Advanced Samples for the NVIDIA OptiX 7 Ray Tracing SDK
The goal of the three initial introduction examples is to show how to port an existing OptiX application based on the previous OptiX 5 or 6 API to OptiX 7.
For that, two of the existing OptiX Introduction Samples have been ported to the OptiX 7 SDK.
intro_runtime and intro_driver are ports from optixIntro_07, and intro_denoiser is a port of the optixIntro_10 example showing the built-in AI denoiser. Those are already demonstrating some advanced methods to architect renderers using OptiX 7 on the way.
If you need a basic introduction into OptiX 7 programming, please refer to the OptiX 7 SIGGRAPH course material first and maybe read through the OptiX developer forum as well for many topics about OptiX 7.
The landing page for online NVIDIA ray tracing programming guides and API reference documentation can be found here: NVIDIA ray tracing documentation. This contains more up-to-date information compared to documents shipping with the SDKs and is easy to search including cross-reference links.
Please always read the OptiX SDK Release Notes before setting up a development environment.
OptiX 7 applications are written using the CUDA programming APIs. There are two to choose from: The CUDA Runtime API and the CUDA Driver API.
The CUDA Runtime API is a little more high-level and usually requires a library to be shipped with the application if not linked statically, while the CUDA Driver API is more explicit and always ships with the NVIDIA display drivers. The documentation inside the CUDA API headers cross-reference the respective function names of each other API.
To demonstrate the CUDA host API differences, intro_runtime and intro_driver are both a port of OptiX Introduction sample #7 just using the CUDA Runtime API resp. CUDA Driver API for easy comparison.
intro_denoiser is a port from OptiX Introduction sample #10 to OptiX 7.
That example is the same as intro_driver with additional code demonstrating the built-in denoiser functionality with HDR denoising on beauty and optional albedo and normal buffers, all in float4
and half4
format (compile time options in config.h
).
intro_motion_blur demonstrates how to implement motion blur with linear matrix transforms, scale-rotate-translate (SRT) motion transforms, and optional camera motion blur in an animation timeline where frame number, frames per seconds, object velocity and angular velocity of the rotating object can be changed interactively.
It's also based on intro_driver which makes it easy to see the code differences adding the transform and camera motion blur.
intro_motion_blur will only be built when the OptiX SDK 7.2.0 or newer is found, because that version removed the OptixBuildInputInstanceArray
aabbs
and numAabbs
fields which makes adding motion blur a lot simpler.
All four intro examples implement the exact same rendering with their scene data generated at runtime and make use of a single device (ordinal 0
) only.
(If you have multiple NVIDIA devices installed you can switch between them, by using the CUDA_VISIBLE_DEVICES
environment variable.)
rtigo3 is meant as a testbed for multi-GPU rendering distribution and OpenGL interoperability. There are different multi-GPU strategies implemented (single GPU, dual GPU peer-to-peer, multi-GPU pinned memory, multi-GPU local distribution and compositing). Then there are three different OpenGL interop modes (none, render to pixel buffer object, copy to mapped texture array).
The implementation is using the CUDA Driver API on purpose because that allows more fine grained control over CUDA contexts and devices and alleviates the need to ship a CUDA runtime library when not using the static version.
This example contains the same runtime generated geometry as the introduction examples, but also implements a simple file loader using ASSIMP for triangle mesh data. The application operation and scene setup is controlled by two simple text files which also allows generating any scene setup complexity for tests. It's not rendering infinitely as the introduction examples but uses a selectable number of camera samples, as well as render resolutions independent of the windows client area.
nvlink_shared demonstrates peer-to-peer sharing of texture data and/or geometry acceleration structures among GPU devices in an NVLINK island. Peer-to-peer device resource sharing can effectively double the scene size loaded onto a dual-GPU NVLINK setup. Texture sharing comes at a moderate performance cost while geometry acceleration structure and vertex attribute sharing can be considerably slower and depends on the use case, but it's reasonably fast given the bandwidth difference between NVLINK and VRAM transfers. Still a lot better than not being able to load a scene at all on a single board.
To determine the system's NVLINK topology it uses the NVIDIA Management Library NVML which is loaded dynamically. Headers for that library are included inside the CUDA Toolkits and the library ships with the display drivers. The implementation is prepared to fetch all NVML entry points, but currently only needs six functions for the required NVLINK queries and GPU device searches. Note that peer-to-peer access under Windows requires Windows 10 64-bit and SLI enabled inside the NVIDIA Display Control Panel. Under Linux it should work out of the box.
This example is derived from rtigo3 but uses only one rendering strategy ("local-copy") and while it also runs on single GPU systems, the CUDA peer-to-peer sharing functionality will obviously only run on multi-GPU NVLINK systems. The Raytracer class got more smarts over the Device class because the resource distribution decisions need to happen above the devices. The scene description format has been slightly changed to allow different albedo and/or cutout opacity textures per material reference. Still, it's a slightly newer application architecture compared to rtigo3 when you're planning to derive own applications from these examples.
rtigo9 is similar to nvlink_shared but optimized for single-GPU as well to not do the compositing step unless multiple GPUs are used. The main difference is that it shows how to implement more light types. It's supporting the following light types:
- Constant environment light: Uniformly sampled, constant HDR color built from emission color and multiplier.
- Spherical environment map light: Importance sampled area light. Now supporting arbitrary orientations of the environment via a rotation matrix. Also supporting low dynamic range textures scaled by the emission multiplier (as in all light types).
- Point light: Singular light type with or without colored omnidirectional projection texture.
- Spot light: Singular light type with cone spread angle in range [0, 180] degrees (hemisphere) and falloff (exponent on a cosine), with or without colored projection texture limited to the sphere cap described by the cone angle.
- IES light: Singular light type (point light) with omnidirectional emission distribution defined by an IES light profile file which gets converted to a float texture on load. With or without additional colored projection texture.
- Rectangular light: Area light with constant color or importance sampled emission texture. Also supports a cutout opacity texture.
- Arbitrary triangle mesh light: Uniformly sampled light geometry, with or without emission texture. Also supports a cutout opacity texture.
To be able to define scenes with these different light types, this example's scene description file format has been enhanced.
The camera settings as well as the tone mapper settings defined inside the system description file now can be overridden inside the scene description.
The previous hardcoded light definitions inside the system description file have been removed and the scene description has been changed to allow light material definitions and creation of specific light types with these emissive materials, resp. assigning them to arbitrary triangle meshes.
Please read the system_rtigo9_demo.txt
and scene_rtigo9_demo.txt
files which explain the creation of all supported light types inside a single scene.
Also, the previous compile time switch inside the config.h
file to enable or disable direct lighting ("next event estimation") has been converted to a runtime switch which can be toggled inside the GUI. Note that all singular light types do not work without direct lighting enabled because they do not exist as geometry inside the scene and cannot be hit implicitly. (The probability for that is zero. Such lights do not exist in the physical world.)
Additionally to CUDA peer-to-peer data sharing via NVLINK, the rtigo9 example also allows that via PCI-E, but this is absolutely not recommended for geometry for performance reasons. Please read the explanation of the peerToPeer
option inside the system description.
Light types shown in the image above: The grey background is from a constant environment light. Then from left to right: point light, point light with projection texture, spot light with cone angle and falloff, spot light with projection texture, IES light, IES light with projection texture, rectangle area light, rectangle area light with importance sampled emission texture, arbitrary mesh light (cow), arbitrary mesh light with emission texture.
rtigo9_omm is exactly the same as rtigo9, just using the new Opacity Micromap (OMM) feature added in OptiX SDK 7.6.0. It uses the OptiX Toolkit CUDA based OMM Baking Tool to generate OMMs from the RGBA cutout textures. The OptiX Toolkit also requires OptiX SDK 7.6.0 at this time (2023-03-30).
With OMMs, the sharing of geometry acceleration structures (GAS) among different materials is restricted for materials with cutout opacity because the OMM is part of the GAS.
The cutout opacity value calculation has been changed from using the RGB intensity to the alpha channel because that is what the OMM Baking tool defaults to when using RGBA textures.
Another difference is that the shadow/visibility ray implementation can use a faster algorithm with OPTIX_RAY_FLAG_TERMINATE_ON_FIRST_HIT
because fully transparent and fully opaque microtriangles of geometry with cutout opacity textures do not call into the anyhit program anymore. That also means there is no anyhit shadow program for geometry without cutout opacity required anymore.
rtigo10 is meant to show how to architect a renderer for maximum performance with the fastest possible shadow/visibility ray type implementation and the smallest possible shader binding table layout.
It's based on rtigo9 and supports the same system and scene description file format but removed support for cutout opacity and surface materials on emissive area light geometry (arbitrary mesh lights.) The renderer architecture implements all materials as individual closesthit programs instead of a single closesthit program and direct callable programs per material as in all previous examples above. Lens shaders and the explicit light sampling is still done with direct callable programs per light type for optimal code size.
To reduce the shader binding table size, where the previous examples used a hit record entry per instance with additional data for the geometry vertex attribute data and index data defining the mesh topology plus material and light IDs, the shader binding table in rtigo10 holds only one hit record per material shader which is selected via the instance sbtOffset
field. All other data is indexed with via the user defined instance ID field.
On top of that, by not supporting cutout opacity there is no need for anyhit programs in the whole pipeline. The shadow/visibility test ray type is implemented with just a miss shader, which also means there is no need to store hit records for the shadow ray type inside the shader binding table at all.
rtigo12 is based on rtigo10 but changed the integrator to handle the throughput, pdf, and lights like the MDL_renderer.
The GGX-Smith BXDF implementation has been replaced with excerpts from the MDL SDK libbsdf to support direct lighting of glossy transparent materials as well. That means singular light types will now show proper reflections on glossy transparent objects and even caustics (when the roughness is not too smooth) because hitting backfaces will be directly lit from lights on the transmission side which adds radiance. While changing that, support for Specular and GGX-Smith BTDF materials has been added.
Also homogeneous volume scattering is implemented in this example via a random walk through volumes with scattering coefficients the same way as inside the MDL_renderer. (See scene_rtigo12_*.txt files inside the data folder for example scenes.)
Note that mesh and rect lights are now defined with radiant exitance instead of radiant intensity, so with the diffuse EDF these are 1/PI darker than in rtigo10 but match the MDL_renderer.
MDL_renderer is based on rtigo9 but replaced the previously few simple hardcoded BSDFs with NVIDIA Material Definition Language (MDL) shaders.
If you're not familiar with the NVIDIA Material Definition Language, please find the MDL Introduction, Handbook, and Language Specifications on the NVIDIA Ray Tracing Documentation site.
The example is based on functionality shown inside the MDL SDK examples optix7
and df_cuda
.
The renderer architecture stayed similar, just that all material-related direct callable programs are now generated by the MDL SDK at runtime.
Meaning this renderer requires the MDL SDK to compile. There is either the open-source MDL SDK, used while developing this example, or the binary MDL SDK release.
The device code details changed quite a bit though because all shading data structures needed to match to what the MDL-generated code expects and it is actually more elegant in some areas than the previous examples, especially for the path throughput and pdf handling.
The scene description syntax has been adjusted to allow material references selecting an exported MDL material from a given MDL file. The definition of the hardcoded lights has been changed from taking a material reference to using the scene description emission parameters directly. Arbitrary mesh lights are generated automatically for all geometry instances which have an emissive MDL material assigned.
The system description options added a searchPath
option which allows to add arbitrary many paths where MDL files and their resources should be searched for.
The system and user path for the MDL vMaterials set via the environment variables MDL_SYSTEM_PATH
and MDL_USER_PATH
set by the MDL vMaterials installer are automatically added by the application.
Peer-to-peer sharing of MDL texture array resources, measured BSDFs and their CDFs, IES light profiles and their CDFs is supported. The system description option peerToPeer
has two new bits (4 and 5) controlling sharing of the MBSDF resp. light profile data among GPU devices in a CUDA peer-to-peer island. If the peerToPeer
value is not set, the default is to only share textures because that comes at almost no cost via NVLINK.
Please read the system_mdl_vMaterials.txt
and scene_mdl_vMaterials.txt
inside the data folder for more information on additional system and scene options.
The renderer implementation has the following limitations at this time:
- Volume absorption and scattering assumes homogeneous volume coefficients. There is simply no volume data primitive in the scene to sample heterogeneous coefficients from.
- Volume scattering emission intensity not implemented. Goes along with heterogeneous volume scattering support.
- Geometry displacement not implemented. To be revisited once Displacement Micro Meshes (DMM) are supported by OptiX.
- UV-tile and animation textures not implemented.
- rounded_corner_normal() not implemented. That cannot be done by the automatic code generation for the geometry.normal expression.
- Spot and light profile
global_distribution: true
not supported by the MDL SDK code generation. Lights will be black then. The renderer supports own point lights with spot and IES distribution though.
Everything else inside the MDL specifications should just work!
The MDL_renderer has now been updated to also support cubic B-spline curve primitives and the MDL Hair BSDF.
Because that requires two texture coordinates to be fully featured, the NUM_TEXTURE_SPACES
define has been added to the config.h
to allow switching between one and two texture coordinates. If you do not need the hair BSDF, you can set NUM_TEXTURE_SPACES
to 1 for a little more performance.
The MDL hair BSDF supports a fully parameterized fiber surface accessible via the state::texture_coordinate(0)
providing (uFiber, vFiber, thickness) values, which allows implementing parameter changes along the whole fiber and even around it. The provided mdl/bsdf_hair_uv.mdl
material shows this by placing tiny arrows on the fibers pointing from root to tip.
Additionally the second texture coordinate state::texture_coordinate(1)
defines a fixed texture coordinate per fiber, which allows coloring of individual fibers depending on some texture value. The image below used a Perlin noise function to produce highlights in the hair, resp. a 2D texture to color the fibers of the fur.hair
model (included).
The renderer currently loads only *.hair
models which do not have texture coordinates. The example auto-generates a 2D coordinate with a cubemap projection from the root points' center coordinate. There are better ways to do this when actually growing hair from surfaces, not done in this example. Transparency and color values of *.hair files are ignored. The assigned MDL hair material defines these properties.
GLTF_renderer shows how to implement a simple and fast Physically Based Rendering (PBR) material model inside a progressive Monte Carlo global illumination renderer. It implements much of the glTF 2.0 core specification plus quite a number of glTF 2.0 extensions which make the material model a lot more interesting.
NEW: It's now a standalone solution because it shows how to use the native CMake LANGUAGES CUDA feature to build an application which uses native CUDA kernels compiled to binary code and called with the CUDA runtime chevron <<<>>>
operator, as well as OptiX device code translated to OptiX-IR or PTX modules, which is done via a CMake Object Library
.
To build it, a separate solution needs to be built using the GLTF_renderer/CMakeLists.txt
directly! It requires OptiX SDK 8.0.0 or OptiX SDK 7.7.0 to build. See more details in the Building chapter.
Please refer to the specific README.md inside the GLTF_renderer/doc
folder for an explanation of its features and limitations.
- Left Mouse Button + Drag = Orbit (around center of interest)
- Middle Mouse Button + Drag = Pan (The mouse ratio field in the GUI defines how many pixels is one unit.)
- Right Mouse Button + Drag = Dolly (nearest distance limited to center of interest)
- Mouse Wheel = Zoom (1 - 179 degrees field of view possible)
- SPACE = Toggle GUI display on/off
Additionally in all non-intro examples:
- S = If the example uses a system description file, this saves the current system description settings into a new file (e.g. to save camera positions)
- P = Saves the current tone mapped output buffer to a new PNG file. (Destination folder must exist! Check the
prefixScreenshot
option inside the system text files.) - H = Saves the current linear output buffer to a new HDR file.
In the following paragraphs, the *
in all OptiX*
expressions stands for the major and minor OptiX version as 70, 71, 72, 73, 74, 75, 76, 77, 80.
The application framework for all these examples uses GLFW for the window management, GLEW 2.1.0 for the OpenGL functions, DevIL 1.8.0 (optionally 1.7.8) for all image loading and saving, local ImGUI code for the simple GUI, and all non-intro examples use ASSIMP to load triangle mesh geometry. rtigo9_omm uses the OptiX Toolkit CUDA-based Opacity Micromap (OMM) Baking tool to generate OMMs from cutout opacity textures.
GLEW 2.1.0 is required for all examples not named with prefix intro for the UUID matching of devices between OpenGL and CUDA which requires a specific OpenGL extension not supported by GLEW 2.0.0. The intro examples compile with GLEW 2.0.0 though.
The top-level CMakeLists.txt
file will try to find all currently released OptiX SDK versions via the FindOptiX*.cmake
scripts inside the 3rdparty/CMake
folder.
These search OptiX SDK 7.0.0 to 8.0.0 locations by looking at the resp. OPTIX*_PATH
environment variables a developer can set to override the default SDK locations.
If those OPTIX*_PATH
environment variables are not set, the scripts try the default SDK installation folders. Since OptiX 7 and 8 are header-only APIs, only the include directory is required.
The FindOptiX*.cmake
scripts set the resp. OptiX*_FOUND
CMake variables which are later used to select which examples are built at all and with which OptiX SDK. (intro_motion_blur requires OptiX SDK 7.2.0 or higher, rtigo9_omm requires 7.6.0 or higher.)
The individual applications' CMakeLists.txt
files are setup to use the newest OptiX SDK found and automatically handle API differences via the OPTIX_VERSION
define.
When using OptiX SDK 7.5.0 or newer and CUDA Toolkit 11.7 or newer, the OptiX device code will automatically be compiled to the new binary OptiX Intermediate Representation (OptiX IR) instead of PTX code.
This can be changed inside the CMakeLists.txt files of the individual examples by commenting out the three lines enabling USE_OPTIX_IR
and setting nvcc target option --optixir
and the *.optixir
filename extension.
When using the OptiX SDK 8.0.0, the MDL_renderer example will use the Shader Execution Reordering (SER) API added in OptiX 8 which will improve the rendering performance on RTX boards with Ada GPUs.
The GLTF_renderer must be built as a standalone solution directly from the GLTF_renderer/CMakeLists.txt
because it uses the native CMake LANGUAGES CUDA feature to build an application which uses native CUDA kernels compiled to binary code and called with the CUDA runtime chevron <<<>>>
operator, as well as OptiX device code translated to OptiX-IR or PTX modules, which is done via a CMake Object Library
.
Also note that the GLTF_renderer OptiX device code modules are only copied into the GLTF_renderer_core
foder next to the current build target executable when the INSTALL target is built. That can be done automatically when enabling it inside the MSVS Build -> Configuration Manager dialog. It will then always copy only the changed modules on each build. (I have not found a better automatic method under the multi-target build system, where target file names are only provided as generator expressions.) Unfortunately that INSTALL build option needs to be re-enabled every time the CMakeLists.txt is changed.
Windows
Pre-requisites:
- NVIDIA GPU supported by OptiX 7 or 8. (Maxwell GPU or newer, RTX boards highly recommended.)
- Display drivers supporting OptiX 7 or 8. (Please refer to the individual OptiX Release Notes for the supported driver versions.)
- Visual Studio 2017, 2019 or 2022
- CUDA Toolkit 10.x, 11.x or 12.x (Please refer to the OptiX Release Notes for the supported combinations. CUDA 11.8 or higher recommended.)
- Any OptiX SDK 7 or 8 version (OptiX SDK 8.0.0 recommended. intro_motion_blur requires 7.2.0 or higher, rtigo9_omm requires 7.6.0 or higher.)
- OptiX Toolkit for the CUDA Opacity Micromap baking tool used in rtigo9_omm (requires OptiX SDK 7.6.0 or newer).
- Open-source MDL SDK 2023 (367100.2992) or binary MDL SDK supporting MDL 1.8, only required for the MDL_renderer example.
- CMake 3.17 or newer. (Tested with CMake 3.24.2. The OptiX Toolkit requires 3.23.)
3rdparty library setup:
- From the Windows Start Menu (Windows' search bar might not find it!), open the x64 Native Tools Command Prompt for VS2017 or x64 Native Tools Command Prompt for VS2019 or x64 Native Tools Command Prompt for VS2022
- Change directory to the folder containing the
3rdparty.cmd
. This command assumes that CMake is installed inC:\Program Files\cmake\bin\cmake.exe
. If you are using the CMake installed with Microsoft Visual Studio, please adjust3rdparty.cmd
to the proper executable location orcmake.exe
when it's inside the PATH environment variable, which is not the default when installing CMake versions from cmake.org. - Execute the command
3rdparty.cmd
. This will automatically download GLFW 3.3, GLEW 2.1.0, and ASSIMP archives from sourceforge.com or github.com (see3rdparty.cmake
) and unpack, compile and install them into the existing3rdparty
folder in a few minutes. - Note that the GLTF_renderer added github sub-modules of which the
fastgltf
repository is automatically built for Debug and Release targets but can only install one of the static libraries into the lib folder where theFindFastGLTF.cmake
is looking for it because the filenames are identical. The 3rdparty.cmake script will install the Release target! Before building Debug targets of the GLTF_renderer, copy thefastgltf.lib
from its Debug output folder (e.g.3rdparty\fastgltf\build\msvc-14.3\Debug
) to the3rdparty\fastgltf\lib
folder. - Close the x64 Native Tools Command Prompt after it finished.
DevIL:
- The Developer's Image Library DevIL needs to be downloaded manually.
- Go to the Download section there and click on the DevIL 1.8.0 SDK for Windows link to download the headers and pre-built libraries.
- If the file doesn't download automatically, click on the Problems Downloading? button and click the direct link at the top of the dialog box.
- Unzip the archive into the new folder
optix_apps/3rdparty/devil_1_8_0
so that this directly containsinclude
andlib
folders from the archive.
- Optionally the examples can be built with the DevIL 1.7.8 version which also contains support for EXR images.
- Follow this link to find various pre-built DevIL Windows SDK versions.
- Download the
DevIL-SDK-x64-1.7.8.zip
from its respective1.7.8
folder. - If the file doesn't download automatically, click on the Problems Downloading? button and click the direct link at the top of the dialog box.
- Unzip the archive into the new folder
optix_apps/3rdparty/devil_1_7_8
so that this directly contains theinclude
,unicode
and individual*.lib
and*.dll
files from the archive. - Note that the folder hierarchy in that older version is different than in the current 1.8.0 release that's why there is a
FindDevIL_1_8_0.cmake
and aFindDevIL_1_7_8.cmake
inside the3rdparty/CMake
folder. - To switch all example projects to the DevIL 1.7.8 version, replace
find_package(DevIL_1_8_0 REQUIRED)
in all CMakeLists.txt files againstfind_package(DevIL_1_7_8 REQUIRED)
OptiX Toolkit:
- Go to (https://github.com/NVIDIA/optix-toolkit)
- Clone the repository and update its sub-modules to get the OmmBaking repository included.
- Set the CMAKE_INSTALL_PREFIX to a local path where the OptiX Toolkit
bin
,include
andlib
folders should be installed. (The defaultC:\Program Files\OptiXToolkit
usually will not work because that is a protected folder under Windows.) TheFindOptiXToolkit.cmake
will find it automatically if the CMAKE_INSTALL_PREFIX is set to the3rdparty/optix-toolkit
path. - Configure and Generate the solution for your Visual Studio version and x64 platform
- Open the generated
OptiXToolkit.sln
and rebuild theRelease x64
target. - Then build the
INSTALL
target. - Check that the bin, include and lib folders are present inside the folder you selected via CMAKE_INSTALL_PREFIX.
MDL SDK:
- Go to (https://github.com/NVIDIA/MDL-SDK)
- Clone the repository and follow the build instructions in there to build the solution with CMake. (None of the examples are required to be able to build the MDL_render project.)
- Build the release x64 target.
- Build the INSTALL target.
- Set the environment variable MDL_SDK_PATH to the folder into which you cloned the MDL SDK repository. (The MDL_renderer project only needs the MDL SDK
include
folder location. All libraries are loaded dynamically.3rdparty/FindMDL_SDK.cmake
will find it and the MDL_renderer project will be added to the solution.) - For the MDL_renderer example execution only the
libmdl_sdk.dll
,nv_openimageio.dll
, anddds.dll
libraries from the MDL SDKinstall/bin
folder are required. Copy these next to the MDL_renderer executable. - (Optionally the MDL SDK can also build an
nv_freeimage.dll
when setting the MDL_BUILD_FREEIMAGE_PLUGIN CMake variable. Thenv_freeimage.dll
also requires theFreeImage.dll
which needs to come from the FreeImage installation you picked when building the MDL SDK libraries. To load that plugin instead of thenv_openimageio.dll
, change the MDL_renderer config.h define USE_OPENIMAGEIO_PLUGIN to 0.)
Generate the solution:
- If you didn't install the OptiX SDK 7 or 8 into its default directory, set the resp. environment variable
OPTIX*_PATH
to your local installation folder (or adjust theFindOptiX*.cmake
scripts). - If you didn't install the OptiX Toolkit into
3rdparty/optix-toolkit
, create and set the environment variableOPTIX_TOOLKIT_PATH=<path_to_optix_toolkit_installation>
(or adjustFindOptiXToolkit.cmake
script). - From the Start menu Open CMake (cmake-gui).
- Select the
optix_apps
folder in the Where is the source code field. - Select a new build folder inside the Where to build the binaries.
- Click Configure. (On the very first run that will prompt to create the build folder. Click OK.)
- Select the Visual Studio version which matches the one you used to build the 3rdparty libraries. You must select the "x64" version! (Note that newer CMake GUI versions have that in a separate listbox named "Optional platform for generator".)
- Click Finish. (That will list all examples'
PROJECT_NAME
and the resp. include directories and libraries used inside the CMake GUI output window the first time afind_package()
is called. Control that this found all the libraries in the 3rdparty folder and the desired OptiX 7 or 8 include directory. If multiple OptiX SDKs are installed, the highest version is used.) - Click Generate.
Building the examples:
- Open Visual Studio 2017, 2019 resp. 2022 (matching the version with which you built the 3rd party libraries and generated the solution) and load the solution from your build folder.
- Select the Debug or Release x64 target and pick Menu -> Build -> Rebuild Solution. That builds all projects in the solution in parallel.
Adding the libraries and data (Yes, this could be done automatically but this is required only once.):
-
Copy the x64 library DLLs:
cudart64_<toolkit_version>.dll
from the CUDA installation bin folder, and from the respective 3rdparty folders:glew32.dll
,DevIL.dll
,ILU.dll
,ILUT.dll
,assimp-vc<compiler_version>-mt.dll
andCuOmmBaking.dll
from the OptiX Toolkit into the build target folder with the executables (bin/Release or bin/Debug). (E.g.cudart64_101.dll
from CUDA Toolkit 10.1 or cudart64_110.dll from the matching(!) CUDA Toolkit 11.x or 12.x version andassimp-vc143-mt.dll
from the3rdparty/assimp
folder when building with MSVS 2022.) -
For the MDL_renderer, copy the
libmdl_sdk.dll
,nv_openimageio.dll
anddds.dll
libraries from the MDL SDKinstall/bin
folder. -
(Optionally the MDL SDK can also build an
nv_freeimage.dll
when setting the MDL_BUILD_FREEIMAGE_PLUGIN CMake variable. Thenv_freeimage.dll
also requires theFreeImage.dll
which needs to come from the FreeImage installation you picked when building the MDL SDK libraries. To load that plugin instead of thenv_openimageio.dll
, change the MDL_renderer config.h define USE_OPENIMAGEIO_PLUGIN to 0.) -
IMPORTANT: Copy all files from the
data
folder into the build folder with the executables (bin/Release
orbin/Debug
). The executables search for their resources relative to their working directory.
Linux
Pre-requisites:
- NVIDIA GPU supported by OptiX 7 or 8 (Maxwell GPU or newer, RTX boards highly recommended.)
- Display drivers supporting OptiX 7 or 8. (Please refer to the individual OptiX Release Notes for the supported driver versions.)
- GCC supported by CUDA 10.x or CUDA 11.x Toolkit
- CUDA Toolkit 10.x, 11.x or 12.x. (Please refer to the OptiX Release Notes for the supported combinations. CUDA 11.8 or higher recommended.)
- Any OptiX SDK 7 or 8 version (OptiX SDK 8.0.0 recommended. intro_motion_blur requires 7.2.0 or higher, rtigo9_omm requires 7.6.0 or higher.)
- CMake 3.17 or newer. (The OptiX Toolkit requires 3.23.)
- GLFW 3
- GLEW 2.1.0 (required to build all non-intro examples. In case the Linux package manager only supports GLEW 2.0.0, here is a link to the GLEW 2.1.0 sources.)
- DevIL 1.8.0 or 1.7.8. When using 1.7.8 replace
find_package(DevIL_1_8_0 REQUIRED)
againstfind_package(DevIL_1_7_8 REQUIRED)
- ASSIMP
- The GLTF_renderer example added three github repositories as sub-modules:
fastgltf
,glm
,stb
. Thefastgltf
repository needs to be built and installed matching the Debug or Release build target of the GLTF_renderer example. The glm and stb repositories are header only. Please refer to the3rdparty/CMake/FindFastGLTF.cmake
,FindGLM.cmake
andFindSTB.cmake
for how the build system finds these. - OptiX Toolkit (https://github.com/NVIDIA/optix-toolkit) for the CUDA Opacity Micromap baking tool used in rtigo9_omm (requires OptiX SDK 7.6.0). Clone the repository and update its submodules to get the OmmBaking repository included. Set the CMAKE_INSTALL_PREFIX to a path where the bin, include and lib folders of the OptiX Toolkit should be installed. That is the folder specified via the OPTIX_TOOLKIT_PATH environment variable on the CMake command line below when building these examples. Configure and Generate the solution and rebuild the release target. Then build the INSTALL target. Check that the bin, include and lib folders are present inside the folder you selected via CMAKE_INSTALL_PREFIX.
- Open-source MDL SDK 2023 (367100.2992) or binary MDL SDK supporting MDL 1.8 only required for the MDL_renderer example.
Build the Examples:
- Open a shell and change directory into the local
optix_apps
source code repository: - Issue the commands:
mkdir build
cd build
OPTIX80_PATH=<path_to_optix_8.0.0> OPTIX_TOOLKIT_PATH=<path_to_optix_toolkit> MDL_SDK_PATH=<path_to_MDL_SDK> cmake ..
- Similar for all other OptiX 7.x.0 SDKs by changing the version number accordingly. Some examples won't be built when using older OptiX SDK versions.
make
- IMPORTANT: Copy all files from the
data
folder into thebin
folder with the executables. The executables search for their resources relative to their working directory.
Instead of setting the temporary OPTIX80_PATH environment variable, you can also adjust the line set(OPTIX80_PATH "~/NVIDIA-OptiX-SDK-8.0.0-linux64")
inside the 3rdparty/CMake/FindOptiX80.cmake
script to your local OptiX SDK 8.0.0 installation. Similar for the OptiX 7.x.0 versions.
IMPORTANT: When running the examples from inside the debugger, make sure the working directory points to the folder with the executable because resources are searched relative to that. In Visual Studio that is the same as $(TargetDir)
. The default is $(ProjectDir)
which will not work!
Open a command prompt and change directory to the folder with the executables (same under Linux, just without the .exe suffix.)
For the intro-runtime examples, issue the commands:
intro_runtime.exe
intro_runtime.exe --miss 0 --light
intro_runtime.exe --miss 2 --env NV_Default_HDR_3000x1500.hdr
Use the same command line options for intro_driver, intro_denoiser and intro_motion_blur.
For rtigo3, issue the commands (similar for the other scene description files):
rtigo3.exe -s system_rtigo3_cornell_box.txt -d scene_rtigo3_cornell_box.txt
rtigo3.exe -s system_rtigo3_single_gpu.txt -d scene_rtigo3_geometry.txt
rtigo3.exe -s system_rtigo3_single_gpu_interop.txt -d scene_rtigo3_instances.txt
The following scene description uses the Buggy.gltf model from Khronos which is not contained inside this source code repository.
The link is also listed inside the scene_rtigo3_models.txt
file.
rtigo3.exe -s system_rtigo3_single_gpu_interop.txt -d scene_rtigo3_models.txt
If you run a multi-GPU system, read the system_rtigo3_dual_gpu_local.txt
for the modes of operation and interop settings.
rtigo3.exe -s system_rtigo3_dual_gpu_local.txt -d scene_rtigo3_geometry.txt
The nvlink_shared example is meant for multi-GPU systems with NVLINK bridge. It is working on single-GPU setups as well though. I have prepared a geometry-heavy scene with 125 spheres of more than 1 million triangles each. That scene requires about 10 GB of VRAM on a single board.
nvlink_shared.exe -s system_nvlink_shared.txt -d scene_nvlink_spheres_5_5_5.txt
The rtigo9 and rtigo10 examples use an enhanced scene description where camera and tone mapper values can be overridden and materials for surfaces and lights and all light types themselves can be defined per scene now. For that the material definition has changed slightly to support surface and emission distribution functions and some more parameters. Read the provided scene_rtigo9_demo.txt
file for how to define all supported light types.
rtigo9.exe -s system_rtigo9_demo.txt -d scene_rtigo9_demo.txt
That scene_rtigo9_demo.txt
is not using cutout opacity or surface materials on arbitrary mesh lights, which means using it with rtigo10 will result in the same image, it will just run considerably faster.
rtigo10.exe -s system_rtigo9_demo.txt -d scene_rtigo9_demo.txt
The rtigo9_omm example uses Opacity Micromaps (OMM) which are built using the OptiX Toolkit CUDA OMM Baking tool.
The following command loads a generated OBJ file with 15,000 unit quads randomly placed and oriented inside a sphere with radius 20 units. (Generator code is in createQuads()
). The material assigned to the quads is texture mapped with a leaf texture for albedo and cutout opacity. The same command line can be used with rtigo9 to see the performance difference esp. on Ada generation GPUs which accelerate OMMs in hardware. (Try higher rendering resolutions than the default 1024x1024.)
rtigo9_omm.exe -s system_rtigo9_leaf.txt -d scene_rtigo9_leaf.txt
The rtigo12 example uses a slightly enhanced scene description format than rtigo9 and rtigo10 in that it added material parameters for the volume scattering color, scale and bias. Above command lines for rtigo10 work as well, though mesh and rectangle lights will be 1/PI darker due to a change from radiant intensity to radiant exitance definition with diffuse EDFs. The following scene files demonstrate all BXDF implementations and the volume scattering parameters and shows that volumetric shadows just work when placing lights and objects into surrounding objects with volume scattering.
rtigo12.exe -s system_rtigo12_demo.txt -d scene_rtigo12_demo.txt
rtigo12.exe -s system_rtigo12_scattering_bias.txt -d scene_rtigo12_scattering_bias.txt
rtigo12.exe -s system_rtigo12_volume_scattering.txt -d scene_rtigo12_volume_scattering.txt
The MDL_renderer example uses the NVIDIA Material definition language for the shader generation.
The following scene only uses the *.mdl files and resources from the data/mdl
folder you copied next to the executable after building the examples.
These show most of the fundamental MDL BSDFs, EDFs, VDFs, layers, mixers, modifiers, thin-walled geometry, textures, cutout opacity, base helper functions, etc.
MDL_renderer.exe -s system_mdl_demo.txt -d scene_mdl_demo.txt
For a lot more complex materials (this scene requires about 5.4 GB of VRAM), the following command line will work if you have all(!) the NVIDIA MDL vMaterials 1.7, 2.0, 2.1, 2.2, 2.2.1 and 2.3 installed on the system. The application should then automatically find the referenced materials via the two environment variables MDL_SYSTEM_PATH
and MDL_USER_PATH
set by the vMaterials installation script. If a material exists as reference but couldn't be compiled because it isn't found or had errors, the renderer will not put the geometry with that invalid shader into the render graph. Means without the vMaterials installed only the area light should work in that scene because that is using one of the *.mdl files from the data folder. The result should look similar to the MDL_renderer example screenshot above, where some parameter values had been tweaked.
MDL_renderer.exe -s system_mdl_vMaterials.txt -d scene_mdl_vMaterials.txt
For version 2.4 download the materials and run
MDL_renderer.exe -s system_mdl_vMaterials_2.4.txt -d scene_mdl_vMaterials_2.4.txt
For the curves rendering with MDL hair BSDF materials, issue the command line. That will display a sphere with cubic B-spline curves using a red hair material lit by an area light from above. Please read the scene_mdl_hair.txt
for other possible material and model configurations.
MDL_renderer.exe -s system_mdl_hair.txt -d scene_mdl_hair.txt
For the GLTF_renderer please read the specific README.md for all command line options.
NVIDIA is happy to review and consider pull requests for merging into the main tree of the optix_apps for bug fixes and features. Before providing a pull request to NVIDIA, please note the following:
- A pull request provided to this repo by a developer constitutes permission from the developer for NVIDIA to merge the provided changes or any NVIDIA modified version of these changes to the repo. NVIDIA may remove or change the code at any time and in any way deemed appropriate.
- Not all pull requests can be or will be accepted. NVIDIA will close pull requests that it does not intend to merge.
- The modified files and any new files must include the unmodified NVIDIA copyright header seen at the top of all shipping files.
Technical support is available on NVIDIA's Developer Forum, or you can create a git issue.