/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include #include "gtest/gtest.h" #include "nsRegion.h" #include "RegionBuilder.h" #include "mozilla/gfx/TiledRegion.h" #include "mozilla/UniquePtr.h" using namespace mozilla::gfx; //#define REGION_RANDOM_STRESS_TESTS class TestLargestRegion { public: static void TestSingleRect(nsRect r) { nsRegion region(r); EXPECT_TRUE(region.GetLargestRectangle().IsEqualInterior(r)); } // Construct a rectangle, remove part of it, then check the remainder static void TestNonRectangular() { nsRegion r(nsRect(0, 0, 30, 30)); const int nTests = 19; struct { nsRect rect; int64_t expectedArea; } tests[nTests] = {// Remove a 20x10 chunk from the square {nsRect(0, 0, 20, 10), 600}, {nsRect(10, 0, 20, 10), 600}, {nsRect(10, 20, 20, 10), 600}, {nsRect(0, 20, 20, 10), 600}, // Remove a 10x20 chunk from the square {nsRect(0, 0, 10, 20), 600}, {nsRect(20, 0, 10, 20), 600}, {nsRect(20, 10, 10, 20), 600}, {nsRect(0, 10, 10, 20), 600}, // Remove the center 10x10 {nsRect(10, 10, 10, 10), 300}, // Remove the middle column {nsRect(10, 0, 10, 30), 300}, // Remove the middle row {nsRect(0, 10, 30, 10), 300}, // Remove the corners 10x10 {nsRect(0, 0, 10, 10), 600}, {nsRect(20, 20, 10, 10), 600}, {nsRect(20, 0, 10, 10), 600}, {nsRect(0, 20, 10, 10), 600}, // Remove the corners 20x20 {nsRect(0, 0, 20, 20), 300}, {nsRect(10, 10, 20, 20), 300}, {nsRect(10, 0, 20, 20), 300}, {nsRect(0, 10, 20, 20), 300}}; for (int32_t i = 0; i < nTests; i++) { nsRegion r2; r2.Sub(r, tests[i].rect); EXPECT_TRUE(r2.IsComplex()) << "nsRegion code got unexpectedly smarter!"; nsRect largest = r2.GetLargestRectangle(); EXPECT_TRUE(largest.Width() * largest.Height() == tests[i].expectedArea) << "Did not successfully find largest rectangle in non-rectangular " "region on iteration " << i; } } static void TwoRectTest() { nsRegion r(nsRect(0, 0, 100, 100)); const int nTests = 4; struct { nsRect rect1, rect2; int64_t expectedArea; } tests[nTests] = { {nsRect(0, 0, 75, 40), nsRect(0, 60, 75, 40), 2500}, {nsRect(25, 0, 75, 40), nsRect(25, 60, 75, 40), 2500}, {nsRect(25, 0, 75, 40), nsRect(0, 60, 75, 40), 2000}, {nsRect(0, 0, 75, 40), nsRect(25, 60, 75, 40), 2000}, }; for (int32_t i = 0; i < nTests; i++) { nsRegion r2; r2.Sub(r, tests[i].rect1); r2.Sub(r2, tests[i].rect2); EXPECT_TRUE(r2.IsComplex()) << "nsRegion code got unexpectedly smarter!"; nsRect largest = r2.GetLargestRectangle(); EXPECT_TRUE(largest.Width() * largest.Height() == tests[i].expectedArea) << "Did not successfully find largest rectangle in two-rect-subtract " "region on iteration " << i; } } static void TestContainsSpecifiedRect() { nsRegion r(nsRect(0, 0, 100, 100)); r.Or(r, nsRect(0, 300, 50, 50)); EXPECT_TRUE(r.GetLargestRectangle(nsRect(0, 300, 10, 10)) .IsEqualInterior(nsRect(0, 300, 50, 50))) << "Chose wrong rectangle"; } static void TestContainsSpecifiedOverflowingRect() { nsRegion r(nsRect(0, 0, 100, 100)); r.Or(r, nsRect(0, 300, 50, 50)); EXPECT_TRUE(r.GetLargestRectangle(nsRect(0, 290, 10, 20)) .IsEqualInterior(nsRect(0, 300, 50, 50))) << "Chose wrong rectangle"; } }; TEST(Gfx, RegionSingleRect) { TestLargestRegion::TestSingleRect(nsRect(0, 52, 720, 480)); TestLargestRegion::TestSingleRect(nsRect(-20, 40, 50, 20)); TestLargestRegion::TestSingleRect(nsRect(-20, 40, 10, 8)); TestLargestRegion::TestSingleRect(nsRect(-20, -40, 10, 8)); TestLargestRegion::TestSingleRect(nsRect(-10, -10, 20, 20)); } TEST(Gfx, RegionNonRectangular) { TestLargestRegion::TestNonRectangular(); } TEST(Gfx, RegionTwoRectTest) { TestLargestRegion::TwoRectTest(); } TEST(Gfx, RegionContainsSpecifiedRect) { TestLargestRegion::TestContainsSpecifiedRect(); } TEST(Gfx, RegionTestContainsSpecifiedOverflowingRect) { TestLargestRegion::TestContainsSpecifiedOverflowingRect(); } TEST(Gfx, RegionScaleToInside) { { // no rectangles nsRegion r; nsIntRegion scaled = r.ScaleToInsidePixels(1, 1, 60); nsIntRegion result; EXPECT_TRUE(result.IsEqual(scaled)) << "scaled result incorrect"; } { // one rectangle nsRegion r(nsRect(0, 44760, 19096, 264)); nsIntRegion scaled = r.ScaleToInsidePixels(1, 1, 60); nsIntRegion result(mozilla::gfx::IntRect(0, 746, 318, 4)); EXPECT_TRUE(result.IsEqual(scaled)) << "scaled result incorrect"; } { // the first rectangle gets adjusted nsRegion r(nsRect(0, 44760, 19096, 264)); r.Or(r, nsRect(0, 45024, 19360, 1056)); nsIntRegion scaled = r.ScaleToInsidePixels(1, 1, 60); nsIntRegion result(mozilla::gfx::IntRect(0, 746, 318, 5)); result.Or(result, mozilla::gfx::IntRect(0, 751, 322, 17)); EXPECT_TRUE(result.IsEqual(scaled)) << "scaled result incorrect"; } { // the second rectangle gets adjusted nsRegion r(nsRect(0, 44760, 19360, 264)); r.Or(r, nsRect(0, 45024, 19096, 1056)); nsIntRegion scaled = r.ScaleToInsidePixels(1, 1, 60); nsIntRegion result(mozilla::gfx::IntRect(0, 746, 322, 4)); result.Or(result, mozilla::gfx::IntRect(0, 750, 318, 18)); EXPECT_TRUE(result.IsEqual(scaled)) << "scaled result incorrect"; } } TEST(Gfx, RegionIsEqual) { { nsRegion r(nsRect(0, 0, 50, 50)); EXPECT_FALSE(nsRegion().IsEqual(r)); } { nsRegion r1(nsRect(0, 0, 50, 50)); nsRegion r2(nsRect(0, 0, 50, 50)); EXPECT_TRUE(r1.IsEqual(r2)); } { nsRegion r1(nsRect(0, 0, 50, 50)); nsRegion r2(nsRect(0, 0, 60, 50)); EXPECT_FALSE(r1.IsEqual(r2)); } { nsRegion r1(nsRect(0, 0, 50, 50)); r1.OrWith(nsRect(0, 60, 50, 50)); nsRegion r2(nsRect(0, 0, 50, 50)); r2.OrWith(nsRect(0, 60, 50, 50)); EXPECT_TRUE(r1.IsEqual(r2)); } { nsRegion r1(nsRect(0, 0, 50, 50)); r1.OrWith(nsRect(0, 60, 50, 50)); nsRegion r2(nsRect(0, 0, 50, 50)); r2.OrWith(nsRect(0, 70, 50, 50)); EXPECT_FALSE(r1.IsEqual(r2)); } { nsRegion r1(nsRect(0, 0, 50, 50)); r1.OrWith(nsRect(0, 60, 50, 50)); r1.OrWith(nsRect(100, 60, 50, 50)); nsRegion r2(nsRect(0, 0, 50, 50)); r2.OrWith(nsRect(0, 60, 50, 50)); EXPECT_FALSE(r1.IsEqual(r2)); } } TEST(Gfx, RegionOrWith) { PR_Sleep(PR_SecondsToInterval(10)); { nsRegion r(nsRect(11840, 11840, 4640, -10880)); r.OrWith(nsRect(160, 160, 7720, 880)); } { nsRegion r(nsRect(79, 31, 75, 12)); r.OrWith(nsRect(22, 43, 132, 5)); r.OrWith(nsRect(22, 48, 125, 3)); r.OrWith(nsRect(22, 51, 96, 20)); r.OrWith(nsRect(34, 71, 1, 14)); r.OrWith(nsRect(26, 85, 53, 1)); r.OrWith(nsRect(26, 86, 53, 4)); r.OrWith(nsRect(96, 86, 30, 4)); r.OrWith(nsRect(34, 90, 1, 2)); r.OrWith(nsRect(96, 90, 30, 2)); r.OrWith(nsRect(34, 92, 1, 3)); r.OrWith(nsRect(49, 92, 34, 3)); r.OrWith(nsRect(96, 92, 30, 3)); r.OrWith(nsRect(34, 95, 1, 17)); r.OrWith(nsRect(49, 95, 77, 17)); r.OrWith(nsRect(34, 112, 1, 12)); r.OrWith(nsRect(75, 112, 51, 12)); r.OrWith(nsRect(34, 124, 1, 10)); r.OrWith(nsRect(75, 124, 44, 10)); r.OrWith(nsRect(34, 134, 1, 19)); r.OrWith(nsRect(22, 17, 96, 27)); } { nsRegion r(nsRect(0, 8, 257, 32)); r.OrWith(nsRect(3702, 8, 138, 32)); r.OrWith(nsRect(0, 40, 225, 1)); r.OrWith(nsRect(3702, 40, 138, 1)); r.OrWith(nsRect(0, 41, 101, 40)); r.OrWith(nsRect(69, 41, 32, 40)); } { nsRegion r(nsRect(79, 56, 8, 32)); r.OrWith(nsRect(5, 94, 23, 81)); r.OrWith(nsRect(56, 29, 91, 81)); } { nsRegion r(nsRect(0, 82, 3840, 2046)); r.OrWith(nsRect(0, 0, 3840, 82)); } { nsRegion r(nsRect(2, 5, 600, 28)); r.OrWith(nsRect(2, 82, 600, 19)); r.OrWith(nsRect(2, 33, 600, 49)); } { nsRegion r(nsRect(3823, 0, 17, 17)); r.OrWith(nsRect(3823, 2029, 17, 17)); r.OrWith(nsRect(3823, 0, 17, 2046)); } { nsRegion r(nsRect(1036, 4, 32, 21)); r.OrWith(nsRect(1070, 4, 66, 21)); r.OrWith(nsRect(40, 5, 0, 33)); } { nsRegion r(nsRect(0, 0, 1024, 1152)); r.OrWith(nsRect(-335802, -1073741824, 1318851, 1860043520)); } { nsRegion r(nsRect(0, 0, 800, 1000)); r.OrWith(nsRect(0, 0, 536870912, 1073741824)); } { nsRegion r(nsRect(53, 2, 52, 3)); r.OrWith(nsRect(45, 5, 60, 16)); r.OrWith(nsRect(16, 21, 8, 1)); r.OrWith(nsRect(45, 21, 12, 1)); r.OrWith(nsRect(16, 22, 8, 5)); r.OrWith(nsRect(33, 22, 52, 5)); r.OrWith(nsRect(16, 27, 8, 7)); r.OrWith(nsRect(33, 27, 66, 7)); r.OrWith(nsRect(0, 34, 99, 1)); r.OrWith(nsRect(0, 35, 159, 27)); r.OrWith(nsRect(0, 62, 122, 3)); r.OrWith(nsRect(0, 65, 85, 11)); r.OrWith(nsRect(91, 65, 97, 11)); r.OrWith(nsRect(11, 76, 74, 2)); r.OrWith(nsRect(91, 76, 97, 2)); r.OrWith(nsRect(11, 78, 74, 12)); r.OrWith(nsRect(11, 90, 13, 3)); r.OrWith(nsRect(33, 90, 108, 3)); r.OrWith(nsRect(16, 93, 8, 22)); r.OrWith(nsRect(33, 93, 108, 22)); r.OrWith(nsRect(16, 115, 8, 1)); r.OrWith(nsRect(58, 115, 83, 1)); r.OrWith(nsRect(58, 116, 83, 25)); r.OrWith(nsRect(59, 37, 88, 92)); } #ifdef REGION_RANDOM_STRESS_TESTS const uint32_t TestIterations = 100000; const uint32_t RectsPerTest = 100; nsRect rects[RectsPerTest]; for (uint32_t i = 0; i < TestIterations; i++) { nsRegion r; for (uint32_t n = 0; n < RectsPerTest; n++) { rects[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); } r.SetEmpty(); for (uint32_t n = 0; n < RectsPerTest; n++) { r.OrWith(rects[n]); } for (uint32_t n = 0; n < RectsPerTest; n++) { EXPECT_TRUE(r.Contains(rects[n])); } } #endif } TEST(Gfx, RegionSubWith) { { nsRegion r1(nsRect(0, 0, 100, 50)); r1.OrWith(nsRect(50, 50, 50, 50)); nsRegion r2(nsRect(0, 0, 100, 50)); r2.OrWith(nsRect(50, 50, 50, 50)); r1.SubWith(r2); EXPECT_FALSE(r1.Contains(1, 1)); } { nsRegion r1(nsRect(0, 0, 800, 1000)); nsRegion r2(nsRect(8, 108, 22, 20)); r2.OrWith(nsRect(91, 138, 17, 18)); r1.SubWith(r2); EXPECT_TRUE(r1.Contains(400, 130)); } { nsRegion r1(nsRect(392, 2, 28, 7)); r1.OrWith(nsRect(115, 9, 305, 16)); r1.OrWith(nsRect(392, 25, 28, 5)); r1.OrWith(nsRect(0, 32, 1280, 41)); nsRegion r2(nsRect(0, 0, 1280, 9)); r2.OrWith(nsRect(0, 9, 115, 16)); r2.OrWith(nsRect(331, 9, 949, 16)); r2.OrWith(nsRect(0, 25, 1280, 7)); r2.OrWith(nsRect(331, 32, 124, 1)); r1.SubWith(r2); EXPECT_FALSE(r1.Contains(350, 15)); } { nsRegion r1(nsRect(552, 0, 2, 2)); r1.OrWith(nsRect(362, 2, 222, 28)); r1.OrWith(nsRect(552, 30, 2, 2)); r1.OrWith(nsRect(0, 32, 1280, 41)); nsRegion r2(nsRect(512, 0, 146, 9)); r2.OrWith(nsRect(340, 9, 318, 16)); r2.OrWith(nsRect(512, 25, 146, 8)); r1.SubWith(r2); EXPECT_FALSE(r1.Contains(350, 15)); } { nsRegion r(nsRect(0, 0, 229380, 6780)); r.OrWith(nsRect(76800, 6780, 76800, 4440)); r.OrWith(nsRect(76800, 11220, 44082, 1800)); r.OrWith(nsRect(122682, 11220, 30918, 1800)); r.OrWith(nsRect(76800, 13020, 76800, 2340)); r.OrWith(nsRect(85020, 15360, 59340, 75520)); r.OrWith(nsRect(85020, 90880, 38622, 11332)); r.OrWith(nsRect(143789, 90880, 571, 11332)); r.OrWith(nsRect(85020, 102212, 59340, 960)); r.OrWith(nsRect(85020, 103172, 38622, 1560)); r.OrWith(nsRect(143789, 103172, 571, 1560)); r.OrWith(nsRect(85020, 104732, 59340, 12292)); r.OrWith(nsRect(85020, 117024, 38622, 1560)); r.OrWith(nsRect(143789, 117024, 571, 1560)); r.OrWith(nsRect(85020, 118584, 59340, 11976)); r.SubWith(nsRect(123642, 89320, 20147, 1560)); } { nsRegion r(nsRect(0, 0, 9480, 12900)); r.OrWith(nsRect(0, 12900, 8460, 1020)); r.SubWith(nsRect(8460, 0, 1020, 12900)); } { nsRegion r1(nsRect(99, 1, 51, 2)); r1.OrWith(nsRect(85, 3, 65, 1)); r1.OrWith(nsRect(10, 4, 66, 5)); r1.OrWith(nsRect(85, 4, 37, 5)); r1.OrWith(nsRect(10, 9, 112, 3)); r1.OrWith(nsRect(1, 12, 121, 1)); r1.OrWith(nsRect(1, 13, 139, 3)); r1.OrWith(nsRect(0, 16, 140, 3)); r1.OrWith(nsRect(0, 19, 146, 3)); r1.OrWith(nsRect(0, 22, 149, 2)); r1.OrWith(nsRect(0, 24, 154, 2)); r1.OrWith(nsRect(0, 26, 160, 23)); r1.OrWith(nsRect(0, 49, 162, 31)); r1.OrWith(nsRect(0, 80, 171, 19)); r1.OrWith(nsRect(0, 99, 173, 11)); r1.OrWith(nsRect(2, 110, 171, 6)); r1.OrWith(nsRect(6, 116, 165, 5)); r1.OrWith(nsRect(8, 121, 163, 1)); r1.OrWith(nsRect(13, 122, 158, 11)); r1.OrWith(nsRect(14, 133, 157, 23)); r1.OrWith(nsRect(29, 156, 142, 10)); r1.OrWith(nsRect(37, 166, 134, 6)); r1.OrWith(nsRect(55, 172, 4, 4)); r1.OrWith(nsRect(83, 172, 88, 4)); r1.OrWith(nsRect(55, 176, 4, 2)); r1.OrWith(nsRect(89, 176, 6, 2)); r1.OrWith(nsRect(89, 178, 6, 4)); nsRegion r2(nsRect(63, 11, 39, 11)); r2.OrWith(nsRect(63, 22, 99, 16)); r2.OrWith(nsRect(37, 38, 125, 61)); r2.OrWith(nsRect(45, 99, 117, 8)); r2.OrWith(nsRect(47, 107, 115, 7)); r2.OrWith(nsRect(47, 114, 66, 1)); r2.OrWith(nsRect(49, 115, 64, 2)); r2.OrWith(nsRect(49, 117, 54, 30)); r1.SubWith(r2); } { nsRegion r1(nsRect(95, 2, 47, 1)); r1.OrWith(nsRect(62, 3, 80, 2)); r1.OrWith(nsRect(1, 5, 18, 3)); r1.OrWith(nsRect(48, 5, 94, 3)); r1.OrWith(nsRect(1, 8, 18, 3)); r1.OrWith(nsRect(23, 8, 119, 3)); r1.OrWith(nsRect(1, 11, 172, 9)); r1.OrWith(nsRect(1, 20, 18, 8)); r1.OrWith(nsRect(20, 20, 153, 8)); r1.OrWith(nsRect(1, 28, 172, 13)); r1.OrWith(nsRect(1, 41, 164, 1)); r1.OrWith(nsRect(1, 42, 168, 1)); r1.OrWith(nsRect(0, 43, 169, 15)); r1.OrWith(nsRect(1, 58, 168, 26)); r1.OrWith(nsRect(1, 84, 162, 2)); r1.OrWith(nsRect(1, 86, 165, 23)); r1.OrWith(nsRect(1, 109, 162, 23)); r1.OrWith(nsRect(1, 132, 152, 4)); r1.OrWith(nsRect(1, 136, 150, 12)); r1.OrWith(nsRect(12, 148, 139, 4)); r1.OrWith(nsRect(12, 152, 113, 2)); r1.OrWith(nsRect(14, 154, 31, 3)); r1.OrWith(nsRect(82, 154, 43, 3)); r1.OrWith(nsRect(17, 157, 13, 19)); r1.OrWith(nsRect(82, 157, 43, 19)); r1.OrWith(nsRect(17, 176, 13, 16)); nsRegion r2(nsRect(97, 9, 6, 10)); r2.OrWith(nsRect(71, 19, 32, 2)); r2.OrWith(nsRect(20, 21, 83, 2)); r2.OrWith(nsRect(2, 23, 101, 9)); r2.OrWith(nsRect(2, 32, 98, 1)); r2.OrWith(nsRect(2, 33, 104, 5)); r2.OrWith(nsRect(2, 38, 118, 2)); r2.OrWith(nsRect(15, 40, 9, 11)); r2.OrWith(nsRect(36, 40, 84, 11)); r2.OrWith(nsRect(4, 51, 116, 33)); r2.OrWith(nsRect(4, 84, 159, 8)); r2.OrWith(nsRect(4, 92, 116, 13)); r2.OrWith(nsRect(15, 105, 9, 7)); r2.OrWith(nsRect(36, 105, 84, 7)); r2.OrWith(nsRect(36, 112, 84, 22)); r2.OrWith(nsRect(71, 134, 39, 46)); r1.SubWith(r2); } #ifdef REGION_RANDOM_STRESS_TESTS const uint32_t TestIterations = 100000; const uint32_t RectsPerTest = 100; const uint32_t SubRectsPerTest = 10; nsRect rects[RectsPerTest]; nsRect subRects[SubRectsPerTest]; for (uint32_t i = 0; i < TestIterations; i++) { nsRegion r; for (uint32_t n = 0; n < RectsPerTest; n++) { rects[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); } r.SetEmpty(); for (uint32_t n = 0; n < RectsPerTest; n++) { r.OrWith(rects[n]); } for (uint32_t n = 0; n < RectsPerTest; n++) { EXPECT_TRUE(r.Contains(rects[n])); } for (uint32_t n = 0; n < SubRectsPerTest; n++) { subRects[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); } for (uint32_t n = 0; n < SubRectsPerTest; n++) { r.SubWith(subRects[n]); } for (uint32_t n = 0; n < SubRectsPerTest; n++) { EXPECT_FALSE(r.Contains(subRects[n].x, subRects[n].y)); EXPECT_FALSE(r.Contains(subRects[n].x, subRects[n].YMost() - 1)); EXPECT_FALSE( r.Contains(subRects[n].XMost() - 1, subRects[n].YMost() - 1)); EXPECT_FALSE(r.Contains(subRects[n].XMost() - 1, subRects[n].Y())); } } for (uint32_t i = 0; i < TestIterations; i++) { nsRegion r; for (uint32_t n = 0; n < RectsPerTest; n++) { rects[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); } r.SetEmpty(); for (uint32_t n = 0; n < RectsPerTest; n++) { r.OrWith(rects[n]); } for (uint32_t n = 0; n < RectsPerTest; n++) { EXPECT_TRUE(r.Contains(rects[n])); } for (uint32_t n = 0; n < SubRectsPerTest; n++) { subRects[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); } nsRegion r2; for (uint32_t n = 0; n < SubRectsPerTest; n++) { r2.OrWith(subRects[n]); } r.SubWith(r2); for (uint32_t n = 0; n < SubRectsPerTest; n++) { EXPECT_FALSE(r.Contains(subRects[n].x, subRects[n].y)); EXPECT_FALSE(r.Contains(subRects[n].x, subRects[n].YMost() - 1)); EXPECT_FALSE( r.Contains(subRects[n].XMost() - 1, subRects[n].YMost() - 1)); EXPECT_FALSE(r.Contains(subRects[n].XMost() - 1, subRects[n].Y())); } } for (uint32_t i = 0; i < TestIterations; i++) { nsRegion r(nsRect(-1, -1, 202, 202)); for (uint32_t n = 0; n < SubRectsPerTest; n++) { subRects[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); r.SubWith(subRects[n]); } for (uint32_t n = 0; n < SubRectsPerTest; n++) { EXPECT_FALSE(r.Contains(subRects[n].x, subRects[n].y)); EXPECT_FALSE(r.Contains(subRects[n].x, subRects[n].YMost() - 1)); EXPECT_FALSE( r.Contains(subRects[n].XMost() - 1, subRects[n].YMost() - 1)); EXPECT_FALSE(r.Contains(subRects[n].XMost() - 1, subRects[n].Y())); } EXPECT_TRUE(r.Contains(-1, -1)); EXPECT_TRUE(r.Contains(-1, 200)); EXPECT_TRUE(r.Contains(200, -1)); EXPECT_TRUE(r.Contains(200, 200)); } for (uint32_t i = 0; i < TestIterations; i++) { nsRegion r(nsRect(-1, -1, 202, 202)); nsRegion r2; for (uint32_t n = 0; n < SubRectsPerTest; n++) { subRects[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); r2.OrWith(subRects[n]); } r.SubWith(r2); for (uint32_t n = 0; n < SubRectsPerTest; n++) { EXPECT_FALSE(r.Contains(subRects[n].x, subRects[n].y)); EXPECT_FALSE(r.Contains(subRects[n].x, subRects[n].YMost() - 1)); EXPECT_FALSE( r.Contains(subRects[n].XMost() - 1, subRects[n].YMost() - 1)); EXPECT_FALSE(r.Contains(subRects[n].XMost() - 1, subRects[n].Y())); } EXPECT_TRUE(r.Contains(-1, -1)); EXPECT_TRUE(r.Contains(-1, 200)); EXPECT_TRUE(r.Contains(200, -1)); EXPECT_TRUE(r.Contains(200, 200)); } #endif } TEST(Gfx, RegionSub) { { nsRegion r1(nsRect(0, 0, 100, 50)); r1.OrWith(nsRect(50, 50, 50, 50)); nsRegion r2(nsRect(0, 0, 100, 50)); r2.OrWith(nsRect(50, 50, 50, 50)); nsRegion r3; r3.Sub(r1, r2); EXPECT_FALSE(r3.Contains(1, 1)); } { nsRegion r1(nsRect(0, 0, 800, 1000)); nsRegion r2(nsRect(8, 108, 22, 20)); r2.OrWith(nsRect(91, 138, 17, 18)); nsRegion r3; r3.Sub(r1, r2); EXPECT_TRUE(r3.Contains(400, 130)); } { nsRegion r1(nsRect(392, 2, 28, 7)); r1.OrWith(nsRect(115, 9, 305, 16)); r1.OrWith(nsRect(392, 25, 28, 5)); r1.OrWith(nsRect(0, 32, 1280, 41)); nsRegion r2(nsRect(0, 0, 1280, 9)); r2.OrWith(nsRect(0, 9, 115, 16)); r2.OrWith(nsRect(331, 9, 949, 16)); r2.OrWith(nsRect(0, 25, 1280, 7)); r2.OrWith(nsRect(331, 32, 124, 1)); nsRegion r3; r3.Sub(r1, r2); EXPECT_FALSE(r3.Contains(350, 15)); } { nsRegion r1(nsRect(552, 0, 2, 2)); r1.OrWith(nsRect(362, 2, 222, 28)); r1.OrWith(nsRect(552, 30, 2, 2)); r1.OrWith(nsRect(0, 32, 1280, 41)); nsRegion r2(nsRect(512, 0, 146, 9)); r2.OrWith(nsRect(340, 9, 318, 16)); r2.OrWith(nsRect(512, 25, 146, 8)); nsRegion r3; r3.Sub(r1, r2); EXPECT_FALSE(r3.Contains(350, 15)); } { nsRegion r1(nsRect(0, 0, 1265, 1024)); nsRegion r2(nsRect(1265, 0, 15, 685)); r2.OrWith(nsRect(0, 714, 1280, 221)); nsRegion r3; r3.Sub(r1, r2); } { nsRegion r1(nsRect(6, 0, 64, 1)); r1.OrWith(nsRect(6, 1, 67, 1)); r1.OrWith(nsRect(6, 2, 67, 2)); r1.OrWith(nsRect(79, 2, 67, 2)); r1.OrWith(nsRect(6, 4, 67, 1)); r1.OrWith(nsRect(79, 4, 98, 1)); r1.OrWith(nsRect(6, 5, 171, 18)); r1.OrWith(nsRect(1, 23, 176, 3)); r1.OrWith(nsRect(1, 26, 178, 5)); r1.OrWith(nsRect(1, 31, 176, 9)); r1.OrWith(nsRect(0, 40, 177, 57)); r1.OrWith(nsRect(0, 97, 176, 33)); r1.OrWith(nsRect(0, 130, 12, 17)); r1.OrWith(nsRect(15, 130, 161, 17)); r1.OrWith(nsRect(0, 147, 12, 5)); r1.OrWith(nsRect(15, 147, 111, 5)); r1.OrWith(nsRect(0, 152, 12, 7)); r1.OrWith(nsRect(17, 152, 109, 7)); r1.OrWith(nsRect(0, 159, 12, 2)); r1.OrWith(nsRect(17, 159, 98, 2)); r1.OrWith(nsRect(17, 161, 98, 9)); r1.OrWith(nsRect(27, 170, 63, 21)); nsRegion r2(nsRect(9, 9, 37, 17)); r2.OrWith(nsRect(92, 9, 26, 17)); r2.OrWith(nsRect(9, 26, 37, 9)); r2.OrWith(nsRect(84, 26, 65, 9)); r2.OrWith(nsRect(9, 35, 37, 2)); r2.OrWith(nsRect(51, 35, 98, 2)); r2.OrWith(nsRect(51, 37, 98, 11)); r2.OrWith(nsRect(51, 48, 78, 4)); r2.OrWith(nsRect(87, 52, 42, 7)); r2.OrWith(nsRect(19, 59, 12, 5)); r2.OrWith(nsRect(87, 59, 42, 5)); r2.OrWith(nsRect(19, 64, 12, 9)); r2.OrWith(nsRect(32, 64, 97, 9)); r2.OrWith(nsRect(19, 73, 12, 2)); r2.OrWith(nsRect(32, 73, 104, 2)); r2.OrWith(nsRect(19, 75, 117, 5)); r2.OrWith(nsRect(18, 80, 118, 5)); r2.OrWith(nsRect(18, 85, 111, 38)); r2.OrWith(nsRect(87, 123, 42, 11)); nsRegion r3; r3.Sub(r1, r2); } { nsRegion r1(nsRect(27, 0, 39, 1)); r1.OrWith(nsRect(86, 0, 22, 1)); r1.OrWith(nsRect(27, 1, 43, 1)); r1.OrWith(nsRect(86, 1, 22, 1)); r1.OrWith(nsRect(27, 2, 43, 1)); r1.OrWith(nsRect(86, 2, 75, 1)); r1.OrWith(nsRect(12, 3, 58, 1)); r1.OrWith(nsRect(86, 3, 75, 1)); r1.OrWith(nsRect(12, 4, 149, 5)); r1.OrWith(nsRect(0, 9, 161, 9)); r1.OrWith(nsRect(0, 18, 167, 17)); r1.OrWith(nsRect(0, 35, 171, 5)); r1.OrWith(nsRect(0, 40, 189, 28)); r1.OrWith(nsRect(0, 68, 171, 16)); r1.OrWith(nsRect(4, 84, 167, 5)); r1.OrWith(nsRect(4, 89, 177, 9)); r1.OrWith(nsRect(1, 98, 180, 59)); r1.OrWith(nsRect(4, 157, 177, 1)); r1.OrWith(nsRect(4, 158, 139, 15)); r1.OrWith(nsRect(17, 173, 126, 2)); r1.OrWith(nsRect(20, 175, 123, 2)); r1.OrWith(nsRect(20, 177, 118, 6)); r1.OrWith(nsRect(20, 183, 84, 2)); nsRegion r2(nsRect(64, 2, 30, 6)); r2.OrWith(nsRect(26, 11, 41, 17)); r2.OrWith(nsRect(19, 28, 48, 23)); r2.OrWith(nsRect(19, 51, 76, 8)); r2.OrWith(nsRect(4, 59, 91, 31)); r2.OrWith(nsRect(19, 90, 76, 29)); r2.OrWith(nsRect(33, 119, 62, 25)); r2.OrWith(nsRect(33, 144, 4, 21)); nsRegion r3; r3.Sub(r1, r2); } #ifdef REGION_RANDOM_STRESS_TESTS const uint32_t TestIterations = 100000; const uint32_t RectsPerTest = 100; const uint32_t SubRectsPerTest = 10; nsRect rects[RectsPerTest]; nsRect subRects[SubRectsPerTest]; for (uint32_t i = 0; i < TestIterations; i++) { nsRegion r; for (uint32_t n = 0; n < RectsPerTest; n++) { rects[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); } r.SetEmpty(); for (uint32_t n = 0; n < RectsPerTest; n++) { r.OrWith(rects[n]); } for (uint32_t n = 0; n < RectsPerTest; n++) { EXPECT_TRUE(r.Contains(rects[n])); } for (uint32_t n = 0; n < SubRectsPerTest; n++) { subRects[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); } nsRegion r2; for (uint32_t n = 0; n < SubRectsPerTest; n++) { r2.OrWith(subRects[n]); } nsRegion r3; r3.Sub(r, r2); for (uint32_t n = 0; n < SubRectsPerTest; n++) { EXPECT_FALSE(r3.Contains(subRects[n].x, subRects[n].y)); EXPECT_FALSE(r3.Contains(subRects[n].x, subRects[n].YMost() - 1)); EXPECT_FALSE( r3.Contains(subRects[n].XMost() - 1, subRects[n].YMost() - 1)); EXPECT_FALSE(r3.Contains(subRects[n].XMost() - 1, subRects[n].Y())); } } for (uint32_t i = 0; i < TestIterations; i++) { nsRegion r(nsRect(-1, -1, 202, 202)); nsRegion r2; for (uint32_t n = 0; n < SubRectsPerTest; n++) { subRects[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); r2.OrWith(subRects[n]); } nsRegion r3; r3.Sub(r, r2); for (uint32_t n = 0; n < SubRectsPerTest; n++) { EXPECT_FALSE(r3.Contains(subRects[n].x, subRects[n].y)); EXPECT_FALSE(r3.Contains(subRects[n].x, subRects[n].YMost() - 1)); EXPECT_FALSE( r3.Contains(subRects[n].XMost() - 1, subRects[n].YMost() - 1)); EXPECT_FALSE(r3.Contains(subRects[n].XMost() - 1, subRects[n].Y())); } EXPECT_TRUE(r3.Contains(-1, -1)); EXPECT_TRUE(r3.Contains(-1, 200)); EXPECT_TRUE(r3.Contains(200, -1)); EXPECT_TRUE(r3.Contains(200, 200)); } #endif } TEST(Gfx, RegionAndWith) { { nsRegion r(nsRect(20, 0, 20, 20)); r.OrWith(nsRect(0, 20, 40, 20)); r.AndWith(nsRect(0, 0, 5, 5)); EXPECT_FALSE(r.Contains(1, 1)); } { nsRegion r1(nsRect(512, 1792, 256, 256)); nsRegion r2(nsRect(17, 1860, 239, 35)); r2.OrWith(nsRect(17, 1895, 239, 7)); r2.OrWith(nsRect(768, 1895, 154, 7)); r2.OrWith(nsRect(17, 1902, 905, 483)); r1.AndWith(r2); } #ifdef REGION_RANDOM_STRESS_TESTS const uint32_t TestIterations = 100000; const uint32_t RectsPerTest = 50; const uint32_t pointsTested = 100; { nsRect rectsSet1[RectsPerTest]; nsRect rectsSet2[RectsPerTest]; for (uint32_t i = 0; i < TestIterations; i++) { nsRegion r1; nsRegion r2; for (uint32_t n = 0; n < RectsPerTest; n++) { rectsSet1[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); rectsSet2[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); r1.OrWith(rectsSet1[n]); r2.OrWith(rectsSet1[n]); } nsRegion r3 = r1; r3.AndWith(r2); for (uint32_t n = 0; n < pointsTested; n++) { nsPoint p(rand() % 200, rand() % 200); if (r1.Contains(p.x, p.y) && r2.Contains(p.x, p.y)) { EXPECT_TRUE(r3.Contains(p.x, p.y)); } else { EXPECT_FALSE(r3.Contains(p.x, p.y)); } } } } { nsRect rectsSet[RectsPerTest]; nsRect testRect; for (uint32_t i = 0; i < TestIterations; i++) { nsRegion r; for (uint32_t n = 0; n < RectsPerTest; n++) { rectsSet[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); } for (uint32_t n = 0; n < RectsPerTest; n++) { r.OrWith(rectsSet[n]); } testRect.SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); nsRegion r2 = r; r2.AndWith(testRect); for (uint32_t n = 0; n < pointsTested; n++) { nsPoint p(rand() % 200, rand() % 200); if (r.Contains(p.x, p.y) && testRect.Contains(p.x, p.y)) { EXPECT_TRUE(r2.Contains(p.x, p.y)); } else { EXPECT_FALSE(r2.Contains(p.x, p.y)); } } } } #endif } TEST(Gfx, RegionAnd) { { nsRegion r(nsRect(20, 0, 20, 20)); r.OrWith(nsRect(0, 20, 40, 20)); nsRegion r2; r2.And(r, nsRect(0, 0, 5, 5)); EXPECT_FALSE(r.Contains(1, 1)); } { nsRegion r(nsRect(51, 2, 57, 5)); r.OrWith(nsRect(36, 7, 72, 4)); r.OrWith(nsRect(36, 11, 25, 1)); r.OrWith(nsRect(69, 12, 6, 4)); r.OrWith(nsRect(37, 16, 54, 2)); r.OrWith(nsRect(37, 18, 82, 2)); r.OrWith(nsRect(10, 20, 109, 3)); r.OrWith(nsRect(1, 23, 136, 21)); r.OrWith(nsRect(1, 44, 148, 2)); r.OrWith(nsRect(1, 46, 176, 31)); r.OrWith(nsRect(6, 77, 171, 1)); r.OrWith(nsRect(5, 78, 172, 30)); r.OrWith(nsRect(5, 108, 165, 45)); r.OrWith(nsRect(5, 153, 61, 5)); r.OrWith(nsRect(72, 153, 98, 5)); r.OrWith(nsRect(38, 158, 25, 4)); r.OrWith(nsRect(72, 158, 98, 4)); r.OrWith(nsRect(58, 162, 5, 8)); r.OrWith(nsRect(72, 162, 98, 8)); r.OrWith(nsRect(72, 170, 98, 5)); nsRegion r2; r.And(r2, nsRect(18, 78, 53, 45)); } #ifdef REGION_RANDOM_STRESS_TESTS const uint32_t TestIterations = 100000; const uint32_t RectsPerTest = 50; const uint32_t pointsTested = 100; { nsRect rectsSet1[RectsPerTest]; nsRect rectsSet2[RectsPerTest]; for (uint32_t i = 0; i < TestIterations; i++) { nsRegion r1; nsRegion r2; for (uint32_t n = 0; n < RectsPerTest; n++) { rectsSet1[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); rectsSet2[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); r1.OrWith(rectsSet1[n]); r2.OrWith(rectsSet1[n]); } nsRegion r3; r3.And(r1, r2); for (uint32_t n = 0; n < pointsTested; n++) { nsPoint p(rand() % 200, rand() % 200); if (r1.Contains(p.x, p.y) && r2.Contains(p.x, p.y)) { EXPECT_TRUE(r3.Contains(p.x, p.y)); } else { EXPECT_FALSE(r3.Contains(p.x, p.y)); } } } } { nsRect rectsSet[RectsPerTest]; nsRect testRect; for (uint32_t i = 0; i < TestIterations; i++) { nsRegion r; for (uint32_t n = 0; n < RectsPerTest; n++) { rectsSet[n].SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); } for (uint32_t n = 0; n < RectsPerTest; n++) { r.OrWith(rectsSet[n]); } testRect.SetRect(rand() % 100, rand() % 100, rand() % 99 + 1, rand() % 99 + 1); nsRegion r2; r2.And(r, testRect); for (uint32_t n = 0; n < pointsTested; n++) { nsPoint p(rand() % 200, rand() % 200); if (r.Contains(p.x, p.y) && testRect.Contains(p.x, p.y)) { EXPECT_TRUE(r2.Contains(p.x, p.y)); } else { EXPECT_FALSE(r2.Contains(p.x, p.y)); } } } } #endif } TEST(Gfx, RegionSimplify) { { // ensure simplify works on a single rect nsRegion r(nsRect(0, 100, 200, 100)); r.SimplifyOutwardByArea(100 * 100); nsRegion result(nsRect(0, 100, 200, 100)); EXPECT_TRUE(r.IsEqual(result)) << "regions not the same"; } { // the rectangles will be merged nsRegion r(nsRect(0, 100, 200, 100)); r.Or(r, nsRect(0, 200, 300, 200)); r.SimplifyOutwardByArea(100 * 100); nsRegion result(nsRect(0, 100, 300, 300)); EXPECT_TRUE(r.IsEqual(result)) << "regions not merged"; } { // two rectangle on the first span // one on the second nsRegion r(nsRect(0, 100, 200, 100)); r.Or(r, nsRect(0, 200, 300, 200)); r.Or(r, nsRect(250, 100, 50, 100)); EXPECT_TRUE(r.GetNumRects() == 3) << "wrong number of rects"; r.SimplifyOutwardByArea(100 * 100); nsRegion result(nsRect(0, 100, 300, 300)); EXPECT_TRUE(r.IsEqual(result)) << "regions not merged"; } { // the rectangles will be merged nsRegion r(nsRect(0, 100, 200, 100)); r.Or(r, nsRect(0, 200, 300, 200)); r.Or(r, nsRect(250, 100, 50, 100)); r.Sub(r, nsRect(200, 200, 40, 200)); EXPECT_TRUE(r.GetNumRects() == 4) << "wrong number of rects"; r.SimplifyOutwardByArea(100 * 100); nsRegion result(nsRect(0, 100, 300, 300)); result.Sub(result, nsRect(200, 100, 40, 300)); EXPECT_TRUE(r.IsEqual(result)) << "regions not merged"; } { // three spans of rectangles nsRegion r(nsRect(0, 100, 200, 100)); r.Or(r, nsRect(0, 200, 300, 200)); r.Or(r, nsRect(250, 100, 50, 50)); r.Sub(r, nsRect(200, 200, 40, 200)); r.SimplifyOutwardByArea(100 * 100); nsRegion result(nsRect(0, 100, 300, 300)); result.Sub(result, nsRect(200, 100, 40, 300)); EXPECT_TRUE(r.IsEqual(result)) << "regions not merged"; } { // three spans of rectangles and an unmerged rectangle nsRegion r(nsRect(0, 100, 200, 100)); r.Or(r, nsRect(0, 200, 300, 200)); r.Or(r, nsRect(250, 100, 50, 50)); r.Sub(r, nsRect(200, 200, 40, 200)); r.Or(r, nsRect(250, 900, 150, 50)); r.SimplifyOutwardByArea(100 * 100); nsRegion result(nsRect(0, 100, 300, 300)); result.Sub(result, nsRect(200, 100, 40, 300)); result.Or(result, nsRect(250, 900, 150, 50)); EXPECT_TRUE(r.IsEqual(result)) << "regions not merged"; } { // unmerged regions nsRegion r(nsRect(0, 100, 200, 100)); r.Or(r, nsRect(0, 200, 300, 200)); r.SimplifyOutwardByArea(100); nsRegion result(nsRect(0, 100, 200, 100)); result.Or(result, nsRect(0, 200, 300, 200)); EXPECT_TRUE(r.IsEqual(result)) << "regions not merged"; } { // empty region // just make sure this doesn't crash. nsRegion r; r.SimplifyOutwardByArea(100); } } TEST(Gfx, RegionContains) { { // ensure Contains works on a simple region nsRegion r(nsRect(0, 0, 100, 100)); EXPECT_TRUE(r.Contains(0, 0)); EXPECT_TRUE(r.Contains(0, 99)); EXPECT_TRUE(r.Contains(99, 0)); EXPECT_TRUE(r.Contains(99, 99)); EXPECT_FALSE(r.Contains(-1, 50)); EXPECT_FALSE(r.Contains(100, 50)); EXPECT_FALSE(r.Contains(50, -1)); EXPECT_FALSE(r.Contains(50, 100)); EXPECT_TRUE(r.Contains(nsRect(0, 0, 100, 100))); EXPECT_TRUE(r.Contains(nsRect(99, 99, 1, 1))); EXPECT_FALSE(r.Contains(nsRect(100, 100, 1, 1))); EXPECT_FALSE(r.Contains(nsRect(100, 100, 0, 0))); } { // empty regions contain nothing nsRegion r(nsRect(100, 100, 0, 0)); EXPECT_FALSE(r.Contains(0, 0)); EXPECT_FALSE(r.Contains(100, 100)); EXPECT_FALSE(r.Contains(nsRect(100, 100, 0, 0))); EXPECT_FALSE(r.Contains(nsRect(100, 100, 1, 1))); } { // complex region contain tests // The region looks like this, with two squares that overlap. // (hard to do accurately with ASCII art) // +------+ // | | // | +--+ // | | // +--+ | // | | // +------+ nsRegion r(nsRect(0, 0, 100, 100)); r.OrWith(nsRect(50, 50, 100, 100)); EXPECT_TRUE(r.Contains(0, 0)); EXPECT_TRUE(r.Contains(99, 99)); EXPECT_TRUE(r.Contains(50, 100)); EXPECT_TRUE(r.Contains(100, 50)); EXPECT_TRUE(r.Contains(149, 149)); EXPECT_FALSE(r.Contains(49, 100)); EXPECT_FALSE(r.Contains(100, 49)); EXPECT_FALSE(r.Contains(150, 150)); EXPECT_TRUE(r.Contains(nsRect(100, 100, 1, 1))); EXPECT_FALSE(r.Contains(nsRect(49, 99, 2, 2))); } { // region with a hole nsRegion r(nsRect(0, 0, 100, 100)); r.SubOut(nsRect(40, 40, 10, 10)); EXPECT_TRUE(r.Contains(0, 0)); EXPECT_TRUE(r.Contains(39, 39)); EXPECT_FALSE(r.Contains(40, 40)); EXPECT_FALSE(r.Contains(49, 49)); EXPECT_TRUE(r.Contains(50, 50)); EXPECT_FALSE(r.Contains(nsRect(40, 40, 10, 10))); EXPECT_FALSE(r.Contains(nsRect(39, 39, 2, 2))); } } #define DILATE_VALUE 0x88 #define REGION_VALUE 0xff struct RegionBitmap { RegionBitmap(unsigned char* bitmap, int width, int height) : bitmap(bitmap), width(width), height(height) {} void clear() { for (int y = 0; y < height; y++) { for (int x = 0; x < width; x++) { bitmap[x + y * width] = 0; } } } void set(nsRegion& region) { clear(); for (auto iter = region.RectIter(); !iter.Done(); iter.Next()) { const nsRect& r = iter.Get(); for (int y = r.Y(); y < r.YMost(); y++) { for (int x = r.X(); x < r.XMost(); x++) { bitmap[x + y * width] = REGION_VALUE; } } } } void dilate() { for (int y = 0; y < height; y++) { for (int x = 0; x < width; x++) { if (bitmap[x + y * width] == REGION_VALUE) { for (int yn = std::max(y - 1, 0); yn <= std::min(y + 1, height - 1); yn++) { for (int xn = std::max(x - 1, 0); xn <= std::min(x + 1, width - 1); xn++) { if (bitmap[xn + yn * width] == 0) bitmap[xn + yn * width] = DILATE_VALUE; } } } } } } void compare(RegionBitmap& reference) { for (int y = 0; y < height; y++) { for (int x = 0; x < width; x++) { EXPECT_EQ(bitmap[x + y * width], reference.bitmap[x + y * width]); } } } unsigned char* bitmap; int width; int height; }; static void VisitEdge(void* closure, VisitSide side, int x1, int y1, int x2, int y2) { EXPECT_GE(x2, x1); RegionBitmap* visitor = static_cast(closure); unsigned char* bitmap = visitor->bitmap; const int width = visitor->width; if (side == VisitSide::TOP) { while (x1 != x2) { bitmap[x1 + (y1 - 1) * width] = DILATE_VALUE; x1++; } } else if (side == VisitSide::BOTTOM) { while (x1 != x2) { bitmap[x1 + y1 * width] = DILATE_VALUE; x1++; } } else if (side == VisitSide::LEFT) { while (y1 != y2) { bitmap[x1 - 1 + y1 * width] = DILATE_VALUE; y1++; } } else if (side == VisitSide::RIGHT) { while (y1 != y2) { bitmap[x1 + y1 * width] = DILATE_VALUE; y1++; } } } static void TestVisit(nsRegion& r) { auto reference = mozilla::MakeUnique(600 * 600); auto result = mozilla::MakeUnique(600 * 600); RegionBitmap ref(reference.get(), 600, 600); RegionBitmap res(result.get(), 600, 600); ref.set(r); ref.dilate(); res.set(r); r.VisitEdges(VisitEdge, &res); res.compare(ref); } TEST(Gfx, RegionVisitEdges) { { // visit edges nsRegion r(nsRect(20, 20, 100, 100)); r.Or(r, nsRect(20, 120, 200, 100)); TestVisit(r); } { // two rects side by side - 1 pixel inbetween nsRegion r(nsRect(20, 20, 100, 100)); r.Or(r, nsRect(121, 20, 100, 100)); TestVisit(r); } { // two rects side by side - 2 pixels inbetween nsRegion r(nsRect(20, 20, 100, 100)); r.Or(r, nsRect(122, 20, 100, 100)); TestVisit(r); } { // only corner of the rects are touching nsRegion r(nsRect(20, 20, 100, 100)); r.Or(r, nsRect(120, 120, 100, 100)); TestVisit(r); } { // corners are 1 pixel away nsRegion r(nsRect(20, 20, 100, 100)); r.Or(r, nsRect(121, 120, 100, 100)); TestVisit(r); } { // vertically separated nsRegion r(nsRect(20, 20, 100, 100)); r.Or(r, nsRect(120, 125, 100, 100)); TestVisit(r); } { // not touching nsRegion r(nsRect(20, 20, 100, 100)); r.Or(r, nsRect(130, 120, 100, 100)); r.Or(r, nsRect(240, 20, 100, 100)); TestVisit(r); } { // rect with a hole in it nsRegion r(nsRect(20, 20, 100, 100)); r.Sub(r, nsRect(40, 40, 10, 10)); TestVisit(r); } { // left overs nsRegion r(nsRect(20, 20, 10, 10)); r.Or(r, nsRect(50, 20, 10, 10)); r.Or(r, nsRect(90, 20, 10, 10)); r.Or(r, nsRect(24, 30, 10, 10)); r.Or(r, nsRect(20, 40, 15, 10)); r.Or(r, nsRect(50, 40, 15, 10)); r.Or(r, nsRect(90, 40, 15, 10)); TestVisit(r); } { // vertically separated nsRegion r(nsRect(20, 20, 100, 100)); r.Or(r, nsRect(120, 125, 100, 100)); TestVisit(r); } { // two upper rects followed by a lower one // on the same line nsRegion r(nsRect(5, 5, 50, 50)); r.Or(r, nsRect(100, 5, 50, 50)); r.Or(r, nsRect(200, 50, 50, 50)); TestVisit(r); } { // bug 1130978. nsRegion r(nsRect(4, 1, 61, 49)); r.Or(r, nsRect(115, 1, 99, 49)); r.Or(r, nsRect(115, 49, 99, 1)); r.Or(r, nsRect(12, 50, 11, 5)); r.Or(r, nsRect(25, 50, 28, 5)); r.Or(r, nsRect(115, 50, 99, 5)); r.Or(r, nsRect(115, 55, 99, 12)); TestVisit(r); } } // The TiledRegion tests use nsIntRect / IntRegion because nsRect doesn't have // InflateToMultiple which is required by TiledRegion. TEST(Gfx, TiledRegionNoSimplification2Rects) { // Add two rectangles, both rectangles are completely inside // different tiles. nsIntRegion region; region.OrWith(nsIntRect(50, 50, 50, 50)); region.OrWith(nsIntRect(300, 50, 50, 50)); TiledIntRegion tiledRegion; tiledRegion.Add(nsIntRect(50, 50, 50, 50)); tiledRegion.Add(nsIntRect(300, 50, 50, 50)); // No simplification should have happened. EXPECT_TRUE(region.IsEqual(tiledRegion.GetRegion())); } TEST(Gfx, TiledRegionNoSimplification1Region) { // Add two rectangles, both rectangles are completely inside // different tiles. nsIntRegion region; region.OrWith(nsIntRect(50, 50, 50, 50)); region.OrWith(nsIntRect(300, 50, 50, 50)); TiledIntRegion tiledRegion; tiledRegion.Add(region); // No simplification should have happened. EXPECT_TRUE(region.IsEqual(tiledRegion.GetRegion())); } TEST(Gfx, TiledRegionWithSimplification3Rects) { // Add three rectangles. The first two rectangles are completely inside // different tiles, but the third rectangle intersects both tiles. TiledIntRegion tiledRegion; tiledRegion.Add(nsIntRect(50, 50, 50, 50)); tiledRegion.Add(nsIntRect(300, 50, 50, 50)); tiledRegion.Add(nsIntRect(250, 70, 10, 10)); // Both tiles should have simplified their rectangles, and those two // rectangles are adjacent to each other, so they just build up one rect. EXPECT_TRUE(tiledRegion.GetRegion().IsEqual(nsIntRect(50, 50, 300, 50))); } TEST(Gfx, TiledRegionWithSimplification1Region) { // Add three rectangles. The first two rectangles are completely inside // different tiles, but the third rectangle intersects both tiles. nsIntRegion region; region.OrWith(nsIntRect(50, 50, 50, 50)); region.OrWith(nsIntRect(300, 50, 50, 50)); region.OrWith(nsIntRect(250, 70, 10, 10)); TiledIntRegion tiledRegion; tiledRegion.Add(region); // Both tiles should have simplified their rectangles, and those two // rectangles are adjacent to each other, so they just build up one rect. EXPECT_TRUE(tiledRegion.GetRegion().IsEqual(nsIntRect(50, 50, 300, 50))); } TEST(Gfx, TiledRegionContains) { // Add three rectangles. The first two rectangles are completely inside // different tiles, but the third rectangle intersects both tiles. TiledIntRegion tiledRegion; tiledRegion.Add(nsIntRect(50, 50, 50, 50)); tiledRegion.Add(nsIntRect(300, 50, 50, 50)); tiledRegion.Add(nsIntRect(250, 70, 10, 10)); // Both tiles should have simplified their rectangles, and those two // rectangles are adjacent to each other, so they just build up one rect. EXPECT_TRUE(tiledRegion.Contains(nsIntRect(50, 50, 300, 50))); EXPECT_TRUE(tiledRegion.Contains(nsIntRect(50, 50, 50, 50))); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(50, 50, 301, 50))); } TEST(Gfx, TiledRegionIntersects) { // Add three rectangles. The first two rectangles are completely inside // different tiles, but the third rectangle intersects both tiles. TiledIntRegion tiledRegion; tiledRegion.Add(nsIntRect(50, 50, 50, 50)); tiledRegion.Add(nsIntRect(300, 50, 50, 50)); tiledRegion.Add(nsIntRect(250, 70, 10, 10)); // Both tiles should have simplified their rectangles, and those two // rectangles are adjacent to each other, so they just build up one rect. EXPECT_TRUE(tiledRegion.Intersects(nsIntRect(50, 50, 300, 50))); EXPECT_TRUE(tiledRegion.Intersects(nsIntRect(200, 10, 10, 50))); EXPECT_TRUE(tiledRegion.Intersects(nsIntRect(50, 50, 301, 50))); EXPECT_FALSE(tiledRegion.Intersects(nsIntRect(0, 0, 50, 500))); } TEST(Gfx, TiledRegionBoundaryConditions1) { TiledIntRegion tiledRegion; // This one works fine tiledRegion.Add(nsIntRegion(nsIntRect(INT_MIN, INT_MIN, 1, 1))); EXPECT_TRUE(tiledRegion.Contains(nsIntRect(INT_MIN, INT_MIN, 1, 1))); // This causes the tiledRegion.mBounds to overflow, so it is ignored tiledRegion.Add(nsIntRegion(nsIntRect(INT_MAX - 1, INT_MAX - 1, 1, 1))); // Verify that the tiledRegion contains only things we expect EXPECT_TRUE(tiledRegion.Contains(nsIntRect(INT_MIN, INT_MIN, 1, 1))); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(INT_MAX - 1, INT_MAX - 1, 1, 1))); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(0, 0, 1, 1))); } TEST(Gfx, TiledRegionBoundaryConditions2) { TiledIntRegion tiledRegion; // This one works fine tiledRegion.Add(nsIntRegion(nsIntRect(INT_MAX - 1, INT_MIN, 1, 1))); EXPECT_TRUE(tiledRegion.Contains(nsIntRect(INT_MAX - 1, INT_MIN, 1, 1))); // As with TiledRegionBoundaryConditions1, this overflows, so it is ignored tiledRegion.Add(nsIntRegion(nsIntRect(INT_MIN, INT_MAX - 1, 1, 1))); EXPECT_TRUE(tiledRegion.Contains(nsIntRect(INT_MAX - 1, INT_MIN, 1, 1))); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(INT_MIN, INT_MAX - 1, 1, 1))); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(0, 0, 1, 1))); } TEST(Gfx, TiledRegionBigRects) { TiledIntRegion tiledRegion; // Super wide region, forces simplification into bounds mode tiledRegion.Add(nsIntRegion(nsIntRect(INT_MIN, INT_MIN, INT_MAX, 100))); EXPECT_TRUE(tiledRegion.Contains(nsIntRect(INT_MIN, INT_MIN, 1, 1))); EXPECT_TRUE(tiledRegion.Contains(nsIntRect(-2, INT_MIN + 99, 1, 1))); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(-2, INT_MIN + 100, 1, 1))); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(-1, INT_MIN + 99, 1, 1))); // Add another rect, verify that simplification caused the entire bounds // to expand by a lot more. tiledRegion.Add(nsIntRegion(nsIntRect(INT_MIN, INT_MIN + 200, 1, 1))); EXPECT_TRUE(tiledRegion.Contains(nsIntRect(-2, INT_MIN + 100, 1, 1))); EXPECT_TRUE(tiledRegion.Contains(nsIntRect(-2, INT_MIN + 200, 1, 1))); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(-2, INT_MIN + 201, 1, 1))); } TEST(Gfx, TiledRegionBoundaryOverflow) { TiledIntRegion tiledRegion; tiledRegion.Add(nsIntRegion(nsIntRect(100, 100, 1, 1))); EXPECT_TRUE(tiledRegion.Contains(nsIntRect(100, 100, 1, 1))); // The next region is invalid, so it gets ignored tiledRegion.Add(nsIntRegion(nsIntRect(INT_MAX, INT_MAX, 1, 1))); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(INT_MAX, INT_MAX, 1, 1))); // Try that again as a rect, it will also get ignored tiledRegion.Add(nsIntRect(INT_MAX, INT_MAX, 1, 1)); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(INT_MAX, INT_MAX, 1, 1))); // Try with a bigger overflowing rect tiledRegion.Add(nsIntRect(INT_MAX, INT_MAX, 500, 500)); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(INT_MIN, INT_MIN, 10, 10))); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(INT_MAX, INT_MAX, 100, 100))); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(0, 0, 1, 1))); } TEST(Gfx, TiledRegionNegativeRect) { TiledIntRegion tiledRegion; // The next region is invalid, so it gets ignored tiledRegion.Add(nsIntRegion(nsIntRect(0, 0, -500, -500))); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(-50, -50, 1, 1))); // Rects with negative widths/heights are treated as empty and ignored tiledRegion.Add(nsIntRect(0, 0, -500, -500)); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(-1, -1, 1, 1))); EXPECT_FALSE(tiledRegion.Contains(nsIntRect(0, 0, 1, 1))); // Empty rects are always contained EXPECT_TRUE(tiledRegion.Contains(nsIntRect(0, 0, -1, -1))); EXPECT_TRUE(tiledRegion.Contains(nsIntRect(100, 100, -1, -1))); }