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// The actual ARM ISA decoder 46// -------------------------- 47// The following instructions are specified in the ARM ISA 48// Specification. Decoding closely follows the style specified 49// in the ARM ISA specification document starting with Table B.1 or 3-1 50// 51// 52 530: decode ENCODING { 54format DataOp { 55 0x0: decode SEVEN_AND_FOUR { 56 1: decode MISC_OPCODE { 57 0x9: decode PREPOST { 58 0: decode OPCODE { 59 0x0: mul({{ Rn = resTemp = Rm * Rs; }}, none); 60 0x1: mla({{ Rn = resTemp = (Rm * Rs) + Rd; }}, none); 61 0x2: WarnUnimpl::umall(); 62 0x4: umull({{ 63 resTemp = ((uint64_t)Rm)*((uint64_t)Rs); 64 Rd = (uint32_t)(resTemp & 0xffffffff); 65 Rn = (uint32_t)(resTemp >> 32); 66 }}, llbit); 67 0x5: smlal({{ 68 resTemp = ((int64_t)Rm) * ((int64_t)Rs); 69 resTemp += (((uint64_t)Rn) << 32) | ((uint64_t)Rd); 70 Rd = (uint32_t)(resTemp & 0xffffffff); 71 Rn = (uint32_t)(resTemp >> 32); 72 }}, llbit); 73 0x6: smull({{ 74 resTemp = ((int64_t)(int32_t)Rm)* 75 ((int64_t)(int32_t)Rs); 76 Rd = (int32_t)(resTemp & 0xffffffff); 77 Rn = (int32_t)(resTemp >> 32); 78 }}, llbit); 79 0x7: umlal({{ 80 resTemp = ((uint64_t)Rm)*((uint64_t)Rs); 81 resTemp += ((uint64_t)Rn << 32)+((uint64_t)Rd); 82 Rd = (uint32_t)(resTemp & 0xffffffff); 83 Rn = (uint32_t)(resTemp >> 32); 84 }}, llbit); 85 } 86 1: decode PUBWL { 87 0x10: WarnUnimpl::swp(); 88 0x14: WarnUnimpl::swpb(); 89 0x18: WarnUnimpl::strex(); 90 0x19: WarnUnimpl::ldrex(); 91 } 92 } 93 format AddrMode3 { 94 0xb: strh_ldrh(store, {{ Mem.uh = Rd; }}, 95 load, {{ Rd = Mem.uh; }}); 96 0xd: ldrd_ldrsb(load, {{ Rde = bits(Mem.ud, 31, 0); 97 Rdo = bits(Mem.ud, 63, 32); }}, 98 load, {{ Rd = Mem.sb; }}); 99 0xf: strd_ldrsh(store, {{ Mem.ud = (Rde.ud & mask(32)) | 100 (Rdo.ud << 32); }}, 101 load, {{ Rd = Mem.sh; }}); 102 } 103 } 104 0: decode IS_MISC { 105 0: decode OPCODE { 106 0x0: and({{ Rd = resTemp = Rn & op2; }}); 107 0x1: eor({{ Rd = resTemp = Rn ^ op2; }}); 108 0x2: sub({{ Rd = resTemp = Rn - op2; }}, sub); 109 0x3: rsb({{ Rd = resTemp = op2 - Rn; }}, rsb); 110 0x4: add({{ Rd = resTemp = Rn + op2; }}, add); 111 0x5: adc({{ Rd = resTemp = Rn + op2 + CondCodes<29:>; }}, add); 112 0x6: sbc({{ Rd = resTemp = Rn - op2 - !CondCodes<29:>; }}, sub); 113 0x7: rsc({{ Rd = resTemp = op2 - Rn - !CondCodes<29:>; }}, rsb); 114 0x8: tst({{ resTemp = Rn & op2; }}); 115 0x9: teq({{ resTemp = Rn ^ op2; }}); 116 0xa: cmp({{ resTemp = Rn - op2; }}, sub); 117 0xb: cmn({{ resTemp = Rn + op2; }}, add); 118 0xc: orr({{ Rd = resTemp = Rn | op2; }}); 119 0xd: mov({{ Rd = resTemp = op2; }}); 120 0xe: bic({{ Rd = resTemp = Rn & ~op2; }}); 121 0xf: mvn({{ Rd = resTemp = ~op2; }}); 122 } 123 1: decode MISC_OPCODE { 124 0x0: decode OPCODE { 125 0x8: PredOp::mrs_cpsr({{ 126 Rd = (Cpsr | CondCodes) & 0xF8FF03DF; 127 }}); 128 0x9: decode USEIMM { 129 // The mask field is the same as the RN index. 130 0: PredOp::msr_cpsr_reg({{ 131 uint32_t newCpsr = 132 cpsrWriteByInstr(Cpsr | CondCodes, 133 Rm, RN, false); 134 Cpsr = ~CondCodesMask & newCpsr; 135 CondCodes = CondCodesMask & newCpsr; 136 }}); 137 1: PredImmOp::msr_cpsr_imm({{ 138 uint32_t newCpsr = 139 cpsrWriteByInstr(Cpsr | CondCodes, 140 rotated_imm, RN, false); 141 Cpsr = ~CondCodesMask & newCpsr; 142 CondCodes = CondCodesMask & newCpsr; 143 }}); 144 } 145 0xa: PredOp::mrs_spsr({{ Rd = Spsr; }}); 146 0xb: decode USEIMM { 147 // The mask field is the same as the RN index. 148 0: PredOp::msr_spsr_reg({{ 149 Spsr = spsrWriteByInstr(Spsr, Rm, RN, false); 150 }}); 151 1: PredImmOp::msr_spsr_imm({{ 152 Spsr = spsrWriteByInstr(Spsr, rotated_imm, 153 RN, false); 154 }}); 155 } 156 } 157 0x1: decode OPCODE { 158 0x9: BranchExchange::bx({{ }}); 159 0xb: PredOp::clz({{ 160 Rd = ((Rm == 0) ? 32 : (31 - findMsbSet(Rm))); 161 }}); 162 } 163 0x2: decode OPCODE { 164 0x9: WarnUnimpl::bxj(); 165 } 166 0x3: decode OPCODE { 167 0x9: BranchExchange::blx({{ }}, Link); 168 } 169 0x5: decode OPCODE { 170 0x8: WarnUnimpl::qadd(); 171 0x9: WarnUnimpl::qsub(); 172 0xa: WarnUnimpl::qdadd(); 173 0xb: WarnUnimpl::qdsub(); 174 } 175 0x8: decode OPCODE { 176 0x8: smlabb({{ Rn = resTemp = sext<16>(Rm<15:0>) * sext<16>(Rs<15:0>) + Rd; }}, overflow); 177 0x9: WarnUnimpl::smlalbb(); 178 0xa: WarnUnimpl::smlawb(); 179 0xb: smulbb({{ Rn = resTemp = sext<16>(Rm<15:0>) * sext<16>(Rs<15:0>); }}, none); 180 } 181 0xa: decode OPCODE { 182 0x8: smlatb({{ Rn = resTemp = sext<16>(Rm<31:16>) * sext<16>(Rs<15:0>) + Rd; }}, overflow); 183 0x9: smulwb({{ 184 Rn = resTemp = bits(sext<32>(Rm) * sext<16>(Rs<15:0>), 47, 16); 185 }}, none); 186 0xa: WarnUnimpl::smlaltb(); 187 0xb: smultb({{ Rn = resTemp = sext<16>(Rm<31:16>) * sext<16>(Rs<15:0>); }}, none); 188 } 189 0xc: decode OPCODE { 190 0x8: smlabt({{ Rn = resTemp = sext<16>(Rm<15:0>) * sext<16>(Rs<31:16>) + Rd; }}, overflow); 191 0x9: WarnUnimpl::smlawt(); 192 0xa: WarnUnimpl::smlalbt(); 193 0xb: smulbt({{ Rn = resTemp = sext<16>(Rm<15:0>) * sext<16>(Rs<31:16>); }}, none); 194 } 195 0xe: decode OPCODE { 196 0x8: smlatt({{ Rn = resTemp = sext<16>(Rm<31:16>) * sext<16>(Rs<31:16>) + Rd; }}, overflow); 197 0x9: smulwt({{ 198 Rn = resTemp = bits(sext<32>(Rm) * sext<16>(Rs<31:16>), 47, 16); 199 }}, none); 200 0xa: WarnUnimpl::smlaltt(); 201 0xb: smultt({{ Rn = resTemp = sext<16>(Rm<31:16>) * sext<16>(Rs<31:16>); }}, none); 202 } 203 } 204 } 205 } 206 0x1: decode IS_MISC { 207 0: decode OPCODE { 208 format DataImmOp { 209 0x0: andi({{ Rd = resTemp = Rn & rotated_imm; }}); 210 0x1: eori({{ Rd = resTemp = Rn ^ rotated_imm; }}); 211 0x2: subi({{ Rd = resTemp = Rn - rotated_imm; }}, sub); 212 0x3: rsbi({{ Rd = resTemp = rotated_imm - Rn; }}, rsb); 213 0x4: addi({{ Rd = resTemp = Rn + rotated_imm; }}, add); 214 0x5: adci({{ 215 Rd = resTemp = Rn + rotated_imm + CondCodes<29:>; 216 }}, add); 217 0x6: sbci({{ 218 Rd = resTemp = Rn -rotated_imm - !CondCodes<29:>; 219 }}, sub); 220 0x7: rsci({{ 221 Rd = resTemp = rotated_imm - Rn - !CondCodes<29:>; 222 }}, rsb); 223 0x8: tsti({{ resTemp = Rn & rotated_imm; }}); 224 0x9: teqi({{ resTemp = Rn ^ rotated_imm; }}); 225 0xa: cmpi({{ resTemp = Rn - rotated_imm; }}, sub); 226 0xb: cmni({{ resTemp = Rn + rotated_imm; }}, add); 227 0xc: orri({{ Rd = resTemp = Rn | rotated_imm; }}); 228 0xd: movi({{ Rd = resTemp = rotated_imm; }}); 229 0xe: bici({{ Rd = resTemp = Rn & ~rotated_imm; }}); 230 0xf: mvni({{ Rd = resTemp = ~rotated_imm; }}); 231 } 232 } 233 1: decode OPCODE { 234 // The following two instructions aren't supposed to be defined 235 0x8: DataOp::movw({{ Rd = IMMED_11_0 | (RN << 12) ; }}); 236 0x9: decode RN { 237 0: decode IMM { 238 0: PredImmOp::nop({{ ; }}); 239 1: WarnUnimpl::yield(); 240 2: WarnUnimpl::wfe(); 241 3: WarnUnimpl::wfi(); 242 4: WarnUnimpl::sev(); 243 } 244 default: PredImmOp::msr_i_cpsr({{ 245 uint32_t newCpsr = 246 cpsrWriteByInstr(Cpsr | CondCodes, 247 rotated_imm, RN, false); 248 Cpsr = ~CondCodesMask & newCpsr; 249 CondCodes = CondCodesMask & newCpsr; 250 }}); 251 } 252 0xa: PredOp::movt({{ Rd = IMMED_11_0 << 16 | RN << 28 | Rd<15:0>; }}); 253 0xb: PredImmOp::msr_i_spsr({{ 254 Spsr = spsrWriteByInstr(Spsr, rotated_imm, RN, false); 255 }}); 256 } 257 }
|
258 0x2: AddrMode2::addrMode2(Disp, disp);
|
258 0x2: AddrMode2::addrMode2(True, Disp, disp); |
259 0x3: decode OPCODE_4 {
|
260 0: AddrMode2::addrMode2(Shift, Rm_Imm);
|
260 0: AddrMode2::addrMode2(False, Shift, Rm_Imm); |
261 1: decode MEDIA_OPCODE { 262 0x0, 0x1, 0x2, 0x3, 0x4, 0x5, 0x6, 0x7: WarnUnimpl::parallel_add_subtract_instructions(); 263 0x8: decode MISC_OPCODE { 264 0x1, 0x9: WarnUnimpl::pkhbt(); 265 0x7: WarnUnimpl::sxtab16(); 266 0xb: WarnUnimpl::sel(); 267 0x5, 0xd: WarnUnimpl::pkhtb(); 268 0x3: WarnUnimpl::sign_zero_extend_add(); 269 } 270 0xa, 0xb: decode SHIFT { 271 0x0, 0x2: WarnUnimpl::ssat(); 272 0x1: WarnUnimpl::ssat16(); 273 } 274 0xe, 0xf: decode SHIFT { 275 0x0, 0x2: WarnUnimpl::usat(); 276 0x1: WarnUnimpl::usat16(); 277 } 278 0x10: decode RN { 279 0xf: decode MISC_OPCODE { 280 0x1: WarnUnimpl::smuad(); 281 0x3: WarnUnimpl::smuadx(); 282 0x5: WarnUnimpl::smusd(); 283 0x7: WarnUnimpl::smusdx(); 284 } 285 default: decode MISC_OPCODE { 286 0x1: WarnUnimpl::smlad(); 287 0x3: WarnUnimpl::smladx(); 288 0x5: WarnUnimpl::smlsd(); 289 0x7: WarnUnimpl::smlsdx(); 290 } 291 } 292 0x14: decode MISC_OPCODE { 293 0x1: WarnUnimpl::smlald(); 294 0x3: WarnUnimpl::smlaldx(); 295 0x5: WarnUnimpl::smlsld(); 296 0x7: WarnUnimpl::smlsldx(); 297 } 298 0x15: decode RN { 299 0xf: decode MISC_OPCODE { 300 0x1: WarnUnimpl::smmul(); 301 0x3: WarnUnimpl::smmulr(); 302 } 303 default: decode MISC_OPCODE { 304 0x1: WarnUnimpl::smmla(); 305 0x3: WarnUnimpl::smmlar(); 306 0xd: WarnUnimpl::smmls(); 307 0xf: WarnUnimpl::smmlsr(); 308 } 309 } 310 0x18: decode RN { 311 0xf: WarnUnimpl::usada8(); 312 default: WarnUnimpl::usad8(); 313 } 314 } 315 } 316 0x4: decode PUSWL { 317 // Right now we only handle cases when S (PSRUSER) is not set 318 default: ArmMacroStore::ldmstm({{ }}); 319 } 320 0x5: decode OPCODE_24 { 321 // Branch (and Link) Instructions 322 0: Branch::b({{ }}); 323 1: Branch::bl({{ }}, Link); 324 } 325 0x6: decode CPNUM { 326 0x1: decode PUNWL { 327 0x02,0x0a: decode OPCODE_15 { 328 0: ArmStoreMemory::stfs_({{ Mem.sf = Fd.sf; 329 Rn = Rn + disp8; }}, 330 {{ EA = Rn; }}); 331 1: ArmMacroFPAOp::stfd_({{ }}); 332 } 333 0x03,0x0b: decode OPCODE_15 { 334 0: ArmLoadMemory::ldfs_({{ Fd.sf = Mem.sf; 335 Rn = Rn + disp8; }}, 336 {{ EA = Rn; }}); 337 1: ArmMacroFPAOp::ldfd_({{ }}); 338 } 339 0x06,0x0e: decode OPCODE_15 { 340 0: ArmMacroFPAOp::stfe_nw({{ }}); 341 } 342 0x07,0x0f: decode OPCODE_15 { 343 0: ArmMacroFPAOp::ldfe_nw({{ }}); 344 } 345 0x10,0x18: decode OPCODE_15 { 346 0: ArmStoreMemory::stfs_p({{ Mem.sf = Fd.sf; }}, 347 {{ EA = Rn + disp8; }}); 348 1: ArmMacroFPAOp::stfd_p({{ }}); 349 } 350 0x11,0x19: decode OPCODE_15 { 351 0: ArmLoadMemory::ldfs_p({{ Fd.sf = Mem.sf; }}, 352 {{ EA = Rn + disp8; }}); 353 1: ArmMacroFPAOp::ldfd_p({{ }}); 354 } 355 0x12,0x1a: decode OPCODE_15 { 356 0: ArmStoreMemory::stfs_pw({{ Mem.sf = Fd.sf; 357 Rn = Rn + disp8; }}, 358 {{ EA = Rn + disp8; }}); 359 1: ArmMacroFPAOp::stfd_pw({{ }}); 360 } 361 0x13,0x1b: decode OPCODE_15 { 362 0: ArmLoadMemory::ldfs_pw({{ Fd.sf = Mem.sf; 363 Rn = Rn + disp8; }}, 364 {{ EA = Rn + disp8; }}); 365 1: ArmMacroFPAOp::ldfd_pw({{ }}); 366 } 367 0x14,0x1c: decode OPCODE_15 { 368 0: ArmMacroFPAOp::stfe_pn({{ }}); 369 } 370 0x15,0x1d: decode OPCODE_15 { 371 0: ArmMacroFPAOp::ldfe_pn({{ }}); 372 } 373 0x16,0x1e: decode OPCODE_15 { 374 0: ArmMacroFPAOp::stfe_pnw({{ }}); 375 } 376 0x17,0x1f: decode OPCODE_15 { 377 0: ArmMacroFPAOp::ldfe_pnw({{ }}); 378 } 379 } 380 0x2: decode PUNWL { 381 // could really just decode as a single instruction 382 0x00,0x04,0x08,0x0c: ArmMacroFMOp::sfm_({{ }}); 383 0x01,0x05,0x09,0x0d: ArmMacroFMOp::lfm_({{ }}); 384 0x02,0x06,0x0a,0x0e: ArmMacroFMOp::sfm_w({{ }}); 385 0x03,0x07,0x0b,0x0f: ArmMacroFMOp::lfm_w({{ }}); 386 0x10,0x14,0x18,0x1c: ArmMacroFMOp::sfm_p({{ }}); 387 0x11,0x15,0x19,0x1d: ArmMacroFMOp::lfm_p({{ }}); 388 0x12,0x16,0x1a,0x1e: ArmMacroFMOp::sfm_pw({{ }}); 389 0x13,0x17,0x1b,0x1f: ArmMacroFMOp::lfm_pw({{ }}); 390 } 391 0xb: decode LOADOP { 392 0x0: WarnUnimpl::fstmx(); 393 0x1: WarnUnimpl::fldmx(); 394 } 395 } 396 0x7: decode OPCODE_24 { 397 0: decode OPCODE_4 { 398 0: decode CPNUM { 399 0xa, 0xb: decode OPCODE_23_20 { 400##include "vfp.isa" 401 } 402 } // CPNUM 403 1: decode CPNUM { // 27-24=1110,4 ==1 404 1: decode OPCODE_15_12 { 405 format FloatOp { 406 0xf: decode OPCODE_23_21 { 407 format FloatCmp { 408 0x4: cmf({{ Fn.df }}, {{ Fm.df }}); 409 0x5: cnf({{ Fn.df }}, {{ -Fm.df }}); 410 0x6: cmfe({{ Fn.df }}, {{ Fm.df}}); 411 0x7: cnfe({{ Fn.df }}, {{ -Fm.df}}); 412 } 413 } 414 default: decode OPCODE_23_20 { 415 0x0: decode OPCODE_7 { 416 0: flts({{ Fn.sf = (float) Rd.sw; }}); 417 1: fltd({{ Fn.df = (double) Rd.sw; }}); 418 } 419 0x1: decode OPCODE_7 { 420 0: fixs({{ Rd = (uint32_t) Fm.sf; }}); 421 1: fixd({{ Rd = (uint32_t) Fm.df; }}); 422 } 423 0x2: wfs({{ Fpsr = Rd; }}); 424 0x3: rfs({{ Rd = Fpsr; }}); 425 0x4: FailUnimpl::wfc(); 426 0x5: FailUnimpl::rfc(); 427 } 428 } // format FloatOp 429 } 430 0xa: decode MISC_OPCODE { 431 0x1: decode MEDIA_OPCODE { 432 0xf: decode RN { 433 0x0: FloatOp::fmrx_fpsid({{ Rd = Fpsid; }}); 434 0x1: FloatOp::fmrx_fpscr({{ Rd = Fpscr; }}); 435 0x8: FloatOp::fmrx_fpexc({{ Rd = Fpexc; }}); 436 } 437 0xe: decode RN { 438 0x0: FloatOp::fmxr_fpsid({{ Fpsid = Rd; }}); 439 0x1: FloatOp::fmxr_fpscr({{ Fpscr = Rd; }}); 440 0x8: FloatOp::fmxr_fpexc({{ Fpexc = Rd; }}); 441 } 442 } // MEDIA_OPCODE (MISC_OPCODE 0x1) 443 } // MISC_OPCODE (CPNUM 0xA) 444 0xf: decode RN { 445 // Barrriers, Cache Maintence, NOPS 446 7: decode OPCODE_23_21 { 447 0: decode RM { 448 0: decode OPC2 { 449 4: decode OPCODE_20 { 450 0: PredOp::mcr_cp15_nop1({{ }}); // was wfi 451 } 452 } 453 1: WarnUnimpl::cp15_cache_maint(); 454 4: WarnUnimpl::cp15_par(); 455 5: decode OPC2 { 456 0,1: WarnUnimpl::cp15_cache_maint2(); 457 4: PredOp::cp15_isb({{ ; }}, IsMemBarrier, IsSerializeBefore); 458 6,7: WarnUnimpl::cp15_bp_maint(); 459 } 460 6: WarnUnimpl::cp15_cache_maint3(); 461 8: WarnUnimpl::cp15_va_to_pa(); 462 10: decode OPC2 { 463 1,2: WarnUnimpl::cp15_cache_maint3(); 464 4: PredOp::cp15_dsb({{ ; }}, IsMemBarrier, IsSerializeBefore); 465 5: PredOp::cp15_dmb({{ ; }}, IsMemBarrier, IsSerializeBefore); 466 } 467 11: WarnUnimpl::cp15_cache_maint4(); 468 13: decode OPC2 { 469 1: decode OPCODE_20 { 470 0: PredOp::mcr_cp15_nop2({{ }}); // was prefetch 471 } 472 } 473 14: WarnUnimpl::cp15_cache_maint5(); 474 } // RM 475 } // OPCODE_23_21 CR 476 477 // Thread ID and context ID registers 478 // Thread ID register needs cheaper access than miscreg 479 13: WarnUnimpl::mcr_mrc_cp15_c7(); 480 481 // All the rest 482 default: decode OPCODE_20 { 483 0: PredOp::mcr_cp15({{ 484 fault = setCp15Register(Rd, RN, OPCODE_23_21, RM, OPC2); 485 }}); 486 1: PredOp::mrc_cp15({{ 487 fault = readCp15Register(Rd, RN, OPCODE_23_21, RM, OPC2); 488 }}); 489 } 490 } // RN 491 } // CPNUM (OP4 == 1) 492 } //OPCODE_4 493 494#if FULL_SYSTEM 495 1: PredOp::swi({{ fault = new SupervisorCall; }}, IsSerializeAfter, IsNonSpeculative, IsSyscall); 496#else 497 1: PredOp::swi({{ if (testPredicate(CondCodes, condCode)) 498 { 499 if (IMMED_23_0) 500 xc->syscall(IMMED_23_0); 501 else 502 xc->syscall(R7); 503 } 504 }}); 505#endif // FULL_SYSTEM 506 } // OPCODE_24 507 508} 509} 510
|