1/* 2 Copyright (C) Intel Corp. 2006. All Rights Reserved. 3 Intel funded Tungsten Graphics to 4 develop this 3D driver. 5 6 Permission is hereby granted, free of charge, to any person obtaining 7 a copy of this software and associated documentation files (the 8 "Software"), to deal in the Software without restriction, including 9 without limitation the rights to use, copy, modify, merge, publish, 10 distribute, sublicense, and/or sell copies of the Software, and to 11 permit persons to whom the Software is furnished to do so, subject to 12 the following conditions: 13 14 The above copyright notice and this permission notice (including the 15 next paragraph) shall be included in all copies or substantial 16 portions of the Software. 17 18 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, 19 EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF 20 MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. 21 IN NO EVENT SHALL THE COPYRIGHT OWNER(S) AND/OR ITS SUPPLIERS BE 22 LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION 23 OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION 24 WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. 25 26 **********************************************************************/ 27 /* 28 * Authors: 29 * Keith Whitwell <keithw@vmware.com> 30 */ 31 32 33#include "brw_eu_defines.h" 34#include "brw_eu.h" 35#include "brw_shader.h" 36#include "dev/gen_debug.h" 37 38#include "util/ralloc.h" 39 40/* Returns a conditional modifier that negates the condition. */ 41enum brw_conditional_mod 42brw_negate_cmod(uint32_t cmod) 43{ 44 switch (cmod) { 45 case BRW_CONDITIONAL_Z: 46 return BRW_CONDITIONAL_NZ; 47 case BRW_CONDITIONAL_NZ: 48 return BRW_CONDITIONAL_Z; 49 case BRW_CONDITIONAL_G: 50 return BRW_CONDITIONAL_LE; 51 case BRW_CONDITIONAL_GE: 52 return BRW_CONDITIONAL_L; 53 case BRW_CONDITIONAL_L: 54 return BRW_CONDITIONAL_GE; 55 case BRW_CONDITIONAL_LE: 56 return BRW_CONDITIONAL_G; 57 default: 58 return ~0; 59 } 60} 61 62/* Returns the corresponding conditional mod for swapping src0 and 63 * src1 in e.g. CMP. 64 */ 65enum brw_conditional_mod 66brw_swap_cmod(uint32_t cmod) 67{ 68 switch (cmod) { 69 case BRW_CONDITIONAL_Z: 70 case BRW_CONDITIONAL_NZ: 71 return cmod; 72 case BRW_CONDITIONAL_G: 73 return BRW_CONDITIONAL_L; 74 case BRW_CONDITIONAL_GE: 75 return BRW_CONDITIONAL_LE; 76 case BRW_CONDITIONAL_L: 77 return BRW_CONDITIONAL_G; 78 case BRW_CONDITIONAL_LE: 79 return BRW_CONDITIONAL_GE; 80 default: 81 return BRW_CONDITIONAL_NONE; 82 } 83} 84 85/** 86 * Get the least significant bit offset of the i+1-th component of immediate 87 * type \p type. For \p i equal to the two's complement of j, return the 88 * offset of the j-th component starting from the end of the vector. For 89 * scalar register types return zero. 90 */ 91static unsigned 92imm_shift(enum brw_reg_type type, unsigned i) 93{ 94 assert(type != BRW_REGISTER_TYPE_UV && type != BRW_REGISTER_TYPE_V && 95 "Not implemented."); 96 97 if (type == BRW_REGISTER_TYPE_VF) 98 return 8 * (i & 3); 99 else 100 return 0; 101} 102 103/** 104 * Swizzle an arbitrary immediate \p x of the given type according to the 105 * permutation specified as \p swz. 106 */ 107uint32_t 108brw_swizzle_immediate(enum brw_reg_type type, uint32_t x, unsigned swz) 109{ 110 if (imm_shift(type, 1)) { 111 const unsigned n = 32 / imm_shift(type, 1); 112 uint32_t y = 0; 113 114 for (unsigned i = 0; i < n; i++) { 115 /* Shift the specified component all the way to the right and left to 116 * discard any undesired L/MSBs, then shift it right into component i. 117 */ 118 y |= x >> imm_shift(type, (i & ~3) + BRW_GET_SWZ(swz, i & 3)) 119 << imm_shift(type, ~0u) 120 >> imm_shift(type, ~0u - i); 121 } 122 123 return y; 124 } else { 125 return x; 126 } 127} 128 129unsigned 130brw_get_default_exec_size(struct brw_codegen *p) 131{ 132 return p->current->exec_size; 133} 134 135unsigned 136brw_get_default_group(struct brw_codegen *p) 137{ 138 return p->current->group; 139} 140 141unsigned 142brw_get_default_access_mode(struct brw_codegen *p) 143{ 144 return p->current->access_mode; 145} 146 147void 148brw_set_default_exec_size(struct brw_codegen *p, unsigned value) 149{ 150 p->current->exec_size = value; 151} 152 153void brw_set_default_predicate_control( struct brw_codegen *p, unsigned pc ) 154{ 155 p->current->predicate = pc; 156} 157 158void brw_set_default_predicate_inverse(struct brw_codegen *p, bool predicate_inverse) 159{ 160 p->current->pred_inv = predicate_inverse; 161} 162 163void brw_set_default_flag_reg(struct brw_codegen *p, int reg, int subreg) 164{ 165 assert(subreg < 2); 166 p->current->flag_subreg = reg * 2 + subreg; 167} 168 169void brw_set_default_access_mode( struct brw_codegen *p, unsigned access_mode ) 170{ 171 p->current->access_mode = access_mode; 172} 173 174void 175brw_set_default_compression_control(struct brw_codegen *p, 176 enum brw_compression compression_control) 177{ 178 switch (compression_control) { 179 case BRW_COMPRESSION_NONE: 180 /* This is the "use the first set of bits of dmask/vmask/arf 181 * according to execsize" option. 182 */ 183 p->current->group = 0; 184 break; 185 case BRW_COMPRESSION_2NDHALF: 186 /* For SIMD8, this is "use the second set of 8 bits." */ 187 p->current->group = 8; 188 break; 189 case BRW_COMPRESSION_COMPRESSED: 190 /* For SIMD16 instruction compression, use the first set of 16 bits 191 * since we don't do SIMD32 dispatch. 192 */ 193 p->current->group = 0; 194 break; 195 default: 196 unreachable("not reached"); 197 } 198 199 if (p->devinfo->gen <= 6) { 200 p->current->compressed = 201 (compression_control == BRW_COMPRESSION_COMPRESSED); 202 } 203} 204 205/** 206 * Enable or disable instruction compression on the given instruction leaving 207 * the currently selected channel enable group untouched. 208 */ 209void 210brw_inst_set_compression(const struct gen_device_info *devinfo, 211 brw_inst *inst, bool on) 212{ 213 if (devinfo->gen >= 6) { 214 /* No-op, the EU will figure out for us whether the instruction needs to 215 * be compressed. 216 */ 217 } else { 218 /* The channel group and compression controls are non-orthogonal, there 219 * are two possible representations for uncompressed instructions and we 220 * may need to preserve the current one to avoid changing the selected 221 * channel group inadvertently. 222 */ 223 if (on) 224 brw_inst_set_qtr_control(devinfo, inst, BRW_COMPRESSION_COMPRESSED); 225 else if (brw_inst_qtr_control(devinfo, inst) 226 == BRW_COMPRESSION_COMPRESSED) 227 brw_inst_set_qtr_control(devinfo, inst, BRW_COMPRESSION_NONE); 228 } 229} 230 231void 232brw_set_default_compression(struct brw_codegen *p, bool on) 233{ 234 p->current->compressed = on; 235} 236 237/** 238 * Apply the range of channel enable signals given by 239 * [group, group + exec_size) to the instruction passed as argument. 240 */ 241void 242brw_inst_set_group(const struct gen_device_info *devinfo, 243 brw_inst *inst, unsigned group) 244{ 245 if (devinfo->gen >= 7) { 246 assert(group % 4 == 0 && group < 32); 247 brw_inst_set_qtr_control(devinfo, inst, group / 8); 248 brw_inst_set_nib_control(devinfo, inst, (group / 4) % 2); 249 250 } else if (devinfo->gen == 6) { 251 assert(group % 8 == 0 && group < 32); 252 brw_inst_set_qtr_control(devinfo, inst, group / 8); 253 254 } else { 255 assert(group % 8 == 0 && group < 16); 256 /* The channel group and compression controls are non-orthogonal, there 257 * are two possible representations for group zero and we may need to 258 * preserve the current one to avoid changing the selected compression 259 * enable inadvertently. 260 */ 261 if (group == 8) 262 brw_inst_set_qtr_control(devinfo, inst, BRW_COMPRESSION_2NDHALF); 263 else if (brw_inst_qtr_control(devinfo, inst) == BRW_COMPRESSION_2NDHALF) 264 brw_inst_set_qtr_control(devinfo, inst, BRW_COMPRESSION_NONE); 265 } 266} 267 268void 269brw_set_default_group(struct brw_codegen *p, unsigned group) 270{ 271 p->current->group = group; 272} 273 274void brw_set_default_mask_control( struct brw_codegen *p, unsigned value ) 275{ 276 p->current->mask_control = value; 277} 278 279void brw_set_default_saturate( struct brw_codegen *p, bool enable ) 280{ 281 p->current->saturate = enable; 282} 283 284void brw_set_default_acc_write_control(struct brw_codegen *p, unsigned value) 285{ 286 p->current->acc_wr_control = value; 287} 288 289void brw_push_insn_state( struct brw_codegen *p ) 290{ 291 assert(p->current != &p->stack[BRW_EU_MAX_INSN_STACK-1]); 292 *(p->current + 1) = *p->current; 293 p->current++; 294} 295 296void brw_pop_insn_state( struct brw_codegen *p ) 297{ 298 assert(p->current != p->stack); 299 p->current--; 300} 301 302 303/*********************************************************************** 304 */ 305void 306brw_init_codegen(const struct gen_device_info *devinfo, 307 struct brw_codegen *p, void *mem_ctx) 308{ 309 memset(p, 0, sizeof(*p)); 310 311 p->devinfo = devinfo; 312 p->automatic_exec_sizes = true; 313 /* 314 * Set the initial instruction store array size to 1024, if found that 315 * isn't enough, then it will double the store size at brw_next_insn() 316 * until out of memory. 317 */ 318 p->store_size = 1024; 319 p->store = rzalloc_array(mem_ctx, brw_inst, p->store_size); 320 p->nr_insn = 0; 321 p->current = p->stack; 322 memset(p->current, 0, sizeof(p->current[0])); 323 324 p->mem_ctx = mem_ctx; 325 326 /* Some defaults? 327 */ 328 brw_set_default_exec_size(p, BRW_EXECUTE_8); 329 brw_set_default_mask_control(p, BRW_MASK_ENABLE); /* what does this do? */ 330 brw_set_default_saturate(p, 0); 331 brw_set_default_compression_control(p, BRW_COMPRESSION_NONE); 332 333 /* Set up control flow stack */ 334 p->if_stack_depth = 0; 335 p->if_stack_array_size = 16; 336 p->if_stack = rzalloc_array(mem_ctx, int, p->if_stack_array_size); 337 338 p->loop_stack_depth = 0; 339 p->loop_stack_array_size = 16; 340 p->loop_stack = rzalloc_array(mem_ctx, int, p->loop_stack_array_size); 341 p->if_depth_in_loop = rzalloc_array(mem_ctx, int, p->loop_stack_array_size); 342} 343 344 345const unsigned *brw_get_program( struct brw_codegen *p, 346 unsigned *sz ) 347{ 348 *sz = p->next_insn_offset; 349 return (const unsigned *)p->store; 350} 351 352void 353brw_disassemble(const struct gen_device_info *devinfo, 354 const void *assembly, int start, int end, FILE *out) 355{ 356 bool dump_hex = (INTEL_DEBUG & DEBUG_HEX) != 0; 357 358 for (int offset = start; offset < end;) { 359 const brw_inst *insn = assembly + offset; 360 brw_inst uncompacted; 361 bool compacted = brw_inst_cmpt_control(devinfo, insn); 362 if (0) 363 fprintf(out, "0x%08x: ", offset); 364 365 if (compacted) { 366 brw_compact_inst *compacted = (void *)insn; 367 if (dump_hex) { 368 unsigned char * insn_ptr = ((unsigned char *)&insn[0]); 369 const unsigned int blank_spaces = 24; 370 for (int i = 0 ; i < 8; i = i + 4) { 371 fprintf(out, "%02x %02x %02x %02x ", 372 insn_ptr[i], 373 insn_ptr[i + 1], 374 insn_ptr[i + 2], 375 insn_ptr[i + 3]); 376 } 377 /* Make compacted instructions hex value output vertically aligned 378 * with uncompacted instructions hex value 379 */ 380 fprintf(out, "%*c", blank_spaces, ' '); 381 } 382 383 brw_uncompact_instruction(devinfo, &uncompacted, compacted); 384 insn = &uncompacted; 385 offset += 8; 386 } else { 387 if (dump_hex) { 388 unsigned char * insn_ptr = ((unsigned char *)&insn[0]); 389 for (int i = 0 ; i < 16; i = i + 4) { 390 fprintf(out, "%02x %02x %02x %02x ", 391 insn_ptr[i], 392 insn_ptr[i + 1], 393 insn_ptr[i + 2], 394 insn_ptr[i + 3]); 395 } 396 } 397 offset += 16; 398 } 399 400 brw_disassemble_inst(out, devinfo, insn, compacted); 401 } 402} 403 404enum gen { 405 GEN4 = (1 << 0), 406 GEN45 = (1 << 1), 407 GEN5 = (1 << 2), 408 GEN6 = (1 << 3), 409 GEN7 = (1 << 4), 410 GEN75 = (1 << 5), 411 GEN8 = (1 << 6), 412 GEN9 = (1 << 7), 413 GEN10 = (1 << 8), 414 GEN11 = (1 << 9), 415 GEN_ALL = ~0 416}; 417 418#define GEN_LT(gen) ((gen) - 1) 419#define GEN_GE(gen) (~GEN_LT(gen)) 420#define GEN_LE(gen) (GEN_LT(gen) | (gen)) 421 422static const struct opcode_desc opcode_10_descs[] = { 423 { .name = "dim", .nsrc = 1, .ndst = 1, .gens = GEN75 }, 424 { .name = "smov", .nsrc = 0, .ndst = 0, .gens = GEN_GE(GEN8) }, 425}; 426 427static const struct opcode_desc opcode_35_descs[] = { 428 { .name = "iff", .nsrc = 0, .ndst = 0, .gens = GEN_LE(GEN5) }, 429 { .name = "brc", .nsrc = 0, .ndst = 0, .gens = GEN_GE(GEN7) }, 430}; 431 432static const struct opcode_desc opcode_38_descs[] = { 433 { .name = "do", .nsrc = 0, .ndst = 0, .gens = GEN_LE(GEN5) }, 434 { .name = "case", .nsrc = 0, .ndst = 0, .gens = GEN6 }, 435}; 436 437static const struct opcode_desc opcode_44_descs[] = { 438 { .name = "msave", .nsrc = 0, .ndst = 0, .gens = GEN_LE(GEN5) }, 439 { .name = "call", .nsrc = 0, .ndst = 0, .gens = GEN_GE(GEN6) }, 440}; 441 442static const struct opcode_desc opcode_45_descs[] = { 443 { .name = "mrest", .nsrc = 0, .ndst = 0, .gens = GEN_LE(GEN5) }, 444 { .name = "ret", .nsrc = 0, .ndst = 0, .gens = GEN_GE(GEN6) }, 445}; 446 447static const struct opcode_desc opcode_46_descs[] = { 448 { .name = "push", .nsrc = 0, .ndst = 0, .gens = GEN_LE(GEN5) }, 449 { .name = "fork", .nsrc = 0, .ndst = 0, .gens = GEN6 }, 450 { .name = "goto", .nsrc = 0, .ndst = 0, .gens = GEN_GE(GEN8) }, 451}; 452 453static const struct opcode_desc opcode_descs[128] = { 454 [BRW_OPCODE_ILLEGAL] = { 455 .name = "illegal", .nsrc = 0, .ndst = 0, .gens = GEN_ALL, 456 }, 457 [BRW_OPCODE_MOV] = { 458 .name = "mov", .nsrc = 1, .ndst = 1, .gens = GEN_ALL, 459 }, 460 [BRW_OPCODE_SEL] = { 461 .name = "sel", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 462 }, 463 [BRW_OPCODE_MOVI] = { 464 .name = "movi", .nsrc = 2, .ndst = 1, .gens = GEN_GE(GEN45), 465 }, 466 [BRW_OPCODE_NOT] = { 467 .name = "not", .nsrc = 1, .ndst = 1, .gens = GEN_ALL, 468 }, 469 [BRW_OPCODE_AND] = { 470 .name = "and", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 471 }, 472 [BRW_OPCODE_OR] = { 473 .name = "or", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 474 }, 475 [BRW_OPCODE_XOR] = { 476 .name = "xor", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 477 }, 478 [BRW_OPCODE_SHR] = { 479 .name = "shr", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 480 }, 481 [BRW_OPCODE_SHL] = { 482 .name = "shl", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 483 }, 484 [10] = { 485 .table = opcode_10_descs, .size = ARRAY_SIZE(opcode_10_descs), 486 }, 487 /* Reserved - 11 */ 488 [BRW_OPCODE_ASR] = { 489 .name = "asr", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 490 }, 491 /* Reserved - 13-15 */ 492 [BRW_OPCODE_CMP] = { 493 .name = "cmp", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 494 }, 495 [BRW_OPCODE_CMPN] = { 496 .name = "cmpn", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 497 }, 498 [BRW_OPCODE_CSEL] = { 499 .name = "csel", .nsrc = 3, .ndst = 1, .gens = GEN_GE(GEN8), 500 }, 501 [BRW_OPCODE_F32TO16] = { 502 .name = "f32to16", .nsrc = 1, .ndst = 1, .gens = GEN7 | GEN75, 503 }, 504 [BRW_OPCODE_F16TO32] = { 505 .name = "f16to32", .nsrc = 1, .ndst = 1, .gens = GEN7 | GEN75, 506 }, 507 /* Reserved - 21-22 */ 508 [BRW_OPCODE_BFREV] = { 509 .name = "bfrev", .nsrc = 1, .ndst = 1, .gens = GEN_GE(GEN7), 510 }, 511 [BRW_OPCODE_BFE] = { 512 .name = "bfe", .nsrc = 3, .ndst = 1, .gens = GEN_GE(GEN7), 513 }, 514 [BRW_OPCODE_BFI1] = { 515 .name = "bfi1", .nsrc = 2, .ndst = 1, .gens = GEN_GE(GEN7), 516 }, 517 [BRW_OPCODE_BFI2] = { 518 .name = "bfi2", .nsrc = 3, .ndst = 1, .gens = GEN_GE(GEN7), 519 }, 520 /* Reserved - 27-31 */ 521 [BRW_OPCODE_JMPI] = { 522 .name = "jmpi", .nsrc = 0, .ndst = 0, .gens = GEN_ALL, 523 }, 524 [33] = { 525 .name = "brd", .nsrc = 0, .ndst = 0, .gens = GEN_GE(GEN7), 526 }, 527 [BRW_OPCODE_IF] = { 528 .name = "if", .nsrc = 0, .ndst = 0, .gens = GEN_ALL, 529 }, 530 [35] = { 531 .table = opcode_35_descs, .size = ARRAY_SIZE(opcode_35_descs), 532 }, 533 [BRW_OPCODE_ELSE] = { 534 .name = "else", .nsrc = 0, .ndst = 0, .gens = GEN_ALL, 535 }, 536 [BRW_OPCODE_ENDIF] = { 537 .name = "endif", .nsrc = 0, .ndst = 0, .gens = GEN_ALL, 538 }, 539 [38] = { 540 .table = opcode_38_descs, .size = ARRAY_SIZE(opcode_38_descs), 541 }, 542 [BRW_OPCODE_WHILE] = { 543 .name = "while", .nsrc = 0, .ndst = 0, .gens = GEN_ALL, 544 }, 545 [BRW_OPCODE_BREAK] = { 546 .name = "break", .nsrc = 0, .ndst = 0, .gens = GEN_ALL, 547 }, 548 [BRW_OPCODE_CONTINUE] = { 549 .name = "cont", .nsrc = 0, .ndst = 0, .gens = GEN_ALL, 550 }, 551 [BRW_OPCODE_HALT] = { 552 .name = "halt", .nsrc = 0, .ndst = 0, .gens = GEN_ALL, 553 }, 554 [43] = { 555 .name = "calla", .nsrc = 0, .ndst = 0, .gens = GEN_GE(GEN75), 556 }, 557 [44] = { 558 .table = opcode_44_descs, .size = ARRAY_SIZE(opcode_44_descs), 559 }, 560 [45] = { 561 .table = opcode_45_descs, .size = ARRAY_SIZE(opcode_45_descs), 562 }, 563 [46] = { 564 .table = opcode_46_descs, .size = ARRAY_SIZE(opcode_46_descs), 565 }, 566 [47] = { 567 .name = "pop", .nsrc = 2, .ndst = 0, .gens = GEN_LE(GEN5), 568 }, 569 [BRW_OPCODE_WAIT] = { 570 .name = "wait", .nsrc = 1, .ndst = 0, .gens = GEN_ALL, 571 }, 572 [BRW_OPCODE_SEND] = { 573 .name = "send", .nsrc = 1, .ndst = 1, .gens = GEN_ALL, 574 }, 575 [BRW_OPCODE_SENDC] = { 576 .name = "sendc", .nsrc = 1, .ndst = 1, .gens = GEN_ALL, 577 }, 578 [BRW_OPCODE_SENDS] = { 579 .name = "sends", .nsrc = 2, .ndst = 1, .gens = GEN_GE(GEN9), 580 }, 581 [BRW_OPCODE_SENDSC] = { 582 .name = "sendsc", .nsrc = 2, .ndst = 1, .gens = GEN_GE(GEN9), 583 }, 584 /* Reserved 53-55 */ 585 [BRW_OPCODE_MATH] = { 586 .name = "math", .nsrc = 2, .ndst = 1, .gens = GEN_GE(GEN6), 587 }, 588 /* Reserved 57-63 */ 589 [BRW_OPCODE_ADD] = { 590 .name = "add", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 591 }, 592 [BRW_OPCODE_MUL] = { 593 .name = "mul", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 594 }, 595 [BRW_OPCODE_AVG] = { 596 .name = "avg", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 597 }, 598 [BRW_OPCODE_FRC] = { 599 .name = "frc", .nsrc = 1, .ndst = 1, .gens = GEN_ALL, 600 }, 601 [BRW_OPCODE_RNDU] = { 602 .name = "rndu", .nsrc = 1, .ndst = 1, .gens = GEN_ALL, 603 }, 604 [BRW_OPCODE_RNDD] = { 605 .name = "rndd", .nsrc = 1, .ndst = 1, .gens = GEN_ALL, 606 }, 607 [BRW_OPCODE_RNDE] = { 608 .name = "rnde", .nsrc = 1, .ndst = 1, .gens = GEN_ALL, 609 }, 610 [BRW_OPCODE_RNDZ] = { 611 .name = "rndz", .nsrc = 1, .ndst = 1, .gens = GEN_ALL, 612 }, 613 [BRW_OPCODE_MAC] = { 614 .name = "mac", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 615 }, 616 [BRW_OPCODE_MACH] = { 617 .name = "mach", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 618 }, 619 [BRW_OPCODE_LZD] = { 620 .name = "lzd", .nsrc = 1, .ndst = 1, .gens = GEN_ALL, 621 }, 622 [BRW_OPCODE_FBH] = { 623 .name = "fbh", .nsrc = 1, .ndst = 1, .gens = GEN_GE(GEN7), 624 }, 625 [BRW_OPCODE_FBL] = { 626 .name = "fbl", .nsrc = 1, .ndst = 1, .gens = GEN_GE(GEN7), 627 }, 628 [BRW_OPCODE_CBIT] = { 629 .name = "cbit", .nsrc = 1, .ndst = 1, .gens = GEN_GE(GEN7), 630 }, 631 [BRW_OPCODE_ADDC] = { 632 .name = "addc", .nsrc = 2, .ndst = 1, .gens = GEN_GE(GEN7), 633 }, 634 [BRW_OPCODE_SUBB] = { 635 .name = "subb", .nsrc = 2, .ndst = 1, .gens = GEN_GE(GEN7), 636 }, 637 [BRW_OPCODE_SAD2] = { 638 .name = "sad2", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 639 }, 640 [BRW_OPCODE_SADA2] = { 641 .name = "sada2", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 642 }, 643 /* Reserved 82-83 */ 644 [BRW_OPCODE_DP4] = { 645 .name = "dp4", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 646 }, 647 [BRW_OPCODE_DPH] = { 648 .name = "dph", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 649 }, 650 [BRW_OPCODE_DP3] = { 651 .name = "dp3", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 652 }, 653 [BRW_OPCODE_DP2] = { 654 .name = "dp2", .nsrc = 2, .ndst = 1, .gens = GEN_ALL, 655 }, 656 /* Reserved 88 */ 657 [BRW_OPCODE_LINE] = { 658 .name = "line", .nsrc = 2, .ndst = 1, .gens = GEN_LE(GEN10), 659 }, 660 [BRW_OPCODE_PLN] = { 661 .name = "pln", .nsrc = 2, .ndst = 1, .gens = GEN_GE(GEN45) & GEN_LE(GEN10), 662 }, 663 [BRW_OPCODE_MAD] = { 664 .name = "mad", .nsrc = 3, .ndst = 1, .gens = GEN_GE(GEN6), 665 }, 666 [BRW_OPCODE_LRP] = { 667 .name = "lrp", .nsrc = 3, .ndst = 1, .gens = GEN_GE(GEN6) & GEN_LE(GEN10), 668 }, 669 [93] = { 670 .name = "madm", .nsrc = 3, .ndst = 1, .gens = GEN_GE(GEN8), 671 }, 672 /* Reserved 94-124 */ 673 [BRW_OPCODE_NENOP] = { 674 .name = "nenop", .nsrc = 0, .ndst = 0, .gens = GEN45, 675 }, 676 [BRW_OPCODE_NOP] = { 677 .name = "nop", .nsrc = 0, .ndst = 0, .gens = GEN_ALL, 678 }, 679}; 680 681static enum gen 682gen_from_devinfo(const struct gen_device_info *devinfo) 683{ 684 switch (devinfo->gen) { 685 case 4: return devinfo->is_g4x ? GEN45 : GEN4; 686 case 5: return GEN5; 687 case 6: return GEN6; 688 case 7: return devinfo->is_haswell ? GEN75 : GEN7; 689 case 8: return GEN8; 690 case 9: return GEN9; 691 case 10: return GEN10; 692 case 11: return GEN11; 693 default: 694 unreachable("not reached"); 695 } 696} 697 698/* Return the matching opcode_desc for the specified opcode number and 699 * hardware generation, or NULL if the opcode is not supported by the device. 700 */ 701const struct opcode_desc * 702brw_opcode_desc(const struct gen_device_info *devinfo, enum opcode opcode) 703{ 704 if (opcode >= ARRAY_SIZE(opcode_descs)) 705 return NULL; 706 707 enum gen gen = gen_from_devinfo(devinfo); 708 if (opcode_descs[opcode].gens != 0) { 709 if ((opcode_descs[opcode].gens & gen) != 0) { 710 return &opcode_descs[opcode]; 711 } 712 } else if (opcode_descs[opcode].table != NULL) { 713 const struct opcode_desc *table = opcode_descs[opcode].table; 714 for (unsigned i = 0; i < opcode_descs[opcode].size; i++) { 715 if ((table[i].gens & gen) != 0) { 716 return &table[i]; 717 } 718 } 719 } 720 return NULL; 721} 722