1 /* 2 * Copyright(c) 2019-2022 Qualcomm Innovation Center, Inc. All Rights Reserved. 3 * 4 * This program is free software; you can redistribute it and/or modify 5 * it under the terms of the GNU General Public License as published by 6 * the Free Software Foundation; either version 2 of the License, or 7 * (at your option) any later version. 8 * 9 * This program is distributed in the hope that it will be useful, 10 * but WITHOUT ANY WARRANTY; without even the implied warranty of 11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 12 * GNU General Public License for more details. 13 * 14 * You should have received a copy of the GNU General Public License 15 * along with this program; if not, see <http://www.gnu.org/licenses/>. 16 */ 17 18 #include "qemu/osdep.h" 19 #include "iclass.h" 20 #include "attribs.h" 21 #include "genptr.h" 22 #include "decode.h" 23 #include "insn.h" 24 #include "printinsn.h" 25 #include "mmvec/decode_ext_mmvec.h" 26 27 #define fZXTN(N, M, VAL) ((VAL) & ((1LL << (N)) - 1)) 28 29 enum { 30 EXT_IDX_noext = 0, 31 EXT_IDX_noext_AFTER = 4, 32 EXT_IDX_mmvec = 4, 33 EXT_IDX_mmvec_AFTER = 8, 34 XX_LAST_EXT_IDX 35 }; 36 37 /* 38 * Certain operand types represent a non-contiguous set of values. 39 * For example, the compound compare-and-jump instruction can only access 40 * registers R0-R7 and R16-23. 41 * This table represents the mapping from the encoding to the actual values. 42 */ 43 44 #define DEF_REGMAP(NAME, ELEMENTS, ...) \ 45 static const unsigned int DECODE_REGISTER_##NAME[ELEMENTS] = \ 46 { __VA_ARGS__ }; 47 /* Name Num Table */ 48 DEF_REGMAP(R_16, 16, 0, 1, 2, 3, 4, 5, 6, 7, 16, 17, 18, 19, 20, 21, 22, 23) 49 DEF_REGMAP(R__8, 8, 0, 2, 4, 6, 16, 18, 20, 22) 50 DEF_REGMAP(R_8, 8, 0, 1, 2, 3, 4, 5, 6, 7) 51 52 #define DECODE_MAPPED_REG(OPNUM, NAME) \ 53 insn->regno[OPNUM] = DECODE_REGISTER_##NAME[insn->regno[OPNUM]]; 54 55 typedef struct { 56 const struct DectreeTable *table_link; 57 const struct DectreeTable *table_link_b; 58 Opcode opcode; 59 enum { 60 DECTREE_ENTRY_INVALID, 61 DECTREE_TABLE_LINK, 62 DECTREE_SUBINSNS, 63 DECTREE_EXTSPACE, 64 DECTREE_TERMINAL 65 } type; 66 } DectreeEntry; 67 68 typedef struct DectreeTable { 69 unsigned int (*lookup_function)(int startbit, int width, uint32_t opcode); 70 unsigned int size; 71 unsigned int startbit; 72 unsigned int width; 73 const DectreeEntry table[]; 74 } DectreeTable; 75 76 #define DECODE_NEW_TABLE(TAG, SIZE, WHATNOT) \ 77 static const DectreeTable dectree_table_##TAG; 78 #define TABLE_LINK(TABLE) /* NOTHING */ 79 #define TERMINAL(TAG, ENC) /* NOTHING */ 80 #define SUBINSNS(TAG, CLASSA, CLASSB, ENC) /* NOTHING */ 81 #define EXTSPACE(TAG, ENC) /* NOTHING */ 82 #define INVALID() /* NOTHING */ 83 #define DECODE_END_TABLE(...) /* NOTHING */ 84 #define DECODE_MATCH_INFO(...) /* NOTHING */ 85 #define DECODE_LEGACY_MATCH_INFO(...) /* NOTHING */ 86 #define DECODE_OPINFO(...) /* NOTHING */ 87 88 #include "dectree_generated.h.inc" 89 90 #undef DECODE_OPINFO 91 #undef DECODE_MATCH_INFO 92 #undef DECODE_LEGACY_MATCH_INFO 93 #undef DECODE_END_TABLE 94 #undef INVALID 95 #undef TERMINAL 96 #undef SUBINSNS 97 #undef EXTSPACE 98 #undef TABLE_LINK 99 #undef DECODE_NEW_TABLE 100 #undef DECODE_SEPARATOR_BITS 101 102 #define DECODE_SEPARATOR_BITS(START, WIDTH) NULL, START, WIDTH 103 #define DECODE_NEW_TABLE_HELPER(TAG, SIZE, FN, START, WIDTH) \ 104 static const DectreeTable dectree_table_##TAG = { \ 105 .size = SIZE, \ 106 .lookup_function = FN, \ 107 .startbit = START, \ 108 .width = WIDTH, \ 109 .table = { 110 #define DECODE_NEW_TABLE(TAG, SIZE, WHATNOT) \ 111 DECODE_NEW_TABLE_HELPER(TAG, SIZE, WHATNOT) 112 113 #define TABLE_LINK(TABLE) \ 114 { .type = DECTREE_TABLE_LINK, .table_link = &dectree_table_##TABLE }, 115 #define TERMINAL(TAG, ENC) \ 116 { .type = DECTREE_TERMINAL, .opcode = TAG }, 117 #define SUBINSNS(TAG, CLASSA, CLASSB, ENC) \ 118 { \ 119 .type = DECTREE_SUBINSNS, \ 120 .table_link = &dectree_table_DECODE_SUBINSN_##CLASSA, \ 121 .table_link_b = &dectree_table_DECODE_SUBINSN_##CLASSB \ 122 }, 123 #define EXTSPACE(TAG, ENC) { .type = DECTREE_EXTSPACE }, 124 #define INVALID() { .type = DECTREE_ENTRY_INVALID, .opcode = XX_LAST_OPCODE }, 125 126 #define DECODE_END_TABLE(...) } }; 127 128 #define DECODE_MATCH_INFO(...) /* NOTHING */ 129 #define DECODE_LEGACY_MATCH_INFO(...) /* NOTHING */ 130 #define DECODE_OPINFO(...) /* NOTHING */ 131 132 #include "dectree_generated.h.inc" 133 134 #undef DECODE_OPINFO 135 #undef DECODE_MATCH_INFO 136 #undef DECODE_LEGACY_MATCH_INFO 137 #undef DECODE_END_TABLE 138 #undef INVALID 139 #undef TERMINAL 140 #undef SUBINSNS 141 #undef EXTSPACE 142 #undef TABLE_LINK 143 #undef DECODE_NEW_TABLE 144 #undef DECODE_NEW_TABLE_HELPER 145 #undef DECODE_SEPARATOR_BITS 146 147 static const DectreeTable dectree_table_DECODE_EXT_EXT_noext = { 148 .size = 1, .lookup_function = NULL, .startbit = 0, .width = 0, 149 .table = { 150 { .type = DECTREE_ENTRY_INVALID, .opcode = XX_LAST_OPCODE }, 151 } 152 }; 153 154 static const DectreeTable *ext_trees[XX_LAST_EXT_IDX]; 155 156 static void decode_ext_init(void) 157 { 158 int i; 159 for (i = EXT_IDX_noext; i < EXT_IDX_noext_AFTER; i++) { 160 ext_trees[i] = &dectree_table_DECODE_EXT_EXT_noext; 161 } 162 for (i = EXT_IDX_mmvec; i < EXT_IDX_mmvec_AFTER; i++) { 163 ext_trees[i] = &dectree_table_DECODE_EXT_EXT_mmvec; 164 } 165 } 166 167 typedef struct { 168 uint32_t mask; 169 uint32_t match; 170 } DecodeITableEntry; 171 172 #define DECODE_NEW_TABLE(TAG, SIZE, WHATNOT) /* NOTHING */ 173 #define TABLE_LINK(TABLE) /* NOTHING */ 174 #define TERMINAL(TAG, ENC) /* NOTHING */ 175 #define SUBINSNS(TAG, CLASSA, CLASSB, ENC) /* NOTHING */ 176 #define EXTSPACE(TAG, ENC) /* NOTHING */ 177 #define INVALID() /* NOTHING */ 178 #define DECODE_END_TABLE(...) /* NOTHING */ 179 #define DECODE_OPINFO(...) /* NOTHING */ 180 181 #define DECODE_MATCH_INFO_NORMAL(TAG, MASK, MATCH) \ 182 [TAG] = { \ 183 .mask = MASK, \ 184 .match = MATCH, \ 185 }, 186 187 #define DECODE_MATCH_INFO_NULL(TAG, MASK, MATCH) \ 188 [TAG] = { .match = ~0 }, 189 190 #define DECODE_MATCH_INFO(...) DECODE_MATCH_INFO_NORMAL(__VA_ARGS__) 191 #define DECODE_LEGACY_MATCH_INFO(...) /* NOTHING */ 192 193 static const DecodeITableEntry decode_itable[XX_LAST_OPCODE] = { 194 #include "dectree_generated.h.inc" 195 }; 196 197 #undef DECODE_MATCH_INFO 198 #define DECODE_MATCH_INFO(...) DECODE_MATCH_INFO_NULL(__VA_ARGS__) 199 200 #undef DECODE_LEGACY_MATCH_INFO 201 #define DECODE_LEGACY_MATCH_INFO(...) DECODE_MATCH_INFO_NORMAL(__VA_ARGS__) 202 203 static const DecodeITableEntry decode_legacy_itable[XX_LAST_OPCODE] = { 204 #include "dectree_generated.h.inc" 205 }; 206 207 #undef DECODE_OPINFO 208 #undef DECODE_MATCH_INFO 209 #undef DECODE_LEGACY_MATCH_INFO 210 #undef DECODE_END_TABLE 211 #undef INVALID 212 #undef TERMINAL 213 #undef SUBINSNS 214 #undef EXTSPACE 215 #undef TABLE_LINK 216 #undef DECODE_NEW_TABLE 217 #undef DECODE_SEPARATOR_BITS 218 219 void decode_init(void) 220 { 221 decode_ext_init(); 222 } 223 224 void decode_send_insn_to(Packet *packet, int start, int newloc) 225 { 226 Insn tmpinsn; 227 int direction; 228 int i; 229 if (start == newloc) { 230 return; 231 } 232 if (start < newloc) { 233 /* Move towards end */ 234 direction = 1; 235 } else { 236 /* move towards beginning */ 237 direction = -1; 238 } 239 for (i = start; i != newloc; i += direction) { 240 tmpinsn = packet->insn[i]; 241 packet->insn[i] = packet->insn[i + direction]; 242 packet->insn[i + direction] = tmpinsn; 243 } 244 } 245 246 /* Fill newvalue registers with the correct regno */ 247 static void 248 decode_fill_newvalue_regno(Packet *packet) 249 { 250 int i, use_regidx, offset, def_idx, dst_idx; 251 uint16_t def_opcode, use_opcode; 252 char *dststr; 253 254 for (i = 1; i < packet->num_insns; i++) { 255 if (GET_ATTRIB(packet->insn[i].opcode, A_DOTNEWVALUE) && 256 !GET_ATTRIB(packet->insn[i].opcode, A_EXTENSION)) { 257 use_opcode = packet->insn[i].opcode; 258 259 /* It's a store, so we're adjusting the Nt field */ 260 if (GET_ATTRIB(use_opcode, A_STORE)) { 261 use_regidx = strchr(opcode_reginfo[use_opcode], 't') - 262 opcode_reginfo[use_opcode]; 263 } else { /* It's a Jump, so we're adjusting the Ns field */ 264 use_regidx = strchr(opcode_reginfo[use_opcode], 's') - 265 opcode_reginfo[use_opcode]; 266 } 267 268 /* 269 * What's encoded at the N-field is the offset to who's producing 270 * the value. Shift off the LSB which indicates odd/even register, 271 * then walk backwards and skip over the constant extenders. 272 */ 273 offset = packet->insn[i].regno[use_regidx] >> 1; 274 def_idx = i - offset; 275 for (int j = 0; j < offset; j++) { 276 if (GET_ATTRIB(packet->insn[i - j - 1].opcode, A_IT_EXTENDER)) { 277 def_idx--; 278 } 279 } 280 281 /* 282 * Check for a badly encoded N-field which points to an instruction 283 * out-of-range 284 */ 285 g_assert(!((def_idx < 0) || (def_idx > (packet->num_insns - 1)))); 286 287 /* 288 * packet->insn[def_idx] is the producer 289 * Figure out which type of destination it produces 290 * and the corresponding index in the reginfo 291 */ 292 def_opcode = packet->insn[def_idx].opcode; 293 dststr = strstr(opcode_wregs[def_opcode], "Rd"); 294 if (dststr) { 295 dststr = strchr(opcode_reginfo[def_opcode], 'd'); 296 } else { 297 dststr = strstr(opcode_wregs[def_opcode], "Rx"); 298 if (dststr) { 299 dststr = strchr(opcode_reginfo[def_opcode], 'x'); 300 } else { 301 dststr = strstr(opcode_wregs[def_opcode], "Re"); 302 if (dststr) { 303 dststr = strchr(opcode_reginfo[def_opcode], 'e'); 304 } else { 305 dststr = strstr(opcode_wregs[def_opcode], "Ry"); 306 if (dststr) { 307 dststr = strchr(opcode_reginfo[def_opcode], 'y'); 308 } else { 309 g_assert_not_reached(); 310 } 311 } 312 } 313 } 314 g_assert(dststr != NULL); 315 316 /* Now patch up the consumer with the register number */ 317 dst_idx = dststr - opcode_reginfo[def_opcode]; 318 packet->insn[i].regno[use_regidx] = 319 packet->insn[def_idx].regno[dst_idx]; 320 /* 321 * We need to remember who produces this value to later 322 * check if it was dynamically cancelled 323 */ 324 packet->insn[i].new_value_producer_slot = 325 packet->insn[def_idx].slot; 326 } 327 } 328 } 329 330 /* Split CJ into a compare and a jump */ 331 static void decode_split_cmpjump(Packet *pkt) 332 { 333 int last, i; 334 int numinsns = pkt->num_insns; 335 336 /* 337 * First, split all compare-jumps. 338 * The compare is sent to the end as a new instruction. 339 * Do it this way so we don't reorder dual jumps. Those need to stay in 340 * original order. 341 */ 342 for (i = 0; i < numinsns; i++) { 343 /* It's a cmp-jump */ 344 if (GET_ATTRIB(pkt->insn[i].opcode, A_NEWCMPJUMP)) { 345 last = pkt->num_insns; 346 pkt->insn[last] = pkt->insn[i]; /* copy the instruction */ 347 pkt->insn[last].part1 = true; /* last insn does the CMP */ 348 pkt->insn[i].part1 = false; /* existing insn does the JUMP */ 349 pkt->num_insns++; 350 } 351 } 352 353 /* Now re-shuffle all the compares back to the beginning */ 354 for (i = 0; i < pkt->num_insns; i++) { 355 if (pkt->insn[i].part1) { 356 decode_send_insn_to(pkt, i, 0); 357 } 358 } 359 } 360 361 static bool decode_opcode_can_jump(int opcode) 362 { 363 if ((GET_ATTRIB(opcode, A_JUMP)) || 364 (GET_ATTRIB(opcode, A_CALL)) || 365 (opcode == J2_trap0) || 366 (opcode == J2_pause)) { 367 /* Exception to A_JUMP attribute */ 368 if (opcode == J4_hintjumpr) { 369 return false; 370 } 371 return true; 372 } 373 374 return false; 375 } 376 377 static bool decode_opcode_ends_loop(int opcode) 378 { 379 return GET_ATTRIB(opcode, A_HWLOOP0_END) || 380 GET_ATTRIB(opcode, A_HWLOOP1_END); 381 } 382 383 /* Set the is_* fields in each instruction */ 384 static void decode_set_insn_attr_fields(Packet *pkt) 385 { 386 int i; 387 int numinsns = pkt->num_insns; 388 uint16_t opcode; 389 390 pkt->pkt_has_cof = false; 391 pkt->pkt_has_multi_cof = false; 392 pkt->pkt_has_endloop = false; 393 pkt->pkt_has_dczeroa = false; 394 395 for (i = 0; i < numinsns; i++) { 396 opcode = pkt->insn[i].opcode; 397 if (pkt->insn[i].part1) { 398 continue; /* Skip compare of cmp-jumps */ 399 } 400 401 if (GET_ATTRIB(opcode, A_DCZEROA)) { 402 pkt->pkt_has_dczeroa = true; 403 } 404 405 if (GET_ATTRIB(opcode, A_STORE)) { 406 if (GET_ATTRIB(opcode, A_SCALAR_STORE) && 407 !GET_ATTRIB(opcode, A_MEMSIZE_0B)) { 408 if (pkt->insn[i].slot == 0) { 409 pkt->pkt_has_store_s0 = true; 410 } else { 411 pkt->pkt_has_store_s1 = true; 412 } 413 } 414 } 415 416 if (decode_opcode_can_jump(opcode)) { 417 if (pkt->pkt_has_cof) { 418 pkt->pkt_has_multi_cof = true; 419 } 420 pkt->pkt_has_cof = true; 421 } 422 423 pkt->insn[i].is_endloop = decode_opcode_ends_loop(opcode); 424 425 pkt->pkt_has_endloop |= pkt->insn[i].is_endloop; 426 427 if (pkt->pkt_has_endloop) { 428 if (pkt->pkt_has_cof) { 429 pkt->pkt_has_multi_cof = true; 430 } 431 pkt->pkt_has_cof = true; 432 } 433 } 434 } 435 436 /* 437 * Shuffle for execution 438 * Move stores to end (in same order as encoding) 439 * Move compares to beginning (for use by .new insns) 440 */ 441 static void decode_shuffle_for_execution(Packet *packet) 442 { 443 bool changed = false; 444 int i; 445 bool flag; /* flag means we've seen a non-memory instruction */ 446 int n_mems; 447 int last_insn = packet->num_insns - 1; 448 449 /* 450 * Skip end loops, somehow an end loop is getting in and messing 451 * up the order 452 */ 453 if (decode_opcode_ends_loop(packet->insn[last_insn].opcode)) { 454 last_insn--; 455 } 456 457 do { 458 changed = false; 459 /* 460 * Stores go last, must not reorder. 461 * Cannot shuffle stores past loads, either. 462 * Iterate backwards. If we see a non-memory instruction, 463 * then a store, shuffle the store to the front. Don't shuffle 464 * stores wrt each other or a load. 465 */ 466 for (flag = false, n_mems = 0, i = last_insn; i >= 0; i--) { 467 int opcode = packet->insn[i].opcode; 468 469 if (flag && GET_ATTRIB(opcode, A_STORE)) { 470 decode_send_insn_to(packet, i, last_insn - n_mems); 471 n_mems++; 472 changed = true; 473 } else if (GET_ATTRIB(opcode, A_STORE)) { 474 n_mems++; 475 } else if (GET_ATTRIB(opcode, A_LOAD)) { 476 /* 477 * Don't set flag, since we don't want to shuffle a 478 * store past a load 479 */ 480 n_mems++; 481 } else if (GET_ATTRIB(opcode, A_DOTNEWVALUE)) { 482 /* 483 * Don't set flag, since we don't want to shuffle past 484 * a .new value 485 */ 486 } else { 487 flag = true; 488 } 489 } 490 491 if (changed) { 492 continue; 493 } 494 /* Compares go first, may be reordered wrt each other */ 495 for (flag = false, i = 0; i < last_insn + 1; i++) { 496 int opcode = packet->insn[i].opcode; 497 498 if ((strstr(opcode_wregs[opcode], "Pd4") || 499 strstr(opcode_wregs[opcode], "Pe4")) && 500 GET_ATTRIB(opcode, A_STORE) == 0) { 501 /* This should be a compare (not a store conditional) */ 502 if (flag) { 503 decode_send_insn_to(packet, i, 0); 504 changed = true; 505 continue; 506 } 507 } else if (GET_ATTRIB(opcode, A_IMPLICIT_WRITES_P3) && 508 !decode_opcode_ends_loop(packet->insn[i].opcode)) { 509 /* 510 * spNloop instruction 511 * Don't reorder endloops; they are not valid for .new uses, 512 * and we want to match HW 513 */ 514 if (flag) { 515 decode_send_insn_to(packet, i, 0); 516 changed = true; 517 continue; 518 } 519 } else if (GET_ATTRIB(opcode, A_IMPLICIT_WRITES_P0) && 520 !GET_ATTRIB(opcode, A_NEWCMPJUMP)) { 521 if (flag) { 522 decode_send_insn_to(packet, i, 0); 523 changed = true; 524 continue; 525 } 526 } else { 527 flag = true; 528 } 529 } 530 if (changed) { 531 continue; 532 } 533 } while (changed); 534 535 /* 536 * If we have a .new register compare/branch, move that to the very 537 * very end, past stores 538 */ 539 for (i = 0; i < last_insn; i++) { 540 if (GET_ATTRIB(packet->insn[i].opcode, A_DOTNEWVALUE)) { 541 decode_send_insn_to(packet, i, last_insn); 542 break; 543 } 544 } 545 } 546 547 static void 548 apply_extender(Packet *pkt, int i, uint32_t extender) 549 { 550 int immed_num; 551 uint32_t base_immed; 552 553 immed_num = opcode_which_immediate_is_extended(pkt->insn[i].opcode); 554 base_immed = pkt->insn[i].immed[immed_num]; 555 556 pkt->insn[i].immed[immed_num] = extender | fZXTN(6, 32, base_immed); 557 } 558 559 static void decode_apply_extenders(Packet *packet) 560 { 561 int i; 562 for (i = 0; i < packet->num_insns; i++) { 563 if (GET_ATTRIB(packet->insn[i].opcode, A_IT_EXTENDER)) { 564 packet->insn[i + 1].extension_valid = true; 565 apply_extender(packet, i + 1, packet->insn[i].immed[0]); 566 } 567 } 568 } 569 570 static void decode_remove_extenders(Packet *packet) 571 { 572 int i, j; 573 for (i = 0; i < packet->num_insns; i++) { 574 if (GET_ATTRIB(packet->insn[i].opcode, A_IT_EXTENDER)) { 575 /* Remove this one by moving the remaining instructions down */ 576 for (j = i; 577 (j < packet->num_insns - 1) && (j < INSTRUCTIONS_MAX - 1); 578 j++) { 579 packet->insn[j] = packet->insn[j + 1]; 580 } 581 packet->num_insns--; 582 } 583 } 584 } 585 586 static SlotMask get_valid_slots(const Packet *pkt, unsigned int slot) 587 { 588 if (GET_ATTRIB(pkt->insn[slot].opcode, A_EXTENSION)) { 589 return mmvec_ext_decode_find_iclass_slots(pkt->insn[slot].opcode); 590 } else { 591 return find_iclass_slots(pkt->insn[slot].opcode, 592 pkt->insn[slot].iclass); 593 } 594 } 595 596 #define DECODE_NEW_TABLE(TAG, SIZE, WHATNOT) /* NOTHING */ 597 #define TABLE_LINK(TABLE) /* NOTHING */ 598 #define TERMINAL(TAG, ENC) /* NOTHING */ 599 #define SUBINSNS(TAG, CLASSA, CLASSB, ENC) /* NOTHING */ 600 #define EXTSPACE(TAG, ENC) /* NOTHING */ 601 #define INVALID() /* NOTHING */ 602 #define DECODE_END_TABLE(...) /* NOTHING */ 603 #define DECODE_MATCH_INFO(...) /* NOTHING */ 604 #define DECODE_LEGACY_MATCH_INFO(...) /* NOTHING */ 605 606 #define DECODE_REG(REGNO, WIDTH, STARTBIT) \ 607 insn->regno[REGNO] = ((encoding >> STARTBIT) & ((1 << WIDTH) - 1)); 608 609 #define DECODE_IMPL_REG(REGNO, VAL) \ 610 insn->regno[REGNO] = VAL; 611 612 #define DECODE_IMM(IMMNO, WIDTH, STARTBIT, VALSTART) \ 613 insn->immed[IMMNO] |= (((encoding >> STARTBIT) & ((1 << WIDTH) - 1))) << \ 614 (VALSTART); 615 616 #define DECODE_IMM_SXT(IMMNO, WIDTH) \ 617 insn->immed[IMMNO] = ((((int32_t)insn->immed[IMMNO]) << (32 - WIDTH)) >> \ 618 (32 - WIDTH)); 619 620 #define DECODE_IMM_NEG(IMMNO, WIDTH) \ 621 insn->immed[IMMNO] = -insn->immed[IMMNO]; 622 623 #define DECODE_IMM_SHIFT(IMMNO, SHAMT) \ 624 if ((!insn->extension_valid) || \ 625 (insn->which_extended != IMMNO)) { \ 626 insn->immed[IMMNO] <<= SHAMT; \ 627 } 628 629 #define DECODE_OPINFO(TAG, BEH) \ 630 case TAG: \ 631 { BEH } \ 632 break; \ 633 634 /* 635 * Fill in the operands of the instruction 636 * dectree_generated.h.inc has a DECODE_OPINFO entry for each opcode 637 * For example, 638 * DECODE_OPINFO(A2_addi, 639 * DECODE_REG(0,5,0) 640 * DECODE_REG(1,5,16) 641 * DECODE_IMM(0,7,21,9) 642 * DECODE_IMM(0,9,5,0) 643 * DECODE_IMM_SXT(0,16) 644 * with the macros defined above, we'll fill in a switch statement 645 * where each case is an opcode tag. 646 */ 647 static void 648 decode_op(Insn *insn, Opcode tag, uint32_t encoding) 649 { 650 insn->immed[0] = 0; 651 insn->immed[1] = 0; 652 insn->opcode = tag; 653 if (insn->extension_valid) { 654 insn->which_extended = opcode_which_immediate_is_extended(tag); 655 } 656 657 switch (tag) { 658 #include "dectree_generated.h.inc" 659 default: 660 break; 661 } 662 663 insn->generate = opcode_genptr[tag]; 664 665 insn->iclass = iclass_bits(encoding); 666 } 667 668 #undef DECODE_REG 669 #undef DECODE_IMPL_REG 670 #undef DECODE_IMM 671 #undef DECODE_IMM_SHIFT 672 #undef DECODE_OPINFO 673 #undef DECODE_MATCH_INFO 674 #undef DECODE_LEGACY_MATCH_INFO 675 #undef DECODE_END_TABLE 676 #undef INVALID 677 #undef TERMINAL 678 #undef SUBINSNS 679 #undef EXTSPACE 680 #undef TABLE_LINK 681 #undef DECODE_NEW_TABLE 682 #undef DECODE_SEPARATOR_BITS 683 684 static unsigned int 685 decode_subinsn_tablewalk(Insn *insn, const DectreeTable *table, 686 uint32_t encoding) 687 { 688 unsigned int i; 689 Opcode opc; 690 if (table->lookup_function) { 691 i = table->lookup_function(table->startbit, table->width, encoding); 692 } else { 693 i = extract32(encoding, table->startbit, table->width); 694 } 695 if (table->table[i].type == DECTREE_TABLE_LINK) { 696 return decode_subinsn_tablewalk(insn, table->table[i].table_link, 697 encoding); 698 } else if (table->table[i].type == DECTREE_TERMINAL) { 699 opc = table->table[i].opcode; 700 if ((encoding & decode_itable[opc].mask) != decode_itable[opc].match) { 701 return 0; 702 } 703 decode_op(insn, opc, encoding); 704 return 1; 705 } else { 706 return 0; 707 } 708 } 709 710 static unsigned int get_insn_a(uint32_t encoding) 711 { 712 return extract32(encoding, 0, 13); 713 } 714 715 static unsigned int get_insn_b(uint32_t encoding) 716 { 717 return extract32(encoding, 16, 13); 718 } 719 720 static unsigned int 721 decode_insns_tablewalk(Insn *insn, const DectreeTable *table, 722 uint32_t encoding) 723 { 724 unsigned int i; 725 unsigned int a, b; 726 Opcode opc; 727 if (table->lookup_function) { 728 i = table->lookup_function(table->startbit, table->width, encoding); 729 } else { 730 i = extract32(encoding, table->startbit, table->width); 731 } 732 if (table->table[i].type == DECTREE_TABLE_LINK) { 733 return decode_insns_tablewalk(insn, table->table[i].table_link, 734 encoding); 735 } else if (table->table[i].type == DECTREE_SUBINSNS) { 736 a = get_insn_a(encoding); 737 b = get_insn_b(encoding); 738 b = decode_subinsn_tablewalk(insn, table->table[i].table_link_b, b); 739 a = decode_subinsn_tablewalk(insn + 1, table->table[i].table_link, a); 740 if ((a == 0) || (b == 0)) { 741 return 0; 742 } 743 return 2; 744 } else if (table->table[i].type == DECTREE_TERMINAL) { 745 opc = table->table[i].opcode; 746 if ((encoding & decode_itable[opc].mask) != decode_itable[opc].match) { 747 if ((encoding & decode_legacy_itable[opc].mask) != 748 decode_legacy_itable[opc].match) { 749 return 0; 750 } 751 } 752 decode_op(insn, opc, encoding); 753 return 1; 754 } else if (table->table[i].type == DECTREE_EXTSPACE) { 755 /* 756 * For now, HVX will be the only coproc 757 */ 758 return decode_insns_tablewalk(insn, ext_trees[EXT_IDX_mmvec], encoding); 759 } else { 760 return 0; 761 } 762 } 763 764 static unsigned int 765 decode_insns(Insn *insn, uint32_t encoding) 766 { 767 const DectreeTable *table; 768 if (parse_bits(encoding) != 0) { 769 /* Start with PP table - 32 bit instructions */ 770 table = &dectree_table_DECODE_ROOT_32; 771 } else { 772 /* start with EE table - duplex instructions */ 773 table = &dectree_table_DECODE_ROOT_EE; 774 } 775 return decode_insns_tablewalk(insn, table, encoding); 776 } 777 778 static void decode_add_endloop_insn(Insn *insn, int loopnum) 779 { 780 if (loopnum == 10) { 781 insn->opcode = J2_endloop01; 782 insn->generate = opcode_genptr[J2_endloop01]; 783 } else if (loopnum == 1) { 784 insn->opcode = J2_endloop1; 785 insn->generate = opcode_genptr[J2_endloop1]; 786 } else if (loopnum == 0) { 787 insn->opcode = J2_endloop0; 788 insn->generate = opcode_genptr[J2_endloop0]; 789 } else { 790 g_assert_not_reached(); 791 } 792 } 793 794 static bool decode_parsebits_is_loopend(uint32_t encoding32) 795 { 796 uint32_t bits = parse_bits(encoding32); 797 return bits == 0x2; 798 } 799 800 static void 801 decode_set_slot_number(Packet *pkt) 802 { 803 int slot; 804 int i; 805 bool hit_mem_insn = false; 806 bool hit_duplex = false; 807 bool slot0_found = false; 808 bool slot1_found = false; 809 int slot1_iidx = 0; 810 811 /* 812 * The slots are encoded in reverse order 813 * For each instruction, count down until you find a suitable slot 814 */ 815 for (i = 0, slot = 3; i < pkt->num_insns; i++) { 816 SlotMask valid_slots = get_valid_slots(pkt, i); 817 818 while (!(valid_slots & (1 << slot))) { 819 slot--; 820 } 821 pkt->insn[i].slot = slot; 822 if (slot) { 823 /* I've assigned the slot, now decrement it for the next insn */ 824 slot--; 825 } 826 } 827 828 /* Fix the exceptions - mem insns to slot 0,1 */ 829 for (i = pkt->num_insns - 1; i >= 0; i--) { 830 /* First memory instruction always goes to slot 0 */ 831 if ((GET_ATTRIB(pkt->insn[i].opcode, A_MEMLIKE) || 832 GET_ATTRIB(pkt->insn[i].opcode, A_MEMLIKE_PACKET_RULES)) && 833 !hit_mem_insn) { 834 hit_mem_insn = true; 835 pkt->insn[i].slot = 0; 836 continue; 837 } 838 839 /* Next memory instruction always goes to slot 1 */ 840 if ((GET_ATTRIB(pkt->insn[i].opcode, A_MEMLIKE) || 841 GET_ATTRIB(pkt->insn[i].opcode, A_MEMLIKE_PACKET_RULES)) && 842 hit_mem_insn) { 843 pkt->insn[i].slot = 1; 844 } 845 } 846 847 /* Fix the exceptions - duplex always slot 0,1 */ 848 for (i = pkt->num_insns - 1; i >= 0; i--) { 849 /* First subinsn always goes to slot 0 */ 850 if (GET_ATTRIB(pkt->insn[i].opcode, A_SUBINSN) && !hit_duplex) { 851 hit_duplex = true; 852 pkt->insn[i].slot = 0; 853 continue; 854 } 855 856 /* Next subinsn always goes to slot 1 */ 857 if (GET_ATTRIB(pkt->insn[i].opcode, A_SUBINSN) && hit_duplex) { 858 pkt->insn[i].slot = 1; 859 } 860 } 861 862 /* Fix the exceptions - slot 1 is never empty, always aligns to slot 0 */ 863 for (i = pkt->num_insns - 1; i >= 0; i--) { 864 /* Is slot0 used? */ 865 if (pkt->insn[i].slot == 0) { 866 bool is_endloop = (pkt->insn[i].opcode == J2_endloop01); 867 is_endloop |= (pkt->insn[i].opcode == J2_endloop0); 868 is_endloop |= (pkt->insn[i].opcode == J2_endloop1); 869 870 /* 871 * Make sure it's not endloop since, we're overloading 872 * slot0 for endloop 873 */ 874 if (!is_endloop) { 875 slot0_found = true; 876 } 877 } 878 /* Is slot1 used? */ 879 if (pkt->insn[i].slot == 1) { 880 slot1_found = true; 881 slot1_iidx = i; 882 } 883 } 884 /* Is slot0 empty and slot1 used? */ 885 if ((!slot0_found) && slot1_found) { 886 /* Then push it to slot0 */ 887 pkt->insn[slot1_iidx].slot = 0; 888 } 889 } 890 891 /* 892 * decode_packet 893 * Decodes packet with given words 894 * Returns 0 on insufficient words, 895 * or number of words used on success 896 */ 897 898 int decode_packet(int max_words, const uint32_t *words, Packet *pkt, 899 bool disas_only) 900 { 901 int num_insns = 0; 902 int words_read = 0; 903 bool end_of_packet = false; 904 int new_insns = 0; 905 int i; 906 uint32_t encoding32; 907 908 /* Initialize */ 909 memset(pkt, 0, sizeof(*pkt)); 910 /* Try to build packet */ 911 while (!end_of_packet && (words_read < max_words)) { 912 encoding32 = words[words_read]; 913 end_of_packet = is_packet_end(encoding32); 914 new_insns = decode_insns(&pkt->insn[num_insns], encoding32); 915 g_assert(new_insns > 0); 916 /* 917 * If we saw an extender, mark next word extended so immediate 918 * decode works 919 */ 920 if (pkt->insn[num_insns].opcode == A4_ext) { 921 pkt->insn[num_insns + 1].extension_valid = true; 922 } 923 num_insns += new_insns; 924 words_read++; 925 } 926 927 pkt->num_insns = num_insns; 928 if (!end_of_packet) { 929 /* Ran out of words! */ 930 return 0; 931 } 932 pkt->encod_pkt_size_in_bytes = words_read * 4; 933 pkt->pkt_has_hvx = false; 934 for (i = 0; i < num_insns; i++) { 935 pkt->pkt_has_hvx |= 936 GET_ATTRIB(pkt->insn[i].opcode, A_CVI); 937 } 938 939 /* 940 * Check for :endloop in the parse bits 941 * Section 10.6 of the Programmer's Reference describes the encoding 942 * The end of hardware loop 0 can be encoded with 2 words 943 * The end of hardware loop 1 needs 3 words 944 */ 945 if ((words_read == 2) && (decode_parsebits_is_loopend(words[0]))) { 946 decode_add_endloop_insn(&pkt->insn[pkt->num_insns++], 0); 947 } 948 if (words_read >= 3) { 949 bool has_loop0, has_loop1; 950 has_loop0 = decode_parsebits_is_loopend(words[0]); 951 has_loop1 = decode_parsebits_is_loopend(words[1]); 952 if (has_loop0 && has_loop1) { 953 decode_add_endloop_insn(&pkt->insn[pkt->num_insns++], 10); 954 } else if (has_loop1) { 955 decode_add_endloop_insn(&pkt->insn[pkt->num_insns++], 1); 956 } else if (has_loop0) { 957 decode_add_endloop_insn(&pkt->insn[pkt->num_insns++], 0); 958 } 959 } 960 961 decode_apply_extenders(pkt); 962 if (!disas_only) { 963 decode_remove_extenders(pkt); 964 } 965 decode_set_slot_number(pkt); 966 decode_fill_newvalue_regno(pkt); 967 968 if (pkt->pkt_has_hvx) { 969 mmvec_ext_decode_checks(pkt, disas_only); 970 } 971 972 if (!disas_only) { 973 decode_shuffle_for_execution(pkt); 974 decode_split_cmpjump(pkt); 975 decode_set_insn_attr_fields(pkt); 976 } 977 978 return words_read; 979 } 980 981 /* Used for "-d in_asm" logging */ 982 int disassemble_hexagon(uint32_t *words, int nwords, bfd_vma pc, 983 GString *buf) 984 { 985 Packet pkt; 986 987 if (decode_packet(nwords, words, &pkt, true) > 0) { 988 snprint_a_pkt_disas(buf, &pkt, words, pc); 989 return pkt.encod_pkt_size_in_bytes; 990 } else { 991 g_string_assign(buf, "<invalid>"); 992 return 0; 993 } 994 } 995