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livetrax/libs/ardour/step_sequencer.cc
Paul Davis b35518e212 switch from boost::{shared,weak}_ptr to std::{shared,weak}_ptr
This is mostly a simple lexical search+replace but the absence of operator< for
std::weak_ptr<T> leads to some complications, particularly with Evoral::Sequence
and ExportPortChannel.
2023-03-24 14:19:15 -06:00

933 lines
20 KiB
C++

/*
* Copyright (C) 2018 Paul Davis <paul@linuxaudiosystems.com>
*
* 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, 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 <cassert>
#include <glibmm/fileutils.h>
#include "pbd/i18n.h"
#include "ardour/audioengine.h"
#include "ardour/midi_buffer.h"
#include "ardour/midi_state_tracker.h"
#include "ardour/session.h"
#include "ardour/smf_source.h"
#include "ardour/source_factory.h"
#include "ardour/step_sequencer.h"
#include "ardour/tempo.h"
using namespace PBD;
using namespace ARDOUR;
using namespace std;
using std::cerr;
using std::endl;
Step::Step (StepSequence &s, size_t n, Temporal::Beats const & b, int base_note)
: _sequence (s)
, _index (n)
, _enabled (true)
, _nominal_beat (b)
, _skipped (false)
, _mode (AbsolutePitch)
, _octave_shift (0)
, _duration (1)
{
_notes[0].number = base_note;
for (size_t n = 1; n < _notes_per_step; ++n) {
_notes[n].number = -1;
}
for (size_t n = 0; n < _parameters_per_step; ++n) {
_parameters[n].parameter = -1;
}
}
Step::~Step ()
{
}
StepSequencer&
Step::sequencer() const
{
return _sequence.sequencer();
}
void
Step::set_mode (Mode m)
{
_mode = m;
}
void
Step::set_beat (Temporal::Beats const & b)
{
_nominal_beat = b;
}
void
Step::set_note (double note, double velocity, int n)
{
assert (n < _notes_per_step);
_notes[n].number = note;
_notes[n].velocity = velocity;
}
void
Step::set_velocity (double velocity, size_t n)
{
assert (n < _notes_per_step);
if (_notes[n].velocity != velocity) {
_notes[n].velocity = velocity;
PropertyChange pc;
PropertyChanged (pc);
}
}
void
Step::set_octave_shift (int s)
{
if (s > 4) {
s = 4;
} else if (s < -4) {
s = -4;
}
if (s == _octave_shift) {
return;
}
_octave_shift = s;
PropertyChange pc;
PropertyChanged (pc);
}
void
Step::set_chord (size_t note_cnt, double* notes)
{
}
void
Step::set_parameter (int number, double value, int n)
{
assert (n < _parameters_per_step);
_parameters[n].parameter = number;
_parameters[n].value = value;
}
void
Step::set_enabled (bool yn)
{
_enabled = yn;
}
void
Step::adjust_duration (DurationRatio const & amt)
{
set_duration (_duration + amt);
}
void
Step::set_duration (DurationRatio const & dur)
{
if (dur > DurationRatio (1)) {
_duration = DurationRatio (1);
} else if (dur < DurationRatio()) {
_duration = DurationRatio ();
} else {
_duration = dur;
}
PropertyChange pc;
PropertyChanged (pc);
}
void
Step::adjust_offset (double fraction)
{
const Temporal::Beats incr_size = Temporal::Beats::ticks (lrintf (floor (sequencer().step_size().to_ticks() * fraction)));
set_offset (_notes[0].offset + incr_size);
}
void
Step::set_offset (Temporal::Beats const & b, size_t n)
{
if (_notes[n].offset != b) {
_notes[n].offset = b;
PropertyChange pc;
PropertyChanged (pc);
}
}
void
Step::adjust_pitch (int amt)
{
Step::Note& note (_notes[0]);
note.number += amt;
if (note.number > 127.0) {
note.number = 127.0;
}
if (note.number < 0.0) {
note.number = 0.0;
}
PropertyChange pc;
PropertyChanged (pc);
}
void
Step::adjust_velocity (int amt)
{
Step::Note& note (_notes[0]);
note.velocity += (1.0/128.0) * amt;
if (note.velocity > 1.0) {
note.velocity = 1.0;
}
if (note.velocity < 0.0) {
note.velocity = 0.0;
}
PropertyChange pc;
PropertyChanged (pc);
}
void
Step::adjust_octave (int amt)
{
set_octave_shift (_octave_shift + amt);
}
bool
Step::run (MidiBuffer& buf, bool running, samplepos_t start_sample, samplepos_t end_sample, MidiNoteTracker& tracker)
{
for (size_t n = 0; n < _parameters_per_step; ++n) {
check_parameter (n, buf, running, start_sample, end_sample);
}
for (size_t n = 0; n < _notes_per_step; ++n) {
check_note (n, buf, running, start_sample, end_sample, tracker);
}
if (running) {
samplepos_t scheduled_samples = sequencer().tempo_map().sample_at_beat ((_scheduled_beat + _notes[0].offset).to_double());
if (scheduled_samples >= start_sample && scheduled_samples < end_sample) {
/* this step was covered by the run() range, so update its next
* scheduled time.
*/
_scheduled_beat += sequencer().duration();
} else if (scheduled_samples < start_sample) {
/* missed it, maybe due to offset: schedule 2 cycles ahead */
_scheduled_beat += sequencer().duration();
_scheduled_beat += sequencer().duration();
}
}
return true;
}
void
Step::check_parameter (size_t n, MidiBuffer& buf, bool running, samplepos_t start_sample, samplepos_t end_sample)
{
}
void
Step::dump_parameter (MusicTimeEvents& events, size_t n, Temporal::Beats const & pattern_length) const
{
}
void
Step::check_note (size_t n, MidiBuffer& buf, bool running, samplepos_t start_sample, samplepos_t end_sample, MidiNoteTracker& tracker)
{
Note& note (_notes[n]);
if (_duration == DurationRatio ()) {
/* no duration, so no new notes on */
return;
}
if (note.number < 0) {
/* note not set .. ignore */
return;
}
/* figure out when this note would sound */
Temporal::Beats note_on_time = _scheduled_beat;
note_on_time += note.offset;
/* don't play silent notes */
if (note.velocity == 0) {
return;
}
samplepos_t on_samples = sequencer().tempo_map().sample_at_beat (note_on_time.to_double());
if (on_samples >= start_sample && on_samples < end_sample) {
uint8_t mbuf[3];
/* prepare 3 MIDI bytes for note on */
mbuf[0] = 0x90 | _sequence.channel();
switch (_mode) {
case AbsolutePitch:
mbuf[1] = note.number;
break;
case RelativePitch:
mbuf[1] = _sequence.root() + note.interval;
break;
}
if (_octave_shift) {
const int t = mbuf[1] + (12 * _octave_shift);
if (t > 127 || t < 0) {
/* Out of range */
return;
}
mbuf[1] = t;
}
mbuf[2] = (uint8_t) floor (note.velocity * 127.0);
note.off_msg[0] = 0x80 | _sequence.channel();
note.off_msg[1] = mbuf[1];
note.off_msg[2] = mbuf[2];
/* Put it into the MIDI buffer */
buf.write (on_samples - start_sample, Evoral::MIDI_EVENT, 3, mbuf);
tracker.add (mbuf[1], _sequence.channel());
/* compute note off time based on our duration */
Temporal::Beats off_at = note_on_time;
if (_duration == DurationRatio (1)) {
/* use 1 tick less than the sequence step size
* just to get non-simultaneous on/off events at
* step boundaries.
*/
off_at += Temporal::Beats (0, sequencer().step_size().to_ticks() - 1);
} else {
off_at += Temporal::Beats (0, (sequencer().step_size().to_ticks() * _duration.numerator()) / _duration.denominator());
}
sequencer().queue_note_off (off_at, mbuf[1], mbuf[2], _sequence.channel());
}
}
void
Step::dump_note (MusicTimeEvents& events, size_t n, Temporal::Beats const & pattern_length) const
{
Note const & note (_notes[n]);
if (_duration == DurationRatio ()) {
/* no duration, so no new notes on */
return;
}
if (note.number < 0) {
/* note not set .. ignore */
return;
}
/* figure out when this note would sound */
Temporal::Beats note_on_time (sequencer().step_size() * _index);
note_on_time += note.offset;
note_on_time %= pattern_length;
/* don't play silent notes */
if (note.velocity == 0) {
return;
}
uint8_t mbuf[3];
/* prepare 3 MIDI bytes for note on */
mbuf[0] = 0x90 | _sequence.channel();
switch (_mode) {
case AbsolutePitch:
mbuf[1] = note.number;
break;
case RelativePitch:
mbuf[1] = _sequence.root() + note.interval;
break;
}
if (_octave_shift) {
const int t = mbuf[1] + (12 * _octave_shift);
if (t > 127 || t < 0) {
/* Out of range */
return;
}
mbuf[1] = t;
}
mbuf[2] = (uint8_t) floor (note.velocity * 127.0);
events.push_back (new MusicTimeEvent (Evoral::MIDI_EVENT, note_on_time, 3, mbuf, true));
mbuf[0] = 0x80 | _sequence.channel();
/* compute note off time based on our duration */
Temporal::Beats off_at = note_on_time;
if (_duration == DurationRatio (1)) {
/* use 1 tick less than the sequence step size
* just to get non-simultaneous on/off events at
* step boundaries.
*/
off_at += Temporal::Beats (0, sequencer().step_size().to_ticks() - 1);
} else {
off_at += Temporal::Beats (0, (sequencer().step_size().to_ticks() * _duration.numerator()) / _duration.denominator());
}
off_at %= pattern_length;
events.push_back (new MusicTimeEvent (Evoral::MIDI_EVENT, off_at, 3, mbuf, true));
}
void
Step::reschedule (Temporal::Beats const & start, Temporal::Beats const & offset)
{
if (_nominal_beat < offset) {
_scheduled_beat = start + _nominal_beat + sequencer().duration(); /* schedule into the next loop iteration */
} else {
_scheduled_beat = start + _nominal_beat; /* schedule into the current loop iteration */
}
}
XMLNode&
Step::get_state () const
{
return *new XMLNode (X_("Step"));
}
int
Step::set_state (XMLNode const &, int)
{
return 0;
}
void
Step::dump (MusicTimeEvents& events, Temporal::Beats const & pattern_length) const
{
for (size_t n = 0; n < _parameters_per_step; ++n) {
dump_parameter (events, n, pattern_length);
}
for (size_t n = 0; n < _notes_per_step; ++n) {
dump_note (events, n, pattern_length);
}
}
/**/
StepSequence::StepSequence (StepSequencer& s, size_t cnt, size_t nsteps, Temporal::Beats const & step_size, Temporal::Beats const & bar_size, int r)
: _sequencer (s)
, _index (cnt)
, _channel (0)
, _root (r)
, _mode (MusicalMode::IonianMajor)
{
Temporal::Beats beats;
for (size_t s = 0; s < nsteps; ++s) {
/* beats is wrong but we will correct in ::schedule */
_steps.push_back (new Step (*this, s, beats, _root));
}
/* schedule them all from zero for now */
schedule (beats);
}
StepSequence::~StepSequence ()
{
for (Steps::iterator i = _steps.begin(); i != _steps.end(); ++i) {
delete *i;
}
}
void
StepSequence::schedule (Temporal::Beats const & start)
{
Temporal::Beats beats (start);
const size_t s = _sequencer.start_step();
const size_t e = _sequencer.end_step();
for (size_t n = s; n < e; ++n) {
_steps[n]->set_beat (beats);
beats += _sequencer.step_size();
}
}
void
StepSequence::reschedule (Temporal::Beats const & start, Temporal::Beats const & offset)
{
const size_t s = _sequencer.start_step();
const size_t e = _sequencer.end_step();
for (size_t n = s; n < e; ++n) {
_steps[n]->reschedule (start, offset);
}
}
void
StepSequence::set_channel (int c)
{
_channel = c;
}
bool
StepSequence::run (MidiBuffer& buf, bool running, samplepos_t start_sample, samplepos_t end_sample, MidiNoteTracker& tracker)
{
const size_t s = _sequencer.start_step();
const size_t e = _sequencer.end_step();
const size_t t = _steps.size();
size_t n = 0;
/* steps before the start step .. may still have pending off's or ... */
while (n < s) {
_steps[n++]->run (buf, false, start_sample, end_sample, tracker);
}
/* currently in use steps */
while (n < e) {
_steps[n++]->run (buf, running, start_sample, end_sample, tracker);
}
/* steps after the end step .. may still have pending off's or ... */
while (n < t) {
_steps[n++]->run (buf, false, start_sample, end_sample, tracker);
}
return true;
}
Step&
StepSequence::step (size_t n) const
{
assert (n < _steps.size());
return *_steps[n];
}
XMLNode&
StepSequence::get_state() const
{
return *new XMLNode (X_("StepSequence"));
}
int
StepSequence::set_state (XMLNode const &, int)
{
return 0;
}
void
StepSequence::dump (MusicTimeEvents& events, Temporal::Beats const & pattern_length) const
{
const size_t s = _sequencer.start_step();
const size_t e = _sequencer.end_step();
for (size_t n = s; n < e; ++n) {
_steps[n]->dump (events, pattern_length);
}
}
/**/
MultiAllocSingleReleasePool StepSequencer::Request::pool (X_("step sequencer requests"), sizeof (StepSequencer::Request), 64);
Pool StepSequencer::NoteOffBlob::pool (X_("step sequencer noteoffs"), sizeof (StepSequencer::NoteOffBlob), 1024);
StepSequencer::StepSequencer (TempoMap& tmap, size_t nseqs, size_t nsteps, Temporal::Beats const & step_size, Temporal::Beats const & bar_size, int notenum)
: _tempo_map (tmap)
, _last_step (0)
, _step_size (step_size)
, _start_step (0)
, _end_step (nsteps)
, last_start (0)
, last_end (0)
, _running (false)
, _step_capacity (nsteps)
, requests (64)
{
for (size_t n = 0; n < nseqs; ++n) {
_sequences.push_back (new StepSequence (*this, n, nsteps, step_size, bar_size, notenum));
notenum++;
}
}
StepSequencer::~StepSequencer ()
{
for (StepSequences::iterator i = _sequences.begin(); i != _sequences.end(); ++i) {
delete *i;
}
}
Temporal::Beats
StepSequencer::reschedule (samplepos_t start_sample)
{
/* compute the beat position of this first "while-moving
* run() call as an offset into the sequencer's current loop
* length.
*/
const Temporal::Beats start_beat (_tempo_map.beat_at_sample (start_sample));
const int32_t tick_duration = duration().to_ticks();
const Temporal::Beats closest_previous_loop_start = Temporal::Beats::ticks ((start_beat.to_ticks() / tick_duration) * tick_duration);
const Temporal::Beats offset = Temporal::Beats::ticks ((start_beat.to_ticks() % tick_duration));
for (StepSequences::iterator s = _sequences.begin(); s != _sequences.end(); ++s) {
(*s)->reschedule (closest_previous_loop_start, offset);
}
return closest_previous_loop_start;
}
bool
StepSequencer::run (MidiBuffer& buf, samplepos_t start_sample, samplepos_t end_sample, double speed, pframes_t, bool)
{
Glib::Threads::Mutex::Lock lm (_sequence_lock);
bool resolve = false;
bool need_reschedule = check_requests ();
if (speed == 0) {
if (_running) {
resolve = true;
_running = false;
}
}
if (speed != 0) {
if (!_running || (last_end != start_sample)) {
if (last_end != start_sample) {
/* non-linear motion, need to resolve notes */
resolve = true;
}
_last_startup = reschedule (start_sample);
last_start = start_sample;
need_reschedule = false;
_running = true;
}
}
if (need_reschedule) {
reschedule (start_sample);
need_reschedule = false;
}
check_note_offs (buf, start_sample, end_sample);
for (StepSequences::iterator s = _sequences.begin(); s != _sequences.end(); ++s) {
(*s)->run (buf, _running, start_sample, end_sample, outbound_tracker);
}
const Temporal::Beats terminal_beat = Temporal::Beats (_tempo_map.beat_at_sample (end_sample - 1));
const size_t dur_ticks = duration().to_ticks();
const size_t step_ticks = _step_size.to_ticks();
_last_step = _start_step + (((terminal_beat - _last_startup).to_ticks() % dur_ticks) / step_ticks);
if (resolve) {
outbound_tracker.resolve_notes (buf, 0);
clear_note_offs ();
}
last_start = start_sample;
last_end = end_sample;
return true;
}
int
StepSequencer::last_step () const
{
return _last_step;
}
void
StepSequencer::sync ()
{
}
void
StepSequencer::reset ()
{
{
Glib::Threads::Mutex::Lock lm1 (_sequence_lock);
for (StepSequences::iterator s = _sequences.begin(); s != _sequences.end(); ++s) {
(*s)->reset ();
}
}
}
Temporal::Beats
StepSequencer::duration() const
{
return _step_size * (_end_step - _start_step) ;
}
void
StepSequence::reset ()
{
}
StepSequence&
StepSequencer::sequence (size_t n) const
{
assert (n < _sequences.size());
return *_sequences[n];
}
void
StepSequencer::set_start_step (size_t n)
{
Request* r = new Request;
r->type = Request::SetStartStep;
r->start_step = n;
requests.write (&r, 1);
}
void
StepSequencer::set_end_step (size_t n)
{
Request* r = new Request;
r->type = Request::SetEndStep;
r->end_step = n;
requests.write (&r, 1);
}
XMLNode&
StepSequencer::get_state() const
{
return *new XMLNode (X_("StepSequencer"));
}
int
StepSequencer::set_state (XMLNode const &, int)
{
return 0;
}
bool
StepSequencer::check_requests ()
{
Request* req;
bool changed = false;
bool reschedule = false;
while (requests.read (&req, 1)) {
if (req->type & Request::SetStartStep) {
if (req->start_step != _start_step) {
if (req->start_step < _end_step) {
_start_step = req->start_step;
reschedule = true;
changed = true;
}
}
}
if (req->type & Request::SetEndStep) {
if (req->end_step != _end_step) {
if (req->end_step > _start_step) {
_end_step = req->end_step;
reschedule = true;
changed = true;
}
}
}
if (req->type & Request::SetNSequences) {
// XXXX
}
if (req->type & Request::SetStepSize) {
if (_step_size != req->step_size) {
_step_size = req->step_size;
reschedule = true;
changed = true;
}
}
delete req;
}
if (changed) {
PropertyChange pc;
PropertyChanged (pc);
}
return reschedule;
}
void
StepSequencer::queue_note_off (Temporal::Beats const & when, uint8_t n, uint8_t v, uint8_t c)
{
NoteOffBlob* nob = new NoteOffBlob (when, n, v, c);
NoteOffList::iterator i = std::upper_bound (note_offs.begin(), note_offs.end(), *nob);
note_offs.insert (i, *nob);
}
void
StepSequencer::check_note_offs (MidiBuffer& mbuf, samplepos_t start_sample, samplepos_t end_sample)
{
for (NoteOffList::iterator i = note_offs.begin(); i != note_offs.end(); ) {
samplepos_t when = _tempo_map.sample_at_beat (i->when.to_double()); /* XXX nutempo */
if (when >= start_sample && when < end_sample) {
mbuf.write (when - start_sample, Evoral::MIDI_EVENT, 3, i->buf);
NoteOffBlob& nob (*i);
i = note_offs.erase (i);
delete &nob;
} else if (when < start_sample) {
i = note_offs.erase (i);
} else {
++i;
}
}
}
void
StepSequencer::clear_note_offs ()
{
for (NoteOffList::iterator i = note_offs.begin(); i != note_offs.end(); ) {
NoteOffBlob& nob (*i);
delete &nob;
i = note_offs.erase (i);
}
}
std::shared_ptr<Source>
StepSequencer::write_to_source (Session& session, string path) const
{
std::shared_ptr<SMFSource> src;
/* caller must check for pre-existing file */
assert (!path.empty());
assert (!Glib::file_test (path, Glib::FILE_TEST_EXISTS));
src = std::dynamic_pointer_cast<SMFSource>(SourceFactory::createWritable (DataType::MIDI, session, path, false, session.sample_rate()));
try {
if (src->create (path)) {
return std::shared_ptr<Source>();
}
} catch (...) {
return std::shared_ptr<Source>();
}
if (!fill_midi_source (src)) {
/* src will go out of scope, and its destructor will remove the
file, if any
*/
return std::shared_ptr<Source>();
}
return src;
}
struct ETC {
bool operator() (MusicTimeEvent const * a, MusicTimeEvent const * b) {
return a->time() < b->time();
}
};
bool
StepSequencer::fill_midi_source (std::shared_ptr<SMFSource> src) const
{
Temporal::Beats smf_beats;
Source::WriterLock lck (src->mutex());
/* first pass: run through the sequence one time to get all events, and
* then sort them. We have no idea what order they are in when we pull
* them, because each step may consist of several messages with
* arbitrary offsets.
*/
MusicTimeEvents events;
events.reserve ((_sequences.size() * nsteps() * (Step::_notes_per_step * 2) * 3) + // the note on and off messages
((_sequences.size() * nsteps() * Step::_parameters_per_step) * 3)); // CC messages
const Temporal::Beats total_steps = _step_size * nsteps();
for (StepSequences::const_iterator s = _sequences.begin(); s != _sequences.end(); ++s) {
(*s)->dump (events, total_steps);
}
sort (events.begin(), events.end(), ETC());
try {
src->mark_streaming_midi_write_started (lck, Sustained);
src->begin_write ();
for (MusicTimeEvents::iterator e = events.begin(); e != events.end(); ++e) {
src->append_event_beats (lck, **e);
}
src->end_write (src->path());
src->mark_nonremovable ();
src->mark_streaming_write_completed (lck);
return true;
} catch (...) {
cerr << "Exception during beatbox write to SMF... " << endl;
}
for (MusicTimeEvents::iterator e = events.begin(); e != events.end(); ++e) {
delete *e;
}
return false;
}