nvpro-samples

The build_all folder is an optional folder that allows you to synchronize and build all the samples that you have cloned using a single solution.

CMakeLists.txt: the CMake file that will walk through samples to include them in the project
README.md: this file
LICENSE: the license used for all nvpro-samples
batch/script files: allows to easily clone/pull all existing samples

Running the clone_all batch/script will create the following directory structure:

build_all
nvpro_core
... (all repositories specified in the script)

Each sample can be built either individually, or with build_all/CMakeLists.txt as single solution. You can also configure the solution for build_all to only include a subset of projects with the appropriate BUILD_sample_name checkbox in the CMake UI.

All samples must be built for a 64-bit architecture, and most samples require C++14. All of these samples support Windows (MSVC 2017 is our minimum compiler), while many of them also support Linux as well (more comprehensive Linux support is in progress).

Shared Dependencies

nvpro_core: The primary framework that all samples depend on. Contains window management, UI, and various API helpers.

Vulkan Samples

These samples are "pure" Vulkan samples and use its WSI system to create the window swapchain.

vk_async_resources

In Vulkan lifetime management such as deleting resources is a bit more complex than in OpenGL. The basic sample describes a strategy that delays deletion of Vulkan resources for a few frames. Furthermore Vulkan provides multiple ways to upload data to the device, three different approaches are described.

Tags: synchronization

vk_compute_mipmaps

Demonstrates a customizable cache-aware mipmap generation algorithm using compute shaders. Includes the nvpro_pyramid library, which can be used independently of this sample with no dependencies besides standard C++ and Vulkan. Supports non-power-of-2 textures while outperforming the conventional blit algorithm.

Tags: mipmapping, image processing, compute shader, library, subgroups, procedural

vk_denoise

This example is an extension of the vk_raytrace example. After a few iterations, the image will be denoised using the Optix7 denoiser. To achieve this, an interop between CUDA and Vulkan is set. Vulkan images are converted to CUDA buffers and converted back after been denoised. This pass is inserted between other rendering passes, as it is done in vk_raytrace.

Loads .gltf 2 models
VK_NV_ray_tracing
VK_EXT_descriptor_indexing
VK_KHR_external_memory
VK_KHR_external_semaphore
VK_KHR_external_fence

Tags: ray tracing, path tracing, glTF, HDR, tonemapper, picking, BLAS, TLAS, PBR material, denoising, Cuda, interop, OptiX

vk_device_generated_cmds

In this sample the functionality of the VK_NV_device_generated_commands is demonstrated. This extension greatly enhances the indirect drawing capabilities and adds the ability to change shaders on the device. Furthermore the usage of bindless buffers is shown, as an alternative to the classic descriptor set binding model.

Loads .csf and .gltf 2 models
VK_NV_device_generated_commands
VK_EXT_buffer_device_address
GLSL_EXT_buffer_reference

Tags: Device Generated Commands, glTF, synchronization, bindless

vk_idbuffer_rasterization

Shows how to render per-part IDs efficiently. This can be used for selection for or id/item-buffer rasterization where a pixel represents each part uniquely.

A CAD object is made of many parts; rendering them all individually is too slow. Use gl_PrimitiveID to accelerate the process and allow larger drawcalls that represent many parts at once.
Use 64-bit atomics to do a very cheap selection highlight mechanism in the fragment shader.

Tags: idbuffer, item buffer, optimization, selection highlight

vk_inherited_viewport

Demonstrates how to use the VK_NV_inherited_viewport_scissor extension to redraw scenes with dynamically changing scissor and viewport settings without having to re-record secondary command buffers.

Tags: optimization, indirect draw, instancing

vk_mini_path_tracer

A beginner-friendly Vulkan path tracing tutorial in under 300 lines of C++. Intended as both an introduction to Vulkan, and as an introduction to computer graphics through ray tracing. Includes tips and tricks along the way, and extra chapters show how to extend the path tracer, implement production techniques, and use a performance analysis tool. Dovetails into vk_raytracing_tutorial_KHR.

VK_KHR_acceleration_structure
VK_KHR_shader_non_semantic_info
VK_KHR_ray_query
VK_KHR_ray_tracing_pipeline

Tags: ray tracing, path tracing, ray queries, ray tracing pipelines, compute shaders, debug printf, BLAS, TLAS, OBJ, beginner

vk_raytrace

Reads a glTF scene and renders the scene using NVIDIA ray tracing. It uses techniques like image base lighting and importance sampling, reflections, transparency and indirect illumination. The camera simulates a pin-hole whitted camera and the image is toned mapped using various tone mappers.

The example shows as well how to implement a picking ray, which is using the same acceleration structure for drawing, but is using the hit data to return the information under the mouse cursor. This information can be use for setting the camera interest position, or to debug any shading data.

Loads .gltf 2 models
VK_NV_ray_tracing
VK_EXT_descriptor_indexing

Tags: ray tracing, glTF, HDR, tonemapper, picking, BLAS, TLAS, PBR material

vk_raytracing_tutorial_KHR

A tutorial that explains step-by-step what is needed to add ray tracing to an existing Vulkan application. The first tutorial is the base of ray tracing, and from this base, many other tutorials are explaining the various features of RTX.

Explain Vulkan ray tracing
Animating BLAS and TLAS
Using any hit shaders
Using memory managers for handling many objects and instances
Using an intersection shader and rendering implicit geometries
Jittering camera ray generation and image accumulation for anti-aliased images
Using various closest hit shaders
Using shader record to modify the behavior of the shader.
Recursive reflection vs iterative reflection

Tags: ray tracing, OBJ, tonemapper, BLAS, TLAS

vk_offline

Simple offline application which using Vulkan to render without opening a window.

Very simple Vulkan offline rendering
Create Vulkan context
Render to frame buffer
Save frame buffer to disk (PNG)

Tags: compute shader, offline rendering

vk_order_independent_transparency

Demonstates seven different techniques for rendering transparent objects without requiring them to be sorted in advance.

Shows seven different ways to implement transparency
Includes antialiasing techniques and linear colorspace rendering
Render pass subpasses used to implement Weighted, Blended Order-Independent Transparency
Shows how to construct linked lists on the GPU
Includes example of fragment shader interlock (GL_ARB_fragment_shader_interlock, much like rasterizer order views in Direct3D 11.3)
Shows how to use 64-bit atomics and the VK_KHR_shader_atomic_int64 extension.

Tags: transparency, subpasses, MSAA, algorithms

vk_shaded_gltfscene

Load a glTF scene with materials and textures. Display a HDR image in the background and use it for lighting the scene. It renders in multiple passes, background, scene, then tonemap the result and add UI at the end. Shows how to deal with many objects, many materials and textures. This example will push the material parameters through push_constant and uses different descriptor sets to enable the textures to use. It also shows how to read the depth buffer to un-project the mouse coordinate to 3D position to set the camera interest.

Loads .gltf 2 models

Tags: glTF, PBR material, HDR, tonemapper, textures, mipmapping, debugging shader, depth buffer reading, picking, importance sampling, cubemap

vk_timeline_semaphore

Provides a concrete example of how timeline semaphores and asynchronous compute-only queues can be used to speed up a heterogeneous compute/graphics Vulkan application.

Implicit surface rendering using the marching cubes algorithm
VK_KHR_timeline_semaphore

Tags: synchronization, compute shader, procedural

vk_toon_shader

Rendering object outlines and details from canvases render with rasterizer or ray tracer.

Extracting object contours
Rendering lines for normal and depth discontinuities
Post-process chaining, image processed used by next post-process
FXAA on line buffers
Toon effect with shading and Kuwahara post-effect

Tags: silhouette, contour, toon shading, post-process, fxaa

vk_video_samples

Encodes and decodes video with an all-Vulkan end-to-end pipeline using the Vulkan Video APIs.

Hardware video decoding
YCbCr-to-RGB conversion via VK_KHR_sampler_ycbcr_conversion
Picture parameter extraction
YCbCr 4:2:0 h.264 encoding
Extensions: VK_KHR_video_queue, VK_KHR_video_decode_queue, VK_KHR_video_encode_queue, VK_EXT_video_decode_h264, VK_EXT_video_decode_h265, VK_EXT_video_encode_h264

Tags: video, image processing

glsl_indexed_types_generator

This project serves as proof of concept how to simplify the usage of VK_EXT_descriptor_indexing and GL_EXT_nonuniform_qualifier within GLSL (typically used in combination with VK_NV_ray_tracing). A Lua script generates structures and function overloads to hide the code for indexing descriptor sets of samplers and textures.

stand-alone, does not depend on nvpro_core
VK_EXT_descriptor_indexing
GL_EXT_nonuniform_qualifier

OpenGL / Vulkan Samples

These samples use the gl_vk_ prefix and showcase Vulkan and OpenGL techniques within the same application (gl_vk_sample_name.exe) or just Vulkan alone (vk_sample_name.exe). If available, using the BUILD_gl_vk_sample_name_VULKAN_ONLY option, you can omit building the combined executable file. The VULKAN_ONLY mode uses Vulkan's WSI system to create the swapchain, the combined executable uses GL_NV_draw_vulkan_image.

gl_vk_threaded_cadscene

OpenGL and Vulkan comparison on rendering a CAD scene using various techniques. Stresses CPU bottlenecks due to the scene having lots of tiny drawcalls. Also touches upon different ways how to provide per-draw data in Vulkan, as well as how to create drawcalls on multiple threads in both OpenGL and Vulkan.

Loads .csf and .gltf 2 models
GL_NV_draw_vulkan_image (not used in VULKAN_ONLY)
GL_NV_command_list
GL_NV_vertex_buffer_unified_memory
GL_NV_uniform_buffer_unified_memory

gl_vk_meshlet_cadscene

This OpenGL/Vulkan sample illustrates the use of mesh shaders for rendering CAD models.

Loads .csf and .gltf 2 models
GL_NV_draw_vulkan_image (not used in VULKAN_ONLY)
GL_NV_mesh_shader
VK_NV_mesh_shader

gl_vk_chopper

Renders an articulated scene with animated and textured models.

GL_NV_draw_vulkan_image

gl_vk_bk3dthreaded

Vulkan sample rendering 3D with worker-threads

GL_NV_draw_vulkan_image

gl_vk_supersampled

Vulkan sample showing a high quality super-sampled rendering

GL_NV_draw_vulkan_image

gl_vk_simple_interop

Rendering an animated image using a Vulkan compute shader and displaying this image using OpenGL on an animated triangle. The image is allocated with Vulkan and shared using Interop.

GL_EXT_memory_object
GL_EXT_semaphore
VK_KHR_external_memory
VK_KHR_external_semaphore
VK_KHR_external_fence

gl_vk_raytrace_interop

This example is adding ray traced ambient occlusion in an OpenGL scene. All buffers are shared between OpenGL and Vulkan to create the acceleration structure needed to ray trace. Rays are sent from the G-Buffer position rendered by the OpenGL rasterizer.

GL_EXT_memory_object
GL_EXT_semaphore
VK_NV_ray_tracing
VK_KHR_external_memory
VK_KHR_external_semaphore
VK_KHR_external_fence

gl_render_vk_direct_display

This example shows how to use Vulkan Direct Display functionality from an OpenGL renderer. A Vulkan Direct Display class provides render textures to an OpenGL renderer, which after rendering submits the textures back to the Vulkan class for presentation on the Direct Display device.

VK_KHR_display
VK_KHR_external_memory
VK_KHR_external_semaphore

OpenGL Samples

gl_cadscene_rendertechniques

OpenGL sample on various rendering approaches for typical CAD scenes. Stresses CPU bottlenecks due to lots of low-complexity drawcalls.

Loads .csf and .gltf 2 models
GL_ARB_multi_draw_indirect
GL_NV_command_list
GL_NV_vertex_buffer_unified_memory
GL_NV_uniform_buffer_unified_memory

gl_occlusion_culling

Sample for shader-based occlusion culling, which is more scalable on modern GPUs than traditional occlusion query techniques. Also showcases how to generate drawcalls on the GPU, so that occlusion culling techniques don't need CPU readbacks.

GL_ARB_multi_draw_indirect
GL_ARB_indirect_parameters
GL_NV_command_list
GL_NV_representative_fragment_test

gl_ssao

Optimized screen-space ambient occlusion, cache-aware HBAO

GL_NV_geometry_shader_passthrough

gl_dynamic_lod

GPU classifies how to render millions of particles. Close/large particles use tessellation, medium sized particles use an optimized instancing technique and distant particles are rendered as points. No CPU readbacks needed.

GL_ARB_compute_shader
GL_ARB_multi_draw_indirect

gl_commandlist_basic

Basic sample for NV_command_list

GL_NV_command_list

gl_path_rendering_CMYK

Example of how to use path rendering; and how to use it with CMYK (using multi-render target)

GL_NV_path_rendering

gl_multicast

Basic sample showcasing multicast capabilities, where one GL stream is very efficiently sent to multiple GPUs. Typical use-case is for example VR SLI, where each GPU renders a different eye.

GL_NV_gpu_multicast

Other APIs

nvml_enterprise_gpu_check

Shows how to correctly load the NVML library for GPU information, and to robustly check using NVML's API if a GPU is an Enterprise/Quadro GPU. (This works even when the GPU, such as the RTX A6000, doesn't have "Quadro" in its name.

nvmlInit
nvmlDeviceGetCount
nvmlDeviceGetHandleByIndex
nvmlDeviceGetBrand

nvtt_samples

(full resolution compression comparison here)

Shows how to use NVTT 3, a GPU-accelerated texture compression and image processing library. This includes several small samples intended as tutorials — such as a program that uses NVTT to load an image and compress it to a one-mipmap DDS file using BC7 block compression in less than 250 C++ characters — and the source code for several tools from NVTT 3 ported to the nvpro-samples framework.

Tags: compression, image processing, CUDA

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