Merge pull request #2122 from ReinUsesLisp/vulkan-resource-manager
vk_resource_manager: Implement fence and command buffer allocator
This commit is contained in:
commit
4bce08d497
@ -105,7 +105,9 @@ if (ENABLE_VULKAN)
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target_sources(video_core PRIVATE
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renderer_vulkan/declarations.h
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renderer_vulkan/vk_device.cpp
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renderer_vulkan/vk_device.h)
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renderer_vulkan/vk_device.h
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renderer_vulkan/vk_resource_manager.cpp
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renderer_vulkan/vk_resource_manager.h)
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target_include_directories(video_core PRIVATE ../../externals/Vulkan-Headers/include)
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target_compile_definitions(video_core PRIVATE HAS_VULKAN)
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285
src/video_core/renderer_vulkan/vk_resource_manager.cpp
Normal file
285
src/video_core/renderer_vulkan/vk_resource_manager.cpp
Normal file
@ -0,0 +1,285 @@
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// Copyright 2018 yuzu Emulator Project
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// Licensed under GPLv2 or any later version
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// Refer to the license.txt file included.
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#include <algorithm>
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#include <optional>
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#include "common/assert.h"
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#include "common/logging/log.h"
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#include "video_core/renderer_vulkan/declarations.h"
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#include "video_core/renderer_vulkan/vk_device.h"
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#include "video_core/renderer_vulkan/vk_resource_manager.h"
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namespace Vulkan {
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// TODO(Rodrigo): Fine tune these numbers.
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constexpr std::size_t COMMAND_BUFFER_POOL_SIZE = 0x1000;
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constexpr std::size_t FENCES_GROW_STEP = 0x40;
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class CommandBufferPool final : public VKFencedPool {
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public:
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CommandBufferPool(const VKDevice& device)
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: VKFencedPool(COMMAND_BUFFER_POOL_SIZE), device{device} {}
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void Allocate(std::size_t begin, std::size_t end) {
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const auto dev = device.GetLogical();
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const auto& dld = device.GetDispatchLoader();
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const u32 graphics_family = device.GetGraphicsFamily();
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auto pool = std::make_unique<Pool>();
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// Command buffers are going to be commited, recorded, executed every single usage cycle.
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// They are also going to be reseted when commited.
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const auto pool_flags = vk::CommandPoolCreateFlagBits::eTransient |
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vk::CommandPoolCreateFlagBits::eResetCommandBuffer;
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const vk::CommandPoolCreateInfo cmdbuf_pool_ci(pool_flags, graphics_family);
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pool->handle = dev.createCommandPoolUnique(cmdbuf_pool_ci, nullptr, dld);
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const vk::CommandBufferAllocateInfo cmdbuf_ai(*pool->handle,
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vk::CommandBufferLevel::ePrimary,
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static_cast<u32>(COMMAND_BUFFER_POOL_SIZE));
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pool->cmdbufs =
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dev.allocateCommandBuffersUnique<std::allocator<UniqueCommandBuffer>>(cmdbuf_ai, dld);
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pools.push_back(std::move(pool));
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}
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vk::CommandBuffer Commit(VKFence& fence) {
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const std::size_t index = CommitResource(fence);
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const auto pool_index = index / COMMAND_BUFFER_POOL_SIZE;
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const auto sub_index = index % COMMAND_BUFFER_POOL_SIZE;
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return *pools[pool_index]->cmdbufs[sub_index];
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}
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private:
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struct Pool {
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UniqueCommandPool handle;
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std::vector<UniqueCommandBuffer> cmdbufs;
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};
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const VKDevice& device;
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std::vector<std::unique_ptr<Pool>> pools;
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};
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VKResource::VKResource() = default;
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VKResource::~VKResource() = default;
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VKFence::VKFence(const VKDevice& device, UniqueFence handle)
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: device{device}, handle{std::move(handle)} {}
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VKFence::~VKFence() = default;
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void VKFence::Wait() {
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const auto dev = device.GetLogical();
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const auto& dld = device.GetDispatchLoader();
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dev.waitForFences({*handle}, true, std::numeric_limits<u64>::max(), dld);
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}
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void VKFence::Release() {
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is_owned = false;
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}
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void VKFence::Commit() {
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is_owned = true;
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is_used = true;
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}
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bool VKFence::Tick(bool gpu_wait, bool owner_wait) {
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if (!is_used) {
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// If a fence is not used it's always free.
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return true;
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}
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if (is_owned && !owner_wait) {
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// The fence is still being owned (Release has not been called) and ownership wait has
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// not been asked.
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return false;
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}
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const auto dev = device.GetLogical();
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const auto& dld = device.GetDispatchLoader();
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if (gpu_wait) {
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// Wait for the fence if it has been requested.
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dev.waitForFences({*handle}, true, std::numeric_limits<u64>::max(), dld);
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} else {
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if (dev.getFenceStatus(*handle, dld) != vk::Result::eSuccess) {
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// Vulkan fence is not ready, not much it can do here
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return false;
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}
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}
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// Broadcast resources their free state.
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for (auto* resource : protected_resources) {
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resource->OnFenceRemoval(this);
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}
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protected_resources.clear();
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// Prepare fence for reusage.
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dev.resetFences({*handle}, dld);
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is_used = false;
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return true;
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}
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void VKFence::Protect(VKResource* resource) {
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protected_resources.push_back(resource);
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}
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void VKFence::Unprotect(const VKResource* resource) {
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const auto it = std::find(protected_resources.begin(), protected_resources.end(), resource);
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if (it != protected_resources.end()) {
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protected_resources.erase(it);
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}
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}
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VKFenceWatch::VKFenceWatch() = default;
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VKFenceWatch::~VKFenceWatch() {
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if (fence) {
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fence->Unprotect(this);
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}
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}
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void VKFenceWatch::Wait() {
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if (!fence) {
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return;
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}
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fence->Wait();
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fence->Unprotect(this);
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fence = nullptr;
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}
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void VKFenceWatch::Watch(VKFence& new_fence) {
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Wait();
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fence = &new_fence;
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fence->Protect(this);
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}
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bool VKFenceWatch::TryWatch(VKFence& new_fence) {
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if (fence) {
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return false;
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}
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fence = &new_fence;
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fence->Protect(this);
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return true;
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}
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void VKFenceWatch::OnFenceRemoval(VKFence* signaling_fence) {
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ASSERT_MSG(signaling_fence == fence, "Removing the wrong fence");
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fence = nullptr;
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}
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VKFencedPool::VKFencedPool(std::size_t grow_step) : grow_step{grow_step} {}
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VKFencedPool::~VKFencedPool() = default;
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std::size_t VKFencedPool::CommitResource(VKFence& fence) {
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const auto Search = [&](std::size_t begin, std::size_t end) -> std::optional<std::size_t> {
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for (std::size_t iterator = begin; iterator < end; ++iterator) {
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if (watches[iterator]->TryWatch(fence)) {
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// The resource is now being watched, a free resource was successfully found.
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return iterator;
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}
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}
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return {};
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};
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// Try to find a free resource from the hinted position to the end.
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auto found = Search(free_iterator, watches.size());
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if (!found) {
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// Search from beginning to the hinted position.
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found = Search(0, free_iterator);
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if (!found) {
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// Both searches failed, the pool is full; handle it.
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const std::size_t free_resource = ManageOverflow();
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// Watch will wait for the resource to be free.
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watches[free_resource]->Watch(fence);
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found = free_resource;
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}
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}
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// Free iterator is hinted to the resource after the one that's been commited.
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free_iterator = (*found + 1) % watches.size();
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return *found;
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}
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std::size_t VKFencedPool::ManageOverflow() {
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const std::size_t old_capacity = watches.size();
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Grow();
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// The last entry is guaranted to be free, since it's the first element of the freshly
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// allocated resources.
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return old_capacity;
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}
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void VKFencedPool::Grow() {
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const std::size_t old_capacity = watches.size();
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watches.resize(old_capacity + grow_step);
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std::generate(watches.begin() + old_capacity, watches.end(),
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[]() { return std::make_unique<VKFenceWatch>(); });
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Allocate(old_capacity, old_capacity + grow_step);
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}
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VKResourceManager::VKResourceManager(const VKDevice& device) : device{device} {
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GrowFences(FENCES_GROW_STEP);
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command_buffer_pool = std::make_unique<CommandBufferPool>(device);
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}
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VKResourceManager::~VKResourceManager() = default;
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VKFence& VKResourceManager::CommitFence() {
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const auto StepFences = [&](bool gpu_wait, bool owner_wait) -> VKFence* {
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const auto Tick = [=](auto& fence) { return fence->Tick(gpu_wait, owner_wait); };
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const auto hinted = fences.begin() + fences_iterator;
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auto it = std::find_if(hinted, fences.end(), Tick);
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if (it == fences.end()) {
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it = std::find_if(fences.begin(), hinted, Tick);
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if (it == hinted) {
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return nullptr;
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}
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}
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fences_iterator = std::distance(fences.begin(), it) + 1;
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if (fences_iterator >= fences.size())
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fences_iterator = 0;
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auto& fence = *it;
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fence->Commit();
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return fence.get();
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};
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VKFence* found_fence = StepFences(false, false);
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if (!found_fence) {
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// Try again, this time waiting.
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found_fence = StepFences(true, false);
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if (!found_fence) {
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// Allocate new fences and try again.
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LOG_INFO(Render_Vulkan, "Allocating new fences {} -> {}", fences.size(),
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fences.size() + FENCES_GROW_STEP);
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GrowFences(FENCES_GROW_STEP);
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found_fence = StepFences(true, false);
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ASSERT(found_fence != nullptr);
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}
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}
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return *found_fence;
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}
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vk::CommandBuffer VKResourceManager::CommitCommandBuffer(VKFence& fence) {
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return command_buffer_pool->Commit(fence);
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}
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void VKResourceManager::GrowFences(std::size_t new_fences_count) {
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const auto dev = device.GetLogical();
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const auto& dld = device.GetDispatchLoader();
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const vk::FenceCreateInfo fence_ci;
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const std::size_t previous_size = fences.size();
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fences.resize(previous_size + new_fences_count);
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std::generate(fences.begin() + previous_size, fences.end(), [&]() {
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return std::make_unique<VKFence>(device, dev.createFenceUnique(fence_ci, nullptr, dld));
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});
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}
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} // namespace Vulkan
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180
src/video_core/renderer_vulkan/vk_resource_manager.h
Normal file
180
src/video_core/renderer_vulkan/vk_resource_manager.h
Normal file
@ -0,0 +1,180 @@
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// Copyright 2018 yuzu Emulator Project
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// Licensed under GPLv2 or any later version
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// Refer to the license.txt file included.
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#pragma once
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#include <cstddef>
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#include <memory>
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#include <vector>
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#include "video_core/renderer_vulkan/declarations.h"
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namespace Vulkan {
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class VKDevice;
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class VKFence;
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class VKResourceManager;
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class CommandBufferPool;
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/// Interface for a Vulkan resource
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class VKResource {
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public:
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explicit VKResource();
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virtual ~VKResource();
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/**
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* Signals the object that an owning fence has been signaled.
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* @param signaling_fence Fence that signals its usage end.
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*/
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virtual void OnFenceRemoval(VKFence* signaling_fence) = 0;
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};
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/**
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* Fences take ownership of objects, protecting them from GPU-side or driver-side concurrent access.
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* They must be commited from the resource manager. Their usage flow is: commit the fence from the
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* resource manager, protect resources with it and use them, send the fence to an execution queue
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* and Wait for it if needed and then call Release. Used resources will automatically be signaled
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* when they are free to be reused.
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* @brief Protects resources for concurrent usage and signals its release.
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*/
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class VKFence {
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friend class VKResourceManager;
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public:
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explicit VKFence(const VKDevice& device, UniqueFence handle);
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~VKFence();
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/**
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* Waits for the fence to be signaled.
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* @warning You must have ownership of the fence and it has to be previously sent to a queue to
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* call this function.
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*/
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void Wait();
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/**
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* Releases ownership of the fence. Pass after it has been sent to an execution queue.
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* Unmanaged usage of the fence after the call will result in undefined behavior because it may
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* be being used for something else.
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*/
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void Release();
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/// Protects a resource with this fence.
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void Protect(VKResource* resource);
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/// Removes protection for a resource.
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void Unprotect(const VKResource* resource);
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/// Retreives the fence.
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operator vk::Fence() const {
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return *handle;
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}
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private:
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/// Take ownership of the fence.
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void Commit();
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/**
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* Updates the fence status.
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* @warning Waiting for the owner might soft lock the execution.
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* @param gpu_wait Wait for the fence to be signaled by the driver.
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* @param owner_wait Wait for the owner to signal its freedom.
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* @returns True if the fence is free. Waiting for gpu and owner will always return true.
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*/
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bool Tick(bool gpu_wait, bool owner_wait);
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const VKDevice& device; ///< Device handler
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UniqueFence handle; ///< Vulkan fence
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std::vector<VKResource*> protected_resources; ///< List of resources protected by this fence
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bool is_owned = false; ///< The fence has been commited but not released yet.
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bool is_used = false; ///< The fence has been commited but it has not been checked to be free.
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};
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/**
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* A fence watch is used to keep track of the usage of a fence and protect a resource or set of
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* resources without having to inherit VKResource from their handlers.
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*/
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class VKFenceWatch final : public VKResource {
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public:
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explicit VKFenceWatch();
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~VKFenceWatch();
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/// Waits for the fence to be released.
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void Wait();
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/**
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* Waits for a previous fence and watches a new one.
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* @param new_fence New fence to wait to.
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*/
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void Watch(VKFence& new_fence);
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/**
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* Checks if it's currently being watched and starts watching it if it's available.
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* @returns True if a watch has started, false if it's being watched.
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*/
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bool TryWatch(VKFence& new_fence);
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void OnFenceRemoval(VKFence* signaling_fence) override;
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private:
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VKFence* fence{}; ///< Fence watching this resource. nullptr when the watch is free.
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};
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/**
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* Handles a pool of resources protected by fences. Manages resource overflow allocating more
|
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* resources.
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*/
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class VKFencedPool {
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public:
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explicit VKFencedPool(std::size_t grow_step);
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virtual ~VKFencedPool();
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protected:
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/**
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* Commits a free resource and protects it with a fence. It may allocate new resources.
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* @param fence Fence that protects the commited resource.
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* @returns Index of the resource commited.
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*/
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std::size_t CommitResource(VKFence& fence);
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/// Called when a chunk of resources have to be allocated.
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virtual void Allocate(std::size_t begin, std::size_t end) = 0;
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private:
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/// Manages pool overflow allocating new resources.
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std::size_t ManageOverflow();
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/// Allocates a new page of resources.
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void Grow();
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std::size_t grow_step = 0; ///< Number of new resources created after an overflow
|
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std::size_t free_iterator = 0; ///< Hint to where the next free resources is likely to be found
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std::vector<std::unique_ptr<VKFenceWatch>> watches; ///< Set of watched resources
|
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};
|
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|
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/**
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* The resource manager handles all resources that can be protected with a fence avoiding
|
||||
* driver-side or GPU-side concurrent usage. Usage is documented in VKFence.
|
||||
*/
|
||||
class VKResourceManager final {
|
||||
public:
|
||||
explicit VKResourceManager(const VKDevice& device);
|
||||
~VKResourceManager();
|
||||
|
||||
/// Commits a fence. It has to be sent to a queue and released.
|
||||
VKFence& CommitFence();
|
||||
|
||||
/// Commits an unused command buffer and protects it with a fence.
|
||||
vk::CommandBuffer CommitCommandBuffer(VKFence& fence);
|
||||
|
||||
private:
|
||||
/// Allocates new fences.
|
||||
void GrowFences(std::size_t new_fences_count);
|
||||
|
||||
const VKDevice& device; ///< Device handler.
|
||||
std::size_t fences_iterator = 0; ///< Index where a free fence is likely to be found.
|
||||
std::vector<std::unique_ptr<VKFence>> fences; ///< Pool of fences.
|
||||
std::unique_ptr<CommandBufferPool> command_buffer_pool; ///< Pool of command buffers.
|
||||
};
|
||||
|
||||
} // namespace Vulkan
|
Loading…
Reference in New Issue
Block a user