vkd3d/libs/vkd3d/device.c

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/*
* Copyright 2016 Józef Kucia for CodeWeavers
*
2017-06-16 12:05:54 -07:00
* 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.
*
2017-06-16 12:05:54 -07:00
* 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.
*
2017-06-16 12:05:54 -07:00
* 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 "vkd3d_version.h"
#define VKD3D_MAX_UAV_CLEAR_DESCRIPTORS_PER_TYPE 256u
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;
}
static uint32_t vkd3d_get_vk_version(void)
{
int major, minor;
vkd3d_parse_version(PACKAGE_VERSION, &major, &minor);
return VK_MAKE_VERSION(major, minor, 0);
}
struct vkd3d_optional_extension_info
{
const char *extension_name;
ptrdiff_t vulkan_info_offset;
bool is_debug_only;
};
#define VK_EXTENSION(name, member) \
{VK_ ## name ## _EXTENSION_NAME, offsetof(struct vkd3d_vulkan_info, member)}
#define VK_DEBUG_EXTENSION(name, member) \
{VK_ ## name ## _EXTENSION_NAME, offsetof(struct vkd3d_vulkan_info, member), true}
static const struct vkd3d_optional_extension_info optional_instance_extensions[] =
{
/* KHR extensions */
VK_EXTENSION(KHR_GET_PHYSICAL_DEVICE_PROPERTIES_2, KHR_get_physical_device_properties2),
/* EXT extensions */
VK_DEBUG_EXTENSION(EXT_DEBUG_REPORT, EXT_debug_report),
};
static const char * const required_device_extensions[] =
{
VK_KHR_MAINTENANCE1_EXTENSION_NAME,
VK_KHR_SHADER_DRAW_PARAMETERS_EXTENSION_NAME,
};
/* In general we don't want to enable Vulkan beta extensions, but make an
* exception for VK_KHR_portability_subset because we draw no real feature from
* it, but it's still useful to be able to develop for MoltenVK without being
* spammed with validation errors. */
#ifndef VK_KHR_PORTABILITY_SUBSET_EXTENSION_NAME
#define VK_KHR_PORTABILITY_SUBSET_EXTENSION_NAME "VK_KHR_portability_subset"
#endif
static const struct vkd3d_optional_extension_info optional_device_extensions[] =
{
/* KHR extensions */
VK_EXTENSION(KHR_DEDICATED_ALLOCATION, KHR_dedicated_allocation),
VK_EXTENSION(KHR_DRAW_INDIRECT_COUNT, KHR_draw_indirect_count),
VK_EXTENSION(KHR_GET_MEMORY_REQUIREMENTS_2, KHR_get_memory_requirements2),
VK_EXTENSION(KHR_IMAGE_FORMAT_LIST, KHR_image_format_list),
VK_EXTENSION(KHR_MAINTENANCE2, KHR_maintenance2),
VK_EXTENSION(KHR_MAINTENANCE3, KHR_maintenance3),
VK_EXTENSION(KHR_PORTABILITY_SUBSET, KHR_portability_subset),
VK_EXTENSION(KHR_PUSH_DESCRIPTOR, KHR_push_descriptor),
VK_EXTENSION(KHR_SAMPLER_MIRROR_CLAMP_TO_EDGE, KHR_sampler_mirror_clamp_to_edge),
VK_EXTENSION(KHR_TIMELINE_SEMAPHORE, KHR_timeline_semaphore),
/* EXT extensions */
VK_EXTENSION(EXT_4444_FORMATS, EXT_4444_formats),
VK_EXTENSION(EXT_CALIBRATED_TIMESTAMPS, EXT_calibrated_timestamps),
VK_EXTENSION(EXT_CONDITIONAL_RENDERING, EXT_conditional_rendering),
VK_DEBUG_EXTENSION(EXT_DEBUG_MARKER, EXT_debug_marker),
VK_EXTENSION(EXT_DEPTH_CLIP_ENABLE, EXT_depth_clip_enable),
VK_EXTENSION(EXT_DESCRIPTOR_INDEXING, EXT_descriptor_indexing),
VK_EXTENSION(EXT_FRAGMENT_SHADER_INTERLOCK, EXT_fragment_shader_interlock),
VK_EXTENSION(EXT_MUTABLE_DESCRIPTOR_TYPE, EXT_mutable_descriptor_type),
VK_EXTENSION(EXT_ROBUSTNESS_2, EXT_robustness2),
VK_EXTENSION(EXT_SHADER_DEMOTE_TO_HELPER_INVOCATION, EXT_shader_demote_to_helper_invocation),
VK_EXTENSION(EXT_SHADER_STENCIL_EXPORT, EXT_shader_stencil_export),
VK_EXTENSION(EXT_SHADER_VIEWPORT_INDEX_LAYER, EXT_shader_viewport_index_layer),
VK_EXTENSION(EXT_TEXEL_BUFFER_ALIGNMENT, EXT_texel_buffer_alignment),
VK_EXTENSION(EXT_TRANSFORM_FEEDBACK, EXT_transform_feedback),
VK_EXTENSION(EXT_VERTEX_ATTRIBUTE_DIVISOR, EXT_vertex_attribute_divisor),
};
vkd3d: Back descriptor heaps with Vulkan descriptor sets if descriptor indexing is available. The existing implementation using virtual descriptor heaps, where Vk descriptor sets are created for the bindings in the root descriptor tables, is inefficient when multiple command lists are used with large descriptor heaps. It also cannot support updating a descriptor set after it is bound. This patch creates Vk sets for each D3D12 heap. Because D3D12 heaps can contain CBV, SRV and UAV descriptors in the same heap, multiple Vk sets are needed for each heap, however the total number of populated descriptors is never more than (heap size + UAV counter count). A new 'virtual_heaps' config option is introduced to make the old implementation available when needed. It's not always possible to determine if this is necessary when the device is created. Up to nine Vk descriptor sets may be used. It's theoretically possible to reduce this to eight by placing immutable samplers in the push descriptor set layout, but contradictions in earlier versions of the Vulkan spec made driver support inconsistent. The documentation was corrected in version 1.2.203. This patch also adds support for UAV counter descriptor arrays. It's not practical to add this in a separate patch due to complications with combining the old UAV counter implementation with the new descriptor heap implementation. Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47713 Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47154 Signed-off-by: Conor McCarthy <cmccarthy@codeweavers.com> Signed-off-by: Henri Verbeet <hverbeet@codeweavers.com> Signed-off-by: Alexandre Julliard <julliard@winehq.org>
2022-02-21 07:18:59 -08:00
static HRESULT vkd3d_create_vk_descriptor_heap_layout(struct d3d12_device *device, unsigned int index)
{
const struct vkd3d_vk_device_procs *vk_procs = &device->vk_procs;
VkDescriptorSetLayoutBindingFlagsCreateInfoEXT flags_info;
VkMutableDescriptorTypeCreateInfoEXT mutable_info;
VkMutableDescriptorTypeListEXT type_list;
vkd3d: Back descriptor heaps with Vulkan descriptor sets if descriptor indexing is available. The existing implementation using virtual descriptor heaps, where Vk descriptor sets are created for the bindings in the root descriptor tables, is inefficient when multiple command lists are used with large descriptor heaps. It also cannot support updating a descriptor set after it is bound. This patch creates Vk sets for each D3D12 heap. Because D3D12 heaps can contain CBV, SRV and UAV descriptors in the same heap, multiple Vk sets are needed for each heap, however the total number of populated descriptors is never more than (heap size + UAV counter count). A new 'virtual_heaps' config option is introduced to make the old implementation available when needed. It's not always possible to determine if this is necessary when the device is created. Up to nine Vk descriptor sets may be used. It's theoretically possible to reduce this to eight by placing immutable samplers in the push descriptor set layout, but contradictions in earlier versions of the Vulkan spec made driver support inconsistent. The documentation was corrected in version 1.2.203. This patch also adds support for UAV counter descriptor arrays. It's not practical to add this in a separate patch due to complications with combining the old UAV counter implementation with the new descriptor heap implementation. Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47713 Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47154 Signed-off-by: Conor McCarthy <cmccarthy@codeweavers.com> Signed-off-by: Henri Verbeet <hverbeet@codeweavers.com> Signed-off-by: Alexandre Julliard <julliard@winehq.org>
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VkDescriptorSetLayoutCreateInfo set_desc;
VkDescriptorBindingFlagsEXT set_flags;
VkDescriptorSetLayoutBinding binding;
VkResult vr;
static const VkDescriptorType descriptor_types[] =
{
VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER,
VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER,
VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE,
VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER,
VK_DESCRIPTOR_TYPE_STORAGE_IMAGE,
};
if (device->vk_info.EXT_mutable_descriptor_type && index && index != VKD3D_SET_INDEX_UAV_COUNTER
&& device->vk_descriptor_heap_layouts[index].applicable_heap_type == D3D12_DESCRIPTOR_HEAP_TYPE_CBV_SRV_UAV)
{
device->vk_descriptor_heap_layouts[index].vk_set_layout = VK_NULL_HANDLE;
return S_OK;
}
vkd3d: Back descriptor heaps with Vulkan descriptor sets if descriptor indexing is available. The existing implementation using virtual descriptor heaps, where Vk descriptor sets are created for the bindings in the root descriptor tables, is inefficient when multiple command lists are used with large descriptor heaps. It also cannot support updating a descriptor set after it is bound. This patch creates Vk sets for each D3D12 heap. Because D3D12 heaps can contain CBV, SRV and UAV descriptors in the same heap, multiple Vk sets are needed for each heap, however the total number of populated descriptors is never more than (heap size + UAV counter count). A new 'virtual_heaps' config option is introduced to make the old implementation available when needed. It's not always possible to determine if this is necessary when the device is created. Up to nine Vk descriptor sets may be used. It's theoretically possible to reduce this to eight by placing immutable samplers in the push descriptor set layout, but contradictions in earlier versions of the Vulkan spec made driver support inconsistent. The documentation was corrected in version 1.2.203. This patch also adds support for UAV counter descriptor arrays. It's not practical to add this in a separate patch due to complications with combining the old UAV counter implementation with the new descriptor heap implementation. Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47713 Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47154 Signed-off-by: Conor McCarthy <cmccarthy@codeweavers.com> Signed-off-by: Henri Verbeet <hverbeet@codeweavers.com> Signed-off-by: Alexandre Julliard <julliard@winehq.org>
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binding.binding = 0;
binding.descriptorType = (device->vk_info.EXT_mutable_descriptor_type && !index)
? VK_DESCRIPTOR_TYPE_MUTABLE_EXT : device->vk_descriptor_heap_layouts[index].type;
vkd3d: Back descriptor heaps with Vulkan descriptor sets if descriptor indexing is available. The existing implementation using virtual descriptor heaps, where Vk descriptor sets are created for the bindings in the root descriptor tables, is inefficient when multiple command lists are used with large descriptor heaps. It also cannot support updating a descriptor set after it is bound. This patch creates Vk sets for each D3D12 heap. Because D3D12 heaps can contain CBV, SRV and UAV descriptors in the same heap, multiple Vk sets are needed for each heap, however the total number of populated descriptors is never more than (heap size + UAV counter count). A new 'virtual_heaps' config option is introduced to make the old implementation available when needed. It's not always possible to determine if this is necessary when the device is created. Up to nine Vk descriptor sets may be used. It's theoretically possible to reduce this to eight by placing immutable samplers in the push descriptor set layout, but contradictions in earlier versions of the Vulkan spec made driver support inconsistent. The documentation was corrected in version 1.2.203. This patch also adds support for UAV counter descriptor arrays. It's not practical to add this in a separate patch due to complications with combining the old UAV counter implementation with the new descriptor heap implementation. Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47713 Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47154 Signed-off-by: Conor McCarthy <cmccarthy@codeweavers.com> Signed-off-by: Henri Verbeet <hverbeet@codeweavers.com> Signed-off-by: Alexandre Julliard <julliard@winehq.org>
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binding.descriptorCount = device->vk_descriptor_heap_layouts[index].count;
binding.stageFlags = VK_SHADER_STAGE_ALL;
binding.pImmutableSamplers = NULL;
set_desc.sType = VK_STRUCTURE_TYPE_DESCRIPTOR_SET_LAYOUT_CREATE_INFO;
set_desc.pNext = &flags_info;
set_desc.flags = VK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT_EXT;
set_desc.bindingCount = 1;
set_desc.pBindings = &binding;
set_flags = VK_DESCRIPTOR_BINDING_VARIABLE_DESCRIPTOR_COUNT_BIT_EXT
| VK_DESCRIPTOR_BINDING_PARTIALLY_BOUND_BIT_EXT | VK_DESCRIPTOR_BINDING_UPDATE_AFTER_BIND_BIT_EXT
| VK_DESCRIPTOR_BINDING_UPDATE_UNUSED_WHILE_PENDING_BIT_EXT;
flags_info.sType = VK_STRUCTURE_TYPE_DESCRIPTOR_SET_LAYOUT_BINDING_FLAGS_CREATE_INFO_EXT;
flags_info.pNext = NULL;
flags_info.bindingCount = 1;
flags_info.pBindingFlags = &set_flags;
if (binding.descriptorType == VK_DESCRIPTOR_TYPE_MUTABLE_EXT)
{
type_list.descriptorTypeCount = ARRAY_SIZE(descriptor_types);
type_list.pDescriptorTypes = descriptor_types;
mutable_info.sType = VK_STRUCTURE_TYPE_MUTABLE_DESCRIPTOR_TYPE_CREATE_INFO_EXT;
mutable_info.pNext = NULL;
mutable_info.mutableDescriptorTypeListCount = 1;
mutable_info.pMutableDescriptorTypeLists = &type_list;
flags_info.pNext = &mutable_info;
}
vkd3d: Back descriptor heaps with Vulkan descriptor sets if descriptor indexing is available. The existing implementation using virtual descriptor heaps, where Vk descriptor sets are created for the bindings in the root descriptor tables, is inefficient when multiple command lists are used with large descriptor heaps. It also cannot support updating a descriptor set after it is bound. This patch creates Vk sets for each D3D12 heap. Because D3D12 heaps can contain CBV, SRV and UAV descriptors in the same heap, multiple Vk sets are needed for each heap, however the total number of populated descriptors is never more than (heap size + UAV counter count). A new 'virtual_heaps' config option is introduced to make the old implementation available when needed. It's not always possible to determine if this is necessary when the device is created. Up to nine Vk descriptor sets may be used. It's theoretically possible to reduce this to eight by placing immutable samplers in the push descriptor set layout, but contradictions in earlier versions of the Vulkan spec made driver support inconsistent. The documentation was corrected in version 1.2.203. This patch also adds support for UAV counter descriptor arrays. It's not practical to add this in a separate patch due to complications with combining the old UAV counter implementation with the new descriptor heap implementation. Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47713 Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47154 Signed-off-by: Conor McCarthy <cmccarthy@codeweavers.com> Signed-off-by: Henri Verbeet <hverbeet@codeweavers.com> Signed-off-by: Alexandre Julliard <julliard@winehq.org>
2022-02-21 07:18:59 -08:00
if ((vr = VK_CALL(vkCreateDescriptorSetLayout(device->vk_device, &set_desc, NULL,
&device->vk_descriptor_heap_layouts[index].vk_set_layout))) < 0)
{
WARN("Failed to create Vulkan descriptor set layout, vr %d.\n", vr);
return hresult_from_vk_result(vr);
}
return S_OK;
}
static void vkd3d_vk_descriptor_heap_layouts_cleanup(struct d3d12_device *device)
{
const struct vkd3d_vk_device_procs *vk_procs = &device->vk_procs;
enum vkd3d_vk_descriptor_set_index set;
for (set = 0; set < ARRAY_SIZE(device->vk_descriptor_heap_layouts); ++set)
VK_CALL(vkDestroyDescriptorSetLayout(device->vk_device, device->vk_descriptor_heap_layouts[set].vk_set_layout,
NULL));
}
static HRESULT vkd3d_vk_descriptor_heap_layouts_init(struct d3d12_device *device)
{
static const struct vkd3d_vk_descriptor_heap_layout vk_descriptor_heap_layouts[VKD3D_SET_INDEX_COUNT] =
{
{VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER, true, D3D12_DESCRIPTOR_HEAP_TYPE_CBV_SRV_UAV},
{VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER, true, D3D12_DESCRIPTOR_HEAP_TYPE_CBV_SRV_UAV},
{VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE, false, D3D12_DESCRIPTOR_HEAP_TYPE_CBV_SRV_UAV},
{VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER, true, D3D12_DESCRIPTOR_HEAP_TYPE_CBV_SRV_UAV},
{VK_DESCRIPTOR_TYPE_STORAGE_IMAGE, false, D3D12_DESCRIPTOR_HEAP_TYPE_CBV_SRV_UAV},
{VK_DESCRIPTOR_TYPE_SAMPLER, false, D3D12_DESCRIPTOR_HEAP_TYPE_SAMPLER},
/* UAV counters */
{VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER, true, D3D12_DESCRIPTOR_HEAP_TYPE_CBV_SRV_UAV},
};
const struct vkd3d_device_descriptor_limits *limits = &device->vk_info.descriptor_limits;
enum vkd3d_vk_descriptor_set_index set;
HRESULT hr;
for (set = 0; set < ARRAY_SIZE(device->vk_descriptor_heap_layouts); ++set)
device->vk_descriptor_heap_layouts[set] = vk_descriptor_heap_layouts[set];
if (!device->use_vk_heaps)
return S_OK;
for (set = 0; set < ARRAY_SIZE(device->vk_descriptor_heap_layouts); ++set)
{
switch (device->vk_descriptor_heap_layouts[set].type)
{
case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER:
device->vk_descriptor_heap_layouts[set].count = limits->uniform_buffer_max_descriptors;
break;
case VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER:
case VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE:
device->vk_descriptor_heap_layouts[set].count = limits->sampled_image_max_descriptors;
break;
case VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER:
case VK_DESCRIPTOR_TYPE_STORAGE_IMAGE:
device->vk_descriptor_heap_layouts[set].count = limits->storage_image_max_descriptors;
break;
case VK_DESCRIPTOR_TYPE_SAMPLER:
device->vk_descriptor_heap_layouts[set].count = limits->sampler_max_descriptors;
break;
default:
ERR("Unhandled descriptor type %#x.\n", device->vk_descriptor_heap_layouts[set].type);
break;
}
if (FAILED(hr = vkd3d_create_vk_descriptor_heap_layout(device, set)))
{
vkd3d_vk_descriptor_heap_layouts_cleanup(device);
return hr;
}
}
return S_OK;
}
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;
if (!(disabled_extensions = getenv("VKD3D_DISABLE_EXTENSIONS")))
return false;
return vkd3d_debug_list_has_member(disabled_extensions, extension_name);
}
static bool has_extension(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))
{
if (is_extension_disabled(extension_name))
{
WARN("Extension %s is disabled.\n", debugstr_a(extension_name));
return false;
}
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,
bool is_debug_enabled)
{
unsigned int extension_count = 0;
unsigned int i;
for (i = 0; i < required_extension_count; ++i)
{
if (!has_extension(extensions, count, required_extensions[i]))
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 *supported = (void *)((uintptr_t)vulkan_info + offset);
if (!is_debug_enabled && optional_extensions[i].is_debug_only)
{
*supported = false;
TRACE("Skipping debug-only extension %s.\n", debugstr_a(extension_name));
continue;
}
if ((*supported = has_extension(extensions, count, extension_name)))
{
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]))
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]))
{
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)
2016-10-13 04:50:36 -07:00
{
ERR("Failed to enumerate instance extensions, vr %d.\n", vr);
return hresult_from_vk_result(vr);
}
if (!(vk_extensions = vkd3d_calloc(count, sizeof(*vk_extensions))))
return E_OUTOFMEMORY;
2016-10-13 04:50:36 -07:00
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",
instance->config_flags & VKD3D_CONFIG_FLAG_VULKAN_DEBUG);
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 = vkd3d_dlopen(SONAME_LIBVULKAN)))
{
ERR("Failed to load libvulkan: %s.\n", vkd3d_dlerror());
return E_FAIL;
}
if (!(vkGetInstanceProcAddr = vkd3d_dlsym(instance->libvulkan, "vkGetInstanceProcAddr")))
{
ERR("Could not load function pointer for vkGetInstanceProcAddr().\n");
vkd3d_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)
vkd3d_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 const struct vkd3d_debug_option vkd3d_config_options[] =
{
vkd3d: Back descriptor heaps with Vulkan descriptor sets if descriptor indexing is available. The existing implementation using virtual descriptor heaps, where Vk descriptor sets are created for the bindings in the root descriptor tables, is inefficient when multiple command lists are used with large descriptor heaps. It also cannot support updating a descriptor set after it is bound. This patch creates Vk sets for each D3D12 heap. Because D3D12 heaps can contain CBV, SRV and UAV descriptors in the same heap, multiple Vk sets are needed for each heap, however the total number of populated descriptors is never more than (heap size + UAV counter count). A new 'virtual_heaps' config option is introduced to make the old implementation available when needed. It's not always possible to determine if this is necessary when the device is created. Up to nine Vk descriptor sets may be used. It's theoretically possible to reduce this to eight by placing immutable samplers in the push descriptor set layout, but contradictions in earlier versions of the Vulkan spec made driver support inconsistent. The documentation was corrected in version 1.2.203. This patch also adds support for UAV counter descriptor arrays. It's not practical to add this in a separate patch due to complications with combining the old UAV counter implementation with the new descriptor heap implementation. Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47713 Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47154 Signed-off-by: Conor McCarthy <cmccarthy@codeweavers.com> Signed-off-by: Henri Verbeet <hverbeet@codeweavers.com> Signed-off-by: Alexandre Julliard <julliard@winehq.org>
2022-02-21 07:18:59 -08:00
{"virtual_heaps", VKD3D_CONFIG_FLAG_VIRTUAL_HEAPS}, /* always use virtual descriptor heaps */
{"vk_debug", VKD3D_CONFIG_FLAG_VULKAN_DEBUG}, /* enable Vulkan debug extensions */
};
static uint64_t vkd3d_init_config_flags(void)
{
uint64_t config_flags;
const char *config;
config = getenv("VKD3D_CONFIG");
config_flags = vkd3d_parse_debug_options(config, vkd3d_config_options, ARRAY_SIZE(vkd3d_config_options));
if (config_flags)
TRACE("VKD3D_CONFIG='%s'.\n", config);
return config_flags;
}
/* TICKSPERSEC from Wine */
#define VKD3D_DEFAULT_HOST_TICKS_PER_SECOND 10000000
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;
const struct vkd3d_application_info *vkd3d_application_info;
const struct vkd3d_host_time_domain_info *time_domain_info;
2024-04-09 18:43:09 -07:00
PFN_vkEnumerateInstanceVersion vkEnumerateInstanceVersion;
bool *user_extension_supported = NULL;
VkApplicationInfo application_info;
VkInstanceCreateInfo instance_info;
char application_name[PATH_MAX];
uint32_t extension_count;
const char **extensions;
2024-04-09 18:43:09 -07:00
uint32_t vk_api_version;
VkInstance vk_instance;
VkResult vr;
HRESULT hr;
TRACE("Build: " PACKAGE_STRING VKD3D_VCS_ID ".\n");
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;
instance->config_flags = vkd3d_init_config_flags();
if (FAILED(hr = vkd3d_init_vk_global_procs(instance, create_info->pfn_vkGetInstanceProcAddr)))
{
ERR("Failed to initialise Vulkan global procs, hr %s.\n", debugstr_hresult(hr));
return hr;
}
if (FAILED(hr = vkd3d_init_instance_caps(instance, create_info,
&extension_count, &user_extension_supported)))
{
if (instance->libvulkan)
vkd3d_dlclose(instance->libvulkan);
return hr;
}
application_info.sType = VK_STRUCTURE_TYPE_APPLICATION_INFO;
application_info.pNext = NULL;
application_info.pApplicationName = NULL;
application_info.applicationVersion = 0;
application_info.pEngineName = PACKAGE_NAME;
application_info.engineVersion = vkd3d_get_vk_version();
application_info.apiVersion = VK_API_VERSION_1_0;
instance->api_version = VKD3D_API_VERSION_1_0;
2024-04-09 18:43:09 -07:00
/* vkEnumerateInstanceVersion was added in Vulkan 1.1, and its absence indicates only 1.0 is supported. */
vkEnumerateInstanceVersion = (void *)vk_global_procs->vkGetInstanceProcAddr(NULL, "vkEnumerateInstanceVersion");
if (vkEnumerateInstanceVersion && vkEnumerateInstanceVersion(&vk_api_version) >= 0
&& vk_api_version >= VK_API_VERSION_1_1)
{
TRACE("Vulkan API version 1.1 is available; requesting it.\n");
application_info.apiVersion = VK_API_VERSION_1_1;
}
instance->vk_api_version = application_info.apiVersion;
if ((vkd3d_application_info = vkd3d_find_struct(create_info->next, APPLICATION_INFO)))
{
if (vkd3d_application_info->application_name)
application_info.pApplicationName = vkd3d_application_info->application_name;
else if (vkd3d_get_program_name(application_name))
application_info.pApplicationName = application_name;
application_info.applicationVersion = vkd3d_application_info->application_version;
if (vkd3d_application_info->engine_name)
{
application_info.pEngineName = vkd3d_application_info->engine_name;
application_info.engineVersion = vkd3d_application_info->engine_version;
}
instance->api_version = vkd3d_application_info->api_version;
}
else if (vkd3d_get_program_name(application_name))
{
application_info.pApplicationName = application_name;
}
TRACE("Application: %s.\n", debugstr_a(application_info.pApplicationName));
TRACE("vkd3d API version: %u.\n", instance->api_version);
if (!(extensions = vkd3d_calloc(extension_count, sizeof(*extensions))))
{
if (instance->libvulkan)
vkd3d_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);
2016-10-13 04:50:36 -07:00
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)
vkd3d_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 %s.\n", debugstr_hresult(hr));
if (instance->vk_procs.vkDestroyInstance)
instance->vk_procs.vkDestroyInstance(vk_instance, NULL);
if (instance->libvulkan)
vkd3d_dlclose(instance->libvulkan);
return hr;
}
if ((time_domain_info = vkd3d_find_struct(create_info->next, HOST_TIME_DOMAIN_INFO)))
instance->host_ticks_per_second = time_domain_info->ticks_per_second;
else
instance->host_ticks_per_second = VKD3D_DEFAULT_HOST_TICKS_PER_SECOND;
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)
vkd3d_dlclose(instance->libvulkan);
vkd3d_free(instance);
}
ULONG vkd3d_instance_incref(struct vkd3d_instance *instance)
{
unsigned int refcount = vkd3d_atomic_increment_u32(&instance->refcount);
TRACE("%p increasing refcount to %u.\n", instance, refcount);
return refcount;
}
ULONG vkd3d_instance_decref(struct vkd3d_instance *instance)
{
unsigned int refcount = vkd3d_atomic_decrement_u32(&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 bool d3d12_device_environment_is_vulkan_min_1_1(struct d3d12_device *device)
{
return device->environment == VKD3D_SHADER_SPIRV_ENVIRONMENT_VULKAN_1_1;
}
struct vkd3d_physical_device_info
{
/* properties */
VkPhysicalDeviceDescriptorIndexingPropertiesEXT descriptor_indexing_properties;
VkPhysicalDeviceMaintenance3Properties maintenance3_properties;
VkPhysicalDeviceTexelBufferAlignmentPropertiesEXT texel_buffer_alignment_properties;
VkPhysicalDeviceTransformFeedbackPropertiesEXT xfb_properties;
VkPhysicalDeviceVertexAttributeDivisorPropertiesEXT vertex_divisor_properties;
VkPhysicalDeviceSubgroupProperties subgroup_properties;
VkPhysicalDeviceProperties2KHR properties2;
/* features */
VkPhysicalDeviceConditionalRenderingFeaturesEXT conditional_rendering_features;
VkPhysicalDeviceDepthClipEnableFeaturesEXT depth_clip_features;
VkPhysicalDeviceDescriptorIndexingFeaturesEXT descriptor_indexing_features;
VkPhysicalDeviceFragmentShaderInterlockFeaturesEXT fragment_shader_interlock_features;
VkPhysicalDeviceRobustness2FeaturesEXT robustness2_features;
VkPhysicalDeviceShaderDemoteToHelperInvocationFeaturesEXT demote_features;
VkPhysicalDeviceTexelBufferAlignmentFeaturesEXT texel_buffer_alignment_features;
VkPhysicalDeviceTransformFeedbackFeaturesEXT xfb_features;
VkPhysicalDeviceVertexAttributeDivisorFeaturesEXT vertex_divisor_features;
VkPhysicalDeviceTimelineSemaphoreFeaturesKHR timeline_semaphore_features;
VkPhysicalDeviceMutableDescriptorTypeFeaturesEXT mutable_features;
VkPhysicalDevice4444FormatsFeaturesEXT formats4444_features;
VkPhysicalDeviceFeatures2 features2;
};
static void vkd3d_physical_device_info_init(struct vkd3d_physical_device_info *info, struct d3d12_device *device)
{
const struct vkd3d_vk_instance_procs *vk_procs = &device->vkd3d_instance->vk_procs;
VkPhysicalDeviceConditionalRenderingFeaturesEXT *conditional_rendering_features;
VkPhysicalDeviceDescriptorIndexingPropertiesEXT *descriptor_indexing_properties;
VkPhysicalDeviceVertexAttributeDivisorPropertiesEXT *vertex_divisor_properties;
VkPhysicalDeviceTexelBufferAlignmentPropertiesEXT *buffer_alignment_properties;
VkPhysicalDeviceDescriptorIndexingFeaturesEXT *descriptor_indexing_features;
VkPhysicalDeviceFragmentShaderInterlockFeaturesEXT *fragment_shader_interlock_features;
VkPhysicalDeviceRobustness2FeaturesEXT *robustness2_features;
VkPhysicalDeviceVertexAttributeDivisorFeaturesEXT *vertex_divisor_features;
VkPhysicalDeviceTexelBufferAlignmentFeaturesEXT *buffer_alignment_features;
VkPhysicalDeviceShaderDemoteToHelperInvocationFeaturesEXT *demote_features;
VkPhysicalDeviceTimelineSemaphoreFeaturesKHR *timeline_semaphore_features;
VkPhysicalDeviceMutableDescriptorTypeFeaturesEXT *mutable_features;
VkPhysicalDeviceDepthClipEnableFeaturesEXT *depth_clip_features;
VkPhysicalDeviceMaintenance3Properties *maintenance3_properties;
VkPhysicalDeviceTransformFeedbackPropertiesEXT *xfb_properties;
VkPhysicalDevice physical_device = device->vk_physical_device;
VkPhysicalDevice4444FormatsFeaturesEXT *formats4444_features;
VkPhysicalDeviceTransformFeedbackFeaturesEXT *xfb_features;
struct vkd3d_vulkan_info *vulkan_info = &device->vk_info;
VkPhysicalDeviceSubgroupProperties *subgroup_properties;
memset(info, 0, sizeof(*info));
conditional_rendering_features = &info->conditional_rendering_features;
depth_clip_features = &info->depth_clip_features;
descriptor_indexing_features = &info->descriptor_indexing_features;
fragment_shader_interlock_features = &info->fragment_shader_interlock_features;
robustness2_features = &info->robustness2_features;
descriptor_indexing_properties = &info->descriptor_indexing_properties;
maintenance3_properties = &info->maintenance3_properties;
demote_features = &info->demote_features;
buffer_alignment_features = &info->texel_buffer_alignment_features;
buffer_alignment_properties = &info->texel_buffer_alignment_properties;
vertex_divisor_features = &info->vertex_divisor_features;
vertex_divisor_properties = &info->vertex_divisor_properties;
timeline_semaphore_features = &info->timeline_semaphore_features;
mutable_features = &info->mutable_features;
formats4444_features = &info->formats4444_features;
xfb_features = &info->xfb_features;
xfb_properties = &info->xfb_properties;
subgroup_properties = &info->subgroup_properties;
info->features2.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_FEATURES_2;
conditional_rendering_features->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_CONDITIONAL_RENDERING_FEATURES_EXT;
if (vulkan_info->EXT_conditional_rendering)
vk_prepend_struct(&info->features2, conditional_rendering_features);
depth_clip_features->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_DEPTH_CLIP_ENABLE_FEATURES_EXT;
if (vulkan_info->EXT_depth_clip_enable)
vk_prepend_struct(&info->features2, depth_clip_features);
descriptor_indexing_features->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_DESCRIPTOR_INDEXING_FEATURES_EXT;
if (vulkan_info->EXT_descriptor_indexing)
vk_prepend_struct(&info->features2, descriptor_indexing_features);
fragment_shader_interlock_features->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_FRAGMENT_SHADER_INTERLOCK_FEATURES_EXT;
if (vulkan_info->EXT_fragment_shader_interlock)
vk_prepend_struct(&info->features2, fragment_shader_interlock_features);
robustness2_features->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_ROBUSTNESS_2_FEATURES_EXT;
if (vulkan_info->EXT_robustness2)
vk_prepend_struct(&info->features2, robustness2_features);
demote_features->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_SHADER_DEMOTE_TO_HELPER_INVOCATION_FEATURES_EXT;
if (vulkan_info->EXT_shader_demote_to_helper_invocation)
vk_prepend_struct(&info->features2, demote_features);
buffer_alignment_features->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_TEXEL_BUFFER_ALIGNMENT_FEATURES_EXT;
if (vulkan_info->EXT_texel_buffer_alignment)
vk_prepend_struct(&info->features2, buffer_alignment_features);
xfb_features->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_TRANSFORM_FEEDBACK_FEATURES_EXT;
if (vulkan_info->EXT_transform_feedback)
vk_prepend_struct(&info->features2, xfb_features);
vertex_divisor_features->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_VERTEX_ATTRIBUTE_DIVISOR_FEATURES_EXT;
if (vulkan_info->EXT_vertex_attribute_divisor)
vk_prepend_struct(&info->features2, vertex_divisor_features);
timeline_semaphore_features->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_TIMELINE_SEMAPHORE_FEATURES_KHR;
if (vulkan_info->KHR_timeline_semaphore)
vk_prepend_struct(&info->features2, timeline_semaphore_features);
mutable_features->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_MUTABLE_DESCRIPTOR_TYPE_FEATURES_EXT;
if (vulkan_info->EXT_mutable_descriptor_type)
vk_prepend_struct(&info->features2, mutable_features);
formats4444_features->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_4444_FORMATS_FEATURES_EXT;
if (vulkan_info->EXT_4444_formats)
vk_prepend_struct(&info->features2, formats4444_features);
if (vulkan_info->KHR_get_physical_device_properties2)
VK_CALL(vkGetPhysicalDeviceFeatures2KHR(physical_device, &info->features2));
else
VK_CALL(vkGetPhysicalDeviceFeatures(physical_device, &info->features2.features));
info->properties2.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_PROPERTIES_2;
maintenance3_properties->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_MAINTENANCE_3_PROPERTIES;
if (vulkan_info->KHR_maintenance3)
vk_prepend_struct(&info->properties2, maintenance3_properties);
descriptor_indexing_properties->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_DESCRIPTOR_INDEXING_PROPERTIES_EXT;
if (vulkan_info->EXT_descriptor_indexing)
vk_prepend_struct(&info->properties2, descriptor_indexing_properties);
buffer_alignment_properties->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_TEXEL_BUFFER_ALIGNMENT_PROPERTIES_EXT;
if (vulkan_info->EXT_texel_buffer_alignment)
vk_prepend_struct(&info->properties2, buffer_alignment_properties);
xfb_properties->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_TRANSFORM_FEEDBACK_PROPERTIES_EXT;
if (vulkan_info->EXT_transform_feedback)
vk_prepend_struct(&info->properties2, xfb_properties);
vertex_divisor_properties->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_VERTEX_ATTRIBUTE_DIVISOR_PROPERTIES_EXT;
if (vulkan_info->EXT_vertex_attribute_divisor)
vk_prepend_struct(&info->properties2, vertex_divisor_properties);
subgroup_properties->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_SUBGROUP_PROPERTIES;
if (d3d12_device_environment_is_vulkan_min_1_1(device))
vk_prepend_struct(&info->properties2, subgroup_properties);
if (vulkan_info->KHR_get_physical_device_properties2)
VK_CALL(vkGetPhysicalDeviceProperties2KHR(physical_device, &info->properties2));
else
VK_CALL(vkGetPhysicalDeviceProperties(physical_device, &info->properties2.properties));
}
static void vkd3d_trace_physical_device_properties(const VkPhysicalDeviceProperties *properties)
{
const uint32_t driver_version = properties->driverVersion;
const uint32_t api_version = properties->apiVersion;
TRACE("Device name: %s.\n", properties->deviceName);
TRACE("Vendor ID: %#x, Device ID: %#x.\n", properties->vendorID, properties->deviceID);
TRACE("Driver version: %#x (%u.%u.%u, %u.%u.%u.%u).\n", driver_version,
VK_VERSION_MAJOR(driver_version), VK_VERSION_MINOR(driver_version), VK_VERSION_PATCH(driver_version),
driver_version >> 22, (driver_version >> 14) & 0xff, (driver_version >> 6) & 0xff, driver_version & 0x3f);
TRACE("API version: %u.%u.%u.\n",
VK_VERSION_MAJOR(api_version), VK_VERSION_MINOR(api_version), VK_VERSION_PATCH(api_version));
}
static void vkd3d_trace_physical_device(VkPhysicalDevice device,
const struct vkd3d_physical_device_info *info,
const struct vkd3d_vk_instance_procs *vk_procs)
{
VkPhysicalDeviceMemoryProperties memory_properties;
VkQueueFamilyProperties *queue_properties;
unsigned int i, j;
uint32_t count;
vkd3d_trace_physical_device_properties(&info->properties2.properties);
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));
}
}
}
static void vkd3d_trace_physical_device_limits(const struct vkd3d_physical_device_info *info)
{
const VkPhysicalDeviceVertexAttributeDivisorPropertiesEXT *divisor_properties;
const VkPhysicalDeviceLimits *limits = &info->properties2.properties.limits;
const VkPhysicalDeviceDescriptorIndexingPropertiesEXT *descriptor_indexing;
const VkPhysicalDeviceTexelBufferAlignmentPropertiesEXT *buffer_alignment;
const VkPhysicalDeviceMaintenance3Properties *maintenance3;
const VkPhysicalDeviceTransformFeedbackPropertiesEXT *xfb;
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);
descriptor_indexing = &info->descriptor_indexing_properties;
TRACE(" VkPhysicalDeviceDescriptorIndexingPropertiesEXT:\n");
TRACE(" maxUpdateAfterBindDescriptorsInAllPools: %u.\n",
descriptor_indexing->maxUpdateAfterBindDescriptorsInAllPools);
TRACE(" shaderUniformBufferArrayNonUniformIndexingNative: %#x.\n",
descriptor_indexing->shaderUniformBufferArrayNonUniformIndexingNative);
TRACE(" shaderSampledImageArrayNonUniformIndexingNative: %#x.\n",
descriptor_indexing->shaderSampledImageArrayNonUniformIndexingNative);
TRACE(" shaderStorageBufferArrayNonUniformIndexingNative: %#x.\n",
descriptor_indexing->shaderStorageBufferArrayNonUniformIndexingNative);
TRACE(" shaderStorageImageArrayNonUniformIndexingNative: %#x.\n",
descriptor_indexing->shaderStorageImageArrayNonUniformIndexingNative);
TRACE(" shaderInputAttachmentArrayNonUniformIndexingNative: %#x.\n",
descriptor_indexing->shaderInputAttachmentArrayNonUniformIndexingNative);
TRACE(" robustBufferAccessUpdateAfterBind: %#x.\n",
descriptor_indexing->robustBufferAccessUpdateAfterBind);
TRACE(" quadDivergentImplicitLod: %#x.\n",
descriptor_indexing->quadDivergentImplicitLod);
TRACE(" maxPerStageDescriptorUpdateAfterBindSamplers: %u.\n",
descriptor_indexing->maxPerStageDescriptorUpdateAfterBindSamplers);
TRACE(" maxPerStageDescriptorUpdateAfterBindUniformBuffers: %u.\n",
descriptor_indexing->maxPerStageDescriptorUpdateAfterBindUniformBuffers);
TRACE(" maxPerStageDescriptorUpdateAfterBindStorageBuffers: %u.\n",
descriptor_indexing->maxPerStageDescriptorUpdateAfterBindStorageBuffers);
TRACE(" maxPerStageDescriptorUpdateAfterBindSampledImages: %u.\n",
descriptor_indexing->maxPerStageDescriptorUpdateAfterBindSampledImages);
TRACE(" maxPerStageDescriptorUpdateAfterBindStorageImages: %u.\n",
descriptor_indexing->maxPerStageDescriptorUpdateAfterBindStorageImages);
TRACE(" maxPerStageDescriptorUpdateAfterBindInputAttachments: %u.\n",
descriptor_indexing->maxPerStageDescriptorUpdateAfterBindInputAttachments);
TRACE(" maxPerStageUpdateAfterBindResources: %u.\n",
descriptor_indexing->maxPerStageUpdateAfterBindResources);
TRACE(" maxDescriptorSetUpdateAfterBindSamplers: %u.\n",
descriptor_indexing->maxDescriptorSetUpdateAfterBindSamplers);
TRACE(" maxDescriptorSetUpdateAfterBindUniformBuffers: %u.\n",
descriptor_indexing->maxDescriptorSetUpdateAfterBindUniformBuffers);
TRACE(" maxDescriptorSetUpdateAfterBindUniformBuffersDynamic: %u.\n",
descriptor_indexing->maxDescriptorSetUpdateAfterBindUniformBuffersDynamic);
TRACE(" maxDescriptorSetUpdateAfterBindStorageBuffers: %u.\n",
descriptor_indexing->maxDescriptorSetUpdateAfterBindStorageBuffers);
TRACE(" maxDescriptorSetUpdateAfterBindStorageBuffersDynamic: %u.\n",
descriptor_indexing->maxDescriptorSetUpdateAfterBindStorageBuffersDynamic);
TRACE(" maxDescriptorSetUpdateAfterBindSampledImages: %u.\n",
descriptor_indexing->maxDescriptorSetUpdateAfterBindSampledImages);
TRACE(" maxDescriptorSetUpdateAfterBindStorageImages: %u.\n",
descriptor_indexing->maxDescriptorSetUpdateAfterBindStorageImages);
TRACE(" maxDescriptorSetUpdateAfterBindInputAttachments: %u.\n",
descriptor_indexing->maxDescriptorSetUpdateAfterBindInputAttachments);
maintenance3 = &info->maintenance3_properties;
TRACE(" VkPhysicalDeviceMaintenance3Properties:\n");
TRACE(" maxPerSetDescriptors: %u.\n", maintenance3->maxPerSetDescriptors);
TRACE(" maxMemoryAllocationSize: %#"PRIx64".\n", maintenance3->maxMemoryAllocationSize);
buffer_alignment = &info->texel_buffer_alignment_properties;
TRACE(" VkPhysicalDeviceTexelBufferAlignmentPropertiesEXT:\n");
TRACE(" storageTexelBufferOffsetAlignmentBytes: %#"PRIx64".\n",
buffer_alignment->storageTexelBufferOffsetAlignmentBytes);
TRACE(" storageTexelBufferOffsetSingleTexelAlignment: %#x.\n",
buffer_alignment->storageTexelBufferOffsetSingleTexelAlignment);
TRACE(" uniformTexelBufferOffsetAlignmentBytes: %#"PRIx64".\n",
buffer_alignment->uniformTexelBufferOffsetAlignmentBytes);
TRACE(" uniformTexelBufferOffsetSingleTexelAlignment: %#x.\n",
buffer_alignment->uniformTexelBufferOffsetSingleTexelAlignment);
xfb = &info->xfb_properties;
TRACE(" VkPhysicalDeviceTransformFeedbackPropertiesEXT:\n");
TRACE(" maxTransformFeedbackStreams: %u.\n", xfb->maxTransformFeedbackStreams);
TRACE(" maxTransformFeedbackBuffers: %u.\n", xfb->maxTransformFeedbackBuffers);
TRACE(" maxTransformFeedbackBufferSize: %#"PRIx64".\n", xfb->maxTransformFeedbackBufferSize);
TRACE(" maxTransformFeedbackStreamDataSize: %u.\n", xfb->maxTransformFeedbackStreamDataSize);
TRACE(" maxTransformFeedbackBufferDataSize: %u.\n", xfb->maxTransformFeedbackBufferDataSize);
TRACE(" maxTransformFeedbackBufferDataStride: %u.\n", xfb->maxTransformFeedbackBufferDataStride);
TRACE(" transformFeedbackQueries: %#x.\n", xfb->transformFeedbackQueries);
TRACE(" transformFeedbackStreamsLinesTriangles: %#x.\n", xfb->transformFeedbackStreamsLinesTriangles);
TRACE(" transformFeedbackRasterizationStreamSelect: %#x.\n", xfb->transformFeedbackRasterizationStreamSelect);
TRACE(" transformFeedbackDraw: %x.\n", xfb->transformFeedbackDraw);
divisor_properties = &info->vertex_divisor_properties;
TRACE(" VkPhysicalDeviceVertexAttributeDivisorPropertiesEXT:\n");
TRACE(" maxVertexAttribDivisor: %u.\n", divisor_properties->maxVertexAttribDivisor);
}
static void vkd3d_trace_physical_device_features(const struct vkd3d_physical_device_info *info)
{
const VkPhysicalDeviceFragmentShaderInterlockFeaturesEXT *fragment_shader_interlock_features;
const VkPhysicalDeviceConditionalRenderingFeaturesEXT *conditional_rendering_features;
const VkPhysicalDeviceShaderDemoteToHelperInvocationFeaturesEXT *demote_features;
const VkPhysicalDeviceTexelBufferAlignmentFeaturesEXT *buffer_alignment_features;
const VkPhysicalDeviceVertexAttributeDivisorFeaturesEXT *divisor_features;
const VkPhysicalDeviceDescriptorIndexingFeaturesEXT *descriptor_indexing;
const VkPhysicalDeviceDepthClipEnableFeaturesEXT *depth_clip_features;
const VkPhysicalDeviceFeatures *features = &info->features2.features;
const VkPhysicalDeviceTransformFeedbackFeaturesEXT *xfb;
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);
descriptor_indexing = &info->descriptor_indexing_features;
TRACE(" VkPhysicalDeviceDescriptorIndexingFeaturesEXT:\n");
TRACE(" shaderInputAttachmentArrayDynamicIndexing: %#x.\n",
descriptor_indexing->shaderInputAttachmentArrayDynamicIndexing);
TRACE(" shaderUniformTexelBufferArrayDynamicIndexing: %#x.\n",
descriptor_indexing->shaderUniformTexelBufferArrayDynamicIndexing);
TRACE(" shaderStorageTexelBufferArrayDynamicIndexing: %#x.\n",
descriptor_indexing->shaderStorageTexelBufferArrayDynamicIndexing);
TRACE(" shaderUniformBufferArrayNonUniformIndexing: %#x.\n",
descriptor_indexing->shaderUniformBufferArrayNonUniformIndexing);
TRACE(" shaderSampledImageArrayNonUniformIndexing: %#x.\n",
descriptor_indexing->shaderSampledImageArrayNonUniformIndexing);
TRACE(" shaderStorageBufferArrayNonUniformIndexing: %#x.\n",
descriptor_indexing->shaderStorageBufferArrayNonUniformIndexing);
TRACE(" shaderStorageImageArrayNonUniformIndexing: %#x.\n",
descriptor_indexing->shaderStorageImageArrayNonUniformIndexing);
TRACE(" shaderInputAttachmentArrayNonUniformIndexing: %#x.\n",
descriptor_indexing->shaderInputAttachmentArrayNonUniformIndexing);
TRACE(" shaderUniformTexelBufferArrayNonUniformIndexing: %#x.\n",
descriptor_indexing->shaderUniformTexelBufferArrayNonUniformIndexing);
TRACE(" shaderStorageTexelBufferArrayNonUniformIndexing: %#x.\n",
descriptor_indexing->shaderStorageTexelBufferArrayNonUniformIndexing);
TRACE(" descriptorBindingUniformBufferUpdateAfterBind: %#x.\n",
descriptor_indexing->descriptorBindingUniformBufferUpdateAfterBind);
TRACE(" descriptorBindingSampledImageUpdateAfterBind: %#x.\n",
descriptor_indexing->descriptorBindingSampledImageUpdateAfterBind);
TRACE(" descriptorBindingStorageImageUpdateAfterBind: %#x.\n",
descriptor_indexing->descriptorBindingStorageImageUpdateAfterBind);
TRACE(" descriptorBindingStorageBufferUpdateAfterBind: %#x.\n",
descriptor_indexing->descriptorBindingStorageBufferUpdateAfterBind);
TRACE(" descriptorBindingUniformTexelBufferUpdateAfterBind: %#x.\n",
descriptor_indexing->descriptorBindingUniformTexelBufferUpdateAfterBind);
TRACE(" descriptorBindingStorageTexelBufferUpdateAfterBind: %#x.\n",
descriptor_indexing->descriptorBindingStorageTexelBufferUpdateAfterBind);
TRACE(" descriptorBindingUpdateUnusedWhilePending: %#x.\n",
descriptor_indexing->descriptorBindingUpdateUnusedWhilePending);
TRACE(" descriptorBindingPartiallyBound: %#x.\n",
descriptor_indexing->descriptorBindingPartiallyBound);
TRACE(" descriptorBindingVariableDescriptorCount: %#x.\n",
descriptor_indexing->descriptorBindingVariableDescriptorCount);
TRACE(" runtimeDescriptorArray: %#x.\n",
descriptor_indexing->runtimeDescriptorArray);
conditional_rendering_features = &info->conditional_rendering_features;
TRACE(" VkPhysicalDeviceConditionalRenderingFeaturesEXT:\n");
TRACE(" conditionalRendering: %#x.\n", conditional_rendering_features->conditionalRendering);
depth_clip_features = &info->depth_clip_features;
TRACE(" VkPhysicalDeviceDepthClipEnableFeaturesEXT:\n");
TRACE(" depthClipEnable: %#x.\n", depth_clip_features->depthClipEnable);
fragment_shader_interlock_features = &info->fragment_shader_interlock_features;
TRACE(" VkPhysicalDeviceFragmentShaderInterlockFeaturesEXT:\n");
TRACE(" fragmentShaderSampleInterlock: %#x.\n",
fragment_shader_interlock_features->fragmentShaderSampleInterlock);
TRACE(" fragmentShaderPixelInterlock: %#x.\n",
fragment_shader_interlock_features->fragmentShaderPixelInterlock);
TRACE(" fragmentShaderShadingRateInterlock: %#x.\n",
fragment_shader_interlock_features->fragmentShaderShadingRateInterlock);
demote_features = &info->demote_features;
TRACE(" VkPhysicalDeviceShaderDemoteToHelperInvocationFeaturesEXT:\n");
TRACE(" shaderDemoteToHelperInvocation: %#x.\n", demote_features->shaderDemoteToHelperInvocation);
buffer_alignment_features = &info->texel_buffer_alignment_features;
TRACE(" VkPhysicalDeviceTexelBufferAlignmentFeaturesEXT:\n");
TRACE(" texelBufferAlignment: %#x.\n", buffer_alignment_features->texelBufferAlignment);
xfb = &info->xfb_features;
TRACE(" VkPhysicalDeviceTransformFeedbackFeaturesEXT:\n");
TRACE(" transformFeedback: %#x.\n", xfb->transformFeedback);
TRACE(" geometryStreams: %#x.\n", xfb->geometryStreams);
divisor_features = &info->vertex_divisor_features;
TRACE(" VkPhysicalDeviceVertexAttributeDivisorFeaturesEXT:\n");
TRACE(" vertexAttributeInstanceRateDivisor: %#x.\n",
divisor_features->vertexAttributeInstanceRateDivisor);
TRACE(" vertexAttributeInstanceRateZeroDivisor: %#x.\n",
divisor_features->vertexAttributeInstanceRateZeroDivisor);
}
static void vkd3d_init_feature_level(struct vkd3d_vulkan_info *vk_info,
const VkPhysicalDeviceFeatures *features,
const D3D12_FEATURE_DATA_D3D12_OPTIONS *d3d12_options)
{
bool have_11_0 = true;
#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"); \
have_11_0 = false; \
}
if (!vk_info->device_limits.timestampComputeAndGraphics)
WARN("Timestamps are not supported on all graphics and compute queues.\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(depthBiasClamp);
CHECK_FEATURE(depthClamp);
CHECK_FEATURE(drawIndirectFirstInstance);
CHECK_FEATURE(dualSrcBlend);
CHECK_FEATURE(fragmentStoresAndAtomics);
CHECK_FEATURE(fullDrawIndexUint32);
CHECK_FEATURE(geometryShader);
CHECK_FEATURE(imageCubeArray);
CHECK_FEATURE(independentBlend);
CHECK_FEATURE(multiDrawIndirect);
CHECK_FEATURE(multiViewport);
CHECK_FEATURE(occlusionQueryPrecise);
CHECK_FEATURE(pipelineStatisticsQuery);
CHECK_FEATURE(samplerAnisotropy);
CHECK_FEATURE(sampleRateShading);
CHECK_FEATURE(shaderClipDistance);
CHECK_FEATURE(shaderCullDistance);
CHECK_FEATURE(shaderImageGatherExtended);
CHECK_FEATURE(shaderStorageImageWriteWithoutFormat);
CHECK_FEATURE(tessellationShader);
if (!vk_info->EXT_depth_clip_enable)
WARN("Depth clip enable is not supported.\n");
if (!vk_info->EXT_transform_feedback)
WARN("Stream output is not supported.\n");
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
vk_info->max_feature_level = D3D_FEATURE_LEVEL_11_0;
if (have_11_0
&& d3d12_options->OutputMergerLogicOp
&& features->vertexPipelineStoresAndAtomics
&& vk_info->device_limits.maxPerStageDescriptorStorageBuffers >= D3D12_UAV_SLOT_COUNT
&& vk_info->device_limits.maxPerStageDescriptorStorageImages >= D3D12_UAV_SLOT_COUNT)
vk_info->max_feature_level = D3D_FEATURE_LEVEL_11_1;
/* TODO: MinMaxFiltering */
if (vk_info->max_feature_level >= D3D_FEATURE_LEVEL_11_1
&& d3d12_options->TiledResourcesTier >= D3D12_TILED_RESOURCES_TIER_2
&& d3d12_options->ResourceBindingTier >= D3D12_RESOURCE_BINDING_TIER_2
&& d3d12_options->TypedUAVLoadAdditionalFormats)
vk_info->max_feature_level = D3D_FEATURE_LEVEL_12_0;
if (vk_info->max_feature_level >= D3D_FEATURE_LEVEL_12_0
&& d3d12_options->ROVsSupported
&& d3d12_options->ConservativeRasterizationTier >= D3D12_CONSERVATIVE_RASTERIZATION_TIER_1)
vk_info->max_feature_level = D3D_FEATURE_LEVEL_12_1;
TRACE("Max feature level: %#x.\n", vk_info->max_feature_level);
}
static void vkd3d_device_descriptor_limits_init(struct vkd3d_device_descriptor_limits *limits,
const VkPhysicalDeviceLimits *device_limits)
{
limits->uniform_buffer_max_descriptors = device_limits->maxDescriptorSetUniformBuffers;
limits->sampled_image_max_descriptors = device_limits->maxDescriptorSetSampledImages;
limits->storage_buffer_max_descriptors = device_limits->maxDescriptorSetStorageBuffers;
limits->storage_image_max_descriptors = device_limits->maxDescriptorSetStorageImages;
limits->sampler_max_descriptors = min(device_limits->maxDescriptorSetSamplers, VKD3D_MAX_DESCRIPTOR_SET_SAMPLERS);
}
vkd3d: Back descriptor heaps with Vulkan descriptor sets if descriptor indexing is available. The existing implementation using virtual descriptor heaps, where Vk descriptor sets are created for the bindings in the root descriptor tables, is inefficient when multiple command lists are used with large descriptor heaps. It also cannot support updating a descriptor set after it is bound. This patch creates Vk sets for each D3D12 heap. Because D3D12 heaps can contain CBV, SRV and UAV descriptors in the same heap, multiple Vk sets are needed for each heap, however the total number of populated descriptors is never more than (heap size + UAV counter count). A new 'virtual_heaps' config option is introduced to make the old implementation available when needed. It's not always possible to determine if this is necessary when the device is created. Up to nine Vk descriptor sets may be used. It's theoretically possible to reduce this to eight by placing immutable samplers in the push descriptor set layout, but contradictions in earlier versions of the Vulkan spec made driver support inconsistent. The documentation was corrected in version 1.2.203. This patch also adds support for UAV counter descriptor arrays. It's not practical to add this in a separate patch due to complications with combining the old UAV counter implementation with the new descriptor heap implementation. Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47713 Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47154 Signed-off-by: Conor McCarthy <cmccarthy@codeweavers.com> Signed-off-by: Henri Verbeet <hverbeet@codeweavers.com> Signed-off-by: Alexandre Julliard <julliard@winehq.org>
2022-02-21 07:18:59 -08:00
static void vkd3d_device_vk_heaps_descriptor_limits_init(struct vkd3d_device_descriptor_limits *limits,
const VkPhysicalDeviceDescriptorIndexingPropertiesEXT *properties)
{
const unsigned int root_provision = D3D12_MAX_ROOT_COST / 2;
unsigned int srv_divisor = 1, uav_divisor = 1;
/* The total number of populated sampled image or storage image descriptors never exceeds the size of
* one set (or two sets if every UAV has a counter), but the total size of bound layouts will exceed
* device limits if each set size is maxDescriptorSet*, because of the D3D12 buffer + image allowance
* (and UAV counters). Breaking limits for layouts seems to work with RADV and Nvidia drivers at
* least, but let's try to stay within them if limits are high enough. */
if (properties->maxDescriptorSetUpdateAfterBindSampledImages >= (1u << 21))
{
srv_divisor = 2;
uav_divisor = properties->maxDescriptorSetUpdateAfterBindSampledImages >= (3u << 20) ? 3 : 2;
}
limits->uniform_buffer_max_descriptors = min(properties->maxDescriptorSetUpdateAfterBindUniformBuffers,
properties->maxPerStageDescriptorUpdateAfterBindUniformBuffers - root_provision);
limits->sampled_image_max_descriptors = min(properties->maxDescriptorSetUpdateAfterBindSampledImages,
properties->maxPerStageDescriptorUpdateAfterBindSampledImages / srv_divisor - root_provision);
limits->storage_buffer_max_descriptors = min(properties->maxDescriptorSetUpdateAfterBindStorageBuffers,
properties->maxPerStageDescriptorUpdateAfterBindStorageBuffers - root_provision);
limits->storage_image_max_descriptors = min(properties->maxDescriptorSetUpdateAfterBindStorageImages,
properties->maxPerStageDescriptorUpdateAfterBindStorageImages / uav_divisor - root_provision);
limits->sampler_max_descriptors = min(properties->maxDescriptorSetUpdateAfterBindSamplers,
properties->maxPerStageDescriptorUpdateAfterBindSamplers - root_provision);
limits->sampler_max_descriptors = min(limits->sampler_max_descriptors, VKD3D_MAX_DESCRIPTOR_SET_SAMPLERS);
}
static bool d3d12_device_supports_typed_uav_load_additional_formats(const struct d3d12_device *device)
{
const struct vkd3d_vk_instance_procs *vk_procs = &device->vkd3d_instance->vk_procs;
const struct vkd3d_format *format;
VkFormatProperties properties;
unsigned int i;
static const DXGI_FORMAT additional_formats[] =
{
DXGI_FORMAT_R32G32B32A32_FLOAT,
DXGI_FORMAT_R32G32B32A32_UINT,
DXGI_FORMAT_R32G32B32A32_SINT,
DXGI_FORMAT_R16G16B16A16_FLOAT,
DXGI_FORMAT_R16G16B16A16_UINT,
DXGI_FORMAT_R16G16B16A16_SINT,
DXGI_FORMAT_R8G8B8A8_UNORM,
DXGI_FORMAT_R8G8B8A8_UINT,
DXGI_FORMAT_R8G8B8A8_SINT,
DXGI_FORMAT_R16_FLOAT,
DXGI_FORMAT_R16_UINT,
DXGI_FORMAT_R16_SINT,
DXGI_FORMAT_R8_UNORM,
DXGI_FORMAT_R8_UINT,
DXGI_FORMAT_R8_SINT,
};
for (i = 0; i < ARRAY_SIZE(additional_formats); ++i)
{
format = vkd3d_get_format(device, additional_formats[i], false);
assert(format);
VK_CALL(vkGetPhysicalDeviceFormatProperties(device->vk_physical_device, format->vk_format, &properties));
if (!((properties.linearTilingFeatures | properties.optimalTilingFeatures) & VK_FORMAT_FEATURE_STORAGE_IMAGE_BIT))
return false;
}
return true;
}
static HRESULT vkd3d_check_device_extensions(struct d3d12_device *device,
const struct vkd3d_device_create_info *create_info, VkExtensionProperties **vk_extensions,
uint32_t *vk_extension_count, uint32_t *device_extension_count, bool **user_extension_supported)
{
const struct vkd3d_vk_instance_procs *vk_procs = &device->vkd3d_instance->vk_procs;
const struct vkd3d_optional_device_extensions_info *optional_extensions;
VkPhysicalDevice physical_device = device->vk_physical_device;
struct vkd3d_vulkan_info *vulkan_info = &device->vk_info;
VkResult vr;
*device_extension_count = 0;
if ((vr = VK_CALL(vkEnumerateDeviceExtensionProperties(physical_device, NULL, vk_extension_count, NULL))) < 0)
{
ERR("Failed to enumerate device extensions, vr %d.\n", vr);
return hresult_from_vk_result(vr);
}
if (!(*vk_extensions = vkd3d_calloc(*vk_extension_count, sizeof(**vk_extensions))))
return E_OUTOFMEMORY;
TRACE("Enumerating %u device extensions.\n", *vk_extension_count);
if ((vr = VK_CALL(vkEnumerateDeviceExtensionProperties(physical_device, NULL, vk_extension_count, *vk_extensions))) < 0)
{
ERR("Failed to enumerate device extensions, vr %d.\n", vr);
vkd3d_free(*vk_extensions);
return hresult_from_vk_result(vr);
}
optional_extensions = vkd3d_find_struct(create_info->next, OPTIONAL_DEVICE_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;
}
*device_extension_count = vkd3d_check_extensions(*vk_extensions, *vk_extension_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,
optional_extensions ? optional_extensions->extensions : NULL,
optional_extensions ? optional_extensions->extension_count : 0,
*user_extension_supported, vulkan_info, "device",
device->vkd3d_instance->config_flags & VKD3D_CONFIG_FLAG_VULKAN_DEBUG);
return S_OK;
}
static HRESULT vkd3d_init_device_caps(struct d3d12_device *device,
const struct vkd3d_device_create_info *create_info,
struct vkd3d_physical_device_info *physical_device_info,
uint32_t *device_extension_count, bool **user_extension_supported)
{
const VkPhysicalDeviceSubgroupProperties *subgroup_properties = &physical_device_info->subgroup_properties;
const struct vkd3d_vk_instance_procs *vk_procs = &device->vkd3d_instance->vk_procs;
VkPhysicalDeviceFragmentShaderInterlockFeaturesEXT *fragment_shader_interlock;
VkPhysicalDeviceDescriptorIndexingFeaturesEXT *descriptor_indexing;
VkPhysicalDevice physical_device = device->vk_physical_device;
struct vkd3d_vulkan_info *vulkan_info = &device->vk_info;
VkExtensionProperties *vk_extensions;
VkPhysicalDeviceFeatures *features;
uint32_t vk_extension_count;
HRESULT hr;
/* SHUFFLE is required to implement WaveReadLaneAt with dynamically uniform index before SPIR-V 1.5 / Vulkan 1.2. */
static const VkSubgroupFeatureFlags required_subgroup_features = VK_SUBGROUP_FEATURE_ARITHMETIC_BIT
| VK_SUBGROUP_FEATURE_BASIC_BIT
| VK_SUBGROUP_FEATURE_BALLOT_BIT
| VK_SUBGROUP_FEATURE_SHUFFLE_BIT
| VK_SUBGROUP_FEATURE_QUAD_BIT
| VK_SUBGROUP_FEATURE_VOTE_BIT;
static const VkSubgroupFeatureFlags required_stages = VK_SHADER_STAGE_COMPUTE_BIT | VK_SHADER_STAGE_FRAGMENT_BIT;
if (FAILED(hr = vkd3d_check_device_extensions(device, create_info, &vk_extensions, &vk_extension_count,
device_extension_count, user_extension_supported)))
return hr;
vkd3d_physical_device_info_init(physical_device_info, device);
vkd3d_trace_physical_device(physical_device, physical_device_info, vk_procs);
vkd3d_trace_physical_device_features(physical_device_info);
vkd3d_trace_physical_device_limits(physical_device_info);
features = &physical_device_info->features2.features;
if (!features->sparseResidencyBuffer || !features->sparseResidencyImage2D)
{
features->sparseResidencyBuffer = VK_FALSE;
features->sparseResidencyImage2D = VK_FALSE;
physical_device_info->properties2.properties.sparseProperties.residencyNonResidentStrict = VK_FALSE;
}
vulkan_info->device_limits = physical_device_info->properties2.properties.limits;
vulkan_info->sparse_properties = physical_device_info->properties2.properties.sparseProperties;
vulkan_info->geometry_shaders = physical_device_info->features2.features.geometryShader;
vulkan_info->tessellation_shaders = physical_device_info->features2.features.tessellationShader;
vulkan_info->sparse_binding = features->sparseBinding;
vulkan_info->sparse_residency_3d = features->sparseResidencyImage3D;
vulkan_info->rasterization_stream = physical_device_info->xfb_properties.transformFeedbackRasterizationStreamSelect;
vulkan_info->transform_feedback_queries = physical_device_info->xfb_properties.transformFeedbackQueries;
vulkan_info->uav_read_without_format = features->shaderStorageImageReadWithoutFormat;
vulkan_info->max_vertex_attrib_divisor = max(physical_device_info->vertex_divisor_properties.maxVertexAttribDivisor, 1);
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;
/* FIXME: Implement tiled resources. */
if (device->feature_options.TiledResourcesTier)
{
WARN("Tiled resources are not implemented yet.\n");
device->feature_options.TiledResourcesTier = D3D12_TILED_RESOURCES_TIER_NOT_SUPPORTED;
}
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.TypedUAVLoadAdditionalFormats = features->shaderStorageImageReadWithoutFormat
&& d3d12_device_supports_typed_uav_load_additional_formats(device);
/* GL_INTEL_conservative_rasterization, no Vulkan equivalent. */
device->feature_options.ConservativeRasterizationTier = D3D12_CONSERVATIVE_RASTERIZATION_TIER_NOT_SUPPORTED;
device->feature_options.MaxGPUVirtualAddressBitsPerResource = 40; /* FIXME */
device->feature_options.StandardSwizzle64KBSupported = FALSE;
device->feature_options.CrossNodeSharingTier = D3D12_CROSS_NODE_SHARING_TIER_NOT_SUPPORTED;
device->feature_options.CrossAdapterRowMajorTextureSupported = FALSE;
device->feature_options.ResourceHeapTier = D3D12_RESOURCE_HEAP_TIER_2;
/* Shader Model 6 support. */
device->feature_options1.WaveOps = subgroup_properties->subgroupSize >= 4
&& (subgroup_properties->supportedOperations & required_subgroup_features) == required_subgroup_features
&& (subgroup_properties->supportedStages & required_stages) == required_stages;
device->feature_options1.WaveLaneCountMin = subgroup_properties->subgroupSize;
device->feature_options1.WaveLaneCountMax = subgroup_properties->subgroupSize;
device->feature_options1.TotalLaneCount = 32 * subgroup_properties->subgroupSize; /* approx. */
device->feature_options1.ExpandedComputeResourceStates = TRUE;
device->feature_options1.Int64ShaderOps = features->shaderInt64;
2023-07-17 22:50:18 -07:00
device->feature_options2.DepthBoundsTestSupported = features->depthBounds;
/* d3d12_command_list_SetSamplePositions() is not implemented. */
device->feature_options2.ProgrammableSamplePositionsTier = D3D12_PROGRAMMABLE_SAMPLE_POSITIONS_TIER_NOT_SUPPORTED;
device->feature_options3.CopyQueueTimestampQueriesSupported = FALSE;
device->feature_options3.CastingFullyTypedFormatSupported = FALSE;
device->feature_options3.WriteBufferImmediateSupportFlags = D3D12_COMMAND_LIST_SUPPORT_FLAG_NONE;
device->feature_options3.ViewInstancingTier = D3D12_VIEW_INSTANCING_TIER_NOT_SUPPORTED;
device->feature_options3.BarycentricsSupported = FALSE;
device->feature_options4.MSAA64KBAlignedTextureSupported = FALSE;
device->feature_options4.SharedResourceCompatibilityTier = D3D12_SHARED_RESOURCE_COMPATIBILITY_TIER_0;
/* An SM 6.2 feature. This would require features->shaderInt16 and
* VK_KHR_shader_float16_int8. */
device->feature_options4.Native16BitShaderOpsSupported = FALSE;
device->feature_options5.SRVOnlyTiledResourceTier3 = FALSE;
device->feature_options5.RenderPassesTier = D3D12_RENDER_PASS_TIER_0;
device->feature_options5.RaytracingTier = D3D12_RAYTRACING_TIER_NOT_SUPPORTED;
fragment_shader_interlock = &physical_device_info->fragment_shader_interlock_features;
if (!fragment_shader_interlock->fragmentShaderSampleInterlock
|| !fragment_shader_interlock->fragmentShaderPixelInterlock)
vulkan_info->EXT_fragment_shader_interlock = false;
device->feature_options.ROVsSupported = vulkan_info->EXT_fragment_shader_interlock;
if (!physical_device_info->conditional_rendering_features.conditionalRendering)
vulkan_info->EXT_conditional_rendering = false;
if (!physical_device_info->depth_clip_features.depthClipEnable)
vulkan_info->EXT_depth_clip_enable = false;
if (!physical_device_info->robustness2_features.nullDescriptor)
vulkan_info->EXT_robustness2 = false;
if (!physical_device_info->demote_features.shaderDemoteToHelperInvocation)
vulkan_info->EXT_shader_demote_to_helper_invocation = false;
if (!physical_device_info->texel_buffer_alignment_features.texelBufferAlignment)
vulkan_info->EXT_texel_buffer_alignment = false;
if (!physical_device_info->mutable_features.mutableDescriptorType)
vulkan_info->EXT_mutable_descriptor_type = false;
if (!physical_device_info->timeline_semaphore_features.timelineSemaphore)
vulkan_info->KHR_timeline_semaphore = false;
physical_device_info->formats4444_features.formatA4B4G4R4 = VK_FALSE;
vulkan_info->texel_buffer_alignment_properties = physical_device_info->texel_buffer_alignment_properties;
if (get_spec_version(vk_extensions, vk_extension_count, VK_EXT_VERTEX_ATTRIBUTE_DIVISOR_EXTENSION_NAME) >= 3)
{
const VkPhysicalDeviceVertexAttributeDivisorFeaturesEXT *divisor_features;
divisor_features = &physical_device_info->vertex_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_free(vk_extensions);
device->feature_options.PSSpecifiedStencilRefSupported = vulkan_info->EXT_shader_stencil_export;
device->feature_options.VPAndRTArrayIndexFromAnyShaderFeedingRasterizerSupportedWithoutGSEmulation =
vulkan_info->EXT_shader_viewport_index_layer;
vkd3d_init_feature_level(vulkan_info, features, &device->feature_options);
if (vulkan_info->max_feature_level < create_info->minimum_feature_level)
{
WARN("Feature level %#x is not supported.\n", create_info->minimum_feature_level);
vkd3d_free(*user_extension_supported);
*user_extension_supported = NULL;
return E_INVALIDARG;
}
/* Shader extensions. */
if (vulkan_info->EXT_shader_demote_to_helper_invocation)
{
vulkan_info->shader_extension_count = 1;
vulkan_info->shader_extensions[0] = VKD3D_SHADER_SPIRV_EXTENSION_EXT_DEMOTE_TO_HELPER_INVOCATION;
}
if (vulkan_info->EXT_descriptor_indexing)
vulkan_info->shader_extensions[vulkan_info->shader_extension_count++]
= VKD3D_SHADER_SPIRV_EXTENSION_EXT_DESCRIPTOR_INDEXING;
if (vulkan_info->EXT_fragment_shader_interlock)
vulkan_info->shader_extensions[vulkan_info->shader_extension_count++]
= VKD3D_SHADER_SPIRV_EXTENSION_EXT_FRAGMENT_SHADER_INTERLOCK;
if (vulkan_info->EXT_shader_stencil_export)
vulkan_info->shader_extensions[vulkan_info->shader_extension_count++]
= VKD3D_SHADER_SPIRV_EXTENSION_EXT_STENCIL_EXPORT;
if (vulkan_info->EXT_shader_viewport_index_layer)
vulkan_info->shader_extensions[vulkan_info->shader_extension_count++]
= VKD3D_SHADER_SPIRV_EXTENSION_EXT_VIEWPORT_INDEX_LAYER;
/* Disable unused Vulkan features. */
features->shaderTessellationAndGeometryPointSize = VK_FALSE;
descriptor_indexing = &physical_device_info->descriptor_indexing_features;
descriptor_indexing->shaderInputAttachmentArrayDynamicIndexing = VK_FALSE;
descriptor_indexing->shaderInputAttachmentArrayNonUniformIndexing = VK_FALSE;
/* We do not use storage buffers currently. */
features->shaderStorageBufferArrayDynamicIndexing = VK_FALSE;
descriptor_indexing->shaderStorageBufferArrayNonUniformIndexing = VK_FALSE;
descriptor_indexing->descriptorBindingStorageBufferUpdateAfterBind = VK_FALSE;
if (vulkan_info->EXT_descriptor_indexing && descriptor_indexing
&& (descriptor_indexing->descriptorBindingUniformBufferUpdateAfterBind
|| descriptor_indexing->descriptorBindingStorageBufferUpdateAfterBind
|| descriptor_indexing->descriptorBindingUniformTexelBufferUpdateAfterBind
|| descriptor_indexing->descriptorBindingStorageTexelBufferUpdateAfterBind)
&& !physical_device_info->descriptor_indexing_properties.robustBufferAccessUpdateAfterBind)
{
WARN("Disabling robust buffer access for the update after bind feature.\n");
features->robustBufferAccess = VK_FALSE;
physical_device_info->robustness2_features.robustBufferAccess2 = VK_FALSE;
}
vkd3d: Back descriptor heaps with Vulkan descriptor sets if descriptor indexing is available. The existing implementation using virtual descriptor heaps, where Vk descriptor sets are created for the bindings in the root descriptor tables, is inefficient when multiple command lists are used with large descriptor heaps. It also cannot support updating a descriptor set after it is bound. This patch creates Vk sets for each D3D12 heap. Because D3D12 heaps can contain CBV, SRV and UAV descriptors in the same heap, multiple Vk sets are needed for each heap, however the total number of populated descriptors is never more than (heap size + UAV counter count). A new 'virtual_heaps' config option is introduced to make the old implementation available when needed. It's not always possible to determine if this is necessary when the device is created. Up to nine Vk descriptor sets may be used. It's theoretically possible to reduce this to eight by placing immutable samplers in the push descriptor set layout, but contradictions in earlier versions of the Vulkan spec made driver support inconsistent. The documentation was corrected in version 1.2.203. This patch also adds support for UAV counter descriptor arrays. It's not practical to add this in a separate patch due to complications with combining the old UAV counter implementation with the new descriptor heap implementation. Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47713 Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47154 Signed-off-by: Conor McCarthy <cmccarthy@codeweavers.com> Signed-off-by: Henri Verbeet <hverbeet@codeweavers.com> Signed-off-by: Alexandre Julliard <julliard@winehq.org>
2022-02-21 07:18:59 -08:00
/* Select descriptor heap implementation. Forcing virtual heaps may be useful if
* a client allocates descriptor heaps too large for the Vulkan device, or the
* root signature cost exceeds the available push constant size. Virtual heaps
* use only enough descriptors for the descriptor tables of the currently bound
* root signature, and don't require a 32-bit push constant for each table. */
device->use_vk_heaps = vulkan_info->EXT_descriptor_indexing
&& !(device->vkd3d_instance->config_flags & VKD3D_CONFIG_FLAG_VIRTUAL_HEAPS)
&& descriptor_indexing->descriptorBindingUniformBufferUpdateAfterBind
&& descriptor_indexing->descriptorBindingSampledImageUpdateAfterBind
&& descriptor_indexing->descriptorBindingStorageImageUpdateAfterBind
&& descriptor_indexing->descriptorBindingUniformTexelBufferUpdateAfterBind
&& descriptor_indexing->descriptorBindingStorageTexelBufferUpdateAfterBind;
vkd3d: Back descriptor heaps with Vulkan descriptor sets if descriptor indexing is available. The existing implementation using virtual descriptor heaps, where Vk descriptor sets are created for the bindings in the root descriptor tables, is inefficient when multiple command lists are used with large descriptor heaps. It also cannot support updating a descriptor set after it is bound. This patch creates Vk sets for each D3D12 heap. Because D3D12 heaps can contain CBV, SRV and UAV descriptors in the same heap, multiple Vk sets are needed for each heap, however the total number of populated descriptors is never more than (heap size + UAV counter count). A new 'virtual_heaps' config option is introduced to make the old implementation available when needed. It's not always possible to determine if this is necessary when the device is created. Up to nine Vk descriptor sets may be used. It's theoretically possible to reduce this to eight by placing immutable samplers in the push descriptor set layout, but contradictions in earlier versions of the Vulkan spec made driver support inconsistent. The documentation was corrected in version 1.2.203. This patch also adds support for UAV counter descriptor arrays. It's not practical to add this in a separate patch due to complications with combining the old UAV counter implementation with the new descriptor heap implementation. Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47713 Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47154 Signed-off-by: Conor McCarthy <cmccarthy@codeweavers.com> Signed-off-by: Henri Verbeet <hverbeet@codeweavers.com> Signed-off-by: Alexandre Julliard <julliard@winehq.org>
2022-02-21 07:18:59 -08:00
if (device->use_vk_heaps)
vkd3d_device_vk_heaps_descriptor_limits_init(&vulkan_info->descriptor_limits,
&physical_device_info->descriptor_indexing_properties);
else
vkd3d_device_descriptor_limits_init(&vulkan_info->descriptor_limits,
&physical_device_info->properties2.properties.limits);
return S_OK;
}
static HRESULT vkd3d_select_physical_device(struct vkd3d_instance *instance,
unsigned int device_index, VkPhysicalDevice *selected_device)
{
VkPhysicalDevice dgpu_device = VK_NULL_HANDLE, igpu_device = VK_NULL_HANDLE;
const struct vkd3d_vk_instance_procs *vk_procs = &instance->vk_procs;
VkInstance vk_instance = instance->vk_instance;
VkPhysicalDeviceProperties device_properties;
VkPhysicalDevice device = VK_NULL_HANDLE;
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);
}
if (device_index != ~0u && device_index >= count)
WARN("Device index %u is out of range.\n", device_index);
for (i = 0; i < count; ++i)
{
VK_CALL(vkGetPhysicalDeviceProperties(physical_devices[i], &device_properties));
vkd3d_trace_physical_device_properties(&device_properties);
if (i == device_index)
device = physical_devices[i];
if (device_properties.deviceType == VK_PHYSICAL_DEVICE_TYPE_DISCRETE_GPU && !dgpu_device)
dgpu_device = physical_devices[i];
else if (device_properties.deviceType == VK_PHYSICAL_DEVICE_TYPE_INTEGRATED_GPU && !igpu_device)
igpu_device = physical_devices[i];
}
if (!device)
device = dgpu_device ? dgpu_device : igpu_device;
if (!device)
device = physical_devices[0];
vkd3d_free(physical_devices);
VK_CALL(vkGetPhysicalDeviceProperties(device, &device_properties));
TRACE("Using device: %s, %#x:%#x.\n", device_properties.deviceName,
device_properties.vendorID, device_properties.deviceID);
*selected_device = device;
return S_OK;
}
/* Vulkan queues */
enum vkd3d_queue_family
{
VKD3D_QUEUE_FAMILY_DIRECT,
VKD3D_QUEUE_FAMILY_COMPUTE,
VKD3D_QUEUE_FAMILY_TRANSFER,
VKD3D_QUEUE_FAMILY_COUNT,
};
struct vkd3d_device_queue_info
{
unsigned int family_index[VKD3D_QUEUE_FAMILY_COUNT];
VkQueueFamilyProperties vk_properties[VKD3D_QUEUE_FAMILY_COUNT];
unsigned int vk_family_count;
VkDeviceQueueCreateInfo vk_queue_create_info[VKD3D_QUEUE_FAMILY_COUNT];
};
static void d3d12_device_destroy_vkd3d_queues(struct d3d12_device *device)
{
if (device->direct_queue)
vkd3d_queue_destroy(device->direct_queue, device);
if (device->compute_queue && device->compute_queue != device->direct_queue)
vkd3d_queue_destroy(device->compute_queue, device);
if (device->copy_queue && device->copy_queue != device->direct_queue
&& device->copy_queue != device->compute_queue)
vkd3d_queue_destroy(device->copy_queue, device);
device->direct_queue = NULL;
device->compute_queue = NULL;
device->copy_queue = NULL;
}
static HRESULT d3d12_device_create_vkd3d_queues(struct d3d12_device *device,
const struct vkd3d_device_queue_info *queue_info)
{
uint32_t transfer_family_index = queue_info->family_index[VKD3D_QUEUE_FAMILY_TRANSFER];
uint32_t compute_family_index = queue_info->family_index[VKD3D_QUEUE_FAMILY_COMPUTE];
uint32_t direct_family_index = queue_info->family_index[VKD3D_QUEUE_FAMILY_DIRECT];
HRESULT hr;
device->direct_queue = NULL;
device->compute_queue = NULL;
device->copy_queue = NULL;
device->queue_family_count = 0;
memset(device->queue_family_indices, 0, sizeof(device->queue_family_indices));
if (SUCCEEDED((hr = vkd3d_queue_create(device, direct_family_index,
&queue_info->vk_properties[VKD3D_QUEUE_FAMILY_DIRECT], &device->direct_queue))))
device->queue_family_indices[device->queue_family_count++] = direct_family_index;
else
goto out_destroy_queues;
if (compute_family_index == direct_family_index)
device->compute_queue = device->direct_queue;
else if (SUCCEEDED(hr = vkd3d_queue_create(device, compute_family_index,
&queue_info->vk_properties[VKD3D_QUEUE_FAMILY_COMPUTE], &device->compute_queue)))
device->queue_family_indices[device->queue_family_count++] = compute_family_index;
else
goto out_destroy_queues;
if (transfer_family_index == direct_family_index)
device->copy_queue = device->direct_queue;
else if (transfer_family_index == compute_family_index)
device->copy_queue = device->compute_queue;
else if (SUCCEEDED(hr = vkd3d_queue_create(device, transfer_family_index,
&queue_info->vk_properties[VKD3D_QUEUE_FAMILY_TRANSFER], &device->copy_queue)))
device->queue_family_indices[device->queue_family_count++] = transfer_family_index;
else
goto out_destroy_queues;
device->feature_options3.CopyQueueTimestampQueriesSupported = !!device->copy_queue->timestamp_bits;
return S_OK;
out_destroy_queues:
d3d12_device_destroy_vkd3d_queues(device);
return hr;
}
static float queue_priorities[] = {1.0f};
static HRESULT vkd3d_select_queues(const struct vkd3d_instance *vkd3d_instance,
VkPhysicalDevice physical_device, struct vkd3d_device_queue_info *info)
{
const struct vkd3d_vk_instance_procs *vk_procs = &vkd3d_instance->vk_procs;
VkQueueFamilyProperties *queue_properties = NULL;
VkDeviceQueueCreateInfo *queue_info = NULL;
unsigned int i;
uint32_t count;
memset(info, 0, sizeof(*info));
for (i = 0; i < ARRAY_SIZE(info->family_index); ++i)
info->family_index[i] = ~0u;
VK_CALL(vkGetPhysicalDeviceQueueFamilyProperties(physical_device, &count, NULL));
if (!(queue_properties = vkd3d_calloc(count, sizeof(*queue_properties))))
return E_OUTOFMEMORY;
VK_CALL(vkGetPhysicalDeviceQueueFamilyProperties(physical_device, &count, queue_properties));
for (i = 0; i < count; ++i)
{
enum vkd3d_queue_family vkd3d_family = VKD3D_QUEUE_FAMILY_COUNT;
if ((queue_properties[i].queueFlags & (VK_QUEUE_GRAPHICS_BIT | VK_QUEUE_COMPUTE_BIT))
== (VK_QUEUE_GRAPHICS_BIT | VK_QUEUE_COMPUTE_BIT))
{
vkd3d_family = VKD3D_QUEUE_FAMILY_DIRECT;
}
if ((queue_properties[i].queueFlags & (VK_QUEUE_GRAPHICS_BIT | VK_QUEUE_COMPUTE_BIT))
== VK_QUEUE_COMPUTE_BIT)
{
vkd3d_family = VKD3D_QUEUE_FAMILY_COMPUTE;
}
if ((queue_properties[i].queueFlags & ~VK_QUEUE_SPARSE_BINDING_BIT) == VK_QUEUE_TRANSFER_BIT)
{
vkd3d_family = VKD3D_QUEUE_FAMILY_TRANSFER;
}
if (vkd3d_family == VKD3D_QUEUE_FAMILY_COUNT)
continue;
info->family_index[vkd3d_family] = i;
info->vk_properties[vkd3d_family] = queue_properties[i];
queue_info = &info->vk_queue_create_info[vkd3d_family];
queue_info->sType = VK_STRUCTURE_TYPE_DEVICE_QUEUE_CREATE_INFO;
queue_info->pNext = NULL;
queue_info->flags = 0;
queue_info->queueFamilyIndex = i;
queue_info->queueCount = 1; /* FIXME: Use multiple queues. */
queue_info->pQueuePriorities = queue_priorities;
}
vkd3d_free(queue_properties);
if (info->family_index[VKD3D_QUEUE_FAMILY_DIRECT] == ~0u)
{
FIXME("Could not find a suitable queue family for a direct command queue.\n");
return E_FAIL;
}
/* No compute-only queue family, reuse the direct queue family with graphics and compute. */
if (info->family_index[VKD3D_QUEUE_FAMILY_COMPUTE] == ~0u)
{
info->family_index[VKD3D_QUEUE_FAMILY_COMPUTE] = info->family_index[VKD3D_QUEUE_FAMILY_DIRECT];
info->vk_properties[VKD3D_QUEUE_FAMILY_COMPUTE] = info->vk_properties[VKD3D_QUEUE_FAMILY_DIRECT];
}
if (info->family_index[VKD3D_QUEUE_FAMILY_TRANSFER] == ~0u)
{
info->family_index[VKD3D_QUEUE_FAMILY_TRANSFER] = info->family_index[VKD3D_QUEUE_FAMILY_DIRECT];
info->vk_properties[VKD3D_QUEUE_FAMILY_TRANSFER] = info->vk_properties[VKD3D_QUEUE_FAMILY_DIRECT];
}
/* Compact the array. */
info->vk_family_count = 1;
for (i = info->vk_family_count; i < ARRAY_SIZE(info->vk_queue_create_info); ++i)
{
if (info->vk_queue_create_info[i].queueCount)
info->vk_queue_create_info[info->vk_family_count++] = info->vk_queue_create_info[i];
}
return S_OK;
}
/* The 4 MiB alignment requirement for MSAA resources was lowered to 64KB on
* hardware that supports it. This is distinct from the small MSAA requirement
* which applies to resources of a total size of 4 MiB or less. */
static bool d3d12_is_64k_msaa_supported(struct d3d12_device *device)
{
struct vkd3d_resource_allocation_info info;
2024-02-04 20:57:35 -08:00
D3D12_RESOURCE_DESC1 resource_desc;
memset(&resource_desc, 0, sizeof(resource_desc));
resource_desc.Dimension = D3D12_RESOURCE_DIMENSION_TEXTURE2D;
resource_desc.Width = 1024;
resource_desc.Height = 1025;
resource_desc.DepthOrArraySize = 1;
resource_desc.MipLevels = 1;
resource_desc.Format = DXGI_FORMAT_R8G8B8A8_UNORM;
resource_desc.SampleDesc.Count = 4;
resource_desc.Flags = D3D12_RESOURCE_FLAG_ALLOW_RENDER_TARGET;
/* FIXME: in some cases Vulkan requires 0x20000 or more for non-MSAA
* resources, which must have 0x10000 in their description, so we might
* reasonably return true here for 0x20000 or 0x40000. */
return SUCCEEDED(vkd3d_get_image_allocation_info(device, &resource_desc, &info))
&& info.alignment <= 0x10000;
}
static HRESULT vkd3d_create_vk_device(struct d3d12_device *device,
const struct vkd3d_device_create_info *create_info)
{
const struct vkd3d_vk_instance_procs *vk_procs = &device->vkd3d_instance->vk_procs;
const struct vkd3d_optional_device_extensions_info *optional_extensions;
struct vkd3d_physical_device_info physical_device_info;
struct vkd3d_device_queue_info device_queue_info;
bool *user_extension_supported = NULL;
VkPhysicalDevice physical_device;
VkDeviceCreateInfo device_info;
unsigned int device_index;
uint32_t extension_count;
const char **extensions;
VkDevice vk_device;
VkResult vr;
HRESULT hr;
TRACE("device %p, create_info %p.\n", device, create_info);
physical_device = create_info->vk_physical_device;
device_index = vkd3d_env_var_as_uint("VKD3D_VULKAN_DEVICE", ~0u);
if ((!physical_device || device_index != ~0u)
&& FAILED(hr = vkd3d_select_physical_device(device->vkd3d_instance, device_index, &physical_device)))
return hr;
device->vk_physical_device = physical_device;
if (FAILED(hr = vkd3d_select_queues(device->vkd3d_instance, physical_device, &device_queue_info)))
return hr;
TRACE("Using queue family %u for direct command queues.\n",
device_queue_info.family_index[VKD3D_QUEUE_FAMILY_DIRECT]);
TRACE("Using queue family %u for compute command queues.\n",
device_queue_info.family_index[VKD3D_QUEUE_FAMILY_COMPUTE]);
TRACE("Using queue family %u for copy command queues.\n",
device_queue_info.family_index[VKD3D_QUEUE_FAMILY_TRANSFER]);
VK_CALL(vkGetPhysicalDeviceMemoryProperties(physical_device, &device->memory_properties));
if (FAILED(hr = vkd3d_init_device_caps(device, create_info, &physical_device_info,
&extension_count, &user_extension_supported)))
return hr;
if (!(extensions = vkd3d_calloc(extension_count, sizeof(*extensions))))
{
vkd3d_free(user_extension_supported);
return E_OUTOFMEMORY;
}
optional_extensions = vkd3d_find_struct(create_info->next, OPTIONAL_DEVICE_EXTENSIONS_INFO);
/* Create device */
device_info.sType = VK_STRUCTURE_TYPE_DEVICE_CREATE_INFO;
device_info.pNext = physical_device_info.features2.pNext;
device_info.flags = 0;
device_info.queueCreateInfoCount = device_queue_info.vk_family_count;
device_info.pQueueCreateInfos = device_queue_info.vk_queue_create_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,
optional_extensions ? optional_extensions->extensions : NULL,
optional_extensions ? optional_extensions->extension_count : 0,
user_extension_supported, &device->vk_info);
2016-10-13 04:50:36 -07:00
device_info.ppEnabledExtensionNames = extensions;
device_info.pEnabledFeatures = &physical_device_info.features2.features;
vkd3d_free(user_extension_supported);
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);
return hresult_from_vk_result(vr);
}
if (FAILED(hr = vkd3d_load_vk_device_procs(&device->vk_procs, vk_procs, vk_device)))
{
ERR("Failed to load device procs, hr %s.\n", debugstr_hresult(hr));
if (device->vk_procs.vkDestroyDevice)
device->vk_procs.vkDestroyDevice(vk_device, NULL);
return hr;
}
device->vk_device = vk_device;
if (FAILED(hr = d3d12_device_create_vkd3d_queues(device, &device_queue_info)))
{
ERR("Failed to create queues, hr %s.\n", debugstr_hresult(hr));
device->vk_procs.vkDestroyDevice(vk_device, NULL);
return hr;
}
device->feature_options4.MSAA64KBAlignedTextureSupported = d3d12_is_64k_msaa_supported(device);
TRACE("Created Vulkan device %p.\n", vk_device);
return hr;
}
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;
vkd3d_mutex_init(&device->pipeline_cache_mutex);
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));
vkd3d_mutex_destroy(&device->pipeline_cache_mutex);
}
#define VKD3D_VA_FALLBACK_BASE 0x8000000000000000ull
#define VKD3D_VA_SLAB_BASE 0x0000001000000000ull
#define VKD3D_VA_SLAB_SIZE_SHIFT 32
#define VKD3D_VA_SLAB_SIZE (1ull << VKD3D_VA_SLAB_SIZE_SHIFT)
#define VKD3D_VA_SLAB_COUNT (64 * 1024)
static D3D12_GPU_VIRTUAL_ADDRESS vkd3d_gpu_va_allocator_allocate_slab(struct vkd3d_gpu_va_allocator *allocator,
uint64_t aligned_size, void *ptr)
{
struct vkd3d_gpu_va_slab *slab;
D3D12_GPU_VIRTUAL_ADDRESS address;
unsigned slab_idx;
slab = allocator->free_slab;
allocator->free_slab = slab->ptr;
slab->size = aligned_size;
slab->ptr = ptr;
/* It is critical that the multiplication happens in 64-bit to not
* overflow. */
slab_idx = slab - allocator->slabs;
address = VKD3D_VA_SLAB_BASE + slab_idx * VKD3D_VA_SLAB_SIZE;
TRACE("Allocated address %#"PRIx64", slab %u, size %"PRIu64".\n", address, slab_idx, aligned_size);
return address;
}
static D3D12_GPU_VIRTUAL_ADDRESS vkd3d_gpu_va_allocator_allocate_fallback(struct vkd3d_gpu_va_allocator *allocator,
size_t alignment, uint64_t aligned_size, void *ptr)
{
struct vkd3d_gpu_va_allocation *allocation;
D3D12_GPU_VIRTUAL_ADDRESS base, ceiling;
base = allocator->fallback_floor;
ceiling = ~(D3D12_GPU_VIRTUAL_ADDRESS)0;
ceiling -= alignment - 1;
if (aligned_size > ceiling || ceiling - aligned_size < base)
return 0;
base = (base + (alignment - 1)) & ~((D3D12_GPU_VIRTUAL_ADDRESS)alignment - 1);
if (!vkd3d_array_reserve((void **)&allocator->fallback_allocations, &allocator->fallback_allocations_size,
allocator->fallback_allocation_count + 1, sizeof(*allocator->fallback_allocations)))
return 0;
allocation = &allocator->fallback_allocations[allocator->fallback_allocation_count++];
allocation->base = base;
allocation->size = aligned_size;
allocation->ptr = ptr;
/* This pointer is bumped and never lowered on a free. However, this will
* only fail once we have exhausted 63 bits of address space. */
allocator->fallback_floor = base + aligned_size;
TRACE("Allocated address %#"PRIx64", size %"PRIu64".\n", base, aligned_size);
return base;
}
D3D12_GPU_VIRTUAL_ADDRESS vkd3d_gpu_va_allocator_allocate(struct vkd3d_gpu_va_allocator *allocator,
size_t alignment, uint64_t size, void *ptr)
{
D3D12_GPU_VIRTUAL_ADDRESS address;
if (size > ~(uint64_t)0 - (alignment - 1))
return 0;
size = align(size, alignment);
vkd3d_mutex_lock(&allocator->mutex);
if (size <= VKD3D_VA_SLAB_SIZE && allocator->free_slab)
address = vkd3d_gpu_va_allocator_allocate_slab(allocator, size, ptr);
else
address = vkd3d_gpu_va_allocator_allocate_fallback(allocator, alignment, size, ptr);
vkd3d_mutex_unlock(&allocator->mutex);
return address;
}
static void *vkd3d_gpu_va_allocator_dereference_slab(struct vkd3d_gpu_va_allocator *allocator,
D3D12_GPU_VIRTUAL_ADDRESS address)
{
const struct vkd3d_gpu_va_slab *slab;
D3D12_GPU_VIRTUAL_ADDRESS base_offset;
unsigned int slab_idx;
base_offset = address - VKD3D_VA_SLAB_BASE;
slab_idx = base_offset >> VKD3D_VA_SLAB_SIZE_SHIFT;
if (slab_idx >= VKD3D_VA_SLAB_COUNT)
{
ERR("Invalid slab index %u for address %#"PRIx64".\n", slab_idx, address);
return NULL;
}
slab = &allocator->slabs[slab_idx];
base_offset -= slab_idx * VKD3D_VA_SLAB_SIZE;
if (base_offset >= slab->size)
{
ERR("Address %#"PRIx64" is %#"PRIx64" bytes into slab %u of size %"PRIu64".\n",
address, base_offset, slab_idx, slab->size);
return NULL;
}
return slab->ptr;
}
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;
}
static void *vkd3d_gpu_va_allocator_dereference_fallback(struct vkd3d_gpu_va_allocator *allocator,
D3D12_GPU_VIRTUAL_ADDRESS address)
{
struct vkd3d_gpu_va_allocation *allocation;
allocation = bsearch(&address, allocator->fallback_allocations, allocator->fallback_allocation_count,
sizeof(*allocation), vkd3d_gpu_va_allocation_compare);
return allocation ? allocation->ptr : NULL;
}
void *vkd3d_gpu_va_allocator_dereference(struct vkd3d_gpu_va_allocator *allocator,
D3D12_GPU_VIRTUAL_ADDRESS address)
{
void *ret;
/* If we land in the non-fallback region, dereferencing VA is lock-less.
* The base pointer is immutable, and the only way we can have a data race
* is if some other thread is poking into the
* slab_mem_allocation[base_index] block. This can only happen if someone
* is trying to free the entry while we're dereferencing it, which would
* be a serious application bug. */
if (address < VKD3D_VA_FALLBACK_BASE)
return vkd3d_gpu_va_allocator_dereference_slab(allocator, address);
/* Slow fallback. */
vkd3d_mutex_lock(&allocator->mutex);
ret = vkd3d_gpu_va_allocator_dereference_fallback(allocator, address);
vkd3d_mutex_unlock(&allocator->mutex);
return ret;
}
static void vkd3d_gpu_va_allocator_free_slab(struct vkd3d_gpu_va_allocator *allocator,
D3D12_GPU_VIRTUAL_ADDRESS address)
{
D3D12_GPU_VIRTUAL_ADDRESS base_offset;
struct vkd3d_gpu_va_slab *slab;
unsigned int slab_idx;
base_offset = address - VKD3D_VA_SLAB_BASE;
slab_idx = base_offset >> VKD3D_VA_SLAB_SIZE_SHIFT;
if (slab_idx >= VKD3D_VA_SLAB_COUNT)
{
ERR("Invalid slab index %u for address %#"PRIx64".\n", slab_idx, address);
return;
}
TRACE("Freeing address %#"PRIx64", slab %u.\n", address, slab_idx);
slab = &allocator->slabs[slab_idx];
slab->size = 0;
slab->ptr = allocator->free_slab;
allocator->free_slab = slab;
}
static void vkd3d_gpu_va_allocator_free_fallback(struct vkd3d_gpu_va_allocator *allocator,
D3D12_GPU_VIRTUAL_ADDRESS address)
{
struct vkd3d_gpu_va_allocation *allocation;
unsigned int index;
allocation = bsearch(&address, allocator->fallback_allocations, allocator->fallback_allocation_count,
sizeof(*allocation), vkd3d_gpu_va_allocation_compare);
if (!allocation || allocation->base != address)
{
ERR("Address %#"PRIx64" does not match any allocation.\n", address);
return;
}
index = allocation - allocator->fallback_allocations;
--allocator->fallback_allocation_count;
if (index != allocator->fallback_allocation_count)
memmove(&allocator->fallback_allocations[index], &allocator->fallback_allocations[index + 1],
(allocator->fallback_allocation_count - index) * sizeof(*allocation));
}
void vkd3d_gpu_va_allocator_free(struct vkd3d_gpu_va_allocator *allocator, D3D12_GPU_VIRTUAL_ADDRESS address)
{
vkd3d_mutex_lock(&allocator->mutex);
if (address < VKD3D_VA_FALLBACK_BASE)
{
vkd3d_gpu_va_allocator_free_slab(allocator, address);
vkd3d_mutex_unlock(&allocator->mutex);
return;
}
vkd3d_gpu_va_allocator_free_fallback(allocator, address);
vkd3d_mutex_unlock(&allocator->mutex);
}
static bool vkd3d_gpu_va_allocator_init(struct vkd3d_gpu_va_allocator *allocator)
{
unsigned int i;
memset(allocator, 0, sizeof(*allocator));
allocator->fallback_floor = VKD3D_VA_FALLBACK_BASE;
/* To remain lock-less, we cannot grow the slabs array after the fact. If
* we commit to a maximum number of allocations here, we can dereference
* without taking a lock as the base pointer never changes. We would be
* able to grow more seamlessly using an array of pointers, but that would
* make dereferencing slightly less efficient. */
if (!(allocator->slabs = vkd3d_calloc(VKD3D_VA_SLAB_COUNT, sizeof(*allocator->slabs))))
return false;
/* Mark all slabs as free. */
allocator->free_slab = &allocator->slabs[0];
for (i = 0; i < VKD3D_VA_SLAB_COUNT - 1; ++i)
{
allocator->slabs[i].ptr = &allocator->slabs[i + 1];
}
vkd3d_mutex_init(&allocator->mutex);
return true;
}
static void vkd3d_gpu_va_allocator_cleanup(struct vkd3d_gpu_va_allocator *allocator)
{
vkd3d_mutex_lock(&allocator->mutex);
vkd3d_free(allocator->slabs);
vkd3d_free(allocator->fallback_allocations);
vkd3d_mutex_unlock(&allocator->mutex);
vkd3d_mutex_destroy(&allocator->mutex);
}
static bool have_vk_time_domain(VkTimeDomainEXT *domains, unsigned int count, VkTimeDomainEXT domain)
{
unsigned int i;
for (i = 0; i < count; ++i)
if (domains[i] == domain)
return true;
return false;
}
static void vkd3d_time_domains_init(struct d3d12_device *device)
{
static const VkTimeDomainEXT host_time_domains[] =
{
/* In order of preference */
VK_TIME_DOMAIN_CLOCK_MONOTONIC_RAW_EXT,
VK_TIME_DOMAIN_CLOCK_MONOTONIC_EXT,
VK_TIME_DOMAIN_QUERY_PERFORMANCE_COUNTER_EXT,
};
const struct vkd3d_vk_instance_procs *vk_procs = &device->vkd3d_instance->vk_procs;
VkTimeDomainEXT domains[8];
unsigned int i;
uint32_t count;
VkResult vr;
device->vk_host_time_domain = -1;
if (!device->vk_info.EXT_calibrated_timestamps)
return;
count = ARRAY_SIZE(domains);
if ((vr = VK_CALL(vkGetPhysicalDeviceCalibrateableTimeDomainsEXT(device->vk_physical_device,
&count, domains))) != VK_SUCCESS && vr != VK_INCOMPLETE)
{
WARN("Failed to get calibrated time domains, vr %d.\n", vr);
return;
}
if (vr == VK_INCOMPLETE)
FIXME("Calibrated time domain list is incomplete.\n");
if (!have_vk_time_domain(domains, count, VK_TIME_DOMAIN_DEVICE_EXT))
{
WARN("Device time domain not found. Calibrated timestamps will not be available.\n");
return;
}
for (i = 0; i < ARRAY_SIZE(host_time_domains); ++i)
{
if (!have_vk_time_domain(domains, count, host_time_domains[i]))
continue;
device->vk_host_time_domain = host_time_domains[i];
break;
}
if (device->vk_host_time_domain == -1)
WARN("Found no acceptable host time domain. Calibrated timestamps will not be available.\n");
}
static void device_init_descriptor_pool_sizes(struct d3d12_device *device)
{
const struct vkd3d_device_descriptor_limits *limits = &device->vk_info.descriptor_limits;
VkDescriptorPoolSize *pool_sizes = device->vk_pool_sizes;
if (device->use_vk_heaps)
{
pool_sizes[0].type = VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER;
pool_sizes[0].descriptorCount = min(limits->storage_image_max_descriptors,
VKD3D_MAX_UAV_CLEAR_DESCRIPTORS_PER_TYPE);
pool_sizes[1].type = VK_DESCRIPTOR_TYPE_STORAGE_IMAGE;
pool_sizes[1].descriptorCount = pool_sizes[0].descriptorCount;
device->vk_pool_count = 2;
return;
}
assert(ARRAY_SIZE(device->vk_pool_sizes) >= 6);
pool_sizes[0].type = VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER;
pool_sizes[0].descriptorCount = min(limits->uniform_buffer_max_descriptors,
VKD3D_MAX_VIRTUAL_HEAP_DESCRIPTORS_PER_TYPE);
pool_sizes[1].type = VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER;
pool_sizes[1].descriptorCount = min(limits->sampled_image_max_descriptors,
VKD3D_MAX_VIRTUAL_HEAP_DESCRIPTORS_PER_TYPE);
pool_sizes[2].type = VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE;
pool_sizes[2].descriptorCount = pool_sizes[1].descriptorCount;
pool_sizes[3].type = VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER;
pool_sizes[3].descriptorCount = min(limits->storage_image_max_descriptors,
VKD3D_MAX_VIRTUAL_HEAP_DESCRIPTORS_PER_TYPE);
pool_sizes[4].type = VK_DESCRIPTOR_TYPE_STORAGE_IMAGE;
pool_sizes[4].descriptorCount = pool_sizes[3].descriptorCount;
pool_sizes[5].type = VK_DESCRIPTOR_TYPE_SAMPLER;
pool_sizes[5].descriptorCount = min(limits->sampler_max_descriptors,
VKD3D_MAX_VIRTUAL_HEAP_DESCRIPTORS_PER_TYPE);
device->vk_pool_count = 6;
};
static void vkd3d_desc_object_cache_init(struct vkd3d_desc_object_cache *cache, size_t size)
{
memset(cache, 0, sizeof(*cache));
cache->size = size;
}
static void vkd3d_desc_object_cache_cleanup(struct vkd3d_desc_object_cache *cache)
{
union d3d12_desc_object u;
unsigned int i;
void *next;
for (i = 0; i < ARRAY_SIZE(cache->heads); ++i)
{
for (u.object = cache->heads[i].head; u.object; u.object = next)
{
next = u.header->next;
vkd3d_free(u.object);
}
}
}
/* ID3D12ShaderCacheSession */
struct d3d12_cache_session
{
ID3D12ShaderCacheSession ID3D12ShaderCacheSession_iface;
unsigned int refcount;
struct list cache_list_entry;
struct d3d12_device *device;
struct vkd3d_private_store private_store;
D3D12_SHADER_CACHE_SESSION_DESC desc;
struct vkd3d_shader_cache *cache;
};
static struct vkd3d_mutex cache_list_mutex = VKD3D_MUTEX_INITIALIZER;
static struct list cache_list = LIST_INIT(cache_list);
static inline struct d3d12_cache_session *impl_from_ID3D12ShaderCacheSession(ID3D12ShaderCacheSession *iface)
{
return CONTAINING_RECORD(iface, struct d3d12_cache_session, ID3D12ShaderCacheSession_iface);
}
static HRESULT STDMETHODCALLTYPE d3d12_cache_session_QueryInterface(ID3D12ShaderCacheSession *iface,
REFIID iid, void **object)
{
TRACE("iface %p, iid %s, object %p.\n", iface, debugstr_guid(iid), object);
if (!object)
{
WARN("Output pointer is NULL, returning E_POINTER.\n");
return E_POINTER;
}
if (IsEqualGUID(iid, &IID_ID3D12ShaderCacheSession)
|| IsEqualGUID(iid, &IID_ID3D12DeviceChild)
|| IsEqualGUID(iid, &IID_ID3D12Object)
|| IsEqualGUID(iid, &IID_IUnknown))
{
ID3D12ShaderCacheSession_AddRef(iface);
*object = iface;
return S_OK;
}
WARN("%s not implemented, returning E_NOINTERFACE.\n", debugstr_guid(iid));
*object = NULL;
return E_NOINTERFACE;
}
static ULONG STDMETHODCALLTYPE d3d12_cache_session_AddRef(ID3D12ShaderCacheSession *iface)
{
struct d3d12_cache_session *session = impl_from_ID3D12ShaderCacheSession(iface);
unsigned int refcount = vkd3d_atomic_increment_u32(&session->refcount);
TRACE("%p increasing refcount to %u.\n", session, refcount);
return refcount;
}
static void d3d12_cache_session_destroy(struct d3d12_cache_session *session)
{
struct d3d12_device *device = session->device;
TRACE("Destroying cache session %p.\n", session);
vkd3d_mutex_lock(&cache_list_mutex);
list_remove(&session->cache_list_entry);
vkd3d_mutex_unlock(&cache_list_mutex);
vkd3d_shader_cache_decref(session->cache);
vkd3d_private_store_destroy(&session->private_store);
vkd3d_free(session);
d3d12_device_release(device);
}
static ULONG STDMETHODCALLTYPE d3d12_cache_session_Release(ID3D12ShaderCacheSession *iface)
{
struct d3d12_cache_session *session = impl_from_ID3D12ShaderCacheSession(iface);
unsigned int refcount = vkd3d_atomic_decrement_u32(&session->refcount);
TRACE("%p decreasing refcount to %u.\n", session, refcount);
if (!refcount)
d3d12_cache_session_destroy(session);
return refcount;
}
static HRESULT STDMETHODCALLTYPE d3d12_cache_session_GetPrivateData(ID3D12ShaderCacheSession *iface,
REFGUID guid, UINT *data_size, void *data)
{
struct d3d12_cache_session *session = impl_from_ID3D12ShaderCacheSession(iface);
TRACE("iface %p, guid %s, data_size %p, data %p.\n", iface, debugstr_guid(guid), data_size, data);
return vkd3d_get_private_data(&session->private_store, guid, data_size, data);
}
static HRESULT STDMETHODCALLTYPE d3d12_cache_session_SetPrivateData(ID3D12ShaderCacheSession *iface,
REFGUID guid, UINT data_size, const void *data)
{
struct d3d12_cache_session *session = impl_from_ID3D12ShaderCacheSession(iface);
TRACE("iface %p, guid %s, data_size %u, data %p.\n", iface, debugstr_guid(guid), data_size, data);
return vkd3d_set_private_data(&session->private_store, guid, data_size, data);
}
static HRESULT STDMETHODCALLTYPE d3d12_cache_session_SetPrivateDataInterface(
ID3D12ShaderCacheSession *iface, REFGUID guid, const IUnknown *data)
{
struct d3d12_cache_session *session = impl_from_ID3D12ShaderCacheSession(iface);
TRACE("iface %p, guid %s, data %p.\n", iface, debugstr_guid(guid), data);
return vkd3d_set_private_data_interface(&session->private_store, guid, data);
}
static HRESULT STDMETHODCALLTYPE d3d12_cache_session_SetName(ID3D12ShaderCacheSession *iface,
const WCHAR *name)
{
struct d3d12_cache_session *session = impl_from_ID3D12ShaderCacheSession(iface);
TRACE("iface %p, name %s.\n", iface, debugstr_w(name, session->device->wchar_size));
return name ? S_OK : E_INVALIDARG;
}
static HRESULT STDMETHODCALLTYPE d3d12_cache_session_GetDevice(ID3D12ShaderCacheSession *iface,
REFIID iid, void **device)
{
struct d3d12_cache_session *session = impl_from_ID3D12ShaderCacheSession(iface);
TRACE("iface %p, iid %s, device %p.\n", iface, debugstr_guid(iid), device);
return d3d12_device_query_interface(session->device, iid, device);
}
static HRESULT STDMETHODCALLTYPE d3d12_cache_session_FindValue(ID3D12ShaderCacheSession *iface,
const void *key, UINT key_size, void *value, UINT *value_size)
{
struct d3d12_cache_session *session = impl_from_ID3D12ShaderCacheSession(iface);
enum vkd3d_result ret;
size_t size;
TRACE("iface %p, key %p, key_size %#x, value %p, value_size %p.\n",
iface, key, key_size, value, value_size);
if (!value_size)
{
WARN("value_size is NULL, returning E_INVALIDARG.\n");
return E_INVALIDARG;
}
size = *value_size;
ret = vkd3d_shader_cache_get(session->cache, key, key_size, value, &size);
*value_size = size;
return hresult_from_vkd3d_result(ret);
}
static HRESULT STDMETHODCALLTYPE d3d12_cache_session_StoreValue(ID3D12ShaderCacheSession *iface,
const void *key, UINT key_size, const void *value, UINT value_size)
{
struct d3d12_cache_session *session = impl_from_ID3D12ShaderCacheSession(iface);
enum vkd3d_result ret;
TRACE("iface %p, key %p, key_size %#x, value %p, value_size %u.\n",
iface, key, key_size, value, value_size);
if (!key || !key_size || !value || !value_size)
{
WARN("Invalid input parameters, returning E_INVALIDARG.\n");
return E_INVALIDARG;
}
ret = vkd3d_shader_cache_put(session->cache, key, key_size, value, value_size);
return hresult_from_vkd3d_result(ret);
}
static void STDMETHODCALLTYPE d3d12_cache_session_SetDeleteOnDestroy(ID3D12ShaderCacheSession *iface)
{
FIXME("iface %p stub!\n", iface);
}
static D3D12_SHADER_CACHE_SESSION_DESC * STDMETHODCALLTYPE d3d12_cache_session_GetDesc(
ID3D12ShaderCacheSession *iface, D3D12_SHADER_CACHE_SESSION_DESC *desc)
{
struct d3d12_cache_session *session = impl_from_ID3D12ShaderCacheSession(iface);
TRACE("iface %p.\n", iface);
*desc = session->desc;
return desc;
}
static const struct ID3D12ShaderCacheSessionVtbl d3d12_cache_session_vtbl =
{
/* IUnknown methods */
d3d12_cache_session_QueryInterface,
d3d12_cache_session_AddRef,
d3d12_cache_session_Release,
/* ID3D12Object methods */
d3d12_cache_session_GetPrivateData,
d3d12_cache_session_SetPrivateData,
d3d12_cache_session_SetPrivateDataInterface,
d3d12_cache_session_SetName,
/* ID3D12DeviceChild methods */
d3d12_cache_session_GetDevice,
/* ID3D12ShaderCacheSession methods */
d3d12_cache_session_FindValue,
d3d12_cache_session_StoreValue,
d3d12_cache_session_SetDeleteOnDestroy,
d3d12_cache_session_GetDesc,
};
static HRESULT d3d12_cache_session_init(struct d3d12_cache_session *session,
struct d3d12_device *device, const D3D12_SHADER_CACHE_SESSION_DESC *desc)
{
struct d3d12_cache_session *i;
enum vkd3d_result ret;
HRESULT hr;
session->ID3D12ShaderCacheSession_iface.lpVtbl = &d3d12_cache_session_vtbl;
session->refcount = 1;
session->desc = *desc;
session->cache = NULL;
if (!session->desc.MaximumValueFileSizeBytes)
session->desc.MaximumValueFileSizeBytes = 128 * 1024 * 1024;
if (!session->desc.MaximumInMemoryCacheSizeBytes)
session->desc.MaximumInMemoryCacheSizeBytes = 1024 * 1024;
if (!session->desc.MaximumInMemoryCacheEntries)
session->desc.MaximumInMemoryCacheEntries = 128;
if (FAILED(hr = vkd3d_private_store_init(&session->private_store)))
return hr;
vkd3d_mutex_lock(&cache_list_mutex);
/* We expect the number of open caches to be small. */
LIST_FOR_EACH_ENTRY(i, &cache_list, struct d3d12_cache_session, cache_list_entry)
{
if (!memcmp(&i->desc.Identifier, &desc->Identifier, sizeof(desc->Identifier)))
{
TRACE("Found an existing cache %p from session %p.\n", i->cache, i);
if (desc->Version == i->desc.Version)
{
session->desc = i->desc;
vkd3d_shader_cache_incref(session->cache = i->cache);
break;
}
else
{
WARN("version mismatch: Existing %"PRIu64" new %"PRIu64".\n",
i->desc.Version, desc->Version);
hr = DXGI_ERROR_ALREADY_EXISTS;
goto error;
}
}
}
if (!session->cache)
{
if (session->desc.Mode == D3D12_SHADER_CACHE_MODE_DISK)
FIXME("Disk caches are not yet implemented.\n");
ret = vkd3d_shader_open_cache(&session->cache);
if (ret)
{
WARN("Failed to open shader cache.\n");
hr = hresult_from_vkd3d_result(ret);
goto error;
}
}
/* Add it to the list even if we reused an existing cache. The other session might be destroyed,
* but the cache stays alive and can be opened a third time. */
list_add_tail(&cache_list, &session->cache_list_entry);
d3d12_device_add_ref(session->device = device);
vkd3d_mutex_unlock(&cache_list_mutex);
return S_OK;
error:
vkd3d_private_store_destroy(&session->private_store);
vkd3d_mutex_unlock(&cache_list_mutex);
return hr;
}
/* ID3D12Device */
static inline struct d3d12_device *impl_from_ID3D12Device9(ID3D12Device9 *iface)
{
return CONTAINING_RECORD(iface, struct d3d12_device, ID3D12Device9_iface);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_QueryInterface(ID3D12Device9 *iface,
REFIID riid, void **object)
{
TRACE("iface %p, riid %s, object %p.\n", iface, debugstr_guid(riid), object);
if (IsEqualGUID(riid, &IID_ID3D12Device9)
|| IsEqualGUID(riid, &IID_ID3D12Device8)
|| IsEqualGUID(riid, &IID_ID3D12Device7)
|| IsEqualGUID(riid, &IID_ID3D12Device6)
|| IsEqualGUID(riid, &IID_ID3D12Device5)
|| IsEqualGUID(riid, &IID_ID3D12Device4)
|| IsEqualGUID(riid, &IID_ID3D12Device3)
|| IsEqualGUID(riid, &IID_ID3D12Device2)
2023-08-25 03:55:07 -07:00
|| IsEqualGUID(riid, &IID_ID3D12Device1)
|| IsEqualGUID(riid, &IID_ID3D12Device)
|| IsEqualGUID(riid, &IID_ID3D12Object)
|| IsEqualGUID(riid, &IID_IUnknown))
{
2024-04-18 11:00:46 -07:00
ID3D12Device9_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(ID3D12Device9 *iface)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
unsigned int refcount = vkd3d_atomic_increment_u32(&device->refcount);
TRACE("%p increasing refcount to %u.\n", device, refcount);
return refcount;
}
static HRESULT device_worker_stop(struct d3d12_device *device)
{
HRESULT hr;
TRACE("device %p.\n", device);
vkd3d_mutex_lock(&device->worker_mutex);
device->worker_should_exit = true;
vkd3d_cond_signal(&device->worker_cond);
vkd3d_mutex_unlock(&device->worker_mutex);
if (FAILED(hr = vkd3d_join_thread(device->vkd3d_instance, &device->worker_thread)))
return hr;
vkd3d_mutex_destroy(&device->worker_mutex);
vkd3d_cond_destroy(&device->worker_cond);
return S_OK;
}
static ULONG STDMETHODCALLTYPE d3d12_device_Release(ID3D12Device9 *iface)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
unsigned int refcount = vkd3d_atomic_decrement_u32(&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_mutex_destroy(&device->blocked_queues_mutex);
vkd3d_private_store_destroy(&device->private_store);
vkd3d_cleanup_format_info(device);
vkd3d: Back descriptor heaps with Vulkan descriptor sets if descriptor indexing is available. The existing implementation using virtual descriptor heaps, where Vk descriptor sets are created for the bindings in the root descriptor tables, is inefficient when multiple command lists are used with large descriptor heaps. It also cannot support updating a descriptor set after it is bound. This patch creates Vk sets for each D3D12 heap. Because D3D12 heaps can contain CBV, SRV and UAV descriptors in the same heap, multiple Vk sets are needed for each heap, however the total number of populated descriptors is never more than (heap size + UAV counter count). A new 'virtual_heaps' config option is introduced to make the old implementation available when needed. It's not always possible to determine if this is necessary when the device is created. Up to nine Vk descriptor sets may be used. It's theoretically possible to reduce this to eight by placing immutable samplers in the push descriptor set layout, but contradictions in earlier versions of the Vulkan spec made driver support inconsistent. The documentation was corrected in version 1.2.203. This patch also adds support for UAV counter descriptor arrays. It's not practical to add this in a separate patch due to complications with combining the old UAV counter implementation with the new descriptor heap implementation. Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47713 Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47154 Signed-off-by: Conor McCarthy <cmccarthy@codeweavers.com> Signed-off-by: Henri Verbeet <hverbeet@codeweavers.com> Signed-off-by: Alexandre Julliard <julliard@winehq.org>
2022-02-21 07:18:59 -08:00
vkd3d_vk_descriptor_heap_layouts_cleanup(device);
vkd3d_uav_clear_state_cleanup(&device->uav_clear_state, device);
vkd3d_destroy_null_resources(&device->null_resources, device);
vkd3d_gpu_va_allocator_cleanup(&device->gpu_va_allocator);
vkd3d_render_pass_cache_cleanup(&device->render_pass_cache, device);
d3d12_device_destroy_pipeline_cache(device);
d3d12_device_destroy_vkd3d_queues(device);
vkd3d_desc_object_cache_cleanup(&device->view_desc_cache);
vkd3d_desc_object_cache_cleanup(&device->cbuffer_desc_cache);
if (device->use_vk_heaps)
device_worker_stop(device);
vkd3d_free(device->heaps);
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(ID3D12Device9 *iface,
REFGUID guid, UINT *data_size, void *data)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
TRACE("iface %p, guid %s, data_size %p, data %p.\n",
iface, debugstr_guid(guid), data_size, data);
return vkd3d_get_private_data(&device->private_store, guid, data_size, data);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_SetPrivateData(ID3D12Device9 *iface,
REFGUID guid, UINT data_size, const void *data)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
TRACE("iface %p, guid %s, data_size %u, data %p.\n",
iface, debugstr_guid(guid), data_size, data);
return vkd3d_set_private_data(&device->private_store, guid, data_size, data);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_SetPrivateDataInterface(ID3D12Device9 *iface,
REFGUID guid, const IUnknown *data)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
TRACE("iface %p, guid %s, data %p.\n", iface, debugstr_guid(guid), data);
return vkd3d_set_private_data_interface(&device->private_store, guid, data);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_SetName(ID3D12Device9 *iface, const WCHAR *name)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
TRACE("iface %p, name %s.\n", iface, debugstr_w(name, device->wchar_size));
return vkd3d_set_vk_object_name(device, (uint64_t)(uintptr_t)device->vk_device,
VK_DEBUG_REPORT_OBJECT_TYPE_DEVICE_EXT, name);
}
static UINT STDMETHODCALLTYPE d3d12_device_GetNodeCount(ID3D12Device9 *iface)
{
TRACE("iface %p.\n", iface);
return 1;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateCommandQueue(ID3D12Device9 *iface,
const D3D12_COMMAND_QUEUE_DESC *desc, REFIID riid, void **command_queue)
{
struct d3d12_device *device = impl_from_ID3D12Device9(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(ID3D12Device9 *iface,
D3D12_COMMAND_LIST_TYPE type, REFIID riid, void **command_allocator)
{
struct d3d12_device *device = impl_from_ID3D12Device9(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(ID3D12Device9 *iface,
const D3D12_GRAPHICS_PIPELINE_STATE_DESC *desc, REFIID riid, void **pipeline_state)
{
struct d3d12_device *device = impl_from_ID3D12Device9(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(ID3D12Device9 *iface,
const D3D12_COMPUTE_PIPELINE_STATE_DESC *desc, REFIID riid, void **pipeline_state)
{
struct d3d12_device *device = impl_from_ID3D12Device9(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(ID3D12Device9 *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_ID3D12Device9(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->ID3D12GraphicsCommandList5_iface,
&IID_ID3D12GraphicsCommandList5, 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 d3d12_device_check_multisample_quality_levels(struct d3d12_device *device,
D3D12_FEATURE_DATA_MULTISAMPLE_QUALITY_LEVELS *data)
{
const struct vkd3d_vk_device_procs *vk_procs = &device->vk_procs;
VkImageFormatProperties vk_properties;
const struct vkd3d_format *format;
VkSampleCountFlagBits vk_samples;
VkImageUsageFlags vk_usage = 0;
VkResult vr;
TRACE("Format %#x, sample count %u, flags %#x.\n", data->Format, data->SampleCount, data->Flags);
data->NumQualityLevels = 0;
if (!(vk_samples = vk_samples_from_sample_count(data->SampleCount)))
WARN("Invalid sample count %u.\n", data->SampleCount);
if (!data->SampleCount)
return E_FAIL;
if (data->SampleCount == 1)
{
data->NumQualityLevels = 1;
goto done;
}
if (data->Format == DXGI_FORMAT_UNKNOWN)
goto done;
if (!(format = vkd3d_get_format(device, data->Format, false)))
format = vkd3d_get_format(device, data->Format, true);
if (!format)
{
FIXME("Unhandled format %#x.\n", data->Format);
return E_INVALIDARG;
}
if (data->Flags)
FIXME("Ignoring flags %#x.\n", data->Flags);
if (format->vk_aspect_mask & VK_IMAGE_ASPECT_COLOR_BIT)
vk_usage |= VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT;
else
vk_usage |= VK_IMAGE_USAGE_DEPTH_STENCIL_ATTACHMENT_BIT;
vr = VK_CALL(vkGetPhysicalDeviceImageFormatProperties(device->vk_physical_device,
format->vk_format, VK_IMAGE_TYPE_2D, VK_IMAGE_TILING_OPTIMAL, vk_usage, 0, &vk_properties));
if (vr == VK_ERROR_FORMAT_NOT_SUPPORTED)
{
WARN("Format %#x is not supported.\n", format->dxgi_format);
goto done;
}
if (vr < 0)
{
ERR("Failed to get image format properties, vr %d.\n", vr);
return hresult_from_vk_result(vr);
}
if (vk_properties.sampleCounts & vk_samples)
data->NumQualityLevels = 1;
done:
TRACE("Returning %u quality levels.\n", data->NumQualityLevels);
return S_OK;
}
bool d3d12_device_is_uma(struct d3d12_device *device, bool *coherent)
{
unsigned int i;
if (coherent)
*coherent = true;
for (i = 0; i < device->memory_properties.memoryTypeCount; ++i)
{
if (!(device->memory_properties.memoryTypes[i].propertyFlags & VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT))
return false;
if (coherent && !(device->memory_properties.memoryTypes[i].propertyFlags
& VK_MEMORY_PROPERTY_HOST_COHERENT_BIT))
*coherent = false;
}
return true;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CheckFeatureSupport(ID3D12Device9 *iface,
D3D12_FEATURE feature, void *feature_data, UINT feature_data_size)
{
struct d3d12_device *device = impl_from_ID3D12Device9(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;
TRACE("Double precision shader ops %#x.\n", data->DoublePrecisionFloatShaderOps);
TRACE("Output merger logic op %#x.\n", data->OutputMergerLogicOp);
TRACE("Shader min precision support %#x.\n", data->MinPrecisionSupport);
TRACE("Tiled resources tier %#x.\n", data->TiledResourcesTier);
TRACE("Resource binding tier %#x.\n", data->ResourceBindingTier);
TRACE("PS specified stencil ref %#x.\n", data->PSSpecifiedStencilRefSupported);
TRACE("Typed UAV load and additional formats %#x.\n", data->TypedUAVLoadAdditionalFormats);
TRACE("ROV %#x.\n", data->ROVsSupported);
TRACE("Conservative rasterization tier %#x.\n", data->ConservativeRasterizationTier);
TRACE("Max GPU virtual address bits per resource %u.\n", data->MaxGPUVirtualAddressBitsPerResource);
TRACE("Standard swizzle 64KB %#x.\n", data->StandardSwizzle64KBSupported);
TRACE("Cross-node sharing tier %#x.\n", data->CrossNodeSharingTier);
TRACE("Cross-adapter row-major texture %#x.\n", data->CrossAdapterRowMajorTextureSupported);
TRACE("VP and RT array index from any shader without GS emulation %#x.\n",
data->VPAndRTArrayIndexFromAnyShaderFeedingRasterizerSupportedWithoutGSEmulation);
TRACE("Resource heap tier %#x.\n", data->ResourceHeapTier);
return S_OK;
}
case D3D12_FEATURE_ARCHITECTURE:
{
D3D12_FEATURE_DATA_ARCHITECTURE *data = feature_data;
bool coherent;
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;
}
WARN("Assuming device does not support tile based rendering.\n");
data->TileBasedRenderer = FALSE;
data->UMA = d3d12_device_is_uma(device, &coherent);
data->CacheCoherentUMA = data->UMA && coherent;
TRACE("Tile based renderer %#x, UMA %#x, cache coherent UMA %#x.\n",
data->TileBasedRenderer, data->UMA, data->CacheCoherentUMA);
return S_OK;
}
case D3D12_FEATURE_FEATURE_LEVELS:
{
struct vkd3d_vulkan_info *vulkan_info = &device->vk_info;
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 && fl <= vulkan_info->max_feature_level)
data->MaxSupportedFeatureLevel = fl;
}
TRACE("Max supported feature level %#x.\n", data->MaxSupportedFeatureLevel);
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(device, data->Format, false)))
format = vkd3d_get_format(device, data->Format, true);
if (!format)
{
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 (device->vk_info.uav_read_without_format)
data->Support2 |= D3D12_FORMAT_SUPPORT2_UAV_TYPED_LOAD;
/* We effectively require shaderStorageImageWriteWithoutFormat,
* so we can just report UAV_TYPED_STORE unconditionally. */
data->Support2 |= D3D12_FORMAT_SUPPORT2_UAV_TYPED_STORE;
}
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);
TRACE("Format %#x, support1 %#x, support2 %#x.\n", data->Format, data->Support1, data->Support2);
return S_OK;
}
case D3D12_FEATURE_MULTISAMPLE_QUALITY_LEVELS:
{
D3D12_FEATURE_DATA_MULTISAMPLE_QUALITY_LEVELS *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
return d3d12_device_check_multisample_quality_levels(device, data);
}
case D3D12_FEATURE_FORMAT_INFO:
{
D3D12_FEATURE_DATA_FORMAT_INFO *data = feature_data;
const struct vkd3d_format *format;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
if (data->Format == DXGI_FORMAT_UNKNOWN)
{
data->PlaneCount = 1;
return S_OK;
}
if (!(format = vkd3d_get_format(device, data->Format, false)))
format = vkd3d_get_format(device, data->Format, true);
if (!format)
{
FIXME("Unhandled format %#x.\n", data->Format);
return E_INVALIDARG;
}
data->PlaneCount = format->plane_count;
TRACE("Format %#x, plane count %"PRIu8".\n", data->Format, data->PlaneCount);
return S_OK;
}
case D3D12_FEATURE_GPU_VIRTUAL_ADDRESS_SUPPORT:
{
const D3D12_FEATURE_DATA_D3D12_OPTIONS *options = &device->feature_options;
D3D12_FEATURE_DATA_GPU_VIRTUAL_ADDRESS_SUPPORT *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
data->MaxGPUVirtualAddressBitsPerResource = options->MaxGPUVirtualAddressBitsPerResource;
data->MaxGPUVirtualAddressBitsPerProcess = options->MaxGPUVirtualAddressBitsPerResource;
TRACE("Max GPU virtual address bits per resource %u, Max GPU virtual address bits per process %u.\n",
data->MaxGPUVirtualAddressBitsPerResource, data->MaxGPUVirtualAddressBitsPerProcess);
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;
}
if (data->HighestShaderModel != D3D_SHADER_MODEL_5_1
&& (data->HighestShaderModel < D3D_SHADER_MODEL_6_0
|| data->HighestShaderModel > D3D_HIGHEST_SHADER_MODEL))
{
WARN("Unknown shader model %#x.\n", data->HighestShaderModel);
return E_INVALIDARG;
}
TRACE("Request shader model %#x.\n", data->HighestShaderModel);
#ifdef VKD3D_SHADER_UNSUPPORTED_DXIL
data->HighestShaderModel = min(data->HighestShaderModel, D3D_SHADER_MODEL_6_0);
#else
data->HighestShaderModel = min(data->HighestShaderModel, D3D_SHADER_MODEL_5_1);
#endif
TRACE("Shader model %#x.\n", data->HighestShaderModel);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS1:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS1 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
*data = device->feature_options1;
TRACE("Wave ops %#x.\n", data->WaveOps);
TRACE("Min wave lane count %#x.\n", data->WaveLaneCountMin);
TRACE("Max wave lane count %#x.\n", data->WaveLaneCountMax);
TRACE("Total lane count %#x.\n", data->TotalLaneCount);
TRACE("Expanded compute resource states %#x.\n", data->ExpandedComputeResourceStates);
TRACE("Int64 shader ops %#x.\n", data->Int64ShaderOps);
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;
}
TRACE("Root signature requested %#x.\n", data->HighestVersion);
data->HighestVersion = min(data->HighestVersion, D3D_ROOT_SIGNATURE_VERSION_1_1);
if (device->vkd3d_instance->api_version < VKD3D_API_VERSION_1_2)
data->HighestVersion = min(data->HighestVersion, D3D_ROOT_SIGNATURE_VERSION_1_0);
TRACE("Root signature version %#x.\n", data->HighestVersion);
return S_OK;
}
case D3D12_FEATURE_ARCHITECTURE1:
{
D3D12_FEATURE_DATA_ARCHITECTURE1 *data = feature_data;
bool coherent;
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;
}
WARN("Assuming device does not support tile based rendering.\n");
data->TileBasedRenderer = FALSE;
data->UMA = d3d12_device_is_uma(device, &coherent);
data->CacheCoherentUMA = data->UMA && coherent;
WARN("Assuming device does not have an isolated memory management unit.\n");
data->IsolatedMMU = FALSE;
TRACE("Tile based renderer %#x, UMA %#x, cache coherent UMA %#x, isolated MMU %#x.\n",
data->TileBasedRenderer, data->UMA, data->CacheCoherentUMA, data->IsolatedMMU);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS2:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS2 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
*data = device->feature_options2;
TRACE("Depth bounds test %#x.\n", data->DepthBoundsTestSupported);
TRACE("Programmable sample positions tier %#x.\n", data->ProgrammableSamplePositionsTier);
return S_OK;
}
case D3D12_FEATURE_SHADER_CACHE:
{
D3D12_FEATURE_DATA_SHADER_CACHE *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
/* FIXME: The d3d12 documentation states that
* D3D12_SHADER_CACHE_SUPPORT_SINGLE_PSO is always supported, but
* the CachedPSO field of D3D12_GRAPHICS_PIPELINE_STATE_DESC is
* ignored and GetCachedBlob() is a stub. */
data->SupportFlags = D3D12_SHADER_CACHE_SUPPORT_NONE;
TRACE("Shader cache support %#x.\n", data->SupportFlags);
return S_OK;
}
case D3D12_FEATURE_COMMAND_QUEUE_PRIORITY:
{
D3D12_FEATURE_DATA_COMMAND_QUEUE_PRIORITY *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
switch (data->CommandListType)
{
case D3D12_COMMAND_LIST_TYPE_DIRECT:
case D3D12_COMMAND_LIST_TYPE_COMPUTE:
case D3D12_COMMAND_LIST_TYPE_COPY:
data->PriorityForTypeIsSupported = FALSE;
TRACE("Command list type %#x, priority %u, supported %#x.\n",
data->CommandListType, data->Priority, data->PriorityForTypeIsSupported);
return S_OK;
default:
FIXME("Unhandled command list type %#x.\n", data->CommandListType);
return E_INVALIDARG;
}
}
case D3D12_FEATURE_D3D12_OPTIONS3:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS3 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
*data = device->feature_options3;
TRACE("Copy queue timestamp queries %#x.\n", data->CopyQueueTimestampQueriesSupported);
TRACE("Casting fully typed format %#x.\n", data->CastingFullyTypedFormatSupported);
TRACE("Write buffer immediate %#x.\n", data->WriteBufferImmediateSupportFlags);
TRACE("View instancing tier %#x.\n", data->ViewInstancingTier);
TRACE("Barycentrics %#x.\n", data->BarycentricsSupported);
return S_OK;
}
case D3D12_FEATURE_EXISTING_HEAPS:
{
D3D12_FEATURE_DATA_EXISTING_HEAPS *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
data->Supported = FALSE;
TRACE("Existing heaps %#x.\n", data->Supported);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS4:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS4 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
*data = device->feature_options4;
TRACE("64 KiB aligned MSAA textures %#x.\n", data->MSAA64KBAlignedTextureSupported);
TRACE("Shared resource compatibility tier %#x.\n", data->SharedResourceCompatibilityTier);
TRACE("Native 16-bit shader ops %#x.\n", data->Native16BitShaderOpsSupported);
return S_OK;
}
case D3D12_FEATURE_SERIALIZATION:
{
D3D12_FEATURE_DATA_SERIALIZATION *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;
}
data->HeapSerializationTier = D3D12_HEAP_SERIALIZATION_TIER_0;
TRACE("Heap serialisation tier %#x.\n", data->HeapSerializationTier);
return S_OK;
}
case D3D12_FEATURE_CROSS_NODE:
{
D3D12_FEATURE_DATA_CROSS_NODE *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
data->SharingTier = device->feature_options.CrossNodeSharingTier;
data->AtomicShaderInstructions = FALSE;
TRACE("Cross node sharing tier %#x.\n", data->SharingTier);
TRACE("Cross node shader atomics %#x.\n", data->AtomicShaderInstructions);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS5:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS5 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
*data = device->feature_options5;
TRACE("SRV tiled resource tier 3 only %#x.\n", data->SRVOnlyTiledResourceTier3);
TRACE("Render pass tier %#x.\n", data->RenderPassesTier);
TRACE("Ray tracing tier %#x.\n", data->RaytracingTier);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS6:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS6 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
data->AdditionalShadingRatesSupported = FALSE;
data->PerPrimitiveShadingRateSupportedWithViewportIndexing = FALSE;
data->VariableShadingRateTier = D3D12_VARIABLE_SHADING_RATE_TIER_NOT_SUPPORTED;
data->ShadingRateImageTileSize = 0;
data->BackgroundProcessingSupported = FALSE;
TRACE("Additional shading rates support %#x.\n", data->AdditionalShadingRatesSupported);
TRACE("Per-primitive shading rates with viewport indexing %#x.\n",
data->PerPrimitiveShadingRateSupportedWithViewportIndexing);
TRACE("Variable shading rate tier %#x.\n", data->VariableShadingRateTier);
TRACE("Shading rate image tile size %#x.\n", data->ShadingRateImageTileSize);
TRACE("Background processing support %#x.\n", data->BackgroundProcessingSupported);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS7:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS7 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
data->MeshShaderTier = D3D12_MESH_SHADER_TIER_NOT_SUPPORTED;
data->SamplerFeedbackTier = D3D12_SAMPLER_FEEDBACK_TIER_NOT_SUPPORTED;
TRACE("Mesh shading tier %#x.\n", data->MeshShaderTier);
TRACE("Sampler feedback tier %#x.\n", data->SamplerFeedbackTier);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS8:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS8 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
/* Vulkan does not restrict block texture alignment. */
data->UnalignedBlockTexturesSupported = TRUE;
TRACE("Unaligned block texture support %#x.\n", data->UnalignedBlockTexturesSupported);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS9:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS9 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
data->MeshShaderPipelineStatsSupported = FALSE;
data->MeshShaderSupportsFullRangeRenderTargetArrayIndex = FALSE;
data->AtomicInt64OnTypedResourceSupported = FALSE;
data->AtomicInt64OnGroupSharedSupported = FALSE;
data->DerivativesInMeshAndAmplificationShadersSupported = FALSE;
data->WaveMMATier = D3D12_WAVE_MMA_TIER_NOT_SUPPORTED;
TRACE("Mesh shader pipeline stats support %#x.\n", data->MeshShaderPipelineStatsSupported);
TRACE("Mesh shader RT array index full range %#x.\n", data->MeshShaderSupportsFullRangeRenderTargetArrayIndex);
TRACE("Atomic int64 on typed resource %#x.\n", data->AtomicInt64OnTypedResourceSupported);
TRACE("Atomic int64 on group shared mem %#x.\n", data->AtomicInt64OnGroupSharedSupported);
TRACE("Derivatives in mesh and amp shaders %#x.\n", data->DerivativesInMeshAndAmplificationShadersSupported);
TRACE("Wave MMA tier %#x.\n", data->WaveMMATier);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS10:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS10 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
data->VariableRateShadingSumCombinerSupported = FALSE;
data->MeshShaderPerPrimitiveShadingRateSupported = FALSE;
TRACE("Variable rate shading sum combiner %#x.\n", data->VariableRateShadingSumCombinerSupported);
TRACE("Mesh shader per primitive shading rate %#x.\n", data->MeshShaderPerPrimitiveShadingRateSupported);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS11:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS11 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
data->AtomicInt64OnDescriptorHeapResourceSupported = FALSE;
TRACE("Atomic int64 on descriptor heap resource %#x.\n", data->AtomicInt64OnDescriptorHeapResourceSupported);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS12:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS12 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
data->MSPrimitivesPipelineStatisticIncludesCulledPrimitives = D3D12_TRI_STATE_UNKNOWN;
data->EnhancedBarriersSupported = FALSE;
data->RelaxedFormatCastingSupported = FALSE;
TRACE("Mesh shader primitives pipeline stats include cull primitives %#x.\n",
data->MSPrimitivesPipelineStatisticIncludesCulledPrimitives);
TRACE("Enhanced barriers %#x.\n", data->EnhancedBarriersSupported);
TRACE("Relaxed format casting %#x.\n", data->RelaxedFormatCastingSupported);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS13:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS13 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
return E_INVALIDARG;
}
data->UnrestrictedBufferTextureCopyPitchSupported = FALSE;
data->UnrestrictedVertexElementAlignmentSupported = FALSE;
data->InvertedViewportHeightFlipsYSupported = FALSE;
data->InvertedViewportDepthFlipsZSupported = FALSE;
data->TextureCopyBetweenDimensionsSupported = FALSE;
data->AlphaBlendFactorSupported = FALSE;
TRACE("Unrestricted buffer-texture copy pitch %#x.\n", data->UnrestrictedBufferTextureCopyPitchSupported);
TRACE("Unrestricted vertex element alignment %#x.\n", data->UnrestrictedVertexElementAlignmentSupported);
TRACE("Inverted viewport height flips Y %#x.\n", data->InvertedViewportHeightFlipsYSupported);
TRACE("Inverted viewport depth flips Z %#x.\n", data->InvertedViewportDepthFlipsZSupported);
TRACE("Texture copy between dimensions %#x.\n", data->TextureCopyBetweenDimensionsSupported);
TRACE("Alpha blend factor support %#x.\n", data->AlphaBlendFactorSupported);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS14:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS14 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
}
data->AdvancedTextureOpsSupported = FALSE;
data->WriteableMSAATexturesSupported = FALSE;
data->IndependentFrontAndBackStencilRefMaskSupported = FALSE;
TRACE("Advanced texture ops %#x.\n", data->AdvancedTextureOpsSupported);
TRACE("Writeable MSAA textures %#x.\n", data->WriteableMSAATexturesSupported);
TRACE("Independent front and back stencil ref mask %#x.\n", data->IndependentFrontAndBackStencilRefMaskSupported);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS15:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS15 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
}
data->TriangleFanSupported = FALSE;
data->DynamicIndexBufferStripCutSupported = FALSE;
TRACE("Triangle fan %#x.\n", data->TriangleFanSupported);
TRACE("Dynamic index buffer strip cut %#x.\n", data->DynamicIndexBufferStripCutSupported);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS16:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS16 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
}
data->DynamicDepthBiasSupported = FALSE;
data->GPUUploadHeapSupported = FALSE;
TRACE("Dynamic depth bias %#x.\n", data->DynamicDepthBiasSupported);
TRACE("GPU upload heap %#x.\n", data->GPUUploadHeapSupported);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS17:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS17 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
}
data->NonNormalizedCoordinateSamplersSupported = FALSE;
data->ManualWriteTrackingResourceSupported = FALSE;
TRACE("Non-normalized coordinate samplers %#x.\n", data->NonNormalizedCoordinateSamplersSupported);
TRACE("Manual write tracking resource %#x.\n", data->ManualWriteTrackingResourceSupported);
return S_OK;
}
case D3D12_FEATURE_D3D12_OPTIONS18:
{
D3D12_FEATURE_DATA_D3D12_OPTIONS18 *data = feature_data;
if (feature_data_size != sizeof(*data))
{
WARN("Invalid size %u.\n", feature_data_size);
}
data->RenderPassesValid = FALSE;
TRACE("Render passes valid %#x.\n", data->RenderPassesValid);
return S_OK;
}
default:
FIXME("Unhandled feature %#x.\n", feature);
return E_NOTIMPL;
}
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateDescriptorHeap(ID3D12Device9 *iface,
const D3D12_DESCRIPTOR_HEAP_DESC *desc, REFIID riid, void **descriptor_heap)
{
struct d3d12_device *device = impl_from_ID3D12Device9(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(ID3D12Device9 *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(ID3D12Device9 *iface,
UINT node_mask, const void *bytecode, SIZE_T bytecode_length,
REFIID riid, void **root_signature)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
struct d3d12_root_signature *object;
HRESULT hr;
TRACE("iface %p, node_mask 0x%08x, bytecode %p, bytecode_length %"PRIuPTR", riid %s, root_signature %p.\n",
iface, node_mask, bytecode, (uintptr_t)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(ID3D12Device9 *iface,
const D3D12_CONSTANT_BUFFER_VIEW_DESC *desc, D3D12_CPU_DESCRIPTOR_HANDLE descriptor)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
struct d3d12_desc tmp = {0};
TRACE("iface %p, desc %p, descriptor %s.\n", iface, desc, debug_cpu_handle(descriptor));
d3d12_desc_create_cbv(&tmp, device, desc);
d3d12_desc_write_atomic(d3d12_desc_from_cpu_handle(descriptor), &tmp, device);
}
static void STDMETHODCALLTYPE d3d12_device_CreateShaderResourceView(ID3D12Device9 *iface,
ID3D12Resource *resource, const D3D12_SHADER_RESOURCE_VIEW_DESC *desc,
D3D12_CPU_DESCRIPTOR_HANDLE descriptor)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
struct d3d12_desc tmp = {0};
TRACE("iface %p, resource %p, desc %p, descriptor %s.\n",
iface, resource, desc, debug_cpu_handle(descriptor));
d3d12_desc_create_srv(&tmp, device, unsafe_impl_from_ID3D12Resource(resource), desc);
d3d12_desc_write_atomic(d3d12_desc_from_cpu_handle(descriptor), &tmp, device);
}
static void STDMETHODCALLTYPE d3d12_device_CreateUnorderedAccessView(ID3D12Device9 *iface,
ID3D12Resource *resource, ID3D12Resource *counter_resource,
const D3D12_UNORDERED_ACCESS_VIEW_DESC *desc, D3D12_CPU_DESCRIPTOR_HANDLE descriptor)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
struct d3d12_desc tmp = {0};
TRACE("iface %p, resource %p, counter_resource %p, desc %p, descriptor %s.\n",
iface, resource, counter_resource, desc, debug_cpu_handle(descriptor));
d3d12_desc_create_uav(&tmp, device, unsafe_impl_from_ID3D12Resource(resource),
unsafe_impl_from_ID3D12Resource(counter_resource), desc);
d3d12_desc_write_atomic(d3d12_desc_from_cpu_handle(descriptor), &tmp, device);
}
static void STDMETHODCALLTYPE d3d12_device_CreateRenderTargetView(ID3D12Device9 *iface,
ID3D12Resource *resource, const D3D12_RENDER_TARGET_VIEW_DESC *desc,
D3D12_CPU_DESCRIPTOR_HANDLE descriptor)
{
TRACE("iface %p, resource %p, desc %p, descriptor %s.\n",
iface, resource, desc, debug_cpu_handle(descriptor));
d3d12_rtv_desc_create_rtv(d3d12_rtv_desc_from_cpu_handle(descriptor),
impl_from_ID3D12Device9(iface), unsafe_impl_from_ID3D12Resource(resource), desc);
}
static void STDMETHODCALLTYPE d3d12_device_CreateDepthStencilView(ID3D12Device9 *iface,
ID3D12Resource *resource, const D3D12_DEPTH_STENCIL_VIEW_DESC *desc,
D3D12_CPU_DESCRIPTOR_HANDLE descriptor)
{
TRACE("iface %p, resource %p, desc %p, descriptor %s.\n",
iface, resource, desc, debug_cpu_handle(descriptor));
d3d12_dsv_desc_create_dsv(d3d12_dsv_desc_from_cpu_handle(descriptor),
impl_from_ID3D12Device9(iface), unsafe_impl_from_ID3D12Resource(resource), desc);
}
static void STDMETHODCALLTYPE d3d12_device_CreateSampler(ID3D12Device9 *iface,
const D3D12_SAMPLER_DESC *desc, D3D12_CPU_DESCRIPTOR_HANDLE descriptor)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
struct d3d12_desc tmp = {0};
TRACE("iface %p, desc %p, descriptor %s.\n", iface, desc, debug_cpu_handle(descriptor));
d3d12_desc_create_sampler(&tmp, device, desc);
d3d12_desc_write_atomic(d3d12_desc_from_cpu_handle(descriptor), &tmp, device);
}
static void STDMETHODCALLTYPE d3d12_device_CopyDescriptors(ID3D12Device9 *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_ID3D12Device9(iface);
unsigned int dst_range_idx, dst_idx, src_range_idx, src_idx;
unsigned int dst_range_size, src_range_size;
struct d3d12_descriptor_heap *dst_heap;
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;
}
if (!dst_descriptor_range_count)
return;
dst_range_idx = dst_idx = 0;
src_range_idx = src_idx = 0;
while (dst_range_idx < dst_descriptor_range_count && src_range_idx < src_descriptor_range_count)
{
dst_range_size = dst_descriptor_range_sizes ? dst_descriptor_range_sizes[dst_range_idx] : 1;
src_range_size = src_descriptor_range_sizes ? src_descriptor_range_sizes[src_range_idx] : 1;
dst = d3d12_desc_from_cpu_handle(dst_descriptor_range_offsets[dst_range_idx]);
dst_heap = d3d12_desc_get_descriptor_heap(dst);
src = d3d12_desc_from_cpu_handle(src_descriptor_range_offsets[src_range_idx]);
for (; dst_idx < dst_range_size && src_idx < src_range_size; ++dst_idx, ++src_idx)
{
if (dst[dst_idx].s.u.object == src[src_idx].s.u.object)
continue;
d3d12_desc_copy(&dst[dst_idx], &src[src_idx], dst_heap, device);
}
if (dst_idx >= dst_range_size)
{
++dst_range_idx;
dst_idx = 0;
}
if (src_idx >= src_range_size)
{
++src_range_idx;
src_idx = 0;
}
}
}
static void STDMETHODCALLTYPE d3d12_device_CopyDescriptorsSimple(ID3D12Device9 *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 %s, "
"src_descriptor_range_offset %s, descriptor_heap_type %#x.\n",
iface, descriptor_count, debug_cpu_handle(dst_descriptor_range_offset),
debug_cpu_handle(src_descriptor_range_offset), 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 void d3d12_resource_allocation_info1_from_vkd3d(D3D12_RESOURCE_ALLOCATION_INFO1 *result,
const struct vkd3d_resource_allocation_info *info)
{
result->Offset = info->offset;
result->Alignment = info->alignment;
result->SizeInBytes = info->size_in_bytes;
}
2024-02-04 20:57:35 -08:00
static void d3d12_device_get_resource1_allocation_info(struct d3d12_device *device,
D3D12_RESOURCE_ALLOCATION_INFO1 *infos1, unsigned int count, const D3D12_RESOURCE_DESC1 *resource_descs,
D3D12_RESOURCE_ALLOCATION_INFO *result)
{
struct vkd3d_resource_allocation_info info;
2024-02-04 20:57:35 -08:00
const D3D12_RESOURCE_DESC1 *desc;
uint64_t requested_alignment;
unsigned int i;
result->Alignment = 0;
result->SizeInBytes = 0;
info.offset = 0;
for (i = 0; i < count; ++i)
{
desc = &resource_descs[i];
if (FAILED(d3d12_resource_validate_desc(desc, device)))
{
WARN("Invalid resource desc.\n");
goto invalid;
}
if (desc->Dimension == D3D12_RESOURCE_DIMENSION_BUFFER)
{
info.alignment = D3D12_DEFAULT_RESOURCE_PLACEMENT_ALIGNMENT;
info.offset = align(info.offset, info.alignment);
info.size_in_bytes = align(desc->Width, D3D12_DEFAULT_RESOURCE_PLACEMENT_ALIGNMENT);
}
else
{
if (FAILED(vkd3d_get_image_allocation_info(device, desc, &info)))
{
WARN("Failed to get allocation info for texture.\n");
goto invalid;
}
requested_alignment = desc->Alignment
? desc->Alignment : D3D12_DEFAULT_RESOURCE_PLACEMENT_ALIGNMENT;
info.alignment = max(info.alignment, requested_alignment);
info.size_in_bytes = align(info.size_in_bytes, info.alignment);
/* Pad by the maximum heap offset increase which may be needed to align to a higher
* Vulkan requirement an offset supplied by the calling application. This allows
* us to return the standard D3D12 alignment and adjust resource placement later. */
if (info.alignment > requested_alignment)
{
info.size_in_bytes += info.alignment - requested_alignment;
info.alignment = requested_alignment;
}
info.offset = align(info.offset, info.alignment);
}
if (infos1)
d3d12_resource_allocation_info1_from_vkd3d(&infos1[i], &info);
info.offset += info.size_in_bytes;
result->Alignment = max(result->Alignment, info.alignment);
result->SizeInBytes = info.offset;
}
return;
invalid:
result->SizeInBytes = UINT64_MAX;
/* FIXME: Should we support D3D12_DEFAULT_RESOURCE_PLACEMENT_ALIGNMENT for small MSAA resources? */
if (desc->SampleDesc.Count != 1)
result->Alignment = D3D12_DEFAULT_MSAA_RESOURCE_PLACEMENT_ALIGNMENT;
else
result->Alignment = D3D12_DEFAULT_RESOURCE_PLACEMENT_ALIGNMENT;
TRACE("Alignment %#"PRIx64".\n", result->Alignment);
}
2024-02-04 20:57:35 -08:00
static void d3d12_device_get_resource_allocation_info(struct d3d12_device *device,
D3D12_RESOURCE_ALLOCATION_INFO1 *infos1, unsigned int count, const D3D12_RESOURCE_DESC *resource_descs,
D3D12_RESOURCE_ALLOCATION_INFO *result)
{
/* Avoid spurious compiler warning for uninitialized use. */
D3D12_RESOURCE_DESC1 resource_descs1[4] = {0};
D3D12_RESOURCE_DESC1 *descs1;
unsigned int i;
if (count <= ARRAY_SIZE(resource_descs1))
{
descs1 = resource_descs1;
}
else if (!(descs1 = vkd3d_calloc(count, sizeof(*descs1))))
{
ERR("Failed to allocate %u resource descriptions.\n", count);
result->SizeInBytes = UINT64_MAX;
result->Alignment = D3D12_DEFAULT_RESOURCE_PLACEMENT_ALIGNMENT;
return;
}
for (i = 0; i < count; ++i)
d3d12_resource_desc1_from_desc(&descs1[i], &resource_descs[i]);
d3d12_device_get_resource1_allocation_info(device, infos1, count, descs1, result);
if (descs1 != resource_descs1)
vkd3d_free(descs1);
}
static D3D12_RESOURCE_ALLOCATION_INFO * STDMETHODCALLTYPE d3d12_device_GetResourceAllocationInfo(
ID3D12Device9 *iface, D3D12_RESOURCE_ALLOCATION_INFO *info, UINT visible_mask,
UINT count, const D3D12_RESOURCE_DESC *resource_descs)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
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);
d3d12_device_get_resource_allocation_info(device, NULL, count, resource_descs, info);
return info;
}
static D3D12_HEAP_PROPERTIES * STDMETHODCALLTYPE d3d12_device_GetCustomHeapProperties(ID3D12Device9 *iface,
D3D12_HEAP_PROPERTIES *heap_properties, UINT node_mask, D3D12_HEAP_TYPE heap_type)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
bool coherent;
TRACE("iface %p, heap_properties %p, node_mask 0x%08x, heap_type %#x.\n",
iface, heap_properties, node_mask, heap_type);
debug_ignored_node_mask(node_mask);
heap_properties->Type = D3D12_HEAP_TYPE_CUSTOM;
switch (heap_type)
{
case D3D12_HEAP_TYPE_DEFAULT:
heap_properties->CPUPageProperty = D3D12_CPU_PAGE_PROPERTY_NOT_AVAILABLE;
heap_properties->MemoryPoolPreference = d3d12_device_is_uma(device, NULL)
? D3D12_MEMORY_POOL_L0 : D3D12_MEMORY_POOL_L1;
break;
case D3D12_HEAP_TYPE_UPLOAD:
heap_properties->CPUPageProperty = d3d12_device_is_uma(device, &coherent) && coherent
? D3D12_CPU_PAGE_PROPERTY_WRITE_BACK : D3D12_CPU_PAGE_PROPERTY_WRITE_COMBINE;
heap_properties->MemoryPoolPreference = D3D12_MEMORY_POOL_L0;
break;
case D3D12_HEAP_TYPE_READBACK:
heap_properties->CPUPageProperty = D3D12_CPU_PAGE_PROPERTY_WRITE_BACK;
heap_properties->MemoryPoolPreference = D3D12_MEMORY_POOL_L0;
break;
default:
FIXME("Unhandled heap type %#x.\n", heap_type);
break;
};
heap_properties->CreationNodeMask = 1;
heap_properties->VisibleNodeMask = 1;
return heap_properties;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateCommittedResource(ID3D12Device9 *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_ID3D12Device9(iface);
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D3D12_RESOURCE_DESC1 resource_desc;
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);
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d3d12_resource_desc1_from_desc(&resource_desc, desc);
if (FAILED(hr = d3d12_committed_resource_create(device, heap_properties, heap_flags,
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&resource_desc, initial_state, optimized_clear_value, NULL, &object)))
{
*resource = NULL;
return hr;
}
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return return_interface(&object->ID3D12Resource2_iface, &IID_ID3D12Resource2, iid, resource);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateHeap(ID3D12Device9 *iface,
const D3D12_HEAP_DESC *desc, REFIID iid, void **heap)
{
struct d3d12_device *device = impl_from_ID3D12Device9(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, NULL, NULL, &object)))
{
*heap = NULL;
return hr;
}
return return_interface(&object->ID3D12Heap_iface, &IID_ID3D12Heap, iid, heap);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreatePlacedResource(ID3D12Device9 *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_ID3D12Device9(iface);
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D3D12_RESOURCE_DESC1 resource_desc;
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);
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d3d12_resource_desc1_from_desc(&resource_desc, desc);
if (FAILED(hr = d3d12_placed_resource_create(device, heap_object, heap_offset,
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&resource_desc, initial_state, optimized_clear_value, &object)))
return hr;
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return return_interface(&object->ID3D12Resource2_iface, &IID_ID3D12Resource2, iid, resource);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateReservedResource(ID3D12Device9 *iface,
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_ID3D12Device9(iface);
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D3D12_RESOURCE_DESC1 resource_desc;
struct d3d12_resource *object;
HRESULT hr;
TRACE("iface %p, desc %p, initial_state %#x, optimized_clear_value %p, iid %s, resource %p.\n",
iface, desc, initial_state, optimized_clear_value, debugstr_guid(iid), resource);
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d3d12_resource_desc1_from_desc(&resource_desc, desc);
if (FAILED(hr = d3d12_reserved_resource_create(device,
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&resource_desc, initial_state, optimized_clear_value, &object)))
return hr;
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return return_interface(&object->ID3D12Resource2_iface, &IID_ID3D12Resource2, iid, resource);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateSharedHandle(ID3D12Device9 *iface,
ID3D12DeviceChild *object, const SECURITY_ATTRIBUTES *attributes, DWORD access,
const WCHAR *name, HANDLE *handle)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
FIXME("iface %p, object %p, attributes %p, access %#x, name %s, handle %p stub!\n",
iface, object, attributes, (uint32_t)access, debugstr_w(name, device->wchar_size), handle);
return E_NOTIMPL;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_OpenSharedHandle(ID3D12Device9 *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(ID3D12Device9 *iface,
const WCHAR *name, DWORD access, HANDLE *handle)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
FIXME("iface %p, name %s, access %#x, handle %p stub!\n",
iface, debugstr_w(name, device->wchar_size), (uint32_t)access, handle);
return E_NOTIMPL;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_MakeResident(ID3D12Device9 *iface,
UINT object_count, ID3D12Pageable * const *objects)
{
ID3D12Fence *fence;
HRESULT hr;
TRACE("iface %p, object_count %u, objects %p.\n", iface, object_count, objects);
if (FAILED(hr = ID3D12Device9_CreateFence(iface, 0, 0, &IID_ID3D12Fence, (void **)&fence)))
return hr;
hr = ID3D12Device9_EnqueueMakeResident(iface, 0, object_count, objects, fence, 1);
if (SUCCEEDED(hr))
ID3D12Fence_SetEventOnCompletion(fence, 1, NULL);
ID3D12Fence_Release(fence);
return hr;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_Evict(ID3D12Device9 *iface,
UINT object_count, ID3D12Pageable * const *objects)
{
FIXME_ONCE("iface %p, object_count %u, objects %p stub!\n",
iface, object_count, objects);
return S_OK;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateFence(ID3D12Device9 *iface,
UINT64 initial_value, D3D12_FENCE_FLAGS flags, REFIID riid, void **fence)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
struct d3d12_fence *object;
HRESULT hr;
TRACE("iface %p, initial_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;
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return return_interface(&object->ID3D12Fence1_iface, &IID_ID3D12Fence1, riid, fence);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_GetDeviceRemovedReason(ID3D12Device9 *iface)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
TRACE("iface %p.\n", iface);
return device->removed_reason;
}
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static void d3d12_device_get_copyable_footprints(struct d3d12_device *device,
const D3D12_RESOURCE_DESC1 *desc, unsigned int first_sub_resource, unsigned int sub_resource_count,
uint64_t base_offset, D3D12_PLACED_SUBRESOURCE_FOOTPRINT *layouts, UINT *row_counts,
UINT64 *row_sizes, UINT64 *total_bytes)
{
unsigned int i, sub_resource_idx, miplevel_idx, row_count, row_size, row_pitch;
unsigned int width, height, depth, plane_count, sub_resources_per_plane;
const struct vkd3d_format *format;
uint64_t offset, size, total;
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_t)0;
if (!(format = vkd3d_format_from_d3d12_resource_desc(device, desc, 0)))
{
WARN("Invalid format %#x.\n", desc->Format);
return;
}
if (FAILED(d3d12_resource_validate_desc(desc, device)))
{
WARN("Invalid resource desc.\n");
return;
}
plane_count = ((format->vk_aspect_mask & VK_IMAGE_ASPECT_DEPTH_BIT)
&& (format->vk_aspect_mask & VK_IMAGE_ASPECT_STENCIL_BIT)) ? 2 : 1;
sub_resources_per_plane = d3d12_resource_desc_get_sub_resource_count(desc);
if (!vkd3d_bound_range(first_sub_resource, sub_resource_count, sub_resources_per_plane * plane_count))
{
WARN("Invalid sub-resource range %u-%u for resource.\n", first_sub_resource, sub_resource_count);
return;
}
offset = 0;
total = 0;
for (i = 0; i < sub_resource_count; ++i)
{
sub_resource_idx = (first_sub_resource + i) % sub_resources_per_plane;
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 = base_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 void STDMETHODCALLTYPE d3d12_device_GetCopyableFootprints(ID3D12Device9 *iface,
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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)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
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D3D12_RESOURCE_DESC1 resource_desc;
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);
d3d12_resource_desc1_from_desc(&resource_desc, desc);
d3d12_device_get_copyable_footprints(device, &resource_desc, first_sub_resource, sub_resource_count,
base_offset, layouts, row_counts, row_sizes, total_bytes);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateQueryHeap(ID3D12Device9 *iface,
const D3D12_QUERY_HEAP_DESC *desc, REFIID iid, void **heap)
{
struct d3d12_device *device = impl_from_ID3D12Device9(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(ID3D12Device9 *iface, BOOL enable)
{
FIXME("iface %p, enable %#x stub!\n", iface, enable);
return E_NOTIMPL;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateCommandSignature(ID3D12Device9 *iface,
const D3D12_COMMAND_SIGNATURE_DESC *desc, ID3D12RootSignature *root_signature,
REFIID iid, void **command_signature)
{
struct d3d12_device *device = impl_from_ID3D12Device9(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);
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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(ID3D12Device9 *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)
{
const struct d3d12_resource *resource_impl = impl_from_ID3D12Resource(resource);
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
TRACE("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.\n",
iface, resource, total_tile_count, packed_mip_info, standard_tile_shape,
sub_resource_tiling_count, first_sub_resource_tiling,
sub_resource_tilings);
d3d12_resource_get_tiling(device, resource_impl, 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(ID3D12Device9 *iface, LUID *luid)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
TRACE("iface %p, luid %p.\n", iface, luid);
*luid = device->adapter_luid;
return luid;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreatePipelineLibrary(ID3D12Device9 *iface,
const void *blob, SIZE_T blob_size, REFIID iid, void **lib)
{
FIXME("iface %p, blob %p, blob_size %"PRIuPTR", iid %s, lib %p stub!\n",
iface, blob, (uintptr_t)blob_size, debugstr_guid(iid), lib);
return DXGI_ERROR_UNSUPPORTED;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_SetEventOnMultipleFenceCompletion(ID3D12Device9 *iface,
ID3D12Fence *const *fences, const UINT64 *values, UINT fence_count,
D3D12_MULTIPLE_FENCE_WAIT_FLAGS flags, HANDLE event)
{
FIXME("iface %p, fences %p, values %p, fence_count %u, flags %#x, event %p stub!\n",
iface, fences, values, fence_count, flags, event);
return E_NOTIMPL;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_SetResidencyPriority(ID3D12Device9 *iface,
UINT object_count, ID3D12Pageable *const *objects, const D3D12_RESIDENCY_PRIORITY *priorities)
{
FIXME_ONCE("iface %p, object_count %u, objects %p, priorities %p stub!\n", iface, object_count, objects, priorities);
return S_OK;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreatePipelineState(ID3D12Device9 *iface,
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const D3D12_PIPELINE_STATE_STREAM_DESC *desc, REFIID iid, void **pipeline_state)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
struct d3d12_pipeline_state *object;
HRESULT hr;
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TRACE("iface %p, desc %p, iid %s, pipeline_state %p.\n", iface, desc, debugstr_guid(iid), pipeline_state);
if (FAILED(hr = d3d12_pipeline_state_create(device, desc, &object)))
return hr;
return return_interface(&object->ID3D12PipelineState_iface, &IID_ID3D12PipelineState, iid, pipeline_state);
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}
static HRESULT STDMETHODCALLTYPE d3d12_device_OpenExistingHeapFromAddress(ID3D12Device9 *iface,
const void *address, REFIID iid, void **heap)
{
FIXME("iface %p, address %p, iid %s, heap %p stub!\n", iface, address, debugstr_guid(iid), heap);
return E_NOTIMPL;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_OpenExistingHeapFromFileMapping(ID3D12Device9 *iface,
HANDLE file_mapping, REFIID iid, void **heap)
{
FIXME("iface %p, file_mapping %p, iid %s, heap %p stub!\n", iface, file_mapping, debugstr_guid(iid), heap);
return E_NOTIMPL;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_EnqueueMakeResident(ID3D12Device9 *iface,
D3D12_RESIDENCY_FLAGS flags, UINT num_objects, ID3D12Pageable *const *objects,
ID3D12Fence *fence, UINT64 fence_value)
{
FIXME_ONCE("iface %p, flags %#x, num_objects %u, objects %p, fence %p, fence_value %#"PRIx64" stub!\n",
iface, flags, num_objects, objects, fence, fence_value);
ID3D12Fence_Signal(fence, fence_value);
return S_OK;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateCommandList1(ID3D12Device9 *iface,
UINT node_mask, D3D12_COMMAND_LIST_TYPE type, D3D12_COMMAND_LIST_FLAGS flags,
REFIID iid, void **command_list)
{
FIXME("iface %p, node_mask 0x%08x, type %#x, flags %#x, iid %s, command_list %p stub!\n",
iface, node_mask, type, flags, debugstr_guid(iid), command_list);
return E_NOTIMPL;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateProtectedResourceSession(ID3D12Device9 *iface,
const D3D12_PROTECTED_RESOURCE_SESSION_DESC *desc, REFIID iid, void **session)
{
FIXME("iface %p, desc %p, iid %s, session %p stub!\n", iface, desc, debugstr_guid(iid), session);
return E_NOTIMPL;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateCommittedResource1(ID3D12Device9 *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,
ID3D12ProtectedResourceSession *protected_session, REFIID iid, void **resource)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
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D3D12_RESOURCE_DESC1 resource_desc;
struct d3d12_resource *object;
HRESULT hr;
TRACE("iface %p, heap_properties %p, heap_flags %#x, desc %p, initial_state %#x, "
"optimized_clear_value %p, protected_session %p, iid %s, resource %p.\n",
iface, heap_properties, heap_flags, desc, initial_state,
optimized_clear_value, protected_session, debugstr_guid(iid), resource);
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d3d12_resource_desc1_from_desc(&resource_desc, desc);
if (FAILED(hr = d3d12_committed_resource_create(device, heap_properties, heap_flags,
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&resource_desc, initial_state, optimized_clear_value, protected_session, &object)))
{
*resource = NULL;
return hr;
}
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return return_interface(&object->ID3D12Resource2_iface, &IID_ID3D12Resource2, iid, resource);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateHeap1(ID3D12Device9 *iface,
const D3D12_HEAP_DESC *desc, ID3D12ProtectedResourceSession *protected_session,
REFIID iid, void **heap)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
struct d3d12_heap *object;
HRESULT hr;
TRACE("iface %p, desc %p, protected_session %p, iid %s, heap %p.\n",
iface, desc, protected_session, debugstr_guid(iid), heap);
if (FAILED(hr = d3d12_heap_create(device, desc, NULL, protected_session, &object)))
{
*heap = NULL;
return hr;
}
return return_interface(&object->ID3D12Heap_iface, &IID_ID3D12Heap, iid, heap);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateReservedResource1(ID3D12Device9 *iface,
const D3D12_RESOURCE_DESC *desc, D3D12_RESOURCE_STATES initial_state,
const D3D12_CLEAR_VALUE *optimized_clear_value,
ID3D12ProtectedResourceSession *protected_session, REFIID iid, void **resource)
{
FIXME("iface %p, desc %p, initial_state %#x, optimized_clear_value %p, "
"protected_session %p, iid %s, resource %p stub!\n",
iface, desc, initial_state, optimized_clear_value, protected_session,
debugstr_guid(iid), resource);
return E_NOTIMPL;
}
static D3D12_RESOURCE_ALLOCATION_INFO * STDMETHODCALLTYPE d3d12_device_GetResourceAllocationInfo1(
ID3D12Device9 *iface, D3D12_RESOURCE_ALLOCATION_INFO *info, UINT visible_mask,
UINT count, const D3D12_RESOURCE_DESC *resource_descs,
D3D12_RESOURCE_ALLOCATION_INFO1 *info1)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
TRACE("iface %p, info %p, visible_mask 0x%08x, count %u, resource_descs %p, info1 %p.\n",
iface, info, visible_mask, count, resource_descs, info1);
debug_ignored_node_mask(visible_mask);
d3d12_device_get_resource_allocation_info(device, info1, count, resource_descs, info);
return info;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateLifetimeTracker(ID3D12Device9 *iface,
ID3D12LifetimeOwner *owner, REFIID iid, void **tracker)
{
FIXME("iface %p, owner %p, iid %s, tracker %p stub!\n", iface, owner, debugstr_guid(iid), tracker);
return E_NOTIMPL;
}
static void STDMETHODCALLTYPE d3d12_device_RemoveDevice(ID3D12Device9 *iface)
{
FIXME("iface %p stub!\n", iface);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_EnumerateMetaCommands(ID3D12Device9 *iface,
UINT *num_meta_commands, D3D12_META_COMMAND_DESC *command_desc)
{
FIXME("iface %p, num_meta_commands %p, command_desc %p stub!\n", iface,
num_meta_commands, command_desc);
return E_NOTIMPL;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_EnumerateMetaCommandParameters(ID3D12Device9 *iface,
REFGUID command_id, D3D12_META_COMMAND_PARAMETER_STAGE stage,
UINT *size_in_bytes, UINT *parameter_count,
D3D12_META_COMMAND_PARAMETER_DESC *parameter_desc)
{
FIXME("iface %p, command_id %s, stage %u, size_in_bytes %p, "
"parameter_count %p, parameter_desc %p stub!\n", iface,
debugstr_guid(command_id), stage, size_in_bytes, parameter_count, parameter_desc);
return E_NOTIMPL;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateMetaCommand(ID3D12Device9 *iface,
REFGUID command_id, UINT node_mask, const void *parameters_data,
SIZE_T data_size_in_bytes, REFIID iid, void **meta_command)
{
FIXME("iface %p, command_id %s, node_mask %#x, parameters_data %p, "
"data_size_in_bytes %"PRIuPTR", iid %s, meta_command %p stub!\n", iface,
debugstr_guid(command_id), node_mask, parameters_data,
(uintptr_t)data_size_in_bytes, debugstr_guid(iid), meta_command);
return E_NOTIMPL;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateStateObject(ID3D12Device9 *iface,
const D3D12_STATE_OBJECT_DESC *desc, REFIID iid, void **state_object)
{
FIXME("iface %p, desc %p, iid %s, state_object %p stub!\n", iface, desc, debugstr_guid(iid), state_object);
return E_NOTIMPL;
}
static void STDMETHODCALLTYPE d3d12_device_GetRaytracingAccelerationStructurePrebuildInfo(ID3D12Device9 *iface,
const D3D12_BUILD_RAYTRACING_ACCELERATION_STRUCTURE_INPUTS *desc,
D3D12_RAYTRACING_ACCELERATION_STRUCTURE_PREBUILD_INFO *info)
{
FIXME("iface %p, desc %p, info %p stub!\n", iface, desc, info);
}
static D3D12_DRIVER_MATCHING_IDENTIFIER_STATUS STDMETHODCALLTYPE d3d12_device_CheckDriverMatchingIdentifier(ID3D12Device9 *iface,
D3D12_SERIALIZED_DATA_TYPE data_type, const D3D12_SERIALIZED_DATA_DRIVER_MATCHING_IDENTIFIER *identifier)
{
FIXME("iface %p, data_type %u, identifier %p stub!\n", iface, data_type, identifier);
return D3D12_DRIVER_MATCHING_IDENTIFIER_UNRECOGNIZED;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_SetBackgroundProcessingMode(ID3D12Device9 *iface,
D3D12_BACKGROUND_PROCESSING_MODE mode, D3D12_MEASUREMENTS_ACTION action, HANDLE event,
BOOL *further_measurements_desired)
{
FIXME("iface %p, mode %#x, action %#x, event %p, further_measurements_desired %p stub!\n",
iface, mode, action, event, further_measurements_desired);
return E_NOTIMPL;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_AddToStateObject(ID3D12Device9 *iface,
const D3D12_STATE_OBJECT_DESC *addition, ID3D12StateObject *state_object_to_grow_from,
REFIID riid, void **new_state_object)
{
FIXME("iface %p, addition %p, state_object_to_grow_from %p, riid %s, new_state_object %p stub!\n",
iface, addition, state_object_to_grow_from, debugstr_guid(riid), new_state_object);
return E_NOTIMPL;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateProtectedResourceSession1(ID3D12Device9 *iface,
const D3D12_PROTECTED_RESOURCE_SESSION_DESC1 *desc, REFIID riid, void **session)
{
FIXME("iface %p, desc %p, riid %s, session %p stub!\n", iface, desc, debugstr_guid(riid), session);
return E_NOTIMPL;
}
static D3D12_RESOURCE_ALLOCATION_INFO * STDMETHODCALLTYPE d3d12_device_GetResourceAllocationInfo2(ID3D12Device9 *iface,
D3D12_RESOURCE_ALLOCATION_INFO *info, UINT visible_mask, UINT count,
const D3D12_RESOURCE_DESC1 *resource_descs, D3D12_RESOURCE_ALLOCATION_INFO1 *info1)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
TRACE("iface %p, info %p, visible_mask 0x%08x, count %u, resource_descs %p, info1 %p.\n",
iface, info, visible_mask, count, resource_descs, info1);
debug_ignored_node_mask(visible_mask);
d3d12_device_get_resource1_allocation_info(device, info1, count, resource_descs, info);
return info;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateCommittedResource2(ID3D12Device9 *iface,
const D3D12_HEAP_PROPERTIES *heap_properties, D3D12_HEAP_FLAGS heap_flags, const D3D12_RESOURCE_DESC1 *desc,
D3D12_RESOURCE_STATES initial_state, const D3D12_CLEAR_VALUE *optimized_clear_value,
ID3D12ProtectedResourceSession *protected_session, REFIID iid, void **resource)
{
struct d3d12_device *device = impl_from_ID3D12Device9(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, protected_session %p, iid %s, resource %p.\n",
iface, heap_properties, heap_flags, desc, initial_state,
optimized_clear_value, protected_session, debugstr_guid(iid), resource);
if (FAILED(hr = d3d12_committed_resource_create(device, heap_properties, heap_flags,
desc, initial_state, optimized_clear_value, protected_session, &object)))
{
*resource = NULL;
return hr;
}
return return_interface(&object->ID3D12Resource2_iface, &IID_ID3D12Resource2, iid, resource);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreatePlacedResource1(ID3D12Device9 *iface,
ID3D12Heap *heap, UINT64 heap_offset, const D3D12_RESOURCE_DESC1 *resource_desc,
D3D12_RESOURCE_STATES initial_state, const D3D12_CLEAR_VALUE *optimized_clear_value,
REFIID iid, void **resource)
{
struct d3d12_device *device = impl_from_ID3D12Device9(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, resource_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,
resource_desc, initial_state, optimized_clear_value, &object)))
return hr;
return return_interface(&object->ID3D12Resource2_iface, &IID_ID3D12Resource2, iid, resource);
}
static void STDMETHODCALLTYPE d3d12_device_CreateSamplerFeedbackUnorderedAccessView(ID3D12Device9 *iface,
ID3D12Resource *target_resource, ID3D12Resource *feedback_resource, D3D12_CPU_DESCRIPTOR_HANDLE descriptor)
{
FIXME("iface %p, target_resource %p, feedback_resource %p, descriptor %s stub!\n",
iface, target_resource, feedback_resource, debug_cpu_handle(descriptor));
}
static void STDMETHODCALLTYPE d3d12_device_GetCopyableFootprints1(ID3D12Device9 *iface,
const D3D12_RESOURCE_DESC1 *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)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
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);
d3d12_device_get_copyable_footprints(device, desc, first_sub_resource, sub_resource_count,
base_offset, layouts, row_counts, row_sizes, total_bytes);
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateShaderCacheSession(ID3D12Device9 *iface,
const D3D12_SHADER_CACHE_SESSION_DESC *desc, REFIID iid, void **session)
{
struct d3d12_device *device = impl_from_ID3D12Device9(iface);
struct d3d12_cache_session *object;
static const GUID guid_null = {0};
HRESULT hr;
static const UINT valid_flags = D3D12_SHADER_CACHE_FLAG_DRIVER_VERSIONED
| D3D12_SHADER_CACHE_FLAG_USE_WORKING_DIR;
TRACE("iface %p, desc %p, iid %s, session %p.\n", iface, desc, debugstr_guid(iid), session);
if (!desc || !memcmp(&desc->Identifier, &guid_null, sizeof(desc->Identifier)))
{
WARN("No description or identifier, returning E_INVALIDARG.\n");
return E_INVALIDARG;
}
if (desc->MaximumValueFileSizeBytes > 1024 * 1024 * 1024)
{
WARN("Requested size is larger than 1GiB, returning E_INVALIDARG.\n");
return E_INVALIDARG;
}
if (desc->Flags & ~valid_flags)
{
WARN("Invalid flags %#x, returning E_INVALIDARG.\n", desc->Flags);
return E_INVALIDARG;
}
if (desc->Mode != D3D12_SHADER_CACHE_MODE_MEMORY && desc->Mode != D3D12_SHADER_CACHE_MODE_DISK)
{
WARN("Invalid mode %#x, returning E_INVALIDARG.\n", desc->Mode);
return E_INVALIDARG;
}
if (!session)
{
WARN("No output pointer, returning S_FALSE.\n");
return S_FALSE;
}
*session = NULL;
if (!(object = vkd3d_malloc(sizeof(*object))))
return E_OUTOFMEMORY;
if (FAILED(hr = d3d12_cache_session_init(object, device, desc)))
{
vkd3d_free(object);
return hr;
}
hr = ID3D12ShaderCacheSession_QueryInterface(&object->ID3D12ShaderCacheSession_iface, iid,
session);
ID3D12ShaderCacheSession_Release(&object->ID3D12ShaderCacheSession_iface);
return hr;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_ShaderCacheControl(ID3D12Device9 *iface,
D3D12_SHADER_CACHE_KIND_FLAGS kinds, D3D12_SHADER_CACHE_CONTROL_FLAGS control)
{
FIXME("iface %p, kinds %#x control %#x stub!\n", iface, kinds, control);
return E_NOTIMPL;
}
static HRESULT STDMETHODCALLTYPE d3d12_device_CreateCommandQueue1(ID3D12Device9 *iface,
const D3D12_COMMAND_QUEUE_DESC *desc, REFIID creator_id, REFIID iid,
void **command_queue)
{
FIXME("iface %p, desc %p, creator %s, iid %s, queue %p stub!\n", iface, desc,
debugstr_guid(creator_id), debugstr_guid(iid), command_queue);
return E_NOTIMPL;
}
static const struct ID3D12Device9Vtbl 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,
/* ID3D12Device1 methods */
d3d12_device_CreatePipelineLibrary,
d3d12_device_SetEventOnMultipleFenceCompletion,
d3d12_device_SetResidencyPriority,
2023-08-25 03:55:07 -07:00
/* ID3D12Device2 methods */
d3d12_device_CreatePipelineState,
/* ID3D12Device3 methods */
d3d12_device_OpenExistingHeapFromAddress,
d3d12_device_OpenExistingHeapFromFileMapping,
d3d12_device_EnqueueMakeResident,
/* ID3D12Device4 methods */
d3d12_device_CreateCommandList1,
d3d12_device_CreateProtectedResourceSession,
d3d12_device_CreateCommittedResource1,
d3d12_device_CreateHeap1,
d3d12_device_CreateReservedResource1,
d3d12_device_GetResourceAllocationInfo1,
/* ID3D12Device5 methods */
d3d12_device_CreateLifetimeTracker,
d3d12_device_RemoveDevice,
d3d12_device_EnumerateMetaCommands,
d3d12_device_EnumerateMetaCommandParameters,
d3d12_device_CreateMetaCommand,
d3d12_device_CreateStateObject,
d3d12_device_GetRaytracingAccelerationStructurePrebuildInfo,
d3d12_device_CheckDriverMatchingIdentifier,
/* ID3D12Device6 methods */
d3d12_device_SetBackgroundProcessingMode,
/* ID3D12Device7 methods */
d3d12_device_AddToStateObject,
d3d12_device_CreateProtectedResourceSession1,
/* ID3D12Device8 methods */
d3d12_device_GetResourceAllocationInfo2,
d3d12_device_CreateCommittedResource2,
d3d12_device_CreatePlacedResource1,
d3d12_device_CreateSamplerFeedbackUnorderedAccessView,
d3d12_device_GetCopyableFootprints1,
/* ID3D12Device9 methods */
d3d12_device_CreateShaderCacheSession,
d3d12_device_ShaderCacheControl,
d3d12_device_CreateCommandQueue1,
};
struct d3d12_device *unsafe_impl_from_ID3D12Device9(ID3D12Device9 *iface)
{
if (!iface)
return NULL;
assert(iface->lpVtbl == &d3d12_device_vtbl);
return impl_from_ID3D12Device9(iface);
}
static void *device_worker_main(void *arg)
{
struct d3d12_descriptor_heap *heap;
struct d3d12_device *device = arg;
size_t i;
vkd3d_set_thread_name("device_worker");
vkd3d_mutex_lock(&device->worker_mutex);
while (!device->worker_should_exit)
{
for (i = 0; i < device->heap_count; ++i)
{
/* Descriptor updates are not written to Vulkan descriptor sets until a command list
* is submitted to a queue, while the client is free to write d3d12 descriptors earlier,
* from any thread. This causes a delay right before command list execution, so
* handling these updates in a worker thread can speed up execution significantly. */
heap = device->heaps[i];
if (heap->dirty_list_head == UINT_MAX)
continue;
vkd3d_mutex_lock(&heap->vk_sets_mutex);
d3d12_desc_flush_vk_heap_updates_locked(heap, device);
vkd3d_mutex_unlock(&heap->vk_sets_mutex);
}
vkd3d_cond_wait(&device->worker_cond, &device->worker_mutex);
}
vkd3d_mutex_unlock(&device->worker_mutex);
return NULL;
}
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->ID3D12Device9_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->wchar_size = instance->wchar_size;
2024-04-09 18:43:09 -07:00
device->environment = (instance->vk_api_version >= VK_API_VERSION_1_1)
? VKD3D_SHADER_SPIRV_ENVIRONMENT_VULKAN_1_1 : VKD3D_SHADER_SPIRV_ENVIRONMENT_VULKAN_1_0;
device->adapter_luid = create_info->adapter_luid;
device->removed_reason = S_OK;
device->vk_device = VK_NULL_HANDLE;
device->heaps = NULL;
device->heap_capacity = 0;
device->heap_count = 0;
memset(&device->worker_thread, 0, sizeof(device->worker_thread));
device->worker_should_exit = false;
vkd3d_mutex_init(&device->worker_mutex);
vkd3d_cond_init(&device->worker_cond);
if (FAILED(hr = vkd3d_create_vk_device(device, create_info)))
goto out_free_instance;
if (FAILED(hr = d3d12_device_init_pipeline_cache(device)))
goto out_free_vk_resources;
if (FAILED(hr = vkd3d_private_store_init(&device->private_store)))
goto out_free_pipeline_cache;
if (FAILED(hr = vkd3d_init_format_info(device)))
goto out_free_private_store;
if (FAILED(hr = vkd3d_init_null_resources(&device->null_resources, device)))
goto out_cleanup_format_info;
if (FAILED(hr = vkd3d_uav_clear_state_init(&device->uav_clear_state, device)))
goto out_destroy_null_resources;
vkd3d: Back descriptor heaps with Vulkan descriptor sets if descriptor indexing is available. The existing implementation using virtual descriptor heaps, where Vk descriptor sets are created for the bindings in the root descriptor tables, is inefficient when multiple command lists are used with large descriptor heaps. It also cannot support updating a descriptor set after it is bound. This patch creates Vk sets for each D3D12 heap. Because D3D12 heaps can contain CBV, SRV and UAV descriptors in the same heap, multiple Vk sets are needed for each heap, however the total number of populated descriptors is never more than (heap size + UAV counter count). A new 'virtual_heaps' config option is introduced to make the old implementation available when needed. It's not always possible to determine if this is necessary when the device is created. Up to nine Vk descriptor sets may be used. It's theoretically possible to reduce this to eight by placing immutable samplers in the push descriptor set layout, but contradictions in earlier versions of the Vulkan spec made driver support inconsistent. The documentation was corrected in version 1.2.203. This patch also adds support for UAV counter descriptor arrays. It's not practical to add this in a separate patch due to complications with combining the old UAV counter implementation with the new descriptor heap implementation. Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47713 Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47154 Signed-off-by: Conor McCarthy <cmccarthy@codeweavers.com> Signed-off-by: Henri Verbeet <hverbeet@codeweavers.com> Signed-off-by: Alexandre Julliard <julliard@winehq.org>
2022-02-21 07:18:59 -08:00
if (FAILED(hr = vkd3d_vk_descriptor_heap_layouts_init(device)))
goto out_cleanup_uav_clear_state;
if (device->use_vk_heaps && FAILED(hr = vkd3d_create_thread(device->vkd3d_instance,
device_worker_main, device, &device->worker_thread)))
{
WARN("Failed to create worker thread, hr %s.\n", debugstr_hresult(hr));
goto out_cleanup_descriptor_heap_layouts;
}
vkd3d_render_pass_cache_init(&device->render_pass_cache);
vkd3d_gpu_va_allocator_init(&device->gpu_va_allocator);
vkd3d_time_domains_init(device);
device->blocked_queue_count = 0;
vkd3d_mutex_init(&device->blocked_queues_mutex);
vkd3d_desc_object_cache_init(&device->view_desc_cache, sizeof(struct vkd3d_view));
vkd3d_desc_object_cache_init(&device->cbuffer_desc_cache, sizeof(struct vkd3d_cbuffer_desc));
device_init_descriptor_pool_sizes(device);
if ((device->parent = create_info->parent))
IUnknown_AddRef(device->parent);
return S_OK;
out_cleanup_descriptor_heap_layouts:
vkd3d_vk_descriptor_heap_layouts_cleanup(device);
vkd3d: Back descriptor heaps with Vulkan descriptor sets if descriptor indexing is available. The existing implementation using virtual descriptor heaps, where Vk descriptor sets are created for the bindings in the root descriptor tables, is inefficient when multiple command lists are used with large descriptor heaps. It also cannot support updating a descriptor set after it is bound. This patch creates Vk sets for each D3D12 heap. Because D3D12 heaps can contain CBV, SRV and UAV descriptors in the same heap, multiple Vk sets are needed for each heap, however the total number of populated descriptors is never more than (heap size + UAV counter count). A new 'virtual_heaps' config option is introduced to make the old implementation available when needed. It's not always possible to determine if this is necessary when the device is created. Up to nine Vk descriptor sets may be used. It's theoretically possible to reduce this to eight by placing immutable samplers in the push descriptor set layout, but contradictions in earlier versions of the Vulkan spec made driver support inconsistent. The documentation was corrected in version 1.2.203. This patch also adds support for UAV counter descriptor arrays. It's not practical to add this in a separate patch due to complications with combining the old UAV counter implementation with the new descriptor heap implementation. Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47713 Wine-Bug: https://bugs.winehq.org/show_bug.cgi?id=47154 Signed-off-by: Conor McCarthy <cmccarthy@codeweavers.com> Signed-off-by: Henri Verbeet <hverbeet@codeweavers.com> Signed-off-by: Alexandre Julliard <julliard@winehq.org>
2022-02-21 07:18:59 -08:00
out_cleanup_uav_clear_state:
vkd3d_uav_clear_state_cleanup(&device->uav_clear_state, device);
out_destroy_null_resources:
vkd3d_destroy_null_resources(&device->null_resources, device);
out_cleanup_format_info:
vkd3d_cleanup_format_info(device);
out_free_private_store:
vkd3d_private_store_destroy(&device->private_store);
out_free_pipeline_cache:
d3d12_device_destroy_pipeline_cache(device);
out_free_vk_resources:
vk_procs = &device->vk_procs;
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 %s, \"%s\").\n",
device, debugstr_hresult(reason), vkd3d_dbg_vsprintf(message, args));
va_end(args);
device->removed_reason = reason;
}
HRESULT d3d12_device_add_descriptor_heap(struct d3d12_device *device, struct d3d12_descriptor_heap *heap)
{
vkd3d_mutex_lock(&device->worker_mutex);
if (!vkd3d_array_reserve((void **)&device->heaps, &device->heap_capacity, device->heap_count + 1,
sizeof(*device->heaps)))
{
vkd3d_mutex_unlock(&device->worker_mutex);
return E_OUTOFMEMORY;
}
device->heaps[device->heap_count++] = heap;
vkd3d_mutex_unlock(&device->worker_mutex);
return S_OK;
}
void d3d12_device_remove_descriptor_heap(struct d3d12_device *device, struct d3d12_descriptor_heap *heap)
{
size_t i;
vkd3d_mutex_lock(&device->worker_mutex);
for (i = 0; i < device->heap_count; ++i)
{
if (device->heaps[i] == heap)
{
device->heaps[i] = device->heaps[--device->heap_count];
break;
}
}
vkd3d_mutex_unlock(&device->worker_mutex);
}
#ifdef _WIN32
struct thread_data
{
PFN_vkd3d_thread main_pfn;
void *data;
};
static DWORD WINAPI call_thread_main(void *data)
{
struct thread_data *thread_data = data;
thread_data->main_pfn(thread_data->data);
vkd3d_free(thread_data);
return 0;
}
#endif
HRESULT vkd3d_create_thread(struct vkd3d_instance *instance,
PFN_vkd3d_thread thread_main, void *data, union vkd3d_thread_handle *thread)
{
HRESULT hr = S_OK;
if (instance->create_thread)
{
if (!(thread->handle = instance->create_thread(thread_main, data)))
{
ERR("Failed to create thread.\n");
hr = E_FAIL;
}
}
else
{
#ifdef _WIN32
struct thread_data *thread_data;
if (!(thread_data = vkd3d_malloc(sizeof(*thread_data))))
return E_OUTOFMEMORY;
thread_data->main_pfn = thread_main;
thread_data->data = data;
if (!(thread->handle = CreateThread(NULL, 0, call_thread_main, thread_data, 0, NULL)))
{
ERR("Failed to create thread, error %lu.\n", GetLastError());
vkd3d_free(thread_data);
hr = E_FAIL;
}
#else
int rc;
if ((rc = pthread_create(&thread->pthread, NULL, thread_main, data)))
{
ERR("Failed to create thread, error %d.\n", rc);
hr = hresult_from_errno(rc);
}
#endif
}
return hr;
}
HRESULT vkd3d_join_thread(struct vkd3d_instance *instance, union vkd3d_thread_handle *thread)
{
HRESULT hr = S_OK;
int rc;
if (instance->join_thread)
{
if (FAILED(hr = instance->join_thread(thread->handle)))
ERR("Failed to join thread, hr %s.\n", debugstr_hresult(hr));
}
else
{
#ifdef _WIN32
if ((rc = WaitForSingleObject(thread->handle, INFINITE)) != WAIT_OBJECT_0)
{
ERR("Failed to wait for thread, ret %#x.\n", rc);
hr = E_FAIL;
}
CloseHandle(thread->handle);
#else
if ((rc = pthread_join(thread->pthread, NULL)))
{
ERR("Failed to join thread, error %d.\n", rc);
hr = hresult_from_errno(rc);
}
#endif
}
return hr;
}
IUnknown *vkd3d_get_device_parent(ID3D12Device *device)
{
struct d3d12_device *d3d12_device = impl_from_ID3D12Device9((ID3D12Device9 *)device);
return d3d12_device->parent;
}
VkDevice vkd3d_get_vk_device(ID3D12Device *device)
{
struct d3d12_device *d3d12_device = impl_from_ID3D12Device9((ID3D12Device9 *)device);
return d3d12_device->vk_device;
}
VkPhysicalDevice vkd3d_get_vk_physical_device(ID3D12Device *device)
{
struct d3d12_device *d3d12_device = impl_from_ID3D12Device9((ID3D12Device9 *)device);
return d3d12_device->vk_physical_device;
}
struct vkd3d_instance *vkd3d_instance_from_device(ID3D12Device *device)
{
struct d3d12_device *d3d12_device = impl_from_ID3D12Device9((ID3D12Device9 *)device);
return d3d12_device->vkd3d_instance;
}