/* * Copyright 2018 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ // This is a GPU-backend specific test. It relies on static initializers to work #include "include/core/SkTypes.h" #if SK_SUPPORT_GPU && defined(SK_BUILD_FOR_ANDROID) && __ANDROID_API__ >= 26 && defined(SK_VULKAN) #include "include/core/SkBitmap.h" #include "include/core/SkCanvas.h" #include "include/core/SkColorSpace.h" #include "include/core/SkImage.h" #include "include/core/SkSurface.h" #include "include/gpu/GrBackendSemaphore.h" #include "include/gpu/GrDirectContext.h" #include "include/gpu/vk/GrVkBackendContext.h" #include "include/gpu/vk/GrVkExtensions.h" #include "src/core/SkAutoMalloc.h" #include "src/gpu/ganesh/GrDirectContextPriv.h" #include "src/gpu/ganesh/GrGpu.h" #include "src/gpu/ganesh/GrProxyProvider.h" #include "src/gpu/ganesh/SkGr.h" #include "src/gpu/ganesh/gl/GrGLDefines_impl.h" #include "src/gpu/ganesh/gl/GrGLUtil.h" #include "tests/Test.h" #include "tools/gpu/GrContextFactory.h" #include "tools/gpu/vk/VkTestUtils.h" #include #include #include #include #include #include static const int DEV_W = 16, DEV_H = 16; class BaseTestHelper { public: virtual ~BaseTestHelper() {} virtual bool init(skiatest::Reporter* reporter) = 0; virtual void cleanup() = 0; virtual void releaseImage() = 0; virtual sk_sp importHardwareBufferForRead(skiatest::Reporter* reporter, AHardwareBuffer* buffer) = 0; virtual sk_sp importHardwareBufferForWrite(skiatest::Reporter* reporter, AHardwareBuffer* buffer) = 0; virtual void doClientSync() = 0; virtual bool flushSurfaceAndSignalSemaphore(skiatest::Reporter* reporter, sk_sp) = 0; virtual bool importAndWaitOnSemaphore(skiatest::Reporter* reporter, int fdHandle, sk_sp) = 0; virtual void makeCurrent() = 0; virtual GrDirectContext* directContext() = 0; int getFdHandle() { return fFdHandle; } protected: BaseTestHelper() {} int fFdHandle = 0; }; #ifdef SK_GL class EGLTestHelper : public BaseTestHelper { public: EGLTestHelper(const GrContextOptions& options) : fFactory(options) {} ~EGLTestHelper() override {} void releaseImage() override { this->makeCurrent(); if (!fGLCtx) { return; } if (EGL_NO_IMAGE_KHR != fImage) { fGLCtx->destroyEGLImage(fImage); fImage = EGL_NO_IMAGE_KHR; } if (fTexID) { GR_GL_CALL(fGLCtx->gl(), DeleteTextures(1, &fTexID)); fTexID = 0; } } void cleanup() override { this->releaseImage(); } bool init(skiatest::Reporter* reporter) override; sk_sp importHardwareBufferForRead(skiatest::Reporter* reporter, AHardwareBuffer* buffer) override; sk_sp importHardwareBufferForWrite(skiatest::Reporter* reporter, AHardwareBuffer* buffer) override; void doClientSync() override; bool flushSurfaceAndSignalSemaphore(skiatest::Reporter* reporter, sk_sp) override; bool importAndWaitOnSemaphore(skiatest::Reporter* reporter, int fdHandle, sk_sp) override; void makeCurrent() override { fGLCtx->makeCurrent(); } GrDirectContext* directContext() override { return fDirectContext; } private: bool importHardwareBuffer(skiatest::Reporter* reporter, AHardwareBuffer* buffer); typedef EGLClientBuffer (*EGLGetNativeClientBufferANDROIDProc)(const struct AHardwareBuffer*); typedef EGLImageKHR (*EGLCreateImageKHRProc)(EGLDisplay, EGLContext, EGLenum, EGLClientBuffer, const EGLint*); typedef void (*EGLImageTargetTexture2DOESProc)(EGLenum, void*); EGLGetNativeClientBufferANDROIDProc fEGLGetNativeClientBufferANDROID; EGLCreateImageKHRProc fEGLCreateImageKHR; EGLImageTargetTexture2DOESProc fEGLImageTargetTexture2DOES; PFNEGLCREATESYNCKHRPROC fEGLCreateSyncKHR; PFNEGLWAITSYNCKHRPROC fEGLWaitSyncKHR; PFNEGLGETSYNCATTRIBKHRPROC fEGLGetSyncAttribKHR; PFNEGLDUPNATIVEFENCEFDANDROIDPROC fEGLDupNativeFenceFDANDROID; PFNEGLDESTROYSYNCKHRPROC fEGLDestroySyncKHR; EGLImageKHR fImage = EGL_NO_IMAGE_KHR; GrGLuint fTexID = 0; sk_gpu_test::GrContextFactory fFactory; sk_gpu_test::ContextInfo fGLESContextInfo; sk_gpu_test::GLTestContext* fGLCtx = nullptr; GrDirectContext* fDirectContext = nullptr; }; bool EGLTestHelper::init(skiatest::Reporter* reporter) { fGLESContextInfo = fFactory.getContextInfo(sk_gpu_test::GrContextFactory::kGLES_ContextType); fDirectContext = fGLESContextInfo.directContext(); fGLCtx = fGLESContextInfo.glContext(); if (!fDirectContext || !fGLCtx) { return false; } if (kGLES_GrGLStandard != fGLCtx->gl()->fStandard) { return false; } // Confirm we have egl and the needed extensions if (!fGLCtx->gl()->hasExtension("EGL_KHR_image") || !fGLCtx->gl()->hasExtension("EGL_ANDROID_get_native_client_buffer") || !fGLCtx->gl()->hasExtension("GL_OES_EGL_image_external") || !fGLCtx->gl()->hasExtension("GL_OES_EGL_image") || !fGLCtx->gl()->hasExtension("EGL_KHR_fence_sync") || !fGLCtx->gl()->hasExtension("EGL_ANDROID_native_fence_sync")) { return false; } fEGLGetNativeClientBufferANDROID = (EGLGetNativeClientBufferANDROIDProc) eglGetProcAddress("eglGetNativeClientBufferANDROID"); if (!fEGLGetNativeClientBufferANDROID) { ERRORF(reporter, "Failed to get the eglGetNativeClientBufferAndroid proc"); return false; } fEGLCreateImageKHR = (EGLCreateImageKHRProc) eglGetProcAddress("eglCreateImageKHR"); if (!fEGLCreateImageKHR) { ERRORF(reporter, "Failed to get the proc eglCreateImageKHR"); return false; } fEGLImageTargetTexture2DOES = (EGLImageTargetTexture2DOESProc) eglGetProcAddress("glEGLImageTargetTexture2DOES"); if (!fEGLImageTargetTexture2DOES) { ERRORF(reporter, "Failed to get the proc EGLImageTargetTexture2DOES"); return false; } fEGLCreateSyncKHR = (PFNEGLCREATESYNCKHRPROC) eglGetProcAddress("eglCreateSyncKHR"); if (!fEGLCreateSyncKHR) { ERRORF(reporter, "Failed to get the proc eglCreateSyncKHR"); return false; } fEGLWaitSyncKHR = (PFNEGLWAITSYNCKHRPROC) eglGetProcAddress("eglWaitSyncKHR"); if (!fEGLWaitSyncKHR) { ERRORF(reporter, "Failed to get the proc eglWaitSyncKHR"); return false; } fEGLGetSyncAttribKHR = (PFNEGLGETSYNCATTRIBKHRPROC) eglGetProcAddress("eglGetSyncAttribKHR"); if (!fEGLGetSyncAttribKHR) { ERRORF(reporter, "Failed to get the proc eglGetSyncAttribKHR"); return false; } fEGLDupNativeFenceFDANDROID = (PFNEGLDUPNATIVEFENCEFDANDROIDPROC) eglGetProcAddress("eglDupNativeFenceFDANDROID"); if (!fEGLDupNativeFenceFDANDROID) { ERRORF(reporter, "Failed to get the proc eglDupNativeFenceFDANDROID"); return false; } fEGLDestroySyncKHR = (PFNEGLDESTROYSYNCKHRPROC) eglGetProcAddress("eglDestroySyncKHR"); if (!fEGLDestroySyncKHR) { ERRORF(reporter, "Failed to get the proc eglDestroySyncKHR"); return false; } return true; } bool EGLTestHelper::importHardwareBuffer(skiatest::Reporter* reporter, AHardwareBuffer* buffer) { while (fGLCtx->gl()->fFunctions.fGetError() != GR_GL_NO_ERROR) {} EGLClientBuffer eglClientBuffer = fEGLGetNativeClientBufferANDROID(buffer); EGLint eglAttribs[] = { EGL_IMAGE_PRESERVED_KHR, EGL_TRUE, EGL_NONE }; EGLDisplay eglDisplay = eglGetCurrentDisplay(); fImage = fEGLCreateImageKHR(eglDisplay, EGL_NO_CONTEXT, EGL_NATIVE_BUFFER_ANDROID, eglClientBuffer, eglAttribs); if (EGL_NO_IMAGE_KHR == fImage) { SkDebugf("Could not create EGL image, err = (%#x)\n", (int) eglGetError() ); return false; } GR_GL_CALL(fGLCtx->gl(), GenTextures(1, &fTexID)); if (!fTexID) { ERRORF(reporter, "Failed to create GL Texture"); return false; } GR_GL_CALL_NOERRCHECK(fGLCtx->gl(), BindTexture(GR_GL_TEXTURE_2D, fTexID)); if (fGLCtx->gl()->fFunctions.fGetError() != GR_GL_NO_ERROR) { ERRORF(reporter, "Failed to bind GL Texture"); return false; } fEGLImageTargetTexture2DOES(GL_TEXTURE_2D, fImage); if (GrGLenum error = fGLCtx->gl()->fFunctions.fGetError(); error != GR_GL_NO_ERROR) { ERRORF(reporter, "EGLImageTargetTexture2DOES failed (%#x)", (int) error); return false; } fDirectContext->resetContext(kTextureBinding_GrGLBackendState); return true; } sk_sp EGLTestHelper::importHardwareBufferForRead(skiatest::Reporter* reporter, AHardwareBuffer* buffer) { if (!this->importHardwareBuffer(reporter, buffer)) { return nullptr; } GrGLTextureInfo textureInfo; textureInfo.fTarget = GR_GL_TEXTURE_2D; textureInfo.fID = fTexID; textureInfo.fFormat = GR_GL_RGBA8; GrBackendTexture backendTex(DEV_W, DEV_H, GrMipmapped::kNo, textureInfo); REPORTER_ASSERT(reporter, backendTex.isValid()); sk_sp image = SkImage::MakeFromTexture(fDirectContext, backendTex, kTopLeft_GrSurfaceOrigin, kRGBA_8888_SkColorType, kPremul_SkAlphaType, nullptr); if (!image) { ERRORF(reporter, "Failed to make wrapped GL SkImage"); return nullptr; } return image; } sk_sp EGLTestHelper::importHardwareBufferForWrite(skiatest::Reporter* reporter, AHardwareBuffer* buffer) { if (!this->importHardwareBuffer(reporter, buffer)) { return nullptr; } GrGLTextureInfo textureInfo; textureInfo.fTarget = GR_GL_TEXTURE_2D; textureInfo.fID = fTexID; textureInfo.fFormat = GR_GL_RGBA8; GrBackendTexture backendTex(DEV_W, DEV_H, GrMipmapped::kNo, textureInfo); REPORTER_ASSERT(reporter, backendTex.isValid()); sk_sp surface = SkSurface::MakeFromBackendTexture(fDirectContext, backendTex, kTopLeft_GrSurfaceOrigin, 0, kRGBA_8888_SkColorType, nullptr, nullptr); if (!surface) { ERRORF(reporter, "Failed to make wrapped GL SkSurface"); return nullptr; } return surface; } bool EGLTestHelper::flushSurfaceAndSignalSemaphore(skiatest::Reporter* reporter, sk_sp surface) { EGLDisplay eglDisplay = eglGetCurrentDisplay(); EGLSyncKHR eglsync = fEGLCreateSyncKHR(eglDisplay, EGL_SYNC_NATIVE_FENCE_ANDROID, nullptr); if (EGL_NO_SYNC_KHR == eglsync) { ERRORF(reporter, "Failed to create EGLSync for EGL_SYNC_NATIVE_FENCE_ANDROID\n"); return false; } surface->flushAndSubmit(); GR_GL_CALL(fGLCtx->gl(), Flush()); fFdHandle = fEGLDupNativeFenceFDANDROID(eglDisplay, eglsync); EGLint result = fEGLDestroySyncKHR(eglDisplay, eglsync); if (EGL_TRUE != result) { ERRORF(reporter, "Failed to delete EGLSync, error: %d\n", result); return false; } return true; } bool EGLTestHelper::importAndWaitOnSemaphore(skiatest::Reporter* reporter, int fdHandle, sk_sp surface) { EGLDisplay eglDisplay = eglGetCurrentDisplay(); EGLint attr[] = { EGL_SYNC_NATIVE_FENCE_FD_ANDROID, fdHandle, EGL_NONE }; EGLSyncKHR eglsync = fEGLCreateSyncKHR(eglDisplay, EGL_SYNC_NATIVE_FENCE_ANDROID, attr); if (EGL_NO_SYNC_KHR == eglsync) { ERRORF(reporter, "Failed to create EGLSync when importing EGL_SYNC_NATIVE_FENCE_FD_ANDROID\n"); return false; } EGLint result = fEGLWaitSyncKHR(eglDisplay, eglsync, 0); if (EGL_TRUE != result) { ERRORF(reporter, "Failed called to eglWaitSyncKHR, error: %d\n", result); // Don't return false yet, try to delete the sync first } result = fEGLDestroySyncKHR(eglDisplay, eglsync); if (EGL_TRUE != result) { ERRORF(reporter, "Failed to delete EGLSync, error: %d\n", result); return false; } return true; } void EGLTestHelper::doClientSync() { this->directContext()->flush(); this->directContext()->submit(true); } #endif // SK_GL #define DECLARE_VK_PROC(name) PFN_vk##name fVk##name #define ACQUIRE_INST_VK_PROC(name) \ do { \ fVk##name = reinterpret_cast(getProc("vk" #name, fBackendContext.fInstance,\ VK_NULL_HANDLE)); \ if (fVk##name == nullptr) { \ ERRORF(reporter, "Function ptr for vk%s could not be acquired\n", #name); \ return false; \ } \ } while(false) #define ACQUIRE_DEVICE_VK_PROC(name) \ do { \ fVk##name = reinterpret_cast(getProc("vk" #name, VK_NULL_HANDLE, fDevice)); \ if (fVk##name == nullptr) { \ ERRORF(reporter, "Function ptr for vk%s could not be acquired\n", #name); \ return false; \ } \ } while(false) class VulkanTestHelper : public BaseTestHelper { public: VulkanTestHelper() {} ~VulkanTestHelper() override {} void releaseImage() override { if (VK_NULL_HANDLE == fDevice) { return; } if (fImage != VK_NULL_HANDLE) { fVkDestroyImage(fDevice, fImage, nullptr); fImage = VK_NULL_HANDLE; } if (fMemory != VK_NULL_HANDLE) { fVkFreeMemory(fDevice, fMemory, nullptr); fMemory = VK_NULL_HANDLE; } } void cleanup() override { fDirectContext.reset(); this->releaseImage(); if (fSignalSemaphore != VK_NULL_HANDLE) { fVkDestroySemaphore(fDevice, fSignalSemaphore, nullptr); fSignalSemaphore = VK_NULL_HANDLE; } fBackendContext.fMemoryAllocator.reset(); if (fDevice != VK_NULL_HANDLE) { fVkDeviceWaitIdle(fDevice); fVkDestroyDevice(fDevice, nullptr); fDevice = VK_NULL_HANDLE; } #ifdef SK_ENABLE_VK_LAYERS if (fDebugCallback != VK_NULL_HANDLE) { fDestroyDebugCallback(fBackendContext.fInstance, fDebugCallback, nullptr); } #endif if (fBackendContext.fInstance != VK_NULL_HANDLE) { fVkDestroyInstance(fBackendContext.fInstance, nullptr); fBackendContext.fInstance = VK_NULL_HANDLE; } delete fExtensions; sk_gpu_test::FreeVulkanFeaturesStructs(fFeatures); delete fFeatures; } bool init(skiatest::Reporter* reporter) override; void doClientSync() override { if (!fDirectContext) { return; } fDirectContext->submit(true); } bool flushSurfaceAndSignalSemaphore(skiatest::Reporter* reporter, sk_sp) override; bool importAndWaitOnSemaphore(skiatest::Reporter* reporter, int fdHandle, sk_sp) override; sk_sp importHardwareBufferForRead(skiatest::Reporter* reporter, AHardwareBuffer* buffer) override; sk_sp importHardwareBufferForWrite(skiatest::Reporter* reporter, AHardwareBuffer* buffer) override; void makeCurrent() override {} GrDirectContext* directContext() override { return fDirectContext.get(); } private: bool checkOptimalHardwareBuffer(skiatest::Reporter* reporter); bool importHardwareBuffer(skiatest::Reporter* reporter, AHardwareBuffer* buffer, bool forWrite, GrVkImageInfo* outImageInfo); bool setupSemaphoreForSignaling(skiatest::Reporter* reporter, GrBackendSemaphore*); bool exportSemaphore(skiatest::Reporter* reporter, const GrBackendSemaphore&); DECLARE_VK_PROC(DestroyInstance); DECLARE_VK_PROC(DeviceWaitIdle); DECLARE_VK_PROC(DestroyDevice); DECLARE_VK_PROC(GetPhysicalDeviceExternalSemaphoreProperties); DECLARE_VK_PROC(GetPhysicalDeviceImageFormatProperties2); DECLARE_VK_PROC(GetPhysicalDeviceMemoryProperties2); DECLARE_VK_PROC(GetAndroidHardwareBufferPropertiesANDROID); DECLARE_VK_PROC(CreateImage); DECLARE_VK_PROC(GetImageMemoryRequirements2); DECLARE_VK_PROC(DestroyImage); DECLARE_VK_PROC(AllocateMemory); DECLARE_VK_PROC(BindImageMemory2); DECLARE_VK_PROC(FreeMemory); DECLARE_VK_PROC(CreateSemaphore); DECLARE_VK_PROC(GetSemaphoreFdKHR); DECLARE_VK_PROC(ImportSemaphoreFdKHR); DECLARE_VK_PROC(DestroySemaphore); VkImage fImage = VK_NULL_HANDLE; VkDeviceMemory fMemory = VK_NULL_HANDLE; GrVkExtensions* fExtensions = nullptr; VkPhysicalDeviceFeatures2* fFeatures = nullptr; VkDebugReportCallbackEXT fDebugCallback = VK_NULL_HANDLE; PFN_vkDestroyDebugReportCallbackEXT fDestroyDebugCallback = nullptr; // We hold on to the semaphore so we can delete once the GPU is done. VkSemaphore fSignalSemaphore = VK_NULL_HANDLE; VkDevice fDevice = VK_NULL_HANDLE; GrVkBackendContext fBackendContext; sk_sp fDirectContext; }; bool VulkanTestHelper::init(skiatest::Reporter* reporter) { PFN_vkGetInstanceProcAddr instProc; if (!sk_gpu_test::LoadVkLibraryAndGetProcAddrFuncs(&instProc)) { return false; } fExtensions = new GrVkExtensions(); fFeatures = new VkPhysicalDeviceFeatures2; memset(fFeatures, 0, sizeof(VkPhysicalDeviceFeatures2)); fFeatures->sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_FEATURES_2; fFeatures->pNext = nullptr; fBackendContext.fInstance = VK_NULL_HANDLE; fBackendContext.fDevice = VK_NULL_HANDLE; if (!sk_gpu_test::CreateVkBackendContext(instProc, &fBackendContext, fExtensions, fFeatures, &fDebugCallback)) { return false; } fDevice = fBackendContext.fDevice; auto getProc = fBackendContext.fGetProc; if (fDebugCallback != VK_NULL_HANDLE) { fDestroyDebugCallback = (PFN_vkDestroyDebugReportCallbackEXT) instProc( fBackendContext.fInstance, "vkDestroyDebugReportCallbackEXT"); } ACQUIRE_INST_VK_PROC(DestroyInstance); ACQUIRE_INST_VK_PROC(DeviceWaitIdle); ACQUIRE_INST_VK_PROC(DestroyDevice); if (!fExtensions->hasExtension(VK_ANDROID_EXTERNAL_MEMORY_ANDROID_HARDWARE_BUFFER_EXTENSION_NAME, 2)) { return false; } if (!fExtensions->hasExtension(VK_KHR_SAMPLER_YCBCR_CONVERSION_EXTENSION_NAME, 1)) { return false; } if (!fExtensions->hasExtension(VK_KHR_EXTERNAL_SEMAPHORE_FD_EXTENSION_NAME, 1)) { return false; } if (!fExtensions->hasExtension(VK_EXT_QUEUE_FAMILY_FOREIGN_EXTENSION_NAME, 1)) { // return false; } ACQUIRE_INST_VK_PROC(GetPhysicalDeviceMemoryProperties2); ACQUIRE_INST_VK_PROC(GetPhysicalDeviceImageFormatProperties2); ACQUIRE_INST_VK_PROC(GetPhysicalDeviceExternalSemaphoreProperties); ACQUIRE_DEVICE_VK_PROC(GetAndroidHardwareBufferPropertiesANDROID); ACQUIRE_DEVICE_VK_PROC(CreateImage); ACQUIRE_DEVICE_VK_PROC(GetImageMemoryRequirements2); ACQUIRE_DEVICE_VK_PROC(DestroyImage); ACQUIRE_DEVICE_VK_PROC(AllocateMemory); ACQUIRE_DEVICE_VK_PROC(BindImageMemory2); ACQUIRE_DEVICE_VK_PROC(FreeMemory); ACQUIRE_DEVICE_VK_PROC(CreateSemaphore); ACQUIRE_DEVICE_VK_PROC(GetSemaphoreFdKHR); ACQUIRE_DEVICE_VK_PROC(ImportSemaphoreFdKHR); ACQUIRE_DEVICE_VK_PROC(DestroySemaphore); fDirectContext = GrDirectContext::MakeVulkan(fBackendContext); REPORTER_ASSERT(reporter, fDirectContext.get()); if (!fDirectContext) { return false; } return this->checkOptimalHardwareBuffer(reporter); } bool VulkanTestHelper::checkOptimalHardwareBuffer(skiatest::Reporter* reporter) { VkResult err; VkPhysicalDeviceExternalImageFormatInfo externalImageFormatInfo; externalImageFormatInfo.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_EXTERNAL_IMAGE_FORMAT_INFO; externalImageFormatInfo.pNext = nullptr; externalImageFormatInfo.handleType = VK_EXTERNAL_MEMORY_HANDLE_TYPE_ANDROID_HARDWARE_BUFFER_BIT_ANDROID; //externalImageFormatInfo.handType = 0x80; // We will create the hardware buffer with gpu sampled so these usages should all be valid VkImageUsageFlags usageFlags = VK_IMAGE_USAGE_SAMPLED_BIT | VK_IMAGE_USAGE_TRANSFER_SRC_BIT | VK_IMAGE_USAGE_TRANSFER_DST_BIT; VkPhysicalDeviceImageFormatInfo2 imageFormatInfo; imageFormatInfo.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_IMAGE_FORMAT_INFO_2; imageFormatInfo.pNext = &externalImageFormatInfo; imageFormatInfo.format = VK_FORMAT_R8G8B8A8_UNORM; imageFormatInfo.type = VK_IMAGE_TYPE_2D; imageFormatInfo.tiling = VK_IMAGE_TILING_OPTIMAL; imageFormatInfo.usage = usageFlags; imageFormatInfo.flags = 0; VkAndroidHardwareBufferUsageANDROID hwbUsage; hwbUsage.sType = VK_STRUCTURE_TYPE_ANDROID_HARDWARE_BUFFER_USAGE_ANDROID; hwbUsage.pNext = nullptr; VkExternalImageFormatProperties externalImgFormatProps; externalImgFormatProps.sType = VK_STRUCTURE_TYPE_EXTERNAL_IMAGE_FORMAT_PROPERTIES; externalImgFormatProps.pNext = &hwbUsage; VkImageFormatProperties2 imgFormProps; imgFormProps.sType = VK_STRUCTURE_TYPE_IMAGE_FORMAT_PROPERTIES_2; imgFormProps.pNext = &externalImgFormatProps; err = fVkGetPhysicalDeviceImageFormatProperties2(fBackendContext.fPhysicalDevice, &imageFormatInfo, &imgFormProps); if (VK_SUCCESS != err) { ERRORF(reporter, "vkGetPhysicalDeviceImageFormatProperites failed, err: %d", err); return false; } const VkImageFormatProperties& imageFormatProperties = imgFormProps.imageFormatProperties; REPORTER_ASSERT(reporter, DEV_W <= imageFormatProperties.maxExtent.width); REPORTER_ASSERT(reporter, DEV_H <= imageFormatProperties.maxExtent.height); const VkExternalMemoryProperties& externalImageFormatProps = externalImgFormatProps.externalMemoryProperties; REPORTER_ASSERT(reporter, SkToBool(VK_EXTERNAL_MEMORY_FEATURE_DEDICATED_ONLY_BIT & externalImageFormatProps.externalMemoryFeatures)); REPORTER_ASSERT(reporter, SkToBool(VK_EXTERNAL_MEMORY_FEATURE_IMPORTABLE_BIT & externalImageFormatProps.externalMemoryFeatures)); REPORTER_ASSERT(reporter, SkToBool(AHARDWAREBUFFER_USAGE_GPU_SAMPLED_IMAGE & hwbUsage.androidHardwareBufferUsage)); return true; } bool VulkanTestHelper::importHardwareBuffer(skiatest::Reporter* reporter, AHardwareBuffer* buffer, bool forWrite, GrVkImageInfo* outImageInfo) { VkResult err; VkAndroidHardwareBufferFormatPropertiesANDROID hwbFormatProps; hwbFormatProps.sType = VK_STRUCTURE_TYPE_ANDROID_HARDWARE_BUFFER_FORMAT_PROPERTIES_ANDROID; hwbFormatProps.pNext = nullptr; VkAndroidHardwareBufferPropertiesANDROID hwbProps; hwbProps.sType = VK_STRUCTURE_TYPE_ANDROID_HARDWARE_BUFFER_PROPERTIES_ANDROID; hwbProps.pNext = &hwbFormatProps; err = fVkGetAndroidHardwareBufferPropertiesANDROID(fDevice, buffer, &hwbProps); if (VK_SUCCESS != err) { ERRORF(reporter, "GetAndroidHardwareBufferPropertiesAndroid failed, err: %d", err); return false; } REPORTER_ASSERT(reporter, VK_FORMAT_R8G8B8A8_UNORM == hwbFormatProps.format); REPORTER_ASSERT(reporter, SkToBool(VK_FORMAT_FEATURE_SAMPLED_IMAGE_BIT & hwbFormatProps.formatFeatures) && SkToBool(VK_FORMAT_FEATURE_TRANSFER_SRC_BIT & hwbFormatProps.formatFeatures) && SkToBool(VK_FORMAT_FEATURE_TRANSFER_DST_BIT & hwbFormatProps.formatFeatures)); if (forWrite) { REPORTER_ASSERT(reporter, SkToBool(VK_FORMAT_FEATURE_COLOR_ATTACHMENT_BIT & hwbFormatProps.formatFeatures)); } bool useExternalFormat = VK_FORMAT_UNDEFINED == hwbFormatProps.format; const VkExternalFormatANDROID externalFormatInfo { VK_STRUCTURE_TYPE_EXTERNAL_FORMAT_ANDROID, // sType nullptr, // pNext useExternalFormat ? hwbFormatProps.externalFormat : 0, // externalFormat }; const VkExternalMemoryImageCreateInfo externalMemoryImageInfo { VK_STRUCTURE_TYPE_EXTERNAL_MEMORY_IMAGE_CREATE_INFO, // sType &externalFormatInfo, // pNext VK_EXTERNAL_MEMORY_HANDLE_TYPE_ANDROID_HARDWARE_BUFFER_BIT_ANDROID, // handleTypes }; VkImageUsageFlags usageFlags = VK_IMAGE_USAGE_SAMPLED_BIT | VK_IMAGE_USAGE_TRANSFER_SRC_BIT | VK_IMAGE_USAGE_TRANSFER_DST_BIT; if (forWrite) { usageFlags |= VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT; } const VkImageCreateInfo imageCreateInfo = { VK_STRUCTURE_TYPE_IMAGE_CREATE_INFO, // sType &externalMemoryImageInfo, // pNext 0, // VkImageCreateFlags VK_IMAGE_TYPE_2D, // VkImageType hwbFormatProps.format, // VkFormat { DEV_W, DEV_H, 1 }, // VkExtent3D 1, // mipLevels 1, // arrayLayers VK_SAMPLE_COUNT_1_BIT, // samples VK_IMAGE_TILING_OPTIMAL, // VkImageTiling usageFlags, // VkImageUsageFlags VK_SHARING_MODE_EXCLUSIVE, // VkSharingMode 0, // queueFamilyCount 0, // pQueueFamilyIndices VK_IMAGE_LAYOUT_UNDEFINED, // initialLayout }; err = fVkCreateImage(fDevice, &imageCreateInfo, nullptr, &fImage); if (VK_SUCCESS != err) { ERRORF(reporter, "Create Image failed, err: %d", err); return false; } VkPhysicalDeviceMemoryProperties2 phyDevMemProps; phyDevMemProps.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_MEMORY_PROPERTIES_2; phyDevMemProps.pNext = nullptr; uint32_t typeIndex = 0; uint32_t heapIndex = 0; bool foundHeap = false; fVkGetPhysicalDeviceMemoryProperties2(fBackendContext.fPhysicalDevice, &phyDevMemProps); uint32_t memTypeCnt = phyDevMemProps.memoryProperties.memoryTypeCount; for (uint32_t i = 0; i < memTypeCnt && !foundHeap; ++i) { if (hwbProps.memoryTypeBits & (1 << i)) { const VkPhysicalDeviceMemoryProperties& pdmp = phyDevMemProps.memoryProperties; uint32_t supportedFlags = pdmp.memoryTypes[i].propertyFlags & VK_MEMORY_PROPERTY_DEVICE_LOCAL_BIT; if (supportedFlags == VK_MEMORY_PROPERTY_DEVICE_LOCAL_BIT) { typeIndex = i; heapIndex = pdmp.memoryTypes[i].heapIndex; foundHeap = true; } } } if (!foundHeap) { ERRORF(reporter, "Failed to find valid heap for imported memory"); return false; } VkImportAndroidHardwareBufferInfoANDROID hwbImportInfo; hwbImportInfo.sType = VK_STRUCTURE_TYPE_IMPORT_ANDROID_HARDWARE_BUFFER_INFO_ANDROID; hwbImportInfo.pNext = nullptr; hwbImportInfo.buffer = buffer; VkMemoryDedicatedAllocateInfo dedicatedAllocInfo; dedicatedAllocInfo.sType = VK_STRUCTURE_TYPE_MEMORY_DEDICATED_ALLOCATE_INFO; dedicatedAllocInfo.pNext = &hwbImportInfo; dedicatedAllocInfo.image = fImage; dedicatedAllocInfo.buffer = VK_NULL_HANDLE; VkMemoryAllocateInfo allocInfo = { VK_STRUCTURE_TYPE_MEMORY_ALLOCATE_INFO, // sType &dedicatedAllocInfo, // pNext hwbProps.allocationSize, // allocationSize typeIndex, // memoryTypeIndex }; err = fVkAllocateMemory(fDevice, &allocInfo, nullptr, &fMemory); if (VK_SUCCESS != err) { ERRORF(reporter, "AllocateMemory failed for imported buffer, err: %d", err); return false; } VkBindImageMemoryInfo bindImageInfo; bindImageInfo.sType = VK_STRUCTURE_TYPE_BIND_IMAGE_MEMORY_INFO; bindImageInfo.pNext = nullptr; bindImageInfo.image = fImage; bindImageInfo.memory = fMemory; bindImageInfo.memoryOffset = 0; err = fVkBindImageMemory2(fDevice, 1, &bindImageInfo); if (VK_SUCCESS != err) { ERRORF(reporter, "BindImageMemory failed for imported buffer, err: %d", err); return false; } GrVkAlloc alloc; alloc.fMemory = fMemory; alloc.fOffset = 0; alloc.fSize = hwbProps.allocationSize; alloc.fFlags = 0; outImageInfo->fImage = fImage; outImageInfo->fAlloc = alloc; outImageInfo->fImageTiling = VK_IMAGE_TILING_OPTIMAL; outImageInfo->fImageLayout = VK_IMAGE_LAYOUT_UNDEFINED; outImageInfo->fFormat = VK_FORMAT_R8G8B8A8_UNORM; outImageInfo->fImageUsageFlags = usageFlags; outImageInfo->fLevelCount = 1; outImageInfo->fCurrentQueueFamily = VK_QUEUE_FAMILY_EXTERNAL; return true; } sk_sp VulkanTestHelper::importHardwareBufferForRead(skiatest::Reporter* reporter, AHardwareBuffer* buffer) { GrVkImageInfo imageInfo; if (!this->importHardwareBuffer(reporter, buffer, false, &imageInfo)) { return nullptr; } GrBackendTexture backendTex(DEV_W, DEV_H, imageInfo); sk_sp wrappedImage = SkImage::MakeFromTexture(fDirectContext.get(), backendTex, kTopLeft_GrSurfaceOrigin, kRGBA_8888_SkColorType, kPremul_SkAlphaType, nullptr); if (!wrappedImage.get()) { ERRORF(reporter, "Failed to create wrapped Vulkan SkImage"); return nullptr; } return wrappedImage; } bool VulkanTestHelper::flushSurfaceAndSignalSemaphore(skiatest::Reporter* reporter, sk_sp surface) { surface->flushAndSubmit(); surface.reset(); GrBackendSemaphore semaphore; if (!this->setupSemaphoreForSignaling(reporter, &semaphore)) { return false; } GrFlushInfo info; info.fNumSemaphores = 1; info.fSignalSemaphores = &semaphore; GrSemaphoresSubmitted submitted = fDirectContext->flush(info); fDirectContext->submit(); if (GrSemaphoresSubmitted::kNo == submitted) { ERRORF(reporter, "Failing call to flush on GrDirectContext"); return false; } SkASSERT(semaphore.isInitialized()); if (!this->exportSemaphore(reporter, semaphore)) { return false; } return true; } bool VulkanTestHelper::setupSemaphoreForSignaling(skiatest::Reporter* reporter, GrBackendSemaphore* beSemaphore) { // Query supported info VkPhysicalDeviceExternalSemaphoreInfo exSemInfo; exSemInfo.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_EXTERNAL_SEMAPHORE_INFO; exSemInfo.pNext = nullptr; exSemInfo.handleType = VK_EXTERNAL_SEMAPHORE_HANDLE_TYPE_SYNC_FD_BIT; VkExternalSemaphoreProperties exSemProps; exSemProps.sType = VK_STRUCTURE_TYPE_EXTERNAL_SEMAPHORE_PROPERTIES; exSemProps.pNext = nullptr; fVkGetPhysicalDeviceExternalSemaphoreProperties(fBackendContext.fPhysicalDevice, &exSemInfo, &exSemProps); if (!SkToBool(exSemProps.exportFromImportedHandleTypes & VK_EXTERNAL_SEMAPHORE_HANDLE_TYPE_SYNC_FD_BIT)) { ERRORF(reporter, "HANDLE_TYPE_SYNC_FD not listed as exportFromImportedHandleTypes"); return false; } if (!SkToBool(exSemProps.compatibleHandleTypes & VK_EXTERNAL_SEMAPHORE_HANDLE_TYPE_SYNC_FD_BIT)) { ERRORF(reporter, "HANDLE_TYPE_SYNC_FD not listed as compatibleHandleTypes"); return false; } if (!SkToBool(exSemProps.externalSemaphoreFeatures & VK_EXTERNAL_SEMAPHORE_FEATURE_EXPORTABLE_BIT) || !SkToBool(exSemProps.externalSemaphoreFeatures & VK_EXTERNAL_SEMAPHORE_FEATURE_IMPORTABLE_BIT)) { ERRORF(reporter, "HANDLE_TYPE_SYNC_FD doesn't support export and import feature"); return false; } VkExportSemaphoreCreateInfo exportInfo; exportInfo.sType = VK_STRUCTURE_TYPE_EXPORT_SEMAPHORE_CREATE_INFO; exportInfo.pNext = nullptr; exportInfo.handleTypes = VK_EXTERNAL_SEMAPHORE_HANDLE_TYPE_SYNC_FD_BIT; VkSemaphoreCreateInfo semaphoreInfo; semaphoreInfo.sType = VK_STRUCTURE_TYPE_SEMAPHORE_CREATE_INFO; semaphoreInfo.pNext = &exportInfo; semaphoreInfo.flags = 0; VkSemaphore semaphore; VkResult err = fVkCreateSemaphore(fDevice, &semaphoreInfo, nullptr, &semaphore); if (VK_SUCCESS != err) { ERRORF(reporter, "Failed to create signal semaphore, err: %d", err); return false; } beSemaphore->initVulkan(semaphore); return true; } bool VulkanTestHelper::exportSemaphore(skiatest::Reporter* reporter, const GrBackendSemaphore& beSemaphore) { VkSemaphore semaphore = beSemaphore.vkSemaphore(); if (VK_NULL_HANDLE == semaphore) { ERRORF(reporter, "Invalid vulkan handle in export call"); return false; } VkSemaphoreGetFdInfoKHR getFdInfo; getFdInfo.sType = VK_STRUCTURE_TYPE_SEMAPHORE_GET_FD_INFO_KHR; getFdInfo.pNext = nullptr; getFdInfo.semaphore = semaphore; getFdInfo.handleType = VK_EXTERNAL_SEMAPHORE_HANDLE_TYPE_SYNC_FD_BIT; VkResult err = fVkGetSemaphoreFdKHR(fDevice, &getFdInfo, &fFdHandle); if (VK_SUCCESS != err) { ERRORF(reporter, "Failed to export signal semaphore, err: %d", err); return false; } fSignalSemaphore = semaphore; return true; } bool VulkanTestHelper::importAndWaitOnSemaphore(skiatest::Reporter* reporter, int fdHandle, sk_sp surface) { VkSemaphoreCreateInfo semaphoreInfo; semaphoreInfo.sType = VK_STRUCTURE_TYPE_SEMAPHORE_CREATE_INFO; semaphoreInfo.pNext = nullptr; semaphoreInfo.flags = 0; VkSemaphore semaphore; VkResult err = fVkCreateSemaphore(fDevice, &semaphoreInfo, nullptr, &semaphore); if (VK_SUCCESS != err) { ERRORF(reporter, "Failed to create import semaphore, err: %d", err); return false; } VkImportSemaphoreFdInfoKHR importInfo; importInfo.sType = VK_STRUCTURE_TYPE_IMPORT_SEMAPHORE_FD_INFO_KHR; importInfo.pNext = nullptr; importInfo.semaphore = semaphore; importInfo.flags = VK_SEMAPHORE_IMPORT_TEMPORARY_BIT; importInfo.handleType = VK_EXTERNAL_SEMAPHORE_HANDLE_TYPE_SYNC_FD_BIT; importInfo.fd = fdHandle; err = fVkImportSemaphoreFdKHR(fDevice, &importInfo); if (VK_SUCCESS != err) { ERRORF(reporter, "Failed to import semaphore, err: %d", err); return false; } GrBackendSemaphore beSemaphore; beSemaphore.initVulkan(semaphore); if (!surface->wait(1, &beSemaphore)) { ERRORF(reporter, "Failed to add wait semaphore to surface"); fVkDestroySemaphore(fDevice, semaphore, nullptr); return false; } return true; } sk_sp VulkanTestHelper::importHardwareBufferForWrite(skiatest::Reporter* reporter, AHardwareBuffer* buffer) { GrVkImageInfo imageInfo; if (!this->importHardwareBuffer(reporter, buffer, true, &imageInfo)) { return nullptr; } GrBackendTexture backendTex(DEV_W, DEV_H, imageInfo); sk_sp surface = SkSurface::MakeFromBackendTexture(fDirectContext.get(), backendTex, kTopLeft_GrSurfaceOrigin, 0, kRGBA_8888_SkColorType, nullptr, nullptr); if (!surface.get()) { ERRORF(reporter, "Failed to create wrapped Vulkan SkSurface"); return nullptr; } return surface; } static SkPMColor get_src_color(int x, int y) { SkASSERT(x >= 0 && x < DEV_W); SkASSERT(y >= 0 && y < DEV_H); U8CPU r = x; U8CPU g = y; U8CPU b = 0xc; U8CPU a = 0xff; switch ((x+y) % 5) { case 0: a = 0xff; break; case 1: a = 0x80; break; case 2: a = 0xCC; break; case 4: a = 0x01; break; case 3: a = 0x00; break; } a = 0xff; return SkPremultiplyARGBInline(a, r, g, b); } static SkBitmap make_src_bitmap() { static SkBitmap bmp; if (bmp.isNull()) { bmp.allocN32Pixels(DEV_W, DEV_H); intptr_t pixels = reinterpret_cast(bmp.getPixels()); for (int y = 0; y < DEV_H; ++y) { for (int x = 0; x < DEV_W; ++x) { SkPMColor* pixel = reinterpret_cast( pixels + y * bmp.rowBytes() + x * bmp.bytesPerPixel()); *pixel = get_src_color(x, y); } } } return bmp; } static bool check_read(skiatest::Reporter* reporter, const SkBitmap& srcBitmap, const SkBitmap& dstBitmap) { bool result = true; for (int y = 0; y < DEV_H && result; ++y) { for (int x = 0; x < DEV_W && result; ++x) { const uint32_t srcPixel = *srcBitmap.getAddr32(x, y); const uint32_t dstPixel = *dstBitmap.getAddr32(x, y); if (srcPixel != dstPixel) { ERRORF(reporter, "Expected readback pixel (%d, %d) value 0x%08x, got 0x%08x.", x, y, srcPixel, dstPixel); result = false; } /*else { ERRORF(reporter, "Got good readback pixel (%d, %d) value 0x%08x, got 0x%08x.", x, y, srcPixel, dstPixel); }*/ } } return result; } static void cleanup_resources(BaseTestHelper* srcHelper, BaseTestHelper* dstHelper, AHardwareBuffer* buffer) { if (srcHelper) { srcHelper->cleanup(); } if (dstHelper) { dstHelper->cleanup(); } if (buffer) { AHardwareBuffer_release(buffer); } } enum class SrcType { kCPU, kEGL, kVulkan, }; enum class DstType { kEGL, kVulkan, }; void run_test(skiatest::Reporter* reporter, const GrContextOptions& options, SrcType srcType, DstType dstType, bool shareSyncs) { if (SrcType::kCPU == srcType && shareSyncs) { // We don't currently test this since we don't do any syncs in this case. return; } std::unique_ptr srcHelper; std::unique_ptr dstHelper; AHardwareBuffer* buffer = nullptr; if (SrcType::kVulkan == srcType) { srcHelper.reset(new VulkanTestHelper()); } else if (SrcType::kEGL == srcType) { #ifdef SK_GL srcHelper.reset(new EGLTestHelper(options)); #else SkASSERT(false, "SrcType::kEGL used without OpenGL support."); #endif } if (srcHelper) { if (!srcHelper->init(reporter)) { cleanup_resources(srcHelper.get(), dstHelper.get(), buffer); return; } } if (DstType::kVulkan == dstType) { dstHelper.reset(new VulkanTestHelper()); } else { #ifdef SK_GL SkASSERT(DstType::kEGL == dstType); dstHelper.reset(new EGLTestHelper(options)); #else SkASSERT(false, "DstType::kEGL used without OpenGL support."); #endif } if (dstHelper) { if (!dstHelper->init(reporter)) { cleanup_resources(srcHelper.get(), dstHelper.get(), buffer); return; } } /////////////////////////////////////////////////////////////////////////// // Setup SkBitmaps /////////////////////////////////////////////////////////////////////////// SkBitmap srcBitmap = make_src_bitmap(); SkBitmap dstBitmapSurface; dstBitmapSurface.allocN32Pixels(DEV_W, DEV_H); SkBitmap dstBitmapFinal; dstBitmapFinal.allocN32Pixels(DEV_W, DEV_H); /////////////////////////////////////////////////////////////////////////// // Setup AHardwareBuffer /////////////////////////////////////////////////////////////////////////// AHardwareBuffer_Desc hwbDesc; hwbDesc.width = DEV_W; hwbDesc.height = DEV_H; hwbDesc.layers = 1; if (SrcType::kCPU == srcType) { hwbDesc.usage = AHARDWAREBUFFER_USAGE_CPU_READ_NEVER | AHARDWAREBUFFER_USAGE_CPU_WRITE_OFTEN | AHARDWAREBUFFER_USAGE_GPU_SAMPLED_IMAGE; } else { hwbDesc.usage = AHARDWAREBUFFER_USAGE_CPU_READ_NEVER | AHARDWAREBUFFER_USAGE_CPU_WRITE_NEVER | AHARDWAREBUFFER_USAGE_GPU_SAMPLED_IMAGE | AHARDWAREBUFFER_USAGE_GPU_COLOR_OUTPUT; } hwbDesc.format = AHARDWAREBUFFER_FORMAT_R8G8B8A8_UNORM; // The following three are not used in the allocate hwbDesc.stride = 0; hwbDesc.rfu0= 0; hwbDesc.rfu1= 0; if (int error = AHardwareBuffer_allocate(&hwbDesc, &buffer)) { ERRORF(reporter, "Failed to allocated hardware buffer, error: %d", error); cleanup_resources(srcHelper.get(), dstHelper.get(), buffer); return; } if (SrcType::kCPU == srcType) { // Get actual desc for allocated buffer so we know the stride for uploading cpu data. AHardwareBuffer_describe(buffer, &hwbDesc); uint32_t* bufferAddr; if (AHardwareBuffer_lock(buffer, AHARDWAREBUFFER_USAGE_CPU_WRITE_OFTEN, -1, nullptr, reinterpret_cast(&bufferAddr))) { ERRORF(reporter, "Failed to lock hardware buffer"); cleanup_resources(srcHelper.get(), dstHelper.get(), buffer); return; } int bbp = srcBitmap.bytesPerPixel(); uint32_t* src = (uint32_t*)srcBitmap.getPixels(); uint32_t* dst = bufferAddr; for (int y = 0; y < DEV_H; ++y) { memcpy(dst, src, DEV_W * bbp); src += DEV_W; dst += hwbDesc.stride; } for (int y = 0; y < DEV_H; ++y) { for (int x = 0; x < DEV_W; ++x) { const uint32_t srcPixel = *srcBitmap.getAddr32(x, y); uint32_t dstPixel = bufferAddr[y * hwbDesc.stride + x]; if (srcPixel != dstPixel) { ERRORF(reporter, "CPU HWB Expected readpix (%d, %d) value 0x%08x, got 0x%08x.", x, y, srcPixel, dstPixel); } } } AHardwareBuffer_unlock(buffer, nullptr); } else { srcHelper->makeCurrent(); sk_sp surface = srcHelper->importHardwareBufferForWrite(reporter, buffer); if (!surface) { cleanup_resources(srcHelper.get(), dstHelper.get(), buffer); return; } sk_sp srcBmpImage = SkImage::MakeFromBitmap(srcBitmap); surface->getCanvas()->drawImage(srcBmpImage, 0, 0); // If we are testing sharing of syncs, don't do a read here since it forces sychronization // to occur. if (!shareSyncs) { bool readResult = surface->readPixels(dstBitmapSurface, 0, 0); if (!readResult) { ERRORF(reporter, "Read Pixels on surface failed"); surface.reset(); cleanup_resources(srcHelper.get(), dstHelper.get(), buffer); return; } REPORTER_ASSERT(reporter, check_read(reporter, srcBitmap, dstBitmapSurface)); } /////////////////////////////////////////////////////////////////////////// // Cleanup GL/EGL and add syncs /////////////////////////////////////////////////////////////////////////// if (shareSyncs) { if (!srcHelper->flushSurfaceAndSignalSemaphore(reporter, std::move(surface))) { cleanup_resources(srcHelper.get(), dstHelper.get(), buffer); return; } } else { surface.reset(); srcHelper->doClientSync(); srcHelper->releaseImage(); } } /////////////////////////////////////////////////////////////////////////// // Import the HWB into backend and draw it to a surface /////////////////////////////////////////////////////////////////////////// dstHelper->makeCurrent(); sk_sp wrappedImage = dstHelper->importHardwareBufferForRead(reporter, buffer); if (!wrappedImage) { cleanup_resources(srcHelper.get(), dstHelper.get(), buffer); return; } auto direct = dstHelper->directContext(); // Make SkSurface to render wrapped HWB into. SkImageInfo imageInfo = SkImageInfo::Make(DEV_W, DEV_H, kRGBA_8888_SkColorType, kPremul_SkAlphaType, nullptr); sk_sp dstSurf = SkSurface::MakeRenderTarget(direct, SkBudgeted::kNo, imageInfo, 0, kTopLeft_GrSurfaceOrigin, nullptr, false); if (!dstSurf.get()) { ERRORF(reporter, "Failed to create destination SkSurface"); wrappedImage.reset(); cleanup_resources(srcHelper.get(), dstHelper.get(), buffer); return; } if (shareSyncs) { if (!dstHelper->importAndWaitOnSemaphore(reporter, srcHelper->getFdHandle(), dstSurf)) { wrappedImage.reset(); cleanup_resources(srcHelper.get(), dstHelper.get(), buffer); return; } } dstSurf->getCanvas()->drawImage(wrappedImage, 0, 0); bool readResult = dstSurf->readPixels(dstBitmapFinal, 0, 0); if (!readResult) { ERRORF(reporter, "Read Pixels failed"); wrappedImage.reset(); dstSurf.reset(); dstHelper->doClientSync(); cleanup_resources(srcHelper.get(), dstHelper.get(), buffer); return; } REPORTER_ASSERT(reporter, check_read(reporter, srcBitmap, dstBitmapFinal)); dstSurf.reset(); wrappedImage.reset(); dstHelper->doClientSync(); cleanup_resources(srcHelper.get(), dstHelper.get(), buffer); } DEF_GPUTEST(VulkanHardwareBuffer_CPU_Vulkan, reporter, options) { run_test(reporter, options, SrcType::kCPU, DstType::kVulkan, false); } DEF_GPUTEST(VulkanHardwareBuffer_Vulkan_Vulkan, reporter, options) { run_test(reporter, options, SrcType::kVulkan, DstType::kVulkan, false); } DEF_GPUTEST(VulkanHardwareBuffer_Vulkan_Vulkan_Syncs, reporter, options) { run_test(reporter, options, SrcType::kVulkan, DstType::kVulkan, true); } #if defined(SK_GL) DEF_GPUTEST(VulkanHardwareBuffer_EGL_Vulkan, reporter, options) { run_test(reporter, options, SrcType::kEGL, DstType::kVulkan, false); } DEF_GPUTEST(VulkanHardwareBuffer_CPU_EGL, reporter, options) { run_test(reporter, options, SrcType::kCPU, DstType::kEGL, false); } DEF_GPUTEST(VulkanHardwareBuffer_EGL_EGL, reporter, options) { run_test(reporter, options, SrcType::kEGL, DstType::kEGL, false); } DEF_GPUTEST(VulkanHardwareBuffer_Vulkan_EGL, reporter, options) { run_test(reporter, options, SrcType::kVulkan, DstType::kEGL, false); } DEF_GPUTEST(VulkanHardwareBuffer_EGL_EGL_Syncs, reporter, options) { run_test(reporter, options, SrcType::kEGL, DstType::kEGL, true); } DEF_GPUTEST(VulkanHardwareBuffer_Vulkan_EGL_Syncs, reporter, options) { run_test(reporter, options, SrcType::kVulkan, DstType::kEGL, true); } DEF_GPUTEST(VulkanHardwareBuffer_EGL_Vulkan_Syncs, reporter, options) { run_test(reporter, options, SrcType::kEGL, DstType::kVulkan, true); } #endif #endif // SK_SUPPORT_GPU && defined(SK_BUILD_FOR_ANDROID) && // __ANDROID_API__ >= 26 && defined(SK_VULKAN)