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/* ===========================================================
* JFreeChart : a free chart library for the Java(tm) platform
* ===========================================================
*
* (C) Copyright 2000-present, by David Gilbert and Contributors.
*
* Project Info: http://www.jfree.org/jfreechart/index.html
*
* This library is free software; you can redistribute it and/or modify it
* under the terms of the GNU Lesser General Public License as published by
* the Free Software Foundation; either version 2.1 of the License, or
* (at your option) any later version.
*
* This library 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 Lesser General Public
* License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301,
* USA.
*
* [Oracle and Java are registered trademarks of Oracle and/or its affiliates.
* Other names may be trademarks of their respective owners.]
*
* ---------------------------
* StackedXYAreaRenderer2.java
* ---------------------------
* (C) Copyright 2004-present, by David Gilbert and Contributors.
*
* Original Author: David Gilbert, based on
* the StackedXYAreaRenderer class by Richard Atkinson;
* Contributor(s): Ulrich Voigt (patch #312);
*
*/
package org.jfree.chart.renderer.xy;
import java.awt.Graphics2D;
import java.awt.Paint;
import java.awt.geom.Area;
import java.awt.geom.GeneralPath;
import java.awt.geom.Rectangle2D;
import java.io.Serializable;
import org.jfree.chart.axis.ValueAxis;
import org.jfree.chart.entity.EntityCollection;
import org.jfree.chart.event.RendererChangeEvent;
import org.jfree.chart.labels.XYToolTipGenerator;
import org.jfree.chart.plot.CrosshairState;
import org.jfree.chart.plot.PlotOrientation;
import org.jfree.chart.plot.PlotRenderingInfo;
import org.jfree.chart.plot.XYPlot;
import org.jfree.chart.ui.RectangleEdge;
import org.jfree.chart.urls.XYURLGenerator;
import org.jfree.chart.util.PublicCloneable;
import org.jfree.data.Range;
import org.jfree.data.xy.TableXYDataset;
import org.jfree.data.xy.XYDataset;
/**
* A stacked area renderer for the {@link XYPlot} class.
* The example shown here is generated by the
* {@code StackedXYAreaChartDemo2.java} program included in the
* JFreeChart demo collection:
*
*
*/
public class StackedXYAreaRenderer2 extends XYAreaRenderer2
implements Cloneable, PublicCloneable, Serializable {
/** For serialization. */
private static final long serialVersionUID = 7752676509764539182L;
/**
* This flag controls whether or not the x-coordinates (in Java2D space)
* are rounded to integers. When set to true, this can avoid the vertical
* striping that anti-aliasing can generate. However, the rounding may not
* be appropriate for output in high resolution formats (for example,
* vector graphics formats such as SVG and PDF).
*/
private boolean roundXCoordinates;
/**
* Creates a new renderer.
*/
public StackedXYAreaRenderer2() {
this(null, null);
}
/**
* Constructs a new renderer.
*
* @param labelGenerator the tool tip generator to use ({@code null}
* permitted).
* @param urlGenerator the URL generator ({@code null} permitted).
*/
public StackedXYAreaRenderer2(XYToolTipGenerator labelGenerator,
XYURLGenerator urlGenerator) {
super(labelGenerator, urlGenerator);
this.roundXCoordinates = true;
}
/**
* Returns the flag that controls whether or not the x-coordinates (in
* Java2D space) are rounded to integer values.
*
* @return The flag.
*
* @see #setRoundXCoordinates(boolean)
*/
public boolean getRoundXCoordinates() {
return this.roundXCoordinates;
}
/**
* Sets the flag that controls whether or not the x-coordinates (in
* Java2D space) are rounded to integer values, and sends a
* {@link RendererChangeEvent} to all registered listeners.
*
* @param round the new flag value.
*
* @see #getRoundXCoordinates()
*/
public void setRoundXCoordinates(boolean round) {
this.roundXCoordinates = round;
fireChangeEvent();
}
/**
* Returns the range of values the renderer requires to display all the
* items from the specified dataset.
*
* @param dataset the dataset ({@code null} permitted).
*
* @return The range (or {@code null} if the dataset is {@code null} or
* empty).
*/
@Override
public Range findRangeBounds(XYDataset dataset) {
if (dataset == null) {
return null;
}
double min = Double.POSITIVE_INFINITY;
double max = Double.NEGATIVE_INFINITY;
TableXYDataset d = (TableXYDataset) dataset;
int itemCount = d.getItemCount();
for (int i = 0; i < itemCount; i++) {
double[] stackValues = getStackValues((TableXYDataset) dataset,
d.getSeriesCount(), i);
min = Math.min(min, stackValues[0]);
max = Math.max(max, stackValues[1]);
}
if (min == Double.POSITIVE_INFINITY) {
return null;
}
return new Range(min, max);
}
/**
* Returns the number of passes required by the renderer.
*
* @return 1.
*/
@Override
public int getPassCount() {
return 1;
}
/**
* Draws the visual representation of a single data item.
*
* @param g2 the graphics device.
* @param state the renderer state.
* @param dataArea the area within which the data is being drawn.
* @param info collects information about the drawing.
* @param plot the plot (can be used to obtain standard color information
* etc).
* @param domainAxis the domain axis.
* @param rangeAxis the range axis.
* @param dataset the dataset.
* @param series the series index (zero-based).
* @param item the item index (zero-based).
* @param crosshairState information about crosshairs on a plot.
* @param pass the pass index.
*/
@Override
public void drawItem(Graphics2D g2, XYItemRendererState state,
Rectangle2D dataArea, PlotRenderingInfo info, XYPlot plot,
ValueAxis domainAxis, ValueAxis rangeAxis, XYDataset dataset,
int series, int item, CrosshairState crosshairState, int pass) {
// setup for collecting optional entity info...
EntityCollection entities = null;
if (info != null) {
entities = info.getOwner().getEntityCollection();
}
TableXYDataset tdataset = (TableXYDataset) dataset;
PlotOrientation orientation = plot.getOrientation();
// get the data point...
double x1 = dataset.getXValue(series, item);
double y1 = dataset.getYValue(series, item);
if (Double.isNaN(y1)) {
y1 = 0.0;
}
double[] stack1 = getStackValues(tdataset, series, item);
// get the previous point and the next point so we can calculate a
// "hot spot" for the area (used by the chart entity)...
double x0 = dataset.getXValue(series, Math.max(item - 1, 0));
double y0 = dataset.getYValue(series, Math.max(item - 1, 0));
if (Double.isNaN(y0)) {
y0 = 0.0;
}
double[] stack0 = getStackValues(tdataset, series, Math.max(item - 1,
0));
int itemCount = dataset.getItemCount(series);
double x2 = dataset.getXValue(series, Math.min(item + 1,
itemCount - 1));
double y2 = dataset.getYValue(series, Math.min(item + 1,
itemCount - 1));
if (Double.isNaN(y2)) {
y2 = 0.0;
}
double[] stack2 = getStackValues(tdataset, series, Math.min(item + 1,
itemCount - 1));
double xleft = (x0 + x1) / 2.0;
double xright = (x1 + x2) / 2.0;
double[] stackLeft = averageStackValues(stack0, stack1);
double[] stackRight = averageStackValues(stack1, stack2);
double[] adjStackLeft = adjustedStackValues(stack0, stack1);
double[] adjStackRight = adjustedStackValues(stack1, stack2);
RectangleEdge edge0 = plot.getDomainAxisEdge();
float transX1 = (float) domainAxis.valueToJava2D(x1, dataArea, edge0);
float transXLeft = (float) domainAxis.valueToJava2D(xleft, dataArea,
edge0);
float transXRight = (float) domainAxis.valueToJava2D(xright, dataArea,
edge0);
if (this.roundXCoordinates) {
transX1 = Math.round(transX1);
transXLeft = Math.round(transXLeft);
transXRight = Math.round(transXRight);
}
float transY1;
RectangleEdge edge1 = plot.getRangeAxisEdge();
GeneralPath left = new GeneralPath();
GeneralPath right = new GeneralPath();
if (y1 >= 0.0) { // handle positive value
transY1 = (float) rangeAxis.valueToJava2D(y1 + stack1[1], dataArea,
edge1);
float transStack1 = (float) rangeAxis.valueToJava2D(stack1[1],
dataArea, edge1);
float transStackLeft = (float) rangeAxis.valueToJava2D(
adjStackLeft[1], dataArea, edge1);
// LEFT POLYGON
if (y0 >= 0.0) {
double yleft = (y0 + y1) / 2.0 + stackLeft[1];
float transYLeft
= (float) rangeAxis.valueToJava2D(yleft, dataArea, edge1);
if (orientation == PlotOrientation.VERTICAL) {
left.moveTo(transX1, transY1);
left.lineTo(transX1, transStack1);
left.lineTo(transXLeft, transStackLeft);
left.lineTo(transXLeft, transYLeft);
} else {
left.moveTo(transY1, transX1);
left.lineTo(transStack1, transX1);
left.lineTo(transStackLeft, transXLeft);
left.lineTo(transYLeft, transXLeft);
}
left.closePath();
} else {
if (orientation == PlotOrientation.VERTICAL) {
left.moveTo(transX1, transStack1);
left.lineTo(transX1, transY1);
left.lineTo(transXLeft, transStackLeft);
} else {
left.moveTo(transStack1, transX1);
left.lineTo(transY1, transX1);
left.lineTo(transStackLeft, transXLeft);
}
left.closePath();
}
float transStackRight = (float) rangeAxis.valueToJava2D(
adjStackRight[1], dataArea, edge1);
// RIGHT POLYGON
if (y2 >= 0.0) {
double yright = (y1 + y2) / 2.0 + stackRight[1];
float transYRight
= (float) rangeAxis.valueToJava2D(yright, dataArea, edge1);
if (orientation == PlotOrientation.VERTICAL) {
right.moveTo(transX1, transStack1);
right.lineTo(transX1, transY1);
right.lineTo(transXRight, transYRight);
right.lineTo(transXRight, transStackRight);
} else {
right.moveTo(transStack1, transX1);
right.lineTo(transY1, transX1);
right.lineTo(transYRight, transXRight);
right.lineTo(transStackRight, transXRight);
}
right.closePath();
}
else {
if (orientation == PlotOrientation.VERTICAL) {
right.moveTo(transX1, transStack1);
right.lineTo(transX1, transY1);
right.lineTo(transXRight, transStackRight);
} else {
right.moveTo(transStack1, transX1);
right.lineTo(transY1, transX1);
right.lineTo(transStackRight, transXRight);
}
right.closePath();
}
}
else { // handle negative value
transY1 = (float) rangeAxis.valueToJava2D(y1 + stack1[0], dataArea,
edge1);
float transStack1 = (float) rangeAxis.valueToJava2D(stack1[0],
dataArea, edge1);
float transStackLeft = (float) rangeAxis.valueToJava2D(
adjStackLeft[0], dataArea, edge1);
// LEFT POLYGON
if (y0 >= 0.0) {
if (orientation == PlotOrientation.VERTICAL) {
left.moveTo(transX1, transStack1);
left.lineTo(transX1, transY1);
left.lineTo(transXLeft, transStackLeft);
} else {
left.moveTo(transStack1, transX1);
left.lineTo(transY1, transX1);
left.lineTo(transStackLeft, transXLeft);
}
left.clone();
} else {
double yleft = (y0 + y1) / 2.0 + stackLeft[0];
float transYLeft = (float) rangeAxis.valueToJava2D(yleft,
dataArea, edge1);
if (orientation == PlotOrientation.VERTICAL) {
left.moveTo(transX1, transY1);
left.lineTo(transX1, transStack1);
left.lineTo(transXLeft, transStackLeft);
left.lineTo(transXLeft, transYLeft);
} else {
left.moveTo(transY1, transX1);
left.lineTo(transStack1, transX1);
left.lineTo(transStackLeft, transXLeft);
left.lineTo(transYLeft, transXLeft);
}
left.closePath();
}
float transStackRight = (float) rangeAxis.valueToJava2D(
adjStackRight[0], dataArea, edge1);
// RIGHT POLYGON
if (y2 >= 0.0) {
if (orientation == PlotOrientation.VERTICAL) {
right.moveTo(transX1, transStack1);
right.lineTo(transX1, transY1);
right.lineTo(transXRight, transStackRight);
} else {
right.moveTo(transStack1, transX1);
right.lineTo(transY1, transX1);
right.lineTo(transStackRight, transXRight);
}
right.closePath();
} else {
double yright = (y1 + y2) / 2.0 + stackRight[0];
float transYRight = (float) rangeAxis.valueToJava2D(yright,
dataArea, edge1);
if (orientation == PlotOrientation.VERTICAL) {
right.moveTo(transX1, transStack1);
right.lineTo(transX1, transY1);
right.lineTo(transXRight, transYRight);
right.lineTo(transXRight, transStackRight);
} else {
right.moveTo(transStack1, transX1);
right.lineTo(transY1, transX1);
right.lineTo(transYRight, transXRight);
right.lineTo(transStackRight, transXRight);
}
right.closePath();
}
}
// Get series Paint and Stroke
Paint itemPaint = getItemPaint(series, item);
if (pass == 0) {
g2.setPaint(itemPaint);
g2.fill(left);
g2.fill(right);
}
// add an entity for the item...
if (entities != null) {
// Create the entity area and limit it to the data area
Area dataAreaHotspot = new Area(left);
dataAreaHotspot.add(new Area(right));
dataAreaHotspot.intersect(new Area(dataArea));
if (!dataAreaHotspot.isEmpty()) {
addEntity(entities, dataAreaHotspot, dataset, series, item,
0.0, 0.0);
}
}
}
/**
* Calculates the stacked values (one positive and one negative) of all
* series up to, but not including, {@code series} for the specified
* item. It returns [0.0, 0.0] if {@code series} is the first series.
*
* @param dataset the dataset ({@code null} not permitted).
* @param series the series index.
* @param index the item index.
*
* @return An array containing the cumulative negative and positive values
* for all series values up to but excluding {@code series}
* for {@code index}.
*/
private double[] getStackValues(TableXYDataset dataset,
int series, int index) {
double[] result = new double[2];
for (int i = 0; i < series; i++) {
double v = dataset.getYValue(i, index);
if (!Double.isNaN(v)) {
if (v >= 0.0) {
result[1] += v;
}
else {
result[0] += v;
}
}
}
return result;
}
/**
* Returns a pair of "stack" values calculated as the mean of the two
* specified stack value pairs.
*
* @param stack1 the first stack pair.
* @param stack2 the second stack pair.
*
* @return A pair of average stack values.
*/
private double[] averageStackValues(double[] stack1, double[] stack2) {
double[] result = new double[2];
result[0] = (stack1[0] + stack2[0]) / 2.0;
result[1] = (stack1[1] + stack2[1]) / 2.0;
return result;
}
/**
* Calculates adjusted stack values from the supplied values. The value is
* the mean of the supplied values, unless either of the supplied values
* is zero, in which case the adjusted value is zero also.
*
* @param stack1 the first stack pair.
* @param stack2 the second stack pair.
*
* @return A pair of average stack values.
*/
private double[] adjustedStackValues(double[] stack1, double[] stack2) {
double[] result = new double[2];
if (stack1[0] == 0.0 || stack2[0] == 0.0) {
result[0] = 0.0;
}
else {
result[0] = (stack1[0] + stack2[0]) / 2.0;
}
if (stack1[1] == 0.0 || stack2[1] == 0.0) {
result[1] = 0.0;
}
else {
result[1] = (stack1[1] + stack2[1]) / 2.0;
}
return result;
}
/**
* Tests this renderer for equality with an arbitrary object.
*
* @param obj the object ({@code null} permitted).
*
* @return A boolean.
*/
@Override
public boolean equals(Object obj) {
if (obj == this) {
return true;
}
if (!(obj instanceof StackedXYAreaRenderer2)) {
return false;
}
StackedXYAreaRenderer2 that = (StackedXYAreaRenderer2) obj;
if (this.roundXCoordinates != that.roundXCoordinates) {
return false;
}
return super.equals(obj);
}
/**
* Returns a clone of the renderer.
*
* @return A clone.
*
* @throws CloneNotSupportedException if the renderer cannot be cloned.
*/
@Override
public Object clone() throws CloneNotSupportedException {
return super.clone();
}
}
*/
public class StackedXYAreaRenderer2 extends XYAreaRenderer2
implements Cloneable, PublicCloneable, Serializable {
/** For serialization. */
private static final long serialVersionUID = 7752676509764539182L;
/**
* This flag controls whether or not the x-coordinates (in Java2D space)
* are rounded to integers. When set to true, this can avoid the vertical
* striping that anti-aliasing can generate. However, the rounding may not
* be appropriate for output in high resolution formats (for example,
* vector graphics formats such as SVG and PDF).
*/
private boolean roundXCoordinates;
/**
* Creates a new renderer.
*/
public StackedXYAreaRenderer2() {
this(null, null);
}
/**
* Constructs a new renderer.
*
* @param labelGenerator the tool tip generator to use ({@code null}
* permitted).
* @param urlGenerator the URL generator ({@code null} permitted).
*/
public StackedXYAreaRenderer2(XYToolTipGenerator labelGenerator,
XYURLGenerator urlGenerator) {
super(labelGenerator, urlGenerator);
this.roundXCoordinates = true;
}
/**
* Returns the flag that controls whether or not the x-coordinates (in
* Java2D space) are rounded to integer values.
*
* @return The flag.
*
* @see #setRoundXCoordinates(boolean)
*/
public boolean getRoundXCoordinates() {
return this.roundXCoordinates;
}
/**
* Sets the flag that controls whether or not the x-coordinates (in
* Java2D space) are rounded to integer values, and sends a
* {@link RendererChangeEvent} to all registered listeners.
*
* @param round the new flag value.
*
* @see #getRoundXCoordinates()
*/
public void setRoundXCoordinates(boolean round) {
this.roundXCoordinates = round;
fireChangeEvent();
}
/**
* Returns the range of values the renderer requires to display all the
* items from the specified dataset.
*
* @param dataset the dataset ({@code null} permitted).
*
* @return The range (or {@code null} if the dataset is {@code null} or
* empty).
*/
@Override
public Range findRangeBounds(XYDataset dataset) {
if (dataset == null) {
return null;
}
double min = Double.POSITIVE_INFINITY;
double max = Double.NEGATIVE_INFINITY;
TableXYDataset d = (TableXYDataset) dataset;
int itemCount = d.getItemCount();
for (int i = 0; i < itemCount; i++) {
double[] stackValues = getStackValues((TableXYDataset) dataset,
d.getSeriesCount(), i);
min = Math.min(min, stackValues[0]);
max = Math.max(max, stackValues[1]);
}
if (min == Double.POSITIVE_INFINITY) {
return null;
}
return new Range(min, max);
}
/**
* Returns the number of passes required by the renderer.
*
* @return 1.
*/
@Override
public int getPassCount() {
return 1;
}
/**
* Draws the visual representation of a single data item.
*
* @param g2 the graphics device.
* @param state the renderer state.
* @param dataArea the area within which the data is being drawn.
* @param info collects information about the drawing.
* @param plot the plot (can be used to obtain standard color information
* etc).
* @param domainAxis the domain axis.
* @param rangeAxis the range axis.
* @param dataset the dataset.
* @param series the series index (zero-based).
* @param item the item index (zero-based).
* @param crosshairState information about crosshairs on a plot.
* @param pass the pass index.
*/
@Override
public void drawItem(Graphics2D g2, XYItemRendererState state,
Rectangle2D dataArea, PlotRenderingInfo info, XYPlot plot,
ValueAxis domainAxis, ValueAxis rangeAxis, XYDataset dataset,
int series, int item, CrosshairState crosshairState, int pass) {
// setup for collecting optional entity info...
EntityCollection entities = null;
if (info != null) {
entities = info.getOwner().getEntityCollection();
}
TableXYDataset tdataset = (TableXYDataset) dataset;
PlotOrientation orientation = plot.getOrientation();
// get the data point...
double x1 = dataset.getXValue(series, item);
double y1 = dataset.getYValue(series, item);
if (Double.isNaN(y1)) {
y1 = 0.0;
}
double[] stack1 = getStackValues(tdataset, series, item);
// get the previous point and the next point so we can calculate a
// "hot spot" for the area (used by the chart entity)...
double x0 = dataset.getXValue(series, Math.max(item - 1, 0));
double y0 = dataset.getYValue(series, Math.max(item - 1, 0));
if (Double.isNaN(y0)) {
y0 = 0.0;
}
double[] stack0 = getStackValues(tdataset, series, Math.max(item - 1,
0));
int itemCount = dataset.getItemCount(series);
double x2 = dataset.getXValue(series, Math.min(item + 1,
itemCount - 1));
double y2 = dataset.getYValue(series, Math.min(item + 1,
itemCount - 1));
if (Double.isNaN(y2)) {
y2 = 0.0;
}
double[] stack2 = getStackValues(tdataset, series, Math.min(item + 1,
itemCount - 1));
double xleft = (x0 + x1) / 2.0;
double xright = (x1 + x2) / 2.0;
double[] stackLeft = averageStackValues(stack0, stack1);
double[] stackRight = averageStackValues(stack1, stack2);
double[] adjStackLeft = adjustedStackValues(stack0, stack1);
double[] adjStackRight = adjustedStackValues(stack1, stack2);
RectangleEdge edge0 = plot.getDomainAxisEdge();
float transX1 = (float) domainAxis.valueToJava2D(x1, dataArea, edge0);
float transXLeft = (float) domainAxis.valueToJava2D(xleft, dataArea,
edge0);
float transXRight = (float) domainAxis.valueToJava2D(xright, dataArea,
edge0);
if (this.roundXCoordinates) {
transX1 = Math.round(transX1);
transXLeft = Math.round(transXLeft);
transXRight = Math.round(transXRight);
}
float transY1;
RectangleEdge edge1 = plot.getRangeAxisEdge();
GeneralPath left = new GeneralPath();
GeneralPath right = new GeneralPath();
if (y1 >= 0.0) { // handle positive value
transY1 = (float) rangeAxis.valueToJava2D(y1 + stack1[1], dataArea,
edge1);
float transStack1 = (float) rangeAxis.valueToJava2D(stack1[1],
dataArea, edge1);
float transStackLeft = (float) rangeAxis.valueToJava2D(
adjStackLeft[1], dataArea, edge1);
// LEFT POLYGON
if (y0 >= 0.0) {
double yleft = (y0 + y1) / 2.0 + stackLeft[1];
float transYLeft
= (float) rangeAxis.valueToJava2D(yleft, dataArea, edge1);
if (orientation == PlotOrientation.VERTICAL) {
left.moveTo(transX1, transY1);
left.lineTo(transX1, transStack1);
left.lineTo(transXLeft, transStackLeft);
left.lineTo(transXLeft, transYLeft);
} else {
left.moveTo(transY1, transX1);
left.lineTo(transStack1, transX1);
left.lineTo(transStackLeft, transXLeft);
left.lineTo(transYLeft, transXLeft);
}
left.closePath();
} else {
if (orientation == PlotOrientation.VERTICAL) {
left.moveTo(transX1, transStack1);
left.lineTo(transX1, transY1);
left.lineTo(transXLeft, transStackLeft);
} else {
left.moveTo(transStack1, transX1);
left.lineTo(transY1, transX1);
left.lineTo(transStackLeft, transXLeft);
}
left.closePath();
}
float transStackRight = (float) rangeAxis.valueToJava2D(
adjStackRight[1], dataArea, edge1);
// RIGHT POLYGON
if (y2 >= 0.0) {
double yright = (y1 + y2) / 2.0 + stackRight[1];
float transYRight
= (float) rangeAxis.valueToJava2D(yright, dataArea, edge1);
if (orientation == PlotOrientation.VERTICAL) {
right.moveTo(transX1, transStack1);
right.lineTo(transX1, transY1);
right.lineTo(transXRight, transYRight);
right.lineTo(transXRight, transStackRight);
} else {
right.moveTo(transStack1, transX1);
right.lineTo(transY1, transX1);
right.lineTo(transYRight, transXRight);
right.lineTo(transStackRight, transXRight);
}
right.closePath();
}
else {
if (orientation == PlotOrientation.VERTICAL) {
right.moveTo(transX1, transStack1);
right.lineTo(transX1, transY1);
right.lineTo(transXRight, transStackRight);
} else {
right.moveTo(transStack1, transX1);
right.lineTo(transY1, transX1);
right.lineTo(transStackRight, transXRight);
}
right.closePath();
}
}
else { // handle negative value
transY1 = (float) rangeAxis.valueToJava2D(y1 + stack1[0], dataArea,
edge1);
float transStack1 = (float) rangeAxis.valueToJava2D(stack1[0],
dataArea, edge1);
float transStackLeft = (float) rangeAxis.valueToJava2D(
adjStackLeft[0], dataArea, edge1);
// LEFT POLYGON
if (y0 >= 0.0) {
if (orientation == PlotOrientation.VERTICAL) {
left.moveTo(transX1, transStack1);
left.lineTo(transX1, transY1);
left.lineTo(transXLeft, transStackLeft);
} else {
left.moveTo(transStack1, transX1);
left.lineTo(transY1, transX1);
left.lineTo(transStackLeft, transXLeft);
}
left.clone();
} else {
double yleft = (y0 + y1) / 2.0 + stackLeft[0];
float transYLeft = (float) rangeAxis.valueToJava2D(yleft,
dataArea, edge1);
if (orientation == PlotOrientation.VERTICAL) {
left.moveTo(transX1, transY1);
left.lineTo(transX1, transStack1);
left.lineTo(transXLeft, transStackLeft);
left.lineTo(transXLeft, transYLeft);
} else {
left.moveTo(transY1, transX1);
left.lineTo(transStack1, transX1);
left.lineTo(transStackLeft, transXLeft);
left.lineTo(transYLeft, transXLeft);
}
left.closePath();
}
float transStackRight = (float) rangeAxis.valueToJava2D(
adjStackRight[0], dataArea, edge1);
// RIGHT POLYGON
if (y2 >= 0.0) {
if (orientation == PlotOrientation.VERTICAL) {
right.moveTo(transX1, transStack1);
right.lineTo(transX1, transY1);
right.lineTo(transXRight, transStackRight);
} else {
right.moveTo(transStack1, transX1);
right.lineTo(transY1, transX1);
right.lineTo(transStackRight, transXRight);
}
right.closePath();
} else {
double yright = (y1 + y2) / 2.0 + stackRight[0];
float transYRight = (float) rangeAxis.valueToJava2D(yright,
dataArea, edge1);
if (orientation == PlotOrientation.VERTICAL) {
right.moveTo(transX1, transStack1);
right.lineTo(transX1, transY1);
right.lineTo(transXRight, transYRight);
right.lineTo(transXRight, transStackRight);
} else {
right.moveTo(transStack1, transX1);
right.lineTo(transY1, transX1);
right.lineTo(transYRight, transXRight);
right.lineTo(transStackRight, transXRight);
}
right.closePath();
}
}
// Get series Paint and Stroke
Paint itemPaint = getItemPaint(series, item);
if (pass == 0) {
g2.setPaint(itemPaint);
g2.fill(left);
g2.fill(right);
}
// add an entity for the item...
if (entities != null) {
// Create the entity area and limit it to the data area
Area dataAreaHotspot = new Area(left);
dataAreaHotspot.add(new Area(right));
dataAreaHotspot.intersect(new Area(dataArea));
if (!dataAreaHotspot.isEmpty()) {
addEntity(entities, dataAreaHotspot, dataset, series, item,
0.0, 0.0);
}
}
}
/**
* Calculates the stacked values (one positive and one negative) of all
* series up to, but not including, {@code series} for the specified
* item. It returns [0.0, 0.0] if {@code series} is the first series.
*
* @param dataset the dataset ({@code null} not permitted).
* @param series the series index.
* @param index the item index.
*
* @return An array containing the cumulative negative and positive values
* for all series values up to but excluding {@code series}
* for {@code index}.
*/
private double[] getStackValues(TableXYDataset dataset,
int series, int index) {
double[] result = new double[2];
for (int i = 0; i < series; i++) {
double v = dataset.getYValue(i, index);
if (!Double.isNaN(v)) {
if (v >= 0.0) {
result[1] += v;
}
else {
result[0] += v;
}
}
}
return result;
}
/**
* Returns a pair of "stack" values calculated as the mean of the two
* specified stack value pairs.
*
* @param stack1 the first stack pair.
* @param stack2 the second stack pair.
*
* @return A pair of average stack values.
*/
private double[] averageStackValues(double[] stack1, double[] stack2) {
double[] result = new double[2];
result[0] = (stack1[0] + stack2[0]) / 2.0;
result[1] = (stack1[1] + stack2[1]) / 2.0;
return result;
}
/**
* Calculates adjusted stack values from the supplied values. The value is
* the mean of the supplied values, unless either of the supplied values
* is zero, in which case the adjusted value is zero also.
*
* @param stack1 the first stack pair.
* @param stack2 the second stack pair.
*
* @return A pair of average stack values.
*/
private double[] adjustedStackValues(double[] stack1, double[] stack2) {
double[] result = new double[2];
if (stack1[0] == 0.0 || stack2[0] == 0.0) {
result[0] = 0.0;
}
else {
result[0] = (stack1[0] + stack2[0]) / 2.0;
}
if (stack1[1] == 0.0 || stack2[1] == 0.0) {
result[1] = 0.0;
}
else {
result[1] = (stack1[1] + stack2[1]) / 2.0;
}
return result;
}
/**
* Tests this renderer for equality with an arbitrary object.
*
* @param obj the object ({@code null} permitted).
*
* @return A boolean.
*/
@Override
public boolean equals(Object obj) {
if (obj == this) {
return true;
}
if (!(obj instanceof StackedXYAreaRenderer2)) {
return false;
}
StackedXYAreaRenderer2 that = (StackedXYAreaRenderer2) obj;
if (this.roundXCoordinates != that.roundXCoordinates) {
return false;
}
return super.equals(obj);
}
/**
* Returns a clone of the renderer.
*
* @return A clone.
*
* @throws CloneNotSupportedException if the renderer cannot be cloned.
*/
@Override
public Object clone() throws CloneNotSupportedException {
return super.clone();
}
}