/* Copyright (C) 2008 Paul Davis Author: Hans Baier 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., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include #include #include #include #include "pbd/error.h" #include "pbd/failed_constructor.h" #include "pbd/pthread_utils.h" #include "pbd/convert.h" #include "midi++/port.h" #include "ardour/debug.h" #include "ardour/midi_buffer.h" #include "ardour/midi_port.h" #include "ardour/slave.h" #include "ardour/tempo.h" #include "pbd/i18n.h" using namespace std; using namespace ARDOUR; using namespace MIDI; using namespace PBD; MIDIClock_Slave::MIDIClock_Slave (Session& s, MidiPort& p, int ppqn) : ppqn (ppqn) , bandwidth (2.0 / 60.0) // 1 BpM = 1 / 60 Hz { session = (ISlaveSessionProxy *) new SlaveSessionProxy(s); rebind (p); reset (); } MIDIClock_Slave::MIDIClock_Slave (ISlaveSessionProxy* session_proxy, int ppqn) : session(session_proxy) , ppqn (ppqn) , bandwidth (2.0 / 60.0) // 1 BpM = 1 / 60 Hz { reset (); } MIDIClock_Slave::~MIDIClock_Slave() { delete session; } void MIDIClock_Slave::rebind (MidiPort& port) { DEBUG_TRACE (DEBUG::MidiClock, string_compose ("MIDIClock_Slave: connecting to port %1\n", port.name())); port_connections.drop_connections (); port.self_parser().timing.connect_same_thread (port_connections, boost::bind (&MIDIClock_Slave::update_midi_clock, this, _1, _2)); port.self_parser().start.connect_same_thread (port_connections, boost::bind (&MIDIClock_Slave::start, this, _1, _2)); port.self_parser().contineu.connect_same_thread (port_connections, boost::bind (&MIDIClock_Slave::contineu, this, _1, _2)); port.self_parser().stop.connect_same_thread (port_connections, boost::bind (&MIDIClock_Slave::stop, this, _1, _2)); port.self_parser().position.connect_same_thread (port_connections, boost::bind (&MIDIClock_Slave::position, this, _1, _2, 3)); } void MIDIClock_Slave::calculate_one_ppqn_in_frames_at(framepos_t time) { const double frames_per_quarter_note = session->tempo_map().frames_per_quarter_note_at (time, session->frame_rate()); one_ppqn_in_frames = frames_per_quarter_note / double (ppqn); // DEBUG_TRACE (DEBUG::MidiClock, string_compose ("at %1, one ppqn = %2\n", time, one_ppqn_in_frames)); } ARDOUR::framepos_t MIDIClock_Slave::calculate_song_position(uint16_t song_position_in_sixteenth_notes) { framepos_t song_position_frames = 0; for (uint16_t i = 1; i <= song_position_in_sixteenth_notes; ++i) { // one quarter note contains ppqn pulses, so a sixteenth note is ppqn / 4 pulses calculate_one_ppqn_in_frames_at(song_position_frames); song_position_frames += one_ppqn_in_frames * (framepos_t)(ppqn / 4); } return song_position_frames; } void MIDIClock_Slave::calculate_filter_coefficients() { // omega = 2 * PI * Bandwidth / MIDI clock frame frequency in Hz omega = 2.0 * M_PI * bandwidth * one_ppqn_in_frames / session->frame_rate(); b = 1.4142135623730950488 * omega; c = omega * omega; } void MIDIClock_Slave::update_midi_clock (Parser& /*parser*/, framepos_t timestamp) { // some pieces of hardware send MIDI Clock all the time if ( (!_starting) && (!_started) ) { return; } pframes_t cycle_offset = timestamp - session->sample_time_at_cycle_start(); calculate_one_ppqn_in_frames_at(should_be_position); framepos_t elapsed_since_start = timestamp - first_timestamp; double error = 0; if (_starting || last_timestamp == 0) { midi_clock_count = 0; first_timestamp = timestamp; elapsed_since_start = should_be_position; DEBUG_TRACE (DEBUG::MidiClock, string_compose ("first clock message after start received @ %1\n", timestamp)); // calculate filter coefficients calculate_filter_coefficients(); // initialize DLL e2 = double(one_ppqn_in_frames) / double(session->frame_rate()); t0 = double(elapsed_since_start) / double(session->frame_rate()); t1 = t0 + e2; // let ardour go after first MIDI Clock Event _starting = false; } else { midi_clock_count++; should_be_position += one_ppqn_in_frames; calculate_filter_coefficients(); // calculate loop error // we use session->transport_frame() instead of t1 here // because t1 is used to calculate the transport speed, // so the loop will compensate for accumulating rounding errors error = (double(should_be_position) - (double(session->transport_frame()) + double(cycle_offset))); e = error / double(session->frame_rate()); current_delta = error; // update DLL t0 = t1; t1 += b * e + e2; e2 += c * e; } DEBUG_TRACE (DEBUG::MidiClock, string_compose ("clock #%1 @ %2 should-be %3 transport %4 error %5 appspeed %6 " "read-delta %7 should-be delta %8 t1-t0 %9 t0 %10 t1 %11 framerate %12 engine %13\n", midi_clock_count, // # elapsed_since_start, // @ should_be_position, // should-be session->transport_frame(), // transport error, // error ((t1 - t0) * session->frame_rate()) / one_ppqn_in_frames, // appspeed timestamp - last_timestamp, // read delta one_ppqn_in_frames, // should-be delta (t1 - t0) * session->frame_rate(), // t1-t0 t0 * session->frame_rate(), // t0 t1 * session->frame_rate(), // t1 session->frame_rate(), // framerate session->frame_time() )); last_timestamp = timestamp; } void MIDIClock_Slave::start (Parser& /*parser*/, framepos_t timestamp) { DEBUG_TRACE (DEBUG::MidiClock, string_compose ("MIDIClock_Slave got start message at time %1 engine time %2 transport_frame %3\n", timestamp, session->frame_time(), session->transport_frame())); if (!_started) { reset(); _started = true; _starting = true; should_be_position = session->transport_frame(); } } void MIDIClock_Slave::reset () { DEBUG_TRACE (DEBUG::MidiClock, string_compose ("MidiClock_Slave reset(): calculated filter bandwidth is %1 for period size %2\n", bandwidth, session->frames_per_cycle())); should_be_position = session->transport_frame(); last_timestamp = 0; _starting = true; _started = true; // session->request_locate(0, false); current_delta = 0; } void MIDIClock_Slave::contineu (Parser& /*parser*/, framepos_t /*timestamp*/) { DEBUG_TRACE (DEBUG::MidiClock, "MIDIClock_Slave got continue message\n"); if (!_started) { _starting = true; _started = true; } } void MIDIClock_Slave::stop (Parser& /*parser*/, framepos_t /*timestamp*/) { DEBUG_TRACE (DEBUG::MidiClock, "MIDIClock_Slave got stop message\n"); if (_started || _starting) { _starting = false; _started = false; // locate to last MIDI clock position session->request_transport_speed(0.0); // we need to go back to the last MIDI beat (6 ppqn) // and lets hope the tempo didnt change in the meantime :) // begin at the should be position, because // that is the position of the last MIDI Clock // message and that is probably what the master // expects where we are right now framepos_t stop_position = should_be_position; // find out the last MIDI beat: go back #midi_clocks mod 6 // and lets hope the tempo didnt change in those last 6 beats :) stop_position -= (midi_clock_count % 6) * one_ppqn_in_frames; session->request_locate(stop_position, false); should_be_position = stop_position; last_timestamp = 0; } } void MIDIClock_Slave::position (Parser& /*parser*/, MIDI::byte* message, size_t size) { // we are note supposed to get position messages while we are running // so lets be robust and ignore those if (_started || _starting) { return; } assert(size == 3); MIDI::byte lsb = message[1]; MIDI::byte msb = message[2]; assert((lsb <= 0x7f) && (msb <= 0x7f)); uint16_t position_in_sixteenth_notes = (uint16_t(msb) << 7) | uint16_t(lsb); framepos_t position_in_frames = calculate_song_position(position_in_sixteenth_notes); DEBUG_TRACE (DEBUG::MidiClock, string_compose ("Song Position: %1 frames: %2\n", position_in_sixteenth_notes, position_in_frames)); session->request_locate(position_in_frames, false); should_be_position = position_in_frames; last_timestamp = 0; } bool MIDIClock_Slave::locked () const { return true; } bool MIDIClock_Slave::ok() const { return true; } bool MIDIClock_Slave::starting() const { return false; } bool MIDIClock_Slave::stop_if_no_more_clock_events(framepos_t& pos, framepos_t now) { /* no timecode for 1/4 second ? conclude that its stopped */ if (last_timestamp && now > last_timestamp && now - last_timestamp > session->frame_rate() / 4) { DEBUG_TRACE (DEBUG::MidiClock, "No MIDI Clock frames received for some time, stopping!\n"); pos = should_be_position; session->request_transport_speed (0); session->request_locate (should_be_position, false); return true; } else { return false; } } bool MIDIClock_Slave::speed_and_position (double& speed, framepos_t& pos) { if (!_started || _starting) { speed = 0.0; pos = should_be_position; return true; } framepos_t engine_now = session->frame_time(); if (stop_if_no_more_clock_events(pos, engine_now)) { return false; } // calculate speed speed = ((t1 - t0) * session->frame_rate()) / one_ppqn_in_frames; // provide a 0.1% deadzone to lock the speed if (fabs(speed - 1.0) <= 0.001) speed = 1.0; // calculate position if (engine_now > last_timestamp) { // we are in between MIDI clock messages // so we interpolate position according to speed framecnt_t elapsed = engine_now - last_timestamp; pos = (framepos_t) (should_be_position + double(elapsed) * speed); } else { // A new MIDI clock message has arrived this cycle pos = should_be_position; } DEBUG_TRACE (DEBUG::MidiClock, string_compose ("speed_and_position: speed %1 should-be %2 transport %3 \n", speed, pos, session->transport_frame())); return true; } ARDOUR::framecnt_t MIDIClock_Slave::resolution() const { // one beat return (framecnt_t) one_ppqn_in_frames * ppqn; } std::string MIDIClock_Slave::approximate_current_delta() const { char delta[80]; if (last_timestamp == 0 || _starting) { snprintf(delta, sizeof(delta), "\u2012\u2012\u2012\u2012"); } else { snprintf(delta, sizeof(delta), "\u0394%s%s%" PRIi64 "sm", LEADINGZERO(abs(current_delta)), PLUSMINUS(-current_delta), abs(current_delta)); } return std::string(delta); }