Struct vek::vec::repr_simd::rgb::Rgb

#[repr(simd)]
pub struct Rgb<T> {
    pub r: T,
    pub g: T,
    pub b: T,
}

Vector type suited for RGB color data.

There is no trait bound on ColorComponent, but if T doesn't implement it, you'll miss some goodies.

Fields

r: T

g: T

b: T

Methods

impl<T> Rgb<T>

pub const fn new(r: T, g: T, b: T) -> Self

Creates a vector from elements.

impl<T> Rgb<T>

pub fn broadcast(val: T) -> Self where
    T: Copy, 

Broadcasts a single value to all elements of a new vector.

This function is also named splat() in some libraries, or set1() in Intel intrinsics.

"Broadcast" was chosen as the name because it is explicit enough and is the same wording as the description in relevant Intel intrinsics.

assert_eq!(Vec4::broadcast(5), Vec4::new(5,5,5,5));
assert_eq!(Vec4::broadcast(5), Vec4::from(5));

pub fn zero() -> Self where
    T: Zero, 

Creates a new vector with all elements set to zero.

assert_eq!(Vec4::zero(), Vec4::new(0,0,0,0));
assert_eq!(Vec4::zero(), Vec4::broadcast(0));
assert_eq!(Vec4::zero(), Vec4::from(0));

pub fn one() -> Self where
    T: One, 

Creates a new vector with all elements set to one.

assert_eq!(Vec4::one(), Vec4::new(1,1,1,1));
assert_eq!(Vec4::one(), Vec4::broadcast(1));
assert_eq!(Vec4::one(), Vec4::from(1));

pub fn iota() -> Self where
    T: Zero + One + AddAssign + Copy, 

Produces a vector of the first n integers, starting from zero, where n is the number of elements for this vector type.

The iota (ι) function, originating from APL.

See this StackOverflow answer.

This is mostly useful for debugging purposes and tests.

assert_eq!(Vec4::iota(), Vec4::new(0, 1, 2, 3));

pub const fn elem_count(&self) -> usize

Convenience method which returns the number of elements of this vector.

let v = Vec4::new(0,1,2,3);
assert_eq!(v.elem_count(), 4);

pub const ELEM_COUNT: usize

Convenience constant representing the number of elements for this vector type.

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

Converts this into a tuple with the same number of elements by consuming.

pub fn into_array(self) -> [T; 3]

Converts this vector into a fixed-size array.

pub fn as_slice(&self) -> &[T]

View this vector as an immutable slice.

pub fn as_mut_slice(&mut self) -> &mut [T]

View this vector as a mutable slice.

pub fn from_slice(slice: &[T]) -> Self where
    T: Default + Copy, 

Collects the content of a slice into a new vector. Elements are initialized to their default values.

pub fn map<D, F>(self, f: F) -> Rgb<D> where
    F: FnMut(T) -> D, 

Returns a memberwise-converted copy of this vector, using the given conversion closure.

let v = Vec4::new(0_f32, 1., 1.8, 3.14);
let i = v.map(|x| x.round() as i32);
assert_eq!(i, Vec4::new(0, 1, 2, 3));

Performing LERP on integer vectors by concisely converting them to floats:

let a = Vec4::new(0,1,2,3).map(|x| x as f32);
let b = Vec4::new(2,3,4,5).map(|x| x as f32);
let v = Vec4::lerp(a, b, 0.5_f32).map(|x| x.round() as i32);
assert_eq!(v, Vec4::new(1,2,3,4));

pub fn map2<D, F, S>(self, other: Rgb<S>, f: F) -> Rgb<D> where
    F: FnMut(T, S) -> D, 

Applies the function f to each element of two vectors, pairwise, and returns the result.

let a = Vec4::<u8>::new(255, 254, 253, 252);
let b = Vec4::<u8>::new(1, 2, 3, 4);
let v = a.map2(b, |a, b| a.wrapping_add(b));
assert_eq!(v, Vec4::zero());
let v = a.map2(b, u8::wrapping_add);
assert_eq!(v, Vec4::zero());

pub fn apply<F>(&mut self, f: F) where
    T: Copy,
    F: FnMut(T) -> T, 

Applies the function f to each element of this vector, in-place.

let mut v = Vec4::new(0_u32, 1, 2, 3);
v.apply(|x| x.count_ones());
assert_eq!(v, Vec4::new(0, 1, 1, 2));

pub fn apply2<F, S>(&mut self, other: Rgb<S>, f: F) where
    T: Copy,
    F: FnMut(T, S) -> T, 

Applies the function f to each element of two vectors, pairwise, in-place.

let mut a = Vec4::<u8>::new(255, 254, 253, 252);
let b = Vec4::<u8>::new(1, 2, 3, 4);
a.apply2(b, |a, b| a.wrapping_add(b));
assert_eq!(a, Vec4::zero());
a.apply2(b, u8::wrapping_add);
assert_eq!(a, b);

pub fn zip<S>(self, other: Rgb<S>) -> Rgb<(T, S)>

"Zips" two vectors together into a vector of tuples.

let a = Vec4::<u8>::new(255, 254, 253, 252);
let b = Vec4::<u8>::new(1, 2, 3, 4);
assert_eq!(a.zip(b), Vec4::new((255, 1), (254, 2), (253, 3), (252, 4)));

pub fn numcast<D>(self) -> Option<Rgb<D>> where
    T: NumCast,
    D: NumCast, 

Returns a memberwise-converted copy of this vector, using NumCast.

let v = Vec4::new(0_f32, 1., 2., 3.);
let i: Vec4<i32> = v.numcast().unwrap();
assert_eq!(i, Vec4::new(0, 1, 2, 3));

pub fn mul_add<V: Into<Self>>(self, mul: V, add: V) -> Self where
    T: MulAdd<T, T, Output = T>, 

Fused multiply-add. Returns self * mul + add, and may be implemented efficiently by the hardware.

The compiler is often able to detect this kind of operation, so generally you don't need to use it. However, it can make your intent clear.

The name for this method is the one used by the same operation on primitive floating-point types.

let a = Vec4::new(0,1,2,3);
let b = Vec4::new(4,5,6,7);
let c = Vec4::new(8,9,0,1);
assert_eq!(a*b+c, a.mul_add(b, c));

pub fn is_any_negative(&self) -> bool where
    T: Signed, 

Is any of the elements negative ?

This was intended for checking the validity of extent vectors, but can make sense for other types too.

pub fn are_all_positive(&self) -> bool where
    T: Signed, 

Are all of the elements positive ?

pub fn min<V>(a: V, b: V) -> Self where
    V: Into<Self>,
    T: Ord, 

Compares elements of a and b, and returns the minimum values into a new vector, using total ordering.

let a = Vec4::new(0,1,2,3);
let b = Vec4::new(3,2,1,0);
let m = Vec4::new(0,1,1,0);
assert_eq!(m, Vec4::min(a, b));

pub fn max<V>(a: V, b: V) -> Self where
    V: Into<Self>,
    T: Ord, 

Compares elements of a and b, and returns the maximum values into a new vector, using total ordering.

let a = Vec4::new(0,1,2,3);
let b = Vec4::new(3,2,1,0);
let m = Vec4::new(3,2,2,3);
assert_eq!(m, Vec4::max(a, b));

pub fn partial_min<V>(a: V, b: V) -> Self where
    V: Into<Self>,
    T: PartialOrd, 

Compares elements of a and b, and returns the minimum values into a new vector, using partial ordering.

let a = Vec4::new(0,1,2,3);
let b = Vec4::new(3,2,1,0);
let m = Vec4::new(0,1,1,0);
assert_eq!(m, Vec4::partial_min(a, b));

pub fn partial_max<V>(a: V, b: V) -> Self where
    V: Into<Self>,
    T: PartialOrd, 

Compares elements of a and b, and returns the minimum values into a new vector, using partial ordering.

let a = Vec4::new(0,1,2,3);
let b = Vec4::new(3,2,1,0);
let m = Vec4::new(3,2,2,3);
assert_eq!(m, Vec4::partial_max(a, b));

pub fn reduce_min(self) -> T where
    T: Ord, 

Returns the element which has the lowest value in this vector, using total ordering.

assert_eq!(-5, Vec4::new(0, 5, -5, 8).reduce_min());

pub fn reduce_max(self) -> T where
    T: Ord, 

Returns the element which has the highest value in this vector, using total ordering.

assert_eq!(8, Vec4::new(0, 5, -5, 8).reduce_max());

pub fn reduce_partial_min(self) -> T where
    T: PartialOrd, 

Returns the element which has the lowest value in this vector, using partial ordering.

assert_eq!(-5_f32, Vec4::new(0_f32, 5., -5., 8.).reduce_partial_min());

pub fn reduce_partial_max(self) -> T where
    T: PartialOrd, 

Returns the element which has the highest value in this vector, using partial ordering.

assert_eq!(8_f32, Vec4::new(0_f32, 5., -5., 8.).reduce_partial_max());

pub fn reduce_bitand(self) -> T where
    T: BitAnd<T, Output = T>, 

Returns the result of bitwise-AND (&) on all elements of this vector.

assert_eq!(true,  Vec4::new(true, true, true, true).reduce_bitand());
assert_eq!(false, Vec4::new(true, false, true, true).reduce_bitand());
assert_eq!(false, Vec4::new(true, true, true, false).reduce_bitand());

pub fn reduce_bitor(self) -> T where
    T: BitOr<T, Output = T>, 

Returns the result of bitwise-OR (|) on all elements of this vector.

assert_eq!(false, Vec4::new(false, false, false, false).reduce_bitor());
assert_eq!(true,  Vec4::new(false, false, true, false).reduce_bitor());

pub fn reduce_bitxor(self) -> T where
    T: BitXor<T, Output = T>, 

Returns the result of bitwise-XOR (^) on all elements of this vector.

assert_eq!(false, Vec4::new(true, true, true, true).reduce_bitxor());
assert_eq!(true,  Vec4::new(true, false, true, true).reduce_bitxor());

pub fn reduce<F>(self, f: F) -> T where
    F: FnMut(T, T) -> T, 

Reduces this vector with the given accumulator closure.

pub fn product(self) -> T where
    T: Product, 

Returns the product of each of this vector's elements.

assert_eq!(1*2*3*4, Vec4::new(1, 2, 3, 4).product());

pub fn sum(self) -> T where
    T: Sum, 

Returns the sum of each of this vector's elements.

assert_eq!(1+2+3+4, Vec4::new(1, 2, 3, 4).sum());

pub fn average(self) -> T where
    T: Sum + Div<T, Output = T> + From<u8>, 

Returns the average of this vector's elements.

assert_eq!(2.5_f32, Vec4::new(1_f32, 2., 3., 4.).average());

You should avoid using it on u8 vectors, not only because integer overflows cause panics in debug mode, but also because of integer division, the result may not be the one you expect.

// This causes a panic!
let red = Vec4::new(255u8, 1, 0, 0);
let grey_level = red.average();
assert_eq!(grey_level, 128);

You may want to convert the elements to bigger integers (or floating-point) instead:

let red = Vec4::new(255u8, 1, 128, 128);

let red = red.map(|c| c as u16);
let grey_level = red.average() as u8;
assert_eq!(grey_level, 128);

let red = red.map(|c| c as f32);
let grey_level = red.average().round() as u8;
assert_eq!(grey_level, 128);

pub fn sqrt(self) -> Self where
    T: Real, 

Returns a new vector which elements are the respective square roots of this vector's elements.

let v = Vec4::new(1f32, 2f32, 3f32, 4f32);
let s = Vec4::new(1f32, 4f32, 9f32, 16f32);
assert_eq!(v, s.sqrt());

pub fn rsqrt(self) -> Self where
    T: Real, 

Returns a new vector which elements are the respective reciprocal square roots of this vector's elements.

let v = Vec4::new(1f32, 0.5f32, 1f32/3f32, 0.25f32);
let s = Vec4::new(1f32, 4f32, 9f32, 16f32);
assert_eq!(v, s.rsqrt());

pub fn recip(self) -> Self where
    T: Real, 

Returns a new vector which elements are the respective reciprocal of this vector's elements.

let v = Vec4::new(1f32, 0.5f32, 0.25f32, 0.125f32);
let s = Vec4::new(1f32, 2f32, 4f32, 8f32);
assert_eq!(v, s.recip());
assert_eq!(s, v.recip());

pub fn ceil(self) -> Self where
    T: Real, 

Returns a new vector which elements are rounded to the nearest greater integer.

let v = Vec4::new(0_f32, 1., 1.8, 3.14);
assert_eq!(v.ceil(), Vec4::new(0f32, 1f32, 2f32, 4f32));

pub fn floor(self) -> Self where
    T: Real, 

Returns a new vector which elements are rounded down to the nearest lower integer.

let v = Vec4::new(0_f32, 1., 1.8, 3.14);
assert_eq!(v.floor(), Vec4::new(0f32, 1f32, 1f32, 3f32));

pub fn round(self) -> Self where
    T: Real, 

Returns a new vector which elements are rounded to the nearest integer.

let v = Vec4::new(0_f32, 1., 1.8, 3.14);
assert_eq!(v.round(), Vec4::new(0f32, 1f32, 2f32, 3f32));

pub fn hadd(self, rhs: Self) -> Self where
    T: Add<T, Output = T>, 

Horizontally adds adjacent pairs of elements in self and rhs into a new vector.

let a = Vec4::new(0, 1, 2, 3);
let b = Vec4::new(4, 5, 6, 7);
let h = Vec4::new(0+1, 2+3, 4+5, 6+7);
assert_eq!(h, a.hadd(b));

pub fn partial_cmpeq<Rhs: AsRef<Self>>(&self, rhs: &Rhs) -> Rgb<bool> where
    T: PartialEq, 

Compares each element of two vectors with the partial equality test, returning a boolean vector.

let u = Vec4::new(0,2,2,6);
let v = Vec4::new(0,1,2,3);
assert_eq!(u.partial_cmpeq(&v), Vec4::new(true, false, true, false));

pub fn partial_cmpne<Rhs: AsRef<Self>>(&self, rhs: &Rhs) -> Rgb<bool> where
    T: PartialEq, 

Compares each element of two vectors with the partial not-equal test, returning a boolean vector.

let u = Vec4::new(0,2,2,6);
let v = Vec4::new(0,1,2,3);
assert_eq!(u.partial_cmpne(&v), Vec4::new(false, true, false, true));

pub fn partial_cmpge<Rhs: AsRef<Self>>(&self, rhs: &Rhs) -> Rgb<bool> where
    T: PartialOrd, 

Compares each element of two vectors with the partial greater-or-equal test, returning a boolean vector.

let u = Vec4::new(0,2,2,2);
let v = Vec4::new(0,1,2,3);
assert_eq!(u.partial_cmpge(&v), Vec4::new(true, true, true, false));

pub fn partial_cmpgt<Rhs: AsRef<Self>>(&self, rhs: &Rhs) -> Rgb<bool> where
    T: PartialOrd, 

Compares each element of two vectors with the partial greater-than test, returning a boolean vector.

let u = Vec4::new(0,2,2,6);
let v = Vec4::new(0,1,2,3);
assert_eq!(u.partial_cmpgt(&v), Vec4::new(false, true, false, true));

pub fn partial_cmple<Rhs: AsRef<Self>>(&self, rhs: &Rhs) -> Rgb<bool> where
    T: PartialOrd, 

Compares each element of two vectors with the partial less-or-equal test, returning a boolean vector.

let u = Vec4::new(0,2,2,2);
let v = Vec4::new(0,1,2,3);
assert_eq!(u.partial_cmple(&v), Vec4::new(true, false, true, true));

pub fn partial_cmplt<Rhs: AsRef<Self>>(&self, rhs: &Rhs) -> Rgb<bool> where
    T: PartialOrd, 

Compares each element of two vectors with the partial less-than test, returning a boolean vector.

let u = Vec4::new(0,2,2,2);
let v = Vec4::new(0,1,2,3);
assert_eq!(u.partial_cmplt(&v), Vec4::new(false, false, false, true));

pub fn cmpeq<Rhs: AsRef<Self>>(&self, rhs: &Rhs) -> Rgb<bool> where
    T: Eq, 

Compares each element of two vectors with the partial equality test, returning a boolean vector.

let u = Vec4::new(0,2,2,6);
let v = Vec4::new(0,1,2,3);
assert_eq!(u.cmpeq(&v), Vec4::new(true, false, true, false));

pub fn cmpne<Rhs: AsRef<Self>>(&self, rhs: &Rhs) -> Rgb<bool> where
    T: Eq, 

Compares each element of two vectors with the total not-equal test, returning a boolean vector.

let u = Vec4::new(0,2,2,6);
let v = Vec4::new(0,1,2,3);
assert_eq!(u.cmpne(&v), Vec4::new(false, true, false, true));

pub fn cmpge<Rhs: AsRef<Self>>(&self, rhs: &Rhs) -> Rgb<bool> where
    T: Ord, 

Compares each element of two vectors with the total greater-or-equal test, returning a boolean vector.

let u = Vec4::new(0,2,2,2);
let v = Vec4::new(0,1,2,3);
assert_eq!(u.cmpge(&v), Vec4::new(true, true, true, false));

pub fn cmpgt<Rhs: AsRef<Self>>(&self, rhs: &Rhs) -> Rgb<bool> where
    T: Ord, 

Compares each element of two vectors with the total greater-than test, returning a boolean vector.

let u = Vec4::new(0,2,2,6);
let v = Vec4::new(0,1,2,3);
assert_eq!(u.cmpgt(&v), Vec4::new(false, true, false, true));

pub fn cmple<Rhs: AsRef<Self>>(&self, rhs: &Rhs) -> Rgb<bool> where
    T: Ord, 

Compares each element of two vectors with the total less-or-equal test, returning a boolean vector.

let u = Vec4::new(0,2,2,2);
let v = Vec4::new(0,1,2,3);
assert_eq!(u.cmple(&v), Vec4::new(true, false, true, true));

pub fn cmplt<Rhs: AsRef<Self>>(&self, rhs: &Rhs) -> Rgb<bool> where
    T: Ord, 

Compares each element of two vectors with the total less-than test, returning a boolean vector.

let u = Vec4::new(0,2,2,2);
let v = Vec4::new(0,1,2,3);
assert_eq!(u.cmplt(&v), Vec4::new(false, false, false, true));

pub fn lerp_unclamped_precise<S: Into<Self>>(
    from: Self,
    to: Self,
    factor: S
) -> Self where
    T: Copy + One + Mul<Output = T> + Sub<Output = T> + MulAdd<T, T, Output = T>, 

Returns the linear interpolation of from to to with factor unconstrained. See the Lerp trait.

pub fn lerp_unclamped<S: Into<Self>>(from: Self, to: Self, factor: S) -> Self where
    T: Copy + Sub<Output = T> + MulAdd<T, T, Output = T>, 

Same as lerp_unclamped_precise, implemented as a possibly faster but less precise operation. See the Lerp trait.

pub fn lerp<S: Into<Self> + Clamp + Zero + One>(
    from: Self,
    to: Self,
    factor: S
) -> Self where
    T: Copy + Sub<Output = T> + MulAdd<T, T, Output = T>, 

Returns the linear interpolation of from to to with factor constrained to be between 0 and 1. See the Lerp trait.

pub fn lerp_precise<S: Into<Self> + Clamp + Zero + One>(
    from: Self,
    to: Self,
    factor: S
) -> Self where
    T: Copy + One + Mul<Output = T> + Sub<Output = T> + MulAdd<T, T, Output = T>, 

Returns the linear interpolation of from to to with factor constrained to be between 0 and 1. See the Lerp trait.

impl Rgb<bool>

pub fn reduce_and(self) -> bool

Returns the result of logical AND (&&) on all elements of this vector.

assert_eq!(true,  Vec4::new(true, true, true, true).reduce_and());
assert_eq!(false, Vec4::new(true, false, true, true).reduce_and());
assert_eq!(false, Vec4::new(true, true, true, false).reduce_and());

pub fn reduce_or(self) -> bool

Returns the result of logical OR (||) on all elements of this vector.

assert_eq!(false, Vec4::new(false, false, false, false).reduce_or());
assert_eq!(true,  Vec4::new(false, false, true, false).reduce_or());

pub fn reduce_ne(self) -> bool

Reduces this vector using total inequality.

assert_eq!(false, Vec4::new(true, true, true, true).reduce_ne());
assert_eq!(true,  Vec4::new(true, false, true, true).reduce_ne());

impl<T> Rgb<T>

pub fn into_repr_c(self) -> CVec<T>

Converts this vector into its #[repr(C)] counterpart.

impl<T: ColorComponent> Rgb<T>

pub fn black() -> Self

pub fn white() -> Self

pub fn red() -> Self

pub fn green() -> Self

pub fn blue() -> Self

pub fn cyan() -> Self

pub fn magenta() -> Self

pub fn yellow() -> Self

pub fn gray(value: T) -> Self where
    T: Copy, 

pub fn grey(value: T) -> Self where
    T: Copy, 

pub fn inverted_rgb(self) -> Self where
    T: Sub<Output = T>, 

Returns this color with RGB elements inverted.

let orange = Rgb::new(255_u8, 128, 0);
assert_eq!(orange.inverted_rgb(), Rgb::new(0, 127, 255));
assert_eq!(Rgb::<u8>::black().inverted_rgb(), Rgb::white());
assert_eq!(Rgb::<u8>::white().inverted_rgb(), Rgb::black());
assert_eq!(Rgb::<u8>::red().inverted_rgb(), Rgb::cyan());

pub fn average_rgb(self) -> T where
    T: Sum + Div<T, Output = T> + From<u8>, 

Returns the average of this vector's RGB elements.

For Rgb, this is the same as average, and is provided for compatibility with Rgba. Be careful when calling this on integer vectors. See the average() method of vectors for a discussion and example.

impl<T> Rgb<T>

pub fn shuffled_bgr(self) -> Self

Returns this vector with R and B elements swapped.

Trait Implementations

impl<T: IsBetween<Output = bool> + Copy> IsBetween<T> for Rgb<T>

type Output = Rgb<bool>

bool for scalars, or vector of bools for vectors.

fn is_between(self, lower: T, upper: T) -> Self::Output

Returns whether this value is between lower and upper (inclusive).

fn is_between01(self) -> Self::Output where
    Bound: Zero + One, 

Returns whether this value is between 0 and 1 (inclusive).

impl<T: IsBetween<Output = bool>> IsBetween<Rgb<T>> for Rgb<T>

type Output = Rgb<bool>

bool for scalars, or vector of bools for vectors.

fn is_between(self, lower: Self, upper: Self) -> Self::Output

Returns whether this value is between lower and upper (inclusive).

fn is_between01(self) -> Self::Output where
    Bound: Zero + One, 

Returns whether this value is between 0 and 1 (inclusive).

impl<T: Clamp + Copy> Clamp<T> for Rgb<T>

fn clamped(self, lower: T, upper: T) -> Self

Constrains this value to be between lower and upper (inclusive).

fn clamp(val: Self, lower: Bound, upper: Bound) -> Self

Alias to clamped, which doesn't take self.

fn clamped01(self) -> Self where
    Bound: Zero + One, 

Constrains this value to be between 0 and 1 (inclusive).

fn clamp01(val: Self) -> Self where
    Bound: Zero + One, 

Alias to clamped01, which doesn't take self.

impl<T: Clamp> Clamp<Rgb<T>> for Rgb<T>

fn clamped(self, lower: Self, upper: Self) -> Self

Constrains this value to be between lower and upper (inclusive).

fn clamp(val: Self, lower: Bound, upper: Bound) -> Self

Alias to clamped, which doesn't take self.

fn clamped01(self) -> Self where
    Bound: Zero + One, 

Constrains this value to be between 0 and 1 (inclusive).

fn clamp01(val: Self) -> Self where
    Bound: Zero + One, 

Alias to clamped01, which doesn't take self.

impl<T> MulAdd<Rgb<T>, Rgb<T>> for Rgb<T> where
    T: MulAdd<T, T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the fused multiply-add operation.

fn mul_add(self, a: Rgb<T>, b: Rgb<T>) -> Self::Output

Returns (self * mul) + add as a possibly faster and more precise single operation.

impl<'c, T> MulAdd<Rgb<T>, Rgb<T>> for &'c Rgb<T> where
    &'c T: MulAdd<T, T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the fused multiply-add operation.

fn mul_add(self, a: Rgb<T>, b: Rgb<T>) -> Self::Output

Returns (self * mul) + add as a possibly faster and more precise single operation.

impl<'b, T> MulAdd<Rgb<T>, &'b Rgb<T>> for Rgb<T> where
    T: MulAdd<T, &'b T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the fused multiply-add operation.

fn mul_add(self, a: Rgb<T>, b: &'b Rgb<T>) -> Self::Output

Returns (self * mul) + add as a possibly faster and more precise single operation.

impl<'b, 'c, T> MulAdd<Rgb<T>, &'b Rgb<T>> for &'c Rgb<T> where
    &'c T: MulAdd<T, &'b T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the fused multiply-add operation.

fn mul_add(self, a: Rgb<T>, b: &'b Rgb<T>) -> Self::Output

Returns (self * mul) + add as a possibly faster and more precise single operation.

impl<'a, T> MulAdd<&'a Rgb<T>, Rgb<T>> for Rgb<T> where
    T: MulAdd<&'a T, T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the fused multiply-add operation.

fn mul_add(self, a: &'a Rgb<T>, b: Rgb<T>) -> Self::Output

Returns (self * mul) + add as a possibly faster and more precise single operation.

impl<'a, 'c, T> MulAdd<&'a Rgb<T>, Rgb<T>> for &'c Rgb<T> where
    &'c T: MulAdd<&'a T, T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the fused multiply-add operation.

fn mul_add(self, a: &'a Rgb<T>, b: Rgb<T>) -> Self::Output

Returns (self * mul) + add as a possibly faster and more precise single operation.

impl<'a, 'b, T> MulAdd<&'a Rgb<T>, &'b Rgb<T>> for Rgb<T> where
    T: MulAdd<&'a T, &'b T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the fused multiply-add operation.

fn mul_add(self, a: &'a Rgb<T>, b: &'b Rgb<T>) -> Self::Output

Returns (self * mul) + add as a possibly faster and more precise single operation.

impl<'a, 'b, 'c, T> MulAdd<&'a Rgb<T>, &'b Rgb<T>> for &'c Rgb<T> where
    &'c T: MulAdd<&'a T, &'b T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the fused multiply-add operation.

fn mul_add(self, a: &'a Rgb<T>, b: &'b Rgb<T>) -> Self::Output

Returns (self * mul) + add as a possibly faster and more precise single operation.

impl<T, Factor> Lerp<Factor> for Rgb<T> where
    T: Lerp<Factor, Output = T>,
    Factor: Copy, 

type Output = Self

The resulting type after performing the LERP operation.

fn lerp_unclamped_precise(from: Self, to: Self, factor: Factor) -> Self

Returns the linear interpolation of from to to with factor unconstrained, using a possibly slower but more precise operation.

fn lerp_unclamped(from: Self, to: Self, factor: Factor) -> Self

Returns the linear interpolation of from to to with factor unconstrained, using the supposedly fastest but less precise implementation.

fn lerp(from: Self, to: Self, factor: Factor) -> Self::Output where
    Factor: Clamp + Zero + One, 

Alias to lerp_unclamped which constrains factor to be between 0 and 1 (inclusive).

fn lerp_precise(from: Self, to: Self, factor: Factor) -> Self::Output where
    Factor: Clamp + Zero + One, 

Alias to lerp_unclamped_precise which constrains factor to be between 0 and 1 (inclusive).

impl<'a, T, Factor> Lerp<Factor> for &'a Rgb<T> where
    &'a T: Lerp<Factor, Output = T>,
    Factor: Copy, 

type Output = Rgb<T>

The resulting type after performing the LERP operation.

fn lerp_unclamped_precise(from: Self, to: Self, factor: Factor) -> Rgb<T>

Returns the linear interpolation of from to to with factor unconstrained, using a possibly slower but more precise operation.

fn lerp_unclamped(from: Self, to: Self, factor: Factor) -> Rgb<T>

Returns the linear interpolation of from to to with factor unconstrained, using the supposedly fastest but less precise implementation.

fn lerp(from: Self, to: Self, factor: Factor) -> Self::Output where
    Factor: Clamp + Zero + One, 

Alias to lerp_unclamped which constrains factor to be between 0 and 1 (inclusive).

fn lerp_precise(from: Self, to: Self, factor: Factor) -> Self::Output where
    Factor: Clamp + Zero + One, 

Alias to lerp_unclamped_precise which constrains factor to be between 0 and 1 (inclusive).

impl<T: Wrap + Copy> Wrap<T> for Rgb<T>

fn wrapped(self, upper: T) -> Self

Returns this value, wrapped between zero and some upper bound (both inclusive).

fn wrapped_between(self, lower: T, upper: T) -> Self

Returns this value, wrapped between lower (inclusive) and upper (exclusive).

fn pingpong(self, upper: T) -> Self

Wraps a value such that it goes back and forth from zero to upper (inclusive) as it increases.

fn wrap(val: Self, upper: Bound) -> Self

Alias to wrapped() which doesn't take self.

fn wrapped_2pi(self) -> Self where
    Bound: FloatConst + Add<Output = Bound>, 

Returns this value, wrapped between zero and two times 𝛑 (inclusive).

fn wrap_2pi(val: Self) -> Self where
    Bound: FloatConst + Add<Output = Bound>, 

Alias to wrapped_2pi which doesn't take self.

fn wrap_between(val: Self, lower: Bound, upper: Bound) -> Self where
    Self: Sub<Output = Self> + Add<Output = Self> + From<Bound>,
    Bound: Copy + Sub<Output = Bound> + PartialOrd, 

Alias to wrapped_between which doesn't take self.

fn delta_angle(self, target: Self) -> Self where
    Self: From<Bound> + Sub<Output = Self> + PartialOrd,
    Bound: FloatConst + Add<Output = Bound>, 

Calculates the shortest difference between two given angles, in radians.

fn delta_angle_degrees(self, target: Self) -> Self where
    Self: From<Bound> + Sub<Output = Self> + PartialOrd,
    Bound: From<u16>, 

Calculates the shortest difference between two given angles, in degrees.

impl<T: Wrap> Wrap<Rgb<T>> for Rgb<T>

fn wrapped(self, upper: Rgb<T>) -> Self

Returns this value, wrapped between zero and some upper bound (both inclusive).

fn wrapped_between(self, lower: Self, upper: Self) -> Self

Returns this value, wrapped between lower (inclusive) and upper (exclusive).

fn pingpong(self, upper: Self) -> Self

Wraps a value such that it goes back and forth from zero to upper (inclusive) as it increases.

fn wrap(val: Self, upper: Bound) -> Self

Alias to wrapped() which doesn't take self.

fn wrapped_2pi(self) -> Self where
    Bound: FloatConst + Add<Output = Bound>, 

Returns this value, wrapped between zero and two times 𝛑 (inclusive).

fn wrap_2pi(val: Self) -> Self where
    Bound: FloatConst + Add<Output = Bound>, 

Alias to wrapped_2pi which doesn't take self.

fn wrap_between(val: Self, lower: Bound, upper: Bound) -> Self where
    Self: Sub<Output = Self> + Add<Output = Self> + From<Bound>,
    Bound: Copy + Sub<Output = Bound> + PartialOrd, 

Alias to wrapped_between which doesn't take self.

fn delta_angle(self, target: Self) -> Self where
    Self: From<Bound> + Sub<Output = Self> + PartialOrd,
    Bound: FloatConst + Add<Output = Bound>, 

Calculates the shortest difference between two given angles, in radians.

fn delta_angle_degrees(self, target: Self) -> Self where
    Self: From<Bound> + Sub<Output = Self> + PartialOrd,
    Bound: From<u16>, 

Calculates the shortest difference between two given angles, in degrees.

impl<T> DerefMut for Rgb<T>

fn deref_mut(&mut self) -> &mut [T]

Mutably dereferences the value.

impl<T> Deref for Rgb<T>

type Target = [T]

The resulting type after dereferencing.

fn deref(&self) -> &[T]

Dereferences the value.

impl<T: Display> Display for Rgb<T>

Displays the vector, formatted as rgb({}, {}, {}).

fn fmt(&self, f: &mut Formatter) -> Result

Formats the value using the given formatter.

impl<T: Debug> Debug for Rgb<T>

fn fmt(&self, f: &mut Formatter) -> Result

Formats the value using the given formatter.

impl<V, T> Div<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: Div<T, Output = T>, 

type Output = Self

The resulting type after applying the / operator.

fn div(self, rhs: V) -> Self::Output

Performs the / operation.

impl<'a, T> Div<&'a Rgb<T>> for Rgb<T> where
    T: Div<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the / operator.

fn div(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the / operation.

impl<'a, T> Div<Rgb<T>> for &'a Rgb<T> where
    &'a T: Div<T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the / operator.

fn div(self, rhs: Rgb<T>) -> Self::Output

Performs the / operation.

impl<'a, 'b, T> Div<&'a Rgb<T>> for &'b Rgb<T> where
    &'b T: Div<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the / operator.

fn div(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the / operation.

impl<'a, T> Div<T> for &'a Rgb<T> where
    &'a T: Div<T, Output = T>,
    T: Copy, 

type Output = Rgb<T>

The resulting type after applying the / operator.

fn div(self, rhs: T) -> Self::Output

Performs the / operation.

impl<'a, 'b, T> Div<&'a T> for &'b Rgb<T> where
    &'b T: Div<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the / operator.

fn div(self, rhs: &'a T) -> Self::Output

Performs the / operation.

impl<V, T> Rem<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: Rem<T, Output = T>, 

type Output = Self

The resulting type after applying the % operator.

fn rem(self, rhs: V) -> Self::Output

Performs the % operation.

impl<'a, T> Rem<&'a Rgb<T>> for Rgb<T> where
    T: Rem<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the % operator.

fn rem(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the % operation.

impl<'a, T> Rem<Rgb<T>> for &'a Rgb<T> where
    &'a T: Rem<T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the % operator.

fn rem(self, rhs: Rgb<T>) -> Self::Output

Performs the % operation.

impl<'a, 'b, T> Rem<&'a Rgb<T>> for &'b Rgb<T> where
    &'b T: Rem<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the % operator.

fn rem(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the % operation.

impl<'a, T> Rem<T> for &'a Rgb<T> where
    &'a T: Rem<T, Output = T>,
    T: Copy, 

type Output = Rgb<T>

The resulting type after applying the % operator.

fn rem(self, rhs: T) -> Self::Output

Performs the % operation.

impl<'a, 'b, T> Rem<&'a T> for &'b Rgb<T> where
    &'b T: Rem<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the % operator.

fn rem(self, rhs: &'a T) -> Self::Output

Performs the % operation.

impl<T: PartialEq> PartialEq<Rgb<T>> for Rgb<T>

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

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

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

This method tests for !=.

impl<T: Eq> Eq for Rgb<T>

impl<V, T> Add<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: Add<T, Output = T>, 

type Output = Self

The resulting type after applying the + operator.

fn add(self, rhs: V) -> Self::Output

Performs the + operation.

impl<'a, T> Add<&'a Rgb<T>> for Rgb<T> where
    T: Add<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the + operator.

fn add(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the + operation.

impl<'a, T> Add<Rgb<T>> for &'a Rgb<T> where
    &'a T: Add<T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the + operator.

fn add(self, rhs: Rgb<T>) -> Self::Output

Performs the + operation.

impl<'a, 'b, T> Add<&'a Rgb<T>> for &'b Rgb<T> where
    &'b T: Add<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the + operator.

fn add(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the + operation.

impl<'a, T> Add<T> for &'a Rgb<T> where
    &'a T: Add<T, Output = T>,
    T: Copy, 

type Output = Rgb<T>

The resulting type after applying the + operator.

fn add(self, rhs: T) -> Self::Output

Performs the + operation.

impl<'a, 'b, T> Add<&'a T> for &'b Rgb<T> where
    &'b T: Add<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the + operator.

fn add(self, rhs: &'a T) -> Self::Output

Performs the + operation.

impl Add<Rgb<i8>> for i8

type Output = Rgb<i8>

The resulting type after applying the + operator.

fn add(self, rhs: Rgb<i8>) -> Self::Output

Performs the + operation.

impl Add<Rgb<u8>> for u8

type Output = Rgb<u8>

The resulting type after applying the + operator.

fn add(self, rhs: Rgb<u8>) -> Self::Output

Performs the + operation.

impl Add<Rgb<i16>> for i16

type Output = Rgb<i16>

The resulting type after applying the + operator.

fn add(self, rhs: Rgb<i16>) -> Self::Output

Performs the + operation.

impl Add<Rgb<u16>> for u16

type Output = Rgb<u16>

The resulting type after applying the + operator.

fn add(self, rhs: Rgb<u16>) -> Self::Output

Performs the + operation.

impl Add<Rgb<i32>> for i32

type Output = Rgb<i32>

The resulting type after applying the + operator.

fn add(self, rhs: Rgb<i32>) -> Self::Output

Performs the + operation.

impl Add<Rgb<u32>> for u32

type Output = Rgb<u32>

The resulting type after applying the + operator.

fn add(self, rhs: Rgb<u32>) -> Self::Output

Performs the + operation.

impl Add<Rgb<i64>> for i64

type Output = Rgb<i64>

The resulting type after applying the + operator.

fn add(self, rhs: Rgb<i64>) -> Self::Output

Performs the + operation.

impl Add<Rgb<u64>> for u64

type Output = Rgb<u64>

The resulting type after applying the + operator.

fn add(self, rhs: Rgb<u64>) -> Self::Output

Performs the + operation.

impl Add<Rgb<f32>> for f32

type Output = Rgb<f32>

The resulting type after applying the + operator.

fn add(self, rhs: Rgb<f32>) -> Self::Output

Performs the + operation.

impl Add<Rgb<f64>> for f64

type Output = Rgb<f64>

The resulting type after applying the + operator.

fn add(self, rhs: Rgb<f64>) -> Self::Output

Performs the + operation.

impl<V, T> Sub<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: Sub<T, Output = T>, 

type Output = Self

The resulting type after applying the - operator.

fn sub(self, rhs: V) -> Self::Output

Performs the - operation.

impl<'a, T> Sub<&'a Rgb<T>> for Rgb<T> where
    T: Sub<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the - operator.

fn sub(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the - operation.

impl<'a, T> Sub<Rgb<T>> for &'a Rgb<T> where
    &'a T: Sub<T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the - operator.

fn sub(self, rhs: Rgb<T>) -> Self::Output

Performs the - operation.

impl<'a, 'b, T> Sub<&'a Rgb<T>> for &'b Rgb<T> where
    &'b T: Sub<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the - operator.

fn sub(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the - operation.

impl<'a, T> Sub<T> for &'a Rgb<T> where
    &'a T: Sub<T, Output = T>,
    T: Copy, 

type Output = Rgb<T>

The resulting type after applying the - operator.

fn sub(self, rhs: T) -> Self::Output

Performs the - operation.

impl<'a, 'b, T> Sub<&'a T> for &'b Rgb<T> where
    &'b T: Sub<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the - operator.

fn sub(self, rhs: &'a T) -> Self::Output

Performs the - operation.

impl<V, T> Mul<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: Mul<T, Output = T>, 

type Output = Self

The resulting type after applying the * operator.

fn mul(self, rhs: V) -> Self::Output

Performs the * operation.

impl<'a, T> Mul<&'a Rgb<T>> for Rgb<T> where
    T: Mul<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the * operator.

fn mul(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the * operation.

impl<'a, T> Mul<Rgb<T>> for &'a Rgb<T> where
    &'a T: Mul<T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the * operator.

fn mul(self, rhs: Rgb<T>) -> Self::Output

Performs the * operation.

impl<'a, 'b, T> Mul<&'a Rgb<T>> for &'b Rgb<T> where
    &'b T: Mul<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the * operator.

fn mul(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the * operation.

impl<'a, T> Mul<T> for &'a Rgb<T> where
    &'a T: Mul<T, Output = T>,
    T: Copy, 

type Output = Rgb<T>

The resulting type after applying the * operator.

fn mul(self, rhs: T) -> Self::Output

Performs the * operation.

impl<'a, 'b, T> Mul<&'a T> for &'b Rgb<T> where
    &'b T: Mul<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the * operator.

fn mul(self, rhs: &'a T) -> Self::Output

Performs the * operation.

impl Mul<Rgb<i8>> for i8

type Output = Rgb<i8>

The resulting type after applying the * operator.

fn mul(self, rhs: Rgb<i8>) -> Self::Output

Performs the * operation.

impl Mul<Rgb<u8>> for u8

type Output = Rgb<u8>

The resulting type after applying the * operator.

fn mul(self, rhs: Rgb<u8>) -> Self::Output

Performs the * operation.

impl Mul<Rgb<i16>> for i16

type Output = Rgb<i16>

The resulting type after applying the * operator.

fn mul(self, rhs: Rgb<i16>) -> Self::Output

Performs the * operation.

impl Mul<Rgb<u16>> for u16

type Output = Rgb<u16>

The resulting type after applying the * operator.

fn mul(self, rhs: Rgb<u16>) -> Self::Output

Performs the * operation.

impl Mul<Rgb<i32>> for i32

type Output = Rgb<i32>

The resulting type after applying the * operator.

fn mul(self, rhs: Rgb<i32>) -> Self::Output

Performs the * operation.

impl Mul<Rgb<u32>> for u32

type Output = Rgb<u32>

The resulting type after applying the * operator.

fn mul(self, rhs: Rgb<u32>) -> Self::Output

Performs the * operation.

impl Mul<Rgb<i64>> for i64

type Output = Rgb<i64>

The resulting type after applying the * operator.

fn mul(self, rhs: Rgb<i64>) -> Self::Output

Performs the * operation.

impl Mul<Rgb<u64>> for u64

type Output = Rgb<u64>

The resulting type after applying the * operator.

fn mul(self, rhs: Rgb<u64>) -> Self::Output

Performs the * operation.

impl Mul<Rgb<f32>> for f32

type Output = Rgb<f32>

The resulting type after applying the * operator.

fn mul(self, rhs: Rgb<f32>) -> Self::Output

Performs the * operation.

impl Mul<Rgb<f64>> for f64

type Output = Rgb<f64>

The resulting type after applying the * operator.

fn mul(self, rhs: Rgb<f64>) -> Self::Output

Performs the * operation.

impl<T> Neg for Rgb<T> where
    T: Neg<Output = T>, 

type Output = Self

The resulting type after applying the - operator.

fn neg(self) -> Self::Output

Performs the unary - operation.

impl<V, T> AddAssign<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: AddAssign<T>, 

fn add_assign(&mut self, rhs: V)

Performs the += operation.

impl<V, T> SubAssign<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: SubAssign<T>, 

fn sub_assign(&mut self, rhs: V)

Performs the -= operation.

impl<V, T> MulAssign<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: MulAssign<T>, 

fn mul_assign(&mut self, rhs: V)

Performs the *= operation.

impl<V, T> DivAssign<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: DivAssign<T>, 

fn div_assign(&mut self, rhs: V)

Performs the /= operation.

impl<V, T> RemAssign<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: RemAssign<T>, 

fn rem_assign(&mut self, rhs: V)

Performs the %= operation.

impl<T> Not for Rgb<T> where
    T: Not<Output = T>, 

type Output = Self

The resulting type after applying the ! operator.

fn not(self) -> Self::Output

Performs the unary ! operation.

impl<V, T> BitAnd<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: BitAnd<T, Output = T>, 

type Output = Self

The resulting type after applying the & operator.

fn bitand(self, rhs: V) -> Self::Output

Performs the & operation.

impl<'a, T> BitAnd<&'a Rgb<T>> for Rgb<T> where
    T: BitAnd<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the & operator.

fn bitand(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the & operation.

impl<'a, T> BitAnd<Rgb<T>> for &'a Rgb<T> where
    &'a T: BitAnd<T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the & operator.

fn bitand(self, rhs: Rgb<T>) -> Self::Output

Performs the & operation.

impl<'a, 'b, T> BitAnd<&'a Rgb<T>> for &'b Rgb<T> where
    &'b T: BitAnd<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the & operator.

fn bitand(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the & operation.

impl<'a, T> BitAnd<T> for &'a Rgb<T> where
    &'a T: BitAnd<T, Output = T>,
    T: Copy, 

type Output = Rgb<T>

The resulting type after applying the & operator.

fn bitand(self, rhs: T) -> Self::Output

Performs the & operation.

impl<'a, 'b, T> BitAnd<&'a T> for &'b Rgb<T> where
    &'b T: BitAnd<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the & operator.

fn bitand(self, rhs: &'a T) -> Self::Output

Performs the & operation.

impl<V, T> BitOr<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: BitOr<T, Output = T>, 

type Output = Self

The resulting type after applying the | operator.

fn bitor(self, rhs: V) -> Self::Output

Performs the | operation.

impl<'a, T> BitOr<&'a Rgb<T>> for Rgb<T> where
    T: BitOr<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the | operator.

fn bitor(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the | operation.

impl<'a, T> BitOr<Rgb<T>> for &'a Rgb<T> where
    &'a T: BitOr<T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the | operator.

fn bitor(self, rhs: Rgb<T>) -> Self::Output

Performs the | operation.

impl<'a, 'b, T> BitOr<&'a Rgb<T>> for &'b Rgb<T> where
    &'b T: BitOr<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the | operator.

fn bitor(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the | operation.

impl<'a, T> BitOr<T> for &'a Rgb<T> where
    &'a T: BitOr<T, Output = T>,
    T: Copy, 

type Output = Rgb<T>

The resulting type after applying the | operator.

fn bitor(self, rhs: T) -> Self::Output

Performs the | operation.

impl<'a, 'b, T> BitOr<&'a T> for &'b Rgb<T> where
    &'b T: BitOr<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the | operator.

fn bitor(self, rhs: &'a T) -> Self::Output

Performs the | operation.

impl<V, T> BitXor<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: BitXor<T, Output = T>, 

type Output = Self

The resulting type after applying the ^ operator.

fn bitxor(self, rhs: V) -> Self::Output

Performs the ^ operation.

impl<'a, T> BitXor<&'a Rgb<T>> for Rgb<T> where
    T: BitXor<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the ^ operator.

fn bitxor(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the ^ operation.

impl<'a, T> BitXor<Rgb<T>> for &'a Rgb<T> where
    &'a T: BitXor<T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the ^ operator.

fn bitxor(self, rhs: Rgb<T>) -> Self::Output

Performs the ^ operation.

impl<'a, 'b, T> BitXor<&'a Rgb<T>> for &'b Rgb<T> where
    &'b T: BitXor<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the ^ operator.

fn bitxor(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the ^ operation.

impl<'a, T> BitXor<T> for &'a Rgb<T> where
    &'a T: BitXor<T, Output = T>,
    T: Copy, 

type Output = Rgb<T>

The resulting type after applying the ^ operator.

fn bitxor(self, rhs: T) -> Self::Output

Performs the ^ operation.

impl<'a, 'b, T> BitXor<&'a T> for &'b Rgb<T> where
    &'b T: BitXor<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the ^ operator.

fn bitxor(self, rhs: &'a T) -> Self::Output

Performs the ^ operation.

impl<V, T> Shl<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: Shl<T, Output = T>, 

type Output = Self

The resulting type after applying the << operator.

fn shl(self, rhs: V) -> Self::Output

Performs the << operation.

impl<'a, T> Shl<&'a Rgb<T>> for Rgb<T> where
    T: Shl<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the << operator.

fn shl(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the << operation.

impl<'a, T> Shl<Rgb<T>> for &'a Rgb<T> where
    &'a T: Shl<T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the << operator.

fn shl(self, rhs: Rgb<T>) -> Self::Output

Performs the << operation.

impl<'a, 'b, T> Shl<&'a Rgb<T>> for &'b Rgb<T> where
    &'b T: Shl<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the << operator.

fn shl(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the << operation.

impl<'a, T> Shl<T> for &'a Rgb<T> where
    &'a T: Shl<T, Output = T>,
    T: Copy, 

type Output = Rgb<T>

The resulting type after applying the << operator.

fn shl(self, rhs: T) -> Self::Output

Performs the << operation.

impl<'a, 'b, T> Shl<&'a T> for &'b Rgb<T> where
    &'b T: Shl<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the << operator.

fn shl(self, rhs: &'a T) -> Self::Output

Performs the << operation.

impl<V, T> Shr<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: Shr<T, Output = T>, 

type Output = Self

The resulting type after applying the >> operator.

fn shr(self, rhs: V) -> Self::Output

Performs the >> operation.

impl<'a, T> Shr<&'a Rgb<T>> for Rgb<T> where
    T: Shr<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the >> operator.

fn shr(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the >> operation.

impl<'a, T> Shr<Rgb<T>> for &'a Rgb<T> where
    &'a T: Shr<T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the >> operator.

fn shr(self, rhs: Rgb<T>) -> Self::Output

Performs the >> operation.

impl<'a, 'b, T> Shr<&'a Rgb<T>> for &'b Rgb<T> where
    &'b T: Shr<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the >> operator.

fn shr(self, rhs: &'a Rgb<T>) -> Self::Output

Performs the >> operation.

impl<'a, T> Shr<T> for &'a Rgb<T> where
    &'a T: Shr<T, Output = T>,
    T: Copy, 

type Output = Rgb<T>

The resulting type after applying the >> operator.

fn shr(self, rhs: T) -> Self::Output

Performs the >> operation.

impl<'a, 'b, T> Shr<&'a T> for &'b Rgb<T> where
    &'b T: Shr<&'a T, Output = T>, 

type Output = Rgb<T>

The resulting type after applying the >> operator.

fn shr(self, rhs: &'a T) -> Self::Output

Performs the >> operation.

impl<V, T> BitAndAssign<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: BitAndAssign<T>, 

fn bitand_assign(&mut self, rhs: V)

Performs the &= operation.

impl<V, T> BitOrAssign<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: BitOrAssign<T>, 

fn bitor_assign(&mut self, rhs: V)

Performs the |= operation.

impl<V, T> BitXorAssign<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: BitXorAssign<T>, 

fn bitxor_assign(&mut self, rhs: V)

Performs the ^= operation.

impl<V, T> ShlAssign<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: ShlAssign<T>, 

fn shl_assign(&mut self, rhs: V)

Performs the <<= operation.

impl<V, T> ShrAssign<V> for Rgb<T> where
    V: Into<Rgb<T>>,
    T: ShrAssign<T>, 

fn shr_assign(&mut self, rhs: V)

Performs the >>= operation.

impl<T: Hash> Hash for Rgb<T>

fn hash<__H: Hasher>(&self, state: &mut __H)

Feeds this value into the given [Hasher].

fn hash_slice<H>(data: &[Self], state: &mut H) where
    H: Hasher, 

Feeds a slice of this type into the given [Hasher].

impl<T> Sum<Rgb<T>> for Rgb<T> where
    T: Add<T, Output = T> + Zero, 

fn sum<I: Iterator<Item = Rgb<T>>>(iter: I) -> Rgb<T>

Method which takes an iterator and generates Self from the elements by "summing up" the items.

impl<T> Product<Rgb<T>> for Rgb<T> where
    T: Mul<T, Output = T> + One, 

fn product<I: Iterator<Item = Rgb<T>>>(iter: I) -> Rgb<T>

Method which takes an iterator and generates Self from the elements by multiplying the items.

impl<'a, T> IntoIterator for &'a Rgb<T>

type Item = &'a T

The type of the elements being iterated over.

type IntoIter = Iter<'a, T>

Which kind of iterator are we turning this into?

fn into_iter(self) -> Self::IntoIter

Creates an iterator from a value.

impl<'a, T> IntoIterator for &'a mut Rgb<T>

type Item = &'a mut T

The type of the elements being iterated over.

type IntoIter = IterMut<'a, T>

Which kind of iterator are we turning this into?

fn into_iter(self) -> Self::IntoIter

Creates an iterator from a value.

impl<T> IntoIterator for Rgb<T>

type Item = T

The type of the elements being iterated over.

type IntoIter = IntoIter<T>

Which kind of iterator are we turning this into?

fn into_iter(self) -> Self::IntoIter

Creates an iterator from a value.

impl<T: Copy> Copy for Rgb<T>

impl<T: Default> FromIterator<T> for Rgb<T>

fn from_iter<I>(iter: I) -> Self where
    I: IntoIterator<Item = T>, 

Creates a value from an iterator.

impl<T> AsRef<[T]> for Rgb<T>

fn as_ref(&self) -> &[T]

Performs the conversion.

impl<T> AsRef<Rgb<T>> for Rgb<T>

fn as_ref(&self) -> &Self

Performs the conversion.

impl<T> AsMut<[T]> for Rgb<T>

fn as_mut(&mut self) -> &mut [T]

Performs the conversion.

impl<T> AsMut<Rgb<T>> for Rgb<T>

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

Performs the conversion.

impl<T> From<Rgb<T>> for Vec3<T>

fn from(v: Rgb<T>) -> Self

Performs the conversion.

impl<T: ColorComponent> From<Rgb<T>> for Rgba<T>

fn from(v: Rgb<T>) -> Self

Performs the conversion.

impl<T> From<(T, T, T)> for Rgb<T>

fn from(tuple: (T, T, T)) -> Self

Performs the conversion.

impl<T> From<[T; 3]> for Rgb<T>

fn from(array: [T; 3]) -> Self

Performs the conversion.

impl<T: Copy> From<T> for Rgb<T>

A vector can be obtained from a single scalar by broadcasting it.

This conversion is important because it allows scalars to be smoothly accepted as operands in most vector operations.

For instance :

assert_eq!(Vec4::min(4, 5), Vec4::broadcast(4));
assert_eq!(Vec4::max(4, 5), Vec4::broadcast(5));
assert_eq!(Vec4::from(4), Vec4::broadcast(4));
assert_eq!(Vec4::from(4).mul_add(4, 5), Vec4::broadcast(21));

// scaling_3d() logically accepts a Vec3...
let _ = Mat4::<f32>::scaling_3d(Vec3::broadcast(5.0));
// ... but there you go; quick uniform scale, thanks to Into !
let _ = Mat4::scaling_3d(5_f32);

On the other hand, it also allows writing nonsense. To minimize surprises, the names of operations try to be as explicit as possible.

// This creates a matrix that translates to (5,5,5), but it's probably not what you meant.
// Hopefully the `_3d` suffix would help you catch this.
let _ = Mat4::translation_3d(5_f32);
// translation_3d() takes V: Into<Vec3> because it allows it to accept
// Vec2, Vec3 and Vec4, and also with both repr(C) and repr(simd) layouts.

fn from(val: T) -> Self

Performs the conversion.

impl<T> From<Rgb<T>> for Rgb<T>

fn from(v: CVec<T>) -> Self

Performs the conversion.

impl<T> From<Rgb<T>> for CVec<T>

fn from(v: Rgb<T>) -> Self

Performs the conversion.

impl<T> From<Vec3<T>> for Rgb<T>

fn from(v: Vec3<T>) -> Self

Performs the conversion.

impl<T> From<Rgba<T>> for Rgb<T>

fn from(v: Rgba<T>) -> Self

Performs the conversion.

impl<T: Clone> Clone for Rgb<T>

fn clone(&self) -> Rgb<T>

Returns a copy of the value.

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

Performs copy-assignment from source.

impl<T: Default> Default for Rgb<T>

fn default() -> Rgb<T>

Returns the "default value" for a type.

impl<T> Borrow<[T]> for Rgb<T>

fn borrow(&self) -> &[T]

Immutably borrows from an owned value.

impl<T> BorrowMut<[T]> for Rgb<T>

fn borrow_mut(&mut self) -> &mut [T]

Mutably borrows from an owned value.

impl<T: Zero + PartialEq> Zero for Rgb<T>

fn zero() -> Self

Returns the additive identity element of Self, 0. # Purity

fn is_zero(&self) -> bool

Returns true if self is equal to the additive identity.

fn set_zero(&mut self)

Sets self to the additive identity element of Self, 0.

impl<T: One> One for Rgb<T>

fn one() -> Self

Returns the multiplicative identity element of Self, 1.

fn set_one(&mut self)

Sets self to the multiplicative identity element of Self, 1.

fn is_one(&self) -> bool where
    Self: PartialEq<Self>, 

Returns true if self is equal to the multiplicative identity.

impl<T: ApproxEq> ApproxEq for Rgb<T> where
    T::Epsilon: Copy, 

type Epsilon = T::Epsilon

Used for specifying relative comparisons.

fn default_epsilon() -> T::Epsilon

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

fn default_max_relative() -> T::Epsilon

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

fn default_max_ulps() -> u32

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

fn relative_eq(
    &self,
    other: &Self,
    epsilon: T::Epsilon,
    max_relative: T::Epsilon
) -> bool

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

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

The inverse of ApproxEq::relative_eq.

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

The inverse of ApproxEq::ulps_eq.