ref: dc593372bfc4224c6cf91d2031d0ad0aeadaddfe
dir: /sys/src/games/md/mem.c/
#include <u.h> #include <libc.h> #include <thread.h> #include "../eui.h" #include "dat.h" #include "fns.h" u16int ram[32768], vram[32768]; u16int cram[64], vsram[40]; u32int cramc[64]; u8int zram[8192]; u8int reg[32]; u8int ctl[15]; u8int dma; u8int vdplatch; u16int vdpaddr, vdpdata; u8int yma1, yma2; u8int z80bus = RESET; u16int z80bank; //#define vramdebug(a, s, a1, a2, a3) if((a & ~1) == 0xe7a0) print(s, a1, a2, a3); #define vramdebug(a, s, a1, a2, a3) u8int regread(u16int a) { u16int v; switch(a | 1){ case 0x0001: return 0xa0; case 0x0003: v = ~(keys & 0xffff); if((ctl[0] & 0x40) == 0) v >>= 8; return ctl[0] & 0xc0 | v & 0x3f; case 0x0005: case 0x0007: return ctl[a-3>>1] & 0xc0 | 0x3f; case 0x0009: case 0x000b: case 0x000d: return ctl[a-3>>1]; case 0x1101: return (~z80bus & BUSACK) >> 1; } sysfatal("read from 0xa1%.4ux (pc=%#.6ux)", a, curpc); return 0; } void regwrite(u16int a, u16int v) { switch(a | 1){ case 0x0003: case 0x0005: case 0x0007: case 0x0009: case 0x000b: case 0x000d: ctl[a-3>>1] = v; return; case 0x1101: z80bus = z80bus & ~BUSREQ | v & BUSREQ; return; case 0x1201: if((v & 1) == 0){ z80bus |= RESET; z80bus &= ~BUSACK; }else z80bus &= ~RESET; return; case 0x30f1: if((v & 1) != 0) sramctl |= SRAMEN; else sramctl &= ~SRAMEN; return; case 0x30f3: case 0x30f5: case 0x30f7: case 0x30f9: case 0x30fb: return; } fprint(2, "write to 0xa1%.4x (pc=%#.6ux)", a, curpc); } void vdpwrite(u16int v) { u8int a; if((vdplatch & 0x80) == 0){ if((v & 0xc000) == 0x8000){ a = v >> 8 & 0x1f; reg[a] = v & 0xff; if(a == 0x0c) vdpmode(); vdplatch = 0; return; } vdplatch = vdplatch & 0xfc | v >> 14 | 0x80; vdpaddr = vdpaddr & 0xc000 | v & 0x3fff; }else{ vdplatch = vdplatch & 0x03 | v >> 2 & 0x1c; vdpaddr = vdpaddr & 0x3fff | v << 14 & 0xc000; if((v & 0x80) != 0 && (reg[MODE2] & DMAEN) != 0){ dma = reg[23] >> 6 & 3; if(dma == 0) dma++; } } } void cramwrite(u16int a, u16int v) { u32int w; cram[a/2] = v; w = v << 12 & 0xe00000 | v << 8 & 0xe000 | v << 4 & 0xe0; cramc[a/2] = w; } u16int memread(u32int a) { u16int v; switch(a >> 21 & 7){ case 0: case 1: if((sramctl & SRAMEN) != 0 && a >= sram0 && a <= sram1) switch(sramctl & ADDRMASK){ case ADDREVEN: return sram[(a - sram0) >> 1] << 8; case ADDRODD: return sram[(a - sram0) >> 1]; case ADDRBOTH: return sram[a - sram0] << 8 | sram[a - sram0 + 1]; } return prg[(a % nprg) / 2]; case 5: switch(a >> 16 & 0xff){ case 0xa0: if((z80bus & BUSACK) != 0) v = z80read(a & 0x7fff); else v = 0; return v << 8 | v; case 0xa1: v = regread(a); return v << 8 | v; } goto invalid; case 6: if((a & 0xe700e0) != 0xc00000) goto invalid; switch(a & 30){ case 0: case 2: vdplatch &= 0x7f; switch(vdplatch & 0xf){ case 0: v = vram[vdpaddr/2]; vdpaddr += reg[AUTOINC]; break; case 4: v = vdpaddr & 0x7f; if(v < 80) v = vsram[v / 2]; else v = 0; vdpaddr = (vdpaddr + reg[AUTOINC]) & 0x7f; break; case 8: v = cram[(vdpaddr & 0x7f) / 2]; vdpaddr = (vdpaddr + reg[AUTOINC]) & 0x7f; break; default: v = 0; } return v; case 4: case 6: vdplatch &= 0x7f; v = vdpstat; if(dma != 0 && dma != 2) v |= STATDMA; if(vdpx >= 0xe4 || vdpx < 0x08) v |= STATHBL; return v; case 8: case 10: case 12: case 14: if((reg[MODE4] & WIDE) != 0) v = vdpx - (vdpx >= 360 ? 406 : 0); else v = vdpx - (vdpx >= 296 ? 342 : 0); if(intla) return vdpy - (vdpy >= 234 ? 5 : 0) << 8 & 0xfe00 | frame << 8 | v >> 1 & 0xff; return vdpy - (vdpy >= 234 ? 5 : 0) << 8 | v >> 1 & 0xff; default: goto invalid; } case 7: return ram[((u16int)a) / 2]; default: invalid: sysfatal("read from %#.6ux (pc=%#.6ux)", a, curpc); return 0; } } void memwrite(u32int a, u16int v, u16int m) { u16int *p; u16int w; if(0 && (a & 0xe0fffe) == 0xe0df46) print("%x %x %x\n", curpc, v, m); switch((a >> 21) & 7){ case 0: case 1: if((sramctl & SRAMEN) != 0 && a >= sram0 && a <= sram1){ switch(sramctl & ADDRMASK){ case ADDREVEN: sram[(a - sram0) >> 1] = v >> 8; break; case ADDRODD: sram[(a - sram0) >> 1] = v; break; case ADDRBOTH: if((m & 0xff00) == 0xff00) sram[a - sram0] = v >> 8; if((m & 0xff) == 0xff) sram[a + 1 - sram0] = v; break; } if(saveclock == 0) saveclock = SAVEFREQ; return; } goto invalid; case 5: switch(a >> 16 & 0xff){ case 0xa0: if((z80bus & BUSACK) != 0) z80write(a & 0xffff, v >> 8); return; case 0xa1: regwrite(a, v >> 8); return; default: goto invalid; } case 6: if((a & 0xe700e0) != 0xc00000) goto invalid; switch(a & 30){ case 0: case 2: if(dma == 2){ dma = 4; vdpdata = v >> 8; vramdebug(vdpaddr, "vdp fill write val %x (pc = %x) %d\n", v & 0xff, curpc, 0); p = &vram[vdpaddr / 2]; if((vdpaddr & 1) == 0) *p = *p & 0xff | v << 8; else *p = *p & 0xff00 | v & 0xff; return; } vdplatch &= 0x7f; switch(vdplatch & 0xf){ case 1: if((vdpaddr & 1) != 0) v = v << 8 | v >> 8; p = &vram[vdpaddr / 2]; vramdebug(vdpaddr, "vdp write val %x mask %x (pc = %x)\n", v, m, curpc); *p = *p & ~m | v & m; vdpaddr += reg[AUTOINC]; return; case 3: cramwrite(vdpaddr & 0x7f, v); vdpaddr = (vdpaddr + reg[AUTOINC]) & 0x7f; return; case 5: w = vdpaddr & 0x7f; if(w < 80) vsram[w / 2] = v; vdpaddr = (vdpaddr + reg[AUTOINC]) & 0x7f; return; default: return; } case 4: case 6: vdpwrite(v); return; case 16: case 18: case 20: case 22: return; default: goto invalid; } case 7: p = &ram[((u16int)a) / 2]; *p = *p & ~m | v & m; break; default: invalid: fprint(2, "write to %#.6x (pc=%#.6x)", a, curpc); } } void dmastep(void) { u16int v, *p; u32int a; switch(dma){ case 1: a = reg[DMASRC0] << 1 | reg[DMASRC1] << 9 | reg[DMASRC2] << 17; v = memread(a); if(++reg[DMASRC0] == 0) reg[DMASRC1]++; switch(vdplatch & 0x7){ case 1: if((vdpaddr & 1) != 0) v = v >> 8 | v << 8; vramdebug(vdpaddr, "dma from 68K %x val %x (%d)\n", a, v, 0); vram[vdpaddr / 2] = v; break; case 3: if(vdpaddr > 0x7f) dma = 0; else cramwrite(vdpaddr, v); break; case 5: if(vdpaddr < 80) vsram[vdpaddr / 2] = v; break; } break; case 2: return; case 3: a = reg[DMASRC0] | reg[DMASRC1] << 8; v = vram[a / 2]; if((a & 1) == 0) v = v >> 8; if(++reg[DMASRC0] == 0) reg[DMASRC1]++; vramdebug(vdpaddr, "dma copy from %x val %x (%d)\n", a, v, 0); p = &vram[vdpaddr / 2]; if((vdpaddr & 1) != 0) *p = *p & 0xff00 | v & 0xff; else *p = *p & 0xff | v << 8; break; case 4: p = &vram[vdpaddr / 2]; vramdebug(vdpaddr, "dma fill val %x (%d%d)\n", vdpdata, 0, 0); if((vdpaddr & 1) == 0) *p = *p & 0xff00 | vdpdata; else *p = *p & 0xff | vdpdata << 8; break; } vdpaddr += reg[AUTOINC]; if(reg[DMACL]-- == 0) reg[DMACH]--; if((reg[DMACL] | reg[DMACH]) == 0) dma = 0; } u8int z80read(u16int a) { u16int v; switch(a >> 13){ case 0: case 1: return zram[a & 0x1fff]; case 2: return ymstat; case 3: if(a >= 0x7f00){ v = memread(0xc00000 | a & 0x7e); if((a & 1) == 0) v >>= 8; return v; } sysfatal("z80 read from %#.4x (pc=%#.4x)", a, scurpc); default: v = memread(z80bank << 15 | a & 0x7ffe); if((a & 1) == 0) v >>= 8; return v; } } void z80write(u16int a, u8int v) { switch(a >> 13){ case 0: case 1: zram[a & 0x1fff] = v; return; case 2: switch(a & 3){ case 0: yma1 = v; return; case 1: ymwrite(yma1, v, 0); return; case 2: yma2 = v; return; case 3: ymwrite(yma2, v, 3); return; } case 3: if(a < 0x6100){ z80bank = z80bank >> 1 | v << 8 & 0x100; return; } if(a >= 0x7f00){ memwrite(0xc00000 | a & 0x7e, v | v << 8, (a & 1) != 0 ? 0xff : 0xff00); return; } fprint(2, "z80 write to %#.4x (pc=%#.4x)", a, scurpc); return; default: memwrite(z80bank << 15 | a & 0x7ffe, v << 8 | v, (a & 1) != 0 ? 0xff : 0xff00); } } u8int z80in(u8int) { return 0xff; } void z80out(u8int, u8int) { } u32int irql[8] = {[6] INTVBL, [4] INTHOR}; int intack(int l) { switch(l){ case 4: irq &= ~INTHOR; break; case 6: irq &= ~INTVBL; break; } return 24 + l; }