/* * Copyright 2023 Google LLC * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "tools/window/VulkanWindowContext.h" #include "include/core/SkSurface.h" #include "include/gpu/ganesh/GrBackendSemaphore.h" #include "include/gpu/ganesh/GrBackendSurface.h" #include "include/gpu/ganesh/GrDirectContext.h" #include "include/gpu/ganesh/SkSurfaceGanesh.h" #include "include/gpu/ganesh/vk/GrVkBackendSemaphore.h" #include "include/gpu/ganesh/vk/GrVkBackendSurface.h" #include "include/gpu/ganesh/vk/GrVkDirectContext.h" #include "include/gpu/ganesh/vk/GrVkTypes.h" #include "include/gpu/vk/VulkanExtensions.h" #include "src/gpu/GpuTypesPriv.h" #include "include/gpu/vk/VulkanMutableTextureState.h" #include "src/base/SkAutoMalloc.h" #include "src/gpu/ganesh/vk/GrVkImage.h" #include "src/gpu/ganesh/vk/GrVkUtil.h" #include "src/gpu/vk/VulkanInterface.h" #include "src/gpu/vk/vulkanmemoryallocator/VulkanAMDMemoryAllocator.h" #ifdef VK_USE_PLATFORM_WIN32_KHR // windows wants to define this as CreateSemaphoreA or CreateSemaphoreW #undef CreateSemaphore #endif #define GET_PROC(F) f ## F = \ (PFN_vk ## F) backendContext.fGetProc("vk" #F, fInstance, VK_NULL_HANDLE) #define GET_DEV_PROC(F) f ## F = \ (PFN_vk ## F) backendContext.fGetProc("vk" #F, VK_NULL_HANDLE, fDevice) namespace skwindow::internal { VulkanWindowContext::VulkanWindowContext(std::unique_ptr params, CreateVkSurfaceFn createVkSurface, CanPresentFn canPresent, PFN_vkGetInstanceProcAddr instProc) : WindowContext(std::move(params)) , fDeviceSurface(VK_NULL_HANDLE) , fSwapchain(VK_NULL_HANDLE) , fCreateVkSurfaceFn(std::move(createVkSurface)) , fCanPresentFn(std::move(canPresent)) { fGetInstanceProcAddr = instProc; this->initializeContext(); } void VulkanWindowContext::initializeContext() { SkASSERT(!fContext); // Any config code here (particularly for msaa)? PFN_vkGetInstanceProcAddr getInstanceProc = fGetInstanceProcAddr; skgpu::VulkanBackendContext backendContext; skgpu::VulkanExtensions extensions; sk_gpu_test::TestVkFeatures features; if (!sk_gpu_test::CreateVkBackendContext(getInstanceProc, &backendContext, &extensions, &features, &fDebugMessenger, &fPresentQueueIndex, fCanPresentFn, fDisplayParams->createProtectedNativeBackend())) { return; } if (!extensions.hasExtension(VK_KHR_SURFACE_EXTENSION_NAME, 25) || !extensions.hasExtension(VK_KHR_SWAPCHAIN_EXTENSION_NAME, 68)) { return; } fInstance = backendContext.fInstance; fPhysicalDevice = backendContext.fPhysicalDevice; fDevice = backendContext.fDevice; fGraphicsQueueIndex = backendContext.fGraphicsQueueIndex; fGraphicsQueue = backendContext.fQueue; PFN_vkGetPhysicalDeviceProperties localGetPhysicalDeviceProperties = reinterpret_cast( backendContext.fGetProc("vkGetPhysicalDeviceProperties", backendContext.fInstance, VK_NULL_HANDLE)); if (!localGetPhysicalDeviceProperties) { return; } VkPhysicalDeviceProperties physDeviceProperties; localGetPhysicalDeviceProperties(backendContext.fPhysicalDevice, &physDeviceProperties); uint32_t physDevVersion = physDeviceProperties.apiVersion; fInterface.reset(new skgpu::VulkanInterface(backendContext.fGetProc, fInstance, fDevice, backendContext.fMaxAPIVersion, physDevVersion, &extensions)); GET_PROC(DestroyInstance); if (fDebugMessenger != VK_NULL_HANDLE) { GET_PROC(DestroyDebugUtilsMessengerEXT); } GET_PROC(DestroySurfaceKHR); GET_PROC(GetPhysicalDeviceSurfaceSupportKHR); GET_PROC(GetPhysicalDeviceSurfaceCapabilitiesKHR); GET_PROC(GetPhysicalDeviceSurfaceFormatsKHR); GET_PROC(GetPhysicalDeviceSurfacePresentModesKHR); GET_DEV_PROC(DeviceWaitIdle); GET_DEV_PROC(QueueWaitIdle); GET_DEV_PROC(DestroyDevice); GET_DEV_PROC(CreateSwapchainKHR); GET_DEV_PROC(DestroySwapchainKHR); GET_DEV_PROC(GetSwapchainImagesKHR); GET_DEV_PROC(AcquireNextImageKHR); GET_DEV_PROC(QueuePresentKHR); GET_DEV_PROC(GetDeviceQueue); backendContext.fMemoryAllocator = skgpu::VulkanAMDMemoryAllocator::Make(fInstance, backendContext.fPhysicalDevice, backendContext.fDevice, physDevVersion, &extensions, fInterface.get(), skgpu::ThreadSafe::kNo, /*blockSize=*/std::nullopt); fContext = GrDirectContexts::MakeVulkan(backendContext, fDisplayParams->grContextOptions()); fDeviceSurface = fCreateVkSurfaceFn(fInstance); if (VK_NULL_HANDLE == fDeviceSurface) { this->destroyContext(); return; } VkBool32 supported; VkResult res = fGetPhysicalDeviceSurfaceSupportKHR( fPhysicalDevice, fPresentQueueIndex, fDeviceSurface, &supported); if (VK_SUCCESS != res) { this->destroyContext(); return; } if (!this->createSwapchain(-1, -1)) { this->destroyContext(); return; } fGetDeviceQueue(fDevice, fPresentQueueIndex, /*queueIndex=*/0, &fPresentQueue); } bool VulkanWindowContext::createSwapchain(int width, int height) { // Check surface capabilities VkSurfaceCapabilitiesKHR caps; VkResult res = fGetPhysicalDeviceSurfaceCapabilitiesKHR(fPhysicalDevice, fDeviceSurface, &caps); if (VK_SUCCESS != res) { return false; } uint32_t surfaceFormatCount; res = fGetPhysicalDeviceSurfaceFormatsKHR(fPhysicalDevice, fDeviceSurface, &surfaceFormatCount, nullptr); if (VK_SUCCESS != res) { return false; } SkAutoMalloc surfaceFormatAlloc(surfaceFormatCount * sizeof(VkSurfaceFormatKHR)); VkSurfaceFormatKHR* surfaceFormats = (VkSurfaceFormatKHR*)surfaceFormatAlloc.get(); res = fGetPhysicalDeviceSurfaceFormatsKHR(fPhysicalDevice, fDeviceSurface, &surfaceFormatCount, surfaceFormats); if (VK_SUCCESS != res) { return false; } uint32_t presentModeCount; res = fGetPhysicalDeviceSurfacePresentModesKHR(fPhysicalDevice, fDeviceSurface, &presentModeCount, nullptr); if (VK_SUCCESS != res) { return false; } SkAutoMalloc presentModeAlloc(presentModeCount * sizeof(VkPresentModeKHR)); VkPresentModeKHR* presentModes = (VkPresentModeKHR*)presentModeAlloc.get(); res = fGetPhysicalDeviceSurfacePresentModesKHR(fPhysicalDevice, fDeviceSurface, &presentModeCount, presentModes); if (VK_SUCCESS != res) { return false; } VkExtent2D extent = caps.currentExtent; // Use the hints for width + height if (extent.width == (uint32_t)-1) { extent.width = width; extent.height = height; } // Clamp the values to protect from broken hints if (extent.width < caps.minImageExtent.width) { extent.width = caps.minImageExtent.width; } else if (extent.width > caps.maxImageExtent.width) { extent.width = caps.maxImageExtent.width; } if (extent.height < caps.minImageExtent.height) { extent.height = caps.minImageExtent.height; } else if (extent.height > caps.maxImageExtent.height) { extent.height = caps.maxImageExtent.height; } fWidth = (int)extent.width; fHeight = (int)extent.height; uint32_t imageCount = caps.minImageCount + 2; if (caps.maxImageCount > 0 && imageCount > caps.maxImageCount) { // Application must settle for fewer images than desired: imageCount = caps.maxImageCount; } VkImageUsageFlags usageFlags = VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT | VK_IMAGE_USAGE_TRANSFER_SRC_BIT | VK_IMAGE_USAGE_TRANSFER_DST_BIT; SkASSERT((caps.supportedUsageFlags & usageFlags) == usageFlags); if (caps.supportedUsageFlags & VK_IMAGE_USAGE_INPUT_ATTACHMENT_BIT) { usageFlags |= VK_IMAGE_USAGE_INPUT_ATTACHMENT_BIT; } if (caps.supportedUsageFlags & VK_IMAGE_USAGE_SAMPLED_BIT) { usageFlags |= VK_IMAGE_USAGE_SAMPLED_BIT; } SkASSERT(caps.supportedTransforms & caps.currentTransform); SkASSERT(caps.supportedCompositeAlpha & (VK_COMPOSITE_ALPHA_OPAQUE_BIT_KHR | VK_COMPOSITE_ALPHA_INHERIT_BIT_KHR)); VkCompositeAlphaFlagBitsKHR composite_alpha = (caps.supportedCompositeAlpha & VK_COMPOSITE_ALPHA_INHERIT_BIT_KHR) ? VK_COMPOSITE_ALPHA_INHERIT_BIT_KHR : VK_COMPOSITE_ALPHA_OPAQUE_BIT_KHR; // Pick our surface format. VkFormat surfaceFormat = VK_FORMAT_UNDEFINED; VkColorSpaceKHR colorSpace = VK_COLORSPACE_SRGB_NONLINEAR_KHR; for (uint32_t i = 0; i < surfaceFormatCount; ++i) { VkFormat localFormat = surfaceFormats[i].format; if (GrVkFormatIsSupported(localFormat)) { surfaceFormat = localFormat; colorSpace = surfaceFormats[i].colorSpace; break; } } fSampleCount = std::max(1, fDisplayParams->msaaSampleCount()); fStencilBits = 8; if (VK_FORMAT_UNDEFINED == surfaceFormat) { return false; } SkColorType colorType; switch (surfaceFormat) { case VK_FORMAT_R8G8B8A8_UNORM: // fall through case VK_FORMAT_R8G8B8A8_SRGB: colorType = kRGBA_8888_SkColorType; break; case VK_FORMAT_B8G8R8A8_UNORM: // fall through colorType = kBGRA_8888_SkColorType; break; default: return false; } // If mailbox mode is available, use it, as it is the lowest-latency non- // tearing mode. If not, fall back to FIFO which is always available. VkPresentModeKHR mode = VK_PRESENT_MODE_FIFO_KHR; bool hasImmediate = false; for (uint32_t i = 0; i < presentModeCount; ++i) { // use mailbox if (VK_PRESENT_MODE_MAILBOX_KHR == presentModes[i]) { mode = VK_PRESENT_MODE_MAILBOX_KHR; } if (VK_PRESENT_MODE_IMMEDIATE_KHR == presentModes[i]) { hasImmediate = true; } } if (fDisplayParams->disableVsync() && hasImmediate) { mode = VK_PRESENT_MODE_IMMEDIATE_KHR; } VkSwapchainCreateInfoKHR swapchainCreateInfo; memset(&swapchainCreateInfo, 0, sizeof(VkSwapchainCreateInfoKHR)); swapchainCreateInfo.sType = VK_STRUCTURE_TYPE_SWAPCHAIN_CREATE_INFO_KHR; swapchainCreateInfo.flags = fDisplayParams->createProtectedNativeBackend() ? VK_SWAPCHAIN_CREATE_PROTECTED_BIT_KHR : 0; swapchainCreateInfo.surface = fDeviceSurface; swapchainCreateInfo.minImageCount = imageCount; swapchainCreateInfo.imageFormat = surfaceFormat; swapchainCreateInfo.imageColorSpace = colorSpace; swapchainCreateInfo.imageExtent = extent; swapchainCreateInfo.imageArrayLayers = 1; swapchainCreateInfo.imageUsage = usageFlags; uint32_t queueFamilies[] = { fGraphicsQueueIndex, fPresentQueueIndex }; if (fGraphicsQueueIndex != fPresentQueueIndex) { swapchainCreateInfo.imageSharingMode = VK_SHARING_MODE_CONCURRENT; swapchainCreateInfo.queueFamilyIndexCount = 2; swapchainCreateInfo.pQueueFamilyIndices = queueFamilies; } else { swapchainCreateInfo.imageSharingMode = VK_SHARING_MODE_EXCLUSIVE; swapchainCreateInfo.queueFamilyIndexCount = 0; swapchainCreateInfo.pQueueFamilyIndices = nullptr; } swapchainCreateInfo.preTransform = VK_SURFACE_TRANSFORM_IDENTITY_BIT_KHR; swapchainCreateInfo.compositeAlpha = composite_alpha; swapchainCreateInfo.presentMode = mode; swapchainCreateInfo.clipped = true; swapchainCreateInfo.oldSwapchain = fSwapchain; res = fCreateSwapchainKHR(fDevice, &swapchainCreateInfo, nullptr, &fSwapchain); if (VK_SUCCESS != res) { return false; } // Destroy the old swapchain if (swapchainCreateInfo.oldSwapchain != VK_NULL_HANDLE) { fDeviceWaitIdle(fDevice); this->resetSwapchainImages(); fDestroySwapchainKHR(fDevice, swapchainCreateInfo.oldSwapchain, nullptr); swapchainCreateInfo.oldSwapchain = VK_NULL_HANDLE; } // If buffer creation fails, destroy the swapchain. if (!this->populateSwapchainImages(swapchainCreateInfo.imageFormat, usageFlags, colorType, swapchainCreateInfo.imageSharingMode)) { fDeviceWaitIdle(fDevice); this->resetSwapchainImages(); fDestroySwapchainKHR(fDevice, swapchainCreateInfo.oldSwapchain, nullptr); swapchainCreateInfo.oldSwapchain = VK_NULL_HANDLE; return false; } return true; } bool VulkanWindowContext::populateSwapchainImages(VkFormat format, VkImageUsageFlags usageFlags, SkColorType colorType, VkSharingMode sharingMode) { // Determine number of swapchain images uint32_t swapchainImgCount; fGetSwapchainImagesKHR(fDevice, fSwapchain, &swapchainImgCount, /*pSwapchainImages*/nullptr); SkASSERT(swapchainImgCount); // Define an array of VkImages and query the driver to populate it skia_private::AutoTArray vkImages((size_t)swapchainImgCount); std::fill_n(vkImages.get(), swapchainImgCount, VK_NULL_HANDLE); fGetSwapchainImagesKHR(fDevice, fSwapchain, &swapchainImgCount, vkImages.get()); // Populate all swapchain image representations fImages = skia_private::AutoTArray((size_t)swapchainImgCount); for (uint32_t i = 0; i < swapchainImgCount; ++i) { // Make sure we were provided a valid VkImage handle SkASSERT(vkImages[i] != VK_NULL_HANDLE); fImages[i].fVkImage = vkImages[i]; // Create the semaphore that will be signaled once the image done being rendered static const VkSemaphoreCreateInfo submitSemInfo = {VK_STRUCTURE_TYPE_SEMAPHORE_CREATE_INFO, /*pNext=*/nullptr, /*flags=*/0}; SkDEBUGCODE(VkResult result = )GR_VK_CALL( fInterface, CreateSemaphore(fDevice, &submitSemInfo, /*pAllocator=*/nullptr, &fImages[i].fRenderCompletionSemaphore)); SkASSERT(result == VK_SUCCESS && fImages[i].fRenderCompletionSemaphore != VK_NULL_HANDLE); // Populate GrVkImageInfo for Surface creation GrVkImageInfo info; info.fImage = vkImages[i]; info.fAlloc = skgpu::VulkanAlloc(); info.fFormat = format; info.fImageUsageFlags = usageFlags; info.fLevelCount = 1; info.fCurrentQueueFamily = fPresentQueueIndex; info.fProtected = skgpu::Protected(fDisplayParams->createProtectedNativeBackend()); info.fSharingMode = sharingMode; // Based on whether the image can be sampled, create a Surface to present each image if (usageFlags & VK_IMAGE_USAGE_SAMPLED_BIT) { GrBackendTexture backendTexture = GrBackendTextures::MakeVk(fWidth, fHeight, info); fImages[i].fSurface = SkSurfaces::WrapBackendTexture(fContext.get(), backendTexture, kTopLeft_GrSurfaceOrigin, fDisplayParams->msaaSampleCount(), colorType, fDisplayParams->colorSpace(), &fDisplayParams->surfaceProps()); } else { if (fDisplayParams->msaaSampleCount() > 1) { return false; } info.fSampleCount = fSampleCount; GrBackendRenderTarget backendRT = GrBackendRenderTargets::MakeVk(fWidth, fHeight, info); fImages[i].fSurface = SkSurfaces::WrapBackendRenderTarget(fContext.get(), backendRT, kTopLeft_GrSurfaceOrigin, colorType, fDisplayParams->colorSpace(), &fDisplayParams->surfaceProps()); } // If surface creation was unsuccessful, return false to indicate failure if (!fImages[i].fSurface) { // Clean up any previously-created semaphores before returning this->resetSwapchainImages(); return false; } } return true; } void VulkanWindowContext::submitToGpu() { SkSurface* surface = fImages[fCurrentImageIndex].fSurface.get(); GrBackendSemaphore backendRenderSemaphore = GrBackendSemaphores::MakeVk(fImages[fCurrentImageIndex].fRenderCompletionSemaphore); GrFlushInfo info; info.fNumSemaphores = 1; info.fSignalSemaphores = &backendRenderSemaphore; skgpu::MutableTextureState presentState = skgpu::MutableTextureStates::MakeVulkan( VK_IMAGE_LAYOUT_PRESENT_SRC_KHR, fPresentQueueIndex); auto dContext = surface->recordingContext()->asDirectContext(); dContext->flush(surface, info, &presentState); dContext->submit(); } void VulkanWindowContext::resetSwapchainImages() { if (fImages.empty()) { return; } // Clean up the image's semaphores for (size_t i = 0; i < fImages.size(); i++) { if (fImages[i].fRenderCompletionSemaphore != VK_NULL_HANDLE) { GR_VK_CALL(fInterface, DestroySemaphore(fDevice, fImages[i].fRenderCompletionSemaphore, /*pAllocator=*/nullptr)); } } fImages.reset(); } VulkanWindowContext::~VulkanWindowContext() { this->destroyContext(); } void VulkanWindowContext::destroyContext() { if (this->isValid()) { fQueueWaitIdle(fPresentQueue); fDeviceWaitIdle(fDevice); this->resetSwapchainImages(); if (VK_NULL_HANDLE != fSwapchain) { fDestroySwapchainKHR(fDevice, fSwapchain, nullptr); fSwapchain = VK_NULL_HANDLE; } if (VK_NULL_HANDLE != fDeviceSurface) { fDestroySurfaceKHR(fInstance, fDeviceSurface, nullptr); fDeviceSurface = VK_NULL_HANDLE; } } SkASSERT(fContext->unique()); fContext.reset(); fInterface.reset(); if (VK_NULL_HANDLE != fDevice) { fDestroyDevice(fDevice, nullptr); fDevice = VK_NULL_HANDLE; } #ifdef SK_ENABLE_VK_LAYERS if (fDebugMessenger != VK_NULL_HANDLE) { fDestroyDebugUtilsMessengerEXT(fInstance, fDebugMessenger, nullptr); } #endif fPhysicalDevice = VK_NULL_HANDLE; if (VK_NULL_HANDLE != fInstance) { fDestroyInstance(fInstance, nullptr); fInstance = VK_NULL_HANDLE; } } sk_sp VulkanWindowContext::getBackbufferSurface() { // Create a new, unsignaled semaphore to be signaled upon swapchain image acquisition. static const VkSemaphoreCreateInfo acquireSemInfo = { VK_STRUCTURE_TYPE_SEMAPHORE_CREATE_INFO, /*pNext=*/nullptr, /*flags=*/0 }; SkDEBUGCODE(VkResult result = )GR_VK_CALL( fInterface, CreateSemaphore(fDevice, &acquireSemInfo, /*pAllocator=*/nullptr, &fAcquireSemaphore)); SkASSERT(result == VK_SUCCESS && fAcquireSemaphore != VK_NULL_HANDLE); // Acquire the next available presentable image's index. VkResult res = fAcquireNextImageKHR(fDevice, fSwapchain, /*timeout=*/UINT64_MAX, fAcquireSemaphore, /*VkFence=*/VK_NULL_HANDLE, &fCurrentImageIndex); if (VK_ERROR_SURFACE_LOST_KHR == res) { // TODO: Recreate fDeviceSurface using fCreateVkSurfaceFn, and then rebuild the swapchain GR_VK_CALL(fInterface, DestroySemaphore(fDevice, fAcquireSemaphore, /*pAllocator=*/nullptr)); return nullptr; } if (VK_ERROR_OUT_OF_DATE_KHR == res) { if (!this->createSwapchain(-1, -1)) { GR_VK_CALL(fInterface, DestroySemaphore(fDevice, fAcquireSemaphore, /*pAllocator=*/nullptr)); return nullptr; } res = fAcquireNextImageKHR(fDevice, fSwapchain, UINT64_MAX, fAcquireSemaphore, /*VkFence=*/VK_NULL_HANDLE, &fCurrentImageIndex); if (VK_SUCCESS != res) { GR_VK_CALL(fInterface, DestroySemaphore(fDevice, fAcquireSemaphore, /*pAllocator=*/nullptr)); return nullptr; } } // Set up the SkSurface associated with the current backbuffer's image and return it. SkSurface* surface = fImages[fCurrentImageIndex].fSurface.get(); GrBackendSemaphore beSemaphore = GrBackendSemaphores::MakeVk(fAcquireSemaphore); surface->wait(/*numSemaphores=*/1, &beSemaphore); return sk_ref_sp(surface); } void VulkanWindowContext::onSwapBuffers() { // Submit the GPU work associated with the current backbuffer this->submitToGpu(); // Submit present operation to present queue auto renderCompletionSemaphore = &fImages[fCurrentImageIndex].fRenderCompletionSemaphore; const VkPresentInfoKHR presentInfo = {VK_STRUCTURE_TYPE_PRESENT_INFO_KHR, // sType nullptr, // pNext 1, // waitSemaphoreCount renderCompletionSemaphore, // pWaitSemaphores 1, // swapchainCount &fSwapchain, // pSwapchains &fCurrentImageIndex, // pImageIndices nullptr}; // pResults fQueuePresentKHR(fPresentQueue, &presentInfo); } } // namespace skwindow::internal