// Memory I/O handlers for Sega/Mega CD. // Loosely based on Gens code. // (c) Copyright 2007, Grazvydas "notaz" Ignotas #include "../PicoInt.h" #include "../sound/ym2612.h" #include "../sound/sn76496.h" #include "gfx_cd.h" #include "pcm.h" #ifndef UTYPES_DEFINED typedef unsigned char u8; typedef unsigned short u16; typedef unsigned int u32; #define UTYPES_DEFINED #endif //#define rdprintf dprintf #define rdprintf(...) //#define wrdprintf dprintf #define wrdprintf(...) #ifdef EMU_CORE_DEBUG extern u32 lastread_a, lastread_d[16], lastwrite_cyc_d[16]; extern int lrp_cyc, lwp_cyc; #undef USE_POLL_DETECT #endif // ----------------------------------------------------------------- // poller detection #define POLL_LIMIT 16 #define POLL_CYCLES 124 // int m68k_poll_addr, m68k_poll_cnt; unsigned int s68k_poll_adclk, s68k_poll_cnt; #ifndef _ASM_CD_MEMORY_C static u32 m68k_reg_read16(u32 a) { u32 d=0; a &= 0x3e; // dprintf("m68k_regs r%2i: [%02x] @%06x", realsize&~1, a+(realsize&1), SekPc); switch (a) { case 0: d = ((Pico_mcd->s68k_regs[0x33]<<13)&0x8000) | Pico_mcd->m.busreq; // here IFL2 is always 0, just like in Gens goto end; case 2: d = (Pico_mcd->s68k_regs[a]<<8) | (Pico_mcd->s68k_regs[a+1]&0xc7); // the DMNA delay must only be visible on s68k side (Lunar2, Silpheed) if (Pico_mcd->m.state_flags&2) { d &= ~1; d |= 2; } //printf("m68k_regs r3: %02x @%06x\n", (u8)d, SekPc); goto end; case 4: d = Pico_mcd->s68k_regs[4]<<8; goto end; case 6: d = *(u16 *)(Pico_mcd->bios + 0x72); goto end; case 8: d = Read_CDC_Host(0); goto end; case 0xA: elprintf(EL_UIO, "m68k FIXME: reserved read"); goto end; case 0xC: d = Pico_mcd->m.timer_stopwatch >> 16; dprintf("m68k stopwatch timer read (%04x)", d); goto end; } if (a < 0x30) { // comm flag/cmd/status (0xE-0x2F) d = (Pico_mcd->s68k_regs[a]<<8) | Pico_mcd->s68k_regs[a+1]; goto end; } elprintf(EL_UIO, "m68k_regs FIXME invalid read @ %02x", a); end: return d; } #endif #ifndef _ASM_CD_MEMORY_C static #endif void m68k_reg_write8(u32 a, u32 d) { a &= 0x3f; // dprintf("m68k_regs w%2i: [%02x] %02x @%06x", realsize, a, d, SekPc); switch (a) { case 0: d &= 1; if ((d&1) && (Pico_mcd->s68k_regs[0x33]&(1<<2))) { elprintf(EL_INTS, "m68k: s68k irq 2"); SekInterruptS68k(2); } return; case 1: d &= 3; if (!(d&1)) Pico_mcd->m.state_flags |= 1; // reset pending, needed to be sure we fetch the right vectors on reset if ( (Pico_mcd->m.busreq&1) != (d&1)) dprintf("m68k: s68k reset %i", !(d&1)); if ( (Pico_mcd->m.busreq&2) != (d&2)) dprintf("m68k: s68k brq %i", (d&2)>>1); if ((Pico_mcd->m.state_flags&1) && (d&3)==1) { SekResetS68k(); // S68k comes out of RESET or BRQ state Pico_mcd->m.state_flags&=~1; dprintf("m68k: resetting s68k, cycles=%i", SekCyclesLeft); } Pico_mcd->m.busreq = d; return; case 2: dprintf("m68k: prg wp=%02x", d); Pico_mcd->s68k_regs[2] = d; // really use s68k side register return; case 3: { u32 dold = Pico_mcd->s68k_regs[3]&0x1f; //printf("m68k_regs w3: %02x @%06x\n", (u8)d, SekPc); d &= 0xc2; if ((dold>>6) != ((d>>6)&3)) dprintf("m68k: prg bank: %i -> %i", (Pico_mcd->s68k_regs[a]>>6), ((d>>6)&3)); //if ((Pico_mcd->s68k_regs[3]&4) != (d&4)) dprintf("m68k: ram mode %i mbit", (d&4) ? 1 : 2); //if ((Pico_mcd->s68k_regs[3]&2) != (d&2)) dprintf("m68k: %s", (d&4) ? ((d&2) ? "word swap req" : "noop?") : // ((d&2) ? "word ram to s68k" : "word ram to m68k")); if (dold & 4) { d ^= 2; // writing 0 to DMNA actually sets it, 1 does nothing } else { //dold &= ~2; // ?? #if 1 if ((d & 2) && !(dold & 2)) { Pico_mcd->m.state_flags |= 2; // we must delay setting DMNA bit (needed for Silpheed) d &= ~2; } #else if (d & 2) dold &= ~1; // return word RAM to s68k in 2M mode #endif } Pico_mcd->s68k_regs[3] = d | dold; // really use s68k side register #ifdef USE_POLL_DETECT if ((s68k_poll_adclk&0xfe) == 2 && s68k_poll_cnt > POLL_LIMIT) { SekSetStopS68k(0); s68k_poll_adclk = 0; elprintf(EL_CDPOLL, "s68k poll release, a=%02x", a); } #endif return; } case 6: Pico_mcd->bios[0x72 + 1] = d; // simple hint vector changer return; case 7: Pico_mcd->bios[0x72] = d; dprintf("hint vector set to %08x", PicoRead32(0x70)); return; case 0xf: d = (d << 1) | ((d >> 7) & 1); // rol8 1 (special case) case 0xe: //dprintf("m68k: comm flag: %02x", d); Pico_mcd->s68k_regs[0xe] = d; #ifdef USE_POLL_DETECT if ((s68k_poll_adclk&0xfe) == 0xe && s68k_poll_cnt > POLL_LIMIT) { SekSetStopS68k(0); s68k_poll_adclk = 0; elprintf(EL_CDPOLL, "s68k poll release, a=%02x", a); } #endif return; } if ((a&0xf0) == 0x10) { Pico_mcd->s68k_regs[a] = d; #ifdef USE_POLL_DETECT if ((a&0xfe) == (s68k_poll_adclk&0xfe) && s68k_poll_cnt > POLL_LIMIT) { SekSetStopS68k(0); s68k_poll_adclk = 0; elprintf(EL_CDPOLL, "s68k poll release, a=%02x", a); } #endif return; } elprintf(EL_UIO, "m68k FIXME: invalid write? [%02x] %02x", a, d); } #ifndef _ASM_CD_MEMORY_C static #endif u32 s68k_poll_detect(u32 a, u32 d) { #ifdef USE_POLL_DETECT // needed mostly for Cyclone, which doesn't always check it's cycle counter if (SekIsStoppedS68k()) return d; // polling detection if (a == (s68k_poll_adclk&0xff)) { unsigned int clkdiff = SekCyclesDoneS68k() - (s68k_poll_adclk>>8); if (clkdiff <= POLL_CYCLES) { s68k_poll_cnt++; //printf("-- diff: %u, cnt = %i\n", clkdiff, s68k_poll_cnt); if (s68k_poll_cnt > POLL_LIMIT) { SekSetStopS68k(1); elprintf(EL_CDPOLL, "s68k poll detected @ %06x, a=%02x", SekPcS68k, a); } s68k_poll_adclk = (SekCyclesDoneS68k() << 8) | a; return d; } } s68k_poll_adclk = (SekCyclesDoneS68k() << 8) | a; s68k_poll_cnt = 0; #endif return d; } #define READ_FONT_DATA(basemask) \ { \ unsigned int fnt = *(unsigned int *)(Pico_mcd->s68k_regs + 0x4c); \ unsigned int col0 = (fnt >> 8) & 0x0f, col1 = (fnt >> 12) & 0x0f; \ if (fnt & (basemask << 0)) d = col1 ; else d = col0; \ if (fnt & (basemask << 1)) d |= col1 << 4; else d |= col0 << 4; \ if (fnt & (basemask << 2)) d |= col1 << 8; else d |= col0 << 8; \ if (fnt & (basemask << 3)) d |= col1 << 12; else d |= col0 << 12; \ } #ifndef _ASM_CD_MEMORY_C static #endif u32 s68k_reg_read16(u32 a) { u32 d=0; // dprintf("s68k_regs r%2i: [%02x] @ %06x", realsize&~1, a+(realsize&1), SekPcS68k); switch (a) { case 0: return ((Pico_mcd->s68k_regs[0]&3)<<8) | 1; // ver = 0, not in reset state case 2: d = (Pico_mcd->s68k_regs[2]<<8) | (Pico_mcd->s68k_regs[3]&0x1f); //printf("s68k_regs r3: %02x @%06x\n", (u8)d, SekPcS68k); return s68k_poll_detect(a, d); case 6: return CDC_Read_Reg(); case 8: return Read_CDC_Host(1); // Gens returns 0 here on byte reads case 0xC: d = Pico_mcd->m.timer_stopwatch >> 16; dprintf("s68k stopwatch timer read (%04x)", d); return d; case 0x30: dprintf("s68k int3 timer read (%02x)", Pico_mcd->s68k_regs[31]); return Pico_mcd->s68k_regs[31]; case 0x34: // fader return 0; // no busy bit case 0x50: // font data (check: Lunar 2, Silpheed) READ_FONT_DATA(0x00100000); return d; case 0x52: READ_FONT_DATA(0x00010000); return d; case 0x54: READ_FONT_DATA(0x10000000); return d; case 0x56: READ_FONT_DATA(0x01000000); return d; } d = (Pico_mcd->s68k_regs[a]<<8) | Pico_mcd->s68k_regs[a+1]; if (a >= 0x0e && a < 0x30) return s68k_poll_detect(a, d); return d; } #ifndef _ASM_CD_MEMORY_C static #endif void s68k_reg_write8(u32 a, u32 d) { //dprintf("s68k_regs w%2i: [%02x] %02x @ %06x", realsize, a, d, SekPcS68k); // Warning: d might have upper bits set switch (a) { case 2: return; // only m68k can change WP case 3: { int dold = Pico_mcd->s68k_regs[3]; //printf("s68k_regs w3: %02x @%06x\n", (u8)d, SekPcS68k); d &= 0x1d; d |= dold&0xc2; if (d&4) { if ((d ^ dold) & 5) { d &= ~2; // in case of mode or bank change we clear DMNA (m68k req) bit PicoMemResetCD(d); } #ifdef _ASM_CD_MEMORY_C if ((d ^ dold) & 0x1d) PicoMemResetCDdecode(d); #endif if (!(dold & 4)) { dprintf("wram mode 2M->1M"); wram_2M_to_1M(Pico_mcd->word_ram2M); } } else { if (dold & 4) { dprintf("wram mode 1M->2M"); if (!(d&1)) { // it didn't set the ret bit, which means it doesn't want to give WRAM to m68k d &= ~3; d |= (dold&1) ? 2 : 1; // then give it to the one which had bank0 in 1M mode } wram_1M_to_2M(Pico_mcd->word_ram2M); PicoMemResetCD(d); } else d |= dold&1; if (d&1) d &= ~2; // return word RAM to m68k in 2M mode } break; } case 4: dprintf("s68k CDC dest: %x", d&7); Pico_mcd->s68k_regs[4] = (Pico_mcd->s68k_regs[4]&0xC0) | (d&7); // CDC mode return; case 5: //dprintf("s68k CDC reg addr: %x", d&0xf); break; case 7: CDC_Write_Reg(d); return; case 0xa: dprintf("s68k set CDC dma addr"); break; case 0xc: case 0xd: dprintf("s68k set stopwatch timer"); Pico_mcd->m.timer_stopwatch = 0; return; case 0xe: Pico_mcd->s68k_regs[0xf] = (d>>1) | (d<<7); // ror8 1, Gens note: Dragons lair return; case 0x31: dprintf("s68k set int3 timer: %02x", d); Pico_mcd->m.timer_int3 = (d & 0xff) << 16; break; case 0x33: // IRQ mask dprintf("s68k irq mask: %02x", d); if ((d&(1<<4)) && (Pico_mcd->s68k_regs[0x37]&4) && !(Pico_mcd->s68k_regs[0x33]&(1<<4))) { CDD_Export_Status(); } break; case 0x34: // fader Pico_mcd->s68k_regs[a] = (u8) d & 0x7f; return; case 0x36: return; // d/m bit is unsetable case 0x37: { u32 d_old = Pico_mcd->s68k_regs[0x37]; Pico_mcd->s68k_regs[0x37] = d&7; if ((d&4) && !(d_old&4)) { CDD_Export_Status(); } return; } case 0x4b: Pico_mcd->s68k_regs[a] = (u8) d; CDD_Import_Command(); return; } if ((a&0x1f0) == 0x10 || (a >= 0x38 && a < 0x42)) { elprintf(EL_UIO, "s68k FIXME: invalid write @ %02x?", a); return; } Pico_mcd->s68k_regs[a] = (u8) d; } #ifndef _ASM_CD_MEMORY_C static u32 OtherRead16End(u32 a, int realsize) { u32 d=0; if ((a&0xffffc0)==0xa12000) { d=m68k_reg_read16(a); goto end; } if (a==0x400000) { if (SRam.data != NULL) d=3; // 64k cart goto end; } if ((a&0xfe0000)==0x600000) { if (SRam.data != NULL) { d=SRam.data[((a>>1)&0xffff)+0x2000]; if (realsize == 8) d|=d<<8; } goto end; } if (a==0x7ffffe) { d=Pico_mcd->m.bcram_reg; goto end; } elprintf(EL_UIO, "m68k FIXME: unusual r%i: %06x @%06x", realsize&~1, (a&0xfffffe)+(realsize&1), SekPc); end: return d; } static void OtherWrite8End(u32 a, u32 d, int realsize) { if ((a&0xffffc0)==0xa12000) { m68k_reg_write8(a, d); return; } if ((a&0xfe0000)==0x600000) { if (SRam.data != NULL && (Pico_mcd->m.bcram_reg&1)) { SRam.data[((a>>1)&0xffff)+0x2000]=d; SRam.changed = 1; } return; } if (a==0x7fffff) { Pico_mcd->m.bcram_reg=d; return; } elprintf(EL_UIO, "m68k FIXME: strange w%i: [%06x], %08x @%06x", realsize, a&0xffffff, d, SekPc); } #define _CD_MEMORY_C #undef _ASM_MEMORY_C #include "../MemoryCmn.c" #include "cell_map.c" #endif // !def _ASM_CD_MEMORY_C // ----------------------------------------------------------------- // Read Rom and read Ram #ifdef _ASM_CD_MEMORY_C u32 PicoReadM68k8(u32 a); #else u32 PicoReadM68k8(u32 a) { u32 d=0; a&=0xffffff; switch (a >> 17) { case 0x00>>1: // BIOS: 000000 - 020000 d = *(u8 *)(Pico_mcd->bios+(a^1)); break; case 0x02>>1: // prg RAM if ((Pico_mcd->m.busreq&3)!=1) { u8 *prg_bank = Pico_mcd->prg_ram_b[Pico_mcd->s68k_regs[3]>>6]; d = *(prg_bank+((a^1)&0x1ffff)); } break; case 0x20>>1: // word RAM: 200000 - 220000 wrdprintf("m68k_wram r8: [%06x] @%06x", a, SekPc); a &= 0x1ffff; if (Pico_mcd->s68k_regs[3]&4) { // 1M mode? int bank = Pico_mcd->s68k_regs[3]&1; d = Pico_mcd->word_ram1M[bank][a^1]; } else { // allow access in any mode, like Gens does d = Pico_mcd->word_ram2M[a^1]; } wrdprintf("ret = %02x", (u8)d); break; case 0x22>>1: // word RAM: 220000 - 240000 wrdprintf("m68k_wram r8: [%06x] @%06x", a, SekPc); if (Pico_mcd->s68k_regs[3]&4) { // 1M mode? int bank = Pico_mcd->s68k_regs[3]&1; a = (a&3) | (cell_map(a >> 2) << 2); // cell arranged d = Pico_mcd->word_ram1M[bank][a^1]; } else { // allow access in any mode, like Gens does d = Pico_mcd->word_ram2M[(a^1)&0x3ffff]; } wrdprintf("ret = %02x", (u8)d); break; case 0xc0>>1: case 0xc2>>1: case 0xc4>>1: case 0xc6>>1: case 0xc8>>1: case 0xca>>1: case 0xcc>>1: case 0xce>>1: case 0xd0>>1: case 0xd2>>1: case 0xd4>>1: case 0xd6>>1: case 0xd8>>1: case 0xda>>1: case 0xdc>>1: case 0xde>>1: // VDP if ((a&0xe700e0)==0xc00000) { d=PicoVideoRead(a); if ((a&1)==0) d>>=8; } break; case 0xe0>>1: case 0xe2>>1: case 0xe4>>1: case 0xe6>>1: case 0xe8>>1: case 0xea>>1: case 0xec>>1: case 0xee>>1: case 0xf0>>1: case 0xf2>>1: case 0xf4>>1: case 0xf6>>1: case 0xf8>>1: case 0xfa>>1: case 0xfc>>1: case 0xfe>>1: // RAM: d = *(u8 *)(Pico.ram+((a^1)&0xffff)); break; default: if ((a&0xff4000)==0xa00000) { d=z80Read8(a); break; } // Z80 Ram if ((a&0xffffc0)==0xa12000) rdprintf("m68k_regs r8: [%02x] @%06x", a&0x3f, SekPc); d=OtherRead16(a&~1, 8|(a&1)); if ((a&1)==0) d>>=8; if ((a&0xffffc0)==0xa12000) rdprintf("ret = %02x", (u8)d); break; } elprintf(EL_IO, "r8 : %06x, %02x @%06x", a&0xffffff, (u8)d, SekPc); #ifdef EMU_CORE_DEBUG if (a>=Pico.romsize) { lastread_a = a; lastread_d[lrp_cyc++&15] = d; } #endif return d; } #endif #ifdef _ASM_CD_MEMORY_C u32 PicoReadM68k16(u32 a); #else static u32 PicoReadM68k16(u32 a) { u32 d=0; a&=0xfffffe; switch (a >> 17) { case 0x00>>1: // BIOS: 000000 - 020000 d = *(u16 *)(Pico_mcd->bios+a); break; case 0x02>>1: // prg RAM if ((Pico_mcd->m.busreq&3)!=1) { u8 *prg_bank = Pico_mcd->prg_ram_b[Pico_mcd->s68k_regs[3]>>6]; wrdprintf("m68k_prgram r16: [%i,%06x] @%06x", Pico_mcd->s68k_regs[3]>>6, a, SekPc); d = *(u16 *)(prg_bank+(a&0x1fffe)); wrdprintf("ret = %04x", d); } break; case 0x20>>1: // word RAM: 200000 - 220000 wrdprintf("m68k_wram r16: [%06x] @%06x", a, SekPc); a &= 0x1fffe; if (Pico_mcd->s68k_regs[3]&4) { // 1M mode? int bank = Pico_mcd->s68k_regs[3]&1; d = *(u16 *)(Pico_mcd->word_ram1M[bank]+a); } else { // allow access in any mode, like Gens does d = *(u16 *)(Pico_mcd->word_ram2M+a); } wrdprintf("ret = %04x", d); break; case 0x22>>1: // word RAM: 220000 - 240000 wrdprintf("m68k_wram r16: [%06x] @%06x", a, SekPc); if (Pico_mcd->s68k_regs[3]&4) { // 1M mode? int bank = Pico_mcd->s68k_regs[3]&1; a = (a&2) | (cell_map(a >> 2) << 2); // cell arranged d = *(u16 *)(Pico_mcd->word_ram1M[bank]+a); } else { // allow access in any mode, like Gens does d = *(u16 *)(Pico_mcd->word_ram2M+(a&0x3fffe)); } wrdprintf("ret = %04x", d); break; case 0xc0>>1: case 0xc2>>1: case 0xc4>>1: case 0xc6>>1: case 0xc8>>1: case 0xca>>1: case 0xcc>>1: case 0xce>>1: case 0xd0>>1: case 0xd2>>1: case 0xd4>>1: case 0xd6>>1: case 0xd8>>1: case 0xda>>1: case 0xdc>>1: case 0xde>>1: // VDP if ((a&0xe700e0)==0xc00000) d=PicoVideoRead(a); break; case 0xe0>>1: case 0xe2>>1: case 0xe4>>1: case 0xe6>>1: case 0xe8>>1: case 0xea>>1: case 0xec>>1: case 0xee>>1: case 0xf0>>1: case 0xf2>>1: case 0xf4>>1: case 0xf6>>1: case 0xf8>>1: case 0xfa>>1: case 0xfc>>1: case 0xfe>>1: // RAM: d=*(u16 *)(Pico.ram+(a&0xfffe)); break; default: if ((a&0xffffc0)==0xa12000) rdprintf("m68k_regs r16: [%02x] @%06x", a&0x3f, SekPc); d = OtherRead16(a, 16); if ((a&0xffffc0)==0xa12000) rdprintf("ret = %04x", d); break; } elprintf(EL_IO, "r16: %06x, %04x @%06x", a&0xffffff, d, SekPc); #ifdef EMU_CORE_DEBUG if (a>=Pico.romsize) { lastread_a = a; lastread_d[lrp_cyc++&15] = d; } #endif return d; } #endif #ifdef _ASM_CD_MEMORY_C u32 PicoReadM68k32(u32 a); #else static u32 PicoReadM68k32(u32 a) { u32 d=0; a&=0xfffffe; switch (a >> 17) { case 0x00>>1: { // BIOS: 000000 - 020000 u16 *pm=(u16 *)(Pico_mcd->bios+a); d = (pm[0]<<16)|pm[1]; break; } case 0x02>>1: // prg RAM if ((Pico_mcd->m.busreq&3)!=1) { u8 *prg_bank = Pico_mcd->prg_ram_b[Pico_mcd->s68k_regs[3]>>6]; u16 *pm=(u16 *)(prg_bank+(a&0x1fffe)); d = (pm[0]<<16)|pm[1]; } break; case 0x20>>1: // word RAM: 200000 - 220000 wrdprintf("m68k_wram r32: [%06x] @%06x", a, SekPc); a&=0x1fffe; if (Pico_mcd->s68k_regs[3]&4) { // 1M mode? int bank = Pico_mcd->s68k_regs[3]&1; u16 *pm=(u16 *)(Pico_mcd->word_ram1M[bank]+a); d = (pm[0]<<16)|pm[1]; } else { // allow access in any mode, like Gens does u16 *pm=(u16 *)(Pico_mcd->word_ram2M+a); d = (pm[0]<<16)|pm[1]; } wrdprintf("ret = %08x", d); break; case 0x22>>1: // word RAM: 220000 - 240000 wrdprintf("m68k_wram r32: [%06x] @%06x", a, SekPc); if (Pico_mcd->s68k_regs[3]&4) { // 1M mode, cell arranged? u32 a1, a2; int bank = Pico_mcd->s68k_regs[3]&1; a1 = (a&2) | (cell_map(a >> 2) << 2); if (a&2) a2 = cell_map((a+2) >> 2) << 2; else a2 = a1 + 2; d = *(u16 *)(Pico_mcd->word_ram1M[bank]+a1) << 16; d |= *(u16 *)(Pico_mcd->word_ram1M[bank]+a2); } else { // allow access in any mode, like Gens does u16 *pm=(u16 *)(Pico_mcd->word_ram2M+(a&0x3fffe)); d = (pm[0]<<16)|pm[1]; } wrdprintf("ret = %08x", d); break; case 0xc0>>1: case 0xc2>>1: case 0xc4>>1: case 0xc6>>1: case 0xc8>>1: case 0xca>>1: case 0xcc>>1: case 0xce>>1: case 0xd0>>1: case 0xd2>>1: case 0xd4>>1: case 0xd6>>1: case 0xd8>>1: case 0xda>>1: case 0xdc>>1: case 0xde>>1: // VDP d = (PicoVideoRead(a)<<16)|PicoVideoRead(a+2); break; case 0xe0>>1: case 0xe2>>1: case 0xe4>>1: case 0xe6>>1: case 0xe8>>1: case 0xea>>1: case 0xec>>1: case 0xee>>1: case 0xf0>>1: case 0xf2>>1: case 0xf4>>1: case 0xf6>>1: case 0xf8>>1: case 0xfa>>1: case 0xfc>>1: case 0xfe>>1: { // RAM: u16 *pm=(u16 *)(Pico.ram+(a&0xfffe)); d = (pm[0]<<16)|pm[1]; break; } default: if ((a&0xffffc0)==0xa12000) rdprintf("m68k_regs r32: [%02x] @%06x", a&0x3f, SekPc); d = (OtherRead16(a, 32)<<16)|OtherRead16(a+2, 32); if ((a&0xffffc0)==0xa12000) rdprintf("ret = %08x", d); break; } elprintf(EL_IO, "r32: %06x, %08x @%06x", a&0xffffff, d, SekPc); #ifdef EMU_CORE_DEBUG if (a>=Pico.romsize) { lastread_a = a; lastread_d[lrp_cyc++&15] = d; } #endif return d; } #endif // ----------------------------------------------------------------- #ifdef _ASM_CD_MEMORY_C void PicoWriteM68k8(u32 a,u8 d); #else void PicoWriteM68k8(u32 a,u8 d) { elprintf(EL_IO, "w8 : %06x, %02x @%06x", a&0xffffff, d, SekPc); #ifdef EMU_CORE_DEBUG lastwrite_cyc_d[lwp_cyc++&15] = d; #endif if ((a&0xe00000)==0xe00000) { // Ram *(u8 *)(Pico.ram+((a^1)&0xffff)) = d; return; } // prg RAM if ((a&0xfe0000)==0x020000 && (Pico_mcd->m.busreq&3)!=1) { u8 *prg_bank = Pico_mcd->prg_ram_b[Pico_mcd->s68k_regs[3]>>6]; *(u8 *)(prg_bank+((a^1)&0x1ffff))=d; return; } a&=0xffffff; // word RAM if ((a&0xfc0000)==0x200000) { wrdprintf("m68k_wram w8: [%06x] %02x @%06x", a, d, SekPc); if (Pico_mcd->s68k_regs[3]&4) { // 1M mode? int bank = Pico_mcd->s68k_regs[3]&1; if (a >= 0x220000) a = (a&3) | (cell_map(a >> 2) << 2); // cell arranged else a &= 0x1ffff; *(u8 *)(Pico_mcd->word_ram1M[bank]+(a^1))=d; } else { // allow access in any mode, like Gens does *(u8 *)(Pico_mcd->word_ram2M+((a^1)&0x3ffff))=d; } return; } if ((a&0xffffc0)==0xa12000) { rdprintf("m68k_regs w8: [%02x] %02x @%06x", a&0x3f, d, SekPc); m68k_reg_write8(a, d); return; } OtherWrite8(a,d); } #endif #ifdef _ASM_CD_MEMORY_C void PicoWriteM68k16(u32 a,u16 d); #else static void PicoWriteM68k16(u32 a,u16 d) { elprintf(EL_IO, "w16: %06x, %04x", a&0xffffff, d); #ifdef EMU_CORE_DEBUG lastwrite_cyc_d[lwp_cyc++&15] = d; #endif if ((a&0xe00000)==0xe00000) { // Ram *(u16 *)(Pico.ram+(a&0xfffe))=d; return; } // prg RAM if ((a&0xfe0000)==0x020000 && (Pico_mcd->m.busreq&3)!=1) { u8 *prg_bank = Pico_mcd->prg_ram_b[Pico_mcd->s68k_regs[3]>>6]; wrdprintf("m68k_prgram w16: [%i,%06x] %04x @%06x", Pico_mcd->s68k_regs[3]>>6, a, d, SekPc); *(u16 *)(prg_bank+(a&0x1fffe))=d; return; } a&=0xfffffe; // word RAM if ((a&0xfc0000)==0x200000) { wrdprintf("m68k_wram w16: [%06x] %04x @%06x", a, d, SekPc); if (Pico_mcd->s68k_regs[3]&4) { // 1M mode? int bank = Pico_mcd->s68k_regs[3]&1; if (a >= 0x220000) a = (a&2) | (cell_map(a >> 2) << 2); // cell arranged else a &= 0x1fffe; *(u16 *)(Pico_mcd->word_ram1M[bank]+a)=d; } else { // allow access in any mode, like Gens does *(u16 *)(Pico_mcd->word_ram2M+(a&0x3fffe))=d; } return; } // regs if ((a&0xffffc0)==0xa12000) { rdprintf("m68k_regs w16: [%02x] %04x @%06x", a&0x3f, d, SekPc); if (a == 0xe) { // special case, 2 byte writes would be handled differently Pico_mcd->s68k_regs[0xe] = d >> 8; #ifdef USE_POLL_DETECT if ((s68k_poll_adclk&0xfe) == 0xe && s68k_poll_cnt > POLL_LIMIT) { SekSetStopS68k(0); s68k_poll_adclk = 0; elprintf(EL_CDPOLL, "s68k poll release, a=%02x", a); } #endif return; } m68k_reg_write8(a, d>>8); m68k_reg_write8(a+1,d&0xff); return; } // VDP if ((a&0xe700e0)==0xc00000) { PicoVideoWrite(a,(u16)d); return; } OtherWrite16(a,d); } #endif #ifdef _ASM_CD_MEMORY_C void PicoWriteM68k32(u32 a,u32 d); #else static void PicoWriteM68k32(u32 a,u32 d) { elprintf(EL_IO, "w32: %06x, %08x", a&0xffffff, d); #ifdef EMU_CORE_DEBUG lastwrite_cyc_d[lwp_cyc++&15] = d; #endif if ((a&0xe00000)==0xe00000) { // Ram: u16 *pm=(u16 *)(Pico.ram+(a&0xfffe)); pm[0]=(u16)(d>>16); pm[1]=(u16)d; return; } // prg RAM if ((a&0xfe0000)==0x020000 && (Pico_mcd->m.busreq&3)!=1) { u8 *prg_bank = Pico_mcd->prg_ram_b[Pico_mcd->s68k_regs[3]>>6]; u16 *pm=(u16 *)(prg_bank+(a&0x1fffe)); pm[0]=(u16)(d>>16); pm[1]=(u16)d; return; } a&=0xfffffe; // word RAM if ((a&0xfc0000)==0x200000) { if (d != 0) // don't log clears wrdprintf("m68k_wram w32: [%06x] %08x @%06x", a, d, SekPc); if (Pico_mcd->s68k_regs[3]&4) { // 1M mode? int bank = Pico_mcd->s68k_regs[3]&1; if (a >= 0x220000) { // cell arranged u32 a1, a2; a1 = (a&2) | (cell_map(a >> 2) << 2); if (a&2) a2 = cell_map((a+2) >> 2) << 2; else a2 = a1 + 2; *(u16 *)(Pico_mcd->word_ram1M[bank]+a1) = d >> 16; *(u16 *)(Pico_mcd->word_ram1M[bank]+a2) = d; } else { u16 *pm=(u16 *)(Pico_mcd->word_ram1M[bank]+(a&0x1fffe)); pm[0]=(u16)(d>>16); pm[1]=(u16)d; } } else { // allow access in any mode, like Gens does u16 *pm=(u16 *)(Pico_mcd->word_ram2M+(a&0x3fffe)); pm[0]=(u16)(d>>16); pm[1]=(u16)d; } return; } if ((a&0xffffc0)==0xa12000) { rdprintf("m68k_regs w32: [%02x] %08x @%06x", a&0x3f, d, SekPc); if ((a&0x3e) == 0xe) dprintf("m68k FIXME: w32 [%02x]", a&0x3f); } // VDP if ((a&0xe700e0)==0xc00000) { PicoVideoWrite(a, (u16)(d>>16)); PicoVideoWrite(a+2,(u16)d); return; } OtherWrite16(a, (u16)(d>>16)); OtherWrite16(a+2,(u16)d); } #endif // ----------------------------------------------------------------- // S68k // ----------------------------------------------------------------- #ifdef _ASM_CD_MEMORY_C u32 PicoReadS68k8(u32 a); #else static u32 PicoReadS68k8(u32 a) { u32 d=0; #ifdef EMU_CORE_DEBUG u32 ab=a&0xfffffe; #endif a&=0xffffff; // prg RAM if (a < 0x80000) { d = *(Pico_mcd->prg_ram+(a^1)); goto end; } // regs if ((a&0xfffe00) == 0xff8000) { a &= 0x1ff; rdprintf("s68k_regs r8: [%02x] @ %06x", a, SekPcS68k); if (a >= 0x0e && a < 0x30) { d = Pico_mcd->s68k_regs[a]; s68k_poll_detect(a, d); rdprintf("ret = %02x", (u8)d); goto end; } else if (a >= 0x58 && a < 0x68) d = gfx_cd_read(a&~1); else d = s68k_reg_read16(a&~1); if ((a&1)==0) d>>=8; rdprintf("ret = %02x", (u8)d); goto end; } // word RAM (2M area) if ((a&0xfc0000)==0x080000) { // 080000-0bffff // test: batman returns wrdprintf("s68k_wram2M r8: [%06x] @%06x", a, SekPcS68k); if (Pico_mcd->s68k_regs[3]&4) { // 1M decode mode? int bank = (Pico_mcd->s68k_regs[3]&1)^1; d = Pico_mcd->word_ram1M[bank][((a>>1)^1)&0x1ffff]; if (a&1) d &= 0x0f; else d >>= 4; } else { // allow access in any mode, like Gens does d = Pico_mcd->word_ram2M[(a^1)&0x3ffff]; } wrdprintf("ret = %02x", (u8)d); goto end; } // word RAM (1M area) if ((a&0xfe0000)==0x0c0000 && (Pico_mcd->s68k_regs[3]&4)) { // 0c0000-0dffff int bank; wrdprintf("s68k_wram1M r8: [%06x] @%06x", a, SekPcS68k); // if (!(Pico_mcd->s68k_regs[3]&4)) // dprintf("s68k_wram1M FIXME: wrong mode"); bank = (Pico_mcd->s68k_regs[3]&1)^1; d = Pico_mcd->word_ram1M[bank][(a^1)&0x1ffff]; wrdprintf("ret = %02x", (u8)d); goto end; } // PCM if ((a&0xff8000)==0xff0000) { elprintf(EL_IO, "s68k_pcm r8: [%06x] @%06x", a, SekPcS68k); a &= 0x7fff; if (a >= 0x2000) d = Pico_mcd->pcm_ram_b[Pico_mcd->pcm.bank][(a>>1)&0xfff]; else if (a >= 0x20) { a &= 0x1e; d = Pico_mcd->pcm.ch[a>>2].addr >> PCM_STEP_SHIFT; if (a & 2) d >>= 8; } elprintf(EL_IO, "ret = %02x", (u8)d); goto end; } // bram if ((a&0xff0000)==0xfe0000) { d = Pico_mcd->bram[(a>>1)&0x1fff]; goto end; } elprintf(EL_UIO, "s68k r8 : %06x, %02x @%06x", a&0xffffff, (u8)d, SekPcS68k); end: elprintf(EL_IO, "s68k r8 : %06x, %02x @%06x", a&0xffffff, (u8)d, SekPcS68k); #ifdef EMU_CORE_DEBUG lastread_a = ab; lastread_d[lrp_cyc++&15] = d; #endif return d; } #endif #ifdef _ASM_CD_MEMORY_C u32 PicoReadS68k16(u32 a); #else static u32 PicoReadS68k16(u32 a) { u32 d=0; #ifdef EMU_CORE_DEBUG u32 ab=a&0xfffffe; #endif a&=0xfffffe; // prg RAM if (a < 0x80000) { wrdprintf("s68k_prgram r16: [%06x] @%06x", a, SekPcS68k); d = *(u16 *)(Pico_mcd->prg_ram+a); wrdprintf("ret = %04x", d); goto end; } // regs if ((a&0xfffe00) == 0xff8000) { a &= 0x1fe; rdprintf("s68k_regs r16: [%02x] @ %06x", a, SekPcS68k); if (a >= 0x58 && a < 0x68) d = gfx_cd_read(a); else d = s68k_reg_read16(a); rdprintf("ret = %04x", d); goto end; } // word RAM (2M area) if ((a&0xfc0000)==0x080000) { // 080000-0bffff wrdprintf("s68k_wram2M r16: [%06x] @%06x", a, SekPcS68k); if (Pico_mcd->s68k_regs[3]&4) { // 1M decode mode? int bank = (Pico_mcd->s68k_regs[3]&1)^1; d = Pico_mcd->word_ram1M[bank][((a>>1)^1)&0x1ffff]; d |= d << 4; d &= ~0xf0; } else { // allow access in any mode, like Gens does d = *(u16 *)(Pico_mcd->word_ram2M+(a&0x3fffe)); } wrdprintf("ret = %04x", d); goto end; } // word RAM (1M area) if ((a&0xfe0000)==0x0c0000 && (Pico_mcd->s68k_regs[3]&4)) { // 0c0000-0dffff int bank; wrdprintf("s68k_wram1M r16: [%06x] @%06x", a, SekPcS68k); // if (!(Pico_mcd->s68k_regs[3]&4)) // dprintf("s68k_wram1M FIXME: wrong mode"); bank = (Pico_mcd->s68k_regs[3]&1)^1; d = *(u16 *)(Pico_mcd->word_ram1M[bank]+(a&0x1fffe)); wrdprintf("ret = %04x", d); goto end; } // bram if ((a&0xff0000)==0xfe0000) { dprintf("FIXME: s68k_bram r16: [%06x] @%06x", a, SekPcS68k); a = (a>>1)&0x1fff; d = Pico_mcd->bram[a++]; // Gens does little endian here, and so do we.. d|= Pico_mcd->bram[a++] << 8; // This is most likely wrong dprintf("ret = %04x", d); goto end; } // PCM if ((a&0xff8000)==0xff0000) { dprintf("FIXME: s68k_pcm r16: [%06x] @%06x", a, SekPcS68k); a &= 0x7fff; if (a >= 0x2000) d = Pico_mcd->pcm_ram_b[Pico_mcd->pcm.bank][(a>>1)&0xfff]; else if (a >= 0x20) { a &= 0x1e; d = Pico_mcd->pcm.ch[a>>2].addr >> PCM_STEP_SHIFT; if (a & 2) d >>= 8; } dprintf("ret = %04x", d); goto end; } elprintf(EL_UIO, "s68k r16: %06x, %04x @%06x", a&0xffffff, d, SekPcS68k); end: elprintf(EL_IO, "s68k r16: %06x, %04x @%06x", a&0xffffff, d, SekPcS68k); #ifdef EMU_CORE_DEBUG lastread_a = ab; lastread_d[lrp_cyc++&15] = d; #endif return d; } #endif #ifdef _ASM_CD_MEMORY_C u32 PicoReadS68k32(u32 a); #else static u32 PicoReadS68k32(u32 a) { u32 d=0; #ifdef EMU_CORE_DEBUG u32 ab=a&0xfffffe; #endif a&=0xfffffe; // prg RAM if (a < 0x80000) { u16 *pm=(u16 *)(Pico_mcd->prg_ram+a); d = (pm[0]<<16)|pm[1]; goto end; } // regs if ((a&0xfffe00) == 0xff8000) { a &= 0x1fe; rdprintf("s68k_regs r32: [%02x] @ %06x", a, SekPcS68k); if (a >= 0x58 && a < 0x68) d = (gfx_cd_read(a)<<16)|gfx_cd_read(a+2); else d = (s68k_reg_read16(a)<<16)|s68k_reg_read16(a+2); rdprintf("ret = %08x", d); goto end; } // word RAM (2M area) if ((a&0xfc0000)==0x080000) { // 080000-0bffff wrdprintf("s68k_wram2M r32: [%06x] @%06x", a, SekPcS68k); if (Pico_mcd->s68k_regs[3]&4) { // 1M decode mode? int bank = (Pico_mcd->s68k_regs[3]&1)^1; a >>= 1; d = Pico_mcd->word_ram1M[bank][((a+0)^1)&0x1ffff] << 16; d |= Pico_mcd->word_ram1M[bank][((a+1)^1)&0x1ffff]; d |= d << 4; d &= 0x0f0f0f0f; } else { // allow access in any mode, like Gens does u16 *pm=(u16 *)(Pico_mcd->word_ram2M+(a&0x3fffe)); d = (pm[0]<<16)|pm[1]; } wrdprintf("ret = %08x", d); goto end; } // word RAM (1M area) if ((a&0xfe0000)==0x0c0000 && (Pico_mcd->s68k_regs[3]&4)) { // 0c0000-0dffff int bank; wrdprintf("s68k_wram1M r32: [%06x] @%06x", a, SekPcS68k); // if (!(Pico_mcd->s68k_regs[3]&4)) // dprintf("s68k_wram1M FIXME: wrong mode"); bank = (Pico_mcd->s68k_regs[3]&1)^1; u16 *pm=(u16 *)(Pico_mcd->word_ram1M[bank]+(a&0x1fffe)); d = (pm[0]<<16)|pm[1]; wrdprintf("ret = %08x", d); goto end; } // PCM if ((a&0xff8000)==0xff0000) { dprintf("s68k_pcm r32: [%06x] @%06x", a, SekPcS68k); a &= 0x7fff; if (a >= 0x2000) { a >>= 1; d = Pico_mcd->pcm_ram_b[Pico_mcd->pcm.bank][a&0xfff] << 16; d |= Pico_mcd->pcm_ram_b[Pico_mcd->pcm.bank][(a+1)&0xfff]; } else if (a >= 0x20) { a &= 0x1e; if (a & 2) { a >>= 2; d = (Pico_mcd->pcm.ch[a].addr >> (PCM_STEP_SHIFT-8)) & 0xff0000; d |= (Pico_mcd->pcm.ch[(a+1)&7].addr >> PCM_STEP_SHIFT) & 0xff; } else { d = Pico_mcd->pcm.ch[a>>2].addr >> PCM_STEP_SHIFT; d = ((d<<16)&0xff0000) | ((d>>8)&0xff); // PCM chip is LE } } dprintf("ret = %08x", d); goto end; } // bram if ((a&0xff0000)==0xfe0000) { dprintf("FIXME: s68k_bram r32: [%06x] @%06x", a, SekPcS68k); a = (a>>1)&0x1fff; d = Pico_mcd->bram[a++] << 16; // middle endian? TODO: verify against Fusion.. d|= Pico_mcd->bram[a++] << 24; d|= Pico_mcd->bram[a++]; d|= Pico_mcd->bram[a++] << 8; dprintf("ret = %08x", d); goto end; } elprintf(EL_UIO, "s68k r32: %06x, %08x @%06x", a&0xffffff, d, SekPcS68k); end: elprintf(EL_IO, "s68k r32: %06x, %08x @%06x", a&0xffffff, d, SekPcS68k); #ifdef EMU_CORE_DEBUG if (ab > 0x78) { // not vectors and stuff lastread_a = ab; lastread_d[lrp_cyc++&15] = d; } #endif return d; } #endif #ifndef _ASM_CD_MEMORY_C /* check: jaguar xj 220 (draws entire world using decode) */ static void decode_write8(u32 a, u8 d, int r3) { u8 *pd = Pico_mcd->word_ram1M[(r3 & 1)^1] + (((a>>1)^1)&0x1ffff); u8 oldmask = (a&1) ? 0xf0 : 0x0f; r3 &= 0x18; d &= 0x0f; if (!(a&1)) d <<= 4; if (r3 == 8) { if ((!(*pd & (~oldmask))) && d) goto do_it; } else if (r3 > 8) { if (d) goto do_it; } else { goto do_it; } return; do_it: *pd = d | (*pd & oldmask); } static void decode_write16(u32 a, u16 d, int r3) { u8 *pd = Pico_mcd->word_ram1M[(r3 & 1)^1] + (((a>>1)^1)&0x1ffff); //if ((a & 0x3ffff) < 0x28000) return; r3 &= 0x18; d &= 0x0f0f; d |= d >> 4; if (r3 == 8) { u8 dold = *pd; if (!(dold & 0xf0)) dold |= d & 0xf0; if (!(dold & 0x0f)) dold |= d & 0x0f; *pd = dold; } else if (r3 > 8) { u8 dold = *pd; if (!(d & 0xf0)) d |= dold & 0xf0; if (!(d & 0x0f)) d |= dold & 0x0f; *pd = d; } else { *pd = d; } } #endif // ----------------------------------------------------------------- #ifdef _ASM_CD_MEMORY_C void PicoWriteS68k8(u32 a,u8 d); #else static void PicoWriteS68k8(u32 a,u8 d) { elprintf(EL_IO, "s68k w8 : %06x, %02x @%06x", a&0xffffff, d, SekPcS68k); a&=0xffffff; #ifdef EMU_CORE_DEBUG lastwrite_cyc_d[lwp_cyc++&15] = d; #endif // prg RAM if (a < 0x80000) { u8 *pm=(u8 *)(Pico_mcd->prg_ram+(a^1)); if (a >= (Pico_mcd->s68k_regs[2]<<8)) *pm=d; return; } // regs if ((a&0xfffe00) == 0xff8000) { a &= 0x1ff; rdprintf("s68k_regs w8: [%02x] %02x @ %06x", a, d, SekPcS68k); if (a >= 0x58 && a < 0x68) gfx_cd_write16(a&~1, (d<<8)|d); else s68k_reg_write8(a,d); return; } // word RAM (2M area) if ((a&0xfc0000)==0x080000) { // 080000-0bffff int r3 = Pico_mcd->s68k_regs[3]; wrdprintf("s68k_wram2M w8: [%06x] %02x @%06x", a, d, SekPcS68k); if (r3 & 4) { // 1M decode mode? decode_write8(a, d, r3); } else { // allow access in any mode, like Gens does *(u8 *)(Pico_mcd->word_ram2M+((a^1)&0x3ffff))=d; } return; } // word RAM (1M area) if ((a&0xfe0000)==0x0c0000 && (Pico_mcd->s68k_regs[3]&4)) { // 0c0000-0dffff // Wing Commander tries to write here in wrong mode int bank; if (d) wrdprintf("s68k_wram1M w8: [%06x] %02x @%06x", a, d, SekPcS68k); // if (!(Pico_mcd->s68k_regs[3]&4)) // dprintf("s68k_wram1M FIXME: wrong mode"); bank = (Pico_mcd->s68k_regs[3]&1)^1; *(u8 *)(Pico_mcd->word_ram1M[bank]+((a^1)&0x1ffff))=d; return; } // PCM if ((a&0xff8000)==0xff0000) { a &= 0x7fff; if (a >= 0x2000) Pico_mcd->pcm_ram_b[Pico_mcd->pcm.bank][(a>>1)&0xfff] = d; else if (a < 0x12) pcm_write(a>>1, d); return; } // bram if ((a&0xff0000)==0xfe0000) { Pico_mcd->bram[(a>>1)&0x1fff] = d; SRam.changed = 1; return; } elprintf(EL_UIO, "s68k w8 : %06x, %02x @%06x", a&0xffffff, d, SekPcS68k); } #endif #ifdef _ASM_CD_MEMORY_C void PicoWriteS68k16(u32 a,u16 d); #else static void PicoWriteS68k16(u32 a,u16 d) { elprintf(EL_IO, "s68k w16: %06x, %04x @%06x", a&0xffffff, d, SekPcS68k); a&=0xfffffe; #ifdef EMU_CORE_DEBUG lastwrite_cyc_d[lwp_cyc++&15] = d; #endif // prg RAM if (a < 0x80000) { wrdprintf("s68k_prgram w16: [%06x] %04x @%06x", a, d, SekPcS68k); if (a >= (Pico_mcd->s68k_regs[2]<<8)) // needed for Dungeon Explorer *(u16 *)(Pico_mcd->prg_ram+a)=d; return; } // regs if ((a&0xfffe00) == 0xff8000) { a &= 0x1fe; rdprintf("s68k_regs w16: [%02x] %04x @ %06x", a, d, SekPcS68k); if (a >= 0x58 && a < 0x68) gfx_cd_write16(a, d); else { if (a == 0xe) { // special case, 2 byte writes would be handled differently Pico_mcd->s68k_regs[0xf] = d; return; } s68k_reg_write8(a, d>>8); s68k_reg_write8(a+1,d&0xff); } return; } // word RAM (2M area) if ((a&0xfc0000)==0x080000) { // 080000-0bffff int r3 = Pico_mcd->s68k_regs[3]; wrdprintf("s68k_wram2M w16: [%06x] %04x @%06x", a, d, SekPcS68k); if (r3 & 4) { // 1M decode mode? decode_write16(a, d, r3); } else { // allow access in any mode, like Gens does *(u16 *)(Pico_mcd->word_ram2M+(a&0x3fffe))=d; } return; } // word RAM (1M area) if ((a&0xfe0000)==0x0c0000 && (Pico_mcd->s68k_regs[3]&4)) { // 0c0000-0dffff int bank; if (d) wrdprintf("s68k_wram1M w16: [%06x] %04x @%06x", a, d, SekPcS68k); // if (!(Pico_mcd->s68k_regs[3]&4)) // dprintf("s68k_wram1M FIXME: wrong mode"); bank = (Pico_mcd->s68k_regs[3]&1)^1; *(u16 *)(Pico_mcd->word_ram1M[bank]+(a&0x1fffe))=d; return; } // PCM if ((a&0xff8000)==0xff0000) { a &= 0x7fff; if (a >= 0x2000) Pico_mcd->pcm_ram_b[Pico_mcd->pcm.bank][(a>>1)&0xfff] = d; else if (a < 0x12) pcm_write(a>>1, d & 0xff); return; } // bram if ((a&0xff0000)==0xfe0000) { dprintf("s68k_bram w16: [%06x] %04x @%06x", a, d, SekPcS68k); a = (a>>1)&0x1fff; Pico_mcd->bram[a++] = d; // Gens does little endian here, an so do we.. Pico_mcd->bram[a++] = d >> 8; SRam.changed = 1; return; } elprintf(EL_UIO, "s68k w16: %06x, %04x @%06x", a&0xffffff, d, SekPcS68k); } #endif #ifdef _ASM_CD_MEMORY_C void PicoWriteS68k32(u32 a,u32 d); #else static void PicoWriteS68k32(u32 a,u32 d) { elprintf(EL_IO, "s68k w32: %06x, %08x @%06x", a&0xffffff, d, SekPcS68k); a&=0xfffffe; #ifdef EMU_CORE_DEBUG lastwrite_cyc_d[lwp_cyc++&15] = d; #endif // prg RAM if (a < 0x80000) { if (a >= (Pico_mcd->s68k_regs[2]<<8)) { u16 *pm=(u16 *)(Pico_mcd->prg_ram+a); pm[0]=(u16)(d>>16); pm[1]=(u16)d; } return; } // regs if ((a&0xfffe00) == 0xff8000) { a &= 0x1fe; rdprintf("s68k_regs w32: [%02x] %08x @ %06x", a, d, SekPcS68k); if (a >= 0x58 && a < 0x68) { gfx_cd_write16(a, d>>16); gfx_cd_write16(a+2, d&0xffff); } else { if ((a&0x1fe) == 0xe) dprintf("s68k FIXME: w32 [%02x]", a&0x3f); s68k_reg_write8(a, d>>24); s68k_reg_write8(a+1,(d>>16)&0xff); s68k_reg_write8(a+2,(d>>8) &0xff); s68k_reg_write8(a+3, d &0xff); } return; } // word RAM (2M area) if ((a&0xfc0000)==0x080000) { // 080000-0bffff int r3 = Pico_mcd->s68k_regs[3]; wrdprintf("s68k_wram2M w32: [%06x] %08x @%06x", a, d, SekPcS68k); if (r3 & 4) { // 1M decode mode? decode_write16(a , d >> 16, r3); decode_write16(a+2, d , r3); } else { // allow access in any mode, like Gens does u16 *pm=(u16 *)(Pico_mcd->word_ram2M+(a&0x3fffe)); pm[0]=(u16)(d>>16); pm[1]=(u16)d; } return; } // word RAM (1M area) if ((a&0xfe0000)==0x0c0000 && (Pico_mcd->s68k_regs[3]&4)) { // 0c0000-0dffff int bank; u16 *pm; if (d) wrdprintf("s68k_wram1M w32: [%06x] %08x @%06x", a, d, SekPcS68k); // if (!(Pico_mcd->s68k_regs[3]&4)) // dprintf("s68k_wram1M FIXME: wrong mode"); bank = (Pico_mcd->s68k_regs[3]&1)^1; pm=(u16 *)(Pico_mcd->word_ram1M[bank]+(a&0x1fffe)); pm[0]=(u16)(d>>16); pm[1]=(u16)d; return; } // PCM if ((a&0xff8000)==0xff0000) { a &= 0x7fff; if (a >= 0x2000) { a >>= 1; Pico_mcd->pcm_ram_b[Pico_mcd->pcm.bank][a&0xfff] = (d >> 16); Pico_mcd->pcm_ram_b[Pico_mcd->pcm.bank][(a+1)&0xfff] = d; } else if (a < 0x12) { a >>= 1; pcm_write(a, (d>>16) & 0xff); pcm_write(a+1, d & 0xff); } return; } // bram if ((a&0xff0000)==0xfe0000) { dprintf("s68k_bram w32: [%06x] %08x @%06x", a, d, SekPcS68k); a = (a>>1)&0x1fff; Pico_mcd->bram[a++] = d >> 16; // middle endian? verify? Pico_mcd->bram[a++] = d >> 24; Pico_mcd->bram[a++] = d; Pico_mcd->bram[a++] = d >> 8; SRam.changed = 1; return; } elprintf(EL_UIO, "s68k w32: %06x, %08x @%06x", a&0xffffff, d, SekPcS68k); } #endif // ----------------------------------------------------------------- #ifdef EMU_C68K static __inline int PicoMemBaseM68k(u32 pc) { if ((pc&0xe00000)==0xe00000) return (int)Pico.ram-(pc&0xff0000); // Program Counter in Ram if (pc < 0x20000) return (int)Pico_mcd->bios; // Program Counter in BIOS if ((pc&0xfc0000)==0x200000) { if (!(Pico_mcd->s68k_regs[3]&4)) return (int)Pico_mcd->word_ram2M - 0x200000; // Program Counter in Word Ram if (pc < 0x220000) { int bank = Pico_mcd->s68k_regs[3]&1; return (int)Pico_mcd->word_ram1M[bank] - 0x200000; } } // Error - Program Counter is invalid elprintf(EL_ANOMALY, "m68k FIXME: unhandled jump to %06x", pc); return (int)Pico_mcd->bios; } static u32 PicoCheckPcM68k(u32 pc) { pc-=PicoCpuCM68k.membase; // Get real pc pc&=0xfffffe; PicoCpuCM68k.membase=PicoMemBaseM68k(pc); return PicoCpuCM68k.membase+pc; } static __inline int PicoMemBaseS68k(u32 pc) { if (pc < 0x80000) // PRG RAM return (int)Pico_mcd->prg_ram; if ((pc&0xfc0000)==0x080000) // WORD RAM 2M area (assume we are in the right mode..) return (int)Pico_mcd->word_ram2M - 0x080000; if ((pc&0xfe0000)==0x0c0000) { // word RAM 1M area int bank = (Pico_mcd->s68k_regs[3]&1)^1; return (int)Pico_mcd->word_ram1M[bank] - 0x0c0000; } // Error - Program Counter is invalid elprintf(EL_ANOMALY, "s68k FIXME: unhandled jump to %06x", pc); return (int)Pico_mcd->prg_ram; } static u32 PicoCheckPcS68k(u32 pc) { pc-=PicoCpuCS68k.membase; // Get real pc pc&=0xfffffe; PicoCpuCS68k.membase=PicoMemBaseS68k(pc); return PicoCpuCS68k.membase+pc; } #endif #ifndef _ASM_CD_MEMORY_C void PicoMemResetCD(int r3) { #ifdef EMU_F68K // update fetchmap.. int i; if (!(r3 & 4)) { for (i = M68K_FETCHBANK1*2/16; (i<<(24-FAMEC_FETCHBITS)) < 0x240000; i++) PicoCpuFM68k.Fetch[i] = (unsigned int)Pico_mcd->word_ram2M - 0x200000; } else { for (i = M68K_FETCHBANK1*2/16; (i<<(24-FAMEC_FETCHBITS)) < 0x220000; i++) PicoCpuFM68k.Fetch[i] = (unsigned int)Pico_mcd->word_ram1M[r3 & 1] - 0x200000; for (i = M68K_FETCHBANK1*0x0c/0x100; (i<<(24-FAMEC_FETCHBITS)) < 0x0e0000; i++) PicoCpuFS68k.Fetch[i] = (unsigned int)Pico_mcd->word_ram1M[(r3&1)^1] - 0x0c0000; } #endif } #endif PICO_INTERNAL void PicoMemSetupCD(void) { // additional handlers for common code PicoRead16Hook = OtherRead16End; PicoWrite8Hook = OtherWrite8End; #ifdef EMU_C68K // Setup m68k memory callbacks: PicoCpuCM68k.checkpc=PicoCheckPcM68k; PicoCpuCM68k.fetch8 =PicoCpuCM68k.read8 =PicoReadM68k8; PicoCpuCM68k.fetch16=PicoCpuCM68k.read16=PicoReadM68k16; PicoCpuCM68k.fetch32=PicoCpuCM68k.read32=PicoReadM68k32; PicoCpuCM68k.write8 =PicoWriteM68k8; PicoCpuCM68k.write16=PicoWriteM68k16; PicoCpuCM68k.write32=PicoWriteM68k32; // s68k PicoCpuCS68k.checkpc=PicoCheckPcS68k; PicoCpuCS68k.fetch8 =PicoCpuCS68k.read8 =PicoReadS68k8; PicoCpuCS68k.fetch16=PicoCpuCS68k.read16=PicoReadS68k16; PicoCpuCS68k.fetch32=PicoCpuCS68k.read32=PicoReadS68k32; PicoCpuCS68k.write8 =PicoWriteS68k8; PicoCpuCS68k.write16=PicoWriteS68k16; PicoCpuCS68k.write32=PicoWriteS68k32; #endif #ifdef EMU_F68K // m68k PicoCpuFM68k.read_byte =PicoReadM68k8; PicoCpuFM68k.read_word =PicoReadM68k16; PicoCpuFM68k.read_long =PicoReadM68k32; PicoCpuFM68k.write_byte=PicoWriteM68k8; PicoCpuFM68k.write_word=PicoWriteM68k16; PicoCpuFM68k.write_long=PicoWriteM68k32; // s68k PicoCpuFS68k.read_byte =PicoReadS68k8; PicoCpuFS68k.read_word =PicoReadS68k16; PicoCpuFS68k.read_long =PicoReadS68k32; PicoCpuFS68k.write_byte=PicoWriteS68k8; PicoCpuFS68k.write_word=PicoWriteS68k16; PicoCpuFS68k.write_long=PicoWriteS68k32; // setup FAME fetchmap { int i; // M68k // by default, point everything to fitst 64k of ROM (BIOS) for (i = 0; i < M68K_FETCHBANK1; i++) PicoCpuFM68k.Fetch[i] = (unsigned int)Pico.rom - (i<<(24-FAMEC_FETCHBITS)); // now real ROM (BIOS) for (i = 0; i < M68K_FETCHBANK1 && (i<<(24-FAMEC_FETCHBITS)) < Pico.romsize; i++) PicoCpuFM68k.Fetch[i] = (unsigned int)Pico.rom; // .. and RAM for (i = M68K_FETCHBANK1*14/16; i < M68K_FETCHBANK1; i++) PicoCpuFM68k.Fetch[i] = (unsigned int)Pico.ram - (i<<(24-FAMEC_FETCHBITS)); // S68k // PRG RAM is default for (i = 0; i < M68K_FETCHBANK1; i++) PicoCpuFS68k.Fetch[i] = (unsigned int)Pico_mcd->prg_ram - (i<<(24-FAMEC_FETCHBITS)); // real PRG RAM for (i = 0; i < M68K_FETCHBANK1 && (i<<(24-FAMEC_FETCHBITS)) < 0x80000; i++) PicoCpuFS68k.Fetch[i] = (unsigned int)Pico_mcd->prg_ram; // WORD RAM 2M area for (i = M68K_FETCHBANK1*0x08/0x100; i < M68K_FETCHBANK1 && (i<<(24-FAMEC_FETCHBITS)) < 0xc0000; i++) PicoCpuFS68k.Fetch[i] = (unsigned int)Pico_mcd->word_ram2M - 0x80000; // PicoMemResetCD() will setup word ram for both } #endif // m68k_poll_addr = m68k_poll_cnt = 0; s68k_poll_adclk = s68k_poll_cnt = 0; } #ifdef EMU_M68K unsigned char PicoReadCD8w (unsigned int a) { return m68ki_cpu_p == &PicoCpuMS68k ? PicoReadS68k8(a) : PicoReadM68k8(a); } unsigned short PicoReadCD16w(unsigned int a) { return m68ki_cpu_p == &PicoCpuMS68k ? PicoReadS68k16(a) : PicoReadM68k16(a); } unsigned int PicoReadCD32w(unsigned int a) { return m68ki_cpu_p == &PicoCpuMS68k ? PicoReadS68k32(a) : PicoReadM68k32(a); } void PicoWriteCD8w (unsigned int a, unsigned char d) { if (m68ki_cpu_p == &PicoCpuMS68k) PicoWriteS68k8(a, d); else PicoWriteM68k8(a, d); } void PicoWriteCD16w(unsigned int a, unsigned short d) { if (m68ki_cpu_p == &PicoCpuMS68k) PicoWriteS68k16(a, d); else PicoWriteM68k16(a, d); } void PicoWriteCD32w(unsigned int a, unsigned int d) { if (m68ki_cpu_p == &PicoCpuMS68k) PicoWriteS68k32(a, d); else PicoWriteM68k32(a, d); } // these are allowed to access RAM unsigned int m68k_read_pcrelative_CD8 (unsigned int a) { a&=0xffffff; if(m68ki_cpu_p == &PicoCpuMS68k) { if (a < 0x80000) return *(u8 *)(Pico_mcd->prg_ram+(a^1)); // PRG Ram if ((a&0xfc0000)==0x080000 && !(Pico_mcd->s68k_regs[3]&4)) // word RAM (2M area: 080000-0bffff) return *(u8 *)(Pico_mcd->word_ram2M+((a^1)&0x3ffff)); if ((a&0xfe0000)==0x0c0000 && (Pico_mcd->s68k_regs[3]&4)) { // word RAM (1M area: 0c0000-0dffff) int bank = (Pico_mcd->s68k_regs[3]&1)^1; return *(u8 *)(Pico_mcd->word_ram1M[bank]+((a^1)&0x1ffff)); } elprintf(EL_ANOMALY, "s68k_read_pcrelative_CD8 FIXME: can't handle %06x", a); } else { if((a&0xe00000)==0xe00000) return *(u8 *)(Pico.ram+((a^1)&0xffff)); // Ram if(a<0x20000) return *(u8 *)(Pico.rom+(a^1)); // Bios if((a&0xfc0000)==0x200000) { // word RAM if(!(Pico_mcd->s68k_regs[3]&4)) // 2M? return *(u8 *)(Pico_mcd->word_ram2M+((a^1)&0x3ffff)); else if (a < 0x220000) { int bank = Pico_mcd->s68k_regs[3]&1; return *(u8 *)(Pico_mcd->word_ram1M[bank]+((a^1)&0x1ffff)); } } elprintf(EL_ANOMALY, "m68k_read_pcrelative_CD8 FIXME: can't handle %06x", a); } return 0;//(u8) lastread_d; } unsigned int m68k_read_pcrelative_CD16(unsigned int a) { a&=0xffffff; if(m68ki_cpu_p == &PicoCpuMS68k) { if (a < 0x80000) return *(u16 *)(Pico_mcd->prg_ram+(a&~1)); // PRG Ram if ((a&0xfc0000)==0x080000 && !(Pico_mcd->s68k_regs[3]&4)) // word RAM (2M area: 080000-0bffff) return *(u16 *)(Pico_mcd->word_ram2M+(a&0x3fffe)); if ((a&0xfe0000)==0x0c0000 && (Pico_mcd->s68k_regs[3]&4)) { // word RAM (1M area: 0c0000-0dffff) int bank = (Pico_mcd->s68k_regs[3]&1)^1; return *(u16 *)(Pico_mcd->word_ram1M[bank]+(a&0x1fffe)); } elprintf(EL_ANOMALY, "s68k_read_pcrelative_CD16 FIXME: can't handle %06x", a); } else { if((a&0xe00000)==0xe00000) return *(u16 *)(Pico.ram+(a&0xfffe)); // Ram if(a<0x20000) return *(u16 *)(Pico.rom+(a&~1)); // Bios if((a&0xfc0000)==0x200000) { // word RAM if(!(Pico_mcd->s68k_regs[3]&4)) // 2M? return *(u16 *)(Pico_mcd->word_ram2M+(a&0x3fffe)); else if (a < 0x220000) { int bank = Pico_mcd->s68k_regs[3]&1; return *(u16 *)(Pico_mcd->word_ram1M[bank]+(a&0x1fffe)); } } elprintf(EL_ANOMALY, "m68k_read_pcrelative_CD16 FIXME: can't handle %06x", a); } return 0; } unsigned int m68k_read_pcrelative_CD32(unsigned int a) { u16 *pm; a&=0xffffff; if(m68ki_cpu_p == &PicoCpuMS68k) { if (a < 0x80000) { u16 *pm=(u16 *)(Pico_mcd->prg_ram+(a&~1)); return (pm[0]<<16)|pm[1]; } // PRG Ram if ((a&0xfc0000)==0x080000 && !(Pico_mcd->s68k_regs[3]&4)) // word RAM (2M area: 080000-0bffff) { pm=(u16 *)(Pico_mcd->word_ram2M+(a&0x3fffe)); return (pm[0]<<16)|pm[1]; } if ((a&0xfe0000)==0x0c0000 && (Pico_mcd->s68k_regs[3]&4)) { // word RAM (1M area: 0c0000-0dffff) int bank = (Pico_mcd->s68k_regs[3]&1)^1; pm=(u16 *)(Pico_mcd->word_ram1M[bank]+(a&0x1fffe)); return (pm[0]<<16)|pm[1]; } elprintf(EL_ANOMALY, "s68k_read_pcrelative_CD32 FIXME: can't handle %06x", a); } else { if((a&0xe00000)==0xe00000) { u16 *pm=(u16 *)(Pico.ram+(a&0xfffe)); return (pm[0]<<16)|pm[1]; } // Ram if(a<0x20000) { u16 *pm=(u16 *)(Pico.rom+(a&~1)); return (pm[0]<<16)|pm[1]; } if((a&0xfc0000)==0x200000) { // word RAM if(!(Pico_mcd->s68k_regs[3]&4)) // 2M? { pm=(u16 *)(Pico_mcd->word_ram2M+(a&0x3fffe)); return (pm[0]<<16)|pm[1]; } else if (a < 0x220000) { int bank = Pico_mcd->s68k_regs[3]&1; pm=(u16 *)(Pico_mcd->word_ram1M[bank]+(a&0x1fffe)); return (pm[0]<<16)|pm[1]; } } elprintf(EL_ANOMALY, "m68k_read_pcrelative_CD32 FIXME: can't handle %06x", a); } return 0; } #endif // EMU_M68K