package org.opentrafficsim.graphs;
import static org.junit.Assert.assertEquals;
import static org.junit.Assert.assertFalse;
import static org.junit.Assert.assertTrue;
import static org.junit.Assert.fail;
import java.awt.Component;
import java.awt.Container;
import java.awt.event.ActionEvent;
import java.awt.event.MouseListener;
import java.util.ArrayList;
import java.util.List;
import javax.swing.JLabel;
import javax.swing.JOptionPane;
import nl.tudelft.simulation.dsol.SimRuntimeException;
import nl.tudelft.simulation.dsol.simulators.SimulatorInterface;
import org.djunits.unit.AccelerationUnit;
import org.djunits.unit.LengthUnit;
import org.djunits.unit.TimeUnit;
import org.djunits.unit.UNITS;
import org.djunits.value.vdouble.scalar.Acceleration;
import org.djunits.value.vdouble.scalar.DoubleScalar;
import org.djunits.value.vdouble.scalar.Length;
import org.djunits.value.vdouble.scalar.Speed;
import org.djunits.value.vdouble.scalar.Time;
import org.jfree.chart.ChartPanel;
import org.jfree.data.DomainOrder;
import org.junit.Test;
import org.opentrafficsim.core.dsol.OTSModelInterface;
import org.opentrafficsim.core.dsol.OTSSimTimeDouble;
import org.opentrafficsim.core.geometry.OTSPoint3D;
import org.opentrafficsim.core.gtu.GTUType;
import org.opentrafficsim.core.network.LongitudinalDirectionality;
import org.opentrafficsim.core.network.OTSNetwork;
import org.opentrafficsim.core.network.OTSNode;
import org.opentrafficsim.road.car.CarTest;
import org.opentrafficsim.road.gtu.lane.LaneBasedIndividualGTU;
import org.opentrafficsim.road.gtu.lane.tactical.following.FixedAccelerationModel;
import org.opentrafficsim.road.gtu.lane.tactical.following.SequentialFixedAccelerationModel;
import org.opentrafficsim.road.gtu.lane.tactical.lanechangemobil.Egoistic;
import org.opentrafficsim.road.gtu.lane.tactical.lanechangemobil.LaneChangeModel;
import org.opentrafficsim.road.network.factory.LaneFactory;
import org.opentrafficsim.road.network.lane.Lane;
import org.opentrafficsim.road.network.lane.LaneType;
import org.opentrafficsim.simulationengine.SimpleSimulator;
/**
* Test the non-GUI part of the ContourPlot class.
*
* Copyright (c) 2013-2015 Delft University of Technology, PO Box 5, 2600 AA, Delft, the Netherlands. All rights reserved.
* BSD-style license. See OpenTrafficSim License.
*
* $LastChangedDate: 2015-09-14 01:33:02 +0200 (Mon, 14 Sep 2015) $, @version $Revision: 1401 $, by $Author: averbraeck $,
* initial version Aug 21, 2014
* @author Peter Knoppers
*/
public class ContourPlotTest implements UNITS
{
/**
* Create a dummy path for the tests.
* @param laneType the lane type
* @param gtuType the GTU type
* @return List<Lane>; the dummy path
* @throws Exception when something goes wrong (should not happen)
*/
private List dummyPath(final LaneType laneType, final GTUType gtuType) throws Exception
{
OTSNode b = new OTSNode("B", new OTSPoint3D(12345, 0, 0));
ArrayList result = new ArrayList();
Lane[] lanes =
LaneFactory.makeMultiLane("AtoB", new OTSNode("A", new OTSPoint3D(1234, 0, 0)), b, null, 1, laneType,
new Speed(100, KM_PER_HOUR), null, LongitudinalDirectionality.DIR_PLUS);
result.add(lanes[0]);
// Make a continuation lane to prevent errors when the operational plan exceeds the available remaining length
lanes =
LaneFactory.makeMultiLane("BtoC", b, new OTSNode("C", new OTSPoint3D(99999, 0, 0)), null, 1, laneType,
new Speed(100, KM_PER_HOUR), null, LongitudinalDirectionality.DIR_PLUS);
// System.out.println("continuation lane is " + lanes[0] + " length is " + lanes[0].getLength());
// System.out.println("next lanes is " + result.get(0).nextLanes(gtuType));
return result;
}
/**
* Test the AccelerationContourPlot.
* @throws Exception when something goes wrong (should not happen)
*/
@SuppressWarnings("static-method")
@Test
public final void accelerationContourTest() throws Exception
{
LaneType laneType = new LaneType("CarLane");
GTUType gtuType = GTUType.makeGTUType("Car");
laneType.addCompatibility(gtuType);
List path = dummyPath(laneType, gtuType);
AccelerationContourPlot acp = new AccelerationContourPlot("Acceleration", path);
assertTrue("newly created AccelerationContourPlot should not be null", null != acp);
assertEquals("SeriesKey should be \"acceleration\"", "acceleration", acp.getSeriesKey(0));
standardContourTests(acp, path.get(0), gtuType, Double.NaN, 0);
}
/**
* Test the DensityContourPlot.
* @throws Exception when something goes wrong (should not happen)
*/
@SuppressWarnings("static-method")
@Test
public final void densityContourTest() throws Exception
{
LaneType laneType = new LaneType("CarLane");
GTUType gtuType = GTUType.makeGTUType("Car");
laneType.addCompatibility(gtuType);
List path = dummyPath(laneType, gtuType);
DensityContourPlot dcp = new DensityContourPlot("Density", path);
assertTrue("newly created DensityContourPlot should not be null", null != dcp);
assertEquals("SeriesKey should be \"density\"", "density", dcp.getSeriesKey(0));
standardContourTests(dcp, path.get(0), gtuType, 0, Double.NaN);
}
/**
* Debugging method.
* @param cp
* @param fromX
* @param toX
* @param fromY
* @param toY
*/
static void printMatrix(ContourPlot cp, int fromX, int toX, int fromY, int toY)
{
System.out.println("Contour plot data:");
int maxItem = cp.getItemCount(0);
for (int y = fromY; y <= toY; y++)
{
System.out.print(String.format("y=%3d ", y));
for (int x = fromX; x <= toX; x++)
{
// Find the item with the requested x and y
int item;
for (item = 0; item < maxItem; item++)
{
if (cp.getXValue(0, item) == x && cp.getYValue(0, item) == y)
{
break;
}
}
if (item < maxItem)
{
System.out.print(String.format("%10.6f", cp.getZValue(0, item)));
}
else
{
System.out.print(" -------- ");
}
}
System.out.println("");
}
System.out.print("");
}
/**
* Test the FlowContourPlot.
* @throws Exception when something goes wrong (should not happen)
*/
@SuppressWarnings("static-method")
@Test
public final void flowContourTest() throws Exception
{
LaneType laneType = new LaneType("CarLane");
GTUType gtuType = GTUType.makeGTUType("Car");
laneType.addCompatibility(gtuType);
List path = dummyPath(laneType, gtuType);
FlowContourPlot fcp = new FlowContourPlot("Density", path);
assertTrue("newly created DensityContourPlot should not be null", null != fcp);
assertEquals("SeriesKey should be \"flow\"", "flow", fcp.getSeriesKey(0));
standardContourTests(fcp, path.get(0), gtuType, 0, Double.NaN);
}
/**
* Test the SpeedContourPlot.
* @throws Exception when something goes wrong (should not happen)
*/
@SuppressWarnings("static-method")
@Test
public final void speedContourTest() throws Exception
{
LaneType laneType = new LaneType("CarLane");
GTUType gtuType = GTUType.makeGTUType("Car");
laneType.addCompatibility(gtuType);
List path = dummyPath(laneType, gtuType);
SpeedContourPlot scp = new SpeedContourPlot("Density", path);
assertTrue("newly created DensityContourPlot should not be null", null != scp);
assertEquals("SeriesKey should be \"speed\"", "speed", scp.getSeriesKey(0));
standardContourTests(scp, path.get(0), gtuType, Double.NaN, 50);
}
/**
* Test various properties of a ContourPlot that has no observed data added.
* @param cp ContourPlot; the ContourPlot to test
* @param lane Lane; the lane on which the test GTUs are run
* @param gtuType GTUType; the type of GTU
* @param expectedZValue double; the value that getZ and getZValue should return for a valid item when no car has passed
* @param expectedZValueWithTraffic double; the value that getZ and getZValue should return a valid item where a car has
* traveled at constant speed of 50 km/h. Supply Double.NaN if the value varies but differs from the value
* expected when no car has passed
* @throws Exception when something goes wrong (should not happen)
*/
public static void standardContourTests(final ContourPlot cp, Lane lane, GTUType gtuType,
final double expectedZValue, final double expectedZValueWithTraffic) throws Exception
{
assertEquals("seriesCount should be 1", 1, cp.getSeriesCount());
assertEquals("domainOrder should be ASCENDING", DomainOrder.ASCENDING, cp.getDomainOrder());
assertEquals("indexOf always returns 0", 0, cp.indexOf(0));
assertEquals("indexOf always returns 0", 0, cp.indexOf("abc"));
assertEquals("getGroup always returns null", null, cp.getGroup());
int xBins = cp.xAxisBins();
int yBins = cp.yAxisBins();
int expectedXBins =
(int) Math.ceil((DoubleScalar.minus(ContourPlot.INITIALUPPERTIMEBOUND, ContourPlot.INITIALLOWERTIMEBOUND)
.getSI()) / ContourPlot.STANDARDTIMEGRANULARITIES[ContourPlot.STANDARDINITIALTIMEGRANULARITYINDEX]);
assertEquals("Initial xBins should be " + expectedXBins, expectedXBins, xBins);
int expectedYBins =
(int) Math.ceil(lane.getLength().getSI()
/ ContourPlot.STANDARDDISTANCEGRANULARITIES[ContourPlot.STANDARDINITIALDISTANCEGRANULARITYINDEX]);
assertEquals("yBins should be " + expectedYBins, expectedYBins, yBins);
int bins = cp.getItemCount(0);
assertEquals("Total bin count is product of xBins * yBins", xBins * yBins, bins);
// Cache the String equivalents of minimumDistance and maximumDistance, INITIALLOWERTIMEBOUND and
// INITUALUPPERTIMEBOUND
String initialLowerTimeBoundString = ContourPlot.INITIALLOWERTIMEBOUND.toString();
String initialUpperTimeBoundString = ContourPlot.INITIALUPPERTIMEBOUND.toString();
// Vary the x granularity
for (double timeGranularity : ContourPlot.STANDARDTIMEGRANULARITIES)
{
cp.actionPerformed(new ActionEvent(cp, 0, "setTimeGranularity " + timeGranularity));
for (double distanceGranularity : ContourPlot.STANDARDDISTANCEGRANULARITIES)
{
cp.actionPerformed(new ActionEvent(cp, 0, "setDistanceGranularity " + distanceGranularity));
cp.reGraph();
expectedXBins =
(int) Math.ceil((DoubleScalar.minus(ContourPlot.INITIALUPPERTIMEBOUND,
ContourPlot.INITIALLOWERTIMEBOUND).getSI()) / timeGranularity);
xBins = cp.xAxisBins();
assertEquals("Modified xBins should be " + expectedXBins, expectedXBins, xBins);
expectedYBins = (int) Math.ceil(lane.getLength().getSI() / distanceGranularity);
yBins = cp.yAxisBins();
assertEquals("Modified yBins should be " + expectedYBins, expectedYBins, yBins);
bins = cp.getItemCount(0);
assertEquals("Total bin count is product of xBins * yBins", xBins * yBins, bins);
for (int item = 0; item < bins; item++)
{
double x = cp.getXValue(0, item);
assertTrue("X should be >= " + initialLowerTimeBoundString,
x >= ContourPlot.INITIALLOWERTIMEBOUND.getSI());
assertTrue("X should be <= " + initialUpperTimeBoundString,
x <= ContourPlot.INITIALUPPERTIMEBOUND.getSI());
Number alternateX = cp.getX(0, item);
assertEquals("getXValue and getX should return things that have the same value", x,
alternateX.doubleValue(), 0.000001);
double y = cp.getYValue(0, item);
Number alternateY = cp.getY(0, item);
assertEquals("getYValue and getY should return things that have the same value", y,
alternateY.doubleValue(), 0.000001);
double z = cp.getZValue(0, item);
if (Double.isNaN(expectedZValue))
{
assertTrue("Z value should be NaN", Double.isNaN(z));
}
else
{
assertEquals("Z value should be " + expectedZValue, expectedZValue, z, 0.0001);
}
Number alternateZ = cp.getZ(0, item);
if (Double.isNaN(expectedZValue))
{
assertTrue("Alternate Z value should be NaN", Double.isNaN(alternateZ.doubleValue()));
}
else
{
assertEquals("Alternate Z value should be " + expectedZValue, expectedZValue,
alternateZ.doubleValue(), 0.0000);
}
}
try
{
cp.getXValue(0, -1);
fail("Should have thrown an Exception");
}
catch (RuntimeException e)
{
// Ignore
}
try
{
cp.getXValue(0, bins);
fail("Should have thrown an Exception");
}
catch (RuntimeException e)
{
// Ignore
}
try
{
cp.yAxisBin(-1);
fail("Should have thrown an Exception");
}
catch (RuntimeException e)
{
// Ignore
}
try
{
cp.yAxisBin(bins);
fail("Should have thrown an Exception");
}
catch (RuntimeException e)
{
// Ignore
}
}
}
// Test some ActionEvents that ContourPlot can not handle
try
{
cp.actionPerformed(new ActionEvent(cp, 0, "blabla"));
fail("Should have thrown an Exception");
}
catch (RuntimeException e)
{
// Ignore
}
try
{
cp.actionPerformed(new ActionEvent(cp, 0, "setDistanceGranularity -1"));
fail("Should have thrown an Exception");
}
catch (RuntimeException e)
{
// ignore
}
try
{
cp.actionPerformed(new ActionEvent(cp, 0, "setDistanceGranularity abc"));
fail("Should have thrown an Exception");
}
catch (RuntimeException e)
{
// ignore
}
try
{
cp.actionPerformed(new ActionEvent(cp, 0, "setDistanceGranularitIE 10")); // typo in the event name
fail("Should have thrown an Exception");
}
catch (RuntimeException e)
{
// ignore
}
// Make the time granularity a bit more reasonable
final double useTimeGranularity = 30; // [s]
cp.actionPerformed(new ActionEvent(cp, 0, "setTimeGranularity " + useTimeGranularity));
final double useDistanceGranularity =
ContourPlot.STANDARDDISTANCEGRANULARITIES[ContourPlot.STANDARDDISTANCEGRANULARITIES.length - 1];
cp.actionPerformed(new ActionEvent(cp, 0, "setDistanceGranularity " + useDistanceGranularity));
cp.reGraph();
bins = cp.getItemCount(0);
Time.Abs initialTime = new Time.Abs(0, SECOND);
Length.Rel initialPosition = new Length.Rel(100, METER);
Speed initialSpeed = new Speed(50, KM_PER_HOUR);
ContourPlotModel model = new ContourPlotModel();
SimpleSimulator simulator =
new SimpleSimulator(initialTime, new Time.Rel(0, SECOND), new Time.Rel(1800, SECOND), model);
// Create a car running 50 km.h
SequentialFixedAccelerationModel gtuFollowingModel =
new SequentialFixedAccelerationModel(simulator, new Acceleration(2.0, AccelerationUnit.METER_PER_SECOND_2));
// Make the car run at constant speed for one minute
gtuFollowingModel.addStep(new FixedAccelerationModel(new Acceleration(0, METER_PER_SECOND_2), new Time.Rel(60,
SECOND)));
// Make the car run at constant speed for another minute
gtuFollowingModel.addStep(new FixedAccelerationModel(new Acceleration(0, METER_PER_SECOND_2), new Time.Rel(600,
SECOND)));
// Make the car run at constant speed for five more minutes
gtuFollowingModel.addStep(new FixedAccelerationModel(new Acceleration(0, METER_PER_SECOND_2), new Time.Rel(300,
SECOND)));
LaneChangeModel laneChangeModel = new Egoistic();
OTSNetwork network = new OTSNetwork("network");
LaneBasedIndividualGTU car =
CarTest.makeReferenceCar("0", gtuType, lane, initialPosition, initialSpeed, simulator, gtuFollowingModel,
laneChangeModel, network);
car.getStrategicalPlanner().getDrivingCharacteristics()
.setForwardHeadwayDistance(new Length.Rel(10, LengthUnit.KILOMETER));
// Check that the initial data in the graph contains no trace of any car.
for (int item = 0; item < bins; item++)
{
double x = cp.getXValue(0, item);
assertTrue("X should be >= " + ContourPlot.INITIALLOWERTIMEBOUND,
x >= ContourPlot.INITIALLOWERTIMEBOUND.getSI());
assertTrue("X should be <= " + ContourPlot.INITIALUPPERTIMEBOUND,
x <= ContourPlot.INITIALUPPERTIMEBOUND.getSI());
Number alternateX = cp.getX(0, item);
assertEquals("getXValue and getX should return things that have the same value", x,
alternateX.doubleValue(), 0.000001);
double y = cp.getYValue(0, item);
Number alternateY = cp.getY(0, item);
assertEquals("getYValue and getY should return things that have the same value", y,
alternateY.doubleValue(), 0.000001);
double z = cp.getZValue(0, item);
if (Double.isNaN(expectedZValue))
{
assertTrue("Z value should be NaN (got " + z + ")", Double.isNaN(z));
}
else
{
assertEquals("Z value should be " + expectedZValue, expectedZValue, z, 0.0001);
}
Number alternateZ = cp.getZ(0, item);
if (Double.isNaN(expectedZValue))
{
assertTrue("Alternate Z value should be NaN", Double.isNaN(alternateZ.doubleValue()));
}
else
{
assertEquals("Alternate Z value should be " + expectedZValue, expectedZValue, alternateZ.doubleValue(),
0.0000);
}
}
// System.out.println("Running simulator from " + simulator.getSimulatorTime().get() + " to "
// + gtuFollowingModel.timeAfterCompletionOfStep(0));
double stopTime = gtuFollowingModel.timeAfterCompletionOfStep(0).si;
simulator.runUpToAndIncluding(new Time.Abs(stopTime, TimeUnit.SI));
while (simulator.isRunning())
{
try
{
Thread.sleep(10);
}
catch (InterruptedException ie)
{
ie = null; // ignore
}
}
// System.out.println("Simulator is now at " + simulator.getSimulatorTime().get());
// System.out.println("Car at start time " + car.getOperationalPlan().getStartTime() + " is at "
// + car.getPosition(car.getOperationalPlan().getStartTime()));
// System.out.println("At time " + simulator.getSimulator().getSimulatorTime().getTime() + " car is at " + car);
for (int item = 0; item < bins; item++)
{
double x = cp.getXValue(0, item);
assertTrue("X should be >= " + ContourPlot.INITIALLOWERTIMEBOUND,
x >= ContourPlot.INITIALLOWERTIMEBOUND.getSI());
assertTrue("X should be <= " + ContourPlot.INITIALUPPERTIMEBOUND,
x <= ContourPlot.INITIALUPPERTIMEBOUND.getSI());
Number alternateX = cp.getX(0, item);
assertEquals("getXValue and getX should return things that have the same value", x,
alternateX.doubleValue(), 0.000001);
double y = cp.getYValue(0, item);
Number alternateY = cp.getY(0, item);
assertEquals("getYValue and getY should return things that have the same value", y,
alternateY.doubleValue(), 0.000001);
double z = cp.getZValue(0, item);
// figure out if the car has traveled through this cell
// if (x >= 180)
// System.out.println(String.format("t=%.3f, x=%.3f z=%f, exp=%.3f, carLastEval=%s, carNextEval=%s", x, y, z,
// expectedZValue, car.getOperationalPlan().getStartTime().getSI(), car.getOperationalPlan().getEndTime()
// .getSI()));
boolean hit = false;
if (x + useTimeGranularity >= 0// car.getOperationalPlan().getStartTime().getSI()
&& x < 60)// car.getOperationalPlan().getEndTime().getSI())
{
// the car MAY have contributed to this cell
Time.Abs cellStartTime =
new Time.Abs(Math.max(car.getOperationalPlan().getStartTime().getSI(), x), SECOND);
Time.Abs cellEndTime =
new Time.Abs(Math.min(car.getOperationalPlan().getEndTime().getSI(), x + useTimeGranularity),
SECOND);
// System.out.println("cellStartTime=" + cellStartTime + ", cellEndTime=" + cellEndTime);
// The next if statement is the problem
// if (cellStartTime.lt(cellEndTime)
// && car.position(lane, car.getRear(), cellStartTime).getSI() <= y + useDistanceGranularity
// && car.position(lane, car.getRear(), cellEndTime).getSI() >= y)
double xAtCellStartTime = initialPosition.si + initialSpeed.si * cellStartTime.si;
double xAtCellEndTime = initialPosition.si + initialSpeed.si * cellEndTime.si;
if (xAtCellStartTime < y + useDistanceGranularity && xAtCellEndTime >= y)
{
hit = true;
}
}
// System.out.println(String.format(
// "hit=%s, t=%.3f, x=%.3f z=%f, exp=%.3f, carLastEval=%s, carNextEval=%s, simulatortime=%s", hit, x, y, z,
// expectedZValue, car.getOperationalPlan().getStartTime().getSI(), car.getOperationalPlan().getEndTime()
// .getSI(), car.getSimulator().getSimulatorTime().get()));
Number alternateZ = cp.getZ(0, item);
if (hit)
{
if (!Double.isNaN(expectedZValueWithTraffic))
{
if (Double.isNaN(z))
{
printMatrix(cp, 0, 10, 0, 10);
System.out.println("Oops - z is NaN, expected z value with traffic is "
+ expectedZValueWithTraffic);
}
assertEquals("Z value should be " + expectedZValueWithTraffic, expectedZValueWithTraffic, z, 0.0001);
assertEquals("Z value should be " + expectedZValueWithTraffic, expectedZValueWithTraffic,
alternateZ.doubleValue(), 0.0001);
}
else
{
if (Double.isNaN(expectedZValue))
{ // FIXME looks wrong / PK
assertFalse("Z value should not be NaN", Double.isNaN(z));
}
}
}
else
{
if (Double.isNaN(expectedZValue))
{
// if (!Double.isNaN(z))
// {
// System.out.println("Oops");
// Time.Abs cellStartTime = new Time.Abs(x, SECOND);
// Time.Abs cellEndTime =
// new Time.Abs(Math.min(car.getOperationalPlan().getEndTime().getSI(), x + useTimeGranularity),
// SECOND);
// double xAtCellStartTime = initialPosition.si + initialSpeed.si * cellStartTime.si;
// double xAtCellEndTime = initialPosition.si + initialSpeed.si * cellEndTime.si;
// System.out.println("cellStartTime=" + cellStartTime + " cellEndTime=" + cellEndTime
// + " xAtCellStartTime=" + xAtCellStartTime + " xAtCellEndTime=" + xAtCellEndTime);
// double cellX = cp.getXValue(0, item);
// double cellY = cp.getYValue(0, item);
// double cellZ = cp.getZValue(0, item);
// System.out.println("cellX=" + cellX + " cellY=" + cellY + " cellZ=" + cellZ + " timeGranularity="
// + useTimeGranularity + " distanceGranularity=" + useDistanceGranularity);
// cp.getZValue(0, item);
// }
assertTrue("Z value should be NaN", Double.isNaN(z));
}
else
{
assertEquals("Z value should be " + expectedZValue, expectedZValue, z, 0.0001);
}
if (Double.isNaN(expectedZValue))
{
assertTrue("Alternate Z value should be NaN", Double.isNaN(alternateZ.doubleValue()));
}
else
{
assertEquals("Alternate Z value should be " + expectedZValue, expectedZValue,
alternateZ.doubleValue(), 0.0000);
}
}
}
// System.out.println("Running simulator from " + simulator.getSimulatorTime().get() + " to "
// + gtuFollowingModel.timeAfterCompletionOfStep(1));
stopTime = gtuFollowingModel.timeAfterCompletionOfStep(1).si;
simulator.runUpToAndIncluding(new Time.Abs(stopTime, TimeUnit.SI));
while (simulator.isRunning())
{
try
{
Thread.sleep(10);
}
catch (InterruptedException ie)
{
ie = null; // ignore
}
}
// System.out.println("Simulator is now at " + simulator.getSimulatorTime().get());
// Check that the time range has expanded
xBins = cp.xAxisBins();
bins = cp.getItemCount(0);
double observedHighestTime = Double.MIN_VALUE;
for (int bin = 0; bin < bins; bin++)
{
double xValue = cp.getXValue(0, bin);
if (xValue > observedHighestTime)
{
observedHighestTime = xValue;
}
}
double expectedHighestTime =
Math.floor((car.getSimulator().getSimulatorTime().get().si - 0.001) / useTimeGranularity)
* useTimeGranularity;
assertEquals("Time range should run up to " + expectedHighestTime, expectedHighestTime, observedHighestTime,
0.0001);
// Check the updateHint method in the PointerHandler
// First get the panel that stores the result of updateHint (this is ugly)
JLabel hintPanel = null;
ChartPanel chartPanel = null;
for (Component c0 : cp.getComponents())
{
for (Component c1 : ((Container) c0).getComponents())
{
if (c1 instanceof Container)
{
for (Component c2 : ((Container) c1).getComponents())
{
// System.out.println("c2 is " + c2);
if (c2 instanceof Container)
{
for (Component c3 : ((Container) c2).getComponents())
{
// System.out.println("c3 is " + c3);
if (c3 instanceof JLabel)
{
if (null == hintPanel)
{
hintPanel = (JLabel) c3;
}
else
{
fail("There should be only one JPanel in a ContourPlot");
}
}
if (c3 instanceof ChartPanel)
{
if (null == chartPanel)
{
chartPanel = (ChartPanel) c3;
}
else
{
fail("There should be only one ChartPanel in a ContourPlot");
}
}
}
}
}
}
}
}
if (null == hintPanel)
{
fail("Could not find a JLabel in ContourPlot");
}
if (null == chartPanel)
{
fail("Could not find a ChartPanel in ContourPlot");
}
assertEquals("Initially the text should be a single space", " ", hintPanel.getText());
PointerHandler ph = null;
for (MouseListener ml : chartPanel.getMouseListeners())
{
if (ml instanceof PointerHandler)
{
if (null == ph)
{
ph = (PointerHandler) ml;
}
else
{
fail("There should be only one PointerHandler on the chartPanel");
}
}
}
if (null == ph)
{
fail("Could not find the PointerHandler for the chartPanel");
}
ph.updateHint(1, 2);
// System.out.println("Hint text is now " + hintPanel.getText());
assertFalse("Hint should not be a single space", " ".equals(hintPanel.getText()));
ph.updateHint(Double.NaN, Double.NaN);
assertEquals("The text should again be a single space", " ", hintPanel.getText());
}
/**
* Run the DensityContourPlot stand-alone for profiling.
* @param args String[]; the command line arguments (not used)
* @throws Exception when something goes wrong (should not happen)
*/
public static void main(final String[] args) throws Exception
{
ContourPlotTest cpt = new ContourPlotTest();
System.out.println("Click the OK button");
JOptionPane.showMessageDialog(null, "ContourPlot", "Start experiment", JOptionPane.INFORMATION_MESSAGE);
System.out.println("Running ...");
cpt.densityContourTest();
System.out.println("Finished");
}
}
/**
*
* Copyright (c) 2013-2015 Delft University of Technology, PO Box 5, 2600 AA, Delft, the Netherlands. All rights reserved.
* BSD-style license. See OpenTrafficSim License.
*
* $LastChangedDate: 2015-09-14 01:33:02 +0200 (Mon, 14 Sep 2015) $, @version $Revision: 1401 $, by $Author: averbraeck $,
* initial version feb. 2015
* @author Peter Knoppers
*/
class ContourPlotModel implements OTSModelInterface
{
/** */
private static final long serialVersionUID = 20150209L;
/** {@inheritDoc} */
@Override
public void constructModel(
SimulatorInterface, DoubleScalar.Rel, OTSSimTimeDouble> simulator)
throws SimRuntimeException
{
// NOT USED
}
/** {@inheritDoc} */
@Override
public SimulatorInterface, DoubleScalar.Rel, OTSSimTimeDouble> getSimulator()
{
return null;
}
}