/* * UAE - The Un*x Amiga Emulator * * Custom chip emulation * * (c) 1995 Bernd Schmidt, Alessandro Bissacco * (c) 2002 - 2005 Toni Wilen */ //#define BLITTER_DEBUG //#define BLITTER_SLOWDOWNDEBUG 4 #define SPEEDUP #include "sysconfig.h" #include "sysdeps.h" #include "options.h" #include "uae.h" #include "memory.h" #include "custom.h" #include "custom_private.h" #include "events.h" #include "newcpu.h" #include "blitter.h" #include "blit.h" #include "savestate.h" /* we must not change ce-mode while blitter is running.. */ static int blitter_cycle_exact; uae_u16 bltcon0, bltcon1; uae_u32 bltapt, bltbpt, bltcpt, bltdpt; unsigned int blinea_shift; static uae_u16 blinea, blineb; static unsigned int blitline, blitfc, blitfill, blitife, blitsing, blitdesc; static unsigned int blitonedot, blitsign; static int blit_add; static int blit_modadda, blit_modaddb, blit_modaddc, blit_modaddd; static unsigned int blit_ch; #ifdef BLITTER_DEBUG static int blitter_dontdo; static int blitter_delayed_debug; #endif #ifdef BLITTER_SLOWDOWNDEBUG static int blitter_slowdowndebug; #endif struct bltinfo blt_info; static uae_u8 blit_filltable[256][4][2]; uae_u32 blit_masktable[BLITTER_MAX_WORDS]; enum blitter_states bltstate; static unsigned int blit_cyclecounter; static unsigned int blit_maxcyclecounter; static int blit_slowdown; #ifdef BLITTER_DEBUG static int blit_misscyclecounter; #endif #ifdef CPUEMU_6 extern uae_u8 cycle_line[]; #endif static unsigned long blit_firstline_cycles; static unsigned long blit_first_cycle; static unsigned int blit_last_cycle, blit_dmacount, blit_dmacount2; static unsigned int blit_nod; static const uae_s8 *blit_diag; static uae_u16 ddat1, ddat2; static unsigned int ddat1use, ddat2use; /* Confirmed blitter �formation by Toni Wilen (order of channels or position of idle cycles are not confirmed) 1=BLTCON0 channel mask 2=total cycles per blitted word [3=steals all cycles if BLTNASTY=1 (always if A-channel is enabled. this is illogical..)] 4=total cycles per blitted word in fillmode 5=cycle diagram (first cycle) 6=main cycle diagram (ABCD=channels,-=idle cycle,x=idle cycle but bus allocated) 1 234 5 6 F 4*4*ABC- ABCD E 4*4*ABC- ABC- D 3*4 AB- ABD C 3*3 AB- AB- B 3*3*AC- ACD A 2*2*AC AC 9 2*3 A- AD 8 2*2 A- A- 7 4 4 -BC- -BCD 6 4 4 -BC- -BC- 5 3 4 -B- -BD 4 3 3 -B- -B- 3 3 3 -C- -CD 2 3 3 -C- -C- 1 2 3 -D -D 0 2 3 -- -- NOTES: (BLTNASTY=1) - Blitter ALWAYS needs free bus cycle, even if it is running an "idle" cycle. Exception: possible extra fill mode idle cycle is "real" idle cycle. Can someone explain this? Why does idle cycles need bus cycles? - Fill mode may add one extra real idle cycle.(depends on channel mask) - All blits with channel A enabled use all available bus cycles (stops CPU accesses to Agnus bus if BLTNASTY=1) WTF? I did another test and this can't be true... Maybe I am becoming crazy.. - idle cycles (no A-channel enabled) are not "used" by blitter, they are freely available for CPU. BLTNASTY=0 makes things even more interesting.. - even zero channel blits get slower if BLTNASTY=0 depending on the number of active bitplanes. ALSO "2 cycle" blits with one real cycle and one idle cycle have the exact same speed as zero channel blit in all situations -> only the total number of cycles count, number of active channels does not matter. */ /* -1 = idle cycle and allocate bus */ static const uae_s8 blit_cycle_diagram[][10] = { { 0, 2, 0,0 }, /* 0 */ { 0, 2, 0,4 }, /* 1 */ { 0, 3, 0,3,0 }, /* 2 */ { 2, 3, 0,3,4, 3,0 }, /* 3 */ { 0, 3, 0,2,0 }, /* 4 */ { 2, 3, 0,2,4, 2,0 }, /* 5 */ { 0, 4, 0,2,3,0 }, /* 6 */ { 3, 4, 0,2,3,4, 2,3,0 }, /* 7 */ { 0, 2, 1,0 }, /* 8 */ { 2, 2, 1,4, 1,0 }, /* 9 */ { 0, 2, 1,3 }, /* A */ { 3, 3, 1,3,4, 1,3,0 }, /* B */ { 2, 3, 1,2,0, 1,2 }, /* C */ { 3, 3, 1,2,4, 1,2,0 }, /* D */ { 0, 4, 1,2,3,0 }, /* E */ { 4, 4, 1,2,3,4, 1,2,3,0 } /* F */ }; /* 5 = fill mode idle cycle ("real" idle cycle) */ static const uae_s8 blit_cycle_diagram_fill[][10] = { { 0, 3, 0,5,0 }, /* 0 */ { 0, 3, 3,5,4 }, /* 1 */ { 0, 3, 0,3,0 }, /* 2 */ { 2, 3, 3,5,4, 3,0 }, /* 3 */ { 0, 3, 0,2,5 }, /* 4 */ { 3, 4, 0,2,5,4, 2,0,0 }, /* 5 */ { 0, 4, 2,3,5,0 }, /* 6 */ { 3, 4, 2,3,5,4, 2,3,0 }, /* 7 */ { 0, 2, 1,5 }, /* 8 */ { 2, 3, 1,5,4, 1,0}, /* 9 */ { 0, 2, 1,3 }, /* A */ { 3, 3, 1,3,4, 1,3,0 }, /* B */ { 2, 3, 1,2,5, 1,2 }, /* C */ { 3, 4, 1,2,5,4, 1,2,0 }, /* D */ { 0, 4, 1,2,3,0 }, /* E */ { 4, 4, 1,2,3,4, 1,2,3,0 } /* F */ }; /* line draw takes 4 cycles (-X-X) it also have real idle cycles and only 2 dma fetches (read from C, write to D, but see below) Oddities: - first word is written to address pointed by BLTDPT but all following writes go to address pointed by BLTCPT! - BLTDMOD is ignored by blitter (BLTCMOD is used) - state of D-channel enable bit does not matter! - disabling A-channel freezes the content of BPLAPT */ static const uae_s8 blit_cycle_diagram_line[] = { 0, 4, 0,3,0,4, 0,0,0,0,0,0,0,0,0,0 /* guessed */ }; static const uae_s8 blit_cycle_diagram_finald[] = { 0, 2, 0,4 }; void build_blitfilltable (void) { unsigned int d, fillmask; unsigned int i; for (i = 0; i < BLITTER_MAX_WORDS; i++) blit_masktable[i] = 0xFFFF; for (d = 0; d < 256; d++) { for (i = 0; i < 4; i++) { unsigned int fc = i & 1; uae_u8 data = d; for (fillmask = 1; fillmask != 0x100; fillmask <<= 1) { uae_u16 tmp = data; if (fc) { if (i & 2) data |= fillmask; else data ^= fillmask; } if (tmp & fillmask) fc = !fc; } blit_filltable[d][i][0] = data; blit_filltable[d][i][1] = fc; } } } static void blitter_dump (void) { write_log ("APT=%08.8X BPT=%08.8X CPT=%08.8X DPT=%08.8X\n", bltapt, bltbpt, bltcpt, bltdpt); write_log ("CON0=%04.4X CON1=%04.4X ADAT=%04.4X BDAT=%04.4X CDAT=%04.4X\n", bltcon0, bltcon1, blt_info.bltadat, blt_info.bltbdat, blt_info.bltcdat); write_log ("AFWM=%04.4X ALWM=%04.4X AMOD=%04.4X BMOD=%04.4X CMOD=%04.4X DMOD=%04.4X\n", blt_info.bltafwm, blt_info.bltalwm, blt_info.bltamod & 0xffff, blt_info.bltbmod & 0xffff, blt_info.bltcmod & 0xffff, blt_info.bltdmod & 0xffff); } STATIC_INLINE int channel_state (unsigned int cycles) { if ((int)cycles < blit_diag[0]) return blit_diag[blit_diag[1] + 2 + cycles]; return blit_diag[((cycles - blit_diag[0]) % blit_diag[1]) + 2]; } #ifdef CPUEMU_6 STATIC_INLINE int canblit (unsigned int hpos) { if (is_bitplane_dma (hpos)) return 0; if (cycle_line[hpos] == 0) return 1; if (cycle_line[hpos] & CYCLE_REFRESH) return -1; return 0; } #endif static void blitter_done (void) { ddat1use = ddat2use = 0; bltstate = BLT_done; blitter_done_notify (); INTREQ(0x8040); eventtab[ev_blitter].active = 0; unset_special (®s, SPCFLAG_BLTNASTY); #ifdef BLITTER_DEBUG write_log ("vpos=%d, cycles %d, missed %d, total %d\n", vpos, blit_cyclecounter, blit_misscyclecounter, blit_cyclecounter + blit_misscyclecounter); #endif } static void blitter_dofast (void) { int i,j; uaecptr bltadatptr = 0, bltbdatptr = 0, bltcdatptr = 0, bltddatptr = 0; uae_u8 mt = bltcon0 & 0xFF; blit_masktable[0] = blt_info.bltafwm; blit_masktable[blt_info.hblitsize - 1] &= blt_info.bltalwm; if (bltcon0 & 0x800) { bltadatptr = bltapt; bltapt += (blt_info.hblitsize*2 + blt_info.bltamod)*blt_info.vblitsize; } if (bltcon0 & 0x400) { bltbdatptr = bltbpt; bltbpt += (blt_info.hblitsize*2 + blt_info.bltbmod)*blt_info.vblitsize; } if (bltcon0 & 0x200) { bltcdatptr = bltcpt; bltcpt += (blt_info.hblitsize*2 + blt_info.bltcmod)*blt_info.vblitsize; } if (bltcon0 & 0x100) { bltddatptr = bltdpt; bltdpt += (blt_info.hblitsize*2 + blt_info.bltdmod)*blt_info.vblitsize; } #ifdef SPEEDUP if (blitfunc_dofast[mt] && !blitfill) { (*blitfunc_dofast[mt])(bltadatptr, bltbdatptr, bltcdatptr, bltddatptr, &blt_info); } else #endif { uae_u32 blitbhold = blt_info.bltbhold; uae_u32 preva = 0, prevb = 0; uaecptr dstp = 0; int dodst = 0; /*if (!blitfill) write_log ("minterm %x not present\n",mt); */ for (j = 0; j < blt_info.vblitsize; j++) { blitfc = !!(bltcon1 & 0x4); for (i = 0; i < blt_info.hblitsize; i++) { uae_u32 bltadat, blitahold; uae_u16 bltbdat; if (bltadatptr) { blt_info.bltadat = bltadat = chipmem_wget (bltadatptr); bltadatptr += 2; } else bltadat = blt_info.bltadat; bltadat &= blit_masktable[i]; blitahold = (((uae_u32)preva << 16) | bltadat) >> blt_info.blitashift; preva = bltadat; if (bltbdatptr) { blt_info.bltbdat = bltbdat = chipmem_wget (bltbdatptr); bltbdatptr += 2; blitbhold = (((uae_u32)prevb << 16) | bltbdat) >> blt_info.blitbshift; prevb = bltbdat; } if (bltcdatptr) { blt_info.bltcdat = chipmem_wget (bltcdatptr); bltcdatptr += 2; } if (dodst) chipmem_wput (dstp, blt_info.bltddat); blt_info.bltddat = blit_func (blitahold, blitbhold, blt_info.bltcdat, mt) & 0xFFFF; if (blitfill) { uae_u16 d = blt_info.bltddat; int ifemode = blitife ? 2 : 0; int fc1 = blit_filltable[d & 255][ifemode + blitfc][1]; blt_info.bltddat = (blit_filltable[d & 255][ifemode + blitfc][0] + (blit_filltable[d >> 8][ifemode + fc1][0] << 8)); blitfc = blit_filltable[d >> 8][ifemode + fc1][1]; } if (blt_info.bltddat) blt_info.blitzero = 0; if (bltddatptr) { dodst = 1; dstp = bltddatptr; bltddatptr += 2; } } if (bltadatptr) bltadatptr += blt_info.bltamod; if (bltbdatptr) bltbdatptr += blt_info.bltbmod; if (bltcdatptr) bltcdatptr += blt_info.bltcmod; if (bltddatptr) bltddatptr += blt_info.bltdmod; } if (dodst) chipmem_wput (dstp, blt_info.bltddat); blt_info.bltbhold = blitbhold; } blit_masktable[0] = 0xFFFF; blit_masktable[blt_info.hblitsize - 1] = 0xFFFF; bltstate = BLT_done; } static void blitter_dofast_desc (void) { int i,j; uaecptr bltadatptr = 0, bltbdatptr = 0, bltcdatptr = 0, bltddatptr = 0; uae_u8 mt = bltcon0 & 0xFF; blit_masktable[0] = blt_info.bltafwm; blit_masktable[blt_info.hblitsize - 1] &= blt_info.bltalwm; if (bltcon0 & 0x800) { bltadatptr = bltapt; bltapt -= (blt_info.hblitsize*2 + blt_info.bltamod)*blt_info.vblitsize; } if (bltcon0 & 0x400) { bltbdatptr = bltbpt; bltbpt -= (blt_info.hblitsize*2 + blt_info.bltbmod)*blt_info.vblitsize; } if (bltcon0 & 0x200) { bltcdatptr = bltcpt; bltcpt -= (blt_info.hblitsize*2 + blt_info.bltcmod)*blt_info.vblitsize; } if (bltcon0 & 0x100) { bltddatptr = bltdpt; bltdpt -= (blt_info.hblitsize*2 + blt_info.bltdmod)*blt_info.vblitsize; } #ifdef SPEEDUP if (blitfunc_dofast_desc[mt] && !blitfill) { (*blitfunc_dofast_desc[mt])(bltadatptr, bltbdatptr, bltcdatptr, bltddatptr, &blt_info); } else #endif { uae_u32 blitbhold = blt_info.bltbhold; uae_u32 preva = 0, prevb = 0; uaecptr dstp = 0; int dodst = 0; for (j = 0; j < blt_info.vblitsize; j++) { blitfc = !!(bltcon1 & 0x4); for (i = 0; i < blt_info.hblitsize; i++) { uae_u32 bltadat, blitahold; uae_u16 bltbdat; if (bltadatptr) { bltadat = blt_info.bltadat = chipmem_wget (bltadatptr); bltadatptr -= 2; } else bltadat = blt_info.bltadat; bltadat &= blit_masktable[i]; blitahold = (((uae_u32)bltadat << 16) | preva) >> blt_info.blitdownashift; preva = bltadat; if (bltbdatptr) { blt_info.bltbdat = bltbdat = chipmem_wget (bltbdatptr); bltbdatptr -= 2; blitbhold = (((uae_u32)bltbdat << 16) | prevb) >> blt_info.blitdownbshift; prevb = bltbdat; } if (bltcdatptr) { blt_info.bltcdat = blt_info.bltbdat = chipmem_wget (bltcdatptr); bltcdatptr -= 2; } if (dodst) chipmem_wput (dstp, blt_info.bltddat); blt_info.bltddat = blit_func (blitahold, blitbhold, blt_info.bltcdat, mt) & 0xFFFF; if (blitfill) { uae_u16 d = blt_info.bltddat; int ifemode = blitife ? 2 : 0; int fc1 = blit_filltable[d & 255][ifemode + blitfc][1]; blt_info.bltddat = (blit_filltable[d & 255][ifemode + blitfc][0] + (blit_filltable[d >> 8][ifemode + fc1][0] << 8)); blitfc = blit_filltable[d >> 8][ifemode + fc1][1]; } if (blt_info.bltddat) blt_info.blitzero = 0; if (bltddatptr) { dstp = bltddatptr; dodst = 1; bltddatptr -= 2; } } if (bltadatptr) bltadatptr -= blt_info.bltamod; if (bltbdatptr) bltbdatptr -= blt_info.bltbmod; if (bltcdatptr) bltcdatptr -= blt_info.bltcmod; if (bltddatptr) bltddatptr -= blt_info.bltdmod; } if (dodst) chipmem_wput (dstp, blt_info.bltddat); blt_info.bltbhold = blitbhold; } blit_masktable[0] = 0xFFFF; blit_masktable[blt_info.hblitsize - 1] = 0xFFFF; bltstate = BLT_done; } STATIC_INLINE void blitter_read (void) { if (bltcon0 & 0x200) { if (!dmaen(DMA_BLITTER)) return; blt_info.bltcdat = chipmem_bank.wget(bltcpt); } bltstate = BLT_work; } STATIC_INLINE void blitter_write (void) { if (blt_info.bltddat) blt_info.blitzero = 0; /* D-channel state has no effect on linedraw, but C must be enabled or nothing is drawn! */ if (bltcon0 & 0x200) { if (!dmaen(DMA_BLITTER)) return; chipmem_bank.wput(bltdpt, blt_info.bltddat); } bltstate = BLT_next; } STATIC_INLINE void blitter_line_incx (void) { if (++blinea_shift == 16) { blinea_shift = 0; bltcpt += 2; } } STATIC_INLINE void blitter_line_decx (void) { if (blinea_shift-- == 0) { blinea_shift = 15; bltcpt -= 2; } } STATIC_INLINE void blitter_line_decy (void) { bltcpt -= blt_info.bltcmod; blitonedot = 0; } STATIC_INLINE void blitter_line_incy (void) { bltcpt += blt_info.bltcmod; blitonedot = 0; } static void blitter_line (void) { uae_u16 blitahold = blinea >> blinea_shift; uae_u16 blitbhold = blineb & 1 ? 0xFFFF : 0; uae_u16 blitchold = blt_info.bltcdat; if (blitsing && blitonedot) blitahold = 0; blitonedot = 1; blt_info.bltddat = blit_func(blitahold, blitbhold, blitchold, bltcon0 & 0xFF); } static void blitter_line_proc (void) { if (!blitsign) { if (bltcon0 & 0x800) bltapt += (uae_s16)blt_info.bltamod; if (bltcon1 & 0x10){ if (bltcon1 & 0x8) blitter_line_decy(); else blitter_line_incy(); } else { if (bltcon1 & 0x8) blitter_line_decx(); else blitter_line_incx(); } } else { if (bltcon0 & 0x800) bltapt += (uae_s16)blt_info.bltbmod; } if (bltcon1 & 0x10){ if (bltcon1 & 0x4) blitter_line_decx(); else blitter_line_incx(); } else { if (bltcon1 & 0x4) blitter_line_decy(); else blitter_line_incy(); } blitsign = 0 > (uae_s16)bltapt; bltstate = BLT_write; } STATIC_INLINE void blitter_nxline (void) { blineb = (blineb << 1) | (blineb >> 15); blt_info.vblitsize--; bltstate = BLT_read; } #ifdef CPUEMU_6 static unsigned int blit_last_hpos; static unsigned int blitter_cyclecounter; static int blitter_hcounter1, blitter_hcounter2; static int blitter_vcounter1, blitter_vcounter2; static void decide_blitter_line (unsigned int hpos) { hpos++; if (dmaen (DMA_BLITTER)) { while (blit_last_hpos < hpos) { int c = channel_state (blit_cyclecounter); for (;;) { if (c) { if (!canblit (blit_last_hpos)) break; } blit_cyclecounter++; if (c == 3) { blitter_read(); cycle_line[blit_last_hpos] |= CYCLE_BLITTER; } else if (c == 4) { if (ddat1use) { bltdpt = bltcpt; } ddat1use = 1; blitter_line(); blitter_line_proc(); blitter_nxline(); blitter_write(); cycle_line[blit_last_hpos] |= CYCLE_BLITTER; if (blt_info.vblitsize == 0) { bltdpt = bltcpt; blitter_done(); return; } } break; } blit_last_hpos++; } } else { blit_last_hpos = hpos; } if (blit_last_hpos > maxhpos) blit_last_hpos = 0; } #endif static void actually_do_blit (void) { if (blitline) { do { blitter_read (); blitter_line (); blitter_line_proc (); blitter_write (); bltdpt = bltcpt; blitter_nxline (); if (blt_info.vblitsize == 0) bltstate = BLT_done; } while (bltstate != BLT_done); } else { if (blitdesc) blitter_dofast_desc (); else blitter_dofast (); bltstate = BLT_done; } } void blitter_handler (void) { static int blitter_stuck; if (!dmaen (DMA_BLITTER)) { eventtab[ev_blitter].active = 1; eventtab[ev_blitter].oldcycles = get_cycles (); eventtab[ev_blitter].evtime = 10 * CYCLE_UNIT + get_cycles (); /* wait a little */ blitter_stuck++; if (blitter_stuck < 20000 || !currprefs.immediate_blits) return; /* gotta come back later. */ /* "free" blitter in immediate mode if it has been "stuck" ~3 frames * fixes some JIT game incompatibilities */ write_log ("Blitter force-unstuck!\n"); } blitter_stuck = 0; if (blit_slowdown > 0 && !currprefs.immediate_blits) { eventtab[ev_blitter].active = 1; eventtab[ev_blitter].oldcycles = get_cycles (); eventtab[ev_blitter].evtime = blit_slowdown * CYCLE_UNIT + get_cycles (); blit_slowdown = -1; return; } #ifdef BLITTER_DEBUG if (!blitter_dontdo) actually_do_blit (); else bltstate = BLT_done; #else actually_do_blit (); #endif blitter_done (); } #ifdef CPUEMU_6 static uae_u32 preva, prevb; STATIC_INLINE uae_u16 blitter_doblit (void) { uae_u32 blitahold; uae_u16 bltadat, ddat; uae_u8 mt = bltcon0 & 0xFF; bltadat = blt_info.bltadat; if (blitter_hcounter1 == 0) bltadat &= blt_info.bltafwm; if (blitter_hcounter1 == blt_info.hblitsize - 1) bltadat &= blt_info.bltalwm; if (blitdesc) blitahold = (((uae_u32)bltadat << 16) | preva) >> blt_info.blitdownashift; else blitahold = (((uae_u32)preva << 16) | bltadat) >> blt_info.blitashift; preva = bltadat; ddat = blit_func (blitahold, blt_info.bltbhold, blt_info.bltcdat, mt) & 0xFFFF; if (bltcon1 & 0x18) { uae_u16 d = ddat; int ifemode = blitife ? 2 : 0; int fc1 = blit_filltable[d & 255][ifemode + blitfc][1]; ddat = (blit_filltable[d & 255][ifemode + blitfc][0] + (blit_filltable[d >> 8][ifemode + fc1][0] << 8)); blitfc = blit_filltable[d >> 8][ifemode + fc1][1]; } if (ddat) blt_info.blitzero = 0; return ddat; } STATIC_INLINE int blitter_doddma (void) { int wd; uae_u16 d; wd = 0; if (blit_dmacount2 == 0) { d = blitter_doblit (); wd = -1; } else if (ddat2use) { d = ddat2; ddat2use = 0; wd = 2; } else if (ddat1use) { d = ddat1; ddat1use = 0; wd = 1; } if (wd) { chipmem_wput (bltdpt, d); bltdpt += blit_add; blitter_hcounter2++; if (blitter_hcounter2 == blt_info.hblitsize) { blitter_hcounter2 = 0; bltdpt += blit_modaddd; blitter_vcounter2++; if (blitter_vcounter2 > blitter_vcounter1) blitter_vcounter1 = blitter_vcounter2; } if (blit_ch == 1) blitter_hcounter1 = blitter_hcounter2; } return wd; } STATIC_INLINE void blitter_dodma (unsigned int ch) { switch (ch) { case 1: blt_info.bltadat = chipmem_wget (bltapt); bltapt += blit_add; break; case 2: blt_info.bltbdat = chipmem_wget (bltbpt); bltbpt += blit_add; if (blitdesc) blt_info.bltbhold = (((uae_u32)blt_info.bltbdat << 16) | prevb) >> blt_info.blitdownbshift; else blt_info.bltbhold = (((uae_u32)prevb << 16) | blt_info.bltbdat) >> blt_info.blitbshift; prevb = blt_info.bltbdat; break; case 3: blt_info.bltcdat = chipmem_wget (bltcpt); bltcpt += blit_add; break; } blitter_cyclecounter++; if (blitter_cyclecounter >= blit_dmacount2) { blitter_cyclecounter = 0; ddat2 = ddat1; ddat2use = ddat1use; ddat1use = 0; ddat1 = blitter_doblit (); if (bltcon0 & 0x100) ddat1use = 1; blitter_hcounter1++; if (blitter_hcounter1 == blt_info.hblitsize) { blitter_hcounter1 = 0; if (bltcon0 & 0x800) bltapt += blit_modadda; if (bltcon0 & 0x400) bltbpt += blit_modaddb; if (bltcon0 & 0x200) bltcpt += blit_modaddc; blitter_vcounter1++; blitfc = !!(bltcon1 & 0x4); } } } void decide_blitter (unsigned int hpos) { if (bltstate == BLT_done) return; #ifdef BLITTER_DEBUG if (blitter_delayed_debug) { blitter_delayed_debug = 0; blitter_dump (); } #endif if (!blitter_cycle_exact) return; if (blitline) { decide_blitter_line (hpos); return; } hpos++; if (dmaen (DMA_BLITTER)) { while (blit_last_hpos < hpos) { int c = channel_state (blit_cyclecounter); #ifdef BLITTER_SLOWDOWNDEBUG blitter_slowdowndebug--; if (blitter_slowdowndebug < 0) { cycle_line[blit_last_hpos] |= CYCLE_BLITTER; blitter_slowdowndebug = BLITTER_SLOWDOWNDEBUG; } #endif for (;;) { int v; if (c == 5) { /* real idle cycle */ blit_cyclecounter++; break; } /* all cycles need free bus, even idle cycles (except fillmode idle) */ v = canblit (blit_last_hpos); if (v < 0 && c == 0) { blit_cyclecounter++; break; } if (v <= 0) { #ifdef BLITTER_DEBUG blit_misscyclecounter++; #endif break; } if (c < 0) { /* no channel but bus still needs to be allocated.. */ cycle_line[blit_last_hpos] |= CYCLE_BLITTER; blit_cyclecounter++; } else if (c == 4) { if (blitter_doddma ()) { cycle_line[blit_last_hpos] |= CYCLE_BLITTER; blit_cyclecounter++; } } else if (c) { if (blitter_vcounter1 < blt_info.vblitsize) { cycle_line[blit_last_hpos] |= CYCLE_BLITTER; blitter_dodma (c); } blit_cyclecounter++; } else { blit_cyclecounter++; /* check if blit with zero channels has ended */ if (blit_cyclecounter >= blit_maxcyclecounter) { blitter_done (); return; } } if (blitter_vcounter1 >= blt_info.vblitsize && blitter_vcounter2 >= blt_info.vblitsize) { if (!ddat1use && !ddat2use) { blitter_done (); return; } if (blit_diag != blit_cycle_diagram_finald) { blit_cyclecounter = 0; blit_diag = blit_cycle_diagram_finald; } } break; } blit_last_hpos++; } } else { blit_last_hpos = hpos; } if (blit_last_hpos > maxhpos) blit_last_hpos = 0; } #else void decide_blitter (unsigned int hpos) { } #endif static void blitter_force_finish (void) { uae_u16 odmacon; if (bltstate == BLT_done) return; if (bltstate != BLT_done) { /* blitter is currently running * force finish (no blitter state support yet) */ odmacon = dmacon; dmacon |= DMA_MASTER | DMA_BLITTER; write_log ("forcing blitter finish\n"); #ifdef CPUEMU_6 if (currprefs.blitter_cycle_exact) { int rounds = 10000; while (bltstate != BLT_done && rounds > 0) { memset (cycle_line, 0, maxhpos); decide_blitter (maxhpos); rounds--; } if (rounds == 0) write_log ("blitter froze!?\n"); } else #endif actually_do_blit (); blitter_done (); dmacon = odmacon; } } static void blit_bltset (unsigned int con) { int i; blitline = bltcon1 & 1; blitfill = bltcon1 & 0x18; blitdesc = bltcon1 & 2; blit_ch = (bltcon0 & 0x0f00) >> 8; if (blitline) { if (blt_info.hblitsize != 2) write_log ("weird hblitsize in linemode: %d vsize=%d PC%=%x\n", blt_info.hblitsize, blt_info.vblitsize, m68k_getpc (®s)); blit_diag = blit_cycle_diagram_line; } else { if (con & 2) { blitfc = !!(bltcon1 & 0x4); blitife = bltcon1 & 0x8; if ((bltcon1 & 0x18) == 0x18) { /* Digital "Trash" demo does this; others too. Apparently, no * negative effects. */ static int warn = 1; if (warn) write_log ("warning: weird fill mode (further messages suppressed) PC=%x\n", m68k_getpc (®s)); warn = 0; blitife = 0; } } if (blitfill && !blitdesc) { static int warn = 1; if (warn) write_log ("warning: blitter fill without desc (further messages suppressed) PC=%x\n", m68k_getpc (®s)); warn = 0; } blit_diag = blitfill ? blit_cycle_diagram_fill[blit_ch] : blit_cycle_diagram[blit_ch]; } if ((bltcon1 & 0x80) && (currprefs.chipset_mask & CSMASK_ECS_AGNUS)) write_log("warning: BLTCON1 DOFF-bit set\n"); ddat1use = ddat2use = 0; blit_dmacount = blit_dmacount2 = 0; blit_nod = 1; for (i = 0; i < blit_diag[1]; i++) { int v = blit_diag[2 + i]; if (v) blit_dmacount++; if (v > 0 && v < 4) blit_dmacount2++; if (v == 4) blit_nod = 0; } blt_info.blitashift = bltcon0 >> 12; blt_info.blitdownashift = 16 - blt_info.blitashift; blt_info.blitbshift = bltcon1 >> 12; blt_info.blitdownbshift = 16 - blt_info.blitbshift; } static void blit_modset (void) { int mult; blit_add = blitdesc ? -2 : 2; mult = blitdesc ? -1 : 1; blit_modadda = mult * blt_info.bltamod; blit_modaddb = mult * blt_info.bltbmod; blit_modaddc = mult * blt_info.bltcmod; blit_modaddd = mult * blt_info.bltdmod; } void reset_blit (unsigned int bltcon) { if (bltstate == BLT_done) return; if (bltcon) blit_bltset (bltcon); blit_modset (); } void do_blitter (unsigned int hpos) { unsigned int cycles; #ifdef BLITTER_DEBUG enum blitter_states oldstate = bltstate; #endif blitter_cycle_exact = currprefs.blitter_cycle_exact; blt_info.blitzero = 1; bltstate = BLT_init; #ifdef CPUEMU_6 preva = 0; prevb = 0; #endif blit_firstline_cycles = blit_first_cycle = get_cycles (); #ifdef BLITTER_DEBUG blit_misscyclecounter = 0; #endif blit_last_cycle = 0; blit_maxcyclecounter = 0; blit_cyclecounter = 0; #ifdef CPUEMU_6 blit_last_hpos = hpos; #endif reset_blit (1|2); if (blitline) { blitsing = bltcon1 & 0x2; blinea = blt_info.bltadat; blineb = (blt_info.bltbdat >> blt_info.blitbshift) | (blt_info.bltbdat << (16 - blt_info.blitbshift)); blitsign = bltcon1 & 0x40; blitonedot = 0; cycles = blt_info.vblitsize; } else { blit_firstline_cycles = blit_first_cycle + blit_diag[1] * blt_info.hblitsize * CYCLE_UNIT; cycles = blt_info.vblitsize * blt_info.hblitsize; } #ifdef BLITTER_DEBUG blitter_dontdo = 0; if (1) { if (oldstate != BLT_done) write_log ("blitter was already active!\n"); write_log("blitstart: v=%03.3d h=%03.3d %dx%d %d (%d) d=%d f=%02.2X n=%d pc=%p l=%d dma=%d\n", vpos, hpos, blt_info.hblitsize, blt_info.vblitsize, cycles, blit_ch, blitdesc ? 1 : 0, blitfill, dmaen(DMA_BLITPRI) ? 1 : 0, m68k_getpc (®s), blitline, dmaen(DMA_BLITTER)); blitter_dump (); } #endif blit_slowdown = 0; unset_special (®s, SPCFLAG_BLTNASTY); if (dmaen (DMA_BLITPRI)) set_special (®s, SPCFLAG_BLTNASTY); if (blt_info.vblitsize == 0 || (blitline && blt_info.hblitsize != 2)) { blitter_done (); return; } if (dmaen (DMA_BLITTER)) bltstate = BLT_work; blit_maxcyclecounter = 0x7fffffff; #ifdef CPUEMU_6 if (currprefs.blitter_cycle_exact) { blitter_hcounter1 = blitter_hcounter2 = 0; blitter_vcounter1 = blitter_vcounter2 = 0; if (blit_nod) blitter_vcounter2 = blt_info.vblitsize; if (blit_ch == 0) blit_maxcyclecounter = blt_info.hblitsize * blt_info.vblitsize; return; } #endif if (currprefs.immediate_blits) cycles = 1; eventtab[ev_blitter].active = 1; eventtab[ev_blitter].oldcycles = get_cycles (); eventtab[ev_blitter].evtime = cycles * blit_diag[1] * CYCLE_UNIT + get_cycles (); events_schedule(); } void maybe_blit (unsigned int hpos, int hack) { static int warned; if (bltstate == BLT_done) return; if (!warned && dmaen (DMA_BLITTER)) { #ifndef BLITTER_DEBUG warned = 1; #endif if (m68k_getpc (®s) < 0xe0000 || m68k_getpc (®s) >= 0x10000000) write_log ("warning: Program does not wait for blitter %p vpos=%d tc=%d\n", m68k_getpc (®s), vpos, blit_cyclecounter); } if (blitter_cycle_exact) { decide_blitter (hpos); goto end; } if (!eventtab[ev_blitter].active) write_log ("FOO!!?\n"); if (hack == 1 && get_cycles() < blit_firstline_cycles) goto end; blitter_handler (); end:; #ifdef BLITTER_DEBUG blitter_delayed_debug = 1; #endif } unsigned int blitnasty (void) { unsigned int cycles, ccnt; if (bltstate == BLT_done) return 0; if (!dmaen(DMA_BLITTER)) return 0; if ((int)blit_last_cycle >= blit_diag[0] && (int)blit_dmacount == blit_diag[1]) return 0; cycles = (get_cycles () - blit_first_cycle) / CYCLE_UNIT; ccnt = 0; while (blit_last_cycle < cycles) { int c = channel_state (blit_last_cycle++); if (!c) ccnt++; } return ccnt; } /* very approximate emulation of blitter slowdown caused by bitplane DMA */ void blitter_slowdown (int ddfstrt, int ddfstop, unsigned int totalcycles, unsigned int freecycles) { static int oddfstrt, oddfstop; static unsigned ototal, ofree; static int slow; if (!totalcycles || ddfstrt < 0 || ddfstop < 0) return; if (ddfstrt != oddfstrt || ddfstop != oddfstop || totalcycles != ototal || ofree != freecycles) { int linecycles = ((ddfstop - ddfstrt + totalcycles - 1) / totalcycles) * totalcycles; int freelinecycles = ((ddfstop - ddfstrt + totalcycles - 1) / totalcycles) * freecycles; int dmacycles = (linecycles * blit_dmacount) / blit_diag[1]; oddfstrt = ddfstrt; oddfstop = ddfstop; ototal = totalcycles; ofree = freecycles; slow = 0; if (dmacycles > freelinecycles) slow = dmacycles - freelinecycles; } if (blit_slowdown < 0 || blitline) return; blit_slowdown += slow; #ifdef BLITTER_DEBUG blit_misscyclecounter += slow; #endif } #ifdef SAVESTATE const uae_u8 *restore_blitter (const uae_u8 *src) { uae_u32 flags = restore_u32 (); bltstate = (flags & 1) ? BLT_init : BLT_done; if (flags & 2) { write_log ("blitter was force-finished when this statefile was saved\n"); write_log ("contact the author if restored program freezes\n"); } return src; } void restore_blitter_finish (void) { if (bltstate == BLT_init) { write_log ("blitter was started but DMA was inactive during save\n"); do_blitter (0); } } uae_u8 *save_blitter (uae_u32 *len, uae_u8 *dstptr) { uae_u8 *dstbak, *dst; int forced; forced = 0; if (bltstate != BLT_done && bltstate != BLT_init) { write_log ("blitter is active, forcing immediate finish\n"); /* blitter is active just now but we don't have blitter state support yet */ blitter_force_finish (); forced = 2; } if (dstptr) dstbak = dst = dstptr; else dstbak = dst = malloc (16); save_u32 (((bltstate != BLT_done) ? 0 : 1) | forced); *len = dst - dstbak; return dstbak; } #endif /* SAVESTATE */