Genesis-Plus-GX/source/mem68k.c

1253 lines
32 KiB
C

/***************************************************************************************
* Genesis Plus
* Main 68k bus handlers
*
* Copyright (C) 1998, 1999, 2000, 2001, 2002, 2003 Charles Mac Donald (original code)
* Copyright (C) 2007-2012 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 += 8; /* ZRAM access latency (fixes Pacman 2: New Adventures) */
return;
}
}
}
void z80_write_word(unsigned int address, unsigned int data)
{
z80_write_byte(address, data >> 8);
}
/*--------------------------------------------------------------------------*/
/* I/O Control */
/*--------------------------------------------------------------------------*/
static void m68k_poll_detect(reg)
{
/* detect MAIN-CPU register polling */
if (m68k.poll.detected == (1 << reg))
{
if (m68k.cycles <= m68k.poll.cycle)
{
if (m68k.pc == m68k.poll.pc)
{
/* stop MAIN-CPU until register is modified by SUB-CPU */
#ifdef LOG_SCD
error("m68k stopped from %d cycles\n", m68k.cycles);
#endif
m68k.cycles = m68k.cycle_end;
m68k.stopped = 1 << reg;
}
return;
}
}
else
{
/* set MAIN-CPU register access flag */
m68k.poll.detected = 1 << reg;
}
/* restart MAIN-CPU polling detection */
m68k.poll.cycle = m68k.cycles + 280;
m68k.poll.pc = m68k.pc;
}
static void m68k_poll_sync(reg)
{
/* relative SUB-CPU cycle counter */
unsigned int cycles = (m68k.cycles * SCYCLES_PER_LINE) / MCYCLES_PER_LINE;
/* sync SUB-CPU with MAIN-CPU */
if (!s68k.stopped && (s68k.cycles < cycles))
{
s68k_run(cycles);
}
/* SUB-CPU stopped on register polling ? */
if (s68k.stopped & (3 << reg))
{
/* 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(s) access flags */
m68k.poll.detected &= ~(3 << reg);
s68k.poll.detected &= ~(3 << reg);
}
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(0x03);
return scd.regs[0x03>>1].byte.l;
}
/* SUB-CPU communication flags */
if (index == 0x0f)
{
m68k_poll_detect(0x0f);
return scd.regs[0x0f>>1].byte.l;
}
/* default registers */
if (index < 0x30)
{
/* SUB-CPU communication words */
if (index >= 0x20)
{
m68k_poll_detect(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 0x10: /* MEMORY MODE */
case 0x12: /* Z80 RESET */
case 0x13: /* unknown */
case 0x40: /* TMSS */
case 0x44: /* RADICA */
case 0x50: /* SVP */
{
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(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[0].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)
{
m68k_poll_detect(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 & 0xFD) == 0)
{
return svp->ssp1601.gr[SSP_XST].byte.h;
}
if ((address & 0xFF) == 4)
{
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)
{
/* relative SUB-CPU cycle counter */
unsigned int cycles = (m68k.cycles * SCYCLES_PER_LINE) / MCYCLES_PER_LINE;
/* sync SUB-CPU with MAIN-CPU */
if (!s68k.stopped && (s68k.cycles < cycles))
{
s68k_run(cycles);
}
/* 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 */
{
/* RESET bit */
if (data & 0x01)
{
/* trigger reset on 0->1 transition */
if (!(scd.regs[0x00].byte.l & 0x01))
{
/* reset SUB-CPU */
s68k_pulse_reset();
}
/* BUSREQ bit */
if (data & 0x02)
{
/* SUB-CPU bus requested */
s68k_pulse_halt();
}
else
{
/* SUB-CPU bus released */
s68k_clear_halt();
}
}
else
{
/* SUB-CPU is halted while !RESET is asserted */
s68k_pulse_halt();
}
scd.regs[0x00].byte.l = data;
return;
}
case 0x03: /* Memory mode */
{
m68k_poll_sync(0x02);
/* 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 set 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 in 2M mode does nothing */
if (data & 0x02)
{
/* Word-RAM is assigned to SUB-CPU */
scd.dmna = 1;
/* clear RET bit */
scd.regs[0x03>>1].byte.l = (scd.regs[0x03>>1].byte.l & ~0xc3) | (data & 0xc2);
return;
}
}
/* update BK0-1 bits */
scd.regs[0x03>>1].byte.l = (scd.regs[0x02>>1].byte.l & ~0xc0) | (data & 0xc0);
return;
}
case 0x0f: /* SUB-CPU communication flags, normally read-only (Space Ace, Dragon's Lair) */
{
/* ROL8 operation */
data = (data << 1) | ((data >> 7) & 1);
}
case 0x0e: /* MAIN-CPU communication flags */
{
m68k_poll_sync(0x0e);
scd.regs[0x0e>>1].byte.h = data;
return;
}
default:
{
/* MAIN-CPU communication words */
if ((address & 0x30) == 0x10)
{
m68k_poll_sync(address & 0x1e);
/* 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 */
{
/* RESET bit */
if (data & 0x01)
{
/* trigger reset on 0->1 transition */
if (!(scd.regs[0x00].byte.l & 0x01))
{
/* reset SUB-CPU */
s68k_pulse_reset();
}
/* BUSREQ bit */
if (data & 0x02)
{
/* SUB-CPU bus requested */
s68k_pulse_halt();
}
else
{
/* SUB-CPU bus released */
s68k_clear_halt();
}
}
else
{
/* SUB-CPU is halted while !RESET is asserted */
s68k_pulse_halt();
}
/* 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);
}
}
/* update LSB only */
scd.regs[0x00].byte.l = data & 0xff;
return;
}
case 0x02: /* Memory Mode */
{
m68k_poll_sync(0x02);
/* 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 set 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 in 2M mode does nothing */
if (data & 0x02)
{
/* Word-RAM is assigned to SUB-CPU */
scd.dmna = 1;
/* clear RET bit */
scd.regs[0x02>>1].w = (scd.regs[0x02>>1].w & ~0xffc3) | (data & 0xffc2);
return;
}
}
/* update WP0-7 & BK0-1 bits */
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[0].base + 0x72) = data;
return;
}
case 0x0e: /* MAIN-CPU communication flags */
{
m68k_poll_sync(0x0e);
/* LSB is read-only (Mortal Kombat) */
scd.regs[0x0e>>1].byte.h = data;
return;
}
default:
{
/* MAIN-CPU communication words */
if ((address & 0x30) == 0x10)
{
m68k_poll_sync(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)
{
SN76489_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:
{
SN76489_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));
}