/* 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. * * $URL$ * $Id$ * */ // FIXME: This is cribbed together from the SAGA music player. It needs cleanup // and testing. #include "m4/m4.h" #include "m4/midi.h" #include "common/stream.h" namespace M4 { MidiPlayer::MidiPlayer(M4Engine *vm, MidiDriver *driver) : _vm(vm), _midiData(NULL), _driver(driver), _isPlaying(false), _passThrough(false), _isGM(false) { memset(_channel, 0, sizeof(_channel)); _masterVolume = 0; _parser = MidiParser::createParser_SMF(); _parser->setMidiDriver(this); _parser->setTimerRate(getBaseTempo()); open(); } MidiPlayer::~MidiPlayer() { _driver->setTimerCallback(NULL, NULL); _parser->setMidiDriver(NULL); stopMusic(); close(); delete _parser; delete _midiData; } void MidiPlayer::setVolume(int volume) { Common::StackLock lock(_mutex); if (volume < 0) volume = 0; else if (volume > 255) volume = 255; if (_masterVolume == volume) return; _masterVolume = volume; for (int i = 0; i < 16; ++i) { if (_channel[i]) { _channel[i]->volume(_channelVolume[i] * _masterVolume / 255); } } } int MidiPlayer::open() { // Don't ever call open without first setting the output driver! if (!_driver) return 255; int ret = _driver->open(); if (ret) return ret; _driver->setTimerCallback(this, &onTimer); return 0; } void MidiPlayer::close() { stopMusic(); if (_driver) _driver->close(); _driver = 0; } void MidiPlayer::send(uint32 b) { if (_passThrough) { _driver->send(b); return; } byte channel = (byte)(b & 0x0F); if ((b & 0xFFF0) == 0x07B0) { // Adjust volume changes by master volume byte volume = (byte)((b >> 16) & 0x7F); _channelVolume[channel] = volume; volume = volume * _masterVolume / 255; b = (b & 0xFF00FFFF) | (volume << 16); } else if ((b & 0xF0) == 0xC0 && !_isGM && !_nativeMT32) { b = (b & 0xFFFF00FF) | MidiDriver::_mt32ToGm[(b >> 8) & 0xFF] << 8; } else if ((b & 0xFFF0) == 0x007BB0) { //Only respond to All Notes Off if this channel //has currently been allocated if (_channel[b & 0x0F]) return; } if (!_channel[channel]) _channel[channel] = (channel == 9) ? _driver->getPercussionChannel() : _driver->allocateChannel(); if (_channel[channel]) _channel[channel]->send(b); } void MidiPlayer::metaEvent(byte type, byte *data, uint16 length) { switch (type) { case 0x2F: // End of track. (Not called when auto-looping.) stopMusic(); break; case 0x51: // Set tempo. Handled by the standard MIDI parser already. break; default: warning("Unhandled meta event: %02x", type); break; } } void MidiPlayer::onTimer(void *refCon) { MidiPlayer *midi = (MidiPlayer *)refCon; Common::StackLock lock(midi->_mutex); if (midi->_isPlaying) midi->_parser->onTimer(); } void MidiPlayer::playMusic(const char *name, int32 vol, bool loop, int32 trigger, int32 scene) { stopMusic(); char fullname[144]; _vm->res()->changeExtension(fullname, name, "HMP"); Common::SeekableReadStream *midiFile = _vm->res()->get(fullname); byte *hmpData = new byte[midiFile->size()]; uint32 smfSize; midiFile->read(hmpData, midiFile->size()); _midiData = convertHMPtoSMF(hmpData, midiFile->size(), smfSize); delete[] hmpData; _vm->res()->toss(fullname); _vm->res()->purge(); if (_midiData) { /* FILE *out = fopen("music.mid", "wb"); fwrite(_midiData, smfSize, 1, out); fclose(out); */ _parser->loadMusic(_midiData, smfSize); _parser->property(MidiParser::mpAutoLoop, loop); } setVolume(255); _isPlaying = true; } void MidiPlayer::stopMusic() { Common::StackLock lock(_mutex); _isPlaying = false; if (_parser) { _parser->unloadMusic(); } delete[] _midiData; _midiData = NULL; } // This function will convert HMP music into type 1 SMF, which our SMF parser // will be able to handle. It is based on Hans de Goede's HMP 2 MIDI file // converter, which in turn is "based on the conversion algorithms found in // d1x, d2x-xl and jjffe". Hans's original code is licensed under the LGPL. // // TODO: It would probably be nicer to write a MIDI parser class to deal with // HMP data directly. Though the multi-track nature of HMP makes that tricky. byte *MidiPlayer::convertHMPtoSMF(byte *data, uint32 inSize, uint32 &outSize) { Common::MemoryReadStream readS(data, inSize); Common::MemoryWriteStreamDynamic writeS; byte buf[8]; readS.read(buf, sizeof(buf)); if (memcmp(buf, "HMIMIDIP", 8) != 0) { warning("convertHMPtoSMF: Invalid HMP header"); return NULL; } // Read the number of tracks. Note that all the tracks are still part // of the same song, just like in type 1 SMF files. readS.seek(0x30); uint32 numTracks = readS.readUint32LE(); // The first track starts on offset 0x300. It's currently unknown what // the skipped data is for. readS.seek(0x300); // For some reason, we skip the first track entirely. byte a = readS.readByte(); byte b = readS.readByte(); byte c = readS.readByte(); while (a != 0xFF || b != 0x2F || c != 0x00) { a = b; b = c; c = readS.readByte(); } // The beginning of the MIDI header static const byte midiHeader1[] = { 'M', 'T', 'h', 'd', 0, 0, 0, 6, 0, 1 }; // The last 2 bytes of the midi header and track 0 static const byte midiHeader2[] = { 0, 0xC0, 'M', 'T', 'r', 'k', 0, 0, 0, 0x0B, 0, 0xFF, 0x51, 0x03, 0x18, 0x80, 0, 0, 0xFF, 0x2F, 0 }; // Write the MIDI header writeS.write(midiHeader1, sizeof(midiHeader1)); // Write the number of tracks writeS.writeUint16BE(numTracks); // Write the rest of the MIDI header and track 0. writeS.write(midiHeader2, sizeof(midiHeader2)); // Read and convert all the tracks for (uint i = 1; i < numTracks; i++) { if (readS.readUint32LE() != i) { warning("convertHMPtoSMF: Invalid HMP track number"); delete[] writeS.getData(); return NULL; } uint32 trackLength = readS.readUint32LE() - 12; readS.readUint32LE(); // Unused? // Write the track header writeS.write("MTrk", 4); // This is where we will write the length of the track. uint32 trackLengthPos = writeS.pos(); writeS.writeUint32LE(0); // In the original, this is cleared once at the beginning of // the function, but surely the last command does not carry // over to the next track? byte lastCmd = 0; // Now we can finally convert the track int32 endPos = readS.pos() + trackLength; while (readS.pos() < endPos) { // Convert the VLQ byte vlq[4]; int j = -1; do { j++; vlq[j] = readS.readByte(); } while (!(vlq[j] & 0x80)); for (int k = 0; k <= j; k++) { a = vlq[j - k] & 0x7F; if (k != j) a |= 0x80; writeS.writeByte(a); } a = readS.readByte(); if (a == 0xFF) { // META event b = readS.readByte(); c = readS.readByte(); writeS.writeByte(a); writeS.writeByte(b); writeS.writeByte(c); if (c > 0) { byte *metaBuf = new byte[c]; readS.read(metaBuf, c); writeS.write(metaBuf, c); delete[] metaBuf; } if (b == 0x2F) { if (c != 0x00) { warning("convertHMPtoSMF: End of track with non-zero size"); delete[] writeS.getData(); return NULL; } break; } } else { if (a != lastCmd) writeS.writeByte(a); switch (a & 0xF0) { case 0x80: case 0x90: case 0xA0: case 0xB0: case 0xE0: b = readS.readByte(); c = readS.readByte(); writeS.writeByte(b); writeS.writeByte(c); break; case 0xC0: case 0xD0: b = readS.readByte(); writeS.writeByte(b); break; default: warning("convertHMPtoSMF: Invalid HMP command %02X", a); delete[] writeS.getData(); return NULL; } lastCmd = a; } } if (readS.pos() != endPos) { warning("convertHMPtoSMF: Invalid track length"); delete[] writeS.getData(); return NULL; } WRITE_BE_UINT32(writeS.getData() + trackLengthPos, writeS.pos() - trackLengthPos - 4); } outSize = writeS.size(); return writeS.getData(); } } // End of namespace M4