fp.isa revision 7394:bd00fbc41bb1
1// -*- mode:c++ -*- 2 3// Copyright (c) 2010 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 48def template FPAExecute {{ 49 Fault %(class_name)s::execute(%(CPU_exec_context)s *xc, Trace::InstRecord *traceData) const 50 { 51 Fault fault = NoFault; 52 53 %(fp_enable_check)s; 54 55 %(op_decl)s; 56 %(op_rd)s; 57 58 if (%(predicate_test)s) { 59 %(code)s; 60 if (fault == NoFault) { 61 %(op_wb)s; 62 } 63 } 64 65 return fault; 66 } 67}}; 68 69def template FloatDoubleDecode {{ 70 { 71 ArmStaticInst *i = NULL; 72 switch (OPCODE_19 << 1 | OPCODE_7) 73 { 74 case 0: 75 i = (ArmStaticInst *)new %(class_name)sS(machInst); 76 break; 77 case 1: 78 i = (ArmStaticInst *)new %(class_name)sD(machInst); 79 break; 80 case 2: 81 case 3: 82 default: 83 panic("Cannot decode float/double nature of the instruction"); 84 } 85 return i; 86 } 87}}; 88 89// Primary format for float point operate instructions: 90def format FloatOp(code, *flags) {{ 91 orig_code = code 92 93 cblk = code 94 iop = InstObjParams(name, Name, 'PredOp', 95 {"code": cblk, 96 "predicate_test": predicateTest}, 97 flags) 98 header_output = BasicDeclare.subst(iop) 99 decoder_output = BasicConstructor.subst(iop) 100 exec_output = FPAExecute.subst(iop) 101 102 sng_cblk = code 103 sng_iop = InstObjParams(name, Name+'S', 'PredOp', 104 {"code": sng_cblk, 105 "predicate_test": predicateTest}, 106 flags) 107 header_output += BasicDeclare.subst(sng_iop) 108 decoder_output += BasicConstructor.subst(sng_iop) 109 exec_output += FPAExecute.subst(sng_iop) 110 111 dbl_code = re.sub(r'\.sf', '.df', orig_code) 112 113 dbl_cblk = dbl_code 114 dbl_iop = InstObjParams(name, Name+'D', 'PredOp', 115 {"code": dbl_cblk, 116 "predicate_test": predicateTest}, 117 flags) 118 header_output += BasicDeclare.subst(dbl_iop) 119 decoder_output += BasicConstructor.subst(dbl_iop) 120 exec_output += FPAExecute.subst(dbl_iop) 121 122 decode_block = FloatDoubleDecode.subst(iop) 123}}; 124 125let {{ 126 calcFPCcCode = ''' 127 uint16_t _in, _iz, _ic, _iv; 128 129 _in = %(fReg1)s < %(fReg2)s; 130 _iz = %(fReg1)s == %(fReg2)s; 131 _ic = %(fReg1)s >= %(fReg2)s; 132 _iv = (isnan(%(fReg1)s) || isnan(%(fReg2)s)) & 1; 133 134 CondCodes = _in << 31 | _iz << 30 | _ic << 29 | _iv << 28 | 135 (CondCodes & 0x0FFFFFFF); 136 ''' 137}}; 138 139def format FloatCmp(fReg1, fReg2, *flags) {{ 140 code = calcFPCcCode % vars() 141 iop = InstObjParams(name, Name, 'PredOp', 142 {"code": code, 143 "predicate_test": predicateTest}, 144 flags) 145 header_output = BasicDeclare.subst(iop) 146 decoder_output = BasicConstructor.subst(iop) 147 decode_block = BasicDecode.subst(iop) 148 exec_output = FPAExecute.subst(iop) 149}}; 150 151let {{ 152 header_output = ''' 153 StaticInstPtr 154 decodeExtensionRegLoadStore(ExtMachInst machInst); 155 ''' 156 decoder_output = ''' 157 StaticInstPtr 158 decodeExtensionRegLoadStore(ExtMachInst machInst) 159 { 160 const uint32_t opcode = bits(machInst, 24, 20); 161 const uint32_t offset = bits(machInst, 7, 0); 162 const bool single = (bits(machInst, 8) == 0); 163 const IntRegIndex rn = (IntRegIndex)(uint32_t)bits(machInst, 19, 16); 164 RegIndex vd; 165 if (single) { 166 vd = (RegIndex)(uint32_t)((bits(machInst, 15, 12) << 1) | 167 bits(machInst, 22)); 168 } else { 169 vd = (RegIndex)(uint32_t)((bits(machInst, 15, 12) << 1) | 170 (bits(machInst, 22) << 5)); 171 } 172 switch (bits(opcode, 4, 3)) { 173 case 0x0: 174 if (bits(opcode, 4, 1) == 0x2 && 175 !(machInst.thumb == 1 && bits(machInst, 28) == 1) && 176 !(machInst.thumb == 0 && machInst.condCode == 0xf)) { 177 if ((bits(machInst, 7, 4) & 0xd) != 1) { 178 break; 179 } 180 const IntRegIndex rt = 181 (IntRegIndex)(uint32_t)bits(machInst, 15, 12); 182 const IntRegIndex rt2 = 183 (IntRegIndex)(uint32_t)bits(machInst, 19, 16); 184 const bool op = bits(machInst, 20); 185 uint32_t vm; 186 if (single) { 187 vm = (bits(machInst, 3, 0) << 1) | bits(machInst, 5); 188 } else { 189 vm = (bits(machInst, 3, 0) << 1) | 190 (bits(machInst, 5) << 5); 191 } 192 if (op) { 193 return new Vmov2Core2Reg(machInst, rt, rt2, 194 (IntRegIndex)vm); 195 } else { 196 return new Vmov2Reg2Core(machInst, (IntRegIndex)vm, 197 rt, rt2); 198 } 199 } 200 break; 201 case 0x1: 202 switch (bits(opcode, 1, 0)) { 203 case 0x0: 204 return new VLdmStm(machInst, rn, vd, single, 205 true, false, false, offset); 206 case 0x1: 207 return new VLdmStm(machInst, rn, vd, single, 208 true, false, true, offset); 209 case 0x2: 210 return new VLdmStm(machInst, rn, vd, single, 211 true, true, false, offset); 212 case 0x3: 213 // If rn == sp, then this is called vpop. 214 return new VLdmStm(machInst, rn, vd, single, 215 true, true, true, offset); 216 } 217 case 0x2: 218 if (bits(opcode, 1, 0) == 0x2) { 219 // If rn == sp, then this is called vpush. 220 return new VLdmStm(machInst, rn, vd, single, 221 false, true, false, offset); 222 } else if (bits(opcode, 1, 0) == 0x3) { 223 return new VLdmStm(machInst, rn, vd, single, 224 false, true, true, offset); 225 } 226 // Fall through on purpose 227 case 0x3: 228 const bool up = (bits(machInst, 23) == 1); 229 const uint32_t imm = bits(machInst, 7, 0) << 2; 230 RegIndex vd; 231 if (single) { 232 vd = (RegIndex)(uint32_t)((bits(machInst, 15, 12) << 1) | 233 (bits(machInst, 22))); 234 } else { 235 vd = (RegIndex)(uint32_t)((bits(machInst, 15, 12) << 1) | 236 (bits(machInst, 22) << 5)); 237 } 238 if (bits(opcode, 1, 0) == 0x0) { 239 if (single) { 240 if (up) { 241 return new %(vstr_us)s(machInst, vd, rn, up, imm); 242 } else { 243 return new %(vstr_s)s(machInst, vd, rn, up, imm); 244 } 245 } else { 246 if (up) { 247 return new %(vstr_ud)s(machInst, vd, vd + 1, 248 rn, up, imm); 249 } else { 250 return new %(vstr_d)s(machInst, vd, vd + 1, 251 rn, up, imm); 252 } 253 } 254 } else if (bits(opcode, 1, 0) == 0x1) { 255 if (single) { 256 if (up) { 257 return new %(vldr_us)s(machInst, vd, rn, up, imm); 258 } else { 259 return new %(vldr_s)s(machInst, vd, rn, up, imm); 260 } 261 } else { 262 if (up) { 263 return new %(vldr_ud)s(machInst, vd, vd + 1, 264 rn, up, imm); 265 } else { 266 return new %(vldr_d)s(machInst, vd, vd + 1, 267 rn, up, imm); 268 } 269 } 270 } 271 } 272 return new Unknown(machInst); 273 } 274 ''' % { 275 "vldr_us" : "VLDR_" + loadImmClassName(False, True, False), 276 "vldr_s" : "VLDR_" + loadImmClassName(False, False, False), 277 "vldr_ud" : "VLDR_" + loadDoubleImmClassName(False, True, False), 278 "vldr_d" : "VLDR_" + loadDoubleImmClassName(False, False, False), 279 "vstr_us" : "VSTR_" + storeImmClassName(False, True, False), 280 "vstr_s" : "VSTR_" + storeImmClassName(False, False, False), 281 "vstr_ud" : "VSTR_" + storeDoubleImmClassName(False, True, False), 282 "vstr_d" : "VSTR_" + storeDoubleImmClassName(False, False, False) 283 } 284}}; 285 286def format ExtensionRegLoadStore() {{ 287 decode_block = ''' 288 return decodeExtensionRegLoadStore(machInst); 289 ''' 290}}; 291 292let {{ 293 header_output = ''' 294 StaticInstPtr 295 decodeShortFpTransfer(ExtMachInst machInst); 296 ''' 297 decoder_output = ''' 298 StaticInstPtr 299 decodeShortFpTransfer(ExtMachInst machInst) 300 { 301 const uint32_t l = bits(machInst, 20); 302 const uint32_t c = bits(machInst, 8); 303 const uint32_t a = bits(machInst, 23, 21); 304 const uint32_t b = bits(machInst, 6, 5); 305 if ((machInst.thumb == 1 && bits(machInst, 28) == 1) || 306 (machInst.thumb == 0 && machInst.condCode == 0xf)) { 307 return new Unknown(machInst); 308 } 309 if (l == 0 && c == 0) { 310 if (a == 0) { 311 const uint32_t vn = (bits(machInst, 19, 16) << 1) | 312 bits(machInst, 7); 313 const IntRegIndex rt = 314 (IntRegIndex)(uint32_t)bits(machInst, 15, 12); 315 if (bits(machInst, 20) == 1) { 316 return new VmovRegCoreW(machInst, rt, (IntRegIndex)vn); 317 } else { 318 return new VmovCoreRegW(machInst, (IntRegIndex)vn, rt); 319 } 320 } else if (a == 0x7) { 321 const IntRegIndex rt = 322 (IntRegIndex)(uint32_t)bits(machInst, 15, 12); 323 uint32_t specReg = bits(machInst, 19, 16); 324 switch (specReg) { 325 case 0: 326 specReg = MISCREG_FPSID; 327 break; 328 case 1: 329 specReg = MISCREG_FPSCR; 330 break; 331 case 6: 332 specReg = MISCREG_MVFR1; 333 break; 334 case 7: 335 specReg = MISCREG_MVFR0; 336 break; 337 case 8: 338 specReg = MISCREG_FPEXC; 339 break; 340 default: 341 return new Unknown(machInst); 342 } 343 return new Vmsr(machInst, (IntRegIndex)specReg, rt); 344 } 345 } else if (l == 0 && c == 1) { 346 if (bits(a, 2) == 0) { 347 uint32_t vd = (bits(machInst, 7) << 5) | 348 (bits(machInst, 19, 16) << 1); 349 uint32_t index, size; 350 const IntRegIndex rt = 351 (IntRegIndex)(uint32_t)bits(machInst, 15, 12); 352 if (bits(machInst, 22) == 1) { 353 size = 8; 354 index = (bits(machInst, 21) << 2) | 355 bits(machInst, 6, 5); 356 } else if (bits(machInst, 5) == 1) { 357 size = 16; 358 index = (bits(machInst, 21) << 1) | 359 bits(machInst, 6); 360 } else if (bits(machInst, 6) == 0) { 361 size = 32; 362 index = bits(machInst, 21); 363 } else { 364 return new Unknown(machInst); 365 } 366 if (index >= (32 / size)) { 367 index -= (32 / size); 368 vd++; 369 } 370 switch (size) { 371 case 8: 372 return new VmovCoreRegB(machInst, (IntRegIndex)vd, 373 rt, index); 374 case 16: 375 return new VmovCoreRegH(machInst, (IntRegIndex)vd, 376 rt, index); 377 case 32: 378 return new VmovCoreRegW(machInst, (IntRegIndex)vd, rt); 379 } 380 } else if (bits(b, 1) == 0) { 381 // A8-594 382 return new WarnUnimplemented("vdup", machInst); 383 } 384 } else if (l == 1 && c == 0) { 385 if (a == 0) { 386 const uint32_t vn = (bits(machInst, 19, 16) << 1) | 387 bits(machInst, 7); 388 const IntRegIndex rt = 389 (IntRegIndex)(uint32_t)bits(machInst, 15, 12); 390 if (bits(machInst, 20) == 1) { 391 return new VmovRegCoreW(machInst, rt, (IntRegIndex)vn); 392 } else { 393 return new VmovCoreRegW(machInst, (IntRegIndex)vn, rt); 394 } 395 } else if (a == 7) { 396 const IntRegIndex rt = 397 (IntRegIndex)(uint32_t)bits(machInst, 15, 12); 398 uint32_t specReg = bits(machInst, 19, 16); 399 switch (specReg) { 400 case 0: 401 specReg = MISCREG_FPSID; 402 break; 403 case 1: 404 specReg = MISCREG_FPSCR; 405 break; 406 case 6: 407 specReg = MISCREG_MVFR1; 408 break; 409 case 7: 410 specReg = MISCREG_MVFR0; 411 break; 412 case 8: 413 specReg = MISCREG_FPEXC; 414 break; 415 default: 416 return new Unknown(machInst); 417 } 418 if (rt == 0xf) { 419 CPSR cpsrMask = 0; 420 cpsrMask.n = 1; 421 cpsrMask.z = 1; 422 cpsrMask.c = 1; 423 cpsrMask.v = 1; 424 return new VmrsApsr(machInst, INTREG_CONDCODES, 425 (IntRegIndex)specReg, (uint32_t)cpsrMask); 426 } else { 427 return new Vmrs(machInst, rt, (IntRegIndex)specReg); 428 } 429 } 430 } else { 431 uint32_t vd = (bits(machInst, 7) << 5) | 432 (bits(machInst, 19, 16) << 1); 433 uint32_t index, size; 434 const IntRegIndex rt = 435 (IntRegIndex)(uint32_t)bits(machInst, 15, 12); 436 const bool u = (bits(machInst, 23) == 1); 437 if (bits(machInst, 22) == 1) { 438 size = 8; 439 index = (bits(machInst, 21) << 2) | 440 bits(machInst, 6, 5); 441 } else if (bits(machInst, 5) == 1) { 442 size = 16; 443 index = (bits(machInst, 21) << 1) | 444 bits(machInst, 6); 445 } else if (bits(machInst, 6) == 0 && !u) { 446 size = 32; 447 index = bits(machInst, 21); 448 } else { 449 return new Unknown(machInst); 450 } 451 if (index >= (32 / size)) { 452 index -= (32 / size); 453 vd++; 454 } 455 switch (size) { 456 case 8: 457 if (u) { 458 return new VmovRegCoreUB(machInst, rt, 459 (IntRegIndex)vd, index); 460 } else { 461 return new VmovRegCoreSB(machInst, rt, 462 (IntRegIndex)vd, index); 463 } 464 case 16: 465 if (u) { 466 return new VmovRegCoreUH(machInst, rt, 467 (IntRegIndex)vd, index); 468 } else { 469 return new VmovRegCoreSH(machInst, rt, 470 (IntRegIndex)vd, index); 471 } 472 case 32: 473 return new VmovRegCoreW(machInst, rt, (IntRegIndex)vd); 474 } 475 } 476 return new Unknown(machInst); 477 } 478 ''' 479}}; 480 481def format ShortFpTransfer() {{ 482 decode_block = ''' 483 return decodeShortFpTransfer(machInst); 484 ''' 485}}; 486 487let {{ 488 header_output = ''' 489 StaticInstPtr 490 decodeVfpData(ExtMachInst machInst); 491 ''' 492 decoder_output = ''' 493 StaticInstPtr 494 decodeVfpData(ExtMachInst machInst) 495 { 496 const uint32_t opc1 = bits(machInst, 23, 20); 497 const uint32_t opc2 = bits(machInst, 19, 16); 498 const uint32_t opc3 = bits(machInst, 7, 6); 499 //const uint32_t opc4 = bits(machInst, 3, 0); 500 const bool single = (bits(machInst, 8) == 0); 501 // Used to select between vcmp and vcmpe. 502 const bool e = (bits(machInst, 7) == 1); 503 IntRegIndex vd; 504 IntRegIndex vm; 505 IntRegIndex vn; 506 if (single) { 507 vd = (IntRegIndex)(bits(machInst, 22) | 508 (bits(machInst, 15, 12) << 1)); 509 vm = (IntRegIndex)(bits(machInst, 5) | 510 (bits(machInst, 3, 0) << 1)); 511 vn = (IntRegIndex)(bits(machInst, 7) | 512 (bits(machInst, 19, 16) << 1)); 513 } else { 514 vd = (IntRegIndex)((bits(machInst, 22) << 5) | 515 (bits(machInst, 15, 12) << 1)); 516 vm = (IntRegIndex)((bits(machInst, 5) << 5) | 517 (bits(machInst, 3, 0) << 1)); 518 vn = (IntRegIndex)((bits(machInst, 7) << 5) | 519 (bits(machInst, 19, 16) << 1)); 520 } 521 switch (opc1 & 0xb /* 1011 */) { 522 case 0x0: 523 if (bits(machInst, 6) == 0) { 524 if (single) { 525 return decodeVfpRegRegRegOp<VmlaS>( 526 machInst, vd, vn, vm, false); 527 } else { 528 return decodeVfpRegRegRegOp<VmlaD>( 529 machInst, vd, vn, vm, true); 530 } 531 } else { 532 if (single) { 533 return decodeVfpRegRegRegOp<VmlsS>( 534 machInst, vd, vn, vm, false); 535 } else { 536 return decodeVfpRegRegRegOp<VmlsD>( 537 machInst, vd, vn, vm, true); 538 } 539 } 540 case 0x1: 541 if (bits(machInst, 6) == 1) { 542 if (single) { 543 return decodeVfpRegRegRegOp<VnmlaS>( 544 machInst, vd, vn, vm, false); 545 } else { 546 return decodeVfpRegRegRegOp<VnmlaD>( 547 machInst, vd, vn, vm, true); 548 } 549 } else { 550 if (single) { 551 return decodeVfpRegRegRegOp<VnmlsS>( 552 machInst, vd, vn, vm, false); 553 } else { 554 return decodeVfpRegRegRegOp<VnmlsD>( 555 machInst, vd, vn, vm, true); 556 } 557 } 558 case 0x2: 559 if ((opc3 & 0x1) == 0) { 560 if (single) { 561 return decodeVfpRegRegRegOp<VmulS>( 562 machInst, vd, vn, vm, false); 563 } else { 564 return decodeVfpRegRegRegOp<VmulD>( 565 machInst, vd, vn, vm, true); 566 } 567 } else { 568 if (single) { 569 return decodeVfpRegRegRegOp<VnmulS>( 570 machInst, vd, vn, vm, false); 571 } else { 572 return decodeVfpRegRegRegOp<VnmulD>( 573 machInst, vd, vn, vm, true); 574 } 575 } 576 case 0x3: 577 if ((opc3 & 0x1) == 0) { 578 if (single) { 579 return decodeVfpRegRegRegOp<VaddS>( 580 machInst, vd, vn, vm, false); 581 } else { 582 return decodeVfpRegRegRegOp<VaddD>( 583 machInst, vd, vn, vm, true); 584 } 585 } else { 586 if (single) { 587 return decodeVfpRegRegRegOp<VsubS>( 588 machInst, vd, vn, vm, false); 589 } else { 590 return decodeVfpRegRegRegOp<VsubD>( 591 machInst, vd, vn, vm, true); 592 } 593 } 594 case 0x8: 595 if ((opc3 & 0x1) == 0) { 596 if (single) { 597 return decodeVfpRegRegRegOp<VdivS>( 598 machInst, vd, vn, vm, false); 599 } else { 600 return decodeVfpRegRegRegOp<VdivD>( 601 machInst, vd, vn, vm, true); 602 } 603 } 604 break; 605 case 0xb: 606 if ((opc3 & 0x1) == 0) { 607 const uint32_t baseImm = 608 bits(machInst, 3, 0) | (bits(machInst, 19, 16) << 4); 609 if (single) { 610 uint32_t imm = vfp_modified_imm(baseImm, false); 611 return decodeVfpRegImmOp<VmovImmS>( 612 machInst, vd, imm, false); 613 } else { 614 uint64_t imm = vfp_modified_imm(baseImm, true); 615 return decodeVfpRegImmOp<VmovImmD>( 616 machInst, vd, imm, true); 617 } 618 } 619 switch (opc2) { 620 case 0x0: 621 if (opc3 == 1) { 622 if (single) { 623 return decodeVfpRegRegOp<VmovRegS>( 624 machInst, vd, vm, false); 625 } else { 626 return decodeVfpRegRegOp<VmovRegD>( 627 machInst, vd, vm, true); 628 } 629 } else { 630 if (single) { 631 return decodeVfpRegRegOp<VabsS>( 632 machInst, vd, vm, false); 633 } else { 634 return decodeVfpRegRegOp<VabsD>( 635 machInst, vd, vm, true); 636 } 637 } 638 case 0x1: 639 if (opc3 == 1) { 640 if (single) { 641 return decodeVfpRegRegOp<VnegS>( 642 machInst, vd, vm, false); 643 } else { 644 return decodeVfpRegRegOp<VnegD>( 645 machInst, vd, vm, true); 646 } 647 } else { 648 if (single) { 649 return decodeVfpRegRegOp<VsqrtS>( 650 machInst, vd, vm, false); 651 } else { 652 return decodeVfpRegRegOp<VsqrtD>( 653 machInst, vd, vm, true); 654 } 655 } 656 case 0x2: 657 case 0x3: 658 // Between half and single precision. 659 return new WarnUnimplemented("vcvtb, vcvtt", machInst); 660 case 0x4: 661 if (single) { 662 if (e) { 663 return new VcmpeS(machInst, vd, vm); 664 } else { 665 return new VcmpS(machInst, vd, vm); 666 } 667 } else { 668 if (e) { 669 return new VcmpeD(machInst, vd, vm); 670 } else { 671 return new VcmpD(machInst, vd, vm); 672 } 673 } 674 case 0x5: 675 if (single) { 676 if (e) { 677 return new VcmpeZeroS(machInst, vd, 0); 678 } else { 679 return new VcmpZeroS(machInst, vd, 0); 680 } 681 } else { 682 if (e) { 683 return new VcmpeZeroD(machInst, vd, 0); 684 } else { 685 return new VcmpZeroD(machInst, vd, 0); 686 } 687 } 688 case 0x7: 689 if (opc3 == 0x3) { 690 if (single) { 691 vm = (IntRegIndex)(bits(machInst, 5) | 692 (bits(machInst, 3, 0) << 1)); 693 return new VcvtFpSFpD(machInst, vd, vm); 694 } else { 695 vd = (IntRegIndex)(bits(machInst, 22) | 696 (bits(machInst, 15, 12) << 1)); 697 return new VcvtFpDFpS(machInst, vd, vm); 698 } 699 } 700 break; 701 case 0x8: 702 if (bits(machInst, 7) == 0) { 703 if (single) { 704 return new VcvtUIntFpS(machInst, vd, vm); 705 } else { 706 vm = (IntRegIndex)(bits(machInst, 5) | 707 (bits(machInst, 3, 0) << 1)); 708 return new VcvtUIntFpD(machInst, vd, vm); 709 } 710 } else { 711 if (single) { 712 return new VcvtSIntFpS(machInst, vd, vm); 713 } else { 714 vm = (IntRegIndex)(bits(machInst, 5) | 715 (bits(machInst, 3, 0) << 1)); 716 return new VcvtSIntFpD(machInst, vd, vm); 717 } 718 } 719 case 0xa: 720 { 721 const bool half = (bits(machInst, 7) == 0); 722 const uint32_t imm = bits(machInst, 5) | 723 (bits(machInst, 3, 0) << 1); 724 const uint32_t size = 725 (bits(machInst, 7) == 0 ? 16 : 32) - imm; 726 if (single) { 727 if (half) { 728 return new VcvtSHFixedFpS(machInst, vd, vd, size); 729 } else { 730 return new VcvtSFixedFpS(machInst, vd, vd, size); 731 } 732 } else { 733 if (half) { 734 return new VcvtSHFixedFpD(machInst, vd, vd, size); 735 } else { 736 return new VcvtSFixedFpD(machInst, vd, vd, size); 737 } 738 } 739 } 740 case 0xb: 741 { 742 const bool half = (bits(machInst, 7) == 0); 743 const uint32_t imm = bits(machInst, 5) | 744 (bits(machInst, 3, 0) << 1); 745 const uint32_t size = 746 (bits(machInst, 7) == 0 ? 16 : 32) - imm; 747 if (single) { 748 if (half) { 749 return new VcvtUHFixedFpS(machInst, vd, vd, size); 750 } else { 751 return new VcvtUFixedFpS(machInst, vd, vd, size); 752 } 753 } else { 754 if (half) { 755 return new VcvtUHFixedFpD(machInst, vd, vd, size); 756 } else { 757 return new VcvtUFixedFpD(machInst, vd, vd, size); 758 } 759 } 760 } 761 case 0xc: 762 if (bits(machInst, 7) == 0) { 763 if (single) { 764 return new VcvtFpUIntSR(machInst, vd, vm); 765 } else { 766 vd = (IntRegIndex)(bits(machInst, 22) | 767 (bits(machInst, 15, 12) << 1)); 768 return new VcvtFpUIntDR(machInst, vd, vm); 769 } 770 } else { 771 if (single) { 772 return new VcvtFpUIntS(machInst, vd, vm); 773 } else { 774 vd = (IntRegIndex)(bits(machInst, 22) | 775 (bits(machInst, 15, 12) << 1)); 776 return new VcvtFpUIntD(machInst, vd, vm); 777 } 778 } 779 case 0xd: 780 if (bits(machInst, 7) == 0) { 781 if (single) { 782 return new VcvtFpSIntSR(machInst, vd, vm); 783 } else { 784 vd = (IntRegIndex)(bits(machInst, 22) | 785 (bits(machInst, 15, 12) << 1)); 786 return new VcvtFpSIntDR(machInst, vd, vm); 787 } 788 } else { 789 if (single) { 790 return new VcvtFpSIntS(machInst, vd, vm); 791 } else { 792 vd = (IntRegIndex)(bits(machInst, 22) | 793 (bits(machInst, 15, 12) << 1)); 794 return new VcvtFpSIntD(machInst, vd, vm); 795 } 796 } 797 case 0xe: 798 { 799 const bool half = (bits(machInst, 7) == 0); 800 const uint32_t imm = bits(machInst, 5) | 801 (bits(machInst, 3, 0) << 1); 802 const uint32_t size = 803 (bits(machInst, 7) == 0 ? 16 : 32) - imm; 804 if (single) { 805 if (half) { 806 return new VcvtFpSHFixedS(machInst, vd, vd, size); 807 } else { 808 return new VcvtFpSFixedS(machInst, vd, vd, size); 809 } 810 } else { 811 if (half) { 812 return new VcvtFpSHFixedD(machInst, vd, vd, size); 813 } else { 814 return new VcvtFpSFixedD(machInst, vd, vd, size); 815 } 816 } 817 } 818 case 0xf: 819 { 820 const bool half = (bits(machInst, 7) == 0); 821 const uint32_t imm = bits(machInst, 5) | 822 (bits(machInst, 3, 0) << 1); 823 const uint32_t size = 824 (bits(machInst, 7) == 0 ? 16 : 32) - imm; 825 if (single) { 826 if (half) { 827 return new VcvtFpUHFixedS(machInst, vd, vd, size); 828 } else { 829 return new VcvtFpUFixedS(machInst, vd, vd, size); 830 } 831 } else { 832 if (half) { 833 return new VcvtFpUHFixedD(machInst, vd, vd, size); 834 } else { 835 return new VcvtFpUFixedD(machInst, vd, vd, size); 836 } 837 } 838 } 839 } 840 break; 841 } 842 return new Unknown(machInst); 843 } 844 ''' 845}}; 846 847def format VfpData() {{ 848 decode_block = ''' 849 return decodeVfpData(machInst); 850 ''' 851}}; 852