use std::ops::{Index, IndexMut};
use num_traits::{NumCast, ToPrimitive, Zero};
use crate::traits::{Pixel, Primitive};
#[derive(Copy, PartialEq, Eq, Debug, Clone, Hash)]
pub enum ColorType {
L8,
La8,
Rgb8,
Rgba8,
L16,
La16,
Rgb16,
Rgba16,
Bgr8,
Bgra8,
#[doc(hidden)]
__NonExhaustive(crate::utils::NonExhaustiveMarker),
}
impl ColorType {
pub fn bytes_per_pixel(self) -> u8 {
match self {
ColorType::L8 => 1,
ColorType::L16 | ColorType::La8 => 2,
ColorType::Rgb8 | ColorType::Bgr8 => 3,
ColorType::Rgba8 | ColorType::Bgra8 | ColorType::La16 => 4,
ColorType::Rgb16 => 6,
ColorType::Rgba16 => 8,
ColorType::__NonExhaustive(marker) => match marker._private {},
}
}
pub fn has_alpha(self) -> bool {
use ColorType::*;
match self {
L8 | L16 | Rgb8 | Bgr8 | Rgb16 => false,
La8 | Rgba8 | Bgra8 | La16 | Rgba16 => true,
__NonExhaustive(marker) => match marker._private {},
}
}
pub fn has_color(self) -> bool {
use ColorType::*;
match self {
L8 | L16 | La8 | La16 => false,
Rgb8 | Bgr8 | Rgb16 | Rgba8 | Bgra8 | Rgba16 => true,
__NonExhaustive(marker) => match marker._private {},
}
}
pub fn bits_per_pixel(self) -> u16 {
<u16 as From<u8>>::from(self.bytes_per_pixel()) * 8
}
pub fn channel_count(self) -> u8 {
let e: ExtendedColorType = self.into();
e.channel_count()
}
}
#[derive(Copy, PartialEq, Eq, Debug, Clone, Hash)]
pub enum ExtendedColorType {
A8,
L1,
La1,
Rgb1,
Rgba1,
L2,
La2,
Rgb2,
Rgba2,
L4,
La4,
Rgb4,
Rgba4,
L8,
La8,
Rgb8,
Rgba8,
L16,
La16,
Rgb16,
Rgba16,
Bgr8,
Bgra8,
Unknown(u8),
#[doc(hidden)]
__NonExhaustive(crate::utils::NonExhaustiveMarker),
}
impl ExtendedColorType {
pub fn channel_count(self) -> u8 {
match self {
ExtendedColorType::A8 |
ExtendedColorType::L1 |
ExtendedColorType::L2 |
ExtendedColorType::L4 |
ExtendedColorType::L8 |
ExtendedColorType::L16 |
ExtendedColorType::Unknown(_) => 1,
ExtendedColorType::La1 |
ExtendedColorType::La2 |
ExtendedColorType::La4 |
ExtendedColorType::La8 |
ExtendedColorType::La16 => 2,
ExtendedColorType::Rgb1 |
ExtendedColorType::Rgb2 |
ExtendedColorType::Rgb4 |
ExtendedColorType::Rgb8 |
ExtendedColorType::Rgb16 |
ExtendedColorType::Bgr8 => 3,
ExtendedColorType::Rgba1 |
ExtendedColorType::Rgba2 |
ExtendedColorType::Rgba4 |
ExtendedColorType::Rgba8 |
ExtendedColorType::Rgba16 |
ExtendedColorType::Bgra8 => 4,
ExtendedColorType::__NonExhaustive(marker) => match marker._private {},
}
}
}
impl From<ColorType> for ExtendedColorType {
fn from(c: ColorType) -> Self {
match c {
ColorType::L8 => ExtendedColorType::L8,
ColorType::La8 => ExtendedColorType::La8,
ColorType::Rgb8 => ExtendedColorType::Rgb8,
ColorType::Rgba8 => ExtendedColorType::Rgba8,
ColorType::L16 => ExtendedColorType::L16,
ColorType::La16 => ExtendedColorType::La16,
ColorType::Rgb16 => ExtendedColorType::Rgb16,
ColorType::Rgba16 => ExtendedColorType::Rgba16,
ColorType::Bgr8 => ExtendedColorType::Bgr8,
ColorType::Bgra8 => ExtendedColorType::Bgra8,
ColorType::__NonExhaustive(marker) => match marker._private {},
}
}
}
macro_rules! define_colors {
{$(
$ident:ident,
$channels: expr,
$alphas: expr,
$interpretation: expr,
$color_type_u8: expr,
$color_type_u16: expr,
#[$doc:meta];
)*} => {
$(
#[$doc]
#[derive(PartialEq, Eq, Clone, Debug, Copy, Hash)]
#[repr(C)]
#[allow(missing_docs)]
pub struct $ident<T: Primitive> (pub [T; $channels]);
impl<T: Primitive + 'static> Pixel for $ident<T> {
type Subpixel = T;
const CHANNEL_COUNT: u8 = $channels;
const COLOR_MODEL: &'static str = $interpretation;
const COLOR_TYPE: ColorType =
[$color_type_u8, $color_type_u16][(std::mem::size_of::<T>() > 1) as usize];
#[inline(always)]
fn channels(&self) -> &[T] {
&self.0
}
#[inline(always)]
fn channels_mut(&mut self) -> &mut [T] {
&mut self.0
}
fn channels4(&self) -> (T, T, T, T) {
const CHANNELS: usize = $channels;
let mut channels = [T::max_value(); 4];
channels[0..CHANNELS].copy_from_slice(&self.0);
(channels[0], channels[1], channels[2], channels[3])
}
fn from_channels(a: T, b: T, c: T, d: T,) -> $ident<T> {
const CHANNELS: usize = $channels;
*<$ident<T> as Pixel>::from_slice(&[a, b, c, d][..CHANNELS])
}
fn from_slice(slice: &[T]) -> &$ident<T> {
assert_eq!(slice.len(), $channels);
unsafe { &*(slice.as_ptr() as *const $ident<T>) }
}
fn from_slice_mut(slice: &mut [T]) -> &mut $ident<T> {
assert_eq!(slice.len(), $channels);
unsafe { &mut *(slice.as_mut_ptr() as *mut $ident<T>) }
}
fn to_rgb(&self) -> Rgb<T> {
let mut pix = Rgb([Zero::zero(), Zero::zero(), Zero::zero()]);
pix.from_color(self);
pix
}
fn to_bgr(&self) -> Bgr<T> {
let mut pix = Bgr([Zero::zero(), Zero::zero(), Zero::zero()]);
pix.from_color(self);
pix
}
fn to_rgba(&self) -> Rgba<T> {
let mut pix = Rgba([Zero::zero(), Zero::zero(), Zero::zero(), Zero::zero()]);
pix.from_color(self);
pix
}
fn to_bgra(&self) -> Bgra<T> {
let mut pix = Bgra([Zero::zero(), Zero::zero(), Zero::zero(), Zero::zero()]);
pix.from_color(self);
pix
}
fn to_luma(&self) -> Luma<T> {
let mut pix = Luma([Zero::zero()]);
pix.from_color(self);
pix
}
fn to_luma_alpha(&self) -> LumaA<T> {
let mut pix = LumaA([Zero::zero(), Zero::zero()]);
pix.from_color(self);
pix
}
fn map<F>(& self, f: F) -> $ident<T> where F: FnMut(T) -> T {
let mut this = (*self).clone();
this.apply(f);
this
}
fn apply<F>(&mut self, mut f: F) where F: FnMut(T) -> T {
for v in &mut self.0 {
*v = f(*v)
}
}
fn map_with_alpha<F, G>(&self, f: F, g: G) -> $ident<T> where F: FnMut(T) -> T, G: FnMut(T) -> T {
let mut this = (*self).clone();
this.apply_with_alpha(f, g);
this
}
fn apply_with_alpha<F, G>(&mut self, mut f: F, mut g: G) where F: FnMut(T) -> T, G: FnMut(T) -> T {
const ALPHA: usize = $channels - $alphas;
for v in self.0[..ALPHA].iter_mut() {
*v = f(*v)
}
if let Some(v) = self.0.get_mut(ALPHA) {
*v = g(*v)
}
}
fn map2<F>(&self, other: &Self, f: F) -> $ident<T> where F: FnMut(T, T) -> T {
let mut this = (*self).clone();
this.apply2(other, f);
this
}
fn apply2<F>(&mut self, other: &$ident<T>, mut f: F) where F: FnMut(T, T) -> T {
for (a, &b) in self.0.iter_mut().zip(other.0.iter()) {
*a = f(*a, b)
}
}
fn invert(&mut self) {
Invert::invert(self)
}
fn blend(&mut self, other: &$ident<T>) {
Blend::blend(self, other)
}
}
impl<T: Primitive> Index<usize> for $ident<T> {
type Output = T;
#[inline(always)]
fn index(&self, _index: usize) -> &T {
&self.0[_index]
}
}
impl<T: Primitive> IndexMut<usize> for $ident<T> {
#[inline(always)]
fn index_mut(&mut self, _index: usize) -> &mut T {
&mut self.0[_index]
}
}
impl<T: Primitive + 'static> From<[T; $channels]> for $ident<T> {
fn from(c: [T; $channels]) -> Self {
Self(c)
}
}
)*
}
}
define_colors! {
Rgb, 3, 0, "RGB", ColorType::Rgb8, ColorType::Rgb16, #[doc = "RGB colors"];
Bgr, 3, 0, "BGR", ColorType::Bgr8, ColorType::Bgr8, #[doc = "BGR colors"];
Luma, 1, 0, "Y", ColorType::L8, ColorType::L16, #[doc = "Grayscale colors"];
Rgba, 4, 1, "RGBA", ColorType::Rgba8, ColorType::Rgba16, #[doc = "RGB colors + alpha channel"];
Bgra, 4, 1, "BGRA", ColorType::Bgra8, ColorType::Bgra8, #[doc = "BGR colors + alpha channel"];
LumaA, 2, 1, "YA", ColorType::La8, ColorType::La16, #[doc = "Grayscale colors + alpha channel"];
}
pub trait FromColor<Other> {
fn from_color(&mut self, _: &Other);
}
impl<A: Copy> FromColor<A> for A {
fn from_color(&mut self, other: &A) {
*self = *other;
}
}
pub(crate) trait IntoColor<Other> {
fn into_color(&self) -> Other;
}
impl<O, S> IntoColor<O> for S
where
O: Pixel + FromColor<S> {
fn into_color(&self) -> O {
let mut pix = O::from_channels(Zero::zero(), Zero::zero(), Zero::zero(), Zero::zero());
pix.from_color(self);
pix
}
}
const SRGB_LUMA: [f32; 3] = [0.2126, 0.7152, 0.0722];
#[inline]
fn rgb_to_luma<T: Primitive>(rgb: &[T]) -> T {
let l = SRGB_LUMA[0] * rgb[0].to_f32().unwrap()
+ SRGB_LUMA[1] * rgb[1].to_f32().unwrap()
+ SRGB_LUMA[2] * rgb[2].to_f32().unwrap();
NumCast::from(l).unwrap()
}
#[inline]
fn bgr_to_luma<T: Primitive>(bgr: &[T]) -> T {
let l = SRGB_LUMA[0] * bgr[2].to_f32().unwrap()
+ SRGB_LUMA[1] * bgr[1].to_f32().unwrap()
+ SRGB_LUMA[2] * bgr[0].to_f32().unwrap();
NumCast::from(l).unwrap()
}
#[inline]
fn downcast_channel(c16: u16) -> u8 {
NumCast::from(c16.to_u64().unwrap() >> 8).unwrap()
}
#[inline]
fn upcast_channel(c8: u8) -> u16 {
NumCast::from(c8.to_u64().unwrap() << 8).unwrap()
}
impl<T: Primitive + 'static> FromColor<Rgba<T>> for Luma<T> {
fn from_color(&mut self, other: &Rgba<T>) {
let gray = self.channels_mut();
let rgba = other.channels();
gray[0] = rgb_to_luma(rgba);
}
}
impl<T: Primitive + 'static> FromColor<Bgra<T>> for Luma<T> {
fn from_color(&mut self, other: &Bgra<T>) {
let gray = self.channels_mut();
let bgra = other.channels();
gray[0] = bgr_to_luma(bgra);
}
}
impl<T: Primitive + 'static> FromColor<Rgb<T>> for Luma<T> {
fn from_color(&mut self, other: &Rgb<T>) {
let gray = self.channels_mut();
let rgb = other.channels();
gray[0] = rgb_to_luma(rgb);
}
}
impl<T: Primitive + 'static> FromColor<Bgr<T>> for Luma<T> {
fn from_color(&mut self, other: &Bgr<T>) {
let gray = self.channels_mut();
let bgr = other.channels();
gray[0] = bgr_to_luma(bgr);
}
}
impl<T: Primitive + 'static> FromColor<LumaA<T>> for Luma<T> {
fn from_color(&mut self, other: &LumaA<T>) {
self.channels_mut()[0] = other.channels()[0]
}
}
impl FromColor<Rgba<u16>> for Luma<u8> {
fn from_color(&mut self, other: &Rgba<u16>) {
let gray = self.channels_mut();
let rgb = other.channels();
let l = rgb_to_luma(rgb);
gray[0] = downcast_channel(l);
}
}
impl FromColor<Rgb<u16>> for Luma<u8> {
fn from_color(&mut self, other: &Rgb<u16>) {
let gray = self.channels_mut();
let rgb = other.channels();
let l = rgb_to_luma(rgb);
gray[0] = downcast_channel(l);
}
}
impl FromColor<Luma<u16>> for Luma<u8> {
fn from_color(&mut self, other: &Luma<u16>) {
let l = other.channels()[0];
self.channels_mut()[0] = downcast_channel(l);
}
}
impl FromColor<Luma<u8>> for Luma<u16> {
fn from_color(&mut self, other: &Luma<u8>) {
let l = other.channels()[0];
self.channels_mut()[0] = upcast_channel(l);
}
}
impl FromColor<LumaA<u16>> for Luma<u8> {
fn from_color(&mut self, other: &LumaA<u16>) {
let l = other.channels()[0];
self.channels_mut()[0] = downcast_channel(l);
}
}
impl FromColor<LumaA<u8>> for Luma<u16> {
fn from_color(&mut self, other: &LumaA<u8>) {
let la8 = other.channels();
let gray = self.channels_mut();
gray[0] = upcast_channel(la8[0]);
}
}
impl FromColor<Rgb<u8>> for Luma<u16> {
fn from_color(&mut self, other: &Rgb<u8>) {
let rgb = other.channels();
let gray = self.channels_mut();
gray[0] = upcast_channel(rgb_to_luma(rgb));
}
}
impl FromColor<Rgba<u8>> for Luma<u16> {
fn from_color(&mut self, other: &Rgba<u8>) {
let rgba = other.channels();
let gray = self.channels_mut();
gray[0] = upcast_channel(rgb_to_luma(rgba));
}
}
impl FromColor<Bgr<u8>> for Luma<u16> {
fn from_color(&mut self, other: &Bgr<u8>) {
let bgr = other.channels();
let gray = self.channels_mut();
gray[0] = upcast_channel(bgr_to_luma(bgr));
}
}
impl FromColor<Bgra<u8>> for Luma<u16> {
fn from_color(&mut self, other: &Bgra<u8>) {
let bgra = other.channels();
let gray = self.channels_mut();
gray[0] = upcast_channel(bgr_to_luma(bgra));
}
}
impl<T: Primitive + 'static> FromColor<Rgba<T>> for LumaA<T> {
fn from_color(&mut self, other: &Rgba<T>) {
let gray_a = self.channels_mut();
let rgba = other.channels();
gray_a[0] = rgb_to_luma(rgba);
gray_a[1] = rgba[3];
}
}
impl<T: Primitive + 'static> FromColor<Bgra<T>> for LumaA<T> {
fn from_color(&mut self, other: &Bgra<T>) {
let gray_a = self.channels_mut();
let bgra = other.channels();
gray_a[0] = bgr_to_luma(bgra);
gray_a[1] = bgra[3];
}
}
impl<T: Primitive + 'static> FromColor<Rgb<T>> for LumaA<T> {
fn from_color(&mut self, other: &Rgb<T>) {
let gray_a = self.channels_mut();
let rgb = other.channels();
gray_a[0] = rgb_to_luma(rgb);
gray_a[1] = T::max_value();
}
}
impl<T: Primitive + 'static> FromColor<Bgr<T>> for LumaA<T> {
fn from_color(&mut self, other: &Bgr<T>) {
let gray_a = self.channels_mut();
let bgr = other.channels();
gray_a[0] = bgr_to_luma(bgr);
gray_a[1] = T::max_value();
}
}
impl<T: Primitive + 'static> FromColor<Luma<T>> for LumaA<T> {
fn from_color(&mut self, other: &Luma<T>) {
let gray_a = self.channels_mut();
gray_a[0] = other.channels()[0];
gray_a[1] = T::max_value();
}
}
impl FromColor<LumaA<u16>> for LumaA<u8> {
fn from_color(&mut self, other: &LumaA<u16>) {
let la8 = self.channels_mut();
let gray = other.channels()[0];
let alpha = other.channels()[1];
la8[0] = downcast_channel(gray);
la8[1] = downcast_channel(alpha);
}
}
impl FromColor<LumaA<u8>> for LumaA<u16> {
fn from_color(&mut self, other: &LumaA<u8>) {
let la8 = self.channels_mut();
let gray = other.channels()[0];
let alpha = other.channels()[1];
la8[0] = upcast_channel(gray);
la8[1] = upcast_channel(alpha);
}
}
impl FromColor<Luma<u8>> for LumaA<u16> {
fn from_color(&mut self, other: &Luma<u8>) {
let l8 = other.channels()[0];
let gray_a = self.channels_mut();
gray_a[0] = upcast_channel(l8);
gray_a[1] = u16::max_value();
}
}
impl FromColor<Rgb<u8>> for LumaA<u16> {
fn from_color(&mut self, other: &Rgb<u8>) {
let rgb = other.channels();
let gray_a = self.channels_mut();
gray_a[0] = upcast_channel(rgb_to_luma(rgb));
gray_a[1] = u16::max_value();
}
}
impl FromColor<Rgba<u8>> for LumaA<u16> {
fn from_color(&mut self, other: &Rgba<u8>) {
let rgba = other.channels();
let gray_a = self.channels_mut();
gray_a[0] = upcast_channel(rgb_to_luma(rgba));
gray_a[1] = upcast_channel(rgba[3]);
}
}
impl FromColor<Bgr<u8>> for LumaA<u16> {
fn from_color(&mut self, other: &Bgr<u8>) {
let bgr = other.channels();
let gray_a = self.channels_mut();
gray_a[0] = upcast_channel(bgr_to_luma(bgr));
gray_a[1] = u16::max_value();
}
}
impl FromColor<Bgra<u8>> for LumaA<u16> {
fn from_color(&mut self, other: &Bgra<u8>) {
let bgra = other.channels();
let gray_a = self.channels_mut();
gray_a[0] = upcast_channel(bgr_to_luma(bgra));
gray_a[1] = upcast_channel(bgra[3]);
}
}
impl<T: Primitive + 'static> FromColor<Rgb<T>> for Rgba<T> {
fn from_color(&mut self, other: &Rgb<T>) {
let rgba = self.channels_mut();
let rgb = other.channels();
rgba[0] = rgb[0];
rgba[1] = rgb[1];
rgba[2] = rgb[2];
rgba[3] = T::max_value();
}
}
impl<T: Primitive + 'static> FromColor<Bgr<T>> for Rgba<T> {
fn from_color(&mut self, other: &Bgr<T>) {
let rgba = self.channels_mut();
let bgr = other.channels();
rgba[0] = bgr[2];
rgba[1] = bgr[1];
rgba[2] = bgr[0];
rgba[3] = T::max_value();
}
}
impl<T: Primitive + 'static> FromColor<Bgra<T>> for Rgba<T> {
fn from_color(&mut self, other: &Bgra<T>) {
let rgba = self.channels_mut();
let bgra = other.channels();
rgba[0] = bgra[2];
rgba[1] = bgra[1];
rgba[2] = bgra[0];
rgba[3] = bgra[3];
}
}
impl<T: Primitive + 'static> FromColor<LumaA<T>> for Rgba<T> {
fn from_color(&mut self, other: &LumaA<T>) {
let rgba = self.channels_mut();
let gray = other.channels();
rgba[0] = gray[0];
rgba[1] = gray[0];
rgba[2] = gray[0];
rgba[3] = gray[1];
}
}
impl<T: Primitive + 'static> FromColor<Luma<T>> for Rgba<T> {
fn from_color(&mut self, gray: &Luma<T>) {
let rgba = self.channels_mut();
let gray = gray.channels()[0];
rgba[0] = gray;
rgba[1] = gray;
rgba[2] = gray;
rgba[3] = T::max_value();
}
}
impl FromColor<Rgba<u16>> for Rgba<u8> {
fn from_color(&mut self, other: &Rgba<u16>) {
let rgba = self.channels_mut();
let rgba16 = other.channels();
rgba[0] = downcast_channel(rgba16[0]);
rgba[1] = downcast_channel(rgba16[1]);
rgba[2] = downcast_channel(rgba16[2]);
rgba[3] = downcast_channel(rgba16[3]);
}
}
impl FromColor<Rgba<u8>> for Rgba<u16> {
fn from_color(&mut self, other: &Rgba<u8>) {
let rgba = self.channels_mut();
let rgba8 = other.channels();
rgba[0] = upcast_channel(rgba8[0]);
rgba[1] = upcast_channel(rgba8[1]);
rgba[2] = upcast_channel(rgba8[2]);
rgba[3] = upcast_channel(rgba8[3]);
}
}
impl FromColor<LumaA<u8>> for Rgba<u16> {
fn from_color(&mut self, other: &LumaA<u8>) {
let la8 = other.channels();
let gray = upcast_channel(la8[0]);
let alpha = upcast_channel(la8[1]);
let rgba = self.channels_mut();
rgba[0] = gray;
rgba[1] = gray;
rgba[2] = gray;
rgba[3] = alpha;
}
}
impl FromColor<Rgb<u8>> for Rgba<u16> {
fn from_color(&mut self, other: &Rgb<u8>) {
let rgb = other.channels();
let rgba = self.channels_mut();
rgba[0] = upcast_channel(rgb[0]);
rgba[1] = upcast_channel(rgb[1]);
rgba[2] = upcast_channel(rgb[2]);
rgba[3] = u16::max_value();
}
}
impl FromColor<Luma<u8>> for Rgba<u16> {
fn from_color(&mut self, other: &Luma<u8>) {
let l8 = other.channels();
let rgba = self.channels_mut();
let gray = upcast_channel(l8[0]);
rgba[0] = gray;
rgba[1] = gray;
rgba[2] = gray;
rgba[3] = u16::max_value();
}
}
impl FromColor<Bgr<u8>> for Rgba<u16> {
fn from_color(&mut self, other: &Bgr<u8>) {
let bgr = other.channels();
let rgba = self.channels_mut();
rgba[0] = upcast_channel(bgr[2]);
rgba[1] = upcast_channel(bgr[1]);
rgba[2] = upcast_channel(bgr[0]);
rgba[3] = u16::max_value();
}
}
impl FromColor<Bgra<u8>> for Rgba<u16> {
fn from_color(&mut self, other: &Bgra<u8>) {
let bgra = other.channels();
let rgba = self.channels_mut();
rgba[0] = upcast_channel(bgra[2]);
rgba[1] = upcast_channel(bgra[1]);
rgba[2] = upcast_channel(bgra[0]);
rgba[3] = upcast_channel(bgra[3]);
}
}
impl<T: Primitive + 'static> FromColor<Rgb<T>> for Bgra<T> {
fn from_color(&mut self, other: &Rgb<T>) {
let bgra = self.channels_mut();
let rgb = other.channels();
bgra[0] = rgb[2];
bgra[1] = rgb[1];
bgra[2] = rgb[0];
bgra[3] = T::max_value();
}
}
impl<T: Primitive + 'static> FromColor<Bgr<T>> for Bgra<T> {
fn from_color(&mut self, other: &Bgr<T>) {
let bgra = self.channels_mut();
let bgr = other.channels();
bgra[0] = bgr[0];
bgra[1] = bgr[1];
bgra[2] = bgr[2];
bgra[3] = T::max_value();
}
}
impl<T: Primitive + 'static> FromColor<Rgba<T>> for Bgra<T> {
fn from_color(&mut self, other: &Rgba<T>) {
let bgra = self.channels_mut();
let rgba = other.channels();
bgra[2] = rgba[0];
bgra[1] = rgba[1];
bgra[0] = rgba[2];
bgra[3] = rgba[3];
}
}
impl<T: Primitive + 'static> FromColor<LumaA<T>> for Bgra<T> {
fn from_color(&mut self, other: &LumaA<T>) {
let bgra = self.channels_mut();
let gray = other.channels();
bgra[0] = gray[0];
bgra[1] = gray[0];
bgra[2] = gray[0];
bgra[3] = gray[1];
}
}
impl<T: Primitive + 'static> FromColor<Luma<T>> for Bgra<T> {
fn from_color(&mut self, gray: &Luma<T>) {
let bgra = self.channels_mut();
let gray = gray.channels()[0];
bgra[0] = gray;
bgra[1] = gray;
bgra[2] = gray;
bgra[3] = T::max_value();
}
}
impl<T: Primitive + 'static> FromColor<Rgba<T>> for Rgb<T> {
fn from_color(&mut self, other: &Rgba<T>) {
let rgb = self.channels_mut();
let rgba = other.channels();
rgb[0] = rgba[0];
rgb[1] = rgba[1];
rgb[2] = rgba[2];
}
}
impl<T: Primitive + 'static> FromColor<Bgra<T>> for Rgb<T> {
fn from_color(&mut self, other: &Bgra<T>) {
let rgb = self.channels_mut();
let bgra = other.channels();
rgb[0] = bgra[2];
rgb[1] = bgra[1];
rgb[2] = bgra[0];
}
}
impl<T: Primitive + 'static> FromColor<Bgr<T>> for Rgb<T> {
fn from_color(&mut self, other: &Bgr<T>) {
let rgb = self.channels_mut();
let bgr = other.channels();
rgb[0] = bgr[2];
rgb[1] = bgr[1];
rgb[2] = bgr[0];
}
}
impl<T: Primitive + 'static> FromColor<LumaA<T>> for Rgb<T> {
fn from_color(&mut self, other: &LumaA<T>) {
let rgb = self.channels_mut();
let gray = other.channels()[0];
rgb[0] = gray;
rgb[1] = gray;
rgb[2] = gray;
}
}
impl<T: Primitive + 'static> FromColor<Luma<T>> for Rgb<T> {
fn from_color(&mut self, gray: &Luma<T>) {
let rgb = self.channels_mut();
let gray = gray.channels()[0];
rgb[0] = gray;
rgb[1] = gray;
rgb[2] = gray;
}
}
impl FromColor<Rgb<u16>> for Rgb<u8> {
fn from_color(&mut self, other: &Rgb<u16>) {
for (c8, &c16) in self.channels_mut().iter_mut().zip(other.channels()) {
*c8 = downcast_channel(c16);
}
}
}
impl FromColor<Rgb<u8>> for Rgb<u16> {
fn from_color(&mut self, other: &Rgb<u8>) {
for (c8, &c16) in self.channels_mut().iter_mut().zip(other.channels()) {
*c8 = upcast_channel(c16);
}
}
}
impl FromColor<LumaA<u8>> for Rgb<u16> {
fn from_color(&mut self, other: &LumaA<u8>) {
let la8 = other.channels();
let gray = upcast_channel(la8[0]);
let rgb = self.channels_mut();
rgb[0] = gray;
rgb[1] = gray;
rgb[2] = gray;
}
}
impl FromColor<Rgba<u8>> for Rgb<u16> {
fn from_color(&mut self, other: &Rgba<u8>) {
let rgba = other.channels();
let rgb = self.channels_mut();
rgb[0] = upcast_channel(rgba[0]);
rgb[1] = upcast_channel(rgba[1]);
rgb[2] = upcast_channel(rgba[2]);
}
}
impl FromColor<Luma<u8>> for Rgb<u16> {
fn from_color(&mut self, other: &Luma<u8>) {
let l8 = other.channels();
let rgb = self.channels_mut();
let gray = upcast_channel(l8[0]);
rgb[0] = gray;
rgb[1] = gray;
rgb[2] = gray;
}
}
impl FromColor<Bgr<u8>> for Rgb<u16> {
fn from_color(&mut self, other: &Bgr<u8>) {
let bgr = other.channels();
let rgb = self.channels_mut();
rgb[0] = upcast_channel(bgr[2]);
rgb[1] = upcast_channel(bgr[1]);
rgb[2] = upcast_channel(bgr[0]);
}
}
impl FromColor<Bgra<u8>> for Rgb<u16> {
fn from_color(&mut self, other: &Bgra<u8>) {
let bgra = other.channels();
let rgb = self.channels_mut();
rgb[0] = upcast_channel(bgra[2]);
rgb[1] = upcast_channel(bgra[1]);
rgb[2] = upcast_channel(bgra[0]);
}
}
impl<T: Primitive + 'static> FromColor<Rgba<T>> for Bgr<T> {
fn from_color(&mut self, other: &Rgba<T>) {
let bgr = self.channels_mut();
let rgba = other.channels();
bgr[0] = rgba[2];
bgr[1] = rgba[1];
bgr[2] = rgba[0];
}
}
impl<T: Primitive + 'static> FromColor<Rgb<T>> for Bgr<T> {
fn from_color(&mut self, other: &Rgb<T>) {
let bgr = self.channels_mut();
let rgb = other.channels();
bgr[0] = rgb[2];
bgr[1] = rgb[1];
bgr[2] = rgb[0];
}
}
impl<T: Primitive + 'static> FromColor<Bgra<T>> for Bgr<T> {
fn from_color(&mut self, other: &Bgra<T>) {
let bgr = self.channels_mut();
let bgra = other.channels();
bgr[0] = bgra[0];
bgr[1] = bgra[1];
bgr[2] = bgra[2];
}
}
impl<T: Primitive + 'static> FromColor<LumaA<T>> for Bgr<T> {
fn from_color(&mut self, other: &LumaA<T>) {
let bgr = self.channels_mut();
let gray = other.channels()[0];
bgr[0] = gray;
bgr[1] = gray;
bgr[2] = gray;
}
}
impl<T: Primitive + 'static> FromColor<Luma<T>> for Bgr<T> {
fn from_color(&mut self, gray: &Luma<T>) {
let bgr = self.channels_mut();
let gray = gray.channels()[0];
bgr[0] = gray;
bgr[1] = gray;
bgr[2] = gray;
}
}
macro_rules! downcast_bit_depth_early {
($src:ident, $intermediate:ident, $dst:ident) => {
impl FromColor<$src<u16>> for $dst<u8> {
fn from_color(&mut self, other: &$src<u16>) {
let mut intermediate: $intermediate<u8> = $intermediate([Zero::zero(); <$intermediate<u8> as Pixel>::CHANNEL_COUNT as usize]);
intermediate.from_color(other);
self.from_color(&intermediate);
}
}
};
}
downcast_bit_depth_early!(Luma, Luma, LumaA);
downcast_bit_depth_early!(Rgb, Rgb, LumaA);
downcast_bit_depth_early!(Rgba, Rgba, LumaA);
downcast_bit_depth_early!(Luma, Luma, Rgb);
downcast_bit_depth_early!(LumaA, LumaA, Rgb);
downcast_bit_depth_early!(Rgba, Rgba, Rgb);
downcast_bit_depth_early!(Luma, Luma, Rgba);
downcast_bit_depth_early!(LumaA, LumaA, Rgba);
downcast_bit_depth_early!(Rgb, Rgb, Rgba);
downcast_bit_depth_early!(Luma, Luma, Bgr);
downcast_bit_depth_early!(LumaA, LumaA, Bgr);
downcast_bit_depth_early!(Rgb, Rgb, Bgr);
downcast_bit_depth_early!(Rgba, Rgba, Bgr);
downcast_bit_depth_early!(Luma, Luma, Bgra);
downcast_bit_depth_early!(LumaA, LumaA, Bgra);
downcast_bit_depth_early!(Rgb, Rgb, Bgra);
downcast_bit_depth_early!(Rgba, Rgba, Bgra);
pub(crate) trait Blend {
fn blend(&mut self, other: &Self);
}
impl<T: Primitive> Blend for LumaA<T> {
fn blend(&mut self, other: &LumaA<T>) {
let max_t = T::max_value();
let max_t = max_t.to_f32().unwrap();
let (bg_luma, bg_a) = (self.0[0], self.0[1]);
let (fg_luma, fg_a) = (other.0[0], other.0[1]);
let (bg_luma, bg_a) = (
bg_luma.to_f32().unwrap() / max_t,
bg_a.to_f32().unwrap() / max_t,
);
let (fg_luma, fg_a) = (
fg_luma.to_f32().unwrap() / max_t,
fg_a.to_f32().unwrap() / max_t,
);
let alpha_final = bg_a + fg_a - bg_a * fg_a;
if alpha_final == 0.0 {
return;
};
let bg_luma_a = bg_luma * bg_a;
let fg_luma_a = fg_luma * fg_a;
let out_luma_a = fg_luma_a + bg_luma_a * (1.0 - fg_a);
let out_luma = out_luma_a / alpha_final;
*self = LumaA([
NumCast::from(max_t * out_luma).unwrap(),
NumCast::from(max_t * alpha_final).unwrap(),
])
}
}
impl<T: Primitive> Blend for Luma<T> {
fn blend(&mut self, other: &Luma<T>) {
*self = *other
}
}
impl<T: Primitive> Blend for Rgba<T> {
fn blend(&mut self, other: &Rgba<T>) {
let max_t = T::max_value();
let max_t = max_t.to_f32().unwrap();
let (bg_r, bg_g, bg_b, bg_a) = (self.0[0], self.0[1], self.0[2], self.0[3]);
let (fg_r, fg_g, fg_b, fg_a) = (other.0[0], other.0[1], other.0[2], other.0[3]);
let (bg_r, bg_g, bg_b, bg_a) = (
bg_r.to_f32().unwrap() / max_t,
bg_g.to_f32().unwrap() / max_t,
bg_b.to_f32().unwrap() / max_t,
bg_a.to_f32().unwrap() / max_t,
);
let (fg_r, fg_g, fg_b, fg_a) = (
fg_r.to_f32().unwrap() / max_t,
fg_g.to_f32().unwrap() / max_t,
fg_b.to_f32().unwrap() / max_t,
fg_a.to_f32().unwrap() / max_t,
);
let alpha_final = bg_a + fg_a - bg_a * fg_a;
if alpha_final == 0.0 {
return;
};
let (bg_r_a, bg_g_a, bg_b_a) = (bg_r * bg_a, bg_g * bg_a, bg_b * bg_a);
let (fg_r_a, fg_g_a, fg_b_a) = (fg_r * fg_a, fg_g * fg_a, fg_b * fg_a);
let (out_r_a, out_g_a, out_b_a) = (
fg_r_a + bg_r_a * (1.0 - fg_a),
fg_g_a + bg_g_a * (1.0 - fg_a),
fg_b_a + bg_b_a * (1.0 - fg_a),
);
let (out_r, out_g, out_b) = (
out_r_a / alpha_final,
out_g_a / alpha_final,
out_b_a / alpha_final,
);
*self = Rgba([
NumCast::from(max_t * out_r).unwrap(),
NumCast::from(max_t * out_g).unwrap(),
NumCast::from(max_t * out_b).unwrap(),
NumCast::from(max_t * alpha_final).unwrap(),
])
}
}
impl<T: Primitive> Blend for Bgra<T> {
fn blend(&mut self, other: &Bgra<T>) {
let max_t = T::max_value();
let max_t = max_t.to_f32().unwrap();
let (bg_r, bg_g, bg_b, bg_a) = (self.0[2], self.0[1], self.0[0], self.0[3]);
let (fg_r, fg_g, fg_b, fg_a) = (other.0[2], other.0[1], other.0[0], other.0[3]);
let (bg_r, bg_g, bg_b, bg_a) = (
bg_r.to_f32().unwrap() / max_t,
bg_g.to_f32().unwrap() / max_t,
bg_b.to_f32().unwrap() / max_t,
bg_a.to_f32().unwrap() / max_t,
);
let (fg_r, fg_g, fg_b, fg_a) = (
fg_r.to_f32().unwrap() / max_t,
fg_g.to_f32().unwrap() / max_t,
fg_b.to_f32().unwrap() / max_t,
fg_a.to_f32().unwrap() / max_t,
);
let alpha_final = bg_a + fg_a - bg_a * fg_a;
if alpha_final == 0.0 {
return;
};
let (bg_r_a, bg_g_a, bg_b_a) = (bg_r * bg_a, bg_g * bg_a, bg_b * bg_a);
let (fg_r_a, fg_g_a, fg_b_a) = (fg_r * fg_a, fg_g * fg_a, fg_b * fg_a);
let (out_r_a, out_g_a, out_b_a) = (
fg_r_a + bg_r_a * (1.0 - fg_a),
fg_g_a + bg_g_a * (1.0 - fg_a),
fg_b_a + bg_b_a * (1.0 - fg_a),
);
let (out_r, out_g, out_b) = (
out_r_a / alpha_final,
out_g_a / alpha_final,
out_b_a / alpha_final,
);
*self = Bgra([
NumCast::from(max_t * out_b).unwrap(),
NumCast::from(max_t * out_g).unwrap(),
NumCast::from(max_t * out_r).unwrap(),
NumCast::from(max_t * alpha_final).unwrap(),
])
}
}
impl<T: Primitive> Blend for Rgb<T> {
fn blend(&mut self, other: &Rgb<T>) {
*self = *other
}
}
impl<T: Primitive> Blend for Bgr<T> {
fn blend(&mut self, other: &Bgr<T>) {
*self = *other
}
}
pub(crate) trait Invert {
fn invert(&mut self);
}
impl<T: Primitive> Invert for LumaA<T> {
fn invert(&mut self) {
let l = self.0;
let max = T::max_value();
*self = LumaA([max - l[0], l[1]])
}
}
impl<T: Primitive> Invert for Luma<T> {
fn invert(&mut self) {
let l = self.0;
let max = T::max_value();
let l1 = max - l[0];
*self = Luma([l1])
}
}
impl<T: Primitive> Invert for Rgba<T> {
fn invert(&mut self) {
let rgba = self.0;
let max = T::max_value();
*self = Rgba([max - rgba[0], max - rgba[1], max - rgba[2], rgba[3]])
}
}
impl<T: Primitive> Invert for Bgra<T> {
fn invert(&mut self) {
let bgra = self.0;
let max = T::max_value();
*self = Bgra([max - bgra[2], max - bgra[1], max - bgra[0], bgra[3]])
}
}
impl<T: Primitive> Invert for Rgb<T> {
fn invert(&mut self) {
let rgb = self.0;
let max = T::max_value();
let r1 = max - rgb[0];
let g1 = max - rgb[1];
let b1 = max - rgb[2];
*self = Rgb([r1, g1, b1])
}
}
impl<T: Primitive> Invert for Bgr<T> {
fn invert(&mut self) {
let bgr = self.0;
let max = T::max_value();
let r1 = max - bgr[2];
let g1 = max - bgr[1];
let b1 = max - bgr[0];
*self = Bgr([b1, g1, r1])
}
}
#[cfg(test)]
mod tests {
use super::{Bgr, Bgra, Luma, LumaA, Pixel, Rgb, Rgba};
#[test]
fn test_apply_with_alpha_rgba() {
let mut rgba = Rgba([0, 0, 0, 0]);
rgba.apply_with_alpha(|s| s, |_| 0xFF);
assert_eq!(rgba, Rgba([0, 0, 0, 0xFF]));
}
#[test]
fn test_apply_with_alpha_bgra() {
let mut bgra = Bgra([0, 0, 0, 0]);
bgra.apply_with_alpha(|s| s, |_| 0xFF);
assert_eq!(bgra, Bgra([0, 0, 0, 0xFF]));
}
#[test]
fn test_apply_with_alpha_rgb() {
let mut rgb = Rgb([0, 0, 0]);
rgb.apply_with_alpha(|s| s, |_| panic!("bug"));
assert_eq!(rgb, Rgb([0, 0, 0]));
}
#[test]
fn test_apply_with_alpha_bgr() {
let mut bgr = Bgr([0, 0, 0]);
bgr.apply_with_alpha(|s| s, |_| panic!("bug"));
assert_eq!(bgr, Bgr([0, 0, 0]));
}
#[test]
fn test_map_with_alpha_rgba() {
let rgba = Rgba([0, 0, 0, 0]).map_with_alpha(|s| s, |_| 0xFF);
assert_eq!(rgba, Rgba([0, 0, 0, 0xFF]));
}
#[test]
fn test_map_with_alpha_rgb() {
let rgb = Rgb([0, 0, 0]).map_with_alpha(|s| s, |_| panic!("bug"));
assert_eq!(rgb, Rgb([0, 0, 0]));
}
#[test]
fn test_map_with_alpha_bgr() {
let bgr = Bgr([0, 0, 0]).map_with_alpha(|s| s, |_| panic!("bug"));
assert_eq!(bgr, Bgr([0, 0, 0]));
}
#[test]
fn test_map_with_alpha_bgra() {
let bgra = Bgra([0, 0, 0, 0]).map_with_alpha(|s| s, |_| 0xFF);
assert_eq!(bgra, Bgra([0, 0, 0, 0xFF]));
}
#[test]
fn test_blend_luma_alpha() {
let ref mut a = LumaA([255 as u8, 255]);
let b = LumaA([255 as u8, 255]);
a.blend(&b);
assert_eq!(a.0[0], 255);
assert_eq!(a.0[1], 255);
let ref mut a = LumaA([255 as u8, 0]);
let b = LumaA([255 as u8, 255]);
a.blend(&b);
assert_eq!(a.0[0], 255);
assert_eq!(a.0[1], 255);
let ref mut a = LumaA([255 as u8, 255]);
let b = LumaA([255 as u8, 0]);
a.blend(&b);
assert_eq!(a.0[0], 255);
assert_eq!(a.0[1], 255);
let ref mut a = LumaA([255 as u8, 0]);
let b = LumaA([255 as u8, 0]);
a.blend(&b);
assert_eq!(a.0[0], 255);
assert_eq!(a.0[1], 0);
}
#[test]
fn test_blend_rgba() {
let ref mut a = Rgba([255 as u8, 255, 255, 255]);
let b = Rgba([255 as u8, 255, 255, 255]);
a.blend(&b);
assert_eq!(a.0, [255, 255, 255, 255]);
let ref mut a = Rgba([255 as u8, 255, 255, 0]);
let b = Rgba([255 as u8, 255, 255, 255]);
a.blend(&b);
assert_eq!(a.0, [255, 255, 255, 255]);
let ref mut a = Rgba([255 as u8, 255, 255, 255]);
let b = Rgba([255 as u8, 255, 255, 0]);
a.blend(&b);
assert_eq!(a.0, [255, 255, 255, 255]);
let ref mut a = Rgba([255 as u8, 255, 255, 0]);
let b = Rgba([255 as u8, 255, 255, 0]);
a.blend(&b);
assert_eq!(a.0, [255, 255, 255, 0]);
}
#[test]
fn test_apply_without_alpha_rgba() {
let mut rgba = Rgba([0, 0, 0, 0]);
rgba.apply_without_alpha(|s| s + 1);
assert_eq!(rgba, Rgba([1, 1, 1, 0]));
}
#[test]
fn test_apply_without_alpha_bgra() {
let mut bgra = Bgra([0, 0, 0, 0]);
bgra.apply_without_alpha(|s| s + 1);
assert_eq!(bgra, Bgra([1, 1, 1, 0]));
}
#[test]
fn test_apply_without_alpha_rgb() {
let mut rgb = Rgb([0, 0, 0]);
rgb.apply_without_alpha(|s| s + 1);
assert_eq!(rgb, Rgb([1, 1, 1]));
}
#[test]
fn test_apply_without_alpha_bgr() {
let mut bgr = Bgr([0, 0, 0]);
bgr.apply_without_alpha(|s| s + 1);
assert_eq!(bgr, Bgr([1, 1, 1]));
}
#[test]
fn test_map_without_alpha_rgba() {
let rgba = Rgba([0, 0, 0, 0]).map_without_alpha(|s| s + 1);
assert_eq!(rgba, Rgba([1, 1, 1, 0]));
}
#[test]
fn test_map_without_alpha_rgb() {
let rgb = Rgb([0, 0, 0]).map_without_alpha(|s| s + 1);
assert_eq!(rgb, Rgb([1, 1, 1]));
}
#[test]
fn test_map_without_alpha_bgr() {
let bgr = Bgr([0, 0, 0]).map_without_alpha(|s| s + 1);
assert_eq!(bgr, Bgr([1, 1, 1]));
}
#[test]
fn test_map_without_alpha_bgra() {
let bgra = Bgra([0, 0, 0, 0]).map_without_alpha(|s| s + 1);
assert_eq!(bgra, Bgra([1, 1, 1, 0]));
}
macro_rules! test_lossless_conversion {
($a:ty, $b:ty, $c:ty) => {
let a: $a = [<$a as Pixel>::Subpixel::max_value() >> 2; <$a as Pixel>::CHANNEL_COUNT as usize].into();
let b: $b = a.into_color();
let c: $c = b.into_color();
assert_eq!(a.channels(), c.channels());
};
}
#[test]
fn test_lossless_conversions() {
use super::IntoColor;
test_lossless_conversion!(Bgr<u8>, Rgba<u8>, Bgr<u8>);
test_lossless_conversion!(Bgra<u8>, Rgba<u8>, Bgra<u8>);
test_lossless_conversion!(Luma<u8>, Luma<u16>, Luma<u8>);
test_lossless_conversion!(LumaA<u8>, LumaA<u16>, LumaA<u8>);
test_lossless_conversion!(Rgb<u8>, Rgb<u16>, Rgb<u8>);
test_lossless_conversion!(Rgba<u8>, Rgba<u16>, Rgba<u8>);
}
}