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livetrax/libs/evoral/Sequence.cc

1449 lines
41 KiB
C++

/*
* Copyright (C) 2008-2012 Hans Baier <hansfbaier@googlemail.com>
* Copyright (C) 2008-2016 David Robillard <d@drobilla.net>
* Copyright (C) 2008-2017 Paul Davis <paul@linuxaudiosystems.com>
* Copyright (C) 2009-2011 Carl Hetherington <carl@carlh.net>
* Copyright (C) 2014-2019 Robin Gareus <robin@gareus.org>
*
* 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.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License along
* with this program; if not, write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/
#include <algorithm>
#include <cmath>
#include <iostream>
#include <limits>
#include <stdexcept>
#include <stdint.h>
#include <cstdio>
#if __clang__
#include "evoral/Note.h"
#endif
#include "pbd/compose.h"
#include "pbd/error.h"
#include "temporal/beats.h"
#include "evoral/Control.h"
#include "evoral/ControlList.h"
#include "evoral/ControlSet.h"
#include "evoral/EventSink.h"
#include "evoral/ParameterDescriptor.h"
#include "evoral/Sequence.h"
#include "evoral/TypeMap.h"
#include "evoral/midi_util.h"
#include "pbd/i18n.h"
using namespace std;
using namespace PBD;
/** Minimum time between MIDI outputs from a single interpolated controller,
expressed in beats. This is to limit the rate at which MIDI messages
are generated. It is only applied to interpolated controllers.
XXX: This is a hack. The time should probably be expressed in
seconds rather than beats, and should be configurable etc. etc.
*/
static Temporal::Beats const time_between_interpolated_controller_outputs = Temporal::Beats::ticks (256);
namespace Evoral {
// Read iterator (const_iterator)
template<typename Time>
Sequence<Time>::const_iterator::const_iterator()
: _seq(NULL)
, _event(boost::shared_ptr< Event<Time> >(new Event<Time>()))
, _active_patch_change_message (NO_EVENT)
, _type(NIL)
, _is_end(true)
, _control_iter(_control_iters.end())
, _force_discrete(false)
{
}
/** @param force_discrete true to force ControlLists to use discrete evaluation, otherwise false to get them to use their configured mode */
template<typename Time>
Sequence<Time>::const_iterator::const_iterator(const Sequence<Time>& seq,
Time t,
bool force_discrete,
const std::set<Evoral::Parameter>& filtered,
std::set<WeakNotePtr> const * active_notes)
: _seq(&seq)
, _active_patch_change_message (0)
, _type(NIL)
, _is_end((t == DBL_MAX) || seq.empty())
, _note_iter(seq.notes().end())
, _sysex_iter(seq.sysexes().end())
, _patch_change_iter(seq.patch_changes().end())
, _control_iter(_control_iters.end())
, _force_discrete (force_discrete)
{
DEBUG_TRACE (DEBUG::Sequence, string_compose ("Created Iterator @ %1 (is end: %2)\n)", t, _is_end));
if (_is_end) {
return;
}
_lock = seq.read_lock();
// Add currently active notes, if given
if (active_notes) {
for (typename std::set<WeakNotePtr>::const_iterator i = active_notes->begin(); i != active_notes->end(); ++i) {
NotePtr note = i->lock();
if (note && note->time() <= t && note->end_time() > t) {
_active_notes.push(note);
}
}
}
// Find first note which begins at or after t
_note_iter = seq.note_lower_bound(t);
// Find first sysex event at or after t
for (typename Sequence<Time>::SysExes::const_iterator i = seq.sysexes().begin();
i != seq.sysexes().end(); ++i) {
if ((*i)->time() >= t) {
_sysex_iter = i;
break;
}
}
assert(_sysex_iter == seq.sysexes().end() || (*_sysex_iter)->time() >= t);
// Find first patch event at or after t
for (typename Sequence<Time>::PatchChanges::const_iterator i = seq.patch_changes().begin(); i != seq.patch_changes().end(); ++i) {
if ((*i)->time() >= t) {
_patch_change_iter = i;
break;
}
}
assert (_patch_change_iter == seq.patch_changes().end() || (*_patch_change_iter)->time() >= t);
// Find first control event after t
_control_iters.reserve(seq._controls.size());
bool found = false;
size_t earliest_control_index = 0;
Temporal::timepos_t earliest_control_x = std::numeric_limits<Temporal::timepos_t>::max();
for (Controls::const_iterator i = seq._controls.begin(); i != seq._controls.end(); ++i) {
if (filtered.find (i->first) != filtered.end()) {
/* this parameter is filtered, so don't bother setting up an iterator for it */
continue;
}
DEBUG_TRACE (DEBUG::Sequence, string_compose ("Iterator: control: %1\n", seq._type_map.to_symbol(i->first)));
Temporal::timepos_t xtime (Temporal::AudioTime); /* domain may change */
double y;
bool ret;
if (_force_discrete || i->second->list()->interpolation() == ControlList::Discrete) {
ret = i->second->list()->rt_safe_earliest_event_discrete_unlocked (Temporal::timepos_t (t), xtime, y, true);
} else {
ret = i->second->list()->rt_safe_earliest_event_linear_unlocked(Temporal::timepos_t (t), xtime, y, true);
}
if (!ret) {
DEBUG_TRACE (DEBUG::Sequence, string_compose ("Iterator: CC %1 (size %2) has no events past %3\n",
i->first.id(), i->second->list()->size(), t));
continue;
}
const ParameterDescriptor& desc = seq.type_map().descriptor(i->first);
if (y < desc.lower || y > desc.upper) {
cerr << "ERROR: Controller value " << y
<< " out of range [" << desc.lower << "," << desc.upper
<< "], event ignored" << endl;
continue;
}
DEBUG_TRACE (DEBUG::Sequence, string_compose ("Iterator: CC %1 added (%2, %3)\n", i->first.id(), xtime, y));
const ControlIterator new_iter(i->second->list(), xtime, y);
_control_iters.push_back(new_iter);
// Found a new earliest_control
if (xtime < earliest_control_x) {
earliest_control_x = xtime;
earliest_control_index = _control_iters.size() - 1;
found = true;
}
}
if (found) {
_control_iter = _control_iters.begin() + earliest_control_index;
assert(_control_iter != _control_iters.end());
assert(_control_iter->list);
} else {
_control_iter = _control_iters.end();
}
// Choose the earliest event overall to point to
choose_next(t);
// Allocate a new event for storing the current event in MIDI format
_event = boost::shared_ptr< Event<Time> >(
new Event<Time>(NO_EVENT, Time(), 4, NULL, true));
// Set event from chosen sub-iterator
set_event();
if (_is_end) {
DEBUG_TRACE(DEBUG::Sequence,
string_compose("Starting at end @ %1\n", t));
} else {
DEBUG_TRACE(DEBUG::Sequence,
string_compose("Starting at type 0x%1 : 0x%2 @ %3\n",
(int)_event->event_type(),
(int)_event->buffer()[0],
_event->time()));
}
}
template<typename Time>
void
Sequence<Time>::const_iterator::get_active_notes (std::set<WeakNotePtr>& active_notes) const
{
/* can't iterate over a std::priority_queue<> such as ActiveNotes */
ActiveNotes copy (_active_notes);
while (!copy.empty()) {
active_notes.insert (copy.top());
copy.pop ();
}
}
template<typename Time>
void
Sequence<Time>::const_iterator::invalidate(bool preserve_active_notes)
{
if (!preserve_active_notes) {
_active_notes = ActiveNotes();
}
_type = NIL;
_is_end = true;
if (_seq) {
_note_iter = _seq->notes().end();
_sysex_iter = _seq->sysexes().end();
_patch_change_iter = _seq->patch_changes().end();
_active_patch_change_message = 0;
}
_control_iters.clear();
_control_iter = _control_iters.end();
_lock.reset();
}
template<typename Time>
Time
Sequence<Time>::const_iterator::choose_next(Time earliest_t)
{
_type = NIL;
// Next earliest note on, if any
if (_note_iter != _seq->notes().end()) {
_type = NOTE_ON;
earliest_t = (*_note_iter)->time();
}
/* Use the next earliest patch change iff it is earlier or coincident with the note-on.
* A patch-change with the same time-stamp applies to the concurrent note-on */
if (_patch_change_iter != _seq->patch_changes().end()) {
if (_type == NIL || (*_patch_change_iter)->time() <= earliest_t) {
_type = PATCH_CHANGE;
earliest_t = (*_patch_change_iter)->time();
}
}
/* Use the next earliest controller iff it's earlier or coincident with the note-on
* or patch-change. Bank-select (CC0, CC32) needs to be sent before the PGM. */
if (_control_iter != _control_iters.end() &&
_control_iter->list && _control_iter->x != std::numeric_limits<Temporal::timepos_t>::max()) {
if (_type == NIL || _control_iter->x <= earliest_t) {
_type = CONTROL;
earliest_t = _control_iter->x.beats();
}
}
/* .. but prefer to send any Note-off first */
if ((!_active_notes.empty())) {
if (_type == NIL || _active_notes.top()->end_time() <= earliest_t) {
_type = NOTE_OFF;
earliest_t = _active_notes.top()->end_time();
}
}
/* SysEx is last, always sent after any other concurrent 3 byte event */
if (_sysex_iter != _seq->sysexes().end()) {
if (_type == NIL || (*_sysex_iter)->time() < earliest_t) {
_type = SYSEX;
earliest_t = (*_sysex_iter)->time();
}
}
return earliest_t;
}
template<typename Time>
void
Sequence<Time>::const_iterator::set_event()
{
switch (_type) {
case NOTE_ON:
DEBUG_TRACE(DEBUG::Sequence, "iterator = note on\n");
_event->assign ((*_note_iter)->on_event());
_active_notes.push(*_note_iter);
break;
case NOTE_OFF:
DEBUG_TRACE(DEBUG::Sequence, "iterator = note off\n");
assert(!_active_notes.empty());
_event->assign (_active_notes.top()->off_event());
// We don't pop the active note until we increment past it
break;
case SYSEX:
DEBUG_TRACE(DEBUG::Sequence, "iterator = sysex\n");
_event->assign (*(*_sysex_iter));
break;
case CONTROL:
DEBUG_TRACE(DEBUG::Sequence, "iterator = control\n");
_seq->control_to_midi_event(_event, *_control_iter);
break;
case PATCH_CHANGE:
DEBUG_TRACE(DEBUG::Sequence, "iterator = program change\n");
_event->assign ((*_patch_change_iter)->message (_active_patch_change_message));
break;
default:
_is_end = true;
break;
}
if (_type == NIL || !_event || _event->size() == 0) {
DEBUG_TRACE(DEBUG::Sequence, "iterator = end\n");
_type = NIL;
_is_end = true;
} else {
assert(midi_event_is_valid(_event->buffer(), _event->size()));
}
}
template<typename Time>
const typename Sequence<Time>::const_iterator&
Sequence<Time>::const_iterator::operator++()
{
if (_is_end) {
throw std::logic_error("Attempt to iterate past end of Sequence");
}
assert(_event && _event->buffer() && _event->size() > 0);
const Event<Time>& ev = *_event.get();
if (!( ev.is_note()
|| ev.is_cc()
|| ev.is_pgm_change()
|| ev.is_pitch_bender()
|| ev.is_channel_pressure()
|| ev.is_poly_pressure()
|| ev.is_sysex()) ) {
cerr << "WARNING: Unknown event (type " << _type << "): " << hex
<< int(ev.buffer()[0]) << int(ev.buffer()[1]) << int(ev.buffer()[2]) << endl;
}
Temporal::timepos_t x (Temporal::AudioTime);
Temporal::timepos_t xtime (Temporal::AudioTime);
double y = 0.0;
bool ret = false;
// Increment past current event
switch (_type) {
case NOTE_ON:
++_note_iter;
break;
case NOTE_OFF:
_active_notes.pop();
break;
case CONTROL:
// Increment current controller iterator
if (_force_discrete || _control_iter->list->interpolation() == ControlList::Discrete) {
ret = _control_iter->list->rt_safe_earliest_event_discrete_unlocked (_control_iter->x, xtime, y, false);
} else {
ret = _control_iter->list->rt_safe_earliest_event_linear_unlocked (
_control_iter->x, xtime, y, false, Temporal::timecnt_t::from_ticks (time_between_interpolated_controller_outputs));
}
assert(!ret || x > _control_iter->x);
if (ret) {
_control_iter->x = xtime;
_control_iter->y = y;
} else {
_control_iter->list.reset();
_control_iter->x = std::numeric_limits<Time>::max();
_control_iter->y = DBL_MAX;
}
// Find the controller with the next earliest event time
_control_iter = _control_iters.begin();
for (ControlIterators::iterator i = _control_iters.begin();
i != _control_iters.end(); ++i) {
if (i->x < _control_iter->x) {
_control_iter = i;
}
}
break;
case SYSEX:
++_sysex_iter;
break;
case PATCH_CHANGE:
++_active_patch_change_message;
if (_active_patch_change_message == (*_patch_change_iter)->messages()) {
++_patch_change_iter;
_active_patch_change_message = 0;
}
break;
default:
assert(false);
}
// Choose the earliest event overall to point to
choose_next(std::numeric_limits<Time>::max());
// Set event from chosen sub-iterator
set_event();
assert(_is_end || (_event->size() > 0 && _event->buffer() && _event->buffer()[0] != '\0'));
return *this;
}
template<typename Time>
bool
Sequence<Time>::const_iterator::operator==(const const_iterator& other) const
{
if (_seq != other._seq) {
return false;
} else if (_is_end || other._is_end) {
return (_is_end == other._is_end);
} else if (_type != other._type) {
return false;
} else {
return (_event == other._event);
}
}
template<typename Time>
typename Sequence<Time>::const_iterator&
Sequence<Time>::const_iterator::operator=(const const_iterator& other)
{
_seq = other._seq;
_event = other._event;
_active_notes = other._active_notes;
_type = other._type;
_is_end = other._is_end;
_note_iter = other._note_iter;
_sysex_iter = other._sysex_iter;
_patch_change_iter = other._patch_change_iter;
_control_iters = other._control_iters;
_force_discrete = other._force_discrete;
_active_patch_change_message = other._active_patch_change_message;
if (other._lock) {
_lock = _seq->read_lock();
} else {
_lock.reset();
}
if (other._control_iter == other._control_iters.end()) {
_control_iter = _control_iters.end();
} else {
const size_t index = other._control_iter - other._control_iters.begin();
_control_iter = _control_iters.begin() + index;
}
return *this;
}
// Sequence
template<typename Time>
Sequence<Time>::Sequence(const TypeMap& type_map)
: _edited(false)
, _overlapping_pitches_accepted (true)
, _overlap_pitch_resolution (FirstOnFirstOff)
, _writing(false)
, _type_map(type_map)
, _end_iter(*this, std::numeric_limits<Time>::max(), false, std::set<Evoral::Parameter> ())
, _percussive(false)
, _lowest_note(127)
, _highest_note(0)
{
DEBUG_TRACE (DEBUG::Sequence, string_compose ("Sequence constructed: %1\n", this));
assert(_end_iter._is_end);
assert( ! _end_iter._lock);
for (int i = 0; i < 16; ++i) {
_bank[i] = 0;
}
}
template<typename Time>
Sequence<Time>::Sequence(const Sequence<Time>& other)
: ControlSet (other)
, _edited(false)
, _overlapping_pitches_accepted (other._overlapping_pitches_accepted)
, _overlap_pitch_resolution (other._overlap_pitch_resolution)
, _writing(false)
, _type_map(other._type_map)
, _end_iter(*this, std::numeric_limits<Time>::max(), false, std::set<Evoral::Parameter> ())
, _percussive(other._percussive)
, _lowest_note(other._lowest_note)
, _highest_note(other._highest_note)
{
for (typename Notes::const_iterator i = other._notes.begin(); i != other._notes.end(); ++i) {
NotePtr n (new Note<Time> (**i));
_notes.insert (n);
}
for (typename SysExes::const_iterator i = other._sysexes.begin(); i != other._sysexes.end(); ++i) {
boost::shared_ptr<Event<Time> > n (new Event<Time> (**i, true));
_sysexes.insert (n);
}
for (typename PatchChanges::const_iterator i = other._patch_changes.begin(); i != other._patch_changes.end(); ++i) {
PatchChangePtr n (new PatchChange<Time> (**i));
_patch_changes.insert (n);
}
for (int i = 0; i < 16; ++i) {
_bank[i] = other._bank[i];
}
DEBUG_TRACE (DEBUG::Sequence, string_compose ("Sequence copied: %1\n", this));
assert(_end_iter._is_end);
assert(! _end_iter._lock);
}
/** Write the controller event pointed to by `iter` to `ev`.
* The buffer of `ev` will be allocated or resized as necessary.
* \return true on success
*/
template<typename Time>
bool
Sequence<Time>::control_to_midi_event(
boost::shared_ptr< Event<Time> >& ev,
const ControlIterator& iter) const
{
assert(iter.list.get());
// initialize the event pointer with a new event, if necessary
if (!ev) {
ev = boost::shared_ptr< Event<Time> >(new Event<Time>(NO_EVENT, Time(), 3, NULL, true));
}
const uint8_t midi_type = _type_map.parameter_midi_type(iter.list->parameter());
ev->set_event_type(MIDI_EVENT);
ev->set_id(-1);
switch (midi_type) {
case MIDI_CMD_CONTROL:
assert(iter.list.get());
assert(iter.list->parameter().channel() < 16);
assert(iter.list->parameter().id() <= INT8_MAX);
assert(iter.y <= INT8_MAX);
ev->set_time(iter.x.beats());
ev->realloc(3);
ev->buffer()[0] = MIDI_CMD_CONTROL + iter.list->parameter().channel();
ev->buffer()[1] = (uint8_t)iter.list->parameter().id();
ev->buffer()[2] = (uint8_t)iter.y;
break;
case MIDI_CMD_PGM_CHANGE:
assert(iter.list.get());
assert(iter.list->parameter().channel() < 16);
assert(iter.y <= INT8_MAX);
ev->set_time(iter.x.beats());
ev->realloc(2);
ev->buffer()[0] = MIDI_CMD_PGM_CHANGE + iter.list->parameter().channel();
ev->buffer()[1] = (uint8_t)iter.y;
break;
case MIDI_CMD_BENDER:
assert(iter.list.get());
assert(iter.list->parameter().channel() < 16);
assert(iter.y < (1<<14));
ev->set_time(iter.x.beats());
ev->realloc(3);
ev->buffer()[0] = MIDI_CMD_BENDER + iter.list->parameter().channel();
ev->buffer()[1] = uint16_t(iter.y) & 0x7F; // LSB
ev->buffer()[2] = (uint16_t(iter.y) >> 7) & 0x7F; // MSB
break;
case MIDI_CMD_NOTE_PRESSURE:
assert(iter.list.get());
assert(iter.list->parameter().channel() < 16);
assert(iter.list->parameter().id() <= INT8_MAX);
assert(iter.y <= INT8_MAX);
ev->set_time(iter.x.beats());
ev->realloc(3);
ev->buffer()[0] = MIDI_CMD_NOTE_PRESSURE + iter.list->parameter().channel();
ev->buffer()[1] = (uint8_t)iter.list->parameter().id();
ev->buffer()[2] = (uint8_t)iter.y;
break;
case MIDI_CMD_CHANNEL_PRESSURE:
assert(iter.list.get());
assert(iter.list->parameter().channel() < 16);
assert(iter.y <= INT8_MAX);
ev->set_time(iter.x.beats());
ev->realloc(2);
ev->buffer()[0] = MIDI_CMD_CHANNEL_PRESSURE + iter.list->parameter().channel();
ev->buffer()[1] = (uint8_t)iter.y;
break;
default:
return false;
}
return true;
}
/** Clear all events from the model.
*/
template<typename Time>
void
Sequence<Time>::clear()
{
WriteLock lock(write_lock());
_notes.clear();
for (Controls::iterator li = _controls.begin(); li != _controls.end(); ++li)
li->second->list()->clear();
}
/** Begin a write of events to the model.
*
* If \a mode is Sustained, complete notes with length are constructed as note
* on/off events are received. Otherwise (Percussive), only note on events are
* stored; note off events are discarded entirely and all contained notes will
* have length 0.
*/
template<typename Time>
void
Sequence<Time>::start_write()
{
DEBUG_TRACE (DEBUG::Sequence, string_compose ("%1 : start_write (percussive = %2)\n", this, _percussive));
WriteLock lock(write_lock());
_writing = true;
for (int i = 0; i < 16; ++i) {
_write_notes[i].clear();
}
}
/** Finish a write of events to the model.
*
* If \a delete_stuck is true and the current mode is Sustained, note on events
* that were never resolved with a corresonding note off will be deleted.
* Otherwise they will remain as notes with length 0.
*/
template<typename Time>
void
Sequence<Time>::end_write (StuckNoteOption option, Time when)
{
WriteLock lock(write_lock());
if (!_writing) {
return;
}
DEBUG_TRACE (DEBUG::Sequence, string_compose ("%1 : end_write (%2 notes) delete stuck option %3 @ %4\n", this, _notes.size(), option, when));
for (typename Notes::iterator n = _notes.begin(); n != _notes.end() ;) {
typename Notes::iterator next = n;
++next;
if ((*n)->end_time() == std::numeric_limits<Temporal::Beats>::max()) {
switch (option) {
case Relax:
break;
case DeleteStuckNotes:
cerr << "WARNING: Stuck note lost (end was " << when << "): " << (**n) << endl;
_notes.erase(n);
break;
case ResolveStuckNotes:
if (when <= (*n)->time()) {
cerr << "WARNING: Stuck note resolution - end time @ "
<< when << " is before note on: " << (**n) << endl;
_notes.erase (n);
} else {
(*n)->set_length (when - (*n)->time());
cerr << "WARNING: resolved note-on with no note-off to generate " << (**n) << endl;
}
break;
}
}
n = next;
}
for (int i = 0; i < 16; ++i) {
_write_notes[i].clear();
}
_writing = false;
}
template<typename Time>
bool
Sequence<Time>::add_note_unlocked(const NotePtr note, void* arg)
{
/* This is the core method to add notes to a Sequence
*/
DEBUG_TRACE (DEBUG::Sequence, string_compose ("%1 add note %2 @ %3 dur %4\n", this, (int)note->note(), note->time(), note->length()));
if (resolve_overlaps_unlocked (note, arg)) {
DEBUG_TRACE (DEBUG::Sequence, string_compose ("%1 DISALLOWED: note %2 @ %3\n", this, (int)note->note(), note->time()));
return false;
}
if (note->id() < 0) {
note->set_id (Evoral::next_event_id());
}
if (note->note() < _lowest_note)
_lowest_note = note->note();
if (note->note() > _highest_note)
_highest_note = note->note();
_notes.insert (note);
_pitches[note->channel()].insert (note);
_edited = true;
return true;
}
template<typename Time>
void
Sequence<Time>::remove_note_unlocked(const constNotePtr note)
{
bool erased = false;
bool id_matched = false;
DEBUG_TRACE (DEBUG::Sequence, string_compose ("%1 remove note #%2 %3 @ %4\n", this, note->id(), (int)note->note(), note->time()));
/* first try searching for the note using the time index, which is
* faster since the container is "indexed" by time. (technically, this
* means that lower_bound() can do a binary search rather than linear)
*
* this may not work, for reasons explained below.
*/
typename Sequence<Time>::Notes::iterator i;
for (i = note_lower_bound(note->time()); i != _notes.end() && (*i)->time() == note->time(); ++i) {
if (*i == note) {
DEBUG_TRACE (DEBUG::Sequence, string_compose ("%1\terasing note #%2 %3 @ %4\n", this, (*i)->id(), (int)(*i)->note(), (*i)->time()));
_notes.erase (i);
if (note->note() == _lowest_note || note->note() == _highest_note) {
_lowest_note = 127;
_highest_note = 0;
for (typename Sequence<Time>::Notes::iterator ii = _notes.begin(); ii != _notes.end(); ++ii) {
if ((*ii)->note() < _lowest_note)
_lowest_note = (*ii)->note();
if ((*ii)->note() > _highest_note)
_highest_note = (*ii)->note();
}
}
erased = true;
break;
}
}
DEBUG_TRACE (DEBUG::Sequence, string_compose ("%1\ttime-based lookup did not find note #%2 %3 @ %4\n", this, note->id(), (int)note->note(), note->time()));
if (!erased) {
/* if the note's time property was changed in tandem with some
* other property as the next operation after it was added to
* the sequence, then at the point where we call this to undo
* the add, the note we are targetting currently has a
* different time property than the one we we passed via
* the argument.
*
* in this scenario, we have no choice other than to linear
* search the list of notes and find the note by ID.
*/
for (i = _notes.begin(); i != _notes.end(); ++i) {
if ((*i)->id() == note->id()) {
DEBUG_TRACE (DEBUG::Sequence, string_compose ("%1\tID-based pass, erasing note #%2 %3 @ %4\n", this, (*i)->id(), (int)(*i)->note(), (*i)->time()));
_notes.erase (i);
if (note->note() == _lowest_note || note->note() == _highest_note) {
_lowest_note = 127;
_highest_note = 0;
for (typename Sequence<Time>::Notes::iterator ii = _notes.begin(); ii != _notes.end(); ++ii) {
if ((*ii)->note() < _lowest_note)
_lowest_note = (*ii)->note();
if ((*ii)->note() > _highest_note)
_highest_note = (*ii)->note();
}
}
erased = true;
id_matched = true;
break;
}
}
}
if (erased) {
Pitches& p (pitches (note->channel()));
typename Pitches::iterator j;
/* if we had to ID-match above, we can't expect to find it in
* pitches via note comparison either. so do another linear
* search to locate it. otherwise, we can use the note index
* to potentially speed things up.
*/
if (id_matched) {
for (j = p.begin(); j != p.end(); ++j) {
if ((*j)->id() == note->id()) {
p.erase (j);
break;
}
}
} else {
/* Now find the same note in the "pitches" list (which indexes
* notes by channel+time. We care only about its note number
* so the search_note has all other properties unset.
*/
NotePtr search_note (new Note<Time>(0, Time(), Time(), note->note(), 0));
for (j = p.lower_bound (search_note); j != p.end() && (*j)->note() == note->note(); ++j) {
if ((*j) == note) {
DEBUG_TRACE (DEBUG::Sequence, string_compose ("%1\terasing pitch %2 @ %3\n", this, (int)(*j)->note(), (*j)->time()));
p.erase (j);
break;
}
}
}
if (j == p.end()) {
warning << string_compose ("erased note %1 not found in pitches for channel %2", *note, (int) note->channel()) << endmsg;
}
_edited = true;
} else {
cerr << "Unable to find note to erase matching " << *note.get() << endmsg;
}
}
template<typename Time>
void
Sequence<Time>::remove_patch_change_unlocked (const constPatchChangePtr p)
{
typename Sequence<Time>::PatchChanges::iterator i = patch_change_lower_bound (p->time ());
while (i != _patch_changes.end() && ((*i)->time() == p->time())) {
typename Sequence<Time>::PatchChanges::iterator tmp = i;
++tmp;
if (**i == *p) {
_patch_changes.erase (i);
}
i = tmp;
}
}
template<typename Time>
void
Sequence<Time>::remove_sysex_unlocked (const SysExPtr sysex)
{
typename Sequence<Time>::SysExes::iterator i = sysex_lower_bound (sysex->time ());
while (i != _sysexes.end() && (*i)->time() == sysex->time()) {
typename Sequence<Time>::SysExes::iterator tmp = i;
++tmp;
if (*i == sysex) {
_sysexes.erase (i);
}
i = tmp;
}
}
/** Append \a ev to model. NOT realtime safe.
*
* The timestamp of event is expected to be relative to
* the start of this model (t=0) and MUST be monotonically increasing
* and MUST be >= the latest event currently in the model.
*/
template<typename Time>
void
Sequence<Time>::append(const Event<Time>& ev, event_id_t evid)
{
WriteLock lock(write_lock());
assert(_notes.empty() || ev.time() >= (*_notes.rbegin())->time());
assert(_writing);
if (!midi_event_is_valid(ev.buffer(), ev.size())) {
cerr << "WARNING: Sequence ignoring illegal MIDI event" << endl;
return;
}
if (ev.is_note_on() && ev.velocity() > 0) {
append_note_on_unlocked (ev, evid);
} else if (ev.is_note_off() || (ev.is_note_on() && ev.velocity() == 0)) {
/* XXX note: event ID is discarded because we merge the on+off events into
a single note object
*/
append_note_off_unlocked (ev);
} else if (ev.is_sysex()) {
append_sysex_unlocked(ev, evid);
} else if (ev.is_cc() && (ev.cc_number() == MIDI_CTL_MSB_BANK || ev.cc_number() == MIDI_CTL_LSB_BANK)) {
/* note bank numbers in our _bank[] array, so that we can write an event when the program change arrives */
if (ev.cc_number() == MIDI_CTL_MSB_BANK) {
_bank[ev.channel()] &= ~(0x7f << 7);
_bank[ev.channel()] |= ev.cc_value() << 7;
} else {
_bank[ev.channel()] &= ~0x7f;
_bank[ev.channel()] |= ev.cc_value();
}
} else if (ev.is_cc()) {
const ParameterType ptype = _type_map.midi_parameter_type(ev.buffer(), ev.size());
append_control_unlocked(
Parameter(ptype, ev.channel(), ev.cc_number()),
ev.time(), ev.cc_value(), evid);
} else if (ev.is_pgm_change()) {
/* write a patch change with this program change and any previously set-up bank number */
append_patch_change_unlocked (
PatchChange<Time> (ev.time(), ev.channel(),
ev.pgm_number(), _bank[ev.channel()]), evid);
} else if (ev.is_pitch_bender()) {
const ParameterType ptype = _type_map.midi_parameter_type(ev.buffer(), ev.size());
append_control_unlocked(
Parameter(ptype, ev.channel()),
ev.time(), double ((0x7F & ev.pitch_bender_msb()) << 7
| (0x7F & ev.pitch_bender_lsb())),
evid);
} else if (ev.is_poly_pressure()) {
const ParameterType ptype = _type_map.midi_parameter_type(ev.buffer(), ev.size());
append_control_unlocked (Parameter (ptype, ev.channel(), ev.poly_note()), ev.time(), ev.poly_pressure(), evid);
} else if (ev.is_channel_pressure()) {
const ParameterType ptype = _type_map.midi_parameter_type(ev.buffer(), ev.size());
append_control_unlocked(
Parameter(ptype, ev.channel()),
ev.time(), ev.channel_pressure(), evid);
} else if (!_type_map.type_is_midi(ev.event_type())) {
printf("WARNING: Sequence: Unknown event type %X: ", ev.event_type());
for (size_t i=0; i < ev.size(); ++i) {
printf("%X ", ev.buffer()[i]);
}
printf("\n");
} else {
printf("WARNING: Sequence: Unknown MIDI event type %X\n", ev.type());
}
_edited = true;
}
template<typename Time>
void
Sequence<Time>::append_note_on_unlocked (const Event<Time>& ev, event_id_t evid)
{
DEBUG_TRACE (DEBUG::Sequence, string_compose ("%1 c=%2 note %3 on @ %4 v=%5\n", this,
(int)ev.channel(), (int)ev.note(),
ev.time(), (int)ev.velocity()));
assert(_writing);
if (ev.note() > 127) {
error << string_compose (_("invalid note on number (%1) ignored"), (int) ev.note()) << endmsg;
return;
} else if (ev.channel() >= 16) {
error << string_compose (_("invalid note on channel (%1) ignored"), (int) ev.channel()) << endmsg;
return;
} else if (ev.velocity() == 0) {
// Note on with velocity 0 handled as note off by caller
error << string_compose (_("invalid note on velocity (%1) ignored"), (int) ev.velocity()) << endmsg;
return;
}
/* nascent (incoming notes without a note-off ...yet) have a duration
that extends to Beats::max()
*/
NotePtr note(new Note<Time>(ev.channel(), ev.time(), std::numeric_limits<Temporal::Beats>::max() - ev.time(), ev.note(), ev.velocity()));
assert (note->end_time() == std::numeric_limits<Temporal::Beats>::max());
note->set_id (evid);
add_note_unlocked (note);
DEBUG_TRACE (DEBUG::Sequence, string_compose ("Appending active note on %1 channel %2\n",
(unsigned)(uint8_t)note->note(), note->channel()));
_write_notes[note->channel()].insert (note);
}
template<typename Time>
void
Sequence<Time>::append_note_off_unlocked (const Event<Time>& ev)
{
DEBUG_TRACE (DEBUG::Sequence, string_compose ("%1 c=%2 note %3 OFF @ %4 v=%5\n",
this, (int)ev.channel(),
(int)ev.note(), ev.time(), (int)ev.velocity()));
assert(_writing);
if (ev.note() > 127) {
error << string_compose (_("invalid note off number (%1) ignored"), (int) ev.note()) << endmsg;
return;
} else if (ev.channel() >= 16) {
error << string_compose (_("invalid note off channel (%1) ignored"), (int) ev.channel()) << endmsg;
return;
}
_edited = true;
bool resolved = false;
/* _write_notes is sorted earliest-latest, so this will find the first matching note (FIFO) that
matches this note (by pitch & channel). the MIDI specification doesn't provide any guidance
whether to use FIFO or LIFO for this matching process, so SMF is fundamentally a lossy
format.
*/
/* XXX use _overlap_pitch_resolution to determine FIFO/LIFO ... */
for (typename WriteNotes::iterator n = _write_notes[ev.channel()].begin(); n != _write_notes[ev.channel()].end(); ) {
typename WriteNotes::iterator tmp = n;
++tmp;
NotePtr nn = *n;
if (ev.note() == nn->note() && nn->channel() == ev.channel()) {
assert(ev.time() >= nn->time());
nn->set_length (ev.time() - nn->time());
nn->set_off_velocity (ev.velocity());
_write_notes[ev.channel()].erase(n);
DEBUG_TRACE (DEBUG::Sequence, string_compose ("resolved note @ %2 length: %1\n", nn->length(), nn->time()));
resolved = true;
break;
}
n = tmp;
}
if (!resolved) {
cerr << this << " spurious note off chan " << (int)ev.channel()
<< ", note " << (int)ev.note() << " @ " << ev.time() << endl;
}
}
template<typename Time>
void
Sequence<Time>::append_control_unlocked(const Parameter& param, Time time, double value, event_id_t /* evid */)
{
DEBUG_TRACE (DEBUG::Sequence, string_compose ("%1 %2 @ %3 = %4 # controls: %5\n",
this, _type_map.to_symbol(param), time, value, _controls.size()));
boost::shared_ptr<Control> c = control(param, true);
c->list()->add (Temporal::timepos_t (time), value, true, false);
/* XXX control events should use IDs */
}
template<typename Time>
void
Sequence<Time>::append_sysex_unlocked(const Event<Time>& ev, event_id_t /* evid */)
{
#ifdef DEBUG_SEQUENCE
cerr << this << " SysEx @ " << ev.time() << " \t= \t [ " << hex;
for (size_t i=0; i < ev.size(); ++i) {
cerr << int(ev.buffer()[i]) << " ";
} cerr << "]" << endl;
#endif
boost::shared_ptr< Event<Time> > event(new Event<Time>(ev, true));
/* XXX sysex events should use IDs */
_sysexes.insert(event);
}
template<typename Time>
void
Sequence<Time>::append_patch_change_unlocked (const PatchChange<Time>& ev, event_id_t id)
{
PatchChangePtr p (new PatchChange<Time> (ev));
if (p->id() < 0) {
p->set_id (id);
}
_patch_changes.insert (p);
}
template<typename Time>
void
Sequence<Time>::add_patch_change_unlocked (PatchChangePtr p)
{
if (p->id () < 0) {
p->set_id (Evoral::next_event_id ());
}
_patch_changes.insert (p);
}
template<typename Time>
void
Sequence<Time>::add_sysex_unlocked (SysExPtr s)
{
if (s->id () < 0) {
s->set_id (Evoral::next_event_id ());
}
_sysexes.insert (s);
}
template<typename Time>
bool
Sequence<Time>::contains (const NotePtr& note) const
{
ReadLock lock (read_lock());
return contains_unlocked (note);
}
template<typename Time>
bool
Sequence<Time>::contains_unlocked (const NotePtr& note) const
{
const Pitches& p (pitches (note->channel()));
NotePtr search_note(new Note<Time>(0, Time(), Time(), note->note()));
for (typename Pitches::const_iterator i = p.lower_bound (search_note);
i != p.end() && (*i)->note() == note->note(); ++i) {
if (**i == *note) {
return true;
}
}
return false;
}
template<typename Time>
bool
Sequence<Time>::overlaps (const NotePtr& note, const NotePtr& without) const
{
ReadLock lock (read_lock());
return overlaps_unlocked (note, without);
}
template<typename Time>
bool
Sequence<Time>::overlaps_unlocked (const NotePtr& note, const NotePtr& without) const
{
Time sa = note->time();
Time ea = note->end_time();
const Pitches& p (pitches (note->channel()));
NotePtr search_note(new Note<Time>(0, Time(), Time(), note->note()));
for (typename Pitches::const_iterator i = p.lower_bound (search_note);
i != p.end() && (*i)->note() == note->note(); ++i) {
if (without && (**i) == *without) {
continue;
}
Time sb = (*i)->time();
Time eb = (*i)->end_time();
if (((sb > sa) && (eb <= ea)) ||
((eb >= sa) && (eb <= ea)) ||
((sb > sa) && (sb <= ea)) ||
((sa >= sb) && (sa <= eb) && (ea <= eb))) {
return true;
}
}
return false;
}
template<typename Time>
void
Sequence<Time>::set_notes (const typename Sequence<Time>::Notes& n)
{
_notes = n;
}
// CONST iterator implementations (x3)
/** Return the earliest note with time >= t */
template<typename Time>
typename Sequence<Time>::Notes::const_iterator
Sequence<Time>::note_lower_bound (Time t) const
{
NotePtr search_note(new Note<Time>(0, t, Time(), 0, 0));
typename Sequence<Time>::Notes::const_iterator i = _notes.lower_bound(search_note);
assert(i == _notes.end() || (*i)->time() >= t);
return i;
}
/** Return the earliest patch change with time >= t */
template<typename Time>
typename Sequence<Time>::PatchChanges::const_iterator
Sequence<Time>::patch_change_lower_bound (Time t) const
{
PatchChangePtr search (new PatchChange<Time> (t, 0, 0, 0));
typename Sequence<Time>::PatchChanges::const_iterator i = _patch_changes.lower_bound (search);
assert (i == _patch_changes.end() || (*i)->time() >= t);
return i;
}
/** Return the earliest sysex with time >= t */
template<typename Time>
typename Sequence<Time>::SysExes::const_iterator
Sequence<Time>::sysex_lower_bound (Time t) const
{
SysExPtr search (new Event<Time> (NO_EVENT, t));
typename Sequence<Time>::SysExes::const_iterator i = _sysexes.lower_bound (search);
assert (i == _sysexes.end() || (*i)->time() >= t);
return i;
}
// NON-CONST iterator implementations (x3)
/** Return the earliest note with time >= t */
template<typename Time>
typename Sequence<Time>::Notes::iterator
Sequence<Time>::note_lower_bound (Time t)
{
NotePtr search_note(new Note<Time>(0, t, Time(), 0, 0));
typename Sequence<Time>::Notes::iterator i = _notes.lower_bound(search_note);
assert(i == _notes.end() || (*i)->time() >= t);
return i;
}
/** Return the earliest patch change with time >= t */
template<typename Time>
typename Sequence<Time>::PatchChanges::iterator
Sequence<Time>::patch_change_lower_bound (Time t)
{
PatchChangePtr search (new PatchChange<Time> (t, 0, 0, 0));
typename Sequence<Time>::PatchChanges::iterator i = _patch_changes.lower_bound (search);
assert (i == _patch_changes.end() || (*i)->time() >= t);
return i;
}
/** Return the earliest sysex with time >= t */
template<typename Time>
typename Sequence<Time>::SysExes::iterator
Sequence<Time>::sysex_lower_bound (Time t)
{
SysExPtr search (new Event<Time> (NO_EVENT, t));
typename Sequence<Time>::SysExes::iterator i = _sysexes.lower_bound (search);
assert (i == _sysexes.end() || (*i)->time() >= t);
return i;
}
template<typename Time>
void
Sequence<Time>::get_notes (Notes& n, NoteOperator op, uint8_t val, int chan_mask) const
{
switch (op) {
case PitchEqual:
case PitchLessThan:
case PitchLessThanOrEqual:
case PitchGreater:
case PitchGreaterThanOrEqual:
get_notes_by_pitch (n, op, val, chan_mask);
break;
case VelocityEqual:
case VelocityLessThan:
case VelocityLessThanOrEqual:
case VelocityGreater:
case VelocityGreaterThanOrEqual:
get_notes_by_velocity (n, op, val, chan_mask);
break;
}
}
template<typename Time>
void
Sequence<Time>::get_notes_by_pitch (Notes& n, NoteOperator op, uint8_t val, int chan_mask) const
{
for (uint8_t c = 0; c < 16; ++c) {
if (chan_mask != 0 && !((1<<c) & chan_mask)) {
continue;
}
const Pitches& p (pitches (c));
NotePtr search_note(new Note<Time>(0, Time(), Time(), val, 0));
typename Pitches::const_iterator i;
switch (op) {
case PitchEqual:
i = p.lower_bound (search_note);
while (i != p.end() && (*i)->note() == val) {
n.insert (*i);
}
break;
case PitchLessThan:
i = p.upper_bound (search_note);
while (i != p.end() && (*i)->note() < val) {
n.insert (*i);
}
break;
case PitchLessThanOrEqual:
i = p.upper_bound (search_note);
while (i != p.end() && (*i)->note() <= val) {
n.insert (*i);
}
break;
case PitchGreater:
i = p.lower_bound (search_note);
while (i != p.end() && (*i)->note() > val) {
n.insert (*i);
}
break;
case PitchGreaterThanOrEqual:
i = p.lower_bound (search_note);
while (i != p.end() && (*i)->note() >= val) {
n.insert (*i);
}
break;
default:
//fatal << string_compose (_("programming error: %1 %2", X_("get_notes_by_pitch() called with illegal operator"), op)) << endmsg;
abort(); /* NOTREACHED*/
}
}
}
template<typename Time>
void
Sequence<Time>::get_notes_by_velocity (Notes& n, NoteOperator op, uint8_t val, int chan_mask) const
{
ReadLock lock (read_lock());
for (typename Notes::const_iterator i = _notes.begin(); i != _notes.end(); ++i) {
if (chan_mask != 0 && !((1<<((*i)->channel())) & chan_mask)) {
continue;
}
switch (op) {
case VelocityEqual:
if ((*i)->velocity() == val) {
n.insert (*i);
}
break;
case VelocityLessThan:
if ((*i)->velocity() < val) {
n.insert (*i);
}
break;
case VelocityLessThanOrEqual:
if ((*i)->velocity() <= val) {
n.insert (*i);
}
break;
case VelocityGreater:
if ((*i)->velocity() > val) {
n.insert (*i);
}
break;
case VelocityGreaterThanOrEqual:
if ((*i)->velocity() >= val) {
n.insert (*i);
}
break;
default:
// fatal << string_compose (_("programming error: %1 %2", X_("get_notes_by_velocity() called with illegal operator"), op)) << endmsg;
abort(); /* NOTREACHED*/
}
}
}
template<typename Time>
void
Sequence<Time>::set_overlap_pitch_resolution (OverlapPitchResolution opr)
{
_overlap_pitch_resolution = opr;
/* XXX todo: clean up existing overlaps in source data? */
}
template<typename Time>
void
Sequence<Time>::control_list_marked_dirty ()
{
set_edited (true);
}
template<typename Time>
void
Sequence<Time>::dump (ostream& str, typename Sequence<Time>::const_iterator x, uint32_t limit) const
{
typename Sequence<Time>::const_iterator i = begin();
if (x != end()) {
i = x;
}
str << "+++ dump";
if (i != end()) {
str << " from " << i->time();
}
str << endl;
for (; i != end() && (limit >= 0); ++i) {
str << *i << endl;
if (limit) {
if (--limit == 0) {
break;
}
}
}
str << "--- dump\n";
}
template class Sequence<Temporal::Beats>;
} // namespace Evoral