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servo/components/shared/compositing/rendering_context.rs
Martin Robinson 0caa271176
compositing: Combine webrender_traits and compositing_traits (#36372) 
These two traits both exposed different parts of the compositing API,
but now that the compositor doesn't depend directly on `script` any
longer and the `script_traits` crate has been split into the
`constellation_traits` crate, this can be finally be cleaned up without
causing circular dependencies. In addition, some unit tests for the
`IOPCompositor`'s scroll node tree are also moved into
`compositing_traits` as well.

Testing: This just combines two crates, so no new tests are necessary.
Fixes: #35984.
Signed-off-by: Martin Robinson <mrobinson@igalia.com>

Signed-off-by: Martin Robinson <mrobinson@igalia.com>
2025-04-06 17:34:18 +00:00

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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at https://mozilla.org/MPL/2.0/. */
#![deny(unsafe_code)]
use std::cell::{Cell, RefCell, RefMut};
use std::num::NonZeroU32;
use std::rc::Rc;
use std::sync::Arc;
use dpi::PhysicalSize;
use euclid::default::{Rect, Size2D as UntypedSize2D};
use euclid::{Point2D, Size2D};
use gleam::gl::{self, Gl};
use glow::NativeFramebuffer;
use image::RgbaImage;
use log::{debug, trace, warn};
use raw_window_handle::{DisplayHandle, WindowHandle};
pub use surfman::Error;
use surfman::chains::{PreserveBuffer, SwapChain};
use surfman::{
Adapter, Connection, Context, ContextAttributeFlags, ContextAttributes, Device, GLApi,
NativeContext, NativeWidget, Surface, SurfaceAccess, SurfaceInfo, SurfaceTexture, SurfaceType,
};
use webrender_api::units::{DeviceIntRect, DevicePixel};
/// The `RenderingContext` trait defines a set of methods for managing
/// an OpenGL or GLES rendering context.
/// Implementors of this trait are responsible for handling the creation,
/// management, and destruction of the rendering context and its associated
/// resources.
pub trait RenderingContext {
/// Prepare this [`RenderingContext`] to be rendered upon by Servo. For instance,
/// by binding a framebuffer to the current OpenGL context.
fn prepare_for_rendering(&self) {}
/// Read the contents of this [`Renderingcontext`] into an in-memory image. If the
/// image cannot be read (for instance, if no rendering has taken place yet), then
/// `None` is returned.
///
/// In a double-buffered [`RenderingContext`] this is expected to read from the back
/// buffer. That means that once Servo renders to the context, this should return those
/// results, even before [`RenderingContext::present`] is called.
fn read_to_image(&self, source_rectangle: DeviceIntRect) -> Option<RgbaImage>;
/// Get the current size of this [`RenderingContext`].
fn size(&self) -> PhysicalSize<u32>;
/// Get the current size of this [`RenderingContext`] as [`Size2D`].
fn size2d(&self) -> Size2D<u32, DevicePixel> {
let size = self.size();
Size2D::new(size.width, size.height)
}
/// Resizes the rendering surface to the given size.
fn resize(&self, size: PhysicalSize<u32>);
/// Presents the rendered frame to the screen. In a double-buffered context, this would
/// swap buffers.
fn present(&self);
/// Makes the context the current OpenGL context for this thread.
/// After calling this function, it is valid to use OpenGL rendering
/// commands.
fn make_current(&self) -> Result<(), Error>;
/// Returns the `gleam` version of the OpenGL or GLES API.
fn gleam_gl_api(&self) -> Rc<dyn gleam::gl::Gl>;
/// Returns the OpenGL or GLES API.
fn glow_gl_api(&self) -> Arc<glow::Context>;
/// Creates a texture from a given surface and returns the surface texture,
/// the OpenGL texture object, and the size of the surface. Default to `None`.
fn create_texture(
&self,
_surface: Surface,
) -> Option<(SurfaceTexture, u32, UntypedSize2D<i32>)> {
None
}
/// Destroys the texture and returns the surface. Default to `None`.
fn destroy_texture(&self, _surface_texture: SurfaceTexture) -> Option<Surface> {
None
}
/// The connection to the display server for WebGL. Default to `None`.
fn connection(&self) -> Option<Connection> {
None
}
}
/// A rendering context that uses the Surfman library to create and manage
/// the OpenGL context and surface. This struct provides the default implementation
/// of the `RenderingContext` trait, handling the creation, management, and destruction
/// of the rendering context and its associated resources.
///
/// The `SurfmanRenderingContext` struct encapsulates the necessary data and methods
/// to interact with the Surfman library, including creating surfaces, binding surfaces,
/// resizing surfaces, presenting rendered frames, and managing the OpenGL context state.
struct SurfmanRenderingContext {
gleam_gl: Rc<dyn Gl>,
glow_gl: Arc<glow::Context>,
device: RefCell<Device>,
context: RefCell<Context>,
}
impl Drop for SurfmanRenderingContext {
fn drop(&mut self) {
let device = &mut self.device.borrow_mut();
let context = &mut self.context.borrow_mut();
let _ = device.destroy_context(context);
}
}
impl SurfmanRenderingContext {
fn new(connection: &Connection, adapter: &Adapter) -> Result<Self, Error> {
let mut device = connection.create_device(adapter)?;
let flags = ContextAttributeFlags::ALPHA |
ContextAttributeFlags::DEPTH |
ContextAttributeFlags::STENCIL;
let gl_api = connection.gl_api();
let version = match &gl_api {
GLApi::GLES => surfman::GLVersion { major: 3, minor: 0 },
GLApi::GL => surfman::GLVersion { major: 3, minor: 2 },
};
let context_descriptor =
device.create_context_descriptor(&ContextAttributes { flags, version })?;
let context = device.create_context(&context_descriptor, None)?;
#[allow(unsafe_code)]
let gleam_gl = {
match gl_api {
GLApi::GL => unsafe {
gl::GlFns::load_with(|func_name| device.get_proc_address(&context, func_name))
},
GLApi::GLES => unsafe {
gl::GlesFns::load_with(|func_name| device.get_proc_address(&context, func_name))
},
}
};
#[allow(unsafe_code)]
let glow_gl = unsafe {
glow::Context::from_loader_function(|function_name| {
device.get_proc_address(&context, function_name)
})
};
Ok(SurfmanRenderingContext {
gleam_gl,
glow_gl: Arc::new(glow_gl),
device: RefCell::new(device),
context: RefCell::new(context),
})
}
fn create_surface(&self, surface_type: SurfaceType<NativeWidget>) -> Result<Surface, Error> {
let device = &mut self.device.borrow_mut();
let context = &self.context.borrow();
device.create_surface(context, SurfaceAccess::GPUOnly, surface_type)
}
fn bind_surface(&self, surface: Surface) -> Result<(), Error> {
let device = &self.device.borrow();
let context = &mut self.context.borrow_mut();
device
.bind_surface_to_context(context, surface)
.map_err(|(err, mut surface)| {
let _ = device.destroy_surface(context, &mut surface);
err
})?;
Ok(())
}
fn create_attached_swap_chain(&self) -> Result<SwapChain<Device>, Error> {
let device = &mut self.device.borrow_mut();
let context = &mut self.context.borrow_mut();
SwapChain::create_attached(device, context, SurfaceAccess::GPUOnly)
}
fn resize_surface(&self, size: PhysicalSize<u32>) -> Result<(), Error> {
let size = Size2D::new(size.width as i32, size.height as i32);
let device = &mut self.device.borrow_mut();
let context = &mut self.context.borrow_mut();
let mut surface = device.unbind_surface_from_context(context)?.unwrap();
device.resize_surface(context, &mut surface, size)?;
device
.bind_surface_to_context(context, surface)
.map_err(|(err, mut surface)| {
let _ = device.destroy_surface(context, &mut surface);
err
})
}
fn present_bound_surface(&self) -> Result<(), Error> {
let device = &self.device.borrow();
let context = &mut self.context.borrow_mut();
let mut surface = device.unbind_surface_from_context(context)?.unwrap();
device.present_surface(context, &mut surface)?;
device
.bind_surface_to_context(context, surface)
.map_err(|(err, mut surface)| {
let _ = device.destroy_surface(context, &mut surface);
err
})
}
#[allow(dead_code)]
fn native_context(&self) -> NativeContext {
let device = &self.device.borrow();
let context = &self.context.borrow();
device.native_context(context)
}
fn framebuffer(&self) -> Option<NativeFramebuffer> {
let device = &self.device.borrow();
let context = &self.context.borrow();
device
.context_surface_info(context)
.unwrap_or(None)
.and_then(|info| info.framebuffer_object)
}
fn prepare_for_rendering(&self) {
let framebuffer_id = self
.framebuffer()
.map_or(0, |framebuffer| framebuffer.0.into());
self.gleam_gl
.bind_framebuffer(gleam::gl::FRAMEBUFFER, framebuffer_id);
}
fn read_to_image(&self, source_rectangle: DeviceIntRect) -> Option<RgbaImage> {
let framebuffer_id = self
.framebuffer()
.map_or(0, |framebuffer| framebuffer.0.into());
Framebuffer::read_framebuffer_to_image(&self.gleam_gl, framebuffer_id, source_rectangle)
}
fn make_current(&self) -> Result<(), Error> {
let device = &self.device.borrow();
let context = &mut self.context.borrow();
device.make_context_current(context)
}
fn create_texture(
&self,
surface: Surface,
) -> Option<(SurfaceTexture, u32, UntypedSize2D<i32>)> {
let device = &self.device.borrow();
let context = &mut self.context.borrow_mut();
let SurfaceInfo {
id: front_buffer_id,
size,
..
} = device.surface_info(&surface);
debug!("... getting texture for surface {:?}", front_buffer_id);
let surface_texture = device.create_surface_texture(context, surface).unwrap();
let gl_texture = device
.surface_texture_object(&surface_texture)
.map(|tex| tex.0.get())
.unwrap_or(0);
Some((surface_texture, gl_texture, size))
}
fn destroy_texture(&self, surface_texture: SurfaceTexture) -> Option<Surface> {
let device = &self.device.borrow();
let context = &mut self.context.borrow_mut();
device
.destroy_surface_texture(context, surface_texture)
.map_err(|(error, _)| error)
.ok()
}
fn connection(&self) -> Option<Connection> {
Some(self.device.borrow().connection())
}
}
/// A software rendering context that uses a software OpenGL implementation to render
/// Servo. This will generally have bad performance, but can be used in situations where
/// it is more convenient to have consistent, but slower display output.
///
/// The results of the render can be accessed via [`RenderingContext::read_to_image`].
pub struct SoftwareRenderingContext {
size: Cell<PhysicalSize<u32>>,
surfman_rendering_info: SurfmanRenderingContext,
swap_chain: SwapChain<Device>,
}
impl SoftwareRenderingContext {
pub fn new(size: PhysicalSize<u32>) -> Result<Self, Error> {
let connection = Connection::new()?;
let adapter = connection.create_software_adapter()?;
let surfman_rendering_info = SurfmanRenderingContext::new(&connection, &adapter)?;
let surfman_size = Size2D::new(size.width as i32, size.height as i32);
let surface =
surfman_rendering_info.create_surface(SurfaceType::Generic { size: surfman_size })?;
surfman_rendering_info.bind_surface(surface)?;
surfman_rendering_info.make_current()?;
let swap_chain = surfman_rendering_info.create_attached_swap_chain()?;
Ok(SoftwareRenderingContext {
size: Cell::new(size),
surfman_rendering_info,
swap_chain,
})
}
}
impl Drop for SoftwareRenderingContext {
fn drop(&mut self) {
let device = &mut self.surfman_rendering_info.device.borrow_mut();
let context = &mut self.surfman_rendering_info.context.borrow_mut();
let _ = self.swap_chain.destroy(device, context);
}
}
impl RenderingContext for SoftwareRenderingContext {
fn prepare_for_rendering(&self) {
self.surfman_rendering_info.prepare_for_rendering();
}
fn read_to_image(&self, source_rectangle: DeviceIntRect) -> Option<RgbaImage> {
self.surfman_rendering_info.read_to_image(source_rectangle)
}
fn size(&self) -> PhysicalSize<u32> {
self.size.get()
}
fn resize(&self, size: PhysicalSize<u32>) {
if self.size.get() == size {
return;
}
self.size.set(size);
let device = &mut self.surfman_rendering_info.device.borrow_mut();
let context = &mut self.surfman_rendering_info.context.borrow_mut();
let size = Size2D::new(size.width as i32, size.height as i32);
let _ = self.swap_chain.resize(device, context, size);
}
fn present(&self) {
let device = &mut self.surfman_rendering_info.device.borrow_mut();
let context = &mut self.surfman_rendering_info.context.borrow_mut();
let _ = self
.swap_chain
.swap_buffers(device, context, PreserveBuffer::No);
}
fn make_current(&self) -> Result<(), Error> {
self.surfman_rendering_info.make_current()
}
fn gleam_gl_api(&self) -> Rc<dyn gleam::gl::Gl> {
self.surfman_rendering_info.gleam_gl.clone()
}
fn glow_gl_api(&self) -> Arc<glow::Context> {
self.surfman_rendering_info.glow_gl.clone()
}
fn create_texture(
&self,
surface: Surface,
) -> Option<(SurfaceTexture, u32, UntypedSize2D<i32>)> {
self.surfman_rendering_info.create_texture(surface)
}
fn destroy_texture(&self, surface_texture: SurfaceTexture) -> Option<Surface> {
self.surfman_rendering_info.destroy_texture(surface_texture)
}
fn connection(&self) -> Option<Connection> {
self.surfman_rendering_info.connection()
}
}
/// A [`RenderingContext`] that uses the `surfman` library to render to a
/// `raw-window-handle` identified window. `surfman` will attempt to create an
/// OpenGL context and surface for this window. This is a simple implementation
/// of the [`RenderingContext`] crate, but by default it paints to the entire window
/// surface.
///
/// If you would like to paint to only a portion of the window, consider using
/// [`OffscreenRenderingContext`] by calling [`WindowRenderingContext::offscreen_context`].
pub struct WindowRenderingContext {
size: Cell<PhysicalSize<u32>>,
surfman_context: SurfmanRenderingContext,
}
impl WindowRenderingContext {
pub fn new(
display_handle: DisplayHandle,
window_handle: WindowHandle,
size: PhysicalSize<u32>,
) -> Result<Self, Error> {
let connection = Connection::from_display_handle(display_handle)?;
let adapter = connection.create_adapter()?;
let surfman_context = SurfmanRenderingContext::new(&connection, &adapter)?;
let native_widget = connection
.create_native_widget_from_window_handle(
window_handle,
Size2D::new(size.width as i32, size.height as i32),
)
.expect("Failed to create native widget");
let surface = surfman_context.create_surface(SurfaceType::Widget { native_widget })?;
surfman_context.bind_surface(surface)?;
surfman_context.make_current()?;
Ok(Self {
size: Cell::new(size),
surfman_context,
})
}
pub fn offscreen_context(
self: &Rc<Self>,
size: PhysicalSize<u32>,
) -> OffscreenRenderingContext {
OffscreenRenderingContext::new(self.clone(), size)
}
/// Stop rendering to the window that was used to create this `WindowRenderingContext`
/// or last set with [`Self::set_window`].
///
/// TODO: This should be removed once `WebView`s can replace their `RenderingContext`s.
pub fn take_window(&self) -> Result<(), Error> {
let device = self.surfman_context.device.borrow_mut();
let mut context = self.surfman_context.context.borrow_mut();
let mut surface = device.unbind_surface_from_context(&mut context)?.unwrap();
device.destroy_surface(&mut context, &mut surface)?;
Ok(())
}
/// Replace the window that this [`WindowRenderingContext`] renders to and give it a new
/// size.
///
/// TODO: This should be removed once `WebView`s can replace their `RenderingContext`s.
pub fn set_window(
&self,
window_handle: WindowHandle,
size: PhysicalSize<u32>,
) -> Result<(), Error> {
let mut device = self.surfman_context.device.borrow_mut();
let mut context = self.surfman_context.context.borrow_mut();
let native_widget = device
.connection()
.create_native_widget_from_window_handle(
window_handle,
Size2D::new(size.width as i32, size.height as i32),
)
.expect("Failed to create native widget");
let surface_access = SurfaceAccess::GPUOnly;
let surface_type = SurfaceType::Widget { native_widget };
let surface = device.create_surface(&context, surface_access, surface_type)?;
device
.bind_surface_to_context(&mut context, surface)
.map_err(|(err, mut surface)| {
let _ = device.destroy_surface(&mut context, &mut surface);
err
})?;
device.make_context_current(&context)?;
Ok(())
}
pub fn surfman_details(&self) -> (RefMut<Device>, RefMut<Context>) {
(
self.surfman_context.device.borrow_mut(),
self.surfman_context.context.borrow_mut(),
)
}
}
impl RenderingContext for WindowRenderingContext {
fn prepare_for_rendering(&self) {
self.surfman_context.prepare_for_rendering();
}
fn read_to_image(&self, source_rectangle: DeviceIntRect) -> Option<RgbaImage> {
self.surfman_context.read_to_image(source_rectangle)
}
fn size(&self) -> PhysicalSize<u32> {
self.size.get()
}
fn resize(&self, size: PhysicalSize<u32>) {
match self.surfman_context.resize_surface(size) {
Ok(..) => self.size.set(size),
Err(error) => warn!("Error resizing surface: {error:?}"),
}
}
fn present(&self) {
if let Err(error) = self.surfman_context.present_bound_surface() {
warn!("Error presenting surface: {error:?}");
}
}
fn make_current(&self) -> Result<(), Error> {
self.surfman_context.make_current()
}
fn gleam_gl_api(&self) -> Rc<dyn gleam::gl::Gl> {
self.surfman_context.gleam_gl.clone()
}
fn glow_gl_api(&self) -> Arc<glow::Context> {
self.surfman_context.glow_gl.clone()
}
fn create_texture(
&self,
surface: Surface,
) -> Option<(SurfaceTexture, u32, UntypedSize2D<i32>)> {
self.surfman_context.create_texture(surface)
}
fn destroy_texture(&self, surface_texture: SurfaceTexture) -> Option<Surface> {
self.surfman_context.destroy_texture(surface_texture)
}
fn connection(&self) -> Option<Connection> {
self.surfman_context.connection()
}
}
struct Framebuffer {
gl: Rc<dyn Gl>,
framebuffer_id: gl::GLuint,
renderbuffer_id: gl::GLuint,
texture_id: gl::GLuint,
}
impl Framebuffer {
fn bind(&self) {
trace!("Binding FBO {}", self.framebuffer_id);
self.gl
.bind_framebuffer(gl::FRAMEBUFFER, self.framebuffer_id)
}
}
impl Drop for Framebuffer {
fn drop(&mut self) {
self.gl.bind_framebuffer(gl::FRAMEBUFFER, 0);
self.gl.delete_textures(&[self.texture_id]);
self.gl.delete_renderbuffers(&[self.renderbuffer_id]);
self.gl.delete_framebuffers(&[self.framebuffer_id]);
}
}
impl Framebuffer {
fn new(gl: Rc<dyn Gl>, size: PhysicalSize<u32>) -> Self {
let framebuffer_ids = gl.gen_framebuffers(1);
gl.bind_framebuffer(gl::FRAMEBUFFER, framebuffer_ids[0]);
let texture_ids = gl.gen_textures(1);
gl.bind_texture(gl::TEXTURE_2D, texture_ids[0]);
gl.tex_image_2d(
gl::TEXTURE_2D,
0,
gl::RGBA as gl::GLint,
size.width as gl::GLsizei,
size.height as gl::GLsizei,
0,
gl::RGBA,
gl::UNSIGNED_BYTE,
None,
);
gl.tex_parameter_i(
gl::TEXTURE_2D,
gl::TEXTURE_MAG_FILTER,
gl::NEAREST as gl::GLint,
);
gl.tex_parameter_i(
gl::TEXTURE_2D,
gl::TEXTURE_MIN_FILTER,
gl::NEAREST as gl::GLint,
);
gl.framebuffer_texture_2d(
gl::FRAMEBUFFER,
gl::COLOR_ATTACHMENT0,
gl::TEXTURE_2D,
texture_ids[0],
0,
);
gl.bind_texture(gl::TEXTURE_2D, 0);
let renderbuffer_ids = gl.gen_renderbuffers(1);
let depth_rb = renderbuffer_ids[0];
gl.bind_renderbuffer(gl::RENDERBUFFER, depth_rb);
gl.renderbuffer_storage(
gl::RENDERBUFFER,
gl::DEPTH_COMPONENT24,
size.width as gl::GLsizei,
size.height as gl::GLsizei,
);
gl.framebuffer_renderbuffer(
gl::FRAMEBUFFER,
gl::DEPTH_ATTACHMENT,
gl::RENDERBUFFER,
depth_rb,
);
Self {
gl,
framebuffer_id: *framebuffer_ids
.first()
.expect("Guaranteed by GL operations"),
renderbuffer_id: *renderbuffer_ids
.first()
.expect("Guaranteed by GL operations"),
texture_id: *texture_ids.first().expect("Guaranteed by GL operations"),
}
}
fn read_to_image(&self, source_rectangle: DeviceIntRect) -> Option<RgbaImage> {
Self::read_framebuffer_to_image(&self.gl, self.framebuffer_id, source_rectangle)
}
fn read_framebuffer_to_image(
gl: &Rc<dyn Gl>,
framebuffer_id: u32,
source_rectangle: DeviceIntRect,
) -> Option<RgbaImage> {
gl.bind_framebuffer(gl::FRAMEBUFFER, framebuffer_id);
// For some reason, OSMesa fails to render on the 3rd
// attempt in headless mode, under some conditions.
// I think this can only be some kind of synchronization
// bug in OSMesa, but explicitly un-binding any vertex
// array here seems to work around that bug.
// See https://github.com/servo/servo/issues/18606.
gl.bind_vertex_array(0);
let mut pixels = gl.read_pixels(
source_rectangle.min.x,
source_rectangle.min.y,
source_rectangle.width(),
source_rectangle.height(),
gl::RGBA,
gl::UNSIGNED_BYTE,
);
let gl_error = gl.get_error();
if gl_error != gl::NO_ERROR {
warn!("GL error code 0x{gl_error:x} set after read_pixels");
}
// flip image vertically (texture is upside down)
let source_rectangle = source_rectangle.to_usize();
let orig_pixels = pixels.clone();
let stride = source_rectangle.width() * 4;
for y in 0..source_rectangle.height() {
let dst_start = y * stride;
let src_start = (source_rectangle.height() - y - 1) * stride;
let src_slice = &orig_pixels[src_start..src_start + stride];
pixels[dst_start..dst_start + stride].clone_from_slice(&src_slice[..stride]);
}
RgbaImage::from_raw(
source_rectangle.width() as u32,
source_rectangle.height() as u32,
pixels,
)
}
}
pub struct OffscreenRenderingContext {
parent_context: Rc<WindowRenderingContext>,
size: Cell<PhysicalSize<u32>>,
framebuffer: RefCell<Framebuffer>,
}
type RenderToParentCallback = Box<dyn Fn(&glow::Context, Rect<i32>) + Send + Sync>;
impl OffscreenRenderingContext {
fn new(parent_context: Rc<WindowRenderingContext>, size: PhysicalSize<u32>) -> Self {
let framebuffer = RefCell::new(Framebuffer::new(parent_context.gleam_gl_api(), size));
Self {
parent_context,
size: Cell::new(size),
framebuffer,
}
}
pub fn parent_context(&self) -> &WindowRenderingContext {
&self.parent_context
}
pub fn render_to_parent_callback(&self) -> Option<RenderToParentCallback> {
// Don't accept a `None` context for the source framebuffer.
let front_framebuffer_id =
NonZeroU32::new(self.framebuffer.borrow().framebuffer_id).map(NativeFramebuffer)?;
let parent_context_framebuffer_id = self.parent_context.surfman_context.framebuffer();
let size = self.size.get();
let size = Size2D::new(size.width as i32, size.height as i32);
Some(Box::new(move |gl, target_rect| {
Self::blit_framebuffer(
gl,
Rect::new(Point2D::origin(), size.to_i32()),
front_framebuffer_id,
target_rect,
parent_context_framebuffer_id,
);
}))
}
#[allow(unsafe_code)]
fn blit_framebuffer(
gl: &glow::Context,
source_rect: Rect<i32>,
source_framebuffer_id: NativeFramebuffer,
target_rect: Rect<i32>,
target_framebuffer_id: Option<NativeFramebuffer>,
) {
use glow::HasContext as _;
unsafe {
gl.clear_color(0.0, 0.0, 0.0, 0.0);
gl.scissor(
target_rect.origin.x,
target_rect.origin.y,
target_rect.width(),
target_rect.height(),
);
gl.enable(gl::SCISSOR_TEST);
gl.clear(gl::COLOR_BUFFER_BIT);
gl.disable(gl::SCISSOR_TEST);
gl.bind_framebuffer(gl::READ_FRAMEBUFFER, Some(source_framebuffer_id));
gl.bind_framebuffer(gl::DRAW_FRAMEBUFFER, target_framebuffer_id);
gl.blit_framebuffer(
source_rect.origin.x,
source_rect.origin.y,
source_rect.origin.x + source_rect.width(),
source_rect.origin.y + source_rect.height(),
target_rect.origin.x,
target_rect.origin.y,
target_rect.origin.x + target_rect.width(),
target_rect.origin.y + target_rect.height(),
gl::COLOR_BUFFER_BIT,
gl::NEAREST,
);
gl.bind_framebuffer(gl::FRAMEBUFFER, target_framebuffer_id);
}
}
}
impl RenderingContext for OffscreenRenderingContext {
fn size(&self) -> PhysicalSize<u32> {
self.size.get()
}
fn resize(&self, new_size: PhysicalSize<u32>) {
let old_size = self.size.get();
if old_size == new_size {
return;
}
let gl = self.parent_context.gleam_gl_api();
let new_framebuffer = Framebuffer::new(gl.clone(), new_size);
let old_framebuffer =
std::mem::replace(&mut *self.framebuffer.borrow_mut(), new_framebuffer);
self.size.set(new_size);
let blit_size = new_size.min(old_size);
let rect = Rect::new(
Point2D::origin(),
Size2D::new(blit_size.width, blit_size.height),
)
.to_i32();
let Some(old_framebuffer_id) =
NonZeroU32::new(old_framebuffer.framebuffer_id).map(NativeFramebuffer)
else {
return;
};
let new_framebuffer_id =
NonZeroU32::new(self.framebuffer.borrow().framebuffer_id).map(NativeFramebuffer);
Self::blit_framebuffer(
&self.glow_gl_api(),
rect,
old_framebuffer_id,
rect,
new_framebuffer_id,
);
}
fn prepare_for_rendering(&self) {
self.framebuffer.borrow().bind();
}
fn present(&self) {}
fn make_current(&self) -> Result<(), surfman::Error> {
self.parent_context.make_current()
}
fn gleam_gl_api(&self) -> Rc<dyn gleam::gl::Gl> {
self.parent_context.gleam_gl_api()
}
fn glow_gl_api(&self) -> Arc<glow::Context> {
self.parent_context.glow_gl_api()
}
fn create_texture(
&self,
surface: Surface,
) -> Option<(SurfaceTexture, u32, UntypedSize2D<i32>)> {
self.parent_context.create_texture(surface)
}
fn destroy_texture(&self, surface_texture: SurfaceTexture) -> Option<Surface> {
self.parent_context.destroy_texture(surface_texture)
}
fn connection(&self) -> Option<Connection> {
self.parent_context.connection()
}
fn read_to_image(&self, source_rectangle: DeviceIntRect) -> Option<RgbaImage> {
self.framebuffer.borrow().read_to_image(source_rectangle)
}
}
#[cfg(test)]
mod test {
use dpi::PhysicalSize;
use euclid::{Box2D, Point2D, Size2D};
use gleam::gl;
use image::Rgba;
use surfman::{Connection, ContextAttributeFlags, ContextAttributes, Error, GLApi, GLVersion};
use super::Framebuffer;
#[test]
#[allow(unsafe_code)]
fn test_read_pixels() -> Result<(), Error> {
let connection = Connection::new()?;
let adapter = connection.create_software_adapter()?;
let mut device = connection.create_device(&adapter)?;
let context_descriptor = device.create_context_descriptor(&ContextAttributes {
version: GLVersion::new(3, 0),
flags: ContextAttributeFlags::empty(),
})?;
let mut context = device.create_context(&context_descriptor, None)?;
let gl = match connection.gl_api() {
GLApi::GL => unsafe { gl::GlFns::load_with(|s| device.get_proc_address(&context, s)) },
GLApi::GLES => unsafe {
gl::GlesFns::load_with(|s| device.get_proc_address(&context, s))
},
};
device.make_context_current(&context)?;
{
const SIZE: u32 = 16;
let framebuffer = Framebuffer::new(gl, PhysicalSize::new(SIZE, SIZE));
framebuffer.bind();
framebuffer
.gl
.clear_color(12.0 / 255.0, 34.0 / 255.0, 56.0 / 255.0, 78.0 / 255.0);
framebuffer.gl.clear(gl::COLOR_BUFFER_BIT);
let rect = Box2D::from_origin_and_size(Point2D::zero(), Size2D::new(SIZE, SIZE));
let img = framebuffer
.read_to_image(rect.to_i32())
.expect("Should have been able to read back image.");
assert_eq!(img.width(), SIZE);
assert_eq!(img.height(), SIZE);
let expected_pixel: Rgba<u8> = Rgba([12, 34, 56, 78]);
assert!(img.pixels().all(|&p| p == expected_pixel));
}
device.destroy_context(&mut context)?;
Ok(())
}
}
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