Exemplo n.º 1
0
void FixWinding(SkPath* path) {
    SkPath::FillType fillType = path->getFillType();
    if (fillType == SkPath::kInverseEvenOdd_FillType) {
        fillType = SkPath::kInverseWinding_FillType;
    } else if (fillType == SkPath::kEvenOdd_FillType) {
        fillType = SkPath::kWinding_FillType;
    }
    SkPathPriv::FirstDirection dir;
    if (one_contour(*path) && SkPathPriv::CheapComputeFirstDirection(*path, &dir)) {
        if (dir != SkPathPriv::kCCW_FirstDirection) {
            SkPath temp;
            temp.reverseAddPath(*path);
            *path = temp;
        }
        path->setFillType(fillType);
        return;
    }
    SkChunkAlloc allocator(4096);
    SkOpContourHead contourHead;
    SkOpGlobalState globalState(nullptr, &contourHead  SkDEBUGPARAMS(nullptr));
    SkOpEdgeBuilder builder(*path, &contourHead, &allocator, &globalState);
    builder.finish(&allocator);
    SkASSERT(contourHead.next());
    contourHead.resetReverse();
    bool writePath = false;
    SkOpSpan* topSpan;
    globalState.setPhase(SkOpGlobalState::kFixWinding);
    while ((topSpan = FindSortableTop(&contourHead))) {
        SkOpSegment* topSegment = topSpan->segment();
        SkOpContour* topContour = topSegment->contour();
        SkASSERT(topContour->isCcw() >= 0);
#if DEBUG_WINDING
        SkDebugf("%s id=%d nested=%d ccw=%d\n",  __FUNCTION__,
                topSegment->debugID(), globalState.nested(), topContour->isCcw());
#endif
        if ((globalState.nested() & 1) != SkToBool(topContour->isCcw())) {
            topContour->setReverse();
            writePath = true;
        }
        topContour->markDone();
        globalState.clearNested();
    }
    if (!writePath) {
        path->setFillType(fillType);
        return;
    }
    SkPath empty;
    SkPathWriter woundPath(empty);
    SkOpContour* test = &contourHead;
    do {
        if (test->reversed()) {
            test->toReversePath(&woundPath);
        } else {
            test->toPath(&woundPath);
        }
    } while ((test = test->next()));
    *path = *woundPath.nativePath();
    path->setFillType(fillType);
}
Exemplo n.º 2
0
static void test_rev(SkCanvas* canvas, const SkPath& path) {
    test_path(canvas, path);

    SkPath rev;
    rev.reverseAddPath(path);
    canvas->save();
    canvas->translate(150, 0);
    test_path(canvas, rev);
    canvas->restore();
}
Exemplo n.º 3
0
SkPath makePath() {
    SkPath path;
    for (uint32_t cIndex = 0; cIndex < fPathContourCount; ++cIndex) {
        uint32_t segments = makeSegmentCount();
        for (uint32_t sIndex = 0; sIndex < segments; ++sIndex) {
            RandomAddPath addPathType = makeAddPathType();
            ++fAddCount;
            if (fPrintName) {
                SkDebugf("%.*s%s\n", fPathDepth * 3, fTab,
                        gRandomAddPathNames[addPathType]);
            }
            switch (addPathType) {
                case kAddArc: {
                    SkRect oval = makeRect();
                    SkScalar startAngle = makeAngle();
                    SkScalar sweepAngle = makeAngle();
                    path.addArc(oval, startAngle, sweepAngle);
                    validate(path);
                    } break;
                case kAddRoundRect1: {
                    SkRect rect = makeRect();
                    SkScalar rx = makeScalar(), ry = makeScalar();
                    SkPath::Direction dir = makeDirection();
                    path.addRoundRect(rect, rx, ry, dir);
                    validate(path);
                    } break;
                case kAddRoundRect2: {
                    SkRect rect = makeRect();
                    SkScalar radii[8];
                    makeScalarArray(SK_ARRAY_COUNT(radii), radii);
                    SkPath::Direction dir = makeDirection();
                    path.addRoundRect(rect, radii, dir);
                    validate(path);
                    } break;
                case kAddRRect: {
                    SkRRect rrect = makeRRect();
                    SkPath::Direction dir = makeDirection();
                    path.addRRect(rrect, dir);
                    validate(path);
                    } break;
                case kAddPoly: {
                    SkTDArray<SkPoint> points;
                    makePointArray(&points);
                    bool close = makeBool();
                    path.addPoly(&points[0], points.count(), close);
                    validate(path);
                    } break;
                case kAddPath1:
                    if (fPathDepth < fPathDepthLimit) {
                        ++fPathDepth;
                        SkPath src = makePath();
                        validate(src);
                        SkScalar dx = makeScalar();
                        SkScalar dy = makeScalar();
                        SkPath::AddPathMode mode = makeAddPathMode();
                        path.addPath(src, dx, dy, mode);
                        --fPathDepth;
                        validate(path);
                    }
                    break;
                case kAddPath2:
                    if (fPathDepth < fPathDepthLimit) {
                        ++fPathDepth;
                        SkPath src = makePath();
                        validate(src);
                        SkPath::AddPathMode mode = makeAddPathMode();
                        path.addPath(src, mode);
                        --fPathDepth;
                        validate(path);
                    }
                    break;
                case kAddPath3:
                    if (fPathDepth < fPathDepthLimit) {
                        ++fPathDepth;
                        SkPath src = makePath();
                        validate(src);
                        SkMatrix matrix = makeMatrix();
                        SkPath::AddPathMode mode = makeAddPathMode();
                        path.addPath(src, matrix, mode);
                        --fPathDepth;
                        validate(path);
                    }
                    break;
                case kReverseAddPath:
                    if (fPathDepth < fPathDepthLimit) {
                        ++fPathDepth;
                        SkPath src = makePath();
                        validate(src);
                        path.reverseAddPath(src);
                        --fPathDepth;
                        validate(path);
                    }
                    break;
                case kMoveToPath: {
                    SkScalar x = makeScalar();
                    SkScalar y = makeScalar();
                    path.moveTo(x, y);
                    validate(path);
                    } break;
                case kRMoveToPath: {
                    SkScalar x = makeScalar();
                    SkScalar y = makeScalar();
                    path.rMoveTo(x, y);
                    validate(path);
                    } break;
                case kLineToPath: {
                    SkScalar x = makeScalar();
                    SkScalar y = makeScalar();
                    path.lineTo(x, y);
                    validate(path);
                    } break;
                case kRLineToPath: {
                    SkScalar x = makeScalar();
                    SkScalar y = makeScalar();
                    path.rLineTo(x, y);
                    validate(path);
                    } break;
                case kQuadToPath: {
                    SkPoint pt[2];
                    makePointArray(SK_ARRAY_COUNT(pt), pt);
                    path.quadTo(pt[0], pt[1]);
                    validate(path);
                    } break;
                case kRQuadToPath: {
                    SkPoint pt[2];
                    makePointArray(SK_ARRAY_COUNT(pt), pt);
                    path.rQuadTo(pt[0].fX, pt[0].fY, pt[1].fX, pt[1].fY);
                    validate(path);
                    } break;
                case kConicToPath: {
                    SkPoint pt[2];
                    makePointArray(SK_ARRAY_COUNT(pt), pt);
                    SkScalar weight = makeScalar();
                    path.conicTo(pt[0], pt[1], weight);
                    validate(path);
                    } break;
                case kRConicToPath: {
                    SkPoint pt[2];
                    makePointArray(SK_ARRAY_COUNT(pt), pt);
                    SkScalar weight = makeScalar();
                    path.rConicTo(pt[0].fX, pt[0].fY, pt[1].fX, pt[1].fY, weight);
                    validate(path);
                    } break;
                case kCubicToPath: {
                    SkPoint pt[3];
                    makePointArray(SK_ARRAY_COUNT(pt), pt);
                    path.cubicTo(pt[0], pt[1], pt[2]);
                    validate(path);
                    } break;
                case kRCubicToPath: {
                    SkPoint pt[3];
                    makePointArray(SK_ARRAY_COUNT(pt), pt);
                    path.rCubicTo(pt[0].fX, pt[0].fY, pt[1].fX, pt[1].fY, pt[2].fX, pt[2].fY);
                    validate(path);
                    } break;
                case kArcToPath: {
                    SkPoint pt[2];
                    makePointArray(SK_ARRAY_COUNT(pt), pt);
                    SkScalar radius = makeScalar();
                    path.arcTo(pt[0], pt[1], radius);
                    validate(path);
                    } break;
                case kArcTo2Path: {
                    SkRect oval = makeRect();
                    SkScalar startAngle = makeAngle();
                    SkScalar sweepAngle = makeAngle();
                    bool forceMoveTo = makeBool();
                    path.arcTo(oval, startAngle, sweepAngle, forceMoveTo);
                    validate(path);
                    } break;
                case kClosePath:
                    path.close();
                    validate(path);
                    break;
            }
        }
    }
    return path;
}
Exemplo n.º 4
0
/* OPTIMIZATION: Union doesn't need to be all-or-nothing. A run of three or more convex
   paths with union ops could be locally resolved and still improve over doing the
   ops one at a time. */
bool SkOpBuilder::resolve(SkPath* result) {
    SkPath original = *result;
    int count = fOps.count();
    bool allUnion = true;
    SkPathPriv::FirstDirection firstDir = SkPathPriv::kUnknown_FirstDirection;
    for (int index = 0; index < count; ++index) {
        SkPath* test = &fPathRefs[index];
        if (kUnion_SkPathOp != fOps[index] || test->isInverseFillType()) {
            allUnion = false;
            break;
        }
        // If all paths are convex, track direction, reversing as needed.
        if (test->isConvex()) {
            SkPathPriv::FirstDirection dir;
            if (!SkPathPriv::CheapComputeFirstDirection(*test, &dir)) {
                allUnion = false;
                break;
            }
            if (firstDir == SkPathPriv::kUnknown_FirstDirection) {
                firstDir = dir;
            } else if (firstDir != dir) {
                SkPath temp;
                temp.reverseAddPath(*test);
                *test = temp;
            }
            continue;
        }
        // If the path is not convex but its bounds do not intersect the others, simplify is enough.
        const SkRect& testBounds = test->getBounds();
        for (int inner = 0; inner < index; ++inner) {
            // OPTIMIZE: check to see if the contour bounds do not intersect other contour bounds?
            if (SkRect::Intersects(fPathRefs[inner].getBounds(), testBounds)) {
                allUnion = false;
                break;
            }
        }
    }
    if (!allUnion) {
        *result = fPathRefs[0];
        for (int index = 1; index < count; ++index) {
            if (!Op(*result, fPathRefs[index], fOps[index], result)) {
                reset();
                *result = original;
                return false;
            }
        }
        reset();
        return true;
    }
    SkPath sum;
    for (int index = 0; index < count; ++index) {
        if (!Simplify(fPathRefs[index], &fPathRefs[index])) {
            reset();
            *result = original;
            return false;
        }
        if (!fPathRefs[index].isEmpty()) {
            // convert the even odd result back to winding form before accumulating it
            if (!FixWinding(&fPathRefs[index])) {
                *result = original;
                return false;
            }
            sum.addPath(fPathRefs[index]);
        }
    }
    reset();
    bool success = Simplify(sum, result);
    if (!success) {
        *result = original;
    }
    return success;
}