/* * PicoDrive * (C) notaz, 2009,2010,2013 * * This work is licensed under the terms of MAME license. * See COPYING file in the top-level directory. * * Register map: * a15100 F....... R.....EA F.....AC N...VHMP 4000 // Fm Ren nrEs Aden Cart heN V H cMd Pwm * a15102 ........ ......SM ? 4002 // intS intM * a15104 ........ ......10 ........ hhhhhhhh 4004 // bk1 bk0 Hint * a15106 ........ F....SDR UE...... .....SDR 4006 // Full 68S Dma Rv fUll[fb] Empt[fb] * a15108 (32bit DREQ src) 4008 * a1510c (32bit DREQ dst) 400c * a15110 llllllll llllll00 4010 // DREQ Len * a15112 (16bit FIFO reg) 4012 * a15114 0 (16bit VRES clr) 4014 * a15116 0 (16bit Vint clr) 4016 * a15118 0 (16bit Hint clr) 4018 * a1511a .......? .......C (16bit CMD clr) 401a // TV Cm * a1511c 0 (16bit PWM clr) 401c * a1511e 0 ? 401e * a15120 (16 bytes comm) 2020 * a15130 (PWM) 2030 * * SH2 addr lines: * iii. .cc. ..xx * // Internal, Cs, x * * sh2 map, wait/bus cycles (from docs): * r w * rom 0000000-0003fff 1 - * sys reg 0004000-00040ff 1 1 * vdp reg 0004100-00041ff 5 5 * vdp pal 0004200-00043ff 5 5 * cart 2000000-23fffff 6-15 * dram/fb 4000000-401ffff 5-12 1-3 * fb ovr 4020000-403ffff * sdram 6000000-603ffff 12 2 (cycles) * d.a. c0000000-? */ #include "../pico_int.h" #include "../memory.h" #include "../../cpu/sh2/compiler.h" DRC_DECLARE_SR; static const char str_mars[] = "MARS"; void *p32x_bios_g, *p32x_bios_m, *p32x_bios_s; struct Pico32xMem *Pico32xMem; static void bank_switch_rom_68k(int b); static void (*m68k_write8_io)(u32 a, u32 d); static void (*m68k_write16_io)(u32 a, u32 d); // addressing byte in 16bit reg #define REG8IN16(ptr, offs) ((u8 *)ptr)[(offs) ^ 1] // poll detection #define POLL_THRESHOLD 3 static struct { u32 addr1, addr2, cycles; int cnt; } m68k_poll; static int m68k_poll_detect(u32 a, u32 cycles, u32 flags) { int ret = 0; // support polling on 2 addresses - seen in Wolfenstein int match = (a - m68k_poll.addr1 <= 2 || a - m68k_poll.addr2 <= 2); if (match && cycles - m68k_poll.cycles <= 64 && !SekNotPolling) { // detect split 32bit access by same cycle count, and ignore those if (cycles != m68k_poll.cycles && m68k_poll.cnt++ > POLL_THRESHOLD) { if (!(Pico32x.emu_flags & flags)) { elprintf(EL_32X, "m68k poll addr %08x, cyc %u", a, cycles - m68k_poll.cycles); } Pico32x.emu_flags |= flags; ret = 1; } } else { // reset poll state in case of restart by interrupt Pico32x.emu_flags &= ~(P32XF_68KCPOLL|P32XF_68KVPOLL); SekSetStop(0); m68k_poll.cnt = 0; if (!match) { m68k_poll.addr2 = m68k_poll.addr1; m68k_poll.addr1 = a; } SekNotPolling = 0; } m68k_poll.cycles = cycles; return ret; } void p32x_m68k_poll_event(u32 flags) { if (Pico32x.emu_flags & flags) { elprintf(EL_32X, "m68k poll %02x -> %02x", Pico32x.emu_flags, Pico32x.emu_flags & ~flags); Pico32x.emu_flags &= ~flags; SekSetStop(0); } m68k_poll.addr1 = m68k_poll.addr2 = m68k_poll.cnt = 0; } static void NOINLINE sh2_poll_detect(u32 a, SH2 *sh2, u32 flags, int maxcnt) { u32 cycles_done = sh2_cycles_done_t(sh2); if (a - sh2->poll_addr <= 2 && CYCLES_GE(sh2->poll_cycles+20, cycles_done)) { if (sh2->poll_cycles != cycles_done && ++sh2->poll_cnt >= maxcnt) { if (!(sh2->state & flags)) elprintf_sh2(sh2, EL_32X, "state: %02x->%02x", sh2->state, sh2->state | flags); sh2->state |= flags; sh2_end_run(sh2, 1); pevt_log_sh2(sh2, EVT_POLL_START); #ifdef DRC_SH2 if ((a & 0xc6000000) == 0x06000000) { unsigned char *p = sh2->p_drcblk_ram; p[(a & 0x3ffff) >> SH2_DRCBLK_RAM_SHIFT] |= 0x80; } #endif } } else if (!(sh2->state & (SH2_STATE_CPOLL|SH2_STATE_VPOLL|SH2_STATE_RPOLL))) { sh2->poll_cnt = 0; sh2->poll_addr = a; } sh2->poll_cycles = cycles_done; } void NOINLINE p32x_sh2_poll_event(SH2 *sh2, u32 flags, u32 m68k_cycles) { if (sh2->state & flags) { elprintf_sh2(sh2, EL_32X, "state: %02x->%02x", sh2->state, sh2->state & ~flags); if (sh2->m68krcycles_done < m68k_cycles) sh2->m68krcycles_done = m68k_cycles; pevt_log_sh2_o(sh2, EVT_POLL_END); sh2->state &= ~flags; #ifdef DRC_SH2 if ((sh2->poll_addr & 0xc6000000) == 0x06000000) { unsigned char *p = sh2->p_drcblk_ram; p[(sh2->poll_addr & 0x3ffff) >> SH2_DRCBLK_RAM_SHIFT] &= ~0x80; } #endif } if (!(sh2->state & (SH2_STATE_CPOLL|SH2_STATE_VPOLL|SH2_STATE_RPOLL))) sh2->poll_addr = sh2->poll_cycles = sh2->poll_cnt = 0; } static void sh2s_sync_on_read(SH2 *sh2) { int cycles; if (sh2->poll_cnt != 0) return; cycles = sh2_cycles_done(sh2); if (cycles > 600) p32x_sync_other_sh2(sh2, sh2->m68krcycles_done + C_SH2_TO_M68K(sh2, cycles)); } void p32x_sh2_poll_memory(unsigned int a, SH2 *sh2) { DRC_SAVE_SR(sh2); sh2_poll_detect(a, sh2, SH2_STATE_RPOLL, 5); sh2s_sync_on_read(sh2); DRC_RESTORE_SR(sh2); } // SH2 faking //#define FAKE_SH2 #ifdef FAKE_SH2 static int p32x_csum_faked; static const u16 comm_fakevals[] = { 0x4d5f, 0x4f4b, // M_OK 0x535f, 0x4f4b, // S_OK 0x4D41, 0x5346, // MASF - Brutal Unleashed 0x5331, 0x4d31, // Darxide 0x5332, 0x4d32, 0x5333, 0x4d33, 0x0000, 0x0000, // eq for doom 0x0002, // Mortal Kombat // 0, // pad }; static u32 sh2_comm_faker(u32 a) { static int f = 0; if (a == 0x28 && !p32x_csum_faked) { p32x_csum_faked = 1; return *(unsigned short *)(Pico.rom + 0x18e); } if (f >= sizeof(comm_fakevals) / sizeof(comm_fakevals[0])) f = 0; return comm_fakevals[f++]; } #endif // ------------------------------------------------------------------ // 68k regs static u32 p32x_reg_read16(u32 a) { a &= 0x3e; #if 0 if ((a & 0x30) == 0x20) return sh2_comm_faker(a); #else if ((a & 0x30) == 0x20) { unsigned int cycles = SekCyclesDone(); int comreg = 1 << (a & 0x0f) / 2; if (cycles - msh2.m68krcycles_done > 244 || (Pico32x.comm_dirty & comreg)) p32x_sync_sh2s(cycles); if (m68k_poll_detect(a, cycles, P32XF_68KCPOLL)) { SekSetStop(1); SekEndRun(16); } goto out; } #endif if (a == 2) { // INTM, INTS unsigned int cycles = SekCyclesDone(); if (cycles - msh2.m68krcycles_done > 64) p32x_sync_sh2s(cycles); goto out; } if ((a & 0x30) == 0x30) return p32x_pwm_read16(a, NULL, SekCyclesDone()); out: return Pico32x.regs[a / 2]; } static void dreq0_write(u16 *r, u32 d) { if (!(r[6 / 2] & P32XS_68S)) { elprintf(EL_32X|EL_ANOMALY, "DREQ FIFO w16 without 68S?"); return; // ignored - tested } if (Pico32x.dmac0_fifo_ptr < DMAC_FIFO_LEN) { Pico32x.dmac_fifo[Pico32x.dmac0_fifo_ptr++] = d; if (Pico32x.dmac0_fifo_ptr == DMAC_FIFO_LEN) r[6 / 2] |= P32XS_FULL; // tested: len register decrements and 68S clears // even if SH2s/DMAC aren't active.. r[0x10 / 2]--; if (r[0x10 / 2] == 0) r[6 / 2] &= ~P32XS_68S; if ((Pico32x.dmac0_fifo_ptr & 3) == 0) { p32x_sync_sh2s(SekCyclesDone()); p32x_dreq0_trigger(); } } else elprintf(EL_32X|EL_ANOMALY, "DREQ FIFO overflow!"); } // writable bits tested static void p32x_reg_write8(u32 a, u32 d) { u16 *r = Pico32x.regs; a &= 0x3f; // for things like bset on comm port m68k_poll.cnt = 0; switch (a) { case 0x00: // adapter ctl: FM writable REG8IN16(r, 0x00) = d & 0x80; return; case 0x01: // adapter ctl: RES and ADEN writable if ((d ^ r[0]) & d & P32XS_nRES) p32x_reset_sh2s(); REG8IN16(r, 0x01) &= ~(P32XS_nRES|P32XS_ADEN); REG8IN16(r, 0x01) |= d & (P32XS_nRES|P32XS_ADEN); return; case 0x02: // ignored, always 0 return; case 0x03: // irq ctl if ((d ^ r[0x02 / 2]) & 3) { int cycles = SekCyclesDone(); p32x_sync_sh2s(cycles); r[0x02 / 2] = d & 3; p32x_update_cmd_irq(NULL, cycles); } return; case 0x04: // ignored, always 0 return; case 0x05: // bank d &= 3; if (r[0x04 / 2] != d) { r[0x04 / 2] = d; bank_switch_rom_68k(d); } return; case 0x06: // ignored, always 0 return; case 0x07: // DREQ ctl REG8IN16(r, 0x07) &= ~(P32XS_68S|P32XS_DMA|P32XS_RV); if (!(d & P32XS_68S)) { Pico32x.dmac0_fifo_ptr = 0; REG8IN16(r, 0x07) &= ~P32XS_FULL; } REG8IN16(r, 0x07) |= d & (P32XS_68S|P32XS_DMA|P32XS_RV); return; case 0x08: // ignored, always 0 return; case 0x09: // DREQ src REG8IN16(r, 0x09) = d; return; case 0x0a: REG8IN16(r, 0x0a) = d; return; case 0x0b: REG8IN16(r, 0x0b) = d & 0xfe; return; case 0x0c: // ignored, always 0 return; case 0x0d: // DREQ dest case 0x0e: case 0x0f: case 0x10: // DREQ len REG8IN16(r, a) = d; return; case 0x11: REG8IN16(r, a) = d & 0xfc; return; // DREQ FIFO - writes to odd addr go to fifo // do writes to even work? Reads return 0 case 0x12: REG8IN16(r, a) = d; return; case 0x13: d = (REG8IN16(r, 0x12) << 8) | (d & 0xff); REG8IN16(r, 0x12) = 0; dreq0_write(r, d); return; case 0x14: // ignored, always 0 case 0x15: case 0x16: case 0x17: case 0x18: case 0x19: return; case 0x1a: // what's this? elprintf(EL_32X|EL_ANOMALY, "mystery w8 %02x %02x", a, d); REG8IN16(r, a) = d & 0x01; return; case 0x1b: // TV REG8IN16(r, a) = d & 0x01; return; case 0x1c: // ignored, always 0 case 0x1d: case 0x1e: case 0x1f: case 0x30: return; case 0x31: // PWM control REG8IN16(r, a) &= ~0x0f; REG8IN16(r, a) |= d & 0x0f; d = r[0x30 / 2]; goto pwm_write; case 0x32: // PWM cycle REG8IN16(r, a) = d & 0x0f; d = r[0x32 / 2]; goto pwm_write; case 0x33: REG8IN16(r, a) = d; d = r[0x32 / 2]; goto pwm_write; // PWM pulse regs.. Only writes to odd address send a value // to FIFO; reads are 0 (except status bits) case 0x34: case 0x36: case 0x38: REG8IN16(r, a) = d; return; case 0x35: case 0x37: case 0x39: d = (REG8IN16(r, a ^ 1) << 8) | (d & 0xff); REG8IN16(r, a ^ 1) = 0; goto pwm_write; case 0x3a: // ignored, always 0 case 0x3b: case 0x3c: case 0x3d: case 0x3e: case 0x3f: return; pwm_write: p32x_pwm_write16(a & ~1, d, NULL, SekCyclesDone()); return; } if ((a & 0x30) == 0x20) { int cycles = SekCyclesDone(); int comreg; if (REG8IN16(r, a) == d) return; p32x_sync_sh2s(cycles); REG8IN16(r, a) = d; p32x_sh2_poll_event(&sh2s[0], SH2_STATE_CPOLL, cycles); p32x_sh2_poll_event(&sh2s[1], SH2_STATE_CPOLL, cycles); comreg = 1 << (a & 0x0f) / 2; Pico32x.comm_dirty |= comreg; return; } } static void p32x_reg_write16(u32 a, u32 d) { u16 *r = Pico32x.regs; a &= 0x3e; // for things like bset on comm port m68k_poll.cnt = 0; switch (a) { case 0x00: // adapter ctl if ((d ^ r[0]) & d & P32XS_nRES) p32x_reset_sh2s(); r[0] &= ~(P32XS_FM|P32XS_nRES|P32XS_ADEN); r[0] |= d & (P32XS_FM|P32XS_nRES|P32XS_ADEN); return; case 0x08: // DREQ src r[a / 2] = d & 0xff; return; case 0x0a: r[a / 2] = d & ~1; return; case 0x0c: // DREQ dest r[a / 2] = d & 0xff; return; case 0x0e: r[a / 2] = d; return; case 0x10: // DREQ len r[a / 2] = d & ~3; return; case 0x12: // FIFO reg dreq0_write(r, d); return; case 0x1a: // TV + mystery bit r[a / 2] = d & 0x0101; return; case 0x30: // PWM control d = (r[a / 2] & ~0x0f) | (d & 0x0f); r[a / 2] = d; p32x_pwm_write16(a, d, NULL, SekCyclesDone()); return; } // comm port if ((a & 0x30) == 0x20) { int cycles = SekCyclesDone(); int comreg; if (r[a / 2] == d) return; p32x_sync_sh2s(cycles); r[a / 2] = d; p32x_sh2_poll_event(&sh2s[0], SH2_STATE_CPOLL, cycles); p32x_sh2_poll_event(&sh2s[1], SH2_STATE_CPOLL, cycles); comreg = 1 << (a & 0x0f) / 2; Pico32x.comm_dirty |= comreg; return; } // PWM else if ((a & 0x30) == 0x30) { p32x_pwm_write16(a, d, NULL, SekCyclesDone()); return; } p32x_reg_write8(a + 1, d); } // ------------------------------------------------------------------ // VDP regs static u32 p32x_vdp_read16(u32 a) { u32 d; a &= 0x0e; d = Pico32x.vdp_regs[a / 2]; if (a == 0x0a) { // tested: FEN seems to be randomly pulsing on hcnt 0x80-0xf0, // most often at 0xb1-0xb5, even during vblank, // what's the deal with that? // we'll just fake it along with hblank for now Pico32x.vdp_fbcr_fake++; if (Pico32x.vdp_fbcr_fake & 4) d |= P32XV_HBLK; if ((Pico32x.vdp_fbcr_fake & 7) == 0) d |= P32XV_nFEN; } return d; } static void p32x_vdp_write8(u32 a, u32 d) { u16 *r = Pico32x.vdp_regs; a &= 0x0f; // TODO: verify what's writeable switch (a) { case 0x01: // priority inversion is handled in palette if ((r[0] ^ d) & P32XV_PRI) Pico32x.dirty_pal = 1; r[0] = (r[0] & P32XV_nPAL) | (d & 0xff); break; case 0x03: // shift (for pp mode) r[2 / 2] = d & 1; break; case 0x05: // fill len r[4 / 2] = d & 0xff; break; case 0x0b: d &= 1; Pico32x.pending_fb = d; // if we are blanking and FS bit is changing if (((r[0x0a/2] & P32XV_VBLK) || (r[0] & P32XV_Mx) == 0) && ((r[0x0a/2] ^ d) & P32XV_FS)) { r[0x0a/2] ^= P32XV_FS; Pico32xSwapDRAM(d ^ 1); elprintf(EL_32X, "VDP FS: %d", r[0x0a/2] & P32XV_FS); } break; } } static void p32x_vdp_write16(u32 a, u32 d, SH2 *sh2) { a &= 0x0e; if (a == 6) { // fill start Pico32x.vdp_regs[6 / 2] = d; return; } if (a == 8) { // fill data u16 *dram = Pico32xMem->dram[(Pico32x.vdp_regs[0x0a/2] & P32XV_FS) ^ 1]; int len = Pico32x.vdp_regs[4 / 2] + 1; int len1 = len; a = Pico32x.vdp_regs[6 / 2]; while (len1--) { dram[a] = d; a = (a & 0xff00) | ((a + 1) & 0xff); } Pico32x.vdp_regs[0x06 / 2] = a; Pico32x.vdp_regs[0x08 / 2] = d; if (sh2 != NULL && len > 4) { Pico32x.vdp_regs[0x0a / 2] |= P32XV_nFEN; // supposedly takes 3 bus/6 sh2 cycles? or 3 sh2 cycles? p32x_event_schedule_sh2(sh2, P32X_EVENT_FILLEND, 3 + len); } return; } p32x_vdp_write8(a | 1, d); } // ------------------------------------------------------------------ // SH2 regs static u32 p32x_sh2reg_read16(u32 a, SH2 *sh2) { u16 *r = Pico32x.regs; a &= 0x3e; switch (a) { case 0x00: // adapter/irq ctl return (r[0] & P32XS_FM) | Pico32x.sh2_regs[0] | Pico32x.sh2irq_mask[sh2->is_slave]; case 0x04: // H count (often as comm too) sh2_poll_detect(a, sh2, SH2_STATE_CPOLL, 7); sh2s_sync_on_read(sh2); return Pico32x.sh2_regs[4 / 2]; case 0x06: return (r[a / 2] & ~P32XS_FULL) | 0x4000; case 0x08: // DREQ src case 0x0a: case 0x0c: // DREQ dst case 0x0e: case 0x10: // DREQ len return r[a / 2]; case 0x12: // DREQ FIFO - does this work on hw? if (Pico32x.dmac0_fifo_ptr > 0) { Pico32x.dmac0_fifo_ptr--; r[a / 2] = Pico32x.dmac_fifo[0]; memmove(&Pico32x.dmac_fifo[0], &Pico32x.dmac_fifo[1], Pico32x.dmac0_fifo_ptr * 2); } return r[a / 2]; case 0x14: case 0x16: case 0x18: case 0x1a: case 0x1c: return 0; // ? } // comm port if ((a & 0x30) == 0x20) { sh2_poll_detect(a, sh2, SH2_STATE_CPOLL, 7); sh2s_sync_on_read(sh2); return r[a / 2]; } if ((a & 0x30) == 0x30) return p32x_pwm_read16(a, sh2, sh2_cycles_done_m68k(sh2)); elprintf_sh2(sh2, EL_32X|EL_ANOMALY, "unhandled sysreg r16 [%02x] @%08x", a, sh2_pc(sh2)); return 0; } static void p32x_sh2reg_write8(u32 a, u32 d, SH2 *sh2) { u16 *r = Pico32x.regs; u32 old; a &= 0x3f; sh2->poll_cnt = 0; switch (a) { case 0x00: // FM r[0] &= ~P32XS_FM; r[0] |= (d << 8) & P32XS_FM; return; case 0x01: // HEN/irq masks old = Pico32x.sh2irq_mask[sh2->is_slave]; if ((d ^ old) & 1) p32x_pwm_sync_to_sh2(sh2); Pico32x.sh2irq_mask[sh2->is_slave] = d & 0x0f; Pico32x.sh2_regs[0] &= ~0x80; Pico32x.sh2_regs[0] |= d & 0x80; if ((d ^ old) & 1) p32x_pwm_schedule_sh2(sh2); if ((old ^ d) & 2) p32x_update_cmd_irq(sh2, 0); if ((old ^ d) & 4) p32x_schedule_hint(sh2, 0); return; case 0x04: // ignored? return; case 0x05: // H count d &= 0xff; if (Pico32x.sh2_regs[4 / 2] != d) { Pico32x.sh2_regs[4 / 2] = d; p32x_sh2_poll_event(sh2->other_sh2, SH2_STATE_CPOLL, sh2_cycles_done_m68k(sh2)); sh2_end_run(sh2, 4); } return; case 0x30: REG8IN16(r, a) = d & 0x0f; d = r[0x30 / 2]; goto pwm_write; case 0x31: // PWM control REG8IN16(r, a) = d & 0x8f; d = r[0x30 / 2]; goto pwm_write; case 0x32: // PWM cycle REG8IN16(r, a) = d & 0x0f; d = r[0x32 / 2]; goto pwm_write; case 0x33: REG8IN16(r, a) = d; d = r[0x32 / 2]; goto pwm_write; // PWM pulse regs.. Only writes to odd address send a value // to FIFO; reads are 0 (except status bits) case 0x34: case 0x36: case 0x38: REG8IN16(r, a) = d; return; case 0x35: case 0x37: case 0x39: d = (REG8IN16(r, a ^ 1) << 8) | (d & 0xff); REG8IN16(r, a ^ 1) = 0; goto pwm_write; case 0x3a: // ignored, always 0? case 0x3b: case 0x3c: case 0x3d: case 0x3e: case 0x3f: return; pwm_write: p32x_pwm_write16(a & ~1, d, sh2, sh2_cycles_done_m68k(sh2)); return; } if ((a & 0x30) == 0x20) { int comreg; if (REG8IN16(r, a) == d) return; REG8IN16(r, a) = d; sh2_end_run(sh2, 1); p32x_m68k_poll_event(P32XF_68KCPOLL); p32x_sh2_poll_event(sh2->other_sh2, SH2_STATE_CPOLL, sh2_cycles_done_m68k(sh2)); comreg = 1 << (a & 0x0f) / 2; Pico32x.comm_dirty |= comreg; return; } elprintf(EL_32X|EL_ANOMALY, "unhandled sysreg w8 [%02x] %02x @%08x", a, d, sh2_pc(sh2)); } static void p32x_sh2reg_write16(u32 a, u32 d, SH2 *sh2) { a &= 0x3e; sh2->poll_cnt = 0; // comm if ((a & 0x30) == 0x20) { int comreg; if (Pico32x.regs[a / 2] == d) return; Pico32x.regs[a / 2] = d; sh2_end_run(sh2, 1); p32x_m68k_poll_event(P32XF_68KCPOLL); p32x_sh2_poll_event(sh2->other_sh2, SH2_STATE_CPOLL, sh2_cycles_done_m68k(sh2)); comreg = 1 << (a & 0x0f) / 2; Pico32x.comm_dirty |= comreg; return; } // PWM else if ((a & 0x30) == 0x30) { p32x_pwm_write16(a, d, sh2, sh2_cycles_done_m68k(sh2)); return; } switch (a) { case 0: // FM Pico32x.regs[0] &= ~P32XS_FM; Pico32x.regs[0] |= d & P32XS_FM; break; case 0x14: Pico32x.sh2irqs &= ~P32XI_VRES; goto irls; case 0x16: Pico32x.sh2irqi[sh2->is_slave] &= ~P32XI_VINT; goto irls; case 0x18: Pico32x.sh2irqi[sh2->is_slave] &= ~P32XI_HINT; goto irls; case 0x1a: Pico32x.regs[2 / 2] &= ~(1 << sh2->is_slave); p32x_update_cmd_irq(sh2, 0); return; case 0x1c: p32x_pwm_sync_to_sh2(sh2); Pico32x.sh2irqi[sh2->is_slave] &= ~P32XI_PWM; p32x_pwm_schedule_sh2(sh2); goto irls; } p32x_sh2reg_write8(a | 1, d, sh2); return; irls: p32x_update_irls(sh2, 0); } // ------------------------------------------------------------------ // 32x 68k handlers // after ADEN static u32 PicoRead8_32x_on(u32 a) { u32 d = 0; if ((a & 0xffc0) == 0x5100) { // a15100 d = p32x_reg_read16(a); goto out_16to8; } if ((a & 0xfc00) != 0x5000) { if (PicoIn.AHW & PAHW_MCD) return PicoRead8_mcd_io(a); else return PicoRead8_io(a); } if ((a & 0xfff0) == 0x5180) { // a15180 d = p32x_vdp_read16(a); goto out_16to8; } if ((a & 0xfe00) == 0x5200) { // a15200 d = Pico32xMem->pal[(a & 0x1ff) / 2]; goto out_16to8; } if ((a & 0xfffc) == 0x30ec) { // a130ec d = str_mars[a & 3]; goto out; } elprintf(EL_UIO, "m68k unmapped r8 [%06x] @%06x", a, SekPc); return d; out_16to8: if (a & 1) d &= 0xff; else d >>= 8; out: elprintf(EL_32X, "m68k 32x r8 [%06x] %02x @%06x", a, d, SekPc); return d; } static u32 PicoRead16_32x_on(u32 a) { u32 d = 0; if ((a & 0xffc0) == 0x5100) { // a15100 d = p32x_reg_read16(a); goto out; } if ((a & 0xfc00) != 0x5000) { if (PicoIn.AHW & PAHW_MCD) return PicoRead16_mcd_io(a); else return PicoRead16_io(a); } if ((a & 0xfff0) == 0x5180) { // a15180 d = p32x_vdp_read16(a); goto out; } if ((a & 0xfe00) == 0x5200) { // a15200 d = Pico32xMem->pal[(a & 0x1ff) / 2]; goto out; } if ((a & 0xfffc) == 0x30ec) { // a130ec d = !(a & 2) ? ('M'<<8)|'A' : ('R'<<8)|'S'; goto out; } elprintf(EL_UIO, "m68k unmapped r16 [%06x] @%06x", a, SekPc); return d; out: elprintf(EL_32X, "m68k 32x r16 [%06x] %04x @%06x", a, d, SekPc); return d; } static void PicoWrite8_32x_on(u32 a, u32 d) { if ((a & 0xfc00) == 0x5000) elprintf(EL_32X, "m68k 32x w8 [%06x] %02x @%06x", a, d & 0xff, SekPc); if ((a & 0xffc0) == 0x5100) { // a15100 p32x_reg_write8(a, d); return; } if ((a & 0xfc00) != 0x5000) { m68k_write8_io(a, d); return; } if (!(Pico32x.regs[0] & P32XS_FM)) { if ((a & 0xfff0) == 0x5180) { // a15180 p32x_vdp_write8(a, d); return; } // TODO: verify if ((a & 0xfe00) == 0x5200) { // a15200 elprintf(EL_32X|EL_ANOMALY, "m68k 32x PAL w8 [%06x] %02x @%06x", a, d & 0xff, SekPc); ((u8 *)Pico32xMem->pal)[(a & 0x1ff) ^ 1] = d; Pico32x.dirty_pal = 1; return; } } elprintf(EL_UIO, "m68k unmapped w8 [%06x] %02x @%06x", a, d & 0xff, SekPc); } static void PicoWrite8_32x_on_io(u32 a, u32 d) { PicoWrite8_io(a, d); if (a == 0xa130f1) bank_switch_rom_68k(Pico32x.regs[4 / 2]); } static void PicoWrite8_32x_on_io_cd(u32 a, u32 d) { PicoWrite8_mcd_io(a, d); if (a == 0xa130f1) bank_switch_rom_68k(Pico32x.regs[4 / 2]); } static void PicoWrite8_32x_on_io_ssf2(u32 a, u32 d) { carthw_ssf2_write8(a, d); if ((a & ~0x0e) == 0xa130f1) bank_switch_rom_68k(Pico32x.regs[4 / 2]); } static void PicoWrite16_32x_on(u32 a, u32 d) { if ((a & 0xfc00) == 0x5000) elprintf(EL_32X, "m68k 32x w16 [%06x] %04x @%06x", a, d & 0xffff, SekPc); if ((a & 0xffc0) == 0x5100) { // a15100 p32x_reg_write16(a, d); return; } if ((a & 0xfc00) != 0x5000) { m68k_write16_io(a, d); return; } if (!(Pico32x.regs[0] & P32XS_FM)) { if ((a & 0xfff0) == 0x5180) { // a15180 p32x_vdp_write16(a, d, NULL); // FIXME? return; } if ((a & 0xfe00) == 0x5200) { // a15200 Pico32xMem->pal[(a & 0x1ff) / 2] = d; Pico32x.dirty_pal = 1; return; } } elprintf(EL_UIO, "m68k unmapped w16 [%06x] %04x @%06x", a, d & 0xffff, SekPc); } static void PicoWrite16_32x_on_io(u32 a, u32 d) { PicoWrite16_io(a, d); if (a == 0xa130f0) bank_switch_rom_68k(Pico32x.regs[4 / 2]); } static void PicoWrite16_32x_on_io_cd(u32 a, u32 d) { PicoWrite16_mcd_io(a, d); if (a == 0xa130f0) bank_switch_rom_68k(Pico32x.regs[4 / 2]); } static void PicoWrite16_32x_on_io_ssf2(u32 a, u32 d) { PicoWrite16_io(a, d); if ((a & ~0x0f) == 0xa130f0) { carthw_ssf2_write8(a + 1, d); bank_switch_rom_68k(Pico32x.regs[4 / 2]); } } // before ADEN u32 PicoRead8_32x(u32 a) { u32 d = 0; if (PicoIn.opt & POPT_EN_32X) { if ((a & 0xffc0) == 0x5100) { // a15100 // regs are always readable d = ((u8 *)Pico32x.regs)[(a & 0x3f) ^ 1]; goto out; } if ((a & 0xfffc) == 0x30ec) { // a130ec d = str_mars[a & 3]; goto out; } } elprintf(EL_UIO, "m68k unmapped r8 [%06x] @%06x", a, SekPc); return d; out: elprintf(EL_32X, "m68k 32x r8 [%06x] %02x @%06x", a, d, SekPc); return d; } u32 PicoRead16_32x(u32 a) { u32 d = 0; if (PicoIn.opt & POPT_EN_32X) { if ((a & 0xffc0) == 0x5100) { // a15100 d = Pico32x.regs[(a & 0x3f) / 2]; goto out; } if ((a & 0xfffc) == 0x30ec) { // a130ec d = !(a & 2) ? ('M'<<8)|'A' : ('R'<<8)|'S'; goto out; } } elprintf(EL_UIO, "m68k unmapped r16 [%06x] @%06x", a, SekPc); return d; out: elprintf(EL_32X, "m68k 32x r16 [%06x] %04x @%06x", a, d, SekPc); return d; } void PicoWrite8_32x(u32 a, u32 d) { if ((PicoIn.opt & POPT_EN_32X) && (a & 0xffc0) == 0x5100) // a15100 { u16 *r = Pico32x.regs; elprintf(EL_32X, "m68k 32x w8 [%06x] %02x @%06x", a, d & 0xff, SekPc); a &= 0x3f; if (a == 1) { if ((d ^ r[0]) & d & P32XS_ADEN) { Pico32xStartup(); r[0] &= ~P32XS_nRES; // causes reset if specified by this write r[0] |= P32XS_ADEN; p32x_reg_write8(a, d); // forward for reset processing } return; } // allow only COMM for now if ((a & 0x30) == 0x20) { u8 *r8 = (u8 *)r; r8[a ^ 1] = d; } return; } elprintf(EL_UIO, "m68k unmapped w8 [%06x] %02x @%06x", a, d & 0xff, SekPc); } void PicoWrite16_32x(u32 a, u32 d) { if ((PicoIn.opt & POPT_EN_32X) && (a & 0xffc0) == 0x5100) // a15100 { u16 *r = Pico32x.regs; elprintf(EL_UIO, "m68k 32x w16 [%06x] %04x @%06x", a, d & 0xffff, SekPc); a &= 0x3e; if (a == 0) { if ((d ^ r[0]) & d & P32XS_ADEN) { Pico32xStartup(); r[0] &= ~P32XS_nRES; // causes reset if specified by this write r[0] |= P32XS_ADEN; p32x_reg_write16(a, d); // forward for reset processing } return; } // allow only COMM for now if ((a & 0x30) == 0x20) r[a / 2] = d; return; } elprintf(EL_UIO, "m68k unmapped w16 [%06x] %04x @%06x", a, d & 0xffff, SekPc); } /* quirk: in both normal and overwrite areas only nonzero values go through */ #define sh2_write8_dramN(p, a, d) \ if ((d & 0xff) != 0) { \ u8 *dram = (u8 *)p; \ dram[(a & 0x1ffff) ^ 1] = d; \ } static void m68k_write8_dram0_ow(u32 a, u32 d) { sh2_write8_dramN(Pico32xMem->dram[0], a, d); } static void m68k_write8_dram1_ow(u32 a, u32 d) { sh2_write8_dramN(Pico32xMem->dram[1], a, d); } #define sh2_write16_dramN(p, a, d) \ u16 *pd = &((u16 *)p)[(a & 0x1ffff) / 2]; \ if (!(a & 0x20000)) { \ *pd = d; \ } else { \ u16 v = *pd; /* overwrite */ \ if (!(d & 0x00ff)) d |= v & 0x00ff; \ if (!(d & 0xff00)) d |= v & 0xff00; \ *pd = d; \ } static void m68k_write16_dram0_ow(u32 a, u32 d) { sh2_write16_dramN(Pico32xMem->dram[0], a, d); } static void m68k_write16_dram1_ow(u32 a, u32 d) { sh2_write16_dramN(Pico32xMem->dram[1], a, d); } // ----------------------------------------------------------------- // hint vector is writeable static void PicoWrite8_hint(u32 a, u32 d) { if ((a & 0xfffc) == 0x0070) { Pico32xMem->m68k_rom[a ^ 1] = d; return; } elprintf(EL_UIO, "m68k unmapped w8 [%06x] %02x @%06x", a, d & 0xff, SekPc); } static void PicoWrite16_hint(u32 a, u32 d) { if ((a & 0xfffc) == 0x0070) { ((u16 *)Pico32xMem->m68k_rom)[a/2] = d; return; } elprintf(EL_UIO, "m68k unmapped w16 [%06x] %04x @%06x", a, d & 0xffff, SekPc); } // normally not writable, but somebody could make a RAM cart static void PicoWrite8_cart(u32 a, u32 d) { elprintf(EL_UIO, "m68k w8 [%06x] %02x @%06x", a, d & 0xff, SekPc); a &= 0xfffff; m68k_write8(a, d); } static void PicoWrite16_cart(u32 a, u32 d) { elprintf(EL_UIO, "m68k w16 [%06x] %04x @%06x", a, d & 0xffff, SekPc); a &= 0xfffff; m68k_write16(a, d); } // same with bank, but save ram is sometimes here static u32 PicoRead8_bank(u32 a) { a = (Pico32x.regs[4 / 2] << 20) | (a & 0xfffff); return m68k_read8(a); } static u32 PicoRead16_bank(u32 a) { a = (Pico32x.regs[4 / 2] << 20) | (a & 0xfffff); return m68k_read16(a); } static void PicoWrite8_bank(u32 a, u32 d) { if (!(Pico.m.sram_reg & SRR_MAPPED)) elprintf(EL_UIO, "m68k w8 [%06x] %02x @%06x", a, d & 0xff, SekPc); a = (Pico32x.regs[4 / 2] << 20) | (a & 0xfffff); m68k_write8(a, d); } static void PicoWrite16_bank(u32 a, u32 d) { if (!(Pico.m.sram_reg & SRR_MAPPED)) elprintf(EL_UIO, "m68k w16 [%06x] %04x @%06x", a, d & 0xffff, SekPc); a = (Pico32x.regs[4 / 2] << 20) | (a & 0xfffff); m68k_write16(a, d); } static void bank_map_handler(void) { cpu68k_map_set(m68k_read8_map, 0x900000, 0x9fffff, PicoRead8_bank, 1); cpu68k_map_set(m68k_read16_map, 0x900000, 0x9fffff, PicoRead16_bank, 1); } static void bank_switch_rom_68k(int b) { unsigned int rs, bank, bank2; if (Pico.m.ncart_in) return; bank = b << 20; if ((Pico.m.sram_reg & SRR_MAPPED) && bank == Pico.sv.start) { bank_map_handler(); return; } if (bank >= Pico.romsize) { elprintf(EL_32X|EL_ANOMALY, "missing bank @ %06x", bank); bank_map_handler(); return; } // 32X ROM (XXX: consider mirroring?) rs = (Pico.romsize + M68K_BANK_MASK) & ~M68K_BANK_MASK; if (!carthw_ssf2_active) { rs -= bank; if (rs > 0x100000) rs = 0x100000; cpu68k_map_set(m68k_read8_map, 0x900000, 0x900000 + rs - 1, Pico.rom + bank, 0); cpu68k_map_set(m68k_read16_map, 0x900000, 0x900000 + rs - 1, Pico.rom + bank, 0); elprintf(EL_32X, "bank %06x-%06x -> %06x", 0x900000, 0x900000 + rs - 1, bank); } else { bank = bank >> 19; bank2 = carthw_ssf2_banks[bank + 0] << 19; cpu68k_map_set(m68k_read8_map, 0x900000, 0x97ffff, Pico.rom + bank2, 0); cpu68k_map_set(m68k_read16_map, 0x900000, 0x97ffff, Pico.rom + bank2, 0); bank2 = carthw_ssf2_banks[bank + 1] << 19; cpu68k_map_set(m68k_read8_map, 0x980000, 0x9fffff, Pico.rom + bank2, 0); cpu68k_map_set(m68k_read16_map, 0x980000, 0x9fffff, Pico.rom + bank2, 0); } } // ----------------------------------------------------------------- // SH2 // ----------------------------------------------------------------- // read8 static REGPARM(2) u32 sh2_read8_unmapped(u32 a, SH2 *sh2) { elprintf_sh2(sh2, EL_32X, "unmapped r8 [%08x] %02x @%06x", a, 0, sh2_pc(sh2)); return 0; } static u32 REGPARM(2) sh2_read8_cs0(u32 a, SH2 *sh2) { u32 d = 0; DRC_SAVE_SR(sh2); sh2_burn_cycles(sh2, 1*2); // 0x3ffc0 is veridied if ((a & 0x3ffc0) == 0x4000) { d = p32x_sh2reg_read16(a, sh2); goto out_16to8; } if ((a & 0x3fff0) == 0x4100) { d = p32x_vdp_read16(a); sh2_poll_detect(a, sh2, SH2_STATE_VPOLL, 9); goto out_16to8; } if ((a & 0x3fe00) == 0x4200) { d = Pico32xMem->pal[(a & 0x1ff) / 2]; goto out_16to8; } // TODO: mirroring? if (!sh2->is_slave && a < sizeof(Pico32xMem->sh2_rom_m)) d = Pico32xMem->sh2_rom_m.b[a ^ 1]; else if (sh2->is_slave && a < sizeof(Pico32xMem->sh2_rom_s)) d = Pico32xMem->sh2_rom_s.b[a ^ 1]; else d = sh2_read8_unmapped(a, sh2); goto out; out_16to8: if (a & 1) d &= 0xff; else d >>= 8; out: elprintf_sh2(sh2, EL_32X, "r8 [%08x] %02x @%06x", a, d, sh2_pc(sh2)); DRC_RESTORE_SR(sh2); return (s8)d; } // for ssf2 static u32 REGPARM(2) sh2_read8_rom(u32 a, SH2 *sh2) { u32 bank = carthw_ssf2_banks[(a >> 19) & 7] << 19; s8 *p = sh2->p_rom; return p[(bank + (a & 0x7ffff)) ^ 1]; } // read16 static u32 REGPARM(2) sh2_read16_unmapped(u32 a, SH2 *sh2) { elprintf_sh2(sh2, EL_32X, "unmapped r16 [%08x] %04x @%06x", a, 0, sh2_pc(sh2)); return 0; } static u32 REGPARM(2) sh2_read16_cs0(u32 a, SH2 *sh2) { u32 d = 0; DRC_SAVE_SR(sh2); sh2_burn_cycles(sh2, 1*2); if ((a & 0x3ffc0) == 0x4000) { d = p32x_sh2reg_read16(a, sh2); if (!(EL_LOGMASK & EL_PWM) && (a & 0x30) == 0x30) // hide PWM goto out_noprint; goto out; } if ((a & 0x3fff0) == 0x4100) { d = p32x_vdp_read16(a); sh2_poll_detect(a, sh2, SH2_STATE_VPOLL, 9); goto out; } if ((a & 0x3fe00) == 0x4200) { d = Pico32xMem->pal[(a & 0x1ff) / 2]; goto out; } if (!sh2->is_slave && a < sizeof(Pico32xMem->sh2_rom_m)) d = Pico32xMem->sh2_rom_m.w[a / 2]; else if (sh2->is_slave && a < sizeof(Pico32xMem->sh2_rom_s)) d = Pico32xMem->sh2_rom_s.w[a / 2]; else d = sh2_read16_unmapped(a, sh2); out: elprintf_sh2(sh2, EL_32X, "r16 [%08x] %04x @%06x", a, d, sh2_pc(sh2)); out_noprint: DRC_RESTORE_SR(sh2); return (s16)d; } static u32 REGPARM(2) sh2_read16_rom(u32 a, SH2 *sh2) { u32 bank = carthw_ssf2_banks[(a >> 19) & 7] << 19; s16 *p = sh2->p_rom; return p[(bank + (a & 0x7fffe)) / 2]; } static u32 REGPARM(2) sh2_read32_unmapped(u32 a, SH2 *sh2) { elprintf_sh2(sh2, EL_32X, "unmapped r32 [%08x] %08x @%06x", a, 0, sh2_pc(sh2)); return 0; } static u32 REGPARM(2) sh2_read32_cs0(u32 a, SH2 *sh2) { u32 d1 = sh2_read16_cs0(a, sh2) << 16, d2 = sh2_read16_cs0(a + 2, sh2) << 16; return d1 | (d2 >> 16); } static u32 REGPARM(2) sh2_read32_rom(u32 a, SH2 *sh2) { u32 bank = carthw_ssf2_banks[(a >> 19) & 7] << 19; u32 *p = sh2->p_rom; u32 d = p[(bank + (a & 0x7fffc)) / 4]; return (d << 16) | (d >> 16); } // writes #ifdef DRC_SH2 void NOINLINE sh2_sdram_checks(u32 a, int t, SH2 *sh2) { int v = t & ~0x80; if (v) sh2_drc_wcheck_ram(a, v, sh2); if (t & 0x80) { DRC_SAVE_SR(sh2); sh2_end_run(sh2, 1); p32x_sh2_poll_event(sh2->other_sh2, SH2_STATE_RPOLL, sh2_cycles_done_m68k(sh2)); DRC_RESTORE_SR(sh2); } } #ifndef _ASM_32X_MEMORY_C static void sh2_da_checks(u32 a, int t, SH2 *sh2) { if (t) sh2_drc_wcheck_da(a, t, sh2); } #endif #endif static void REGPARM(3) sh2_write_ignore(u32 a, u32 d, SH2 *sh2) { } // write8 static void REGPARM(3) sh2_write8_unmapped(u32 a, u32 d, SH2 *sh2) { elprintf_sh2(sh2, EL_32X, "unmapped w8 [%08x] %02x @%06x", a, d & 0xff, sh2_pc(sh2)); } static void REGPARM(3) sh2_write8_cs0(u32 a, u32 d, SH2 *sh2) { DRC_SAVE_SR(sh2); elprintf_sh2(sh2, EL_32X, "w8 [%08x] %02x @%06x", a, d & 0xff, sh2_pc(sh2)); if (Pico32x.regs[0] & P32XS_FM) { if ((a & 0x3fff0) == 0x4100) { sh2->poll_cnt = 0; p32x_vdp_write8(a, d); goto out; } if ((a & 0x3fe00) == 0x4200) { ((u8 *)Pico32xMem->pal)[(a & 0x1ff) ^ 1] = d; Pico32x.dirty_pal = 1; goto out; } } if ((a & 0x3ffc0) == 0x4000) { p32x_sh2reg_write8(a, d, sh2); goto out; } sh2_write8_unmapped(a, d, sh2); out: DRC_RESTORE_SR(sh2); } #ifdef _ASM_32X_MEMORY_C extern void REGPARM(3) sh2_write8_dram(u32 a, u32 d, SH2 *sh2); extern void REGPARM(3) sh2_write8_sdram(u32 a, u32 d, SH2 *sh2); extern void REGPARM(3) sh2_write8_da(u32 a, u32 d, SH2 *sh2); #else static void REGPARM(3) sh2_write8_dram(u32 a, u32 d, SH2 *sh2) { sh2_write8_dramN(sh2->p_dram, a, d); } static void REGPARM(3) sh2_write8_sdram(u32 a, u32 d, SH2 *sh2) { u32 a1 = (a & 0x3ffff) ^ 1; ((u8 *)sh2->p_sdram)[a1] = d; #ifdef DRC_SH2 u8 *p = sh2->p_drcblk_ram; int t = p[a1 >> SH2_DRCBLK_RAM_SHIFT]; if (t) sh2_sdram_checks(a, t, sh2); #endif } static void REGPARM(3) sh2_write8_da(u32 a, u32 d, SH2 *sh2) { u32 a1 = (a & 0xfff) ^ 1; sh2->data_array[a1] = d; #ifdef DRC_SH2 u8 *p = sh2->p_drcblk_da; int t = p[a1 >> SH2_DRCBLK_DA_SHIFT]; if (t) sh2_da_checks(a, t, sh2); #endif } #endif // write16 static void REGPARM(3) sh2_write16_unmapped(u32 a, u32 d, SH2 *sh2) { elprintf_sh2(sh2, EL_32X, "unmapped w16 [%08x] %04x @%06x", a, d & 0xffff, sh2_pc(sh2)); } static void REGPARM(3) sh2_write16_cs0(u32 a, u32 d, SH2 *sh2) { DRC_SAVE_SR(sh2); if (((EL_LOGMASK & EL_PWM) || (a & 0x30) != 0x30)) // hide PWM elprintf_sh2(sh2, EL_32X, "w16 [%08x] %04x @%06x", a, d & 0xffff, sh2_pc(sh2)); if (Pico32x.regs[0] & P32XS_FM) { if ((a & 0x3fff0) == 0x4100) { sh2->poll_cnt = 0; p32x_vdp_write16(a, d, sh2); goto out; } if ((a & 0x3fe00) == 0x4200) { Pico32xMem->pal[(a & 0x1ff) / 2] = d; Pico32x.dirty_pal = 1; goto out; } } if ((a & 0x3ffc0) == 0x4000) { p32x_sh2reg_write16(a, d, sh2); goto out; } sh2_write16_unmapped(a, d, sh2); out: DRC_RESTORE_SR(sh2); } #ifdef _ASM_32X_MEMORY_C extern void REGPARM(3) sh2_write16_dram(u32 a, u32 d, SH2 *sh2); extern void REGPARM(3) sh2_write16_sdram(u32 a, u32 d, SH2 *sh2); extern void REGPARM(3) sh2_write16_da(u32 a, u32 d, SH2 *sh2); #else static void REGPARM(3) sh2_write16_dram(u32 a, u32 d, SH2 *sh2) { sh2_write16_dramN(sh2->p_dram, a, d); } static void REGPARM(3) sh2_write16_sdram(u32 a, u32 d, SH2 *sh2) { u32 a1 = a & 0x3fffe; ((u16 *)sh2->p_sdram)[a1 / 2] = d; #ifdef DRC_SH2 u8 *p = sh2->p_drcblk_ram; int t = p[a1 >> SH2_DRCBLK_RAM_SHIFT]; if (t) sh2_sdram_checks(a, t, sh2); #endif } static void REGPARM(3) sh2_write16_da(u32 a, u32 d, SH2 *sh2) { u32 a1 = a & 0xffe; ((u16 *)sh2->data_array)[a1 / 2] = d; #ifdef DRC_SH2 u8 *p = sh2->p_drcblk_da; int t = p[a1 >> SH2_DRCBLK_DA_SHIFT]; if (t) sh2_da_checks(a, t, sh2); #endif } #endif static void REGPARM(3) sh2_write16_rom(u32 a, u32 d, SH2 *sh2) { u32 a1 = a & 0x3ffffe; // tweak for WWF Raw: does writes to ROM area, and it doesn't work without // allowing this. // Presumably the write goes to the CPU cache and is read back from there, // but it would be extremely costly to emulate cache behaviour. Just allow // writes to that region, hoping that the original ROM values are never used. if ((a1 & 0x3e0000) == 0x3e0000) ((u16 *)sh2->p_rom)[a1 / 2] = d; else sh2_write16_unmapped(a, d, sh2); } static void REGPARM(3) sh2_write32_unmapped(u32 a, u32 d, SH2 *sh2) { elprintf_sh2(sh2, EL_32X, "unmapped w32 [%08x] %08x @%06x", a, d, sh2_pc(sh2)); } static void REGPARM(3) sh2_write32_cs0(u32 a, u32 d, SH2 *sh2) { sh2_write16_cs0(a, d >> 16, sh2); sh2_write16_cs0(a + 2, d, sh2); } #define sh2_write32_dramN(p, a, d) \ u32 *pd = &((u32 *)p)[(a & 0x1ffff) / 4]; \ if (!(a & 0x20000)) { \ *pd = (d << 16) | (d >> 16); \ } else { \ /* overwrite */ \ u32 v = *pd, m = 0; d = (d << 16) | (d >> 16) ; \ if (!(d & 0x000000ff)) m |= 0x000000ff; \ if (!(d & 0x0000ff00)) m |= 0x0000ff00; \ if (!(d & 0x00ff0000)) m |= 0x00ff0000; \ if (!(d & 0xff000000)) m |= 0xff000000; \ *pd = d | (v&m); \ } #ifdef _ASM_32X_MEMORY_C extern void REGPARM(3) sh2_write32_dram(u32 a, u32 d, SH2 *sh2); extern void REGPARM(3) sh2_write32_sdram(u32 a, u32 d, SH2 *sh2); extern void REGPARM(3) sh2_write32_da(u32 a, u32 d, SH2 *sh2); #else static void REGPARM(3) sh2_write32_dram(u32 a, u32 d, SH2 *sh2) { sh2_write32_dramN(sh2->p_dram, a, d); } static void REGPARM(3) sh2_write32_sdram(u32 a, u32 d, SH2 *sh2) { u32 a1 = a & 0x3fffc; *(u32 *)(sh2->p_sdram + a1) = (d << 16) | (d >> 16); #ifdef DRC_SH2 u8 *p = sh2->p_drcblk_ram; int t = p[a1 >> SH2_DRCBLK_RAM_SHIFT]; if (t) sh2_sdram_checks(a, t, sh2); int u = p[(a1+2) >> SH2_DRCBLK_RAM_SHIFT]; if (u) sh2_sdram_checks(a+2, u, sh2); #endif } static void REGPARM(3) sh2_write32_da(u32 a, u32 d, SH2 *sh2) { u32 a1 = a & 0xffc; *((u32 *)sh2->data_array + a1/4) = (d << 16) | (d >> 16); #ifdef DRC_SH2 u8 *p = sh2->p_drcblk_da; int t = p[a1 >> SH2_DRCBLK_DA_SHIFT]; if (t) sh2_da_checks(a, t, sh2); int u = p[(a1+2) >> SH2_DRCBLK_DA_SHIFT]; if (u) sh2_da_checks(a+2, u, sh2); #endif } #endif static void REGPARM(3) sh2_write32_rom(u32 a, u32 d, SH2 *sh2) { sh2_write16_rom(a, d >> 16, sh2); sh2_write16_rom(a + 2, d, sh2); } typedef u32 (sh2_read_handler)(u32 a, SH2 *sh2); typedef void REGPARM(3) (sh2_write_handler)(u32 a, u32 d, SH2 *sh2); #define SH2MAP_ADDR2OFFS_R(a) \ ((u32)(a) >> SH2_READ_SHIFT) #define SH2MAP_ADDR2OFFS_W(a) \ ((u32)(a) >> SH2_WRITE_SHIFT) u32 REGPARM(2) p32x_sh2_read8(u32 a, SH2 *sh2) { const sh2_memmap *sh2_map = sh2->read8_map; uptr p; sh2_map += SH2MAP_ADDR2OFFS_R(a); p = sh2_map->addr; if (!map_flag_set(p)) return *(s8 *)((p << 1) + ((a & sh2_map->mask) ^ 1)); else return ((sh2_read_handler *)(p << 1))(a, sh2); } u32 REGPARM(2) p32x_sh2_read16(u32 a, SH2 *sh2) { const sh2_memmap *sh2_map = sh2->read16_map; uptr p; sh2_map += SH2MAP_ADDR2OFFS_R(a); p = sh2_map->addr; if (!map_flag_set(p)) return *(s16 *)((p << 1) + (a & sh2_map->mask)); else return ((sh2_read_handler *)(p << 1))(a, sh2); } u32 REGPARM(2) p32x_sh2_read32(u32 a, SH2 *sh2) { const sh2_memmap *sh2_map = sh2->read32_map; uptr p; sh2_map += SH2MAP_ADDR2OFFS_R(a); p = sh2_map->addr; if (!map_flag_set(p)) { u32 *pd = (u32 *)((p << 1) + (a & sh2_map->mask)); return (*pd << 16) | (*pd >> 16); } else return ((sh2_read_handler *)(p << 1))(a, sh2); } void REGPARM(3) p32x_sh2_write8(u32 a, u32 d, SH2 *sh2) { const void **sh2_wmap = sh2->write8_tab; sh2_write_handler *wh; wh = sh2_wmap[SH2MAP_ADDR2OFFS_W(a)]; wh(a, d, sh2); } void REGPARM(3) p32x_sh2_write16(u32 a, u32 d, SH2 *sh2) { const void **sh2_wmap = sh2->write16_tab; sh2_write_handler *wh; wh = sh2_wmap[SH2MAP_ADDR2OFFS_W(a)]; wh(a, d, sh2); } void REGPARM(3) p32x_sh2_write32(u32 a, u32 d, SH2 *sh2) { const void **sh2_wmap = sh2->write32_tab; sh2_write_handler *wh; wh = sh2_wmap[SH2MAP_ADDR2OFFS_W(a)]; wh(a, d, sh2); } void *p32x_sh2_get_mem_ptr(u32 a, u32 *mask, SH2 *sh2) { const sh2_memmap *mm = sh2->read8_map; void *ret = (void *)-1; u32 am; mm += a >> SH2_READ_SHIFT; am = a & ((1 << SH2_READ_SHIFT)-1); if (!map_flag_set(mm->addr) && !(am & ~mm->mask)) { // directly mapped memory (SDRAM, ROM, data array) ret = (void *)(mm->addr << 1); *mask = mm->mask; } else if ((a & ~0x7ff) == 0) { // BIOS, has handler function since it shares its segment with I/O ret = sh2->is_slave ? Pico32xMem->sh2_rom_s.w : Pico32xMem->sh2_rom_m.w; *mask = 0x7ff; } else if ((a & 0xc6000000) == 0x02000000) { // banked ROM. Return bank address u32 bank = carthw_ssf2_banks[(a >> 19) & 7] << 19; ret = sh2->p_rom + bank; *mask = 0x07ffff; } return ret; } // ----------------------------------------------------------------- static void z80_md_bank_write_32x(unsigned int a, unsigned char d) { unsigned int addr68k; addr68k = Pico.m.z80_bank68k << 15; addr68k += a & 0x7fff; if ((addr68k & 0xfff000) == 0xa15000) Pico32x.emu_flags |= P32XF_Z80_32X_IO; elprintf(EL_Z80BNK, "z80->68k w8 [%06x] %02x", addr68k, d); m68k_write8(addr68k, d); } // ----------------------------------------------------------------- static const u16 msh2_code[] = { // trap instructions 0xaffe, // 200 bra 0x0009, // 202 nop // have to wait a bit until m68k initial program finishes clearing stuff // to avoid races with game SH2 code, like in Tempo 0xd406, // 204 mov.l @(_m_ok,pc), r4 0xc400, // 206 mov.b @(h'0,gbr),r0 0xc801, // 208 tst #1, r0 0x8b0f, // 20a bf cd_start 0xd105, // 20c mov.l @(_cnt,pc), r1 0xd206, // 20e mov.l @(_start,pc), r2 0x71ff, // 210 add #-1, r1 0x4115, // 212 cmp/pl r1 0x89fc, // 214 bt -2 0x6043, // 216 mov r4, r0 0xc208, // 218 mov.l r0, @(h'20,gbr) 0x6822, // 21a mov.l @r2, r8 0x482b, // 21c jmp @r8 0x0009, // 21e nop ('M'<<8)|'_', ('O'<<8)|'K', // 220 _m_ok 0x0001, 0x0000, // 224 _cnt 0x2200, 0x03e0, // master start pointer in ROM // cd_start: 0xd20d, // 22c mov.l @(__cd_,pc), r2 0xc608, // 22e mov.l @(h'20,gbr), r0 0x3200, // 230 cmp/eq r0, r2 0x8bfc, // 232 bf #-2 0xe000, // 234 mov #0, r0 0xcf80, // 236 or.b #0x80,@(r0,gbr) 0xd80b, // 238 mov.l @(_start_cd,pc), r8 // 24000018 0xd30c, // 23a mov.l @(_max_len,pc), r3 0x5b84, // 23c mov.l @(h'10,r8), r11 // master vbr 0x5a82, // 23e mov.l @(8,r8), r10 // entry 0x5081, // 240 mov.l @(4,r8), r0 // len 0x5980, // 242 mov.l @(0,r8), r9 // dst 0x3036, // 244 cmp/hi r3,r0 0x8b00, // 246 bf #1 0x6033, // 248 mov r3,r0 0x7820, // 24a add #0x20, r8 // ipl_copy: 0x6286, // 24c mov.l @r8+, r2 0x2922, // 24e mov.l r2, @r9 0x7904, // 250 add #4, r9 0x70fc, // 252 add #-4, r0 0x8800, // 254 cmp/eq #0, r0 0x8bf9, // 256 bf #-5 // 0x4b2e, // 258 ldc r11, vbr 0x6043, // 25a mov r4, r0 // M_OK 0xc208, // 25c mov.l r0, @(h'20,gbr) 0x4a2b, // 25e jmp @r10 0x0009, // 260 nop 0x0009, // 262 nop // pad ('_'<<8)|'C', ('D'<<8)|'_', // 264 __cd_ 0x2400, 0x0018, // 268 _start_cd 0x0001, 0xffe0, // 26c _max_len }; static const u16 ssh2_code[] = { 0xaffe, // 200 bra 0x0009, // 202 nop // code to wait for master, in case authentic master BIOS is used 0xd106, // 204 mov.l @(_m_ok,pc), r1 0xd208, // 206 mov.l @(_start,pc), r2 0xc608, // 208 mov.l @(h'20,gbr), r0 0x3100, // 20a cmp/eq r0, r1 0x8bfc, // 20c bf #-2 0xc400, // 20e mov.b @(h'0,gbr),r0 0xc801, // 210 tst #1, r0 0xd004, // 212 mov.l @(_s_ok,pc), r0 0x8b0a, // 214 bf cd_start 0xc209, // 216 mov.l r0, @(h'24,gbr) 0x6822, // 218 mov.l @r2, r8 0x482b, // 21a jmp @r8 0x0009, // 21c nop 0x0009, // 21e nop ('M'<<8)|'_', ('O'<<8)|'K', // 220 ('S'<<8)|'_', ('O'<<8)|'K', // 224 0x2200, 0x03e4, // slave start pointer in ROM // cd_start: 0xd803, // 22c mov.l @(_start_cd,pc), r8 // 24000018 0x5b85, // 22e mov.l @(h'14,r8), r11 // slave vbr 0x5a83, // 230 mov.l @(h'0c,r8), r10 // entry 0x4b2e, // 232 ldc r11, vbr 0xc209, // 234 mov.l r0, @(h'24,gbr) // write S_OK 0x4a2b, // 236 jmp @r10 0x0009, // 238 nop 0x0009, // 23a nop 0x2400, 0x0018, // 23c _start_cd }; #define HWSWAP(x) (((u16)(x) << 16) | ((x) >> 16)) static void get_bios(void) { u16 *ps; u32 *pl; int i; // M68K ROM if (p32x_bios_g != NULL) { elprintf(EL_STATUS|EL_32X, "32x: using supplied 68k BIOS"); Byteswap(Pico32xMem->m68k_rom, p32x_bios_g, sizeof(Pico32xMem->m68k_rom)); } else { static const u16 andb[] = { 0x0239, 0x00fe, 0x00a1, 0x5107 }; static const u16 p_d4[] = { 0x48e7, 0x8040, // movem.l d0/a1, -(sp) 0x227c, 0x00a1, 0x30f1, // movea.l #0xa130f1, a1 0x7007, // moveq.l #7, d0 0x12d8, //0: move.b (a0)+, (a1)+ 0x5289, // addq.l #1, a1 0x51c8, 0xfffa, // dbra d0, 0b 0x0239, 0x00fe, 0x00a1, // and.b #0xfe, (0xa15107).l 0x5107, 0x4cdf, 0x0201 // movem.l (sp)+, d0/a1 }; // generate 68k ROM ps = (u16 *)Pico32xMem->m68k_rom; pl = (u32 *)ps; for (i = 1; i < 0xc0/4; i++) pl[i] = HWSWAP(0x880200 + (i - 1) * 6); pl[0x70/4] = 0; // fill with nops for (i = 0xc0/2; i < 0x100/2; i++) ps[i] = 0x4e71; // c0: don't need to care about RV - not emulated ps[0xc8/2] = 0x1280; // move.b d0, (a1) memcpy(ps + 0xca/2, andb, sizeof(andb)); // and.b #0xfe, (a15107) ps[0xd2/2] = 0x4e75; // rts // d4: memcpy(ps + 0xd4/2, p_d4, sizeof(p_d4)); ps[0xfe/2] = 0x4e75; // rts } // fill remaining m68k_rom page with game ROM memcpy(Pico32xMem->m68k_rom_bank + sizeof(Pico32xMem->m68k_rom), Pico.rom + sizeof(Pico32xMem->m68k_rom), sizeof(Pico32xMem->m68k_rom_bank) - sizeof(Pico32xMem->m68k_rom)); // MSH2 if (p32x_bios_m != NULL) { elprintf(EL_STATUS|EL_32X, "32x: using supplied master SH2 BIOS"); Byteswap(&Pico32xMem->sh2_rom_m, p32x_bios_m, sizeof(Pico32xMem->sh2_rom_m)); } else { pl = (u32 *)&Pico32xMem->sh2_rom_m; // fill exception vector table to our trap address for (i = 0; i < 128; i++) pl[i] = HWSWAP(0x200); // start pl[0] = pl[2] = HWSWAP(0x204); // reset SP pl[1] = pl[3] = HWSWAP(0x6040000); // startup code memcpy(&Pico32xMem->sh2_rom_m.b[0x200], msh2_code, sizeof(msh2_code)); } // SSH2 if (p32x_bios_s != NULL) { elprintf(EL_STATUS|EL_32X, "32x: using supplied slave SH2 BIOS"); Byteswap(&Pico32xMem->sh2_rom_s, p32x_bios_s, sizeof(Pico32xMem->sh2_rom_s)); } else { pl = (u32 *)&Pico32xMem->sh2_rom_s; // fill exception vector table to our trap address for (i = 0; i < 128; i++) pl[i] = HWSWAP(0x200); // start pl[0] = pl[2] = HWSWAP(0x204); // reset SP pl[1] = pl[3] = HWSWAP(0x603f800); // startup code memcpy(&Pico32xMem->sh2_rom_s.b[0x200], ssh2_code, sizeof(ssh2_code)); } } #define MAP_MEMORY(m) ((uptr)(m) >> 1) #define MAP_HANDLER(h) ( ((uptr)(h) >> 1) | ((uptr)1 << (sizeof(uptr) * 8 - 1)) ) static sh2_memmap msh2_read8_map[0x80], msh2_read16_map[0x80], msh2_read32_map[0x80]; static sh2_memmap ssh2_read8_map[0x80], ssh2_read16_map[0x80], ssh2_read32_map[0x80]; // for writes we are using handlers only static sh2_write_handler *msh2_write8_map[0x80], *msh2_write16_map[0x80], *msh2_write32_map[0x80]; static sh2_write_handler *ssh2_write8_map[0x80], *ssh2_write16_map[0x80], *ssh2_write32_map[0x80]; void Pico32xSwapDRAM(int b) { cpu68k_map_set(m68k_read8_map, 0x840000, 0x85ffff, Pico32xMem->dram[b], 0); cpu68k_map_set(m68k_read16_map, 0x840000, 0x85ffff, Pico32xMem->dram[b], 0); cpu68k_map_set(m68k_read8_map, 0x860000, 0x87ffff, Pico32xMem->dram[b], 0); cpu68k_map_set(m68k_read16_map, 0x860000, 0x87ffff, Pico32xMem->dram[b], 0); cpu68k_map_set(m68k_write8_map, 0x840000, 0x87ffff, b ? m68k_write8_dram1_ow : m68k_write8_dram0_ow, 1); cpu68k_map_set(m68k_write16_map, 0x840000, 0x87ffff, b ? m68k_write16_dram1_ow : m68k_write16_dram0_ow, 1); // SH2 msh2_read8_map[0x04/2].addr = msh2_read8_map[0x24/2].addr = msh2_read16_map[0x04/2].addr = msh2_read16_map[0x24/2].addr = msh2_read32_map[0x04/2].addr = msh2_read32_map[0x24/2].addr = MAP_MEMORY(Pico32xMem->dram[b]); ssh2_read8_map[0x04/2].addr = ssh2_read8_map[0x24/2].addr = ssh2_read16_map[0x04/2].addr = ssh2_read16_map[0x24/2].addr = ssh2_read32_map[0x04/2].addr = ssh2_read32_map[0x24/2].addr = MAP_MEMORY(Pico32xMem->dram[b]); msh2.p_dram = ssh2.p_dram = Pico32xMem->dram[b]; // DRC conveniance ptr msh2.p_rom = ssh2.p_rom = Pico.rom; } static void bank_switch_rom_sh2(void) { if (!carthw_ssf2_active) { // easy msh2_read8_map[0x02/2].addr = msh2_read8_map[0x22/2].addr = msh2_read16_map[0x02/2].addr = msh2_read16_map[0x22/2].addr = msh2_read32_map[0x02/2].addr = msh2_read32_map[0x22/2].addr = MAP_MEMORY(Pico.rom); ssh2_read8_map[0x02/2].addr = ssh2_read8_map[0x22/2].addr = ssh2_read16_map[0x02/2].addr = ssh2_read16_map[0x22/2].addr = ssh2_read32_map[0x02/2].addr = ssh2_read32_map[0x22/2].addr = MAP_MEMORY(Pico.rom); } else { msh2_read8_map[0x02/2].addr = msh2_read8_map[0x22/2].addr = MAP_HANDLER(sh2_read8_rom); msh2_read16_map[0x02/2].addr = msh2_read16_map[0x22/2].addr = MAP_HANDLER(sh2_read16_rom); msh2_read32_map[0x02/2].addr = msh2_read32_map[0x22/2].addr = MAP_HANDLER(sh2_read32_rom); ssh2_read8_map[0x02/2].addr = ssh2_read8_map[0x22/2].addr = MAP_HANDLER(sh2_read8_rom); ssh2_read16_map[0x02/2].addr = ssh2_read16_map[0x22/2].addr = MAP_HANDLER(sh2_read16_rom); ssh2_read32_map[0x02/2].addr = ssh2_read32_map[0x22/2].addr = MAP_HANDLER(sh2_read32_rom); } } void PicoMemSetup32x(void) { unsigned int rs; int i; Pico32xMem = plat_mmap(0x06000000, sizeof(*Pico32xMem), 0, 0); if (Pico32xMem == NULL) { elprintf(EL_STATUS, "OOM"); return; } get_bios(); // cartridge area becomes unmapped // XXX: we take the easy way and don't unmap ROM, // so that we can avoid handling the RV bit. // m68k_map_unmap(0x000000, 0x3fffff); if (!Pico.m.ncart_in) { // MD ROM area rs = sizeof(Pico32xMem->m68k_rom_bank); cpu68k_map_set(m68k_read8_map, 0x000000, rs - 1, Pico32xMem->m68k_rom_bank, 0); cpu68k_map_set(m68k_read16_map, 0x000000, rs - 1, Pico32xMem->m68k_rom_bank, 0); cpu68k_map_set(m68k_write8_map, 0x000000, rs - 1, PicoWrite8_hint, 1); // TODO verify cpu68k_map_set(m68k_write16_map, 0x000000, rs - 1, PicoWrite16_hint, 1); // 32X ROM (unbanked, XXX: consider mirroring?) rs = (Pico.romsize + M68K_BANK_MASK) & ~M68K_BANK_MASK; if (rs > 0x80000) rs = 0x80000; cpu68k_map_set(m68k_read8_map, 0x880000, 0x880000 + rs - 1, Pico.rom, 0); cpu68k_map_set(m68k_read16_map, 0x880000, 0x880000 + rs - 1, Pico.rom, 0); cpu68k_map_set(m68k_write8_map, 0x880000, 0x880000 + rs - 1, PicoWrite8_cart, 1); cpu68k_map_set(m68k_write16_map, 0x880000, 0x880000 + rs - 1, PicoWrite16_cart, 1); // 32X ROM (banked) bank_switch_rom_68k(0); cpu68k_map_set(m68k_write8_map, 0x900000, 0x9fffff, PicoWrite8_bank, 1); cpu68k_map_set(m68k_write16_map, 0x900000, 0x9fffff, PicoWrite16_bank, 1); } // SYS regs cpu68k_map_set(m68k_read8_map, 0xa10000, 0xa1ffff, PicoRead8_32x_on, 1); cpu68k_map_set(m68k_read16_map, 0xa10000, 0xa1ffff, PicoRead16_32x_on, 1); cpu68k_map_set(m68k_write8_map, 0xa10000, 0xa1ffff, PicoWrite8_32x_on, 1); cpu68k_map_set(m68k_write16_map, 0xa10000, 0xa1ffff, PicoWrite16_32x_on, 1); // TODO: cd + carthw if (PicoIn.AHW & PAHW_MCD) { m68k_write8_io = PicoWrite8_32x_on_io_cd; m68k_write16_io = PicoWrite16_32x_on_io_cd; } else if (carthw_ssf2_active) { m68k_write8_io = PicoWrite8_32x_on_io_ssf2; m68k_write16_io = PicoWrite16_32x_on_io_ssf2; } else { m68k_write8_io = PicoWrite8_32x_on_io; m68k_write16_io = PicoWrite16_32x_on_io; } // SH2 maps: A31,A30,A29,CS1,CS0 // all unmapped by default for (i = 0; i < ARRAY_SIZE(msh2_read8_map); i++) { msh2_read8_map[i].addr = MAP_HANDLER(sh2_read8_unmapped); msh2_read16_map[i].addr = MAP_HANDLER(sh2_read16_unmapped); msh2_read32_map[i].addr = MAP_HANDLER(sh2_read32_unmapped); } for (i = 0; i < ARRAY_SIZE(msh2_write8_map); i++) { msh2_write8_map[i] = sh2_write8_unmapped; msh2_write16_map[i] = sh2_write16_unmapped; msh2_write32_map[i] = sh2_write32_unmapped; } // "purge area" for (i = 0x40; i <= 0x5f; i++) { msh2_write8_map[i >> 1] = msh2_write16_map[i >> 1] = msh2_write32_map[i >> 1] = sh2_write_ignore; } // CS0 msh2_read8_map[0x00/2].addr = msh2_read8_map[0x20/2].addr = MAP_HANDLER(sh2_read8_cs0); msh2_read16_map[0x00/2].addr = msh2_read16_map[0x20/2].addr = MAP_HANDLER(sh2_read16_cs0); msh2_read32_map[0x00/2].addr = msh2_read32_map[0x20/2].addr = MAP_HANDLER(sh2_read32_cs0); msh2_write8_map[0x00/2] = msh2_write8_map[0x20/2] = sh2_write8_cs0; msh2_write16_map[0x00/2] = msh2_write16_map[0x20/2] = sh2_write16_cs0; msh2_write32_map[0x00/2] = msh2_write32_map[0x20/2] = sh2_write32_cs0; // CS1 - ROM bank_switch_rom_sh2(); msh2_read8_map[0x02/2].mask = msh2_read8_map[0x22/2].mask = 0x3fffff; // FIXME msh2_read16_map[0x02/2].mask = msh2_read16_map[0x22/2].mask = 0x3ffffe; // FIXME msh2_read32_map[0x02/2].mask = msh2_read32_map[0x22/2].mask = 0x3ffffc; // FIXME msh2_write16_map[0x02/2] = msh2_write16_map[0x22/2] = sh2_write16_rom; msh2_write32_map[0x02/2] = msh2_write32_map[0x22/2] = sh2_write32_rom; // CS2 - DRAM msh2_read8_map[0x04/2].mask = msh2_read8_map[0x24/2].mask = 0x01ffff; msh2_read16_map[0x04/2].mask = msh2_read16_map[0x24/2].mask = 0x01fffe; msh2_read32_map[0x04/2].mask = msh2_read32_map[0x24/2].mask = 0x01fffc; msh2_write8_map[0x04/2] = msh2_write8_map[0x24/2] = sh2_write8_dram; msh2_write16_map[0x04/2] = msh2_write16_map[0x24/2] = sh2_write16_dram; msh2_write32_map[0x04/2] = msh2_write32_map[0x24/2] = sh2_write32_dram; // CS3 - SDRAM msh2_read8_map[0x06/2].addr = msh2_read8_map[0x26/2].addr = msh2_read16_map[0x06/2].addr = msh2_read16_map[0x26/2].addr = msh2_read32_map[0x06/2].addr = msh2_read32_map[0x26/2].addr = MAP_MEMORY(Pico32xMem->sdram); msh2_write8_map[0x06/2] = msh2_write8_map[0x26/2] = sh2_write8_sdram; msh2_write16_map[0x06/2] = msh2_write16_map[0x26/2] = sh2_write16_sdram; msh2_write32_map[0x06/2] = msh2_write32_map[0x26/2] = sh2_write32_sdram; msh2_read8_map[0x06/2].mask = msh2_read8_map[0x26/2].mask = 0x03ffff; msh2_read16_map[0x06/2].mask = msh2_read16_map[0x26/2].mask = 0x03fffe; msh2_read32_map[0x06/2].mask = msh2_read32_map[0x26/2].mask = 0x03fffc; // SH2 data array msh2_read8_map[0xc0/2].mask = 0x0fff; msh2_read16_map[0xc0/2].mask = 0x0ffe; msh2_read32_map[0xc0/2].mask = 0x0ffc; msh2_write8_map[0xc0/2] = sh2_write8_da; msh2_write16_map[0xc0/2] = sh2_write16_da; msh2_write32_map[0xc0/2] = sh2_write32_da; // SH2 IO msh2_read8_map[0xff/2].addr = MAP_HANDLER(sh2_peripheral_read8); msh2_read16_map[0xff/2].addr = MAP_HANDLER(sh2_peripheral_read16); msh2_read32_map[0xff/2].addr = MAP_HANDLER(sh2_peripheral_read32); msh2_write8_map[0xff/2] = sh2_peripheral_write8; msh2_write16_map[0xff/2] = sh2_peripheral_write16; msh2_write32_map[0xff/2] = sh2_peripheral_write32; memcpy(ssh2_read8_map, msh2_read8_map, sizeof(msh2_read8_map)); memcpy(ssh2_read16_map, msh2_read16_map, sizeof(msh2_read16_map)); memcpy(ssh2_read32_map, msh2_read32_map, sizeof(msh2_read32_map)); memcpy(ssh2_write8_map, msh2_write8_map, sizeof(msh2_write8_map)); memcpy(ssh2_write16_map, msh2_write16_map, sizeof(msh2_write16_map)); memcpy(ssh2_write32_map, msh2_write32_map, sizeof(msh2_write32_map)); msh2_read8_map[0xc0/2].addr = msh2_read16_map[0xc0/2].addr = msh2_read32_map[0xc0/2].addr = MAP_MEMORY(msh2.data_array); ssh2_read8_map[0xc0/2].addr = ssh2_read16_map[0xc0/2].addr = ssh2_read32_map[0xc0/2].addr = MAP_MEMORY(ssh2.data_array); // map DRAM area, both 68k and SH2 Pico32xSwapDRAM(1); msh2.read8_map = msh2_read8_map; ssh2.read8_map = ssh2_read8_map; msh2.read16_map = msh2_read16_map; ssh2.read16_map = ssh2_read16_map; msh2.read32_map = msh2_read32_map; ssh2.read32_map = ssh2_read32_map; msh2.write8_tab = (const void **)(void *)msh2_write8_map; msh2.write16_tab = (const void **)(void *)msh2_write16_map; msh2.write32_tab = (const void **)(void *)msh2_write32_map; ssh2.write8_tab = (const void **)(void *)ssh2_write8_map; ssh2.write16_tab = (const void **)(void *)ssh2_write16_map; ssh2.write32_tab = (const void **)(void *)ssh2_write32_map; sh2_drc_mem_setup(&msh2); sh2_drc_mem_setup(&ssh2); // z80 hack z80_map_set(z80_write_map, 0x8000, 0xffff, z80_md_bank_write_32x, 1); } void p32x_update_banks(void) { bank_switch_rom_68k(Pico32x.regs[4 / 2]); bank_switch_rom_sh2(); if (Pico32x.emu_flags & P32XF_DRC_ROM_C) sh2_drc_flush_all(); } void Pico32xMemStateLoaded(void) { bank_switch_rom_68k(Pico32x.regs[4 / 2]); Pico32xSwapDRAM((Pico32x.vdp_regs[0x0a / 2] & P32XV_FS) ^ P32XV_FS); memset(Pico32xMem->pwm, 0, sizeof(Pico32xMem->pwm)); Pico32x.dirty_pal = 1; Pico32x.emu_flags &= ~(P32XF_68KCPOLL | P32XF_68KVPOLL); memset(&m68k_poll, 0, sizeof(m68k_poll)); msh2.state = 0; msh2.poll_addr = msh2.poll_cycles = msh2.poll_cnt = 0; ssh2.state = 0; ssh2.poll_addr = ssh2.poll_cycles = ssh2.poll_cnt = 0; sh2_drc_flush_all(); } // vim:shiftwidth=2:ts=2:expandtab