Exemplo n.º 1
0
int Measure::AdjustXPos(FunctorParams *functorParams)
{
    AdjustXPosParams *params = dynamic_cast<AdjustXPosParams *>(functorParams);
    assert(params);

    params->m_minPos = 0;
    params->m_upcomingMinPos = VRV_UNSET;
    params->m_cumulatedXShift = 0;

    std::vector<int>::iterator iter;
    ArrayOfComparisons filters;
    for (iter = params->m_staffNs.begin(); iter != params->m_staffNs.end(); ++iter) {
        params->m_minPos = 0;
        params->m_upcomingMinPos = VRV_UNSET;
        params->m_cumulatedXShift = 0;
        params->m_staffN = (*iter);
        filters.clear();
        // Create ad comparison object for each type / @n
        std::vector<int> ns;
        // -1 for barline attributes that need to be taken into account each time
        ns.push_back(-1);
        ns.push_back(*iter);
        AttNIntegerComparisonAny matchStaff(ALIGNMENT_REFERENCE, ns);
        filters.push_back(&matchStaff);

        m_measureAligner.Process(params->m_functor, params, params->m_functorEnd, &filters);
    }

    // m_measureAligner.Process(params->m_functor, params, params->m_functorEnd);

    int minMeasureWidth
        = params->m_doc->GetOptions()->m_unit.GetValue() * params->m_doc->GetOptions()->m_measureMinWidth.GetValue();
    // First try to see if we have a double measure length element
    MeasureAlignerTypeComparison alignmentComparison(ALIGNMENT_FULLMEASURE2);
    Alignment *fullMeasure2
        = dynamic_cast<Alignment *>(m_measureAligner.FindChildByComparison(&alignmentComparison, 1));

    // With a double measure with element (mRpt2, multiRpt)
    if (fullMeasure2 != NULL) {
        minMeasureWidth *= 2;
    }
    // Nothing if the measure has at least one note or @metcon="false"
    else if ((this->FindChildByType(NOTE) != NULL) || (this->GetMetcon() == BOOLEAN_false)) {
        minMeasureWidth = 0;
    }

    int currentMeasureWidth = this->GetRightBarLineLeft() - this->GetLeftBarLineRight();
    if (currentMeasureWidth < minMeasureWidth) {
        ArrayOfAdjustmentTuples boundaries{ std::make_tuple(this->GetLeftBarLine()->GetAlignment(),
            this->GetRightBarLine()->GetAlignment(), minMeasureWidth - currentMeasureWidth) };
        m_measureAligner.AdjustProportionally(boundaries);
    }

    return FUNCTOR_SIBLINGS;
}
Exemplo n.º 2
0
data_STEMDIRECTION Layer::GetDrawingStemDir(double time, double duration, Measure *measure, int staff)
{
    assert(measure);

    Functor findSpaceInAlignment(&Object::FindSpaceInReferenceAlignments);
    FindSpaceInAlignmentParams findSpaceInAlignmentParams(
        GetCurrentMeterSig(), GetCurrentMensur(), &findSpaceInAlignment);
    findSpaceInAlignmentParams.m_time = time;
    findSpaceInAlignmentParams.m_duration = duration;

    ArrayOfComparisons filters;
    AttNIntegerComparison matchStaff(ALIGNMENT_REFERENCE, staff);
    filters.push_back(&matchStaff);

    measure->m_measureAligner.Process(&findSpaceInAlignment, &findSpaceInAlignmentParams, NULL, &filters);

    if (findSpaceInAlignmentParams.m_success && (findSpaceInAlignmentParams.m_layerCount < 3)) {
        return STEMDIRECTION_NONE;
    }

    return m_drawingStemDir;
}
Exemplo n.º 3
0
int Measure::AdjustLayers(FunctorParams *functorParams)
{
    AdjustLayersParams *params = dynamic_cast<AdjustLayersParams *>(functorParams);
    assert(params);

    if (!m_hasAlignmentRefWithMultipleLayers) return FUNCTOR_SIBLINGS;

    std::vector<int>::iterator iter;
    ArrayOfComparisons filters;
    for (iter = params->m_staffNs.begin(); iter != params->m_staffNs.end(); ++iter) {
        filters.clear();
        // Create ad comparison object for each type / @n
        std::vector<int> ns;
        // -1 for barline attributes that need to be taken into account each time
        ns.push_back(-1);
        ns.push_back(*iter);
        AttNIntegerComparisonAny matchStaff(ALIGNMENT_REFERENCE, ns);
        filters.push_back(&matchStaff);

        m_measureAligner.Process(params->m_functor, params, NULL, &filters);
    }

    return FUNCTOR_SIBLINGS;
}
Exemplo n.º 4
0
float View::CalcInitialSlur(
    FloatingCurvePositioner *curve, Slur *slur, Staff *staff, int layerN, curvature_CURVEDIR curveDir, Point points[4])
{
    // For readability makes them p1 and p2
    Point p1 = points[0];
    Point p2 = points[3];

    /************** height **************/

    // the 'height' of the bezier
    int height;
    if (slur->HasBulge()) {
        height = m_doc->GetDrawingUnit(staff->m_drawingStaffSize) * slur->GetBulge();
    }
    else {
        int dist = abs(p2.x - p1.x);
        height = std::max(int(m_options->m_slurMinHeight.GetValue() * m_doc->GetDrawingUnit(staff->m_drawingStaffSize)),
            dist / m_options->m_slurHeightFactor.GetValue());
        height = std::min(
            int(m_options->m_slurMaxHeight.GetValue() * m_doc->GetDrawingUnit(staff->m_drawingStaffSize)), height);
    }

    // the height of the control points
    height = height * 4 / 3;

    /************** content **************/

    System *system = dynamic_cast<System *>(staff->GetFirstParent(SYSTEM));
    assert(system);
    FindSpannedLayerElementsParams findSpannedLayerElementsParams(slur, slur);
    findSpannedLayerElementsParams.m_minPos = p1.x;
    findSpannedLayerElementsParams.m_maxPos = p2.x;
    findSpannedLayerElementsParams.m_classIds
        = { ACCID, ARTIC_PART, ARTIC, CHORD, FLAG, NOTE, STEM, TIE, TUPLET_BRACKET, TUPLET_NUM };
    ArrayOfComparisons filters;
    // Create ad comparison object for each type / @n
    // For now we only look at one layer (assumed layer1 == layer2)
    AttNIntegerComparison matchStaff(STAFF, staff->GetN());
    AttNIntegerComparison matchLayer(LAYER, layerN);
    filters.push_back(&matchStaff);
    filters.push_back(&matchLayer);

    Functor findSpannedLayerElements(&Object::FindSpannedLayerElements);
    system->Process(&findSpannedLayerElements, &findSpannedLayerElementsParams, NULL, &filters);

    curve->ClearSpannedElements();
    for (auto &element : findSpannedLayerElementsParams.m_elements) {

        Point pRotated;
        Point pLeft;
        pLeft.x = element->GetSelfLeft();
        // if ((pLeft.x > p1->x) && (pLeft.x < p2->x)) {
        //    pLeft.y = (curveDir == curvature_CURVEDIR_above) ? element->GetSelfTop() : element->GetSelfBottom();
        //    spannedElements->push_back(spannedElement);
        //}
        Point pRight;
        pRight.x = element->GetSelfRight();
        // if ((pRight.x > p1->x) && (pRight.x < p2->x)) {
        //    pRight.y = (curveDir == curvature_CURVEDIR_above) ? element->GetSelfTop() : element->GetSelfBottom();
        //    spannedElements->push_back(spannedElement);
        //}
        if (((pLeft.x > p1.x) && (pLeft.x < p2.x)) || ((pRight.x > p1.x) && (pRight.x < p2.x))) {
            CurveSpannedElement *spannedElement = new CurveSpannedElement;
            spannedElement->m_boundingBox = element;
            curve->AddSpannedElement(spannedElement);
        }
    }

    for (auto &positioner : findSpannedLayerElementsParams.m_ties) {
        CurveSpannedElement *spannedElement = new CurveSpannedElement;
        spannedElement->m_boundingBox = positioner;
        curve->AddSpannedElement(spannedElement);
    }

    /************** angle **************/

    const ArrayOfCurveSpannedElements *spannedElements = curve->GetSpannedElements();
    float slurAngle = slur->GetAdjustedSlurAngle(m_doc, p1, p2, curveDir, (spannedElements->size() > 0));
    Point rotatedP2 = BoundingBox::CalcPositionAfterRotation(p2, -slurAngle, p1);

    /************** control points **************/

    Point rotatedC1, rotatedC2;
    slur->GetControlPoints(m_doc, p1, rotatedP2, rotatedC1, rotatedC2, curveDir, height, staff->m_drawingStaffSize);

    points[0] = p1;
    points[1] = BoundingBox::CalcPositionAfterRotation(rotatedC1, slurAngle, p1);
    points[2] = BoundingBox::CalcPositionAfterRotation(rotatedC2, slurAngle, p1);
    points[3] = BoundingBox::CalcPositionAfterRotation(rotatedP2, slurAngle, p1);

    return slurAngle;
}