/*************************************************************************************** * Genesis Plus * Main 68k bus handlers * * Copyright (C) 1998-2003 Charles Mac Donald (original code) * Copyright (C) 2007-2023 Eke-Eke (Genesis Plus GX) * * Redistribution and use of this code or any derivative works are permitted * provided that the following conditions are met: * * - Redistributions may not be sold, nor may they be used in a commercial * product or activity. * * - Redistributions that are modified from the original source must include the * complete source code, including the source code for all components used by a * binary built from the modified sources. However, as a special exception, the * source code distributed need not include anything that is normally distributed * (in either source or binary form) with the major components (compiler, kernel, * and so on) of the operating system on which the executable runs, unless that * component itself accompanies the executable. * * - Redistributions must reproduce the above copyright notice, this list of * conditions and the following disclaimer in the documentation and/or other * materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * ****************************************************************************************/ #include "shared.h" /*--------------------------------------------------------------------------*/ /* Unused areas (return open bus data, i.e prefetched instruction word) */ /*--------------------------------------------------------------------------*/ unsigned int m68k_read_bus_8(unsigned int address) { #ifdef LOGERROR error("Unused read8 %08X (%08X)\n", address, m68k_get_reg(M68K_REG_PC)); #endif address = m68k.pc | (address & 1); return READ_BYTE(m68k.memory_map[((address)>>16)&0xff].base, (address) & 0xffff); } unsigned int m68k_read_bus_16(unsigned int address) { #ifdef LOGERROR error("Unused read16 %08X (%08X)\n", address, m68k_get_reg(M68K_REG_PC)); #endif address = m68k.pc; return *(uint16 *)(m68k.memory_map[((address)>>16)&0xff].base + ((address) & 0xffff)); } void m68k_unused_8_w(unsigned int address, unsigned int data) { #ifdef LOGERROR error("Unused write8 %08X = %02X (%08X)\n", address, data, m68k_get_reg(M68K_REG_PC)); #endif } void m68k_unused_16_w(unsigned int address, unsigned int data) { #ifdef LOGERROR error("Unused write16 %08X = %04X (%08X)\n", address, data, m68k_get_reg(M68K_REG_PC)); #endif } /*--------------------------------------------------------------------------*/ /* Illegal areas (cause system to lock-up since !DTACK is not returned) */ /*--------------------------------------------------------------------------*/ void m68k_lockup_w_8 (unsigned int address, unsigned int data) { #ifdef LOGERROR error ("Lockup %08X = %02X (%08X)\n", address, data, m68k_get_reg(M68K_REG_PC)); #endif if (!config.force_dtack) { m68k_pulse_halt(); m68k.cycles = m68k.cycle_end; } } void m68k_lockup_w_16 (unsigned int address, unsigned int data) { #ifdef LOGERROR error ("Lockup %08X = %04X (%08X)\n", address, data, m68k_get_reg(M68K_REG_PC)); #endif if (!config.force_dtack) { m68k_pulse_halt(); m68k.cycles = m68k.cycle_end; } } unsigned int m68k_lockup_r_8 (unsigned int address) { #ifdef LOGERROR error ("Lockup %08X.b (%08X)\n", address, m68k_get_reg(M68K_REG_PC)); #endif if (!config.force_dtack) { m68k_pulse_halt(); m68k.cycles = m68k.cycle_end; } address = m68k.pc | (address & 1); return READ_BYTE(m68k.memory_map[((address)>>16)&0xff].base, (address) & 0xffff); } unsigned int m68k_lockup_r_16 (unsigned int address) { #ifdef LOGERROR error ("Lockup %08X.w (%08X)\n", address, m68k_get_reg(M68K_REG_PC)); #endif if (!config.force_dtack) { m68k_pulse_halt(); m68k.cycles = m68k.cycle_end; } address = m68k.pc; return *(uint16 *)(m68k.memory_map[((address)>>16)&0xff].base + ((address) & 0xffff)); } /*--------------------------------------------------------------------------*/ /* Z80 bus (accessed through I/O chip) */ /*--------------------------------------------------------------------------*/ unsigned int z80_read_byte(unsigned int address) { switch ((address >> 13) & 3) { case 2: /* YM2612 */ { return fm_read(m68k.cycles, address & 3); } case 3: /* Misc */ { /* VDP (through 68k bus) */ if ((address & 0xFF00) == 0x7F00) { return m68k_lockup_r_8(address); } return (m68k_read_bus_8(address) | 0xFF); } default: /* ZRAM */ { return zram[address & 0x1FFF]; } } } unsigned int z80_read_word(unsigned int address) { unsigned int data = z80_read_byte(address); return (data | (data << 8)); } void z80_write_byte(unsigned int address, unsigned int data) { switch ((address >> 13) & 3) { case 2: /* YM2612 */ { fm_write(m68k.cycles, address & 3, data); return; } case 3: { switch ((address >> 8) & 0x7F) { case 0x60: /* Bank register */ { gen_zbank_w(data & 1); return; } case 0x7F: /* VDP */ { m68k_lockup_w_8(address, data); return; } default: { m68k_unused_8_w(address, data); return; } } } default: /* ZRAM */ { zram[address & 0x1FFF] = data; m68k.cycles += 2 * 7; /* ZRAM access latency (fixes Pacman 2: New Adventures & Puyo Puyo 2) */ return; } } } void z80_write_word(unsigned int address, unsigned int data) { z80_write_byte(address, data >> 8); } /*--------------------------------------------------------------------------*/ /* MAIN-CPU polling detection and SUB-CPU synchronization (MEGA CD mode) */ /*--------------------------------------------------------------------------*/ static void m68k_poll_detect(unsigned int reg_mask) { /* detect MAIN-CPU register polling */ if (m68k.poll.detected & reg_mask) { if (m68k.cycles <= m68k.poll.cycle) { if (m68k.pc == m68k.poll.pc) { /* MAIN-CPU polling confirmed ? */ if (m68k.poll.detected & 1) { /* idle MAIN-CPU until register is modified */ m68k.cycles = m68k.cycle_end; m68k.stopped = reg_mask; #ifdef LOG_SCD error("m68k stopped from %d cycles\n", m68k.cycles); #endif } else { /* confirm MAIN-CPU polling */ m68k.poll.detected |= 1; m68k.poll.cycle = m68k.cycles + 840; } } return; } } else { /* set MAIN-CPU register access flag */ m68k.poll.detected = reg_mask; } /* reset MAIN-CPU polling detection */ m68k.poll.cycle = m68k.cycles + 840; m68k.poll.pc = m68k.pc; } static void m68k_poll_sync(unsigned int reg_mask) { /* relative SUB-CPU cycle counter */ unsigned int cycles = (m68k.cycles * SCYCLES_PER_LINE) / MCYCLES_PER_LINE; if (!s68k.stopped) { /* save current SUB-CPU end cycle count (recursive execution is possible) */ int end_cycle = s68k.cycle_end; /* sync SUB-CPU with MAIN-CPU */ s68k_run(cycles); /* restore SUB-CPU end cycle count */ s68k.cycle_end = end_cycle; } /* SUB-CPU idle on register polling ? */ if (s68k.stopped & reg_mask) { /* sync SUB-CPU with MAIN-CPU */ s68k.cycles = cycles; /* restart SUB-CPU */ s68k.stopped = 0; #ifdef LOG_SCD error("s68k started from %d cycles\n", cycles); #endif } /* clear CPU register access flags */ s68k.poll.detected &= ~reg_mask; m68k.poll.detected &= ~reg_mask; } /*--------------------------------------------------------------------------*/ /* I/O Control */ /*--------------------------------------------------------------------------*/ unsigned int ctrl_io_read_byte(unsigned int address) { switch ((address >> 8) & 0xFF) { case 0x00: /* I/O chip */ { if (!(address & 0xE0)) { return io_68k_read((address >> 1) & 0x0F); } return m68k_read_bus_8(address); } case 0x11: /* Z80 BUSACK */ { if (!(address & 1)) { /* Unused bits return prefetched bus data (Time Killers) */ address = m68k.pc; /* Check if bus has been requested and is not reseted */ if (zstate == 3) { /* D0 is cleared */ return (READ_BYTE(m68k.memory_map[((address)>>16)&0xff].base, (address) & 0xffff) & 0xFE); } /* D0 is set */ return (READ_BYTE(m68k.memory_map[((address)>>16)&0xff].base, (address) & 0xffff) | 0x01); } return m68k_read_bus_8(address); } case 0x20: /* MEGA-CD */ { #ifdef LOG_SCD error("[%d][%d]read byte CD register %X (%X)\n", v_counter, m68k.cycles, address, m68k.pc); #endif if (system_hw == SYSTEM_MCD) { /* register index ($A12000-A1203F mirrored up to $A120FF) */ uint8 index = address & 0x3f; /* Memory Mode */ if (index == 0x03) { m68k_poll_detect(1<<0x03); return scd.regs[0x03>>1].byte.l; } /* SUB-CPU communication flags */ if (index == 0x0f) { if (!s68k.stopped) { /* relative SUB-CPU cycle counter */ unsigned int cycles = (m68k.cycles * SCYCLES_PER_LINE) / MCYCLES_PER_LINE; /* save current SUB-CPU end cycle count (recursive execution is possible) */ int end_cycle = s68k.cycle_end; /* sync SUB-CPU with MAIN-CPU (Dracula Unleashed w/ Sega CD Model 2 Boot ROM) */ s68k_run(cycles); /* restore SUB-CPU end cycle count */ s68k.cycle_end = end_cycle; } m68k_poll_detect(1<<0x0f); return scd.regs[0x0f>>1].byte.l; } /* default registers */ if (index < 0x30) { /* SUB-CPU communication words */ if (index >= 0x20) { m68k_poll_detect(1 << (index - 0x10)); } /* register LSB */ if (address & 1) { return scd.regs[index >> 1].byte.l; } /* register MSB */ return scd.regs[index >> 1].byte.h; } } return m68k_read_bus_8(address); } case 0x30: /* TIME */ { if (cart.hw.time_r) { unsigned int data = cart.hw.time_r(address); if (address & 1) { return (data & 0xFF); } return (data >> 8); } return m68k_read_bus_8(address); } case 0x41: /* BOOT ROM */ { if ((config.bios & 1) && (address & 1)) { unsigned int data = gen_bankswitch_r() & 1; /* Unused bits return prefetched bus data */ address = m68k.pc; data |= (READ_BYTE(m68k.memory_map[((address)>>16)&0xff].base, (address) & 0xffff) & 0xFE); return data; } return m68k_read_bus_8(address); } case 0x50: /* SVP */ { if ((address & 0xFC) == 0x00) { unsigned int data = svp->ssp1601.gr[SSP_XST].byte.h; return (address & 1) ? (data & 0xFF) : (data >> 8); } if ((address & 0xFE) == 0x04) { unsigned int data = svp->ssp1601.gr[SSP_PM0].byte.h; svp->ssp1601.gr[SSP_PM0].byte.h &= ~1; return (address & 1) ? (data & 0xFF) : (data >> 8); } return m68k_read_bus_8(address); } case 0x10: /* MEMORY MODE */ case 0x12: /* Z80 RESET */ case 0x13: /* unknown */ case 0x40: /* TMSS */ case 0x44: /* RADICA */ { return m68k_read_bus_8(address); } default: /* Invalid address */ { return m68k_lockup_r_8(address); } } } unsigned int ctrl_io_read_word(unsigned int address) { switch ((address >> 8) & 0xFF) { case 0x00: /* I/O chip */ { if (!(address & 0xE0)) { unsigned int data = io_68k_read((address >> 1) & 0x0F); return (data << 8 | data); } return m68k_read_bus_16(address); } case 0x11: /* Z80 BUSACK */ { /* Unused bits return prefetched bus data (Time Killers) */ address = m68k.pc; /* Check if bus has been requested and is not reseted */ if (zstate == 3) { /* D8 is cleared */ return (*(uint16 *)(m68k.memory_map[((address)>>16)&0xff].base + ((address) & 0xffff)) & 0xFEFF); } /* D8 is set */ return (*(uint16 *)(m68k.memory_map[((address)>>16)&0xff].base + ((address) & 0xffff)) | 0x0100); } case 0x20: /* MEGA-CD */ { #ifdef LOG_SCD error("[%d][%d]read word CD register %X (%X)\n", v_counter, m68k.cycles, address, m68k.pc); #endif if (system_hw == SYSTEM_MCD) { /* register index ($A12000-A1203F mirrored up to $A120FF) */ uint8 index = address & 0x3f; /* Memory Mode */ if (index == 0x02) { m68k_poll_detect(1<<0x03); return scd.regs[0x03>>1].w; } /* CDC host data (word access only ?) */ if (index == 0x08) { return cdc_host_r(); } /* H-INT vector (word access only ?) */ if (index == 0x06) { return *(uint16 *)(m68k.memory_map[scd.cartridge.boot].base + 0x72); } /* Stopwatch counter (word read access only ?) */ if (index == 0x0c) { /* relative SUB-CPU cycle counter */ unsigned int cycles = (m68k.cycles * SCYCLES_PER_LINE) / MCYCLES_PER_LINE; /* cycle-accurate counter value */ return (scd.regs[0x0c>>1].w + ((cycles - scd.stopwatch) / TIMERS_SCYCLES_RATIO)) & 0xfff; } /* default registers */ if (index < 0x30) { /* SUB-CPU communication words */ if (index >= 0x20) { if (!s68k.stopped) { /* relative SUB-CPU cycle counter */ unsigned int cycles = (m68k.cycles * SCYCLES_PER_LINE) / MCYCLES_PER_LINE; /* save current SUB-CPU end cycle count (recursive execution is possible) */ int end_cycle = s68k.cycle_end; /* sync SUB-CPU with MAIN-CPU (Soul Star) */ s68k_run(cycles); /* restore SUB-CPU end cycle count */ s68k.cycle_end = end_cycle; } m68k_poll_detect(3 << (index - 0x10)); } return scd.regs[index >> 1].w; } } /* invalid address */ return m68k_read_bus_16(address); } case 0x30: /* TIME */ { if (cart.hw.time_r) { return cart.hw.time_r(address); } return m68k_read_bus_16(address); } case 0x50: /* SVP */ { if ((address & 0xFC) == 0x00) { return svp->ssp1601.gr[SSP_XST].byte.h; } if ((address & 0xFE) == 0x04) { unsigned int data = svp->ssp1601.gr[SSP_PM0].byte.h; svp->ssp1601.gr[SSP_PM0].byte.h &= ~1; return data; } return m68k_read_bus_16(address); } case 0x10: /* MEMORY MODE */ case 0x12: /* Z80 RESET */ case 0x13: /* unknown */ case 0x40: /* TMSS */ case 0x41: /* BOOT ROM */ case 0x44: /* RADICA */ { return m68k_read_bus_16(address); } default: /* Invalid address */ { return m68k_lockup_r_16(address); } } } void ctrl_io_write_byte(unsigned int address, unsigned int data) { switch ((address >> 8) & 0xFF) { case 0x00: /* I/O chip */ { if ((address & 0xE1) == 0x01) { /* get /LWR only */ io_68k_write((address >> 1) & 0x0F, data); return; } m68k_unused_8_w(address, data); return; } case 0x11: /* Z80 BUSREQ */ { if (!(address & 1)) { gen_zbusreq_w(data & 1, m68k.cycles); return; } m68k_unused_8_w(address, data); return; } case 0x12: /* Z80 RESET */ { if (!(address & 1)) { gen_zreset_w(data & 1, m68k.cycles); return; } m68k_unused_8_w(address, data); return; } case 0x20: /* MEGA-CD */ { #ifdef LOG_SCD error("[%d][%d]write byte CD register %X -> 0x%02X (%X)\n", v_counter, m68k.cycles, address, data, m68k.pc); #endif if (system_hw == SYSTEM_MCD) { /* register index ($A12000-A1203F mirrored up to $A120FF) */ switch (address & 0x3f) { case 0x00: /* SUB-CPU interrupt */ { /* IFL2 bit */ if (data & 0x01) { /* level 2 interrupt enabled ? */ if (scd.regs[0x32>>1].byte.l & 0x04) { if (!s68k.stopped) { /* relative SUB-CPU cycle counter */ unsigned int cycles = (m68k.cycles * SCYCLES_PER_LINE) / MCYCLES_PER_LINE; /* save current SUB-CPU end cycle count (recursive execution is possible) */ int end_cycle = s68k.cycle_end; /* sync SUB-CPU with MAIN-CPU (Earnest Evans, Fhey Area) */ s68k_run(cycles); /* restore SUB-CPU end cycle count */ s68k.cycle_end = end_cycle; } /* set IFL2 flag */ scd.regs[0x00].byte.h |= 0x01; /* trigger level 2 interrupt */ scd.pending |= (1 << 2); /* update IRQ level */ s68k_update_irq((scd.pending & scd.regs[0x32>>1].byte.l) >> 1); } } /* writing 0 does nothing */ return; } case 0x01: /* SUB-CPU control */ { unsigned int halted = s68k.stopped; /* RESET bit */ if (data & 0x01) { /* SUB-CPU reset is triggered on /RESET input 0->1 transition */ if (!(scd.regs[0x00].byte.l & 0x01)) { s68k_pulse_reset(); } /* BUSREQ bit */ if (data & 0x02) { /* SUB-CPU is halted (/HALT input is asserted) */ s68k_pulse_halt(); } else { /* SUB-CPU is running (/HALT input is released) */ s68k_clear_halt(); } /* update BUSREQ and RESET bits */ scd.regs[0x00].byte.l = data & 0x03; } else { /* SUB-CPU is halted (/HALT and /RESET inputs are asserted) */ s68k_pulse_halt(); /* RESET bit is cleared and BUSREQ bit is set to 1 (verified on real hardware) */ scd.regs[0x00].byte.l = 0x02; } /* check if SUB-CPU halt status has changed */ if (s68k.stopped != halted) { /* PRG-RAM (128KB bank) is normally mapped to $020000-$03FFFF (resp. $420000-$43FFFF) */ unsigned int base = scd.cartridge.boot + 0x02; /* BUSREQ bit remains set to 0 if SUB-CPU is halted while stopped (verified on real hardware) */ if (s68k.stopped & 0x01) { scd.regs[0x00].byte.l &= ~0x02; } /* PRG-RAM can only be accessed from MAIN-CPU & Z80 when BUSREQ bit is set (Dungeon Explorer USA version) */ if (scd.regs[0x00].byte.l & 0x02) { m68k.memory_map[base].read8 = m68k.memory_map[base+1].read8 = NULL; m68k.memory_map[base].read16 = m68k.memory_map[base+1].read16 = NULL; m68k.memory_map[base].write8 = m68k.memory_map[base+1].write8 = NULL; m68k.memory_map[base].write16 = m68k.memory_map[base+1].write16 = NULL; zbank_memory_map[base].read = zbank_memory_map[base+1].read = NULL; zbank_memory_map[base].write = zbank_memory_map[base+1].write = NULL; } else { m68k.memory_map[base].read8 = m68k.memory_map[base+1].read8 = m68k_read_bus_8; m68k.memory_map[base].read16 = m68k.memory_map[base+1].read16 = m68k_read_bus_16; m68k.memory_map[base].write8 = m68k.memory_map[base+1].write8 = m68k_unused_8_w; m68k.memory_map[base].write16 = m68k.memory_map[base+1].write16 = m68k_unused_16_w; zbank_memory_map[base].read = zbank_memory_map[base+1].read = zbank_unused_r; zbank_memory_map[base].write = zbank_memory_map[base+1].write = zbank_unused_w; } } return; } case 0x02: /* PRG-RAM Write Protection */ { scd.regs[0x02>>1].byte.h = data; return; } case 0x03: /* Memory mode */ { m68k_poll_sync(1<<0x03); /* PRG-RAM 128k bank mapped to $020000-$03FFFF (resp. $420000-$43FFFF) */ m68k.memory_map[scd.cartridge.boot + 0x02].base = scd.prg_ram + ((data & 0xc0) << 11); m68k.memory_map[scd.cartridge.boot + 0x03].base = m68k.memory_map[scd.cartridge.boot + 0x02].base + 0x10000; /* check current mode */ if (scd.regs[0x03>>1].byte.l & 0x04) { /* DMNA bit */ if (data & 0x02) { /* writing 1 to DMNA in 1M mode will return Word-RAM to SUB-CPU in 2M mode */ scd.dmna = 1; } else { /* writing 0 to DMNA in 1M mode actually sets DMNA bit */ data |= 0x02; /* update BK0-1 & DMNA bits */ scd.regs[0x03>>1].byte.l = (scd.regs[0x03>>1].byte.l & ~0xc2) | (data & 0xc2); return; } } else { /* writing 0 to DMNA in 2M mode does nothing */ if (data & 0x02) { /* Word-RAM is assigned to SUB-CPU */ scd.dmna = 1; /* clear RET bit and update BK0-1 & DMNA bits */ scd.regs[0x03>>1].byte.l = (scd.regs[0x03>>1].byte.l & ~0xc3) | (data & 0xc2); /* check if graphics operation is running */ if (scd.regs[0x58>>1].byte.h & 0x80) { /* relative SUB-CPU cycle counter */ unsigned int cycles = (m68k.cycles * SCYCLES_PER_LINE) / MCYCLES_PER_LINE; /* synchronize GFX processing with SUB-CPU (only if not already ahead) */ if (gfx.cycles < cycles) { gfx.cycles = cycles; } } return; } } /* update BK0-1 bits only */ scd.regs[0x03>>1].byte.l = (scd.regs[0x02>>1].byte.l & ~0xc0) | (data & 0xc0); return; } case 0x0e: /* MAIN-CPU communication flags */ case 0x0f: /* !LWR is ignored (Space Ace, Dragon's Lair) */ { m68k_poll_sync(1<<0x0e); scd.regs[0x0e>>1].byte.h = data; return; } default: { /* MAIN-CPU communication words */ if ((address & 0x30) == 0x10) { m68k_poll_sync(1 << (address & 0x1f)); /* register LSB */ if (address & 1) { scd.regs[(address >> 1) & 0xff].byte.l = data; return; } /* register MSB */ scd.regs[(address >> 1) & 0xff].byte.h = data; return; } /* invalid address */ m68k_unused_8_w(address, data); return; } } } m68k_unused_8_w(address, data); return; } case 0x30: /* TIME */ { cart.hw.time_w(address, data); return; } case 0x41: /* BOOT ROM */ { if ((config.bios & 1) && (address & 1)) { gen_bankswitch_w(data & 1); return; } m68k_unused_8_w(address, data); return; } case 0x10: /* MEMORY MODE */ case 0x13: /* unknown */ case 0x40: /* TMSS */ case 0x44: /* RADICA */ case 0x50: /* SVP */ { m68k_unused_8_w(address, data); return; } default: /* Invalid address */ { m68k_lockup_w_8(address, data); return; } } } void ctrl_io_write_word(unsigned int address, unsigned int data) { switch ((address >> 8) & 0xFF) { case 0x00: /* I/O chip */ { if (!(address & 0xE0)) { io_68k_write((address >> 1) & 0x0F, data & 0xFF); return; } m68k_unused_16_w(address, data); return; } case 0x11: /* Z80 BUSREQ */ { gen_zbusreq_w((data >> 8) & 1, m68k.cycles); return; } case 0x12: /* Z80 RESET */ { gen_zreset_w((data >> 8) & 1, m68k.cycles); return; } case 0x20: /* MEGA-CD */ { #ifdef LOG_SCD error("[%d][%d]write word CD register %X -> 0x%04X (%X)\n", v_counter, m68k.cycles, address, data, m68k.pc); #endif if (system_hw == SYSTEM_MCD) { /* register index ($A12000-A1203F mirrored up to $A120FF) */ switch (address & 0x3e) { case 0x00: /* SUB-CPU interrupt & control */ { unsigned int halted = s68k.stopped; /* RESET bit */ if (data & 0x01) { /* SUB-CPU reset is triggered on /RESET input 0->1 transition */ if (!(scd.regs[0x00].byte.l & 0x01)) { s68k_pulse_reset(); } /* BUSREQ bit */ if (data & 0x02) { /* SUB-CPU is halted (/HALT input is asserted) */ s68k_pulse_halt(); } else { /* SUB-CPU is running (/HALT input is released) */ s68k_clear_halt(); } /* update BUSREQ and RESET bits */ scd.regs[0x00].byte.l = data & 0x03; } else { /* SUB-CPU is halted (/HALT and /RESET inputs are asserted) */ s68k_pulse_halt(); /* RESET bit is cleared and BUSREQ bit is set to 1 (verified on real hardware) */ scd.regs[0x00].byte.l = 0x02; } /* check if SUB-CPU halt status has changed */ if (s68k.stopped != halted) { /* PRG-RAM (128KB bank) is normally mapped to $020000-$03FFFF (resp. $420000-$43FFFF) */ unsigned int base = scd.cartridge.boot + 0x02; /* BUSREQ bit remains set to 0 if SUB-CPU is halted while stopped (verified on real hardware) */ if (s68k.stopped & 0x01) { scd.regs[0x00].byte.l &= ~0x02; } /* PRG-RAM can only be accessed from MAIN-CPU & Z80 when BUSREQ bit is set (Dungeon Explorer USA version) */ if (scd.regs[0x00].byte.l & 0x02) { m68k.memory_map[base].read8 = m68k.memory_map[base+1].read8 = NULL; m68k.memory_map[base].read16 = m68k.memory_map[base+1].read16 = NULL; m68k.memory_map[base].write8 = m68k.memory_map[base+1].write8 = NULL; m68k.memory_map[base].write16 = m68k.memory_map[base+1].write16 = NULL; zbank_memory_map[base].read = zbank_memory_map[base+1].read = NULL; zbank_memory_map[base].write = zbank_memory_map[base+1].write = NULL; } else { m68k.memory_map[base].read8 = m68k.memory_map[base+1].read8 = m68k_read_bus_8; m68k.memory_map[base].read16 = m68k.memory_map[base+1].read16 = m68k_read_bus_16; m68k.memory_map[base].write8 = m68k.memory_map[base+1].write8 = m68k_unused_8_w; m68k.memory_map[base].write16 = m68k.memory_map[base+1].write16 = m68k_unused_16_w; zbank_memory_map[base].read = zbank_memory_map[base+1].read = zbank_unused_r; zbank_memory_map[base].write = zbank_memory_map[base+1].write = zbank_unused_w; } } /* IFL2 bit */ if (data & 0x100) { /* level 2 interrupt enabled ? */ if (scd.regs[0x32>>1].byte.l & 0x04) { /* set IFL2 flag */ scd.regs[0x00].byte.h |= 0x01; /* trigger level 2 interrupt */ scd.pending |= (1 << 2); /* update IRQ level */ s68k_update_irq((scd.pending & scd.regs[0x32>>1].byte.l) >> 1); } } return; } case 0x02: /* Memory Mode */ { m68k_poll_sync(1<<0x03); /* PRG-RAM 128k bank mapped to $020000-$03FFFF (resp. $420000-$43FFFF) */ m68k.memory_map[scd.cartridge.boot + 0x02].base = scd.prg_ram + ((data & 0xc0) << 11); m68k.memory_map[scd.cartridge.boot + 0x03].base = m68k.memory_map[scd.cartridge.boot + 0x02].base + 0x10000; /* check current mode */ if (scd.regs[0x03>>1].byte.l & 0x04) { /* DMNA bit */ if (data & 0x02) { /* writing 1 to DMNA in 1M mode will return Word-RAM to SUB-CPU in 2M mode */ scd.dmna = 1; } else { /* writing 0 to DMNA in 1M mode actually sets DMNA bit */ data |= 0x02; /* update WP0-7, BK0-1 & DMNA bits */ scd.regs[0x02>>1].w = (scd.regs[0x02>>1].w & ~0xffc2) | (data & 0xffc2); return; } } else { /* writing 0 to DMNA in 2M mode does nothing */ if (data & 0x02) { /* Word-RAM is assigned to SUB-CPU */ scd.dmna = 1; /* clear RET bit and update WP0-7 & BK0-1 bits */ scd.regs[0x02>>1].w = (scd.regs[0x02>>1].w & ~0xffc3) | (data & 0xffc2); /* check if graphics operation is running */ if (scd.regs[0x58>>1].byte.h & 0x80) { /* relative SUB-CPU cycle counter */ unsigned int cycles = (m68k.cycles * SCYCLES_PER_LINE) / MCYCLES_PER_LINE; /* synchronize GFX processing with SUB-CPU (only if not already ahead) */ if (gfx.cycles < cycles) { gfx.cycles = cycles; } } return; } } /* update WP0-7 & BK0-1 bits only */ scd.regs[0x02>>1].w = (scd.regs[0x02>>1].w & ~0xffc0) | (data & 0xffc0); return; } case 0x06: /* H-INT vector (word access only ?) */ { *(uint16 *)(m68k.memory_map[scd.cartridge.boot].base + 0x72) = data; return; } case 0x0e: /* CPU communication flags */ { m68k_poll_sync(1<<0x0e); /* D8-D15 ignored -> only MAIN-CPU flags are updated (Mortal Kombat) */ scd.regs[0x0e>>1].byte.h = data & 0xff; return; } default: { /* MAIN-CPU communication words */ if ((address & 0x30) == 0x10) { m68k_poll_sync(3 << (address & 0x1e)); scd.regs[(address >> 1) & 0xff].w = data; return; } /* invalid address */ m68k_unused_16_w (address, data); return; } } } m68k_unused_16_w (address, data); return; } case 0x30: /* TIME */ { cart.hw.time_w(address, data); return; } case 0x40: /* TMSS */ { if (config.bios & 1) { gen_tmss_w(address & 3, data); return; } m68k_unused_16_w(address, data); return; } case 0x50: /* SVP */ { if (!(address & 0xFD)) { svp->ssp1601.gr[SSP_XST].byte.h = data; svp->ssp1601.gr[SSP_PM0].byte.h |= 2; svp->ssp1601.emu_status &= ~SSP_WAIT_PM0; return; } m68k_unused_16_w(address, data); return; } case 0x10: /* MEMORY MODE */ case 0x13: /* unknown */ case 0x41: /* BOOT ROM */ case 0x44: /* RADICA */ { m68k_unused_16_w (address, data); return; } default: /* Invalid address */ { m68k_lockup_w_16 (address, data); return; } } } /*--------------------------------------------------------------------------*/ /* VDP */ /*--------------------------------------------------------------------------*/ unsigned int vdp_read_byte(unsigned int address) { switch (address & 0xFD) { case 0x00: /* DATA */ { return (vdp_68k_data_r() >> 8); } case 0x01: /* DATA */ { return (vdp_68k_data_r() & 0xFF); } case 0x04: /* CTRL */ { unsigned int data = (vdp_68k_ctrl_r(m68k.cycles) >> 8) & 3; /* Unused bits return prefetched bus data */ address = m68k.pc; data |= (READ_BYTE(m68k.memory_map[((address)>>16)&0xff].base, (address) & 0xffff) & 0xFC); return data; } case 0x05: /* CTRL */ { return (vdp_68k_ctrl_r(m68k.cycles) & 0xFF); } case 0x08: /* HVC */ case 0x0C: { return (vdp_hvc_r(m68k.cycles) >> 8); } case 0x09: /* HVC */ case 0x0D: { return (vdp_hvc_r(m68k.cycles) & 0xFF); } case 0x18: /* Unused */ case 0x19: case 0x1C: case 0x1D: { return m68k_read_bus_8(address); } default: /* Invalid address */ { return m68k_lockup_r_8(address); } } } unsigned int vdp_read_word(unsigned int address) { switch (address & 0xFC) { case 0x00: /* DATA */ { return vdp_68k_data_r(); } case 0x04: /* CTRL */ { unsigned int data = vdp_68k_ctrl_r(m68k.cycles) & 0x3FF; /* Unused bits return prefetched bus data */ address = m68k.pc; data |= (*(uint16 *)(m68k.memory_map[((address)>>16)&0xff].base + ((address) & 0xffff)) & 0xFC00); return data; } case 0x08: /* HVC */ case 0x0C: { return vdp_hvc_r(m68k.cycles); } case 0x18: /* Unused */ case 0x1C: { return m68k_read_bus_16(address); } default: /* Invalid address */ { return m68k_lockup_r_16(address); } } } void vdp_write_byte(unsigned int address, unsigned int data) { switch (address & 0xFC) { case 0x00: /* Data port */ { vdp_68k_data_w(data << 8 | data); return; } case 0x04: /* Control port */ { vdp_68k_ctrl_w(data << 8 | data); return; } case 0x10: /* PSG */ case 0x14: { if (address & 1) { psg_write(m68k.cycles, data); return; } m68k_unused_8_w(address, data); return; } case 0x18: /* Unused */ { m68k_unused_8_w(address, data); return; } case 0x1C: /* TEST register */ { vdp_test_w(data << 8 | data); return; } default: /* Invalid address */ { m68k_lockup_w_8(address, data); return; } } } void vdp_write_word(unsigned int address, unsigned int data) { switch (address & 0xFC) { case 0x00: /* DATA */ { vdp_68k_data_w(data); return; } case 0x04: /* CTRL */ { vdp_68k_ctrl_w(data); return; } case 0x10: /* PSG */ case 0x14: { psg_write(m68k.cycles, data & 0xFF); return; } case 0x18: /* Unused */ { m68k_unused_16_w(address, data); return; } case 0x1C: /* Test register */ { vdp_test_w(data); return; } default: /* Invalid address */ { m68k_lockup_w_16 (address, data); return; } } } /*--------------------------------------------------------------------------*/ /* PICO (incomplete) */ /*--------------------------------------------------------------------------*/ unsigned int pico_read_byte(unsigned int address) { switch (address & 0xFF) { case 0x01: /* VERSION register */ { return (region_code >> 1); } case 0x03: /* IO register */ { return ~input.pad[0]; } case 0x05: /* PEN X coordinate (MSB) */ { return (input.analog[0][0] >> 8); } case 0x07: /* PEN X coordinate (LSB) */ { return (input.analog[0][0] & 0xFF); } case 0x09: /* PEN Y coordinate (MSB) */ { return (input.analog[0][1] >> 8); } case 0x0B: /* PEN Y coordinate (LSB) */ { return (input.analog[0][1] & 0xFF); } case 0x0D: /* PAGE register */ { return (1 << pico_current) - 1; } case 0x10: /* ADPCM data registers (TODO) */ case 0x11: { return 0xff; } case 0x12: /* ADPCM control registers (TODO) */ { return 0x80; } default: { return m68k_read_bus_8(address); } } } unsigned int pico_read_word(unsigned int address) { return (pico_read_byte(address | 1) | (pico_read_byte(address) << 8)); }