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video_core: Resolve more variable shadowing scenarios pt.2

Migrates the video core code closer to enabling variable shadowing
warnings as errors.

This primarily sorts out shadowing occurrences within the Vulkan code.
This commit is contained in:
Lioncash 2020-12-05 04:51:14 -05:00
parent e6a896c4bd
commit 414a87a4f4
39 changed files with 305 additions and 296 deletions

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@ -374,43 +374,43 @@ void VP9::InsertEntropy(u64 offset, Vp9EntropyProbs& dst) {
}
Vp9FrameContainer VP9::GetCurrentFrame(const NvdecCommon::NvdecRegisters& state) {
Vp9FrameContainer frame{};
Vp9FrameContainer current_frame{};
{
gpu.SyncGuestHost();
frame.info = GetVp9PictureInfo(state);
frame.bit_stream.resize(frame.info.bitstream_size);
gpu.MemoryManager().ReadBlock(state.frame_bitstream_offset, frame.bit_stream.data(),
frame.info.bitstream_size);
current_frame.info = GetVp9PictureInfo(state);
current_frame.bit_stream.resize(current_frame.info.bitstream_size);
gpu.MemoryManager().ReadBlock(state.frame_bitstream_offset, current_frame.bit_stream.data(),
current_frame.info.bitstream_size);
}
// Buffer two frames, saving the last show frame info
if (!next_next_frame.bit_stream.empty()) {
Vp9FrameContainer temp{
.info = frame.info,
.bit_stream = std::move(frame.bit_stream),
.info = current_frame.info,
.bit_stream = std::move(current_frame.bit_stream),
};
next_next_frame.info.show_frame = frame.info.last_frame_shown;
frame.info = next_next_frame.info;
frame.bit_stream = std::move(next_next_frame.bit_stream);
next_next_frame.info.show_frame = current_frame.info.last_frame_shown;
current_frame.info = next_next_frame.info;
current_frame.bit_stream = std::move(next_next_frame.bit_stream);
next_next_frame = std::move(temp);
if (!next_frame.bit_stream.empty()) {
Vp9FrameContainer temp2{
.info = frame.info,
.bit_stream = std::move(frame.bit_stream),
.info = current_frame.info,
.bit_stream = std::move(current_frame.bit_stream),
};
next_frame.info.show_frame = frame.info.last_frame_shown;
frame.info = next_frame.info;
frame.bit_stream = std::move(next_frame.bit_stream);
next_frame.info.show_frame = current_frame.info.last_frame_shown;
current_frame.info = next_frame.info;
current_frame.bit_stream = std::move(next_frame.bit_stream);
next_frame = std::move(temp2);
} else {
next_frame.info = frame.info;
next_frame.bit_stream = std::move(frame.bit_stream);
next_frame.info = current_frame.info;
next_frame.bit_stream = std::move(current_frame.bit_stream);
}
} else {
next_next_frame.info = frame.info;
next_next_frame.bit_stream = std::move(frame.bit_stream);
next_next_frame.info = current_frame.info;
next_next_frame.bit_stream = std::move(current_frame.bit_stream);
}
return frame;
return current_frame;
}
std::vector<u8> VP9::ComposeCompressedHeader() {

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@ -243,8 +243,8 @@ std::string BuildCommaSeparatedExtensions(std::vector<std::string> available_ext
RendererVulkan::RendererVulkan(Core::TelemetrySession& telemetry_session_,
Core::Frontend::EmuWindow& emu_window,
Core::Memory::Memory& cpu_memory_, Tegra::GPU& gpu_,
std::unique_ptr<Core::Frontend::GraphicsContext> context)
: RendererBase{emu_window, std::move(context)}, telemetry_session{telemetry_session_},
std::unique_ptr<Core::Frontend::GraphicsContext> context_)
: RendererBase{emu_window, std::move(context_)}, telemetry_session{telemetry_session_},
cpu_memory{cpu_memory_}, gpu{gpu_} {}
RendererVulkan::~RendererVulkan() {

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@ -45,9 +45,9 @@ struct VKScreenInfo {
class RendererVulkan final : public VideoCore::RendererBase {
public:
explicit RendererVulkan(Core::TelemetrySession& telemtry_session,
Core::Frontend::EmuWindow& emu_window, Core::Memory::Memory& cpu_memory,
Tegra::GPU& gpu,
std::unique_ptr<Core::Frontend::GraphicsContext> context);
Core::Frontend::EmuWindow& emu_window,
Core::Memory::Memory& cpu_memory_, Tegra::GPU& gpu_,
std::unique_ptr<Core::Frontend::GraphicsContext> context_);
~RendererVulkan() override;
bool Init() override;

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@ -461,15 +461,15 @@ VkDescriptorSet VKComputePass::CommitDescriptorSet(
return set;
}
QuadArrayPass::QuadArrayPass(const VKDevice& device, VKScheduler& scheduler,
VKDescriptorPool& descriptor_pool,
VKStagingBufferPool& staging_buffer_pool,
VKUpdateDescriptorQueue& update_descriptor_queue)
: VKComputePass(device, descriptor_pool, BuildQuadArrayPassDescriptorSetLayoutBinding(),
QuadArrayPass::QuadArrayPass(const VKDevice& device_, VKScheduler& scheduler_,
VKDescriptorPool& descriptor_pool_,
VKStagingBufferPool& staging_buffer_pool_,
VKUpdateDescriptorQueue& update_descriptor_queue_)
: VKComputePass(device_, descriptor_pool_, BuildQuadArrayPassDescriptorSetLayoutBinding(),
BuildQuadArrayPassDescriptorUpdateTemplateEntry(),
BuildComputePushConstantRange(sizeof(u32)), std::size(quad_array), quad_array),
scheduler{scheduler}, staging_buffer_pool{staging_buffer_pool},
update_descriptor_queue{update_descriptor_queue} {}
scheduler{scheduler_}, staging_buffer_pool{staging_buffer_pool_},
update_descriptor_queue{update_descriptor_queue_} {}
QuadArrayPass::~QuadArrayPass() = default;
@ -510,14 +510,14 @@ std::pair<VkBuffer, VkDeviceSize> QuadArrayPass::Assemble(u32 num_vertices, u32
return {*buffer.handle, 0};
}
Uint8Pass::Uint8Pass(const VKDevice& device, VKScheduler& scheduler,
VKDescriptorPool& descriptor_pool, VKStagingBufferPool& staging_buffer_pool,
VKUpdateDescriptorQueue& update_descriptor_queue)
: VKComputePass(device, descriptor_pool, BuildInputOutputDescriptorSetBindings(),
Uint8Pass::Uint8Pass(const VKDevice& device_, VKScheduler& scheduler_,
VKDescriptorPool& descriptor_pool_, VKStagingBufferPool& staging_buffer_pool_,
VKUpdateDescriptorQueue& update_descriptor_queue_)
: VKComputePass(device_, descriptor_pool_, BuildInputOutputDescriptorSetBindings(),
BuildInputOutputDescriptorUpdateTemplate(), {}, std::size(uint8_pass),
uint8_pass),
scheduler{scheduler}, staging_buffer_pool{staging_buffer_pool},
update_descriptor_queue{update_descriptor_queue} {}
scheduler{scheduler_}, staging_buffer_pool{staging_buffer_pool_},
update_descriptor_queue{update_descriptor_queue_} {}
Uint8Pass::~Uint8Pass() = default;
@ -555,16 +555,16 @@ std::pair<VkBuffer, u64> Uint8Pass::Assemble(u32 num_vertices, VkBuffer src_buff
return {*buffer.handle, 0};
}
QuadIndexedPass::QuadIndexedPass(const VKDevice& device, VKScheduler& scheduler,
VKDescriptorPool& descriptor_pool,
VKStagingBufferPool& staging_buffer_pool,
VKUpdateDescriptorQueue& update_descriptor_queue)
: VKComputePass(device, descriptor_pool, BuildInputOutputDescriptorSetBindings(),
QuadIndexedPass::QuadIndexedPass(const VKDevice& device_, VKScheduler& scheduler_,
VKDescriptorPool& descriptor_pool_,
VKStagingBufferPool& staging_buffer_pool_,
VKUpdateDescriptorQueue& update_descriptor_queue_)
: VKComputePass(device_, descriptor_pool_, BuildInputOutputDescriptorSetBindings(),
BuildInputOutputDescriptorUpdateTemplate(),
BuildComputePushConstantRange(sizeof(u32) * 2), std::size(QUAD_INDEXED_SPV),
QUAD_INDEXED_SPV),
scheduler{scheduler}, staging_buffer_pool{staging_buffer_pool},
update_descriptor_queue{update_descriptor_queue} {}
scheduler{scheduler_}, staging_buffer_pool{staging_buffer_pool_},
update_descriptor_queue{update_descriptor_queue_} {}
QuadIndexedPass::~QuadIndexedPass() = default;

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@ -43,10 +43,10 @@ private:
class QuadArrayPass final : public VKComputePass {
public:
explicit QuadArrayPass(const VKDevice& device, VKScheduler& scheduler,
VKDescriptorPool& descriptor_pool,
VKStagingBufferPool& staging_buffer_pool,
VKUpdateDescriptorQueue& update_descriptor_queue);
explicit QuadArrayPass(const VKDevice& device_, VKScheduler& scheduler_,
VKDescriptorPool& descriptor_pool_,
VKStagingBufferPool& staging_buffer_pool_,
VKUpdateDescriptorQueue& update_descriptor_queue_);
~QuadArrayPass();
std::pair<VkBuffer, VkDeviceSize> Assemble(u32 num_vertices, u32 first);
@ -59,9 +59,10 @@ private:
class Uint8Pass final : public VKComputePass {
public:
explicit Uint8Pass(const VKDevice& device, VKScheduler& scheduler,
VKDescriptorPool& descriptor_pool, VKStagingBufferPool& staging_buffer_pool,
VKUpdateDescriptorQueue& update_descriptor_queue);
explicit Uint8Pass(const VKDevice& device_, VKScheduler& scheduler_,
VKDescriptorPool& descriptor_pool_,
VKStagingBufferPool& staging_buffer_pool_,
VKUpdateDescriptorQueue& update_descriptor_queue_);
~Uint8Pass();
std::pair<VkBuffer, u64> Assemble(u32 num_vertices, VkBuffer src_buffer, u64 src_offset);
@ -74,10 +75,10 @@ private:
class QuadIndexedPass final : public VKComputePass {
public:
explicit QuadIndexedPass(const VKDevice& device, VKScheduler& scheduler,
VKDescriptorPool& descriptor_pool,
VKStagingBufferPool& staging_buffer_pool,
VKUpdateDescriptorQueue& update_descriptor_queue);
explicit QuadIndexedPass(const VKDevice& device_, VKScheduler& scheduler_,
VKDescriptorPool& descriptor_pool_,
VKStagingBufferPool& staging_buffer_pool_,
VKUpdateDescriptorQueue& update_descriptor_queue_);
~QuadIndexedPass();
std::pair<VkBuffer, u64> Assemble(Tegra::Engines::Maxwell3D::Regs::IndexFormat index_format,

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@ -15,16 +15,16 @@
namespace Vulkan {
VKComputePipeline::VKComputePipeline(const VKDevice& device, VKScheduler& scheduler,
VKDescriptorPool& descriptor_pool,
VKUpdateDescriptorQueue& update_descriptor_queue,
const SPIRVShader& shader)
: device{device}, scheduler{scheduler}, entries{shader.entries},
VKComputePipeline::VKComputePipeline(const VKDevice& device_, VKScheduler& scheduler_,
VKDescriptorPool& descriptor_pool_,
VKUpdateDescriptorQueue& update_descriptor_queue_,
const SPIRVShader& shader_)
: device{device_}, scheduler{scheduler_}, entries{shader_.entries},
descriptor_set_layout{CreateDescriptorSetLayout()},
descriptor_allocator{descriptor_pool, *descriptor_set_layout},
update_descriptor_queue{update_descriptor_queue}, layout{CreatePipelineLayout()},
descriptor_allocator{descriptor_pool_, *descriptor_set_layout},
update_descriptor_queue{update_descriptor_queue_}, layout{CreatePipelineLayout()},
descriptor_template{CreateDescriptorUpdateTemplate()},
shader_module{CreateShaderModule(shader.code)}, pipeline{CreatePipeline()} {}
shader_module{CreateShaderModule(shader_.code)}, pipeline{CreatePipeline()} {}
VKComputePipeline::~VKComputePipeline() = default;

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@ -17,10 +17,10 @@ class VKUpdateDescriptorQueue;
class VKComputePipeline final {
public:
explicit VKComputePipeline(const VKDevice& device, VKScheduler& scheduler,
VKDescriptorPool& descriptor_pool,
VKUpdateDescriptorQueue& update_descriptor_queue,
const SPIRVShader& shader);
explicit VKComputePipeline(const VKDevice& device_, VKScheduler& scheduler_,
VKDescriptorPool& descriptor_pool_,
VKUpdateDescriptorQueue& update_descriptor_queue_,
const SPIRVShader& shader_);
~VKComputePipeline();
VkDescriptorSet CommitDescriptorSet();

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@ -491,8 +491,8 @@ bool VKDevice::IsOptimalAstcSupported(const VkPhysicalDeviceFeatures& features)
VK_FORMAT_FEATURE_BLIT_DST_BIT | VK_FORMAT_FEATURE_TRANSFER_SRC_BIT |
VK_FORMAT_FEATURE_TRANSFER_DST_BIT};
for (const auto format : astc_formats) {
const auto format_properties{physical.GetFormatProperties(format)};
if (!(format_properties.optimalTilingFeatures & format_feature_usage)) {
const auto physical_format_properties{physical.GetFormatProperties(format)};
if ((physical_format_properties.optimalTilingFeatures & format_feature_usage) == 0) {
return false;
}
}
@ -644,8 +644,8 @@ std::vector<const char*> VKDevice::LoadExtensions() {
VkPhysicalDeviceFeatures2KHR features;
features.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_FEATURES_2_KHR;
VkPhysicalDeviceProperties2KHR properties;
properties.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_PROPERTIES_2_KHR;
VkPhysicalDeviceProperties2KHR physical_properties;
physical_properties.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_PROPERTIES_2_KHR;
if (has_khr_shader_float16_int8) {
VkPhysicalDeviceFloat16Int8FeaturesKHR float16_int8_features;
@ -670,8 +670,8 @@ std::vector<const char*> VKDevice::LoadExtensions() {
subgroup_properties.sType =
VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_SUBGROUP_SIZE_CONTROL_PROPERTIES_EXT;
subgroup_properties.pNext = nullptr;
properties.pNext = &subgroup_properties;
physical.GetProperties2KHR(properties);
physical_properties.pNext = &subgroup_properties;
physical.GetProperties2KHR(physical_properties);
is_warp_potentially_bigger = subgroup_properties.maxSubgroupSize > GuestWarpSize;
@ -695,8 +695,8 @@ std::vector<const char*> VKDevice::LoadExtensions() {
VkPhysicalDeviceTransformFeedbackPropertiesEXT tfb_properties;
tfb_properties.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_TRANSFORM_FEEDBACK_PROPERTIES_EXT;
tfb_properties.pNext = nullptr;
properties.pNext = &tfb_properties;
physical.GetProperties2KHR(properties);
physical_properties.pNext = &tfb_properties;
physical.GetProperties2KHR(physical_properties);
if (tfb_features.transformFeedback && tfb_features.geometryStreams &&
tfb_properties.maxTransformFeedbackStreams >= 4 &&

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@ -14,12 +14,13 @@
namespace Vulkan {
InnerFence::InnerFence(const VKDevice& device, VKScheduler& scheduler, u32 payload, bool is_stubbed)
: VideoCommon::FenceBase(payload, is_stubbed), device{device}, scheduler{scheduler} {}
InnerFence::InnerFence(const VKDevice& device_, VKScheduler& scheduler_, u32 payload_,
bool is_stubbed_)
: FenceBase{payload_, is_stubbed_}, device{device_}, scheduler{scheduler_} {}
InnerFence::InnerFence(const VKDevice& device, VKScheduler& scheduler, GPUVAddr address,
u32 payload, bool is_stubbed)
: VideoCommon::FenceBase(address, payload, is_stubbed), device{device}, scheduler{scheduler} {}
InnerFence::InnerFence(const VKDevice& device_, VKScheduler& scheduler_, GPUVAddr address_,
u32 payload_, bool is_stubbed_)
: FenceBase{address_, payload_, is_stubbed_}, device{device_}, scheduler{scheduler_} {}
InnerFence::~InnerFence() = default;
@ -71,11 +72,12 @@ bool InnerFence::IsEventSignalled() const {
}
}
VKFenceManager::VKFenceManager(VideoCore::RasterizerInterface& rasterizer, Tegra::GPU& gpu,
Tegra::MemoryManager& memory_manager, VKTextureCache& texture_cache,
VKBufferCache& buffer_cache, VKQueryCache& query_cache,
const VKDevice& device_, VKScheduler& scheduler_)
: GenericFenceManager(rasterizer, gpu, texture_cache, buffer_cache, query_cache),
VKFenceManager::VKFenceManager(VideoCore::RasterizerInterface& rasterizer_, Tegra::GPU& gpu_,
Tegra::MemoryManager& memory_manager_,
VKTextureCache& texture_cache_, VKBufferCache& buffer_cache_,
VKQueryCache& query_cache_, const VKDevice& device_,
VKScheduler& scheduler_)
: GenericFenceManager{rasterizer_, gpu_, texture_cache_, buffer_cache_, query_cache_},
device{device_}, scheduler{scheduler_} {}
Fence VKFenceManager::CreateFence(u32 value, bool is_stubbed) {

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@ -28,10 +28,10 @@ class VKTextureCache;
class InnerFence : public VideoCommon::FenceBase {
public:
explicit InnerFence(const VKDevice& device, VKScheduler& scheduler, u32 payload,
bool is_stubbed);
explicit InnerFence(const VKDevice& device, VKScheduler& scheduler, GPUVAddr address,
u32 payload, bool is_stubbed);
explicit InnerFence(const VKDevice& device_, VKScheduler& scheduler_, u32 payload_,
bool is_stubbed_);
explicit InnerFence(const VKDevice& device_, VKScheduler& scheduler_, GPUVAddr address_,
u32 payload_, bool is_stubbed_);
~InnerFence();
void Queue();
@ -55,10 +55,10 @@ using GenericFenceManager =
class VKFenceManager final : public GenericFenceManager {
public:
explicit VKFenceManager(VideoCore::RasterizerInterface& rasterizer, Tegra::GPU& gpu,
Tegra::MemoryManager& memory_manager, VKTextureCache& texture_cache,
VKBufferCache& buffer_cache, VKQueryCache& query_cache,
const VKDevice& device, VKScheduler& scheduler);
explicit VKFenceManager(VideoCore::RasterizerInterface& rasterizer_, Tegra::GPU& gpu_,
Tegra::MemoryManager& memory_manager_, VKTextureCache& texture_cache_,
VKBufferCache& buffer_cache_, VKQueryCache& query_cache_,
const VKDevice& device_, VKScheduler& scheduler_);
protected:
Fence CreateFence(u32 value, bool is_stubbed) override;

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@ -71,21 +71,21 @@ VkViewportSwizzleNV UnpackViewportSwizzle(u16 swizzle) {
} // Anonymous namespace
VKGraphicsPipeline::VKGraphicsPipeline(const VKDevice& device, VKScheduler& scheduler,
VKDescriptorPool& descriptor_pool,
VKUpdateDescriptorQueue& update_descriptor_queue,
VKRenderPassCache& renderpass_cache,
const GraphicsPipelineCacheKey& key,
vk::Span<VkDescriptorSetLayoutBinding> bindings,
const SPIRVProgram& program)
: device{device}, scheduler{scheduler}, cache_key{key}, hash{cache_key.Hash()},
descriptor_set_layout{CreateDescriptorSetLayout(bindings)},
descriptor_allocator{descriptor_pool, *descriptor_set_layout},
update_descriptor_queue{update_descriptor_queue}, layout{CreatePipelineLayout()},
descriptor_template{CreateDescriptorUpdateTemplate(program)}, modules{CreateShaderModules(
program)},
renderpass{renderpass_cache.GetRenderPass(cache_key.renderpass_params)},
pipeline{CreatePipeline(cache_key.renderpass_params, program)} {}
VKGraphicsPipeline::VKGraphicsPipeline(const VKDevice& device_, VKScheduler& scheduler_,
VKDescriptorPool& descriptor_pool_,
VKUpdateDescriptorQueue& update_descriptor_queue_,
VKRenderPassCache& renderpass_cache_,
const GraphicsPipelineCacheKey& key_,
vk::Span<VkDescriptorSetLayoutBinding> bindings_,
const SPIRVProgram& program_)
: device{device_}, scheduler{scheduler_}, cache_key{key_}, hash{cache_key.Hash()},
descriptor_set_layout{CreateDescriptorSetLayout(bindings_)},
descriptor_allocator{descriptor_pool_, *descriptor_set_layout},
update_descriptor_queue{update_descriptor_queue_}, layout{CreatePipelineLayout()},
descriptor_template{CreateDescriptorUpdateTemplate(program_)}, modules{CreateShaderModules(
program_)},
renderpass{renderpass_cache_.GetRenderPass(cache_key.renderpass_params)},
pipeline{CreatePipeline(cache_key.renderpass_params, program_)} {}
VKGraphicsPipeline::~VKGraphicsPipeline() = default;
@ -162,8 +162,8 @@ std::vector<vk::ShaderModule> VKGraphicsPipeline::CreateShaderModules(
.codeSize = 0,
};
std::vector<vk::ShaderModule> modules;
modules.reserve(Maxwell::MaxShaderStage);
std::vector<vk::ShaderModule> shader_modules;
shader_modules.reserve(Maxwell::MaxShaderStage);
for (std::size_t i = 0; i < Maxwell::MaxShaderStage; ++i) {
const auto& stage = program[i];
if (!stage) {
@ -174,9 +174,9 @@ std::vector<vk::ShaderModule> VKGraphicsPipeline::CreateShaderModules(
ci.codeSize = stage->code.size() * sizeof(u32);
ci.pCode = stage->code.data();
modules.push_back(device.GetLogical().CreateShaderModule(ci));
shader_modules.push_back(device.GetLogical().CreateShaderModule(ci));
}
return modules;
return shader_modules;
}
vk::Pipeline VKGraphicsPipeline::CreatePipeline(const RenderPassParams& renderpass_params,

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@ -51,13 +51,13 @@ using SPIRVProgram = std::array<std::optional<SPIRVShader>, Maxwell::MaxShaderSt
class VKGraphicsPipeline final {
public:
explicit VKGraphicsPipeline(const VKDevice& device, VKScheduler& scheduler,
VKDescriptorPool& descriptor_pool,
VKUpdateDescriptorQueue& update_descriptor_queue,
VKRenderPassCache& renderpass_cache,
const GraphicsPipelineCacheKey& key,
vk::Span<VkDescriptorSetLayoutBinding> bindings,
const SPIRVProgram& program);
explicit VKGraphicsPipeline(const VKDevice& device_, VKScheduler& scheduler_,
VKDescriptorPool& descriptor_pool_,
VKUpdateDescriptorQueue& update_descriptor_queue_,
VKRenderPassCache& renderpass_cache_,
const GraphicsPipelineCacheKey& key_,
vk::Span<VkDescriptorSetLayoutBinding> bindings_,
const SPIRVProgram& program_);
~VKGraphicsPipeline();
VkDescriptorSet CommitDescriptorSet();

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@ -13,18 +13,18 @@
namespace Vulkan {
VKImage::VKImage(const VKDevice& device, VKScheduler& scheduler, const VkImageCreateInfo& image_ci,
VkImageAspectFlags aspect_mask)
: device{device}, scheduler{scheduler}, format{image_ci.format}, aspect_mask{aspect_mask},
image_num_layers{image_ci.arrayLayers}, image_num_levels{image_ci.mipLevels} {
UNIMPLEMENTED_IF_MSG(image_ci.queueFamilyIndexCount != 0,
VKImage::VKImage(const VKDevice& device_, VKScheduler& scheduler_,
const VkImageCreateInfo& image_ci_, VkImageAspectFlags aspect_mask_)
: device{device_}, scheduler{scheduler_}, format{image_ci_.format}, aspect_mask{aspect_mask_},
image_num_layers{image_ci_.arrayLayers}, image_num_levels{image_ci_.mipLevels} {
UNIMPLEMENTED_IF_MSG(image_ci_.queueFamilyIndexCount != 0,
"Queue family tracking is not implemented");
image = device.GetLogical().CreateImage(image_ci);
image = device_.GetLogical().CreateImage(image_ci_);
const u32 num_ranges = image_num_layers * image_num_levels;
barriers.resize(num_ranges);
subrange_states.resize(num_ranges, {{}, image_ci.initialLayout});
subrange_states.resize(num_ranges, {{}, image_ci_.initialLayout});
}
VKImage::~VKImage() = default;

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@ -17,8 +17,8 @@ class VKScheduler;
class VKImage {
public:
explicit VKImage(const VKDevice& device, VKScheduler& scheduler,
const VkImageCreateInfo& image_ci, VkImageAspectFlags aspect_mask);
explicit VKImage(const VKDevice& device_, VKScheduler& scheduler_,
const VkImageCreateInfo& image_ci_, VkImageAspectFlags aspect_mask_);
~VKImage();
/// Records in the passed command buffer an image transition and updates the state of the image.

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@ -29,10 +29,10 @@ u64 GetAllocationChunkSize(u64 required_size) {
class VKMemoryAllocation final {
public:
explicit VKMemoryAllocation(const VKDevice& device, vk::DeviceMemory memory,
VkMemoryPropertyFlags properties, u64 allocation_size, u32 type)
: device{device}, memory{std::move(memory)}, properties{properties},
allocation_size{allocation_size}, shifted_type{ShiftType(type)} {}
explicit VKMemoryAllocation(const VKDevice& device_, vk::DeviceMemory memory_,
VkMemoryPropertyFlags properties_, u64 allocation_size_, u32 type_)
: device{device_}, memory{std::move(memory_)}, properties{properties_},
allocation_size{allocation_size_}, shifted_type{ShiftType(type_)} {}
VKMemoryCommit Commit(VkDeviceSize commit_size, VkDeviceSize alignment) {
auto found = TryFindFreeSection(free_iterator, allocation_size,
@ -117,8 +117,8 @@ private:
std::vector<const VKMemoryCommitImpl*> commits;
};
VKMemoryManager::VKMemoryManager(const VKDevice& device)
: device{device}, properties{device.GetPhysical().GetMemoryProperties()} {}
VKMemoryManager::VKMemoryManager(const VKDevice& device_)
: device{device_}, properties{device_.GetPhysical().GetMemoryProperties()} {}
VKMemoryManager::~VKMemoryManager() = default;
@ -207,9 +207,9 @@ VKMemoryCommit VKMemoryManager::TryAllocCommit(const VkMemoryRequirements& requi
return {};
}
VKMemoryCommitImpl::VKMemoryCommitImpl(const VKDevice& device, VKMemoryAllocation* allocation,
const vk::DeviceMemory& memory, u64 begin, u64 end)
: device{device}, memory{memory}, interval{begin, end}, allocation{allocation} {}
VKMemoryCommitImpl::VKMemoryCommitImpl(const VKDevice& device_, VKMemoryAllocation* allocation_,
const vk::DeviceMemory& memory_, u64 begin_, u64 end_)
: device{device_}, memory{memory_}, interval{begin_, end_}, allocation{allocation_} {}
VKMemoryCommitImpl::~VKMemoryCommitImpl() {
allocation->Free(this);

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@ -21,7 +21,7 @@ using VKMemoryCommit = std::unique_ptr<VKMemoryCommitImpl>;
class VKMemoryManager final {
public:
explicit VKMemoryManager(const VKDevice& device);
explicit VKMemoryManager(const VKDevice& device_);
VKMemoryManager(const VKMemoryManager&) = delete;
~VKMemoryManager();
@ -58,8 +58,8 @@ class VKMemoryCommitImpl final {
friend MemoryMap;
public:
explicit VKMemoryCommitImpl(const VKDevice& device, VKMemoryAllocation* allocation,
const vk::DeviceMemory& memory, u64 begin, u64 end);
explicit VKMemoryCommitImpl(const VKDevice& device_, VKMemoryAllocation* allocation_,
const vk::DeviceMemory& memory_, u64 begin_, u64 end_);
~VKMemoryCommitImpl();
/// Maps a memory region and returns a pointer to it.
@ -93,8 +93,8 @@ private:
/// Holds ownership of a memory map.
class MemoryMap final {
public:
explicit MemoryMap(const VKMemoryCommitImpl* commit, u8* address)
: commit{commit}, address{address} {}
explicit MemoryMap(const VKMemoryCommitImpl* commit_, u8* address_)
: commit{commit_}, address{address_} {}
~MemoryMap() {
if (commit) {

View File

@ -66,15 +66,15 @@ void QueryPool::Reserve(std::pair<VkQueryPool, u32> query) {
usage[pool_index * GROW_STEP + static_cast<std::ptrdiff_t>(query.second)] = false;
}
VKQueryCache::VKQueryCache(VideoCore::RasterizerInterface& rasterizer,
Tegra::Engines::Maxwell3D& maxwell3d, Tegra::MemoryManager& gpu_memory,
const VKDevice& device, VKScheduler& scheduler)
: VideoCommon::QueryCacheBase<VKQueryCache, CachedQuery, CounterStream,
HostCounter>{rasterizer, maxwell3d, gpu_memory},
device{device}, scheduler{scheduler}, query_pools{
QueryPool{device, scheduler,
QueryType::SamplesPassed},
} {}
VKQueryCache::VKQueryCache(VideoCore::RasterizerInterface& rasterizer_,
Tegra::Engines::Maxwell3D& maxwell3d_, Tegra::MemoryManager& gpu_memory_,
const VKDevice& device_, VKScheduler& scheduler_)
: QueryCacheBase<VKQueryCache, CachedQuery, CounterStream, HostCounter>{rasterizer_, maxwell3d_,
gpu_memory_},
device{device_}, scheduler{scheduler_}, query_pools{
QueryPool{device_, scheduler_,
QueryType::SamplesPassed},
} {}
VKQueryCache::~VKQueryCache() {
// TODO(Rodrigo): This is a hack to destroy all HostCounter instances before the base class
@ -95,12 +95,12 @@ void VKQueryCache::Reserve(QueryType type, std::pair<VkQueryPool, u32> query) {
query_pools[static_cast<std::size_t>(type)].Reserve(query);
}
HostCounter::HostCounter(VKQueryCache& cache, std::shared_ptr<HostCounter> dependency,
QueryType type)
: VideoCommon::HostCounterBase<VKQueryCache, HostCounter>{std::move(dependency)}, cache{cache},
type{type}, query{cache.AllocateQuery(type)}, tick{cache.Scheduler().CurrentTick()} {
const vk::Device* logical = &cache.Device().GetLogical();
cache.Scheduler().Record([logical, query = query](vk::CommandBuffer cmdbuf) {
HostCounter::HostCounter(VKQueryCache& cache_, std::shared_ptr<HostCounter> dependency_,
QueryType type_)
: HostCounterBase<VKQueryCache, HostCounter>{std::move(dependency_)}, cache{cache_},
type{type_}, query{cache_.AllocateQuery(type_)}, tick{cache_.Scheduler().CurrentTick()} {
const vk::Device* logical = &cache_.Device().GetLogical();
cache_.Scheduler().Record([logical, query = query](vk::CommandBuffer cmdbuf) {
logical->ResetQueryPoolEXT(query.first, query.second, 1);
cmdbuf.BeginQuery(query.first, query.second, VK_QUERY_CONTROL_PRECISE_BIT);
});

View File

@ -53,9 +53,9 @@ private:
class VKQueryCache final
: public VideoCommon::QueryCacheBase<VKQueryCache, CachedQuery, CounterStream, HostCounter> {
public:
explicit VKQueryCache(VideoCore::RasterizerInterface& rasterizer,
Tegra::Engines::Maxwell3D& maxwell3d, Tegra::MemoryManager& gpu_memory,
const VKDevice& device, VKScheduler& scheduler);
explicit VKQueryCache(VideoCore::RasterizerInterface& rasterizer_,
Tegra::Engines::Maxwell3D& maxwell3d_, Tegra::MemoryManager& gpu_memory_,
const VKDevice& device_, VKScheduler& scheduler_);
~VKQueryCache();
std::pair<VkQueryPool, u32> AllocateQuery(VideoCore::QueryType type);
@ -78,8 +78,8 @@ private:
class HostCounter final : public VideoCommon::HostCounterBase<VKQueryCache, HostCounter> {
public:
explicit HostCounter(VKQueryCache& cache, std::shared_ptr<HostCounter> dependency,
VideoCore::QueryType type);
explicit HostCounter(VKQueryCache& cache_, std::shared_ptr<HostCounter> dependency_,
VideoCore::QueryType type_);
~HostCounter();
void EndQuery();

View File

@ -904,15 +904,14 @@ void RasterizerVulkan::SetupShaderDescriptors(
texture_cache.GuardSamplers(false);
}
void RasterizerVulkan::SetupImageTransitions(
Texceptions texceptions, const std::array<View, Maxwell::NumRenderTargets>& color_attachments,
const View& zeta_attachment) {
void RasterizerVulkan::SetupImageTransitions(Texceptions texceptions, const ColorAttachments& color,
const ZetaAttachment& zeta) {
TransitionImages(sampled_views, VK_PIPELINE_STAGE_ALL_GRAPHICS_BIT, VK_ACCESS_SHADER_READ_BIT);
TransitionImages(image_views, VK_PIPELINE_STAGE_ALL_GRAPHICS_BIT,
VK_ACCESS_SHADER_READ_BIT | VK_ACCESS_SHADER_WRITE_BIT);
for (std::size_t rt = 0; rt < std::size(color_attachments); ++rt) {
const auto color_attachment = color_attachments[rt];
for (std::size_t rt = 0; rt < color.size(); ++rt) {
const auto color_attachment = color[rt];
if (color_attachment == nullptr) {
continue;
}
@ -923,13 +922,13 @@ void RasterizerVulkan::SetupImageTransitions(
VK_ACCESS_COLOR_ATTACHMENT_WRITE_BIT);
}
if (zeta_attachment != nullptr) {
if (zeta != nullptr) {
const auto image_layout = texceptions[ZETA_TEXCEPTION_INDEX]
? VK_IMAGE_LAYOUT_GENERAL
: VK_IMAGE_LAYOUT_DEPTH_STENCIL_ATTACHMENT_OPTIMAL;
zeta_attachment->Transition(image_layout, VK_PIPELINE_STAGE_LATE_FRAGMENT_TESTS_BIT,
VK_ACCESS_DEPTH_STENCIL_ATTACHMENT_READ_BIT |
VK_ACCESS_DEPTH_STENCIL_ATTACHMENT_WRITE_BIT);
zeta->Transition(image_layout, VK_PIPELINE_STAGE_LATE_FRAGMENT_TESTS_BIT,
VK_ACCESS_DEPTH_STENCIL_ATTACHMENT_READ_BIT |
VK_ACCESS_DEPTH_STENCIL_ATTACHMENT_WRITE_BIT);
}
}

View File

@ -160,6 +160,9 @@ private:
bool is_indexed = 0;
};
using ColorAttachments = std::array<View, Maxwell::NumRenderTargets>;
using ZetaAttachment = View;
using Texceptions = std::bitset<Maxwell::NumRenderTargets + 1>;
static constexpr std::size_t ZETA_TEXCEPTION_INDEX = 8;
@ -181,9 +184,8 @@ private:
/// Setup descriptors in the graphics pipeline.
void SetupShaderDescriptors(const std::array<Shader*, Maxwell::MaxShaderProgram>& shaders);
void SetupImageTransitions(Texceptions texceptions,
const std::array<View, Maxwell::NumRenderTargets>& color_attachments,
const View& zeta_attachment);
void SetupImageTransitions(Texceptions texceptions, const ColorAttachments& color,
const ZetaAttachment& zeta);
void UpdateDynamicStates();
@ -308,8 +310,8 @@ private:
vk::Event wfi_event;
VideoCommon::Shader::AsyncShaders async_shaders;
std::array<View, Maxwell::NumRenderTargets> color_attachments;
View zeta_attachment;
ColorAttachments color_attachments;
ZetaAttachment zeta_attachment;
std::vector<ImageView> sampled_views;
std::vector<ImageView> image_views;

View File

@ -24,7 +24,7 @@ bool RenderPassParams::operator==(const RenderPassParams& rhs) const noexcept {
return std::memcmp(&rhs, this, sizeof *this) == 0;
}
VKRenderPassCache::VKRenderPassCache(const VKDevice& device) : device{device} {}
VKRenderPassCache::VKRenderPassCache(const VKDevice& device_) : device{device_} {}
VKRenderPassCache::~VKRenderPassCache() = default;

View File

@ -55,7 +55,7 @@ namespace Vulkan {
class VKRenderPassCache final {
public:
explicit VKRenderPassCache(const VKDevice& device);
explicit VKRenderPassCache(const VKDevice& device_);
~VKRenderPassCache();
VkRenderPass GetRenderPass(const RenderPassParams& params);

View File

@ -36,7 +36,7 @@ VkBorderColor ConvertBorderColor(std::array<float, 4> color) {
} // Anonymous namespace
VKSamplerCache::VKSamplerCache(const VKDevice& device) : device{device} {}
VKSamplerCache::VKSamplerCache(const VKDevice& device_) : device{device_} {}
VKSamplerCache::~VKSamplerCache() = default;

View File

@ -14,7 +14,7 @@ class VKDevice;
class VKSamplerCache final : public VideoCommon::SamplerCache<VkSampler, vk::Sampler> {
public:
explicit VKSamplerCache(const VKDevice& device);
explicit VKSamplerCache(const VKDevice& device_);
~VKSamplerCache();
protected:

View File

@ -104,7 +104,7 @@ private:
template <typename T>
class TypedCommand final : public Command {
public:
explicit TypedCommand(T&& command) : command{std::move(command)} {}
explicit TypedCommand(T&& command_) : command{std::move(command_)} {}
~TypedCommand() override = default;
TypedCommand(TypedCommand&&) = delete;

View File

@ -55,8 +55,8 @@ enum class Type { Void, Bool, Bool2, Float, Int, Uint, HalfFloat };
class Expression final {
public:
Expression(Id id, Type type) : id{id}, type{type} {
ASSERT(type != Type::Void);
Expression(Id id_, Type type_) : id{id_}, type{type_} {
ASSERT(type_ != Type::Void);
}
Expression() : type{Type::Void} {}
@ -281,12 +281,12 @@ u32 ShaderVersion(const VKDevice& device) {
class SPIRVDecompiler final : public Sirit::Module {
public:
explicit SPIRVDecompiler(const VKDevice& device, const ShaderIR& ir, ShaderType stage,
const Registry& registry, const Specialization& specialization)
: Module(ShaderVersion(device)), device{device}, ir{ir}, stage{stage},
header{ir.GetHeader()}, registry{registry}, specialization{specialization} {
if (stage != ShaderType::Compute) {
transform_feedback = BuildTransformFeedback(registry.GetGraphicsInfo());
explicit SPIRVDecompiler(const VKDevice& device_, const ShaderIR& ir_, ShaderType stage_,
const Registry& registry_, const Specialization& specialization_)
: Module(ShaderVersion(device_)), device{device_}, ir{ir_}, stage{stage_},
header{ir_.GetHeader()}, registry{registry_}, specialization{specialization_} {
if (stage_ != ShaderType::Compute) {
transform_feedback = BuildTransformFeedback(registry_.GetGraphicsInfo());
}
AddCapability(spv::Capability::Shader);
@ -330,7 +330,7 @@ public:
if (device.IsFloat16Supported()) {
AddCapability(spv::Capability::Float16);
}
t_scalar_half = Name(TypeFloat(device.IsFloat16Supported() ? 16 : 32), "scalar_half");
t_scalar_half = Name(TypeFloat(device_.IsFloat16Supported() ? 16 : 32), "scalar_half");
t_half = Name(TypeVector(t_scalar_half, 2), "half");
const Id main = Decompile();
@ -1088,9 +1088,9 @@ private:
indices.point_size = AddBuiltIn(t_float, spv::BuiltIn::PointSize, "point_size");
}
const auto& output_attributes = ir.GetOutputAttributes();
const bool declare_clip_distances =
std::any_of(output_attributes.begin(), output_attributes.end(), [](const auto& index) {
const auto& ir_output_attributes = ir.GetOutputAttributes();
const bool declare_clip_distances = std::any_of(
ir_output_attributes.begin(), ir_output_attributes.end(), [](const auto& index) {
return index == Attribute::Index::ClipDistances0123 ||
index == Attribute::Index::ClipDistances4567;
});
@ -2891,7 +2891,7 @@ private:
class ExprDecompiler {
public:
explicit ExprDecompiler(SPIRVDecompiler& decomp) : decomp{decomp} {}
explicit ExprDecompiler(SPIRVDecompiler& decomp_) : decomp{decomp_} {}
Id operator()(const ExprAnd& expr) {
const Id type_def = decomp.GetTypeDefinition(Type::Bool);
@ -2947,7 +2947,7 @@ private:
class ASTDecompiler {
public:
explicit ASTDecompiler(SPIRVDecompiler& decomp) : decomp{decomp} {}
explicit ASTDecompiler(SPIRVDecompiler& decomp_) : decomp{decomp_} {}
void operator()(const ASTProgram& ast) {
ASTNode current = ast.nodes.GetFirst();

View File

@ -30,8 +30,8 @@ constexpr u32 DESCRIPTOR_SET = 0;
class ConstBufferEntry : public VideoCommon::Shader::ConstBuffer {
public:
explicit constexpr ConstBufferEntry(const VideoCommon::Shader::ConstBuffer& entry, u32 index)
: VideoCommon::Shader::ConstBuffer{entry}, index{index} {}
explicit constexpr ConstBufferEntry(const ConstBuffer& entry_, u32 index_)
: ConstBuffer{entry_}, index{index_} {}
constexpr u32 GetIndex() const {
return index;
@ -43,8 +43,8 @@ private:
class GlobalBufferEntry {
public:
constexpr explicit GlobalBufferEntry(u32 cbuf_index, u32 cbuf_offset, bool is_written)
: cbuf_index{cbuf_index}, cbuf_offset{cbuf_offset}, is_written{is_written} {}
constexpr explicit GlobalBufferEntry(u32 cbuf_index_, u32 cbuf_offset_, bool is_written_)
: cbuf_index{cbuf_index_}, cbuf_offset{cbuf_offset_}, is_written{is_written_} {}
constexpr u32 GetCbufIndex() const {
return cbuf_index;

View File

@ -180,19 +180,19 @@ VkImageCreateInfo GenerateImageCreateInfo(const VKDevice& device, const SurfaceP
return ci;
}
u32 EncodeSwizzle(Tegra::Texture::SwizzleSource x_source, Tegra::Texture::SwizzleSource y_source,
Tegra::Texture::SwizzleSource z_source, Tegra::Texture::SwizzleSource w_source) {
u32 EncodeSwizzle(SwizzleSource x_source, SwizzleSource y_source, SwizzleSource z_source,
SwizzleSource w_source) {
return (static_cast<u32>(x_source) << 24) | (static_cast<u32>(y_source) << 16) |
(static_cast<u32>(z_source) << 8) | static_cast<u32>(w_source);
}
} // Anonymous namespace
CachedSurface::CachedSurface(const VKDevice& device, VKMemoryManager& memory_manager,
VKScheduler& scheduler, VKStagingBufferPool& staging_pool,
GPUVAddr gpu_addr, const SurfaceParams& params)
: SurfaceBase<View>{gpu_addr, params, device.IsOptimalAstcSupported()}, device{device},
memory_manager{memory_manager}, scheduler{scheduler}, staging_pool{staging_pool} {
CachedSurface::CachedSurface(const VKDevice& device_, VKMemoryManager& memory_manager_,
VKScheduler& scheduler_, VKStagingBufferPool& staging_pool_,
GPUVAddr gpu_addr_, const SurfaceParams& params_)
: SurfaceBase<View>{gpu_addr_, params_, device_.IsOptimalAstcSupported()}, device{device_},
memory_manager{memory_manager_}, scheduler{scheduler_}, staging_pool{staging_pool_} {
if (params.IsBuffer()) {
buffer = CreateBuffer(device, params, host_memory_size);
commit = memory_manager.Commit(buffer, false);
@ -234,7 +234,7 @@ void CachedSurface::UploadTexture(const std::vector<u8>& staging_buffer) {
void CachedSurface::DownloadTexture(std::vector<u8>& staging_buffer) {
UNIMPLEMENTED_IF(params.IsBuffer());
if (params.pixel_format == VideoCore::Surface::PixelFormat::A1B5G5R5_UNORM) {
if (params.pixel_format == PixelFormat::A1B5G5R5_UNORM) {
LOG_WARNING(Render_Vulkan, "A1B5G5R5 flushing is stubbed");
}
@ -244,10 +244,10 @@ void CachedSurface::DownloadTexture(std::vector<u8>& staging_buffer) {
FullTransition(VK_PIPELINE_STAGE_TRANSFER_BIT, VK_ACCESS_TRANSFER_READ_BIT,
VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL);
const auto& buffer = staging_pool.GetUnusedBuffer(host_memory_size, true);
const auto& unused_buffer = staging_pool.GetUnusedBuffer(host_memory_size, true);
// TODO(Rodrigo): Do this in a single copy
for (u32 level = 0; level < params.num_levels; ++level) {
scheduler.Record([image = *image->GetHandle(), buffer = *buffer.handle,
scheduler.Record([image = *image->GetHandle(), buffer = *unused_buffer.handle,
copy = GetBufferImageCopy(level)](vk::CommandBuffer cmdbuf) {
cmdbuf.CopyImageToBuffer(image, VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL, buffer, copy);
});
@ -255,16 +255,17 @@ void CachedSurface::DownloadTexture(std::vector<u8>& staging_buffer) {
scheduler.Finish();
// TODO(Rodrigo): Use an intern buffer for staging buffers and avoid this unnecessary memcpy.
std::memcpy(staging_buffer.data(), buffer.commit->Map(host_memory_size), host_memory_size);
std::memcpy(staging_buffer.data(), unused_buffer.commit->Map(host_memory_size),
host_memory_size);
}
void CachedSurface::DecorateSurfaceName() {
// TODO(Rodrigo): Add name decorations
}
View CachedSurface::CreateView(const ViewParams& params) {
View CachedSurface::CreateView(const ViewParams& view_params) {
// TODO(Rodrigo): Add name decorations
return views[params] = std::make_shared<CachedSurfaceView>(device, *this, params);
return views[view_params] = std::make_shared<CachedSurfaceView>(device, *this, view_params);
}
void CachedSurface::UploadBuffer(const std::vector<u8>& staging_buffer) {
@ -348,21 +349,21 @@ VkImageSubresourceRange CachedSurface::GetImageSubresourceRange() const {
static_cast<u32>(params.GetNumLayers())};
}
CachedSurfaceView::CachedSurfaceView(const VKDevice& device, CachedSurface& surface,
const ViewParams& params)
: VideoCommon::ViewBase{params}, params{surface.GetSurfaceParams()},
image{surface.GetImageHandle()}, buffer_view{surface.GetBufferViewHandle()},
aspect_mask{surface.GetAspectMask()}, device{device}, surface{surface},
base_level{params.base_level}, num_levels{params.num_levels},
image_view_type{image ? GetImageViewType(params.target) : VK_IMAGE_VIEW_TYPE_1D} {
CachedSurfaceView::CachedSurfaceView(const VKDevice& device_, CachedSurface& surface_,
const ViewParams& view_params_)
: ViewBase{view_params_}, surface_params{surface_.GetSurfaceParams()},
image{surface_.GetImageHandle()}, buffer_view{surface_.GetBufferViewHandle()},
aspect_mask{surface_.GetAspectMask()}, device{device_}, surface{surface_},
base_level{view_params_.base_level}, num_levels{view_params_.num_levels},
image_view_type{image ? GetImageViewType(view_params_.target) : VK_IMAGE_VIEW_TYPE_1D} {
if (image_view_type == VK_IMAGE_VIEW_TYPE_3D) {
base_layer = 0;
num_layers = 1;
base_slice = params.base_layer;
num_slices = params.num_layers;
base_slice = view_params_.base_layer;
num_slices = view_params_.num_layers;
} else {
base_layer = params.base_layer;
num_layers = params.num_layers;
base_layer = view_params_.base_layer;
num_layers = view_params_.num_layers;
}
}
@ -384,7 +385,7 @@ VkImageView CachedSurfaceView::GetImageView(SwizzleSource x_source, SwizzleSourc
std::array swizzle{MaxwellToVK::SwizzleSource(x_source), MaxwellToVK::SwizzleSource(y_source),
MaxwellToVK::SwizzleSource(z_source), MaxwellToVK::SwizzleSource(w_source)};
if (params.pixel_format == VideoCore::Surface::PixelFormat::A1B5G5R5_UNORM) {
if (surface_params.pixel_format == PixelFormat::A1B5G5R5_UNORM) {
// A1B5G5R5 is implemented as A1R5G5B5, we have to change the swizzle here.
std::swap(swizzle[0], swizzle[2]);
}
@ -395,12 +396,12 @@ VkImageView CachedSurfaceView::GetImageView(SwizzleSource x_source, SwizzleSourc
if (aspect == (VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT)) {
UNIMPLEMENTED_IF(x_source != SwizzleSource::R && x_source != SwizzleSource::G);
const bool is_first = x_source == SwizzleSource::R;
switch (params.pixel_format) {
case VideoCore::Surface::PixelFormat::D24_UNORM_S8_UINT:
case VideoCore::Surface::PixelFormat::D32_FLOAT_S8_UINT:
switch (surface_params.pixel_format) {
case PixelFormat::D24_UNORM_S8_UINT:
case PixelFormat::D32_FLOAT_S8_UINT:
aspect = is_first ? VK_IMAGE_ASPECT_DEPTH_BIT : VK_IMAGE_ASPECT_STENCIL_BIT;
break;
case VideoCore::Surface::PixelFormat::S8_UINT_D24_UNORM:
case PixelFormat::S8_UINT_D24_UNORM:
aspect = is_first ? VK_IMAGE_ASPECT_STENCIL_BIT : VK_IMAGE_ASPECT_DEPTH_BIT;
break;
default:
@ -417,7 +418,7 @@ VkImageView CachedSurfaceView::GetImageView(SwizzleSource x_source, SwizzleSourc
if (image_view_type == VK_IMAGE_VIEW_TYPE_3D) {
ASSERT(base_slice == 0);
ASSERT(num_slices == params.depth);
ASSERT(num_slices == surface_params.depth);
}
image_view = device.GetLogical().CreateImageView({

View File

@ -40,9 +40,9 @@ class CachedSurface final : public VideoCommon::SurfaceBase<View> {
friend CachedSurfaceView;
public:
explicit CachedSurface(const VKDevice& device, VKMemoryManager& memory_manager,
VKScheduler& scheduler, VKStagingBufferPool& staging_pool,
GPUVAddr gpu_addr, const SurfaceParams& params);
explicit CachedSurface(const VKDevice& device_, VKMemoryManager& memory_manager_,
VKScheduler& scheduler_, VKStagingBufferPool& staging_pool_,
GPUVAddr gpu_addr_, const SurfaceParams& params_);
~CachedSurface();
void UploadTexture(const std::vector<u8>& staging_buffer) override;
@ -84,7 +84,7 @@ public:
protected:
void DecorateSurfaceName();
View CreateView(const ViewParams& params) override;
View CreateView(const ViewParams& view_params) override;
private:
void UploadBuffer(const std::vector<u8>& staging_buffer);
@ -110,8 +110,8 @@ private:
class CachedSurfaceView final : public VideoCommon::ViewBase {
public:
explicit CachedSurfaceView(const VKDevice& device, CachedSurface& surface,
const ViewParams& params);
explicit CachedSurfaceView(const VKDevice& device_, CachedSurface& surface_,
const ViewParams& view_params_);
~CachedSurfaceView();
VkImageView GetImageView(Tegra::Texture::SwizzleSource x_source,
@ -126,11 +126,11 @@ public:
}
u32 GetWidth() const {
return params.GetMipWidth(base_level);
return surface_params.GetMipWidth(base_level);
}
u32 GetHeight() const {
return params.GetMipHeight(base_level);
return surface_params.GetMipHeight(base_level);
}
u32 GetNumLayers() const {
@ -169,7 +169,7 @@ public:
private:
// Store a copy of these values to avoid double dereference when reading them
const SurfaceParams params;
const SurfaceParams surface_params;
const VkImage image;
const VkBufferView buffer_view;
const VkImageAspectFlags aspect_mask;

View File

@ -14,8 +14,8 @@
namespace Vulkan {
VKUpdateDescriptorQueue::VKUpdateDescriptorQueue(const VKDevice& device, VKScheduler& scheduler)
: device{device}, scheduler{scheduler} {}
VKUpdateDescriptorQueue::VKUpdateDescriptorQueue(const VKDevice& device_, VKScheduler& scheduler_)
: device{device_}, scheduler{scheduler_} {}
VKUpdateDescriptorQueue::~VKUpdateDescriptorQueue() = default;

View File

@ -31,7 +31,7 @@ struct DescriptorUpdateEntry {
class VKUpdateDescriptorQueue final {
public:
explicit VKUpdateDescriptorQueue(const VKDevice& device, VKScheduler& scheduler);
explicit VKUpdateDescriptorQueue(const VKDevice& device_, VKScheduler& scheduler_);
~VKUpdateDescriptorQueue();
void TickFrame();

View File

@ -417,7 +417,7 @@ VkResult Free(VkDevice device, VkCommandPool handle, Span<VkCommandBuffer> buffe
}
Instance Instance::Create(u32 version, Span<const char*> layers, Span<const char*> extensions,
InstanceDispatch& dld) noexcept {
InstanceDispatch& dispatch) noexcept {
const VkApplicationInfo application_info{
.sType = VK_STRUCTURE_TYPE_APPLICATION_INFO,
.pNext = nullptr,
@ -439,17 +439,17 @@ Instance Instance::Create(u32 version, Span<const char*> layers, Span<const char
};
VkInstance instance;
if (dld.vkCreateInstance(&ci, nullptr, &instance) != VK_SUCCESS) {
if (dispatch.vkCreateInstance(&ci, nullptr, &instance) != VK_SUCCESS) {
// Failed to create the instance.
return {};
}
if (!Proc(dld.vkDestroyInstance, dld, "vkDestroyInstance", instance)) {
if (!Proc(dispatch.vkDestroyInstance, dispatch, "vkDestroyInstance", instance)) {
// We successfully created an instance but the destroy function couldn't be loaded.
// This is a good moment to panic.
return {};
}
return Instance(instance, dld);
return Instance(instance, dispatch);
}
std::optional<std::vector<VkPhysicalDevice>> Instance::EnumeratePhysicalDevices() {
@ -540,7 +540,7 @@ std::vector<VkImage> SwapchainKHR::GetImages() const {
Device Device::Create(VkPhysicalDevice physical_device, Span<VkDeviceQueueCreateInfo> queues_ci,
Span<const char*> enabled_extensions, const void* next,
DeviceDispatch& dld) noexcept {
DeviceDispatch& dispatch) noexcept {
const VkDeviceCreateInfo ci{
.sType = VK_STRUCTURE_TYPE_DEVICE_CREATE_INFO,
.pNext = next,
@ -555,11 +555,11 @@ Device Device::Create(VkPhysicalDevice physical_device, Span<VkDeviceQueueCreate
};
VkDevice device;
if (dld.vkCreateDevice(physical_device, &ci, nullptr, &device) != VK_SUCCESS) {
if (dispatch.vkCreateDevice(physical_device, &ci, nullptr, &device) != VK_SUCCESS) {
return {};
}
Load(device, dld);
return Device(device, dld);
Load(device, dispatch);
return Device(device, dispatch);
}
Queue Device::GetQueue(u32 family_index) const noexcept {

View File

@ -52,7 +52,7 @@ public:
/// Construct a span from a pointer and a size.
/// This is inteded for subranges.
constexpr Span(const T* ptr, std::size_t num) noexcept : ptr{ptr}, num{num} {}
constexpr Span(const T* ptr_, std::size_t num_) noexcept : ptr{ptr_}, num{num_} {}
/// Returns the data pointer by the span.
constexpr const T* data() const noexcept {
@ -469,9 +469,10 @@ public:
PoolAllocations() = default;
/// Construct an allocation. Errors are reported through IsOutOfPoolMemory().
explicit PoolAllocations(std::unique_ptr<AllocationType[]> allocations, std::size_t num,
VkDevice device, PoolType pool, const DeviceDispatch& dld) noexcept
: allocations{std::move(allocations)}, num{num}, device{device}, pool{pool}, dld{&dld} {}
explicit PoolAllocations(std::unique_ptr<AllocationType[]> allocations_, std::size_t num_,
VkDevice device_, PoolType pool_, const DeviceDispatch& dld_) noexcept
: allocations{std::move(allocations_)}, num{num_}, device{device_}, pool{pool_},
dld{&dld_} {}
/// Copying Vulkan allocations is not supported and will never be.
PoolAllocations(const PoolAllocations&) = delete;
@ -565,7 +566,7 @@ class Instance : public Handle<VkInstance, NoOwner, InstanceDispatch> {
public:
/// Creates a Vulkan instance. Use "operator bool" for error handling.
static Instance Create(u32 version, Span<const char*> layers, Span<const char*> extensions,
InstanceDispatch& dld) noexcept;
InstanceDispatch& dispatch) noexcept;
/// Enumerates physical devices.
/// @return Physical devices and an empty handle on failure.
@ -581,7 +582,8 @@ public:
constexpr Queue() noexcept = default;
/// Construct a queue handle.
constexpr Queue(VkQueue queue, const DeviceDispatch& dld) noexcept : queue{queue}, dld{&dld} {}
constexpr Queue(VkQueue queue_, const DeviceDispatch& dld_) noexcept
: queue{queue_}, dld{&dld_} {}
VkResult Submit(Span<VkSubmitInfo> submit_infos,
VkFence fence = VK_NULL_HANDLE) const noexcept {
@ -720,7 +722,7 @@ class Device : public Handle<VkDevice, NoOwner, DeviceDispatch> {
public:
static Device Create(VkPhysicalDevice physical_device, Span<VkDeviceQueueCreateInfo> queues_ci,
Span<const char*> enabled_extensions, const void* next,
DeviceDispatch& dld) noexcept;
DeviceDispatch& dispatch) noexcept;
Queue GetQueue(u32 family_index) const noexcept;
@ -809,8 +811,9 @@ class PhysicalDevice {
public:
constexpr PhysicalDevice() noexcept = default;
constexpr PhysicalDevice(VkPhysicalDevice physical_device, const InstanceDispatch& dld) noexcept
: physical_device{physical_device}, dld{&dld} {}
constexpr PhysicalDevice(VkPhysicalDevice physical_device_,
const InstanceDispatch& dld_) noexcept
: physical_device{physical_device_}, dld{&dld_} {}
constexpr operator VkPhysicalDevice() const noexcept {
return physical_device;
@ -849,8 +852,8 @@ class CommandBuffer {
public:
CommandBuffer() noexcept = default;
explicit CommandBuffer(VkCommandBuffer handle, const DeviceDispatch& dld) noexcept
: handle{handle}, dld{&dld} {}
explicit CommandBuffer(VkCommandBuffer handle_, const DeviceDispatch& dld_) noexcept
: handle{handle_}, dld{&dld_} {}
const VkCommandBuffer* address() const noexcept {
return &handle;

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@ -241,10 +241,10 @@ std::pair<ParseResult, ParseInfo> ParseCode(CFGRebuildState& state, u32 address)
ParseInfo parse_info{};
SingleBranch single_branch{};
const auto insert_label = [](CFGRebuildState& state, u32 address) {
const auto pair = state.labels.emplace(address);
const auto insert_label = [](CFGRebuildState& rebuild_state, u32 label_address) {
const auto pair = rebuild_state.labels.emplace(label_address);
if (pair.second) {
state.inspect_queries.push_back(address);
rebuild_state.inspect_queries.push_back(label_address);
}
};

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@ -358,9 +358,9 @@ u32 ShaderIR::DecodeImage(NodeBlock& bb, u32 pc) {
instr.suldst.GetStoreDataLayout() != StoreType::Bits64);
auto descriptor = [this, instr] {
std::optional<Tegra::Engines::SamplerDescriptor> descriptor;
std::optional<Tegra::Engines::SamplerDescriptor> sampler_descriptor;
if (instr.suldst.is_immediate) {
descriptor =
sampler_descriptor =
registry.ObtainBoundSampler(static_cast<u32>(instr.image.index.Value()));
} else {
const Node image_register = GetRegister(instr.gpr39);
@ -368,12 +368,12 @@ u32 ShaderIR::DecodeImage(NodeBlock& bb, u32 pc) {
static_cast<s64>(global_code.size()));
const auto buffer = std::get<1>(result);
const auto offset = std::get<2>(result);
descriptor = registry.ObtainBindlessSampler(buffer, offset);
sampler_descriptor = registry.ObtainBindlessSampler(buffer, offset);
}
if (!descriptor) {
if (!sampler_descriptor) {
UNREACHABLE_MSG("Failed to obtain image descriptor");
}
return *descriptor;
return *sampler_descriptor;
}();
const auto comp_mask = GetImageComponentMask(descriptor.format);

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@ -90,11 +90,11 @@ u32 ShaderIR::DecodeOther(NodeBlock& bb, u32 pc) {
UNIMPLEMENTED_MSG("S2R WscaleFactorZ is not implemented");
return Immediate(0U);
case SystemVariable::Tid: {
Node value = Immediate(0);
value = BitfieldInsert(value, Operation(OperationCode::LocalInvocationIdX), 0, 9);
value = BitfieldInsert(value, Operation(OperationCode::LocalInvocationIdY), 16, 9);
value = BitfieldInsert(value, Operation(OperationCode::LocalInvocationIdZ), 26, 5);
return value;
Node val = Immediate(0);
val = BitfieldInsert(val, Operation(OperationCode::LocalInvocationIdX), 0, 9);
val = BitfieldInsert(val, Operation(OperationCode::LocalInvocationIdY), 16, 9);
val = BitfieldInsert(val, Operation(OperationCode::LocalInvocationIdZ), 26, 5);
return val;
}
case SystemVariable::TidX:
return Operation(OperationCode::LocalInvocationIdX);

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@ -167,27 +167,28 @@ std::vector<CopyParams> SurfaceBaseImpl::BreakDownNonLayered(const SurfaceParams
return result;
}
void SurfaceBaseImpl::SwizzleFunc(MortonSwizzleMode mode, u8* memory, const SurfaceParams& params,
u8* buffer, u32 level) {
const u32 width{params.GetMipWidth(level)};
const u32 height{params.GetMipHeight(level)};
const u32 block_height{params.GetMipBlockHeight(level)};
const u32 block_depth{params.GetMipBlockDepth(level)};
void SurfaceBaseImpl::SwizzleFunc(MortonSwizzleMode mode, u8* memory,
const SurfaceParams& surface_params, u8* buffer, u32 level) {
const u32 width{surface_params.GetMipWidth(level)};
const u32 height{surface_params.GetMipHeight(level)};
const u32 block_height{surface_params.GetMipBlockHeight(level)};
const u32 block_depth{surface_params.GetMipBlockDepth(level)};
std::size_t guest_offset{mipmap_offsets[level]};
if (params.is_layered) {
if (surface_params.is_layered) {
std::size_t host_offset = 0;
const std::size_t guest_stride = layer_size;
const std::size_t host_stride = params.GetHostLayerSize(level);
for (u32 layer = 0; layer < params.depth; ++layer) {
MortonSwizzle(mode, params.pixel_format, width, block_height, height, block_depth, 1,
params.tile_width_spacing, buffer + host_offset, memory + guest_offset);
const std::size_t host_stride = surface_params.GetHostLayerSize(level);
for (u32 layer = 0; layer < surface_params.depth; ++layer) {
MortonSwizzle(mode, surface_params.pixel_format, width, block_height, height,
block_depth, 1, surface_params.tile_width_spacing, buffer + host_offset,
memory + guest_offset);
guest_offset += guest_stride;
host_offset += host_stride;
}
} else {
MortonSwizzle(mode, params.pixel_format, width, block_height, height, block_depth,
params.GetMipDepth(level), params.tile_width_spacing, buffer,
MortonSwizzle(mode, surface_params.pixel_format, width, block_height, height, block_depth,
surface_params.GetMipDepth(level), surface_params.tile_width_spacing, buffer,
memory + guest_offset);
}
}

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@ -167,8 +167,8 @@ protected:
std::vector<std::size_t> mipmap_offsets;
private:
void SwizzleFunc(MortonSwizzleMode mode, u8* memory, const SurfaceParams& params, u8* buffer,
u32 level);
void SwizzleFunc(MortonSwizzleMode mode, u8* memory, const SurfaceParams& surface_params,
u8* buffer, u32 level);
std::vector<CopyParams> BreakDownLayered(const SurfaceParams& in_params) const;

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@ -356,18 +356,18 @@ std::size_t SurfaceParams::GetLayerSize(bool as_host_size, bool uncompressed) co
std::size_t SurfaceParams::GetInnerMipmapMemorySize(u32 level, bool as_host_size,
bool uncompressed) const {
const u32 width{GetMipmapSize(uncompressed, GetMipWidth(level), GetDefaultBlockWidth())};
const u32 height{GetMipmapSize(uncompressed, GetMipHeight(level), GetDefaultBlockHeight())};
const u32 depth{is_layered ? 1U : GetMipDepth(level)};
const u32 mip_width{GetMipmapSize(uncompressed, GetMipWidth(level), GetDefaultBlockWidth())};
const u32 mip_height{GetMipmapSize(uncompressed, GetMipHeight(level), GetDefaultBlockHeight())};
const u32 mip_depth{is_layered ? 1U : GetMipDepth(level)};
if (is_tiled) {
return Tegra::Texture::CalculateSize(!as_host_size, GetBytesPerPixel(), width, height,
depth, GetMipBlockHeight(level),
return Tegra::Texture::CalculateSize(!as_host_size, GetBytesPerPixel(), mip_width,
mip_height, mip_depth, GetMipBlockHeight(level),
GetMipBlockDepth(level));
} else if (as_host_size || IsBuffer()) {
return GetBytesPerPixel() * width * height * depth;
return GetBytesPerPixel() * mip_width * mip_height * mip_depth;
} else {
// Linear Texture Case
return pitch * height * depth;
return pitch * mip_height * mip_depth;
}
}