// David Eberly, Geometric Tools, Redmond WA 98052
// Copyright (c) 1998-2020
// Distributed under the Boost Software License, Version 1.0.
// https://www.boost.org/LICENSE_1_0.txt
// https://www.geometrictools.com/License/Boost/LICENSE_1_0.txt
// Version: 4.0.2019.08.13
#pragma once
#include <Mathematics/Math.h>
// Minimax polynomial approximations to sin(x). The polynomial p(x) of
// degree D has only odd-power terms, is required to have linear term x,
// and p(pi/2) = sin(pi/2) = 1. It minimizes the quantity
// maximum{|sin(x) - p(x)| : x in [-pi/2,pi/2]} over all polynomials of
// degree D subject to the constraints mentioned.
namespace WwiseGTE
{
template <typename Real>
class SinEstimate
{
public:
// The input constraint is x in [-pi/2,pi/2]. For example,
// float x; // in [-pi/2,pi/2]
// float result = SinEstimate<float>::Degree<3>(x);
template <int D>
inline static Real Degree(Real x)
{
return Evaluate(degree<D>(), x);
}
// The input x can be any real number. Range reduction is used to
// generate a value y in [-pi/2,pi/2] for which sin(y) = sin(x).
// For example,
// float x; // x any real number
// float result = SinEstimate<float>::DegreeRR<3>(x);
template <int D>
inline static Real DegreeRR(Real x)
{
return Degree<D>(Reduce(x));
}
private:
// Metaprogramming and private implementation to allow specialization
// of a template member function.
template <int D> struct degree {};
inline static Real Evaluate(degree<3>, Real x)
{
Real xsqr = x * x;
Real poly;
poly = (Real)GTE_C_SIN_DEG3_C1;
poly = (Real)GTE_C_SIN_DEG3_C0 + poly * xsqr;
poly = poly * x;
return poly;
}
inline static Real Evaluate(degree<5>, Real x)
{
Real xsqr = x * x;
Real poly;
poly = (Real)GTE_C_SIN_DEG5_C2;
poly = (Real)GTE_C_SIN_DEG5_C1 + poly * xsqr;
poly = (Real)GTE_C_SIN_DEG5_C0 + poly * xsqr;
poly = poly * x;
return poly;
}
inline static Real Evaluate(degree<7>, Real x)
{
Real xsqr = x * x;
Real poly;
poly = (Real)GTE_C_SIN_DEG7_C3;
poly = (Real)GTE_C_SIN_DEG7_C2 + poly * xsqr;
poly = (Real)GTE_C_SIN_DEG7_C1 + poly * xsqr;
poly = (Real)GTE_C_SIN_DEG7_C0 + poly * xsqr;
poly = poly * x;
return poly;
}
inline static Real Evaluate(degree<9>, Real x)
{
Real xsqr = x * x;
Real poly;
poly = (Real)GTE_C_SIN_DEG9_C4;
poly = (Real)GTE_C_SIN_DEG9_C3 + poly * xsqr;
poly = (Real)GTE_C_SIN_DEG9_C2 + poly * xsqr;
poly = (Real)GTE_C_SIN_DEG9_C1 + poly * xsqr;
poly = (Real)GTE_C_SIN_DEG9_C0 + poly * xsqr;
poly = poly * x;
return poly;
}
inline static Real Evaluate(degree<11>, Real x)
{
Real xsqr = x * x;
Real poly;
poly = (Real)GTE_C_SIN_DEG11_C5;
poly = (Real)GTE_C_SIN_DEG11_C4 + poly * xsqr;
poly = (Real)GTE_C_SIN_DEG11_C3 + poly * xsqr;
poly = (Real)GTE_C_SIN_DEG11_C2 + poly * xsqr;
poly = (Real)GTE_C_SIN_DEG11_C1 + poly * xsqr;
poly = (Real)GTE_C_SIN_DEG11_C0 + poly * xsqr;
poly = poly * x;
return poly;
}
// Support for range reduction.
inline static Real Reduce(Real x)
{
// Map x to y in [-pi,pi], x = 2*pi*quotient + remainder.
Real quotient = (Real)GTE_C_INV_TWO_PI * x;
if (x >= (Real)0)
{
quotient = (Real)((int)(quotient + (Real)0.5));
}
else
{
quotient = (Real)((int)(quotient - (Real)0.5));
}
Real y = x - (Real)GTE_C_TWO_PI * quotient;
// Map y to [-pi/2,pi/2] with sin(y) = sin(x).
if (y > (Real)GTE_C_HALF_PI)
{
y = (Real)GTE_C_PI - y;
}
else if (y < (Real)-GTE_C_HALF_PI)
{
y = (Real)-GTE_C_PI - y;
}
return y;
}
};
}