Exemplo n.º 1
0
void SkRRect::setRectXY(const SkRect& rect, SkScalar xRad, SkScalar yRad) {
    if (rect.isEmpty() || !rect.isFinite()) {
        this->setEmpty();
        return;
    }

    if (!SkScalarsAreFinite(xRad, yRad)) {
        xRad = yRad = 0;    // devolve into a simple rect
    }
    if (xRad <= 0 || yRad <= 0) {
        // all corners are square in this case
        this->setRect(rect);
        return;
    }

    if (rect.width() < xRad+xRad || rect.height() < yRad+yRad) {
        SkScalar scale = SkMinScalar(rect.width() / (xRad + xRad), rect.height() / (yRad + yRad));
        SkASSERT(scale < SK_Scalar1);
        xRad = SkScalarMul(xRad, scale);
        yRad = SkScalarMul(yRad, scale);
    }

    fRect = rect;
    for (int i = 0; i < 4; ++i) {
        fRadii[i].set(xRad, yRad);
    }
    fType = kSimple_Type;
    if (xRad >= SkScalarHalf(fRect.width()) && yRad >= SkScalarHalf(fRect.height())) {
        fType = kOval_Type;
        // TODO: assert that all the x&y radii are already W/2 & H/2
    }

    SkDEBUGCODE(this->validate();)
}
Exemplo n.º 2
0
sk_sp<SkPathEffect> SkStrokePathEffect::Make(SkScalar width, SkPaint::Join join, SkPaint::Cap cap,
                                             SkScalar miter) {
    if (!SkScalarsAreFinite(width, miter) || width < 0 || miter < 0) {
        return nullptr;
    }
    return sk_sp<SkPathEffect>(new SkStrokePE(width, join, cap, miter));
}
Exemplo n.º 3
0
void SkRRect::setNinePatch(const SkRect& rect, SkScalar leftRad, SkScalar topRad,
                           SkScalar rightRad, SkScalar bottomRad) {
    if (rect.isEmpty() || !rect.isFinite()) {
        this->setEmpty();
        return;
    }

    const SkScalar array[4] = { leftRad, topRad, rightRad, bottomRad };
    if (!SkScalarsAreFinite(array, 4)) {
        this->setRect(rect);    // devolve into a simple rect
        return;
    }

    leftRad = SkMaxScalar(leftRad, 0);
    topRad = SkMaxScalar(topRad, 0);
    rightRad = SkMaxScalar(rightRad, 0);
    bottomRad = SkMaxScalar(bottomRad, 0);

    SkScalar scale = SK_Scalar1;
    if (leftRad + rightRad > rect.width()) {
        scale = rect.width() / (leftRad + rightRad);
    }
    if (topRad + bottomRad > rect.height()) {
        scale = SkMinScalar(scale, rect.height() / (topRad + bottomRad));
    }

    if (scale < SK_Scalar1) {
        leftRad = SkScalarMul(leftRad, scale);
        topRad = SkScalarMul(topRad, scale);
        rightRad = SkScalarMul(rightRad, scale);
        bottomRad = SkScalarMul(bottomRad, scale);
    }

    if (leftRad == rightRad && topRad == bottomRad) {
        if (leftRad >= SkScalarHalf(rect.width()) && topRad >= SkScalarHalf(rect.height())) {
            fType = kOval_Type;
        } else if (0 == leftRad || 0 == topRad) {
            // If the left and (by equality check above) right radii are zero then it is a rect.
            // Same goes for top/bottom.
            fType = kRect_Type;
            leftRad = 0;
            topRad = 0;
            rightRad = 0;
            bottomRad = 0;
        } else {
            fType = kSimple_Type;
        }
    } else {
        fType = kNinePatch_Type;
    }

    fRect = rect;
    fRadii[kUpperLeft_Corner].set(leftRad, topRad);
    fRadii[kUpperRight_Corner].set(rightRad, topRad);
    fRadii[kLowerRight_Corner].set(rightRad, bottomRad);
    fRadii[kLowerLeft_Corner].set(leftRad, bottomRad);

    SkDEBUGCODE(this->validate();)
}
Exemplo n.º 4
0
bool SkDCubic::toFloatPoints(SkPoint* pts) const {
    const double* dCubic = &fPts[0].fX;
    SkScalar* cubic = &pts[0].fX;
    for (int index = 0; index < kPointCount * 2; ++index) {
        *cubic++ = SkDoubleToScalar(*dCubic++);
    }
    return SkScalarsAreFinite(&pts->fX, kPointCount * 2);
}
Exemplo n.º 5
0
sk_sp<SkPathEffect> SkTrimPathEffect::Make(SkScalar startT, SkScalar stopT, Mode mode) {
    if (!SkScalarsAreFinite(startT, stopT)) {
        return nullptr;
    }

    if (startT <= 0 && stopT >= 1 && mode == Mode::kNormal) {
        return nullptr;
    }

    startT = SkTPin(startT, 0.f, 1.f);
    stopT  = SkTPin(stopT,  0.f, 1.f);

    if (startT >= stopT && mode == Mode::kInverted) {
        return nullptr;
    }

    return sk_sp<SkPathEffect>(new SkTrimPE(startT, stopT, mode));
}
Exemplo n.º 6
0
void SkRRect::setRectRadii(const SkRect& rect, const SkVector radii[4]) {
    fRect = rect;
    fRect.sort();

    if (fRect.isEmpty() || !fRect.isFinite()) {
        this->setEmpty();
        return;
    }

    if (!SkScalarsAreFinite(&radii[0].fX, 8)) {
        this->setRect(rect);    // devolve into a simple rect
        return;
    }

    memcpy(fRadii, radii, sizeof(fRadii));

    bool allCornersSquare = true;

    // Clamp negative radii to zero
    for (int i = 0; i < 4; ++i) {
        if (fRadii[i].fX <= 0 || fRadii[i].fY <= 0) {
            // In this case we are being a little fast & loose. Since one of
            // the radii is 0 the corner is square. However, the other radii
            // could still be non-zero and play in the global scale factor
            // computation.
            fRadii[i].fX = 0;
            fRadii[i].fY = 0;
        } else {
            allCornersSquare = false;
        }
    }

    if (allCornersSquare) {
        this->setRect(rect);
        return;
    }

    this->scaleRadii();
}
Exemplo n.º 7
0
sk_sp<SkShader> SkShader::MakeColorShader(const SkColor4f& color, sk_sp<SkColorSpace> space) {
    if (!SkScalarsAreFinite(color.vec(), 4)) {
        return nullptr;
    }
    return sk_make_sp<SkColor4Shader>(color, std::move(space));
}
Exemplo n.º 8
0
void SkRRect::setRectRadii(const SkRect& rect, const SkVector radii[4]) {
    fRect = rect;
    fRect.sort();

    if (fRect.isEmpty() || !fRect.isFinite()) {
        this->setEmpty();
        return;
    }

    if (!SkScalarsAreFinite(&radii[0].fX, 8)) {
        this->setRect(rect);    // devolve into a simple rect
        return;
    }

    memcpy(fRadii, radii, sizeof(fRadii));

    bool allCornersSquare = true;

    // Clamp negative radii to zero
    for (int i = 0; i < 4; ++i) {
        if (fRadii[i].fX <= 0 || fRadii[i].fY <= 0) {
            // In this case we are being a little fast & loose. Since one of
            // the radii is 0 the corner is square. However, the other radii
            // could still be non-zero and play in the global scale factor
            // computation.
            fRadii[i].fX = 0;
            fRadii[i].fY = 0;
        } else {
            allCornersSquare = false;
        }
    }

    if (allCornersSquare) {
        this->setRect(rect);
        return;
    }

    // Proportionally scale down all radii to fit. Find the minimum ratio
    // of a side and the radii on that side (for all four sides) and use
    // that to scale down _all_ the radii. This algorithm is from the
    // W3 spec (http://www.w3.org/TR/css3-background/) section 5.5 - Overlapping
    // Curves:
    // "Let f = min(Li/Si), where i is one of { top, right, bottom, left },
    //   Si is the sum of the two corresponding radii of the corners on side i,
    //   and Ltop = Lbottom = the width of the box,
    //   and Lleft = Lright = the height of the box.
    // If f < 1, then all corner radii are reduced by multiplying them by f."
    double scale = 1.0;

    scale = compute_min_scale(fRadii[0].fX, fRadii[1].fX, fRect.width(),  scale);
    scale = compute_min_scale(fRadii[1].fY, fRadii[2].fY, fRect.height(), scale);
    scale = compute_min_scale(fRadii[2].fX, fRadii[3].fX, fRect.width(),  scale);
    scale = compute_min_scale(fRadii[3].fY, fRadii[0].fY, fRect.height(), scale);

    if (scale < 1.0) {
        for (int i = 0; i < 4; ++i) {
            fRadii[i].fX *= scale;
            fRadii[i].fY *= scale;
        }
    }

    // skbug.com/3239 -- its possible that we can hit the following inconsistency:
    //     rad == bounds.bottom - bounds.top
    //     bounds.bottom - radius < bounds.top
    //     YIKES
    // We need to detect and "fix" this now, otherwise we can have the following wackiness:
    //     path.addRRect(rrect);
    //     rrect.rect() != path.getBounds()
    for (int i = 0; i < 4; ++i) {
        fRadii[i].fX = clamp_radius_check_predicates(fRadii[i].fX, fRect.fLeft, fRect.fRight);
        fRadii[i].fY = clamp_radius_check_predicates(fRadii[i].fY, fRect.fTop, fRect.fBottom);
    }
    // At this point we're either oval, simple, or complex (not empty or rect).
    this->computeType();

    SkDEBUGCODE(this->validate();)
}
Exemplo n.º 9
0
bool SkOpEdgeBuilder::walk() {
    uint8_t* verbPtr = fPathVerbs.begin();
    uint8_t* endOfFirstHalf = &verbPtr[fSecondHalf];
    SkPoint* pointsPtr = fPathPts.begin() - 1;
    SkScalar* weightPtr = fWeights.begin();
    SkPath::Verb verb;
    while ((verb = (SkPath::Verb) *verbPtr) != SkPath::kDone_Verb) {
        if (verbPtr == endOfFirstHalf) {
            fOperand = true;
        }
        verbPtr++;
        switch (verb) {
            case SkPath::kMove_Verb:
                if (fCurrentContour && fCurrentContour->count()) {
                    if (fAllowOpenContours) {
                        complete();
                    } else if (!close()) {
                        return false;
                    }
                }
                if (!fCurrentContour) {
                    fCurrentContour = fContoursHead->appendContour();
                }
                fCurrentContour->init(fGlobalState, fOperand,
                    fXorMask[fOperand] == kEvenOdd_PathOpsMask);
                pointsPtr += 1;
                continue;
            case SkPath::kLine_Verb:
                fCurrentContour->addLine(pointsPtr);
                break;
            case SkPath::kQuad_Verb:
                {
                    SkVector v1 = pointsPtr[1] - pointsPtr[0];
                    SkVector v2 = pointsPtr[2] - pointsPtr[1];
                    if (v1.dot(v2) < 0) {
                        SkPoint pair[5];
                        if (SkChopQuadAtMaxCurvature(pointsPtr, pair) == 1) {
                            goto addOneQuad;
                        }
                        if (!SkScalarsAreFinite(&pair[0].fX, SK_ARRAY_COUNT(pair) * 2)) {
                            return false;
                        }
                        SkPoint cStorage[2][2];
                        SkPath::Verb v1 = SkReduceOrder::Quad(&pair[0], cStorage[0]);
                        SkPath::Verb v2 = SkReduceOrder::Quad(&pair[2], cStorage[1]);
                        SkPoint* curve1 = v1 != SkPath::kLine_Verb ? &pair[0] : cStorage[0];
                        SkPoint* curve2 = v2 != SkPath::kLine_Verb ? &pair[2] : cStorage[1];
                        if (can_add_curve(v1, curve1) && can_add_curve(v2, curve2)) {
                            fCurrentContour->addCurve(v1, curve1);
                            fCurrentContour->addCurve(v2, curve2);
                            break;
                        }
                    }
                }
            addOneQuad:
                fCurrentContour->addQuad(pointsPtr);
                break;
            case SkPath::kConic_Verb: {
                SkVector v1 = pointsPtr[1] - pointsPtr[0];
                SkVector v2 = pointsPtr[2] - pointsPtr[1];
                SkScalar weight = *weightPtr++;
                if (v1.dot(v2) < 0) {
                    // FIXME: max curvature for conics hasn't been implemented; use placeholder
                    SkScalar maxCurvature = SkFindQuadMaxCurvature(pointsPtr);
                    if (maxCurvature > 0) {
                        SkConic conic(pointsPtr, weight);
                        SkConic pair[2];
                        if (!conic.chopAt(maxCurvature, pair)) {
                            // if result can't be computed, use original
                            fCurrentContour->addConic(pointsPtr, weight);
                            break;
                        }
                        SkPoint cStorage[2][3];
                        SkPath::Verb v1 = SkReduceOrder::Conic(pair[0], cStorage[0]);
                        SkPath::Verb v2 = SkReduceOrder::Conic(pair[1], cStorage[1]);
                        SkPoint* curve1 = v1 != SkPath::kLine_Verb ? pair[0].fPts : cStorage[0];
                        SkPoint* curve2 = v2 != SkPath::kLine_Verb ? pair[1].fPts : cStorage[1];
                        if (can_add_curve(v1, curve1) && can_add_curve(v2, curve2)) {
                            fCurrentContour->addCurve(v1, curve1, pair[0].fW);
                            fCurrentContour->addCurve(v2, curve2, pair[1].fW);
                            break;
                        }
                    }
                }
                fCurrentContour->addConic(pointsPtr, weight);
                } break;
            case SkPath::kCubic_Verb:
                {
                    // Split complex cubics (such as self-intersecting curves or
                    // ones with difficult curvature) in two before proceeding.
                    // This can be required for intersection to succeed.
                    SkScalar splitT;
                    if (SkDCubic::ComplexBreak(pointsPtr, &splitT)) {
                        SkPoint pair[7];
                        SkChopCubicAt(pointsPtr, pair, splitT);
                        if (!SkScalarsAreFinite(&pair[0].fX, SK_ARRAY_COUNT(pair) * 2)) {
                            return false;
                        }
                        SkPoint cStorage[2][4];
                        SkPath::Verb v1 = SkReduceOrder::Cubic(&pair[0], cStorage[0]);
                        SkPath::Verb v2 = SkReduceOrder::Cubic(&pair[3], cStorage[1]);
                        SkPoint* curve1 = v1 == SkPath::kCubic_Verb ? &pair[0] : cStorage[0];
                        SkPoint* curve2 = v2 == SkPath::kCubic_Verb ? &pair[3] : cStorage[1];
                        if (can_add_curve(v1, curve1) && can_add_curve(v2, curve2)) {
                            fCurrentContour->addCurve(v1, curve1);
                            fCurrentContour->addCurve(v2, curve2);
                            break;
                        } 
                    }
                }
                fCurrentContour->addCubic(pointsPtr);
                break;
            case SkPath::kClose_Verb:
                SkASSERT(fCurrentContour);
                if (!close()) {
                    return false;
                }
                continue;
            default:
                SkDEBUGFAIL("bad verb");
                return false;
        }
        SkASSERT(fCurrentContour);
        fCurrentContour->debugValidate();
        pointsPtr += SkPathOpsVerbToPoints(verb);
    }
   if (fCurrentContour && fCurrentContour->count() &&!fAllowOpenContours && !close()) {
       return false;
   }
   return true;
}
Exemplo n.º 10
0
sk_sp<SkPathEffect> SkMatrixPathEffect::MakeTranslate(SkScalar dx, SkScalar dy) {
    if (!SkScalarsAreFinite(dx, dy)) {
        return nullptr;
    }
    return sk_sp<SkPathEffect>(new SkMatrixPE(SkMatrix::MakeTrans(dx, dy)));
}
Exemplo n.º 11
0
bool SkOpEdgeBuilder::walk() {
    uint8_t* verbPtr = fPathVerbs.begin();
    uint8_t* endOfFirstHalf = &verbPtr[fSecondHalf];
    SkPoint* pointsPtr = fPathPts.begin() - 1;
    SkScalar* weightPtr = fWeights.begin();
    SkPath::Verb verb;
    SkOpContour* contour = fContourBuilder.contour();
    while ((verb = (SkPath::Verb) *verbPtr) != SkPath::kDone_Verb) {
        if (verbPtr == endOfFirstHalf) {
            fOperand = true;
        }
        verbPtr++;
        switch (verb) {
            case SkPath::kMove_Verb:
                if (contour && contour->count()) {
                    if (fAllowOpenContours) {
                        complete();
                    } else if (!close()) {
                        return false;
                    }
                }
                if (!contour) {
                    fContourBuilder.setContour(contour = fContoursHead->appendContour());
                }
                contour->init(fGlobalState, fOperand,
                    fXorMask[fOperand] == kEvenOdd_PathOpsMask);
                pointsPtr += 1;
                continue;
            case SkPath::kLine_Verb:
                fContourBuilder.addLine(pointsPtr);
                break;
            case SkPath::kQuad_Verb:
                {
                    SkVector v1 = pointsPtr[1] - pointsPtr[0];
                    SkVector v2 = pointsPtr[2] - pointsPtr[1];
                    if (v1.dot(v2) < 0) {
                        SkPoint pair[5];
                        if (SkChopQuadAtMaxCurvature(pointsPtr, pair) == 1) {
                            goto addOneQuad;
                        }
                        if (!SkScalarsAreFinite(&pair[0].fX, SK_ARRAY_COUNT(pair) * 2)) {
                            return false;
                        }
                        for (unsigned index = 0; index < SK_ARRAY_COUNT(pair); ++index) {
                            force_small_to_zero(&pair[index]);
                        }
                        SkPoint cStorage[2][2];
                        SkPath::Verb v1 = SkReduceOrder::Quad(&pair[0], cStorage[0]);
                        SkPath::Verb v2 = SkReduceOrder::Quad(&pair[2], cStorage[1]);
                        SkPoint* curve1 = v1 != SkPath::kLine_Verb ? &pair[0] : cStorage[0];
                        SkPoint* curve2 = v2 != SkPath::kLine_Verb ? &pair[2] : cStorage[1];
                        if (can_add_curve(v1, curve1) && can_add_curve(v2, curve2)) {
                            fContourBuilder.addCurve(v1, curve1);
                            fContourBuilder.addCurve(v2, curve2);
                            break;
                        }
                    }
                }
            addOneQuad:
                fContourBuilder.addQuad(pointsPtr);
                break;
            case SkPath::kConic_Verb: {
                SkVector v1 = pointsPtr[1] - pointsPtr[0];
                SkVector v2 = pointsPtr[2] - pointsPtr[1];
                SkScalar weight = *weightPtr++;
                if (v1.dot(v2) < 0) {
                    // FIXME: max curvature for conics hasn't been implemented; use placeholder
                    SkScalar maxCurvature = SkFindQuadMaxCurvature(pointsPtr);
                    if (maxCurvature > 0) {
                        SkConic conic(pointsPtr, weight);
                        SkConic pair[2];
                        if (!conic.chopAt(maxCurvature, pair)) {
                            // if result can't be computed, use original
                            fContourBuilder.addConic(pointsPtr, weight);
                            break;
                        }
                        SkPoint cStorage[2][3];
                        SkPath::Verb v1 = SkReduceOrder::Conic(pair[0], cStorage[0]);
                        SkPath::Verb v2 = SkReduceOrder::Conic(pair[1], cStorage[1]);
                        SkPoint* curve1 = v1 != SkPath::kLine_Verb ? pair[0].fPts : cStorage[0];
                        SkPoint* curve2 = v2 != SkPath::kLine_Verb ? pair[1].fPts : cStorage[1];
                        if (can_add_curve(v1, curve1) && can_add_curve(v2, curve2)) {
                            fContourBuilder.addCurve(v1, curve1, pair[0].fW);
                            fContourBuilder.addCurve(v2, curve2, pair[1].fW);
                            break;
                        }
                    }
                }
                fContourBuilder.addConic(pointsPtr, weight);
                } break;
            case SkPath::kCubic_Verb:
                {
                    // Split complex cubics (such as self-intersecting curves or
                    // ones with difficult curvature) in two before proceeding.
                    // This can be required for intersection to succeed.
                    SkScalar splitT[3];
                    int breaks = SkDCubic::ComplexBreak(pointsPtr, splitT);
                    if (!breaks) {
                        fContourBuilder.addCubic(pointsPtr);
                        break;
                    }
                    SkASSERT(breaks <= (int) SK_ARRAY_COUNT(splitT));
                    struct Splitsville {
                        double fT[2];
                        SkPoint fPts[4];
                        SkPoint fReduced[4];
                        SkPath::Verb fVerb;
                        bool fCanAdd;
                    } splits[4];
                    SkASSERT(SK_ARRAY_COUNT(splits) == SK_ARRAY_COUNT(splitT) + 1);
                    SkTQSort(splitT, &splitT[breaks - 1]);
                    for (int index = 0; index <= breaks; ++index) {
                        Splitsville* split = &splits[index];
                        split->fT[0] = index ? splitT[index - 1] : 0;
                        split->fT[1] = index < breaks ? splitT[index] : 1;
                        SkDCubic part = SkDCubic::SubDivide(pointsPtr, split->fT[0], split->fT[1]);
                        if (!part.toFloatPoints(split->fPts)) {
                            return false;
                        }
                        split->fVerb = SkReduceOrder::Cubic(split->fPts, split->fReduced);
                        SkPoint* curve = SkPath::kCubic_Verb == verb
                                ? split->fPts : split->fReduced;
                        split->fCanAdd = can_add_curve(split->fVerb, curve);
                    }
                    for (int index = 0; index <= breaks; ++index) {
                        Splitsville* split = &splits[index];
                        if (!split->fCanAdd) {
                            continue;
                        }
                        int prior = index;
                        while (prior > 0 && !splits[prior - 1].fCanAdd) {
                            --prior;
                        }
                        if (prior < index) {
                            split->fT[0] = splits[prior].fT[0];
                            split->fPts[0] = splits[prior].fPts[0];
                        }
                        int next = index;
                        int breakLimit = SkTMin(breaks, (int) SK_ARRAY_COUNT(splits) - 1);
                        while (next < breakLimit && !splits[next + 1].fCanAdd) {
                            ++next;
                        }
                        if (next > index) {
                            split->fT[1] = splits[next].fT[1];
                            split->fPts[3] = splits[next].fPts[3];
                        }
                        if (prior < index || next > index) {
                            split->fVerb = SkReduceOrder::Cubic(split->fPts, split->fReduced);
                        }
                        SkPoint* curve = SkPath::kCubic_Verb == split->fVerb
                                ? split->fPts : split->fReduced;
                        if (!can_add_curve(split->fVerb, curve)) {
                            return false;
                        }
                        fContourBuilder.addCurve(split->fVerb, curve);
                    }
                }
                break;
            case SkPath::kClose_Verb:
                SkASSERT(contour);
                if (!close()) {
                    return false;
                }
                contour = nullptr;
                continue;
            default:
                SkDEBUGFAIL("bad verb");
                return false;
        }
        SkASSERT(contour);
        if (contour->count()) {
            contour->debugValidate();
        }
        pointsPtr += SkPathOpsVerbToPoints(verb);
    }
    fContourBuilder.flush();
    if (contour && contour->count() &&!fAllowOpenContours && !close()) {
        return false;
    }
    return true;
}