/* 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. * * $URL$ * $Id$ */ /* * Based on AdLib emulation code of DOSBox * Copyright (C) 2002-2009 The DOSBox Team * Licensed under GPLv2+ * http://www.dosbox.com */ #ifndef DISABLE_DOSBOX_OPL #include "dosbox.h" #include "common/system.h" #include "common/scummsys.h" #include #include namespace OPL { namespace DOSBox { Timer::Timer() { masked = false; overflow = false; enabled = false; counter = 0; delay = 0; } void Timer::update(double time) { if (!enabled || !delay) return; double deltaStart = time - startTime; // Only set the overflow flag when not masked if (deltaStart >= 0 && !masked) overflow = 1; } void Timer::reset(double time) { overflow = false; if (!delay || !enabled) return; double delta = (time - startTime); double rem = fmod(delta, delay); double next = delay - rem; startTime = time + next; } void Timer::stop() { enabled = false; } void Timer::start(double time, int scale) { //Don't enable again if (enabled) return; enabled = true; delay = 0.001 * (256 - counter) * scale; startTime = time + delay; } bool Chip::write(uint32 reg, uint8 val) { switch (reg) { case 0x02: timer[0].counter = val; return true; case 0x03: timer[1].counter = val; return true; case 0x04: double time = g_system->getMillis() / 1000.0; 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; } uint8 Chip::read() { double time = g_system->getMillis() / 1000.0; timer[0].update(time); timer[1].update(time); uint8 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; } namespace OPL2 { #include "opl_impl.h" struct Handler : public DOSBox::Handler { void writeReg(uint32 reg, uint8 val) { adlib_write(reg, val); } uint32 writeAddr(uint32 port, uint8 val) { return val; } void generate(int16 *chan, uint samples) { adlib_getsample(chan, samples); } void init(uint rate) { adlib_init(rate); } }; } // End of namespace OPL2 namespace OPL3 { #define OPLTYPE_IS_OPL3 #include "opl_impl.h" struct Handler : public DOSBox::Handler { void writeReg(uint32 reg, uint8 val) { adlib_write(reg, val); } uint32 writeAddr(uint32 port, uint8 val) { adlib_write_index(port, val); return opl_index; } void generate(int16 *chan, uint samples) { adlib_getsample(chan, samples); } void init(uint rate) { adlib_init(rate); } }; } // End of namespace OPL3 OPL::OPL(Config::OplType type) : _type(type), _rate(0), _handler(0) { } OPL::~OPL() { free(); } void OPL::free() { delete _handler; _handler = 0; } bool OPL::init(int rate) { free(); memset(&_reg, 0, sizeof(_reg)); memset(_chip, 0, sizeof(_chip)); switch (_type) { case Config::kOpl2: _handler = new OPL2::Handler(); break; case Config::kDualOpl2: case Config::kOpl3: _handler = new OPL3::Handler(); break; default: return false; } _handler->init(rate); if (_type == Config::kDualOpl2) { // Setup opl3 mode in the hander _handler->writeReg(0x105, 1); } _rate = rate; return true; } void OPL::reset() { init(_rate); } void OPL::write(int port, int val) { if (port&1) { switch (_type) { case Config::kOpl2: case Config::kOpl3: if (!_chip[0].write(_reg.normal, val)) _handler->writeReg(_reg.normal, val); break; case Config::kDualOpl2: // Not a 0x??8 port, then write to a specific port if (!(port & 0x8)) { byte 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 (_type) { case Config::kOpl2: _reg.normal = _handler->writeAddr(port, val) & 0xff; break; case Config::kOpl3: _reg.normal = _handler->writeAddr(port, val) & 0x1ff; break; case Config::kDualOpl2: // Not a 0x?88 port, when write to a specific side if (!(port & 0x8)) { byte index = (port & 2) >> 1; _reg.dual[index] = val & 0xff; } else { _reg.dual[0] = val & 0xff; _reg.dual[1] = val & 0xff; } break; } } } byte OPL::read(int port) { switch (_type) { case Config::kOpl2: if (!(port & 1)) //Make sure the low bits are 6 on opl2 return _chip[0].read() | 0x6; break; case Config::kOpl3: if (!(port & 1)) return _chip[0].read(); break; case Config::kDualOpl2: // 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 OPL::writeReg(int r, int v) { byte tempReg = 0; switch (_type) { case Config::kOpl2: case Config::kDualOpl2: case Config::kOpl3: // We can't use _handler->writeReg here directly, since it would miss timer changes. // Backup old setup register tempReg = _reg.normal; // We need to set the register we want to write to via port 0x388 write(0x388, r); // Do the real writing to the register write(0x389, v); // Restore the old register write(0x388, tempReg); break; }; } void OPL::dualWrite(uint8 index, uint8 reg, uint8 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 && reg <= 0xE8) val &= 3; // Write to the timer? if (_chip[index].write(reg, val)) return; // Enabling panning if (reg >= 0xC0 && reg <= 0xC8) { val &= 15; val |= index ? 0xA0 : 0x50; } uint32 fullReg = reg + (index ? 0x100 : 0); _handler->writeReg(fullReg, val); } void OPL::readBuffer(int16 *buffer, int length) { // For stereo OPL cards, we divide the sample count by 2, // to match stereo AudioStream behavior. if (_type != Config::kOpl2) length >>= 1; _handler->generate(buffer, length); } } // End of namespace DOSBox } // End of namespace OPL #endif // !DISABLE_DOSBOX_ADLIB