/* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */ /* Rosegarden A MIDI and audio sequencer and musical notation editor. Copyright 2000-2011 the Rosegarden development team. Other copyrights also apply to some parts of this work. Please see the AUTHORS file and individual file headers for details. 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 "MupExporter.h" #include "misc/Debug.h" #include "base/BaseProperties.h" #include "base/Composition.h" #include "base/Event.h" #include "base/Exception.h" #include "base/NotationQuantizer.h" #include "base/NotationTypes.h" #include "base/Segment.h" #include "base/SegmentNotationHelper.h" #include "base/Sets.h" #include "base/Track.h" #include "gui/general/ProgressReporter.h" #include using std::string; namespace Rosegarden { using namespace BaseProperties; MupExporter::MupExporter(QObject *parent, Composition *composition, string fileName) : ProgressReporter(parent, "mupExporter"), m_composition(composition), m_fileName(fileName) { // nothing else } MupExporter::~MupExporter() { // nothing } bool MupExporter::write() { Composition *c = m_composition; std::ofstream str(m_fileName.c_str(), std::ios::out); if (!str) { std::cerr << "MupExporter::write() - can't write file " << m_fileName << std::endl; return false; } str << "score\n"; str << "\tstaffs=" << c->getNbTracks() << "\n"; int ts = c->getTimeSignatureCount(); std::pair tspair; if (ts > 0) tspair = c->getTimeSignatureChange(0); str << "\ttime=" << tspair.second.getNumerator() << "/" << tspair.second.getDenominator() << "\n"; for (int barNo = -1; barNo < c->getNbBars(); ++barNo) { for (TrackId trackNo = c->getMinTrackId(); trackNo <= c->getMaxTrackId(); ++trackNo) { if (barNo < 0) { writeClefAndKey(str, trackNo); continue; } if (barNo == 0 && trackNo == 0) { str << "\nmusic\n"; } str << "\t" << trackNo + 1 << ":"; Segment *s = 0; timeT barStart = c->getBarStart(barNo); timeT barEnd = c->getBarEnd(barNo); for (Composition::iterator ci = c->begin(); ci != c->end(); ++ci) { if ((*ci)->getTrack() == trackNo && (*ci)->getStartTime() < barEnd && (*ci)->getEndMarkerTime() > barStart) { s = *ci; break; } } TimeSignature timeSig(c->getTimeSignatureAt(barStart)); if (!s) { // write empty bar writeInventedRests(str, timeSig, 0, barEnd - barStart); continue; } if (s->getStartTime() > barStart) { writeInventedRests(str, timeSig, 0, s->getStartTime() - barStart); } // Mup insists that every bar has the correct duration, and won't // recover if one goes wrong. Keep careful tabs on this: it means // that for example we have to round chord durations down where // the next chord starts too soon //!!! we _really_ can't cope with time sig changes yet! timeT writtenDuration = writeBar(str, c, s, barStart, barEnd, timeSig, trackNo); if (writtenDuration < timeSig.getBarDuration()) { RG_DEBUG << "writtenDuration: " << writtenDuration << ", bar duration " << timeSig.getBarDuration() << endl; writeInventedRests(str, timeSig, writtenDuration, timeSig.getBarDuration() - writtenDuration); } else if (writtenDuration > timeSig.getBarDuration()) { std::cerr << "WARNING: overfull bar in Mup export: duration " << writtenDuration << " into bar of duration " << timeSig.getBarDuration() << std::endl; //!!! warn user } str << "\n"; } if (barNo >= 0) str << "bar" << std::endl; } str << "\n" << std::endl; str.close(); return true; } timeT MupExporter::writeBar(std::ofstream &str, Composition *c, Segment *s, timeT barStart, timeT barEnd, TimeSignature &timeSig, TrackId trackNo) { timeT writtenDuration = 0; SegmentNotationHelper helper(*s); helper.setNotationProperties(); long currentGroupId = -1; string currentGroupType = ""; long currentTupletCount = 3; bool first = true; bool openBeamWaiting = false; for (Segment::iterator si = SegmentNotationHelper(*s).findNotationAbsoluteTime(barStart); s->isBeforeEndMarker(si) && (*si)->getNotationAbsoluteTime() < barEnd; ++si) { if ((*si)->isa(Note::EventType)) { Chord chord(*s, si, c->getNotationQuantizer()); Event *e = *chord.getInitialNote(); timeT absTime = e->getNotationAbsoluteTime(); timeT duration = e->getNotationDuration(); try { // tuplet compensation, etc Note::Type type = e->get(NOTE_TYPE); int dots = e->get (NOTE_DOTS); duration = Note(type, dots).getDuration(); } catch (Exception e) { // no properties std::cerr << "WARNING: MupExporter::writeBar: incomplete note properties: " << e.getMessage() << std::endl; } timeT toNext = duration; Segment::iterator nextElt = chord.getFinalElement(); if (s->isBeforeEndMarker(++nextElt)) { toNext = (*nextElt)->getNotationAbsoluteTime() - absTime; if (toNext < duration) duration = toNext; } bool enteringGroup = false; if (e->has(BEAMED_GROUP_ID) && e->has(BEAMED_GROUP_TYPE)) { long id = e->get (BEAMED_GROUP_ID); string type = e->get (BEAMED_GROUP_TYPE); if (id != currentGroupId) { // leave previous group first if (currentGroupId >= 0) { if (!openBeamWaiting) str << " ebm"; openBeamWaiting = false; if (currentGroupType == GROUP_TYPE_TUPLED) { str << "; }" << currentTupletCount; } } currentGroupId = id; currentGroupType = type; enteringGroup = true; } } else { if (currentGroupId >= 0) { if (!openBeamWaiting) str << " ebm"; openBeamWaiting = false; if (currentGroupType == GROUP_TYPE_TUPLED) { str << "; }" << currentTupletCount; } currentGroupId = -1; currentGroupType = ""; } } if (openBeamWaiting) str << " bm"; if (!first) str << ";"; str << " "; if (currentGroupType == GROUP_TYPE_TUPLED) { e->get (BEAMED_GROUP_UNTUPLED_COUNT, currentTupletCount); if (enteringGroup) str << "{ "; //!!! duration = helper.getCompensatedNotationDuration(e); } writeDuration(str, duration); if (toNext > duration && currentGroupType != GROUP_TYPE_TUPLED) { writeInventedRests (str, timeSig, absTime + duration - barStart, toNext - duration); } writtenDuration += toNext; for (Chord::iterator chi = chord.begin(); chi != chord.end(); ++chi) { writePitch(str, trackNo, **chi); } openBeamWaiting = false; if (currentGroupType == GROUP_TYPE_BEAMED || currentGroupType == GROUP_TYPE_TUPLED) { if (enteringGroup) openBeamWaiting = true; } si = chord.getFinalElement(); first = false; } else if ((*si)->isa(Note::EventRestType)) { if (currentGroupId >= 0) { if (!openBeamWaiting) str << " ebm"; openBeamWaiting = false; if (currentGroupType == GROUP_TYPE_TUPLED) { str << "; }" << currentTupletCount; } currentGroupId = -1; currentGroupType = ""; } if (openBeamWaiting) str << " bm"; if (!first) str << ";"; str << " "; writeDuration(str, (*si)->getNotationDuration()); writtenDuration += (*si)->getNotationDuration(); str << "r"; first = false; openBeamWaiting = false; } // ignore all other sorts of events for now } if (currentGroupId >= 0) { if (!openBeamWaiting) str << " ebm"; openBeamWaiting = false; if (currentGroupType == GROUP_TYPE_TUPLED) { str << "; }" << currentTupletCount; } } if (openBeamWaiting) str << " bm"; if (!first) str << ";"; return writtenDuration; } void MupExporter::writeClefAndKey(std::ofstream &str, TrackId trackNo) { Composition *c = m_composition; for (Composition::iterator i = c->begin(); i != c->end(); ++i) { if ((*i)->getTrack() == trackNo) { Clef clef((*i)->getClefAtTime((*i)->getStartTime())); Rosegarden::Key key((*i)->getKeyAtTime((*i)->getStartTime())); str << "staff " << trackNo + 1 << "\n"; if (clef.getClefType() == Clef::Treble) { str << "\tclef=treble\n"; } else if (clef.getClefType() == Clef::Alto) { str << "\tclef=alto\n"; } else if (clef.getClefType() == Clef::Tenor) { str << "\tclef=tenor\n"; } else if (clef.getClefType() == Clef::Bass) { str << "\tclef=bass\n"; } str << "\tkey=" << key.getAccidentalCount() << (key.isSharp() ? "#" : "&") << (key.isMinor() ? "minor" : "major") << std::endl; m_clefKeyMap[trackNo] = ClefKeyPair(clef, key); return ; } } } void MupExporter::writeInventedRests(std::ofstream &str, TimeSignature &timeSig, timeT offset, timeT duration) { str << " "; DurationList dlist; timeSig.getDurationListForInterval(dlist, duration, offset); for (DurationList::iterator i = dlist.begin(); i != dlist.end(); ++i) { writeDuration(str, *i); str << "r;"; } } void MupExporter::writePitch(std::ofstream &str, TrackId trackNo, Event *event) { long pitch = 0; if (!event->get (PITCH, pitch)) { str << "c"; // have to write something, or it won't parse return ; } Accidental accidental = Accidentals::NoAccidental; (void)event->get (ACCIDENTAL, accidental); // mup octave: treble clef is in octave 4? ClefKeyPair ck; ClefKeyMap::iterator ckmi = m_clefKeyMap.find(trackNo); if (ckmi != m_clefKeyMap.end()) ck = ckmi->second; Pitch p(pitch, accidental); Accidental acc(p.getDisplayAccidental(ck.second)); char note(p.getNoteName(ck.second)); int octave(p.getOctave()); // just to avoid assuming that the note names returned by Pitch are in // the same set as those expected by Mup -- in practice they are the same // letters but this changes the case str << "cdefgab"[Pitch::getIndexForNote(note)]; if (acc == Accidentals::DoubleFlat) str << "&&"; else if (acc == Accidentals::Flat) str << "&"; else if (acc == Accidentals::Sharp) str << "#"; else if (acc == Accidentals::DoubleSharp) str << "##"; else if (acc == Accidentals::Natural) str << "n"; str << octave + 1; } void MupExporter::writeDuration(std::ofstream &str, timeT duration) { Note note(Note::getNearestNote(duration, 2)); int n = Note::Semibreve - note.getNoteType(); if (n < 0) str << "1/" << (1 << ( -n)); else str << (1 << n); for (int d = 0; d < note.getDots(); ++d) str << "."; } }