Struct nannou::color::luma::Luma

#[repr(C)]pub struct Luma<S = Srgb, T = f32> where
    S: LumaStandard,
    T: Component,  {
    pub luma: T,
    pub standard: PhantomData<S>,
}

Luminance.

Luma is a purely gray scale color space, which is included more for completeness than anything else, and represents how bright a color is perceived to be. It's basically the Y component of CIE XYZ. The lack of any form of hue representation limits the set of operations that can be performed on it.

Fields

luma: T

The lightness of the color. 0.0 is black and 1.0 is white.

standard: PhantomData<S>

The kind of RGB standard. sRGB is the default.

Implementations

impl<S, T> Luma<S, T> where
    S: LumaStandard,
    T: Component, 

pub fn new(luma: T) -> Luma<S, T>

Create a luminance color.

pub fn into_format<U>(self) -> Luma<S, U> where
    U: Component, 

Convert into another component type.

pub fn from_format<U>(color: Luma<S, U>) -> Luma<S, T> where
    U: Component, 

Convert from another component type.

pub fn into_components(self) -> (T,)

Convert to a (luma,) tuple.

pub fn from_components((T,)) -> Luma<S, T>

Convert from a (luma,) tuple.

impl<S, T> Luma<S, T> where
    S: LumaStandard,
    T: Component + Float, 

pub fn into_linear(self) -> Luma<Linear<<S as LumaStandard>::WhitePoint>, T>

Convert the color to linear luminance.

pub fn from_linear(
    color: Luma<Linear<<S as LumaStandard>::WhitePoint>, T>
) -> Luma<S, T>

Convert linear luminance to nonlinear luminance.

pub fn into_encoding<St>(self) -> Luma<St, T> where
    St: LumaStandard<WhitePoint = <S as LumaStandard>::WhitePoint>, 

Convert the color to a different encoding.

pub fn from_encoding<St>(color: Luma<St, T>) -> Luma<S, T> where
    St: LumaStandard<WhitePoint = <S as LumaStandard>::WhitePoint>, 

Convert luminance from a different encoding.

Trait Implementations

impl<S, T> AbsDiffEq<Luma<S, T>> for Luma<S, T> where
    S: LumaStandard + PartialEq<S>,
    T: Component + AbsDiffEq<T>,
    <T as AbsDiffEq<T>>::Epsilon: Copy, 

type Epsilon = <T as AbsDiffEq<T>>::Epsilon

Used for specifying relative comparisons.

fn default_epsilon() -> <Luma<S, T> as AbsDiffEq<Luma<S, T>>>::Epsilon

The default tolerance to use when testing values that are close together.

fn abs_diff_eq(
    &self,
    other: &Luma<S, T>,
    epsilon: <Luma<S, T> as AbsDiffEq<Luma<S, T>>>::Epsilon
) -> bool

A test for equality that uses the absolute difference to compute the approximate equality of two numbers.

fn abs_diff_ne(&self, other: &Rhs, epsilon: Self::Epsilon) -> bool

The inverse of ApproxEq::abs_diff_eq.

impl<S, T> Add<Luma<S, T>> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + Add<T>,
    <T as Add<T>>::Output: Component, 

type Output = Luma<S, <T as Add<T>>::Output>

The resulting type after applying the + operator.

fn add(self, other: Luma<S, T>) -> <Luma<S, T> as Add<Luma<S, T>>>::Output

Performs the + operation.

impl<S, T> Add<T> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + Add<T>,
    <T as Add<T>>::Output: Component, 

type Output = Luma<S, <T as Add<T>>::Output>

The resulting type after applying the + operator.

fn add(self, c: T) -> <Luma<S, T> as Add<T>>::Output

Performs the + operation.

impl<S, T> AddAssign<Luma<S, T>> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + AddAssign<T>, 

fn add_assign(&mut self, other: Luma<S, T>)

Performs the += operation.

impl<S, T> AddAssign<T> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + AddAssign<T>, 

fn add_assign(&mut self, c: T)

Performs the += operation.

impl<S, T, P> AsMut<P> for Luma<S, T> where
    P: RawPixel<T> + ?Sized,
    S: LumaStandard,
    T: Component, 

fn as_mut(&mut self) -> &mut P

Convert to a raw pixel format.

use palette::SrgbLuma;

let mut luma = SrgbLuma::new(100);
{
    let raw: &mut [u8] = luma.as_mut();
    raw[0] = 5;
}

assert_eq!(luma.luma, 5);

impl<S, T, P> AsRef<P> for Luma<S, T> where
    P: RawPixel<T> + ?Sized,
    S: LumaStandard,
    T: Component, 

fn as_ref(&self) -> &P

Convert to a raw pixel format.

use palette::SrgbLuma;

let luma = SrgbLuma::new(100);
let raw: &[u8] = luma.as_ref();

assert_eq!(raw[0], 100);

impl<S, T> Blend for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + Float, 

type Color = Luma<S, T>

The core color type. Typically Self for color types without alpha.

fn into_premultiplied(self) -> PreAlpha<Luma<S, T>, T>

Convert the color to premultiplied alpha.

fn from_premultiplied(color: PreAlpha<Luma<S, T>, T>) -> Luma<S, T>

Convert the color from premultiplied alpha.

fn blend<F>(self, destination: Self, blend_function: F) -> Self where
    F: BlendFunction<Self::Color>, 

Blend self, as the source color, with destination, using blend_function. Anything that implements BlendFunction is acceptable, including functions and closures.

fn over(self, other: Self) -> Self

Place self over other. This is the good old common alpha composition equation.

fn inside(self, other: Self) -> Self

Results in the parts of self that overlaps the visible parts of other.

fn outside(self, other: Self) -> Self

Results in the parts of self that lies outside the visible parts of other.

fn atop(self, other: Self) -> Self

Place self over only the visible parts of other.

fn xor(self, other: Self) -> Self

Results in either self or other, where they do not overlap.

fn plus(self, other: Self) -> Self

Add self and other. This uses the alpha component to regulate the effect, so it's not just plain component wise addition.

fn multiply(self, other: Self) -> Self

Multiply self with other. This uses the alpha component to regulate the effect, so it's not just plain component wise multiplication.

fn screen(self, other: Self) -> Self

Make a color which is at least as light as self or other.

fn overlay(self, other: Self) -> Self

Multiply self or other if other is dark, or screen them if other is light. This results in an S curve.

fn darken(self, other: Self) -> Self

Return the darkest parts of self and other.

fn lighten(self, other: Self) -> Self

Return the lightest parts of self and other.

fn dodge(self, other: Self) -> Self

Lighten other to reflect self. Results in other if self is black.

fn burn(self, other: Self) -> Self

Darken other to reflect self. Results in other if self is white.

fn hard_light(self, other: Self) -> Self

Multiply self or other if other is dark, or screen them if self is light. This is similar to overlay, but depends on self instead of other.

fn soft_light(self, other: Self) -> Self

Lighten other if self is light, or darken other as if it's burned if self is dark. The effect is increased if the components of self is further from 0.5.

fn difference(self, other: Self) -> Self

Return the absolute difference between self and other. It's basically abs(self - other), but regulated by the alpha component.

fn exclusion(self, other: Self) -> Self

Similar to difference, but appears to result in a lower contrast. other is inverted if self is white, and preserved if self is black.

impl<S, T> Clone for Luma<S, T> where
    S: LumaStandard,
    T: Component, 

fn clone(&self) -> Luma<S, T>

Returns a copy of the value.

fn clone_from(&mut self, source: &Self)

Performs copy-assignment from source.

impl<S, T> ComponentWise for Luma<S, T> where
    S: LumaStandard,
    T: Component, 

type Scalar = T

The scalar type for color components.

fn component_wise<F>(&self, other: &Luma<S, T>, f: F) -> Luma<S, T> where
    F: FnMut(T, T) -> T, 

Perform a binary operation on this and an other color.

fn component_wise_self<F>(&self, f: F) -> Luma<S, T> where
    F: FnMut(T) -> T, 

Perform a unary operation on this color.

impl<S, T> Copy for Luma<S, T> where
    S: LumaStandard,
    T: Component, 

impl<S, T> Debug for Luma<S, T> where
    S: Debug + LumaStandard,
    T: Debug + Component, 

fn fmt(&self, f: &mut Formatter<'_>) -> Result<(), Error>

Formats the value using the given formatter.

impl<S, T> Default for Luma<S, T> where
    S: LumaStandard,
    T: Component, 

fn default() -> Luma<S, T>

Returns the "default value" for a type.

impl<S, T> Div<Luma<S, T>> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + Div<T>,
    <T as Div<T>>::Output: Component, 

type Output = Luma<S, <T as Div<T>>::Output>

The resulting type after applying the / operator.

fn div(self, other: Luma<S, T>) -> <Luma<S, T> as Div<Luma<S, T>>>::Output

Performs the / operation.

impl<S, T> Div<T> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + Div<T>,
    <T as Div<T>>::Output: Component, 

type Output = Luma<S, <T as Div<T>>::Output>

The resulting type after applying the / operator.

fn div(self, c: T) -> <Luma<S, T> as Div<T>>::Output

Performs the / operation.

impl<S, T> DivAssign<Luma<S, T>> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + DivAssign<T>, 

fn div_assign(&mut self, other: Luma<S, T>)

Performs the /= operation.

impl<S, T> DivAssign<T> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + DivAssign<T>, 

fn div_assign(&mut self, c: T)

Performs the /= operation.

impl<S, T> From<(T,)> for Luma<S, T> where
    S: LumaStandard,
    T: Component, 

fn from(components: (T,)) -> Luma<S, T>

Performs the conversion.

impl<S, T, _S> From<Alpha<Hsl<_S, T>, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float,
    _S: RgbSpace<WhitePoint = <S as LumaStandard>::WhitePoint>, 

fn from(color: Alpha<Hsl<_S, T>, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T, _S> From<Alpha<Hsv<_S, T>, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float,
    _S: RgbSpace<WhitePoint = <S as LumaStandard>::WhitePoint>, 

fn from(color: Alpha<Hsv<_S, T>, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T, _S> From<Alpha<Hwb<_S, T>, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float,
    _S: RgbSpace<WhitePoint = <S as LumaStandard>::WhitePoint>, 

fn from(color: Alpha<Hwb<_S, T>, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T> From<Alpha<Lab<<S as LumaStandard>::WhitePoint, T>, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float, 

fn from(color: Alpha<Lab<<S as LumaStandard>::WhitePoint, T>, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T> From<Alpha<Lch<<S as LumaStandard>::WhitePoint, T>, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float, 

fn from(color: Alpha<Lch<<S as LumaStandard>::WhitePoint, T>, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T, _S> From<Alpha<Luma<_S, T>, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float,
    _S: LumaStandard<WhitePoint = <S as LumaStandard>::WhitePoint>, 

fn from(color: Alpha<Luma<_S, T>, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T, _S> From<Alpha<Rgb<_S, T>, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float,
    _S: RgbStandard,
    <_S as RgbStandard>::Space: RgbSpace,
    <<_S as RgbStandard>::Space as RgbSpace>::WhitePoint == <S as LumaStandard>::WhitePoint, 

fn from(color: Alpha<Rgb<_S, T>, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T> From<Alpha<Xyz<<S as LumaStandard>::WhitePoint, T>, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float, 

fn from(color: Alpha<Xyz<<S as LumaStandard>::WhitePoint, T>, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T> From<Alpha<Yxy<<S as LumaStandard>::WhitePoint, T>, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float, 

fn from(color: Alpha<Yxy<<S as LumaStandard>::WhitePoint, T>, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T, _S> From<Hsl<_S, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float,
    _S: RgbSpace<WhitePoint = <S as LumaStandard>::WhitePoint>, 

fn from(color: Hsl<_S, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T, _S> From<Hsv<_S, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float,
    _S: RgbSpace<WhitePoint = <S as LumaStandard>::WhitePoint>, 

fn from(color: Hsv<_S, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T, _S> From<Hwb<_S, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float,
    _S: RgbSpace<WhitePoint = <S as LumaStandard>::WhitePoint>, 

fn from(color: Hwb<_S, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T> From<Lab<<S as LumaStandard>::WhitePoint, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float, 

fn from(color: Lab<<S as LumaStandard>::WhitePoint, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T> From<Lch<<S as LumaStandard>::WhitePoint, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float, 

fn from(color: Lch<<S as LumaStandard>::WhitePoint, T>) -> Luma<S, T>

Performs the conversion.

impl<Wp, T, S> From<Luma<S, T>> for Xyz<Wp, T> where
    S: LumaStandard<WhitePoint = Wp>,
    T: Component + Float,
    Wp: WhitePoint, 

fn from(color: Luma<S, T>) -> Xyz<Wp, T>

Performs the conversion.

impl<S, T> From<Luma<S, T>> for Yxy<<S as LumaStandard>::WhitePoint, T> where
    S: LumaStandard,
    T: Component + Float, 

fn from(luma: Luma<S, T>) -> Yxy<<S as LumaStandard>::WhitePoint, T>

Performs the conversion.

impl<S, T, St, Wp> From<Luma<St, T>> for Rgb<S, T> where
    S: RgbStandard,
    St: LumaStandard<WhitePoint = Wp>,
    T: Component + Float,
    Wp: WhitePoint,
    <S as RgbStandard>::Space: RgbSpace,
    <<S as RgbStandard>::Space as RgbSpace>::WhitePoint == Wp, 

fn from(color: Luma<St, T>) -> Rgb<S, T>

Performs the conversion.

impl<S, T, _S> From<Luma<_S, T>> for Alpha<Rgb<S, T>, T> where
    S: RgbStandard,
    T: Component + Float,
    _S: LumaStandard<WhitePoint = <<S as RgbStandard>::Space as RgbSpace>::WhitePoint>, 

fn from(color: Luma<_S, T>) -> Alpha<Rgb<S, T>, T>

Performs the conversion.

impl<S, T, _S> From<Luma<_S, T>> for Hsl<S, T> where
    S: RgbSpace,
    T: Component + Float,
    _S: LumaStandard<WhitePoint = <S as RgbSpace>::WhitePoint>, 

fn from(color: Luma<_S, T>) -> Hsl<S, T>

Performs the conversion.

impl<S, T, _S> From<Luma<_S, T>> for Hwb<S, T> where
    S: RgbSpace,
    T: Component + Float,
    _S: LumaStandard<WhitePoint = <S as RgbSpace>::WhitePoint>, 

fn from(color: Luma<_S, T>) -> Hwb<S, T>

Performs the conversion.

impl<Wp, T, _S> From<Luma<_S, T>> for Alpha<Xyz<Wp, T>, T> where
    T: Component + Float,
    Wp: WhitePoint,
    _S: LumaStandard<WhitePoint = Wp>, 

fn from(color: Luma<_S, T>) -> Alpha<Xyz<Wp, T>, T>

Performs the conversion.

impl<Wp, T, _S> From<Luma<_S, T>> for Alpha<Lab<Wp, T>, T> where
    T: Component + Float,
    Wp: WhitePoint,
    _S: LumaStandard<WhitePoint = Wp>, 

fn from(color: Luma<_S, T>) -> Alpha<Lab<Wp, T>, T>

Performs the conversion.

impl<S, T, _S> From<Luma<_S, T>> for Alpha<Hsl<S, T>, T> where
    S: RgbSpace,
    T: Component + Float,
    _S: LumaStandard<WhitePoint = <S as RgbSpace>::WhitePoint>, 

fn from(color: Luma<_S, T>) -> Alpha<Hsl<S, T>, T>

Performs the conversion.

impl<S, T, _S> From<Luma<_S, T>> for Alpha<Hsv<S, T>, T> where
    S: RgbSpace,
    T: Component + Float,
    _S: LumaStandard<WhitePoint = <S as RgbSpace>::WhitePoint>, 

fn from(color: Luma<_S, T>) -> Alpha<Hsv<S, T>, T>

Performs the conversion.

impl<S, T, _S> From<Luma<_S, T>> for Hsv<S, T> where
    S: RgbSpace,
    T: Component + Float,
    _S: LumaStandard<WhitePoint = <S as RgbSpace>::WhitePoint>, 

fn from(color: Luma<_S, T>) -> Hsv<S, T>

Performs the conversion.

impl<Wp, T, _S> From<Luma<_S, T>> for Alpha<Lch<Wp, T>, T> where
    T: Component + Float,
    Wp: WhitePoint,
    _S: LumaStandard<WhitePoint = Wp>, 

fn from(color: Luma<_S, T>) -> Alpha<Lch<Wp, T>, T>

Performs the conversion.

impl<Wp, T, _S> From<Luma<_S, T>> for Alpha<Yxy<Wp, T>, T> where
    T: Component + Float,
    Wp: WhitePoint,
    _S: LumaStandard<WhitePoint = Wp>, 

fn from(color: Luma<_S, T>) -> Alpha<Yxy<Wp, T>, T>

Performs the conversion.

impl<Wp, T, _S> From<Luma<_S, T>> for Lch<Wp, T> where
    T: Component + Float,
    Wp: WhitePoint,
    _S: LumaStandard<WhitePoint = Wp>, 

fn from(color: Luma<_S, T>) -> Lch<Wp, T>

Performs the conversion.

impl<Wp, T, _S> From<Luma<_S, T>> for Lab<Wp, T> where
    T: Component + Float,
    Wp: WhitePoint,
    _S: LumaStandard<WhitePoint = Wp>, 

fn from(color: Luma<_S, T>) -> Lab<Wp, T>

Performs the conversion.

impl<S, T, _S> From<Luma<_S, T>> for Alpha<Hwb<S, T>, T> where
    S: RgbSpace,
    T: Component + Float,
    _S: LumaStandard<WhitePoint = <S as RgbSpace>::WhitePoint>, 

fn from(color: Luma<_S, T>) -> Alpha<Hwb<S, T>, T>

Performs the conversion.

impl<S, T, _S> From<Rgb<_S, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float,
    _S: RgbStandard,
    <_S as RgbStandard>::Space: RgbSpace,
    <<_S as RgbStandard>::Space as RgbSpace>::WhitePoint == <S as LumaStandard>::WhitePoint, 

fn from(color: Rgb<_S, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T> From<Xyz<<S as LumaStandard>::WhitePoint, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float, 

fn from(color: Xyz<<S as LumaStandard>::WhitePoint, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T> From<Yxy<<S as LumaStandard>::WhitePoint, T>> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float, 

fn from(color: Yxy<<S as LumaStandard>::WhitePoint, T>) -> Luma<S, T>

Performs the conversion.

impl<S, T> FromColor<<S as LumaStandard>::WhitePoint, T> for Luma<S, T> where
    S: LumaStandard,
    T: Component + Float, 

fn from_xyz(color: Xyz<<S as LumaStandard>::WhitePoint, T>) -> Luma<S, T>

Convert from XYZ color space

fn from_yxy(color: Yxy<<S as LumaStandard>::WhitePoint, T>) -> Luma<S, T>

Convert from Yxy color space

fn from_luma(
    color: Luma<Linear<<S as LumaStandard>::WhitePoint>, T>
) -> Luma<S, T>

Convert from Luma

fn from_lab(inp: Lab<Wp, T>) -> Self

Convert from L*a*b* color space

fn from_lch(inp: Lch<Wp, T>) -> Self

Convert from L*C*h° color space

fn from_rgb<S>(inp: Rgb<Linear<S>, T>) -> Self where
    S: RgbSpace<WhitePoint = Wp>, 

Convert from RGB color space

fn from_hsl<S>(inp: Hsl<S, T>) -> Self where
    S: RgbSpace<WhitePoint = Wp>, 

Convert from HSL color space

fn from_hsv<S>(inp: Hsv<S, T>) -> Self where
    S: RgbSpace<WhitePoint = Wp>, 

Convert from HSV color space

fn from_hwb<S>(inp: Hwb<S, T>) -> Self where
    S: RgbSpace<WhitePoint = Wp>, 

Convert from HWB color space

impl<S, T> Into<(T,)> for Luma<S, T> where
    S: LumaStandard,
    T: Component, 

fn into(self) -> (T,)

Performs the conversion.

impl<S, Wp, T> IntoColor<Wp, T> for Luma<S, T> where
    S: LumaStandard<WhitePoint = Wp>,
    T: Component + Float,
    Wp: WhitePoint, 

fn into_xyz(self) -> Xyz<Wp, T>

Convert into XYZ space

fn into_yxy(self) -> Yxy<Wp, T>

Convert into Yxy color space

fn into_luma(self) -> Luma<Linear<Wp>, T>

Convert into Luma

fn into_lab(self) -> Lab<Wp, T>

Convert into L*a*b* color space

fn into_lch(self) -> Lch<Wp, T>

Convert into L*C*h° color space

fn into_rgb<S>(self) -> Rgb<Linear<S>, T> where
    S: RgbSpace<WhitePoint = Wp>, 

Convert into RGB color space.

fn into_hsl<S>(self) -> Hsl<S, T> where
    S: RgbSpace<WhitePoint = Wp>, 

Convert into HSL color space

fn into_hsv<S>(self) -> Hsv<S, T> where
    S: RgbSpace<WhitePoint = Wp>, 

Convert into HSV color space

fn into_hwb<S>(self) -> Hwb<S, T> where
    S: RgbSpace<WhitePoint = Wp>, 

Convert into HWB color space

impl<S, T> Limited for Luma<S, T> where
    S: LumaStandard,
    T: Component, 

fn is_valid(&self) -> bool

Check if the color's components are within the expected ranges.

fn clamp(&self) -> Luma<S, T>

Return a new color where the components has been clamped to the nearest valid values.

fn clamp_self(&mut self)

Clamp the color's components to the nearest valid values.

impl<S, T> LowerHex for Luma<S, T> where
    S: LumaStandard,
    T: Component + LowerHex, 

fn fmt(&self, f: &mut Formatter<'_>) -> Result<(), Error>

Formats the value using the given formatter.

impl<S, T> Mix for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + Float, 

type Scalar = T

The type of the mixing factor.

fn mix(&self, other: &Luma<S, T>, factor: T) -> Luma<S, T>

Mix the color with an other color, by factor.

impl<S, T> Mul<Luma<S, T>> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + Mul<T>,
    <T as Mul<T>>::Output: Component, 

type Output = Luma<S, <T as Mul<T>>::Output>

The resulting type after applying the * operator.

fn mul(self, other: Luma<S, T>) -> <Luma<S, T> as Mul<Luma<S, T>>>::Output

Performs the * operation.

impl<S, T> Mul<T> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + Mul<T>,
    <T as Mul<T>>::Output: Component, 

type Output = Luma<S, <T as Mul<T>>::Output>

The resulting type after applying the * operator.

fn mul(self, c: T) -> <Luma<S, T> as Mul<T>>::Output

Performs the * operation.

impl<S, T> MulAssign<Luma<S, T>> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + MulAssign<T>, 

fn mul_assign(&mut self, other: Luma<S, T>)

Performs the *= operation.

impl<S, T> MulAssign<T> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + MulAssign<T>, 

fn mul_assign(&mut self, c: T)

Performs the *= operation.

impl<S, T> PartialEq<Luma<S, T>> for Luma<S, T> where
    S: PartialEq<S> + LumaStandard,
    T: PartialEq<T> + Component, 

fn eq(&self, other: &Luma<S, T>) -> bool

This method tests for self and other values to be equal, and is used by ==.

fn ne(&self, other: &Luma<S, T>) -> bool

This method tests for !=.

impl<S, T> Pixel<T> for Luma<S, T> where
    S: LumaStandard,
    T: Component, 

const CHANNELS: usize

The number of color channels.

fn as_raw<P>(&self) -> &P where
    P: RawPixel<T> + ?Sized, 

Cast as a reference to raw color components.

fn as_raw_mut<P>(&mut self) -> &mut P where
    P: RawPixel<T> + ?Sized, 

Cast as a mutable reference to raw color components.

fn into_raw<P>(self) -> P where
    P: RawPixelSized<T>, 

Convert from raw color components.

fn from_raw<P>(pixel: &P) -> &Self where
    P: RawPixel<T> + ?Sized, 

Cast from a reference to raw color components.

fn from_raw_mut<P>(pixel: &mut P) -> &mut Self where
    P: RawPixel<T> + ?Sized, 

Cast from a mutable reference to raw color components.

fn from_raw_slice(slice: &[T]) -> &[Self]

Cast a slice of raw color components to a slice of colors.

fn from_raw_slice_mut(slice: &mut [T]) -> &mut [Self]

Cast a mutable slice of raw color components to a mutable slice of colors.

fn into_raw_slice(slice: &[Self]) -> &[T]

Cast a slice of colors to a slice of raw color components.

fn into_raw_slice_mut(slice: &mut [Self]) -> &mut [T]

Cast a mutable slice of colors to a mutable slice of raw color components.

impl<S, T> RelativeEq<Luma<S, T>> for Luma<S, T> where
    S: LumaStandard + PartialEq<S>,
    T: Component + RelativeEq<T>,
    <T as AbsDiffEq<T>>::Epsilon: Copy, 

fn default_max_relative() -> <Luma<S, T> as AbsDiffEq<Luma<S, T>>>::Epsilon

The default relative tolerance for testing values that are far-apart.

fn relative_eq(
    &self,
    other: &Luma<S, T>,
    epsilon: <Luma<S, T> as AbsDiffEq<Luma<S, T>>>::Epsilon,
    max_relative: <Luma<S, T> as AbsDiffEq<Luma<S, T>>>::Epsilon
) -> bool

A test for equality that uses a relative comparison if the values are far apart.

fn relative_ne(
    &self,
    other: &Rhs,
    epsilon: Self::Epsilon,
    max_relative: Self::Epsilon
) -> bool

The inverse of ApproxEq::relative_eq.

impl<S, T> Shade for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + Float, 

type Scalar = T

The type of the lighten/darken amount.

fn lighten(&self, amount: T) -> Luma<S, T>

Lighten the color by amount.

fn darken(&self, amount: Self::Scalar) -> Self

Darken the color by amount.

impl<S, T> StructuralPartialEq for Luma<S, T> where
    S: LumaStandard,
    T: Component, 

impl<S, T> Sub<Luma<S, T>> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + Sub<T>,
    <T as Sub<T>>::Output: Component, 

type Output = Luma<S, <T as Sub<T>>::Output>

The resulting type after applying the - operator.

fn sub(self, other: Luma<S, T>) -> <Luma<S, T> as Sub<Luma<S, T>>>::Output

Performs the - operation.

impl<S, T> Sub<T> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + Sub<T>,
    <T as Sub<T>>::Output: Component, 

type Output = Luma<S, <T as Sub<T>>::Output>

The resulting type after applying the - operator.

fn sub(self, c: T) -> <Luma<S, T> as Sub<T>>::Output

Performs the - operation.

impl<S, T> SubAssign<Luma<S, T>> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + SubAssign<T>, 

fn sub_assign(&mut self, other: Luma<S, T>)

Performs the -= operation.

impl<S, T> SubAssign<T> for Luma<S, T> where
    S: LumaStandard<TransferFn = LinearFn>,
    T: Component + SubAssign<T>, 

fn sub_assign(&mut self, c: T)

Performs the -= operation.

impl<S, T> UlpsEq<Luma<S, T>> for Luma<S, T> where
    S: LumaStandard + PartialEq<S>,
    T: Component + UlpsEq<T>,
    <T as AbsDiffEq<T>>::Epsilon: Copy, 

fn default_max_ulps() -> u32

The default ULPs to tolerate when testing values that are far-apart.

fn ulps_eq(
    &self,
    other: &Luma<S, T>,
    epsilon: <Luma<S, T> as AbsDiffEq<Luma<S, T>>>::Epsilon,
    max_ulps: u32
) -> bool

A test for equality that uses units in the last place (ULP) if the values are far apart.

fn ulps_ne(&self, other: &Rhs, epsilon: Self::Epsilon, max_ulps: u32) -> bool

The inverse of ApproxEq::ulps_eq.

impl<S, T> UpperHex for Luma<S, T> where
    S: LumaStandard,
    T: Component + UpperHex, 

fn fmt(&self, f: &mut Formatter<'_>) -> Result<(), Error>

Formats the value using the given formatter.