Fri, 02 Dec 2022 18:08:40 +0200
Remove ergodic tolerance; it's not useful.
//! Implementation of the indicator function of a ball with respect to various norms. use float_extras::f64::{tgamma as gamma}; use numeric_literals::replace_float_literals; use serde::Serialize; use alg_tools::types::*; use alg_tools::norms::*; use alg_tools::loc::Loc; use alg_tools::sets::Cube; use alg_tools::bisection_tree::{ Support, Constant, Bounds, LocalAnalysis, GlobalAnalysis, }; use alg_tools::mapping::Apply; use alg_tools::maputil::array_init; use alg_tools::coefficients::factorial; use super::base::*; /// Representation of the indicator of the ball $𝔹_q = \\{ x ∈ ℝ^N \mid \\|x\\|\_q ≤ r \\}$, /// where $q$ is the `Exponent`, and $r$ is the radius [`Constant`] `C`. #[derive(Copy,Clone,Serialize,Debug,Eq,PartialEq)] pub struct BallIndicator<C : Constant, Exponent : NormExponent, const N : usize> { /// The radius of the ball. pub r : C, /// The exponent $q$ of the norm creating the ball pub exponent : Exponent, } /// Alias for the representation of the indicator of the $∞$-norm-ball /// $𝔹_∞ = \\{ x ∈ ℝ^N \mid \\|x\\|\_∞ ≤ c \\}$. pub type CubeIndicator<C, const N : usize> = BallIndicator<C, Linfinity, N>; #[replace_float_literals(C::Type::cast_from(literal))] impl<'a, F : Float, C : Constant<Type=F>, Exponent : NormExponent, const N : usize> Apply<&'a Loc<C::Type, N>> for BallIndicator<C, Exponent, N> where Loc<F, N> : Norm<F, Exponent> { type Output = C::Type; #[inline] fn apply(&self, x : &'a Loc<C::Type, N>) -> Self::Output { let r = self.r.value(); let n = x.norm(self.exponent); if n <= r { 1.0 } else { 0.0 } } } impl<F : Float, C : Constant<Type=F>, Exponent : NormExponent, const N : usize> Apply<Loc<C::Type, N>> for BallIndicator<C, Exponent, N> where Loc<F, N> : Norm<F, Exponent> { type Output = C::Type; #[inline] fn apply(&self, x : Loc<C::Type, N>) -> Self::Output { self.apply(&x) } } impl<'a, F : Float, C : Constant<Type=F>, Exponent : NormExponent, const N : usize> Support<C::Type, N> for BallIndicator<C, Exponent, N> where Loc<F, N> : Norm<F, Exponent>, Linfinity : Dominated<F, Exponent, Loc<F, N>> { #[inline] fn support_hint(&self) -> Cube<F,N> { let r = Linfinity.from_norm(self.r.value(), self.exponent); array_init(|| [-r, r]).into() } #[inline] fn in_support(&self, x : &Loc<F,N>) -> bool { let r = Linfinity.from_norm(self.r.value(), self.exponent); x.norm(self.exponent) <= r } /// This can only really work in a reasonable fashion for N=1. #[inline] fn bisection_hint(&self, cube : &Cube<F, N>) -> [Option<F>; N] { let r = Linfinity.from_norm(self.r.value(), self.exponent); cube.map(|a, b| symmetric_interval_hint(r, a, b)) } } #[replace_float_literals(F::cast_from(literal))] impl<'a, F : Float, C : Constant<Type=F>, Exponent : NormExponent, const N : usize> GlobalAnalysis<F, Bounds<F>> for BallIndicator<C, Exponent, N> where Loc<F, N> : Norm<F, Exponent> { #[inline] fn global_analysis(&self) -> Bounds<F> { Bounds(0.0, 1.0) } } #[replace_float_literals(F::cast_from(literal))] impl<'a, F : Float, C : Constant<Type=F>, Exponent : NormExponent, const N : usize> Norm<F, Linfinity> for BallIndicator<C, Exponent, N> where Loc<F, N> : Norm<F, Exponent> { #[inline] fn norm(&self, _ : Linfinity) -> F { 1.0 } } #[replace_float_literals(F::cast_from(literal))] impl<'a, F : Float, C : Constant<Type=F>, const N : usize> Norm<F, L1> for BallIndicator<C, L1, N> { #[inline] fn norm(&self, _ : L1) -> F { // Using https://en.wikipedia.org/wiki/Volume_of_an_n-ball#Balls_in_Lp_norms, // we have V_N^1(r) = (2r)^N / N! let r = self.r.value(); if N==1 { 2.0 * r } else if N==2 { r*r } else { (2.0 * r).powi(N as i32) * F::cast_from(factorial(N)) } } } #[replace_float_literals(F::cast_from(literal))] impl<'a, F : Float, C : Constant<Type=F>, const N : usize> Norm<F, L1> for BallIndicator<C, L2, N> { #[inline] fn norm(&self, _ : L1) -> F { // See https://en.wikipedia.org/wiki/Volume_of_an_n-ball#The_volume. let r = self.r.value(); let π = F::PI; if N==1 { 2.0 * r } else if N==2 { π * (r * r) } else { let ndiv2 = F::cast_from(N) / 2.0; let γ = F::cast_from(gamma((ndiv2 + 1.0).as_())); π.powf(ndiv2) / γ * r.powi(N as i32) } } } #[replace_float_literals(F::cast_from(literal))] impl<'a, F : Float, C : Constant<Type=F>, const N : usize> Norm<F, L1> for BallIndicator<C, Linfinity, N> { #[inline] fn norm(&self, _ : L1) -> F { let two_r = 2.0 * self.r.value(); two_r.powi(N as i32) } } macro_rules! indicator_local_analysis { ($exponent:ident) => { impl<'a, F : Float, C : Constant<Type=F>, const N : usize> LocalAnalysis<F, Bounds<F>, N> for BallIndicator<C, $exponent, N> where Loc<F, N> : Norm<F, $exponent>, Linfinity : Dominated<F, $exponent, Loc<F, N>> { #[inline] fn local_analysis(&self, cube : &Cube<F, N>) -> Bounds<F> { // The function is maximised/minimised where the 2-norm is minimised/maximised. let lower = self.apply(cube.maxnorm_point()); let upper = self.apply(cube.minnorm_point()); Bounds(lower, upper) } } } } indicator_local_analysis!(L1); indicator_local_analysis!(L2); indicator_local_analysis!(Linfinity); #[replace_float_literals(F::cast_from(literal))] impl<'a, F : Float, R, const N : usize> Apply<&'a Loc<F, N>> for AutoConvolution<CubeIndicator<R, N>> where R : Constant<Type=F> { type Output = F; #[inline] fn apply(&self, y : &'a Loc<F, N>) -> F { let two_r = 2.0 * self.0.r.value(); // This is just a product of one-dimensional versions y.iter().map(|&x| { 0.0.max(two_r - x.abs()) }).product() } } impl<F : Float, R, const N : usize> Apply<Loc<F, N>> for AutoConvolution<CubeIndicator<R, N>> where R : Constant<Type=F> { type Output = F; #[inline] fn apply(&self, y : Loc<F, N>) -> F { self.apply(&y) } } #[replace_float_literals(F::cast_from(literal))] impl<F : Float, R, const N : usize> Support<F, N> for AutoConvolution<CubeIndicator<R, N>> where R : Constant<Type=F> { #[inline] fn support_hint(&self) -> Cube<F, N> { let two_r = 2.0 * self.0.r.value(); array_init(|| [-two_r, two_r]).into() } #[inline] fn in_support(&self, y : &Loc<F, N>) -> bool { let two_r = 2.0 * self.0.r.value(); y.iter().all(|x| x.abs() <= two_r) } #[inline] fn bisection_hint(&self, cube : &Cube<F, N>) -> [Option<F>; N] { let two_r = 2.0 * self.0.r.value(); cube.map(|c, d| symmetric_interval_hint(two_r, c, d)) } } #[replace_float_literals(F::cast_from(literal))] impl<F : Float, R, const N : usize> GlobalAnalysis<F, Bounds<F>> for AutoConvolution<CubeIndicator<R, N>> where R : Constant<Type=F> { #[inline] fn global_analysis(&self) -> Bounds<F> { Bounds(0.0, self.apply(Loc::ORIGIN)) } } impl<F : Float, R, const N : usize> LocalAnalysis<F, Bounds<F>, N> for AutoConvolution<CubeIndicator<R, N>> where R : Constant<Type=F> { #[inline] fn local_analysis(&self, cube : &Cube<F, N>) -> Bounds<F> { // The function is maximised/minimised where the absolute value is minimised/maximised. let lower = self.apply(cube.maxnorm_point()); let upper = self.apply(cube.minnorm_point()); Bounds(lower, upper) } }