/* * Copyright 2020 Google LLC * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "src/gpu/ganesh/v1/ClipStack.h" #include "tests/Test.h" #include "include/core/SkColorSpace.h" #include "include/core/SkPath.h" #include "include/core/SkRRect.h" #include "include/core/SkRect.h" #include "include/core/SkRegion.h" #include "include/core/SkShader.h" #include "include/gpu/GrDirectContext.h" #include "src/core/SkMatrixProvider.h" #include "src/core/SkRRectPriv.h" #include "src/core/SkRectPriv.h" #include "src/gpu/ganesh/GrDirectContextPriv.h" #include "src/gpu/ganesh/GrProxyProvider.h" #include "src/gpu/ganesh/ops/GrDrawOp.h" #include "src/gpu/ganesh/v1/SurfaceDrawContext_v1.h" namespace { class TestCaseBuilder; class ElementsBuilder; enum class SavePolicy { kNever, kAtStart, kAtEnd, kBetweenEveryOp }; // TODO: We could add a RestorePolicy enum that tests different places to restore, but that would // make defining the test expectations and order independence more cumbersome. class TestCase { public: using ClipStack = skgpu::v1::ClipStack; // Provides fluent API to describe actual clip commands and expected clip elements: // TestCase test = TestCase::Build("example", deviceBounds) // .actual().rect(r, GrAA::kYes, SkClipOp::kIntersect) // .localToDevice(matrix) // .nonAA() // .difference() // .path(p1) // .path(p2) // .finishElements() // .expectedState(kDeviceRect) // .expectedBounds(r.roundOut()) // .expect().rect(r, GrAA::kYes, SkClipOp::kIntersect) // .finishElements() // .finishTest(); static TestCaseBuilder Build(const char* name, const SkIRect& deviceBounds); void run(const std::vector& order, SavePolicy policy, skiatest::Reporter* reporter) const; const SkIRect& deviceBounds() const { return fDeviceBounds; } ClipStack::ClipState expectedState() const { return fExpectedState; } const std::vector& initialElements() const { return fElements; } const std::vector& expectedElements() const { return fExpectedElements; } private: friend class TestCaseBuilder; TestCase(SkString name, const SkIRect& deviceBounds, ClipStack::ClipState expectedState, std::vector actual, std::vector expected) : fName(name) , fElements(std::move(actual)) , fDeviceBounds(deviceBounds) , fExpectedElements(std::move(expected)) , fExpectedState(expectedState) {} SkString getTestName(const std::vector& order, SavePolicy policy) const; // This may be tighter than ClipStack::getConservativeBounds() because this always accounts // for difference ops, whereas ClipStack only sometimes can subtract the inner bounds for a // difference op. std::pair getOptimalBounds() const; SkString fName; // The input shapes+state to ClipStack std::vector fElements; SkIRect fDeviceBounds; // The expected output of iterating over the ClipStack after all fElements are added, although // order is not important std::vector fExpectedElements; ClipStack::ClipState fExpectedState; }; class ElementsBuilder { public: using ClipStack = skgpu::v1::ClipStack; // Update the default matrix, aa, and op state for elements that are added. ElementsBuilder& localToDevice(const SkMatrix& m) { fLocalToDevice = m; return *this; } ElementsBuilder& aa() { fAA = GrAA::kYes; return *this; } ElementsBuilder& nonAA() { fAA = GrAA::kNo; return *this; } ElementsBuilder& intersect() { fOp = SkClipOp::kIntersect; return *this; } ElementsBuilder& difference() { fOp = SkClipOp::kDifference; return *this; } // Add rect, rrect, or paths to the list of elements, possibly overriding the last set // matrix, aa, and op state. ElementsBuilder& rect(const SkRect& rect) { return this->rect(rect, fLocalToDevice, fAA, fOp); } ElementsBuilder& rect(const SkRect& rect, GrAA aa, SkClipOp op) { return this->rect(rect, fLocalToDevice, aa, op); } ElementsBuilder& rect(const SkRect& rect, const SkMatrix& m, GrAA aa, SkClipOp op) { fElements->push_back({GrShape(rect), m, op, aa}); return *this; } ElementsBuilder& rrect(const SkRRect& rrect) { return this->rrect(rrect, fLocalToDevice, fAA, fOp); } ElementsBuilder& rrect(const SkRRect& rrect, GrAA aa, SkClipOp op) { return this->rrect(rrect, fLocalToDevice, aa, op); } ElementsBuilder& rrect(const SkRRect& rrect, const SkMatrix& m, GrAA aa, SkClipOp op) { fElements->push_back({GrShape(rrect), m, op, aa}); return *this; } ElementsBuilder& path(const SkPath& path) { return this->path(path, fLocalToDevice, fAA, fOp); } ElementsBuilder& path(const SkPath& path, GrAA aa, SkClipOp op) { return this->path(path, fLocalToDevice, aa, op); } ElementsBuilder& path(const SkPath& path, const SkMatrix& m, GrAA aa, SkClipOp op) { fElements->push_back({GrShape(path), m, op, aa}); return *this; } // Finish and return the original test case builder TestCaseBuilder& finishElements() { return *fBuilder; } private: friend class TestCaseBuilder; ElementsBuilder(TestCaseBuilder* builder, std::vector* elements) : fBuilder(builder) , fElements(elements) {} SkMatrix fLocalToDevice = SkMatrix::I(); GrAA fAA = GrAA::kNo; SkClipOp fOp = SkClipOp::kIntersect; TestCaseBuilder* fBuilder; std::vector* fElements; }; class TestCaseBuilder { public: using ClipStack = skgpu::v1::ClipStack; ElementsBuilder actual() { return ElementsBuilder(this, &fActualElements); } ElementsBuilder expect() { return ElementsBuilder(this, &fExpectedElements); } TestCaseBuilder& expectActual() { fExpectedElements = fActualElements; return *this; } TestCaseBuilder& state(ClipStack::ClipState state) { fExpectedState = state; return *this; } TestCase finishTest() { TestCase test(fName, fDeviceBounds, fExpectedState, std::move(fActualElements), std::move(fExpectedElements)); fExpectedState = ClipStack::ClipState::kWideOpen; return test; } private: friend class TestCase; explicit TestCaseBuilder(const char* name, const SkIRect& deviceBounds) : fName(name) , fDeviceBounds(deviceBounds) , fExpectedState(ClipStack::ClipState::kWideOpen) {} SkString fName; SkIRect fDeviceBounds; ClipStack::ClipState fExpectedState; std::vector fActualElements; std::vector fExpectedElements; }; TestCaseBuilder TestCase::Build(const char* name, const SkIRect& deviceBounds) { return TestCaseBuilder(name, deviceBounds); } SkString TestCase::getTestName(const std::vector& order, SavePolicy policy) const { SkString name = fName; SkString policyName; switch(policy) { case SavePolicy::kNever: policyName = "never"; break; case SavePolicy::kAtStart: policyName = "start"; break; case SavePolicy::kAtEnd: policyName = "end"; break; case SavePolicy::kBetweenEveryOp: policyName = "between"; break; } name.appendf("(save %s, order [", policyName.c_str()); for (size_t i = 0; i < order.size(); ++i) { if (i > 0) { name.append(","); } name.appendf("%d", order[i]); } name.append("])"); return name; } std::pair TestCase::getOptimalBounds() const { if (fExpectedState == ClipStack::ClipState::kEmpty) { return {SkIRect::MakeEmpty(), true}; } bool expectOptimal = true; SkRegion region(fDeviceBounds); for (const ClipStack::Element& e : fExpectedElements) { bool intersect = (e.fOp == SkClipOp::kIntersect && !e.fShape.inverted()) || (e.fOp == SkClipOp::kDifference && e.fShape.inverted()); SkIRect elementBounds; SkRegion::Op op; if (intersect) { op = SkRegion::kIntersect_Op; expectOptimal &= e.fLocalToDevice.isIdentity(); elementBounds = GrClip::GetPixelIBounds(e.fLocalToDevice.mapRect(e.fShape.bounds()), e.fAA, GrClip::BoundsType::kExterior); } else { op = SkRegion::kDifference_Op; expectOptimal = false; if (e.fShape.isRect() && e.fLocalToDevice.isIdentity()) { elementBounds = GrClip::GetPixelIBounds(e.fShape.rect(), e.fAA, GrClip::BoundsType::kInterior); } else if (e.fShape.isRRect() && e.fLocalToDevice.isIdentity()) { elementBounds = GrClip::GetPixelIBounds(SkRRectPriv::InnerBounds(e.fShape.rrect()), e.fAA, GrClip::BoundsType::kInterior); } else { elementBounds = SkIRect::MakeEmpty(); } } region.op(SkRegion(elementBounds), op); } return {region.getBounds(), expectOptimal}; } static bool compare_elements(const skgpu::v1::ClipStack::Element& a, const skgpu::v1::ClipStack::Element& b) { if (a.fAA != b.fAA || a.fOp != b.fOp || a.fLocalToDevice != b.fLocalToDevice || a.fShape.type() != b.fShape.type()) { return false; } switch(a.fShape.type()) { case GrShape::Type::kRect: return a.fShape.rect() == b.fShape.rect(); case GrShape::Type::kRRect: return a.fShape.rrect() == b.fShape.rrect(); case GrShape::Type::kPath: // A path's points are never transformed, the only modification is fill type which does // not change the generation ID. For convex polygons, we check == so that more complex // test cases can be evaluated. return a.fShape.path().getGenerationID() == b.fShape.path().getGenerationID() || (a.fShape.convex() && a.fShape.segmentMask() == SkPathSegmentMask::kLine_SkPathSegmentMask && a.fShape.path() == b.fShape.path()); default: SkDEBUGFAIL("Shape type not handled by test case yet."); return false; } } void TestCase::run(const std::vector& order, SavePolicy policy, skiatest::Reporter* reporter) const { SkASSERT(fElements.size() == order.size()); SkMatrixProvider matrixProvider(SkMatrix::I()); ClipStack cs(fDeviceBounds, &matrixProvider, false); if (policy == SavePolicy::kAtStart) { cs.save(); } for (int i : order) { if (policy == SavePolicy::kBetweenEveryOp) { cs.save(); } const ClipStack::Element& e = fElements[i]; switch(e.fShape.type()) { case GrShape::Type::kRect: cs.clipRect(e.fLocalToDevice, e.fShape.rect(), e.fAA, e.fOp); break; case GrShape::Type::kRRect: cs.clipRRect(e.fLocalToDevice, e.fShape.rrect(), e.fAA, e.fOp); break; case GrShape::Type::kPath: cs.clipPath(e.fLocalToDevice, e.fShape.path(), e.fAA, e.fOp); break; default: SkDEBUGFAIL("Shape type not handled by test case yet."); } } if (policy == SavePolicy::kAtEnd) { cs.save(); } // Now validate SkString name = this->getTestName(order, policy); REPORTER_ASSERT(reporter, cs.clipState() == fExpectedState, "%s, clip state expected %d, actual %d", name.c_str(), (int) fExpectedState, (int) cs.clipState()); SkIRect actualBounds = cs.getConservativeBounds(); SkIRect optimalBounds; bool expectOptimal; std::tie(optimalBounds, expectOptimal) = this->getOptimalBounds(); if (expectOptimal) { REPORTER_ASSERT(reporter, actualBounds == optimalBounds, "%s, bounds expected [%d %d %d %d], actual [%d %d %d %d]", name.c_str(), optimalBounds.fLeft, optimalBounds.fTop, optimalBounds.fRight, optimalBounds.fBottom, actualBounds.fLeft, actualBounds.fTop, actualBounds.fRight, actualBounds.fBottom); } else { REPORTER_ASSERT(reporter, actualBounds.contains(optimalBounds), "%s, bounds are not conservative, optimal [%d %d %d %d], actual [%d %d %d %d]", name.c_str(), optimalBounds.fLeft, optimalBounds.fTop, optimalBounds.fRight, optimalBounds.fBottom, actualBounds.fLeft, actualBounds.fTop, actualBounds.fRight, actualBounds.fBottom); } size_t matchedElements = 0; for (const ClipStack::Element& a : cs) { bool found = false; for (const ClipStack::Element& e : fExpectedElements) { if (compare_elements(a, e)) { // shouldn't match multiple expected elements or it's a bad test case SkASSERT(!found); found = true; } } REPORTER_ASSERT(reporter, found, "%s, unexpected clip element in stack: shape %d, aa %d, op %d", name.c_str(), (int) a.fShape.type(), (int) a.fAA, (int) a.fOp); matchedElements += found ? 1 : 0; } REPORTER_ASSERT(reporter, matchedElements == fExpectedElements.size(), "%s, did not match all expected elements: expected %zu but matched only %zu", name.c_str(), fExpectedElements.size(), matchedElements); // Validate restoration behavior if (policy == SavePolicy::kAtEnd) { ClipStack::ClipState oldState = cs.clipState(); cs.restore(); REPORTER_ASSERT(reporter, cs.clipState() == oldState, "%s, restoring an empty save record should not change clip state: " "expected %d but got %d", name.c_str(), (int) oldState, (int) cs.clipState()); } else if (policy != SavePolicy::kNever) { int restoreCount = policy == SavePolicy::kAtStart ? 1 : (int) order.size(); for (int i = 0; i < restoreCount; ++i) { cs.restore(); } // Should be wide open if everything is restored to base state REPORTER_ASSERT(reporter, cs.clipState() == ClipStack::ClipState::kWideOpen, "%s, restore should make stack become wide-open, not %d", name.c_str(), (int) cs.clipState()); } } // All clip operations are commutative so applying actual elements in every possible order should // always produce the same set of expected elements. static void run_test_case(skiatest::Reporter* r, const TestCase& test) { int n = (int) test.initialElements().size(); std::vector order(n); std::vector stack(n); // Initial order sequence and zeroed stack for (int i = 0; i < n; ++i) { order[i] = i; stack[i] = 0; } auto runTest = [&]() { static const SavePolicy kPolicies[] = { SavePolicy::kNever, SavePolicy::kAtStart, SavePolicy::kAtEnd, SavePolicy::kBetweenEveryOp }; for (auto policy : kPolicies) { test.run(order, policy, r); } }; // Heap's algorithm (non-recursive) to generate every permutation over the test case's elements // https://en.wikipedia.org/wiki/Heap%27s_algorithm runTest(); static constexpr int kMaxRuns = 720; // Don't run more than 6! configurations, even if n > 6 int testRuns = 1; int i = 0; while (i < n && testRuns < kMaxRuns) { if (stack[i] < i) { using std::swap; if (i % 2 == 0) { swap(order[0], order[i]); } else { swap(order[stack[i]], order[i]); } runTest(); stack[i]++; i = 0; testRuns++; } else { stack[i] = 0; ++i; } } } static SkPath make_octagon(const SkRect& r, SkScalar lr, SkScalar tb) { SkPath p; p.moveTo(r.fLeft + lr, r.fTop); p.lineTo(r.fRight - lr, r.fTop); p.lineTo(r.fRight, r.fTop + tb); p.lineTo(r.fRight, r.fBottom - tb); p.lineTo(r.fRight - lr, r.fBottom); p.lineTo(r.fLeft + lr, r.fBottom); p.lineTo(r.fLeft, r.fBottom - tb); p.lineTo(r.fLeft, r.fTop + tb); p.close(); return p; } static SkPath make_octagon(const SkRect& r) { SkScalar lr = 0.3f * r.width(); SkScalar tb = 0.3f * r.height(); return make_octagon(r, lr, tb); } static constexpr SkIRect kDeviceBounds = {0, 0, 100, 100}; class NoOp : public GrDrawOp { public: static NoOp* Get() { static NoOp gNoOp; return &gNoOp; } private: DEFINE_OP_CLASS_ID NoOp() : GrDrawOp(ClassID()) {} const char* name() const override { return "NoOp"; } GrProcessorSet::Analysis finalize(const GrCaps&, const GrAppliedClip*, GrClampType) override { return GrProcessorSet::EmptySetAnalysis(); } void onPrePrepare(GrRecordingContext*, const GrSurfaceProxyView&, GrAppliedClip*, const GrDstProxyView&, GrXferBarrierFlags, GrLoadOp) override {} void onPrepare(GrOpFlushState*) override {} void onExecute(GrOpFlushState*, const SkRect&) override {} }; } // anonymous namespace /////////////////////////////////////////////////////////////////////////////// // These tests use the TestCase infrastructure to define clip stacks and // associated expectations. // Tests that the initialized state of the clip stack is wide-open DEF_TEST(ClipStack_InitialState, r) { run_test_case(r, TestCase::Build("initial-state", SkIRect::MakeWH(100, 100)).finishTest()); } // Tests that intersection of rects combine to a single element when they have the same AA type, // or are pixel-aligned. DEF_TEST(ClipStack_RectRectAACombine, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkRect pixelAligned = {0, 0, 10, 10}; SkRect fracRect1 = pixelAligned.makeOffset(5.3f, 3.7f); SkRect fracRect2 = {fracRect1.fLeft + 0.75f * fracRect1.width(), fracRect1.fTop + 0.75f * fracRect1.height(), fracRect1.fRight, fracRect1.fBottom}; SkRect fracIntersect; SkAssertResult(fracIntersect.intersect(fracRect1, fracRect2)); SkRect alignedIntersect; SkAssertResult(alignedIntersect.intersect(pixelAligned, fracRect1)); // Both AA combine to one element run_test_case(r, TestCase::Build("aa", kDeviceBounds) .actual().aa().intersect() .rect(fracRect1).rect(fracRect2) .finishElements() .expect().aa().intersect().rect(fracIntersect).finishElements() .state(ClipState::kDeviceRect) .finishTest()); // Both non-AA combine to one element run_test_case(r, TestCase::Build("nonaa", kDeviceBounds) .actual().nonAA().intersect() .rect(fracRect1).rect(fracRect2) .finishElements() .expect().nonAA().intersect().rect(fracIntersect).finishElements() .state(ClipState::kDeviceRect) .finishTest()); // Pixel-aligned AA and non-AA combine run_test_case(r, TestCase::Build("aligned-aa+nonaa", kDeviceBounds) .actual().intersect() .aa().rect(pixelAligned).nonAA().rect(fracRect1) .finishElements() .expect().nonAA().intersect().rect(alignedIntersect).finishElements() .state(ClipState::kDeviceRect) .finishTest()); // AA and pixel-aligned non-AA combine run_test_case(r, TestCase::Build("aa+aligned-nonaa", kDeviceBounds) .actual().intersect() .aa().rect(fracRect1).nonAA().rect(pixelAligned) .finishElements() .expect().aa().intersect().rect(alignedIntersect).finishElements() .state(ClipState::kDeviceRect) .finishTest()); // Other mixed AA modes do not combine run_test_case(r, TestCase::Build("aa+nonaa", kDeviceBounds) .actual().intersect() .aa().rect(fracRect1).nonAA().rect(fracRect2) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); } // Tests that an intersection and a difference op do not combine, even if they would have if both // were intersection ops. DEF_TEST(ClipStack_DifferenceNoCombine, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkRect r1 = {15.f, 14.f, 23.22f, 58.2f}; SkRect r2 = r1.makeOffset(5.f, 8.f); SkASSERT(r1.intersects(r2)); run_test_case(r, TestCase::Build("no-combine", kDeviceBounds) .actual().aa().intersect().rect(r1) .difference().rect(r2) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); } // Tests that intersection of rects in the same coordinate space can still be combined, but do not // when the spaces differ. DEF_TEST(ClipStack_RectRectNonAxisAligned, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkRect pixelAligned = {0, 0, 10, 10}; SkRect fracRect1 = pixelAligned.makeOffset(5.3f, 3.7f); SkRect fracRect2 = {fracRect1.fLeft + 0.75f * fracRect1.width(), fracRect1.fTop + 0.75f * fracRect1.height(), fracRect1.fRight, fracRect1.fBottom}; SkRect fracIntersect; SkAssertResult(fracIntersect.intersect(fracRect1, fracRect2)); SkMatrix lm = SkMatrix::RotateDeg(45.f); // Both AA combine run_test_case(r, TestCase::Build("aa", kDeviceBounds) .actual().aa().intersect().localToDevice(lm) .rect(fracRect1).rect(fracRect2) .finishElements() .expect().aa().intersect().localToDevice(lm) .rect(fracIntersect).finishElements() .state(ClipState::kComplex) .finishTest()); // Both non-AA combine run_test_case(r, TestCase::Build("nonaa", kDeviceBounds) .actual().nonAA().intersect().localToDevice(lm) .rect(fracRect1).rect(fracRect2) .finishElements() .expect().nonAA().intersect().localToDevice(lm) .rect(fracIntersect).finishElements() .state(ClipState::kComplex) .finishTest()); // Integer-aligned coordinates under a local matrix with mixed AA don't combine, though run_test_case(r, TestCase::Build("local-aa", kDeviceBounds) .actual().intersect().localToDevice(lm) .aa().rect(pixelAligned).nonAA().rect(fracRect1) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); } // Tests that intersection of two round rects can simplify to a single round rect when they have // the same AA type. DEF_TEST(ClipStack_RRectRRectAACombine, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkRRect r1 = SkRRect::MakeRectXY(SkRect::MakeWH(12, 12), 2.f, 2.f); SkRRect r2 = r1.makeOffset(6.f, 6.f); SkRRect intersect = SkRRectPriv::ConservativeIntersect(r1, r2); SkASSERT(!intersect.isEmpty()); // Both AA combine run_test_case(r, TestCase::Build("aa", kDeviceBounds) .actual().aa().intersect() .rrect(r1).rrect(r2) .finishElements() .expect().aa().intersect().rrect(intersect).finishElements() .state(ClipState::kDeviceRRect) .finishTest()); // Both non-AA combine run_test_case(r, TestCase::Build("nonaa", kDeviceBounds) .actual().nonAA().intersect() .rrect(r1).rrect(r2) .finishElements() .expect().nonAA().intersect().rrect(intersect).finishElements() .state(ClipState::kDeviceRRect) .finishTest()); // Mixed do not combine run_test_case(r, TestCase::Build("aa+nonaa", kDeviceBounds) .actual().intersect() .aa().rrect(r1).nonAA().rrect(r2) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); // Same AA state can combine in the same local coordinate space SkMatrix lm = SkMatrix::RotateDeg(45.f); run_test_case(r, TestCase::Build("local-aa", kDeviceBounds) .actual().aa().intersect().localToDevice(lm) .rrect(r1).rrect(r2) .finishElements() .expect().aa().intersect().localToDevice(lm) .rrect(intersect).finishElements() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("local-nonaa", kDeviceBounds) .actual().nonAA().intersect().localToDevice(lm) .rrect(r1).rrect(r2) .finishElements() .expect().nonAA().intersect().localToDevice(lm) .rrect(intersect).finishElements() .state(ClipState::kComplex) .finishTest()); } // Tests that intersection of a round rect and rect can simplify to a new round rect or even a rect. DEF_TEST(ClipStack_RectRRectCombine, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkRRect rrect = SkRRect::MakeRectXY({0, 0, 10, 10}, 2.f, 2.f); SkRect cutTop = {-10, -10, 10, 4}; SkRect cutMid = {-10, 3, 10, 7}; // Rect + RRect becomes a round rect with some square corners SkVector cutCorners[4] = {{2.f, 2.f}, {2.f, 2.f}, {0, 0}, {0, 0}}; SkRRect cutRRect; cutRRect.setRectRadii({0, 0, 10, 4}, cutCorners); run_test_case(r, TestCase::Build("still-rrect", kDeviceBounds) .actual().intersect().aa().rrect(rrect).rect(cutTop).finishElements() .expect().intersect().aa().rrect(cutRRect).finishElements() .state(ClipState::kDeviceRRect) .finishTest()); // Rect + RRect becomes a rect SkRect cutRect = {0, 3, 10, 7}; run_test_case(r, TestCase::Build("to-rect", kDeviceBounds) .actual().intersect().aa().rrect(rrect).rect(cutMid).finishElements() .expect().intersect().aa().rect(cutRect).finishElements() .state(ClipState::kDeviceRect) .finishTest()); // But they can only combine when the intersecting shape is representable as a [r]rect. cutRect = {0, 0, 1.5f, 5.f}; run_test_case(r, TestCase::Build("no-combine", kDeviceBounds) .actual().intersect().aa().rrect(rrect).rect(cutRect).finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); } // Tests that a rect shape is actually pre-clipped to the device bounds DEF_TEST(ClipStack_RectDeviceClip, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkRect crossesDeviceEdge = {20.f, kDeviceBounds.fTop - 13.2f, kDeviceBounds.fRight + 15.5f, 30.f}; SkRect insideDevice = {20.f, kDeviceBounds.fTop, kDeviceBounds.fRight, 30.f}; run_test_case(r, TestCase::Build("device-aa-rect", kDeviceBounds) .actual().intersect().aa().rect(crossesDeviceEdge).finishElements() .expect().intersect().aa().rect(insideDevice).finishElements() .state(ClipState::kDeviceRect) .finishTest()); run_test_case(r, TestCase::Build("device-nonaa-rect", kDeviceBounds) .actual().intersect().nonAA().rect(crossesDeviceEdge).finishElements() .expect().intersect().nonAA().rect(insideDevice).finishElements() .state(ClipState::kDeviceRect) .finishTest()); } // Tests that other shapes' bounds are contained by the device bounds, even if their shape is not. DEF_TEST(ClipStack_ShapeDeviceBoundsClip, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkRect crossesDeviceEdge = {20.f, kDeviceBounds.fTop - 13.2f, kDeviceBounds.fRight + 15.5f, 30.f}; // RRect run_test_case(r, TestCase::Build("device-rrect", kDeviceBounds) .actual().intersect().aa() .rrect(SkRRect::MakeRectXY(crossesDeviceEdge, 4.f, 4.f)) .finishElements() .expectActual() .state(ClipState::kDeviceRRect) .finishTest()); // Path run_test_case(r, TestCase::Build("device-path", kDeviceBounds) .actual().intersect().aa() .path(make_octagon(crossesDeviceEdge)) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); } // Tests that a simplifiable path turns into a simpler element type DEF_TEST(ClipStack_PathSimplify, r) { using ClipState = skgpu::v1::ClipStack::ClipState; // Empty, point, and line paths -> empty SkPath empty; run_test_case(r, TestCase::Build("empty", kDeviceBounds) .actual().path(empty).finishElements() .state(ClipState::kEmpty) .finishTest()); SkPath point; point.moveTo({0.f, 0.f}); run_test_case(r, TestCase::Build("point", kDeviceBounds) .actual().path(point).finishElements() .state(ClipState::kEmpty) .finishTest()); SkPath line; line.moveTo({0.f, 0.f}); line.lineTo({10.f, 5.f}); run_test_case(r, TestCase::Build("line", kDeviceBounds) .actual().path(line).finishElements() .state(ClipState::kEmpty) .finishTest()); // Rect path -> rect element SkRect rect = {0.f, 2.f, 10.f, 15.4f}; SkPath rectPath; rectPath.addRect(rect); run_test_case(r, TestCase::Build("rect", kDeviceBounds) .actual().path(rectPath).finishElements() .expect().rect(rect).finishElements() .state(ClipState::kDeviceRect) .finishTest()); // Oval path -> rrect element SkPath ovalPath; ovalPath.addOval(rect); run_test_case(r, TestCase::Build("oval", kDeviceBounds) .actual().path(ovalPath).finishElements() .expect().rrect(SkRRect::MakeOval(rect)).finishElements() .state(ClipState::kDeviceRRect) .finishTest()); // RRect path -> rrect element SkRRect rrect = SkRRect::MakeRectXY(rect, 2.f, 2.f); SkPath rrectPath; rrectPath.addRRect(rrect); run_test_case(r, TestCase::Build("rrect", kDeviceBounds) .actual().path(rrectPath).finishElements() .expect().rrect(rrect).finishElements() .state(ClipState::kDeviceRRect) .finishTest()); } // Tests that repeated identical clip operations are idempotent DEF_TEST(ClipStack_RepeatElement, r) { using ClipState = skgpu::v1::ClipStack::ClipState; // Same rect SkRect rect = {5.3f, 62.f, 20.f, 85.f}; run_test_case(r, TestCase::Build("same-rects", kDeviceBounds) .actual().rect(rect).rect(rect).rect(rect).finishElements() .expect().rect(rect).finishElements() .state(ClipState::kDeviceRect) .finishTest()); SkMatrix lm; lm.setRotate(30.f, rect.centerX(), rect.centerY()); run_test_case(r, TestCase::Build("same-local-rects", kDeviceBounds) .actual().localToDevice(lm).rect(rect).rect(rect).rect(rect) .finishElements() .expect().localToDevice(lm).rect(rect).finishElements() .state(ClipState::kComplex) .finishTest()); // Same rrect SkRRect rrect = SkRRect::MakeRectXY(rect, 5.f, 2.5f); run_test_case(r, TestCase::Build("same-rrects", kDeviceBounds) .actual().rrect(rrect).rrect(rrect).rrect(rrect).finishElements() .expect().rrect(rrect).finishElements() .state(ClipState::kDeviceRRect) .finishTest()); run_test_case(r, TestCase::Build("same-local-rrects", kDeviceBounds) .actual().localToDevice(lm).rrect(rrect).rrect(rrect).rrect(rrect) .finishElements() .expect().localToDevice(lm).rrect(rrect).finishElements() .state(ClipState::kComplex) .finishTest()); // Same convex path, by == run_test_case(r, TestCase::Build("same-convex", kDeviceBounds) .actual().path(make_octagon(rect)).path(make_octagon(rect)) .finishElements() .expect().path(make_octagon(rect)).finishElements() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("same-local-convex", kDeviceBounds) .actual().localToDevice(lm) .path(make_octagon(rect)).path(make_octagon(rect)) .finishElements() .expect().localToDevice(lm).path(make_octagon(rect)) .finishElements() .state(ClipState::kComplex) .finishTest()); // Same complicated path by gen-id but not == SkPath path; // an hour glass path.moveTo({0.f, 0.f}); path.lineTo({20.f, 20.f}); path.lineTo({0.f, 20.f}); path.lineTo({20.f, 0.f}); path.close(); run_test_case(r, TestCase::Build("same-path", kDeviceBounds) .actual().path(path).path(path).path(path).finishElements() .expect().path(path).finishElements() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("same-local-path", kDeviceBounds) .actual().localToDevice(lm) .path(path).path(path).path(path).finishElements() .expect().localToDevice(lm).path(path) .finishElements() .state(ClipState::kComplex) .finishTest()); } // Tests that inverse-filled paths are canonicalized to a regular fill and a swapped clip op DEF_TEST(ClipStack_InverseFilledPath, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkRect rect = {0.f, 0.f, 16.f, 17.f}; SkPath rectPath; rectPath.addRect(rect); SkPath inverseRectPath = rectPath; inverseRectPath.toggleInverseFillType(); SkPath complexPath = make_octagon(rect); SkPath inverseComplexPath = complexPath; inverseComplexPath.toggleInverseFillType(); // Inverse filled rect + intersect -> diff rect run_test_case(r, TestCase::Build("inverse-rect-intersect", kDeviceBounds) .actual().aa().intersect().path(inverseRectPath).finishElements() .expect().aa().difference().rect(rect).finishElements() .state(ClipState::kComplex) .finishTest()); // Inverse filled rect + difference -> int. rect run_test_case(r, TestCase::Build("inverse-rect-difference", kDeviceBounds) .actual().aa().difference().path(inverseRectPath).finishElements() .expect().aa().intersect().rect(rect).finishElements() .state(ClipState::kDeviceRect) .finishTest()); // Inverse filled path + intersect -> diff path run_test_case(r, TestCase::Build("inverse-path-intersect", kDeviceBounds) .actual().aa().intersect().path(inverseComplexPath).finishElements() .expect().aa().difference().path(complexPath).finishElements() .state(ClipState::kComplex) .finishTest()); // Inverse filled path + difference -> int. path run_test_case(r, TestCase::Build("inverse-path-difference", kDeviceBounds) .actual().aa().difference().path(inverseComplexPath).finishElements() .expect().aa().intersect().path(complexPath).finishElements() .state(ClipState::kComplex) .finishTest()); } // Tests that clip operations that are offscreen either make the clip empty or stay wide open DEF_TEST(ClipStack_Offscreen, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkRect offscreenRect = {kDeviceBounds.fRight + 10.f, kDeviceBounds.fTop + 20.f, kDeviceBounds.fRight + 40.f, kDeviceBounds.fTop + 60.f}; SkASSERT(!offscreenRect.intersects(SkRect::Make(kDeviceBounds))); SkRRect offscreenRRect = SkRRect::MakeRectXY(offscreenRect, 5.f, 5.f); SkPath offscreenPath = make_octagon(offscreenRect); // Intersect -> empty run_test_case(r, TestCase::Build("intersect-combo", kDeviceBounds) .actual().aa().intersect() .rect(offscreenRect) .rrect(offscreenRRect) .path(offscreenPath) .finishElements() .state(ClipState::kEmpty) .finishTest()); run_test_case(r, TestCase::Build("intersect-rect", kDeviceBounds) .actual().aa().intersect() .rect(offscreenRect) .finishElements() .state(ClipState::kEmpty) .finishTest()); run_test_case(r, TestCase::Build("intersect-rrect", kDeviceBounds) .actual().aa().intersect() .rrect(offscreenRRect) .finishElements() .state(ClipState::kEmpty) .finishTest()); run_test_case(r, TestCase::Build("intersect-path", kDeviceBounds) .actual().aa().intersect() .path(offscreenPath) .finishElements() .state(ClipState::kEmpty) .finishTest()); // Difference -> wide open run_test_case(r, TestCase::Build("difference-combo", kDeviceBounds) .actual().aa().difference() .rect(offscreenRect) .rrect(offscreenRRect) .path(offscreenPath) .finishElements() .state(ClipState::kWideOpen) .finishTest()); run_test_case(r, TestCase::Build("difference-rect", kDeviceBounds) .actual().aa().difference() .rect(offscreenRect) .finishElements() .state(ClipState::kWideOpen) .finishTest()); run_test_case(r, TestCase::Build("difference-rrect", kDeviceBounds) .actual().aa().difference() .rrect(offscreenRRect) .finishElements() .state(ClipState::kWideOpen) .finishTest()); run_test_case(r, TestCase::Build("difference-path", kDeviceBounds) .actual().aa().difference() .path(offscreenPath) .finishElements() .state(ClipState::kWideOpen) .finishTest()); } // Tests that an empty shape updates the clip state directly without needing an element DEF_TEST(ClipStack_EmptyShape, r) { using ClipState = skgpu::v1::ClipStack::ClipState; // Intersect -> empty run_test_case(r, TestCase::Build("empty-intersect", kDeviceBounds) .actual().intersect().rect(SkRect::MakeEmpty()).finishElements() .state(ClipState::kEmpty) .finishTest()); // Difference -> no-op run_test_case(r, TestCase::Build("empty-difference", kDeviceBounds) .actual().difference().rect(SkRect::MakeEmpty()).finishElements() .state(ClipState::kWideOpen) .finishTest()); SkRRect rrect = SkRRect::MakeRectXY({4.f, 10.f, 16.f, 32.f}, 2.f, 2.f); run_test_case(r, TestCase::Build("noop-difference", kDeviceBounds) .actual().difference().rrect(rrect).rect(SkRect::MakeEmpty()) .finishElements() .expect().difference().rrect(rrect).finishElements() .state(ClipState::kComplex) .finishTest()); } // Tests that sufficiently large difference operations can shrink the conservative bounds DEF_TEST(ClipStack_DifferenceBounds, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkRect rightSide = {50.f, -10.f, 2.f * kDeviceBounds.fRight, kDeviceBounds.fBottom + 10.f}; SkRect clipped = rightSide; SkAssertResult(clipped.intersect(SkRect::Make(kDeviceBounds))); run_test_case(r, TestCase::Build("difference-cut", kDeviceBounds) .actual().nonAA().difference().rect(rightSide).finishElements() .expect().nonAA().difference().rect(clipped).finishElements() .state(ClipState::kComplex) .finishTest()); } // Tests that intersections can combine even if there's a difference operation in the middle DEF_TEST(ClipStack_NoDifferenceInterference, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkRect intR1 = {0.f, 0.f, 30.f, 30.f}; SkRect intR2 = {15.f, 15.f, 45.f, 45.f}; SkRect intCombo = {15.f, 15.f, 30.f, 30.f}; SkRect diff = {20.f, 6.f, 50.f, 50.f}; run_test_case(r, TestCase::Build("cross-diff-combine", kDeviceBounds) .actual().rect(intR1, GrAA::kYes, SkClipOp::kIntersect) .rect(diff, GrAA::kYes, SkClipOp::kDifference) .rect(intR2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .expect().rect(intCombo, GrAA::kYes, SkClipOp::kIntersect) .rect(diff, GrAA::kYes, SkClipOp::kDifference) .finishElements() .state(ClipState::kComplex) .finishTest()); } // Tests that multiple path operations are all recorded, but not otherwise consolidated DEF_TEST(ClipStack_MultiplePaths, r) { using ClipState = skgpu::v1::ClipStack::ClipState; // Chosen to be greater than the number of inline-allocated elements and save records of the // ClipStack so that we test heap allocation as well. static constexpr int kNumOps = 16; auto b = TestCase::Build("many-paths-difference", kDeviceBounds); SkRect d = {0.f, 0.f, 12.f, 12.f}; for (int i = 0; i < kNumOps; ++i) { b.actual().path(make_octagon(d), GrAA::kNo, SkClipOp::kDifference); d.offset(15.f, 0.f); if (d.fRight > kDeviceBounds.fRight) { d.fLeft = 0.f; d.fRight = 12.f; d.offset(0.f, 15.f); } } run_test_case(r, b.expectActual() .state(ClipState::kComplex) .finishTest()); b = TestCase::Build("many-paths-intersect", kDeviceBounds); d = {0.f, 0.f, 12.f, 12.f}; for (int i = 0; i < kNumOps; ++i) { b.actual().path(make_octagon(d), GrAA::kYes, SkClipOp::kIntersect); d.offset(0.01f, 0.01f); } run_test_case(r, b.expectActual() .state(ClipState::kComplex) .finishTest()); } // Tests that a single rect is treated as kDeviceRect state when it's axis-aligned and intersect. DEF_TEST(ClipStack_DeviceRect, r) { using ClipState = skgpu::v1::ClipStack::ClipState; // Axis-aligned + intersect -> kDeviceRect SkRect rect = {0, 0, 20, 20}; run_test_case(r, TestCase::Build("device-rect", kDeviceBounds) .actual().intersect().aa().rect(rect).finishElements() .expectActual() .state(ClipState::kDeviceRect) .finishTest()); // Not axis-aligned -> kComplex SkMatrix lm = SkMatrix::RotateDeg(15.f); run_test_case(r, TestCase::Build("unaligned-rect", kDeviceBounds) .actual().localToDevice(lm).intersect().aa().rect(rect) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); // Not intersect -> kComplex run_test_case(r, TestCase::Build("diff-rect", kDeviceBounds) .actual().difference().aa().rect(rect).finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); } // Tests that a single rrect is treated as kDeviceRRect state when it's axis-aligned and intersect. DEF_TEST(ClipStack_DeviceRRect, r) { using ClipState = skgpu::v1::ClipStack::ClipState; // Axis-aligned + intersect -> kDeviceRRect SkRect rect = {0, 0, 20, 20}; SkRRect rrect = SkRRect::MakeRectXY(rect, 5.f, 5.f); run_test_case(r, TestCase::Build("device-rrect", kDeviceBounds) .actual().intersect().aa().rrect(rrect).finishElements() .expectActual() .state(ClipState::kDeviceRRect) .finishTest()); // Not axis-aligned -> kComplex SkMatrix lm = SkMatrix::RotateDeg(15.f); run_test_case(r, TestCase::Build("unaligned-rrect", kDeviceBounds) .actual().localToDevice(lm).intersect().aa().rrect(rrect) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); // Not intersect -> kComplex run_test_case(r, TestCase::Build("diff-rrect", kDeviceBounds) .actual().difference().aa().rrect(rrect).finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); } // Tests that scale+translate matrices are pre-applied to rects and rrects, which also then allows // elements with different scale+translate matrices to be consolidated as if they were in the same // coordinate space. DEF_TEST(ClipStack_ScaleTranslate, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkMatrix lm = SkMatrix::Scale(2.f, 4.f); lm.postTranslate(15.5f, 14.3f); SkASSERT(lm.preservesAxisAlignment() && lm.isScaleTranslate()); // Rect -> matrix is applied up front SkRect rect = {0.f, 0.f, 10.f, 10.f}; run_test_case(r, TestCase::Build("st+rect", kDeviceBounds) .actual().rect(rect, lm, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .expect().rect(lm.mapRect(rect), GrAA::kYes, SkClipOp::kIntersect) .finishElements() .state(ClipState::kDeviceRect) .finishTest()); // RRect -> matrix is applied up front SkRRect localRRect = SkRRect::MakeRectXY(rect, 2.f, 2.f); SkRRect deviceRRect; SkAssertResult(localRRect.transform(lm, &deviceRRect)); run_test_case(r, TestCase::Build("st+rrect", kDeviceBounds) .actual().rrect(localRRect, lm, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .expect().rrect(deviceRRect, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .state(ClipState::kDeviceRRect) .finishTest()); // Path -> matrix is NOT applied run_test_case(r, TestCase::Build("st+path", kDeviceBounds) .actual().intersect().localToDevice(lm).path(make_octagon(rect)) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); } // Tests that rect-stays-rect matrices that are not scale+translate matrices are pre-applied. DEF_TEST(ClipStack_PreserveAxisAlignment, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkMatrix lm = SkMatrix::RotateDeg(90.f); lm.postTranslate(15.5f, 14.3f); SkASSERT(lm.preservesAxisAlignment() && !lm.isScaleTranslate()); // Rect -> matrix is applied up front SkRect rect = {0.f, 0.f, 10.f, 10.f}; run_test_case(r, TestCase::Build("r90+rect", kDeviceBounds) .actual().rect(rect, lm, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .expect().rect(lm.mapRect(rect), GrAA::kYes, SkClipOp::kIntersect) .finishElements() .state(ClipState::kDeviceRect) .finishTest()); // RRect -> matrix is applied up front SkRRect localRRect = SkRRect::MakeRectXY(rect, 2.f, 2.f); SkRRect deviceRRect; SkAssertResult(localRRect.transform(lm, &deviceRRect)); run_test_case(r, TestCase::Build("r90+rrect", kDeviceBounds) .actual().rrect(localRRect, lm, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .expect().rrect(deviceRRect, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .state(ClipState::kDeviceRRect) .finishTest()); // Path -> matrix is NOT applied run_test_case(r, TestCase::Build("r90+path", kDeviceBounds) .actual().intersect().localToDevice(lm).path(make_octagon(rect)) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); } // Tests that a convex path element can contain a rect or round rect, allowing the stack to be // simplified DEF_TEST(ClipStack_ConvexPathContains, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkRect rect = {15.f, 15.f, 30.f, 30.f}; SkRRect rrect = SkRRect::MakeRectXY(rect, 5.f, 5.f); SkPath bigPath = make_octagon(rect.makeOutset(10.f, 10.f), 5.f, 5.f); // Intersect -> path element isn't kept run_test_case(r, TestCase::Build("convex+rect-intersect", kDeviceBounds) .actual().aa().intersect().rect(rect).path(bigPath).finishElements() .expect().aa().intersect().rect(rect).finishElements() .state(ClipState::kDeviceRect) .finishTest()); run_test_case(r, TestCase::Build("convex+rrect-intersect", kDeviceBounds) .actual().aa().intersect().rrect(rrect).path(bigPath).finishElements() .expect().aa().intersect().rrect(rrect).finishElements() .state(ClipState::kDeviceRRect) .finishTest()); // Difference -> path element is the only one left run_test_case(r, TestCase::Build("convex+rect-difference", kDeviceBounds) .actual().aa().difference().rect(rect).path(bigPath).finishElements() .expect().aa().difference().path(bigPath).finishElements() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("convex+rrect-difference", kDeviceBounds) .actual().aa().difference().rrect(rrect).path(bigPath) .finishElements() .expect().aa().difference().path(bigPath).finishElements() .state(ClipState::kComplex) .finishTest()); // Intersect small shape + difference big path -> empty run_test_case(r, TestCase::Build("convex-diff+rect-int", kDeviceBounds) .actual().aa().intersect().rect(rect) .difference().path(bigPath).finishElements() .state(ClipState::kEmpty) .finishTest()); run_test_case(r, TestCase::Build("convex-diff+rrect-int", kDeviceBounds) .actual().aa().intersect().rrect(rrect) .difference().path(bigPath).finishElements() .state(ClipState::kEmpty) .finishTest()); // Diff small shape + intersect big path -> both run_test_case(r, TestCase::Build("convex-int+rect-diff", kDeviceBounds) .actual().aa().intersect().path(bigPath).difference().rect(rect) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("convex-int+rrect-diff", kDeviceBounds) .actual().aa().intersect().path(bigPath).difference().rrect(rrect) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); } // Tests that rects/rrects in different coordinate spaces can be consolidated when one is fully // contained by the other. DEF_TEST(ClipStack_NonAxisAlignedContains, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkMatrix lm1 = SkMatrix::RotateDeg(45.f); SkRect bigR = {-20.f, -20.f, 20.f, 20.f}; SkRRect bigRR = SkRRect::MakeRectXY(bigR, 1.f, 1.f); SkMatrix lm2 = SkMatrix::RotateDeg(-45.f); SkRect smR = {-10.f, -10.f, 10.f, 10.f}; SkRRect smRR = SkRRect::MakeRectXY(smR, 1.f, 1.f); // I+I should select the smaller 2nd shape (r2 or rr2) run_test_case(r, TestCase::Build("rect-rect-ii", kDeviceBounds) .actual().rect(bigR, lm1, GrAA::kYes, SkClipOp::kIntersect) .rect(smR, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .expect().rect(smR, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("rrect-rrect-ii", kDeviceBounds) .actual().rrect(bigRR, lm1, GrAA::kYes, SkClipOp::kIntersect) .rrect(smRR, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .expect().rrect(smRR, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("rect-rrect-ii", kDeviceBounds) .actual().rect(bigR, lm1, GrAA::kYes, SkClipOp::kIntersect) .rrect(smRR, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .expect().rrect(smRR, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("rrect-rect-ii", kDeviceBounds) .actual().rrect(bigRR, lm1, GrAA::kYes, SkClipOp::kIntersect) .rect(smR, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .expect().rect(smR, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .state(ClipState::kComplex) .finishTest()); // D+D should select the larger shape (r1 or rr1) run_test_case(r, TestCase::Build("rect-rect-dd", kDeviceBounds) .actual().rect(bigR, lm1, GrAA::kYes, SkClipOp::kDifference) .rect(smR, lm2, GrAA::kYes, SkClipOp::kDifference) .finishElements() .expect().rect(bigR, lm1, GrAA::kYes, SkClipOp::kDifference) .finishElements() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("rrect-rrect-dd", kDeviceBounds) .actual().rrect(bigRR, lm1, GrAA::kYes, SkClipOp::kDifference) .rrect(smRR, lm2, GrAA::kYes, SkClipOp::kDifference) .finishElements() .expect().rrect(bigRR, lm1, GrAA::kYes, SkClipOp::kDifference) .finishElements() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("rect-rrect-dd", kDeviceBounds) .actual().rect(bigR, lm1, GrAA::kYes, SkClipOp::kDifference) .rrect(smRR, lm2, GrAA::kYes, SkClipOp::kDifference) .finishElements() .expect().rect(bigR, lm1, GrAA::kYes, SkClipOp::kDifference) .finishElements() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("rrect-rect-dd", kDeviceBounds) .actual().rrect(bigRR, lm1, GrAA::kYes, SkClipOp::kDifference) .rect(smR, lm2, GrAA::kYes, SkClipOp::kDifference) .finishElements() .expect().rrect(bigRR, lm1, GrAA::kYes, SkClipOp::kDifference) .finishElements() .state(ClipState::kComplex) .finishTest()); // D(1)+I(2) should result in empty run_test_case(r, TestCase::Build("rectD-rectI", kDeviceBounds) .actual().rect(bigR, lm1, GrAA::kYes, SkClipOp::kDifference) .rect(smR, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .state(ClipState::kEmpty) .finishTest()); run_test_case(r, TestCase::Build("rrectD-rrectI", kDeviceBounds) .actual().rrect(bigRR, lm1, GrAA::kYes, SkClipOp::kDifference) .rrect(smRR, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .state(ClipState::kEmpty) .finishTest()); run_test_case(r, TestCase::Build("rectD-rrectI", kDeviceBounds) .actual().rect(bigR, lm1, GrAA::kYes, SkClipOp::kDifference) .rrect(smRR, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .state(ClipState::kEmpty) .finishTest()); run_test_case(r, TestCase::Build("rrectD-rectI", kDeviceBounds) .actual().rrect(bigRR, lm1, GrAA::kYes, SkClipOp::kDifference) .rect(smR, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .state(ClipState::kEmpty) .finishTest()); // I(1)+D(2) should result in both shapes run_test_case(r, TestCase::Build("rectI+rectD", kDeviceBounds) .actual().rect(bigR, lm1, GrAA::kYes, SkClipOp::kIntersect) .rect(smR, lm2, GrAA::kYes, SkClipOp::kDifference) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("rrectI+rrectD", kDeviceBounds) .actual().rrect(bigRR, lm1, GrAA::kYes, SkClipOp::kIntersect) .rrect(smRR, lm2, GrAA::kYes, SkClipOp::kDifference) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("rrectI+rectD", kDeviceBounds) .actual().rrect(bigRR, lm1, GrAA::kYes, SkClipOp::kIntersect) .rect(smR, lm2, GrAA::kYes, SkClipOp::kDifference) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("rectI+rrectD", kDeviceBounds) .actual().rect(bigR, lm1, GrAA::kYes, SkClipOp::kIntersect) .rrect(smRR, lm2, GrAA::kYes, SkClipOp::kDifference) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); } // Tests that shapes with mixed AA state that contain each other can still be consolidated, // unless they are too close to the edge and non-AA snapping can't be predicted DEF_TEST(ClipStack_MixedAAContains, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkMatrix lm1 = SkMatrix::RotateDeg(45.f); SkRect r1 = {-20.f, -20.f, 20.f, 20.f}; SkMatrix lm2 = SkMatrix::RotateDeg(-45.f); SkRect r2Safe = {-10.f, -10.f, 10.f, 10.f}; SkRect r2Unsafe = {-19.5f, -19.5f, 19.5f, 19.5f}; // Non-AA sufficiently inside AA element can discard the outer AA element run_test_case(r, TestCase::Build("mixed-outeraa-combine", kDeviceBounds) .actual().rect(r1, lm1, GrAA::kYes, SkClipOp::kIntersect) .rect(r2Safe, lm2, GrAA::kNo, SkClipOp::kIntersect) .finishElements() .expect().rect(r2Safe, lm2, GrAA::kNo, SkClipOp::kIntersect) .finishElements() .state(ClipState::kComplex) .finishTest()); // Vice versa run_test_case(r, TestCase::Build("mixed-inneraa-combine", kDeviceBounds) .actual().rect(r1, lm1, GrAA::kNo, SkClipOp::kIntersect) .rect(r2Safe, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .expect().rect(r2Safe, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .state(ClipState::kComplex) .finishTest()); // Non-AA too close to AA edges keeps both run_test_case(r, TestCase::Build("mixed-outeraa-nocombine", kDeviceBounds) .actual().rect(r1, lm1, GrAA::kYes, SkClipOp::kIntersect) .rect(r2Unsafe, lm2, GrAA::kNo, SkClipOp::kIntersect) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); run_test_case(r, TestCase::Build("mixed-inneraa-nocombine", kDeviceBounds) .actual().rect(r1, lm1, GrAA::kNo, SkClipOp::kIntersect) .rect(r2Unsafe, lm2, GrAA::kYes, SkClipOp::kIntersect) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); } // Tests that a shape that contains the device bounds updates the clip state directly DEF_TEST(ClipStack_ShapeContainsDevice, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkRect rect = SkRect::Make(kDeviceBounds).makeOutset(10.f, 10.f); SkRRect rrect = SkRRect::MakeRectXY(rect, 10.f, 10.f); SkPath convex = make_octagon(rect, 10.f, 10.f); // Intersect -> no-op run_test_case(r, TestCase::Build("rect-intersect", kDeviceBounds) .actual().intersect().rect(rect).finishElements() .state(ClipState::kWideOpen) .finishTest()); run_test_case(r, TestCase::Build("rrect-intersect", kDeviceBounds) .actual().intersect().rrect(rrect).finishElements() .state(ClipState::kWideOpen) .finishTest()); run_test_case(r, TestCase::Build("convex-intersect", kDeviceBounds) .actual().intersect().path(convex).finishElements() .state(ClipState::kWideOpen) .finishTest()); // Difference -> empty run_test_case(r, TestCase::Build("rect-difference", kDeviceBounds) .actual().difference().rect(rect).finishElements() .state(ClipState::kEmpty) .finishTest()); run_test_case(r, TestCase::Build("rrect-difference", kDeviceBounds) .actual().difference().rrect(rrect).finishElements() .state(ClipState::kEmpty) .finishTest()); run_test_case(r, TestCase::Build("convex-difference", kDeviceBounds) .actual().difference().path(convex).finishElements() .state(ClipState::kEmpty) .finishTest()); } // Tests that shapes that do not overlap make for an empty clip (when intersecting), pick just the // intersecting op (when mixed), or are all kept (when diff'ing). DEF_TEST(ClipStack_DisjointShapes, r) { using ClipState = skgpu::v1::ClipStack::ClipState; SkRect rt = {10.f, 10.f, 20.f, 20.f}; SkRRect rr = SkRRect::MakeOval(rt.makeOffset({20.f, 0.f})); SkPath p = make_octagon(rt.makeOffset({0.f, 20.f})); // I+I run_test_case(r, TestCase::Build("iii", kDeviceBounds) .actual().aa().intersect().rect(rt).rrect(rr).path(p).finishElements() .state(ClipState::kEmpty) .finishTest()); // D+D run_test_case(r, TestCase::Build("ddd", kDeviceBounds) .actual().nonAA().difference().rect(rt).rrect(rr).path(p) .finishElements() .expectActual() .state(ClipState::kComplex) .finishTest()); // I+D from rect run_test_case(r, TestCase::Build("idd", kDeviceBounds) .actual().aa().intersect().rect(rt) .nonAA().difference().rrect(rr).path(p) .finishElements() .expect().aa().intersect().rect(rt).finishElements() .state(ClipState::kDeviceRect) .finishTest()); // I+D from rrect run_test_case(r, TestCase::Build("did", kDeviceBounds) .actual().aa().intersect().rrect(rr) .nonAA().difference().rect(rt).path(p) .finishElements() .expect().aa().intersect().rrect(rr).finishElements() .state(ClipState::kDeviceRRect) .finishTest()); // I+D from path run_test_case(r, TestCase::Build("ddi", kDeviceBounds) .actual().aa().intersect().path(p) .nonAA().difference().rect(rt).rrect(rr) .finishElements() .expect().aa().intersect().path(p).finishElements() .state(ClipState::kComplex) .finishTest()); } DEF_TEST(ClipStack_ComplexClip, reporter) { using ClipStack = skgpu::v1::ClipStack; static constexpr float kN = 10.f; static constexpr float kR = kN / 3.f; // 4 rectangles that overlap by kN x 2kN (horiz), 2kN x kN (vert), or kN x kN (diagonal) static const SkRect kTL = {0.f, 0.f, 2.f * kN, 2.f * kN}; static const SkRect kTR = {kN, 0.f, 3.f * kN, 2.f * kN}; static const SkRect kBL = {0.f, kN, 2.f * kN, 3.f * kN}; static const SkRect kBR = {kN, kN, 3.f * kN, 3.f * kN}; enum ShapeType { kRect, kRRect, kConvex }; SkRect rects[] = { kTL, kTR, kBL, kBR }; for (ShapeType type : { kRect, kRRect, kConvex }) { for (int opBits = 6; opBits < 16; ++opBits) { SkString name; name.appendf("complex-%d-%d", (int) type, opBits); SkRect expectedRectIntersection = SkRect::Make(kDeviceBounds); SkRRect expectedRRectIntersection = SkRRect::MakeRect(expectedRectIntersection); auto b = TestCase::Build(name.c_str(), kDeviceBounds); for (int i = 0; i < 4; ++i) { SkClipOp op = (opBits & (1 << i)) ? SkClipOp::kIntersect : SkClipOp::kDifference; switch(type) { case kRect: { SkRect r = rects[i]; if (op == SkClipOp::kDifference) { // Shrink the rect for difference ops, otherwise in the rect testcase // any difference op would remove the intersection of the other ops // given how the rects are defined, and that's just not interesting. r.inset(kR, kR); } b.actual().rect(r, GrAA::kYes, op); if (op == SkClipOp::kIntersect) { SkAssertResult(expectedRectIntersection.intersect(r)); } else { b.expect().rect(r, GrAA::kYes, SkClipOp::kDifference); } break; } case kRRect: { SkRRect rrect = SkRRect::MakeRectXY(rects[i], kR, kR); b.actual().rrect(rrect, GrAA::kYes, op); if (op == SkClipOp::kIntersect) { expectedRRectIntersection = SkRRectPriv::ConservativeIntersect( expectedRRectIntersection, rrect); SkASSERT(!expectedRRectIntersection.isEmpty()); } else { b.expect().rrect(rrect, GrAA::kYes, SkClipOp::kDifference); } break; } case kConvex: b.actual().path(make_octagon(rects[i], kR, kR), GrAA::kYes, op); // NOTE: We don't set any expectations here, since convex just calls // expectActual() at the end. break; } } // The expectations differ depending on the shape type ClipStack::ClipState state = ClipStack::ClipState::kComplex; if (type == kConvex) { // The simplest case is when the paths cannot be combined together, so we expect // the actual elements to be unmodified (both intersect and difference). b.expectActual(); } else if (opBits) { // All intersection ops were pre-computed into expectedR[R]ectIntersection // - difference ops already added in the for loop if (type == kRect) { SkASSERT(expectedRectIntersection != SkRect::Make(kDeviceBounds) && !expectedRectIntersection.isEmpty()); b.expect().rect(expectedRectIntersection, GrAA::kYes, SkClipOp::kIntersect); if (opBits == 0xf) { state = ClipStack::ClipState::kDeviceRect; } } else { SkASSERT(expectedRRectIntersection != SkRRect::MakeRect(SkRect::Make(kDeviceBounds)) && !expectedRRectIntersection.isEmpty()); b.expect().rrect(expectedRRectIntersection, GrAA::kYes, SkClipOp::kIntersect); if (opBits == 0xf) { state = ClipStack::ClipState::kDeviceRRect; } } } run_test_case(reporter, b.state(state).finishTest()); } } } // /////////////////////////////////////////////////////////////////////////////// // // These tests do not use the TestCase infrastructure and manipulate a // // ClipStack directly. // Tests that replaceClip() works as expected across save/restores DEF_TEST(ClipStack_ReplaceClip, r) { using ClipStack = skgpu::v1::ClipStack; ClipStack cs(kDeviceBounds, nullptr, false); SkRRect rrect = SkRRect::MakeRectXY({15.f, 12.25f, 40.3f, 23.5f}, 4.f, 6.f); cs.clipRRect(SkMatrix::I(), rrect, GrAA::kYes, SkClipOp::kIntersect); SkIRect replace = {50, 25, 75, 40}; // Is disjoint from the rrect element cs.save(); cs.replaceClip(replace); REPORTER_ASSERT(r, cs.clipState() == ClipStack::ClipState::kDeviceRect, "Clip did not become a device rect"); REPORTER_ASSERT(r, cs.getConservativeBounds() == replace, "Unexpected replaced clip bounds"); const ClipStack::Element& replaceElement = *cs.begin(); REPORTER_ASSERT(r, replaceElement.fShape.rect() == SkRect::Make(replace) && replaceElement.fAA == GrAA::kNo && replaceElement.fOp == SkClipOp::kIntersect && replaceElement.fLocalToDevice == SkMatrix::I(), "Unexpected replace element state"); // Restore should undo the replaced clip and bring back the rrect cs.restore(); REPORTER_ASSERT(r, cs.clipState() == ClipStack::ClipState::kDeviceRRect, "Unexpected state after restore, not kDeviceRRect"); const ClipStack::Element& rrectElem = *cs.begin(); REPORTER_ASSERT(r, rrectElem.fShape.rrect() == rrect && rrectElem.fAA == GrAA::kYes && rrectElem.fOp == SkClipOp::kIntersect && rrectElem.fLocalToDevice == SkMatrix::I(), "RRect element state not restored properly after replace clip undone"); } // Try to overflow the number of allowed window rects (see skbug.com/10989) DEF_TEST(ClipStack_DiffRects, r) { using ClipStack = skgpu::v1::ClipStack; using SurfaceDrawContext = skgpu::v1::SurfaceDrawContext; GrMockOptions options; options.fMaxWindowRectangles = 8; SkMatrixProvider matrixProvider = SkMatrix::I(); sk_sp context = GrDirectContext::MakeMock(&options); std::unique_ptr sdc = SurfaceDrawContext::Make( context.get(), GrColorType::kRGBA_8888, SkColorSpace::MakeSRGB(), SkBackingFit::kExact, kDeviceBounds.size(), SkSurfaceProps(), /*label=*/{}); ClipStack cs(kDeviceBounds, &matrixProvider, false); cs.save(); for (int y = 0; y < 10; ++y) { for (int x = 0; x < 10; ++x) { cs.clipRect(SkMatrix::I(), SkRect::MakeXYWH(10*x+1, 10*y+1, 8, 8), GrAA::kNo, SkClipOp::kDifference); } } GrAppliedClip out(kDeviceBounds.size()); SkRect drawBounds = SkRect::Make(kDeviceBounds); GrClip::Effect effect = cs.apply(context.get(), sdc.get(), NoOp::Get(), GrAAType::kCoverage, &out, &drawBounds); REPORTER_ASSERT(r, effect == GrClip::Effect::kClipped); REPORTER_ASSERT(r, out.windowRectsState().numWindows() == 8); cs.restore(); } // Tests that when a stack is forced to always be AA, non-AA elements become AA DEF_TEST(ClipStack_ForceAA, r) { using ClipStack = skgpu::v1::ClipStack; ClipStack cs(kDeviceBounds, nullptr, true); // AA will remain AA SkRect aaRect = {0.25f, 12.43f, 25.2f, 23.f}; cs.clipRect(SkMatrix::I(), aaRect, GrAA::kYes, SkClipOp::kIntersect); // Non-AA will become AA SkPath nonAAPath = make_octagon({2.f, 10.f, 16.f, 20.f}); cs.clipPath(SkMatrix::I(), nonAAPath, GrAA::kNo, SkClipOp::kIntersect); // Non-AA rects remain non-AA so they can be applied as a scissor SkRect nonAARect = {4.5f, 5.f, 17.25f, 18.23f}; cs.clipRect(SkMatrix::I(), nonAARect, GrAA::kNo, SkClipOp::kIntersect); // The stack reports elements newest first, but the non-AA rect op was combined in place with // the first aa rect, so we should see nonAAPath as AA, and then the intersection of rects. auto elements = cs.begin(); const ClipStack::Element& nonAARectElement = *elements; REPORTER_ASSERT(r, nonAARectElement.fShape.isRect(), "Expected rect element"); REPORTER_ASSERT(r, nonAARectElement.fAA == GrAA::kNo, "Axis-aligned non-AA rect ignores forceAA"); REPORTER_ASSERT(r, nonAARectElement.fShape.rect() == nonAARect, "Mixed AA rects should not combine"); ++elements; const ClipStack::Element& aaPathElement = *elements; REPORTER_ASSERT(r, aaPathElement.fShape.isPath(), "Expected path element"); REPORTER_ASSERT(r, aaPathElement.fShape.path() == nonAAPath, "Wrong path element"); REPORTER_ASSERT(r, aaPathElement.fAA == GrAA::kYes, "Path element not promoted to AA"); ++elements; const ClipStack::Element& aaRectElement = *elements; REPORTER_ASSERT(r, aaRectElement.fShape.isRect(), "Expected rect element"); REPORTER_ASSERT(r, aaRectElement.fShape.rect() == aaRect, "Mixed AA rects should not combine"); REPORTER_ASSERT(r, aaRectElement.fAA == GrAA::kYes, "Rect element stays AA"); ++elements; REPORTER_ASSERT(r, !(elements != cs.end()), "Expected only three clip elements"); } // Tests preApply works as expected for device rects, rrects, and reports clipped-out, etc. as // expected. DEF_TEST(ClipStack_PreApply, r) { using ClipStack = skgpu::v1::ClipStack; ClipStack cs(kDeviceBounds, nullptr, false); // Offscreen is kClippedOut GrClip::PreClipResult result = cs.preApply({-10.f, -10.f, -1.f, -1.f}, GrAA::kYes); REPORTER_ASSERT(r, result.fEffect == GrClip::Effect::kClippedOut, "Offscreen draw is kClippedOut"); // Intersecting screen with wide-open clip is kUnclipped result = cs.preApply({-10.f, -10.f, 10.f, 10.f}, GrAA::kYes); REPORTER_ASSERT(r, result.fEffect == GrClip::Effect::kUnclipped, "Wide open screen intersection is still kUnclipped"); // Empty clip is clipped out cs.save(); cs.clipRect(SkMatrix::I(), SkRect::MakeEmpty(), GrAA::kNo, SkClipOp::kIntersect); result = cs.preApply({0.f, 0.f, 20.f, 20.f}, GrAA::kYes); REPORTER_ASSERT(r, result.fEffect == GrClip::Effect::kClippedOut, "Empty clip stack preApplies as kClippedOut"); cs.restore(); // Contained inside clip is kUnclipped (using rrect for the outer clip element since paths // don't support an inner bounds and anything complex is otherwise skipped in preApply). SkRect rect = {10.f, 10.f, 40.f, 40.f}; SkRRect bigRRect = SkRRect::MakeRectXY(rect.makeOutset(5.f, 5.f), 5.f, 5.f); cs.save(); cs.clipRRect(SkMatrix::I(), bigRRect, GrAA::kYes, SkClipOp::kIntersect); result = cs.preApply(rect, GrAA::kYes); REPORTER_ASSERT(r, result.fEffect == GrClip::Effect::kUnclipped, "Draw contained within clip is kUnclipped"); // Disjoint from clip (but still on screen) is kClippedOut result = cs.preApply({50.f, 50.f, 60.f, 60.f}, GrAA::kYes); REPORTER_ASSERT(r, result.fEffect == GrClip::Effect::kClippedOut, "Draw not intersecting clip is kClippedOut"); cs.restore(); // Intersecting clip is kClipped for complex shape cs.save(); SkPath path = make_octagon(rect.makeOutset(5.f, 5.f), 5.f, 5.f); cs.clipPath(SkMatrix::I(), path, GrAA::kYes, SkClipOp::kIntersect); result = cs.preApply(path.getBounds(), GrAA::kNo); REPORTER_ASSERT(r, result.fEffect == GrClip::Effect::kClipped && !result.fIsRRect, "Draw with complex clip is kClipped, but is not an rrect"); cs.restore(); // Intersecting clip is kDeviceRect for axis-aligned rect clip cs.save(); cs.clipRect(SkMatrix::I(), rect, GrAA::kYes, SkClipOp::kIntersect); result = cs.preApply(rect.makeOffset(2.f, 2.f), GrAA::kNo); REPORTER_ASSERT(r, result.fEffect == GrClip::Effect::kClipped && result.fAA == GrAA::kYes && result.fIsRRect && result.fRRect == SkRRect::MakeRect(rect), "kDeviceRect clip stack should be reported by preApply"); cs.restore(); // Intersecting clip is kDeviceRRect for axis-aligned rrect clip cs.save(); SkRRect clipRRect = SkRRect::MakeRectXY(rect, 5.f, 5.f); cs.clipRRect(SkMatrix::I(), clipRRect, GrAA::kYes, SkClipOp::kIntersect); result = cs.preApply(rect.makeOffset(2.f, 2.f), GrAA::kNo); REPORTER_ASSERT(r, result.fEffect == GrClip::Effect::kClipped && result.fAA == GrAA::kYes && result.fIsRRect && result.fRRect == clipRRect, "kDeviceRRect clip stack should be reported by preApply"); cs.restore(); } // Tests the clip shader entry point DEF_TEST(ClipStack_Shader, r) { using ClipStack = skgpu::v1::ClipStack; using SurfaceDrawContext = skgpu::v1::SurfaceDrawContext; sk_sp shader = SkShaders::Color({0.f, 0.f, 0.f, 0.5f}, nullptr); SkMatrixProvider matrixProvider = SkMatrix::I(); sk_sp context = GrDirectContext::MakeMock(nullptr); std::unique_ptr sdc = SurfaceDrawContext::Make( context.get(), GrColorType::kRGBA_8888, SkColorSpace::MakeSRGB(), SkBackingFit::kExact, kDeviceBounds.size(), SkSurfaceProps(), /*label=*/{}); ClipStack cs(kDeviceBounds, &matrixProvider, false); cs.save(); cs.clipShader(shader); REPORTER_ASSERT(r, cs.clipState() == ClipStack::ClipState::kComplex, "A clip shader should be reported as a complex clip"); GrAppliedClip out(kDeviceBounds.size()); SkRect drawBounds = {10.f, 11.f, 16.f, 32.f}; GrClip::Effect effect = cs.apply(context.get(), sdc.get(), NoOp::Get(), GrAAType::kCoverage, &out, &drawBounds); REPORTER_ASSERT(r, effect == GrClip::Effect::kClipped, "apply() should return kClipped for a clip shader"); REPORTER_ASSERT(r, out.hasCoverageFragmentProcessor(), "apply() should have converted clip shader to a coverage FP"); GrAppliedClip out2(kDeviceBounds.size()); drawBounds = {-15.f, -10.f, -1.f, 10.f}; // offscreen effect = cs.apply(context.get(), sdc.get(), NoOp::Get(), GrAAType::kCoverage, &out2, &drawBounds); REPORTER_ASSERT(r, effect == GrClip::Effect::kClippedOut, "apply() should still discard offscreen draws with a clip shader"); cs.restore(); REPORTER_ASSERT(r, cs.clipState() == ClipStack::ClipState::kWideOpen, "restore() should get rid of the clip shader"); // Adding a clip shader on top of a device rect clip should prevent preApply from reporting // it as a device rect cs.clipRect(SkMatrix::I(), {10, 15, 30, 30}, GrAA::kNo, SkClipOp::kIntersect); SkASSERT(cs.clipState() == ClipStack::ClipState::kDeviceRect); // test precondition cs.clipShader(shader); GrClip::PreClipResult result = cs.preApply(SkRect::Make(kDeviceBounds), GrAA::kYes); REPORTER_ASSERT(r, result.fEffect == GrClip::Effect::kClipped && !result.fIsRRect, "A clip shader should not produce a device rect from preApply"); } // Tests apply() under simple circumstances, that don't require actual rendering of masks, or // atlases. This lets us define the test regularly instead of a GPU-only test. // - This is not exhaustive and is challenging to unit test, so apply() is predominantly tested by // the GMs instead. DEF_TEST(ClipStack_SimpleApply, r) { using ClipStack = skgpu::v1::ClipStack; using SurfaceDrawContext = skgpu::v1::SurfaceDrawContext; SkMatrixProvider matrixProvider = SkMatrix::I(); sk_sp context = GrDirectContext::MakeMock(nullptr); std::unique_ptr sdc = SurfaceDrawContext::Make( context.get(), GrColorType::kRGBA_8888, SkColorSpace::MakeSRGB(), SkBackingFit::kExact, kDeviceBounds.size(), SkSurfaceProps(), /*label=*/{}); ClipStack cs(kDeviceBounds, &matrixProvider, false); // Offscreen draw is kClippedOut { SkRect drawBounds = {-15.f, -15.f, -1.f, -1.f}; GrAppliedClip out(kDeviceBounds.size()); GrClip::Effect effect = cs.apply(context.get(), sdc.get(), NoOp::Get(), GrAAType::kCoverage, &out, &drawBounds); REPORTER_ASSERT(r, effect == GrClip::Effect::kClippedOut, "Offscreen draw is clipped out"); } // Draw contained in clip is kUnclipped { SkRect drawBounds = {15.4f, 16.3f, 26.f, 32.f}; cs.save(); cs.clipPath(SkMatrix::I(), make_octagon(drawBounds.makeOutset(5.f, 5.f), 5.f, 5.f), GrAA::kYes, SkClipOp::kIntersect); GrAppliedClip out(kDeviceBounds.size()); GrClip::Effect effect = cs.apply(context.get(), sdc.get(), NoOp::Get(), GrAAType::kCoverage, &out, &drawBounds); REPORTER_ASSERT(r, effect == GrClip::Effect::kUnclipped, "Draw inside clip is unclipped"); cs.restore(); } // Draw bounds are cropped to device space before checking contains { SkRect clipRect = {kDeviceBounds.fRight - 20.f, 10.f, kDeviceBounds.fRight, 20.f}; SkRect drawRect = clipRect.makeOffset(10.f, 0.f); cs.save(); cs.clipRect(SkMatrix::I(), clipRect, GrAA::kNo, SkClipOp::kIntersect); GrAppliedClip out(kDeviceBounds.size()); GrClip::Effect effect = cs.apply(context.get(), sdc.get(), NoOp::Get(), GrAAType::kCoverage, &out, &drawRect); REPORTER_ASSERT(r, SkRect::Make(kDeviceBounds).contains(drawRect), "Draw rect should be clipped to device rect"); REPORTER_ASSERT(r, effect == GrClip::Effect::kUnclipped, "After device clipping, this should be detected as contained within clip"); cs.restore(); } // Non-AA device rect intersect is just a scissor { SkRect clipRect = {15.3f, 17.23f, 30.2f, 50.8f}; SkRect drawRect = clipRect.makeOutset(10.f, 10.f); SkIRect expectedScissor = clipRect.round(); cs.save(); cs.clipRect(SkMatrix::I(), clipRect, GrAA::kNo, SkClipOp::kIntersect); GrAppliedClip out(kDeviceBounds.size()); GrClip::Effect effect = cs.apply(context.get(), sdc.get(), NoOp::Get(), GrAAType::kCoverage, &out, &drawRect); REPORTER_ASSERT(r, effect == GrClip::Effect::kClipped, "Draw should be clipped by rect"); REPORTER_ASSERT(r, !out.hasCoverageFragmentProcessor(), "Clip should not use coverage FPs"); REPORTER_ASSERT(r, !out.hardClip().hasStencilClip(), "Clip should not need stencil"); REPORTER_ASSERT(r, !out.hardClip().windowRectsState().enabled(), "Clip should not need window rects"); REPORTER_ASSERT(r, out.scissorState().enabled() && out.scissorState().rect() == expectedScissor, "Clip has unexpected scissor rectangle"); cs.restore(); } // Analytic coverage FPs auto testHasCoverageFP = [&](SkRect drawBounds) { GrAppliedClip out(kDeviceBounds.size()); GrClip::Effect effect = cs.apply(context.get(), sdc.get(), NoOp::Get(), GrAAType::kCoverage, &out, &drawBounds); REPORTER_ASSERT(r, effect == GrClip::Effect::kClipped, "Draw should be clipped"); REPORTER_ASSERT(r, out.scissorState().enabled(), "Coverage FPs should still set scissor"); REPORTER_ASSERT(r, out.hasCoverageFragmentProcessor(), "Clip should use coverage FP"); }; // Axis-aligned rect can be an analytic FP { cs.save(); cs.clipRect(SkMatrix::I(), {10.2f, 8.342f, 63.f, 23.3f}, GrAA::kYes, SkClipOp::kDifference); testHasCoverageFP({9.f, 10.f, 30.f, 18.f}); cs.restore(); } // Axis-aligned round rect can be an analytic FP { SkRect rect = {4.f, 8.f, 20.f, 20.f}; cs.save(); cs.clipRRect(SkMatrix::I(), SkRRect::MakeRectXY(rect, 3.f, 3.f), GrAA::kYes, SkClipOp::kIntersect); testHasCoverageFP(rect.makeOffset(2.f, 2.f)); cs.restore(); } // Transformed rect can be an analytic FP { SkRect rect = {14.f, 8.f, 30.f, 22.34f}; SkMatrix rot = SkMatrix::RotateDeg(34.f); cs.save(); cs.clipRect(rot, rect, GrAA::kNo, SkClipOp::kIntersect); testHasCoverageFP(rot.mapRect(rect)); cs.restore(); } // Convex polygons can be an analytic FP { SkRect rect = {15.f, 15.f, 45.f, 45.f}; cs.save(); cs.clipPath(SkMatrix::I(), make_octagon(rect), GrAA::kYes, SkClipOp::kIntersect); testHasCoverageFP(rect.makeOutset(2.f, 2.f)); cs.restore(); } } // Must disable tessellation in order to trigger SW mask generation when the clip stack is applied. static void disable_tessellation_atlas(GrContextOptions* options) { options->fGpuPathRenderers = GpuPathRenderers::kNone; options->fAvoidStencilBuffers = true; } DEF_GPUTEST_FOR_CONTEXTS(ClipStack_SWMask, sk_gpu_test::GrContextFactory::IsRenderingContext, r, ctxInfo, disable_tessellation_atlas) { using ClipStack = skgpu::v1::ClipStack; using SurfaceDrawContext = skgpu::v1::SurfaceDrawContext; GrDirectContext* context = ctxInfo.directContext(); std::unique_ptr sdc = SurfaceDrawContext::Make( context, GrColorType::kRGBA_8888, nullptr, SkBackingFit::kExact, kDeviceBounds.size(), SkSurfaceProps(), /*label=*/{}); SkMatrixProvider matrixProvider = SkMatrix::I(); std::unique_ptr cs(new ClipStack(kDeviceBounds, &matrixProvider, false)); auto addMaskRequiringClip = [&](SkScalar x, SkScalar y, SkScalar radius) { SkPath path; path.addCircle(x, y, radius); path.addCircle(x + radius / 2.f, y + radius / 2.f, radius); path.setFillType(SkPathFillType::kEvenOdd); // Use AA so that clip application does not route through the stencil buffer cs->clipPath(SkMatrix::I(), path, GrAA::kYes, SkClipOp::kIntersect); }; auto drawRect = [&](SkRect drawBounds) { GrPaint paint; paint.setColor4f({1.f, 1.f, 1.f, 1.f}); sdc->drawRect(cs.get(), std::move(paint), GrAA::kYes, SkMatrix::I(), drawBounds); }; auto generateMask = [&](SkRect drawBounds) { skgpu::UniqueKey priorKey = cs->testingOnly_getLastSWMaskKey(); drawRect(drawBounds); skgpu::UniqueKey newKey = cs->testingOnly_getLastSWMaskKey(); REPORTER_ASSERT(r, priorKey != newKey, "Did not generate a new SW mask key as expected"); return newKey; }; auto verifyKeys = [&](const std::vector& expectedKeys, const std::vector& releasedKeys) { context->flush(); GrProxyProvider* proxyProvider = context->priv().proxyProvider(); #ifdef SK_DEBUG // The proxy providers key count fluctuates based on proxy lifetime, but we want to // verify the resource count, and that requires using key tags that are debug-only. SkASSERT(expectedKeys.size() > 0 || releasedKeys.size() > 0); const char* tag = expectedKeys.size() > 0 ? expectedKeys[0].tag() : releasedKeys[0].tag(); GrResourceCache* cache = context->priv().getResourceCache(); int numProxies = cache->countUniqueKeysWithTag(tag); REPORTER_ASSERT(r, (int) expectedKeys.size() == numProxies, "Unexpected proxy count, got %d, not %d", numProxies, (int) expectedKeys.size()); #endif for (const auto& key : expectedKeys) { auto proxy = proxyProvider->findOrCreateProxyByUniqueKey(key); REPORTER_ASSERT(r, SkToBool(proxy), "Unable to find resource for expected mask key"); } for (const auto& key : releasedKeys) { auto proxy = proxyProvider->findOrCreateProxyByUniqueKey(key); REPORTER_ASSERT(r, !SkToBool(proxy), "SW mask not released as expected"); } }; // Creates a mask for a complex clip cs->save(); addMaskRequiringClip(5.f, 5.f, 20.f); skgpu::UniqueKey keyADepth1 = generateMask({0.f, 0.f, 20.f, 20.f}); skgpu::UniqueKey keyBDepth1 = generateMask({10.f, 10.f, 30.f, 30.f}); verifyKeys({keyADepth1, keyBDepth1}, {}); // Creates a new mask for a new save record, but doesn't delete the old records cs->save(); addMaskRequiringClip(6.f, 6.f, 15.f); skgpu::UniqueKey keyADepth2 = generateMask({0.f, 0.f, 20.f, 20.f}); skgpu::UniqueKey keyBDepth2 = generateMask({10.f, 10.f, 30.f, 30.f}); verifyKeys({keyADepth1, keyBDepth1, keyADepth2, keyBDepth2}, {}); // Release after modifying the current record (even if we don't draw anything) addMaskRequiringClip(4.f, 4.f, 15.f); skgpu::UniqueKey keyCDepth2 = generateMask({4.f, 4.f, 16.f, 20.f}); verifyKeys({keyADepth1, keyBDepth1, keyCDepth2}, {keyADepth2, keyBDepth2}); // Release after restoring an older record cs->restore(); verifyKeys({keyADepth1, keyBDepth1}, {keyCDepth2}); // Drawing finds the old masks at depth 1 still w/o making new ones drawRect({0.f, 0.f, 20.f, 20.f}); drawRect({10.f, 10.f, 30.f, 30.f}); verifyKeys({keyADepth1, keyBDepth1}, {}); // Drawing something contained within a previous mask also does not make a new one drawRect({5.f, 5.f, 15.f, 15.f}); verifyKeys({keyADepth1, keyBDepth1}, {}); // Release on destruction cs = nullptr; verifyKeys({}, {keyADepth1, keyBDepth1}); }