| .. | ||
| .vscode | ||
| Build_instructions.txt | ||
| findvulkan.mk | ||
| frag.spv | ||
| linmath.h | ||
| Makefile | ||
| NsightEclipse.xml | ||
| README.md | ||
| shader.frag | ||
| shader.vert | ||
| teapot1024.ppm | ||
| vert.spv | ||
| vulkanImageCUDA_vs2017.sln | ||
| vulkanImageCUDA_vs2017.vcxproj | ||
| vulkanImageCUDA_vs2019.sln | ||
| vulkanImageCUDA_vs2019.vcxproj | ||
| vulkanImageCUDA_vs2022.sln | ||
| vulkanImageCUDA_vs2022.vcxproj | ||
| vulkanImageCUDA.cu | ||
vulkanImageCUDA - Vulkan Image - CUDA Interop
Description
This sample demonstrates Vulkan Image - CUDA Interop. CUDA imports the Vulkan image buffer, performs box filtering over it, and synchronizes with Vulkan through vulkan semaphores imported by CUDA. This sample depends on Vulkan SDK, GLFW3 libraries, for building this sample please refer to "Build_instructions.txt" provided in this sample's directory
Key Concepts
Graphics Interop, CUDA Vulkan Interop, Data Parallel Algorithms
Supported SM Architectures
SM 3.5 SM 3.7 SM 5.0 SM 5.2 SM 5.3 SM 6.0 SM 6.1 SM 7.0 SM 7.2 SM 7.5 SM 8.0 SM 8.6 SM 8.7
Supported OSes
Linux, Windows
Supported CPU Architecture
x86_64, aarch64
CUDA APIs involved
CUDA Runtime API
cudaGetMipmappedArrayLevel, cudaImportExternalSemaphore, cudaExternalMemoryGetMappedMipmappedArray, cudaMemcpy, cudaDestroyExternalMemory, cudaSignalExternalSemaphoresAsync, cudaFreeMipmappedArray, cudaVkSemaphoreSignal, cudaVkImportImageMem, cudaDestroySurfaceObject, cudaImportExternalMemory, cudaMalloc, cudaSetDevice, cudaGetDeviceProperties, cudaGetDeviceCount, cudaDestroyTextureObject, cudaUpdateVkImage, cudaDestroyExternalSemaphore, cudaFree, cudaStreamCreate, cudaVkSemaphoreWait, cudaExtent, cudaVkImportSemaphore, cudaCreateSurfaceObject, cudaMallocMipmappedArray, cudaCreateTextureObject, cudaWaitExternalSemaphoresAsync
Dependencies needed to build/run
Prerequisites
Download and install the CUDA Toolkit 11.6 for your corresponding platform. Make sure the dependencies mentioned in Dependencies section above are installed.
Build and Run
Windows
The Windows samples are built using the Visual Studio IDE. Solution files (.sln) are provided for each supported version of Visual Studio, using the format:
*_vs<version>.sln - for Visual Studio <version>
Each individual sample has its own set of solution files in its directory:
To build/examine all the samples at once, the complete solution files should be used. To build/examine a single sample, the individual sample solution files should be used.
Note: Some samples require that the Microsoft DirectX SDK (June 2010 or newer) be installed and that the VC++ directory paths are properly set up (Tools > Options...). Check DirectX Dependencies section for details."
Linux
The Linux samples are built using makefiles. To use the makefiles, change the current directory to the sample directory you wish to build, and run make:
$ cd <sample_dir>
$ make
The samples makefiles can take advantage of certain options:
-
TARGET_ARCH= - cross-compile targeting a specific architecture. Allowed architectures are x86_64, aarch64. By default, TARGET_ARCH is set to HOST_ARCH. On a x86_64 machine, not setting TARGET_ARCH is the equivalent of setting TARGET_ARCH=x86_64.
$ make TARGET_ARCH=x86_64
$ make TARGET_ARCH=aarch64
See here for more details. -
dbg=1 - build with debug symbols
$ make dbg=1 -
SMS="A B ..." - override the SM architectures for which the sample will be built, where
"A B ..."is a space-delimited list of SM architectures. For example, to generate SASS for SM 50 and SM 60, useSMS="50 60".$ make SMS="50 60" -
HOST_COMPILER=<host_compiler> - override the default g++ host compiler. See the Linux Installation Guide for a list of supported host compilers.
$ make HOST_COMPILER=g++