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skia/external/github.com/linebender/vello/refs/heads/tmp_perf_measurement/./piet-gpu/bin/cli.rs
blob: fe8c4aca46133e8cd33e3290f734a83cc690d9e7 [file] [edit]
use std::fs::File;
use std::io::BufWriter;
use std::path::Path;
use piet_gpu_hal::vulkan::VkInstance;
use piet_gpu_hal::{CmdBuf, Device, Error, MemFlags};
use piet_gpu::{render_scene, PietGpuRenderContext, Renderer, HEIGHT, WIDTH};
#[allow(unused)]
fn dump_scene(buf: &[u8]) {
for i in 0..(buf.len() / 4) {
let mut buf_u32 = [0u8; 4];
buf_u32.copy_from_slice(&buf[i * 4..i * 4 + 4]);
println!("{:4x}: {:8x}", i * 4, u32::from_le_bytes(buf_u32));
}
}
#[allow(unused)]
fn dump_state(buf: &[u8]) {
for i in 0..(buf.len() / 48) {
let j = i * 48;
let floats = (0..11).map(|k| {
let mut buf_f32 = [0u8; 4];
buf_f32.copy_from_slice(&buf[j + k * 4..j + k * 4 + 4]);
f32::from_le_bytes(buf_f32)
}).collect::<Vec<_>>();
println!("{}: [{} {} {} {} {} {}] ({}, {})-({} {}) {} {}",
i,
floats[0], floats[1], floats[2], floats[3], floats[4], floats[5],
floats[6], floats[7], floats[8], floats[9],
floats[10], buf[j + 44]);
}
}
/// Interpret the output of the binning stage, for diagnostic purposes.
#[allow(unused)]
fn trace_merge(buf: &[u32]) {
for bin in 0..256 {
println!("bin {}:", bin);
let mut starts = (0..16).map(|i| Some((bin * 16 + i) * 64)).collect::<Vec<Option<usize>>>();
loop {
let min_start = starts.iter().map(|st|
st.map(|st|
if buf[st / 4] == 0 {
!0
} else {
buf[st / 4 + 2]
}).unwrap_or(!0)).min().unwrap();
if min_start == !0 {
break;
}
let mut selected = !0;
for i in 0..16 {
if let Some(st) = starts[i] {
if buf[st/4] != 0 && buf[st/4 + 2] == min_start {
selected = i;
break;
}
}
}
let st = starts[selected].unwrap();
println!("selected {}, start {:x}", selected, st);
for j in 0..buf[st/4] {
println!("{:x}", buf[st/4 + 2 + j as usize])
}
if buf[st/4 + 1] == 0 {
starts[selected] = None;
} else {
starts[selected] = Some(buf[st/4 + 1] as usize);
}
}
}
}
/// Interpret the output of the coarse raster stage, for diagnostic purposes.
#[allow(unused)]
fn trace_ptcl(buf: &[u32]) {
for y in 0..96 {
for x in 0..128 {
let tile_ix = y * 128 + x;
println!("tile {} @({}, {})", tile_ix, x, y);
let mut tile_offset = tile_ix * 1024;
loop {
let tag = buf[tile_offset / 4];
match tag {
0 => break,
3 => {
let backdrop = buf[tile_offset / 4 + 2];
let rgba_color = buf[tile_offset / 4 + 3];
println!(" {:x}: fill {:x} {}", tile_offset, rgba_color, backdrop);
let mut seg_chunk = buf[tile_offset / 4 + 1] as usize;
let n = buf[seg_chunk / 4] as usize;
let segs = buf[seg_chunk / 4 + 2] as usize;
println!(" chunk @{:x}: n={}, segs @{:x}", seg_chunk, n, segs);
for i in 0..n {
let x0 = f32::from_bits(buf[segs / 4 + i * 5]);
let y0 = f32::from_bits(buf[segs / 4 + i * 5 + 1]);
let x1 = f32::from_bits(buf[segs / 4 + i * 5 + 2]);
let y1 = f32::from_bits(buf[segs / 4 + i * 5 + 3]);
let y_edge = f32::from_bits(buf[segs / 4 + i * 5 + 4]);
println!(" ({:.3}, {:.3}) - ({:.3}, {:.3}) | {:.3}", x0, y0, x1, y1, y_edge);
}
loop {
seg_chunk = buf[seg_chunk / 4 + 1] as usize;
if seg_chunk == 0 {
break;
}
}
}
4 => {
let line_width = f32::from_bits(buf[tile_offset / 4 + 2]);
let rgba_color = buf[tile_offset / 4 + 3];
println!(" {:x}: stroke {:x} {}", tile_offset, rgba_color, line_width);
let mut seg_chunk = buf[tile_offset / 4 + 1] as usize;
let n = buf[seg_chunk / 4] as usize;
let segs = buf[seg_chunk / 4 + 2] as usize;
println!(" chunk @{:x}: n={}, segs @{:x}", seg_chunk, n, segs);
for i in 0..n {
let x0 = f32::from_bits(buf[segs / 4 + i * 5]);
let y0 = f32::from_bits(buf[segs / 4 + i * 5 + 1]);
let x1 = f32::from_bits(buf[segs / 4 + i * 5 + 2]);
let y1 = f32::from_bits(buf[segs / 4 + i * 5 + 3]);
let y_edge = f32::from_bits(buf[segs / 4 + i * 5 + 4]);
println!(" ({:.3}, {:.3}) - ({:.3}, {:.3}) | {:.3}", x0, y0, x1, y1, y_edge);
}
loop {
seg_chunk = buf[seg_chunk / 4 + 1] as usize;
if seg_chunk == 0 {
break;
}
}
}
_ => {
println!("{:x}: {}", tile_offset, tag);
}
}
if tag == 0 {
break;
}
if tag == 8 {
tile_offset = buf[tile_offset / 4 + 1] as usize;
} else {
tile_offset += 20;
}
}
}
}
}
fn main() -> Result<(), Error> {
let (instance, _) = VkInstance::new(None)?;
unsafe {
let device = instance.device(None)?;
let fence = device.create_fence(false)?;
let mut cmd_buf = device.create_cmd_buf()?;
let query_pool = device.create_query_pool(5)?;
let mut ctx = PietGpuRenderContext::new();
render_scene(&mut ctx);
let scene = ctx.get_scene_buf();
//dump_scene(&scene);
let renderer = Renderer::new(&device, scene)?;
let image_buf =
device.create_buffer((WIDTH * HEIGHT * 4) as u64, MemFlags::host_coherent())?;
cmd_buf.begin();
renderer.record(&mut cmd_buf, &query_pool);
cmd_buf.copy_image_to_buffer(&renderer.image_dev, &image_buf);
cmd_buf.finish();
device.run_cmd_buf(&cmd_buf, &[], &[], Some(&fence))?;
device.wait_and_reset(&[fence])?;
let ts = device.reap_query_pool(&query_pool).unwrap();
println!("Element kernel time: {:.3}ms", ts[0] * 1e3);
println!("Binning kernel time: {:.3}ms", (ts[1] - ts[0]) * 1e3);
println!("Coarse kernel time: {:.3}ms", (ts[2] - ts[1]) * 1e3);
println!("Render kernel time: {:.3}ms", (ts[3] - ts[2]) * 1e3);
/*
let mut data: Vec<u32> = Default::default();
device.read_buffer(&renderer.ptcl_buf, &mut data).unwrap();
//piet_gpu::dump_k1_data(&data);
trace_ptcl(&data);
*/
let mut img_data: Vec<u8> = Default::default();
// Note: because png can use a `&[u8]` slice, we could avoid an extra copy
// (probably passing a slice into a closure). But for now: keep it simple.
device.read_buffer(&image_buf, &mut img_data).unwrap();
// Write image as PNG file.
let path = Path::new("image.png");
let file = File::create(path).unwrap();
let ref mut w = BufWriter::new(file);
let mut encoder = png::Encoder::new(w, WIDTH as u32, HEIGHT as u32);
encoder.set_color(png::ColorType::RGBA);
encoder.set_depth(png::BitDepth::Eight);
let mut writer = encoder.write_header().unwrap();
writer.write_image_data(&img_data).unwrap();
}
Ok(())
}