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6 commits
Author | SHA1 | Message | Date | |
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Carter Anderson
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e5905379de |
Use new let-else syntax where possible (#6463)
# Objective Let-else syntax is now stable! ## Solution Use it where possible! |
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github-actions[bot]
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444150025d |
Bump Version after Release (#5576)
Bump version after release This PR has been auto-generated |
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github-actions[bot]
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856588ed7c |
Release 0.8.0 (#5490)
Preparing next release This PR has been auto-generated |
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Matthew Taylor
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50a44417ba |
Derive AsBindGroup Improvements: Better errors, more options, update examples (#5364)
# Objective - Provide better compile-time errors and diagnostics. - Add more options to allow more textures types and sampler types. - Update array_texture example to use upgraded AsBindGroup derive macro. ## Solution Split out the parsing of the inner struct/field attributes (the inside part of a `#[foo(...)]` attribute) for better clarity Parse the binding index for all inner attributes, as it is part of all attributes (`#[foo(0, ...)`), then allow each attribute implementer to parse the rest of the attribute metadata as needed. This should make it very trivial to extend/change if needed in the future. Replaced invocations of `panic!` with the `syn::Error` type, providing fine-grained errors that retains span information. This provides much nicer compile-time errors, and even better IDE errors. ![image](https://user-images.githubusercontent.com/7478134/179452241-6d85d440-4b67-44da-80a7-9d47e8c88b8a.png) Updated the array_texture example to demonstrate the new changes. ## New AsBindGroup attribute options ### `#[texture(u32, ...)]` Where `...` is an optional list of arguments. | Arguments | Values | Default | |-------------- |---------------------------------------------------------------- | ----------- | | dimension = "..." | `"1d"`, `"2d"`, `"2d_array"`, `"3d"`, `"cube"`, `"cube_array"` | `"2d"` | | sample_type = "..." | `"float"`, `"depth"`, `"s_int"` or `"u_int"` | `"float"` | | filterable = ... | `true`, `false` | `true` | | multisampled = ... | `true`, `false` | `false` | | visibility(...) | `all`, `none`, or a list-combination of `vertex`, `fragment`, `compute` | `vertex`, `fragment` | Example: `#[texture(0, dimension = "2d_array", visibility(vertex, fragment))]` ### `#[sampler(u32, ...)]` Where `...` is an optional list of arguments. | Arguments | Values | Default | |----------- |--------------------------------------------------- | ----------- | | sampler_type = "..." | `"filtering"`, `"non_filtering"`, `"comparison"`. | `"filtering"` | | visibility(...) | `all`, `none`, or a list-combination of `vertex`, `fragment`, `compute` | `vertex`, `fragment` | Example: `#[sampler(0, sampler_type = "filtering", visibility(vertex, fragment)]` ## Changelog - Added more options to `#[texture(...)]` and `#[sampler(...)]` attributes, supporting more kinds of materials. See above for details. - Upgraded IDE and compile-time error messages. - Updated array_texture example using the new options. |
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Carter Anderson
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747b0c69b0 |
Better Materials: AsBindGroup trait and derive, simpler Material trait (#5053)
# Objective This PR reworks Bevy's Material system, making the user experience of defining Materials _much_ nicer. Bevy's previous material system leaves a lot to be desired: * Materials require manually implementing the `RenderAsset` trait, which involves manually generating the bind group, handling gpu buffer data transfer, looking up image textures, etc. Even the simplest single-texture material involves writing ~80 unnecessary lines of code. This was never the long term plan. * There are two material traits, which is confusing, hard to document, and often redundant: `Material` and `SpecializedMaterial`. `Material` implicitly implements `SpecializedMaterial`, and `SpecializedMaterial` is used in most high level apis to support both use cases. Most users shouldn't need to think about specialization at all (I consider it a "power-user tool"), so the fact that `SpecializedMaterial` is front-and-center in our apis is a miss. * Implementing either material trait involves a lot of "type soup". The "prepared asset" parameter is particularly heinous: `&<Self as RenderAsset>::PreparedAsset`. Defining vertex and fragment shaders is also more verbose than it needs to be. ## Solution Say hello to the new `Material` system: ```rust #[derive(AsBindGroup, TypeUuid, Debug, Clone)] #[uuid = "f690fdae-d598-45ab-8225-97e2a3f056e0"] pub struct CoolMaterial { #[uniform(0)] color: Color, #[texture(1)] #[sampler(2)] color_texture: Handle<Image>, } impl Material for CoolMaterial { fn fragment_shader() -> ShaderRef { "cool_material.wgsl".into() } } ``` Thats it! This same material would have required [~80 lines of complicated "type heavy" code](https://github.com/bevyengine/bevy/blob/v0.7.0/examples/shader/shader_material.rs) in the old Material system. Now it is just 14 lines of simple, readable code. This is thanks to a new consolidated `Material` trait and the new `AsBindGroup` trait / derive. ### The new `Material` trait The old "split" `Material` and `SpecializedMaterial` traits have been removed in favor of a new consolidated `Material` trait. All of the functions on the trait are optional. The difficulty of implementing `Material` has been reduced by simplifying dataflow and removing type complexity: ```rust // Old impl Material for CustomMaterial { fn fragment_shader(asset_server: &AssetServer) -> Option<Handle<Shader>> { Some(asset_server.load("custom_material.wgsl")) } fn alpha_mode(render_asset: &<Self as RenderAsset>::PreparedAsset) -> AlphaMode { render_asset.alpha_mode } } // New impl Material for CustomMaterial { fn fragment_shader() -> ShaderRef { "custom_material.wgsl".into() } fn alpha_mode(&self) -> AlphaMode { self.alpha_mode } } ``` Specialization is still supported, but it is hidden by default under the `specialize()` function (more on this later). ### The `AsBindGroup` trait / derive The `Material` trait now requires the `AsBindGroup` derive. This can be implemented manually relatively easily, but deriving it will almost always be preferable. Field attributes like `uniform` and `texture` are used to define which fields should be bindings, what their binding type is, and what index they should be bound at: ```rust #[derive(AsBindGroup)] struct CoolMaterial { #[uniform(0)] color: Color, #[texture(1)] #[sampler(2)] color_texture: Handle<Image>, } ``` In WGSL shaders, the binding looks like this: ```wgsl struct CoolMaterial { color: vec4<f32>; }; [[group(1), binding(0)]] var<uniform> material: CoolMaterial; [[group(1), binding(1)]] var color_texture: texture_2d<f32>; [[group(1), binding(2)]] var color_sampler: sampler; ``` Note that the "group" index is determined by the usage context. It is not defined in `AsBindGroup`. Bevy material bind groups are bound to group 1. The following field-level attributes are supported: * `uniform(BINDING_INDEX)` * The field will be converted to a shader-compatible type using the `ShaderType` trait, written to a `Buffer`, and bound as a uniform. It can also be derived for custom structs. * `texture(BINDING_INDEX)` * This field's `Handle<Image>` will be used to look up the matching `Texture` gpu resource, which will be bound as a texture in shaders. The field will be assumed to implement `Into<Option<Handle<Image>>>`. In practice, most fields should be a `Handle<Image>` or `Option<Handle<Image>>`. If the value of an `Option<Handle<Image>>` is `None`, the new `FallbackImage` resource will be used instead. This attribute can be used in conjunction with a `sampler` binding attribute (with a different binding index). * `sampler(BINDING_INDEX)` * Behaves exactly like the `texture` attribute, but sets the Image's sampler binding instead of the texture. Note that fields without field-level binding attributes will be ignored. ```rust #[derive(AsBindGroup)] struct CoolMaterial { #[uniform(0)] color: Color, this_field_is_ignored: String, } ``` As mentioned above, `Option<Handle<Image>>` is also supported: ```rust #[derive(AsBindGroup)] struct CoolMaterial { #[uniform(0)] color: Color, #[texture(1)] #[sampler(2)] color_texture: Option<Handle<Image>>, } ``` This is useful if you want a texture to be optional. When the value is `None`, the `FallbackImage` will be used for the binding instead, which defaults to "pure white". Field uniforms with the same binding index will be combined into a single binding: ```rust #[derive(AsBindGroup)] struct CoolMaterial { #[uniform(0)] color: Color, #[uniform(0)] roughness: f32, } ``` In WGSL shaders, the binding would look like this: ```wgsl struct CoolMaterial { color: vec4<f32>; roughness: f32; }; [[group(1), binding(0)]] var<uniform> material: CoolMaterial; ``` Some less common scenarios will require "struct-level" attributes. These are the currently supported struct-level attributes: * `uniform(BINDING_INDEX, ConvertedShaderType)` * Similar to the field-level `uniform` attribute, but instead the entire `AsBindGroup` value is converted to `ConvertedShaderType`, which must implement `ShaderType`. This is useful if more complicated conversion logic is required. * `bind_group_data(DataType)` * The `AsBindGroup` type will be converted to some `DataType` using `Into<DataType>` and stored as `AsBindGroup::Data` as part of the `AsBindGroup::as_bind_group` call. This is useful if data needs to be stored alongside the generated bind group, such as a unique identifier for a material's bind group. The most common use case for this attribute is "shader pipeline specialization". The previous `CoolMaterial` example illustrating "combining multiple field-level uniform attributes with the same binding index" can also be equivalently represented with a single struct-level uniform attribute: ```rust #[derive(AsBindGroup)] #[uniform(0, CoolMaterialUniform)] struct CoolMaterial { color: Color, roughness: f32, } #[derive(ShaderType)] struct CoolMaterialUniform { color: Color, roughness: f32, } impl From<&CoolMaterial> for CoolMaterialUniform { fn from(material: &CoolMaterial) -> CoolMaterialUniform { CoolMaterialUniform { color: material.color, roughness: material.roughness, } } } ``` ### Material Specialization Material shader specialization is now _much_ simpler: ```rust #[derive(AsBindGroup, TypeUuid, Debug, Clone)] #[uuid = "f690fdae-d598-45ab-8225-97e2a3f056e0"] #[bind_group_data(CoolMaterialKey)] struct CoolMaterial { #[uniform(0)] color: Color, is_red: bool, } #[derive(Copy, Clone, Hash, Eq, PartialEq)] struct CoolMaterialKey { is_red: bool, } impl From<&CoolMaterial> for CoolMaterialKey { fn from(material: &CoolMaterial) -> CoolMaterialKey { CoolMaterialKey { is_red: material.is_red, } } } impl Material for CoolMaterial { fn fragment_shader() -> ShaderRef { "cool_material.wgsl".into() } fn specialize( pipeline: &MaterialPipeline<Self>, descriptor: &mut RenderPipelineDescriptor, layout: &MeshVertexBufferLayout, key: MaterialPipelineKey<Self>, ) -> Result<(), SpecializedMeshPipelineError> { if key.bind_group_data.is_red { let fragment = descriptor.fragment.as_mut().unwrap(); fragment.shader_defs.push("IS_RED".to_string()); } Ok(()) } } ``` Setting `bind_group_data` is not required for specialization (it defaults to `()`). Scenarios like "custom vertex attributes" also benefit from this system: ```rust impl Material for CustomMaterial { fn vertex_shader() -> ShaderRef { "custom_material.wgsl".into() } fn fragment_shader() -> ShaderRef { "custom_material.wgsl".into() } fn specialize( pipeline: &MaterialPipeline<Self>, descriptor: &mut RenderPipelineDescriptor, layout: &MeshVertexBufferLayout, key: MaterialPipelineKey<Self>, ) -> Result<(), SpecializedMeshPipelineError> { let vertex_layout = layout.get_layout(&[ Mesh::ATTRIBUTE_POSITION.at_shader_location(0), ATTRIBUTE_BLEND_COLOR.at_shader_location(1), ])?; descriptor.vertex.buffers = vec![vertex_layout]; Ok(()) } } ``` ### Ported `StandardMaterial` to the new `Material` system Bevy's built-in PBR material uses the new Material system (including the AsBindGroup derive): ```rust #[derive(AsBindGroup, Debug, Clone, TypeUuid)] #[uuid = "7494888b-c082-457b-aacf-517228cc0c22"] #[bind_group_data(StandardMaterialKey)] #[uniform(0, StandardMaterialUniform)] pub struct StandardMaterial { pub base_color: Color, #[texture(1)] #[sampler(2)] pub base_color_texture: Option<Handle<Image>>, /* other fields omitted for brevity */ ``` ### Ported Bevy examples to the new `Material` system The overall complexity of Bevy's "custom shader examples" has gone down significantly. Take a look at the diffs if you want a dopamine spike. Please note that while this PR has a net increase in "lines of code", most of those extra lines come from added documentation. There is a significant reduction in the overall complexity of the code (even accounting for the new derive logic). --- ## Changelog ### Added * `AsBindGroup` trait and derive, which make it much easier to transfer data to the gpu and generate bind groups for a given type. ### Changed * The old `Material` and `SpecializedMaterial` traits have been replaced by a consolidated (much simpler) `Material` trait. Materials no longer implement `RenderAsset`. * `StandardMaterial` was ported to the new material system. There are no user-facing api changes to the `StandardMaterial` struct api, but it now implements `AsBindGroup` and `Material` instead of `RenderAsset` and `SpecializedMaterial`. ## Migration Guide The Material system has been reworked to be much simpler. We've removed a lot of boilerplate with the new `AsBindGroup` derive and the `Material` trait is simpler as well! ### Bevy 0.7 (old) ```rust #[derive(Debug, Clone, TypeUuid)] #[uuid = "f690fdae-d598-45ab-8225-97e2a3f056e0"] pub struct CustomMaterial { color: Color, color_texture: Handle<Image>, } #[derive(Clone)] pub struct GpuCustomMaterial { _buffer: Buffer, bind_group: BindGroup, } impl RenderAsset for CustomMaterial { type ExtractedAsset = CustomMaterial; type PreparedAsset = GpuCustomMaterial; type Param = (SRes<RenderDevice>, SRes<MaterialPipeline<Self>>); fn extract_asset(&self) -> Self::ExtractedAsset { self.clone() } fn prepare_asset( extracted_asset: Self::ExtractedAsset, (render_device, material_pipeline): &mut SystemParamItem<Self::Param>, ) -> Result<Self::PreparedAsset, PrepareAssetError<Self::ExtractedAsset>> { let color = Vec4::from_slice(&extracted_asset.color.as_linear_rgba_f32()); let byte_buffer = [0u8; Vec4::SIZE.get() as usize]; let mut buffer = encase::UniformBuffer::new(byte_buffer); buffer.write(&color).unwrap(); let buffer = render_device.create_buffer_with_data(&BufferInitDescriptor { contents: buffer.as_ref(), label: None, usage: BufferUsages::UNIFORM | BufferUsages::COPY_DST, }); let (texture_view, texture_sampler) = if let Some(result) = material_pipeline .mesh_pipeline .get_image_texture(gpu_images, &Some(extracted_asset.color_texture.clone())) { result } else { return Err(PrepareAssetError::RetryNextUpdate(extracted_asset)); }; let bind_group = render_device.create_bind_group(&BindGroupDescriptor { entries: &[ BindGroupEntry { binding: 0, resource: buffer.as_entire_binding(), }, BindGroupEntry { binding: 0, resource: BindingResource::TextureView(texture_view), }, BindGroupEntry { binding: 1, resource: BindingResource::Sampler(texture_sampler), }, ], label: None, layout: &material_pipeline.material_layout, }); Ok(GpuCustomMaterial { _buffer: buffer, bind_group, }) } } impl Material for CustomMaterial { fn fragment_shader(asset_server: &AssetServer) -> Option<Handle<Shader>> { Some(asset_server.load("custom_material.wgsl")) } fn bind_group(render_asset: &<Self as RenderAsset>::PreparedAsset) -> &BindGroup { &render_asset.bind_group } fn bind_group_layout(render_device: &RenderDevice) -> BindGroupLayout { render_device.create_bind_group_layout(&BindGroupLayoutDescriptor { entries: &[ BindGroupLayoutEntry { binding: 0, visibility: ShaderStages::FRAGMENT, ty: BindingType::Buffer { ty: BufferBindingType::Uniform, has_dynamic_offset: false, min_binding_size: Some(Vec4::min_size()), }, count: None, }, BindGroupLayoutEntry { binding: 1, visibility: ShaderStages::FRAGMENT, ty: BindingType::Texture { multisampled: false, sample_type: TextureSampleType::Float { filterable: true }, view_dimension: TextureViewDimension::D2Array, }, count: None, }, BindGroupLayoutEntry { binding: 2, visibility: ShaderStages::FRAGMENT, ty: BindingType::Sampler(SamplerBindingType::Filtering), count: None, }, ], label: None, }) } } ``` ### Bevy 0.8 (new) ```rust impl Material for CustomMaterial { fn fragment_shader() -> ShaderRef { "custom_material.wgsl".into() } } #[derive(AsBindGroup, TypeUuid, Debug, Clone)] #[uuid = "f690fdae-d598-45ab-8225-97e2a3f056e0"] pub struct CustomMaterial { #[uniform(0)] color: Color, #[texture(1)] #[sampler(2)] color_texture: Handle<Image>, } ``` ## Future Work * Add support for more binding types (cubemaps, buffers, etc). This PR intentionally includes a bare minimum number of binding types to keep "reviewability" in check. * Consider optionally eliding binding indices using binding names. `AsBindGroup` could pass in (optional?) reflection info as a "hint". * This would make it possible for the derive to do this: ```rust #[derive(AsBindGroup)] pub struct CustomMaterial { #[uniform] color: Color, #[texture] #[sampler] color_texture: Option<Handle<Image>>, alpha_mode: AlphaMode, } ``` * Or this ```rust #[derive(AsBindGroup)] pub struct CustomMaterial { #[binding] color: Color, #[binding] color_texture: Option<Handle<Image>>, alpha_mode: AlphaMode, } ``` * Or even this (if we flip to "include bindings by default") ```rust #[derive(AsBindGroup)] pub struct CustomMaterial { color: Color, color_texture: Option<Handle<Image>>, #[binding(ignore)] alpha_mode: AlphaMode, } ``` * If we add the option to define custom draw functions for materials (which could be done in a type-erased way), I think that would be enough to support extra non-material bindings. Worth considering! |
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Robert Swain
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a0a3d8798b |
ExtractResourcePlugin (#3745)
# Objective - Add an `ExtractResourcePlugin` for convenience and consistency ## Solution - Add an `ExtractResourcePlugin` similar to `ExtractComponentPlugin` but for ECS `Resource`s. The system that is executed simply clones the main world resource into a render world resource, if and only if the main world resource was either added or changed since the last execution of the system. - Add an `ExtractResource` trait with a `fn extract_resource(res: &Self) -> Self` function. This is used by the `ExtractResourcePlugin` to extract the resource - Add a derive macro for `ExtractResource` on a `Resource` with the `Clone` trait, that simply returns `res.clone()` - Use `ExtractResourcePlugin` wherever both possible and appropriate |