org.jfree.chart.axis.LogAxis Maven / Gradle / Ivy
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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.]
*
* ------------
* LogAxis.java
* ------------
* (C) Copyright 2006-present, by David Gilbert and Contributors.
*
* Original Author: David Gilbert;
* Contributor(s): Andrew Mickish (patch 1868745);
* Peter Kolb (patches 1934255 and 2603321);
*/
package org.jfree.chart.axis;
import java.awt.Font;
import java.awt.Graphics2D;
import java.awt.font.FontRenderContext;
import java.awt.font.LineMetrics;
import java.awt.font.TextAttribute;
import java.awt.geom.Rectangle2D;
import java.text.AttributedString;
import java.text.DecimalFormat;
import java.text.Format;
import java.text.NumberFormat;
import java.util.ArrayList;
import java.util.List;
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.AttrStringUtils;
import org.jfree.chart.util.Args;
import org.jfree.data.Range;
/**
* A numerical axis that uses a logarithmic scale. The class is an
* alternative to the {@link LogarithmicAxis} class.
*/
public class LogAxis extends ValueAxis {
/** The logarithm base. */
private double base = 10.0;
/** The logarithm of the base value - cached for performance. */
private double baseLog = Math.log(10.0);
/**
* The base symbol to display (if {@code null} then the numerical
* value of the base is displayed).
*/
private String baseSymbol = null;
/**
* The formatter to use for the base value when the base is displayed
* as a numerical value.
*/
private Format baseFormatter = new DecimalFormat("0");
/** The smallest value permitted on the axis. */
private double smallestValue = 1E-100;
/** The current tick unit. */
private NumberTickUnit tickUnit;
/** The override number format. */
private NumberFormat numberFormatOverride;
/**
* Creates a new {@code LogAxis} with no label.
*/
public LogAxis() {
this(null);
}
/**
* Creates a new {@code LogAxis} with the given label.
*
* @param label the axis label ({@code null} permitted).
*/
public LogAxis(String label) {
super(label, new NumberTickUnitSource());
setDefaultAutoRange(new Range(0.01, 1.0));
this.tickUnit = new NumberTickUnit(1.0, new DecimalFormat("0.#"), 10);
}
/**
* Returns the base for the logarithm calculation. The default value is
* {@code 10.0}.
*
* @return The base for the logarithm calculation.
*
* @see #setBase(double)
*/
public double getBase() {
return this.base;
}
/**
* Sets the base for the logarithm calculation and sends a change event to
* all registered listeners.
*
* @param base the base value (must be > 1.0).
*
* @see #getBase()
*/
public void setBase(double base) {
if (base <= 1.0) {
throw new IllegalArgumentException("Requires 'base' > 1.0.");
}
this.base = base;
this.baseLog = Math.log(base);
fireChangeEvent();
}
/**
* Returns the symbol used to represent the base of the logarithmic scale
* for the axis. If this is {@code null} (the default) then the
* numerical value of the base is displayed.
*
* @return The base symbol (possibly {@code null}).
*/
public String getBaseSymbol() {
return this.baseSymbol;
}
/**
* Sets the symbol used to represent the base value of the logarithmic
* scale and sends a change event to all registered listeners.
*
* @param symbol the symbol ({@code null} permitted).
*/
public void setBaseSymbol(String symbol) {
this.baseSymbol = symbol;
fireChangeEvent();
}
/**
* Returns the formatter used to format the base value of the logarithmic
* scale when it is displayed numerically. The default value is
* {@code new DecimalFormat("0")}.
*
* @return The base formatter (never {@code null}).
*/
public Format getBaseFormatter() {
return this.baseFormatter;
}
/**
* Sets the formatter used to format the base value of the logarithmic
* scale when it is displayed numerically and sends a change event to all
* registered listeners.
*
* @param formatter the formatter ({@code null} not permitted).
*/
public void setBaseFormatter(Format formatter) {
Args.nullNotPermitted(formatter, "formatter");
this.baseFormatter = formatter;
fireChangeEvent();
}
/**
* Returns the smallest value represented by the axis.
*
* @return The smallest value represented by the axis.
*
* @see #setSmallestValue(double)
*/
public double getSmallestValue() {
return this.smallestValue;
}
/**
* Sets the smallest value represented by the axis and sends a change event
* to all registered listeners.
*
* @param value the value.
*
* @see #getSmallestValue()
*/
public void setSmallestValue(double value) {
if (value <= 0.0) {
throw new IllegalArgumentException("Requires 'value' > 0.0.");
}
this.smallestValue = value;
fireChangeEvent();
}
/**
* Returns the current tick unit.
*
* @return The current tick unit.
*
* @see #setTickUnit(NumberTickUnit)
*/
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()
*/
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?
*
* @see #getTickUnit()
*/
public void setTickUnit(NumberTickUnit unit, boolean notify,
boolean turnOffAutoSelect) {
Args.nullNotPermitted(unit, "unit");
this.tickUnit = unit;
if (turnOffAutoSelect) {
setAutoTickUnitSelection(false, false);
}
if (notify) {
fireChangeEvent();
}
}
/**
* Returns the number format override. If this is non-{@code 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 and sends a change event to all
* registered listeners. If this is non-{@code 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;
fireChangeEvent();
}
/**
* Calculates the log of the given value, using the current base.
*
* @param value the value.
*
* @return The log of the given value.
*
* @see #calculateValue(double)
* @see #getBase()
*/
public double calculateLog(double value) {
return Math.log(value) / this.baseLog;
}
/**
* Calculates the value from a given log.
*
* @param log the log value.
*
* @return The value with the given log.
*
* @see #calculateLog(double)
* @see #getBase()
*/
public double calculateValue(double log) {
return Math.pow(this.base, log);
}
private double calculateValueNoINF(double log) {
double result = calculateValue(log);
if (Double.isInfinite(result)) {
result = Double.MAX_VALUE;
}
if (result <= 0.0) {
result = Double.MIN_VALUE;
}
return result;
}
/**
* Converts a Java2D coordinate to an axis value, assuming that the
* axis is aligned to the specified {@code edge} of the {@code area}.
*
* @param java2DValue the Java2D coordinate.
* @param area the area for plotting data ({@code null} not
* permitted).
* @param edge the edge that the axis is aligned to ({@code null} not
* permitted).
*
* @return A value along the axis scale.
*/
@Override
public double java2DToValue(double java2DValue, Rectangle2D area,
RectangleEdge edge) {
Range range = getRange();
double axisMin = calculateLog(Math.max(this.smallestValue,
range.getLowerBound()));
double axisMax = calculateLog(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();
}
double log;
if (isInverted()) {
log = axisMax - (java2DValue - min) / (max - min)
* (axisMax - axisMin);
} else {
log = axisMin + (java2DValue - min) / (max - min)
* (axisMax - axisMin);
}
return calculateValue(log);
}
/**
* Converts a value on the axis scale to a Java2D coordinate relative to
* the given {@code area}, based on the axis running along the
* specified {@code edge}.
*
* @param value the data value.
* @param area the area ({@code null} not permitted).
* @param edge the edge ({@code null} not permitted).
*
* @return The Java2D coordinate corresponding to {@code value}.
*/
@Override
public double valueToJava2D(double value, Rectangle2D area,
RectangleEdge edge) {
Range range = getRange();
double axisMin = calculateLog(range.getLowerBound());
double axisMax = calculateLog(range.getUpperBound());
value = calculateLog(value);
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);
}
}
/**
* Configures the axis. This method is typically called when an axis
* is assigned to a new plot.
*/
@Override
public void configure() {
if (isAutoRange()) {
autoAdjustRange();
}
}
/**
* Adjusts the axis range to match the data range that the axis is
* required to display.
*/
@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 = Math.max(r.getLowerBound(), this.smallestValue);
double range = upper - lower;
// if fixed auto range, then derive lower bound...
double fixedAutoRange = getFixedAutoRange();
if (fixedAutoRange > 0.0) {
lower = Math.max(upper - fixedAutoRange, this.smallestValue);
}
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;
}
// apply the margins - these should apply to the exponent range
double logUpper = calculateLog(upper);
double logLower = calculateLog(lower);
double logRange = logUpper - logLower;
logUpper = logUpper + getUpperMargin() * logRange;
logLower = logLower - getLowerMargin() * logRange;
upper = calculateValueNoINF(logUpper);
lower = calculateValueNoINF(logLower);
}
setRange(new Range(lower, upper), false, false);
}
}
/**
* 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 (determines where to draw the axis).
* @param plotArea the area within which the axes and plot should be drawn.
* @param dataArea the area within which the data should be drawn.
* @param edge the axis location ({@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;
}
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;
}
/**
* 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;
}
/**
* Returns a list of ticks for an axis at the top or bottom of the chart.
*
* @param g2 the graphics device ({@code null} not permitted).
* @param dataArea the data area ({@code null} not permitted).
* @param edge the edge ({@code null} not permitted).
*
* @return A list of ticks.
*/
protected List refreshTicksHorizontal(Graphics2D g2, Rectangle2D dataArea,
RectangleEdge edge) {
Range range = getRange();
List ticks = new ArrayList();
Font tickLabelFont = getTickLabelFont();
g2.setFont(tickLabelFont);
TextAnchor textAnchor;
if (edge == RectangleEdge.TOP) {
textAnchor = TextAnchor.BOTTOM_CENTER;
}
else {
textAnchor = TextAnchor.TOP_CENTER;
}
if (isAutoTickUnitSelection()) {
selectAutoTickUnit(g2, dataArea, edge);
}
int minorTickCount = this.tickUnit.getMinorTickCount();
double unit = getTickUnit().getSize();
double index = Math.ceil(calculateLog(getRange().getLowerBound())
/ unit);
double start = index * unit;
double end = calculateLog(getUpperBound());
double current = start;
boolean hasTicks = (this.tickUnit.getSize() > 0.0)
&& !Double.isInfinite(start);
while (hasTicks && current <= end) {
double v = calculateValueNoINF(current);
if (range.contains(v)) {
ticks.add(new LogTick(TickType.MAJOR, v, createTickLabel(v),
textAnchor));
}
// add minor ticks (for gridlines)
double next = Math.pow(this.base, current
+ this.tickUnit.getSize());
for (int i = 1; i < minorTickCount; i++) {
double minorV = v + i * ((next - v) / minorTickCount);
if (range.contains(minorV)) {
ticks.add(new LogTick(TickType.MINOR, minorV, null,
textAnchor));
}
}
current = current + this.tickUnit.getSize();
}
return ticks;
}
/**
* Returns a list of ticks for an axis at the left or right of the chart.
*
* @param g2 the graphics device ({@code null} not permitted).
* @param dataArea the data area ({@code null} not permitted).
* @param edge the edge that the axis is aligned to ({@code null}
* not permitted).
*
* @return A list of ticks.
*/
protected List refreshTicksVertical(Graphics2D g2, Rectangle2D dataArea,
RectangleEdge edge) {
Range range = getRange();
List ticks = new ArrayList();
Font tickLabelFont = getTickLabelFont();
g2.setFont(tickLabelFont);
TextAnchor textAnchor;
if (edge == RectangleEdge.RIGHT) {
textAnchor = TextAnchor.CENTER_LEFT;
}
else {
textAnchor = TextAnchor.CENTER_RIGHT;
}
if (isAutoTickUnitSelection()) {
selectAutoTickUnit(g2, dataArea, edge);
}
int minorTickCount = this.tickUnit.getMinorTickCount();
double unit = getTickUnit().getSize();
double index = Math.ceil(calculateLog(getRange().getLowerBound())
/ unit);
double start = index * unit;
double end = calculateLog(getUpperBound());
double current = start;
boolean hasTicks = (this.tickUnit.getSize() > 0.0)
&& !Double.isInfinite(start);
while (hasTicks && current <= end) {
double v = calculateValueNoINF(current);
if (range.contains(v)) {
ticks.add(new LogTick(TickType.MAJOR, v, createTickLabel(v),
textAnchor));
}
// add minor ticks (for gridlines)
double next = Math.pow(this.base, current
+ this.tickUnit.getSize());
for (int i = 1; i < minorTickCount; i++) {
double minorV = v + i * ((next - v) / minorTickCount);
if (range.contains(minorV)) {
ticks.add(new LogTick(TickType.MINOR, minorV, null,
textAnchor));
}
}
current = current + this.tickUnit.getSize();
}
return ticks;
}
/**
* 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 ({@code null} not permitted).
* @param dataArea the area defined by the axes ({@code null} not
* permitted).
* @param edge the axis location ({@code null} not permitted).
*/
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) {
// select a tick unit that is the next one bigger than the current
// (log) range divided by 50
Range range = getRange();
double logAxisMin = calculateLog(Math.max(this.smallestValue,
range.getLowerBound()));
double logAxisMax = calculateLog(range.getUpperBound());
double size = (logAxisMax - logAxisMin) / 50;
TickUnitSource tickUnits = getStandardTickUnits();
TickUnit candidate = tickUnits.getCeilingTickUnit(size);
TickUnit prevCandidate = candidate;
boolean found = false;
while (!found) {
// while the tick labels overlap and there are more tick sizes available,
// choose the next bigger label
this.tickUnit = (NumberTickUnit) candidate;
double tickLabelWidth = estimateMaximumTickLabelWidth(g2,
candidate);
// what is the available space for one unit?
double candidateWidth = exponentLengthToJava2D(candidate.getSize(),
dataArea, edge);
if (tickLabelWidth < candidateWidth) {
found = true;
} else if (Double.isNaN(candidateWidth)) {
candidate = prevCandidate;
found = true;
} else {
prevCandidate = candidate;
candidate = tickUnits.getLargerTickUnit(prevCandidate);
if (candidate.equals(prevCandidate)) {
found = true; // there are no more candidates
}
}
}
setTickUnit((NumberTickUnit) candidate, false, false);
}
/**
* 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 exponentLengthToJava2D(double length, Rectangle2D area,
RectangleEdge edge) {
double one = valueToJava2D(calculateValueNoINF(1.0), area, edge);
double l = valueToJava2D(calculateValueNoINF(length + 1.0), area, edge);
return Math.abs(l - one);
}
/**
* 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) {
// select a tick unit that is the next one bigger than the current
// (log) range divided by 50
Range range = getRange();
double logAxisMin = calculateLog(Math.max(this.smallestValue,
range.getLowerBound()));
double logAxisMax = calculateLog(range.getUpperBound());
double size = (logAxisMax - logAxisMin) / 50;
TickUnitSource tickUnits = getStandardTickUnits();
TickUnit candidate = tickUnits.getCeilingTickUnit(size);
TickUnit prevCandidate = candidate;
boolean found = false;
while (!found) {
// while the tick labels overlap and there are more tick sizes available,
// choose the next bigger label
this.tickUnit = (NumberTickUnit) candidate;
double tickLabelHeight = estimateMaximumTickLabelHeight(g2);
// what is the available space for one unit?
double candidateHeight = exponentLengthToJava2D(candidate.getSize(),
dataArea, edge);
if (tickLabelHeight < candidateHeight) {
found = true;
} else if (Double.isNaN(candidateHeight)) {
candidate = prevCandidate;
found = true;
} else {
prevCandidate = candidate;
candidate = tickUnits.getLargerTickUnit(prevCandidate);
if (candidate.equals(prevCandidate)) {
found = true; // there are no more candidates
}
}
}
setTickUnit((NumberTickUnit) candidate, false, false);
}
/**
* Creates a tick label for the specified value based on the current
* tick unit (used for formatting the exponent).
*
* @param value the value.
*
* @return The label.
*/
protected AttributedString createTickLabel(double value) {
if (this.numberFormatOverride != null) {
String text = this.numberFormatOverride.format(value);
AttributedString as = new AttributedString(text);
as.addAttribute(TextAttribute.FONT, getTickLabelFont());
return as;
} else {
String baseStr = this.baseSymbol;
if (baseStr == null) {
baseStr = this.baseFormatter.format(this.base);
}
double logy = calculateLog(value);
String exponentStr = getTickUnit().valueToString(logy);
AttributedString as = new AttributedString(baseStr + exponentStr);
as.addAttributes(getTickLabelFont().getAttributes(), 0, (baseStr
+ exponentStr).length());
as.addAttribute(TextAttribute.SUPERSCRIPT,
TextAttribute.SUPERSCRIPT_SUPER, baseStr.length(),
baseStr.length() + exponentStr.length());
return as;
}
}
/**
* 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...
Range range = getRange();
double lower = range.getLowerBound();
double upper = range.getUpperBound();
AttributedString lowerStr = createTickLabel(lower);
AttributedString upperStr = createTickLabel(upper);
double w1 = AttrStringUtils.getTextBounds(lowerStr, g2).getWidth();
double w2 = AttrStringUtils.getTextBounds(upperStr, g2).getWidth();
result += Math.max(w1, w2);
}
return result;
}
/**
* Zooms in on the current range.
*
* @param lowerPercent the new lower bound.
* @param upperPercent the new upper bound.
*/
@Override
public void zoomRange(double lowerPercent, double upperPercent) {
Range range = getRange();
double start = range.getLowerBound();
double end = range.getUpperBound();
double log1 = calculateLog(start);
double log2 = calculateLog(end);
double length = log2 - log1;
Range adjusted;
if (isInverted()) {
double logA = log1 + length * (1 - upperPercent);
double logB = log1 + length * (1 - lowerPercent);
adjusted = new Range(calculateValueNoINF(logA),
calculateValueNoINF(logB));
}
else {
double logA = log1 + length * lowerPercent;
double logB = log1 + length * upperPercent;
adjusted = new Range(calculateValueNoINF(logA),
calculateValueNoINF(logB));
}
setRange(adjusted);
}
/**
* Slides the axis range by the specified percentage.
*
* @param percent the percentage.
*/
@Override
public void pan(double percent) {
Range range = getRange();
double lower = range.getLowerBound();
double upper = range.getUpperBound();
double log1 = calculateLog(lower);
double log2 = calculateLog(upper);
double length = log2 - log1;
double adj = length * percent;
log1 = log1 + adj;
log2 = log2 + adj;
setRange(calculateValueNoINF(log1), calculateValueNoINF(log2));
}
/**
* 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)
*/
@Override
public void resizeRange(double percent) {
Range range = getRange();
double logMin = calculateLog(range.getLowerBound());
double logMax = calculateLog(range.getUpperBound());
double centralValue = calculateValueNoINF((logMin + logMax) / 2.0);
resizeRange(percent, centralValue);
}
@Override
public void resizeRange(double percent, double anchorValue) {
resizeRange2(percent, anchorValue);
}
/**
* Resizes the axis length to the specified percentage of the current
* range and sends a change event to all registered listeners. If
* {@code percent} is greater than 1.0 (100 percent) then the axis
* range is increased (which has the effect of zooming out), while if the
* {@code percent} is less than 1.0 the axis range is decreased
* (which has the effect of zooming in). The resize occurs around an
* anchor value (which may not be in the center of the axis). This is used
* to support mouse wheel zooming around an arbitrary point on the plot.
*
* This method is overridden to perform the percentage calculations on the
* log values (which are linear for this axis).
*
* @param percent the percentage (must be greater than zero).
* @param anchorValue the anchor value.
*/
@Override
public void resizeRange2(double percent, double anchorValue) {
if (percent > 0.0) {
double logAnchorValue = calculateLog(anchorValue);
Range range = getRange();
double logAxisMin = calculateLog(range.getLowerBound());
double logAxisMax = calculateLog(range.getUpperBound());
double left = percent * (logAnchorValue - logAxisMin);
double right = percent * (logAxisMax - logAnchorValue);
double upperBound = calculateValueNoINF(logAnchorValue + right);
Range adjusted = new Range(calculateValueNoINF(
logAnchorValue - left), upperBound);
setRange(adjusted);
}
else {
setAutoRange(true);
}
}
/**
* Tests this 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 LogAxis)) {
return false;
}
LogAxis that = (LogAxis) obj;
if (this.base != that.base) {
return false;
}
if (!Objects.equals(this.baseSymbol, that.baseSymbol)) {
return false;
}
if (!this.baseFormatter.equals(that.baseFormatter)) {
return false;
}
if (this.smallestValue != that.smallestValue) {
return false;
}
if (!Objects.equals(this.numberFormatOverride,
that.numberFormatOverride)) {
return false;
}
return super.equals(obj);
}
/**
* Returns a hash code for this instance.
*
* @return A hash code.
*/
@Override
public int hashCode() {
int result = 193;
long temp = Double.doubleToLongBits(this.base);
result = 37 * result + (int) (temp ^ (temp >>> 32));
temp = Double.doubleToLongBits(this.smallestValue);
result = 37 * result + (int) (temp ^ (temp >>> 32));
if (this.numberFormatOverride != null) {
result = 37 * result + this.numberFormatOverride.hashCode();
}
result = 37 * result + this.tickUnit.hashCode();
return result;
}
}