src/util.rs - external/github.com/linebender/vello - Git at Google

 // Copyright 2022 Google LLC
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     https://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 //
 // Also licensed under MIT license, at your choice.

 //! Simple helpers for managing wgpu state and surfaces.

 use std::future::Future;

 use super::Result;

 use raw_window_handle::{HasRawDisplayHandle, HasRawWindowHandle};
 use wgpu::{
     Adapter, Device, Instance, Limits, Queue, RequestAdapterOptions, Surface, SurfaceConfiguration,
 };

 /// Simple render context that maintains wgpu state for rendering the pipeline.
 pub struct RenderContext {
     pub instance: Instance,
     pub devices: Vec<DeviceHandle>,
 }

 pub struct DeviceHandle {
     adapter: Adapter,
     pub device: Device,
     pub queue: Queue,
 }

 impl RenderContext {
     pub fn new() -> Result<Self> {
         let instance = Instance::new(wgpu::Backends::PRIMARY);
         Ok(Self {
             instance,
             devices: Vec::new(),
         })
     }

     /// Creates a new surface for the specified window and dimensions.
     pub async fn create_surface<W>(&mut self, window: &W, width: u32, height: u32) -> RenderSurface
     where
         W: HasRawWindowHandle + HasRawDisplayHandle,
     {
         let surface = unsafe { self.instance.create_surface(window) };
         let format = wgpu::TextureFormat::Bgra8Unorm;
         let config = wgpu::SurfaceConfiguration {
             usage: wgpu::TextureUsages::RENDER_ATTACHMENT,
             format,
             width,
             height,
             present_mode: wgpu::PresentMode::Fifo,
             alpha_mode: wgpu::CompositeAlphaMode::Auto,
         };
         let dev_id = self.device(Some(&surface)).await.unwrap();
         surface.configure(&self.devices[dev_id].device, &config);
         RenderSurface {
             surface,
             config,
             dev_id,
         }
     }

     /// Resizes the surface to the new dimensions.
     pub fn resize_surface(&self, surface: &mut RenderSurface, width: u32, height: u32) {
         surface.config.width = width;
         surface.config.height = height;
         surface
             .surface
             .configure(&self.devices[surface.dev_id].device, &surface.config);
     }

     /// Finds or creates a compatible device handle id.
     async fn device(&mut self, compatible_surface: Option<&Surface>) -> Option<usize> {
         let compatible = match compatible_surface {
             Some(s) => self
                 .devices
                 .iter()
                 .enumerate()
                 .find(|(_, d)| d.adapter.is_surface_supported(s))
                 .map(|(i, _)| i),
             None => (!self.devices.is_empty()).then_some(0),
         };
         if compatible.is_none() {
             return self.new_device(compatible_surface).await;
         }
         compatible
     }

     /// Creates a compatible device handle id.
     async fn new_device(&mut self, compatible_surface: Option<&Surface>) -> Option<usize> {
         let adapter = wgpu::util::initialize_adapter_from_env_or_default(
             &self.instance,
             wgpu::Backends::PRIMARY,
             compatible_surface,
         )
         .await?;
         let features = adapter.features();
         let limits = Limits::default();
         let (device, queue) = adapter
             .request_device(
                 &wgpu::DeviceDescriptor {
                     label: None,
                     features: features
                         & (wgpu::Features::TIMESTAMP_QUERY | wgpu::Features::CLEAR_TEXTURE),
                     limits,
                 },
                 None,
             )
             .await
             .ok()?;
         let device_handle = DeviceHandle {
             adapter,
             device,
             queue,
         };
         self.devices.push(device_handle);
         Some(self.devices.len() - 1)
     }
 }

 /// Combination of surface and its configuration.
 pub struct RenderSurface {
     pub surface: Surface,
     pub config: SurfaceConfiguration,
     pub dev_id: usize,
 }

 struct NullWake;

 impl std::task::Wake for NullWake {
     fn wake(self: std::sync::Arc<Self>) {}
 }

 /// Block on a future, polling the device as needed.
 ///
 /// This will deadlock if the future is awaiting anything other than GPU progress.
 pub fn block_on_wgpu<F: Future>(device: &Device, mut fut: F) -> F::Output {
     let waker = std::task::Waker::from(std::sync::Arc::new(NullWake));
     let mut context = std::task::Context::from_waker(&waker);
     // Same logic as `pin_mut!` macro from `pin_utils`.
     let mut fut = unsafe { std::pin::Pin::new_unchecked(&mut fut) };
     loop {
         match fut.as_mut().poll(&mut context) {
             std::task::Poll::Pending => {
                 device.poll(wgpu::Maintain::Wait);
             }
             std::task::Poll::Ready(item) => break item,
         }
     }
 }
	// Copyright 2022 Google LLC
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// https://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.
	//
	// Also licensed under MIT license, at your choice.

	//! Simple helpers for managing wgpu state and surfaces.

	use std::future::Future;

	use super::Result;

	use raw_window_handle::{HasRawDisplayHandle, HasRawWindowHandle};
	use wgpu::{
	Adapter, Device, Instance, Limits, Queue, RequestAdapterOptions, Surface, SurfaceConfiguration,
	};

	/// Simple render context that maintains wgpu state for rendering the pipeline.
	pub struct RenderContext {
	pub instance: Instance,
	pub devices: Vec<DeviceHandle>,
	}

	pub struct DeviceHandle {
	adapter: Adapter,
	pub device: Device,
	pub queue: Queue,
	}

	impl RenderContext {
	pub fn new() -> Result<Self> {
	let instance = Instance::new(wgpu::Backends::PRIMARY);
	Ok(Self {
	instance,
	devices: Vec::new(),
	})
	}

	/// Creates a new surface for the specified window and dimensions.
	pub async fn create_surface<W>(&mut self, window: &W, width: u32, height: u32) -> RenderSurface
	where
	W: HasRawWindowHandle + HasRawDisplayHandle,
	{
	let surface = unsafe { self.instance.create_surface(window) };
	let format = wgpu::TextureFormat::Bgra8Unorm;
	let config = wgpu::SurfaceConfiguration {
	usage: wgpu::TextureUsages::RENDER_ATTACHMENT,
	format,
	width,
	height,
	present_mode: wgpu::PresentMode::Fifo,
	alpha_mode: wgpu::CompositeAlphaMode::Auto,
	};
	let dev_id = self.device(Some(&surface)).await.unwrap();
	surface.configure(&self.devices[dev_id].device, &config);
	RenderSurface {
	surface,
	config,
	dev_id,
	}
	}

	/// Resizes the surface to the new dimensions.
	pub fn resize_surface(&self, surface: &mut RenderSurface, width: u32, height: u32) {
	surface.config.width = width;
	surface.config.height = height;
	surface
	.surface
	.configure(&self.devices[surface.dev_id].device, &surface.config);
	}

	/// Finds or creates a compatible device handle id.
	async fn device(&mut self, compatible_surface: Option<&Surface>) -> Option<usize> {
	let compatible = match compatible_surface {
	Some(s) => self
	.devices
	.iter()
	.enumerate()
	.find(\|(_, d)\| d.adapter.is_surface_supported(s))
	.map(\|(i, _)\| i),
	None => (!self.devices.is_empty()).then_some(0),
	};
	if compatible.is_none() {
	return self.new_device(compatible_surface).await;
	}
	compatible
	}

	/// Creates a compatible device handle id.
	async fn new_device(&mut self, compatible_surface: Option<&Surface>) -> Option<usize> {
	let adapter = wgpu::util::initialize_adapter_from_env_or_default(
	&self.instance,
	wgpu::Backends::PRIMARY,
	compatible_surface,
	)
	.await?;
	let features = adapter.features();
	let limits = Limits::default();
	let (device, queue) = adapter
	.request_device(
	&wgpu::DeviceDescriptor {
	label: None,
	features: features
	& (wgpu::Features::TIMESTAMP_QUERY \| wgpu::Features::CLEAR_TEXTURE),
	limits,
	},
	None,
	)
	.await
	.ok()?;
	let device_handle = DeviceHandle {
	adapter,
	device,
	queue,
	};
	self.devices.push(device_handle);
	Some(self.devices.len() - 1)
	}
	}

	/// Combination of surface and its configuration.
	pub struct RenderSurface {
	pub surface: Surface,
	pub config: SurfaceConfiguration,
	pub dev_id: usize,
	}

	struct NullWake;

	impl std::task::Wake for NullWake {
	fn wake(self: std::sync::Arc<Self>) {}
	}

	/// Block on a future, polling the device as needed.
	///
	/// This will deadlock if the future is awaiting anything other than GPU progress.
	pub fn block_on_wgpu<F: Future>(device: &Device, mut fut: F) -> F::Output {
	let waker = std::task::Waker::from(std::sync::Arc::new(NullWake));
	let mut context = std::task::Context::from_waker(&waker);
	// Same logic as `pin_mut!` macro from `pin_utils`.
	let mut fut = unsafe { std::pin::Pin::new_unchecked(&mut fut) };
	loop {
	match fut.as_mut().poll(&mut context) {
	std::task::Poll::Pending => {
	device.poll(wgpu::Maintain::Wait);
	}
	std::task::Poll::Ready(item) => break item,
	}
	}
	}