vkd3d-proton/libs/vkd3d/device.c

/*
 * Copyright 2016 Józef Kucia for CodeWeavers
 *
 * This library is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2.1 of the License, or (at your option) any later version.
 *
 * This library is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public
 * License along with this library; if not, write to the Free Software
 * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
 */

#include "vkd3d_private.h"

#include <dlfcn.h>

struct vkd3d_struct
{
    enum vkd3d_structure_type type;
    const void *next;
};

#define vkd3d_find_struct(c, t) vkd3d_find_struct_(c, VKD3D_STRUCTURE_TYPE_##t)
static const void *vkd3d_find_struct_(const struct vkd3d_struct *chain,
        enum vkd3d_structure_type type)
{
    while (chain)
    {
        if (chain->type == type)
            return chain;

        chain = chain->next;
    }

    return NULL;
}

struct vk_struct
{
    VkStructureType sType;
    struct vk_struct *pNext;
};

#define vk_find_struct(c, t) vk_find_struct_(c, VK_STRUCTURE_TYPE_##t)
static const void *vk_find_struct_(struct vk_struct *chain, VkStructureType sType)
{
    while (chain)
    {
        if (chain->sType == sType)
            return chain;

        chain = chain->pNext;
    }

    return NULL;
}

struct vkd3d_optional_extension_info
{
    const char *extension_name;
    ptrdiff_t vulkan_info_offset;
    bool is_debug_only;
};

static const struct vkd3d_optional_extension_info optional_instance_extensions[] =
{
    {VK_KHR_GET_PHYSICAL_DEVICE_PROPERTIES_2_EXTENSION_NAME,
            offsetof(struct vkd3d_vulkan_info, KHR_get_physical_device_properties2)},
    {VK_EXT_DEBUG_REPORT_EXTENSION_NAME, offsetof(struct vkd3d_vulkan_info, EXT_debug_report), true},
};

static const char * const required_device_extensions[] =
{
    VK_KHR_MAINTENANCE1_EXTENSION_NAME,
    VK_KHR_SHADER_DRAW_PARAMETERS_EXTENSION_NAME,
};

static const struct vkd3d_optional_extension_info optional_device_extensions[] =
{
    {VK_KHR_PUSH_DESCRIPTOR_EXTENSION_NAME, offsetof(struct vkd3d_vulkan_info, KHR_push_descriptor)},
    {VK_EXT_VERTEX_ATTRIBUTE_DIVISOR_EXTENSION_NAME,
            offsetof(struct vkd3d_vulkan_info, EXT_vertex_attribute_divisor)},
};

static unsigned int get_spec_version(const VkExtensionProperties *extensions,
        unsigned int count, const char *extension_name)
{
    unsigned int i;

    for (i = 0; i < count; ++i)
    {
        if (!strcmp(extensions[i].extensionName, extension_name))
            return extensions[i].specVersion;
    }
    return 0;
}

static bool is_extension_disabled(const char *extension_name)
{
    const char *disabled_extensions;
    const char *s;
    size_t len;

    if (!(disabled_extensions = getenv("VKD3D_DISABLE_EXTENSIONS")))
        return false;

    if (!(s = strstr(disabled_extensions, extension_name)))
        return false;
    len = strlen(extension_name);
    return s[len] == ';' || s[len] == '\0';
}

static bool has_extension(const VkExtensionProperties *extensions,
        unsigned int count, const char *extension_name, bool is_debug_only)
{
    unsigned int i;

    for (i = 0; i < count; ++i)
    {
        if (strcmp(extensions[i].extensionName, extension_name))
            continue;
        if (is_extension_disabled(extension_name))
        {
            WARN("Extension %s is disabled.\n", debugstr_a(extension_name));
            continue;
        }
        if (is_debug_only && vkd3d_dbg_get_level() < VKD3D_DBG_LEVEL_WARN)
        {
            TRACE("Skipping debug-only extension %s.\n", debugstr_a(extension_name));
            continue;
        }
        return true;
    }
    return false;
}

static unsigned int vkd3d_check_extensions(const VkExtensionProperties *extensions, unsigned int count,
        const char * const *required_extensions, unsigned int required_extension_count,
        const struct vkd3d_optional_extension_info *optional_extensions, unsigned int optional_extension_count,
        const char * const *user_extensions, unsigned int user_extension_count,
        const char * const *optional_user_extensions, unsigned int optional_user_extension_count,
        bool *user_extension_supported, struct vkd3d_vulkan_info *vulkan_info, const char *extension_type)
{
    unsigned int extension_count = 0;
    unsigned int i;

    for (i = 0; i < required_extension_count; ++i)
    {
        if (!has_extension(extensions, count, required_extensions[i], false))
            ERR("Required %s extension %s is not supported.\n",
                    extension_type, debugstr_a(required_extensions[i]));
        ++extension_count;
    }

    for (i = 0; i < optional_extension_count; ++i)
    {
        const char *extension_name = optional_extensions[i].extension_name;
        ptrdiff_t offset = optional_extensions[i].vulkan_info_offset;
        bool is_debug_only = optional_extensions[i].is_debug_only;
        bool *supported = (void *)((uintptr_t)vulkan_info + offset);

        if ((*supported = has_extension(extensions, count, extension_name, is_debug_only)))
        {
            TRACE("Found %s extension.\n", debugstr_a(extension_name));
            ++extension_count;
        }
    }

    for (i = 0; i < user_extension_count; ++i)
    {
        if (!has_extension(extensions, count, user_extensions[i], false))
            ERR("Required user %s extension %s is not supported.\n",
                    extension_type, debugstr_a(user_extensions[i]));
        ++extension_count;
    }

    assert(!optional_user_extension_count || user_extension_supported);
    for (i = 0; i < optional_user_extension_count; ++i)
    {
        if (has_extension(extensions, count, optional_user_extensions[i], false))
        {
            user_extension_supported[i] = true;
            ++extension_count;
        }
        else
        {
            user_extension_supported[i] = false;
            WARN("Optional user %s extension %s is not supported.\n",
                    extension_type, debugstr_a(optional_user_extensions[i]));
        }
    }

    return extension_count;
}

static unsigned int vkd3d_append_extension(const char *extensions[],
        unsigned int extension_count, const char *extension_name)
{
    unsigned int i;

    /* avoid duplicates */
    for (i = 0; i < extension_count; ++i)
    {
        if (!strcmp(extensions[i], extension_name))
            return extension_count;
    }

    extensions[extension_count++] = extension_name;
    return extension_count;
}

static unsigned int vkd3d_enable_extensions(const char *extensions[],
        const char * const *required_extensions, unsigned int required_extension_count,
        const struct vkd3d_optional_extension_info *optional_extensions, unsigned int optional_extension_count,
        const char * const *user_extensions, unsigned int user_extension_count,
        const char * const *optional_user_extensions, unsigned int optional_user_extension_count,
        bool *user_extension_supported, const struct vkd3d_vulkan_info *vulkan_info)
{
    unsigned int extension_count = 0;
    unsigned int i;

    for (i = 0; i < required_extension_count; ++i)
    {
        extensions[extension_count++] = required_extensions[i];
    }
    for (i = 0; i < optional_extension_count; ++i)
    {
        ptrdiff_t offset = optional_extensions[i].vulkan_info_offset;
        const bool *supported = (void *)((uintptr_t)vulkan_info + offset);

        if (*supported)
            extensions[extension_count++] = optional_extensions[i].extension_name;
    }

    for (i = 0; i < user_extension_count; ++i)
    {
        extension_count = vkd3d_append_extension(extensions, extension_count, user_extensions[i]);
    }
    assert(!optional_user_extension_count || user_extension_supported);
    for (i = 0; i < optional_user_extension_count; ++i)
    {
        if (!user_extension_supported[i])
            continue;
        extension_count = vkd3d_append_extension(extensions, extension_count, optional_user_extensions[i]);
    }

    return extension_count;
}

static HRESULT vkd3d_init_instance_caps(struct vkd3d_instance *instance,
        const struct vkd3d_instance_create_info *create_info,
        uint32_t *instance_extension_count, bool **user_extension_supported)
{
    const struct vkd3d_vk_global_procs *vk_procs = &instance->vk_global_procs;
    const struct vkd3d_optional_instance_extensions_info *optional_extensions;
    struct vkd3d_vulkan_info *vulkan_info = &instance->vk_info;
    VkExtensionProperties *vk_extensions;
    uint32_t count;
    VkResult vr;

    memset(vulkan_info, 0, sizeof(*vulkan_info));
    *instance_extension_count = 0;

    if ((vr = vk_procs->vkEnumerateInstanceExtensionProperties(NULL, &count, NULL)) < 0)
    {
        ERR("Failed to enumerate instance extensions, vr %d.\n", vr);
        return hresult_from_vk_result(vr);
    }
    if (!count)
        return S_OK;

    if (!(vk_extensions = vkd3d_calloc(count, sizeof(*vk_extensions))))
        return E_OUTOFMEMORY;

    TRACE("Enumerating %u instance extensions.\n", count);
    if ((vr = vk_procs->vkEnumerateInstanceExtensionProperties(NULL, &count, vk_extensions)) < 0)
    {
        ERR("Failed to enumerate instance extensions, vr %d.\n", vr);
        vkd3d_free(vk_extensions);
        return hresult_from_vk_result(vr);
    }

    optional_extensions = vkd3d_find_struct(create_info->next, OPTIONAL_INSTANCE_EXTENSIONS_INFO);
    if (optional_extensions && optional_extensions->extension_count)
    {
        if (!(*user_extension_supported = vkd3d_calloc(optional_extensions->extension_count, sizeof(bool))))
        {
            vkd3d_free(vk_extensions);
            return E_OUTOFMEMORY;
        }
    }
    else
    {
        *user_extension_supported = NULL;
    }

    *instance_extension_count = vkd3d_check_extensions(vk_extensions, count, NULL, 0,
            optional_instance_extensions, ARRAY_SIZE(optional_instance_extensions),
            create_info->instance_extensions, create_info->instance_extension_count,
            optional_extensions ? optional_extensions->extensions : NULL,
            optional_extensions ? optional_extensions->extension_count : 0,
            *user_extension_supported, vulkan_info, "instance");

    vkd3d_free(vk_extensions);
    return S_OK;
}

static HRESULT vkd3d_init_vk_global_procs(struct vkd3d_instance *instance,
        PFN_vkGetInstanceProcAddr vkGetInstanceProcAddr)
{
    HRESULT hr;

    if (!vkGetInstanceProcAddr)
    {
        if (!(instance->libvulkan = dlopen(SONAME_LIBVULKAN, RTLD_NOW)))
        {
            ERR("Failed to load libvulkan: %s.\n", dlerror());
            return E_FAIL;
        }

        if (!(vkGetInstanceProcAddr = dlsym(instance->libvulkan, "vkGetInstanceProcAddr")))
        {
            ERR("Could not load function pointer for vkGetInstanceProcAddr().\n");
            dlclose(instance->libvulkan);
            instance->libvulkan = NULL;
            return E_FAIL;
        }
    }
    else
    {
        instance->libvulkan = NULL;
    }

    if (FAILED(hr = vkd3d_load_vk_global_procs(&instance->vk_global_procs, vkGetInstanceProcAddr)))
    {
        if (instance->libvulkan)
            dlclose(instance->libvulkan);
        instance->libvulkan = NULL;
        return hr;
    }

    return S_OK;
}

static VkBool32 VKAPI_PTR vkd3d_debug_report_callback(VkDebugReportFlagsEXT flags,
        VkDebugReportObjectTypeEXT object_type, uint64_t object, size_t location,
        int32_t message_code, const char *layer_prefix, const char *message, void *user_data)
{
    FIXME("%s\n", debugstr_a(message));
    return VK_FALSE;
}

static void vkd3d_init_debug_report(struct vkd3d_instance *instance)
{
    const struct vkd3d_vk_instance_procs *vk_procs = &instance->vk_procs;
    VkDebugReportCallbackCreateInfoEXT callback_info;
    VkInstance vk_instance = instance->vk_instance;
    VkDebugReportCallbackEXT callback;
    VkResult vr;

    callback_info.sType = VK_STRUCTURE_TYPE_DEBUG_REPORT_CALLBACK_CREATE_INFO_EXT;
    callback_info.pNext = NULL;
    callback_info.flags = VK_DEBUG_REPORT_ERROR_BIT_EXT | VK_DEBUG_REPORT_WARNING_BIT_EXT;
    callback_info.pfnCallback = vkd3d_debug_report_callback;
    callback_info.pUserData = NULL;
    if ((vr = VK_CALL(vkCreateDebugReportCallbackEXT(vk_instance, &callback_info, NULL, &callback)) < 0))
    {
        WARN("Failed to create debug report callback, vr %d.\n", vr);
        return;
    }

    instance->vk_debug_callback = callback;
}

static HRESULT vkd3d_instance_init(struct vkd3d_instance *instance,
        const struct vkd3d_instance_create_info *create_info)
{
    const struct vkd3d_vk_global_procs *vk_global_procs = &instance->vk_global_procs;
    const struct vkd3d_optional_instance_extensions_info *optional_extensions;
    bool *user_extension_supported = NULL;
    VkApplicationInfo application_info;
    VkInstanceCreateInfo instance_info;
    uint32_t extension_count;
    const char **extensions;
    VkInstance vk_instance;
    VkResult vr;
    HRESULT hr;

    TRACE("Build: %s.\n", vkd3d_build);

    if (!create_info->pfn_signal_event)
    {
        ERR("Invalid signal event function pointer.\n");
        return E_INVALIDARG;
    }
    if (!create_info->pfn_create_thread != !create_info->pfn_join_thread)
    {
        ERR("Invalid create/join thread function pointers.\n");
        return E_INVALIDARG;
    }
    if (create_info->wchar_size != 2 && create_info->wchar_size != 4)
    {
        ERR("Unexpected WCHAR size %zu.\n", create_info->wchar_size);
        return E_INVALIDARG;
    }

    instance->signal_event = create_info->pfn_signal_event;
    instance->create_thread = create_info->pfn_create_thread;
    instance->join_thread = create_info->pfn_join_thread;
    instance->wchar_size = create_info->wchar_size;

    if (FAILED(hr = vkd3d_init_vk_global_procs(instance, create_info->pfn_vkGetInstanceProcAddr)))
    {
        ERR("Failed to initialize Vulkan global procs, hr %#x.\n", hr);
        return hr;
    }

    if (FAILED(hr = vkd3d_init_instance_caps(instance, create_info,
            &extension_count, &user_extension_supported)))
    {
        if (instance->libvulkan)
            dlclose(instance->libvulkan);
        return hr;
    }

    application_info.sType = VK_STRUCTURE_TYPE_APPLICATION_INFO;
    application_info.pNext = NULL;
    application_info.pApplicationName = PACKAGE_NAME;
    application_info.applicationVersion = 0;
    application_info.pEngineName = NULL;
    application_info.engineVersion = 0;
    application_info.apiVersion = VK_API_VERSION_1_0;

    if (!(extensions = vkd3d_calloc(extension_count, sizeof(*extensions))))
    {
        if (instance->libvulkan)
            dlclose(instance->libvulkan);
        vkd3d_free(user_extension_supported);
        return E_OUTOFMEMORY;
    }

    optional_extensions = vkd3d_find_struct(create_info->next, OPTIONAL_INSTANCE_EXTENSIONS_INFO);

    instance_info.sType = VK_STRUCTURE_TYPE_INSTANCE_CREATE_INFO;
    instance_info.pNext = NULL;
    instance_info.flags = 0;
    instance_info.pApplicationInfo = &application_info;
    instance_info.enabledLayerCount = 0;
    instance_info.ppEnabledLayerNames = NULL;
    instance_info.enabledExtensionCount = vkd3d_enable_extensions(extensions, NULL, 0,
            optional_instance_extensions, ARRAY_SIZE(optional_instance_extensions),
            create_info->instance_extensions, create_info->instance_extension_count,
            optional_extensions ? optional_extensions->extensions : NULL,
            optional_extensions ? optional_extensions->extension_count : 0,
            user_extension_supported, &instance->vk_info);
    instance_info.ppEnabledExtensionNames = extensions;
    vkd3d_free(user_extension_supported);

    vr = vk_global_procs->vkCreateInstance(&instance_info, NULL, &vk_instance);
    vkd3d_free(extensions);
    if (vr < 0)
    {
        ERR("Failed to create Vulkan instance, vr %d.\n", vr);
        if (instance->libvulkan)
            dlclose(instance->libvulkan);
        return hresult_from_vk_result(vr);
    }

    if (FAILED(hr = vkd3d_load_vk_instance_procs(&instance->vk_procs, vk_global_procs, vk_instance)))
    {
        ERR("Failed to load instance procs, hr %#x.\n", hr);
        if (instance->vk_procs.vkDestroyInstance)
            instance->vk_procs.vkDestroyInstance(vk_instance, NULL);
        if (instance->libvulkan)
            dlclose(instance->libvulkan);
        return hr;
    }

    instance->vk_instance = vk_instance;

    TRACE("Created Vulkan instance %p.\n", vk_instance);

    instance->refcount = 1;

    instance->vk_debug_callback = VK_NULL_HANDLE;
    if (instance->vk_info.EXT_debug_report)
        vkd3d_init_debug_report(instance);

    return S_OK;
}

HRESULT vkd3d_create_instance(const struct vkd3d_instance_create_info *create_info,
        struct vkd3d_instance **instance)
{
    struct vkd3d_instance *object;
    HRESULT hr;

    TRACE("create_info %p, instance %p.\n", create_info, instance);

    if (!create_info || !instance)
        return E_INVALIDARG;
    if (create_info->type != VKD3D_STRUCTURE_TYPE_INSTANCE_CREATE_INFO)
    {
        WARN("Invalid structure type %#x.\n", create_info->type);
        return E_INVALIDARG;
    }

    if (!(object = vkd3d_malloc(sizeof(*object))))
        return E_OUTOFMEMORY;

    if (FAILED(hr = vkd3d_instance_init(object, create_info)))
    {
        vkd3d_free(object);
        return hr;
    }

    TRACE("Created instance %p.\n", object);

    *instance = object;

    return S_OK;
}

static void vkd3d_destroy_instance(struct vkd3d_instance *instance)
{
    const struct vkd3d_vk_instance_procs *vk_procs = &instance->vk_procs;
    VkInstance vk_instance = instance->vk_instance;

    if (instance->vk_debug_callback)
        VK_CALL(vkDestroyDebugReportCallbackEXT(vk_instance, instance->vk_debug_callback, NULL));

    VK_CALL(vkDestroyInstance(vk_instance, NULL));

    if (instance->libvulkan)
        dlclose(instance->libvulkan);

    vkd3d_free(instance);
}

ULONG vkd3d_instance_incref(struct vkd3d_instance *instance)
{
    ULONG refcount = InterlockedIncrement(&instance->refcount);

    TRACE("%p increasing refcount to %u.\n", instance, refcount);

    return refcount;
}

ULONG vkd3d_instance_decref(struct vkd3d_instance *instance)
{
    ULONG refcount = InterlockedDecrement(&instance->refcount);

    TRACE("%p decreasing refcount to %u.\n", instance, refcount);

    if (!refcount)
        vkd3d_destroy_instance(instance);

    return refcount;
}

VkInstance vkd3d_instance_get_vk_instance(struct vkd3d_instance *instance)
{
    return instance->vk_instance;
}

static void vkd3d_trace_physical_device(VkPhysicalDevice device,
        const struct vkd3d_vk_instance_procs *vk_procs)
{
    VkPhysicalDeviceMemoryProperties memory_properties;
    VkPhysicalDeviceProperties device_properties;
    VkQueueFamilyProperties *queue_properties;
    VkPhysicalDeviceLimits *limits;
    unsigned int i, j;
    uint32_t count;

    VK_CALL(vkGetPhysicalDeviceProperties(device, &device_properties));
    TRACE("Device name: %s.\n", device_properties.deviceName);
    TRACE("Vendor ID: %#x, Device ID: %#x.\n", device_properties.vendorID, device_properties.deviceID);
    TRACE("Driver version: %#x.\n", device_properties.driverVersion);
    TRACE("API version: %u.%u.%u.\n", VK_VERSION_MAJOR(device_properties.apiVersion),
            VK_VERSION_MINOR(device_properties.apiVersion), VK_VERSION_PATCH(device_properties.apiVersion));

    VK_CALL(vkGetPhysicalDeviceQueueFamilyProperties(device, &count, NULL));
    TRACE("Queue families [%u]:\n", count);

    if (!(queue_properties = vkd3d_calloc(count, sizeof(VkQueueFamilyProperties))))
        return;
    VK_CALL(vkGetPhysicalDeviceQueueFamilyProperties(device, &count, queue_properties));

    for (i = 0; i < count; ++i)
    {
        TRACE(" Queue family [%u]: flags %s, count %u, timestamp bits %u, image transfer granularity %s.\n",
                i, debug_vk_queue_flags(queue_properties[i].queueFlags),
                queue_properties[i].queueCount, queue_properties[i].timestampValidBits,
                debug_vk_extent_3d(queue_properties[i].minImageTransferGranularity));
    }
    vkd3d_free(queue_properties);

    VK_CALL(vkGetPhysicalDeviceMemoryProperties(device, &memory_properties));
    for (i = 0; i < memory_properties.memoryHeapCount; ++i)
    {
        const VkMemoryHeap *heap = &memory_properties.memoryHeaps[i];
        TRACE("Memory heap [%u]: size %#"PRIx64" (%"PRIu64" MiB), flags %s, memory types:\n",
                i, heap->size, heap->size / 1024 / 1024, debug_vk_memory_heap_flags(heap->flags));
        for (j = 0; j < memory_properties.memoryTypeCount; ++j)
        {
            const VkMemoryType *type = &memory_properties.memoryTypes[j];
            if (type->heapIndex != i)
                continue;
            TRACE("  Memory type [%u]: flags %s.\n", j, debug_vk_memory_property_flags(type->propertyFlags));
        }
    }

    limits = &device_properties.limits;
    TRACE("Device limits:\n");
    TRACE("  maxImageDimension1D: %u.\n", limits->maxImageDimension1D);
    TRACE("  maxImageDimension2D: %u.\n", limits->maxImageDimension2D);
    TRACE("  maxImageDimension3D: %u.\n", limits->maxImageDimension3D);
    TRACE("  maxImageDimensionCube: %u.\n", limits->maxImageDimensionCube);
    TRACE("  maxImageArrayLayers: %u.\n", limits->maxImageArrayLayers);
    TRACE("  maxTexelBufferElements: %u.\n", limits->maxTexelBufferElements);
    TRACE("  maxUniformBufferRange: %u.\n", limits->maxUniformBufferRange);
    TRACE("  maxStorageBufferRange: %u.\n", limits->maxStorageBufferRange);
    TRACE("  maxPushConstantsSize: %u.\n", limits->maxPushConstantsSize);
    TRACE("  maxMemoryAllocationCount: %u.\n", limits->maxMemoryAllocationCount);
    TRACE("  maxSamplerAllocationCount: %u.\n", limits->maxSamplerAllocationCount);
    TRACE("  bufferImageGranularity: %#"PRIx64".\n", limits->bufferImageGranularity);
    TRACE("  sparseAddressSpaceSize: %#"PRIx64".\n", limits->sparseAddressSpaceSize);
    TRACE("  maxBoundDescriptorSets: %u.\n", limits->maxBoundDescriptorSets);
    TRACE("  maxPerStageDescriptorSamplers: %u.\n", limits->maxPerStageDescriptorSamplers);
    TRACE("  maxPerStageDescriptorUniformBuffers: %u.\n", limits->maxPerStageDescriptorUniformBuffers);
    TRACE("  maxPerStageDescriptorStorageBuffers: %u.\n", limits->maxPerStageDescriptorStorageBuffers);
    TRACE("  maxPerStageDescriptorSampledImages: %u.\n", limits->maxPerStageDescriptorSampledImages);
    TRACE("  maxPerStageDescriptorStorageImages: %u.\n", limits->maxPerStageDescriptorStorageImages);
    TRACE("  maxPerStageDescriptorInputAttachments: %u.\n", limits->maxPerStageDescriptorInputAttachments);
    TRACE("  maxPerStageResources: %u.\n", limits->maxPerStageResources);
    TRACE("  maxDescriptorSetSamplers: %u.\n", limits->maxDescriptorSetSamplers);
    TRACE("  maxDescriptorSetUniformBuffers: %u.\n", limits->maxDescriptorSetUniformBuffers);
    TRACE("  maxDescriptorSetUniformBuffersDynamic: %u.\n", limits->maxDescriptorSetUniformBuffersDynamic);
    TRACE("  maxDescriptorSetStorageBuffers: %u.\n", limits->maxDescriptorSetStorageBuffers);
    TRACE("  maxDescriptorSetStorageBuffersDynamic: %u.\n", limits->maxDescriptorSetStorageBuffersDynamic);
    TRACE("  maxDescriptorSetSampledImages: %u.\n", limits->maxDescriptorSetSampledImages);
    TRACE("  maxDescriptorSetStorageImages: %u.\n", limits->maxDescriptorSetStorageImages);
    TRACE("  maxDescriptorSetInputAttachments: %u.\n", limits->maxDescriptorSetInputAttachments);
    TRACE("  maxVertexInputAttributes: %u.\n", limits->maxVertexInputAttributes);
    TRACE("  maxVertexInputBindings: %u.\n", limits->maxVertexInputBindings);
    TRACE("  maxVertexInputAttributeOffset: %u.\n", limits->maxVertexInputAttributeOffset);
    TRACE("  maxVertexInputBindingStride: %u.\n", limits->maxVertexInputBindingStride);
    TRACE("  maxVertexOutputComponents: %u.\n", limits->maxVertexOutputComponents);
    TRACE("  maxTessellationGenerationLevel: %u.\n", limits->maxTessellationGenerationLevel);
    TRACE("  maxTessellationPatchSize: %u.\n", limits->maxTessellationPatchSize);
    TRACE("  maxTessellationControlPerVertexInputComponents: %u.\n",
            limits->maxTessellationControlPerVertexInputComponents);
    TRACE("  maxTessellationControlPerVertexOutputComponents: %u.\n",
            limits->maxTessellationControlPerVertexOutputComponents);
    TRACE("  maxTessellationControlPerPatchOutputComponents: %u.\n",
            limits->maxTessellationControlPerPatchOutputComponents);
    TRACE("  maxTessellationControlTotalOutputComponents: %u.\n",
            limits->maxTessellationControlTotalOutputComponents);
    TRACE("  maxTessellationEvaluationInputComponents: %u.\n",
            limits->maxTessellationEvaluationInputComponents);
    TRACE("  maxTessellationEvaluationOutputComponents: %u.\n",
            limits->maxTessellationEvaluationOutputComponents);
    TRACE("  maxGeometryShaderInvocations: %u.\n", limits->maxGeometryShaderInvocations);
    TRACE("  maxGeometryInputComponents: %u.\n", limits->maxGeometryInputComponents);
    TRACE("  maxGeometryOutputComponents: %u.\n", limits->maxGeometryOutputComponents);
    TRACE("  maxGeometryOutputVertices: %u.\n", limits->maxGeometryOutputVertices);
    TRACE("  maxGeometryTotalOutputComponents: %u.\n", limits->maxGeometryTotalOutputComponents);
    TRACE("  maxFragmentInputComponents: %u.\n", limits->maxFragmentInputComponents);
    TRACE("  maxFragmentOutputAttachments: %u.\n", limits->maxFragmentOutputAttachments);
    TRACE("  maxFragmentDualSrcAttachments: %u.\n", limits->maxFragmentDualSrcAttachments);
    TRACE("  maxFragmentCombinedOutputResources: %u.\n", limits->maxFragmentCombinedOutputResources);
    TRACE("  maxComputeSharedMemorySize: %u.\n", limits->maxComputeSharedMemorySize);
    TRACE("  maxComputeWorkGroupCount: %u, %u, %u.\n", limits->maxComputeWorkGroupCount[0],
            limits->maxComputeWorkGroupCount[1], limits->maxComputeWorkGroupCount[2]);
    TRACE("  maxComputeWorkGroupInvocations: %u.\n", limits->maxComputeWorkGroupInvocations);
    TRACE("  maxComputeWorkGroupSize: %u, %u, %u.\n", limits->maxComputeWorkGroupSize[0],
            limits->maxComputeWorkGroupSize[1], limits->maxComputeWorkGroupSize[2]);
    TRACE("  subPixelPrecisionBits: %u.\n", limits->subPixelPrecisionBits);
    TRACE("  subTexelPrecisionBits: %u.\n", limits->subTexelPrecisionBits);
    TRACE("  mipmapPrecisionBits: %u.\n", limits->mipmapPrecisionBits);
    TRACE("  maxDrawIndexedIndexValue: %u.\n", limits->maxDrawIndexedIndexValue);
    TRACE("  maxDrawIndirectCount: %u.\n", limits->maxDrawIndirectCount);
    TRACE("  maxSamplerLodBias: %f.\n", limits->maxSamplerLodBias);
    TRACE("  maxSamplerAnisotropy: %f.\n", limits->maxSamplerAnisotropy);
    TRACE("  maxViewports: %u.\n", limits->maxViewports);
    TRACE("  maxViewportDimensions: %u, %u.\n", limits->maxViewportDimensions[0],
            limits->maxViewportDimensions[1]);
    TRACE("  viewportBoundsRange: %f, %f.\n", limits->viewportBoundsRange[0], limits->viewportBoundsRange[1]);
    TRACE("  viewportSubPixelBits: %u.\n", limits->viewportSubPixelBits);
    TRACE("  minMemoryMapAlignment: %u.\n", (unsigned int)limits->minMemoryMapAlignment);
    TRACE("  minTexelBufferOffsetAlignment: %#"PRIx64".\n", limits->minTexelBufferOffsetAlignment);
    TRACE("  minUniformBufferOffsetAlignment: %#"PRIx64".\n", limits->minUniformBufferOffsetAlignment);
    TRACE("  minStorageBufferOffsetAlignment: %#"PRIx64".\n", limits->minStorageBufferOffsetAlignment);
    TRACE("  minTexelOffset: %d.\n", limits->minTexelOffset);
    TRACE("  maxTexelOffset: %u.\n", limits->maxTexelOffset);
    TRACE("  minTexelGatherOffset: %d.\n", limits->minTexelGatherOffset);
    TRACE("  maxTexelGatherOffset: %u.\n", limits->maxTexelGatherOffset);
    TRACE("  minInterpolationOffset: %f.\n", limits->minInterpolationOffset);
    TRACE("  maxInterpolationOffset: %f.\n", limits->maxInterpolationOffset);
    TRACE("  subPixelInterpolationOffsetBits: %u.\n", limits->subPixelInterpolationOffsetBits);
    TRACE("  maxFramebufferWidth: %u.\n", limits->maxFramebufferWidth);
    TRACE("  maxFramebufferHeight: %u.\n", limits->maxFramebufferHeight);
    TRACE("  maxFramebufferLayers: %u.\n", limits->maxFramebufferLayers);
    TRACE("  framebufferColorSampleCounts: %#x.\n", limits->framebufferColorSampleCounts);
    TRACE("  framebufferDepthSampleCounts: %#x.\n", limits->framebufferDepthSampleCounts);
    TRACE("  framebufferStencilSampleCounts: %#x.\n", limits->framebufferStencilSampleCounts);
    TRACE("  framebufferNoAttachmentsSampleCounts: %#x.\n", limits->framebufferNoAttachmentsSampleCounts);
    TRACE("  maxColorAttachments: %u.\n", limits->maxColorAttachments);
    TRACE("  sampledImageColorSampleCounts: %#x.\n", limits->sampledImageColorSampleCounts);
    TRACE("  sampledImageIntegerSampleCounts: %#x.\n", limits->sampledImageIntegerSampleCounts);
    TRACE("  sampledImageDepthSampleCounts: %#x.\n", limits->sampledImageDepthSampleCounts);
    TRACE("  sampledImageStencilSampleCounts: %#x.\n", limits->sampledImageStencilSampleCounts);
    TRACE("  storageImageSampleCounts: %#x.\n", limits->storageImageSampleCounts);
    TRACE("  maxSampleMaskWords: %u.\n", limits->maxSampleMaskWords);
    TRACE("  timestampComputeAndGraphics: %#x.\n", limits->timestampComputeAndGraphics);
    TRACE("  timestampPeriod: %f.\n", limits->timestampPeriod);
    TRACE("  maxClipDistances: %u.\n", limits->maxClipDistances);
    TRACE("  maxCullDistances: %u.\n", limits->maxCullDistances);
    TRACE("  maxCombinedClipAndCullDistances: %u.\n", limits->maxCombinedClipAndCullDistances);
    TRACE("  discreteQueuePriorities: %u.\n", limits->discreteQueuePriorities);
    TRACE("  pointSizeRange: %f, %f.\n", limits->pointSizeRange[0], limits->pointSizeRange[1]);
    TRACE("  lineWidthRange: %f, %f,\n", limits->lineWidthRange[0], limits->lineWidthRange[1]);
    TRACE("  pointSizeGranularity: %f.\n", limits->pointSizeGranularity);
    TRACE("  lineWidthGranularity: %f.\n", limits->lineWidthGranularity);
    TRACE("  strictLines: %#x.\n", limits->strictLines);
    TRACE("  standardSampleLocations: %#x.\n", limits->standardSampleLocations);
    TRACE("  optimalBufferCopyOffsetAlignment: %#"PRIx64".\n", limits->optimalBufferCopyOffsetAlignment);
    TRACE("  optimalBufferCopyRowPitchAlignment: %#"PRIx64".\n", limits->optimalBufferCopyRowPitchAlignment);
    TRACE("  nonCoherentAtomSize: %#"PRIx64".\n", limits->nonCoherentAtomSize);
}

static void vkd3d_trace_physical_device_features(const VkPhysicalDeviceFeatures2KHR *features2)
{
    const VkPhysicalDeviceVertexAttributeDivisorFeaturesEXT *divisor_features;
    const VkPhysicalDeviceFeatures *features = &features2->features;

    TRACE("Device features:\n");
    TRACE("  robustBufferAccess: %#x.\n", features->robustBufferAccess);
    TRACE("  fullDrawIndexUint32: %#x.\n", features->fullDrawIndexUint32);
    TRACE("  imageCubeArray: %#x.\n", features->imageCubeArray);
    TRACE("  independentBlend: %#x.\n", features->independentBlend);
    TRACE("  geometryShader: %#x.\n", features->geometryShader);
    TRACE("  tessellationShader: %#x.\n", features->tessellationShader);
    TRACE("  sampleRateShading: %#x.\n", features->sampleRateShading);
    TRACE("  dualSrcBlend: %#x.\n", features->dualSrcBlend);
    TRACE("  logicOp: %#x.\n", features->logicOp);
    TRACE("  multiDrawIndirect: %#x.\n", features->multiDrawIndirect);
    TRACE("  drawIndirectFirstInstance: %#x.\n", features->drawIndirectFirstInstance);
    TRACE("  depthClamp: %#x.\n", features->depthClamp);
    TRACE("  depthBiasClamp: %#x.\n", features->depthBiasClamp);
    TRACE("  fillModeNonSolid: %#x.\n", features->fillModeNonSolid);
    TRACE("  depthBounds: %#x.\n", features->depthBounds);
    TRACE("  wideLines: %#x.\n", features->wideLines);
    TRACE("  largePoints: %#x.\n", features->largePoints);
    TRACE("  alphaToOne: %#x.\n", features->alphaToOne);
    TRACE("  multiViewport: %#x.\n", features->multiViewport);
    TRACE("  samplerAnisotropy: %#x.\n", features->samplerAnisotropy);
    TRACE("  textureCompressionETC2: %#x.\n", features->textureCompressionETC2);
    TRACE("  textureCompressionASTC_LDR: %#x.\n", features->textureCompressionASTC_LDR);
    TRACE("  textureCompressionBC: %#x.\n", features->textureCompressionBC);
    TRACE("  occlusionQueryPrecise: %#x.\n", features->occlusionQueryPrecise);
    TRACE("  pipelineStatisticsQuery: %#x.\n", features->pipelineStatisticsQuery);
    TRACE("  vertexOipelineStoresAndAtomics: %#x.\n", features->vertexPipelineStoresAndAtomics);
    TRACE("  fragmentStoresAndAtomics: %#x.\n", features->fragmentStoresAndAtomics);
    TRACE("  shaderTessellationAndGeometryPointSize: %#x.\n", features->shaderTessellationAndGeometryPointSize);
    TRACE("  shaderImageGatherExtended: %#x.\n", features->shaderImageGatherExtended);
    TRACE("  shaderStorageImageExtendedFormats: %#x.\n", features->shaderStorageImageExtendedFormats);
    TRACE("  shaderStorageImageMultisample: %#x.\n", features->shaderStorageImageMultisample);
    TRACE("  shaderStorageImageReadWithoutFormat: %#x.\n", features->shaderStorageImageReadWithoutFormat);
    TRACE("  shaderStorageImageWriteWithoutFormat: %#x.\n", features->shaderStorageImageWriteWithoutFormat);
    TRACE("  shaderUniformBufferArrayDynamicIndexing: %#x.\n", features->shaderUniformBufferArrayDynamicIndexing);
    TRACE("  shaderSampledImageArrayDynamicIndexing: %#x.\n", features->shaderSampledImageArrayDynamicIndexing);
    TRACE("  shaderStorageBufferArrayDynamicIndexing: %#x.\n", features->shaderStorageBufferArrayDynamicIndexing);
    TRACE("  shaderStorageImageArrayDynamicIndexing: %#x.\n", features->shaderStorageImageArrayDynamicIndexing);
    TRACE("  shaderClipDistance: %#x.\n", features->shaderClipDistance);
    TRACE("  shaderCullDistance: %#x.\n", features->shaderCullDistance);
    TRACE("  shaderFloat64: %#x.\n", features->shaderFloat64);
    TRACE("  shaderInt64: %#x.\n", features->shaderInt64);
    TRACE("  shaderInt16: %#x.\n", features->shaderInt16);
    TRACE("  shaderResourceResidency: %#x.\n", features->shaderResourceResidency);
    TRACE("  shaderResourceMinLod: %#x.\n", features->shaderResourceMinLod);
    TRACE("  sparseBinding: %#x.\n", features->sparseBinding);
    TRACE("  sparseResidencyBuffer: %#x.\n", features->sparseResidencyBuffer);
    TRACE("  sparseResidencyImage2D: %#x.\n", features->sparseResidencyImage2D);
    TRACE("  sparseResidencyImage3D: %#x.\n", features->sparseResidencyImage3D);
    TRACE("  sparseResidency2Samples: %#x.\n", features->sparseResidency2Samples);
    TRACE("  sparseResidency4Samples: %#x.\n", features->sparseResidency4Samples);
    TRACE("  sparseResidency8Samples: %#x.\n", features->sparseResidency8Samples);
    TRACE("  sparseResidency16Samples: %#x.\n", features->sparseResidency16Samples);
    TRACE("  sparseResidencyAliased: %#x.\n", features->sparseResidencyAliased);
    TRACE("  variableMultisampleRate: %#x.\n", features->variableMultisampleRate);
    TRACE("  inheritedQueries: %#x.\n", features->inheritedQueries);

    divisor_features = vk_find_struct(features2->pNext, PHYSICAL_DEVICE_VERTEX_ATTRIBUTE_DIVISOR_FEATURES_EXT);
    if (divisor_features)
    {
        TRACE("  VkPhysicalDeviceVertexAttributeDivisorFeaturesEXT:\n");
        TRACE("    vertexAttributeInstanceRateDivisor: %#x.\n",
                divisor_features->vertexAttributeInstanceRateDivisor);
        TRACE("    vertexAttributeInstanceRateZeroDivisor: %#x.\n",
                divisor_features->vertexAttributeInstanceRateZeroDivisor);
    }
}

static void vkd3d_check_feature_level_11_requirements(const struct vkd3d_vulkan_info *vk_info,
        const VkPhysicalDeviceFeatures *features)
{
#define CHECK_MIN_REQUIREMENT(name, value) \
    if (vk_info->device_limits.name < value) \
        WARN(#name " does not meet feature level 11_0 requirements.\n");
#define CHECK_MAX_REQUIREMENT(name, value) \
    if (vk_info->device_limits.name > value) \
        WARN(#name " does not meet feature level 11_0 requirements.\n");
#define CHECK_FEATURE(name) \
    if (!features->name) \
        WARN(#name " is not supported.\n");

    CHECK_MIN_REQUIREMENT(maxPushConstantsSize, D3D12_MAX_ROOT_COST * sizeof(uint32_t));
    CHECK_MIN_REQUIREMENT(maxComputeSharedMemorySize, D3D12_CS_TGSM_REGISTER_COUNT * sizeof(uint32_t));

    CHECK_MAX_REQUIREMENT(viewportBoundsRange[0], D3D12_VIEWPORT_BOUNDS_MIN);
    CHECK_MIN_REQUIREMENT(viewportBoundsRange[1], D3D12_VIEWPORT_BOUNDS_MAX);
    CHECK_MIN_REQUIREMENT(viewportSubPixelBits, 8);

    CHECK_MIN_REQUIREMENT(maxPerStageDescriptorUniformBuffers,
            D3D12_COMMONSHADER_CONSTANT_BUFFER_REGISTER_COUNT);

    CHECK_FEATURE(imageCubeArray);
    CHECK_FEATURE(independentBlend);
    CHECK_FEATURE(geometryShader);
    CHECK_FEATURE(tessellationShader);
    CHECK_FEATURE(sampleRateShading);
    CHECK_FEATURE(dualSrcBlend);
    CHECK_FEATURE(multiDrawIndirect);
    CHECK_FEATURE(drawIndirectFirstInstance);
    CHECK_FEATURE(depthClamp);
    CHECK_FEATURE(depthBiasClamp);
    CHECK_FEATURE(multiViewport);
    CHECK_FEATURE(occlusionQueryPrecise);
    CHECK_FEATURE(pipelineStatisticsQuery);
    CHECK_FEATURE(fragmentStoresAndAtomics);
    CHECK_FEATURE(shaderImageGatherExtended);
    CHECK_FEATURE(shaderStorageImageWriteWithoutFormat);
    CHECK_FEATURE(shaderClipDistance);
    CHECK_FEATURE(shaderCullDistance);

    if (!vk_info->EXT_vertex_attribute_divisor)
        WARN("Vertex attribute instance rate divisor is not supported.\n");
    else if (!vk_info->vertex_attrib_zero_divisor)
        WARN("Vertex attribute instance rate zero divisor is not supported.\n");

#undef CHECK_MIN_REQUIREMENT
#undef CHECK_MAX_REQUIREMENT
#undef CHECK_FEATURE
}

static HRESULT vkd3d_init_device_caps(struct d3d12_device *device,
        const struct vkd3d_device_create_info *create_info,
        VkPhysicalDeviceFeatures2KHR *features2, uint32_t *device_extension_count)
{
    const struct vkd3d_vk_instance_procs *vk_procs = &device->vkd3d_instance->vk_procs;
    const VkPhysicalDeviceVertexAttributeDivisorFeaturesEXT *divisor_features;
    VkPhysicalDevice physical_device = device->vk_physical_device;
    VkPhysicalDeviceFeatures *features = &features2->features;
    struct vkd3d_vulkan_info *vulkan_info = &device->vk_info;
    VkPhysicalDeviceProperties device_properties;
    VkExtensionProperties *vk_extensions;
    uint32_t count;
    VkResult vr;

    *device_extension_count = 0;

    vkd3d_trace_physical_device_features(features2);

    VK_CALL(vkGetPhysicalDeviceProperties(physical_device, &device_properties));
    vulkan_info->device_limits = device_properties.limits;
    vulkan_info->sparse_properties = device_properties.sparseProperties;

    device->feature_options.DoublePrecisionFloatShaderOps = features->shaderFloat64;
    device->feature_options.OutputMergerLogicOp = features->logicOp;
    /* SPV_KHR_16bit_storage */
    device->feature_options.MinPrecisionSupport = D3D12_SHADER_MIN_PRECISION_SUPPORT_NONE;

    if (!features->sparseBinding)
        device->feature_options.TiledResourcesTier = D3D12_TILED_RESOURCES_TIER_NOT_SUPPORTED;
    else if (!device->vk_info.sparse_properties.residencyNonResidentStrict)
        device->feature_options.TiledResourcesTier = D3D12_TILED_RESOURCES_TIER_1;
    else if (!features->sparseResidencyImage3D)
        device->feature_options.TiledResourcesTier = D3D12_TILED_RESOURCES_TIER_2;
    else
        device->feature_options.TiledResourcesTier = D3D12_TILED_RESOURCES_TIER_3;

    if (device->vk_info.device_limits.maxPerStageDescriptorSamplers <= 16)
        device->feature_options.ResourceBindingTier = D3D12_RESOURCE_BINDING_TIER_1;
    else if (device->vk_info.device_limits.maxPerStageDescriptorUniformBuffers <= 14)
        device->feature_options.ResourceBindingTier = D3D12_RESOURCE_BINDING_TIER_2;
    else
        device->feature_options.ResourceBindingTier = D3D12_RESOURCE_BINDING_TIER_3;

    device->feature_options.PSSpecifiedStencilRefSupported = FALSE;
    device->feature_options.TypedUAVLoadAdditionalFormats = features->shaderStorageImageExtendedFormats;
    /* GL_INTEL_fragment_shader_ordering, no Vulkan equivalent. */
    device->feature_options.ROVsSupported = FALSE;
    /* GL_INTEL_conservative_rasterization, no Vulkan equivalent. */
    device->feature_options.ConservativeRasterizationTier = D3D12_CONSERVATIVE_RASTERIZATION_TIER_NOT_SUPPORTED;
    device->feature_options.MaxGPUVirtualAddressBitsPerResource = sizeof(D3D12_GPU_VIRTUAL_ADDRESS) * 8;
    device->feature_options.StandardSwizzle64KBSupported = FALSE;
    device->feature_options.CrossNodeSharingTier = D3D12_CROSS_NODE_SHARING_TIER_NOT_SUPPORTED;
    device->feature_options.CrossAdapterRowMajorTextureSupported = FALSE;
    /* SPV_EXT_shader_viewport_index_layer */
    device->feature_options.VPAndRTArrayIndexFromAnyShaderFeedingRasterizerSupportedWithoutGSEmulation = FALSE;
    device->feature_options.ResourceHeapTier = D3D12_RESOURCE_HEAP_TIER_2;

    if ((vr = VK_CALL(vkEnumerateDeviceExtensionProperties(physical_device, NULL,
            &count, NULL))) < 0)
    {
        ERR("Failed to enumerate device extensions, vr %d.\n", vr);
        return hresult_from_vk_result(vr);
    }
    if (!count)
        return S_OK;

    if (!(vk_extensions = vkd3d_calloc(count, sizeof(*vk_extensions))))
        return E_OUTOFMEMORY;

    TRACE("Enumerating %u device extensions.\n", count);
    if ((vr = VK_CALL(vkEnumerateDeviceExtensionProperties(physical_device, NULL,
            &count, vk_extensions))) < 0)
    {
        ERR("Failed to enumerate device extensions, vr %d.\n", vr);
        vkd3d_free(vk_extensions);
        return hresult_from_vk_result(vr);
    }

    *device_extension_count = vkd3d_check_extensions(vk_extensions, count,
            required_device_extensions, ARRAY_SIZE(required_device_extensions),
            optional_device_extensions, ARRAY_SIZE(optional_device_extensions),
            create_info->device_extensions, create_info->device_extension_count,
            NULL, 0, NULL, vulkan_info, "device");

    divisor_features = vk_find_struct(features2->pNext, PHYSICAL_DEVICE_VERTEX_ATTRIBUTE_DIVISOR_FEATURES_EXT);
    if (get_spec_version(vk_extensions, count, VK_EXT_VERTEX_ATTRIBUTE_DIVISOR_EXTENSION_NAME) >= 3
            && divisor_features)
    {
        if (!divisor_features->vertexAttributeInstanceRateDivisor)
            vulkan_info->EXT_vertex_attribute_divisor = false;
        vulkan_info->vertex_attrib_zero_divisor = divisor_features->vertexAttributeInstanceRateZeroDivisor;
    }
    else
    {
        vulkan_info->vertex_attrib_zero_divisor = false;
    }

    vkd3d_check_feature_level_11_requirements(vulkan_info, features);

    features->shaderTessellationAndGeometryPointSize = VK_FALSE;

    vkd3d_free(vk_extensions);

    return S_OK;
}

static HRESULT vkd3d_select_physical_device(struct vkd3d_instance *instance,
        VkPhysicalDevice *selected_device)
{
    const struct vkd3d_vk_instance_procs *vk_procs = &instance->vk_procs;
    VkInstance vk_instance = instance->vk_instance;
    VkPhysicalDevice *physical_devices;
    uint32_t count;
    unsigned int i;
    VkResult vr;

    count = 0;
    if ((vr = VK_CALL(vkEnumeratePhysicalDevices(vk_instance, &count, NULL))) < 0)
    {
        ERR("Failed to enumerate physical devices, vr %d.\n", vr);
        return hresult_from_vk_result(vr);
    }
    if (!count)
    {
        ERR("No physical device available.\n");
        return E_FAIL;
    }
    if (!(physical_devices = vkd3d_calloc(count, sizeof(*physical_devices))))
        return E_OUTOFMEMORY;

    TRACE("Enumerating %u physical device(s).\n", count);
    if ((vr = VK_CALL(vkEnumeratePhysicalDevices(vk_instance, &count, physical_devices))) < 0)
    {
        ERR("Failed to enumerate physical devices, vr %d.\n", vr);
        vkd3d_free(physical_devices);
        return hresult_from_vk_result(vr);
    }

    for (i = 0; i < count; ++i)
        vkd3d_trace_physical_device(physical_devices[i], vk_procs);

    if (count > 1)
        FIXME("Multiple physical devices available, selecting the first one.\n");

    *selected_device = physical_devices[0];

    vkd3d_free(physical_devices);

    return S_OK;
}

static void d3d12_device_destroy_vkd3d_queues(struct d3d12_device *device)
{
    if (device->direct_queue)
        vkd3d_queue_destroy(device->direct_queue);
    if (device->compute_queue && device->compute_queue != device->direct_queue)
        vkd3d_queue_destroy(device->compute_queue);
    if (device->copy_queue && device->copy_queue != device->direct_queue
            && device->copy_queue != device->compute_queue)
        vkd3d_queue_destroy(device->copy_queue);

    device->direct_queue = NULL;
    device->compute_queue = NULL;
    device->copy_queue = NULL;
}

static HRESULT d3d12_device_create_vkd3d_queues(struct d3d12_device *device,
        const VkQueueFamilyProperties *queue_properties, uint32_t direct_queue_family_index,
        uint32_t compute_queue_family_index, uint32_t copy_queue_family_index)
{
    HRESULT hr;

    device->direct_queue = NULL;
    device->compute_queue = NULL;
    device->copy_queue = NULL;

    if (FAILED((hr = vkd3d_queue_create(device, direct_queue_family_index,
            &queue_properties[direct_queue_family_index], &device->direct_queue))))
        goto out_destroy_queues;

    if (compute_queue_family_index == direct_queue_family_index)
        device->compute_queue = device->direct_queue;
    else if (FAILED(hr = vkd3d_queue_create(device, compute_queue_family_index,
            &queue_properties[compute_queue_family_index], &device->compute_queue)))
        goto out_destroy_queues;

    if (copy_queue_family_index == direct_queue_family_index)
        device->copy_queue = device->direct_queue;
    else if (copy_queue_family_index == compute_queue_family_index)
        device->copy_queue = device->compute_queue;
    else if (FAILED(hr = vkd3d_queue_create(device, copy_queue_family_index,
            &queue_properties[copy_queue_family_index], &device->copy_queue)))
        goto out_destroy_queues;

    return S_OK;

out_destroy_queues:
    d3d12_device_destroy_vkd3d_queues(device);
    return hr;
}

static HRESULT vkd3d_create_vk_device(struct d3d12_device *device,
        const struct vkd3d_device_create_info *create_info)
{
    unsigned int direct_queue_family_index, copy_queue_family_index, compute_queue_family_index;
    const struct vkd3d_vk_instance_procs *vk_procs = &device->vkd3d_instance->vk_procs;
    VkPhysicalDeviceVertexAttributeDivisorFeaturesEXT vertex_divisor_features;
    struct vkd3d_vulkan_info *vulkan_info = &device->vk_info;
    VkQueueFamilyProperties *queue_properties = NULL;
    VkDeviceQueueCreateInfo *queue_info = NULL;
    VkPhysicalDeviceFeatures2 features2;
    VkPhysicalDevice physical_device;
    VkDeviceCreateInfo device_info;
    uint32_t queue_family_count;
    uint32_t extension_count;
    const char **extensions;
    VkDevice vk_device;
    unsigned int i;
    VkResult vr;
    HRESULT hr;

    TRACE("device %p, create_info %p.\n", device, create_info);

    physical_device = create_info->vk_physical_device;
    if (!physical_device
            && FAILED(hr = vkd3d_select_physical_device(device->vkd3d_instance, &physical_device)))
        return hr;

    device->vk_physical_device = physical_device;

    /* Create command queues */
    VK_CALL(vkGetPhysicalDeviceQueueFamilyProperties(physical_device, &queue_family_count, NULL));
    if (!(queue_properties = vkd3d_calloc(queue_family_count, sizeof(*queue_properties))))
        return E_OUTOFMEMORY;
    VK_CALL(vkGetPhysicalDeviceQueueFamilyProperties(physical_device,
            &queue_family_count, queue_properties));

    if (!(queue_info = vkd3d_calloc(queue_family_count, sizeof(*queue_info))))
    {
        hr = E_OUTOFMEMORY;
        goto done;
    }

    direct_queue_family_index = ~0u;
    copy_queue_family_index = ~0u;
    compute_queue_family_index = ~0u;
    for (i = 0; i < queue_family_count; ++i)
    {
        static float priorities[] = {1.0f};

        queue_info[i].sType = VK_STRUCTURE_TYPE_DEVICE_QUEUE_CREATE_INFO;
        queue_info[i].pNext = NULL;
        queue_info[i].flags = 0;
        queue_info[i].queueFamilyIndex = i;
        queue_info[i].queueCount = 1;
        queue_info[i].pQueuePriorities = priorities;

        if ((queue_properties[i].queueFlags & (VK_QUEUE_GRAPHICS_BIT | VK_QUEUE_COMPUTE_BIT))
                == (VK_QUEUE_GRAPHICS_BIT | VK_QUEUE_COMPUTE_BIT))
        {
            direct_queue_family_index = i;
        }
        if (queue_properties[i].queueFlags & VK_QUEUE_TRANSFER_BIT)
        {
            copy_queue_family_index = i;
        }
        if ((queue_properties[i].queueFlags & (VK_QUEUE_GRAPHICS_BIT | VK_QUEUE_COMPUTE_BIT))
                == VK_QUEUE_COMPUTE_BIT)
        {
            compute_queue_family_index = i;
        }
    }

    if (direct_queue_family_index == ~0u)
    {
        FIXME("Could not find a suitable queue family for a direct command queue.\n");
        hr = E_FAIL;
        goto done;
    }
    if (copy_queue_family_index == ~0u)
    {
        FIXME("Could not find a suitable queue family for a copy command queue.\n");
        hr = E_FAIL;
        goto done;
    }
    if (compute_queue_family_index == ~0u)
    {
        /* No compute-only queue family, reuse the direct queue family with graphics and compute. */
        compute_queue_family_index = direct_queue_family_index;
    }

    TRACE("Using queue family %u for direct command queues.\n", direct_queue_family_index);
    TRACE("Using queue family %u for copy command queues.\n", copy_queue_family_index);
    TRACE("Using queue family %u for compute command queues.\n", compute_queue_family_index);

    VK_CALL(vkGetPhysicalDeviceMemoryProperties(physical_device, &device->memory_properties));

    memset(&vertex_divisor_features, 0, sizeof(vertex_divisor_features));
    vertex_divisor_features.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_VERTEX_ATTRIBUTE_DIVISOR_FEATURES_EXT;
    features2.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_FEATURES_2;
    features2.pNext = &vertex_divisor_features;
    if (vulkan_info->KHR_get_physical_device_properties2)
        VK_CALL(vkGetPhysicalDeviceFeatures2KHR(physical_device, &features2));
    else
        VK_CALL(vkGetPhysicalDeviceFeatures(physical_device, &features2.features));

    if (FAILED(hr = vkd3d_init_device_caps(device, create_info, &features2, &extension_count)))
        goto done;

    if (!(extensions = vkd3d_calloc(extension_count, sizeof(*extensions))))
    {
        hr = E_OUTOFMEMORY;
        goto done;
    }

    /* Create device */
    device_info.sType = VK_STRUCTURE_TYPE_DEVICE_CREATE_INFO;
    device_info.pNext = &vertex_divisor_features;
    device_info.flags = 0;
    device_info.queueCreateInfoCount = queue_family_count;
    device_info.pQueueCreateInfos = queue_info;
    device_info.enabledLayerCount = 0;
    device_info.ppEnabledLayerNames = NULL;
    device_info.enabledExtensionCount = vkd3d_enable_extensions(extensions,
            required_device_extensions, ARRAY_SIZE(required_device_extensions),
            optional_device_extensions, ARRAY_SIZE(optional_device_extensions),
            create_info->device_extensions, create_info->device_extension_count,
            NULL, 0, NULL, &device->vk_info);
    device_info.ppEnabledExtensionNames = extensions;
    device_info.pEnabledFeatures = &features2.features;

    vr = VK_CALL(vkCreateDevice(physical_device, &device_info, NULL, &vk_device));
    vkd3d_free(extensions);
    if (vr < 0)
    {
        ERR("Failed to create Vulkan device, vr %d.\n", vr);
        hr = hresult_from_vk_result(vr);
        goto done;
    }

    if (FAILED(hr = vkd3d_load_vk_device_procs(&device->vk_procs, vk_procs, vk_device)))
    {
        ERR("Failed to load device procs, hr %#x.\n", hr);
        if (device->vk_procs.vkDestroyDevice)
            device->vk_procs.vkDestroyDevice(vk_device, NULL);
        goto done;
    }

    device->vk_device = vk_device;

    if (FAILED(hr = d3d12_device_create_vkd3d_queues(device, queue_properties,
            direct_queue_family_index, compute_queue_family_index, copy_queue_family_index)))
    {
        ERR("Failed to create queues, hr %#x.\n", hr);
        device->vk_procs.vkDestroyDevice(vk_device, NULL);
        goto done;
    }

    TRACE("Created Vulkan device %p.\n", vk_device);

done:
    if (queue_properties)
        vkd3d_free(queue_properties);
    if (queue_info)
        vkd3d_free(queue_info);
    return hr;
}

static HRESULT d3d12_device_create_dummy_sampler(struct d3d12_device *device)
{
    D3D12_STATIC_SAMPLER_DESC sampler_desc;

    memset(&sampler_desc, 0, sizeof(sampler_desc));
    sampler_desc.Filter = D3D12_FILTER_MIN_MAG_MIP_POINT;
    sampler_desc.AddressU = D3D12_TEXTURE_ADDRESS_MODE_CLAMP;
    sampler_desc.AddressV = D3D12_TEXTURE_ADDRESS_MODE_CLAMP;
    sampler_desc.AddressW = D3D12_TEXTURE_ADDRESS_MODE_CLAMP;
    return vkd3d_create_static_sampler(device, &sampler_desc, &device->vk_dummy_sampler);
}

static HRESULT d3d12_device_init_pipeline_cache(struct d3d12_device *device)
{
    const struct vkd3d_vk_device_procs *vk_procs = &device->vk_procs;
    VkPipelineCacheCreateInfo cache_info;
    VkResult vr;
    int rc;

    if ((rc = pthread_mutex_init(&device->pipeline_cache_mutex, NULL)))
    {
        ERR("Failed to initialize mutex, error %d.\n", rc);
        return E_FAIL;
    }

    cache_info.sType = VK_STRUCTURE_TYPE_PIPELINE_CACHE_CREATE_INFO;
    cache_info.pNext = NULL;
    cache_info.flags = 0;
    cache_info.initialDataSize = 0;
    cache_info.pInitialData = NULL;
    if ((vr = VK_CALL(vkCreatePipelineCache(device->vk_device, &cache_info, NULL,
            &device->vk_pipeline_cache))) < 0)
    {
        ERR("Failed to create Vulkan pipeline cache, vr %d.\n", vr);
        device->vk_pipeline_cache = VK_NULL_HANDLE;
    }

    return S_OK;
}

static void d3d12_device_destroy_pipeline_cache(struct d3d12_device *device)
{
    const struct vkd3d_vk_device_procs *vk_procs = &device->vk_procs;

    if (device->vk_pipeline_cache)
        VK_CALL(vkDestroyPipelineCache(device->vk_device, device->vk_pipeline_cache, NULL));

    pthread_mutex_destroy(&device->pipeline_cache_mutex);
}

D3D12_GPU_VIRTUAL_ADDRESS vkd3d_gpu_va_allocator_allocate(struct vkd3d_gpu_va_allocator *allocator,
        size_t size, void *ptr)
{
    D3D12_GPU_VIRTUAL_ADDRESS ceiling = ~(D3D12_GPU_VIRTUAL_ADDRESS)0;
    struct vkd3d_gpu_va_allocation *allocation;
    int rc;

    if ((rc = pthread_mutex_lock(&allocator->mutex)))
    {
        ERR("Failed to lock mutex, error %d.\n", rc);
        return 0;
    }

    if (!vkd3d_array_reserve((void **)&allocator->allocations, &allocator->allocations_size,
            allocator->allocation_count + 1, sizeof(*allocator->allocations)))
    {
        pthread_mutex_unlock(&allocator->mutex);
        return 0;
    }

    if (size > ceiling || ceiling - size < allocator->floor)
    {
        pthread_mutex_unlock(&allocator->mutex);
        return 0;
    }

    allocation = &allocator->allocations[allocator->allocation_count++];
    allocation->base = allocator->floor;
    allocation->size = size;
    allocation->ptr = ptr;

    allocator->floor += size;

    pthread_mutex_unlock(&allocator->mutex);

    return allocation->base;
}

static int vkd3d_gpu_va_allocation_compare(const void *k, const void *e)
{
    const struct vkd3d_gpu_va_allocation *allocation = e;
    const D3D12_GPU_VIRTUAL_ADDRESS *address = k;

    if (*address < allocation->base)
        return -1;
    if (*address - allocation->base >= allocation->size)
        return 1;
    return 0;
}

void *vkd3d_gpu_va_allocator_dereference(struct vkd3d_gpu_va_allocator *allocator,
        D3D12_GPU_VIRTUAL_ADDRESS address)
{
    struct vkd3d_gpu_va_allocation *allocation;
    int rc;

    if ((rc = pthread_mutex_lock(&allocator->mutex)))
    {
        ERR("Failed to lock mutex, error %d.\n", rc);
        return NULL;
    }

    allocation = bsearch(&address, allocator->allocations, allocator->allocation_count,
            sizeof(*allocation), vkd3d_gpu_va_allocation_compare);

    pthread_mutex_unlock(&allocator->mutex);

    return allocation ? allocation->ptr : NULL;
}

void vkd3d_gpu_va_allocator_free(struct vkd3d_gpu_va_allocator *allocator, D3D12_GPU_VIRTUAL_ADDRESS address)
{
    struct vkd3d_gpu_va_allocation *allocation;
    int rc;

    if ((rc = pthread_mutex_lock(&allocator->mutex)))
    {
        ERR("Failed to lock mutex, error %d.\n", rc);
        return;
    }

    allocation = bsearch(&address, allocator->allocations, allocator->allocation_count,
            sizeof(*allocation), vkd3d_gpu_va_allocation_compare);
    if (allocation && allocation->base == address)
        allocation->ptr = NULL;

    pthread_mutex_unlock(&allocator->mutex);
}

static bool vkd3d_gpu_va_allocator_init(struct vkd3d_gpu_va_allocator *allocator)
{
    int rc;

    memset(allocator, 0, sizeof(*allocator));
    allocator->floor = 0x1000;

    if ((rc = pthread_mutex_init(&allocator->mutex, NULL)))
    {
        ERR("Failed to initialize mutex, error %d.\n", rc);
        return false;
    }

    return true;
}

static void vkd3d_gpu_va_allocator_cleanup(struct vkd3d_gpu_va_allocator *allocator)
{
    int rc;

    if ((rc = pthread_mutex_lock(&allocator->mutex)))
    {
        ERR("Failed to lock mutex, error %d.\n", rc);
        return;
    }
    vkd3d_free(allocator->allocations);
    pthread_mutex_unlock(&allocator->mutex);
    pthread_mutex_destroy(&allocator->mutex);
}

/* ID3D12Device */
static inline struct d3d12_device *impl_from_ID3D12Device(ID3D12Device *iface)
{
    return CONTAINING_RECORD(iface, struct d3d12_device, ID3D12Device_iface);
}

static HRESULT STDMETHODCALLTYPE d3d12_device_QueryInterface(ID3D12Device *iface,
        REFIID riid, void **object)
{
    TRACE("iface %p, riid %s, object %p.\n", iface, debugstr_guid(riid), object);

    if (IsEqualGUID(riid, &IID_ID3D12Device)
            || IsEqualGUID(riid, &IID_ID3D12Object)
            || IsEqualGUID(riid, &IID_IUnknown))
    {
        ID3D12Device_AddRef(iface);
        *object = iface;
        return S_OK;
    }

    WARN("%s not implemented, returning E_NOINTERFACE.\n", debugstr_guid(riid));

    *object = NULL;
    return E_NOINTERFACE;
}

static ULONG STDMETHODCALLTYPE d3d12_device_AddRef(ID3D12Device *iface)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    ULONG refcount = InterlockedIncrement(&device->refcount);

    TRACE("%p increasing refcount to %u.\n", device, refcount);

    return refcount;
}

static ULONG STDMETHODCALLTYPE d3d12_device_Release(ID3D12Device *iface)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    ULONG refcount = InterlockedDecrement(&device->refcount);

    TRACE("%p decreasing refcount to %u.\n", device, refcount);

    if (!refcount)
    {
        const struct vkd3d_vk_device_procs *vk_procs = &device->vk_procs;

        vkd3d_gpu_va_allocator_cleanup(&device->gpu_va_allocator);
        vkd3d_fence_worker_stop(&device->fence_worker, device);
        VK_CALL(vkDestroySampler(device->vk_device, device->vk_dummy_sampler, NULL));
        d3d12_device_destroy_pipeline_cache(device);
        d3d12_device_destroy_vkd3d_queues(device);
        VK_CALL(vkDestroyDevice(device->vk_device, NULL));
        if (device->parent)
            IUnknown_Release(device->parent);
        vkd3d_instance_decref(device->vkd3d_instance);

        vkd3d_free(device);
    }

    return refcount;
}

static HRESULT STDMETHODCALLTYPE d3d12_device_GetPrivateData(ID3D12Device *iface,
        REFGUID guid, UINT *data_size, void *data)
{
    FIXME("iface %p, guid %s, data_size %p, data %p stub!",
            iface, debugstr_guid(guid), data_size, data);

    return E_NOTIMPL;
}

static HRESULT STDMETHODCALLTYPE d3d12_device_SetPrivateData(ID3D12Device *iface,
        REFGUID guid, UINT data_size, const void *data)
{
    FIXME("iface %p, guid %s, data_size %u, data %p stub!\n",
            iface, debugstr_guid(guid), data_size, data);

    return E_NOTIMPL;
}

static HRESULT STDMETHODCALLTYPE d3d12_device_SetPrivateDataInterface(ID3D12Device *iface,
        REFGUID guid, const IUnknown *data)
{
    FIXME("iface %p, guid %s, data %p stub!\n", iface, debugstr_guid(guid), data);

    return E_NOTIMPL;
}

static HRESULT STDMETHODCALLTYPE d3d12_device_SetName(ID3D12Device *iface, const WCHAR *name)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);

    FIXME("iface %p, name %s stub!\n", iface, debugstr_w(name, device->wchar_size));

    return E_NOTIMPL;
}

static UINT STDMETHODCALLTYPE d3d12_device_GetNodeCount(ID3D12Device *iface)
{
    TRACE("iface %p.\n", iface);

    return 1;
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreateCommandQueue(ID3D12Device *iface,
        const D3D12_COMMAND_QUEUE_DESC *desc, REFIID riid, void **command_queue)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    struct d3d12_command_queue *object;
    HRESULT hr;

    TRACE("iface %p, desc %p, riid %s, command_queue %p.\n",
            iface, desc, debugstr_guid(riid), command_queue);

    if (FAILED(hr = d3d12_command_queue_create(device, desc, &object)))
        return hr;

    return return_interface(&object->ID3D12CommandQueue_iface, &IID_ID3D12CommandQueue,
            riid, command_queue);
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreateCommandAllocator(ID3D12Device *iface,
        D3D12_COMMAND_LIST_TYPE type, REFIID riid, void **command_allocator)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    struct d3d12_command_allocator *object;
    HRESULT hr;

    TRACE("iface %p, type %#x, riid %s, command_allocator %p.\n",
            iface, type, debugstr_guid(riid), command_allocator);

    if (FAILED(hr = d3d12_command_allocator_create(device, type, &object)))
        return hr;

    return return_interface(&object->ID3D12CommandAllocator_iface, &IID_ID3D12CommandAllocator,
            riid, command_allocator);
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreateGraphicsPipelineState(ID3D12Device *iface,
        const D3D12_GRAPHICS_PIPELINE_STATE_DESC *desc, REFIID riid, void **pipeline_state)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    struct d3d12_pipeline_state *object;
    HRESULT hr;

    TRACE("iface %p, desc %p, riid %s, pipeline_state %p.\n",
            iface, desc, debugstr_guid(riid), pipeline_state);

    if (FAILED(hr = d3d12_pipeline_state_create_graphics(device, desc, &object)))
        return hr;

    return return_interface(&object->ID3D12PipelineState_iface,
            &IID_ID3D12PipelineState, riid, pipeline_state);
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreateComputePipelineState(ID3D12Device *iface,
        const D3D12_COMPUTE_PIPELINE_STATE_DESC *desc, REFIID riid, void **pipeline_state)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    struct d3d12_pipeline_state *object;
    HRESULT hr;

    TRACE("iface %p, desc %p, riid %s, pipeline_state %p.\n",
            iface, desc, debugstr_guid(riid), pipeline_state);

    if (FAILED(hr = d3d12_pipeline_state_create_compute(device, desc, &object)))
        return hr;

    return return_interface(&object->ID3D12PipelineState_iface,
            &IID_ID3D12PipelineState, riid, pipeline_state);
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreateCommandList(ID3D12Device *iface,
        UINT node_mask, D3D12_COMMAND_LIST_TYPE type, ID3D12CommandAllocator *command_allocator,
        ID3D12PipelineState *initial_pipeline_state, REFIID riid, void **command_list)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    struct d3d12_command_list *object;
    HRESULT hr;

    TRACE("iface %p, node_mask 0x%08x, type %#x, command_allocator %p, "
            "initial_pipeline_state %p, riid %s, command_list %p.\n",
            iface, node_mask, type, command_allocator,
            initial_pipeline_state, debugstr_guid(riid), command_list);

    if (FAILED(hr = d3d12_command_list_create(device, node_mask, type, command_allocator,
            initial_pipeline_state, &object)))
        return hr;

    return return_interface(&object->ID3D12GraphicsCommandList_iface,
            &IID_ID3D12GraphicsCommandList, riid, command_list);
}

/* Direct3D feature levels restrict which formats can be optionally supported. */
static void vkd3d_restrict_format_support_for_feature_level(D3D12_FEATURE_DATA_FORMAT_SUPPORT *format_support)
{
    static const D3D12_FEATURE_DATA_FORMAT_SUPPORT blacklisted_format_features[] =
    {
        {DXGI_FORMAT_B8G8R8A8_TYPELESS, D3D12_FORMAT_SUPPORT1_TYPED_UNORDERED_ACCESS_VIEW,
                D3D12_FORMAT_SUPPORT2_UAV_TYPED_LOAD | D3D12_FORMAT_SUPPORT2_UAV_TYPED_STORE},
        {DXGI_FORMAT_B8G8R8A8_UNORM,    D3D12_FORMAT_SUPPORT1_TYPED_UNORDERED_ACCESS_VIEW,
                D3D12_FORMAT_SUPPORT2_UAV_TYPED_LOAD | D3D12_FORMAT_SUPPORT2_UAV_TYPED_STORE},
    };
    unsigned int i;

    for (i = 0; i < ARRAY_SIZE(blacklisted_format_features); ++i)
    {
        if (blacklisted_format_features[i].Format == format_support->Format)
        {
            format_support->Support1 &= ~blacklisted_format_features[i].Support1;
            format_support->Support2 &= ~blacklisted_format_features[i].Support2;
            break;
        }
    }
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CheckFeatureSupport(ID3D12Device *iface,
        D3D12_FEATURE feature, void *feature_data, UINT feature_data_size)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);

    TRACE("iface %p, feature %#x, feature_data %p, feature_data_size %u.\n",
            iface, feature, feature_data, feature_data_size);

    switch (feature)
    {
        case D3D12_FEATURE_D3D12_OPTIONS:
        {
            D3D12_FEATURE_DATA_D3D12_OPTIONS *data = feature_data;

            if (feature_data_size != sizeof(*data))
            {
                WARN("Invalid size %u.\n", feature_data_size);
                return E_INVALIDARG;
            }

            *data = device->feature_options;

            return S_OK;
        }

        case D3D12_FEATURE_ARCHITECTURE:
        {
            D3D12_FEATURE_DATA_ARCHITECTURE *data = feature_data;

            if (feature_data_size != sizeof(*data))
            {
                WARN("Invalid size %u.\n", feature_data_size);
                return E_INVALIDARG;
            }

            if (data->NodeIndex)
            {
                FIXME("Multi-adapter not supported.\n");
                return E_INVALIDARG;
            }

            FIXME("Assuming device does not support tile based rendering.\n");
            data->TileBasedRenderer = FALSE;

            if (device->memory_properties.memoryTypeCount == 1)
            {
                TRACE("Assuming cache coherent UMA.\n");
                data->UMA = TRUE;
                data->CacheCoherentUMA = TRUE;
            }
            else
            {
                FIXME("Assuming NUMA.\n");
                data->UMA = FALSE;
                data->CacheCoherentUMA = FALSE;
            }
            return S_OK;
        }

        case D3D12_FEATURE_FEATURE_LEVELS:
        {
            D3D12_FEATURE_DATA_FEATURE_LEVELS *data = feature_data;
            unsigned int i;

            if (feature_data_size != sizeof(*data))
            {
                WARN("Invalid size %u.\n", feature_data_size);
                return E_INVALIDARG;
            }
            if (!data->NumFeatureLevels)
                return E_INVALIDARG;

            data->MaxSupportedFeatureLevel = 0;
            for (i = 0; i < data->NumFeatureLevels; ++i)
            {
                D3D_FEATURE_LEVEL fl = data->pFeatureLevelsRequested[i];
                if (data->MaxSupportedFeatureLevel < fl && check_feature_level_support(fl))
                    data->MaxSupportedFeatureLevel = fl;
            }
            return S_OK;
        }

        case D3D12_FEATURE_FORMAT_SUPPORT:
        {
            const struct vkd3d_vk_device_procs *vk_procs = &device->vk_procs;
            D3D12_FEATURE_DATA_FORMAT_SUPPORT *data = feature_data;
            VkFormatFeatureFlagBits image_features;
            const struct vkd3d_format *format;
            VkFormatProperties properties;

            if (feature_data_size != sizeof(*data))
            {
                WARN("Invalid size %u.\n", feature_data_size);
                return E_INVALIDARG;
            }

            data->Support1 = D3D12_FORMAT_SUPPORT1_NONE;
            data->Support2 = D3D12_FORMAT_SUPPORT2_NONE;
            if (!(format = vkd3d_get_format(data->Format, false)))
            {
                FIXME("Unhandled format %#x.\n", data->Format);
                return E_INVALIDARG;
            }

            VK_CALL(vkGetPhysicalDeviceFormatProperties(device->vk_physical_device, format->vk_format, &properties));
            image_features = properties.linearTilingFeatures | properties.optimalTilingFeatures;

            if (properties.bufferFeatures)
                data->Support1 |= D3D12_FORMAT_SUPPORT1_BUFFER;
            if (properties.bufferFeatures & VK_FORMAT_FEATURE_VERTEX_BUFFER_BIT)
                data->Support1 |= D3D12_FORMAT_SUPPORT1_IA_VERTEX_BUFFER;
            if (data->Format == DXGI_FORMAT_R16_UINT || data->Format == DXGI_FORMAT_R32_UINT)
                data->Support1 |= D3D12_FORMAT_SUPPORT1_IA_INDEX_BUFFER;
            if (image_features)
                data->Support1 |= D3D12_FORMAT_SUPPORT1_TEXTURE1D | D3D12_FORMAT_SUPPORT1_TEXTURE2D
                        | D3D12_FORMAT_SUPPORT1_TEXTURE3D | D3D12_FORMAT_SUPPORT1_TEXTURECUBE;
            if (image_features & VK_FORMAT_FEATURE_SAMPLED_IMAGE_BIT)
            {
                data->Support1 |= D3D12_FORMAT_SUPPORT1_SHADER_LOAD | D3D12_FORMAT_SUPPORT1_MULTISAMPLE_LOAD
                        | D3D12_FORMAT_SUPPORT1_SHADER_GATHER;
                if (image_features & VK_FORMAT_FEATURE_SAMPLED_IMAGE_FILTER_LINEAR_BIT)
                {
                    data->Support1 |= D3D12_FORMAT_SUPPORT1_SHADER_SAMPLE
                            | D3D12_FORMAT_SUPPORT1_MIP;
                }
                if (format->vk_aspect_mask & VK_IMAGE_ASPECT_DEPTH_BIT)
                    data->Support1 |= D3D12_FORMAT_SUPPORT1_SHADER_SAMPLE_COMPARISON
                            | D3D12_FORMAT_SUPPORT1_SHADER_GATHER_COMPARISON;
            }
            if (image_features & VK_FORMAT_FEATURE_COLOR_ATTACHMENT_BIT)
                data->Support1 |= D3D12_FORMAT_SUPPORT1_RENDER_TARGET | D3D12_FORMAT_SUPPORT1_MULTISAMPLE_RENDERTARGET;
            if (image_features & VK_FORMAT_FEATURE_COLOR_ATTACHMENT_BLEND_BIT)
                data->Support1 |= D3D12_FORMAT_SUPPORT1_BLENDABLE;
            if (image_features & VK_FORMAT_FEATURE_DEPTH_STENCIL_ATTACHMENT_BIT)
                data->Support1 |= D3D12_FORMAT_SUPPORT1_DEPTH_STENCIL;
            if (image_features & VK_FORMAT_FEATURE_BLIT_SRC_BIT)
                data->Support1 |= D3D12_FORMAT_SUPPORT1_MULTISAMPLE_RESOLVE;
            if (image_features & VK_FORMAT_FEATURE_STORAGE_IMAGE_BIT)
                data->Support1 |= D3D12_FORMAT_SUPPORT1_TYPED_UNORDERED_ACCESS_VIEW;

            if (image_features & VK_FORMAT_FEATURE_STORAGE_IMAGE_ATOMIC_BIT)
                data->Support2 |= D3D12_FORMAT_SUPPORT2_UAV_ATOMIC_ADD
                        | D3D12_FORMAT_SUPPORT2_UAV_ATOMIC_BITWISE_OPS
                        | D3D12_FORMAT_SUPPORT2_UAV_ATOMIC_COMPARE_STORE_OR_COMPARE_EXCHANGE
                        | D3D12_FORMAT_SUPPORT2_UAV_ATOMIC_EXCHANGE
                        | D3D12_FORMAT_SUPPORT2_UAV_ATOMIC_SIGNED_MIN_OR_MAX
                        | D3D12_FORMAT_SUPPORT2_UAV_ATOMIC_UNSIGNED_MIN_OR_MAX;

            vkd3d_restrict_format_support_for_feature_level(data);

            return S_OK;
        }

        case D3D12_FEATURE_SHADER_MODEL:
        {
            D3D12_FEATURE_DATA_SHADER_MODEL *data = feature_data;

            if (feature_data_size != sizeof(*data))
            {
                WARN("Invalid size %u.\n", feature_data_size);
                return E_INVALIDARG;
            }

            TRACE("Request shader model %#x.\n", data->HighestShaderModel);

            data->HighestShaderModel = D3D_SHADER_MODEL_5_1;
            return S_OK;
        }

        case D3D12_FEATURE_ROOT_SIGNATURE:
        {
            D3D12_FEATURE_DATA_ROOT_SIGNATURE *data = feature_data;

            if (feature_data_size != sizeof(*data))
            {
                WARN("Invalid size %u.\n", feature_data_size);
                return E_INVALIDARG;
            }

            FIXME("Root signature version 1_1 not supported yet.\n");
            data->HighestVersion = D3D_ROOT_SIGNATURE_VERSION_1_0;
            return S_OK;
        }

        default:
            FIXME("Unhandled feature %#x.\n", feature);
            return E_NOTIMPL;
    }
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreateDescriptorHeap(ID3D12Device *iface,
        const D3D12_DESCRIPTOR_HEAP_DESC *desc, REFIID riid, void **descriptor_heap)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    struct d3d12_descriptor_heap *object;
    HRESULT hr;

    TRACE("iface %p, desc %p, riid %s, descriptor_heap %p.\n",
            iface, desc, debugstr_guid(riid), descriptor_heap);

    if (FAILED(hr = d3d12_descriptor_heap_create(device, desc, &object)))
        return hr;

    return return_interface(&object->ID3D12DescriptorHeap_iface,
            &IID_ID3D12DescriptorHeap, riid, descriptor_heap);
}

static UINT STDMETHODCALLTYPE d3d12_device_GetDescriptorHandleIncrementSize(ID3D12Device *iface,
        D3D12_DESCRIPTOR_HEAP_TYPE descriptor_heap_type)
{
    TRACE("iface %p, descriptor_heap_type %#x.\n", iface, descriptor_heap_type);

    switch (descriptor_heap_type)
    {
        case D3D12_DESCRIPTOR_HEAP_TYPE_CBV_SRV_UAV:
        case D3D12_DESCRIPTOR_HEAP_TYPE_SAMPLER:
            return sizeof(struct d3d12_desc);

        case D3D12_DESCRIPTOR_HEAP_TYPE_RTV:
            return sizeof(struct d3d12_rtv_desc);

        case D3D12_DESCRIPTOR_HEAP_TYPE_DSV:
            return sizeof(struct d3d12_dsv_desc);

        default:
            FIXME("Unhandled type %#x.\n", descriptor_heap_type);
            return 0;
    }
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreateRootSignature(ID3D12Device *iface,
        UINT node_mask, const void *bytecode, SIZE_T bytecode_length,
        REFIID riid, void **root_signature)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    struct d3d12_root_signature *object;
    HRESULT hr;

    TRACE("iface %p, node_mask 0x%08x, bytecode %p, bytecode_length %lu, riid %s, root_signature %p.\n",
            iface, node_mask, bytecode, bytecode_length, debugstr_guid(riid), root_signature);

    debug_ignored_node_mask(node_mask);

    if (FAILED(hr = d3d12_root_signature_create(device, bytecode, bytecode_length, &object)))
        return hr;

    return return_interface(&object->ID3D12RootSignature_iface,
            &IID_ID3D12RootSignature, riid, root_signature);
}

static void STDMETHODCALLTYPE d3d12_device_CreateConstantBufferView(ID3D12Device *iface,
        const D3D12_CONSTANT_BUFFER_VIEW_DESC *desc, D3D12_CPU_DESCRIPTOR_HANDLE descriptor)
{
    TRACE("iface %p, desc %p, descriptor %#lx.\n", iface, desc, descriptor.ptr);

    d3d12_desc_create_cbv(d3d12_desc_from_cpu_handle(descriptor),
            impl_from_ID3D12Device(iface), desc);
}

static void STDMETHODCALLTYPE d3d12_device_CreateShaderResourceView(ID3D12Device *iface,
        ID3D12Resource *resource, const D3D12_SHADER_RESOURCE_VIEW_DESC *desc,
        D3D12_CPU_DESCRIPTOR_HANDLE descriptor)
{
    TRACE("iface %p, resource %p, desc %p, descriptor %#lx.\n",
            iface, resource, desc, descriptor.ptr);

    d3d12_desc_create_srv(d3d12_desc_from_cpu_handle(descriptor),
            impl_from_ID3D12Device(iface), unsafe_impl_from_ID3D12Resource(resource), desc);
}

static void STDMETHODCALLTYPE d3d12_device_CreateUnorderedAccessView(ID3D12Device *iface,
        ID3D12Resource *resource, ID3D12Resource *counter_resource,
        const D3D12_UNORDERED_ACCESS_VIEW_DESC *desc, D3D12_CPU_DESCRIPTOR_HANDLE descriptor)
{
    TRACE("iface %p, resource %p, counter_resource %p, desc %p, descriptor %#lx.\n",
            iface, resource, counter_resource, desc, descriptor.ptr);

    d3d12_desc_create_uav(d3d12_desc_from_cpu_handle(descriptor),
            impl_from_ID3D12Device(iface), unsafe_impl_from_ID3D12Resource(resource),
            unsafe_impl_from_ID3D12Resource(counter_resource), desc);
}

static void STDMETHODCALLTYPE d3d12_device_CreateRenderTargetView(ID3D12Device *iface,
        ID3D12Resource *resource, const D3D12_RENDER_TARGET_VIEW_DESC *desc,
        D3D12_CPU_DESCRIPTOR_HANDLE descriptor)
{
    TRACE("iface %p, resource %p, desc %p, descriptor %#lx.\n",
            iface, resource, desc, descriptor.ptr);

    d3d12_rtv_desc_create_rtv(d3d12_rtv_desc_from_cpu_handle(descriptor),
            impl_from_ID3D12Device(iface), unsafe_impl_from_ID3D12Resource(resource), desc);
}

static void STDMETHODCALLTYPE d3d12_device_CreateDepthStencilView(ID3D12Device *iface,
        ID3D12Resource *resource, const D3D12_DEPTH_STENCIL_VIEW_DESC *desc,
        D3D12_CPU_DESCRIPTOR_HANDLE descriptor)
{
    TRACE("iface %p, resource %p, desc %p, descriptor %#lx.\n",
            iface, resource, desc, descriptor.ptr);

    d3d12_dsv_desc_create_dsv(d3d12_dsv_desc_from_cpu_handle(descriptor),
            impl_from_ID3D12Device(iface), unsafe_impl_from_ID3D12Resource(resource), desc);
}

static void STDMETHODCALLTYPE d3d12_device_CreateSampler(ID3D12Device *iface,
        const D3D12_SAMPLER_DESC *desc, D3D12_CPU_DESCRIPTOR_HANDLE descriptor)
{
    TRACE("iface %p, desc %p, descriptor %#lx.\n", iface, desc, descriptor.ptr);

    d3d12_desc_create_sampler(d3d12_desc_from_cpu_handle(descriptor),
            impl_from_ID3D12Device(iface), desc);
}

static void STDMETHODCALLTYPE d3d12_device_CopyDescriptors(ID3D12Device *iface,
        UINT dst_descriptor_range_count, const D3D12_CPU_DESCRIPTOR_HANDLE *dst_descriptor_range_offsets,
        const UINT *dst_descriptor_range_sizes,
        UINT src_descriptor_range_count, const D3D12_CPU_DESCRIPTOR_HANDLE *src_descriptor_range_offsets,
        const UINT *src_descriptor_range_sizes,
        D3D12_DESCRIPTOR_HEAP_TYPE descriptor_heap_type)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    unsigned int dst_range_idx, dst_idx, src_range_idx, src_idx;
    unsigned int dst_range_size, src_range_size;
    const struct d3d12_desc *src;
    struct d3d12_desc *dst;

    TRACE("iface %p, dst_descriptor_range_count %u, dst_descriptor_range_offsets %p, "
            "dst_descriptor_range_sizes %p, src_descriptor_range_count %u, "
            "src_descriptor_range_offsets %p, src_descriptor_range_sizes %p, "
            "descriptor_heap_type %#x.\n",
            iface, dst_descriptor_range_count, dst_descriptor_range_offsets,
            dst_descriptor_range_sizes, src_descriptor_range_count, src_descriptor_range_offsets,
            src_descriptor_range_sizes, descriptor_heap_type);

    if (descriptor_heap_type != D3D12_DESCRIPTOR_HEAP_TYPE_CBV_SRV_UAV
            && descriptor_heap_type != D3D12_DESCRIPTOR_HEAP_TYPE_SAMPLER)
    {
        FIXME("Unhandled descriptor heap type %#x.\n", descriptor_heap_type);
        return;
    }

    dst_range_idx = dst_idx = 0;
    dst = d3d12_desc_from_cpu_handle(dst_descriptor_range_offsets[0]);
    dst_range_size = dst_descriptor_range_sizes ? dst_descriptor_range_sizes[0] : 1;
    for (src_range_idx = 0; src_range_idx < src_descriptor_range_count; ++src_range_idx)
    {
        src = d3d12_desc_from_cpu_handle(src_descriptor_range_offsets[src_range_idx]);
        src_range_size = src_descriptor_range_sizes ? src_descriptor_range_sizes[src_range_idx] : 1;
        for (src_idx = 0; src_idx < src_range_size; ++src_idx)
        {
            if (dst_idx >= dst_range_size)
            {
                dst_idx = 0;
                ++dst_range_idx;
                dst = d3d12_desc_from_cpu_handle(dst_descriptor_range_offsets[dst_range_idx]);
                dst_range_size = dst_descriptor_range_sizes ? dst_descriptor_range_sizes[dst_range_idx] : 1;
            }

            assert(dst_range_idx < dst_descriptor_range_count);
            assert(dst_idx < dst_range_size);

            d3d12_desc_copy(dst++, src++, device);

            ++dst_idx;
        }
    }

    assert(dst_idx == dst_range_size);
    assert(dst_range_idx == dst_descriptor_range_count - 1);
}

static void STDMETHODCALLTYPE d3d12_device_CopyDescriptorsSimple(ID3D12Device *iface,
        UINT descriptor_count, const D3D12_CPU_DESCRIPTOR_HANDLE dst_descriptor_range_offset,
        const D3D12_CPU_DESCRIPTOR_HANDLE src_descriptor_range_offset,
        D3D12_DESCRIPTOR_HEAP_TYPE descriptor_heap_type)
{
    TRACE("iface %p, descriptor_count %u, dst_descriptor_range_offset %#lx, "
            "src_descriptor_range_offset %#lx, descriptor_heap_type %#x.\n",
            iface, descriptor_count, dst_descriptor_range_offset.ptr, src_descriptor_range_offset.ptr,
            descriptor_heap_type);

    d3d12_device_CopyDescriptors(iface, 1, &dst_descriptor_range_offset, &descriptor_count,
            1, &src_descriptor_range_offset, &descriptor_count, descriptor_heap_type);
}

static D3D12_RESOURCE_ALLOCATION_INFO * STDMETHODCALLTYPE d3d12_device_GetResourceAllocationInfo(
        ID3D12Device *iface, D3D12_RESOURCE_ALLOCATION_INFO *info, UINT visible_mask,
        UINT count, const D3D12_RESOURCE_DESC *resource_descs)
{
    UINT64 default_alignment = D3D12_DEFAULT_RESOURCE_PLACEMENT_ALIGNMENT;
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    const D3D12_RESOURCE_DESC *desc;
    bool valid = true;

    TRACE("iface %p, info %p, visible_mask 0x%08x, count %u, resource_descs %p.\n",
            iface, info, visible_mask, count, resource_descs);

    debug_ignored_node_mask(visible_mask);

    info->SizeInBytes = 0;
    info->Alignment = 0;

    if (count != 1)
    {
        FIXME("Multiple resource descriptions not supported.\n");
        return info;
    }

    desc = &resource_descs[0];

    if (FAILED(d3d12_resource_validate_desc(desc)))
    {
        WARN("Invalid resource desc.\n");
        valid = false;
    }

    if (desc->Dimension == D3D12_RESOURCE_DIMENSION_BUFFER)
    {
        info->SizeInBytes = desc->Width;
        info->Alignment = D3D12_DEFAULT_RESOURCE_PLACEMENT_ALIGNMENT;
    }
    else
    {
        if (desc->SampleDesc.Count != 1)
            default_alignment = D3D12_DEFAULT_MSAA_RESOURCE_PLACEMENT_ALIGNMENT;

        if (valid && FAILED(vkd3d_get_image_allocation_info(device, desc, info)))
        {
            WARN("Failed to get allocation info for texture.\n");
            valid = false;
        }
    }

    if (desc->Alignment % info->Alignment)
    {
        WARN("Invalid resource alignment %#"PRIx64" (required %#"PRIx64").\n",
                desc->Alignment, info->Alignment);
        valid = false;
    }

    if (valid)
    {
        info->SizeInBytes = align(info->SizeInBytes, info->Alignment);
    }
    else
    {
        info->SizeInBytes = ~(UINT64)0;
        info->Alignment = default_alignment;
    }

    TRACE("Size %#"PRIx64", alignment %#"PRIx64".\n", info->SizeInBytes, info->Alignment);

    return info;
}

static D3D12_HEAP_PROPERTIES * STDMETHODCALLTYPE d3d12_device_GetCustomHeapProperties(ID3D12Device *iface,
        D3D12_HEAP_PROPERTIES *heap_properties, UINT node_mask, D3D12_HEAP_TYPE heap_type)
{
    FIXME("iface %p, heap_properties %p, node_mask 0x%08x, heap_type %#x stub!\n",
            iface, heap_properties, node_mask, heap_type);

    debug_ignored_node_mask(node_mask);

    return heap_properties;
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreateCommittedResource(ID3D12Device *iface,
        const D3D12_HEAP_PROPERTIES *heap_properties, D3D12_HEAP_FLAGS heap_flags,
        const D3D12_RESOURCE_DESC *desc, D3D12_RESOURCE_STATES initial_state,
        const D3D12_CLEAR_VALUE *optimized_clear_value, REFIID iid, void **resource)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    struct d3d12_resource *object;
    HRESULT hr;

    TRACE("iface %p, heap_properties %p, heap_flags %#x,  desc %p, initial_state %#x, "
            "optimized_clear_value %p, iid %s, resource %p.\n",
            iface, heap_properties, heap_flags, desc, initial_state,
            optimized_clear_value, debugstr_guid(iid), resource);

    if (FAILED(hr = d3d12_committed_resource_create(device, heap_properties, heap_flags,
            desc, initial_state, optimized_clear_value, &object)))
    {
        *resource = NULL;
        return hr;
    }

    return return_interface(&object->ID3D12Resource_iface, &IID_ID3D12Resource, iid, resource);
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreateHeap(ID3D12Device *iface,
        const D3D12_HEAP_DESC *desc, REFIID iid, void **heap)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    struct d3d12_heap *object;
    HRESULT hr;

    TRACE("iface %p, desc %p, iid %s, heap %p.\n",
            iface, desc, debugstr_guid(iid), heap);

    if (FAILED(hr = d3d12_heap_create(device, desc, &object)))
    {
        *heap = NULL;
        return hr;
    }

    return return_interface(&object->ID3D12Heap_iface, &IID_ID3D12Heap, iid, heap);
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreatePlacedResource(ID3D12Device *iface,
        ID3D12Heap *heap, UINT64 heap_offset,
        const D3D12_RESOURCE_DESC *desc, D3D12_RESOURCE_STATES initial_state,
        const D3D12_CLEAR_VALUE *optimized_clear_value, REFIID iid, void **resource)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    struct d3d12_heap *heap_object;
    struct d3d12_resource *object;
    HRESULT hr;

    TRACE("iface %p, heap %p, heap_offset %#"PRIx64", desc %p, initial_state %#x, "
            "optimized_clear_value %p, iid %s, resource %p.\n",
            iface, heap, heap_offset, desc, initial_state,
            optimized_clear_value, debugstr_guid(iid), resource);

    heap_object = unsafe_impl_from_ID3D12Heap(heap);

    if (FAILED(hr = d3d12_placed_resource_create(device, heap_object, heap_offset,
            desc, initial_state, optimized_clear_value, &object)))
        return hr;

    return return_interface(&object->ID3D12Resource_iface, &IID_ID3D12Resource, iid, resource);
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreateReservedResource(ID3D12Device *iface,
        const D3D12_RESOURCE_DESC *desc, D3D12_RESOURCE_STATES initial_state,
        const D3D12_CLEAR_VALUE *optimized_clear_value,
        REFIID riid, void **resource)
{
    FIXME("iface %p, desc %p, initial_state %#x, optimized_clear_value %p, "
            "riid %s, resource %p stub!\n",
            iface, desc, initial_state, optimized_clear_value, debugstr_guid(riid), resource);

    return E_NOTIMPL;
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreateSharedHandle(ID3D12Device *iface,
        ID3D12DeviceChild *object, const SECURITY_ATTRIBUTES *attributes, DWORD access,
        const WCHAR *name, HANDLE *handle)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);

    FIXME("iface %p, object %p, attributes %p, access %#x, name %s, handle %p stub!\n",
            iface, object, attributes, access, debugstr_w(name, device->wchar_size), handle);

    return E_NOTIMPL;
}

static HRESULT STDMETHODCALLTYPE d3d12_device_OpenSharedHandle(ID3D12Device *iface,
        HANDLE handle, REFIID riid, void **object)
{
    FIXME("iface %p, handle %p, riid %s, object %p stub!\n",
            iface, handle, debugstr_guid(riid), object);

    return E_NOTIMPL;
}

static HRESULT STDMETHODCALLTYPE d3d12_device_OpenSharedHandleByName(ID3D12Device *iface,
        const WCHAR *name, DWORD access, HANDLE *handle)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);

    FIXME("iface %p, name %s, access %#x, handle %p stub!\n",
            iface, debugstr_w(name, device->wchar_size), access, handle);

    return E_NOTIMPL;
}

static HRESULT STDMETHODCALLTYPE d3d12_device_MakeResident(ID3D12Device *iface,
        UINT object_count, ID3D12Pageable * const *objects)
{
    FIXME("iface %p, object_count %u, objects %p stub!\n",
            iface, object_count, objects);

    return E_NOTIMPL;
}

static HRESULT STDMETHODCALLTYPE d3d12_device_Evict(ID3D12Device *iface,
        UINT object_count, ID3D12Pageable * const *objects)
{
    FIXME("iface %p, object_count %u, objects %p stub!\n",
            iface, object_count, objects);

    return E_NOTIMPL;
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreateFence(ID3D12Device *iface,
        UINT64 initial_value, D3D12_FENCE_FLAGS flags, REFIID riid, void **fence)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    struct d3d12_fence *object;
    HRESULT hr;

    TRACE("iface %p, intial_value %#"PRIx64", flags %#x, riid %s, fence %p.\n",
            iface, initial_value, flags, debugstr_guid(riid), fence);

    if (FAILED(hr = d3d12_fence_create(device, initial_value, flags, &object)))
        return hr;

    return return_interface(&object->ID3D12Fence_iface, &IID_ID3D12Fence, riid, fence);
}

static HRESULT STDMETHODCALLTYPE d3d12_device_GetDeviceRemovedReason(ID3D12Device *iface)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);

    TRACE("iface %p.\n", iface);

    return device->removed_reason;
}

static void STDMETHODCALLTYPE d3d12_device_GetCopyableFootprints(ID3D12Device *iface,
        const D3D12_RESOURCE_DESC *desc, UINT first_sub_resource, UINT sub_resource_count,
        UINT64 base_offset, D3D12_PLACED_SUBRESOURCE_FOOTPRINT *layouts,
        UINT *row_counts, UINT64 *row_sizes, UINT64 *total_bytes)
{
    static const struct vkd3d_format vkd3d_format_unknown
            = {DXGI_FORMAT_UNKNOWN, VK_FORMAT_UNDEFINED, 1, 1, 1, 1, 0};

    unsigned int i, sub_resource_idx, miplevel_idx, row_count, row_size, row_pitch;
    unsigned int width, height, depth, array_size;
    const struct vkd3d_format *format;
    UINT64 offset, size, total;

    TRACE("iface %p, desc %p, first_sub_resource %u, sub_resource_count %u, base_offset %#"PRIx64", "
            "layouts %p, row_counts %p, row_sizes %p, total_bytes %p.\n",
            iface, desc, first_sub_resource, sub_resource_count, base_offset,
            layouts, row_counts, row_sizes, total_bytes);

    if (layouts)
        memset(layouts, 0xff, sizeof(*layouts) * sub_resource_count);
    if (row_counts)
        memset(row_counts, 0xff, sizeof(*row_counts) * sub_resource_count);
    if (row_sizes)
        memset(row_sizes, 0xff, sizeof(*row_sizes) * sub_resource_count);
    if (total_bytes)
        *total_bytes = ~(UINT64)0;

    if (desc->Dimension == D3D12_RESOURCE_DIMENSION_BUFFER)
    {
        format = &vkd3d_format_unknown;
    }
    else if (!(format = vkd3d_format_from_d3d12_resource_desc(desc, 0)))
    {
        WARN("Invalid format %#x.\n", desc->Format);
        return;
    }

    if (FAILED(d3d12_resource_validate_desc(desc)))
    {
        WARN("Invalid resource desc.\n");
        return;
    }

    array_size = d3d12_resource_desc_get_layer_count(desc);

    if (first_sub_resource >= desc->MipLevels * array_size
            || sub_resource_count > desc->MipLevels * array_size - first_sub_resource)
    {
        WARN("Invalid sub-resource range %u-%u for resource.\n", first_sub_resource, sub_resource_count);
        return;
    }

    if (align(desc->Width, format->block_width) != desc->Width
            || align(desc->Height, format->block_height) != desc->Height)
    {
        WARN("Resource size (%"PRIu64"x%u) not aligned to format block size.\n", desc->Width, desc->Height);
        return;
    }

    if (base_offset)
        FIXME("Ignoring base offset %#"PRIx64".\n", base_offset);

    offset = 0;
    total = 0;
    for (i = 0; i < sub_resource_count; ++i)
    {
        sub_resource_idx = first_sub_resource + i;
        miplevel_idx = sub_resource_idx % desc->MipLevels;
        width = align(d3d12_resource_desc_get_width(desc, miplevel_idx), format->block_width);
        height = align(d3d12_resource_desc_get_height(desc, miplevel_idx), format->block_height);
        depth = d3d12_resource_desc_get_depth(desc, miplevel_idx);
        row_count = height / format->block_height;
        row_size = (width / format->block_width) * format->byte_count * format->block_byte_count;
        row_pitch = align(row_size, D3D12_TEXTURE_DATA_PITCH_ALIGNMENT);

        if (layouts)
        {
            layouts[i].Offset = offset;
            layouts[i].Footprint.Format = desc->Format;
            layouts[i].Footprint.Width = width;
            layouts[i].Footprint.Height = height;
            layouts[i].Footprint.Depth = depth;
            layouts[i].Footprint.RowPitch = row_pitch;
        }
        if (row_counts)
            row_counts[i] = row_count;
        if (row_sizes)
            row_sizes[i] = row_size;

        size = max(0, row_count - 1) * row_pitch + row_size;
        size = max(0, depth - 1) * align(size, D3D12_TEXTURE_DATA_PITCH_ALIGNMENT) + size;

        total = offset + size;
        offset = align(total, D3D12_TEXTURE_DATA_PLACEMENT_ALIGNMENT);
    }
    if (total_bytes)
        *total_bytes = total;
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreateQueryHeap(ID3D12Device *iface,
        const D3D12_QUERY_HEAP_DESC *desc, REFIID iid, void **heap)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    struct d3d12_query_heap *object;
    HRESULT hr;

    TRACE("iface %p, desc %p, iid %s, heap %p.\n",
            iface, desc, debugstr_guid(iid), heap);

    if (FAILED(hr = d3d12_query_heap_create(device, desc, &object)))
        return hr;

    return return_interface(&object->ID3D12QueryHeap_iface, &IID_ID3D12QueryHeap, iid, heap);
}

static HRESULT STDMETHODCALLTYPE d3d12_device_SetStablePowerState(ID3D12Device *iface, BOOL enable)
{
    FIXME("iface %p, enable %#x stub!\n", iface, enable);

    return E_NOTIMPL;
}

static HRESULT STDMETHODCALLTYPE d3d12_device_CreateCommandSignature(ID3D12Device *iface,
        const D3D12_COMMAND_SIGNATURE_DESC *desc, ID3D12RootSignature *root_signature,
        REFIID iid, void **command_signature)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);
    struct d3d12_command_signature *object;
    HRESULT hr;

    TRACE("iface %p, desc %p, root_signature %p, iid %s, command_signature %p.\n",
            iface, desc, root_signature, debugstr_guid(iid), command_signature);

    if (FAILED(hr = d3d12_command_signature_create(device, desc, &object)))
        return hr;

    return return_interface(&object->ID3D12CommandSignature_iface,
            &IID_ID3D12CommandSignature, iid, command_signature);
}

static void STDMETHODCALLTYPE d3d12_device_GetResourceTiling(ID3D12Device *iface,
        ID3D12Resource *resource, UINT *total_tile_count,
        D3D12_PACKED_MIP_INFO *packed_mip_info, D3D12_TILE_SHAPE *standard_tile_shape,
        UINT *sub_resource_tiling_count, UINT first_sub_resource_tiling,
        D3D12_SUBRESOURCE_TILING *sub_resource_tilings)
{
    FIXME("iface %p, resource %p, total_tile_count %p, packed_mip_info %p, "
            "standard_title_shape %p, sub_resource_tiling_count %p, "
            "first_sub_resource_tiling %u, sub_resource_tilings %p stub!\n",
            iface, resource, total_tile_count, packed_mip_info, standard_tile_shape,
            sub_resource_tiling_count, first_sub_resource_tiling,
            sub_resource_tilings);
}

static LUID * STDMETHODCALLTYPE d3d12_device_GetAdapterLuid(ID3D12Device *iface, LUID *luid)
{
    struct d3d12_device *device = impl_from_ID3D12Device(iface);

    TRACE("iface %p, luid %p.\n", iface, luid);

    *luid = device->adapter_luid;

    return luid;
}

static const struct ID3D12DeviceVtbl d3d12_device_vtbl =
{
    /* IUnknown methods */
    d3d12_device_QueryInterface,
    d3d12_device_AddRef,
    d3d12_device_Release,
    /* ID3D12Object methods */
    d3d12_device_GetPrivateData,
    d3d12_device_SetPrivateData,
    d3d12_device_SetPrivateDataInterface,
    d3d12_device_SetName,
    /* ID3D12Device methods */
    d3d12_device_GetNodeCount,
    d3d12_device_CreateCommandQueue,
    d3d12_device_CreateCommandAllocator,
    d3d12_device_CreateGraphicsPipelineState,
    d3d12_device_CreateComputePipelineState,
    d3d12_device_CreateCommandList,
    d3d12_device_CheckFeatureSupport,
    d3d12_device_CreateDescriptorHeap,
    d3d12_device_GetDescriptorHandleIncrementSize,
    d3d12_device_CreateRootSignature,
    d3d12_device_CreateConstantBufferView,
    d3d12_device_CreateShaderResourceView,
    d3d12_device_CreateUnorderedAccessView,
    d3d12_device_CreateRenderTargetView,
    d3d12_device_CreateDepthStencilView,
    d3d12_device_CreateSampler,
    d3d12_device_CopyDescriptors,
    d3d12_device_CopyDescriptorsSimple,
    d3d12_device_GetResourceAllocationInfo,
    d3d12_device_GetCustomHeapProperties,
    d3d12_device_CreateCommittedResource,
    d3d12_device_CreateHeap,
    d3d12_device_CreatePlacedResource,
    d3d12_device_CreateReservedResource,
    d3d12_device_CreateSharedHandle,
    d3d12_device_OpenSharedHandle,
    d3d12_device_OpenSharedHandleByName,
    d3d12_device_MakeResident,
    d3d12_device_Evict,
    d3d12_device_CreateFence,
    d3d12_device_GetDeviceRemovedReason,
    d3d12_device_GetCopyableFootprints,
    d3d12_device_CreateQueryHeap,
    d3d12_device_SetStablePowerState,
    d3d12_device_CreateCommandSignature,
    d3d12_device_GetResourceTiling,
    d3d12_device_GetAdapterLuid,
};

struct d3d12_device *unsafe_impl_from_ID3D12Device(ID3D12Device *iface)
{
    if (!iface)
        return NULL;
    assert(iface->lpVtbl == &d3d12_device_vtbl);
    return impl_from_ID3D12Device(iface);
}

static HRESULT d3d12_device_init(struct d3d12_device *device,
        struct vkd3d_instance *instance, const struct vkd3d_device_create_info *create_info)
{
    const struct vkd3d_vk_device_procs *vk_procs;
    HRESULT hr;

    device->ID3D12Device_iface.lpVtbl = &d3d12_device_vtbl;
    device->refcount = 1;

    vkd3d_instance_incref(device->vkd3d_instance = instance);
    device->vk_info = instance->vk_info;
    device->signal_event = instance->signal_event;
    device->create_thread = instance->create_thread;
    device->join_thread = instance->join_thread;
    device->wchar_size = instance->wchar_size;

    device->adapter_luid = create_info->adapter_luid;
    device->removed_reason = S_OK;

    device->vk_device = VK_NULL_HANDLE;
    device->vk_dummy_sampler = VK_NULL_HANDLE;

    if (FAILED(hr = vkd3d_create_vk_device(device, create_info)))
        goto out_free_instance;

    if (FAILED(hr = d3d12_device_create_dummy_sampler(device)))
    {
        ERR("Failed to create dummy sampler, hr %#x.\n", hr);
        goto out_free_vk_resources;
    }

    if (FAILED(hr = d3d12_device_init_pipeline_cache(device)))
        goto out_free_vk_resources;

    if (FAILED(hr = vkd3d_fence_worker_start(&device->fence_worker, device)))
        goto out_free_pipeline_cache;

    vkd3d_gpu_va_allocator_init(&device->gpu_va_allocator);

    if ((device->parent = create_info->parent))
        IUnknown_AddRef(device->parent);

    return S_OK;

out_free_pipeline_cache:
    d3d12_device_destroy_pipeline_cache(device);
out_free_vk_resources:
    vk_procs = &device->vk_procs;
    VK_CALL(vkDestroySampler(device->vk_device, device->vk_dummy_sampler, NULL));
    VK_CALL(vkDestroyDevice(device->vk_device, NULL));
out_free_instance:
    vkd3d_instance_decref(device->vkd3d_instance);
    return hr;
}

HRESULT d3d12_device_create(struct vkd3d_instance *instance,
        const struct vkd3d_device_create_info *create_info, struct d3d12_device **device)
{
    struct d3d12_device *object;
    HRESULT hr;

    if (!(object = vkd3d_malloc(sizeof(*object))))
        return E_OUTOFMEMORY;

    if (FAILED(hr = d3d12_device_init(object, instance, create_info)))
    {
        vkd3d_free(object);
        return hr;
    }

    TRACE("Created device %p.\n", object);

    *device = object;

    return S_OK;
}

void d3d12_device_mark_as_removed(struct d3d12_device *device, HRESULT reason,
        const char *message, ...)
{
    va_list args;

    va_start(args, message);
    WARN("Device %p is lost (reason %#x, message \"%s\").\n",
            device, reason, vkd3d_dbg_vsprintf(message, args));
    va_end(args);

    device->removed_reason = reason;
}

IUnknown *vkd3d_get_device_parent(ID3D12Device *device)
{
    struct d3d12_device *d3d12_device = impl_from_ID3D12Device(device);

    return d3d12_device->parent;
}

VkDevice vkd3d_get_vk_device(ID3D12Device *device)
{
    struct d3d12_device *d3d12_device = impl_from_ID3D12Device(device);

    return d3d12_device->vk_device;
}

VkPhysicalDevice vkd3d_get_vk_physical_device(ID3D12Device *device)
{
    struct d3d12_device *d3d12_device = impl_from_ID3D12Device(device);

    return d3d12_device->vk_physical_device;
}

struct vkd3d_instance *vkd3d_instance_from_device(ID3D12Device *device)
{
    struct d3d12_device *d3d12_device = impl_from_ID3D12Device(device);

    return d3d12_device->vkd3d_instance;
}