use iced_native::svg; use std::{ collections::{HashMap, HashSet}, rc::Rc, }; pub enum Svg { Loaded { tree: resvg::usvg::Tree }, NotFound, } impl Svg { pub fn viewport_dimensions(&self) -> (u32, u32) { match self { Svg::Loaded { tree } => { let size = tree.svg_node().size; (size.width() as u32, size.height() as u32) } Svg::NotFound => (1, 1), } } } impl std::fmt::Debug for Svg { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { write!(f, "Svg") } } #[derive(Debug)] pub struct Cache { svgs: HashMap, rasterized: HashMap<(u64, u32, u32), Rc>, svg_hits: HashSet, rasterized_hits: HashSet<(u64, u32, u32)>, } impl Cache { pub fn new() -> Self { Self { svgs: HashMap::new(), rasterized: HashMap::new(), svg_hits: HashSet::new(), rasterized_hits: HashSet::new(), } } pub fn load(&mut self, handle: &svg::Handle) -> &Svg { if self.svgs.contains_key(&handle.id()) { return self.svgs.get(&handle.id()).unwrap(); } let opt = resvg::Options::default(); let svg = match resvg::usvg::Tree::from_file(handle.path(), &opt.usvg) { Ok(tree) => Svg::Loaded { tree }, Err(_) => Svg::NotFound, }; let _ = self.svgs.insert(handle.id(), svg); self.svgs.get(&handle.id()).unwrap() } pub fn upload( &mut self, handle: &svg::Handle, [width, height]: [f32; 2], scale: f32, device: &wgpu::Device, encoder: &mut wgpu::CommandEncoder, texture_layout: &wgpu::BindGroupLayout, ) -> Option> { let id = handle.id(); let (width, height) = ( (scale * width).round() as u32, (scale * height).round() as u32, ); // TODO: Optimize! // We currently rerasterize the SVG when its size changes. This is slow // as heck. A GPU rasterizer like `pathfinder` may perform better. // It would be cool to be able to smooth resize the `svg` example. if let Some(bind_group) = self.rasterized.get(&(id, width, height)) { let _ = self.svg_hits.insert(id); let _ = self.rasterized_hits.insert((id, width, height)); return Some(bind_group.clone()); } match self.load(handle) { Svg::Loaded { tree } => { let extent = wgpu::Extent3d { width, height, depth: 1, }; let texture = device.create_texture(&wgpu::TextureDescriptor { size: extent, array_layer_count: 1, mip_level_count: 1, sample_count: 1, dimension: wgpu::TextureDimension::D2, format: wgpu::TextureFormat::Bgra8UnormSrgb, usage: wgpu::TextureUsage::COPY_DST | wgpu::TextureUsage::SAMPLED, }); let temp_buf = { let screen_size = resvg::ScreenSize::new(width, height).unwrap(); let mut canvas = resvg::raqote::DrawTarget::new( width as i32, height as i32, ); resvg::backend_raqote::render_to_canvas( &tree, &resvg::Options::default(), screen_size, &mut canvas, ); let slice = canvas.get_data(); device .create_buffer_mapped( slice.len(), wgpu::BufferUsage::COPY_SRC, ) .fill_from_slice(slice) }; encoder.copy_buffer_to_texture( wgpu::BufferCopyView { buffer: &temp_buf, offset: 0, row_pitch: 4 * width as u32, image_height: height as u32, }, wgpu::TextureCopyView { texture: &texture, array_layer: 0, mip_level: 0, origin: wgpu::Origin3d { x: 0.0, y: 0.0, z: 0.0, }, }, extent, ); let bind_group = device.create_bind_group(&wgpu::BindGroupDescriptor { layout: texture_layout, bindings: &[wgpu::Binding { binding: 0, resource: wgpu::BindingResource::TextureView( &texture.create_default_view(), ), }], }); let bind_group = Rc::new(bind_group); let _ = self .rasterized .insert((id, width, height), bind_group.clone()); let _ = self.svg_hits.insert(id); let _ = self.rasterized_hits.insert((id, width, height)); Some(bind_group) } Svg::NotFound => None, } } pub fn trim(&mut self) { let svg_hits = &self.svg_hits; let rasterized_hits = &self.rasterized_hits; self.svgs.retain(|k, _| svg_hits.contains(k)); self.rasterized.retain(|k, _| rasterized_hits.contains(k)); self.svg_hits.clear(); self.rasterized_hits.clear(); } }