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use std::{fmt::Display, mem::transmute};
use crate::error::PngError;
#[repr(u8)]
#[derive(Debug, PartialEq, Eq, PartialOrd, Ord, Clone, Copy, Hash)]
pub enum RowFilter {
None,
Sub,
Up,
Average,
Paeth,
MinSum,
Entropy,
Bigrams,
BigEnt,
Brute,
}
impl TryFrom<u8> for RowFilter {
type Error = ();
fn try_from(value: u8) -> Result<Self, Self::Error> {
if value > Self::LAST {
return Err(());
}
unsafe { transmute(value as i8) }
}
}
impl Display for RowFilter {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
write!(
f,
"{:8}",
match *self {
Self::None => "None",
Self::Sub => "Sub",
Self::Up => "Up",
Self::Average => "Average",
Self::Paeth => "Paeth",
Self::MinSum => "MinSum",
Self::Entropy => "Entropy",
Self::Bigrams => "Bigrams",
Self::BigEnt => "BigEnt",
Self::Brute => "Brute",
}
)
}
}
impl RowFilter {
pub const LAST: u8 = Self::Brute as u8;
pub const STANDARD: [Self; 5] = [Self::None, Self::Sub, Self::Up, Self::Average, Self::Paeth];
pub const SINGLE_LINE: [Self; 2] = [Self::None, Self::Sub];
pub fn filter_line(
self,
bpp: usize,
data: &mut [u8],
prev_line: &[u8],
buf: &mut Vec<u8>,
alpha_bytes: usize,
) {
assert!(data.len() >= bpp);
assert_eq!(data.len(), prev_line.len());
if alpha_bytes != 0 {
self.optimize_alpha(bpp, data, prev_line, bpp - alpha_bytes);
}
buf.clear();
buf.reserve(data.len() + 1);
buf.push(self as u8);
match self {
Self::None => {
buf.extend_from_slice(data);
}
Self::Sub => {
buf.extend_from_slice(&data[0..bpp]);
buf.extend(
data.iter()
.skip(bpp)
.zip(data.iter())
.map(|(cur, last)| cur.wrapping_sub(*last)),
);
}
Self::Up => {
buf.extend(
data.iter()
.zip(prev_line.iter())
.map(|(cur, last)| cur.wrapping_sub(*last)),
);
}
Self::Average => {
for (i, byte) in data.iter().enumerate() {
buf.push(match i.checked_sub(bpp) {
Some(x) => byte.wrapping_sub(
((u16::from(data[x]) + u16::from(prev_line[i])) >> 1) as u8,
),
None => byte.wrapping_sub(prev_line[i] >> 1),
});
}
}
Self::Paeth => {
for (i, byte) in data.iter().enumerate() {
buf.push(match i.checked_sub(bpp) {
Some(x) => {
byte.wrapping_sub(paeth_predictor(data[x], prev_line[i], prev_line[x]))
}
None => byte.wrapping_sub(prev_line[i]),
});
}
}
_ => unreachable!(),
}
}
fn optimize_alpha(self, bpp: usize, data: &mut [u8], prev_line: &[u8], color_bytes: usize) {
if self == Self::None {
return;
}
let mut pixels: Vec<_> = data.chunks_mut(bpp).collect();
let prev_pixels: Vec<_> = prev_line.chunks(bpp).collect();
for i in 0..pixels.len() {
if pixels[i].iter().skip(color_bytes).all(|b| *b == 0) {
let prev = match i {
0 => pixels
.iter()
.position(|px| px.iter().skip(color_bytes).any(|b| *b != 0))
.unwrap_or(i),
_ => i - 1,
};
match self {
Self::Sub => {
for j in 0..color_bytes {
pixels[i][j] = pixels[prev][j];
}
}
Self::Up => {
pixels[i][0..color_bytes].copy_from_slice(&prev_pixels[i][0..color_bytes]);
}
Self::Average => {
for j in 0..color_bytes {
pixels[i][j] = match i {
0 => prev_pixels[i][j] >> 1,
_ => {
((u16::from(pixels[i - 1][j]) + u16::from(prev_pixels[i][j]))
>> 1) as u8
}
};
}
}
Self::Paeth => {
for j in 0..color_bytes {
pixels[i][j] = match i {
0 => pixels[prev][j].min(prev_pixels[i][j]),
_ => paeth_predictor(
pixels[i - 1][j],
prev_pixels[i][j],
prev_pixels[i - 1][j],
),
};
}
}
_ => unreachable!(),
}
}
}
}
pub fn unfilter_line(
self,
bpp: usize,
data: &[u8],
prev_line: &[u8],
buf: &mut Vec<u8>,
) -> Result<(), PngError> {
buf.clear();
buf.reserve(data.len());
assert!(data.len() >= bpp);
assert_eq!(data.len(), prev_line.len());
match self {
Self::None => {
buf.extend_from_slice(data);
}
Self::Sub => {
for (i, &cur) in data.iter().enumerate() {
let prev_byte = i.checked_sub(bpp).and_then(|x| buf.get(x).copied());
buf.push(match prev_byte {
Some(b) => cur.wrapping_add(b),
None => cur,
});
}
}
Self::Up => {
buf.extend(
data.iter()
.zip(prev_line)
.map(|(&cur, &last)| cur.wrapping_add(last)),
);
}
Self::Average => {
for (i, (&cur, &last)) in data.iter().zip(prev_line).enumerate() {
let prev_byte = i.checked_sub(bpp).and_then(|x| buf.get(x).copied());
buf.push(match prev_byte {
Some(b) => cur.wrapping_add(((u16::from(b) + u16::from(last)) >> 1) as u8),
None => cur.wrapping_add(last >> 1),
});
}
}
Self::Paeth => {
for (i, (&cur, &up)) in data.iter().zip(prev_line).enumerate() {
buf.push(
match i
.checked_sub(bpp)
.map(|x| (buf.get(x).copied(), prev_line.get(x).copied()))
{
Some((Some(left), Some(left_up))) => {
cur.wrapping_add(paeth_predictor(left, up, left_up))
}
_ => cur.wrapping_add(up),
},
);
}
}
_ => return Err(PngError::InvalidData),
}
Ok(())
}
}
fn paeth_predictor(a: u8, b: u8, c: u8) -> u8 {
let p = i32::from(a) + i32::from(b) - i32::from(c);
let pa = (p - i32::from(a)).abs();
let pb = (p - i32::from(b)).abs();
let pc = (p - i32::from(c)).abs();
if pa <= pb && pa <= pc {
a
} else if pb <= pc {
b
} else {
c
}
}