabled = false; for (i = 0; i < pCreateInfo->enabledExtensionCount; i++) { if (strcmp(pCreateInfo->ppEnabledExtensionNames[i], VK_KHR_SWAPCHAIN_EXTENSION_NAME) == 0) dev_data->device_extensions.wsi_enabled = true; if (strcmp(pCreateInfo->ppEnabledExtensionNames[i], VK_KHR_DISPLAY_SWAPCHAIN_EXTENSION_NAME) == 0) dev_data->device_extensions.wsi_display_swapchain_enabled = true; } } // Verify that queue family has been properly requested bool ValidateRequestedQueueFamilyProperties(instance_layer_data *instance_data, VkPhysicalDevice gpu, const VkDeviceCreateInfo *create_info) { bool skip_call = false; auto physical_device_state = getPhysicalDeviceState(instance_data, gpu); // First check is app has actually requested queueFamilyProperties if (!physical_device_state) { skip_call |= log_msg(instance_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PHYSICAL_DEVICE_EXT, 0, __LINE__, DEVLIMITS_MUST_QUERY_COUNT, "DL", "Invalid call to vkCreateDevice() w/o first calling vkEnumeratePhysicalDevices()."); } else if (QUERY_DETAILS != physical_device_state->vkGetPhysicalDeviceQueueFamilyPropertiesState) { // TODO: This is not called out as an invalid use in the spec so make more informative recommendation. skip_call |= log_msg(instance_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PHYSICAL_DEVICE_EXT, 0, __LINE__, DEVLIMITS_INVALID_QUEUE_CREATE_REQUEST, "DL", "Call to vkCreateDevice() w/o first calling vkGetPhysicalDeviceQueueFamilyProperties()."); } else { // Check that the requested queue properties are valid for (uint32_t i = 0; i < create_info->queueCreateInfoCount; i++) { uint32_t requestedIndex = create_info->pQueueCreateInfos[i].queueFamilyIndex; if (requestedIndex >= physical_device_state->queue_family_properties.size()) { skip_call |= log_msg( instance_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PHYSICAL_DEVICE_EXT, 0, __LINE__, DEVLIMITS_INVALID_QUEUE_CREATE_REQUEST, "DL", "Invalid queue create request in vkCreateDevice(). Invalid queueFamilyIndex %u requested.", requestedIndex); } else if (create_info->pQueueCreateInfos[i].queueCount > physical_device_state->queue_family_properties[requestedIndex].queueCount) { skip_call |= log_msg(instance_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PHYSICAL_DEVICE_EXT, 0, __LINE__, DEVLIMITS_INVALID_QUEUE_CREATE_REQUEST, "DL", "Invalid queue create request in vkCreateDevice(). QueueFamilyIndex %u only has %u queues, but " "requested queueCount is %u.", requestedIndex, physical_device_state->queue_family_properties[requestedIndex].queueCount, create_info->pQueueCreateInfos[i].queueCount); } } } return skip_call; } // Verify that features have been queried and that they are available static bool ValidateRequestedFeatures(instance_layer_data *dev_data, VkPhysicalDevice phys, const VkPhysicalDeviceFeatures *requested_features) { bool skip_call = false; auto phys_device_state = getPhysicalDeviceState(dev_data, phys); const VkBool32 *actual = reinterpret_cast(&phys_device_state->features); const VkBool32 *requested = reinterpret_cast(requested_features); // TODO : This is a nice, compact way to loop through struct, but a bad way to report issues // Need to provide the struct member name with the issue. To do that seems like we'll // have to loop through each struct member which should be done w/ codegen to keep in synch. uint32_t errors = 0; uint32_t total_bools = sizeof(VkPhysicalDeviceFeatures) / sizeof(VkBool32); for (uint32_t i = 0; i < total_bools; i++) { if (requested[i] > actual[i]) { // TODO: Add index to struct member name helper to be able to include a feature name skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PHYSICAL_DEVICE_EXT, 0, __LINE__, DEVLIMITS_INVALID_FEATURE_REQUESTED, "DL", "While calling vkCreateDevice(), requesting feature #%u in VkPhysicalDeviceFeatures struct, " "which is not available on this device.", i); errors++; } } if (errors && (UNCALLED == phys_device_state->vkGetPhysicalDeviceFeaturesState)) { // If user didn't request features, notify them that they should // TODO: Verify this against the spec. I believe this is an invalid use of the API and should return an error skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PHYSICAL_DEVICE_EXT, 0, __LINE__, DEVLIMITS_INVALID_FEATURE_REQUESTED, "DL", "You requested features that are unavailable on this device. You should first query feature " "availability by calling vkGetPhysicalDeviceFeatures()."); } return skip_call; } VKAPI_ATTR VkResult VKAPI_CALL CreateDevice(VkPhysicalDevice gpu, const VkDeviceCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkDevice *pDevice) { instance_layer_data *my_instance_data = get_my_data_ptr(get_dispatch_key(gpu), instance_layer_data_map); bool skip_call = false; // Check that any requested features are available if (pCreateInfo->pEnabledFeatures) { skip_call |= ValidateRequestedFeatures(my_instance_data, gpu, pCreateInfo->pEnabledFeatures); } skip_call |= ValidateRequestedQueueFamilyProperties(my_instance_data, gpu, pCreateInfo); if (skip_call) { return VK_ERROR_VALIDATION_FAILED_EXT; } VkLayerDeviceCreateInfo *chain_info = get_chain_info(pCreateInfo, VK_LAYER_LINK_INFO); assert(chain_info->u.pLayerInfo); PFN_vkGetInstanceProcAddr fpGetInstanceProcAddr = chain_info->u.pLayerInfo->pfnNextGetInstanceProcAddr; PFN_vkGetDeviceProcAddr fpGetDeviceProcAddr = chain_info->u.pLayerInfo->pfnNextGetDeviceProcAddr; PFN_vkCreateDevice fpCreateDevice = (PFN_vkCreateDevice)fpGetInstanceProcAddr(my_instance_data->instance, "vkCreateDevice"); if (fpCreateDevice == NULL) { return VK_ERROR_INITIALIZATION_FAILED; } // Advance the link info for the next element on the chain chain_info->u.pLayerInfo = chain_info->u.pLayerInfo->pNext; VkResult result = fpCreateDevice(gpu, pCreateInfo, pAllocator, pDevice); if (result != VK_SUCCESS) { return result; } std::unique_lock lock(global_lock); layer_data *my_device_data = get_my_data_ptr(get_dispatch_key(*pDevice), layer_data_map); my_device_data->instance_data = my_instance_data; // Setup device dispatch table layer_init_device_dispatch_table(*pDevice, &my_device_data->dispatch_table, fpGetDeviceProcAddr); my_device_data->device = *pDevice; // Save PhysicalDevice handle my_device_data->physical_device = gpu; my_device_data->report_data = layer_debug_report_create_device(my_instance_data->report_data, *pDevice); checkDeviceRegisterExtensions(pCreateInfo, *pDevice); // Get physical device limits for this device my_instance_data->dispatch_table.GetPhysicalDeviceProperties(gpu, &(my_device_data->phys_dev_properties.properties)); uint32_t count; my_instance_data->dispatch_table.GetPhysicalDeviceQueueFamilyProperties(gpu, &count, nullptr); my_device_data->phys_dev_properties.queue_family_properties.resize(count); my_instance_data->dispatch_table.GetPhysicalDeviceQueueFamilyProperties( gpu, &count, &my_device_data->phys_dev_properties.queue_family_properties[0]); // TODO: device limits should make sure these are compatible if (pCreateInfo->pEnabledFeatures) { my_device_data->enabled_features = *pCreateInfo->pEnabledFeatures; } else { memset(&my_device_data->enabled_features, 0, sizeof(VkPhysicalDeviceFeatures)); } // Store physical device mem limits into device layer_data struct my_instance_data->dispatch_table.GetPhysicalDeviceMemoryProperties(gpu, &my_device_data->phys_dev_mem_props); lock.unlock(); ValidateLayerOrdering(*pCreateInfo); return result; } // prototype VKAPI_ATTR void VKAPI_CALL DestroyDevice(VkDevice device, const VkAllocationCallbacks *pAllocator) { // TODOSC : Shouldn't need any customization here bool skip = false; dispatch_key key = get_dispatch_key(device); layer_data *dev_data = get_my_data_ptr(key, layer_data_map); // Free all the memory std::unique_lock lock(global_lock); deletePipelines(dev_data); dev_data->renderPassMap.clear(); deleteCommandBuffers(dev_data); // This will also delete all sets in the pool & remove them from setMap deletePools(dev_data); // All sets should be removed assert(dev_data->setMap.empty()); for (auto del_layout : dev_data->descriptorSetLayoutMap) { delete del_layout.second; } dev_data->descriptorSetLayoutMap.clear(); dev_data->imageViewMap.clear(); dev_data->imageMap.clear(); dev_data->imageSubresourceMap.clear(); dev_data->imageLayoutMap.clear(); dev_data->bufferViewMap.clear(); dev_data->bufferMap.clear(); // Queues persist until device is destroyed dev_data->queueMap.clear(); log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_EXT, (uint64_t)device, __LINE__, MEMTRACK_NONE, "MEM", "Printing List details prior to vkDestroyDevice()"); log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_EXT, (uint64_t)device, __LINE__, MEMTRACK_NONE, "MEM", "================================================"); print_mem_list(dev_data); printCBList(dev_data); // Report any memory leaks DEVICE_MEM_INFO *pInfo = NULL; if (!dev_data->memObjMap.empty()) { for (auto ii = dev_data->memObjMap.begin(); ii != dev_data->memObjMap.end(); ++ii) { pInfo = (*ii).second.get(); if (pInfo->alloc_info.allocationSize != 0) { // Valid Usage: All child objects created on device must have been destroyed prior to destroying device skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, (uint64_t)pInfo->mem, __LINE__, MEMTRACK_MEMORY_LEAK, "MEM", "Mem Object 0x%" PRIx64 " has not been freed. You should clean up this memory by calling " "vkFreeMemory(0x%" PRIx64 ") prior to vkDestroyDevice().", (uint64_t)(pInfo->mem), (uint64_t)(pInfo->mem)); } } } layer_debug_report_destroy_device(device); lock.unlock(); #if DISPATCH_MAP_DEBUG fprintf(stderr, "Device: 0x%p, key: 0x%p\n", device, key); #endif if (!skip) { dev_data->dispatch_table.DestroyDevice(device, pAllocator); layer_data_map.erase(key); } } static const VkExtensionProperties instance_extensions[] = {{VK_EXT_DEBUG_REPORT_EXTENSION_NAME, VK_EXT_DEBUG_REPORT_SPEC_VERSION}}; // This validates that the initial layout specified in the command buffer for // the IMAGE is the same // as the global IMAGE layout static bool ValidateCmdBufImageLayouts(layer_data *dev_data, GLOBAL_CB_NODE *pCB) { bool skip_call = false; for (auto cb_image_data : pCB->imageLayoutMap) { VkImageLayout imageLayout; if (!FindLayout(dev_data, cb_image_data.first, imageLayout)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Cannot submit cmd buffer using deleted image 0x%" PRIx64 ".", reinterpret_cast(cb_image_data.first)); } else { if (cb_image_data.second.initialLayout == VK_IMAGE_LAYOUT_UNDEFINED) { // TODO: Set memory invalid which is in mem_tracker currently } else if (imageLayout != cb_image_data.second.initialLayout) { if (cb_image_data.first.hasSubresource) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(pCB->commandBuffer), __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Cannot submit cmd buffer using image (0x%" PRIx64 ") [sub-resource: aspectMask 0x%X array layer %u, mip level %u], " "with layout %s when first use is %s.", reinterpret_cast(cb_image_data.first.image), cb_image_data.first.subresource.aspectMask, cb_image_data.first.subresource.arrayLayer, cb_image_data.first.subresource.mipLevel, string_VkImageLayout(imageLayout), string_VkImageLayout(cb_image_data.second.initialLayout)); } else { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(pCB->commandBuffer), __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Cannot submit cmd buffer using image (0x%" PRIx64 ") with layout %s when " "first use is %s.", reinterpret_cast(cb_image_data.first.image), string_VkImageLayout(imageLayout), string_VkImageLayout(cb_image_data.second.initialLayout)); } } SetLayout(dev_data, cb_image_data.first, cb_image_data.second.layout); } } return skip_call; } // Loop through bound objects and increment their in_use counts // For any unknown objects, flag an error static bool ValidateAndIncrementBoundObjects(layer_data *dev_data, GLOBAL_CB_NODE const *cb_node) { bool skip = false; DRAW_STATE_ERROR error_code = DRAWSTATE_NONE; BASE_NODE *base_obj = nullptr; for (auto obj : cb_node->object_bindings) { switch (obj.type) { case VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT: { base_obj = getSetNode(dev_data, reinterpret_cast(obj.handle)); error_code = DRAWSTATE_INVALID_DESCRIPTOR_SET; break; } case VK_DEBUG_REPORT_OBJECT_TYPE_SAMPLER_EXT: { base_obj = getSamplerState(dev_data, reinterpret_cast(obj.handle)); error_code = DRAWSTATE_INVALID_SAMPLER; break; } case VK_DEBUG_REPORT_OBJECT_TYPE_QUERY_POOL_EXT: { base_obj = getQueryPoolNode(dev_data, reinterpret_cast(obj.handle)); error_code = DRAWSTATE_INVALID_QUERY_POOL; break; } case VK_DEBUG_REPORT_OBJECT_TYPE_PIPELINE_EXT: { base_obj = getPipelineState(dev_data, reinterpret_cast(obj.handle)); error_code = DRAWSTATE_INVALID_PIPELINE; break; } case VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT: { base_obj = getBufferState(dev_data, reinterpret_cast(obj.handle)); error_code = DRAWSTATE_INVALID_BUFFER; break; } case VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_VIEW_EXT: { base_obj = getBufferViewState(dev_data, reinterpret_cast(obj.handle)); error_code = DRAWSTATE_INVALID_BUFFER_VIEW; break; } case VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT: { base_obj = getImageState(dev_data, reinterpret_cast(obj.handle)); error_code = DRAWSTATE_INVALID_IMAGE; break; } case VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_VIEW_EXT: { base_obj = getImageViewState(dev_data, reinterpret_cast(obj.handle)); error_code = DRAWSTATE_INVALID_IMAGE_VIEW; break; } case VK_DEBUG_REPORT_OBJECT_TYPE_EVENT_EXT: { base_obj = getEventNode(dev_data, reinterpret_cast(obj.handle)); error_code = DRAWSTATE_INVALID_EVENT; break; } case VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_POOL_EXT: { base_obj = getDescriptorPoolState(dev_data, reinterpret_cast(obj.handle)); error_code = DRAWSTATE_INVALID_DESCRIPTOR_POOL; break; } case VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_POOL_EXT: { base_obj = getCommandPoolNode(dev_data, reinterpret_cast(obj.handle)); error_code = DRAWSTATE_INVALID_COMMAND_POOL; break; } case VK_DEBUG_REPORT_OBJECT_TYPE_FRAMEBUFFER_EXT: { base_obj = getFramebufferState(dev_data, reinterpret_cast(obj.handle)); error_code = DRAWSTATE_INVALID_FRAMEBUFFER; break; } case VK_DEBUG_REPORT_OBJECT_TYPE_RENDER_PASS_EXT: { base_obj = getRenderPassState(dev_data, reinterpret_cast(obj.handle)); error_code = DRAWSTATE_INVALID_RENDERPASS; break; } case VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT: { base_obj = getMemObjInfo(dev_data, reinterpret_cast(obj.handle)); error_code = DRAWSTATE_INVALID_DEVICE_MEMORY; break; } default: // TODO : Merge handling of other objects types into this code break; } if (!base_obj) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, obj.type, obj.handle, __LINE__, error_code, "DS", "Cannot submit cmd buffer using deleted %s 0x%" PRIx64 ".", object_type_to_string(obj.type), obj.handle); } else { base_obj->in_use.fetch_add(1); } } return skip; } // Track which resources are in-flight by atomically incrementing their "in_use" count static bool validateAndIncrementResources(layer_data *dev_data, GLOBAL_CB_NODE *cb_node) { bool skip_call = false; cb_node->in_use.fetch_add(1); dev_data->globalInFlightCmdBuffers.insert(cb_node->commandBuffer); // First Increment for all "generic" objects bound to cmd buffer, followed by special-case objects below skip_call |= ValidateAndIncrementBoundObjects(dev_data, cb_node); // TODO : We should be able to remove the NULL look-up checks from the code below as long as // all the corresponding cases are verified to cause CB_INVALID state and the CB_INVALID state // should then be flagged prior to calling this function for (auto drawDataElement : cb_node->drawData) { for (auto buffer : drawDataElement.buffers) { auto buffer_state = getBufferState(dev_data, buffer); if (!buffer_state) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT, (uint64_t)(buffer), __LINE__, DRAWSTATE_INVALID_BUFFER, "DS", "Cannot submit cmd buffer using deleted buffer 0x%" PRIx64 ".", (uint64_t)(buffer)); } else { buffer_state->in_use.fetch_add(1); } } } for (auto event : cb_node->writeEventsBeforeWait) { auto event_state = getEventNode(dev_data, event); if (event_state) event_state->write_in_use++; } return skip_call; } // Note: This function assumes that the global lock is held by the calling // thread. // TODO: untangle this. static bool cleanInFlightCmdBuffer(layer_data *my_data, VkCommandBuffer cmdBuffer) { bool skip_call = false; GLOBAL_CB_NODE *pCB = getCBNode(my_data, cmdBuffer); if (pCB) { for (auto queryEventsPair : pCB->waitedEventsBeforeQueryReset) { for (auto event : queryEventsPair.second) { if (my_data->eventMap[event].needsSignaled) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_QUERY_POOL_EXT, 0, 0, DRAWSTATE_INVALID_QUERY, "DS", "Cannot get query results on queryPool 0x%" PRIx64 " with index %d which was guarded by unsignaled event 0x%" PRIx64 ".", (uint64_t)(queryEventsPair.first.pool), queryEventsPair.first.index, (uint64_t)(event)); } } } } return skip_call; } // TODO: nuke this completely. // Decrement cmd_buffer in_use and if it goes to 0 remove cmd_buffer from globalInFlightCmdBuffers static inline void removeInFlightCmdBuffer(layer_data *dev_data, VkCommandBuffer cmd_buffer) { // Pull it off of global list initially, but if we find it in any other queue list, add it back in GLOBAL_CB_NODE *pCB = getCBNode(dev_data, cmd_buffer); pCB->in_use.fetch_sub(1); if (!pCB->in_use.load()) { dev_data->globalInFlightCmdBuffers.erase(cmd_buffer); } } // Decrement in-use count for objects bound to command buffer static void DecrementBoundResources(layer_data *dev_data, GLOBAL_CB_NODE const *cb_node) { BASE_NODE *base_obj = nullptr; for (auto obj : cb_node->object_bindings) { base_obj = GetStateStructPtrFromObject(dev_data, obj); if (base_obj) { base_obj->in_use.fetch_sub(1); } } } static bool RetireWorkOnQueue(layer_data *dev_data, QUEUE_NODE *pQueue, uint64_t seq) { bool skip_call = false; // TODO: extract everything that might fail to precheck std::unordered_map otherQueueSeqs; // Roll this queue forward, one submission at a time. while (pQueue->seq < seq) { auto & submission = pQueue->submissions.front(); for (auto & wait : submission.waitSemaphores) { auto pSemaphore = getSemaphoreNode(dev_data, wait.semaphore); if (pSemaphore) { pSemaphore->in_use.fetch_sub(1); } auto & lastSeq = otherQueueSeqs[wait.queue]; lastSeq = std::max(lastSeq, wait.seq); } for (auto & semaphore : submission.signalSemaphores) { auto pSemaphore = getSemaphoreNode(dev_data, semaphore); if (pSemaphore) { pSemaphore->in_use.fetch_sub(1); } } for (auto cb : submission.cbs) { auto cb_node = getCBNode(dev_data, cb); if (!cb_node) { continue; } // First perform decrement on general case bound objects DecrementBoundResources(dev_data, cb_node); for (auto drawDataElement : cb_node->drawData) { for (auto buffer : drawDataElement.buffers) { auto buffer_state = getBufferState(dev_data, buffer); if (buffer_state) { buffer_state->in_use.fetch_sub(1); } } } for (auto event : cb_node->writeEventsBeforeWait) { auto eventNode = dev_data->eventMap.find(event); if (eventNode != dev_data->eventMap.end()) { eventNode->second.write_in_use--; } } for (auto queryStatePair : cb_node->queryToStateMap) { dev_data->queryToStateMap[queryStatePair.first] = queryStatePair.second; } for (auto eventStagePair : cb_node->eventToStageMap) { dev_data->eventMap[eventStagePair.first].stageMask = eventStagePair.second; } skip_call |= cleanInFlightCmdBuffer(dev_data, cb); removeInFlightCmdBuffer(dev_data, cb); } auto pFence = getFenceNode(dev_data, submission.fence); if (pFence) { pFence->state = FENCE_RETIRED; } pQueue->submissions.pop_front(); pQueue->seq++; } // Roll other queues forward to the highest seq we saw a wait for for (auto qs : otherQueueSeqs) { skip_call |= RetireWorkOnQueue(dev_data, getQueueNode(dev_data, qs.first), qs.second); } return skip_call; } // Submit a fence to a queue, delimiting previous fences and previous untracked // work by it. static void SubmitFence(QUEUE_NODE *pQueue, FENCE_NODE *pFence, uint64_t submitCount) { pFence->state = FENCE_INFLIGHT; pFence->signaler.first = pQueue->queue; pFence->signaler.second = pQueue->seq + pQueue->submissions.size() + submitCount; } static bool validateCommandBufferSimultaneousUse(layer_data *dev_data, GLOBAL_CB_NODE *pCB) { bool skip_call = false; if (dev_data->globalInFlightCmdBuffers.count(pCB->commandBuffer) && !(pCB->beginInfo.flags & VK_COMMAND_BUFFER_USAGE_SIMULTANEOUS_USE_BIT)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, 0, __LINE__, DRAWSTATE_INVALID_CB_SIMULTANEOUS_USE, "DS", "Command Buffer 0x%" PRIx64 " is already in use and is not marked for simultaneous use.", reinterpret_cast(pCB->commandBuffer)); } return skip_call; } static bool validateCommandBufferState(layer_data *dev_data, GLOBAL_CB_NODE *pCB, const char *call_source) { bool skip = false; if (dev_data->instance_data->disabled.command_buffer_state) return skip; // Validate ONE_TIME_SUBMIT_BIT CB is not being submitted more than once if ((pCB->beginInfo.flags & VK_COMMAND_BUFFER_USAGE_ONE_TIME_SUBMIT_BIT) && (pCB->submitCount > 1)) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, 0, __LINE__, DRAWSTATE_COMMAND_BUFFER_SINGLE_SUBMIT_VIOLATION, "DS", "Commandbuffer 0x%" PRIxLEAST64 " was begun w/ VK_COMMAND_BUFFER_USAGE_ONE_TIME_SUBMIT_BIT " "set, but has been submitted 0x%" PRIxLEAST64 " times.", (uint64_t)(pCB->commandBuffer), pCB->submitCount); } // Validate that cmd buffers have been updated if (CB_RECORDED != pCB->state) { if (CB_INVALID == pCB->state) { // Inform app of reason CB invalid for (auto obj : pCB->broken_bindings) { const char *type_str = object_type_to_string(obj.type); // Descriptor sets are a special case that can be either destroyed or updated to invalidated a CB const char *cause_str = (obj.type == VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT) ? "destroyed or updated" : "destroyed"; skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(pCB->commandBuffer), __LINE__, DRAWSTATE_INVALID_COMMAND_BUFFER, "DS", "You are submitting command buffer 0x%" PRIxLEAST64 " that is invalid because bound %s 0x%" PRIxLEAST64 " was %s.", reinterpret_cast(pCB->commandBuffer), type_str, obj.handle, cause_str); } } else { // Flag error for using CB w/o vkEndCommandBuffer() called skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)(pCB->commandBuffer), __LINE__, DRAWSTATE_NO_END_COMMAND_BUFFER, "DS", "You must call vkEndCommandBuffer() on command buffer 0x%" PRIxLEAST64 " before this call to %s!", reinterpret_cast(pCB->commandBuffer), call_source); } } return skip; } // Validate that queueFamilyIndices of primary command buffers match this queue // Secondary command buffers were previously validated in vkCmdExecuteCommands(). static bool validateQueueFamilyIndices(layer_data *dev_data, GLOBAL_CB_NODE *pCB, VkQueue queue) { bool skip_call = false; auto pPool = getCommandPoolNode(dev_data, pCB->createInfo.commandPool); auto queue_node = getQueueNode(dev_data, queue); if (pPool && queue_node && (pPool->queueFamilyIndex != queue_node->queueFamilyIndex)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(pCB->commandBuffer), __LINE__, DRAWSTATE_INVALID_QUEUE_FAMILY, "DS", "vkQueueSubmit: Primary command buffer 0x%" PRIxLEAST64 " created in queue family %d is being submitted on queue 0x%" PRIxLEAST64 " from queue family %d.", reinterpret_cast(pCB->commandBuffer), pPool->queueFamilyIndex, reinterpret_cast(queue), queue_node->queueFamilyIndex); } return skip_call; } static bool validatePrimaryCommandBufferState(layer_data *dev_data, GLOBAL_CB_NODE *pCB) { // Track in-use for resources off of primary and any secondary CBs bool skip_call = false; // If USAGE_SIMULTANEOUS_USE_BIT not set then CB cannot already be executing // on device skip_call |= validateCommandBufferSimultaneousUse(dev_data, pCB); skip_call |= validateAndIncrementResources(dev_data, pCB); if (!pCB->secondaryCommandBuffers.empty()) { for (auto secondaryCmdBuffer : pCB->secondaryCommandBuffers) { GLOBAL_CB_NODE *pSubCB = getCBNode(dev_data, secondaryCmdBuffer); skip_call |= validateAndIncrementResources(dev_data, pSubCB); if ((pSubCB->primaryCommandBuffer != pCB->commandBuffer) && !(pSubCB->beginInfo.flags & VK_COMMAND_BUFFER_USAGE_SIMULTANEOUS_USE_BIT)) { log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, 0, __LINE__, DRAWSTATE_COMMAND_BUFFER_SINGLE_SUBMIT_VIOLATION, "DS", "Commandbuffer 0x%" PRIxLEAST64 " was submitted with secondary buffer 0x%" PRIxLEAST64 " but that buffer has subsequently been bound to " "primary cmd buffer 0x%" PRIxLEAST64 " and it does not have VK_COMMAND_BUFFER_USAGE_SIMULTANEOUS_USE_BIT set.", reinterpret_cast(pCB->commandBuffer), reinterpret_cast(secondaryCmdBuffer), reinterpret_cast(pSubCB->primaryCommandBuffer)); } } } skip_call |= validateCommandBufferState(dev_data, pCB, "vkQueueSubmit()"); return skip_call; } static bool ValidateFenceForSubmit(layer_data *dev_data, FENCE_NODE *pFence) { bool skip_call = false; if (pFence) { if (pFence->state == FENCE_INFLIGHT) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_FENCE_EXT, (uint64_t)(pFence->fence), __LINE__, DRAWSTATE_INVALID_FENCE, "DS", "Fence 0x%" PRIx64 " is already in use by another submission.", (uint64_t)(pFence->fence)); } else if (pFence->state == FENCE_RETIRED) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_FENCE_EXT, reinterpret_cast(pFence->fence), __LINE__, MEMTRACK_INVALID_FENCE_STATE, "MEM", "Fence 0x%" PRIxLEAST64 " submitted in SIGNALED state. Fences must be reset before being submitted", reinterpret_cast(pFence->fence)); } } return skip_call; } VKAPI_ATTR VkResult VKAPI_CALL QueueSubmit(VkQueue queue, uint32_t submitCount, const VkSubmitInfo *pSubmits, VkFence fence) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(queue), layer_data_map); VkResult result = VK_ERROR_VALIDATION_FAILED_EXT; std::unique_lock lock(global_lock); auto pQueue = getQueueNode(dev_data, queue); auto pFence = getFenceNode(dev_data, fence); skip_call |= ValidateFenceForSubmit(dev_data, pFence); if (skip_call) { return VK_ERROR_VALIDATION_FAILED_EXT; } // TODO : Review these old print functions and clean up as appropriate print_mem_list(dev_data); printCBList(dev_data); // Mark the fence in-use. if (pFence) { SubmitFence(pQueue, pFence, std::max(1u, submitCount)); } // Now verify each individual submit for (uint32_t submit_idx = 0; submit_idx < submitCount; submit_idx++) { const VkSubmitInfo *submit = &pSubmits[submit_idx]; vector semaphore_waits; vector semaphore_signals; for (uint32_t i = 0; i < submit->waitSemaphoreCount; ++i) { VkSemaphore semaphore = submit->pWaitSemaphores[i]; auto pSemaphore = getSemaphoreNode(dev_data, semaphore); if (pSemaphore) { if (pSemaphore->signaled) { if (pSemaphore->signaler.first != VK_NULL_HANDLE) { semaphore_waits.push_back({semaphore, pSemaphore->signaler.first, pSemaphore->signaler.second}); pSemaphore->in_use.fetch_add(1); } pSemaphore->signaler.first = VK_NULL_HANDLE; pSemaphore->signaled = false; } else { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_SEMAPHORE_EXT, reinterpret_cast(semaphore), __LINE__, DRAWSTATE_QUEUE_FORWARD_PROGRESS, "DS", "Queue 0x%" PRIx64 " is waiting on semaphore 0x%" PRIx64 " that has no way to be signaled.", reinterpret_cast(queue), reinterpret_cast(semaphore)); } } } for (uint32_t i = 0; i < submit->signalSemaphoreCount; ++i) { VkSemaphore semaphore = submit->pSignalSemaphores[i]; auto pSemaphore = getSemaphoreNode(dev_data, semaphore); if (pSemaphore) { if (pSemaphore->signaled) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_SEMAPHORE_EXT, reinterpret_cast(semaphore), __LINE__, DRAWSTATE_QUEUE_FORWARD_PROGRESS, "DS", "Queue 0x%" PRIx64 " is signaling semaphore 0x%" PRIx64 " that has already been signaled but not waited on by queue 0x%" PRIx64 ".", reinterpret_cast(queue), reinterpret_cast(semaphore), reinterpret_cast(pSemaphore->signaler.first)); } else { pSemaphore->signaler.first = queue; pSemaphore->signaler.second = pQueue->seq + pQueue->submissions.size() + 1; pSemaphore->signaled = true; pSemaphore->in_use.fetch_add(1); semaphore_signals.push_back(semaphore); } } } std::vector cbs; for (uint32_t i = 0; i < submit->commandBufferCount; i++) { auto cb_node = getCBNode(dev_data, submit->pCommandBuffers[i]); skip_call |= ValidateCmdBufImageLayouts(dev_data, cb_node); if (cb_node) { cbs.push_back(submit->pCommandBuffers[i]); for (auto secondaryCmdBuffer : cb_node->secondaryCommandBuffers) { cbs.push_back(secondaryCmdBuffer); } cb_node->submitCount++; // increment submit count skip_call |= validatePrimaryCommandBufferState(dev_data, cb_node); skip_call |= validateQueueFamilyIndices(dev_data, cb_node, queue); // Potential early exit here as bad object state may crash in delayed function calls if (skip_call) return result; // Call submit-time functions to validate/update state for (auto &function : cb_node->validate_functions) { skip_call |= function(); } for (auto &function : cb_node->eventUpdates) { skip_call |= function(queue); } for (auto &function : cb_node->queryUpdates) { skip_call |= function(queue); } } } pQueue->submissions.emplace_back(cbs, semaphore_waits, semaphore_signals, submit_idx == submitCount - 1 ? fence : VK_NULL_HANDLE); } if (pFence && !submitCount) { // If no submissions, but just dropping a fence on the end of the queue, // record an empty submission with just the fence, so we can determine // its completion. pQueue->submissions.emplace_back(std::vector(), std::vector(), std::vector(), fence); } lock.unlock(); if (!skip_call) result = dev_data->dispatch_table.QueueSubmit(queue, submitCount, pSubmits, fence); return result; } static bool PreCallValidateAllocateMemory(layer_data *dev_data) { bool skip = false; if (dev_data->memObjMap.size() >= dev_data->phys_dev_properties.properties.limits.maxMemoryAllocationCount) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_EXT, reinterpret_cast(dev_data->device), __LINE__, VALIDATION_ERROR_00611, "MEM", "Number of currently valid memory objects is not less than the maximum allowed (%u). %s", dev_data->phys_dev_properties.properties.limits.maxMemoryAllocationCount, validation_error_map[VALIDATION_ERROR_00611]); } return skip; } static void PostCallRecordAllocateMemory(layer_data *dev_data, const VkMemoryAllocateInfo *pAllocateInfo, VkDeviceMemory *pMemory) { add_mem_obj_info(dev_data, dev_data->device, *pMemory, pAllocateInfo); print_mem_list(dev_data); return; } VKAPI_ATTR VkResult VKAPI_CALL AllocateMemory(VkDevice device, const VkMemoryAllocateInfo *pAllocateInfo, const VkAllocationCallbacks *pAllocator, VkDeviceMemory *pMemory) { VkResult result = VK_ERROR_VALIDATION_FAILED_EXT; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); std::unique_lock lock(global_lock); bool skip = PreCallValidateAllocateMemory(dev_data); if (!skip) { lock.unlock(); result = dev_data->dispatch_table.AllocateMemory(device, pAllocateInfo, pAllocator, pMemory); lock.lock(); if (VK_SUCCESS == result) { PostCallRecordAllocateMemory(dev_data, pAllocateInfo, pMemory); } } return result; } // For given obj node, if it is use, flag a validation error and return callback result, else return false bool ValidateObjectNotInUse(const layer_data *dev_data, BASE_NODE *obj_node, VK_OBJECT obj_struct, UNIQUE_VALIDATION_ERROR_CODE error_code) { if (dev_data->instance_data->disabled.object_in_use) return false; bool skip = false; if (obj_node->in_use.load()) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, obj_struct.type, obj_struct.handle, __LINE__, error_code, "DS", "Cannot delete %s 0x%" PRIx64 " that is currently in use by a command buffer. %s", object_type_to_string(obj_struct.type), obj_struct.handle, validation_error_map[error_code]); } return skip; } static bool PreCallValidateFreeMemory(layer_data *dev_data, VkDeviceMemory mem, DEVICE_MEM_INFO **mem_info, VK_OBJECT *obj_struct) { *mem_info = getMemObjInfo(dev_data, mem); *obj_struct = {reinterpret_cast(mem), VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT}; if (dev_data->instance_data->disabled.free_memory) return false; bool skip = false; if (*mem_info) { skip |= ValidateObjectNotInUse(dev_data, *mem_info, *obj_struct, VALIDATION_ERROR_00620); } return skip; } static void PostCallRecordFreeMemory(layer_data *dev_data, VkDeviceMemory mem, DEVICE_MEM_INFO *mem_info, VK_OBJECT obj_struct) { // Clear mem binding for any bound objects for (auto obj : mem_info->obj_bindings) { log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, obj.type, obj.handle, __LINE__, MEMTRACK_FREED_MEM_REF, "MEM", "VK Object 0x%" PRIxLEAST64 " still has a reference to mem obj 0x%" PRIxLEAST64, obj.handle, (uint64_t)mem_info->mem); switch (obj.type) { case VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT: { auto image_state = getImageState(dev_data, reinterpret_cast(obj.handle)); assert(image_state); // Any destroyed images should already be removed from bindings image_state->binding.mem = MEMORY_UNBOUND; break; } case VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT: { auto buffer_state = getBufferState(dev_data, reinterpret_cast(obj.handle)); assert(buffer_state); // Any destroyed buffers should already be removed from bindings buffer_state->binding.mem = MEMORY_UNBOUND; break; } default: // Should only have buffer or image objects bound to memory assert(0); } } // Any bound cmd buffers are now invalid invalidateCommandBuffers(mem_info->cb_bindings, obj_struct); dev_data->memObjMap.erase(mem); } VKAPI_ATTR void VKAPI_CALL FreeMemory(VkDevice device, VkDeviceMemory mem, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); DEVICE_MEM_INFO *mem_info = nullptr; VK_OBJECT obj_struct; std::unique_lock lock(global_lock); bool skip = PreCallValidateFreeMemory(dev_data, mem, &mem_info, &obj_struct); if (!skip) { lock.unlock(); dev_data->dispatch_table.FreeMemory(device, mem, pAllocator); lock.lock(); PostCallRecordFreeMemory(dev_data, mem, mem_info, obj_struct); } } // Validate that given Map memory range is valid. This means that the memory should not already be mapped, // and that the size of the map range should be: // 1. Not zero // 2. Within the size of the memory allocation static bool ValidateMapMemRange(layer_data *my_data, VkDeviceMemory mem, VkDeviceSize offset, VkDeviceSize size) { bool skip_call = false; if (size == 0) { skip_call = log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, (uint64_t)mem, __LINE__, MEMTRACK_INVALID_MAP, "MEM", "VkMapMemory: Attempting to map memory range of size zero"); } auto mem_element = my_data->memObjMap.find(mem); if (mem_element != my_data->memObjMap.end()) { auto mem_info = mem_element->second.get(); // It is an application error to call VkMapMemory on an object that is already mapped if (mem_info->mem_range.size != 0) { skip_call = log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, (uint64_t)mem, __LINE__, MEMTRACK_INVALID_MAP, "MEM", "VkMapMemory: Attempting to map memory on an already-mapped object 0x%" PRIxLEAST64, (uint64_t)mem); } // Validate that offset + size is within object's allocationSize if (size == VK_WHOLE_SIZE) { if (offset >= mem_info->alloc_info.allocationSize) { skip_call = log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, (uint64_t)mem, __LINE__, MEMTRACK_INVALID_MAP, "MEM", "Mapping Memory from 0x%" PRIx64 " to 0x%" PRIx64 " with size of VK_WHOLE_SIZE oversteps total array size 0x%" PRIx64, offset, mem_info->alloc_info.allocationSize, mem_info->alloc_info.allocationSize); } } else { if ((offset + size) > mem_info->alloc_info.allocationSize) { skip_call = log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, (uint64_t)mem, __LINE__, MEMTRACK_INVALID_MAP, "MEM", "Mapping Memory from 0x%" PRIx64 " to 0x%" PRIx64 " oversteps total array size 0x%" PRIx64, offset, size + offset, mem_info->alloc_info.allocationSize); } } } return skip_call; } static void storeMemRanges(layer_data *my_data, VkDeviceMemory mem, VkDeviceSize offset, VkDeviceSize size) { auto mem_info = getMemObjInfo(my_data, mem); if (mem_info) { mem_info->mem_range.offset = offset; mem_info->mem_range.size = size; } } static bool deleteMemRanges(layer_data *my_data, VkDeviceMemory mem) { bool skip_call = false; auto mem_info = getMemObjInfo(my_data, mem); if (mem_info) { if (!mem_info->mem_range.size) { // Valid Usage: memory must currently be mapped skip_call = log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, (uint64_t)mem, __LINE__, MEMTRACK_INVALID_MAP, "MEM", "Unmapping Memory without memory being mapped: mem obj 0x%" PRIxLEAST64, (uint64_t)mem); } mem_info->mem_range.size = 0; if (mem_info->shadow_copy) { free(mem_info->shadow_copy_base); mem_info->shadow_copy_base = 0; mem_info->shadow_copy = 0; } } return skip_call; } // Guard value for pad data static char NoncoherentMemoryFillValue = 0xb; static void initializeAndTrackMemory(layer_data *dev_data, VkDeviceMemory mem, VkDeviceSize offset, VkDeviceSize size, void **ppData) { auto mem_info = getMemObjInfo(dev_data, mem); if (mem_info) { mem_info->p_driver_data = *ppData; uint32_t index = mem_info->alloc_info.memoryTypeIndex; if (dev_data->phys_dev_mem_props.memoryTypes[index].propertyFlags & VK_MEMORY_PROPERTY_HOST_COHERENT_BIT) { mem_info->shadow_copy = 0; } else { if (size == VK_WHOLE_SIZE) { size = mem_info->alloc_info.allocationSize - offset; } mem_info->shadow_pad_size = dev_data->phys_dev_properties.properties.limits.minMemoryMapAlignment; assert(vk_safe_modulo(mem_info->shadow_pad_size, dev_data->phys_dev_properties.properties.limits.minMemoryMapAlignment) == 0); // Ensure start of mapped region reflects hardware alignment constraints uint64_t map_alignment = dev_data->phys_dev_properties.properties.limits.minMemoryMapAlignment; // From spec: (ppData - offset) must be aligned to at least limits::minMemoryMapAlignment. uint64_t start_offset = offset % map_alignment; // Data passed to driver will be wrapped by a guardband of data to detect over- or under-writes. mem_info->shadow_copy_base = malloc(static_cast(2 * mem_info->shadow_pad_size + size + map_alignment + start_offset)); mem_info->shadow_copy = reinterpret_cast((reinterpret_cast(mem_info->shadow_copy_base) + map_alignment) & ~(map_alignment - 1)) + start_offset; assert(vk_safe_modulo(reinterpret_cast(mem_info->shadow_copy) + mem_info->shadow_pad_size - start_offset, map_alignment) == 0); memset(mem_info->shadow_copy, NoncoherentMemoryFillValue, static_cast(2 * mem_info->shadow_pad_size + size)); *ppData = static_cast(mem_info->shadow_copy) + mem_info->shadow_pad_size; } } } // Verify that state for fence being waited on is appropriate. That is, // a fence being waited on should not already be signaled and // it should have been submitted on a queue or during acquire next image static inline bool verifyWaitFenceState(layer_data *dev_data, VkFence fence, const char *apiCall) { bool skip_call = false; auto pFence = getFenceNode(dev_data, fence); if (pFence) { if (pFence->state == FENCE_UNSIGNALED) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_FENCE_EXT, reinterpret_cast(fence), __LINE__, MEMTRACK_INVALID_FENCE_STATE, "MEM", "%s called for fence 0x%" PRIxLEAST64 " which has not been submitted on a Queue or during " "acquire next image.", apiCall, reinterpret_cast(fence)); } } return skip_call; } static bool RetireFence(layer_data *dev_data, VkFence fence) { auto pFence = getFenceNode(dev_data, fence); if (pFence->signaler.first != VK_NULL_HANDLE) { /* Fence signaller is a queue -- use this as proof that prior operations * on that queue have completed. */ return RetireWorkOnQueue(dev_data, getQueueNode(dev_data, pFence->signaler.first), pFence->signaler.second); } else { /* Fence signaller is the WSI. We're not tracking what the WSI op * actually /was/ in CV yet, but we need to mark the fence as retired. */ pFence->state = FENCE_RETIRED; return false; } } VKAPI_ATTR VkResult VKAPI_CALL WaitForFences(VkDevice device, uint32_t fenceCount, const VkFence *pFences, VkBool32 waitAll, uint64_t timeout) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); bool skip_call = false; // Verify fence status of submitted fences std::unique_lock lock(global_lock); for (uint32_t i = 0; i < fenceCount; i++) { skip_call |= verifyWaitFenceState(dev_data, pFences[i], "vkWaitForFences"); } lock.unlock(); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult result = dev_data->dispatch_table.WaitForFences(device, fenceCount, pFences, waitAll, timeout); if (result == VK_SUCCESS) { lock.lock(); // When we know that all fences are complete we can clean/remove their CBs if (waitAll || fenceCount == 1) { for (uint32_t i = 0; i < fenceCount; i++) { skip_call |= RetireFence(dev_data, pFences[i]); } } // NOTE : Alternate case not handled here is when some fences have completed. In // this case for app to guarantee which fences completed it will have to call // vkGetFenceStatus() at which point we'll clean/remove their CBs if complete. lock.unlock(); } if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; return result; } VKAPI_ATTR VkResult VKAPI_CALL GetFenceStatus(VkDevice device, VkFence fence) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); bool skip_call = false; std::unique_lock lock(global_lock); skip_call = verifyWaitFenceState(dev_data, fence, "vkGetFenceStatus"); lock.unlock(); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult result = dev_data->dispatch_table.GetFenceStatus(device, fence); lock.lock(); if (result == VK_SUCCESS) { skip_call |= RetireFence(dev_data, fence); } lock.unlock(); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; return result; } VKAPI_ATTR void VKAPI_CALL GetDeviceQueue(VkDevice device, uint32_t queueFamilyIndex, uint32_t queueIndex, VkQueue *pQueue) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); dev_data->dispatch_table.GetDeviceQueue(device, queueFamilyIndex, queueIndex, pQueue); std::lock_guard lock(global_lock); // Add queue to tracking set only if it is new auto result = dev_data->queues.emplace(*pQueue); if (result.second == true) { QUEUE_NODE *pQNode = &dev_data->queueMap[*pQueue]; pQNode->queue = *pQueue; pQNode->queueFamilyIndex = queueFamilyIndex; pQNode->seq = 0; } } VKAPI_ATTR VkResult VKAPI_CALL QueueWaitIdle(VkQueue queue) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(queue), layer_data_map); bool skip_call = false; std::unique_lock lock(global_lock); auto pQueue = getQueueNode(dev_data, queue); skip_call |= RetireWorkOnQueue(dev_data, pQueue, pQueue->seq + pQueue->submissions.size()); lock.unlock(); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult result = dev_data->dispatch_table.QueueWaitIdle(queue); return result; } VKAPI_ATTR VkResult VKAPI_CALL DeviceWaitIdle(VkDevice device) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); std::unique_lock lock(global_lock); for (auto & queue : dev_data->queueMap) { skip_call |= RetireWorkOnQueue(dev_data, &queue.second, queue.second.seq + queue.second.submissions.size()); } lock.unlock(); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult result = dev_data->dispatch_table.DeviceWaitIdle(device); return result; } VKAPI_ATTR void VKAPI_CALL DestroyFence(VkDevice device, VkFence fence, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); bool skip_call = false; std::unique_lock lock(global_lock); auto fence_pair = dev_data->fenceMap.find(fence); if (fence_pair != dev_data->fenceMap.end()) { if (fence_pair->second.state == FENCE_INFLIGHT) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_FENCE_EXT, (uint64_t)(fence), __LINE__, DRAWSTATE_INVALID_FENCE, "DS", "Fence 0x%" PRIx64 " is in use.", (uint64_t)(fence)); } dev_data->fenceMap.erase(fence_pair); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.DestroyFence(device, fence, pAllocator); } VKAPI_ATTR void VKAPI_CALL DestroySemaphore(VkDevice device, VkSemaphore semaphore, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); bool skip = false; std::unique_lock lock(global_lock); auto sema_node = getSemaphoreNode(dev_data, semaphore); if (sema_node) { skip |= ValidateObjectNotInUse(dev_data, sema_node, {reinterpret_cast(semaphore), VK_DEBUG_REPORT_OBJECT_TYPE_SEMAPHORE_EXT}, VALIDATION_ERROR_00199); } if (!skip) { dev_data->semaphoreMap.erase(semaphore); lock.unlock(); dev_data->dispatch_table.DestroySemaphore(device, semaphore, pAllocator); } } static bool PreCallValidateDestroyEvent(layer_data *dev_data, VkEvent event, EVENT_STATE **event_state, VK_OBJECT *obj_struct) { *event_state = getEventNode(dev_data, event); *obj_struct = {reinterpret_cast(event), VK_DEBUG_REPORT_OBJECT_TYPE_EVENT_EXT}; if (dev_data->instance_data->disabled.destroy_event) return false; bool skip = false; if (*event_state) { skip |= ValidateObjectNotInUse(dev_data, *event_state, *obj_struct, VALIDATION_ERROR_00213); } return skip; } static void PostCallRecordDestroyEvent(layer_data *dev_data, VkEvent event, EVENT_STATE *event_state, VK_OBJECT obj_struct) { invalidateCommandBuffers(event_state->cb_bindings, obj_struct); dev_data->eventMap.erase(event); } VKAPI_ATTR void VKAPI_CALL DestroyEvent(VkDevice device, VkEvent event, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); EVENT_STATE *event_state = nullptr; VK_OBJECT obj_struct; std::unique_lock lock(global_lock); bool skip = PreCallValidateDestroyEvent(dev_data, event, &event_state, &obj_struct); if (!skip) { lock.unlock(); dev_data->dispatch_table.DestroyEvent(device, event, pAllocator); lock.lock(); PostCallRecordDestroyEvent(dev_data, event, event_state, obj_struct); } } VKAPI_ATTR void VKAPI_CALL DestroyQueryPool(VkDevice device, VkQueryPool queryPool, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); bool skip = false; std::unique_lock lock(global_lock); auto qp_node = getQueryPoolNode(dev_data, queryPool); if (qp_node) { VK_OBJECT obj_struct = {reinterpret_cast(queryPool), VK_DEBUG_REPORT_OBJECT_TYPE_QUERY_POOL_EXT}; skip |= ValidateObjectNotInUse(dev_data, qp_node, obj_struct, VALIDATION_ERROR_01012); // Any bound cmd buffers are now invalid invalidateCommandBuffers(qp_node->cb_bindings, obj_struct); } if (!skip) { dev_data->queryPoolMap.erase(queryPool); lock.unlock(); dev_data->dispatch_table.DestroyQueryPool(device, queryPool, pAllocator); } } VKAPI_ATTR VkResult VKAPI_CALL GetQueryPoolResults(VkDevice device, VkQueryPool queryPool, uint32_t firstQuery, uint32_t queryCount, size_t dataSize, void *pData, VkDeviceSize stride, VkQueryResultFlags flags) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); unordered_map> queriesInFlight; std::unique_lock lock(global_lock); for (auto cmdBuffer : dev_data->globalInFlightCmdBuffers) { auto pCB = getCBNode(dev_data, cmdBuffer); for (auto queryStatePair : pCB->queryToStateMap) { queriesInFlight[queryStatePair.first].push_back(cmdBuffer); } } bool skip_call = false; for (uint32_t i = 0; i < queryCount; ++i) { QueryObject query = {queryPool, firstQuery + i}; auto queryElement = queriesInFlight.find(query); auto queryToStateElement = dev_data->queryToStateMap.find(query); if (queryToStateElement != dev_data->queryToStateMap.end()) { // Available and in flight if (queryElement != queriesInFlight.end() && queryToStateElement != dev_data->queryToStateMap.end() && queryToStateElement->second) { for (auto cmdBuffer : queryElement->second) { auto pCB = getCBNode(dev_data, cmdBuffer); auto queryEventElement = pCB->waitedEventsBeforeQueryReset.find(query); if (queryEventElement == pCB->waitedEventsBeforeQueryReset.end()) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_QUERY_POOL_EXT, 0, __LINE__, DRAWSTATE_INVALID_QUERY, "DS", "Cannot get query results on queryPool 0x%" PRIx64 " with index %d which is in flight.", (uint64_t)(queryPool), firstQuery + i); } else { for (auto event : queryEventElement->second) { dev_data->eventMap[event].needsSignaled = true; } } } // Unavailable and in flight } else if (queryElement != queriesInFlight.end() && queryToStateElement != dev_data->queryToStateMap.end() && !queryToStateElement->second) { // TODO : Can there be the same query in use by multiple command buffers in flight? bool make_available = false; for (auto cmdBuffer : queryElement->second) { auto pCB = getCBNode(dev_data, cmdBuffer); make_available |= pCB->queryToStateMap[query]; } if (!(((flags & VK_QUERY_RESULT_PARTIAL_BIT) || (flags & VK_QUERY_RESULT_WAIT_BIT)) && make_available)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_QUERY_POOL_EXT, 0, __LINE__, DRAWSTATE_INVALID_QUERY, "DS", "Cannot get query results on queryPool 0x%" PRIx64 " with index %d which is unavailable.", (uint64_t)(queryPool), firstQuery + i); } // Unavailable } else if (queryToStateElement != dev_data->queryToStateMap.end() && !queryToStateElement->second) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_QUERY_POOL_EXT, 0, __LINE__, DRAWSTATE_INVALID_QUERY, "DS", "Cannot get query results on queryPool 0x%" PRIx64 " with index %d which is unavailable.", (uint64_t)(queryPool), firstQuery + i); // Unitialized } else if (queryToStateElement == dev_data->queryToStateMap.end()) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_QUERY_POOL_EXT, 0, __LINE__, DRAWSTATE_INVALID_QUERY, "DS", "Cannot get query results on queryPool 0x%" PRIx64 " with index %d as data has not been collected for this index.", (uint64_t)(queryPool), firstQuery + i); } } } lock.unlock(); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; return dev_data->dispatch_table.GetQueryPoolResults(device, queryPool, firstQuery, queryCount, dataSize, pData, stride, flags); } static bool validateIdleBuffer(const layer_data *my_data, VkBuffer buffer) { bool skip_call = false; auto buffer_state = getBufferState(my_data, buffer); if (!buffer_state) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT, (uint64_t)(buffer), __LINE__, DRAWSTATE_DOUBLE_DESTROY, "DS", "Cannot free buffer 0x%" PRIxLEAST64 " that has not been allocated.", (uint64_t)(buffer)); } else { if (buffer_state->in_use.load()) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT, (uint64_t)(buffer), __LINE__, DRAWSTATE_OBJECT_INUSE, "DS", "Cannot free buffer 0x%" PRIxLEAST64 " that is in use by a command buffer.", (uint64_t)(buffer)); } } return skip_call; } // Return true if given ranges intersect, else false // Prereq : For both ranges, range->end - range->start > 0. This case should have already resulted // in an error so not checking that here // pad_ranges bool indicates a linear and non-linear comparison which requires padding // In the case where padding is required, if an alias is encountered then a validation error is reported and skip_call // may be set by the callback function so caller should merge in skip_call value if padding case is possible. static bool rangesIntersect(layer_data const *dev_data, MEMORY_RANGE const *range1, MEMORY_RANGE const *range2, bool *skip_call) { *skip_call = false; auto r1_start = range1->start; auto r1_end = range1->end; auto r2_start = range2->start; auto r2_end = range2->end; VkDeviceSize pad_align = 1; if (range1->linear != range2->linear) { pad_align = dev_data->phys_dev_properties.properties.limits.bufferImageGranularity; } if ((r1_end & ~(pad_align - 1)) < (r2_start & ~(pad_align - 1))) return false; if ((r1_start & ~(pad_align - 1)) > (r2_end & ~(pad_align - 1))) return false; if (range1->linear != range2->linear) { // In linear vs. non-linear case, it's an error to alias const char *r1_linear_str = range1->linear ? "Linear" : "Non-linear"; const char *r1_type_str = range1->image ? "image" : "buffer"; const char *r2_linear_str = range2->linear ? "linear" : "non-linear"; const char *r2_type_str = range2->image ? "image" : "buffer"; auto obj_type = range1->image ? VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT : VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT; *skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, obj_type, range1->handle, 0, MEMTRACK_INVALID_ALIASING, "MEM", "%s %s 0x%" PRIx64 " is aliased with %s %s 0x%" PRIx64 " which is in violation of the Buffer-Image Granularity section of the Vulkan specification.", r1_linear_str, r1_type_str, range1->handle, r2_linear_str, r2_type_str, range2->handle); } // Ranges intersect return true; } // Simplified rangesIntersect that calls above function to check range1 for intersection with offset & end addresses static bool rangesIntersect(layer_data const *dev_data, MEMORY_RANGE const *range1, VkDeviceSize offset, VkDeviceSize end) { // Create a local MEMORY_RANGE struct to wrap offset/size MEMORY_RANGE range_wrap; // Synch linear with range1 to avoid padding and potential validation error case range_wrap.linear = range1->linear; range_wrap.start = offset; range_wrap.end = end; bool tmp_bool; return rangesIntersect(dev_data, range1, &range_wrap, &tmp_bool); } // For given mem_info, set all ranges valid that intersect [offset-end] range // TODO : For ranges where there is no alias, we may want to create new buffer ranges that are valid static void SetMemRangesValid(layer_data const *dev_data, DEVICE_MEM_INFO *mem_info, VkDeviceSize offset, VkDeviceSize end) { bool tmp_bool = false; MEMORY_RANGE map_range; map_range.linear = true; map_range.start = offset; map_range.end = end; for (auto &handle_range_pair : mem_info->bound_ranges) { if (rangesIntersect(dev_data, &handle_range_pair.second, &map_range, &tmp_bool)) { // TODO : WARN here if tmp_bool true? handle_range_pair.second.valid = true; } } } // Object with given handle is being bound to memory w/ given mem_info struct. // Track the newly bound memory range with given memoryOffset // Also scan any previous ranges, track aliased ranges with new range, and flag an error if a linear // and non-linear range incorrectly overlap. // Return true if an error is flagged and the user callback returns "true", otherwise false // is_image indicates an image object, otherwise handle is for a buffer // is_linear indicates a buffer or linear image static bool InsertMemoryRange(layer_data const *dev_data, uint64_t handle, DEVICE_MEM_INFO *mem_info, VkDeviceSize memoryOffset, VkMemoryRequirements memRequirements, bool is_image, bool is_linear) { bool skip_call = false; MEMORY_RANGE range; range.image = is_image; range.handle = handle; range.linear = is_linear; range.valid = mem_info->global_valid; range.memory = mem_info->mem; range.start = memoryOffset; range.size = memRequirements.size; range.end = memoryOffset + memRequirements.size - 1; range.aliases.clear(); // Update Memory aliasing // Save aliase ranges so we can copy into final map entry below. Can't do it in loop b/c we don't yet have final ptr. If we // inserted into map before loop to get the final ptr, then we may enter loop when not needed & we check range against itself std::unordered_set tmp_alias_ranges; for (auto &obj_range_pair : mem_info->bound_ranges) { auto check_range = &obj_range_pair.second; bool intersection_error = false; if (rangesIntersect(dev_data, &range, check_range, &intersection_error)) { skip_call |= intersection_error; range.aliases.insert(check_range); tmp_alias_ranges.insert(check_range); } } mem_info->bound_ranges[handle] = std::move(range); for (auto tmp_range : tmp_alias_ranges) { tmp_range->aliases.insert(&mem_info->bound_ranges[handle]); } if (is_image) mem_info->bound_images.insert(handle); else mem_info->bound_buffers.insert(handle); return skip_call; } static bool InsertImageMemoryRange(layer_data const *dev_data, VkImage image, DEVICE_MEM_INFO *mem_info, VkDeviceSize mem_offset, VkMemoryRequirements mem_reqs, bool is_linear) { return InsertMemoryRange(dev_data, reinterpret_cast(image), mem_info, mem_offset, mem_reqs, true, is_linear); } static bool InsertBufferMemoryRange(layer_data const *dev_data, VkBuffer buffer, DEVICE_MEM_INFO *mem_info, VkDeviceSize mem_offset, VkMemoryRequirements mem_reqs) { return InsertMemoryRange(dev_data, reinterpret_cast(buffer), mem_info, mem_offset, mem_reqs, false, true); } // Remove MEMORY_RANGE struct for give handle from bound_ranges of mem_info // is_image indicates if handle is for image or buffer // This function will also remove the handle-to-index mapping from the appropriate // map and clean up any aliases for range being removed. static void RemoveMemoryRange(uint64_t handle, DEVICE_MEM_INFO *mem_info, bool is_image) { auto erase_range = &mem_info->bound_ranges[handle]; for (auto alias_range : erase_range->aliases) { alias_range->aliases.erase(erase_range); } erase_range->aliases.clear(); mem_info->bound_ranges.erase(handle); if (is_image) { mem_info->bound_images.erase(handle); } else { mem_info->bound_buffers.erase(handle); } } static void RemoveBufferMemoryRange(uint64_t handle, DEVICE_MEM_INFO *mem_info) { RemoveMemoryRange(handle, mem_info, false); } static void RemoveImageMemoryRange(uint64_t handle, DEVICE_MEM_INFO *mem_info) { RemoveMemoryRange(handle, mem_info, true); } VKAPI_ATTR void VKAPI_CALL DestroyBuffer(VkDevice device, VkBuffer buffer, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); std::unique_lock lock(global_lock); if (!validateIdleBuffer(dev_data, buffer)) { // Clean up memory binding and range information for buffer auto buffer_state = getBufferState(dev_data, buffer); if (buffer_state) { // Any bound cmd buffers are now invalid invalidateCommandBuffers(buffer_state->cb_bindings, {reinterpret_cast(buffer_state->buffer), VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT}); for (auto mem_binding : buffer_state->GetBoundMemory()) { auto mem_info = getMemObjInfo(dev_data, mem_binding); if (mem_info) { RemoveBufferMemoryRange(reinterpret_cast(buffer), mem_info); } } ClearMemoryObjectBindings(dev_data, reinterpret_cast(buffer), VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT); dev_data->bufferMap.erase(buffer_state->buffer); } lock.unlock(); dev_data->dispatch_table.DestroyBuffer(device, buffer, pAllocator); } } static bool PreCallValidateDestroyBufferView(layer_data *dev_data, VkBufferView buffer_view, BUFFER_VIEW_STATE **buffer_view_state, VK_OBJECT *obj_struct) { *buffer_view_state = getBufferViewState(dev_data, buffer_view); *obj_struct = {reinterpret_cast(buffer_view), VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_VIEW_EXT}; if (dev_data->instance_data->disabled.destroy_buffer_view) return false; bool skip = false; if (*buffer_view_state) { skip |= ValidateObjectNotInUse(dev_data, *buffer_view_state, *obj_struct, VALIDATION_ERROR_00701); } return skip; } static void PostCallRecordDestroyBufferView(layer_data *dev_data, VkBufferView buffer_view, BUFFER_VIEW_STATE *buffer_view_state, VK_OBJECT obj_struct) { // Any bound cmd buffers are now invalid invalidateCommandBuffers(buffer_view_state->cb_bindings, obj_struct); dev_data->bufferViewMap.erase(buffer_view); } VKAPI_ATTR void VKAPI_CALL DestroyBufferView(VkDevice device, VkBufferView bufferView, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); // Common data objects used pre & post call BUFFER_VIEW_STATE *buffer_view_state = nullptr; VK_OBJECT obj_struct; std::unique_lock lock(global_lock); // Validate state before calling down chain, update common data if we'll be calling down chain bool skip = PreCallValidateDestroyBufferView(dev_data, bufferView, &buffer_view_state, &obj_struct); if (!skip) { lock.unlock(); dev_data->dispatch_table.DestroyBufferView(device, bufferView, pAllocator); lock.lock(); PostCallRecordDestroyBufferView(dev_data, bufferView, buffer_view_state, obj_struct); } } static bool PreCallValidateDestroyImage(layer_data *dev_data, VkImage image, IMAGE_STATE **image_state, VK_OBJECT *obj_struct) { *image_state = getImageState(dev_data, image); *obj_struct = {reinterpret_cast(image), VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT}; if (dev_data->instance_data->disabled.destroy_image) return false; bool skip = false; if (*image_state) { skip |= ValidateObjectNotInUse(dev_data, *image_state, *obj_struct, VALIDATION_ERROR_00743); } return skip; } static void PostCallRecordDestroyImage(layer_data *dev_data, VkImage image, IMAGE_STATE *image_state, VK_OBJECT obj_struct) { invalidateCommandBuffers(image_state->cb_bindings, obj_struct); // Clean up memory mapping, bindings and range references for image for (auto mem_binding : image_state->GetBoundMemory()) { auto mem_info = getMemObjInfo(dev_data, mem_binding); if (mem_info) { RemoveImageMemoryRange(obj_struct.handle, mem_info); } } ClearMemoryObjectBindings(dev_data, obj_struct.handle, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT); // Remove image from imageMap dev_data->imageMap.erase(image); const auto &sub_entry = dev_data->imageSubresourceMap.find(image); if (sub_entry != dev_data->imageSubresourceMap.end()) { for (const auto &pair : sub_entry->second) { dev_data->imageLayoutMap.erase(pair); } dev_data->imageSubresourceMap.erase(sub_entry); } } VKAPI_ATTR void VKAPI_CALL DestroyImage(VkDevice device, VkImage image, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); IMAGE_STATE *image_state = nullptr; VK_OBJECT obj_struct; std::unique_lock lock(global_lock); bool skip = PreCallValidateDestroyImage(dev_data, image, &image_state, &obj_struct); if (!skip) { lock.unlock(); dev_data->dispatch_table.DestroyImage(device, image, pAllocator); lock.lock(); PostCallRecordDestroyImage(dev_data, image, image_state, obj_struct); } } static bool ValidateMemoryTypes(const layer_data *dev_data, const DEVICE_MEM_INFO *mem_info, const uint32_t memory_type_bits, const char *funcName) { bool skip_call = false; if (((1 << mem_info->alloc_info.memoryTypeIndex) & memory_type_bits) == 0) { skip_call = log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, reinterpret_cast(mem_info->mem), __LINE__, MEMTRACK_INVALID_MEM_TYPE, "MT", "%s(): MemoryRequirements->memoryTypeBits (0x%X) for this object type are not compatible with the memory " "type (0x%X) of this memory object 0x%" PRIx64 ".", funcName, memory_type_bits, mem_info->alloc_info.memoryTypeIndex, reinterpret_cast(mem_info->mem)); } return skip_call; } VKAPI_ATTR VkResult VKAPI_CALL BindBufferMemory(VkDevice device, VkBuffer buffer, VkDeviceMemory mem, VkDeviceSize memoryOffset) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = VK_ERROR_VALIDATION_FAILED_EXT; std::unique_lock lock(global_lock); // Track objects tied to memory uint64_t buffer_handle = reinterpret_cast(buffer); bool skip_call = SetMemBinding(dev_data, mem, buffer_handle, VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT, "vkBindBufferMemory"); auto buffer_state = getBufferState(dev_data, buffer); if (buffer_state) { if (!buffer_state->memory_requirements_checked) { // There's not an explicit requirement in the spec to call vkGetBufferMemoryRequirements() prior to calling // BindBufferMemory but it's implied in that memory being bound must conform with VkMemoryRequirements from // vkGetBufferMemoryRequirements() skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT, buffer_handle, __LINE__, DRAWSTATE_INVALID_BUFFER, "DS", "vkBindBufferMemory(): Binding memory to buffer 0x%" PRIxLEAST64 " but vkGetBufferMemoryRequirements() has not been called on that buffer.", buffer_handle); // Make the call for them so we can verify the state lock.unlock(); dev_data->dispatch_table.GetBufferMemoryRequirements(device, buffer, &buffer_state->requirements); lock.lock(); } buffer_state->binding.mem = mem; buffer_state->binding.offset = memoryOffset; buffer_state->binding.size = buffer_state->requirements.size; // Track and validate bound memory range information auto mem_info = getMemObjInfo(dev_data, mem); if (mem_info) { skip_call |= InsertBufferMemoryRange(dev_data, buffer, mem_info, memoryOffset, buffer_state->requirements); skip_call |= ValidateMemoryTypes(dev_data, mem_info, buffer_state->requirements.memoryTypeBits, "BindBufferMemory"); } // Validate memory requirements alignment if (vk_safe_modulo(memoryOffset, buffer_state->requirements.alignment) != 0) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PHYSICAL_DEVICE_EXT, 0, __LINE__, DRAWSTATE_INVALID_BUFFER_MEMORY_OFFSET, "DS", "vkBindBufferMemory(): memoryOffset is 0x%" PRIxLEAST64 " but must be an integer multiple of the " "VkMemoryRequirements::alignment value 0x%" PRIxLEAST64 ", returned from a call to vkGetBufferMemoryRequirements with buffer", memoryOffset, buffer_state->requirements.alignment); } // Validate device limits alignments static const VkBufferUsageFlagBits usage_list[3] = { static_cast(VK_BUFFER_USAGE_UNIFORM_TEXEL_BUFFER_BIT | VK_BUFFER_USAGE_STORAGE_TEXEL_BUFFER_BIT), VK_BUFFER_USAGE_UNIFORM_BUFFER_BIT, VK_BUFFER_USAGE_STORAGE_BUFFER_BIT}; static const char *memory_type[3] = {"texel", "uniform", "storage"}; static const char *offset_name[3] = { "minTexelBufferOffsetAlignment", "minUniformBufferOffsetAlignment", "minStorageBufferOffsetAlignment" }; // Keep this one fresh! const VkDeviceSize offset_requirement[3] = { dev_data->phys_dev_properties.properties.limits.minTexelBufferOffsetAlignment, dev_data->phys_dev_properties.properties.limits.minUniformBufferOffsetAlignment, dev_data->phys_dev_properties.properties.limits.minStorageBufferOffsetAlignment }; VkBufferUsageFlags usage = dev_data->bufferMap[buffer].get()->createInfo.usage; for (int i = 0; i < 3; i++) { if (usage & usage_list[i]) { if (vk_safe_modulo(memoryOffset, offset_requirement[i]) != 0) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PHYSICAL_DEVICE_EXT, 0, __LINE__, DRAWSTATE_INVALID_TEXEL_BUFFER_OFFSET, "DS", "vkBindBufferMemory(): %s memoryOffset is 0x%" PRIxLEAST64 " but must be a multiple of " "device limit %s 0x%" PRIxLEAST64, memory_type[i], memoryOffset, offset_name[i], offset_requirement[i]); } } } } print_mem_list(dev_data); lock.unlock(); if (!skip_call) { result = dev_data->dispatch_table.BindBufferMemory(device, buffer, mem, memoryOffset); } return result; } VKAPI_ATTR void VKAPI_CALL GetBufferMemoryRequirements(VkDevice device, VkBuffer buffer, VkMemoryRequirements *pMemoryRequirements) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); dev_data->dispatch_table.GetBufferMemoryRequirements(device, buffer, pMemoryRequirements); auto buffer_state = getBufferState(dev_data, buffer); if (buffer_state) { buffer_state->requirements = *pMemoryRequirements; buffer_state->memory_requirements_checked = true; } } VKAPI_ATTR void VKAPI_CALL GetImageMemoryRequirements(VkDevice device, VkImage image, VkMemoryRequirements *pMemoryRequirements) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); dev_data->dispatch_table.GetImageMemoryRequirements(device, image, pMemoryRequirements); auto image_state = getImageState(dev_data, image); if (image_state) { image_state->requirements = *pMemoryRequirements; image_state->memory_requirements_checked = true; } } static bool PreCallValidateDestroyImageView(layer_data *dev_data, VkImageView image_view, IMAGE_VIEW_STATE **image_view_state, VK_OBJECT *obj_struct) { *image_view_state = getImageViewState(dev_data, image_view); *obj_struct = {reinterpret_cast(image_view), VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_VIEW_EXT}; if (dev_data->instance_data->disabled.destroy_image_view) return false; bool skip = false; if (*image_view_state) { skip |= ValidateObjectNotInUse(dev_data, *image_view_state, *obj_struct, VALIDATION_ERROR_00776); } return skip; } static void PostCallRecordDestroyImageView(layer_data *dev_data, VkImageView image_view, IMAGE_VIEW_STATE *image_view_state, VK_OBJECT obj_struct) { // Any bound cmd buffers are now invalid invalidateCommandBuffers(image_view_state->cb_bindings, obj_struct); dev_data->imageViewMap.erase(image_view); } VKAPI_ATTR void VKAPI_CALL DestroyImageView(VkDevice device, VkImageView imageView, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); // Common data objects used pre & post call IMAGE_VIEW_STATE *image_view_state = nullptr; VK_OBJECT obj_struct; std::unique_lock lock(global_lock); bool skip = PreCallValidateDestroyImageView(dev_data, imageView, &image_view_state, &obj_struct); if (!skip) { lock.unlock(); dev_data->dispatch_table.DestroyImageView(device, imageView, pAllocator); lock.lock(); PostCallRecordDestroyImageView(dev_data, imageView, image_view_state, obj_struct); } } VKAPI_ATTR void VKAPI_CALL DestroyShaderModule(VkDevice device, VkShaderModule shaderModule, const VkAllocationCallbacks *pAllocator) { layer_data *my_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); std::unique_lock lock(global_lock); my_data->shaderModuleMap.erase(shaderModule); lock.unlock(); my_data->dispatch_table.DestroyShaderModule(device, shaderModule, pAllocator); } static bool PreCallValidateDestroyPipeline(layer_data *dev_data, VkPipeline pipeline, PIPELINE_STATE **pipeline_state, VK_OBJECT *obj_struct) { *pipeline_state = getPipelineState(dev_data, pipeline); *obj_struct = {reinterpret_cast(pipeline), VK_DEBUG_REPORT_OBJECT_TYPE_PIPELINE_EXT}; if (dev_data->instance_data->disabled.destroy_pipeline) return false; bool skip = false; if (*pipeline_state) { skip |= ValidateObjectNotInUse(dev_data, *pipeline_state, *obj_struct, VALIDATION_ERROR_00555); } return skip; } static void PostCallRecordDestroyPipeline(layer_data *dev_data, VkPipeline pipeline, PIPELINE_STATE *pipeline_state, VK_OBJECT obj_struct) { // Any bound cmd buffers are now invalid invalidateCommandBuffers(pipeline_state->cb_bindings, obj_struct); dev_data->pipelineMap.erase(pipeline); } VKAPI_ATTR void VKAPI_CALL DestroyPipeline(VkDevice device, VkPipeline pipeline, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); PIPELINE_STATE *pipeline_state = nullptr; VK_OBJECT obj_struct; std::unique_lock lock(global_lock); bool skip = PreCallValidateDestroyPipeline(dev_data, pipeline, &pipeline_state, &obj_struct); if (!skip) { lock.unlock(); dev_data->dispatch_table.DestroyPipeline(device, pipeline, pAllocator); lock.lock(); PostCallRecordDestroyPipeline(dev_data, pipeline, pipeline_state, obj_struct); } } VKAPI_ATTR void VKAPI_CALL DestroyPipelineLayout(VkDevice device, VkPipelineLayout pipelineLayout, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); std::unique_lock lock(global_lock); dev_data->pipelineLayoutMap.erase(pipelineLayout); lock.unlock(); dev_data->dispatch_table.DestroyPipelineLayout(device, pipelineLayout, pAllocator); } static bool PreCallValidateDestroySampler(layer_data *dev_data, VkSampler sampler, SAMPLER_STATE **sampler_state, VK_OBJECT *obj_struct) { *sampler_state = getSamplerState(dev_data, sampler); *obj_struct = {reinterpret_cast(sampler), VK_DEBUG_REPORT_OBJECT_TYPE_SAMPLER_EXT}; if (dev_data->instance_data->disabled.destroy_sampler) return false; bool skip = false; if (*sampler_state) { skip |= ValidateObjectNotInUse(dev_data, *sampler_state, *obj_struct, VALIDATION_ERROR_00837); } return skip; } static void PostCallRecordDestroySampler(layer_data *dev_data, VkSampler sampler, SAMPLER_STATE *sampler_state, VK_OBJECT obj_struct) { // Any bound cmd buffers are now invalid if (sampler_state) invalidateCommandBuffers(sampler_state->cb_bindings, obj_struct); dev_data->samplerMap.erase(sampler); } VKAPI_ATTR void VKAPI_CALL DestroySampler(VkDevice device, VkSampler sampler, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); SAMPLER_STATE *sampler_state = nullptr; VK_OBJECT obj_struct; std::unique_lock lock(global_lock); bool skip = PreCallValidateDestroySampler(dev_data, sampler, &sampler_state, &obj_struct); if (!skip) { lock.unlock(); dev_data->dispatch_table.DestroySampler(device, sampler, pAllocator); lock.lock(); PostCallRecordDestroySampler(dev_data, sampler, sampler_state, obj_struct); } } VKAPI_ATTR void VKAPI_CALL DestroyDescriptorSetLayout(VkDevice device, VkDescriptorSetLayout descriptorSetLayout, const VkAllocationCallbacks *pAllocator) { // TODO : Clean up any internal data structures using this obj. get_my_data_ptr(get_dispatch_key(device), layer_data_map) ->dispatch_table.DestroyDescriptorSetLayout(device, descriptorSetLayout, pAllocator); } static bool PreCallValidateDestroyDescriptorPool(layer_data *dev_data, VkDescriptorPool pool, DESCRIPTOR_POOL_STATE **desc_pool_state, VK_OBJECT *obj_struct) { *desc_pool_state = getDescriptorPoolState(dev_data, pool); *obj_struct = {reinterpret_cast(pool), VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_POOL_EXT}; if (dev_data->instance_data->disabled.destroy_descriptor_pool) return false; bool skip = false; if (*desc_pool_state) { skip |= ValidateObjectNotInUse(dev_data, *desc_pool_state, *obj_struct, VALIDATION_ERROR_00901); } return skip; } static void PostCallRecordDestroyDescriptorPool(layer_data *dev_data, VkDescriptorPool descriptorPool, DESCRIPTOR_POOL_STATE *desc_pool_state, VK_OBJECT obj_struct) { // Any bound cmd buffers are now invalid invalidateCommandBuffers(desc_pool_state->cb_bindings, obj_struct); // Free sets that were in this pool for (auto ds : desc_pool_state->sets) { freeDescriptorSet(dev_data, ds); } dev_data->descriptorPoolMap.erase(descriptorPool); } VKAPI_ATTR void VKAPI_CALL DestroyDescriptorPool(VkDevice device, VkDescriptorPool descriptorPool, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); DESCRIPTOR_POOL_STATE *desc_pool_state = nullptr; VK_OBJECT obj_struct; std::unique_lock lock(global_lock); bool skip = PreCallValidateDestroyDescriptorPool(dev_data, descriptorPool, &desc_pool_state, &obj_struct); if (!skip) { lock.unlock(); dev_data->dispatch_table.DestroyDescriptorPool(device, descriptorPool, pAllocator); lock.lock(); PostCallRecordDestroyDescriptorPool(dev_data, descriptorPool, desc_pool_state, obj_struct); } } // Verify cmdBuffer in given cb_node is not in global in-flight set, and return skip_call result // If this is a secondary command buffer, then make sure its primary is also in-flight // If primary is not in-flight, then remove secondary from global in-flight set // This function is only valid at a point when cmdBuffer is being reset or freed static bool checkCommandBufferInFlight(layer_data *dev_data, const GLOBAL_CB_NODE *cb_node, const char *action, UNIQUE_VALIDATION_ERROR_CODE error_code) { bool skip_call = false; if (dev_data->globalInFlightCmdBuffers.count(cb_node->commandBuffer)) { // Primary CB or secondary where primary is also in-flight is an error if ((cb_node->createInfo.level != VK_COMMAND_BUFFER_LEVEL_SECONDARY) || (dev_data->globalInFlightCmdBuffers.count(cb_node->primaryCommandBuffer))) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(cb_node->commandBuffer), __LINE__, error_code, "DS", "Attempt to %s command buffer (0x%" PRIxLEAST64 ") which is in use. %s", action, reinterpret_cast(cb_node->commandBuffer), validation_error_map[error_code]); } } return skip_call; } // Iterate over all cmdBuffers in given commandPool and verify that each is not in use static bool checkCommandBuffersInFlight(layer_data *dev_data, COMMAND_POOL_NODE *pPool, const char *action, UNIQUE_VALIDATION_ERROR_CODE error_code) { bool skip_call = false; for (auto cmd_buffer : pPool->commandBuffers) { if (dev_data->globalInFlightCmdBuffers.count(cmd_buffer)) { skip_call |= checkCommandBufferInFlight(dev_data, getCBNode(dev_data, cmd_buffer), action, error_code); } } return skip_call; } static void clearCommandBuffersInFlight(layer_data *dev_data, COMMAND_POOL_NODE *pPool) { for (auto cmd_buffer : pPool->commandBuffers) { dev_data->globalInFlightCmdBuffers.erase(cmd_buffer); } } VKAPI_ATTR void VKAPI_CALL FreeCommandBuffers(VkDevice device, VkCommandPool commandPool, uint32_t commandBufferCount, const VkCommandBuffer *pCommandBuffers) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); bool skip_call = false; std::unique_lock lock(global_lock); for (uint32_t i = 0; i < commandBufferCount; i++) { auto cb_node = getCBNode(dev_data, pCommandBuffers[i]); // Delete CB information structure, and remove from commandBufferMap if (cb_node) { skip_call |= checkCommandBufferInFlight(dev_data, cb_node, "free", VALIDATION_ERROR_00096); } } if (skip_call) return; auto pPool = getCommandPoolNode(dev_data, commandPool); for (uint32_t i = 0; i < commandBufferCount; i++) { auto cb_node = getCBNode(dev_data, pCommandBuffers[i]); // Delete CB information structure, and remove from commandBufferMap if (cb_node) { dev_data->globalInFlightCmdBuffers.erase(cb_node->commandBuffer); // reset prior to delete for data clean-up resetCB(dev_data, cb_node->commandBuffer); dev_data->commandBufferMap.erase(cb_node->commandBuffer); delete cb_node; } // Remove commandBuffer reference from commandPoolMap pPool->commandBuffers.remove(pCommandBuffers[i]); } printCBList(dev_data); lock.unlock(); dev_data->dispatch_table.FreeCommandBuffers(device, commandPool, commandBufferCount, pCommandBuffers); } VKAPI_ATTR VkResult VKAPI_CALL CreateCommandPool(VkDevice device, const VkCommandPoolCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkCommandPool *pCommandPool) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = dev_data->dispatch_table.CreateCommandPool(device, pCreateInfo, pAllocator, pCommandPool); if (VK_SUCCESS == result) { std::lock_guard lock(global_lock); dev_data->commandPoolMap[*pCommandPool].createFlags = pCreateInfo->flags; dev_data->commandPoolMap[*pCommandPool].queueFamilyIndex = pCreateInfo->queueFamilyIndex; } return result; } VKAPI_ATTR VkResult VKAPI_CALL CreateQueryPool(VkDevice device, const VkQueryPoolCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkQueryPool *pQueryPool) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = dev_data->dispatch_table.CreateQueryPool(device, pCreateInfo, pAllocator, pQueryPool); if (result == VK_SUCCESS) { std::lock_guard lock(global_lock); QUERY_POOL_NODE *qp_node = &dev_data->queryPoolMap[*pQueryPool]; qp_node->createInfo = *pCreateInfo; } return result; } static bool PreCallValidateDestroyCommandPool(layer_data *dev_data, VkCommandPool pool, COMMAND_POOL_NODE **cp_state) { *cp_state = getCommandPoolNode(dev_data, pool); if (dev_data->instance_data->disabled.destroy_command_pool) return false; bool skip = false; if (*cp_state) { // Verify that command buffers in pool are complete (not in-flight) skip |= checkCommandBuffersInFlight(dev_data, *cp_state, "destroy command pool with", VALIDATION_ERROR_00077); } return skip; } static void PostCallRecordDestroyCommandPool(layer_data *dev_data, VkCommandPool pool, COMMAND_POOL_NODE *cp_state) { // Must remove cmdpool from cmdpoolmap, after removing all cmdbuffers in its list from the commandBufferMap clearCommandBuffersInFlight(dev_data, cp_state); for (auto cb : cp_state->commandBuffers) { clear_cmd_buf_and_mem_references(dev_data, cb); auto cb_node = getCBNode(dev_data, cb); // Remove references to this cb_node prior to delete // TODO : Need better solution here, resetCB? for (auto obj : cb_node->object_bindings) { removeCommandBufferBinding(dev_data, &obj, cb_node); } for (auto framebuffer : cb_node->framebuffers) { auto fb_state = getFramebufferState(dev_data, framebuffer); if (fb_state) fb_state->cb_bindings.erase(cb_node); } dev_data->commandBufferMap.erase(cb); // Remove this command buffer delete cb_node; // delete CB info structure } dev_data->commandPoolMap.erase(pool); } // Destroy commandPool along with all of the commandBuffers allocated from that pool VKAPI_ATTR void VKAPI_CALL DestroyCommandPool(VkDevice device, VkCommandPool commandPool, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); COMMAND_POOL_NODE *cp_state = nullptr; std::unique_lock lock(global_lock); bool skip = PreCallValidateDestroyCommandPool(dev_data, commandPool, &cp_state); if (!skip) { lock.unlock(); dev_data->dispatch_table.DestroyCommandPool(device, commandPool, pAllocator); lock.lock(); PostCallRecordDestroyCommandPool(dev_data, commandPool, cp_state); } } VKAPI_ATTR VkResult VKAPI_CALL ResetCommandPool(VkDevice device, VkCommandPool commandPool, VkCommandPoolResetFlags flags) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); bool skip_call = false; std::unique_lock lock(global_lock); auto pPool = getCommandPoolNode(dev_data, commandPool); skip_call |= checkCommandBuffersInFlight(dev_data, pPool, "reset command pool with", VALIDATION_ERROR_00072); lock.unlock(); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult result = dev_data->dispatch_table.ResetCommandPool(device, commandPool, flags); // Reset all of the CBs allocated from this pool if (VK_SUCCESS == result) { lock.lock(); clearCommandBuffersInFlight(dev_data, pPool); for (auto cmdBuffer : pPool->commandBuffers) { resetCB(dev_data, cmdBuffer); } lock.unlock(); } return result; } VKAPI_ATTR VkResult VKAPI_CALL ResetFences(VkDevice device, uint32_t fenceCount, const VkFence *pFences) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); bool skip_call = false; std::unique_lock lock(global_lock); for (uint32_t i = 0; i < fenceCount; ++i) { auto pFence = getFenceNode(dev_data, pFences[i]); if (pFence && pFence->state == FENCE_INFLIGHT) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_FENCE_EXT, reinterpret_cast(pFences[i]), __LINE__, DRAWSTATE_INVALID_FENCE, "DS", "Fence 0x%" PRIx64 " is in use.", reinterpret_cast(pFences[i])); } } lock.unlock(); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult result = dev_data->dispatch_table.ResetFences(device, fenceCount, pFences); if (result == VK_SUCCESS) { lock.lock(); for (uint32_t i = 0; i < fenceCount; ++i) { auto pFence = getFenceNode(dev_data, pFences[i]); if (pFence) { pFence->state = FENCE_UNSIGNALED; } } lock.unlock(); } return result; } // For given cb_nodes, invalidate them and track object causing invalidation void invalidateCommandBuffers(std::unordered_set cb_nodes, VK_OBJECT obj) { for (auto cb_node : cb_nodes) { cb_node->state = CB_INVALID; cb_node->broken_bindings.push_back(obj); } } static bool PreCallValidateDestroyFramebuffer(layer_data *dev_data, VkFramebuffer framebuffer, FRAMEBUFFER_STATE **framebuffer_state, VK_OBJECT *obj_struct) { *framebuffer_state = getFramebufferState(dev_data, framebuffer); *obj_struct = {reinterpret_cast(framebuffer), VK_DEBUG_REPORT_OBJECT_TYPE_FRAMEBUFFER_EXT}; if (dev_data->instance_data->disabled.destroy_framebuffer) return false; bool skip = false; if (*framebuffer_state) { skip |= ValidateObjectNotInUse(dev_data, *framebuffer_state, *obj_struct, VALIDATION_ERROR_00422); } return skip; } static void PostCallRecordDestroyFramebuffer(layer_data *dev_data, VkFramebuffer framebuffer, FRAMEBUFFER_STATE *framebuffer_state, VK_OBJECT obj_struct) { invalidateCommandBuffers(framebuffer_state->cb_bindings, obj_struct); dev_data->frameBufferMap.erase(framebuffer); } VKAPI_ATTR void VKAPI_CALL DestroyFramebuffer(VkDevice device, VkFramebuffer framebuffer, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); FRAMEBUFFER_STATE *framebuffer_state = nullptr; VK_OBJECT obj_struct; std::unique_lock lock(global_lock); bool skip = PreCallValidateDestroyFramebuffer(dev_data, framebuffer, &framebuffer_state, &obj_struct); if (!skip) { lock.unlock(); dev_data->dispatch_table.DestroyFramebuffer(device, framebuffer, pAllocator); lock.lock(); PostCallRecordDestroyFramebuffer(dev_data, framebuffer, framebuffer_state, obj_struct); } } static bool PreCallValidateDestroyRenderPass(layer_data *dev_data, VkRenderPass render_pass, RENDER_PASS_STATE **rp_state, VK_OBJECT *obj_struct) { *rp_state = getRenderPassState(dev_data, render_pass); *obj_struct = {reinterpret_cast(render_pass), VK_DEBUG_REPORT_OBJECT_TYPE_RENDER_PASS_EXT}; if (dev_data->instance_data->disabled.destroy_renderpass) return false; bool skip = false; if (*rp_state) { skip |= ValidateObjectNotInUse(dev_data, *rp_state, *obj_struct, VALIDATION_ERROR_00393); } return skip; } static void PostCallRecordDestroyRenderPass(layer_data *dev_data, VkRenderPass render_pass, RENDER_PASS_STATE *rp_state, VK_OBJECT obj_struct) { invalidateCommandBuffers(rp_state->cb_bindings, obj_struct); dev_data->renderPassMap.erase(render_pass); } VKAPI_ATTR void VKAPI_CALL DestroyRenderPass(VkDevice device, VkRenderPass renderPass, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); RENDER_PASS_STATE *rp_state = nullptr; VK_OBJECT obj_struct; std::unique_lock lock(global_lock); bool skip = PreCallValidateDestroyRenderPass(dev_data, renderPass, &rp_state, &obj_struct); if (!skip) { lock.unlock(); dev_data->dispatch_table.DestroyRenderPass(device, renderPass, pAllocator); lock.lock(); PostCallRecordDestroyRenderPass(dev_data, renderPass, rp_state, obj_struct); } } VKAPI_ATTR VkResult VKAPI_CALL CreateBuffer(VkDevice device, const VkBufferCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkBuffer *pBuffer) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); // TODO: Add check for VALIDATION_ERROR_00658 // TODO: Add check for VALIDATION_ERROR_00666 // TODO: Add check for VALIDATION_ERROR_00667 // TODO: Add check for VALIDATION_ERROR_00668 // TODO: Add check for VALIDATION_ERROR_00669 VkResult result = dev_data->dispatch_table.CreateBuffer(device, pCreateInfo, pAllocator, pBuffer); if (VK_SUCCESS == result) { std::lock_guard lock(global_lock); // TODO : This doesn't create deep copy of pQueueFamilyIndices so need to fix that if/when we want that data to be valid dev_data->bufferMap.insert(std::make_pair(*pBuffer, unique_ptr(new BUFFER_STATE(*pBuffer, pCreateInfo)))); } return result; } static bool PreCallValidateCreateBufferView(layer_data *dev_data, const VkBufferViewCreateInfo *pCreateInfo) { bool skip_call = false; BUFFER_STATE *buffer_state = getBufferState(dev_data, pCreateInfo->buffer); // If this isn't a sparse buffer, it needs to have memory backing it at CreateBufferView time if (buffer_state) { skip_call |= ValidateMemoryIsBoundToBuffer(dev_data, buffer_state, "vkCreateBufferView()"); // In order to create a valid buffer view, the buffer must have been created with at least one of the // following flags: UNIFORM_TEXEL_BUFFER_BIT or STORAGE_TEXEL_BUFFER_BIT skip_call |= ValidateBufferUsageFlags( dev_data, buffer_state, VK_BUFFER_USAGE_UNIFORM_TEXEL_BUFFER_BIT | VK_BUFFER_USAGE_STORAGE_TEXEL_BUFFER_BIT, false, VALIDATION_ERROR_00694, "vkCreateBufferView()", "VK_BUFFER_USAGE_[STORAGE|UNIFORM]_TEXEL_BUFFER_BIT"); } return skip_call; } VKAPI_ATTR VkResult VKAPI_CALL CreateBufferView(VkDevice device, const VkBufferViewCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkBufferView *pView) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); std::unique_lock lock(global_lock); bool skip_call = PreCallValidateCreateBufferView(dev_data, pCreateInfo); lock.unlock(); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult result = dev_data->dispatch_table.CreateBufferView(device, pCreateInfo, pAllocator, pView); if (VK_SUCCESS == result) { lock.lock(); dev_data->bufferViewMap[*pView] = unique_ptr(new BUFFER_VIEW_STATE(*pView, pCreateInfo)); lock.unlock(); } return result; } VKAPI_ATTR VkResult VKAPI_CALL CreateImage(VkDevice device, const VkImageCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkImage *pImage) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = dev_data->dispatch_table.CreateImage(device, pCreateInfo, pAllocator, pImage); if (VK_SUCCESS == result) { std::lock_guard lock(global_lock); IMAGE_LAYOUT_NODE image_state; image_state.layout = pCreateInfo->initialLayout; image_state.format = pCreateInfo->format; dev_data->imageMap.insert(std::make_pair(*pImage, unique_ptr(new IMAGE_STATE(*pImage, pCreateInfo)))); ImageSubresourcePair subpair = {*pImage, false, VkImageSubresource()}; dev_data->imageSubresourceMap[*pImage].push_back(subpair); dev_data->imageLayoutMap[subpair] = image_state; } return result; } static void ResolveRemainingLevelsLayers(layer_data *dev_data, VkImageSubresourceRange *range, VkImage image) { /* expects global_lock to be held by caller */ auto image_state = getImageState(dev_data, image); if (image_state) { /* If the caller used the special values VK_REMAINING_MIP_LEVELS and * VK_REMAINING_ARRAY_LAYERS, resolve them now in our internal state to * the actual values. */ if (range->levelCount == VK_REMAINING_MIP_LEVELS) { range->levelCount = image_state->createInfo.mipLevels - range->baseMipLevel; } if (range->layerCount == VK_REMAINING_ARRAY_LAYERS) { range->layerCount = image_state->createInfo.arrayLayers - range->baseArrayLayer; } } } // Return the correct layer/level counts if the caller used the special // values VK_REMAINING_MIP_LEVELS or VK_REMAINING_ARRAY_LAYERS. static void ResolveRemainingLevelsLayers(layer_data *dev_data, uint32_t *levels, uint32_t *layers, VkImageSubresourceRange range, VkImage image) { /* expects global_lock to be held by caller */ *levels = range.levelCount; *layers = range.layerCount; auto image_state = getImageState(dev_data, image); if (image_state) { if (range.levelCount == VK_REMAINING_MIP_LEVELS) { *levels = image_state->createInfo.mipLevels - range.baseMipLevel; } if (range.layerCount == VK_REMAINING_ARRAY_LAYERS) { *layers = image_state->createInfo.arrayLayers - range.baseArrayLayer; } } } // For the given format verify that the aspect masks make sense static bool ValidateImageAspectMask(layer_data *dev_data, VkImage image, VkFormat format, VkImageAspectFlags aspect_mask, const char *func_name) { bool skip = false; if (vk_format_is_color(format)) { if ((aspect_mask & VK_IMAGE_ASPECT_COLOR_BIT) != VK_IMAGE_ASPECT_COLOR_BIT) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, (uint64_t)image, __LINE__, VALIDATION_ERROR_00741, "IMAGE", "%s: Color image formats must have the VK_IMAGE_ASPECT_COLOR_BIT set. %s", func_name, validation_error_map[VALIDATION_ERROR_00741]); } if ((aspect_mask & VK_IMAGE_ASPECT_COLOR_BIT) != aspect_mask) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, (uint64_t)image, __LINE__, VALIDATION_ERROR_00741, "IMAGE", "%s: Color image formats must have ONLY the VK_IMAGE_ASPECT_COLOR_BIT set. %s", func_name, validation_error_map[VALIDATION_ERROR_00741]); } } else if (vk_format_is_depth_and_stencil(format)) { if ((aspect_mask & (VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT)) == 0) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, (uint64_t)image, __LINE__, VALIDATION_ERROR_00741, "IMAGE", "%s: Depth/stencil image formats must have " "at least one of VK_IMAGE_ASPECT_DEPTH_BIT " "and VK_IMAGE_ASPECT_STENCIL_BIT set. %s", func_name, validation_error_map[VALIDATION_ERROR_00741]); } if ((aspect_mask & (VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT)) != aspect_mask) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, (uint64_t)image, __LINE__, VALIDATION_ERROR_00741, "IMAGE", "%s: Combination depth/stencil image formats can have only the VK_IMAGE_ASPECT_DEPTH_BIT and " "VK_IMAGE_ASPECT_STENCIL_BIT set. %s", func_name, validation_error_map[VALIDATION_ERROR_00741]); } } else if (vk_format_is_depth_only(format)) { if ((aspect_mask & VK_IMAGE_ASPECT_DEPTH_BIT) != VK_IMAGE_ASPECT_DEPTH_BIT) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, (uint64_t)image, __LINE__, VALIDATION_ERROR_00741, "IMAGE", "%s: Depth-only image formats must have the VK_IMAGE_ASPECT_DEPTH_BIT set. %s", func_name, validation_error_map[VALIDATION_ERROR_00741]); } if ((aspect_mask & VK_IMAGE_ASPECT_DEPTH_BIT) != aspect_mask) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, (uint64_t)image, __LINE__, VALIDATION_ERROR_00741, "IMAGE", "%s: Depth-only image formats can have only the VK_IMAGE_ASPECT_DEPTH_BIT set. %s", func_name, validation_error_map[VALIDATION_ERROR_00741]); } } else if (vk_format_is_stencil_only(format)) { if ((aspect_mask & VK_IMAGE_ASPECT_STENCIL_BIT) != VK_IMAGE_ASPECT_STENCIL_BIT) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, (uint64_t)image, __LINE__, VALIDATION_ERROR_00741, "IMAGE", "%s: Stencil-only image formats must have the VK_IMAGE_ASPECT_STENCIL_BIT set. %s", func_name, validation_error_map[VALIDATION_ERROR_00741]); } if ((aspect_mask & VK_IMAGE_ASPECT_STENCIL_BIT) != aspect_mask) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, (uint64_t)image, __LINE__, VALIDATION_ERROR_00741, "IMAGE", "%s: Stencil-only image formats can have only the VK_IMAGE_ASPECT_STENCIL_BIT set. %s", func_name, validation_error_map[VALIDATION_ERROR_00741]); } } return skip; } static bool PreCallValidateCreateImageView(layer_data *dev_data, const VkImageViewCreateInfo *create_info) { bool skip = false; IMAGE_STATE *image_state = getImageState(dev_data, create_info->image); if (image_state) { skip |= ValidateImageUsageFlags( dev_data, image_state, VK_IMAGE_USAGE_SAMPLED_BIT | VK_IMAGE_USAGE_STORAGE_BIT | VK_IMAGE_USAGE_INPUT_ATTACHMENT_BIT | VK_IMAGE_USAGE_DEPTH_STENCIL_ATTACHMENT_BIT | VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT, false, -1, "vkCreateImageView()", "VK_IMAGE_USAGE_[SAMPLED|STORAGE|COLOR_ATTACHMENT|DEPTH_STENCIL_ATTACHMENT|INPUT_ATTACHMENT]_BIT"); // If this isn't a sparse image, it needs to have memory backing it at CreateImageView time skip |= ValidateMemoryIsBoundToImage(dev_data, image_state, "vkCreateImageView()"); // Checks imported from image layer if (create_info->subresourceRange.baseMipLevel >= image_state->createInfo.mipLevels) { std::stringstream ss; ss << "vkCreateImageView called with baseMipLevel " << create_info->subresourceRange.baseMipLevel << " for image " << create_info->image << " that only has " << image_state->createInfo.mipLevels << " mip levels."; skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, VALIDATION_ERROR_00768, "IMAGE", "%s %s", ss.str().c_str(), validation_error_map[VALIDATION_ERROR_00768]); } if (create_info->subresourceRange.baseArrayLayer >= image_state->createInfo.arrayLayers) { std::stringstream ss; ss << "vkCreateImageView called with baseArrayLayer " << create_info->subresourceRange.baseArrayLayer << " for image " << create_info->image << " that only has " << image_state->createInfo.arrayLayers << " array layers."; skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, VALIDATION_ERROR_00769, "IMAGE", "%s %s", ss.str().c_str(), validation_error_map[VALIDATION_ERROR_00769]); } // TODO: Need new valid usage language for levelCount == 0 & layerCount == 0 if (!create_info->subresourceRange.levelCount) { std::stringstream ss; ss << "vkCreateImageView called with 0 in pCreateInfo->subresourceRange.levelCount."; skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, VALIDATION_ERROR_00768, "IMAGE", "%s %s", ss.str().c_str(), validation_error_map[VALIDATION_ERROR_00768]); } if (!create_info->subresourceRange.layerCount) { std::stringstream ss; ss << "vkCreateImageView called with 0 in pCreateInfo->subresourceRange.layerCount."; skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, VALIDATION_ERROR_00769, "IMAGE", "%s %s", ss.str().c_str(), validation_error_map[VALIDATION_ERROR_00769]); } VkImageCreateFlags image_flags = image_state->createInfo.flags; VkFormat image_format = image_state->createInfo.format; VkFormat view_format = create_info->format; VkImageAspectFlags aspect_mask = create_info->subresourceRange.aspectMask; // Validate VK_IMAGE_CREATE_MUTABLE_FORMAT_BIT state if (image_flags & VK_IMAGE_CREATE_MUTABLE_FORMAT_BIT) { // Format MUST be compatible (in the same format compatibility class) as the format the image was created with if (vk_format_get_compatibility_class(image_format) != vk_format_get_compatibility_class(view_format)) { std::stringstream ss; ss << "vkCreateImageView(): ImageView format " << string_VkFormat(view_format) << " is not in the same format compatibility class as image (" << (uint64_t)create_info->image << ") format " << string_VkFormat(image_format) << ". Images created with the VK_IMAGE_CREATE_MUTABLE_FORMAT BIT " << "can support ImageViews with differing formats but they must be in the same compatibility class."; skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, VALIDATION_ERROR_02171, "IMAGE", "%s %s", ss.str().c_str(), validation_error_map[VALIDATION_ERROR_02171]); } } else { // Format MUST be IDENTICAL to the format the image was created with if (image_format != view_format) { std::stringstream ss; ss << "vkCreateImageView() format " << string_VkFormat(view_format) << " differs from image " << (uint64_t)create_info->image << " format " << string_VkFormat(image_format) << ". Formats MUST be IDENTICAL unless VK_IMAGE_CREATE_MUTABLE_FORMAT BIT was set on image creation."; skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, VALIDATION_ERROR_02172, "IMAGE", "%s %s", ss.str().c_str(), validation_error_map[VALIDATION_ERROR_02172]); } } // Validate correct image aspect bits for desired formats and format consistency skip |= ValidateImageAspectMask(dev_data, image_state->image, image_format, aspect_mask, "vkCreateImageView()"); if (vk_format_is_color(image_format) && !vk_format_is_color(view_format)) { std::stringstream ss; ss << "vkCreateImageView: The image view's format can differ from the parent image's format, but both must be " << "color formats. ImageFormat is " << string_VkFormat(image_format) << " ImageViewFormat is " << string_VkFormat(view_format); skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, (uint64_t)create_info->image, __LINE__, VALIDATION_ERROR_02171, "IMAGE", "%s %s", ss.str().c_str(), validation_error_map[VALIDATION_ERROR_02171]); // TODO: Uncompressed formats are compatible if they occupy they same number of bits per pixel. // Compressed formats are compatible if the only difference between them is the numerical type of // the uncompressed pixels (e.g. signed vs. unsigned, or sRGB vs. UNORM encoding). } } return skip; } static inline void PostCallRecordCreateImageView(layer_data *dev_data, const VkImageViewCreateInfo *create_info, VkImageView view) { dev_data->imageViewMap[view] = unique_ptr(new IMAGE_VIEW_STATE(view, create_info)); ResolveRemainingLevelsLayers(dev_data, &dev_data->imageViewMap[view].get()->create_info.subresourceRange, create_info->image); } VKAPI_ATTR VkResult VKAPI_CALL CreateImageView(VkDevice device, const VkImageViewCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkImageView *pView) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); std::unique_lock lock(global_lock); bool skip = PreCallValidateCreateImageView(dev_data, pCreateInfo); lock.unlock(); if (skip) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult result = dev_data->dispatch_table.CreateImageView(device, pCreateInfo, pAllocator, pView); if (VK_SUCCESS == result) { lock.lock(); PostCallRecordCreateImageView(dev_data, pCreateInfo, *pView); lock.unlock(); } return result; } VKAPI_ATTR VkResult VKAPI_CALL CreateFence(VkDevice device, const VkFenceCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkFence *pFence) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = dev_data->dispatch_table.CreateFence(device, pCreateInfo, pAllocator, pFence); if (VK_SUCCESS == result) { std::lock_guard lock(global_lock); auto &fence_node = dev_data->fenceMap[*pFence]; fence_node.fence = *pFence; fence_node.createInfo = *pCreateInfo; fence_node.state = (pCreateInfo->flags & VK_FENCE_CREATE_SIGNALED_BIT) ? FENCE_RETIRED : FENCE_UNSIGNALED; } return result; } // TODO handle pipeline caches VKAPI_ATTR VkResult VKAPI_CALL CreatePipelineCache(VkDevice device, const VkPipelineCacheCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkPipelineCache *pPipelineCache) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = dev_data->dispatch_table.CreatePipelineCache(device, pCreateInfo, pAllocator, pPipelineCache); return result; } VKAPI_ATTR void VKAPI_CALL DestroyPipelineCache(VkDevice device, VkPipelineCache pipelineCache, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); dev_data->dispatch_table.DestroyPipelineCache(device, pipelineCache, pAllocator); } VKAPI_ATTR VkResult VKAPI_CALL GetPipelineCacheData(VkDevice device, VkPipelineCache pipelineCache, size_t *pDataSize, void *pData) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = dev_data->dispatch_table.GetPipelineCacheData(device, pipelineCache, pDataSize, pData); return result; } VKAPI_ATTR VkResult VKAPI_CALL MergePipelineCaches(VkDevice device, VkPipelineCache dstCache, uint32_t srcCacheCount, const VkPipelineCache *pSrcCaches) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = dev_data->dispatch_table.MergePipelineCaches(device, dstCache, srcCacheCount, pSrcCaches); return result; } // utility function to set collective state for pipeline void set_pipeline_state(PIPELINE_STATE *pPipe) { // If any attachment used by this pipeline has blendEnable, set top-level blendEnable if (pPipe->graphicsPipelineCI.pColorBlendState) { for (size_t i = 0; i < pPipe->attachments.size(); ++i) { if (VK_TRUE == pPipe->attachments[i].blendEnable) { if (((pPipe->attachments[i].dstAlphaBlendFactor >= VK_BLEND_FACTOR_CONSTANT_COLOR) && (pPipe->attachments[i].dstAlphaBlendFactor <= VK_BLEND_FACTOR_ONE_MINUS_CONSTANT_ALPHA)) || ((pPipe->attachments[i].dstColorBlendFactor >= VK_BLEND_FACTOR_CONSTANT_COLOR) && (pPipe->attachments[i].dstColorBlendFactor <= VK_BLEND_FACTOR_ONE_MINUS_CONSTANT_ALPHA)) || ((pPipe->attachments[i].srcAlphaBlendFactor >= VK_BLEND_FACTOR_CONSTANT_COLOR) && (pPipe->attachments[i].srcAlphaBlendFactor <= VK_BLEND_FACTOR_ONE_MINUS_CONSTANT_ALPHA)) || ((pPipe->attachments[i].srcColorBlendFactor >= VK_BLEND_FACTOR_CONSTANT_COLOR) && (pPipe->attachments[i].srcColorBlendFactor <= VK_BLEND_FACTOR_ONE_MINUS_CONSTANT_ALPHA))) { pPipe->blendConstantsEnabled = true; } } } } } static bool PreCallCreateGraphicsPipelines(layer_data *device_data, uint32_t count, const VkGraphicsPipelineCreateInfo *create_infos, vector &pipe_state) { bool skip = false; instance_layer_data *instance_data = get_my_data_ptr(get_dispatch_key(device_data->instance_data->instance), instance_layer_data_map); for (uint32_t i = 0; i < count; i++) { skip |= verifyPipelineCreateState(device_data, pipe_state, i); if (create_infos[i].pVertexInputState != NULL) { for (uint32_t j = 0; j < create_infos[i].pVertexInputState->vertexAttributeDescriptionCount; j++) { VkFormat format = create_infos[i].pVertexInputState->pVertexAttributeDescriptions[j].format; // Internal call to get format info. Still goes through layers, could potentially go directly to ICD. VkFormatProperties properties; instance_data->dispatch_table.GetPhysicalDeviceFormatProperties(device_data->physical_device, format, &properties); if ((properties.bufferFeatures & VK_FORMAT_FEATURE_VERTEX_BUFFER_BIT) == 0) { skip |= log_msg( device_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_UNKNOWN_EXT, 0, __LINE__, VALIDATION_ERROR_01413, "IMAGE", "vkCreateGraphicsPipelines: pCreateInfo[%d].pVertexInputState->vertexAttributeDescriptions[%d].format " "(%s) is not a supported vertex buffer format. %s", i, j, string_VkFormat(format), validation_error_map[VALIDATION_ERROR_01413]); } } } } return skip; } VKAPI_ATTR VkResult VKAPI_CALL CreateGraphicsPipelines(VkDevice device, VkPipelineCache pipelineCache, uint32_t count, const VkGraphicsPipelineCreateInfo *pCreateInfos, const VkAllocationCallbacks *pAllocator, VkPipeline *pPipelines) { // TODO What to do with pipelineCache? // The order of operations here is a little convoluted but gets the job done // 1. Pipeline create state is first shadowed into PIPELINE_STATE struct // 2. Create state is then validated (which uses flags setup during shadowing) // 3. If everything looks good, we'll then create the pipeline and add NODE to pipelineMap VkResult result = VK_ERROR_VALIDATION_FAILED_EXT; bool skip = false; // TODO : Improve this data struct w/ unique_ptrs so cleanup below is automatic vector pipe_state(count); layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); uint32_t i = 0; std::unique_lock lock(global_lock); for (i = 0; i < count; i++) { pipe_state[i] = new PIPELINE_STATE; pipe_state[i]->initGraphicsPipeline(&pCreateInfos[i]); pipe_state[i]->render_pass_ci.initialize(getRenderPassState(dev_data, pCreateInfos[i].renderPass)->createInfo.ptr()); pipe_state[i]->pipeline_layout = *getPipelineLayout(dev_data, pCreateInfos[i].layout); } skip |= PreCallCreateGraphicsPipelines(dev_data, count, pCreateInfos, pipe_state); if (!skip) { lock.unlock(); result = dev_data->dispatch_table.CreateGraphicsPipelines(device, pipelineCache, count, pCreateInfos, pAllocator, pPipelines); lock.lock(); for (i = 0; i < count; i++) { pipe_state[i]->pipeline = pPipelines[i]; dev_data->pipelineMap[pipe_state[i]->pipeline] = pipe_state[i]; } lock.unlock(); } else { for (i = 0; i < count; i++) { delete pipe_state[i]; } lock.unlock(); } return result; } VKAPI_ATTR VkResult VKAPI_CALL CreateComputePipelines(VkDevice device, VkPipelineCache pipelineCache, uint32_t count, const VkComputePipelineCreateInfo *pCreateInfos, const VkAllocationCallbacks *pAllocator, VkPipeline *pPipelines) { VkResult result = VK_SUCCESS; bool skip_call = false; // TODO : Improve this data struct w/ unique_ptrs so cleanup below is automatic vector pPipeState(count); layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); uint32_t i = 0; std::unique_lock lock(global_lock); for (i = 0; i < count; i++) { // TODO: Verify compute stage bits // Create and initialize internal tracking data structure pPipeState[i] = new PIPELINE_STATE; pPipeState[i]->initComputePipeline(&pCreateInfos[i]); pPipeState[i]->pipeline_layout = *getPipelineLayout(dev_data, pCreateInfos[i].layout); // memcpy(&pPipeState[i]->computePipelineCI, (const void *)&pCreateInfos[i], sizeof(VkComputePipelineCreateInfo)); // TODO: Add Compute Pipeline Verification skip_call |= !validate_compute_pipeline(dev_data->report_data, pPipeState[i], &dev_data->enabled_features, dev_data->shaderModuleMap); // skip_call |= verifyPipelineCreateState(dev_data, pPipeState[i]); } if (!skip_call) { lock.unlock(); result = dev_data->dispatch_table.CreateComputePipelines(device, pipelineCache, count, pCreateInfos, pAllocator, pPipelines); lock.lock(); for (i = 0; i < count; i++) { pPipeState[i]->pipeline = pPipelines[i]; dev_data->pipelineMap[pPipeState[i]->pipeline] = pPipeState[i]; } lock.unlock(); } else { for (i = 0; i < count; i++) { // Clean up any locally allocated data structures delete pPipeState[i]; } lock.unlock(); return VK_ERROR_VALIDATION_FAILED_EXT; } return result; } VKAPI_ATTR VkResult VKAPI_CALL CreateSampler(VkDevice device, const VkSamplerCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkSampler *pSampler) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = dev_data->dispatch_table.CreateSampler(device, pCreateInfo, pAllocator, pSampler); if (VK_SUCCESS == result) { std::lock_guard lock(global_lock); dev_data->samplerMap[*pSampler] = unique_ptr(new SAMPLER_STATE(pSampler, pCreateInfo)); } return result; } static bool PreCallValidateCreateDescriptorSetLayout(layer_data *dev_data, const VkDescriptorSetLayoutCreateInfo *create_info) { if (dev_data->instance_data->disabled.create_descriptor_set_layout) return false; return cvdescriptorset::DescriptorSetLayout::ValidateCreateInfo(dev_data->report_data, create_info); } static void PostCallRecordCreateDescriptorSetLayout(layer_data *dev_data, const VkDescriptorSetLayoutCreateInfo *create_info, VkDescriptorSetLayout set_layout) { // TODO: Convert this to unique_ptr to avoid leaks dev_data->descriptorSetLayoutMap[set_layout] = new cvdescriptorset::DescriptorSetLayout(create_info, set_layout); } VKAPI_ATTR VkResult VKAPI_CALL CreateDescriptorSetLayout(VkDevice device, const VkDescriptorSetLayoutCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkDescriptorSetLayout *pSetLayout) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = VK_ERROR_VALIDATION_FAILED_EXT; std::unique_lock lock(global_lock); bool skip = PreCallValidateCreateDescriptorSetLayout(dev_data, pCreateInfo); if (!skip) { lock.unlock(); result = dev_data->dispatch_table.CreateDescriptorSetLayout(device, pCreateInfo, pAllocator, pSetLayout); if (VK_SUCCESS == result) { lock.lock(); PostCallRecordCreateDescriptorSetLayout(dev_data, pCreateInfo, *pSetLayout); } } return result; } // Used by CreatePipelineLayout and CmdPushConstants. // Note that the index argument is optional and only used by CreatePipelineLayout. static bool validatePushConstantRange(const layer_data *dev_data, const uint32_t offset, const uint32_t size, const char *caller_name, uint32_t index = 0) { if (dev_data->instance_data->disabled.push_constant_range) return false; uint32_t const maxPushConstantsSize = dev_data->phys_dev_properties.properties.limits.maxPushConstantsSize; bool skip_call = false; // Check that offset + size don't exceed the max. // Prevent arithetic overflow here by avoiding addition and testing in this order. // TODO : This check combines VALIDATION_ERROR_00877 & 880, need to break out separately if ((offset >= maxPushConstantsSize) || (size > maxPushConstantsSize - offset)) { // This is a pain just to adapt the log message to the caller, but better to sort it out only when there is a problem. if (0 == strcmp(caller_name, "vkCreatePipelineLayout()")) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, VALIDATION_ERROR_00877, "DS", "%s call has push constants index %u with offset %u and size %u that " "exceeds this device's maxPushConstantSize of %u. %s", caller_name, index, offset, size, maxPushConstantsSize, validation_error_map[VALIDATION_ERROR_00877]); } else if (0 == strcmp(caller_name, "vkCmdPushConstants()")) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_PUSH_CONSTANTS_ERROR, "DS", "%s call has push constants with offset %u and size %u that " "exceeds this device's maxPushConstantSize of %u.", caller_name, offset, size, maxPushConstantsSize); } else { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INTERNAL_ERROR, "DS", "%s caller not supported.", caller_name); } } // size needs to be non-zero and a multiple of 4. // TODO : This check combines VALIDATION_ERROR_00878 & 879, need to break out separately if ((size == 0) || ((size & 0x3) != 0)) { if (0 == strcmp(caller_name, "vkCreatePipelineLayout()")) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, VALIDATION_ERROR_00878, "DS", "%s call has push constants index %u with " "size %u. Size must be greater than zero and a multiple of 4. %s", caller_name, index, size, validation_error_map[VALIDATION_ERROR_00878]); } else if (0 == strcmp(caller_name, "vkCmdPushConstants()")) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_PUSH_CONSTANTS_ERROR, "DS", "%s call has push constants with " "size %u. Size must be greater than zero and a multiple of 4.", caller_name, size); } else { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INTERNAL_ERROR, "DS", "%s caller not supported.", caller_name); } } // offset needs to be a multiple of 4. if ((offset & 0x3) != 0) { if (0 == strcmp(caller_name, "vkCreatePipelineLayout()")) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_PUSH_CONSTANTS_ERROR, "DS", "%s call has push constants index %u with " "offset %u. Offset must be a multiple of 4.", caller_name, index, offset); } else if (0 == strcmp(caller_name, "vkCmdPushConstants()")) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_PUSH_CONSTANTS_ERROR, "DS", "%s call has push constants with " "offset %u. Offset must be a multiple of 4.", caller_name, offset); } else { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INTERNAL_ERROR, "DS", "%s caller not supported.", caller_name); } } return skip_call; } VKAPI_ATTR VkResult VKAPI_CALL CreatePipelineLayout(VkDevice device, const VkPipelineLayoutCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkPipelineLayout *pPipelineLayout) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); // TODO : Add checks for VALIDATION_ERRORS 865-871 // Push Constant Range checks uint32_t i, j; for (i = 0; i < pCreateInfo->pushConstantRangeCount; ++i) { skip_call |= validatePushConstantRange(dev_data, pCreateInfo->pPushConstantRanges[i].offset, pCreateInfo->pPushConstantRanges[i].size, "vkCreatePipelineLayout()", i); if (0 == pCreateInfo->pPushConstantRanges[i].stageFlags) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_PUSH_CONSTANTS_ERROR, "DS", "vkCreatePipelineLayout() call has no stageFlags set."); } } if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; // Each range has been validated. Now check for overlap between ranges (if they are good). // There's no explicit Valid Usage language against this, so issue a warning instead of an error. for (i = 0; i < pCreateInfo->pushConstantRangeCount; ++i) { for (j = i + 1; j < pCreateInfo->pushConstantRangeCount; ++j) { const uint32_t minA = pCreateInfo->pPushConstantRanges[i].offset; const uint32_t maxA = minA + pCreateInfo->pPushConstantRanges[i].size; const uint32_t minB = pCreateInfo->pPushConstantRanges[j].offset; const uint32_t maxB = minB + pCreateInfo->pPushConstantRanges[j].size; if ((minA <= minB && maxA > minB) || (minB <= minA && maxB > minA)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_PUSH_CONSTANTS_ERROR, "DS", "vkCreatePipelineLayout() call has push constants with " "overlapping ranges: %u:[%u, %u), %u:[%u, %u)", i, minA, maxA, j, minB, maxB); } } } VkResult result = dev_data->dispatch_table.CreatePipelineLayout(device, pCreateInfo, pAllocator, pPipelineLayout); if (VK_SUCCESS == result) { std::lock_guard lock(global_lock); PIPELINE_LAYOUT_NODE &plNode = dev_data->pipelineLayoutMap[*pPipelineLayout]; plNode.layout = *pPipelineLayout; plNode.set_layouts.resize(pCreateInfo->setLayoutCount); for (i = 0; i < pCreateInfo->setLayoutCount; ++i) { plNode.set_layouts[i] = getDescriptorSetLayout(dev_data, pCreateInfo->pSetLayouts[i]); } plNode.push_constant_ranges.resize(pCreateInfo->pushConstantRangeCount); for (i = 0; i < pCreateInfo->pushConstantRangeCount; ++i) { plNode.push_constant_ranges[i] = pCreateInfo->pPushConstantRanges[i]; } } return result; } VKAPI_ATTR VkResult VKAPI_CALL CreateDescriptorPool(VkDevice device, const VkDescriptorPoolCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkDescriptorPool *pDescriptorPool) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = dev_data->dispatch_table.CreateDescriptorPool(device, pCreateInfo, pAllocator, pDescriptorPool); if (VK_SUCCESS == result) { if (log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_POOL_EXT, (uint64_t)*pDescriptorPool, __LINE__, DRAWSTATE_OUT_OF_MEMORY, "DS", "Created Descriptor Pool 0x%" PRIxLEAST64, (uint64_t)*pDescriptorPool)) return VK_ERROR_VALIDATION_FAILED_EXT; DESCRIPTOR_POOL_STATE *pNewNode = new DESCRIPTOR_POOL_STATE(*pDescriptorPool, pCreateInfo); if (NULL == pNewNode) { if (log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_POOL_EXT, (uint64_t)*pDescriptorPool, __LINE__, DRAWSTATE_OUT_OF_MEMORY, "DS", "Out of memory while attempting to allocate DESCRIPTOR_POOL_STATE in vkCreateDescriptorPool()")) return VK_ERROR_VALIDATION_FAILED_EXT; } else { std::lock_guard lock(global_lock); dev_data->descriptorPoolMap[*pDescriptorPool] = pNewNode; } } else { // Need to do anything if pool create fails? } return result; } VKAPI_ATTR VkResult VKAPI_CALL ResetDescriptorPool(VkDevice device, VkDescriptorPool descriptorPool, VkDescriptorPoolResetFlags flags) { // TODO : Add checks for VALIDATION_ERROR_00928 layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = dev_data->dispatch_table.ResetDescriptorPool(device, descriptorPool, flags); if (VK_SUCCESS == result) { std::lock_guard lock(global_lock); clearDescriptorPool(dev_data, device, descriptorPool, flags); } return result; } // Ensure the pool contains enough descriptors and descriptor sets to satisfy // an allocation request. Fills common_data with the total number of descriptors of each type required, // as well as DescriptorSetLayout ptrs used for later update. static bool PreCallValidateAllocateDescriptorSets(layer_data *dev_data, const VkDescriptorSetAllocateInfo *pAllocateInfo, cvdescriptorset::AllocateDescriptorSetsData *common_data) { if (dev_data->instance_data->disabled.allocate_descriptor_sets) return false; // All state checks for AllocateDescriptorSets is done in single function return cvdescriptorset::ValidateAllocateDescriptorSets(dev_data->report_data, pAllocateInfo, dev_data, common_data); } // Allocation state was good and call down chain was made so update state based on allocating descriptor sets static void PostCallRecordAllocateDescriptorSets(layer_data *dev_data, const VkDescriptorSetAllocateInfo *pAllocateInfo, VkDescriptorSet *pDescriptorSets, const cvdescriptorset::AllocateDescriptorSetsData *common_data) { // All the updates are contained in a single cvdescriptorset function cvdescriptorset::PerformAllocateDescriptorSets(pAllocateInfo, pDescriptorSets, common_data, &dev_data->descriptorPoolMap, &dev_data->setMap, dev_data); } VKAPI_ATTR VkResult VKAPI_CALL AllocateDescriptorSets(VkDevice device, const VkDescriptorSetAllocateInfo *pAllocateInfo, VkDescriptorSet *pDescriptorSets) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); std::unique_lock lock(global_lock); cvdescriptorset::AllocateDescriptorSetsData common_data(pAllocateInfo->descriptorSetCount); bool skip_call = PreCallValidateAllocateDescriptorSets(dev_data, pAllocateInfo, &common_data); lock.unlock(); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult result = dev_data->dispatch_table.AllocateDescriptorSets(device, pAllocateInfo, pDescriptorSets); if (VK_SUCCESS == result) { lock.lock(); PostCallRecordAllocateDescriptorSets(dev_data, pAllocateInfo, pDescriptorSets, &common_data); lock.unlock(); } return result; } // Verify state before freeing DescriptorSets static bool PreCallValidateFreeDescriptorSets(const layer_data *dev_data, VkDescriptorPool pool, uint32_t count, const VkDescriptorSet *descriptor_sets) { if (dev_data->instance_data->disabled.free_descriptor_sets) return false; bool skip_call = false; // First make sure sets being destroyed are not currently in-use for (uint32_t i = 0; i < count; ++i) skip_call |= validateIdleDescriptorSet(dev_data, descriptor_sets[i], "vkFreeDescriptorSets"); DESCRIPTOR_POOL_STATE *pool_state = getDescriptorPoolState(dev_data, pool); if (pool_state && !(VK_DESCRIPTOR_POOL_CREATE_FREE_DESCRIPTOR_SET_BIT & pool_state->createInfo.flags)) { // Can't Free from a NON_FREE pool skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_POOL_EXT, reinterpret_cast(pool), __LINE__, VALIDATION_ERROR_00922, "DS", "It is invalid to call vkFreeDescriptorSets() with a pool created without setting " "VK_DESCRIPTOR_POOL_CREATE_FREE_DESCRIPTOR_SET_BIT. %s", validation_error_map[VALIDATION_ERROR_00922]); } return skip_call; } // Sets have been removed from the pool so update underlying state static void PostCallRecordFreeDescriptorSets(layer_data *dev_data, VkDescriptorPool pool, uint32_t count, const VkDescriptorSet *descriptor_sets) { DESCRIPTOR_POOL_STATE *pool_state = getDescriptorPoolState(dev_data, pool); // Update available descriptor sets in pool pool_state->availableSets += count; // For each freed descriptor add its resources back into the pool as available and remove from pool and setMap for (uint32_t i = 0; i < count; ++i) { auto set_state = dev_data->setMap[descriptor_sets[i]]; uint32_t type_index = 0, descriptor_count = 0; for (uint32_t j = 0; j < set_state->GetBindingCount(); ++j) { type_index = static_cast(set_state->GetTypeFromIndex(j)); descriptor_count = set_state->GetDescriptorCountFromIndex(j); pool_state->availableDescriptorTypeCount[type_index] += descriptor_count; } freeDescriptorSet(dev_data, set_state); pool_state->sets.erase(set_state); } } VKAPI_ATTR VkResult VKAPI_CALL FreeDescriptorSets(VkDevice device, VkDescriptorPool descriptorPool, uint32_t count, const VkDescriptorSet *pDescriptorSets) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); // Make sure that no sets being destroyed are in-flight std::unique_lock lock(global_lock); bool skip_call = PreCallValidateFreeDescriptorSets(dev_data, descriptorPool, count, pDescriptorSets); lock.unlock(); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult result = dev_data->dispatch_table.FreeDescriptorSets(device, descriptorPool, count, pDescriptorSets); if (VK_SUCCESS == result) { lock.lock(); PostCallRecordFreeDescriptorSets(dev_data, descriptorPool, count, pDescriptorSets); lock.unlock(); } return result; } // TODO : This is a Proof-of-concept for core validation architecture // Really we'll want to break out these functions to separate files but // keeping it all together here to prove out design // PreCallValidate* handles validating all of the state prior to calling down chain to UpdateDescriptorSets() static bool PreCallValidateUpdateDescriptorSets(layer_data *dev_data, uint32_t descriptorWriteCount, const VkWriteDescriptorSet *pDescriptorWrites, uint32_t descriptorCopyCount, const VkCopyDescriptorSet *pDescriptorCopies) { if (dev_data->instance_data->disabled.update_descriptor_sets) return false; // First thing to do is perform map look-ups. // NOTE : UpdateDescriptorSets is somewhat unique in that it's operating on a number of DescriptorSets // so we can't just do a single map look-up up-front, but do them individually in functions below // Now make call(s) that validate state, but don't perform state updates in this function // Note, here DescriptorSets is unique in that we don't yet have an instance. Using a helper function in the // namespace which will parse params and make calls into specific class instances return cvdescriptorset::ValidateUpdateDescriptorSets(dev_data->report_data, dev_data, descriptorWriteCount, pDescriptorWrites, descriptorCopyCount, pDescriptorCopies); } // PostCallRecord* handles recording state updates following call down chain to UpdateDescriptorSets() static void PostCallRecordUpdateDescriptorSets(layer_data *dev_data, uint32_t descriptorWriteCount, const VkWriteDescriptorSet *pDescriptorWrites, uint32_t descriptorCopyCount, const VkCopyDescriptorSet *pDescriptorCopies) { cvdescriptorset::PerformUpdateDescriptorSets(dev_data, descriptorWriteCount, pDescriptorWrites, descriptorCopyCount, pDescriptorCopies); } VKAPI_ATTR void VKAPI_CALL UpdateDescriptorSets(VkDevice device, uint32_t descriptorWriteCount, const VkWriteDescriptorSet *pDescriptorWrites, uint32_t descriptorCopyCount, const VkCopyDescriptorSet *pDescriptorCopies) { // Only map look-up at top level is for device-level layer_data layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); std::unique_lock lock(global_lock); bool skip_call = PreCallValidateUpdateDescriptorSets(dev_data, descriptorWriteCount, pDescriptorWrites, descriptorCopyCount, pDescriptorCopies); lock.unlock(); if (!skip_call) { dev_data->dispatch_table.UpdateDescriptorSets(device, descriptorWriteCount, pDescriptorWrites, descriptorCopyCount, pDescriptorCopies); lock.lock(); // Since UpdateDescriptorSets() is void, nothing to check prior to updating state PostCallRecordUpdateDescriptorSets(dev_data, descriptorWriteCount, pDescriptorWrites, descriptorCopyCount, pDescriptorCopies); } } VKAPI_ATTR VkResult VKAPI_CALL AllocateCommandBuffers(VkDevice device, const VkCommandBufferAllocateInfo *pCreateInfo, VkCommandBuffer *pCommandBuffer) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = dev_data->dispatch_table.AllocateCommandBuffers(device, pCreateInfo, pCommandBuffer); if (VK_SUCCESS == result) { std::unique_lock lock(global_lock); auto pPool = getCommandPoolNode(dev_data, pCreateInfo->commandPool); if (pPool) { for (uint32_t i = 0; i < pCreateInfo->commandBufferCount; i++) { // Add command buffer to its commandPool map pPool->commandBuffers.push_back(pCommandBuffer[i]); GLOBAL_CB_NODE *pCB = new GLOBAL_CB_NODE; // Add command buffer to map dev_data->commandBufferMap[pCommandBuffer[i]] = pCB; resetCB(dev_data, pCommandBuffer[i]); pCB->createInfo = *pCreateInfo; pCB->device = device; } } printCBList(dev_data); lock.unlock(); } return result; } // Add bindings between the given cmd buffer & framebuffer and the framebuffer's children static void AddFramebufferBinding(layer_data *dev_data, GLOBAL_CB_NODE *cb_state, FRAMEBUFFER_STATE *fb_state) { addCommandBufferBinding(&fb_state->cb_bindings, {reinterpret_cast(fb_state->framebuffer), VK_DEBUG_REPORT_OBJECT_TYPE_FRAMEBUFFER_EXT}, cb_state); for (auto attachment : fb_state->attachments) { auto view_state = attachment.view_state; if (view_state) { AddCommandBufferBindingImageView(dev_data, cb_state, view_state); } auto rp_state = getRenderPassState(dev_data, fb_state->createInfo.renderPass); if (rp_state) { addCommandBufferBinding( &rp_state->cb_bindings, {reinterpret_cast(rp_state->renderPass), VK_DEBUG_REPORT_OBJECT_TYPE_RENDER_PASS_EXT}, cb_state); } } } VKAPI_ATTR VkResult VKAPI_CALL BeginCommandBuffer(VkCommandBuffer commandBuffer, const VkCommandBufferBeginInfo *pBeginInfo) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); // Validate command buffer level GLOBAL_CB_NODE *cb_node = getCBNode(dev_data, commandBuffer); if (cb_node) { // This implicitly resets the Cmd Buffer so make sure any fence is done and then clear memory references if (dev_data->globalInFlightCmdBuffers.count(commandBuffer)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)commandBuffer, __LINE__, MEMTRACK_RESET_CB_WHILE_IN_FLIGHT, "MEM", "Calling vkBeginCommandBuffer() on active command buffer 0x%p before it has completed. " "You must check command buffer fence before this call.", commandBuffer); } clear_cmd_buf_and_mem_references(dev_data, cb_node); if (cb_node->createInfo.level != VK_COMMAND_BUFFER_LEVEL_PRIMARY) { // Secondary Command Buffer const VkCommandBufferInheritanceInfo *pInfo = pBeginInfo->pInheritanceInfo; if (!pInfo) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(commandBuffer), __LINE__, DRAWSTATE_BEGIN_CB_INVALID_STATE, "DS", "vkBeginCommandBuffer(): Secondary Command Buffer (0x%p) must have inheritance info.", reinterpret_cast(commandBuffer)); } else { if (pBeginInfo->flags & VK_COMMAND_BUFFER_USAGE_RENDER_PASS_CONTINUE_BIT) { if (!pInfo->renderPass) { // renderpass should NOT be null for a Secondary CB skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(commandBuffer), __LINE__, DRAWSTATE_BEGIN_CB_INVALID_STATE, "DS", "vkBeginCommandBuffer(): Secondary Command Buffers (0x%p) must specify a valid renderpass parameter.", reinterpret_cast(commandBuffer)); } if (!pInfo->framebuffer) { // framebuffer may be null for a Secondary CB, but this affects perf skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(commandBuffer), __LINE__, DRAWSTATE_BEGIN_CB_INVALID_STATE, "DS", "vkBeginCommandBuffer(): Secondary Command Buffers (0x%p) may perform better if a " "valid framebuffer parameter is specified.", reinterpret_cast(commandBuffer)); } else { string errorString = ""; auto framebuffer = getFramebufferState(dev_data, pInfo->framebuffer); if (framebuffer) { if ((framebuffer->createInfo.renderPass != pInfo->renderPass) && !verify_renderpass_compatibility(dev_data, framebuffer->renderPassCreateInfo.ptr(), getRenderPassState(dev_data, pInfo->renderPass)->createInfo.ptr(), errorString)) { // renderPass that framebuffer was created with must be compatible with local renderPass skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(commandBuffer), __LINE__, DRAWSTATE_RENDERPASS_INCOMPATIBLE, "DS", "vkBeginCommandBuffer(): Secondary Command " "Buffer (0x%p) renderPass (0x%" PRIxLEAST64 ") is incompatible w/ framebuffer " "(0x%" PRIxLEAST64 ") w/ render pass (0x%" PRIxLEAST64 ") due to: %s", reinterpret_cast(commandBuffer), reinterpret_cast(pInfo->renderPass), reinterpret_cast(pInfo->framebuffer), reinterpret_cast(framebuffer->createInfo.renderPass), errorString.c_str()); } // Connect this framebuffer and its children to this cmdBuffer AddFramebufferBinding(dev_data, cb_node, framebuffer); } } } if ((pInfo->occlusionQueryEnable == VK_FALSE || dev_data->enabled_features.occlusionQueryPrecise == VK_FALSE) && (pInfo->queryFlags & VK_QUERY_CONTROL_PRECISE_BIT)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(commandBuffer), __LINE__, DRAWSTATE_BEGIN_CB_INVALID_STATE, "DS", "vkBeginCommandBuffer(): Secondary Command Buffer (0x%p) must not have " "VK_QUERY_CONTROL_PRECISE_BIT if occulusionQuery is disabled or the device does not " "support precise occlusion queries.", reinterpret_cast(commandBuffer)); } } if (pInfo && pInfo->renderPass != VK_NULL_HANDLE) { auto renderPass = getRenderPassState(dev_data, pInfo->renderPass); if (renderPass) { if (pInfo->subpass >= renderPass->createInfo.subpassCount) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)commandBuffer, __LINE__, DRAWSTATE_BEGIN_CB_INVALID_STATE, "DS", "vkBeginCommandBuffer(): Secondary Command Buffers (0x%p) must has a subpass index (%d) " "that is less than the number of subpasses (%d).", (void *)commandBuffer, pInfo->subpass, renderPass->createInfo.subpassCount); } } } } if (CB_RECORDING == cb_node->state) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)commandBuffer, __LINE__, DRAWSTATE_BEGIN_CB_INVALID_STATE, "DS", "vkBeginCommandBuffer(): Cannot call Begin on command buffer (0x%" PRIxLEAST64 ") in the RECORDING state. Must first call vkEndCommandBuffer().", (uint64_t)commandBuffer); } else if (CB_RECORDED == cb_node->state || (CB_INVALID == cb_node->state && CMD_END == cb_node->cmds.back().type)) { VkCommandPool cmdPool = cb_node->createInfo.commandPool; auto pPool = getCommandPoolNode(dev_data, cmdPool); if (!(VK_COMMAND_POOL_CREATE_RESET_COMMAND_BUFFER_BIT & pPool->createFlags)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)commandBuffer, __LINE__, DRAWSTATE_INVALID_COMMAND_BUFFER_RESET, "DS", "Call to vkBeginCommandBuffer() on command buffer (0x%" PRIxLEAST64 ") attempts to implicitly reset cmdBuffer created from command pool (0x%" PRIxLEAST64 ") that does NOT have the VK_COMMAND_POOL_CREATE_RESET_COMMAND_BUFFER_BIT bit set.", (uint64_t)commandBuffer, (uint64_t)cmdPool); } resetCB(dev_data, commandBuffer); } // Set updated state here in case implicit reset occurs above cb_node->state = CB_RECORDING; cb_node->beginInfo = *pBeginInfo; if (cb_node->beginInfo.pInheritanceInfo) { cb_node->inheritanceInfo = *(cb_node->beginInfo.pInheritanceInfo); cb_node->beginInfo.pInheritanceInfo = &cb_node->inheritanceInfo; // If we are a secondary command-buffer and inheriting. Update the items we should inherit. if ((cb_node->createInfo.level != VK_COMMAND_BUFFER_LEVEL_PRIMARY) && (cb_node->beginInfo.flags & VK_COMMAND_BUFFER_USAGE_RENDER_PASS_CONTINUE_BIT)) { cb_node->activeRenderPass = getRenderPassState(dev_data, cb_node->beginInfo.pInheritanceInfo->renderPass); cb_node->activeSubpass = cb_node->beginInfo.pInheritanceInfo->subpass; cb_node->activeFramebuffer = cb_node->beginInfo.pInheritanceInfo->framebuffer; cb_node->framebuffers.insert(cb_node->beginInfo.pInheritanceInfo->framebuffer); } } } else { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)commandBuffer, __LINE__, DRAWSTATE_INVALID_COMMAND_BUFFER, "DS", "In vkBeginCommandBuffer() and unable to find CommandBuffer Node for command buffer 0x%p!", (void *)commandBuffer); } lock.unlock(); if (skip_call) { return VK_ERROR_VALIDATION_FAILED_EXT; } VkResult result = dev_data->dispatch_table.BeginCommandBuffer(commandBuffer, pBeginInfo); return result; } VKAPI_ATTR VkResult VKAPI_CALL EndCommandBuffer(VkCommandBuffer commandBuffer) { bool skip_call = false; VkResult result = VK_SUCCESS; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { if ((VK_COMMAND_BUFFER_LEVEL_PRIMARY == pCB->createInfo.level) || !(pCB->beginInfo.flags & VK_COMMAND_BUFFER_USAGE_RENDER_PASS_CONTINUE_BIT)) { // This needs spec clarification to update valid usage, see comments in PR: // https://github.com/KhronosGroup/Vulkan-LoaderAndValidationLayers/pull/516#discussion_r63013756 skip_call |= insideRenderPass(dev_data, pCB, "vkEndCommandBuffer"); } skip_call |= addCmd(dev_data, pCB, CMD_END, "vkEndCommandBuffer()"); for (auto query : pCB->activeQueries) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_QUERY, "DS", "Ending command buffer with in progress query: queryPool 0x%" PRIx64 ", index %d", (uint64_t)(query.pool), query.index); } } if (!skip_call) { lock.unlock(); result = dev_data->dispatch_table.EndCommandBuffer(commandBuffer); lock.lock(); if (VK_SUCCESS == result) { pCB->state = CB_RECORDED; // Reset CB status flags pCB->status = 0; printCB(dev_data, commandBuffer); } } else { result = VK_ERROR_VALIDATION_FAILED_EXT; } lock.unlock(); return result; } VKAPI_ATTR VkResult VKAPI_CALL ResetCommandBuffer(VkCommandBuffer commandBuffer, VkCommandBufferResetFlags flags) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); VkCommandPool cmdPool = pCB->createInfo.commandPool; auto pPool = getCommandPoolNode(dev_data, cmdPool); if (!(VK_COMMAND_POOL_CREATE_RESET_COMMAND_BUFFER_BIT & pPool->createFlags)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)commandBuffer, __LINE__, DRAWSTATE_INVALID_COMMAND_BUFFER_RESET, "DS", "Attempt to reset command buffer (0x%" PRIxLEAST64 ") created from command pool (0x%" PRIxLEAST64 ") that does NOT have the VK_COMMAND_POOL_CREATE_RESET_COMMAND_BUFFER_BIT bit set.", (uint64_t)commandBuffer, (uint64_t)cmdPool); } skip_call |= checkCommandBufferInFlight(dev_data, pCB, "reset", VALIDATION_ERROR_00092); lock.unlock(); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult result = dev_data->dispatch_table.ResetCommandBuffer(commandBuffer, flags); if (VK_SUCCESS == result) { lock.lock(); dev_data->globalInFlightCmdBuffers.erase(commandBuffer); resetCB(dev_data, commandBuffer); lock.unlock(); } return result; } VKAPI_ATTR void VKAPI_CALL CmdBindPipeline(VkCommandBuffer commandBuffer, VkPipelineBindPoint pipelineBindPoint, VkPipeline pipeline) { bool skip = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *cb_state = getCBNode(dev_data, commandBuffer); if (cb_state) { skip |= addCmd(dev_data, cb_state, CMD_BINDPIPELINE, "vkCmdBindPipeline()"); if ((VK_PIPELINE_BIND_POINT_COMPUTE == pipelineBindPoint) && (cb_state->activeRenderPass)) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PIPELINE_EXT, (uint64_t)pipeline, __LINE__, DRAWSTATE_INVALID_RENDERPASS_CMD, "DS", "Incorrectly binding compute pipeline (0x%" PRIxLEAST64 ") during active RenderPass (0x%" PRIxLEAST64 ")", (uint64_t)pipeline, (uint64_t)cb_state->activeRenderPass->renderPass); } PIPELINE_STATE *pipe_state = getPipelineState(dev_data, pipeline); if (pipe_state) { cb_state->lastBound[pipelineBindPoint].pipeline_state = pipe_state; set_cb_pso_status(cb_state, pipe_state); set_pipeline_state(pipe_state); } else { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PIPELINE_EXT, (uint64_t)pipeline, __LINE__, DRAWSTATE_INVALID_PIPELINE, "DS", "Attempt to bind Pipeline 0x%" PRIxLEAST64 " that doesn't exist!", (uint64_t)(pipeline)); } addCommandBufferBinding(&pipe_state->cb_bindings, {reinterpret_cast(pipeline), VK_DEBUG_REPORT_OBJECT_TYPE_PIPELINE_EXT}, cb_state); if (VK_PIPELINE_BIND_POINT_GRAPHICS == pipelineBindPoint) { // Add binding for child renderpass auto rp_state = getRenderPassState(dev_data, pipe_state->graphicsPipelineCI.renderPass); if (rp_state) { addCommandBufferBinding( &rp_state->cb_bindings, {reinterpret_cast(rp_state->renderPass), VK_DEBUG_REPORT_OBJECT_TYPE_RENDER_PASS_EXT}, cb_state); } } } lock.unlock(); if (!skip) dev_data->dispatch_table.CmdBindPipeline(commandBuffer, pipelineBindPoint, pipeline); } VKAPI_ATTR void VKAPI_CALL CmdSetViewport(VkCommandBuffer commandBuffer, uint32_t firstViewport, uint32_t viewportCount, const VkViewport *pViewports) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_SETVIEWPORTSTATE, "vkCmdSetViewport()"); pCB->viewportMask |= ((1u<dispatch_table.CmdSetViewport(commandBuffer, firstViewport, viewportCount, pViewports); } VKAPI_ATTR void VKAPI_CALL CmdSetScissor(VkCommandBuffer commandBuffer, uint32_t firstScissor, uint32_t scissorCount, const VkRect2D *pScissors) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_SETSCISSORSTATE, "vkCmdSetScissor()"); pCB->scissorMask |= ((1u<dispatch_table.CmdSetScissor(commandBuffer, firstScissor, scissorCount, pScissors); } VKAPI_ATTR void VKAPI_CALL CmdSetLineWidth(VkCommandBuffer commandBuffer, float lineWidth) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_SETLINEWIDTHSTATE, "vkCmdSetLineWidth()"); pCB->status |= CBSTATUS_LINE_WIDTH_SET; PIPELINE_STATE *pPipeTrav = pCB->lastBound[VK_PIPELINE_BIND_POINT_GRAPHICS].pipeline_state; if (pPipeTrav != NULL && !isDynamic(pPipeTrav, VK_DYNAMIC_STATE_LINE_WIDTH)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, (VkDebugReportObjectTypeEXT)0, reinterpret_cast(commandBuffer), __LINE__, DRAWSTATE_INVALID_SET, "DS", "vkCmdSetLineWidth called but pipeline was created without VK_DYNAMIC_STATE_LINE_WIDTH " "flag. This is undefined behavior and could be ignored."); } else { skip_call |= verifyLineWidth(dev_data, DRAWSTATE_INVALID_SET, reinterpret_cast(commandBuffer), lineWidth); } } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdSetLineWidth(commandBuffer, lineWidth); } VKAPI_ATTR void VKAPI_CALL CmdSetDepthBias(VkCommandBuffer commandBuffer, float depthBiasConstantFactor, float depthBiasClamp, float depthBiasSlopeFactor) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_SETDEPTHBIASSTATE, "vkCmdSetDepthBias()"); pCB->status |= CBSTATUS_DEPTH_BIAS_SET; } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdSetDepthBias(commandBuffer, depthBiasConstantFactor, depthBiasClamp, depthBiasSlopeFactor); } VKAPI_ATTR void VKAPI_CALL CmdSetBlendConstants(VkCommandBuffer commandBuffer, const float blendConstants[4]) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_SETBLENDSTATE, "vkCmdSetBlendConstants()"); pCB->status |= CBSTATUS_BLEND_CONSTANTS_SET; } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdSetBlendConstants(commandBuffer, blendConstants); } VKAPI_ATTR void VKAPI_CALL CmdSetDepthBounds(VkCommandBuffer commandBuffer, float minDepthBounds, float maxDepthBounds) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_SETDEPTHBOUNDSSTATE, "vkCmdSetDepthBounds()"); pCB->status |= CBSTATUS_DEPTH_BOUNDS_SET; } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdSetDepthBounds(commandBuffer, minDepthBounds, maxDepthBounds); } VKAPI_ATTR void VKAPI_CALL CmdSetStencilCompareMask(VkCommandBuffer commandBuffer, VkStencilFaceFlags faceMask, uint32_t compareMask) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_SETSTENCILREADMASKSTATE, "vkCmdSetStencilCompareMask()"); pCB->status |= CBSTATUS_STENCIL_READ_MASK_SET; } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdSetStencilCompareMask(commandBuffer, faceMask, compareMask); } VKAPI_ATTR void VKAPI_CALL CmdSetStencilWriteMask(VkCommandBuffer commandBuffer, VkStencilFaceFlags faceMask, uint32_t writeMask) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_SETSTENCILWRITEMASKSTATE, "vkCmdSetStencilWriteMask()"); pCB->status |= CBSTATUS_STENCIL_WRITE_MASK_SET; } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdSetStencilWriteMask(commandBuffer, faceMask, writeMask); } VKAPI_ATTR void VKAPI_CALL CmdSetStencilReference(VkCommandBuffer commandBuffer, VkStencilFaceFlags faceMask, uint32_t reference) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_SETSTENCILREFERENCESTATE, "vkCmdSetStencilReference()"); pCB->status |= CBSTATUS_STENCIL_REFERENCE_SET; } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdSetStencilReference(commandBuffer, faceMask, reference); } VKAPI_ATTR void VKAPI_CALL CmdBindDescriptorSets(VkCommandBuffer commandBuffer, VkPipelineBindPoint pipelineBindPoint, VkPipelineLayout layout, uint32_t firstSet, uint32_t setCount, const VkDescriptorSet *pDescriptorSets, uint32_t dynamicOffsetCount, const uint32_t *pDynamicOffsets) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { if (pCB->state == CB_RECORDING) { // Track total count of dynamic descriptor types to make sure we have an offset for each one uint32_t totalDynamicDescriptors = 0; string errorString = ""; uint32_t lastSetIndex = firstSet + setCount - 1; if (lastSetIndex >= pCB->lastBound[pipelineBindPoint].boundDescriptorSets.size()) { pCB->lastBound[pipelineBindPoint].boundDescriptorSets.resize(lastSetIndex + 1); pCB->lastBound[pipelineBindPoint].dynamicOffsets.resize(lastSetIndex + 1); } auto oldFinalBoundSet = pCB->lastBound[pipelineBindPoint].boundDescriptorSets[lastSetIndex]; auto pipeline_layout = getPipelineLayout(dev_data, layout); for (uint32_t i = 0; i < setCount; i++) { cvdescriptorset::DescriptorSet *pSet = getSetNode(dev_data, pDescriptorSets[i]); if (pSet) { pCB->lastBound[pipelineBindPoint].pipeline_layout = *pipeline_layout; pCB->lastBound[pipelineBindPoint].boundDescriptorSets[i + firstSet] = pSet; skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT, (uint64_t)pDescriptorSets[i], __LINE__, DRAWSTATE_NONE, "DS", "Descriptor Set 0x%" PRIxLEAST64 " bound on pipeline %s", (uint64_t)pDescriptorSets[i], string_VkPipelineBindPoint(pipelineBindPoint)); if (!pSet->IsUpdated() && (pSet->GetTotalDescriptorCount() != 0)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT, (uint64_t)pDescriptorSets[i], __LINE__, DRAWSTATE_DESCRIPTOR_SET_NOT_UPDATED, "DS", "Descriptor Set 0x%" PRIxLEAST64 " bound but it was never updated. You may want to either update it or not bind it.", (uint64_t)pDescriptorSets[i]); } // Verify that set being bound is compatible with overlapping setLayout of pipelineLayout if (!verify_set_layout_compatibility(dev_data, pSet, pipeline_layout, i + firstSet, errorString)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT, (uint64_t)pDescriptorSets[i], __LINE__, DRAWSTATE_PIPELINE_LAYOUTS_INCOMPATIBLE, "DS", "descriptorSet #%u being bound is not compatible with overlapping descriptorSetLayout " "at index %u of pipelineLayout 0x%" PRIxLEAST64 " due to: %s", i, i + firstSet, reinterpret_cast(layout), errorString.c_str()); } auto setDynamicDescriptorCount = pSet->GetDynamicDescriptorCount(); pCB->lastBound[pipelineBindPoint].dynamicOffsets[firstSet + i].clear(); if (setDynamicDescriptorCount) { // First make sure we won't overstep bounds of pDynamicOffsets array if ((totalDynamicDescriptors + setDynamicDescriptorCount) > dynamicOffsetCount) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT, (uint64_t)pDescriptorSets[i], __LINE__, DRAWSTATE_INVALID_DYNAMIC_OFFSET_COUNT, "DS", "descriptorSet #%u (0x%" PRIxLEAST64 ") requires %u dynamicOffsets, but only %u dynamicOffsets are left in pDynamicOffsets " "array. There must be one dynamic offset for each dynamic descriptor being bound.", i, (uint64_t)pDescriptorSets[i], pSet->GetDynamicDescriptorCount(), (dynamicOffsetCount - totalDynamicDescriptors)); } else { // Validate and store dynamic offsets with the set // Validate Dynamic Offset Minimums uint32_t cur_dyn_offset = totalDynamicDescriptors; for (uint32_t d = 0; d < pSet->GetTotalDescriptorCount(); d++) { if (pSet->GetTypeFromGlobalIndex(d) == VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC) { if (vk_safe_modulo( pDynamicOffsets[cur_dyn_offset], dev_data->phys_dev_properties.properties.limits.minUniformBufferOffsetAlignment) != 0) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PHYSICAL_DEVICE_EXT, 0, __LINE__, DRAWSTATE_INVALID_UNIFORM_BUFFER_OFFSET, "DS", "vkCmdBindDescriptorSets(): pDynamicOffsets[%d] is %d but must be a multiple of " "device limit minUniformBufferOffsetAlignment 0x%" PRIxLEAST64, cur_dyn_offset, pDynamicOffsets[cur_dyn_offset], dev_data->phys_dev_properties.properties.limits.minUniformBufferOffsetAlignment); } cur_dyn_offset++; } else if (pSet->GetTypeFromGlobalIndex(d) == VK_DESCRIPTOR_TYPE_STORAGE_BUFFER_DYNAMIC) { if (vk_safe_modulo( pDynamicOffsets[cur_dyn_offset], dev_data->phys_dev_properties.properties.limits.minStorageBufferOffsetAlignment) != 0) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PHYSICAL_DEVICE_EXT, 0, __LINE__, DRAWSTATE_INVALID_STORAGE_BUFFER_OFFSET, "DS", "vkCmdBindDescriptorSets(): pDynamicOffsets[%d] is %d but must be a multiple of " "device limit minStorageBufferOffsetAlignment 0x%" PRIxLEAST64, cur_dyn_offset, pDynamicOffsets[cur_dyn_offset], dev_data->phys_dev_properties.properties.limits.minStorageBufferOffsetAlignment); } cur_dyn_offset++; } } pCB->lastBound[pipelineBindPoint].dynamicOffsets[firstSet + i] = std::vector(pDynamicOffsets + totalDynamicDescriptors, pDynamicOffsets + totalDynamicDescriptors + setDynamicDescriptorCount); // Keep running total of dynamic descriptor count to verify at the end totalDynamicDescriptors += setDynamicDescriptorCount; } } } else { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT, (uint64_t)pDescriptorSets[i], __LINE__, DRAWSTATE_INVALID_SET, "DS", "Attempt to bind descriptor set 0x%" PRIxLEAST64 " that doesn't exist!", (uint64_t)pDescriptorSets[i]); } skip_call |= addCmd(dev_data, pCB, CMD_BINDDESCRIPTORSETS, "vkCmdBindDescriptorSets()"); // For any previously bound sets, need to set them to "invalid" if they were disturbed by this update if (firstSet > 0) { // Check set #s below the first bound set for (uint32_t i = 0; i < firstSet; ++i) { if (pCB->lastBound[pipelineBindPoint].boundDescriptorSets[i] && !verify_set_layout_compatibility(dev_data, pCB->lastBound[pipelineBindPoint].boundDescriptorSets[i], pipeline_layout, i, errorString)) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_PERFORMANCE_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT, (uint64_t)pCB->lastBound[pipelineBindPoint].boundDescriptorSets[i], __LINE__, DRAWSTATE_NONE, "DS", "DescriptorSet 0x%" PRIxLEAST64 " previously bound as set #%u was disturbed by newly bound pipelineLayout (0x%" PRIxLEAST64 ")", (uint64_t)pCB->lastBound[pipelineBindPoint].boundDescriptorSets[i], i, (uint64_t)layout); pCB->lastBound[pipelineBindPoint].boundDescriptorSets[i] = VK_NULL_HANDLE; } } } // Check if newly last bound set invalidates any remaining bound sets if ((pCB->lastBound[pipelineBindPoint].boundDescriptorSets.size() - 1) > (lastSetIndex)) { if (oldFinalBoundSet && !verify_set_layout_compatibility(dev_data, oldFinalBoundSet, pipeline_layout, lastSetIndex, errorString)) { auto old_set = oldFinalBoundSet->GetSet(); skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_PERFORMANCE_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DESCRIPTOR_SET_EXT, reinterpret_cast(old_set), __LINE__, DRAWSTATE_NONE, "DS", "DescriptorSet 0x%" PRIxLEAST64 " previously bound as set #%u is incompatible with set 0x%" PRIxLEAST64 " newly bound as set #%u so set #%u and any subsequent sets were " "disturbed by newly bound pipelineLayout (0x%" PRIxLEAST64 ")", reinterpret_cast(old_set), lastSetIndex, (uint64_t)pCB->lastBound[pipelineBindPoint].boundDescriptorSets[lastSetIndex], lastSetIndex, lastSetIndex + 1, (uint64_t)layout); pCB->lastBound[pipelineBindPoint].boundDescriptorSets.resize(lastSetIndex + 1); } } } // dynamicOffsetCount must equal the total number of dynamic descriptors in the sets being bound if (totalDynamicDescriptors != dynamicOffsetCount) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)commandBuffer, __LINE__, DRAWSTATE_INVALID_DYNAMIC_OFFSET_COUNT, "DS", "Attempting to bind %u descriptorSets with %u dynamic descriptors, but dynamicOffsetCount " "is %u. It should exactly match the number of dynamic descriptors.", setCount, totalDynamicDescriptors, dynamicOffsetCount); } } else { skip_call |= report_error_no_cb_begin(dev_data, commandBuffer, "vkCmdBindDescriptorSets()"); } } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdBindDescriptorSets(commandBuffer, pipelineBindPoint, layout, firstSet, setCount, pDescriptorSets, dynamicOffsetCount, pDynamicOffsets); } VKAPI_ATTR void VKAPI_CALL CmdBindIndexBuffer(VkCommandBuffer commandBuffer, VkBuffer buffer, VkDeviceSize offset, VkIndexType indexType) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); // TODO : Somewhere need to verify that IBs have correct usage state flagged std::unique_lock lock(global_lock); auto buffer_state = getBufferState(dev_data, buffer); auto cb_node = getCBNode(dev_data, commandBuffer); if (cb_node && buffer_state) { skip_call |= ValidateMemoryIsBoundToBuffer(dev_data, buffer_state, "vkCmdBindIndexBuffer()"); std::function function = [=]() { return ValidateBufferMemoryIsValid(dev_data, buffer_state, "vkCmdBindIndexBuffer()"); }; cb_node->validate_functions.push_back(function); skip_call |= addCmd(dev_data, cb_node, CMD_BINDINDEXBUFFER, "vkCmdBindIndexBuffer()"); VkDeviceSize offset_align = 0; switch (indexType) { case VK_INDEX_TYPE_UINT16: offset_align = 2; break; case VK_INDEX_TYPE_UINT32: offset_align = 4; break; default: // ParamChecker should catch bad enum, we'll also throw alignment error below if offset_align stays 0 break; } if (!offset_align || (offset % offset_align)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_VTX_INDEX_ALIGNMENT_ERROR, "DS", "vkCmdBindIndexBuffer() offset (0x%" PRIxLEAST64 ") does not fall on alignment (%s) boundary.", offset, string_VkIndexType(indexType)); } cb_node->status |= CBSTATUS_INDEX_BUFFER_BOUND; } else { assert(0); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdBindIndexBuffer(commandBuffer, buffer, offset, indexType); } void updateResourceTracking(GLOBAL_CB_NODE *pCB, uint32_t firstBinding, uint32_t bindingCount, const VkBuffer *pBuffers) { uint32_t end = firstBinding + bindingCount; if (pCB->currentDrawData.buffers.size() < end) { pCB->currentDrawData.buffers.resize(end); } for (uint32_t i = 0; i < bindingCount; ++i) { pCB->currentDrawData.buffers[i + firstBinding] = pBuffers[i]; } } static inline void updateResourceTrackingOnDraw(GLOBAL_CB_NODE *pCB) { pCB->drawData.push_back(pCB->currentDrawData); } VKAPI_ATTR void VKAPI_CALL CmdBindVertexBuffers(VkCommandBuffer commandBuffer, uint32_t firstBinding, uint32_t bindingCount, const VkBuffer *pBuffers, const VkDeviceSize *pOffsets) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); // TODO : Somewhere need to verify that VBs have correct usage state flagged std::unique_lock lock(global_lock); auto cb_node = getCBNode(dev_data, commandBuffer); if (cb_node) { for (uint32_t i = 0; i < bindingCount; ++i) { auto buffer_state = getBufferState(dev_data, pBuffers[i]); assert(buffer_state); skip_call |= ValidateMemoryIsBoundToBuffer(dev_data, buffer_state, "vkCmdBindVertexBuffers()"); std::function function = [=]() { return ValidateBufferMemoryIsValid(dev_data, buffer_state, "vkCmdBindVertexBuffers()"); }; cb_node->validate_functions.push_back(function); } addCmd(dev_data, cb_node, CMD_BINDVERTEXBUFFER, "vkCmdBindVertexBuffer()"); updateResourceTracking(cb_node, firstBinding, bindingCount, pBuffers); } else { skip_call |= report_error_no_cb_begin(dev_data, commandBuffer, "vkCmdBindVertexBuffer()"); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdBindVertexBuffers(commandBuffer, firstBinding, bindingCount, pBuffers, pOffsets); } /* expects global_lock to be held by caller */ static bool markStoreImagesAndBuffersAsWritten(layer_data *dev_data, GLOBAL_CB_NODE *pCB) { bool skip_call = false; for (auto imageView : pCB->updateImages) { auto view_state = getImageViewState(dev_data, imageView); if (!view_state) continue; auto image_state = getImageState(dev_data, view_state->create_info.image); assert(image_state); std::function function = [=]() { SetImageMemoryValid(dev_data, image_state, true); return false; }; pCB->validate_functions.push_back(function); } for (auto buffer : pCB->updateBuffers) { auto buffer_state = getBufferState(dev_data, buffer); assert(buffer_state); std::function function = [=]() { SetBufferMemoryValid(dev_data, buffer_state, true); return false; }; pCB->validate_functions.push_back(function); } return skip_call; } VKAPI_ATTR void VKAPI_CALL CmdDraw(VkCommandBuffer commandBuffer, uint32_t vertexCount, uint32_t instanceCount, uint32_t firstVertex, uint32_t firstInstance) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_DRAW, "vkCmdDraw()"); pCB->drawCount[DRAW]++; skip_call |= validate_and_update_draw_state(dev_data, pCB, false, VK_PIPELINE_BIND_POINT_GRAPHICS, "vkCmdDraw"); skip_call |= markStoreImagesAndBuffersAsWritten(dev_data, pCB); // TODO : Need to pass commandBuffer as srcObj here skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, 0, __LINE__, DRAWSTATE_NONE, "DS", "vkCmdDraw() call 0x%" PRIx64 ", reporting descriptor set state:", g_drawCount[DRAW]++); skip_call |= synchAndPrintDSConfig(dev_data, commandBuffer); if (!skip_call) { updateResourceTrackingOnDraw(pCB); } skip_call |= outsideRenderPass(dev_data, pCB, "vkCmdDraw"); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdDraw(commandBuffer, vertexCount, instanceCount, firstVertex, firstInstance); } VKAPI_ATTR void VKAPI_CALL CmdDrawIndexed(VkCommandBuffer commandBuffer, uint32_t indexCount, uint32_t instanceCount, uint32_t firstIndex, int32_t vertexOffset, uint32_t firstInstance) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); bool skip_call = false; std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_DRAWINDEXED, "vkCmdDrawIndexed()"); pCB->drawCount[DRAW_INDEXED]++; skip_call |= validate_and_update_draw_state(dev_data, pCB, true, VK_PIPELINE_BIND_POINT_GRAPHICS, "vkCmdDrawIndexed"); skip_call |= markStoreImagesAndBuffersAsWritten(dev_data, pCB); // TODO : Need to pass commandBuffer as srcObj here skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, 0, __LINE__, DRAWSTATE_NONE, "DS", "vkCmdDrawIndexed() call 0x%" PRIx64 ", reporting descriptor set state:", g_drawCount[DRAW_INDEXED]++); skip_call |= synchAndPrintDSConfig(dev_data, commandBuffer); if (!skip_call) { updateResourceTrackingOnDraw(pCB); } skip_call |= outsideRenderPass(dev_data, pCB, "vkCmdDrawIndexed"); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdDrawIndexed(commandBuffer, indexCount, instanceCount, firstIndex, vertexOffset, firstInstance); } VKAPI_ATTR void VKAPI_CALL CmdDrawIndirect(VkCommandBuffer commandBuffer, VkBuffer buffer, VkDeviceSize offset, uint32_t count, uint32_t stride) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); bool skip_call = false; std::unique_lock lock(global_lock); auto cb_node = getCBNode(dev_data, commandBuffer); auto buffer_state = getBufferState(dev_data, buffer); if (cb_node && buffer_state) { skip_call |= ValidateMemoryIsBoundToBuffer(dev_data, buffer_state, "vkCmdDrawIndirect()"); AddCommandBufferBindingBuffer(dev_data, cb_node, buffer_state); skip_call |= addCmd(dev_data, cb_node, CMD_DRAWINDIRECT, "vkCmdDrawIndirect()"); cb_node->drawCount[DRAW_INDIRECT]++; skip_call |= validate_and_update_draw_state(dev_data, cb_node, false, VK_PIPELINE_BIND_POINT_GRAPHICS, "vkCmdDrawIndirect"); skip_call |= markStoreImagesAndBuffersAsWritten(dev_data, cb_node); // TODO : Need to pass commandBuffer as srcObj here skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, 0, __LINE__, DRAWSTATE_NONE, "DS", "vkCmdDrawIndirect() call 0x%" PRIx64 ", reporting descriptor set state:", g_drawCount[DRAW_INDIRECT]++); skip_call |= synchAndPrintDSConfig(dev_data, commandBuffer); if (!skip_call) { updateResourceTrackingOnDraw(cb_node); } skip_call |= outsideRenderPass(dev_data, cb_node, "vkCmdDrawIndirect()"); } else { assert(0); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdDrawIndirect(commandBuffer, buffer, offset, count, stride); } VKAPI_ATTR void VKAPI_CALL CmdDrawIndexedIndirect(VkCommandBuffer commandBuffer, VkBuffer buffer, VkDeviceSize offset, uint32_t count, uint32_t stride) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); auto cb_node = getCBNode(dev_data, commandBuffer); auto buffer_state = getBufferState(dev_data, buffer); if (cb_node && buffer_state) { skip_call |= ValidateMemoryIsBoundToBuffer(dev_data, buffer_state, "vkCmdDrawIndexedIndirect()"); AddCommandBufferBindingBuffer(dev_data, cb_node, buffer_state); skip_call |= addCmd(dev_data, cb_node, CMD_DRAWINDEXEDINDIRECT, "vkCmdDrawIndexedIndirect()"); cb_node->drawCount[DRAW_INDEXED_INDIRECT]++; skip_call |= validate_and_update_draw_state(dev_data, cb_node, true, VK_PIPELINE_BIND_POINT_GRAPHICS, "vkCmdDrawIndexedIndirect"); skip_call |= markStoreImagesAndBuffersAsWritten(dev_data, cb_node); // TODO : Need to pass commandBuffer as srcObj here skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_INFORMATION_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, 0, __LINE__, DRAWSTATE_NONE, "DS", "vkCmdDrawIndexedIndirect() call 0x%" PRIx64 ", reporting descriptor set state:", g_drawCount[DRAW_INDEXED_INDIRECT]++); skip_call |= synchAndPrintDSConfig(dev_data, commandBuffer); if (!skip_call) { updateResourceTrackingOnDraw(cb_node); } skip_call |= outsideRenderPass(dev_data, cb_node, "vkCmdDrawIndexedIndirect()"); } else { assert(0); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdDrawIndexedIndirect(commandBuffer, buffer, offset, count, stride); } VKAPI_ATTR void VKAPI_CALL CmdDispatch(VkCommandBuffer commandBuffer, uint32_t x, uint32_t y, uint32_t z) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= validate_and_update_draw_state(dev_data, pCB, false, VK_PIPELINE_BIND_POINT_COMPUTE, "vkCmdDispatch"); skip_call |= markStoreImagesAndBuffersAsWritten(dev_data, pCB); skip_call |= addCmd(dev_data, pCB, CMD_DISPATCH, "vkCmdDispatch()"); skip_call |= insideRenderPass(dev_data, pCB, "vkCmdDispatch"); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdDispatch(commandBuffer, x, y, z); } VKAPI_ATTR void VKAPI_CALL CmdDispatchIndirect(VkCommandBuffer commandBuffer, VkBuffer buffer, VkDeviceSize offset) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); auto cb_node = getCBNode(dev_data, commandBuffer); auto buffer_state = getBufferState(dev_data, buffer); if (cb_node && buffer_state) { skip_call |= ValidateMemoryIsBoundToBuffer(dev_data, buffer_state, "vkCmdDispatchIndirect()"); AddCommandBufferBindingBuffer(dev_data, cb_node, buffer_state); skip_call |= validate_and_update_draw_state(dev_data, cb_node, false, VK_PIPELINE_BIND_POINT_COMPUTE, "vkCmdDispatchIndirect"); skip_call |= markStoreImagesAndBuffersAsWritten(dev_data, cb_node); skip_call |= addCmd(dev_data, cb_node, CMD_DISPATCHINDIRECT, "vkCmdDispatchIndirect()"); skip_call |= insideRenderPass(dev_data, cb_node, "vkCmdDispatchIndirect()"); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdDispatchIndirect(commandBuffer, buffer, offset); } VKAPI_ATTR void VKAPI_CALL CmdCopyBuffer(VkCommandBuffer commandBuffer, VkBuffer srcBuffer, VkBuffer dstBuffer, uint32_t regionCount, const VkBufferCopy *pRegions) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); auto cb_node = getCBNode(dev_data, commandBuffer); auto src_buff_state = getBufferState(dev_data, srcBuffer); auto dst_buff_state = getBufferState(dev_data, dstBuffer); if (cb_node && src_buff_state && dst_buff_state) { skip_call |= ValidateMemoryIsBoundToBuffer(dev_data, src_buff_state, "vkCmdCopyBuffer()"); skip_call |= ValidateMemoryIsBoundToBuffer(dev_data, dst_buff_state, "vkCmdCopyBuffer()"); // Update bindings between buffers and cmd buffer AddCommandBufferBindingBuffer(dev_data, cb_node, src_buff_state); AddCommandBufferBindingBuffer(dev_data, cb_node, dst_buff_state); // Validate that SRC & DST buffers have correct usage flags set skip_call |= ValidateBufferUsageFlags(dev_data, src_buff_state, VK_BUFFER_USAGE_TRANSFER_SRC_BIT, true, VALIDATION_ERROR_01164, "vkCmdCopyBuffer()", "VK_BUFFER_USAGE_TRANSFER_SRC_BIT"); skip_call |= ValidateBufferUsageFlags(dev_data, dst_buff_state, VK_BUFFER_USAGE_TRANSFER_DST_BIT, true, VALIDATION_ERROR_01165, "vkCmdCopyBuffer()", "VK_BUFFER_USAGE_TRANSFER_DST_BIT"); std::function function = [=]() { return ValidateBufferMemoryIsValid(dev_data, src_buff_state, "vkCmdCopyBuffer()"); }; cb_node->validate_functions.push_back(function); function = [=]() { SetBufferMemoryValid(dev_data, dst_buff_state, true); return false; }; cb_node->validate_functions.push_back(function); skip_call |= addCmd(dev_data, cb_node, CMD_COPYBUFFER, "vkCmdCopyBuffer()"); skip_call |= insideRenderPass(dev_data, cb_node, "vkCmdCopyBuffer()"); } else { // Param_checker will flag errors on invalid objects, just assert here as debugging aid assert(0); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdCopyBuffer(commandBuffer, srcBuffer, dstBuffer, regionCount, pRegions); } static bool VerifySourceImageLayout(layer_data *dev_data, GLOBAL_CB_NODE *cb_node, VkImage srcImage, VkImageSubresourceLayers subLayers, VkImageLayout srcImageLayout) { bool skip_call = false; for (uint32_t i = 0; i < subLayers.layerCount; ++i) { uint32_t layer = i + subLayers.baseArrayLayer; VkImageSubresource sub = {subLayers.aspectMask, subLayers.mipLevel, layer}; IMAGE_CMD_BUF_LAYOUT_NODE node; if (!FindLayout(cb_node, srcImage, sub, node)) { SetLayout(cb_node, srcImage, sub, IMAGE_CMD_BUF_LAYOUT_NODE(srcImageLayout, srcImageLayout)); continue; } if (node.layout != srcImageLayout) { // TODO: Improve log message in the next pass skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Cannot copy from an image whose source layout is %s " "and doesn't match the current layout %s.", string_VkImageLayout(srcImageLayout), string_VkImageLayout(node.layout)); } } if (srcImageLayout != VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL) { if (srcImageLayout == VK_IMAGE_LAYOUT_GENERAL) { // TODO : Can we deal with image node from the top of call tree and avoid map look-up here? auto image_state = getImageState(dev_data, srcImage); if (image_state->createInfo.tiling != VK_IMAGE_TILING_LINEAR) { // LAYOUT_GENERAL is allowed, but may not be performance optimal, flag as perf warning. skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_PERFORMANCE_WARNING_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Layout for input image should be TRANSFER_SRC_OPTIMAL instead of GENERAL."); } } else { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Layout for input image is %s but can only be " "TRANSFER_SRC_OPTIMAL or GENERAL.", string_VkImageLayout(srcImageLayout)); } } return skip_call; } static bool VerifyDestImageLayout(layer_data *dev_data, GLOBAL_CB_NODE *cb_node, VkImage destImage, VkImageSubresourceLayers subLayers, VkImageLayout destImageLayout) { bool skip_call = false; for (uint32_t i = 0; i < subLayers.layerCount; ++i) { uint32_t layer = i + subLayers.baseArrayLayer; VkImageSubresource sub = {subLayers.aspectMask, subLayers.mipLevel, layer}; IMAGE_CMD_BUF_LAYOUT_NODE node; if (!FindLayout(cb_node, destImage, sub, node)) { SetLayout(cb_node, destImage, sub, IMAGE_CMD_BUF_LAYOUT_NODE(destImageLayout, destImageLayout)); continue; } if (node.layout != destImageLayout) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Cannot copy from an image whose dest layout is %s and " "doesn't match the current layout %s.", string_VkImageLayout(destImageLayout), string_VkImageLayout(node.layout)); } } if (destImageLayout != VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL) { if (destImageLayout == VK_IMAGE_LAYOUT_GENERAL) { auto image_state = getImageState(dev_data, destImage); if (image_state->createInfo.tiling != VK_IMAGE_TILING_LINEAR) { // LAYOUT_GENERAL is allowed, but may not be performance optimal, flag as perf warning. skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_PERFORMANCE_WARNING_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Layout for output image should be TRANSFER_DST_OPTIMAL instead of GENERAL."); } } else { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Layout for output image is %s but can only be " "TRANSFER_DST_OPTIMAL or GENERAL.", string_VkImageLayout(destImageLayout)); } } return skip_call; } // Test if two VkExtent3D structs are equivalent static inline bool IsExtentEqual(const VkExtent3D *extent, const VkExtent3D *other_extent) { bool result = true; if ((extent->width != other_extent->width) || (extent->height != other_extent->height) || (extent->depth != other_extent->depth)) { result = false; } return result; } // Returns the image extent of a specific subresource. static inline VkExtent3D GetImageSubresourceExtent(const IMAGE_STATE *img, const VkImageSubresourceLayers *subresource) { const uint32_t mip = subresource->mipLevel; VkExtent3D extent = img->createInfo.extent; extent.width = std::max(1U, extent.width >> mip); extent.height = std::max(1U, extent.height >> mip); extent.depth = std::max(1U, extent.depth >> mip); return extent; } // Test if the extent argument has all dimensions set to 0. static inline bool IsExtentZero(const VkExtent3D *extent) { return ((extent->width == 0) && (extent->height == 0) && (extent->depth == 0)); } // Returns the image transfer granularity for a specific image scaled by compressed block size if necessary. static inline VkExtent3D GetScaledItg(layer_data *dev_data, const GLOBAL_CB_NODE *cb_node, const IMAGE_STATE *img) { // Default to (0, 0, 0) granularity in case we can't find the real granularity for the physical device. VkExtent3D granularity = { 0, 0, 0 }; auto pPool = getCommandPoolNode(dev_data, cb_node->createInfo.commandPool); if (pPool) { granularity = dev_data->phys_dev_properties.queue_family_properties[pPool->queueFamilyIndex].minImageTransferGranularity; if (vk_format_is_compressed(img->createInfo.format)) { auto block_size = vk_format_compressed_block_size(img->createInfo.format); granularity.width *= block_size.width; granularity.height *= block_size.height; } } return granularity; } // Test elements of a VkExtent3D structure against alignment constraints contained in another VkExtent3D structure static inline bool IsExtentAligned(const VkExtent3D *extent, const VkExtent3D *granularity) { bool valid = true; if ((vk_safe_modulo(extent->depth, granularity->depth) != 0) || (vk_safe_modulo(extent->width, granularity->width) != 0) || (vk_safe_modulo(extent->height, granularity->height) != 0)) { valid = false; } return valid; } // Check elements of a VkOffset3D structure against a queue family's Image Transfer Granularity values static inline bool CheckItgOffset(layer_data *dev_data, const GLOBAL_CB_NODE *cb_node, const VkOffset3D *offset, const VkExtent3D *granularity, const uint32_t i, const char *function, const char *member) { bool skip = false; VkExtent3D offset_extent = {}; offset_extent.width = static_cast(abs(offset->x)); offset_extent.height = static_cast(abs(offset->y)); offset_extent.depth = static_cast(abs(offset->z)); if (IsExtentZero(granularity)) { // If the queue family image transfer granularity is (0, 0, 0), then the offset must always be (0, 0, 0) if (IsExtentZero(&offset_extent) == false) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_IMAGE_TRANSFER_GRANULARITY, "DS", "%s: pRegion[%d].%s (x=%d, y=%d, z=%d) must be (x=0, y=0, z=0) " "when the command buffer's queue family image transfer granularity is (w=0, h=0, d=0).", function, i, member, offset->x, offset->y, offset->z); } } else { // If the queue family image transfer granularity is not (0, 0, 0), then the offset dimensions must always be even // integer multiples of the image transfer granularity. if (IsExtentAligned(&offset_extent, granularity) == false) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_IMAGE_TRANSFER_GRANULARITY, "DS", "%s: pRegion[%d].%s (x=%d, y=%d, z=%d) dimensions must be even integer " "multiples of this command buffer's queue family image transfer granularity (w=%d, h=%d, d=%d).", function, i, member, offset->x, offset->y, offset->z, granularity->width, granularity->height, granularity->depth); } } return skip; } // Check elements of a VkExtent3D structure against a queue family's Image Transfer Granularity values static inline bool CheckItgExtent(layer_data *dev_data, const GLOBAL_CB_NODE *cb_node, const VkExtent3D *extent, const VkOffset3D *offset, const VkExtent3D *granularity, const VkExtent3D *subresource_extent, const uint32_t i, const char *function, const char *member) { bool skip = false; if (IsExtentZero(granularity)) { // If the queue family image transfer granularity is (0, 0, 0), then the extent must always match the image // subresource extent. if (IsExtentEqual(extent, subresource_extent) == false) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_IMAGE_TRANSFER_GRANULARITY, "DS", "%s: pRegion[%d].%s (w=%d, h=%d, d=%d) must match the image subresource extents (w=%d, h=%d, d=%d) " "when the command buffer's queue family image transfer granularity is (w=0, h=0, d=0).", function, i, member, extent->width, extent->height, extent->depth, subresource_extent->width, subresource_extent->height, subresource_extent->depth); } } else { // If the queue family image transfer granularity is not (0, 0, 0), then the extent dimensions must always be even // integer multiples of the image transfer granularity or the offset + extent dimensions must always match the image // subresource extent dimensions. VkExtent3D offset_extent_sum = {}; offset_extent_sum.width = static_cast(abs(offset->x)) + extent->width; offset_extent_sum.height = static_cast(abs(offset->y)) + extent->height; offset_extent_sum.depth = static_cast(abs(offset->z)) + extent->depth; if ((IsExtentAligned(extent, granularity) == false) && (IsExtentEqual(&offset_extent_sum, subresource_extent) == false)) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_IMAGE_TRANSFER_GRANULARITY, "DS", "%s: pRegion[%d].%s (w=%d, h=%d, d=%d) dimensions must be even integer multiples of this command buffer's " "queue family image transfer granularity (w=%d, h=%d, d=%d) or offset (x=%d, y=%d, z=%d) + " "extent (w=%d, h=%d, d=%d) must match the image subresource extents (w=%d, h=%d, d=%d).", function, i, member, extent->width, extent->height, extent->depth, granularity->width, granularity->height, granularity->depth, offset->x, offset->y, offset->z, extent->width, extent->height, extent->depth, subresource_extent->width, subresource_extent->height, subresource_extent->depth); } } return skip; } // Check a uint32_t width or stride value against a queue family's Image Transfer Granularity width value static inline bool CheckItgInt(layer_data *dev_data, const GLOBAL_CB_NODE *cb_node, const uint32_t value, const uint32_t granularity, const uint32_t i, const char *function, const char *member) { bool skip = false; if (vk_safe_modulo(value, granularity) != 0) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_IMAGE_TRANSFER_GRANULARITY, "DS", "%s: pRegion[%d].%s (%d) must be an even integer multiple of this command buffer's queue family image " "transfer granularity width (%d).", function, i, member, value, granularity); } return skip; } // Check a VkDeviceSize value against a queue family's Image Transfer Granularity width value static inline bool CheckItgSize(layer_data *dev_data, const GLOBAL_CB_NODE *cb_node, const VkDeviceSize value, const uint32_t granularity, const uint32_t i, const char *function, const char *member) { bool skip = false; if (vk_safe_modulo(value, granularity) != 0) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_IMAGE_TRANSFER_GRANULARITY, "DS", "%s: pRegion[%d].%s (%" PRIdLEAST64 ") must be an even integer multiple of this command buffer's queue family image transfer " "granularity width (%d).", function, i, member, value, granularity); } return skip; } // Check valid usage Image Tranfer Granularity requirements for elements of a VkImageCopy structure static inline bool ValidateCopyImageTransferGranularityRequirements(layer_data *dev_data, const GLOBAL_CB_NODE *cb_node, const IMAGE_STATE *img, const VkImageCopy *region, const uint32_t i, const char *function) { bool skip = false; VkExtent3D granularity = GetScaledItg(dev_data, cb_node, img); skip |= CheckItgOffset(dev_data, cb_node, ®ion->srcOffset, &granularity, i, function, "srcOffset"); skip |= CheckItgOffset(dev_data, cb_node, ®ion->dstOffset, &granularity, i, function, "dstOffset"); VkExtent3D subresource_extent = GetImageSubresourceExtent(img, ®ion->dstSubresource); skip |= CheckItgExtent(dev_data, cb_node, ®ion->extent, ®ion->dstOffset, &granularity, &subresource_extent, i, function, "extent"); return skip; } // Check valid usage Image Tranfer Granularity requirements for elements of a VkBufferImageCopy structure static inline bool ValidateCopyBufferImageTransferGranularityRequirements(layer_data *dev_data, const GLOBAL_CB_NODE *cb_node, const IMAGE_STATE *img, const VkBufferImageCopy *region, const uint32_t i, const char *function) { bool skip = false; VkExtent3D granularity = GetScaledItg(dev_data, cb_node, img); skip |= CheckItgSize(dev_data, cb_node, region->bufferOffset, granularity.width, i, function, "bufferOffset"); skip |= CheckItgInt(dev_data, cb_node, region->bufferRowLength, granularity.width, i, function, "bufferRowLength"); skip |= CheckItgInt(dev_data, cb_node, region->bufferImageHeight, granularity.width, i, function, "bufferImageHeight"); skip |= CheckItgOffset(dev_data, cb_node, ®ion->imageOffset, &granularity, i, function, "imageOffset"); VkExtent3D subresource_extent = GetImageSubresourceExtent(img, ®ion->imageSubresource); skip |= CheckItgExtent(dev_data, cb_node, ®ion->imageExtent, ®ion->imageOffset, &granularity, &subresource_extent, i, function, "imageExtent"); return skip; } VKAPI_ATTR void VKAPI_CALL CmdCopyImage(VkCommandBuffer commandBuffer, VkImage srcImage, VkImageLayout srcImageLayout, VkImage dstImage, VkImageLayout dstImageLayout, uint32_t regionCount, const VkImageCopy *pRegions) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); auto cb_node = getCBNode(dev_data, commandBuffer); auto src_image_state = getImageState(dev_data, srcImage); auto dst_image_state = getImageState(dev_data, dstImage); if (cb_node && src_image_state && dst_image_state) { skip_call |= ValidateMemoryIsBoundToImage(dev_data, src_image_state, "vkCmdCopyImage()"); skip_call |= ValidateMemoryIsBoundToImage(dev_data, dst_image_state, "vkCmdCopyImage()"); // Update bindings between images and cmd buffer AddCommandBufferBindingImage(dev_data, cb_node, src_image_state); AddCommandBufferBindingImage(dev_data, cb_node, dst_image_state); // Validate that SRC & DST images have correct usage flags set skip_call |= ValidateImageUsageFlags(dev_data, src_image_state, VK_IMAGE_USAGE_TRANSFER_SRC_BIT, true, VALIDATION_ERROR_01178, "vkCmdCopyImage()", "VK_IMAGE_USAGE_TRANSFER_SRC_BIT"); skip_call |= ValidateImageUsageFlags(dev_data, dst_image_state, VK_IMAGE_USAGE_TRANSFER_DST_BIT, true, VALIDATION_ERROR_01181, "vkCmdCopyImage()", "VK_IMAGE_USAGE_TRANSFER_DST_BIT"); std::function function = [=]() { return ValidateImageMemoryIsValid(dev_data, src_image_state, "vkCmdCopyImage()"); }; cb_node->validate_functions.push_back(function); function = [=]() { SetImageMemoryValid(dev_data, dst_image_state, true); return false; }; cb_node->validate_functions.push_back(function); skip_call |= addCmd(dev_data, cb_node, CMD_COPYIMAGE, "vkCmdCopyImage()"); skip_call |= insideRenderPass(dev_data, cb_node, "vkCmdCopyImage()"); for (uint32_t i = 0; i < regionCount; ++i) { skip_call |= VerifySourceImageLayout(dev_data, cb_node, srcImage, pRegions[i].srcSubresource, srcImageLayout); skip_call |= VerifyDestImageLayout(dev_data, cb_node, dstImage, pRegions[i].dstSubresource, dstImageLayout); skip_call |= ValidateCopyImageTransferGranularityRequirements(dev_data, cb_node, dst_image_state, &pRegions[i], i, "vkCmdCopyImage()"); } } else { assert(0); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdCopyImage(commandBuffer, srcImage, srcImageLayout, dstImage, dstImageLayout, regionCount, pRegions); } // Validate that an image's sampleCount matches the requirement for a specific API call static inline bool ValidateImageSampleCount(layer_data *dev_data, IMAGE_STATE *image_state, VkSampleCountFlagBits sample_count, const char *location) { bool skip = false; if (image_state->createInfo.samples != sample_count) { skip = log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, reinterpret_cast(image_state->image), 0, DRAWSTATE_NUM_SAMPLES_MISMATCH, "DS", "%s for image 0x%" PRIxLEAST64 " was created with a sample count of %s but must be %s.", location, reinterpret_cast(image_state->image), string_VkSampleCountFlagBits(image_state->createInfo.samples), string_VkSampleCountFlagBits(sample_count)); } return skip; } VKAPI_ATTR void VKAPI_CALL CmdBlitImage(VkCommandBuffer commandBuffer, VkImage srcImage, VkImageLayout srcImageLayout, VkImage dstImage, VkImageLayout dstImageLayout, uint32_t regionCount, const VkImageBlit *pRegions, VkFilter filter) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); auto cb_node = getCBNode(dev_data, commandBuffer); auto src_image_state = getImageState(dev_data, srcImage); auto dst_image_state = getImageState(dev_data, dstImage); if (cb_node && src_image_state && dst_image_state) { skip_call |= ValidateImageSampleCount(dev_data, src_image_state, VK_SAMPLE_COUNT_1_BIT, "vkCmdBlitImage(): srcImage"); skip_call |= ValidateImageSampleCount(dev_data, dst_image_state, VK_SAMPLE_COUNT_1_BIT, "vkCmdBlitImage(): dstImage"); skip_call |= ValidateMemoryIsBoundToImage(dev_data, src_image_state, "vkCmdBlitImage()"); skip_call |= ValidateMemoryIsBoundToImage(dev_data, dst_image_state, "vkCmdBlitImage()"); // Update bindings between images and cmd buffer AddCommandBufferBindingImage(dev_data, cb_node, src_image_state); AddCommandBufferBindingImage(dev_data, cb_node, dst_image_state); // Validate that SRC & DST images have correct usage flags set skip_call |= ValidateImageUsageFlags(dev_data, src_image_state, VK_IMAGE_USAGE_TRANSFER_SRC_BIT, true, VALIDATION_ERROR_02182, "vkCmdBlitImage()", "VK_IMAGE_USAGE_TRANSFER_SRC_BIT"); skip_call |= ValidateImageUsageFlags(dev_data, dst_image_state, VK_IMAGE_USAGE_TRANSFER_DST_BIT, true, VALIDATION_ERROR_02186, "vkCmdBlitImage()", "VK_IMAGE_USAGE_TRANSFER_DST_BIT"); std::function function = [=]() { return ValidateImageMemoryIsValid(dev_data, src_image_state, "vkCmdBlitImage()"); }; cb_node->validate_functions.push_back(function); function = [=]() { SetImageMemoryValid(dev_data, dst_image_state, true); return false; }; cb_node->validate_functions.push_back(function); skip_call |= addCmd(dev_data, cb_node, CMD_BLITIMAGE, "vkCmdBlitImage()"); skip_call |= insideRenderPass(dev_data, cb_node, "vkCmdBlitImage()"); } else { assert(0); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdBlitImage(commandBuffer, srcImage, srcImageLayout, dstImage, dstImageLayout, regionCount, pRegions, filter); } VKAPI_ATTR void VKAPI_CALL CmdCopyBufferToImage(VkCommandBuffer commandBuffer, VkBuffer srcBuffer, VkImage dstImage, VkImageLayout dstImageLayout, uint32_t regionCount, const VkBufferImageCopy *pRegions) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); auto cb_node = getCBNode(dev_data, commandBuffer); auto src_buff_state = getBufferState(dev_data, srcBuffer); auto dst_image_state = getImageState(dev_data, dstImage); if (cb_node && src_buff_state && dst_image_state) { skip_call |= ValidateImageSampleCount(dev_data, dst_image_state, VK_SAMPLE_COUNT_1_BIT, "vkCmdCopyBufferToImage(): dstImage"); skip_call |= ValidateMemoryIsBoundToBuffer(dev_data, src_buff_state, "vkCmdCopyBufferToImage()"); skip_call |= ValidateMemoryIsBoundToImage(dev_data, dst_image_state, "vkCmdCopyBufferToImage()"); AddCommandBufferBindingBuffer(dev_data, cb_node, src_buff_state); AddCommandBufferBindingImage(dev_data, cb_node, dst_image_state); skip_call |= ValidateBufferUsageFlags(dev_data, src_buff_state, VK_BUFFER_USAGE_TRANSFER_SRC_BIT, true, VALIDATION_ERROR_01230, "vkCmdCopyBufferToImage()", "VK_BUFFER_USAGE_TRANSFER_SRC_BIT"); skip_call |= ValidateImageUsageFlags(dev_data, dst_image_state, VK_IMAGE_USAGE_TRANSFER_DST_BIT, true, VALIDATION_ERROR_01231, "vkCmdCopyBufferToImage()", "VK_IMAGE_USAGE_TRANSFER_DST_BIT"); std::function function = [=]() { SetImageMemoryValid(dev_data, dst_image_state, true); return false; }; cb_node->validate_functions.push_back(function); function = [=]() { return ValidateBufferMemoryIsValid(dev_data, src_buff_state, "vkCmdCopyBufferToImage()"); }; cb_node->validate_functions.push_back(function); skip_call |= addCmd(dev_data, cb_node, CMD_COPYBUFFERTOIMAGE, "vkCmdCopyBufferToImage()"); skip_call |= insideRenderPass(dev_data, cb_node, "vkCmdCopyBufferToImage()"); for (uint32_t i = 0; i < regionCount; ++i) { skip_call |= VerifyDestImageLayout(dev_data, cb_node, dstImage, pRegions[i].imageSubresource, dstImageLayout); skip_call |= ValidateCopyBufferImageTransferGranularityRequirements(dev_data, cb_node, dst_image_state, &pRegions[i], i, "vkCmdCopyBufferToImage()"); } } else { assert(0); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdCopyBufferToImage(commandBuffer, srcBuffer, dstImage, dstImageLayout, regionCount, pRegions); } VKAPI_ATTR void VKAPI_CALL CmdCopyImageToBuffer(VkCommandBuffer commandBuffer, VkImage srcImage, VkImageLayout srcImageLayout, VkBuffer dstBuffer, uint32_t regionCount, const VkBufferImageCopy *pRegions) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); auto cb_node = getCBNode(dev_data, commandBuffer); auto src_image_state = getImageState(dev_data, srcImage); auto dst_buff_state = getBufferState(dev_data, dstBuffer); if (cb_node && src_image_state && dst_buff_state) { skip_call |= ValidateImageSampleCount(dev_data, src_image_state, VK_SAMPLE_COUNT_1_BIT, "vkCmdCopyImageToBuffer(): srcImage"); skip_call |= ValidateMemoryIsBoundToImage(dev_data, src_image_state, "vkCmdCopyImageToBuffer()"); skip_call |= ValidateMemoryIsBoundToBuffer(dev_data, dst_buff_state, "vkCmdCopyImageToBuffer()"); // Update bindings between buffer/image and cmd buffer AddCommandBufferBindingImage(dev_data, cb_node, src_image_state); AddCommandBufferBindingBuffer(dev_data, cb_node, dst_buff_state); // Validate that SRC image & DST buffer have correct usage flags set skip_call |= ValidateImageUsageFlags(dev_data, src_image_state, VK_IMAGE_USAGE_TRANSFER_SRC_BIT, true, VALIDATION_ERROR_01248, "vkCmdCopyImageToBuffer()", "VK_IMAGE_USAGE_TRANSFER_SRC_BIT"); skip_call |= ValidateBufferUsageFlags(dev_data, dst_buff_state, VK_BUFFER_USAGE_TRANSFER_DST_BIT, true, VALIDATION_ERROR_01252, "vkCmdCopyImageToBuffer()", "VK_BUFFER_USAGE_TRANSFER_DST_BIT"); std::function function = [=]() { return ValidateImageMemoryIsValid(dev_data, src_image_state, "vkCmdCopyImageToBuffer()"); }; cb_node->validate_functions.push_back(function); function = [=]() { SetBufferMemoryValid(dev_data, dst_buff_state, true); return false; }; cb_node->validate_functions.push_back(function); skip_call |= addCmd(dev_data, cb_node, CMD_COPYIMAGETOBUFFER, "vkCmdCopyImageToBuffer()"); skip_call |= insideRenderPass(dev_data, cb_node, "vkCmdCopyImageToBuffer()"); for (uint32_t i = 0; i < regionCount; ++i) { skip_call |= VerifySourceImageLayout(dev_data, cb_node, srcImage, pRegions[i].imageSubresource, srcImageLayout); skip_call |= ValidateCopyBufferImageTransferGranularityRequirements(dev_data, cb_node, src_image_state, &pRegions[i], i, "CmdCopyImageToBuffer"); } } else { assert(0); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdCopyImageToBuffer(commandBuffer, srcImage, srcImageLayout, dstBuffer, regionCount, pRegions); } VKAPI_ATTR void VKAPI_CALL CmdUpdateBuffer(VkCommandBuffer commandBuffer, VkBuffer dstBuffer, VkDeviceSize dstOffset, VkDeviceSize dataSize, const uint32_t *pData) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); auto cb_node = getCBNode(dev_data, commandBuffer); auto dst_buff_state = getBufferState(dev_data, dstBuffer); if (cb_node && dst_buff_state) { skip_call |= ValidateMemoryIsBoundToBuffer(dev_data, dst_buff_state, "vkCmdUpdateBuffer()"); // Update bindings between buffer and cmd buffer AddCommandBufferBindingBuffer(dev_data, cb_node, dst_buff_state); // Validate that DST buffer has correct usage flags set skip_call |= ValidateBufferUsageFlags(dev_data, dst_buff_state, VK_BUFFER_USAGE_TRANSFER_DST_BIT, true, VALIDATION_ERROR_01146, "vkCmdUpdateBuffer()", "VK_BUFFER_USAGE_TRANSFER_DST_BIT"); std::function function = [=]() { SetBufferMemoryValid(dev_data, dst_buff_state, true); return false; }; cb_node->validate_functions.push_back(function); skip_call |= addCmd(dev_data, cb_node, CMD_UPDATEBUFFER, "vkCmdUpdateBuffer()"); skip_call |= insideRenderPass(dev_data, cb_node, "vkCmdCopyUpdateBuffer()"); } else { assert(0); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdUpdateBuffer(commandBuffer, dstBuffer, dstOffset, dataSize, pData); } VKAPI_ATTR void VKAPI_CALL CmdFillBuffer(VkCommandBuffer commandBuffer, VkBuffer dstBuffer, VkDeviceSize dstOffset, VkDeviceSize size, uint32_t data) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); auto cb_node = getCBNode(dev_data, commandBuffer); auto dst_buff_state = getBufferState(dev_data, dstBuffer); if (cb_node && dst_buff_state) { skip_call |= ValidateMemoryIsBoundToBuffer(dev_data, dst_buff_state, "vkCmdFillBuffer()"); // Update bindings between buffer and cmd buffer AddCommandBufferBindingBuffer(dev_data, cb_node, dst_buff_state); // Validate that DST buffer has correct usage flags set skip_call |= ValidateBufferUsageFlags(dev_data, dst_buff_state, VK_BUFFER_USAGE_TRANSFER_DST_BIT, true, VALIDATION_ERROR_01137, "vkCmdFillBuffer()", "VK_BUFFER_USAGE_TRANSFER_DST_BIT"); std::function function = [=]() { SetBufferMemoryValid(dev_data, dst_buff_state, true); return false; }; cb_node->validate_functions.push_back(function); skip_call |= addCmd(dev_data, cb_node, CMD_FILLBUFFER, "vkCmdFillBuffer()"); skip_call |= insideRenderPass(dev_data, cb_node, "vkCmdCopyFillBuffer()"); } else { assert(0); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdFillBuffer(commandBuffer, dstBuffer, dstOffset, size, data); } VKAPI_ATTR void VKAPI_CALL CmdClearAttachments(VkCommandBuffer commandBuffer, uint32_t attachmentCount, const VkClearAttachment *pAttachments, uint32_t rectCount, const VkClearRect *pRects) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_CLEARATTACHMENTS, "vkCmdClearAttachments()"); // Warn if this is issued prior to Draw Cmd and clearing the entire attachment if (!hasDrawCmd(pCB) && (pCB->activeRenderPassBeginInfo.renderArea.extent.width == pRects[0].rect.extent.width) && (pCB->activeRenderPassBeginInfo.renderArea.extent.height == pRects[0].rect.extent.height)) { // There are times where app needs to use ClearAttachments (generally when reusing a buffer inside of a render pass) // Can we make this warning more specific? I'd like to avoid triggering this test if we can tell it's a use that must // call CmdClearAttachments // Otherwise this seems more like a performance warning. skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_PERFORMANCE_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(commandBuffer), 0, DRAWSTATE_CLEAR_CMD_BEFORE_DRAW, "DS", "vkCmdClearAttachments() issued on command buffer object 0x%" PRIxLEAST64 " prior to any Draw Cmds." " It is recommended you use RenderPass LOAD_OP_CLEAR on Attachments prior to any Draw.", (uint64_t)(commandBuffer)); } skip_call |= outsideRenderPass(dev_data, pCB, "vkCmdClearAttachments()"); } // Validate that attachment is in reference list of active subpass if (pCB->activeRenderPass) { const VkRenderPassCreateInfo *pRPCI = pCB->activeRenderPass->createInfo.ptr(); const VkSubpassDescription *pSD = &pRPCI->pSubpasses[pCB->activeSubpass]; auto framebuffer = getFramebufferState(dev_data, pCB->activeFramebuffer); for (uint32_t i = 0; i < attachmentCount; i++) { auto clear_desc = &pAttachments[i]; VkImageView image_view = VK_NULL_HANDLE; if (clear_desc->aspectMask & VK_IMAGE_ASPECT_COLOR_BIT) { if (clear_desc->colorAttachment >= pSD->colorAttachmentCount) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)commandBuffer, __LINE__, VALIDATION_ERROR_01114, "DS", "vkCmdClearAttachments() color attachment index %d out of range for active subpass %d. %s", clear_desc->colorAttachment, pCB->activeSubpass, validation_error_map[VALIDATION_ERROR_01114]); } else if (pSD->pColorAttachments[clear_desc->colorAttachment].attachment == VK_ATTACHMENT_UNUSED) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_PERFORMANCE_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)commandBuffer, __LINE__, DRAWSTATE_MISSING_ATTACHMENT_REFERENCE, "DS", "vkCmdClearAttachments() color attachment index %d is VK_ATTACHMENT_UNUSED; ignored.", clear_desc->colorAttachment); } else { image_view = framebuffer->createInfo.pAttachments[pSD->pColorAttachments[clear_desc->colorAttachment].attachment]; } } else if (clear_desc->aspectMask & (VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT)) { if (!pSD->pDepthStencilAttachment || // Says no DS will be used in active subpass (pSD->pDepthStencilAttachment->attachment == VK_ATTACHMENT_UNUSED)) { // Says no DS will be used in active subpass skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_PERFORMANCE_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)commandBuffer, __LINE__, DRAWSTATE_MISSING_ATTACHMENT_REFERENCE, "DS", "vkCmdClearAttachments() depth/stencil clear with no depth/stencil attachment in subpass; ignored"); } else { image_view = framebuffer->createInfo.pAttachments[pSD->pDepthStencilAttachment->attachment]; } } if (image_view) { auto image_view_state = getImageViewState(dev_data, image_view); auto aspects_present = image_view_state->create_info.subresourceRange.aspectMask; auto extra_aspects = clear_desc->aspectMask & ~aspects_present; if (extra_aspects) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_VIEW_EXT, reinterpret_cast(image_view), __LINE__, VALIDATION_ERROR_01125, "DS", "vkCmdClearAttachments() with aspects not present in image view: %s. %s", string_VkImageAspectFlagBits((VkImageAspectFlagBits)extra_aspects), validation_error_map[VALIDATION_ERROR_01125]); } } } } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdClearAttachments(commandBuffer, attachmentCount, pAttachments, rectCount, pRects); } VKAPI_ATTR void VKAPI_CALL CmdClearColorImage(VkCommandBuffer commandBuffer, VkImage image, VkImageLayout imageLayout, const VkClearColorValue *pColor, uint32_t rangeCount, const VkImageSubresourceRange *pRanges) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); // TODO : Verify memory is in VK_IMAGE_STATE_CLEAR state auto cb_node = getCBNode(dev_data, commandBuffer); auto image_state = getImageState(dev_data, image); if (cb_node && image_state) { skip_call |= ValidateMemoryIsBoundToImage(dev_data, image_state, "vkCmdClearColorImage()"); AddCommandBufferBindingImage(dev_data, cb_node, image_state); std::function function = [=]() { SetImageMemoryValid(dev_data, image_state, true); return false; }; cb_node->validate_functions.push_back(function); skip_call |= addCmd(dev_data, cb_node, CMD_CLEARCOLORIMAGE, "vkCmdClearColorImage()"); skip_call |= insideRenderPass(dev_data, cb_node, "vkCmdClearColorImage()"); } else { assert(0); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdClearColorImage(commandBuffer, image, imageLayout, pColor, rangeCount, pRanges); } VKAPI_ATTR void VKAPI_CALL CmdClearDepthStencilImage(VkCommandBuffer commandBuffer, VkImage image, VkImageLayout imageLayout, const VkClearDepthStencilValue *pDepthStencil, uint32_t rangeCount, const VkImageSubresourceRange *pRanges) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); // TODO : Verify memory is in VK_IMAGE_STATE_CLEAR state auto cb_node = getCBNode(dev_data, commandBuffer); auto image_state = getImageState(dev_data, image); if (cb_node && image_state) { skip_call |= ValidateMemoryIsBoundToImage(dev_data, image_state, "vkCmdClearDepthStencilImage()"); AddCommandBufferBindingImage(dev_data, cb_node, image_state); std::function function = [=]() { SetImageMemoryValid(dev_data, image_state, true); return false; }; cb_node->validate_functions.push_back(function); skip_call |= addCmd(dev_data, cb_node, CMD_CLEARDEPTHSTENCILIMAGE, "vkCmdClearDepthStencilImage()"); skip_call |= insideRenderPass(dev_data, cb_node, "vkCmdClearDepthStencilImage()"); } else { assert(0); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdClearDepthStencilImage(commandBuffer, image, imageLayout, pDepthStencil, rangeCount, pRanges); } VKAPI_ATTR void VKAPI_CALL CmdResolveImage(VkCommandBuffer commandBuffer, VkImage srcImage, VkImageLayout srcImageLayout, VkImage dstImage, VkImageLayout dstImageLayout, uint32_t regionCount, const VkImageResolve *pRegions) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); auto cb_node = getCBNode(dev_data, commandBuffer); auto src_image_state = getImageState(dev_data, srcImage); auto dst_image_state = getImageState(dev_data, dstImage); if (cb_node && src_image_state && dst_image_state) { skip_call |= ValidateMemoryIsBoundToImage(dev_data, src_image_state, "vkCmdResolveImage()"); skip_call |= ValidateMemoryIsBoundToImage(dev_data, dst_image_state, "vkCmdResolveImage()"); // Update bindings between images and cmd buffer AddCommandBufferBindingImage(dev_data, cb_node, src_image_state); AddCommandBufferBindingImage(dev_data, cb_node, dst_image_state); std::function function = [=]() { return ValidateImageMemoryIsValid(dev_data, src_image_state, "vkCmdResolveImage()"); }; cb_node->validate_functions.push_back(function); function = [=]() { SetImageMemoryValid(dev_data, dst_image_state, true); return false; }; cb_node->validate_functions.push_back(function); skip_call |= addCmd(dev_data, cb_node, CMD_RESOLVEIMAGE, "vkCmdResolveImage()"); skip_call |= insideRenderPass(dev_data, cb_node, "vkCmdResolveImage()"); } else { assert(0); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdResolveImage(commandBuffer, srcImage, srcImageLayout, dstImage, dstImageLayout, regionCount, pRegions); } bool setEventStageMask(VkQueue queue, VkCommandBuffer commandBuffer, VkEvent event, VkPipelineStageFlags stageMask) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { pCB->eventToStageMap[event] = stageMask; } auto queue_data = dev_data->queueMap.find(queue); if (queue_data != dev_data->queueMap.end()) { queue_data->second.eventToStageMap[event] = stageMask; } return false; } VKAPI_ATTR void VKAPI_CALL CmdSetEvent(VkCommandBuffer commandBuffer, VkEvent event, VkPipelineStageFlags stageMask) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_SETEVENT, "vkCmdSetEvent()"); skip_call |= insideRenderPass(dev_data, pCB, "vkCmdSetEvent"); auto event_state = getEventNode(dev_data, event); if (event_state) { addCommandBufferBinding(&event_state->cb_bindings, {reinterpret_cast(event), VK_DEBUG_REPORT_OBJECT_TYPE_EVENT_EXT}, pCB); event_state->cb_bindings.insert(pCB); } pCB->events.push_back(event); if (!pCB->waitedEvents.count(event)) { pCB->writeEventsBeforeWait.push_back(event); } std::function eventUpdate = std::bind(setEventStageMask, std::placeholders::_1, commandBuffer, event, stageMask); pCB->eventUpdates.push_back(eventUpdate); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdSetEvent(commandBuffer, event, stageMask); } VKAPI_ATTR void VKAPI_CALL CmdResetEvent(VkCommandBuffer commandBuffer, VkEvent event, VkPipelineStageFlags stageMask) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_RESETEVENT, "vkCmdResetEvent()"); skip_call |= insideRenderPass(dev_data, pCB, "vkCmdResetEvent"); auto event_state = getEventNode(dev_data, event); if (event_state) { addCommandBufferBinding(&event_state->cb_bindings, {reinterpret_cast(event), VK_DEBUG_REPORT_OBJECT_TYPE_EVENT_EXT}, pCB); event_state->cb_bindings.insert(pCB); } pCB->events.push_back(event); if (!pCB->waitedEvents.count(event)) { pCB->writeEventsBeforeWait.push_back(event); } std::function eventUpdate = std::bind(setEventStageMask, std::placeholders::_1, commandBuffer, event, VkPipelineStageFlags(0)); pCB->eventUpdates.push_back(eventUpdate); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdResetEvent(commandBuffer, event, stageMask); } static bool TransitionImageLayouts(VkCommandBuffer cmdBuffer, uint32_t memBarrierCount, const VkImageMemoryBarrier *pImgMemBarriers) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(cmdBuffer), layer_data_map); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, cmdBuffer); bool skip = false; uint32_t levelCount = 0; uint32_t layerCount = 0; for (uint32_t i = 0; i < memBarrierCount; ++i) { auto mem_barrier = &pImgMemBarriers[i]; if (!mem_barrier) continue; // TODO: Do not iterate over every possibility - consolidate where // possible ResolveRemainingLevelsLayers(dev_data, &levelCount, &layerCount, mem_barrier->subresourceRange, mem_barrier->image); for (uint32_t j = 0; j < levelCount; j++) { uint32_t level = mem_barrier->subresourceRange.baseMipLevel + j; for (uint32_t k = 0; k < layerCount; k++) { uint32_t layer = mem_barrier->subresourceRange.baseArrayLayer + k; VkImageSubresource sub = {mem_barrier->subresourceRange.aspectMask, level, layer}; IMAGE_CMD_BUF_LAYOUT_NODE node; if (!FindLayout(pCB, mem_barrier->image, sub, node)) { SetLayout(pCB, mem_barrier->image, sub, IMAGE_CMD_BUF_LAYOUT_NODE(mem_barrier->oldLayout, mem_barrier->newLayout)); continue; } if (mem_barrier->oldLayout == VK_IMAGE_LAYOUT_UNDEFINED) { // TODO: Set memory invalid which is in mem_tracker currently } else if (node.layout != mem_barrier->oldLayout) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "You cannot transition the layout from %s " "when current layout is %s.", string_VkImageLayout(mem_barrier->oldLayout), string_VkImageLayout(node.layout)); } SetLayout(pCB, mem_barrier->image, sub, mem_barrier->newLayout); } } } return skip; } // Print readable FlagBits in FlagMask static std::string string_VkAccessFlags(VkAccessFlags accessMask) { std::string result; std::string separator; if (accessMask == 0) { result = "[None]"; } else { result = "["; for (auto i = 0; i < 32; i++) { if (accessMask & (1 << i)) { result = result + separator + string_VkAccessFlagBits((VkAccessFlagBits)(1 << i)); separator = " | "; } } result = result + "]"; } return result; } // AccessFlags MUST have 'required_bit' set, and may have one or more of 'optional_bits' set. // If required_bit is zero, accessMask must have at least one of 'optional_bits' set // TODO: Add tracking to ensure that at least one barrier has been set for these layout transitions static bool ValidateMaskBits(const layer_data *my_data, VkCommandBuffer cmdBuffer, const VkAccessFlags &accessMask, const VkImageLayout &layout, VkAccessFlags required_bit, VkAccessFlags optional_bits, const char *type) { bool skip_call = false; if ((accessMask & required_bit) || (!required_bit && (accessMask & optional_bits))) { if (accessMask & ~(required_bit | optional_bits)) { // TODO: Verify against Valid Use skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_BARRIER, "DS", "Additional bits in %s accessMask 0x%X %s are specified when layout is %s.", type, accessMask, string_VkAccessFlags(accessMask).c_str(), string_VkImageLayout(layout)); } } else { if (!required_bit) { skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_BARRIER, "DS", "%s AccessMask %d %s must contain at least one of access bits %d " "%s when layout is %s, unless the app has previously added a " "barrier for this transition.", type, accessMask, string_VkAccessFlags(accessMask).c_str(), optional_bits, string_VkAccessFlags(optional_bits).c_str(), string_VkImageLayout(layout)); } else { std::string opt_bits; if (optional_bits != 0) { std::stringstream ss; ss << optional_bits; opt_bits = "and may have optional bits " + ss.str() + ' ' + string_VkAccessFlags(optional_bits); } skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_BARRIER, "DS", "%s AccessMask %d %s must have required access bit %d %s %s when " "layout is %s, unless the app has previously added a barrier for " "this transition.", type, accessMask, string_VkAccessFlags(accessMask).c_str(), required_bit, string_VkAccessFlags(required_bit).c_str(), opt_bits.c_str(), string_VkImageLayout(layout)); } } return skip_call; } static bool ValidateMaskBitsFromLayouts(const layer_data *my_data, VkCommandBuffer cmdBuffer, const VkAccessFlags &accessMask, const VkImageLayout &layout, const char *type) { bool skip_call = false; switch (layout) { case VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL: { skip_call |= ValidateMaskBits(my_data, cmdBuffer, accessMask, layout, VK_ACCESS_COLOR_ATTACHMENT_WRITE_BIT, VK_ACCESS_COLOR_ATTACHMENT_READ_BIT | VK_ACCESS_INPUT_ATTACHMENT_READ_BIT, type); break; } case VK_IMAGE_LAYOUT_DEPTH_STENCIL_ATTACHMENT_OPTIMAL: { skip_call |= ValidateMaskBits(my_data, cmdBuffer, accessMask, layout, VK_ACCESS_DEPTH_STENCIL_ATTACHMENT_WRITE_BIT, VK_ACCESS_DEPTH_STENCIL_ATTACHMENT_READ_BIT | VK_ACCESS_INPUT_ATTACHMENT_READ_BIT, type); break; } case VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL: { skip_call |= ValidateMaskBits(my_data, cmdBuffer, accessMask, layout, VK_ACCESS_TRANSFER_WRITE_BIT, 0, type); break; } case VK_IMAGE_LAYOUT_DEPTH_STENCIL_READ_ONLY_OPTIMAL: { skip_call |= ValidateMaskBits(my_data, cmdBuffer, accessMask, layout, 0, VK_ACCESS_DEPTH_STENCIL_ATTACHMENT_READ_BIT | VK_ACCESS_SHADER_READ_BIT | VK_ACCESS_INPUT_ATTACHMENT_READ_BIT, type); break; } case VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL: { skip_call |= ValidateMaskBits(my_data, cmdBuffer, accessMask, layout, 0, VK_ACCESS_INPUT_ATTACHMENT_READ_BIT | VK_ACCESS_SHADER_READ_BIT, type); break; } case VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL: { skip_call |= ValidateMaskBits(my_data, cmdBuffer, accessMask, layout, VK_ACCESS_TRANSFER_READ_BIT, 0, type); break; } case VK_IMAGE_LAYOUT_PRESENT_SRC_KHR: { skip_call |= ValidateMaskBits(my_data, cmdBuffer, accessMask, layout, VK_ACCESS_MEMORY_READ_BIT, 0, type); break; } case VK_IMAGE_LAYOUT_UNDEFINED: { if (accessMask != 0) { // TODO: Verify against Valid Use section spec skip_call |= log_msg(my_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_BARRIER, "DS", "Additional bits in %s accessMask 0x%X %s are specified when layout is %s.", type, accessMask, string_VkAccessFlags(accessMask).c_str(), string_VkImageLayout(layout)); } break; } case VK_IMAGE_LAYOUT_GENERAL: default: { break; } } return skip_call; } static bool ValidateBarriers(const char *funcName, VkCommandBuffer cmdBuffer, uint32_t memBarrierCount, const VkMemoryBarrier *pMemBarriers, uint32_t bufferBarrierCount, const VkBufferMemoryBarrier *pBufferMemBarriers, uint32_t imageMemBarrierCount, const VkImageMemoryBarrier *pImageMemBarriers) { bool skip = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(cmdBuffer), layer_data_map); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, cmdBuffer); if (pCB->activeRenderPass && memBarrierCount) { if (!pCB->activeRenderPass->hasSelfDependency[pCB->activeSubpass]) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_BARRIER, "DS", "%s: Barriers cannot be set during subpass %d " "with no self dependency specified.", funcName, pCB->activeSubpass); } } for (uint32_t i = 0; i < imageMemBarrierCount; ++i) { auto mem_barrier = &pImageMemBarriers[i]; auto image_data = getImageState(dev_data, mem_barrier->image); if (image_data) { uint32_t src_q_f_index = mem_barrier->srcQueueFamilyIndex; uint32_t dst_q_f_index = mem_barrier->dstQueueFamilyIndex; if (image_data->createInfo.sharingMode == VK_SHARING_MODE_CONCURRENT) { // srcQueueFamilyIndex and dstQueueFamilyIndex must both // be VK_QUEUE_FAMILY_IGNORED if ((src_q_f_index != VK_QUEUE_FAMILY_IGNORED) || (dst_q_f_index != VK_QUEUE_FAMILY_IGNORED)) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_QUEUE_INDEX, "DS", "%s: Image Barrier for image 0x%" PRIx64 " was created with sharingMode of " "VK_SHARING_MODE_CONCURRENT. Src and dst " "queueFamilyIndices must be VK_QUEUE_FAMILY_IGNORED.", funcName, reinterpret_cast(mem_barrier->image)); } } else { // Sharing mode is VK_SHARING_MODE_EXCLUSIVE. srcQueueFamilyIndex and // dstQueueFamilyIndex must either both be VK_QUEUE_FAMILY_IGNORED, // or both be a valid queue family if (((src_q_f_index == VK_QUEUE_FAMILY_IGNORED) || (dst_q_f_index == VK_QUEUE_FAMILY_IGNORED)) && (src_q_f_index != dst_q_f_index)) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_QUEUE_INDEX, "DS", "%s: Image 0x%" PRIx64 " was created with sharingMode " "of VK_SHARING_MODE_EXCLUSIVE. If one of src- or " "dstQueueFamilyIndex is VK_QUEUE_FAMILY_IGNORED, both " "must be.", funcName, reinterpret_cast(mem_barrier->image)); } else if (((src_q_f_index != VK_QUEUE_FAMILY_IGNORED) && (dst_q_f_index != VK_QUEUE_FAMILY_IGNORED)) && ((src_q_f_index >= dev_data->phys_dev_properties.queue_family_properties.size()) || (dst_q_f_index >= dev_data->phys_dev_properties.queue_family_properties.size()))) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_QUEUE_INDEX, "DS", "%s: Image 0x%" PRIx64 " was created with sharingMode " "of VK_SHARING_MODE_EXCLUSIVE, but srcQueueFamilyIndex %d" " or dstQueueFamilyIndex %d is greater than " PRINTF_SIZE_T_SPECIFIER "queueFamilies crated for this device.", funcName, reinterpret_cast(mem_barrier->image), src_q_f_index, dst_q_f_index, dev_data->phys_dev_properties.queue_family_properties.size()); } } } if (mem_barrier) { if (mem_barrier->oldLayout != mem_barrier->newLayout) { skip |= ValidateMaskBitsFromLayouts(dev_data, cmdBuffer, mem_barrier->srcAccessMask, mem_barrier->oldLayout, "Source"); skip |= ValidateMaskBitsFromLayouts(dev_data, cmdBuffer, mem_barrier->dstAccessMask, mem_barrier->newLayout, "Dest"); } if (mem_barrier->newLayout == VK_IMAGE_LAYOUT_UNDEFINED || mem_barrier->newLayout == VK_IMAGE_LAYOUT_PREINITIALIZED) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_BARRIER, "DS", "%s: Image Layout cannot be transitioned to UNDEFINED or " "PREINITIALIZED.", funcName); } auto image_data = getImageState(dev_data, mem_barrier->image); VkFormat format = VK_FORMAT_UNDEFINED; uint32_t arrayLayers = 0, mipLevels = 0; bool imageFound = false; if (image_data) { format = image_data->createInfo.format; arrayLayers = image_data->createInfo.arrayLayers; mipLevels = image_data->createInfo.mipLevels; imageFound = true; } else if (dev_data->device_extensions.wsi_enabled) { auto imageswap_data = getSwapchainFromImage(dev_data, mem_barrier->image); if (imageswap_data) { auto swapchain_data = getSwapchainNode(dev_data, imageswap_data); if (swapchain_data) { format = swapchain_data->createInfo.imageFormat; arrayLayers = swapchain_data->createInfo.imageArrayLayers; mipLevels = 1; imageFound = true; } } } if (imageFound) { auto aspect_mask = mem_barrier->subresourceRange.aspectMask; skip |= ValidateImageAspectMask(dev_data, image_data->image, format, aspect_mask, funcName); int layerCount = (mem_barrier->subresourceRange.layerCount == VK_REMAINING_ARRAY_LAYERS) ? 1 : mem_barrier->subresourceRange.layerCount; if ((mem_barrier->subresourceRange.baseArrayLayer + layerCount) > arrayLayers) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_BARRIER, "DS", "%s: Subresource must have the sum of the " "baseArrayLayer (%d) and layerCount (%d) be less " "than or equal to the total number of layers (%d).", funcName, mem_barrier->subresourceRange.baseArrayLayer, mem_barrier->subresourceRange.layerCount, arrayLayers); } int levelCount = (mem_barrier->subresourceRange.levelCount == VK_REMAINING_MIP_LEVELS) ? 1 : mem_barrier->subresourceRange.levelCount; if ((mem_barrier->subresourceRange.baseMipLevel + levelCount) > mipLevels) { skip |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_BARRIER, "DS", "%s: Subresource must have the sum of the baseMipLevel " "(%d) and levelCount (%d) be less than or equal to " "the total number of levels (%d).", funcName, mem_barrier->subresourceRange.baseMipLevel, mem_barrier->subresourceRange.levelCount, mipLevels); } } } } for (uint32_t i = 0; i < bufferBarrierCount; ++i) { auto mem_barrier = &pBufferMemBarriers[i]; if (pCB->activeRenderPass) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_BARRIER, "DS", "%s: Buffer Barriers cannot be used during a render pass.", funcName); } if (!mem_barrier) continue; // Validate buffer barrier queue family indices if ((mem_barrier->srcQueueFamilyIndex != VK_QUEUE_FAMILY_IGNORED && mem_barrier->srcQueueFamilyIndex >= dev_data->phys_dev_properties.queue_family_properties.size()) || (mem_barrier->dstQueueFamilyIndex != VK_QUEUE_FAMILY_IGNORED && mem_barrier->dstQueueFamilyIndex >= dev_data->phys_dev_properties.queue_family_properties.size())) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_QUEUE_INDEX, "DS", "%s: Buffer Barrier 0x%" PRIx64 " has QueueFamilyIndex greater " "than the number of QueueFamilies (" PRINTF_SIZE_T_SPECIFIER ") for this device.", funcName, reinterpret_cast(mem_barrier->buffer), dev_data->phys_dev_properties.queue_family_properties.size()); } auto buffer_state = getBufferState(dev_data, mem_barrier->buffer); if (buffer_state) { auto buffer_size = buffer_state->requirements.size; if (mem_barrier->offset >= buffer_size) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_BARRIER, "DS", "%s: Buffer Barrier 0x%" PRIx64 " has offset 0x%" PRIx64 " which is not less than total size 0x%" PRIx64 ".", funcName, reinterpret_cast(mem_barrier->buffer), reinterpret_cast(mem_barrier->offset), reinterpret_cast(buffer_size)); } else if (mem_barrier->size != VK_WHOLE_SIZE && (mem_barrier->offset + mem_barrier->size > buffer_size)) { skip |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_BARRIER, "DS", "%s: Buffer Barrier 0x%" PRIx64 " has offset 0x%" PRIx64 " and size 0x%" PRIx64 " whose sum is greater than total size 0x%" PRIx64 ".", funcName, reinterpret_cast(mem_barrier->buffer), reinterpret_cast(mem_barrier->offset), reinterpret_cast(mem_barrier->size), reinterpret_cast(buffer_size)); } } } return skip; } bool validateEventStageMask(VkQueue queue, GLOBAL_CB_NODE *pCB, uint32_t eventCount, size_t firstEventIndex, VkPipelineStageFlags sourceStageMask) { bool skip_call = false; VkPipelineStageFlags stageMask = 0; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(queue), layer_data_map); for (uint32_t i = 0; i < eventCount; ++i) { auto event = pCB->events[firstEventIndex + i]; auto queue_data = dev_data->queueMap.find(queue); if (queue_data == dev_data->queueMap.end()) return false; auto event_data = queue_data->second.eventToStageMap.find(event); if (event_data != queue_data->second.eventToStageMap.end()) { stageMask |= event_data->second; } else { auto global_event_data = getEventNode(dev_data, event); if (!global_event_data) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_EVENT_EXT, reinterpret_cast(event), __LINE__, DRAWSTATE_INVALID_EVENT, "DS", "Event 0x%" PRIx64 " cannot be waited on if it has never been set.", reinterpret_cast(event)); } else { stageMask |= global_event_data->stageMask; } } } // TODO: Need to validate that host_bit is only set if set event is called // but set event can be called at any time. if (sourceStageMask != stageMask && sourceStageMask != (stageMask | VK_PIPELINE_STAGE_HOST_BIT)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_EVENT, "DS", "Submitting cmdbuffer with call to VkCmdWaitEvents " "using srcStageMask 0x%X which must be the bitwise " "OR of the stageMask parameters used in calls to " "vkCmdSetEvent and VK_PIPELINE_STAGE_HOST_BIT if " "used with vkSetEvent but instead is 0x%X.", sourceStageMask, stageMask); } return skip_call; } VKAPI_ATTR void VKAPI_CALL CmdWaitEvents(VkCommandBuffer commandBuffer, uint32_t eventCount, const VkEvent *pEvents, VkPipelineStageFlags sourceStageMask, VkPipelineStageFlags dstStageMask, uint32_t memoryBarrierCount, const VkMemoryBarrier *pMemoryBarriers, uint32_t bufferMemoryBarrierCount, const VkBufferMemoryBarrier *pBufferMemoryBarriers, uint32_t imageMemoryBarrierCount, const VkImageMemoryBarrier *pImageMemoryBarriers) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { auto firstEventIndex = pCB->events.size(); for (uint32_t i = 0; i < eventCount; ++i) { auto event_state = getEventNode(dev_data, pEvents[i]); if (event_state) { addCommandBufferBinding(&event_state->cb_bindings, {reinterpret_cast(pEvents[i]), VK_DEBUG_REPORT_OBJECT_TYPE_EVENT_EXT}, pCB); event_state->cb_bindings.insert(pCB); } pCB->waitedEvents.insert(pEvents[i]); pCB->events.push_back(pEvents[i]); } std::function eventUpdate = std::bind(validateEventStageMask, std::placeholders::_1, pCB, eventCount, firstEventIndex, sourceStageMask); pCB->eventUpdates.push_back(eventUpdate); if (pCB->state == CB_RECORDING) { skip_call |= addCmd(dev_data, pCB, CMD_WAITEVENTS, "vkCmdWaitEvents()"); } else { skip_call |= report_error_no_cb_begin(dev_data, commandBuffer, "vkCmdWaitEvents()"); } skip_call |= TransitionImageLayouts(commandBuffer, imageMemoryBarrierCount, pImageMemoryBarriers); skip_call |= ValidateBarriers("vkCmdWaitEvents", commandBuffer, memoryBarrierCount, pMemoryBarriers, bufferMemoryBarrierCount, pBufferMemoryBarriers, imageMemoryBarrierCount, pImageMemoryBarriers); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdWaitEvents(commandBuffer, eventCount, pEvents, sourceStageMask, dstStageMask, memoryBarrierCount, pMemoryBarriers, bufferMemoryBarrierCount, pBufferMemoryBarriers, imageMemoryBarrierCount, pImageMemoryBarriers); } VKAPI_ATTR void VKAPI_CALL CmdPipelineBarrier(VkCommandBuffer commandBuffer, VkPipelineStageFlags srcStageMask, VkPipelineStageFlags dstStageMask, VkDependencyFlags dependencyFlags, uint32_t memoryBarrierCount, const VkMemoryBarrier *pMemoryBarriers, uint32_t bufferMemoryBarrierCount, const VkBufferMemoryBarrier *pBufferMemoryBarriers, uint32_t imageMemoryBarrierCount, const VkImageMemoryBarrier *pImageMemoryBarriers) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= addCmd(dev_data, pCB, CMD_PIPELINEBARRIER, "vkCmdPipelineBarrier()"); skip_call |= TransitionImageLayouts(commandBuffer, imageMemoryBarrierCount, pImageMemoryBarriers); skip_call |= ValidateBarriers("vkCmdPipelineBarrier", commandBuffer, memoryBarrierCount, pMemoryBarriers, bufferMemoryBarrierCount, pBufferMemoryBarriers, imageMemoryBarrierCount, pImageMemoryBarriers); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdPipelineBarrier(commandBuffer, srcStageMask, dstStageMask, dependencyFlags, memoryBarrierCount, pMemoryBarriers, bufferMemoryBarrierCount, pBufferMemoryBarriers, imageMemoryBarrierCount, pImageMemoryBarriers); } bool setQueryState(VkQueue queue, VkCommandBuffer commandBuffer, QueryObject object, bool value) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { pCB->queryToStateMap[object] = value; } auto queue_data = dev_data->queueMap.find(queue); if (queue_data != dev_data->queueMap.end()) { queue_data->second.queryToStateMap[object] = value; } return false; } VKAPI_ATTR void VKAPI_CALL CmdBeginQuery(VkCommandBuffer commandBuffer, VkQueryPool queryPool, uint32_t slot, VkFlags flags) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { QueryObject query = {queryPool, slot}; pCB->activeQueries.insert(query); if (!pCB->startedQueries.count(query)) { pCB->startedQueries.insert(query); } skip_call |= addCmd(dev_data, pCB, CMD_BEGINQUERY, "vkCmdBeginQuery()"); addCommandBufferBinding(&getQueryPoolNode(dev_data, queryPool)->cb_bindings, {reinterpret_cast(queryPool), VK_DEBUG_REPORT_OBJECT_TYPE_QUERY_POOL_EXT}, pCB); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdBeginQuery(commandBuffer, queryPool, slot, flags); } VKAPI_ATTR void VKAPI_CALL CmdEndQuery(VkCommandBuffer commandBuffer, VkQueryPool queryPool, uint32_t slot) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { QueryObject query = {queryPool, slot}; if (!pCB->activeQueries.count(query)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_QUERY, "DS", "Ending a query before it was started: queryPool 0x%" PRIx64 ", index %d", (uint64_t)(queryPool), slot); } else { pCB->activeQueries.erase(query); } std::function queryUpdate = std::bind(setQueryState, std::placeholders::_1, commandBuffer, query, true); pCB->queryUpdates.push_back(queryUpdate); if (pCB->state == CB_RECORDING) { skip_call |= addCmd(dev_data, pCB, CMD_ENDQUERY, "VkCmdEndQuery()"); } else { skip_call |= report_error_no_cb_begin(dev_data, commandBuffer, "vkCmdEndQuery()"); } addCommandBufferBinding(&getQueryPoolNode(dev_data, queryPool)->cb_bindings, {reinterpret_cast(queryPool), VK_DEBUG_REPORT_OBJECT_TYPE_QUERY_POOL_EXT}, pCB); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdEndQuery(commandBuffer, queryPool, slot); } VKAPI_ATTR void VKAPI_CALL CmdResetQueryPool(VkCommandBuffer commandBuffer, VkQueryPool queryPool, uint32_t firstQuery, uint32_t queryCount) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { for (uint32_t i = 0; i < queryCount; i++) { QueryObject query = {queryPool, firstQuery + i}; pCB->waitedEventsBeforeQueryReset[query] = pCB->waitedEvents; std::function queryUpdate = std::bind(setQueryState, std::placeholders::_1, commandBuffer, query, false); pCB->queryUpdates.push_back(queryUpdate); } if (pCB->state == CB_RECORDING) { skip_call |= addCmd(dev_data, pCB, CMD_RESETQUERYPOOL, "VkCmdResetQueryPool()"); } else { skip_call |= report_error_no_cb_begin(dev_data, commandBuffer, "vkCmdResetQueryPool()"); } skip_call |= insideRenderPass(dev_data, pCB, "vkCmdQueryPool"); addCommandBufferBinding(&getQueryPoolNode(dev_data, queryPool)->cb_bindings, {reinterpret_cast(queryPool), VK_DEBUG_REPORT_OBJECT_TYPE_QUERY_POOL_EXT}, pCB); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdResetQueryPool(commandBuffer, queryPool, firstQuery, queryCount); } bool validateQuery(VkQueue queue, GLOBAL_CB_NODE *pCB, VkQueryPool queryPool, uint32_t queryCount, uint32_t firstQuery) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(pCB->commandBuffer), layer_data_map); auto queue_data = dev_data->queueMap.find(queue); if (queue_data == dev_data->queueMap.end()) return false; for (uint32_t i = 0; i < queryCount; i++) { QueryObject query = {queryPool, firstQuery + i}; auto query_data = queue_data->second.queryToStateMap.find(query); bool fail = false; if (query_data != queue_data->second.queryToStateMap.end()) { if (!query_data->second) { fail = true; } } else { auto global_query_data = dev_data->queryToStateMap.find(query); if (global_query_data != dev_data->queryToStateMap.end()) { if (!global_query_data->second) { fail = true; } } else { fail = true; } } if (fail) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_QUERY, "DS", "Requesting a copy from query to buffer with invalid query: queryPool 0x%" PRIx64 ", index %d", reinterpret_cast(queryPool), firstQuery + i); } } return skip_call; } VKAPI_ATTR void VKAPI_CALL CmdCopyQueryPoolResults(VkCommandBuffer commandBuffer, VkQueryPool queryPool, uint32_t firstQuery, uint32_t queryCount, VkBuffer dstBuffer, VkDeviceSize dstOffset, VkDeviceSize stride, VkQueryResultFlags flags) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); auto cb_node = getCBNode(dev_data, commandBuffer); auto dst_buff_state = getBufferState(dev_data, dstBuffer); if (cb_node && dst_buff_state) { skip_call |= ValidateMemoryIsBoundToBuffer(dev_data, dst_buff_state, "vkCmdCopyQueryPoolResults()"); // Update bindings between buffer and cmd buffer AddCommandBufferBindingBuffer(dev_data, cb_node, dst_buff_state); // Validate that DST buffer has correct usage flags set skip_call |= ValidateBufferUsageFlags(dev_data, dst_buff_state, VK_BUFFER_USAGE_TRANSFER_DST_BIT, true, VALIDATION_ERROR_01066, "vkCmdCopyQueryPoolResults()", "VK_BUFFER_USAGE_TRANSFER_DST_BIT"); std::function function = [=]() { SetBufferMemoryValid(dev_data, dst_buff_state, true); return false; }; cb_node->validate_functions.push_back(function); std::function queryUpdate = std::bind(validateQuery, std::placeholders::_1, cb_node, queryPool, queryCount, firstQuery); cb_node->queryUpdates.push_back(queryUpdate); if (cb_node->state == CB_RECORDING) { skip_call |= addCmd(dev_data, cb_node, CMD_COPYQUERYPOOLRESULTS, "vkCmdCopyQueryPoolResults()"); } else { skip_call |= report_error_no_cb_begin(dev_data, commandBuffer, "vkCmdCopyQueryPoolResults()"); } skip_call |= insideRenderPass(dev_data, cb_node, "vkCmdCopyQueryPoolResults()"); addCommandBufferBinding(&getQueryPoolNode(dev_data, queryPool)->cb_bindings, {reinterpret_cast(queryPool), VK_DEBUG_REPORT_OBJECT_TYPE_QUERY_POOL_EXT}, cb_node); } else { assert(0); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdCopyQueryPoolResults(commandBuffer, queryPool, firstQuery, queryCount, dstBuffer, dstOffset, stride, flags); } VKAPI_ATTR void VKAPI_CALL CmdPushConstants(VkCommandBuffer commandBuffer, VkPipelineLayout layout, VkShaderStageFlags stageFlags, uint32_t offset, uint32_t size, const void *pValues) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { if (pCB->state == CB_RECORDING) { skip_call |= addCmd(dev_data, pCB, CMD_PUSHCONSTANTS, "vkCmdPushConstants()"); } else { skip_call |= report_error_no_cb_begin(dev_data, commandBuffer, "vkCmdPushConstants()"); } } skip_call |= validatePushConstantRange(dev_data, offset, size, "vkCmdPushConstants()"); if (0 == stageFlags) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_PUSH_CONSTANTS_ERROR, "DS", "vkCmdPushConstants() call has no stageFlags set."); } // Check if push constant update is within any of the ranges with the same stage flags specified in pipeline layout. auto pipeline_layout = getPipelineLayout(dev_data, layout); // Coalesce adjacent/overlapping pipeline ranges before checking to see if incoming range is // contained in the pipeline ranges. // Build a {start, end} span list for ranges with matching stage flags. const auto &ranges = pipeline_layout->push_constant_ranges; struct span { uint32_t start; uint32_t end; }; std::vector spans; spans.reserve(ranges.size()); for (const auto &iter : ranges) { if (iter.stageFlags == stageFlags) { spans.push_back({iter.offset, iter.offset + iter.size}); } } if (spans.size() == 0) { // There were no ranges that matched the stageFlags. skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_PUSH_CONSTANTS_ERROR, "DS", "vkCmdPushConstants() stageFlags = 0x%" PRIx32 " do not match " "the stageFlags in any of the ranges in pipeline layout 0x%" PRIx64 ".", (uint32_t)stageFlags, (uint64_t)layout); } else { // Sort span list by start value. struct comparer { bool operator()(struct span i, struct span j) { return i.start < j.start; } } my_comparer; std::sort(spans.begin(), spans.end(), my_comparer); // Examine two spans at a time. std::vector::iterator current = spans.begin(); std::vector::iterator next = current + 1; while (next != spans.end()) { if (current->end < next->start) { // There is a gap; cannot coalesce. Move to the next two spans. ++current; ++next; } else { // Coalesce the two spans. The start of the next span // is within the current span, so pick the larger of // the end values to extend the current span. // Then delete the next span and set next to the span after it. current->end = max(current->end, next->end); next = spans.erase(next); } } // Now we can check if the incoming range is within any of the spans. bool contained_in_a_range = false; for (uint32_t i = 0; i < spans.size(); ++i) { if ((offset >= spans[i].start) && ((uint64_t)offset + (uint64_t)size <= (uint64_t)spans[i].end)) { contained_in_a_range = true; break; } } if (!contained_in_a_range) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_PUSH_CONSTANTS_ERROR, "DS", "vkCmdPushConstants() Push constant range [%d, %d) " "with stageFlags = 0x%" PRIx32 " " "not within flag-matching ranges in pipeline layout 0x%" PRIx64 ".", offset, offset + size, (uint32_t)stageFlags, (uint64_t)layout); } } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdPushConstants(commandBuffer, layout, stageFlags, offset, size, pValues); } VKAPI_ATTR void VKAPI_CALL CmdWriteTimestamp(VkCommandBuffer commandBuffer, VkPipelineStageFlagBits pipelineStage, VkQueryPool queryPool, uint32_t slot) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { QueryObject query = {queryPool, slot}; std::function queryUpdate = std::bind(setQueryState, std::placeholders::_1, commandBuffer, query, true); pCB->queryUpdates.push_back(queryUpdate); if (pCB->state == CB_RECORDING) { skip_call |= addCmd(dev_data, pCB, CMD_WRITETIMESTAMP, "vkCmdWriteTimestamp()"); } else { skip_call |= report_error_no_cb_begin(dev_data, commandBuffer, "vkCmdWriteTimestamp()"); } } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdWriteTimestamp(commandBuffer, pipelineStage, queryPool, slot); } static bool MatchUsage(layer_data *dev_data, uint32_t count, const VkAttachmentReference *attachments, const VkFramebufferCreateInfo *fbci, VkImageUsageFlagBits usage_flag) { bool skip_call = false; for (uint32_t attach = 0; attach < count; attach++) { if (attachments[attach].attachment != VK_ATTACHMENT_UNUSED) { // Attachment counts are verified elsewhere, but prevent an invalid access if (attachments[attach].attachment < fbci->attachmentCount) { const VkImageView *image_view = &fbci->pAttachments[attachments[attach].attachment]; auto view_state = getImageViewState(dev_data, *image_view); if (view_state) { const VkImageCreateInfo *ici = &getImageState(dev_data, view_state->create_info.image)->createInfo; if (ici != nullptr) { if ((ici->usage & usage_flag) == 0) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_USAGE, "DS", "vkCreateFramebuffer: Framebuffer Attachment (%d) conflicts with the image's " "IMAGE_USAGE flags (%s).", attachments[attach].attachment, string_VkImageUsageFlagBits(usage_flag)); } } } } } } return skip_call; } // Validate VkFramebufferCreateInfo which includes: // 1. attachmentCount equals renderPass attachmentCount // 2. corresponding framebuffer and renderpass attachments have matching formats // 3. corresponding framebuffer and renderpass attachments have matching sample counts // 4. fb attachments only have a single mip level // 5. fb attachment dimensions are each at least as large as the fb // 6. fb attachments use idenity swizzle // 7. fb attachments used by renderPass for color/input/ds have correct usage bit set // 8. fb dimensions are within physical device limits static bool ValidateFramebufferCreateInfo(layer_data *dev_data, const VkFramebufferCreateInfo *pCreateInfo) { bool skip_call = false; auto rp_state = getRenderPassState(dev_data, pCreateInfo->renderPass); if (rp_state) { const VkRenderPassCreateInfo *rpci = rp_state->createInfo.ptr(); if (rpci->attachmentCount != pCreateInfo->attachmentCount) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_RENDER_PASS_EXT, reinterpret_cast(pCreateInfo->renderPass), __LINE__, DRAWSTATE_RENDERPASS_INCOMPATIBLE, "DS", "vkCreateFramebuffer(): VkFramebufferCreateInfo attachmentCount of %u does not match attachmentCount of %u of " "renderPass (0x%" PRIxLEAST64 ") being used to create Framebuffer.", pCreateInfo->attachmentCount, rpci->attachmentCount, reinterpret_cast(pCreateInfo->renderPass)); } else { // attachmentCounts match, so make sure corresponding attachment details line up const VkImageView *image_views = pCreateInfo->pAttachments; for (uint32_t i = 0; i < pCreateInfo->attachmentCount; ++i) { auto view_state = getImageViewState(dev_data, image_views[i]); auto &ivci = view_state->create_info; if (ivci.format != rpci->pAttachments[i].format) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_RENDER_PASS_EXT, reinterpret_cast(pCreateInfo->renderPass), __LINE__, DRAWSTATE_RENDERPASS_INCOMPATIBLE, "DS", "vkCreateFramebuffer(): VkFramebufferCreateInfo attachment #%u has format of %s that does not match " "the format of " "%s used by the corresponding attachment for renderPass (0x%" PRIxLEAST64 ").", i, string_VkFormat(ivci.format), string_VkFormat(rpci->pAttachments[i].format), reinterpret_cast(pCreateInfo->renderPass)); } const VkImageCreateInfo *ici = &getImageState(dev_data, ivci.image)->createInfo; if (ici->samples != rpci->pAttachments[i].samples) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_RENDER_PASS_EXT, reinterpret_cast(pCreateInfo->renderPass), __LINE__, DRAWSTATE_RENDERPASS_INCOMPATIBLE, "DS", "vkCreateFramebuffer(): VkFramebufferCreateInfo attachment #%u has %s samples that do not match " "the %s samples used by the corresponding attachment for renderPass (0x%" PRIxLEAST64 ").", i, string_VkSampleCountFlagBits(ici->samples), string_VkSampleCountFlagBits(rpci->pAttachments[i].samples), reinterpret_cast(pCreateInfo->renderPass)); } // Verify that view only has a single mip level if (ivci.subresourceRange.levelCount != 1) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, DRAWSTATE_INVALID_FRAMEBUFFER_CREATE_INFO, "DS", "vkCreateFramebuffer(): VkFramebufferCreateInfo attachment #%u has mip levelCount of %u " "but only a single mip level (levelCount == 1) is allowed when creating a Framebuffer.", i, ivci.subresourceRange.levelCount); } const uint32_t mip_level = ivci.subresourceRange.baseMipLevel; uint32_t mip_width = max(1u, ici->extent.width >> mip_level); uint32_t mip_height = max(1u, ici->extent.height >> mip_level); if ((ivci.subresourceRange.layerCount < pCreateInfo->layers) || (mip_width < pCreateInfo->width) || (mip_height < pCreateInfo->height)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, DRAWSTATE_INVALID_FRAMEBUFFER_CREATE_INFO, "DS", "vkCreateFramebuffer(): VkFramebufferCreateInfo attachment #%u mip level %u has dimensions smaller " "than the corresponding " "framebuffer dimensions. Attachment dimensions must be at least as large. Here are the respective " "dimensions for " "attachment #%u, framebuffer:\n" "width: %u, %u\n" "height: %u, %u\n" "layerCount: %u, %u\n", i, ivci.subresourceRange.baseMipLevel, i, mip_width, pCreateInfo->width, mip_height, pCreateInfo->height, ivci.subresourceRange.layerCount, pCreateInfo->layers); } if (((ivci.components.r != VK_COMPONENT_SWIZZLE_IDENTITY) && (ivci.components.r != VK_COMPONENT_SWIZZLE_R)) || ((ivci.components.g != VK_COMPONENT_SWIZZLE_IDENTITY) && (ivci.components.g != VK_COMPONENT_SWIZZLE_G)) || ((ivci.components.b != VK_COMPONENT_SWIZZLE_IDENTITY) && (ivci.components.b != VK_COMPONENT_SWIZZLE_B)) || ((ivci.components.a != VK_COMPONENT_SWIZZLE_IDENTITY) && (ivci.components.a != VK_COMPONENT_SWIZZLE_A))) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, DRAWSTATE_INVALID_FRAMEBUFFER_CREATE_INFO, "DS", "vkCreateFramebuffer(): VkFramebufferCreateInfo attachment #%u has non-identy swizzle. All framebuffer " "attachments must have been created with the identity swizzle. Here are the actual swizzle values:\n" "r swizzle = %s\n" "g swizzle = %s\n" "b swizzle = %s\n" "a swizzle = %s\n", i, string_VkComponentSwizzle(ivci.components.r), string_VkComponentSwizzle(ivci.components.g), string_VkComponentSwizzle(ivci.components.b), string_VkComponentSwizzle(ivci.components.a)); } } } // Verify correct attachment usage flags for (uint32_t subpass = 0; subpass < rpci->subpassCount; subpass++) { // Verify input attachments: skip_call |= MatchUsage(dev_data, rpci->pSubpasses[subpass].inputAttachmentCount, rpci->pSubpasses[subpass].pInputAttachments, pCreateInfo, VK_IMAGE_USAGE_INPUT_ATTACHMENT_BIT); // Verify color attachments: skip_call |= MatchUsage(dev_data, rpci->pSubpasses[subpass].colorAttachmentCount, rpci->pSubpasses[subpass].pColorAttachments, pCreateInfo, VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT); // Verify depth/stencil attachments: if (rpci->pSubpasses[subpass].pDepthStencilAttachment != nullptr) { skip_call |= MatchUsage(dev_data, 1, rpci->pSubpasses[subpass].pDepthStencilAttachment, pCreateInfo, VK_IMAGE_USAGE_DEPTH_STENCIL_ATTACHMENT_BIT); } } } else { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_RENDER_PASS_EXT, reinterpret_cast(pCreateInfo->renderPass), __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "vkCreateFramebuffer(): Attempt to create framebuffer with invalid renderPass (0x%" PRIxLEAST64 ").", reinterpret_cast(pCreateInfo->renderPass)); } // Verify FB dimensions are within physical device limits if ((pCreateInfo->height > dev_data->phys_dev_properties.properties.limits.maxFramebufferHeight) || (pCreateInfo->width > dev_data->phys_dev_properties.properties.limits.maxFramebufferWidth) || (pCreateInfo->layers > dev_data->phys_dev_properties.properties.limits.maxFramebufferLayers)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, DRAWSTATE_INVALID_FRAMEBUFFER_CREATE_INFO, "DS", "vkCreateFramebuffer(): Requested VkFramebufferCreateInfo dimensions exceed physical device limits. " "Here are the respective dimensions: requested, device max:\n" "width: %u, %u\n" "height: %u, %u\n" "layerCount: %u, %u\n", pCreateInfo->width, dev_data->phys_dev_properties.properties.limits.maxFramebufferWidth, pCreateInfo->height, dev_data->phys_dev_properties.properties.limits.maxFramebufferHeight, pCreateInfo->layers, dev_data->phys_dev_properties.properties.limits.maxFramebufferLayers); } return skip_call; } // Validate VkFramebufferCreateInfo state prior to calling down chain to create Framebuffer object // Return true if an error is encountered and callback returns true to skip call down chain // false indicates that call down chain should proceed static bool PreCallValidateCreateFramebuffer(layer_data *dev_data, const VkFramebufferCreateInfo *pCreateInfo) { // TODO : Verify that renderPass FB is created with is compatible with FB bool skip_call = false; skip_call |= ValidateFramebufferCreateInfo(dev_data, pCreateInfo); return skip_call; } // CreateFramebuffer state has been validated and call down chain completed so record new framebuffer object static void PostCallRecordCreateFramebuffer(layer_data *dev_data, const VkFramebufferCreateInfo *pCreateInfo, VkFramebuffer fb) { // Shadow create info and store in map std::unique_ptr fb_state( new FRAMEBUFFER_STATE(fb, pCreateInfo, dev_data->renderPassMap[pCreateInfo->renderPass]->createInfo.ptr())); for (uint32_t i = 0; i < pCreateInfo->attachmentCount; ++i) { VkImageView view = pCreateInfo->pAttachments[i]; auto view_state = getImageViewState(dev_data, view); if (!view_state) { continue; } MT_FB_ATTACHMENT_INFO fb_info; fb_info.mem = getImageState(dev_data, view_state->create_info.image)->binding.mem; fb_info.view_state = view_state; fb_info.image = view_state->create_info.image; fb_state->attachments.push_back(fb_info); } dev_data->frameBufferMap[fb] = std::move(fb_state); } VKAPI_ATTR VkResult VKAPI_CALL CreateFramebuffer(VkDevice device, const VkFramebufferCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkFramebuffer *pFramebuffer) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); std::unique_lock lock(global_lock); bool skip_call = PreCallValidateCreateFramebuffer(dev_data, pCreateInfo); lock.unlock(); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult result = dev_data->dispatch_table.CreateFramebuffer(device, pCreateInfo, pAllocator, pFramebuffer); if (VK_SUCCESS == result) { lock.lock(); PostCallRecordCreateFramebuffer(dev_data, pCreateInfo, *pFramebuffer); lock.unlock(); } return result; } static bool FindDependency(const int index, const int dependent, const std::vector &subpass_to_node, std::unordered_set &processed_nodes) { // If we have already checked this node we have not found a dependency path so return false. if (processed_nodes.count(index)) return false; processed_nodes.insert(index); const DAGNode &node = subpass_to_node[index]; // Look for a dependency path. If one exists return true else recurse on the previous nodes. if (std::find(node.prev.begin(), node.prev.end(), dependent) == node.prev.end()) { for (auto elem : node.prev) { if (FindDependency(elem, dependent, subpass_to_node, processed_nodes)) return true; } } else { return true; } return false; } static bool CheckDependencyExists(const layer_data *dev_data, const int subpass, const std::vector &dependent_subpasses, const std::vector &subpass_to_node, bool &skip_call) { bool result = true; // Loop through all subpasses that share the same attachment and make sure a dependency exists for (uint32_t k = 0; k < dependent_subpasses.size(); ++k) { if (static_cast(subpass) == dependent_subpasses[k]) continue; const DAGNode &node = subpass_to_node[subpass]; // Check for a specified dependency between the two nodes. If one exists we are done. auto prev_elem = std::find(node.prev.begin(), node.prev.end(), dependent_subpasses[k]); auto next_elem = std::find(node.next.begin(), node.next.end(), dependent_subpasses[k]); if (prev_elem == node.prev.end() && next_elem == node.next.end()) { // If no dependency exits an implicit dependency still might. If not, throw an error. std::unordered_set processed_nodes; if (!(FindDependency(subpass, dependent_subpasses[k], subpass_to_node, processed_nodes) || FindDependency(dependent_subpasses[k], subpass, subpass_to_node, processed_nodes))) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "A dependency between subpasses %d and %d must exist but one is not specified.", subpass, dependent_subpasses[k]); result = false; } } } return result; } static bool CheckPreserved(const layer_data *dev_data, const VkRenderPassCreateInfo *pCreateInfo, const int index, const uint32_t attachment, const std::vector &subpass_to_node, int depth, bool &skip_call) { const DAGNode &node = subpass_to_node[index]; // If this node writes to the attachment return true as next nodes need to preserve the attachment. const VkSubpassDescription &subpass = pCreateInfo->pSubpasses[index]; for (uint32_t j = 0; j < subpass.colorAttachmentCount; ++j) { if (attachment == subpass.pColorAttachments[j].attachment) return true; } if (subpass.pDepthStencilAttachment && subpass.pDepthStencilAttachment->attachment != VK_ATTACHMENT_UNUSED) { if (attachment == subpass.pDepthStencilAttachment->attachment) return true; } bool result = false; // Loop through previous nodes and see if any of them write to the attachment. for (auto elem : node.prev) { result |= CheckPreserved(dev_data, pCreateInfo, elem, attachment, subpass_to_node, depth + 1, skip_call); } // If the attachment was written to by a previous node than this node needs to preserve it. if (result && depth > 0) { const VkSubpassDescription &subpass = pCreateInfo->pSubpasses[index]; bool has_preserved = false; for (uint32_t j = 0; j < subpass.preserveAttachmentCount; ++j) { if (subpass.pPreserveAttachments[j] == attachment) { has_preserved = true; break; } } if (!has_preserved) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "Attachment %d is used by a later subpass and must be preserved in subpass %d.", attachment, index); } } return result; } template bool isRangeOverlapping(T offset1, T size1, T offset2, T size2) { return (((offset1 + size1) > offset2) && ((offset1 + size1) < (offset2 + size2))) || ((offset1 > offset2) && (offset1 < (offset2 + size2))); } bool isRegionOverlapping(VkImageSubresourceRange range1, VkImageSubresourceRange range2) { return (isRangeOverlapping(range1.baseMipLevel, range1.levelCount, range2.baseMipLevel, range2.levelCount) && isRangeOverlapping(range1.baseArrayLayer, range1.layerCount, range2.baseArrayLayer, range2.layerCount)); } static bool ValidateDependencies(const layer_data *dev_data, FRAMEBUFFER_STATE const *framebuffer, RENDER_PASS_STATE const *renderPass) { bool skip_call = false; auto const pFramebufferInfo = framebuffer->createInfo.ptr(); auto const pCreateInfo = renderPass->createInfo.ptr(); auto const & subpass_to_node = renderPass->subpassToNode; std::vector> output_attachment_to_subpass(pCreateInfo->attachmentCount); std::vector> input_attachment_to_subpass(pCreateInfo->attachmentCount); std::vector> overlapping_attachments(pCreateInfo->attachmentCount); // Find overlapping attachments for (uint32_t i = 0; i < pCreateInfo->attachmentCount; ++i) { for (uint32_t j = i + 1; j < pCreateInfo->attachmentCount; ++j) { VkImageView viewi = pFramebufferInfo->pAttachments[i]; VkImageView viewj = pFramebufferInfo->pAttachments[j]; if (viewi == viewj) { overlapping_attachments[i].push_back(j); overlapping_attachments[j].push_back(i); continue; } auto view_state_i = getImageViewState(dev_data, viewi); auto view_state_j = getImageViewState(dev_data, viewj); if (!view_state_i || !view_state_j) { continue; } auto view_ci_i = view_state_i->create_info; auto view_ci_j = view_state_j->create_info; if (view_ci_i.image == view_ci_j.image && isRegionOverlapping(view_ci_i.subresourceRange, view_ci_j.subresourceRange)) { overlapping_attachments[i].push_back(j); overlapping_attachments[j].push_back(i); continue; } auto image_data_i = getImageState(dev_data, view_ci_i.image); auto image_data_j = getImageState(dev_data, view_ci_j.image); if (!image_data_i || !image_data_j) { continue; } if (image_data_i->binding.mem == image_data_j->binding.mem && isRangeOverlapping(image_data_i->binding.offset, image_data_i->binding.size, image_data_j->binding.offset, image_data_j->binding.size)) { overlapping_attachments[i].push_back(j); overlapping_attachments[j].push_back(i); } } } for (uint32_t i = 0; i < overlapping_attachments.size(); ++i) { uint32_t attachment = i; for (auto other_attachment : overlapping_attachments[i]) { if (!(pCreateInfo->pAttachments[attachment].flags & VK_ATTACHMENT_DESCRIPTION_MAY_ALIAS_BIT)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "Attachment %d aliases attachment %d but doesn't " "set VK_ATTACHMENT_DESCRIPTION_MAY_ALIAS_BIT.", attachment, other_attachment); } if (!(pCreateInfo->pAttachments[other_attachment].flags & VK_ATTACHMENT_DESCRIPTION_MAY_ALIAS_BIT)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "Attachment %d aliases attachment %d but doesn't " "set VK_ATTACHMENT_DESCRIPTION_MAY_ALIAS_BIT.", other_attachment, attachment); } } } // Find for each attachment the subpasses that use them. unordered_set attachmentIndices; for (uint32_t i = 0; i < pCreateInfo->subpassCount; ++i) { const VkSubpassDescription &subpass = pCreateInfo->pSubpasses[i]; attachmentIndices.clear(); for (uint32_t j = 0; j < subpass.inputAttachmentCount; ++j) { uint32_t attachment = subpass.pInputAttachments[j].attachment; if (attachment == VK_ATTACHMENT_UNUSED) continue; input_attachment_to_subpass[attachment].push_back(i); for (auto overlapping_attachment : overlapping_attachments[attachment]) { input_attachment_to_subpass[overlapping_attachment].push_back(i); } } for (uint32_t j = 0; j < subpass.colorAttachmentCount; ++j) { uint32_t attachment = subpass.pColorAttachments[j].attachment; if (attachment == VK_ATTACHMENT_UNUSED) continue; output_attachment_to_subpass[attachment].push_back(i); for (auto overlapping_attachment : overlapping_attachments[attachment]) { output_attachment_to_subpass[overlapping_attachment].push_back(i); } attachmentIndices.insert(attachment); } if (subpass.pDepthStencilAttachment && subpass.pDepthStencilAttachment->attachment != VK_ATTACHMENT_UNUSED) { uint32_t attachment = subpass.pDepthStencilAttachment->attachment; output_attachment_to_subpass[attachment].push_back(i); for (auto overlapping_attachment : overlapping_attachments[attachment]) { output_attachment_to_subpass[overlapping_attachment].push_back(i); } if (attachmentIndices.count(attachment)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "Cannot use same attachment (%u) as both color and depth output in same subpass (%u).", attachment, i); } } } // If there is a dependency needed make sure one exists for (uint32_t i = 0; i < pCreateInfo->subpassCount; ++i) { const VkSubpassDescription &subpass = pCreateInfo->pSubpasses[i]; // If the attachment is an input then all subpasses that output must have a dependency relationship for (uint32_t j = 0; j < subpass.inputAttachmentCount; ++j) { uint32_t attachment = subpass.pInputAttachments[j].attachment; if (attachment == VK_ATTACHMENT_UNUSED) continue; CheckDependencyExists(dev_data, i, output_attachment_to_subpass[attachment], subpass_to_node, skip_call); } // If the attachment is an output then all subpasses that use the attachment must have a dependency relationship for (uint32_t j = 0; j < subpass.colorAttachmentCount; ++j) { uint32_t attachment = subpass.pColorAttachments[j].attachment; if (attachment == VK_ATTACHMENT_UNUSED) continue; CheckDependencyExists(dev_data, i, output_attachment_to_subpass[attachment], subpass_to_node, skip_call); CheckDependencyExists(dev_data, i, input_attachment_to_subpass[attachment], subpass_to_node, skip_call); } if (subpass.pDepthStencilAttachment && subpass.pDepthStencilAttachment->attachment != VK_ATTACHMENT_UNUSED) { const uint32_t &attachment = subpass.pDepthStencilAttachment->attachment; CheckDependencyExists(dev_data, i, output_attachment_to_subpass[attachment], subpass_to_node, skip_call); CheckDependencyExists(dev_data, i, input_attachment_to_subpass[attachment], subpass_to_node, skip_call); } } // Loop through implicit dependencies, if this pass reads make sure the attachment is preserved for all passes after it was // written. for (uint32_t i = 0; i < pCreateInfo->subpassCount; ++i) { const VkSubpassDescription &subpass = pCreateInfo->pSubpasses[i]; for (uint32_t j = 0; j < subpass.inputAttachmentCount; ++j) { CheckPreserved(dev_data, pCreateInfo, i, subpass.pInputAttachments[j].attachment, subpass_to_node, 0, skip_call); } } return skip_call; } // ValidateLayoutVsAttachmentDescription is a general function where we can validate various state associated with the // VkAttachmentDescription structs that are used by the sub-passes of a renderpass. Initial check is to make sure that // READ_ONLY layout attachments don't have CLEAR as their loadOp. static bool ValidateLayoutVsAttachmentDescription(debug_report_data *report_data, const VkImageLayout first_layout, const uint32_t attachment, const VkAttachmentDescription &attachment_description) { bool skip_call = false; // Verify that initial loadOp on READ_ONLY attachments is not CLEAR if (attachment_description.loadOp == VK_ATTACHMENT_LOAD_OP_CLEAR) { if ((first_layout == VK_IMAGE_LAYOUT_DEPTH_STENCIL_READ_ONLY_OPTIMAL) || (first_layout == VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL)) { skip_call |= log_msg(report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_UNKNOWN_EXT, VkDebugReportObjectTypeEXT(0), __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Cannot clear attachment %d with invalid first layout %s.", attachment, string_VkImageLayout(first_layout)); } } return skip_call; } static bool ValidateLayouts(const layer_data *dev_data, VkDevice device, const VkRenderPassCreateInfo *pCreateInfo) { bool skip = false; // Track when we're observing the first use of an attachment std::vector attach_first_use(pCreateInfo->attachmentCount, true); for (uint32_t i = 0; i < pCreateInfo->subpassCount; ++i) { const VkSubpassDescription &subpass = pCreateInfo->pSubpasses[i]; for (uint32_t j = 0; j < subpass.colorAttachmentCount; ++j) { auto attach_index = subpass.pColorAttachments[j].attachment; if (attach_index == VK_ATTACHMENT_UNUSED) continue; switch (subpass.pColorAttachments[j].layout) { case VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL: /* This is ideal. */ break; case VK_IMAGE_LAYOUT_GENERAL: /* May not be optimal; TODO: reconsider this warning based on * other constraints? */ skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_PERFORMANCE_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_UNKNOWN_EXT, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Layout for color attachment is GENERAL but should be COLOR_ATTACHMENT_OPTIMAL."); break; default: skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_UNKNOWN_EXT, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Layout for color attachment is %s but can only be COLOR_ATTACHMENT_OPTIMAL or GENERAL.", string_VkImageLayout(subpass.pColorAttachments[j].layout)); } if (attach_first_use[attach_index]) { skip |= ValidateLayoutVsAttachmentDescription(dev_data->report_data, subpass.pColorAttachments[j].layout, attach_index, pCreateInfo->pAttachments[attach_index]); } attach_first_use[attach_index] = false; } if (subpass.pDepthStencilAttachment && subpass.pDepthStencilAttachment->attachment != VK_ATTACHMENT_UNUSED) { switch (subpass.pDepthStencilAttachment->layout) { case VK_IMAGE_LAYOUT_DEPTH_STENCIL_ATTACHMENT_OPTIMAL: case VK_IMAGE_LAYOUT_DEPTH_STENCIL_READ_ONLY_OPTIMAL: /* These are ideal. */ break; case VK_IMAGE_LAYOUT_GENERAL: /* May not be optimal; TODO: reconsider this warning based on * other constraints? GENERAL can be better than doing a bunch * of transitions. */ skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_PERFORMANCE_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_UNKNOWN_EXT, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "GENERAL layout for depth attachment may not give optimal performance."); break; default: /* No other layouts are acceptable */ skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_UNKNOWN_EXT, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Layout for depth attachment is %s but can only be DEPTH_STENCIL_ATTACHMENT_OPTIMAL, " "DEPTH_STENCIL_READ_ONLY_OPTIMAL or GENERAL.", string_VkImageLayout(subpass.pDepthStencilAttachment->layout)); } auto attach_index = subpass.pDepthStencilAttachment->attachment; if (attach_first_use[attach_index]) { skip |= ValidateLayoutVsAttachmentDescription(dev_data->report_data, subpass.pDepthStencilAttachment->layout, attach_index, pCreateInfo->pAttachments[attach_index]); } attach_first_use[attach_index] = false; } for (uint32_t j = 0; j < subpass.inputAttachmentCount; ++j) { auto attach_index = subpass.pInputAttachments[j].attachment; if (attach_index == VK_ATTACHMENT_UNUSED) continue; switch (subpass.pInputAttachments[j].layout) { case VK_IMAGE_LAYOUT_DEPTH_STENCIL_READ_ONLY_OPTIMAL: case VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL: /* These are ideal. */ break; case VK_IMAGE_LAYOUT_GENERAL: /* May not be optimal. TODO: reconsider this warning based on * other constraints. */ skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_PERFORMANCE_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_UNKNOWN_EXT, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Layout for input attachment is GENERAL but should be READ_ONLY_OPTIMAL."); break; default: /* No other layouts are acceptable */ skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Layout for input attachment is %s but can only be READ_ONLY_OPTIMAL or GENERAL.", string_VkImageLayout(subpass.pInputAttachments[j].layout)); } if (attach_first_use[attach_index]) { skip |= ValidateLayoutVsAttachmentDescription(dev_data->report_data, subpass.pInputAttachments[j].layout, attach_index, pCreateInfo->pAttachments[attach_index]); } attach_first_use[attach_index] = false; } } return skip; } static bool CreatePassDAG(const layer_data *dev_data, VkDevice device, const VkRenderPassCreateInfo *pCreateInfo, std::vector &subpass_to_node, std::vector &has_self_dependency) { bool skip_call = false; for (uint32_t i = 0; i < pCreateInfo->subpassCount; ++i) { DAGNode &subpass_node = subpass_to_node[i]; subpass_node.pass = i; } for (uint32_t i = 0; i < pCreateInfo->dependencyCount; ++i) { const VkSubpassDependency &dependency = pCreateInfo->pDependencies[i]; if (dependency.srcSubpass == VK_SUBPASS_EXTERNAL || dependency.dstSubpass == VK_SUBPASS_EXTERNAL) { if (dependency.srcSubpass == dependency.dstSubpass) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "The src and dest subpasses cannot both be external."); } } else if (dependency.srcSubpass > dependency.dstSubpass) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "Depedency graph must be specified such that an earlier pass cannot depend on a later pass."); } else if (dependency.srcSubpass == dependency.dstSubpass) { has_self_dependency[dependency.srcSubpass] = true; } else { subpass_to_node[dependency.dstSubpass].prev.push_back(dependency.srcSubpass); subpass_to_node[dependency.srcSubpass].next.push_back(dependency.dstSubpass); } } return skip_call; } VKAPI_ATTR VkResult VKAPI_CALL CreateShaderModule(VkDevice device, const VkShaderModuleCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkShaderModule *pShaderModule) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); bool skip_call = false; /* Use SPIRV-Tools validator to try and catch any issues with the module itself */ spv_context ctx = spvContextCreate(SPV_ENV_VULKAN_1_0); spv_const_binary_t binary { pCreateInfo->pCode, pCreateInfo->codeSize / sizeof(uint32_t) }; spv_diagnostic diag = nullptr; auto result = spvValidate(ctx, &binary, &diag); if (result != SPV_SUCCESS) { skip_call |= log_msg(dev_data->report_data, result == SPV_WARNING ? VK_DEBUG_REPORT_WARNING_BIT_EXT : VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, SHADER_CHECKER_INCONSISTENT_SPIRV, "SC", "SPIR-V module not valid: %s", diag && diag->error ? diag->error : "(no error text)"); } spvDiagnosticDestroy(diag); spvContextDestroy(ctx); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult res = dev_data->dispatch_table.CreateShaderModule(device, pCreateInfo, pAllocator, pShaderModule); if (res == VK_SUCCESS) { std::lock_guard lock(global_lock); dev_data->shaderModuleMap[*pShaderModule] = unique_ptr(new shader_module(pCreateInfo)); } return res; } static bool ValidateAttachmentIndex(layer_data *dev_data, uint32_t attachment, uint32_t attachment_count, const char *type) { bool skip_call = false; if (attachment >= attachment_count && attachment != VK_ATTACHMENT_UNUSED) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_ATTACHMENT_INDEX, "DS", "CreateRenderPass: %s attachment %d cannot be greater than the total number of attachments %d.", type, attachment, attachment_count); } return skip_call; } static bool IsPowerOfTwo(unsigned x) { return x && !(x & (x-1)); } static bool ValidateRenderpassAttachmentUsage(layer_data *dev_data, const VkRenderPassCreateInfo *pCreateInfo) { bool skip_call = false; for (uint32_t i = 0; i < pCreateInfo->subpassCount; ++i) { const VkSubpassDescription &subpass = pCreateInfo->pSubpasses[i]; if (subpass.pipelineBindPoint != VK_PIPELINE_BIND_POINT_GRAPHICS) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "CreateRenderPass: Pipeline bind point for subpass %d must be VK_PIPELINE_BIND_POINT_GRAPHICS.", i); } for (uint32_t j = 0; j < subpass.preserveAttachmentCount; ++j) { uint32_t attachment = subpass.pPreserveAttachments[j]; if (attachment == VK_ATTACHMENT_UNUSED) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_ATTACHMENT_INDEX, "DS", "CreateRenderPass: Preserve attachment (%d) must not be VK_ATTACHMENT_UNUSED.", j); } else { skip_call |= ValidateAttachmentIndex(dev_data, attachment, pCreateInfo->attachmentCount, "Preserve"); } } auto subpass_performs_resolve = subpass.pResolveAttachments && std::any_of( subpass.pResolveAttachments, subpass.pResolveAttachments + subpass.colorAttachmentCount, [](VkAttachmentReference ref) { return ref.attachment != VK_ATTACHMENT_UNUSED; }); unsigned sample_count = 0; for (uint32_t j = 0; j < subpass.colorAttachmentCount; ++j) { uint32_t attachment; if (subpass.pResolveAttachments) { attachment = subpass.pResolveAttachments[j].attachment; skip_call |= ValidateAttachmentIndex(dev_data, attachment, pCreateInfo->attachmentCount, "Resolve"); if (!skip_call && attachment != VK_ATTACHMENT_UNUSED && pCreateInfo->pAttachments[attachment].samples != VK_SAMPLE_COUNT_1_BIT) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "CreateRenderPass: Subpass %u requests multisample resolve into attachment %u, " "which must have VK_SAMPLE_COUNT_1_BIT but has %s", i, attachment, string_VkSampleCountFlagBits(pCreateInfo->pAttachments[attachment].samples)); } } attachment = subpass.pColorAttachments[j].attachment; skip_call |= ValidateAttachmentIndex(dev_data, attachment, pCreateInfo->attachmentCount, "Color"); if (!skip_call && attachment != VK_ATTACHMENT_UNUSED) { sample_count |= (unsigned)pCreateInfo->pAttachments[attachment].samples; if (subpass_performs_resolve && pCreateInfo->pAttachments[attachment].samples == VK_SAMPLE_COUNT_1_BIT) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "CreateRenderPass: Subpass %u requests multisample resolve from attachment %u " "which has VK_SAMPLE_COUNT_1_BIT", i, attachment); } } } if (subpass.pDepthStencilAttachment && subpass.pDepthStencilAttachment->attachment != VK_ATTACHMENT_UNUSED) { uint32_t attachment = subpass.pDepthStencilAttachment->attachment; skip_call |= ValidateAttachmentIndex(dev_data, attachment, pCreateInfo->attachmentCount, "Depth stencil"); if (!skip_call && attachment != VK_ATTACHMENT_UNUSED) { sample_count |= (unsigned)pCreateInfo->pAttachments[attachment].samples; } } for (uint32_t j = 0; j < subpass.inputAttachmentCount; ++j) { uint32_t attachment = subpass.pInputAttachments[j].attachment; skip_call |= ValidateAttachmentIndex(dev_data, attachment, pCreateInfo->attachmentCount, "Input"); } if (sample_count && !IsPowerOfTwo(sample_count)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VkDebugReportObjectTypeEXT(0), 0, __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "CreateRenderPass: Subpass %u attempts to render to " "attachments with inconsistent sample counts", i); } } return skip_call; } VKAPI_ATTR VkResult VKAPI_CALL CreateRenderPass(VkDevice device, const VkRenderPassCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkRenderPass *pRenderPass) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); std::unique_lock lock(global_lock); skip_call |= ValidateLayouts(dev_data, device, pCreateInfo); // TODO: As part of wrapping up the mem_tracker/core_validation merge the following routine should be consolidated with // ValidateLayouts. skip_call |= ValidateRenderpassAttachmentUsage(dev_data, pCreateInfo); lock.unlock(); if (skip_call) { return VK_ERROR_VALIDATION_FAILED_EXT; } VkResult result = dev_data->dispatch_table.CreateRenderPass(device, pCreateInfo, pAllocator, pRenderPass); if (VK_SUCCESS == result) { lock.lock(); std::vector has_self_dependency(pCreateInfo->subpassCount); std::vector subpass_to_node(pCreateInfo->subpassCount); skip_call |= CreatePassDAG(dev_data, device, pCreateInfo, subpass_to_node, has_self_dependency); auto render_pass = unique_ptr(new RENDER_PASS_STATE(pCreateInfo)); render_pass->renderPass = *pRenderPass; render_pass->hasSelfDependency = has_self_dependency; render_pass->subpassToNode = subpass_to_node; // TODO: Maybe fill list and then copy instead of locking std::unordered_map &attachment_first_read = render_pass->attachment_first_read; std::unordered_map &attachment_first_layout = render_pass->attachment_first_layout; for (uint32_t i = 0; i < pCreateInfo->subpassCount; ++i) { const VkSubpassDescription &subpass = pCreateInfo->pSubpasses[i]; for (uint32_t j = 0; j < subpass.colorAttachmentCount; ++j) { uint32_t attachment = subpass.pColorAttachments[j].attachment; if (!attachment_first_read.count(attachment)) { attachment_first_read.insert(std::make_pair(attachment, false)); attachment_first_layout.insert(std::make_pair(attachment, subpass.pColorAttachments[j].layout)); } } if (subpass.pDepthStencilAttachment && subpass.pDepthStencilAttachment->attachment != VK_ATTACHMENT_UNUSED) { uint32_t attachment = subpass.pDepthStencilAttachment->attachment; if (!attachment_first_read.count(attachment)) { attachment_first_read.insert(std::make_pair(attachment, false)); attachment_first_layout.insert(std::make_pair(attachment, subpass.pDepthStencilAttachment->layout)); } } for (uint32_t j = 0; j < subpass.inputAttachmentCount; ++j) { uint32_t attachment = subpass.pInputAttachments[j].attachment; if (!attachment_first_read.count(attachment)) { attachment_first_read.insert(std::make_pair(attachment, true)); attachment_first_layout.insert(std::make_pair(attachment, subpass.pInputAttachments[j].layout)); } } } dev_data->renderPassMap[*pRenderPass] = std::move(render_pass); } return result; } static bool VerifyFramebufferAndRenderPassLayouts(layer_data *dev_data, GLOBAL_CB_NODE *pCB, const VkRenderPassBeginInfo *pRenderPassBegin) { bool skip_call = false; auto const pRenderPassInfo = getRenderPassState(dev_data, pRenderPassBegin->renderPass)->createInfo.ptr(); auto const & framebufferInfo = dev_data->frameBufferMap[pRenderPassBegin->framebuffer]->createInfo; if (pRenderPassInfo->attachmentCount != framebufferInfo.attachmentCount) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "You cannot start a render pass using a framebuffer " "with a different number of attachments."); } for (uint32_t i = 0; i < pRenderPassInfo->attachmentCount; ++i) { const VkImageView &image_view = framebufferInfo.pAttachments[i]; auto view_state = getImageViewState(dev_data, image_view); assert(view_state); const VkImage &image = view_state->create_info.image; const VkImageSubresourceRange &subRange = view_state->create_info.subresourceRange; IMAGE_CMD_BUF_LAYOUT_NODE newNode = {pRenderPassInfo->pAttachments[i].initialLayout, pRenderPassInfo->pAttachments[i].initialLayout}; // TODO: Do not iterate over every possibility - consolidate where possible for (uint32_t j = 0; j < subRange.levelCount; j++) { uint32_t level = subRange.baseMipLevel + j; for (uint32_t k = 0; k < subRange.layerCount; k++) { uint32_t layer = subRange.baseArrayLayer + k; VkImageSubresource sub = {subRange.aspectMask, level, layer}; IMAGE_CMD_BUF_LAYOUT_NODE node; if (!FindLayout(pCB, image, sub, node)) { SetLayout(pCB, image, sub, newNode); continue; } if (newNode.layout != VK_IMAGE_LAYOUT_UNDEFINED && newNode.layout != node.layout) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "You cannot start a render pass using attachment %u " "where the render pass initial layout is %s and the previous " "known layout of the attachment is %s. The layouts must match, or " "the render pass initial layout for the attachment must be " "VK_IMAGE_LAYOUT_UNDEFINED", i, string_VkImageLayout(newNode.layout), string_VkImageLayout(node.layout)); } } } } return skip_call; } static void TransitionAttachmentRefLayout(layer_data *dev_data, GLOBAL_CB_NODE *pCB, FRAMEBUFFER_STATE *pFramebuffer, VkAttachmentReference ref) { if (ref.attachment != VK_ATTACHMENT_UNUSED) { auto image_view = pFramebuffer->createInfo.pAttachments[ref.attachment]; SetLayout(dev_data, pCB, image_view, ref.layout); } } static void TransitionSubpassLayouts(layer_data *dev_data, GLOBAL_CB_NODE *pCB, const VkRenderPassBeginInfo *pRenderPassBegin, const int subpass_index) { auto renderPass = getRenderPassState(dev_data, pRenderPassBegin->renderPass); if (!renderPass) return; auto framebuffer = getFramebufferState(dev_data, pRenderPassBegin->framebuffer); if (!framebuffer) return; auto const &subpass = renderPass->createInfo.pSubpasses[subpass_index]; for (uint32_t j = 0; j < subpass.inputAttachmentCount; ++j) { TransitionAttachmentRefLayout(dev_data, pCB, framebuffer, subpass.pInputAttachments[j]); } for (uint32_t j = 0; j < subpass.colorAttachmentCount; ++j) { TransitionAttachmentRefLayout(dev_data, pCB, framebuffer, subpass.pColorAttachments[j]); } if (subpass.pDepthStencilAttachment) { TransitionAttachmentRefLayout(dev_data, pCB, framebuffer, *subpass.pDepthStencilAttachment); } } static bool validatePrimaryCommandBuffer(const layer_data *dev_data, const GLOBAL_CB_NODE *pCB, const std::string &cmd_name) { bool skip_call = false; if (pCB->createInfo.level != VK_COMMAND_BUFFER_LEVEL_PRIMARY) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_COMMAND_BUFFER, "DS", "Cannot execute command %s on a secondary command buffer.", cmd_name.c_str()); } return skip_call; } static void TransitionFinalSubpassLayouts(layer_data *dev_data, GLOBAL_CB_NODE *pCB, const VkRenderPassBeginInfo *pRenderPassBegin) { auto renderPass = getRenderPassState(dev_data, pRenderPassBegin->renderPass); if (!renderPass) return; const VkRenderPassCreateInfo *pRenderPassInfo = renderPass->createInfo.ptr(); auto framebuffer = getFramebufferState(dev_data, pRenderPassBegin->framebuffer); if (!framebuffer) return; for (uint32_t i = 0; i < pRenderPassInfo->attachmentCount; ++i) { auto image_view = framebuffer->createInfo.pAttachments[i]; SetLayout(dev_data, pCB, image_view, pRenderPassInfo->pAttachments[i].finalLayout); } } static bool VerifyRenderAreaBounds(const layer_data *dev_data, const VkRenderPassBeginInfo *pRenderPassBegin) { bool skip_call = false; const safe_VkFramebufferCreateInfo *pFramebufferInfo = &getFramebufferState(dev_data, pRenderPassBegin->framebuffer)->createInfo; if (pRenderPassBegin->renderArea.offset.x < 0 || (pRenderPassBegin->renderArea.offset.x + pRenderPassBegin->renderArea.extent.width) > pFramebufferInfo->width || pRenderPassBegin->renderArea.offset.y < 0 || (pRenderPassBegin->renderArea.offset.y + pRenderPassBegin->renderArea.extent.height) > pFramebufferInfo->height) { skip_call |= static_cast(log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_RENDER_AREA, "CORE", "Cannot execute a render pass with renderArea not within the bound of the " "framebuffer. RenderArea: x %d, y %d, width %d, height %d. Framebuffer: width %d, " "height %d.", pRenderPassBegin->renderArea.offset.x, pRenderPassBegin->renderArea.offset.y, pRenderPassBegin->renderArea.extent.width, pRenderPassBegin->renderArea.extent.height, pFramebufferInfo->width, pFramebufferInfo->height)); } return skip_call; } // If this is a stencil format, make sure the stencil[Load|Store]Op flag is checked, while if it is a depth/color attachment the // [load|store]Op flag must be checked // TODO: The memory valid flag in DEVICE_MEM_INFO should probably be split to track the validity of stencil memory separately. template static bool FormatSpecificLoadAndStoreOpSettings(VkFormat format, T color_depth_op, T stencil_op, T op) { if (color_depth_op != op && stencil_op != op) { return false; } bool check_color_depth_load_op = !vk_format_is_stencil_only(format); bool check_stencil_load_op = vk_format_is_depth_and_stencil(format) || !check_color_depth_load_op; return (((check_color_depth_load_op == true) && (color_depth_op == op)) || ((check_stencil_load_op == true) && (stencil_op == op))); } VKAPI_ATTR void VKAPI_CALL CmdBeginRenderPass(VkCommandBuffer commandBuffer, const VkRenderPassBeginInfo *pRenderPassBegin, VkSubpassContents contents) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *cb_node = getCBNode(dev_data, commandBuffer); auto renderPass = pRenderPassBegin ? getRenderPassState(dev_data, pRenderPassBegin->renderPass) : nullptr; auto framebuffer = pRenderPassBegin ? getFramebufferState(dev_data, pRenderPassBegin->framebuffer) : nullptr; if (cb_node) { if (renderPass) { uint32_t clear_op_size = 0; // Make sure pClearValues is at least as large as last LOAD_OP_CLEAR cb_node->activeFramebuffer = pRenderPassBegin->framebuffer; for (uint32_t i = 0; i < renderPass->createInfo.attachmentCount; ++i) { MT_FB_ATTACHMENT_INFO &fb_info = framebuffer->attachments[i]; auto pAttachment = &renderPass->createInfo.pAttachments[i]; if (FormatSpecificLoadAndStoreOpSettings(pAttachment->format, pAttachment->loadOp, pAttachment->stencilLoadOp, VK_ATTACHMENT_LOAD_OP_CLEAR)) { clear_op_size = static_cast(i) + 1; std::function function = [=]() { SetImageMemoryValid(dev_data, getImageState(dev_data, fb_info.image), true); return false; }; cb_node->validate_functions.push_back(function); } else if (FormatSpecificLoadAndStoreOpSettings(pAttachment->format, pAttachment->loadOp, pAttachment->stencilLoadOp, VK_ATTACHMENT_LOAD_OP_DONT_CARE)) { std::function function = [=]() { SetImageMemoryValid(dev_data, getImageState(dev_data, fb_info.image), false); return false; }; cb_node->validate_functions.push_back(function); } else if (FormatSpecificLoadAndStoreOpSettings(pAttachment->format, pAttachment->loadOp, pAttachment->stencilLoadOp, VK_ATTACHMENT_LOAD_OP_LOAD)) { std::function function = [=]() { return ValidateImageMemoryIsValid(dev_data, getImageState(dev_data, fb_info.image), "vkCmdBeginRenderPass()"); }; cb_node->validate_functions.push_back(function); } if (renderPass->attachment_first_read[i]) { std::function function = [=]() { return ValidateImageMemoryIsValid(dev_data, getImageState(dev_data, fb_info.image), "vkCmdBeginRenderPass()"); }; cb_node->validate_functions.push_back(function); } } if (clear_op_size > pRenderPassBegin->clearValueCount) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_RENDER_PASS_EXT, reinterpret_cast(renderPass), __LINE__, VALIDATION_ERROR_00442, "DS", "In vkCmdBeginRenderPass() the VkRenderPassBeginInfo struct has a clearValueCount of %u but there must " "be at least %u " "entries in pClearValues array to account for the highest index attachment in renderPass 0x%" PRIx64 " that uses VK_ATTACHMENT_LOAD_OP_CLEAR is %u. Note that the pClearValues array " "is indexed by attachment number so even if some pClearValues entries between 0 and %u correspond to " "attachments that aren't cleared they will be ignored. %s", pRenderPassBegin->clearValueCount, clear_op_size, reinterpret_cast(renderPass), clear_op_size, clear_op_size - 1, validation_error_map[VALIDATION_ERROR_00442]); } skip_call |= VerifyRenderAreaBounds(dev_data, pRenderPassBegin); skip_call |= VerifyFramebufferAndRenderPassLayouts(dev_data, cb_node, pRenderPassBegin); skip_call |= insideRenderPass(dev_data, cb_node, "vkCmdBeginRenderPass"); skip_call |= ValidateDependencies(dev_data, framebuffer, renderPass); skip_call |= validatePrimaryCommandBuffer(dev_data, cb_node, "vkCmdBeginRenderPass"); skip_call |= addCmd(dev_data, cb_node, CMD_BEGINRENDERPASS, "vkCmdBeginRenderPass()"); cb_node->activeRenderPass = renderPass; // This is a shallow copy as that is all that is needed for now cb_node->activeRenderPassBeginInfo = *pRenderPassBegin; cb_node->activeSubpass = 0; cb_node->activeSubpassContents = contents; cb_node->framebuffers.insert(pRenderPassBegin->framebuffer); // Connect this framebuffer and its children to this cmdBuffer AddFramebufferBinding(dev_data, cb_node, framebuffer); // transition attachments to the correct layouts for the first subpass TransitionSubpassLayouts(dev_data, cb_node, &cb_node->activeRenderPassBeginInfo, cb_node->activeSubpass); } else { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_RENDERPASS, "DS", "You cannot use a NULL RenderPass object in vkCmdBeginRenderPass()"); } } lock.unlock(); if (!skip_call) { dev_data->dispatch_table.CmdBeginRenderPass(commandBuffer, pRenderPassBegin, contents); } } VKAPI_ATTR void VKAPI_CALL CmdNextSubpass(VkCommandBuffer commandBuffer, VkSubpassContents contents) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { skip_call |= validatePrimaryCommandBuffer(dev_data, pCB, "vkCmdNextSubpass"); skip_call |= addCmd(dev_data, pCB, CMD_NEXTSUBPASS, "vkCmdNextSubpass()"); skip_call |= outsideRenderPass(dev_data, pCB, "vkCmdNextSubpass"); auto subpassCount = pCB->activeRenderPass->createInfo.subpassCount; if (pCB->activeSubpass == subpassCount - 1) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(commandBuffer), __LINE__, DRAWSTATE_INVALID_SUBPASS_INDEX, "DS", "vkCmdNextSubpass(): Attempted to advance beyond final subpass"); } } lock.unlock(); if (skip_call) return; dev_data->dispatch_table.CmdNextSubpass(commandBuffer, contents); if (pCB) { lock.lock(); pCB->activeSubpass++; pCB->activeSubpassContents = contents; TransitionSubpassLayouts(dev_data, pCB, &pCB->activeRenderPassBeginInfo, pCB->activeSubpass); } } VKAPI_ATTR void VKAPI_CALL CmdEndRenderPass(VkCommandBuffer commandBuffer) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); auto pCB = getCBNode(dev_data, commandBuffer); if (pCB) { RENDER_PASS_STATE *rp_state = pCB->activeRenderPass; auto framebuffer = getFramebufferState(dev_data, pCB->activeFramebuffer); if (rp_state) { if (pCB->activeSubpass != rp_state->createInfo.subpassCount - 1) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(commandBuffer), __LINE__, DRAWSTATE_INVALID_SUBPASS_INDEX, "DS", "vkCmdEndRenderPass(): Called before reaching final subpass"); } for (size_t i = 0; i < rp_state->createInfo.attachmentCount; ++i) { MT_FB_ATTACHMENT_INFO &fb_info = framebuffer->attachments[i]; auto pAttachment = &rp_state->createInfo.pAttachments[i]; if (FormatSpecificLoadAndStoreOpSettings(pAttachment->format, pAttachment->storeOp, pAttachment->stencilStoreOp, VK_ATTACHMENT_STORE_OP_STORE)) { std::function function = [=]() { SetImageMemoryValid(dev_data, getImageState(dev_data, fb_info.image), true); return false; }; pCB->validate_functions.push_back(function); } else if (FormatSpecificLoadAndStoreOpSettings(pAttachment->format, pAttachment->storeOp, pAttachment->stencilStoreOp, VK_ATTACHMENT_STORE_OP_DONT_CARE)) { std::function function = [=]() { SetImageMemoryValid(dev_data, getImageState(dev_data, fb_info.image), false); return false; }; pCB->validate_functions.push_back(function); } } } skip_call |= outsideRenderPass(dev_data, pCB, "vkCmdEndRenderpass"); skip_call |= validatePrimaryCommandBuffer(dev_data, pCB, "vkCmdEndRenderPass"); skip_call |= addCmd(dev_data, pCB, CMD_ENDRENDERPASS, "vkCmdEndRenderPass()"); } lock.unlock(); if (skip_call) return; dev_data->dispatch_table.CmdEndRenderPass(commandBuffer); if (pCB) { lock.lock(); TransitionFinalSubpassLayouts(dev_data, pCB, &pCB->activeRenderPassBeginInfo); pCB->activeRenderPass = nullptr; pCB->activeSubpass = 0; pCB->activeFramebuffer = VK_NULL_HANDLE; } } static bool logInvalidAttachmentMessage(layer_data *dev_data, VkCommandBuffer secondaryBuffer, uint32_t primaryAttach, uint32_t secondaryAttach, const char *msg) { return log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_SECONDARY_COMMAND_BUFFER, "DS", "vkCmdExecuteCommands() called w/ invalid Secondary Cmd Buffer 0x%" PRIx64 " which has a render pass " "that is not compatible with the Primary Cmd Buffer current render pass. " "Attachment %u is not compatible with %u: %s", reinterpret_cast(secondaryBuffer), primaryAttach, secondaryAttach, msg); } static bool validateAttachmentCompatibility(layer_data *dev_data, VkCommandBuffer primaryBuffer, VkRenderPassCreateInfo const *primaryPassCI, uint32_t primaryAttach, VkCommandBuffer secondaryBuffer, VkRenderPassCreateInfo const *secondaryPassCI, uint32_t secondaryAttach, bool is_multi) { bool skip_call = false; if (primaryPassCI->attachmentCount <= primaryAttach) { primaryAttach = VK_ATTACHMENT_UNUSED; } if (secondaryPassCI->attachmentCount <= secondaryAttach) { secondaryAttach = VK_ATTACHMENT_UNUSED; } if (primaryAttach == VK_ATTACHMENT_UNUSED && secondaryAttach == VK_ATTACHMENT_UNUSED) { return skip_call; } if (primaryAttach == VK_ATTACHMENT_UNUSED) { skip_call |= logInvalidAttachmentMessage(dev_data, secondaryBuffer, primaryAttach, secondaryAttach, "The first is unused while the second is not."); return skip_call; } if (secondaryAttach == VK_ATTACHMENT_UNUSED) { skip_call |= logInvalidAttachmentMessage(dev_data, secondaryBuffer, primaryAttach, secondaryAttach, "The second is unused while the first is not."); return skip_call; } if (primaryPassCI->pAttachments[primaryAttach].format != secondaryPassCI->pAttachments[secondaryAttach].format) { skip_call |= logInvalidAttachmentMessage(dev_data, secondaryBuffer, primaryAttach, secondaryAttach, "They have different formats."); } if (primaryPassCI->pAttachments[primaryAttach].samples != secondaryPassCI->pAttachments[secondaryAttach].samples) { skip_call |= logInvalidAttachmentMessage(dev_data, secondaryBuffer, primaryAttach, secondaryAttach, "They have different samples."); } if (is_multi && primaryPassCI->pAttachments[primaryAttach].flags != secondaryPassCI->pAttachments[secondaryAttach].flags) { skip_call |= logInvalidAttachmentMessage(dev_data, secondaryBuffer, primaryAttach, secondaryAttach, "They have different flags."); } return skip_call; } static bool validateSubpassCompatibility(layer_data *dev_data, VkCommandBuffer primaryBuffer, VkRenderPassCreateInfo const *primaryPassCI, VkCommandBuffer secondaryBuffer, VkRenderPassCreateInfo const *secondaryPassCI, const int subpass, bool is_multi) { bool skip_call = false; const VkSubpassDescription &primary_desc = primaryPassCI->pSubpasses[subpass]; const VkSubpassDescription &secondary_desc = secondaryPassCI->pSubpasses[subpass]; uint32_t maxInputAttachmentCount = std::max(primary_desc.inputAttachmentCount, secondary_desc.inputAttachmentCount); for (uint32_t i = 0; i < maxInputAttachmentCount; ++i) { uint32_t primary_input_attach = VK_ATTACHMENT_UNUSED, secondary_input_attach = VK_ATTACHMENT_UNUSED; if (i < primary_desc.inputAttachmentCount) { primary_input_attach = primary_desc.pInputAttachments[i].attachment; } if (i < secondary_desc.inputAttachmentCount) { secondary_input_attach = secondary_desc.pInputAttachments[i].attachment; } skip_call |= validateAttachmentCompatibility(dev_data, primaryBuffer, primaryPassCI, primary_input_attach, secondaryBuffer, secondaryPassCI, secondary_input_attach, is_multi); } uint32_t maxColorAttachmentCount = std::max(primary_desc.colorAttachmentCount, secondary_desc.colorAttachmentCount); for (uint32_t i = 0; i < maxColorAttachmentCount; ++i) { uint32_t primary_color_attach = VK_ATTACHMENT_UNUSED, secondary_color_attach = VK_ATTACHMENT_UNUSED; if (i < primary_desc.colorAttachmentCount) { primary_color_attach = primary_desc.pColorAttachments[i].attachment; } if (i < secondary_desc.colorAttachmentCount) { secondary_color_attach = secondary_desc.pColorAttachments[i].attachment; } skip_call |= validateAttachmentCompatibility(dev_data, primaryBuffer, primaryPassCI, primary_color_attach, secondaryBuffer, secondaryPassCI, secondary_color_attach, is_multi); uint32_t primary_resolve_attach = VK_ATTACHMENT_UNUSED, secondary_resolve_attach = VK_ATTACHMENT_UNUSED; if (i < primary_desc.colorAttachmentCount && primary_desc.pResolveAttachments) { primary_resolve_attach = primary_desc.pResolveAttachments[i].attachment; } if (i < secondary_desc.colorAttachmentCount && secondary_desc.pResolveAttachments) { secondary_resolve_attach = secondary_desc.pResolveAttachments[i].attachment; } skip_call |= validateAttachmentCompatibility(dev_data, primaryBuffer, primaryPassCI, primary_resolve_attach, secondaryBuffer, secondaryPassCI, secondary_resolve_attach, is_multi); } uint32_t primary_depthstencil_attach = VK_ATTACHMENT_UNUSED, secondary_depthstencil_attach = VK_ATTACHMENT_UNUSED; if (primary_desc.pDepthStencilAttachment) { primary_depthstencil_attach = primary_desc.pDepthStencilAttachment[0].attachment; } if (secondary_desc.pDepthStencilAttachment) { secondary_depthstencil_attach = secondary_desc.pDepthStencilAttachment[0].attachment; } skip_call |= validateAttachmentCompatibility(dev_data, primaryBuffer, primaryPassCI, primary_depthstencil_attach, secondaryBuffer, secondaryPassCI, secondary_depthstencil_attach, is_multi); return skip_call; } // Verify that given renderPass CreateInfo for primary and secondary command buffers are compatible. // This function deals directly with the CreateInfo, there are overloaded versions below that can take the renderPass handle and // will then feed into this function static bool validateRenderPassCompatibility(layer_data *dev_data, VkCommandBuffer primaryBuffer, VkRenderPassCreateInfo const *primaryPassCI, VkCommandBuffer secondaryBuffer, VkRenderPassCreateInfo const *secondaryPassCI) { bool skip_call = false; if (primaryPassCI->subpassCount != secondaryPassCI->subpassCount) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_SECONDARY_COMMAND_BUFFER, "DS", "vkCmdExecuteCommands() called w/ invalid secondary Cmd Buffer 0x%" PRIx64 " that has a subpassCount of %u that is incompatible with the primary Cmd Buffer 0x%" PRIx64 " that has a subpassCount of %u.", reinterpret_cast(secondaryBuffer), secondaryPassCI->subpassCount, reinterpret_cast(primaryBuffer), primaryPassCI->subpassCount); } else { for (uint32_t i = 0; i < primaryPassCI->subpassCount; ++i) { skip_call |= validateSubpassCompatibility(dev_data, primaryBuffer, primaryPassCI, secondaryBuffer, secondaryPassCI, i, primaryPassCI->subpassCount > 1); } } return skip_call; } static bool validateFramebuffer(layer_data *dev_data, VkCommandBuffer primaryBuffer, const GLOBAL_CB_NODE *pCB, VkCommandBuffer secondaryBuffer, const GLOBAL_CB_NODE *pSubCB) { bool skip_call = false; if (!pSubCB->beginInfo.pInheritanceInfo) { return skip_call; } VkFramebuffer primary_fb = pCB->activeFramebuffer; VkFramebuffer secondary_fb = pSubCB->beginInfo.pInheritanceInfo->framebuffer; if (secondary_fb != VK_NULL_HANDLE) { if (primary_fb != secondary_fb) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_FRAMEBUFFER_INCOMPATIBLE, "DS", "vkCmdExecuteCommands() called w/ invalid secondary command buffer 0x%" PRIx64 " which has a framebuffer 0x%" PRIx64 " that is not the same as the primary command buffer's current active framebuffer 0x%" PRIx64 ".", reinterpret_cast(secondaryBuffer), reinterpret_cast(secondary_fb), reinterpret_cast(primary_fb)); } auto fb = getFramebufferState(dev_data, secondary_fb); if (!fb) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_SECONDARY_COMMAND_BUFFER, "DS", "vkCmdExecuteCommands() called w/ invalid Cmd Buffer 0x%p " "which has invalid framebuffer 0x%" PRIx64 ".", (void *)secondaryBuffer, (uint64_t)(secondary_fb)); return skip_call; } auto cb_renderpass = getRenderPassState(dev_data, pSubCB->beginInfo.pInheritanceInfo->renderPass); if (cb_renderpass->renderPass != fb->createInfo.renderPass) { skip_call |= validateRenderPassCompatibility(dev_data, secondaryBuffer, fb->renderPassCreateInfo.ptr(), secondaryBuffer, cb_renderpass->createInfo.ptr()); } } return skip_call; } static bool validateSecondaryCommandBufferState(layer_data *dev_data, GLOBAL_CB_NODE *pCB, GLOBAL_CB_NODE *pSubCB) { bool skip_call = false; unordered_set activeTypes; for (auto queryObject : pCB->activeQueries) { auto queryPoolData = dev_data->queryPoolMap.find(queryObject.pool); if (queryPoolData != dev_data->queryPoolMap.end()) { if (queryPoolData->second.createInfo.queryType == VK_QUERY_TYPE_PIPELINE_STATISTICS && pSubCB->beginInfo.pInheritanceInfo) { VkQueryPipelineStatisticFlags cmdBufStatistics = pSubCB->beginInfo.pInheritanceInfo->pipelineStatistics; if ((cmdBufStatistics & queryPoolData->second.createInfo.pipelineStatistics) != cmdBufStatistics) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_SECONDARY_COMMAND_BUFFER, "DS", "vkCmdExecuteCommands() called w/ invalid Cmd Buffer 0x%p " "which has invalid active query pool 0x%" PRIx64 ". Pipeline statistics is being queried so the command " "buffer must have all bits set on the queryPool.", reinterpret_cast(pCB->commandBuffer), reinterpret_cast(queryPoolData->first)); } } activeTypes.insert(queryPoolData->second.createInfo.queryType); } } for (auto queryObject : pSubCB->startedQueries) { auto queryPoolData = dev_data->queryPoolMap.find(queryObject.pool); if (queryPoolData != dev_data->queryPoolMap.end() && activeTypes.count(queryPoolData->second.createInfo.queryType)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_SECONDARY_COMMAND_BUFFER, "DS", "vkCmdExecuteCommands() called w/ invalid Cmd Buffer 0x%p " "which has invalid active query pool 0x%" PRIx64 "of type %d but a query of that type has been started on " "secondary Cmd Buffer 0x%p.", reinterpret_cast(pCB->commandBuffer), reinterpret_cast(queryPoolData->first), queryPoolData->second.createInfo.queryType, reinterpret_cast(pSubCB->commandBuffer)); } } auto primary_pool = getCommandPoolNode(dev_data, pCB->createInfo.commandPool); auto secondary_pool = getCommandPoolNode(dev_data, pSubCB->createInfo.commandPool); if (primary_pool && secondary_pool && (primary_pool->queueFamilyIndex != secondary_pool->queueFamilyIndex)) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(pSubCB->commandBuffer), __LINE__, DRAWSTATE_INVALID_QUEUE_FAMILY, "DS", "vkCmdExecuteCommands(): Primary command buffer 0x%" PRIxLEAST64 " created in queue family %d has secondary command buffer 0x%" PRIxLEAST64 " created in queue family %d.", reinterpret_cast(pCB->commandBuffer), primary_pool->queueFamilyIndex, reinterpret_cast(pSubCB->commandBuffer), secondary_pool->queueFamilyIndex); } return skip_call; } VKAPI_ATTR void VKAPI_CALL CmdExecuteCommands(VkCommandBuffer commandBuffer, uint32_t commandBuffersCount, const VkCommandBuffer *pCommandBuffers) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(commandBuffer), layer_data_map); std::unique_lock lock(global_lock); GLOBAL_CB_NODE *pCB = getCBNode(dev_data, commandBuffer); if (pCB) { GLOBAL_CB_NODE *pSubCB = NULL; for (uint32_t i = 0; i < commandBuffersCount; i++) { pSubCB = getCBNode(dev_data, pCommandBuffers[i]); if (!pSubCB) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_SECONDARY_COMMAND_BUFFER, "DS", "vkCmdExecuteCommands() called w/ invalid Cmd Buffer 0x%p in element %u of pCommandBuffers array.", (void *)pCommandBuffers[i], i); } else if (VK_COMMAND_BUFFER_LEVEL_PRIMARY == pSubCB->createInfo.level) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_SECONDARY_COMMAND_BUFFER, "DS", "vkCmdExecuteCommands() called w/ Primary Cmd Buffer 0x%p in element %u of pCommandBuffers " "array. All cmd buffers in pCommandBuffers array must be secondary.", (void *)pCommandBuffers[i], i); } else if (pCB->activeRenderPass) { // Secondary CB w/i RenderPass must have *CONTINUE_BIT set auto secondary_rp_state = getRenderPassState(dev_data, pSubCB->beginInfo.pInheritanceInfo->renderPass); if (!(pSubCB->beginInfo.flags & VK_COMMAND_BUFFER_USAGE_RENDER_PASS_CONTINUE_BIT)) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)pCommandBuffers[i], __LINE__, DRAWSTATE_BEGIN_CB_INVALID_STATE, "DS", "vkCmdExecuteCommands(): Secondary Command Buffer (0x%p) executed within render pass (0x%" PRIxLEAST64 ") must have had vkBeginCommandBuffer() called w/ VK_COMMAND_BUFFER_USAGE_RENDER_PASS_CONTINUE_BIT set.", (void *)pCommandBuffers[i], (uint64_t)pCB->activeRenderPass->renderPass); } else { // Make sure render pass is compatible with parent command buffer pass if has continue if (pCB->activeRenderPass->renderPass != secondary_rp_state->renderPass) { skip_call |= validateRenderPassCompatibility(dev_data, commandBuffer, pCB->activeRenderPass->createInfo.ptr(), pCommandBuffers[i], secondary_rp_state->createInfo.ptr()); } // If framebuffer for secondary CB is not NULL, then it must match active FB from primaryCB skip_call |= validateFramebuffer(dev_data, commandBuffer, pCB, pCommandBuffers[i], pSubCB); } string errorString = ""; // secondaryCB must have been created w/ RP compatible w/ primaryCB active renderpass if ((pCB->activeRenderPass->renderPass != secondary_rp_state->renderPass) && !verify_renderpass_compatibility(dev_data, pCB->activeRenderPass->createInfo.ptr(), secondary_rp_state->createInfo.ptr(), errorString)) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)pCommandBuffers[i], __LINE__, DRAWSTATE_RENDERPASS_INCOMPATIBLE, "DS", "vkCmdExecuteCommands(): Secondary Command Buffer (0x%p) w/ render pass (0x%" PRIxLEAST64 ") is incompatible w/ primary command buffer (0x%p) w/ render pass (0x%" PRIxLEAST64 ") due to: %s", (void *)pCommandBuffers[i], (uint64_t)pSubCB->beginInfo.pInheritanceInfo->renderPass, (void *)commandBuffer, (uint64_t)pCB->activeRenderPass->renderPass, errorString.c_str()); } } // TODO(mlentine): Move more logic into this method skip_call |= validateSecondaryCommandBufferState(dev_data, pCB, pSubCB); skip_call |= validateCommandBufferState(dev_data, pSubCB, "vkCmdExecuteCommands()"); // Secondary cmdBuffers are considered pending execution starting w/ // being recorded if (!(pSubCB->beginInfo.flags & VK_COMMAND_BUFFER_USAGE_SIMULTANEOUS_USE_BIT)) { if (dev_data->globalInFlightCmdBuffers.find(pSubCB->commandBuffer) != dev_data->globalInFlightCmdBuffers.end()) { skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)(pCB->commandBuffer), __LINE__, DRAWSTATE_INVALID_CB_SIMULTANEOUS_USE, "DS", "Attempt to simultaneously execute command buffer 0x%" PRIxLEAST64 " without VK_COMMAND_BUFFER_USAGE_SIMULTANEOUS_USE_BIT set!", (uint64_t)(pCB->commandBuffer)); } if (pCB->beginInfo.flags & VK_COMMAND_BUFFER_USAGE_SIMULTANEOUS_USE_BIT) { // Warn that non-simultaneous secondary cmd buffer renders primary non-simultaneous skip_call |= log_msg( dev_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, (uint64_t)(pCommandBuffers[i]), __LINE__, DRAWSTATE_INVALID_CB_SIMULTANEOUS_USE, "DS", "vkCmdExecuteCommands(): Secondary Command Buffer (0x%" PRIxLEAST64 ") does not have VK_COMMAND_BUFFER_USAGE_SIMULTANEOUS_USE_BIT set and will cause primary command buffer " "(0x%" PRIxLEAST64 ") to be treated as if it does not have VK_COMMAND_BUFFER_USAGE_SIMULTANEOUS_USE_BIT " "set, even though it does.", (uint64_t)(pCommandBuffers[i]), (uint64_t)(pCB->commandBuffer)); pCB->beginInfo.flags &= ~VK_COMMAND_BUFFER_USAGE_SIMULTANEOUS_USE_BIT; } } if (!pCB->activeQueries.empty() && !dev_data->enabled_features.inheritedQueries) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, reinterpret_cast(pCommandBuffers[i]), __LINE__, DRAWSTATE_INVALID_COMMAND_BUFFER, "DS", "vkCmdExecuteCommands(): Secondary Command Buffer " "(0x%" PRIxLEAST64 ") cannot be submitted with a query in " "flight and inherited queries not " "supported on this device.", reinterpret_cast(pCommandBuffers[i])); } // Propagate layout transitions to the primary cmd buffer for (auto ilm_entry : pSubCB->imageLayoutMap) { SetLayout(pCB, ilm_entry.first, ilm_entry.second); } pSubCB->primaryCommandBuffer = pCB->commandBuffer; pCB->secondaryCommandBuffers.insert(pSubCB->commandBuffer); dev_data->globalInFlightCmdBuffers.insert(pSubCB->commandBuffer); for (auto &function : pSubCB->queryUpdates) { pCB->queryUpdates.push_back(function); } } skip_call |= validatePrimaryCommandBuffer(dev_data, pCB, "vkCmdExecuteComands"); skip_call |= addCmd(dev_data, pCB, CMD_EXECUTECOMMANDS, "vkCmdExecuteComands()"); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.CmdExecuteCommands(commandBuffer, commandBuffersCount, pCommandBuffers); } // For any image objects that overlap mapped memory, verify that their layouts are PREINIT or GENERAL static bool ValidateMapImageLayouts(VkDevice device, DEVICE_MEM_INFO const *mem_info, VkDeviceSize offset, VkDeviceSize end_offset) { bool skip_call = false; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); // Iterate over all bound image ranges and verify that for any that overlap the // map ranges, the layouts are VK_IMAGE_LAYOUT_PREINITIALIZED or VK_IMAGE_LAYOUT_GENERAL // TODO : This can be optimized if we store ranges based on starting address and early exit when we pass our range for (auto image_handle : mem_info->bound_images) { auto img_it = mem_info->bound_ranges.find(image_handle); if (img_it != mem_info->bound_ranges.end()) { if (rangesIntersect(dev_data, &img_it->second, offset, end_offset)) { std::vector layouts; if (FindLayouts(dev_data, VkImage(image_handle), layouts)) { for (auto layout : layouts) { if (layout != VK_IMAGE_LAYOUT_PREINITIALIZED && layout != VK_IMAGE_LAYOUT_GENERAL) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, (VkDebugReportObjectTypeEXT)0, 0, __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Cannot map an image with layout %s. Only " "GENERAL or PREINITIALIZED are supported.", string_VkImageLayout(layout)); } } } } } } return skip_call; } VKAPI_ATTR VkResult VKAPI_CALL MapMemory(VkDevice device, VkDeviceMemory mem, VkDeviceSize offset, VkDeviceSize size, VkFlags flags, void **ppData) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); bool skip_call = false; VkResult result = VK_ERROR_VALIDATION_FAILED_EXT; std::unique_lock lock(global_lock); DEVICE_MEM_INFO *mem_info = getMemObjInfo(dev_data, mem); if (mem_info) { // TODO : This could me more fine-grained to track just region that is valid mem_info->global_valid = true; auto end_offset = (VK_WHOLE_SIZE == size) ? mem_info->alloc_info.allocationSize - 1 : offset + size - 1; skip_call |= ValidateMapImageLayouts(device, mem_info, offset, end_offset); // TODO : Do we need to create new "bound_range" for the mapped range? SetMemRangesValid(dev_data, mem_info, offset, end_offset); if ((dev_data->phys_dev_mem_props.memoryTypes[mem_info->alloc_info.memoryTypeIndex].propertyFlags & VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT) == 0) { skip_call = log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, (uint64_t)mem, __LINE__, MEMTRACK_INVALID_STATE, "MEM", "Mapping Memory without VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT set: mem obj 0x%" PRIxLEAST64, (uint64_t)mem); } } skip_call |= ValidateMapMemRange(dev_data, mem, offset, size); lock.unlock(); if (!skip_call) { result = dev_data->dispatch_table.MapMemory(device, mem, offset, size, flags, ppData); if (VK_SUCCESS == result) { lock.lock(); // TODO : What's the point of this range? See comment on creating new "bound_range" above, which may replace this storeMemRanges(dev_data, mem, offset, size); initializeAndTrackMemory(dev_data, mem, offset, size, ppData); lock.unlock(); } } return result; } VKAPI_ATTR void VKAPI_CALL UnmapMemory(VkDevice device, VkDeviceMemory mem) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); bool skip_call = false; std::unique_lock lock(global_lock); skip_call |= deleteMemRanges(dev_data, mem); lock.unlock(); if (!skip_call) { dev_data->dispatch_table.UnmapMemory(device, mem); } } static bool validateMemoryIsMapped(layer_data *dev_data, const char *funcName, uint32_t memRangeCount, const VkMappedMemoryRange *pMemRanges) { bool skip = false; for (uint32_t i = 0; i < memRangeCount; ++i) { auto mem_info = getMemObjInfo(dev_data, pMemRanges[i].memory); if (mem_info) { if (pMemRanges[i].size == VK_WHOLE_SIZE) { if (mem_info->mem_range.offset > pMemRanges[i].offset) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, (uint64_t)pMemRanges[i].memory, __LINE__, VALIDATION_ERROR_00643, "MEM", "%s: Flush/Invalidate offset (" PRINTF_SIZE_T_SPECIFIER ") is less than Memory Object's offset " "(" PRINTF_SIZE_T_SPECIFIER "). %s", funcName, static_cast(pMemRanges[i].offset), static_cast(mem_info->mem_range.offset), validation_error_map[VALIDATION_ERROR_00643]); } } else { const uint64_t data_end = (mem_info->mem_range.size == VK_WHOLE_SIZE) ? mem_info->alloc_info.allocationSize : (mem_info->mem_range.offset + mem_info->mem_range.size); if ((mem_info->mem_range.offset > pMemRanges[i].offset) || (data_end < (pMemRanges[i].offset + pMemRanges[i].size))) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, (uint64_t)pMemRanges[i].memory, __LINE__, VALIDATION_ERROR_00642, "MEM", "%s: Flush/Invalidate size or offset (" PRINTF_SIZE_T_SPECIFIER ", " PRINTF_SIZE_T_SPECIFIER ") exceed the Memory Object's upper-bound " "(" PRINTF_SIZE_T_SPECIFIER "). %s", funcName, static_cast(pMemRanges[i].offset + pMemRanges[i].size), static_cast(pMemRanges[i].offset), static_cast(data_end), validation_error_map[VALIDATION_ERROR_00642]); } } } } return skip; } static bool ValidateAndCopyNoncoherentMemoryToDriver(layer_data *dev_data, uint32_t mem_range_count, const VkMappedMemoryRange *mem_ranges) { bool skip = false; for (uint32_t i = 0; i < mem_range_count; ++i) { auto mem_info = getMemObjInfo(dev_data, mem_ranges[i].memory); if (mem_info) { if (mem_info->shadow_copy) { VkDeviceSize size = (mem_info->mem_range.size != VK_WHOLE_SIZE) ? mem_info->mem_range.size : (mem_info->alloc_info.allocationSize - mem_info->mem_range.offset); char *data = static_cast(mem_info->shadow_copy); for (uint64_t j = 0; j < mem_info->shadow_pad_size; ++j) { if (data[j] != NoncoherentMemoryFillValue) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, (uint64_t)mem_ranges[i].memory, __LINE__, MEMTRACK_INVALID_MAP, "MEM", "Memory underflow was detected on mem obj 0x%" PRIxLEAST64, (uint64_t)mem_ranges[i].memory); } } for (uint64_t j = (size + mem_info->shadow_pad_size); j < (2 * mem_info->shadow_pad_size + size); ++j) { if (data[j] != NoncoherentMemoryFillValue) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, (uint64_t)mem_ranges[i].memory, __LINE__, MEMTRACK_INVALID_MAP, "MEM", "Memory overflow was detected on mem obj 0x%" PRIxLEAST64, (uint64_t)mem_ranges[i].memory); } } memcpy(mem_info->p_driver_data, static_cast(data + mem_info->shadow_pad_size), (size_t)(size)); } } } return skip; } static void CopyNoncoherentMemoryFromDriver(layer_data *dev_data, uint32_t mem_range_count, const VkMappedMemoryRange *mem_ranges) { for (uint32_t i = 0; i < mem_range_count; ++i) { auto mem_info = getMemObjInfo(dev_data, mem_ranges[i].memory); if (mem_info && mem_info->shadow_copy) { VkDeviceSize size = (mem_info->mem_range.size != VK_WHOLE_SIZE) ? mem_info->mem_range.size : (mem_info->alloc_info.allocationSize - mem_ranges[i].offset); char *data = static_cast(mem_info->shadow_copy); memcpy(data + mem_info->shadow_pad_size, mem_info->p_driver_data, (size_t)(size)); } } } static bool ValidateMappedMemoryRangeDeviceLimits(layer_data *dev_data, const char *func_name, uint32_t mem_range_count, const VkMappedMemoryRange *mem_ranges) { bool skip = false; for (uint32_t i = 0; i < mem_range_count; ++i) { uint64_t atom_size = dev_data->phys_dev_properties.properties.limits.nonCoherentAtomSize; if (vk_safe_modulo(mem_ranges[i].offset, atom_size) != 0) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_UNKNOWN_EXT, 0, __LINE__, VALIDATION_ERROR_00644, "MEM", "%s: Offset in pMemRanges[%d] is 0x%" PRIxLEAST64 ", which is not a multiple of VkPhysicalDeviceLimits::nonCoherentAtomSize (0x%" PRIxLEAST64 "). %s", func_name, i, mem_ranges[i].offset, atom_size, validation_error_map[VALIDATION_ERROR_00644]); } if ((mem_ranges[i].size != VK_WHOLE_SIZE) && (vk_safe_modulo(mem_ranges[i].size, atom_size) != 0)) { skip |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_UNKNOWN_EXT, 0, __LINE__, VALIDATION_ERROR_00645, "MEM", "%s: Size in pMemRanges[%d] is 0x%" PRIxLEAST64 ", which is not a multiple of VkPhysicalDeviceLimits::nonCoherentAtomSize (0x%" PRIxLEAST64 "). %s", func_name, i, mem_ranges[i].size, atom_size, validation_error_map[VALIDATION_ERROR_00645]); } } return skip; } static bool PreCallValidateFlushMappedMemoryRanges(layer_data *dev_data, uint32_t mem_range_count, const VkMappedMemoryRange *mem_ranges) { bool skip = false; std::lock_guard lock(global_lock); skip |= ValidateMappedMemoryRangeDeviceLimits(dev_data, "vkFlushMappedMemoryRanges", mem_range_count, mem_ranges); skip |= ValidateAndCopyNoncoherentMemoryToDriver(dev_data, mem_range_count, mem_ranges); skip |= validateMemoryIsMapped(dev_data, "vkFlushMappedMemoryRanges", mem_range_count, mem_ranges); return skip; } VKAPI_ATTR VkResult VKAPI_CALL FlushMappedMemoryRanges(VkDevice device, uint32_t memRangeCount, const VkMappedMemoryRange *pMemRanges) { VkResult result = VK_ERROR_VALIDATION_FAILED_EXT; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); if (!PreCallValidateFlushMappedMemoryRanges(dev_data, memRangeCount, pMemRanges)) { result = dev_data->dispatch_table.FlushMappedMemoryRanges(device, memRangeCount, pMemRanges); } return result; } static bool PreCallValidateInvalidateMappedMemoryRanges(layer_data *dev_data, uint32_t mem_range_count, const VkMappedMemoryRange *mem_ranges) { bool skip = false; std::lock_guard lock(global_lock); skip |= ValidateMappedMemoryRangeDeviceLimits(dev_data, "vkInvalidateMappedMemoryRanges", mem_range_count, mem_ranges); skip |= validateMemoryIsMapped(dev_data, "vkInvalidateMappedMemoryRanges", mem_range_count, mem_ranges); return skip; } static void PostCallRecordInvalidateMappedMemoryRanges(layer_data *dev_data, uint32_t mem_range_count, const VkMappedMemoryRange *mem_ranges) { std::lock_guard lock(global_lock); // Update our shadow copy with modified driver data CopyNoncoherentMemoryFromDriver(dev_data, mem_range_count, mem_ranges); } VKAPI_ATTR VkResult VKAPI_CALL InvalidateMappedMemoryRanges(VkDevice device, uint32_t memRangeCount, const VkMappedMemoryRange *pMemRanges) { VkResult result = VK_ERROR_VALIDATION_FAILED_EXT; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); if (!PreCallValidateInvalidateMappedMemoryRanges(dev_data, memRangeCount, pMemRanges)) { result = dev_data->dispatch_table.InvalidateMappedMemoryRanges(device, memRangeCount, pMemRanges); if (result == VK_SUCCESS) { PostCallRecordInvalidateMappedMemoryRanges(dev_data, memRangeCount, pMemRanges); } } return result; } VKAPI_ATTR VkResult VKAPI_CALL BindImageMemory(VkDevice device, VkImage image, VkDeviceMemory mem, VkDeviceSize memoryOffset) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = VK_ERROR_VALIDATION_FAILED_EXT; bool skip_call = false; std::unique_lock lock(global_lock); auto image_state = getImageState(dev_data, image); if (image_state) { // Track objects tied to memory uint64_t image_handle = reinterpret_cast(image); skip_call = SetMemBinding(dev_data, mem, image_handle, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, "vkBindImageMemory"); if (!image_state->memory_requirements_checked) { // There's not an explicit requirement in the spec to call vkGetImageMemoryRequirements() prior to calling // BindImageMemory but it's implied in that memory being bound must conform with VkMemoryRequirements from // vkGetImageMemoryRequirements() skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, image_handle, __LINE__, DRAWSTATE_INVALID_IMAGE, "DS", "vkBindBufferMemory(): Binding memory to image 0x%" PRIxLEAST64 " but vkGetImageMemoryRequirements() has not been called on that image.", image_handle); // Make the call for them so we can verify the state lock.unlock(); dev_data->dispatch_table.GetImageMemoryRequirements(device, image, &image_state->requirements); lock.lock(); } // Track and validate bound memory range information auto mem_info = getMemObjInfo(dev_data, mem); if (mem_info) { skip_call |= InsertImageMemoryRange(dev_data, image, mem_info, memoryOffset, image_state->requirements, image_state->createInfo.tiling == VK_IMAGE_TILING_LINEAR); skip_call |= ValidateMemoryTypes(dev_data, mem_info, image_state->requirements.memoryTypeBits, "vkBindImageMemory"); } print_mem_list(dev_data); lock.unlock(); if (!skip_call) { result = dev_data->dispatch_table.BindImageMemory(device, image, mem, memoryOffset); lock.lock(); image_state->binding.mem = mem; image_state->binding.offset = memoryOffset; image_state->binding.size = image_state->requirements.size; lock.unlock(); } } else { log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_MEMORY_EXT, reinterpret_cast(image), __LINE__, MEMTRACK_INVALID_OBJECT, "MT", "vkBindImageMemory: Cannot find invalid image 0x%" PRIx64 ", has it already been deleted?", reinterpret_cast(image)); } return result; } VKAPI_ATTR VkResult VKAPI_CALL SetEvent(VkDevice device, VkEvent event) { bool skip_call = false; VkResult result = VK_ERROR_VALIDATION_FAILED_EXT; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); std::unique_lock lock(global_lock); auto event_state = getEventNode(dev_data, event); if (event_state) { event_state->needsSignaled = false; event_state->stageMask = VK_PIPELINE_STAGE_HOST_BIT; if (event_state->write_in_use) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_EVENT_EXT, reinterpret_cast(event), __LINE__, DRAWSTATE_QUEUE_FORWARD_PROGRESS, "DS", "Cannot call vkSetEvent() on event 0x%" PRIxLEAST64 " that is already in use by a command buffer.", reinterpret_cast(event)); } } lock.unlock(); // Host setting event is visible to all queues immediately so update stageMask for any queue that's seen this event // TODO : For correctness this needs separate fix to verify that app doesn't make incorrect assumptions about the // ordering of this command in relation to vkCmd[Set|Reset]Events (see GH297) for (auto queue_data : dev_data->queueMap) { auto event_entry = queue_data.second.eventToStageMap.find(event); if (event_entry != queue_data.second.eventToStageMap.end()) { event_entry->second |= VK_PIPELINE_STAGE_HOST_BIT; } } if (!skip_call) result = dev_data->dispatch_table.SetEvent(device, event); return result; } VKAPI_ATTR VkResult VKAPI_CALL QueueBindSparse(VkQueue queue, uint32_t bindInfoCount, const VkBindSparseInfo *pBindInfo, VkFence fence) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(queue), layer_data_map); VkResult result = VK_ERROR_VALIDATION_FAILED_EXT; bool skip_call = false; std::unique_lock lock(global_lock); auto pFence = getFenceNode(dev_data, fence); auto pQueue = getQueueNode(dev_data, queue); // First verify that fence is not in use skip_call |= ValidateFenceForSubmit(dev_data, pFence); if (pFence) { SubmitFence(pQueue, pFence, bindInfoCount); } for (uint32_t bindIdx = 0; bindIdx < bindInfoCount; ++bindIdx) { const VkBindSparseInfo &bindInfo = pBindInfo[bindIdx]; // Track objects tied to memory for (uint32_t j = 0; j < bindInfo.bufferBindCount; j++) { for (uint32_t k = 0; k < bindInfo.pBufferBinds[j].bindCount; k++) { auto sparse_binding = bindInfo.pBufferBinds[j].pBinds[k]; if (SetSparseMemBinding(dev_data, {sparse_binding.memory, sparse_binding.memoryOffset, sparse_binding.size}, (uint64_t)bindInfo.pBufferBinds[j].buffer, VK_DEBUG_REPORT_OBJECT_TYPE_BUFFER_EXT, "vkQueueBindSparse")) skip_call = true; } } for (uint32_t j = 0; j < bindInfo.imageOpaqueBindCount; j++) { for (uint32_t k = 0; k < bindInfo.pImageOpaqueBinds[j].bindCount; k++) { auto sparse_binding = bindInfo.pImageOpaqueBinds[j].pBinds[k]; if (SetSparseMemBinding(dev_data, {sparse_binding.memory, sparse_binding.memoryOffset, sparse_binding.size}, (uint64_t)bindInfo.pImageOpaqueBinds[j].image, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, "vkQueueBindSparse")) skip_call = true; } } for (uint32_t j = 0; j < bindInfo.imageBindCount; j++) { for (uint32_t k = 0; k < bindInfo.pImageBinds[j].bindCount; k++) { auto sparse_binding = bindInfo.pImageBinds[j].pBinds[k]; // TODO: This size is broken for non-opaque bindings, need to update to comprehend full sparse binding data VkDeviceSize size = sparse_binding.extent.depth * sparse_binding.extent.height * sparse_binding.extent.width * 4; if (SetSparseMemBinding(dev_data, {sparse_binding.memory, sparse_binding.memoryOffset, size}, (uint64_t)bindInfo.pImageBinds[j].image, VK_DEBUG_REPORT_OBJECT_TYPE_IMAGE_EXT, "vkQueueBindSparse")) skip_call = true; } } std::vector semaphore_waits; std::vector semaphore_signals; for (uint32_t i = 0; i < bindInfo.waitSemaphoreCount; ++i) { VkSemaphore semaphore = bindInfo.pWaitSemaphores[i]; auto pSemaphore = getSemaphoreNode(dev_data, semaphore); if (pSemaphore) { if (pSemaphore->signaled) { if (pSemaphore->signaler.first != VK_NULL_HANDLE) { semaphore_waits.push_back({semaphore, pSemaphore->signaler.first, pSemaphore->signaler.second}); pSemaphore->in_use.fetch_add(1); } pSemaphore->signaler.first = VK_NULL_HANDLE; pSemaphore->signaled = false; } else { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_SEMAPHORE_EXT, reinterpret_cast(semaphore), __LINE__, DRAWSTATE_QUEUE_FORWARD_PROGRESS, "DS", "vkQueueBindSparse: Queue 0x%" PRIx64 " is waiting on semaphore 0x%" PRIx64 " that has no way to be signaled.", reinterpret_cast(queue), reinterpret_cast(semaphore)); } } } for (uint32_t i = 0; i < bindInfo.signalSemaphoreCount; ++i) { VkSemaphore semaphore = bindInfo.pSignalSemaphores[i]; auto pSemaphore = getSemaphoreNode(dev_data, semaphore); if (pSemaphore) { if (pSemaphore->signaled) { skip_call = log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_SEMAPHORE_EXT, reinterpret_cast(semaphore), __LINE__, DRAWSTATE_QUEUE_FORWARD_PROGRESS, "DS", "vkQueueBindSparse: Queue 0x%" PRIx64 " is signaling semaphore 0x%" PRIx64 ", but that semaphore is already signaled.", reinterpret_cast(queue), reinterpret_cast(semaphore)); } else { pSemaphore->signaler.first = queue; pSemaphore->signaler.second = pQueue->seq + pQueue->submissions.size() + 1; pSemaphore->signaled = true; pSemaphore->in_use.fetch_add(1); semaphore_signals.push_back(semaphore); } } } pQueue->submissions.emplace_back(std::vector(), semaphore_waits, semaphore_signals, bindIdx == bindInfoCount - 1 ? fence : VK_NULL_HANDLE); } if (pFence && !bindInfoCount) { // No work to do, just dropping a fence in the queue by itself. pQueue->submissions.emplace_back(std::vector(), std::vector(), std::vector(), fence); } print_mem_list(dev_data); lock.unlock(); if (!skip_call) return dev_data->dispatch_table.QueueBindSparse(queue, bindInfoCount, pBindInfo, fence); return result; } VKAPI_ATTR VkResult VKAPI_CALL CreateSemaphore(VkDevice device, const VkSemaphoreCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkSemaphore *pSemaphore) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = dev_data->dispatch_table.CreateSemaphore(device, pCreateInfo, pAllocator, pSemaphore); if (result == VK_SUCCESS) { std::lock_guard lock(global_lock); SEMAPHORE_NODE* sNode = &dev_data->semaphoreMap[*pSemaphore]; sNode->signaler.first = VK_NULL_HANDLE; sNode->signaler.second = 0; sNode->signaled = false; } return result; } VKAPI_ATTR VkResult VKAPI_CALL CreateEvent(VkDevice device, const VkEventCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkEvent *pEvent) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = dev_data->dispatch_table.CreateEvent(device, pCreateInfo, pAllocator, pEvent); if (result == VK_SUCCESS) { std::lock_guard lock(global_lock); dev_data->eventMap[*pEvent].needsSignaled = false; dev_data->eventMap[*pEvent].write_in_use = 0; dev_data->eventMap[*pEvent].stageMask = VkPipelineStageFlags(0); } return result; } static bool PreCallValidateCreateSwapchainKHR(layer_data *dev_data, VkSwapchainCreateInfoKHR const *pCreateInfo, SURFACE_STATE *surface_state, SWAPCHAIN_NODE *old_swapchain_state) { auto most_recent_swapchain = surface_state->swapchain ? surface_state->swapchain : surface_state->old_swapchain; if (most_recent_swapchain != old_swapchain_state || (surface_state->old_swapchain && surface_state->swapchain)) { if (log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_EXT, reinterpret_cast(dev_data->device), __LINE__, DRAWSTATE_SWAPCHAIN_ALREADY_EXISTS, "DS", "vkCreateSwapchainKHR(): surface has an existing swapchain other than oldSwapchain")) return true; } if (old_swapchain_state && old_swapchain_state->createInfo.surface != pCreateInfo->surface) { if (log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_SWAPCHAIN_KHR_EXT, reinterpret_cast(pCreateInfo->oldSwapchain), __LINE__, DRAWSTATE_SWAPCHAIN_WRONG_SURFACE, "DS", "vkCreateSwapchainKHR(): pCreateInfo->oldSwapchain's surface is not pCreateInfo->surface")) return true; } return false; } VKAPI_ATTR VkResult VKAPI_CALL CreateSwapchainKHR(VkDevice device, const VkSwapchainCreateInfoKHR *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkSwapchainKHR *pSwapchain) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); auto surface_state = getSurfaceState(dev_data->instance_data, pCreateInfo->surface); auto old_swapchain_state = getSwapchainNode(dev_data, pCreateInfo->oldSwapchain); if (PreCallValidateCreateSwapchainKHR(dev_data, pCreateInfo, surface_state, old_swapchain_state)) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult result = dev_data->dispatch_table.CreateSwapchainKHR(device, pCreateInfo, pAllocator, pSwapchain); if (VK_SUCCESS == result) { std::lock_guard lock(global_lock); auto swapchain_state = unique_ptr(new SWAPCHAIN_NODE(pCreateInfo, *pSwapchain)); surface_state->swapchain = swapchain_state.get(); dev_data->device_extensions.swapchainMap[*pSwapchain] = std::move(swapchain_state); } else { surface_state->swapchain = nullptr; } // Spec requires that even if CreateSwapchainKHR fails, oldSwapchain behaves as replaced. surface_state->old_swapchain = old_swapchain_state; return result; } VKAPI_ATTR void VKAPI_CALL DestroySwapchainKHR(VkDevice device, VkSwapchainKHR swapchain, const VkAllocationCallbacks *pAllocator) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); bool skip_call = false; std::unique_lock lock(global_lock); auto swapchain_data = getSwapchainNode(dev_data, swapchain); if (swapchain_data) { if (swapchain_data->images.size() > 0) { for (auto swapchain_image : swapchain_data->images) { auto image_sub = dev_data->imageSubresourceMap.find(swapchain_image); if (image_sub != dev_data->imageSubresourceMap.end()) { for (auto imgsubpair : image_sub->second) { auto image_item = dev_data->imageLayoutMap.find(imgsubpair); if (image_item != dev_data->imageLayoutMap.end()) { dev_data->imageLayoutMap.erase(image_item); } } dev_data->imageSubresourceMap.erase(image_sub); } skip_call = ClearMemoryObjectBindings(dev_data, (uint64_t)swapchain_image, VK_DEBUG_REPORT_OBJECT_TYPE_SWAPCHAIN_KHR_EXT); dev_data->imageMap.erase(swapchain_image); } } auto surface_state = getSurfaceState(dev_data->instance_data, swapchain_data->createInfo.surface); if (surface_state) { if (surface_state->swapchain == swapchain_data) surface_state->swapchain = nullptr; if (surface_state->old_swapchain == swapchain_data) surface_state->old_swapchain = nullptr; } dev_data->device_extensions.swapchainMap.erase(swapchain); } lock.unlock(); if (!skip_call) dev_data->dispatch_table.DestroySwapchainKHR(device, swapchain, pAllocator); } VKAPI_ATTR VkResult VKAPI_CALL GetSwapchainImagesKHR(VkDevice device, VkSwapchainKHR swapchain, uint32_t *pCount, VkImage *pSwapchainImages) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); VkResult result = dev_data->dispatch_table.GetSwapchainImagesKHR(device, swapchain, pCount, pSwapchainImages); if (result == VK_SUCCESS && pSwapchainImages != NULL) { // This should never happen and is checked by param checker. if (!pCount) return result; std::lock_guard lock(global_lock); const size_t count = *pCount; auto swapchain_node = getSwapchainNode(dev_data, swapchain); if (swapchain_node && !swapchain_node->images.empty()) { // TODO : Not sure I like the memcmp here, but it works const bool mismatch = (swapchain_node->images.size() != count || memcmp(&swapchain_node->images[0], pSwapchainImages, sizeof(swapchain_node->images[0]) * count)); if (mismatch) { // TODO: Verify against Valid Usage section of extension log_msg(dev_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_SWAPCHAIN_KHR_EXT, (uint64_t)swapchain, __LINE__, MEMTRACK_NONE, "SWAP_CHAIN", "vkGetSwapchainInfoKHR(0x%" PRIx64 ", VK_SWAP_CHAIN_INFO_TYPE_PERSISTENT_IMAGES_KHR) returned mismatching data", (uint64_t)(swapchain)); } } for (uint32_t i = 0; i < *pCount; ++i) { IMAGE_LAYOUT_NODE image_layout_node; image_layout_node.layout = VK_IMAGE_LAYOUT_UNDEFINED; image_layout_node.format = swapchain_node->createInfo.imageFormat; // Add imageMap entries for each swapchain image VkImageCreateInfo image_ci = {}; image_ci.mipLevels = 1; image_ci.arrayLayers = swapchain_node->createInfo.imageArrayLayers; image_ci.usage = swapchain_node->createInfo.imageUsage; image_ci.format = swapchain_node->createInfo.imageFormat; image_ci.samples = VK_SAMPLE_COUNT_1_BIT; image_ci.extent.width = swapchain_node->createInfo.imageExtent.width; image_ci.extent.height = swapchain_node->createInfo.imageExtent.height; image_ci.sharingMode = swapchain_node->createInfo.imageSharingMode; dev_data->imageMap[pSwapchainImages[i]] = unique_ptr(new IMAGE_STATE(pSwapchainImages[i], &image_ci)); auto &image_state = dev_data->imageMap[pSwapchainImages[i]]; image_state->valid = false; image_state->binding.mem = MEMTRACKER_SWAP_CHAIN_IMAGE_KEY; swapchain_node->images.push_back(pSwapchainImages[i]); ImageSubresourcePair subpair = {pSwapchainImages[i], false, VkImageSubresource()}; dev_data->imageSubresourceMap[pSwapchainImages[i]].push_back(subpair); dev_data->imageLayoutMap[subpair] = image_layout_node; dev_data->device_extensions.imageToSwapchainMap[pSwapchainImages[i]] = swapchain; } } return result; } VKAPI_ATTR VkResult VKAPI_CALL QueuePresentKHR(VkQueue queue, const VkPresentInfoKHR *pPresentInfo) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(queue), layer_data_map); bool skip_call = false; std::lock_guard lock(global_lock); for (uint32_t i = 0; i < pPresentInfo->waitSemaphoreCount; ++i) { auto pSemaphore = getSemaphoreNode(dev_data, pPresentInfo->pWaitSemaphores[i]); if (pSemaphore && !pSemaphore->signaled) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_COMMAND_BUFFER_EXT, 0, __LINE__, DRAWSTATE_QUEUE_FORWARD_PROGRESS, "DS", "Queue 0x%" PRIx64 " is waiting on semaphore 0x%" PRIx64 " that has no way to be signaled.", reinterpret_cast(queue), reinterpret_cast(pPresentInfo->pWaitSemaphores[i])); } } for (uint32_t i = 0; i < pPresentInfo->swapchainCount; ++i) { auto swapchain_data = getSwapchainNode(dev_data, pPresentInfo->pSwapchains[i]); if (swapchain_data) { if (pPresentInfo->pImageIndices[i] >= swapchain_data->images.size()) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_SWAPCHAIN_KHR_EXT, reinterpret_cast(pPresentInfo->pSwapchains[i]), __LINE__, DRAWSTATE_SWAPCHAIN_INVALID_IMAGE, "DS", "vkQueuePresentKHR: Swapchain image index too large (%u). There are only %u images in this swapchain.", pPresentInfo->pImageIndices[i], (uint32_t)swapchain_data->images.size()); } else { auto image = swapchain_data->images[pPresentInfo->pImageIndices[i]]; auto image_state = getImageState(dev_data, image); skip_call |= ValidateImageMemoryIsValid(dev_data, image_state, "vkQueuePresentKHR()"); if (!image_state->acquired) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_SWAPCHAIN_KHR_EXT, reinterpret_cast(pPresentInfo->pSwapchains[i]), __LINE__, DRAWSTATE_SWAPCHAIN_IMAGE_NOT_ACQUIRED, "DS", "vkQueuePresentKHR: Swapchain image index %u has not been acquired.", pPresentInfo->pImageIndices[i]); } vector layouts; if (FindLayouts(dev_data, image, layouts)) { for (auto layout : layouts) { if (layout != VK_IMAGE_LAYOUT_PRESENT_SRC_KHR) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_QUEUE_EXT, reinterpret_cast(queue), __LINE__, DRAWSTATE_INVALID_IMAGE_LAYOUT, "DS", "Images passed to present must be in layout " "VK_IMAGE_LAYOUT_PRESENT_SRC_KHR but is in %s", string_VkImageLayout(layout)); } } } } } } if (skip_call) { return VK_ERROR_VALIDATION_FAILED_EXT; } VkResult result = dev_data->dispatch_table.QueuePresentKHR(queue, pPresentInfo); if (result != VK_ERROR_VALIDATION_FAILED_EXT) { // Semaphore waits occur before error generation, if the call reached // the ICD. (Confirm?) for (uint32_t i = 0; i < pPresentInfo->waitSemaphoreCount; ++i) { auto pSemaphore = getSemaphoreNode(dev_data, pPresentInfo->pWaitSemaphores[i]); if (pSemaphore) { pSemaphore->signaler.first = VK_NULL_HANDLE; pSemaphore->signaled = false; } } for (uint32_t i = 0; i < pPresentInfo->swapchainCount; ++i) { // Note: this is imperfect, in that we can get confused about what // did or didn't succeed-- but if the app does that, it's confused // itself just as much. auto local_result = pPresentInfo->pResults ? pPresentInfo->pResults[i] : result; if (local_result != VK_SUCCESS && local_result != VK_SUBOPTIMAL_KHR) continue; // this present didn't actually happen. // Mark the image as having been released to the WSI auto swapchain_data = getSwapchainNode(dev_data, pPresentInfo->pSwapchains[i]); auto image = swapchain_data->images[pPresentInfo->pImageIndices[i]]; auto image_state = getImageState(dev_data, image); image_state->acquired = false; } // Note: even though presentation is directed to a queue, there is no // direct ordering between QP and subsequent work, so QP (and its // semaphore waits) /never/ participate in any completion proof. } return result; } VKAPI_ATTR VkResult VKAPI_CALL CreateSharedSwapchainsKHR(VkDevice device, uint32_t swapchainCount, const VkSwapchainCreateInfoKHR *pCreateInfos, const VkAllocationCallbacks *pAllocator, VkSwapchainKHR *pSwapchains) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); std::unique_lock lock(global_lock); VkResult result = dev_data->dispatch_table.CreateSharedSwapchainsKHR(device, swapchainCount, pCreateInfos, pAllocator, pSwapchains); return result; } VKAPI_ATTR VkResult VKAPI_CALL AcquireNextImageKHR(VkDevice device, VkSwapchainKHR swapchain, uint64_t timeout, VkSemaphore semaphore, VkFence fence, uint32_t *pImageIndex) { layer_data *dev_data = get_my_data_ptr(get_dispatch_key(device), layer_data_map); bool skip_call = false; std::unique_lock lock(global_lock); if (fence == VK_NULL_HANDLE && semaphore == VK_NULL_HANDLE) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_EXT, reinterpret_cast(device), __LINE__, DRAWSTATE_SWAPCHAIN_NO_SYNC_FOR_ACQUIRE, "DS", "vkAcquireNextImageKHR: Semaphore and fence cannot both be VK_NULL_HANDLE. There would be no way " "to determine the completion of this operation."); } auto pSemaphore = getSemaphoreNode(dev_data, semaphore); if (pSemaphore && pSemaphore->signaled) { skip_call |= log_msg(dev_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_SEMAPHORE_EXT, reinterpret_cast(semaphore), __LINE__, DRAWSTATE_QUEUE_FORWARD_PROGRESS, "DS", "vkAcquireNextImageKHR: Semaphore must not be currently signaled or in a wait state"); } auto pFence = getFenceNode(dev_data, fence); if (pFence) { skip_call |= ValidateFenceForSubmit(dev_data, pFence); } lock.unlock(); if (skip_call) return VK_ERROR_VALIDATION_FAILED_EXT; VkResult result = dev_data->dispatch_table.AcquireNextImageKHR(device, swapchain, timeout, semaphore, fence, pImageIndex); lock.lock(); if (result == VK_SUCCESS || result == VK_SUBOPTIMAL_KHR) { if (pFence) { pFence->state = FENCE_INFLIGHT; pFence->signaler.first = VK_NULL_HANDLE; // ANI isn't on a queue, so this can't participate in a completion proof. } // A successful call to AcquireNextImageKHR counts as a signal operation on semaphore if (pSemaphore) { pSemaphore->signaled = true; pSemaphore->signaler.first = VK_NULL_HANDLE; } // Mark the image as acquired. auto swapchain_data = getSwapchainNode(dev_data, swapchain); auto image = swapchain_data->images[*pImageIndex]; auto image_state = getImageState(dev_data, image); image_state->acquired = true; } lock.unlock(); return result; } VKAPI_ATTR VkResult VKAPI_CALL EnumeratePhysicalDevices(VkInstance instance, uint32_t *pPhysicalDeviceCount, VkPhysicalDevice *pPhysicalDevices) { bool skip_call = false; instance_layer_data *instance_data = get_my_data_ptr(get_dispatch_key(instance), instance_layer_data_map); if (instance_data) { // For this instance, flag when vkEnumeratePhysicalDevices goes to QUERY_COUNT and then QUERY_DETAILS if (NULL == pPhysicalDevices) { instance_data->vkEnumeratePhysicalDevicesState = QUERY_COUNT; } else { if (UNCALLED == instance_data->vkEnumeratePhysicalDevicesState) { // Flag warning here. You can call this without having queried the count, but it may not be // robust on platforms with multiple physical devices. skip_call |= log_msg(instance_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_INSTANCE_EXT, 0, __LINE__, DEVLIMITS_MISSING_QUERY_COUNT, "DL", "Call sequence has vkEnumeratePhysicalDevices() w/ non-NULL pPhysicalDevices. You should first " "call vkEnumeratePhysicalDevices() w/ NULL pPhysicalDevices to query pPhysicalDeviceCount."); } // TODO : Could also flag a warning if re-calling this function in QUERY_DETAILS state else if (instance_data->physical_devices_count != *pPhysicalDeviceCount) { // Having actual count match count from app is not a requirement, so this can be a warning skip_call |= log_msg(instance_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PHYSICAL_DEVICE_EXT, 0, __LINE__, DEVLIMITS_COUNT_MISMATCH, "DL", "Call to vkEnumeratePhysicalDevices() w/ pPhysicalDeviceCount value %u, but actual count " "supported by this instance is %u.", *pPhysicalDeviceCount, instance_data->physical_devices_count); } instance_data->vkEnumeratePhysicalDevicesState = QUERY_DETAILS; } if (skip_call) { return VK_ERROR_VALIDATION_FAILED_EXT; } VkResult result = instance_data->dispatch_table.EnumeratePhysicalDevices(instance, pPhysicalDeviceCount, pPhysicalDevices); if (NULL == pPhysicalDevices) { instance_data->physical_devices_count = *pPhysicalDeviceCount; } else if (result == VK_SUCCESS){ // Save physical devices for (uint32_t i = 0; i < *pPhysicalDeviceCount; i++) { auto & phys_device_state = instance_data->physical_device_map[pPhysicalDevices[i]]; phys_device_state.phys_device = pPhysicalDevices[i]; // Init actual features for each physical device instance_data->dispatch_table.GetPhysicalDeviceFeatures(pPhysicalDevices[i], &phys_device_state.features); } } return result; } else { log_msg(instance_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_INSTANCE_EXT, 0, __LINE__, DEVLIMITS_INVALID_INSTANCE, "DL", "Invalid instance (0x%" PRIxLEAST64 ") passed into vkEnumeratePhysicalDevices().", (uint64_t)instance); } return VK_ERROR_VALIDATION_FAILED_EXT; } VKAPI_ATTR void VKAPI_CALL GetPhysicalDeviceQueueFamilyProperties(VkPhysicalDevice physicalDevice, uint32_t *pCount, VkQueueFamilyProperties *pQueueFamilyProperties) { bool skip_call = false; instance_layer_data *instance_data = get_my_data_ptr(get_dispatch_key(physicalDevice), instance_layer_data_map); auto physical_device_state = getPhysicalDeviceState(instance_data, physicalDevice); if (physical_device_state) { if (!pQueueFamilyProperties) { physical_device_state->vkGetPhysicalDeviceQueueFamilyPropertiesState = QUERY_COUNT; } else { // Verify that for each physical device, this function is called first with NULL pQueueFamilyProperties ptr in order to // get count if (UNCALLED == physical_device_state->vkGetPhysicalDeviceQueueFamilyPropertiesState) { skip_call |= log_msg(instance_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PHYSICAL_DEVICE_EXT, 0, __LINE__, DEVLIMITS_MISSING_QUERY_COUNT, "DL", "Call sequence has vkGetPhysicalDeviceQueueFamilyProperties() w/ non-NULL " "pQueueFamilyProperties. You should first call vkGetPhysicalDeviceQueueFamilyProperties() w/ " "NULL pQueueFamilyProperties to query pCount."); } // Then verify that pCount that is passed in on second call matches what was returned if (physical_device_state->queueFamilyPropertiesCount != *pCount) { // TODO: this is not a requirement of the Valid Usage section for vkGetPhysicalDeviceQueueFamilyProperties, so // provide as warning skip_call |= log_msg(instance_data->report_data, VK_DEBUG_REPORT_WARNING_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PHYSICAL_DEVICE_EXT, 0, __LINE__, DEVLIMITS_COUNT_MISMATCH, "DL", "Call to vkGetPhysicalDeviceQueueFamilyProperties() w/ pCount value %u, but actual count " "supported by this physicalDevice is %u.", *pCount, physical_device_state->queueFamilyPropertiesCount); } physical_device_state->vkGetPhysicalDeviceQueueFamilyPropertiesState = QUERY_DETAILS; } if (skip_call) { return; } instance_data->dispatch_table.GetPhysicalDeviceQueueFamilyProperties(physicalDevice, pCount, pQueueFamilyProperties); if (!pQueueFamilyProperties) { physical_device_state->queueFamilyPropertiesCount = *pCount; } else { // Save queue family properties if (physical_device_state->queue_family_properties.size() < *pCount) physical_device_state->queue_family_properties.resize(*pCount); for (uint32_t i = 0; i < *pCount; i++) { physical_device_state->queue_family_properties[i] = pQueueFamilyProperties[i]; } } } else { log_msg(instance_data->report_data, VK_DEBUG_REPORT_ERROR_BIT_EXT, VK_DEBUG_REPORT_OBJECT_TYPE_PHYSICAL_DEVICE_EXT, 0, __LINE__, DEVLIMITS_INVALID_PHYSICAL_DEVICE, "DL", "Invalid physicalDevice (0x%" PRIxLEAST64 ") passed into vkGetPhysicalDeviceQueueFamilyProperties().", (uint64_t)physicalDevice); } } template static VkResult CreateSurface(VkInstance instance, TCreateInfo const *pCreateInfo, VkAllocationCallbacks const *pAllocator, VkSurfaceKHR *pSurface, FPtr fptr) { instance_layer_data *instance_data = get_my_data_ptr(get_dispatch_key(instance), instance_layer_data_map); // Call down the call chain: VkResult result = (instance_data->dispatch_table.*fptr)(instance, pCreateInfo, pAllocator, pSurface); if (result == VK_SUCCESS) { std::unique_lock lock(global_lock); instance_data->surface_map[*pSurface] = SURFACE_STATE(*pSurface); lock.unlock(); } return result; } VKAPI_ATTR void VKAPI_CALL DestroySurfaceKHR(VkInstance instance, VkSurfaceKHR surface, const VkAllocationCallbacks *pAllocator) { bool skip_call = false; instance_layer_data *instance_data = get_my_data_ptr(get_dispatch_key(instance), instance_layer_data_map); std::unique_lock lock(global_lock); auto surface_state = getSurfaceState(instance_data, surface); if (surface_state) { // TODO: track swapchains created from this surface. instance_data->surface_map.erase(surface); } lock.unlock(); if (!skip_call) { // Call down the call chain: instance_data->dispatch_table.DestroySurfaceKHR(instance, surface, pAllocator); } } #ifdef VK_USE_PLATFORM_ANDROID_KHR VKAPI_ATTR VkResult VKAPI_CALL CreateAndroidSurfaceKHR(VkInstance instance, const VkAndroidSurfaceCreateInfoKHR *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkSurfaceKHR *pSurface) { return CreateSurface(instance, pCreateInfo, pAllocator, pSurface, &VkLayerInstanceDispatchTable::CreateAndroidSurfaceKHR); } #endif // VK_USE_PLATFORM_ANDROID_KHR #ifdef VK_USE_PLATFORM_MIR_KHR VKAPI_ATTR VkResult VKAPI_CALL CreateMirSurfaceKHR(VkInstance instance, const VkMirSurfaceCreateInfoKHR *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkSurfaceKHR *pSurface) { return CreateSurface(instance, pCreateInfo, pAllocator, pSurface, &VkLayerInstanceDispatchTable::CreateMirSurfaceKHR); } #endif // VK_USE_PLATFORM_MIR_KHR #ifdef VK_USE_PLATFORM_WAYLAND_KHR VKAPI_ATTR VkResult VKAPI_CALL CreateWaylandSurfaceKHR(VkInstance instance, const VkWaylandSurfaceCreateInfoKHR *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkSurfaceKHR *pSurface) { return CreateSurface(instance, pCreateInfo, pAllocator, pSurface, &VkLayerInstanceDispatchTable::CreateWaylandSurfaceKHR); } #endif // VK_USE_PLATFORM_WAYLAND_KHR #ifdef VK_USE_PLATFORM_WIN32_KHR VKAPI_ATTR VkResult VKAPI_CALL CreateWin32SurfaceKHR(VkInstance instance, const VkWin32SurfaceCreateInfoKHR *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkSurfaceKHR *pSurface) { return CreateSurface(instance, pCreateInfo, pAllocator, pSurface, &VkLayerInstanceDispatchTable::CreateWin32SurfaceKHR); } #endif // VK_USE_PLATFORM_WIN32_KHR #ifdef VK_USE_PLATFORM_XCB_KHR VKAPI_ATTR VkResult VKAPI_CALL CreateXcbSurfaceKHR(VkInstance instance, const VkXcbSurfaceCreateInfoKHR *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkSurfaceKHR *pSurface) { return CreateSurface(instance, pCreateInfo, pAllocator, pSurface, &VkLayerInstanceDispatchTable::CreateXcbSurfaceKHR); } #endif // VK_USE_PLATFORM_XCB_KHR #ifdef VK_USE_PLATFORM_XLIB_KHR VKAPI_ATTR VkResult VKAPI_CALL CreateXlibSurfaceKHR(VkInstance instance, const VkXlibSurfaceCreateInfoKHR *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkSurfaceKHR *pSurface) { return CreateSurface(instance, pCreateInfo, pAllocator, pSurface, &VkLayerInstanceDispatchTable::CreateXlibSurfaceKHR); } #endif // VK_USE_PLATFORM_XLIB_KHR VKAPI_ATTR VkResult VKAPI_CALL CreateDebugReportCallbackEXT(VkInstance instance, const VkDebugReportCallbackCreateInfoEXT *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkDebugReportCallbackEXT *pMsgCallback) { instance_layer_data *instance_data = get_my_data_ptr(get_dispatch_key(instance), instance_layer_data_map); VkResult res = instance_data->dispatch_table.CreateDebugReportCallbackEXT(instance, pCreateInfo, pAllocator, pMsgCallback); if (VK_SUCCESS == res) { std::lock_guard lock(global_lock); res = layer_create_msg_callback(instance_data->report_data, false, pCreateInfo, pAllocator, pMsgCallback); } return res; } VKAPI_ATTR void VKAPI_CALL DestroyDebugReportCallbackEXT(VkInstance instance, VkDebugReportCallbackEXT msgCallback, const VkAllocationCallbacks *pAllocator) { instance_layer_data *instance_data = get_my_data_ptr(get_dispatch_key(instance), instance_layer_data_map); instance_data->dispatch_table.DestroyDebugReportCallbackEXT(instance, msgCallback, pAllocator); std::lock_guard lock(global_lock); layer_destroy_msg_callback(instance_data->report_data, msgCallback, pAllocator); } VKAPI_ATTR void VKAPI_CALL DebugReportMessageEXT(VkInstance instance, VkDebugReportFlagsEXT flags, VkDebugReportObjectTypeEXT objType, uint64_t object, size_t location, int32_t msgCode, const char *pLayerPrefix, const char *pMsg) { instance_layer_data *instance_data = get_my_data_ptr(get_dispatch_key(instance), instance_layer_data_map); instance_data->dispatch_table.DebugReportMessageEXT(instance, flags, objType, object, location, msgCode, pLayerPrefix, pMsg); } VKAPI_ATTR VkResult VKAPI_CALL EnumerateInstanceLayerProperties(uint32_t *pCount, VkLayerProperties *pProperties) { return util_GetLayerProperties(1, &global_layer, pCount, pProperties); } VKAPI_ATTR VkResult VKAPI_CALL EnumerateDeviceLayerProperties(VkPhysicalDevice physicalDevice, uint32_t *pCount, VkLayerProperties *pProperties) { return util_GetLayerProperties(1, &global_layer, pCount, pProperties); } VKAPI_ATTR VkResult VKAPI_CALL EnumerateInstanceExtensionProperties(const char *pLayerName, uint32_t *pCount, VkExtensionProperties *pProperties) { if (pLayerName && !strcmp(pLayerName, global_layer.layerName)) return util_GetExtensionProperties(1, instance_extensions, pCount, pProperties); return VK_ERROR_LAYER_NOT_PRESENT; } VKAPI_ATTR VkResult VKAPI_CALL EnumerateDeviceExtensionProperties(VkPhysicalDevice physicalDevice, const char *pLayerName, uint32_t *pCount, VkExtensionProperties *pProperties) { if (pLayerName && !strcmp(pLayerName, global_layer.layerName)) return util_GetExtensionProperties(0, NULL, pCount, pProperties); assert(physicalDevice); instance_layer_data *instance_data = get_my_data_ptr(get_dispatch_key(physicalDevice), instance_layer_data_map); return instance_data->dispatch_table.EnumerateDeviceExtensionProperties(physicalDevice, NULL, pCount, pProperties); } static PFN_vkVoidFunction intercept_core_instance_command(const char *name); static PFN_vkVoidFunction intercept_core_device_command(const char *name); static PFN_vkVoidFunction intercept_khr_swapchain_command(const char *name, VkDevice dev); static PFN_vkVoidFunction intercept_khr_surface_command(const char *name, VkInstance instance); VKAPI_ATTR PFN_vkVoidFunction VKAPI_CALL GetDeviceProcAddr(VkDevice dev, const char *funcName) { PFN_vkVoidFunction proc = intercept_core_device_command(funcName); if (proc) return proc; assert(dev); proc = intercept_khr_swapchain_command(funcName, dev); if (proc) return proc; layer_data *dev_data = get_my_data_ptr(get_dispatch_key(dev), layer_data_map); auto &table = dev_data->dispatch_table; if (!table.GetDeviceProcAddr) return nullptr; return table.GetDeviceProcAddr(dev, funcName); } VKAPI_ATTR PFN_vkVoidFunction VKAPI_CALL GetInstanceProcAddr(VkInstance instance, const char *funcName) { PFN_vkVoidFunction proc = intercept_core_instance_command(funcName); if (!proc) proc = intercept_core_device_command(funcName); if (!proc) proc = intercept_khr_swapchain_command(funcName, VK_NULL_HANDLE); if (!proc) proc = intercept_khr_surface_command(funcName, instance); if (proc) return proc; assert(instance); instance_layer_data *instance_data = get_my_data_ptr(get_dispatch_key(instance), instance_layer_data_map); proc = debug_report_get_instance_proc_addr(instance_data->report_data, funcName); if (proc) return proc; auto &table = instance_data->dispatch_table; if (!table.GetInstanceProcAddr) return nullptr; return table.GetInstanceProcAddr(instance, funcName); } static PFN_vkVoidFunction intercept_core_instance_command(const char *name) { static const struct { const char *name; PFN_vkVoidFunction proc; } core_instance_commands[] = { { "vkGetInstanceProcAddr", reinterpret_cast(GetInstanceProcAddr) }, { "vkGetDeviceProcAddr", reinterpret_cast(GetDeviceProcAddr) }, { "vkCreateInstance", reinterpret_cast(CreateInstance) }, { "vkCreateDevice", reinterpret_cast(CreateDevice) }, { "vkEnumeratePhysicalDevices", reinterpret_cast(EnumeratePhysicalDevices) }, { "vkGetPhysicalDeviceQueueFamilyProperties", reinterpret_cast(GetPhysicalDeviceQueueFamilyProperties) }, { "vkDestroyInstance", reinterpret_cast(DestroyInstance) }, { "vkEnumerateInstanceLayerProperties", reinterpret_cast(EnumerateInstanceLayerProperties) }, { "vkEnumerateDeviceLayerProperties", reinterpret_cast(EnumerateDeviceLayerProperties) }, { "vkEnumerateInstanceExtensionProperties", reinterpret_cast(EnumerateInstanceExtensionProperties) }, { "vkEnumerateDeviceExtensionProperties", reinterpret_cast(EnumerateDeviceExtensionProperties) }, }; for (size_t i = 0; i < ARRAY_SIZE(core_instance_commands); i++) { if (!strcmp(core_instance_commands[i].name, name)) return core_instance_commands[i].proc; } return nullptr; } static PFN_vkVoidFunction intercept_core_device_command(const char *name) { static const struct { const char *name; PFN_vkVoidFunction proc; } core_device_commands[] = { {"vkGetDeviceProcAddr", reinterpret_cast(GetDeviceProcAddr)}, {"vkQueueSubmit", reinterpret_cast(QueueSubmit)}, {"vkWaitForFences", reinterpret_cast(WaitForFences)}, {"vkGetFenceStatus", reinterpret_cast(GetFenceStatus)}, {"vkQueueWaitIdle", reinterpret_cast(QueueWaitIdle)}, {"vkDeviceWaitIdle", reinterpret_cast(DeviceWaitIdle)}, {"vkGetDeviceQueue", reinterpret_cast(GetDeviceQueue)}, {"vkDestroyInstance", reinterpret_cast(DestroyInstance)}, {"vkDestroyDevice", reinterpret_cast(DestroyDevice)}, {"vkDestroyFence", reinterpret_cast(DestroyFence)}, {"vkResetFences", reinterpret_cast(ResetFences)}, {"vkDestroySemaphore", reinterpret_cast(DestroySemaphore)}, {"vkDestroyEvent", reinterpret_cast(DestroyEvent)}, {"vkDestroyQueryPool", reinterpret_cast(DestroyQueryPool)}, {"vkDestroyBuffer", reinterpret_cast(DestroyBuffer)}, {"vkDestroyBufferView", reinterpret_cast(DestroyBufferView)}, {"vkDestroyImage", reinterpret_cast(DestroyImage)}, {"vkDestroyImageView", reinterpret_cast(DestroyImageView)}, {"vkDestroyShaderModule", reinterpret_cast(DestroyShaderModule)}, {"vkDestroyPipeline", reinterpret_cast(DestroyPipeline)}, {"vkDestroyPipelineLayout", reinterpret_cast(DestroyPipelineLayout)}, {"vkDestroySampler", reinterpret_cast(DestroySampler)}, {"vkDestroyDescriptorSetLayout", reinterpret_cast(DestroyDescriptorSetLayout)}, {"vkDestroyDescriptorPool", reinterpret_cast(DestroyDescriptorPool)}, {"vkDestroyFramebuffer", reinterpret_cast(DestroyFramebuffer)}, {"vkDestroyRenderPass", reinterpret_cast(DestroyRenderPass)}, {"vkCreateBuffer", reinterpret_cast(CreateBuffer)}, {"vkCreateBufferView", reinterpret_cast(CreateBufferView)}, {"vkCreateImage", reinterpret_cast(CreateImage)}, {"vkCreateImageView", reinterpret_cast(CreateImageView)}, {"vkCreateFence", reinterpret_cast(CreateFence)}, {"vkCreatePipelineCache", reinterpret_cast(CreatePipelineCache)}, {"vkDestroyPipelineCache", reinterpret_cast(DestroyPipelineCache)}, {"vkGetPipelineCacheData", reinterpret_cast(GetPipelineCacheData)}, {"vkMergePipelineCaches", reinterpret_cast(MergePipelineCaches)}, {"vkCreateGraphicsPipelines", reinterpret_cast(CreateGraphicsPipelines)}, {"vkCreateComputePipelines", reinterpret_cast(CreateComputePipelines)}, {"vkCreateSampler", reinterpret_cast(CreateSampler)}, {"vkCreateDescriptorSetLayout", reinterpret_cast(CreateDescriptorSetLayout)}, {"vkCreatePipelineLayout", reinterpret_cast(CreatePipelineLayout)}, {"vkCreateDescriptorPool", reinterpret_cast(CreateDescriptorPool)}, {"vkResetDescriptorPool", reinterpret_cast(ResetDescriptorPool)}, {"vkAllocateDescriptorSets", reinterpret_cast(AllocateDescriptorSets)}, {"vkFreeDescriptorSets", reinterpret_cast(FreeDescriptorSets)}, {"vkUpdateDescriptorSets", reinterpret_cast(UpdateDescriptorSets)}, {"vkCreateCommandPool", reinterpret_cast(CreateCommandPool)}, {"vkDestroyCommandPool", reinterpret_cast(DestroyCommandPool)}, {"vkResetCommandPool", reinterpret_cast(ResetCommandPool)}, {"vkCreateQueryPool", reinterpret_cast(CreateQueryPool)}, {"vkAllocateCommandBuffers", reinterpret_cast(AllocateCommandBuffers)}, {"vkFreeCommandBuffers", reinterpret_cast(FreeCommandBuffers)}, {"vkBeginCommandBuffer", reinterpret_cast(BeginCommandBuffer)}, {"vkEndCommandBuffer", reinterpret_cast(EndCommandBuffer)}, {"vkResetCommandBuffer", reinterpret_cast(ResetCommandBuffer)}, {"vkCmdBindPipeline", reinterpret_cast(CmdBindPipeline)}, {"vkCmdSetViewport", reinterpret_cast(CmdSetViewport)}, {"vkCmdSetScissor", reinterpret_cast(CmdSetScissor)}, {"vkCmdSetLineWidth", reinterpret_cast(CmdSetLineWidth)}, {"vkCmdSetDepthBias", reinterpret_cast(CmdSetDepthBias)}, {"vkCmdSetBlendConstants", reinterpret_cast(CmdSetBlendConstants)}, {"vkCmdSetDepthBounds", reinterpret_cast(CmdSetDepthBounds)}, {"vkCmdSetStencilCompareMask", reinterpret_cast(CmdSetStencilCompareMask)}, {"vkCmdSetStencilWriteMask", reinterpret_cast(CmdSetStencilWriteMask)}, {"vkCmdSetStencilReference", reinterpret_cast(CmdSetStencilReference)}, {"vkCmdBindDescriptorSets", reinterpret_cast(CmdBindDescriptorSets)}, {"vkCmdBindVertexBuffers", reinterpret_cast(CmdBindVertexBuffers)}, {"vkCmdBindIndexBuffer", reinterpret_cast(CmdBindIndexBuffer)}, {"vkCmdDraw", reinterpret_cast(CmdDraw)}, {"vkCmdDrawIndexed", reinterpret_cast(CmdDrawIndexed)}, {"vkCmdDrawIndirect", reinterpret_cast(CmdDrawIndirect)}, {"vkCmdDrawIndexedIndirect", reinterpret_cast(CmdDrawIndexedIndirect)}, {"vkCmdDispatch", reinterpret_cast(CmdDispatch)}, {"vkCmdDispatchIndirect", reinterpret_cast(CmdDispatchIndirect)}, {"vkCmdCopyBuffer", reinterpret_cast(CmdCopyBuffer)}, {"vkCmdCopyImage", reinterpret_cast(CmdCopyImage)}, {"vkCmdBlitImage", reinterpret_cast(CmdBlitImage)}, {"vkCmdCopyBufferToImage", reinterpret_cast(CmdCopyBufferToImage)}, {"vkCmdCopyImageToBuffer", reinterpret_cast(CmdCopyImageToBuffer)}, {"vkCmdUpdateBuffer", reinterpret_cast(CmdUpdateBuffer)}, {"vkCmdFillBuffer", reinterpret_cast(CmdFillBuffer)}, {"vkCmdClearColorImage", reinterpret_cast(CmdClearColorImage)}, {"vkCmdClearDepthStencilImage", reinterpret_cast(CmdClearDepthStencilImage)}, {"vkCmdClearAttachments", reinterpret_cast(CmdClearAttachments)}, {"vkCmdResolveImage", reinterpret_cast(CmdResolveImage)}, {"vkCmdSetEvent", reinterpret_cast(CmdSetEvent)}, {"vkCmdResetEvent", reinterpret_cast(CmdResetEvent)}, {"vkCmdWaitEvents", reinterpret_cast(CmdWaitEvents)}, {"vkCmdPipelineBarrier", reinterpret_cast(CmdPipelineBarrier)}, {"vkCmdBeginQuery", reinterpret_cast(CmdBeginQuery)}, {"vkCmdEndQuery", reinterpret_cast(CmdEndQuery)}, {"vkCmdResetQueryPool", reinterpret_cast(CmdResetQueryPool)}, {"vkCmdCopyQueryPoolResults", reinterpret_cast(CmdCopyQueryPoolResults)}, {"vkCmdPushConstants", reinterpret_cast(CmdPushConstants)}, {"vkCmdWriteTimestamp", reinterpret_cast(CmdWriteTimestamp)}, {"vkCreateFramebuffer", reinterpret_cast(CreateFramebuffer)}, {"vkCreateShaderModule", reinterpret_cast(CreateShaderModule)}, {"vkCreateRenderPass", reinterpret_cast(CreateRenderPass)}, {"vkCmdBeginRenderPass", reinterpret_cast(CmdBeginRenderPass)}, {"vkCmdNextSubpass", reinterpret_cast(CmdNextSubpass)}, {"vkCmdEndRenderPass", reinterpret_cast(CmdEndRenderPass)}, {"vkCmdExecuteCommands", reinterpret_cast(CmdExecuteCommands)}, {"vkSetEvent", reinterpret_cast(SetEvent)}, {"vkMapMemory", reinterpret_cast(MapMemory)}, {"vkUnmapMemory", reinterpret_cast(UnmapMemory)}, {"vkFlushMappedMemoryRanges", reinterpret_cast(FlushMappedMemoryRanges)}, {"vkInvalidateMappedMemoryRanges", reinterpret_cast(InvalidateMappedMemoryRanges)}, {"vkAllocateMemory", reinterpret_cast(AllocateMemory)}, {"vkFreeMemory", reinterpret_cast(FreeMemory)}, {"vkBindBufferMemory", reinterpret_cast(BindBufferMemory)}, {"vkGetBufferMemoryRequirements", reinterpret_cast(GetBufferMemoryRequirements)}, {"vkGetImageMemoryRequirements", reinterpret_cast(GetImageMemoryRequirements)}, {"vkGetQueryPoolResults", reinterpret_cast(GetQueryPoolResults)}, {"vkBindImageMemory", reinterpret_cast(BindImageMemory)}, {"vkQueueBindSparse", reinterpret_cast(QueueBindSparse)}, {"vkCreateSemaphore", reinterpret_cast(CreateSemaphore)}, {"vkCreateEvent", reinterpret_cast(CreateEvent)}, }; for (size_t i = 0; i < ARRAY_SIZE(core_device_commands); i++) { if (!strcmp(core_device_commands[i].name, name)) return core_device_commands[i].proc; } return nullptr; } static PFN_vkVoidFunction intercept_khr_swapchain_command(const char *name, VkDevice dev) { static const struct { const char *name; PFN_vkVoidFunction proc; } khr_swapchain_commands[] = { { "vkCreateSwapchainKHR", reinterpret_cast(CreateSwapchainKHR) }, { "vkDestroySwapchainKHR", reinterpret_cast(DestroySwapchainKHR) }, { "vkGetSwapchainImagesKHR", reinterpret_cast(GetSwapchainImagesKHR) }, { "vkAcquireNextImageKHR", reinterpret_cast(AcquireNextImageKHR) }, { "vkQueuePresentKHR", reinterpret_cast(QueuePresentKHR) }, }; layer_data *dev_data = nullptr; if (dev) { dev_data = get_my_data_ptr(get_dispatch_key(dev), layer_data_map); if (!dev_data->device_extensions.wsi_enabled) return nullptr; } for (size_t i = 0; i < ARRAY_SIZE(khr_swapchain_commands); i++) { if (!strcmp(khr_swapchain_commands[i].name, name)) return khr_swapchain_commands[i].proc; } if (dev_data) { if (!dev_data->device_extensions.wsi_display_swapchain_enabled) return nullptr; } if (!strcmp("vkCreateSharedSwapchainsKHR", name)) return reinterpret_cast(CreateSharedSwapchainsKHR); return nullptr; } static PFN_vkVoidFunction intercept_khr_surface_command(const char *name, VkInstance instance) { static const struct { const char *name; PFN_vkVoidFunction proc; bool instance_layer_data::*enable; } khr_surface_commands[] = { #ifdef VK_USE_PLATFORM_ANDROID_KHR {"vkCreateAndroidSurfaceKHR", reinterpret_cast(CreateAndroidSurfaceKHR), &instance_layer_data::androidSurfaceExtensionEnabled}, #endif // VK_USE_PLATFORM_ANDROID_KHR #ifdef VK_USE_PLATFORM_MIR_KHR {"vkCreateMirSurfaceKHR", reinterpret_cast(CreateMirSurfaceKHR), &instance_layer_data::mirSurfaceExtensionEnabled}, #endif // VK_USE_PLATFORM_MIR_KHR #ifdef VK_USE_PLATFORM_WAYLAND_KHR {"vkCreateWaylandSurfaceKHR", reinterpret_cast(CreateWaylandSurfaceKHR), &instance_layer_data::waylandSurfaceExtensionEnabled}, #endif // VK_USE_PLATFORM_WAYLAND_KHR #ifdef VK_USE_PLATFORM_WIN32_KHR {"vkCreateWin32SurfaceKHR", reinterpret_cast(CreateWin32SurfaceKHR), &instance_layer_data::win32SurfaceExtensionEnabled}, #endif // VK_USE_PLATFORM_WIN32_KHR #ifdef VK_USE_PLATFORM_XCB_KHR {"vkCreateXcbSurfaceKHR", reinterpret_cast(CreateXcbSurfaceKHR), &instance_layer_data::xcbSurfaceExtensionEnabled}, #endif // VK_USE_PLATFORM_XCB_KHR #ifdef VK_USE_PLATFORM_XLIB_KHR {"vkCreateXlibSurfaceKHR", reinterpret_cast(CreateXlibSurfaceKHR), &instance_layer_data::xlibSurfaceExtensionEnabled}, #endif // VK_USE_PLATFORM_XLIB_KHR {"vkDestroySurfaceKHR", reinterpret_cast(DestroySurfaceKHR), &instance_layer_data::surfaceExtensionEnabled}, }; instance_layer_data *instance_data = nullptr; if (instance) { instance_data = get_my_data_ptr(get_dispatch_key(instance), instance_layer_data_map); } for (size_t i = 0; i < ARRAY_SIZE(khr_surface_commands); i++) { if (!strcmp(khr_surface_commands[i].name, name)) { if (instance_data && !(instance_data->*(khr_surface_commands[i].enable))) return nullptr; return khr_surface_commands[i].proc; } } return nullptr; } } // namespace core_validation // vk_layer_logging.h expects these to be defined VKAPI_ATTR VkResult VKAPI_CALL vkCreateDebugReportCallbackEXT(VkInstance instance, const VkDebugReportCallbackCreateInfoEXT *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkDebugReportCallbackEXT *pMsgCallback) { return core_validation::CreateDebugReportCallbackEXT(instance, pCreateInfo, pAllocator, pMsgCallback); } VKAPI_ATTR void VKAPI_CALL vkDestroyDebugReportCallbackEXT(VkInstance instance, VkDebugReportCallbackEXT msgCallback, const VkAllocationCallbacks *pAllocator) { core_validation::DestroyDebugReportCallbackEXT(instance, msgCallback, pAllocator); } VKAPI_ATTR void VKAPI_CALL vkDebugReportMessageEXT(VkInstance instance, VkDebugReportFlagsEXT flags, VkDebugReportObjectTypeEXT objType, uint64_t object, size_t location, int32_t msgCode, const char *pLayerPrefix, const char *pMsg) { core_validation::DebugReportMessageEXT(instance, flags, objType, object, location, msgCode, pLayerPrefix, pMsg); } // loader-layer interface v0, just wrappers since there is only a layer VK_LAYER_EXPORT VKAPI_ATTR VkResult VKAPI_CALL vkEnumerateInstanceExtensionProperties(const char *pLayerName, uint32_t *pCount, VkExtensionProperties *pProperties) { return core_validation::EnumerateInstanceExtensionProperties(pLayerName, pCount, pProperties); } VK_LAYER_EXPORT VKAPI_ATTR VkResult VKAPI_CALL vkEnumerateInstanceLayerProperties(uint32_t *pCount, VkLayerProperties *pProperties) { return core_validation::EnumerateInstanceLayerProperties(pCount, pProperties); } VK_LAYER_EXPORT VKAPI_ATTR VkResult VKAPI_CALL vkEnumerateDeviceLayerProperties(VkPhysicalDevice physicalDevice, uint32_t *pCount, VkLayerProperties *pProperties) { // the layer command handles VK_NULL_HANDLE just fine internally assert(physicalDevice == VK_NULL_HANDLE); return core_validation::EnumerateDeviceLayerProperties(VK_NULL_HANDLE, pCount, pProperties); } VK_LAYER_EXPORT VKAPI_ATTR VkResult VKAPI_CALL vkEnumerateDeviceExtensionProperties(VkPhysicalDevice physicalDevice, const char *pLayerName, uint32_t *pCount, VkExtensionProperties *pProperties) { // the layer command handles VK_NULL_HANDLE just fine internally assert(physicalDevice == VK_NULL_HANDLE); return core_validation::EnumerateDeviceExtensionProperties(VK_NULL_HANDLE, pLayerName, pCount, pProperties); } VK_LAYER_EXPORT VKAPI_ATTR PFN_vkVoidFunction VKAPI_CALL vkGetDeviceProcAddr(VkDevice dev, const char *funcName) { return core_validation::GetDeviceProcAddr(dev, funcName); } VK_LAYER_EXPORT VKAPI_ATTR PFN_vkVoidFunction VKAPI_CALL vkGetInstanceProcAddr(VkInstance instance, const char *funcName) { return core_validation::GetInstanceProcAddr(instance, funcName); }