librashader

Mega Bezel SMOOTH-ADV on DirectX 11

librashader (/ˈli:brəʃeɪdɚ/) is a preprocessor, compiler, and runtime for RetroArch 'slang' shaders, rewritten in pure Rust.

Supported Render APIs

librashader supports OpenGL 3, OpenGL 4.6, Vulkan, Direct3D 11, and Direct3D 12. Metal and WebGPU are not currently supported (but pull-requests are welcome). librashader does not support legacy render APIs such as older versions of OpenGL, or legacy versions of Direct3D.

API	Status	librashader feature
OpenGL 3.3+	✔	gl
OpenGL 4.6	✔	gl
Vulkan	✔	vk
Direct3D 11	✔	d3d11
Direct3D 12	✔	d3d12
Metal	❌
WebGPU	❌

✔ = Render API is supported — ❌ Render API is not supported

Usage

librashader provides both a Rust API under the librashader crate, and a C API. Both APIs are first-class and fully supported. The C API is geared more towards integration with existing projects. The Rust librashader crate exposes more of the internals if you wish to use parts of librashader piecemeal.

The librashader C API is best used by including librashader_ld.h in your project, which implements a loader that dynamically loads the librashader (librashader.so or librashader.dll) implementation in the search path.

C compatibility

The recommended way of integrating librashader is by the librashader_ld single header library which implements a dynamic loader for librashader.dll / librashader.so. See the versioning policy for details on how librashader handles C ABI and API stability with regards to library updates.

Linking statically against librashader.h is possible, but is not officially supported. You will need to ensure linkage parameters are correct in order to successfully link with librashader.lib or librashader.a. The corrosion CMake package is highly recommended.

Thread safety

In general, it is safe to create a filter chain instance from a different thread, but drawing frames requires external synchronization of the filter chain object.

Filter chains can be created from any thread, but requires external synchronization of the graphics device queue where applicable (in Direct3D 11, the immediate context is considered the graphics device queue), as loading LUTs requires command submission to the GPU. Initialization of GPU resources may be deferred asynchronously using the filter_chain_create_deferred functions, but the caller is responsible for submitting the recorded commands to the graphics device queue, and ensuring that the work is complete before drawing shader pass frames.

OpenGL has an additional restriction where creating the filter chain instance in a different thread is safe if and only if the thread local OpenGL context is initialized to the same context as the drawing thread. Support for deferral of GPU resource initialization is not available to OpenGL.

Quad vertices and rotations

All runtimes except OpenGL render with an identity matrix MVP and a VBO for with range [-1, 1]. The final pass uses a Quad VBO with range [0, 1] and the following projection matrix by default.

static DEFAULT_MVP: &[f32; 16] = &[
  2.0, 0.0, 0.0, 0.0,
  0.0, 2.0, 0.0, 0.0,
  0.0, 0.0, 0.0, 0.0,
  -1.0, -1.0, 0.0, 1.0,
];

As with RetroArch, a rotation on this MVP will be applied only on the final pass for these runtimes. This is the only way to pass orientation information to shaders.

The OpenGL runtime uses a VBO for range [0, 1] for all passes and the following MVP for all passes.

static GL_DEFAULT_MVP: &[f32; 16] = &[
    2.0, 0.0, 0.0, 0.0,
    0.0, 2.0, 0.0, 0.0,
    0.0, 0.0, 2.0, 0.0,
    -1.0, -1.0, 0.0, 1.0,
];

Building

librashader requires the following build time dependencies

• The Vulkan SDK
• CMake 3.8 or later

For DXIL support on Windows, the following is also needed

• Meson
• Python 3.6 or later

---

For Rust projects, simply add the crate tofil your Cargo.toml.

cargo add librashader

To build the C compatible dynamic library, run the build script.

cargo run -p librashader-build-script -- --profile optimized

This will output a librashader.dll or librashader.so in the target folder. Profile can be debug, release, or optimized for full LTO.

Writing a librashader Runtime

If you wish to contribute a runtime implementation not already available, see the librashader-runtime crate for helpers and shared logic used across all librashader runtime implementations. Using these helpers and traits will ensure that your runtime has consistent behaviour for uniform and texture semantics bindings with the existing librashader runtimes.

These types should not be exposed to the end user in the runtime's public API, and should be kept internal to the implementation of the runtime.

Examples

The following Rust examples show how to use each librashader runtime.

• Vulkan
• OpenGL
• Direct3D 11
• Direct3D 12

Some basic examples on using the C API are also provided in the librashader-capi-tests directory.

Compatibility

librashader implements the entire RetroArch shader pipeline and is highly compatible with existing shaders.

Please report an issue if you run into a shader that works in RetroArch, but not under librashader.

• Filter chains do not terminate at the backbuffer.
  • Unlike RetroArch, librashader does not have full knowledge of the entire rendering state and is designed to be pluggable at any point in your render pipeline. Instead, filter chains terminate at a caller-provided output surface and viewport. It is the caller's responsibility to blit the surface back to the backbuffer.
• Shaders are compiled in parallel where possible. This should noticeably decrease preset compile times. Parallel shader compilation is not available to OpenGL.
• HDR10 support is not part of any shader runtime and is not supported by librashader.
• For performance reasons, mipmaps are never generated for the input texture. In theory, this means that presets with mipmap_input0 = "true" will not get a mipmapped input. In practice, no known shader presets set mipmap_input0 = "true".
• The preset parser is a substantially stricter implementation that the one in RetroArch. Not all shader presets may be compatible. If you find this is the case, please file an issue so a workaround can be added.

Runtime specific differences

• OpenGL
  • Copying of in-flight framebuffer contents to history is done via glBlitFramebuffer rather than drawing a quad into an intermediate FBO.
  • Sampler objects are used rather than glTexParameter.
  • Sampler inputs and outputs are not renamed. This is useful for debugging shaders in RenderDoc.
  • UBO and Push Constant Buffer sizes are padded to 16-byte boundaries.
• OpenGL 4.6+
  • All caveats from the OpenGL 3.3+ section should be considered.
  • Should work on OpenGL 4.5 but this is not guaranteed. The OpenGL 4.6 runtime may eventually switch to using ARB_spirv_extensions for loading shaders, and this will not be marked as a breaking change.
  • The OpenGL 4.6 runtime uses Direct State Access to minimize changes to the OpenGL state. For GPUs released within the last 5 years, this may improve performance.
• Vulkan
  • The Vulkan runtime uses VK_KHR_dynamic_rendering by default. This extension must be enabled at device creation. Explicit render passes can be used by configuring filter chain options, but may have reduced performance compared to dynamic rendering.
  • Allocations within the runtime are done through gpu-allocator rather than handled manually.
• Direct3D 11
  • Framebuffer copies are done via ID3D11DeviceContext::CopySubresourceRegion rather than a CPU conversion + copy.
• Direct3D 12
  • The Direct3D 12 runtime uses render passes. This feature has been available since Windows 10 version 1809, which was released in late 2018.
  • For maximum compatibility with shaders, a shader compile pipeline based on spirv-to-dxil is used, with the SPIRV-Cross HLSL pipeline used as a fallback. This brings shader compatibility beyond what the RetroArch Direct3D 12 driver provides. The HLSL pipeline fallback may be removed in the future as spirv-to-dxil improves.
  • The Direct3D 12 runtime requires dxil.dll and dxcompiler.dll from the DirectX Shader Compiler.

Most, if not all shader presets should work fine on librashader. The runtime specific differences should not affect the output, and are more a heads-up for integrating librashader into your project.

Versioning

librashader typically follows Semantic Versioning with respect to the Rust API, where a minor version number bump indicates a 'breaking change' during 0.x.y, and a non-'breaking change' after 1.x.y. However, a "breaking change" that results in a version number bump does not correspond to a break in the C API after version 0.1.0.

The C API is instead versioned separately with two monotonically increasing version numbers exported to the librashader C headers

• LIBRASHADER_CURRENT_VERSION specifies the API version exported by the librashader implementation.
• LIBRASHADER_CURRENT_ABI specifies the ABI version exported by the librashader implementation.

An increase in LIBRASHADER_CURRENT_VERSION is guaranteed to be backwards compatible for the same LIBRASHADER_CURRENT_ABI. It somewhat corresponds to a "minor" version in semantic versioning terminology, except that it is always monotonically increasing. Backwards-compatible additions to the C API will result in an increase to LIBRASHADER_CURRENT_VERSION.

APIs introduced after a certain LIBRASHADER_CURRENT_VERSION may or may not be available to prior versions. In particular, new features enabled by filter or frame option structs require LIBRASHADER_CURRENT_VERSION be the greater than or equal to the version in which the option was introduced, or a default value will be passed, which may or may not enable the feature depending on backwards compatibility for that particular feature.

Any change to LIBRASHADER_CURRENT_ABI indicates a breaking change for the C ABI. For safety reasons, librashader_ld.h will check to ensure that LIBRASHADER_CURRENT_ABI matches that of the loaded librashader binary. If it does not match, librashader will not load. A value of 0 for LIBRASHADER_CURRENT_ABI indicates the "null" instance where every operation is a no-op, which occurs if no compatible librashader implementation could be found.

The above does not apply to releases of librashader prior to 0.1.0, which were allowed to break API and ABI compatibility in both the Rust and C API without an increase to either LIBRASHADER_CURRENT_VERSION or LIBRASHADER_CURRENT_ABI.

License

The core parts of librashader such as the preprocessor, the preset parser, the reflection library, and the runtimes, are all licensed under the Mozilla Public License version 2.0.

The librashader C API, i.e. its headers and definitions, not its implementation in librashader-capi, are more permissively licensed, and may allow you to use librashader in your permissively licensed or proprietary project.

To facilitate easier use of librashader in projects incompatible with MPL-2.0, librashader_ld implements a loader which thunks its calls to any librashader.so or librashader.dll library found in the load path. A non-MPL-2.0 compatible project may link against librashader_ld to use the librashader runtime, provided that librashader.so or librashader.dll are distributed under the restrictions of MPLv2.

Note that this means that if your project is unable to comply with the requirements of MPL-2.0, you can not distribute librashader.so or librashader.dll alongside your project. The end user must obtain the implementation of librashader themselves. For more information, see the MPL 2.0 FAQ.

At your discretion, you may instead choose to distribute librashader under the terms of GPLv3 rather than MPL-2.0.