/* * Copyright 2012 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "include/core/SkString.h" #include "tests/PathOpsDebug.h" #include "tests/PathOpsExtendedTest.h" #include "tests/PathOpsThreadedCommon.h" #include // four rects, of four sizes // for 3 smaller sizes, tall, wide // top upper mid lower bottom aligned (3 bits, 5 values) // same with x (3 bits, 5 values) // not included, square, tall, wide (2 bits) // cw or ccw (1 bit) static int loopNo = 6; static std::atomic gRectsTestNo{0}; static void testPathOpsRectsMain(PathOpsThreadState* data) { SkASSERT(data); const SkPathFillType fts[] = { SkPathFillType::kWinding, SkPathFillType::kEvenOdd }; PathOpsThreadState& state = *data; SkString pathStr; for (int a = 0 ; a < 6; ++a) { for (int b = a + 1 ; b < 7; ++b) { for (int c = 0 ; c < 6; ++c) { for (int d = c + 1 ; d < 7; ++d) { for (auto e : fts) { for (auto f : fts) { SkPath pathA, pathB; pathA.setFillType((SkPathFillType) e); pathA.addRect(SkIntToScalar(state.fA), SkIntToScalar(state.fA), SkIntToScalar(state.fB), SkIntToScalar(state.fB), SkPathDirection::kCW); pathA.addRect(SkIntToScalar(state.fC), SkIntToScalar(state.fC), SkIntToScalar(state.fD), SkIntToScalar(state.fD), SkPathDirection::kCW); pathA.close(); pathB.setFillType((SkPathFillType) f); pathB.addRect(SkIntToScalar(a), SkIntToScalar(a), SkIntToScalar(b), SkIntToScalar(b), SkPathDirection::kCW); pathB.addRect(SkIntToScalar(c), SkIntToScalar(c), SkIntToScalar(d), SkIntToScalar(d), SkPathDirection::kCW); pathB.close(); for (int op = 0 ; op <= kXOR_SkPathOp; ++op) { if (state.fReporter->verbose()) { pathStr.printf( "static void rects%d(skiatest::Reporter* reporter," "const char* filename) {\n", loopNo); pathStr.appendf(" SkPath path, pathB;"); pathStr.appendf(" path.setFillType(SkPathFillType::k%s);\n", e == SkPathFillType::kWinding ? "Winding" : e == SkPathFillType::kEvenOdd ? "EvenOdd" : "?UNDEFINED"); pathStr.appendf(" path.addRect(%d, %d, %d, %d," " SkPathDirection::kCW);\n", state.fA, state.fA, state.fB, state.fB); pathStr.appendf(" path.addRect(%d, %d, %d, %d," " SkPathDirection::kCW);\n", state.fC, state.fC, state.fD, state.fD); pathStr.appendf(" pathB.setFillType(SkPathFillType::k%s);\n", f == SkPathFillType::kWinding ? "Winding" : f == SkPathFillType::kEvenOdd ? "EvenOdd" : "?UNDEFINED"); pathStr.appendf(" pathB.addRect(%d, %d, %d, %d," " SkPathDirection::kCW);\n", a, a, b, b); pathStr.appendf(" pathB.addRect(%d, %d, %d, %d," " SkPathDirection::kCW);\n", c, c, d, d); pathStr.appendf(" testPathOp(reporter, path, pathB, %s, filename);\n", SkPathOpsDebug::OpStr((SkPathOp) op)); pathStr.appendf("}\n\n"); state.outputProgress(pathStr.c_str(), (SkPathOp) op); } SkString testName; testName.printf("thread_rects%d", ++gRectsTestNo); if (!testPathOp(state.fReporter, pathA, pathB, (SkPathOp) op, testName.c_str())) { if (state.fReporter->verbose()) { ++loopNo; goto skipToNext; } } if (PathOpsDebug::gCheckForDuplicateNames) return; } } } skipToNext: ; } } } } } DEF_TEST(PathOpsRectsThreaded, reporter) { initializeTests(reporter, "testOp"); PathOpsThreadedTestRunner testRunner(reporter); for (int a = 0; a < 6; ++a) { // outermost for (int b = a + 1; b < 7; ++b) { for (int c = 0 ; c < 6; ++c) { for (int d = c + 1; d < 7; ++d) { *testRunner.fRunnables.append() = new PathOpsThreadedRunnable( &testPathOpsRectsMain, a, b, c, d, &testRunner); } } if (!reporter->allowExtendedTest()) goto finish; } } finish: testRunner.render(); } static std::atomic gFastTestNo{0}; static void testPathOpsFastMain(PathOpsThreadState* data) { SkASSERT(data); const SkPathFillType fts[] = { SkPathFillType::kWinding, SkPathFillType::kEvenOdd, SkPathFillType::kInverseWinding, SkPathFillType::kInverseEvenOdd }; PathOpsThreadState& state = *data; SkString pathStr; int step = data->fReporter->allowExtendedTest() ? 2 : 5; for (bool a : { false, true } ) { for (bool b : { false, true } ) { for (int c = 0; c < 6; c += step) { for (int d = 0; d < 6; d += step) { for (auto e : fts) { for (auto f : fts) { SkPath pathA, pathB; pathA.setFillType(e); if (a) { pathA.addRect(SkIntToScalar(state.fA), SkIntToScalar(state.fA), SkIntToScalar(state.fB) + c, SkIntToScalar(state.fB), SkPathDirection::kCW); } pathA.close(); pathB.setFillType(f); if (b) { pathB.addRect(SkIntToScalar(state.fC), SkIntToScalar(state.fC), SkIntToScalar(state.fD) + d, SkIntToScalar(state.fD), SkPathDirection::kCW); } pathB.close(); const char* fillTypeStr[] = { "Winding", "EvenOdd", "InverseWinding", "InverseEvenOdd" }; for (int op = 0; op <= kXOR_SkPathOp; ++op) { if (state.fReporter->verbose()) { pathStr.printf( "static void fast%d(skiatest::Reporter* reporter," "const char* filename) {\n", loopNo); pathStr.appendf(" SkPath path, pathB;"); pathStr.appendf(" path.setFillType(SkPathFillType::k%s);\n", fillTypeStr[(int)e]); if (a) { pathStr.appendf(" path.addRect(%d, %d, %d, %d," " SkPathDirection::kCW);\n", state.fA, state.fA, state.fB + c, state.fB); } pathStr.appendf(" path.setFillType(SkPathFillType::k%s);\n", fillTypeStr[(int)f]); if (b) { pathStr.appendf(" path.addRect(%d, %d, %d, %d," " SkPathDirection::kCW);\n", state.fC, state.fC, state.fD + d, state.fD); } pathStr.appendf(" testPathOp(reporter, path, pathB, %s, filename);\n", SkPathOpsDebug::OpStr((SkPathOp) op)); pathStr.appendf("}\n\n"); state.outputProgress(pathStr.c_str(), (SkPathOp) op); } SkString testName; testName.printf("fast%d", ++gFastTestNo); if (!testPathOp(state.fReporter, pathA, pathB, (SkPathOp) op, testName.c_str())) { if (state.fReporter->verbose()) { ++loopNo; goto skipToNext; } } if (PathOpsDebug::gCheckForDuplicateNames) return; } } } skipToNext: ; } } } } } DEF_TEST(PathOpsFastThreaded, reporter) { initializeTests(reporter, "testOp"); PathOpsThreadedTestRunner testRunner(reporter); int step = reporter->allowExtendedTest() ? 2 : 5; for (int a = 0; a < 6; a += step) { // outermost for (int b = a + 1; b < 7; b += step) { for (int c = 0 ; c < 6; c += step) { for (int d = c + 1; d < 7; d += step) { *testRunner.fRunnables.append() = new PathOpsThreadedRunnable( &testPathOpsFastMain, a, b, c, d, &testRunner); } } } } testRunner.render(); }