/* ScummVM - Scumm Interpreter
* Copyright (C) 2001-2003 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 "scummsys.h"
#include "common/system.h"
#include "common/file.h"
#include "sound/midistreamer.h"
#include "sound/mixer.h"
#include "simon/simon.h"
MidiPlayer::MidiPlayer() {
// Since initialize() is called every time the music changes,
// this is where we'll initialize stuff that must persist
// between songs.
_masterVolume = 255;
}
void MidiPlayer::read_all_songs(File *in, uint music) {
uint i, num;
_currentSong = _songs;
num = in->readByte();
for (i = 0; i != num; i++) {
read_one_song(in, &_songs[i], music);
}
}
void MidiPlayer::read_all_songs_old(File *in, uint music) {
uint i, num;
_currentSong = _songs;
num = 1;
for (i = 0; i != num; i++) {
read_one_song(in, &_songs[i], music);
}
}
void MidiPlayer::read_all_songs_old(File *in, uint music, uint16 size) {
_currentSong = _songs;
_lastDelay = 0;
read_one_song(in, &_songs[0], music, size);
}
void MidiPlayer::read_mthd(File *in, Song *s, bool old, uint music, uint16 size) {
Track *t;
uint i;
if (!old) {
if (in->readUint32BE() != 6)
error("Invalid 'MThd' chunk size");
s->midi_format = in->readUint16BE();
s->num_tracks = in->readUint16BE();
s->ppqn = in->readUint16BE();
} else {
s->midi_format = 0;
s->num_tracks = 1;
s->ppqn = 0xc0;
in->readUint16BE();
in->readByte();
}
s->tracks = t = (Track *)calloc(s->num_tracks, sizeof(Track));
if (t == NULL)
error("Out of memory when allocating MIDI tracks");
for (i = 0; i != s->num_tracks; i++, t++) {
if (!old) {
if (in->readUint32BE() != 'MTrk')
error("Midi track has no 'MTrk'");
t->data_size = in->readUint32BE();
} else {
//FIXME We currently don't know how to find out music track size for GMF midi format
// So we use music files sizes minues header for now to allow looping
int music_data_size[] = {8900, 12166, 2848, 3442, 4034, 4508, 7064, 9730, 6014, 4742, 3138,
6570, 5384, 8909, 6457, 16321, 2742, 8968, 4804, 8442, 7717,
9444, 5800, 1381, 5660, 6684, 2456, 4744, 2455, 1177, 1232,
17256, 5103, 8794, 4884, 16};
if (size)
t->data_size = size - 8;
else
t->data_size = music_data_size[music] - 8;
}
t->data_ptr = (byte *)calloc(t->data_size, 1);
if (t->data_ptr == NULL)
error("Out of memory when allocating MIDI track data (%d)", t->data_size);
in->read(t->data_ptr, t->data_size);
t->data_cur_size = t->data_size;
t->data_cur_ptr = t->data_ptr;
t->a = 0;
t->last_cmd = 0;
t->delay = 0;
if (t->data_cur_size == 0) {
t->a |= 1;
continue;
}
t->delay = track_read_gamma(t);
}
}
void MidiPlayer::read_one_song(File *in, Song *s, uint music, uint16 size) {
_lastDelay = 0;
s->ppqn = 0;
s->midi_format = 0;
s->num_tracks = 0;
s->tracks = NULL;
uint32 id = in->readUint32BE();
switch (id) {
case 'MThd':
read_mthd(in, s, false, music, size);
break;
case 'GMF\x1':
read_mthd(in, s, true, music, size);
break;
default:
error("Midi song has no 'MThd'");
}
}
uint32 MidiPlayer::track_read_gamma(Track *t) {
uint32 sum;
byte b;
sum = 0;
do {
b = track_read_byte(t);
sum = (sum << 7) | (b & 0x7F);
} while (b & 0x80);
return sum;
}
byte MidiPlayer::track_read_byte(Track *t) {
if (t->a & 1)
error("Trying to read byte from MIDI stream when end reached");
if (!--t->data_cur_size) {
t->a |= 1;
}
return *t->data_cur_ptr++;
}
void MidiPlayer::initialize() {
int res;
int i;
for (i = 0; i != 16; i++)
_volumeTable[i] = 127;
_midiDriver->property(MidiDriver::PROP_TIMEDIV, _songs[0].ppqn);
res = _midiDriver->open();
if (res != 0)
error("MidiPlayer::initializer, got %s", MidiDriver::getErrorName(res));
if (_paused)
_midiDriver->pause (true);
}
int MidiPlayer::fill(MidiEvent *me, int num_event) {
uint32 best, j;
Track *best_track, *t;
bool did_reset;
NoteRec midi_tmp_note_rec;
int i = 0;
did_reset = false;
for (i = 0; i != num_event;) {
best_track = NULL;
best = 0xFFFFFFFF;
/* Locate which track that's next */
t = _currentSong->tracks;
for (j = _currentSong->num_tracks; j; j--, t++) {
if (!(t->a & 1)) {
if (t->delay < best) {
best = t->delay;
best_track = t;
}
}
}
if (best_track == NULL) {
/* reset tracks if song ended? */
if (did_reset) {
/* exit if song ended completely */
return i;
}
did_reset = true;
reset_tracks();
continue;
}
read_next_note(best_track, &midi_tmp_note_rec);
if (fill_helper(&midi_tmp_note_rec, me + i))
i++;
if (midi_tmp_note_rec.sysex_data)
free(midi_tmp_note_rec.sysex_data);
}
return i;
}
int MidiPlayer::on_fill(void *param, MidiEvent *ev, int num) {
MidiPlayer *mp = (MidiPlayer *) param;
return mp->fill(ev, num);
}
bool MidiPlayer::fill_helper(NoteRec *nr, MidiEvent *me) {
uint b;
b = nr->delay - _lastDelay;
_lastDelay = nr->delay;
if (nr->cmd < 0xF0) {
me->delta = b;
me->event = nr->cmd | (nr->param_1 << 8) | (nr->param_2 << 16);
if ((nr->cmd & 0xF0) == 0xB0 && nr->param_1 == 7) {
_volumeTable[nr->cmd & 0xF] = nr->param_2;
// nr->param_1 = 0x76;
me->event = nr->cmd | (nr->param_1 << 8) | ((nr->param_2 * _masterVolume / 255) << 16) /* | MEVT_F_CALLBACK */ ;
}
return true;
}
if (nr->cmd == 0xF0 || nr->cmd == 0xF7 || nr->param_1 != 0x51) {
return false;
}
int tempo = nr->sysex_data[2] | (nr->sysex_data[1] << 8) | (nr->sysex_data[0] << 16);
// _midi_var8 = (_currentSong->ppqn * 60000) / tempo;
me->delta = b;
me->event = (MidiStreamer::ME_TEMPO << 24) | tempo;
return true;
}
void MidiPlayer::reset_tracks() {
if (_midi_sfx_toggle)
return;
Track *t;
uint i;
_lastDelay = 0;
for (i = 0, t = _currentSong->tracks; i != _currentSong->num_tracks; i++, t++) {
t->data_cur_size = t->data_size;
t->data_cur_ptr = t->data_ptr;
t->a = 0;
t->last_cmd = 0;
t->delay = 0;
if (t->data_cur_size == 0) {
t->a |= 1;
} else {
t->delay = track_read_gamma(t);
}
}
}
void MidiPlayer::read_next_note(Track *t, NoteRec *nr) {
byte cmd_byte;
uint i;
nr->delay = 0;
nr->cmd = 0;
nr->param_1 = 0;
nr->param_2 = 0;
nr->cmd_length = 0;
nr->sysex_data = NULL;
if (t->a & 1 || t->data_cur_size == 0)
error("read next note when track ended");
/* read next midi byte, but skip any pitch bends. */
for (;;) {
cmd_byte = track_read_byte(t);
if ((cmd_byte & 0xF0) != 0xE0)
break;
track_read_byte(t);
// track_read_byte(t);
}
if (!(cmd_byte & 0x80)) {
/* running status? */
if (t->last_cmd == 0)
error("Last cmd = 0");
nr->cmd = t->last_cmd;
nr->param_1 = cmd_byte;
cmd_byte = nr->cmd & 0xF0;
nr->cmd_length = 2;
if (cmd_byte != 0xC0 && cmd_byte != 0xD0) {
nr->param_2 = track_read_byte(t);
nr->cmd_length++;
}
} else if ((cmd_byte & 0xF0) != 0xF0) {
nr->cmd = cmd_byte;
t->last_cmd = cmd_byte;
cmd_byte &= 0xF0;
nr->cmd_length = (cmd_byte == 0xC0 || cmd_byte == 0xD0) ? 2 : 3;
if (t->data_cur_size < nr->cmd_length - 1) {
error("read_next_note: end of stream");
}
nr->param_1 = track_read_byte(t);
if (nr->cmd_length == 3)
nr->param_2 = track_read_byte(t);
} else if (cmd_byte == 0xF0 || cmd_byte == 0xF7) {
nr->cmd = cmd_byte;
nr->cmd_length = track_read_gamma(t);
if (t->data_cur_size < nr->cmd_length)
error("read_next_note: end of stream 2");
nr->sysex_data = (byte *)malloc(nr->cmd_length);
if (nr->sysex_data == NULL)
error("read_next_note: out of memory");
for (i = 0; i != nr->cmd_length; i++)
nr->sysex_data[i] = track_read_byte(t);
} else if (cmd_byte == 0xFF) {
nr->cmd = cmd_byte;
nr->param_1 = track_read_byte(t);
nr->cmd_length = track_read_gamma(t);
if (nr->cmd_length) {
if (t->data_cur_size < nr->cmd_length)
error("read_next_note: end of stream 3");
nr->sysex_data = (byte *)malloc(nr->cmd_length);
if (nr->sysex_data == NULL)
error("read_next_note: out of memory");
for (i = 0; i != nr->cmd_length; i++)
nr->sysex_data[i] = track_read_byte(t);
}
if (nr->param_1 == 0x2F)
t->a |= 1;
} else {
error("Invalid sysex cmd");
}
nr->delay = t->delay;
if (!(t->a & 1)) {
t->delay += track_read_gamma(t);
}
}
void MidiPlayer::shutdown() {
_midiDriver->close();
unload();
}
void MidiPlayer::unload() {
uint i, j;
Song *s;
Track *t;
for (i = 0, s = _songs; i != 8; i++, s++) {
if (s->tracks) {
for (j = 0, t = s->tracks; j != s->num_tracks; j++, t++) {
if (t->data_ptr)
free(t->data_ptr);
}
free(s->tracks);
s->tracks = NULL;
}
}
}
void MidiPlayer::play() {
if (!_paused)
_midiDriver->pause(false);
}
void MidiPlayer::pause (bool b) {
if (_paused == b)
return;
_paused = b;
_midiDriver->pause(b);
for (int i = ARRAYSIZE (_volumeTable); i; --i) {
_midiDriver->send (((_paused ? 0 : (_volumeTable[i-1] * _masterVolume / 255)) << 16) | (7 << 8) | 0xB0 | i);
}
}
int MidiPlayer::get_volume() {
return _masterVolume;
}
void MidiPlayer::set_volume (int volume) {
if (volume < 0)
volume = 0;
else if (volume > 255)
volume = 255;
if (_masterVolume == volume)
return;
_masterVolume = volume;
// Now tell all the channels this.
if (_midiDriver && !_paused) {
for (int i = ARRAYSIZE (_volumeTable); i; --i) {
_midiDriver->send (((_volumeTable[i-1] * _masterVolume / 255) << 16) | (7 << 8) | 0xB0 | i);
}
}
}
void MidiPlayer::set_driver(MidiDriver *md) {
// We must always use the MidiStreamer front-end
// so we can support user-initiated MIDI events (like volume).
_midiDriver = new MidiStreamer (md);
_midiDriver->set_stream_callback(this, on_fill);
}