boost/math/tools/toms748_solve.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_SOLVE_ROOT_HPP #define BOOST_MATH_TOOLS_SOLVE_ROOT_HPP #ifdef _MSC_VER #pragma once #endif #include <boost/math/tools/precision.hpp> #include <boost/math/policies/error_handling.hpp> #include <boost/math/tools/config.hpp> #include <boost/math/special_functions/sign.hpp> #include <limits> #include <utility> #include <cstdint> #ifdef BOOST_MATH_LOG_ROOT_ITERATIONS # define BOOST_MATH_LOGGER_INCLUDE <boost/math/tools/iteration_logger.hpp> # include BOOST_MATH_LOGGER_INCLUDE # undef BOOST_MATH_LOGGER_INCLUDE #else # define BOOST_MATH_LOG_COUNT(count) #endif namespace boost{ namespace math{ namespace tools{ template <class T> class eps_tolerance { public: eps_tolerance() : eps(4 * tools::epsilon<T>()) { } eps_tolerance(unsigned bits) { BOOST_MATH_STD_USING eps = (std::max)(T(ldexp(1.0F, 1-bits)), T(4 * tools::epsilon<T>())); } bool operator()(const T& a, const T& b) { BOOST_MATH_STD_USING return fabs(a - b) <= (eps * (std::min)(fabs(a), fabs(b))); } private: T eps; }; struct equal_floor { equal_floor()= default; template <class T> bool operator()(const T& a, const T& b) { BOOST_MATH_STD_USING return floor(a) == floor(b); } }; struct equal_ceil { equal_ceil()= default; template <class T> bool operator()(const T& a, const T& b) { BOOST_MATH_STD_USING return ceil(a) == ceil(b); } }; struct equal_nearest_integer { equal_nearest_integer()= default; template <class T> bool operator()(const T& a, const T& b) { BOOST_MATH_STD_USING return floor(a + 0.5f) == floor(b + 0.5f); } }; namespace detail{ template <class F, class T> void bracket(F f, T& a, T& b, T c, T& fa, T& fb, T& d, T& fd) { // // Given a point c inside the existing enclosing interval // [a, b] sets a = c if f(c) == 0, otherwise finds the new // enclosing interval: either [a, c] or [c, b] and sets // d and fd to the point that has just been removed from // the interval. In other words d is the third best guess // to the root. // BOOST_MATH_STD_USING // For ADL of std math functions T tol = tools::epsilon<T>() * 2; // // If the interval [a,b] is very small, or if c is too close // to one end of the interval then we need to adjust the // location of c accordingly: // if((b - a) < 2 * tol * a) { c = a + (b - a) / 2; } else if(c <= a + fabs(a) * tol) { c = a + fabs(a) * tol; } else if(c >= b - fabs(b) * tol) { c = b - fabs(b) * tol; } // // OK, lets invoke f(c): // T fc = f(c); // // if we have a zero then we have an exact solution to the root: // if(fc == 0) { a = c; fa = 0; d = 0; fd = 0; return; } // // Non-zero fc, update the interval: // if(boost::math::sign(fa) * boost::math::sign(fc) < 0) { d = b; fd = fb; b = c; fb = fc; } else { d = a; fd = fa; a = c; fa= fc; } } template <class T> inline T safe_div(T num, T denom, T r) { // // return num / denom without overflow, // return r if overflow would occur. // BOOST_MATH_STD_USING // For ADL of std math functions if(fabs(denom) < 1) { if(fabs(denom * tools::max_value<T>()) <= fabs(num)) return r; } return num / denom; } template <class T> inline T secant_interpolate(const T& a, const T& b, const T& fa, const T& fb) { // // Performs standard secant interpolation of [a,b] given // function evaluations f(a) and f(b). Performs a bisection // if secant interpolation would leave us very close to either // a or b. Rationale: we only call this function when at least // one other form of interpolation has already failed, so we know // that the function is unlikely to be smooth with a root very // close to a or b. // BOOST_MATH_STD_USING // For ADL of std math functions T tol = tools::epsilon<T>() * 5; T c = a - (fa / (fb - fa)) * (b - a); if((c <= a + fabs(a) * tol) || (c >= b - fabs(b) * tol)) return (a + b) / 2; return c; } template <class T> T quadratic_interpolate(const T& a, const T& b, T const& d, const T& fa, const T& fb, T const& fd, unsigned count) { // // Performs quadratic interpolation to determine the next point, // takes count Newton steps to find the location of the // quadratic polynomial. // // Point d must lie outside of the interval [a,b], it is the third // best approximation to the root, after a and b. // // Note: this does not guarantee to find a root // inside [a, b], so we fall back to a secant step should // the result be out of range. // // Start by obtaining the coefficients of the quadratic polynomial: // T B = safe_div(T(fb - fa), T(b - a), tools::max_value<T>()); T A = safe_div(T(fd - fb), T(d - b), tools::max_value<T>()); A = safe_div(T(A - B), T(d - a), T(0)); if(A == 0) { // failure to determine coefficients, try a secant step: return secant_interpolate(a, b, fa, fb); } // // Determine the starting point of the Newton steps: // T c; if(boost::math::sign(A) * boost::math::sign(fa) > 0) { c = a; } else { c = b; } // // Take the Newton steps: // for(unsigned i = 1; i <= count; ++i) { //c -= safe_div(B * c, (B + A * (2 * c - a - b)), 1 + c - a); c -= safe_div(T(fa+(B+A*(c-b))*(c-a)), T(B + A * (2 * c - a - b)), T(1 + c - a)); } if((c <= a) || (c >= b)) { // Oops, failure, try a secant step: c = secant_interpolate(a, b, fa, fb); } return c; } template <class T> T cubic_interpolate(const T& a, const T& b, const T& d, const T& e, const T& fa, const T& fb, const T& fd, const T& fe) { // // Uses inverse cubic interpolation of f(x) at points // [a,b,d,e] to obtain an approximate root of f(x). // Points d and e lie outside the interval [a,b] // and are the third and forth best approximations // to the root that we have found so far. // // Note: this does not guarantee to find a root // inside [a, b], so we fall back to quadratic // interpolation in case of an erroneous result. // BOOST_MATH_INSTRUMENT_CODE(" a = " << a << " b = " << b << " d = " << d << " e = " << e << " fa = " << fa << " fb = " << fb << " fd = " << fd << " fe = " << fe); T q11 = (d - e) * fd / (fe - fd); T q21 = (b - d) * fb / (fd - fb); T q31 = (a - b) * fa / (fb - fa); T d21 = (b - d) * fd / (fd - fb); T d31 = (a - b) * fb / (fb - fa); BOOST_MATH_INSTRUMENT_CODE( "q11 = " << q11 << " q21 = " << q21 << " q31 = " << q31 << " d21 = " << d21 << " d31 = " << d31); T q22 = (d21 - q11) * fb / (fe - fb); T q32 = (d31 - q21) * fa / (fd - fa); T d32 = (d31 - q21) * fd / (fd - fa); T q33 = (d32 - q22) * fa / (fe - fa); T c = q31 + q32 + q33 + a; BOOST_MATH_INSTRUMENT_CODE( "q22 = " << q22 << " q32 = " << q32 << " d32 = " << d32 << " q33 = " << q33 << " c = " << c); if((c <= a) || (c >= b)) { // Out of bounds step, fall back to quadratic interpolation: c = quadratic_interpolate(a, b, d, fa, fb, fd, 3); BOOST_MATH_INSTRUMENT_CODE( "Out of bounds interpolation, falling back to quadratic interpolation. c = " << c); } return c; } } // namespace detail template <class F, class T, class Tol, class Policy> std::pair<T, T> toms748_solve(F f, const T& ax, const T& bx, const T& fax, const T& fbx, Tol tol, std::uintmax_t& max_iter, const Policy& pol) { // // Main entry point and logic for Toms Algorithm 748 // root finder. // BOOST_MATH_STD_USING // For ADL of std math functions static const char* function = "boost::math::tools::toms748_solve<%1%>"; // // Sanity check - are we allowed to iterate at all? // if (max_iter == 0) return std::make_pair(ax, bx); std::uintmax_t count = max_iter; T a, b, fa, fb, c, u, fu, a0, b0, d, fd, e, fe; static const T mu = 0.5f; // initialise a, b and fa, fb: a = ax; b = bx; if(a >= b) return boost::math::detail::pair_from_single(policies::raise_domain_error( function, "Parameters a and b out of order: a=%1%", a, pol)); fa = fax; fb = fbx; if(tol(a, b) || (fa == 0) || (fb == 0)) { max_iter = 0; if(fa == 0) b = a; else if(fb == 0) a = b; return std::make_pair(a, b); } if(boost::math::sign(fa) * boost::math::sign(fb) > 0) return boost::math::detail::pair_from_single(policies::raise_domain_error( function, "Parameters a and b do not bracket the root: a=%1%", a, pol)); // dummy value for fd, e and fe: fe = e = fd = 1e5F; if(fa != 0) { // // On the first step we take a secant step: // c = detail::secant_interpolate(a, b, fa, fb); detail::bracket(f, a, b, c, fa, fb, d, fd); --count; BOOST_MATH_INSTRUMENT_CODE(" a = " << a << " b = " << b); if(count && (fa != 0) && !tol(a, b)) { // // On the second step we take a quadratic interpolation: // c = detail::quadratic_interpolate(a, b, d, fa, fb, fd, 2); e = d; fe = fd; detail::bracket(f, a, b, c, fa, fb, d, fd); --count; BOOST_MATH_INSTRUMENT_CODE(" a = " << a << " b = " << b); } } while(count && (fa != 0) && !tol(a, b)) { // save our brackets: a0 = a; b0 = b; // // Starting with the third step taken // we can use either quadratic or cubic interpolation. // Cubic interpolation requires that all four function values // fa, fb, fd, and fe are distinct, should that not be the case // then variable prof will get set to true, and we'll end up // taking a quadratic step instead. // T min_diff = tools::min_value<T>() * 32; bool prof = (fabs(fa - fb) < min_diff) || (fabs(fa - fd) < min_diff) || (fabs(fa - fe) < min_diff) || (fabs(fb - fd) < min_diff) || (fabs(fb - fe) < min_diff) || (fabs(fd - fe) < min_diff); if(prof) { c = detail::quadratic_interpolate(a, b, d, fa, fb, fd, 2); BOOST_MATH_INSTRUMENT_CODE("Can't take cubic step!!!!"); } else { c = detail::cubic_interpolate(a, b, d, e, fa, fb, fd, fe); } // // re-bracket, and check for termination: // e = d; fe = fd; detail::bracket(f, a, b, c, fa, fb, d, fd); if((0 == --count) || (fa == 0) || tol(a, b)) break; BOOST_MATH_INSTRUMENT_CODE(" a = " << a << " b = " << b); // // Now another interpolated step: // prof = (fabs(fa - fb) < min_diff) || (fabs(fa - fd) < min_diff) || (fabs(fa - fe) < min_diff) || (fabs(fb - fd) < min_diff) || (fabs(fb - fe) < min_diff) || (fabs(fd - fe) < min_diff); if(prof) { c = detail::quadratic_interpolate(a, b, d, fa, fb, fd, 3); BOOST_MATH_INSTRUMENT_CODE("Can't take cubic step!!!!"); } else { c = detail::cubic_interpolate(a, b, d, e, fa, fb, fd, fe); } // // Bracket again, and check termination condition, update e: // detail::bracket(f, a, b, c, fa, fb, d, fd); if((0 == --count) || (fa == 0) || tol(a, b)) break; BOOST_MATH_INSTRUMENT_CODE(" a = " << a << " b = " << b); // // Now we take a double-length secant step: // if(fabs(fa) < fabs(fb)) { u = a; fu = fa; } else { u = b; fu = fb; } c = u - 2 * (fu / (fb - fa)) * (b - a); if(fabs(c - u) > (b - a) / 2) { c = a + (b - a) / 2; } // // Bracket again, and check termination condition: // e = d; fe = fd; detail::bracket(f, a, b, c, fa, fb, d, fd); BOOST_MATH_INSTRUMENT_CODE(" a = " << a << " b = " << b); BOOST_MATH_INSTRUMENT_CODE(" tol = " << T((fabs(a) - fabs(b)) / fabs(a))); if((0 == --count) || (fa == 0) || tol(a, b)) break; // // And finally... check to see if an additional bisection step is // to be taken, we do this if we're not converging fast enough: // if((b - a) < mu * (b0 - a0)) continue; // // bracket again on a bisection: // e = d; fe = fd; detail::bracket(f, a, b, T(a + (b - a) / 2), fa, fb, d, fd); --count; BOOST_MATH_INSTRUMENT_CODE("Not converging: Taking a bisection!!!!"); BOOST_MATH_INSTRUMENT_CODE(" a = " << a << " b = " << b); } // while loop max_iter -= count; if(fa == 0) { b = a; } else if(fb == 0) { a = b; } BOOST_MATH_LOG_COUNT(max_iter) return std::make_pair(a, b); } template <class F, class T, class Tol> inline std::pair<T, T> toms748_solve(F f, const T& ax, const T& bx, const T& fax, const T& fbx, Tol tol, std::uintmax_t& max_iter) { return toms748_solve(f, ax, bx, fax, fbx, tol, max_iter, policies::policy<>()); } template <class F, class T, class Tol, class Policy> inline std::pair<T, T> toms748_solve(F f, const T& ax, const T& bx, Tol tol, std::uintmax_t& max_iter, const Policy& pol) { if (max_iter <= 2) return std::make_pair(ax, bx); max_iter -= 2; std::pair<T, T> r = toms748_solve(f, ax, bx, f(ax), f(bx), tol, max_iter, pol); max_iter += 2; return r; } template <class F, class T, class Tol> inline std::pair<T, T> toms748_solve(F f, const T& ax, const T& bx, Tol tol, std::uintmax_t& max_iter) { return toms748_solve(f, ax, bx, tol, max_iter, policies::policy<>()); } template <class F, class T, class Tol, class Policy> std::pair<T, T> bracket_and_solve_root(F f, const T& guess, T factor, bool rising, Tol tol, std::uintmax_t& max_iter, const Policy& pol) { BOOST_MATH_STD_USING static const char* function = "boost::math::tools::bracket_and_solve_root<%1%>"; // // Set up initial brackets: // T a = guess; T b = a; T fa = f(a); T fb = fa; // // Set up invocation count: // std::uintmax_t count = max_iter - 1; int step = 32; if((fa < 0) == (guess < 0 ? !rising : rising)) { // // Zero is to the right of b, so walk upwards // until we find it: // while((boost::math::sign)(fb) == (boost::math::sign)(fa)) { if(count == 0) return boost::math::detail::pair_from_single(policies::raise_evaluation_error(function, "Unable to bracket root, last nearest value was %1%", b, pol)); // // Heuristic: normally it's best not to increase the step sizes as we'll just end up // with a really wide range to search for the root. However, if the initial guess was *really* // bad then we need to speed up the search otherwise we'll take forever if we're orders of // magnitude out. This happens most often if the guess is a small value (say 1) and the result // we're looking for is close to std::numeric_limits<T>::min(). // if((max_iter - count) % step == 0) { factor *= 2; if(step > 1) step /= 2; } // // Now go ahead and move our guess by "factor": // a = b; fa = fb; b *= factor; fb = f(b); --count; BOOST_MATH_INSTRUMENT_CODE("a = " << a << " b = " << b << " fa = " << fa << " fb = " << fb << " count = " << count); } } else { // // Zero is to the left of a, so walk downwards // until we find it: // while((boost::math::sign)(fb) == (boost::math::sign)(fa)) { if(fabs(a) < tools::min_value<T>()) { // Escape route just in case the answer is zero! max_iter -= count; max_iter += 1; return a > 0 ? std::make_pair(T(0), T(a)) : std::make_pair(T(a), T(0)); } if(count == 0) return boost::math::detail::pair_from_single(policies::raise_evaluation_error(function, "Unable to bracket root, last nearest value was %1%", a, pol)); // // Heuristic: normally it's best not to increase the step sizes as we'll just end up // with a really wide range to search for the root. However, if the initial guess was *really* // bad then we need to speed up the search otherwise we'll take forever if we're orders of // magnitude out. This happens most often if the guess is a small value (say 1) and the result // we're looking for is close to std::numeric_limits<T>::min(). // if((max_iter - count) % step == 0) { factor *= 2; if(step > 1) step /= 2; } // // Now go ahead and move are guess by "factor": // b = a; fb = fa; a /= factor; fa = f(a); --count; BOOST_MATH_INSTRUMENT_CODE("a = " << a << " b = " << b << " fa = " << fa << " fb = " << fb << " count = " << count); } } max_iter -= count; max_iter += 1; std::pair<T, T> r = toms748_solve( f, (a < 0 ? b : a), (a < 0 ? a : b), (a < 0 ? fb : fa), (a < 0 ? fa : fb), tol, count, pol); max_iter += count; BOOST_MATH_INSTRUMENT_CODE("max_iter = " << max_iter << " count = " << count); BOOST_MATH_LOG_COUNT(max_iter) return r; } template <class F, class T, class Tol> inline std::pair<T, T> bracket_and_solve_root(F f, const T& guess, const T& factor, bool rising, Tol tol, std::uintmax_t& max_iter) { return bracket_and_solve_root(f, guess, factor, rising, tol, max_iter, policies::policy<>()); } } // namespace tools } // namespace math } // namespace boost #endif // BOOST_MATH_TOOLS_SOLVE_ROOT_HPP