use api::{ColorF, ColorU};
use crate::renderer::DebugRenderer;
use crate::device::query::GpuTimer;
use euclid::{Point2D, Rect, Size2D, vec2, default};
use crate::internal_types::FastHashMap;
use crate::renderer::{FullFrameStats, MAX_VERTEX_TEXTURE_WIDTH, wr_has_been_initialized};
use api::units::DeviceIntSize;
use std::collections::vec_deque::VecDeque;
use std::fmt::{Write, Debug};
use std::f32;
use std::ffi::CStr;
use std::ops::Range;
use std::time::Duration;
use time::precise_time_ns;
macro_rules! set_text {
($dst:expr, $($arg:tt)*) => {
$dst.clear();
write!($dst, $($arg)*).unwrap();
};
}
const GRAPH_WIDTH: f32 = 1024.0;
const GRAPH_HEIGHT: f32 = 320.0;
const GRAPH_PADDING: f32 = 8.0;
const GRAPH_FRAME_HEIGHT: f32 = 16.0;
const PROFILE_SPACING: f32 = 15.0;
const PROFILE_PADDING: f32 = 10.0;
const BACKGROUND_COLOR: ColorU = ColorU { r: 20, g: 20, b: 20, a: 220 };
const ONE_SECOND_NS: u64 = 1_000_000_000;
static PROFILER_PRESETS: &'static[(&'static str, &'static str)] = &[
(&"Default", &"FPS,|,Slow indicators,_,Time graphs,|,Frame times, ,Transaction times, ,Frame stats, ,Memory, ,Interners,_,GPU time queries,_,Paint phase graph"),
(&"Compact", &"FPS, ,Frame times, ,Frame stats"),
(&"Slow indicators", &"*Slow transaction,*Slow frame"),
(&"Transaction times", &"DisplayList,Scene building,Content send,API send"),
(&"Frame times", &"Frame CPU total,Frame building,Visibility,Prepare,Batching,Glyph resolve,Texture cache update,Renderer,GPU"),
(&"Frame stats", &"Primitives,Visible primitives,Draw calls,Vertices,Color passes,Alpha passes,Rendered picture tiles,Rasterized glyphs"),
(&"Texture cache stats", &"Atlas textures mem, Standalone textures mem, Picture tiles mem, Render targets mem, Depth targets mem, Atlas items mem,
Texture cache standalone pressure, Texture cache eviction count, Texture cache youngest evicted, ,
Atlas RGBA8 linear pixels, Atlas RGBA8 glyphs pixels, Atlas A8 glyphs pixels, Atlas A8 pixels, Atlas A16 pixels, Atlas RGBA8 nearest pixels,
Atlas RGBA8 linear textures, Atlas RGBA8 glyphs textures, Atlas A8 glyphs textures, Atlas A8 textures, Atlas A16 textures, Atlas RGBA8 nearest textures,
Atlas RGBA8 linear pressure, Atlas RGBA8 glyphs pressure, Atlas A8 glyphs pressure, Atlas A8 pressure, Atlas A16 pressure, Atlas RGBA8 nearest pressure,"
),
(&"Texture upload perf", &"#Texture cache update,#Texture cache upload, ,#Staging CPU allocation,#Staging GPU allocation,#Staging CPU copy,#Staging GPU copy,#Upload time, ,#Upload copy batches,#Rasterized glyphs, ,#Cache texture creation,#Cache texture deletion"),
(&"Time graphs", &"#DisplayList,#Scene building,#Blob rasterization, ,#Frame CPU total,#Frame building,#Renderer,#Texture cache update, ,#GPU,"),
(&"Backend graphs", &"#Frame building, #Visibility, #Prepare, #Batching, #Glyph resolve"),
(&"Renderer graphs", &"#Rendered picture tiles,#Draw calls,#Rasterized glyphs,#Texture uploads,#Texture uploads mem, ,#Texture cache update,#Renderer,"),
(&"Memory", &"Image templates,Image templates mem,Font templates,Font templates mem,DisplayList mem,Picture tiles mem"),
(&"Interners", "Interned primitives,Interned clips,Interned pictures,Interned text runs,Interned normal borders,Interned image borders,Interned images,Interned YUV images,Interned line decorations,Interned linear gradients,Interned radial gradients,Interned conic gradients,Interned filter data,Interned backdrops"),
(&"GPU samplers", &"Alpha targets samplers,Transparent pass samplers,Opaque pass samplers,Total samplers"),
];
fn find_preset(name: &str) -> Option<&'static str> {
for preset in PROFILER_PRESETS {
if preset.0 == name {
return Some(preset.1);
}
}
None
}
pub const FRAME_BUILDING_TIME: usize = 0;
pub const FRAME_VISIBILITY_TIME: usize = 1;
pub const FRAME_PREPARE_TIME: usize = 2;
pub const FRAME_BATCHING_TIME: usize = 3;
pub const RENDERER_TIME: usize = 4;
pub const TOTAL_FRAME_CPU_TIME: usize = 5;
pub const GPU_TIME: usize = 6;
pub const CONTENT_SEND_TIME: usize = 7;
pub const API_SEND_TIME: usize = 8;
pub const DISPLAY_LIST_BUILD_TIME: usize = 9;
pub const DISPLAY_LIST_MEM: usize = 10;
pub const SCENE_BUILD_TIME: usize = 11;
pub const SLOW_FRAME: usize = 12;
pub const SLOW_TXN: usize = 13;
pub const FRAME_TIME: usize = 14;
pub const TEXTURE_UPLOADS: usize = 15;
pub const TEXTURE_UPLOADS_MEM: usize = 16;
pub const TEXTURE_CACHE_UPDATE_TIME: usize = 17;
pub const CPU_TEXTURE_ALLOCATION_TIME: usize = 18;
pub const STAGING_TEXTURE_ALLOCATION_TIME: usize = 19;
pub const UPLOAD_CPU_COPY_TIME: usize = 20;
pub const UPLOAD_GPU_COPY_TIME: usize = 21;
pub const UPLOAD_TIME: usize = 22;
pub const UPLOAD_NUM_COPY_BATCHES: usize = 23;
pub const TOTAL_UPLOAD_TIME: usize = 24;
pub const CREATE_CACHE_TEXTURE_TIME: usize = 25;
pub const DELETE_CACHE_TEXTURE_TIME: usize = 26;
pub const GPU_CACHE_UPLOAD_TIME: usize = 27;
pub const RASTERIZED_BLOBS: usize = 28;
pub const RASTERIZED_BLOB_TILES: usize = 29;
pub const RASTERIZED_BLOBS_PX: usize = 30;
pub const BLOB_RASTERIZATION_TIME: usize = 31;
pub const RASTERIZED_GLYPHS: usize = 32;
pub const GLYPH_RESOLVE_TIME: usize = 33;
pub const DRAW_CALLS: usize = 34;
pub const VERTICES: usize = 35;
pub const PRIMITIVES: usize = 36;
pub const VISIBLE_PRIMITIVES: usize = 37;
pub const USED_TARGETS: usize = 38;
pub const CREATED_TARGETS: usize = 39;
pub const PICTURE_CACHE_SLICES: usize = 40;
pub const COLOR_PASSES: usize = 41;
pub const ALPHA_PASSES: usize = 42;
pub const PICTURE_TILES: usize = 43;
pub const RENDERED_PICTURE_TILES: usize = 44;
pub const FONT_TEMPLATES: usize = 45;
pub const FONT_TEMPLATES_MEM: usize = 46;
pub const IMAGE_TEMPLATES: usize = 47;
pub const IMAGE_TEMPLATES_MEM: usize = 48;
pub const GPU_CACHE_ROWS_TOTAL: usize = 49;
pub const GPU_CACHE_ROWS_UPDATED: usize = 50;
pub const GPU_CACHE_BLOCKS_TOTAL: usize = 51;
pub const GPU_CACHE_BLOCKS_UPDATED: usize = 52;
pub const GPU_CACHE_BLOCKS_SAVED: usize = 53;
pub const ATLAS_ITEMS_MEM: usize = 54;
pub const ATLAS_A8_PIXELS: usize = 55;
pub const ATLAS_A8_TEXTURES: usize = 56;
pub const ATLAS_A16_PIXELS: usize = 57;
pub const ATLAS_A16_TEXTURES: usize = 58;
pub const ATLAS_RGBA8_LINEAR_PIXELS: usize = 59;
pub const ATLAS_RGBA8_LINEAR_TEXTURES: usize = 60;
pub const ATLAS_RGBA8_NEAREST_PIXELS: usize = 61;
pub const ATLAS_RGBA8_NEAREST_TEXTURES: usize = 62;
pub const ATLAS_RGBA8_GLYPHS_PIXELS: usize = 63;
pub const ATLAS_RGBA8_GLYPHS_TEXTURES: usize = 64;
pub const ATLAS_A8_GLYPHS_PIXELS: usize = 65;
pub const ATLAS_A8_GLYPHS_TEXTURES: usize = 66;
pub const ATLAS_COLOR8_LINEAR_PRESSURE: usize = 67;
pub const ATLAS_COLOR8_NEAREST_PRESSURE: usize = 68;
pub const ATLAS_COLOR8_GLYPHS_PRESSURE: usize = 69;
pub const ATLAS_ALPHA8_PRESSURE: usize = 70;
pub const ATLAS_ALPHA8_GLYPHS_PRESSURE: usize = 71;
pub const ATLAS_ALPHA16_PRESSURE: usize = 72;
pub const ATLAS_STANDALONE_PRESSURE: usize = 73;
pub const TEXTURE_CACHE_EVICTION_COUNT: usize = 74;
pub const TEXTURE_CACHE_YOUNGEST_EVICTION: usize = 75;
pub const EXTERNAL_IMAGE_BYTES: usize = 76;
pub const ATLAS_TEXTURES_MEM: usize = 77;
pub const STANDALONE_TEXTURES_MEM: usize = 78;
pub const PICTURE_TILES_MEM: usize = 79;
pub const RENDER_TARGET_MEM: usize = 80;
pub const ALPHA_TARGETS_SAMPLERS: usize = 81;
pub const TRANSPARENT_PASS_SAMPLERS: usize = 82;
pub const OPAQUE_PASS_SAMPLERS: usize = 83;
pub const TOTAL_SAMPLERS: usize = 84;
pub const INTERNED_PRIMITIVES: usize = 85;
pub const INTERNED_CLIPS: usize = 86;
pub const INTERNED_TEXT_RUNS: usize = 87;
pub const INTERNED_NORMAL_BORDERS: usize = 88;
pub const INTERNED_IMAGE_BORDERS: usize = 89;
pub const INTERNED_IMAGES: usize = 90;
pub const INTERNED_YUV_IMAGES: usize = 91;
pub const INTERNED_LINE_DECORATIONS: usize = 92;
pub const INTERNED_LINEAR_GRADIENTS: usize = 93;
pub const INTERNED_RADIAL_GRADIENTS: usize = 94;
pub const INTERNED_CONIC_GRADIENTS: usize = 95;
pub const INTERNED_PICTURES: usize = 96;
pub const INTERNED_FILTER_DATA: usize = 97;
pub const INTERNED_BACKDROPS: usize = 98;
pub const INTERNED_POLYGONS: usize = 99;
pub const DEPTH_TARGETS_MEM: usize = 100;
pub const NUM_PROFILER_EVENTS: usize = 101;
pub struct Profiler {
counters: Vec<Counter>,
gpu_frames: ProfilerFrameCollection,
frame_stats: ProfilerFrameCollection,
start: u64,
avg_over_period: u64,
num_graph_samples: usize,
frame_timestamps_within_last_second: Vec<u64>,
ui: Vec<Item>,
}
impl Profiler {
pub fn new() -> Self {
fn float(name: &'static str, unit: &'static str, index: usize, expected: Expected<f64>) -> CounterDescriptor {
CounterDescriptor { name, unit, show_as: ShowAs::Float, index, expected }
}
fn int(name: &'static str, unit: &'static str, index: usize, expected: Expected<i64>) -> CounterDescriptor {
CounterDescriptor { name, unit, show_as: ShowAs::Int, index, expected: expected.into_float() }
}
let profile_counters = &[
float("Frame building", "ms", FRAME_BUILDING_TIME, expected(0.0..6.0).avg(0.0..3.0)),
float("Visibility", "ms", FRAME_VISIBILITY_TIME, expected(0.0..3.0).avg(0.0..2.0)),
float("Prepare", "ms", FRAME_PREPARE_TIME, expected(0.0..3.0).avg(0.0..2.0)),
float("Batching", "ms", FRAME_BATCHING_TIME, expected(0.0..3.0).avg(0.0..2.0)),
float("Renderer", "ms", RENDERER_TIME, expected(0.0..8.0).avg(0.0..5.0)),
float("Frame CPU total", "ms", TOTAL_FRAME_CPU_TIME, expected(0.0..15.0).avg(0.0..6.0)),
float("GPU", "ms", GPU_TIME, expected(0.0..15.0).avg(0.0..8.0)),
float("Content send", "ms", CONTENT_SEND_TIME, expected(0.0..1.0).avg(0.0..1.0)),
float("API send", "ms", API_SEND_TIME, expected(0.0..1.0).avg(0.0..0.4)),
float("DisplayList", "ms", DISPLAY_LIST_BUILD_TIME, expected(0.0..5.0).avg(0.0..3.0)),
float("DisplayList mem", "MB", DISPLAY_LIST_MEM, expected(0.0..20.0)),
float("Scene building", "ms", SCENE_BUILD_TIME, expected(0.0..4.0).avg(0.0..3.0)),
float("Slow frame", "", SLOW_FRAME, expected(0.0..0.0)),
float("Slow transaction", "", SLOW_TXN, expected(0.0..0.0)),
float("Frame", "ms", FRAME_TIME, Expected::none()),
int("Texture uploads", "", TEXTURE_UPLOADS, expected(0..10)),
float("Texture uploads mem", "MB", TEXTURE_UPLOADS_MEM, expected(0.0..10.0)),
float("Texture cache update", "ms", TEXTURE_CACHE_UPDATE_TIME, expected(0.0..3.0)),
float("Staging CPU allocation", "ms", CPU_TEXTURE_ALLOCATION_TIME, Expected::none()),
float("Staging GPU allocation", "ms", STAGING_TEXTURE_ALLOCATION_TIME, Expected::none()),
float("Staging CPU copy", "ms", UPLOAD_CPU_COPY_TIME, Expected::none()),
float("Staging GPU copy", "ms", UPLOAD_GPU_COPY_TIME, Expected::none()),
float("Upload time", "ms", UPLOAD_TIME, Expected::none()),
int("Upload copy batches", "", UPLOAD_NUM_COPY_BATCHES, Expected::none()),
float("Texture cache upload", "ms", TOTAL_UPLOAD_TIME, expected(0.0..5.0)),
float("Cache texture creation", "ms", CREATE_CACHE_TEXTURE_TIME, expected(0.0..2.0)),
float("Cache texture deletion", "ms", DELETE_CACHE_TEXTURE_TIME, expected(0.0..1.0)),
float("GPU cache upload", "ms", GPU_CACHE_UPLOAD_TIME, expected(0.0..2.0)),
int("Rasterized blobs", "", RASTERIZED_BLOBS, expected(0..15)),
int("Rasterized blob tiles", "", RASTERIZED_BLOB_TILES, expected(0..15)),
int("Rasterized blob pixels", "px", RASTERIZED_BLOBS_PX, expected(0..300_000)),
float("Blob rasterization", "ms", BLOB_RASTERIZATION_TIME, expected(0.0..8.0)),
int("Rasterized glyphs", "", RASTERIZED_GLYPHS, expected(0..15)),
float("Glyph resolve", "ms", GLYPH_RESOLVE_TIME, expected(0.0..4.0)),
int("Draw calls", "", DRAW_CALLS, expected(1..120).avg(1..90)),
int("Vertices", "", VERTICES, expected(10..5000)),
int("Primitives", "", PRIMITIVES, expected(10..5000)),
int("Visible primitives", "", VISIBLE_PRIMITIVES, expected(1..5000)),
int("Used targets", "", USED_TARGETS, expected(1..4)),
int("Created targets", "", CREATED_TARGETS, expected(0..3)),
int("Picture cache slices", "", PICTURE_CACHE_SLICES, expected(0..5)),
int("Color passes", "", COLOR_PASSES, expected(1..4)),
int("Alpha passes", "", ALPHA_PASSES, expected(0..3)),
int("Picture tiles", "", PICTURE_TILES, expected(0..15)),
int("Rendered picture tiles", "", RENDERED_PICTURE_TILES, expected(0..5)),
int("Font templates", "", FONT_TEMPLATES, expected(0..40)),
float("Font templates mem", "MB", FONT_TEMPLATES_MEM, expected(0.0..20.0)),
int("Image templates", "", IMAGE_TEMPLATES, expected(0..100)),
float("Image templates mem", "MB", IMAGE_TEMPLATES_MEM, expected(0.0..50.0)),
int("GPU cache rows total", "", GPU_CACHE_ROWS_TOTAL, expected(1..50)),
int("GPU cache rows updated", "", GPU_CACHE_ROWS_UPDATED, expected(0..25)),
int("GPU blocks total", "", GPU_CACHE_BLOCKS_TOTAL, expected(1..65_000)),
int("GPU blocks updated", "", GPU_CACHE_BLOCKS_UPDATED, expected(0..1000)),
int("GPU blocks saved", "", GPU_CACHE_BLOCKS_SAVED, expected(0..50_000)),
float("Atlas items mem", "MB", ATLAS_ITEMS_MEM, expected(0.0..100.0)),
int("Atlas A8 pixels", "px", ATLAS_A8_PIXELS, expected(0..1_000_000)),
int("Atlas A8 textures", "", ATLAS_A8_TEXTURES, expected(0..2)),
int("Atlas A16 pixels", "px", ATLAS_A16_PIXELS, expected(0..260_000)),
int("Atlas A16 textures", "", ATLAS_A16_TEXTURES, expected(0..2)),
int("Atlas RGBA8 linear pixels", "px", ATLAS_RGBA8_LINEAR_PIXELS, expected(0..8_000_000)),
int("Atlas RGBA8 linear textures", "", ATLAS_RGBA8_LINEAR_TEXTURES, expected(0..3)),
int("Atlas RGBA8 nearest pixels", "px", ATLAS_RGBA8_NEAREST_PIXELS, expected(0..260_000)),
int("Atlas RGBA8 nearest textures", "", ATLAS_RGBA8_NEAREST_TEXTURES, expected(0..2)),
int("Atlas RGBA8 glyphs pixels", "px", ATLAS_RGBA8_GLYPHS_PIXELS, expected(0..4_000_000)),
int("Atlas RGBA8 glyphs textures", "", ATLAS_RGBA8_GLYPHS_TEXTURES, expected(0..2)),
int("Atlas A8 glyphs pixels", "px", ATLAS_A8_GLYPHS_PIXELS, expected(0..4_000_000)),
int("Atlas A8 glyphs textures", "", ATLAS_A8_GLYPHS_TEXTURES, expected(0..2)),
float("Atlas RGBA8 linear pressure", "", ATLAS_COLOR8_LINEAR_PRESSURE, expected(0.0..1.0)),
float("Atlas RGBA8 nearest pressure", "", ATLAS_COLOR8_NEAREST_PRESSURE, expected(0.0..1.0)),
float("Atlas RGBA8 glyphs pressure", "", ATLAS_COLOR8_GLYPHS_PRESSURE, expected(0.0..1.0)),
float("Atlas A8 pressure", "", ATLAS_ALPHA8_PRESSURE, expected(0.0..1.0)),
float("Atlas A8 glyphs pressure", "", ATLAS_ALPHA8_GLYPHS_PRESSURE, expected(0.0..1.0)),
float("Atlas A16 pressure", "", ATLAS_ALPHA16_PRESSURE, expected(0.0..1.0)),
float("Texture cache standalone pressure", "", ATLAS_STANDALONE_PRESSURE, expected(0.0..1.0)),
int("Texture cache eviction count", "items", TEXTURE_CACHE_EVICTION_COUNT, Expected::none()),
int("Texture cache youngest evicted", "frames", TEXTURE_CACHE_YOUNGEST_EVICTION, Expected::none()),
float("External image mem", "MB", EXTERNAL_IMAGE_BYTES, Expected::none()),
float("Atlas textures mem", "MB", ATLAS_TEXTURES_MEM, Expected::none()),
float("Standalone textures mem", "MB", STANDALONE_TEXTURES_MEM, Expected::none()),
float("Picture tiles mem", "MB", PICTURE_TILES_MEM, expected(0.0..150.0)),
float("Render targets mem", "MB", RENDER_TARGET_MEM, Expected::none()),
float("Alpha targets samplers", "%", ALPHA_TARGETS_SAMPLERS, Expected::none()),
float("Transparent pass samplers", "%", TRANSPARENT_PASS_SAMPLERS, Expected::none()),
float("Opaque pass samplers", "%", OPAQUE_PASS_SAMPLERS, Expected::none()),
float("Total samplers", "%", TOTAL_SAMPLERS, Expected::none()),
int("Interned primitives", "", INTERNED_PRIMITIVES, Expected::none()),
int("Interned clips", "", INTERNED_CLIPS, Expected::none()),
int("Interned text runs", "", INTERNED_TEXT_RUNS, Expected::none()),
int("Interned normal borders", "", INTERNED_NORMAL_BORDERS, Expected::none()),
int("Interned image borders", "", INTERNED_IMAGE_BORDERS, Expected::none()),
int("Interned images", "", INTERNED_IMAGES, Expected::none()),
int("Interned YUV images", "", INTERNED_YUV_IMAGES, Expected::none()),
int("Interned line decorations", "", INTERNED_LINE_DECORATIONS, Expected::none()),
int("Interned linear gradients", "", INTERNED_LINEAR_GRADIENTS, Expected::none()),
int("Interned radial gradients", "", INTERNED_RADIAL_GRADIENTS, Expected::none()),
int("Interned conic gradients", "", INTERNED_CONIC_GRADIENTS, Expected::none()),
int("Interned pictures", "", INTERNED_PICTURES, Expected::none()),
int("Interned filter data", "", INTERNED_FILTER_DATA, Expected::none()),
int("Interned backdrops", "", INTERNED_BACKDROPS, Expected::none()),
int("Interned polygons", "", INTERNED_POLYGONS, Expected::none()),
float("Depth targets mem", "MB", DEPTH_TARGETS_MEM, Expected::none()),
];
let mut counters = Vec::with_capacity(profile_counters.len());
for (idx, descriptor) in profile_counters.iter().enumerate() {
debug_assert_eq!(descriptor.index, idx);
counters.push(Counter::new(descriptor));
}
Profiler {
gpu_frames: ProfilerFrameCollection::new(),
frame_stats: ProfilerFrameCollection::new(),
counters,
start: precise_time_ns(),
avg_over_period: ONE_SECOND_NS / 2,
num_graph_samples: 500, frame_timestamps_within_last_second: Vec::new(),
ui: Vec::new(),
}
}
fn update_slow_event(&mut self, dst_counter: usize, counters: &[usize], threshold: f64) {
let mut total = 0.0;
for &counter in counters {
if self.counters[counter].value.is_finite() {
total += self.counters[counter].value;
}
}
if total > threshold {
self.counters[dst_counter].set(total);
}
}
pub fn update(&mut self) {
let now = precise_time_ns();
let update_avg = (now - self.start) > self.avg_over_period;
if update_avg {
self.start = now;
}
let one_second_ago = now - ONE_SECOND_NS;
self.frame_timestamps_within_last_second.retain(|t| *t > one_second_ago);
self.frame_timestamps_within_last_second.push(now);
self.update_slow_event(
SLOW_FRAME,
&[TOTAL_FRAME_CPU_TIME],
15.0,
);
self.update_slow_event(
SLOW_TXN,
&[DISPLAY_LIST_BUILD_TIME, CONTENT_SEND_TIME, SCENE_BUILD_TIME],
80.0
);
for counter in &mut self.counters {
counter.update(update_avg);
}
}
pub fn update_frame_stats(&mut self, stats: FullFrameStats) {
if stats.gecko_display_list_time != 0.0 {
self.frame_stats.push(stats.into());
}
}
pub fn set_gpu_time_queries(&mut self, gpu_queries: Vec<GpuTimer>) {
let mut gpu_time_ns = 0;
for sample in &gpu_queries {
gpu_time_ns += sample.time_ns;
}
self.gpu_frames.push(ProfilerFrame {
total_time: gpu_time_ns,
samples: gpu_queries
});
self.counters[GPU_TIME].set_f64(ns_to_ms(gpu_time_ns));
}
pub fn index_of(&self, name: &str) -> Option<usize> {
self.counters.iter().position(|counter| counter.name == name)
}
pub fn set_ui(&mut self, names: &str) {
let mut selection = Vec::new();
self.append_to_ui(&mut selection, names);
if selection == self.ui {
return;
}
for counter in &mut self.counters {
counter.disable_graph();
}
for item in &selection {
if let Item::Graph(idx) = item {
self.counters[*idx].enable_graph(self.num_graph_samples);
}
}
self.ui = selection;
}
fn append_to_ui(&mut self, selection: &mut Vec<Item>, names: &str) {
fn flush_counters(counters: &mut Vec<usize>, selection: &mut Vec<Item>) {
if !counters.is_empty() {
selection.push(Item::Counters(std::mem::take(counters)))
}
}
let mut counters = Vec::new();
for name in names.split(",") {
let name = name.trim();
let is_graph = name.starts_with("#");
let is_indicator = name.starts_with("*");
let name = if is_graph || is_indicator {
&name[1..]
} else {
name
};
match name {
"" => {
flush_counters(&mut counters, selection);
selection.push(Item::Space);
}
"|" => {
flush_counters(&mut counters, selection);
selection.push(Item::Column);
}
"_" => {
flush_counters(&mut counters, selection);
selection.push(Item::Row);
}
"FPS" => {
flush_counters(&mut counters, selection);
selection.push(Item::Fps);
}
"GPU time queries" => {
flush_counters(&mut counters, selection);
selection.push(Item::GpuTimeQueries);
}
"GPU cache bars" => {
flush_counters(&mut counters, selection);
selection.push(Item::GpuCacheBars);
}
"Paint phase graph" => {
flush_counters(&mut counters, selection);
selection.push(Item::PaintPhaseGraph);
}
_ => {
if let Some(idx) = self.index_of(name) {
if is_graph {
flush_counters(&mut counters, selection);
selection.push(Item::Graph(idx));
} else if is_indicator {
flush_counters(&mut counters, selection);
selection.push(Item::ChangeIndicator(idx));
} else {
counters.push(idx);
}
} else if let Some(preset_str) = find_preset(name) {
flush_counters(&mut counters, selection);
self.append_to_ui(selection, preset_str);
} else {
selection.push(Item::Text(format!("Unknonw counter: {}", name)));
}
}
}
}
flush_counters(&mut counters, selection);
}
pub fn set_counters(&mut self, counters: &mut TransactionProfile) {
for (id, evt) in counters.events.iter_mut().enumerate() {
if let Event::Value(val) = *evt {
self.counters[id].set(val);
}
*evt = Event::None;
}
}
pub fn get(&self, id: usize) -> Option<f64> {
self.counters[id].get()
}
fn draw_counters(
counters: &[Counter],
selected: &[usize],
mut x: f32, mut y: f32,
text_buffer: &mut String,
debug_renderer: &mut DebugRenderer,
) -> default::Rect<f32> {
let line_height = debug_renderer.line_height();
x += PROFILE_PADDING;
y += PROFILE_PADDING;
let origin = default::Point2D::new(x, y);
y += line_height * 0.5;
let mut total_rect = Rect::zero();
let mut color_index = 0;
let colors = [
ColorU::new(255, 255, 255, 255),
ColorU::new(255, 255, 0, 255),
ColorU::new(255, 80, 0, 255),
ColorU::new(255, 0, 0, 255),
];
for idx in selected {
let counter = &counters[*idx];
let rect = debug_renderer.add_text(
x, y,
counter.name,
colors[color_index],
None,
);
color_index = (color_index + 1) % 2;
total_rect = total_rect.union(&rect);
y += line_height;
}
color_index = 0;
x = total_rect.max_x() + 60.0;
y = origin.y + line_height * 0.5;
for idx in selected {
let counter = &counters[*idx];
let expected_offset = if counter.has_unexpected_avg_max() { 2 } else { 0 };
counter.write_value(text_buffer);
let rect = debug_renderer.add_text(
x,
y,
&text_buffer,
colors[color_index + expected_offset],
None,
);
color_index = (color_index + 1) % 2;
total_rect = total_rect.union(&rect);
y += line_height;
}
total_rect = total_rect
.union(&Rect { origin, size: Size2D::new(1.0, 1.0) })
.inflate(PROFILE_PADDING, PROFILE_PADDING);
debug_renderer.add_quad(
total_rect.min_x(),
total_rect.min_y(),
total_rect.max_x(),
total_rect.max_y(),
BACKGROUND_COLOR,
BACKGROUND_COLOR,
);
total_rect
}
fn draw_graph(
counter: &Counter,
x: f32,
y: f32,
text_buffer: &mut String,
debug_renderer: &mut DebugRenderer,
) -> default::Rect<f32> {
let graph = counter.graph.as_ref().unwrap();
let max_samples = graph.values.capacity() as f32;
let size = Size2D::new(max_samples, 100.0);
let line_height = debug_renderer.line_height();
let graph_rect = Rect::new(Point2D::new(x + PROFILE_PADDING, y + PROFILE_PADDING), size);
let mut rect = graph_rect.inflate(PROFILE_PADDING, PROFILE_PADDING);
let stats = graph.stats();
let text_color = ColorU::new(255, 255, 0, 255);
let text_origin = rect.origin + vec2(rect.size.width, 25.0);
set_text!(text_buffer, "{} ({})", counter.name, counter.unit);
debug_renderer.add_text(
text_origin.x,
text_origin.y,
if counter.unit == "" { counter.name } else { text_buffer },
ColorU::new(0, 255, 0, 255),
None,
);
set_text!(text_buffer, "Samples: {}", stats.samples);
debug_renderer.add_text(
text_origin.x,
text_origin.y + line_height,
text_buffer,
text_color,
None,
);
if stats.samples > 0 {
set_text!(text_buffer, "Min: {:.2} {}", stats.min, counter.unit);
debug_renderer.add_text(
text_origin.x,
text_origin.y + line_height * 2.0,
text_buffer,
text_color,
None,
);
set_text!(text_buffer, "Avg: {:.2} {}", stats.avg, counter.unit);
debug_renderer.add_text(
text_origin.x,
text_origin.y + line_height * 3.0,
text_buffer,
text_color,
None,
);
set_text!(text_buffer, "Max: {:.2} {}", stats.max, counter.unit);
debug_renderer.add_text(
text_origin.x,
text_origin.y + line_height * 4.0,
text_buffer,
text_color,
None,
);
}
rect.size.width += 220.0;
debug_renderer.add_quad(
rect.min_x(),
rect.min_y(),
rect.max_x(),
rect.max_y(),
BACKGROUND_COLOR,
BACKGROUND_COLOR,
);
let bx1 = graph_rect.max_x();
let by1 = graph_rect.max_y();
let w = graph_rect.size.width / max_samples;
let h = graph_rect.size.height;
let color_t0 = ColorU::new(0, 255, 0, 255);
let color_b0 = ColorU::new(0, 180, 0, 255);
let color_t2 = ColorU::new(255, 0, 0, 255);
let color_b2 = ColorU::new(180, 0, 0, 255);
for (index, sample) in graph.values.iter().enumerate() {
if !sample.is_finite() {
continue;
}
let sample = *sample as f32;
let x1 = bx1 - index as f32 * w;
let x0 = x1 - w;
let y0 = by1 - (sample / stats.max as f32) as f32 * h;
let y1 = by1;
let (color_top, color_bottom) = if counter.is_unexpected_value(sample as f64) {
(color_t2, color_b2)
} else {
(color_t0, color_b0)
};
debug_renderer.add_quad(x0, y0, x1, y1, color_top, color_bottom);
}
rect
}
fn draw_change_indicator(
counter: &Counter,
x: f32, y: f32,
debug_renderer: &mut DebugRenderer
) -> default::Rect<f32> {
let height = 10.0;
let width = 20.0;
let color = if counter.has_unexpected_value() || counter.has_unexpected_avg_max() {
ColorU::new(255, 20, 20, 255)
} else {
ColorU::new(0, 100, 250, 255)
};
let tx = counter.change_indicator as f32 * width;
debug_renderer.add_quad(
x,
y,
x + 15.0 * width,
y + height,
ColorU::new(0, 0, 0, 150),
ColorU::new(0, 0, 0, 150),
);
debug_renderer.add_quad(
x + tx,
y,
x + tx + width,
y + height,
color,
ColorU::new(25, 25, 25, 255),
);
Rect {
origin: Point2D::new(x, y),
size: Size2D::new(15.0 * width + 20.0, height),
}
}
fn draw_bar(
label: &str,
label_color: ColorU,
counters: &[(ColorU, usize)],
x: f32, y: f32,
debug_renderer: &mut DebugRenderer,
) -> default::Rect<f32> {
let x = x + 8.0;
let y = y + 24.0;
let text_rect = debug_renderer.add_text(
x, y,
label,
label_color,
None,
);
let x_base = text_rect.max_x() + 10.0;
let width = 300.0;
let total_value = counters.last().unwrap().1;
let scale = width / total_value as f32;
let mut x_current = x_base;
for &(color, counter) in counters {
let x_stop = x_base + counter as f32 * scale;
debug_renderer.add_quad(
x_current,
text_rect.origin.y,
x_stop,
text_rect.max_y(),
color,
color,
);
x_current = x_stop;
}
let mut total_rect = text_rect;
total_rect.size.width += width + 10.0;
total_rect
}
fn draw_gpu_cache_bars(&self, x: f32, mut y: f32, text_buffer: &mut String, debug_renderer: &mut DebugRenderer) -> default::Rect<f32> {
let color_updated = ColorU::new(0xFF, 0, 0, 0xFF);
let color_free = ColorU::new(0, 0, 0xFF, 0xFF);
let color_saved = ColorU::new(0, 0xFF, 0, 0xFF);
let updated_blocks = self.get(GPU_CACHE_BLOCKS_UPDATED).unwrap_or(0.0) as usize;
let saved_blocks = self.get(GPU_CACHE_BLOCKS_SAVED).unwrap_or(0.0) as usize;
let allocated_blocks = self.get(GPU_CACHE_BLOCKS_TOTAL).unwrap_or(0.0) as usize;
let allocated_rows = self.get(GPU_CACHE_ROWS_TOTAL).unwrap_or(0.0) as usize;
let updated_rows = self.get(GPU_CACHE_ROWS_UPDATED).unwrap_or(0.0) as usize;
let requested_blocks = updated_blocks + saved_blocks;
let total_blocks = allocated_rows * MAX_VERTEX_TEXTURE_WIDTH;
set_text!(text_buffer, "GPU cache rows ({}):", allocated_rows);
let rect0 = Profiler::draw_bar(
text_buffer,
ColorU::new(0xFF, 0xFF, 0xFF, 0xFF),
&[
(color_updated, updated_rows),
(color_free, allocated_rows),
],
x, y,
debug_renderer,
);
y = rect0.max_y();
let rect1 = Profiler::draw_bar(
"GPU cache blocks",
ColorU::new(0xFF, 0xFF, 0, 0xFF),
&[
(color_updated, updated_blocks),
(color_saved, requested_blocks),
(color_free, allocated_blocks),
(ColorU::new(0, 0, 0, 0xFF), total_blocks),
],
x, y,
debug_renderer,
);
let total_rect = rect0.union(&rect1).inflate(10.0, 10.0);
debug_renderer.add_quad(
total_rect.origin.x,
total_rect.origin.y,
total_rect.origin.x + total_rect.size.width,
total_rect.origin.y + total_rect.size.height,
ColorF::new(0.1, 0.1, 0.1, 0.8).into(),
ColorF::new(0.2, 0.2, 0.2, 0.8).into(),
);
total_rect
}
fn draw_frame_graph(
frame_collection: &ProfilerFrameCollection,
x: f32, y: f32,
debug_renderer: &mut DebugRenderer,
) -> default::Rect<f32> {
let mut has_data = false;
for frame in &frame_collection.frames {
if !frame.samples.is_empty() {
has_data = true;
break;
}
}
if !has_data {
return Rect::zero();
}
let graph_rect = Rect::new(
Point2D::new(x + GRAPH_PADDING, y + GRAPH_PADDING),
Size2D::new(GRAPH_WIDTH, GRAPH_HEIGHT),
);
let bounding_rect = graph_rect.inflate(GRAPH_PADDING, GRAPH_PADDING);
debug_renderer.add_quad(
bounding_rect.origin.x,
bounding_rect.origin.y,
bounding_rect.origin.x + bounding_rect.size.width,
bounding_rect.origin.y + bounding_rect.size.height,
BACKGROUND_COLOR,
BACKGROUND_COLOR,
);
let w = graph_rect.size.width;
let mut y0 = graph_rect.origin.y;
let mut max_time = frame_collection.frames
.iter()
.max_by_key(|f| f.total_time)
.unwrap()
.total_time as f32;
let baseline_ns = 16_000_000.0; max_time = max_time.max(baseline_ns);
let mut tags_present = FastHashMap::default();
for frame in &frame_collection.frames {
let y1 = y0 + GRAPH_FRAME_HEIGHT;
let mut current_ns = 0;
for sample in &frame.samples {
let x0 = graph_rect.origin.x + w * current_ns as f32 / max_time;
current_ns += sample.time_ns;
let x1 = graph_rect.origin.x + w * current_ns as f32 / max_time;
let mut bottom_color = sample.tag.color;
bottom_color.a *= 0.5;
debug_renderer.add_quad(
x0,
y0,
x1,
y1,
sample.tag.color.into(),
bottom_color.into(),
);
tags_present.insert(sample.tag.label, sample.tag.color);
}
y0 = y1;
}
if max_time > baseline_ns {
let x = graph_rect.origin.x + w * baseline_ns as f32 / max_time;
let height = frame_collection.frames.len() as f32 * GRAPH_FRAME_HEIGHT;
debug_renderer.add_quad(
x,
graph_rect.origin.y,
x + 4.0,
graph_rect.origin.y + height,
ColorU::new(120, 00, 00, 150),
ColorU::new(120, 00, 00, 100),
);
}
const LEGEND_SIZE: f32 = 20.0;
const PADDED_LEGEND_SIZE: f32 = 25.0;
if !tags_present.is_empty() {
debug_renderer.add_quad(
bounding_rect.max_x() + GRAPH_PADDING,
bounding_rect.origin.y,
bounding_rect.max_x() + GRAPH_PADDING + 200.0,
bounding_rect.origin.y + tags_present.len() as f32 * PADDED_LEGEND_SIZE + GRAPH_PADDING,
BACKGROUND_COLOR,
BACKGROUND_COLOR,
);
}
for (i, (label, &color)) in tags_present.iter().enumerate() {
let x0 = bounding_rect.origin.x + bounding_rect.size.width + GRAPH_PADDING * 2.0;
let y0 = bounding_rect.origin.y + GRAPH_PADDING + i as f32 * PADDED_LEGEND_SIZE;
debug_renderer.add_quad(
x0, y0, x0 + LEGEND_SIZE, y0 + LEGEND_SIZE,
color.into(),
color.into(),
);
debug_renderer.add_text(
x0 + PADDED_LEGEND_SIZE,
y0 + LEGEND_SIZE * 0.75,
label,
ColorU::new(255, 255, 0, 255),
None,
);
}
bounding_rect
}
pub fn draw_profile(
&mut self,
_frame_index: u64,
debug_renderer: &mut DebugRenderer,
device_size: DeviceIntSize,
) {
let x_start = 20.0;
let mut y_start = 150.0;
let default_column_width = 400.0;
let mut text_buffer = String::with_capacity(32);
let mut column_width = default_column_width;
let mut max_y = y_start;
let mut x = x_start;
let mut y = y_start;
for elt in &self.ui {
let rect = match elt {
Item::Counters(indices) => {
Profiler::draw_counters(&self.counters, &indices, x, y, &mut text_buffer, debug_renderer)
}
Item::Graph(idx) => {
Profiler::draw_graph(&self.counters[*idx], x, y, &mut text_buffer, debug_renderer)
}
Item::ChangeIndicator(idx) => {
Profiler::draw_change_indicator(&self.counters[*idx], x, y, debug_renderer)
}
Item::GpuTimeQueries => {
Profiler::draw_frame_graph(&self.gpu_frames, x, y, debug_renderer)
}
Item::GpuCacheBars => {
self.draw_gpu_cache_bars(x, y, &mut text_buffer, debug_renderer)
}
Item::PaintPhaseGraph => {
Profiler::draw_frame_graph(&self.frame_stats, x, y, debug_renderer)
}
Item::Text(text) => {
let p = 10.0;
let mut rect = debug_renderer.add_text(
x + p,
y + p,
&text,
ColorU::new(255, 255, 255, 255),
None,
);
rect = rect.inflate(p, p);
debug_renderer.add_quad(
rect.origin.x,
rect.origin.y,
rect.max_x(),
rect.max_y(),
BACKGROUND_COLOR,
BACKGROUND_COLOR,
);
rect
}
Item::Fps => {
let fps = self.frame_timestamps_within_last_second.len();
set_text!(&mut text_buffer, "{} fps", fps);
let mut rect = debug_renderer.add_text(
x + PROFILE_PADDING,
y + PROFILE_PADDING + 5.0,
&text_buffer,
ColorU::new(255, 255, 255, 255),
None,
);
rect = rect.inflate(PROFILE_PADDING, PROFILE_PADDING);
debug_renderer.add_quad(
rect.min_x(),
rect.min_y(),
rect.max_x(),
rect.max_y(),
BACKGROUND_COLOR,
BACKGROUND_COLOR,
);
rect
}
Item::Space => {
Rect { origin: Point2D::new(x, y), size: Size2D::new(0.0, PROFILE_SPACING) }
}
Item::Column => {
max_y = max_y.max(y);
x += column_width + PROFILE_SPACING;
y = y_start;
column_width = default_column_width;
continue;
}
Item::Row => {
max_y = max_y.max(y);
y_start = max_y + PROFILE_SPACING;
y = y_start;
x = x_start;
column_width = default_column_width;
continue;
}
};
column_width = column_width.max(rect.size.width);
y = rect.max_y();
if y > device_size.height as f32 - 100.0 {
max_y = max_y.max(y);
x += column_width + PROFILE_SPACING;
y = y_start;
column_width = default_column_width;
}
}
}
#[cfg(feature = "capture")]
pub fn dump_stats(&self, sink: &mut dyn std::io::Write) -> std::io::Result<()> {
for counter in &self.counters {
if counter.value.is_finite() {
writeln!(sink, "{} {:?}{}", counter.name, counter.value, counter.unit)?;
}
}
Ok(())
}
}
pub trait ProfilerHooks : Send + Sync {
fn register_thread(&self, thread_name: &str);
fn unregister_thread(&self);
fn begin_marker(&self, label: &CStr);
fn end_marker(&self, label: &CStr);
fn event_marker(&self, label: &CStr);
fn add_text_marker(&self, label: &CStr, text: &str, duration: Duration);
fn thread_is_being_profiled(&self) -> bool;
}
pub static mut PROFILER_HOOKS: Option<&'static dyn ProfilerHooks> = None;
pub fn set_profiler_hooks(hooks: Option<&'static dyn ProfilerHooks>) {
if !wr_has_been_initialized() {
unsafe {
PROFILER_HOOKS = hooks;
}
}
}
pub struct ProfileScope {
name: &'static CStr,
}
pub fn register_thread(thread_name: &str) {
unsafe {
if let Some(ref hooks) = PROFILER_HOOKS {
hooks.register_thread(thread_name);
}
}
}
pub fn unregister_thread() {
unsafe {
if let Some(ref hooks) = PROFILER_HOOKS {
hooks.unregister_thread();
}
}
}
pub fn add_text_marker(label: &CStr, text: &str, duration: Duration) {
unsafe {
if let Some(ref hooks) = PROFILER_HOOKS {
hooks.add_text_marker(label, text, duration);
}
}
}
pub fn add_event_marker(label: &CStr) {
unsafe {
if let Some(ref hooks) = PROFILER_HOOKS {
hooks.event_marker(label);
}
}
}
pub fn thread_is_being_profiled() -> bool {
unsafe {
PROFILER_HOOKS.map_or(false, |h| h.thread_is_being_profiled())
}
}
impl ProfileScope {
pub fn new(name: &'static CStr) -> Self {
unsafe {
if let Some(ref hooks) = PROFILER_HOOKS {
hooks.begin_marker(name);
}
}
ProfileScope {
name,
}
}
}
impl Drop for ProfileScope {
fn drop(&mut self) {
unsafe {
if let Some(ref hooks) = PROFILER_HOOKS {
hooks.end_marker(self.name);
}
}
}
}
macro_rules! profile_marker {
($string:expr) => {
let _scope = $crate::profiler::ProfileScope::new(cstr!($string));
};
}
#[derive(Debug, Clone)]
pub struct GpuProfileTag {
pub label: &'static str,
pub color: ColorF,
}
#[derive(Clone, Debug)]
pub struct Expected<T> {
pub range: Option<Range<T>>,
pub avg: Option<Range<T>>,
}
impl<T> Expected<T> {
const fn none() -> Self {
Expected {
range: None,
avg: None,
}
}
}
const fn expected<T>(range: Range<T>) -> Expected<T> {
Expected {
range: Some(range),
avg: None,
}
}
impl Expected<f64> {
const fn avg(mut self, avg: Range<f64>) -> Self {
self.avg = Some(avg);
self
}
}
impl Expected<i64> {
const fn avg(mut self, avg: Range<i64>) -> Self {
self.avg = Some(avg);
self
}
fn into_float(self) -> Expected<f64> {
Expected {
range: match self.range {
Some(r) => Some(r.start as f64 .. r.end as f64),
None => None,
},
avg: match self.avg {
Some(r) => Some(r.start as f64 .. r.end as f64),
None => None,
},
}
}
}
pub struct CounterDescriptor {
pub name: &'static str,
pub unit: &'static str,
pub index: usize,
pub show_as: ShowAs,
pub expected: Expected<f64>,
}
#[derive(Debug)]
pub struct Counter {
pub name: &'static str,
pub unit: &'static str,
pub show_as: ShowAs,
pub expected: Expected<f64>,
value: f64,
num_samples: u64,
sum: f64,
next_max: f64,
max: f64,
avg: f64,
change_indicator: u8,
index: usize,
graph: Option<Graph>,
}
impl Counter {
pub fn new(descriptor: &CounterDescriptor) -> Self {
Counter {
name: descriptor.name,
unit: descriptor.unit,
show_as: descriptor.show_as,
expected: descriptor.expected.clone(),
index: descriptor.index,
value: std::f64::NAN,
num_samples: 0,
sum: 0.0,
next_max: 0.0,
max: 0.0,
avg: 0.0,
change_indicator: 0,
graph: None,
}
}
pub fn set_f64(&mut self, val: f64) {
self.value = val;
}
pub fn set<T>(&mut self, val: T) where T: Into<f64> {
self.set_f64(val.into());
}
pub fn get(&self) -> Option<f64> {
if self.value.is_finite() {
Some(self.value)
} else {
None
}
}
pub fn write_value(&self, output: &mut String) {
match self.show_as {
ShowAs::Float => {
set_text!(output, "{:.2} {} (max: {:.2})", self.avg, self.unit, self.max);
}
ShowAs::Int => {
set_text!(output, "{:.0} {} (max: {:.0})", self.avg.round(), self.unit, self.max.round());
}
}
}
pub fn enable_graph(&mut self, max_samples: usize) {
if self.graph.is_some() {
return;
}
self.graph = Some(Graph::new(max_samples));
}
pub fn disable_graph(&mut self) {
self.graph = None;
}
pub fn is_unexpected_value(&self, value: f64) -> bool {
if let Some(range) = &self.expected.range {
return value.is_finite() && value >= range.end;
}
false
}
pub fn has_unexpected_value(&self) -> bool {
self.is_unexpected_value(self.value)
}
pub fn has_unexpected_avg_max(&self) -> bool {
if let Some(range) = &self.expected.range {
if self.max.is_finite() && self.max >= range.end {
return true;
}
}
if let Some(range) = &self.expected.avg {
if self.avg < range.start || self.avg >= range.end {
return true;
}
}
false
}
fn update(&mut self, update_avg: bool) {
let updated = self.value.is_finite();
if updated {
self.next_max = self.next_max.max(self.value);
self.sum += self.value;
self.num_samples += 1;
self.change_indicator = (self.change_indicator + 1) % 15;
}
if let Some(graph) = &mut self.graph {
graph.set(self.value);
}
self.value = std::f64::NAN;
if update_avg && self.num_samples > 0 {
self.avg = self.sum / self.num_samples as f64;
self.max = self.next_max;
self.sum = 0.0;
self.num_samples = 0;
self.next_max = std::f64::MIN;
}
}
}
#[derive(Copy, Clone, Debug)]
pub enum Event {
Start(u64),
Value(f64),
None,
}
pub trait EventValue {
fn into_f64(self) -> f64;
}
impl EventValue for f64 { fn into_f64(self) -> f64 { self } }
impl EventValue for f32 { fn into_f64(self) -> f64 { self as f64 } }
impl EventValue for u32 { fn into_f64(self) -> f64 { self as f64 } }
impl EventValue for i32 { fn into_f64(self) -> f64 { self as f64 } }
impl EventValue for u64 { fn into_f64(self) -> f64 { self as f64 } }
impl EventValue for usize { fn into_f64(self) -> f64 { self as f64 } }
pub struct TransactionProfile {
pub events: Vec<Event>,
}
impl TransactionProfile {
pub fn new() -> Self {
TransactionProfile {
events: vec![Event::None; NUM_PROFILER_EVENTS],
}
}
pub fn start_time(&mut self, id: usize) {
let ns = precise_time_ns();
self.events[id] = Event::Start(ns);
}
pub fn end_time(&mut self, id: usize) -> f64 {
self.end_time_if_started(id).unwrap()
}
pub fn end_time_if_started(&mut self, id: usize) -> Option<f64> {
if let Event::Start(start) = self.events[id] {
let now = precise_time_ns();
let time_ns = now - start;
let time_ms = ns_to_ms(time_ns);
self.events[id] = Event::Value(time_ms);
Some(time_ms)
} else {
None
}
}
pub fn set<T>(&mut self, id: usize, value: T) where T: EventValue {
self.set_f64(id, value.into_f64());
}
pub fn set_f64(&mut self, id: usize, value: f64) {
self.events[id] = Event::Value(value);
}
pub fn get(&self, id: usize) -> Option<f64> {
if let Event::Value(val) = self.events[id] {
Some(val)
} else {
None
}
}
pub fn get_or(&self, id: usize, or: f64) -> f64 {
self.get(id).unwrap_or(or)
}
pub fn add<T>(&mut self, id: usize, n: T) where T: EventValue {
let n = n.into_f64();
let evt = &mut self.events[id];
let val = match *evt {
Event::Value(v) => v + n,
Event::None => n,
Event::Start(..) => { panic!(); }
};
*evt = Event::Value(val);
}
pub fn inc(&mut self, id: usize) {
self.add(id, 1.0);
}
pub fn take(&mut self) -> Self {
TransactionProfile {
events: std::mem::take(&mut self.events),
}
}
pub fn take_and_reset(&mut self) -> Self {
let events = std::mem::take(&mut self.events);
*self = TransactionProfile::new();
TransactionProfile { events }
}
pub fn merge(&mut self, other: &mut Self) {
for i in 0..self.events.len() {
match (self.events[i], other.events[i]) {
(Event::Value(v1), Event::Value(v2)) => {
self.events[i] = Event::Value(v1.max(v2));
}
(Event::Value(_), _) => {}
(_, Event::Value(v2)) => {
self.events[i] = Event::Value(v2);
}
(Event::None, evt) => {
self.events[i] = evt;
}
(Event::Start(s1), Event::Start(s2)) => {
self.events[i] = Event::Start(s1.max(s2));
}
_=> {}
}
other.events[i] = Event::None;
}
}
pub fn clear(&mut self) {
for evt in &mut self.events {
*evt = Event::None;
}
}
}
#[derive(Debug)]
pub struct GraphStats {
pub min: f64,
pub avg: f64,
pub max: f64,
pub sum: f64,
pub samples: usize,
}
#[derive(Debug)]
pub struct Graph {
values: VecDeque<f64>,
}
impl Graph {
fn new(max_samples: usize) -> Self {
let mut values = VecDeque::new();
values.reserve(max_samples);
Graph { values }
}
fn set(&mut self, val: f64) {
if self.values.len() == self.values.capacity() {
self.values.pop_back();
}
self.values.push_front(val);
}
pub fn stats(&self) -> GraphStats {
let mut stats = GraphStats {
min: f64::MAX,
avg: 0.0,
max: -f64::MAX,
sum: 0.0,
samples: 0,
};
let mut samples = 0;
for value in &self.values {
if value.is_finite() {
stats.min = stats.min.min(*value);
stats.max = stats.max.max(*value);
stats.sum += *value;
samples += 1;
}
}
if samples > 0 {
stats.avg = stats.sum / samples as f64;
stats.samples = samples;
}
stats
}
}
#[derive(Copy, Clone, Debug, PartialEq, Eq)]
pub enum ShowAs {
Float,
Int,
}
struct ProfilerFrame {
total_time: u64,
samples: Vec<GpuTimer>,
}
struct ProfilerFrameCollection {
frames: VecDeque<ProfilerFrame>,
}
impl ProfilerFrameCollection {
fn new() -> Self {
ProfilerFrameCollection {
frames: VecDeque::new(),
}
}
fn push(&mut self, frame: ProfilerFrame) {
if self.frames.len() == 20 {
self.frames.pop_back();
}
self.frames.push_front(frame);
}
}
impl From<FullFrameStats> for ProfilerFrame {
fn from(stats: FullFrameStats) -> ProfilerFrame {
let new_sample = |time, label, color| -> GpuTimer {
let tag = GpuProfileTag {
label,
color
};
let time_ns = ms_to_ns(time);
GpuTimer {
tag, time_ns
}
};
let samples = vec![
new_sample(stats.gecko_display_list_time, "Gecko DL", ColorF { r: 0.0, g: 1.0, b: 0.0, a: 1.0 }),
new_sample(stats.wr_display_list_time, "WR DL", ColorF { r: 0.0, g: 1.0, b: 1.0, a: 1.0 }),
new_sample(stats.scene_build_time, "Scene Build", ColorF { r: 1.0, g: 0.0, b: 1.0, a: 1.0 }),
new_sample(stats.frame_build_time, "Frame Build", ColorF { r: 1.0, g: 0.0, b: 0.0, a: 1.0 }),
];
ProfilerFrame {
total_time: ms_to_ns(stats.total()),
samples
}
}
}
pub fn ns_to_ms(ns: u64) -> f64 {
ns as f64 / 1_000_000.0
}
pub fn ms_to_ns(ms: f64) -> u64 {
(ms * 1_000_000.0) as u64
}
pub fn bytes_to_mb(bytes: usize) -> f64 {
bytes as f64 / 1_000_000.0
}
#[derive(Debug, PartialEq)]
enum Item {
Counters(Vec<usize>),
Graph(usize),
ChangeIndicator(usize),
Fps,
GpuTimeQueries,
GpuCacheBars,
PaintPhaseGraph,
Text(String),
Space,
Column,
Row,
}