fp.isa revision 13978:896f9f7a1d16
1// -*- mode:c++ -*- 2 3// Copyright (c) 2010-2011, 2016-2019 ARM Limited 4// All rights reserved 5// 6// The license below extends only to copyright in the software and shall 7// not be construed as granting a license to any other intellectual 8// property including but not limited to intellectual property relating 9// to a hardware implementation of the functionality of the software 10// licensed hereunder. You may use the software subject to the license 11// terms below provided that you ensure that this notice is replicated 12// unmodified and in its entirety in all distributions of the software, 13// modified or unmodified, in source code or in binary form. 14// 15// Copyright (c) 2007-2008 The Florida State University 16// All rights reserved. 17// 18// Redistribution and use in source and binary forms, with or without 19// modification, are permitted provided that the following conditions are 20// met: redistributions of source code must retain the above copyright 21// notice, this list of conditions and the following disclaimer; 22// redistributions in binary form must reproduce the above copyright 23// notice, this list of conditions and the following disclaimer in the 24// documentation and/or other materials provided with the distribution; 25// neither the name of the copyright holders nor the names of its 26// contributors may be used to endorse or promote products derived from 27// this software without specific prior written permission. 28// 29// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 30// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 31// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR 32// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT 33// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 34// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT 35// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 36// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 37// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 38// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE 39// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 40// 41// Authors: Stephen Hines 42 43//////////////////////////////////////////////////////////////////// 44// 45// Floating Point operate instructions 46// 47 48output header {{ 49 50 template<template <typename T> class Base> 51 StaticInstPtr 52 newNeonMemInst(const unsigned size, 53 const ExtMachInst &machInst, 54 const RegIndex dest, const RegIndex ra, 55 const uint32_t imm, const unsigned extraMemFlags) 56 { 57 switch (size) { 58 case 0: 59 return new Base<uint8_t>(machInst, dest, ra, imm, extraMemFlags); 60 case 1: 61 return new Base<uint16_t>(machInst, dest, ra, imm, extraMemFlags); 62 case 2: 63 return new Base<uint32_t>(machInst, dest, ra, imm, extraMemFlags); 64 case 3: 65 return new Base<uint64_t>(machInst, dest, ra, imm, extraMemFlags); 66 default: 67 panic("Unrecognized width %d for Neon mem inst.\n", (1 << size)); 68 } 69 } 70 71 template<template <typename T> class Base> 72 StaticInstPtr 73 newNeonMixInst(const unsigned size, 74 const ExtMachInst &machInst, 75 const RegIndex dest, const RegIndex op1, 76 const uint32_t step) 77 { 78 switch (size) { 79 case 0: 80 return new Base<uint8_t>(machInst, dest, op1, step); 81 case 1: 82 return new Base<uint16_t>(machInst, dest, op1, step); 83 case 2: 84 return new Base<uint32_t>(machInst, dest, op1, step); 85 case 3: 86 return new Base<uint64_t>(machInst, dest, op1, step); 87 default: 88 panic("Unrecognized width %d for Neon mem inst.\n", (1 << size)); 89 } 90 } 91 92}}; 93 94let {{ 95 header_output = ''' 96 StaticInstPtr 97 decodeNeonMem(ExtMachInst machInst); 98 99 StaticInstPtr 100 decodeNeonData(ExtMachInst machInst); 101 ''' 102 103 decoder_output = ''' 104 StaticInstPtr 105 decodeNeonMem(ExtMachInst machInst) 106 { 107 const uint32_t b = bits(machInst, 11, 8); 108 const bool single = bits(machInst, 23); 109 const bool singleAll = single && (bits(b, 3, 2) == 3); 110 const bool load = bits(machInst, 21); 111 112 unsigned width = 0; 113 114 if (single) { 115 width = bits(b, 1, 0) + 1; 116 } else { 117 switch (bits(b, 3, 1)) { 118 case 0x0: width = 4; 119 break; 120 case 0x1: width = (b & 0x1) ? 2 : 1; 121 break; 122 case 0x2: width = 3; 123 break; 124 case 0x3: width = 1; 125 break; 126 case 0x4: width = 2; 127 break; 128 case 0x5: 129 if ((b & 0x1) == 0) { 130 width = 1; 131 break; 132 } 133 M5_FALLTHROUGH; 134 default: 135 return new Unknown(machInst); 136 } 137 } 138 assert(width > 0 && width <= 4); 139 140 const RegIndex rm = (RegIndex)(uint32_t)bits(machInst, 3, 0); 141 const RegIndex rn = (RegIndex)(uint32_t)bits(machInst, 19, 16); 142 const RegIndex vd = (RegIndex)(uint32_t)(bits(machInst, 15, 12) | 143 bits(machInst, 22) << 4); 144 const uint32_t type = bits(machInst, 11, 8); 145 uint32_t size = 0; 146 uint32_t align = TLB::MustBeOne; 147 unsigned inc = 1; 148 unsigned regs = 1; 149 unsigned lane = 0; 150 if (single) { 151 if (singleAll) { 152 size = bits(machInst, 7, 6); 153 bool t = bits(machInst, 5); 154 align = size | TLB::AllowUnaligned; 155 if (width == 1) { 156 regs = t ? 2 : 1; 157 inc = 1; 158 } else { 159 regs = width; 160 inc = t ? 2 : 1; 161 } 162 switch (width) { 163 case 1: 164 case 2: 165 if (bits(machInst, 4)) 166 align = size + width - 1; 167 break; 168 case 3: 169 break; 170 case 4: 171 if (size == 3) { 172 if (bits(machInst, 4) == 0) 173 return new Unknown(machInst); 174 size = 2; 175 align = 0x4; 176 } else if (size == 2) { 177 if (bits(machInst, 4)) 178 align = 0x3; 179 } else { 180 if (bits(machInst, 4)) 181 align = size + 2; 182 } 183 break; 184 } 185 } else { 186 size = bits(machInst, 11, 10); 187 align = size | TLB::AllowUnaligned; 188 regs = width; 189 unsigned indexAlign = bits(machInst, 7, 4); 190 // If width is 1, inc is always 1. That's overridden later. 191 switch (size) { 192 case 0: 193 inc = 1; 194 lane = bits(indexAlign, 3, 1); 195 break; 196 case 1: 197 inc = bits(indexAlign, 1) ? 2 : 1; 198 lane = bits(indexAlign, 3, 2); 199 break; 200 case 2: 201 inc = bits(indexAlign, 2) ? 2 : 1; 202 lane = bits(indexAlign, 3); 203 break; 204 } 205 // Override inc for width of 1. 206 if (width == 1) { 207 inc = 1; 208 } 209 switch (width) { 210 case 1: 211 switch (size) { 212 case 0: 213 break; 214 case 1: 215 if (bits(indexAlign, 0)) 216 align = 1; 217 break; 218 case 2: 219 if (bits(indexAlign, 1, 0)) 220 align = 2; 221 break; 222 } 223 break; 224 case 2: 225 if (bits(indexAlign, 0)) 226 align = size + 1; 227 break; 228 case 3: 229 break; 230 case 4: 231 switch (size) { 232 case 0: 233 case 1: 234 if (bits(indexAlign, 0)) 235 align = size + 2; 236 break; 237 case 2: 238 if (bits(indexAlign, 0)) 239 align = bits(indexAlign, 1, 0) + 2; 240 break; 241 } 242 break; 243 } 244 } 245 if (size == 0x3) { 246 return new Unknown(machInst); 247 } 248 } else { 249 size = bits(machInst, 7, 6); 250 align = bits(machInst, 5, 4); 251 if (align == 0) { 252 // @align wasn't specified, so alignment can be turned off. 253 align = size | TLB::AllowUnaligned; 254 } else { 255 align = align + 2; 256 } 257 switch (width) { 258 case 1: 259 switch (type) { 260 case 0x7: regs = 1; 261 break; 262 case 0xa: regs = 2; 263 break; 264 case 0x6: regs = 3; 265 break; 266 case 0x2: regs = 4; 267 break; 268 default: 269 return new Unknown(machInst); 270 } 271 break; 272 case 2: 273 // Regs doesn't behave exactly as it does in the manual 274 // because they loop over regs registers twice and we break 275 // it down in the macroop. 276 switch (type) { 277 case 0x8: regs = 2; inc = 1; 278 break; 279 case 0x9: regs = 2; inc = 2; 280 break; 281 case 0x3: regs = 4; inc = 2; 282 break; 283 default: 284 return new Unknown(machInst); 285 } 286 break; 287 case 3: 288 regs = 3; 289 switch (type) { 290 case 0x4: inc = 1; 291 break; 292 case 0x5: inc = 2;; 293 break; 294 default: 295 return new Unknown(machInst); 296 } 297 break; 298 case 4: 299 regs = 4; 300 switch (type) { 301 case 0: inc = 1; 302 break; 303 case 1: inc = 2; 304 break; 305 default: 306 return new Unknown(machInst); 307 } 308 break; 309 } 310 } 311 312 if (load) { 313 // Load instructions. 314 if (single) { 315 return new VldSingle(machInst, singleAll, width, rn, vd, 316 regs, inc, size, align, rm, lane); 317 } else { 318 return new VldMult(machInst, width, rn, vd, 319 regs, inc, size, align, rm); 320 } 321 } else { 322 // Store instructions. 323 if (single) { 324 if (singleAll) { 325 return new Unknown(machInst); 326 } else { 327 return new VstSingle(machInst, false, width, rn, vd, 328 regs, inc, size, align, rm, lane); 329 } 330 } else { 331 return new VstMult(machInst, width, rn, vd, 332 regs, inc, size, align, rm); 333 } 334 } 335 return new Unknown(machInst); 336 } 337 ''' 338 339 decoder_output += ''' 340 static StaticInstPtr 341 decodeNeonThreeRegistersSameLength(ExtMachInst machInst) 342 { 343 const bool u = THUMB ? bits(machInst, 28) : bits(machInst, 24); 344 const uint32_t opc = bits(machInst, 11, 8); 345 const bool o1 = bits(machInst, 4); 346 const uint32_t size = bits(machInst, 21, 20); 347 const IntRegIndex vd = 348 (IntRegIndex)(2 * (bits(machInst, 15, 12) | 349 (bits(machInst, 22) << 4))); 350 const IntRegIndex vn = 351 (IntRegIndex)(2 * (bits(machInst, 19, 16) | 352 (bits(machInst, 7) << 4))); 353 const IntRegIndex vm = 354 (IntRegIndex)(2 * (bits(machInst, 3, 0) | 355 (bits(machInst, 5) << 4))); 356 const bool q = bits(machInst, 6); 357 if (q && ((vd & 0x1) || (vn & 0x1) || (vm & 0x1))) 358 return new Unknown(machInst); 359 switch (opc) { 360 case 0x0: 361 if (o1) { 362 if (u) { 363 return decodeNeonUThreeReg<VqaddUD, VqaddUQ>( 364 q, size, machInst, vd, vn, vm); 365 } else { 366 return decodeNeonSThreeReg<VqaddSD, VqaddSQ>( 367 q, size, machInst, vd, vn, vm); 368 } 369 } else { 370 if (size == 3) 371 return new Unknown(machInst); 372 return decodeNeonUSThreeReg<VhaddD, VhaddQ>( 373 q, u, size, machInst, vd, vn, vm); 374 } 375 case 0x1: 376 if (!o1) { 377 return decodeNeonUSThreeReg<VrhaddD, VrhaddQ>( 378 q, u, size, machInst, vd, vn, vm); 379 } else { 380 if (u) { 381 switch (size) { 382 case 0: 383 if (q) { 384 return new VeorQ<uint64_t>(machInst, vd, vn, vm); 385 } else { 386 return new VeorD<uint64_t>(machInst, vd, vn, vm); 387 } 388 case 1: 389 if (q) { 390 return new VbslQ<uint64_t>(machInst, vd, vn, vm); 391 } else { 392 return new VbslD<uint64_t>(machInst, vd, vn, vm); 393 } 394 case 2: 395 if (q) { 396 return new VbitQ<uint64_t>(machInst, vd, vn, vm); 397 } else { 398 return new VbitD<uint64_t>(machInst, vd, vn, vm); 399 } 400 case 3: 401 if (q) { 402 return new VbifQ<uint64_t>(machInst, vd, vn, vm); 403 } else { 404 return new VbifD<uint64_t>(machInst, vd, vn, vm); 405 } 406 default: 407 M5_UNREACHABLE; 408 } 409 } else { 410 switch (size) { 411 case 0: 412 if (q) { 413 return new VandQ<uint64_t>(machInst, vd, vn, vm); 414 } else { 415 return new VandD<uint64_t>(machInst, vd, vn, vm); 416 } 417 case 1: 418 if (q) { 419 return new VbicQ<uint64_t>(machInst, vd, vn, vm); 420 } else { 421 return new VbicD<uint64_t>(machInst, vd, vn, vm); 422 } 423 case 2: 424 if (vn == vm) { 425 if (q) { 426 return new VmovQ<uint64_t>( 427 machInst, vd, vn, vm); 428 } else { 429 return new VmovD<uint64_t>( 430 machInst, vd, vn, vm); 431 } 432 } else { 433 if (q) { 434 return new VorrQ<uint64_t>( 435 machInst, vd, vn, vm); 436 } else { 437 return new VorrD<uint64_t>( 438 machInst, vd, vn, vm); 439 } 440 } 441 case 3: 442 if (q) { 443 return new VornQ<uint64_t>( 444 machInst, vd, vn, vm); 445 } else { 446 return new VornD<uint64_t>( 447 machInst, vd, vn, vm); 448 } 449 default: 450 M5_UNREACHABLE; 451 } 452 } 453 } 454 case 0x2: 455 if (o1) { 456 if (u) { 457 return decodeNeonUThreeReg<VqsubUD, VqsubUQ>( 458 q, size, machInst, vd, vn, vm); 459 } else { 460 return decodeNeonSThreeReg<VqsubSD, VqsubSQ>( 461 q, size, machInst, vd, vn, vm); 462 } 463 } else { 464 if (size == 3) 465 return new Unknown(machInst); 466 return decodeNeonUSThreeReg<VhsubD, VhsubQ>( 467 q, u, size, machInst, vd, vn, vm); 468 } 469 case 0x3: 470 if (o1) { 471 return decodeNeonUSThreeReg<VcgeD, VcgeQ>( 472 q, u, size, machInst, vd, vn, vm); 473 } else { 474 return decodeNeonUSThreeReg<VcgtD, VcgtQ>( 475 q, u, size, machInst, vd, vn, vm); 476 } 477 case 0x4: 478 if (o1) { 479 if (u) { 480 return decodeNeonUThreeReg<VqshlUD, VqshlUQ>( 481 q, size, machInst, vd, vm, vn); 482 } else { 483 return decodeNeonSThreeReg<VqshlSD, VqshlSQ>( 484 q, size, machInst, vd, vm, vn); 485 } 486 } else { 487 return decodeNeonUSThreeReg<VshlD, VshlQ>( 488 q, u, size, machInst, vd, vm, vn); 489 } 490 case 0x5: 491 if (o1) { 492 if (u) { 493 return decodeNeonUThreeReg<VqrshlUD, VqrshlUQ>( 494 q, size, machInst, vd, vm, vn); 495 } else { 496 return decodeNeonSThreeReg<VqrshlSD, VqrshlSQ>( 497 q, size, machInst, vd, vm, vn); 498 } 499 } else { 500 return decodeNeonUSThreeReg<VrshlD, VrshlQ>( 501 q, u, size, machInst, vd, vm, vn); 502 } 503 case 0x6: 504 if (o1) { 505 return decodeNeonUSThreeReg<VminD, VminQ>( 506 q, u, size, machInst, vd, vn, vm); 507 } else { 508 return decodeNeonUSThreeReg<VmaxD, VmaxQ>( 509 q, u, size, machInst, vd, vn, vm); 510 } 511 case 0x7: 512 if (o1) { 513 return decodeNeonUSThreeReg<VabaD, VabaQ>( 514 q, u, size, machInst, vd, vn, vm); 515 } else { 516 if (bits(machInst, 23) == 1) { 517 if (q) { 518 return new Unknown(machInst); 519 } else { 520 return decodeNeonUSThreeUSReg<Vabdl>( 521 u, size, machInst, vd, vn, vm); 522 } 523 } else { 524 return decodeNeonUSThreeReg<VabdD, VabdQ>( 525 q, u, size, machInst, vd, vn, vm); 526 } 527 } 528 case 0x8: 529 if (o1) { 530 if (u) { 531 return decodeNeonUThreeReg<VceqD, VceqQ>( 532 q, size, machInst, vd, vn, vm); 533 } else { 534 return decodeNeonUThreeReg<VtstD, VtstQ>( 535 q, size, machInst, vd, vn, vm); 536 } 537 } else { 538 if (u) { 539 return decodeNeonUThreeReg<NVsubD, NVsubQ>( 540 q, size, machInst, vd, vn, vm); 541 } else { 542 return decodeNeonUThreeReg<NVaddD, NVaddQ>( 543 q, size, machInst, vd, vn, vm); 544 } 545 } 546 case 0x9: 547 if (o1) { 548 if (u) { 549 return decodeNeonUThreeReg<NVmulpD, NVmulpQ>( 550 q, size, machInst, vd, vn, vm); 551 } else { 552 return decodeNeonSThreeReg<NVmulD, NVmulQ>( 553 q, size, machInst, vd, vn, vm); 554 } 555 } else { 556 if (u) { 557 return decodeNeonUSThreeReg<NVmlsD, NVmlsQ>( 558 q, u, size, machInst, vd, vn, vm); 559 } else { 560 return decodeNeonUSThreeReg<NVmlaD, NVmlaQ>( 561 q, u, size, machInst, vd, vn, vm); 562 } 563 } 564 case 0xa: 565 if (q) 566 return new Unknown(machInst); 567 if (o1) { 568 return decodeNeonUSThreeUSReg<VpminD>( 569 u, size, machInst, vd, vn, vm); 570 } else { 571 return decodeNeonUSThreeUSReg<VpmaxD>( 572 u, size, machInst, vd, vn, vm); 573 } 574 case 0xb: 575 if (o1) { 576 if (u || q) { 577 return new Unknown(machInst); 578 } else { 579 return decodeNeonUThreeUSReg<NVpaddD>( 580 size, machInst, vd, vn, vm); 581 } 582 } else { 583 if (u) { 584 return decodeNeonSThreeSReg<VqrdmulhD, VqrdmulhQ>( 585 q, size, machInst, vd, vn, vm); 586 } else { 587 return decodeNeonSThreeSReg<VqdmulhD, VqdmulhQ>( 588 q, size, machInst, vd, vn, vm); 589 } 590 } 591 case 0xc: 592 if (o1) { 593 if (!u) { 594 if (bits(size, 1) == 0) { 595 if (q) { 596 return new NVfmaQFp<float>(machInst, vd, vn, vm); 597 } else { 598 return new NVfmaDFp<float>(machInst, vd, vn, vm); 599 } 600 } else { 601 if (q) { 602 return new NVfmsQFp<float>(machInst, vd, vn, vm); 603 } else { 604 return new NVfmsDFp<float>(machInst, vd, vn, vm); 605 } 606 } 607 } 608 } else { 609 if (u) { 610 switch (size) { 611 case 0x0: 612 return new SHA256H(machInst, vd, vn, vm); 613 case 0x1: 614 return new SHA256H2(machInst, vd, vn, vm); 615 case 0x2: 616 return new SHA256SU1(machInst, vd, vn, vm); 617 case 0x3: 618 return new Unknown(machInst); 619 default: 620 M5_UNREACHABLE; 621 } 622 } else { 623 switch (size) { 624 case 0x0: 625 return new SHA1C(machInst, vd, vn, vm); 626 case 0x1: 627 return new SHA1P(machInst, vd, vn, vm); 628 case 0x2: 629 return new SHA1M(machInst, vd, vn, vm); 630 case 0x3: 631 return new SHA1SU0(machInst, vd, vn, vm); 632 default: 633 M5_UNREACHABLE; 634 } 635 } 636 } 637 return new Unknown(machInst); 638 case 0xd: 639 if (o1) { 640 if (u) { 641 if (bits(size, 1) == 0) { 642 if (q) { 643 return new NVmulQFp<float>(machInst, vd, vn, vm); 644 } else { 645 return new NVmulDFp<float>(machInst, vd, vn, vm); 646 } 647 } else { 648 return new Unknown(machInst); 649 } 650 } else { 651 if (bits(size, 1) == 0) { 652 if (q) { 653 return new NVmlaQFp<float>(machInst, vd, vn, vm); 654 } else { 655 return new NVmlaDFp<float>(machInst, vd, vn, vm); 656 } 657 } else { 658 if (q) { 659 return new NVmlsQFp<float>(machInst, vd, vn, vm); 660 } else { 661 return new NVmlsDFp<float>(machInst, vd, vn, vm); 662 } 663 } 664 } 665 } else { 666 if (u) { 667 if (bits(size, 1) == 0) { 668 if (q) { 669 return new VpaddQFp<float>(machInst, vd, vn, vm); 670 } else { 671 return new VpaddDFp<float>(machInst, vd, vn, vm); 672 } 673 } else { 674 if (q) { 675 return new VabdQFp<float>(machInst, vd, vn, vm); 676 } else { 677 return new VabdDFp<float>(machInst, vd, vn, vm); 678 } 679 } 680 } else { 681 if (bits(size, 1) == 0) { 682 if (q) { 683 return new VaddQFp<float>(machInst, vd, vn, vm); 684 } else { 685 return new VaddDFp<float>(machInst, vd, vn, vm); 686 } 687 } else { 688 if (q) { 689 return new VsubQFp<float>(machInst, vd, vn, vm); 690 } else { 691 return new VsubDFp<float>(machInst, vd, vn, vm); 692 } 693 } 694 } 695 } 696 case 0xe: 697 if (o1) { 698 if (u) { 699 if (bits(size, 1) == 0) { 700 if (q) { 701 return new VacgeQFp<float>(machInst, vd, vn, vm); 702 } else { 703 return new VacgeDFp<float>(machInst, vd, vn, vm); 704 } 705 } else { 706 if (q) { 707 return new VacgtQFp<float>(machInst, vd, vn, vm); 708 } else { 709 return new VacgtDFp<float>(machInst, vd, vn, vm); 710 } 711 } 712 } else { 713 return new Unknown(machInst); 714 } 715 } else { 716 if (u) { 717 if (bits(size, 1) == 0) { 718 if (q) { 719 return new VcgeQFp<float>(machInst, vd, vn, vm); 720 } else { 721 return new VcgeDFp<float>(machInst, vd, vn, vm); 722 } 723 } else { 724 if (q) { 725 return new VcgtQFp<float>(machInst, vd, vn, vm); 726 } else { 727 return new VcgtDFp<float>(machInst, vd, vn, vm); 728 } 729 } 730 } else { 731 if (bits(size, 1) == 0) { 732 if (q) { 733 return new VceqQFp<float>(machInst, vd, vn, vm); 734 } else { 735 return new VceqDFp<float>(machInst, vd, vn, vm); 736 } 737 } else { 738 return new Unknown(machInst); 739 } 740 } 741 } 742 case 0xf: 743 if (o1) { 744 if (u) { 745 if (bits(size, 1) == 0) { 746 if (q) { 747 return new VmaxnmQFp<uint32_t>( 748 machInst, vd, vn, vm); 749 } else { 750 return new VmaxnmDFp<uint32_t>( 751 machInst, vd, vn, vm); 752 } 753 } else { 754 if (q) { 755 return new VminnmQFp<uint32_t>( 756 machInst, vd, vn, vm); 757 } else { 758 return new VminnmDFp<uint32_t>( 759 machInst, vd, vn, vm); 760 } 761 } 762 } else { 763 if (bits(size, 1) == 0) { 764 if (q) { 765 return new VrecpsQFp<float>(machInst, vd, vn, vm); 766 } else { 767 return new VrecpsDFp<float>(machInst, vd, vn, vm); 768 } 769 } else { 770 if (q) { 771 return new VrsqrtsQFp<float>(machInst, vd, vn, vm); 772 } else { 773 return new VrsqrtsDFp<float>(machInst, vd, vn, vm); 774 } 775 } 776 } 777 } else { 778 if (u) { 779 if (bits(size, 1) == 0) { 780 if (q) { 781 return new VpmaxQFp<uint32_t>( 782 machInst, vd, vn, vm); 783 } else { 784 return new VpmaxDFp<uint32_t>( 785 machInst, vd, vn, vm); 786 } 787 } else { 788 if (q) { 789 return new VpminQFp<uint32_t>( 790 machInst, vd, vn, vm); 791 } else { 792 return new VpminDFp<uint32_t>( 793 machInst, vd, vn, vm); 794 } 795 } 796 } else { 797 if (bits(size, 1) == 0) { 798 if (q) { 799 return new VmaxQFp<uint32_t>( 800 machInst, vd, vn, vm); 801 } else { 802 return new VmaxDFp<uint32_t>( 803 machInst, vd, vn, vm); 804 } 805 } else { 806 if (q) { 807 return new VminQFp<uint32_t>( 808 machInst, vd, vn, vm); 809 } else { 810 return new VminDFp<uint32_t>( 811 machInst, vd, vn, vm); 812 } 813 } 814 } 815 } 816 } 817 return new Unknown(machInst); 818 } 819 820 static StaticInstPtr 821 decodeNeonOneRegModImm(ExtMachInst machInst) 822 { 823 const IntRegIndex vd = 824 (IntRegIndex)(2 * (bits(machInst, 15, 12) | 825 (bits(machInst, 22) << 4))); 826 const bool q = bits(machInst, 6); 827 const bool op = bits(machInst, 5); 828 const uint8_t cmode = bits(machInst, 11, 8); 829 const uint8_t imm = ((THUMB ? bits(machInst, 28) : 830 bits(machInst, 24)) << 7) | 831 (bits(machInst, 18, 16) << 4) | 832 (bits(machInst, 3, 0) << 0); 833 834 // Check for invalid immediate encodings and return an unknown op 835 // if it happens 836 bool immValid = true; 837 const uint64_t bigImm = simd_modified_imm(op, cmode, imm, immValid); 838 if (!immValid) { 839 return new Unknown(machInst); 840 } 841 842 if (op) { 843 if (bits(cmode, 3) == 0) { 844 if (bits(cmode, 0) == 0) { 845 if (q) 846 return new NVmvniQ<uint64_t>(machInst, vd, bigImm); 847 else 848 return new NVmvniD<uint64_t>(machInst, vd, bigImm); 849 } else { 850 if (q) 851 return new NVbiciQ<uint64_t>(machInst, vd, bigImm); 852 else 853 return new NVbiciD<uint64_t>(machInst, vd, bigImm); 854 } 855 } else { 856 if (bits(cmode, 2) == 1) { 857 switch (bits(cmode, 1, 0)) { 858 case 0: 859 case 1: 860 if (q) 861 return new NVmvniQ<uint64_t>(machInst, vd, bigImm); 862 else 863 return new NVmvniD<uint64_t>(machInst, vd, bigImm); 864 case 2: 865 if (q) 866 return new NVmoviQ<uint64_t>(machInst, vd, bigImm); 867 else 868 return new NVmoviD<uint64_t>(machInst, vd, bigImm); 869 case 3: 870 if (q) 871 return new Unknown(machInst); 872 else 873 return new Unknown(machInst); 874 } 875 } else { 876 if (bits(cmode, 0) == 0) { 877 if (q) 878 return new NVmvniQ<uint64_t>(machInst, vd, bigImm); 879 else 880 return new NVmvniD<uint64_t>(machInst, vd, bigImm); 881 } else { 882 if (q) 883 return new NVbiciQ<uint64_t>(machInst, vd, bigImm); 884 else 885 return new NVbiciD<uint64_t>(machInst, vd, bigImm); 886 } 887 } 888 } 889 } else { 890 if (bits(cmode, 3) == 0) { 891 if (bits(cmode, 0) == 0) { 892 if (q) 893 return new NVmoviQ<uint64_t>(machInst, vd, bigImm); 894 else 895 return new NVmoviD<uint64_t>(machInst, vd, bigImm); 896 } else { 897 if (q) 898 return new NVorriQ<uint64_t>(machInst, vd, bigImm); 899 else 900 return new NVorriD<uint64_t>(machInst, vd, bigImm); 901 } 902 } else { 903 if (bits(cmode, 2) == 1) { 904 if (q) 905 return new NVmoviQ<uint64_t>(machInst, vd, bigImm); 906 else 907 return new NVmoviD<uint64_t>(machInst, vd, bigImm); 908 } else { 909 if (bits(cmode, 0) == 0) { 910 if (q) 911 return new NVmoviQ<uint64_t>(machInst, vd, bigImm); 912 else 913 return new NVmoviD<uint64_t>(machInst, vd, bigImm); 914 } else { 915 if (q) 916 return new NVorriQ<uint64_t>(machInst, vd, bigImm); 917 else 918 return new NVorriD<uint64_t>(machInst, vd, bigImm); 919 } 920 } 921 } 922 } 923 return new Unknown(machInst); 924 } 925 926 static StaticInstPtr 927 decodeNeonTwoRegAndShift(ExtMachInst machInst) 928 { 929 const uint32_t opc = bits(machInst, 11, 8); 930 const bool u = THUMB ? bits(machInst, 28) : bits(machInst, 24); 931 const bool q = bits(machInst, 6); 932 const bool l = bits(machInst, 7); 933 const IntRegIndex vd = 934 (IntRegIndex)(2 * (bits(machInst, 15, 12) | 935 (bits(machInst, 22) << 4))); 936 const IntRegIndex vm = 937 (IntRegIndex)(2 * (bits(machInst, 3, 0) | 938 (bits(machInst, 5) << 4))); 939 unsigned imm6 = bits(machInst, 21, 16); 940 unsigned imm = ((l ? 1 : 0) << 6) | imm6; 941 unsigned size = 3; 942 unsigned lShiftAmt = 0; 943 unsigned bitSel; 944 for (bitSel = 1 << 6; true; bitSel >>= 1) { 945 if (bitSel & imm) 946 break; 947 else if (!size) 948 return new Unknown(machInst); 949 size--; 950 } 951 lShiftAmt = imm6 & ~bitSel; 952 unsigned rShiftAmt = 0; 953 if (opc != 0xe && opc != 0xf) { 954 if (size > 2) 955 rShiftAmt = 64 - imm6; 956 else 957 rShiftAmt = 2 * (8 << size) - imm6; 958 } 959 960 switch (opc) { 961 case 0x0: 962 return decodeNeonUSTwoShiftReg<NVshrD, NVshrQ>( 963 q, u, size, machInst, vd, vm, rShiftAmt); 964 case 0x1: 965 return decodeNeonUSTwoShiftReg<NVsraD, NVsraQ>( 966 q, u, size, machInst, vd, vm, rShiftAmt); 967 case 0x2: 968 return decodeNeonUSTwoShiftReg<NVrshrD, NVrshrQ>( 969 q, u, size, machInst, vd, vm, rShiftAmt); 970 case 0x3: 971 return decodeNeonUSTwoShiftReg<NVrsraD, NVrsraQ>( 972 q, u, size, machInst, vd, vm, rShiftAmt); 973 case 0x4: 974 if (u) { 975 return decodeNeonUTwoShiftReg<NVsriD, NVsriQ>( 976 q, size, machInst, vd, vm, rShiftAmt); 977 } else { 978 return new Unknown(machInst); 979 } 980 case 0x5: 981 if (u) { 982 return decodeNeonUTwoShiftReg<NVsliD, NVsliQ>( 983 q, size, machInst, vd, vm, lShiftAmt); 984 } else { 985 return decodeNeonUTwoShiftReg<NVshlD, NVshlQ>( 986 q, size, machInst, vd, vm, lShiftAmt); 987 } 988 case 0x6: 989 case 0x7: 990 if (u) { 991 if (opc == 0x6) { 992 return decodeNeonSTwoShiftReg<NVqshlusD, NVqshlusQ>( 993 q, size, machInst, vd, vm, lShiftAmt); 994 } else { 995 return decodeNeonUTwoShiftReg<NVqshluD, NVqshluQ>( 996 q, size, machInst, vd, vm, lShiftAmt); 997 } 998 } else { 999 return decodeNeonSTwoShiftReg<NVqshlD, NVqshlQ>( 1000 q, size, machInst, vd, vm, lShiftAmt); 1001 } 1002 case 0x8: 1003 if (l) { 1004 return new Unknown(machInst); 1005 } else if (u) { 1006 return decodeNeonSTwoShiftSReg<NVqshruns, NVqrshruns>( 1007 q, size, machInst, vd, vm, rShiftAmt); 1008 } else { 1009 return decodeNeonUTwoShiftSReg<NVshrn, NVrshrn>( 1010 q, size, machInst, vd, vm, rShiftAmt); 1011 } 1012 case 0x9: 1013 if (l) { 1014 return new Unknown(machInst); 1015 } else if (u) { 1016 return decodeNeonUTwoShiftSReg<NVqshrun, NVqrshrun>( 1017 q, size, machInst, vd, vm, rShiftAmt); 1018 } else { 1019 return decodeNeonSTwoShiftSReg<NVqshrn, NVqrshrn>( 1020 q, size, machInst, vd, vm, rShiftAmt); 1021 } 1022 case 0xa: 1023 if (l || q) { 1024 return new Unknown(machInst); 1025 } else { 1026 return decodeNeonUSTwoShiftSReg<NVmovl, NVshll>( 1027 lShiftAmt, u, size, machInst, vd, vm, lShiftAmt); 1028 } 1029 case 0xe: 1030 if (l) { 1031 return new Unknown(machInst); 1032 } else { 1033 if (bits(imm6, 5) == 0) 1034 return new Unknown(machInst); 1035 if (u) { 1036 if (q) { 1037 return new NVcvtu2fpQ<float>( 1038 machInst, vd, vm, 64 - imm6); 1039 } else { 1040 return new NVcvtu2fpD<float>( 1041 machInst, vd, vm, 64 - imm6); 1042 } 1043 } else { 1044 if (q) { 1045 return new NVcvts2fpQ<float>( 1046 machInst, vd, vm, 64 - imm6); 1047 } else { 1048 return new NVcvts2fpD<float>( 1049 machInst, vd, vm, 64 - imm6); 1050 } 1051 } 1052 } 1053 case 0xf: 1054 if (l) { 1055 return new Unknown(machInst); 1056 } else { 1057 if (bits(imm6, 5) == 0) 1058 return new Unknown(machInst); 1059 if (u) { 1060 if (q) { 1061 return new NVcvt2ufxQ<float>( 1062 machInst, vd, vm, 64 - imm6); 1063 } else { 1064 return new NVcvt2ufxD<float>( 1065 machInst, vd, vm, 64 - imm6); 1066 } 1067 } else { 1068 if (q) { 1069 return new NVcvt2sfxQ<float>( 1070 machInst, vd, vm, 64 - imm6); 1071 } else { 1072 return new NVcvt2sfxD<float>( 1073 machInst, vd, vm, 64 - imm6); 1074 } 1075 } 1076 } 1077 } 1078 return new Unknown(machInst); 1079 } 1080 1081 static StaticInstPtr 1082 decodeNeonThreeRegDiffLengths(ExtMachInst machInst) 1083 { 1084 const bool u = THUMB ? bits(machInst, 28) : bits(machInst, 24); 1085 const uint32_t opc = bits(machInst, 11, 8); 1086 const IntRegIndex vd = 1087 (IntRegIndex)(2 * (bits(machInst, 15, 12) | 1088 (bits(machInst, 22) << 4))); 1089 const IntRegIndex vn = 1090 (IntRegIndex)(2 * (bits(machInst, 19, 16) | 1091 (bits(machInst, 7) << 4))); 1092 const IntRegIndex vm = 1093 (IntRegIndex)(2 * (bits(machInst, 3, 0) | 1094 (bits(machInst, 5) << 4))); 1095 const unsigned size = bits(machInst, 21, 20); 1096 switch (opc) { 1097 case 0x0: 1098 return decodeNeonUSThreeUSReg<Vaddl>( 1099 u, size, machInst, vd, vn, vm); 1100 case 0x1: 1101 return decodeNeonUSThreeUSReg<Vaddw>( 1102 u, size, machInst, vd, vn, vm); 1103 case 0x2: 1104 return decodeNeonUSThreeUSReg<Vsubl>( 1105 u, size, machInst, vd, vn, vm); 1106 case 0x3: 1107 return decodeNeonUSThreeUSReg<Vsubw>( 1108 u, size, machInst, vd, vn, vm); 1109 case 0x4: 1110 if (u) { 1111 return decodeNeonUThreeUSReg<Vraddhn>( 1112 size, machInst, vd, vn, vm); 1113 } else { 1114 return decodeNeonUThreeUSReg<Vaddhn>( 1115 size, machInst, vd, vn, vm); 1116 } 1117 case 0x5: 1118 return decodeNeonUSThreeUSReg<Vabal>( 1119 u, size, machInst, vd, vn, vm); 1120 case 0x6: 1121 if (u) { 1122 return decodeNeonUThreeUSReg<Vrsubhn>( 1123 size, machInst, vd, vn, vm); 1124 } else { 1125 return decodeNeonUThreeUSReg<Vsubhn>( 1126 size, machInst, vd, vn, vm); 1127 } 1128 case 0x7: 1129 if (bits(machInst, 23)) { 1130 return decodeNeonUSThreeUSReg<Vabdl>( 1131 u, size, machInst, vd, vn, vm); 1132 } else { 1133 return decodeNeonUSThreeReg<VabdD, VabdQ>( 1134 bits(machInst, 6), u, size, machInst, vd, vn, vm); 1135 } 1136 case 0x8: 1137 return decodeNeonUSThreeUSReg<Vmlal>( 1138 u, size, machInst, vd, vn, vm); 1139 case 0xa: 1140 return decodeNeonUSThreeUSReg<Vmlsl>( 1141 u, size, machInst, vd, vn, vm); 1142 case 0x9: 1143 if (u) { 1144 return new Unknown(machInst); 1145 } else { 1146 return decodeNeonSThreeUSReg<Vqdmlal>( 1147 size, machInst, vd, vn, vm); 1148 } 1149 case 0xb: 1150 if (u) { 1151 return new Unknown(machInst); 1152 } else { 1153 return decodeNeonSThreeUSReg<Vqdmlsl>( 1154 size, machInst, vd, vn, vm); 1155 } 1156 case 0xc: 1157 return decodeNeonUSThreeUSReg<Vmull>( 1158 u, size, machInst, vd, vn, vm); 1159 case 0xd: 1160 if (u) { 1161 return new Unknown(machInst); 1162 } else { 1163 return decodeNeonSThreeUSReg<Vqdmull>( 1164 size, machInst, vd, vn, vm); 1165 } 1166 case 0xe: 1167 return decodeNeonUThreeUSReg<Vmullp>( 1168 size, machInst, vd, vn, vm); 1169 } 1170 return new Unknown(machInst); 1171 } 1172 1173 static StaticInstPtr 1174 decodeNeonTwoRegScalar(ExtMachInst machInst) 1175 { 1176 const bool u = THUMB ? bits(machInst, 28) : bits(machInst, 24); 1177 const uint32_t opc = bits(machInst, 11, 8); 1178 const unsigned size = bits(machInst, 21, 20); 1179 const IntRegIndex vd = 1180 (IntRegIndex)(2 * (bits(machInst, 15, 12) | 1181 (bits(machInst, 22) << 4))); 1182 const IntRegIndex vn = 1183 (IntRegIndex)(2 * (bits(machInst, 19, 16) | 1184 (bits(machInst, 7) << 4))); 1185 const IntRegIndex vm = (size == 2) ? 1186 (IntRegIndex)(2 * bits(machInst, 3, 0)) : 1187 (IntRegIndex)(2 * bits(machInst, 2, 0)); 1188 const unsigned index = (size == 2) ? (unsigned)bits(machInst, 5) : 1189 (bits(machInst, 3) | (bits(machInst, 5) << 1)); 1190 switch (opc) { 1191 case 0x0: 1192 if (u) { 1193 switch (size) { 1194 case 1: 1195 return new VmlasQ<uint16_t>(machInst, vd, vn, vm, index); 1196 case 2: 1197 return new VmlasQ<uint32_t>(machInst, vd, vn, vm, index); 1198 default: 1199 return new Unknown(machInst); 1200 } 1201 } else { 1202 switch (size) { 1203 case 1: 1204 return new VmlasD<uint16_t>(machInst, vd, vn, vm, index); 1205 case 2: 1206 return new VmlasD<uint32_t>(machInst, vd, vn, vm, index); 1207 default: 1208 return new Unknown(machInst); 1209 } 1210 } 1211 case 0x1: 1212 if (u) 1213 return new VmlasQFp<float>(machInst, vd, vn, vm, index); 1214 else 1215 return new VmlasDFp<float>(machInst, vd, vn, vm, index); 1216 case 0x4: 1217 if (u) { 1218 switch (size) { 1219 case 1: 1220 return new VmlssQ<uint16_t>(machInst, vd, vn, vm, index); 1221 case 2: 1222 return new VmlssQ<uint32_t>(machInst, vd, vn, vm, index); 1223 default: 1224 return new Unknown(machInst); 1225 } 1226 } else { 1227 switch (size) { 1228 case 1: 1229 return new VmlssD<uint16_t>(machInst, vd, vn, vm, index); 1230 case 2: 1231 return new VmlssD<uint32_t>(machInst, vd, vn, vm, index); 1232 default: 1233 return new Unknown(machInst); 1234 } 1235 } 1236 case 0x5: 1237 if (u) 1238 return new VmlssQFp<float>(machInst, vd, vn, vm, index); 1239 else 1240 return new VmlssDFp<float>(machInst, vd, vn, vm, index); 1241 case 0x2: 1242 if (u) { 1243 switch (size) { 1244 case 1: 1245 return new Vmlals<uint16_t>(machInst, vd, vn, vm, index); 1246 case 2: 1247 return new Vmlals<uint32_t>(machInst, vd, vn, vm, index); 1248 default: 1249 return new Unknown(machInst); 1250 } 1251 } else { 1252 switch (size) { 1253 case 1: 1254 return new Vmlals<int16_t>(machInst, vd, vn, vm, index); 1255 case 2: 1256 return new Vmlals<int32_t>(machInst, vd, vn, vm, index); 1257 default: 1258 return new Unknown(machInst); 1259 } 1260 } 1261 case 0x6: 1262 if (u) { 1263 switch (size) { 1264 case 1: 1265 return new Vmlsls<uint16_t>(machInst, vd, vn, vm, index); 1266 case 2: 1267 return new Vmlsls<uint32_t>(machInst, vd, vn, vm, index); 1268 default: 1269 return new Unknown(machInst); 1270 } 1271 } else { 1272 switch (size) { 1273 case 1: 1274 return new Vmlsls<int16_t>(machInst, vd, vn, vm, index); 1275 case 2: 1276 return new Vmlsls<int32_t>(machInst, vd, vn, vm, index); 1277 default: 1278 return new Unknown(machInst); 1279 } 1280 } 1281 case 0x3: 1282 if (u) { 1283 return new Unknown(machInst); 1284 } else { 1285 switch (size) { 1286 case 1: 1287 return new Vqdmlals<int16_t>(machInst, vd, vn, vm, index); 1288 case 2: 1289 return new Vqdmlals<int32_t>(machInst, vd, vn, vm, index); 1290 default: 1291 return new Unknown(machInst); 1292 } 1293 } 1294 case 0x7: 1295 if (u) { 1296 return new Unknown(machInst); 1297 } else { 1298 switch (size) { 1299 case 1: 1300 return new Vqdmlsls<int16_t>(machInst, vd, vn, vm, index); 1301 case 2: 1302 return new Vqdmlsls<int32_t>(machInst, vd, vn, vm, index); 1303 default: 1304 return new Unknown(machInst); 1305 } 1306 } 1307 case 0x8: 1308 if (u) { 1309 switch (size) { 1310 case 1: 1311 return new VmulsQ<uint16_t>(machInst, vd, vn, vm, index); 1312 case 2: 1313 return new VmulsQ<uint32_t>(machInst, vd, vn, vm, index); 1314 default: 1315 return new Unknown(machInst); 1316 } 1317 } else { 1318 switch (size) { 1319 case 1: 1320 return new VmulsD<uint16_t>(machInst, vd, vn, vm, index); 1321 case 2: 1322 return new VmulsD<uint32_t>(machInst, vd, vn, vm, index); 1323 default: 1324 return new Unknown(machInst); 1325 } 1326 } 1327 case 0x9: 1328 if (u) 1329 return new VmulsQFp<float>(machInst, vd, vn, vm, index); 1330 else 1331 return new VmulsDFp<float>(machInst, vd, vn, vm, index); 1332 case 0xa: 1333 if (u) { 1334 switch (size) { 1335 case 1: 1336 return new Vmulls<uint16_t>(machInst, vd, vn, vm, index); 1337 case 2: 1338 return new Vmulls<uint32_t>(machInst, vd, vn, vm, index); 1339 default: 1340 return new Unknown(machInst); 1341 } 1342 } else { 1343 switch (size) { 1344 case 1: 1345 return new Vmulls<int16_t>(machInst, vd, vn, vm, index); 1346 case 2: 1347 return new Vmulls<int32_t>(machInst, vd, vn, vm, index); 1348 default: 1349 return new Unknown(machInst); 1350 } 1351 } 1352 case 0xb: 1353 if (u) { 1354 return new Unknown(machInst); 1355 } else { 1356 if (u) { 1357 switch (size) { 1358 case 1: 1359 return new Vqdmulls<uint16_t>( 1360 machInst, vd, vn, vm, index); 1361 case 2: 1362 return new Vqdmulls<uint32_t>( 1363 machInst, vd, vn, vm, index); 1364 default: 1365 return new Unknown(machInst); 1366 } 1367 } else { 1368 switch (size) { 1369 case 1: 1370 return new Vqdmulls<int16_t>( 1371 machInst, vd, vn, vm, index); 1372 case 2: 1373 return new Vqdmulls<int32_t>( 1374 machInst, vd, vn, vm, index); 1375 default: 1376 return new Unknown(machInst); 1377 } 1378 } 1379 } 1380 case 0xc: 1381 if (u) { 1382 switch (size) { 1383 case 1: 1384 return new VqdmulhsQ<int16_t>( 1385 machInst, vd, vn, vm, index); 1386 case 2: 1387 return new VqdmulhsQ<int32_t>( 1388 machInst, vd, vn, vm, index); 1389 default: 1390 return new Unknown(machInst); 1391 } 1392 } else { 1393 switch (size) { 1394 case 1: 1395 return new VqdmulhsD<int16_t>( 1396 machInst, vd, vn, vm, index); 1397 case 2: 1398 return new VqdmulhsD<int32_t>( 1399 machInst, vd, vn, vm, index); 1400 default: 1401 return new Unknown(machInst); 1402 } 1403 } 1404 case 0xd: 1405 if (u) { 1406 switch (size) { 1407 case 1: 1408 return new VqrdmulhsQ<int16_t>( 1409 machInst, vd, vn, vm, index); 1410 case 2: 1411 return new VqrdmulhsQ<int32_t>( 1412 machInst, vd, vn, vm, index); 1413 default: 1414 return new Unknown(machInst); 1415 } 1416 } else { 1417 switch (size) { 1418 case 1: 1419 return new VqrdmulhsD<int16_t>( 1420 machInst, vd, vn, vm, index); 1421 case 2: 1422 return new VqrdmulhsD<int32_t>( 1423 machInst, vd, vn, vm, index); 1424 default: 1425 return new Unknown(machInst); 1426 } 1427 } 1428 } 1429 return new Unknown(machInst); 1430 } 1431 1432 static StaticInstPtr 1433 decodeNeonTwoRegMisc(ExtMachInst machInst) 1434 { 1435 const uint32_t opc1 = bits(machInst, 17, 16); 1436 const uint32_t b = bits(machInst, 10, 6); 1437 const bool q = bits(machInst, 6); 1438 const IntRegIndex vd = 1439 (IntRegIndex)(2 * (bits(machInst, 15, 12) | 1440 (bits(machInst, 22) << 4))); 1441 const IntRegIndex vm = 1442 (IntRegIndex)(2 * (bits(machInst, 3, 0) | 1443 (bits(machInst, 5) << 4))); 1444 const unsigned size = bits(machInst, 19, 18); 1445 switch (opc1) { 1446 case 0x0: 1447 switch (bits(b, 4, 1)) { 1448 case 0x0: 1449 switch (size) { 1450 case 0: 1451 if (q) { 1452 return new NVrev64Q<uint8_t>(machInst, vd, vm); 1453 } else { 1454 return new NVrev64D<uint8_t>(machInst, vd, vm); 1455 } 1456 case 1: 1457 if (q) { 1458 return new NVrev64Q<uint16_t>(machInst, vd, vm); 1459 } else { 1460 return new NVrev64D<uint16_t>(machInst, vd, vm); 1461 } 1462 case 2: 1463 if (q) { 1464 return new NVrev64Q<uint32_t>(machInst, vd, vm); 1465 } else { 1466 return new NVrev64D<uint32_t>(machInst, vd, vm); 1467 } 1468 default: 1469 return new Unknown(machInst); 1470 } 1471 case 0x1: 1472 switch (size) { 1473 case 0: 1474 if (q) { 1475 return new NVrev32Q<uint8_t>(machInst, vd, vm); 1476 } else { 1477 return new NVrev32D<uint8_t>(machInst, vd, vm); 1478 } 1479 case 1: 1480 if (q) { 1481 return new NVrev32Q<uint16_t>(machInst, vd, vm); 1482 } else { 1483 return new NVrev32D<uint16_t>(machInst, vd, vm); 1484 } 1485 default: 1486 return new Unknown(machInst); 1487 } 1488 case 0x2: 1489 if (size != 0) { 1490 return new Unknown(machInst); 1491 } else if (q) { 1492 return new NVrev16Q<uint8_t>(machInst, vd, vm); 1493 } else { 1494 return new NVrev16D<uint8_t>(machInst, vd, vm); 1495 } 1496 case 0x4: 1497 return decodeNeonSTwoMiscSReg<NVpaddlD, NVpaddlQ>( 1498 q, size, machInst, vd, vm); 1499 case 0x5: 1500 return decodeNeonUTwoMiscSReg<NVpaddlD, NVpaddlQ>( 1501 q, size, machInst, vd, vm); 1502 case 0x6: 1503 if (q == 0) { 1504 return new AESE(machInst, vd, vd, vm); 1505 } else { 1506 return new AESD(machInst, vd, vd, vm); 1507 } 1508 case 0x7: 1509 if (q == 0) { 1510 return new AESMC(machInst, vd, vm); 1511 } else { 1512 return new AESIMC(machInst, vd, vm); 1513 } 1514 case 0x8: 1515 return decodeNeonSTwoMiscReg<NVclsD, NVclsQ>( 1516 q, size, machInst, vd, vm); 1517 case 0x9: 1518 return decodeNeonSTwoMiscReg<NVclzD, NVclzQ>( 1519 q, size, machInst, vd, vm); 1520 case 0xa: 1521 return decodeNeonUTwoMiscReg<NVcntD, NVcntQ>( 1522 q, size, machInst, vd, vm); 1523 case 0xb: 1524 if (q) 1525 return new NVmvnQ<uint64_t>(machInst, vd, vm); 1526 else 1527 return new NVmvnD<uint64_t>(machInst, vd, vm); 1528 case 0xc: 1529 return decodeNeonSTwoMiscSReg<NVpadalD, NVpadalQ>( 1530 q, size, machInst, vd, vm); 1531 case 0xd: 1532 return decodeNeonUTwoMiscSReg<NVpadalD, NVpadalQ>( 1533 q, size, machInst, vd, vm); 1534 case 0xe: 1535 return decodeNeonSTwoMiscReg<NVqabsD, NVqabsQ>( 1536 q, size, machInst, vd, vm); 1537 case 0xf: 1538 return decodeNeonSTwoMiscReg<NVqnegD, NVqnegQ>( 1539 q, size, machInst, vd, vm); 1540 default: 1541 return new Unknown(machInst); 1542 } 1543 case 0x1: 1544 switch (bits(b, 3, 1)) { 1545 case 0x0: 1546 if (bits(b, 4)) { 1547 if (q) { 1548 return new NVcgtQFp<float>(machInst, vd, vm); 1549 } else { 1550 return new NVcgtDFp<float>(machInst, vd, vm); 1551 } 1552 } else { 1553 return decodeNeonSTwoMiscReg<NVcgtD, NVcgtQ>( 1554 q, size, machInst, vd, vm); 1555 } 1556 case 0x1: 1557 if (bits(b, 4)) { 1558 if (q) { 1559 return new NVcgeQFp<float>(machInst, vd, vm); 1560 } else { 1561 return new NVcgeDFp<float>(machInst, vd, vm); 1562 } 1563 } else { 1564 return decodeNeonSTwoMiscReg<NVcgeD, NVcgeQ>( 1565 q, size, machInst, vd, vm); 1566 } 1567 case 0x2: 1568 if (bits(b, 4)) { 1569 if (q) { 1570 return new NVceqQFp<float>(machInst, vd, vm); 1571 } else { 1572 return new NVceqDFp<float>(machInst, vd, vm); 1573 } 1574 } else { 1575 return decodeNeonSTwoMiscReg<NVceqD, NVceqQ>( 1576 q, size, machInst, vd, vm); 1577 } 1578 case 0x3: 1579 if (bits(b, 4)) { 1580 if (q) { 1581 return new NVcleQFp<float>(machInst, vd, vm); 1582 } else { 1583 return new NVcleDFp<float>(machInst, vd, vm); 1584 } 1585 } else { 1586 return decodeNeonSTwoMiscReg<NVcleD, NVcleQ>( 1587 q, size, machInst, vd, vm); 1588 } 1589 case 0x4: 1590 if (bits(b, 4)) { 1591 if (q) { 1592 return new NVcltQFp<float>(machInst, vd, vm); 1593 } else { 1594 return new NVcltDFp<float>(machInst, vd, vm); 1595 } 1596 } else { 1597 return decodeNeonSTwoMiscReg<NVcltD, NVcltQ>( 1598 q, size, machInst, vd, vm); 1599 } 1600 case 0x5: 1601 if (q) { 1602 return new SHA1H(machInst, vd, vm); 1603 } else { 1604 return new Unknown(machInst); 1605 } 1606 case 0x6: 1607 if (bits(machInst, 10)) { 1608 if (q) 1609 return new NVabsQFp<float>(machInst, vd, vm); 1610 else 1611 return new NVabsDFp<float>(machInst, vd, vm); 1612 } else { 1613 return decodeNeonSTwoMiscReg<NVabsD, NVabsQ>( 1614 q, size, machInst, vd, vm); 1615 } 1616 case 0x7: 1617 if (bits(machInst, 10)) { 1618 if (q) 1619 return new NVnegQFp<float>(machInst, vd, vm); 1620 else 1621 return new NVnegDFp<float>(machInst, vd, vm); 1622 } else { 1623 return decodeNeonSTwoMiscReg<NVnegD, NVnegQ>( 1624 q, size, machInst, vd, vm); 1625 } 1626 default: 1627 return new Unknown64(machInst); 1628 } 1629 case 0x2: 1630 switch (bits(b, 4, 1)) { 1631 case 0x0: 1632 if (q) 1633 return new NVswpQ<uint64_t>(machInst, vd, vm); 1634 else 1635 return new NVswpD<uint64_t>(machInst, vd, vm); 1636 case 0x1: 1637 return decodeNeonUTwoMiscSReg<NVtrnD, NVtrnQ>( 1638 q, size, machInst, vd, vm); 1639 case 0x2: 1640 return decodeNeonUTwoMiscReg<NVuzpD, NVuzpQ>( 1641 q, size, machInst, vd, vm); 1642 case 0x3: 1643 return decodeNeonUTwoMiscReg<NVzipD, NVzipQ>( 1644 q, size, machInst, vd, vm); 1645 case 0x4: 1646 if (b == 0x8) { 1647 return decodeNeonUTwoMiscUSReg<NVmovn>( 1648 size, machInst, vd, vm); 1649 } else { 1650 return decodeNeonSTwoMiscUSReg<NVqmovuns>( 1651 size, machInst, vd, vm); 1652 } 1653 case 0x5: 1654 if (q) { 1655 return decodeNeonUTwoMiscUSReg<NVqmovun>( 1656 size, machInst, vd, vm); 1657 } else { 1658 return decodeNeonSTwoMiscUSReg<NVqmovn>( 1659 size, machInst, vd, vm); 1660 } 1661 case 0x6: 1662 if (b == 0xc) { 1663 return decodeNeonSTwoShiftUSReg<NVshll>( 1664 size, machInst, vd, vm, 8 << size); 1665 } else { 1666 return new Unknown(machInst); 1667 } 1668 case 0x7: 1669 if (q) { 1670 return new SHA256SU0(machInst, vd, vm); 1671 } else { 1672 return new SHA1SU1(machInst, vd, vm); 1673 } 1674 case 0xc: 1675 case 0xe: 1676 if (b == 0x18) { 1677 if (size != 1 || (vm % 2)) 1678 return new Unknown(machInst); 1679 return new NVcvts2h<uint16_t>(machInst, vd, vm); 1680 } else if (b == 0x1c) { 1681 if (size != 1 || (vd % 2)) 1682 return new Unknown(machInst); 1683 return new NVcvth2s<uint16_t>(machInst, vd, vm); 1684 } else { 1685 return new Unknown(machInst); 1686 } 1687 default: 1688 return new Unknown(machInst); 1689 } 1690 case 0x3: 1691 if (bits(b, 4, 3) == 0x3) { 1692 if ((q && (vd % 2 || vm % 2)) || size != 2) { 1693 return new Unknown(machInst); 1694 } else { 1695 if (bits(b, 2)) { 1696 if (bits(b, 1)) { 1697 if (q) { 1698 return new NVcvt2ufxQ<float>( 1699 machInst, vd, vm, 0); 1700 } else { 1701 return new NVcvt2ufxD<float>( 1702 machInst, vd, vm, 0); 1703 } 1704 } else { 1705 if (q) { 1706 return new NVcvt2sfxQ<float>( 1707 machInst, vd, vm, 0); 1708 } else { 1709 return new NVcvt2sfxD<float>( 1710 machInst, vd, vm, 0); 1711 } 1712 } 1713 } else { 1714 if (bits(b, 1)) { 1715 if (q) { 1716 return new NVcvtu2fpQ<float>( 1717 machInst, vd, vm, 0); 1718 } else { 1719 return new NVcvtu2fpD<float>( 1720 machInst, vd, vm, 0); 1721 } 1722 } else { 1723 if (q) { 1724 return new NVcvts2fpQ<float>( 1725 machInst, vd, vm, 0); 1726 } else { 1727 return new NVcvts2fpD<float>( 1728 machInst, vd, vm, 0); 1729 } 1730 } 1731 } 1732 } 1733 } else if ((b & 0x1a) == 0x10) { 1734 if (bits(b, 2)) { 1735 if (q) { 1736 return new NVrecpeQFp<float>(machInst, vd, vm); 1737 } else { 1738 return new NVrecpeDFp<float>(machInst, vd, vm); 1739 } 1740 } else { 1741 if (q) { 1742 return new NVrecpeQ<uint32_t>(machInst, vd, vm); 1743 } else { 1744 return new NVrecpeD<uint32_t>(machInst, vd, vm); 1745 } 1746 } 1747 } else if ((b & 0x1a) == 0x12) { 1748 if (bits(b, 2)) { 1749 if (q) { 1750 return new NVrsqrteQFp<float>(machInst, vd, vm); 1751 } else { 1752 return new NVrsqrteDFp<float>(machInst, vd, vm); 1753 } 1754 } else { 1755 if (q) { 1756 return new NVrsqrteQ<uint32_t>(machInst, vd, vm); 1757 } else { 1758 return new NVrsqrteD<uint32_t>(machInst, vd, vm); 1759 } 1760 } 1761 } else { 1762 return new Unknown(machInst); 1763 } 1764 } 1765 return new Unknown(machInst); 1766 } 1767 1768 StaticInstPtr 1769 decodeNeonData(ExtMachInst machInst) 1770 { 1771 const bool u = THUMB ? bits(machInst, 28) : bits(machInst, 24); 1772 const uint32_t a = bits(machInst, 23, 19); 1773 const uint32_t q = bits(machInst, 11, 8); 1774 const uint32_t c = bits(machInst, 7, 4); 1775 if (bits(a, 4) == 0) { 1776 return decodeNeonThreeRegistersSameLength(machInst); 1777 } else if ((c & 0x9) == 1) { 1778 if ((a & 0x7) == 0) { 1779 return decodeNeonOneRegModImm(machInst); 1780 } else { 1781 return decodeNeonTwoRegAndShift(machInst); 1782 } 1783 } else if ((c & 0x9) == 9) { 1784 return decodeNeonTwoRegAndShift(machInst); 1785 } else if (bits(a, 2, 1) != 0x3) { 1786 if ((c & 0x5) == 0) { 1787 return decodeNeonThreeRegDiffLengths(machInst); 1788 } else if ((c & 0x5) == 4) { 1789 return decodeNeonTwoRegScalar(machInst); 1790 } 1791 } else if ((a & 0x16) == 0x16) { 1792 const IntRegIndex vd = 1793 (IntRegIndex)(2 * (bits(machInst, 15, 12) | 1794 (bits(machInst, 22) << 4))); 1795 const IntRegIndex vn = 1796 (IntRegIndex)(2 * (bits(machInst, 19, 16) | 1797 (bits(machInst, 7) << 4))); 1798 const IntRegIndex vm = 1799 (IntRegIndex)(2 * (bits(machInst, 3, 0) | 1800 (bits(machInst, 5) << 4))); 1801 if (!u) { 1802 if (bits(c, 0) == 0) { 1803 unsigned imm4 = bits(machInst, 11, 8); 1804 bool q = bits(machInst, 6); 1805 if (imm4 >= 16 && !q) 1806 return new Unknown(machInst); 1807 if (q) { 1808 return new NVextQ<uint8_t>(machInst, vd, vn, vm, imm4); 1809 } else { 1810 return new NVextD<uint8_t>(machInst, vd, vn, vm, imm4); 1811 } 1812 } 1813 } else if (bits(q, 3) == 0 && bits(c, 0) == 0) { 1814 return decodeNeonTwoRegMisc(machInst); 1815 } else if (bits(q, 3, 2) == 0x2 && bits(c, 0) == 0) { 1816 unsigned length = bits(machInst, 9, 8) + 1; 1817 if ((uint32_t)vn / 2 + length > 32) 1818 return new Unknown(machInst); 1819 if (bits(machInst, 6) == 0) { 1820 switch (length) { 1821 case 1: 1822 return new NVtbl1(machInst, vd, vn, vm); 1823 case 2: 1824 return new NVtbl2(machInst, vd, vn, vm); 1825 case 3: 1826 return new NVtbl3(machInst, vd, vn, vm); 1827 case 4: 1828 return new NVtbl4(machInst, vd, vn, vm); 1829 } 1830 } else { 1831 switch (length) { 1832 case 1: 1833 return new NVtbx1(machInst, vd, vn, vm); 1834 case 2: 1835 return new NVtbx2(machInst, vd, vn, vm); 1836 case 3: 1837 return new NVtbx3(machInst, vd, vn, vm); 1838 case 4: 1839 return new NVtbx4(machInst, vd, vn, vm); 1840 } 1841 } 1842 } else if (q == 0xc && (c & 0x9) == 0) { 1843 unsigned imm4 = bits(machInst, 19, 16); 1844 if (bits(imm4, 2, 0) == 0) 1845 return new Unknown(machInst); 1846 unsigned size = 0; 1847 while ((imm4 & 0x1) == 0) { 1848 size++; 1849 imm4 >>= 1; 1850 } 1851 unsigned index = imm4 >> 1; 1852 const bool q = bits(machInst, 6); 1853 return decodeNeonUTwoShiftSReg<NVdupD, NVdupQ>( 1854 q, size, machInst, vd, vm, index); 1855 } 1856 } 1857 return new Unknown(machInst); 1858 } 1859 ''' 1860}}; 1861 1862def format ThumbNeonMem() {{ 1863 decode_block = ''' 1864 return decodeNeonMem(machInst); 1865 ''' 1866}}; 1867 1868def format ThumbNeonData() {{ 1869 decode_block = ''' 1870 return decodeNeonData(machInst); 1871 ''' 1872}}; 1873 1874let {{ 1875 header_output = ''' 1876 StaticInstPtr 1877 decodeExtensionRegLoadStore(ExtMachInst machInst); 1878 ''' 1879 decoder_output = ''' 1880 StaticInstPtr 1881 decodeExtensionRegLoadStore(ExtMachInst machInst) 1882 { 1883 const uint32_t opcode = bits(machInst, 24, 20); 1884 const uint32_t offset = bits(machInst, 7, 0); 1885 const bool single = (bits(machInst, 8) == 0); 1886 const IntRegIndex rn = (IntRegIndex)(uint32_t)bits(machInst, 19, 16); 1887 RegIndex vd; 1888 if (single) { 1889 vd = (RegIndex)(uint32_t)((bits(machInst, 15, 12) << 1) | 1890 bits(machInst, 22)); 1891 } else { 1892 vd = (RegIndex)(uint32_t)((bits(machInst, 15, 12) << 1) | 1893 (bits(machInst, 22) << 5)); 1894 } 1895 switch (bits(opcode, 4, 3)) { 1896 case 0x0: 1897 if (bits(opcode, 4, 1) == 0x2 && 1898 !(machInst.thumb == 1 && bits(machInst, 28) == 1) && 1899 !(machInst.thumb == 0 && machInst.condCode == 0xf)) { 1900 if ((bits(machInst, 7, 4) & 0xd) != 1) { 1901 break; 1902 } 1903 const IntRegIndex rt = 1904 (IntRegIndex)(uint32_t)bits(machInst, 15, 12); 1905 const IntRegIndex rt2 = 1906 (IntRegIndex)(uint32_t)bits(machInst, 19, 16); 1907 const bool op = bits(machInst, 20); 1908 uint32_t vm; 1909 if (single) { 1910 vm = (bits(machInst, 3, 0) << 1) | bits(machInst, 5); 1911 } else { 1912 vm = (bits(machInst, 3, 0) << 1) | 1913 (bits(machInst, 5) << 5); 1914 } 1915 if (op) { 1916 return new Vmov2Core2Reg(machInst, rt, rt2, 1917 (IntRegIndex)vm); 1918 } else { 1919 return new Vmov2Reg2Core(machInst, (IntRegIndex)vm, 1920 rt, rt2); 1921 } 1922 } 1923 break; 1924 case 0x1: 1925 { 1926 if (offset == 0 || vd + offset/2 > NumFloatV7ArchRegs) { 1927 break; 1928 } 1929 switch (bits(opcode, 1, 0)) { 1930 case 0x0: 1931 return new VLdmStm(machInst, rn, vd, single, 1932 true, false, false, offset); 1933 case 0x1: 1934 return new VLdmStm(machInst, rn, vd, single, 1935 true, false, true, offset); 1936 case 0x2: 1937 return new VLdmStm(machInst, rn, vd, single, 1938 true, true, false, offset); 1939 case 0x3: 1940 // If rn == sp, then this is called vpop. 1941 return new VLdmStm(machInst, rn, vd, single, 1942 true, true, true, offset); 1943 default: 1944 M5_UNREACHABLE; 1945 } 1946 } 1947 case 0x2: 1948 if (bits(opcode, 1, 0) == 0x2) { 1949 // If rn == sp, then this is called vpush. 1950 return new VLdmStm(machInst, rn, vd, single, 1951 false, true, false, offset); 1952 } else if (bits(opcode, 1, 0) == 0x3) { 1953 return new VLdmStm(machInst, rn, vd, single, 1954 false, true, true, offset); 1955 } 1956 M5_FALLTHROUGH; 1957 case 0x3: 1958 const bool up = (bits(machInst, 23) == 1); 1959 const uint32_t imm = bits(machInst, 7, 0) << 2; 1960 if (single) { 1961 vd = (RegIndex)(uint32_t)((bits(machInst, 15, 12) << 1) | 1962 (bits(machInst, 22))); 1963 } else { 1964 vd = (RegIndex)(uint32_t)((bits(machInst, 15, 12) << 1) | 1965 (bits(machInst, 22) << 5)); 1966 } 1967 if (bits(opcode, 1, 0) == 0x0) { 1968 if (single) { 1969 if (up) { 1970 return new %(vstr_us)s(machInst, vd, rn, up, imm); 1971 } else { 1972 return new %(vstr_s)s(machInst, vd, rn, up, imm); 1973 } 1974 } else { 1975 if (up) { 1976 return new %(vstr_ud)s(machInst, vd, vd + 1, 1977 rn, up, imm); 1978 } else { 1979 return new %(vstr_d)s(machInst, vd, vd + 1, 1980 rn, up, imm); 1981 } 1982 } 1983 } else if (bits(opcode, 1, 0) == 0x1) { 1984 if (single) { 1985 if (up) { 1986 return new %(vldr_us)s(machInst, vd, rn, up, imm); 1987 } else { 1988 return new %(vldr_s)s(machInst, vd, rn, up, imm); 1989 } 1990 } else { 1991 if (up) { 1992 return new %(vldr_ud)s(machInst, vd, vd + 1, 1993 rn, up, imm); 1994 } else { 1995 return new %(vldr_d)s(machInst, vd, vd + 1, 1996 rn, up, imm); 1997 } 1998 } 1999 } 2000 } 2001 return new Unknown(machInst); 2002 } 2003 ''' % { 2004 "vldr_us" : "VLDR_" + loadImmClassName(False, True, False), 2005 "vldr_s" : "VLDR_" + loadImmClassName(False, False, False), 2006 "vldr_ud" : "VLDR_" + loadDoubleImmClassName(False, True, False), 2007 "vldr_d" : "VLDR_" + loadDoubleImmClassName(False, False, False), 2008 "vstr_us" : "VSTR_" + storeImmClassName(False, True, False), 2009 "vstr_s" : "VSTR_" + storeImmClassName(False, False, False), 2010 "vstr_ud" : "VSTR_" + storeDoubleImmClassName(False, True, False), 2011 "vstr_d" : "VSTR_" + storeDoubleImmClassName(False, False, False) 2012 } 2013}}; 2014 2015def format ExtensionRegLoadStore() {{ 2016 decode_block = ''' 2017 return decodeExtensionRegLoadStore(machInst); 2018 ''' 2019}}; 2020 2021let {{ 2022 header_output = ''' 2023 StaticInstPtr 2024 decodeShortFpTransfer(ExtMachInst machInst); 2025 ''' 2026 decoder_output = ''' 2027 IntRegIndex decodeFpVd(ExtMachInst machInst, uint32_t size, bool isInt) 2028 { 2029 if (!isInt and size == 3) { 2030 return (IntRegIndex)((bits(machInst, 22) << 5) | 2031 (bits(machInst, 15, 12) << 1)); 2032 } else { 2033 return (IntRegIndex)(bits(machInst, 22) | 2034 (bits(machInst, 15, 12) << 1)); 2035 } 2036 } 2037 IntRegIndex decodeFpVm(ExtMachInst machInst, uint32_t size, bool isInt) 2038 { 2039 if (!isInt and size == 3) { 2040 return (IntRegIndex)((bits(machInst, 5) << 5) | 2041 (bits(machInst, 3, 0) << 1)); 2042 } else { 2043 return (IntRegIndex)(bits(machInst, 5) | 2044 (bits(machInst, 3, 0) << 1)); 2045 } 2046 } 2047 StaticInstPtr 2048 decodeShortFpTransfer(ExtMachInst machInst) 2049 { 2050 const uint32_t l = bits(machInst, 20); 2051 const uint32_t c = bits(machInst, 8); 2052 const uint32_t a = bits(machInst, 23, 21); 2053 const uint32_t q = bits(machInst, 6, 5); 2054 const uint32_t o1 = bits(machInst, 18); 2055 if ((machInst.thumb == 1 && bits(machInst, 28) == 1) || 2056 (machInst.thumb == 0 && machInst.condCode == 0xf)) { 2057 // Determine if this is backported aarch64 FP instruction 2058 const bool b31_b24 = bits(machInst, 31, 24) == 0xFE; 2059 const bool b23 = bits(machInst, 23); 2060 const bool b21_b19 = bits(machInst, 21, 19) == 0x7; 2061 const bool b11_b9 = bits(machInst, 11, 9) == 0x5; 2062 const uint32_t size = bits(machInst, 9, 8); 2063 const bool op3 = bits(machInst, 6); 2064 const bool b4 = bits(machInst, 4) == 0x0; 2065 const uint32_t rm = bits(machInst, 17, 16); 2066 IntRegIndex vd = decodeFpVd(machInst, size, false); 2067 IntRegIndex vm = decodeFpVm(machInst, size, false); 2068 IntRegIndex vdInt = decodeFpVd(machInst, size, true); 2069 if (b31_b24 && b23 && b21_b19 && b11_b9 && op3 && b4) { 2070 if (o1 == 0) { 2071 // VINT* Integer Rounding Instruction 2072 if (size == 3) { 2073 switch(rm) { 2074 case 0x0: 2075 return decodeVfpRegRegOp<VRIntAD>(machInst, vd, vm, 2076 true); 2077 case 0x1: 2078 return decodeVfpRegRegOp<VRIntND>(machInst, vd, vm, 2079 true); 2080 case 0x2: 2081 return decodeVfpRegRegOp<VRIntPD>(machInst, vd, vm, 2082 true); 2083 case 0x3: 2084 return decodeVfpRegRegOp<VRIntMD>(machInst, vd, vm, 2085 true); 2086 default: return new Unknown(machInst); 2087 } 2088 } else { 2089 switch(rm) { 2090 case 0x0: 2091 return decodeVfpRegRegOp<VRIntAS>(machInst, vd, vm, 2092 false); 2093 case 0x1: 2094 return decodeVfpRegRegOp<VRIntNS>(machInst, vd, vm, 2095 false); 2096 case 0x2: 2097 return decodeVfpRegRegOp<VRIntPS>(machInst, vd, vm, 2098 false); 2099 case 0x3: 2100 return decodeVfpRegRegOp<VRIntMS>(machInst, vd, vm, 2101 false); 2102 default: return new Unknown(machInst); 2103 } 2104 } 2105 } else { 2106 const bool op = bits(machInst, 7); 2107 switch(rm) { 2108 case 0x0: 2109 switch(size) { 2110 case 0x0: 2111 return new Unknown(machInst); 2112 case 0x1: 2113 return new FailUnimplemented( 2114 "vcvta.u32.f16", machInst); 2115 case 0x2: 2116 if (op) { 2117 return new VcvtaFpSIntS(machInst, vdInt, vm); 2118 } else { 2119 return new VcvtaFpUIntS(machInst, vdInt, vm); 2120 } 2121 case 0x3: 2122 if (op) { 2123 return new VcvtaFpSIntD(machInst, vdInt, vm); 2124 } else { 2125 return new VcvtaFpUIntD(machInst, vdInt, vm); 2126 } 2127 default: return new Unknown(machInst); 2128 } 2129 case 0x1: 2130 switch(size) { 2131 case 0x0: 2132 return new Unknown(machInst); 2133 case 0x1: 2134 return new FailUnimplemented( 2135 "vcvtn.u32.f16", machInst); 2136 case 0x2: 2137 if (op) { 2138 return new VcvtnFpSIntS(machInst, vdInt, vm); 2139 } else { 2140 return new VcvtnFpUIntS(machInst, vdInt, vm); 2141 } 2142 case 0x3: 2143 if (op) { 2144 return new VcvtnFpSIntD(machInst, vdInt, vm); 2145 } else { 2146 return new VcvtnFpUIntD(machInst, vdInt, vm); 2147 } 2148 default: return new Unknown(machInst); 2149 } 2150 case 0x2: 2151 switch(size) { 2152 case 0x0: 2153 return new Unknown(machInst); 2154 case 0x1: 2155 return new FailUnimplemented( 2156 "vcvtp.u32.f16", machInst); 2157 case 0x2: 2158 if (op) { 2159 return new VcvtpFpSIntS(machInst, vdInt, vm); 2160 } else { 2161 return new VcvtpFpUIntS(machInst, vdInt, vm); 2162 } 2163 case 0x3: 2164 if (op) { 2165 return new VcvtpFpSIntD(machInst, vdInt, vm); 2166 } else { 2167 return new VcvtpFpUIntD(machInst, vdInt, vm); 2168 } 2169 default: return new Unknown(machInst); 2170 } 2171 case 0x3: 2172 switch(size) { 2173 case 0x0: 2174 return new Unknown(machInst); 2175 case 0x1: 2176 return new FailUnimplemented( 2177 "vcvtm.u32.f16", machInst); 2178 case 0x2: 2179 if (op) { 2180 return new VcvtmFpSIntS(machInst, vdInt, vm); 2181 } else { 2182 return new VcvtmFpUIntS(machInst, vdInt, vm); 2183 } 2184 case 0x3: 2185 if (op) { 2186 return new VcvtmFpSIntD(machInst, vdInt, vm); 2187 } else { 2188 return new VcvtmFpUIntD(machInst, vdInt, vm); 2189 } 2190 default: return new Unknown(machInst); 2191 } 2192 default: return new Unknown(machInst); 2193 } 2194 } 2195 } else if (b31_b24 && !b23 && b11_b9 && !op3 && b4){ 2196 // VSEL* floating point conditional select 2197 2198 ConditionCode cond; 2199 switch(bits(machInst, 21, 20)) { 2200 case 0x0: cond = COND_EQ; break; 2201 case 0x1: cond = COND_VS; break; 2202 case 0x2: cond = COND_GE; break; 2203 case 0x3: cond = COND_GT; break; 2204 } 2205 2206 if (size == 3) { 2207 const IntRegIndex vn = 2208 (IntRegIndex)((bits(machInst, 7) << 5) | 2209 (bits(machInst, 19, 16) << 1)); 2210 return new VselD(machInst, vd, vn, vm, cond); 2211 } else { 2212 const IntRegIndex vn = 2213 (IntRegIndex)((bits(machInst, 19, 16) << 1) | 2214 bits(machInst, 7)); 2215 return new VselS(machInst, vd, vn, vm, cond); 2216 } 2217 } else { 2218 return new Unknown(machInst); 2219 } 2220 } 2221 if (l == 0 && c == 0) { 2222 if (a == 0) { 2223 const uint32_t vn = (bits(machInst, 19, 16) << 1) | 2224 bits(machInst, 7); 2225 const IntRegIndex rt = 2226 (IntRegIndex)(uint32_t)bits(machInst, 15, 12); 2227 if (bits(machInst, 20) == 1) { 2228 return new VmovRegCoreW(machInst, rt, (IntRegIndex)vn); 2229 } else { 2230 return new VmovCoreRegW(machInst, (IntRegIndex)vn, rt); 2231 } 2232 } else if (a == 0x7) { 2233 const IntRegIndex rt = 2234 (IntRegIndex)(uint32_t)bits(machInst, 15, 12); 2235 uint32_t reg = bits(machInst, 19, 16); 2236 uint32_t specReg; 2237 switch (reg) { 2238 case 0: 2239 specReg = MISCREG_FPSID; 2240 break; 2241 case 1: 2242 specReg = MISCREG_FPSCR; 2243 break; 2244 case 6: 2245 specReg = MISCREG_MVFR1; 2246 break; 2247 case 7: 2248 specReg = MISCREG_MVFR0; 2249 break; 2250 case 8: 2251 specReg = MISCREG_FPEXC; 2252 break; 2253 default: 2254 return new Unknown(machInst); 2255 } 2256 if (specReg == MISCREG_FPSCR) { 2257 return new VmsrFpscr(machInst, (IntRegIndex)specReg, rt); 2258 } else { 2259 uint32_t iss = mcrMrcIssBuild(0, bits(machInst, 3, 0), rt, 2260 reg, a, bits(machInst, 7, 5)); 2261 return new Vmsr(machInst, (IntRegIndex)specReg, rt, iss); 2262 } 2263 } 2264 } else if (l == 0 && c == 1) { 2265 if (bits(a, 2) == 0) { 2266 uint32_t vd = (bits(machInst, 7) << 5) | 2267 (bits(machInst, 19, 16) << 1); 2268 // Handle accessing each single precision half of the vector. 2269 vd += bits(machInst, 21); 2270 const IntRegIndex rt = 2271 (IntRegIndex)(uint32_t)bits(machInst, 15, 12); 2272 if (bits(machInst, 22) == 1) { 2273 return new VmovCoreRegB(machInst, (IntRegIndex)vd, 2274 rt, bits(machInst, 6, 5)); 2275 } else if (bits(machInst, 5) == 1) { 2276 return new VmovCoreRegH(machInst, (IntRegIndex)vd, 2277 rt, bits(machInst, 6)); 2278 } else if (bits(machInst, 6) == 0) { 2279 return new VmovCoreRegW(machInst, (IntRegIndex)vd, rt); 2280 } else { 2281 return new Unknown(machInst); 2282 } 2283 } else if (bits(q, 1) == 0) { 2284 bool q = bits(machInst, 21); 2285 unsigned be = (bits(machInst, 22) << 1) | (bits(machInst, 5)); 2286 IntRegIndex vd = (IntRegIndex)(2 * (uint32_t) 2287 (bits(machInst, 19, 16) | (bits(machInst, 7) << 4))); 2288 IntRegIndex rt = (IntRegIndex)(uint32_t) 2289 bits(machInst, 15, 12); 2290 if (q) { 2291 switch (be) { 2292 case 0: 2293 return new NVdupQGpr<uint32_t>(machInst, vd, rt); 2294 case 1: 2295 return new NVdupQGpr<uint16_t>(machInst, vd, rt); 2296 case 2: 2297 return new NVdupQGpr<uint8_t>(machInst, vd, rt); 2298 case 3: 2299 return new Unknown(machInst); 2300 } 2301 } else { 2302 switch (be) { 2303 case 0: 2304 return new NVdupDGpr<uint32_t>(machInst, vd, rt); 2305 case 1: 2306 return new NVdupDGpr<uint16_t>(machInst, vd, rt); 2307 case 2: 2308 return new NVdupDGpr<uint8_t>(machInst, vd, rt); 2309 case 3: 2310 return new Unknown(machInst); 2311 } 2312 } 2313 } 2314 } else if (l == 1 && c == 0) { 2315 if (a == 0) { 2316 const uint32_t vn = (bits(machInst, 19, 16) << 1) | 2317 bits(machInst, 7); 2318 const IntRegIndex rt = 2319 (IntRegIndex)(uint32_t)bits(machInst, 15, 12); 2320 if (bits(machInst, 20) == 1) { 2321 return new VmovRegCoreW(machInst, rt, (IntRegIndex)vn); 2322 } else { 2323 return new VmovCoreRegW(machInst, (IntRegIndex)vn, rt); 2324 } 2325 } else if (a == 7) { 2326 const IntRegIndex rt = 2327 (IntRegIndex)(uint32_t)bits(machInst, 15, 12); 2328 uint32_t reg = bits(machInst, 19, 16); 2329 uint32_t specReg; 2330 switch (reg) { 2331 case 0: 2332 specReg = MISCREG_FPSID; 2333 break; 2334 case 1: 2335 specReg = MISCREG_FPSCR; 2336 break; 2337 case 6: 2338 specReg = MISCREG_MVFR1; 2339 break; 2340 case 7: 2341 specReg = MISCREG_MVFR0; 2342 break; 2343 case 8: 2344 specReg = MISCREG_FPEXC; 2345 break; 2346 default: 2347 return new Unknown(machInst); 2348 } 2349 if (rt == 0xf) { 2350 if (specReg == MISCREG_FPSCR) { 2351 return new VmrsApsrFpscr(machInst); 2352 } else { 2353 return new Unknown(machInst); 2354 } 2355 } else if (specReg == MISCREG_FPSCR) { 2356 return new VmrsFpscr(machInst, rt, (IntRegIndex)specReg); 2357 } else { 2358 uint32_t iss = mcrMrcIssBuild(l, bits(machInst, 3, 0), rt, 2359 reg, a, bits(machInst, 7, 5)); 2360 return new Vmrs(machInst, rt, (IntRegIndex)specReg, iss); 2361 } 2362 } 2363 } else { 2364 uint32_t vd = (bits(machInst, 7) << 5) | 2365 (bits(machInst, 19, 16) << 1); 2366 // Handle indexing into each single precision half of the vector. 2367 vd += bits(machInst, 21); 2368 uint32_t index; 2369 const IntRegIndex rt = 2370 (IntRegIndex)(uint32_t)bits(machInst, 15, 12); 2371 const bool u = (bits(machInst, 23) == 1); 2372 if (bits(machInst, 22) == 1) { 2373 index = bits(machInst, 6, 5); 2374 if (u) { 2375 return new VmovRegCoreUB(machInst, rt, 2376 (IntRegIndex)vd, index); 2377 } else { 2378 return new VmovRegCoreSB(machInst, rt, 2379 (IntRegIndex)vd, index); 2380 } 2381 } else if (bits(machInst, 5) == 1) { 2382 index = bits(machInst, 6); 2383 if (u) { 2384 return new VmovRegCoreUH(machInst, rt, 2385 (IntRegIndex)vd, index); 2386 } else { 2387 return new VmovRegCoreSH(machInst, rt, 2388 (IntRegIndex)vd, index); 2389 } 2390 } else if (bits(machInst, 6) == 0 && !u) { 2391 return new VmovRegCoreW(machInst, rt, (IntRegIndex)vd); 2392 } else { 2393 return new Unknown(machInst); 2394 } 2395 } 2396 return new Unknown(machInst); 2397 } 2398 ''' 2399}}; 2400 2401def format ShortFpTransfer() {{ 2402 decode_block = ''' 2403 return decodeShortFpTransfer(machInst); 2404 ''' 2405}}; 2406 2407let {{ 2408 header_output = ''' 2409 StaticInstPtr 2410 decodeVfpData(ExtMachInst machInst); 2411 ''' 2412 decoder_output = ''' 2413 StaticInstPtr 2414 decodeVfpData(ExtMachInst machInst) 2415 { 2416 const uint32_t opc1 = bits(machInst, 23, 20); 2417 const uint32_t opc2 = bits(machInst, 19, 16); 2418 const uint32_t opc3 = bits(machInst, 7, 6); 2419 //const uint32_t opc4 = bits(machInst, 3, 0); 2420 const bool single = (bits(machInst, 8) == 0); 2421 // Used to select between vcmp and vcmpe. 2422 const bool e = (bits(machInst, 7) == 1); 2423 IntRegIndex vd; 2424 IntRegIndex vm; 2425 IntRegIndex vn; 2426 if (single) { 2427 vd = (IntRegIndex)(bits(machInst, 22) | 2428 (bits(machInst, 15, 12) << 1)); 2429 vm = (IntRegIndex)(bits(machInst, 5) | 2430 (bits(machInst, 3, 0) << 1)); 2431 vn = (IntRegIndex)(bits(machInst, 7) | 2432 (bits(machInst, 19, 16) << 1)); 2433 } else { 2434 vd = (IntRegIndex)((bits(machInst, 22) << 5) | 2435 (bits(machInst, 15, 12) << 1)); 2436 vm = (IntRegIndex)((bits(machInst, 5) << 5) | 2437 (bits(machInst, 3, 0) << 1)); 2438 vn = (IntRegIndex)((bits(machInst, 7) << 5) | 2439 (bits(machInst, 19, 16) << 1)); 2440 } 2441 switch (opc1 & 0xb /* 1011 */) { 2442 case 0x0: 2443 if (bits(machInst, 6) == 0) { 2444 if (single) { 2445 return decodeVfpRegRegRegOp<VmlaS>( 2446 machInst, vd, vn, vm, false); 2447 } else { 2448 return decodeVfpRegRegRegOp<VmlaD>( 2449 machInst, vd, vn, vm, true); 2450 } 2451 } else { 2452 if (single) { 2453 return decodeVfpRegRegRegOp<VmlsS>( 2454 machInst, vd, vn, vm, false); 2455 } else { 2456 return decodeVfpRegRegRegOp<VmlsD>( 2457 machInst, vd, vn, vm, true); 2458 } 2459 } 2460 case 0x1: 2461 if (bits(machInst, 6) == 1) { 2462 if (single) { 2463 return decodeVfpRegRegRegOp<VnmlaS>( 2464 machInst, vd, vn, vm, false); 2465 } else { 2466 return decodeVfpRegRegRegOp<VnmlaD>( 2467 machInst, vd, vn, vm, true); 2468 } 2469 } else { 2470 if (single) { 2471 return decodeVfpRegRegRegOp<VnmlsS>( 2472 machInst, vd, vn, vm, false); 2473 } else { 2474 return decodeVfpRegRegRegOp<VnmlsD>( 2475 machInst, vd, vn, vm, true); 2476 } 2477 } 2478 case 0x2: 2479 if ((opc3 & 0x1) == 0) { 2480 if (single) { 2481 return decodeVfpRegRegRegOp<VmulS>( 2482 machInst, vd, vn, vm, false); 2483 } else { 2484 return decodeVfpRegRegRegOp<VmulD>( 2485 machInst, vd, vn, vm, true); 2486 } 2487 } else { 2488 if (single) { 2489 return decodeVfpRegRegRegOp<VnmulS>( 2490 machInst, vd, vn, vm, false); 2491 } else { 2492 return decodeVfpRegRegRegOp<VnmulD>( 2493 machInst, vd, vn, vm, true); 2494 } 2495 } 2496 case 0x3: 2497 if ((opc3 & 0x1) == 0) { 2498 if (single) { 2499 return decodeVfpRegRegRegOp<VaddS>( 2500 machInst, vd, vn, vm, false); 2501 } else { 2502 return decodeVfpRegRegRegOp<VaddD>( 2503 machInst, vd, vn, vm, true); 2504 } 2505 } else { 2506 if (single) { 2507 return decodeVfpRegRegRegOp<VsubS>( 2508 machInst, vd, vn, vm, false); 2509 } else { 2510 return decodeVfpRegRegRegOp<VsubD>( 2511 machInst, vd, vn, vm, true); 2512 } 2513 } 2514 case 0x8: 2515 if ((opc3 & 0x1) == 0) { 2516 if (single) { 2517 return decodeVfpRegRegRegOp<VdivS>( 2518 machInst, vd, vn, vm, false); 2519 } else { 2520 return decodeVfpRegRegRegOp<VdivD>( 2521 machInst, vd, vn, vm, true); 2522 } 2523 } 2524 break; 2525 case 0x9: 2526 if ((opc3 & 0x1) == 0) { 2527 if (single) { 2528 return decodeVfpRegRegRegOp<VfnmaS>( 2529 machInst, vd, vn, vm, false); 2530 } else { 2531 return decodeVfpRegRegRegOp<VfnmaD>( 2532 machInst, vd, vn, vm, true); 2533 } 2534 } else { 2535 if (single) { 2536 return decodeVfpRegRegRegOp<VfnmsS>( 2537 machInst, vd, vn, vm, false); 2538 } else { 2539 return decodeVfpRegRegRegOp<VfnmsD>( 2540 machInst, vd, vn, vm, true); 2541 } 2542 } 2543 break; 2544 case 0xa: 2545 if ((opc3 & 0x1) == 0) { 2546 if (single) { 2547 return decodeVfpRegRegRegOp<VfmaS>( 2548 machInst, vd, vn, vm, false); 2549 } else { 2550 return decodeVfpRegRegRegOp<VfmaD>( 2551 machInst, vd, vn, vm, true); 2552 } 2553 } else { 2554 if (single) { 2555 return decodeVfpRegRegRegOp<VfmsS>( 2556 machInst, vd, vn, vm, false); 2557 } else { 2558 return decodeVfpRegRegRegOp<VfmsD>( 2559 machInst, vd, vn, vm, true); 2560 } 2561 } 2562 break; 2563 case 0xb: 2564 if ((opc3 & 0x1) == 0) { 2565 const uint32_t baseImm = 2566 bits(machInst, 3, 0) | (bits(machInst, 19, 16) << 4); 2567 if (single) { 2568 uint32_t imm = vfp_modified_imm(baseImm, FpDataType::Fp32); 2569 return decodeVfpRegImmOp<VmovImmS>( 2570 machInst, vd, imm, false); 2571 } else { 2572 uint64_t imm = vfp_modified_imm(baseImm, FpDataType::Fp64); 2573 return decodeVfpRegImmOp<VmovImmD>( 2574 machInst, vd, imm, true); 2575 } 2576 } 2577 switch (opc2) { 2578 case 0x0: 2579 if (opc3 == 1) { 2580 if (single) { 2581 return decodeVfpRegRegOp<VmovRegS>( 2582 machInst, vd, vm, false); 2583 } else { 2584 return decodeVfpRegRegOp<VmovRegD>( 2585 machInst, vd, vm, true); 2586 } 2587 } else { 2588 if (single) { 2589 return decodeVfpRegRegOp<VabsS>( 2590 machInst, vd, vm, false); 2591 } else { 2592 return decodeVfpRegRegOp<VabsD>( 2593 machInst, vd, vm, true); 2594 } 2595 } 2596 case 0x1: 2597 if (opc3 == 1) { 2598 if (single) { 2599 return decodeVfpRegRegOp<VnegS>( 2600 machInst, vd, vm, false); 2601 } else { 2602 return decodeVfpRegRegOp<VnegD>( 2603 machInst, vd, vm, true); 2604 } 2605 } else { 2606 if (single) { 2607 return decodeVfpRegRegOp<VsqrtS>( 2608 machInst, vd, vm, false); 2609 } else { 2610 return decodeVfpRegRegOp<VsqrtD>( 2611 machInst, vd, vm, true); 2612 } 2613 } 2614 case 0x2: 2615 case 0x3: 2616 { 2617 const bool toHalf = bits(machInst, 16); 2618 const bool top = bits(machInst, 7); 2619 if (top) { 2620 if (toHalf) { 2621 return new VcvtFpSFpHT(machInst, vd, vm); 2622 } else { 2623 return new VcvtFpHTFpS(machInst, vd, vm); 2624 } 2625 } else { 2626 if (toHalf) { 2627 return new VcvtFpSFpHB(machInst, vd, vm); 2628 } else { 2629 return new VcvtFpHBFpS(machInst, vd, vm); 2630 } 2631 } 2632 } 2633 case 0x4: 2634 if (single) { 2635 if (e) { 2636 return new VcmpeS(machInst, vd, vm); 2637 } else { 2638 return new VcmpS(machInst, vd, vm); 2639 } 2640 } else { 2641 if (e) { 2642 return new VcmpeD(machInst, vd, vm); 2643 } else { 2644 return new VcmpD(machInst, vd, vm); 2645 } 2646 } 2647 case 0x5: 2648 if (single) { 2649 if (e) { 2650 return new VcmpeZeroS(machInst, vd, 0); 2651 } else { 2652 return new VcmpZeroS(machInst, vd, 0); 2653 } 2654 } else { 2655 if (e) { 2656 return new VcmpeZeroD(machInst, vd, 0); 2657 } else { 2658 return new VcmpZeroD(machInst, vd, 0); 2659 } 2660 } 2661 case 0x7: 2662 if (opc3 == 0x3) { 2663 if (single) { 2664 vd = (IntRegIndex)((bits(machInst, 22) << 5) | 2665 (bits(machInst, 15, 12) << 1)); 2666 return new VcvtFpSFpD(machInst, vd, vm); 2667 } else { 2668 vd = (IntRegIndex)(bits(machInst, 22) | 2669 (bits(machInst, 15, 12) << 1)); 2670 return new VcvtFpDFpS(machInst, vd, vm); 2671 } 2672 } 2673 break; 2674 case 0x8: 2675 if (bits(machInst, 7) == 0) { 2676 if (single) { 2677 return new VcvtUIntFpS(machInst, vd, vm); 2678 } else { 2679 vm = (IntRegIndex)(bits(machInst, 5) | 2680 (bits(machInst, 3, 0) << 1)); 2681 return new VcvtUIntFpD(machInst, vd, vm); 2682 } 2683 } else { 2684 if (single) { 2685 return new VcvtSIntFpS(machInst, vd, vm); 2686 } else { 2687 vm = (IntRegIndex)(bits(machInst, 5) | 2688 (bits(machInst, 3, 0) << 1)); 2689 return new VcvtSIntFpD(machInst, vd, vm); 2690 } 2691 } 2692 case 0xa: 2693 { 2694 const bool half = (bits(machInst, 7) == 0); 2695 const uint32_t imm = bits(machInst, 5) | 2696 (bits(machInst, 3, 0) << 1); 2697 const uint32_t size = 2698 (bits(machInst, 7) == 0 ? 16 : 32) - imm; 2699 if (single) { 2700 if (half) { 2701 return new VcvtSHFixedFpS(machInst, vd, vd, size); 2702 } else { 2703 return new VcvtSFixedFpS(machInst, vd, vd, size); 2704 } 2705 } else { 2706 if (half) { 2707 return new VcvtSHFixedFpD(machInst, vd, vd, size); 2708 } else { 2709 return new VcvtSFixedFpD(machInst, vd, vd, size); 2710 } 2711 } 2712 } 2713 case 0xb: 2714 { 2715 const bool half = (bits(machInst, 7) == 0); 2716 const uint32_t imm = bits(machInst, 5) | 2717 (bits(machInst, 3, 0) << 1); 2718 const uint32_t size = 2719 (bits(machInst, 7) == 0 ? 16 : 32) - imm; 2720 if (single) { 2721 if (half) { 2722 return new VcvtUHFixedFpS(machInst, vd, vd, size); 2723 } else { 2724 return new VcvtUFixedFpS(machInst, vd, vd, size); 2725 } 2726 } else { 2727 if (half) { 2728 return new VcvtUHFixedFpD(machInst, vd, vd, size); 2729 } else { 2730 return new VcvtUFixedFpD(machInst, vd, vd, size); 2731 } 2732 } 2733 } 2734 case 0xc: 2735 if (bits(machInst, 7) == 0) { 2736 if (single) { 2737 return new VcvtFpUIntSR(machInst, vd, vm); 2738 } else { 2739 vd = (IntRegIndex)(bits(machInst, 22) | 2740 (bits(machInst, 15, 12) << 1)); 2741 return new VcvtFpUIntDR(machInst, vd, vm); 2742 } 2743 } else { 2744 if (single) { 2745 return new VcvtFpUIntS(machInst, vd, vm); 2746 } else { 2747 vd = (IntRegIndex)(bits(machInst, 22) | 2748 (bits(machInst, 15, 12) << 1)); 2749 return new VcvtFpUIntD(machInst, vd, vm); 2750 } 2751 } 2752 case 0xd: 2753 if (bits(machInst, 7) == 0) { 2754 if (single) { 2755 return new VcvtFpSIntSR(machInst, vd, vm); 2756 } else { 2757 vd = (IntRegIndex)(bits(machInst, 22) | 2758 (bits(machInst, 15, 12) << 1)); 2759 return new VcvtFpSIntDR(machInst, vd, vm); 2760 } 2761 } else { 2762 if (single) { 2763 return new VcvtFpSIntS(machInst, vd, vm); 2764 } else { 2765 vd = (IntRegIndex)(bits(machInst, 22) | 2766 (bits(machInst, 15, 12) << 1)); 2767 return new VcvtFpSIntD(machInst, vd, vm); 2768 } 2769 } 2770 case 0xe: 2771 { 2772 const bool half = (bits(machInst, 7) == 0); 2773 const uint32_t imm = bits(machInst, 5) | 2774 (bits(machInst, 3, 0) << 1); 2775 const uint32_t size = 2776 (bits(machInst, 7) == 0 ? 16 : 32) - imm; 2777 if (single) { 2778 if (half) { 2779 return new VcvtFpSHFixedS(machInst, vd, vd, size); 2780 } else { 2781 return new VcvtFpSFixedS(machInst, vd, vd, size); 2782 } 2783 } else { 2784 if (half) { 2785 return new VcvtFpSHFixedD(machInst, vd, vd, size); 2786 } else { 2787 return new VcvtFpSFixedD(machInst, vd, vd, size); 2788 } 2789 } 2790 } 2791 case 0xf: 2792 { 2793 const bool half = (bits(machInst, 7) == 0); 2794 const uint32_t imm = bits(machInst, 5) | 2795 (bits(machInst, 3, 0) << 1); 2796 const uint32_t size = 2797 (bits(machInst, 7) == 0 ? 16 : 32) - imm; 2798 if (single) { 2799 if (half) { 2800 return new VcvtFpUHFixedS(machInst, vd, vd, size); 2801 } else { 2802 return new VcvtFpUFixedS(machInst, vd, vd, size); 2803 } 2804 } else { 2805 if (half) { 2806 return new VcvtFpUHFixedD(machInst, vd, vd, size); 2807 } else { 2808 return new VcvtFpUFixedD(machInst, vd, vd, size); 2809 } 2810 } 2811 } 2812 } 2813 break; 2814 } 2815 return new Unknown(machInst); 2816 } 2817 ''' 2818}}; 2819 2820def format VfpData() {{ 2821 decode_block = ''' 2822 return decodeVfpData(machInst); 2823 ''' 2824}}; 2825