/*************************************************************************************** * Genesis Plus * Mega CD / Sega CD hardware * * Copyright (C) 2012-2019 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 area (return open bus data, i.e prefetched instruction word) */ /*--------------------------------------------------------------------------*/ static unsigned int s68k_read_bus_8(unsigned int address) { #ifdef LOGERROR error("[SUB 68k] Unused read8 %08X (%08X)\n", address, s68k.pc); #endif address = s68k.pc | (address & 1); return READ_BYTE(s68k.memory_map[((address)>>16)&0xff].base, (address) & 0xffff); } static unsigned int s68k_read_bus_16(unsigned int address) { #ifdef LOGERROR error("[SUB 68k] Unused read16 %08X (%08X)\n", address, s68k.pc); #endif address = s68k.pc; return *(uint16 *)(s68k.memory_map[((address)>>16)&0xff].base + ((address) & 0xffff)); } static void s68k_unused_8_w(unsigned int address, unsigned int data) { #ifdef LOGERROR error("[SUB 68k] Unused write8 %08X = %02X (%08X)\n", address, data, s68k.pc); #endif } static void s68k_unused_16_w(unsigned int address, unsigned int data) { #ifdef LOGERROR error("[SUB 68k] Unused write16 %08X = %04X (%08X)\n", address, data, s68k.pc); #endif } /*--------------------------------------------------------------------------*/ /* PRG-RAM DMA access */ /*--------------------------------------------------------------------------*/ void prg_ram_dma_w(unsigned int words) { uint16 data; /* CDC buffer source address */ uint16 src_index = cdc.dac.w & 0x3ffe; /* PRG-RAM destination address*/ uint32 dst_index = (scd.regs[0x0a>>1].w << 3) & 0x7fffe; /* update DMA destination address */ scd.regs[0x0a>>1].w += (words >> 2); /* update DMA source address */ cdc.dac.w += (words << 1); /* check PRG-RAM write protected area */ if (dst_index < (scd.regs[0x02>>1].byte.h << 9)) { return; } /* DMA transfer */ while (words--) { /* read 16-bit word from CDC RAM buffer (big-endian format) */ data = READ_WORD(cdc.ram, src_index); /* write 16-bit word to PRG-RAM */ *(uint16 *)(scd.prg_ram + dst_index) = data ; /* increment CDC buffer source address */ src_index = (src_index + 2) & 0x3ffe; /* increment PRG-RAM destination address */ dst_index = (dst_index + 2) & 0x7fffe; } } /*--------------------------------------------------------------------------*/ /* PRG-RAM write protected area */ /*--------------------------------------------------------------------------*/ static void prg_ram_write_byte(unsigned int address, unsigned int data) { address &= 0x7ffff; if (address >= (scd.regs[0x02>>1].byte.h << 9)) { WRITE_BYTE(scd.prg_ram, address, data); return; } #ifdef LOGERROR error("[SUB 68k] PRG-RAM protected write8 %08X = %02X (%08X)\n", address, data, s68k.pc); #endif } static void prg_ram_write_word(unsigned int address, unsigned int data) { address &= 0x7fffe; if (address >= (scd.regs[0x02>>1].byte.h << 9)) { *(uint16 *)(scd.prg_ram + address) = data; return; } #ifdef LOGERROR error("[SUB 68k] PRG-RAM protected write16 %08X = %02X (%08X)\n", address, data, s68k.pc); #endif } /*--------------------------------------------------------------------------*/ /* PRG-RAM bank mirrored access */ /*--------------------------------------------------------------------------*/ static unsigned int prg_ram_z80_read_byte(unsigned int address) { int offset = (address >> 16) & 0x03; if (zbank_memory_map[offset].read) { return zbank_memory_map[offset].read(address); } return READ_BYTE(m68k.memory_map[offset].base, address & 0xffff); } static void prg_ram_z80_write_byte(unsigned int address, unsigned int data) { int offset = (address >> 16) & 0x03; if (zbank_memory_map[offset].write) { zbank_memory_map[offset].write(address, data); } else { WRITE_BYTE(m68k.memory_map[offset].base, address & 0xffff, data); } } static unsigned int prg_ram_m68k_read_byte(unsigned int address) { int offset = (address >> 16) & 0x03; if (m68k.memory_map[offset].read8) { return m68k.memory_map[offset].read8(address); } return READ_BYTE(m68k.memory_map[offset].base, address & 0xffff); } static unsigned int prg_ram_m68k_read_word(unsigned int address) { int offset = (address >> 16) & 0x03; if (m68k.memory_map[offset].read16) { return m68k.memory_map[offset].read16(address); } return *(uint16 *)(m68k.memory_map[offset].base + (address & 0xffff)); } static void prg_ram_m68k_write_byte(unsigned int address, unsigned int data) { int offset = (address >> 16) & 0x03; if (m68k.memory_map[offset].write8) { m68k.memory_map[offset].write8(address, data); } else { WRITE_BYTE(m68k.memory_map[offset].base, address & 0xffff, data); } } static void prg_ram_m68k_write_word(unsigned int address, unsigned int data) { int offset = (address >> 16) & 0x03; if (m68k.memory_map[offset].write16) { m68k.memory_map[offset].write16(address, data); } else { *(uint16 *)(m68k.memory_map[offset].base + (address & 0xffff)) = data; } } /*--------------------------------------------------------------------------*/ /* Word-RAM bank mirrored access */ /*--------------------------------------------------------------------------*/ static unsigned int word_ram_z80_read_byte(unsigned int address) { int offset = (address >> 16) & 0x23; if (zbank_memory_map[offset].read) { return zbank_memory_map[offset].read(address); } return READ_BYTE(m68k.memory_map[offset].base, address & 0xffff); } static void word_ram_z80_write_byte(unsigned int address, unsigned int data) { int offset = (address >> 16) & 0x23; if (zbank_memory_map[offset].write) { zbank_memory_map[offset].write(address, data); } else { *(uint16 *)(m68k.memory_map[offset].base + (address & 0xfffe)) = data | (data << 8); } } static unsigned int word_ram_m68k_read_byte(unsigned int address) { int offset = (address >> 16) & 0x23; if (m68k.memory_map[offset].read8) { return m68k.memory_map[offset].read8(address); } return READ_BYTE(m68k.memory_map[offset].base, address & 0xffff); } static unsigned int word_ram_m68k_read_word(unsigned int address) { int offset = (address >> 16) & 0x23; if (m68k.memory_map[offset].read16) { return m68k.memory_map[offset].read16(address); } return *(uint16 *)(m68k.memory_map[offset].base + (address & 0xffff)); } static void word_ram_m68k_write_byte(unsigned int address, unsigned int data) { int offset = (address >> 16) & 0x23; if (m68k.memory_map[offset].write8) { m68k.memory_map[offset].write8(address, data); } else { *(uint16 *)(m68k.memory_map[offset].base + (address & 0xfffe)) = data | (data << 8); } } static void word_ram_m68k_write_word(unsigned int address, unsigned int data) { int offset = (address >> 16) & 0x23; if (m68k.memory_map[offset].write16) { m68k.memory_map[offset].write16(address, data); } else { *(uint16 *)(m68k.memory_map[offset].base + (address & 0xffff)) = data; } } static unsigned int word_ram_s68k_read_byte(unsigned int address) { int offset = (address >> 16) & 0x0f; if (s68k.memory_map[offset].read8) { return s68k.memory_map[offset].read8(address); } return READ_BYTE(s68k.memory_map[offset].base, address & 0xffff); } static unsigned int word_ram_s68k_read_word(unsigned int address) { int offset = (address >> 16) & 0x0f; if (s68k.memory_map[offset].read16) { return s68k.memory_map[offset].read16(address); } return *(uint16 *)(s68k.memory_map[offset].base + (address & 0xffff)); } static void word_ram_s68k_write_byte(unsigned int address, unsigned int data) { int offset = (address >> 16) & 0x0f; if (s68k.memory_map[offset].write8) { s68k.memory_map[offset].write8(address, data); } else { *(uint16 *)(s68k.memory_map[offset].base + (address & 0xfffe)) = data | (data << 8); } } static void word_ram_s68k_write_word(unsigned int address, unsigned int data) { int offset = (address >> 16) & 0x0f; if (s68k.memory_map[offset].write16) { s68k.memory_map[offset].write16(address, data); } else { *(uint16 *)(s68k.memory_map[offset].base + (address & 0xffff)) = data; } } /*--------------------------------------------------------------------------*/ /* internal backup RAM (8KB) */ /*--------------------------------------------------------------------------*/ static unsigned int bram_read_byte(unsigned int address) { /* LSB only */ if (address & 0x01) { return scd.bram[(address >> 1) & 0x1fff]; } return 0xff; } static unsigned int bram_read_word(unsigned int address) { return (scd.bram[(address >> 1) & 0x1fff] | 0xff00); } static void bram_write_byte(unsigned int address, unsigned int data) { /* LSB only */ if (address & 0x01) { scd.bram[(address >> 1) & 0x1fff] = data; } } static void bram_write_word(unsigned int address, unsigned int data) { scd.bram[(address >> 1) & 0x1fff] = data & 0xff; } /*--------------------------------------------------------------------------*/ /* SUB-CPU polling detection and MAIN-CPU synchronization */ /*--------------------------------------------------------------------------*/ static void s68k_poll_detect(unsigned int reg_mask) { /* detect SUB-CPU register polling */ if (s68k.poll.detected & reg_mask) { if (s68k.cycles <= s68k.poll.cycle) { if (s68k.pc == s68k.poll.pc) { /* SUB-CPU polling confirmed ? */ if (s68k.poll.detected & 1) { /* idle SUB-CPU until register is modified */ s68k.cycles = s68k.cycle_end; s68k.stopped = reg_mask; #ifdef LOG_SCD error("s68k stopped from %d cycles\n", s68k.cycles); #endif } else { /* confirm SUB-CPU polling */ s68k.poll.detected |= 1; s68k.poll.cycle = s68k.cycles + 392; } } return; } } else { /* set SUB-CPU register access flag */ s68k.poll.detected = reg_mask; } /* reset SUB-CPU polling detection */ s68k.poll.cycle = s68k.cycles + 392; s68k.poll.pc = s68k.pc; } static void s68k_poll_sync(unsigned int reg_mask) { /* relative MAIN-CPU cycle counter */ unsigned int cycles = (s68k.cycles * MCYCLES_PER_LINE) / SCYCLES_PER_LINE; if (!m68k.stopped) { /* save current MAIN-CPU end cycle count (recursive execution is possible) */ int end_cycle = m68k.cycle_end; /* sync MAIN-CPU with SUB-CPU */ m68k_run(cycles); /* restore MAIN-CPU end cycle count */ m68k.cycle_end = end_cycle; } /* MAIN-CPU idle on register polling ? */ if (m68k.stopped & reg_mask) { /* sync MAIN-CPU with SUB-CPU */ m68k.cycles = cycles; /* restart MAIN-CPU */ m68k.stopped = 0; #ifdef LOG_SCD error("m68k started from %d cycles\n", cycles); #endif } /* clear CPU register access flags */ s68k.poll.detected &= ~reg_mask; m68k.poll.detected &= ~reg_mask; } /*--------------------------------------------------------------------------*/ /* PCM chip & Gate-Array area */ /*--------------------------------------------------------------------------*/ static unsigned int scd_read_byte(unsigned int address) { /* PCM area (8K) mirrored into $xF0000-$xF7FFF */ if (!(address & 0x8000)) { /* get /LDS only */ if (address & 1) { return pcm_read((address >> 1) & 0x1fff); } return s68k_read_bus_8(address); } #ifdef LOG_SCD error("[%d][%d]read byte CD register %X (%X)\n", v_counter, s68k.cycles, address, s68k.pc); #endif /* only A1-A8 are used for decoding */ address &= 0x1ff; /* Memory Mode */ if (address == 0x03) { s68k_poll_detect(1<<0x03); return scd.regs[0x03>>1].byte.l; } /* MAIN-CPU communication flags */ if (address == 0x0e) { s68k_poll_detect(1<<0x0e); return scd.regs[0x0e>>1].byte.h; } /* CDC transfer status */ if (address == 0x04) { s68k_poll_detect(1<<0x04); return scd.regs[0x04>>1].byte.h; } /* GFX operation status */ if (address == 0x58) { s68k_poll_detect(1<<0x08); return scd.regs[0x58>>1].byte.h; } /* CDC register data (controlled by BIOS, byte access only ?) */ if (address == 0x07) { unsigned int data = cdc_reg_r(); #ifdef LOG_CDC error("CDC register %X read 0x%02X (%X)\n", scd.regs[0x04>>1].byte.l & 0x0F, data, s68k.pc); #endif return data; } /* LED status */ if (address == 0x00) { /* register $00 is reserved for MAIN-CPU, we use $06 instead */ return scd.regs[0x06>>1].byte.h; } /* RESET status */ if (address == 0x01) { /* always return 1 */ return 0x01; } /* Font data */ if ((address >= 0x50) && (address <= 0x56)) { /* shifted 4-bit input (xxxx00) */ uint8 bits = (scd.regs[0x4e>>1].w >> (((address & 6) ^ 6) << 1)) << 2; /* color code */ uint8 code = scd.regs[0x4c>>1].byte.l; /* 16-bit font data (4 pixels = 16 bits) */ uint16 data = (code >> (bits & 4)) & 0x0f; bits = bits >> 1; data = data | (((code >> (bits & 4)) << 4) & 0xf0); bits = bits >> 1; data = data | (((code >> (bits & 4)) << 8) & 0xf00); bits = bits >> 1; data = data | (((code >> (bits & 4)) << 12) & 0xf000); return (address & 1) ? (data & 0xff) : (data >> 8); } /* MAIN-CPU communication words */ if ((address & 0x1f0) == 0x10) { s68k_poll_detect(1 << (address & 0x1f)); } /* Subcode buffer */ else if (address & 0x100) { /* 64 x 16-bit mirrored */ address &= 0x17f; } /* default registers */ if (address & 1) { /* register LSB */ return scd.regs[address >> 1].byte.l; } /* register MSB */ return scd.regs[address >> 1].byte.h; } static unsigned int scd_read_word(unsigned int address) { /* PCM area (8K) mirrored into $xF0000-$xF7FFF */ if (!(address & 0x8000)) { /* get /LDS only */ return pcm_read((address >> 1) & 0x1fff); } #ifdef LOG_SCD error("[%d][%d]read word CD register %X (%X)\n", v_counter, s68k.cycles, address, s68k.pc); #endif /* only A1-A8 are used for decoding */ address &= 0x1ff; /* Memory Mode */ if (address == 0x02) { s68k_poll_detect(1<<0x03); return scd.regs[0x03>>1].w; } /* CDC host data (word access only ?) */ if (address == 0x08) { return cdc_host_r(); } /* LED & RESET status */ if (address == 0x00) { /* register $00 is reserved for MAIN-CPU, we use $06 instead */ return scd.regs[0x06>>1].w; } /* Stopwatch counter (word access only ?) */ if (address == 0x0c) { /* cycle-accurate counter value */ return (scd.regs[0x0c>>1].w + ((s68k.cycles - scd.stopwatch) / TIMERS_SCYCLES_RATIO)) & 0xfff; } /* Font data */ if ((address >= 0x50) && (address <= 0x56)) { /* shifted 4-bit input (xxxx00) */ uint8 bits = (scd.regs[0x4e>>1].w >> (((address & 6) ^ 6) << 1)) << 2; /* color code */ uint8 code = scd.regs[0x4c>>1].byte.l; /* 16-bit font data (4 pixels = 16 bits) */ uint16 data = (code >> (bits & 4)) & 0x0f; bits = bits >> 1; data = data | (((code >> (bits & 4)) << 4) & 0xf0); bits = bits >> 1; data = data | (((code >> (bits & 4)) << 8) & 0xf00); bits = bits >> 1; data = data | (((code >> (bits & 4)) << 12) & 0xf000); return data; } /* MAIN-CPU communication words */ if ((address & 0x1f0) == 0x10) { if (!m68k.stopped) { /* relative MAIN-CPU cycle counter */ unsigned int cycles = (s68k.cycles * MCYCLES_PER_LINE) / SCYCLES_PER_LINE; /* save current MAIN-CPU end cycle count (recursive execution is possible) */ int end_cycle = m68k.cycle_end; /* sync MAIN-CPU with SUB-CPU (Mighty Morphin Power Rangers) */ m68k_run(cycles); /* restore MAIN-CPU end cycle count */ m68k.cycle_end = end_cycle; } s68k_poll_detect(3 << (address & 0x1e)); } /* Subcode buffer */ else if (address & 0x100) { /* 64 x 16-bit mirrored */ address &= 0x17f; } /* default registers */ return scd.regs[address >> 1].w; } INLINE void word_ram_switch(uint8 mode) { int i; uint16 *ptr1 = (uint16 *)(scd.word_ram_2M); uint16 *ptr2 = (uint16 *)(scd.word_ram[0]); uint16 *ptr3 = (uint16 *)(scd.word_ram[1]); if (mode & 0x04) { /* 2M -> 1M mode */ for (i=0; i<0x10000; i++) { *ptr2++=*ptr1++; *ptr3++=*ptr1++; } } else { /* 1M -> 2M mode */ for (i=0; i<0x10000; i++) { *ptr1++=*ptr2++; *ptr1++=*ptr3++; } /* MAIN-CPU: $200000-$21FFFF is mapped to 256K Word-RAM (lower 128K) */ for (i=scd.cartridge.boot+0x20; i> 1) & 0x1fff, data); return; } s68k_unused_8_w(address, data); return; } #ifdef LOG_SCD error("[%d][%d]write byte CD register %X -> 0x%02x (%X)\n", v_counter, s68k.cycles, address, data, s68k.pc); #endif /* Gate-Array registers */ switch (address & 0x1ff) { case 0x00: /* LED status */ { /* register $00 is reserved for MAIN-CPU, use $06 instead */ scd.regs[0x06 >> 1].byte.h = data; return; } case 0x01: /* RESET status */ { /* RESET bit cleared ? */ if (!(data & 0x01)) { /* reset CD hardware */ scd_reset(0); } return; } case 0x03: /* Memory Mode */ { s68k_poll_sync(1<<0x03); /* detect MODE & RET bits modifications */ if ((data ^ scd.regs[0x03 >> 1].byte.l) & 0x05) { int i; /* MODE bit */ if (data & 0x04) { /* 2M->1M mode switch */ if (!(scd.regs[0x03 >> 1].byte.l & 0x04)) { /* re-arrange Word-RAM banks */ word_ram_switch(0x04); } /* RET bit in 1M Mode */ if (data & 0x01) { /* Word-RAM 1 assigned to MAIN-CPU */ for (i=scd.cartridge.boot+0x20; i> 1].byte.l = (scd.regs[0x02 >> 1].byte.l & ~0x1f) | (data & 0x1d); return; } else { /* 1M->2M mode switch */ if (scd.regs[0x02 >> 1].byte.l & 0x04) { /* re-arrange Word-RAM banks */ word_ram_switch(0x00); /* RET bit set during 1M mode ? */ data |= ~scd.dmna & 0x01; /* check if RET bit is cleared */ if (!(data & 0x01)) { /* set DMNA bit */ data |= 0x02; /* mask BK0-1 bits (MAIN-CPU side only) */ scd.regs[0x02 >> 1].byte.l = (scd.regs[0x02 >> 1].byte.l & ~0x1f) | (data & 0x1f); return; } } /* RET bit set in 2M mode */ if (data & 0x01) { /* Word-RAM is returned to MAIN-CPU */ scd.dmna = 0; /* clear DMNA bit */ scd.regs[0x02 >> 1].byte.l = (scd.regs[0x02 >> 1].byte.l & ~0x1f) | (data & 0x1d); return; } } } /* update PM0-1 & MODE bits */ scd.regs[0x02 >> 1].byte.l = (scd.regs[0x02 >> 1].byte.l & ~0x1c) | (data & 0x1c); return; } case 0x07: /* CDC register write */ { cdc_reg_w(data); return; } case 0x0e: /* SUB-CPU communication flags */ case 0x0f: /* !LWR is ignored (Space Ace, Dragon's Lair) */ { s68k_poll_sync(1<<0x0f); scd.regs[0x0f>>1].byte.l = data; return; } case 0x31: /* Timer */ { /* reload timer (one timer clock = 384 CPU cycles) */ scd.timer = data * TIMERS_SCYCLES_RATIO; /* only non-zero data starts timer, writing zero stops it */ if (data) { /* adjust regarding current CPU cycle */ scd.timer += (s68k.cycles - scd.cycles); } scd.regs[0x30>>1].byte.l = data; return; } case 0x33: /* Interrupts */ { /* update register value before updating interrupts */ scd.regs[0x32>>1].byte.l = data; /* update IEN2 flag */ scd.regs[0x00].byte.h = (scd.regs[0x00].byte.h & 0x7f) | ((data & 0x04) << 5); /* clear level 1 interrupt if disabled ("Batman Returns" option menu) */ scd.pending &= 0xfd | (data & 0x02); /* update IRQ level */ s68k_update_irq((scd.pending & data) >> 1); return; } case 0x37: /* CDD control (controlled by BIOS, byte access only ?) */ { /* CDD communication started ? */ if ((data & 0x04) && !(scd.regs[0x37>>1].byte.l & 0x04)) { /* reset CDD cycle counter */ cdd.cycles = (scd.cycles - s68k.cycles) * 3; /* set pending interrupt level 4 */ scd.pending |= (1 << 4); /* update IRQ level if interrupt is enabled */ if (scd.regs[0x32>>1].byte.l & 0x10) { s68k_update_irq((scd.pending & scd.regs[0x32>>1].byte.l) >> 1); } } scd.regs[0x37>>1].byte.l = data; return; } default: { /* SUB-CPU communication words */ if ((address & 0x1f0) == 0x20) { s68k_poll_sync(1 << ((address - 0x10) & 0x1f)); } /* MAIN-CPU communication words */ else if ((address & 0x1f0) == 0x10) { /* read-only (Sega Classic Arcade Collection) */ return; } /* default registers */ if (address & 1) { /* register LSB */ scd.regs[(address >> 1) & 0xff].byte.l = data; return; } /* register MSB */ scd.regs[(address >> 1) & 0xff].byte.h = data; return; } } } static void scd_write_word(unsigned int address, unsigned int data) { /* PCM area (8K) mirrored into $xF0000-$xF7FFF */ if (!(address & 0x8000)) { /* get /LDS only */ pcm_write((address >> 1) & 0x1fff, data); return; } #ifdef LOG_SCD error("[%d][%d]write word CD register %X -> 0x%04x (%X)\n", v_counter, s68k.cycles, address, data, s68k.pc); #endif /* Gate-Array registers */ switch (address & 0x1fe) { case 0x00: /* LED status & RESET */ { /* only update LED status (register $00 is reserved for MAIN-CPU, use $06 instead) */ scd.regs[0x06>>1].byte.h = data >> 8; /* RESET bit cleared ? */ if (!(data & 0x01)) { /* reset CD hardware */ scd_reset(0); } return; } case 0x02: /* Memory Mode */ { s68k_poll_sync(1<<0x03); /* detect MODE & RET bits modifications */ if ((data ^ scd.regs[0x03>>1].byte.l) & 0x05) { int i; /* MODE bit */ if (data & 0x04) { /* 2M->1M mode switch */ if (!(scd.regs[0x03 >> 1].byte.l & 0x04)) { /* re-arrange Word-RAM banks */ word_ram_switch(0x04); } /* RET bit in 1M Mode */ if (data & 0x01) { /* Word-RAM 1 assigned to MAIN-CPU */ for (i=scd.cartridge.boot+0x20; i>1].byte.l = (scd.regs[0x03>>1].byte.l & ~0x1f) | (data & 0x1d); return; } else { /* 1M->2M mode switch */ if (scd.regs[0x03>>1].byte.l & 0x04) { /* re-arrange Word-RAM banks */ word_ram_switch(0x00); /* RET bit set during 1M mode ? */ data |= ~scd.dmna & 0x01; /* check if RET bit is cleared */ if (!(data & 0x01)) { /* set DMNA bit */ data |= 0x02; /* mask BK0-1 bits (MAIN-CPU side only) */ scd.regs[0x03>>1].byte.l = (scd.regs[0x03>>1].byte.l & ~0x1f) | (data & 0x1f); return; } } /* RET bit set in 2M mode */ if (data & 0x01) { /* Word-RAM is returned to MAIN-CPU */ scd.dmna = 0; /* clear DMNA bit */ scd.regs[0x03>>1].byte.l = (scd.regs[0x03>>1].byte.l & ~0x1f) | (data & 0x1d); return; } } } /* update PM0-1 & MODE bits */ scd.regs[0x03>>1].byte.l = (scd.regs[0x03>>1].byte.l & ~0x1c) | (data & 0x1c); return; } case 0x06: /* CDC register write */ { cdc_reg_w(data); return; } case 0x0c: /* Stopwatch (word access only) */ { /* synchronize the counter with SUB-CPU */ int ticks = (s68k.cycles - scd.stopwatch) / TIMERS_SCYCLES_RATIO; scd.stopwatch += (ticks * TIMERS_SCYCLES_RATIO); /* any writes clear the counter */ scd.regs[0x0c>>1].w = 0; return; } case 0x0e: /* CPU Communication flags */ { s68k_poll_sync(1<<0x0f); /* D8-D15 ignored -> only SUB-CPU flags are updated */ scd.regs[0x0f>>1].byte.l = data & 0xff; return; } case 0x30: /* Timer */ { /* LSB only */ data &= 0xff; /* reload timer (one timer clock = 384 CPU cycles) */ scd.timer = data * TIMERS_SCYCLES_RATIO; /* only non-zero data starts timer, writing zero stops it */ if (data) { /* adjust regarding current CPU cycle */ scd.timer += (s68k.cycles - scd.cycles); } scd.regs[0x30>>1].byte.l = data; return; } case 0x32: /* Interrupts */ { /* LSB only */ data &= 0xff; /* update register value before updating interrupts */ scd.regs[0x32>>1].byte.l = data; /* update IEN2 flag */ scd.regs[0x00].byte.h = (scd.regs[0x00].byte.h & 0x7f) | ((data & 0x04) << 5); /* clear pending level 1 interrupt if disabled ("Batman Returns" option menu) */ scd.pending &= 0xfd | (data & 0x02); /* update IRQ level */ s68k_update_irq((scd.pending & data) >> 1); return; } case 0x34: /* CD Fader */ { /* Wondermega hardware (CXD2554M digital filter) */ if (cdd.type == CD_TYPE_WONDERMEGA) { /* only MSB is latched by CXD2554M chip, LSB is ignored (8-bit digital filter) */ /* attenuator data is 7-bit only (bits 0-7) */ data = (data >> 8) & 0x7f; /* scale CXD2554M volume (0-127) to full (LC7883KM compatible) volume range (0-1024) */ cdd.fader[1] = (1024 * data) / 127 ; } /* Wondermega M2 / X'Eye hardware (SM5841A digital filter) */ else if (cdd.type == CD_TYPE_WONDERMEGA_M2) { /* only MSB is latched by SM5841A chip, LSB is ignored (8-bit digital filter) */ data = data >> 8; /* attenuator data is set only when command bit (bit 0) is cleared (other commands are ignored) */ if (data & 0x01) return; /* attenuator data is 7-bit only (bits 8-1) and reverted (bit 1 = msb) */ /* bit reversing formula taken from http://graphics.stanford.edu/~seander/bithacks.html#ReverseByteWith32Bits */ data = (((((data * 0x0802) & 0x22110) | ((data * 0x8020) & 0x88440)) * 0x10101) >> 16) & 0x7f; /* convert & scale SM5841A attenuation (127-0) to full (LC7883KM compatible) volume range (0-1024) */ cdd.fader[1] = (1024 * (127 - data)) / 127 ; } /* default CD hardware (LC7883KM digital filter) */ else { /* get LC7883KM volume data (12-bit) */ cdd.fader[1] = data >> 4 ; } return; } case 0x4a: /* CDD command 9 (controlled by BIOS, word access only ?) */ { scd.regs[0x4a>>1].w = 0; cdd_process(); #ifdef LOG_CDD error("CDD command: %02x %02x %02x %02x %02x %02x %02x %02x\n",scd.regs[0x42>>1].byte.h, scd.regs[0x42>>1].byte.l, scd.regs[0x44>>1].byte.h, scd.regs[0x44>>1].byte.l, scd.regs[0x46>>1].byte.h, scd.regs[0x46>>1].byte.l, scd.regs[0x48>>1].byte.h, scd.regs[0x48>>1].byte.l); error("CDD status: %02x %02x %02x %02x %02x %02x %02x %02x %02x %02x\n",scd.regs[0x38>>1].byte.h, scd.regs[0x38>>1].byte.l, scd.regs[0x3a>>1].byte.h, scd.regs[0x3a>>1].byte.l, scd.regs[0x3c>>1].byte.h, scd.regs[0x3c>>1].byte.l, scd.regs[0x3e>>1].byte.h, scd.regs[0x3e>>1].byte.l, scd.regs[0x40>>1].byte.h, scd.regs[0x40>>1].byte.l); #endif break; } case 0x66: /* Trace vector base address */ { scd.regs[0x66>>1].w = data; /* start GFX operation */ gfx_start(data, s68k.cycles); return; } default: { /* SUB-CPU communication words */ if ((address & 0x1f0) == 0x20) { s68k_poll_sync(3 << ((address - 0x10) & 0x1e)); } /* MAIN-CPU communication words */ else if ((address & 0x1f0) == 0x10) { /* read-only (Sega Classic Arcade Collection) */ return; } /* default registers */ scd.regs[(address >> 1) & 0xff].w = data; return; } } } void scd_init(void) { int i; /****************************************************************/ /* MAIN-CPU low memory map ($000000-$7FFFFF) */ /****************************************************************/ /* 0x00: boot from CD (default) */ /* 0x40: boot from cartridge (mode 1) when /CART is asserted */ int base = scd.cartridge.boot; /* $400000-$7FFFFF (resp. $000000-$3FFFFF): cartridge port (/CE0 asserted) */ cd_cart_init(); /* $000000-$1FFFFF (resp. $400000-$5FFFFF): expansion port (/ROM asserted) */ for (i=base+0x00; i (base + 0x03)) { m68k.memory_map[i].read8 = prg_ram_m68k_read_byte; m68k.memory_map[i].read16 = prg_ram_m68k_read_word; m68k.memory_map[i].write8 = prg_ram_m68k_write_byte; m68k.memory_map[i].write16 = prg_ram_m68k_write_word; zbank_memory_map[i].read = prg_ram_z80_read_byte; zbank_memory_map[i].write = prg_ram_z80_write_byte; } else { m68k.memory_map[i].read8 = NULL; m68k.memory_map[i].read16 = NULL; m68k.memory_map[i].write8 = NULL; m68k.memory_map[i].write16 = NULL; zbank_memory_map[i].read = NULL; zbank_memory_map[i].write = NULL; } break; } } } /* $200000-$3FFFFF (resp. $600000-$7FFFFF): expansion port (/RAS2 asserted) */ for (i=base+0x20; i (base + 0x23)) { m68k.memory_map[i].read8 = word_ram_m68k_read_byte; m68k.memory_map[i].read16 = word_ram_m68k_read_word; m68k.memory_map[i].write8 = word_ram_m68k_write_byte; m68k.memory_map[i].write16 = word_ram_m68k_write_word; zbank_memory_map[i].read = word_ram_z80_read_byte; zbank_memory_map[i].write = word_ram_z80_write_byte; } else { m68k.memory_map[i].read8 = NULL; m68k.memory_map[i].read16 = NULL; m68k.memory_map[i].write8 = NULL; m68k.memory_map[i].write16 = NULL; zbank_memory_map[i].read = NULL; zbank_memory_map[i].write = NULL; } } /****************************************************************/ /* SUB-CPU memory map ($000000-$FFFFFF) */ /****************************************************************/ for (i=0x00; i<0x100; i++) { /* only A1-A19 are connected to SUB-CPU */ switch (i & 0x0f) { case 0x00: case 0x01: case 0x02: case 0x03: case 0x04: case 0x05: case 0x06: case 0x07: { /* $000000-$07FFFF (mirrored every 1MB): PRG-RAM (512KB) */ s68k.memory_map[i].base = scd.prg_ram + ((i & 0x07) << 16); s68k.memory_map[i].read8 = NULL; s68k.memory_map[i].read16 = NULL; /* first 128KB can be write-protected */ s68k.memory_map[i].write8 = (i & 0x0e) ? NULL : prg_ram_write_byte; s68k.memory_map[i].write16 = (i & 0x0e) ? NULL : prg_ram_write_word; break; } case 0x08: case 0x09: case 0x0a: case 0x0b: { /* $080000-$0BFFFF (mirrored every 1MB): Word-RAM in 2M mode (256KB)*/ s68k.memory_map[i].base = scd.word_ram_2M + ((i & 0x03) << 16); /* automatic mirrored range remapping when switching Word-RAM */ if (i > 0x0f) { s68k.memory_map[i].read8 = word_ram_s68k_read_byte; s68k.memory_map[i].read16 = word_ram_s68k_read_word; s68k.memory_map[i].write8 = word_ram_s68k_write_byte; s68k.memory_map[i].write16 = word_ram_s68k_write_word; } else { s68k.memory_map[i].read8 = NULL; s68k.memory_map[i].read16 = NULL; s68k.memory_map[i].write8 = NULL; s68k.memory_map[i].write16 = NULL; } break; } case 0x0c: case 0x0d: { /* $0C0000-$0DFFFF (mirrored every 1MB): unused in 2M mode (?) */ s68k.memory_map[i].base = scd.word_ram_2M + ((i & 0x03) << 16); /* automatic mirrored range remapping when switching Word-RAM */ if (i > 0x0f) { s68k.memory_map[i].read8 = word_ram_s68k_read_byte; s68k.memory_map[i].read16 = word_ram_s68k_read_word; s68k.memory_map[i].write8 = word_ram_s68k_write_byte; s68k.memory_map[i].write16 = word_ram_s68k_write_word; } else { s68k.memory_map[i].read8 = s68k_read_bus_8; s68k.memory_map[i].read16 = s68k_read_bus_16; s68k.memory_map[i].write8 = s68k_unused_8_w; s68k.memory_map[i].write16 = s68k_unused_16_w; } break; } case 0x0e: { /* $FE0000-$FEFFFF (mirrored every 1MB): 8KB backup RAM */ s68k.memory_map[i].base = NULL; s68k.memory_map[i].read8 = bram_read_byte; s68k.memory_map[i].read16 = bram_read_word; s68k.memory_map[i].write8 = bram_write_byte; s68k.memory_map[i].write16 = bram_write_word; break; } case 0x0f: { /* $FF0000-$FFFFFF (mirrored every 1MB): PCM hardware & SUB-CPU registers */ s68k.memory_map[i].base = NULL; s68k.memory_map[i].read8 = scd_read_byte; s68k.memory_map[i].read16 = scd_read_word; s68k.memory_map[i].write8 = scd_write_byte; s68k.memory_map[i].write16 = scd_write_word; break; } } } /* Initialize CD hardware */ cdc_init(); gfx_init(); /* Initialize CD hardware master clock count per scanline */ scd.cycles_per_line = (uint32) (MCYCLES_PER_LINE * ((float)SCD_CLOCK / (float)system_clock)); /* Clear RAM */ memset(scd.prg_ram, 0x00, sizeof(scd.prg_ram)); memset(scd.word_ram, 0x00, sizeof(scd.word_ram)); memset(scd.word_ram_2M, 0x00, sizeof(scd.word_ram_2M)); memset(scd.bram, 0x00, sizeof(scd.bram)); } void scd_reset(int hard) { /* TODO: figure what exactly is resetted when RESET bit is cleared by SUB-CPU */ if (hard) { /* Clear all ASIC registers by default */ memset(scd.regs, 0, sizeof(scd.regs)); /* Clear pending DMNA write status */ scd.dmna = 0; /* H-INT default vector */ *(uint16 *)(m68k.memory_map[scd.cartridge.boot].base + 0x70) = 0x00FF; *(uint16 *)(m68k.memory_map[scd.cartridge.boot].base + 0x72) = 0xFFFF; /* Power ON initial values (MAIN-CPU side) */ scd.regs[0x00>>1].w = 0x0002; scd.regs[0x02>>1].w = 0x0001; /* 2M mode */ word_ram_switch(0); /* reset PRG-RAM bank on MAIN-CPU side */ m68k.memory_map[scd.cartridge.boot + 0x02].base = scd.prg_ram; m68k.memory_map[scd.cartridge.boot + 0x03].base = scd.prg_ram + 0x10000; /* allow access to PRG-RAM from MAIN-CPU */ m68k.memory_map[scd.cartridge.boot + 0x02].read8 = NULL; m68k.memory_map[scd.cartridge.boot + 0x03].read8 = NULL; m68k.memory_map[scd.cartridge.boot + 0x02].read16 = NULL; m68k.memory_map[scd.cartridge.boot + 0x03].read16 = NULL; m68k.memory_map[scd.cartridge.boot + 0x02].write8 = NULL; m68k.memory_map[scd.cartridge.boot + 0x03].write8 = NULL; m68k.memory_map[scd.cartridge.boot + 0x02].write16 = NULL; m68k.memory_map[scd.cartridge.boot + 0x03].write16 = NULL; zbank_memory_map[scd.cartridge.boot + 0x02].read = NULL; zbank_memory_map[scd.cartridge.boot + 0x03].read = NULL; zbank_memory_map[scd.cartridge.boot + 0x02].write = NULL; zbank_memory_map[scd.cartridge.boot + 0x03].write = NULL; /* reset & halt SUB-CPU */ s68k.cycles = 0; s68k_pulse_reset(); s68k_pulse_halt(); /* Reset frame cycle counter */ scd.cycles = 0; } else { /* Clear only SUB-CPU side registers */ memset(&scd.regs[0x04>>1], 0, sizeof(scd.regs) - 4); } /* SUB-CPU side default values */ scd.regs[0x08>>1].w = 0xffff; scd.regs[0x0a>>1].w = 0xffff; scd.regs[0x36>>1].w = 0x0100; scd.regs[0x40>>1].w = 0x000f; scd.regs[0x42>>1].w = 0xffff; scd.regs[0x44>>1].w = 0xffff; scd.regs[0x46>>1].w = 0xffff; scd.regs[0x48>>1].w = 0xffff; scd.regs[0x4a>>1].w = 0xffff; /* RESET register always return 1 (register $06 is unused by both sides, it is used for SUB-CPU first register) */ scd.regs[0x06>>1].byte.l = 0x01; /* Reset Timer & Stopwatch counters */ scd.timer = 0; scd.stopwatch = s68k.cycles; /* Clear pending interrupts */ scd.pending = 0; /* Clear CPU polling detection */ memset(&m68k.poll, 0, sizeof(m68k.poll)); memset(&s68k.poll, 0, sizeof(s68k.poll)); /* reset CDD cycle counter */ cdd.cycles = (scd.cycles - s68k.cycles) * 3; /* Reset CD hardware */ cdd_reset(); cdc_reset(); gfx_reset(); pcm_reset(); } void scd_update(unsigned int cycles) { /* update CDC DMA transfer */ if (cdc.dma_w) { cdc_dma_update(); } /* run both CPU in sync until end of line */ do { m68k_run(cycles); s68k_run(scd.cycles + SCYCLES_PER_LINE); } while ((m68k.cycles < cycles) || (s68k.cycles < (scd.cycles + SCYCLES_PER_LINE))); /* increment CD hardware cycle counter */ scd.cycles += SCYCLES_PER_LINE; /* CDD processing at 75Hz (one clock = 12500000/75 = 500000/3 CPU clocks) */ cdd.cycles += (SCYCLES_PER_LINE * 3); if (cdd.cycles >= (500000 * 4)) { /* reload CDD cycle counter */ cdd.cycles -= (500000 * 4); /* update CDD sector */ cdd_update(); /* check if a new CDD command has been processed */ if (!(scd.regs[0x4a>>1].byte.l & 0xf0)) { /* reset CDD command wait flag */ scd.regs[0x4a>>1].byte.l = 0xf0; /* pending level 4 interrupt */ scd.pending |= (1 << 4); /* level 4 interrupt enabled */ if (scd.regs[0x32>>1].byte.l & 0x10) { /* update IRQ level */ s68k_update_irq((scd.pending & scd.regs[0x32>>1].byte.l) >> 1); } } } /* Timer */ if (scd.timer) { /* decrement timer */ scd.timer -= SCYCLES_PER_LINE; if (scd.timer <= 0) { /* reload timer (one timer clock = 384 CPU cycles) */ scd.timer += (scd.regs[0x30>>1].byte.l * TIMERS_SCYCLES_RATIO); /* level 3 interrupt enabled ? */ if (scd.regs[0x32>>1].byte.l & 0x08) { /* trigger level 3 interrupt */ scd.pending |= (1 << 3); /* update IRQ level */ s68k_update_irq((scd.pending & scd.regs[0x32>>1].byte.l) >> 1); } } } /* GFX processing */ if (scd.regs[0x58>>1].byte.h & 0x80) { /* update graphics operation if running */ gfx_update(scd.cycles); } } void scd_end_frame(unsigned int cycles) { /* run Stopwatch until end of frame */ int ticks = (cycles - scd.stopwatch) / TIMERS_SCYCLES_RATIO; scd.regs[0x0c>>1].w = (scd.regs[0x0c>>1].w + ticks) & 0xfff; /* adjust Stopwatch counter for next frame (can be negative) */ scd.stopwatch += (ticks * TIMERS_SCYCLES_RATIO) - cycles; /* adjust SUB-CPU & GPU cycle counters for next frame */ s68k.cycles -= cycles; gfx.cycles -= cycles; /* reset CPU registers polling */ m68k.poll.cycle = 0; s68k.poll.cycle = 0; } int scd_context_save(uint8 *state) { uint16 tmp16; uint32 tmp32; int bufferptr = 0; /* internal harware */ save_param(scd.regs, sizeof(scd.regs)); save_param(&scd.cycles, sizeof(scd.cycles)); save_param(&scd.stopwatch, sizeof(scd.stopwatch)); save_param(&scd.timer, sizeof(scd.timer)); save_param(&scd.pending, sizeof(scd.pending)); save_param(&scd.dmna, sizeof(scd.dmna)); /* GFX processor */ bufferptr += gfx_context_save(&state[bufferptr]); /* CD Data controller */ bufferptr += cdc_context_save(&state[bufferptr]); /* CD Drive processor */ bufferptr += cdd_context_save(&state[bufferptr]); /* PCM chip */ bufferptr += pcm_context_save(&state[bufferptr]); /* PRG-RAM */ save_param(scd.prg_ram, sizeof(scd.prg_ram)); /* Word-RAM */ if (scd.regs[0x03>>1].byte.l & 0x04) { /* 1M mode */ save_param(scd.word_ram, sizeof(scd.word_ram)); } else { /* 2M mode */ save_param(scd.word_ram_2M, sizeof(scd.word_ram_2M)); } /* MAIN-CPU & SUB-CPU polling */ save_param(&m68k.poll, sizeof(m68k.poll)); save_param(&s68k.poll, sizeof(s68k.poll)); /* H-INT default vector */ tmp16 = *(uint16 *)(m68k.memory_map[scd.cartridge.boot].base + 0x72); save_param(&tmp16, 2); /* SUB-CPU registers */ tmp32 = s68k_get_reg(M68K_REG_D0); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_D1); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_D2); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_D3); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_D4); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_D5); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_D6); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_D7); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_A0); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_A1); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_A2); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_A3); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_A4); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_A5); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_A6); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_A7); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_PC); save_param(&tmp32, 4); tmp16 = s68k_get_reg(M68K_REG_SR); save_param(&tmp16, 2); tmp32 = s68k_get_reg(M68K_REG_USP); save_param(&tmp32, 4); tmp32 = s68k_get_reg(M68K_REG_ISP); save_param(&tmp32, 4); /* SUB-CPU internal state */ save_param(&s68k.cycles, sizeof(s68k.cycles)); save_param(&s68k.int_level, sizeof(s68k.int_level)); save_param(&s68k.stopped, sizeof(s68k.stopped)); /* bootable MD cartridge */ if (scd.cartridge.boot) { bufferptr += md_cart_context_save(&state[bufferptr]); } return bufferptr; } int scd_context_load(uint8 *state) { int i; uint16 tmp16; uint32 tmp32; int bufferptr = 0; /* internal harware */ load_param(scd.regs, sizeof(scd.regs)); load_param(&scd.cycles, sizeof(scd.cycles)); load_param(&scd.stopwatch, sizeof(scd.stopwatch)); load_param(&scd.timer, sizeof(scd.timer)); load_param(&scd.pending, sizeof(scd.pending)); load_param(&scd.dmna, sizeof(scd.dmna)); /* GFX processor */ bufferptr += gfx_context_load(&state[bufferptr]); /* CD Data controller */ bufferptr += cdc_context_load(&state[bufferptr]); /* CD Drive processor */ bufferptr += cdd_context_load(&state[bufferptr]); /* PCM chip */ bufferptr += pcm_context_load(&state[bufferptr]); /* PRG-RAM */ load_param(scd.prg_ram, sizeof(scd.prg_ram)); /* PRG-RAM 128K bank mapped on MAIN-CPU side */ m68k.memory_map[scd.cartridge.boot + 0x02].base = scd.prg_ram + ((scd.regs[0x03>>1].byte.l & 0xc0) << 11); m68k.memory_map[scd.cartridge.boot + 0x03].base = m68k.memory_map[scd.cartridge.boot + 0x02].base + 0x10000; /* PRG-RAM can only be accessed from MAIN 68K & Z80 if SUB-CPU is halted (Dungeon Explorer USA version) */ if ((scd.regs[0x00].byte.l & 0x03) != 0x01) { m68k.memory_map[scd.cartridge.boot + 0x02].read8 = m68k.memory_map[scd.cartridge.boot + 0x03].read8 = NULL; m68k.memory_map[scd.cartridge.boot + 0x02].read16 = m68k.memory_map[scd.cartridge.boot + 0x03].read16 = NULL; m68k.memory_map[scd.cartridge.boot + 0x02].write8 = m68k.memory_map[scd.cartridge.boot + 0x03].write8 = NULL; m68k.memory_map[scd.cartridge.boot + 0x02].write16 = m68k.memory_map[scd.cartridge.boot + 0x03].write16 = NULL; zbank_memory_map[scd.cartridge.boot + 0x02].read = zbank_memory_map[scd.cartridge.boot + 0x03].read = NULL; zbank_memory_map[scd.cartridge.boot + 0x02].write = zbank_memory_map[scd.cartridge.boot + 0x03].write = NULL; } else { m68k.memory_map[scd.cartridge.boot + 0x02].read8 = m68k.memory_map[scd.cartridge.boot + 0x03].read8 = m68k_read_bus_8; m68k.memory_map[scd.cartridge.boot + 0x02].read16 = m68k.memory_map[scd.cartridge.boot + 0x03].read16 = m68k_read_bus_16; m68k.memory_map[scd.cartridge.boot + 0x02].write8 = m68k.memory_map[scd.cartridge.boot + 0x03].write8 = m68k_unused_8_w; m68k.memory_map[scd.cartridge.boot + 0x02].write16 = m68k.memory_map[scd.cartridge.boot + 0x03].write16 = m68k_unused_16_w; zbank_memory_map[scd.cartridge.boot + 0x02].read = zbank_memory_map[scd.cartridge.boot + 0x03].read = zbank_unused_r; zbank_memory_map[scd.cartridge.boot + 0x02].write = zbank_memory_map[scd.cartridge.boot + 0x03].write = zbank_unused_w; } /* Word-RAM */ if (scd.regs[0x03>>1].byte.l & 0x04) { /* 1M Mode */ load_param(scd.word_ram, sizeof(scd.word_ram)); if (scd.regs[0x03>>1].byte.l & 0x01) { /* Word-RAM 1 assigned to MAIN-CPU */ for (i=scd.cartridge.boot+0x20; i>1].byte.l) >> 1); } return M68K_INT_ACK_AUTOVECTOR; }