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/* 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.
*
*/
#ifndef AGI_SOUND_2GS_H
#define AGI_SOUND_2GS_H
#include "common/frac.h"
#include "audio/audiostream.h"
namespace Agi {
// Sample data in SIERRASTANDARD files is in unsigned 8-bit format. A zero
// occurring in the sample data causes the ES5503 wavetable sound chip in
// Apple IIGS to halt the corresponding oscillator immediately. We preprocess
// the sample data by converting it to signed values and the instruments by
// detecting prematurely stopping samples beforehand.
//
// Note: None of the tested SIERRASTANDARD files have zeroes in them. So in
// practice there is no need to check for them. However, they still do exist
// in the sample resources.
#define ZERO_OFFSET 0x80
// Apple IIGS envelope update frequency defaults to 100Hz. It can be changed,
// so there might be differences per game, for example.
#define ENVELOPE_COEF 100 / _sampleRate
// MIDI player commands
#define MIDI_NOTE_OFF 0x8
#define MIDI_NOTE_ON 0x9
#define MIDI_CONTROLLER 0xB
#define MIDI_PROGRAM_CHANGE 0xC
#define MIDI_PITCH_WHEEL 0xE
#define MIDI_STOP_SEQUENCE 0xFC
#define MIDI_TIMER_SYNC 0xF8
// Size of the SIERRASTANDARD file (i.e. the wave file i.e. the sample data used by the instruments).
#define SIERRASTANDARD_SIZE 65536
// Maximum number of instruments in an Apple IIGS instrument set.
// Chosen empirically based on Apple IIGS AGI game data, increase if needed.
#define MAX_INSTRUMENTS 28
// The MIDI player allocates one generator for each note it starts to play.
// Here the maximum number of generators is defined. Feel free to increase
// this if it does not seem to be enough.
#define MAX_GENERATORS 16
#define ENVELOPE_SEGMENT_COUNT 8
#define MAX_OSCILLATOR_WAVES 127 // Maximum is one for every MIDI key
struct IIgsInstrumentHeader {
struct {
frac_t bp; ///< Envelope segment breakpoint
frac_t inc; ///< Envelope segment velocity
} env[ENVELOPE_SEGMENT_COUNT];
uint8 seg; ///< Envelope release segment
uint8 bend; ///< Maximum range for pitch bend
uint8 vibDepth; ///< Vibrato depth
uint8 vibSpeed; ///< Vibrato speed
uint8 waveCount[2]; ///< Wave count for both generators
struct {
uint8 key; ///< Highest MIDI key to use this wave
int offset; ///< Offset of wave data, relative to base
uint size; ///< Wave size
bool halt; ///< Oscillator halted?
bool loop; ///< Loop mode?
bool swap; ///< Swap mode?
bool chn; ///< Output channel (left / right)
int16 tune; ///< Fine tune in semitones (8.8 fixed point)
} wave[2][MAX_OSCILLATOR_WAVES];
int8* base; ///< Base of wave data
/**
* Read an Apple IIGS instrument header from the given stream.
* @param stream The source stream from which to read the data.
* @param ignoreAddr Should we ignore wave infos' wave address variable's value?
* @return True if successful, false otherwise.
*/
bool read(Common::SeekableReadStream &stream, bool ignoreAddr = false);
bool finalize(int8 *);
};
struct IIgsSampleHeader {
uint16 type;
uint8 pitch; ///< Logarithmic, base is 2**(1/12), unknown multiplier (Possibly in range 1040-1080)
uint8 unknownByte_Ofs3; // 0x7F in Gold Rush's sound resource 60, 0 in all others.
uint8 volume; ///< Current guess: Logarithmic in 6 dB steps
uint8 unknownByte_Ofs5; ///< 0 in all tested samples.
uint16 instrumentSize; ///< Little endian. 44 in all tested samples. A guess.
uint16 sampleSize; ///< Little endian. Accurate in all tested samples excluding Manhunter I's sound resource 16.
IIgsInstrumentHeader instrument;
/**
* Read an Apple IIGS AGI sample header from the given stream.
* @param stream The source stream from which to read the data.
* @return True if successful, false otherwise.
*/
bool read(Common::SeekableReadStream &stream);
bool finalize(int8 *sample);
};
class IIgsGenerator {
public:
IIgsGenerator() : ins(NULL), key(-1), chn(-1) {}
const IIgsInstrumentHeader *ins; ///< Currently used instrument
int key; ///< MIDI key
int vel; ///< MIDI velocity (& channel volume)
int chn; ///< MIDI channel
struct {
int8 *base; ///< Sample base pointer
uint size; ///< Sample size
frac_t p; ///< Sample pointer
frac_t pd; ///< Sample pointer delta
bool halt; ///< Is oscillator halted?
bool loop; ///< Is looping enabled?
bool swap; ///< Is swapping enabled?
bool chn; ///< Output channel (left / right)
} osc[2];
int seg; ///< Current envelope segment
frac_t a; ///< Current envelope amplitude
};
class IIgsMidi : public AgiSound {
public:
IIgsMidi(uint8 *data, uint32 len, int resnum, SoundMgr &manager);
~IIgsMidi() { if (_data != NULL) free(_data); }
virtual uint16 type() { return _type; }
virtual const uint8 *getPtr() { return _ptr; }
virtual void setPtr(const uint8 *ptr) { _ptr = ptr; }
virtual void rewind() { _ptr = _data + 2; _ticks = 0; }
protected:
uint8 *_data; ///< Raw sound resource data
const uint8 *_ptr; ///< Pointer to the current position in the MIDI data
uint32 _len; ///< Length of the raw sound resource
uint16 _type; ///< Sound resource type
public:
uint _ticks; ///< MIDI song position in ticks (1/60ths of a second)
};
class IIgsSample : public AgiSound {
public:
IIgsSample(uint8 *data, uint32 len, int resnum, SoundMgr &manager);
~IIgsSample() { delete[] _sample; }
virtual uint16 type() { return _header.type; }
const IIgsSampleHeader &getHeader() const { return _header; }
const int8 *getSample() const { return _sample; }
protected:
IIgsSampleHeader _header; ///< Apple IIGS AGI sample header
int8 *_sample; ///< Sample data (8-bit signed format)
};
/** Apple IIGS MIDI program change to instrument number mapping. */
struct IIgsMidiProgramMapping {
byte midiProgToInst[44]; ///< Lookup table for the MIDI program number to instrument number mapping
byte undefinedInst; ///< The undefined instrument number
// Maps the MIDI program number to an instrument number
byte map(uint midiProg) const {
return midiProg < ARRAYSIZE(midiProgToInst) ? midiProgToInst[midiProg] : undefinedInst;
}
};
/** Apple IIGS AGI instrument set information. */
struct IIgsInstrumentSetInfo {
uint byteCount; ///< Length of the whole instrument set in bytes
uint instCount; ///< Amount of instrument in the set
const char *md5; ///< MD5 hex digest of the whole instrument set
const char *waveFileMd5; ///< MD5 hex digest of the wave file (i.e. the sample data used by the instruments)
const IIgsMidiProgramMapping *progToInst; ///< Program change to instrument number mapping
};
/** Apple IIGS AGI executable file information. */
struct IIgsExeInfo {
enum AgiGameID gameid; ///< Game ID
const char *exePrefix; ///< Prefix of the Apple IIGS AGI executable (e.g. "SQ", "PQ", "KQ4" etc)
uint agiVer; ///< Apple IIGS AGI version number, not strictly needed
uint exeSize; ///< Size of the Apple IIGS AGI executable file in bytes
uint instSetStart; ///< Starting offset of the instrument set inside the executable file
const IIgsInstrumentSetInfo *instSet; ///< Information about the used instrument set
};
class IIgsMidiChannel {
public:
IIgsMidiChannel() : _instrument(NULL), _volume(127) {}
void setInstrument(const IIgsInstrumentHeader *instrument) { _instrument = instrument; }
const IIgsInstrumentHeader* getInstrument() { return _instrument; }
void setVolume(int volume) { _volume = volume; }
int getVolume() { return _volume; }
private:
const IIgsInstrumentHeader *_instrument; ///< Instrument used on this MIDI channel
int _volume; ///< MIDI controller number 7 (Volume)
};
class SoundGen2GS : public SoundGen, public Audio::AudioStream {
public:
SoundGen2GS(AgiEngine *vm, Audio::Mixer *pMixer);
~SoundGen2GS();
void play(int resnum);
void stop(void);
int readBuffer(int16 *buffer, const int numSamples);
bool isStereo() const { return true; }
bool endOfData() const { return false; }
int getRate() const { return _sampleRate; }
private:
// Loader methods
bool loadInstruments();
bool loadInstrumentHeaders(Common::String &exePath, const IIgsExeInfo &exeInfo);
bool loadWaveFile(Common::String &wavePath, const IIgsExeInfo &exeInfo);
const IIgsExeInfo *getIIgsExeInfo(enum AgiGameID gameid) const;
void setProgramChangeMapping(const IIgsMidiProgramMapping *mapping);
// Player methods
void advancePlayer(); ///< Advance the player
void advanceMidiPlayer(); ///< Advance MIDI player
uint generateOutput(); ///< Fill the output buffer
void haltGenerators(); ///< Halt all generators
uint activeGenerators(); ///< How many generators are active?
void midiNoteOff(int channel, int note, int velocity);
void midiNoteOn(int channel, int note, int velocity);
double midiKeyToFreq(int key, double finetune);
IIgsInstrumentHeader* getInstrument(uint8 program) { return &_instruments[_progToInst->map(program)]; };
IIgsGenerator* allocateGenerator() { IIgsGenerator* g = &_generators[_nextGen++]; _nextGen %= 16; return g; }
bool _disableMidi; ///< Disable MIDI if loading instruments fail
int _playingSound; ///< Resource number for the currently playing sound
bool _playing; ///< True when the resource is still playing
IIgsGenerator _generators[MAX_GENERATORS]; ///< IIGS sound generators that are used to play single notes
uint _nextGen; ///< Next generator available for allocation
IIgsMidiChannel _channels[16]; ///< MIDI channels
Common::Array<IIgsInstrumentHeader> _instruments; ///< Instrument data
const IIgsMidiProgramMapping *_progToInst; ///< MIDI program number to instrument mapping
int8 *_wavetable; ///< Sample data used by the instruments
uint _ticks; ///< MIDI ticks (60Hz)
int16 *_out; ///< Output buffer
uint _outSize; ///< Output buffer size
static const int kSfxMidiChannel = 15; ///< MIDI channel used for playing sample resources
};
} // End of namespace Agi
#endif /* AGI_SOUND_2GS_H */
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