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Segment.C

// -*- c-basic-offset: 4 -*-

/*
    Rosegarden-4
    A sequencer and musical notation editor.

    This program is Copyright 2000-2006
        Guillaume Laurent   <glaurent@telegraph-road.org>,
        Chris Cannam        <cannam@all-day-breakfast.com>,
        Richard Bown        <bownie@bownie.com>

    The moral right of the authors to claim authorship of this work
    has been asserted.

    This program is free software; you can redistribute it and/or
    modify it under the terms of the GNU General Public License as
    published by the Free Software Foundation; either version 2 of the
    License, or (at your option) any later version.  See the file
    COPYING included with this distribution for more information.
*/

#include "Segment.h"
#include "NotationTypes.h"
#include "BaseProperties.h"
#include "Composition.h"
#include "Quantizer.h"
#include "Profiler.h"

#include <iostream>
#include <algorithm>
#include <iterator>
#include <cstdio>

namespace Rosegarden 
{
using std::cerr;
using std::endl;
using std::string;

//#define DEBUG_NORMALIZE_RESTS 1    

static int _runtimeSegmentId = 0;

Segment::Segment(SegmentType segmentType, timeT startTime) :
    std::multiset<Event*, Event::EventCmp>(),
    m_composition(0),
    m_startTime(startTime),
    m_endMarkerTime(0),
    m_endTime(startTime),
    m_track(0),
    m_type(segmentType),
    m_colourIndex(0),
    m_id(0),
    m_audioFileId(0),
    m_audioStartTime(0, 0),
    m_audioEndTime(0, 0),
    m_repeating(false),
    m_quantizer(new BasicQuantizer()),
    m_quantize(false),
    m_transpose(0),
    m_delay(0),
    m_realTimeDelay(0, 0),
    m_clefKeyList(0),
    m_runtimeSegmentId(_runtimeSegmentId++),
    m_snapGridSize(-1),
    m_viewFeatures(0),
    m_autoFade(false),
    m_fadeInTime(Rosegarden::RealTime::zeroTime),
    m_fadeOutTime(Rosegarden::RealTime::zeroTime),
    m_highestPlayable(127),
    m_lowestPlayable(0)
{
}

Segment::Segment(const Segment &segment):
    std::multiset<Event*, Event::EventCmp>(),
    m_composition(0), // Composition should decide what's in it and what's not
    m_startTime(segment.getStartTime()),
    m_endMarkerTime(segment.m_endMarkerTime ?
                new timeT(*segment.m_endMarkerTime) : 0),
    m_endTime(segment.getEndTime()),
    m_track(segment.getTrack()),
    m_type(segment.getType()),
    m_label(segment.getLabel()),
    m_colourIndex(segment.getColourIndex()),
    m_id(0),
    m_audioFileId(segment.getAudioFileId()),
    m_audioStartTime(segment.getAudioStartTime()),
    m_audioEndTime(segment.getAudioEndTime()),
    m_repeating(segment.isRepeating()),
    m_quantizer(new BasicQuantizer(segment.m_quantizer->getUnit(),
                           segment.m_quantizer->getDoDurations())),
    m_quantize(segment.hasQuantization()),
    m_transpose(segment.getTranspose()),
    m_delay(segment.getDelay()),
    m_realTimeDelay(segment.getRealTimeDelay()),
    m_clefKeyList(0),
    m_runtimeSegmentId(_runtimeSegmentId++),
    m_snapGridSize(-1),
    m_viewFeatures(0),
    m_autoFade(segment.isAutoFading()),
    m_fadeInTime(segment.getFadeInTime()),
    m_fadeOutTime(segment.getFadeOutTime()),
    m_highestPlayable(127),
    m_lowestPlayable(0)
{
    for (const_iterator it = segment.begin();
       segment.isBeforeEndMarker(it); ++it) {
        insert(new Event(**it));
    }
}

Segment::~Segment()
{
    if (!m_observers.empty()) {
      cerr << "Warning: Segment::~Segment() with " << m_observers.size()
           << " observers still extant" << endl;
      cerr << "Observers are:";
      for (ObserverSet::const_iterator i = m_observers.begin();
           i != m_observers.end(); ++i) {
          cerr << " " << (void *)(*i);
      }
      cerr << endl;
    }

    notifySourceDeletion();

    if (m_composition) m_composition->detachSegment(this);

    if (m_clefKeyList) {
      // don't delete contents of m_clefKeyList: the pointers
      // are just aliases for events in the main segment
      delete m_clefKeyList;
    }

    // Clear EventRulers
    //
    EventRulerListIterator it;
    for (it = m_eventRulerList.begin(); it != m_eventRulerList.end(); ++it) delete *it;
    m_eventRulerList.clear();

    // delete content
    for (iterator it = begin(); it != end(); ++it) delete (*it);

    delete m_endMarkerTime;
}


void
Segment::setTrack(TrackId id)
{
    Composition *c = m_composition;
    if (c) c->weakDetachSegment(this); // sets m_composition to 0
    TrackId oldTrack = m_track;
    m_track = id;
    if (c) {
        c->weakAddSegment(this);
        c->updateRefreshStatuses();
      c->notifySegmentTrackChanged(this, oldTrack, id);
    }
}

timeT
Segment::getStartTime() const
{
    return m_startTime;
}

timeT
Segment::getEndMarkerTime() const
{
    timeT endTime;

    if (m_type == Audio && m_composition) {

      RealTime startRT = m_composition->getElapsedRealTime(m_startTime);
      RealTime endRT = startRT - m_audioStartTime + m_audioEndTime;
      endTime = m_composition->getElapsedTimeForRealTime(endRT);

    } else {

      if (m_endMarkerTime) {
          endTime = *m_endMarkerTime;
      } else {
          endTime = getEndTime();
      }

      if (m_composition) {
          endTime = std::min(endTime, m_composition->getEndMarker());
      }
    }

    return endTime;
}

timeT
Segment::getEndTime() const
{
    if (m_type == Audio && m_composition) {
      RealTime startRT = m_composition->getElapsedRealTime(m_startTime);
      RealTime endRT = startRT - m_audioStartTime + m_audioEndTime;
      return m_composition->getElapsedTimeForRealTime(endRT);
    } else {
      return m_endTime;
    }
}

void
Segment::setStartTime(timeT t)
{
    int dt = t - m_startTime;
    if (dt == 0) return;

    // reset the time of all events.  can't just setAbsoluteTime on these,
    // partly 'cos we're not allowed, partly 'cos it might screw up the
    // quantizer (which is why we're not allowed)

    // still, this is rather unsatisfactory
    
    FastVector<Event *> events;

    for (iterator i = begin(); i != end(); ++i) {
      events.push_back((*i)->copyMoving(dt));
    }

    timeT previousEndTime = m_endTime;

    erase(begin(), end());

    m_endTime = previousEndTime + dt;
    if (m_endMarkerTime) *m_endMarkerTime += dt;

    if (m_composition) m_composition->setSegmentStartTime(this, t);
    else m_startTime = t;

    for (int i = 0; i < events.size(); ++i) {
      insert(events[i]);
    }
}

void
Segment::setEndMarkerTime(timeT t)
{
    if (t < m_startTime) t = m_startTime;

    if (m_type == Audio) {
      if (m_endMarkerTime) *m_endMarkerTime = t;
      else m_endMarkerTime = new timeT(t);
      RealTime oldAudioEndTime = m_audioEndTime;
      if (m_composition) {
          m_audioEndTime = m_audioStartTime +
            m_composition->getRealTimeDifference(m_startTime, t);
          if (oldAudioEndTime != m_audioEndTime) {
            notifyEndMarkerChange(m_audioEndTime < oldAudioEndTime);
          }
      }
    } else {

      timeT endTime = getEndTime();
      timeT oldEndMarker = getEndMarkerTime();
      bool shorten = (t < oldEndMarker);

      if (t > endTime) {
          fillWithRests(endTime, t);
          if (oldEndMarker < endTime) {
              updateRefreshStatuses(oldEndMarker, t);
          }
      } else {
          // only need to do this if we aren't inserting or
          // deleting any actual events
          if (oldEndMarker < t) {
              updateRefreshStatuses(oldEndMarker, t);
          }
          updateRefreshStatuses(t, endTime);
      }

      if (m_endMarkerTime) *m_endMarkerTime = t;
      else m_endMarkerTime = new timeT(t);
      notifyEndMarkerChange(shorten);
    }
}

void
Segment::setEndTime(timeT t)
{
    timeT endTime = getEndTime();
    if (t < m_startTime) t = m_startTime;

    if (m_type == Audio) {
      setEndMarkerTime(t);
    } else {
      if (t < endTime) {
          erase(findTime(t), end());
          endTime = getEndTime();
          if (m_endMarkerTime && endTime < *m_endMarkerTime) {
            *m_endMarkerTime = endTime;
            notifyEndMarkerChange(true);
          }
      } else if (t > endTime) {
          fillWithRests(endTime, t);
      }
    }
}

Segment::iterator 
Segment::getEndMarker()
{
    if (m_endMarkerTime) {
      return findTime(*m_endMarkerTime);
    } else {
      return end();
    }
}

bool
Segment::isBeforeEndMarker(const_iterator i) const
{ 
    if (i == end()) return false;

    timeT absTime = (*i)->getAbsoluteTime();
    timeT endTime = getEndMarkerTime();

    return ((absTime <  endTime) ||
          (absTime == endTime && (*i)->getDuration() == 0));
}

void
Segment::clearEndMarker()
{
    delete m_endMarkerTime;
    m_endMarkerTime = 0;
    notifyEndMarkerChange(false);
}

const timeT *
Segment::getRawEndMarkerTime() const
{
    return m_endMarkerTime;
}


void
Segment::updateRefreshStatuses(timeT startTime, timeT endTime)
{
    for(unsigned int i = 0; i < m_refreshStatusArray.size(); ++i)
        m_refreshStatusArray.getRefreshStatus(i).push(startTime, endTime);
}


Segment::iterator
Segment::insert(Event *e)
{
    assert(e);

    timeT t0 = e->getAbsoluteTime();
    timeT t1 = t0 + e->getDuration();

    if (t0 < m_startTime ||
      (begin() == end() && t0 > m_startTime)) {

        if (m_composition) m_composition->setSegmentStartTime(this, t0);
      else m_startTime = t0;
    }

    if (t1 > m_endTime ||
      begin() == end()) {
      m_endTime = t1;
    }

    iterator i = std::multiset<Event*, Event::EventCmp>::insert(e);
    notifyAdd(e);
    updateRefreshStatuses(e->getAbsoluteTime(),
                    e->getAbsoluteTime() + e->getDuration());
    return i;
}


void
Segment::updateEndTime()
{
    m_endTime = m_startTime;
    for (iterator i = begin(); i != end(); ++i) {
      timeT t = (*i)->getAbsoluteTime() + (*i)->getDuration();
      if (t > m_endTime) m_endTime = t;
    }
}


void
Segment::erase(iterator pos)
{
    Event *e = *pos;

    assert(e);

    timeT t0 = e->getAbsoluteTime();
    timeT t1 = t0 + e->getDuration();

    std::multiset<Event*, Event::EventCmp>::erase(pos);
    notifyRemove(e);
    delete e;
    updateRefreshStatuses(t0, t1);

    if (t0 == m_startTime && begin() != end()) {
      timeT startTime = (*begin())->getAbsoluteTime();
        if (m_composition) m_composition->setSegmentStartTime(this, startTime);
      else m_startTime = startTime;
    }
    if (t1 == m_endTime) {
      updateEndTime();
    }
}


void
Segment::erase(iterator from, iterator to)
{
    timeT startTime = 0, endTime = m_endTime;
    if (from != end()) startTime = (*from)->getAbsoluteTime();
    if (to != end()) endTime = (*to)->getAbsoluteTime() + (*to)->getDuration();

    // Not very efficient, but without an observer event for
    // multiple erase we can't do any better.

    for (Segment::iterator i = from; i != to; ) {

      Segment::iterator j(i);
        ++j;

      Event *e = *i;
      assert(e);

      std::multiset<Event*, Event::EventCmp>::erase(i);
      notifyRemove(e);
      delete e;

      i = j;
    }

    if (startTime == m_startTime && begin() != end()) {
      timeT startTime = (*begin())->getAbsoluteTime();
        if (m_composition) m_composition->setSegmentStartTime(this, startTime);
      else m_startTime = startTime;
    }

    if (endTime == m_endTime) {
      updateEndTime();
    }

    updateRefreshStatuses(startTime, endTime);
}


bool
Segment::eraseSingle(Event* e)
{
    iterator elPos = findSingle(e);

    if (elPos != end()) {

        erase(elPos);
        return true;
            
    } else return false;
    
}


Segment::iterator
Segment::findSingle(Event* e) 
{
    iterator res = end();

    std::pair<iterator, iterator> interval = equal_range(e);

    for (iterator i = interval.first; i != interval.second; ++i) {
        if (*i == e) {
            res = i;
            break;
        }
    }
    return res;
}


Segment::iterator
Segment::findTime(timeT t)
{
    Event dummy("dummy", t, 0, MIN_SUBORDERING);
    return lower_bound(&dummy);
}


Segment::iterator
Segment::findNearestTime(timeT t)
{
    iterator i = findTime(t);
    if (i == end() || (*i)->getAbsoluteTime() > t) {
      if (i == begin()) return end();
      else --i;
    }
    return i;
}


timeT
Segment::getBarStartForTime(timeT t) const
{
    if (t < getStartTime()) t = getStartTime();
    return getComposition()->getBarStartForTime(t);
}


timeT
Segment::getBarEndForTime(timeT t) const
{
    if (t > getEndMarkerTime()) t = getEndMarkerTime();
    return getComposition()->getBarEndForTime(t);
}


int Segment::getNextId() const
{
    return m_id++;
}


void
Segment::fillWithRests(timeT endTime)
{
    fillWithRests(getEndTime(), endTime);
}

void
Segment::fillWithRests(timeT startTime, timeT endTime)
{
    if (startTime < m_startTime) {
        if (m_composition) m_composition->setSegmentStartTime(this, startTime);
      else m_startTime = startTime;
    }

    TimeSignature ts;
    timeT sigTime = 0;

    if (getComposition()) {
      sigTime = getComposition()->getTimeSignatureAt(startTime, ts);
    }

    timeT restDuration = endTime - startTime;
    if (restDuration <= 0) return;

#ifdef DEBUG_NORMALIZE_RESTS
    cerr << "fillWithRests (" << startTime << "->" << endTime << "), composition "
       << (getComposition() ? "exists" : "does not exist") << ", sigTime "
       << sigTime << ", timeSig duration " << ts.getBarDuration() << ", restDuration " << restDuration << endl;
#endif

    DurationList dl;
    ts.getDurationListForInterval(dl, restDuration, startTime - sigTime);

    timeT acc = startTime;

    for (DurationList::iterator i = dl.begin(); i != dl.end(); ++i) {
      Event *e = new Event(Note::EventRestType, acc, *i,
                       Note::EventRestSubOrdering);
      insert(e);
      acc += *i;
    }
}

void
Segment::normalizeRests(timeT startTime, timeT endTime)
{
    Profiler profiler("Segment::normalizeRests");

#ifdef DEBUG_NORMALIZE_RESTS
    cerr << "normalizeRests (" << startTime << "->" << endTime << "), segment starts at " << m_startTime << endl;
#endif

    if (startTime < m_startTime) {
#ifdef DEBUG_NORMALIZE_RESTS
      cerr << "normalizeRests: pulling start time back from "
           << m_startTime << " to " << startTime << endl;
#endif
        if (m_composition) m_composition->setSegmentStartTime(this, startTime);
      else m_startTime = startTime;
    }

    //!!! Need to remove the rests then relocate the start time
    // and get the notation end time for the nearest note before that
    // (?)

    //!!! We need to insert rests at fictitious unquantized times that
    //are broadly correct, so as to maintain ordering of notes and
    //rests in the unquantized segment.  The quantized times should go
    //in notation-prefix properties.

    // Preliminary: If there are any time signature changes between
    // the start and end times, consider separately each of the sections
    // they divide the range up into.

    Composition *composition = getComposition();
    if (composition) {
      int timeSigNo = composition->getTimeSignatureNumberAt(startTime);
      if (timeSigNo < composition->getTimeSignatureCount() - 1) {
          timeT nextSigTime =
            composition->getTimeSignatureChange(timeSigNo + 1).first;
          if (nextSigTime < endTime) {
#ifdef DEBUG_NORMALIZE_RESTS
            cerr << "normalizeRests: divide-and-conquer on timesig at " << nextSigTime << endl;
#endif
            normalizeRests(startTime, nextSigTime);
            normalizeRests(nextSigTime, endTime);
            return;
          }
      }
    }

    // First stage: erase all existing non-tupleted rests in this range.

    timeT segmentEndTime = m_endTime;

    iterator ia = findNearestTime(startTime);
    if (ia == end()) ia = begin();
    if (ia == end()) { // the segment is empty
#ifdef DEBUG_NORMALIZE_RESTS
      cerr << "normalizeRests: empty segment" << endl;
#endif
      fillWithRests(startTime, endTime);
      return;
    } else {
      if (startTime > (*ia)->getNotationAbsoluteTime()) {
          startTime = (*ia)->getNotationAbsoluteTime();
      }
    }

    iterator ib = findTime(endTime);
    if (ib == end()) {
      if (ib != begin()) {
          --ib;
          // if we're pointing at the real-end-time of the last event,
          // use its notation-end-time instead
          if (endTime == (*ib)->getAbsoluteTime() + (*ib)->getDuration()) {
            endTime =
                (*ib)->getNotationAbsoluteTime() +
                (*ib)->getNotationDuration();
          }
          ++ib;
      }
    } else {
      endTime = (*ib)->getNotationAbsoluteTime();
    }

    // If there's a rest preceding the start time, with no notes
    // between us and it, and if it doesn't have precisely the
    // right duration, then we need to normalize it too

    //!!! needs modification for new scheme

    iterator scooter = ia;
    while (scooter-- != begin()) {
//    if ((*scooter)->isa(Note::EventRestType)) { //!!! experimental
      if ((*scooter)->getDuration() > 0) { 
          if ((*scooter)->getNotationAbsoluteTime() +
            (*scooter)->getNotationDuration() !=
            startTime) {
            startTime = (*scooter)->getNotationAbsoluteTime();
#ifdef DEBUG_NORMALIZE_RESTS
            cerr << "normalizeRests: scooting back to " << startTime << endl;
#endif
            ia = scooter;
          }
          break;
/*!!!
      } else if ((*scooter)->getDuration() > 0) {
          break;
*/
      }
    }

    for (iterator i = ia, j = i; i != ib && i != end(); i = j) {
      ++j;
      if ((*i)->isa(Note::EventRestType) &&
          !(*i)->has(BaseProperties::BEAMED_GROUP_TUPLET_BASE)) {
#ifdef DEBUG_NORMALIZE_RESTS
          cerr << "normalizeRests: erasing rest at " << (*i)->getAbsoluteTime() << endl;
#endif
          erase(i);
      }
    }

    // It's possible we've just removed all the events between here
    // and the end of the segment, if they were all rests.  Check.

    if (endTime < segmentEndTime && m_endTime < segmentEndTime) {
      endTime = segmentEndTime;
    }

    // Second stage: find the gaps that need to be filled with
    // rests.  We don't mind about the case where two simultaneous
    // notes end at different times -- we're only interested in
    // the one ending sooner.  Each time an event ends, we start
    // a candidate gap.

    std::vector<std::pair<timeT, timeT> > gaps;

    timeT lastNoteStarts = startTime;
    timeT lastNoteEnds = startTime;
    
    // Re-find this, as it might have been erased
    ia = findNearestTime(startTime);

    if (ia == end()) {
      // already have good lastNoteStarts, lastNoteEnds
      ia = begin();
    } else {
      lastNoteStarts = (*ia)->getNotationAbsoluteTime();
      lastNoteEnds = lastNoteStarts;
    }

    if (ib != end()) {
      //!!! This and related code really need to get a quantized
      // absolute time of a note event that has the same unquantized
      // time as ib, not necessarily of ib itself... or else the
      // quantizer needs to set the quantized times of all non-note
      // events that happen at the same unquantized time as a note
      // event to the same as that of the note event... yeah, that's
      // probably the right thing
      endTime = (*ib)->getNotationAbsoluteTime();

      // was this just a nasty hack?
      ++ib;
    }

    iterator i = ia;

    for (; i != ib && i != end(); ++i) {

      // if we have any rests remaining in this area, treat them
      // as "hard" rests (they had tuplet data, so we don't want to
      // disturb them)
      if (!((*i)->isa(Note::EventType) || (*i)->isa(Note::EventRestType))) {
          continue;
      }

      timeT thisNoteStarts = (*i)->getNotationAbsoluteTime();

#ifdef DEBUG_NORMALIZE_RESTS
      cerr << "normalizeRests: scanning: thisNoteStarts " << thisNoteStarts
           << ", lastNoteStarts " << lastNoteStarts
           << ", lastNoteEnds " << lastNoteEnds << endl;
#endif

      /* BR #988185: "Notation: Rest can be simultaneous with note but follow it"

         This conditional tested whether a note started before the
         preceding note ended, and if so inserted rests simultaneous
         with the preceding note to make up the gap.  Without the
         ability to lay out those rests partwise, this is never any
         better than plain confusing.  Revert the change.

      if (thisNoteStarts < lastNoteEnds &&
          thisNoteStarts > lastNoteStarts) {
          gaps.push_back(std::pair<timeT, timeT>
                     (lastNoteStarts,
                      thisNoteStarts - lastNoteStarts));
      }
      */

      if (thisNoteStarts > lastNoteEnds) {
          gaps.push_back(std::pair<timeT, timeT>
                     (lastNoteEnds,
                      thisNoteStarts - lastNoteEnds));
      }

      lastNoteStarts = thisNoteStarts;
      lastNoteEnds = thisNoteStarts + (*i)->getNotationDuration();
    }

    if (endTime > lastNoteEnds) {
      gaps.push_back(std::pair<timeT, timeT>
                   (lastNoteEnds, endTime - lastNoteEnds));
    }

    timeT duration;

    for (unsigned int gi = 0; gi < gaps.size(); ++gi) {

#ifdef DEBUG_NORMALIZE_RESTS
      cerr << "normalizeRests: gap " << gi << ": " << gaps[gi].first << " -> " << (gaps[gi].first + gaps[gi].second) << endl;
#endif

        startTime = gaps[gi].first;
      duration = gaps[gi].second;

      if (duration >= Note(Note::Shortest).getDuration()) {
          fillWithRests(startTime, startTime + duration);
      }
    }
}



void Segment::getTimeSlice(timeT absoluteTime, iterator &start, iterator &end)
{
    Event dummy("dummy", absoluteTime, 0, MIN_SUBORDERING);

    // No, this won't work -- we need to include things that don't
    // compare equal because they have different suborderings, as long
    // as they have the same times
  
//    std::pair<iterator, iterator> res = equal_range(&dummy);

//    start = res.first;
//    end = res.second;

    // Got to do this instead:

    start = end = lower_bound(&dummy);

    while (end != this->end() &&
         (*end)->getAbsoluteTime() == (*start)->getAbsoluteTime())
      ++end;
}

void Segment::getTimeSlice(timeT absoluteTime, const_iterator &start, const_iterator &end)
    const
{
    Event dummy("dummy", absoluteTime, 0, MIN_SUBORDERING);

    start = end = lower_bound(&dummy);

    while (end != this->end() &&
         (*end)->getAbsoluteTime() == (*start)->getAbsoluteTime())
      ++end;
}

void
Segment::setQuantization(bool quantize)
{
    if (m_quantize != quantize) {
      m_quantize = quantize;
      if (m_quantize) {
          m_quantizer->quantize(this, begin(), end());
      } else {
          m_quantizer->unquantize(this, begin(), end());
      }
    }
}

bool
Segment::hasQuantization() const
{
    return m_quantize;
}

void
Segment::setQuantizeLevel(timeT unit)
{
    if (m_quantizer->getUnit() == unit) return;

    m_quantizer->setUnit(unit);
    if (m_quantize) m_quantizer->quantize(this, begin(), end());
}

const BasicQuantizer *
Segment::getQuantizer() const
{
    return m_quantizer;
}


void
Segment::setRepeating(bool value)
{
    m_repeating = value;
    if (m_composition) {
        m_composition->updateRefreshStatuses();
        m_composition->notifySegmentRepeatChanged(this, value);
    }
}

void
Segment::setDelay(timeT delay)
{
    m_delay = delay;
    if (m_composition) {
        // don't updateRefreshStatuses() - affects playback only 
        m_composition->notifySegmentEventsTimingChanged(this, delay, RealTime::zeroTime);
    }
}

void
Segment::setRealTimeDelay(RealTime delay)
{
    m_realTimeDelay = delay;
    if (m_composition) {
        // don't updateRefreshStatuses() - affects playback only 
        m_composition->notifySegmentEventsTimingChanged(this, 0, delay);
    }
}

void
Segment::setTranspose(int transpose)
{
    m_transpose = transpose;
    if (m_composition) {
        // don't updateRefreshStatuses() - affects playback only 
        m_composition->notifySegmentTransposeChanged(this, transpose);
    }
}

void
Segment::setAudioFileId(unsigned int id)
{
    m_audioFileId = id;
    updateRefreshStatuses(getStartTime(), getEndTime());
}

void
Segment::setAudioStartTime(const RealTime &time)
{
    m_audioStartTime = time;
    updateRefreshStatuses(getStartTime(), getEndTime());
}

void
Segment::setAudioEndTime(const RealTime &time)
{
    RealTime oldAudioEndTime = m_audioEndTime;
    m_audioEndTime = time;
    updateRefreshStatuses(getStartTime(), getEndTime());
    notifyEndMarkerChange(time < oldAudioEndTime);
}

void
Segment::setAutoFade(bool value)
{
    m_autoFade = value;
    updateRefreshStatuses(getStartTime(), getEndTime());
}

void
Segment::setFadeInTime(const RealTime &time)
{
    m_fadeInTime = time;
    updateRefreshStatuses(getStartTime(), getEndTime());
}

void
Segment::setFadeOutTime(const RealTime &time)
{
    m_fadeOutTime = time;
    updateRefreshStatuses(getStartTime(), getEndTime());
}

void
Segment::setLabel(const std::string &label)
{
    m_label = label; 
    if (m_composition) m_composition->updateRefreshStatuses();
    notifyAppearanceChange();
}

bool
Segment::ClefKeyCmp::operator()(const Event *e1, const Event *e2) const
{
    if (e1->getType() == e2->getType()) return Event::EventCmp()(e1, e2);
    else return e1->getType() < e2->getType();
}

Clef
Segment::getClefAtTime(timeT time) const
{
    timeT ctime;
    return getClefAtTime(time, ctime);
}

Clef
Segment::getClefAtTime(timeT time, timeT &ctime) const
{
    if (!m_clefKeyList) return Clef();

    Event ec(Clef::EventType, time);
    ClefKeyList::iterator i = m_clefKeyList->lower_bound(&ec);

    while (i == m_clefKeyList->end() ||
         (*i)->getAbsoluteTime() > time ||
         (*i)->getType() != Clef::EventType) {

      if (i == m_clefKeyList->begin()) {
          ctime = getStartTime();
          return Clef();
      }
      --i;
    }

    try {
      ctime = (*i)->getAbsoluteTime();
      return Clef(**i);
    } catch (const Exception &e) {
      std::cerr << "Segment::getClefAtTime(" << time
              << "): bogus clef in ClefKeyList: event dump follows:"
              << std::endl;
      (*i)->dump(std::cerr);
      return Clef();
    }
}

Key
Segment::getKeyAtTime(timeT time) const
{
    timeT ktime;
    return getKeyAtTime(time, ktime);
}

Key
Segment::getKeyAtTime(timeT time, timeT &ktime) const
{
    if (!m_clefKeyList) return Key();

    Event ek(Key::EventType, time);
    ClefKeyList::iterator i = m_clefKeyList->lower_bound(&ek);

    while (i == m_clefKeyList->end() ||
         (*i)->getAbsoluteTime() > time ||
         (*i)->getType() != Key::EventType) {

      if (i == m_clefKeyList->begin()) {
          ktime = getStartTime();
          return Key();
      }
      --i;
    }

    try {
      ktime = (*i)->getAbsoluteTime();
      return Key(**i);
    } catch (const Exception &e) {
      std::cerr << "Segment::getClefAtTime(" << time
              << "): bogus key in ClefKeyList: event dump follows:"
              << std::endl;
      (*i)->dump(std::cerr);
      return Key();
    }
}

timeT
Segment::getRepeatEndTime() const
{
    if (m_repeating && m_composition) {
      Composition::iterator i(m_composition->findSegment(this));
      assert(i != m_composition->end());
      ++i;
      if (i != m_composition->end() && (*i)->getTrack() == getTrack()) {
          return (*i)->getStartTime();
      } else {
            return m_composition->getEndMarker();
      }
    }
    return getEndMarkerTime();
}


void
Segment::notifyAdd(Event *e) const
{
    if (e->isa(Clef::EventType) || e->isa(Key::EventType)) {
      if (!m_clefKeyList) m_clefKeyList = new ClefKeyList;
      m_clefKeyList->insert(e);
    }

    for (ObserverSet::const_iterator i = m_observers.begin();
       i != m_observers.end(); ++i) {
      (*i)->eventAdded(this, e);
    }
}

 
void
Segment::notifyRemove(Event *e) const
{
    if (m_clefKeyList && (e->isa(Clef::EventType) || e->isa(Key::EventType))) {
      ClefKeyList::iterator i; 
      for (i = m_clefKeyList->find(e); i != m_clefKeyList->end(); ++i) {
            // fix for bug#1485643 (crash erasing a duplicated key signature)
            if ((*i) == e) {
              m_clefKeyList->erase(i);
                break;
            }
      }
    }
    
    for (ObserverSet::const_iterator i = m_observers.begin();
       i != m_observers.end(); ++i) {
      (*i)->eventRemoved(this, e);
    }
}
 

void
Segment::notifyAppearanceChange() const
{
    for (ObserverSet::const_iterator i = m_observers.begin();
       i != m_observers.end(); ++i) {
      (*i)->appearanceChanged(this);
    }
}

void
Segment::notifyEndMarkerChange(bool shorten)
{
    for (ObserverSet::const_iterator i = m_observers.begin();
       i != m_observers.end(); ++i) {
      (*i)->endMarkerTimeChanged(this, shorten);
    }
    if (m_composition) {
      m_composition->notifySegmentEndMarkerChange(this, shorten);
    }
}


void
Segment::notifySourceDeletion() const
{
    for (ObserverSet::const_iterator i = m_observers.begin();
       i != m_observers.end(); ++i) {
      (*i)->segmentDeleted(this);
    }
}


void
Segment::setColourIndex(const unsigned int input)
{
    m_colourIndex = input;
    updateRefreshStatuses(getStartTime(), getEndTime());
    if (m_composition) m_composition->updateRefreshStatuses();
    notifyAppearanceChange();
}

void
Segment::addEventRuler(const std::string &type, int controllerValue, bool active)
{
    EventRulerListConstIterator it;

    for (it = m_eventRulerList.begin(); it != m_eventRulerList.end(); ++it)
        if ((*it)->m_type == type && (*it)->m_controllerValue == controllerValue)
            return;

    m_eventRulerList.push_back(new EventRuler(type, controllerValue, active));
}

bool 
Segment::deleteEventRuler(const std::string &type, int controllerValue)
{
    EventRulerListIterator it;

    for (it = m_eventRulerList.begin(); it != m_eventRulerList.end(); ++it)
    {
        if ((*it)->m_type == type && (*it)->m_controllerValue == controllerValue)
        {
            delete *it;
            m_eventRulerList.erase(it);
            return true;
        }
    }

    return false;
}

Segment::EventRuler*
Segment::getEventRuler(const std::string &type, int controllerValue)
{
    EventRulerListConstIterator it;
    for (it = m_eventRulerList.begin(); it != m_eventRulerList.end(); ++it)
        if ((*it)->m_type == type && (*it)->m_controllerValue == controllerValue)
            return *it;

    return 0;
}



SegmentHelper::~SegmentHelper() { }


void 
SegmentRefreshStatus::push(timeT from, timeT to)
{
    if (!needsRefresh()) { // don't do anything subtle - just erase the old data

        m_from = from;
        m_to = to;

    } else { // accumulate on what was already there

        if (from < m_from) m_from = from;
        if (to > m_to) m_to = to;

    }

    if (m_to < m_from) std::swap(m_from, m_to);

    setNeedsRefresh(true);
}



 
}

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