/* 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 crate::{WindowWrapper, NotifierEvent}; use image::load as load_piston_image; use image::png::PNGEncoder; use image::{ColorType, ImageFormat}; use crate::parse_function::parse_function; use crate::png::save_flipped; use std::{cmp, env}; use std::fmt::{Display, Error, Formatter}; use std::fs::File; use std::io::{BufRead, BufReader}; use std::path::{Path, PathBuf}; use std::process::Command; use std::sync::mpsc::Receiver; use webrender::RenderResults; use webrender::api::*; use webrender::render_api::*; use webrender::api::units::*; use crate::wrench::{Wrench, WrenchThing}; use crate::yaml_frame_reader::YamlFrameReader; const OPTION_DISABLE_SUBPX: &str = "disable-subpixel"; const OPTION_DISABLE_AA: &str = "disable-aa"; const OPTION_ALLOW_MIPMAPS: &str = "allow-mipmaps"; pub struct ReftestOptions { // These override values that are lower. pub allow_max_difference: usize, pub allow_num_differences: usize, } impl ReftestOptions { pub fn default() -> Self { ReftestOptions { allow_max_difference: 0, allow_num_differences: 0, } } } #[derive(Debug, Copy, Clone)] pub enum ReftestOp { /// Expect that the images match the reference Equal, /// Expect that the images *don't* match the reference NotEqual, /// Expect that drawing the reference at different tiles sizes gives the same pixel exact result. Accurate, /// Expect that drawing the reference at different tiles sizes gives a *different* pixel exact result. Inaccurate, } impl Display for ReftestOp { fn fmt(&self, f: &mut Formatter) -> Result<(), Error> { write!( f, "{}", match *self { ReftestOp::Equal => "==".to_owned(), ReftestOp::NotEqual => "!=".to_owned(), ReftestOp::Accurate => "**".to_owned(), ReftestOp::Inaccurate => "!*".to_owned(), } ) } } #[derive(Debug)] enum ExtraCheck { DrawCalls(usize), AlphaTargets(usize), ColorTargets(usize), } impl ExtraCheck { fn run(&self, results: &[RenderResults]) -> bool { match *self { ExtraCheck::DrawCalls(x) => x == results.last().unwrap().stats.total_draw_calls, ExtraCheck::AlphaTargets(x) => x == results.last().unwrap().stats.alpha_target_count, ExtraCheck::ColorTargets(x) => x == results.last().unwrap().stats.color_target_count, } } } pub struct RefTestFuzzy { max_difference: usize, num_differences: usize, } pub struct Reftest { op: ReftestOp, test: Vec, reference: PathBuf, font_render_mode: Option, fuzziness: Vec, extra_checks: Vec, allow_mipmaps: bool, force_subpixel_aa_where_possible: Option, max_surface_override: Option, } impl Reftest { /// Check the positive case (expecting equality) and report details if different fn check_and_report_equality_failure( &self, comparison: ReftestImageComparison, test: &ReftestImage, reference: &ReftestImage, ) -> bool { match comparison { ReftestImageComparison::Equal => { true } ReftestImageComparison::NotEqual { difference_histogram, max_difference, count_different } => { // Each entry in the sorted self.fuzziness list represents a bucket which // allows at most num_differences pixels with a difference of at most // max_difference -- but with the caveat that a difference which is small // enough to be less than a max_difference of an earlier bucket, must be // counted against that bucket. // // Thus the test will fail if the number of pixels with a difference // > fuzzy[j-1].max_difference and <= fuzzy[j].max_difference // exceeds fuzzy[j].num_differences. // // (For the first entry, consider fuzzy[j-1] to allow zero pixels of zero // difference). // // For example, say we have this histogram of differences: // // | [0] [1] [2] [3] [4] [5] [6] ... [255] // ------+------------------------------------------ // Hist. | 0 3 2 1 6 2 0 ... 0 // // Ie. image comparison found 3 pixels that differ by 1, 2 that differ by 2, etc. // (Note that entry 0 is always zero, we don't count matching pixels.) // // First we calculate an inclusive prefix sum: // // | [0] [1] [2] [3] [4] [5] [6] ... [255] // ------+------------------------------------------ // Hist. | 0 3 2 1 6 2 0 ... 0 // Sum | 0 3 5 6 12 14 14 ... 14 // // Let's say the fuzzy statements are: // Fuzzy( 2, 6 ) -- allow up to 6 pixels that differ by 2 or less // Fuzzy( 4, 8 ) -- allow up to 8 pixels that differ by 4 or less _but_ // also by more than 2 (= by 3 or 4). // // The first check is Sum[2] <= max 6 which passes: 5 <= 6. // The second check is Sum[4] - Sum[2] <= max 8 which passes: 12-5 <= 8. // Finally we check if there are any pixels that exceed the max difference (4) // by checking Sum[255] - Sum[4] which shows there are 14-12 == 2 so we fail. let prefix_sum = difference_histogram.iter() .scan(0, |sum, i| { *sum += i; Some(*sum) }) .collect::>(); // check each fuzzy statement for violations. assert_eq!(0, difference_histogram[0]); assert_eq!(0, prefix_sum[0]); // loop invariant: this is the max_difference of the previous iteration's 'fuzzy' let mut previous_max_diff = 0; // loop invariant: this is the number of pixels to ignore as they have been counted // against previous iterations' fuzzy statements. let mut previous_sum_fail = 0; // == prefix_sum[previous_max_diff] let mut is_failing = false; let mut fail_text = String::new(); for fuzzy in &self.fuzziness { let fuzzy_max_difference = cmp::min(255, fuzzy.max_difference); let num_differences = prefix_sum[fuzzy_max_difference] - previous_sum_fail; if num_differences > fuzzy.num_differences { fail_text.push_str( &format!("{} differences > {} and <= {} (allowed {}); ", num_differences, previous_max_diff, fuzzy_max_difference, fuzzy.num_differences)); is_failing = true; } previous_max_diff = fuzzy_max_difference; previous_sum_fail = prefix_sum[previous_max_diff]; } // do we have any pixels with a difference above the highest allowed // max difference? if so, we fail the test: let num_differences = prefix_sum[255] - previous_sum_fail; if num_differences > 0 { fail_text.push_str( &format!("{} num_differences > {} and <= {} (allowed {}); ", num_differences, previous_max_diff, 255, 0)); is_failing = true; } if is_failing { println!( "REFTEST TEST-UNEXPECTED-FAIL | {} | \ image comparison, max difference: {}, number of differing pixels: {} | {}", self, max_difference, count_different, fail_text, ); println!("REFTEST IMAGE 1 (TEST): {}", test.clone().create_data_uri()); println!( "REFTEST IMAGE 2 (REFERENCE): {}", reference.clone().create_data_uri() ); println!("REFTEST TEST-END | {}", self); false } else { true } } } } /// Report details of the negative case fn report_unexpected_equality(&self) { println!("REFTEST TEST-UNEXPECTED-FAIL | {} | image comparison", self); println!("REFTEST TEST-END | {}", self); } } impl Display for Reftest { fn fmt(&self, f: &mut Formatter) -> Result<(), Error> { let paths: Vec = self.test.iter().map(|t| t.display().to_string()).collect(); write!( f, "{} {} {}", paths.join(", "), self.op, self.reference.display() ) } } #[derive(Clone)] pub struct ReftestImage { pub data: Vec, pub size: DeviceIntSize, } #[derive(Debug, Clone)] pub enum ReftestImageComparison { Equal, NotEqual { /// entry[j] = number of pixels with a difference of exactly j difference_histogram: Vec, max_difference: usize, count_different: usize, }, } impl ReftestImage { pub fn compare(&self, other: &ReftestImage) -> ReftestImageComparison { assert_eq!(self.size, other.size); assert_eq!(self.data.len(), other.data.len()); assert_eq!(self.data.len() % 4, 0); let mut histogram = [0usize; 256]; let mut count = 0; let mut max = 0; for (a, b) in self.data.chunks(4).zip(other.data.chunks(4)) { if a != b { let pixel_max = a.iter() .zip(b.iter()) .map(|(x, y)| (*x as isize - *y as isize).abs() as usize) .max() .unwrap(); count += 1; assert!(pixel_max < 256, "pixel values are not 8 bit, update the histogram binning code"); // deliberately avoid counting pixels that match -- // histogram[0] stays at zero. // this helps our prefix sum later during analysis to // only count actual differences. histogram[pixel_max as usize] += 1; max = cmp::max(max, pixel_max); } } if count != 0 { ReftestImageComparison::NotEqual { difference_histogram: histogram.to_vec(), max_difference: max, count_different: count, } } else { ReftestImageComparison::Equal } } pub fn create_data_uri(mut self) -> String { let width = self.size.width; let height = self.size.height; // flip image vertically (texture is upside down) let orig_pixels = self.data.clone(); let stride = width as usize * 4; for y in 0 .. height as usize { let dst_start = y * stride; let src_start = (height as usize - y - 1) * stride; let src_slice = &orig_pixels[src_start .. src_start + stride]; (&mut self.data[dst_start .. dst_start + stride]) .clone_from_slice(&src_slice[.. stride]); } let mut png: Vec = vec![]; { let encoder = PNGEncoder::new(&mut png); encoder .encode(&self.data[..], width as u32, height as u32, ColorType::Rgba8) .expect("Unable to encode PNG!"); } let png_base64 = base64::encode(&png); format!("data:image/png;base64,{}", png_base64) } } struct ReftestManifest { reftests: Vec, } impl ReftestManifest { fn new(manifest: &Path, environment: &ReftestEnvironment, options: &ReftestOptions) -> ReftestManifest { let dir = manifest.parent().unwrap(); let f = File::open(manifest).unwrap_or_else(|_| panic!("couldn't open manifest: {}", manifest.display())); let file = BufReader::new(&f); let mut reftests = Vec::new(); for line in file.lines() { let l = line.unwrap(); // strip the comments let s = &l[0 .. l.find('#').unwrap_or(l.len())]; let s = s.trim(); if s.is_empty() { continue; } let tokens: Vec<&str> = s.split_whitespace().collect(); let mut fuzziness = Vec::new(); let mut op = None; let mut font_render_mode = None; let mut extra_checks = vec![]; let mut allow_mipmaps = false; let mut force_subpixel_aa_where_possible = None; let mut max_surface_override = None; let mut parse_command = |token: &str| -> bool { match token { function if function.starts_with("force_subpixel_aa_where_possible(") => { let (_, args, _) = parse_function(function); force_subpixel_aa_where_possible = Some(args[0].parse().unwrap()); } function if function.starts_with("fuzzy-range(") || function.starts_with("fuzzy-range-if(") => { let (_, mut args, _) = parse_function(function); if function.starts_with("fuzzy-range-if(") { if !environment.parse_condition(args.remove(0)).expect("unknown condition") { return true; } fuzziness.clear(); } let num_range = args.len() / 2; for range in 0..num_range { let mut max = args[range * 2 ]; let mut num = args[range * 2 + 1]; if max.starts_with("<=") { // trim_start_matches would allow <=<=123 max = &max[2..]; } if num.starts_with('*') { num = &num[1..]; } let max_difference = max.parse().unwrap(); let num_differences = num.parse().unwrap(); fuzziness.push(RefTestFuzzy { max_difference, num_differences }); } } function if function.starts_with("fuzzy(") || function.starts_with("fuzzy-if(") => { let (_, mut args, _) = parse_function(function); if function.starts_with("fuzzy-if(") { if !environment.parse_condition(args.remove(0)).expect("unknown condition") { return true; } fuzziness.clear(); } let max_difference = args[0].parse().unwrap(); let num_differences = args[1].parse().unwrap(); assert!(fuzziness.is_empty()); // if this fires, consider fuzzy-range instead fuzziness.push(RefTestFuzzy { max_difference, num_differences }); } function if function.starts_with("draw_calls(") => { let (_, args, _) = parse_function(function); extra_checks.push(ExtraCheck::DrawCalls(args[0].parse().unwrap())); } function if function.starts_with("alpha_targets(") => { let (_, args, _) = parse_function(function); extra_checks.push(ExtraCheck::AlphaTargets(args[0].parse().unwrap())); } function if function.starts_with("color_targets(") => { let (_, args, _) = parse_function(function); extra_checks.push(ExtraCheck::ColorTargets(args[0].parse().unwrap())); } function if function.starts_with("max_surface_size(") => { let (_, args, _) = parse_function(function); max_surface_override = Some(args[0].parse().unwrap()); } options if options.starts_with("options(") => { let (_, args, _) = parse_function(options); if args.iter().any(|arg| arg == &OPTION_DISABLE_SUBPX) { font_render_mode = Some(FontRenderMode::Alpha); } if args.iter().any(|arg| arg == &OPTION_DISABLE_AA) { font_render_mode = Some(FontRenderMode::Mono); } if args.iter().any(|arg| arg == &OPTION_ALLOW_MIPMAPS) { allow_mipmaps = true; } } _ => return false, } true }; let mut paths = vec![]; for (i, token) in tokens.iter().enumerate() { match *token { "include" => { assert!(i == 0, "include must be by itself"); let include = dir.join(tokens[1]); reftests.append( &mut ReftestManifest::new(include.as_path(), environment, options).reftests, ); break; } "==" => { op = Some(ReftestOp::Equal); } "!=" => { op = Some(ReftestOp::NotEqual); } "**" => { op = Some(ReftestOp::Accurate); } "!*" => { op = Some(ReftestOp::Inaccurate); } cond if cond.starts_with("if(") => { let (_, args, _) = parse_function(cond); if environment.parse_condition(args[0]).expect("unknown condition") { for command in &args[1..] { parse_command(command); } } } command if parse_command(command) => {} _ => { match environment.parse_condition(*token) { Some(true) => {} Some(false) => break, _ => paths.push(dir.join(*token)), } } } } // Don't try to add tests for include lines. if op.is_none() { assert!(paths.is_empty(), "paths = {:?}", paths); continue; } let op = op.unwrap(); // The reference is the last path provided. If multiple paths are // passed for the test, they render sequentially before being // compared to the reference, which is useful for testing // invalidation. let reference = paths.pop().unwrap(); let test = paths; if environment.platform == "android" { // Add some fuzz on mobile as we do for non-wrench reftests. // First remove the ranges with difference <= 2, otherwise they might cause the // test to fail before the new range is picked up. fuzziness.retain(|fuzzy| fuzzy.max_difference > 2); fuzziness.push(RefTestFuzzy { max_difference: 2, num_differences: std::usize::MAX }); } // to avoid changing the meaning of existing tests, the case of // only a single (or no) 'fuzzy' keyword means we use the max // of that fuzzy and options.allow_.. (we don't want that to // turn into a test that allows fuzzy.allow_ *plus* options.allow_): match fuzziness.len() { 0 => fuzziness.push(RefTestFuzzy { max_difference: options.allow_max_difference, num_differences: options.allow_num_differences }), 1 => { let mut fuzzy = &mut fuzziness[0]; fuzzy.max_difference = cmp::max(fuzzy.max_difference, options.allow_max_difference); fuzzy.num_differences = cmp::max(fuzzy.num_differences, options.allow_num_differences); }, _ => { // ignore options, use multiple fuzzy keywords instead. make sure // the list is sorted to speed up counting violations. fuzziness.sort_by(|a, b| a.max_difference.cmp(&b.max_difference)); for pair in fuzziness.windows(2) { if pair[0].max_difference == pair[1].max_difference { println!("Warning: repeated fuzzy of max_difference {} ignored.", pair[1].max_difference); } } } } reftests.push(Reftest { op, test, reference, font_render_mode, fuzziness, extra_checks, allow_mipmaps, force_subpixel_aa_where_possible, max_surface_override, }); } ReftestManifest { reftests } } fn find(&self, prefix: &Path) -> Vec<&Reftest> { self.reftests .iter() .filter(|x| { x.test.iter().any(|t| t.starts_with(prefix)) || x.reference.starts_with(prefix) }) .collect() } } struct YamlRenderOutput { image: ReftestImage, results: RenderResults, } struct ReftestEnvironment { pub platform: &'static str, pub version: Option, pub mode: &'static str, } impl ReftestEnvironment { fn new(wrench: &Wrench, window: &WindowWrapper) -> Self { Self { platform: Self::platform(wrench, window), version: Self::version(wrench, window), mode: Self::mode(), } } fn has(&self, condition: &str) -> bool { if self.platform == condition || self.mode == condition { return true; } if let (Some(v), Ok(r)) = (&self.version, &semver::VersionReq::parse(condition)) { if r.matches(v) { return true; } } let envkey = format!("WRENCH_REFTEST_CONDITION_{}", condition.to_uppercase()); env::var(envkey).is_ok() } fn platform(_wrench: &Wrench, window: &WindowWrapper) -> &'static str { if window.is_software() { "swgl" } else if cfg!(target_os = "windows") { "win" } else if cfg!(target_os = "linux") { "linux" } else if cfg!(target_os = "macos") { "mac" } else if cfg!(target_os = "android") { "android" } else { "other" } } fn version(_wrench: &Wrench, window: &WindowWrapper) -> Option { if window.is_software() { None } else if cfg!(target_os = "macos") { use std::str; let version_bytes = Command::new("defaults") .arg("read") .arg("loginwindow") .arg("SystemVersionStampAsString") .output() .expect("Failed to get macOS version") .stdout; let mut version_string = str::from_utf8(&version_bytes) .expect("Failed to read macOS version") .trim() .to_string(); // On some machines this produces just the major.minor and on // some machines this gives major.minor.patch. But semver requires // the patch so we fake one if it's not there. if version_string.chars().filter(|c| *c == '.').count() == 1 { version_string.push_str(".0"); } Some(semver::Version::parse(&version_string) .unwrap_or_else(|_| panic!("Failed to parse macOS version {}", version_string))) } else { None } } fn mode() -> &'static str { if cfg!(debug_assertions) { "debug" } else { "release" } } fn parse_condition(&self, token: &str) -> Option { match token { platform if platform.starts_with("skip_on(") => { // e.g. skip_on(android,debug) will skip only when // running on a debug android build. let (_, args, _) = parse_function(platform); Some(!args.iter().all(|arg| self.has(arg))) } platform if platform.starts_with("env(") => { // non-negated version of skip_on for nested conditions let (_, args, _) = parse_function(platform); Some(args.iter().all(|arg| self.has(arg))) } platform if platform.starts_with("platform(") => { let (_, args, _) = parse_function(platform); // Skip due to platform not matching Some(args.iter().any(|arg| arg == &self.platform)) } op if op.starts_with("not(") => { let (_, args, _) = parse_function(op); Some(!self.parse_condition(args[0]).expect("unknown condition")) } op if op.starts_with("or(") => { let (_, args, _) = parse_function(op); Some(args.iter().any(|arg| self.parse_condition(arg).expect("unknown condition"))) } op if op.starts_with("and(") => { let (_, args, _) = parse_function(op); Some(args.iter().all(|arg| self.parse_condition(arg).expect("unknown condition"))) } _ => None, } } } pub struct ReftestHarness<'a> { wrench: &'a mut Wrench, window: &'a mut WindowWrapper, rx: &'a Receiver, environment: ReftestEnvironment, } impl<'a> ReftestHarness<'a> { pub fn new(wrench: &'a mut Wrench, window: &'a mut WindowWrapper, rx: &'a Receiver) -> Self { let environment = ReftestEnvironment::new(wrench, window); ReftestHarness { wrench, window, rx, environment } } pub fn run(mut self, base_manifest: &Path, reftests: Option<&Path>, options: &ReftestOptions) -> usize { let manifest = ReftestManifest::new(base_manifest, &self.environment, options); let reftests = manifest.find(reftests.unwrap_or(&PathBuf::new())); let mut total_passing = 0; let mut failing = Vec::new(); for t in reftests { if self.run_reftest(t) { total_passing += 1; } else { failing.push(t); } } println!( "REFTEST INFO | {} passing, {} failing", total_passing, failing.len() ); if !failing.is_empty() { println!("\nReftests with unexpected results:"); for reftest in &failing { println!("\t{}", reftest); } } failing.len() } fn run_reftest(&mut self, t: &Reftest) -> bool { let test_name = t.to_string(); println!("REFTEST {}", test_name); profile_scope!("wrench reftest", text: &test_name); self.wrench .api .send_debug_cmd( DebugCommand::ClearCaches(ClearCache::all()) ); let quality_settings = QualitySettings { force_subpixel_aa_where_possible: t.force_subpixel_aa_where_possible.unwrap_or_default(), }; self.wrench.set_quality_settings(quality_settings); if let Some(max_surface_override) = t.max_surface_override { self.wrench .api .send_debug_cmd( DebugCommand::SetMaximumSurfaceSize(Some(max_surface_override)) ); } let window_size = self.window.get_inner_size(); let reference_image = match t.reference.extension().unwrap().to_str().unwrap() { "yaml" => None, "png" => Some(self.load_image(t.reference.as_path(), ImageFormat::Png)), other => panic!("Unknown reftest extension: {}", other), }; let test_size = reference_image.as_ref().map_or(window_size, |img| img.size); // The reference can be smaller than the window size, in which case // we only compare the intersection. // // Note also that, when we have multiple test scenes in sequence, we // want to test the picture caching machinery. But since picture caching // only takes effect after the result has been the same several frames in // a row, we need to render the scene multiple times. let mut images = vec![]; let mut results = vec![]; match t.op { ReftestOp::Equal | ReftestOp::NotEqual => { // For equality tests, render each test image and store result for filename in t.test.iter() { let output = self.render_yaml( filename, test_size, t.font_render_mode, t.allow_mipmaps, ); images.push(output.image); results.push(output.results); } } ReftestOp::Accurate | ReftestOp::Inaccurate => { // For accuracy tests, render the reference yaml at an arbitrary series // of tile sizes, and compare to the reference drawn at normal tile size. let tile_sizes = [ DeviceIntSize::new(128, 128), DeviceIntSize::new(256, 256), DeviceIntSize::new(512, 512), ]; for tile_size in &tile_sizes { self.wrench .api .send_debug_cmd( DebugCommand::SetPictureTileSize(Some(*tile_size)) ); let output = self.render_yaml( &t.reference, test_size, t.font_render_mode, t.allow_mipmaps, ); images.push(output.image); results.push(output.results); } self.wrench .api .send_debug_cmd( DebugCommand::SetPictureTileSize(None) ); } } let reference = if let Some(image) = reference_image { let save_all_png = false; // flip to true to update all the tests! if save_all_png { let img = images.last().unwrap(); save_flipped(&t.reference, img.data.clone(), img.size); } image } else { let output = self.render_yaml( &t.reference, test_size, t.font_render_mode, t.allow_mipmaps, ); output.image }; if let Some(_) = t.max_surface_override { self.wrench .api .send_debug_cmd( DebugCommand::SetMaximumSurfaceSize(None) ); } for extra_check in t.extra_checks.iter() { if !extra_check.run(&results) { println!( "REFTEST TEST-UNEXPECTED-FAIL | {} | Failing Check: {:?} | Actual Results: {:?}", t, extra_check, results, ); println!("REFTEST TEST-END | {}", t); return false; } } match t.op { ReftestOp::Equal => { // Ensure that the final image matches the reference let test = images.pop().unwrap(); let comparison = test.compare(&reference); t.check_and_report_equality_failure( comparison, &test, &reference, ) } ReftestOp::NotEqual => { // Ensure that the final image *doesn't* match the reference let test = images.pop().unwrap(); let comparison = test.compare(&reference); match comparison { ReftestImageComparison::Equal => { t.report_unexpected_equality(); false } ReftestImageComparison::NotEqual { .. } => { true } } } ReftestOp::Accurate => { // Ensure that *all* images match the reference for test in images.drain(..) { let comparison = test.compare(&reference); if !t.check_and_report_equality_failure( comparison, &test, &reference, ) { return false; } } true } ReftestOp::Inaccurate => { // Ensure that at least one of the images doesn't match the reference let all_same = images.iter().all(|image| { match image.compare(&reference) { ReftestImageComparison::Equal => true, ReftestImageComparison::NotEqual { .. } => false, } }); if all_same { t.report_unexpected_equality(); } !all_same } } } fn load_image(&mut self, filename: &Path, format: ImageFormat) -> ReftestImage { let file = BufReader::new(File::open(filename).unwrap()); let img_raw = load_piston_image(file, format).unwrap(); let img = img_raw.flipv().to_rgba(); let size = img.dimensions(); ReftestImage { data: img.into_raw(), size: DeviceIntSize::new(size.0 as i32, size.1 as i32), } } fn render_yaml( &mut self, filename: &Path, size: DeviceIntSize, font_render_mode: Option, allow_mipmaps: bool, ) -> YamlRenderOutput { let mut reader = YamlFrameReader::new(filename); reader.set_font_render_mode(font_render_mode); reader.allow_mipmaps(allow_mipmaps); reader.do_frame(self.wrench); self.wrench.api.flush_scene_builder(); // wait for the frame self.rx.recv().unwrap(); let results = self.wrench.render(); let window_size = self.window.get_inner_size(); assert!( size.width <= window_size.width && size.height <= window_size.height, "size={:?} ws={:?}", size, window_size ); // taking the bottom left sub-rectangle let rect = FramebufferIntRect::from_origin_and_size( FramebufferIntPoint::new(0, window_size.height - size.height), FramebufferIntSize::new(size.width, size.height), ); let pixels = self.wrench.renderer.read_pixels_rgba8(rect); self.window.swap_buffers(); let write_debug_images = false; if write_debug_images { let debug_path = filename.with_extension("yaml.png"); save_flipped(debug_path, pixels.clone(), size); } reader.deinit(self.wrench); YamlRenderOutput { image: ReftestImage { data: pixels, size }, results, } } }