src/encoding/encoding.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.

 use crate::encoding::DrawImage;

 use super::{
     resolve::Patch, DrawColor, DrawLinearGradient, DrawRadialGradient, DrawTag, Glyph, GlyphRun,
     PathEncoder, PathTag, Transform,
 };

 use fello::NormalizedCoord;
 use peniko::{kurbo::Shape, BlendMode, BrushRef, ColorStop, Extend, GradientKind, Image};

 /// Encoded data streams for a scene.
 #[derive(Clone, Default)]
 pub struct Encoding {
     /// The path tag stream.
     pub path_tags: Vec<PathTag>,
     /// The path data stream.
     pub path_data: Vec<u8>,
     /// The draw tag stream.
     pub draw_tags: Vec<DrawTag>,
     /// The draw data stream.
     pub draw_data: Vec<u8>,
     /// Draw data patches for late bound resources.
     pub patches: Vec<Patch>,
     /// Color stop collection for gradients.
     pub color_stops: Vec<ColorStop>,
     /// The transform stream.
     pub transforms: Vec<Transform>,
     /// The line width stream.
     pub linewidths: Vec<f32>,
     /// Positioned glyph buffer.
     pub glyphs: Vec<Glyph>,
     /// Sequences of glyphs.
     pub glyph_runs: Vec<GlyphRun>,
     /// Normalized coordinate buffer for variable fonts.
     pub normalized_coords: Vec<NormalizedCoord>,
     /// Number of encoded paths.
     pub n_paths: u32,
     /// Number of encoded path segments.
     pub n_path_segments: u32,
     /// Number of encoded clips/layers.
     pub n_clips: u32,
     /// Number of unclosed clips/layers.
     pub n_open_clips: u32,
 }

 impl Encoding {
     /// Creates a new encoding.
     pub fn new() -> Self {
         Self::default()
     }

     /// Returns true if the encoding is empty.
     pub fn is_empty(&self) -> bool {
         self.path_tags.is_empty()
     }

     /// Clears the encoding.
     pub fn reset(&mut self, is_fragment: bool) {
         self.transforms.clear();
         self.path_tags.clear();
         self.path_data.clear();
         self.linewidths.clear();
         self.draw_data.clear();
         self.draw_tags.clear();
         self.glyphs.clear();
         self.glyph_runs.clear();
         self.normalized_coords.clear();
         self.n_paths = 0;
         self.n_path_segments = 0;
         self.n_clips = 0;
         self.n_open_clips = 0;
         self.patches.clear();
         self.color_stops.clear();
         if !is_fragment {
             self.transforms.push(Transform::IDENTITY);
             self.linewidths.push(f32::INFINITY);
         }
     }

     /// Appends another encoding to this one with an optional transform.
     pub fn append(&mut self, other: &Self, transform: &Option<Transform>) {
         let stops_base = self.color_stops.len();
         let glyph_runs_base = self.glyph_runs.len();
         let glyphs_base = self.glyphs.len();
         let coords_base = self.normalized_coords.len();
         let offsets = self.stream_offsets();
         self.path_tags.extend_from_slice(&other.path_tags);
         self.path_data.extend_from_slice(&other.path_data);
         self.draw_tags.extend_from_slice(&other.draw_tags);
         self.draw_data.extend_from_slice(&other.draw_data);
         self.glyphs.extend_from_slice(&other.glyphs);
         self.normalized_coords
             .extend_from_slice(&other.normalized_coords);
         self.glyph_runs
             .extend(other.glyph_runs.iter().cloned().map(|mut run| {
                 run.glyphs.start += glyphs_base;
                 run.normalized_coords.start += coords_base;
                 run.stream_offsets.path_tags += offsets.path_tags;
                 run.stream_offsets.path_data += offsets.path_data;
                 run.stream_offsets.draw_tags += offsets.draw_tags;
                 run.stream_offsets.draw_data += offsets.draw_data;
                 run.stream_offsets.transforms += offsets.transforms;
                 run.stream_offsets.linewidths += offsets.linewidths;
                 run
             }));
         self.n_paths += other.n_paths;
         self.n_path_segments += other.n_path_segments;
         self.n_clips += other.n_clips;
         self.n_open_clips += other.n_open_clips;
         self.patches
             .extend(other.patches.iter().map(|patch| match patch {
                 Patch::Ramp {
                     draw_data_offset: offset,
                     stops,
                 } => {
                     let stops = stops.start + stops_base..stops.end + stops_base;
                     Patch::Ramp {
                         draw_data_offset: offset + offsets.draw_data,
                         stops,
                     }
                 }
                 Patch::GlyphRun { index } => Patch::GlyphRun {
                     index: index + glyph_runs_base,
                 },
                 Patch::Image {
                     image,
                     draw_data_offset,
                 } => Patch::Image {
                     image: image.clone(),
                     draw_data_offset: *draw_data_offset + offsets.draw_data,
                 },
             }));
         self.color_stops.extend_from_slice(&other.color_stops);
         if let Some(transform) = *transform {
             self.transforms
                 .extend(other.transforms.iter().map(|x| transform * *x));
             for run in &mut self.glyph_runs[glyph_runs_base..] {
                 run.transform = transform * run.transform;
             }
         } else {
             self.transforms.extend_from_slice(&other.transforms);
         }
         self.linewidths.extend_from_slice(&other.linewidths);
     }

     /// Returns a snapshot of the current stream offsets.
     pub fn stream_offsets(&self) -> StreamOffsets {
         StreamOffsets {
             path_tags: self.path_tags.len(),
             path_data: self.path_data.len(),
             draw_tags: self.draw_tags.len(),
             draw_data: self.draw_data.len(),
             transforms: self.transforms.len(),
             linewidths: self.linewidths.len(),
         }
     }
 }

 impl Encoding {
     /// Encodes a linewidth.
     pub fn encode_linewidth(&mut self, linewidth: f32) {
         if self.linewidths.last() != Some(&linewidth) {
             self.path_tags.push(PathTag::LINEWIDTH);
             self.linewidths.push(linewidth);
         }
     }

     pub fn encode_fill(&mut self, even_odd: bool) {
         if even_odd {
             self.encode_linewidth(f32::from_bits(0x7f800000));
         } else {
             self.encode_linewidth(f32::from_bits(0x7fc00000));
         }
     }

     pub fn encode_stroke(&mut self, width: f32, scaled: bool) {
         if scaled {
             self.encode_linewidth(width);
         } else {
             self.encode_linewidth(-width);
         }
     }

     /// Encodes a transform.
     ///
     /// If the given transform is different from the current one, encodes it and
     /// returns true. Otherwise, encodes nothing and returns false.
     pub fn encode_transform(&mut self, transform: Transform) -> bool {
         if self.transforms.last() != Some(&transform) {
             self.path_tags.push(PathTag::TRANSFORM);
             self.transforms.push(transform);
             true
         } else {
             false
         }
     }

     /// Returns an encoder for encoding a path. If `is_fill` is true, all subpaths will
     /// be automatically closed.
     pub fn encode_path(&mut self, is_fill: bool) -> PathEncoder {
         PathEncoder::new(
             &mut self.path_tags,
             &mut self.path_data,
             &mut self.n_path_segments,
             &mut self.n_paths,
             is_fill,
         )
     }

     /// Encodes a shape. If `is_fill` is true, all subpaths will be automatically closed.
     /// Returns true if a non-zero number of segments were encoded.
     pub fn encode_shape(&mut self, shape: &impl Shape, is_fill: bool) -> bool {
         let mut encoder = self.encode_path(is_fill);
         encoder.shape(shape);
         encoder.finish(true) != 0
     }

     /// Encodes a brush with an optional alpha modifier.
     pub fn encode_brush<'b>(&mut self, brush: impl Into<BrushRef<'b>>, alpha: f32) {
         use super::math::point_to_f32;
         match brush.into() {
             BrushRef::Solid(color) => {
                 let color = if alpha != 1.0 {
                     color.with_alpha_factor(alpha)
                 } else {
                     color
                 };
                 self.encode_color(DrawColor::new(color));
             }
             BrushRef::Gradient(gradient) => match gradient.kind {
                 GradientKind::Linear { start, end } => {
                     self.encode_linear_gradient(
                         DrawLinearGradient {
                             index: 0,
                             p0: point_to_f32(start),
                             p1: point_to_f32(end),
                         },
                         gradient.stops.iter().copied(),
                         alpha,
                         gradient.extend,
                     );
                 }
                 GradientKind::Radial {
                     start_center,
                     start_radius,
                     end_center,
                     end_radius,
                 } => {
                     self.encode_radial_gradient(
                         DrawRadialGradient {
                             index: 0,
                             p0: point_to_f32(start_center),
                             p1: point_to_f32(end_center),
                             r0: start_radius,
                             r1: end_radius,
                         },
                         gradient.stops.iter().copied(),
                         alpha,
                         gradient.extend,
                     );
                 }
                 GradientKind::Sweep { .. } => {
                     todo!("sweep gradients aren't supported yet!")
                 }
             },
             BrushRef::Image(image) => {
                 self.encode_image(image, alpha);
             }
         }
     }

     /// Encodes a solid color brush.
     pub fn encode_color(&mut self, color: DrawColor) {
         self.draw_tags.push(DrawTag::COLOR);
         self.draw_data.extend_from_slice(bytemuck::bytes_of(&color));
     }

     /// Encodes a linear gradient brush.
     pub fn encode_linear_gradient(
         &mut self,
         gradient: DrawLinearGradient,
         color_stops: impl Iterator<Item = ColorStop>,
         alpha: f32,
         _extend: Extend,
     ) {
         self.add_ramp(color_stops, alpha);
         self.draw_tags.push(DrawTag::LINEAR_GRADIENT);
         self.draw_data
             .extend_from_slice(bytemuck::bytes_of(&gradient));
     }

     /// Encodes a radial gradient brush.
     pub fn encode_radial_gradient(
         &mut self,
         gradient: DrawRadialGradient,
         color_stops: impl Iterator<Item = ColorStop>,
         alpha: f32,
         _extend: Extend,
     ) {
         self.add_ramp(color_stops, alpha);
         self.draw_tags.push(DrawTag::RADIAL_GRADIENT);
         self.draw_data
             .extend_from_slice(bytemuck::bytes_of(&gradient));
     }

     /// Encodes an image brush.
     pub fn encode_image(&mut self, image: &Image, _alpha: f32) {
         // TODO: feed the alpha multiplier through the full pipeline for consistency
         // with other brushes?
         self.patches.push(Patch::Image {
             image: image.clone(),
             draw_data_offset: self.draw_data.len(),
         });
         self.draw_tags.push(DrawTag::IMAGE);
         self.draw_data
             .extend_from_slice(bytemuck::bytes_of(&DrawImage {
                 xy: 0,
                 width_height: (image.width << 16) | (image.height & 0xFFFF),
             }));
     }

     /// Encodes a begin clip command.
     pub fn encode_begin_clip(&mut self, blend_mode: BlendMode, alpha: f32) {
         use super::DrawBeginClip;
         self.draw_tags.push(DrawTag::BEGIN_CLIP);
         self.draw_data
             .extend_from_slice(bytemuck::bytes_of(&DrawBeginClip::new(blend_mode, alpha)));
         self.n_clips += 1;
         self.n_open_clips += 1;
     }

     /// Encodes an end clip command.
     pub fn encode_end_clip(&mut self) {
         if self.n_open_clips > 0 {
             self.draw_tags.push(DrawTag::END_CLIP);
             // This is a dummy path, and will go away with the new clip impl.
             self.path_tags.push(PathTag::PATH);
             self.n_paths += 1;
             self.n_clips += 1;
             self.n_open_clips -= 1;
         }
     }

     // Swap the last two tags in the path tag stream; used for transformed
     // gradients.
     pub fn swap_last_path_tags(&mut self) {
         let len = self.path_tags.len();
         self.path_tags.swap(len - 1, len - 2);
     }

     fn add_ramp(&mut self, color_stops: impl Iterator<Item = ColorStop>, alpha: f32) {
         let offset = self.draw_data.len();
         let stops_start = self.color_stops.len();
         if alpha != 1.0 {
             self.color_stops
                 .extend(color_stops.map(|stop| stop.with_alpha_factor(alpha)));
         } else {
             self.color_stops.extend(color_stops);
         }
         self.patches.push(Patch::Ramp {
             draw_data_offset: offset,
             stops: stops_start..self.color_stops.len(),
         });
     }
 }

 /// Snapshot of offsets for encoded streams.
 #[derive(Copy, Clone, Default, Debug)]
 pub struct StreamOffsets {
     /// Current length of path tag stream.
     pub path_tags: usize,
     /// Current length of path data stream.
     pub path_data: usize,
     /// Current length of draw tag stream.
     pub draw_tags: usize,
     /// Current length of draw data stream.
     pub draw_data: usize,
     /// Current length of transform stream.
     pub transforms: usize,
     /// Current length of linewidth stream.
     pub linewidths: usize,
 }

 impl StreamOffsets {
     pub(crate) fn add(&mut self, other: &Self) {
         self.path_tags += other.path_tags;
         self.path_data += other.path_data;
         self.draw_tags += other.draw_tags;
         self.draw_data += other.draw_data;
         self.transforms += other.transforms;
         self.linewidths += other.linewidths;
     }
 }
	// 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.

	use crate::encoding::DrawImage;

	use super::{
	resolve::Patch, DrawColor, DrawLinearGradient, DrawRadialGradient, DrawTag, Glyph, GlyphRun,
	PathEncoder, PathTag, Transform,
	};

	use fello::NormalizedCoord;
	use peniko::{kurbo::Shape, BlendMode, BrushRef, ColorStop, Extend, GradientKind, Image};

	/// Encoded data streams for a scene.
	#[derive(Clone, Default)]
	pub struct Encoding {
	/// The path tag stream.
	pub path_tags: Vec<PathTag>,
	/// The path data stream.
	pub path_data: Vec<u8>,
	/// The draw tag stream.
	pub draw_tags: Vec<DrawTag>,
	/// The draw data stream.
	pub draw_data: Vec<u8>,
	/// Draw data patches for late bound resources.
	pub patches: Vec<Patch>,
	/// Color stop collection for gradients.
	pub color_stops: Vec<ColorStop>,
	/// The transform stream.
	pub transforms: Vec<Transform>,
	/// The line width stream.
	pub linewidths: Vec<f32>,
	/// Positioned glyph buffer.
	pub glyphs: Vec<Glyph>,
	/// Sequences of glyphs.
	pub glyph_runs: Vec<GlyphRun>,
	/// Normalized coordinate buffer for variable fonts.
	pub normalized_coords: Vec<NormalizedCoord>,
	/// Number of encoded paths.
	pub n_paths: u32,
	/// Number of encoded path segments.
	pub n_path_segments: u32,
	/// Number of encoded clips/layers.
	pub n_clips: u32,
	/// Number of unclosed clips/layers.
	pub n_open_clips: u32,
	}

	impl Encoding {
	/// Creates a new encoding.
	pub fn new() -> Self {
	Self::default()
	}

	/// Returns true if the encoding is empty.
	pub fn is_empty(&self) -> bool {
	self.path_tags.is_empty()
	}

	/// Clears the encoding.
	pub fn reset(&mut self, is_fragment: bool) {
	self.transforms.clear();
	self.path_tags.clear();
	self.path_data.clear();
	self.linewidths.clear();
	self.draw_data.clear();
	self.draw_tags.clear();
	self.glyphs.clear();
	self.glyph_runs.clear();
	self.normalized_coords.clear();
	self.n_paths = 0;
	self.n_path_segments = 0;
	self.n_clips = 0;
	self.n_open_clips = 0;
	self.patches.clear();
	self.color_stops.clear();
	if !is_fragment {
	self.transforms.push(Transform::IDENTITY);
	self.linewidths.push(f32::INFINITY);
	}
	}

	/// Appends another encoding to this one with an optional transform.
	pub fn append(&mut self, other: &Self, transform: &Option<Transform>) {
	let stops_base = self.color_stops.len();
	let glyph_runs_base = self.glyph_runs.len();
	let glyphs_base = self.glyphs.len();
	let coords_base = self.normalized_coords.len();
	let offsets = self.stream_offsets();
	self.path_tags.extend_from_slice(&other.path_tags);
	self.path_data.extend_from_slice(&other.path_data);
	self.draw_tags.extend_from_slice(&other.draw_tags);
	self.draw_data.extend_from_slice(&other.draw_data);
	self.glyphs.extend_from_slice(&other.glyphs);
	self.normalized_coords
	.extend_from_slice(&other.normalized_coords);
	self.glyph_runs
	.extend(other.glyph_runs.iter().cloned().map(\|mut run\| {
	run.glyphs.start += glyphs_base;
	run.normalized_coords.start += coords_base;
	run.stream_offsets.path_tags += offsets.path_tags;
	run.stream_offsets.path_data += offsets.path_data;
	run.stream_offsets.draw_tags += offsets.draw_tags;
	run.stream_offsets.draw_data += offsets.draw_data;
	run.stream_offsets.transforms += offsets.transforms;
	run.stream_offsets.linewidths += offsets.linewidths;
	run
	}));
	self.n_paths += other.n_paths;
	self.n_path_segments += other.n_path_segments;
	self.n_clips += other.n_clips;
	self.n_open_clips += other.n_open_clips;
	self.patches
	.extend(other.patches.iter().map(\|patch\| match patch {
	Patch::Ramp {
	draw_data_offset: offset,
	stops,
	} => {
	let stops = stops.start + stops_base..stops.end + stops_base;
	Patch::Ramp {
	draw_data_offset: offset + offsets.draw_data,
	stops,
	}
	}
	Patch::GlyphRun { index } => Patch::GlyphRun {
	index: index + glyph_runs_base,
	},
	Patch::Image {
	image,
	draw_data_offset,
	} => Patch::Image {
	image: image.clone(),
	draw_data_offset: *draw_data_offset + offsets.draw_data,
	},
	}));
	self.color_stops.extend_from_slice(&other.color_stops);
	if let Some(transform) = *transform {
	self.transforms
	.extend(other.transforms.iter().map(\|x\| transform * *x));
	for run in &mut self.glyph_runs[glyph_runs_base..] {
	run.transform = transform * run.transform;
	}
	} else {
	self.transforms.extend_from_slice(&other.transforms);
	}
	self.linewidths.extend_from_slice(&other.linewidths);
	}

	/// Returns a snapshot of the current stream offsets.
	pub fn stream_offsets(&self) -> StreamOffsets {
	StreamOffsets {
	path_tags: self.path_tags.len(),
	path_data: self.path_data.len(),
	draw_tags: self.draw_tags.len(),
	draw_data: self.draw_data.len(),
	transforms: self.transforms.len(),
	linewidths: self.linewidths.len(),
	}
	}
	}

	impl Encoding {
	/// Encodes a linewidth.
	pub fn encode_linewidth(&mut self, linewidth: f32) {
	if self.linewidths.last() != Some(&linewidth) {
	self.path_tags.push(PathTag::LINEWIDTH);
	self.linewidths.push(linewidth);
	}
	}

	pub fn encode_fill(&mut self, even_odd: bool) {
	if even_odd {
	self.encode_linewidth(f32::from_bits(0x7f800000));
	} else {
	self.encode_linewidth(f32::from_bits(0x7fc00000));
	}
	}

	pub fn encode_stroke(&mut self, width: f32, scaled: bool) {
	if scaled {
	self.encode_linewidth(width);
	} else {
	self.encode_linewidth(-width);
	}
	}

	/// Encodes a transform.
	///
	/// If the given transform is different from the current one, encodes it and
	/// returns true. Otherwise, encodes nothing and returns false.
	pub fn encode_transform(&mut self, transform: Transform) -> bool {
	if self.transforms.last() != Some(&transform) {
	self.path_tags.push(PathTag::TRANSFORM);
	self.transforms.push(transform);
	true
	} else {
	false
	}
	}

	/// Returns an encoder for encoding a path. If `is_fill` is true, all subpaths will
	/// be automatically closed.
	pub fn encode_path(&mut self, is_fill: bool) -> PathEncoder {
	PathEncoder::new(
	&mut self.path_tags,
	&mut self.path_data,
	&mut self.n_path_segments,
	&mut self.n_paths,
	is_fill,
	)
	}

	/// Encodes a shape. If `is_fill` is true, all subpaths will be automatically closed.
	/// Returns true if a non-zero number of segments were encoded.
	pub fn encode_shape(&mut self, shape: &impl Shape, is_fill: bool) -> bool {
	let mut encoder = self.encode_path(is_fill);
	encoder.shape(shape);
	encoder.finish(true) != 0
	}

	/// Encodes a brush with an optional alpha modifier.
	pub fn encode_brush<'b>(&mut self, brush: impl Into<BrushRef<'b>>, alpha: f32) {
	use super::math::point_to_f32;
	match brush.into() {
	BrushRef::Solid(color) => {
	let color = if alpha != 1.0 {
	color.with_alpha_factor(alpha)
	} else {
	color
	};
	self.encode_color(DrawColor::new(color));
	}
	BrushRef::Gradient(gradient) => match gradient.kind {
	GradientKind::Linear { start, end } => {
	self.encode_linear_gradient(
	DrawLinearGradient {
	index: 0,
	p0: point_to_f32(start),
	p1: point_to_f32(end),
	},
	gradient.stops.iter().copied(),
	alpha,
	gradient.extend,
	);
	}
	GradientKind::Radial {
	start_center,
	start_radius,
	end_center,
	end_radius,
	} => {
	self.encode_radial_gradient(
	DrawRadialGradient {
	index: 0,
	p0: point_to_f32(start_center),
	p1: point_to_f32(end_center),
	r0: start_radius,
	r1: end_radius,
	},
	gradient.stops.iter().copied(),
	alpha,
	gradient.extend,
	);
	}
	GradientKind::Sweep { .. } => {
	todo!("sweep gradients aren't supported yet!")
	}
	},
	BrushRef::Image(image) => {
	self.encode_image(image, alpha);
	}
	}
	}

	/// Encodes a solid color brush.
	pub fn encode_color(&mut self, color: DrawColor) {
	self.draw_tags.push(DrawTag::COLOR);
	self.draw_data.extend_from_slice(bytemuck::bytes_of(&color));
	}

	/// Encodes a linear gradient brush.
	pub fn encode_linear_gradient(
	&mut self,
	gradient: DrawLinearGradient,
	color_stops: impl Iterator<Item = ColorStop>,
	alpha: f32,
	_extend: Extend,
	) {
	self.add_ramp(color_stops, alpha);
	self.draw_tags.push(DrawTag::LINEAR_GRADIENT);
	self.draw_data
	.extend_from_slice(bytemuck::bytes_of(&gradient));
	}

	/// Encodes a radial gradient brush.
	pub fn encode_radial_gradient(
	&mut self,
	gradient: DrawRadialGradient,
	color_stops: impl Iterator<Item = ColorStop>,
	alpha: f32,
	_extend: Extend,
	) {
	self.add_ramp(color_stops, alpha);
	self.draw_tags.push(DrawTag::RADIAL_GRADIENT);
	self.draw_data
	.extend_from_slice(bytemuck::bytes_of(&gradient));
	}

	/// Encodes an image brush.
	pub fn encode_image(&mut self, image: &Image, _alpha: f32) {
	// TODO: feed the alpha multiplier through the full pipeline for consistency
	// with other brushes?
	self.patches.push(Patch::Image {
	image: image.clone(),
	draw_data_offset: self.draw_data.len(),
	});
	self.draw_tags.push(DrawTag::IMAGE);
	self.draw_data
	.extend_from_slice(bytemuck::bytes_of(&DrawImage {
	xy: 0,
	width_height: (image.width << 16) \| (image.height & 0xFFFF),
	}));
	}

	/// Encodes a begin clip command.
	pub fn encode_begin_clip(&mut self, blend_mode: BlendMode, alpha: f32) {
	use super::DrawBeginClip;
	self.draw_tags.push(DrawTag::BEGIN_CLIP);
	self.draw_data
	.extend_from_slice(bytemuck::bytes_of(&DrawBeginClip::new(blend_mode, alpha)));
	self.n_clips += 1;
	self.n_open_clips += 1;
	}

	/// Encodes an end clip command.
	pub fn encode_end_clip(&mut self) {
	if self.n_open_clips > 0 {
	self.draw_tags.push(DrawTag::END_CLIP);
	// This is a dummy path, and will go away with the new clip impl.
	self.path_tags.push(PathTag::PATH);
	self.n_paths += 1;
	self.n_clips += 1;
	self.n_open_clips -= 1;
	}
	}

	// Swap the last two tags in the path tag stream; used for transformed
	// gradients.
	pub fn swap_last_path_tags(&mut self) {
	let len = self.path_tags.len();
	self.path_tags.swap(len - 1, len - 2);
	}

	fn add_ramp(&mut self, color_stops: impl Iterator<Item = ColorStop>, alpha: f32) {
	let offset = self.draw_data.len();
	let stops_start = self.color_stops.len();
	if alpha != 1.0 {
	self.color_stops
	.extend(color_stops.map(\|stop\| stop.with_alpha_factor(alpha)));
	} else {
	self.color_stops.extend(color_stops);
	}
	self.patches.push(Patch::Ramp {
	draw_data_offset: offset,
	stops: stops_start..self.color_stops.len(),
	});
	}
	}

	/// Snapshot of offsets for encoded streams.
	#[derive(Copy, Clone, Default, Debug)]
	pub struct StreamOffsets {
	/// Current length of path tag stream.
	pub path_tags: usize,
	/// Current length of path data stream.
	pub path_data: usize,
	/// Current length of draw tag stream.
	pub draw_tags: usize,
	/// Current length of draw data stream.
	pub draw_data: usize,
	/// Current length of transform stream.
	pub transforms: usize,
	/// Current length of linewidth stream.
	pub linewidths: usize,
	}

	impl StreamOffsets {
	pub(crate) fn add(&mut self, other: &Self) {
	self.path_tags += other.path_tags;
	self.path_data += other.path_data;
	self.draw_tags += other.draw_tags;
	self.draw_data += other.draw_data;
	self.transforms += other.transforms;
	self.linewidths += other.linewidths;
	}
	}