package org.opencv.test.core; import org.opencv.core.Point; import org.opencv.core.Rect; import org.opencv.core.RotatedRect; import org.opencv.core.Size; import org.opencv.test.OpenCVTestCase; public class RotatedRectTest extends OpenCVTestCase { private double angle; private Point center; private Size size; @Override protected void setUp() throws Exception { super.setUp(); center = new Point(matSize / 2, matSize / 2); size = new Size(matSize / 4, matSize / 2); angle = 40; } public void testBoundingRect() { size = new Size(matSize / 2, matSize / 2); assertEquals(size.height, size.width); double length = size.height; angle = 45; RotatedRect rr = new RotatedRect(center, size, angle); Rect r = rr.boundingRect(); double halfDiagonal = length * Math.sqrt(2) / 2; assertTrue((r.x == Math.floor(center.x - halfDiagonal)) && (r.y == Math.floor(center.y - halfDiagonal))); assertTrue((r.br().x >= Math.ceil(center.x + halfDiagonal)) && (r.br().y >= Math.ceil(center.y + halfDiagonal))); assertTrue((r.br().x - Math.ceil(center.x + halfDiagonal)) <= 1 && (r.br().y - Math.ceil(center.y + halfDiagonal)) <= 1); } public void testClone() { RotatedRect rrect = new RotatedRect(center, size, angle); RotatedRect clone = rrect.clone(); assertTrue(clone != null); assertTrue(rrect.center.equals(clone.center)); assertTrue(rrect.size.equals(clone.size)); assertTrue(rrect.angle == clone.angle); } public void testEqualsObject() { Point center2 = new Point(matSize / 3, matSize / 1.5); Size size2 = new Size(matSize / 2, matSize / 4); double angle2 = 0; RotatedRect rrect1 = new RotatedRect(center, size, angle); RotatedRect rrect2 = new RotatedRect(center2, size2, angle2); RotatedRect rrect3 = rrect1; RotatedRect clone1 = rrect1.clone(); RotatedRect clone2 = rrect2.clone(); assertTrue(rrect1.equals(rrect3)); assertTrue(!rrect1.equals(rrect2)); assertTrue(rrect2.equals(clone2)); clone2.angle = 10; assertTrue(!rrect2.equals(clone2)); assertTrue(rrect1.equals(clone1)); clone1.center.x += 1; assertTrue(!rrect1.equals(clone1)); clone1.center.x -= 1; assertTrue(rrect1.equals(clone1)); clone1.size.width += 1; assertTrue(!rrect1.equals(clone1)); assertTrue(!rrect1.equals(size)); } public void testHashCode() { RotatedRect rr = new RotatedRect(center, size, angle); assertEquals(rr.hashCode(), rr.hashCode()); } public void testPoints() { RotatedRect rrect = new RotatedRect(center, size, angle); Point p[] = new Point[4]; rrect.points(p); boolean is_p0_irrational = (100 * p[0].x != (int) (100 * p[0].x)) && (100 * p[0].y != (int) (100 * p[0].y)); boolean is_p1_irrational = (100 * p[1].x != (int) (100 * p[1].x)) && (100 * p[1].y != (int) (100 * p[1].y)); boolean is_p2_irrational = (100 * p[2].x != (int) (100 * p[2].x)) && (100 * p[2].y != (int) (100 * p[2].y)); boolean is_p3_irrational = (100 * p[3].x != (int) (100 * p[3].x)) && (100 * p[3].y != (int) (100 * p[3].y)); assertTrue(is_p0_irrational && is_p1_irrational && is_p2_irrational && is_p3_irrational); assertTrue("Symmetric points 0 and 2", Math.abs((p[0].x + p[2].x) / 2 - center.x) + Math.abs((p[0].y + p[2].y) / 2 - center.y) < EPS); assertTrue("Symmetric points 1 and 3", Math.abs((p[1].x + p[3].x) / 2 - center.x) + Math.abs((p[1].y + p[3].y) / 2 - center.y) < EPS); assertTrue("Orthogonal vectors 01 and 12", Math.abs((p[1].x - p[0].x) * (p[2].x - p[1].x) + (p[1].y - p[0].y) * (p[2].y - p[1].y)) < EPS); assertTrue("Orthogonal vectors 12 and 23", Math.abs((p[2].x - p[1].x) * (p[3].x - p[2].x) + (p[2].y - p[1].y) * (p[3].y - p[2].y)) < EPS); assertTrue("Orthogonal vectors 23 and 30", Math.abs((p[3].x - p[2].x) * (p[0].x - p[3].x) + (p[3].y - p[2].y) * (p[0].y - p[3].y)) < EPS); assertTrue("Orthogonal vectors 30 and 01", Math.abs((p[0].x - p[3].x) * (p[1].x - p[0].x) + (p[0].y - p[3].y) * (p[1].y - p[0].y)) < EPS); assertTrue("Length of the vector 01", Math.abs((p[1].x - p[0].x) * (p[1].x - p[0].x) + (p[1].y - p[0].y) * (p[1].y - p[0].y) - size.height * size.height) < EPS); assertTrue("Length of the vector 21", Math.abs((p[1].x - p[2].x) * (p[1].x - p[2].x) + (p[1].y - p[2].y) * (p[1].y - p[2].y) - size.width * size.width) < EPS); assertTrue("Angle of the vector 21 with the axes", Math.abs((p[2].x - p[1].x) / size.width - Math.cos(angle * Math.PI / 180)) < EPS); } public void testRotatedRect() { RotatedRect rr = new RotatedRect(); assertTrue(rr != null); assertTrue(rr.center != null); assertTrue(rr.size != null); assertTrue(rr.angle == 0.0); } public void testRotatedRectDoubleArray() { double[] vals = { 1.5, 2.6, 3.7, 4.2, 5.1 }; RotatedRect rr = new RotatedRect(vals); assertNotNull(rr); assertEquals(1.5, rr.center.x); assertEquals(2.6, rr.center.y); assertEquals(3.7, rr.size.width); assertEquals(4.2, rr.size.height); assertEquals(5.1, rr.angle); } public void testRotatedRectPointSizeDouble() { RotatedRect rr = new RotatedRect(center, size, 40); assertTrue(rr != null); assertTrue(rr.center != null); assertTrue(rr.size != null); assertTrue(rr.angle == 40.0); } public void testSet() { double[] vals1 = {}; RotatedRect r1 = new RotatedRect(center, size, 40); r1.set(vals1); assertEquals(0., r1.angle); assertPointEquals(new Point(0, 0), r1.center, EPS); assertSizeEquals(new Size(0, 0), r1.size, EPS); double[] vals2 = { 1, 2, 3, 4, 5 }; RotatedRect r2 = new RotatedRect(center, size, 40); r2.set(vals2); assertEquals(5., r2.angle); assertPointEquals(new Point(1, 2), r2.center, EPS); assertSizeEquals(new Size(3, 4), r2.size, EPS); } public void testToString() { String actual = new RotatedRect(new Point(1, 2), new Size(10, 12), 4.5).toString(); String expected = "{ {1.0, 2.0} 10x12 * 4.5 }"; assertEquals(expected, actual); } }