/* * Copyright (C) 2002-2010 The DOSBox Team * * 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. */ /* $Id: adlib.cpp,v 1.42 2009-11-03 20:17:42 qbix79 Exp $ */ #include #include #include #include #include "adlib.h" #include "setup.h" #include "mapper.h" #include "mem.h" #include "dbopl.h" namespace OPL2 { #include "opl.cpp" struct Handler : public Adlib::Handler { virtual void WriteReg( Bit32u reg, Bit8u val ) { adlib_write(reg,val); } virtual Bit32u WriteAddr( Bit32u port, Bit8u val ) { return val; } virtual void Generate( MixerChannel* chan, Bitu samples ) { Bit16s buf[1024]; while( samples > 0 ) { Bitu todo = samples > 1024 ? 1024 : samples; samples -= todo; adlib_getsample(buf, todo); chan->AddSamples_m16( todo, buf ); } } virtual void Init( Bitu rate ) { adlib_init(rate); } ~Handler() { } }; } namespace OPL3 { #define OPLTYPE_IS_OPL3 #include "opl.cpp" struct Handler : public Adlib::Handler { virtual void WriteReg( Bit32u reg, Bit8u val ) { adlib_write(reg,val); } virtual Bit32u WriteAddr( Bit32u port, Bit8u val ) { adlib_write_index(port, val); return opl_index; } virtual void Generate( MixerChannel* chan, Bitu samples ) { Bit16s buf[1024*2]; while( samples > 0 ) { Bitu todo = samples > 1024 ? 1024 : samples; samples -= todo; adlib_getsample(buf, todo); chan->AddSamples_s16( todo, buf ); } } virtual void Init( Bitu rate ) { adlib_init(rate); } ~Handler() { } }; } #define RAW_SIZE 1024 /* Main Adlib implementation */ namespace Adlib { /* Raw DRO capture stuff */ #ifdef _MSC_VER #pragma pack (1) #endif #define HW_OPL2 0 #define HW_DUALOPL2 1 #define HW_OPL3 2 struct RawHeader { Bit8u id[8]; /* 0x00, "DBRAWOPL" */ Bit16u versionHigh; /* 0x08, size of the data following the m */ Bit16u versionLow; /* 0x0a, size of the data following the m */ Bit32u commands; /* 0x0c, Bit32u amount of command/data pairs */ Bit32u milliseconds; /* 0x10, Bit32u Total milliseconds of data in this chunk */ Bit8u hardware; /* 0x14, Bit8u Hardware Type 0=opl2,1=dual-opl2,2=opl3 */ Bit8u format; /* 0x15, Bit8u Format 0=cmd/data interleaved, 1 maybe all cdms, followed by all data */ Bit8u compression; /* 0x16, Bit8u Compression Type, 0 = No Compression */ Bit8u delay256; /* 0x17, Bit8u Delay 1-256 msec command */ Bit8u delayShift8; /* 0x18, Bit8u (delay + 1)*256 */ Bit8u conversionTableSize; /* 0x191, Bit8u Raw Conversion Table size */ } GCC_ATTRIBUTE(packed); #ifdef _MSC_VER #pragma pack() #endif /* The Raw Tables is < 128 and is used to convert raw commands into a full register index When the high bit of a raw command is set it indicates the cmd/data pair is to be sent to the 2nd port After the conversion table the raw data follows immediatly till the end of the chunk */ //Table to map the opl register to one <127 for dro saving class Capture { //127 entries to go from raw data to registers Bit8u ToReg[127]; //How many entries in the ToPort are used Bit8u RawUsed; //256 entries to go from port index to raw data Bit8u ToRaw[256]; Bit8u delay256; Bit8u delayShift8; RawHeader header; FILE* handle; //File used for writing Bit32u startTicks; //Start used to check total raw length on end Bit32u lastTicks; //Last ticks when last last cmd was added Bit8u buf[1024]; //16 added for delay commands and what not Bit32u bufUsed; Bit8u cmd[2]; //Last cmd's sent to either ports bool doneOpl3; bool doneDualOpl2; RegisterCache* cache; void MakeEntry( Bit8u reg, Bit8u& raw ) { ToReg[ raw ] = reg; ToRaw[ reg ] = raw; raw++; } void MakeTables( void ) { Bit8u index = 0; memset( ToReg, 0xff, sizeof ( ToReg ) ); memset( ToRaw, 0xff, sizeof ( ToRaw ) ); //Select the entries that are valid and the index is the mapping to the index entry MakeEntry( 0x01, index ); //0x01: Waveform select MakeEntry( 0x04, index ); //104: Four-Operator Enable MakeEntry( 0x05, index ); //105: OPL3 Mode Enable MakeEntry( 0x08, index ); //08: CSW / NOTE-SEL MakeEntry( 0xbd, index ); //BD: Tremolo Depth / Vibrato Depth / Percussion Mode / BD/SD/TT/CY/HH On //Add the 32 byte range that hold the 18 operators for ( int i = 0 ; i < 24; i++ ) { if ( (i & 7) < 6 ) { MakeEntry(0x20 + i, index ); //20-35: Tremolo / Vibrato / Sustain / KSR / Frequency Multiplication Facto MakeEntry(0x40 + i, index ); //40-55: Key Scale Level / Output Level MakeEntry(0x60 + i, index ); //60-75: Attack Rate / Decay Rate MakeEntry(0x80 + i, index ); //80-95: Sustain Level / Release Rate MakeEntry(0xe0 + i, index ); //E0-F5: Waveform Select } } //Add the 9 byte range that hold the 9 channels for ( int i = 0 ; i < 9; i++ ) { MakeEntry(0xa0 + i, index ); //A0-A8: Frequency Number MakeEntry(0xb0 + i, index ); //B0-B8: Key On / Block Number / F-Number(hi bits) MakeEntry(0xc0 + i, index ); //C0-C8: FeedBack Modulation Factor / Synthesis Type } //Store the amount of bytes the table contains RawUsed = index; // assert( RawUsed <= 127 ); delay256 = RawUsed; delayShift8 = RawUsed+1; } void ClearBuf( void ) { fwrite( buf, 1, bufUsed, handle ); header.commands += bufUsed / 2; bufUsed = 0; } void AddBuf( Bit8u raw, Bit8u val ) { buf[bufUsed++] = raw; buf[bufUsed++] = val; if ( bufUsed >= sizeof( buf ) ) { ClearBuf(); } } void AddWrite( Bit32u regFull, Bit8u val ) { Bit8u regMask = regFull & 0xff; /* Do some special checks if we're doing opl3 or dualopl2 commands Although you could pretty much just stick to always doing opl3 on the player side */ //Enabling opl3 4op modes will make us go into opl3 mode if ( header.hardware != HW_OPL3 && regFull == 0x104 && val && (*cache)[0x105] ) { header.hardware = HW_OPL3; } //Writing a keyon to a 2nd address enables dual opl2 otherwise //Maybe also check for rhythm if ( header.hardware == HW_OPL2 && regFull >= 0x1b0 && regFull <=0x1b8 && val ) { header.hardware = HW_DUALOPL2; } Bit8u raw = ToRaw[ regMask ]; if ( raw == 0xff ) return; if ( regFull & 0x100 ) raw |= 128; AddBuf( raw, val ); } void WriteCache( void ) { Bitu i, val; /* Check the registers to add */ for (i=0;i<256;i++) { //Skip the note on entries if (i>=0xb0 && i<=0xb8) continue; val = (*cache)[ i ]; if (val) { AddWrite( i, val ); } val = (*cache)[ 0x100 + i ]; if (val) { AddWrite( 0x100 + i, val ); } } } void InitHeader( void ) { memset( &header, 0, sizeof( header ) ); memcpy( header.id, "DBRAWOPL", 8 ); header.versionLow = 0; header.versionHigh = 2; header.delay256 = delay256; header.delayShift8 = delayShift8; header.conversionTableSize = RawUsed; } void CloseFile( void ) { if ( handle ) { ClearBuf(); /* Endianize the header and write it to beginning of the file */ var_write( &header.versionHigh, header.versionHigh ); var_write( &header.versionLow, header.versionLow ); var_write( &header.commands, header.commands ); var_write( &header.milliseconds, header.milliseconds ); fseek( handle, 0, SEEK_SET ); fwrite( &header, 1, sizeof( header ), handle ); fclose( handle ); handle = 0; } } public: bool DoWrite( Bit32u regFull, Bit8u val ) { Bit8u regMask = regFull & 0xff; //Check the raw index for this register if we actually have to save it if ( handle ) { /* Check if we actually care for this to be logged, else just ignore it */ Bit8u raw = ToRaw[ regMask ]; if ( raw == 0xff ) { return true; } /* Check if this command will not just replace the same value in a reg that doesn't do anything with it */ if ( (*cache)[ regFull ] == val ) return true; /* Check how much time has passed */ Bitu passed = PIC_Ticks - lastTicks; lastTicks = PIC_Ticks; header.milliseconds += passed; //if ( passed > 0 ) LOG_MSG( "Delay %d", passed ) ; // If we passed more than 30 seconds since the last command, we'll restart the the capture if ( passed > 30000 ) { CloseFile(); goto skipWrite; } while (passed > 0) { if (passed < 257) { //1-256 millisecond delay AddBuf( delay256, passed - 1 ); passed = 0; } else { Bitu shift = (passed >> 8); passed -= shift << 8; AddBuf( delayShift8, shift - 1 ); } } AddWrite( regFull, val ); return true; } skipWrite: //Not yet capturing to a file here //Check for commands that would start capturing, if it's not one of them return if ( !( //note on in any channel ( regMask>=0xb0 && regMask<=0xb8 && (val&0x020) ) || //Percussion mode enabled and a note on in any percussion instrument ( regMask == 0xbd && ( (val&0x3f) > 0x20 ) ) )) { return true; } handle = OpenCaptureFile("Raw Opl",".dro"); if (!handle) return false; InitHeader(); //Prepare space at start of the file for the header fwrite( &header, 1, sizeof(header), handle ); /* write the Raw To Reg table */ fwrite( &ToReg, 1, RawUsed, handle ); /* Write the cache of last commands */ WriteCache( ); /* Write the command that triggered this */ AddWrite( regFull, val ); //Init the timing information for the next commands lastTicks = PIC_Ticks; startTicks = PIC_Ticks; return true; } Capture( RegisterCache* _cache ) { cache = _cache; handle = 0; bufUsed = 0; MakeTables(); } ~Capture() { CloseFile(); } }; /* Chip */ bool Chip::Write( Bit32u reg, Bit8u val ) { switch ( reg ) { case 0x02: timer[0].counter = val; return true; case 0x03: timer[1].counter = val; return true; case 0x04: double time; time = PIC_FullIndex(); if ( val & 0x80 ) { timer[0].Reset( time ); timer[1].Reset( time ); } else { timer[0].Update( time ); timer[1].Update( time ); if ( val & 0x1 ) { timer[0].Start( time, 80 ); } else { timer[0].Stop( ); } timer[0].masked = (val & 0x40) > 0; if ( timer[0].masked ) timer[0].overflow = false; if ( val & 0x2 ) { timer[1].Start( time, 320 ); } else { timer[1].Stop( ); } timer[1].masked = (val & 0x20) > 0; if ( timer[1].masked ) timer[1].overflow = false; } return true; } return false; } Bit8u Chip::Read( ) { double time( PIC_FullIndex() ); timer[0].Update( time ); timer[1].Update( time ); Bit8u ret = 0; //Overflow won't be set if a channel is masked if ( timer[0].overflow ) { ret |= 0x40; ret |= 0x80; } if ( timer[1].overflow ) { ret |= 0x20; ret |= 0x80; } return ret; } void Module::CacheWrite( Bit32u reg, Bit8u val ) { //capturing? if ( capture ) { capture->DoWrite( reg, val ); } //Store it into the cache cache[ reg ] = val; } void Module::DualWrite( Bit8u index, Bit8u reg, Bit8u val ) { //Make sure you don't use opl3 features //Don't allow write to disable opl3 if ( reg == 5 ) { return; } //Only allow 4 waveforms if ( reg >= 0xE0 ) { val &= 3; } //Write to the timer? if ( chip[index].Write( reg, val ) ) return; //Enabling panning if ( reg >= 0xc0 && reg <=0xc8 ) { val &= 0x0f; val |= index ? 0xA0 : 0x50; } Bit32u fullReg = reg + (index ? 0x100 : 0); handler->WriteReg( fullReg, val ); CacheWrite( fullReg, val ); } void Module::PortWrite( Bitu port, Bitu val, Bitu iolen ) { //Keep track of last write time lastUsed = PIC_Ticks; //Maybe only enable with a keyon? if ( !mixerChan->enabled ) { mixerChan->Enable(true); } if ( port&1 ) { switch ( mode ) { case MODE_OPL2: case MODE_OPL3: if ( !chip[0].Write( reg.normal, val ) ) { handler->WriteReg( reg.normal, val ); CacheWrite( reg.normal, val ); } break; case MODE_DUALOPL2: //Not a 0x??8 port, then write to a specific port if ( !(port & 0x8) ) { Bit8u index = ( port & 2 ) >> 1; DualWrite( index, reg.dual[index], val ); } else { //Write to both ports DualWrite( 0, reg.dual[0], val ); DualWrite( 1, reg.dual[1], val ); } break; } } else { //Ask the handler to write the address //Make sure to clip them in the right range switch ( mode ) { case MODE_OPL2: reg.normal = handler->WriteAddr( port, val ) & 0xff; break; case MODE_OPL3: reg.normal = handler->WriteAddr( port, val ) & 0x1ff; break; case MODE_DUALOPL2: //Not a 0x?88 port, when write to a specific side if ( !(port & 0x8) ) { Bit8u index = ( port & 2 ) >> 1; reg.dual[index] = val & 0xff; } else { reg.dual[0] = val & 0xff; reg.dual[1] = val & 0xff; } break; } } } Bitu Module::PortRead( Bitu port, Bitu iolen ) { switch ( mode ) { case MODE_OPL2: //We allocated 4 ports, so just return -1 for the higher ones if ( !(port & 3 ) ) { //Make sure the low bits are 6 on opl2 return chip[0].Read() | 0x6; } else { return 0xff; } case MODE_OPL3: //We allocated 4 ports, so just return -1 for the higher ones if ( !(port & 3 ) ) { return chip[0].Read(); } else { return 0xff; } case MODE_DUALOPL2: //Only return for the lower ports if ( port & 1 ) { return 0xff; } //Make sure the low bits are 6 on opl2 return chip[ (port >> 1) & 1].Read() | 0x6; } return 0; } void Module::Init( Mode m ) { mode = m; switch ( mode ) { case MODE_OPL3: case MODE_OPL2: break; case MODE_DUALOPL2: //Setup opl3 mode in the hander handler->WriteReg( 0x105, 1 ); //Also set it up in the cache so the capturing will start opl3 CacheWrite( 0x105, 1 ); break; } } }; //namespace static Adlib::Module* module = 0; static void OPL_CallBack(Bitu len) { module->handler->Generate( module->mixerChan, len ); //Disable the sound generation after 30 seconds of silence if ((PIC_Ticks - module->lastUsed) > 30000) { Bitu i; for (i=0xb0;i<0xb9;i++) if (module->cache[i]&0x20||module->cache[i+0x100]&0x20) break; if (i==0xb9) module->mixerChan->Enable(false); else module->lastUsed = PIC_Ticks; } } static Bitu OPL_Read(Bitu port,Bitu iolen) { return module->PortRead( port, iolen ); } void OPL_Write(Bitu port,Bitu val,Bitu iolen) { module->PortWrite( port, val, iolen ); } /* Save the current state of the operators as instruments in an reality adlib tracker file */ static void SaveRad() { char b[16 * 1024]; int w = 0; FILE* handle = OpenCaptureFile("RAD Capture",".rad"); if ( !handle ) return; //Header fwrite( "RAD by REALiTY!!", 1, 16, handle ); b[w++] = 0x10; //version b[w++] = 0x06; //default speed and no description //Write 18 instuments for all operators in the cache for ( int i = 0; i < 18; i++ ) { Bit8u* set = module->cache + ( i / 9 ) * 256; Bitu offset = ((i % 9) / 3) * 8 + (i % 3); Bit8u* base = set + offset; b[w++] = 1 + i; //instrument number b[w++] = base[0x23]; b[w++] = base[0x20]; b[w++] = base[0x43]; b[w++] = base[0x40]; b[w++] = base[0x63]; b[w++] = base[0x60]; b[w++] = base[0x83]; b[w++] = base[0x80]; b[w++] = set[0xc0 + (i % 9)]; b[w++] = base[0xe3]; b[w++] = base[0xe0]; } b[w++] = 0; //instrument 0, no more instruments following b[w++] = 1; //1 pattern following //Zero out the remaing part of the file a bit to make rad happy for ( int i = 0; i < 64; i++ ) { b[w++] = 0; } fwrite( b, 1, w, handle ); fclose( handle ); }; static void OPL_SaveRawEvent(bool pressed) { if (!pressed) return; // SaveRad();return; /* Check for previously opened wave file */ if ( module->capture ) { delete module->capture; module->capture = 0; LOG_MSG("Stopped Raw OPL capturing."); } else { LOG_MSG("Preparing to capture Raw OPL, will start with first note played."); module->capture = new Adlib::Capture( &module->cache ); } } namespace Adlib { Module::Module( Section* configuration ) : Module_base(configuration) { reg.dual[0] = 0; reg.dual[1] = 0; reg.normal = 0; handler = 0; capture = 0; Section_prop * section=static_cast(configuration); Bitu base = section->Get_hex("sbbase"); Bitu rate = section->Get_int("oplrate"); //Make sure we can't select lower than 8000 to prevent fixed point issues if ( rate < 8000 ) rate = 8000; std::string oplemu( section->Get_string( "oplemu" ) ); mixerChan = mixerObject.Install(OPL_CallBack,rate,"FM"); mixerChan->SetScale( 2.0 ); if (oplemu == "fast") { handler = new DBOPL::Handler(); } else if (oplemu == "compat") { if ( oplmode == OPL_opl2 ) { handler = new OPL2::Handler(); } else { handler = new OPL3::Handler(); } } else { handler = new DBOPL::Handler(); } handler->Init( rate ); bool single = false; switch ( oplmode ) { case OPL_opl2: single = true; Init( Adlib::MODE_OPL2 ); break; case OPL_dualopl2: Init( Adlib::MODE_DUALOPL2 ); break; case OPL_opl3: Init( Adlib::MODE_OPL3 ); break; } //0x388 range WriteHandler[0].Install(0x388,OPL_Write,IO_MB, 4 ); ReadHandler[0].Install(0x388,OPL_Read,IO_MB, 4 ); //0x220 range if ( !single ) { WriteHandler[1].Install(base,OPL_Write,IO_MB, 4 ); ReadHandler[1].Install(base,OPL_Read,IO_MB, 4 ); } //0x228 range WriteHandler[2].Install(base+8,OPL_Write,IO_MB, 2); ReadHandler[2].Install(base+8,OPL_Read,IO_MB, 1); MAPPER_AddHandler(OPL_SaveRawEvent,MK_f7,MMOD1|MMOD2,"caprawopl","Cap OPL"); } Module::~Module() { if ( capture ) { delete capture; } if ( handler ) { delete handler; } } //Initialize static members OPL_Mode Module::oplmode=OPL_none; }; //Adlib Namespace void OPL_Init(Section* sec,OPL_Mode oplmode) { Adlib::Module::oplmode = oplmode; module = new Adlib::Module( sec ); } void OPL_ShutDown(Section* sec){ delete module; module = 0; }