An example path tracer that runs on multiple ray tracing backends (Embree/Embree+SYCL/DXR/OptiX/Vulkan/Metal/OSPRay). Uses tinyobjloader to load OBJ files, tinygltf to load glTF files and, optionally, Ingo Wald's pbrt-parser to load PBRTv3 files. The San Miguel, Sponza and Rungholt models shown below are from Morgan McGuire's Computer Graphics Data Archive.
Binaries built for each platform with support for all rendering backends available on that platform
can be downloaded from the Releases or the latest Actions artifacts.
On Linux set the LD_LIBRARY_PATH
to include the directory where you extract the
application, on macOS do the same for DYLD_LIBRARY_PATH
. On macOS you may need to do some
tweaking/security allowances to get the application to run. Only x86_64 binaries are provided for macOS at the moment.
The camera is an arcball camera that moves around the camera's focal point.
- Zoom in/out using the mousewheel. (Two-finger scroll motion on MacBook Pro etc. trackpad.)
- Click and drag to rotate.
- Right-click and drag to pan. (Two-finger click and drag on MacBook Pro etc. trackpad.)
Keys while the application window is in focus:
- Print the current camera position, center point, up vector and field of view (FOV) to the terminal by pressing the
p
key. - Save image by pressing the
s
key.
-eye <x> <y> <z> Set the camera position
-center <x> <y> <z> Set the camera focus point
-up <x> <y> <z> Set the camera up vector
-fov <fovy> Specify the camera field of view (in degrees)
-camera <n> If the scene contains multiple cameras, specify which
should be used. Defaults to the first camera
-img <x> <y> Specify the window dimensions. Defaults to 1280x720
The currently implemented backends are: Embree, DXR, OptiX, Vulkan, and Metal. When running the program, you can pick which backend you want from those you compiled with on the command line. Running the program with no arguments will print help information.
./chameleonrt <backend> <mesh.obj/gltf/glb>
All five ray tracing backends use SDL2 for window management
and GLM for math.
If CMake doesn't find your SDL2 install you can point it to the root
of your SDL2 directory by passing -DSDL2_DIR=<path>
. GLM will be automatically
downloaded by CMake during the build process.
To track statistics about the number of rays traced per-second
run CMake with -DREPORT_RAY_STATS=ON
. Tracking these statistics can
impact performance slightly.
ChameleonRT only supports per-OBJ group/mesh materials, OBJ files using per-face materials can be reexported from Blender with the "Material Groups" option enabled.
To build with PBRT file support set the CMake option CHAMELEONRT_PBRT_SUPPORT=ON
and pass
-DpbrtParser_DIR=<path>
with <path>
pointing to the CMake export files for
your build of Ingo Wald's pbrt-parser.
Dependencies: Embree 4, TBB and ISPC.
To build the Embree backend run CMake with:
cmake .. -DENABLE_EMBREE=ON \
-Dembree_DIR=<path to embree-config.cmake> \
-DTBB_DIR=<path TBBConfig.cmake> \
-DISPC_DIR=<path to ispc>
You can then pass embree
to use the Embree backend. The TBBConfig.cmake
will
be under <tbb root>/cmake
, while embree-config.cmake
is in the root of the
Embree directory.
Dependencies: Embree 4, TBB and Intel's oneAPI toolkit and the nightly SYCL compiler. Currently (4/4/2023) the Embree4 + SYCL backend requires the 20230304 nightly build of the oneAPI SYCL compiler and the latest Intel Arc GPU drivers. I have tested with driver version 31.0.101.4255 on Windows, it seems that the Ubuntu drivers are on an older version with their last release showing as being in Oct 2022. The regular oneAPI Base Toolkit is also required to provide additional library dependencies, and the build must be run within the oneAPI tools command line (or with the build environment scripts source'd).
After opening the oneAPI command prompt you can start powershell within it, then to build the Embree4 + SYCL backend run CMake with:
cmake .. -G Ninja `
-DCMAKE_C_COMPILER=<path to dpcpp nightly>/bin/clang.exe `
-DCMAKE_CXX_COMPILER=<path to dpcpp nightly>/bin/clang++.exe `
-DENABLE_EMBREE_SYCL=ON `
-Dembree_DIR=<path to embree-config.cmake> `
-DTBB_DIR=<path TBBConfig.cmake>
cmake --build . --config relwithdebinfo
You can then pass embree_sycl
to use the Embree4 + SYCL backend. The TBBConfig.cmake
will
be under <tbb root>/cmake
, while embree-config.cmake
is in the root of the
Embree directory.
Note that building the Embree4 + SYCL backend is currently incompatible with OptiX since the compiler is not supported by CUDA. You can simply build the OptiX backend (or the Embree4 + SYCL) backend in a separate build directory to get builds of both.
Dependencies: OptiX 7.2, CUDA 11.
To build the OptiX backend run CMake with:
cmake .. -DENABLE_OPTIX=ON
You can then pass optix
to use the OptiX backend.
If CMake doesn't find your install of OptiX you can tell it where
it's installed with -DOptiX_INSTALL_DIR
.
If you're on Windows 10 1809 or higher, have the latest Windows 10 SDK installed and a DXR capable GPU you can also run the DirectX Ray Tracing backend.
To build the DXR backend run CMake with:
cmake .. -DENABLE_DXR=ON
You can then pass dxr
to use the DXR backend.
Dependencies: Vulkan (SDK 1.2.162 or higher)
To build the Vulkan backend run CMake with:
cmake .. -DENABLE_VULKAN=ON
You can then pass vulkan
to use the Vulkan backend.
If CMake doesn't find your install of Vulkan you can tell it where it's
installed with -DVULKAN_SDK
. This path should be to the specific version
of Vulkan, for example: -DVULKAN_SDK=<path>/VulkanSDK/<version>/
Dependencies: Metal and a macOS 11+ device that supports ray tracing.
To build the Metal backend run CMake with:
cmake .. -DENABLE_METAL=ON
You can then pass metal
to use the Metal backend.
Dependencies: OSPRay 2.0, TBB.
To build the OSPRay backend run CMake with:
cmake .. -DENABLE_OSPRAY=ON -Dospray_DIR=<path to osprayConfig.cmake>
You may also need to specify OSPRay's dependencies, ospcommon and OpenVKL, depending on how you got or built the OSPRay binaries. If you downloaded the OSPRay release binaries, you just need to specify that path.
You can then pass ospray
to use the OSPRay backend.
If you find ChameleonRT useful in your work, please cite it as:
@misc{chameleonrt,
author = {Will Usher},
year = {2019},
howpublished = {\url{https://github.com/Twinklebear/ChameleonRT}},
title = {{ChameleonRT}}
}