MuseScore/libmscore/tuplet.cpp
2014-05-23 10:35:27 +02:00

942 lines
33 KiB
C++

//=============================================================================
// MuseScore
// Music Composition & Notation
//
// Copyright (C) 2002-2011 Werner Schweer
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License version 2
// as published by the Free Software Foundation and appearing in
// the file LICENCE.GPL
//=============================================================================
#include "tuplet.h"
#include "score.h"
#include "chord.h"
#include "note.h"
#include "xml.h"
#include "staff.h"
#include "style.h"
#include "text.h"
#include "element.h"
#include "undo.h"
#include "stem.h"
#include "beam.h"
#include "measure.h"
namespace Ms {
//---------------------------------------------------------
// Tuplet
//---------------------------------------------------------
Tuplet::Tuplet(Score* s)
: DurationElement(s)
{
setFlags(ElementFlag::MOVABLE | ElementFlag::SELECTABLE);
_numberType = Tuplet::SHOW_NUMBER;
_bracketType = Tuplet::AUTO_BRACKET;
_number = 0;
_hasBracket = false;
_isUp = true;
_direction = Direction::AUTO;
}
Tuplet::Tuplet(const Tuplet& t)
: DurationElement(t)
{
_tick = t._tick;
_numberType = t._numberType;
_bracketType = t._bracketType;
_hasBracket = t._hasBracket;
_ratio = t._ratio;
_baseLen = t._baseLen;
_direction = t._direction;
_isUp = t._isUp;
p1 = t.p1;
p2 = t.p2;
_p1 = t._p1;
_p2 = t._p2;
if (t._number)
_number = new Text(*t._number);
else
_number = 0;
}
//---------------------------------------------------------
// ~Tuplet
//---------------------------------------------------------
Tuplet::~Tuplet()
{
//
// delete all references
//
foreach(DurationElement* e, _elements)
e->setTuplet(0);
delete _number;
}
//---------------------------------------------------------
// setSelected
//---------------------------------------------------------
void Tuplet::setSelected(bool f)
{
Element::setSelected(f);
if (_number)
_number->setSelected(f);
}
//---------------------------------------------------------
// setVisible
//---------------------------------------------------------
void Tuplet::setVisible(bool f)
{
Element::setVisible(f);
if (_number)
_number->setVisible(f);
}
//---------------------------------------------------------
// layout
//---------------------------------------------------------
void Tuplet::layout()
{
if (_elements.empty()) {
qDebug("Tuplet::layout(): tuplet is empty");
return;
}
// is in a TAB without stems, skip any format: tuplets are not shown
if (staff() && staff()->isTabStaff() && staff()->staffType()->slashStyle())
return;
qreal _spatium = spatium();
if (_numberType != NO_TEXT) {
if (_number == 0) {
_number = new Text(score());
_number->setTextStyleType(TEXT_STYLE_TUPLET);
_number->setTrack(track());
_number->setParent(this);
_number->setVisible(visible());
}
if (_numberType == SHOW_NUMBER)
_number->setText(QString("%1").arg(_ratio.numerator()));
else
_number->setText(QString("%1:%2").arg(_ratio.numerator()).arg(_ratio.denominator()));
}
else {
if (_number) {
if (_number->selected())
score()->deselect(_number);
delete _number;
_number = 0;
}
}
//
// find out main direction
//
if (_direction == Direction::AUTO) {
int up = 1;
foreach (const DurationElement* e, _elements) {
if (e->type() == ElementType::CHORD) {
const Chord* c = static_cast<const Chord*>(e);
if (c->stemDirection() != Direction::AUTO)
up += c->stemDirection() == Direction::UP ? 1000 : -1000;
else
up += c->up() ? 1 : -1;
}
else if (e->type() == ElementType::TUPLET) {
// TODO
}
}
_isUp = up > 0;
}
else
_isUp = _direction == Direction::UP;
const DurationElement* cr1 = _elements.front();
while (cr1->type() == ElementType::TUPLET) {
const Tuplet* t = static_cast<const Tuplet*>(cr1);
if (t->elements().empty())
break;
cr1 = t->elements().front();
}
const DurationElement* cr2 = _elements.back();
while (cr2->type() == ElementType::TUPLET) {
const Tuplet* t = static_cast<const Tuplet*>(cr2);
if (t->elements().empty())
break;
cr2 = t->elements().back();
}
//
// shall we draw a bracket?
//
if (_bracketType == AUTO_BRACKET) {
_hasBracket = false;
foreach (DurationElement* e, _elements) {
if (e->type() == ElementType::TUPLET || e->type() == ElementType::REST) {
_hasBracket = true;
break;
}
else if (e->isChordRest()) {
ChordRest* cr = static_cast<ChordRest*>(e);
//
// maybe we should check for more than one beam
//
if (cr->beam() == 0) {
_hasBracket = true;
break;
}
}
}
}
else
_hasBracket = _bracketType != SHOW_NO_BRACKET;
//
// calculate bracket start and end point p1 p2
//
qreal maxSlope = score()->styleD(ST_tupletMaxSlope);
bool outOfStaff = score()->styleB(ST_tupletOufOfStaff);
qreal vHeadDistance = score()->styleS(ST_tupletVHeadDistance).val() * _spatium;
qreal vStemDistance = score()->styleS(ST_tupletVStemDistance).val() * _spatium;
qreal stemLeft = score()->styleS(ST_tupletStemLeftDistance).val() * _spatium;
qreal stemRight = score()->styleS(ST_tupletStemRightDistance).val() * _spatium;
qreal noteLeft = score()->styleS(ST_tupletNoteLeftDistance).val() * _spatium;
qreal noteRight = score()->styleS(ST_tupletNoteRightDistance).val() * _spatium;
qreal l1 = _spatium; // bracket tip height
qreal l2l = vHeadDistance; // left bracket vertical distance
qreal l2r = vHeadDistance; // right bracket vertical distance right
if (_isUp)
vHeadDistance = -vHeadDistance;
p1 = cr1->pagePos();
p2 = cr2->pagePos();
p1.rx() -= noteLeft;
p2.rx() += score()->noteHeadWidth() + noteRight;
p1.ry() += vHeadDistance;
p2.ry() += vHeadDistance;
qreal xx1 = p1.x(); // use to center the number on the beam
if (_isUp) {
if (cr1->type() == ElementType::CHORD) {
const Chord* chord1 = static_cast<const Chord*>(cr1);
Stem* stem = chord1->stem();
if (stem)
xx1 = stem->abbox().x();
if (chord1->up()) {
if (stem) {
if (chord1->beam())
p1.ry() = chord1->beam()->abbox().y();
else
p1.ry() = stem->abbox().y();
l2l = vStemDistance;
}
else {
p1.ry() = chord1->upNote()->abbox().top(); // whole note
}
}
else if (!chord1->up()) {
p1.ry() = chord1->upNote()->abbox().top();
if(stem)
p1.rx() = cr1->pagePos().x() - stemLeft;
}
}
if (cr2->type() == ElementType::CHORD) {
const Chord* chord2 = static_cast<const Chord*>(cr2);
Stem* stem = chord2->stem();
if (stem && chord2->up()) {
if(chord2->beam())
p2.ry() = chord2->beam()->abbox().top();
else
p2.ry() = stem->abbox().top();
l2r = vStemDistance;
p2.rx() = chord2->pagePos().x() + chord2->maxHeadWidth() + stemRight;
}
else {
p2.ry() = chord2->upNote()->abbox().top();
}
}
//
// special case: one of the bracket endpoints is
// a rest
//
if (cr1->type() != ElementType::CHORD && cr2->type() == ElementType::CHORD) {
if (p2.y() < p1.y())
p1.setY(p2.y());
else
p2.setY(p1.y());
}
else if (cr1->type() == ElementType::CHORD && cr2->type() != ElementType::CHORD) {
if (p1.y() < p2.y())
p2.setY(p1.y());
else
p1.setY(p2.y());
}
// outOfStaff
if(outOfStaff) {
qreal min = cr1->measure()->staffabbox(cr1->staffIdx()).y();
if (min < p1.y()) {
p1.ry() = min;
l2l = vStemDistance;
}
min = cr2->measure()->staffabbox(cr2->staffIdx()).y();
if (min < p2.y()) {
p2.ry() = min;
l2r = vStemDistance;
}
}
//check that slope is no more than 30°
qreal d = (p2.y() - p1.y())/(p2.x() - p1.x());
if (d < -maxSlope) {
// move p1 y up
p1.ry() = p2.y() + maxSlope * (p2.x() - p1.x());
}
else if (d > maxSlope) {
// move p2 y up
p2.ry() = p1.ry() + maxSlope * (p2.x() - p1.x());
}
// check for collisions
int n = _elements.size();
if (n >= 3) {
d = (p2.y() - p1.y())/(p2.x() - p1.x());
for (int i = 1; i < (n-1); ++i) {
Element* e = _elements[i];
if (e->type() == ElementType::CHORD) {
const Chord* chord = static_cast<const Chord*>(e);
const Stem* stem = chord->stem();
if (stem) {
QRectF r(chord->up() ? stem->abbox() : chord->abbox());
qreal y3 = r.top();
qreal x3 = r.x() + r.width() * .5;
qreal y0 = p1.y() + (x3 - p1.x()) * d;
qreal c = y0 - y3;
if (c > 0) {
p1.ry() -= c;
p2.ry() -= c;
}
}
}
}
}
}
else {
if (cr1->type() == ElementType::CHORD) {
const Chord* chord1 = static_cast<const Chord*>(cr1);
Stem* stem = chord1->stem();
if (stem)
xx1 = stem->abbox().x();
if (!chord1->up()) {
if(stem) {
if(chord1->beam())
p1.ry() = chord1->beam()->abbox().bottom();
else
p1.ry() = stem->abbox().bottom();
l2l = vStemDistance;
p1.rx() = cr1->pagePos().x() - stemLeft;
}
else{
p1.ry() = chord1->downNote()->abbox().bottom(); // whole note
}
}
else if (chord1->up()) {
p1.ry() = chord1->downNote()->abbox().bottom();
}
}
if (cr2->type() == ElementType::CHORD) {
const Chord* chord2 = static_cast<const Chord*>(cr2);
Stem* stem = chord2->stem();
if (stem && !chord2->up()) {
// if (chord2->beam())
// p2.setX(stem->abbox().x());
if(chord2->beam())
p2.ry() = chord2->beam()->abbox().bottom();
else
p2.ry() = stem->abbox().bottom();
l2r = vStemDistance;
}
else {
p2.ry() = chord2->downNote()->abbox().bottom();
if (stem)
p2.rx() = chord2->pagePos().x() + chord2->maxHeadWidth() + stemRight;
}
}
//
// special case: one of the bracket endpoints is
// a rest
//
if (cr1->type() != ElementType::CHORD && cr2->type() == ElementType::CHORD) {
if (p2.y() > p1.y())
p1.setY(p2.y());
else
p2.setY(p1.y());
}
else if (cr1->type() == ElementType::CHORD && cr2->type() != ElementType::CHORD) {
if (p1.y() > p2.y())
p2.setY(p1.y());
else
p1.setY(p2.y());
}
// outOfStaff
if(outOfStaff) {
qreal max = cr1->measure()->staffabbox(cr1->staffIdx()).bottom();
if (max > p1.y()) {
p1.ry() = max;
l2l = vStemDistance;
}
max = cr2->measure()->staffabbox(cr2->staffIdx()).bottom();
if (max > p2.y()) {
p2.ry() = max;
l2r = vStemDistance;
}
}
//check that slope is no more than 30°
qreal d = (p2.y() - p1.y())/(p2.x() - p1.x());
if (d < -maxSlope) {
// move p1 y up
p2.ry() = p1.y() - maxSlope * (p2.x() - p1.x());
}
else if (d > maxSlope) {
// move p2 y up
p1.ry() = p2.ry() - maxSlope * (p2.x() - p1.x());
}
// check for collisions
int n = _elements.size();
if (n >= 3) {
qreal d = (p2.y() - p1.y())/(p2.x() - p1.x());
for (int i = 1; i < (n-1); ++i) {
Element* e = _elements[i];
if (e->type() == ElementType::CHORD) {
const Chord* chord = static_cast<const Chord*>(e);
const Stem* stem = chord->stem();
if (stem) {
QRectF r(chord->up() ? chord->abbox() : stem->abbox());
qreal y3 = r.bottom();
qreal x3 = r.x() + r.width() * .5;
qreal y0 = p1.y() + (x3 - p1.x()) * d;
qreal c = y0 - y3;
if (c < 0) {
p1.ry() -= c;
p2.ry() -= c;
}
}
}
}
}
}
setPos(0.0, 0.0);
QPointF mp(parent()->pagePos());
p1 -= mp;
p2 -= mp;
p1 += _p1;
p2 += _p2;
xx1 -= mp.x();
p1.ry() -= l2l * (_isUp ? 1.0 : -1.0);
p2.ry() -= l2r * (_isUp ? 1.0 : -1.0);
// center number
qreal x3 = 0.0;
qreal numberWidth = 0.0;
if (_number) {
_number->layout();
numberWidth = _number->bbox().width();
//
// for beamed tuplets, center number on beam
//
if (cr1->beam() && cr2->beam() && cr1->beam() == cr2->beam()) {
const ChordRest* crr = static_cast<const ChordRest*>(cr1);
if(_isUp == crr->up()) {
qreal deltax = cr2->pagePos().x() - cr1->pagePos().x();
x3 = xx1 + deltax * .5;
}
else {
qreal deltax = p2.x() - p1.x();
x3 = p1.x() + deltax * .5;
}
}
else {
qreal deltax = p2.x() - p1.x();
x3 = p1.x() + deltax * .5;
}
qreal y3 = p1.y() + (p2.y() - p1.y()) * .5 - l1 * (_isUp ? 1.0 : -1.0);
_number->setPos(QPointF(x3, y3) - ipos());
}
if (_hasBracket) {
qreal slope = (p2.y() - p1.y()) / (p2.x() - p1.x());
if (_isUp) {
if (_number) {
bracketL[0] = QPointF(p1.x(), p1.y());
bracketL[1] = QPointF(p1.x(), p1.y() - l1);
qreal x = x3 - numberWidth * .5 - _spatium * .5;
qreal y = p1.y() + (x - p1.x()) * slope;
bracketL[2] = QPointF(x, y - l1);
x = x3 + numberWidth * .5 + _spatium * .5;
y = p1.y() + (x - p1.x()) * slope;
bracketR[0] = QPointF(x, y - l1);
bracketR[1] = QPointF(p2.x(), p2.y() - l1);
bracketR[2] = QPointF(p2.x(), p2.y());
}
else {
bracketL[0] = QPointF(p1.x(), p1.y());
bracketL[1] = QPointF(p1.x(), p1.y() - l1);
bracketL[2] = QPointF(p2.x(), p2.y() - l1);
bracketL[3] = QPointF(p2.x(), p2.y());
}
}
else {
if (_number) {
bracketL[0] = QPointF(p1.x(), p1.y());
bracketL[1] = QPointF(p1.x(), p1.y() + l1);
qreal x = x3 - numberWidth * .5 - _spatium * .5;
qreal y = p1.y() + (x - p1.x()) * slope;
bracketL[2] = QPointF(x, y + l1);
x = x3 + numberWidth * .5 + _spatium * .5;
y = p1.y() + (x - p1.x()) * slope;
bracketR[0] = QPointF(x, y + l1);
bracketR[1] = QPointF(p2.x(), p2.y() + l1);
bracketR[2] = QPointF(p2.x(), p2.y());
}
else {
bracketL[0] = QPointF(p1.x(), p1.y());
bracketL[1] = QPointF(p1.x(), p1.y() + l1);
bracketL[2] = QPointF(p2.x(), p2.y() + l1);
bracketL[3] = QPointF(p2.x(), p2.y());
}
}
}
QRectF r;
if (_number) {
r |= _number->bbox().translated(_number->pos());
if (_hasBracket) {
QRectF b;
b.setCoords(bracketL[1].x(), bracketL[1].y(), bracketR[2].x(), bracketR[2].y());
r |= b;
}
}
else if (_hasBracket) {
QRectF b;
b.setCoords(bracketL[1].x(), bracketL[1].y(), bracketL[3].x(), bracketL[3].y());
r |= b;
}
setbbox(r);
}
//---------------------------------------------------------
// draw
//---------------------------------------------------------
void Tuplet::draw(QPainter* painter) const
{
// if in a TAB without stems, tuplets are not shown
if (staff() && staff()->isTabStaff() && staff()->staffType()->slashStyle())
return;
QColor color(curColor());
if (_number) {
painter->setPen(color);
QPointF pos(_number->pos());
painter->translate(pos);
_number->draw(painter);
painter->translate(-pos);
}
if (_hasBracket) {
painter->setPen(QPen(color, spatium() * .1));
if (!_number)
painter->drawPolyline(bracketL, 4);
else {
painter->drawPolyline(bracketL, 3);
painter->drawPolyline(bracketR, 3);
}
}
}
//---------------------------------------------------------
// write
//---------------------------------------------------------
void Tuplet::write(Xml& xml) const
{
xml.stag(QString("Tuplet id=\"%1\"").arg(_id));
if (tuplet())
xml.tag("Tuplet", tuplet()->id());
Element::writeProperties(xml);
writeProperty(xml, P_DIRECTION);
writeProperty(xml, P_NUMBER_TYPE);
writeProperty(xml, P_BRACKET_TYPE);
writeProperty(xml, P_NORMAL_NOTES);
writeProperty(xml, P_ACTUAL_NOTES);
writeProperty(xml, P_P1);
writeProperty(xml, P_P2);
xml.tag("baseNote", _baseLen.name());
if (_number) {
xml.stag("Number");
_number->writeProperties(xml);
xml.etag();
}
if (!userOff().isNull())
xml.tag("offset", userOff() / spatium());
xml.etag();
}
//---------------------------------------------------------
// read
//---------------------------------------------------------
void Tuplet::read(XmlReader& e)
{
int bl = -1;
_id = e.intAttribute("id", 0);
while (e.readNextStartElement()) {
const QStringRef& tag(e.name());
if (tag == "direction")
setProperty(P_DIRECTION, Ms::getProperty(P_DIRECTION, e));
else if (tag == "numberType")
_numberType = e.readInt();
else if (tag == "bracketType")
_bracketType = e.readInt();
else if (tag == "normalNotes")
_ratio.setDenominator(e.readInt());
else if (tag == "actualNotes")
_ratio.setNumerator(e.readInt());
else if (tag == "p1")
_p1 = e.readPoint();
else if (tag == "p2")
_p2 = e.readPoint();
else if (tag == "baseNote")
_baseLen = TDuration(e.readElementText());
else if (tag == "Number") {
_number = new Text(score());
_number->setParent(this);
_number->read(e);
_number->setTextStyleType(TEXT_STYLE_TUPLET);
_number->setVisible(visible()); //?? override saved property
_number->setTrack(track());
}
else if (tag == "subtype") // obsolete
e.skipCurrentElement();
else if (tag == "hasNumber") // obsolete
_numberType = e.readInt() ? SHOW_NUMBER : NO_TEXT;
else if (tag == "hasLine") { // obsolete
_hasBracket = e.readInt();
_bracketType = AUTO_BRACKET;
}
else if (tag == "baseLen") // obsolete
bl = e.readInt();
else if (!DurationElement::readProperties(e))
e.unknown();
}
Fraction f(_ratio.denominator(), _baseLen.fraction().denominator());
setDuration(f);
if (bl != -1) { // obsolete
TDuration d;
d.setVal(bl);
_baseLen = d;
// qDebug("Tuplet base len %d/%d", d.fraction().numerator(), d.fraction().denominator());
// qDebug(" %s dots %d, %d/%d", qPrintable(d.name()), d.dots(), _ratio.numerator(), _ratio.denominator());
d.setVal(bl * _ratio.denominator());
setDuration(d.fraction());
}
}
//---------------------------------------------------------
// add
//---------------------------------------------------------
void Tuplet::add(Element* e)
{
#ifndef NDEBUG
foreach(DurationElement* el, _elements) {
if (el == e) {
qFatal("Tuplet::add: %p %s already there", e, e->name());
}
}
#endif
switch(e->type()) {
case ElementType::TEXT:
_number = static_cast<Text*>(e);
break;
case ElementType::CHORD:
case ElementType::REST:
case ElementType::TUPLET: {
bool found = false;
DurationElement* de = static_cast<DurationElement*>(e);
int tick = de->tick();
if (tick != -1) {
for (int i = 0; i < _elements.size(); ++i) {
if (_elements[i]->tick() > tick) {
_elements.insert(i, de);
found = true;
break;
}
}
}
if (!found)
_elements.append(de);
de->setTuplet(this);
// the tick position of a tuplet is the tick position of its
// first element:
setTick(_elements.front()->tick());
}
break;
default:
qDebug("Tuplet::add() unknown element");
break;
}
}
//---------------------------------------------------------
// remove
//---------------------------------------------------------
void Tuplet::remove(Element* e)
{
switch(e->type()) {
case ElementType::TEXT:
if (e == _number)
_number = 0;
break;
case ElementType::CHORD:
case ElementType::REST:
case ElementType::TUPLET:
if (!_elements.removeOne(static_cast<DurationElement*>(e))) {
qDebug("Tuplet::remove: cannot find element <%s>", e->name());
qDebug(" elements %d", _elements.size());
}
break;
default:
qDebug("Tuplet::remove: unknown element");
break;
}
}
//---------------------------------------------------------
// isEditable
//---------------------------------------------------------
bool Tuplet::isEditable() const
{
return _hasBracket;
}
//---------------------------------------------------------
// editDrag
//---------------------------------------------------------
void Tuplet::editDrag(const EditData& ed)
{
if (ed.curGrip == 0)
_p1 += ed.delta;
else
_p2 += ed.delta;
setGenerated(false);
layout();
score()->setUpdateAll(true);
}
//---------------------------------------------------------
// updateGrips
//---------------------------------------------------------
void Tuplet::updateGrips(int* grips, int* defaultGrip, QRectF*grip) const
{
*grips = 2;
*defaultGrip = 1;
grip[0].translate(pagePos() + p1);
grip[1].translate(pagePos() + p2);
}
//---------------------------------------------------------
// reset
//---------------------------------------------------------
void Tuplet::reset()
{
score()->addRefresh(canvasBoundingRect());
undoChangeProperty(P_P1, QPointF());
undoChangeProperty(P_P2, QPointF());
undoChangeProperty(P_DIRECTION, propertyDefault(P_DIRECTION));
Element::reset();
layout();
score()->addRefresh(canvasBoundingRect());
}
//---------------------------------------------------------
// dump
//---------------------------------------------------------
void Tuplet::dump() const
{
Element::dump();
qDebug("ratio %s", qPrintable(_ratio.print()));
}
//---------------------------------------------------------
// setTrack
//---------------------------------------------------------
void Tuplet::setTrack(int val)
{
if (_number)
_number->setTrack(val);
Element::setTrack(val);
}
//---------------------------------------------------------
// tickGreater
//---------------------------------------------------------
static bool tickGreater(const DurationElement* a, const DurationElement* b)
{
return a->tick() < b->tick();
}
//---------------------------------------------------------
// sortElements
//---------------------------------------------------------
void Tuplet::sortElements()
{
qSort(_elements.begin(), _elements.end(), tickGreater);
}
//---------------------------------------------------------
// elementsDuration
/// Get the sum of the element fraction in the tuplet,
/// even if the tuplet is not complete yet
//---------------------------------------------------------
Fraction Tuplet::elementsDuration()
{
Fraction f;
foreach(DurationElement* el, _elements)
f += el->duration();
return f;
}
//---------------------------------------------------------
// getProperty
//---------------------------------------------------------
QVariant Tuplet::getProperty(P_ID propertyId) const
{
switch(propertyId) {
case P_DIRECTION:
return int(_direction);
case P_NUMBER_TYPE:
return _numberType;
case P_BRACKET_TYPE:
return _bracketType;
case P_NORMAL_NOTES:
return _ratio.denominator();
case P_ACTUAL_NOTES:
return _ratio.numerator();
case P_P1:
return _p1;
case P_P2:
return _p2;
default:
break;
}
return DurationElement::getProperty(propertyId);
}
//---------------------------------------------------------
// setProperty
//---------------------------------------------------------
bool Tuplet::setProperty(P_ID propertyId, const QVariant& v)
{
score()->addRefresh(canvasBoundingRect());
switch(propertyId) {
case P_DIRECTION:
setDirection(Direction(v.toInt()));
break;
case P_NUMBER_TYPE:
setNumberType(v.toInt());
break;
case P_BRACKET_TYPE:
setBracketType(v.toInt());
break;
case P_NORMAL_NOTES:
_ratio.setDenominator(v.toInt());
break;
case P_ACTUAL_NOTES:
_ratio.setNumerator(v.toInt());
break;
case P_P1:
_p1 = v.toPointF();
break;
case P_P2:
_p2 = v.toPointF();
break;
default:
return DurationElement::setProperty(propertyId, v);
break;
}
score()->setLayoutAll(true);
return true;
}
//---------------------------------------------------------
// propertyDefault
//---------------------------------------------------------
QVariant Tuplet::propertyDefault(P_ID id) const
{
switch(id) {
case P_DIRECTION:
return int(Direction::AUTO);
case P_NUMBER_TYPE:
return Tuplet::SHOW_NUMBER;
case P_BRACKET_TYPE:
return Tuplet::AUTO_BRACKET;
case P_NORMAL_NOTES:
case P_ACTUAL_NOTES:
return 1;
case P_P1:
case P_P2:
return QPointF();
default:
return DurationElement::propertyDefault(id);
}
}
}