2 #include "../../PicoInt.h"
5 #define u32 unsigned int
7 static u32 *tcache_ptr = NULL;
9 static int nblocks = 0;
10 static int n_in_ops = 0;
12 extern ssp1601_t *ssp;
14 #define rPC ssp->gr[SSP_PC].h
15 #define rPMC ssp->gr[SSP_PMC]
17 #define SSP_FLAG_Z (1<<0xd)
18 #define SSP_FLAG_N (1<<0xf)
21 #define DUMP_BLOCK 0x0c9a
22 u32 *ssp_block_table[0x5090/2];
23 u32 *ssp_block_table_iram[15][0x800/2];
24 u32 tcache[SSP_TCACHE_SIZE/4];
25 void ssp_drc_next(void){}
26 void ssp_drc_next_patch(void){}
27 void ssp_drc_end(void){}
32 // -----------------------------------------------------
34 static int get_inc(int mode)
36 int inc = (mode >> 11) & 7;
39 inc = 1 << inc; // 0 1 2 4 8 16 32 128
40 if (mode & 0x8000) inc = -inc; // decrement mode
45 u32 ssp_pm_read(int reg)
49 if (ssp->emu_status & SSP_PMC_SET)
51 ssp->pmac_read[reg] = rPMC.v;
52 ssp->emu_status &= ~SSP_PMC_SET;
57 ssp->emu_status &= ~SSP_PMC_HAVE_ADDR;
59 mode = ssp->pmac_read[reg]>>16;
60 if ((mode & 0xfff0) == 0x0800) // ROM
62 d = ((unsigned short *)Pico.rom)[ssp->pmac_read[reg]&0xfffff];
63 ssp->pmac_read[reg] += 1;
65 else if ((mode & 0x47ff) == 0x0018) // DRAM
67 unsigned short *dram = (unsigned short *)svp->dram;
68 int inc = get_inc(mode);
69 d = dram[ssp->pmac_read[reg]&0xffff];
70 ssp->pmac_read[reg] += inc;
73 // PMC value corresponds to last PMR accessed
74 rPMC.v = ssp->pmac_read[reg];
79 #define overwrite_write(dst, d) \
81 if (d & 0xf000) { dst &= ~0xf000; dst |= d & 0xf000; } \
82 if (d & 0x0f00) { dst &= ~0x0f00; dst |= d & 0x0f00; } \
83 if (d & 0x00f0) { dst &= ~0x00f0; dst |= d & 0x00f0; } \
84 if (d & 0x000f) { dst &= ~0x000f; dst |= d & 0x000f; } \
87 void ssp_pm_write(u32 d, int reg)
92 if (ssp->emu_status & SSP_PMC_SET)
94 ssp->pmac_write[reg] = rPMC.v;
95 ssp->emu_status &= ~SSP_PMC_SET;
100 ssp->emu_status &= ~SSP_PMC_HAVE_ADDR;
102 dram = (unsigned short *)svp->dram;
103 mode = ssp->pmac_write[reg]>>16;
104 addr = ssp->pmac_write[reg]&0xffff;
105 if ((mode & 0x43ff) == 0x0018) // DRAM
107 int inc = get_inc(mode);
109 overwrite_write(dram[addr], d);
110 } else dram[addr] = d;
111 ssp->pmac_write[reg] += inc;
113 else if ((mode & 0xfbff) == 0x4018) // DRAM, cell inc
116 overwrite_write(dram[addr], d);
117 } else dram[addr] = d;
118 ssp->pmac_write[reg] += (addr&1) ? 0x1f : 1;
120 else if ((mode & 0x47ff) == 0x001c) // IRAM
122 int inc = get_inc(mode);
123 ((unsigned short *)svp->iram_rom)[addr&0x3ff] = d;
124 ssp->pmac_write[reg] += inc;
125 ssp->drc.iram_dirty = 1;
128 rPMC.v = ssp->pmac_write[reg];
132 // -----------------------------------------------------
135 static unsigned char iram_context_map[] =
137 0, 0, 0, 0, 1, 0, 0, 0, // 04
138 0, 0, 0, 0, 0, 0, 2, 0, // 0e
139 0, 0, 0, 0, 0, 3, 0, 4, // 15 17
140 5, 0, 0, 6, 0, 7, 0, 0, // 18 1b 1d
141 8, 9, 0, 0, 0,10, 0, 0, // 20 21 25
142 0, 0, 0, 0, 0, 0, 0, 0,
143 0, 0,11, 0, 0,12, 0, 0, // 32 35
144 13,14, 0, 0, 0, 0, 0, 0 // 38 39
147 int ssp_get_iram_context(void)
149 unsigned char *ir = (unsigned char *)svp->iram_rom;
150 int val1, val = ir[0x083^1] + ir[0x4FA^1] + ir[0x5F7^1] + ir[0x47B^1];
151 val1 = iram_context_map[(val>>1)&0x3f];
154 printf("val: %02x PC=%04x\n", (val>>1)&0x3f, rPC);
155 //debug_dump2file(name, svp->iram_rom, 0x800);
158 // elprintf(EL_ANOMALY, "iram_context: %02i", val1);
162 // -----------------------------------------------------
164 /* regs with known values */
169 unsigned int pmac_read[5];
170 unsigned int pmac_write[5];
172 unsigned int emu_status;
175 #define KRREG_X (1 << SSP_X)
176 #define KRREG_Y (1 << SSP_Y)
177 #define KRREG_A (1 << SSP_A) /* AH only */
178 #define KRREG_ST (1 << SSP_ST)
179 #define KRREG_STACK (1 << SSP_STACK)
180 #define KRREG_PC (1 << SSP_PC)
181 #define KRREG_P (1 << SSP_P)
182 #define KRREG_PR0 (1 << 8)
183 #define KRREG_PR4 (1 << 12)
184 #define KRREG_AL (1 << 16)
185 #define KRREG_PMCM (1 << 18) /* only mode word of PMC */
186 #define KRREG_PMC (1 << 19)
187 #define KRREG_PM0R (1 << 20)
188 #define KRREG_PM1R (1 << 21)
189 #define KRREG_PM2R (1 << 22)
190 #define KRREG_PM3R (1 << 23)
191 #define KRREG_PM4R (1 << 24)
192 #define KRREG_PM0W (1 << 25)
193 #define KRREG_PM1W (1 << 26)
194 #define KRREG_PM2W (1 << 27)
195 #define KRREG_PM3W (1 << 28)
196 #define KRREG_PM4W (1 << 29)
198 /* bitfield of known register values */
199 static u32 known_regb = 0;
201 /* known vals, which need to be flushed
202 * (only ST, P, r0-r7, PMCx, PMxR, PMxW)
203 * ST means flags are being held in ARM PSR
204 * P means that it needs to be recalculated
206 static u32 dirty_regb = 0;
208 /* known values of host regs.
210 * 000000-00ffff - 16bit value
211 * 100000-10ffff - base reg (r7) + 16bit val
212 * 0r0000 - means reg (low) eq gr[r].h, r != AL
214 static int hostreg_r[4];
216 static void hostreg_clear(void)
219 for (i = 0; i < 4; i++)
223 static void hostreg_sspreg_changed(int sspreg)
226 for (i = 0; i < 4; i++)
227 if (hostreg_r[i] == (sspreg<<16)) hostreg_r[i] = -1;
231 #define PROGRAM(x) ((unsigned short *)svp->iram_rom)[x]
232 #define PROGRAM_P(x) ((unsigned short *)svp->iram_rom + (x))
234 void tr_unhandled(void)
236 FILE *f = fopen("tcache.bin", "wb");
237 fwrite(tcache, 1, (tcache_ptr - tcache)*4, f);
239 printf("unhandled @ %04x\n", known_regs.gr[SSP_PC].h<<1);
243 /* update P, if needed. Trashes r0 */
244 static void tr_flush_dirty_P(void)
247 if (!(dirty_regb & KRREG_P)) return;
248 EOP_MOV_REG_ASR(10, 4, 16); // mov r10, r4, asr #16
249 EOP_MOV_REG_LSL( 0, 4, 16); // mov r0, r4, lsl #16
250 EOP_MOV_REG_ASR( 0, 0, 15); // mov r0, r0, asr #15
251 EOP_MUL(10, 0, 10); // mul r10, r0, r10
252 dirty_regb &= ~KRREG_P;
256 /* write dirty pr to host reg. Nothing is trashed */
257 static void tr_flush_dirty_pr(int r)
261 if (!(dirty_regb & (1 << (r+8)))) return;
264 case 0: ror = 0; break;
265 case 1: ror = 24/2; break;
266 case 2: ror = 16/2; break;
268 reg = (r < 4) ? 8 : 9;
269 EOP_BIC_IMM(reg,reg,ror,0xff);
270 if (known_regs.r[r] != 0)
271 EOP_ORR_IMM(reg,reg,ror,known_regs.r[r]);
272 dirty_regb &= ~(1 << (r+8));
275 /* write all dirty pr0-pr7 to host regs. Nothing is trashed */
276 static void tr_flush_dirty_prs(void)
279 int dirty = dirty_regb >> 8;
280 if ((dirty&7) == 7) {
281 emit_mov_const(A_COND_AL, 8, known_regs.r[0]|(known_regs.r[1]<<8)|(known_regs.r[2]<<16));
284 if ((dirty&0x70) == 0x70) {
285 emit_mov_const(A_COND_AL, 9, known_regs.r[4]|(known_regs.r[5]<<8)|(known_regs.r[6]<<16));
289 for (i = 0; dirty && i < 8; i++, dirty >>= 1)
291 if (!(dirty&1)) continue;
293 case 0: ror = 0; break;
294 case 1: ror = 24/2; break;
295 case 2: ror = 16/2; break;
297 reg = (i < 4) ? 8 : 9;
298 EOP_BIC_IMM(reg,reg,ror,0xff);
299 if (known_regs.r[i] != 0)
300 EOP_ORR_IMM(reg,reg,ror,known_regs.r[i]);
302 dirty_regb &= ~0xff00;
305 /* write dirty pr and "forget" it. Nothing is trashed. */
306 static void tr_release_pr(int r)
308 tr_flush_dirty_pr(r);
309 known_regb &= ~(1 << (r+8));
312 /* fush ARM PSR to r6. Trashes r1 */
313 static void tr_flush_dirty_ST(void)
315 if (!(dirty_regb & KRREG_ST)) return;
316 EOP_BIC_IMM(6,6,0,0x0f);
318 EOP_ORR_REG_LSR(6,6,1,28);
319 dirty_regb &= ~KRREG_ST;
323 /* inverse of above. Trashes r1 */
324 static void tr_make_dirty_ST(void)
326 if (dirty_regb & KRREG_ST) return;
327 if (known_regb & KRREG_ST) {
329 if (known_regs.gr[SSP_ST].h & SSP_FLAG_N) flags |= 8;
330 if (known_regs.gr[SSP_ST].h & SSP_FLAG_Z) flags |= 4;
331 EOP_MSR_IMM(4/2, flags);
333 EOP_MOV_REG_LSL(1, 6, 28);
337 dirty_regb |= KRREG_ST;
340 /* load 16bit val into host reg r0-r3. Nothing is trashed */
341 static void tr_mov16(int r, int val)
343 if (hostreg_r[r] != val) {
344 emit_mov_const(A_COND_AL, r, val);
349 static void tr_mov16_cond(int cond, int r, int val)
351 emit_mov_const(cond, r, val);
356 static void tr_flush_dirty_pmcrs(void)
358 u32 i, val = (u32)-1;
359 if (!(dirty_regb & 0x3ff80000)) return;
361 if (dirty_regb & KRREG_PMC) {
362 val = known_regs.pmc.v;
363 emit_mov_const(A_COND_AL, 1, val);
364 EOP_STR_IMM(1,7,0x400+SSP_PMC*4);
366 if (known_regs.emu_status & (SSP_PMC_SET|SSP_PMC_HAVE_ADDR)) {
367 printf("!! SSP_PMC_SET|SSP_PMC_HAVE_ADDR set on flush\n");
371 for (i = 0; i < 5; i++)
373 if (dirty_regb & (1 << (20+i))) {
374 if (val != known_regs.pmac_read[i]) {
375 val = known_regs.pmac_read[i];
376 emit_mov_const(A_COND_AL, 1, val);
378 EOP_STR_IMM(1,7,0x454+i*4); // pmac_read
380 if (dirty_regb & (1 << (25+i))) {
381 if (val != known_regs.pmac_write[i]) {
382 val = known_regs.pmac_write[i];
383 emit_mov_const(A_COND_AL, 1, val);
385 EOP_STR_IMM(1,7,0x46c+i*4); // pmac_write
388 dirty_regb &= ~0x3ff80000;
392 /* read bank word to r0 (upper bits zero). Thrashes r1. */
393 static void tr_bank_read(int addr) /* word addr 0-0x1ff */
397 if (hostreg_r[1] != (0x100000|((addr&0x180)<<1))) {
398 EOP_ADD_IMM(1,7,30/2,(addr&0x180)>>1); // add r1, r7, ((op&0x180)<<1)
399 hostreg_r[1] = 0x100000|((addr&0x180)<<1);
403 EOP_LDRH_IMM(0,breg,(addr&0x7f)<<1); // ldrh r0, [r1, (op&0x7f)<<1]
407 /* write r0 to bank. Trashes r1. */
408 static void tr_bank_write(int addr)
412 if (hostreg_r[1] != (0x100000|((addr&0x180)<<1))) {
413 EOP_ADD_IMM(1,7,30/2,(addr&0x180)>>1); // add r1, r7, ((op&0x180)<<1)
414 hostreg_r[1] = 0x100000|((addr&0x180)<<1);
418 EOP_STRH_IMM(0,breg,(addr&0x7f)<<1); // strh r0, [r1, (op&0x7f)<<1]
421 /* handle RAM bank pointer modifiers. if need_modulo, trash r1-r3, else nothing */
422 static void tr_ptrr_mod(int r, int mod, int need_modulo, int count)
424 int modulo_shift = -1; /* unknown */
426 if (mod == 0) return;
428 if (!need_modulo || mod == 1) // +!
430 else if (need_modulo && (known_regb & KRREG_ST)) {
431 modulo_shift = known_regs.gr[SSP_ST].h & 7;
432 if (modulo_shift == 0) modulo_shift = 8;
435 if (modulo_shift == -1)
437 int reg = (r < 4) ? 8 : 9;
439 if (dirty_regb & KRREG_ST) {
440 // avoid flushing ARM flags
441 EOP_AND_IMM(1, 6, 0, 0x70);
442 EOP_SUB_IMM(1, 1, 0, 0x10);
443 EOP_AND_IMM(1, 1, 0, 0x70);
444 EOP_ADD_IMM(1, 1, 0, 0x10);
446 EOP_C_DOP_IMM(A_COND_AL,A_OP_AND,1,6,1,0,0x70); // ands r1, r6, #0x70
447 EOP_C_DOP_IMM(A_COND_EQ,A_OP_MOV,0,0,1,0,0x80); // moveq r1, #0x80
449 EOP_MOV_REG_LSR(1, 1, 4); // mov r1, r1, lsr #4
450 EOP_RSB_IMM(2, 1, 0, 8); // rsb r1, r1, #8
451 EOP_MOV_IMM(3, 8/2, count); // mov r3, #0x01000000
453 EOP_ADD_IMM(1, 1, 0, (r&3)*8); // add r1, r1, #(r&3)*8
454 EOP_MOV_REG2_ROR(reg,reg,1); // mov reg, reg, ror r1
456 EOP_SUB_REG2_LSL(reg,reg,3,2); // sub reg, reg, #0x01000000 << r2
457 else EOP_ADD_REG2_LSL(reg,reg,3,2);
458 EOP_RSB_IMM(1, 1, 0, 32); // rsb r1, r1, #32
459 EOP_MOV_REG2_ROR(reg,reg,1); // mov reg, reg, ror r1
460 hostreg_r[1] = hostreg_r[2] = hostreg_r[3] = -1;
462 else if (known_regb & (1 << (r + 8)))
464 int modulo = (1 << modulo_shift) - 1;
466 known_regs.r[r] = (known_regs.r[r] & ~modulo) | ((known_regs.r[r] - count) & modulo);
467 else known_regs.r[r] = (known_regs.r[r] & ~modulo) | ((known_regs.r[r] + count) & modulo);
471 int reg = (r < 4) ? 8 : 9;
472 int ror = ((r&3) + 1)*8 - (8 - modulo_shift);
473 EOP_MOV_REG_ROR(reg,reg,ror);
474 // {add|sub} reg, reg, #1<<shift
475 EOP_C_DOP_IMM(A_COND_AL,(mod==2)?A_OP_SUB:A_OP_ADD,0,reg,reg, 8/2, count << (8 - modulo_shift));
476 EOP_MOV_REG_ROR(reg,reg,32-ror);
480 /* handle writes r0 to (rX). Trashes r1.
481 * fortunately we can ignore modulo increment modes for writes. */
482 static void tr_rX_write(int op)
486 int mod = (op>>2) & 3; // direct addressing
487 tr_bank_write((op & 0x100) + mod);
491 int r = (op&3) | ((op>>6)&4);
492 if (known_regb & (1 << (r + 8))) {
493 tr_bank_write((op&0x100) | known_regs.r[r]);
495 int reg = (r < 4) ? 8 : 9;
496 int ror = ((4 - (r&3))*8) & 0x1f;
497 EOP_AND_IMM(1,reg,ror/2,0xff); // and r1, r{7,8}, <mask>
499 EOP_ORR_IMM(1,1,((ror-8)&0x1f)/2,1); // orr r1, r1, 1<<shift
500 if (r&3) EOP_ADD_REG_LSR(1,7,1, (r&3)*8-1); // add r1, r7, r1, lsr #lsr
501 else EOP_ADD_REG_LSL(1,7,1,1);
502 EOP_STRH_SIMPLE(0,1); // strh r0, [r1]
505 tr_ptrr_mod(r, (op>>2) & 3, 0, 1);
509 /* read (rX) to r0. Trashes r1-r3. */
510 static void tr_rX_read(int r, int mod)
514 tr_bank_read(((r << 6) & 0x100) + mod); // direct addressing
518 if (known_regb & (1 << (r + 8))) {
519 tr_bank_read(((r << 6) & 0x100) | known_regs.r[r]);
521 int reg = (r < 4) ? 8 : 9;
522 int ror = ((4 - (r&3))*8) & 0x1f;
523 EOP_AND_IMM(1,reg,ror/2,0xff); // and r1, r{7,8}, <mask>
525 EOP_ORR_IMM(1,1,((ror-8)&0x1f)/2,1); // orr r1, r1, 1<<shift
526 if (r&3) EOP_ADD_REG_LSR(1,7,1, (r&3)*8-1); // add r1, r7, r1, lsr #lsr
527 else EOP_ADD_REG_LSL(1,7,1,1);
528 EOP_LDRH_SIMPLE(0,1); // ldrh r0, [r1]
529 hostreg_r[0] = hostreg_r[1] = -1;
531 tr_ptrr_mod(r, mod, 1, 1);
535 /* read ((rX)) to r0. Trashes r1,r2. */
536 static void tr_rX_read2(int op)
538 int r = (op&3) | ((op>>6)&4); // src
541 tr_bank_read((op&0x100) | ((op>>2)&3));
542 } else if (known_regb & (1 << (r+8))) {
543 tr_bank_read((op&0x100) | known_regs.r[r]);
545 int reg = (r < 4) ? 8 : 9;
546 int ror = ((4 - (r&3))*8) & 0x1f;
547 EOP_AND_IMM(1,reg,ror/2,0xff); // and r1, r{7,8}, <mask>
549 EOP_ORR_IMM(1,1,((ror-8)&0x1f)/2,1); // orr r1, r1, 1<<shift
550 if (r&3) EOP_ADD_REG_LSR(1,7,1, (r&3)*8-1); // add r1, r7, r1, lsr #lsr
551 else EOP_ADD_REG_LSL(1,7,1,1);
552 EOP_LDRH_SIMPLE(0,1); // ldrh r0, [r1]
554 EOP_LDR_IMM(2,7,0x48c); // ptr_iram_rom
555 EOP_ADD_REG_LSL(2,2,0,1); // add r2, r2, r0, lsl #1
556 EOP_ADD_IMM(0,0,0,1); // add r0, r0, #1
558 tr_bank_write((op&0x100) | ((op>>2)&3));
559 } else if (known_regb & (1 << (r+8))) {
560 tr_bank_write((op&0x100) | known_regs.r[r]);
562 EOP_STRH_SIMPLE(0,1); // strh r0, [r1]
565 EOP_LDRH_SIMPLE(0,2); // ldrh r0, [r2]
566 hostreg_r[0] = hostreg_r[2] = -1;
569 // check if AL is going to be used later in block
570 static int tr_predict_al_need(void)
572 int tmpv, tmpv2, op, pc = known_regs.gr[SSP_PC].h;
581 tmpv2 = (op >> 4) & 0xf; // dst
582 tmpv = op & 0xf; // src
583 if ((tmpv2 == SSP_A && tmpv == SSP_P) || tmpv2 == SSP_AL) // ld A, P; ld AL, *
592 case 0x10: case 0x30: case 0x40: case 0x60: case 0x70:
593 tmpv = op & 0xf; // src
594 if (tmpv == SSP_AL) // OP *, AL
604 case 0x74: pc++; break;
614 // mpya (rj), (ri), b
618 case 0x5b: return 0; // cleared anyway
622 tmpv = op & 0xf; // src
623 if (tmpv == SSP_AL) return 1;
624 case 0x51: case 0x53: case 0x54: case 0x55: case 0x59: case 0x5c:
632 /* get ARM cond which would mean that SSP cond is satisfied. No trash. */
633 static int tr_cond_check(int op)
635 int f = (op & 0x100) >> 8;
637 case 0x00: return A_COND_AL; /* always true */
638 case 0x50: /* Z matches f(?) bit */
639 if (dirty_regb & KRREG_ST) return f ? A_COND_EQ : A_COND_NE;
640 EOP_TST_IMM(6, 0, 4);
641 return f ? A_COND_NE : A_COND_EQ;
642 case 0x70: /* N matches f(?) bit */
643 if (dirty_regb & KRREG_ST) return f ? A_COND_MI : A_COND_PL;
644 EOP_TST_IMM(6, 0, 8);
645 return f ? A_COND_NE : A_COND_EQ;
647 printf("unimplemented cond?\n");
653 static int tr_neg_cond(int cond)
656 case A_COND_AL: printf("neg for AL?\n"); exit(1);
657 case A_COND_EQ: return A_COND_NE;
658 case A_COND_NE: return A_COND_EQ;
659 case A_COND_MI: return A_COND_PL;
660 case A_COND_PL: return A_COND_MI;
661 default: printf("bad cond for neg\n"); exit(1);
666 static int tr_aop_ssp2arm(int op)
669 case 1: return A_OP_SUB;
670 case 3: return A_OP_CMP;
671 case 4: return A_OP_ADD;
672 case 5: return A_OP_AND;
673 case 6: return A_OP_ORR;
674 case 7: return A_OP_EOR;
681 // -----------------------------------------------------
685 //@ r6: STACK and emu flags
689 // read general reg to r0. Trashes r1
690 static void tr_GR0_to_r0(int op)
695 static void tr_X_to_r0(int op)
697 if (hostreg_r[0] != (SSP_X<<16)) {
698 EOP_MOV_REG_LSR(0, 4, 16); // mov r0, r4, lsr #16
699 hostreg_r[0] = SSP_X<<16;
703 static void tr_Y_to_r0(int op)
705 if (hostreg_r[0] != (SSP_Y<<16)) {
706 EOP_MOV_REG_SIMPLE(0, 4); // mov r0, r4
707 hostreg_r[0] = SSP_Y<<16;
711 static void tr_A_to_r0(int op)
713 if (hostreg_r[0] != (SSP_A<<16)) {
714 EOP_MOV_REG_LSR(0, 5, 16); // mov r0, r5, lsr #16 @ AH
715 hostreg_r[0] = SSP_A<<16;
719 static void tr_ST_to_r0(int op)
721 // VR doesn't need much accuracy here..
722 EOP_MOV_REG_LSR(0, 6, 4); // mov r0, r6, lsr #4
723 EOP_AND_IMM(0, 0, 0, 0x67); // and r0, r0, #0x67
727 static void tr_STACK_to_r0(int op)
730 EOP_SUB_IMM(6, 6, 8/2, 0x20); // sub r6, r6, #1<<29
731 EOP_ADD_IMM(1, 7, 24/2, 0x04); // add r1, r7, 0x400
732 EOP_ADD_IMM(1, 1, 0, 0x48); // add r1, r1, 0x048
733 EOP_ADD_REG_LSR(1, 1, 6, 28); // add r1, r1, r6, lsr #28
734 EOP_LDRH_SIMPLE(0, 1); // ldrh r0, [r1]
735 hostreg_r[0] = hostreg_r[1] = -1;
738 static void tr_PC_to_r0(int op)
740 tr_mov16(0, known_regs.gr[SSP_PC].h);
743 static void tr_P_to_r0(int op)
746 EOP_MOV_REG_LSR(0, 10, 16); // mov r0, r10, lsr #16
750 static void tr_AL_to_r0(int op)
753 if (known_regb & KRREG_PMC) {
754 known_regs.emu_status &= ~(SSP_PMC_SET|SSP_PMC_HAVE_ADDR);
756 EOP_LDR_IMM(0,7,0x484); // ldr r1, [r7, #0x484] // emu_status
757 EOP_BIC_IMM(0,0,0,SSP_PMC_SET|SSP_PMC_HAVE_ADDR);
758 EOP_STR_IMM(0,7,0x484);
762 if (hostreg_r[0] != (SSP_AL<<16)) {
763 EOP_MOV_REG_SIMPLE(0, 5); // mov r0, r5
764 hostreg_r[0] = SSP_AL<<16;
768 static void tr_PMX_to_r0(int reg)
770 if ((known_regb & KRREG_PMC) && (known_regs.emu_status & SSP_PMC_SET))
772 known_regs.pmac_read[reg] = known_regs.pmc.v;
773 known_regs.emu_status &= ~SSP_PMC_SET;
774 known_regb |= 1 << (20+reg);
775 dirty_regb |= 1 << (20+reg);
779 if ((known_regb & KRREG_PMC) && (known_regb & (1 << (20+reg))))
781 u32 pmcv = known_regs.pmac_read[reg];
783 known_regs.emu_status &= ~SSP_PMC_HAVE_ADDR;
785 if ((mode & 0xfff0) == 0x0800)
787 EOP_LDR_IMM(1,7,0x488); // rom_ptr
788 emit_mov_const(A_COND_AL, 0, (pmcv&0xfffff)<<1);
789 EOP_LDRH_REG(0,1,0); // ldrh r0, [r1, r0]
790 known_regs.pmac_read[reg] += 1;
792 else if ((mode & 0x47ff) == 0x0018) // DRAM
794 int inc = get_inc(mode);
795 EOP_LDR_IMM(1,7,0x490); // dram_ptr
796 emit_mov_const(A_COND_AL, 0, (pmcv&0xffff)<<1);
797 EOP_LDRH_REG(0,1,0); // ldrh r0, [r1, r0]
798 if (reg == 4 && (pmcv == 0x187f03 || pmcv == 0x187f04)) // wait loop detection
800 int flag = (pmcv == 0x187f03) ? SSP_WAIT_30FE06 : SSP_WAIT_30FE08;
802 EOP_LDR_IMM(1,7,0x484); // ldr r1, [r7, #0x484] // emu_status
803 EOP_TST_REG_SIMPLE(0,0);
804 EOP_C_DOP_IMM(A_COND_EQ,A_OP_SUB,0,11,11,22/2,1); // subeq r11, r11, #1024
805 EOP_C_DOP_IMM(A_COND_EQ,A_OP_ORR,0, 1, 1,24/2,flag>>8); // orreq r1, r1, #SSP_WAIT_30FE08
806 EOP_STR_IMM(1,7,0x484); // str r1, [r7, #0x484] // emu_status
808 known_regs.pmac_read[reg] += inc;
814 known_regs.pmc.v = known_regs.pmac_read[reg];
815 //known_regb |= KRREG_PMC;
816 dirty_regb |= KRREG_PMC;
817 dirty_regb |= 1 << (20+reg);
818 hostreg_r[0] = hostreg_r[1] = -1;
822 known_regb &= ~KRREG_PMC;
823 dirty_regb &= ~KRREG_PMC;
824 known_regb &= ~(1 << (20+reg));
825 dirty_regb &= ~(1 << (20+reg));
827 // call the C code to handle this
829 //tr_flush_dirty_pmcrs();
831 emit_call(A_COND_AL, ssp_pm_read);
835 static void tr_PM0_to_r0(int op)
840 static void tr_PM1_to_r0(int op)
845 static void tr_PM2_to_r0(int op)
850 static void tr_XST_to_r0(int op)
852 EOP_ADD_IMM(0, 7, 24/2, 4); // add r0, r7, #0x400
853 EOP_LDRH_IMM(0, 0, SSP_XST*4+2);
856 static void tr_PM4_to_r0(int op)
861 static void tr_PMC_to_r0(int op)
863 if (known_regb & KRREG_PMC)
865 if (known_regs.emu_status & SSP_PMC_HAVE_ADDR) {
866 known_regs.emu_status |= SSP_PMC_SET;
867 known_regs.emu_status &= ~SSP_PMC_HAVE_ADDR;
868 // do nothing - this is handled elsewhere
870 tr_mov16(0, known_regs.pmc.l);
871 known_regs.emu_status |= SSP_PMC_HAVE_ADDR;
876 EOP_LDR_IMM(1,7,0x484); // ldr r1, [r7, #0x484] // emu_status
879 EOP_LDR_IMM(0, 7, 0x400+SSP_PMC*4);
880 EOP_TST_IMM(1, 0, SSP_PMC_HAVE_ADDR);
881 EOP_C_DOP_IMM(A_COND_EQ,A_OP_ORR,0, 1, 1, 0, SSP_PMC_HAVE_ADDR); // orreq r1, r1, #..
882 EOP_C_DOP_IMM(A_COND_NE,A_OP_BIC,0, 1, 1, 0, SSP_PMC_HAVE_ADDR); // bicne r1, r1, #..
883 EOP_C_DOP_IMM(A_COND_NE,A_OP_ORR,0, 1, 1, 0, SSP_PMC_SET); // orrne r1, r1, #..
884 EOP_STR_IMM(1,7,0x484);
885 hostreg_r[0] = hostreg_r[1] = -1;
890 typedef void (tr_read_func)(int op);
892 static tr_read_func *tr_read_funcs[16] =
907 (tr_read_func *)tr_unhandled,
913 // write r0 to general reg handlers. Trashes r1
914 #define TR_WRITE_R0_TO_REG(reg) \
916 hostreg_sspreg_changed(reg); \
917 hostreg_r[0] = (reg)<<16; \
918 if (const_val != -1) { \
919 known_regs.gr[reg].h = const_val; \
920 known_regb |= 1 << (reg); \
922 known_regb &= ~(1 << (reg)); \
926 static void tr_r0_to_GR0(int const_val)
931 static void tr_r0_to_X(int const_val)
933 EOP_MOV_REG_LSL(4, 4, 16); // mov r4, r4, lsl #16
934 EOP_MOV_REG_LSR(4, 4, 16); // mov r4, r4, lsr #16
935 EOP_ORR_REG_LSL(4, 4, 0, 16); // orr r4, r4, r0, lsl #16
936 dirty_regb |= KRREG_P; // touching X or Y makes P dirty.
937 TR_WRITE_R0_TO_REG(SSP_X);
940 static void tr_r0_to_Y(int const_val)
942 EOP_MOV_REG_LSR(4, 4, 16); // mov r4, r4, lsr #16
943 EOP_ORR_REG_LSL(4, 4, 0, 16); // orr r4, r4, r0, lsl #16
944 EOP_MOV_REG_ROR(4, 4, 16); // mov r4, r4, ror #16
945 dirty_regb |= KRREG_P;
946 TR_WRITE_R0_TO_REG(SSP_Y);
949 static void tr_r0_to_A(int const_val)
951 if (tr_predict_al_need()) {
952 EOP_MOV_REG_LSL(5, 5, 16); // mov r5, r5, lsl #16
953 EOP_MOV_REG_LSR(5, 5, 16); // mov r5, r5, lsr #16 @ AL
954 EOP_ORR_REG_LSL(5, 5, 0, 16); // orr r5, r5, r0, lsl #16
957 EOP_MOV_REG_LSL(5, 0, 16);
958 TR_WRITE_R0_TO_REG(SSP_A);
961 static void tr_r0_to_ST(int const_val)
963 // VR doesn't need much accuracy here..
964 EOP_AND_IMM(1, 0, 0, 0x67); // and r1, r0, #0x67
965 EOP_AND_IMM(6, 6, 8/2, 0xe0); // and r6, r6, #7<<29 @ preserve STACK
966 EOP_ORR_REG_LSL(6, 6, 1, 4); // orr r6, r6, r1, lsl #4
967 TR_WRITE_R0_TO_REG(SSP_ST);
969 dirty_regb &= ~KRREG_ST;
972 static void tr_r0_to_STACK(int const_val)
975 EOP_ADD_IMM(1, 7, 24/2, 0x04); // add r1, r7, 0x400
976 EOP_ADD_IMM(1, 1, 0, 0x48); // add r1, r1, 0x048
977 EOP_ADD_REG_LSR(1, 1, 6, 28); // add r1, r1, r6, lsr #28
978 EOP_STRH_SIMPLE(0, 1); // strh r0, [r1]
979 EOP_ADD_IMM(6, 6, 8/2, 0x20); // add r6, r6, #1<<29
983 static void tr_r0_to_PC(int const_val)
986 * do nothing - dispatcher will take care of this
987 EOP_MOV_REG_LSL(1, 0, 16); // mov r1, r0, lsl #16
988 EOP_STR_IMM(1,7,0x400+6*4); // str r1, [r7, #(0x400+6*8)]
993 static void tr_r0_to_AL(int const_val)
995 EOP_MOV_REG_LSR(5, 5, 16); // mov r5, r5, lsr #16
996 EOP_ORR_REG_LSL(5, 5, 0, 16); // orr r5, r5, r0, lsl #16
997 EOP_MOV_REG_ROR(5, 5, 16); // mov r5, r5, ror #16
998 hostreg_sspreg_changed(SSP_AL);
999 if (const_val != -1) {
1000 known_regs.gr[SSP_A].l = const_val;
1001 known_regb |= 1 << SSP_AL;
1003 known_regb &= ~(1 << SSP_AL);
1006 static void tr_r0_to_PMX(int reg)
1008 if ((known_regb & KRREG_PMC) && (known_regs.emu_status & SSP_PMC_SET))
1010 known_regs.pmac_write[reg] = known_regs.pmc.v;
1011 known_regs.emu_status &= ~SSP_PMC_SET;
1012 known_regb |= 1 << (25+reg);
1013 dirty_regb |= 1 << (25+reg);
1017 if ((known_regb & KRREG_PMC) && (known_regb & (1 << (25+reg))))
1021 known_regs.emu_status &= ~SSP_PMC_HAVE_ADDR;
1023 mode = known_regs.pmac_write[reg]>>16;
1024 addr = known_regs.pmac_write[reg]&0xffff;
1025 if ((mode & 0x43ff) == 0x0018) // DRAM
1027 int inc = get_inc(mode);
1028 if (mode & 0x0400) tr_unhandled();
1029 EOP_LDR_IMM(1,7,0x490); // dram_ptr
1030 emit_mov_const(A_COND_AL, 2, addr<<1);
1031 EOP_STRH_REG(0,1,2); // strh r0, [r1, r2]
1032 known_regs.pmac_write[reg] += inc;
1034 else if ((mode & 0xfbff) == 0x4018) // DRAM, cell inc
1036 if (mode & 0x0400) tr_unhandled();
1037 EOP_LDR_IMM(1,7,0x490); // dram_ptr
1038 emit_mov_const(A_COND_AL, 2, addr<<1);
1039 EOP_STRH_REG(0,1,2); // strh r0, [r1, r2]
1040 known_regs.pmac_write[reg] += (addr&1) ? 31 : 1;
1042 else if ((mode & 0x47ff) == 0x001c) // IRAM
1044 int inc = get_inc(mode);
1045 EOP_LDR_IMM(1,7,0x48c); // iram_ptr
1046 emit_mov_const(A_COND_AL, 2, (addr&0x3ff)<<1);
1047 EOP_STRH_REG(0,1,2); // strh r0, [r1, r2]
1049 EOP_STR_IMM(1,7,0x494); // iram_dirty
1050 known_regs.pmac_write[reg] += inc;
1055 known_regs.pmc.v = known_regs.pmac_write[reg];
1056 //known_regb |= KRREG_PMC;
1057 dirty_regb |= KRREG_PMC;
1058 dirty_regb |= 1 << (25+reg);
1059 hostreg_r[1] = hostreg_r[2] = -1;
1063 known_regb &= ~KRREG_PMC;
1064 dirty_regb &= ~KRREG_PMC;
1065 known_regb &= ~(1 << (25+reg));
1066 dirty_regb &= ~(1 << (25+reg));
1068 // call the C code to handle this
1069 tr_flush_dirty_ST();
1070 //tr_flush_dirty_pmcrs();
1072 emit_call(A_COND_AL, ssp_pm_write);
1076 static void tr_r0_to_PM0(int const_val)
1081 static void tr_r0_to_PM1(int const_val)
1086 static void tr_r0_to_PM2(int const_val)
1091 static void tr_r0_to_PM4(int const_val)
1096 static void tr_r0_to_PMC(int const_val)
1098 if ((known_regb & KRREG_PMC) && const_val != -1)
1100 if (known_regs.emu_status & SSP_PMC_HAVE_ADDR) {
1101 known_regs.emu_status |= SSP_PMC_SET;
1102 known_regs.emu_status &= ~SSP_PMC_HAVE_ADDR;
1103 known_regs.pmc.h = const_val;
1105 known_regs.emu_status |= SSP_PMC_HAVE_ADDR;
1106 known_regs.pmc.l = const_val;
1111 tr_flush_dirty_ST();
1112 if (known_regb & KRREG_PMC) {
1113 emit_mov_const(A_COND_AL, 1, known_regs.pmc.v);
1114 EOP_STR_IMM(1,7,0x400+SSP_PMC*4);
1115 known_regb &= ~KRREG_PMC;
1116 dirty_regb &= ~KRREG_PMC;
1118 EOP_LDR_IMM(1,7,0x484); // ldr r1, [r7, #0x484] // emu_status
1119 EOP_ADD_IMM(2,7,24/2,4); // add r2, r7, #0x400
1120 EOP_TST_IMM(1, 0, SSP_PMC_HAVE_ADDR);
1121 EOP_C_AM3_IMM(A_COND_EQ,1,0,2,0,0,1,SSP_PMC*4); // strxx r0, [r2, #SSP_PMC]
1122 EOP_C_AM3_IMM(A_COND_NE,1,0,2,0,0,1,SSP_PMC*4+2);
1123 EOP_C_DOP_IMM(A_COND_EQ,A_OP_ORR,0, 1, 1, 0, SSP_PMC_HAVE_ADDR); // orreq r1, r1, #..
1124 EOP_C_DOP_IMM(A_COND_NE,A_OP_BIC,0, 1, 1, 0, SSP_PMC_HAVE_ADDR); // bicne r1, r1, #..
1125 EOP_C_DOP_IMM(A_COND_NE,A_OP_ORR,0, 1, 1, 0, SSP_PMC_SET); // orrne r1, r1, #..
1126 EOP_STR_IMM(1,7,0x484);
1127 hostreg_r[1] = hostreg_r[2] = -1;
1131 typedef void (tr_write_func)(int const_val);
1133 static tr_write_func *tr_write_funcs[16] =
1142 (tr_write_func *)tr_unhandled,
1146 (tr_write_func *)tr_unhandled,
1148 (tr_write_func *)tr_unhandled,
1153 static void tr_mac_load_XY(int op)
1155 tr_rX_read(op&3, (op>>2)&3); // X
1156 EOP_MOV_REG_LSL(4, 0, 16);
1157 tr_rX_read(((op>>4)&3)|4, (op>>6)&3); // Y
1158 EOP_ORR_REG_SIMPLE(4, 0);
1159 dirty_regb |= KRREG_P;
1160 hostreg_sspreg_changed(SSP_X);
1161 hostreg_sspreg_changed(SSP_Y);
1162 known_regb &= ~KRREG_X;
1163 known_regb &= ~KRREG_Y;
1166 // -----------------------------------------------------
1168 static int tr_detect_set_pm(unsigned int op, int *pc, int imm)
1171 if (!((op&0xfef0) == 0x08e0 && (PROGRAM(*pc)&0xfef0) == 0x08e0)) return 0;
1177 pmcv = imm | (PROGRAM((*pc)++) << 16);
1178 known_regs.pmc.v = pmcv;
1179 known_regb |= KRREG_PMC;
1180 dirty_regb |= KRREG_PMC;
1181 known_regs.emu_status |= SSP_PMC_SET;
1184 // check for possible reg programming
1185 tmpv = PROGRAM(*pc);
1186 if ((tmpv & 0xfff8) == 0x08 || (tmpv & 0xff8f) == 0x80)
1188 int is_write = (tmpv & 0xff8f) == 0x80;
1189 int reg = is_write ? ((tmpv>>4)&0x7) : (tmpv&0x7);
1190 if (reg > 4) tr_unhandled();
1191 if ((tmpv & 0x0f) != 0 && (tmpv & 0xf0) != 0) tr_unhandled();
1192 known_regs.pmac_read[is_write ? reg + 5 : reg] = pmcv;
1193 known_regb |= is_write ? (1 << (reg+25)) : (1 << (reg+20));
1194 dirty_regb |= is_write ? (1 << (reg+25)) : (1 << (reg+20));
1195 known_regs.emu_status &= ~SSP_PMC_SET;
1205 static const short pm0_block_seq[] = { 0x0880, 0, 0x0880, 0, 0x0840, 0x60 };
1207 static int tr_detect_pm0_block(unsigned int op, int *pc, int imm)
1214 if (op != 0x0840 || imm != 0) return 0;
1215 pp = PROGRAM_P(*pc);
1216 if (memcmp(pp, pm0_block_seq, sizeof(pm0_block_seq)) != 0) return 0;
1218 EOP_AND_IMM(6, 6, 8/2, 0xe0); // and r6, r6, #7<<29 @ preserve STACK
1219 EOP_ORR_IMM(6, 6, 24/2, 6); // orr r6, r6, 0x600
1220 hostreg_sspreg_changed(SSP_ST);
1221 known_regs.gr[SSP_ST].h = 0x60;
1222 known_regb |= 1 << SSP_ST;
1223 dirty_regb &= ~KRREG_ST;
1229 static int tr_detect_rotate(unsigned int op, int *pc, int imm)
1235 if (op != 0x02e3 || PROGRAM(*pc) != 0x04e3 || PROGRAM(*pc + 1) != 0x000f) return 0;
1238 EOP_MOV_REG_LSL(0, 0, 4);
1239 EOP_ORR_REG_LSR(0, 0, 0, 16);
1246 // -----------------------------------------------------
1248 static int translate_op(unsigned int op, int *pc, int imm, int *end_cond, int *jump_pc)
1250 u32 tmpv, tmpv2, tmpv3;
1252 known_regs.gr[SSP_PC].h = *pc;
1258 if (op == 0) { ret++; break; } // nop
1259 tmpv = op & 0xf; // src
1260 tmpv2 = (op >> 4) & 0xf; // dst
1261 if (tmpv2 == SSP_A && tmpv == SSP_P) { // ld A, P
1263 EOP_MOV_REG_SIMPLE(5, 10);
1264 hostreg_sspreg_changed(SSP_A);
1265 known_regb &= ~(KRREG_A|KRREG_AL);
1268 tr_read_funcs[tmpv](op);
1269 tr_write_funcs[tmpv2]((known_regb & (1 << tmpv)) ? known_regs.gr[tmpv].h : -1);
1270 if (tmpv2 == SSP_PC) {
1272 *end_cond = -A_COND_AL;
1278 int r = (op&3) | ((op>>6)&4);
1279 int mod = (op>>2)&3;
1280 tmpv = (op >> 4) & 0xf; // dst
1281 ret = tr_detect_rotate(op, pc, imm);
1287 while (PROGRAM(*pc) == op) {
1288 (*pc)++; cnt++; ret++;
1291 tr_ptrr_mod(r, mod, 1, cnt); // skip
1293 tr_write_funcs[tmpv](-1);
1294 if (tmpv == SSP_PC) {
1296 *end_cond = -A_COND_AL;
1303 tmpv = (op >> 4) & 0xf; // src
1304 tr_read_funcs[tmpv](op);
1310 tr_bank_read(op&0x1ff);
1316 tmpv = (op & 0xf0) >> 4; // dst
1317 ret = tr_detect_pm0_block(op, pc, imm);
1319 ret = tr_detect_set_pm(op, pc, imm);
1322 tr_write_funcs[tmpv](imm);
1323 if (tmpv == SSP_PC) {
1331 tmpv2 = (op >> 4) & 0xf; // dst
1333 tr_write_funcs[tmpv2](-1);
1334 if (tmpv2 == SSP_PC) {
1336 *end_cond = -A_COND_AL;
1349 tr_bank_write(op&0x1ff);
1355 r = (op&3) | ((op>>6)&4); // src
1356 tmpv2 = (op >> 4) & 0xf; // dst
1357 if ((r&3) == 3) tr_unhandled();
1359 if (known_regb & (1 << (r+8))) {
1360 tr_mov16(0, known_regs.r[r]);
1361 tr_write_funcs[tmpv2](known_regs.r[r]);
1363 int reg = (r < 4) ? 8 : 9;
1364 if (r&3) EOP_MOV_REG_LSR(0, reg, (r&3)*8); // mov r0, r{7,8}, lsr #lsr
1365 EOP_AND_IMM(0, (r&3)?0:reg, 0, 0xff); // and r0, r{7,8}, <mask>
1367 tr_write_funcs[tmpv2](-1);
1375 r = (op&3) | ((op>>6)&4); // dst
1376 tmpv = (op >> 4) & 0xf; // src
1377 if ((r&3) == 3) tr_unhandled();
1379 if (known_regb & (1 << tmpv)) {
1380 known_regs.r[r] = known_regs.gr[tmpv].h;
1381 known_regb |= 1 << (r + 8);
1382 dirty_regb |= 1 << (r + 8);
1384 int reg = (r < 4) ? 8 : 9;
1385 int ror = ((4 - (r&3))*8) & 0x1f;
1386 tr_read_funcs[tmpv](op);
1387 EOP_BIC_IMM(reg, reg, ror/2, 0xff); // bic r{7,8}, r{7,8}, <mask>
1388 EOP_AND_IMM(0, 0, 0, 0xff); // and r0, r0, 0xff
1389 EOP_ORR_REG_LSL(reg, reg, 0, (r&3)*8); // orr r{7,8}, r{7,8}, r0, lsl #lsl
1391 known_regb &= ~(1 << (r+8));
1392 dirty_regb &= ~(1 << (r+8));
1400 known_regs.r[tmpv] = op;
1401 known_regb |= 1 << (tmpv + 8);
1402 dirty_regb |= 1 << (tmpv + 8);
1407 u32 *jump_op = NULL;
1408 tmpv = tr_cond_check(op);
1409 if (tmpv != A_COND_AL) {
1410 jump_op = tcache_ptr;
1411 EOP_MOV_IMM(0, 0, 0); // placeholder for branch
1414 tr_r0_to_STACK(*pc);
1415 if (tmpv != A_COND_AL) {
1416 u32 *real_ptr = tcache_ptr;
1417 tcache_ptr = jump_op;
1418 EOP_C_B(tr_neg_cond(tmpv),0,real_ptr - jump_op - 2);
1419 tcache_ptr = real_ptr;
1421 tr_mov16_cond(tmpv, 0, imm);
1422 if (tmpv != A_COND_AL)
1423 tr_mov16_cond(tr_neg_cond(tmpv), 0, *pc);
1424 tr_r0_to_PC(tmpv == A_COND_AL ? imm : -1);
1433 tmpv2 = (op >> 4) & 0xf; // dst
1435 EOP_LDR_IMM(1,7,0x48c); // ptr_iram_rom
1436 EOP_ADD_REG_LSL(0,1,0,1); // add r0, r1, r0, lsl #1
1437 EOP_LDRH_SIMPLE(0,0); // ldrh r0, [r0]
1438 hostreg_r[0] = hostreg_r[1] = -1;
1439 tr_write_funcs[tmpv2](-1);
1440 if (tmpv2 == SSP_PC) {
1442 *end_cond = -A_COND_AL;
1448 tmpv = tr_cond_check(op);
1449 tr_mov16_cond(tmpv, 0, imm);
1450 if (tmpv != A_COND_AL)
1451 tr_mov16_cond(tr_neg_cond(tmpv), 0, *pc);
1452 tr_r0_to_PC(tmpv == A_COND_AL ? imm : -1);
1460 // check for repeats of this op
1462 while (PROGRAM(*pc) == op && (op & 7) != 6) {
1466 if ((op&0xf0) != 0) // !always
1469 tmpv2 = tr_cond_check(op);
1471 case 2: EOP_C_DOP_REG_XIMM(tmpv2,A_OP_MOV,1,0,5,tmpv,A_AM1_ASR,5); break; // shr (arithmetic)
1472 case 3: EOP_C_DOP_REG_XIMM(tmpv2,A_OP_MOV,1,0,5,tmpv,A_AM1_LSL,5); break; // shl
1473 case 6: EOP_C_DOP_IMM(tmpv2,A_OP_RSB,1,5,5,0,0); break; // neg
1474 case 7: EOP_C_DOP_REG_XIMM(tmpv2,A_OP_EOR,0,5,1,31,A_AM1_ASR,5); // eor r1, r5, r5, asr #31
1475 EOP_C_DOP_REG_XIMM(tmpv2,A_OP_ADD,1,1,5,31,A_AM1_LSR,5); // adds r5, r1, r5, lsr #31
1476 hostreg_r[1] = -1; break; // abs
1477 default: tr_unhandled();
1480 hostreg_sspreg_changed(SSP_A);
1481 dirty_regb |= KRREG_ST;
1482 known_regb &= ~KRREG_ST;
1483 known_regb &= ~(KRREG_A|KRREG_AL);
1492 EOP_C_DOP_REG_XIMM(A_COND_AL,A_OP_SUB,1,5,5,0,A_AM1_LSL,10); // subs r5, r5, r10
1493 hostreg_sspreg_changed(SSP_A);
1494 known_regb &= ~(KRREG_A|KRREG_AL);
1495 dirty_regb |= KRREG_ST;
1498 // mpya (rj), (ri), b
1503 EOP_C_DOP_REG_XIMM(A_COND_AL,A_OP_ADD,1,5,5,0,A_AM1_LSL,10); // adds r5, r5, r10
1504 hostreg_sspreg_changed(SSP_A);
1505 known_regb &= ~(KRREG_A|KRREG_AL);
1506 dirty_regb |= KRREG_ST;
1509 // mld (rj), (ri), b
1511 EOP_C_DOP_IMM(A_COND_AL,A_OP_MOV,1,0,5,0,0); // movs r5, #0
1512 hostreg_sspreg_changed(SSP_A);
1513 known_regs.gr[SSP_A].v = 0;
1514 known_regb |= (KRREG_A|KRREG_AL);
1515 dirty_regb |= KRREG_ST;
1526 tmpv = op & 0xf; // src
1527 tmpv2 = tr_aop_ssp2arm(op>>13); // op
1528 tmpv3 = (tmpv2 == A_OP_CMP) ? 0 : 5;
1529 if (tmpv == SSP_P) {
1531 EOP_C_DOP_REG_XIMM(A_COND_AL,tmpv2,1,5,tmpv3, 0,A_AM1_LSL,10); // OPs r5, r5, r10
1532 } else if (tmpv == SSP_A) {
1533 EOP_C_DOP_REG_XIMM(A_COND_AL,tmpv2,1,5,tmpv3, 0,A_AM1_LSL, 5); // OPs r5, r5, r5
1535 tr_read_funcs[tmpv](op);
1536 EOP_C_DOP_REG_XIMM(A_COND_AL,tmpv2,1,5,tmpv3,16,A_AM1_LSL, 0); // OPs r5, r5, r0, lsl #16
1538 hostreg_sspreg_changed(SSP_A);
1539 known_regb &= ~(KRREG_A|KRREG_AL|KRREG_ST);
1540 dirty_regb |= KRREG_ST;
1550 tmpv2 = tr_aop_ssp2arm(op>>13); // op
1551 tmpv3 = (tmpv2 == A_OP_CMP) ? 0 : 5;
1552 tr_rX_read((op&3)|((op>>6)&4), (op>>2)&3);
1553 EOP_C_DOP_REG_XIMM(A_COND_AL,tmpv2,1,5,tmpv3,16,A_AM1_LSL,0); // OPs r5, r5, r0, lsl #16
1554 hostreg_sspreg_changed(SSP_A);
1555 known_regb &= ~(KRREG_A|KRREG_AL|KRREG_ST);
1556 dirty_regb |= KRREG_ST;
1566 tmpv2 = tr_aop_ssp2arm(op>>13); // op
1567 tmpv3 = (tmpv2 == A_OP_CMP) ? 0 : 5;
1568 tr_bank_read(op&0x1ff);
1569 EOP_C_DOP_REG_XIMM(A_COND_AL,tmpv2,1,5,tmpv3,16,A_AM1_LSL,0); // OPs r5, r5, r0, lsl #16
1570 hostreg_sspreg_changed(SSP_A);
1571 known_regb &= ~(KRREG_A|KRREG_AL|KRREG_ST);
1572 dirty_regb |= KRREG_ST;
1582 tmpv = (op & 0xf0) >> 4;
1583 tmpv2 = tr_aop_ssp2arm(op>>13); // op
1584 tmpv3 = (tmpv2 == A_OP_CMP) ? 0 : 5;
1586 EOP_C_DOP_REG_XIMM(A_COND_AL,tmpv2,1,5,tmpv3,16,A_AM1_LSL,0); // OPs r5, r5, r0, lsl #16
1587 hostreg_sspreg_changed(SSP_A);
1588 known_regb &= ~(KRREG_A|KRREG_AL|KRREG_ST);
1589 dirty_regb |= KRREG_ST;
1599 tmpv2 = tr_aop_ssp2arm(op>>13); // op
1600 tmpv3 = (tmpv2 == A_OP_CMP) ? 0 : 5;
1602 EOP_C_DOP_REG_XIMM(A_COND_AL,tmpv2,1,5,tmpv3,16,A_AM1_LSL,0); // OPs r5, r5, r0, lsl #16
1603 hostreg_sspreg_changed(SSP_A);
1604 known_regb &= ~(KRREG_A|KRREG_AL|KRREG_ST);
1605 dirty_regb |= KRREG_ST;
1616 tmpv2 = tr_aop_ssp2arm(op>>13); // op
1617 tmpv3 = (tmpv2 == A_OP_CMP) ? 0 : 5;
1618 r = (op&3) | ((op>>6)&4); // src
1619 if ((r&3) == 3) tr_unhandled();
1621 if (known_regb & (1 << (r+8))) {
1622 EOP_C_DOP_IMM(A_COND_AL,tmpv2,1,5,tmpv3,16/2,known_regs.r[r]); // OPs r5, r5, #val<<16
1624 int reg = (r < 4) ? 8 : 9;
1625 if (r&3) EOP_MOV_REG_LSR(0, reg, (r&3)*8); // mov r0, r{7,8}, lsr #lsr
1626 EOP_AND_IMM(0, (r&3)?0:reg, 0, 0xff); // and r0, r{7,8}, <mask>
1627 EOP_C_DOP_REG_XIMM(A_COND_AL,tmpv2,1,5,tmpv3,16,A_AM1_LSL,0); // OPs r5, r5, r0, lsl #16
1630 hostreg_sspreg_changed(SSP_A);
1631 known_regb &= ~(KRREG_A|KRREG_AL|KRREG_ST);
1632 dirty_regb |= KRREG_ST;
1643 tmpv2 = tr_aop_ssp2arm(op>>13); // op
1644 tmpv3 = (tmpv2 == A_OP_CMP) ? 0 : 5;
1645 EOP_C_DOP_IMM(A_COND_AL,tmpv2,1,5,tmpv3,16/2,op & 0xff); // OPs r5, r5, #val<<16
1646 hostreg_sspreg_changed(SSP_A);
1647 known_regb &= ~(KRREG_A|KRREG_AL|KRREG_ST);
1648 dirty_regb |= KRREG_ST;
1657 static void emit_block_prologue(void)
1659 // check if there are enough cycles..
1660 // note: r0 must contain PC of current block
1661 EOP_CMP_IMM(11,0,0); // cmp r11, #0
1662 emit_call(A_COND_LE, ssp_drc_end);
1666 * >0: direct (un)conditional jump
1669 static void emit_block_epilogue(int cycles, int cond, int pc, int end_pc)
1671 if (cycles > 0xff) { printf("large cycle count: %i\n", cycles); cycles = 0xff; }
1672 EOP_SUB_IMM(11,11,0,cycles); // sub r11, r11, #cycles
1674 if (cond < 0 || (end_pc >= 0x400 && pc < 0x400)) {
1675 // indirect jump, or rom -> iram jump, must use dispatcher
1676 emit_jump(A_COND_AL, ssp_drc_next);
1678 else if (cond == A_COND_AL) {
1679 u32 *target = (pc < 0x400) ? ssp_block_table_iram[ssp->drc.iram_context][pc] : ssp_block_table[pc];
1681 emit_jump(A_COND_AL, target);
1683 emit_jump(A_COND_AL, ssp_drc_next);
1684 // cause the next block to be emitted over jump instrction
1689 u32 *target1 = (pc < 0x400) ? ssp_block_table_iram[ssp->drc.iram_context][pc] : ssp_block_table[pc];
1690 u32 *target2 = (end_pc < 0x400) ? ssp_block_table_iram[ssp->drc.iram_context][end_pc] : ssp_block_table[end_pc];
1691 if (target1 != NULL)
1692 emit_jump(cond, target1);
1693 else emit_call(cond, ssp_drc_next_patch);
1694 if (target2 != NULL)
1695 emit_jump(tr_neg_cond(cond), target2); // neg_cond, to be able to swap jumps if needed
1696 else emit_call(tr_neg_cond(cond), ssp_drc_next_patch);
1700 void *ssp_translate_block(int pc)
1702 unsigned int op, op1, imm, ccount = 0;
1703 unsigned int *block_start;
1704 int ret, end_cond = A_COND_AL, jump_pc = -1;
1706 printf("translate %04x -> %04x\n", pc<<1, (tcache_ptr-tcache)<<2);
1707 block_start = tcache_ptr;
1709 dirty_regb = KRREG_P;
1710 known_regs.emu_status = 0;
1713 emit_block_prologue();
1715 for (; ccount < 100;)
1721 if ((op1 & 0xf) == 4 || (op1 & 0xf) == 6)
1722 imm = PROGRAM(pc++); // immediate
1724 ret = translate_op(op, &pc, imm, &end_cond, &jump_pc);
1727 printf("NULL func! op=%08x (%02x)\n", op, op1);
1731 ccount += ret & 0xffff;
1732 if (ret & 0x10000) break;
1735 if (ccount >= 100) {
1736 end_cond = A_COND_AL;
1738 emit_mov_const(A_COND_AL, 0, pc);
1741 tr_flush_dirty_prs();
1742 tr_flush_dirty_ST();
1743 tr_flush_dirty_pmcrs();
1744 emit_block_epilogue(ccount, end_cond, jump_pc, pc);
1746 if (tcache_ptr - tcache > SSP_TCACHE_SIZE/4) {
1747 printf("tcache overflow!\n");
1754 printf("%i blocks, %i bytes, k=%.3f\n", nblocks, (tcache_ptr - tcache)*4,
1755 (double)(tcache_ptr - tcache) / (double)n_in_ops);
1759 FILE *f = fopen("tcache.bin", "wb");
1760 fwrite(tcache, 1, (tcache_ptr - tcache)*4, f);
1773 // -----------------------------------------------------
1775 static void ssp1601_state_load(void)
1777 ssp->drc.iram_dirty = 1;
1778 ssp->drc.iram_context = 0;
1781 int ssp1601_dyn_startup(void)
1783 memset(tcache, 0, SSP_TCACHE_SIZE);
1784 memset(ssp_block_table, 0, sizeof(ssp_block_table));
1785 memset(ssp_block_table_iram, 0, sizeof(ssp_block_table_iram));
1786 tcache_ptr = tcache;
1788 PicoLoadStateHook = ssp1601_state_load;
1793 ssp_block_table[0x800/2] = (void *) ssp_hle_800;
1794 ssp_block_table[0x902/2] = (void *) ssp_hle_902;
1795 ssp_block_table_iram[ 7][0x030/2] = (void *) ssp_hle_07_030;
1796 ssp_block_table_iram[ 7][0x036/2] = (void *) ssp_hle_07_036;
1797 ssp_block_table_iram[ 7][0x6d6/2] = (void *) ssp_hle_07_6d6;
1798 ssp_block_table_iram[11][0x12c/2] = (void *) ssp_hle_11_12c;
1799 ssp_block_table_iram[11][0x384/2] = (void *) ssp_hle_11_384;
1800 ssp_block_table_iram[11][0x38a/2] = (void *) ssp_hle_11_38a;
1807 void ssp1601_dyn_reset(ssp1601_t *ssp)
1812 FILE *f = fopen("tcache.bin", "wb");
1813 fwrite(tcache, 1, (tcache_ptr - tcache)*4, f);
1816 for (i = 0; i < 0x5090/2; i++)
1817 if (ssp_block_table[i])
1818 printf("%06x -> __:%04x\n", (ssp_block_table[i] - tcache)*4, i<<1);
1819 for (u = 1; u < 15; u++)
1820 for (i = 0; i < 0x800/2; i++)
1821 if (ssp_block_table_iram[u][i])
1822 printf("%06x -> %02i:%04x\n", (ssp_block_table_iram[u][i] - tcache)*4, u, i<<1);
1826 ssp->drc.iram_dirty = 1;
1827 ssp->drc.iram_context = 0;
1828 // must do this here because ssp is not available @ startup()
1829 ssp->drc.ptr_rom = (u32) Pico.rom;
1830 ssp->drc.ptr_iram_rom = (u32) svp->iram_rom;
1831 ssp->drc.ptr_dram = (u32) svp->dram;
1832 ssp->drc.ptr_btable = (u32) ssp_block_table;
1833 ssp->drc.ptr_btable_iram = (u32) ssp_block_table_iram;
1835 // prevent new versions of IRAM from appearing
1836 memset(svp->iram_rom, 0, 0x800);
1839 void ssp1601_dyn_run(int cycles)
1841 if (ssp->emu_status & SSP_WAIT_MASK) return;
1844 ssp_translate_block(DUMP_BLOCK >> 1);
1847 ssp_drc_entry(cycles);