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JFreeChart is a class library, written in Java, for generating charts. Utilising the Java2D APIs, it currently supports bar charts, pie charts, line charts, XY-plots and time series plots.

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/* ===========================================================
 * JFreeChart : a free chart library for the Java(tm) platform
 * ===========================================================
 *
 * (C) Copyright 2000-2014, by Object Refinery Limited 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.]
 *
 * --------------
 * ValueAxis.java
 * --------------
 * (C) Copyright 2000-2014, by Object Refinery Limited and Contributors.
 *
 * Original Author:  David Gilbert (for Object Refinery Limited);
 * Contributor(s):   Jonathan Nash;
 *                   Nicolas Brodu (for Astrium and EADS Corporate Research
 *                   Center);
 *                   Peter Kolb (patch 1934255);
 *                   Andrew Mickish (patch 1870189);
 *
 * Changes
 * -------
 * 18-Sep-2001 : Added standard header and fixed DOS encoding problem (DG);
 * 23-Nov-2001 : Overhauled standard tick unit code (DG);
 * 04-Dec-2001 : Changed constructors to protected, and tidied up default
 *               values (DG);
 * 12-Dec-2001 : Fixed vertical gridlines bug (DG);
 * 16-Jan-2002 : Added an optional crosshair, based on the implementation by
 *               Jonathan Nash (DG);
 * 23-Jan-2002 : Moved the minimum and maximum values to here from NumberAxis,
 *               and changed the type from Number to double (DG);
 * 25-Feb-2002 : Added default value for autoRange. Changed autoAdjustRange
 *               from public to protected. Updated import statements (DG);
 * 23-Apr-2002 : Added setRange() method (DG);
 * 29-Apr-2002 : Added range adjustment methods (DG);
 * 13-Jun-2002 : Modified setCrosshairValue() to notify listeners only when the
 *               crosshairs are visible, to avoid unnecessary repaints, as
 *               suggested by Kees Kuip (DG);
 * 25-Jul-2002 : Moved lower and upper margin attributes from the NumberAxis
 *               class (DG);
 * 05-Sep-2002 : Updated constructor for changes in Axis class (DG);
 * 01-Oct-2002 : Fixed errors reported by Checkstyle (DG);
 * 04-Oct-2002 : Moved standardTickUnits from NumberAxis --> ValueAxis (DG);
 * 08-Nov-2002 : Moved to new package com.jrefinery.chart.axis (DG);
 * 19-Nov-2002 : Removed grid settings (now controlled by the plot) (DG);
 * 27-Nov-2002 : Moved the 'inverted' attribute from NumberAxis to
 *               ValueAxis (DG);
 * 03-Jan-2003 : Small fix to ensure auto-range minimum is observed
 *               immediately (DG);
 * 14-Jan-2003 : Changed autoRangeMinimumSize from Number --> double (DG);
 * 20-Jan-2003 : Replaced monolithic constructor (DG);
 * 26-Mar-2003 : Implemented Serializable (DG);
 * 09-May-2003 : Added AxisLocation parameter to translation methods (DG);
 * 13-Aug-2003 : Implemented Cloneable (DG);
 * 01-Sep-2003 : Fixed bug 793167 (setMaximumAxisValue exception) (DG);
 * 02-Sep-2003 : Fixed bug 795366 (zooming on inverted axes) (DG);
 * 08-Sep-2003 : Completed Serialization support (NB);
 * 08-Sep-2003 : Renamed get/setMinimumValue --> get/setLowerBound,
 *               and get/setMaximumValue --> get/setUpperBound (DG);
 * 27-Oct-2003 : Changed DEFAULT_AUTO_RANGE_MINIMUM_SIZE value - see bug ID
 *               829606 (DG);
 * 07-Nov-2003 : Changes to tick mechanism (DG);
 * 06-Jan-2004 : Moved axis line attributes to Axis class (DG);
 * 21-Jan-2004 : Removed redundant axisLineVisible attribute.  Renamed
 *               translateJava2DToValue --> java2DToValue, and
 *               translateValueToJava2D --> valueToJava2D (DG);
 * 23-Jan-2004 : Fixed setAxisLinePaint() and setAxisLineStroke() which had no
 *               effect ([email protected]);
 * 07-Apr-2004 : Changed text bounds calculation (DG);
 * 26-Apr-2004 : Added getter/setter methods for arrow shapes (DG);
 * 18-May-2004 : Added methods to set axis range *including* current
 *               margins (DG);
 * 02-Jun-2004 : Fixed bug in setRangeWithMargins() method (DG);
 * 30-Sep-2004 : Moved drawRotatedString() from RefineryUtilities
 *               --> TextUtilities (DG);
 * 11-Jan-2005 : Removed deprecated methods in preparation for 1.0.0
 *               release (DG);
 * 21-Apr-2005 : Replaced Insets with RectangleInsets (DG);
 * ------------- JFREECHART 1.0.x ---------------------------------------------
 * 10-Oct-2006 : Source reformatting (DG);
 * 22-Mar-2007 : Added new defaultAutoRange attribute (DG);
 * 02-Aug-2007 : Check for major tick when drawing label (DG);
 * 25-Sep-2008 : Added minor tick support, see patch 1934255 by Peter Kolb (DG);
 * 21-Jan-2009 : Updated default behaviour of minor ticks (DG);
 * 18-Mar-2008 : Added resizeRange2() method which provides more natural
 *               anchored zooming for mouse wheel support (DG);
 * 26-Mar-2009 : In equals(), only check current range if autoRange is
 *               false (DG);
 * 30-Mar-2009 : Added pan(double) method (DG);
 * 03-Sep-2012 : Fix reserveSpace() method, bug 3555275 (DG);
 * 02-Jul-2013 : Use ParamChecks (DG);
 * 18-Mar-2014 : Updates to support attributed tick labels for LogAxis (DG);
 * 29-Jul-2014 : Add hints to normalise axis line and tick marks (DG);
 *
 */

package org.jfree.chart.axis;

import java.awt.Font;
import java.awt.FontMetrics;
import java.awt.Graphics2D;
import java.awt.Polygon;
import java.awt.RenderingHints;
import java.awt.Shape;
import java.awt.font.LineMetrics;
import java.awt.geom.AffineTransform;
import java.awt.geom.Line2D;
import java.awt.geom.Rectangle2D;
import java.io.IOException;
import java.io.ObjectInputStream;
import java.io.ObjectOutputStream;
import java.io.Serializable;
import java.util.Iterator;
import java.util.List;

import org.jfree.chart.event.AxisChangeEvent;
import org.jfree.chart.plot.Plot;
import org.jfree.chart.util.AttrStringUtils;
import org.jfree.chart.util.ParamChecks;
import org.jfree.data.Range;
import org.jfree.io.SerialUtilities;
import org.jfree.text.TextUtilities;
import org.jfree.ui.RectangleEdge;
import org.jfree.ui.RectangleInsets;
import org.jfree.util.ObjectUtilities;
import org.jfree.util.PublicCloneable;

/**
 * The base class for axes that display value data, where values are measured
 * using the double primitive.  The two key subclasses are
 * {@link DateAxis} and {@link NumberAxis}.
 */
public abstract class ValueAxis extends Axis
        implements Cloneable, PublicCloneable, Serializable {

    /** For serialization. */
    private static final long serialVersionUID = 3698345477322391456L;

    /** The default axis range. */
    public static final Range DEFAULT_RANGE = new Range(0.0, 1.0);

    /** The default auto-range value. */
    public static final boolean DEFAULT_AUTO_RANGE = true;

    /** The default inverted flag setting. */
    public static final boolean DEFAULT_INVERTED = false;

    /** The default minimum auto range. */
    public static final double DEFAULT_AUTO_RANGE_MINIMUM_SIZE = 0.00000001;

    /** The default value for the lower margin (0.05 = 5%). */
    public static final double DEFAULT_LOWER_MARGIN = 0.05;

    /** The default value for the upper margin (0.05 = 5%). */
    public static final double DEFAULT_UPPER_MARGIN = 0.05;

    /**
     * The default lower bound for the axis.
     *
     * @deprecated From 1.0.5 onwards, the axis defines a defaultRange
     *     attribute (see {@link #getDefaultAutoRange()}).
     */
    public static final double DEFAULT_LOWER_BOUND = 0.0;

    /**
     * The default upper bound for the axis.
     *
     * @deprecated From 1.0.5 onwards, the axis defines a defaultRange
     *     attribute (see {@link #getDefaultAutoRange()}).
     */
    public static final double DEFAULT_UPPER_BOUND = 1.0;

    /** The default auto-tick-unit-selection value. */
    public static final boolean DEFAULT_AUTO_TICK_UNIT_SELECTION = true;

    /** The maximum tick count. */
    public static final int MAXIMUM_TICK_COUNT = 500;

    /**
     * A flag that controls whether an arrow is drawn at the positive end of
     * the axis line.
     */
    private boolean positiveArrowVisible;

    /**
     * A flag that controls whether an arrow is drawn at the negative end of
     * the axis line.
     */
    private boolean negativeArrowVisible;

    /** The shape used for an up arrow. */
    private transient Shape upArrow;

    /** The shape used for a down arrow. */
    private transient Shape downArrow;

    /** The shape used for a left arrow. */
    private transient Shape leftArrow;

    /** The shape used for a right arrow. */
    private transient Shape rightArrow;

    /** A flag that affects the orientation of the values on the axis. */
    private boolean inverted;

    /** The axis range. */
    private Range range;

    /**
     * Flag that indicates whether the axis automatically scales to fit the
     * chart data.
     */
    private boolean autoRange;

    /** The minimum size for the 'auto' axis range (excluding margins). */
    private double autoRangeMinimumSize;

    /**
     * The default range is used when the dataset is empty and the axis needs
     * to determine the auto range.
     *
     * @since 1.0.5
     */
    private Range defaultAutoRange;

    /**
     * The upper margin percentage.  This indicates the amount by which the
     * maximum axis value exceeds the maximum data value (as a percentage of
     * the range on the axis) when the axis range is determined automatically.
     */
    private double upperMargin;

    /**
     * The lower margin.  This is a percentage that indicates the amount by
     * which the minimum axis value is "less than" the minimum data value when
     * the axis range is determined automatically.
     */
    private double lowerMargin;

    /**
     * If this value is positive, the amount is subtracted from the maximum
     * data value to determine the lower axis range.  This can be used to
     * provide a fixed "window" on dynamic data.
     */
    private double fixedAutoRange;

    /**
     * Flag that indicates whether or not the tick unit is selected
     * automatically.
     */
    private boolean autoTickUnitSelection;

    /** The standard tick units for the axis. */
    private TickUnitSource standardTickUnits;

    /** An index into an array of standard tick values. */
    private int autoTickIndex;

    /**
     * The number of minor ticks per major tick unit.  This is an override
     * field, if the value is > 0 it is used, otherwise the axis refers to the
     * minorTickCount in the current tickUnit.
     */
    private int minorTickCount;

    /** A flag indicating whether or not tick labels are rotated to vertical. */
    private boolean verticalTickLabels;

    /**
     * Constructs a value axis.
     *
     * @param label  the axis label (null permitted).
     * @param standardTickUnits  the source for standard tick units
     *                           (null permitted).
     */
    protected ValueAxis(String label, TickUnitSource standardTickUnits) {

        super(label);

        this.positiveArrowVisible = false;
        this.negativeArrowVisible = false;

        this.range = DEFAULT_RANGE;
        this.autoRange = DEFAULT_AUTO_RANGE;
        this.defaultAutoRange = DEFAULT_RANGE;

        this.inverted = DEFAULT_INVERTED;
        this.autoRangeMinimumSize = DEFAULT_AUTO_RANGE_MINIMUM_SIZE;

        this.lowerMargin = DEFAULT_LOWER_MARGIN;
        this.upperMargin = DEFAULT_UPPER_MARGIN;

        this.fixedAutoRange = 0.0;

        this.autoTickUnitSelection = DEFAULT_AUTO_TICK_UNIT_SELECTION;
        this.standardTickUnits = standardTickUnits;

        Polygon p1 = new Polygon();
        p1.addPoint(0, 0);
        p1.addPoint(-2, 2);
        p1.addPoint(2, 2);

        this.upArrow = p1;

        Polygon p2 = new Polygon();
        p2.addPoint(0, 0);
        p2.addPoint(-2, -2);
        p2.addPoint(2, -2);

        this.downArrow = p2;

        Polygon p3 = new Polygon();
        p3.addPoint(0, 0);
        p3.addPoint(-2, -2);
        p3.addPoint(-2, 2);

        this.rightArrow = p3;

        Polygon p4 = new Polygon();
        p4.addPoint(0, 0);
        p4.addPoint(2, -2);
        p4.addPoint(2, 2);

        this.leftArrow = p4;

        this.verticalTickLabels = false;
        this.minorTickCount = 0;

    }

    /**
     * Returns true if the tick labels should be rotated (to
     * vertical), and false otherwise.
     *
     * @return true or false.
     *
     * @see #setVerticalTickLabels(boolean)
     */
    public boolean isVerticalTickLabels() {
        return this.verticalTickLabels;
    }

    /**
     * Sets the flag that controls whether the tick labels are displayed
     * vertically (that is, rotated 90 degrees from horizontal).  If the flag
     * is changed, an {@link AxisChangeEvent} is sent to all registered
     * listeners.
     *
     * @param flag  the flag.
     *
     * @see #isVerticalTickLabels()
     */
    public void setVerticalTickLabels(boolean flag) {
        if (this.verticalTickLabels != flag) {
            this.verticalTickLabels = flag;
            fireChangeEvent();
        }
    }

    /**
     * Returns a flag that controls whether or not the axis line has an arrow
     * drawn that points in the positive direction for the axis.
     *
     * @return A boolean.
     *
     * @see #setPositiveArrowVisible(boolean)
     */
    public boolean isPositiveArrowVisible() {
        return this.positiveArrowVisible;
    }

    /**
     * Sets a flag that controls whether or not the axis lines has an arrow
     * drawn that points in the positive direction for the axis, and sends an
     * {@link AxisChangeEvent} to all registered listeners.
     *
     * @param visible  the flag.
     *
     * @see #isPositiveArrowVisible()
     */
    public void setPositiveArrowVisible(boolean visible) {
        this.positiveArrowVisible = visible;
        fireChangeEvent();
    }

    /**
     * Returns a flag that controls whether or not the axis line has an arrow
     * drawn that points in the negative direction for the axis.
     *
     * @return A boolean.
     *
     * @see #setNegativeArrowVisible(boolean)
     */
    public boolean isNegativeArrowVisible() {
        return this.negativeArrowVisible;
    }

    /**
     * Sets a flag that controls whether or not the axis lines has an arrow
     * drawn that points in the negative direction for the axis, and sends an
     * {@link AxisChangeEvent} to all registered listeners.
     *
     * @param visible  the flag.
     *
     * @see #setNegativeArrowVisible(boolean)
     */
    public void setNegativeArrowVisible(boolean visible) {
        this.negativeArrowVisible = visible;
        fireChangeEvent();
    }

    /**
     * Returns a shape that can be displayed as an arrow pointing upwards at
     * the end of an axis line.
     *
     * @return A shape (never null).
     *
     * @see #setUpArrow(Shape)
     */
    public Shape getUpArrow() {
        return this.upArrow;
    }

    /**
     * Sets the shape that can be displayed as an arrow pointing upwards at
     * the end of an axis line and sends an {@link AxisChangeEvent} to all
     * registered listeners.
     *
     * @param arrow  the arrow shape (null not permitted).
     *
     * @see #getUpArrow()
     */
    public void setUpArrow(Shape arrow) {
        ParamChecks.nullNotPermitted(arrow, "arrow");
        this.upArrow = arrow;
        fireChangeEvent();
    }

    /**
     * Returns a shape that can be displayed as an arrow pointing downwards at
     * the end of an axis line.
     *
     * @return A shape (never null).
     *
     * @see #setDownArrow(Shape)
     */
    public Shape getDownArrow() {
        return this.downArrow;
    }

    /**
     * Sets the shape that can be displayed as an arrow pointing downwards at
     * the end of an axis line and sends an {@link AxisChangeEvent} to all
     * registered listeners.
     *
     * @param arrow  the arrow shape (null not permitted).
     *
     * @see #getDownArrow()
     */
    public void setDownArrow(Shape arrow) {
        ParamChecks.nullNotPermitted(arrow, "arrow");
        this.downArrow = arrow;
        fireChangeEvent();
    }

    /**
     * Returns a shape that can be displayed as an arrow pointing left at the
     * end of an axis line.
     *
     * @return A shape (never null).
     *
     * @see #setLeftArrow(Shape)
     */
    public Shape getLeftArrow() {
        return this.leftArrow;
    }

    /**
     * Sets the shape that can be displayed as an arrow pointing left at the
     * end of an axis line and sends an {@link AxisChangeEvent} to all
     * registered listeners.
     *
     * @param arrow  the arrow shape (null not permitted).
     *
     * @see #getLeftArrow()
     */
    public void setLeftArrow(Shape arrow) {
        ParamChecks.nullNotPermitted(arrow, "arrow");
        this.leftArrow = arrow;
        fireChangeEvent();
    }

    /**
     * Returns a shape that can be displayed as an arrow pointing right at the
     * end of an axis line.
     *
     * @return A shape (never null).
     *
     * @see #setRightArrow(Shape)
     */
    public Shape getRightArrow() {
        return this.rightArrow;
    }

    /**
     * Sets the shape that can be displayed as an arrow pointing rightwards at
     * the end of an axis line and sends an {@link AxisChangeEvent} to all
     * registered listeners.
     *
     * @param arrow  the arrow shape (null not permitted).
     *
     * @see #getRightArrow()
     */
    public void setRightArrow(Shape arrow) {
        ParamChecks.nullNotPermitted(arrow, "arrow");
        this.rightArrow = arrow;
        fireChangeEvent();
    }

    /**
     * Draws an axis line at the current cursor position and edge.
     *
     * @param g2  the graphics device ({@code null} not permitted).
     * @param cursor  the cursor position.
     * @param dataArea  the data area.
     * @param edge  the edge.
     */
    @Override
    protected void drawAxisLine(Graphics2D g2, double cursor,
            Rectangle2D dataArea, RectangleEdge edge) {
        Line2D axisLine = null;
        double c = cursor;
        if (edge == RectangleEdge.TOP) {
            axisLine = new Line2D.Double(dataArea.getX(), c, dataArea.getMaxX(),
                    c);
        } else if (edge == RectangleEdge.BOTTOM) {
            axisLine = new Line2D.Double(dataArea.getX(), c, dataArea.getMaxX(),
                    c);
        } else if (edge == RectangleEdge.LEFT) {
            axisLine = new Line2D.Double(c, dataArea.getY(), c, 
                    dataArea.getMaxY());
        } else if (edge == RectangleEdge.RIGHT) {
            axisLine = new Line2D.Double(c, dataArea.getY(), c,
                    dataArea.getMaxY());
        }
        g2.setPaint(getAxisLinePaint());
        g2.setStroke(getAxisLineStroke());
        Object saved = g2.getRenderingHint(RenderingHints.KEY_STROKE_CONTROL);
        g2.setRenderingHint(RenderingHints.KEY_STROKE_CONTROL, 
                RenderingHints.VALUE_STROKE_NORMALIZE);
        g2.draw(axisLine);
        g2.setRenderingHint(RenderingHints.KEY_STROKE_CONTROL, saved);

        boolean drawUpOrRight = false;
        boolean drawDownOrLeft = false;
        if (this.positiveArrowVisible) {
            if (this.inverted) {
                drawDownOrLeft = true;
            }
            else {
                drawUpOrRight = true;
            }
        }
        if (this.negativeArrowVisible) {
            if (this.inverted) {
                drawUpOrRight = true;
            } else {
                drawDownOrLeft = true;
            }
        }
        if (drawUpOrRight) {
            double x = 0.0;
            double y = 0.0;
            Shape arrow = null;
            if (edge == RectangleEdge.TOP || edge == RectangleEdge.BOTTOM) {
                x = dataArea.getMaxX();
                y = cursor;
                arrow = this.rightArrow;
            } else if (edge == RectangleEdge.LEFT
                    || edge == RectangleEdge.RIGHT) {
                x = cursor;
                y = dataArea.getMinY();
                arrow = this.upArrow;
            }

            // draw the arrow...
            AffineTransform transformer = new AffineTransform();
            transformer.setToTranslation(x, y);
            Shape shape = transformer.createTransformedShape(arrow);
            g2.fill(shape);
            g2.draw(shape);
        }

        if (drawDownOrLeft) {
            double x = 0.0;
            double y = 0.0;
            Shape arrow = null;
            if (edge == RectangleEdge.TOP || edge == RectangleEdge.BOTTOM) {
                x = dataArea.getMinX();
                y = cursor;
                arrow = this.leftArrow;
            } else if (edge == RectangleEdge.LEFT
                    || edge == RectangleEdge.RIGHT) {
                x = cursor;
                y = dataArea.getMaxY();
                arrow = this.downArrow;
            }

            // draw the arrow...
            AffineTransform transformer = new AffineTransform();
            transformer.setToTranslation(x, y);
            Shape shape = transformer.createTransformedShape(arrow);
            g2.fill(shape);
            g2.draw(shape);
        }

    }

    /**
     * Calculates the anchor point for a tick label.
     *
     * @param tick  the tick.
     * @param cursor  the cursor.
     * @param dataArea  the data area.
     * @param edge  the edge on which the axis is drawn.
     *
     * @return The x and y coordinates of the anchor point.
     */
    protected float[] calculateAnchorPoint(ValueTick tick, double cursor,
            Rectangle2D dataArea, RectangleEdge edge) {

        RectangleInsets insets = getTickLabelInsets();
        float[] result = new float[2];
        if (edge == RectangleEdge.TOP) {
            result[0] = (float) valueToJava2D(tick.getValue(), dataArea, edge);
            result[1] = (float) (cursor - insets.getBottom() - 2.0);
        }
        else if (edge == RectangleEdge.BOTTOM) {
            result[0] = (float) valueToJava2D(tick.getValue(), dataArea, edge);
            result[1] = (float) (cursor + insets.getTop() + 2.0);
        }
        else if (edge == RectangleEdge.LEFT) {
            result[0] = (float) (cursor - insets.getLeft() - 2.0);
            result[1] = (float) valueToJava2D(tick.getValue(), dataArea, edge);
        }
        else if (edge == RectangleEdge.RIGHT) {
            result[0] = (float) (cursor + insets.getRight() + 2.0);
            result[1] = (float) valueToJava2D(tick.getValue(), dataArea, edge);
        }
        return result;
    }

    /**
     * Draws the axis line, tick marks and tick mark labels.
     *
     * @param g2  the graphics device (null not permitted).
     * @param cursor  the cursor.
     * @param plotArea  the plot area (null not permitted).
     * @param dataArea  the data area (null not permitted).
     * @param edge  the edge that the axis is aligned with (null 
     *     not permitted).
     *
     * @return The width or height used to draw the axis.
     */
    protected AxisState drawTickMarksAndLabels(Graphics2D g2,
            double cursor, Rectangle2D plotArea, Rectangle2D dataArea,
            RectangleEdge edge) {

        AxisState state = new AxisState(cursor);
        if (isAxisLineVisible()) {
            drawAxisLine(g2, cursor, dataArea, edge);
        }
        List ticks = refreshTicks(g2, state, dataArea, edge);
        state.setTicks(ticks);
        g2.setFont(getTickLabelFont());
        Object saved = g2.getRenderingHint(RenderingHints.KEY_STROKE_CONTROL);
        g2.setRenderingHint(RenderingHints.KEY_STROKE_CONTROL, 
                RenderingHints.VALUE_STROKE_NORMALIZE);
        Iterator iterator = ticks.iterator();
        while (iterator.hasNext()) {
            ValueTick tick = (ValueTick) iterator.next();
            if (isTickLabelsVisible()) {
                g2.setPaint(getTickLabelPaint());
                float[] anchorPoint = calculateAnchorPoint(tick, cursor,
                        dataArea, edge);
                if (tick instanceof LogTick) {
                    LogTick lt = (LogTick) tick;
                    if (lt.getAttributedLabel() == null) {
                        continue;
                    }
                    AttrStringUtils.drawRotatedString(lt.getAttributedLabel(), 
                            g2, anchorPoint[0], anchorPoint[1], 
                            tick.getTextAnchor(), tick.getAngle(), 
                            tick.getRotationAnchor());
                } else {
                    if (tick.getText() == null) {
                        continue;
                    }
                    TextUtilities.drawRotatedString(tick.getText(), g2,
                            anchorPoint[0], anchorPoint[1], 
                            tick.getTextAnchor(), tick.getAngle(), 
                            tick.getRotationAnchor());
                }
            }

            if ((isTickMarksVisible() && tick.getTickType().equals(
                    TickType.MAJOR)) || (isMinorTickMarksVisible()
                    && tick.getTickType().equals(TickType.MINOR))) {

                double ol = (tick.getTickType().equals(TickType.MINOR)) 
                        ? getMinorTickMarkOutsideLength()
                        : getTickMarkOutsideLength();

                double il = (tick.getTickType().equals(TickType.MINOR)) 
                        ? getMinorTickMarkInsideLength()
                        : getTickMarkInsideLength();

                float xx = (float) valueToJava2D(tick.getValue(), dataArea,
                        edge);
                Line2D mark = null;
                g2.setStroke(getTickMarkStroke());
                g2.setPaint(getTickMarkPaint());
                if (edge == RectangleEdge.LEFT) {
                    mark = new Line2D.Double(cursor - ol, xx, cursor + il, xx);
                }
                else if (edge == RectangleEdge.RIGHT) {
                    mark = new Line2D.Double(cursor + ol, xx, cursor - il, xx);
                }
                else if (edge == RectangleEdge.TOP) {
                    mark = new Line2D.Double(xx, cursor - ol, xx, cursor + il);
                }
                else if (edge == RectangleEdge.BOTTOM) {
                    mark = new Line2D.Double(xx, cursor + ol, xx, cursor - il);
                }
                g2.draw(mark);
            }
        }
        g2.setRenderingHint(RenderingHints.KEY_STROKE_CONTROL, saved);
        
        // need to work out the space used by the tick labels...
        // so we can update the cursor...
        double used = 0.0;
        if (isTickLabelsVisible()) {
            if (edge == RectangleEdge.LEFT) {
                used += findMaximumTickLabelWidth(ticks, g2, plotArea,
                        isVerticalTickLabels());
                state.cursorLeft(used);
            } else if (edge == RectangleEdge.RIGHT) {
                used = findMaximumTickLabelWidth(ticks, g2, plotArea,
                        isVerticalTickLabels());
                state.cursorRight(used);
            } else if (edge == RectangleEdge.TOP) {
                used = findMaximumTickLabelHeight(ticks, g2, plotArea,
                        isVerticalTickLabels());
                state.cursorUp(used);
            } else if (edge == RectangleEdge.BOTTOM) {
                used = findMaximumTickLabelHeight(ticks, g2, plotArea,
                        isVerticalTickLabels());
                state.cursorDown(used);
            }
        }

        return state;
    }

    /**
     * Returns the space required to draw the axis.
     *
     * @param g2  the graphics device.
     * @param plot  the plot that the axis belongs to.
     * @param plotArea  the area within which the plot should be drawn.
     * @param edge  the axis location.
     * @param space  the space already reserved (for other axes).
     *
     * @return The space required to draw the axis (including pre-reserved
     *         space).
     */
    @Override
    public AxisSpace reserveSpace(Graphics2D g2, Plot plot, 
            Rectangle2D plotArea, RectangleEdge edge, AxisSpace space) {

        // create a new space object if one wasn't supplied...
        if (space == null) {
            space = new AxisSpace();
        }

        // if the axis is not visible, no additional space is required...
        if (!isVisible()) {
            return space;
        }

        // if the axis has a fixed dimension, return it...
        double dimension = getFixedDimension();
        if (dimension > 0.0) {
            space.add(dimension, edge);
            return space;
        }

        // calculate the max size of the tick labels (if visible)...
        double tickLabelHeight = 0.0;
        double tickLabelWidth = 0.0;
        if (isTickLabelsVisible()) {
            g2.setFont(getTickLabelFont());
            List ticks = refreshTicks(g2, new AxisState(), plotArea, edge);
            if (RectangleEdge.isTopOrBottom(edge)) {
                tickLabelHeight = findMaximumTickLabelHeight(ticks, g2,
                        plotArea, isVerticalTickLabels());
            }
            else if (RectangleEdge.isLeftOrRight(edge)) {
                tickLabelWidth = findMaximumTickLabelWidth(ticks, g2, plotArea,
                        isVerticalTickLabels());
            }
        }

        // get the axis label size and update the space object...
        Rectangle2D labelEnclosure = getLabelEnclosure(g2, edge);
        if (RectangleEdge.isTopOrBottom(edge)) {
            double labelHeight = labelEnclosure.getHeight();
            space.add(labelHeight + tickLabelHeight, edge);
        }
        else if (RectangleEdge.isLeftOrRight(edge)) {
            double labelWidth = labelEnclosure.getWidth();
            space.add(labelWidth + tickLabelWidth, edge);
        }

        return space;

    }

    /**
     * A utility method for determining the height of the tallest tick label.
     *
     * @param ticks  the ticks.
     * @param g2  the graphics device.
     * @param drawArea  the area within which the plot and axes should be drawn.
     * @param vertical  a flag that indicates whether or not the tick labels
     *                  are 'vertical'.
     *
     * @return The height of the tallest tick label.
     */
    protected double findMaximumTickLabelHeight(List ticks, Graphics2D g2,
            Rectangle2D drawArea, boolean vertical) {

        RectangleInsets insets = getTickLabelInsets();
        Font font = getTickLabelFont();
        g2.setFont(font);
        double maxHeight = 0.0;
        if (vertical) {
            FontMetrics fm = g2.getFontMetrics(font);
            Iterator iterator = ticks.iterator();
            while (iterator.hasNext()) {
                Tick tick = (Tick) iterator.next();
                Rectangle2D labelBounds = null;
                if (tick instanceof LogTick) {
                    LogTick lt = (LogTick) tick;
                    if (lt.getAttributedLabel() != null) {
                        labelBounds = AttrStringUtils.getTextBounds(
                                lt.getAttributedLabel(), g2);
                    }
                } else if (tick.getText() != null) {
                    labelBounds = TextUtilities.getTextBounds(
                            tick.getText(), g2, fm);
                }
                if (labelBounds != null && labelBounds.getWidth() 
                        + insets.getTop() + insets.getBottom() > maxHeight) {
                    maxHeight = labelBounds.getWidth()
                                + insets.getTop() + insets.getBottom();
                }
            }
        } else {
            LineMetrics metrics = font.getLineMetrics("ABCxyz",
                    g2.getFontRenderContext());
            maxHeight = metrics.getHeight()
                        + insets.getTop() + insets.getBottom();
        }
        return maxHeight;

    }

    /**
     * A utility method for determining the width of the widest tick label.
     *
     * @param ticks  the ticks.
     * @param g2  the graphics device.
     * @param drawArea  the area within which the plot and axes should be drawn.
     * @param vertical  a flag that indicates whether or not the tick labels
     *                  are 'vertical'.
     *
     * @return The width of the tallest tick label.
     */
    protected double findMaximumTickLabelWidth(List ticks, Graphics2D g2,
            Rectangle2D drawArea, boolean vertical) {

        RectangleInsets insets = getTickLabelInsets();
        Font font = getTickLabelFont();
        double maxWidth = 0.0;
        if (!vertical) {
            FontMetrics fm = g2.getFontMetrics(font);
            Iterator iterator = ticks.iterator();
            while (iterator.hasNext()) {
                Tick tick = (Tick) iterator.next();
                Rectangle2D labelBounds = null;
                if (tick instanceof LogTick) {
                    LogTick lt = (LogTick) tick;
                    if (lt.getAttributedLabel() != null) {
                        labelBounds = AttrStringUtils.getTextBounds(
                                lt.getAttributedLabel(), g2);
                    }
                } else if (tick.getText() != null) {
                    labelBounds = TextUtilities.getTextBounds(tick.getText(), 
                            g2, fm);
                }
                if (labelBounds != null 
                        && labelBounds.getWidth() + insets.getLeft()
                        + insets.getRight() > maxWidth) {
                    maxWidth = labelBounds.getWidth()
                               + insets.getLeft() + insets.getRight();
                }
            }
        } else {
            LineMetrics metrics = font.getLineMetrics("ABCxyz",
                    g2.getFontRenderContext());
            maxWidth = metrics.getHeight()
                       + insets.getTop() + insets.getBottom();
        }
        return maxWidth;

    }

    /**
     * Returns a flag that controls the direction of values on the axis.
     * 

* For a regular axis, values increase from left to right (for a horizontal * axis) and bottom to top (for a vertical axis). When the axis is * 'inverted', the values increase in the opposite direction. * * @return The flag. * * @see #setInverted(boolean) */ public boolean isInverted() { return this.inverted; } /** * Sets a flag that controls the direction of values on the axis, and * notifies registered listeners that the axis has changed. * * @param flag the flag. * * @see #isInverted() */ public void setInverted(boolean flag) { if (this.inverted != flag) { this.inverted = flag; fireChangeEvent(); } } /** * Returns the flag that controls whether or not the axis range is * automatically adjusted to fit the data values. * * @return The flag. * * @see #setAutoRange(boolean) */ public boolean isAutoRange() { return this.autoRange; } /** * Sets a flag that determines whether or not the axis range is * automatically adjusted to fit the data, and notifies registered * listeners that the axis has been modified. * * @param auto the new value of the flag. * * @see #isAutoRange() */ public void setAutoRange(boolean auto) { setAutoRange(auto, true); } /** * Sets the auto range attribute. If the notify flag is set, * an {@link AxisChangeEvent} is sent to registered listeners. * * @param auto the flag. * @param notify notify listeners? * * @see #isAutoRange() */ protected void setAutoRange(boolean auto, boolean notify) { if (this.autoRange != auto) { this.autoRange = auto; if (this.autoRange) { autoAdjustRange(); } if (notify) { fireChangeEvent(); } } } /** * Returns the minimum size allowed for the axis range when it is * automatically calculated. * * @return The minimum range. * * @see #setAutoRangeMinimumSize(double) */ public double getAutoRangeMinimumSize() { return this.autoRangeMinimumSize; } /** * Sets the auto range minimum size and sends an {@link AxisChangeEvent} * to all registered listeners. * * @param size the size. * * @see #getAutoRangeMinimumSize() */ public void setAutoRangeMinimumSize(double size) { setAutoRangeMinimumSize(size, true); } /** * Sets the minimum size allowed for the axis range when it is * automatically calculated. *

* If requested, an {@link AxisChangeEvent} is forwarded to all registered * listeners. * * @param size the new minimum. * @param notify notify listeners? */ public void setAutoRangeMinimumSize(double size, boolean notify) { if (size <= 0.0) { throw new IllegalArgumentException( "NumberAxis.setAutoRangeMinimumSize(double): must be > 0.0."); } if (this.autoRangeMinimumSize != size) { this.autoRangeMinimumSize = size; if (this.autoRange) { autoAdjustRange(); } if (notify) { fireChangeEvent(); } } } /** * Returns the default auto range. * * @return The default auto range (never null). * * @see #setDefaultAutoRange(Range) * * @since 1.0.5 */ public Range getDefaultAutoRange() { return this.defaultAutoRange; } /** * Sets the default auto range and sends an {@link AxisChangeEvent} to all * registered listeners. * * @param range the range (null not permitted). * * @see #getDefaultAutoRange() * * @since 1.0.5 */ public void setDefaultAutoRange(Range range) { ParamChecks.nullNotPermitted(range, "range"); this.defaultAutoRange = range; fireChangeEvent(); } /** * Returns the lower margin for the axis, expressed as a percentage of the * axis range. This controls the space added to the lower end of the axis * when the axis range is automatically calculated (it is ignored when the * axis range is set explicitly). The default value is 0.05 (five percent). * * @return The lower margin. * * @see #setLowerMargin(double) */ public double getLowerMargin() { return this.lowerMargin; } /** * Sets the lower margin for the axis (as a percentage of the axis range) * and sends an {@link AxisChangeEvent} to all registered listeners. This * margin is added only when the axis range is auto-calculated - if you set * the axis range manually, the margin is ignored. * * @param margin the margin percentage (for example, 0.05 is five percent). * * @see #getLowerMargin() * @see #setUpperMargin(double) */ public void setLowerMargin(double margin) { this.lowerMargin = margin; if (isAutoRange()) { autoAdjustRange(); } fireChangeEvent(); } /** * Returns the upper margin for the axis, expressed as a percentage of the * axis range. This controls the space added to the lower end of the axis * when the axis range is automatically calculated (it is ignored when the * axis range is set explicitly). The default value is 0.05 (five percent). * * @return The upper margin. * * @see #setUpperMargin(double) */ public double getUpperMargin() { return this.upperMargin; } /** * Sets the upper margin for the axis (as a percentage of the axis range) * and sends an {@link AxisChangeEvent} to all registered listeners. This * margin is added only when the axis range is auto-calculated - if you set * the axis range manually, the margin is ignored. * * @param margin the margin percentage (for example, 0.05 is five percent). * * @see #getLowerMargin() * @see #setLowerMargin(double) */ public void setUpperMargin(double margin) { this.upperMargin = margin; if (isAutoRange()) { autoAdjustRange(); } fireChangeEvent(); } /** * Returns the fixed auto range. * * @return The length. * * @see #setFixedAutoRange(double) */ public double getFixedAutoRange() { return this.fixedAutoRange; } /** * Sets the fixed auto range for the axis. * * @param length the range length. * * @see #getFixedAutoRange() */ public void setFixedAutoRange(double length) { this.fixedAutoRange = length; if (isAutoRange()) { autoAdjustRange(); } fireChangeEvent(); } /** * Returns the lower bound of the axis range. * * @return The lower bound. * * @see #setLowerBound(double) */ public double getLowerBound() { return this.range.getLowerBound(); } /** * Sets the lower bound for the axis range. An {@link AxisChangeEvent} is * sent to all registered listeners. * * @param min the new minimum. * * @see #getLowerBound() */ public void setLowerBound(double min) { if (this.range.getUpperBound() > min) { setRange(new Range(min, this.range.getUpperBound())); } else { setRange(new Range(min, min + 1.0)); } } /** * Returns the upper bound for the axis range. * * @return The upper bound. * * @see #setUpperBound(double) */ public double getUpperBound() { return this.range.getUpperBound(); } /** * Sets the upper bound for the axis range, and sends an * {@link AxisChangeEvent} to all registered listeners. * * @param max the new maximum. * * @see #getUpperBound() */ public void setUpperBound(double max) { if (this.range.getLowerBound() < max) { setRange(new Range(this.range.getLowerBound(), max)); } else { setRange(max - 1.0, max); } } /** * Returns the range for the axis. * * @return The axis range (never null). * * @see #setRange(Range) */ public Range getRange() { return this.range; } /** * Sets the range for the axis and sends a change event to all registered * listeners. As a side-effect, the auto-range flag is set to * false. * * @param range the range (null not permitted). * * @see #getRange() */ public void setRange(Range range) { // defer argument checking setRange(range, true, true); } /** * Sets the range for the axis and, if requested, sends a change event to * all registered listeners. Furthermore, if turnOffAutoRange * is true, the auto-range flag is set to false * (normally when setting the axis range manually the caller expects that * range to remain in force). * * @param range the range (null not permitted). * @param turnOffAutoRange a flag that controls whether or not the auto * range is turned off. * @param notify a flag that controls whether or not listeners are * notified. * * @see #getRange() */ public void setRange(Range range, boolean turnOffAutoRange, boolean notify) { ParamChecks.nullNotPermitted(range, "range"); if (range.getLength() <= 0.0) { throw new IllegalArgumentException( "A positive range length is required: " + range); } if (turnOffAutoRange) { this.autoRange = false; } this.range = range; if (notify) { fireChangeEvent(); } } /** * Sets the range for the axis and sends a change event to all registered * listeners. As a side-effect, the auto-range flag is set to * false. * * @param lower the lower axis limit. * @param upper the upper axis limit. * * @see #getRange() * @see #setRange(Range) */ public void setRange(double lower, double upper) { setRange(new Range(lower, upper)); } /** * Sets the range for the axis (after first adding the current margins to * the specified range) and sends an {@link AxisChangeEvent} to all * registered listeners. * * @param range the range (null not permitted). */ public void setRangeWithMargins(Range range) { setRangeWithMargins(range, true, true); } /** * Sets the range for the axis after first adding the current margins to * the range and, if requested, sends an {@link AxisChangeEvent} to all * registered listeners. As a side-effect, the auto-range flag is set to * false (optional). * * @param range the range (excluding margins, null not * permitted). * @param turnOffAutoRange a flag that controls whether or not the auto * range is turned off. * @param notify a flag that controls whether or not listeners are * notified. */ public void setRangeWithMargins(Range range, boolean turnOffAutoRange, boolean notify) { ParamChecks.nullNotPermitted(range, "range"); setRange(Range.expand(range, getLowerMargin(), getUpperMargin()), turnOffAutoRange, notify); } /** * Sets the axis range (after first adding the current margins to the * range) and sends an {@link AxisChangeEvent} to all registered listeners. * As a side-effect, the auto-range flag is set to false. * * @param lower the lower axis limit. * @param upper the upper axis limit. */ public void setRangeWithMargins(double lower, double upper) { setRangeWithMargins(new Range(lower, upper)); } /** * Sets the axis range, where the new range is 'size' in length, and * centered on 'value'. * * @param value the central value. * @param length the range length. */ public void setRangeAboutValue(double value, double length) { setRange(new Range(value - length / 2, value + length / 2)); } /** * Returns a flag indicating whether or not the tick unit is automatically * selected from a range of standard tick units. * * @return A flag indicating whether or not the tick unit is automatically * selected. * * @see #setAutoTickUnitSelection(boolean) */ public boolean isAutoTickUnitSelection() { return this.autoTickUnitSelection; } /** * Sets a flag indicating whether or not the tick unit is automatically * selected from a range of standard tick units. If the flag is changed, * registered listeners are notified that the chart has changed. * * @param flag the new value of the flag. * * @see #isAutoTickUnitSelection() */ public void setAutoTickUnitSelection(boolean flag) { setAutoTickUnitSelection(flag, true); } /** * Sets a flag indicating whether or not the tick unit is automatically * selected from a range of standard tick units. * * @param flag the new value of the flag. * @param notify notify listeners? * * @see #isAutoTickUnitSelection() */ public void setAutoTickUnitSelection(boolean flag, boolean notify) { if (this.autoTickUnitSelection != flag) { this.autoTickUnitSelection = flag; if (notify) { fireChangeEvent(); } } } /** * Returns the source for obtaining standard tick units for the axis. * * @return The source (possibly null). * * @see #setStandardTickUnits(TickUnitSource) */ public TickUnitSource getStandardTickUnits() { return this.standardTickUnits; } /** * Sets the source for obtaining standard tick units for the axis and sends * an {@link AxisChangeEvent} to all registered listeners. The axis will * try to select the smallest tick unit from the source that does not cause * the tick labels to overlap (see also the * {@link #setAutoTickUnitSelection(boolean)} method. * * @param source the source for standard tick units (null * permitted). * * @see #getStandardTickUnits() */ public void setStandardTickUnits(TickUnitSource source) { this.standardTickUnits = source; fireChangeEvent(); } /** * Returns the number of minor tick marks to display. * * @return The number of minor tick marks to display. * * @see #setMinorTickCount(int) * * @since 1.0.12 */ public int getMinorTickCount() { return this.minorTickCount; } /** * Sets the number of minor tick marks to display, and sends an * {@link AxisChangeEvent} to all registered listeners. * * @param count the count. * * @see #getMinorTickCount() * * @since 1.0.12 */ public void setMinorTickCount(int count) { this.minorTickCount = count; fireChangeEvent(); } /** * Converts a data value to a coordinate in Java2D space, assuming that the * axis runs along one edge of the specified dataArea. *

* Note that it is possible for the coordinate to fall outside the area. * * @param value the data value. * @param area the area for plotting the data. * @param edge the edge along which the axis lies. * * @return The Java2D coordinate. * * @see #java2DToValue(double, Rectangle2D, RectangleEdge) */ public abstract double valueToJava2D(double value, Rectangle2D area, RectangleEdge edge); /** * Converts a length in data coordinates into the corresponding length in * Java2D coordinates. * * @param length the length. * @param area the plot area. * @param edge the edge along which the axis lies. * * @return The length in Java2D coordinates. */ public double lengthToJava2D(double length, Rectangle2D area, RectangleEdge edge) { double zero = valueToJava2D(0.0, area, edge); double l = valueToJava2D(length, area, edge); return Math.abs(l - zero); } /** * Converts a coordinate in Java2D space to the corresponding data value, * assuming that the axis runs along one edge of the specified dataArea. * * @param java2DValue the coordinate in Java2D space. * @param area the area in which the data is plotted. * @param edge the edge along which the axis lies. * * @return The data value. * * @see #valueToJava2D(double, Rectangle2D, RectangleEdge) */ public abstract double java2DToValue(double java2DValue, Rectangle2D area, RectangleEdge edge); /** * Automatically sets the axis range to fit the range of values in the * dataset. Sometimes this can depend on the renderer used as well (for * example, the renderer may "stack" values, requiring an axis range * greater than otherwise necessary). */ protected abstract void autoAdjustRange(); /** * Centers the axis range about the specified value and sends an * {@link AxisChangeEvent} to all registered listeners. * * @param value the center value. */ public void centerRange(double value) { double central = this.range.getCentralValue(); Range adjusted = new Range(this.range.getLowerBound() + value - central, this.range.getUpperBound() + value - central); setRange(adjusted); } /** * Increases or decreases the axis range by the specified percentage about * the central value and sends an {@link AxisChangeEvent} to all registered * listeners. *

* To double the length of the axis range, use 200% (2.0). * To halve the length of the axis range, use 50% (0.5). * * @param percent the resize factor. * * @see #resizeRange(double, double) */ public void resizeRange(double percent) { resizeRange(percent, this.range.getCentralValue()); } /** * Increases or decreases the axis range by the specified percentage about * the specified anchor value and sends an {@link AxisChangeEvent} to all * registered listeners. *

* To double the length of the axis range, use 200% (2.0). * To halve the length of the axis range, use 50% (0.5). * * @param percent the resize factor. * @param anchorValue the new central value after the resize. * * @see #resizeRange(double) */ public void resizeRange(double percent, double anchorValue) { if (percent > 0.0) { double halfLength = this.range.getLength() * percent / 2; Range adjusted = new Range(anchorValue - halfLength, anchorValue + halfLength); setRange(adjusted); } else { setAutoRange(true); } } /** * Increases or decreases the axis range by the specified percentage about * the specified anchor value and sends an {@link AxisChangeEvent} to all * registered listeners. *

* To double the length of the axis range, use 200% (2.0). * To halve the length of the axis range, use 50% (0.5). * * @param percent the resize factor. * @param anchorValue the new central value after the resize. * * @see #resizeRange(double) * * @since 1.0.13 */ public void resizeRange2(double percent, double anchorValue) { if (percent > 0.0) { double left = anchorValue - getLowerBound(); double right = getUpperBound() - anchorValue; Range adjusted = new Range(anchorValue - left * percent, anchorValue + right * percent); setRange(adjusted); } else { setAutoRange(true); } } /** * Zooms in on the current range. * * @param lowerPercent the new lower bound. * @param upperPercent the new upper bound. */ public void zoomRange(double lowerPercent, double upperPercent) { double start = this.range.getLowerBound(); double length = this.range.getLength(); double r0, r1; if (isInverted()) { r0 = start + (length * (1 - upperPercent)); r1 = start + (length * (1 - lowerPercent)); } else { r0 = start + length * lowerPercent; r1 = start + length * upperPercent; } if ((r1 > r0) && !Double.isInfinite(r1 - r0)) { setRange(new Range(r0, r1)); } } /** * Slides the axis range by the specified percentage. * * @param percent the percentage. * * @since 1.0.13 */ public void pan(double percent) { Range r = getRange(); double length = range.getLength(); double adj = length * percent; double lower = r.getLowerBound() + adj; double upper = r.getUpperBound() + adj; setRange(lower, upper); } /** * Returns the auto tick index. * * @return The auto tick index. * * @see #setAutoTickIndex(int) */ protected int getAutoTickIndex() { return this.autoTickIndex; } /** * Sets the auto tick index. * * @param index the new value. * * @see #getAutoTickIndex() */ protected void setAutoTickIndex(int index) { this.autoTickIndex = index; } /** * Tests the axis for equality with an arbitrary object. * * @param obj the object (null permitted). * * @return true or false. */ @Override public boolean equals(Object obj) { if (obj == this) { return true; } if (!(obj instanceof ValueAxis)) { return false; } ValueAxis that = (ValueAxis) obj; if (this.positiveArrowVisible != that.positiveArrowVisible) { return false; } if (this.negativeArrowVisible != that.negativeArrowVisible) { return false; } if (this.inverted != that.inverted) { return false; } // if autoRange is true, then the current range is irrelevant if (!this.autoRange && !ObjectUtilities.equal(this.range, that.range)) { return false; } if (this.autoRange != that.autoRange) { return false; } if (this.autoRangeMinimumSize != that.autoRangeMinimumSize) { return false; } if (!this.defaultAutoRange.equals(that.defaultAutoRange)) { return false; } if (this.upperMargin != that.upperMargin) { return false; } if (this.lowerMargin != that.lowerMargin) { return false; } if (this.fixedAutoRange != that.fixedAutoRange) { return false; } if (this.autoTickUnitSelection != that.autoTickUnitSelection) { return false; } if (!ObjectUtilities.equal(this.standardTickUnits, that.standardTickUnits)) { return false; } if (this.verticalTickLabels != that.verticalTickLabels) { return false; } if (this.minorTickCount != that.minorTickCount) { return false; } return super.equals(obj); } /** * Returns a clone of the object. * * @return A clone. * * @throws CloneNotSupportedException if some component of the axis does * not support cloning. */ @Override public Object clone() throws CloneNotSupportedException { ValueAxis clone = (ValueAxis) super.clone(); return clone; } /** * Provides serialization support. * * @param stream the output stream. * * @throws IOException if there is an I/O error. */ private void writeObject(ObjectOutputStream stream) throws IOException { stream.defaultWriteObject(); SerialUtilities.writeShape(this.upArrow, stream); SerialUtilities.writeShape(this.downArrow, stream); SerialUtilities.writeShape(this.leftArrow, stream); SerialUtilities.writeShape(this.rightArrow, stream); } /** * Provides serialization support. * * @param stream the input stream. * * @throws IOException if there is an I/O error. * @throws ClassNotFoundException if there is a classpath problem. */ private void readObject(ObjectInputStream stream) throws IOException, ClassNotFoundException { stream.defaultReadObject(); this.upArrow = SerialUtilities.readShape(stream); this.downArrow = SerialUtilities.readShape(stream); this.leftArrow = SerialUtilities.readShape(stream); this.rightArrow = SerialUtilities.readShape(stream); } }





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