mirror of
https://github.com/vulkano-rs/vulkano.git
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Enforce a consistent comment width (#2444)
* Enforce comment width * `cargo +nightly fmt` * Finishing touches
This commit is contained in:
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@ -1,2 +1,4 @@
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imports_granularity = "Crate"
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comment_width = 99
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group_imports = "One"
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imports_granularity = "Crate"
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wrap_comments = true
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@ -1,11 +1,13 @@
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// Welcome to the mesh shader example!
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//
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// This is a simple, modified version of the `instancing.rs` example that demonstrates how to use mesh shaders to
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// generate geometry, that looks identical to the instancing example. We expect you to be familiar with both
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// instancing and compute shaders before approaching mesh shaders, due to their high complexity.
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// This is a simple, modified version of the `instancing.rs` example that demonstrates how to use
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// mesh shaders to generate geometry, that looks identical to the instancing example. We expect you
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// to be familiar with both instancing and compute shaders before approaching mesh shaders, due to
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// their high complexity.
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//
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// This example is intentionally kept simple and does not follow the recommended pattern by which one should emit
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// vertices and indices. This pattern should best match what the hardware likes, and thus is unique to each vendor.
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// This example is intentionally kept simple and does not follow the recommended pattern by which
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// one should emit vertices and indices. This pattern should best match what the hardware likes,
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// and thus is unique to each vendor.
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//
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// See these presentation slides for an overview of mesh shaders and best practices:
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// https://vulkan.org/user/pages/09.events/vulkanised-2023/vulkanised_mesh_best_practices_2023.02.09-1.pdf
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@ -357,8 +357,9 @@ fn main() {
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.unwrap();
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unsafe {
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// Drawing commands are broadcast to each view in the view mask of the active renderpass which
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// means only a single draw call is needed to draw to multiple layers of the framebuffer.
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// Drawing commands are broadcast to each view in the view mask of the active renderpass
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// which means only a single draw call is needed to draw to multiple layers of the
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// framebuffer.
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builder.draw(vertex_buffer.len() as u32, 1, 0, 0).unwrap();
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}
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@ -313,8 +313,8 @@ fn main() -> Result<(), impl Error> {
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elapsed.as_secs() as f64 + elapsed.subsec_nanos() as f64 / 1_000_000_000.0;
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let rotation = Matrix3::from_angle_y(Rad(rotation as f32));
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// note: this teapot was meant for OpenGL where the origin is at the lower left
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// instead the origin is at the upper left in Vulkan, so we reverse the Y axis
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// NOTE: This teapot was meant for OpenGL where the origin is at the lower left
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// instead the origin is at the upper left in Vulkan, so we reverse the Y axis.
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let aspect_ratio =
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swapchain.image_extent()[0] as f32 / swapchain.image_extent()[1] as f32;
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let proj = cgmath::perspective(
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@ -395,21 +395,21 @@ fn main() -> Result<(), impl Error> {
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PipelineShaderStageCreateInfo::new(fs),
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];
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// We must now create a **pipeline layout** object, which describes the locations and types of
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// descriptor sets and push constants used by the shaders in the pipeline.
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// We must now create a **pipeline layout** object, which describes the locations and types
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// of descriptor sets and push constants used by the shaders in the pipeline.
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//
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// Multiple pipelines can share a common layout object, which is more efficient.
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// The shaders in a pipeline must use a subset of the resources described in its pipeline
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// layout, but the pipeline layout is allowed to contain resources that are not present in the
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// shaders; they can be used by shaders in other pipelines that share the same layout.
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// Thus, it is a good idea to design shaders so that many pipelines have common resource
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// locations, which allows them to share pipeline layouts.
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// layout, but the pipeline layout is allowed to contain resources that are not present in
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// the shaders; they can be used by shaders in other pipelines that share the same
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// layout. Thus, it is a good idea to design shaders so that many pipelines have
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// common resource locations, which allows them to share pipeline layouts.
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let layout = PipelineLayout::new(
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device.clone(),
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// Since we only have one pipeline in this example, and thus one pipeline layout,
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// we automatically generate the creation info for it from the resources used in the
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// shaders. In a real application, you would specify this information manually so that you
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// can re-use one layout in multiple pipelines.
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// shaders. In a real application, you would specify this information manually so that
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// you can re-use one layout in multiple pipelines.
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PipelineDescriptorSetLayoutCreateInfo::from_stages(&stages)
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.into_pipeline_layout_create_info(device.clone())
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.unwrap(),
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@ -448,7 +448,8 @@ fn main() -> Result<(), impl Error> {
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// The default value does not perform any multisampling.
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multisample_state: Some(MultisampleState::default()),
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// How pixel values are combined with the values already present in the framebuffer.
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// The default value overwrites the old value with the new one, without any blending.
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// The default value overwrites the old value with the new one, without any
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// blending.
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color_blend_state: Some(ColorBlendState::with_attachment_states(
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subpass.color_attachment_formats.len() as u32,
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ColorBlendAttachmentState::default(),
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@ -400,21 +400,21 @@ fn main() -> Result<(), impl Error> {
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PipelineShaderStageCreateInfo::new(fs),
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];
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// We must now create a **pipeline layout** object, which describes the locations and types of
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// descriptor sets and push constants used by the shaders in the pipeline.
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// We must now create a **pipeline layout** object, which describes the locations and types
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// of descriptor sets and push constants used by the shaders in the pipeline.
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//
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// Multiple pipelines can share a common layout object, which is more efficient.
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// The shaders in a pipeline must use a subset of the resources described in its pipeline
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// layout, but the pipeline layout is allowed to contain resources that are not present in the
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// shaders; they can be used by shaders in other pipelines that share the same layout.
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// Thus, it is a good idea to design shaders so that many pipelines have common resource
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// locations, which allows them to share pipeline layouts.
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// layout, but the pipeline layout is allowed to contain resources that are not present in
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// the shaders; they can be used by shaders in other pipelines that share the same
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// layout. Thus, it is a good idea to design shaders so that many pipelines have
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// common resource locations, which allows them to share pipeline layouts.
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let layout = PipelineLayout::new(
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device.clone(),
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// Since we only have one pipeline in this example, and thus one pipeline layout,
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// we automatically generate the creation info for it from the resources used in the
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// shaders. In a real application, you would specify this information manually so that you
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// can re-use one layout in multiple pipelines.
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// shaders. In a real application, you would specify this information manually so that
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// you can re-use one layout in multiple pipelines.
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PipelineDescriptorSetLayoutCreateInfo::from_stages(&stages)
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.into_pipeline_layout_create_info(device.clone())
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.unwrap(),
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@ -446,7 +446,8 @@ fn main() -> Result<(), impl Error> {
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// The default value does not perform any multisampling.
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multisample_state: Some(MultisampleState::default()),
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// How pixel values are combined with the values already present in the framebuffer.
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// The default value overwrites the old value with the new one, without any blending.
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// The default value overwrites the old value with the new one, without any
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// blending.
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color_blend_state: Some(ColorBlendState::with_attachment_states(
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subpass.num_color_attachments(),
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ColorBlendAttachmentState::default(),
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//! The procedural macro for vulkano's shader system.
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//! Manages the compile-time compilation of GLSL into SPIR-V and generation of associated Rust code.
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//! Manages the compile-time compilation of GLSL into SPIR-V and generation of associated Rust
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//! code.
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//!
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//! # Basic usage
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//!
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//!
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//! The macro generates the following items of interest:
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//!
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//! - The `load` constructor. This function takes an `Arc<Device>`, constructs a
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//! [`ShaderModule`] with the passed-in device and the shader data provided
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//! via the macro, and returns `Result<Arc<ShaderModule>, Validated<VulkanError>>`.
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//! Before doing so, it checks every capability instruction in the shader data,
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//! verifying that the passed-in `Device` has the appropriate features enabled.
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//! - The `load` constructor. This function takes an `Arc<Device>`, constructs a [`ShaderModule`]
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//! with the passed-in device and the shader data provided via the macro, and returns
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//! `Result<Arc<ShaderModule>, Validated<VulkanError>>`. Before doing so, it checks every
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//! capability instruction in the shader data, verifying that the passed-in `Device` has the
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//! appropriate features enabled.
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//! - If the `shaders` option is used, then instead of one `load` constructor, there is one for
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//! each shader. They are named based on the provided names, `load_first`, `load_second` etc.
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//! - A Rust struct translated from each struct contained in the shader data. By default each
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//! instances of (references to) one or more bottom-level structures. A top-level structure is
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//! intended to contain the whole rendered scene (or the relevant parts of it), while a
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//! bottom-level structure may contain individual objects within the scene. This two-level
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//! arrangement allows you to easily rearrange the scene, adding and removing parts of it as needed.
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//! arrangement allows you to easily rearrange the scene, adding and removing parts of it as
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//! needed.
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//!
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//! # Building an acceleration structure
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//!
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//! - [`AccelerationStructureBuildGeometryInfo::scratch_data`]
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//! - [`AccelerationStructureGeometryTrianglesData::vertex_data`]
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//! - [`AccelerationStructureGeometryTrianglesData::vertex_stride`]
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//! - [`AccelerationStructureGeometryTrianglesData::transform_data`]
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//! (but the variant of `Option` must not change)
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//! - [`AccelerationStructureGeometryTrianglesData::transform_data`] (but the variant of `Option`
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//! must not change)
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//! - [`AccelerationStructureGeometryAabbsData::data`]
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//! - [`AccelerationStructureGeometryAabbsData::stride`]
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//! - [`AccelerationStructureGeometryInstancesData::data`]
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@ -75,7 +76,8 @@
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//!
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//! On the Vulkano side, you can then create a descriptor set layout using
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//! [`DescriptorType::AccelerationStructure`] as a descriptor type, and write the
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//! acceleration structure to a descriptor set using [`WriteDescriptorSet::acceleration_structure`].
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//! acceleration structure to a descriptor set using
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//! [`WriteDescriptorSet::acceleration_structure`].
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//!
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//! [`build_acceleration_structure`]: crate::command_buffer::RecordingCommandBuffer::build_acceleration_structure
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//! [`build_acceleration_structure_indirect`]: crate::command_buffer::RecordingCommandBuffer::build_acceleration_structure_indirect
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@ -113,8 +115,8 @@ impl AccelerationStructure {
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///
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/// # Safety
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///
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/// - `create_info.buffer` (and any subbuffer it overlaps with) must not be accessed
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/// while it is bound to the acceleration structure.
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/// - `create_info.buffer` (and any subbuffer it overlaps with) must not be accessed while it
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/// is bound to the acceleration structure.
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///
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/// [`acceleration_structure`]: crate::device::Features::acceleration_structure
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#[inline]
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@ -1625,7 +1627,8 @@ vulkan_enum! {
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HostOrDevice = HOST_OR_DEVICE,
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}
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/// The minimum sizes needed for various resources during an acceleration structure build operation.
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/// The minimum sizes needed for various resources during an acceleration structure build
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/// operation.
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#[derive(Clone, Debug)]
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pub struct AccelerationStructureBuildSizesInfo {
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/// The minimum required size of the acceleration structure for a build or update operation.
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/// return an error. Similarly if you called [`write`] on the buffer and haven't dropped the
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/// lock, this function will return an error as well.
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///
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/// After this function successfully locks the subbuffer, any attempt to submit a command buffer
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/// that uses it in exclusive mode will fail. You can still submit this subbuffer for
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/// non-exclusive accesses (ie. reads).
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/// After this function successfully locks the subbuffer, any attempt to submit a command
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/// buffer that uses it in exclusive mode will fail. You can still submit this subbuffer
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/// for non-exclusive accesses (ie. reads).
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///
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/// If the memory backing the buffer is not [host-coherent], then this function will lock a
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/// range that is potentially larger than the subbuffer, because the range given to
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@ -344,8 +344,8 @@ where
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// SAFETY:
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// - `self.mapped_slice()` didn't return an error, which means that the subbuffer falls
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// within the mapped range of the memory.
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// - We ensure that memory mappings are always aligned to the non-coherent atom size
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// for non-host-coherent memory, therefore the subbuffer's range aligned to the
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// - We ensure that memory mappings are always aligned to the non-coherent atom size for
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// non-host-coherent memory, therefore the subbuffer's range aligned to the
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// non-coherent atom size must fall within the mapped range of the memory.
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unsafe { allocation.invalidate_range_unchecked(memory_range) }
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.map_err(HostAccessError::Invalidate)?;
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@ -429,8 +429,8 @@ where
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// SAFETY:
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// - `self.mapped_slice()` didn't return an error, which means that the subbuffer falls
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// within the mapped range of the memory.
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// - We ensure that memory mappings are always aligned to the non-coherent atom size
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// for non-host-coherent memory, therefore the subbuffer's range aligned to the
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// - We ensure that memory mappings are always aligned to the non-coherent atom size for
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// non-host-coherent memory, therefore the subbuffer's range aligned to the
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// non-coherent atom size must fall within the mapped range of the memory.
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unsafe { allocation.invalidate_range_unchecked(memory_range) }
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.map_err(HostAccessError::Invalidate)?;
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@ -690,8 +690,8 @@ impl AutoSyncState {
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/// through `Command::buffer(..)` or `Command::image(..)`.
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/// - `PipelineMemoryAccess` must match the way the resource has been used.
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/// - `start_layout` and `end_layout` designate the image layout that the image is expected to
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/// be in when the command starts, and the image layout that the image will be transitioned to
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/// during the command. When it comes to buffers, you should pass `Undefined` for both.
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/// be in when the command starts, and the image layout that the image will be transitioned
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/// to during the command. When it comes to buffers, you should pass `Undefined` for both.
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fn add_resources(&mut self, command_info: &CommandInfo) {
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let &CommandInfo {
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name: command_name,
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//! simultaneously.
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//!
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//! Now imagine that the command buffer contains 10 draw commands instead. Contrary to the dispatch
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//! commands, the draw pipeline contains multiple stages: draw indirect, vertex input, vertex shader,
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//! ..., fragment shader, late fragment test, color output. When there are multiple stages, the
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//! implementations must start and end the stages in order. In other words it can start the draw
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//! indirect stage of all 10 commands, then start the vertex input stage of all 10 commands, and so
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//! on. But it can't for example start the fragment shader stage of a command before starting the
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//! vertex shader stage of another command. Same thing for ending the stages in the right order.
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//! commands, the draw pipeline contains multiple stages: draw indirect, vertex input, vertex
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//! shader, ..., fragment shader, late fragment test, color output. When there are multiple stages,
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//! the implementations must start and end the stages in order. In other words it can start the
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//! draw indirect stage of all 10 commands, then start the vertex input stage of all 10 commands,
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//! and so on. But it can't for example start the fragment shader stage of a command before
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//! starting the vertex shader stage of another command. Same thing for ending the stages in the
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//! right order.
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//!
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//! Depending on the type of the command, the pipeline stages are different. Compute shaders use the
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//! compute stage, while transfer commands use the transfer stage. The compute and transfer stages
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//! aren't ordered.
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//! Depending on the type of the command, the pipeline stages are different. Compute shaders use
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//! the compute stage, while transfer commands use the transfer stage. The compute and transfer
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//! stages aren't ordered.
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//!
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//! When you submit multiple command buffers to a queue, the implementation doesn't do anything in
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//! particular and behaves as if the command buffers were appended to one another. Therefore if you
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//! is done by adding a pipeline barrier between the two commands.
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//!
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//! A pipeline barriers has a source stage and a destination stage (plus various other things).
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//! A barrier represents a split in the list of commands. When you add it, the stages of the commands
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//! before the barrier corresponding to the source stage of the barrier, must finish before the
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//! stages of the commands after the barrier corresponding to the destination stage of the barrier
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//! can start.
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//! A barrier represents a split in the list of commands. When you add it, the stages of the
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//! commands before the barrier corresponding to the source stage of the barrier, must finish
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//! before the stages of the commands after the barrier corresponding to the destination stage of
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//! the barrier can start.
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//!
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//! For example if you add a barrier that transitions from the compute stage to the compute stage,
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//! then the compute stage of all the commands before the barrier must end before the compute stage
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/// - If [`index_data`] is `Some`, then if `index_max` is the highest index value in the index
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/// buffer that is accessed, then the size of [`vertex_data`] must be at least<br/>
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/// [`vertex_stride`] * ([`first_vertex`] + `index_max` + 1).
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/// - If [`transform_data`] is `Some`, then for the
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/// 3x4 matrix in the buffer, the first three columns must be a 3x3 invertible matrix.
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/// - If [`transform_data`] is `Some`, then for the 3x4 matrix in the buffer, the first three
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/// columns must be a 3x3 invertible matrix.
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///
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/// If `info.geometries` is [`AccelerationStructureGeometries::Aabbs`], then for each geometry:
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/// - For each accessed [`AabbPositions`] element in
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@ -54,11 +54,11 @@ impl RecordingCommandBuffer {
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/// of the buffer in [`data`](AccelerationStructureGeometryInstancesData::data) must be valid,
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/// as follows:
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/// - Any [`AccelerationStructureInstance::acceleration_structure_reference`] address contained
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/// in or referenced by [`data`](AccelerationStructureGeometryInstancesData::data)
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/// must be either 0, or a device address that was returned from calling [`device_address`]
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/// on a bottom-level acceleration structure.
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/// - If an [`AccelerationStructureInstance::acceleration_structure_reference`] address is
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/// not 0, then the corresponding acceleration structure object must be kept alive and not be
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/// in or referenced by [`data`](AccelerationStructureGeometryInstancesData::data) must be
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/// either 0, or a device address that was returned from calling [`device_address`] on a
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/// bottom-level acceleration structure.
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/// - If an [`AccelerationStructureInstance::acceleration_structure_reference`] address is not
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/// 0, then the corresponding acceleration structure object must be kept alive and not be
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/// dropped while it is bound to the top-level acceleration structure.
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/// - If [`data`](AccelerationStructureGeometryInstancesData::data) is
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/// [`AccelerationStructureGeometryInstancesDataType::Pointers`], then the addresses in the
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@ -138,8 +138,8 @@ impl RecordingCommandBuffer {
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/// - [`primitive_count`] must not be greater than the corresponding element of
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/// `max_primitive_counts`.
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/// - If `info.geometries` is [`AccelerationStructureGeometries::Instances`], then
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/// [`primitive_count`] must not be greater than the [`max_instance_count`] limit.
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/// Otherwise, it must not be greater than the [`max_primitive_count`] limit.
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/// [`primitive_count`] must not be greater than the [`max_instance_count`] limit. Otherwise,
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/// it must not be greater than the [`max_primitive_count`] limit.
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///
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/// If `info.geometries` is [`AccelerationStructureGeometries::Triangles`], then:
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/// - [`primitive_offset`] must be a multiple of:
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@ -147,15 +147,15 @@ impl RecordingCommandBuffer {
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/// - The byte size of the smallest component of [`vertex_format`] if [`index_data`] is
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/// `None`.
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/// - [`transform_offset`] must be a multiple of 16.
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/// - The size of [`vertex_data`] must be at least<br/>
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/// [`primitive_offset`] + ([`first_vertex`] + 3 * [`primitive_count`]) * [`vertex_stride`]
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/// <br/>if [`index_data`] is `None`, and as in [`build_acceleration_structure`] if
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/// [`index_data`] is `Some`.
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/// - The size of [`index_data`] must be at least<br/>
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/// [`primitive_offset`] + 3 * [`primitive_count`] *
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/// [`index_data.index_type().size()`].
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/// - The size of [`transform_data`] must be at least<br/>
|
||||
/// [`transform_offset`] + `size_of::<TransformMatrix>()`.
|
||||
/// - The size of [`vertex_data`] must be at least<br/> [`primitive_offset`] +
|
||||
/// ([`first_vertex`]
|
||||
/// + 3 * [`primitive_count`]) * [`vertex_stride`] <br/>if [`index_data`] is `None`, and as
|
||||
/// in
|
||||
/// [`build_acceleration_structure`] if [`index_data`] is `Some`.
|
||||
/// - The size of [`index_data`] must be at least<br/> [`primitive_offset`] + 3 *
|
||||
/// [`primitive_count`] * [`index_data.index_type().size()`].
|
||||
/// - The size of [`transform_data`] must be at least<br/> [`transform_offset`] +
|
||||
/// `size_of::<TransformMatrix>()`.
|
||||
///
|
||||
/// If `info.geometries` is [`AccelerationStructureGeometries::Aabbs`], then:
|
||||
/// - [`primitive_offset`] must be a multiple of 8.
|
||||
@ -170,8 +170,7 @@ impl RecordingCommandBuffer {
|
||||
/// `size_of::<AccelerationStructureInstance>()`<br/> if
|
||||
/// [`data`](AccelerationStructureGeometryInstancesData::data) is
|
||||
/// [`AccelerationStructureGeometryInstancesDataType::Values`].
|
||||
/// - [`primitive_offset`] + [`primitive_count`] *
|
||||
/// `size_of::<DeviceSize>()`<br/> if
|
||||
/// - [`primitive_offset`] + [`primitive_count`] * `size_of::<DeviceSize>()`<br/> if
|
||||
/// [`data`](AccelerationStructureGeometryInstancesData::data) is
|
||||
/// [`AccelerationStructureGeometryInstancesDataType::Pointers`].
|
||||
///
|
||||
@ -354,8 +353,8 @@ impl RecordingCommandBuffer {
|
||||
///
|
||||
/// - `info.src` must have been built when this command is executed.
|
||||
/// - `info.dst` must be large enough to hold the serialized form of `info.src`. This can be
|
||||
/// queried using [`write_acceleration_structures_properties`] with a query pool whose type is
|
||||
/// [`QueryType::AccelerationStructureSerializationSize`].
|
||||
/// queried using [`write_acceleration_structures_properties`] with a query pool whose type
|
||||
/// is [`QueryType::AccelerationStructureSerializationSize`].
|
||||
///
|
||||
/// [`write_acceleration_structures_properties`]: Self::write_acceleration_structures_properties
|
||||
#[inline]
|
||||
@ -440,8 +439,8 @@ impl RecordingCommandBuffer {
|
||||
/// - `info.src` must contain data previously serialized using
|
||||
/// [`copy_acceleration_structure_to_memory`], and must have a format compatible with the
|
||||
/// device (as queried by [`Device::acceleration_structure_is_compatible`]).
|
||||
/// - `info.dst.size()` must be at least the size that the structure in `info.src` had
|
||||
/// before it was serialized.
|
||||
/// - `info.dst.size()` must be at least the size that the structure in `info.src` had before
|
||||
/// it was serialized.
|
||||
///
|
||||
/// [`copy_acceleration_structure_to_memory`]: Self::copy_acceleration_structure_to_memory
|
||||
/// [`Device::acceleration_structure_is_compatible`]: crate::device::Device::acceleration_structure_is_compatible
|
||||
@ -528,8 +527,8 @@ impl RecordingCommandBuffer {
|
||||
///
|
||||
/// - All elements of `acceleration_structures` must have been built when this command is
|
||||
/// executed.
|
||||
/// - If `query_pool.query_type()` is [`QueryType::AccelerationStructureCompactedSize`],
|
||||
/// all elements of `acceleration_structures` must have been built with
|
||||
/// - If `query_pool.query_type()` is [`QueryType::AccelerationStructureCompactedSize`], all
|
||||
/// elements of `acceleration_structures` must have been built with
|
||||
/// [`BuildAccelerationStructureFlags::ALLOW_COMPACTION`].
|
||||
/// - The queries must be unavailable, ensured by calling [`reset_query_pool`].
|
||||
///
|
||||
|
@ -1085,7 +1085,8 @@ impl RawRecordingCommandBuffer {
|
||||
break;
|
||||
}
|
||||
|
||||
// push the minimum of the whole remaining data, and the part until the end of this range
|
||||
// push the minimum of the whole remaining data, and the part until the end of this
|
||||
// range
|
||||
let push_size =
|
||||
remaining_size.min(range.offset as usize + range.size as usize - current_offset);
|
||||
current_offset += push_size;
|
||||
@ -1140,7 +1141,8 @@ impl RawRecordingCommandBuffer {
|
||||
break;
|
||||
}
|
||||
|
||||
// push the minimum of the whole remaining data, and the part until the end of this range
|
||||
// push the minimum of the whole remaining data, and the part until the end of this
|
||||
// range
|
||||
let push_size = remaining_size.min(range.offset + range.size - current_offset);
|
||||
let data_offset = (current_offset - offset) as usize;
|
||||
debug_assert!(data_offset < size as usize);
|
||||
|
@ -25,8 +25,7 @@ impl RecordingCommandBuffer {
|
||||
///
|
||||
/// # Panics
|
||||
///
|
||||
/// - Panics if `src_buffer` or `dst_buffer` were not created from the same device
|
||||
/// as `self`.
|
||||
/// - Panics if `src_buffer` or `dst_buffer` were not created from the same device as `self`.
|
||||
pub fn copy_buffer(
|
||||
&mut self,
|
||||
copy_buffer_info: impl Into<CopyBufferInfo>,
|
||||
@ -125,8 +124,7 @@ impl RecordingCommandBuffer {
|
||||
///
|
||||
/// # Panics
|
||||
///
|
||||
/// - Panics if `src_image` or `dst_image` were not created from the same device
|
||||
/// as `self`.
|
||||
/// - Panics if `src_image` or `dst_image` were not created from the same device as `self`.
|
||||
pub fn copy_image(
|
||||
&mut self,
|
||||
copy_image_info: CopyImageInfo,
|
||||
@ -501,8 +499,7 @@ impl RecordingCommandBuffer {
|
||||
///
|
||||
/// # Panics
|
||||
///
|
||||
/// - Panics if `src_image` or `dst_image` were not created from the same device
|
||||
/// as `self`.
|
||||
/// - Panics if `src_image` or `dst_image` were not created from the same device as `self`.
|
||||
pub fn resolve_image(
|
||||
&mut self,
|
||||
resolve_image_info: ResolveImageInfo,
|
||||
@ -5233,7 +5230,8 @@ pub struct BlitImageInfo {
|
||||
///
|
||||
/// The default value is a single region, covering the first mip level, and the smallest of the
|
||||
/// array layers of the two images. The whole extent of each image is covered, scaling if
|
||||
/// necessary. All aspects of each image are selected, or `plane0` if the image is multi-planar.
|
||||
/// necessary. All aspects of each image are selected, or `plane0` if the image is
|
||||
/// multi-planar.
|
||||
pub regions: SmallVec<[ImageBlit; 1]>,
|
||||
|
||||
/// The filter to use for sampling `src_image` when the `src_extent` and
|
||||
|
@ -214,10 +214,10 @@ impl RecordingCommandBuffer {
|
||||
/// and `first_instance` as 0.
|
||||
///
|
||||
/// A primitive shading graphics pipeline must have been bound using
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the graphics
|
||||
/// pipeline, such as descriptor sets, vertex buffers and dynamic state, must have been set
|
||||
/// beforehand. If the bound graphics pipeline uses vertex buffers, then the provided vertex and
|
||||
/// instance ranges must be in range of the bound vertex buffers.
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the
|
||||
/// graphics pipeline, such as descriptor sets, vertex buffers and dynamic state, must have
|
||||
/// been set beforehand. If the bound graphics pipeline uses vertex buffers, then the
|
||||
/// provided vertex and instance ranges must be in range of the bound vertex buffers.
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
@ -404,17 +404,16 @@ impl RecordingCommandBuffer {
|
||||
/// enabled.
|
||||
///
|
||||
/// A primitive shading graphics pipeline must have been bound using
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the graphics
|
||||
/// pipeline, such as descriptor sets, vertex buffers and dynamic state, must have been set
|
||||
/// beforehand. If the bound graphics pipeline uses vertex buffers, then the vertex and instance
|
||||
/// ranges of each `DrawIndirectCommand` in the indirect buffer must be in range of the bound
|
||||
/// vertex buffers.
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the
|
||||
/// graphics pipeline, such as descriptor sets, vertex buffers and dynamic state, must have
|
||||
/// been set beforehand. If the bound graphics pipeline uses vertex buffers, then the
|
||||
/// vertex and instance ranges of each `DrawIndirectCommand` in the indirect buffer must be
|
||||
/// in range of the bound vertex buffers.
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
/// - The general [shader safety requirements](crate::shader#safety) apply.
|
||||
/// - The [safety requirements for `DrawIndirectCommand`](DrawIndirectCommand#safety)
|
||||
/// apply.
|
||||
/// - The [safety requirements for `DrawIndirectCommand`](DrawIndirectCommand#safety) apply.
|
||||
pub unsafe fn draw_indirect(
|
||||
&mut self,
|
||||
indirect_buffer: Subbuffer<[DrawIndirectCommand]>,
|
||||
@ -512,17 +511,16 @@ impl RecordingCommandBuffer {
|
||||
/// [`max_draw_indirect_count`](Properties::max_draw_indirect_count) limit.
|
||||
///
|
||||
/// A primitive shading graphics pipeline must have been bound using
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the graphics
|
||||
/// pipeline, such as descriptor sets, vertex buffers and dynamic state, must have been set
|
||||
/// beforehand. If the bound graphics pipeline uses vertex buffers, then the vertex and instance
|
||||
/// ranges of each `DrawIndirectCommand` in the indirect buffer must be in range of the bound
|
||||
/// vertex buffers.
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the
|
||||
/// graphics pipeline, such as descriptor sets, vertex buffers and dynamic state, must have
|
||||
/// been set beforehand. If the bound graphics pipeline uses vertex buffers, then the
|
||||
/// vertex and instance ranges of each `DrawIndirectCommand` in the indirect buffer must be
|
||||
/// in range of the bound vertex buffers.
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
/// - The general [shader safety requirements](crate::shader#safety) apply.
|
||||
/// - The [safety requirements for `DrawIndirectCommand`](DrawIndirectCommand#safety)
|
||||
/// apply.
|
||||
/// - The [safety requirements for `DrawIndirectCommand`](DrawIndirectCommand#safety) apply.
|
||||
/// - The count stored in `count_buffer` must not be greater than the
|
||||
/// [`max_draw_indirect_count`](Properties::max_draw_indirect_count) device limit.
|
||||
/// - The count stored in `count_buffer` must fall within the range of `indirect_buffer`.
|
||||
@ -652,11 +650,11 @@ impl RecordingCommandBuffer {
|
||||
/// range of the bound index buffer.
|
||||
///
|
||||
/// A primitive shading graphics pipeline must have been bound using
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the graphics
|
||||
/// pipeline, such as descriptor sets, vertex buffers and dynamic state, must have been set
|
||||
/// beforehand. If the bound graphics pipeline uses vertex buffers, then the provided instance
|
||||
/// range must be in range of the bound vertex buffers. The vertex indices in the index buffer
|
||||
/// must be in range of the bound vertex buffers.
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the
|
||||
/// graphics pipeline, such as descriptor sets, vertex buffers and dynamic state, must have
|
||||
/// been set beforehand. If the bound graphics pipeline uses vertex buffers, then the
|
||||
/// provided instance range must be in range of the bound vertex buffers. The vertex
|
||||
/// indices in the index buffer must be in range of the bound vertex buffers.
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
@ -891,17 +889,17 @@ impl RecordingCommandBuffer {
|
||||
/// buffer.
|
||||
///
|
||||
/// A primitive shading graphics pipeline must have been bound using
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the graphics
|
||||
/// pipeline, such as descriptor sets, vertex buffers and dynamic state, must have been set
|
||||
/// beforehand. If the bound graphics pipeline uses vertex buffers, then the instance ranges of
|
||||
/// each `DrawIndexedIndirectCommand` in the indirect buffer must be in range of the bound
|
||||
/// vertex buffers.
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the
|
||||
/// graphics pipeline, such as descriptor sets, vertex buffers and dynamic state, must have
|
||||
/// been set beforehand. If the bound graphics pipeline uses vertex buffers, then the
|
||||
/// instance ranges of each `DrawIndexedIndirectCommand` in the indirect buffer must be in
|
||||
/// range of the bound vertex buffers.
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
/// - The general [shader safety requirements](crate::shader#safety) apply.
|
||||
/// - The [safety requirements for `DrawIndexedIndirectCommand`](DrawIndexedIndirectCommand#safety)
|
||||
/// apply.
|
||||
/// - The [safety requirements for
|
||||
/// `DrawIndexedIndirectCommand`](DrawIndexedIndirectCommand#safety) apply.
|
||||
pub unsafe fn draw_indexed_indirect(
|
||||
&mut self,
|
||||
indirect_buffer: Subbuffer<[DrawIndexedIndirectCommand]>,
|
||||
@ -1013,17 +1011,17 @@ impl RecordingCommandBuffer {
|
||||
/// buffer.
|
||||
///
|
||||
/// A primitive shading graphics pipeline must have been bound using
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the graphics
|
||||
/// pipeline, such as descriptor sets, vertex buffers and dynamic state, must have been set
|
||||
/// beforehand. If the bound graphics pipeline uses vertex buffers, then the instance ranges of
|
||||
/// each `DrawIndexedIndirectCommand` in the indirect buffer must be in range of the bound
|
||||
/// vertex buffers.
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the
|
||||
/// graphics pipeline, such as descriptor sets, vertex buffers and dynamic state, must have
|
||||
/// been set beforehand. If the bound graphics pipeline uses vertex buffers, then the
|
||||
/// instance ranges of each `DrawIndexedIndirectCommand` in the indirect buffer must be in
|
||||
/// range of the bound vertex buffers.
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
/// - The general [shader safety requirements](crate::shader#safety) apply.
|
||||
/// - The [safety requirements for `DrawIndexedIndirectCommand`](DrawIndexedIndirectCommand#safety)
|
||||
/// apply.
|
||||
/// - The [safety requirements for
|
||||
/// `DrawIndexedIndirectCommand`](DrawIndexedIndirectCommand#safety) apply.
|
||||
/// - The count stored in `count_buffer` must not be greater than the
|
||||
/// [`max_draw_indirect_count`](Properties::max_draw_indirect_count) device limit.
|
||||
/// - The count stored in `count_buffer` must fall within the range of `indirect_buffer`.
|
||||
@ -1152,7 +1150,8 @@ impl RecordingCommandBuffer {
|
||||
///
|
||||
/// A mesh shading graphics pipeline must have been bound using
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the
|
||||
/// graphics pipeline, such as descriptor sets and dynamic state, must have been set beforehand.
|
||||
/// graphics pipeline, such as descriptor sets and dynamic state, must have been set
|
||||
/// beforehand.
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
@ -1336,16 +1335,17 @@ impl RecordingCommandBuffer {
|
||||
|
||||
/// Perform multiple draw operations using a mesh shading graphics pipeline.
|
||||
///
|
||||
/// One draw is performed for each [`DrawMeshTasksIndirectCommand`] struct in `indirect_buffer`.
|
||||
/// The maximum number of draw commands in the buffer is limited by the
|
||||
/// One draw is performed for each [`DrawMeshTasksIndirectCommand`] struct in
|
||||
/// `indirect_buffer`. The maximum number of draw commands in the buffer is limited by the
|
||||
/// [`max_draw_indirect_count`](Properties::max_draw_indirect_count) limit.
|
||||
/// This limit is 1 unless the
|
||||
/// [`multi_draw_indirect`](Features::multi_draw_indirect) feature has been
|
||||
/// enabled.
|
||||
///
|
||||
/// A mesh shading graphics pipeline must have been bound using
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the graphics
|
||||
/// pipeline, such as descriptor sets and dynamic state, must have been set beforehand.
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the
|
||||
/// graphics pipeline, such as descriptor sets and dynamic state, must have been set
|
||||
/// beforehand.
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
@ -1458,8 +1458,9 @@ impl RecordingCommandBuffer {
|
||||
/// [`max_draw_indirect_count`](Properties::max_draw_indirect_count) limit.
|
||||
///
|
||||
/// A mesh shading graphics pipeline must have been bound using
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the graphics
|
||||
/// pipeline, such as descriptor sets and dynamic state, must have been set beforehand.
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). Any resources used by the
|
||||
/// graphics pipeline, such as descriptor sets and dynamic state, must have been set
|
||||
/// beforehand.
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
@ -1886,11 +1887,11 @@ impl RecordingCommandBuffer {
|
||||
}));
|
||||
}
|
||||
|
||||
// - If the Sampled Type of the OpTypeImage does not match the numeric format of the
|
||||
// image, as shown in the SPIR-V Sampled Type column of the
|
||||
// Interpretation of Numeric Format table.
|
||||
// - If the signedness of any read or sample operation does not match the signedness of
|
||||
// the image’s format.
|
||||
// - If the Sampled Type of the OpTypeImage does not match the numeric format of
|
||||
// the image, as shown in the SPIR-V Sampled Type column of the Interpretation
|
||||
// of Numeric Format table.
|
||||
// - If the signedness of any read or sample operation does not match the
|
||||
// signedness of the image’s format.
|
||||
if let Some(shader_numeric_type) = binding_reqs.image_scalar_type {
|
||||
let aspects = image_view.subresource_range().aspects;
|
||||
let view_numeric_type = NumericType::from(
|
||||
@ -1955,10 +1956,11 @@ impl RecordingCommandBuffer {
|
||||
}));
|
||||
}
|
||||
|
||||
// - OpImageFetch, OpImageSparseFetch, OpImage*Gather, and OpImageSparse*Gather must not
|
||||
// be used with a sampler that enables sampler Y′CBCR conversion.
|
||||
// - The ConstOffset and Offset operands must not be used with a sampler that enables
|
||||
// - OpImageFetch, OpImageSparseFetch, OpImage*Gather, and
|
||||
// OpImageSparse*Gather must not be used with a sampler that enables
|
||||
// sampler Y′CBCR conversion.
|
||||
// - The ConstOffset and Offset operands must not be used with a sampler
|
||||
// that enables sampler Y′CBCR conversion.
|
||||
if desc_reqs.sampler_no_ycbcr_conversion
|
||||
&& sampler.sampler_ycbcr_conversion().is_some()
|
||||
{
|
||||
@ -1983,8 +1985,8 @@ impl RecordingCommandBuffer {
|
||||
*/
|
||||
|
||||
if desc_reqs.sampler_compare && sampler.compare().is_none() {
|
||||
// - The SPIR-V instruction is one of the OpImage*Dref* instructions and the sampler
|
||||
// compareEnable is VK_FALSE
|
||||
// - The SPIR-V instruction is one of the OpImage*Dref* instructions and
|
||||
// the sampler compareEnable is VK_FALSE
|
||||
return Err(Box::new(ValidationError {
|
||||
problem: format!(
|
||||
"the currently bound pipeline accesses the sampler bound to \
|
||||
@ -1998,8 +2000,8 @@ impl RecordingCommandBuffer {
|
||||
..Default::default()
|
||||
}));
|
||||
} else if !desc_reqs.sampler_compare && sampler.compare().is_some() {
|
||||
// - The SPIR-V instruction is not one of the OpImage*Dref* instructions and the sampler
|
||||
// compareEnable is VK_TRUE
|
||||
// - The SPIR-V instruction is not one of the OpImage*Dref* instructions
|
||||
// and the sampler compareEnable is VK_TRUE
|
||||
return Err(Box::new(ValidationError {
|
||||
problem: format!(
|
||||
"the currently bound pipeline accesses the sampler bound to \
|
||||
@ -2908,7 +2910,8 @@ impl RecordingCommandBuffer {
|
||||
}
|
||||
}
|
||||
// DynamicState::RayTracingPipelineStackSize => unreachable!(
|
||||
// "RayTracingPipelineStackSize dynamic state should not occur on a graphics pipeline"
|
||||
// "RayTracingPipelineStackSize dynamic state should not occur on a graphics \
|
||||
// pipeline",
|
||||
// ),
|
||||
// DynamicState::SampleLocations => todo!(),
|
||||
DynamicState::Scissor => {
|
||||
@ -3188,12 +3191,14 @@ impl RecordingCommandBuffer {
|
||||
}
|
||||
|
||||
// TODO: VUID-vkCmdDrawIndexed-primitiveFragmentShadingRateWithMultipleViewports-04552
|
||||
// If the primitiveFragmentShadingRateWithMultipleViewports limit is not supported,
|
||||
// the bound graphics pipeline was created with the
|
||||
// VK_DYNAMIC_STATE_VIEWPORT_WITH_COUNT_EXT dynamic state enabled, and any of the
|
||||
// shader stages of the bound graphics pipeline write to the PrimitiveShadingRateKHR
|
||||
// built-in, then vkCmdSetViewportWithCountEXT must have been called in the current
|
||||
// command buffer prior to this drawing command, and the viewportCount parameter of
|
||||
// If the primitiveFragmentShadingRateWithMultipleViewports limit is not
|
||||
// supported, the bound graphics pipeline was created with
|
||||
// the VK_DYNAMIC_STATE_VIEWPORT_WITH_COUNT_EXT dynamic
|
||||
// state enabled, and any of the shader stages of the bound
|
||||
// graphics pipeline write to the PrimitiveShadingRateKHR
|
||||
// built-in, then vkCmdSetViewportWithCountEXT must have been called in the
|
||||
// current command buffer prior to this drawing command, and
|
||||
// the viewportCount parameter of
|
||||
// vkCmdSetViewportWithCountEXT must be 1
|
||||
}
|
||||
}
|
||||
|
@ -67,8 +67,10 @@ impl RecordingCommandBuffer {
|
||||
// TODO:
|
||||
|
||||
// VUID-vkCmdBeginRenderPass2-framebuffer-02533
|
||||
// For any attachment in framebuffer that is used by renderPass and is bound to memory locations that are also bound to another attachment used by renderPass, and if at least one of those uses causes either
|
||||
// attachment to be written to, both attachments must have had the VK_ATTACHMENT_DESCRIPTION_MAY_ALIAS_BIT set
|
||||
// For any attachment in framebuffer that is used by renderPass and is bound to memory
|
||||
// locations that are also bound to another attachment used by renderPass, and if at least
|
||||
// one of those uses causes either attachment to be written to, both attachments
|
||||
// must have had the VK_ATTACHMENT_DESCRIPTION_MAY_ALIAS_BIT set
|
||||
|
||||
Ok(())
|
||||
}
|
||||
@ -638,7 +640,8 @@ impl RecordingCommandBuffer {
|
||||
/// `rects` specify the regions to clear.
|
||||
///
|
||||
/// A graphics pipeline must have been bound using
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). And the command must be inside render pass.
|
||||
/// [`bind_pipeline_graphics`](Self::bind_pipeline_graphics). And the command must be inside
|
||||
/// render pass.
|
||||
///
|
||||
/// If the render pass instance this is recorded in uses multiview,
|
||||
/// then `ClearRect.base_array_layer` must be zero and `ClearRect.layer_count` must be one.
|
||||
@ -1223,8 +1226,10 @@ impl RawRecordingCommandBuffer {
|
||||
// TODO:
|
||||
|
||||
// VUID-vkCmdBeginRenderPass2-framebuffer-02533
|
||||
// For any attachment in framebuffer that is used by renderPass and is bound to memory locations that are also bound to another attachment used by renderPass, and if at least one of those uses causes either
|
||||
// attachment to be written to, both attachments must have had the VK_ATTACHMENT_DESCRIPTION_MAY_ALIAS_BIT set
|
||||
// For any attachment in framebuffer that is used by renderPass and is bound to memory
|
||||
// locations that are also bound to another attachment used by renderPass, and if at least
|
||||
// one of those uses causes either attachment to be written to, both attachments
|
||||
// must have had the VK_ATTACHMENT_DESCRIPTION_MAY_ALIAS_BIT set
|
||||
|
||||
Ok(())
|
||||
}
|
||||
@ -1825,7 +1830,8 @@ pub struct RenderPassBeginInfo {
|
||||
|
||||
/// The size of the area that will be rendered to.
|
||||
///
|
||||
/// `render_area_offset + render_area_extent` must not be greater than [`framebuffer.extent()`].
|
||||
/// `render_area_offset + render_area_extent` must not be greater than
|
||||
/// [`framebuffer.extent()`].
|
||||
///
|
||||
/// The default value is [`framebuffer.extent()`].
|
||||
pub render_area_extent: [u32; 2],
|
||||
|
@ -22,8 +22,8 @@
|
||||
//!
|
||||
//! There are two levels of command buffers:
|
||||
//!
|
||||
//! - A primary command buffer can be executed on a queue, and is the main command buffer level.
|
||||
//! It cannot be executed within another command buffer.
|
||||
//! - A primary command buffer can be executed on a queue, and is the main command buffer level. It
|
||||
//! cannot be executed within another command buffer.
|
||||
//! - A secondary command buffer can only be executed within a primary command buffer, not directly
|
||||
//! on a queue.
|
||||
//!
|
||||
@ -155,15 +155,15 @@ pub struct DispatchIndirectCommand {
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
/// - Every vertex number within the specified range must fall within the range of
|
||||
/// the bound vertex-rate vertex buffers.
|
||||
/// - Every instance number within the specified range must fall within the range of
|
||||
/// the bound instance-rate vertex buffers.
|
||||
/// - If the [`draw_indirect_first_instance`](Features::draw_indirect_first_instance) feature
|
||||
/// is not enabled, then `first_instance` must be `0`.
|
||||
/// - If an [instance divisor](VertexInputRate::Instance) other than 1 is used, and
|
||||
/// the [`supports_non_zero_first_instance`](Properties::supports_non_zero_first_instance)
|
||||
/// device property is `false`, then `first_instance` must be `0`.
|
||||
/// - Every vertex number within the specified range must fall within the range of the bound
|
||||
/// vertex-rate vertex buffers.
|
||||
/// - Every instance number within the specified range must fall within the range of the bound
|
||||
/// instance-rate vertex buffers.
|
||||
/// - If the [`draw_indirect_first_instance`](Features::draw_indirect_first_instance) feature is
|
||||
/// not enabled, then `first_instance` must be `0`.
|
||||
/// - If an [instance divisor](VertexInputRate::Instance) other than 1 is used, and the
|
||||
/// [`supports_non_zero_first_instance`](Properties::supports_non_zero_first_instance) device
|
||||
/// property is `false`, then `first_instance` must be `0`.
|
||||
#[repr(C)]
|
||||
#[derive(Clone, Copy, Debug, Default, Zeroable, Pod, PartialEq, Eq)]
|
||||
pub struct DrawIndirectCommand {
|
||||
@ -178,18 +178,18 @@ pub struct DrawIndirectCommand {
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
/// - If the graphics pipeline **does not** include a task shader, then the
|
||||
/// `group_count_x`, `group_count_y` and `group_count_z` values must not be greater than the
|
||||
/// respective elements of the
|
||||
/// [`max_mesh_work_group_count`](Properties::max_mesh_work_group_count) device limit,
|
||||
/// and the product of these three values must not be greater than the
|
||||
/// [`max_mesh_work_group_total_count`](Properties::max_mesh_work_group_total_count) device limit.
|
||||
/// - If the graphics pipeline **does** include a task shader, then the
|
||||
/// `group_count_x`, `group_count_y` and `group_count_z` values must not be greater than the
|
||||
/// respective elements of the
|
||||
/// [`max_task_work_group_count`](Properties::max_task_work_group_count) device limit,
|
||||
/// and the product of these three values must not be greater than the
|
||||
/// [`max_task_work_group_total_count`](Properties::max_task_work_group_total_count) device limit.
|
||||
/// - If the graphics pipeline **does not** include a task shader, then the `group_count_x`,
|
||||
/// `group_count_y` and `group_count_z` values must not be greater than the respective elements
|
||||
/// of the [`max_mesh_work_group_count`](Properties::max_mesh_work_group_count) device limit, and
|
||||
/// the product of these three values must not be greater than the
|
||||
/// [`max_mesh_work_group_total_count`](Properties::max_mesh_work_group_total_count) device
|
||||
/// limit.
|
||||
/// - If the graphics pipeline **does** include a task shader, then the `group_count_x`,
|
||||
/// `group_count_y` and `group_count_z` values must not be greater than the respective elements
|
||||
/// of the [`max_task_work_group_count`](Properties::max_task_work_group_count) device limit, and
|
||||
/// the product of these three values must not be greater than the
|
||||
/// [`max_task_work_group_total_count`](Properties::max_task_work_group_total_count) device
|
||||
/// limit.
|
||||
#[repr(C)]
|
||||
#[derive(Clone, Copy, Debug, Default, Zeroable, Pod, PartialEq, Eq)]
|
||||
pub struct DrawMeshTasksIndirectCommand {
|
||||
@ -204,18 +204,18 @@ pub struct DrawMeshTasksIndirectCommand {
|
||||
/// # Safety
|
||||
///
|
||||
/// - Every index within the specified range must fall within the range of the bound index buffer.
|
||||
/// - Every vertex number that is retrieved from the index buffer must fall within the range of
|
||||
/// the bound vertex-rate vertex buffers.
|
||||
/// - Every vertex number that is retrieved from the index buffer must fall within the range of the
|
||||
/// bound vertex-rate vertex buffers.
|
||||
/// - Every vertex number that is retrieved from the index buffer, if it is not the special
|
||||
/// primitive restart value, must be no greater than the
|
||||
/// [`max_draw_indexed_index_value`](Properties::max_draw_indexed_index_value) device limit.
|
||||
/// - Every instance number within the specified range must fall within the range of
|
||||
/// the bound instance-rate vertex buffers.
|
||||
/// - If the [`draw_indirect_first_instance`](Features::draw_indirect_first_instance) feature
|
||||
/// is not enabled, then `first_instance` must be `0`.
|
||||
/// - If an [instance divisor](VertexInputRate::Instance) other than 1 is used, and
|
||||
/// the [`supports_non_zero_first_instance`](Properties::supports_non_zero_first_instance)
|
||||
/// device property is `false`, then `first_instance` must be `0`.
|
||||
/// - Every instance number within the specified range must fall within the range of the bound
|
||||
/// instance-rate vertex buffers.
|
||||
/// - If the [`draw_indirect_first_instance`](Features::draw_indirect_first_instance) feature is
|
||||
/// not enabled, then `first_instance` must be `0`.
|
||||
/// - If an [instance divisor](VertexInputRate::Instance) other than 1 is used, and the
|
||||
/// [`supports_non_zero_first_instance`](Properties::supports_non_zero_first_instance) device
|
||||
/// property is `false`, then `first_instance` must be `0`.
|
||||
#[repr(C)]
|
||||
#[derive(Clone, Copy, Debug, Default, Zeroable, Pod, PartialEq, Eq)]
|
||||
pub struct DrawIndexedIndirectCommand {
|
||||
@ -747,8 +747,9 @@ pub enum CommandBufferUsage {
|
||||
/// optimizations.
|
||||
OneTimeSubmit = ash::vk::CommandBufferUsageFlags::ONE_TIME_SUBMIT.as_raw(),
|
||||
|
||||
/// The command buffer can be used multiple times, but must not execute or record more than once
|
||||
/// simultaneously. In other words, it is as if executing the command buffer borrows it mutably.
|
||||
/// The command buffer can be used multiple times, but must not execute or record more than
|
||||
/// once simultaneously. In other words, it is as if executing the command buffer borrows
|
||||
/// it mutably.
|
||||
MultipleSubmit = 0,
|
||||
|
||||
/// The command buffer can be executed multiple times in parallel on different queues.
|
||||
@ -907,10 +908,10 @@ pub struct SemaphoreSubmitInfo {
|
||||
|
||||
/// If `semaphore.semaphore_type()` is [`SemaphoreType::Timeline`], specifies the value that
|
||||
/// will be used for the semaphore operation:
|
||||
/// - If it's a signal operation, then the semaphore's value will be set to this value
|
||||
/// when it is signaled.
|
||||
/// - If it's a wait operation, then the semaphore will wait until its value is greater than
|
||||
/// or equal to this value.
|
||||
/// - If it's a signal operation, then the semaphore's value will be set to this value when it
|
||||
/// is signaled.
|
||||
/// - If it's a wait operation, then the semaphore will wait until its value is greater than or
|
||||
/// equal to this value.
|
||||
///
|
||||
/// If `semaphore.semaphore_type()` is [`SemaphoreType::Binary`], then this must be `0`.
|
||||
///
|
||||
@ -921,9 +922,9 @@ pub struct SemaphoreSubmitInfo {
|
||||
/// scope: stages of queue operations following the wait operation that can start executing
|
||||
/// after the semaphore is signalled.
|
||||
///
|
||||
/// For a semaphore signal operation, specifies the pipeline stages in the first synchronization
|
||||
/// scope: stages of queue operations preceding the signal operation that must complete before
|
||||
/// the semaphore is signalled.
|
||||
/// For a semaphore signal operation, specifies the pipeline stages in the first
|
||||
/// synchronization scope: stages of queue operations preceding the signal operation that
|
||||
/// must complete before the semaphore is signalled.
|
||||
/// If this value does not equal [`ALL_COMMANDS`], then the [`synchronization2`] feature must
|
||||
/// be enabled on the device.
|
||||
///
|
||||
|
@ -183,14 +183,13 @@ impl DescriptorPool {
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
/// - When the pool is dropped, the returned descriptor sets must not be in use by either
|
||||
/// the host or device.
|
||||
/// - When the pool is dropped, the returned descriptor sets must not be in use by either the
|
||||
/// host or device.
|
||||
/// - If the device API version is less than 1.1, and the [`khr_maintenance1`] extension is not
|
||||
/// enabled on the device, then
|
||||
/// the length of `allocate_infos` must not be greater than the number of descriptor sets
|
||||
/// remaining in the pool, and
|
||||
/// the total number of descriptors of each type being allocated must not be greater than the
|
||||
/// number of descriptors of that type remaining in the pool.
|
||||
/// enabled on the device, then the length of `allocate_infos` must not be greater than the
|
||||
/// number of descriptor sets remaining in the pool, and the total number of descriptors of
|
||||
/// each type being allocated must not be greater than the number of descriptors of that type
|
||||
/// remaining in the pool.
|
||||
///
|
||||
/// [`khr_maintenance1`]: crate::device::DeviceExtensions::khr_maintenance1
|
||||
#[inline]
|
||||
@ -339,8 +338,8 @@ impl DescriptorPool {
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
/// - All elements of `descriptor_sets` must have been allocated from `self`,
|
||||
/// and not freed previously.
|
||||
/// - All elements of `descriptor_sets` must have been allocated from `self`, and not freed
|
||||
/// previously.
|
||||
/// - All elements of `descriptor_sets` must not be in use by the host or device.
|
||||
#[inline]
|
||||
pub unsafe fn free_descriptor_sets(
|
||||
|
@ -28,8 +28,8 @@ use std::{ops::Range, ptr, sync::Arc};
|
||||
/// provided for each resource type:
|
||||
/// - The basic constructor variant writes a single element to array index 0. It is intended for
|
||||
/// non-arrayed bindings, where `descriptor_count` in the descriptor set layout is 1.
|
||||
/// - The `_array` variant writes several elements and allows specifying the target array index.
|
||||
/// At least one element must be provided; a panic results if the provided iterator is empty.
|
||||
/// - The `_array` variant writes several elements and allows specifying the target array index. At
|
||||
/// least one element must be provided; a panic results if the provided iterator is empty.
|
||||
#[derive(Clone, Debug)]
|
||||
pub struct WriteDescriptorSet {
|
||||
binding: u32,
|
||||
@ -44,8 +44,8 @@ impl WriteDescriptorSet {
|
||||
/// immutable samplers in the layout. The Vulkan spec requires these elements to be explicitly
|
||||
/// written, but since there is no data to write, a dummy write is provided instead.
|
||||
///
|
||||
/// For regular descriptor sets, the data for such descriptors is automatically valid, and dummy
|
||||
/// writes are not allowed.
|
||||
/// For regular descriptor sets, the data for such descriptors is automatically valid, and
|
||||
/// dummy writes are not allowed.
|
||||
#[inline]
|
||||
pub fn none(binding: u32) -> Self {
|
||||
Self::none_array(binding, 0, 1)
|
||||
|
@ -1240,7 +1240,8 @@ pub struct DeviceCreateInfo {
|
||||
/// If the [`khr_portability_subset`](DeviceExtensions::khr_portability_subset) extension is
|
||||
/// available, it will be enabled automatically, so you do not have to do this yourself.
|
||||
/// You are responsible for ensuring that your program can work correctly on such devices.
|
||||
/// See [the documentation of the `instance` module](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// See [the documentation of the `instance`
|
||||
/// module](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// for more information.
|
||||
///
|
||||
/// The default value is [`DeviceExtensions::empty()`].
|
||||
@ -1648,9 +1649,9 @@ pub struct QueueCreateInfo {
|
||||
/// The queues to create for the given queue family, each with a relative priority.
|
||||
///
|
||||
/// The relative priority value is an arbitrary number between 0.0 and 1.0. Giving a queue a
|
||||
/// higher priority is a hint to the driver that the queue should be given more processing time.
|
||||
/// As this is only a hint, different drivers may handle this value differently and there are no
|
||||
/// guarantees about its behavior.
|
||||
/// higher priority is a hint to the driver that the queue should be given more processing
|
||||
/// time. As this is only a hint, different drivers may handle this value differently and
|
||||
/// there are no guarantees about its behavior.
|
||||
///
|
||||
/// The default value is a single queue with a priority of 0.5.
|
||||
pub queues: Vec<f32>,
|
||||
|
@ -2286,8 +2286,8 @@ impl PhysicalDevice {
|
||||
})
|
||||
}
|
||||
|
||||
/// Returns the combinations of format and color space that are supported by the physical device
|
||||
/// for the given surface.
|
||||
/// Returns the combinations of format and color space that are supported by the physical
|
||||
/// device for the given surface.
|
||||
///
|
||||
/// The results of this function are cached, so that future calls with the same arguments
|
||||
/// do not need to make a call to the Vulkan API again.
|
||||
@ -3073,8 +3073,8 @@ impl PhysicalDevice {
|
||||
) != 0
|
||||
}
|
||||
|
||||
/// Queries whether the physical device supports presenting to Win32 surfaces from queues of the
|
||||
/// given queue family.
|
||||
/// Queries whether the physical device supports presenting to Win32 surfaces from queues of
|
||||
/// the given queue family.
|
||||
#[inline]
|
||||
pub fn win32_presentation_support(
|
||||
&self,
|
||||
|
@ -453,7 +453,8 @@ impl<'a> QueueGuard<'a> {
|
||||
/// - The semaphore must be kept alive while the command is being executed.
|
||||
/// - The semaphore must be already in the signaled state, or there must be a previously
|
||||
/// submitted operation that will signal it.
|
||||
/// - When the wait operation is executed, no other queue must be waiting on the same semaphore.
|
||||
/// - When the wait operation is executed, no other queue must be waiting on the same
|
||||
/// semaphore.
|
||||
///
|
||||
/// For every element of `present_info.swapchain_infos`:
|
||||
/// - `swapchain` must be kept alive while the command is being executed.
|
||||
@ -461,8 +462,8 @@ impl<'a> QueueGuard<'a> {
|
||||
/// operation must happen-after the acquire operation.
|
||||
/// - The swapchain image indicated by `swapchain` and `image_index` must be in the
|
||||
/// [`ImageLayout::PresentSrc`] layout when the presentation operation is executed.
|
||||
/// - The swapchain image indicated by `swapchain` and `image_index` must not be accessed
|
||||
/// after this function is called, until it is acquired again.
|
||||
/// - The swapchain image indicated by `swapchain` and `image_index` must not be accessed after
|
||||
/// this function is called, until it is acquired again.
|
||||
/// - If `present_id` is `Some`, then it must be greater than any present ID previously used
|
||||
/// for the same swapchain.
|
||||
///
|
||||
@ -709,8 +710,8 @@ impl<'a> QueueGuard<'a> {
|
||||
/// - If the command buffer's `usage` is [`CommandBufferUsage::MultipleSubmit`], then it must
|
||||
/// not be currently submitted and not yet completed.
|
||||
/// - If a recorded command performs a queue family transfer acquire operation, then a
|
||||
/// corresponding queue family transfer release operation with matching parameters must
|
||||
/// have been previously submitted, and must happen-before it.
|
||||
/// corresponding queue family transfer release operation with matching parameters must have
|
||||
/// been previously submitted, and must happen-before it.
|
||||
/// - If a recorded command references an [`Event`], then that `Event` must not be referenced
|
||||
/// by a command that is currently executing on another queue.
|
||||
///
|
||||
@ -1350,7 +1351,8 @@ pub struct QueueFamilyProperties {
|
||||
/// If timestamps are not supported, this is `None`.
|
||||
pub timestamp_valid_bits: Option<u32>,
|
||||
|
||||
/// The minimum granularity supported for image transfers, in terms of `[width, height, depth]`.
|
||||
/// The minimum granularity supported for image transfers, in terms of `[width, height,
|
||||
/// depth]`.
|
||||
pub min_image_transfer_granularity: [u32; 3],
|
||||
}
|
||||
|
||||
|
@ -13,14 +13,14 @@
|
||||
//! # Creating surfaces that render directly to a display
|
||||
//!
|
||||
//! - Choose the `Display` that you want to render to.
|
||||
//! - Get display plane properties with [`PhysicalDevice::display_plane_properties`],
|
||||
//! and choose a display plane index that is supported with the chosen display.
|
||||
//! - Get display plane properties with [`PhysicalDevice::display_plane_properties`], and choose a
|
||||
//! display plane index that is supported with the chosen display.
|
||||
//! - Choose a `DisplayMode`, which is the combination of a display, a resolution and a refresh
|
||||
//! rate. You can enumerate the modes available on a display with
|
||||
//! [`Display::display_mode_properties`], or create your own mode.
|
||||
//! A display can show multiple planes in a stacking fashion.
|
||||
//! - Create a `Surface` object with `Surface::from_display_plane`,
|
||||
//! and pass the chosen `DisplayMode` and display plane index.
|
||||
//! [`Display::display_mode_properties`], or create your own mode. A display can show multiple
|
||||
//! planes in a stacking fashion.
|
||||
//! - Create a `Surface` object with `Surface::from_display_plane`, and pass the chosen
|
||||
//! `DisplayMode` and display plane index.
|
||||
|
||||
use crate::{
|
||||
cache::{OnceCache, WeakArcOnceCache},
|
||||
@ -125,7 +125,8 @@ impl Display {
|
||||
self.plane_reorder_possible
|
||||
}
|
||||
|
||||
/// Returns whether the content of the display is buffered internally, and therefore persistent.
|
||||
/// Returns whether the content of the display is buffered internally, and therefore
|
||||
/// persistent.
|
||||
#[inline]
|
||||
pub fn persistent_content(&self) -> bool {
|
||||
self.persistent_content
|
||||
|
@ -1,16 +1,16 @@
|
||||
//! All the formats supported by Vulkan.
|
||||
//!
|
||||
//! A format is mostly used to describe the texel data of an image. However, formats also show up in
|
||||
//! a few other places, most notably to describe the format of vertex buffers.
|
||||
//! A format is mostly used to describe the texel data of an image. However, formats also show up
|
||||
//! in a few other places, most notably to describe the format of vertex buffers.
|
||||
//!
|
||||
//! # Format support
|
||||
//!
|
||||
//! Not all formats are supported by every device. Those that devices do support may only be
|
||||
//! supported for certain use cases. It is an error to use a format where it is not supported, but
|
||||
//! you can query a device beforehand for its support by calling `format_properties` on the physical
|
||||
//! device. You can use this to select a usable format from one or more suitable alternatives.
|
||||
//! Some formats are required to be always supported for a particular usage. These are listed in the
|
||||
//! [tables in the Vulkan specification](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/chap43.html#features-required-format-support).
|
||||
//! you can query a device beforehand for its support by calling `format_properties` on the
|
||||
//! physical device. You can use this to select a usable format from one or more suitable
|
||||
//! alternatives. Some formats are required to be always supported for a particular usage. These
|
||||
//! are listed in the [tables in the Vulkan specification](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/chap43.html#features-required-format-support).
|
||||
//!
|
||||
//! # Special format types
|
||||
//!
|
||||
@ -27,8 +27,8 @@
|
||||
//!
|
||||
//! Depth/stencil formats deviate from the others in a few more ways. Their data representation is
|
||||
//! considered opaque, meaning that they do not have a fixed layout in memory nor a fixed size per
|
||||
//! texel. They also have special limitations in several operations such as copying; a depth/stencil
|
||||
//! format is not compatible with any other format, only with itself.
|
||||
//! texel. They also have special limitations in several operations such as copying; a
|
||||
//! depth/stencil format is not compatible with any other format, only with itself.
|
||||
//!
|
||||
//! ## Block-compressed formats
|
||||
//!
|
||||
@ -59,10 +59,10 @@
|
||||
//! requires it.
|
||||
//!
|
||||
//! Many YCbCr formats make use of **chroma subsampling**. This is a technique whereby the two
|
||||
//! chroma components are encoded using a lower resolution than the luma component. The human eye is
|
||||
//! less sensitive to color detail than to detail in brightness, so this allows more detail to be
|
||||
//! encoded in less data. Chroma subsampling is indicated with one of three numbered suffixes in a
|
||||
//! format name:
|
||||
//! chroma components are encoded using a lower resolution than the luma component. The human eye
|
||||
//! is less sensitive to color detail than to detail in brightness, so this allows more detail to
|
||||
//! be encoded in less data. Chroma subsampling is indicated with one of three numbered suffixes in
|
||||
//! a format name:
|
||||
//! - `444` indicates a YCbCr format without chroma subsampling. All components have the same
|
||||
//! resolution.
|
||||
//! - `422` indicates horizontal chroma subsampling. The horizontal resolution of the chroma
|
||||
@ -74,9 +74,9 @@
|
||||
//! of storing the components of a single texel together in memory, the components are separated
|
||||
//! into *planes*, which act like independent images. In 3-plane formats, the planes hold the Y,
|
||||
//! Cb and Cr components respectively, while in 2-plane formats, Cb and Cr are combined into a
|
||||
//! two-component plane. Where chroma subsampling is applied, plane 0 has the full resolution, while
|
||||
//! planes 1 and 2 have reduced resolution. Effectively, they are standalone images with half the
|
||||
//! resolution of the original.
|
||||
//! two-component plane. Where chroma subsampling is applied, plane 0 has the full resolution,
|
||||
//! while planes 1 and 2 have reduced resolution. Effectively, they are standalone images with half
|
||||
//! the resolution of the original.
|
||||
//!
|
||||
//! The texels of multi-planar images cannot be accessed individually, for example to copy or blit,
|
||||
//! since the components of each texel are split across the planes. Instead, you must access each
|
||||
@ -276,8 +276,8 @@ pub enum NumericFormat {
|
||||
SSCALED,
|
||||
/// Unsigned integer that is converted to a floating-point value directly.
|
||||
USCALED,
|
||||
/// Unsigned integer where R, G, B components represent a normalized floating-point value in the
|
||||
/// sRGB color space, while the A component is a simple normalized value as in `UNORM`.
|
||||
/// Unsigned integer where R, G, B components represent a normalized floating-point value in
|
||||
/// the sRGB color space, while the A component is a simple normalized value as in `UNORM`.
|
||||
SRGB,
|
||||
}
|
||||
|
||||
|
@ -1327,8 +1327,7 @@ pub fn max_mip_levels(extent: [u32; 3]) -> u32 {
|
||||
///
|
||||
/// # Panics
|
||||
///
|
||||
/// - In debug mode, panics if `extent` contains 0.
|
||||
/// In release, returns an unspecified value.
|
||||
/// - In debug mode, panics if `extent` contains 0. In release, returns an unspecified value.
|
||||
#[inline]
|
||||
pub fn mip_level_extent(extent: [u32; 3], level: u32) -> Option<[u32; 3]> {
|
||||
if level == 0 {
|
||||
|
@ -19,8 +19,8 @@
|
||||
//!
|
||||
//! It is possible to provide a *bias* to the base LOD value, which is simply added to it.
|
||||
//! An LOD bias can be provided both in the sampler object and as part of the sampling operation in
|
||||
//! the shader, and are combined by addition to produce the final bias value, which is then added to
|
||||
//! the base LOD.
|
||||
//! the shader, and are combined by addition to produce the final bias value, which is then added
|
||||
//! to the base LOD.
|
||||
//!
|
||||
//! Once LOD bias has been applied, the resulting value may be *clamped* to a minimum and maximum
|
||||
//! value to provide the final LOD. A maximum may be specified by the sampler, while a minimum
|
||||
@ -629,7 +629,8 @@ pub struct SamplerCreateInfo {
|
||||
/// [`max_sampler_lod_bias`](crate::device::Properties::max_sampler_lod_bias) limit of the
|
||||
/// device.
|
||||
///
|
||||
/// On [portability subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// On [portability
|
||||
/// subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// devices, if `mip_lod_bias` is not `0.0`, the
|
||||
/// [`sampler_mip_lod_bias`](crate::device::Features::sampler_mip_lod_bias)
|
||||
/// feature must be enabled on the device.
|
||||
@ -640,8 +641,8 @@ pub struct SamplerCreateInfo {
|
||||
/// Whether anisotropic texel filtering is enabled (`Some`), and the maximum anisotropy value
|
||||
/// to use if it is enabled.
|
||||
///
|
||||
/// Anisotropic filtering is a special filtering mode that takes into account the differences in
|
||||
/// scaling between the horizontal and vertical framebuffer axes.
|
||||
/// Anisotropic filtering is a special filtering mode that takes into account the differences
|
||||
/// in scaling between the horizontal and vertical framebuffer axes.
|
||||
///
|
||||
/// If set to `Some`, the [`sampler_anisotropy`](crate::device::Features::sampler_anisotropy)
|
||||
/// feature must be enabled on the device, the provided maximum value must not exceed the
|
||||
@ -657,15 +658,16 @@ pub struct SamplerCreateInfo {
|
||||
/// Depth comparison is an alternative mode for samplers that can be used in combination with
|
||||
/// image views specifying the depth aspect. Instead of returning a value that is sampled from
|
||||
/// the image directly, a comparison operation is applied between the sampled value and a
|
||||
/// reference value that is specified as part of the operation. The result is binary: 1.0 if the
|
||||
/// operation returns `true`, 0.0 if it returns `false`.
|
||||
/// reference value that is specified as part of the operation. The result is binary: 1.0 if
|
||||
/// the operation returns `true`, 0.0 if it returns `false`.
|
||||
///
|
||||
/// If set to `Some`, the `reduction_mode` must be set to
|
||||
/// [`WeightedAverage`](SamplerReductionMode::WeightedAverage).
|
||||
///
|
||||
/// On [portability subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// devices, if the sampler is going to be used as a mutable sampler (written to descriptor sets
|
||||
/// rather than being an immutable part of a descriptor set layout), the
|
||||
/// On [portability
|
||||
/// subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// devices, if the sampler is going to be used as a mutable sampler (written to descriptor
|
||||
/// sets rather than being an immutable part of a descriptor set layout), the
|
||||
/// [`mutable_comparison_samplers`](crate::device::Features::mutable_comparison_samplers)
|
||||
/// feature must be enabled on the device.
|
||||
///
|
||||
|
@ -374,8 +374,8 @@ pub struct SamplerYcbcrConversionCreateInfo {
|
||||
/// The format must support YCbCr conversions, meaning that its `FormatFeatures` must support
|
||||
/// at least one of `cosited_chroma_samples` or `midpoint_chroma_samples`.
|
||||
///
|
||||
/// If this is set to a format that has chroma subsampling (contains `422` or `420` in the name)
|
||||
/// then `component_mapping` is restricted as follows:
|
||||
/// If this is set to a format that has chroma subsampling (contains `422` or `420` in the
|
||||
/// name) then `component_mapping` is restricted as follows:
|
||||
/// - `g` must be identity swizzled.
|
||||
/// - `a` must be identity swizzled or `Zero` or `One`.
|
||||
/// - `r` and `b` must be identity swizzled or mapped to each other.
|
||||
@ -419,8 +419,8 @@ pub struct SamplerYcbcrConversionCreateInfo {
|
||||
/// The default value is [`CositedEven`](ChromaLocation::CositedEven) for both axes.
|
||||
pub chroma_offset: [ChromaLocation; 2],
|
||||
|
||||
/// For formats with chroma subsampling, specifies the filter used for reconstructing the chroma
|
||||
/// components to full resolution.
|
||||
/// For formats with chroma subsampling, specifies the filter used for reconstructing the
|
||||
/// chroma components to full resolution.
|
||||
///
|
||||
/// The `Cubic` filter is not supported. If `Linear` is used, the format must support it.
|
||||
///
|
||||
|
@ -705,14 +705,14 @@ impl RawImage {
|
||||
|
||||
/// Binds device memory to this image.
|
||||
///
|
||||
/// - If `self.flags()` does not contain `ImageCreateFlags::DISJOINT`,
|
||||
/// then `allocations` must contain exactly one element.
|
||||
/// - If `self.flags()` contains `ImageCreateFlags::DISJOINT`, and
|
||||
/// `self.tiling()` is `ImageTiling::Linear` or `ImageTiling::Optimal`, then
|
||||
/// `allocations` must contain exactly `self.format().unwrap().planes().len()` elements.
|
||||
/// - If `self.flags()` contains `ImageCreateFlags::DISJOINT`, and
|
||||
/// `self.tiling()` is `ImageTiling::DrmFormatModifier`, then
|
||||
/// `allocations` must contain exactly `self.drm_format_modifier().unwrap().1` elements.
|
||||
/// - If `self.flags()` does not contain `ImageCreateFlags::DISJOINT`, then `allocations` must
|
||||
/// contain exactly one element.
|
||||
/// - If `self.flags()` contains `ImageCreateFlags::DISJOINT`, and `self.tiling()` is
|
||||
/// `ImageTiling::Linear` or `ImageTiling::Optimal`, then `allocations` must contain exactly
|
||||
/// `self.format().unwrap().planes().len()` elements.
|
||||
/// - If `self.flags()` contains `ImageCreateFlags::DISJOINT`, and `self.tiling()` is
|
||||
/// `ImageTiling::DrmFormatModifier`, then `allocations` must contain exactly
|
||||
/// `self.drm_format_modifier().unwrap().1` elements.
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
@ -1106,14 +1106,14 @@ impl RawImage {
|
||||
|
||||
/// # Safety
|
||||
///
|
||||
/// - If `self.flags()` does not contain `ImageCreateFlags::DISJOINT`,
|
||||
/// then `allocations` must contain exactly one element.
|
||||
/// - If `self.flags()` contains `ImageCreateFlags::DISJOINT`, and
|
||||
/// `self.tiling()` is `ImageTiling::Linear` or `ImageTiling::Optimal`, then
|
||||
/// `allocations` must contain exactly `self.format().unwrap().planes().len()` elements.
|
||||
/// - If `self.flags()` contains `ImageCreateFlags::DISJOINT`, and
|
||||
/// `self.tiling()` is `ImageTiling::DrmFormatModifier`, then
|
||||
/// `allocations` must contain exactly `self.drm_format_modifier().unwrap().1` elements.
|
||||
/// - If `self.flags()` does not contain `ImageCreateFlags::DISJOINT`, then `allocations` must
|
||||
/// contain exactly one element.
|
||||
/// - If `self.flags()` contains `ImageCreateFlags::DISJOINT`, and `self.tiling()` is
|
||||
/// `ImageTiling::Linear` or `ImageTiling::Optimal`, then `allocations` must contain exactly
|
||||
/// `self.format().unwrap().planes().len()` elements.
|
||||
/// - If `self.flags()` contains `ImageCreateFlags::DISJOINT`, and `self.tiling()` is
|
||||
/// `ImageTiling::DrmFormatModifier`, then `allocations` must contain exactly
|
||||
/// `self.drm_format_modifier().unwrap().1` elements.
|
||||
#[cfg_attr(not(feature = "document_unchecked"), doc(hidden))]
|
||||
pub unsafe fn bind_memory_unchecked(
|
||||
self,
|
||||
@ -1723,11 +1723,12 @@ pub struct ImageCreateInfo {
|
||||
|
||||
/// The formats that an image view can have when it is created from this image.
|
||||
///
|
||||
/// If the list is not empty, and `flags` does not contain [`ImageCreateFlags::MUTABLE_FORMAT`],
|
||||
/// then the list must contain at most one element, otherwise any number of elements are
|
||||
/// allowed. The view formats must be compatible with `format`. If `flags` also contains
|
||||
/// [`ImageCreateFlags::BLOCK_TEXEL_VIEW_COMPATIBLE`], then the view formats can also be
|
||||
/// uncompressed formats that are merely size-compatible with `format`.
|
||||
/// If the list is not empty, and `flags` does not contain
|
||||
/// [`ImageCreateFlags::MUTABLE_FORMAT`], then the list must contain at most one element,
|
||||
/// otherwise any number of elements are allowed. The view formats must be compatible with
|
||||
/// `format`. If `flags` also contains [`ImageCreateFlags::BLOCK_TEXEL_VIEW_COMPATIBLE`],
|
||||
/// then the view formats can also be uncompressed formats that are merely size-compatible
|
||||
/// with `format`.
|
||||
///
|
||||
/// If the list is empty, then depending on `flags`, a view must have the same format as
|
||||
/// `format`, can have any compatible format, or additionally any uncompressed size-compatible
|
||||
@ -1752,7 +1753,8 @@ pub struct ImageCreateInfo {
|
||||
|
||||
/// The number of array layers to create the image with.
|
||||
///
|
||||
/// On [portability subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// On [portability
|
||||
/// subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// devices, if `samples` is not [`SampleCount::Sample1`] and `array_layers` is not 1,
|
||||
/// the [`multisample_array_image`](crate::device::Features::multisample_array_image)
|
||||
/// feature must be enabled on the device.
|
||||
@ -1767,7 +1769,8 @@ pub struct ImageCreateInfo {
|
||||
|
||||
/// The number of samples per texel that the image should use.
|
||||
///
|
||||
/// On [portability subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// On [portability
|
||||
/// subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// devices, if `samples` is not [`SampleCount::Sample1`] and `array_layers` is not 1,
|
||||
/// the [`multisample_array_image`](crate::device::Features::multisample_array_image)
|
||||
/// feature must be enabled on the device.
|
||||
|
@ -818,7 +818,8 @@ pub struct ImageViewCreateInfo {
|
||||
/// If this is set to a format that is different from the image, the image must be created with
|
||||
/// the `mutable_format` flag.
|
||||
///
|
||||
/// On [portability subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// On [portability
|
||||
/// subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// devices, if `format` does not have the same number of components and bits per component as
|
||||
/// the parent image's format, the
|
||||
/// [`image_view_format_reinterpretation`](crate::device::Features::image_view_format_reinterpretation)
|
||||
@ -829,7 +830,8 @@ pub struct ImageViewCreateInfo {
|
||||
|
||||
/// How to map components of each pixel.
|
||||
///
|
||||
/// On [portability subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// On [portability
|
||||
/// subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// devices, if `component_mapping` is not the identity mapping, the
|
||||
/// [`image_view_format_swizzle`](crate::device::Features::image_view_format_swizzle)
|
||||
/// feature must be enabled on the device.
|
||||
|
@ -392,7 +392,8 @@ pub struct DebugUtilsMessengerCallbackLabel<'a> {
|
||||
/// The name of the label.
|
||||
pub label_name: &'a str,
|
||||
|
||||
/// An RGBA color value that is associated with the label, with values in the range `0.0..=1.0`.
|
||||
/// An RGBA color value that is associated with the label, with values in the range
|
||||
/// `0.0..=1.0`.
|
||||
pub color: &'a [f32; 4],
|
||||
}
|
||||
|
||||
@ -507,7 +508,8 @@ pub struct DebugUtilsLabel {
|
||||
/// The default value is empty.
|
||||
pub label_name: String,
|
||||
|
||||
/// An RGBA color value that is associated with the label, with values in the range `0.0..=1.0`.
|
||||
/// An RGBA color value that is associated with the label, with values in the range
|
||||
/// `0.0..=1.0`.
|
||||
///
|
||||
/// If set to `[0.0; 4]`, the value is ignored.
|
||||
///
|
||||
|
@ -152,10 +152,10 @@ include!(concat!(env!("OUT_DIR"), "/instance_extensions.rs"));
|
||||
/// functions, even though they could theoretically support a higher version. You can think of it
|
||||
/// as a promise never to use any functionality from a higher version.
|
||||
///
|
||||
/// The maximum API version is not a _minimum_, so it is possible to set it to a higher version than
|
||||
/// what the instance or device inherently support. The final API version that you are able to use
|
||||
/// on an instance or device is the lower of the supported API version and the chosen maximum API
|
||||
/// version of the `Instance`.
|
||||
/// The maximum API version is not a _minimum_, so it is possible to set it to a higher version
|
||||
/// than what the instance or device inherently support. The final API version that you are able to
|
||||
/// use on an instance or device is the lower of the supported API version and the chosen maximum
|
||||
/// API version of the `Instance`.
|
||||
///
|
||||
/// Due to a quirk in how the Vulkan 1.0 specification was written, if the instance only
|
||||
/// supports Vulkan 1.0, then it is not possible to specify a maximum API version higher than 1.0.
|
||||
|
@ -27,25 +27,25 @@
|
||||
//! is suitable for your program. A [`PhysicalDevice`] represents a Vulkan-capable device that
|
||||
//! is available on the system, such as a graphics card, a software implementation, etc.
|
||||
//!
|
||||
//! 6. Create a [`Device`] and accompanying [`Queue`]s from the selected `PhysicalDevice`.
|
||||
//! The `Device` is the most important object of Vulkan, and you need one to create almost
|
||||
//! every other object. `Queue`s are created together with the `Device`, and are used to submit
|
||||
//! work to the device to make it do something.
|
||||
//! 6. Create a [`Device`] and accompanying [`Queue`]s from the selected `PhysicalDevice`. The
|
||||
//! `Device` is the most important object of Vulkan, and you need one to create almost every
|
||||
//! other object. `Queue`s are created together with the `Device`, and are used to submit work
|
||||
//! to the device to make it do something.
|
||||
//!
|
||||
//! 7. If you created a `Surface` earlier, create a [`Swapchain`]. This object contains special
|
||||
//! images that correspond to the contents of the surface. Whenever you want to
|
||||
//! change the contents (show something new to the user), you must first *acquire* one of these
|
||||
//! images from the swapchain, fill it with the new contents (by rendering, copying or any
|
||||
//! other means), and then *present* it back to the swapchain.
|
||||
//! A swapchain can become outdated if the properties of the surface change, such as when
|
||||
//! the size of the window changes. It then becomes necessary to create a new swapchain.
|
||||
//! images that correspond to the contents of the surface. Whenever you want to change the
|
||||
//! contents (show something new to the user), you must first *acquire* one of these images from
|
||||
//! the swapchain, fill it with the new contents (by rendering, copying or any other means), and
|
||||
//! then *present* it back to the swapchain. A swapchain can become outdated if the properties
|
||||
//! of the surface change, such as when the size of the window changes. It then becomes
|
||||
//! necessary to create a new swapchain.
|
||||
//!
|
||||
//! 8. Record a [*command buffer*](crate::command_buffer), containing commands that the device must
|
||||
//! execute. Then build the command buffer and submit it to a `Queue`.
|
||||
//!
|
||||
//! Many different operations can be recorded to a command buffer, such as *draw*, *compute* and
|
||||
//! *transfer* operations. To do any of these things, you will need to create several other objects,
|
||||
//! depending on your specific needs. This includes:
|
||||
//! *transfer* operations. To do any of these things, you will need to create several other
|
||||
//! objects, depending on your specific needs. This includes:
|
||||
//!
|
||||
//! - [*Buffers*] store general-purpose data on memory accessible by the device. This can include
|
||||
//! mesh data (vertices, texture coordinates etc.), lighting information, matrices, and anything
|
||||
@ -55,8 +55,7 @@
|
||||
//! as textures, depth/stencil buffers, framebuffers and as part of a swapchain.
|
||||
//!
|
||||
//! - [*Pipelines*] describe operations on the device. They include one or more [*shader*]s, small
|
||||
//! programs that the device will execute as part of a pipeline.
|
||||
//! Pipelines come in several types:
|
||||
//! programs that the device will execute as part of a pipeline. Pipelines come in several types:
|
||||
//! - A [`ComputePipeline`] describes how *dispatch* commands are to be performed.
|
||||
//! - A [`GraphicsPipeline`] describes how *draw* commands are to be performed.
|
||||
//!
|
||||
@ -65,11 +64,11 @@
|
||||
//! more of these layouts in turn forms a [`PipelineLayout`], which is used when creating a
|
||||
//! pipeline object.
|
||||
//!
|
||||
//! - For more complex, multi-stage draw operations, you can create a [`RenderPass`] object.
|
||||
//! This object describes the stages, known as subpasses, that draw operations consist of,
|
||||
//! how they interact with one another, and which types of images are available in each subpass.
|
||||
//! You must also create a [`Framebuffer`], which contains the image objects that are to be used
|
||||
//! in a render pass.
|
||||
//! - For more complex, multi-stage draw operations, you can create a [`RenderPass`] object. This
|
||||
//! object describes the stages, known as subpasses, that draw operations consist of, how they
|
||||
//! interact with one another, and which types of images are available in each subpass. You must
|
||||
//! also create a [`Framebuffer`], which contains the image objects that are to be used in a
|
||||
//! render pass.
|
||||
//!
|
||||
//! # `_unchecked` functions
|
||||
//!
|
||||
|
@ -349,7 +349,6 @@ impl DynamicLibraryLoader {
|
||||
/// # Safety
|
||||
///
|
||||
/// - The dynamic library must be a valid Vulkan implementation.
|
||||
///
|
||||
pub unsafe fn new(path: impl AsRef<Path>) -> Result<DynamicLibraryLoader, LoadingError> {
|
||||
let vk_lib = Library::new(path.as_ref()).map_err(LoadingError::LibraryLoadFailure)?;
|
||||
|
||||
|
@ -154,7 +154,7 @@
|
||||
//! Now if we free B and D, since these are done out of order, we will be left with holes between
|
||||
//! the other allocations, and we won't be able to fit allocation E anywhere:
|
||||
//!
|
||||
//! ```plain
|
||||
//! ```plain
|
||||
//! +-----+-------------------+-------+-----------+-- - - --+ +-------------------------+
|
||||
//! | | | | | | ? | |
|
||||
//! | A | | C | | ••• | <== | E |
|
||||
|
@ -57,8 +57,8 @@ use std::{
|
||||
/// this trait, but if you **must**:
|
||||
///
|
||||
/// - `allocate` must return a memory block that is in bounds of the region.
|
||||
/// - `allocate` must return a memory block that doesn't alias any other currently allocated
|
||||
/// memory blocks:
|
||||
/// - `allocate` must return a memory block that doesn't alias any other currently allocated memory
|
||||
/// blocks:
|
||||
/// - Two currently allocated memory blocks must not share any memory locations, meaning that the
|
||||
/// intersection of the byte ranges of the two memory blocks must be empty.
|
||||
/// - Two neighboring currently allocated memory blocks must not share any [page] whose size is
|
||||
|
@ -1151,15 +1151,15 @@ pub enum MemoryImportInfo {
|
||||
///
|
||||
/// - `handle` must be a valid Windows handle.
|
||||
/// - Vulkan will not take ownership of `handle`.
|
||||
/// - If `handle_type` is [`ExternalMemoryHandleType::OpaqueWin32`], it owns a reference
|
||||
/// to the underlying resource and must eventually be closed by the caller.
|
||||
/// - If `handle_type` is [`ExternalMemoryHandleType::OpaqueWin32`], it owns a reference to the
|
||||
/// underlying resource and must eventually be closed by the caller.
|
||||
/// - If `handle_type` is [`ExternalMemoryHandleType::OpaqueWin32Kmt`], it does not own a
|
||||
/// reference to the underlying resource.
|
||||
/// - `handle` must be created by the Vulkan API.
|
||||
/// - [`MemoryAllocateInfo::allocation_size`] and [`MemoryAllocateInfo::memory_type_index`]
|
||||
/// must match those of the original memory allocation.
|
||||
/// - If the original memory allocation used [`MemoryAllocateInfo::dedicated_allocation`],
|
||||
/// the imported one must also use it, and the associated buffer or image must be defined
|
||||
/// - If the original memory allocation used [`MemoryAllocateInfo::dedicated_allocation`], the
|
||||
/// imported one must also use it, and the associated buffer or image must be defined
|
||||
/// identically to the original.
|
||||
Win32 {
|
||||
handle_type: ExternalMemoryHandleType,
|
||||
@ -1889,7 +1889,8 @@ impl MappedDeviceMemory {
|
||||
/// # Safety
|
||||
///
|
||||
/// - If there are memory writes by the GPU that have not been propagated into the CPU cache,
|
||||
/// then there must not be any references in Rust code to the specified `range` of the memory.
|
||||
/// then there must not be any references in Rust code to the specified `range` of the
|
||||
/// memory.
|
||||
///
|
||||
/// # Panics
|
||||
///
|
||||
@ -1942,8 +1943,8 @@ impl MappedDeviceMemory {
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
/// - There must be no operations pending or executing in a GPU queue, that access the specified
|
||||
/// `range` of the memory.
|
||||
/// - There must be no operations pending or executing in a GPU queue, that access the
|
||||
/// specified `range` of the memory.
|
||||
///
|
||||
/// # Panics
|
||||
///
|
||||
@ -1992,8 +1993,8 @@ impl MappedDeviceMemory {
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
/// - While the returned reference exists, there must not be any mutable references in Rust code
|
||||
/// to the same memory.
|
||||
/// - While the returned reference exists, there must not be any mutable references in Rust
|
||||
/// code to the same memory.
|
||||
/// - While the returned reference exists, there must be no operations pending or executing in
|
||||
/// a GPU queue, that write to the same memory.
|
||||
///
|
||||
|
@ -805,7 +805,8 @@ pub struct SparseBufferMemoryBind {
|
||||
pub memory: Option<(Arc<DeviceMemory>, DeviceSize)>,
|
||||
}
|
||||
|
||||
/// Parameters for a single sparse bind operation on parts of an image with an opaque memory layout.
|
||||
/// Parameters for a single sparse bind operation on parts of an image with an opaque memory
|
||||
/// layout.
|
||||
///
|
||||
/// This type of sparse bind should be used for mip tail regions, the metadata aspect, and for the
|
||||
/// normal regions of images that do not have the `sparse_residency` flag set.
|
||||
|
@ -9,8 +9,9 @@
|
||||
//! doesn't exist.
|
||||
//!
|
||||
//! Once that is done, you can extract the data from the cache and store it. See the documentation
|
||||
//! of [`get_data`](crate::pipeline::cache::PipelineCache::get_data) for example of how to store the data
|
||||
//! on the disk, and [`new`](crate::pipeline::cache::PipelineCache::new) for how to reload it.
|
||||
//! of [`get_data`](crate::pipeline::cache::PipelineCache::get_data) for example of how to store
|
||||
//! the data on the disk, and [`new`](crate::pipeline::cache::PipelineCache::new) for how to reload
|
||||
//! it.
|
||||
|
||||
use crate::{
|
||||
device::{Device, DeviceOwned},
|
||||
@ -236,7 +237,6 @@ impl PipelineCache {
|
||||
/// Merges other pipeline caches into this one.
|
||||
///
|
||||
/// It is `self` that is modified here. The pipeline caches passed as parameter are untouched.
|
||||
///
|
||||
// FIXME: vkMergePipelineCaches is not thread safe for the destination cache
|
||||
// TODO: write example
|
||||
pub fn merge<'a>(
|
||||
|
@ -7,11 +7,11 @@
|
||||
//! of pipeline. While it theoretically possible to perform graphics operations entirely in a
|
||||
//! compute pipeline, a graphics pipeline is better suited to that task.
|
||||
//!
|
||||
//! A compute pipeline is relatively simple to create, requiring only a pipeline layout and a single
|
||||
//! shader, the *compute shader*. The compute shader is the actual program that performs the work.
|
||||
//! Once created, you can execute a compute pipeline by *binding* it in a command buffer, binding
|
||||
//! any descriptor sets and/or push constants that the pipeline needs, and then issuing a `dispatch`
|
||||
//! command on the command buffer.
|
||||
//! A compute pipeline is relatively simple to create, requiring only a pipeline layout and a
|
||||
//! single shader, the *compute shader*. The compute shader is the actual program that performs the
|
||||
//! work. Once created, you can execute a compute pipeline by *binding* it in a command buffer,
|
||||
//! binding any descriptor sets and/or push constants that the pipeline needs, and then issuing a
|
||||
//! `dispatch` command on the command buffer.
|
||||
|
||||
use super::{PipelineCreateFlags, PipelineShaderStageCreateInfo};
|
||||
use crate::{
|
||||
|
@ -41,8 +41,8 @@ pub struct ColorBlendState {
|
||||
/// The default value is `None`.
|
||||
pub logic_op: Option<LogicOp>,
|
||||
|
||||
/// Sets the blend and output state for each color attachment. The number of elements must match
|
||||
/// the number of color attachments in the subpass.
|
||||
/// Sets the blend and output state for each color attachment. The number of elements must
|
||||
/// match the number of color attachments in the subpass.
|
||||
///
|
||||
/// If there are multiple elements, and the `blend` and `color_write_mask` members of each
|
||||
/// element differ, then the [`independent_blend`](crate::device::Features::independent_blend)
|
||||
|
@ -75,8 +75,8 @@ impl DepthStencilState {
|
||||
Self::default()
|
||||
}
|
||||
|
||||
/// Creates a `DepthStencilState` with a `Less` depth test, `depth_write` set to true, and other
|
||||
/// tests disabled.
|
||||
/// Creates a `DepthStencilState` with a `Less` depth test, `depth_write` set to true, and
|
||||
/// other tests disabled.
|
||||
#[inline]
|
||||
#[deprecated(since = "0.34.0", note = "use `DepthState::simple` instead")]
|
||||
pub fn simple_depth_test() -> Self {
|
||||
@ -301,7 +301,8 @@ pub struct StencilOpState {
|
||||
/// considered to pass if the `compare_op` between the stencil buffer value and this reference
|
||||
/// value yields true.
|
||||
///
|
||||
/// On [portability subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// On [portability
|
||||
/// subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// devices, if culling is disabled, and the `reference` values of the front and back face
|
||||
/// are not equal, then the
|
||||
/// [`separate_stencil_mask_ref`](crate::device::Features::separate_stencil_mask_ref)
|
||||
|
@ -12,10 +12,9 @@
|
||||
//! Due to the parallel nature of a GPU, no strict ordering guarantees may exist.
|
||||
//!
|
||||
//! Graphics pipelines come in two different forms:
|
||||
//! - *Primitive shading* graphics pipelines, which contain a vertex shader, vertex input and
|
||||
//! input assembly state, and optionally tessellation shaders and/or a geometry shader.
|
||||
//! - *Mesh shading* graphics pipelines, which contain a mesh shader, and optionally a
|
||||
//! task shader.
|
||||
//! - *Primitive shading* graphics pipelines, which contain a vertex shader, vertex input and input
|
||||
//! assembly state, and optionally tessellation shaders and/or a geometry shader.
|
||||
//! - *Mesh shading* graphics pipelines, which contain a mesh shader, and optionally a task shader.
|
||||
//!
|
||||
//! These types differ in the operations that are performed in the first half of the pipeline,
|
||||
//! but share a common second half. The type of a graphics pipeline is determined by whether
|
||||
@ -39,8 +38,8 @@
|
||||
//! 1. (Optional) Task shader invocations: the task shader is run once for each workgroup in the
|
||||
//! draw command. The task shader then spawns one or more mesh shader invocations.
|
||||
//! 2. Mesh shader invocations: the mesh shader is run, either once each time it is spawned by a
|
||||
//! task shader, or if there is no task shader, once for each workgroup in the draw command.
|
||||
//! The mesh shader outputs a list of primitives (triangles etc).
|
||||
//! task shader, or if there is no task shader, once for each workgroup in the draw command. The
|
||||
//! mesh shader outputs a list of primitives (triangles etc).
|
||||
//!
|
||||
//! Mesh shading pipelines do not receive any vertex input; their input data is supplied entirely
|
||||
//! from resources bound via descriptor sets, in combination with the x, y and z coordinates of
|
||||
@ -54,8 +53,8 @@
|
||||
//! - Clipping primitives to the view frustum and user-defined clipping planes.
|
||||
//! - Perspective division.
|
||||
//! - Viewport mapping.
|
||||
//! 2. Rasterization: converting primitives into a two-dimensional representation. Primitives may be
|
||||
//! discarded depending on their orientation, and are then converted into a collection of
|
||||
//! 2. Rasterization: converting primitives into a two-dimensional representation. Primitives may
|
||||
//! be discarded depending on their orientation, and are then converted into a collection of
|
||||
//! fragments that are processed further.
|
||||
//! 3. Fragment operations. These include invocations of the fragment shader, which generates the
|
||||
//! values to be written to the color attachment. Various testing and discarding operations can
|
||||
@ -73,8 +72,8 @@
|
||||
//!
|
||||
//! # Using a graphics pipeline
|
||||
//!
|
||||
//! Once a graphics pipeline has been created, you can execute it by first *binding* it in a command
|
||||
//! buffer, binding the necessary vertex buffers, binding any descriptor sets, setting push
|
||||
//! Once a graphics pipeline has been created, you can execute it by first *binding* it in a
|
||||
//! command buffer, binding the necessary vertex buffers, binding any descriptor sets, setting push
|
||||
//! constants, and setting any dynamic state that the pipeline may need. Then you issue a `draw`
|
||||
//! command.
|
||||
|
||||
@ -1093,7 +1092,8 @@ impl GraphicsPipeline {
|
||||
input_assembly_state,
|
||||
tessellation_state,
|
||||
viewport_state,
|
||||
rasterization_state: rasterization_state.unwrap(), // Can be None for pipeline libraries, but we don't support that yet
|
||||
// Can be None for pipeline libraries, but we don't support that yet
|
||||
rasterization_state: rasterization_state.unwrap(),
|
||||
multisample_state,
|
||||
depth_stencil_state,
|
||||
color_blend_state,
|
||||
|
@ -10,9 +10,9 @@ use crate::{
|
||||
/// State of the multisampling.
|
||||
#[derive(Copy, Clone, Debug)]
|
||||
pub struct MultisampleState {
|
||||
/// The number of rasterization samples to take per pixel. The GPU will pick this many different
|
||||
/// locations within each pixel and assign to each of these locations a different depth value.
|
||||
/// The depth and stencil test will then be run for each sample.
|
||||
/// The number of rasterization samples to take per pixel. The GPU will pick this many
|
||||
/// different locations within each pixel and assign to each of these locations a different
|
||||
/// depth value. The depth and stencil test will then be run for each sample.
|
||||
///
|
||||
/// The default value is [`SampleCount::Sample1`].
|
||||
pub rasterization_samples: SampleCount,
|
||||
@ -21,9 +21,9 @@ pub struct MultisampleState {
|
||||
/// fragment shader.
|
||||
///
|
||||
/// If the value is 1.0, then all sub-pixel samples will run
|
||||
/// through the shader and get a different value. If the value is 0.5, about half of the samples
|
||||
/// will run through the shader and the other half will get their values from the ones which
|
||||
/// went through the shader.
|
||||
/// through the shader and get a different value. If the value is 0.5, about half of the
|
||||
/// samples will run through the shader and the other half will get their values from the
|
||||
/// ones which went through the shader.
|
||||
///
|
||||
/// If set to `Some`, the [`sample_rate_shading`](crate::device::Features::sample_rate_shading)
|
||||
/// feature must be enabled on the device.
|
||||
@ -39,9 +39,9 @@ pub struct MultisampleState {
|
||||
|
||||
/// Controls whether the alpha value of the fragment will be used in an implementation-defined
|
||||
/// way to determine which samples get disabled or not. For example if the alpha value is 0.5,
|
||||
/// then about half of the samples will be discarded. If you render to a multisample image, this
|
||||
/// means that the color will end up being mixed with whatever color was underneath, which gives
|
||||
/// the same effect as alpha blending.
|
||||
/// then about half of the samples will be discarded. If you render to a multisample image,
|
||||
/// this means that the color will end up being mixed with whatever color was underneath,
|
||||
/// which gives the same effect as alpha blending.
|
||||
///
|
||||
/// The default value is `false`.
|
||||
pub alpha_to_coverage_enable: bool,
|
||||
|
@ -15,23 +15,23 @@
|
||||
//! components in a location, even if not all bits are actually used.
|
||||
//!
|
||||
//! A variable may take up fewer than four components. For example, a single `float` takes up only
|
||||
//! one component, a `vec2` takes up two, and so on. Using the `component` layout qualifier in GLSL,
|
||||
//! it is possible to fit multiple variables into a single four-component location slot, as long
|
||||
//! as the components of each variable don't overlap.
|
||||
//! one component, a `vec2` takes up two, and so on. Using the `component` layout qualifier in
|
||||
//! GLSL, it is possible to fit multiple variables into a single four-component location slot, as
|
||||
//! long as the components of each variable don't overlap.
|
||||
//!
|
||||
//! If the input variable is an array, then it takes up a series of consecutive locations. Each
|
||||
//! element of the array always starts at a new location, regardless of whether there is still room
|
||||
//! in the previous one. So, for example, an array of three `vec2` takes three locations, since
|
||||
//! `vec2` alone needs one location. An array can be decorated with the `component` qualifier as
|
||||
//! well; this is equivalent to applying the qualifier to every element of the array. If elements do
|
||||
//! not use all components in their locations, those free components can be filled with additional
|
||||
//! variables, just like for non-array types.
|
||||
//! well; this is equivalent to applying the qualifier to every element of the array. If elements
|
||||
//! do not use all components in their locations, those free components can be filled with
|
||||
//! additional variables, just like for non-array types.
|
||||
//!
|
||||
//! Matrices are laid out as if they were an array of column vectors. Thus, a `mat4x3` is laid out
|
||||
//! as an array of four `vec3`s, `mat2x4` as two `vec4`s. As with individual vectors, each column of
|
||||
//! the matrix uses up as many components of its location as there are rows in the matrix, and the
|
||||
//! remaining components are available for additional variables as described above. However, it is
|
||||
//! not possible to use the `component` qualifier on a matrix.
|
||||
//! as an array of four `vec3`s, `mat2x4` as two `vec4`s. As with individual vectors, each column
|
||||
//! of the matrix uses up as many components of its location as there are rows in the matrix, and
|
||||
//! the remaining components are available for additional variables as described above. However, it
|
||||
//! is not possible to use the `component` qualifier on a matrix.
|
||||
//!
|
||||
//! If a 64-bit value is to be passed to a shader, it will take up two adjacent components. Vectors
|
||||
//! of 64-bit values are correspondingly twice as large: `dvec2` takes up all four components of a
|
||||
@ -41,8 +41,8 @@
|
||||
//!
|
||||
//! # Input attributes
|
||||
//!
|
||||
//! An input attribute is a mapping between data in a vertex buffer and the locations and components
|
||||
//! of the vertex shader.
|
||||
//! An input attribute is a mapping between data in a vertex buffer and the locations and
|
||||
//! components of the vertex shader.
|
||||
//!
|
||||
//! Input attributes are assigned on a per-location basis; it is not possible to assign attributes
|
||||
//! to individual components. Instead, each attribute specifies up to four values to be read from
|
||||
@ -603,7 +603,8 @@ pub struct VertexInputAttributeDescription {
|
||||
|
||||
/// Number of bytes between the start of a vertex buffer element and the location of attribute.
|
||||
///
|
||||
/// On [portability subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// On [portability
|
||||
/// subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// devices, if the sum of `offset + format.block_size()` is greater than the `stride` of
|
||||
/// `binding`, the
|
||||
/// [`vertex_attribute_access_beyond_stride`](crate::device::Features::vertex_attribute_access_beyond_stride)
|
||||
|
@ -29,15 +29,14 @@
|
||||
//! Vulkan allows four different setups:
|
||||
//!
|
||||
//! - The state of both the viewports and scissor boxes is known at pipeline creation.
|
||||
//! - The state of viewports is known at pipeline creation, but the state of scissor boxes is
|
||||
//! only known when submitting the draw command.
|
||||
//! - The state of scissor boxes is known at pipeline creation, but the state of viewports is
|
||||
//! only known when submitting the draw command.
|
||||
//! - The state of both the viewports and scissor boxes is only known when submitting the
|
||||
//! draw command.
|
||||
//! - The state of viewports is known at pipeline creation, but the state of scissor boxes is only
|
||||
//! known when submitting the draw command.
|
||||
//! - The state of scissor boxes is known at pipeline creation, but the state of viewports is only
|
||||
//! known when submitting the draw command.
|
||||
//! - The state of both the viewports and scissor boxes is only known when submitting the draw
|
||||
//! command.
|
||||
//!
|
||||
//! In all cases the number of viewports and scissor boxes must be the same.
|
||||
//!
|
||||
|
||||
use crate::{device::Device, Requires, RequiresAllOf, RequiresOneOf, ValidationError, Version};
|
||||
use smallvec::{smallvec, SmallVec};
|
||||
|
@ -41,9 +41,9 @@
|
||||
//!
|
||||
//! - An incompatible definition of `Pc` invalidates all bound descriptor sets.
|
||||
//! - An incompatible definition of `DsN` invalidates all bound descriptor sets *N* and higher.
|
||||
//! - If *N* is the highest set being assigned in a bind command, and it and all lower sets
|
||||
//! have compatible definitions, including the push constants, then descriptor sets above *N*
|
||||
//! remain valid.
|
||||
//! - If *N* is the highest set being assigned in a bind command, and it and all lower sets have
|
||||
//! compatible definitions, including the push constants, then descriptor sets above *N* remain
|
||||
//! valid.
|
||||
//!
|
||||
//! [`RecordingCommandBuffer`] keeps track of this state and will automatically remove descriptor
|
||||
//! sets that have been invalidated by incompatible layouts in subsequent binding commands.
|
||||
|
@ -163,7 +163,8 @@ impl QueryPool {
|
||||
/// enough to hold the data.
|
||||
///
|
||||
/// `true` is returned if every result was available and written to the buffer. `false`
|
||||
/// is returned if some results were not yet available; these will not be written to the buffer.
|
||||
/// is returned if some results were not yet available; these will not be written to the
|
||||
/// buffer.
|
||||
///
|
||||
/// See also [`copy_query_pool_results`].
|
||||
///
|
||||
|
@ -1,9 +1,7 @@
|
||||
// Most of the code in this module comes from the rangemap crate, which is licensed under either of
|
||||
// - Apache License, Version 2.0
|
||||
// (https://github.com/jeffparsons/rangemap/blob/master/LICENSE-APACHE or
|
||||
// http://www.apache.org/licenses/LICENSE-2.0)
|
||||
// - MIT (https://github.com/jeffparsons/rangemap/blob/master/LICENSE-MIT or
|
||||
// http://opensource.org/licenses/MIT)
|
||||
// - Apache License, Version 2.0 (https://github.com/jeffparsons/rangemap/blob/master/LICENSE-APACHE
|
||||
// or http://www.apache.org/licenses/LICENSE-2.0)
|
||||
// - MIT (https://github.com/jeffparsons/rangemap/blob/master/LICENSE-MIT or http://opensource.org/licenses/MIT)
|
||||
// at your option.
|
||||
//
|
||||
// The following changes were made:
|
||||
@ -892,9 +890,7 @@ mod tests {
|
||||
assert_eq!(range_map.to_vec(), vec![]);
|
||||
}
|
||||
|
||||
///
|
||||
/// impl Debug
|
||||
///
|
||||
// impl Debug
|
||||
|
||||
#[test]
|
||||
fn map_debug_repr_looks_right() {
|
||||
|
@ -29,7 +29,8 @@ impl<T: Ord + Copy> RangeSet<T> {
|
||||
|
||||
/// Inserts the elements of `range` into the set.
|
||||
pub fn insert(&mut self, elements: Range<T>) {
|
||||
// Find the first range that is not less than `elements`, and the first range that is greater.
|
||||
// Find the first range that is not less than `elements`, and the first range that is
|
||||
// greater.
|
||||
let index_start = self
|
||||
.0
|
||||
.iter()
|
||||
|
@ -6,8 +6,8 @@
|
||||
//!
|
||||
//! - A *render pass* describes the overall process of drawing a frame. It is subdivided into one
|
||||
//! or more subpasses.
|
||||
//! - A *framebuffer* contains the list of image views that are attached during the drawing of
|
||||
//! each subpass.
|
||||
//! - A *framebuffer* contains the list of image views that are attached during the drawing of each
|
||||
//! subpass.
|
||||
//!
|
||||
//! Render passes are typically created at initialization only (for example during a loading
|
||||
//! screen) because they can be costly, while framebuffers can be created and destroyed either at
|
||||
@ -47,8 +47,8 @@ mod framebuffer;
|
||||
/// A render pass in Vulkan is made up of three parts:
|
||||
/// - A list of attachments, which are image views that are inputs, outputs or intermediate stages
|
||||
/// in the rendering process.
|
||||
/// - One or more subpasses, which are the steps in which the rendering process, takes place,
|
||||
/// and the attachments that are used for each step.
|
||||
/// - One or more subpasses, which are the steps in which the rendering process, takes place, and
|
||||
/// the attachments that are used for each step.
|
||||
/// - Dependencies, which describe how the input and output data of each subpass is to be passed
|
||||
/// from one subpass to the next.
|
||||
///
|
||||
@ -2141,9 +2141,9 @@ vulkan_bitflags! {
|
||||
|
||||
/// Describes one of the subpasses of a render pass.
|
||||
///
|
||||
/// A subpass can use zero or more attachments of various types. Attachment types of which there can
|
||||
/// be multiple are listed in a `Vec` in this structure. The index in these `Vec`s corresponds to
|
||||
/// the index used for that attachment type in the shader.
|
||||
/// A subpass can use zero or more attachments of various types. Attachment types of which there
|
||||
/// can be multiple are listed in a `Vec` in this structure. The index in these `Vec`s corresponds
|
||||
/// to the index used for that attachment type in the shader.
|
||||
///
|
||||
/// If a particular index is not used in the shader, it can be set to `None` in this structure.
|
||||
/// This is useful if an unused index needs to be skipped but a higher index needs to be specified.
|
||||
@ -2158,9 +2158,9 @@ pub struct SubpassDescription {
|
||||
/// The default value is empty.
|
||||
pub flags: SubpassDescriptionFlags,
|
||||
|
||||
/// If not `0`, enables multiview rendering, and specifies the view indices that are rendered to
|
||||
/// in this subpass. The value is a bitmask, so that that for example `0b11` will draw to the
|
||||
/// first two views and `0b101` will draw to the first and third view.
|
||||
/// If not `0`, enables multiview rendering, and specifies the view indices that are rendered
|
||||
/// to in this subpass. The value is a bitmask, so that that for example `0b11` will draw
|
||||
/// to the first two views and `0b101` will draw to the first and third view.
|
||||
///
|
||||
/// If set to a nonzero value, it must be nonzero for all subpasses in the render pass, and the
|
||||
/// [`multiview`](crate::device::Features::multiview) feature must be enabled on the device.
|
||||
@ -2168,16 +2168,18 @@ pub struct SubpassDescription {
|
||||
/// The default value is `0`.
|
||||
pub view_mask: u32,
|
||||
|
||||
/// The attachments of the render pass that are to be used as input attachments in this subpass.
|
||||
/// The attachments of the render pass that are to be used as input attachments in this
|
||||
/// subpass.
|
||||
///
|
||||
/// If an attachment is used here for the first time in this render pass, and it's is not also
|
||||
/// used as a color or depth/stencil attachment in this subpass, then the attachment's `load_op`
|
||||
/// must not be [`AttachmentLoadOp::Clear`].
|
||||
/// used as a color or depth/stencil attachment in this subpass, then the attachment's
|
||||
/// `load_op` must not be [`AttachmentLoadOp::Clear`].
|
||||
///
|
||||
/// The default value is empty.
|
||||
pub input_attachments: Vec<Option<AttachmentReference>>,
|
||||
|
||||
/// The attachments of the render pass that are to be used as color attachments in this subpass.
|
||||
/// The attachments of the render pass that are to be used as color attachments in this
|
||||
/// subpass.
|
||||
///
|
||||
/// The number of color attachments must be less than the
|
||||
/// [`max_color_attachments`](crate::device::Properties::max_color_attachments) limit of the
|
||||
@ -3203,9 +3205,9 @@ impl AttachmentReference {
|
||||
/// then `by_region` must be activated.
|
||||
///
|
||||
/// If `src_subpass` or `dst_subpass` are set to `None`, this specifies an external
|
||||
/// dependency. An external dependency specifies a dependency on commands that were submitted before
|
||||
/// the render pass instance began (for `src_subpass`), or on commands that will be submitted
|
||||
/// after the render pass instance ends (for `dst_subpass`). The values must not both be
|
||||
/// dependency. An external dependency specifies a dependency on commands that were submitted
|
||||
/// before the render pass instance began (for `src_subpass`), or on commands that will be
|
||||
/// submitted after the render pass instance ends (for `dst_subpass`). The values must not both be
|
||||
/// `None`.
|
||||
#[derive(Clone, Debug, PartialEq, Eq)]
|
||||
pub struct SubpassDependency {
|
||||
@ -3249,10 +3251,9 @@ pub struct SubpassDependency {
|
||||
/// Dependency flags that modify behavior of the subpass dependency.
|
||||
///
|
||||
/// If a `src_subpass` equals `dst_subpass`, then:
|
||||
/// - If `src_stages` and `dst_stages` both contain framebuffer-space stages,
|
||||
/// this must include [`BY_REGION`].
|
||||
/// - If the subpass's `view_mask` has more than one view,
|
||||
/// this must include [`VIEW_LOCAL`].
|
||||
/// - If `src_stages` and `dst_stages` both contain framebuffer-space stages, this must include
|
||||
/// [`BY_REGION`].
|
||||
/// - If the subpass's `view_mask` has more than one view, this must include [`VIEW_LOCAL`].
|
||||
///
|
||||
/// The default value is [`DependencyFlags::empty()`].
|
||||
///
|
||||
|
@ -25,15 +25,15 @@
|
||||
//! ## Layout of data
|
||||
//!
|
||||
//! When buffers, push constants or other user-provided data are accessed in shaders,
|
||||
//! the shader expects the values inside to be laid out in a specific way. For every uniform buffer,
|
||||
//! storage buffer or push constant block, the SPIR-V specification requires the SPIR-V code to
|
||||
//! provide the `Offset` decoration for every member of a struct, indicating where it is placed
|
||||
//! relative to the start of the struct. If there are arrays or matrices among the variables, the
|
||||
//! SPIR-V code must also provide an `ArrayStride` or `MatrixStride` decoration for them,
|
||||
//! indicating the number of bytes between the start of each element in the array or column in the
|
||||
//! matrix. When providing data to shaders, you must make sure that your data is placed at the
|
||||
//! locations indicated within the SPIR-V code, or the shader will read the wrong data and produce
|
||||
//! nonsense.
|
||||
//! the shader expects the values inside to be laid out in a specific way. For every uniform
|
||||
//! buffer, storage buffer or push constant block, the SPIR-V specification requires the SPIR-V
|
||||
//! code to provide the `Offset` decoration for every member of a struct, indicating where it is
|
||||
//! placed relative to the start of the struct. If there are arrays or matrices among the
|
||||
//! variables, the SPIR-V code must also provide an `ArrayStride` or `MatrixStride` decoration for
|
||||
//! them, indicating the number of bytes between the start of each element in the array or column
|
||||
//! in the matrix. When providing data to shaders, you must make sure that your data is placed at
|
||||
//! the locations indicated within the SPIR-V code, or the shader will read the wrong data and
|
||||
//! produce nonsense.
|
||||
//!
|
||||
//! GLSL does not require you to give explicit offsets and/or strides to your variables (although
|
||||
//! it has the option to provide them if you wish). Instead, the shader compiler automatically
|
||||
@ -63,12 +63,12 @@
|
||||
//! [`#[repr(C)]`](https://doc.rust-lang.org/nomicon/other-reprs.html#reprc) attribute.
|
||||
//! The shader compiler does not use this alignment by default, so you must use the GLSL
|
||||
//! qualifier. You must also enable the [`scalar_block_layout`] feature in Vulkan.
|
||||
//! - **Base alignment**, also known as **std430** (GLSL qualifier: `layout(std430)`).
|
||||
//! The shader compiler uses this alignment by default for all shader data except uniform buffers.
|
||||
//! If you use the base alignment for a uniform buffer, you must also enable the
|
||||
//! - **Base alignment**, also known as **std430** (GLSL qualifier: `layout(std430)`). The shader
|
||||
//! compiler uses this alignment by default for all shader data except uniform buffers. If you
|
||||
//! use the base alignment for a uniform buffer, you must also enable the
|
||||
//! [`uniform_buffer_standard_layout`] feature in Vulkan.
|
||||
//! - **Extended alignment**, also known as **std140** (GLSL qualifier: `layout(std140)`).
|
||||
//! The shader compiler uses this alignment by default for uniform buffers.
|
||||
//! - **Extended alignment**, also known as **std140** (GLSL qualifier: `layout(std140)`). The
|
||||
//! shader compiler uses this alignment by default for uniform buffers.
|
||||
//!
|
||||
//! Each alignment type is a subset of the ones above it, so if something adheres to the extended
|
||||
//! alignment rules, it also follows the rules for the base and scalar alignments.
|
||||
@ -140,105 +140,112 @@
|
||||
//!
|
||||
//! ## Buffers
|
||||
//!
|
||||
//! - If the [`robust_buffer_access`](Features::robust_buffer_access) feature is not enabled
|
||||
//! on the device, then the shader must not access any values outside the range of the buffer,
|
||||
//! as specified when writing the descriptor set.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-uniformBuffers-06935)
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-storageBuffers-06936)
|
||||
//! - If any `PhysicalStorageBuffer` pointers to device memory are dereferenced in the shader,
|
||||
//! then they must point to valid buffer memory of the correct type.
|
||||
//! - If the [`robust_buffer_access`](Features::robust_buffer_access) feature is not enabled on the
|
||||
//! device, then the shader must not access any values outside the range of the buffer, as
|
||||
//! specified when writing the descriptor set. <sup>[\[06935\]] [\[06936\]]</sup>
|
||||
//! - If any `PhysicalStorageBuffer` pointers to device memory are dereferenced in the shader, then
|
||||
//! they must point to valid buffer memory of the correct type.
|
||||
//!
|
||||
//! ## Image views and buffer views
|
||||
//!
|
||||
//! - The [`view_type`](ImageView::view_type) of the bound image view
|
||||
//! must match the `Dim` operand of the `OpImageType`.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-viewType-07752)
|
||||
//! - The numeric type of the [`format`](ImageView::format) of the bound image view
|
||||
//! must match the `Sampled Type` operand of the `OpImageType`.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-format-07753)
|
||||
//! - For every `OpImageWrite` instruction, the type of the `Texel` operand must have at least
|
||||
//! as many components as the format of the bound image view or buffer view.
|
||||
//! If the bound image view's format is [`Format::A8_UNORM`], then the type of the `Texel`
|
||||
//! operand must have four components.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-OpImageWrite-04469)
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-OpImageWrite-08795)
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-OpImageWrite-08796)
|
||||
//! - The `Sampled Type` operand of the `OpTypeImage` declaration must have a `Width` of 64,
|
||||
//! if and only if the format of the bound image view or buffer view also has a 64-bit component.
|
||||
//! Otherwise, it must have a `Width` of 32.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-SampledType-04470)
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-SampledType-04471)
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-SampledType-04472)
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-SampledType-04473)
|
||||
//! - The [`view_type`](ImageView::view_type) of the bound image view must match the `Dim` operand
|
||||
//! of the `OpImageType`. <sup>[\[07752\]]</sup>
|
||||
//! - The numeric type of the [`format`](ImageView::format) of the bound image view must match the
|
||||
//! `Sampled Type` operand of the `OpImageType`. <sup>[\[07753\]]</sup>
|
||||
//! - For every `OpImageWrite` instruction, the type of the `Texel` operand must have at least as
|
||||
//! many components as the format of the bound image view or buffer view. If the bound image
|
||||
//! view's format is [`Format::A8_UNORM`], then the type of the `Texel` operand must have four
|
||||
//! components. <sup>[\[04469\]] [\[08795\]] [\[08796\]]</sup>
|
||||
//! - The `Sampled Type` operand of the `OpTypeImage` declaration must have a `Width` of 64, if and
|
||||
//! only if the format of the bound image view or buffer view also has a 64-bit component.
|
||||
//! Otherwise, it must have a `Width` of 32. <sup>[\[04470\]] [\[04471\]] [\[04472\]]
|
||||
//! [\[04473\]]</sup>
|
||||
//! - For a storage image/texel buffer declared with `OpTypeImage` with an `Unknown` format:
|
||||
//! - If it is written to in the shader, the format of the bound image view or buffer view must
|
||||
//! have the [`FormatFeatures::STORAGE_WRITE_WITHOUT_FORMAT`] format feature.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-OpTypeImage-07027)
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-OpTypeImage-07029)
|
||||
//! have the [`FormatFeatures::STORAGE_WRITE_WITHOUT_FORMAT`] format feature. <sup>[\[07027\]]
|
||||
//! [\[07029\]]</sup>
|
||||
//! - If it is read from in the shader, the format of the bound image view or buffer view must
|
||||
//! have the [`FormatFeatures::STORAGE_READ_WITHOUT_FORMAT`] format feature.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-OpTypeImage-07028)
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-OpTypeImage-07030)
|
||||
//! have the [`FormatFeatures::STORAGE_READ_WITHOUT_FORMAT`] format feature. <sup>[\[07028\]]
|
||||
//! [\[07030\]]</sup>
|
||||
//! - If atomic operations are used on a storage image/texel buffer:
|
||||
//! - The bound image view's format must have the [`FormatFeatures::STORAGE_IMAGE_ATOMIC`]
|
||||
//! format feature.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-02691)
|
||||
//! - The bound buffer view's format must have the [`FormatFeatures::STORAGE_TEXEL_BUFFER_ATOMIC`]
|
||||
//! format feature.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-07888)
|
||||
//! - The bound image view's format must have the [`FormatFeatures::STORAGE_IMAGE_ATOMIC`] format
|
||||
//! feature. <sup>[\[02691\]]</sup>
|
||||
//! - The bound buffer view's format must have the
|
||||
//! [`FormatFeatures::STORAGE_TEXEL_BUFFER_ATOMIC`] format feature. <sup>[\[07888\]]</sup>
|
||||
//!
|
||||
//! ## Image sampling
|
||||
//!
|
||||
//! If the bound sampler uses [`Filter::Linear`] or [`SamplerMipmapMode::Linear`]:
|
||||
//! - The bound image view's format must have the [`FormatFeatures::SAMPLED_IMAGE_FILTER_LINEAR`]
|
||||
//! format feature.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-magFilter-04553)
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-mipmapMode-04770)
|
||||
//! format feature. <sup>[\[04553\]] [\[04770\]]</sup>
|
||||
//!
|
||||
//! If the bound sampler uses [`Filter::Cubic`]:
|
||||
//! - The bound image view's format must have the [`FormatFeatures::SAMPLED_IMAGE_FILTER_CUBIC`]
|
||||
//! format feature.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-02692)
|
||||
//! format feature. <sup>[\[02692\]]</sup>
|
||||
//! - The bound image view's type and format must support cubic filtering, as indicated in
|
||||
//! [`ImageFormatProperties::filter_cubic`] returned from
|
||||
//! [`PhysicalDevice::image_format_properties`].
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-filterCubic-02694)
|
||||
//! [`PhysicalDevice::image_format_properties`]. <sup>[\[02694\]]</sup>
|
||||
//! - If the sampler's reduction mode is [`SamplerReductionMode::Min`] or
|
||||
//! [`SamplerReductionMode::Max`], the image view type and format must support cubic minmax
|
||||
//! filtering, as indicated in [`ImageFormatProperties::filter_cubic_minmax`] returned from
|
||||
//! [`PhysicalDevice::image_format_properties`].
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-filterCubicMinmax-02695)
|
||||
//! [`PhysicalDevice::image_format_properties`]. <sup>[\[02695\]]</sup>
|
||||
//!
|
||||
//! If the bound sampler uses [depth comparison](SamplerCreateInfo::compare):
|
||||
//! - The bound image view's format must have the [`FormatFeatures::SAMPLED_IMAGE_DEPTH_COMPARISON`]
|
||||
//! format feature.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-06479)
|
||||
//! - The bound image view's format must have the
|
||||
//! [`FormatFeatures::SAMPLED_IMAGE_DEPTH_COMPARISON`] format feature. <sup>[\[06479\]]</sup>
|
||||
//!
|
||||
//! If the bound sampler uses [unnormalized coordinates](SamplerCreateInfo::unnormalized_coordinates):
|
||||
//! - The bound image view must have a type of [`ImageViewType::Dim1d`] or [`ImageViewType::Dim2d`].
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-08609)
|
||||
//! If the bound sampler uses [unnormalized
|
||||
//! coordinates](SamplerCreateInfo::unnormalized_coordinates):
|
||||
//! - The bound image view must have a type of [`ImageViewType::Dim1d`] or
|
||||
//! [`ImageViewType::Dim2d`]. <sup>[\[08609\]]</sup>
|
||||
//! - The sampler must not be used in any `OpImageSample*` or `OpImageSparseSample*` instructions,
|
||||
//! that contain `ImplicitLod`, `Dref` or `Proj` in their name.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-08610)
|
||||
//! that contain `ImplicitLod`, `Dref` or `Proj` in their name. <sup>[\[08610\]]</sup>
|
||||
//! - The sampler must not be used in any `OpImageSample*` or `OpImageSparseSample*` instructions,
|
||||
//! that include an LOD bias or offset operand.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-08611)
|
||||
//! that include an LOD bias or offset operand. <sup>[\[08611\]]</sup>
|
||||
//!
|
||||
//! If the bound sampler has a [sampler YCbCr conversion](crate::image::sampler::ycbcr):
|
||||
//! - The sampler must only be used in `OpImageSample*` or `OpImageSparseSample*` instructions.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-06550)
|
||||
//! <sup>[\[06550\]]</sup>
|
||||
//! - The sampler must not be used with the `ConstOffset` or `Offset` image operands.
|
||||
//! [\[spec\]](https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-ConstOffset-06551)
|
||||
//! <sup>[\[06551\]]</sup>
|
||||
//!
|
||||
//! ## Acceleration structures
|
||||
//!
|
||||
//! - In any top-level acceleration structure, the pointers that refer to the contained
|
||||
//! bottom-level acceleration structure instances must point to valid acceleration structures.
|
||||
//!
|
||||
//! [alignment rules]: <https://registry.khronos.org/vulkan/specs/1.3-extensions/html/chap15.html#interfaces-resources-layout>
|
||||
//! [`GL_EXT_scalar_block_layout`]: <https://github.com/KhronosGroup/GLSL/blob/master/extensions/ext/GL_EXT_scalar_block_layout.txt>
|
||||
//! [alignment rules]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/chap15.html#interfaces-resources-layout
|
||||
//! [`GL_EXT_scalar_block_layout`]: https://github.com/KhronosGroup/GLSL/blob/master/extensions/ext/GL_EXT_scalar_block_layout.txt
|
||||
//! [`scalar_block_layout`]: crate::device::Features::scalar_block_layout
|
||||
//! [`uniform_buffer_standard_layout`]: crate::device::Features::uniform_buffer_standard_layout
|
||||
//! [\[06935\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-uniformBuffers-06935
|
||||
//! [\[06936\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-storageBuffers-06936
|
||||
//! [\[07752\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-viewType-07752
|
||||
//! [\[07753\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-format-07753
|
||||
//! [\[04469\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-OpImageWrite-04469
|
||||
//! [\[08795\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-OpImageWrite-08795
|
||||
//! [\[08796\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-OpImageWrite-08796
|
||||
//! [\[04470\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-SampledType-04470
|
||||
//! [\[04471\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-SampledType-04471
|
||||
//! [\[04472\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-SampledType-04472
|
||||
//! [\[04473\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-SampledType-04473
|
||||
//! [\[07027\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-OpTypeImage-07027
|
||||
//! [\[07029\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-OpTypeImage-07029
|
||||
//! [\[07028\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-OpTypeImage-07028
|
||||
//! [\[07030\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-OpTypeImage-07030
|
||||
//! [\[02691\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-02691
|
||||
//! [\[07888\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-07888
|
||||
//! [\[04553\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-magFilter-04553
|
||||
//! [\[04770\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-mipmapMode-04770
|
||||
//! [\[02692\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-02692
|
||||
//! [\[02694\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-filterCubic-02694
|
||||
//! [\[02695\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-filterCubicMinmax-02695
|
||||
//! [\[06479\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-06479
|
||||
//! [\[08609\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-08609
|
||||
//! [\[08610\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-08610
|
||||
//! [\[08611\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-08611
|
||||
//! [\[06550\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-None-06550
|
||||
//! [\[06551\]]: https://registry.khronos.org/vulkan/specs/1.3-extensions/html/vkspec.html#VUID-vkCmdDispatch-ConstOffset-06551
|
||||
|
||||
use self::spirv::{Id, Instruction};
|
||||
#[cfg(doc)]
|
||||
@ -905,9 +912,9 @@ impl SpecializedShaderModule {
|
||||
self.spirv.as_ref().unwrap_or(&self.base_module.spirv)
|
||||
}
|
||||
|
||||
/// Returns information about the entry point with the provided name. Returns `None` if no entry
|
||||
/// point with that name exists in the shader module or if multiple entry points with the same
|
||||
/// name exist.
|
||||
/// Returns information about the entry point with the provided name. Returns `None` if no
|
||||
/// entry point with that name exists in the shader module or if multiple entry points with
|
||||
/// the same name exist.
|
||||
#[inline]
|
||||
pub fn entry_point(self: &Arc<Self>, name: &str) -> Option<EntryPoint> {
|
||||
self.single_entry_point_filter(|info| info.name == name)
|
||||
|
@ -719,9 +719,9 @@ struct InstructionReader<'a> {
|
||||
}
|
||||
|
||||
impl<'a> InstructionReader<'a> {
|
||||
/// Constructs a new reader from a slice of words for a single instruction, including the opcode
|
||||
/// word. `instruction` is the number of the instruction currently being read, and is used for
|
||||
/// error reporting.
|
||||
/// Constructs a new reader from a slice of words for a single instruction, including the
|
||||
/// opcode word. `instruction` is the number of the instruction currently being read, and
|
||||
/// is used for error reporting.
|
||||
fn new(words: &'a [u32], instruction: usize) -> Self {
|
||||
debug_assert!(!words.is_empty());
|
||||
Self {
|
||||
|
@ -521,7 +521,8 @@ fn evaluate_spec_constant_op(
|
||||
}
|
||||
}
|
||||
|
||||
// Evaluate a SpecConstantInstruction that does calculations on scalars or paired vector components.
|
||||
// Evaluate a SpecConstantInstruction that does calculations on scalars or paired vector
|
||||
// components.
|
||||
fn evaluate_spec_constant_calculation_op(
|
||||
instruction: &SpecConstantInstruction,
|
||||
constants: &HashMap<Id, Constant>,
|
||||
|
@ -2,8 +2,8 @@
|
||||
//!
|
||||
//! Before you can draw on the screen or a window, you have to create two objects:
|
||||
//!
|
||||
//! - Create a `Surface` object that represents the location where the image will show up (either
|
||||
//! a window or a monitor).
|
||||
//! - Create a `Surface` object that represents the location where the image will show up (either a
|
||||
//! window or a monitor).
|
||||
//! - Create a `Swapchain` that uses that `Surface`.
|
||||
//!
|
||||
//! Creating a surface can be done with only an `Instance` object. However creating a swapchain
|
||||
@ -219,8 +219,8 @@
|
||||
//! - Call `swapchain::acquire_next_image`. This function will return the index of the image
|
||||
//! (within the list returned by `Swapchain::new`) that is available to draw, plus a future
|
||||
//! representing the moment when the GPU will gain access to that image.
|
||||
//! - Draw on that image just like you would draw to any other image (see the documentation of
|
||||
//! the `pipeline` module). You need to chain the draw after the future that was returned by
|
||||
//! - Draw on that image just like you would draw to any other image (see the documentation of the
|
||||
//! `pipeline` module). You need to chain the draw after the future that was returned by
|
||||
//! `acquire_next_image`.
|
||||
//! - Call `Swapchain::present` with the same index and by chaining the futures, in order to tell
|
||||
//! the implementation that you are finished drawing to the image and that it can queue a
|
||||
@ -402,7 +402,6 @@ impl Swapchain {
|
||||
///
|
||||
/// - Panics if the device and the surface don't belong to the same instance.
|
||||
/// - Panics if `create_info.usage` is empty.
|
||||
///
|
||||
// TODO: isn't it unsafe to take the surface through an Arc when it comes to vulkano-win?
|
||||
#[inline]
|
||||
pub fn new(
|
||||
@ -1154,8 +1153,8 @@ impl Swapchain {
|
||||
///
|
||||
/// - `handle` and `image_handles` must be valid Vulkan object handles created from `device`.
|
||||
/// - `handle` must not be retired.
|
||||
/// - `image_handles` must be swapchain images owned by `handle`,
|
||||
/// in the same order as they were returned by `vkGetSwapchainImagesKHR`.
|
||||
/// - `image_handles` must be swapchain images owned by `handle`, in the same order as they
|
||||
/// were returned by `vkGetSwapchainImagesKHR`.
|
||||
/// - `surface` and `create_info` must match the info used to create the object.
|
||||
pub unsafe fn from_handle(
|
||||
device: Arc<Device>,
|
||||
@ -1614,8 +1613,8 @@ impl Swapchain {
|
||||
///
|
||||
/// The swapchain must have been created with [`FullScreenExclusive::ApplicationControlled`],
|
||||
/// and must not already hold full-screen exclusivity. Full-screen exclusivity is held until
|
||||
/// either the `release_full_screen_exclusive` is called, or if any of the the other `Swapchain`
|
||||
/// functions return `FullScreenExclusiveLost`.
|
||||
/// either the `release_full_screen_exclusive` is called, or if any of the the other
|
||||
/// `Swapchain` functions return `FullScreenExclusiveLost`.
|
||||
#[inline]
|
||||
pub fn acquire_full_screen_exclusive_mode(&self) -> Result<(), Validated<VulkanError>> {
|
||||
self.validate_acquire_full_screen_exclusive_mode()?;
|
||||
@ -1819,7 +1818,8 @@ pub struct SwapchainCreateInfo {
|
||||
/// The default value is `Format::UNDEFINED`.
|
||||
pub image_format: Format,
|
||||
|
||||
/// The formats that an image view can have when it is created from one of the swapchain images.
|
||||
/// The formats that an image view can have when it is created from one of the swapchain
|
||||
/// images.
|
||||
///
|
||||
/// If the list is not empty, and `flags` does not contain
|
||||
/// [`SwapchainCreateFlags::MUTABLE_FORMAT`], then the list must contain at most one element,
|
||||
@ -1895,9 +1895,10 @@ pub struct SwapchainCreateInfo {
|
||||
/// The default value is empty.
|
||||
pub present_modes: SmallVec<[PresentMode; PresentMode::COUNT]>,
|
||||
|
||||
/// Whether the implementation is allowed to discard rendering operations that affect regions of
|
||||
/// the surface which aren't visible. This is important to take into account if your fragment
|
||||
/// shader has side-effects or if you want to read back the content of the image afterwards.
|
||||
/// Whether the implementation is allowed to discard rendering operations that affect regions
|
||||
/// of the surface which aren't visible. This is important to take into account if your
|
||||
/// fragment shader has side-effects or if you want to read back the content of the image
|
||||
/// afterwards.
|
||||
///
|
||||
/// The default value is `true`.
|
||||
pub clipped: bool,
|
||||
|
@ -167,8 +167,8 @@ impl Surface {
|
||||
///
|
||||
/// - `handle` must be a valid Vulkan object handle created from `instance`.
|
||||
/// - `handle` must have been created using the function specified by `api`.
|
||||
/// - The window object that `handle` was created from must outlive the created `Surface`.
|
||||
/// The `object` parameter can be used to ensure this.
|
||||
/// - The window object that `handle` was created from must outlive the created `Surface`. The
|
||||
/// `object` parameter can be used to ensure this.
|
||||
pub unsafe fn from_handle(
|
||||
instance: Arc<Instance>,
|
||||
handle: ash::vk::SurfaceKHR,
|
||||
@ -191,8 +191,9 @@ impl Surface {
|
||||
|
||||
/// Creates a `Surface` with no backing window or display.
|
||||
///
|
||||
/// Presenting to a headless surface does nothing, so this is mostly useless in itself. However,
|
||||
/// it may be useful for testing, and it is available for future extensions to layer on top of.
|
||||
/// Presenting to a headless surface does nothing, so this is mostly useless in itself.
|
||||
/// However, it may be useful for testing, and it is available for future extensions to
|
||||
/// layer on top of.
|
||||
pub fn headless(
|
||||
instance: Arc<Instance>,
|
||||
object: Option<Arc<dyn Any + Send + Sync>>,
|
||||
@ -434,8 +435,8 @@ impl Surface {
|
||||
/// # Safety
|
||||
///
|
||||
/// - `window` must be a valid Android `ANativeWindow` handle.
|
||||
/// - The object referred to by `window` must outlive the created `Surface`.
|
||||
/// The `object` parameter can be used to ensure this.
|
||||
/// - The object referred to by `window` must outlive the created `Surface`. The `object`
|
||||
/// parameter can be used to ensure this.
|
||||
pub unsafe fn from_android(
|
||||
instance: Arc<Instance>,
|
||||
window: *mut ash::vk::ANativeWindow,
|
||||
@ -505,8 +506,8 @@ impl Surface {
|
||||
///
|
||||
/// - `dfb` must be a valid DirectFB `IDirectFB` handle.
|
||||
/// - `surface` must be a valid DirectFB `IDirectFBSurface` handle.
|
||||
/// - The object referred to by `dfb` and `surface` must outlive the created `Surface`.
|
||||
/// The `object` parameter can be used to ensure this.
|
||||
/// - The object referred to by `dfb` and `surface` must outlive the created `Surface`. The
|
||||
/// `object` parameter can be used to ensure this.
|
||||
pub unsafe fn from_directfb(
|
||||
instance: Arc<Instance>,
|
||||
dfb: *mut ash::vk::IDirectFB,
|
||||
@ -584,8 +585,8 @@ impl Surface {
|
||||
/// # Safety
|
||||
///
|
||||
/// - `image_pipe_handle` must be a valid Fuchsia `zx_handle_t` handle.
|
||||
/// - The object referred to by `image_pipe_handle` must outlive the created `Surface`.
|
||||
/// The `object` parameter can be used to ensure this.
|
||||
/// - The object referred to by `image_pipe_handle` must outlive the created `Surface`. The
|
||||
/// `object` parameter can be used to ensure this.
|
||||
pub unsafe fn from_fuchsia_image_pipe(
|
||||
instance: Arc<Instance>,
|
||||
image_pipe_handle: ash::vk::zx_handle_t,
|
||||
@ -659,8 +660,8 @@ impl Surface {
|
||||
/// # Safety
|
||||
///
|
||||
/// - `stream_descriptor` must be a valid Google Games Platform `GgpStreamDescriptor` handle.
|
||||
/// - The object referred to by `stream_descriptor` must outlive the created `Surface`.
|
||||
/// The `object` parameter can be used to ensure this.
|
||||
/// - The object referred to by `stream_descriptor` must outlive the created `Surface`. The
|
||||
/// `object` parameter can be used to ensure this.
|
||||
pub unsafe fn from_ggp_stream_descriptor(
|
||||
instance: Arc<Instance>,
|
||||
stream_descriptor: ash::vk::GgpStreamDescriptor,
|
||||
@ -734,8 +735,8 @@ impl Surface {
|
||||
/// # Safety
|
||||
///
|
||||
/// - `metal_layer` must be a valid `IOSMetalLayer` handle.
|
||||
/// - The object referred to by `metal_layer` must outlive the created `Surface`.
|
||||
/// The `object` parameter can be used to ensure this.
|
||||
/// - The object referred to by `metal_layer` must outlive the created `Surface`. The `object`
|
||||
/// parameter can be used to ensure this.
|
||||
/// - The `UIView` must be backed by a `CALayer` instance of type `CAMetalLayer`.
|
||||
pub unsafe fn from_ios(
|
||||
instance: Arc<Instance>,
|
||||
@ -808,8 +809,8 @@ impl Surface {
|
||||
/// # Safety
|
||||
///
|
||||
/// - `view` must be a valid `CAMetalLayer` or `NSView` handle.
|
||||
/// - The object referred to by `view` must outlive the created `Surface`.
|
||||
/// The `object` parameter can be used to ensure this.
|
||||
/// - The object referred to by `view` must outlive the created `Surface`. The `object`
|
||||
/// parameter can be used to ensure this.
|
||||
/// - The `NSView` must be backed by a `CALayer` instance of type `CAMetalLayer`.
|
||||
pub unsafe fn from_mac_os(
|
||||
instance: Arc<Instance>,
|
||||
@ -882,8 +883,8 @@ impl Surface {
|
||||
/// # Safety
|
||||
///
|
||||
/// - `layer` must be a valid Metal `CAMetalLayer` handle.
|
||||
/// - The object referred to by `layer` must outlive the created `Surface`.
|
||||
/// The `object` parameter can be used to ensure this.
|
||||
/// - The object referred to by `layer` must outlive the created `Surface`. The `object`
|
||||
/// parameter can be used to ensure this.
|
||||
pub unsafe fn from_metal(
|
||||
instance: Arc<Instance>,
|
||||
layer: *const ash::vk::CAMetalLayer,
|
||||
@ -950,8 +951,8 @@ impl Surface {
|
||||
///
|
||||
/// - `context` must be a valid QNX Screen `_screen_context` handle.
|
||||
/// - `window` must be a valid QNX Screen `_screen_window` handle.
|
||||
/// - The object referred to by `window` must outlive the created `Surface`.
|
||||
/// The `object` parameter can be used to ensure this.
|
||||
/// - The object referred to by `window` must outlive the created `Surface`. The `object`
|
||||
/// parameter can be used to ensure this.
|
||||
pub unsafe fn from_qnx_screen(
|
||||
instance: Arc<Instance>,
|
||||
context: *mut ash::vk::_screen_context,
|
||||
@ -1029,8 +1030,8 @@ impl Surface {
|
||||
/// # Safety
|
||||
///
|
||||
/// - `window` must be a valid `nn::vi::NativeWindowHandle` handle.
|
||||
/// - The object referred to by `window` must outlive the created `Surface`.
|
||||
/// The `object` parameter can be used to ensure this.
|
||||
/// - The object referred to by `window` must outlive the created `Surface`. The `object`
|
||||
/// parameter can be used to ensure this.
|
||||
pub unsafe fn from_vi(
|
||||
instance: Arc<Instance>,
|
||||
window: *mut c_void,
|
||||
@ -1184,8 +1185,8 @@ impl Surface {
|
||||
///
|
||||
/// - `hinstance` must be a valid Win32 `HINSTANCE` handle.
|
||||
/// - `hwnd` must be a valid Win32 `HWND` handle.
|
||||
/// - The objects referred to by `hwnd` and `hinstance` must outlive the created `Surface`.
|
||||
/// The `object` parameter can be used to ensure this.
|
||||
/// - The objects referred to by `hwnd` and `hinstance` must outlive the created `Surface`. The
|
||||
/// `object` parameter can be used to ensure this.
|
||||
pub unsafe fn from_win32(
|
||||
instance: Arc<Instance>,
|
||||
hinstance: ash::vk::HINSTANCE,
|
||||
@ -1348,8 +1349,8 @@ impl Surface {
|
||||
///
|
||||
/// - `display` must be a valid Xlib `Display` handle.
|
||||
/// - `window` must be a valid Xlib `Window` handle.
|
||||
/// - The objects referred to by `display` and `window` must outlive the created `Surface`.
|
||||
/// The `object` parameter can be used to ensure this.
|
||||
/// - The objects referred to by `display` and `window` must outlive the created `Surface`. The
|
||||
/// `object` parameter can be used to ensure this.
|
||||
pub unsafe fn from_xlib(
|
||||
instance: Arc<Instance>,
|
||||
display: *mut ash::vk::Display,
|
||||
@ -2136,7 +2137,8 @@ vulkan_enum! {
|
||||
]),
|
||||
}
|
||||
|
||||
/// Parameters for [`PhysicalDevice::surface_capabilities`] and [`PhysicalDevice::surface_formats`].
|
||||
/// Parameters for [`PhysicalDevice::surface_capabilities`] and
|
||||
/// [`PhysicalDevice::surface_formats`].
|
||||
///
|
||||
/// [`PhysicalDevice::surface_capabilities`]: crate::device::physical::PhysicalDevice::surface_capabilities
|
||||
/// [`PhysicalDevice::surface_formats`]: crate::device::physical::PhysicalDevice::surface_formats
|
||||
|
@ -42,7 +42,8 @@ pub struct Event {
|
||||
impl Event {
|
||||
/// Creates a new `Event`.
|
||||
///
|
||||
/// On [portability subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// On [portability
|
||||
/// subset](crate::instance#portability-subset-devices-and-the-enumerate_portability-flag)
|
||||
/// devices, the
|
||||
/// [`events`](crate::device::Features::events)
|
||||
/// feature must be enabled on the device.
|
||||
|
@ -45,7 +45,8 @@ use std::{
|
||||
time::Duration,
|
||||
};
|
||||
|
||||
/// A two-state synchronization primitive that is signalled by the device and waited on by the host.
|
||||
/// A two-state synchronization primitive that is signalled by the device and waited on by the
|
||||
/// host.
|
||||
#[derive(Debug)]
|
||||
pub struct Fence {
|
||||
handle: ash::vk::Fence,
|
||||
@ -616,9 +617,9 @@ impl Fence {
|
||||
/// # Safety
|
||||
///
|
||||
/// - The fence must not be in use by the device.
|
||||
/// - If in `import_fence_fd_info`, `handle_type` is `ExternalHandleType::OpaqueFd`,
|
||||
/// then `file` must represent a fence that was exported from Vulkan or a compatible API,
|
||||
/// with a driver and device UUID equal to those of the device that owns `self`.
|
||||
/// - If in `import_fence_fd_info`, `handle_type` is `ExternalHandleType::OpaqueFd`, then
|
||||
/// `file` must represent a fence that was exported from Vulkan or a compatible API, with a
|
||||
/// driver and device UUID equal to those of the device that owns `self`.
|
||||
#[inline]
|
||||
pub unsafe fn import_fd(
|
||||
&self,
|
||||
@ -765,8 +766,8 @@ impl Fence {
|
||||
// Shared by Fence and FenceSignalFuture
|
||||
pub(crate) fn poll_impl(&self, cx: &mut Context<'_>) -> Poll<Result<(), VulkanError>> {
|
||||
// Vulkan only allows polling of the fence status, so we have to use a spin future.
|
||||
// This is still better than blocking in async applications, since a smart-enough async engine
|
||||
// can choose to run some other tasks between probing this one.
|
||||
// This is still better than blocking in async applications, since a smart-enough async
|
||||
// engine can choose to run some other tasks between probing this one.
|
||||
|
||||
// Check if we are done without blocking
|
||||
match self.is_signaled() {
|
||||
|
@ -59,8 +59,8 @@ pub enum FenceSignalFutureBehavior {
|
||||
/// Contrary to most other future types, it is possible to block the current thread until the event
|
||||
/// happens. This is done by calling the `wait()` function.
|
||||
///
|
||||
/// This can also be done through Rust's Async system by simply `.await`ing this object. Note though
|
||||
/// that (due to the Vulkan API fence design) this will spin to check the fence, rather than
|
||||
/// This can also be done through Rust's Async system by simply `.await`ing this object. Note
|
||||
/// though that (due to the Vulkan API fence design) this will spin to check the fence, rather than
|
||||
/// blocking in the driver. Therefore if you have a long-running task, blocking may be less
|
||||
/// CPU intense (depending on the driver's implementation).
|
||||
///
|
||||
|
@ -67,8 +67,9 @@ where
|
||||
let first = self.first.build_submission()?;
|
||||
let second = self.second.build_submission()?;
|
||||
|
||||
// In some cases below we have to submit previous command buffers already, this s done by flushing previous.
|
||||
// Since the implementation should remember being flushed it's safe to call build_submission multiple times
|
||||
// In some cases below we have to submit previous command buffers already, this s done by
|
||||
// flushing previous. Since the implementation should remember being flushed it's
|
||||
// safe to call build_submission multiple times
|
||||
Ok(match (first, second) {
|
||||
(SubmitAnyBuilder::Empty, b) => b,
|
||||
(a, SubmitAnyBuilder::Empty) => a,
|
||||
|
@ -171,7 +171,8 @@ where
|
||||
.map(|r| r.map(|_| ()))
|
||||
.fold(Ok(()), Result::and)?;
|
||||
|
||||
// FIXME: problematic because if we return an error and flush() is called again, then we'll submit the present twice
|
||||
// FIXME: problematic because if we return an error and flush() is called again,
|
||||
// then we'll submit the present twice
|
||||
queue_submit(
|
||||
&queue,
|
||||
SubmitInfo {
|
||||
|
@ -3065,7 +3065,8 @@ impl ImageMemoryBarrier {
|
||||
queue_family_ownership_transfer: None,
|
||||
image,
|
||||
subresource_range: ImageSubresourceRange {
|
||||
aspects: ImageAspects::empty(), // Can't use image format aspects because `color` can't be specified with `planeN`.
|
||||
// Can't use image format aspects because `color` can't be specified with `planeN`.
|
||||
aspects: ImageAspects::empty(),
|
||||
mip_levels: 0..0,
|
||||
array_layers: 0..0,
|
||||
},
|
||||
@ -3538,13 +3539,16 @@ impl ImageMemoryBarrier {
|
||||
}
|
||||
|
||||
// VUID-VkImageMemoryBarrier2-synchronization2-07793
|
||||
// If the synchronization2 feature is not enabled, oldLayout must not be VK_IMAGE_LAYOUT_ATTACHMENT_OPTIMAL_KHR or VK_IMAGE_LAYOUT_READ_ONLY_OPTIMAL_KHR
|
||||
// If the synchronization2 feature is not enabled, oldLayout must not be
|
||||
// VK_IMAGE_LAYOUT_ATTACHMENT_OPTIMAL_KHR or VK_IMAGE_LAYOUT_READ_ONLY_OPTIMAL_KHR
|
||||
|
||||
// VUID-VkImageMemoryBarrier2-synchronization2-07794
|
||||
// If the synchronization2 feature is not enabled, newLayout must not be VK_IMAGE_LAYOUT_ATTACHMENT_OPTIMAL_KHR or VK_IMAGE_LAYOUT_READ_ONLY_OPTIMAL_KHR
|
||||
// If the synchronization2 feature is not enabled, newLayout must not be
|
||||
// VK_IMAGE_LAYOUT_ATTACHMENT_OPTIMAL_KHR or VK_IMAGE_LAYOUT_READ_ONLY_OPTIMAL_KHR
|
||||
|
||||
// VUID-VkImageMemoryBarrier2-attachmentFeedbackLoopLayout-07313
|
||||
// If the attachmentFeedbackLoopLayout feature is not enabled, newLayout must not be VK_IMAGE_LAYOUT_ATTACHMENT_FEEDBACK_LOOP_OPTIMAL_EXT
|
||||
// If the attachmentFeedbackLoopLayout feature is not enabled, newLayout must not be
|
||||
// VK_IMAGE_LAYOUT_ATTACHMENT_FEEDBACK_LOOP_OPTIMAL_EXT
|
||||
|
||||
subresource_range
|
||||
.validate(device)
|
||||
|
@ -28,10 +28,10 @@
|
||||
//! Both the device and the host can perform the same two operations on a timeline semaphore:
|
||||
//! - A **semaphore signal operation** will set the semaphore counter value to a specified value.
|
||||
//! - A **semaphore wait operation** will block execution of the operation it is associated with,
|
||||
//! as long as the semaphore's counter value is less than a specified threshold value.
|
||||
//! Once the semaphore's counter value is equal to or greater than the threshold, execution
|
||||
//! continues. Unlike with binary semaphores, waiting does not alter the state of a timeline
|
||||
//! semaphore, so multiple operations can wait for the same semaphore value.
|
||||
//! as long as the semaphore's counter value is less than a specified threshold value. Once the
|
||||
//! semaphore's counter value is equal to or greater than the threshold, execution continues.
|
||||
//! Unlike with binary semaphores, waiting does not alter the state of a timeline semaphore, so
|
||||
//! multiple operations can wait for the same semaphore value.
|
||||
//!
|
||||
//! Additionally, the host can query the current counter value of a timeline semaphore.
|
||||
//!
|
||||
@ -43,14 +43,13 @@
|
||||
//!
|
||||
//! For binary semaphores:
|
||||
//! - When a semaphore signal operation is executed, the semaphore must be in the unsignaled state.
|
||||
//! In other words, the same semaphore cannot be signalled by multiple commands;
|
||||
//! there must always be a wait operation in between them.
|
||||
//! - There must never be more than one semaphore wait operation executing on the same semaphore
|
||||
//! at the same time.
|
||||
//! - When a semaphore wait operation is queued as part of a command,
|
||||
//! the semaphore must already be in the signaled state, or
|
||||
//! the signal operation that it waits for must have been queued previously
|
||||
//! (as part of a previous command, or an earlier batch within the same command).
|
||||
//! In other words, the same semaphore cannot be signalled by multiple commands; there must
|
||||
//! always be a wait operation in between them.
|
||||
//! - There must never be more than one semaphore wait operation executing on the same semaphore at
|
||||
//! the same time.
|
||||
//! - When a semaphore wait operation is queued as part of a command, the semaphore must already be
|
||||
//! in the signaled state, or the signal operation that it waits for must have been queued
|
||||
//! previously (as part of a previous command, or an earlier batch within the same command).
|
||||
//!
|
||||
//! For timeline semaphores:
|
||||
//! - When a semaphore signal operation is executed, the new counter value of the semaphore must be
|
||||
@ -299,8 +298,8 @@ impl Semaphore {
|
||||
///
|
||||
/// # Safety
|
||||
///
|
||||
/// - The safety requirements for semaphores, as detailed in the module documentation,
|
||||
/// must be followed.
|
||||
/// - The safety requirements for semaphores, as detailed in the module documentation, must be
|
||||
/// followed.
|
||||
#[inline]
|
||||
pub unsafe fn signal(
|
||||
&self,
|
||||
@ -856,10 +855,9 @@ impl Semaphore {
|
||||
/// # Safety
|
||||
///
|
||||
/// - The semaphore must not be in use by the device.
|
||||
/// - If in `import_semaphore_fd_info`, `handle_type` is `ExternalHandleType::OpaqueFd`,
|
||||
/// then `file` must represent a binary semaphore that was exported from Vulkan or a
|
||||
/// compatible API, with a driver and device UUID equal to those of the device that owns
|
||||
/// `self`.
|
||||
/// - If in `import_semaphore_fd_info`, `handle_type` is `ExternalHandleType::OpaqueFd`, then
|
||||
/// `file` must represent a binary semaphore that was exported from Vulkan or a compatible
|
||||
/// API, with a driver and device UUID equal to those of the device that owns `self`.
|
||||
#[inline]
|
||||
pub unsafe fn import_fd(
|
||||
&self,
|
||||
|
Loading…
Reference in New Issue
Block a user