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1 /*
2  * Copyright (C) 2012 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 package com.android.gallery3d.filtershow.crop;
18 
19 import android.graphics.Bitmap;
20 import android.graphics.Matrix;
21 import android.graphics.RectF;
22 
23 import com.android.gallery3d.filtershow.imageshow.GeometryMathUtils;
24 
25 import java.util.Arrays;
26 
27 public class CropMath {
28 
29     /**
30      * Gets a float array of the 2D coordinates representing a rectangles
31      * corners.
32      * The order of the corners in the float array is:
33      * 0------->1
34      * ^        |
35      * |        v
36      * 3<-------2
37      *
38      * @param r  the rectangle to get the corners of
39      * @return  the float array of corners (8 floats)
40      */
41 
getCornersFromRect(RectF r)42     public static float[] getCornersFromRect(RectF r) {
43         float[] corners = {
44                 r.left, r.top,
45                 r.right, r.top,
46                 r.right, r.bottom,
47                 r.left, r.bottom
48         };
49         return corners;
50     }
51 
52     /**
53      * Returns true iff point (x, y) is within or on the rectangle's bounds.
54      * RectF's "contains" function treats points on the bottom and right bound
55      * as not being contained.
56      *
57      * @param r the rectangle
58      * @param x the x value of the point
59      * @param y the y value of the point
60      * @return
61      */
inclusiveContains(RectF r, float x, float y)62     public static boolean inclusiveContains(RectF r, float x, float y) {
63         return !(x > r.right || x < r.left || y > r.bottom || y < r.top);
64     }
65 
66     /**
67      * Takes an array of 2D coordinates representing corners and returns the
68      * smallest rectangle containing those coordinates.
69      *
70      * @param array array of 2D coordinates
71      * @return smallest rectangle containing coordinates
72      */
trapToRect(float[] array)73     public static RectF trapToRect(float[] array) {
74         RectF r = new RectF(Float.POSITIVE_INFINITY, Float.POSITIVE_INFINITY,
75                 Float.NEGATIVE_INFINITY, Float.NEGATIVE_INFINITY);
76         for (int i = 1; i < array.length; i += 2) {
77             float x = array[i - 1];
78             float y = array[i];
79             r.left = (x < r.left) ? x : r.left;
80             r.top = (y < r.top) ? y : r.top;
81             r.right = (x > r.right) ? x : r.right;
82             r.bottom = (y > r.bottom) ? y : r.bottom;
83         }
84         r.sort();
85         return r;
86     }
87 
88     /**
89      * If edge point [x, y] in array [x0, y0, x1, y1, ...] is outside of the
90      * image bound rectangle, clamps it to the edge of the rectangle.
91      *
92      * @param imageBound the rectangle to clamp edge points to.
93      * @param array an array of points to clamp to the rectangle, gets set to
94      *            the clamped values.
95      */
getEdgePoints(RectF imageBound, float[] array)96     public static void getEdgePoints(RectF imageBound, float[] array) {
97         if (array.length < 2)
98             return;
99         for (int x = 0; x < array.length; x += 2) {
100             array[x] = GeometryMathUtils.clamp(array[x], imageBound.left, imageBound.right);
101             array[x + 1] = GeometryMathUtils.clamp(array[x + 1], imageBound.top, imageBound.bottom);
102         }
103     }
104 
105     /**
106      * Takes a point and the corners of a rectangle and returns the two corners
107      * representing the side of the rectangle closest to the point.
108      *
109      * @param point the point which is being checked
110      * @param corners the corners of the rectangle
111      * @return two corners representing the side of the rectangle
112      */
closestSide(float[] point, float[] corners)113     public static float[] closestSide(float[] point, float[] corners) {
114         int len = corners.length;
115         float oldMag = Float.POSITIVE_INFINITY;
116         float[] bestLine = null;
117         for (int i = 0; i < len; i += 2) {
118             float[] line = {
119                     corners[i], corners[(i + 1) % len],
120                     corners[(i + 2) % len], corners[(i + 3) % len]
121             };
122             float mag = GeometryMathUtils.vectorLength(
123                     GeometryMathUtils.shortestVectorFromPointToLine(point, line));
124             if (mag < oldMag) {
125                 oldMag = mag;
126                 bestLine = line;
127             }
128         }
129         return bestLine;
130     }
131 
132     /**
133      * Checks if a given point is within a rotated rectangle.
134      *
135      * @param point 2D point to check
136      * @param bound rectangle to rotate
137      * @param rot angle of rotation about rectangle center
138      * @return true if point is within rotated rectangle
139      */
pointInRotatedRect(float[] point, RectF bound, float rot)140     public static boolean pointInRotatedRect(float[] point, RectF bound, float rot) {
141         Matrix m = new Matrix();
142         float[] p = Arrays.copyOf(point, 2);
143         m.setRotate(rot, bound.centerX(), bound.centerY());
144         Matrix m0 = new Matrix();
145         if (!m.invert(m0))
146             return false;
147         m0.mapPoints(p);
148         return inclusiveContains(bound, p[0], p[1]);
149     }
150 
151     /**
152      * Checks if a given point is within a rotated rectangle.
153      *
154      * @param point 2D point to check
155      * @param rotatedRect corners of a rotated rectangle
156      * @param center center of the rotated rectangle
157      * @return true if point is within rotated rectangle
158      */
pointInRotatedRect(float[] point, float[] rotatedRect, float[] center)159     public static boolean pointInRotatedRect(float[] point, float[] rotatedRect, float[] center) {
160         RectF unrotated = new RectF();
161         float angle = getUnrotated(rotatedRect, center, unrotated);
162         return pointInRotatedRect(point, unrotated, angle);
163     }
164 
165     /**
166      * Resizes rectangle to have a certain aspect ratio (center remains
167      * stationary).
168      *
169      * @param r rectangle to resize
170      * @param w new width aspect
171      * @param h new height aspect
172      */
fixAspectRatio(RectF r, float w, float h)173     public static void fixAspectRatio(RectF r, float w, float h) {
174         float scale = Math.min(r.width() / w, r.height() / h);
175         float centX = r.centerX();
176         float centY = r.centerY();
177         float hw = scale * w / 2;
178         float hh = scale * h / 2;
179         r.set(centX - hw, centY - hh, centX + hw, centY + hh);
180     }
181 
182     /**
183      * Resizes rectangle to have a certain aspect ratio (center remains
184      * stationary) while constraining it to remain within the original rect.
185      *
186      * @param r rectangle to resize
187      * @param w new width aspect
188      * @param h new height aspect
189      */
fixAspectRatioContained(RectF r, float w, float h)190     public static void fixAspectRatioContained(RectF r, float w, float h) {
191         float origW = r.width();
192         float origH = r.height();
193         float origA = origW / origH;
194         float a = w / h;
195         float finalW = origW;
196         float finalH = origH;
197         if (origA < a) {
198             finalH = origW / a;
199             r.top = r.centerY() - finalH / 2;
200             r.bottom = r.top + finalH;
201         } else {
202             finalW = origH * a;
203             r.left = r.centerX() - finalW / 2;
204             r.right = r.left + finalW;
205         }
206     }
207 
208     /**
209      * Stretches/Scales/Translates photoBounds to match displayBounds, and
210      * and returns an equivalent stretched/scaled/translated cropBounds or null
211      * if the mapping is invalid.
212      * @param cropBounds  cropBounds to transform
213      * @param photoBounds  original bounds containing crop bounds
214      * @param displayBounds  final bounds for crop
215      * @return  the stretched/scaled/translated crop bounds that fit within displayBounds
216      */
getScaledCropBounds(RectF cropBounds, RectF photoBounds, RectF displayBounds)217     public static RectF getScaledCropBounds(RectF cropBounds, RectF photoBounds,
218             RectF displayBounds) {
219         Matrix m = new Matrix();
220         m.setRectToRect(photoBounds, displayBounds, Matrix.ScaleToFit.FILL);
221         RectF trueCrop = new RectF(cropBounds);
222         if (!m.mapRect(trueCrop)) {
223             return null;
224         }
225         return trueCrop;
226     }
227 
228     /**
229      * Returns the size of a bitmap in bytes.
230      * @param bmap  bitmap whose size to check
231      * @return  bitmap size in bytes
232      */
getBitmapSize(Bitmap bmap)233     public static int getBitmapSize(Bitmap bmap) {
234         return bmap.getRowBytes() * bmap.getHeight();
235     }
236 
237     /**
238      * Constrains rotation to be in [0, 90, 180, 270] rounding down.
239      * @param rotation  any rotation value, in degrees
240      * @return  integer rotation in [0, 90, 180, 270]
241      */
constrainedRotation(float rotation)242     public static int constrainedRotation(float rotation) {
243         int r = (int) ((rotation % 360) / 90);
244         r = (r < 0) ? (r + 4) : r;
245         return r * 90;
246     }
247 
getUnrotated(float[] rotatedRect, float[] center, RectF unrotated)248     private static float getUnrotated(float[] rotatedRect, float[] center, RectF unrotated) {
249         float dy = rotatedRect[1] - rotatedRect[3];
250         float dx = rotatedRect[0] - rotatedRect[2];
251         float angle = (float) (Math.atan(dy / dx) * 180 / Math.PI);
252         Matrix m = new Matrix();
253         m.setRotate(-angle, center[0], center[1]);
254         float[] unrotatedRect = new float[rotatedRect.length];
255         m.mapPoints(unrotatedRect, rotatedRect);
256         unrotated.set(trapToRect(unrotatedRect));
257         return angle;
258     }
259 
260 }
261