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The Math project is a library of lightweight, self-contained mathematics and statistics components addressing the most common practical problems not immediately available in the Java programming language or commons-lang.

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 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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package org.apache.commons.math.ode.events;

import org.apache.commons.math.ConvergenceException;
import org.apache.commons.math.FunctionEvaluationException;
import org.apache.commons.math.analysis.UnivariateRealFunction;
import org.apache.commons.math.analysis.solvers.BrentSolver;
import org.apache.commons.math.exception.MathInternalError;
import org.apache.commons.math.ode.DerivativeException;
import org.apache.commons.math.ode.sampling.StepInterpolator;
import org.apache.commons.math.util.FastMath;

/** This class handles the state for one {@link EventHandler
 * event handler} during integration steps.
 *
 * 

Each time the integrator proposes a step, the event handler * switching function should be checked. This class handles the state * of one handler during one integration step, with references to the * state at the end of the preceding step. This information is used to * decide if the handler should trigger an event or not during the * proposed step (and hence the step should be reduced to ensure the * event occurs at a bound rather than inside the step).

* * @version $Revision: 1073158 $ $Date: 2011-02-21 22:46:52 +0100 (lun. 21 févr. 2011) $ * @since 1.2 */ public class EventState { /** Event handler. */ private final EventHandler handler; /** Maximal time interval between events handler checks. */ private final double maxCheckInterval; /** Convergence threshold for event localization. */ private final double convergence; /** Upper limit in the iteration count for event localization. */ private final int maxIterationCount; /** Time at the beginning of the step. */ private double t0; /** Value of the events handler at the beginning of the step. */ private double g0; /** Simulated sign of g0 (we cheat when crossing events). */ private boolean g0Positive; /** Indicator of event expected during the step. */ private boolean pendingEvent; /** Occurrence time of the pending event. */ private double pendingEventTime; /** Occurrence time of the previous event. */ private double previousEventTime; /** Integration direction. */ private boolean forward; /** Variation direction around pending event. * (this is considered with respect to the integration direction) */ private boolean increasing; /** Next action indicator. */ private int nextAction; /** Simple constructor. * @param handler event handler * @param maxCheckInterval maximal time interval between switching * function checks (this interval prevents missing sign changes in * case the integration steps becomes very large) * @param convergence convergence threshold in the event time search * @param maxIterationCount upper limit of the iteration count in * the event time search */ public EventState(final EventHandler handler, final double maxCheckInterval, final double convergence, final int maxIterationCount) { this.handler = handler; this.maxCheckInterval = maxCheckInterval; this.convergence = FastMath.abs(convergence); this.maxIterationCount = maxIterationCount; // some dummy values ... t0 = Double.NaN; g0 = Double.NaN; g0Positive = true; pendingEvent = false; pendingEventTime = Double.NaN; previousEventTime = Double.NaN; increasing = true; nextAction = EventHandler.CONTINUE; } /** Get the underlying event handler. * @return underlying event handler */ public EventHandler getEventHandler() { return handler; } /** Get the maximal time interval between events handler checks. * @return maximal time interval between events handler checks */ public double getMaxCheckInterval() { return maxCheckInterval; } /** Get the convergence threshold for event localization. * @return convergence threshold for event localization */ public double getConvergence() { return convergence; } /** Get the upper limit in the iteration count for event localization. * @return upper limit in the iteration count for event localization */ public int getMaxIterationCount() { return maxIterationCount; } /** Reinitialize the beginning of the step. * @param interpolator valid for the current step * @exception EventException if the event handler * value cannot be evaluated at the beginning of the step */ public void reinitializeBegin(final StepInterpolator interpolator) throws EventException { try { // excerpt from MATH-421 issue: // If an ODE solver is setup with an EventHandler that return STOP // when the even is triggered, the integrator stops (which is exactly // the expected behavior). If however the user want to restart the // solver from the final state reached at the event with the same // configuration (expecting the event to be triggered again at a // later time), then the integrator may fail to start. It can get stuck // at the previous event. // The use case for the bug MATH-421 is fairly general, so events occurring // less than epsilon after the solver start in the first step should be ignored, // where epsilon is the convergence threshold of the event. The sign of the g // function should be evaluated after this initial ignore zone, not exactly at // beginning (if there are no event at the very beginning g(t0) and g(t0+epsilon) // have the same sign, so this does not hurt ; if there is an event at the very // beginning, g(t0) and g(t0+epsilon) have opposite signs and we want to start // with the second one. Of course, the sign of epsilon depend on the integration // direction (forward or backward). This explains what is done below. final double ignoreZone = interpolator.isForward() ? getConvergence() : -getConvergence(); t0 = interpolator.getPreviousTime() + ignoreZone; interpolator.setInterpolatedTime(t0); g0 = handler.g(t0, interpolator.getInterpolatedState()); if (g0 == 0) { // extremely rare case: there is a zero EXACTLY at end of ignore zone // we will use the opposite of sign at step beginning to force ignoring this zero final double tStart = interpolator.getPreviousTime(); interpolator.setInterpolatedTime(tStart); g0Positive = handler.g(tStart, interpolator.getInterpolatedState()) <= 0; } else { g0Positive = g0 >= 0; } } catch (DerivativeException mue) { throw new EventException(mue); } } /** Evaluate the impact of the proposed step on the event handler. * @param interpolator step interpolator for the proposed step * @return true if the event handler triggers an event before * the end of the proposed step * @exception DerivativeException if the interpolator fails to * compute the switching function somewhere within the step * @exception EventException if the switching function * cannot be evaluated * @exception ConvergenceException if an event cannot be located */ public boolean evaluateStep(final StepInterpolator interpolator) throws DerivativeException, EventException, ConvergenceException { try { forward = interpolator.isForward(); final double t1 = interpolator.getCurrentTime(); if (FastMath.abs(t1 - t0) < convergence) { // we cannot do anything on such a small step, don't trigger any events return false; } final double start = forward ? (t0 + convergence) : t0 - convergence; final double dt = t1 - start; final int n = FastMath.max(1, (int) FastMath.ceil(FastMath.abs(dt) / maxCheckInterval)); final double h = dt / n; double ta = t0; double ga = g0; for (int i = 0; i < n; ++i) { // evaluate handler value at the end of the substep final double tb = start + (i + 1) * h; interpolator.setInterpolatedTime(tb); final double gb = handler.g(tb, interpolator.getInterpolatedState()); // check events occurrence if (g0Positive ^ (gb >= 0)) { // there is a sign change: an event is expected during this step // variation direction, with respect to the integration direction increasing = gb >= ga; final UnivariateRealFunction f = new UnivariateRealFunction() { public double value(final double t) { try { interpolator.setInterpolatedTime(t); return handler.g(t, interpolator.getInterpolatedState()); } catch (DerivativeException e) { throw new EmbeddedDerivativeException(e); } catch (EventException e) { throw new EmbeddedEventException(e); } } }; final BrentSolver solver = new BrentSolver(convergence); if (ga * gb >= 0) { // this is a corner case: // - there was an event near ta, // - there is another event between ta and tb // - when ta was computed, convergence was reached on the "wrong side" of the interval // this implies that the real sign of ga is the same as gb, so we need to slightly // shift ta to make sure ga and gb get opposite signs and the solver won't complain // about bracketing final double epsilon = (forward ? 0.25 : -0.25) * convergence; for (int k = 0; (k < 4) && (ga * gb > 0); ++k) { ta += epsilon; try { ga = f.value(ta); } catch (FunctionEvaluationException ex) { throw new DerivativeException(ex); } } if (ga * gb > 0) { // this should never happen throw new MathInternalError(); } } final double root; try { root = (ta <= tb) ? solver.solve(maxIterationCount, f, ta, tb) : solver.solve(maxIterationCount, f, tb, ta); } catch (FunctionEvaluationException ex) { throw new DerivativeException(ex); } if ((!Double.isNaN(previousEventTime)) && (FastMath.abs(root - ta) <= convergence) && (FastMath.abs(root - previousEventTime) <= convergence)) { // we have either found nothing or found (again ?) a past event, we simply ignore it ta = tb; ga = gb; } else if (Double.isNaN(previousEventTime) || (FastMath.abs(previousEventTime - root) > convergence)) { pendingEventTime = root; pendingEvent = true; return true; } else { // no sign change: there is no event for now ta = tb; ga = gb; } } else { // no sign change: there is no event for now ta = tb; ga = gb; } } // no event during the whole step pendingEvent = false; pendingEventTime = Double.NaN; return false; } catch (EmbeddedDerivativeException ede) { throw ede.getDerivativeException(); } catch (EmbeddedEventException eee) { throw eee.getEventException(); } } /** Get the occurrence time of the event triggered in the current step. * @return occurrence time of the event triggered in the current * step or positive infinity if no events are triggered */ public double getEventTime() { return pendingEvent ? pendingEventTime : Double.POSITIVE_INFINITY; } /** Acknowledge the fact the step has been accepted by the integrator. * @param t value of the independent time variable at the * end of the step * @param y array containing the current value of the state vector * at the end of the step * @exception EventException if the value of the event * handler cannot be evaluated */ public void stepAccepted(final double t, final double[] y) throws EventException { t0 = t; g0 = handler.g(t, y); if (pendingEvent && (FastMath.abs(pendingEventTime - t) <= convergence)) { // force the sign to its value "just after the event" previousEventTime = t; g0Positive = increasing; nextAction = handler.eventOccurred(t, y, !(increasing ^ forward)); } else { g0Positive = g0 >= 0; nextAction = EventHandler.CONTINUE; } } /** Check if the integration should be stopped at the end of the * current step. * @return true if the integration should be stopped */ public boolean stop() { return nextAction == EventHandler.STOP; } /** Let the event handler reset the state if it wants. * @param t value of the independent time variable at the * beginning of the next step * @param y array were to put the desired state vector at the beginning * of the next step * @return true if the integrator should reset the derivatives too * @exception EventException if the state cannot be reseted by the event * handler */ public boolean reset(final double t, final double[] y) throws EventException { if (!(pendingEvent && (FastMath.abs(pendingEventTime - t) <= convergence))) { return false; } if (nextAction == EventHandler.RESET_STATE) { handler.resetState(t, y); } pendingEvent = false; pendingEventTime = Double.NaN; return (nextAction == EventHandler.RESET_STATE) || (nextAction == EventHandler.RESET_DERIVATIVES); } /** Local exception for embedding DerivativeException. */ private static class EmbeddedDerivativeException extends RuntimeException { /** Serializable UID. */ private static final long serialVersionUID = 3574188382434584610L; /** Embedded exception. */ private final DerivativeException derivativeException; /** Simple constructor. * @param derivativeException embedded exception */ public EmbeddedDerivativeException(final DerivativeException derivativeException) { this.derivativeException = derivativeException; } /** Get the embedded exception. * @return embedded exception */ public DerivativeException getDerivativeException() { return derivativeException; } } /** Local exception for embedding EventException. */ private static class EmbeddedEventException extends RuntimeException { /** Serializable UID. */ private static final long serialVersionUID = -1337749250090455474L; /** Embedded exception. */ private final EventException eventException; /** Simple constructor. * @param eventException embedded exception */ public EmbeddedEventException(final EventException eventException) { this.eventException = eventException; } /** Get the embedded exception. * @return embedded exception */ public EventException getEventException() { return eventException; } } }




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