#if defined(CONF_BACKEND_VULKAN) #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifndef VK_API_VERSION_MAJOR #define VK_API_VERSION_MAJOR VK_VERSION_MAJOR #define VK_API_VERSION_MINOR VK_VERSION_MINOR #define VK_API_VERSION_PATCH VK_VERSION_PATCH #endif // for msvc #ifndef PRIu64 #define PRIu64 "I64u" #endif class CCommandProcessorFragment_Vulkan : public CCommandProcessorFragment_GLBase { enum EMemoryBlockUsage { MEMORY_BLOCK_USAGE_TEXTURE = 0, MEMORY_BLOCK_USAGE_BUFFER, MEMORY_BLOCK_USAGE_STREAM, MEMORY_BLOCK_USAGE_STAGING, // whenever dummy is used, make sure to deallocate all memory MEMORY_BLOCK_USAGE_DUMMY, }; bool IsVerbose() { return g_Config.m_DbgGfx == DEBUG_GFX_MODE_VERBOSE || g_Config.m_DbgGfx == DEBUG_GFX_MODE_ALL; } void VerboseAllocatedMemory(VkDeviceSize Size, size_t FrameImageIndex, EMemoryBlockUsage MemUsage) { const char *pUsage = "unknown"; switch(MemUsage) { case MEMORY_BLOCK_USAGE_TEXTURE: pUsage = "texture"; break; case MEMORY_BLOCK_USAGE_BUFFER: pUsage = "buffer"; break; case MEMORY_BLOCK_USAGE_STREAM: pUsage = "stream"; break; case MEMORY_BLOCK_USAGE_STAGING: pUsage = "staging buffer"; break; default: break; } dbg_msg("vulkan", "allocated chunk of memory with size: %" PRIu64 " for frame %" PRIu64 " (%s)", (size_t)Size, (size_t)m_CurImageIndex, pUsage); } void VerboseDeallocatedMemory(VkDeviceSize Size, size_t FrameImageIndex, EMemoryBlockUsage MemUsage) { const char *pUsage = "unknown"; switch(MemUsage) { case MEMORY_BLOCK_USAGE_TEXTURE: pUsage = "texture"; break; case MEMORY_BLOCK_USAGE_BUFFER: pUsage = "buffer"; break; case MEMORY_BLOCK_USAGE_STREAM: pUsage = "stream"; break; case MEMORY_BLOCK_USAGE_STAGING: pUsage = "staging buffer"; break; default: break; } dbg_msg("vulkan", "deallocated chunk of memory with size: %" PRIu64 " for frame %" PRIu64 " (%s)", (size_t)Size, (size_t)m_CurImageIndex, pUsage); } /************************ * STRUCT DEFINITIONS ************************/ static constexpr size_t s_StagingBufferCacheID = 0; static constexpr size_t s_StagingBufferImageCacheID = 1; static constexpr size_t s_VertexBufferCacheID = 2; static constexpr size_t s_ImageBufferCacheID = 3; struct SDeviceMemoryBlock { VkDeviceMemory m_Mem = VK_NULL_HANDLE; VkDeviceSize m_Size = 0; EMemoryBlockUsage m_UsageType; }; struct SDeviceDescriptorPools; struct SDeviceDescriptorSet { VkDescriptorSet m_Descriptor = VK_NULL_HANDLE; SDeviceDescriptorPools *m_pPools = nullptr; size_t m_PoolIndex = std::numeric_limits::max(); }; struct SDeviceDescriptorPool { VkDescriptorPool m_Pool; VkDeviceSize m_Size = 0; VkDeviceSize m_CurSize = 0; }; struct SDeviceDescriptorPools { std::vector m_Pools; VkDeviceSize m_DefaultAllocSize = 0; bool m_IsUniformPool = false; }; // some mix of queue and binary tree struct SMemoryHeap { struct SMemoryHeapElement; struct SMemoryHeapQueueElement { size_t m_AllocationSize; // only useful information for the heap size_t m_OffsetInHeap; // useful for the user of this element size_t m_OffsetToAlign; SMemoryHeapElement *m_pElementInHeap; bool operator>(const SMemoryHeapQueueElement &Other) const { return m_AllocationSize > Other.m_AllocationSize; } }; typedef std::multiset> TMemoryHeapQueue; struct SMemoryHeapElement { size_t m_AllocationSize; size_t m_Offset; SMemoryHeapElement *m_pParent; std::unique_ptr m_pLeft; std::unique_ptr m_pRight; bool m_InUse; TMemoryHeapQueue::iterator m_InQueue; }; SMemoryHeapElement m_Root; TMemoryHeapQueue m_Elements; void Init(size_t Size, size_t Offset) { m_Root.m_AllocationSize = Size; m_Root.m_Offset = Offset; m_Root.m_pParent = nullptr; m_Root.m_InUse = false; SMemoryHeapQueueElement QueueEl; QueueEl.m_AllocationSize = Size; QueueEl.m_OffsetInHeap = Offset; QueueEl.m_OffsetToAlign = Offset; QueueEl.m_pElementInHeap = &m_Root; m_Root.m_InQueue = m_Elements.insert(QueueEl); } bool Allocate(size_t AllocSize, size_t AllocAlignment, SMemoryHeapQueueElement &AllocatedMemory) { if(m_Elements.empty()) { return false; } else { // calculate the alignment size_t ExtraSizeAlign = m_Elements.begin()->m_OffsetInHeap % AllocAlignment; if(ExtraSizeAlign != 0) ExtraSizeAlign = AllocAlignment - ExtraSizeAlign; size_t RealAllocSize = AllocSize + ExtraSizeAlign; // check if there is enough space in this instance if(m_Elements.begin()->m_AllocationSize < RealAllocSize) { return false; } else { auto TopEl = *m_Elements.begin(); m_Elements.erase(TopEl.m_pElementInHeap->m_InQueue); TopEl.m_pElementInHeap->m_InUse = true; // the heap element gets children TopEl.m_pElementInHeap->m_pLeft = std::make_unique(); TopEl.m_pElementInHeap->m_pLeft->m_AllocationSize = RealAllocSize; TopEl.m_pElementInHeap->m_pLeft->m_Offset = TopEl.m_OffsetInHeap; TopEl.m_pElementInHeap->m_pLeft->m_pParent = TopEl.m_pElementInHeap; TopEl.m_pElementInHeap->m_pLeft->m_InUse = true; if(RealAllocSize < TopEl.m_AllocationSize) { SMemoryHeapQueueElement RemainingEl; RemainingEl.m_OffsetInHeap = TopEl.m_OffsetInHeap + RealAllocSize; RemainingEl.m_AllocationSize = TopEl.m_AllocationSize - RealAllocSize; TopEl.m_pElementInHeap->m_pRight = std::make_unique(); TopEl.m_pElementInHeap->m_pRight->m_AllocationSize = RemainingEl.m_AllocationSize; TopEl.m_pElementInHeap->m_pRight->m_Offset = RemainingEl.m_OffsetInHeap; TopEl.m_pElementInHeap->m_pRight->m_pParent = TopEl.m_pElementInHeap; TopEl.m_pElementInHeap->m_pRight->m_InUse = false; RemainingEl.m_pElementInHeap = TopEl.m_pElementInHeap->m_pRight.get(); RemainingEl.m_pElementInHeap->m_InQueue = m_Elements.insert(RemainingEl); } AllocatedMemory.m_pElementInHeap = TopEl.m_pElementInHeap->m_pLeft.get(); AllocatedMemory.m_AllocationSize = RealAllocSize; AllocatedMemory.m_OffsetInHeap = TopEl.m_OffsetInHeap; AllocatedMemory.m_OffsetToAlign = TopEl.m_OffsetInHeap + ExtraSizeAlign; return true; } } } void Free(SMemoryHeapQueueElement &AllocatedMemory) { bool ContinueFree = true; SMemoryHeapQueueElement ThisEl = AllocatedMemory; while(ContinueFree) { // first check if the other block is in use, if not merge them again SMemoryHeapElement *pThisHeapObj = ThisEl.m_pElementInHeap; SMemoryHeapElement *pThisParent = pThisHeapObj->m_pParent; pThisHeapObj->m_InUse = false; SMemoryHeapElement *pOtherHeapObj = nullptr; if(pThisParent != nullptr && pThisHeapObj == pThisParent->m_pLeft.get()) pOtherHeapObj = pThisHeapObj->m_pParent->m_pRight.get(); else if(pThisParent != nullptr) pOtherHeapObj = pThisHeapObj->m_pParent->m_pLeft.get(); if((pThisParent != nullptr && pOtherHeapObj == nullptr) || (pOtherHeapObj != nullptr && !pOtherHeapObj->m_InUse)) { // merge them if(pOtherHeapObj != nullptr) { m_Elements.erase(pOtherHeapObj->m_InQueue); pOtherHeapObj->m_InUse = false; } SMemoryHeapQueueElement ParentEl; ParentEl.m_OffsetInHeap = pThisParent->m_Offset; ParentEl.m_AllocationSize = pThisParent->m_AllocationSize; ParentEl.m_pElementInHeap = pThisParent; pThisParent->m_pLeft = nullptr; pThisParent->m_pRight = nullptr; ThisEl = ParentEl; } else { // else just put this back into queue ThisEl.m_pElementInHeap->m_InQueue = m_Elements.insert(ThisEl); ContinueFree = false; } } } bool IsUnused() { return !m_Root.m_InUse; } }; template struct SMemoryBlock { SMemoryHeap::SMemoryHeapQueueElement m_HeapData; VkDeviceSize m_UsedSize; // optional VkBuffer m_Buffer; SDeviceMemoryBlock m_BufferMem; void *m_pMappedBuffer; bool m_IsCached; SMemoryHeap *m_pHeap; }; template struct SMemoryImageBlock : public SMemoryBlock { uint32_t m_ImageMemoryBits; }; template struct SMemoryBlockCache { struct SMemoryCacheType { struct SMemoryCacheHeap { SMemoryHeap m_Heap; VkBuffer m_Buffer; SDeviceMemoryBlock m_BufferMem; void *m_pMappedBuffer; }; std::vector m_MemoryHeaps; }; SMemoryCacheType m_MemoryCaches; std::vector>> m_FrameDelayedCachedBufferCleanup; bool m_CanShrink = false; void Init(size_t SwapChainImageCount) { m_FrameDelayedCachedBufferCleanup.resize(SwapChainImageCount); } void DestroyFrameData(size_t ImageCount) { for(size_t i = 0; i < ImageCount; ++i) Cleanup(i); m_FrameDelayedCachedBufferCleanup.clear(); } void Destroy(VkDevice &Device) { for(auto it = m_MemoryCaches.m_MemoryHeaps.begin(); it != m_MemoryCaches.m_MemoryHeaps.end();) { auto *pHeap = *it; if(pHeap->m_pMappedBuffer != nullptr) vkUnmapMemory(Device, pHeap->m_BufferMem.m_Mem); if(pHeap->m_Buffer != VK_NULL_HANDLE) vkDestroyBuffer(Device, pHeap->m_Buffer, nullptr); vkFreeMemory(Device, pHeap->m_BufferMem.m_Mem, nullptr); delete pHeap; it = m_MemoryCaches.m_MemoryHeaps.erase(it); } m_MemoryCaches.m_MemoryHeaps.clear(); m_FrameDelayedCachedBufferCleanup.clear(); } void Cleanup(size_t ImgIndex) { for(auto &MemBlock : m_FrameDelayedCachedBufferCleanup[ImgIndex]) { MemBlock.m_UsedSize = 0; MemBlock.m_pHeap->Free(MemBlock.m_HeapData); m_CanShrink = true; } m_FrameDelayedCachedBufferCleanup[ImgIndex].clear(); } void FreeMemBlock(SMemoryBlock &Block, size_t ImgIndex) { m_FrameDelayedCachedBufferCleanup[ImgIndex].push_back(Block); } // returns the total free'd memory size_t Shrink(VkDevice &Device) { size_t FreeedMemory = 0; if(m_CanShrink) { m_CanShrink = false; if(m_MemoryCaches.m_MemoryHeaps.size() > 1) { for(auto it = m_MemoryCaches.m_MemoryHeaps.begin(); it != m_MemoryCaches.m_MemoryHeaps.end();) { auto *pHeap = *it; if(pHeap->m_Heap.IsUnused()) { if(pHeap->m_pMappedBuffer != nullptr) vkUnmapMemory(Device, pHeap->m_BufferMem.m_Mem); if(pHeap->m_Buffer != VK_NULL_HANDLE) vkDestroyBuffer(Device, pHeap->m_Buffer, nullptr); vkFreeMemory(Device, pHeap->m_BufferMem.m_Mem, nullptr); FreeedMemory += pHeap->m_BufferMem.m_Size; delete pHeap; it = m_MemoryCaches.m_MemoryHeaps.erase(it); if(m_MemoryCaches.m_MemoryHeaps.size() == 1) break; } else ++it; } } } return FreeedMemory; } }; struct CTexture { VkImage m_Img = VK_NULL_HANDLE; SMemoryImageBlock m_ImgMem; VkImageView m_ImgView = VK_NULL_HANDLE; VkSampler m_aSamplers[2] = {VK_NULL_HANDLE, VK_NULL_HANDLE}; VkImage m_Img3D = VK_NULL_HANDLE; SMemoryImageBlock m_Img3DMem; VkImageView m_Img3DView = VK_NULL_HANDLE; VkSampler m_Sampler3D = VK_NULL_HANDLE; uint32_t m_Width = 0; uint32_t m_Height = 0; uint32_t m_RescaleCount = 0; uint32_t m_MipMapCount = 1; std::array m_aVKStandardTexturedDescrSets; SDeviceDescriptorSet m_VKStandard3DTexturedDescrSet; SDeviceDescriptorSet m_VKTextDescrSet; }; struct SBufferObject { SMemoryBlock m_Mem; }; struct SBufferObjectFrame { SBufferObject m_BufferObject; // since stream buffers can be used the cur buffer should always be used for rendering bool m_IsStreamedBuffer = false; VkBuffer m_CurBuffer = VK_NULL_HANDLE; size_t m_CurBufferOffset = 0; }; struct SBufferContainer { int m_BufferObjectIndex; }; struct SFrameBuffers { VkBuffer m_Buffer; SDeviceMemoryBlock m_BufferMem; size_t m_OffsetInBuffer = 0; size_t m_Size; size_t m_UsedSize; void *m_pMappedBufferData; SFrameBuffers(VkBuffer Buffer, SDeviceMemoryBlock BufferMem, size_t OffsetInBuffer, size_t Size, size_t UsedSize, void *pMappedBufferData) : m_Buffer(Buffer), m_BufferMem(BufferMem), m_OffsetInBuffer(OffsetInBuffer), m_Size(Size), m_UsedSize(UsedSize), m_pMappedBufferData(pMappedBufferData) { } }; struct SFrameUniformBuffers : public SFrameBuffers { std::array m_aUniformSets; SFrameUniformBuffers(VkBuffer Buffer, SDeviceMemoryBlock BufferMem, size_t OffsetInBuffer, size_t Size, size_t UsedSize, void *pMappedBufferData) : SFrameBuffers(Buffer, BufferMem, OffsetInBuffer, Size, UsedSize, pMappedBufferData) {} }; template struct SStreamMemory { typedef std::vector> TBufferObjectsOfFrame; typedef std::vector> TMemoryMapRangesOfFrame; typedef std::vector TStreamUseCount; TBufferObjectsOfFrame m_BufferObjectsOfFrame; TMemoryMapRangesOfFrame m_BufferObjectsOfFrameRangeData; TStreamUseCount m_CurrentUsedCount; std::vector &GetBuffers(size_t FrameImageIndex) { return m_BufferObjectsOfFrame[FrameImageIndex]; } std::vector &GetRanges(size_t FrameImageIndex) { return m_BufferObjectsOfFrameRangeData[FrameImageIndex]; } size_t GetUsedCount(size_t FrameImageIndex) { return m_CurrentUsedCount[FrameImageIndex]; } void IncreaseUsedCount(size_t FrameImageIndex) { ++m_CurrentUsedCount[FrameImageIndex]; } bool IsUsed(size_t FrameImageIndex) { return GetUsedCount(FrameImageIndex) > 0; } void ResetFrame(size_t FrameImageIndex) { m_CurrentUsedCount[FrameImageIndex] = 0; } void Init(size_t FrameImageCount) { m_BufferObjectsOfFrame.resize(FrameImageCount); m_BufferObjectsOfFrameRangeData.resize(FrameImageCount); m_CurrentUsedCount.resize(FrameImageCount); } typedef std::function TDestroyBufferFunc; void Destroy(TDestroyBufferFunc &&DestroyBuffer) { size_t ImageIndex = 0; for(auto &vBuffersOfFrame : m_BufferObjectsOfFrame) { for(auto &BufferOfFrame : vBuffersOfFrame) { VkDeviceMemory BufferMem = BufferOfFrame.m_BufferMem.m_Mem; DestroyBuffer(ImageIndex, BufferOfFrame); // delete similar buffers for(auto &BufferOfFrameDel : vBuffersOfFrame) { if(BufferOfFrameDel.m_BufferMem.m_Mem == BufferMem) { BufferOfFrameDel.m_Buffer = VK_NULL_HANDLE; BufferOfFrameDel.m_BufferMem.m_Mem = VK_NULL_HANDLE; } } } ++ImageIndex; } m_BufferObjectsOfFrame.clear(); m_BufferObjectsOfFrameRangeData.clear(); m_CurrentUsedCount.clear(); } }; struct SShaderModule { VkShaderModule m_VertShaderModule = VK_NULL_HANDLE; VkShaderModule m_FragShaderModule = VK_NULL_HANDLE; VkDevice m_VKDevice = VK_NULL_HANDLE; ~SShaderModule() { if(m_VKDevice != VK_NULL_HANDLE) { if(m_VertShaderModule != VK_NULL_HANDLE) vkDestroyShaderModule(m_VKDevice, m_VertShaderModule, nullptr); if(m_FragShaderModule != VK_NULL_HANDLE) vkDestroyShaderModule(m_VKDevice, m_FragShaderModule, nullptr); } } }; enum EVulkanBackendAddressModes { VULKAN_BACKEND_ADDRESS_MODE_REPEAT = 0, VULKAN_BACKEND_ADDRESS_MODE_CLAMP_EDGES, VULKAN_BACKEND_ADDRESS_MODE_COUNT, }; enum EVulkanBackendBlendModes { VULKAN_BACKEND_BLEND_MODE_ALPHA = 0, VULKAN_BACKEND_BLEND_MODE_NONE, VULKAN_BACKEND_BLEND_MODE_ADDITATIVE, VULKAN_BACKEND_BLEND_MODE_COUNT, }; enum EVulkanBackendClipModes { VULKAN_BACKEND_CLIP_MODE_NONE = 0, VULKAN_BACKEND_CLIP_MODE_DYNAMIC_SCISSOR_AND_VIEWPORT, VULKAN_BACKEND_CLIP_MODE_COUNT, }; enum EVulkanBackendTextureModes { VULKAN_BACKEND_TEXTURE_MODE_NOT_TEXTURED = 0, VULKAN_BACKEND_TEXTURE_MODE_TEXTURED, VULKAN_BACKEND_TEXTURE_MODE_COUNT, }; struct SPipelineContainer { // 3 blend modes - 2 viewport & scissor modes - 2 texture modes std::array, VULKAN_BACKEND_CLIP_MODE_COUNT>, VULKAN_BACKEND_BLEND_MODE_COUNT> m_aaaPipelineLayouts; std::array, VULKAN_BACKEND_CLIP_MODE_COUNT>, VULKAN_BACKEND_BLEND_MODE_COUNT> m_aaaPipelines; SPipelineContainer() { for(auto &aaPipeLayouts : m_aaaPipelineLayouts) { for(auto &aPipeLayouts : aaPipeLayouts) { for(auto &PipeLayout : aPipeLayouts) { PipeLayout = VK_NULL_HANDLE; } } } for(auto &aaPipe : m_aaaPipelines) { for(auto &aPipe : aaPipe) { for(auto &Pipe : aPipe) { Pipe = VK_NULL_HANDLE; } } } } void Destroy(VkDevice &Device) { for(auto &aaPipeLayouts : m_aaaPipelineLayouts) { for(auto &aPipeLayouts : aaPipeLayouts) { for(auto &PipeLayout : aPipeLayouts) { if(PipeLayout != VK_NULL_HANDLE) vkDestroyPipelineLayout(Device, PipeLayout, nullptr); PipeLayout = VK_NULL_HANDLE; } } } for(auto &aaPipe : m_aaaPipelines) { for(auto &aPipe : aaPipe) { for(auto &Pipe : aPipe) { if(Pipe != VK_NULL_HANDLE) vkDestroyPipeline(Device, Pipe, nullptr); Pipe = VK_NULL_HANDLE; } } } } }; /******************************* * UNIFORM PUSH CONSTANT LAYOUTS ********************************/ struct SUniformGPos { float m_aPos[4 * 2]; }; struct SUniformGTextPos { float m_aPos[4 * 2]; float m_TextureSize; }; struct SUniformTextGFragmentOffset { float m_Padding[3]; }; struct SUniformTextGFragmentConstants { float m_aTextColor[4]; float m_aTextOutlineColor[4]; }; struct SUniformTextFragment { SUniformTextGFragmentConstants m_Constants; }; struct SUniformTileGPos { float m_aPos[4 * 2]; }; struct SUniformTileGPosBorderLine : public SUniformTileGPos { vec2 m_Dir; vec2 m_Offset; }; struct SUniformTileGPosBorder : public SUniformTileGPosBorderLine { int32_t m_JumpIndex; }; struct SUniformTileGVertColor { float m_aColor[4]; }; struct SUniformTileGVertColorAlign { float m_aPad[(64 - 52) / 4]; }; struct SUniformPrimExGPosRotationless { float m_aPos[4 * 2]; }; struct SUniformPrimExGPos : public SUniformPrimExGPosRotationless { vec2 m_Center; float m_Rotation; }; struct SUniformPrimExGVertColor { float m_aColor[4]; }; struct SUniformPrimExGVertColorAlign { float m_aPad[(48 - 44) / 4]; }; struct SUniformSpriteMultiGPos { float m_aPos[4 * 2]; vec2 m_Center; }; struct SUniformSpriteMultiGVertColor { float m_aColor[4]; }; struct SUniformSpriteMultiGVertColorAlign { float m_aPad[(48 - 40) / 4]; }; struct SUniformSpriteMultiPushGPosBase { float m_aPos[4 * 2]; vec2 m_Center; vec2 m_Padding; }; struct SUniformSpriteMultiPushGPos : public SUniformSpriteMultiPushGPosBase { vec4 m_aPSR[1]; }; struct SUniformSpriteMultiPushGVertColor { float m_aColor[4]; }; struct SUniformQuadGPosBase { float m_aPos[4 * 2]; int32_t m_QuadOffset; }; struct SUniformQuadPushGBufferObject { vec4 m_VertColor; vec2 m_Offset; float m_Rotation; float m_Padding; }; struct SUniformQuadPushGPos { float m_aPos[4 * 2]; SUniformQuadPushGBufferObject m_BOPush; int32_t m_QuadOffset; }; struct SUniformQuadGPos { float m_aPos[4 * 2]; int32_t m_QuadOffset; }; enum ESupportedSamplerTypes { SUPPORTED_SAMPLER_TYPE_REPEAT = 0, SUPPORTED_SAMPLER_TYPE_CLAMP_TO_EDGE, SUPPORTED_SAMPLER_TYPE_2D_TEXTURE_ARRAY, SUPPORTED_SAMPLER_TYPE_COUNT, }; struct SShaderFileCache { std::vector m_Binary; }; struct SSwapImgViewportExtent { VkExtent2D m_SwapImg; VkExtent2D m_Viewport; }; struct SSwapChainMultiSampleImage { VkImage m_Image = VK_NULL_HANDLE; SMemoryImageBlock m_ImgMem; VkImageView m_ImgView = VK_NULL_HANDLE; }; /************************ * MEMBER VARIABLES ************************/ std::unordered_map m_ShaderFiles; SMemoryBlockCache m_StagingBufferCache; SMemoryBlockCache m_StagingBufferCacheImage; SMemoryBlockCache m_VertexBufferCache; std::map> m_ImageBufferCaches; std::vector m_NonFlushedStagingBufferRange; std::vector m_Textures; std::atomic *m_pTextureMemoryUsage; std::atomic *m_pBufferMemoryUsage; std::atomic *m_pStreamMemoryUsage; std::atomic *m_pStagingMemoryUsage; TTWGraphicsGPUList *m_pGPUList; int m_GlobalTextureLodBIAS; uint32_t m_MultiSamplingCount = 1; bool m_RecreateSwapChain = false; bool m_SwapchainCreated = false; bool m_RenderingPaused = false; bool m_HasDynamicViewport = false; VkOffset2D m_DynamicViewportOffset; VkExtent2D m_DynamicViewportSize; bool m_AllowsLinearBlitting = false; bool m_OptimalSwapChainImageBlitting = false; bool m_OptimalRGBAImageBlitting = false; bool m_LinearRGBAImageBlitting = false; VkBuffer m_IndexBuffer; SDeviceMemoryBlock m_IndexBufferMemory; VkBuffer m_RenderIndexBuffer; SDeviceMemoryBlock m_RenderIndexBufferMemory; size_t m_CurRenderIndexPrimitiveCount; VkDeviceSize m_NonCoherentMemAlignment; VkDeviceSize m_OptimalImageCopyMemAlignment; uint32_t m_MaxTextureSize; uint32_t m_MaxSamplerAnisotropy; VkSampleCountFlags m_MaxMultiSample; uint32_t m_MinUniformAlign; std::vector m_ScreenshotHelper; SDeviceMemoryBlock m_GetPresentedImgDataHelperMem; VkImage m_GetPresentedImgDataHelperImage = VK_NULL_HANDLE; uint8_t *m_pGetPresentedImgDataHelperMappedMemory = nullptr; VkDeviceSize m_GetPresentedImgDataHelperMappedLayoutOffset = 0; VkDeviceSize m_GetPresentedImgDataHelperMappedLayoutPitch = 0; uint32_t m_GetPresentedImgDataHelperWidth = 0; uint32_t m_GetPresentedImgDataHelperHeight = 0; VkFence m_GetPresentedImgDataHelperFence = VK_NULL_HANDLE; std::array m_aSamplers; class IStorage *m_pStorage; struct SDelayedBufferCleanupItem { VkBuffer m_Buffer; SDeviceMemoryBlock m_Mem; void *m_pMappedData = nullptr; }; std::vector> m_FrameDelayedBufferCleanup; std::vector> m_FrameDelayedTextureCleanup; std::vector>> m_FrameDelayedTextTexturesCleanup; size_t m_ThreadCount = 1; static constexpr size_t ms_MainThreadIndex = 0; size_t m_CurCommandInPipe = 0; size_t m_CurRenderCallCountInPipe = 0; size_t m_CommandsInPipe = 0; size_t m_RenderCallsInPipe = 0; size_t m_LastCommandsInPipeThreadIndex = 0; struct SRenderThread { bool m_IsRendering = false; std::thread m_Thread; std::mutex m_Mutex; std::condition_variable m_Cond; bool m_Finished = false; bool m_Started = false; }; std::vector> m_RenderThreads; private: std::vector m_SwapChainImageViewList; std::vector m_SwapChainMultiSamplingImages; std::vector m_FramebufferList; std::vector m_MainDrawCommandBuffers; std::vector> m_ThreadDrawCommandBuffers; std::vector m_HelperThreadDrawCommandBuffers; std::vector> m_UsedThreadDrawCommandBuffer; std::vector m_MemoryCommandBuffers; std::vector m_UsedMemoryCommandBuffer; // swapped by use case std::vector m_WaitSemaphores; std::vector m_SigSemaphores; std::vector m_MemorySemaphores; std::vector m_FrameFences; std::vector m_ImagesFences; uint64_t m_CurFrame = 0; std::vector m_ImageLastFrameCheck; uint32_t m_LastPresentedSwapChainImageIndex; std::vector m_BufferObjects; std::vector m_BufferContainers; VkInstance m_VKInstance; VkPhysicalDevice m_VKGPU; uint32_t m_VKGraphicsQueueIndex = std::numeric_limits::max(); VkDevice m_VKDevice; VkQueue m_VKGraphicsQueue, m_VKPresentQueue; VkSurfaceKHR m_VKPresentSurface; SSwapImgViewportExtent m_VKSwapImgAndViewportExtent; #ifdef VK_EXT_debug_utils VkDebugUtilsMessengerEXT m_DebugMessenger; #endif VkDescriptorSetLayout m_StandardTexturedDescriptorSetLayout; VkDescriptorSetLayout m_Standard3DTexturedDescriptorSetLayout; VkDescriptorSetLayout m_TextDescriptorSetLayout; VkDescriptorSetLayout m_SpriteMultiUniformDescriptorSetLayout; VkDescriptorSetLayout m_QuadUniformDescriptorSetLayout; SPipelineContainer m_StandardPipeline; SPipelineContainer m_StandardLinePipeline; SPipelineContainer m_Standard3DPipeline; SPipelineContainer m_TextPipeline; SPipelineContainer m_TilePipeline; SPipelineContainer m_TileBorderPipeline; SPipelineContainer m_TileBorderLinePipeline; SPipelineContainer m_PrimExPipeline; SPipelineContainer m_PrimExRotationlessPipeline; SPipelineContainer m_SpriteMultiPipeline; SPipelineContainer m_SpriteMultiPushPipeline; SPipelineContainer m_QuadPipeline; SPipelineContainer m_QuadPushPipeline; std::vector m_vLastPipeline; std::vector m_vCommandPools; VkRenderPass m_VKRenderPass; VkSurfaceFormatKHR m_VKSurfFormat; SDeviceDescriptorPools m_StandardTextureDescrPool; SDeviceDescriptorPools m_TextTextureDescrPool; std::vector m_UniformBufferDescrPools; VkSwapchainKHR m_VKSwapChain = VK_NULL_HANDLE; std::vector m_SwapChainImages; uint32_t m_SwapChainImageCount = 0; std::vector> m_vStreamedVertexBuffers; std::vector> m_vStreamedUniformBuffers; uint32_t m_CurFrames = 0; uint32_t m_CurImageIndex = 0; uint32_t m_CanvasWidth; uint32_t m_CanvasHeight; SDL_Window *m_pWindow; std::array m_aClearColor = {0, 0, 0, 0}; struct SRenderCommandExecuteBuffer { CCommandBuffer::ECommandBufferCMD m_Command; const CCommandBuffer::SCommand *m_pRawCommand; uint32_t m_ThreadIndex; // must be calculated when the buffer gets filled size_t m_EstimatedRenderCallCount = 0; // usefull data VkBuffer m_Buffer; size_t m_BufferOff; std::array m_aDescriptors; VkBuffer m_IndexBuffer; bool m_ClearColorInRenderThread = false; bool m_HasDynamicState = false; VkViewport m_Viewport; VkRect2D m_Scissor; }; typedef std::vector TCommandList; typedef std::vector TThreadCommandList; TThreadCommandList m_ThreadCommandLists; std::vector m_ThreadHelperHadCommands; typedef std::function TCommandBufferCommandCallback; typedef std::function TCommandBufferFillExecuteBufferFunc; struct SCommandCallback { bool m_IsRenderCommand; TCommandBufferFillExecuteBufferFunc m_FillExecuteBuffer; TCommandBufferCommandCallback m_CommandCB; }; std::array m_aCommandCallbacks; protected: /************************ * ERROR MANAGMENT ************************/ char m_aError[1024]; bool m_HasError = false; bool m_CanAssert = false; void SetError(const char *pErr, const char *pErrStrExtra = nullptr) { char aError[1024]; if(pErrStrExtra == nullptr) str_format(aError, std::size(aError), "%s", pErr); else str_format(aError, std::size(aError), "%s: %s", pErr, pErrStrExtra); dbg_msg("vulkan", "vulkan error: %s", aError); m_HasError = true; dbg_assert(!m_CanAssert, aError); } void SetWarning(const char *pErr) { dbg_msg("vulkan", "vulkan warning: %s", pErr); } const char *CheckVulkanCriticalError(VkResult CallResult) { const char *pCriticalError = nullptr; switch(CallResult) { case VK_ERROR_OUT_OF_HOST_MEMORY: pCriticalError = "host ran out of memory"; dbg_msg("vulkan", "%s", pCriticalError); break; case VK_ERROR_OUT_OF_DEVICE_MEMORY: pCriticalError = "device ran out of memory"; dbg_msg("vulkan", "%s", pCriticalError); break; case VK_ERROR_DEVICE_LOST: pCriticalError = "device lost"; dbg_msg("vulkan", "%s", pCriticalError); break; case VK_ERROR_OUT_OF_DATE_KHR: { if(IsVerbose()) { dbg_msg("vulkan", "queueing swap chain recreation because the current is out of date"); } m_RecreateSwapChain = true; break; } case VK_ERROR_SURFACE_LOST_KHR: dbg_msg("vulkan", "surface lost"); break; /*case VK_ERROR_FULL_SCREEN_EXCLUSIVE_MODE_LOST_EXT: dbg_msg("vulkan", "fullscreen exlusive mode lost"); break;*/ case VK_ERROR_INCOMPATIBLE_DRIVER: pCriticalError = "no compatible driver found. Vulkan 1.1 is required."; dbg_msg("vulkan", "%s", pCriticalError); break; case VK_ERROR_INITIALIZATION_FAILED: pCriticalError = "initialization failed for unknown reason."; dbg_msg("vulkan", "%s", pCriticalError); break; case VK_ERROR_LAYER_NOT_PRESENT: SetWarning("One Vulkan layer was not present. (try to disable them)"); break; case VK_ERROR_EXTENSION_NOT_PRESENT: SetWarning("One Vulkan extension was not present. (try to disable them)"); break; case VK_ERROR_NATIVE_WINDOW_IN_USE_KHR: dbg_msg("vulkan", "native window in use"); break; case VK_SUCCESS: break; case VK_SUBOPTIMAL_KHR: if(IsVerbose()) { dbg_msg("vulkan", "queueing swap chain recreation because the current is sub optimal"); } m_RecreateSwapChain = true; break; default: str_format(m_aError, std::size(m_aError), "unknown error %u", (uint32_t)CallResult); pCriticalError = m_aError; break; } return pCriticalError; } /************************ * COMMAND CALLBACKS ************************/ size_t CommandBufferCMDOff(CCommandBuffer::ECommandBufferCMD CommandBufferCMD) { return (size_t)CommandBufferCMD - CCommandBuffer::ECommandBufferCMD::CMD_FIRST; } void RegisterCommands() { m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_TEXTURE_CREATE)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_Texture_Create(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_TEXTURE_DESTROY)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_Texture_Destroy(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_TEXTURE_UPDATE)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_Texture_Update(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_TEXT_TEXTURES_CREATE)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_TextTextures_Create(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_TEXT_TEXTURES_DESTROY)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_TextTextures_Destroy(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_TEXT_TEXTURE_UPDATE)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_TextTexture_Update(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_CLEAR)] = {true, [this](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) { Cmd_Clear_FillExecuteBuffer(ExecBuffer, static_cast(pBaseCommand)); }, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_Clear(ExecBuffer, static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_RENDER)] = {true, [this](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) { Cmd_Render_FillExecuteBuffer(ExecBuffer, static_cast(pBaseCommand)); }, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_Render(static_cast(pBaseCommand), ExecBuffer); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_RENDER_TEX3D)] = {true, [this](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) { Cmd_RenderTex3D_FillExecuteBuffer(ExecBuffer, static_cast(pBaseCommand)); }, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_RenderTex3D(static_cast(pBaseCommand), ExecBuffer); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_CREATE_BUFFER_OBJECT)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_CreateBufferObject(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_RECREATE_BUFFER_OBJECT)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_RecreateBufferObject(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_UPDATE_BUFFER_OBJECT)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_UpdateBufferObject(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_COPY_BUFFER_OBJECT)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_CopyBufferObject(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_DELETE_BUFFER_OBJECT)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_DeleteBufferObject(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_CREATE_BUFFER_CONTAINER)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_CreateBufferContainer(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_DELETE_BUFFER_CONTAINER)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_DeleteBufferContainer(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_UPDATE_BUFFER_CONTAINER)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_UpdateBufferContainer(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_INDICES_REQUIRED_NUM_NOTIFY)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_IndicesRequiredNumNotify(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_RENDER_TILE_LAYER)] = {true, [this](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) { Cmd_RenderTileLayer_FillExecuteBuffer(ExecBuffer, static_cast(pBaseCommand)); }, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_RenderTileLayer(static_cast(pBaseCommand), ExecBuffer); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_RENDER_BORDER_TILE)] = {true, [this](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) { Cmd_RenderBorderTile_FillExecuteBuffer(ExecBuffer, static_cast(pBaseCommand)); }, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_RenderBorderTile(static_cast(pBaseCommand), ExecBuffer); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_RENDER_BORDER_TILE_LINE)] = {true, [this](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) { Cmd_RenderBorderTileLine_FillExecuteBuffer(ExecBuffer, static_cast(pBaseCommand)); }, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_RenderBorderTileLine(static_cast(pBaseCommand), ExecBuffer); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_RENDER_QUAD_LAYER)] = {true, [this](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) { Cmd_RenderQuadLayer_FillExecuteBuffer(ExecBuffer, static_cast(pBaseCommand)); }, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_RenderQuadLayer(static_cast(pBaseCommand), ExecBuffer); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_RENDER_TEXT)] = {true, [this](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) { Cmd_RenderText_FillExecuteBuffer(ExecBuffer, static_cast(pBaseCommand)); }, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_RenderText(static_cast(pBaseCommand), ExecBuffer); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_RENDER_QUAD_CONTAINER)] = {true, [this](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) { Cmd_RenderQuadContainer_FillExecuteBuffer(ExecBuffer, static_cast(pBaseCommand)); }, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_RenderQuadContainer(static_cast(pBaseCommand), ExecBuffer); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_RENDER_QUAD_CONTAINER_EX)] = {true, [this](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) { Cmd_RenderQuadContainerEx_FillExecuteBuffer(ExecBuffer, static_cast(pBaseCommand)); }, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_RenderQuadContainerEx(static_cast(pBaseCommand), ExecBuffer); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_RENDER_QUAD_CONTAINER_SPRITE_MULTIPLE)] = {true, [this](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) { Cmd_RenderQuadContainerAsSpriteMultiple_FillExecuteBuffer(ExecBuffer, static_cast(pBaseCommand)); }, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_RenderQuadContainerAsSpriteMultiple(static_cast(pBaseCommand), ExecBuffer); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_SWAP)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_Swap(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_FINISH)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_Finish(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_VSYNC)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_VSync(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_TRY_SWAP_AND_SCREENSHOT)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_Screenshot(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_UPDATE_VIEWPORT)] = {false, [this](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) { Cmd_Update_Viewport_FillExecuteBuffer(ExecBuffer, static_cast(pBaseCommand)); }, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_Update_Viewport(static_cast(pBaseCommand)); return true; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_WINDOW_CREATE_NTF)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_WindowCreateNtf(static_cast(pBaseCommand)); return false; }}; m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::CMD_WINDOW_DESTROY_NTF)] = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [this](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { Cmd_WindowDestroyNtf(static_cast(pBaseCommand)); return false; }}; for(auto &Callback : m_aCommandCallbacks) { if(!(bool)Callback.m_CommandCB) Callback = {false, [](SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand *pBaseCommand) {}, [](const CCommandBuffer::SCommand *pBaseCommand, SRenderCommandExecuteBuffer &ExecBuffer) { return true; }}; } } /***************************** * VIDEO AND SCREENSHOT HELPER ******************************/ uint8_t *PreparePresentedImageDataImage(uint32_t Width, uint32_t Height) { bool NeedsNewImg = Width != m_GetPresentedImgDataHelperWidth || Height != m_GetPresentedImgDataHelperHeight; if(m_GetPresentedImgDataHelperImage == VK_NULL_HANDLE || NeedsNewImg) { if(m_GetPresentedImgDataHelperImage != VK_NULL_HANDLE) { DeletePresentedImageDataImage(); } m_GetPresentedImgDataHelperWidth = Width; m_GetPresentedImgDataHelperHeight = Height; VkImageCreateInfo ImageInfo{}; ImageInfo.sType = VK_STRUCTURE_TYPE_IMAGE_CREATE_INFO; ImageInfo.imageType = VK_IMAGE_TYPE_2D; ImageInfo.extent.width = Width; ImageInfo.extent.height = Height; ImageInfo.extent.depth = 1; ImageInfo.mipLevels = 1; ImageInfo.arrayLayers = 1; ImageInfo.format = VK_FORMAT_R8G8B8A8_UNORM; ImageInfo.tiling = VK_IMAGE_TILING_LINEAR; ImageInfo.initialLayout = VK_IMAGE_LAYOUT_UNDEFINED; ImageInfo.usage = VK_IMAGE_USAGE_TRANSFER_DST_BIT; ImageInfo.samples = VK_SAMPLE_COUNT_1_BIT; ImageInfo.sharingMode = VK_SHARING_MODE_EXCLUSIVE; vkCreateImage(m_VKDevice, &ImageInfo, nullptr, &m_GetPresentedImgDataHelperImage); // Create memory to back up the image VkMemoryRequirements MemRequirements; vkGetImageMemoryRequirements(m_VKDevice, m_GetPresentedImgDataHelperImage, &MemRequirements); VkMemoryAllocateInfo MemAllocInfo{}; MemAllocInfo.sType = VK_STRUCTURE_TYPE_MEMORY_ALLOCATE_INFO; MemAllocInfo.allocationSize = MemRequirements.size; MemAllocInfo.memoryTypeIndex = FindMemoryType(m_VKGPU, MemRequirements.memoryTypeBits, VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT | VK_MEMORY_PROPERTY_HOST_CACHED_BIT); vkAllocateMemory(m_VKDevice, &MemAllocInfo, nullptr, &m_GetPresentedImgDataHelperMem.m_Mem); vkBindImageMemory(m_VKDevice, m_GetPresentedImgDataHelperImage, m_GetPresentedImgDataHelperMem.m_Mem, 0); ImageBarrier(m_GetPresentedImgDataHelperImage, 0, 1, 0, 1, VK_FORMAT_R8G8B8A8_UNORM, VK_IMAGE_LAYOUT_UNDEFINED, VK_IMAGE_LAYOUT_GENERAL); VkImageSubresource SubResource{VK_IMAGE_ASPECT_COLOR_BIT, 0, 0}; VkSubresourceLayout SubResourceLayout; vkGetImageSubresourceLayout(m_VKDevice, m_GetPresentedImgDataHelperImage, &SubResource, &SubResourceLayout); vkMapMemory(m_VKDevice, m_GetPresentedImgDataHelperMem.m_Mem, 0, VK_WHOLE_SIZE, 0, (void **)&m_pGetPresentedImgDataHelperMappedMemory); m_GetPresentedImgDataHelperMappedLayoutOffset = SubResourceLayout.offset; m_GetPresentedImgDataHelperMappedLayoutPitch = SubResourceLayout.rowPitch; m_pGetPresentedImgDataHelperMappedMemory += m_GetPresentedImgDataHelperMappedLayoutOffset; VkFenceCreateInfo FenceInfo{}; FenceInfo.sType = VK_STRUCTURE_TYPE_FENCE_CREATE_INFO; FenceInfo.flags = VK_FENCE_CREATE_SIGNALED_BIT; vkCreateFence(m_VKDevice, &FenceInfo, nullptr, &m_GetPresentedImgDataHelperFence); } return m_pGetPresentedImgDataHelperMappedMemory; } void DeletePresentedImageDataImage() { if(m_GetPresentedImgDataHelperImage != VK_NULL_HANDLE) { vkDestroyFence(m_VKDevice, m_GetPresentedImgDataHelperFence, nullptr); m_GetPresentedImgDataHelperFence = VK_NULL_HANDLE; vkDestroyImage(m_VKDevice, m_GetPresentedImgDataHelperImage, nullptr); vkUnmapMemory(m_VKDevice, m_GetPresentedImgDataHelperMem.m_Mem); vkFreeMemory(m_VKDevice, m_GetPresentedImgDataHelperMem.m_Mem, nullptr); m_GetPresentedImgDataHelperImage = VK_NULL_HANDLE; m_GetPresentedImgDataHelperMem = {}; m_pGetPresentedImgDataHelperMappedMemory = nullptr; m_GetPresentedImgDataHelperWidth = 0; m_GetPresentedImgDataHelperHeight = 0; } } bool GetPresentedImageDataImpl(uint32_t &Width, uint32_t &Height, uint32_t &Format, std::vector &DstData, bool FlipImgData, bool ResetAlpha) { bool IsB8G8R8A8 = m_VKSurfFormat.format == VK_FORMAT_B8G8R8A8_UNORM; bool UsesRGBALikeFormat = m_VKSurfFormat.format == VK_FORMAT_R8G8B8A8_UNORM || IsB8G8R8A8; if(UsesRGBALikeFormat && m_LastPresentedSwapChainImageIndex != std::numeric_limits::max()) { Width = m_VKSwapImgAndViewportExtent.m_Viewport.width; Height = m_VKSwapImgAndViewportExtent.m_Viewport.height; Format = CImageInfo::FORMAT_RGBA; size_t ImageTotalSize = (size_t)Width * Height * 4; PreparePresentedImageDataImage(Width, Height); VkCommandBuffer CommandBuffer = GetMemoryCommandBuffer(); VkBufferImageCopy Region{}; Region.bufferOffset = 0; Region.bufferRowLength = 0; Region.bufferImageHeight = 0; Region.imageSubresource.aspectMask = VK_IMAGE_ASPECT_COLOR_BIT; Region.imageSubresource.mipLevel = 0; Region.imageSubresource.baseArrayLayer = 0; Region.imageSubresource.layerCount = 1; Region.imageOffset = {0, 0, 0}; Region.imageExtent = {m_VKSwapImgAndViewportExtent.m_Viewport.width, m_VKSwapImgAndViewportExtent.m_Viewport.height, 1}; auto &SwapImg = m_SwapChainImages[m_LastPresentedSwapChainImageIndex]; ImageBarrier(m_GetPresentedImgDataHelperImage, 0, 1, 0, 1, VK_FORMAT_R8G8B8A8_UNORM, VK_IMAGE_LAYOUT_GENERAL, VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL); ImageBarrier(SwapImg, 0, 1, 0, 1, m_VKSurfFormat.format, VK_IMAGE_LAYOUT_PRESENT_SRC_KHR, VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL); // If source and destination support blit we'll blit as this also does automatic format conversion (e.g. from BGR to RGB) if(m_OptimalSwapChainImageBlitting && m_LinearRGBAImageBlitting) { VkOffset3D BlitSize; BlitSize.x = Width; BlitSize.y = Height; BlitSize.z = 1; VkImageBlit ImageBlitRegion{}; ImageBlitRegion.srcSubresource.aspectMask = VK_IMAGE_ASPECT_COLOR_BIT; ImageBlitRegion.srcSubresource.layerCount = 1; ImageBlitRegion.srcOffsets[1] = BlitSize; ImageBlitRegion.dstSubresource.aspectMask = VK_IMAGE_ASPECT_COLOR_BIT; ImageBlitRegion.dstSubresource.layerCount = 1; ImageBlitRegion.dstOffsets[1] = BlitSize; // Issue the blit command vkCmdBlitImage(CommandBuffer, SwapImg, VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL, m_GetPresentedImgDataHelperImage, VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL, 1, &ImageBlitRegion, VK_FILTER_NEAREST); // transformed to RGBA IsB8G8R8A8 = false; } else { // Otherwise use image copy (requires us to manually flip components) VkImageCopy ImageCopyRegion{}; ImageCopyRegion.srcSubresource.aspectMask = VK_IMAGE_ASPECT_COLOR_BIT; ImageCopyRegion.srcSubresource.layerCount = 1; ImageCopyRegion.dstSubresource.aspectMask = VK_IMAGE_ASPECT_COLOR_BIT; ImageCopyRegion.dstSubresource.layerCount = 1; ImageCopyRegion.extent.width = Width; ImageCopyRegion.extent.height = Height; ImageCopyRegion.extent.depth = 1; // Issue the copy command vkCmdCopyImage(CommandBuffer, SwapImg, VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL, m_GetPresentedImgDataHelperImage, VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL, 1, &ImageCopyRegion); } ImageBarrier(m_GetPresentedImgDataHelperImage, 0, 1, 0, 1, VK_FORMAT_R8G8B8A8_UNORM, VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL, VK_IMAGE_LAYOUT_GENERAL); ImageBarrier(SwapImg, 0, 1, 0, 1, m_VKSurfFormat.format, VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL, VK_IMAGE_LAYOUT_PRESENT_SRC_KHR); vkEndCommandBuffer(CommandBuffer); m_UsedMemoryCommandBuffer[m_CurImageIndex] = false; VkSubmitInfo SubmitInfo{}; SubmitInfo.sType = VK_STRUCTURE_TYPE_SUBMIT_INFO; SubmitInfo.commandBufferCount = 1; SubmitInfo.pCommandBuffers = &CommandBuffer; vkResetFences(m_VKDevice, 1, &m_GetPresentedImgDataHelperFence); vkQueueSubmit(m_VKGraphicsQueue, 1, &SubmitInfo, m_GetPresentedImgDataHelperFence); vkWaitForFences(m_VKDevice, 1, &m_GetPresentedImgDataHelperFence, VK_TRUE, std::numeric_limits::max()); VkMappedMemoryRange MemRange{}; MemRange.sType = VK_STRUCTURE_TYPE_MAPPED_MEMORY_RANGE; MemRange.memory = m_GetPresentedImgDataHelperMem.m_Mem; MemRange.offset = m_GetPresentedImgDataHelperMappedLayoutOffset; MemRange.size = VK_WHOLE_SIZE; vkInvalidateMappedMemoryRanges(m_VKDevice, 1, &MemRange); size_t RealFullImageSize = maximum(ImageTotalSize, (size_t)(Height * m_GetPresentedImgDataHelperMappedLayoutPitch)); if(DstData.size() < RealFullImageSize + (Width * 4)) DstData.resize(RealFullImageSize + (Width * 4)); // extra space for flipping mem_copy(DstData.data(), m_pGetPresentedImgDataHelperMappedMemory, RealFullImageSize); // pack image data together without any offset that the driver might require if(Width * 4 < m_GetPresentedImgDataHelperMappedLayoutPitch) { for(uint32_t Y = 0; Y < Height; ++Y) { size_t OffsetImagePacked = (Y * Width * 4); size_t OffsetImageUnpacked = (Y * m_GetPresentedImgDataHelperMappedLayoutPitch); mem_copy(DstData.data() + OffsetImagePacked, DstData.data() + OffsetImageUnpacked, Width * 4); } } if(IsB8G8R8A8 || ResetAlpha) { // swizzle for(uint32_t Y = 0; Y < Height; ++Y) { for(uint32_t X = 0; X < Width; ++X) { size_t ImgOff = (Y * Width * 4) + (X * 4); if(IsB8G8R8A8) { std::swap(DstData[ImgOff], DstData[ImgOff + 2]); } DstData[ImgOff + 3] = 255; } } } if(FlipImgData) { uint8_t *pTempRow = DstData.data() + Width * Height * 4; for(uint32_t Y = 0; Y < Height / 2; ++Y) { mem_copy(pTempRow, DstData.data() + Y * Width * 4, Width * 4); mem_copy(DstData.data() + Y * Width * 4, DstData.data() + ((Height - Y) - 1) * Width * 4, Width * 4); mem_copy(DstData.data() + ((Height - Y) - 1) * Width * 4, pTempRow, Width * 4); } } return true; } else { if(!UsesRGBALikeFormat) { dbg_msg("vulkan", "swap chain image was not in a RGBA like format."); } else { dbg_msg("vulkan", "swap chain image was not ready to be copied."); } return false; } } bool GetPresentedImageData(uint32_t &Width, uint32_t &Height, uint32_t &Format, std::vector &DstData) override { return GetPresentedImageDataImpl(Width, Height, Format, DstData, false, false); } /************************ * MEMORY MANAGMENT ************************/ bool AllocateVulkanMemory(const VkMemoryAllocateInfo *pAllocateInfo, VkDeviceMemory *pMemory) { VkResult Res = vkAllocateMemory(m_VKDevice, pAllocateInfo, nullptr, pMemory); if(Res != VK_SUCCESS) { dbg_msg("vulkan", "vulkan memory allocation failed, trying to recover."); if(Res == VK_ERROR_OUT_OF_HOST_MEMORY || Res == VK_ERROR_OUT_OF_DEVICE_MEMORY) { // aggressivly try to get more memory vkDeviceWaitIdle(m_VKDevice); for(size_t i = 0; i < m_SwapChainImageCount + 1; ++i) NextFrame(); Res = vkAllocateMemory(m_VKDevice, pAllocateInfo, nullptr, pMemory); } if(Res != VK_SUCCESS) { dbg_msg("vulkan", "vulkan memory allocation failed."); return false; } } return true; } void GetBufferImpl(VkDeviceSize RequiredSize, EMemoryBlockUsage MemUsage, VkBuffer &Buffer, SDeviceMemoryBlock &BufferMemory, VkBufferUsageFlags BufferUsage, VkMemoryPropertyFlags BufferProperties) { CreateBuffer(RequiredSize, MemUsage, BufferUsage, BufferProperties, Buffer, BufferMemory); } template SMemoryBlock GetBufferBlockImpl(SMemoryBlockCache &MemoryCache, VkBufferUsageFlags BufferUsage, VkMemoryPropertyFlags BufferProperties, const void *pBufferData, VkDeviceSize RequiredSize, VkDeviceSize TargetAlignment) { SMemoryBlock RetBlock; auto &&CreateCacheBlock = [&]() { bool FoundAllocation = false; SMemoryHeap::SMemoryHeapQueueElement AllocatedMem; SDeviceMemoryBlock TmpBufferMemory; typename SMemoryBlockCache::SMemoryCacheType::SMemoryCacheHeap *pCacheHeap = nullptr; auto &Heaps = MemoryCache.m_MemoryCaches.m_MemoryHeaps; for(size_t i = 0; i < Heaps.size(); ++i) { auto *pHeap = Heaps[i]; if(pHeap->m_Heap.Allocate(RequiredSize, TargetAlignment, AllocatedMem)) { TmpBufferMemory = pHeap->m_BufferMem; FoundAllocation = true; pCacheHeap = pHeap; break; } } if(!FoundAllocation) { typename SMemoryBlockCache::SMemoryCacheType::SMemoryCacheHeap *pNewHeap = new typename SMemoryBlockCache::SMemoryCacheType::SMemoryCacheHeap(); VkBuffer TmpBuffer; GetBufferImpl(MemoryBlockSize * BlockCount, RequiresMapping ? MEMORY_BLOCK_USAGE_STAGING : MEMORY_BLOCK_USAGE_BUFFER, TmpBuffer, TmpBufferMemory, BufferUsage, BufferProperties); void *pMapData = nullptr; if(RequiresMapping) { if(vkMapMemory(m_VKDevice, TmpBufferMemory.m_Mem, 0, VK_WHOLE_SIZE, 0, &pMapData) != VK_SUCCESS) { SetError("Failed to map buffer block memory."); } } pNewHeap->m_Buffer = TmpBuffer; pNewHeap->m_BufferMem = TmpBufferMemory; pNewHeap->m_pMappedBuffer = pMapData; pCacheHeap = pNewHeap; Heaps.emplace_back(pNewHeap); Heaps.back()->m_Heap.Init(MemoryBlockSize * BlockCount, 0); if(!Heaps.back()->m_Heap.Allocate(RequiredSize, TargetAlignment, AllocatedMem)) { dbg_assert(false, "Heap allocation failed directly after creating fresh heap"); } } RetBlock.m_Buffer = pCacheHeap->m_Buffer; RetBlock.m_BufferMem = TmpBufferMemory; if(RequiresMapping) RetBlock.m_pMappedBuffer = ((uint8_t *)pCacheHeap->m_pMappedBuffer) + AllocatedMem.m_OffsetToAlign; else RetBlock.m_pMappedBuffer = nullptr; RetBlock.m_IsCached = true; RetBlock.m_pHeap = &pCacheHeap->m_Heap; RetBlock.m_HeapData = AllocatedMem; RetBlock.m_UsedSize = RequiredSize; if(RequiresMapping) mem_copy(RetBlock.m_pMappedBuffer, pBufferData, RequiredSize); }; if(RequiredSize < (VkDeviceSize)MemoryBlockSize) { CreateCacheBlock(); } else { VkBuffer TmpBuffer; SDeviceMemoryBlock TmpBufferMemory; GetBufferImpl(RequiredSize, RequiresMapping ? MEMORY_BLOCK_USAGE_STAGING : MEMORY_BLOCK_USAGE_BUFFER, TmpBuffer, TmpBufferMemory, BufferUsage, BufferProperties); void *pMapData = nullptr; if(RequiresMapping) { vkMapMemory(m_VKDevice, TmpBufferMemory.m_Mem, 0, VK_WHOLE_SIZE, 0, &pMapData); mem_copy(pMapData, pBufferData, static_cast(RequiredSize)); } RetBlock.m_Buffer = TmpBuffer; RetBlock.m_BufferMem = TmpBufferMemory; RetBlock.m_pMappedBuffer = pMapData; RetBlock.m_pHeap = nullptr; RetBlock.m_IsCached = false; RetBlock.m_HeapData.m_OffsetToAlign = 0; RetBlock.m_HeapData.m_AllocationSize = RequiredSize; RetBlock.m_UsedSize = RequiredSize; } return RetBlock; } SMemoryBlock GetStagingBuffer(const void *pBufferData, VkDeviceSize RequiredSize) { return GetBufferBlockImpl(m_StagingBufferCache, VK_BUFFER_USAGE_TRANSFER_SRC_BIT, VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT | VK_MEMORY_PROPERTY_HOST_CACHED_BIT, pBufferData, RequiredSize, maximum(m_NonCoherentMemAlignment, 16)); } SMemoryBlock GetStagingBufferImage(const void *pBufferData, VkDeviceSize RequiredSize) { return GetBufferBlockImpl(m_StagingBufferCacheImage, VK_BUFFER_USAGE_TRANSFER_SRC_BIT, VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT | VK_MEMORY_PROPERTY_HOST_CACHED_BIT, pBufferData, RequiredSize, maximum(m_OptimalImageCopyMemAlignment, maximum(m_NonCoherentMemAlignment, 16))); } template void PrepareStagingMemRange(SMemoryBlock &Block) { VkMappedMemoryRange UploadRange{}; UploadRange.sType = VK_STRUCTURE_TYPE_MAPPED_MEMORY_RANGE; UploadRange.memory = Block.m_BufferMem.m_Mem; UploadRange.offset = Block.m_HeapData.m_OffsetToAlign; auto AlignmentMod = ((VkDeviceSize)Block.m_HeapData.m_AllocationSize % m_NonCoherentMemAlignment); auto AlignmentReq = (m_NonCoherentMemAlignment - AlignmentMod); if(AlignmentMod == 0) AlignmentReq = 0; UploadRange.size = Block.m_HeapData.m_AllocationSize + AlignmentReq; if(UploadRange.offset + UploadRange.size > Block.m_BufferMem.m_Size) UploadRange.size = VK_WHOLE_SIZE; m_NonFlushedStagingBufferRange.push_back(UploadRange); } void UploadAndFreeStagingMemBlock(SMemoryBlock &Block) { PrepareStagingMemRange(Block); if(!Block.m_IsCached) { m_FrameDelayedBufferCleanup[m_CurImageIndex].push_back({Block.m_Buffer, Block.m_BufferMem, Block.m_pMappedBuffer}); } else { m_StagingBufferCache.FreeMemBlock(Block, m_CurImageIndex); } } void UploadAndFreeStagingImageMemBlock(SMemoryBlock &Block) { PrepareStagingMemRange(Block); if(!Block.m_IsCached) { m_FrameDelayedBufferCleanup[m_CurImageIndex].push_back({Block.m_Buffer, Block.m_BufferMem, Block.m_pMappedBuffer}); } else { m_StagingBufferCacheImage.FreeMemBlock(Block, m_CurImageIndex); } } SMemoryBlock GetVertexBuffer(VkDeviceSize RequiredSize) { return GetBufferBlockImpl(m_VertexBufferCache, VK_BUFFER_USAGE_TRANSFER_DST_BIT | VK_BUFFER_USAGE_VERTEX_BUFFER_BIT, VK_MEMORY_PROPERTY_DEVICE_LOCAL_BIT, nullptr, RequiredSize, 16); } void FreeVertexMemBlock(SMemoryBlock &Block) { if(!Block.m_IsCached) { m_FrameDelayedBufferCleanup[m_CurImageIndex].push_back({Block.m_Buffer, Block.m_BufferMem, nullptr}); } else { m_VertexBufferCache.FreeMemBlock(Block, m_CurImageIndex); } } static size_t ImageMipLevelCount(size_t Width, size_t Height, size_t Depth) { return floor(log2(maximum(Width, maximum(Height, Depth)))) + 1; } static size_t ImageMipLevelCount(VkExtent3D &ImgExtent) { return ImageMipLevelCount(ImgExtent.width, ImgExtent.height, ImgExtent.depth); } // good approximation of 1024x1024 image with mipmaps static constexpr int64_t s_1024x1024ImgSize = (1024 * 1024 * 4) * 2; bool GetImageMemoryImpl(VkDeviceSize RequiredSize, uint32_t RequiredMemoryTypeBits, SDeviceMemoryBlock &BufferMemory, VkMemoryPropertyFlags BufferProperties) { VkMemoryAllocateInfo MemAllocInfo{}; MemAllocInfo.sType = VK_STRUCTURE_TYPE_MEMORY_ALLOCATE_INFO; MemAllocInfo.allocationSize = RequiredSize; MemAllocInfo.memoryTypeIndex = FindMemoryType(m_VKGPU, RequiredMemoryTypeBits, BufferProperties); BufferMemory.m_Size = RequiredSize; m_pTextureMemoryUsage->store(m_pTextureMemoryUsage->load(std::memory_order_relaxed) + RequiredSize, std::memory_order_relaxed); if(IsVerbose()) { VerboseAllocatedMemory(RequiredSize, m_CurImageIndex, MEMORY_BLOCK_USAGE_TEXTURE); } if(!AllocateVulkanMemory(&MemAllocInfo, &BufferMemory.m_Mem)) { SetError("Allocation for image memory failed."); return false; } BufferMemory.m_UsageType = MEMORY_BLOCK_USAGE_TEXTURE; return true; } template SMemoryImageBlock GetImageMemoryBlockImpl(SMemoryBlockCache &MemoryCache, VkMemoryPropertyFlags BufferProperties, VkDeviceSize RequiredSize, VkDeviceSize RequiredAlignment, uint32_t RequiredMemoryTypeBits) { SMemoryImageBlock RetBlock; auto &&CreateCacheBlock = [&]() { bool FoundAllocation = false; SMemoryHeap::SMemoryHeapQueueElement AllocatedMem; SDeviceMemoryBlock TmpBufferMemory; typename SMemoryBlockCache::SMemoryCacheType::SMemoryCacheHeap *pCacheHeap = nullptr; for(size_t i = 0; i < MemoryCache.m_MemoryCaches.m_MemoryHeaps.size(); ++i) { auto *pHeap = MemoryCache.m_MemoryCaches.m_MemoryHeaps[i]; if(pHeap->m_Heap.Allocate(RequiredSize, RequiredAlignment, AllocatedMem)) { TmpBufferMemory = pHeap->m_BufferMem; FoundAllocation = true; pCacheHeap = pHeap; break; } } if(!FoundAllocation) { typename SMemoryBlockCache::SMemoryCacheType::SMemoryCacheHeap *pNewHeap = new typename SMemoryBlockCache::SMemoryCacheType::SMemoryCacheHeap(); GetImageMemoryImpl(MemoryBlockSize * BlockCount, RequiredMemoryTypeBits, TmpBufferMemory, BufferProperties); pNewHeap->m_Buffer = VK_NULL_HANDLE; pNewHeap->m_BufferMem = TmpBufferMemory; pNewHeap->m_pMappedBuffer = nullptr; auto &Heaps = MemoryCache.m_MemoryCaches.m_MemoryHeaps; pCacheHeap = pNewHeap; Heaps.emplace_back(pNewHeap); Heaps.back()->m_Heap.Init(MemoryBlockSize * BlockCount, 0); if(!Heaps.back()->m_Heap.Allocate(RequiredSize, RequiredAlignment, AllocatedMem)) { dbg_assert(false, "Heap allocation failed directly after creating fresh heap for image"); } } RetBlock.m_Buffer = VK_NULL_HANDLE; RetBlock.m_BufferMem = TmpBufferMemory; RetBlock.m_pMappedBuffer = nullptr; RetBlock.m_IsCached = true; RetBlock.m_pHeap = &pCacheHeap->m_Heap; RetBlock.m_HeapData = AllocatedMem; RetBlock.m_UsedSize = RequiredSize; }; if(RequiredSize < (VkDeviceSize)MemoryBlockSize) { CreateCacheBlock(); } else { SDeviceMemoryBlock TmpBufferMemory; GetImageMemoryImpl(RequiredSize, RequiredMemoryTypeBits, TmpBufferMemory, BufferProperties); RetBlock.m_Buffer = VK_NULL_HANDLE; RetBlock.m_BufferMem = TmpBufferMemory; RetBlock.m_pMappedBuffer = nullptr; RetBlock.m_IsCached = false; RetBlock.m_pHeap = nullptr; RetBlock.m_HeapData.m_OffsetToAlign = 0; RetBlock.m_HeapData.m_AllocationSize = RequiredSize; RetBlock.m_UsedSize = RequiredSize; } RetBlock.m_ImageMemoryBits = RequiredMemoryTypeBits; return RetBlock; } SMemoryImageBlock GetImageMemory(VkDeviceSize RequiredSize, VkDeviceSize RequiredAlignment, uint32_t RequiredMemoryTypeBits) { auto it = m_ImageBufferCaches.find(RequiredMemoryTypeBits); if(it == m_ImageBufferCaches.end()) { it = m_ImageBufferCaches.insert({RequiredMemoryTypeBits, {}}).first; it->second.Init(m_SwapChainImageCount); } return GetImageMemoryBlockImpl(it->second, VK_MEMORY_PROPERTY_DEVICE_LOCAL_BIT, RequiredSize, RequiredAlignment, RequiredMemoryTypeBits); } void FreeImageMemBlock(SMemoryImageBlock &Block) { if(!Block.m_IsCached) { m_FrameDelayedBufferCleanup[m_CurImageIndex].push_back({Block.m_Buffer, Block.m_BufferMem, nullptr}); } else { m_ImageBufferCaches[Block.m_ImageMemoryBits].FreeMemBlock(Block, m_CurImageIndex); } } template void UploadStreamedBuffer(SStreamMemory &StreamedBuffer) { size_t RangeUpdateCount = 0; if(StreamedBuffer.IsUsed(m_CurImageIndex)) { for(size_t i = 0; i < StreamedBuffer.GetUsedCount(m_CurImageIndex); ++i) { auto &BufferOfFrame = StreamedBuffer.GetBuffers(m_CurImageIndex)[i]; auto &MemRange = StreamedBuffer.GetRanges(m_CurImageIndex)[RangeUpdateCount++]; MemRange.sType = VK_STRUCTURE_TYPE_MAPPED_MEMORY_RANGE; MemRange.memory = BufferOfFrame.m_BufferMem.m_Mem; MemRange.offset = BufferOfFrame.m_OffsetInBuffer; auto AlignmentMod = ((VkDeviceSize)BufferOfFrame.m_UsedSize % m_NonCoherentMemAlignment); auto AlignmentReq = (m_NonCoherentMemAlignment - AlignmentMod); if(AlignmentMod == 0) AlignmentReq = 0; MemRange.size = BufferOfFrame.m_UsedSize + AlignmentReq; if(MemRange.offset + MemRange.size > BufferOfFrame.m_BufferMem.m_Size) MemRange.size = VK_WHOLE_SIZE; BufferOfFrame.m_UsedSize = 0; } if(RangeUpdateCount > 0 && FlushForRendering) { vkFlushMappedMemoryRanges(m_VKDevice, RangeUpdateCount, StreamedBuffer.GetRanges(m_CurImageIndex).data()); } } StreamedBuffer.ResetFrame(m_CurImageIndex); } void CleanBufferPair(size_t ImageIndex, VkBuffer &Buffer, SDeviceMemoryBlock &BufferMem) { bool IsBuffer = Buffer != VK_NULL_HANDLE; if(IsBuffer) { vkDestroyBuffer(m_VKDevice, Buffer, nullptr); Buffer = VK_NULL_HANDLE; } if(BufferMem.m_Mem != VK_NULL_HANDLE) { vkFreeMemory(m_VKDevice, BufferMem.m_Mem, nullptr); if(BufferMem.m_UsageType == MEMORY_BLOCK_USAGE_BUFFER) m_pBufferMemoryUsage->store(m_pBufferMemoryUsage->load(std::memory_order_relaxed) - BufferMem.m_Size, std::memory_order_relaxed); else if(BufferMem.m_UsageType == MEMORY_BLOCK_USAGE_TEXTURE) m_pTextureMemoryUsage->store(m_pTextureMemoryUsage->load(std::memory_order_relaxed) - BufferMem.m_Size, std::memory_order_relaxed); else if(BufferMem.m_UsageType == MEMORY_BLOCK_USAGE_STREAM) m_pStreamMemoryUsage->store(m_pStreamMemoryUsage->load(std::memory_order_relaxed) - BufferMem.m_Size, std::memory_order_relaxed); else if(BufferMem.m_UsageType == MEMORY_BLOCK_USAGE_STAGING) m_pStagingMemoryUsage->store(m_pStagingMemoryUsage->load(std::memory_order_relaxed) - BufferMem.m_Size, std::memory_order_relaxed); if(IsVerbose()) { VerboseDeallocatedMemory(BufferMem.m_Size, (size_t)ImageIndex, BufferMem.m_UsageType); } BufferMem.m_Mem = VK_NULL_HANDLE; } } void DestroyTexture(CTexture &Texture) { if(Texture.m_Img != VK_NULL_HANDLE) { FreeImageMemBlock(Texture.m_ImgMem); vkDestroyImage(m_VKDevice, Texture.m_Img, nullptr); vkDestroyImageView(m_VKDevice, Texture.m_ImgView, nullptr); } if(Texture.m_Img3D != VK_NULL_HANDLE) { FreeImageMemBlock(Texture.m_Img3DMem); vkDestroyImage(m_VKDevice, Texture.m_Img3D, nullptr); vkDestroyImageView(m_VKDevice, Texture.m_Img3DView, nullptr); } DestroyTexturedStandardDescriptorSets(Texture, 0); DestroyTexturedStandardDescriptorSets(Texture, 1); DestroyTextured3DStandardDescriptorSets(Texture); } void DestroyTextTexture(CTexture &Texture, CTexture &TextureOutline) { if(Texture.m_Img != VK_NULL_HANDLE) { FreeImageMemBlock(Texture.m_ImgMem); vkDestroyImage(m_VKDevice, Texture.m_Img, nullptr); vkDestroyImageView(m_VKDevice, Texture.m_ImgView, nullptr); } if(TextureOutline.m_Img != VK_NULL_HANDLE) { FreeImageMemBlock(TextureOutline.m_ImgMem); vkDestroyImage(m_VKDevice, TextureOutline.m_Img, nullptr); vkDestroyImageView(m_VKDevice, TextureOutline.m_ImgView, nullptr); } DestroyTextDescriptorSets(Texture, TextureOutline); } void ClearFrameData(size_t FrameImageIndex) { UploadStagingBuffers(); // clear pending buffers, that require deletion for(auto &BufferPair : m_FrameDelayedBufferCleanup[FrameImageIndex]) { if(BufferPair.m_pMappedData != nullptr) { vkUnmapMemory(m_VKDevice, BufferPair.m_Mem.m_Mem); } CleanBufferPair(FrameImageIndex, BufferPair.m_Buffer, BufferPair.m_Mem); } m_FrameDelayedBufferCleanup[FrameImageIndex].clear(); // clear pending textures, that require deletion for(auto &Texture : m_FrameDelayedTextureCleanup[FrameImageIndex]) { DestroyTexture(Texture); } m_FrameDelayedTextureCleanup[FrameImageIndex].clear(); for(auto &TexturePair : m_FrameDelayedTextTexturesCleanup[FrameImageIndex]) { DestroyTextTexture(TexturePair.first, TexturePair.second); } m_FrameDelayedTextTexturesCleanup[FrameImageIndex].clear(); m_StagingBufferCache.Cleanup(FrameImageIndex); m_StagingBufferCacheImage.Cleanup(FrameImageIndex); m_VertexBufferCache.Cleanup(FrameImageIndex); for(auto &ImageBufferCache : m_ImageBufferCaches) ImageBufferCache.second.Cleanup(FrameImageIndex); } void ShrinkUnusedCaches() { size_t FreeedMemory = 0; FreeedMemory += m_StagingBufferCache.Shrink(m_VKDevice); FreeedMemory += m_StagingBufferCacheImage.Shrink(m_VKDevice); if(FreeedMemory > 0) { m_pStagingMemoryUsage->store(m_pStagingMemoryUsage->load(std::memory_order_relaxed) - FreeedMemory, std::memory_order_relaxed); if(IsVerbose()) { dbg_msg("vulkan", "deallocated chunks of memory with size: %" PRIu64 " from all frames (staging buffer)", (size_t)FreeedMemory); } } FreeedMemory = 0; FreeedMemory += m_VertexBufferCache.Shrink(m_VKDevice); if(FreeedMemory > 0) { m_pBufferMemoryUsage->store(m_pBufferMemoryUsage->load(std::memory_order_relaxed) - FreeedMemory, std::memory_order_relaxed); if(IsVerbose()) { dbg_msg("vulkan", "deallocated chunks of memory with size: %" PRIu64 " from all frames (buffer)", (size_t)FreeedMemory); } } FreeedMemory = 0; for(auto &ImageBufferCache : m_ImageBufferCaches) FreeedMemory += ImageBufferCache.second.Shrink(m_VKDevice); if(FreeedMemory > 0) { m_pTextureMemoryUsage->store(m_pTextureMemoryUsage->load(std::memory_order_relaxed) - FreeedMemory, std::memory_order_relaxed); if(IsVerbose()) { dbg_msg("vulkan", "deallocated chunks of memory with size: %" PRIu64 " from all frames (texture)", (size_t)FreeedMemory); } } } void MemoryBarrier(VkBuffer Buffer, VkDeviceSize Offset, VkDeviceSize Size, VkAccessFlags BufferAccessType, bool BeforeCommand) { VkCommandBuffer MemCommandBuffer = GetMemoryCommandBuffer(); VkBufferMemoryBarrier Barrier{}; Barrier.sType = VK_STRUCTURE_TYPE_BUFFER_MEMORY_BARRIER; Barrier.srcQueueFamilyIndex = VK_QUEUE_FAMILY_IGNORED; Barrier.dstQueueFamilyIndex = VK_QUEUE_FAMILY_IGNORED; Barrier.buffer = Buffer; Barrier.offset = Offset; Barrier.size = Size; VkPipelineStageFlags SourceStage = VK_PIPELINE_STAGE_TOP_OF_PIPE_BIT; VkPipelineStageFlags DestinationStage = VK_PIPELINE_STAGE_TRANSFER_BIT; if(BeforeCommand) { Barrier.srcAccessMask = BufferAccessType; Barrier.dstAccessMask = VK_ACCESS_TRANSFER_WRITE_BIT; SourceStage = VK_PIPELINE_STAGE_VERTEX_INPUT_BIT; DestinationStage = VK_PIPELINE_STAGE_TRANSFER_BIT; } else { Barrier.srcAccessMask = VK_ACCESS_TRANSFER_WRITE_BIT; Barrier.dstAccessMask = BufferAccessType; SourceStage = VK_PIPELINE_STAGE_TRANSFER_BIT; DestinationStage = VK_PIPELINE_STAGE_VERTEX_INPUT_BIT; } vkCmdPipelineBarrier( MemCommandBuffer, SourceStage, DestinationStage, 0, 0, nullptr, 1, &Barrier, 0, nullptr); } /************************ * SWAPPING MECHANISM ************************/ void StartRenderThread(size_t ThreadIndex) { auto &List = m_ThreadCommandLists[ThreadIndex]; if(!List.empty()) { m_ThreadHelperHadCommands[ThreadIndex] = true; auto *pThread = m_RenderThreads[ThreadIndex].get(); std::unique_lock Lock(pThread->m_Mutex); pThread->m_IsRendering = true; pThread->m_Cond.notify_one(); } } void FinishRenderThreads() { if(m_ThreadCount > 1) { // execute threads for(size_t ThreadIndex = 0; ThreadIndex < m_ThreadCount - 1; ++ThreadIndex) { if(!m_ThreadHelperHadCommands[ThreadIndex]) { StartRenderThread(ThreadIndex); } } for(size_t ThreadIndex = 0; ThreadIndex < m_ThreadCount - 1; ++ThreadIndex) { if(m_ThreadHelperHadCommands[ThreadIndex]) { auto &pRenderThread = m_RenderThreads[ThreadIndex]; m_ThreadHelperHadCommands[ThreadIndex] = false; std::unique_lock Lock(pRenderThread->m_Mutex); pRenderThread->m_Cond.wait(Lock, [&pRenderThread] { return !pRenderThread->m_IsRendering; }); m_vLastPipeline[ThreadIndex + 1] = VK_NULL_HANDLE; } } } } void ExecuteMemoryCommandBuffer() { if(m_UsedMemoryCommandBuffer[m_CurImageIndex]) { auto &MemoryCommandBuffer = m_MemoryCommandBuffers[m_CurImageIndex]; vkEndCommandBuffer(MemoryCommandBuffer); VkSubmitInfo SubmitInfo{}; SubmitInfo.sType = VK_STRUCTURE_TYPE_SUBMIT_INFO; SubmitInfo.commandBufferCount = 1; SubmitInfo.pCommandBuffers = &MemoryCommandBuffer; vkQueueSubmit(m_VKGraphicsQueue, 1, &SubmitInfo, VK_NULL_HANDLE); vkQueueWaitIdle(m_VKGraphicsQueue); m_UsedMemoryCommandBuffer[m_CurImageIndex] = false; } } void ClearFrameMemoryUsage() { ClearFrameData(m_CurImageIndex); ShrinkUnusedCaches(); } void WaitFrame() { FinishRenderThreads(); m_LastCommandsInPipeThreadIndex = 0; UploadNonFlushedBuffers(); auto &CommandBuffer = GetMainGraphicCommandBuffer(); // render threads if(m_ThreadCount > 1) { size_t ThreadedCommandsUsedCount = 0; size_t RenderThreadCount = m_ThreadCount - 1; for(size_t i = 0; i < RenderThreadCount; ++i) { if(m_UsedThreadDrawCommandBuffer[i + 1][m_CurImageIndex]) { auto &GraphicThreadCommandBuffer = m_ThreadDrawCommandBuffers[i + 1][m_CurImageIndex]; m_HelperThreadDrawCommandBuffers[ThreadedCommandsUsedCount++] = GraphicThreadCommandBuffer; m_UsedThreadDrawCommandBuffer[i + 1][m_CurImageIndex] = false; } } if(ThreadedCommandsUsedCount > 0) { vkCmdExecuteCommands(CommandBuffer, ThreadedCommandsUsedCount, m_HelperThreadDrawCommandBuffers.data()); } // special case if swap chain was not completed in one runbuffer call if(m_UsedThreadDrawCommandBuffer[0][m_CurImageIndex]) { auto &GraphicThreadCommandBuffer = m_ThreadDrawCommandBuffers[0][m_CurImageIndex]; vkEndCommandBuffer(GraphicThreadCommandBuffer); vkCmdExecuteCommands(CommandBuffer, 1, &GraphicThreadCommandBuffer); m_UsedThreadDrawCommandBuffer[0][m_CurImageIndex] = false; } } vkCmdEndRenderPass(CommandBuffer); if(vkEndCommandBuffer(CommandBuffer) != VK_SUCCESS) { SetError("Command buffer cannot be ended anymore."); } VkSemaphore WaitSemaphore = m_WaitSemaphores[m_CurFrames]; VkSubmitInfo SubmitInfo{}; SubmitInfo.sType = VK_STRUCTURE_TYPE_SUBMIT_INFO; SubmitInfo.commandBufferCount = 1; SubmitInfo.pCommandBuffers = &CommandBuffer; std::array aCommandBuffers = {}; if(m_UsedMemoryCommandBuffer[m_CurImageIndex]) { auto &MemoryCommandBuffer = m_MemoryCommandBuffers[m_CurImageIndex]; vkEndCommandBuffer(MemoryCommandBuffer); aCommandBuffers[0] = MemoryCommandBuffer; aCommandBuffers[1] = CommandBuffer; SubmitInfo.commandBufferCount = 2; SubmitInfo.pCommandBuffers = aCommandBuffers.data(); m_UsedMemoryCommandBuffer[m_CurImageIndex] = false; } std::array aWaitSemaphores = {WaitSemaphore}; std::array aWaitStages = {(VkPipelineStageFlags)VK_PIPELINE_STAGE_COLOR_ATTACHMENT_OUTPUT_BIT}; SubmitInfo.waitSemaphoreCount = aWaitSemaphores.size(); SubmitInfo.pWaitSemaphores = aWaitSemaphores.data(); SubmitInfo.pWaitDstStageMask = aWaitStages.data(); std::array aSignalSemaphores = {m_SigSemaphores[m_CurFrames]}; SubmitInfo.signalSemaphoreCount = aSignalSemaphores.size(); SubmitInfo.pSignalSemaphores = aSignalSemaphores.data(); vkResetFences(m_VKDevice, 1, &m_FrameFences[m_CurFrames]); VkResult QueueSubmitRes = vkQueueSubmit(m_VKGraphicsQueue, 1, &SubmitInfo, m_FrameFences[m_CurFrames]); if(QueueSubmitRes != VK_SUCCESS) { const char *pCritErrorMsg = CheckVulkanCriticalError(QueueSubmitRes); if(pCritErrorMsg != nullptr) SetError("Submitting to graphics queue failed.", pCritErrorMsg); } std::swap(m_WaitSemaphores[m_CurFrames], m_SigSemaphores[m_CurFrames]); VkPresentInfoKHR PresentInfo{}; PresentInfo.sType = VK_STRUCTURE_TYPE_PRESENT_INFO_KHR; PresentInfo.waitSemaphoreCount = aSignalSemaphores.size(); PresentInfo.pWaitSemaphores = aSignalSemaphores.data(); std::array aSwapChains = {m_VKSwapChain}; PresentInfo.swapchainCount = aSwapChains.size(); PresentInfo.pSwapchains = aSwapChains.data(); PresentInfo.pImageIndices = &m_CurImageIndex; m_LastPresentedSwapChainImageIndex = m_CurImageIndex; VkResult QueuePresentRes = vkQueuePresentKHR(m_VKPresentQueue, &PresentInfo); if(QueuePresentRes != VK_SUCCESS && QueuePresentRes != VK_SUBOPTIMAL_KHR) { const char *pCritErrorMsg = CheckVulkanCriticalError(QueuePresentRes); if(pCritErrorMsg != nullptr) SetError("Presenting graphics queue failed.", pCritErrorMsg); } m_CurFrames = (m_CurFrames + 1) % m_SwapChainImageCount; } void PrepareFrame() { if(m_RecreateSwapChain) { m_RecreateSwapChain = false; if(IsVerbose()) { dbg_msg("vulkan", "recreating swap chain requested by user (prepare frame)."); } RecreateSwapChain(); } auto AcqResult = vkAcquireNextImageKHR(m_VKDevice, m_VKSwapChain, std::numeric_limits::max(), m_SigSemaphores[m_CurFrames], VK_NULL_HANDLE, &m_CurImageIndex); if(AcqResult != VK_SUCCESS) { if(AcqResult == VK_ERROR_OUT_OF_DATE_KHR || m_RecreateSwapChain) { m_RecreateSwapChain = false; if(IsVerbose()) { dbg_msg("vulkan", "recreating swap chain requested by acquire next image (prepare frame)."); } RecreateSwapChain(); PrepareFrame(); return; } else { if(AcqResult != VK_SUBOPTIMAL_KHR) dbg_msg("vulkan", "acquire next image failed %d", (int)AcqResult); const char *pCritErrorMsg = CheckVulkanCriticalError(AcqResult); if(pCritErrorMsg != nullptr) SetError("Acquiring next image failed.", pCritErrorMsg); else if(AcqResult == VK_ERROR_SURFACE_LOST_KHR) { m_RenderingPaused = true; return; } } } std::swap(m_WaitSemaphores[m_CurFrames], m_SigSemaphores[m_CurFrames]); if(m_ImagesFences[m_CurImageIndex] != VK_NULL_HANDLE) { vkWaitForFences(m_VKDevice, 1, &m_ImagesFences[m_CurImageIndex], VK_TRUE, std::numeric_limits::max()); } m_ImagesFences[m_CurImageIndex] = m_FrameFences[m_CurFrames]; // next frame m_CurFrame++; m_ImageLastFrameCheck[m_CurImageIndex] = m_CurFrame; // check if older frames weren't used in a long time for(size_t FrameImageIndex = 0; FrameImageIndex < m_ImageLastFrameCheck.size(); ++FrameImageIndex) { auto LastFrame = m_ImageLastFrameCheck[FrameImageIndex]; if(m_CurFrame - LastFrame > (uint64_t)m_SwapChainImageCount) { if(m_ImagesFences[FrameImageIndex] != VK_NULL_HANDLE) { vkWaitForFences(m_VKDevice, 1, &m_ImagesFences[FrameImageIndex], VK_TRUE, std::numeric_limits::max()); ClearFrameData(FrameImageIndex); m_ImagesFences[FrameImageIndex] = VK_NULL_HANDLE; } m_ImageLastFrameCheck[FrameImageIndex] = m_CurFrame; } } // clear frame's memory data ClearFrameMemoryUsage(); // clear frame vkResetCommandBuffer(GetMainGraphicCommandBuffer(), VK_COMMAND_BUFFER_RESET_RELEASE_RESOURCES_BIT); auto &CommandBuffer = GetMainGraphicCommandBuffer(); VkCommandBufferBeginInfo BeginInfo{}; BeginInfo.sType = VK_STRUCTURE_TYPE_COMMAND_BUFFER_BEGIN_INFO; BeginInfo.flags = VK_COMMAND_BUFFER_USAGE_ONE_TIME_SUBMIT_BIT; if(vkBeginCommandBuffer(CommandBuffer, &BeginInfo) != VK_SUCCESS) { SetError("Command buffer cannot be filled anymore."); } VkRenderPassBeginInfo RenderPassInfo{}; RenderPassInfo.sType = VK_STRUCTURE_TYPE_RENDER_PASS_BEGIN_INFO; RenderPassInfo.renderPass = m_VKRenderPass; RenderPassInfo.framebuffer = m_FramebufferList[m_CurImageIndex]; RenderPassInfo.renderArea.offset = {0, 0}; RenderPassInfo.renderArea.extent = m_VKSwapImgAndViewportExtent.m_Viewport; VkClearValue ClearColorVal = {{{m_aClearColor[0], m_aClearColor[1], m_aClearColor[2], m_aClearColor[3]}}}; RenderPassInfo.clearValueCount = 1; RenderPassInfo.pClearValues = &ClearColorVal; vkCmdBeginRenderPass(CommandBuffer, &RenderPassInfo, m_ThreadCount > 1 ? VK_SUBPASS_CONTENTS_SECONDARY_COMMAND_BUFFERS : VK_SUBPASS_CONTENTS_INLINE); for(auto &LastPipe : m_vLastPipeline) LastPipe = VK_NULL_HANDLE; } void UploadStagingBuffers() { if(!m_NonFlushedStagingBufferRange.empty()) { vkFlushMappedMemoryRanges(m_VKDevice, m_NonFlushedStagingBufferRange.size(), m_NonFlushedStagingBufferRange.data()); m_NonFlushedStagingBufferRange.clear(); } } template void UploadNonFlushedBuffers() { // streamed vertices for(auto &StreamVertexBuffer : m_vStreamedVertexBuffers) UploadStreamedBuffer(StreamVertexBuffer); // now the buffer objects for(auto &StreamUniformBuffer : m_vStreamedUniformBuffers) UploadStreamedBuffer(StreamUniformBuffer); UploadStagingBuffers(); } void PureMemoryFrame() { ExecuteMemoryCommandBuffer(); // reset streamed data UploadNonFlushedBuffers(); ClearFrameMemoryUsage(); } void NextFrame() { if(!m_RenderingPaused) { WaitFrame(); PrepareFrame(); } // else only execute the memory command buffer else { PureMemoryFrame(); } } /************************ * TEXTURES ************************/ size_t VulkanFormatToImageColorChannelCount(VkFormat Format) { if(Format == VK_FORMAT_R8G8B8_UNORM) return 3; else if(Format == VK_FORMAT_R8G8B8A8_UNORM) return 4; else if(Format == VK_FORMAT_R8_UNORM) return 1; return 4; } void UpdateTexture(size_t TextureSlot, VkFormat Format, void *&pData, int64_t XOff, int64_t YOff, size_t Width, size_t Height, size_t ColorChannelCount) { size_t ImageSize = Width * Height * ColorChannelCount; auto StagingBuffer = GetStagingBufferImage(pData, ImageSize); auto &Tex = m_Textures[TextureSlot]; if(Tex.m_RescaleCount > 0) { for(uint32_t i = 0; i < Tex.m_RescaleCount; ++i) { Width >>= 1; Height >>= 1; XOff /= 2; YOff /= 2; } void *pTmpData = Resize((const uint8_t *)pData, Width, Height, Width, Height, VulkanFormatToImageColorChannelCount(Format)); free(pData); pData = pTmpData; } ImageBarrier(Tex.m_Img, 0, Tex.m_MipMapCount, 0, 1, Format, VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL, VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL); CopyBufferToImage(StagingBuffer.m_Buffer, StagingBuffer.m_HeapData.m_OffsetToAlign, Tex.m_Img, XOff, YOff, Width, Height, 1); if(Tex.m_MipMapCount > 1) BuildMipmaps(Tex.m_Img, Format, Width, Height, 1, Tex.m_MipMapCount); else ImageBarrier(Tex.m_Img, 0, 1, 0, 1, Format, VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL, VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL); UploadAndFreeStagingImageMemBlock(StagingBuffer); } void CreateTextureCMD( int Slot, int Width, int Height, int PixelSize, VkFormat Format, VkFormat StoreFormat, int Flags, void *&pData) { size_t ImageIndex = (size_t)Slot; int ImageColorChannels = VulkanFormatToImageColorChannelCount(Format); while(ImageIndex >= m_Textures.size()) { m_Textures.resize((m_Textures.size() * 2) + 1); } // resample if needed uint32_t RescaleCount = 0; if((size_t)Width > m_MaxTextureSize || (size_t)Height > m_MaxTextureSize) { do { Width >>= 1; Height >>= 1; ++RescaleCount; } while((size_t)Width > m_MaxTextureSize || (size_t)Height > m_MaxTextureSize); void *pTmpData = Resize((const uint8_t *)(pData), Width, Height, Width, Height, ImageColorChannels); free(pData); pData = pTmpData; } bool Requires2DTexture = (Flags & CCommandBuffer::TEXFLAG_NO_2D_TEXTURE) == 0; bool Requires2DTextureArray = (Flags & (CCommandBuffer::TEXFLAG_TO_2D_ARRAY_TEXTURE | CCommandBuffer::TEXFLAG_TO_2D_ARRAY_TEXTURE_SINGLE_LAYER)) != 0; bool Is2DTextureSingleLayer = (Flags & CCommandBuffer::TEXFLAG_TO_2D_ARRAY_TEXTURE_SINGLE_LAYER) != 0; bool RequiresMipMaps = (Flags & CCommandBuffer::TEXFLAG_NOMIPMAPS) == 0; size_t MipMapLevelCount = 1; if(RequiresMipMaps) { VkExtent3D ImgSize{(uint32_t)Width, (uint32_t)Height, 1}; MipMapLevelCount = ImageMipLevelCount(ImgSize); if(!m_OptimalRGBAImageBlitting) MipMapLevelCount = 1; } CTexture &Texture = m_Textures[ImageIndex]; Texture.m_Width = Width; Texture.m_Height = Height; Texture.m_RescaleCount = RescaleCount; Texture.m_MipMapCount = MipMapLevelCount; if(Requires2DTexture) { CreateTextureImage(ImageIndex, Texture.m_Img, Texture.m_ImgMem, pData, Format, Width, Height, 1, PixelSize, MipMapLevelCount); VkFormat ImgFormat = Format; VkImageView ImgView = CreateTextureImageView(Texture.m_Img, ImgFormat, VK_IMAGE_VIEW_TYPE_2D, 1, MipMapLevelCount); Texture.m_ImgView = ImgView; VkSampler ImgSampler = GetTextureSampler(SUPPORTED_SAMPLER_TYPE_REPEAT); Texture.m_aSamplers[0] = ImgSampler; ImgSampler = GetTextureSampler(SUPPORTED_SAMPLER_TYPE_CLAMP_TO_EDGE); Texture.m_aSamplers[1] = ImgSampler; CreateNewTexturedStandardDescriptorSets(ImageIndex, 0); CreateNewTexturedStandardDescriptorSets(ImageIndex, 1); } if(Requires2DTextureArray) { int Image3DWidth = Width; int Image3DHeight = Height; int ConvertWidth = Width; int ConvertHeight = Height; if(!Is2DTextureSingleLayer) { if(ConvertWidth == 0 || (ConvertWidth % 16) != 0 || ConvertHeight == 0 || (ConvertHeight % 16) != 0) { dbg_msg("vulkan", "3D/2D array texture was resized"); int NewWidth = maximum(HighestBit(ConvertWidth), 16); int NewHeight = maximum(HighestBit(ConvertHeight), 16); uint8_t *pNewTexData = (uint8_t *)Resize((const uint8_t *)pData, ConvertWidth, ConvertHeight, NewWidth, NewHeight, ImageColorChannels); ConvertWidth = NewWidth; ConvertHeight = NewHeight; free(pData); pData = pNewTexData; } } void *p3DTexData = pData; bool Needs3DTexDel = false; if(!Is2DTextureSingleLayer) { p3DTexData = malloc((size_t)ImageColorChannels * ConvertWidth * ConvertHeight); if(!Texture2DTo3D(pData, ConvertWidth, ConvertHeight, ImageColorChannels, 16, 16, p3DTexData, Image3DWidth, Image3DHeight)) { free(p3DTexData); p3DTexData = nullptr; } Needs3DTexDel = true; } else { Image3DWidth = ConvertWidth; Image3DHeight = ConvertHeight; } if(p3DTexData != nullptr) { const size_t ImageDepth2DArray = Is2DTextureSingleLayer ? 1 : ((size_t)16 * 16); VkExtent3D ImgSize{(uint32_t)Image3DWidth, (uint32_t)Image3DHeight, 1}; if(RequiresMipMaps) { MipMapLevelCount = ImageMipLevelCount(ImgSize); if(!m_OptimalRGBAImageBlitting) MipMapLevelCount = 1; } CreateTextureImage(ImageIndex, Texture.m_Img3D, Texture.m_Img3DMem, p3DTexData, Format, Image3DWidth, Image3DHeight, ImageDepth2DArray, PixelSize, MipMapLevelCount); VkFormat ImgFormat = Format; VkImageView ImgView = CreateTextureImageView(Texture.m_Img3D, ImgFormat, VK_IMAGE_VIEW_TYPE_2D_ARRAY, ImageDepth2DArray, MipMapLevelCount); Texture.m_Img3DView = ImgView; VkSampler ImgSampler = GetTextureSampler(SUPPORTED_SAMPLER_TYPE_2D_TEXTURE_ARRAY); Texture.m_Sampler3D = ImgSampler; CreateNew3DTexturedStandardDescriptorSets(ImageIndex); if(Needs3DTexDel) free(p3DTexData); } } } VkFormat TextureFormatToVulkanFormat(int TexFormat) { if(TexFormat == CCommandBuffer::TEXFORMAT_RGBA) return VK_FORMAT_R8G8B8A8_UNORM; return VK_FORMAT_R8G8B8A8_UNORM; } void BuildMipmaps(VkImage Image, VkFormat ImageFormat, size_t Width, size_t Height, size_t Depth, size_t MipMapLevelCount) { VkCommandBuffer MemCommandBuffer = GetMemoryCommandBuffer(); VkImageMemoryBarrier Barrier{}; Barrier.sType = VK_STRUCTURE_TYPE_IMAGE_MEMORY_BARRIER; Barrier.image = Image; Barrier.srcQueueFamilyIndex = VK_QUEUE_FAMILY_IGNORED; Barrier.dstQueueFamilyIndex = VK_QUEUE_FAMILY_IGNORED; Barrier.subresourceRange.aspectMask = VK_IMAGE_ASPECT_COLOR_BIT; Barrier.subresourceRange.levelCount = 1; Barrier.subresourceRange.baseArrayLayer = 0; Barrier.subresourceRange.layerCount = Depth; int32_t TmpMipWidth = (int32_t)Width; int32_t TmpMipHeight = (int32_t)Height; for(size_t i = 1; i < MipMapLevelCount; ++i) { Barrier.subresourceRange.baseMipLevel = i - 1; Barrier.oldLayout = VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL; Barrier.newLayout = VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL; Barrier.srcAccessMask = VK_ACCESS_TRANSFER_WRITE_BIT; Barrier.dstAccessMask = VK_ACCESS_TRANSFER_READ_BIT; vkCmdPipelineBarrier(MemCommandBuffer, VK_PIPELINE_STAGE_TRANSFER_BIT, VK_PIPELINE_STAGE_TRANSFER_BIT, 0, 0, nullptr, 0, nullptr, 1, &Barrier); VkImageBlit Blit{}; Blit.srcOffsets[0] = {0, 0, 0}; Blit.srcOffsets[1] = {TmpMipWidth, TmpMipHeight, 1}; Blit.srcSubresource.aspectMask = VK_IMAGE_ASPECT_COLOR_BIT; Blit.srcSubresource.mipLevel = i - 1; Blit.srcSubresource.baseArrayLayer = 0; Blit.srcSubresource.layerCount = Depth; Blit.dstOffsets[0] = {0, 0, 0}; Blit.dstOffsets[1] = {TmpMipWidth > 1 ? TmpMipWidth / 2 : 1, TmpMipHeight > 1 ? TmpMipHeight / 2 : 1, 1}; Blit.dstSubresource.aspectMask = VK_IMAGE_ASPECT_COLOR_BIT; Blit.dstSubresource.mipLevel = i; Blit.dstSubresource.baseArrayLayer = 0; Blit.dstSubresource.layerCount = Depth; vkCmdBlitImage(MemCommandBuffer, Image, VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL, Image, VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL, 1, &Blit, m_AllowsLinearBlitting ? VK_FILTER_LINEAR : VK_FILTER_NEAREST); Barrier.oldLayout = VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL; Barrier.newLayout = VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL; Barrier.srcAccessMask = VK_ACCESS_TRANSFER_READ_BIT; Barrier.dstAccessMask = VK_ACCESS_SHADER_READ_BIT; vkCmdPipelineBarrier(MemCommandBuffer, VK_PIPELINE_STAGE_TRANSFER_BIT, VK_PIPELINE_STAGE_FRAGMENT_SHADER_BIT, 0, 0, nullptr, 0, nullptr, 1, &Barrier); if(TmpMipWidth > 1) TmpMipWidth /= 2; if(TmpMipHeight > 1) TmpMipHeight /= 2; } Barrier.subresourceRange.baseMipLevel = MipMapLevelCount - 1; Barrier.oldLayout = VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL; Barrier.newLayout = VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL; Barrier.srcAccessMask = VK_ACCESS_TRANSFER_WRITE_BIT; Barrier.dstAccessMask = VK_ACCESS_SHADER_READ_BIT; vkCmdPipelineBarrier(MemCommandBuffer, VK_PIPELINE_STAGE_TRANSFER_BIT, VK_PIPELINE_STAGE_FRAGMENT_SHADER_BIT, 0, 0, nullptr, 0, nullptr, 1, &Barrier); } bool CreateTextureImage(size_t ImageIndex, VkImage &NewImage, SMemoryImageBlock &NewImgMem, const void *pData, VkFormat Format, size_t Width, size_t Height, size_t Depth, size_t PixelSize, size_t MipMapLevelCount) { int ImageSize = Width * Height * Depth * PixelSize; auto StagingBuffer = GetStagingBufferImage(pData, ImageSize); VkFormat ImgFormat = Format; CreateImage(Width, Height, Depth, MipMapLevelCount, ImgFormat, VK_IMAGE_TILING_OPTIMAL, NewImage, NewImgMem); ImageBarrier(NewImage, 0, MipMapLevelCount, 0, Depth, ImgFormat, VK_IMAGE_LAYOUT_UNDEFINED, VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL); CopyBufferToImage(StagingBuffer.m_Buffer, StagingBuffer.m_HeapData.m_OffsetToAlign, NewImage, 0, 0, static_cast(Width), static_cast(Height), Depth); //ImageBarrier(NewImage, 0, 1, 0, Depth, ImgFormat, VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL, VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL); UploadAndFreeStagingImageMemBlock(StagingBuffer); if(MipMapLevelCount > 1) BuildMipmaps(NewImage, ImgFormat, Width, Height, Depth, MipMapLevelCount); else ImageBarrier(NewImage, 0, 1, 0, Depth, ImgFormat, VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL, VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL); return true; } VkImageView CreateTextureImageView(VkImage TexImage, VkFormat ImgFormat, VkImageViewType ViewType, size_t Depth, size_t MipMapLevelCount) { return CreateImageView(TexImage, ImgFormat, ViewType, Depth, MipMapLevelCount); } bool CreateTextureSamplersImpl(VkSampler &CreatedSampler, VkSamplerAddressMode AddrModeU, VkSamplerAddressMode AddrModeV, VkSamplerAddressMode AddrModeW) { VkSamplerCreateInfo SamplerInfo{}; SamplerInfo.sType = VK_STRUCTURE_TYPE_SAMPLER_CREATE_INFO; SamplerInfo.magFilter = VK_FILTER_LINEAR; SamplerInfo.minFilter = VK_FILTER_LINEAR; SamplerInfo.addressModeU = AddrModeU; SamplerInfo.addressModeV = AddrModeV; SamplerInfo.addressModeW = AddrModeW; SamplerInfo.anisotropyEnable = VK_FALSE; SamplerInfo.maxAnisotropy = m_MaxSamplerAnisotropy; SamplerInfo.borderColor = VK_BORDER_COLOR_INT_OPAQUE_BLACK; SamplerInfo.unnormalizedCoordinates = VK_FALSE; SamplerInfo.compareEnable = VK_FALSE; SamplerInfo.compareOp = VK_COMPARE_OP_ALWAYS; SamplerInfo.mipmapMode = VK_SAMPLER_MIPMAP_MODE_LINEAR; SamplerInfo.mipLodBias = (m_GlobalTextureLodBIAS / 1000.0f); SamplerInfo.minLod = -1000; SamplerInfo.maxLod = 1000; if(vkCreateSampler(m_VKDevice, &SamplerInfo, nullptr, &CreatedSampler) != VK_SUCCESS) { dbg_msg("vulkan", "failed to create texture sampler!"); return false; } return true; } bool CreateTextureSamplers() { bool Ret = true; Ret &= CreateTextureSamplersImpl(m_aSamplers[SUPPORTED_SAMPLER_TYPE_REPEAT], VkSamplerAddressMode::VK_SAMPLER_ADDRESS_MODE_REPEAT, VkSamplerAddressMode::VK_SAMPLER_ADDRESS_MODE_REPEAT, VkSamplerAddressMode::VK_SAMPLER_ADDRESS_MODE_REPEAT); Ret &= CreateTextureSamplersImpl(m_aSamplers[SUPPORTED_SAMPLER_TYPE_CLAMP_TO_EDGE], VkSamplerAddressMode::VK_SAMPLER_ADDRESS_MODE_CLAMP_TO_EDGE, VkSamplerAddressMode::VK_SAMPLER_ADDRESS_MODE_CLAMP_TO_EDGE, VkSamplerAddressMode::VK_SAMPLER_ADDRESS_MODE_CLAMP_TO_EDGE); Ret &= CreateTextureSamplersImpl(m_aSamplers[SUPPORTED_SAMPLER_TYPE_2D_TEXTURE_ARRAY], VkSamplerAddressMode::VK_SAMPLER_ADDRESS_MODE_CLAMP_TO_EDGE, VkSamplerAddressMode::VK_SAMPLER_ADDRESS_MODE_CLAMP_TO_EDGE, VkSamplerAddressMode::VK_SAMPLER_ADDRESS_MODE_MIRRORED_REPEAT); return Ret; } void DestroyTextureSamplers() { vkDestroySampler(m_VKDevice, m_aSamplers[SUPPORTED_SAMPLER_TYPE_REPEAT], nullptr); vkDestroySampler(m_VKDevice, m_aSamplers[SUPPORTED_SAMPLER_TYPE_CLAMP_TO_EDGE], nullptr); vkDestroySampler(m_VKDevice, m_aSamplers[SUPPORTED_SAMPLER_TYPE_2D_TEXTURE_ARRAY], nullptr); } VkSampler GetTextureSampler(ESupportedSamplerTypes SamplerType) { return m_aSamplers[SamplerType]; } VkImageView CreateImageView(VkImage Image, VkFormat Format, VkImageViewType ViewType, size_t Depth, size_t MipMapLevelCount) { VkImageViewCreateInfo ViewCreateInfo{}; ViewCreateInfo.sType = VK_STRUCTURE_TYPE_IMAGE_VIEW_CREATE_INFO; ViewCreateInfo.image = Image; ViewCreateInfo.viewType = ViewType; ViewCreateInfo.format = Format; ViewCreateInfo.subresourceRange.aspectMask = VK_IMAGE_ASPECT_COLOR_BIT; ViewCreateInfo.subresourceRange.baseMipLevel = 0; ViewCreateInfo.subresourceRange.levelCount = MipMapLevelCount; ViewCreateInfo.subresourceRange.baseArrayLayer = 0; ViewCreateInfo.subresourceRange.layerCount = Depth; VkImageView ImageView; if(vkCreateImageView(m_VKDevice, &ViewCreateInfo, nullptr, &ImageView) != VK_SUCCESS) { return VK_NULL_HANDLE; } return ImageView; } void CreateImage(uint32_t Width, uint32_t Height, uint32_t Depth, size_t MipMapLevelCount, VkFormat Format, VkImageTiling Tiling, VkImage &Image, SMemoryImageBlock &ImageMemory, VkImageUsageFlags ImageUsage = VK_IMAGE_USAGE_TRANSFER_SRC_BIT | VK_IMAGE_USAGE_TRANSFER_DST_BIT | VK_IMAGE_USAGE_SAMPLED_BIT) { VkImageCreateInfo ImageInfo{}; ImageInfo.sType = VK_STRUCTURE_TYPE_IMAGE_CREATE_INFO; ImageInfo.imageType = VK_IMAGE_TYPE_2D; ImageInfo.extent.width = Width; ImageInfo.extent.height = Height; ImageInfo.extent.depth = 1; ImageInfo.mipLevels = MipMapLevelCount; ImageInfo.arrayLayers = Depth; ImageInfo.format = Format; ImageInfo.tiling = Tiling; ImageInfo.initialLayout = VK_IMAGE_LAYOUT_UNDEFINED; ImageInfo.usage = ImageUsage; ImageInfo.samples = (ImageUsage & VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT) == 0 ? VK_SAMPLE_COUNT_1_BIT : GetSampleCount(); ImageInfo.sharingMode = VK_SHARING_MODE_EXCLUSIVE; if(vkCreateImage(m_VKDevice, &ImageInfo, nullptr, &Image) != VK_SUCCESS) { dbg_msg("vulkan", "failed to create image!"); } VkMemoryRequirements MemRequirements; vkGetImageMemoryRequirements(m_VKDevice, Image, &MemRequirements); auto ImageMem = GetImageMemory(MemRequirements.size, MemRequirements.alignment, MemRequirements.memoryTypeBits); ImageMemory = ImageMem; vkBindImageMemory(m_VKDevice, Image, ImageMem.m_BufferMem.m_Mem, ImageMem.m_HeapData.m_OffsetToAlign); } void ImageBarrier(VkImage &Image, size_t MipMapBase, size_t MipMapCount, size_t LayerBase, size_t LayerCount, VkFormat Format, VkImageLayout OldLayout, VkImageLayout NewLayout) { VkCommandBuffer MemCommandBuffer = GetMemoryCommandBuffer(); VkImageMemoryBarrier Barrier{}; Barrier.sType = VK_STRUCTURE_TYPE_IMAGE_MEMORY_BARRIER; Barrier.oldLayout = OldLayout; Barrier.newLayout = NewLayout; Barrier.srcQueueFamilyIndex = VK_QUEUE_FAMILY_IGNORED; Barrier.dstQueueFamilyIndex = VK_QUEUE_FAMILY_IGNORED; Barrier.image = Image; Barrier.subresourceRange.aspectMask = VK_IMAGE_ASPECT_COLOR_BIT; Barrier.subresourceRange.baseMipLevel = MipMapBase; Barrier.subresourceRange.levelCount = MipMapCount; Barrier.subresourceRange.baseArrayLayer = LayerBase; Barrier.subresourceRange.layerCount = LayerCount; VkPipelineStageFlags SourceStage = VK_PIPELINE_STAGE_TOP_OF_PIPE_BIT; VkPipelineStageFlags DestinationStage = VK_PIPELINE_STAGE_TRANSFER_BIT; if(OldLayout == VK_IMAGE_LAYOUT_UNDEFINED && NewLayout == VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL) { Barrier.srcAccessMask = 0; Barrier.dstAccessMask = VK_ACCESS_TRANSFER_WRITE_BIT; SourceStage = VK_PIPELINE_STAGE_TOP_OF_PIPE_BIT; DestinationStage = VK_PIPELINE_STAGE_TRANSFER_BIT; } else if(OldLayout == VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL && NewLayout == VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL) { Barrier.srcAccessMask = VK_ACCESS_TRANSFER_WRITE_BIT; Barrier.dstAccessMask = VK_ACCESS_SHADER_READ_BIT; SourceStage = VK_PIPELINE_STAGE_TRANSFER_BIT; DestinationStage = VK_PIPELINE_STAGE_FRAGMENT_SHADER_BIT; } else if(OldLayout == VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL && NewLayout == VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL) { Barrier.srcAccessMask = VK_ACCESS_SHADER_READ_BIT; Barrier.dstAccessMask = VK_ACCESS_TRANSFER_WRITE_BIT; SourceStage = VK_PIPELINE_STAGE_FRAGMENT_SHADER_BIT; DestinationStage = VK_PIPELINE_STAGE_TRANSFER_BIT; } else if(OldLayout == VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL && NewLayout == VK_IMAGE_LAYOUT_PRESENT_SRC_KHR) { Barrier.srcAccessMask = VK_ACCESS_TRANSFER_READ_BIT; Barrier.dstAccessMask = VK_ACCESS_MEMORY_READ_BIT; SourceStage = VK_PIPELINE_STAGE_TRANSFER_BIT; DestinationStage = VK_PIPELINE_STAGE_BOTTOM_OF_PIPE_BIT; } else if(OldLayout == VK_IMAGE_LAYOUT_PRESENT_SRC_KHR && NewLayout == VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL) { Barrier.srcAccessMask = VK_ACCESS_MEMORY_READ_BIT; Barrier.dstAccessMask = VK_ACCESS_TRANSFER_READ_BIT; SourceStage = VK_PIPELINE_STAGE_BOTTOM_OF_PIPE_BIT; DestinationStage = VK_PIPELINE_STAGE_TRANSFER_BIT; } else if(OldLayout == VK_IMAGE_LAYOUT_UNDEFINED && NewLayout == VK_IMAGE_LAYOUT_GENERAL) { Barrier.srcAccessMask = 0; Barrier.dstAccessMask = VK_ACCESS_MEMORY_READ_BIT; SourceStage = VK_PIPELINE_STAGE_TOP_OF_PIPE_BIT; DestinationStage = VK_PIPELINE_STAGE_TRANSFER_BIT; } else if(OldLayout == VK_IMAGE_LAYOUT_GENERAL && NewLayout == VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL) { Barrier.srcAccessMask = VK_ACCESS_MEMORY_READ_BIT; Barrier.dstAccessMask = VK_ACCESS_TRANSFER_WRITE_BIT; SourceStage = VK_PIPELINE_STAGE_TRANSFER_BIT; DestinationStage = VK_PIPELINE_STAGE_TRANSFER_BIT; } else if(OldLayout == VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL && NewLayout == VK_IMAGE_LAYOUT_GENERAL) { Barrier.srcAccessMask = VK_ACCESS_TRANSFER_WRITE_BIT; Barrier.dstAccessMask = VK_ACCESS_MEMORY_READ_BIT; SourceStage = VK_PIPELINE_STAGE_TRANSFER_BIT; DestinationStage = VK_PIPELINE_STAGE_TRANSFER_BIT; } else { dbg_msg("vulkan", "unsupported layout transition!"); } vkCmdPipelineBarrier( MemCommandBuffer, SourceStage, DestinationStage, 0, 0, nullptr, 0, nullptr, 1, &Barrier); } void CopyBufferToImage(VkBuffer Buffer, VkDeviceSize BufferOffset, VkImage Image, int32_t X, int32_t Y, uint32_t Width, uint32_t Height, size_t Depth) { VkCommandBuffer CommandBuffer = GetMemoryCommandBuffer(); VkBufferImageCopy Region{}; Region.bufferOffset = BufferOffset; Region.bufferRowLength = 0; Region.bufferImageHeight = 0; Region.imageSubresource.aspectMask = VK_IMAGE_ASPECT_COLOR_BIT; Region.imageSubresource.mipLevel = 0; Region.imageSubresource.baseArrayLayer = 0; Region.imageSubresource.layerCount = Depth; Region.imageOffset = {X, Y, 0}; Region.imageExtent = { Width, Height, 1}; vkCmdCopyBufferToImage(CommandBuffer, Buffer, Image, VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL, 1, &Region); } /************************ * BUFFERS ************************/ void CreateBufferObject(size_t BufferIndex, const void *pUploadData, VkDeviceSize BufferDataSize, bool IsOneFrameBuffer) { void *pUploadDataTmp = nullptr; if(pUploadData == nullptr) { pUploadDataTmp = malloc(BufferDataSize); pUploadData = pUploadDataTmp; } while(BufferIndex >= m_BufferObjects.size()) { m_BufferObjects.resize((m_BufferObjects.size() * 2) + 1); } auto &BufferObject = m_BufferObjects[BufferIndex]; VkBuffer VertexBuffer; size_t BufferOffset = 0; if(!IsOneFrameBuffer) { auto StagingBuffer = GetStagingBuffer(pUploadData, BufferDataSize); auto Mem = GetVertexBuffer(BufferDataSize); BufferObject.m_BufferObject.m_Mem = Mem; VertexBuffer = Mem.m_Buffer; BufferOffset = Mem.m_HeapData.m_OffsetToAlign; MemoryBarrier(VertexBuffer, Mem.m_HeapData.m_OffsetToAlign, BufferDataSize, VK_ACCESS_VERTEX_ATTRIBUTE_READ_BIT, true); CopyBuffer(StagingBuffer.m_Buffer, VertexBuffer, StagingBuffer.m_HeapData.m_OffsetToAlign, Mem.m_HeapData.m_OffsetToAlign, BufferDataSize); MemoryBarrier(VertexBuffer, Mem.m_HeapData.m_OffsetToAlign, BufferDataSize, VK_ACCESS_VERTEX_ATTRIBUTE_READ_BIT, false); UploadAndFreeStagingMemBlock(StagingBuffer); } else { SDeviceMemoryBlock VertexBufferMemory; CreateStreamVertexBuffer(ms_MainThreadIndex, VertexBuffer, VertexBufferMemory, BufferOffset, pUploadData, BufferDataSize); } BufferObject.m_IsStreamedBuffer = IsOneFrameBuffer; BufferObject.m_CurBuffer = VertexBuffer; BufferObject.m_CurBufferOffset = BufferOffset; if(pUploadDataTmp != nullptr) free(pUploadDataTmp); } void DeleteBufferObject(size_t BufferIndex) { auto &BufferObject = m_BufferObjects[BufferIndex]; if(!BufferObject.m_IsStreamedBuffer) { FreeVertexMemBlock(BufferObject.m_BufferObject.m_Mem); } BufferObject = {}; } void CopyBuffer(VkBuffer SrcBuffer, VkBuffer DstBuffer, VkDeviceSize SrcOffset, VkDeviceSize DstOffset, VkDeviceSize CopySize) { VkCommandBuffer CommandBuffer = GetMemoryCommandBuffer(); VkBufferCopy CopyRegion{}; CopyRegion.srcOffset = SrcOffset; CopyRegion.dstOffset = DstOffset; CopyRegion.size = CopySize; vkCmdCopyBuffer(CommandBuffer, SrcBuffer, DstBuffer, 1, &CopyRegion); } /************************ * RENDER STATES ************************/ void GetStateMatrix(const CCommandBuffer::SState &State, std::array &Matrix) { Matrix = { // column 1 2.f / (State.m_ScreenBR.x - State.m_ScreenTL.x), 0, // column 2 0, 2.f / (State.m_ScreenBR.y - State.m_ScreenTL.y), // column 3 0, 0, // column 4 -((State.m_ScreenTL.x + State.m_ScreenBR.x) / (State.m_ScreenBR.x - State.m_ScreenTL.x)), -((State.m_ScreenTL.y + State.m_ScreenBR.y) / (State.m_ScreenBR.y - State.m_ScreenTL.y)), }; } bool GetIsTextured(const CCommandBuffer::SState &State) { return State.m_Texture != -1; } size_t GetAddressModeIndex(const CCommandBuffer::SState &State) { return State.m_WrapMode == CCommandBuffer::WRAP_REPEAT ? VULKAN_BACKEND_ADDRESS_MODE_REPEAT : VULKAN_BACKEND_ADDRESS_MODE_CLAMP_EDGES; } size_t GetBlendModeIndex(const CCommandBuffer::SState &State) { return State.m_BlendMode == CCommandBuffer::BLEND_ADDITIVE ? VULKAN_BACKEND_BLEND_MODE_ADDITATIVE : (State.m_BlendMode == CCommandBuffer::BLEND_NONE ? VULKAN_BACKEND_BLEND_MODE_NONE : VULKAN_BACKEND_BLEND_MODE_ALPHA); } size_t GetDynamicModeIndexFromState(const CCommandBuffer::SState &State) { return (State.m_ClipEnable || m_HasDynamicViewport) ? VULKAN_BACKEND_CLIP_MODE_DYNAMIC_SCISSOR_AND_VIEWPORT : VULKAN_BACKEND_CLIP_MODE_NONE; } size_t GetDynamicModeIndexFromExecBuffer(const SRenderCommandExecuteBuffer &ExecBuffer) { return (ExecBuffer.m_HasDynamicState) ? VULKAN_BACKEND_CLIP_MODE_DYNAMIC_SCISSOR_AND_VIEWPORT : VULKAN_BACKEND_CLIP_MODE_NONE; } VkPipeline &GetPipeline(SPipelineContainer &Container, bool IsTextured, size_t BlendModeIndex, size_t DynamicIndex) { return Container.m_aaaPipelines[BlendModeIndex][DynamicIndex][(size_t)IsTextured]; } VkPipelineLayout &GetPipeLayout(SPipelineContainer &Container, bool IsTextured, size_t BlendModeIndex, size_t DynamicIndex) { return Container.m_aaaPipelineLayouts[BlendModeIndex][DynamicIndex][(size_t)IsTextured]; } VkPipelineLayout &GetStandardPipeLayout(bool IsLineGeometry, bool IsTextured, size_t BlendModeIndex, size_t DynamicIndex) { if(IsLineGeometry) return GetPipeLayout(m_StandardLinePipeline, IsTextured, BlendModeIndex, DynamicIndex); else return GetPipeLayout(m_StandardPipeline, IsTextured, BlendModeIndex, DynamicIndex); } VkPipeline &GetStandardPipe(bool IsLineGeometry, bool IsTextured, size_t BlendModeIndex, size_t DynamicIndex) { if(IsLineGeometry) return GetPipeline(m_StandardLinePipeline, IsTextured, BlendModeIndex, DynamicIndex); else return GetPipeline(m_StandardPipeline, IsTextured, BlendModeIndex, DynamicIndex); } VkPipelineLayout &GetTileLayerPipeLayout(int Type, bool IsTextured, size_t BlendModeIndex, size_t DynamicIndex) { if(Type == 0) return GetPipeLayout(m_TilePipeline, IsTextured, BlendModeIndex, DynamicIndex); else if(Type == 1) return GetPipeLayout(m_TileBorderPipeline, IsTextured, BlendModeIndex, DynamicIndex); else return GetPipeLayout(m_TileBorderLinePipeline, IsTextured, BlendModeIndex, DynamicIndex); } VkPipeline &GetTileLayerPipe(int Type, bool IsTextured, size_t BlendModeIndex, size_t DynamicIndex) { if(Type == 0) return GetPipeline(m_TilePipeline, IsTextured, BlendModeIndex, DynamicIndex); else if(Type == 1) return GetPipeline(m_TileBorderPipeline, IsTextured, BlendModeIndex, DynamicIndex); else return GetPipeline(m_TileBorderLinePipeline, IsTextured, BlendModeIndex, DynamicIndex); } void GetStateIndices(const SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SState &State, bool &IsTextured, size_t &BlendModeIndex, size_t &DynamicIndex, size_t &AddressModeIndex) { IsTextured = GetIsTextured(State); AddressModeIndex = GetAddressModeIndex(State); BlendModeIndex = GetBlendModeIndex(State); DynamicIndex = GetDynamicModeIndexFromExecBuffer(ExecBuffer); } void ExecBufferFillDynamicStates(const CCommandBuffer::SState &State, SRenderCommandExecuteBuffer &ExecBuffer) { size_t DynamicStateIndex = GetDynamicModeIndexFromState(State); if(DynamicStateIndex == VULKAN_BACKEND_CLIP_MODE_DYNAMIC_SCISSOR_AND_VIEWPORT) { VkViewport Viewport; if(m_HasDynamicViewport) { Viewport.x = (float)m_DynamicViewportOffset.x; Viewport.y = (float)m_DynamicViewportOffset.y; Viewport.width = (float)m_DynamicViewportSize.width; Viewport.height = (float)m_DynamicViewportSize.height; Viewport.minDepth = 0.0f; Viewport.maxDepth = 1.0f; } else { Viewport.x = 0.0f; Viewport.y = 0.0f; Viewport.width = (float)m_VKSwapImgAndViewportExtent.m_Viewport.width; Viewport.height = (float)m_VKSwapImgAndViewportExtent.m_Viewport.height; Viewport.minDepth = 0.0f; Viewport.maxDepth = 1.0f; } VkRect2D Scissor; // convert from OGL to vulkan clip if(State.m_ClipEnable) { int32_t ScissorY = (int32_t)m_VKSwapImgAndViewportExtent.m_Viewport.height - ((int32_t)State.m_ClipY + (int32_t)State.m_ClipH); uint32_t ScissorH = (int32_t)State.m_ClipH; Scissor.offset = {(int32_t)State.m_ClipX, ScissorY}; Scissor.extent = {(uint32_t)State.m_ClipW, ScissorH}; } else { Scissor.offset = {0, 0}; Scissor.extent = {m_VKSwapImgAndViewportExtent.m_Viewport.width, m_VKSwapImgAndViewportExtent.m_Viewport.height}; } Viewport.x = clamp(Viewport.x, 0.0f, std::numeric_limits::max()); Viewport.y = clamp(Viewport.y, 0.0f, std::numeric_limits::max()); Scissor.offset.x = clamp(Scissor.offset.x, 0, std::numeric_limits::max()); Scissor.offset.y = clamp(Scissor.offset.y, 0, std::numeric_limits::max()); ExecBuffer.m_HasDynamicState = true; ExecBuffer.m_Viewport = Viewport; ExecBuffer.m_Scissor = Scissor; } else { ExecBuffer.m_HasDynamicState = false; } } void BindPipeline(size_t RenderThreadIndex, VkCommandBuffer &CommandBuffer, SRenderCommandExecuteBuffer &ExecBuffer, VkPipeline &BindingPipe, const CCommandBuffer::SState &State) { if(m_vLastPipeline[RenderThreadIndex] != BindingPipe) { vkCmdBindPipeline(CommandBuffer, VK_PIPELINE_BIND_POINT_GRAPHICS, BindingPipe); m_vLastPipeline[RenderThreadIndex] = BindingPipe; } size_t DynamicStateIndex = GetDynamicModeIndexFromExecBuffer(ExecBuffer); if(DynamicStateIndex == VULKAN_BACKEND_CLIP_MODE_DYNAMIC_SCISSOR_AND_VIEWPORT) { vkCmdSetViewport(CommandBuffer, 0, 1, &ExecBuffer.m_Viewport); vkCmdSetScissor(CommandBuffer, 0, 1, &ExecBuffer.m_Scissor); } } /************************** * RENDERING IMPLEMENTATION ***************************/ void RenderTileLayer_FillExecuteBuffer(SRenderCommandExecuteBuffer &ExecBuffer, size_t DrawCalls, const CCommandBuffer::SState &State, size_t BufferContainerIndex) { size_t BufferObjectIndex = (size_t)m_BufferContainers[BufferContainerIndex].m_BufferObjectIndex; auto &BufferObject = m_BufferObjects[BufferObjectIndex]; ExecBuffer.m_Buffer = BufferObject.m_CurBuffer; ExecBuffer.m_BufferOff = BufferObject.m_CurBufferOffset; bool IsTextured = GetIsTextured(State); if(IsTextured) { auto &DescrSet = m_Textures[State.m_Texture].m_VKStandard3DTexturedDescrSet; ExecBuffer.m_aDescriptors[0] = DescrSet; } ExecBuffer.m_IndexBuffer = m_RenderIndexBuffer; ExecBuffer.m_EstimatedRenderCallCount = DrawCalls; ExecBufferFillDynamicStates(State, ExecBuffer); } void RenderTileLayer(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SState &State, int Type, const GL_SColorf &Color, const vec2 &Dir, const vec2 &Off, int32_t JumpIndex, size_t IndicesDrawNum, char *const *pIndicesOffsets, const unsigned int *pDrawCount, size_t InstanceCount) { std::array m; GetStateMatrix(State, m); bool IsTextured; size_t BlendModeIndex; size_t DynamicIndex; size_t AddressModeIndex; GetStateIndices(ExecBuffer, State, IsTextured, BlendModeIndex, DynamicIndex, AddressModeIndex); auto &PipeLayout = GetTileLayerPipeLayout(Type, IsTextured, BlendModeIndex, DynamicIndex); auto &PipeLine = GetTileLayerPipe(Type, IsTextured, BlendModeIndex, DynamicIndex); auto &CommandBuffer = GetGraphicCommandBuffer(ExecBuffer.m_ThreadIndex); BindPipeline(ExecBuffer.m_ThreadIndex, CommandBuffer, ExecBuffer, PipeLine, State); std::array aVertexBuffers = {ExecBuffer.m_Buffer}; std::array aOffsets = {(VkDeviceSize)ExecBuffer.m_BufferOff}; vkCmdBindVertexBuffers(CommandBuffer, 0, 1, aVertexBuffers.data(), aOffsets.data()); if(IsTextured) { vkCmdBindDescriptorSets(CommandBuffer, VK_PIPELINE_BIND_POINT_GRAPHICS, PipeLayout, 0, 1, &ExecBuffer.m_aDescriptors[0].m_Descriptor, 0, nullptr); } SUniformTileGPosBorder VertexPushConstants; size_t VertexPushConstantSize = sizeof(SUniformTileGPos); SUniformTileGVertColor FragPushConstants; size_t FragPushConstantSize = sizeof(SUniformTileGVertColor); mem_copy(VertexPushConstants.m_aPos, m.data(), m.size() * sizeof(float)); mem_copy(FragPushConstants.m_aColor, &Color, sizeof(FragPushConstants.m_aColor)); if(Type == 1) { mem_copy(&VertexPushConstants.m_Dir, &Dir, sizeof(Dir)); mem_copy(&VertexPushConstants.m_Offset, &Off, sizeof(Off)); VertexPushConstants.m_JumpIndex = JumpIndex; VertexPushConstantSize = sizeof(SUniformTileGPosBorder); } else if(Type == 2) { mem_copy(&VertexPushConstants.m_Dir, &Dir, sizeof(Dir)); mem_copy(&VertexPushConstants.m_Offset, &Off, sizeof(Off)); VertexPushConstantSize = sizeof(SUniformTileGPosBorderLine); } vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_VERTEX_BIT, 0, VertexPushConstantSize, &VertexPushConstants); vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_FRAGMENT_BIT, sizeof(SUniformTileGPosBorder) + sizeof(SUniformTileGVertColorAlign), FragPushConstantSize, &FragPushConstants); size_t DrawCount = (size_t)IndicesDrawNum; vkCmdBindIndexBuffer(CommandBuffer, ExecBuffer.m_IndexBuffer, 0, VK_INDEX_TYPE_UINT32); for(size_t i = 0; i < DrawCount; ++i) { VkDeviceSize IndexOffset = (VkDeviceSize)((ptrdiff_t)pIndicesOffsets[i] / sizeof(uint32_t)); vkCmdDrawIndexed(CommandBuffer, static_cast(pDrawCount[i]), InstanceCount, IndexOffset, 0, 0); } } template void RenderStandard(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SState &State, int PrimType, const TName *pVertices, int PrimitiveCount) { std::array m; GetStateMatrix(State, m); bool IsLineGeometry = PrimType == CCommandBuffer::PRIMTYPE_LINES; bool IsTextured; size_t BlendModeIndex; size_t DynamicIndex; size_t AddressModeIndex; GetStateIndices(ExecBuffer, State, IsTextured, BlendModeIndex, DynamicIndex, AddressModeIndex); auto &PipeLayout = Is3DTextured ? GetPipeLayout(m_Standard3DPipeline, IsTextured, BlendModeIndex, DynamicIndex) : GetStandardPipeLayout(IsLineGeometry, IsTextured, BlendModeIndex, DynamicIndex); auto &PipeLine = Is3DTextured ? GetPipeline(m_Standard3DPipeline, IsTextured, BlendModeIndex, DynamicIndex) : GetStandardPipe(IsLineGeometry, IsTextured, BlendModeIndex, DynamicIndex); auto &CommandBuffer = GetGraphicCommandBuffer(ExecBuffer.m_ThreadIndex); BindPipeline(ExecBuffer.m_ThreadIndex, CommandBuffer, ExecBuffer, PipeLine, State); size_t VertPerPrim = 2; bool IsIndexed = false; if(PrimType == CCommandBuffer::PRIMTYPE_QUADS) { VertPerPrim = 4; IsIndexed = true; } else if(PrimType == CCommandBuffer::PRIMTYPE_TRIANGLES) { VertPerPrim = 3; } VkBuffer VKBuffer; SDeviceMemoryBlock VKBufferMem; size_t BufferOff = 0; CreateStreamVertexBuffer(ExecBuffer.m_ThreadIndex, VKBuffer, VKBufferMem, BufferOff, pVertices, VertPerPrim * sizeof(TName) * PrimitiveCount); std::array aVertexBuffers = {VKBuffer}; std::array aOffsets = {(VkDeviceSize)BufferOff}; vkCmdBindVertexBuffers(CommandBuffer, 0, 1, aVertexBuffers.data(), aOffsets.data()); if(IsIndexed) vkCmdBindIndexBuffer(CommandBuffer, ExecBuffer.m_IndexBuffer, 0, VK_INDEX_TYPE_UINT32); if(IsTextured) { vkCmdBindDescriptorSets(CommandBuffer, VK_PIPELINE_BIND_POINT_GRAPHICS, PipeLayout, 0, 1, &ExecBuffer.m_aDescriptors[0].m_Descriptor, 0, nullptr); } vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_VERTEX_BIT, 0, sizeof(SUniformGPos), m.data()); if(IsIndexed) vkCmdDrawIndexed(CommandBuffer, static_cast(PrimitiveCount * 6), 1, 0, 0, 0); else vkCmdDraw(CommandBuffer, static_cast(PrimitiveCount * VertPerPrim), 1, 0, 0); } public: CCommandProcessorFragment_Vulkan() { m_Textures.reserve(CCommandBuffer::MAX_TEXTURES); } /************************ * VULKAN SETUP CODE ************************/ bool GetVulkanExtensions(SDL_Window *pWindow, std::vector &VKExtensions) { unsigned int ExtCount = 0; if(!SDL_Vulkan_GetInstanceExtensions(pWindow, &ExtCount, nullptr)) { SetError("Could not get instance extensions from SDL."); return false; } std::vector ExtensionList(ExtCount); if(!SDL_Vulkan_GetInstanceExtensions(pWindow, &ExtCount, ExtensionList.data())) { SetError("Could not get instance extensions from SDL."); return false; } for(uint32_t i = 0; i < ExtCount; i++) { VKExtensions.emplace_back(ExtensionList[i]); } return true; } std::set OurVKLayers() { std::set OurLayers; if(g_Config.m_DbgGfx == DEBUG_GFX_MODE_MINIMUM || g_Config.m_DbgGfx == DEBUG_GFX_MODE_ALL) { OurLayers.emplace("VK_LAYER_KHRONOS_validation"); // deprecated, but VK_LAYER_KHRONOS_validation was released after vulkan 1.1 OurLayers.emplace("VK_LAYER_LUNARG_standard_validation"); } return OurLayers; } std::set OurDeviceExtensions() { std::set OurExt; OurExt.emplace(VK_KHR_SWAPCHAIN_EXTENSION_NAME); return OurExt; } std::vector OurImageUsages() { std::vector ImgUsages; ImgUsages.emplace_back(VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT); ImgUsages.emplace_back(VK_IMAGE_USAGE_TRANSFER_SRC_BIT); return ImgUsages; } bool GetVulkanLayers(std::vector &VKLayers) { uint32_t LayerCount = 0; VkResult Res = vkEnumerateInstanceLayerProperties(&LayerCount, NULL); if(Res != VK_SUCCESS) { SetError("Could not get vulkan layers."); return false; } std::vector VKInstanceLayers(LayerCount); Res = vkEnumerateInstanceLayerProperties(&LayerCount, VKInstanceLayers.data()); if(Res != VK_SUCCESS) { SetError("Could not get vulkan layers."); return false; } std::set ReqLayerNames = OurVKLayers(); VKLayers.clear(); for(const auto &LayerName : VKInstanceLayers) { auto it = ReqLayerNames.find(std::string(LayerName.layerName)); if(it != ReqLayerNames.end()) { VKLayers.emplace_back(LayerName.layerName); } } return true; } bool CreateVulkanInstance(const std::vector &VKLayers, const std::vector &VKExtensions, bool TryDebugExtensions) { std::vector LayersCStr; LayersCStr.reserve(VKLayers.size()); for(const auto &Layer : VKLayers) LayersCStr.emplace_back(Layer.c_str()); std::vector ExtCStr; ExtCStr.reserve(VKExtensions.size() + 1); for(const auto &Ext : VKExtensions) ExtCStr.emplace_back(Ext.c_str()); #ifdef VK_EXT_debug_utils if(TryDebugExtensions && (g_Config.m_DbgGfx == DEBUG_GFX_MODE_MINIMUM || g_Config.m_DbgGfx == DEBUG_GFX_MODE_ALL)) { // debug message support ExtCStr.emplace_back(VK_EXT_DEBUG_UTILS_EXTENSION_NAME); } #endif VkApplicationInfo VKAppInfo = {}; VKAppInfo.sType = VK_STRUCTURE_TYPE_APPLICATION_INFO; VKAppInfo.pNext = NULL; VKAppInfo.pApplicationName = "DDNet"; VKAppInfo.applicationVersion = 1; VKAppInfo.pEngineName = "DDNet-Vulkan"; VKAppInfo.engineVersion = 1; VKAppInfo.apiVersion = VK_API_VERSION_1_0; void *pExt = nullptr; #if defined(VK_EXT_validation_features) && VK_EXT_VALIDATION_FEATURES_SPEC_VERSION >= 5 VkValidationFeaturesEXT Features = {}; std::array aEnables = {VK_VALIDATION_FEATURE_ENABLE_SYNCHRONIZATION_VALIDATION_EXT, VK_VALIDATION_FEATURE_ENABLE_BEST_PRACTICES_EXT}; if(TryDebugExtensions && (g_Config.m_DbgGfx == DEBUG_GFX_MODE_AFFECTS_PERFORMANCE || g_Config.m_DbgGfx == DEBUG_GFX_MODE_ALL)) { Features.sType = VK_STRUCTURE_TYPE_VALIDATION_FEATURES_EXT; Features.enabledValidationFeatureCount = aEnables.size(); Features.pEnabledValidationFeatures = aEnables.data(); pExt = &Features; } #endif VkInstanceCreateInfo VKInstanceInfo = {}; VKInstanceInfo.sType = VK_STRUCTURE_TYPE_INSTANCE_CREATE_INFO; VKInstanceInfo.pNext = pExt; VKInstanceInfo.flags = 0; VKInstanceInfo.pApplicationInfo = &VKAppInfo; VKInstanceInfo.enabledExtensionCount = static_cast(ExtCStr.size()); VKInstanceInfo.ppEnabledExtensionNames = ExtCStr.data(); VKInstanceInfo.enabledLayerCount = static_cast(LayersCStr.size()); VKInstanceInfo.ppEnabledLayerNames = LayersCStr.data(); bool TryAgain = false; VkResult Res = vkCreateInstance(&VKInstanceInfo, NULL, &m_VKInstance); const char *pCritErrorMsg = CheckVulkanCriticalError(Res); if(pCritErrorMsg != nullptr) { SetError("Creating instance failed.", pCritErrorMsg); return false; } else if(Res == VK_ERROR_LAYER_NOT_PRESENT || Res == VK_ERROR_EXTENSION_NOT_PRESENT) TryAgain = true; if(TryAgain && TryDebugExtensions) return CreateVulkanInstance(VKLayers, VKExtensions, false); return true; } bool SelectGPU(char *pRendererName, char *pVendorName, char *pVersionName) { uint32_t DevicesCount = 0; vkEnumeratePhysicalDevices(m_VKInstance, &DevicesCount, nullptr); if(DevicesCount == 0) { SetError("No vulkan compatible devices found."); return false; } std::vector DeviceList(DevicesCount); vkEnumeratePhysicalDevices(m_VKInstance, &DevicesCount, DeviceList.data()); size_t Index = 0; std::vector DevicePropList(DeviceList.size()); m_pGPUList->m_GPUs.reserve(DeviceList.size()); size_t FoundDeviceIndex = 0; size_t AutoGPUIndex = 0; bool IsAutoGPU = str_comp(g_Config.m_GfxGPUName, "auto") == 0; for(auto &CurDevice : DeviceList) { vkGetPhysicalDeviceProperties(CurDevice, &(DevicePropList[Index])); auto &DeviceProp = DevicePropList[Index]; STWGraphicGPU::STWGraphicGPUItem NewGPU; str_copy(NewGPU.m_Name, DeviceProp.deviceName, minimum(sizeof(DeviceProp.deviceName), sizeof(NewGPU.m_Name))); NewGPU.m_IsDiscreteGPU = DeviceProp.deviceType == VK_PHYSICAL_DEVICE_TYPE_DISCRETE_GPU; m_pGPUList->m_GPUs.push_back(NewGPU); Index++; int DevAPIMajor = (int)VK_API_VERSION_MAJOR(DeviceProp.apiVersion); int DevAPIMinor = (int)VK_API_VERSION_MINOR(DeviceProp.apiVersion); if((AutoGPUIndex == 0 && DeviceProp.deviceType == VK_PHYSICAL_DEVICE_TYPE_DISCRETE_GPU) && (DevAPIMajor > gs_BackendVulkanMajor || (DevAPIMajor == gs_BackendVulkanMajor && DevAPIMinor >= gs_BackendVulkanMinor))) { str_copy(m_pGPUList->m_AutoGPU.m_Name, DeviceProp.deviceName, minimum(sizeof(DeviceProp.deviceName), sizeof(m_pGPUList->m_AutoGPU.m_Name))); m_pGPUList->m_AutoGPU.m_IsDiscreteGPU = DeviceProp.deviceType == VK_PHYSICAL_DEVICE_TYPE_DISCRETE_GPU; AutoGPUIndex = Index; } if(((IsAutoGPU && FoundDeviceIndex == 0 && DeviceProp.deviceType == VK_PHYSICAL_DEVICE_TYPE_DISCRETE_GPU) || str_comp(DeviceProp.deviceName, g_Config.m_GfxGPUName) == 0) && (DevAPIMajor > gs_BackendVulkanMajor || (DevAPIMajor == gs_BackendVulkanMajor && DevAPIMinor >= gs_BackendVulkanMinor))) { FoundDeviceIndex = Index; } } if(FoundDeviceIndex == 0) FoundDeviceIndex = 1; { auto &DeviceProp = DevicePropList[FoundDeviceIndex - 1]; int DevAPIMajor = (int)VK_API_VERSION_MAJOR(DeviceProp.apiVersion); int DevAPIMinor = (int)VK_API_VERSION_MINOR(DeviceProp.apiVersion); int DevAPIPatch = (int)VK_API_VERSION_PATCH(DeviceProp.apiVersion); str_copy(pRendererName, DeviceProp.deviceName, gs_GPUInfoStringSize); const char *pVendorNameStr = NULL; switch(DeviceProp.vendorID) { case 0x1002: pVendorNameStr = "AMD"; break; case 0x1010: pVendorNameStr = "ImgTec"; break; case 0x106B: pVendorNameStr = "Apple"; break; case 0x10DE: pVendorNameStr = "NVIDIA"; break; case 0x13B5: pVendorNameStr = "ARM"; break; case 0x5143: pVendorNameStr = "Qualcomm"; break; case 0x8086: pVendorNameStr = "INTEL"; break; case 0x10005: pVendorNameStr = "Mesa"; break; default: dbg_msg("vulkan", "unknown gpu vendor %u", DeviceProp.vendorID); pVendorNameStr = "unknown"; break; } str_copy(pVendorName, pVendorNameStr, gs_GPUInfoStringSize); str_format(pVersionName, gs_GPUInfoStringSize, "Vulkan %d.%d.%d", DevAPIMajor, DevAPIMinor, DevAPIPatch); // get important device limits m_NonCoherentMemAlignment = DeviceProp.limits.nonCoherentAtomSize; m_OptimalImageCopyMemAlignment = DeviceProp.limits.optimalBufferCopyOffsetAlignment; m_MaxTextureSize = DeviceProp.limits.maxImageDimension2D; m_MaxSamplerAnisotropy = DeviceProp.limits.maxSamplerAnisotropy; m_MinUniformAlign = DeviceProp.limits.minUniformBufferOffsetAlignment; m_MaxMultiSample = DeviceProp.limits.framebufferColorSampleCounts; if(IsVerbose()) { dbg_msg("vulkan", "device prop: non-coherent align: %" PRIu64 ", optimal image copy align: %" PRIu64 ", max texture size: %u, max sampler anisotropy: %u", (size_t)m_NonCoherentMemAlignment, (size_t)m_OptimalImageCopyMemAlignment, m_MaxTextureSize, m_MaxSamplerAnisotropy); dbg_msg("vulkan", "device prop: min uniform align: %u, multi sample: %u", m_MinUniformAlign, (uint32_t)m_MaxMultiSample); } } VkPhysicalDevice CurDevice = DeviceList[FoundDeviceIndex - 1]; uint32_t FamQueueCount = 0; vkGetPhysicalDeviceQueueFamilyProperties(CurDevice, &FamQueueCount, nullptr); if(FamQueueCount == 0) { SetError("No vulkan queue family properties found."); return false; } std::vector QueuePropList(FamQueueCount); vkGetPhysicalDeviceQueueFamilyProperties(CurDevice, &FamQueueCount, QueuePropList.data()); uint32_t QueueNodeIndex = std::numeric_limits::max(); for(uint32_t i = 0; i < FamQueueCount; i++) { if(QueuePropList[i].queueCount > 0 && (QueuePropList[i].queueFlags & VK_QUEUE_GRAPHICS_BIT)) { QueueNodeIndex = i; } /*if(QueuePropList[i].queueCount > 0 && (QueuePropList[i].queueFlags & VK_QUEUE_COMPUTE_BIT)) { QueueNodeIndex = i; }*/ } if(QueueNodeIndex == std::numeric_limits::max()) { SetError("No vulkan queue found that matches the requirements: graphics queue"); return false; } m_VKGPU = CurDevice; m_VKGraphicsQueueIndex = QueueNodeIndex; return true; } bool CreateLogicalDevice(const std::vector &VKLayers) { std::vector LayerCNames; LayerCNames.reserve(VKLayers.size()); for(const auto &Layer : VKLayers) LayerCNames.emplace_back(Layer.c_str()); uint32_t DevPropCount = 0; if(vkEnumerateDeviceExtensionProperties(m_VKGPU, NULL, &DevPropCount, NULL) != VK_SUCCESS) { SetError("Querying logical device extension propterties failed."); return false; } std::vector DevPropList(DevPropCount); if(vkEnumerateDeviceExtensionProperties(m_VKGPU, NULL, &DevPropCount, DevPropList.data()) != VK_SUCCESS) { SetError("Querying logical device extension propterties failed."); return false; } std::vector DevPropCNames; std::set OurDevExt = OurDeviceExtensions(); for(const auto &CurExtProp : DevPropList) { auto it = OurDevExt.find(std::string(CurExtProp.extensionName)); if(it != OurDevExt.end()) { DevPropCNames.emplace_back(CurExtProp.extensionName); } } VkDeviceQueueCreateInfo VKQueueCreateInfo; VKQueueCreateInfo.sType = VK_STRUCTURE_TYPE_DEVICE_QUEUE_CREATE_INFO; VKQueueCreateInfo.queueFamilyIndex = m_VKGraphicsQueueIndex; VKQueueCreateInfo.queueCount = 1; std::vector queue_prio = {1.0f}; VKQueueCreateInfo.pQueuePriorities = queue_prio.data(); VKQueueCreateInfo.pNext = NULL; VKQueueCreateInfo.flags = 0; VkDeviceCreateInfo VKCreateInfo; VKCreateInfo.sType = VK_STRUCTURE_TYPE_DEVICE_CREATE_INFO; VKCreateInfo.queueCreateInfoCount = 1; VKCreateInfo.pQueueCreateInfos = &VKQueueCreateInfo; VKCreateInfo.ppEnabledLayerNames = LayerCNames.data(); VKCreateInfo.enabledLayerCount = static_cast(LayerCNames.size()); VKCreateInfo.ppEnabledExtensionNames = DevPropCNames.data(); VKCreateInfo.enabledExtensionCount = static_cast(DevPropCNames.size()); VKCreateInfo.pNext = NULL; VKCreateInfo.pEnabledFeatures = NULL; VKCreateInfo.flags = 0; VkResult res = vkCreateDevice(m_VKGPU, &VKCreateInfo, nullptr, &m_VKDevice); if(res != VK_SUCCESS) { SetError("Logical device could not be created."); return false; } return true; } bool CreateSurface(SDL_Window *pWindow) { if(!SDL_Vulkan_CreateSurface(pWindow, m_VKInstance, &m_VKPresentSurface)) { dbg_msg("vulkan", "error from sdl: %s", SDL_GetError()); SetError("Creating a vulkan surface for the SDL window failed."); return false; } VkBool32 IsSupported = false; vkGetPhysicalDeviceSurfaceSupportKHR(m_VKGPU, m_VKGraphicsQueueIndex, m_VKPresentSurface, &IsSupported); if(!IsSupported) { SetError("The device surface does not support presenting the framebuffer to a screen. (maybe the wrong GPU was selected?)"); return false; } return true; } void DestroySurface() { vkDestroySurfaceKHR(m_VKInstance, m_VKPresentSurface, nullptr); } bool GetPresentationMode(VkPresentModeKHR &VKIOMode) { uint32_t PresentModeCount = 0; if(vkGetPhysicalDeviceSurfacePresentModesKHR(m_VKGPU, m_VKPresentSurface, &PresentModeCount, NULL) != VK_SUCCESS) { SetError("The device surface presentation modes could not be fetched."); return false; } std::vector PresentModeList(PresentModeCount); if(vkGetPhysicalDeviceSurfacePresentModesKHR(m_VKGPU, m_VKPresentSurface, &PresentModeCount, PresentModeList.data()) != VK_SUCCESS) { SetError("The device surface presentation modes could not be fetched."); return false; } VKIOMode = g_Config.m_GfxVsync ? VK_PRESENT_MODE_FIFO_KHR : VK_PRESENT_MODE_IMMEDIATE_KHR; for(auto &Mode : PresentModeList) { if(Mode == VKIOMode) return true; } dbg_msg("vulkan", "warning: requested presentation mode was not available. falling back to mailbox / fifo relaxed."); VKIOMode = g_Config.m_GfxVsync ? VK_PRESENT_MODE_FIFO_RELAXED_KHR : VK_PRESENT_MODE_MAILBOX_KHR; for(auto &Mode : PresentModeList) { if(Mode == VKIOMode) return true; } dbg_msg("vulkan", "warning: requested presentation mode was not available. using first available."); if(PresentModeCount > 0) VKIOMode = PresentModeList[0]; return true; } bool GetSurfaceProperties(VkSurfaceCapabilitiesKHR &VKSurfCapabilities) { if(vkGetPhysicalDeviceSurfaceCapabilitiesKHR(m_VKGPU, m_VKPresentSurface, &VKSurfCapabilities) != VK_SUCCESS) { SetError("The device surface capabilities could not be fetched."); return false; } return true; } uint32_t GetNumberOfSwapImages(const VkSurfaceCapabilitiesKHR &VKCapabilities) { uint32_t ImgNumber = VKCapabilities.minImageCount + 1; if(IsVerbose()) { dbg_msg("vulkan", "minimal swap image count %u", VKCapabilities.minImageCount); } return (VKCapabilities.maxImageCount > 0 && ImgNumber > VKCapabilities.maxImageCount) ? VKCapabilities.maxImageCount : ImgNumber; } SSwapImgViewportExtent GetSwapImageSize(const VkSurfaceCapabilitiesKHR &VKCapabilities) { VkExtent2D RetSize = {m_CanvasWidth, m_CanvasHeight}; if(VKCapabilities.currentExtent.width == std::numeric_limits::max()) { RetSize.width = clamp(RetSize.width, VKCapabilities.minImageExtent.width, VKCapabilities.maxImageExtent.width); RetSize.height = clamp(RetSize.height, VKCapabilities.minImageExtent.height, VKCapabilities.maxImageExtent.height); } else { RetSize = VKCapabilities.currentExtent; } VkExtent2D AutoViewportExtent = RetSize; // keep this in sync with graphics_threaded AdjustViewport's check if(AutoViewportExtent.height > 4 * AutoViewportExtent.width / 5) AutoViewportExtent.height = 4 * AutoViewportExtent.width / 5; return {RetSize, AutoViewportExtent}; } bool GetImageUsage(const VkSurfaceCapabilitiesKHR &VKCapabilities, VkImageUsageFlags &VKOutUsage) { std::vector OurImgUsages = OurImageUsages(); if(OurImgUsages.empty()) { SetError("Framebuffer image attachment types not supported."); return false; } VKOutUsage = OurImgUsages[0]; for(const auto &ImgUsage : OurImgUsages) { VkImageUsageFlags ImgUsageFlags = ImgUsage & VKCapabilities.supportedUsageFlags; if(ImgUsageFlags != ImgUsage) { SetError("Framebuffer image attachment types not supported."); return false; } VKOutUsage = (VKOutUsage | ImgUsage); } return true; } VkSurfaceTransformFlagBitsKHR GetTransform(const VkSurfaceCapabilitiesKHR &VKCapabilities) { if(VKCapabilities.supportedTransforms & VK_SURFACE_TRANSFORM_IDENTITY_BIT_KHR) return VK_SURFACE_TRANSFORM_IDENTITY_BIT_KHR; return VKCapabilities.currentTransform; } bool GetFormat() { uint32_t SurfFormats = 0; VkResult Res = vkGetPhysicalDeviceSurfaceFormatsKHR(m_VKGPU, m_VKPresentSurface, &SurfFormats, nullptr); if(Res != VK_SUCCESS && Res != VK_INCOMPLETE) { SetError("The device surface format fetching failed."); return false; } std::vector SurfFormatList(SurfFormats); Res = vkGetPhysicalDeviceSurfaceFormatsKHR(m_VKGPU, m_VKPresentSurface, &SurfFormats, SurfFormatList.data()); if(Res != VK_SUCCESS && Res != VK_INCOMPLETE) { SetError("The device surface format fetching failed."); return false; } if(Res == VK_INCOMPLETE) { dbg_msg("vulkan", "warning: not all surface formats are requestable with your current settings."); } if(SurfFormatList.size() == 1 && SurfFormatList[0].format == VK_FORMAT_UNDEFINED) { m_VKSurfFormat.format = VK_FORMAT_B8G8R8A8_UNORM; m_VKSurfFormat.colorSpace = VK_COLOR_SPACE_SRGB_NONLINEAR_KHR; dbg_msg("vulkan", "warning: surface format was undefined. This can potentially cause bugs."); return true; } for(const auto &FindFormat : SurfFormatList) { if(FindFormat.format == VK_FORMAT_B8G8R8A8_UNORM && FindFormat.colorSpace == VK_COLOR_SPACE_SRGB_NONLINEAR_KHR) { m_VKSurfFormat = FindFormat; return true; } else if(FindFormat.format == VK_FORMAT_R8G8B8A8_UNORM && FindFormat.colorSpace == VK_COLOR_SPACE_SRGB_NONLINEAR_KHR) { m_VKSurfFormat = FindFormat; return true; } } dbg_msg("vulkan", "warning: surface format was not RGBA(or variants of it). This can potentially cause weird looking images(too bright etc.)."); m_VKSurfFormat = SurfFormatList[0]; return true; } bool CreateSwapChain(VkSwapchainKHR &OldSwapChain) { VkSurfaceCapabilitiesKHR VKSurfCap; if(!GetSurfaceProperties(VKSurfCap)) return false; VkPresentModeKHR PresentMode = VK_PRESENT_MODE_IMMEDIATE_KHR; if(!GetPresentationMode(PresentMode)) return false; uint32_t SwapImgCount = GetNumberOfSwapImages(VKSurfCap); m_VKSwapImgAndViewportExtent = GetSwapImageSize(VKSurfCap); VkImageUsageFlags UsageFlags; if(!GetImageUsage(VKSurfCap, UsageFlags)) return false; VkSurfaceTransformFlagBitsKHR TransformFlagBits = GetTransform(VKSurfCap); if(!GetFormat()) return false; OldSwapChain = m_VKSwapChain; VkSwapchainCreateInfoKHR SwapInfo; SwapInfo.sType = VK_STRUCTURE_TYPE_SWAPCHAIN_CREATE_INFO_KHR; SwapInfo.pNext = nullptr; SwapInfo.flags = 0; SwapInfo.surface = m_VKPresentSurface; SwapInfo.minImageCount = SwapImgCount; SwapInfo.imageFormat = m_VKSurfFormat.format; SwapInfo.imageColorSpace = m_VKSurfFormat.colorSpace; SwapInfo.imageExtent = m_VKSwapImgAndViewportExtent.m_SwapImg; SwapInfo.imageArrayLayers = 1; SwapInfo.imageUsage = UsageFlags; SwapInfo.imageSharingMode = VK_SHARING_MODE_EXCLUSIVE; SwapInfo.queueFamilyIndexCount = 0; SwapInfo.pQueueFamilyIndices = nullptr; SwapInfo.preTransform = TransformFlagBits; SwapInfo.compositeAlpha = VK_COMPOSITE_ALPHA_OPAQUE_BIT_KHR; SwapInfo.presentMode = PresentMode; SwapInfo.clipped = true; SwapInfo.oldSwapchain = OldSwapChain; m_VKSwapChain = VK_NULL_HANDLE; VkResult SwapchainCreateRes = vkCreateSwapchainKHR(m_VKDevice, &SwapInfo, nullptr, &m_VKSwapChain); const char *pCritErrorMsg = CheckVulkanCriticalError(SwapchainCreateRes); if(pCritErrorMsg != nullptr) { SetError("Creating the swap chain failed.", pCritErrorMsg); return false; } else if(SwapchainCreateRes == VK_ERROR_NATIVE_WINDOW_IN_USE_KHR) return false; return true; } void DestroySwapChain(bool ForceDestroy) { if(ForceDestroy) { vkDestroySwapchainKHR(m_VKDevice, m_VKSwapChain, nullptr); m_VKSwapChain = VK_NULL_HANDLE; } } bool GetSwapChainImageHandles() { uint32_t ImgCount = 0; VkResult res = vkGetSwapchainImagesKHR(m_VKDevice, m_VKSwapChain, &ImgCount, nullptr); if(res != VK_SUCCESS) { SetError("Could not get swap chain images."); return false; } m_SwapChainImageCount = ImgCount; m_SwapChainImages.resize(ImgCount); if(vkGetSwapchainImagesKHR(m_VKDevice, m_VKSwapChain, &ImgCount, m_SwapChainImages.data()) != VK_SUCCESS) { SetError("Could not get swap chain images."); return false; } return true; } void ClearSwapChainImageHandles() { m_SwapChainImages.clear(); } void GetDeviceQueue() { vkGetDeviceQueue(m_VKDevice, m_VKGraphicsQueueIndex, 0, &m_VKGraphicsQueue); vkGetDeviceQueue(m_VKDevice, m_VKGraphicsQueueIndex, 0, &m_VKPresentQueue); } #ifdef VK_EXT_debug_utils static VKAPI_ATTR VkBool32 VKAPI_CALL VKDebugCallback(VkDebugUtilsMessageSeverityFlagBitsEXT MessageSeverity, VkDebugUtilsMessageTypeFlagsEXT MessageType, const VkDebugUtilsMessengerCallbackDataEXT *pCallbackData, void *pUserData) { if((MessageSeverity & VK_DEBUG_UTILS_MESSAGE_SEVERITY_ERROR_BIT_EXT) != 0) { dbg_msg("vulkan_debug", "validation error: %s", pCallbackData->pMessage); } else { dbg_msg("vulkan_debug", "%s", pCallbackData->pMessage); } return VK_FALSE; } VkResult CreateDebugUtilsMessengerEXT(const VkDebugUtilsMessengerCreateInfoEXT *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkDebugUtilsMessengerEXT *pDebugMessenger) { auto func = (PFN_vkCreateDebugUtilsMessengerEXT)vkGetInstanceProcAddr(m_VKInstance, "vkCreateDebugUtilsMessengerEXT"); if(func != nullptr) { return func(m_VKInstance, pCreateInfo, pAllocator, pDebugMessenger); } else { return VK_ERROR_EXTENSION_NOT_PRESENT; } } void DestroyDebugUtilsMessengerEXT(VkDebugUtilsMessengerEXT &DebugMessenger) { auto func = (PFN_vkDestroyDebugUtilsMessengerEXT)vkGetInstanceProcAddr(m_VKInstance, "vkDestroyDebugUtilsMessengerEXT"); if(func != nullptr) { func(m_VKInstance, DebugMessenger, nullptr); } } #endif void SetupDebugCallback() { #ifdef VK_EXT_debug_utils VkDebugUtilsMessengerCreateInfoEXT CreateInfo = {}; CreateInfo.sType = VK_STRUCTURE_TYPE_DEBUG_UTILS_MESSENGER_CREATE_INFO_EXT; CreateInfo.messageSeverity = VK_DEBUG_UTILS_MESSAGE_SEVERITY_VERBOSE_BIT_EXT | VK_DEBUG_UTILS_MESSAGE_SEVERITY_WARNING_BIT_EXT | VK_DEBUG_UTILS_MESSAGE_SEVERITY_ERROR_BIT_EXT; CreateInfo.messageType = VK_DEBUG_UTILS_MESSAGE_TYPE_VALIDATION_BIT_EXT | VK_DEBUG_UTILS_MESSAGE_TYPE_PERFORMANCE_BIT_EXT; // | VK_DEBUG_UTILS_MESSAGE_TYPE_GENERAL_BIT_EXT <- too annoying CreateInfo.pfnUserCallback = VKDebugCallback; if(CreateDebugUtilsMessengerEXT(&CreateInfo, nullptr, &m_DebugMessenger) != VK_SUCCESS) { m_DebugMessenger = VK_NULL_HANDLE; dbg_msg("vulkan", "didn't find vulkan debug layer."); } else { dbg_msg("vulkan", "enabled vulkan debug context."); } #endif } void UnregisterDebugCallback() { #ifdef VK_EXT_debug_utils if(m_DebugMessenger != VK_NULL_HANDLE) DestroyDebugUtilsMessengerEXT(m_DebugMessenger); #endif } bool CreateImageViews() { m_SwapChainImageViewList.resize(m_SwapChainImageCount); for(size_t i = 0; i < m_SwapChainImageCount; i++) { VkImageViewCreateInfo CreateInfo{}; CreateInfo.sType = VK_STRUCTURE_TYPE_IMAGE_VIEW_CREATE_INFO; CreateInfo.image = m_SwapChainImages[i]; CreateInfo.viewType = VK_IMAGE_VIEW_TYPE_2D; CreateInfo.format = m_VKSurfFormat.format; CreateInfo.components.r = VK_COMPONENT_SWIZZLE_IDENTITY; CreateInfo.components.g = VK_COMPONENT_SWIZZLE_IDENTITY; CreateInfo.components.b = VK_COMPONENT_SWIZZLE_IDENTITY; CreateInfo.components.a = VK_COMPONENT_SWIZZLE_IDENTITY; CreateInfo.subresourceRange.aspectMask = VK_IMAGE_ASPECT_COLOR_BIT; CreateInfo.subresourceRange.baseMipLevel = 0; CreateInfo.subresourceRange.levelCount = 1; CreateInfo.subresourceRange.baseArrayLayer = 0; CreateInfo.subresourceRange.layerCount = 1; if(vkCreateImageView(m_VKDevice, &CreateInfo, nullptr, &m_SwapChainImageViewList[i]) != VK_SUCCESS) { SetError("Could not create image views for the swap chain framebuffers."); return false; } } return true; } void DestroyImageViews() { for(auto &ImageView : m_SwapChainImageViewList) { vkDestroyImageView(m_VKDevice, ImageView, nullptr); } m_SwapChainImageViewList.clear(); } bool CreateMultiSamplerImageAttachments() { m_SwapChainMultiSamplingImages.resize(m_SwapChainImageCount); if(HasMultiSampling()) { for(size_t i = 0; i < m_SwapChainImageCount; ++i) { CreateImage(m_VKSwapImgAndViewportExtent.m_SwapImg.width, m_VKSwapImgAndViewportExtent.m_SwapImg.height, 1, 1, m_VKSurfFormat.format, VK_IMAGE_TILING_OPTIMAL, m_SwapChainMultiSamplingImages[i].m_Image, m_SwapChainMultiSamplingImages[i].m_ImgMem, VK_IMAGE_USAGE_TRANSIENT_ATTACHMENT_BIT | VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT); m_SwapChainMultiSamplingImages[i].m_ImgView = CreateImageView(m_SwapChainMultiSamplingImages[i].m_Image, m_VKSurfFormat.format, VK_IMAGE_VIEW_TYPE_2D, 1, 1); } } return true; } void DestroyMultiSamplerImageAttachments() { if(HasMultiSampling()) { m_SwapChainMultiSamplingImages.resize(m_SwapChainImageCount); for(size_t i = 0; i < m_SwapChainImageCount; ++i) { vkDestroyImage(m_VKDevice, m_SwapChainMultiSamplingImages[i].m_Image, nullptr); vkDestroyImageView(m_VKDevice, m_SwapChainMultiSamplingImages[i].m_ImgView, nullptr); FreeImageMemBlock(m_SwapChainMultiSamplingImages[i].m_ImgMem); } } m_SwapChainMultiSamplingImages.clear(); } bool CreateRenderPass(bool ClearAttachs) { bool HasMultiSamplingTargets = HasMultiSampling(); VkAttachmentDescription MultiSamplingColorAttachment{}; MultiSamplingColorAttachment.format = m_VKSurfFormat.format; MultiSamplingColorAttachment.samples = GetSampleCount(); MultiSamplingColorAttachment.loadOp = ClearAttachs ? VK_ATTACHMENT_LOAD_OP_CLEAR : VK_ATTACHMENT_LOAD_OP_DONT_CARE; MultiSamplingColorAttachment.storeOp = VK_ATTACHMENT_STORE_OP_DONT_CARE; MultiSamplingColorAttachment.stencilLoadOp = VK_ATTACHMENT_LOAD_OP_DONT_CARE; MultiSamplingColorAttachment.stencilStoreOp = VK_ATTACHMENT_STORE_OP_DONT_CARE; MultiSamplingColorAttachment.initialLayout = VK_IMAGE_LAYOUT_UNDEFINED; MultiSamplingColorAttachment.finalLayout = VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL; VkAttachmentDescription ColorAttachment{}; ColorAttachment.format = m_VKSurfFormat.format; ColorAttachment.samples = VK_SAMPLE_COUNT_1_BIT; ColorAttachment.loadOp = ClearAttachs && !HasMultiSamplingTargets ? VK_ATTACHMENT_LOAD_OP_CLEAR : VK_ATTACHMENT_LOAD_OP_DONT_CARE; ColorAttachment.storeOp = VK_ATTACHMENT_STORE_OP_STORE; ColorAttachment.stencilLoadOp = VK_ATTACHMENT_LOAD_OP_DONT_CARE; ColorAttachment.stencilStoreOp = VK_ATTACHMENT_STORE_OP_DONT_CARE; ColorAttachment.initialLayout = VK_IMAGE_LAYOUT_UNDEFINED; ColorAttachment.finalLayout = VK_IMAGE_LAYOUT_PRESENT_SRC_KHR; VkAttachmentReference MultiSamplingColorAttachmentRef{}; MultiSamplingColorAttachmentRef.attachment = 0; MultiSamplingColorAttachmentRef.layout = VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL; VkAttachmentReference ColorAttachmentRef{}; ColorAttachmentRef.attachment = HasMultiSamplingTargets ? 1 : 0; ColorAttachmentRef.layout = VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL; VkSubpassDescription Subpass{}; Subpass.pipelineBindPoint = VK_PIPELINE_BIND_POINT_GRAPHICS; Subpass.colorAttachmentCount = 1; Subpass.pColorAttachments = HasMultiSamplingTargets ? &MultiSamplingColorAttachmentRef : &ColorAttachmentRef; Subpass.pResolveAttachments = HasMultiSamplingTargets ? &ColorAttachmentRef : nullptr; std::array aAttachments; aAttachments[0] = MultiSamplingColorAttachment; aAttachments[1] = ColorAttachment; VkSubpassDependency Dependency{}; Dependency.srcSubpass = VK_SUBPASS_EXTERNAL; Dependency.dstSubpass = 0; Dependency.srcStageMask = VK_PIPELINE_STAGE_COLOR_ATTACHMENT_OUTPUT_BIT; Dependency.srcAccessMask = 0; Dependency.dstStageMask = VK_PIPELINE_STAGE_COLOR_ATTACHMENT_OUTPUT_BIT; Dependency.dstAccessMask = VK_ACCESS_COLOR_ATTACHMENT_WRITE_BIT; VkRenderPassCreateInfo CreateRenderPassInfo{}; CreateRenderPassInfo.sType = VK_STRUCTURE_TYPE_RENDER_PASS_CREATE_INFO; CreateRenderPassInfo.attachmentCount = HasMultiSamplingTargets ? 2 : 1; CreateRenderPassInfo.pAttachments = HasMultiSamplingTargets ? aAttachments.data() : aAttachments.data() + 1; CreateRenderPassInfo.subpassCount = 1; CreateRenderPassInfo.pSubpasses = &Subpass; CreateRenderPassInfo.dependencyCount = 1; CreateRenderPassInfo.pDependencies = &Dependency; if(vkCreateRenderPass(m_VKDevice, &CreateRenderPassInfo, nullptr, &m_VKRenderPass) != VK_SUCCESS) { SetError("Creating the render pass failed."); return false; } return true; } void DestroyRenderPass() { vkDestroyRenderPass(m_VKDevice, m_VKRenderPass, nullptr); } bool CreateFramebuffers() { m_FramebufferList.resize(m_SwapChainImageCount); for(size_t i = 0; i < m_SwapChainImageCount; i++) { std::array aAttachments = { m_SwapChainMultiSamplingImages[i].m_ImgView, m_SwapChainImageViewList[i]}; bool HasMultiSamplingTargets = HasMultiSampling(); VkFramebufferCreateInfo FramebufferInfo{}; FramebufferInfo.sType = VK_STRUCTURE_TYPE_FRAMEBUFFER_CREATE_INFO; FramebufferInfo.renderPass = m_VKRenderPass; FramebufferInfo.attachmentCount = HasMultiSamplingTargets ? aAttachments.size() : aAttachments.size() - 1; FramebufferInfo.pAttachments = HasMultiSamplingTargets ? aAttachments.data() : aAttachments.data() + 1; FramebufferInfo.width = m_VKSwapImgAndViewportExtent.m_SwapImg.width; FramebufferInfo.height = m_VKSwapImgAndViewportExtent.m_SwapImg.height; FramebufferInfo.layers = 1; if(vkCreateFramebuffer(m_VKDevice, &FramebufferInfo, nullptr, &m_FramebufferList[i]) != VK_SUCCESS) { SetError("Creating the framebuffers failed."); return false; } } return true; } void DestroyFramebuffers() { for(auto &FrameBuffer : m_FramebufferList) { vkDestroyFramebuffer(m_VKDevice, FrameBuffer, nullptr); } m_FramebufferList.clear(); } bool CreateShaderModule(const std::vector &Code, VkShaderModule &ShaderModule) { VkShaderModuleCreateInfo CreateInfo{}; CreateInfo.sType = VK_STRUCTURE_TYPE_SHADER_MODULE_CREATE_INFO; CreateInfo.codeSize = Code.size(); CreateInfo.pCode = (const uint32_t *)(Code.data()); if(vkCreateShaderModule(m_VKDevice, &CreateInfo, nullptr, &ShaderModule) != VK_SUCCESS) { SetError("Shader module was not created."); return false; } return true; } bool CreateDescriptorSetLayouts() { VkDescriptorSetLayoutBinding SamplerLayoutBinding{}; SamplerLayoutBinding.binding = 0; SamplerLayoutBinding.descriptorCount = 1; SamplerLayoutBinding.descriptorType = VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER; SamplerLayoutBinding.pImmutableSamplers = nullptr; SamplerLayoutBinding.stageFlags = VK_SHADER_STAGE_FRAGMENT_BIT; std::array aBindings = {SamplerLayoutBinding}; VkDescriptorSetLayoutCreateInfo LayoutInfo{}; LayoutInfo.sType = VK_STRUCTURE_TYPE_DESCRIPTOR_SET_LAYOUT_CREATE_INFO; LayoutInfo.bindingCount = aBindings.size(); LayoutInfo.pBindings = aBindings.data(); if(vkCreateDescriptorSetLayout(m_VKDevice, &LayoutInfo, nullptr, &m_StandardTexturedDescriptorSetLayout) != VK_SUCCESS) { SetError("Creating descriptor layout failed."); return false; } if(vkCreateDescriptorSetLayout(m_VKDevice, &LayoutInfo, nullptr, &m_Standard3DTexturedDescriptorSetLayout) != VK_SUCCESS) { SetError("Creating descriptor layout failed."); return false; } return true; } void DestroyDescriptorSetLayouts() { vkDestroyDescriptorSetLayout(m_VKDevice, m_StandardTexturedDescriptorSetLayout, nullptr); vkDestroyDescriptorSetLayout(m_VKDevice, m_Standard3DTexturedDescriptorSetLayout, nullptr); } bool LoadShader(const char *pFileName, std::vector *&pShaderData) { auto it = m_ShaderFiles.find(pFileName); if(it == m_ShaderFiles.end()) { auto *pShaderCodeFile = m_pStorage->OpenFile(pFileName, IOFLAG_READ, IStorage::TYPE_ALL); std::vector ShaderBuff; if(pShaderCodeFile) { long FileSize = io_length(pShaderCodeFile); ShaderBuff.resize(FileSize); io_read(pShaderCodeFile, ShaderBuff.data(), FileSize); io_close(pShaderCodeFile); } else return false; it = m_ShaderFiles.insert({pFileName, {std::move(ShaderBuff)}}).first; } pShaderData = &it->second.m_Binary; return true; } bool CreateShaders(const char *pVertName, const char *pFragName, VkPipelineShaderStageCreateInfo (&aShaderStages)[2], SShaderModule &ShaderModule) { bool ShaderLoaded = true; std::vector *pVertBuff; std::vector *pFragBuff; ShaderLoaded &= LoadShader(pVertName, pVertBuff); ShaderLoaded &= LoadShader(pFragName, pFragBuff); ShaderModule.m_VKDevice = m_VKDevice; if(!ShaderLoaded) { SetError("A shader file could not load correctly"); return false; } if(!CreateShaderModule(*pVertBuff, ShaderModule.m_VertShaderModule)) return false; if(!CreateShaderModule(*pFragBuff, ShaderModule.m_FragShaderModule)) return false; VkPipelineShaderStageCreateInfo &VertShaderStageInfo = aShaderStages[0]; VertShaderStageInfo = {}; VertShaderStageInfo.sType = VK_STRUCTURE_TYPE_PIPELINE_SHADER_STAGE_CREATE_INFO; VertShaderStageInfo.stage = VK_SHADER_STAGE_VERTEX_BIT; VertShaderStageInfo.module = ShaderModule.m_VertShaderModule; VertShaderStageInfo.pName = "main"; VkPipelineShaderStageCreateInfo &FragShaderStageInfo = aShaderStages[1]; FragShaderStageInfo = {}; FragShaderStageInfo.sType = VK_STRUCTURE_TYPE_PIPELINE_SHADER_STAGE_CREATE_INFO; FragShaderStageInfo.stage = VK_SHADER_STAGE_FRAGMENT_BIT; FragShaderStageInfo.module = ShaderModule.m_FragShaderModule; FragShaderStageInfo.pName = "main"; return true; } bool GetStandardPipelineInfo(VkPipelineInputAssemblyStateCreateInfo &InputAssembly, VkViewport &Viewport, VkRect2D &Scissor, VkPipelineViewportStateCreateInfo &ViewportState, VkPipelineRasterizationStateCreateInfo &Rasterizer, VkPipelineMultisampleStateCreateInfo &Multisampling, VkPipelineColorBlendAttachmentState &ColorBlendAttachment, VkPipelineColorBlendStateCreateInfo &ColorBlending) { InputAssembly.sType = VK_STRUCTURE_TYPE_PIPELINE_INPUT_ASSEMBLY_STATE_CREATE_INFO; InputAssembly.topology = VK_PRIMITIVE_TOPOLOGY_TRIANGLE_LIST; InputAssembly.primitiveRestartEnable = VK_FALSE; Viewport.x = 0.0f; Viewport.y = 0.0f; Viewport.width = (float)m_VKSwapImgAndViewportExtent.m_Viewport.width; Viewport.height = (float)m_VKSwapImgAndViewportExtent.m_Viewport.height; Viewport.minDepth = 0.0f; Viewport.maxDepth = 1.0f; Scissor.offset = {0, 0}; Scissor.extent = m_VKSwapImgAndViewportExtent.m_Viewport; ViewportState.sType = VK_STRUCTURE_TYPE_PIPELINE_VIEWPORT_STATE_CREATE_INFO; ViewportState.viewportCount = 1; ViewportState.pViewports = &Viewport; ViewportState.scissorCount = 1; ViewportState.pScissors = &Scissor; Rasterizer.sType = VK_STRUCTURE_TYPE_PIPELINE_RASTERIZATION_STATE_CREATE_INFO; Rasterizer.depthClampEnable = VK_FALSE; Rasterizer.rasterizerDiscardEnable = VK_FALSE; Rasterizer.polygonMode = VK_POLYGON_MODE_FILL; Rasterizer.lineWidth = 1.0f; Rasterizer.cullMode = VK_CULL_MODE_NONE; Rasterizer.frontFace = VK_FRONT_FACE_CLOCKWISE; Rasterizer.depthBiasEnable = VK_FALSE; Multisampling.sType = VK_STRUCTURE_TYPE_PIPELINE_MULTISAMPLE_STATE_CREATE_INFO; Multisampling.sampleShadingEnable = VK_FALSE; Multisampling.rasterizationSamples = GetSampleCount(); ColorBlendAttachment.colorWriteMask = VK_COLOR_COMPONENT_R_BIT | VK_COLOR_COMPONENT_G_BIT | VK_COLOR_COMPONENT_B_BIT | VK_COLOR_COMPONENT_A_BIT; ColorBlendAttachment.blendEnable = VK_TRUE; ColorBlendAttachment.srcColorBlendFactor = VK_BLEND_FACTOR_SRC_ALPHA; ColorBlendAttachment.dstColorBlendFactor = VK_BLEND_FACTOR_ONE_MINUS_SRC_ALPHA; ColorBlendAttachment.colorBlendOp = VK_BLEND_OP_ADD; ColorBlendAttachment.srcAlphaBlendFactor = VK_BLEND_FACTOR_SRC_ALPHA; ColorBlendAttachment.dstAlphaBlendFactor = VK_BLEND_FACTOR_ONE_MINUS_SRC_ALPHA; ColorBlendAttachment.alphaBlendOp = VK_BLEND_OP_ADD; ColorBlending.sType = VK_STRUCTURE_TYPE_PIPELINE_COLOR_BLEND_STATE_CREATE_INFO; ColorBlending.logicOpEnable = VK_FALSE; ColorBlending.logicOp = VK_LOGIC_OP_COPY; ColorBlending.attachmentCount = 1; ColorBlending.pAttachments = &ColorBlendAttachment; ColorBlending.blendConstants[0] = 0.0f; ColorBlending.blendConstants[1] = 0.0f; ColorBlending.blendConstants[2] = 0.0f; ColorBlending.blendConstants[3] = 0.0f; return true; } template bool CreateGraphicsPipeline(const char *pVertName, const char *pFragName, SPipelineContainer &PipeContainer, uint32_t Stride, std::array &aInputAttr, std::array &aSetLayouts, std::array &aPushConstants, EVulkanBackendTextureModes TexMode, EVulkanBackendBlendModes BlendMode, EVulkanBackendClipModes DynamicMode, bool IsLinePrim = false) { VkPipelineShaderStageCreateInfo aShaderStages[2]; SShaderModule Module; if(!CreateShaders(pVertName, pFragName, aShaderStages, Module)) return false; bool HasSampler = TexMode == VULKAN_BACKEND_TEXTURE_MODE_TEXTURED; VkPipelineVertexInputStateCreateInfo VertexInputInfo{}; VertexInputInfo.sType = VK_STRUCTURE_TYPE_PIPELINE_VERTEX_INPUT_STATE_CREATE_INFO; VkVertexInputBindingDescription BindingDescription{}; BindingDescription.binding = 0; BindingDescription.stride = Stride; BindingDescription.inputRate = VK_VERTEX_INPUT_RATE_VERTEX; VertexInputInfo.vertexBindingDescriptionCount = 1; VertexInputInfo.vertexAttributeDescriptionCount = aInputAttr.size(); VertexInputInfo.pVertexBindingDescriptions = &BindingDescription; VertexInputInfo.pVertexAttributeDescriptions = aInputAttr.data(); VkPipelineInputAssemblyStateCreateInfo InputAssembly{}; VkViewport Viewport{}; VkRect2D Scissor{}; VkPipelineViewportStateCreateInfo ViewportState{}; VkPipelineRasterizationStateCreateInfo Rasterizer{}; VkPipelineMultisampleStateCreateInfo Multisampling{}; VkPipelineColorBlendAttachmentState ColorBlendAttachment{}; VkPipelineColorBlendStateCreateInfo ColorBlending{}; GetStandardPipelineInfo(InputAssembly, Viewport, Scissor, ViewportState, Rasterizer, Multisampling, ColorBlendAttachment, ColorBlending); InputAssembly.topology = IsLinePrim ? VK_PRIMITIVE_TOPOLOGY_LINE_LIST : VK_PRIMITIVE_TOPOLOGY_TRIANGLE_LIST; VkPipelineLayoutCreateInfo PipelineLayoutInfo{}; PipelineLayoutInfo.sType = VK_STRUCTURE_TYPE_PIPELINE_LAYOUT_CREATE_INFO; PipelineLayoutInfo.setLayoutCount = (HasSampler || ForceRequireDescriptors) ? aSetLayouts.size() : 0; PipelineLayoutInfo.pSetLayouts = (HasSampler || ForceRequireDescriptors) && !aSetLayouts.empty() ? aSetLayouts.data() : nullptr; PipelineLayoutInfo.pushConstantRangeCount = aPushConstants.size(); PipelineLayoutInfo.pPushConstantRanges = !aPushConstants.empty() ? aPushConstants.data() : nullptr; VkPipelineLayout &PipeLayout = GetPipeLayout(PipeContainer, HasSampler, size_t(BlendMode), size_t(DynamicMode)); VkPipeline &Pipeline = GetPipeline(PipeContainer, HasSampler, size_t(BlendMode), size_t(DynamicMode)); if(vkCreatePipelineLayout(m_VKDevice, &PipelineLayoutInfo, nullptr, &PipeLayout) != VK_SUCCESS) { SetError("Creating pipeline layout failed."); return false; } VkGraphicsPipelineCreateInfo PipelineInfo{}; PipelineInfo.sType = VK_STRUCTURE_TYPE_GRAPHICS_PIPELINE_CREATE_INFO; PipelineInfo.stageCount = 2; PipelineInfo.pStages = aShaderStages; PipelineInfo.pVertexInputState = &VertexInputInfo; PipelineInfo.pInputAssemblyState = &InputAssembly; PipelineInfo.pViewportState = &ViewportState; PipelineInfo.pRasterizationState = &Rasterizer; PipelineInfo.pMultisampleState = &Multisampling; PipelineInfo.pColorBlendState = &ColorBlending; PipelineInfo.layout = PipeLayout; PipelineInfo.renderPass = m_VKRenderPass; PipelineInfo.subpass = 0; PipelineInfo.basePipelineHandle = VK_NULL_HANDLE; std::array aDynamicStates = { VK_DYNAMIC_STATE_VIEWPORT, VK_DYNAMIC_STATE_SCISSOR, }; VkPipelineDynamicStateCreateInfo DynamicStateCreate{}; DynamicStateCreate.sType = VK_STRUCTURE_TYPE_PIPELINE_DYNAMIC_STATE_CREATE_INFO; DynamicStateCreate.dynamicStateCount = aDynamicStates.size(); DynamicStateCreate.pDynamicStates = aDynamicStates.data(); if(DynamicMode == VULKAN_BACKEND_CLIP_MODE_DYNAMIC_SCISSOR_AND_VIEWPORT) { PipelineInfo.pDynamicState = &DynamicStateCreate; } if(vkCreateGraphicsPipelines(m_VKDevice, VK_NULL_HANDLE, 1, &PipelineInfo, nullptr, &Pipeline) != VK_SUCCESS) { SetError("Creating the graphic pipeline failed."); return false; } return true; } bool CreateStandardGraphicsPipelineImpl(const char *pVertName, const char *pFragName, SPipelineContainer &PipeContainer, EVulkanBackendTextureModes TexMode, EVulkanBackendBlendModes BlendMode, EVulkanBackendClipModes DynamicMode, bool IsLinePrim) { std::array aAttributeDescriptions = {}; aAttributeDescriptions[0] = {0, 0, VK_FORMAT_R32G32_SFLOAT, 0}; aAttributeDescriptions[1] = {1, 0, VK_FORMAT_R32G32_SFLOAT, sizeof(float) * 2}; aAttributeDescriptions[2] = {2, 0, VK_FORMAT_R8G8B8A8_UNORM, sizeof(float) * (2 + 2)}; std::array aSetLayouts = {m_StandardTexturedDescriptorSetLayout}; std::array aPushConstants{}; aPushConstants[0] = {VK_SHADER_STAGE_VERTEX_BIT, 0, sizeof(SUniformGPos)}; return CreateGraphicsPipeline(pVertName, pFragName, PipeContainer, sizeof(float) * (2 + 2) + sizeof(uint8_t) * 4, aAttributeDescriptions, aSetLayouts, aPushConstants, TexMode, BlendMode, DynamicMode, IsLinePrim); } bool CreateStandardGraphicsPipeline(const char *pVertName, const char *pFragName, bool HasSampler, bool IsLinePipe) { bool Ret = true; EVulkanBackendTextureModes TexMode = HasSampler ? VULKAN_BACKEND_TEXTURE_MODE_TEXTURED : VULKAN_BACKEND_TEXTURE_MODE_NOT_TEXTURED; for(size_t i = 0; i < VULKAN_BACKEND_BLEND_MODE_COUNT; ++i) { for(size_t j = 0; j < VULKAN_BACKEND_CLIP_MODE_COUNT; ++j) { Ret &= CreateStandardGraphicsPipelineImpl(pVertName, pFragName, IsLinePipe ? m_StandardLinePipeline : m_StandardPipeline, TexMode, EVulkanBackendBlendModes(i), EVulkanBackendClipModes(j), IsLinePipe); } } return Ret; } bool CreateStandard3DGraphicsPipelineImpl(const char *pVertName, const char *pFragName, SPipelineContainer &PipeContainer, EVulkanBackendTextureModes TexMode, EVulkanBackendBlendModes BlendMode, EVulkanBackendClipModes DynamicMode) { std::array aAttributeDescriptions = {}; aAttributeDescriptions[0] = {0, 0, VK_FORMAT_R32G32_SFLOAT, 0}; aAttributeDescriptions[1] = {1, 0, VK_FORMAT_R8G8B8A8_UNORM, sizeof(float) * 2}; aAttributeDescriptions[2] = {2, 0, VK_FORMAT_R32G32B32_SFLOAT, sizeof(float) * 2 + sizeof(uint8_t) * 4}; std::array aSetLayouts = {m_Standard3DTexturedDescriptorSetLayout}; std::array aPushConstants{}; aPushConstants[0] = {VK_SHADER_STAGE_VERTEX_BIT, 0, sizeof(SUniformGPos)}; return CreateGraphicsPipeline(pVertName, pFragName, PipeContainer, sizeof(float) * 2 + sizeof(uint8_t) * 4 + sizeof(float) * 3, aAttributeDescriptions, aSetLayouts, aPushConstants, TexMode, BlendMode, DynamicMode); } bool CreateStandard3DGraphicsPipeline(const char *pVertName, const char *pFragName, bool HasSampler) { bool Ret = true; EVulkanBackendTextureModes TexMode = HasSampler ? VULKAN_BACKEND_TEXTURE_MODE_TEXTURED : VULKAN_BACKEND_TEXTURE_MODE_NOT_TEXTURED; for(size_t i = 0; i < VULKAN_BACKEND_BLEND_MODE_COUNT; ++i) { for(size_t j = 0; j < VULKAN_BACKEND_CLIP_MODE_COUNT; ++j) { Ret &= CreateStandard3DGraphicsPipelineImpl(pVertName, pFragName, m_Standard3DPipeline, TexMode, EVulkanBackendBlendModes(i), EVulkanBackendClipModes(j)); } } return Ret; } bool CreateTextDescriptorSetLayout() { VkDescriptorSetLayoutBinding SamplerLayoutBinding{}; SamplerLayoutBinding.binding = 0; SamplerLayoutBinding.descriptorCount = 1; SamplerLayoutBinding.descriptorType = VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER; SamplerLayoutBinding.pImmutableSamplers = nullptr; SamplerLayoutBinding.stageFlags = VK_SHADER_STAGE_FRAGMENT_BIT; auto SamplerLayoutBinding2 = SamplerLayoutBinding; SamplerLayoutBinding2.binding = 1; std::array aBindings = {SamplerLayoutBinding, SamplerLayoutBinding2}; VkDescriptorSetLayoutCreateInfo LayoutInfo{}; LayoutInfo.sType = VK_STRUCTURE_TYPE_DESCRIPTOR_SET_LAYOUT_CREATE_INFO; LayoutInfo.bindingCount = aBindings.size(); LayoutInfo.pBindings = aBindings.data(); if(vkCreateDescriptorSetLayout(m_VKDevice, &LayoutInfo, nullptr, &m_TextDescriptorSetLayout) != VK_SUCCESS) { SetError("Creating descriptor layout failed."); return false; } return true; } void DestroyTextDescriptorSetLayout() { vkDestroyDescriptorSetLayout(m_VKDevice, m_TextDescriptorSetLayout, nullptr); } bool CreateTextGraphicsPipelineImpl(const char *pVertName, const char *pFragName, SPipelineContainer &PipeContainer, EVulkanBackendTextureModes TexMode, EVulkanBackendBlendModes BlendMode, EVulkanBackendClipModes DynamicMode) { std::array aAttributeDescriptions = {}; aAttributeDescriptions[0] = {0, 0, VK_FORMAT_R32G32_SFLOAT, 0}; aAttributeDescriptions[1] = {1, 0, VK_FORMAT_R32G32_SFLOAT, sizeof(float) * 2}; aAttributeDescriptions[2] = {2, 0, VK_FORMAT_R8G8B8A8_UNORM, sizeof(float) * (2 + 2)}; std::array aSetLayouts = {m_TextDescriptorSetLayout}; std::array aPushConstants{}; aPushConstants[0] = {VK_SHADER_STAGE_VERTEX_BIT, 0, sizeof(SUniformGTextPos)}; aPushConstants[1] = {VK_SHADER_STAGE_FRAGMENT_BIT, sizeof(SUniformGTextPos) + sizeof(SUniformTextGFragmentOffset), sizeof(SUniformTextGFragmentConstants)}; return CreateGraphicsPipeline(pVertName, pFragName, PipeContainer, sizeof(float) * (2 + 2) + sizeof(uint8_t) * 4, aAttributeDescriptions, aSetLayouts, aPushConstants, TexMode, BlendMode, DynamicMode); } bool CreateTextGraphicsPipeline(const char *pVertName, const char *pFragName) { bool Ret = true; EVulkanBackendTextureModes TexMode = VULKAN_BACKEND_TEXTURE_MODE_TEXTURED; for(size_t i = 0; i < VULKAN_BACKEND_BLEND_MODE_COUNT; ++i) { for(size_t j = 0; j < VULKAN_BACKEND_CLIP_MODE_COUNT; ++j) { Ret &= CreateTextGraphicsPipelineImpl(pVertName, pFragName, m_TextPipeline, TexMode, EVulkanBackendBlendModes(i), EVulkanBackendClipModes(j)); } } return Ret; } template bool CreateTileGraphicsPipelineImpl(const char *pVertName, const char *pFragName, int Type, SPipelineContainer &PipeContainer, EVulkanBackendTextureModes TexMode, EVulkanBackendBlendModes BlendMode, EVulkanBackendClipModes DynamicMode) { std::array aAttributeDescriptions = {}; aAttributeDescriptions[0] = {0, 0, VK_FORMAT_R32G32_SFLOAT, 0}; if(HasSampler) aAttributeDescriptions[1] = {1, 0, VK_FORMAT_R32G32B32_SFLOAT, sizeof(float) * 2}; std::array aSetLayouts; aSetLayouts[0] = m_Standard3DTexturedDescriptorSetLayout; uint32_t VertPushConstantSize = sizeof(SUniformTileGPos); if(Type == 1) VertPushConstantSize = sizeof(SUniformTileGPosBorder); else if(Type == 2) VertPushConstantSize = sizeof(SUniformTileGPosBorderLine); uint32_t FragPushConstantSize = sizeof(SUniformTileGVertColor); std::array aPushConstants{}; aPushConstants[0] = {VK_SHADER_STAGE_VERTEX_BIT, 0, VertPushConstantSize}; aPushConstants[1] = {VK_SHADER_STAGE_FRAGMENT_BIT, sizeof(SUniformTileGPosBorder) + sizeof(SUniformTileGVertColorAlign), FragPushConstantSize}; return CreateGraphicsPipeline(pVertName, pFragName, PipeContainer, HasSampler ? (sizeof(float) * (2 + 3)) : (sizeof(float) * 2), aAttributeDescriptions, aSetLayouts, aPushConstants, TexMode, BlendMode, DynamicMode); } template bool CreateTileGraphicsPipeline(const char *pVertName, const char *pFragName, int Type) { bool Ret = true; EVulkanBackendTextureModes TexMode = HasSampler ? VULKAN_BACKEND_TEXTURE_MODE_TEXTURED : VULKAN_BACKEND_TEXTURE_MODE_NOT_TEXTURED; for(size_t i = 0; i < VULKAN_BACKEND_BLEND_MODE_COUNT; ++i) { for(size_t j = 0; j < VULKAN_BACKEND_CLIP_MODE_COUNT; ++j) { Ret &= CreateTileGraphicsPipelineImpl(pVertName, pFragName, Type, Type == 0 ? m_TilePipeline : (Type == 1 ? m_TileBorderPipeline : m_TileBorderLinePipeline), TexMode, EVulkanBackendBlendModes(i), EVulkanBackendClipModes(j)); } } return Ret; } bool CreatePrimExGraphicsPipelineImpl(const char *pVertName, const char *pFragName, bool Rotationless, SPipelineContainer &PipeContainer, EVulkanBackendTextureModes TexMode, EVulkanBackendBlendModes BlendMode, EVulkanBackendClipModes DynamicMode) { std::array aAttributeDescriptions = {}; aAttributeDescriptions[0] = {0, 0, VK_FORMAT_R32G32_SFLOAT, 0}; aAttributeDescriptions[1] = {1, 0, VK_FORMAT_R32G32_SFLOAT, sizeof(float) * 2}; aAttributeDescriptions[2] = {2, 0, VK_FORMAT_R8G8B8A8_UNORM, sizeof(float) * (2 + 2)}; std::array aSetLayouts; aSetLayouts[0] = m_StandardTexturedDescriptorSetLayout; uint32_t VertPushConstantSize = sizeof(SUniformPrimExGPos); if(Rotationless) VertPushConstantSize = sizeof(SUniformPrimExGPosRotationless); uint32_t FragPushConstantSize = sizeof(SUniformPrimExGVertColor); std::array aPushConstants{}; aPushConstants[0] = {VK_SHADER_STAGE_VERTEX_BIT, 0, VertPushConstantSize}; aPushConstants[1] = {VK_SHADER_STAGE_FRAGMENT_BIT, sizeof(SUniformPrimExGPos) + sizeof(SUniformPrimExGVertColorAlign), FragPushConstantSize}; return CreateGraphicsPipeline(pVertName, pFragName, PipeContainer, sizeof(float) * (2 + 2) + sizeof(uint8_t) * 4, aAttributeDescriptions, aSetLayouts, aPushConstants, TexMode, BlendMode, DynamicMode); } bool CreatePrimExGraphicsPipeline(const char *pVertName, const char *pFragName, bool HasSampler, bool Rotationless) { bool Ret = true; EVulkanBackendTextureModes TexMode = HasSampler ? VULKAN_BACKEND_TEXTURE_MODE_TEXTURED : VULKAN_BACKEND_TEXTURE_MODE_NOT_TEXTURED; for(size_t i = 0; i < VULKAN_BACKEND_BLEND_MODE_COUNT; ++i) { for(size_t j = 0; j < VULKAN_BACKEND_CLIP_MODE_COUNT; ++j) { Ret &= CreatePrimExGraphicsPipelineImpl(pVertName, pFragName, Rotationless, Rotationless ? m_PrimExRotationlessPipeline : m_PrimExPipeline, TexMode, EVulkanBackendBlendModes(i), EVulkanBackendClipModes(j)); } } return Ret; } bool CreateUniformDescriptorSetLayout(VkDescriptorSetLayout &SetLayout, VkShaderStageFlags StageFlags) { VkDescriptorSetLayoutBinding SamplerLayoutBinding{}; SamplerLayoutBinding.binding = 1; SamplerLayoutBinding.descriptorCount = 1; SamplerLayoutBinding.descriptorType = VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER; SamplerLayoutBinding.pImmutableSamplers = nullptr; SamplerLayoutBinding.stageFlags = StageFlags; std::array aBindings = {SamplerLayoutBinding}; VkDescriptorSetLayoutCreateInfo LayoutInfo{}; LayoutInfo.sType = VK_STRUCTURE_TYPE_DESCRIPTOR_SET_LAYOUT_CREATE_INFO; LayoutInfo.bindingCount = aBindings.size(); LayoutInfo.pBindings = aBindings.data(); if(vkCreateDescriptorSetLayout(m_VKDevice, &LayoutInfo, nullptr, &SetLayout) != VK_SUCCESS) { SetError("Creating descriptor layout failed."); return false; } return true; } bool CreateSpriteMultiUniformDescriptorSetLayout() { return CreateUniformDescriptorSetLayout(m_SpriteMultiUniformDescriptorSetLayout, VK_SHADER_STAGE_VERTEX_BIT); } bool CreateQuadUniformDescriptorSetLayout() { return CreateUniformDescriptorSetLayout(m_QuadUniformDescriptorSetLayout, VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT); } void DestroyUniformDescriptorSetLayouts() { vkDestroyDescriptorSetLayout(m_VKDevice, m_QuadUniformDescriptorSetLayout, nullptr); vkDestroyDescriptorSetLayout(m_VKDevice, m_SpriteMultiUniformDescriptorSetLayout, nullptr); } bool CreateUniformDescriptorSets(size_t RenderThreadIndex, VkDescriptorSetLayout &SetLayout, SDeviceDescriptorSet *pSets, size_t SetCount, VkBuffer BindBuffer, size_t SingleBufferInstanceSize, VkDeviceSize MemoryOffset) { GetDescriptorPoolForAlloc(m_UniformBufferDescrPools[RenderThreadIndex], pSets, SetCount); VkDescriptorSetAllocateInfo DesAllocInfo{}; DesAllocInfo.sType = VK_STRUCTURE_TYPE_DESCRIPTOR_SET_ALLOCATE_INFO; DesAllocInfo.descriptorSetCount = 1; DesAllocInfo.pSetLayouts = &SetLayout; for(size_t i = 0; i < SetCount; ++i) { DesAllocInfo.descriptorPool = pSets[i].m_pPools->m_Pools[pSets[i].m_PoolIndex].m_Pool; if(vkAllocateDescriptorSets(m_VKDevice, &DesAllocInfo, &pSets[i].m_Descriptor) != VK_SUCCESS) { return false; } VkDescriptorBufferInfo BufferInfo{}; BufferInfo.buffer = BindBuffer; BufferInfo.offset = MemoryOffset + SingleBufferInstanceSize * i; BufferInfo.range = SingleBufferInstanceSize; std::array aDescriptorWrites{}; aDescriptorWrites[0].sType = VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET; aDescriptorWrites[0].dstSet = pSets[i].m_Descriptor; aDescriptorWrites[0].dstBinding = 1; aDescriptorWrites[0].dstArrayElement = 0; aDescriptorWrites[0].descriptorType = VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER; aDescriptorWrites[0].descriptorCount = 1; aDescriptorWrites[0].pBufferInfo = &BufferInfo; vkUpdateDescriptorSets(m_VKDevice, static_cast(aDescriptorWrites.size()), aDescriptorWrites.data(), 0, nullptr); } return true; } void DestroyUniformDescriptorSets(SDeviceDescriptorSet *pSets, size_t SetCount) { for(size_t i = 0; i < SetCount; ++i) { vkFreeDescriptorSets(m_VKDevice, pSets[i].m_pPools->m_Pools[pSets[i].m_PoolIndex].m_Pool, 1, &pSets[i].m_Descriptor); pSets[i].m_Descriptor = VK_NULL_HANDLE; } } bool CreateSpriteMultiGraphicsPipelineImpl(const char *pVertName, const char *pFragName, SPipelineContainer &PipeContainer, EVulkanBackendTextureModes TexMode, EVulkanBackendBlendModes BlendMode, EVulkanBackendClipModes DynamicMode) { std::array aAttributeDescriptions = {}; aAttributeDescriptions[0] = {0, 0, VK_FORMAT_R32G32_SFLOAT, 0}; aAttributeDescriptions[1] = {1, 0, VK_FORMAT_R32G32_SFLOAT, sizeof(float) * 2}; aAttributeDescriptions[2] = {2, 0, VK_FORMAT_R8G8B8A8_UNORM, sizeof(float) * (2 + 2)}; std::array aSetLayouts; aSetLayouts[0] = m_StandardTexturedDescriptorSetLayout; aSetLayouts[1] = m_SpriteMultiUniformDescriptorSetLayout; uint32_t VertPushConstantSize = sizeof(SUniformSpriteMultiGPos); uint32_t FragPushConstantSize = sizeof(SUniformSpriteMultiGVertColor); std::array aPushConstants{}; aPushConstants[0] = {VK_SHADER_STAGE_VERTEX_BIT, 0, VertPushConstantSize}; aPushConstants[1] = {VK_SHADER_STAGE_FRAGMENT_BIT, sizeof(SUniformSpriteMultiGPos) + sizeof(SUniformSpriteMultiGVertColorAlign), FragPushConstantSize}; return CreateGraphicsPipeline(pVertName, pFragName, PipeContainer, sizeof(float) * (2 + 2) + sizeof(uint8_t) * 4, aAttributeDescriptions, aSetLayouts, aPushConstants, TexMode, BlendMode, DynamicMode); } bool CreateSpriteMultiGraphicsPipeline(const char *pVertName, const char *pFragName) { bool Ret = true; EVulkanBackendTextureModes TexMode = VULKAN_BACKEND_TEXTURE_MODE_TEXTURED; for(size_t i = 0; i < VULKAN_BACKEND_BLEND_MODE_COUNT; ++i) { for(size_t j = 0; j < VULKAN_BACKEND_CLIP_MODE_COUNT; ++j) { Ret &= CreateSpriteMultiGraphicsPipelineImpl(pVertName, pFragName, m_SpriteMultiPipeline, TexMode, EVulkanBackendBlendModes(i), EVulkanBackendClipModes(j)); } } return Ret; } bool CreateSpriteMultiPushGraphicsPipelineImpl(const char *pVertName, const char *pFragName, SPipelineContainer &PipeContainer, EVulkanBackendTextureModes TexMode, EVulkanBackendBlendModes BlendMode, EVulkanBackendClipModes DynamicMode) { std::array aAttributeDescriptions = {}; aAttributeDescriptions[0] = {0, 0, VK_FORMAT_R32G32_SFLOAT, 0}; aAttributeDescriptions[1] = {1, 0, VK_FORMAT_R32G32_SFLOAT, sizeof(float) * 2}; aAttributeDescriptions[2] = {2, 0, VK_FORMAT_R8G8B8A8_UNORM, sizeof(float) * (2 + 2)}; std::array aSetLayouts; aSetLayouts[0] = m_StandardTexturedDescriptorSetLayout; uint32_t VertPushConstantSize = sizeof(SUniformSpriteMultiPushGPos); uint32_t FragPushConstantSize = sizeof(SUniformSpriteMultiPushGVertColor); std::array aPushConstants{}; aPushConstants[0] = {VK_SHADER_STAGE_VERTEX_BIT, 0, VertPushConstantSize}; aPushConstants[1] = {VK_SHADER_STAGE_FRAGMENT_BIT, sizeof(SUniformSpriteMultiPushGPos), FragPushConstantSize}; return CreateGraphicsPipeline(pVertName, pFragName, PipeContainer, sizeof(float) * (2 + 2) + sizeof(uint8_t) * 4, aAttributeDescriptions, aSetLayouts, aPushConstants, TexMode, BlendMode, DynamicMode); } bool CreateSpriteMultiPushGraphicsPipeline(const char *pVertName, const char *pFragName) { bool Ret = true; EVulkanBackendTextureModes TexMode = VULKAN_BACKEND_TEXTURE_MODE_TEXTURED; for(size_t i = 0; i < VULKAN_BACKEND_BLEND_MODE_COUNT; ++i) { for(size_t j = 0; j < VULKAN_BACKEND_CLIP_MODE_COUNT; ++j) { Ret &= CreateSpriteMultiPushGraphicsPipelineImpl(pVertName, pFragName, m_SpriteMultiPushPipeline, TexMode, EVulkanBackendBlendModes(i), EVulkanBackendClipModes(j)); } } return Ret; } template bool CreateQuadGraphicsPipelineImpl(const char *pVertName, const char *pFragName, SPipelineContainer &PipeContainer, EVulkanBackendTextureModes TexMode, EVulkanBackendBlendModes BlendMode, EVulkanBackendClipModes DynamicMode) { std::array aAttributeDescriptions = {}; aAttributeDescriptions[0] = {0, 0, VK_FORMAT_R32G32B32A32_SFLOAT, 0}; aAttributeDescriptions[1] = {1, 0, VK_FORMAT_R8G8B8A8_UNORM, sizeof(float) * 4}; if(IsTextured) aAttributeDescriptions[2] = {2, 0, VK_FORMAT_R32G32_SFLOAT, sizeof(float) * 4 + sizeof(uint8_t) * 4}; std::array aSetLayouts; if(IsTextured) { aSetLayouts[0] = m_StandardTexturedDescriptorSetLayout; aSetLayouts[1] = m_QuadUniformDescriptorSetLayout; } else { aSetLayouts[0] = m_QuadUniformDescriptorSetLayout; } uint32_t PushConstantSize = sizeof(SUniformQuadGPos); std::array aPushConstants{}; aPushConstants[0] = {VK_SHADER_STAGE_VERTEX_BIT, 0, PushConstantSize}; return CreateGraphicsPipeline(pVertName, pFragName, PipeContainer, sizeof(float) * 4 + sizeof(uint8_t) * 4 + (IsTextured ? (sizeof(float) * 2) : 0), aAttributeDescriptions, aSetLayouts, aPushConstants, TexMode, BlendMode, DynamicMode); } template bool CreateQuadGraphicsPipeline(const char *pVertName, const char *pFragName) { bool Ret = true; EVulkanBackendTextureModes TexMode = HasSampler ? VULKAN_BACKEND_TEXTURE_MODE_TEXTURED : VULKAN_BACKEND_TEXTURE_MODE_NOT_TEXTURED; for(size_t i = 0; i < VULKAN_BACKEND_BLEND_MODE_COUNT; ++i) { for(size_t j = 0; j < VULKAN_BACKEND_CLIP_MODE_COUNT; ++j) { Ret &= CreateQuadGraphicsPipelineImpl(pVertName, pFragName, m_QuadPipeline, TexMode, EVulkanBackendBlendModes(i), EVulkanBackendClipModes(j)); } } return Ret; } template bool CreateQuadPushGraphicsPipelineImpl(const char *pVertName, const char *pFragName, SPipelineContainer &PipeContainer, EVulkanBackendTextureModes TexMode, EVulkanBackendBlendModes BlendMode, EVulkanBackendClipModes DynamicMode) { std::array aAttributeDescriptions = {}; aAttributeDescriptions[0] = {0, 0, VK_FORMAT_R32G32B32A32_SFLOAT, 0}; aAttributeDescriptions[1] = {1, 0, VK_FORMAT_R8G8B8A8_UNORM, sizeof(float) * 4}; if(IsTextured) aAttributeDescriptions[2] = {2, 0, VK_FORMAT_R32G32_SFLOAT, sizeof(float) * 4 + sizeof(uint8_t) * 4}; std::array aSetLayouts; aSetLayouts[0] = m_StandardTexturedDescriptorSetLayout; uint32_t PushConstantSize = sizeof(SUniformQuadPushGPos); std::array aPushConstants{}; aPushConstants[0] = {VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT, 0, PushConstantSize}; return CreateGraphicsPipeline(pVertName, pFragName, PipeContainer, sizeof(float) * 4 + sizeof(uint8_t) * 4 + (IsTextured ? (sizeof(float) * 2) : 0), aAttributeDescriptions, aSetLayouts, aPushConstants, TexMode, BlendMode, DynamicMode); } template bool CreateQuadPushGraphicsPipeline(const char *pVertName, const char *pFragName) { bool Ret = true; EVulkanBackendTextureModes TexMode = HasSampler ? VULKAN_BACKEND_TEXTURE_MODE_TEXTURED : VULKAN_BACKEND_TEXTURE_MODE_NOT_TEXTURED; for(size_t i = 0; i < VULKAN_BACKEND_BLEND_MODE_COUNT; ++i) { for(size_t j = 0; j < VULKAN_BACKEND_CLIP_MODE_COUNT; ++j) { Ret &= CreateQuadPushGraphicsPipelineImpl(pVertName, pFragName, m_QuadPushPipeline, TexMode, EVulkanBackendBlendModes(i), EVulkanBackendClipModes(j)); } } return Ret; } bool CreateCommandPool() { VkCommandPoolCreateInfo CreatePoolInfo{}; CreatePoolInfo.sType = VK_STRUCTURE_TYPE_COMMAND_POOL_CREATE_INFO; CreatePoolInfo.queueFamilyIndex = m_VKGraphicsQueueIndex; CreatePoolInfo.flags = VK_COMMAND_POOL_CREATE_RESET_COMMAND_BUFFER_BIT; m_vCommandPools.resize(m_ThreadCount); for(size_t i = 0; i < m_ThreadCount; ++i) { if(vkCreateCommandPool(m_VKDevice, &CreatePoolInfo, nullptr, &m_vCommandPools[i]) != VK_SUCCESS) { SetError("Creating the command pool failed."); return false; } } return true; } void DestroyCommandPool() { for(size_t i = 0; i < m_ThreadCount; ++i) { vkDestroyCommandPool(m_VKDevice, m_vCommandPools[i], nullptr); } } bool CreateCommandBuffers() { m_MainDrawCommandBuffers.resize(m_SwapChainImageCount); if(m_ThreadCount > 1) { m_ThreadDrawCommandBuffers.resize(m_ThreadCount); m_UsedThreadDrawCommandBuffer.resize(m_ThreadCount); m_HelperThreadDrawCommandBuffers.resize(m_ThreadCount); for(auto &ThreadDrawCommandBuffers : m_ThreadDrawCommandBuffers) { ThreadDrawCommandBuffers.resize(m_SwapChainImageCount); } for(auto &UsedThreadDrawCommandBuffer : m_UsedThreadDrawCommandBuffer) { UsedThreadDrawCommandBuffer.resize(m_SwapChainImageCount, false); } } m_MemoryCommandBuffers.resize(m_SwapChainImageCount); m_UsedMemoryCommandBuffer.resize(m_SwapChainImageCount, false); VkCommandBufferAllocateInfo AllocInfo{}; AllocInfo.sType = VK_STRUCTURE_TYPE_COMMAND_BUFFER_ALLOCATE_INFO; AllocInfo.commandPool = m_vCommandPools[0]; AllocInfo.level = VK_COMMAND_BUFFER_LEVEL_PRIMARY; AllocInfo.commandBufferCount = (uint32_t)m_MainDrawCommandBuffers.size(); if(vkAllocateCommandBuffers(m_VKDevice, &AllocInfo, m_MainDrawCommandBuffers.data()) != VK_SUCCESS) { SetError("Allocating command buffers failed."); return false; } AllocInfo.commandBufferCount = (uint32_t)m_MemoryCommandBuffers.size(); if(vkAllocateCommandBuffers(m_VKDevice, &AllocInfo, m_MemoryCommandBuffers.data()) != VK_SUCCESS) { SetError("Allocating memory command buffers failed."); return false; } if(m_ThreadCount > 1) { size_t Count = 0; for(auto &ThreadDrawCommandBuffers : m_ThreadDrawCommandBuffers) { AllocInfo.commandPool = m_vCommandPools[Count]; ++Count; AllocInfo.commandBufferCount = (uint32_t)ThreadDrawCommandBuffers.size(); AllocInfo.level = VK_COMMAND_BUFFER_LEVEL_SECONDARY; if(vkAllocateCommandBuffers(m_VKDevice, &AllocInfo, ThreadDrawCommandBuffers.data()) != VK_SUCCESS) { SetError("Allocating thread command buffers failed."); return false; } } } return true; } void DestroyCommandBuffer() { if(m_ThreadCount > 1) { size_t Count = 0; for(auto &ThreadDrawCommandBuffers : m_ThreadDrawCommandBuffers) { vkFreeCommandBuffers(m_VKDevice, m_vCommandPools[Count], static_cast(ThreadDrawCommandBuffers.size()), ThreadDrawCommandBuffers.data()); ++Count; } } vkFreeCommandBuffers(m_VKDevice, m_vCommandPools[0], static_cast(m_MemoryCommandBuffers.size()), m_MemoryCommandBuffers.data()); vkFreeCommandBuffers(m_VKDevice, m_vCommandPools[0], static_cast(m_MainDrawCommandBuffers.size()), m_MainDrawCommandBuffers.data()); m_ThreadDrawCommandBuffers.clear(); m_UsedThreadDrawCommandBuffer.clear(); m_HelperThreadDrawCommandBuffers.clear(); m_MainDrawCommandBuffers.clear(); m_MemoryCommandBuffers.clear(); m_UsedMemoryCommandBuffer.clear(); } bool CreateSyncObjects() { m_WaitSemaphores.resize(m_SwapChainImageCount); m_SigSemaphores.resize(m_SwapChainImageCount); m_MemorySemaphores.resize(m_SwapChainImageCount); m_FrameFences.resize(m_SwapChainImageCount); m_ImagesFences.resize(m_SwapChainImageCount, VK_NULL_HANDLE); VkSemaphoreCreateInfo CreateSemaphoreInfo{}; CreateSemaphoreInfo.sType = VK_STRUCTURE_TYPE_SEMAPHORE_CREATE_INFO; VkFenceCreateInfo FenceInfo{}; FenceInfo.sType = VK_STRUCTURE_TYPE_FENCE_CREATE_INFO; FenceInfo.flags = VK_FENCE_CREATE_SIGNALED_BIT; for(size_t i = 0; i < m_SwapChainImageCount; i++) { if(vkCreateSemaphore(m_VKDevice, &CreateSemaphoreInfo, nullptr, &m_WaitSemaphores[i]) != VK_SUCCESS || vkCreateSemaphore(m_VKDevice, &CreateSemaphoreInfo, nullptr, &m_SigSemaphores[i]) != VK_SUCCESS || vkCreateSemaphore(m_VKDevice, &CreateSemaphoreInfo, nullptr, &m_MemorySemaphores[i]) != VK_SUCCESS || vkCreateFence(m_VKDevice, &FenceInfo, nullptr, &m_FrameFences[i]) != VK_SUCCESS) { SetError("Creating swap chain sync objects(fences, semaphores) failed."); return false; } } return true; } void DestroySyncObjects() { for(size_t i = 0; i < m_SwapChainImageCount; i++) { vkDestroySemaphore(m_VKDevice, m_WaitSemaphores[i], nullptr); vkDestroySemaphore(m_VKDevice, m_SigSemaphores[i], nullptr); vkDestroySemaphore(m_VKDevice, m_MemorySemaphores[i], nullptr); vkDestroyFence(m_VKDevice, m_FrameFences[i], nullptr); } m_WaitSemaphores.clear(); m_SigSemaphores.clear(); m_MemorySemaphores.clear(); m_FrameFences.clear(); m_ImagesFences.clear(); } void DestroyBufferOfFrame(size_t ImageIndex, SFrameBuffers &Buffer) { CleanBufferPair(ImageIndex, Buffer.m_Buffer, Buffer.m_BufferMem); } void DestroyUniBufferOfFrame(size_t ImageIndex, SFrameUniformBuffers &Buffer) { CleanBufferPair(ImageIndex, Buffer.m_Buffer, Buffer.m_BufferMem); for(auto &DescrSet : Buffer.m_aUniformSets) { if(DescrSet.m_Descriptor != VK_NULL_HANDLE) { DestroyUniformDescriptorSets(&DescrSet, 1); } } } /************* * SWAP CHAIN **************/ void CleanupVulkanSwapChain(bool ForceSwapChainDestruct) { m_StandardPipeline.Destroy(m_VKDevice); m_StandardLinePipeline.Destroy(m_VKDevice); m_Standard3DPipeline.Destroy(m_VKDevice); m_TextPipeline.Destroy(m_VKDevice); m_TilePipeline.Destroy(m_VKDevice); m_TileBorderPipeline.Destroy(m_VKDevice); m_TileBorderLinePipeline.Destroy(m_VKDevice); m_PrimExPipeline.Destroy(m_VKDevice); m_PrimExRotationlessPipeline.Destroy(m_VKDevice); m_SpriteMultiPipeline.Destroy(m_VKDevice); m_SpriteMultiPushPipeline.Destroy(m_VKDevice); m_QuadPipeline.Destroy(m_VKDevice); m_QuadPushPipeline.Destroy(m_VKDevice); DestroyFramebuffers(); DestroyRenderPass(); DestroyMultiSamplerImageAttachments(); DestroyImageViews(); ClearSwapChainImageHandles(); DestroySwapChain(ForceSwapChainDestruct); m_SwapchainCreated = false; } template void CleanupVulkan() { if(IsLastCleanup) { if(m_SwapchainCreated) CleanupVulkanSwapChain(true); // clean all images, buffers, buffer containers for(auto &Texture : m_Textures) { if(Texture.m_VKTextDescrSet.m_Descriptor != VK_NULL_HANDLE && IsVerbose()) { dbg_msg("vulkan", "text textures not cleared over cmd."); } DestroyTexture(Texture); } for(auto &BufferObject : m_BufferObjects) { if(!BufferObject.m_IsStreamedBuffer) FreeVertexMemBlock(BufferObject.m_BufferObject.m_Mem); } m_BufferContainers.clear(); } m_ImageLastFrameCheck.clear(); m_vLastPipeline.clear(); for(size_t i = 0; i < m_ThreadCount; ++i) { m_vStreamedVertexBuffers[i].Destroy([&](size_t ImageIndex, SFrameBuffers &Buffer) { DestroyBufferOfFrame(ImageIndex, Buffer); }); m_vStreamedUniformBuffers[i].Destroy([&](size_t ImageIndex, SFrameUniformBuffers &Buffer) { DestroyUniBufferOfFrame(ImageIndex, Buffer); }); } m_vStreamedVertexBuffers.clear(); m_vStreamedUniformBuffers.clear(); for(size_t i = 0; i < m_SwapChainImageCount; ++i) { ClearFrameData(i); } m_FrameDelayedBufferCleanup.clear(); m_FrameDelayedTextureCleanup.clear(); m_FrameDelayedTextTexturesCleanup.clear(); m_StagingBufferCache.DestroyFrameData(m_SwapChainImageCount); m_StagingBufferCacheImage.DestroyFrameData(m_SwapChainImageCount); m_VertexBufferCache.DestroyFrameData(m_SwapChainImageCount); for(auto &ImageBufferCache : m_ImageBufferCaches) ImageBufferCache.second.DestroyFrameData(m_SwapChainImageCount); if(IsLastCleanup) { m_StagingBufferCache.Destroy(m_VKDevice); m_StagingBufferCacheImage.Destroy(m_VKDevice); m_VertexBufferCache.Destroy(m_VKDevice); for(auto &ImageBufferCache : m_ImageBufferCaches) ImageBufferCache.second.Destroy(m_VKDevice); m_ImageBufferCaches.clear(); DestroyTextureSamplers(); DestroyDescriptorPools(); DeletePresentedImageDataImage(); } DestroySyncObjects(); DestroyCommandBuffer(); if(IsLastCleanup) { DestroyCommandPool(); } if(IsLastCleanup) { DestroyUniformDescriptorSetLayouts(); DestroyTextDescriptorSetLayout(); DestroyDescriptorSetLayouts(); } } void CleanupVulkanSDL() { if(m_VKInstance != VK_NULL_HANDLE) { DestroySurface(); vkDestroyDevice(m_VKDevice, nullptr); if(g_Config.m_DbgGfx == DEBUG_GFX_MODE_MINIMUM || g_Config.m_DbgGfx == DEBUG_GFX_MODE_ALL) { UnregisterDebugCallback(); } vkDestroyInstance(m_VKInstance, nullptr); } } int RecreateSwapChain() { int Ret = 0; vkDeviceWaitIdle(m_VKDevice); if(IsVerbose()) { dbg_msg("vulkan", "recreating swap chain."); } VkSwapchainKHR OldSwapChain = VK_NULL_HANDLE; uint32_t OldSwapChainImageCount = m_SwapChainImageCount; if(m_SwapchainCreated) CleanupVulkanSwapChain(false); if(!m_SwapchainCreated) Ret = InitVulkanSwapChain(OldSwapChain); if(OldSwapChainImageCount != m_SwapChainImageCount) { CleanupVulkan(); InitVulkan(); } if(OldSwapChain != VK_NULL_HANDLE) { vkDestroySwapchainKHR(m_VKDevice, OldSwapChain, nullptr); } if(Ret != 0 && IsVerbose()) { dbg_msg("vulkan", "recreating swap chain failed."); } return Ret; } int InitVulkanSDL(SDL_Window *pWindow, uint32_t CanvasWidth, uint32_t CanvasHeight, char *pRendererString, char *pVendorString, char *pVersionString) { std::vector VKExtensions; std::vector VKLayers; m_CanvasWidth = CanvasWidth; m_CanvasHeight = CanvasHeight; if(!GetVulkanExtensions(pWindow, VKExtensions)) return -1; if(!GetVulkanLayers(VKLayers)) return -1; if(!CreateVulkanInstance(VKLayers, VKExtensions, true)) return -1; if(g_Config.m_DbgGfx == DEBUG_GFX_MODE_MINIMUM || g_Config.m_DbgGfx == DEBUG_GFX_MODE_ALL) { SetupDebugCallback(); for(auto &VKLayer : VKLayers) { dbg_msg("vulkan", "Validation layer: %s", VKLayer.c_str()); } } if(!SelectGPU(pRendererString, pVendorString, pVersionString)) return -1; if(!CreateLogicalDevice(VKLayers)) return -1; GetDeviceQueue(); if(!CreateSurface(pWindow)) return -1; return 0; } /************************ * MEMORY MANAGMENT ************************/ uint32_t FindMemoryType(VkPhysicalDevice PhyDevice, uint32_t TypeFilter, VkMemoryPropertyFlags Properties) { VkPhysicalDeviceMemoryProperties MemProperties; vkGetPhysicalDeviceMemoryProperties(PhyDevice, &MemProperties); for(uint32_t i = 0; i < MemProperties.memoryTypeCount; i++) { if((TypeFilter & (1 << i)) && (MemProperties.memoryTypes[i].propertyFlags & Properties) == Properties) { return i; } } return 0; } bool CreateBuffer(VkDeviceSize BufferSize, EMemoryBlockUsage MemUsage, VkBufferUsageFlags BufferUsage, VkMemoryPropertyFlags MemoryProperties, VkBuffer &VKBuffer, SDeviceMemoryBlock &VKBufferMemory) { VkBufferCreateInfo BufferInfo{}; BufferInfo.sType = VK_STRUCTURE_TYPE_BUFFER_CREATE_INFO; BufferInfo.size = BufferSize; BufferInfo.usage = BufferUsage; BufferInfo.sharingMode = VK_SHARING_MODE_EXCLUSIVE; if(vkCreateBuffer(m_VKDevice, &BufferInfo, nullptr, &VKBuffer) != VK_SUCCESS) { SetError("Buffer creation failed."); return false; } VkMemoryRequirements MemRequirements; vkGetBufferMemoryRequirements(m_VKDevice, VKBuffer, &MemRequirements); VkMemoryAllocateInfo MemAllocInfo{}; MemAllocInfo.sType = VK_STRUCTURE_TYPE_MEMORY_ALLOCATE_INFO; MemAllocInfo.allocationSize = MemRequirements.size; MemAllocInfo.memoryTypeIndex = FindMemoryType(m_VKGPU, MemRequirements.memoryTypeBits, MemoryProperties); VKBufferMemory.m_Size = MemRequirements.size; if(MemUsage == MEMORY_BLOCK_USAGE_BUFFER) m_pBufferMemoryUsage->store(m_pBufferMemoryUsage->load(std::memory_order_relaxed) + MemRequirements.size, std::memory_order_relaxed); else if(MemUsage == MEMORY_BLOCK_USAGE_STAGING) m_pStagingMemoryUsage->store(m_pStagingMemoryUsage->load(std::memory_order_relaxed) + MemRequirements.size, std::memory_order_relaxed); else if(MemUsage == MEMORY_BLOCK_USAGE_STREAM) m_pStreamMemoryUsage->store(m_pStreamMemoryUsage->load(std::memory_order_relaxed) + MemRequirements.size, std::memory_order_relaxed); if(IsVerbose()) { VerboseAllocatedMemory(MemRequirements.size, m_CurImageIndex, MemUsage); } if(!AllocateVulkanMemory(&MemAllocInfo, &VKBufferMemory.m_Mem)) { SetError("Allocation for buffer object failed."); return false; } VKBufferMemory.m_UsageType = MemUsage; if(vkBindBufferMemory(m_VKDevice, VKBuffer, VKBufferMemory.m_Mem, 0) != VK_SUCCESS) { SetError("Binding memory to buffer failed."); return false; } return true; } bool AllocateDescriptorPool(SDeviceDescriptorPools &DescriptorPools, size_t AllocPoolSize) { SDeviceDescriptorPool NewPool; NewPool.m_Size = AllocPoolSize; VkDescriptorPoolSize PoolSize{}; if(DescriptorPools.m_IsUniformPool) PoolSize.type = VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER; else PoolSize.type = VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER; PoolSize.descriptorCount = AllocPoolSize; VkDescriptorPoolCreateInfo PoolInfo{}; PoolInfo.sType = VK_STRUCTURE_TYPE_DESCRIPTOR_POOL_CREATE_INFO; PoolInfo.poolSizeCount = 1; PoolInfo.pPoolSizes = &PoolSize; PoolInfo.maxSets = AllocPoolSize; PoolInfo.flags = VK_DESCRIPTOR_POOL_CREATE_FREE_DESCRIPTOR_SET_BIT; if(vkCreateDescriptorPool(m_VKDevice, &PoolInfo, nullptr, &NewPool.m_Pool) != VK_SUCCESS) { SetError("Creating the descriptor pool failed."); return false; } DescriptorPools.m_Pools.push_back(NewPool); return true; } bool CreateDescriptorPools() { m_StandardTextureDescrPool.m_IsUniformPool = false; m_StandardTextureDescrPool.m_DefaultAllocSize = 1024; m_TextTextureDescrPool.m_IsUniformPool = false; m_TextTextureDescrPool.m_DefaultAllocSize = 8; m_UniformBufferDescrPools.resize(m_ThreadCount); for(auto &UniformBufferDescrPool : m_UniformBufferDescrPools) { UniformBufferDescrPool.m_IsUniformPool = true; UniformBufferDescrPool.m_DefaultAllocSize = 512; } bool Ret = AllocateDescriptorPool(m_StandardTextureDescrPool, CCommandBuffer::MAX_TEXTURES); Ret |= AllocateDescriptorPool(m_TextTextureDescrPool, 8); for(auto &UniformBufferDescrPool : m_UniformBufferDescrPools) { Ret |= AllocateDescriptorPool(UniformBufferDescrPool, 64); } return Ret; } void DestroyDescriptorPools() { for(auto &DescrPool : m_StandardTextureDescrPool.m_Pools) vkDestroyDescriptorPool(m_VKDevice, DescrPool.m_Pool, nullptr); for(auto &DescrPool : m_TextTextureDescrPool.m_Pools) vkDestroyDescriptorPool(m_VKDevice, DescrPool.m_Pool, nullptr); for(auto &UniformBufferDescrPool : m_UniformBufferDescrPools) { for(auto &DescrPool : UniformBufferDescrPool.m_Pools) vkDestroyDescriptorPool(m_VKDevice, DescrPool.m_Pool, nullptr); } m_UniformBufferDescrPools.clear(); } VkDescriptorPool GetDescriptorPoolForAlloc(SDeviceDescriptorPools &DescriptorPools, SDeviceDescriptorSet *pSets, size_t AllocNum) { size_t CurAllocNum = AllocNum; size_t CurAllocOffset = 0; VkDescriptorPool RetDescr = VK_NULL_HANDLE; while(CurAllocNum > 0) { size_t AllocatedInThisRun = 0; bool Found = false; size_t DescriptorPoolIndex = std::numeric_limits::max(); for(size_t i = 0; i < DescriptorPools.m_Pools.size(); ++i) { auto &Pool = DescriptorPools.m_Pools[i]; if(Pool.m_CurSize + CurAllocNum < Pool.m_Size) { AllocatedInThisRun = CurAllocNum; Pool.m_CurSize += CurAllocNum; Found = true; if(RetDescr == VK_NULL_HANDLE) RetDescr = Pool.m_Pool; DescriptorPoolIndex = i; break; } else { size_t RemainingPoolCount = Pool.m_Size - Pool.m_CurSize; if(RemainingPoolCount > 0) { AllocatedInThisRun = RemainingPoolCount; Pool.m_CurSize += RemainingPoolCount; Found = true; if(RetDescr == VK_NULL_HANDLE) RetDescr = Pool.m_Pool; DescriptorPoolIndex = i; break; } } } if(!Found) { DescriptorPoolIndex = DescriptorPools.m_Pools.size(); AllocateDescriptorPool(DescriptorPools, DescriptorPools.m_DefaultAllocSize); AllocatedInThisRun = minimum((size_t)DescriptorPools.m_DefaultAllocSize, CurAllocNum); auto &Pool = DescriptorPools.m_Pools.back(); Pool.m_CurSize += AllocatedInThisRun; if(RetDescr == VK_NULL_HANDLE) RetDescr = Pool.m_Pool; } for(size_t i = CurAllocOffset; i < CurAllocOffset + AllocatedInThisRun; ++i) { pSets[i].m_pPools = &DescriptorPools; pSets[i].m_PoolIndex = DescriptorPoolIndex; } CurAllocOffset += AllocatedInThisRun; CurAllocNum -= AllocatedInThisRun; } return RetDescr; } bool CreateNewTexturedStandardDescriptorSets(size_t TextureSlot, size_t DescrIndex) { auto &Texture = m_Textures[TextureSlot]; auto &DescrSet = Texture.m_aVKStandardTexturedDescrSets[DescrIndex]; VkDescriptorSetAllocateInfo DesAllocInfo{}; DesAllocInfo.sType = VK_STRUCTURE_TYPE_DESCRIPTOR_SET_ALLOCATE_INFO; DesAllocInfo.descriptorPool = GetDescriptorPoolForAlloc(m_StandardTextureDescrPool, &DescrSet, 1); DesAllocInfo.descriptorSetCount = 1; DesAllocInfo.pSetLayouts = &m_StandardTexturedDescriptorSetLayout; if(vkAllocateDescriptorSets(m_VKDevice, &DesAllocInfo, &DescrSet.m_Descriptor) != VK_SUCCESS) { return false; } VkDescriptorImageInfo ImageInfo{}; ImageInfo.imageLayout = VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL; ImageInfo.imageView = Texture.m_ImgView; ImageInfo.sampler = Texture.m_aSamplers[DescrIndex]; std::array aDescriptorWrites{}; aDescriptorWrites[0].sType = VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET; aDescriptorWrites[0].dstSet = DescrSet.m_Descriptor; aDescriptorWrites[0].dstBinding = 0; aDescriptorWrites[0].dstArrayElement = 0; aDescriptorWrites[0].descriptorType = VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER; aDescriptorWrites[0].descriptorCount = 1; aDescriptorWrites[0].pImageInfo = &ImageInfo; vkUpdateDescriptorSets(m_VKDevice, static_cast(aDescriptorWrites.size()), aDescriptorWrites.data(), 0, nullptr); return true; } void DestroyTexturedStandardDescriptorSets(CTexture &Texture, size_t DescrIndex) { auto &DescrSet = Texture.m_aVKStandardTexturedDescrSets[DescrIndex]; if(DescrSet.m_PoolIndex != std::numeric_limits::max()) vkFreeDescriptorSets(m_VKDevice, DescrSet.m_pPools->m_Pools[DescrSet.m_PoolIndex].m_Pool, 1, &DescrSet.m_Descriptor); DescrSet = {}; } bool CreateNew3DTexturedStandardDescriptorSets(size_t TextureSlot) { auto &Texture = m_Textures[TextureSlot]; auto &DescrSet = Texture.m_VKStandard3DTexturedDescrSet; VkDescriptorSetAllocateInfo DesAllocInfo{}; DesAllocInfo.sType = VK_STRUCTURE_TYPE_DESCRIPTOR_SET_ALLOCATE_INFO; DesAllocInfo.descriptorPool = GetDescriptorPoolForAlloc(m_StandardTextureDescrPool, &DescrSet, 1); DesAllocInfo.descriptorSetCount = 1; DesAllocInfo.pSetLayouts = &m_Standard3DTexturedDescriptorSetLayout; if(vkAllocateDescriptorSets(m_VKDevice, &DesAllocInfo, &DescrSet.m_Descriptor) != VK_SUCCESS) { return false; } VkDescriptorImageInfo ImageInfo{}; ImageInfo.imageLayout = VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL; ImageInfo.imageView = Texture.m_Img3DView; ImageInfo.sampler = Texture.m_Sampler3D; std::array aDescriptorWrites{}; aDescriptorWrites[0].sType = VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET; aDescriptorWrites[0].dstSet = DescrSet.m_Descriptor; aDescriptorWrites[0].dstBinding = 0; aDescriptorWrites[0].dstArrayElement = 0; aDescriptorWrites[0].descriptorType = VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER; aDescriptorWrites[0].descriptorCount = 1; aDescriptorWrites[0].pImageInfo = &ImageInfo; vkUpdateDescriptorSets(m_VKDevice, static_cast(aDescriptorWrites.size()), aDescriptorWrites.data(), 0, nullptr); return true; } void DestroyTextured3DStandardDescriptorSets(CTexture &Texture) { auto &DescrSet = Texture.m_VKStandard3DTexturedDescrSet; if(DescrSet.m_PoolIndex != std::numeric_limits::max()) vkFreeDescriptorSets(m_VKDevice, DescrSet.m_pPools->m_Pools[DescrSet.m_PoolIndex].m_Pool, 1, &DescrSet.m_Descriptor); } bool CreateNewTextDescriptorSets(size_t Texture, size_t TextureOutline) { auto &TextureText = m_Textures[Texture]; auto &TextureTextOutline = m_Textures[TextureOutline]; auto &DescrSetText = TextureText.m_VKTextDescrSet; auto &DescrSetTextOutline = TextureText.m_VKTextDescrSet; VkDescriptorSetAllocateInfo DesAllocInfo{}; DesAllocInfo.sType = VK_STRUCTURE_TYPE_DESCRIPTOR_SET_ALLOCATE_INFO; DesAllocInfo.descriptorPool = GetDescriptorPoolForAlloc(m_TextTextureDescrPool, &DescrSetText, 1); DesAllocInfo.descriptorSetCount = 1; DesAllocInfo.pSetLayouts = &m_TextDescriptorSetLayout; if(vkAllocateDescriptorSets(m_VKDevice, &DesAllocInfo, &DescrSetText.m_Descriptor) != VK_SUCCESS) { return false; } std::array aImageInfo{}; aImageInfo[0].imageLayout = VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL; aImageInfo[0].imageView = TextureText.m_ImgView; aImageInfo[0].sampler = TextureText.m_aSamplers[0]; aImageInfo[1].imageLayout = VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL; aImageInfo[1].imageView = TextureTextOutline.m_ImgView; aImageInfo[1].sampler = TextureTextOutline.m_aSamplers[0]; std::array aDescriptorWrites{}; aDescriptorWrites[0].sType = VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET; aDescriptorWrites[0].dstSet = DescrSetText.m_Descriptor; aDescriptorWrites[0].dstBinding = 0; aDescriptorWrites[0].dstArrayElement = 0; aDescriptorWrites[0].descriptorType = VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER; aDescriptorWrites[0].descriptorCount = 1; aDescriptorWrites[0].pImageInfo = aImageInfo.data(); aDescriptorWrites[1] = aDescriptorWrites[0]; aDescriptorWrites[1].dstBinding = 1; aDescriptorWrites[1].pImageInfo = &aImageInfo[1]; vkUpdateDescriptorSets(m_VKDevice, static_cast(aDescriptorWrites.size()), aDescriptorWrites.data(), 0, nullptr); DescrSetTextOutline = DescrSetText; return true; } void DestroyTextDescriptorSets(CTexture &Texture, CTexture &TextureOutline) { auto &DescrSet = Texture.m_VKTextDescrSet; if(DescrSet.m_PoolIndex != std::numeric_limits::max()) vkFreeDescriptorSets(m_VKDevice, DescrSet.m_pPools->m_Pools[DescrSet.m_PoolIndex].m_Pool, 1, &DescrSet.m_Descriptor); } bool HasMultiSampling() { return GetSampleCount() != VK_SAMPLE_COUNT_1_BIT; } VkSampleCountFlagBits GetSampleCount() { if(m_MultiSamplingCount >= 64 && m_MaxMultiSample & VK_SAMPLE_COUNT_64_BIT) return VK_SAMPLE_COUNT_64_BIT; else if(m_MultiSamplingCount >= 32 && m_MaxMultiSample & VK_SAMPLE_COUNT_32_BIT) return VK_SAMPLE_COUNT_32_BIT; else if(m_MultiSamplingCount >= 16 && m_MaxMultiSample & VK_SAMPLE_COUNT_16_BIT) return VK_SAMPLE_COUNT_16_BIT; else if(m_MultiSamplingCount >= 8 && m_MaxMultiSample & VK_SAMPLE_COUNT_8_BIT) return VK_SAMPLE_COUNT_8_BIT; else if(m_MultiSamplingCount >= 4 && m_MaxMultiSample & VK_SAMPLE_COUNT_4_BIT) return VK_SAMPLE_COUNT_4_BIT; else if(m_MultiSamplingCount >= 2 && m_MaxMultiSample & VK_SAMPLE_COUNT_2_BIT) return VK_SAMPLE_COUNT_2_BIT; return VK_SAMPLE_COUNT_1_BIT; } int InitVulkanSwapChain(VkSwapchainKHR &OldSwapChain) { OldSwapChain = VK_NULL_HANDLE; if(!CreateSwapChain(OldSwapChain)) return -1; if(!GetSwapChainImageHandles()) return -1; if(!CreateImageViews()) return -1; if(!CreateMultiSamplerImageAttachments()) { return -1; } m_LastPresentedSwapChainImageIndex = std::numeric_limits::max(); if(!CreateRenderPass(true)) return -1; if(!CreateFramebuffers()) return -1; if(!CreateStandardGraphicsPipeline("shader/vulkan/prim.vert.spv", "shader/vulkan/prim.frag.spv", false, false)) return -1; if(!CreateStandardGraphicsPipeline("shader/vulkan/prim_textured.vert.spv", "shader/vulkan/prim_textured.frag.spv", true, false)) return -1; if(!CreateStandardGraphicsPipeline("shader/vulkan/prim.vert.spv", "shader/vulkan/prim.frag.spv", false, true)) return -1; if(!CreateStandard3DGraphicsPipeline("shader/vulkan/prim3d.vert.spv", "shader/vulkan/prim3d.frag.spv", false)) return -1; if(!CreateStandard3DGraphicsPipeline("shader/vulkan/prim3d_textured.vert.spv", "shader/vulkan/prim3d_textured.frag.spv", true)) return -1; if(!CreateTextGraphicsPipeline("shader/vulkan/text.vert.spv", "shader/vulkan/text.frag.spv")) return -1; if(!CreateTileGraphicsPipeline("shader/vulkan/tile.vert.spv", "shader/vulkan/tile.frag.spv", 0)) return -1; if(!CreateTileGraphicsPipeline("shader/vulkan/tile_textured.vert.spv", "shader/vulkan/tile_textured.frag.spv", 0)) return -1; if(!CreateTileGraphicsPipeline("shader/vulkan/tile_border.vert.spv", "shader/vulkan/tile_border.frag.spv", 1)) return -1; if(!CreateTileGraphicsPipeline("shader/vulkan/tile_border_textured.vert.spv", "shader/vulkan/tile_border_textured.frag.spv", 1)) return -1; if(!CreateTileGraphicsPipeline("shader/vulkan/tile_border_line.vert.spv", "shader/vulkan/tile_border_line.frag.spv", 2)) return -1; if(!CreateTileGraphicsPipeline("shader/vulkan/tile_border_line_textured.vert.spv", "shader/vulkan/tile_border_line_textured.frag.spv", 2)) return -1; if(!CreatePrimExGraphicsPipeline("shader/vulkan/primex_rotationless.vert.spv", "shader/vulkan/primex_rotationless.frag.spv", false, true)) return -1; if(!CreatePrimExGraphicsPipeline("shader/vulkan/primex_tex_rotationless.vert.spv", "shader/vulkan/primex_tex_rotationless.frag.spv", true, true)) return -1; if(!CreatePrimExGraphicsPipeline("shader/vulkan/primex.vert.spv", "shader/vulkan/primex.frag.spv", false, false)) return -1; if(!CreatePrimExGraphicsPipeline("shader/vulkan/primex_tex.vert.spv", "shader/vulkan/primex_tex.frag.spv", true, false)) return -1; if(!CreateSpriteMultiGraphicsPipeline("shader/vulkan/spritemulti.vert.spv", "shader/vulkan/spritemulti.frag.spv")) return -1; if(!CreateSpriteMultiPushGraphicsPipeline("shader/vulkan/spritemulti_push.vert.spv", "shader/vulkan/spritemulti_push.frag.spv")) return -1; if(!CreateQuadGraphicsPipeline("shader/vulkan/quad.vert.spv", "shader/vulkan/quad.frag.spv")) return -1; if(!CreateQuadGraphicsPipeline("shader/vulkan/quad_textured.vert.spv", "shader/vulkan/quad_textured.frag.spv")) return -1; if(!CreateQuadPushGraphicsPipeline("shader/vulkan/quad_push.vert.spv", "shader/vulkan/quad_push.frag.spv")) return -1; if(!CreateQuadPushGraphicsPipeline("shader/vulkan/quad_push_textured.vert.spv", "shader/vulkan/quad_push_textured.frag.spv")) return -1; m_SwapchainCreated = true; return 0; } template int InitVulkan() { if(!CreateDescriptorSetLayouts()) return -1; if(!CreateTextDescriptorSetLayout()) return -1; if(!CreateSpriteMultiUniformDescriptorSetLayout()) return -1; if(!CreateQuadUniformDescriptorSetLayout()) return -1; if(IsFirstInitialization) { VkSwapchainKHR OldSwapChain = VK_NULL_HANDLE; if(InitVulkanSwapChain(OldSwapChain) != 0) return -1; } if(IsFirstInitialization) { if(!CreateCommandPool()) return -1; } if(!CreateCommandBuffers()) return -1; if(!CreateSyncObjects()) return -1; if(IsFirstInitialization) { if(!CreateDescriptorPools()) return -1; if(!CreateTextureSamplers()) return -1; } m_vStreamedVertexBuffers.resize(m_ThreadCount); m_vStreamedUniformBuffers.resize(m_ThreadCount); for(size_t i = 0; i < m_ThreadCount; ++i) { m_vStreamedVertexBuffers[i].Init(m_SwapChainImageCount); m_vStreamedUniformBuffers[i].Init(m_SwapChainImageCount); } m_vLastPipeline.resize(m_ThreadCount, VK_NULL_HANDLE); m_FrameDelayedBufferCleanup.resize(m_SwapChainImageCount); m_FrameDelayedTextureCleanup.resize(m_SwapChainImageCount); m_FrameDelayedTextTexturesCleanup.resize(m_SwapChainImageCount); m_StagingBufferCache.Init(m_SwapChainImageCount); m_StagingBufferCacheImage.Init(m_SwapChainImageCount); m_VertexBufferCache.Init(m_SwapChainImageCount); for(auto &ImageBufferCache : m_ImageBufferCaches) ImageBufferCache.second.Init(m_SwapChainImageCount); m_ImageLastFrameCheck.resize(m_SwapChainImageCount, 0); if(IsFirstInitialization) { // check if image format supports linear blitting VkFormatProperties FormatProperties; vkGetPhysicalDeviceFormatProperties(m_VKGPU, VK_FORMAT_R8G8B8A8_UNORM, &FormatProperties); if((FormatProperties.optimalTilingFeatures & VK_FORMAT_FEATURE_SAMPLED_IMAGE_FILTER_LINEAR_BIT) != 0) { m_AllowsLinearBlitting = true; } if((FormatProperties.optimalTilingFeatures & VK_FORMAT_FEATURE_BLIT_SRC_BIT) != 0 && (FormatProperties.optimalTilingFeatures & VK_FORMAT_FEATURE_BLIT_DST_BIT) != 0) { m_OptimalRGBAImageBlitting = true; } // check if image format supports blitting to linear tiled images if((FormatProperties.linearTilingFeatures & VK_FORMAT_FEATURE_BLIT_DST_BIT) != 0) { m_LinearRGBAImageBlitting = true; } vkGetPhysicalDeviceFormatProperties(m_VKGPU, m_VKSurfFormat.format, &FormatProperties); if((FormatProperties.optimalTilingFeatures & VK_FORMAT_FEATURE_BLIT_SRC_BIT) != 0) { m_OptimalSwapChainImageBlitting = true; } } return 0; } VkCommandBuffer &GetMemoryCommandBuffer() { VkCommandBuffer &MemCommandBuffer = m_MemoryCommandBuffers[m_CurImageIndex]; if(!m_UsedMemoryCommandBuffer[m_CurImageIndex]) { m_UsedMemoryCommandBuffer[m_CurImageIndex] = true; vkResetCommandBuffer(MemCommandBuffer, VK_COMMAND_BUFFER_RESET_RELEASE_RESOURCES_BIT); VkCommandBufferBeginInfo BeginInfo{}; BeginInfo.sType = VK_STRUCTURE_TYPE_COMMAND_BUFFER_BEGIN_INFO; BeginInfo.flags = VK_COMMAND_BUFFER_USAGE_ONE_TIME_SUBMIT_BIT; if(vkBeginCommandBuffer(MemCommandBuffer, &BeginInfo) != VK_SUCCESS) { SetError("Command buffer cannot be filled anymore."); } } return MemCommandBuffer; } VkCommandBuffer &GetGraphicCommandBuffer(size_t RenderThreadIndex) { if(m_ThreadCount < 2) { return m_MainDrawCommandBuffers[m_CurImageIndex]; } else { VkCommandBuffer &DrawCommandBuffer = m_ThreadDrawCommandBuffers[RenderThreadIndex][m_CurImageIndex]; if(!m_UsedThreadDrawCommandBuffer[RenderThreadIndex][m_CurImageIndex]) { m_UsedThreadDrawCommandBuffer[RenderThreadIndex][m_CurImageIndex] = true; vkResetCommandBuffer(DrawCommandBuffer, VK_COMMAND_BUFFER_RESET_RELEASE_RESOURCES_BIT); VkCommandBufferBeginInfo BeginInfo{}; BeginInfo.sType = VK_STRUCTURE_TYPE_COMMAND_BUFFER_BEGIN_INFO; BeginInfo.flags = VK_COMMAND_BUFFER_USAGE_ONE_TIME_SUBMIT_BIT | VK_COMMAND_BUFFER_USAGE_RENDER_PASS_CONTINUE_BIT; VkCommandBufferInheritanceInfo InheretInfo{}; InheretInfo.sType = VK_STRUCTURE_TYPE_COMMAND_BUFFER_INHERITANCE_INFO; InheretInfo.framebuffer = m_FramebufferList[m_CurImageIndex]; InheretInfo.occlusionQueryEnable = VK_FALSE; InheretInfo.renderPass = m_VKRenderPass; InheretInfo.subpass = 0; BeginInfo.pInheritanceInfo = &InheretInfo; if(vkBeginCommandBuffer(DrawCommandBuffer, &BeginInfo) != VK_SUCCESS) { SetError("Thread draw command buffer cannot be filled anymore."); } } return DrawCommandBuffer; } } VkCommandBuffer &GetMainGraphicCommandBuffer() { return m_MainDrawCommandBuffers[m_CurImageIndex]; } /************************ * STREAM BUFFERS SETUP ************************/ typedef std::function TNewMemFunc; // returns true, if the stream memory was just allocated template void CreateStreamBuffer(TStreamMemName *&pBufferMem, TNewMemFunc &&NewMemFunc, SStreamMemory &StreamUniformBuffer, VkBufferUsageFlagBits Usage, VkBuffer &NewBuffer, SDeviceMemoryBlock &NewBufferMem, size_t &BufferOffset, const void *pData, size_t DataSize) { VkBuffer Buffer = VK_NULL_HANDLE; SDeviceMemoryBlock BufferMem; size_t Offset = 0; uint8_t *pMem = nullptr; size_t it = 0; if(UsesCurrentCountOffset) it = StreamUniformBuffer.GetUsedCount(m_CurImageIndex); for(; it < StreamUniformBuffer.GetBuffers(m_CurImageIndex).size(); ++it) { auto &BufferOfFrame = StreamUniformBuffer.GetBuffers(m_CurImageIndex)[it]; if(BufferOfFrame.m_Size >= DataSize + BufferOfFrame.m_UsedSize) { if(BufferOfFrame.m_UsedSize == 0) StreamUniformBuffer.IncreaseUsedCount(m_CurImageIndex); Buffer = BufferOfFrame.m_Buffer; BufferMem = BufferOfFrame.m_BufferMem; Offset = BufferOfFrame.m_UsedSize; BufferOfFrame.m_UsedSize += DataSize; pMem = (uint8_t *)BufferOfFrame.m_pMappedBufferData; pBufferMem = &BufferOfFrame; break; } } if(BufferMem.m_Mem == VK_NULL_HANDLE) { // create memory VkBuffer StreamBuffer; SDeviceMemoryBlock StreamBufferMemory; const VkDeviceSize NewBufferSingleSize = sizeof(TInstanceTypeName) * InstanceTypeCount; const VkDeviceSize NewBufferSize = NewBufferSingleSize * BufferCreateCount; CreateBuffer(NewBufferSize, MEMORY_BLOCK_USAGE_STREAM, Usage, VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT | VK_MEMORY_PROPERTY_HOST_CACHED_BIT, StreamBuffer, StreamBufferMemory); void *pMappedData = nullptr; vkMapMemory(m_VKDevice, StreamBufferMemory.m_Mem, 0, VK_WHOLE_SIZE, 0, &pMappedData); size_t NewBufferIndex = StreamUniformBuffer.GetBuffers(m_CurImageIndex).size(); for(size_t i = 0; i < BufferCreateCount; ++i) { StreamUniformBuffer.GetBuffers(m_CurImageIndex).push_back(TStreamMemName(StreamBuffer, StreamBufferMemory, NewBufferSingleSize * i, NewBufferSingleSize, 0, ((uint8_t *)pMappedData) + (NewBufferSingleSize * i))); StreamUniformBuffer.GetRanges(m_CurImageIndex).push_back({}); NewMemFunc(StreamUniformBuffer.GetBuffers(m_CurImageIndex).back(), StreamBuffer, NewBufferSingleSize * i); } auto &NewStreamBuffer = StreamUniformBuffer.GetBuffers(m_CurImageIndex)[NewBufferIndex]; Buffer = StreamBuffer; BufferMem = StreamBufferMemory; pBufferMem = &NewStreamBuffer; pMem = (uint8_t *)NewStreamBuffer.m_pMappedBufferData; Offset = NewStreamBuffer.m_OffsetInBuffer; NewStreamBuffer.m_UsedSize += DataSize; StreamUniformBuffer.IncreaseUsedCount(m_CurImageIndex); } { mem_copy(pMem + Offset, pData, (size_t)DataSize); } NewBuffer = Buffer; NewBufferMem = BufferMem; BufferOffset = Offset; } void CreateStreamVertexBuffer(size_t RenderThreadIndex, VkBuffer &NewBuffer, SDeviceMemoryBlock &NewBufferMem, size_t &BufferOffset, const void *pData, size_t DataSize) { SFrameBuffers *pStreamBuffer; CreateStreamBuffer( pStreamBuffer, [](SFrameBuffers &, VkBuffer, VkDeviceSize) {}, m_vStreamedVertexBuffers[RenderThreadIndex], VK_BUFFER_USAGE_VERTEX_BUFFER_BIT, NewBuffer, NewBufferMem, BufferOffset, pData, DataSize); } template void GetUniformBufferObjectImpl(size_t RenderThreadIndex, bool RequiresSharedStagesDescriptor, SStreamMemory &StreamUniformBuffer, SDeviceDescriptorSet &DescrSet, const void *pData, size_t DataSize) { VkBuffer NewBuffer; SDeviceMemoryBlock NewBufferMem; size_t BufferOffset; SFrameUniformBuffers *pMem; CreateStreamBuffer( pMem, [this, RenderThreadIndex](SFrameBuffers &Mem, VkBuffer Buffer, VkDeviceSize MemOffset) { CreateUniformDescriptorSets(RenderThreadIndex, m_SpriteMultiUniformDescriptorSetLayout, ((SFrameUniformBuffers *)(&Mem))->m_aUniformSets.data(), 1, Buffer, InstanceMaxParticleCount * sizeof(TName), MemOffset); CreateUniformDescriptorSets(RenderThreadIndex, m_QuadUniformDescriptorSetLayout, &((SFrameUniformBuffers *)(&Mem))->m_aUniformSets[1], 1, Buffer, InstanceMaxParticleCount * sizeof(TName), MemOffset); }, StreamUniformBuffer, VK_BUFFER_USAGE_UNIFORM_BUFFER_BIT, NewBuffer, NewBufferMem, BufferOffset, pData, DataSize); DescrSet = pMem->m_aUniformSets[RequiresSharedStagesDescriptor ? 1 : 0]; } void GetUniformBufferObject(size_t RenderThreadIndex, bool RequiresSharedStagesDescriptor, SDeviceDescriptorSet &DescrSet, size_t ParticleCount, const void *pData, size_t DataSize) { GetUniformBufferObjectImpl(RenderThreadIndex, RequiresSharedStagesDescriptor, m_vStreamedUniformBuffers[RenderThreadIndex], DescrSet, pData, DataSize); } bool CreateIndexBuffer(void *pData, size_t DataSize, VkBuffer &Buffer, SDeviceMemoryBlock &Memory) { VkDeviceSize BufferDataSize = DataSize; auto StagingBuffer = GetStagingBuffer(pData, DataSize); SDeviceMemoryBlock VertexBufferMemory; VkBuffer VertexBuffer; CreateBuffer(BufferDataSize, MEMORY_BLOCK_USAGE_BUFFER, VK_BUFFER_USAGE_TRANSFER_DST_BIT | VK_BUFFER_USAGE_INDEX_BUFFER_BIT, VK_MEMORY_PROPERTY_DEVICE_LOCAL_BIT, VertexBuffer, VertexBufferMemory); MemoryBarrier(VertexBuffer, 0, BufferDataSize, VK_ACCESS_INDEX_READ_BIT, true); CopyBuffer(StagingBuffer.m_Buffer, VertexBuffer, StagingBuffer.m_HeapData.m_OffsetToAlign, 0, BufferDataSize); MemoryBarrier(VertexBuffer, 0, BufferDataSize, VK_ACCESS_INDEX_READ_BIT, false); UploadAndFreeStagingMemBlock(StagingBuffer); Buffer = VertexBuffer; Memory = VertexBufferMemory; return true; } void DestroyIndexBuffer(VkBuffer &Buffer, SDeviceMemoryBlock &Memory) { CleanBufferPair(0, Buffer, Memory); } /************************ * COMMAND IMPLEMENTATION ************************/ template static bool IsInCommandRange(TName CMD, TName Min, TName Max) { return CMD >= Min && CMD < Max; } bool RunCommand(const CCommandBuffer::SCommand *pBaseCommand) override { if(IsInCommandRangem_Cmd)>(pBaseCommand->m_Cmd, CCommandBuffer::CMD_FIRST, CCommandBuffer::CMD_COUNT)) { auto &CallbackObj = m_aCommandCallbacks[CommandBufferCMDOff(CCommandBuffer::ECommandBufferCMD(pBaseCommand->m_Cmd))]; SRenderCommandExecuteBuffer Buffer; Buffer.m_Command = (CCommandBuffer::ECommandBufferCMD)pBaseCommand->m_Cmd; Buffer.m_pRawCommand = pBaseCommand; Buffer.m_ThreadIndex = 0; if(m_CurCommandInPipe + 1 == m_CommandsInPipe && Buffer.m_Command != CCommandBuffer::CMD_FINISH) { m_LastCommandsInPipeThreadIndex = std::numeric_limits::max(); } bool CanStartThread = false; if(CallbackObj.m_IsRenderCommand) { bool ForceSingleThread = m_LastCommandsInPipeThreadIndex == std::numeric_limits::max(); size_t PotentiallyNextThread = (((m_CurCommandInPipe * (m_ThreadCount - 1)) / m_CommandsInPipe) + 1); if(PotentiallyNextThread - 1 > m_LastCommandsInPipeThreadIndex) { CanStartThread = true; m_LastCommandsInPipeThreadIndex = PotentiallyNextThread - 1; } Buffer.m_ThreadIndex = m_ThreadCount > 1 && !ForceSingleThread ? (m_LastCommandsInPipeThreadIndex + 1) : 0; CallbackObj.m_FillExecuteBuffer(Buffer, pBaseCommand); m_CurRenderCallCountInPipe += Buffer.m_EstimatedRenderCallCount; } bool Ret = true; if(!CallbackObj.m_IsRenderCommand || (Buffer.m_ThreadIndex == 0 && !m_RenderingPaused)) { Ret = CallbackObj.m_CommandCB(pBaseCommand, Buffer); } else if(!m_RenderingPaused) { if(CanStartThread) { StartRenderThread(m_LastCommandsInPipeThreadIndex - 1); } m_ThreadCommandLists[Buffer.m_ThreadIndex - 1].push_back(Buffer); } ++m_CurCommandInPipe; return Ret; } if(m_CurCommandInPipe + 1 == m_CommandsInPipe) { m_LastCommandsInPipeThreadIndex = std::numeric_limits::max(); } ++m_CurCommandInPipe; switch(pBaseCommand->m_Cmd) { case CCommandProcessorFragment_GLBase::CMD_INIT: Cmd_Init(static_cast(pBaseCommand)); break; case CCommandProcessorFragment_GLBase::CMD_SHUTDOWN: Cmd_Shutdown(static_cast(pBaseCommand)); break; case CCommandProcessorFragment_GLBase::CMD_PRE_INIT: Cmd_PreInit(static_cast(pBaseCommand)); break; case CCommandProcessorFragment_GLBase::CMD_POST_SHUTDOWN: Cmd_PostShutdown(static_cast(pBaseCommand)); break; default: return false; } return true; } void Cmd_Init(const SCommand_Init *pCommand) { pCommand->m_pCapabilities->m_TileBuffering = true; pCommand->m_pCapabilities->m_QuadBuffering = true; pCommand->m_pCapabilities->m_TextBuffering = true; pCommand->m_pCapabilities->m_QuadContainerBuffering = true; pCommand->m_pCapabilities->m_ShaderSupport = true; pCommand->m_pCapabilities->m_MipMapping = true; pCommand->m_pCapabilities->m_3DTextures = false; pCommand->m_pCapabilities->m_2DArrayTextures = true; pCommand->m_pCapabilities->m_NPOTTextures = true; pCommand->m_pCapabilities->m_ContextMajor = 1; pCommand->m_pCapabilities->m_ContextMinor = 1; pCommand->m_pCapabilities->m_ContextPatch = 0; pCommand->m_pCapabilities->m_TrianglesAsQuads = true; m_GlobalTextureLodBIAS = g_Config.m_GfxGLTextureLODBIAS; m_pTextureMemoryUsage = pCommand->m_pTextureMemoryUsage; m_pBufferMemoryUsage = pCommand->m_pBufferMemoryUsage; m_pStreamMemoryUsage = pCommand->m_pStreamMemoryUsage; m_pStagingMemoryUsage = pCommand->m_pStagingMemoryUsage; m_MultiSamplingCount = (g_Config.m_GfxFsaaSamples & 0xFFFFFFFE); // ignore the uneven bit, only even multi sampling works TGLBackendReadPresentedImageData &ReadPresentedImgDataFunc = *pCommand->m_pReadPresentedImageDataFunc; ReadPresentedImgDataFunc = [this](uint32_t &Width, uint32_t &Height, uint32_t &Format, std::vector &DstData) { return GetPresentedImageData(Width, Height, Format, DstData); }; m_pWindow = pCommand->m_pWindow; *pCommand->m_pInitError = m_VKInstance != VK_NULL_HANDLE ? 0 : -1; if(m_VKInstance == VK_NULL_HANDLE) { *pCommand->m_pInitError = -2; return; } m_pStorage = pCommand->m_pStorage; if(InitVulkan() != 0) { *pCommand->m_pInitError = -2; return; } std::array aIndices; int Primq = 0; for(int i = 0; i < CCommandBuffer::MAX_VERTICES / 4 * 6; i += 6) { aIndices[i] = Primq; aIndices[i + 1] = Primq + 1; aIndices[i + 2] = Primq + 2; aIndices[i + 3] = Primq; aIndices[i + 4] = Primq + 2; aIndices[i + 5] = Primq + 3; Primq += 4; } PrepareFrame(); if(m_HasError) { *pCommand->m_pInitError = -2; return; } if(!CreateIndexBuffer(aIndices.data(), sizeof(uint32_t) * aIndices.size(), m_IndexBuffer, m_IndexBufferMemory)) { *pCommand->m_pInitError = -2; return; } if(!CreateIndexBuffer(aIndices.data(), sizeof(uint32_t) * aIndices.size(), m_RenderIndexBuffer, m_RenderIndexBufferMemory)) { *pCommand->m_pInitError = -2; return; } m_CurRenderIndexPrimitiveCount = CCommandBuffer::MAX_VERTICES / 4; m_CanAssert = true; } void Cmd_Shutdown(const SCommand_Shutdown *pCommand) { vkDeviceWaitIdle(m_VKDevice); DestroyIndexBuffer(m_IndexBuffer, m_IndexBufferMemory); DestroyIndexBuffer(m_RenderIndexBuffer, m_RenderIndexBufferMemory); CleanupVulkan(); } void Cmd_Texture_Update(const CCommandBuffer::SCommand_Texture_Update *pCommand) { size_t IndexTex = pCommand->m_Slot; void *pData = pCommand->m_pData; UpdateTexture(IndexTex, VK_FORMAT_B8G8R8A8_UNORM, pData, pCommand->m_X, pCommand->m_Y, pCommand->m_Width, pCommand->m_Height, TexFormatToImageColorChannelCount(pCommand->m_Format)); free(pData); } void Cmd_Texture_Destroy(const CCommandBuffer::SCommand_Texture_Destroy *pCommand) { size_t ImageIndex = (size_t)pCommand->m_Slot; auto &Texture = m_Textures[ImageIndex]; m_FrameDelayedTextureCleanup[m_CurImageIndex].push_back(Texture); Texture = CTexture{}; } void Cmd_Texture_Create(const CCommandBuffer::SCommand_Texture_Create *pCommand) { int Slot = pCommand->m_Slot; int Width = pCommand->m_Width; int Height = pCommand->m_Height; int PixelSize = pCommand->m_PixelSize; int Format = pCommand->m_Format; int StoreFormat = pCommand->m_StoreFormat; int Flags = pCommand->m_Flags; void *pData = pCommand->m_pData; CreateTextureCMD(Slot, Width, Height, PixelSize, TextureFormatToVulkanFormat(Format), TextureFormatToVulkanFormat(StoreFormat), Flags, pData); free(pData); } void Cmd_TextTextures_Create(const CCommandBuffer::SCommand_TextTextures_Create *pCommand) { int Slot = pCommand->m_Slot; int SlotOutline = pCommand->m_SlotOutline; int Width = pCommand->m_Width; int Height = pCommand->m_Height; void *pTmpData = pCommand->m_pTextData; void *pTmpData2 = pCommand->m_pTextOutlineData; CreateTextureCMD(Slot, Width, Height, 1, VK_FORMAT_R8_UNORM, VK_FORMAT_R8_UNORM, CCommandBuffer::TEXFLAG_NOMIPMAPS, pTmpData); CreateTextureCMD(SlotOutline, Width, Height, 1, VK_FORMAT_R8_UNORM, VK_FORMAT_R8_UNORM, CCommandBuffer::TEXFLAG_NOMIPMAPS, pTmpData2); CreateNewTextDescriptorSets(Slot, SlotOutline); free(pTmpData); free(pTmpData2); } void Cmd_TextTextures_Destroy(const CCommandBuffer::SCommand_TextTextures_Destroy *pCommand) { size_t ImageIndex = (size_t)pCommand->m_Slot; size_t ImageIndexOutline = (size_t)pCommand->m_SlotOutline; auto &Texture = m_Textures[ImageIndex]; auto &TextureOutline = m_Textures[ImageIndexOutline]; m_FrameDelayedTextTexturesCleanup[m_CurImageIndex].push_back({Texture, TextureOutline}); Texture = {}; TextureOutline = {}; } void Cmd_TextTexture_Update(const CCommandBuffer::SCommand_TextTexture_Update *pCommand) { size_t IndexTex = pCommand->m_Slot; void *pData = pCommand->m_pData; UpdateTexture(IndexTex, VK_FORMAT_R8_UNORM, pData, pCommand->m_X, pCommand->m_Y, pCommand->m_Width, pCommand->m_Height, 1); free(pData); } void Cmd_Clear_FillExecuteBuffer(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand_Clear *pCommand) { if(!pCommand->m_ForceClear) { bool ColorChanged = m_aClearColor[0] != pCommand->m_Color.r || m_aClearColor[1] != pCommand->m_Color.g || m_aClearColor[2] != pCommand->m_Color.b || m_aClearColor[3] != pCommand->m_Color.a; m_aClearColor[0] = pCommand->m_Color.r; m_aClearColor[1] = pCommand->m_Color.g; m_aClearColor[2] = pCommand->m_Color.b; m_aClearColor[3] = pCommand->m_Color.a; if(ColorChanged) ExecBuffer.m_ClearColorInRenderThread = true; } else { ExecBuffer.m_ClearColorInRenderThread = true; } ExecBuffer.m_EstimatedRenderCallCount = 0; } void Cmd_Clear(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand_Clear *pCommand) { if(ExecBuffer.m_ClearColorInRenderThread) { std::array aAttachments = {VkClearAttachment{VK_IMAGE_ASPECT_COLOR_BIT, 0, VkClearValue{VkClearColorValue{{pCommand->m_Color.r, pCommand->m_Color.g, pCommand->m_Color.b, pCommand->m_Color.a}}}}}; std::array aClearRects = {VkClearRect{{{0, 0}, m_VKSwapImgAndViewportExtent.m_SwapImg}, 0, 1}}; vkCmdClearAttachments(GetGraphicCommandBuffer(ExecBuffer.m_ThreadIndex), aAttachments.size(), aAttachments.data(), aClearRects.size(), aClearRects.data()); } } void Cmd_Render_FillExecuteBuffer(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand_Render *pCommand) { bool IsTextured = GetIsTextured(pCommand->m_State); if(IsTextured) { size_t AddressModeIndex = GetAddressModeIndex(pCommand->m_State); auto &DescrSet = m_Textures[pCommand->m_State.m_Texture].m_aVKStandardTexturedDescrSets[AddressModeIndex]; ExecBuffer.m_aDescriptors[0] = DescrSet; } ExecBuffer.m_IndexBuffer = m_IndexBuffer; ExecBuffer.m_EstimatedRenderCallCount = 1; ExecBufferFillDynamicStates(pCommand->m_State, ExecBuffer); } void Cmd_Render(const CCommandBuffer::SCommand_Render *pCommand, SRenderCommandExecuteBuffer &ExecBuffer) { RenderStandard(ExecBuffer, pCommand->m_State, pCommand->m_PrimType, pCommand->m_pVertices, pCommand->m_PrimCount); } void Cmd_Screenshot(const CCommandBuffer::SCommand_TrySwapAndScreenshot *pCommand) { NextFrame(); *pCommand->m_pSwapped = true; uint32_t Width; uint32_t Height; uint32_t Format; if(GetPresentedImageDataImpl(Width, Height, Format, m_ScreenshotHelper, false, true)) { size_t ImgSize = (size_t)Width * (size_t)Height * (size_t)4; pCommand->m_pImage->m_pData = malloc(ImgSize); mem_copy(pCommand->m_pImage->m_pData, m_ScreenshotHelper.data(), ImgSize); } else { pCommand->m_pImage->m_pData = nullptr; } pCommand->m_pImage->m_Width = (int)Width; pCommand->m_pImage->m_Height = (int)Height; pCommand->m_pImage->m_Format = (int)Format; } void Cmd_RenderTex3D_FillExecuteBuffer(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand_RenderTex3D *pCommand) { bool IsTextured = GetIsTextured(pCommand->m_State); if(IsTextured) { auto &DescrSet = m_Textures[pCommand->m_State.m_Texture].m_VKStandard3DTexturedDescrSet; ExecBuffer.m_aDescriptors[0] = DescrSet; } ExecBuffer.m_IndexBuffer = m_IndexBuffer; ExecBuffer.m_EstimatedRenderCallCount = 1; ExecBufferFillDynamicStates(pCommand->m_State, ExecBuffer); } void Cmd_RenderTex3D(const CCommandBuffer::SCommand_RenderTex3D *pCommand, SRenderCommandExecuteBuffer &ExecBuffer) { RenderStandard(ExecBuffer, pCommand->m_State, pCommand->m_PrimType, pCommand->m_pVertices, pCommand->m_PrimCount); } void Cmd_Update_Viewport_FillExecuteBuffer(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand_Update_Viewport *pCommand) { ExecBuffer.m_EstimatedRenderCallCount = 0; } void Cmd_Update_Viewport(const CCommandBuffer::SCommand_Update_Viewport *pCommand) { if(pCommand->m_ByResize) { if(IsVerbose()) { dbg_msg("vulkan", "queueing swap chain recreation because the viewport changed"); } m_CanvasWidth = (uint32_t)pCommand->m_Width; m_CanvasHeight = (uint32_t)pCommand->m_Height; m_RecreateSwapChain = true; } else if(!pCommand->m_ByResize) { if(pCommand->m_X != 0 || pCommand->m_Y != 0 || (uint32_t)pCommand->m_Width != m_VKSwapImgAndViewportExtent.m_Viewport.width || (uint32_t)pCommand->m_Height != m_VKSwapImgAndViewportExtent.m_Viewport.height) { m_HasDynamicViewport = true; // convert viewport from OGL to vulkan int32_t ViewportY = (int32_t)m_VKSwapImgAndViewportExtent.m_Viewport.height - ((int32_t)pCommand->m_Y + (int32_t)pCommand->m_Height); uint32_t ViewportH = (int32_t)pCommand->m_Height; m_DynamicViewportOffset = {(int32_t)pCommand->m_X, ViewportY}; m_DynamicViewportSize = {(uint32_t)pCommand->m_Width, ViewportH}; } else { m_HasDynamicViewport = false; } } } void Cmd_VSync(const CCommandBuffer::SCommand_VSync *pCommand) { if(IsVerbose()) { dbg_msg("vulkan", "queueing swap chain recreation because vsync was changed"); } m_RecreateSwapChain = true; *pCommand->m_pRetOk = true; } void Cmd_Finish(const CCommandBuffer::SCommand_Finish *pCommand) { // just ignore it with vulkan } void Cmd_Swap(const CCommandBuffer::SCommand_Swap *pCommand) { NextFrame(); } void Cmd_CreateBufferObject(const CCommandBuffer::SCommand_CreateBufferObject *pCommand) { bool IsOneFrameBuffer = (pCommand->m_Flags & IGraphics::EBufferObjectCreateFlags::BUFFER_OBJECT_CREATE_FLAGS_ONE_TIME_USE_BIT) != 0; CreateBufferObject((size_t)pCommand->m_BufferIndex, pCommand->m_pUploadData, (VkDeviceSize)pCommand->m_DataSize, IsOneFrameBuffer); if(pCommand->m_DeletePointer) free(pCommand->m_pUploadData); } void Cmd_UpdateBufferObject(const CCommandBuffer::SCommand_UpdateBufferObject *pCommand) { size_t BufferIndex = (size_t)pCommand->m_BufferIndex; bool DeletePointer = pCommand->m_DeletePointer; VkDeviceSize Offset = (VkDeviceSize)((intptr_t)pCommand->m_pOffset); void *pUploadData = pCommand->m_pUploadData; VkDeviceSize DataSize = (VkDeviceSize)pCommand->m_DataSize; auto StagingBuffer = GetStagingBuffer(pUploadData, DataSize); auto &MemBlock = m_BufferObjects[BufferIndex].m_BufferObject.m_Mem; VkBuffer VertexBuffer = MemBlock.m_Buffer; MemoryBarrier(VertexBuffer, Offset + MemBlock.m_HeapData.m_OffsetToAlign, DataSize, VK_ACCESS_VERTEX_ATTRIBUTE_READ_BIT, true); CopyBuffer(StagingBuffer.m_Buffer, VertexBuffer, StagingBuffer.m_HeapData.m_OffsetToAlign, Offset + MemBlock.m_HeapData.m_OffsetToAlign, DataSize); MemoryBarrier(VertexBuffer, Offset + MemBlock.m_HeapData.m_OffsetToAlign, DataSize, VK_ACCESS_VERTEX_ATTRIBUTE_READ_BIT, false); UploadAndFreeStagingMemBlock(StagingBuffer); if(DeletePointer) free(pUploadData); } void Cmd_RecreateBufferObject(const CCommandBuffer::SCommand_RecreateBufferObject *pCommand) { DeleteBufferObject((size_t)pCommand->m_BufferIndex); bool IsOneFrameBuffer = (pCommand->m_Flags & IGraphics::EBufferObjectCreateFlags::BUFFER_OBJECT_CREATE_FLAGS_ONE_TIME_USE_BIT) != 0; CreateBufferObject((size_t)pCommand->m_BufferIndex, pCommand->m_pUploadData, (VkDeviceSize)pCommand->m_DataSize, IsOneFrameBuffer); } void Cmd_CopyBufferObject(const CCommandBuffer::SCommand_CopyBufferObject *pCommand) { size_t ReadBufferIndex = (size_t)pCommand->m_ReadBufferIndex; size_t WriteBufferIndex = (size_t)pCommand->m_WriteBufferIndex; auto &ReadMemBlock = m_BufferObjects[ReadBufferIndex].m_BufferObject.m_Mem; auto &WriteMemBlock = m_BufferObjects[WriteBufferIndex].m_BufferObject.m_Mem; VkBuffer ReadBuffer = ReadMemBlock.m_Buffer; VkBuffer WriteBuffer = WriteMemBlock.m_Buffer; VkDeviceSize DataSize = (VkDeviceSize)pCommand->m_CopySize; VkDeviceSize ReadOffset = (VkDeviceSize)pCommand->m_pReadOffset + ReadMemBlock.m_HeapData.m_OffsetToAlign; VkDeviceSize WriteOffset = (VkDeviceSize)pCommand->m_pWriteOffset + WriteMemBlock.m_HeapData.m_OffsetToAlign; MemoryBarrier(ReadBuffer, ReadOffset, DataSize, VK_ACCESS_VERTEX_ATTRIBUTE_READ_BIT, true); MemoryBarrier(WriteBuffer, WriteOffset, DataSize, VK_ACCESS_VERTEX_ATTRIBUTE_READ_BIT, true); CopyBuffer(ReadBuffer, WriteBuffer, ReadOffset, WriteOffset, DataSize); MemoryBarrier(WriteBuffer, WriteOffset, DataSize, VK_ACCESS_VERTEX_ATTRIBUTE_READ_BIT, false); MemoryBarrier(ReadBuffer, ReadOffset, DataSize, VK_ACCESS_VERTEX_ATTRIBUTE_READ_BIT, false); } void Cmd_DeleteBufferObject(const CCommandBuffer::SCommand_DeleteBufferObject *pCommand) { size_t BufferIndex = (size_t)pCommand->m_BufferIndex; DeleteBufferObject(BufferIndex); } void Cmd_CreateBufferContainer(const CCommandBuffer::SCommand_CreateBufferContainer *pCommand) { size_t ContainerIndex = (size_t)pCommand->m_BufferContainerIndex; while(ContainerIndex >= m_BufferContainers.size()) m_BufferContainers.resize((m_BufferContainers.size() * 2) + 1); m_BufferContainers[ContainerIndex].m_BufferObjectIndex = pCommand->m_VertBufferBindingIndex; } void Cmd_UpdateBufferContainer(const CCommandBuffer::SCommand_UpdateBufferContainer *pCommand) { size_t ContainerIndex = (size_t)pCommand->m_BufferContainerIndex; m_BufferContainers[ContainerIndex].m_BufferObjectIndex = pCommand->m_VertBufferBindingIndex; } void Cmd_DeleteBufferContainer(const CCommandBuffer::SCommand_DeleteBufferContainer *pCommand) { size_t ContainerIndex = (size_t)pCommand->m_BufferContainerIndex; bool DeleteAllBO = pCommand->m_DestroyAllBO; if(DeleteAllBO) { size_t BufferIndex = (size_t)m_BufferContainers[ContainerIndex].m_BufferObjectIndex; DeleteBufferObject(BufferIndex); } } void Cmd_IndicesRequiredNumNotify(const CCommandBuffer::SCommand_IndicesRequiredNumNotify *pCommand) { size_t IndicesCount = pCommand->m_RequiredIndicesNum; if(m_CurRenderIndexPrimitiveCount < IndicesCount / 6) { m_FrameDelayedBufferCleanup[m_CurImageIndex].push_back({m_RenderIndexBuffer, m_RenderIndexBufferMemory}); std::vector Indices(IndicesCount); uint32_t Primq = 0; for(size_t i = 0; i < IndicesCount; i += 6) { Indices[i] = Primq; Indices[i + 1] = Primq + 1; Indices[i + 2] = Primq + 2; Indices[i + 3] = Primq; Indices[i + 4] = Primq + 2; Indices[i + 5] = Primq + 3; Primq += 4; } CreateIndexBuffer(Indices.data(), Indices.size() * sizeof(uint32_t), m_RenderIndexBuffer, m_RenderIndexBufferMemory); m_CurRenderIndexPrimitiveCount = IndicesCount / 6; } } void Cmd_RenderTileLayer_FillExecuteBuffer(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand_RenderTileLayer *pCommand) { RenderTileLayer_FillExecuteBuffer(ExecBuffer, pCommand->m_IndicesDrawNum, pCommand->m_State, pCommand->m_BufferContainerIndex); } void Cmd_RenderTileLayer(const CCommandBuffer::SCommand_RenderTileLayer *pCommand, SRenderCommandExecuteBuffer &ExecBuffer) { int Type = 0; vec2 Dir{}; vec2 Off{}; int32_t JumpIndex = 0; RenderTileLayer(ExecBuffer, pCommand->m_State, Type, pCommand->m_Color, Dir, Off, JumpIndex, (size_t)pCommand->m_IndicesDrawNum, pCommand->m_pIndicesOffsets, pCommand->m_pDrawCount, 1); } void Cmd_RenderBorderTile_FillExecuteBuffer(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand_RenderBorderTile *pCommand) { RenderTileLayer_FillExecuteBuffer(ExecBuffer, 1, pCommand->m_State, pCommand->m_BufferContainerIndex); } void Cmd_RenderBorderTile(const CCommandBuffer::SCommand_RenderBorderTile *pCommand, SRenderCommandExecuteBuffer &ExecBuffer) { int Type = 1; vec2 Dir = {pCommand->m_Dir[0], pCommand->m_Dir[1]}; vec2 Off = {pCommand->m_Offset[0], pCommand->m_Offset[1]}; unsigned int DrawNum = 6; RenderTileLayer(ExecBuffer, pCommand->m_State, Type, pCommand->m_Color, Dir, Off, pCommand->m_JumpIndex, (size_t)1, &pCommand->m_pIndicesOffset, &DrawNum, pCommand->m_DrawNum); } void Cmd_RenderBorderTileLine_FillExecuteBuffer(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand_RenderBorderTileLine *pCommand) { RenderTileLayer_FillExecuteBuffer(ExecBuffer, 1, pCommand->m_State, pCommand->m_BufferContainerIndex); } void Cmd_RenderBorderTileLine(const CCommandBuffer::SCommand_RenderBorderTileLine *pCommand, SRenderCommandExecuteBuffer &ExecBuffer) { int Type = 2; vec2 Dir = {pCommand->m_Dir[0], pCommand->m_Dir[1]}; vec2 Off = {pCommand->m_Offset[0], pCommand->m_Offset[1]}; RenderTileLayer(ExecBuffer, pCommand->m_State, Type, pCommand->m_Color, Dir, Off, 0, (size_t)1, &pCommand->m_pIndicesOffset, &pCommand->m_IndexDrawNum, pCommand->m_DrawNum); } void Cmd_RenderQuadLayer_FillExecuteBuffer(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand_RenderQuadLayer *pCommand) { size_t BufferContainerIndex = (size_t)pCommand->m_BufferContainerIndex; size_t BufferObjectIndex = (size_t)m_BufferContainers[BufferContainerIndex].m_BufferObjectIndex; auto &BufferObject = m_BufferObjects[BufferObjectIndex]; ExecBuffer.m_Buffer = BufferObject.m_CurBuffer; ExecBuffer.m_BufferOff = BufferObject.m_CurBufferOffset; bool IsTextured = GetIsTextured(pCommand->m_State); if(IsTextured) { size_t AddressModeIndex = GetAddressModeIndex(pCommand->m_State); auto &DescrSet = m_Textures[pCommand->m_State.m_Texture].m_aVKStandardTexturedDescrSets[AddressModeIndex]; ExecBuffer.m_aDescriptors[0] = DescrSet; } ExecBuffer.m_IndexBuffer = m_RenderIndexBuffer; ExecBuffer.m_EstimatedRenderCallCount = ((pCommand->m_QuadNum - 1) / gs_GraphicsMaxQuadsRenderCount) + 1; ExecBufferFillDynamicStates(pCommand->m_State, ExecBuffer); } void Cmd_RenderQuadLayer(const CCommandBuffer::SCommand_RenderQuadLayer *pCommand, SRenderCommandExecuteBuffer &ExecBuffer) { std::array m; GetStateMatrix(pCommand->m_State, m); bool CanBePushed = pCommand->m_QuadNum == 1; bool IsTextured; size_t BlendModeIndex; size_t DynamicIndex; size_t AddressModeIndex; GetStateIndices(ExecBuffer, pCommand->m_State, IsTextured, BlendModeIndex, DynamicIndex, AddressModeIndex); auto &PipeLayout = GetPipeLayout(CanBePushed ? m_QuadPushPipeline : m_QuadPipeline, IsTextured, BlendModeIndex, DynamicIndex); auto &PipeLine = GetPipeline(CanBePushed ? m_QuadPushPipeline : m_QuadPipeline, IsTextured, BlendModeIndex, DynamicIndex); auto &CommandBuffer = GetGraphicCommandBuffer(ExecBuffer.m_ThreadIndex); BindPipeline(ExecBuffer.m_ThreadIndex, CommandBuffer, ExecBuffer, PipeLine, pCommand->m_State); std::array aVertexBuffers = {ExecBuffer.m_Buffer}; std::array aOffsets = {(VkDeviceSize)ExecBuffer.m_BufferOff}; vkCmdBindVertexBuffers(CommandBuffer, 0, 1, aVertexBuffers.data(), aOffsets.data()); vkCmdBindIndexBuffer(CommandBuffer, ExecBuffer.m_IndexBuffer, 0, VK_INDEX_TYPE_UINT32); if(IsTextured) { vkCmdBindDescriptorSets(CommandBuffer, VK_PIPELINE_BIND_POINT_GRAPHICS, PipeLayout, 0, 1, &ExecBuffer.m_aDescriptors[0].m_Descriptor, 0, nullptr); } if(CanBePushed) { SUniformQuadPushGPos PushConstantVertex; mem_copy(&PushConstantVertex.m_BOPush, &pCommand->m_pQuadInfo[0], sizeof(PushConstantVertex.m_BOPush)); mem_copy(PushConstantVertex.m_aPos, m.data(), sizeof(PushConstantVertex.m_aPos)); PushConstantVertex.m_QuadOffset = pCommand->m_QuadOffset; vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT, 0, sizeof(SUniformQuadPushGPos), &PushConstantVertex); } else { SUniformQuadGPos PushConstantVertex; mem_copy(PushConstantVertex.m_aPos, m.data(), sizeof(PushConstantVertex.m_aPos)); PushConstantVertex.m_QuadOffset = pCommand->m_QuadOffset; vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_VERTEX_BIT, 0, sizeof(PushConstantVertex), &PushConstantVertex); } uint32_t DrawCount = (uint32_t)pCommand->m_QuadNum; size_t RenderOffset = 0; while(DrawCount > 0) { uint32_t RealDrawCount = (DrawCount > gs_GraphicsMaxQuadsRenderCount ? gs_GraphicsMaxQuadsRenderCount : DrawCount); VkDeviceSize IndexOffset = (VkDeviceSize)((ptrdiff_t)(pCommand->m_QuadOffset + RenderOffset) * 6); if(!CanBePushed) { // create uniform buffer SDeviceDescriptorSet UniDescrSet; GetUniformBufferObject(ExecBuffer.m_ThreadIndex, true, UniDescrSet, RealDrawCount, (const float *)(pCommand->m_pQuadInfo + RenderOffset), RealDrawCount * sizeof(SQuadRenderInfo)); vkCmdBindDescriptorSets(CommandBuffer, VK_PIPELINE_BIND_POINT_GRAPHICS, PipeLayout, IsTextured ? 1 : 0, 1, &UniDescrSet.m_Descriptor, 0, nullptr); if(RenderOffset > 0) { int32_t QuadOffset = pCommand->m_QuadOffset + RenderOffset; vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_VERTEX_BIT, sizeof(SUniformQuadGPos) - sizeof(int32_t), sizeof(int32_t), &QuadOffset); } } vkCmdDrawIndexed(CommandBuffer, static_cast(RealDrawCount * 6), 1, IndexOffset, 0, 0); RenderOffset += RealDrawCount; DrawCount -= RealDrawCount; } } void Cmd_RenderText_FillExecuteBuffer(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand_RenderText *pCommand) { size_t BufferContainerIndex = (size_t)pCommand->m_BufferContainerIndex; size_t BufferObjectIndex = (size_t)m_BufferContainers[BufferContainerIndex].m_BufferObjectIndex; auto &BufferObject = m_BufferObjects[BufferObjectIndex]; ExecBuffer.m_Buffer = BufferObject.m_CurBuffer; ExecBuffer.m_BufferOff = BufferObject.m_CurBufferOffset; auto &TextTextureDescr = m_Textures[pCommand->m_TextTextureIndex].m_VKTextDescrSet; ExecBuffer.m_aDescriptors[0] = TextTextureDescr; ExecBuffer.m_IndexBuffer = m_RenderIndexBuffer; ExecBuffer.m_EstimatedRenderCallCount = 1; ExecBufferFillDynamicStates(pCommand->m_State, ExecBuffer); } void Cmd_RenderText(const CCommandBuffer::SCommand_RenderText *pCommand, SRenderCommandExecuteBuffer &ExecBuffer) { std::array m; GetStateMatrix(pCommand->m_State, m); bool IsTextured; size_t BlendModeIndex; size_t DynamicIndex; size_t AddressModeIndex; GetStateIndices(ExecBuffer, pCommand->m_State, IsTextured, BlendModeIndex, DynamicIndex, AddressModeIndex); IsTextured = true; // text is always textured auto &PipeLayout = GetPipeLayout(m_TextPipeline, IsTextured, BlendModeIndex, DynamicIndex); auto &PipeLine = GetPipeline(m_TextPipeline, IsTextured, BlendModeIndex, DynamicIndex); auto &CommandBuffer = GetGraphicCommandBuffer(ExecBuffer.m_ThreadIndex); BindPipeline(ExecBuffer.m_ThreadIndex, CommandBuffer, ExecBuffer, PipeLine, pCommand->m_State); std::array aVertexBuffers = {ExecBuffer.m_Buffer}; std::array aOffsets = {(VkDeviceSize)ExecBuffer.m_BufferOff}; vkCmdBindVertexBuffers(CommandBuffer, 0, 1, aVertexBuffers.data(), aOffsets.data()); vkCmdBindIndexBuffer(CommandBuffer, ExecBuffer.m_IndexBuffer, 0, VK_INDEX_TYPE_UINT32); vkCmdBindDescriptorSets(CommandBuffer, VK_PIPELINE_BIND_POINT_GRAPHICS, PipeLayout, 0, 1, &ExecBuffer.m_aDescriptors[0].m_Descriptor, 0, nullptr); SUniformGTextPos PosTexSizeConstant; mem_copy(PosTexSizeConstant.m_aPos, m.data(), m.size() * sizeof(float)); PosTexSizeConstant.m_TextureSize = pCommand->m_TextureSize; vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_VERTEX_BIT, 0, sizeof(SUniformGTextPos), &PosTexSizeConstant); SUniformTextFragment FragmentConstants; mem_copy(FragmentConstants.m_Constants.m_aTextColor, pCommand->m_aTextColor, sizeof(FragmentConstants.m_Constants.m_aTextColor)); mem_copy(FragmentConstants.m_Constants.m_aTextOutlineColor, pCommand->m_aTextOutlineColor, sizeof(FragmentConstants.m_Constants.m_aTextOutlineColor)); vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_FRAGMENT_BIT, sizeof(SUniformGTextPos) + sizeof(SUniformTextGFragmentOffset), sizeof(SUniformTextFragment), &FragmentConstants); vkCmdDrawIndexed(CommandBuffer, static_cast(pCommand->m_DrawNum), 1, 0, 0, 0); } void BufferContainer_FillExecuteBuffer(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SState &State, size_t BufferContainerIndex, size_t DrawCalls) { size_t BufferObjectIndex = (size_t)m_BufferContainers[BufferContainerIndex].m_BufferObjectIndex; auto &BufferObject = m_BufferObjects[BufferObjectIndex]; ExecBuffer.m_Buffer = BufferObject.m_CurBuffer; ExecBuffer.m_BufferOff = BufferObject.m_CurBufferOffset; bool IsTextured = GetIsTextured(State); if(IsTextured) { size_t AddressModeIndex = GetAddressModeIndex(State); auto &DescrSet = m_Textures[State.m_Texture].m_aVKStandardTexturedDescrSets[AddressModeIndex]; ExecBuffer.m_aDescriptors[0] = DescrSet; } ExecBuffer.m_IndexBuffer = m_RenderIndexBuffer; ExecBuffer.m_EstimatedRenderCallCount = DrawCalls; ExecBufferFillDynamicStates(State, ExecBuffer); } void Cmd_RenderQuadContainer_FillExecuteBuffer(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand_RenderQuadContainer *pCommand) { BufferContainer_FillExecuteBuffer(ExecBuffer, pCommand->m_State, (size_t)pCommand->m_BufferContainerIndex, 1); } void Cmd_RenderQuadContainer(const CCommandBuffer::SCommand_RenderQuadContainer *pCommand, SRenderCommandExecuteBuffer &ExecBuffer) { std::array m; GetStateMatrix(pCommand->m_State, m); bool IsTextured; size_t BlendModeIndex; size_t DynamicIndex; size_t AddressModeIndex; GetStateIndices(ExecBuffer, pCommand->m_State, IsTextured, BlendModeIndex, DynamicIndex, AddressModeIndex); auto &PipeLayout = GetStandardPipeLayout(false, IsTextured, BlendModeIndex, DynamicIndex); auto &PipeLine = GetStandardPipe(false, IsTextured, BlendModeIndex, DynamicIndex); auto &CommandBuffer = GetGraphicCommandBuffer(ExecBuffer.m_ThreadIndex); BindPipeline(ExecBuffer.m_ThreadIndex, CommandBuffer, ExecBuffer, PipeLine, pCommand->m_State); std::array aVertexBuffers = {ExecBuffer.m_Buffer}; std::array aOffsets = {(VkDeviceSize)ExecBuffer.m_BufferOff}; vkCmdBindVertexBuffers(CommandBuffer, 0, 1, aVertexBuffers.data(), aOffsets.data()); VkDeviceSize IndexOffset = (VkDeviceSize)((ptrdiff_t)pCommand->m_pOffset); vkCmdBindIndexBuffer(CommandBuffer, ExecBuffer.m_IndexBuffer, IndexOffset, VK_INDEX_TYPE_UINT32); if(IsTextured) { vkCmdBindDescriptorSets(CommandBuffer, VK_PIPELINE_BIND_POINT_GRAPHICS, PipeLayout, 0, 1, &ExecBuffer.m_aDescriptors[0].m_Descriptor, 0, nullptr); } vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_VERTEX_BIT, 0, sizeof(SUniformGPos), m.data()); vkCmdDrawIndexed(CommandBuffer, static_cast(pCommand->m_DrawNum), 1, 0, 0, 0); } void Cmd_RenderQuadContainerEx_FillExecuteBuffer(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand_RenderQuadContainerEx *pCommand) { BufferContainer_FillExecuteBuffer(ExecBuffer, pCommand->m_State, (size_t)pCommand->m_BufferContainerIndex, 1); } void Cmd_RenderQuadContainerEx(const CCommandBuffer::SCommand_RenderQuadContainerEx *pCommand, SRenderCommandExecuteBuffer &ExecBuffer) { std::array m; GetStateMatrix(pCommand->m_State, m); bool IsRotationless = !(pCommand->m_Rotation != 0); bool IsTextured; size_t BlendModeIndex; size_t DynamicIndex; size_t AddressModeIndex; GetStateIndices(ExecBuffer, pCommand->m_State, IsTextured, BlendModeIndex, DynamicIndex, AddressModeIndex); auto &PipeLayout = GetPipeLayout(IsRotationless ? m_PrimExRotationlessPipeline : m_PrimExPipeline, IsTextured, BlendModeIndex, DynamicIndex); auto &PipeLine = GetPipeline(IsRotationless ? m_PrimExRotationlessPipeline : m_PrimExPipeline, IsTextured, BlendModeIndex, DynamicIndex); auto &CommandBuffer = GetGraphicCommandBuffer(ExecBuffer.m_ThreadIndex); BindPipeline(ExecBuffer.m_ThreadIndex, CommandBuffer, ExecBuffer, PipeLine, pCommand->m_State); std::array aVertexBuffers = {ExecBuffer.m_Buffer}; std::array aOffsets = {(VkDeviceSize)ExecBuffer.m_BufferOff}; vkCmdBindVertexBuffers(CommandBuffer, 0, 1, aVertexBuffers.data(), aOffsets.data()); VkDeviceSize IndexOffset = (VkDeviceSize)((ptrdiff_t)pCommand->m_pOffset); vkCmdBindIndexBuffer(CommandBuffer, ExecBuffer.m_IndexBuffer, IndexOffset, VK_INDEX_TYPE_UINT32); if(IsTextured) { vkCmdBindDescriptorSets(CommandBuffer, VK_PIPELINE_BIND_POINT_GRAPHICS, PipeLayout, 0, 1, &ExecBuffer.m_aDescriptors[0].m_Descriptor, 0, nullptr); } SUniformPrimExGVertColor PushConstantColor; SUniformPrimExGPos PushConstantVertex; size_t VertexPushConstantSize = sizeof(PushConstantVertex); mem_copy(PushConstantColor.m_aColor, &pCommand->m_VertexColor, sizeof(PushConstantColor.m_aColor)); mem_copy(PushConstantVertex.m_aPos, m.data(), sizeof(PushConstantVertex.m_aPos)); if(!IsRotationless) { PushConstantVertex.m_Rotation = pCommand->m_Rotation; PushConstantVertex.m_Center = {pCommand->m_Center.x, pCommand->m_Center.y}; } else { VertexPushConstantSize = sizeof(SUniformPrimExGPosRotationless); } vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_VERTEX_BIT, 0, VertexPushConstantSize, &PushConstantVertex); vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_FRAGMENT_BIT, sizeof(SUniformPrimExGPos) + sizeof(SUniformPrimExGVertColorAlign), sizeof(PushConstantColor), &PushConstantColor); vkCmdDrawIndexed(CommandBuffer, static_cast(pCommand->m_DrawNum), 1, 0, 0, 0); } void Cmd_RenderQuadContainerAsSpriteMultiple_FillExecuteBuffer(SRenderCommandExecuteBuffer &ExecBuffer, const CCommandBuffer::SCommand_RenderQuadContainerAsSpriteMultiple *pCommand) { BufferContainer_FillExecuteBuffer(ExecBuffer, pCommand->m_State, (size_t)pCommand->m_BufferContainerIndex, ((pCommand->m_DrawCount - 1) / gs_GraphicsMaxParticlesRenderCount) + 1); } void Cmd_RenderQuadContainerAsSpriteMultiple(const CCommandBuffer::SCommand_RenderQuadContainerAsSpriteMultiple *pCommand, SRenderCommandExecuteBuffer &ExecBuffer) { std::array m; GetStateMatrix(pCommand->m_State, m); bool CanBePushed = pCommand->m_DrawCount <= 1; bool IsTextured; size_t BlendModeIndex; size_t DynamicIndex; size_t AddressModeIndex; GetStateIndices(ExecBuffer, pCommand->m_State, IsTextured, BlendModeIndex, DynamicIndex, AddressModeIndex); auto &PipeLayout = GetPipeLayout(CanBePushed ? m_SpriteMultiPushPipeline : m_SpriteMultiPipeline, IsTextured, BlendModeIndex, DynamicIndex); auto &PipeLine = GetPipeline(CanBePushed ? m_SpriteMultiPushPipeline : m_SpriteMultiPipeline, IsTextured, BlendModeIndex, DynamicIndex); auto &CommandBuffer = GetGraphicCommandBuffer(ExecBuffer.m_ThreadIndex); BindPipeline(ExecBuffer.m_ThreadIndex, CommandBuffer, ExecBuffer, PipeLine, pCommand->m_State); std::array aVertexBuffers = {ExecBuffer.m_Buffer}; std::array aOffsets = {(VkDeviceSize)ExecBuffer.m_BufferOff}; vkCmdBindVertexBuffers(CommandBuffer, 0, 1, aVertexBuffers.data(), aOffsets.data()); VkDeviceSize IndexOffset = (VkDeviceSize)((ptrdiff_t)pCommand->m_pOffset); vkCmdBindIndexBuffer(CommandBuffer, ExecBuffer.m_IndexBuffer, IndexOffset, VK_INDEX_TYPE_UINT32); vkCmdBindDescriptorSets(CommandBuffer, VK_PIPELINE_BIND_POINT_GRAPHICS, PipeLayout, 0, 1, &ExecBuffer.m_aDescriptors[0].m_Descriptor, 0, nullptr); if(CanBePushed) { SUniformSpriteMultiPushGVertColor PushConstantColor; SUniformSpriteMultiPushGPos PushConstantVertex; mem_copy(PushConstantColor.m_aColor, &pCommand->m_VertexColor, sizeof(PushConstantColor.m_aColor)); mem_copy(PushConstantVertex.m_aPos, m.data(), sizeof(PushConstantVertex.m_aPos)); mem_copy(&PushConstantVertex.m_Center, &pCommand->m_Center, sizeof(PushConstantVertex.m_Center)); for(size_t i = 0; i < pCommand->m_DrawCount; ++i) PushConstantVertex.m_aPSR[i] = vec4(pCommand->m_pRenderInfo[i].m_Pos[0], pCommand->m_pRenderInfo[i].m_Pos[1], pCommand->m_pRenderInfo[i].m_Scale, pCommand->m_pRenderInfo[i].m_Rotation); vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_VERTEX_BIT, 0, sizeof(SUniformSpriteMultiPushGPosBase) + sizeof(vec4) * pCommand->m_DrawCount, &PushConstantVertex); vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_FRAGMENT_BIT, sizeof(SUniformSpriteMultiPushGPos), sizeof(PushConstantColor), &PushConstantColor); } else { SUniformSpriteMultiGVertColor PushConstantColor; SUniformSpriteMultiGPos PushConstantVertex; mem_copy(PushConstantColor.m_aColor, &pCommand->m_VertexColor, sizeof(PushConstantColor.m_aColor)); mem_copy(PushConstantVertex.m_aPos, m.data(), sizeof(PushConstantVertex.m_aPos)); mem_copy(&PushConstantVertex.m_Center, &pCommand->m_Center, sizeof(PushConstantVertex.m_Center)); vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_VERTEX_BIT, 0, sizeof(PushConstantVertex), &PushConstantVertex); vkCmdPushConstants(CommandBuffer, PipeLayout, VK_SHADER_STAGE_FRAGMENT_BIT, sizeof(SUniformSpriteMultiGPos) + sizeof(SUniformSpriteMultiGVertColorAlign), sizeof(PushConstantColor), &PushConstantColor); } const int RSPCount = 512; int DrawCount = pCommand->m_DrawCount; size_t RenderOffset = 0; while(DrawCount > 0) { int UniformCount = (DrawCount > RSPCount ? RSPCount : DrawCount); if(!CanBePushed) { // create uniform buffer SDeviceDescriptorSet UniDescrSet; GetUniformBufferObject(ExecBuffer.m_ThreadIndex, false, UniDescrSet, UniformCount, (const float *)(pCommand->m_pRenderInfo + RenderOffset), UniformCount * sizeof(IGraphics::SRenderSpriteInfo)); vkCmdBindDescriptorSets(CommandBuffer, VK_PIPELINE_BIND_POINT_GRAPHICS, PipeLayout, 1, 1, &UniDescrSet.m_Descriptor, 0, nullptr); } vkCmdDrawIndexed(CommandBuffer, static_cast(pCommand->m_DrawNum), UniformCount, 0, 0, 0); RenderOffset += RSPCount; DrawCount -= RSPCount; } } void Cmd_WindowCreateNtf(const CCommandBuffer::SCommand_WindowCreateNtf *pCommand) { dbg_msg("vulkan", "creating new surface."); m_pWindow = SDL_GetWindowFromID(pCommand->m_WindowID); if(m_RenderingPaused) { #ifdef CONF_PLATFORM_ANDROID CreateSurface(m_pWindow); m_RecreateSwapChain = true; #endif m_RenderingPaused = false; PureMemoryFrame(); PrepareFrame(); } } void Cmd_WindowDestroyNtf(const CCommandBuffer::SCommand_WindowDestroyNtf *pCommand) { dbg_msg("vulkan", "surface got destroyed."); if(!m_RenderingPaused) { WaitFrame(); m_RenderingPaused = true; vkDeviceWaitIdle(m_VKDevice); #ifdef CONF_PLATFORM_ANDROID CleanupVulkanSwapChain(true); #endif } } void Cmd_PreInit(const CCommandProcessorFragment_GLBase::SCommand_PreInit *pCommand) { m_pGPUList = pCommand->m_pGPUList; if(InitVulkanSDL(pCommand->m_pWindow, pCommand->m_Width, pCommand->m_Height, pCommand->m_pRendererString, pCommand->m_pVendorString, pCommand->m_pVersionString) != 0) { m_VKInstance = VK_NULL_HANDLE; } RegisterCommands(); m_ThreadCount = g_Config.m_GfxRenderThreadCount; if(m_ThreadCount <= 1) m_ThreadCount = 1; else { m_ThreadCount = clamp(m_ThreadCount, 3, std::thread::hardware_concurrency()); } // start threads dbg_assert(m_ThreadCount != 2, "Either use 1 main thread or at least 2 extra rendering threads."); if(m_ThreadCount > 1) { m_ThreadCommandLists.resize(m_ThreadCount - 1); m_ThreadHelperHadCommands.resize(m_ThreadCount - 1, false); for(auto &ThreadCommandList : m_ThreadCommandLists) { ThreadCommandList.reserve(256); } for(size_t i = 0; i < m_ThreadCount - 1; ++i) { auto *pRenderThread = new SRenderThread(); std::unique_lock Lock(pRenderThread->m_Mutex); m_RenderThreads.emplace_back(pRenderThread); pRenderThread->m_Thread = std::thread([this, i]() { RunThread(i); }); // wait until thread started pRenderThread->m_Cond.wait(Lock, [pRenderThread]() -> bool { return pRenderThread->m_Started; }); } } } void Cmd_PostShutdown(const CCommandProcessorFragment_GLBase::SCommand_PostShutdown *pCommand) { for(size_t i = 0; i < m_ThreadCount - 1; ++i) { auto *pThread = m_RenderThreads[i].get(); { std::unique_lock Lock(pThread->m_Mutex); pThread->m_Finished = true; pThread->m_Cond.notify_one(); } pThread->m_Thread.join(); } m_RenderThreads.clear(); m_ThreadCommandLists.clear(); m_ThreadHelperHadCommands.clear(); m_ThreadCount = 1; CleanupVulkanSDL(); } void StartCommands(size_t CommandCount, size_t EstimatedRenderCallCount) override { m_CommandsInPipe = CommandCount; m_RenderCallsInPipe = EstimatedRenderCallCount; m_CurCommandInPipe = 0; m_CurRenderCallCountInPipe = 0; } void EndCommands() override { FinishRenderThreads(); m_CommandsInPipe = 0; m_RenderCallsInPipe = 0; } /**************** * RENDER THREADS *****************/ void RunThread(size_t ThreadIndex) { auto *pThread = m_RenderThreads[ThreadIndex].get(); std::unique_lock Lock(pThread->m_Mutex); pThread->m_Started = true; pThread->m_Cond.notify_one(); while(!pThread->m_Finished) { pThread->m_Cond.wait(Lock, [pThread]() -> bool { return pThread->m_IsRendering || pThread->m_Finished; }); pThread->m_Cond.notify_one(); // set this to true, if you want to benchmark the render thread times static constexpr bool s_BenchmarkRenderThreads = false; int64_t ThreadRenderTime = 0; if(IsVerbose() && s_BenchmarkRenderThreads) { ThreadRenderTime = time_get_microseconds(); } if(!pThread->m_Finished) { for(auto &NextCmd : m_ThreadCommandLists[ThreadIndex]) { m_aCommandCallbacks[CommandBufferCMDOff(NextCmd.m_Command)].m_CommandCB(NextCmd.m_pRawCommand, NextCmd); } m_ThreadCommandLists[ThreadIndex].clear(); if(m_UsedThreadDrawCommandBuffer[ThreadIndex + 1][m_CurImageIndex]) { auto &GraphicThreadCommandBuffer = m_ThreadDrawCommandBuffers[ThreadIndex + 1][m_CurImageIndex]; vkEndCommandBuffer(GraphicThreadCommandBuffer); } } if(IsVerbose() && s_BenchmarkRenderThreads) { dbg_msg("vulkan", "render thread %" PRIu64 " took %d microseconds to finish", ThreadIndex, (int)(time_get_microseconds() - ThreadRenderTime)); } pThread->m_IsRendering = false; } } }; CCommandProcessorFragment_GLBase *CreateVulkanCommandProcessorFragment() { return new CCommandProcessorFragment_Vulkan(); } #endif