// TODO: SCSP and (especially) WonderSwan /************************ * DAC Stream Control * ***********************/ // (Custom Driver to handle PCM Streams of YM2612 DAC and PWM.) // // Written on 3 February 2011 by Valley Bell // Last Update: 13 April 2014 // // Only for usage in non-commercial, VGM file related software. /* How it basically works: 1. send command X with data Y at frequency F to chip C 2. do that until you receive a STOP command, or until you sent N commands */ #include "mamedef.h" #include "dac_control.h" //#include "../ChipMapper.h" void chip_reg_write(void *param, UINT8 ChipType, UINT8 ChipID, UINT8 Port, UINT8 Offset, UINT8 Data); #define DAC_SMPL_RATE chip->SampleRate typedef struct _dac_control { // Commands sent to dest-chip UINT8 DstChipType; UINT8 DstChipID; UINT16 DstCommand; UINT8 CmdSize; UINT32 Frequency; // Frequency (Hz) at which the commands are sent UINT32 DataLen; // to protect from reading beyond End Of Data const UINT8* Data; UINT32 DataStart; // Position where to start UINT8 StepSize; // usually 1, set to 2 for L/R interleaved data UINT8 StepBase; // usually 0, set to 0/1 for L/R interleaved data UINT32 CmdsToSend; // Running Bits: 0 (01) - is playing // 2 (04) - loop sample (simple loop from start to end) // 4 (10) - already sent this command // 7 (80) - disabled UINT8 Running; UINT8 Reverse; UINT32 Step; // Position in Player SampleRate UINT32 Pos; // Position in Data SampleRate UINT32 RemainCmds; UINT32 RealPos; // true Position in Data (== Pos, if Reverse is off) UINT8 DataStep; // always StepSize * CmdSize void* param; UINT32 SampleRate; } dac_control; #define NULL (void*)0 INLINE void daccontrol_SendCommand(dac_control *chip) { UINT8 Port; UINT8 Command; UINT8 Data; const UINT8* ChipData; if (chip->Running & 0x10) // command already sent return; if (chip->DataStart + chip->RealPos >= chip->DataLen) return; //if (! chip->Reverse) ChipData = chip->Data + (chip->DataStart + chip->RealPos); //else // ChipData = chip->Data + (chip->DataStart + chip->CmdsToSend - 1 - chip->Pos); switch(chip->DstChipType) { // Support for the important chips case 0x02: // YM2612 (16-bit Register (actually 9 Bit), 8-bit Data) Port = (chip->DstCommand & 0xFF00) >> 8; Command = (chip->DstCommand & 0x00FF) >> 0; Data = ChipData[0x00]; chip_reg_write(chip->param, chip->DstChipType, chip->DstChipID, Port, Command, Data); break; case 0x11: // PWM (4-bit Register, 12-bit Data) Port = (chip->DstCommand & 0x000F) >> 0; Command = ChipData[0x01] & 0x0F; Data = ChipData[0x00]; chip_reg_write(chip->param, chip->DstChipType, chip->DstChipID, Port, Command, Data); break; // Support for other chips (mainly for completeness) case 0x00: // SN76496 (4-bit Register, 4-bit/10-bit Data) Command = (chip->DstCommand & 0x00F0) >> 0; Data = ChipData[0x00] & 0x0F; if (Command & 0x10) { // Volume Change (4-Bit value) chip_reg_write(chip->param, chip->DstChipType, chip->DstChipID, 0x00, 0x00, Command | Data); } else { // Frequency Write (10-Bit value) Port = ((ChipData[0x01] & 0x03) << 4) | ((ChipData[0x00] & 0xF0) >> 4); chip_reg_write(chip->param, chip->DstChipType, chip->DstChipID, 0x00, 0x00, Command | Data); chip_reg_write(chip->param, chip->DstChipType, chip->DstChipID, 0x00, 0x00, Port); } break; case 0x18: // OKIM6295 - TODO: verify Command = (chip->DstCommand & 0x00FF) >> 0; Data = ChipData[0x00]; if (! Command) { Port = (chip->DstCommand & 0x0F00) >> 8; if (Data & 0x80) { // Sample Start // write sample ID chip_reg_write(chip->param, chip->DstChipType, chip->DstChipID, 0x00, Command, Data); // write channel(s) that should play the sample chip_reg_write(chip->param, chip->DstChipType, chip->DstChipID, 0x00, Command, Port << 4); } else { // Sample Stop chip_reg_write(chip->param, chip->DstChipType, chip->DstChipID, 0x00, Command, Port << 3); } } else { chip_reg_write(chip->param, chip->DstChipType, chip->DstChipID, 0x00, Command, Data); } break; // Generic support: 8-bit Register, 8-bit Data case 0x01: // YM2413 case 0x03: // YM2151 case 0x06: // YM2203 case 0x09: // YM3812 case 0x0A: // YM3526 case 0x0B: // Y8950 case 0x0F: // YMZ280B case 0x12: // AY8910 case 0x13: // GameBoy DMG case 0x14: // NES APU // case 0x15: // MultiPCM case 0x16: // UPD7759 case 0x17: // OKIM6258 case 0x1D: // K053260 - TODO: Verify case 0x1E: // Pokey - TODO: Verify Command = (chip->DstCommand & 0x00FF) >> 0; Data = ChipData[0x00]; chip_reg_write(chip->param, chip->DstChipType, chip->DstChipID, 0x00, Command, Data); break; // Generic support: 16-bit Register, 8-bit Data case 0x07: // YM2608 case 0x08: // YM2610/B case 0x0C: // YMF262 case 0x0D: // YMF278B case 0x0E: // YMF271 case 0x19: // K051649 - TODO: Verify case 0x1A: // K054539 - TODO: Verify case 0x1C: // C140 - TODO: Verify Port = (chip->DstCommand & 0xFF00) >> 8; Command = (chip->DstCommand & 0x00FF) >> 0; Data = ChipData[0x00]; chip_reg_write(chip->param, chip->DstChipType, chip->DstChipID, Port, Command, Data); break; // Generic support: 8-bit Register with Channel Select, 8-bit Data case 0x05: // RF5C68 case 0x10: // RF5C164 case 0x1B: // HuC6280 Port = (chip->DstCommand & 0xFF00) >> 8; Command = (chip->DstCommand & 0x00FF) >> 0; Data = ChipData[0x00]; if (Port != 0xFF) // Send Channel Select chip_reg_write(chip->param, chip->DstChipType, chip->DstChipID, 0x00, Command >> 4, Port); // Send Data chip_reg_write(chip->param, chip->DstChipType, chip->DstChipID, 0x00, Command & 0x0F, Data); break; // Generic support: 8-bit Register, 16-bit Data case 0x1F: // QSound Command = (chip->DstCommand & 0x00FF) >> 0; chip_reg_write(chip->param, chip->DstChipType, chip->DstChipID, ChipData[0x00], ChipData[0x01], Command); break; } chip->Running |= 0x10; return; } INLINE UINT32 muldiv64round(UINT32 Multiplicand, UINT32 Multiplier, UINT32 Divisor) { // Yes, I'm correctly rounding the values. return (UINT32)(((UINT64)Multiplicand * Multiplier + Divisor / 2) / Divisor); } void daccontrol_update(void *_info, UINT32 samples) { dac_control *chip = (dac_control *)_info; UINT32 NewPos; INT16 RealDataStp; if (chip->Running & 0x80) // disabled return; if (! (chip->Running & 0x01)) // stopped return; if (! chip->Reverse) RealDataStp = chip->DataStep; else RealDataStp = -chip->DataStep; if (samples > 0x20) { // very effective Speed Hack for fast seeking NewPos = chip->Step + (samples - 0x10); NewPos = muldiv64round(NewPos * chip->DataStep, chip->Frequency, DAC_SMPL_RATE); while(chip->RemainCmds && chip->Pos < NewPos) { chip->Pos += chip->DataStep; chip->RealPos += RealDataStp; chip->RemainCmds --; } } chip->Step += samples; // Formula: Step * Freq / SampleRate NewPos = muldiv64round(chip->Step * chip->DataStep, chip->Frequency, DAC_SMPL_RATE); daccontrol_SendCommand(chip); while(chip->RemainCmds && chip->Pos < NewPos) { daccontrol_SendCommand(chip); chip->Pos += chip->DataStep; chip->RealPos += RealDataStp; chip->Running &= ~0x10; chip->RemainCmds --; } if (! chip->RemainCmds && (chip->Running & 0x04)) { // loop back to start chip->RemainCmds = chip->CmdsToSend; chip->Step = 0x00; chip->Pos = 0x00; if (! chip->Reverse) chip->RealPos = 0x00; else chip->RealPos = (chip->CmdsToSend - 0x01) * chip->DataStep; } if (! chip->RemainCmds) chip->Running &= ~0x01; // stop return; } UINT8 device_start_daccontrol(void **_info, void *param, int SampleRate) { dac_control *chip; chip = (dac_control *) calloc(1, sizeof(dac_control)); *_info = (void *) chip; chip->param = param; chip->SampleRate = SampleRate; chip->DstChipType = 0xFF; chip->DstChipID = 0x00; chip->DstCommand = 0x0000; chip->Running = 0xFF; // disable all actions (except setup_chip) return 1; } void device_stop_daccontrol(void *_info) { dac_control *chip = (dac_control *)_info; chip->Running = 0xFF; free(chip); return; } void device_reset_daccontrol(void *_info) { dac_control *chip = (dac_control *)_info; chip->DstChipType = 0x00; chip->DstChipID = 0x00; chip->DstCommand = 0x00; chip->CmdSize = 0x00; chip->Frequency = 0; chip->DataLen = 0x00; chip->Data = NULL; chip->DataStart = 0x00; chip->StepSize = 0x00; chip->StepBase = 0x00; chip->Running = 0x00; chip->Reverse = 0x00; chip->Step = 0x00; chip->Pos = 0x00; chip->RealPos = 0x00; chip->RemainCmds = 0x00; chip->DataStep = 0x00; return; } void daccontrol_setup_chip(void *_info, UINT8 ChType, UINT8 ChNum, UINT16 Command) { dac_control *chip = (dac_control *)_info; chip->DstChipType = ChType; // TypeID (e.g. 0x02 for YM2612) chip->DstChipID = ChNum; // chip number (to send commands to 1st or 2nd chip) chip->DstCommand = Command; // Port and Command (would be 0x02A for YM2612) switch(chip->DstChipType) { case 0x00: // SN76496 if (chip->DstCommand & 0x0010) chip->CmdSize = 0x01; // Volume Write else chip->CmdSize = 0x02; // Frequency Write break; case 0x02: // YM2612 chip->CmdSize = 0x01; break; case 0x11: // PWM case 0x1F: // QSound chip->CmdSize = 0x02; break; default: chip->CmdSize = 0x01; break; } chip->DataStep = chip->CmdSize * chip->StepSize; return; } void daccontrol_set_data(void *_info, UINT8* Data, UINT32 DataLen, UINT8 StepSize, UINT8 StepBase) { dac_control *chip = (dac_control *)_info; if (chip->Running & 0x80) return; if (DataLen && Data != NULL) { chip->DataLen = DataLen; chip->Data = Data; } else { chip->DataLen = 0x00; chip->Data = NULL; } chip->StepSize = StepSize ? StepSize : 1; chip->StepBase = StepBase; chip->DataStep = chip->CmdSize * chip->StepSize; return; } void daccontrol_refresh_data(void *_info, UINT8* Data, UINT32 DataLen) { // Should be called to fix the data pointer. (e.g. after a realloc) dac_control *chip = (dac_control *)_info; if (chip->Running & 0x80) return; if (DataLen && Data != NULL) { chip->DataLen = DataLen; chip->Data = Data; } else { chip->DataLen = 0x00; chip->Data = NULL; } return; } void daccontrol_set_frequency(void *_info, UINT32 Frequency) { dac_control *chip = (dac_control *)_info; if (chip->Running & 0x80) return; chip->Frequency = Frequency; return; } void daccontrol_start(void *_info, UINT32 DataPos, UINT8 LenMode, UINT32 Length) { dac_control *chip = (dac_control *)_info; UINT16 CmdStepBase; if (chip->Running & 0x80) return; CmdStepBase = chip->CmdSize * chip->StepBase; if (DataPos != 0xFFFFFFFF) // skip setting DataStart, if Pos == -1 { chip->DataStart = DataPos + CmdStepBase; if (chip->DataStart > chip->DataLen) // catch bad value and force silence chip->DataStart = chip->DataLen; } switch(LenMode & 0x0F) { case DCTRL_LMODE_IGNORE: // Length is already set - ignore break; case DCTRL_LMODE_CMDS: // Length = number of commands chip->CmdsToSend = Length; break; case DCTRL_LMODE_MSEC: // Length = time in msec chip->CmdsToSend = 1000 * Length / chip->Frequency; break; case DCTRL_LMODE_TOEND: // play unti stop-command is received (or data-end is reached) chip->CmdsToSend = (chip->DataLen - (chip->DataStart - CmdStepBase)) / chip->DataStep; break; case DCTRL_LMODE_BYTES: // raw byte count chip->CmdsToSend = Length / chip->DataStep; break; default: chip->CmdsToSend = 0x00; break; } chip->Reverse = (LenMode & 0x10) >> 4; chip->RemainCmds = chip->CmdsToSend; chip->Step = 0x00; chip->Pos = 0x00; if (! chip->Reverse) chip->RealPos = 0x00; else chip->RealPos = (chip->CmdsToSend - 0x01) * chip->DataStep; chip->Running &= ~0x04; chip->Running |= (LenMode & 0x80) ? 0x04 : 0x00; // set loop mode chip->Running |= 0x01; // start chip->Running &= ~0x10; // command isn't yet sent return; } void daccontrol_stop(void *_info) { dac_control *chip = (dac_control *)_info; if (chip->Running & 0x80) return; chip->Running &= ~0x01; // stop return; }