qoi/tests/test_gen.rs

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mod common;
use bytemuck::cast_slice;
use std::borrow::Cow;
use std::fmt::Debug;
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use cfg_if::cfg_if;
use rand::{rngs::StdRng, Rng, SeedableRng};
use libqoi::{qoi_decode, qoi_encode};
use qoi_fast::consts::{
QOI_HEADER_SIZE, QOI_MASK_2, QOI_OP_DIFF, QOI_OP_INDEX, QOI_OP_LUMA, QOI_OP_RGB, QOI_OP_RGBA,
QOI_OP_RUN, QOI_PADDING_SIZE,
};
use qoi_fast::{decode_header, decode_to_vec, encode_to_vec};
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use self::common::hash;
struct GenState<const N: usize> {
index: [[u8; N]; 64],
pixels: Vec<u8>,
prev: [u8; N],
len: usize,
}
impl<const N: usize> GenState<N> {
pub fn with_capacity(capacity: usize) -> Self {
Self {
index: [[0; N]; 64],
pixels: Vec::with_capacity(capacity * N),
prev: Self::zero(),
len: 0,
}
}
pub fn write(&mut self, px: [u8; N]) {
self.index[hash(px) as usize] = px;
for i in 0..N {
self.pixels.push(px[i]);
}
self.prev = px;
self.len += 1;
}
pub fn pick_from_index(&self, rng: &mut impl Rng) -> [u8; N] {
self.index[rng.gen_range(0_usize..64)]
}
pub fn zero() -> [u8; N] {
let mut px = [0; N];
if N >= 4 {
px[3] = 0xff;
}
px
}
}
struct ImageGen {
p_new: f64,
p_index: f64,
p_repeat: f64,
p_diff: f64,
p_luma: f64,
}
impl ImageGen {
pub fn new_random(rng: &mut impl Rng) -> Self {
let p = [0; 6].map(|_| rng.gen::<f64>());
let t = p.iter().sum::<f64>();
Self {
p_new: p[0] / t,
p_index: p[1] / t,
p_repeat: p[2] / t,
p_diff: p[3] / t,
p_luma: p[4] / t,
}
}
pub fn generate(&self, rng: &mut impl Rng, channels: usize, min_len: usize) -> Vec<u8> {
match channels {
3 => self.generate_const::<_, 3>(rng, min_len),
4 => self.generate_const::<_, 4>(rng, min_len),
_ => panic!(),
}
}
fn generate_const<R: Rng, const N: usize>(&self, rng: &mut R, min_len: usize) -> Vec<u8> {
let mut s = GenState::<N>::with_capacity(min_len);
let zero = GenState::<N>::zero();
while s.len < min_len {
let mut p = rng.gen_range(0.0..1.0);
if p < self.p_new {
s.write([0; N].map(|_| rng.gen()));
continue;
}
p -= self.p_new;
if p < self.p_index {
let px = s.pick_from_index(rng);
s.write(px);
continue;
}
p -= self.p_index;
if p < self.p_repeat {
let px = s.prev;
let n_repeat = rng.gen_range(1_usize..=70);
for _ in 0..n_repeat {
s.write(px);
}
continue;
}
p -= self.p_repeat;
if p < self.p_diff {
let mut px = s.prev;
let d = [0; 3].map(|_| rng.gen_range(0_u8..4).wrapping_sub(2));
px[0] = px[0].wrapping_add(d[0]);
px[1] = px[1].wrapping_add(d[0]);
px[2] = px[2].wrapping_add(d[0]);
s.write(px);
continue;
}
p -= self.p_diff;
if p < self.p_luma {
let mut px = s.prev;
let vg = rng.gen_range(0_u8..64).wrapping_sub(32);
let vr = rng.gen_range(0_u8..16).wrapping_sub(8).wrapping_add(vg);
let vb = rng.gen_range(0_u8..16).wrapping_sub(8).wrapping_add(vg);
px[0] = px[0].wrapping_add(vr);
px[1] = px[1].wrapping_add(vg);
px[2] = px[2].wrapping_add(vb);
s.write(px);
continue;
}
s.write(zero);
}
s.pixels
}
}
fn format_encoded(encoded: &[u8]) -> String {
let header = decode_header(encoded).unwrap();
let mut data = &encoded[QOI_HEADER_SIZE..encoded.len() - QOI_PADDING_SIZE];
let mut s = format!("{}x{}:{} = [", header.width, header.height, header.channels.as_u8());
while !data.is_empty() {
let b1 = data[0];
data = &data[1..];
match b1 {
QOI_OP_RGB => {
s.push_str(&format!("rgb({},{},{})", data[0], data[1], data[2]));
data = &data[3..];
}
QOI_OP_RGBA => {
s.push_str(&format!("rgba({},{},{},{})", data[0], data[1], data[2], data[3]));
data = &data[4..];
}
_ => match b1 & QOI_MASK_2 {
QOI_OP_INDEX => s.push_str(&format!("index({})", b1 & 0x3f)),
QOI_OP_RUN => s.push_str(&format!("run({})", b1 & 0x3f)),
QOI_OP_DIFF => s.push_str(&format!(
"diff({},{},{})",
(b1 >> 4) & 0x03,
(b1 >> 2) & 0x03,
b1 & 0x03
)),
QOI_OP_LUMA => {
let b2 = data[0];
data = &data[1..];
s.push_str(&format!("luma({},{},{})", (b2 >> 4) & 0x0f, b1 & 0x3f, b2 & 0x0f))
}
_ => {}
},
}
s.push_str(", ");
}
s.pop().unwrap();
s.pop().unwrap();
s.push(']');
s
}
fn check_roundtrip<E, D, VE, VD, EE, ED>(
msg: &str, mut data: &[u8], channels: usize, encode: E, decode: D,
) where
E: Fn(&[u8], u32) -> Result<VE, EE>,
D: Fn(&[u8]) -> Result<VD, ED>,
VE: AsRef<[u8]>,
VD: AsRef<[u8]>,
EE: Debug,
ED: Debug,
{
macro_rules! rt {
($data:expr, $n:expr) => {
decode(encode($data, $n as _).unwrap().as_ref()).unwrap()
};
}
macro_rules! fail {
($msg:expr, $data:expr, $decoded:expr, $encoded:expr, $channels:expr) => {
assert!(
false,
"{} roundtrip failed\n\n image: {:?}\ndecoded: {:?}\nencoded: {}",
$msg,
cast_slice::<_, [u8; $channels]>($data.as_ref()),
cast_slice::<_, [u8; $channels]>($decoded.as_ref()),
format_encoded($encoded.as_ref()),
);
};
}
let mut n_pixels = data.len() / channels;
assert_eq!(n_pixels * channels, data.len());
// if all ok, return
// ... but if roundtrip check fails, try to reduce the example to the smallest we can find
if rt!(data, n_pixels).as_ref() == data {
return;
}
// try removing pixels from the beginning
while n_pixels > 1 {
let slice = &data[..data.len() - channels];
if rt!(slice, n_pixels - 1).as_ref() != slice {
data = slice;
n_pixels -= 1;
} else {
break;
}
}
// try removing pixels from the end
while n_pixels > 1 {
let slice = &data[channels..];
if rt!(slice, n_pixels - 1).as_ref() != slice {
data = slice;
n_pixels -= 1;
} else {
break;
}
}
// try removing pixels from the middle
let mut data = Cow::from(data);
let mut pos = 1;
while n_pixels > 1 && pos < n_pixels - 1 {
let mut vec = data.to_vec();
for _ in 0..channels {
vec.remove(pos * channels);
}
if rt!(vec.as_slice(), n_pixels - 1).as_ref() != vec.as_slice() {
data = Cow::from(vec);
n_pixels -= 1;
} else {
pos += 1;
}
}
let encoded = encode(data.as_ref(), n_pixels as _).unwrap();
let decoded = decode(encoded.as_ref()).unwrap();
assert_ne!(decoded.as_ref(), data.as_ref());
if channels == 3 {
fail!(msg, data, decoded, encoded, 3);
} else {
fail!(msg, data, decoded, encoded, 4);
}
}
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#[test]
fn test_generated() {
let mut rng = StdRng::seed_from_u64(0);
let mut n_pixels = 0;
while n_pixels < 20_000_000 {
let min_len = rng.gen_range(1..=5000);
let channels = rng.gen_range(3..=4);
let gen = ImageGen::new_random(&mut rng);
let img = gen.generate(&mut rng, channels, min_len);
let encode = |data: &[u8], size| encode_to_vec(data, size, 1);
let decode = |data: &[u8]| decode_to_vec(data).map(|r| r.1);
let encode_c = |data: &[u8], size| qoi_encode(data, size, 1, channels as _);
let decode_c = |data: &[u8]| qoi_decode(data, channels as _).map(|r| r.1);
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check_roundtrip("qoi-fast -> qoi-fast", &img, channels as _, encode, decode);
check_roundtrip("qoi-fast -> qoi.h", &img, channels as _, encode, decode_c);
check_roundtrip("qoi.h -> qoi-fast", &img, channels as _, encode_c, decode);
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let size = (img.len() / channels) as u32;
let encoded = encode(&img, size).unwrap();
let encoded_c = encode_c(&img, size).unwrap();
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cfg_if! {
if #[cfg(feature = "reference")] {
let eq = encoded.as_slice() == encoded_c.as_ref();
assert!(eq, "qoi-fast [reference mode] doesn't match qoi.h");
} else {
let eq = encoded.len() == encoded_c.len();
assert!(eq, "qoi-fast [non-reference mode] length doesn't match qoi.h");
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}
}
n_pixels += size;
}
}