scummvm/sound/midiparser.cpp

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/* ScummVM - Scumm Interpreter
* Copyright (C) 2001-2004 The ScummVM project
*
* 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., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*
* $Header$
*
*/
#include "stdafx.h"
#include "midiparser.h"
#include "mididrv.h"
#include "common/util.h"
//////////////////////////////////////////////////
//
// MidiParser implementation
//
//////////////////////////////////////////////////
MidiParser::MidiParser() :
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_hanging_notes_count (0),
_driver (0),
_timer_rate (0x4A0000),
_ppqn (96),
_tempo (500000),
_psec_per_tick (5208), // 500000 / 96
_autoLoop (false),
_smartJump (false),
_num_tracks (0),
_active_track (255),
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_abort_parse (0) {
memset (_active_notes, 0, sizeof(_active_notes));
}
void MidiParser::property (int prop, int value) {
switch (prop) {
case mpAutoLoop:
_autoLoop = (value != 0);
case mpSmartJump:
_smartJump = (value != 0);
}
}
void MidiParser::setTempo (uint32 tempo) {
_tempo = tempo;
if (_ppqn)
_psec_per_tick = (tempo + (_ppqn >> 2)) / _ppqn;
}
// This is the conventional (i.e. SMF) variable length quantity
uint32 MidiParser::readVLQ (byte * &data) {
byte str;
uint32 value = 0;
int i;
for (i = 0; i < 4; ++i) {
str = data[0];
++data;
value = (value << 7) | (str & 0x7F);
if (!(str & 0x80))
break;
}
return value;
}
void MidiParser::activeNote (byte channel, byte note, bool active) {
if (note >= 128 || channel >= 16)
return;
if (active)
_active_notes[note] |= (1 << channel);
else
_active_notes[note] &= ~(1 << channel);
// See if there are hanging notes that we can cancel
NoteTimer *ptr = _hanging_notes;
int i;
for (i = ARRAYSIZE(_hanging_notes); i; --i, ++ptr) {
if (ptr->channel == channel && ptr->note == note && ptr->time_left) {
ptr->time_left = 0;
--_hanging_notes_count;
break;
}
}
}
void MidiParser::hangingNote (byte channel, byte note, uint32 time_left, bool recycle) {
NoteTimer *best = 0;
NoteTimer *ptr = _hanging_notes;
int i;
if (_hanging_notes_count >= ARRAYSIZE(_hanging_notes)) {
printf ("WARNING! MidiParser::hangingNote(): Exceeded polyphony!\n");
return;
}
for (i = ARRAYSIZE(_hanging_notes); i; --i, ++ptr) {
if (ptr->channel == channel && ptr->note == note) {
if (ptr->time_left && ptr->time_left < time_left && recycle)
return;
best = ptr;
if (ptr->time_left) {
if (recycle) _driver->send (0x80 | channel | note << 8);
--_hanging_notes_count;
}
break;
} else if (!best && ptr->time_left == 0) {
best = ptr;
}
}
// Occassionally we might get a zero or negative note
// length, if the note should be turned on and off in
// the same iteration. For now just set it to 1 and
// we'll turn it off in the next cycle.
if (!time_left || time_left & 0x80000000)
time_left = 1;
if (best) {
best->channel = channel;
best->note = note;
best->time_left = time_left;
++_hanging_notes_count;
} else {
// We checked this up top. We should never get here!
printf ("WARNING! MidiParser::hangingNote(): Internal error!\n");
}
}
void MidiParser::onTimer() {
uint32 end_time;
uint32 event_time;
if (!_position._play_pos || !_driver)
return;
_abort_parse = false;
end_time = _position._play_time + _timer_rate;
// Scan our hanging notes for any
// that should be turned off.
if (_hanging_notes_count) {
NoteTimer *ptr = &_hanging_notes[0];
int i;
for (i = ARRAYSIZE(_hanging_notes); i; --i, ++ptr) {
if (ptr->time_left) {
if (ptr->time_left <= _timer_rate) {
_driver->send (0x80 | ptr->channel | ptr->note << 8);
ptr->time_left = 0;
--_hanging_notes_count;
} else {
ptr->time_left -= _timer_rate;
}
}
}
}
while (!_abort_parse) {
EventInfo &info = _next_event;
event_time = _position._last_event_time + info.delta * _psec_per_tick;
if (event_time > end_time)
break;
// Process the next info.
_position._last_event_tick += info.delta;
if (info.event < 0x80) {
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printf ("ERROR! Bad command or running status %02X\n", info.event);
_position._play_pos = 0;
return;
}
if (info.event == 0xF0) {
// SysEx event
_driver->sysEx (info.ext.data, (uint16) info.length);
} else if (info.event == 0xFF) {
// META event
if (info.ext.type == 0x2F) {
// End of Track must be processed by us,
// as well as sending it to the output device.
if (_autoLoop) {
jumpToTick (0);
parseNextEvent (_next_event);
} else {
allNotesOff();
resetTracking();
_driver->metaEvent (info.ext.type, info.ext.data, (uint16) info.length);
}
return;
} else if (info.ext.type == 0x51) {
if (info.length >= 3) {
setTempo (info.ext.data[0] << 16 | info.ext.data[1] << 8 | info.ext.data[2]);
}
}
_driver->metaEvent (info.ext.type, info.ext.data, (uint16) info.length);
} else {
if (info.command() == 0x8) {
activeNote (info.channel(), info.basic.param1, false);
} else if (info.command() == 0x9) {
if (info.length > 0)
hangingNote (info.channel(), info.basic.param1, info.length * _psec_per_tick - (end_time - event_time));
else
activeNote (info.channel(), info.basic.param1, true);
}
_driver->send (info.event | info.basic.param1 << 8 | info.basic.param2 << 16);
}
if (!_abort_parse) {
_position._last_event_time = event_time;
parseNextEvent (_next_event);
}
}
if (!_abort_parse) {
_position._play_time = end_time;
_position._play_tick = (_position._play_time - _position._last_event_time) / _psec_per_tick + _position._last_event_tick;
}
}
void MidiParser::allNotesOff() {
if (!_driver)
return;
int i, j;
// Turn off all active notes
for (i = 0; i < 128; ++i) {
for (j = 0; j < 16; ++j) {
if (_active_notes[i] & (1 << j)) {
_driver->send (0x80 | j | i << 8);
}
}
}
// To be sure, send an "All Note Off" event (but not all MIDI devices support this...)
for (i = 0; i < 16; ++i)
_driver->send (0x007BB0 | i);
for (i = 0; i < ARRAYSIZE(_hanging_notes); ++i)
_hanging_notes[i].time_left = 0;
_hanging_notes_count = 0;
memset (_active_notes, 0, sizeof(_active_notes));
}
void MidiParser::resetTracking() {
_position.clear();
}
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bool MidiParser::setTrack (int track) {
if (track < 0 || track >= _num_tracks)
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return false;
else if (track == _active_track)
return true;
if (_smartJump)
hangAllActiveNotes();
else
allNotesOff();
resetTracking();
memset (_active_notes, 0, sizeof(_active_notes));
_active_track = track;
_position._play_pos = _tracks[track];
parseNextEvent (_next_event);
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return true;
}
void MidiParser::hangAllActiveNotes() {
// Search for note off events until we have
// accounted for every active note.
uint16 temp_active [128];
memcpy (temp_active, _active_notes, sizeof (temp_active));
uint32 advance_tick = _position._last_event_tick;
while (true) {
int i, j;
for (i = 0; i < 128; ++i)
if (temp_active[i] != 0) break;
if (i == 128) break;
parseNextEvent (_next_event);
advance_tick += _next_event.delta;
if (_next_event.command() == 0x8) {
if (temp_active[_next_event.basic.param1] & (1 << _next_event.channel())) {
hangingNote (_next_event.channel(), _next_event.basic.param1, (advance_tick - _position._last_event_tick) * _psec_per_tick, false);
temp_active[_next_event.basic.param1] &= ~ (1 << _next_event.channel());
}
} else if (_next_event.event == 0xFF && _next_event.ext.type == 0x2F) {
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// printf ("MidiParser::hangAllActiveNotes(): Hit End of Track with active notes left!\n");
for (i = 0; i < 128; ++i) {
for (j = 0; j < 16; ++j) {
if (temp_active[i] & (1 << j)) {
activeNote (j, i, false);
_driver->send (0x80 | j | i << 8);
}
}
}
break;
}
}
}
bool MidiParser::jumpToTick (uint32 tick, bool fireEvents) {
if (_active_track >= _num_tracks)
return false;
Tracker currentPos (_position);
EventInfo currentEvent (_next_event);
resetTracking();
_position._play_pos = _tracks[_active_track];
parseNextEvent (_next_event);
if (tick > 0) {
while (true) {
EventInfo &info = _next_event;
if (_position._last_event_tick + info.delta >= tick) {
_position._play_time += (tick - _position._last_event_tick) * _psec_per_tick;
_position._play_tick = tick;
break;
}
_position._last_event_tick += info.delta;
_position._last_event_time += info.delta * _psec_per_tick;
_position._play_tick = _position._last_event_tick;
_position._play_time = _position._last_event_time;
if (info.event == 0xFF) {
if (info.ext.type == 0x2F) { // End of track
_position = currentPos;
_next_event = currentEvent;
return false;
} else {
if (info.ext.type == 0x51 && info.length >= 3) // Tempo
setTempo (info.ext.data[0] << 16 | info.ext.data[1] << 8 | info.ext.data[2]);
if (fireEvents)
_driver->metaEvent (info.ext.type, info.ext.data, (uint16) info.length);
}
} else if (fireEvents) {
if (info.event == 0xF0)
_driver->sysEx (info.ext.data, (uint16) info.length);
else
_driver->send (info.event | info.basic.param1 << 8 | info.basic.param2 << 16);
}
parseNextEvent (_next_event);
}
}
if (!_smartJump || !currentPos._play_pos) {
allNotesOff();
} else {
EventInfo targetEvent (_next_event);
Tracker targetPosition (_position);
_position = currentPos;
_next_event = currentEvent;
hangAllActiveNotes();
_next_event = targetEvent;
_position = targetPosition;
}
_abort_parse = true;
return true;
}
void MidiParser::unloadMusic() {
resetTracking();
allNotesOff();
_num_tracks = 0;
_active_track = 255;
_abort_parse = true;
}