// Copyright (c) 2012 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "base/basictypes.h" #include "testing/gtest/include/gtest/gtest.h" #include "ui/gfx/geometry/quad_f.h" #include "ui/gfx/geometry/rect_f.h" namespace gfx { TEST(QuadTest, Construction) { // Verify constructors. PointF a(1, 1); PointF b(2, 1); PointF c(2, 2); PointF d(1, 2); PointF e; QuadF q1; QuadF q2(e, e, e, e); QuadF q3(a, b, c, d); QuadF q4(BoundingRect(a, c)); EXPECT_EQ(q1, q2); EXPECT_EQ(q3, q4); // Verify getters. EXPECT_EQ(q3.p1(), a); EXPECT_EQ(q3.p2(), b); EXPECT_EQ(q3.p3(), c); EXPECT_EQ(q3.p4(), d); // Verify setters. q3.set_p1(b); q3.set_p2(c); q3.set_p3(d); q3.set_p4(a); EXPECT_EQ(q3.p1(), b); EXPECT_EQ(q3.p2(), c); EXPECT_EQ(q3.p3(), d); EXPECT_EQ(q3.p4(), a); // Verify operator=(Rect) EXPECT_NE(q1, q4); q1 = BoundingRect(a, c); EXPECT_EQ(q1, q4); // Verify operator=(Quad) EXPECT_NE(q1, q3); q1 = q3; EXPECT_EQ(q1, q3); } TEST(QuadTest, AddingVectors) { PointF a(1, 1); PointF b(2, 1); PointF c(2, 2); PointF d(1, 2); Vector2dF v(3.5f, -2.5f); QuadF q1(a, b, c, d); QuadF added = q1 + v; q1 += v; QuadF expected1(PointF(4.5f, -1.5f), PointF(5.5f, -1.5f), PointF(5.5f, -0.5f), PointF(4.5f, -0.5f)); EXPECT_EQ(expected1, added); EXPECT_EQ(expected1, q1); QuadF q2(a, b, c, d); QuadF subtracted = q2 - v; q2 -= v; QuadF expected2(PointF(-2.5f, 3.5f), PointF(-1.5f, 3.5f), PointF(-1.5f, 4.5f), PointF(-2.5f, 4.5f)); EXPECT_EQ(expected2, subtracted); EXPECT_EQ(expected2, q2); QuadF q3(a, b, c, d); q3 += v; q3 -= v; EXPECT_EQ(QuadF(a, b, c, d), q3); EXPECT_EQ(q3, (q3 + v - v)); } TEST(QuadTest, IsRectilinear) { PointF a(1, 1); PointF b(2, 1); PointF c(2, 2); PointF d(1, 2); Vector2dF v(3.5f, -2.5f); EXPECT_TRUE(QuadF().IsRectilinear()); EXPECT_TRUE(QuadF(a, b, c, d).IsRectilinear()); EXPECT_TRUE((QuadF(a, b, c, d) + v).IsRectilinear()); float epsilon = std::numeric_limits::epsilon(); PointF a2(1 + epsilon / 2, 1 + epsilon / 2); PointF b2(2 + epsilon / 2, 1 + epsilon / 2); PointF c2(2 + epsilon / 2, 2 + epsilon / 2); PointF d2(1 + epsilon / 2, 2 + epsilon / 2); EXPECT_TRUE(QuadF(a2, b, c, d).IsRectilinear()); EXPECT_TRUE((QuadF(a2, b, c, d) + v).IsRectilinear()); EXPECT_TRUE(QuadF(a, b2, c, d).IsRectilinear()); EXPECT_TRUE((QuadF(a, b2, c, d) + v).IsRectilinear()); EXPECT_TRUE(QuadF(a, b, c2, d).IsRectilinear()); EXPECT_TRUE((QuadF(a, b, c2, d) + v).IsRectilinear()); EXPECT_TRUE(QuadF(a, b, c, d2).IsRectilinear()); EXPECT_TRUE((QuadF(a, b, c, d2) + v).IsRectilinear()); struct { PointF a_off, b_off, c_off, d_off; } tests[] = { { PointF(1, 1.00001f), PointF(2, 1.00001f), PointF(2, 2.00001f), PointF(1, 2.00001f) }, { PointF(1.00001f, 1), PointF(2.00001f, 1), PointF(2.00001f, 2), PointF(1.00001f, 2) }, { PointF(1.00001f, 1.00001f), PointF(2.00001f, 1.00001f), PointF(2.00001f, 2.00001f), PointF(1.00001f, 2.00001f) }, { PointF(1, 0.99999f), PointF(2, 0.99999f), PointF(2, 1.99999f), PointF(1, 1.99999f) }, { PointF(0.99999f, 1), PointF(1.99999f, 1), PointF(1.99999f, 2), PointF(0.99999f, 2) }, { PointF(0.99999f, 0.99999f), PointF(1.99999f, 0.99999f), PointF(1.99999f, 1.99999f), PointF(0.99999f, 1.99999f) } }; for (size_t i = 0; i < arraysize(tests); ++i) { PointF a_off = tests[i].a_off; PointF b_off = tests[i].b_off; PointF c_off = tests[i].c_off; PointF d_off = tests[i].d_off; EXPECT_FALSE(QuadF(a_off, b, c, d).IsRectilinear()); EXPECT_FALSE((QuadF(a_off, b, c, d) + v).IsRectilinear()); EXPECT_FALSE(QuadF(a, b_off, c, d).IsRectilinear()); EXPECT_FALSE((QuadF(a, b_off, c, d) + v).IsRectilinear()); EXPECT_FALSE(QuadF(a, b, c_off, d).IsRectilinear()); EXPECT_FALSE((QuadF(a, b, c_off, d) + v).IsRectilinear()); EXPECT_FALSE(QuadF(a, b, c, d_off).IsRectilinear()); EXPECT_FALSE((QuadF(a, b, c, d_off) + v).IsRectilinear()); EXPECT_FALSE(QuadF(a_off, b, c_off, d).IsRectilinear()); EXPECT_FALSE((QuadF(a_off, b, c_off, d) + v).IsRectilinear()); EXPECT_FALSE(QuadF(a, b_off, c, d_off).IsRectilinear()); EXPECT_FALSE((QuadF(a, b_off, c, d_off) + v).IsRectilinear()); EXPECT_FALSE(QuadF(a, b_off, c_off, d_off).IsRectilinear()); EXPECT_FALSE((QuadF(a, b_off, c_off, d_off) + v).IsRectilinear()); EXPECT_FALSE(QuadF(a_off, b, c_off, d_off).IsRectilinear()); EXPECT_FALSE((QuadF(a_off, b, c_off, d_off) + v).IsRectilinear()); EXPECT_FALSE(QuadF(a_off, b_off, c, d_off).IsRectilinear()); EXPECT_FALSE((QuadF(a_off, b_off, c, d_off) + v).IsRectilinear()); EXPECT_FALSE(QuadF(a_off, b_off, c_off, d).IsRectilinear()); EXPECT_FALSE((QuadF(a_off, b_off, c_off, d) + v).IsRectilinear()); EXPECT_TRUE(QuadF(a_off, b_off, c_off, d_off).IsRectilinear()); EXPECT_TRUE((QuadF(a_off, b_off, c_off, d_off) + v).IsRectilinear()); } } TEST(QuadTest, IsCounterClockwise) { PointF a1(1, 1); PointF b1(2, 1); PointF c1(2, 2); PointF d1(1, 2); EXPECT_FALSE(QuadF(a1, b1, c1, d1).IsCounterClockwise()); EXPECT_FALSE(QuadF(b1, c1, d1, a1).IsCounterClockwise()); EXPECT_TRUE(QuadF(a1, d1, c1, b1).IsCounterClockwise()); EXPECT_TRUE(QuadF(c1, b1, a1, d1).IsCounterClockwise()); // Slightly more complicated quads should work just as easily. PointF a2(1.3f, 1.4f); PointF b2(-0.7f, 4.9f); PointF c2(1.8f, 6.2f); PointF d2(2.1f, 1.6f); EXPECT_TRUE(QuadF(a2, b2, c2, d2).IsCounterClockwise()); EXPECT_TRUE(QuadF(b2, c2, d2, a2).IsCounterClockwise()); EXPECT_FALSE(QuadF(a2, d2, c2, b2).IsCounterClockwise()); EXPECT_FALSE(QuadF(c2, b2, a2, d2).IsCounterClockwise()); // Quads with 3 collinear points should work correctly, too. PointF a3(0, 0); PointF b3(1, 0); PointF c3(2, 0); PointF d3(1, 1); EXPECT_FALSE(QuadF(a3, b3, c3, d3).IsCounterClockwise()); EXPECT_FALSE(QuadF(b3, c3, d3, a3).IsCounterClockwise()); EXPECT_TRUE(QuadF(a3, d3, c3, b3).IsCounterClockwise()); // The next expectation in particular would fail for an implementation // that incorrectly uses only a cross product of the first 3 vertices. EXPECT_TRUE(QuadF(c3, b3, a3, d3).IsCounterClockwise()); // Non-convex quads should work correctly, too. PointF a4(0, 0); PointF b4(1, 1); PointF c4(2, 0); PointF d4(1, 3); EXPECT_FALSE(QuadF(a4, b4, c4, d4).IsCounterClockwise()); EXPECT_FALSE(QuadF(b4, c4, d4, a4).IsCounterClockwise()); EXPECT_TRUE(QuadF(a4, d4, c4, b4).IsCounterClockwise()); EXPECT_TRUE(QuadF(c4, b4, a4, d4).IsCounterClockwise()); // A quad with huge coordinates should not fail this check due to // single-precision overflow. PointF a5(1e30f, 1e30f); PointF b5(1e35f, 1e30f); PointF c5(1e35f, 1e35f); PointF d5(1e30f, 1e35f); EXPECT_FALSE(QuadF(a5, b5, c5, d5).IsCounterClockwise()); EXPECT_FALSE(QuadF(b5, c5, d5, a5).IsCounterClockwise()); EXPECT_TRUE(QuadF(a5, d5, c5, b5).IsCounterClockwise()); EXPECT_TRUE(QuadF(c5, b5, a5, d5).IsCounterClockwise()); } TEST(QuadTest, BoundingBox) { RectF r(3.2f, 5.4f, 7.007f, 12.01f); EXPECT_EQ(r, QuadF(r).BoundingBox()); PointF a(1.3f, 1.4f); PointF b(-0.7f, 4.9f); PointF c(1.8f, 6.2f); PointF d(2.1f, 1.6f); float left = -0.7f; float top = 1.4f; float right = 2.1f; float bottom = 6.2f; EXPECT_EQ(RectF(left, top, right - left, bottom - top), QuadF(a, b, c, d).BoundingBox()); } TEST(QuadTest, ContainsPoint) { PointF a(1.3f, 1.4f); PointF b(-0.8f, 4.4f); PointF c(1.8f, 6.1f); PointF d(2.1f, 1.6f); Vector2dF epsilon_x(2 * std::numeric_limits::epsilon(), 0); Vector2dF epsilon_y(0, 2 * std::numeric_limits::epsilon()); Vector2dF ac_center = c - a; ac_center.Scale(0.5f); Vector2dF bd_center = d - b; bd_center.Scale(0.5f); EXPECT_TRUE(QuadF(a, b, c, d).Contains(a + ac_center)); EXPECT_TRUE(QuadF(a, b, c, d).Contains(b + bd_center)); EXPECT_TRUE(QuadF(a, b, c, d).Contains(c - ac_center)); EXPECT_TRUE(QuadF(a, b, c, d).Contains(d - bd_center)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(a - ac_center)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(b - bd_center)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(c + ac_center)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(d + bd_center)); EXPECT_TRUE(QuadF(a, b, c, d).Contains(a)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(a - epsilon_x)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(a - epsilon_y)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(a + epsilon_x)); EXPECT_TRUE(QuadF(a, b, c, d).Contains(a + epsilon_y)); EXPECT_TRUE(QuadF(a, b, c, d).Contains(b)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(b - epsilon_x)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(b - epsilon_y)); EXPECT_TRUE(QuadF(a, b, c, d).Contains(b + epsilon_x)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(b + epsilon_y)); EXPECT_TRUE(QuadF(a, b, c, d).Contains(c)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(c - epsilon_x)); EXPECT_TRUE(QuadF(a, b, c, d).Contains(c - epsilon_y)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(c + epsilon_x)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(c + epsilon_y)); EXPECT_TRUE(QuadF(a, b, c, d).Contains(d)); EXPECT_TRUE(QuadF(a, b, c, d).Contains(d - epsilon_x)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(d - epsilon_y)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(d + epsilon_x)); EXPECT_FALSE(QuadF(a, b, c, d).Contains(d + epsilon_y)); // Test a simple square. PointF s1(-1, -1); PointF s2(1, -1); PointF s3(1, 1); PointF s4(-1, 1); // Top edge. EXPECT_FALSE(QuadF(s1, s2, s3, s4).Contains(PointF(-1.1f, -1.0f))); EXPECT_TRUE(QuadF(s1, s2, s3, s4).Contains(PointF(-1.0f, -1.0f))); EXPECT_TRUE(QuadF(s1, s2, s3, s4).Contains(PointF(0.0f, -1.0f))); EXPECT_TRUE(QuadF(s1, s2, s3, s4).Contains(PointF(1.0f, -1.0f))); EXPECT_FALSE(QuadF(s1, s2, s3, s4).Contains(PointF(1.1f, -1.0f))); // Bottom edge. EXPECT_FALSE(QuadF(s1, s2, s3, s4).Contains(PointF(-1.1f, 1.0f))); EXPECT_TRUE(QuadF(s1, s2, s3, s4).Contains(PointF(-1.0f, 1.0f))); EXPECT_TRUE(QuadF(s1, s2, s3, s4).Contains(PointF(0.0f, 1.0f))); EXPECT_TRUE(QuadF(s1, s2, s3, s4).Contains(PointF(1.0f, 1.0f))); EXPECT_FALSE(QuadF(s1, s2, s3, s4).Contains(PointF(1.1f, 1.0f))); // Left edge. EXPECT_FALSE(QuadF(s1, s2, s3, s4).Contains(PointF(-1.0f, -1.1f))); EXPECT_TRUE(QuadF(s1, s2, s3, s4).Contains(PointF(-1.0f, -1.0f))); EXPECT_TRUE(QuadF(s1, s2, s3, s4).Contains(PointF(-1.0f, 0.0f))); EXPECT_TRUE(QuadF(s1, s2, s3, s4).Contains(PointF(-1.0f, 1.0f))); EXPECT_FALSE(QuadF(s1, s2, s3, s4).Contains(PointF(-1.0f, 1.1f))); // Right edge. EXPECT_FALSE(QuadF(s1, s2, s3, s4).Contains(PointF(1.0f, -1.1f))); EXPECT_TRUE(QuadF(s1, s2, s3, s4).Contains(PointF(1.0f, -1.0f))); EXPECT_TRUE(QuadF(s1, s2, s3, s4).Contains(PointF(1.0f, 0.0f))); EXPECT_TRUE(QuadF(s1, s2, s3, s4).Contains(PointF(1.0f, 1.0f))); EXPECT_FALSE(QuadF(s1, s2, s3, s4).Contains(PointF(1.0f, 1.1f))); // Centered inside. EXPECT_TRUE(QuadF(s1, s2, s3, s4).Contains(PointF(0, 0))); // Centered outside. EXPECT_FALSE(QuadF(s1, s2, s3, s4).Contains(PointF(-1.1f, 0))); EXPECT_FALSE(QuadF(s1, s2, s3, s4).Contains(PointF(1.1f, 0))); EXPECT_FALSE(QuadF(s1, s2, s3, s4).Contains(PointF(0, -1.1f))); EXPECT_FALSE(QuadF(s1, s2, s3, s4).Contains(PointF(0, 1.1f))); } TEST(QuadTest, Scale) { PointF a(1.3f, 1.4f); PointF b(-0.8f, 4.4f); PointF c(1.8f, 6.1f); PointF d(2.1f, 1.6f); QuadF q1(a, b, c, d); q1.Scale(1.5f); PointF a_scaled = ScalePoint(a, 1.5f); PointF b_scaled = ScalePoint(b, 1.5f); PointF c_scaled = ScalePoint(c, 1.5f); PointF d_scaled = ScalePoint(d, 1.5f); EXPECT_EQ(q1, QuadF(a_scaled, b_scaled, c_scaled, d_scaled)); QuadF q2; q2.Scale(1.5f); EXPECT_EQ(q2, q2); } } // namespace gfx