#include "Hiopl.h" #include #include "JuceHeader.h" // A wrapper around the DOSBox and ZDoom OPL emulators. // Used by the first recording instance to claim master status Hiopl* Hiopl::master = NULL; bool Hiopl::IsAnInstanceRecording() { return NULL != Hiopl::master; } Hiopl::Hiopl(int buflen, Emulator emulator) { InitCaptureVariables(); adlib = new DBOPL::Handler(); zdoom = JavaOPLCreate(false); _op1offset[1] = 0x0; _op1offset[2] = 0x1; _op1offset[3] = 0x2; _op1offset[4] = 0x8; _op1offset[5] = 0x9; _op1offset[6] = 0xa; _op1offset[7] = 0x10; _op1offset[8] = 0x11; _op1offset[9] = 0x12; _op2offset[1] = 0x3; _op2offset[2] = 0x4; _op2offset[3] = 0x5; _op2offset[4] = 0xb; _op2offset[5] = 0xc; _op2offset[6] = 0xd; _op2offset[7] = 0x13; _op2offset[8] = 0x14; _op2offset[9] = 0x15; SetEmulator(emulator); _ClearRegisters(); } void Hiopl::_ClearRegisters() { for (int i = 0; i < 256; i++) { _WriteReg(i, 0); } } void Hiopl::SetEmulator(Emulator emulator) { this->emulator = emulator; } void Hiopl::Generate(int length, float* buffer) { // This would be better done using Juce's built in audio format conversion. if (DOSBOX == emulator) { Bit32s* buf32 = new Bit32s[length]; adlib->Generate(length, buf32); for (int i = 0; i < length; i++) { // The magic divisor is tuned to match to ZDoom output amplitude. buffer[i] = (float)(buf32[i])/8200.0f; } delete buf32; } else if (ZDOOM == emulator) { // ZDoom hacked to write mono samples zdoom->Update(buffer, length); } } void Hiopl::SetSampleRate(int hz) { adlib->Init(hz); } void Hiopl::_WriteReg(Bit32u reg, Bit8u value, Bit8u mask) { if (mask > 0) { value = (regCache[reg] & (~mask)) | (value & mask); } // Write to the registers of both emulators. //if (DOSBOX == emulator) { adlib->WriteReg(reg, value); //} else if (ZDOOM == emulator) { zdoom->WriteReg(reg, value); //} regCache[reg] = value; _CaptureRegWriteWithDelay(reg, value); } void Hiopl::_ClearRegBits(Bit32u reg, Bit8u mask) { _WriteReg(reg, regCache[reg] & ~mask); } void Hiopl::EnableWaveformControl() { _WriteReg(0x01, 0x20); } void Hiopl::SetWaveform(int ch, int osc, Waveform wave) { int offset = this->_GetOffset(ch, osc); _WriteReg(0xe0+offset, (Bit8u)wave, 0x7); } void Hiopl::SetAttenuation(int ch, int osc, int level) { int offset = this->_GetOffset(ch, osc); _WriteReg(0x40+offset, (Bit8u)level, 0x3f); } void Hiopl::SetKsl(int ch, int osc, int level) { int offset = this->_GetOffset(ch, osc); _WriteReg(0x40+offset, (Bit8u)(level<<6), 0xc0); } void Hiopl::SetFrequencyMultiple(int ch, int osc, FreqMultiple mult) { int offset = this->_GetOffset(ch, osc); _WriteReg(0x20+offset, (Bit8u)mult, 0xf); } void Hiopl::SetEnvelopeAttack(int ch, int osc, int t) { int offset = this->_GetOffset(ch, osc); _WriteReg(0x60+offset, (Bit8u)t<<4, 0xf0); } void Hiopl::SetEnvelopeDecay(int ch, int osc, int t) { int offset = this->_GetOffset(ch, osc); _WriteReg(0x60+offset, (Bit8u)t, 0x0f); } void Hiopl::SetEnvelopeSustain(int ch, int osc, int level) { int offset = this->_GetOffset(ch, osc); _WriteReg(0x80+offset, (Bit8u)level<<4, 0xf0); } void Hiopl::SetEnvelopeRelease(int ch, int osc, int t) { int offset = this->_GetOffset(ch, osc); _WriteReg(0x80+offset, (Bit8u)t, 0x0f); } void Hiopl::EnableTremolo(int ch, int osc, bool enable) { int offset = this->_GetOffset(ch, osc); _WriteReg(0x20+offset, enable ? 0x80 : 0x0, 0x80); } void Hiopl::EnableVibrato(int ch, int osc, bool enable) { int offset = this->_GetOffset(ch, osc); _WriteReg(0x20+offset, enable ? 0x40 : 0x0, 0x40); } void Hiopl::TremoloDepth(bool high) { _WriteReg(0xbd, high ? 0x80 : 0x0, 0x80); } void Hiopl::VibratoDepth(bool high) { _WriteReg(0xbd, high ? 0x40 : 0x0, 0x40); } void Hiopl::EnableSustain(int ch, int osc, bool enable) { int offset = this->_GetOffset(ch, osc); _WriteReg(0x20+offset, enable ? 0x20 : 0x0, 0x20); } void Hiopl::EnableKsr(int ch, int osc, bool enable) { int offset = this->_GetOffset(ch, osc); _WriteReg(0x20+offset, enable ? 0x10 : 0x0, 0x10); } void Hiopl::EnableAdditiveSynthesis(int ch, bool enable) { int offset = this->_GetOffset(ch); _WriteReg(0xc0+offset, enable ? 0x1 : 0x0, 0x1); } void Hiopl::SetModulatorFeedback(int ch, int level) { int offset = this->_GetOffset(ch); _WriteReg(0xc0+offset, (Bit8u)level, 0x0e); } void Hiopl::KeyOn(int ch, float frqHz) { Hiopl::SetFrequency(ch, frqHz, true); } void Hiopl::KeyOff(int ch) { int offset = this->_GetOffset(ch); _ClearRegBits(0xb0+offset, 0x20); } void Hiopl::SetFrequency(int ch, float frqHz, bool keyOn) { unsigned int fnum, block; int offset = this->_GetOffset(ch); // ZDoom emulator seems to be tuned down by two semitones for some reason. if (ZDOOM == emulator) { frqHz *= 1.122461363636364f; } _milliHertzToFnum((unsigned int)(frqHz * 1000.0), &fnum, &block); _WriteReg(0xa0+offset, fnum % 0x100); uint8 trig = (regCache[0xb0+offset] & 0x20) | (keyOn ? 0x20 : 0x00); _WriteReg(0xb0+offset, trig|((block&0x7)<<2)|(0x3&(fnum/0x100))); } // from libgamemusic, opl-util.cpp void Hiopl::_milliHertzToFnum(unsigned int milliHertz, unsigned int *fnum, unsigned int *block, unsigned int conversionFactor) { // Special case to avoid divide by zero if (milliHertz == 0) { *block = 0; // actually any block will work *fnum = 0; return; } // Special case for frequencies too high to produce if (milliHertz > 6208431) { *block = 7; *fnum = 1023; return; } // This is a bit more efficient and doesn't need log2() from math.h if (milliHertz > 3104215) *block = 7; else if (milliHertz > 1552107) *block = 6; else if (milliHertz > 776053) *block = 5; else if (milliHertz > 388026) *block = 4; else if (milliHertz > 194013) *block = 3; else if (milliHertz > 97006) *block = 2; else if (milliHertz > 48503) *block = 1; else *block = 0; // Slightly more efficient version *fnum = (unsigned int)(((unsigned long long)milliHertz << (20 - *block)) / (conversionFactor * 1000.0) + 0.5); if ((*block == 7) && (*fnum > 1023)) { // frequency out of range, clipping to maximum value. *fnum = 1023; } assert(*block <= 7); assert(*fnum < 1024); return; } static Bit8u dro_header[]={ 'D','B','R','A', /* 0x00, Bit32u ID */ 'W','O','P','L', /* 0x04, Bit32u ID */ 0x0,0x00, /* 0x08, Bit16u version low */ 0x1,0x00, /* 0x09, Bit16u version high */ 0x0,0x0,0x0,0x0, /* 0x0c, Bit32u total milliseconds */ 0x0,0x0,0x0,0x0, /* 0x10, Bit32u total data */ 0x0,0x0,0x0,0x0 /* 0x14, Bit32u Type 0=opl2,1=opl3,2=dual-opl2 */ }; static Bit8u dro_opl3_enable[]={ 0x03, // switch to extended register bank 0x05, // register 0x105 0x01, // value 0x1 0x02 // switch back to regular OPL2 registers }; void Hiopl::StartCapture(const char* filepath) { Hiopl::master = this; lastWrite = -1; captureLengthBytes = 0; captureStart = Time::currentTimeMillis(); captureHandle = fopen(filepath, "wb"); fwrite(dro_header, 1, sizeof(dro_header), captureHandle); for (int i = 0; i <= 0xff; i++) { _CaptureRegWrite(i, 0); } //_CaptureRegWrite(0x1, 0x20); /* for (int ch = 1; ch <= CHANNELS; ch++) { int offset1 = this->_GetOffset(ch, 1); int offset2 = this->_GetOffset(ch, 2); int offset0 = this->_GetOffset(ch); _CaptureRegWrite(0x20 + offset1, regCache[0x20 + offset1]); _CaptureRegWrite(0x20 + offset2, regCache[0x20 + offset2]); _CaptureRegWrite(0x40 + offset1, regCache[0x40 + offset1]); _CaptureRegWrite(0x40 + offset2, regCache[0x40 + offset2]); _CaptureRegWrite(0x60 + offset1, regCache[0x60 + offset1]); _CaptureRegWrite(0x60 + offset2, regCache[0x60 + offset2]); _CaptureRegWrite(0x80 + offset1, regCache[0x80 + offset1]); _CaptureRegWrite(0x80 + offset2, regCache[0x80 + offset2]); _CaptureRegWrite(0xe0 + offset1, regCache[0xe0 + offset1]); _CaptureRegWrite(0xe0 + offset2, regCache[0xe0 + offset2]); _CaptureRegWrite(0xc0 + offset0, regCache[0xc0 + offset0]); } */ _CaptureOpl3Enable(); for (Bit8u i = 0x20; i <= 0x35; i++) { _CaptureRegWrite(i, regCache[i]); } for (Bit8u i = 0x40; i <= 0x55; i++) { _CaptureRegWrite(i, regCache[i]); } for (Bit8u i = 0x60; i <= 0x75; i++) { _CaptureRegWrite(i, regCache[i]); } for (Bit8u i = 0x80; i <= 0x95; i++) { _CaptureRegWrite(i, regCache[i]); } _CaptureRegWrite(0xbd, regCache[0xbd]); for (Bit8u i = 0xc0; i <= 0xc8; i++) { _CaptureRegWrite(i, regCache[i] | 0x30); // enable L + R channels } for (Bit8u i = 0xe0; i <= 0xf5; i++) { _CaptureRegWrite(i, regCache[i]); } } INLINE void host_writed(Bit8u *off, Bit32u val) { off[0]=(Bit8u)(val); off[1]=(Bit8u)(val >> 8); off[2]=(Bit8u)(val >> 16); off[3]=(Bit8u)(val >> 24); }; void Hiopl::InitCaptureVariables() { captureHandle = NULL; captureLengthBytes = 0; lastWrite = -1; captureStart = -1; } void Hiopl::StopCapture() { if (NULL != captureHandle) { Bit16u finalDelay = (Bit16u)(Time::currentTimeMillis() - lastWrite); _CaptureDelay(finalDelay); Bit32u lengthMilliseconds = (Bit32u)(finalDelay + Time::currentTimeMillis() - captureStart); host_writed(&dro_header[0x0c], lengthMilliseconds); host_writed(&dro_header[0x10], captureLengthBytes); //if (opl.raw.opl3 && opl.raw.dualopl2) host_writed(&dro_header[0x14],0x1); //else if (opl.raw.dualopl2) host_writed(&dro_header[0x14],0x2); //else host_writed(&dro_header[0x14],0x0); host_writed(&dro_header[0x14], 0x1); // OPL3 fseek(captureHandle, 0, 0); fwrite(dro_header, 1, sizeof(dro_header), captureHandle); fclose(captureHandle); } InitCaptureVariables(); } void Hiopl::_CaptureDelay(Bit16u delayMs) { Bit8u delay[3]; delay[0] = 0x01; delay[1] = delayMs & 0xff; delay[2] = (delayMs >> 8) & 0xff; fwrite(delay, 1, 3, captureHandle); captureLengthBytes += 3; } void Hiopl::_CaptureRegWrite(Bit32u reg, Bit8u value) { if (reg <= 0x4) { Bit8u escape = 0x4; fwrite(&escape, 1, 1, captureHandle); captureLengthBytes += 1; } Bit8u regAndVal[2]; regAndVal[0] = (Bit8u)reg; regAndVal[1] = value; fwrite(regAndVal, 1, 2, captureHandle); captureLengthBytes += 2; } void Hiopl::_CaptureRegWriteWithDelay(Bit32u reg, Bit8u value) { if (NULL != captureHandle) { Bit64s t = Time::currentTimeMillis(); if (lastWrite >= 0) { // Delays of over 65 seconds will be truncated, but that kind of delay is a bit silly anyway.. _CaptureDelay((Bit16u)(t - lastWrite)); } _CaptureRegWrite(reg, value); lastWrite = t; } } void Hiopl::_CaptureOpl3Enable() { fwrite(dro_opl3_enable, 1, 4, captureHandle); captureLengthBytes += 4; } Hiopl::~Hiopl() { }; bool Hiopl::_CheckParams(int ch, int osc=OSCILLATORS) { return ch > 0 && ch <= CHANNELS && osc > 0 && osc <= OSCILLATORS; } int Hiopl::_GetOffset(int ch, int osc) { assert(_CheckParams(ch, osc)); return (1 == osc) ? _op1offset[ch] : _op2offset[ch]; } int Hiopl::_GetOffset(int ch) { assert(_CheckParams(ch)); return ch - 1; }