// -*- c-basic-offset: 4 -*- /* Rosegarden A sequencer and musical notation editor. This program is Copyright 2000-2008 Guillaume Laurent , Chris Cannam , Richard Bown This file is Copyright 2002 Randall Farmer with additional work by Chris Cannam. 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. */ // !!!TODO: handle timeslices #include #include #include "CompositionTimeSliceAdapter.h" #include "Segment.h" #include "Composition.h" #include "Selection.h" namespace Rosegarden { using std::list; using std::pair; CompositionTimeSliceAdapter::CompositionTimeSliceAdapter(Composition *c, timeT begin, timeT end) : m_composition(c), m_begin(begin), m_end(end) { if (begin == end) { m_begin = 0; m_end = c->getDuration(); } for (Composition::iterator ci = m_composition->begin(); ci != m_composition->end(); ++ci) { m_segmentList.push_back(*ci); } } CompositionTimeSliceAdapter::CompositionTimeSliceAdapter(Composition *c, SegmentSelection* s, timeT begin, timeT end) : m_composition(c), m_begin(begin), m_end(end) { if (begin == end) { m_begin = 0; m_end = c->getDuration(); } for (Composition::iterator ci = m_composition->begin(); ci != m_composition->end(); ++ci) { if (!s || s->find(*ci) != s->end()) { m_segmentList.push_back(*ci); } } } CompositionTimeSliceAdapter::CompositionTimeSliceAdapter(Composition *c, const TrackSet &trackIDs, timeT begin, timeT end) : m_composition(c), m_begin(begin), m_end(end) { if (begin == end) { m_begin = 0; m_end = c->getDuration(); } for (Composition::iterator ci = m_composition->begin(); ci != m_composition->end(); ++ci) { if (trackIDs.find((*ci)->getTrack()) != trackIDs.end()) { m_segmentList.push_back(*ci); } } } CompositionTimeSliceAdapter::iterator CompositionTimeSliceAdapter::begin() const { if (m_beginItr.m_a == 0) { m_beginItr = iterator(this); fill(m_beginItr, false); } return m_beginItr; } CompositionTimeSliceAdapter::iterator CompositionTimeSliceAdapter::end() const { return iterator(this); } void CompositionTimeSliceAdapter::fill(iterator &i, bool atEnd) const { // The segment iterators should all point to events starting at or // after m_begin (if atEnd false) or at or before m_end (if atEnd true). for (unsigned int k = 0; k < m_segmentList.size(); ++k) { Segment::iterator j = m_segmentList[k]->findTime(atEnd ? m_end : m_begin); i.m_segmentItrList.push_back(j); } // fill m_curEvent & m_curTrack if (!atEnd) ++i; } CompositionTimeSliceAdapter::iterator& CompositionTimeSliceAdapter::iterator::operator=(const iterator &i) { if (&i == this) return *this; m_segmentItrList.clear(); for (segmentitrlist::const_iterator j = i.m_segmentItrList.begin(); j != i.m_segmentItrList.end(); ++j) { m_segmentItrList.push_back(Segment::iterator(*j)); } m_a = i.m_a; m_curTrack = i.m_curTrack; m_curEvent = i.m_curEvent; m_needFill = i.m_needFill; return *this; } CompositionTimeSliceAdapter::iterator::iterator(const iterator &i) : m_a(i.m_a), m_curEvent(i.m_curEvent), m_curTrack(i.m_curTrack), m_needFill(i.m_needFill) { for (segmentitrlist::const_iterator j = i.m_segmentItrList.begin(); j != i.m_segmentItrList.end(); ++j) { m_segmentItrList.push_back(Segment::iterator(*j)); } } CompositionTimeSliceAdapter::iterator& CompositionTimeSliceAdapter::iterator::operator++() { assert(m_a != 0); // needFill is only set true for iterators created at end() if (m_needFill) { m_a->fill(*this, true); m_needFill = false; } Event *e = 0; unsigned int pos = 0; for (unsigned int i = 0; i < m_a->m_segmentList.size(); ++i) { if (!m_a->m_segmentList[i]->isBeforeEndMarker(m_segmentItrList[i])) continue; if (!e || strictLessThan(*m_segmentItrList[i], e)) { e = *m_segmentItrList[i]; m_curTrack = m_a->m_segmentList[i]->getTrack(); pos = i; } } // Check whether we're past the end time, if there is one if (!e || e->getAbsoluteTime() >= m_a->m_end) { m_curEvent = 0; m_curTrack = -1; return *this; } // e is now an Event* less than or equal to any that the iterator // hasn't already passed over m_curEvent = e; // m_segmentItrList[pos] is a segment::iterator that points to e ++m_segmentItrList[pos]; return *this; } CompositionTimeSliceAdapter::iterator& CompositionTimeSliceAdapter::iterator::operator--() { assert(m_a != 0); // needFill is only set true for iterators created at end() if (m_needFill) { m_a->fill(*this, true); m_needFill = false; } Event *e = 0; int pos = -1; // Decrement is more subtle than increment. We have to scan the // iterators available, and decrement the one that points to // m_curEvent. Then to fill m_curEvent we need to find the next // greatest event back that is not itself m_curEvent. for (unsigned int i = 0; i < m_a->m_segmentList.size(); ++i) { if (m_segmentItrList[i] == m_a->m_segmentList[i]->begin()) continue; Segment::iterator si(m_segmentItrList[i]); --si; if (*si == m_curEvent) { pos = i; } else if (!e || !strictLessThan(*si, e)) { e = *si; m_curTrack = m_a->m_segmentList[i]->getTrack(); } } if (e) m_curEvent = e; if (pos >= 0) { --m_segmentItrList[pos]; } return *this; } bool CompositionTimeSliceAdapter::iterator::operator==(const iterator& other) const { return m_a == other.m_a && m_curEvent == other.m_curEvent; } bool CompositionTimeSliceAdapter::iterator::operator!=(const iterator& other) const { return !operator==(other); } Event * CompositionTimeSliceAdapter::iterator::operator*() const { return m_curEvent; } Event & CompositionTimeSliceAdapter::iterator::operator->() const { return *m_curEvent; } int CompositionTimeSliceAdapter::iterator::getTrack() const { return m_curTrack; } bool CompositionTimeSliceAdapter::iterator::strictLessThan(Event *e1, Event *e2) { // We need a complete ordering of events -- we can't cope with two events // comparing equal. i.e. one of e1 < e2 and e2 < e1 must be true. The // ordering can be arbitrary -- we just compare addresses for events the // event comparator doesn't distinguish between. We know we're always // dealing with event pointers, not copies of events. if (*e1 < *e2) return true; else if (*e2 < *e1) return false; else return e1 < e2; } }