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JFreeChart is a class library, written in Java, for generating charts. Utilising the Java2D API, it supports a wide range of chart types including bar charts, pie charts, line charts, XY-plots, time series plots, Sankey charts and more.

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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.]
 *
 * ---------------
 * NumberAxis.java
 * ---------------
 * (C) Copyright 2000-present, by David Gilbert and Contributors.
 *
 * Original Author:  David Gilbert;
 * Contributor(s):   Laurence Vanhelsuwe;
 *                   Peter Kolb (patches 1934255 and 2603321);
 * 
 */

package org.jfree.chart.axis;

import java.awt.Font;
import java.awt.FontMetrics;
import java.awt.Graphics2D;
import java.awt.font.FontRenderContext;
import java.awt.font.LineMetrics;
import java.awt.geom.Rectangle2D;
import java.io.Serializable;
import java.text.DecimalFormat;
import java.text.NumberFormat;
import java.util.ArrayList;
import java.util.List;
import java.util.Locale;
import java.util.Objects;

import org.jfree.chart.event.AxisChangeEvent;
import org.jfree.chart.plot.Plot;
import org.jfree.chart.plot.PlotRenderingInfo;
import org.jfree.chart.plot.ValueAxisPlot;
import org.jfree.chart.ui.RectangleEdge;
import org.jfree.chart.ui.RectangleInsets;
import org.jfree.chart.ui.TextAnchor;
import org.jfree.chart.util.Args;
import org.jfree.data.Range;
import org.jfree.data.RangeType;

/**
 * An axis for displaying numerical data.
 * 

* If the axis is set up to automatically determine its range to fit the data, * you can ensure that the range includes zero (statisticians usually prefer * this) by setting the {@code autoRangeIncludesZero} flag to * {@code true}. *

* The {@code NumberAxis} class has a mechanism for automatically * selecting a tick unit that is appropriate for the current axis range. */ public class NumberAxis extends ValueAxis implements Cloneable, Serializable { /** For serialization. */ private static final long serialVersionUID = 2805933088476185789L; /** The default value for the autoRangeIncludesZero flag. */ public static final boolean DEFAULT_AUTO_RANGE_INCLUDES_ZERO = true; /** The default value for the autoRangeStickyZero flag. */ public static final boolean DEFAULT_AUTO_RANGE_STICKY_ZERO = true; /** The default tick unit. */ public static final NumberTickUnit DEFAULT_TICK_UNIT = new NumberTickUnit( 1.0, new DecimalFormat("0")); /** The default setting for the vertical tick labels flag. */ public static final boolean DEFAULT_VERTICAL_TICK_LABELS = false; /** * The range type (can be used to force the axis to display only positive * values or only negative values). */ private RangeType rangeType; /** * A flag that affects the axis range when the range is determined * automatically. If the auto range does NOT include zero and this flag * is TRUE, then the range is changed to include zero. */ private boolean autoRangeIncludesZero; /** * A flag that affects the size of the margins added to the axis range when * the range is determined automatically. If the value 0 falls within the * margin and this flag is TRUE, then the margin is truncated at zero. */ private boolean autoRangeStickyZero; /** The tick unit for the axis. */ private NumberTickUnit tickUnit; /** The override number format. */ private NumberFormat numberFormatOverride; /** An optional band for marking regions on the axis. */ private MarkerAxisBand markerBand; /** * Default constructor. */ public NumberAxis() { this(null); } /** * Constructs a number axis, using default values where necessary. * * @param label the axis label ({@code null} permitted). */ public NumberAxis(String label) { super(label, NumberAxis.createStandardTickUnits()); this.rangeType = RangeType.FULL; this.autoRangeIncludesZero = DEFAULT_AUTO_RANGE_INCLUDES_ZERO; this.autoRangeStickyZero = DEFAULT_AUTO_RANGE_STICKY_ZERO; this.tickUnit = DEFAULT_TICK_UNIT; this.numberFormatOverride = null; this.markerBand = null; } /** * Returns the axis range type. * * @return The axis range type (never {@code null}). * * @see #setRangeType(RangeType) */ public RangeType getRangeType() { return this.rangeType; } /** * Sets the axis range type. * * @param rangeType the range type ({@code null} not permitted). * * @see #getRangeType() */ public void setRangeType(RangeType rangeType) { Args.nullNotPermitted(rangeType, "rangeType"); this.rangeType = rangeType; notifyListeners(new AxisChangeEvent(this)); } /** * Returns the flag that indicates whether or not the automatic axis range * (if indeed it is determined automatically) is forced to include zero. * * @return The flag. */ public boolean getAutoRangeIncludesZero() { return this.autoRangeIncludesZero; } /** * Sets the flag that indicates whether or not the axis range, if * automatically calculated, is forced to include zero. *

* If the flag is changed to {@code true}, the axis range is * recalculated. *

* Any change to the flag will trigger an {@link AxisChangeEvent}. * * @param flag the new value of the flag. * * @see #getAutoRangeIncludesZero() */ public void setAutoRangeIncludesZero(boolean flag) { if (this.autoRangeIncludesZero != flag) { this.autoRangeIncludesZero = flag; if (isAutoRange()) { autoAdjustRange(); } notifyListeners(new AxisChangeEvent(this)); } } /** * Returns a flag that affects the auto-range when zero falls outside the * data range but inside the margins defined for the axis. * * @return The flag. * * @see #setAutoRangeStickyZero(boolean) */ public boolean getAutoRangeStickyZero() { return this.autoRangeStickyZero; } /** * Sets a flag that affects the auto-range when zero falls outside the data * range but inside the margins defined for the axis. * * @param flag the new flag. * * @see #getAutoRangeStickyZero() */ public void setAutoRangeStickyZero(boolean flag) { if (this.autoRangeStickyZero != flag) { this.autoRangeStickyZero = flag; if (isAutoRange()) { autoAdjustRange(); } notifyListeners(new AxisChangeEvent(this)); } } /** * Returns the tick unit for the axis. *

* Note: if the {@code autoTickUnitSelection} flag is * {@code true} the tick unit may be changed while the axis is being * drawn, so in that case the return value from this method may be * irrelevant if the method is called before the axis has been drawn. * * @return The tick unit for the axis. * * @see #setTickUnit(NumberTickUnit) * @see ValueAxis#isAutoTickUnitSelection() */ public NumberTickUnit getTickUnit() { return this.tickUnit; } /** * Sets the tick unit for the axis and sends an {@link AxisChangeEvent} to * all registered listeners. A side effect of calling this method is that * the "auto-select" feature for tick units is switched off (you can * restore it using the {@link ValueAxis#setAutoTickUnitSelection(boolean)} * method). * * @param unit the new tick unit ({@code null} not permitted). * * @see #getTickUnit() * @see #setTickUnit(NumberTickUnit, boolean, boolean) */ public void setTickUnit(NumberTickUnit unit) { // defer argument checking... setTickUnit(unit, true, true); } /** * Sets the tick unit for the axis and, if requested, sends an * {@link AxisChangeEvent} to all registered listeners. In addition, an * option is provided to turn off the "auto-select" feature for tick units * (you can restore it using the * {@link ValueAxis#setAutoTickUnitSelection(boolean)} method). * * @param unit the new tick unit ({@code null} not permitted). * @param notify notify listeners? * @param turnOffAutoSelect turn off the auto-tick selection? */ public void setTickUnit(NumberTickUnit unit, boolean notify, boolean turnOffAutoSelect) { Args.nullNotPermitted(unit, "unit"); this.tickUnit = unit; if (turnOffAutoSelect) { setAutoTickUnitSelection(false, false); } if (notify) { notifyListeners(new AxisChangeEvent(this)); } } /** * Returns the number format override. If this is non-null, then it will * be used to format the numbers on the axis. * * @return The number formatter (possibly {@code null}). * * @see #setNumberFormatOverride(NumberFormat) */ public NumberFormat getNumberFormatOverride() { return this.numberFormatOverride; } /** * Sets the number format override. If this is non-null, then it will be * used to format the numbers on the axis. * * @param formatter the number formatter ({@code null} permitted). * * @see #getNumberFormatOverride() */ public void setNumberFormatOverride(NumberFormat formatter) { this.numberFormatOverride = formatter; notifyListeners(new AxisChangeEvent(this)); } /** * Returns the (optional) marker band for the axis. * * @return The marker band (possibly {@code null}). * * @see #setMarkerBand(MarkerAxisBand) */ public MarkerAxisBand getMarkerBand() { return this.markerBand; } /** * Sets the marker band for the axis. *

* The marker band is optional, leave it set to {@code null} if you * don't require it. * * @param band the new band ({@code null} permitted). * * @see #getMarkerBand() */ public void setMarkerBand(MarkerAxisBand band) { this.markerBand = band; notifyListeners(new AxisChangeEvent(this)); } /** * Configures the axis to work with the specified plot. If the axis has * auto-scaling, then sets the maximum and minimum values. */ @Override public void configure() { if (isAutoRange()) { autoAdjustRange(); } } /** * Rescales the axis to ensure that all data is visible. */ @Override protected void autoAdjustRange() { Plot plot = getPlot(); if (plot == null) { return; // no plot, no data } if (plot instanceof ValueAxisPlot) { ValueAxisPlot vap = (ValueAxisPlot) plot; Range r = vap.getDataRange(this); if (r == null) { r = getDefaultAutoRange(); } double upper = r.getUpperBound(); double lower = r.getLowerBound(); if (this.rangeType == RangeType.POSITIVE) { lower = Math.max(0.0, lower); upper = Math.max(0.0, upper); } else if (this.rangeType == RangeType.NEGATIVE) { lower = Math.min(0.0, lower); upper = Math.min(0.0, upper); } if (getAutoRangeIncludesZero()) { lower = Math.min(lower, 0.0); upper = Math.max(upper, 0.0); } double range = upper - lower; // if fixed auto range, then derive lower bound... double fixedAutoRange = getFixedAutoRange(); if (fixedAutoRange > 0.0) { lower = upper - fixedAutoRange; } else { // ensure the autorange is at least in size... double minRange = getAutoRangeMinimumSize(); if (range < minRange) { double expand = (minRange - range) / 2; upper = upper + expand; lower = lower - expand; if (lower == upper) { // see bug report 1549218 double adjust = Math.abs(lower) / 10.0; lower = lower - adjust; upper = upper + adjust; } if (this.rangeType == RangeType.POSITIVE) { if (lower < 0.0) { upper = upper - lower; lower = 0.0; } } else if (this.rangeType == RangeType.NEGATIVE) { if (upper > 0.0) { lower = lower - upper; upper = 0.0; } } } if (getAutoRangeStickyZero()) { if (upper <= 0.0) { upper = Math.min(0.0, upper + getUpperMargin() * range); } else { upper = upper + getUpperMargin() * range; } if (lower >= 0.0) { lower = Math.max(0.0, lower - getLowerMargin() * range); } else { lower = lower - getLowerMargin() * range; } } else { upper = upper + getUpperMargin() * range; lower = lower - getLowerMargin() * range; } } setRange(new Range(lower, upper), false, false); } } /** * 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 plotArea. * * @param value the data value. * @param area the area for plotting the data. * @param edge the axis location. * * @return The Java2D coordinate. * * @see #java2DToValue(double, Rectangle2D, RectangleEdge) */ @Override public double valueToJava2D(double value, Rectangle2D area, RectangleEdge edge) { Range range = getRange(); double axisMin = range.getLowerBound(); double axisMax = range.getUpperBound(); double min = 0.0; double max = 0.0; if (RectangleEdge.isTopOrBottom(edge)) { min = area.getX(); max = area.getMaxX(); } else if (RectangleEdge.isLeftOrRight(edge)) { max = area.getMinY(); min = area.getMaxY(); } if (isInverted()) { return max - ((value - axisMin) / (axisMax - axisMin)) * (max - min); } else { return min + ((value - axisMin) / (axisMax - axisMin)) * (max - min); } } /** * 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 location. * * @return The data value. * * @see #valueToJava2D(double, Rectangle2D, RectangleEdge) */ @Override public double java2DToValue(double java2DValue, Rectangle2D area, RectangleEdge edge) { Range range = getRange(); double axisMin = range.getLowerBound(); double axisMax = range.getUpperBound(); double min = 0.0; double max = 0.0; if (RectangleEdge.isTopOrBottom(edge)) { min = area.getX(); max = area.getMaxX(); } else if (RectangleEdge.isLeftOrRight(edge)) { min = area.getMaxY(); max = area.getY(); } if (isInverted()) { return axisMax - (java2DValue - min) / (max - min) * (axisMax - axisMin); } else { return axisMin + (java2DValue - min) / (max - min) * (axisMax - axisMin); } } /** * Calculates the value of the lowest visible tick on the axis. * * @return The value of the lowest visible tick on the axis. * * @see #calculateHighestVisibleTickValue() */ protected double calculateLowestVisibleTickValue() { double unit = getTickUnit().getSize(); double index = Math.ceil(getRange().getLowerBound() / unit); return index * unit; } /** * Calculates the value of the highest visible tick on the axis. * * @return The value of the highest visible tick on the axis. * * @see #calculateLowestVisibleTickValue() */ protected double calculateHighestVisibleTickValue() { double unit = getTickUnit().getSize(); double index = Math.floor(getRange().getUpperBound() / unit); return index * unit; } /** * Calculates the number of visible ticks. * * @return The number of visible ticks on the axis. */ protected int calculateVisibleTickCount() { double unit = getTickUnit().getSize(); Range range = getRange(); return (int) (Math.floor(range.getUpperBound() / unit) - Math.ceil(range.getLowerBound() / unit) + 1); } /** * Draws the axis on a Java 2D graphics device (such as the screen or a * printer). * * @param g2 the graphics device ({@code null} not permitted). * @param cursor the cursor location. * @param plotArea the area within which the axes and data should be drawn * ({@code null} not permitted). * @param dataArea the area within which the data should be drawn * ({@code null} not permitted). * @param edge the location of the axis ({@code null} not permitted). * @param plotState collects information about the plot * ({@code null} permitted). * * @return The axis state (never {@code null}). */ @Override public AxisState draw(Graphics2D g2, double cursor, Rectangle2D plotArea, Rectangle2D dataArea, RectangleEdge edge, PlotRenderingInfo plotState) { AxisState state; // if the axis is not visible, don't draw it... if (!isVisible()) { state = new AxisState(cursor); // even though the axis is not visible, we need ticks for the // gridlines... List ticks = refreshTicks(g2, state, dataArea, edge); state.setTicks(ticks); return state; } // draw the tick marks and labels... state = drawTickMarksAndLabels(g2, cursor, plotArea, dataArea, edge); if (getAttributedLabel() != null) { state = drawAttributedLabel(getAttributedLabel(), g2, plotArea, dataArea, edge, state); } else { state = drawLabel(getLabel(), g2, plotArea, dataArea, edge, state); } createAndAddEntity(cursor, state, dataArea, edge, plotState); return state; } /** * Creates the standard tick units. *

* If you don't like these defaults, create your own instance of TickUnits * and then pass it to the setStandardTickUnits() method in the * NumberAxis class. * * @return The standard tick units. * * @see #setStandardTickUnits(TickUnitSource) * @see #createIntegerTickUnits() */ public static TickUnitSource createStandardTickUnits() { return new NumberTickUnitSource(); } /** * Returns a collection of tick units for integer values. * * @return A collection of tick units for integer values. * * @see #setStandardTickUnits(TickUnitSource) * @see #createStandardTickUnits() */ public static TickUnitSource createIntegerTickUnits() { return new NumberTickUnitSource(true); } /** * Creates a collection of standard tick units. The supplied locale is * used to create the number formatter (a localised instance of * {@code NumberFormat}). *

* If you don't like these defaults, create your own instance of * {@link TickUnits} and then pass it to the * {@code setStandardTickUnits()} method. * * @param locale the locale. * * @return A tick unit collection. * * @see #setStandardTickUnits(TickUnitSource) */ public static TickUnitSource createStandardTickUnits(Locale locale) { NumberFormat numberFormat = NumberFormat.getNumberInstance(locale); return new NumberTickUnitSource(false, numberFormat); } /** * Returns a collection of tick units for integer values. * Uses a given Locale to create the DecimalFormats. * * @param locale the locale to use to represent Numbers. * * @return A collection of tick units for integer values. * * @see #setStandardTickUnits(TickUnitSource) */ public static TickUnitSource createIntegerTickUnits(Locale locale) { NumberFormat numberFormat = NumberFormat.getNumberInstance(locale); return new NumberTickUnitSource(true, numberFormat); } /** * Estimates the maximum tick label height. * * @param g2 the graphics device. * * @return The maximum height. */ protected double estimateMaximumTickLabelHeight(Graphics2D g2) { RectangleInsets tickLabelInsets = getTickLabelInsets(); double result = tickLabelInsets.getTop() + tickLabelInsets.getBottom(); Font tickLabelFont = getTickLabelFont(); FontRenderContext frc = g2.getFontRenderContext(); result += tickLabelFont.getLineMetrics("123", frc).getHeight(); return result; } /** * Estimates the maximum width of the tick labels, assuming the specified * tick unit is used. *

* Rather than computing the string bounds of every tick on the axis, we * just look at two values: the lower bound and the upper bound for the * axis. These two values will usually be representative. * * @param g2 the graphics device. * @param unit the tick unit to use for calculation. * * @return The estimated maximum width of the tick labels. */ protected double estimateMaximumTickLabelWidth(Graphics2D g2, TickUnit unit) { RectangleInsets tickLabelInsets = getTickLabelInsets(); double result = tickLabelInsets.getLeft() + tickLabelInsets.getRight(); if (isVerticalTickLabels()) { // all tick labels have the same width (equal to the height of the // font)... FontRenderContext frc = g2.getFontRenderContext(); LineMetrics lm = getTickLabelFont().getLineMetrics("0", frc); result += lm.getHeight(); } else { // look at lower and upper bounds... FontMetrics fm = g2.getFontMetrics(getTickLabelFont()); Range range = getRange(); double lower = range.getLowerBound(); double upper = range.getUpperBound(); String lowerStr, upperStr; NumberFormat formatter = getNumberFormatOverride(); if (formatter != null) { lowerStr = formatter.format(lower); upperStr = formatter.format(upper); } else { lowerStr = unit.valueToString(lower); upperStr = unit.valueToString(upper); } double w1 = fm.stringWidth(lowerStr); double w2 = fm.stringWidth(upperStr); result += Math.max(w1, w2); } return result; } /** * Selects an appropriate tick value for the axis. The strategy is to * display as many ticks as possible (selected from an array of 'standard' * tick units) without the labels overlapping. * * @param g2 the graphics device. * @param dataArea the area defined by the axes. * @param edge the axis location. */ protected void selectAutoTickUnit(Graphics2D g2, Rectangle2D dataArea, RectangleEdge edge) { if (RectangleEdge.isTopOrBottom(edge)) { selectHorizontalAutoTickUnit(g2, dataArea, edge); } else if (RectangleEdge.isLeftOrRight(edge)) { selectVerticalAutoTickUnit(g2, dataArea, edge); } } /** * Selects an appropriate tick value for the axis. The strategy is to * display as many ticks as possible (selected from an array of 'standard' * tick units) without the labels overlapping. * * @param g2 the graphics device. * @param dataArea the area defined by the axes. * @param edge the axis location. */ protected void selectHorizontalAutoTickUnit(Graphics2D g2, Rectangle2D dataArea, RectangleEdge edge) { TickUnit unit = getTickUnit(); TickUnitSource tickUnitSource = getStandardTickUnits(); // we should start with the current tick unit if it gives a count in // the range 3 to 40 otherwise estimate one that will give a count <= 10 double length = getRange().getLength(); int count = (int) (length / unit.getSize()); if (count < 3 || count > 40) { unit = tickUnitSource.getCeilingTickUnit(length / 10); } // now consider the label size relative to the width of the tick unit // and make a guess at the ideal size TickUnit unit1 = tickUnitSource.getCeilingTickUnit(unit); double tickLabelWidth = estimateMaximumTickLabelWidth(g2, unit1); double unit1Width = lengthToJava2D(unit1.getSize(), dataArea, edge); NumberTickUnit unit2 = (NumberTickUnit) unit1; double guess = (tickLabelWidth / unit1Width) * unit1.getSize(); // due to limitations of double precision, when you zoom very far into // a chart, eventually the visible axis range will get reported as // having length 0, and then 'guess' above will be infinite ... in that // case we'll just stick with the tick unit we have, it's better than // throwing an exception // https://github.com/jfree/jfreechart/issues/64 if (Double.isFinite(guess)) { unit2 = (NumberTickUnit) tickUnitSource.getCeilingTickUnit(guess); double unit2Width = lengthToJava2D(unit2.getSize(), dataArea, edge); tickLabelWidth = estimateMaximumTickLabelWidth(g2, unit2); if (tickLabelWidth > unit2Width) { unit2 = (NumberTickUnit) tickUnitSource.getLargerTickUnit(unit2); } } setTickUnit(unit2, false, false); } /** * Selects an appropriate tick value for the axis. The strategy is to * display as many ticks as possible (selected from an array of 'standard' * tick units) without the labels overlapping. * * @param g2 the graphics device. * @param dataArea the area in which the plot should be drawn. * @param edge the axis location. */ protected void selectVerticalAutoTickUnit(Graphics2D g2, Rectangle2D dataArea, RectangleEdge edge) { double tickLabelHeight = estimateMaximumTickLabelHeight(g2); // start with the current tick unit... TickUnitSource tickUnits = getStandardTickUnits(); TickUnit unit1 = tickUnits.getCeilingTickUnit(getTickUnit()); double unitHeight = lengthToJava2D(unit1.getSize(), dataArea, edge); double guess; if (unitHeight > 0) { // then extrapolate... guess = (tickLabelHeight / unitHeight) * unit1.getSize(); } else { guess = getRange().getLength() / 20.0; } NumberTickUnit unit2 = (NumberTickUnit) tickUnits.getCeilingTickUnit( guess); double unit2Height = lengthToJava2D(unit2.getSize(), dataArea, edge); tickLabelHeight = estimateMaximumTickLabelHeight(g2); if (tickLabelHeight > unit2Height) { unit2 = (NumberTickUnit) tickUnits.getLargerTickUnit(unit2); } setTickUnit(unit2, false, false); } /** * Calculates the positions of the tick labels for the axis, storing the * results in the tick label list (ready for drawing). * * @param g2 the graphics device. * @param state the axis state. * @param dataArea the area in which the plot should be drawn. * @param edge the location of the axis. * * @return A list of ticks. */ @Override public List refreshTicks(Graphics2D g2, AxisState state, Rectangle2D dataArea, RectangleEdge edge) { List result = new java.util.ArrayList(); if (RectangleEdge.isTopOrBottom(edge)) { result = refreshTicksHorizontal(g2, dataArea, edge); } else if (RectangleEdge.isLeftOrRight(edge)) { result = refreshTicksVertical(g2, dataArea, edge); } return result; } /** * Calculates the positions of the tick labels for the axis, storing the * results in the tick label list (ready for drawing). * * @param g2 the graphics device. * @param dataArea the area in which the data should be drawn. * @param edge the location of the axis. * * @return A list of ticks. */ protected List refreshTicksHorizontal(Graphics2D g2, Rectangle2D dataArea, RectangleEdge edge) { List result = new java.util.ArrayList(); Font tickLabelFont = getTickLabelFont(); g2.setFont(tickLabelFont); if (isAutoTickUnitSelection()) { selectAutoTickUnit(g2, dataArea, edge); } TickUnit tu = getTickUnit(); double size = tu.getSize(); int count = calculateVisibleTickCount(); double lowestTickValue = calculateLowestVisibleTickValue(); if (count <= ValueAxis.MAXIMUM_TICK_COUNT) { int minorTickSpaces = getMinorTickCount(); if (minorTickSpaces <= 0) { minorTickSpaces = tu.getMinorTickCount(); } for (int minorTick = 1; minorTick < minorTickSpaces; minorTick++) { double minorTickValue = lowestTickValue - size * minorTick / minorTickSpaces; if (getRange().contains(minorTickValue)) { result.add(new NumberTick(TickType.MINOR, minorTickValue, "", TextAnchor.TOP_CENTER, TextAnchor.CENTER, 0.0)); } } for (int i = 0; i < count; i++) { double currentTickValue = lowestTickValue + (i * size); String tickLabel; NumberFormat formatter = getNumberFormatOverride(); if (formatter != null) { tickLabel = formatter.format(currentTickValue); } else { tickLabel = getTickUnit().valueToString(currentTickValue); } TextAnchor anchor, rotationAnchor; double angle = 0.0; if (isVerticalTickLabels()) { anchor = TextAnchor.CENTER_RIGHT; rotationAnchor = TextAnchor.CENTER_RIGHT; if (edge == RectangleEdge.TOP) { angle = Math.PI / 2.0; } else { angle = -Math.PI / 2.0; } } else { if (edge == RectangleEdge.TOP) { anchor = TextAnchor.BOTTOM_CENTER; rotationAnchor = TextAnchor.BOTTOM_CENTER; } else { anchor = TextAnchor.TOP_CENTER; rotationAnchor = TextAnchor.TOP_CENTER; } } Tick tick = new NumberTick(currentTickValue, tickLabel, anchor, rotationAnchor, angle); result.add(tick); double nextTickValue = lowestTickValue + ((i + 1) * size); for (int minorTick = 1; minorTick < minorTickSpaces; minorTick++) { double minorTickValue = currentTickValue + (nextTickValue - currentTickValue) * minorTick / minorTickSpaces; if (getRange().contains(minorTickValue)) { result.add(new NumberTick(TickType.MINOR, minorTickValue, "", TextAnchor.TOP_CENTER, TextAnchor.CENTER, 0.0)); } } } } return result; } /** * Calculates the positions of the tick labels for the axis, storing the * results in the tick label list (ready for drawing). * * @param g2 the graphics device. * @param dataArea the area in which the plot should be drawn. * @param edge the location of the axis. * * @return A list of ticks. */ protected List refreshTicksVertical(Graphics2D g2, Rectangle2D dataArea, RectangleEdge edge) { List result = new ArrayList<>(); Font tickLabelFont = getTickLabelFont(); g2.setFont(tickLabelFont); if (isAutoTickUnitSelection()) { selectAutoTickUnit(g2, dataArea, edge); } TickUnit tu = getTickUnit(); double size = tu.getSize(); int count = calculateVisibleTickCount(); double lowestTickValue = calculateLowestVisibleTickValue(); if (count <= ValueAxis.MAXIMUM_TICK_COUNT) { int minorTickSpaces = getMinorTickCount(); if (minorTickSpaces <= 0) { minorTickSpaces = tu.getMinorTickCount(); } for (int minorTick = 1; minorTick < minorTickSpaces; minorTick++) { double minorTickValue = lowestTickValue - size * minorTick / minorTickSpaces; if (getRange().contains(minorTickValue)) { result.add(new NumberTick(TickType.MINOR, minorTickValue, "", TextAnchor.TOP_CENTER, TextAnchor.CENTER, 0.0)); } } for (int i = 0; i < count; i++) { double currentTickValue = lowestTickValue + (i * size); String tickLabel; NumberFormat formatter = getNumberFormatOverride(); if (formatter != null) { tickLabel = formatter.format(currentTickValue); } else { tickLabel = getTickUnit().valueToString(currentTickValue); } TextAnchor anchor; TextAnchor rotationAnchor; double angle = 0.0; if (isVerticalTickLabels()) { if (edge == RectangleEdge.LEFT) { anchor = TextAnchor.BOTTOM_CENTER; rotationAnchor = TextAnchor.BOTTOM_CENTER; angle = -Math.PI / 2.0; } else { anchor = TextAnchor.BOTTOM_CENTER; rotationAnchor = TextAnchor.BOTTOM_CENTER; angle = Math.PI / 2.0; } } else { if (edge == RectangleEdge.LEFT) { anchor = TextAnchor.CENTER_RIGHT; rotationAnchor = TextAnchor.CENTER_RIGHT; } else { anchor = TextAnchor.CENTER_LEFT; rotationAnchor = TextAnchor.CENTER_LEFT; } } Tick tick = new NumberTick(currentTickValue, tickLabel, anchor, rotationAnchor, angle); result.add(tick); double nextTickValue = lowestTickValue + ((i + 1) * size); for (int minorTick = 1; minorTick < minorTickSpaces; minorTick++) { double minorTickValue = currentTickValue + (nextTickValue - currentTickValue) * minorTick / minorTickSpaces; if (getRange().contains(minorTickValue)) { result.add(new NumberTick(TickType.MINOR, minorTickValue, "", TextAnchor.TOP_CENTER, TextAnchor.CENTER, 0.0)); } } } } return result; } /** * Returns a clone of the axis. * * @return A clone * * @throws CloneNotSupportedException if some component of the axis does * not support cloning. */ @Override public Object clone() throws CloneNotSupportedException { NumberAxis clone = (NumberAxis) super.clone(); if (this.numberFormatOverride != null) { clone.numberFormatOverride = (NumberFormat) this.numberFormatOverride.clone(); } return clone; } /** * Tests the axis 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 NumberAxis)) { return false; } NumberAxis that = (NumberAxis) obj; if (this.autoRangeIncludesZero != that.autoRangeIncludesZero) { return false; } if (this.autoRangeStickyZero != that.autoRangeStickyZero) { return false; } if (!Objects.equals(this.tickUnit, that.tickUnit)) { return false; } if (!Objects.equals(this.numberFormatOverride, that.numberFormatOverride)) { return false; } if (!this.rangeType.equals(that.rangeType)) { return false; } return super.equals(obj); } /** * Returns a hash code for this object. * * @return A hash code. */ @Override public int hashCode() { return super.hashCode(); } }





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