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Quelle render_target.rs
Sprache: unbekannt
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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 http://mozilla.org/MPL/2.0/. */
use api::units::*;
use api::{ColorF, LineOrientation, BorderStyle};
use crate::batch::{AlphaBatchBuilder, AlphaBatchContainer, BatchTextures};
use crate::batch::{ClipBatcher, BatchBuilder, INVALID_SEGMENT_INDEX, ClipMaskInstanc eList};
use crate::command_buffer::{CommandBufferList, QuadFlags};
use crate::pattern::{Pattern, PatternKind, PatternShaderInput};
use crate::segment::EdgeAaSegmentMask;
use crate::spatial_tree::SpatialTree;
use crate::clip::{ClipStore, ClipItemKind};
use crate::frame_builder::FrameGlobalResources;
use crate::gpu_cache::{GpuCache, GpuCacheAddress};
use crate::gpu_types::{BorderInstance, SvgFilterInstance, SVGFEFilterInstance, BlurDirection, BlurInstance, PrimitiveHeaders, ScalingInstance};
use crate::gpu_types::{TransformPalette, ZBufferIdGenerator, MaskInstance, ClipSpace};
use crate::gpu_types::{ZBufferId, QuadSegment, PrimitiveInstanceData, TransformPaletteId};
use crate::internal_types::{CacheTextureId, FastHashMap, FilterGraphOp, FrameAllocator, FrameMemory, FrameVec, TextureSource};
use crate::picture::{SliceId, SurfaceInfo, ResolvedSurfaceTexture, TileCacheInstance};
use crate::quad;
use crate::prim_store::{PrimitiveInstance, PrimitiveStore, PrimitiveScratchBuffer};
use crate::prim_store::gradient::{
FastLinearGradientInstance, LinearGradientInstance, RadialGradientInstance,
ConicGradientInstance,
};
use crate::renderer::{GpuBufferAddress, GpuBufferBuilder};
use crate::render_backend::DataStores;
use crate::render_task::{RenderTaskKind, RenderTaskAddress, SubPass};
use crate::render_task::{RenderTask, ScalingTask, SvgFilterInfo, MaskSubPass, SVGFEFilterTask};
use crate::render_task_graph::{RenderTaskGraph, RenderTaskId};
use crate::resource_cache::ResourceCache;
use crate::spatial_tree::SpatialNodeIndex;
use crate::util::ScaleOffset;
const STYLE_SOLID: i32 = ((BorderStyle::Solid as i32) << 8) | ((BorderStyle::Solid as i32) << 16);
const STYLE_MASK: i32 = 0x00FF_FF00;
/// A tag used to identify the output format of a `RenderTarget`.
#[derive(Debug, Copy, Clone, Eq, PartialEq, Hash)]
#[cfg_attr(feature = "capture", derive(Serialize))]
#[cfg_attr(feature = "replay", derive(Deserialize))]
pub enum RenderTargetKind {
Color, // RGBA8
Alpha, // R8
}
pub struct RenderTargetContext<'a, 'rc> {
pub global_device_pixel_scale: DevicePixelScale,
pub prim_store: &'a PrimitiveStore,
pub clip_store: &'a ClipStore,
pub resource_cache: &'rc mut ResourceCache,
pub use_dual_source_blending: bool,
pub use_advanced_blending: bool,
pub break_advanced_blend_batches: bool,
pub batch_lookback_count: usize,
pub spatial_tree: &'a SpatialTree,
pub data_stores: &'a DataStores,
pub surfaces: &'a [SurfaceInfo],
pub scratch: &'a PrimitiveScratchBuffer,
pub screen_world_rect: WorldRect,
pub globals: &'a FrameGlobalResources,
pub tile_caches: &'a FastHashMap<SliceId, Box<TileCacheInstance>>,
pub root_spatial_node_index: SpatialNodeIndex,
pub frame_memory: &'a mut FrameMemory,
}
/// A series of `RenderTarget` instances, serving as the high-level container
/// into which `RenderTasks` are assigned.
///
/// During the build phase, we iterate over the tasks in each `RenderPass`. For
/// each task, we invoke `allocate()` on the `RenderTargetList`, which in turn
/// attempts to allocate an output region in the last `RenderTarget` in the
/// list. If allocation fails (or if the list is empty), a new `RenderTarget` is
/// created and appended to the list. The build phase then assign the task into
/// the target associated with the final allocation.
///
/// The result is that each `RenderPass` is associated with one or two
/// `RenderTargetLists`, depending on whether we have all our tasks have the
/// same `RenderTargetKind`. The lists are then shipped to the `Renderer`, which
/// allocates a device texture array, with one slice per render target in the
/// list.
///
/// The upshot of this scheme is that it maximizes batching. In a given pass,
/// we need to do a separate batch for each individual render target. But with
/// the texture array, we can expose the entirety of the previous pass to each
/// task in the current pass in a single batch, which generally allows each
/// task to be drawn in a single batch regardless of how many results from the
/// previous pass it depends on.
///
/// Note that in some cases (like drop-shadows), we can depend on the output of
/// a pass earlier than the immediately-preceding pass.
#[cfg_attr(feature = "capture", derive(Serialize))]
#[cfg_attr(feature = "replay", derive(Deserialize))]
pub struct RenderTargetList {
pub targets: FrameVec<RenderTarget>,
}
impl RenderTargetList {
pub fn new(allocator: FrameAllocator) -> Self {
RenderTargetList {
targets: allocator.new_vec(),
}
}
pub fn build(
&mut self,
ctx: &mut RenderTargetContext,
gpu_cache: &mut GpuCache,
render_tasks: &RenderTaskGraph,
prim_headers: &mut PrimitiveHeaders,
transforms: &mut TransformPalette,
z_generator: &mut ZBufferIdGenerator,
prim_instances: &[PrimitiveInstance],
cmd_buffers: &CommandBufferList,
gpu_buffer_builder: &mut GpuBufferBuilder,
) {
if self.targets.is_empty() {
return;
}
for target in &mut self.targets {
target.build(
ctx,
gpu_cache,
render_tasks,
prim_headers,
transforms,
z_generator,
prim_instances,
cmd_buffers,
gpu_buffer_builder,
);
}
}
}
const NUM_PATTERNS: usize = crate::pattern::NUM_PATTERNS as usize;
/// Contains the work (in the form of instance arrays) needed to fill a color
/// color (RGBA8) or alpha output surface.
///
/// In graphics parlance, a "render target" usually means "a surface (texture or
/// framebuffer) bound to the output of a shader". This struct has a slightly
/// different meaning, in that it represents the operations on that surface
/// _before_ it's actually bound and rendered. So a `RenderTarget` is built by
/// the `RenderBackend` by inserting tasks, and then shipped over to the
/// `Renderer` where a device surface is resolved and the tasks are transformed
/// into draw commands on that surface.
#[cfg_attr(feature = "capture", derive(Serialize))]
#[cfg_attr(feature = "replay", derive(Deserialize))]
pub struct RenderTarget {
pub target_kind: RenderTargetKind,
pub cached: bool,
screen_size: DeviceIntSize,
pub texture_id: CacheTextureId,
pub alpha_batch_containers: FrameVec<AlphaBatchContainer>,
// List of blur operations to apply for this render target.
pub vertical_blurs: FastHashMap<TextureSource, FrameVec<BlurInstance>>,
pub horizontal_blurs: FastHashMap<TextureSource, FrameVec<BlurInstance>>,
pub scalings: FastHashMap<TextureSource, FrameVec<ScalingInstance>>,
pub svg_filters: FrameVec<(BatchTextures, FrameVec<SvgFilterInstance>)>,
pub svg_nodes: FrameVec<(BatchTextures, FrameVec<SVGFEFilterInstance>)>,
pub blits: FrameVec<BlitJob>,
alpha_tasks: FrameVec<RenderTaskId>,
pub resolve_ops: FrameVec<ResolveOp>,
pub prim_instances: [FastHashMap<TextureSource, FrameVec<PrimitiveInstanceData>>; NUM_PATTERNS],
pub prim_instances_with_scissor: FastHashMap<(DeviceIntRect, PatternKind), FastHashMap<TextureSource, FrameVec<PrimitiveInstanceData>>>,
pub clip_masks: ClipMaskInstanceList,
pub border_segments_complex: FrameVec<BorderInstance>,
pub border_segments_solid: FrameVec<BorderInstance>,
pub line_decorations: FrameVec<LineDecorationJob>,
pub fast_linear_gradients: FrameVec<FastLinearGradientInstance>,
pub linear_gradients: FrameVec<LinearGradientInstance>,
pub radial_gradients: FrameVec<RadialGradientInstance>,
pub conic_gradients: FrameVec<ConicGradientInstance>,
pub clip_batcher: ClipBatcher,
// Clearing render targets has a fair amount of special cases.
// The general rules are:
// - Depth (for at least the used potion of the target) is always cleared if it
// is used by the target. The rest of this explaination focuses on clearing
// color/alpha textures.
// - For non-cached targets we either clear the entire target or the used portion
// (unless clear_color is None).
// - Cached render targets require precise partial clears which are specified
// via the vectors below (if clearing is needed at all).
//
// See also: Renderer::clear_render_target
// Areas that *must* be cleared.
// Even if a global target clear is done, we try to honor clearing the rects that
// have a different color than the global clear color.
pub clears: FrameVec<(DeviceIntRect, ColorF)>,
// Optionally track the used rect of the render target, to give the renderer
// an opportunity to only clear the used portion of the target as an optimization.
// Note: We make the simplifying assumption that if clear vectors AND used_rect
// are specified, then the rects from the clear vectors are contained in
// used_rect.
pub used_rect: Option<DeviceIntRect>,
// The global clear color is Some(TRANSPARENT) by default. If we are drawing
// a single render task in this target, it can be set to something else.
// If clear_color is None, only the clears/zero_clears/one_clears are done.
pub clear_color: Option<ColorF>,
}
impl RenderTarget {
pub fn new(
target_kind: RenderTargetKind,
cached: bool,
texture_id: CacheTextureId,
screen_size: DeviceIntSize,
gpu_supports_fast_clears: bool,
used_rect: Option<DeviceIntRect>,
memory: &FrameMemory,
) -> Self {
RenderTarget {
target_kind,
cached,
screen_size,
texture_id,
alpha_batch_containers: memory.new_vec(),
vertical_blurs: FastHashMap::default(),
horizontal_blurs: FastHashMap::default(),
scalings: FastHashMap::default(),
svg_filters: memory.new_vec(),
svg_nodes: memory.new_vec(),
blits: memory.new_vec(),
alpha_tasks: memory.new_vec(),
used_rect,
resolve_ops: memory.new_vec(),
clear_color: Some(ColorF::TRANSPARENT),
prim_instances: [FastHashMap::default(), FastHashMap::default(), FastHashMap::default(), FastHashMap::default()],
prim_instances_with_scissor: FastHashMap::default(),
clip_masks: ClipMaskInstanceList::new(memory),
clip_batcher: ClipBatcher::new(gpu_supports_fast_clears, memory),
border_segments_complex: memory.new_vec(),
border_segments_solid: memory.new_vec(),
clears: memory.new_vec(),
line_decorations: memory.new_vec(),
fast_linear_gradients: memory.new_vec(),
linear_gradients: memory.new_vec(),
radial_gradients: memory.new_vec(),
conic_gradients: memory.new_vec(),
}
}
pub fn build(
&mut self,
ctx: &mut RenderTargetContext,
gpu_cache: &mut GpuCache,
render_tasks: &RenderTaskGraph,
prim_headers: &mut PrimitiveHeaders,
transforms: &mut TransformPalette,
z_generator: &mut ZBufferIdGenerator,
prim_instances: &[PrimitiveInstance],
cmd_buffers: &CommandBufferList,
gpu_buffer_builder: &mut GpuBufferBuilder,
) {
profile_scope!("build");
let mut merged_batches = AlphaBatchContainer::new(None, &ctx.frame_memory);
for task_id in &self.alpha_tasks {
profile_scope!("alpha_task");
let task = &render_tasks[*task_id];
match task.kind {
RenderTaskKind::Picture(ref pic_task) => {
let target_rect = task.get_target_rect();
let scissor_rect = if pic_task.can_merge {
None
} else {
Some(target_rect)
};
if !pic_task.can_use_shared_surface {
self.clear_color = pic_task.clear_color;
}
if let Some(clear_color) = pic_task.clear_color {
self.clears.push((target_rect, clear_color));
} else if self.cached {
self.clears.push((target_rect, ColorF::TRANSPARENT));
}
// TODO(gw): The type names of AlphaBatchBuilder and BatchBuilder
// are still confusing. Once more of the picture caching
// improvement code lands, the AlphaBatchBuilder and
// AlphaBatchList types will be collapsed into one, which
// should simplify coming up with better type names.
let alpha_batch_builder = AlphaBatchBuilder::new(
self.screen_size,
ctx.break_advanced_blend_batches,
ctx.batch_lookback_count,
*task_id,
(*task_id).into(),
&ctx.frame_memory,
);
let mut batch_builder = BatchBuilder::new(alpha_batch_builder);
let cmd_buffer = cmd_buffers.get(pic_task.cmd_buffer_index);
cmd_buffer.iter_prims(&mut |cmd, spatial_node_index, segments| {
batch_builder.add_prim_to_batch(
cmd,
spatial_node_index,
ctx,
gpu_cache,
render_tasks,
prim_headers,
transforms,
pic_task.raster_spatial_node_index,
pic_task.surface_spatial_node_index,
z_generator,
prim_instances,
gpu_buffer_builder,
segments,
);
});
let alpha_batch_builder = batch_builder.finalize();
alpha_batch_builder.build(
&mut self.alpha_batch_containers,
&mut merged_batches,
target_rect,
scissor_rect,
);
}
_ => {
unreachable!();
}
}
}
if !merged_batches.is_empty() {
self.alpha_batch_containers.push(merged_batches);
}
}
pub fn texture_id(&self) -> CacheTextureId {
self.texture_id
}
pub fn add_task(
&mut self,
task_id: RenderTaskId,
ctx: &RenderTargetContext,
gpu_cache: &mut GpuCache,
gpu_buffer_builder: &mut GpuBufferBuilder,
render_tasks: &RenderTaskGraph,
clip_store: &ClipStore,
transforms: &mut TransformPalette,
) {
profile_scope!("add_task");
let task = &render_tasks[task_id];
let target_rect = task.get_target_rect();
match task.kind {
RenderTaskKind::Prim(ref info) => {
let render_task_address = task_id.into();
quad::add_to_batch(
info.pattern,
info.pattern_input,
render_task_address,
info.transform_id,
info.prim_address_f,
info.quad_flags,
info.edge_flags,
INVALID_SEGMENT_INDEX as u8,
info.texture_input,
ZBufferId(0),
render_tasks,
gpu_buffer_builder,
|key, instance| {
if info.prim_needs_scissor_rect {
self.prim_instances_with_scissor
.entry((target_rect, info.pattern))
.or_insert(FastHashMap::default())
.entry(key.textures.input.colors[0])
.or_insert_with(|| ctx.frame_memory.new_vec())
.push(instance);
} else {
self.prim_instances[info.pattern as usize]
.entry(key.textures.input.colors[0])
.or_insert_with(|| ctx.frame_memory.new_vec())
.push(instance);
}
}
);
}
RenderTaskKind::VerticalBlur(ref info) => {
if self.target_kind == RenderTargetKind::Alpha {
self.clears.push((target_rect, ColorF::TRANSPARENT));
}
add_blur_instances(
&mut self.vertical_blurs,
BlurDirection::Vertical,
info.blur_std_deviation,
info.blur_region,
task_id.into(),
task.children[0],
render_tasks,
&ctx.frame_memory,
);
}
RenderTaskKind::HorizontalBlur(ref info) => {
if self.target_kind == RenderTargetKind::Alpha {
self.clears.push((target_rect, ColorF::TRANSPARENT));
}
add_blur_instances(
&mut self.horizontal_blurs,
BlurDirection::Horizontal,
info.blur_std_deviation,
info.blur_region,
task_id.into(),
task.children[0],
render_tasks,
&ctx.frame_memory,
);
}
RenderTaskKind::Picture(ref pic_task) => {
if let Some(ref resolve_op) = pic_task.resolve_op {
self.resolve_ops.push(resolve_op.clone());
}
self.alpha_tasks.push(task_id);
}
RenderTaskKind::SvgFilter(ref task_info) => {
add_svg_filter_instances(
&mut self.svg_filters,
render_tasks,
&task_info.info,
task_id,
task.children.get(0).cloned(),
task.children.get(1).cloned(),
task_info.extra_gpu_cache_handle.map(|handle| gpu_cache.get_address(&handle)),
&ctx.frame_memory,
)
}
RenderTaskKind::SVGFENode(ref task_info) => {
add_svg_filter_node_instances(
&mut self.svg_nodes,
render_tasks,
&task_info,
task,
task.children.get(0).cloned(),
task.children.get(1).cloned(),
task_info.extra_gpu_cache_handle.map(|handle| gpu_cache.get_address(&handle)),
&ctx.frame_memory,
)
}
RenderTaskKind::Empty(..) => {
// TODO(gw): Could likely be more efficient by choosing to clear to 0 or 1
// based on the clip chain, or even skipping clear and masking the
// prim region with blend disabled.
self.clears.push((target_rect, ColorF::WHITE));
}
RenderTaskKind::CacheMask(ref task_info) => {
let clear_to_one = self.clip_batcher.add(
task_info.clip_node_range,
task_info.root_spatial_node_index,
render_tasks,
gpu_cache,
clip_store,
transforms,
task_info.actual_rect,
task_info.device_pixel_scale,
target_rect.min.to_f32(),
task_info.actual_rect.min,
ctx,
);
if task_info.clear_to_one || clear_to_one {
self.clears.push((target_rect, ColorF::WHITE));
}
}
RenderTaskKind::ClipRegion(ref region_task) => {
if region_task.clear_to_one {
self.clears.push((target_rect, ColorF::WHITE));
}
let device_rect = DeviceRect::from_size(
target_rect.size().to_f32(),
);
self.clip_batcher.add_clip_region(
region_task.local_pos,
device_rect,
region_task.clip_data.clone(),
target_rect.min.to_f32(),
DevicePoint::zero(),
region_task.device_pixel_scale.0,
);
}
RenderTaskKind::Scaling(ref info) => {
add_scaling_instances(
info,
&mut self.scalings,
task,
task.children.first().map(|&child| &render_tasks[child]),
&ctx.frame_memory,
);
}
RenderTaskKind::Blit(ref task_info) => {
let target_rect = task.get_target_rect();
self.blits.push(BlitJob {
source: task_info.source,
source_rect: task_info.source_rect,
target_rect,
});
}
RenderTaskKind::LineDecoration(ref info) => {
self.clears.push((target_rect, ColorF::TRANSPARENT));
self.line_decorations.push(LineDecorationJob {
task_rect: target_rect.to_f32(),
local_size: info.local_size,
style: info.style as i32,
axis_select: match info.orientation {
LineOrientation::Horizontal => 0.0,
LineOrientation::Vertical => 1.0,
},
wavy_line_thickness: info.wavy_line_thickness,
});
}
RenderTaskKind::Border(ref task_info) => {
self.clears.push((target_rect, ColorF::TRANSPARENT));
let task_origin = target_rect.min.to_f32();
// TODO(gw): Clone here instead of a move of this vec, since the frame
// graph is immutable by this point. It's rare that borders
// are drawn since they are persisted in the texture cache,
// but perhaps this could be improved in future.
let instances = task_info.instances.clone();
for mut instance in instances {
// TODO(gw): It may be better to store the task origin in
// the render task data instead of per instance.
instance.task_origin = task_origin;
if instance.flags & STYLE_MASK == STYLE_SOLID {
self.border_segments_solid.push(instance);
} else {
self.border_segments_complex.push(instance);
}
}
}
RenderTaskKind::FastLinearGradient(ref task_info) => {
self.fast_linear_gradients.push(task_info.to_instance(&target_rect));
}
RenderTaskKind::LinearGradient(ref task_info) => {
self.linear_gradients.push(task_info.to_instance(&target_rect));
}
RenderTaskKind::RadialGradient(ref task_info) => {
self.radial_gradients.push(task_info.to_instance(&target_rect));
}
RenderTaskKind::ConicGradient(ref task_info) => {
self.conic_gradients.push(task_info.to_instance(&target_rect));
}
RenderTaskKind::Image(..) |
RenderTaskKind::Cached(..) |
RenderTaskKind::TileComposite(..) => {
panic!("Should not be added to color target!");
}
RenderTaskKind::Readback(..) => {}
#[cfg(test)]
RenderTaskKind::Test(..) => {}
}
build_sub_pass(
task_id,
task,
gpu_buffer_builder,
render_tasks,
transforms,
ctx,
&mut self.clip_masks,
);
}
pub fn needs_depth(&self) -> bool {
self.alpha_batch_containers.iter().any(|ab| {
!ab.opaque_batches.is_empty()
})
}
}
#[cfg_attr(feature = "capture", derive(Serialize))]
#[cfg_attr(feature = "replay", derive(Deserialize))]
#[derive(Debug, PartialEq, Clone)]
pub struct ResolveOp {
pub src_task_ids: Vec<RenderTaskId>,
pub dest_task_id: RenderTaskId,
}
#[cfg_attr(feature = "capture", derive(Serialize))]
#[cfg_attr(feature = "replay", derive(Deserialize))]
pub enum PictureCacheTargetKind {
Draw {
alpha_batch_container: AlphaBatchContainer,
},
Blit {
task_id: RenderTaskId,
sub_rect_offset: DeviceIntVector2D,
},
}
#[cfg_attr(feature = "capture", derive(Serialize))]
#[cfg_attr(feature = "replay", derive(Deserialize))]
pub struct PictureCacheTarget {
pub surface: ResolvedSurfaceTexture,
pub kind: PictureCacheTargetKind,
pub clear_color: Option<ColorF>,
pub dirty_rect: DeviceIntRect,
pub valid_rect: DeviceIntRect,
}
fn add_blur_instances(
instances: &mut FastHashMap<TextureSource, FrameVec<BlurInstance>>,
blur_direction: BlurDirection,
blur_std_deviation: f32,
blur_region: DeviceIntSize,
task_address: RenderTaskAddress,
src_task_id: RenderTaskId,
render_tasks: &RenderTaskGraph,
memory: &FrameMemory,
) {
let source = render_tasks[src_task_id].get_texture_source();
let instance = BlurInstance {
task_address,
src_task_address: src_task_id.into(),
blur_direction: blur_direction.as_int(),
blur_std_deviation,
blur_region: blur_region.to_f32(),
};
instances
.entry(source)
.or_insert_with(|| memory.new_vec())
.push(instance);
}
fn add_scaling_instances(
task: &ScalingTask,
instances: &mut FastHashMap<TextureSource, FrameVec<ScalingInstance>>,
target_task: &RenderTask,
source_task: Option<&RenderTask>,
memory: &FrameMemory,
) {
let target_rect = target_task
.get_target_rect()
.inner_box(task.padding)
.to_f32();
let source = source_task.unwrap().get_texture_source();
let source_rect = source_task.unwrap().get_target_rect().to_f32();
instances
.entry(source)
.or_insert_with(|| memory.new_vec())
.push(ScalingInstance::new(
target_rect,
source_rect,
source.uses_normalized_uvs(),
));
}
fn add_svg_filter_instances(
instances: &mut FrameVec<(BatchTextures, FrameVec<SvgFilterInstance>)>,
render_tasks: &RenderTaskGraph,
filter: &SvgFilterInfo,
task_id: RenderTaskId,
input_1_task: Option<RenderTaskId>,
input_2_task: Option<RenderTaskId>,
extra_data_address: Option<GpuCacheAddress>,
memory: &FrameMemory,
) {
let mut textures = BatchTextures::empty();
if let Some(id) = input_1_task {
textures.input.colors[0] = render_tasks[id].get_texture_source();
}
if let Some(id) = input_2_task {
textures.input.colors[1] = render_tasks[id].get_texture_source();
}
let kind = match filter {
SvgFilterInfo::Blend(..) => 0,
SvgFilterInfo::Flood(..) => 1,
SvgFilterInfo::LinearToSrgb => 2,
SvgFilterInfo::SrgbToLinear => 3,
SvgFilterInfo::Opacity(..) => 4,
SvgFilterInfo::ColorMatrix(..) => 5,
SvgFilterInfo::DropShadow(..) => 6,
SvgFilterInfo::Offset(..) => 7,
SvgFilterInfo::ComponentTransfer(..) => 8,
SvgFilterInfo::Identity => 9,
SvgFilterInfo::Composite(..) => 10,
};
let input_count = match filter {
SvgFilterInfo::Flood(..) => 0,
SvgFilterInfo::LinearToSrgb |
SvgFilterInfo::SrgbToLinear |
SvgFilterInfo::Opacity(..) |
SvgFilterInfo::ColorMatrix(..) |
SvgFilterInfo::Offset(..) |
SvgFilterInfo::ComponentTransfer(..) |
SvgFilterInfo::Identity => 1,
// Not techincally a 2 input filter, but we have 2 inputs here: original content & blurred content.
SvgFilterInfo::DropShadow(..) |
SvgFilterInfo::Blend(..) |
SvgFilterInfo::Composite(..) => 2,
};
let generic_int = match filter {
SvgFilterInfo::Blend(mode) => *mode as u16,
SvgFilterInfo::ComponentTransfer(data) =>
(data.r_func.to_int() << 12 |
data.g_func.to_int() << 8 |
data.b_func.to_int() << 4 |
data.a_func.to_int()) as u16,
SvgFilterInfo::Composite(operator) =>
operator.as_int() as u16,
SvgFilterInfo::LinearToSrgb |
SvgFilterInfo::SrgbToLinear |
SvgFilterInfo::Flood(..) |
SvgFilterInfo::Opacity(..) |
SvgFilterInfo::ColorMatrix(..) |
SvgFilterInfo::DropShadow(..) |
SvgFilterInfo::Offset(..) |
SvgFilterInfo::Identity => 0,
};
let instance = SvgFilterInstance {
task_address: task_id.into(),
input_1_task_address: input_1_task.map(|id| id.into()).unwrap_or(RenderTaskAddress(0)),
input_2_task_address: input_2_task.map(|id| id.into()).unwrap_or(RenderTaskAddress(0)),
kind,
input_count,
generic_int,
padding: 0,
extra_data_address: extra_data_address.unwrap_or(GpuCacheAddress::INVALID),
};
for (ref mut batch_textures, ref mut batch) in instances.iter_mut() {
if let Some(combined_textures) = batch_textures.combine_textures(textures) {
batch.push(instance);
// Update the batch textures to the newly combined batch textures
*batch_textures = combined_textures;
return;
}
}
let mut vec = memory.new_vec();
vec.push(instance);
instances.push((textures, vec));
}
/// Generates SVGFEFilterInstances from a single SVGFEFilterTask, this is what
/// prepares vertex data for the shader, and adds it to the appropriate batch.
///
/// The interesting parts of the handling of SVG filters are:
/// * scene_building.rs : wrap_prim_with_filters
/// * picture.rs : get_coverage_svgfe
/// * render_task.rs : new_svg_filter_graph
/// * render_target.rs : add_svg_filter_node_instances (you are here)
fn add_svg_filter_node_instances(
instances: &mut FrameVec<(BatchTextures, FrameVec<SVGFEFilterInstance>)>,
render_tasks: &RenderTaskGraph,
task_info: &SVGFEFilterTask,
target_task: &RenderTask,
input_1_task: Option<RenderTaskId>,
input_2_task: Option<RenderTaskId>,
extra_data_address: Option<GpuCacheAddress>,
memory: &FrameMemory,
) {
let node = &task_info.node;
let op = &task_info.op;
let mut textures = BatchTextures::empty();
// We have to undo the inflate here as the inflated target rect is meant to
// have a blank border
let target_rect = target_task
.get_target_rect()
.inner_box(DeviceIntSideOffsets::new(node.inflate as i32, node.inflate as i32, node.inflate as i32, node.inflate as i32))
.to_f32();
let mut instance = SVGFEFilterInstance {
target_rect,
input_1_content_scale_and_offset: [0.0; 4],
input_2_content_scale_and_offset: [0.0; 4],
input_1_task_address: RenderTaskId::INVALID.into(),
input_2_task_address: RenderTaskId::INVALID.into(),
kind: 0,
input_count: node.inputs.len() as u16,
extra_data_address: extra_data_address.unwrap_or(GpuCacheAddress::INVALID),
};
// Must match FILTER_* in cs_svg_filter_node.glsl
instance.kind = match op {
// Identity does not modify color, no linear case
FilterGraphOp::SVGFEIdentity => 0,
// SourceGraphic does not have its own shader mode, it uses Identity.
FilterGraphOp::SVGFESourceGraphic => 0,
// SourceAlpha does not have its own shader mode, it uses ToAlpha.
FilterGraphOp::SVGFESourceAlpha => 4,
// Opacity scales the entire rgba color, so it does not need a linear
// case as the rgb / a ratio does not change (sRGB is a curve on the RGB
// before alpha multiply, not after)
FilterGraphOp::SVGFEOpacity{..} => 2,
FilterGraphOp::SVGFEToAlpha => 4,
FilterGraphOp::SVGFEBlendColor => {match node.linear {false => 6, true => 7}},
FilterGraphOp::SVGFEBlendColorBurn => {match node.linear {false => 8, true => 9}},
FilterGraphOp::SVGFEBlendColorDodge => {match node.linear {false => 10, true => 11}},
FilterGraphOp::SVGFEBlendDarken => {match node.linear {false => 12, true => 13}},
FilterGraphOp::SVGFEBlendDifference => {match node.linear {false => 14, true => 15}},
FilterGraphOp::SVGFEBlendExclusion => {match node.linear {false => 16, true => 17}},
FilterGraphOp::SVGFEBlendHardLight => {match node.linear {false => 18, true => 19}},
FilterGraphOp::SVGFEBlendHue => {match node.linear {false => 20, true => 21}},
FilterGraphOp::SVGFEBlendLighten => {match node.linear {false => 22, true => 23}},
FilterGraphOp::SVGFEBlendLuminosity => {match node.linear {false => 24, true => 25}},
FilterGraphOp::SVGFEBlendMultiply => {match node.linear {false => 26, true => 27}},
FilterGraphOp::SVGFEBlendNormal => {match node.linear {false => 28, true => 29}},
FilterGraphOp::SVGFEBlendOverlay => {match node.linear {false => 30, true => 31}},
FilterGraphOp::SVGFEBlendSaturation => {match node.linear {false => 32, true => 33}},
FilterGraphOp::SVGFEBlendScreen => {match node.linear {false => 34, true => 35}},
FilterGraphOp::SVGFEBlendSoftLight => {match node.linear {false => 36, true => 37}},
FilterGraphOp::SVGFEColorMatrix{..} => {match node.linear {false => 38, true => 39}},
FilterGraphOp::SVGFEComponentTransfer => unreachable!(),
FilterGraphOp::SVGFEComponentTransferInterned{..} => {match node.linear {false => 40, true => 41}},
FilterGraphOp::SVGFECompositeArithmetic{..} => {match node.linear {false => 42, true => 43}},
FilterGraphOp::SVGFECompositeATop => {match node.linear {false => 44, true => 45}},
FilterGraphOp::SVGFECompositeIn => {match node.linear {false => 46, true => 47}},
FilterGraphOp::SVGFECompositeLighter => {match node.linear {false => 48, true => 49}},
FilterGraphOp::SVGFECompositeOut => {match node.linear {false => 50, true => 51}},
FilterGraphOp::SVGFECompositeOver => {match node.linear {false => 52, true => 53}},
FilterGraphOp::SVGFECompositeXOR => {match node.linear {false => 54, true => 55}},
FilterGraphOp::SVGFEConvolveMatrixEdgeModeDuplicate{..} => {match node.linear {false => 56, true => 57}},
FilterGraphOp::SVGFEConvolveMatrixEdgeModeNone{..} => {match node.linear {false => 58, true => 59}},
FilterGraphOp::SVGFEConvolveMatrixEdgeModeWrap{..} => {match node.linear {false => 60, true => 61}},
FilterGraphOp::SVGFEDiffuseLightingDistant{..} => {match node.linear {false => 62, true => 63}},
FilterGraphOp::SVGFEDiffuseLightingPoint{..} => {match node.linear {false => 64, true => 65}},
FilterGraphOp::SVGFEDiffuseLightingSpot{..} => {match node.linear {false => 66, true => 67}},
FilterGraphOp::SVGFEDisplacementMap{..} => {match node.linear {false => 68, true => 69}},
FilterGraphOp::SVGFEDropShadow{..} => {match node.linear {false => 70, true => 71}},
// feFlood takes an sRGB color and does no math on it, no linear case
FilterGraphOp::SVGFEFlood{..} => 72,
FilterGraphOp::SVGFEGaussianBlur{..} => {match node.linear {false => 74, true => 75}},
// feImage does not meaningfully modify the color of its input, though a
// case could be made for gamma-correct image scaling, that's a bit out
// of scope for now
FilterGraphOp::SVGFEImage{..} => 76,
FilterGraphOp::SVGFEMorphologyDilate{..} => {match node.linear {false => 80, true => 81}},
FilterGraphOp::SVGFEMorphologyErode{..} => {match node.linear {false => 82, true => 83}},
FilterGraphOp::SVGFESpecularLightingDistant{..} => {match node.linear {false => 86, true => 87}},
FilterGraphOp::SVGFESpecularLightingPoint{..} => {match node.linear {false => 88, true => 89}},
FilterGraphOp::SVGFESpecularLightingSpot{..} => {match node.linear {false => 90, true => 91}},
// feTile does not modify color, no linear case
FilterGraphOp::SVGFETile => 92,
FilterGraphOp::SVGFETurbulenceWithFractalNoiseWithNoStitching{..} => {match node.linear {false => 94, true => 95}},
FilterGraphOp::SVGFETurbulenceWithFractalNoiseWithStitching{..} => {match node.linear {false => 96, true => 97}},
FilterGraphOp::SVGFETurbulenceWithTurbulenceNoiseWithNoStitching{..} => {match node.linear {false => 98, true => 99}},
FilterGraphOp::SVGFETurbulenceWithTurbulenceNoiseWithStitching{..} => {match node.linear {false => 100, true => 101}},
};
// This is a bit of an ugly way to do this, but avoids code duplication.
let mut resolve_input = |index: usize, src_task: Option<RenderTaskId>| -> (RenderTaskAddress, [f32; 4]) {
let mut src_task_id = RenderTaskId::INVALID;
let mut resolved_scale_and_offset: [f32; 4] = [0.0; 4];
if let Some(input) = node.inputs.get(index) {
src_task_id = src_task.unwrap();
let src_task = &render_tasks[src_task_id];
textures.input.colors[index] = src_task.get_texture_source();
let src_task_size = src_task.location.size();
let src_scale_x = (src_task_size.width as f32 - input.inflate as f32 * 2.0) / input.subregion.width();
let src_scale_y = (src_task_size.height as f32 - input.inflate as f32 * 2.0) / input.subregion.height();
let scale_x = src_scale_x * node.subregion.width();
let scale_y = src_scale_y * node.subregion.height();
let offset_x = src_scale_x * (node.subregion.min.x - input.subregion.min.x) + input.inflate as f32;
let offset_y = src_scale_y * (node.subregion.min.y - input.subregion.min.y) + input.inflate as f32;
resolved_scale_and_offset = [
scale_x,
scale_y,
offset_x,
offset_y];
}
let address: RenderTaskAddress = src_task_id.into();
(address, resolved_scale_and_offset)
};
(instance.input_1_task_address, instance.input_1_content_scale_and_offset) = resolve_input(0, input_1_task);
(instance.input_2_task_address, instance.input_2_content_scale_and_offset) = resolve_input(1, input_2_task);
// Additional instance modifications for certain filters
match op {
FilterGraphOp::SVGFEOpacity { valuebinding: _, value } => {
// opacity only has one input so we can use the other
// components to store the opacity value
instance.input_2_content_scale_and_offset = [*value, 0.0, 0.0, 0.0];
},
FilterGraphOp::SVGFEMorphologyDilate { radius_x, radius_y } |
FilterGraphOp::SVGFEMorphologyErode { radius_x, radius_y } => {
// morphology filters only use one input, so we use the
// second offset coord to store the radius values.
instance.input_2_content_scale_and_offset = [*radius_x, *radius_y, 0.0, 0.0];
},
FilterGraphOp::SVGFEFlood { color } => {
// flood filters don't use inputs, so we store color here.
// We can't do the same trick on DropShadow because it does have two
// inputs.
instance.input_2_content_scale_and_offset = [color.r, color.g, color.b, color.a];
},
_ => {},
}
for (ref mut batch_textures, ref mut batch) in instances.iter_mut() {
if let Some(combined_textures) = batch_textures.combine_textures(textures) {
batch.push(instance);
// Update the batch textures to the newly combined batch textures
*batch_textures = combined_textures;
// is this really the intended behavior?
return;
}
}
let mut vec = memory.new_vec();
vec.push(instance);
instances.push((textures, vec));
}
// Information required to do a blit from a source to a target.
#[cfg_attr(feature = "capture", derive(Serialize))]
#[cfg_attr(feature = "replay", derive(Deserialize))]
pub struct BlitJob {
pub source: RenderTaskId,
// Normalized region within the source task to blit from
pub source_rect: DeviceIntRect,
pub target_rect: DeviceIntRect,
}
#[cfg_attr(feature = "capture", derive(Serialize))]
#[cfg_attr(feature = "replay", derive(Deserialize))]
#[repr(C)]
#[derive(Clone, Debug)]
pub struct LineDecorationJob {
pub task_rect: DeviceRect,
pub local_size: LayoutSize,
pub wavy_line_thickness: f32,
pub style: i32,
pub axis_select: f32,
}
fn build_mask_tasks(
info: &MaskSubPass,
render_task_address: RenderTaskAddress,
task_world_rect: WorldRect,
target_rect: DeviceIntRect,
main_prim_address: GpuBufferAddress,
prim_spatial_node_index: SpatialNodeIndex,
raster_spatial_node_index: SpatialNodeIndex,
clip_store: &ClipStore,
data_stores: &DataStores,
spatial_tree: &SpatialTree,
gpu_buffer_builder: &mut GpuBufferBuilder,
transforms: &mut TransformPalette,
render_tasks: &RenderTaskGraph,
results: &mut ClipMaskInstanceList,
memory: &FrameMemory,
) {
for i in 0 .. info.clip_node_range.count {
let clip_instance = clip_store.get_instance_from_range(&info.clip_node_range, i);
let clip_node = &data_stores.clip[clip_instance.handle];
let (clip_address, fast_path) = match clip_node.item.kind {
ClipItemKind::RoundedRectangle { rect, radius, mode } => {
let (fast_path, clip_address) = if radius.can_use_fast_path_in(&rect) {
let mut writer = gpu_buffer_builder.f32.write_blocks(3);
writer.push_one(rect);
writer.push_one([
radius.bottom_right.width,
radius.top_right.width,
radius.bottom_left.width,
radius.top_left.width,
]);
writer.push_one([mode as i32 as f32, 0.0, 0.0, 0.0]);
let clip_address = writer.finish();
(true, clip_address)
} else {
let mut writer = gpu_buffer_builder.f32.write_blocks(4);
writer.push_one(rect);
writer.push_one([
radius.top_left.width,
radius.top_left.height,
radius.top_right.width,
radius.top_right.height,
]);
writer.push_one([
radius.bottom_left.width,
radius.bottom_left.height,
radius.bottom_right.width,
radius.bottom_right.height,
]);
writer.push_one([mode as i32 as f32, 0.0, 0.0, 0.0]);
let clip_address = writer.finish();
(false, clip_address)
};
(clip_address, fast_path)
}
ClipItemKind::Rectangle { rect, mode, .. } => {
let mut writer = gpu_buffer_builder.f32.write_blocks(3);
writer.push_one(rect);
writer.push_one([0.0, 0.0, 0.0, 0.0]);
writer.push_one([mode as i32 as f32, 0.0, 0.0, 0.0]);
let clip_address = writer.finish();
(clip_address, true)
}
ClipItemKind::BoxShadow { .. } => {
panic!("bug: box-shadow clips not expected on non-legacy rect/quads");
}
ClipItemKind::Image { rect, .. } => {
let clip_transform_id = transforms.get_id(
clip_node.item.spatial_node_index,
raster_spatial_node_index,
spatial_tree,
);
let is_same_coord_system = spatial_tree.is_matching_coord_system(
prim_spatial_node_index,
raster_spatial_node_index,
);
let pattern = Pattern::color(ColorF::WHITE);
let clip_needs_scissor_rect = !is_same_coord_system;
let mut quad_flags = QuadFlags::IS_MASK;
if is_same_coord_system {
quad_flags |= QuadFlags::APPLY_RENDER_TASK_CLIP;
}
for tile in clip_store.visible_mask_tiles(&clip_instance) {
let clip_prim_address = quad::write_prim_blocks(
&mut gpu_buffer_builder.f32,
rect,
rect,
pattern.base_color,
pattern.texture_input.task_id,
&[QuadSegment {
rect: tile.tile_rect,
task_id: tile.task_id,
}],
ScaleOffset::identity(),
);
let texture = render_tasks
.resolve_texture(tile.task_id)
.expect("bug: texture not found for tile");
quad::add_to_batch(
PatternKind::ColorOrTexture,
PatternShaderInput::default(),
render_task_address,
clip_transform_id,
clip_prim_address,
quad_flags,
EdgeAaSegmentMask::empty(),
0,
tile.task_id,
ZBufferId(0),
render_tasks,
gpu_buffer_builder,
|_, prim| {
if clip_needs_scissor_rect {
results
.image_mask_instances_with_scissor
.entry((target_rect, texture))
.or_insert_with(|| memory.new_vec())
.push(prim);
} else {
results
.image_mask_instances
.entry(texture)
.or_insert_with(|| memory.new_vec())
.push(prim);
}
}
);
}
// TODO(gw): For now, we skip the main mask prim below for image masks. Perhaps
// we can better merge the logic together?
// TODO(gw): How to efficiently handle if the image-mask rect doesn't cover local prim rect?
continue;
}
};
let prim_spatial_node = spatial_tree.get_spatial_node(prim_spatial_node_index);
let clip_spatial_node = spatial_tree.get_spatial_node(clip_node.item.spatial_node_index);
let raster_spatial_node = spatial_tree.get_spatial_node(raster_spatial_node_index);
let raster_clip = raster_spatial_node.coordinate_system_id == clip_spatial_node.coordinate_system_id;
let (clip_space, clip_transform_id, main_prim_address, prim_transform_id, is_same_coord_system) = if raster_clip {
let prim_transform_id = TransformPaletteId::IDENTITY;
let pattern = Pattern::color(ColorF::WHITE);
let clip_transform_id = transforms.get_id(
raster_spatial_node_index,
clip_node.item.spatial_node_index,
spatial_tree,
);
let main_prim_address = quad::write_prim_blocks(
&mut gpu_buffer_builder.f32,
task_world_rect.cast_unit(),
task_world_rect.cast_unit(),
pattern.base_color,
pattern.texture_input.task_id,
&[],
ScaleOffset::identity(),
);
(ClipSpace::Raster, clip_transform_id, main_prim_address, prim_transform_id, true)
} else {
let prim_transform_id = transforms.get_id(
prim_spatial_node_index,
raster_spatial_node_index,
spatial_tree,
);
let clip_transform_id = if prim_spatial_node.coordinate_system_id < clip_spatial_node.coordinate_system_id {
transforms.get_id(
clip_node.item.spatial_node_index,
prim_spatial_node_index,
spatial_tree,
)
} else {
transforms.get_id(
prim_spatial_node_index,
clip_node.item.spatial_node_index,
spatial_tree,
)
};
let is_same_coord_system = spatial_tree.is_matching_coord_system(
prim_spatial_node_index,
raster_spatial_node_index,
);
(ClipSpace::Primitive, clip_transform_id, main_prim_address, prim_transform_id, is_same_coord_system)
};
let clip_needs_scissor_rect = !is_same_coord_system;
let quad_flags = if is_same_coord_system {
QuadFlags::APPLY_RENDER_TASK_CLIP
} else {
QuadFlags::empty()
};
quad::add_to_batch(
PatternKind::Mask,
PatternShaderInput::default(),
render_task_address,
prim_transform_id,
main_prim_address,
quad_flags,
EdgeAaSegmentMask::all(),
INVALID_SEGMENT_INDEX as u8,
RenderTaskId::INVALID,
ZBufferId(0),
render_tasks,
gpu_buffer_builder,
|_, prim| {
let instance = MaskInstance {
prim,
clip_transform_id,
clip_address: clip_address.as_int(),
clip_space: clip_space.as_int(),
unused: 0,
};
if clip_needs_scissor_rect {
if fast_path {
results.mask_instances_fast_with_scissor
.entry(target_rect)
.or_insert_with(|| memory.new_vec())
.push(instance);
} else {
results.mask_instances_slow_with_scissor
.entry(target_rect)
.or_insert_with(|| memory.new_vec())
.push(instance);
}
} else {
if fast_path {
results.mask_instances_fast.push(instance);
} else {
results.mask_instances_slow.push(instance);
}
}
}
);
}
}
fn build_sub_pass(
task_id: RenderTaskId,
task: &RenderTask,
gpu_buffer_builder: &mut GpuBufferBuilder,
render_tasks: &RenderTaskGraph,
transforms: &mut TransformPalette,
ctx: &RenderTargetContext,
output: &mut ClipMaskInstanceList,
) {
if let Some(ref sub_pass) = task.sub_pass {
match sub_pass {
SubPass::Masks { ref masks } => {
let render_task_address = task_id.into();
let target_rect = task.get_target_rect();
let (device_pixel_scale, content_origin, raster_spatial_node_index) = match task.kind {
RenderTaskKind::Picture(ref info) => {
(info.device_pixel_scale, info.content_origin, info.raster_spatial_node_index)
}
RenderTaskKind::Empty(ref info) => {
(info.device_pixel_scale, info.content_origin, info.raster_spatial_node_index)
}
RenderTaskKind::Prim(ref info) => {
(info.device_pixel_scale, info.content_origin, info.raster_spatial_node_index)
}
_ => panic!("unexpected: {}", task.kind.as_str()),
};
let content_rect = DeviceRect::new(
content_origin,
content_origin + target_rect.size().to_f32(),
);
build_mask_tasks(
masks,
render_task_address,
content_rect / device_pixel_scale,
target_rect,
masks.prim_address_f,
masks.prim_spatial_node_index,
raster_spatial_node_index,
ctx.clip_store,
ctx.data_stores,
ctx.spatial_tree,
gpu_buffer_builder,
transforms,
render_tasks,
output,
&ctx.frame_memory,
);
}
}
}
}
[ Dauer der Verarbeitung: 0.44 Sekunden
(vorverarbeitet)
]
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2026-04-04
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