/* * Copyright 2018 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "gm/gm.h" #include "include/core/SkCanvas.h" #include "include/core/SkColor.h" #include "include/core/SkPaint.h" #include "include/core/SkPath.h" #include "include/core/SkPoint.h" #include "include/core/SkRect.h" #include "include/core/SkScalar.h" #include "include/core/SkSize.h" #include "include/core/SkString.h" #include "include/core/SkTypes.h" #include "include/private/SkTDArray.h" #include "src/utils/SkPolyUtils.h" #include "tools/ToolUtils.h" #include #include static void create_ngon(int n, SkPoint* pts, SkScalar w, SkScalar h, SkPathDirection dir) { float angleStep = 360.0f / n, angle = 0.0f; if ((n % 2) == 1) { angle = angleStep/2.0f; } if (SkPathDirection::kCCW == dir) { angle = -angle; angleStep = -angleStep; } for (int i = 0; i < n; ++i) { pts[i].fX = -SkScalarSin(SkDegreesToRadians(angle)) * w; pts[i].fY = SkScalarCos(SkDegreesToRadians(angle)) * h; angle += angleStep; } } namespace PolygonOffsetData { // narrow rect const SkPoint gPoints0[] = { { -1.5f, -50.0f }, { 1.5f, -50.0f }, { 1.5f, 50.0f }, { -1.5f, 50.0f } }; // narrow rect on an angle const SkPoint gPoints1[] = { { -50.0f, -49.0f }, { -49.0f, -50.0f }, { 50.0f, 49.0f }, { 49.0f, 50.0f } }; // trap - narrow on top - wide on bottom const SkPoint gPoints2[] = { { -10.0f, -50.0f }, { 10.0f, -50.0f }, { 50.0f, 50.0f }, { -50.0f, 50.0f } }; // wide skewed rect const SkPoint gPoints3[] = { { -50.0f, -50.0f }, { 0.0f, -50.0f }, { 50.0f, 50.0f }, { 0.0f, 50.0f } }; // thin rect with colinear-ish lines const SkPoint gPoints4[] = { { -6.0f, -50.0f }, { 4.0f, -50.0f }, { 5.0f, -25.0f }, { 6.0f, 0.0f }, { 5.0f, 25.0f }, { 4.0f, 50.0f }, { -4.0f, 50.0f } }; // degenerate const SkPoint gPoints5[] = { { -0.025f, -0.025f }, { 0.025f, -0.025f }, { 0.025f, 0.025f }, { -0.025f, 0.025f } }; // Quad with near coincident point const SkPoint gPoints6[] = { { -20.0f, -13.0f }, { -20.0f, -13.05f }, { 20.0f, -13.0f }, { 20.0f, 27.0f } }; // thin rect with colinear lines const SkPoint gPoints7[] = { { -10.0f, -50.0f }, { 10.0f, -50.0f }, { 10.0f, -20.0f }, { 10.0f, 0.0f }, { 10.0f, 35.0f }, { 10.0f, 50.0f }, { -10.0f, 50.0f } }; // capped teardrop const SkPoint gPoints8[] = { { 50.00f, 50.00f }, { 0.00f, 50.00f }, { -15.45f, 47.55f }, { -29.39f, 40.45f }, { -40.45f, 29.39f }, { -47.55f, 15.45f }, { -50.00f, 0.00f }, { -47.55f, -15.45f }, { -40.45f, -29.39f }, { -29.39f, -40.45f }, { -15.45f, -47.55f }, { 0.00f, -50.00f }, { 50.00f, -50.00f } }; // teardrop const SkPoint gPoints9[] = { { 4.39f, 40.45f }, { -9.55f, 47.55f }, { -25.00f, 50.00f }, { -40.45f, 47.55f }, { -54.39f, 40.45f }, { -65.45f, 29.39f }, { -72.55f, 15.45f }, { -75.00f, 0.00f }, { -72.55f, -15.45f }, { -65.45f, -29.39f }, { -54.39f, -40.45f }, { -40.45f, -47.55f }, { -25.0f, -50.0f }, { -9.55f, -47.55f }, { 4.39f, -40.45f }, { 75.00f, 0.00f } }; // clipped triangle const SkPoint gPoints10[] = { { -10.0f, -50.0f }, { 10.0f, -50.0f }, { 50.0f, 31.0f }, { 40.0f, 50.0f }, { -40.0f, 50.0f }, { -50.0f, 31.0f }, }; // tab const SkPoint gPoints11[] = { { -45, -25 }, { 45, -25 }, { 45, 25 }, { 20, 25 }, { 19.6157f, 25.f + 3.9018f }, { 18.4776f, 25.f + 7.6537f }, { 16.6294f, 25.f + 11.1114f }, { 14.1421f, 25.f + 14.1421f }, { 11.1114f, 25.f + 16.6294f }, { 7.6537f, 25.f + 18.4776f }, { 3.9018f, 25.f + 19.6157f }, { 0, 45.f }, { -3.9018f, 25.f + 19.6157f }, { -7.6537f, 25.f + 18.4776f }, { -11.1114f, 25.f + 16.6294f }, { -14.1421f, 25.f + 14.1421f }, { -16.6294f, 25.f + 11.1114f }, { -18.4776f, 25.f + 7.6537f }, { -19.6157f, 25.f + 3.9018f }, { -20, 25 }, { -45, 25 } }; // star of david const SkPoint gPoints12[] = { { 0.0f, -50.0f }, { 14.43f, -25.0f }, { 43.30f, -25.0f }, { 28.86f, 0.0f }, { 43.30f, 25.0f }, { 14.43f, 25.0f }, { 0.0f, 50.0f }, { -14.43f, 25.0f }, { -43.30f, 25.0f }, { -28.86f, 0.0f }, { -43.30f, -25.0f }, { -14.43f, -25.0f }, }; // notch const SkScalar kBottom = 25.f; const SkPoint gPoints13[] = { { -50, kBottom - 50.f }, { 50, kBottom - 50.f }, { 50, kBottom }, { 20, kBottom }, { 19.6157f, kBottom - 3.9018f }, { 18.4776f, kBottom - 7.6537f }, { 16.6294f, kBottom - 11.1114f }, { 14.1421f, kBottom - 14.1421f }, { 11.1114f, kBottom - 16.6294f }, { 7.6537f, kBottom - 18.4776f }, { 3.9018f, kBottom - 19.6157f }, { 0, kBottom - 20.f }, { -3.9018f, kBottom - 19.6157f }, { -7.6537f, kBottom - 18.4776f }, { -11.1114f, kBottom - 16.6294f }, { -14.1421f, kBottom - 14.1421f }, { -16.6294f, kBottom - 11.1114f }, { -18.4776f, kBottom - 7.6537f }, { -19.6157f, kBottom - 3.9018f }, { -20, kBottom }, { -50, kBottom } }; // crown const SkPoint gPoints14[] = { { -40, -39 }, { 40, -39 }, { 40, -20 }, { 30, 40 }, { 20, -20 }, { 10, 40 }, { 0, -20 }, { -10, 40 }, { -20, -20 }, { -30, 40 }, { -40, -20 } }; // dumbbell const SkPoint gPoints15[] = { { -26, -3 }, { -24, -6.2f }, { -22.5f, -8 }, { -20, -9.9f }, { -17.5f, -10.3f }, { -15, -10.9f }, { -12.5f, -10.2f }, { -10, -9.7f }, { -7.5f, -8.1f }, { -5, -7.7f }, { -2.5f, -7.4f }, { 0, -7.7f }, { 3, -9 }, { 6.5f, -11.5f }, { 10.6f, -14 }, { 14, -15.2f }, { 17, -15.5f }, { 20, -15.2f }, { 23.4f, -14 }, { 27.5f, -11.5f }, { 30, -8 }, { 32, -4 }, { 32.5f, 0 }, { 32, 4 }, { 30, 8 }, { 27.5f, 11.5f }, { 23.4f, 14 }, { 20, 15.2f }, { 17, 15.5f }, { 14, 15.2f }, { 10.6f, 14 }, { 6.5f, 11.5f }, { 3, 9 }, { 0, 7.7f }, { -2.5f, 7.4f }, { -5, 7.7f }, { -7.5f, 8.1f }, { -10, 9.7f }, { -12.5f, 10.2f }, { -15, 10.9f }, { -17.5f, 10.3f }, { -20, 9.9f }, { -22.5f, 8 }, { -24, 6.2f }, { -26, 3 }, { -26.5f, 0 } }; // truncated dumbbell // (checks winding computation in OffsetSimplePolygon) const SkPoint gPoints16[] = { { -15 + 3, -9 }, { -15 + 6.5f, -11.5f }, { -15 + 10.6f, -14 }, { -15 + 14, -15.2f }, { -15 + 17, -15.5f }, { -15 + 20, -15.2f }, { -15 + 23.4f, -14 }, { -15 + 27.5f, -11.5f }, { -15 + 30, -8 }, { -15 + 32, -4 }, { -15 + 32.5f, 0 }, { -15 + 32, 4 }, { -15 + 30, 8 }, { -15 + 27.5f, 11.5f }, { -15 + 23.4f, 14 }, { -15 + 20, 15.2f }, { -15 + 17, 15.5f }, { -15 + 14, 15.2f }, { -15 + 10.6f, 14 }, { -15 + 6.5f, 11.5f }, { -15 + 3, 9 }, }; // square notch // (to detect segment-segment intersection) const SkPoint gPoints17[] = { { -50, kBottom - 50.f }, { 50, kBottom - 50.f }, { 50, kBottom }, { 20, kBottom }, { 20, kBottom - 20.f }, { -20, kBottom - 20.f }, { -20, kBottom }, { -50, kBottom } }; // box with Peano curve const SkPoint gPoints18[] = { { 0, 0 }, { 0, -12 }, { -6, -12 }, { -6, 0 }, { -12, 0 }, { -12, -12}, { -18, -12}, { -18, 18}, { -12, 18}, {-12, 6}, {-6, 6}, {-6, 36}, {-12, 36}, {-12, 24}, {-18, 24}, {-18, 36}, {-24, 36}, {-24, 24}, {-30, 24}, {-30, 36}, {-36, 36}, {-36, 6}, {-30, 6}, {-30, 18}, {-24, 18}, {-24, -12}, {-30, -12}, {-30, 0}, {-36, 0}, {-36, -36}, {36, -36}, {36, 36}, {12, 36}, {12, 24}, {6, 24}, {6, 36}, {0, 36}, {0, 6}, {6, 6}, {6, 18}, {12, 18}, {12, -12}, {6, -12}, {6, 0} }; const SkPoint* gConvexPoints[] = { gPoints0, gPoints1, gPoints2, gPoints3, gPoints4, gPoints5, gPoints6, gPoints7, gPoints8, gPoints9, gPoints10, }; const size_t gConvexSizes[] = { SK_ARRAY_COUNT(gPoints0), SK_ARRAY_COUNT(gPoints1), SK_ARRAY_COUNT(gPoints2), SK_ARRAY_COUNT(gPoints3), SK_ARRAY_COUNT(gPoints4), SK_ARRAY_COUNT(gPoints5), SK_ARRAY_COUNT(gPoints6), SK_ARRAY_COUNT(gPoints7), SK_ARRAY_COUNT(gPoints8), SK_ARRAY_COUNT(gPoints9), SK_ARRAY_COUNT(gPoints10), }; static_assert(SK_ARRAY_COUNT(gConvexSizes) == SK_ARRAY_COUNT(gConvexPoints), "array_mismatch"); const SkPoint* gSimplePoints[] = { gPoints0, gPoints1, gPoints2, gPoints4, gPoints5, gPoints7, gPoints8, gPoints11, gPoints12, gPoints13, gPoints14, gPoints15, gPoints16, gPoints17, gPoints18, }; const size_t gSimpleSizes[] = { SK_ARRAY_COUNT(gPoints0), SK_ARRAY_COUNT(gPoints1), SK_ARRAY_COUNT(gPoints2), SK_ARRAY_COUNT(gPoints4), SK_ARRAY_COUNT(gPoints5), SK_ARRAY_COUNT(gPoints7), SK_ARRAY_COUNT(gPoints8), SK_ARRAY_COUNT(gPoints11), SK_ARRAY_COUNT(gPoints12), SK_ARRAY_COUNT(gPoints13), SK_ARRAY_COUNT(gPoints14), SK_ARRAY_COUNT(gPoints15), SK_ARRAY_COUNT(gPoints16), SK_ARRAY_COUNT(gPoints17), SK_ARRAY_COUNT(gPoints18), }; static_assert(SK_ARRAY_COUNT(gSimpleSizes) == SK_ARRAY_COUNT(gSimplePoints), "array_mismatch"); } // namespace PolygonOffsetData namespace skiagm { // This GM is intended to exercise the offsetting of polygons // When fVariableOffset is true it will skew the offset by x, // to test perspective and other variable offset functions class PolygonOffsetGM : public GM { public: PolygonOffsetGM(bool convexOnly) : fConvexOnly(convexOnly) { this->setBGColor(0xFFFFFFFF); } protected: SkString onShortName() override { if (fConvexOnly) { return SkString("convex-polygon-inset"); } else { return SkString("simple-polygon-offset"); } } SkISize onISize() override { return SkISize::Make(kGMWidth, kGMHeight); } bool runAsBench() const override { return true; } static void GetConvexPolygon(int index, SkPathDirection dir, std::unique_ptr* data, int* numPts) { if (index < (int)SK_ARRAY_COUNT(PolygonOffsetData::gConvexPoints)) { // manually specified *numPts = (int)PolygonOffsetData::gConvexSizes[index]; *data = std::make_unique(*numPts); if (SkPathDirection::kCW == dir) { for (int i = 0; i < *numPts; ++i) { (*data)[i] = PolygonOffsetData::gConvexPoints[index][i]; } } else { for (int i = 0; i < *numPts; ++i) { (*data)[i] = PolygonOffsetData::gConvexPoints[index][*numPts - i - 1]; } } } else { // procedurally generated SkScalar width = kMaxPathHeight / 2; SkScalar height = kMaxPathHeight / 2; int numPtsArray[] = { 3, 4, 5, 5, 6, 8, 8, 20, 100 }; size_t arrayIndex = index - SK_ARRAY_COUNT(PolygonOffsetData::gConvexPoints); SkASSERT(arrayIndex < SK_ARRAY_COUNT(numPtsArray)); *numPts = numPtsArray[arrayIndex]; if (arrayIndex == 3 || arrayIndex == 6) { // squashed pentagon and octagon width = kMaxPathHeight / 5; } *data = std::make_unique(*numPts); create_ngon(*numPts, data->get(), width, height, dir); } } static void GetSimplePolygon(int index, SkPathDirection dir, std::unique_ptr* data, int* numPts) { if (index < (int)SK_ARRAY_COUNT(PolygonOffsetData::gSimplePoints)) { // manually specified *numPts = (int)PolygonOffsetData::gSimpleSizes[index]; *data = std::make_unique(*numPts); if (SkPathDirection::kCW == dir) { for (int i = 0; i < *numPts; ++i) { (*data)[i] = PolygonOffsetData::gSimplePoints[index][i]; } } else { for (int i = 0; i < *numPts; ++i) { (*data)[i] = PolygonOffsetData::gSimplePoints[index][*numPts - i - 1]; } } } else { // procedurally generated SkScalar width = kMaxPathHeight / 2; SkScalar height = kMaxPathHeight / 2; int numPtsArray[] = { 5, 7, 8, 20, 100 }; size_t arrayIndex = index - SK_ARRAY_COUNT(PolygonOffsetData::gSimplePoints); arrayIndex = std::min(arrayIndex, SK_ARRAY_COUNT(numPtsArray) - 1); SkASSERT(arrayIndex < SK_ARRAY_COUNT(numPtsArray)); *numPts = numPtsArray[arrayIndex]; // squash horizontally width = kMaxPathHeight / 5; *data = std::make_unique(*numPts); create_ngon(*numPts, data->get(), width, height, dir); } } // Draw a single polygon with insets and potentially outsets void drawPolygon(SkCanvas* canvas, int index, SkPoint* offset) { SkPoint center; SkRect bounds; { std::unique_ptr data(nullptr); int numPts; if (fConvexOnly) { GetConvexPolygon(index, SkPathDirection::kCW, &data, &numPts); } else { GetSimplePolygon(index, SkPathDirection::kCW, &data, &numPts); } bounds.setBounds(data.get(), numPts); if (!fConvexOnly) { bounds.outset(kMaxOutset, kMaxOutset); } if (offset->fX + bounds.width() > kGMWidth) { offset->fX = 0; offset->fY += kMaxPathHeight; } center = { offset->fX + SkScalarHalf(bounds.width()), offset->fY }; offset->fX += bounds.width(); } const SkPathDirection dirs[2] = { SkPathDirection::kCW, SkPathDirection::kCCW }; const float insets[] = { 5, 10, 15, 20, 25, 30, 35, 40 }; const float offsets[] = { 2, 5, 9, 14, 20, 27, 35, 44, -2, -5, -9 }; const SkColor colors[] = { 0xFF901313, 0xFF8D6214, 0xFF698B14, 0xFF1C8914, 0xFF148755, 0xFF146C84, 0xFF142482, 0xFF4A1480, 0xFF901313, 0xFF8D6214, 0xFF698B14 }; SkPaint paint; paint.setAntiAlias(true); paint.setStyle(SkPaint::kStroke_Style); paint.setStrokeWidth(1); std::unique_ptr data(nullptr); int numPts; if (fConvexOnly) { GetConvexPolygon(index, dirs[index % 2], &data, &numPts); } else { GetSimplePolygon(index, dirs[index % 2], &data, &numPts); } { SkPath path; path.moveTo(data.get()[0]); for (int i = 1; i < numPts; ++i) { path.lineTo(data.get()[i]); } path.close(); canvas->save(); canvas->translate(center.fX, center.fY); canvas->drawPath(path, paint); canvas->restore(); } SkTDArray offsetPoly; size_t count = fConvexOnly ? SK_ARRAY_COUNT(insets) : SK_ARRAY_COUNT(offsets); for (size_t i = 0; i < count; ++i) { SkScalar offset = fConvexOnly ? insets[i] : offsets[i]; std::function offsetFunc; bool result; if (fConvexOnly) { result = SkInsetConvexPolygon(data.get(), numPts, offset, &offsetPoly); } else { SkRect bounds; bounds.setBoundsCheck(data.get(), numPts); result = SkOffsetSimplePolygon(data.get(), numPts, bounds, offset, &offsetPoly); } if (result) { SkPath path; path.moveTo(offsetPoly[0]); for (int i = 1; i < offsetPoly.count(); ++i) { path.lineTo(offsetPoly[i]); } path.close(); paint.setColor(ToolUtils::color_to_565(colors[i])); canvas->save(); canvas->translate(center.fX, center.fY); canvas->drawPath(path, paint); canvas->restore(); } } } void onDraw(SkCanvas* canvas) override { // the right edge of the last drawn path SkPoint offset = { 0, SkScalarHalf(kMaxPathHeight) }; if (!fConvexOnly) { offset.fY += kMaxOutset; } for (int i = 0; i < kNumPaths; ++i) { this->drawPolygon(canvas, i, &offset); } } private: static constexpr int kNumPaths = 20; static constexpr int kMaxPathHeight = 100; static constexpr int kMaxOutset = 16; static constexpr int kGMWidth = 512; static constexpr int kGMHeight = 512; bool fConvexOnly; using INHERITED = GM; }; ////////////////////////////////////////////////////////////////////////////// DEF_GM(return new PolygonOffsetGM(true);) DEF_GM(return new PolygonOffsetGM(false);) } // namespace skiagm