/*
* Copyright (c) 2005-2010 KOM – Multimedia Communications Lab
*
* This file is part of PeerfactSim.KOM.
*
* PeerfactSim.KOM is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* any later version.
*
* PeerfactSim.KOM is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with PeerfactSim.KOM. If not, see .
*
*/
package de.tud.kom.p2psim.impl.topology.movement.modularosm;
import java.util.LinkedHashMap;
import java.util.LinkedHashSet;
import java.util.List;
import java.util.Map;
import java.util.Random;
import java.util.Set;
import java.util.Vector;
import de.tud.kom.p2psim.api.scenario.ConfigurationException;
import de.tud.kom.p2psim.api.topology.Topology;
import de.tud.kom.p2psim.api.topology.movement.MovementModel;
import de.tud.kom.p2psim.api.topology.movement.SimLocationActuator;
import de.tud.kom.p2psim.api.topology.movement.local.LocalMovementStrategy;
import de.tud.kom.p2psim.api.topology.placement.PlacementModel;
import de.tud.kom.p2psim.impl.simengine.Simulator;
import de.tud.kom.p2psim.impl.topology.PositionVector;
import de.tud.kom.p2psim.impl.topology.TopologyFactory;
import de.tud.kom.p2psim.impl.topology.movement.modularosm.attraction.IAttractionGenerator;
import de.tud.kom.p2psim.impl.topology.movement.modularosm.mapvisualization.IMapVisualization;
import de.tud.kom.p2psim.impl.topology.movement.modularosm.transition.ITransitionStrategy;
import de.tud.kom.p2psim.impl.topology.movement.modularosm.transition.ITransitionStrategy.AttractionAssignmentListener;
import de.tud.kom.p2psim.impl.topology.views.VisualizationTopologyView.VisualizationInjector;
import de.tud.kom.p2psim.impl.util.Either;
import de.tudarmstadt.maki.simonstrator.api.Binder;
import de.tudarmstadt.maki.simonstrator.api.Event;
import de.tudarmstadt.maki.simonstrator.api.EventHandler;
import de.tudarmstadt.maki.simonstrator.api.Randoms;
import de.tudarmstadt.maki.simonstrator.api.Time;
import de.tudarmstadt.maki.simonstrator.api.component.sensor.location.AttractionPoint;
/**
* Modular Movement Model uses different models/strategies to create a movement
* model. In this implementation, it has 3 different models/strategies.
*
* M0: AttractionGenerator -> Generates the {@link AttractionPoint}s and place
* them on the map. The {@link AttractionPoint}s can't be moved, because they
* are static POIs from real-world data!
*
* M1: A general {@link MovementModel} is not used, because we use static
* attraction points.
*
* M2: The {@link ITransitionStrategy}! It takes the Hosts, which should be moved
* around, but calculates only the assignment to the {@link AttractionPoint}s.
* It doesn't move the Hosts! It will be only assignment a new AttractionPoint!
*
*
* M3: The {@link LocalMovementStrategy} is responsible for the movement of the
* Hosts. It moves the hosts to the assigned AttractionPoint, and if the
* AttractionPoint has moved, then will be followed. The
* {@link LocalMovementStrategy} will be called from the
* {@link ModularMovementModel} to do a Movement!
*
* This class contains all three components and manage the data exchange.
* Additionally it contains an periodic operation, which handle the movement of
* all hosts. This mean, that it will be call the {@link LocalMovementStrategy}
* with the destination. Please take care, that the handling of the movement of
* the AttractionPoints will be handled by the movement model in M1!
* Further it contains an offset for every Host, which will be added to the
* destination point (AttractionPoint), so that not all hosts, which are
* assigned to one {@link AttractionPoint}, lies on the same point.
*
* CHANGELOG
*
* - 04.01.2017 Clemens Krug: Added the possibility to configure the model
* visualisation via XML. If not specified, the visualisation will use the
* {@link ModularMovementModelViz}, just as before. Thus there shouldn't be any problems
* with older code.
*
* @author Martin Hellwig, Christoph Muenker
* @version 1.0, 07.07.2015
*/
public class ModularMovementModel implements MovementModel, EventHandler, AttractionAssignmentListener {
private final int EVENT_MOVE = 1;
private final int EVENT_INIT = 2;
protected PositionVector worldDimensions;
protected ITransitionStrategy transition;
protected IAttractionGenerator attractionGenerator;
protected LocalMovementStrategy localMovementStrategy;
protected IMapVisualization mapVisualization;
private ModularMovementModelViz modelVisualisation;
protected Set moveableHosts = new LinkedHashSet();
private Map currentTarget = new LinkedHashMap<>();
private Map routeSensorComponents = new LinkedHashMap<>();
private boolean initialized = false;
private long timeBetweenMoveOperation = Simulator.SECOND_UNIT;
private Random rand;
public ModularMovementModel() {
this.worldDimensions = Binder.getComponentOrNull(Topology.class)
.getWorldDimensions();
this.rand = Randoms.getRandom(ModularMovementModel.class);
// scheduling initalization!
Event.scheduleImmediately(this, null, EVENT_INIT);
}
/**
* This Method will be not called from the Components. So we call this
* manually!
*/
public void initialize() {
if (!initialized) {
if (modelVisualisation == null) {
modelVisualisation = new ModularMovementModelViz(this);
}
VisualizationInjector.injectComponent(modelVisualisation);
if (mapVisualization != null) {
VisualizationInjector.injectComponent(mapVisualization);
}
checkConfiguration();
// setWayPointModel
localMovementStrategy.setObstacleModel(Binder
.getComponentOrNull(Topology.class).getObstacleModel());
localMovementStrategy.setWaypointModel(Binder
.getComponentOrNull(Topology.class).getWaypointModel());
/*
* Scale depending on calculation interval, if interval != 1 Second.
*/
localMovementStrategy
.setScaleFactor(timeBetweenMoveOperation / (double) Time.SECOND);
List attractionPoints = attractionGenerator
.getAttractionPoints();
transition.setAttractionPoints(attractionPoints);
transition.addAttractionAssignmentListener(this);
// This adds the mobile hosts (smartphones/users) to the transition
// strategy
for (SimLocationActuator ms : moveableHosts) {
transition.addComponent(ms);
}
setTimeBetweenMoveOperations(timeBetweenMoveOperation);
// initial move
move();
initialized = true;
}
}
/**
* This default implementation relies on {@link PlacementModel}s to be
* configured in the {@link TopologyFactory}
*/
@Override
public void placeComponent(SimLocationActuator actuator) {
// not supported
}
@Override
public void changeTargetLocation(SimLocationActuator actuator, AttractionPoint ap) {
transition.updateTargetAttractionPoint(actuator, ap);
}
@Override
public AttractionPoint getTargetLocation(SimLocationActuator actuator) {
return transition.getAssignment(actuator);
}
@Override
public Set getAllAttractionPoints()
throws UnsupportedOperationException {
return transition.getAllAttractionPoints();
}
private void checkConfiguration() {
if (localMovementStrategy == null) {
throw new ConfigurationException(
"LocalMovementStrategy is missing in ModularMovementModel!");
}
if (transition == null) {
throw new ConfigurationException(
"TransitionStrategy is missing in ModularMovementModel!");
}
if (attractionGenerator == null) {
throw new ConfigurationException(
"AttractionGenerator is missing in ModularMovementModel!");
}
}
@Override
public void addComponent(SimLocationActuator comp) {
moveableHosts.add(comp);
if (!routeSensorComponents.containsKey(comp)) {
routeSensorComponents.put(comp, new RouteSensorComponent(comp));
}
}
public Set getAllLocationActuators() {
return moveableHosts;
}
@Override
public void setTimeBetweenMoveOperations(long time) {
if (time > 0) {
this.timeBetweenMoveOperation = time;
} else {
throw new ConfigurationException(
"time is negative for the Move Operations");
}
}
@Override
public void updatedAttractionAssignment(SimLocationActuator component,
AttractionPoint newAssignment) {
/*
* Use this method to calculate the offset and target location for a
* host.
*/
PositionVector attractionCenter = (PositionVector) newAssignment;
PositionVector destination = null;
/*
* Even if an AP does not have a radius, we slightly offset
*/
double apRadius = Math.max(newAssignment.getRadius(), 25.0);
int tries = 0;
do {
destination = new PositionVector(attractionCenter);
// Gaussian with std = 1 --> >99% of nodes
PositionVector offset = new PositionVector(
rand.nextGaussian() * apRadius / 3,
rand.nextGaussian() * apRadius / 3);
destination.add(offset);
// Check constraints
if (destination.getX() < 0.0
|| destination.getX() > Binder
.getComponentOrNull(Topology.class)
.getWorldDimensions().getX() || destination.getY() < 0.0
|| destination.getY() > Binder
.getComponentOrNull(Topology.class)
.getWorldDimensions().getY()) {
destination = null;
if (tries > 100) {
throw new AssertionError("Unable to find a valid target destination within <100 tries.");
}
}
tries++;
} while (destination == null);
currentTarget.put(component, destination);
}
protected void move() {
for (SimLocationActuator component : moveableHosts) {
assert currentTarget.containsKey(component);
doLocalMovement(component, currentTarget.get(component));
}
Event.scheduleWithDelay(timeBetweenMoveOperation, this, null,
EVENT_MOVE);
}
/**
*
* Ask the local movement strategy for the next position. It may return the
* next position or a boolean with true to notify the movement model that it
* can't get any closer to the current way point.
*
* @param ms
* @param destination
*/
protected void doLocalMovement(SimLocationActuator ms,
PositionVector destination) {
Either either = localMovementStrategy
.nextPosition(ms, destination);
if (either.hasLeft()) {
ms.updateCurrentLocation(either.getLeft());
/*
* Check for negative or out of bound coordinates!
*/
assert ms.getRealPosition().getX() >= 0.0
&& ms.getRealPosition().getX() <= Binder
.getComponentOrNull(Topology.class)
.getWorldDimensions().getX();
assert ms.getRealPosition().getY() >= 0.0
&& ms.getRealPosition().getY() <= Binder
.getComponentOrNull(Topology.class)
.getWorldDimensions().getY();
} else {
transition.reachedAttractionPoint(ms);
}
}
public void setIAttractionGenerator(
IAttractionGenerator attractionGenerator) {
this.attractionGenerator = attractionGenerator;
}
public void setLocalMovementStrategy(
LocalMovementStrategy localMovementStrategy) {
this.localMovementStrategy = localMovementStrategy;
}
public void setITransitionStrategy(ITransitionStrategy transition) {
this.transition = transition;
}
public void setIMapVisualization(IMapVisualization mapVisualization) {
this.mapVisualization = mapVisualization;
}
public void setModelVisualisation(ModularMovementModelViz modelVis)
{
modelVisualisation = modelVis;
modelVisualisation.setMovementModel(this);
}
@Override
public void eventOccurred(Object content, int type) {
if (type == EVENT_INIT) {
initialize();
} else if (type == EVENT_MOVE) {
move();
}
}
/**
* Only for visualization!
*
* @return
*/
public List getAttractionPoints() {
return new Vector(transition.getAllAttractionPoints());
}
}