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- //
- // LolRemez - Remez algorithm implementation
- //
- // Copyright © 2005—2015 Sam Hocevar <sam@hocevar.net>
- //
- // This program is free software. It comes without any warranty, to
- // the extent permitted by applicable law. You can redistribute it
- // and/or modify it under the terms of the Do What the Fuck You Want
- // to Public License, Version 2, as published by the WTFPL Task Force.
- // See http://www.wtfpl.net/ for more details.
- //
-
- #if HAVE_CONFIG_H
- # include "config.h"
- #endif
-
- #include <functional>
-
- #include <lol/engine.h>
-
- #include <lol/math/real.h>
- #include <lol/math/polynomial.h>
-
- #include "matrix.h"
- #include "solver.h"
-
- using lol::real;
-
- remez_solver::remez_solver(int order, int decimals)
- : m_order(order),
- m_decimals(decimals),
- m_has_weight(false)
- {
- /* Spawn 4 worker threads */
- for (int i = 0; i < 4; ++i)
- {
- auto th = new thread(std::bind(&remez_solver::worker_thread, this));
- m_workers.push(th);
- }
- }
-
- remez_solver::~remez_solver()
- {
- /* Signal worker threads to quit, wait for worker threads to answer,
- * and kill worker threads. */
- for (auto worker : m_workers)
- UNUSED(worker), m_questions.push(-1);
-
- for (auto worker : m_workers)
- UNUSED(worker), m_answers.pop();
-
- for (auto worker : m_workers)
- delete worker;
- }
-
- void remez_solver::run(real a, real b, char const *func, char const *weight)
- {
- m_func.parse(func);
-
- if (weight)
- {
- m_weight.parse(weight);
- m_has_weight = true;
- }
-
- m_k1 = (b + a) / 2;
- m_k2 = (b - a) / 2;
- m_epsilon = pow((real)10, (real)-(m_decimals + 2));
-
- remez_init();
- print_poly();
-
- for (int n = 0; ; n++)
- {
- real old_error = m_error;
-
- find_extrema();
- remez_step();
-
- if (m_error >= (real)0
- && fabs(m_error - old_error) < m_error * m_epsilon)
- break;
-
- print_poly();
- find_zeroes();
- }
-
- print_poly();
- }
-
- /*
- * This is basically the first Remez step: we solve a system of
- * order N+1 and get a good initial polynomial estimate.
- */
- void remez_solver::remez_init()
- {
- /* m_order + 1 zeroes of the error function */
- m_zeroes.resize(m_order + 1);
-
- /* m_order + 1 zeroes to find */
- m_zeroes_state.resize(m_order + 1);
-
- /* m_order + 2 control points */
- m_control.resize(m_order + 2);
-
- /* m_order extrema to find */
- m_extrema_state.resize(m_order);
-
- /* Initial estimates for the x_i where the error will be zero and
- * precompute f(x_i). */
- array<real> fxn;
- for (int i = 0; i < m_order + 1; i++)
- {
- m_zeroes[i] = (real)(2 * i - m_order) / (real)(m_order + 1);
- fxn.push(eval_func(m_zeroes[i]));
- }
-
- /* We build a matrix of Chebyshev evaluations: row i contains the
- * evaluations of x_i for polynomial order n = 0, 1, ... */
- linear_system<real> system(m_order + 1);
- for (int n = 0; n < m_order + 1; n++)
- {
- auto p = polynomial<real>::chebyshev(n);
- for (int i = 0; i < m_order + 1; i++)
- system[i][n] = p.eval(m_zeroes[i]);
- }
-
- /* Solve the system */
- system = system.inverse();
-
- /* Compute new Chebyshev estimate */
- m_estimate = polynomial<real>();
- for (int n = 0; n < m_order + 1; n++)
- {
- real weight = 0;
- for (int i = 0; i < m_order + 1; i++)
- weight += system[n][i] * fxn[i];
-
- m_estimate += weight * polynomial<real>::chebyshev(n);
- }
- }
-
- /*
- * Every subsequent iteration of the Remez algorithm: we solve a system
- * of order N+2 to both refine the estimate and compute the error.
- */
- void remez_solver::remez_step()
- {
- Timer t;
-
- /* Pick up x_i where error will be 0 and compute f(x_i) */
- array<real> fxn;
- for (int i = 0; i < m_order + 2; i++)
- fxn.push(eval_func(m_control[i]));
-
- /* We build a matrix of Chebyshev evaluations: row i contains the
- * evaluations of x_i for polynomial order n = 0, 1, ... */
- linear_system<real> system(m_order + 2);
- for (int n = 0; n < m_order + 1; n++)
- {
- auto p = polynomial<real>::chebyshev(n);
- for (int i = 0; i < m_order + 2; i++)
- system[i][n] = p.eval(m_control[i]);
- }
-
- /* The last line of the system is the oscillating error */
- for (int i = 0; i < m_order + 2; i++)
- {
- real error = fabs(eval_weight(m_control[i]));
- system[i][m_order + 1] = (i & 1) ? error : -error;
- }
-
- /* Solve the system */
- system = system.inverse();
-
- /* Compute new polynomial estimate */
- m_estimate = polynomial<real>();
- for (int n = 0; n < m_order + 1; n++)
- {
- real weight = 0;
- for (int i = 0; i < m_order + 2; i++)
- weight += system[n][i] * fxn[i];
-
- m_estimate += weight * polynomial<real>::chebyshev(n);
- }
-
- /* Compute the error (FIXME: unused?) */
- real error = 0;
- for (int i = 0; i < m_order + 2; i++)
- error += system[m_order + 1][i] * fxn[i];
-
- using std::printf;
- printf(" -:- timing for inversion: %f ms\n", t.Get() * 1000.f);
- }
-
- /*
- * Find m_order + 1 zeroes of the error function. No need to compute the
- * relative error: its zeroes are at the same place as the absolute error!
- *
- * The algorithm used here is naïve regula falsi. It still performs a lot
- * better than the midpoint algorithm.
- */
- void remez_solver::find_zeroes()
- {
- Timer t;
-
- static real const limit = ldexp((real)1, -500);
- static real const zero = (real)0;
-
- /* Initialise an [a,b] bracket for each zero we try to find */
- for (int i = 0; i < m_order + 1; i++)
- {
- point &a = m_zeroes_state[i].m1;
- point &b = m_zeroes_state[i].m2;
-
- a.x = m_control[i];
- a.err = eval_estimate(a.x) - eval_func(a.x);
- b.x = m_control[i + 1];
- b.err = eval_estimate(b.x) - eval_func(b.x);
-
- m_questions.push(i);
- }
-
- /* Watch all brackets for updates from worker threads */
- for (int finished = 0; finished < m_order + 1; )
- {
- int i = m_answers.pop();
-
- point &a = m_zeroes_state[i].m1;
- point &b = m_zeroes_state[i].m2;
- point &c = m_zeroes_state[i].m3;
-
- if (c.err == zero || fabs(a.x - b.x) <= limit)
- {
- m_zeroes[i] = c.x;
- ++finished;
- continue;
- }
-
- m_questions.push(i);
- }
-
- using std::printf;
- printf(" -:- timing for zeroes: %f ms\n", t.Get() * 1000.f);
- }
-
- /*
- * Find m_order extrema of the error function. We maximise the relative
- * error, since its extrema are at slightly different locations than the
- * absolute error’s.
- *
- * The algorithm used here is successive parabolic interpolation. FIXME: we
- * could use Brent’s method instead, which combines parabolic interpolation
- * and golden ratio search and has superlinear convergence.
- */
- void remez_solver::find_extrema()
- {
- Timer t;
-
- m_control[0] = -1;
- m_control[m_order + 1] = 1;
- m_error = 0;
-
- /* Initialise an [a,b,c] bracket for each extremum we try to find */
- for (int i = 0; i < m_order; i++)
- {
- point &a = m_extrema_state[i].m1;
- point &b = m_extrema_state[i].m2;
- point &c = m_extrema_state[i].m3;
-
- a.x = m_zeroes[i];
- b.x = m_zeroes[i + 1];
- c.x = a.x + (b.x - a.x) * real(rand(0.4f, 0.6f));
-
- a.err = eval_error(a.x);
- b.err = eval_error(b.x);
- c.err = eval_error(c.x);
-
- m_questions.push(i + 1000);
- }
-
- /* Watch all brackets for updates from worker threads */
- for (int finished = 0; finished < m_order; )
- {
- int i = m_answers.pop();
-
- point &a = m_extrema_state[i - 1000].m1;
- point &b = m_extrema_state[i - 1000].m2;
- point &c = m_extrema_state[i - 1000].m3;
-
- if (b.x - a.x <= m_epsilon)
- {
- m_control[i - 1000 + 1] = c.x;
- if (c.err > m_error)
- m_error = c.err;
- ++finished;
- continue;
- }
-
- m_questions.push(i);
- }
-
- using std::printf;
- printf(" -:- timing for extrema: %f ms\n", t.Get() * 1000.f);
- printf(" -:- error: ");
- m_error.print(m_decimals);
- printf("\n");
- }
-
- void remez_solver::print_poly()
- {
- /* Transform our polynomial in the [-1..1] range into a polynomial
- * in the [a..b] range by composing it with q:
- * q(x) = 2x / (b-a) - (b+a) / (b-a) */
- polynomial<real> q ({ -m_k1 / m_k2, real(1) / m_k2 });
- polynomial<real> r = m_estimate.eval(q);
-
- using std::printf;
- printf("\n");
- for (int j = 0; j < m_order + 1; j++)
- {
- if (j)
- printf(" + x**%i * ", j);
- r[j].print(m_decimals);
- }
- printf("\n\n");
- }
-
- real remez_solver::eval_estimate(real const &x)
- {
- return m_estimate.eval(x);
- }
-
- real remez_solver::eval_func(real const &x)
- {
- return m_func.eval(x * m_k2 + m_k1);
- }
-
- real remez_solver::eval_weight(real const &x)
- {
- return m_has_weight ? m_weight.eval(x * m_k2 + m_k1) : real(1);
- }
-
- real remez_solver::eval_error(real const &x)
- {
- return fabs((eval_estimate(x) - eval_func(x)) / eval_weight(x));
- }
-
- void remez_solver::worker_thread()
- {
- static real const zero = (real)0;
-
- for (;;)
- {
- int i = m_questions.pop();
-
- if (i < 0)
- {
- m_answers.push(i);
- break;
- }
- else if (i < 1000)
- {
- point &a = m_zeroes_state[i].m1;
- point &b = m_zeroes_state[i].m2;
- point &c = m_zeroes_state[i].m3;
-
- real s = abs(b.err) / (abs(a.err) + abs(b.err));
- real newc = b.x + s * (a.x - b.x);
-
- /* If the third point didn't change since last iteration,
- * we may be at an inflection point. Use the midpoint to get
- * out of this situation. */
- c.x = newc != c.x ? newc : (a.x + b.x) / 2;
- c.err = eval_estimate(c.x) - eval_func(c.x);
-
- if ((a.err < zero && c.err < zero)
- || (a.err > zero && c.err > zero))
- a = c;
- else
- b = c;
-
- m_answers.push(i);
- }
- else if (i < 2000)
- {
- point &a = m_extrema_state[i - 1000].m1;
- point &b = m_extrema_state[i - 1000].m2;
- point &c = m_extrema_state[i - 1000].m3;
- point d;
-
- real d1 = c.x - a.x, d2 = c.x - b.x;
- real k1 = d1 * (c.err - b.err);
- real k2 = d2 * (c.err - a.err);
- d.x = c.x - (d1 * k1 - d2 * k2) / (k1 - k2) / 2;
-
- /* If parabolic interpolation failed, pick a number
- * inbetween. */
- if (d.x <= a.x || d.x >= b.x)
- d.x = (a.x + b.x) / 2;
-
- d.err = eval_error(d.x);
-
- /* Update bracketing depending on the new point. */
- if (d.err < c.err)
- {
- (d.x > c.x ? b : a) = d;
- }
- else
- {
- (d.x > c.x ? a : b) = c;
- c = d;
- }
-
- m_answers.push(i);
- }
- }
- }
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