1 // basic, incomplete SSP160x (SSP1601?) interpreter
5 * most names taken from MAME code
9 * desc: Constant register with all bits set (0xffff).
13 * desc: Generic register. When set, updates P (P = X * Y * 2) ??
17 * desc: Generic register. When set, updates P (P = X * Y * 2) ??
25 * desc: Status register. From MAME: bits 0-9 are CONTROL, other FLAG
27 * 210 - RPL (?) "Loop size". If non-zero, makes (rX+) and (rX-) respectively
28 * modulo-increment and modulo-decrement. The value shows which
29 * power of 2 to use, i.e. 4 means modulo by 16.
30 * (e: fir16_32.sc, IIR_4B.SC, DECIM.SC)
32 * 5 - GP0_0 (ST5?) Changed before acessing PM0 (affects banking?).
33 * 6 - GP0_1 (ST6?) Cleared before acessing PM0 (affects banking?). Set after.
34 * datasheet says these (5,6) bits correspond to hardware pins.
35 * 7 - IE (?) Not directly used by SVP code (never set, but preserved)?
36 * 8 - OP (?) Not used by SVP code (only cleared)? (MAME: saturated value
37 * (probably means clamping? i.e. 0x7ffc + 9 -> 0x7fff))
38 * 9 - MACS (?) Not used by SVP code (only cleared)? (e: "mac shift")
39 * a - GPI_0 Interrupt 0 enable/status?
40 * b - GPI_1 Interrupt 1 enable/status?
41 * c - L L flag. Carry?
43 * e - OV Overflow flag.
44 * f - N Negative flag.
45 * seen directly changing code sequences:
46 * ldi ST, 0 ld A, ST ld A, ST ld A, ST ldi st, 20h
47 * ldi ST, 60h ori A, 60h and A, E8h and A, E8h
48 * ld ST, A ld ST, A ori 3
53 * desc: hw stack of 6 levels (according to datasheet)
57 * desc: Program counter.
61 * desc: multiply result register. Updated after mp* instructions,
62 * or writes to X or Y (P = X * Y * 2) ??
63 * probably affected by MACS bit in ST.
65 * 8. "PM0" (PM from PMAR name from Tasco's docs)
67 * desc: Programmable Memory access register.
68 * On reset, or when one (both?) GP0 bits are clear,
69 * acts as status for XST, mapped at 015004 at 68k side:
70 * bit0: ssp has written something to XST (cleared when 015004 is read)
71 * bit1: 68k has written something through a1500{0|2} (cleared on PM0 read)
75 * desc: Programmable Memory access register.
76 * This reg. is only used as PMAR.
80 * desc: Programmable Memory access register.
81 * This reg. is only used as PMAR.
85 * desc: eXternal STate. Mapped to a15000 and a15002 at 68k side.
86 * Can be programmed as PMAR? (only seen in test mode code)
87 * Affects PM0 when written to?
91 * desc: Programmable Memory access register.
92 * This reg. is only used as PMAR. The most used PMAR by VR.
96 * 14. "PMC" (PMC from PMAC name from Tasco's docs)
98 * desc: Programmable Memory access Control. Set using 2 16bit writes,
99 * first address, then mode word. After setting PMAC, PMAR sould
100 * be accessed to program it.
104 * desc: Accumulator Low. 16 least significant bits of accumulator (not 100% sure)
105 * (normally reading acc (ld X, A) you get 16 most significant bits).
108 * There are 8 8-bit pointer registers rX. r0-r3 (ri) point to RAM0, r4-r7 (rj) point to RAM1.
109 * They can be accessed directly, or 2 indirection levels can be used [ (rX), ((rX)) ],
110 * which work similar to * and ** operators in C, only they use different memory banks and
111 * ((rX)) also does post-increment. First indirection level (rX) accesses RAMx, second accesses
112 * program memory at address read from (rX), and increments value in (rX).
114 * r0,r1,r2,r4,r5,r6 can be modified [ex: ldi r0, 5].
115 * 3 modifiers can be applied (optional):
116 * + : post-increment [ex: ld a, (r0+) ]. Can be made modulo-increment by setting RPL bits in ST.
117 * - : post-decrement. Can be made modulo-decrement by setting RPL bits in ST (not sure).
118 * +!: post-increment, unaffected by RPL (probably).
119 * These are only used on 1st indirection level, so things like [ld a, ((r0+))] and [ld X, r6-]
120 * ar probably invalid.
122 * r3 and r7 are special and can not be changed (at least Samsung samples and SVP code never do).
123 * They are fixed to the start of their RAM banks. (They are probably changeable for ssp1605+,
124 * Samsung's old DSP page claims that).
125 * 1 of these 4 modifiers must be used (short form direct addressing?):
126 * |00: RAMx[0] [ex: (r3|00), 0] (based on sample code)
128 * |10: RAMx[2] ? maybe 10h? accortding to Div_c_dp.sc, 2
134 * ld a, * doesn't affect flags! (e: A_LAW.SC, Div_c_dp.sc)
136 * mld (rj), (ri) [, b]
137 * operation: A = 0; P = (rj) * (ri)
138 * notes: based on IIR_4B.SC sample. flags? what is b???
140 * mpya (rj), (ri) [, b]
141 * name: multiply and add?
142 * operation: A += P; P = (rj) * (ri)
145 * name: multiply and subtract?
146 * notes: not used by VR code.
149 * mod cond, shr does arithmetic shift
151 * 'ld -, AL' and probably 'ld AL, -' are for dummy assigns
154 * 000000 - 1fffff ROM, accessable by both
155 * 200000 - 2fffff unused?
156 * 300000 - 31ffff DRAM, both
157 * 320000 - 38ffff unused?
158 * 390000 - 3907ff IRAM. can only be accessed by ssp?
159 * 390000 - 39ffff similar mapping to "cell arrange" in Sega CD, 68k only?
160 * 3a0000 - 3affff similar mapping to "cell arrange" in Sega CD, a bit different
162 * 30fe02 - 0 if SVP busy, 1 if done (set by SVP, checked and cleared by 68k)
163 * 30fe06 - also sync related.
164 * 30fe08 - job number [1-12] for SVP. 0 means no job. Set by 68k, read-cleared by SVP.
167 * + figure out if 'op A, P' is 32bit (nearly sure it is)
168 * * what exactly is AL?
169 * * does mld, mpya load their operands into X and Y?
173 * pressing all buttons while resetting game will kick into test mode
175 * Assumptions in this code
176 * P is not directly writeable
177 * flags correspond to full 32bit accumulator
178 * only Z and N status flags are emulated (others unused by SVP)
179 * modifiers for 'OP a, ri' are ignored (invalid?/not used by SVP)
180 * modifiers '+' and '+!' act the same (this is most likely wrong)
181 * 'ld d, (a)' loads from program ROM
184 #include "../../PicoInt.h"
186 #define u32 unsigned int
189 #define rX ssp->gr[SSP_X].h
190 #define rY ssp->gr[SSP_Y].h
191 #define rA ssp->gr[SSP_A].h
192 #define rST ssp->gr[SSP_ST].h // 4
193 #define rSTACK ssp->gr[SSP_STACK].h
194 #define rPC ssp->gr[SSP_PC].h
195 #define rP ssp->gr[SSP_P]
196 #define rPM0 ssp->gr[SSP_PM0].h // 8
197 #define rPM1 ssp->gr[SSP_PM1].h
198 #define rPM2 ssp->gr[SSP_PM2].h
199 #define rXST ssp->gr[SSP_XST].h
200 #define rPM4 ssp->gr[SSP_PM4].h // 12
202 #define rPMC ssp->gr[SSP_PMC] // will keep addr in .h, mode in .l
203 #define rAL ssp->gr[SSP_A].l
205 #define rA32 ssp->gr[SSP_A].v
208 #define IJind (((op>>6)&4)|(op&3))
210 #define GET_PC() (PC - (unsigned short *)svp->iram_rom)
211 #define GET_PPC_OFFS() ((unsigned int)PC - (unsigned int)svp->iram_rom - 2)
212 #define SET_PC(d) PC = (unsigned short *)svp->iram_rom + d
214 #define REG_READ(r) (((r) <= 4) ? ssp->gr[r].h : read_handlers[r]())
215 #define REG_WRITE(r,d) { \
217 if (r1 >= 4) write_handlers[r1](d); \
218 else if (r1 > 0) ssp->gr[r1].h = d; \
222 #define SSP_FLAG_L (1<<0xc)
223 #define SSP_FLAG_Z (1<<0xd)
224 #define SSP_FLAG_V (1<<0xe)
225 #define SSP_FLAG_N (1<<0xf)
227 // update ZN according to 32bit ACC.
229 rST &= ~(SSP_FLAG_Z|SSP_FLAG_N); \
230 if (!rA32) rST |= SSP_FLAG_Z; \
231 else rST |= (rA32>>16)&SSP_FLAG_N;
233 // it seems SVP code never checks for L and OV, so we leave them out.
234 // rST |= (t>>4)&SSP_FLAG_L;
236 rST &= ~(SSP_FLAG_L|SSP_FLAG_Z|SSP_FLAG_V|SSP_FLAG_N); \
237 if (!rA32) rST |= SSP_FLAG_Z; \
238 else rST |= (rA32>>16)&SSP_FLAG_N;
240 // standard cond processing.
241 // again, only Z and N is checked, as SVP doesn't seem to use any other conds.
244 case 0x00: cond = 1; break; /* always true */ \
245 case 0x50: cond = !((rST ^ (op<<5)) & SSP_FLAG_Z); break; /* Z matches f(?) bit */ \
246 case 0x70: cond = !((rST ^ (op<<7)) & SSP_FLAG_N); break; /* N matches f(?) bit */ \
247 default:elprintf(EL_SVP, "ssp FIXME: unimplemented cond @ %04x", GET_PPC_OFFS()); break; \
250 // ops with accumulator.
251 // how is low word really affected by these?
252 // nearly sure 'ld A' doesn't affect flags
256 #define OP_LDA32(x) \
259 #define OP_SUBA(x) { \
264 #define OP_SUBA32(x) { \
269 #define OP_CMPA(x) { \
270 u32 t = rA32 - ((x) << 16); \
271 rST &= ~(SSP_FLAG_L|SSP_FLAG_Z|SSP_FLAG_V|SSP_FLAG_N); \
272 if (!t) rST |= SSP_FLAG_Z; \
273 else rST |= (t>>16)&SSP_FLAG_N; \
276 #define OP_CMPA32(x) { \
277 u32 t = rA32 - (x); \
278 rST &= ~(SSP_FLAG_L|SSP_FLAG_Z|SSP_FLAG_V|SSP_FLAG_N); \
279 if (!t) rST |= SSP_FLAG_Z; \
280 else rST |= (t>>16)&SSP_FLAG_N; \
283 #define OP_ADDA(x) { \
288 #define OP_ADDA32(x) { \
297 #define OP_ANDA32(x) \
305 #define OP_ORA32(x) \
313 #define OP_EORA32(x) \
318 #define OP_CHECK32(OP) \
319 if ((op & 0x0f) == SSP_P) { /* A <- P */ \
320 read_P(); /* update P */ \
321 OP(ssp->gr[SSP_P].v); \
326 static ssp1601_t *ssp = NULL;
327 static unsigned short *PC;
330 static int running = 0;
331 static int last_iram = 0;
333 // -----------------------------------------------------
334 // register i/o handlers
337 static u32 read_unknown(void)
339 elprintf(EL_ANOMALY|EL_SVP, "ssp16: FIXME: unknown read @ %04x", GET_PPC_OFFS());
343 static void write_unknown(u32 d)
345 elprintf(EL_ANOMALY|EL_SVP, "ssp16: FIXME: unknown write @ %04x", GET_PPC_OFFS());
349 static void write_ST(u32 d)
352 elprintf(EL_SVP, "ssp16: RPL %i -> %i @ %04x", rST&7, d&7, GET_PPC_OFFS());
359 static u32 read_STACK(void)
361 //elprintf(EL_SVP, "pop %i @ %04x", rSTACK, GET_PPC_OFFS());
363 if ((short)rSTACK < 0) {
365 elprintf(EL_ANOMALY|EL_SVP, "ssp16: FIXME: stack underflow! (%i) @ %04x", rSTACK, GET_PPC_OFFS());
367 return ssp->stack[rSTACK];
370 static void write_STACK(u32 d)
374 elprintf(EL_ANOMALY|EL_SVP, "ssp16: FIXME: stack overflow! (%i) @ %04x", rSTACK, GET_PPC_OFFS());
377 ssp->stack[rSTACK++] = d;
381 static u32 read_PC(void)
386 static void write_PC(u32 d)
393 static u32 read_P(void)
395 rP.v = (u32)rX * rY * 2;
399 // -----------------------------------------------------
401 static void iram_write(int addr, u32 d, int reg, int inc)
403 if ((addr&0xfc00) != 0x8000)
404 elprintf(EL_SVP|EL_ANOMALY, "ssp FIXME: invalid IRAM addr: %04x", addr<<1);
405 elprintf(EL_SVP, "ssp IRAM w [%06x] %04x (inc %i)", (addr<<1)&0x7ff, d, inc);
406 ((unsigned short *)svp->iram_rom)[addr&0x3ff] = d;
407 ssp->pmac_write[reg] += inc<<16;
410 int lil[32] = { 0, }, lilp = 0;
412 static void debug_dump2file(const char *fname, void *mem, int len);
414 #define overwite_write(dst, d) \
416 if (d & 0xf000) { dst &= ~0xf000; dst |= d & 0xf000; } \
417 if (d & 0x0f00) { dst &= ~0x0f00; dst |= d & 0x0f00; } \
418 if (d & 0x00f0) { dst &= ~0x00f0; dst |= d & 0x00f0; } \
419 if (d & 0x000f) { dst &= ~0x000f; dst |= d & 0x000f; } \
422 static u32 pm_io(int reg, int write, u32 d)
424 if (ssp->emu_status & SSP_PMC_SET)
426 // this MUST be blind r or w
427 if ((*(PC-1) & 0xff0f) && (*(PC-1) & 0xfff0)) {
428 elprintf(EL_SVP|EL_ANOMALY, "FIXME: tried to set PM%i (%c) with non-blind i/o %08x @ %04x",
429 reg, write ? 'w' : 'r', rPMC.v, GET_PPC_OFFS());
430 ssp->emu_status &= ~SSP_PMC_SET;
433 elprintf(EL_SVP, "PM%i (%c) set to %08x @ %04x", reg, write ? 'w' : 'r', rPMC.v, GET_PPC_OFFS());
434 ssp->pmac_read[write ? reg + 6 : reg] = rPMC.v;
435 ssp->emu_status &= ~SSP_PMC_SET;
436 if ((rPMC.v & 0x7f) == 0x1c && (rPMC.v & 0x7fff0000) == 0) {
437 elprintf(EL_SVP, "IRAM copy from %06x", (ssp->RAM1[0]-1)<<1);
442 for (i = 0; i < 32; i++) {
443 if (lil[i] == last_iram) break;
446 sprintf(buff, "iramrom_%04x.bin", last_iram);
447 debug_dump2file(buff, svp->iram_rom, sizeof(svp->iram_rom));
453 last_iram = (ssp->RAM1[0]-1)<<1;
459 if (ssp->emu_status & SSP_PMC_HAVE_ADDR) {
460 elprintf(EL_SVP|EL_ANOMALY, "FIXME: PM%i (%c) with only addr set @ %04x",
461 reg, write ? 'w' : 'r', GET_PPC_OFFS());
462 ssp->emu_status &= ~SSP_PMC_HAVE_ADDR;
465 // if (ssp->pmac_read[reg] != 0)
466 if (reg == 4 || (rST & 0x60))
468 #define CADDR ((((mode<<16)&0x7f0000)|addr)<<1)
469 unsigned short *dram = (unsigned short *)svp->dram;
472 /* TODO: 0c18 mode? */
473 int mode = ssp->pmac_write[reg]&0xffff;
474 int addr = ssp->pmac_write[reg]>>16;
476 case 0x0018: elprintf(EL_SVP, "ssp PM%i DRAM w [%06x] %04x", reg, CADDR, d);
479 case 0x0418: elprintf(EL_SVP, "ssp PM%i DRAM w [%06x] %04x (overwr)", reg, CADDR, d);
480 overwite_write(dram[addr], d);
482 case 0x0818: elprintf(EL_SVP, "ssp PM%i DRAM w [%06x] %04x (inc 1)", reg, CADDR, d);
484 ssp->pmac_write[reg] += 1<<16;
486 case 0x081c: iram_write(addr, d, reg, 1); break; // checked: used by code @ 0902
487 case 0x101c: iram_write(addr, d, reg, 2); break; // checked: used by code @ 3b7c
488 case 0x4018: elprintf(EL_SVP, "ssp PM%i DRAM w [%06x] %04x (cell inc)", reg, CADDR, d);
490 ssp->pmac_write[reg] += (addr&1) ? (31<<16) : (1<<16);
492 case 0x4418: elprintf(EL_SVP, "ssp PM%i DRAM w [%06x] %04x (overwr, cell inc)", reg, CADDR, d);
493 overwite_write(dram[addr], d);
494 ssp->pmac_write[reg] += (addr&1) ? (31<<16) : (1<<16);
496 default: elprintf(EL_SVP|EL_ANOMALY, "ssp PM%i unhandled write mode %04x, [%06x] %04x @ %04x",
497 reg, mode, CADDR, d, GET_PPC_OFFS()); break;
502 int mode = ssp->pmac_read[reg]&0xffff;
503 int addr = ssp->pmac_read[reg]>>16;
504 if ((mode & 0xfff0) == 0x0800) { // ROM, inc 1, verified to be correct
505 elprintf(EL_SVP, "ssp ROM r [%06x] %04x", CADDR,
506 ((unsigned short *)Pico.rom)[addr|((mode&0xf)<<16)]);
507 ssp->pmac_read[reg] += 1<<16;
508 d = ((unsigned short *)Pico.rom)[addr|((mode&0xf)<<16)];
513 case 0x0018: elprintf(EL_SVP, "ssp DRAM r [%06x] %04x", CADDR, dram[addr]);
514 d = dram[addr]; // checked
516 case 0x0818: elprintf(EL_SVP, "ssp PM%i DRAM r [%06x] %04x (inc 1)", reg, CADDR, dram[addr]);
517 ssp->pmac_read[reg] += 1<<16;
520 case 0x3018: elprintf(EL_SVP, "ssp DRAM r [%06x] %04x (inc 32)", CADDR, dram[addr]);
521 ssp->pmac_read[reg] += 32<<16;
524 case 0xa818: elprintf(EL_SVP, "ssp DRAM r [%06x] %04x (dec 16)", CADDR, dram[addr]);
525 ssp->pmac_read[reg] -= 16<<16;
528 case 0xb818: elprintf(EL_SVP, "ssp DRAM r [%06x] %04x (dec 128?)", CADDR, dram[addr]);
529 ssp->pmac_read[reg] -= 128<<16;
532 default: elprintf(EL_SVP|EL_ANOMALY, "ssp PM%i unhandled read mode %04x, [%06x] @ %04x",
533 reg, mode, CADDR, GET_PPC_OFFS());
540 // PMC value corresponds to last PMR accessed (not sure).
541 rPMC.v = ssp->pmac_read[write ? reg + 6 : reg];
550 static u32 read_PM0(void)
552 u32 d = pm_io(0, 0, 0);
553 if (d != (u32)-1) return d;
554 elprintf(EL_SVP, "PM0 raw r %04x @ %04x", rPM0, GET_PPC_OFFS());
556 if (!(d & 2) && (GET_PPC_OFFS() == 0x800 || GET_PPC_OFFS() == 0x1851E)) {
557 ssp->emu_status |= SSP_WAIT_PM0; elprintf(EL_SVP, "det TIGHT loop: PM0");
563 static void write_PM0(u32 d)
565 u32 r = pm_io(0, 1, d);
566 if (r != (u32)-1) return;
567 elprintf(EL_SVP, "PM0 raw w %04x @ %04x", d, GET_PPC_OFFS());
572 static u32 read_PM1(void)
574 u32 d = pm_io(1, 0, 0);
575 if (d != (u32)-1) return d;
577 elprintf(EL_SVP, "PM1 raw r %04x @ %04x", rPM1, GET_PPC_OFFS());
581 static void write_PM1(u32 d)
583 u32 r = pm_io(1, 1, d);
584 if (r != (u32)-1) return;
586 elprintf(EL_SVP, "PM1 raw w %04x @ %04x", d, GET_PPC_OFFS());
591 static u32 read_PM2(void)
593 u32 d = pm_io(2, 0, 0);
594 if (d != (u32)-1) return d;
596 elprintf(EL_SVP, "PM2 raw r %04x @ %04x", rPM2, GET_PPC_OFFS());
600 static void write_PM2(u32 d)
602 u32 r = pm_io(2, 1, d);
603 if (r != (u32)-1) return;
605 elprintf(EL_SVP, "PM2 raw w %04x @ %04x", d, GET_PPC_OFFS());
610 static u32 read_XST(void)
613 u32 d = pm_io(3, 0, 0);
614 if (d != (u32)-1) return d;
616 elprintf(EL_SVP, "XST raw r %04x @ %04x", rXST, GET_PPC_OFFS());
620 static void write_XST(u32 d)
623 u32 r = pm_io(3, 1, d);
624 if (r != (u32)-1) return;
626 elprintf(EL_SVP, "XST raw w %04x @ %04x", d, GET_PPC_OFFS());
632 static u32 read_PM4(void)
634 u32 d = pm_io(4, 0, 0);
636 switch (GET_PPC_OFFS()) {
637 case 0x0854: ssp->emu_status |= SSP_WAIT_30FE08; elprintf(EL_SVP, "det TIGHT loop: [30fe08]"); break;
638 case 0x4f12: ssp->emu_status |= SSP_WAIT_30FE06; elprintf(EL_SVP, "det TIGHT loop: [30fe06]"); break;
641 if (d != (u32)-1) return d;
643 elprintf(EL_SVP, "PM4 raw r %04x @ %04x", rPM4, GET_PPC_OFFS());
647 static void write_PM4(u32 d)
649 u32 r = pm_io(4, 1, d);
650 if (r != (u32)-1) return;
652 elprintf(EL_SVP, "PM4 raw w %04x @ %04x", d, GET_PPC_OFFS());
657 static u32 read_PMC(void)
659 if (ssp->emu_status & SSP_PMC_HAVE_ADDR) {
660 if (ssp->emu_status & SSP_PMC_SET)
661 elprintf(EL_ANOMALY|EL_SVP, "prev PMC not used @ %04x", GET_PPC_OFFS());
662 ssp->emu_status |= SSP_PMC_SET;
663 ssp->emu_status &= ~SSP_PMC_HAVE_ADDR;
664 elprintf(EL_SVP, "PMC r m %04x @ %04x", rPMC.l, GET_PPC_OFFS());
667 ssp->emu_status |= SSP_PMC_HAVE_ADDR;
668 elprintf(EL_SVP, "PMC r a %04x @ %04x", rPMC.h, GET_PPC_OFFS());
673 static void write_PMC(u32 d)
675 if (ssp->emu_status & SSP_PMC_HAVE_ADDR) {
676 if (ssp->emu_status & SSP_PMC_SET)
677 elprintf(EL_ANOMALY|EL_SVP, "prev PMC not used @ %04x", GET_PPC_OFFS());
678 ssp->emu_status |= SSP_PMC_SET;
679 ssp->emu_status &= ~SSP_PMC_HAVE_ADDR;
681 elprintf(EL_SVP, "PMC w m %04x @ %04x", rPMC.l, GET_PPC_OFFS());
683 ssp->emu_status |= SSP_PMC_HAVE_ADDR;
685 elprintf(EL_SVP, "PMC w a %04x @ %04x", rPMC.h, GET_PPC_OFFS());
690 static u32 read_AL(void)
692 // TODO: figure out what's up with those blind reads..
693 if (*(PC-1) == 0x000f) {
694 elprintf(EL_SVP|EL_ANOMALY, "ssp dummy PM assign %08x, ST=%04x @ %04x", rPMC.v, rST, GET_PPC_OFFS());
695 ssp->emu_status &= ~(SSP_PMC_SET|SSP_PMC_HAVE_ADDR); // ?
697 //elprintf(EL_SVP, "ssp AL read, ST=%04x @ %04x", rST, GET_PPC_OFFS());
702 static void write_AL(u32 d)
704 //elprintf(EL_SVP, "ssp AL write %04x, ST=%04x @ %04x", d, rST, GET_PPC_OFFS());
709 typedef u32 (*read_func_t)(void);
710 typedef void (*write_func_t)(u32 d);
712 static read_func_t read_handlers[16] =
714 read_unknown, read_unknown, read_unknown, read_unknown, // -, X, Y, A
715 read_unknown, // 4 ST
724 read_unknown, // 13 gr13
729 static write_func_t write_handlers[16] =
731 write_unknown, write_unknown, write_unknown, write_unknown, // -, X, Y, A
732 // write_unknown, // 4 ST
733 write_ST, // 4 ST (debug hook)
736 write_unknown, // 7 P
742 write_unknown, // 13 gr13
747 // -----------------------------------------------------
748 // pointer register handlers
751 #define ptr1_read(op) ptr1_read_(op&3,(op>>6)&4,(op<<1)&0x18)
753 static u32 ptr1_read_(int ri, int isj2, int modi3)
755 //int t = (op&3) | ((op>>6)&4) | ((op<<1)&0x18);
756 u32 mask, add = 0, t = ri | isj2 | modi3;
757 unsigned char *rp = NULL;
763 case 0x02: return ssp->RAM0[ssp->r0[t&3]];
764 case 0x03: return ssp->RAM0[0];
767 case 0x06: return ssp->RAM1[ssp->r1[t&3]];
768 case 0x07: return ssp->RAM1[0];
772 case 0x0a: return ssp->RAM0[ssp->r0[t&3]++];
773 case 0x0b: return ssp->RAM0[1];
776 case 0x0e: return ssp->RAM1[ssp->r1[t&3]++];
777 case 0x0f: return ssp->RAM1[1];
781 case 0x12: rp = &ssp->r0[t&3]; t = ssp->RAM0[*rp];
782 if (!(rST&7)) { (*rp)--; return t; }
783 add = -1; goto modulo;
784 case 0x13: return ssp->RAM0[2];
787 case 0x16: rp = &ssp->r1[t&3]; t = ssp->RAM1[*rp];
788 if (!(rST&7)) { (*rp)--; return t; }
789 add = -1; goto modulo;
790 case 0x17: return ssp->RAM1[2];
794 case 0x1a: rp = &ssp->r0[t&3]; t = ssp->RAM0[*rp];
795 if (!(rST&7)) { (*rp)++; return t; }
796 add = 1; goto modulo;
797 case 0x1b: return ssp->RAM0[3];
800 case 0x1e: rp = &ssp->r1[t&3]; t = ssp->RAM1[*rp];
801 if (!(rST&7)) { (*rp)++; return t; }
802 add = 1; goto modulo;
803 case 0x1f: return ssp->RAM1[3];
809 mask = (1 << (rST&7)) - 1;
810 *rp = (*rp & ~mask) | ((*rp + add) & mask);
814 static void ptr1_write(int op, u32 d)
816 int t = (op&3) | ((op>>6)&4) | ((op<<1)&0x18);
822 case 0x02: ssp->RAM0[ssp->r0[t&3]] = d; return;
823 case 0x03: ssp->RAM0[0] = d; return;
826 case 0x06: ssp->RAM1[ssp->r1[t&3]] = d; return;
827 case 0x07: ssp->RAM1[0] = d; return;
835 case 0x1a: ssp->RAM0[ssp->r0[t&3]++] = d; return;
836 case 0x0b: ssp->RAM0[1] = d; return;
842 case 0x1e: ssp->RAM1[ssp->r1[t&3]++] = d; return;
843 case 0x0f: ssp->RAM1[1] = d; return;
847 case 0x12: ssp->RAM0[ssp->r0[t&3]--] = d; return;
848 case 0x13: ssp->RAM0[2] = d; return;
851 case 0x16: ssp->RAM1[ssp->r1[t&3]--] = d; return;
852 case 0x17: ssp->RAM1[2] = d; return;
854 case 0x1b: ssp->RAM0[3] = d; return;
855 case 0x1f: ssp->RAM1[3] = d; return;
859 static u32 ptr2_read(int op)
861 int mv = 0, t = (op&3) | ((op>>6)&4) | ((op<<1)&0x18);
867 case 0x02: mv = ssp->RAM0[ssp->r0[t&3]]++; break;
868 case 0x03: mv = ssp->RAM0[0]++; break;
871 case 0x06: mv = ssp->RAM1[ssp->r1[t&3]]++; break;
872 case 0x07: mv = ssp->RAM1[0]++; break;
874 case 0x0b: mv = ssp->RAM0[1]++; break;
875 case 0x0f: mv = ssp->RAM1[1]++; break;
877 case 0x13: mv = ssp->RAM0[2]++; break;
878 case 0x17: mv = ssp->RAM1[2]++; break;
880 case 0x1b: mv = ssp->RAM0[3]++; break;
881 case 0x1f: mv = ssp->RAM1[3]++; break;
882 default: elprintf(EL_SVP|EL_ANOMALY, "ssp FIXME: invalid mod in ((rX))? @ %04x", GET_PPC_OFFS());
886 return ((unsigned short *)svp->iram_rom)[mv];
890 // -----------------------------------------------------
892 void ssp1601_reset(ssp1601_t *l_ssp)
896 ssp->gr[SSP_GR0].v = 0xffff0000;
898 rSTACK = 0; // ? using ascending stack
903 static void debug_dump(void)
905 printf("GR0: %04x X: %04x Y: %04x A: %08x\n", ssp->gr[SSP_GR0].h, rX, rY, ssp->gr[SSP_A].v);
906 printf("PC: %04x (%04x) P: %08x\n", GET_PC(), GET_PC() << 1, ssp->gr[SSP_P].v);
907 printf("PM0: %04x PM1: %04x PM2: %04x\n", rPM0, rPM1, rPM2);
908 printf("XST: %04x PM4: %04x PMC: %08x\n", rXST, rPM4, ssp->gr[SSP_PMC].v);
909 printf(" ST: %04x %c%c%c%c, GP0_0 %i, GP0_1 %i\n", rST, rST&SSP_FLAG_N?'N':'n', rST&SSP_FLAG_V?'V':'v',
910 rST&SSP_FLAG_Z?'Z':'z', rST&SSP_FLAG_L?'L':'l', (rST>>5)&1, (rST>>6)&1);
911 printf("STACK: %i %04x %04x %04x %04x %04x %04x\n", rSTACK, ssp->stack[0], ssp->stack[1],
912 ssp->stack[2], ssp->stack[3], ssp->stack[4], ssp->stack[5]);
913 printf("r0-r2: %02x %02x %02x r4-r6: %02x %02x %02x\n", rIJ[0], rIJ[1], rIJ[2], rIJ[4], rIJ[5], rIJ[6]);
914 elprintf(EL_SVP, "cycles: %i, emu_status: %x", g_cycles, ssp->emu_status);
917 static void debug_dump_mem(void)
921 for (h = 0; h < 32; h++)
923 if (h == 16) printf("RAM1\n");
924 printf("%03x:", h*16);
925 for (i = 0; i < 16; i++)
926 printf(" %04x", ssp->RAM[h*16+i]);
931 static void debug_dump2file(const char *fname, void *mem, int len)
933 FILE *f = fopen(fname, "wb");
934 unsigned short *p = mem;
937 for (i = 0; i < len/2; i++) p[i] = (p[i]<<8) | (p[i]>>8);
938 fwrite(mem, 1, len, f);
940 for (i = 0; i < len/2; i++) p[i] = (p[i]<<8) | (p[i]>>8);
941 printf("dumped to %s\n", fname);
944 printf("dump failed\n");
947 static int bpts[10] = { 0, };
949 static void debug(unsigned int pc, unsigned int op)
951 static char buffo[64] = {0,};
952 char buff[64] = {0,};
956 for (i = 0; i < 10; i++)
957 if (pc != 0 && bpts[i] == pc) {
958 printf("breakpoint %i\n", i);
965 printf("%04x (%02x) @ %04x\n", op, op >> 9, pc<<1);
971 fgets(buff, sizeof(buff), stdin);
972 if (buff[0] == '\n') strcpy(buff, buffo);
973 else strcpy(buffo, buff);
978 case 'r': running = 1; return;
981 case 'x': debug_dump(); break;
982 case 'm': debug_dump_mem(); break;
984 char *baddr = buff + 2;
986 if (buff[3] == ' ') { i = buff[2] - '0'; baddr = buff + 4; }
987 bpts[i] = strtol(baddr, NULL, 16) >> 1;
988 printf("breakpoint %i set @ %04x\n", i, bpts[i]<<1);
992 sprintf(buff, "iramrom_%04x.bin", last_iram);
993 debug_dump2file(buff, svp->iram_rom, sizeof(svp->iram_rom));
994 debug_dump2file("dram.bin", svp->dram, sizeof(svp->dram));
996 default: printf("unknown command\n"); break;
1001 void ssp1601_run(int cycles)
1006 //if (Pico.m.frame_count == 480) running = 0;
1008 while (g_cycles > 0 && !(ssp->emu_status & SSP_WAIT_MASK))
1014 debug(GET_PC()-1, op);
1019 if (op == 0) break; // nop
1020 if (op == ((SSP_A<<4)|SSP_P)) { // A <- P
1021 // not sure. MAME claims that only hi word is transfered.
1022 read_P(); // update P
1023 rA32 = ssp->gr[SSP_P].v;
1027 tmpv = REG_READ(op & 0x0f);
1028 REG_WRITE((op & 0xf0) >> 4, tmpv);
1033 case 0x01: tmpv = ptr1_read(op); REG_WRITE((op & 0xf0) >> 4, tmpv); break;
1036 case 0x02: tmpv = REG_READ((op & 0xf0) >> 4); ptr1_write(op, tmpv); break;
1039 case 0x04: tmpv = *PC++; REG_WRITE((op & 0xf0) >> 4, tmpv); break;
1042 case 0x05: tmpv = ptr2_read(op); REG_WRITE((op & 0xf0) >> 4, tmpv); break;
1045 case 0x06: tmpv = *PC++; ptr1_write(op, tmpv); break;
1048 case 0x07: ssp->RAM[op & 0x1ff] = rA; break;
1051 case 0x09: tmpv = rIJ[(op&3)|((op>>6)&4)]; REG_WRITE((op & 0xf0) >> 4, tmpv); break;
1054 case 0x0a: rIJ[(op&3)|((op>>6)&4)] = REG_READ((op & 0xf0) >> 4); break;
1060 case 0x0f: rIJ[(op>>8)&7] = op; break;
1066 if (cond) { int new_PC = *PC++; write_STACK(GET_PC()); write_PC(new_PC); }
1072 case 0x25: tmpv = ((unsigned short *)svp->iram_rom)[rA]; REG_WRITE((op & 0xf0) >> 4, tmpv); break;
1078 if (cond) { int new_PC = *PC++; write_PC(new_PC); }
1089 case 2: rA32 = (signed int)rA32 >> 1; break; // shr (arithmetic)
1090 case 3: rA32 <<= 1; break; // shl
1091 case 6: rA32 = -(signed int)rA32; break; // neg
1092 case 7: if ((int)rA32 < 0) rA32 = -(signed int)rA32; break; // abs
1093 default: elprintf(EL_SVP, "ssp16: FIXME unhandled mod %i @ %04x", op&7, GET_PPC_OFFS());
1103 // very uncertain about this one. What about b?
1104 if (!(op&0x100)) elprintf(EL_SVP|EL_ANOMALY, "ssp16: FIXME: no b bit @ %04x", GET_PPC_OFFS());
1105 read_P(); // update P
1106 rA32 -= ssp->gr[SSP_P].v; // maybe only upper word?
1107 // UPD_ACC_ZN // I've seen code checking flags after this
1108 rX = ptr1_read_(op&3, 0, (op<<1)&0x18); // ri (maybe rj?)
1109 rY = ptr1_read_((op>>4)&3, 4, (op>>3)&0x18); // rj
1112 // mpya (rj), (ri), b
1114 // dunno if this is correct. What about b?
1115 if (!(op&0x100)) elprintf(EL_SVP|EL_ANOMALY, "ssp16: FIXME: no b bit @ %04x", GET_PPC_OFFS());
1116 read_P(); // update P
1117 rA32 += ssp->gr[SSP_P].v; // maybe only upper word?
1119 rX = ptr1_read_(op&3, 0, (op<<1)&0x18); // ri (maybe rj?)
1120 rY = ptr1_read_((op>>4)&3, 4, (op>>3)&0x18); // rj
1123 // mld (rj), (ri), b
1125 // dunno if this is correct. What about b?
1126 if (!(op&0x100)) elprintf(EL_SVP|EL_ANOMALY, "ssp16: FIXME: no b bit @ %04x", GET_PPC_OFFS());
1127 rA32 = 0; // maybe only upper word?
1129 rX = ptr1_read_(op&3, 0, (op<<1)&0x18); // ri (maybe rj?)
1130 rY = ptr1_read_((op>>4)&3, 4, (op>>3)&0x18); // rj
1134 case 0x10: OP_CHECK32(OP_SUBA32); tmpv = REG_READ(op & 0x0f); OP_SUBA(tmpv); break;
1135 case 0x30: OP_CHECK32(OP_CMPA32); tmpv = REG_READ(op & 0x0f); OP_CMPA(tmpv); break;
1136 case 0x40: OP_CHECK32(OP_ADDA32); tmpv = REG_READ(op & 0x0f); OP_ADDA(tmpv); break;
1137 case 0x50: OP_CHECK32(OP_ANDA32); tmpv = REG_READ(op & 0x0f); OP_ANDA(tmpv); break;
1138 case 0x60: OP_CHECK32(OP_ORA32 ); tmpv = REG_READ(op & 0x0f); OP_ORA (tmpv); break;
1139 case 0x70: OP_CHECK32(OP_EORA32); tmpv = REG_READ(op & 0x0f); OP_EORA(tmpv); break;
1142 case 0x11: tmpv = ptr1_read(op); OP_SUBA(tmpv); break;
1143 case 0x31: tmpv = ptr1_read(op); OP_CMPA(tmpv); break;
1144 case 0x41: tmpv = ptr1_read(op); OP_ADDA(tmpv); break;
1145 case 0x51: tmpv = ptr1_read(op); OP_ANDA(tmpv); break;
1146 case 0x61: tmpv = ptr1_read(op); OP_ORA (tmpv); break;
1147 case 0x71: tmpv = ptr1_read(op); OP_EORA(tmpv); break;
1150 case 0x03: tmpv = ssp->RAM[op & 0x1ff]; OP_LDA (tmpv); break;
1151 case 0x13: tmpv = ssp->RAM[op & 0x1ff]; OP_SUBA(tmpv); break;
1152 case 0x33: tmpv = ssp->RAM[op & 0x1ff]; OP_CMPA(tmpv); break;
1153 case 0x43: tmpv = ssp->RAM[op & 0x1ff]; OP_ADDA(tmpv); break;
1154 case 0x53: tmpv = ssp->RAM[op & 0x1ff]; OP_ANDA(tmpv); break;
1155 case 0x63: tmpv = ssp->RAM[op & 0x1ff]; OP_ORA (tmpv); break;
1156 case 0x73: tmpv = ssp->RAM[op & 0x1ff]; OP_EORA(tmpv); break;
1159 case 0x14: tmpv = *PC++; OP_SUBA(tmpv); break;
1160 case 0x34: tmpv = *PC++; OP_CMPA(tmpv); break;
1161 case 0x44: tmpv = *PC++; OP_ADDA(tmpv); break;
1162 case 0x54: tmpv = *PC++; OP_ANDA(tmpv); break;
1163 case 0x64: tmpv = *PC++; OP_ORA (tmpv); break;
1164 case 0x74: tmpv = *PC++; OP_EORA(tmpv); break;
1167 case 0x15: tmpv = ptr2_read(op); OP_SUBA(tmpv); break;
1168 case 0x35: tmpv = ptr2_read(op); OP_CMPA(tmpv); break;
1169 case 0x45: tmpv = ptr2_read(op); OP_ADDA(tmpv); break;
1170 case 0x55: tmpv = ptr2_read(op); OP_ANDA(tmpv); break;
1171 case 0x65: tmpv = ptr2_read(op); OP_ORA (tmpv); break;
1172 case 0x75: tmpv = ptr2_read(op); OP_EORA(tmpv); break;
1175 case 0x19: tmpv = rIJ[IJind]; OP_SUBA(tmpv); break;
1176 case 0x39: tmpv = rIJ[IJind]; OP_CMPA(tmpv); break;
1177 case 0x49: tmpv = rIJ[IJind]; OP_ADDA(tmpv); break;
1178 case 0x59: tmpv = rIJ[IJind]; OP_ANDA(tmpv); break;
1179 case 0x69: tmpv = rIJ[IJind]; OP_ORA (tmpv); break;
1180 case 0x79: tmpv = rIJ[IJind]; OP_EORA(tmpv); break;
1183 case 0x1c: OP_SUBA(op & 0xff); if (op&0x100) elprintf(EL_SVP, "FIXME: simm with upper bit set"); break;
1184 case 0x3c: OP_CMPA(op & 0xff); if (op&0x100) elprintf(EL_SVP, "FIXME: simm with upper bit set"); break;
1185 case 0x4c: OP_ADDA(op & 0xff); if (op&0x100) elprintf(EL_SVP, "FIXME: simm with upper bit set"); break;
1186 // MAME code only does LSB of top word, but this looks wrong to me.
1187 case 0x5c: OP_ANDA(op & 0xff); if (op&0x100) elprintf(EL_SVP, "FIXME: simm with upper bit set"); break;
1188 case 0x6c: OP_ORA (op & 0xff); if (op&0x100) elprintf(EL_SVP, "FIXME: simm with upper bit set"); break;
1189 case 0x7c: OP_EORA(op & 0xff); if (op&0x100) elprintf(EL_SVP, "FIXME: simm with upper bit set"); break;
1192 elprintf(EL_ANOMALY|EL_SVP, "ssp16: FIXME unhandled op %04x @ %04x", op, GET_PPC_OFFS());
1198 read_P(); // update P
1201 if (ssp->gr[SSP_GR0].v != 0xffff0000)
1202 elprintf(EL_ANOMALY|EL_SVP, "ssp16: FIXME: REG 0 corruption! %08x", ssp->gr[SSP_GR0].v);