boost/math/tools/minima.hpp
// (C) Copyright John Maddock 2006. // Use, modification and distribution are subject to the // Boost Software License, Version 1.0. (See accompanying file // LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt) #ifndef BOOST_MATH_TOOLS_MINIMA_HPP #define BOOST_MATH_TOOLS_MINIMA_HPP #ifdef _MSC_VER #pragma once #endif #include <cstdint> #include <cmath> #include <utility> #include <boost/math/tools/precision.hpp> #include <boost/math/policies/policy.hpp> namespace boost{ namespace math{ namespace tools{ template <class F, class T> std::pair<T, T> brent_find_minima(F f, T min, T max, int bits, std::uintmax_t& max_iter) noexcept(BOOST_MATH_IS_FLOAT(T) && noexcept(std::declval<F>()(std::declval<T>()))) { BOOST_MATH_STD_USING bits = (std::min)(policies::digits<T, policies::policy<> >() / 2, bits); T tolerance = static_cast<T>(ldexp(1.0, 1-bits)); T x; // minima so far T w; // second best point T v; // previous value of w T u; // most recent evaluation point T delta; // The distance moved in the last step T delta2; // The distance moved in the step before last T fu, fv, fw, fx; // function evaluations at u, v, w, x T mid; // midpoint of min and max T fract1, fract2; // minimal relative movement in x static const T golden = 0.3819660f; // golden ratio, don't need too much precision here! x = w = v = max; fw = fv = fx = f(x); delta2 = delta = 0; uintmax_t count = max_iter; do{ // get midpoint mid = (min + max) / 2; // work out if we're done already: fract1 = tolerance * fabs(x) + tolerance / 4; fract2 = 2 * fract1; if(fabs(x - mid) <= (fract2 - (max - min) / 2)) break; if(fabs(delta2) > fract1) { // try and construct a parabolic fit: T r = (x - w) * (fx - fv); T q = (x - v) * (fx - fw); T p = (x - v) * q - (x - w) * r; q = 2 * (q - r); if(q > 0) p = -p; q = fabs(q); T td = delta2; delta2 = delta; // determine whether a parabolic step is acceptable or not: if((fabs(p) >= fabs(q * td / 2)) || (p <= q * (min - x)) || (p >= q * (max - x))) { // nope, try golden section instead delta2 = (x >= mid) ? min - x : max - x; delta = golden * delta2; } else { // whew, parabolic fit: delta = p / q; u = x + delta; if(((u - min) < fract2) || ((max- u) < fract2)) delta = (mid - x) < 0 ? (T)-fabs(fract1) : (T)fabs(fract1); } } else { // golden section: delta2 = (x >= mid) ? min - x : max - x; delta = golden * delta2; } // update current position: u = (fabs(delta) >= fract1) ? T(x + delta) : (delta > 0 ? T(x + fabs(fract1)) : T(x - fabs(fract1))); fu = f(u); if(fu <= fx) { // good new point is an improvement! // update brackets: if(u >= x) min = x; else max = x; // update control points: v = w; w = x; x = u; fv = fw; fw = fx; fx = fu; } else { // Oh dear, point u is worse than what we have already, // even so it *must* be better than one of our endpoints: if(u < x) min = u; else max = u; if((fu <= fw) || (w == x)) { // however it is at least second best: v = w; w = u; fv = fw; fw = fu; } else if((fu <= fv) || (v == x) || (v == w)) { // third best: v = u; fv = fu; } } }while(--count); max_iter -= count; return std::make_pair(x, fx); } template <class F, class T> inline std::pair<T, T> brent_find_minima(F f, T min, T max, int digits) noexcept(BOOST_MATH_IS_FLOAT(T) && noexcept(std::declval<F>()(std::declval<T>()))) { std::uintmax_t m = (std::numeric_limits<std::uintmax_t>::max)(); return brent_find_minima(f, min, max, digits, m); } }}} // namespaces #endif