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use crate::special::lanczos::{gamma_approx, ln_gamma_approx};
use std::f64::consts::PI;
/// Gaussian function
///
/// `N(x|μ,σ) = 1/√(2πσ^2) exp(-(x-μ)^2/(2σ^2))`
pub fn gaussian(x: f64, mu: f64, sigma: f64) -> f64 {
1f64 / ((2f64 * PI).sqrt() * sigma) * (-0.5 * ((x - mu) / sigma).powi(2)).exp()
}
/// Gamma function
///
/// # Description
/// Use Lanczos approximation to implement Gamma function ($g=5, n=7$)
///
/// # References
/// * [Robert Munafo, Coefficients for the Lanczos Approximation to the Gamma Function](https://mrob.com/pub/ries/lanczos-gamma.html)
/// * [Paul Godfrey, A note on the computation of the convergent Lanczos complex Gamma approximation (web page), 2001.](http://my.fit.edu/~gabdo/gamma.txt)
pub fn gamma(x: f64) -> f64 {
gamma_approx(x)
}
/// Logarithm Gamma function
///
/// # Description
/// Use Lanczos approximation to implement Gamma function ($g=5, n=7$)
///
/// # References
/// * [Robert Munafo, Coefficients for the Lanczos Approximation to the Gamma Function](https://mrob.com/pub/ries/lanczos-gamma.html)
/// * [Paul Godfrey, A note on the computation of the convergent Lanczos complex Gamma approximation (web page), 2001.](http://my.fit.edu/~gabdo/gamma.txt)
pub fn ln_gamma(x: f64) -> f64 {
ln_gamma_approx(x)
}
/// Pochhammer symbol
pub fn poch(x: f64, n: usize) -> f64 {
let mut s = 1f64;
for i in 0..n {
s *= x + i as f64;
}
s
}
// /// Digamma function
// ///
// /// Wrapper of `digamma` function of `special` crate
// pub fn digamma(x: f64) -> f64 {
// x.digamma()
// }
/// Regularized incomplete gamma integral (Lower)
///
/// Wrapper of `gammp` function of `puruspe` crate
pub fn inc_gamma(a: f64, x: f64) -> f64 {
puruspe::gammp(a, x)
}
/// Inverse of regularized incomplete gamma integral (Lower)
///
/// Wrapper of `invgammp` function of `puruspe` crate
pub fn inv_inc_gamma(p: f64, a: f64) -> f64 {
puruspe::invgammp(p, a)
}
/// Error function
///
/// Wrapper of `erf` function of `puruspe` crate
pub fn erf(x: f64) -> f64 {
puruspe::erf(x)
}
/// Complement error function
///
/// Wrapper of `erfc` function of `puruspe` crate
pub fn erfc(x: f64) -> f64 {
puruspe::erfc(x)
}
/// Inverse error function
///
/// Wrapper of `inverf` function of `puruspe` crate
pub fn inv_erf(x: f64) -> f64 {
puruspe::inverf(x)
}
/// Inverse complementary error function
///
/// Wrapper of `inverfc` function of `puruspe` crate
pub fn inv_erfc(p: f64) -> f64 {
puruspe::inverfc(p)
}
/// Beta function
///
/// Wrapper of `beta` function of `puruspe` crate
pub fn beta(a: f64, b: f64) -> f64 {
puruspe::beta(a, b)
}
/// Regularized incomplete Beta function
///
/// Wrapper of `betai` function of `puruspe` crate
pub fn inc_beta(a: f64, b: f64, x: f64) -> f64 {
puruspe::betai(a, b, x)
}
/// Inverse regularized incomplete beta function
///
/// Wrapper of `invbetai` function of `puruspe` crate
pub fn inv_inv_beta(p: f64, a: f64, b: f64) -> f64 {
puruspe::invbetai(p, a, b)
}
/// Phi (CDF for Normal Dist)
///
/// $$\Phi(x) = \frac{1}{2}\left[1 + \text{erf}\left(\frac{x}{\sqrt{2}}\right) \right]$$
pub fn phi(x: f64) -> f64 {
0.5 * (1f64 + erf(x / 2f64.sqrt()))
}
// /// Hypergeometric function 2F1
// ///
// /// Wrapper of `hyp2f1` function of `special-fun` crate
// pub fn hyp2f1(a: f64, b: f64, c: f64, x: f64) -> f64 {
// unsafe {
// special_fun::unsafe_cephes_double::hyp2f1(a, b, c, x)
// }
// }