scummvm/engines/mohawk/sound.cpp

530 lines
16 KiB
C++

/* ScummVM - Graphic Adventure Engine
*
* ScummVM is the legal property of its developers, whose names
* are too numerous to list here. Please refer to the COPYRIGHT
* file distributed with this source distribution.
*
* 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.
*
* $URL$
* $Id$
*
*/
#include "mohawk/sound.h"
#include "common/util.h"
#include "sound/audiostream.h"
#include "sound/mp3.h"
#include "sound/raw.h"
#include "sound/wave.h"
namespace Mohawk {
Sound::Sound(MohawkEngine* vm) : _vm(vm) {
_rivenSoundFile = NULL;
_midiDriver = NULL;
_midiParser = NULL;
for (uint32 i = 0; i < _handles.size(); i++) {
_handles[i].handle = Audio::SoundHandle();
_handles[i].type = kFreeHandle;
}
initMidi();
}
Sound::~Sound() {
stopSound();
stopAllSLST();
delete _rivenSoundFile;
if (_midiDriver) {
_midiDriver->close();
delete _midiDriver;
}
if (_midiParser) {
_midiParser->unloadMusic();
delete _midiParser;
}
}
void Sound::loadRivenSounds(uint16 stack) {
static const char prefixes[] = { 'a', 'b', 'g', 'j', 'o', 'p', 'r', 't' };
if (!_rivenSoundFile)
_rivenSoundFile = new MohawkArchive();
_rivenSoundFile->open(Common::String(prefixes[stack]) + "_Sounds.mhk");
}
void Sound::initMidi() {
if (!(_vm->getFeatures() & GF_HASMIDI))
return;
// Let's get our MIDI parser/driver
_midiParser = MidiParser::createParser_SMF();
_midiDriver = MidiDriver::createMidi(MidiDriver::detectMusicDriver(MDT_ADLIB|MDT_MIDI));
// Set up everything!
_midiDriver->open();
_midiParser->setMidiDriver(_midiDriver);
_midiParser->setTimerRate(_midiDriver->getBaseTempo());
}
Audio::SoundHandle *Sound::playSound(uint16 id, bool mainSoundFile, byte volume) {
debug (0, "Playing sound %d", id);
SndHandle *handle = getHandle();
handle->type = kUsedHandle;
Audio::AudioStream* audStream = NULL;
switch (_vm->getGameType()) {
case GType_MYST:
if (_vm->getFeatures() & GF_ME) {
// Myst ME is a bit more efficient with sound storage than Myst
// Myst has lots of sounds repeated. To overcome this, Myst ME
// has MJMP resources which provide a link to the actual MSND
// resource we're looking for. This saves a lot of space from
// repeated data.
if (_vm->hasResource(ID_MJMP, id)) {
Common::SeekableReadStream *mjmpStream = _vm->getRawData(ID_MJMP, id);
id = mjmpStream->readUint16LE();
delete mjmpStream;
}
audStream = Audio::makeWAVStream(_vm->getRawData(ID_MSND, id), DisposeAfterUse::YES);
} else
audStream = makeMohawkWaveStream(_vm->getRawData(ID_MSND, id));
break;
case GType_RIVEN:
if (mainSoundFile)
audStream = makeMohawkWaveStream(_rivenSoundFile->getRawData(ID_TWAV, id));
else
audStream = makeMohawkWaveStream(_vm->getRawData(ID_TWAV, id));
break;
case GType_ZOOMBINI:
audStream = makeMohawkWaveStream(_vm->getRawData(ID_SND, id));
break;
case GType_CSAMTRAK:
if (mainSoundFile)
audStream = makeMohawkWaveStream(_vm->getRawData(ID_TWAV, id));
else
audStream = getCSAmtrakMusic(id);
break;
case GType_LIVINGBOOKSV1:
audStream = makeOldMohawkWaveStream(_vm->getRawData(ID_WAV, id));
break;
default:
audStream = makeMohawkWaveStream(_vm->getRawData(ID_TWAV, id));
}
if (audStream) {
_vm->_mixer->playInputStream(Audio::Mixer::kPlainSoundType, &handle->handle, audStream, -1, volume);
return &handle->handle;
}
return NULL;
}
void Sound::playMidi(uint16 id) {
uint32 idTag;
if (!(_vm->getFeatures() & GF_HASMIDI)) {
warning ("Attempting to play MIDI in a game without MIDI");
return;
}
assert(_midiDriver && _midiParser);
_midiParser->unloadMusic();
Common::SeekableReadStream *midi = _vm->getRawData(ID_TMID, id);
idTag = midi->readUint32BE();
assert(idTag == ID_MHWK);
midi->readUint32BE(); // Skip size
idTag = midi->readUint32BE();
assert(idTag == ID_MIDI);
byte *midiData = (byte *)malloc(midi->size() - 12); // Enough to cover MThd/Prg#/MTrk
// Read the MThd Data
midi->read(midiData, 14);
// Skip the unknown Prg# section
idTag = midi->readUint32BE();
assert(idTag == ID_PRG);
midi->skip(midi->readUint32BE());
// Read the MTrk Data
uint32 mtrkSize = midi->size() - midi->pos();
midi->read(midiData + 14, mtrkSize);
delete midi;
// Now, play it :)
if (!_midiParser->loadMusic(midiData, 14 + mtrkSize))
error ("Could not play MIDI music from tMID %04x\n", id);
_midiDriver->setTimerCallback(_midiParser, MidiParser::timerCallback);
}
void Sound::playSLST(uint16 index, uint16 card) {
Common::SeekableReadStream *slstStream = _vm->getRawData(ID_SLST, card);
SLSTRecord slstRecord;
uint16 recordCount = slstStream->readUint16BE();
for (uint16 i = 0; i < recordCount; i++) {
slstRecord.index = slstStream->readUint16BE();
slstRecord.sound_count = slstStream->readUint16BE();
slstRecord.sound_ids = new uint16[slstRecord.sound_count];
for (uint16 j = 0; j < slstRecord.sound_count; j++)
slstRecord.sound_ids[j] = slstStream->readUint16BE();
slstRecord.fade_flags = slstStream->readUint16BE();
slstRecord.loop = slstStream->readUint16BE();
slstRecord.global_volume = slstStream->readUint16BE();
slstRecord.u0 = slstStream->readUint16BE(); // Unknown
if (slstRecord.u0 > 1)
warning("slstRecord.u0: %d non-boolean", slstRecord.u0);
slstRecord.u1 = slstStream->readUint16BE(); // Unknown
if (slstRecord.u1 != 0)
warning("slstRecord.u1: %d non-zero", slstRecord.u1);
slstRecord.volumes = new uint16[slstRecord.sound_count];
slstRecord.balances = new int16[slstRecord.sound_count];
slstRecord.u2 = new uint16[slstRecord.sound_count];
for (uint16 j = 0; j < slstRecord.sound_count; j++)
slstRecord.volumes[j] = slstStream->readUint16BE();
for (uint16 j = 0; j < slstRecord.sound_count; j++)
slstRecord.balances[j] = slstStream->readSint16BE(); // negative = left, 0 = center, positive = right
for (uint16 j = 0; j < slstRecord.sound_count; j++) {
slstRecord.u2[j] = slstStream->readUint16BE(); // Unknown
if (slstRecord.u2[j] != 255 && slstRecord.u2[j] != 256)
warning("slstRecord.u2[%d]: %d not 255 or 256", j, slstRecord.u2[j]);
}
if (slstRecord.index == index) {
playSLST(slstRecord);
delete slstStream;
return;
}
delete[] slstRecord.sound_ids;
delete[] slstRecord.volumes;
delete[] slstRecord.balances;
delete[] slstRecord.u2;
}
delete slstStream;
// No matching records, assume we need to stop all SLST's
stopAllSLST();
}
void Sound::playSLST(SLSTRecord slstRecord) {
// End old sounds
for (uint16 i = 0; i < _currentSLSTSounds.size(); i++) {
bool noLongerPlay = true;
for (uint16 j = 0; j < slstRecord.sound_count; j++)
if (_currentSLSTSounds[i].id == slstRecord.sound_ids[j])
noLongerPlay = false;
if (noLongerPlay)
stopSLSTSound(i, (slstRecord.fade_flags & 1) != 0);
}
// Start new sounds
for (uint16 i = 0; i < slstRecord.sound_count; i++) {
bool alreadyPlaying = false;
for (uint16 j = 0; j < _currentSLSTSounds.size(); j++) {
if (_currentSLSTSounds[j].id == slstRecord.sound_ids[i])
alreadyPlaying = true;
}
if (!alreadyPlaying) {
playSLSTSound(slstRecord.sound_ids[i],
(slstRecord.fade_flags & (1 << 1)) != 0,
slstRecord.loop != 0,
slstRecord.volumes[i],
slstRecord.balances[i]);
}
}
}
void Sound::stopAllSLST() {
for (uint16 i = 0; i < _currentSLSTSounds.size(); i++)
_vm->_mixer->stopHandle(*_currentSLSTSounds[i].handle);
_currentSLSTSounds.clear();
}
static int8 convertBalance(int16 balance) {
return (int8)(balance >> 8);
}
void Sound::playSLSTSound(uint16 id, bool fade, bool loop, uint16 volume, int16 balance) {
// WORKAROUND: Some Riven SLST entries have a volume of 0, so we just ignore them.
if (volume == 0)
return;
SLSTSndHandle sndHandle;
sndHandle.handle = new Audio::SoundHandle();
sndHandle.id = id;
_currentSLSTSounds.push_back(sndHandle);
Audio::AudioStream *audStream = makeMohawkWaveStream(_rivenSoundFile->getRawData(ID_TWAV, id), loop);
// The max mixer volume is 255 and the max Riven volume is 256. Just change it to 255.
if (volume == 256)
volume = 255;
// TODO: Handle fading, possibly just raise the volume of the channel in increments?
_vm->_mixer->playInputStream(Audio::Mixer::kPlainSoundType, sndHandle.handle, audStream, -1, volume, convertBalance(balance));
}
void Sound::stopSLSTSound(uint16 index, bool fade) {
// TODO: Fade out, mixer needs to be extended to get volume on a handle
_vm->_mixer->stopHandle(*_currentSLSTSounds[index].handle);
_currentSLSTSounds.remove_at(index);
}
void Sound::pauseSLST() {
for (uint16 i = 0; i < _currentSLSTSounds.size(); i++)
_vm->_mixer->pauseHandle(*_currentSLSTSounds[i].handle, true);
}
void Sound::resumeSLST() {
for (uint16 i = 0; i < _currentSLSTSounds.size(); i++)
_vm->_mixer->pauseHandle(*_currentSLSTSounds[i].handle, false);
}
Audio::AudioStream *Sound::getCSAmtrakMusic(uint16 id) {
char filename[18];
sprintf(filename, "MUSIC/MUSIC%02d.MHK", id);
MohawkArchive *file = new MohawkArchive();
file->open(filename);
Audio::AudioStream *audStream = makeMohawkWaveStream(file->getRawData(ID_TWAV, 2000 + id));
delete file;
return audStream;
}
Audio::AudioStream *Sound::makeMohawkWaveStream(Common::SeekableReadStream *stream, bool loop) {
bool foundData = false;
uint32 tag = 0;
ADPC_Chunk adpc;
Cue_Chunk cue;
Data_Chunk data_chunk;
if (stream->readUint32BE() == ID_MHWK) // MHWK tag again
debug(2, "Found Tag MHWK");
else
error ("Could not find tag \'MHWK\'");
stream->readUint32BE(); // Skip size
if (stream->readUint32BE() == ID_WAVE)
debug(2, "Found Tag WAVE");
else
error ("Could not find tag \'WAVE\'");
while (!foundData) {
tag = stream->readUint32BE();
switch (tag) {
case ID_ADPC:
debug(2, "Found Tag ADPC");
// Riven ADPCM Sound Only
// NOTE: This is completely useless for us. All of this
// is already in the ADPCM decoder in /sound.
adpc.size = stream->readUint32BE();
adpc.u0 = stream->readUint16BE();
adpc.channels = stream->readUint16BE();
adpc.u1 = stream->readUint32BE();
for (uint16 i = 0; i < adpc.channels; i++)
adpc.u2[i] = stream->readUint32BE();
if (adpc.u0 == 2) {
adpc.u3 = stream->readUint32BE();
for (uint16 i = 0; i < adpc.channels; i++)
adpc.u4[i] = stream->readUint32BE();
}
break;
case ID_CUE:
debug(2, "Found Tag Cue#");
// I have not tested this with Myst, but the one Riven test-case,
// pspit tWAV 3, has two cue points: "Beg Loop" and "End Loop".
// So, my guess is that a cue chunk just holds where to loop the
// sound. Some cue chunks even have no point count (such as
// Myst's intro.dat MSND 2. So, my theory is that a cue chunk
// always represents a loop, and if there is a point count, that
// represents the points from which to loop.
//
// This theory is probably not entirely true anymore. I've found
// that the values (which were previously unknown) in the DATA
// chunk are for looping. Since it was only used in Myst, it was
// always 10 0's, Tito just thought it was useless. I'm still not
// sure what purpose this has.
cue.size = stream->readUint32BE();
cue.point_count = stream->readUint16BE();
if (cue.point_count == 0)
debug (2, "Cue# chunk found with no points!");
else
debug (2, "Cue# chunk found with %d point(s)!", cue.point_count);
for (uint16 i = 0; i < cue.point_count; i++) {
cue.cueList[i].position = stream->readUint32BE();
cue.cueList[i].length = stream->readByte();
for (byte j = 0; j < cue.cueList[i].length; j++)
cue.cueList[i].name += stream->readByte();
// Realign to uint16 boundaries...
if (!(cue.cueList[i].length & 1))
stream->readByte();
debug (3, "Cue# chunk point %d: %s", i, cue.cueList[i].name.c_str());
}
break;
case ID_DATA:
debug(2, "Found Tag DATA");
// We subtract 20 from the actual chunk size, which is the total size
// of the chunk's header
data_chunk.size = stream->readUint32BE() - 20;
data_chunk.sample_rate = stream->readUint16BE();
data_chunk.sample_count = stream->readUint32BE();
data_chunk.bitsPerSample = stream->readByte();
data_chunk.channels = stream->readByte();
data_chunk.encoding = stream->readUint16BE();
data_chunk.loop = stream->readUint16BE();
data_chunk.loopStart = stream->readUint32BE();
data_chunk.loopEnd = stream->readUint32BE();
data_chunk.audio_data = (byte *)malloc(data_chunk.size);
stream->read(data_chunk.audio_data, data_chunk.size);
foundData = true;
break;
default:
error ("Unknown tag found in 'tWAV' chunk -- \'%s\'", tag2str(tag));
}
}
// makeMohawkWaveStream always takes control of the original stream
delete stream;
// The sound in Myst uses raw unsigned 8-bit data
// The sound in the CD version of Riven is encoded in Intel DVI ADPCM
// The sound in the DVD version of Riven is encoded in MPEG-2 Layer II or Intel DVI ADPCM
if (data_chunk.encoding == kCodecRaw) {
byte flags = Audio::FLAG_UNSIGNED;
if (data_chunk.channels == 2)
flags |= Audio::FLAG_STEREO;
if (data_chunk.loop == 0xFFFF || loop)
flags |= Audio::FLAG_LOOP;
return Audio::makeRawMemoryStream(data_chunk.audio_data, data_chunk.size, DisposeAfterUse::YES, data_chunk.sample_rate, flags, data_chunk.loopStart, data_chunk.loopEnd);
} else if (data_chunk.encoding == kCodecADPCM) {
Common::MemoryReadStream *dataStream = new Common::MemoryReadStream(data_chunk.audio_data, data_chunk.size, DisposeAfterUse::YES);
uint32 blockAlign = data_chunk.channels * data_chunk.bitsPerSample / 8;
return makeLoopingAudioStream(Audio::makeADPCMStream(dataStream, true, data_chunk.size, Audio::kADPCMIma, data_chunk.sample_rate, data_chunk.channels, blockAlign), loop ? 0 : 1);
} else if (data_chunk.encoding == kCodecMPEG2) {
#ifdef USE_MAD
Common::MemoryReadStream *dataStream = new Common::MemoryReadStream(data_chunk.audio_data, data_chunk.size, DisposeAfterUse::YES);
return Audio::makeLoopingAudioStream(Audio::makeMP3Stream(dataStream, DisposeAfterUse::YES), loop ? 0 : 1);
#else
warning ("MAD library not included - unable to play MP2 audio");
#endif
} else {
error ("Unknown Mohawk WAVE encoding %d", data_chunk.encoding);
}
return NULL;
}
Audio::AudioStream *Sound::makeOldMohawkWaveStream(Common::SeekableReadStream *stream, bool loop) {
uint16 header = stream->readUint16BE();
uint16 rate = 0;
uint32 size = 0;
if (header == 'Wv') { // Big Endian
rate = stream->readUint16BE();
stream->skip(10); // Loop chunk, like the newer format?
size = stream->readUint32BE();
} else if (header == 'vW') { // Little Endian
rate = stream->readUint16LE();
stream->skip(10); // Loop chunk, like the newer format?
size = stream->readUint32LE();
} else
error("Could not find Old Mohawk Sound header");
assert(size);
byte *data = (byte *)malloc(size);
stream->read(data, size);
delete stream;
return Audio::makeLoopingAudioStream(
Audio::makeRawMemoryStream(data, size, DisposeAfterUse::YES, rate, Audio::FLAG_UNSIGNED),
loop ? 0 : 1);
}
SndHandle *Sound::getHandle() {
for (uint32 i = 0; i < _handles.size(); i++) {
if (_handles[i].type == kFreeHandle)
return &_handles[i];
if (!_vm->_mixer->isSoundHandleActive(_handles[i].handle)) {
_handles[i].type = kFreeHandle;
return &_handles[i];
}
}
// Let's add a new sound handle!
SndHandle handle;
handle.handle = Audio::SoundHandle();
handle.type = kFreeHandle;
_handles.push_back(handle);
return &_handles[_handles.size() - 1];
}
void Sound::stopSound() {
for (uint32 i = 0; i < _handles.size(); i++)
if (_handles[i].type == kUsedHandle) {
_vm->_mixer->stopHandle(_handles[i].handle);
_handles[i].type = kFreeHandle;
}
}
void Sound::pauseSound() {
for (uint32 i = 0; i < _handles.size(); i++)
if (_handles[i].type == kUsedHandle)
_vm->_mixer->pauseHandle(_handles[i].handle, true);
}
void Sound::resumeSound() {
for (uint32 i = 0; i < _handles.size(); i++)
if (_handles[i].type == kUsedHandle)
_vm->_mixer->pauseHandle(_handles[i].handle, false);
}
} // End of namespace Mohawk