/* * Copyright (C) 2017 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ package android.support.transition; import android.content.Context; import android.content.res.TypedArray; import android.graphics.Path; import android.support.v4.content.res.TypedArrayUtils; import android.util.AttributeSet; import org.xmlpull.v1.XmlPullParser; /** * A PathMotion that generates a curved path along an arc on an imaginary circle containing * the two points. If the horizontal distance between the points is less than the vertical * distance, then the circle's center point will be horizontally aligned with the end point. If the * vertical distance is less than the horizontal distance then the circle's center point * will be vertically aligned with the end point. *
* When the two points are near horizontal or vertical, the curve of the motion will be * small as the center of the circle will be far from both points. To force curvature of * the path, {@link #setMinimumHorizontalAngle(float)} and * {@link #setMinimumVerticalAngle(float)} may be used to set the minimum angle of the * arc between two points. *
*This may be used in XML as an element inside a transition.
*{@code **/ public class ArcMotion extends PathMotion { private static final float DEFAULT_MIN_ANGLE_DEGREES = 0; private static final float DEFAULT_MAX_ANGLE_DEGREES = 70; private static final float DEFAULT_MAX_TANGENT = (float) Math.tan(Math.toRadians(DEFAULT_MAX_ANGLE_DEGREES / 2)); private float mMinimumHorizontalAngle = 0; private float mMinimumVerticalAngle = 0; private float mMaximumAngle = DEFAULT_MAX_ANGLE_DEGREES; private float mMinimumHorizontalTangent = 0; private float mMinimumVerticalTangent = 0; private float mMaximumTangent = DEFAULT_MAX_TANGENT; public ArcMotion() { } public ArcMotion(Context context, AttributeSet attrs) { super(context, attrs); TypedArray a = context.obtainStyledAttributes(attrs, Styleable.ARC_MOTION); XmlPullParser parser = (XmlPullParser) attrs; float minimumVerticalAngle = TypedArrayUtils.getNamedFloat(a, parser, "minimumVerticalAngle", Styleable.ArcMotion.MINIMUM_VERTICAL_ANGLE, DEFAULT_MIN_ANGLE_DEGREES); setMinimumVerticalAngle(minimumVerticalAngle); float minimumHorizontalAngle = TypedArrayUtils.getNamedFloat(a, parser, "minimumHorizontalAngle", Styleable.ArcMotion.MINIMUM_HORIZONTAL_ANGLE, DEFAULT_MIN_ANGLE_DEGREES); setMinimumHorizontalAngle(minimumHorizontalAngle); float maximumAngle = TypedArrayUtils.getNamedFloat(a, parser, "maximumAngle", Styleable.ArcMotion.MAXIMUM_ANGLE, DEFAULT_MAX_ANGLE_DEGREES); setMaximumAngle(maximumAngle); a.recycle(); } /** * Sets the minimum arc along the circle between two points aligned near horizontally. * When start and end points are close to horizontal, the calculated center point of the * circle will be far from both points, giving a near straight path between the points. * By setting a minimum angle, this forces the center point to be closer and give an * exaggerated curve to the path. ** } **
The default value is 0.
* * @param angleInDegrees The minimum angle of the arc on a circle describing the Path * between two nearly horizontally-separated points. */ public void setMinimumHorizontalAngle(float angleInDegrees) { mMinimumHorizontalAngle = angleInDegrees; mMinimumHorizontalTangent = toTangent(angleInDegrees); } /** * Returns the minimum arc along the circle between two points aligned near horizontally. * When start and end points are close to horizontal, the calculated center point of the * circle will be far from both points, giving a near straight path between the points. * By setting a minimum angle, this forces the center point to be closer and give an * exaggerated curve to the path. *The default value is 0.
* * @return The minimum arc along the circle between two points aligned near horizontally. */ public float getMinimumHorizontalAngle() { return mMinimumHorizontalAngle; } /** * Sets the minimum arc along the circle between two points aligned near vertically. * When start and end points are close to vertical, the calculated center point of the * circle will be far from both points, giving a near straight path between the points. * By setting a minimum angle, this forces the center point to be closer and give an * exaggerated curve to the path. *The default value is 0.
* * @param angleInDegrees The minimum angle of the arc on a circle describing the Path * between two nearly vertically-separated points. */ public void setMinimumVerticalAngle(float angleInDegrees) { mMinimumVerticalAngle = angleInDegrees; mMinimumVerticalTangent = toTangent(angleInDegrees); } /** * Returns the minimum arc along the circle between two points aligned near vertically. * When start and end points are close to vertical, the calculated center point of the * circle will be far from both points, giving a near straight path between the points. * By setting a minimum angle, this forces the center point to be closer and give an * exaggerated curve to the path. *The default value is 0.
* * @return The minimum angle of the arc on a circle describing the Path * between two nearly vertically-separated points. */ public float getMinimumVerticalAngle() { return mMinimumVerticalAngle; } /** * Sets the maximum arc along the circle between two points. When start and end points * have close to equal x and y differences, the curve between them is large. This forces * the curved path to have an arc of at most the given angle. *The default value is 70 degrees.
* * @param angleInDegrees The maximum angle of the arc on a circle describing the Path * between the start and end points. */ public void setMaximumAngle(float angleInDegrees) { mMaximumAngle = angleInDegrees; mMaximumTangent = toTangent(angleInDegrees); } /** * Returns the maximum arc along the circle between two points. When start and end points * have close to equal x and y differences, the curve between them is large. This forces * the curved path to have an arc of at most the given angle. *The default value is 70 degrees.
* * @return The maximum angle of the arc on a circle describing the Path * between the start and end points. */ public float getMaximumAngle() { return mMaximumAngle; } private static float toTangent(float arcInDegrees) { if (arcInDegrees < 0 || arcInDegrees > 90) { throw new IllegalArgumentException("Arc must be between 0 and 90 degrees"); } return (float) Math.tan(Math.toRadians(arcInDegrees / 2)); } @Override public Path getPath(float startX, float startY, float endX, float endY) { // Here's a little ascii art to show how this is calculated: // c---------- b // \ / | // \ d | // \ / e // a----f // This diagram assumes that the horizontal distance is less than the vertical // distance between The start point (a) and end point (b). // d is the midpoint between a and b. c is the center point of the circle with // This path is formed by assuming that start and end points are in // an arc on a circle. The end point is centered in the circle vertically // and start is a point on the circle. // Triangles bfa and bde form similar right triangles. The control points // for the cubic Bezier arc path are the midpoints between a and e and e and b. Path path = new Path(); path.moveTo(startX, startY); float ex; float ey; float deltaX = endX - startX; float deltaY = endY - startY; // hypotenuse squared. float h2 = deltaX * deltaX + deltaY * deltaY; // Midpoint between start and end float dx = (startX + endX) / 2; float dy = (startY + endY) / 2; // Distance squared between end point and mid point is (1/2 hypotenuse)^2 float midDist2 = h2 * 0.25f; float minimumArcDist2; boolean isMovingUpwards = startY > endY; if ((Math.abs(deltaX) < Math.abs(deltaY))) { // Similar triangles bfa and bde mean that (ab/fb = eb/bd) // Therefore, eb = ab * bd / fb // ab = hypotenuse // bd = hypotenuse/2 // fb = deltaY float eDistY = Math.abs(h2 / (2 * deltaY)); if (isMovingUpwards) { ey = endY + eDistY; ex = endX; } else { ey = startY + eDistY; ex = startX; } minimumArcDist2 = midDist2 * mMinimumVerticalTangent * mMinimumVerticalTangent; } else { // Same as above, but flip X & Y and account for negative eDist float eDistX = h2 / (2 * deltaX); if (isMovingUpwards) { ex = startX + eDistX; ey = startY; } else { ex = endX - eDistX; ey = endY; } minimumArcDist2 = midDist2 * mMinimumHorizontalTangent * mMinimumHorizontalTangent; } float arcDistX = dx - ex; float arcDistY = dy - ey; float arcDist2 = arcDistX * arcDistX + arcDistY * arcDistY; float maximumArcDist2 = midDist2 * mMaximumTangent * mMaximumTangent; float newArcDistance2 = 0; if (arcDist2 < minimumArcDist2) { newArcDistance2 = minimumArcDist2; } else if (arcDist2 > maximumArcDist2) { newArcDistance2 = maximumArcDist2; } if (newArcDistance2 != 0) { float ratio2 = newArcDistance2 / arcDist2; float ratio = (float) Math.sqrt(ratio2); ex = dx + (ratio * (ex - dx)); ey = dy + (ratio * (ey - dy)); } float control1X = (startX + ex) / 2; float control1Y = (startY + ey) / 2; float control2X = (ex + endX) / 2; float control2Y = (ey + endY) / 2; path.cubicTo(control1X, control1Y, control2X, control2Y, endX, endY); return path; } }