wgpu
is a cross-platform, safe, pure-rust graphics api. It runs natively on Vulkan, Metal, D3D12, and OpenGL; and on top of WebGL2 and WebGPU on wasm.
The api is based on the WebGPU standard. It serves as the core of the WebGPU integration in Firefox and Deno.
The repository hosts the following libraries:
- - User facing Rust API.
- - Internal safe implementation.
- - Internal unsafe GPU API abstraction layer.
- - Rust types shared between all crates.
- - Stand-alone shader translation library.
- - Collection of thin abstractions over d3d12.
- - WebGPU implementation for the Deno JavaScript/TypeScript runtime
The following binaries:
- - Tool for translating shaders between different languages using naga.
- - Tool for getting information on GPUs in the system.
cts_runner
- WebGPU Conformance Test Suite runner usingdeno_webgpu
.player
- standalone application for replaying the API traces.
For an overview of all the components in the gfx-rs ecosystem, see the big picture.
Rust examples can be found at wgpu/examples. You can run the examples on native with cargo run --bin wgpu-examples <example>
. See the list of examples.
To run the examples on WebGPU on wasm, run cargo xtask run-wasm --bin wgpu-example
. Then connect to http://localhost:8000
in your WebGPU enabled browser, and you can choose an example to run.
To run the examples on WebGL on wasm, run cargo xtask run-wasm --bin wgpu-example --features webgl
. Then connect to http://localhost:8000
in your WebGL enabled browser, and you can choose an example to run.
If you are looking for a wgpu tutorial, look at the following:
To use wgpu in C/C++, you need wgpu-native.
If you are looking for a wgpu C++ tutorial, look at the following:
If you want to use wgpu in other languages, there are many bindings to wgpu-native from languages such as Python, D, Julia, Kotlin, and more. See the list.
We have the Matrix space with a few different rooms that form the wgpu community:
- - discussion of the wgpu's development.
- - discussion of the naga's development.
- - discussion of using the library and the surrounding ecosystem.
- - discussion of everything else.
We have a wiki that serves as a knowledge base.
API | Windows | Linux/Android | macOS/iOS | Web (wasm) |
---|---|---|---|---|
Vulkan | β | β | π | |
Metal | β | |||
DX12 | β | |||
DX11 | π οΈ | |||
OpenGL | π (GL 3.3+) | π (GL ES 3.0+) | π | π (WebGL2) |
WebGPU | β |
β
= First Class Support
π = Downlevel/Best Effort Support
π = Requires the ANGLE translation layer (GL ES 3.0 only)
π = Requires the MoltenVK translation layer
π οΈ = Unsupported, though open to contributions
wgpu supports shaders in WGSL, SPIR-V, and GLSL. Both HLSL and GLSL have compilers to target SPIR-V. All of these shader languages can be used with any backend, we will handle all of the conversion. Additionally, support for these shader inputs is not going away.
While WebGPU does not support any shading language other than WGSL, we will automatically convert your non-WGSL shaders if you're running on WebGPU.
WGSL is always supported by default, but GLSL and SPIR-V need features enabled to compile in support.
Note that the WGSL specification is still under development,
so the draft specification does not exactly describe what wgpu
supports.
See below for details.
To enable SPIR-V shaders, enable the spirv
feature of wgpu.
To enable GLSL shaders, enable the glsl
feature of wgpu.
Angle is a translation layer from GLES to other backends, developed by Google. We support running our GLES3 backend over it in order to reach platforms DX11 support, which aren't accessible otherwise. In order to run with Angle, "angle" feature has to be enabled, and Angle libraries placed in a location visible to the application. These binaries can be downloaded from gfbuild-angle artifacts, manual compilation may be required on Macs with Apple silicon.
On Windows, you generally need to copy them into the working directory, in the same directory as the executable, or somewhere in your path.
On Linux, you can point to them using LD_LIBRARY_PATH
environment.
Due to complex dependants, we have two MSRV policies:
d3d12
,naga
,wgpu-core
,wgpu-hal
, andwgpu-types
's MSRV is 1.65.- The rest of the workspace has the MSRV of 1.70.
It is enforced on CI (in "/.github/workflows/ci.yml") with CORE_MSRV
and REPO_MSRV
variable.
This version can only be upgraded in breaking releases, though we release a breaking version every 3 months.
The naga
, wgpu-core
, wgpu-hal
, and wgpu-types
crates should never
require an MSRV ahead of Firefox's MSRV for nightly builds, as
determined by the value of MINIMUM_RUST_VERSION
in
python/mozboot/mozboot/util.py
.
All testing and example infrastructure shares the same set of environment variables that determine which Backend/GPU it will run on.
WGPU_ADAPTER_NAME
with a substring of the name of the adapter you want to use (ex.1080
will matchNVIDIA GeForce 1080ti
).WGPU_BACKEND
with a comma separated list of the backends you want to use (vulkan
,metal
,dx12
,dx11
, orgl
).WGPU_POWER_PREF
with the power preference to choose when a specific adapter name isn't specified (high
,low
ornone
)WGPU_DX12_COMPILER
with the DX12 shader compiler you wish to use (dxc
orfxc
, note thatdxc
requiresdxil.dll
anddxcompiler.dll
to be in the working directory otherwise it will fall back tofxc
)WGPU_GLES_MINOR_VERSION
with the minor OpenGL ES 3 version number to request (0
,1
,2
orautomatic
).WGPU_ALLOW_NONCOMPLIANT_ADAPTER
with a boolean whether non-compliant drivers are enumerated (0
for false,1
for true).
When running the CTS, use the variables DENO_WEBGPU_ADAPTER_NAME
, DENO_WEBGPU_BACKEND
, DENO_WEBGPU_POWER_PREFERENCE
.
We have multiple methods of testing, each of which tests different qualities about wgpu. We automatically run our tests on CI. The current state of CI testing:
Platform/Backend | Tests | Notes |
---|---|---|
Windows/DX12 | βοΈ | using WARP |
Windows/OpenGL | βοΈ | using llvmpipe |
MacOS/Metal | βοΈ | using hardware runner |
Linux/Vulkan | βοΈ | using lavapipe |
Linux/OpenGL ES | βοΈ | using llvmpipe |
Chrome/WebGL | βοΈ | using swiftshader |
Chrome/WebGPU | β | not set up |
We use a tool called cargo nextest
to run our tests.
To install it, run cargo install cargo-nextest
.
To run the test suite:
cargo xtask test
To run the test suite on WebGL (currently incomplete):
cd wgpu
wasm-pack test --headless --chrome --features webgl --workspace
This will automatically run the tests using a packaged browser. Remove --headless
to run the tests with whatever browser you wish at http://localhost:8000
.
If you are a user and want a way to help contribute to wgpu, we always need more help writing test cases.
WebGPU includes a Conformance Test Suite to validate that implementations are working correctly. We can run this CTS against wgpu.
To run the CTS, first you need to check it out:
git clone https://github.com/gpuweb/cts.git
cd cts
# works in bash and powershell
git checkout $(cat ../cts_runner/revision.txt)
To run a given set of tests:
# Must be inside the cts folder we just checked out, else this will fail
cargo run --manifest-path ../Cargo.toml --bin cts_runner -- ./tools/run_deno --verbose "<test string>"
To find the full list of tests, go to the online cts viewer.
The list of currently enabled CTS tests can be found here.
The wgpu
crate is meant to be an idiomatic Rust translation of the WebGPU API.
That specification, along with its shading language, WGSL,
are both still in the "Working Draft" phase,
and while the general outlines are stable,
details change frequently.
Until the specification is stabilized, the wgpu
crate and the version of WGSL it implements
will likely differ from what is specified,
as the implementation catches up.
Exactly which WGSL features wgpu
supports depends on how you are using it:
-
When running as native code,
wgpu
uses the Naga crate to translate WGSL code into the shading language of your platform's native GPU API. Naga has a milestone for catching up to the WGSL specification, but in general there is no up-to-date summary of the differences between Naga and the WGSL spec. -
When running in a web browser (by compilation to WebAssembly) without the
"webgl"
feature enabled,wgpu
relies on the browser's own WebGPU implementation. WGSL shaders are simply passed through to the browser, so that determines which WGSL features you can use. -
When running in a web browser with
wgpu
's"webgl"
feature enabled,wgpu
uses Naga to translate WGSL programs into GLSL. This uses the same version of Naga as if you were runningwgpu
as native code.
wgpu uses the coordinate systems of D3D and Metal:
Render | Texture |
---|---|