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Collection of methods to achieve better circular arc drawing, as Canvas.drawArc() is unreliable. See the related article: https://medium.com/p/9155f49166b8
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/** | |
* ArcUtils.java | |
* | |
* Copyright (c) 2014 BioWink GmbH. | |
* | |
* Permission is hereby granted, free of charge, to any person obtaining a copy | |
* of this software and associated documentation files (the "Software"), to deal | |
* in the Software without restriction, including without limitation the rights | |
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell | |
* copies of the Software, and to permit persons to whom the Software is | |
* furnished to do so, subject to the following conditions: | |
* | |
* The above copyright notice and this permission notice shall be included in | |
* all copies or substantial portions of the Software. | |
* | |
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR | |
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, | |
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE | |
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER | |
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, | |
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN | |
* THE SOFTWARE. | |
**/ | |
package com.biowink.clue; | |
import android.graphics.Canvas; | |
import android.graphics.Paint; | |
import android.graphics.Path; | |
import android.graphics.PointF; | |
import org.jetbrains.annotations.NotNull; | |
import org.jetbrains.annotations.Nullable; | |
import static java.lang.Math.abs; | |
import static java.lang.Math.ceil; | |
import static java.lang.Math.cos; | |
import static java.lang.Math.floor; | |
import static java.lang.Math.sin; | |
import static java.lang.Math.sqrt; | |
import static java.lang.Math.toRadians; | |
/** | |
* Collection of methods to achieve better circular arc drawing, as | |
* {@link Canvas#drawArc(android.graphics.RectF, float, float, boolean, android.graphics.Paint)} is unreliable. | |
* <p> | |
* To draw a simple arc, use | |
* {@link #drawArc(android.graphics.Canvas, android.graphics.PointF, float, float, float, android.graphics.Paint)}. | |
* </p> | |
*/ | |
public final class ArcUtils | |
{ | |
private static final double FULL_CIRCLE_RADIANS = toRadians(360d); | |
private ArcUtils() { } | |
/** | |
* Draws a circular arc on the given {@code Canvas}. | |
* | |
* @param canvas The canvas to draw into. | |
* @param circleCenter The center of the circle on which to draw the arc. | |
* @param circleRadius The radius of the circle on which to draw the arc. | |
* @param startAngle Starting angle (in degrees) where the arc begins. | |
* @param sweepAngle Sweep angle (in degrees) measured clockwise. | |
* @param paint The paint to use then drawing the arc. | |
* | |
* @see #drawArc(android.graphics.Canvas, android.graphics.PointF, float, float, float, android.graphics.Paint, int, boolean) | |
*/ | |
public static void drawArc(@NotNull Canvas canvas, PointF circleCenter, float circleRadius, | |
float startAngle, float sweepAngle, @NotNull Paint paint) | |
{ | |
drawArc(canvas, circleCenter, circleRadius, startAngle, sweepAngle, paint, 8, false); | |
} | |
/** | |
* Draws a circular arc on the given {@code Canvas}. | |
* | |
* @param canvas The canvas to draw into. | |
* @param circleCenter The center of the circle on which to draw the arc. | |
* @param circleRadius The radius of the circle on which to draw the arc. | |
* @param startAngle Starting angle (in degrees) where the arc begins. | |
* @param sweepAngle Sweep angle (in degrees) measured clockwise. | |
* @param paint The paint to use then drawing the arc. | |
* @param arcsPointsOnCircle See {@link #createBezierArcDegrees(android.graphics.PointF, float, float, float, int, boolean, android.graphics.Path)}. | |
* @param arcsOverlayPoints See {@link #createBezierArcDegrees(android.graphics.PointF, float, float, float, int, boolean, android.graphics.Path)}. | |
* | |
* @see #drawArc(android.graphics.Canvas, android.graphics.PointF, float, float, float, android.graphics.Paint) | |
*/ | |
public static void drawArc(@NotNull Canvas canvas, PointF circleCenter, float circleRadius, | |
float startAngle, float sweepAngle, @NotNull Paint paint, | |
int arcsPointsOnCircle, boolean arcsOverlayPoints) | |
{ | |
if (sweepAngle == 0f) | |
{ | |
final PointF p = pointFromAngleDegrees(circleCenter, circleRadius, startAngle); | |
canvas.drawPoint(p.x, p.y, paint); | |
} | |
else | |
{ | |
canvas.drawPath(createBezierArcDegrees( | |
circleCenter, circleRadius, startAngle, sweepAngle, | |
arcsPointsOnCircle, arcsOverlayPoints, null), paint); | |
} | |
} | |
/** | |
* Normalize the input radians in the range 360° > x >= 0°. | |
* | |
* @param radians The angle to normalize (in radians). | |
* | |
* @return The angle normalized in the range 360° > x >= 0°. | |
*/ | |
public static double normalizeRadians(double radians) | |
{ | |
radians %= FULL_CIRCLE_RADIANS; | |
if (radians < 0d) { radians += FULL_CIRCLE_RADIANS; } | |
if (radians == FULL_CIRCLE_RADIANS) { radians = 0d; } | |
return radians; | |
} | |
/** | |
* Returns the point of a given angle (in radians) on a circle. | |
* | |
* @param center The center of the circle. | |
* @param radius The radius of the circle. | |
* @param angleRadians The angle (in radians). | |
* | |
* @return The point of the given angle on the specified circle. | |
* | |
* @see #pointFromAngleDegrees(android.graphics.PointF, float, float) | |
*/ | |
@NotNull | |
public static PointF pointFromAngleRadians(@NotNull PointF center, float radius, double angleRadians) | |
{ | |
return new PointF((float)(center.x + radius * cos(angleRadians)), | |
(float)(center.y + radius * sin(angleRadians))); | |
} | |
/** | |
* Returns the point of a given angle (in degrees) on a circle. | |
* | |
* @param center The center of the circle. | |
* @param radius The radius of the circle. | |
* @param angleDegrees The angle (in degrees). | |
* | |
* @return The point of the given angle on the specified circle. | |
* | |
* @see #pointFromAngleRadians(android.graphics.PointF, float, double) | |
*/ | |
@NotNull | |
public static PointF pointFromAngleDegrees(@NotNull PointF center, float radius, float angleDegrees) | |
{ | |
return pointFromAngleRadians(center, radius, toRadians(angleDegrees)); | |
} | |
/** | |
* Adds a circular arc to the given path by approximating it through a cubic Bézier curve. | |
* <p/> | |
* <p> | |
* Note that this <strong>does not</strong> split the arc to better approximate it, for that see either: | |
* <ul> | |
* <li>{@link #createBezierArcDegrees(android.graphics.PointF, float, float, float, int, boolean, | |
* android.graphics.Path)}</li> | |
* <li>{@link #createBezierArcRadians(android.graphics.PointF, float, double, double, int, boolean, | |
* android.graphics.Path)}</li> | |
* </ul> | |
* </p> | |
* <p/> | |
* For a technical explanation: | |
* <a href="http://hansmuller-flex.blogspot.de/2011/10/more-about-approximating-circular-arcs.html"> | |
* http://hansmuller-flex.blogspot.de/2011/10/more-about-approximating-circular-arcs.html | |
* </a> | |
* | |
* @param path The path to add the arc to. | |
* @param center The center of the circle. | |
* @param start The starting point of the arc on the circle. | |
* @param end The ending point of the arc on the circle. | |
* @param moveToStart If {@code true}, move to the starting point of the arc | |
* (see: {@link android.graphics.Path#moveTo(float, float)}). | |
* | |
* @see #createBezierArcDegrees(android.graphics.PointF, float, float, float, int, boolean, android.graphics.Path) | |
* @see #createBezierArcRadians(android.graphics.PointF, float, double, double, int, boolean, android.graphics.Path) | |
*/ | |
public static void addBezierArcToPath(@NotNull Path path, @NotNull PointF center, | |
@NotNull PointF start, @NotNull PointF end, boolean moveToStart) | |
{ | |
if (moveToStart) { path.moveTo(start.x, start.y); } | |
if (start.equals(end)) { return; } | |
final double ax = start.x - center.x; | |
final double ay = start.y - center.y; | |
final double bx = end.x - center.x; | |
final double by = end.y - center.y; | |
final double q1 = ax * ax + ay * ay; | |
final double q2 = q1 + ax * bx + ay * by; | |
final double k2 = 4d / 3d * (sqrt(2d * q1 * q2) - q2) / (ax * by - ay * bx); | |
final float x2 = (float)(center.x + ax - k2 * ay); | |
final float y2 = (float)(center.y + ay + k2 * ax); | |
final float x3 = (float)(center.x + bx + k2 * by); | |
final float y3 = (float)(center.y + by - k2 * bx); | |
path.cubicTo(x2, y2, x3, y3, end.x, end.y); | |
} | |
/** | |
* Adds a circular arc to the given path by approximating it through a cubic Bézier curve, splitting it if | |
* necessary. The precision of the approximation can be adjusted through {@code pointsOnCircle} and | |
* {@code overlapPoints} parameters. | |
* <p> | |
* <strong>Example:</strong> imagine an arc starting from 0° and sweeping 100° with a value of | |
* {@code pointsOnCircle} equal to 12 (threshold -> 360° / 12 = 30°): | |
* <ul> | |
* <li>if {@code overlapPoints} is {@code true}, it will be split as following: | |
* <ul> | |
* <li>from 0° to 30° (sweep 30°)</li> | |
* <li>from 30° to 60° (sweep 30°)</li> | |
* <li>from 60° to 90° (sweep 30°)</li> | |
* <li>from 90° to 100° (sweep 10°)</li> | |
* </ul> | |
* </li> | |
* <li>if {@code overlapPoints} is {@code false}, it will be split into 4 equal arcs: | |
* <ul> | |
* <li>from 0° to 25° (sweep 25°)</li> | |
* <li>from 25° to 50° (sweep 25°)</li> | |
* <li>from 50° to 75° (sweep 25°)</li> | |
* <li>from 75° to 100° (sweep 25°)</li> | |
* </ul> | |
* </li> | |
* </ul> | |
* </p> | |
* <p/> | |
* For a technical explanation: | |
* <a href="http://hansmuller-flex.blogspot.de/2011/10/more-about-approximating-circular-arcs.html"> | |
* http://hansmuller-flex.blogspot.de/2011/10/more-about-approximating-circular-arcs.html | |
* </a> | |
* | |
* @param center The center of the circle. | |
* @param radius The radius of the circle. | |
* @param startAngleRadians The starting angle on the circle (in radians). | |
* @param sweepAngleRadians How long to make the total arc (in radians). | |
* @param pointsOnCircle Defines a <i>threshold</i> (360° /{@code pointsOnCircle}) to split the Bézier arc to | |
* better approximate a circular arc, depending also on the value of {@code overlapPoints}. | |
* The suggested number to have a reasonable approximation of a circle is at least 4 (90°). | |
* Less than 1 will be ignored (the arc will not be split). | |
* @param overlapPoints Given the <i>threshold</i> defined through {@code pointsOnCircle}: | |
* <ul> | |
* <li>if {@code true}, split the arc on every angle which is a multiple of the | |
* <i>threshold</i> (yields better results if drawing precision is required, | |
* especially when stacking multiple arcs, but can potentially use more points)</li> | |
* <li>if {@code false}, split the arc equally so that each part is shorter than | |
* the <i>threshold</i></li> | |
* </ul> | |
* @param addToPath An existing path where to add the arc to, or {@code null} to create a new path. | |
* | |
* @return {@code addToPath} if it's not {@code null}, otherwise a new path. | |
* | |
* @see #createBezierArcDegrees(android.graphics.PointF, float, float, float, int, boolean, android.graphics.Path) | |
*/ | |
@NotNull | |
public static Path createBezierArcRadians(@NotNull PointF center, float radius, double startAngleRadians, | |
double sweepAngleRadians, int pointsOnCircle, boolean overlapPoints, | |
@Nullable Path addToPath) | |
{ | |
final Path path = addToPath != null ? addToPath : new Path(); | |
if (sweepAngleRadians == 0d) { return path; } | |
if (pointsOnCircle >= 1) | |
{ | |
final double threshold = FULL_CIRCLE_RADIANS / pointsOnCircle; | |
if (abs(sweepAngleRadians) > threshold) | |
{ | |
double angle = normalizeRadians(startAngleRadians); | |
PointF end, start = pointFromAngleRadians(center, radius, angle); | |
path.moveTo(start.x, start.y); | |
if (overlapPoints) | |
{ | |
final boolean cw = sweepAngleRadians > 0; // clockwise? | |
final double angleEnd = angle + sweepAngleRadians; | |
while (true) | |
{ | |
double next = (cw ? ceil(angle / threshold) : floor(angle / threshold)) * threshold; | |
if (angle == next) { next += threshold * (cw ? 1d : -1d); } | |
final boolean isEnd = cw ? angleEnd <= next : angleEnd >= next; | |
end = pointFromAngleRadians(center, radius, isEnd ? angleEnd : next); | |
addBezierArcToPath(path, center, start, end, false); | |
if (isEnd) { break; } | |
angle = next; | |
start = end; | |
} | |
} | |
else | |
{ | |
final int n = abs((int)ceil(sweepAngleRadians / threshold)); | |
final double sweep = sweepAngleRadians / n; | |
for (int i = 0; | |
i < n; | |
i++, start = end) | |
{ | |
angle += sweep; | |
end = pointFromAngleRadians(center, radius, angle); | |
addBezierArcToPath(path, center, start, end, false); | |
} | |
} | |
return path; | |
} | |
} | |
final PointF start = pointFromAngleRadians(center, radius, startAngleRadians); | |
final PointF end = pointFromAngleRadians(center, radius, startAngleRadians + sweepAngleRadians); | |
addBezierArcToPath(path, center, start, end, true); | |
return path; | |
} | |
/** | |
* Adds a circular arc to the given path by approximating it through a cubic Bézier curve, splitting it if | |
* necessary. The precision of the approximation can be adjusted through {@code pointsOnCircle} and | |
* {@code overlapPoints} parameters. | |
* <p> | |
* <strong>Example:</strong> imagine an arc starting from 0° and sweeping 100° with a value of | |
* {@code pointsOnCircle} equal to 12 (threshold -> 360° / 12 = 30°): | |
* <ul> | |
* <li>if {@code overlapPoints} is {@code true}, it will be split as following: | |
* <ul> | |
* <li>from 0° to 30° (sweep 30°)</li> | |
* <li>from 30° to 60° (sweep 30°)</li> | |
* <li>from 60° to 90° (sweep 30°)</li> | |
* <li>from 90° to 100° (sweep 10°)</li> | |
* </ul> | |
* </li> | |
* <li>if {@code overlapPoints} is {@code false}, it will be split into 4 equal arcs: | |
* <ul> | |
* <li>from 0° to 25° (sweep 25°)</li> | |
* <li>from 25° to 50° (sweep 25°)</li> | |
* <li>from 50° to 75° (sweep 25°)</li> | |
* <li>from 75° to 100° (sweep 25°)</li> | |
* </ul> | |
* </li> | |
* </ul> | |
* </p> | |
* <p/> | |
* For a technical explanation: | |
* <a href="http://hansmuller-flex.blogspot.de/2011/10/more-about-approximating-circular-arcs.html"> | |
* http://hansmuller-flex.blogspot.de/2011/10/more-about-approximating-circular-arcs.html | |
* </a> | |
* | |
* @param center The center of the circle. | |
* @param radius The radius of the circle. | |
* @param startAngleDegrees The starting angle on the circle (in degrees). | |
* @param sweepAngleDegrees How long to make the total arc (in degrees). | |
* @param pointsOnCircle Defines a <i>threshold</i> (360° /{@code pointsOnCircle}) to split the Bézier arc to | |
* better approximate a circular arc, depending also on the value of {@code overlapPoints}. | |
* The suggested number to have a reasonable approximation of a circle is at least 4 (90°). | |
* Less than 1 will ignored (the arc will not be split). | |
* @param overlapPoints Given the <i>threshold</i> defined through {@code pointsOnCircle}: | |
* <ul> | |
* <li>if {@code true}, split the arc on every angle which is a multiple of the | |
* <i>threshold</i> (yields better results if drawing precision is required, | |
* especially when stacking multiple arcs, but can potentially use more points)</li> | |
* <li>if {@code false}, split the arc equally so that each part is shorter than | |
* the <i>threshold</i></li> | |
* </ul> | |
* @param addToPath An existing path where to add the arc to, or {@code null} to create a new path. | |
* | |
* @return {@code addToPath} if it's not {@code null}, otherwise a new path. | |
* | |
* @see #createBezierArcRadians(android.graphics.PointF, float, double, double, int, boolean, android.graphics.Path) | |
*/ | |
@NotNull | |
public static Path createBezierArcDegrees(@NotNull PointF center, float radius, float startAngleDegrees, | |
float sweepAngleDegrees, int pointsOnCircle, boolean overlapPoints, | |
@Nullable Path addToPath) | |
{ | |
return createBezierArcRadians(center, radius, toRadians(startAngleDegrees), toRadians(sweepAngleDegrees), | |
pointsOnCircle, overlapPoints, addToPath); | |
} | |
} |
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