Bochs/bochs/iodev/sb16.h
2004-09-05 10:30:19 +00:00

414 lines
17 KiB
C++

/////////////////////////////////////////////////////////////////////////
// $Id: sb16.h,v 1.19 2004-09-05 10:30:19 vruppert Exp $
/////////////////////////////////////////////////////////////////////////
//
// Copyright (C) 2001 MandrakeSoft S.A.
//
// MandrakeSoft S.A.
// 43, rue d'Aboukir
// 75002 Paris - France
// http://www.linux-mandrake.com/
// http://www.mandrakesoft.com/
//
// This library is free software; you can redistribute it and/or
// modify it under the terms of the GNU Lesser General Public
// License as published by the Free Software Foundation; either
// version 2 of the License, or (at your option) any later version.
//
// This library 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
// Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public
// License along with this library; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
// This file (SB16.H) written and donated by Josef Drexler
#if BX_USE_SB16_SMF
# define BX_SB16_SMF static
# define BX_SB16_THIS theSB16Device->
# define BX_SB16_THISP (theSB16Device)
#else
# define BX_SB16_SMF
# define BX_SB16_THIS this->
# define BX_SB16_THISP (this)
#endif
#if BX_USE_SOUND_VIRTUAL
# define BX_SOUND_VIRTUAL virtual
# define BX_SOUND_OUTPUT_C_DEF bx_sound_output_c
#else
# define BX_SOUND_VIRTUAL
# define BX_SOUND_OUTPUT_C_DEF BX_SOUND_OUTPUT_C
#endif
// If the buffer commands are to be inlined:
#define BX_SB16_BUFINL BX_CPP_INLINE
// BX_CPP_INLINE is defined to the inline keyword for the C++ compiler.
// maximum number of patch translations
#define BX_SB16_PATCHTABLESIZE 1024
// the resources. Of these, IRQ and DMA's can be changed via a DSP command
#define BX_SB16_IO 0x220 // IO base address of DSP, mixer & FM part
#define BX_SB16_IOLEN 16 // number of addresses covered
#define BX_SB16_IOMPU 0x330 // IO base address of MPU402 part
#define BX_SB16_IOMPULEN 4 // number of addresses covered
#define BX_SB16_IOADLIB 0x388 // equivalent to 0x220..0x223 and 0x228..0x229
#define BX_SB16_IOADLIBLEN 4 // number of addresses covered
#define BX_SB16_IRQ theSB16Device->currentirq
#define BX_SB16_IRQMPU BX_SB16_IRQ // IRQ for the MPU401 part - same value
#define BX_SB16_DMAL theSB16Device->currentdma8
#define BX_SB16_DMAH theSB16Device->currentdma16
/*
A few notes:
IRQ, DMA8bit and DMA16bit are for the DSP part. These
are changeable at runtime in mixer registers 0x80 and 0x81.
The defaults after a mixer initialization are IRQ 5, DMA8 1, no DMA16
Any of the address lengths can be zero to disable that particular
subdevice. Turning off the DSP still leaves FM music enabled on the
BX_SB16_IOADLIB ports, unless those are disabled as well.
BX_SB16_IOMPULEN should be 4 or 2. In the latter case, the emulator
is completely invisible, and runtime changes are not possible
BX_SB16_IOADLIBLEN should be 2 or 4. If 0, Ports 0x388.. don't
get used, but the OPL2 can still be accessed at 0x228..0x229.
If 2, the usual Adlib emulation is enabled. If 4, an OPL3 is
emulated at adresses 0x388..0x38b, or two separate OPL2's.
*/
/* Definitions for the output functions */
#define BX_SOUND_OUTPUT_OK 0
#define BX_SOUND_OUTPUT_ERR 1
#define BX_SOUND_OUTPUT_WAVEPACKETSIZE 4096
// the is the size of a DMA chunk sent to output
// it should not be too large to avoid lag, and not too
// small to avoid unnecessary overhead.
#define BX_SB16_MIX_REG 0x100 // total number of mixer registers
// The array containing an instrument/bank remapping
struct bx_sb16_ins_map {
Bit8u oldbankmsb, oldbanklsb, oldprogch;
Bit8u newbankmsb, newbanklsb, newprogch;
};
// One operator of the FM emulation
#define BX_SB16_FM_NOP 36 // OPL3 has 36 operators
#define BX_SB16_FM_OPB 6 // one operator has 6 bytes
typedef Bit8u bx_sb16_fm_operator[BX_SB16_FM_OPB];
/* Explanation of the values:
(note [xx] is one bit for xx; [5 xx] is five bits for xx,
all bits listed MSB to LSB)
[0] = [Tremolo][Vibrato][Sustain][KSR][4 Frequency Multiply]
[1] = [2 Key Scale Level][6 Output Level for modulators, reserved for others]
[2] = [4 Attack Rate][4 Decay Rate]
[3] = [4 Sustain Level][4 Release Rate]
[4] = [2 reserved][Right][Left][3 Feedback Factor][SynthType]
[5] = [5 reserved][3 Waveform Select]
Frequency and Output Level are really properties of the channel,
so they get stored there. However, Output Level of the modulator
in FM synthesis varies the instrument.
[4] is only set for the first operator, and zeroed for the others.
All reserved bits are zeroed.
*/
// One channel (1 to 4 operators)
#define BX_SB16_FM_NCH 18 // OPL3 has at most 18 channels
typedef struct {
int nop; // number of operators used: 0=disabled, 1=percussion, 2 or 4=melodic
int ncarr; // how many carriers this channel has (1..3)
int opnum[4]; // operator numbers
Bit16u freq; // frequency (in a special code)
Bit32u afreq; // actual frequency in milli-Hertz (10^-3 Hz)
bx_bool freqch; // byte of the frequency that has changed recently
Bit8u midichan; // assigned midi channel
bx_bool needprogch; // has the instrument changed
Bit8u midinote; // currently playing midi note
bx_bool midion; // is the note on
Bit16u midibend; // current value of the pitch bender
Bit8u outputlevel[4];// 6-bit output level attenuations
Bit8u midivol; // current midi volume (velocity)
} bx_sb16_fm_channel;
// This is the class for the input and
// output FIFO buffers of the SB16
class bx_sb16_buffer {
public:
BX_SB16_BUFINL bx_sb16_buffer(void);
BX_SB16_BUFINL ~bx_sb16_buffer(void);
BX_SB16_BUFINL void init(int bufferlen);
BX_SB16_BUFINL void reset();
/* These functions return 1 on success and 0 on error */
BX_SB16_BUFINL bx_bool put(Bit8u data); // write one byte in the buffer
BX_SB16_BUFINL bx_bool puts(char *data, ...); // write a formatted string to the buffer
BX_SB16_BUFINL bx_bool get(Bit8u *data); // read the next available byte
BX_SB16_BUFINL bx_bool getw(Bit16u *data); // get word, in order lo/hi
BX_SB16_BUFINL bx_bool getw1(Bit16u *data);// get word, in order hi/lo
BX_SB16_BUFINL bx_bool full(void); // is the buffer full?
BX_SB16_BUFINL bx_bool empty(void); // is it empty?
BX_SB16_BUFINL void flush(void); // empty the buffer
BX_SB16_BUFINL int bytes(void); // return number of bytes in the buffer
BX_SB16_BUFINL Bit8u peek(int ahead); // peek ahead number of bytes
/* These are for caching the command number */
BX_SB16_BUFINL void newcommand(Bit8u newcmd, int bytes); // start a new command with length bytes
BX_SB16_BUFINL Bit8u currentcommand(void); // return the current command
BX_SB16_BUFINL void clearcommand(void); // clear the command
BX_SB16_BUFINL bx_bool commanddone(void); // return if all bytes have arrived
BX_SB16_BUFINL bx_bool hascommand(void); // return if there is a pending command
BX_SB16_BUFINL int commandbytes(void); // return the length of the command
private:
Bit8u *buffer;
int head,tail,length;
Bit8u command;
bx_bool havecommand;
int bytesneeded;
};
// forward definition
class BX_SOUND_OUTPUT_C_DEF;
// The actual emulator class, emulating the sound blaster ports
class bx_sb16_c : public bx_devmodel_c {
public:
bx_sb16_c(void);
~bx_sb16_c(void);
virtual void init(void);
virtual void reset(unsigned type);
/* Make writelog available to output functions */
BX_SB16_SMF void writelog(int loglevel, const char *str, ...);
private:
FILE *logfile;
FILE *midifile,*wavefile; // the output files or devices
BX_SOUND_OUTPUT_C_DEF *output;// the output class
int currentirq;
int currentdma8;
int currentdma16;
// the MPU 401 relevant variables
struct bx_sb16_mpu_struct {
bx_sb16_buffer datain, dataout, cmd, midicmd;
bx_bool uartmode, irqpending, forceuartmode, singlecommand;
int banklsb[BX_SB16_PATCHTABLESIZE];
int bankmsb[BX_SB16_PATCHTABLESIZE]; // current patch lists
int program[BX_SB16_PATCHTABLESIZE];
int outputinit, timer_handle;
int current_timer; // no. of delta times passed
Bit32u last_delta_time; // timer value at last command
} mpu401;
// the DSP variables
struct bx_sb16_dsp_struct {
bx_sb16_buffer datain, dataout;
Bit8u resetport; // last value written to the reset port
Bit8u speaker,prostereo; // properties of the sound input/output
bx_bool irqpending; // Is an IRQ pending (not ack'd)
bx_bool midiuartmode; // Is the DSP in MIDI UART mode
Bit8u testreg;
struct bx_sb16_dsp_dma_struct {
// Properties of the current DMA transfer:
// mode= 0: no transfer, 1: single-cycle transfer, 2: auto-init DMA
// bits= 8 or 16
// fifo= ?? Bit used in DMA command, no idea what it means...
// output= 0: input, 1: output
// bps= bytes per sample; =(dmabits/8)*(dmastereo+1)
// stereo= 0: mono, 1: stereo
// issigned= 0: unsigned data, 1: signed data
// highspeed= 0: normal mode, 1: highspeed mode (only SBPro)
// timer= so many us between data bytes
int mode, bits, fifo, output, bps;
int stereo, issigned, highspeed, format, timer;
Bit16u count; // bytes remaining in this transfer
Bit8u *chunk; // buffers up to BX_SB16_WAVEPACKETSIZE bytes
int chunkindex; // index into the buffer
int chunkcount; // for input: size of the recorded input
Bit16u timeconstant;
Bit16u blocklength, samplerate;
} dma;
int timer_handle; // handle for the DMA timer
int outputinit; // have the output functions been initialized
} dsp;
enum bx_sb16_fm_mode {single, adlib, dual, opl3, fminit};
// the variables common to all FM emulations
struct bx_sb16_opl_struct;
friend struct bx_sb16_opl_struct;
struct bx_sb16_opl_struct {
bx_sb16_fm_mode mode;
// modes: single: one OPL2 (OPL3 disabled),
// adlib: one OPL2 (no OPL3),
// dual: two seperate OPL2
// opl3: one OPL3 (enabled)
int timer_handle;
int timer_running;
Bit16u midichannels; // bitmask: unused midichannels
int drumchannel; // midi channel for percussion (10)
int index[2]; // index register for the two chips
int wsenable[2]; // wave form select enable
int timer[4]; // two timers on each chip
int timerinit[4]; // initial timer counts
int tmask[2]; // the timer masking byte for both chips
int tflag[2]; // shows if the timer overflow has occured
int percmode[2]; // percussion mode enabled
int cyhhnote[2]; // cymbal and high hat midi notes
int cyhhon[2]; // cymbal and high hat notes on
bx_sb16_fm_operator oper[BX_SB16_FM_NOP];
bx_sb16_fm_channel chan[BX_SB16_FM_NCH];
} opl;
struct bx_sb16_mixer_struct {
Bit8u regindex;
Bit8u reg[BX_SB16_MIX_REG];
} mixer;
struct bx_sb16_emul_struct {
bx_sb16_buffer datain, dataout;
bx_sb16_ins_map remaplist[256];
int remaps;
} emuldata;
/* DMA input and output, 8 and 16 bit */
BX_SB16_SMF void dma_write8(Bit8u *data_byte);
BX_SB16_SMF void dma_read8(Bit8u *data_byte);
BX_SB16_SMF void dma_write16(Bit16u *data_word);
BX_SB16_SMF void dma_read16(Bit16u *data_word);
/* the MPU 401 part of the emulator */
BX_SB16_SMF Bit32u mpu_status(); // read status port 3x1
BX_SB16_SMF void mpu_command(Bit32u value); // write command port 3x1
BX_SB16_SMF Bit32u mpu_dataread(); // read data port 3x0
BX_SB16_SMF void mpu_datawrite(Bit32u value); // write data port 3x0
BX_SB16_SMF void mpu_mididata(Bit32u value); // get a midi byte
static void mpu_timer (void *);
/* The DSP part */
BX_SB16_SMF void dsp_reset(Bit32u value); // write to reset port 2x6
BX_SB16_SMF Bit32u dsp_dataread(); // read from data port 2xa
BX_SB16_SMF void dsp_datawrite(Bit32u value); // write to data port 2xa
BX_SB16_SMF Bit32u dsp_bufferstatus(); // read buffer status 2xc
BX_SB16_SMF Bit32u dsp_status(); // read dsp status 2xe
BX_SB16_SMF void dsp_getsamplebyte(Bit8u value);
BX_SB16_SMF Bit8u dsp_putsamplebyte();
BX_SB16_SMF void dsp_sendwavepacket();
BX_SB16_SMF void dsp_getwavepacket();
BX_SB16_SMF Bit32u dsp_irq16ack(); // ack 16 bit IRQ 2xf
BX_SB16_SMF void dsp_dma(Bit8u command, Bit8u mode, Bit16u length, Bit8u comp);
// initiate a DMA transfer
BX_SB16_SMF void dsp_dmadone(); // stop a DMA transfer
BX_SB16_SMF void dsp_enabledma(); // enable the transfer
BX_SB16_SMF void dsp_disabledma(); // temporarily disable DMA
static void dsp_dmatimer (void *);
/* The mixer part */
BX_SB16_SMF Bit32u mixer_readdata(void);
BX_SB16_SMF void mixer_writedata(Bit32u value);
BX_SB16_SMF void mixer_writeregister(Bit32u value);
BX_SB16_SMF void set_irq_dma();
/* The emulator ports to change emulator properties */
BX_SB16_SMF Bit32u emul_read (void); // read emulator port
BX_SB16_SMF void emul_write(Bit32u value); // write emulator port
/* The FM emulation part */
BX_SB16_SMF void opl_entermode(bx_sb16_fm_mode newmode);
BX_SB16_SMF Bit32u opl_status(int chipid);
BX_SB16_SMF void opl_index(Bit32u value, int chipid);
BX_SB16_SMF void opl_data(Bit32u value, int chipid);
static void opl_timer(void *);
BX_SB16_SMF void opl_timerevent(void);
BX_SB16_SMF void opl_changeop(int channum, int opernum, int byte, int value);
BX_SB16_SMF void opl_settimermask(int value, int chipid);
BX_SB16_SMF void opl_set4opmode(int new4opmode);
BX_SB16_SMF void opl_setmodulation(int channel);
BX_SB16_SMF void opl_setpercussion(Bit8u value, int chipid);
BX_SB16_SMF void opl_setvolume(int channel, int opnum, int outlevel);
BX_SB16_SMF void opl_setfreq(int channel);
BX_SB16_SMF void opl_keyonoff(int channel, bx_bool onoff);
BX_SB16_SMF void opl_midichannelinit(int channel);
/* several high level sound handlers */
BX_SB16_SMF int currentdeltatime();
BX_SB16_SMF void processmidicommand(bx_bool force);
BX_SB16_SMF void midiremapprogram(int channel); // remap program change
BX_SB16_SMF int converttodeltatime(Bit32u deltatime, Bit8u value[4]);
BX_SB16_SMF void writemidicommand(int command, int length, Bit8u data[]);
BX_SB16_SMF void writedeltatime(Bit32u deltatime);
// write in delta time coding
BX_SB16_SMF void initmidifile(); // Write midi file header
BX_SB16_SMF void finishmidifile(); // write track length etc.
BX_SB16_SMF void initvocfile(); // Write voc file header
BX_SB16_SMF void writevocblock(int block, Bit32u headerlen, Bit8u header[],
Bit32u datalen, Bit8u data[]);
BX_SB16_SMF void finishvocfile(); // close voc file
/* The port IO multiplexer functions */
static Bit32u read_handler(void *this_ptr, Bit32u address, unsigned io_len);
static void write_handler(void *this_ptr, Bit32u address, Bit32u value, unsigned io_len);
#if !BX_USE_SB16_SMF
Bit32u read(Bit32u address, unsigned io_len);
void write(Bit32u address, Bit32u value, unsigned io_len);
#endif
};
// The class with the output functions
class bx_sound_output_c : public logfunctions {
public:
/* These functions are the sound output functions, sending
the music/sound to the OS specific driver.
They are in a different file (sound.cc) because they are
non-portable, while everything in sb16.cc is portable */
bx_sound_output_c(bx_sb16_c *sb16);
BX_SOUND_VIRTUAL ~bx_sound_output_c();
BX_SOUND_VIRTUAL int waveready();
BX_SOUND_VIRTUAL int midiready();
BX_SOUND_VIRTUAL int openmidioutput(char *device);
BX_SOUND_VIRTUAL int sendmidicommand(int delta, int command, int length, Bit8u data[]);
BX_SOUND_VIRTUAL int closemidioutput();
BX_SOUND_VIRTUAL int openwaveoutput(char *device);
BX_SOUND_VIRTUAL int startwaveplayback(int frequency, int bits, int stereo, int format);
BX_SOUND_VIRTUAL int sendwavepacket(int length, Bit8u data[]);
BX_SOUND_VIRTUAL int stopwaveplayback();
BX_SOUND_VIRTUAL int closewaveoutput();
};
#define WRITELOG sb16->writelog
#define BOTHLOG(x) (x)
#define MIDILOG(x) ((bx_options.sb16.Omidimode->get ()>0?x:0x7f))
#define WAVELOG(x) ((bx_options.sb16.Owavemode->get ()>0?x:0x7f))