decoder.isa revision 8607
1// -*- mode:c++ -*- 2 3// Copyright (c) 2007 MIPS Technologies, Inc. 4// All rights reserved. 5// 6// Redistribution and use in source and binary forms, with or without 7// modification, are permitted provided that the following conditions are 8// met: redistributions of source code must retain the above copyright 9// notice, this list of conditions and the following disclaimer; 10// redistributions in binary form must reproduce the above copyright 11// notice, this list of conditions and the following disclaimer in the 12// documentation and/or other materials provided with the distribution; 13// neither the name of the copyright holders nor the names of its 14// contributors may be used to endorse or promote products derived from 15// this software without specific prior written permission. 16// 17// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 18// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 19// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR 20// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT 21// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 22// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT 23// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 24// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 25// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 26// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE 27// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 28// 29// Authors: Korey Sewell 30// Brett Miller 31// Jaidev Patwardhan 32 33//////////////////////////////////////////////////////////////////// 34// 35// The actual MIPS32 ISA decoder 36// ----------------------------- 37// The following instructions are specified in the MIPS32 ISA 38// Specification. Decoding closely follows the style specified 39// in the MIPS32 ISA specification document starting with Table 40// A-2 (document available @ http://www.mips.com) 41// 42decode OPCODE_HI default Unknown::unknown() { 43 //Table A-2 44 0x0: decode OPCODE_LO { 45 0x0: decode FUNCTION_HI { 46 0x0: decode FUNCTION_LO { 47 0x1: decode MOVCI { 48 format BasicOp { 49 0: movf({{ 50 Rd = (getCondCode(FCSR, CC) == 0) ? Rd : Rs; 51 }}); 52 1: movt({{ 53 Rd = (getCondCode(FCSR, CC) == 1) ? Rd : Rs; 54 }}); 55 } 56 } 57 58 format BasicOp { 59 //Table A-3 Note: "Specific encodings of the rd, rs, and 60 //rt fields are used to distinguish SLL, SSNOP, and EHB 61 //functions 62 0x0: decode RS { 63 0x0: decode RT_RD { 64 0x0: decode SA default Nop::nop() { 65 0x1: ssnop({{;}}); 66 0x3: ehb({{;}}); 67 } 68 default: sll({{ Rd = Rt_uw << SA; }}); 69 } 70 } 71 72 0x2: decode RS_SRL { 73 0x0:decode SRL { 74 0: srl({{ Rd = Rt_uw >> SA; }}); 75 76 //Hardcoded assuming 32-bit ISA, 77 //probably need parameter here 78 1: rotr({{ 79 Rd = (Rt_uw << (32 - SA)) | (Rt_uw >> SA); 80 }}); 81 } 82 } 83 84 0x3: decode RS { 85 0x0: sra({{ 86 uint32_t temp = Rt >> SA; 87 if ( (Rt & 0x80000000) > 0 ) { 88 uint32_t mask = 0x80000000; 89 for(int i=0; i < SA; i++) { 90 temp |= mask; 91 mask = mask >> 1; 92 } 93 } 94 Rd = temp; 95 }}); 96 } 97 98 0x4: sllv({{ Rd = Rt_uw << Rs<4:0>; }}); 99 100 0x6: decode SRLV { 101 0: srlv({{ Rd = Rt_uw >> Rs<4:0>; }}); 102 103 //Hardcoded assuming 32-bit ISA, 104 //probably need parameter here 105 1: rotrv({{ 106 Rd = (Rt_uw << (32 - Rs<4:0>)) | 107 (Rt_uw >> Rs<4:0>); 108 }}); 109 } 110 111 0x7: srav({{ 112 int shift_amt = Rs<4:0>; 113 114 uint32_t temp = Rt >> shift_amt; 115 116 if ((Rt & 0x80000000) > 0) { 117 uint32_t mask = 0x80000000; 118 for (int i = 0; i < shift_amt; i++) { 119 temp |= mask; 120 mask = mask >> 1; 121 } 122 } 123 Rd = temp; 124 }}); 125 } 126 } 127 128 0x1: decode FUNCTION_LO { 129 //Table A-3 Note: "Specific encodings of the hint field are 130 //used to distinguish JR from JR.HB and JALR from JALR.HB" 131 format Jump { 132 0x0: decode HINT { 133 0x1: jr_hb({{ 134 Config1Reg config1 = Config1; 135 if (config1.ca == 0) { 136 NNPC = Rs; 137 } else { 138 panic("MIPS16e not supported\n"); 139 } 140 }}, IsReturn, ClearHazards); 141 default: jr({{ 142 Config1Reg config1 = Config1; 143 if (config1.ca == 0) { 144 NNPC = Rs; 145 } else { 146 panic("MIPS16e not supported\n"); 147 } 148 }}, IsReturn); 149 } 150 151 0x1: decode HINT { 152 0x1: jalr_hb({{ 153 Rd = NNPC; 154 NNPC = Rs; 155 }}, IsCall, ClearHazards); 156 default: jalr({{ 157 Rd = NNPC; 158 NNPC = Rs; 159 }}, IsCall); 160 } 161 } 162 163 format BasicOp { 164 0x2: movz({{ Rd = (Rt == 0) ? Rs : Rd; }}); 165 0x3: movn({{ Rd = (Rt != 0) ? Rs : Rd; }}); 166 0x4: decode FULL_SYSTEM { 167 0: syscall_se({{ xc->syscall(R2); }}, 168 IsSerializeAfter, IsNonSpeculative); 169 default: syscall({{ fault = new SystemCallFault(); }}); 170 } 171 0x7: sync({{ ; }}, IsMemBarrier); 172 0x5: break({{fault = new BreakpointFault();}}); 173 } 174 175 } 176 177 0x2: decode FUNCTION_LO { 178 0x0: HiLoRsSelOp::mfhi({{ Rd = HI_RS_SEL; }}, 179 IntMultOp, IsIprAccess); 180 0x1: HiLoRdSelOp::mthi({{ HI_RD_SEL = Rs; }}); 181 0x2: HiLoRsSelOp::mflo({{ Rd = LO_RS_SEL; }}, 182 IntMultOp, IsIprAccess); 183 0x3: HiLoRdSelOp::mtlo({{ LO_RD_SEL = Rs; }}); 184 } 185 186 0x3: decode FUNCTION_LO { 187 format HiLoRdSelValOp { 188 0x0: mult({{ val = Rs_sd * Rt_sd; }}, IntMultOp); 189 0x1: multu({{ val = Rs_ud * Rt_ud; }}, IntMultOp); 190 } 191 192 format HiLoOp { 193 0x2: div({{ 194 if (Rt_sd != 0) { 195 HI0 = Rs_sd % Rt_sd; 196 LO0 = Rs_sd / Rt_sd; 197 } 198 }}, IntDivOp); 199 200 0x3: divu({{ 201 if (Rt_ud != 0) { 202 HI0 = Rs_ud % Rt_ud; 203 LO0 = Rs_ud / Rt_ud; 204 } 205 }}, IntDivOp); 206 } 207 } 208 209 0x4: decode HINT { 210 0x0: decode FUNCTION_LO { 211 format IntOp { 212 0x0: add({{ 213 IntReg result; 214 Rd = result = Rs + Rt; 215 if (FULL_SYSTEM && 216 findOverflow(32, result, Rs, Rt)) { 217 fault = new IntegerOverflowFault(); 218 } 219 }}); 220 0x1: addu({{ Rd_sw = Rs_sw + Rt_sw;}}); 221 0x2: sub({{ 222 IntReg result; 223 Rd = result = Rs - Rt; 224 if (FULL_SYSTEM && 225 findOverflow(32, result, Rs, ~Rt)) { 226 fault = new IntegerOverflowFault(); 227 } 228 }}); 229 0x3: subu({{ Rd_sw = Rs_sw - Rt_sw; }}); 230 0x4: and({{ Rd = Rs & Rt; }}); 231 0x5: or({{ Rd = Rs | Rt; }}); 232 0x6: xor({{ Rd = Rs ^ Rt; }}); 233 0x7: nor({{ Rd = ~(Rs | Rt); }}); 234 } 235 } 236 } 237 238 0x5: decode HINT { 239 0x0: decode FUNCTION_LO { 240 format IntOp{ 241 0x2: slt({{ Rd_sw = (Rs_sw < Rt_sw) ? 1 : 0 }}); 242 0x3: sltu({{ Rd_uw = (Rs_uw < Rt_uw) ? 1 : 0 }}); 243 } 244 } 245 } 246 247 0x6: decode FUNCTION_LO { 248 format Trap { 249 0x0: tge({{ cond = (Rs_sw >= Rt_sw); }}); 250 0x1: tgeu({{ cond = (Rs_uw >= Rt_uw); }}); 251 0x2: tlt({{ cond = (Rs_sw < Rt_sw); }}); 252 0x3: tltu({{ cond = (Rs_uw < Rt_uw); }}); 253 0x4: teq({{ cond = (Rs_sw == Rt_sw); }}); 254 0x6: tne({{ cond = (Rs_sw != Rt_sw); }}); 255 } 256 } 257 } 258 259 0x1: decode REGIMM_HI { 260 0x0: decode REGIMM_LO { 261 format Branch { 262 0x0: bltz({{ cond = (Rs_sw < 0); }}); 263 0x1: bgez({{ cond = (Rs_sw >= 0); }}); 264 0x2: bltzl({{ cond = (Rs_sw < 0); }}, Likely); 265 0x3: bgezl({{ cond = (Rs_sw >= 0); }}, Likely); 266 } 267 } 268 269 0x1: decode REGIMM_LO { 270 format TrapImm { 271 0x0: tgei( {{ cond = (Rs_sw >= (int16_t)INTIMM); }}); 272 0x1: tgeiu({{ 273 cond = (Rs_uw >= (uint32_t)(int32_t)(int16_t)INTIMM); 274 }}); 275 0x2: tlti( {{ cond = (Rs_sw < (int16_t)INTIMM); }}); 276 0x3: tltiu({{ 277 cond = (Rs_uw < (uint32_t)(int32_t)(int16_t)INTIMM); 278 }}); 279 0x4: teqi( {{ cond = (Rs_sw == (int16_t)INTIMM); }}); 280 0x6: tnei( {{ cond = (Rs_sw != (int16_t)INTIMM); }}); 281 } 282 } 283 284 0x2: decode REGIMM_LO { 285 format Branch { 286 0x0: bltzal({{ cond = (Rs_sw < 0); }}, Link); 287 0x1: decode RS { 288 0x0: bal ({{ cond = 1; }}, IsCall, Link); 289 default: bgezal({{ cond = (Rs_sw >= 0); }}, Link); 290 } 291 0x2: bltzall({{ cond = (Rs_sw < 0); }}, Link, Likely); 292 0x3: bgezall({{ cond = (Rs_sw >= 0); }}, Link, Likely); 293 } 294 } 295 296 0x3: decode REGIMM_LO { 297 // from Table 5-4 MIPS32 REGIMM Encoding of rt Field 298 // (DSP ASE MANUAL) 299 0x4: DspBranch::bposge32({{ cond = (dspctl<5:0> >= 32); }}); 300 format WarnUnimpl { 301 0x7: synci(); 302 } 303 } 304 } 305 306 format Jump { 307 0x2: j({{ NNPC = (NPC & 0xF0000000) | (JMPTARG << 2); }}); 308 0x3: jal({{ NNPC = (NPC & 0xF0000000) | (JMPTARG << 2); }}, 309 IsCall, Link); 310 } 311 312 format Branch { 313 0x4: decode RS_RT { 314 0x0: b({{ cond = 1; }}); 315 default: beq({{ cond = (Rs_sw == Rt_sw); }}); 316 } 317 0x5: bne({{ cond = (Rs_sw != Rt_sw); }}); 318 0x6: blez({{ cond = (Rs_sw <= 0); }}); 319 0x7: bgtz({{ cond = (Rs_sw > 0); }}); 320 } 321 } 322 323 0x1: decode OPCODE_LO { 324 format IntImmOp { 325 0x0: addi({{ 326 IntReg result; 327 Rt = result = Rs + imm; 328 if (FULL_SYSTEM && 329 findOverflow(32, result, Rs, imm)) { 330 fault = new IntegerOverflowFault(); 331 } 332 }}); 333 0x1: addiu({{ Rt_sw = Rs_sw + imm; }}); 334 0x2: slti({{ Rt_sw = (Rs_sw < imm) ? 1 : 0 }}); 335 0x3: sltiu({{ Rt_uw = (Rs_uw < (uint32_t)sextImm) ? 1 : 0;}}); 336 0x4: andi({{ Rt_sw = Rs_sw & zextImm; }}); 337 0x5: ori({{ Rt_sw = Rs_sw | zextImm; }}); 338 0x6: xori({{ Rt_sw = Rs_sw ^ zextImm; }}); 339 340 0x7: decode RS { 341 0x0: lui({{ Rt = imm << 16; }}); 342 } 343 } 344 } 345 346 0x2: decode OPCODE_LO { 347 //Table A-11 MIPS32 COP0 Encoding of rs Field 348 0x0: decode RS_MSB { 349 0x0: decode RS { 350 format CP0Control { 351 0x0: mfc0({{ 352 Config3Reg config3 = Config3; 353 PageGrainReg pageGrain = PageGrain; 354 Rt = CP0_RD_SEL; 355 /* Hack for PageMask */ 356 if (RD == 5) { 357 // PageMask 358 if (config3.sp == 0 || pageGrain.esp == 0) 359 Rt &= 0xFFFFE7FF; 360 } 361 }}); 362 0x4: mtc0({{ 363 CP0_RD_SEL = Rt; 364 CauseReg cause = Cause; 365 IntCtlReg intCtl = IntCtl; 366 if (RD == 11) { 367 // Compare 368 if (cause.ti == 1) { 369 cause.ti = 0; 370 int offset = 10; // corresponding to cause.ip0 371 offset += intCtl.ipti - 2; 372 replaceBits(cause, offset, offset, 0); 373 } 374 } 375 Cause = cause; 376 }}); 377 } 378 format CP0Unimpl { 379 0x1: dmfc0(); 380 0x5: dmtc0(); 381 default: unknown(); 382 } 383 format MT_MFTR { 384 // Decode MIPS MT MFTR instruction into sub-instructions 385 0x8: decode MT_U { 386 0x0: mftc0({{ 387 data = xc->readRegOtherThread((RT << 3 | SEL) + 388 Ctrl_Base_DepTag); 389 }}); 390 0x1: decode SEL { 391 0x0: mftgpr({{ 392 data = xc->readRegOtherThread(RT); 393 }}); 394 0x1: decode RT { 395 0x0: mftlo_dsp0({{ data = xc->readRegOtherThread(INTREG_DSP_LO0); }}); 396 0x1: mfthi_dsp0({{ data = xc->readRegOtherThread(INTREG_DSP_HI0); }}); 397 0x2: mftacx_dsp0({{ data = xc->readRegOtherThread(INTREG_DSP_ACX0); }}); 398 0x4: mftlo_dsp1({{ data = xc->readRegOtherThread(INTREG_DSP_LO1); }}); 399 0x5: mfthi_dsp1({{ data = xc->readRegOtherThread(INTREG_DSP_HI1); }}); 400 0x6: mftacx_dsp1({{ data = xc->readRegOtherThread(INTREG_DSP_ACX1); }}); 401 0x8: mftlo_dsp2({{ data = xc->readRegOtherThread(INTREG_DSP_LO2); }}); 402 0x9: mfthi_dsp2({{ data = xc->readRegOtherThread(INTREG_DSP_HI2); }}); 403 0x10: mftacx_dsp2({{ data = xc->readRegOtherThread(INTREG_DSP_ACX2); }}); 404 0x12: mftlo_dsp3({{ data = xc->readRegOtherThread(INTREG_DSP_LO3); }}); 405 0x13: mfthi_dsp3({{ data = xc->readRegOtherThread(INTREG_DSP_HI3); }}); 406 0x14: mftacx_dsp3({{ data = xc->readRegOtherThread(INTREG_DSP_ACX3); }}); 407 0x16: mftdsp({{ data = xc->readRegOtherThread(INTREG_DSP_CONTROL); }}); 408 default: CP0Unimpl::unknown(); 409 } 410 0x2: decode MT_H { 411 0x0: mftc1({{ data = xc->readRegOtherThread(RT + 412 FP_Base_DepTag); 413 }}); 414 0x1: mfthc1({{ data = xc->readRegOtherThread(RT + 415 FP_Base_DepTag); 416 }}); 417 } 418 0x3: cftc1({{ 419 uint32_t fcsr_val = xc->readRegOtherThread(FLOATREG_FCSR + 420 FP_Base_DepTag); 421 switch (RT) { 422 case 0: 423 data = xc->readRegOtherThread(FLOATREG_FIR + 424 Ctrl_Base_DepTag); 425 break; 426 case 25: 427 data = (fcsr_val & 0xFE000000 >> 24) | 428 (fcsr_val & 0x00800000 >> 23); 429 break; 430 case 26: 431 data = fcsr_val & 0x0003F07C; 432 break; 433 case 28: 434 data = (fcsr_val & 0x00000F80) | 435 (fcsr_val & 0x01000000 >> 21) | 436 (fcsr_val & 0x00000003); 437 break; 438 case 31: 439 data = fcsr_val; 440 break; 441 default: 442 fatal("FP Control Value (%d) Not Valid"); 443 } 444 }}); 445 default: CP0Unimpl::unknown(); 446 } 447 } 448 } 449 450 format MT_MTTR { 451 // Decode MIPS MT MTTR instruction into sub-instructions 452 0xC: decode MT_U { 453 0x0: mttc0({{ xc->setRegOtherThread((RD << 3 | SEL) + Ctrl_Base_DepTag, 454 Rt); 455 }}); 456 0x1: decode SEL { 457 0x0: mttgpr({{ xc->setRegOtherThread(RD, Rt); }}); 458 0x1: decode RT { 459 0x0: mttlo_dsp0({{ xc->setRegOtherThread(INTREG_DSP_LO0, Rt); 460 }}); 461 0x1: mtthi_dsp0({{ xc->setRegOtherThread(INTREG_DSP_HI0, 462 Rt); 463 }}); 464 0x2: mttacx_dsp0({{ xc->setRegOtherThread(INTREG_DSP_ACX0, 465 Rt); 466 }}); 467 0x4: mttlo_dsp1({{ xc->setRegOtherThread(INTREG_DSP_LO1, 468 Rt); 469 }}); 470 0x5: mtthi_dsp1({{ xc->setRegOtherThread(INTREG_DSP_HI1, 471 Rt); 472 }}); 473 0x6: mttacx_dsp1({{ xc->setRegOtherThread(INTREG_DSP_ACX1, 474 Rt); 475 }}); 476 0x8: mttlo_dsp2({{ xc->setRegOtherThread(INTREG_DSP_LO2, 477 Rt); 478 }}); 479 0x9: mtthi_dsp2({{ xc->setRegOtherThread(INTREG_DSP_HI2, 480 Rt); 481 }}); 482 0x10: mttacx_dsp2({{ xc->setRegOtherThread(INTREG_DSP_ACX2, 483 Rt); 484 }}); 485 0x12: mttlo_dsp3({{ xc->setRegOtherThread(INTREG_DSP_LO3, 486 Rt); 487 }}); 488 0x13: mtthi_dsp3({{ xc->setRegOtherThread(INTREG_DSP_HI3, 489 Rt); 490 }}); 491 0x14: mttacx_dsp3({{ xc->setRegOtherThread(INTREG_DSP_ACX3, Rt); 492 }}); 493 0x16: mttdsp({{ xc->setRegOtherThread(INTREG_DSP_CONTROL, Rt); }}); 494 default: CP0Unimpl::unknown(); 495 496 } 497 0x2: mttc1({{ 498 uint64_t data = xc->readRegOtherThread(RD + 499 FP_Base_DepTag); 500 data = insertBits(data, MT_H ? 63 : 31, 501 MT_H ? 32 : 0, Rt); 502 xc->setRegOtherThread(RD + FP_Base_DepTag, 503 data); 504 }}); 505 0x3: cttc1({{ 506 uint32_t data; 507 switch (RD) { 508 case 25: 509 data = (Rt_uw<7:1> << 25) | // move 31-25 510 (FCSR & 0x01000000) | // bit 24 511 (FCSR & 0x004FFFFF); // bit 22-0 512 break; 513 case 26: 514 data = (FCSR & 0xFFFC0000) | // move 31-18 515 Rt_uw<17:12> << 12 | // bit 17-12 516 (FCSR & 0x00000F80) << 7 | // bit 11-7 517 Rt_uw<6:2> << 2 | // bit 6-2 518 (FCSR & 0x00000002); // bit 1...0 519 break; 520 case 28: 521 data = (FCSR & 0xFE000000) | // move 31-25 522 Rt_uw<2:2> << 24 | // bit 24 523 (FCSR & 0x00FFF000) << 23 | // bit 23-12 524 Rt_uw<11:7> << 7 | // bit 24 525 (FCSR & 0x000007E) | 526 Rt_uw<1:0>; // bit 22-0 527 break; 528 case 31: 529 data = Rt_uw; 530 break; 531 default: 532 panic("FP Control Value (%d) " 533 "Not Available. Ignoring " 534 "Access to Floating Control " 535 "S""tatus Register", FS); 536 } 537 xc->setRegOtherThread(FLOATREG_FCSR + FP_Base_DepTag, data); 538 }}); 539 default: CP0Unimpl::unknown(); 540 } 541 } 542 } 543 0xB: decode RD { 544 format MT_Control { 545 0x0: decode POS { 546 0x0: decode SEL { 547 0x1: decode SC { 548 0x0: dvpe({{ 549 MVPControlReg mvpControl = MVPControl; 550 VPEConf0Reg vpeConf0 = VPEConf0; 551 Rt = MVPControl; 552 if (vpeConf0.mvp == 1) 553 mvpControl.evp = 0; 554 MVPControl = mvpControl; 555 }}); 556 0x1: evpe({{ 557 MVPControlReg mvpControl = MVPControl; 558 VPEConf0Reg vpeConf0 = VPEConf0; 559 Rt = MVPControl; 560 if (vpeConf0.mvp == 1) 561 mvpControl.evp = 1; 562 MVPControl = mvpControl; 563 }}); 564 default:CP0Unimpl::unknown(); 565 } 566 default:CP0Unimpl::unknown(); 567 } 568 default:CP0Unimpl::unknown(); 569 } 570 0x1: decode POS { 571 0xF: decode SEL { 572 0x1: decode SC { 573 0x0: dmt({{ 574 VPEControlReg vpeControl = VPEControl; 575 Rt = vpeControl; 576 vpeControl.te = 0; 577 VPEControl = vpeControl; 578 }}); 579 0x1: emt({{ 580 VPEControlReg vpeControl = VPEControl; 581 Rt = vpeControl; 582 vpeControl.te = 1; 583 VPEControl = vpeControl; 584 }}); 585 default:CP0Unimpl::unknown(); 586 } 587 default:CP0Unimpl::unknown(); 588 } 589 default:CP0Unimpl::unknown(); 590 } 591 } 592 0xC: decode POS { 593 0x0: decode SC { 594 0x0: CP0Control::di({{ 595 StatusReg status = Status; 596 ConfigReg config = Config; 597 // Rev 2.0 or beyond? 598 if (config.ar >= 1) { 599 Rt = status; 600 status.ie = 0; 601 } else { 602 // Enable this else branch once we 603 // actually set values for Config on init 604 fault = new ReservedInstructionFault(); 605 } 606 Status = status; 607 }}); 608 0x1: CP0Control::ei({{ 609 StatusReg status = Status; 610 ConfigReg config = Config; 611 if (config.ar >= 1) { 612 Rt = status; 613 status.ie = 1; 614 } else { 615 fault = new ReservedInstructionFault(); 616 } 617 }}); 618 default:CP0Unimpl::unknown(); 619 } 620 } 621 default: CP0Unimpl::unknown(); 622 } 623 format CP0Control { 624 0xA: rdpgpr({{ 625 ConfigReg config = Config; 626 if (config.ar >= 1) { 627 // Rev 2 of the architecture 628 panic("Shadow Sets Not Fully Implemented.\n"); 629 } else { 630 fault = new ReservedInstructionFault(); 631 } 632 }}); 633 0xE: wrpgpr({{ 634 ConfigReg config = Config; 635 if (config.ar >= 1) { 636 // Rev 2 of the architecture 637 panic("Shadow Sets Not Fully Implemented.\n"); 638 } else { 639 fault = new ReservedInstructionFault(); 640 } 641 }}); 642 } 643 } 644 645 //Table A-12 MIPS32 COP0 Encoding of Function Field When rs=CO 646 0x1: decode FUNCTION { 647 format CP0Control { 648 0x18: eret({{ 649 StatusReg status = Status; 650 ConfigReg config = Config; 651 SRSCtlReg srsCtl = SRSCtl; 652 DPRINTF(MipsPRA,"Restoring PC - %x\n",EPC); 653 if (status.erl == 1) { 654 status.erl = 0; 655 NPC = ErrorEPC; 656 // Need to adjust NNPC, otherwise things break 657 NNPC = ErrorEPC + sizeof(MachInst); 658 } else { 659 NPC = EPC; 660 // Need to adjust NNPC, otherwise things break 661 NNPC = EPC + sizeof(MachInst); 662 status.exl = 0; 663 if (config.ar >=1 && 664 srsCtl.hss > 0 && 665 status.bev == 0) { 666 srsCtl.css = srsCtl.pss; 667 //xc->setShadowSet(srsCtl.pss); 668 } 669 } 670 LLFlag = 0; 671 Status = status; 672 SRSCtl = srsCtl; 673 }}, IsReturn, IsSerializing, IsERET); 674 675 0x1F: deret({{ 676 DebugReg debug = Debug; 677 if (debug.dm == 1) { 678 debug.dm = 1; 679 debug.iexi = 0; 680 NPC = DEPC; 681 } else { 682 NPC = NPC; 683 // Undefined; 684 } 685 Debug = debug; 686 }}, IsReturn, IsSerializing, IsERET); 687 } 688 format CP0TLB { 689 0x01: tlbr({{ 690 MipsISA::PTE *PTEntry = 691 xc->tcBase()->getITBPtr()-> 692 getEntry(Index & 0x7FFFFFFF); 693 if (PTEntry == NULL) { 694 fatal("Invalid PTE Entry received on " 695 "a TLBR instruction\n"); 696 } 697 /* Setup PageMask */ 698 // If 1KB pages are not enabled, a read of PageMask 699 // must return 0b00 in bits 12, 11 700 PageMask = (PTEntry->Mask << 11); 701 /* Setup EntryHi */ 702 EntryHi = ((PTEntry->VPN << 11) | (PTEntry->asid)); 703 /* Setup Entry Lo0 */ 704 EntryLo0 = ((PTEntry->PFN0 << 6) | 705 (PTEntry->C0 << 3) | 706 (PTEntry->D0 << 2) | 707 (PTEntry->V0 << 1) | 708 PTEntry->G); 709 /* Setup Entry Lo1 */ 710 EntryLo1 = ((PTEntry->PFN1 << 6) | 711 (PTEntry->C1 << 3) | 712 (PTEntry->D1 << 2) | 713 (PTEntry->V1 << 1) | 714 PTEntry->G); 715 }}); // Need to hook up to TLB 716 717 0x02: tlbwi({{ 718 //Create PTE 719 MipsISA::PTE newEntry; 720 //Write PTE 721 newEntry.Mask = (Addr)(PageMask >> 11); 722 newEntry.VPN = (Addr)(EntryHi >> 11); 723 /* PageGrain _ ESP Config3 _ SP */ 724 if (bits(PageGrain, 28) == 0 || bits(Config3, 4) ==0) { 725 // If 1KB pages are *NOT* enabled, lowest bits of 726 // the mask are 0b11 for TLB writes 727 newEntry.Mask |= 0x3; 728 // Reset bits 0 and 1 if 1KB pages are not enabled 729 newEntry.VPN &= 0xFFFFFFFC; 730 } 731 newEntry.asid = (uint8_t)(EntryHi & 0xFF); 732 733 newEntry.PFN0 = (Addr)(EntryLo0 >> 6); 734 newEntry.PFN1 = (Addr)(EntryLo1 >> 6); 735 newEntry.D0 = (bool)((EntryLo0 >> 2) & 1); 736 newEntry.D1 = (bool)((EntryLo1 >> 2) & 1); 737 newEntry.V1 = (bool)((EntryLo1 >> 1) & 1); 738 newEntry.V0 = (bool)((EntryLo0 >> 1) & 1); 739 newEntry.G = (bool)((EntryLo0 & EntryLo1) & 1); 740 newEntry.C0 = (uint8_t)((EntryLo0 >> 3) & 0x7); 741 newEntry.C1 = (uint8_t)((EntryLo1 >> 3) & 0x7); 742 /* Now, compute the AddrShiftAmount and OffsetMask - 743 TLB optimizations */ 744 /* Addr Shift Amount for 1KB or larger pages */ 745 if ((newEntry.Mask & 0xFFFF) == 3) { 746 newEntry.AddrShiftAmount = 12; 747 } else if ((newEntry.Mask & 0xFFFF) == 0x0000) { 748 newEntry.AddrShiftAmount = 10; 749 } else if ((newEntry.Mask & 0xFFFC) == 0x000C) { 750 newEntry.AddrShiftAmount = 14; 751 } else if ((newEntry.Mask & 0xFFF0) == 0x0030) { 752 newEntry.AddrShiftAmount = 16; 753 } else if ((newEntry.Mask & 0xFFC0) == 0x00C0) { 754 newEntry.AddrShiftAmount = 18; 755 } else if ((newEntry.Mask & 0xFF00) == 0x0300) { 756 newEntry.AddrShiftAmount = 20; 757 } else if ((newEntry.Mask & 0xFC00) == 0x0C00) { 758 newEntry.AddrShiftAmount = 22; 759 } else if ((newEntry.Mask & 0xF000) == 0x3000) { 760 newEntry.AddrShiftAmount = 24; 761 } else if ((newEntry.Mask & 0xC000) == 0xC000) { 762 newEntry.AddrShiftAmount = 26; 763 } else if ((newEntry.Mask & 0x30000) == 0x30000) { 764 newEntry.AddrShiftAmount = 28; 765 } else { 766 fatal("Invalid Mask Pattern Detected!\n"); 767 } 768 newEntry.OffsetMask = 769 (1 << newEntry.AddrShiftAmount) - 1; 770 771 MipsISA::TLB *Ptr = xc->tcBase()->getITBPtr(); 772 Config3Reg config3 = Config3; 773 PageGrainReg pageGrain = PageGrain; 774 int SP = 0; 775 if (bits(config3, config3.sp) == 1 && 776 bits(pageGrain, pageGrain.esp) == 1) { 777 SP = 1; 778 } 779 Ptr->insertAt(newEntry, Index & 0x7FFFFFFF, SP); 780 }}); 781 0x06: tlbwr({{ 782 //Create PTE 783 MipsISA::PTE newEntry; 784 //Write PTE 785 newEntry.Mask = (Addr)(PageMask >> 11); 786 newEntry.VPN = (Addr)(EntryHi >> 11); 787 /* PageGrain _ ESP Config3 _ SP */ 788 if (bits(PageGrain, 28) == 0 || 789 bits(Config3, 4) == 0) { 790 // If 1KB pages are *NOT* enabled, lowest bits of 791 // the mask are 0b11 for TLB writes 792 newEntry.Mask |= 0x3; 793 // Reset bits 0 and 1 if 1KB pages are not enabled 794 newEntry.VPN &= 0xFFFFFFFC; 795 } 796 newEntry.asid = (uint8_t)(EntryHi & 0xFF); 797 798 newEntry.PFN0 = (Addr)(EntryLo0 >> 6); 799 newEntry.PFN1 = (Addr)(EntryLo1 >> 6); 800 newEntry.D0 = (bool)((EntryLo0 >> 2) & 1); 801 newEntry.D1 = (bool)((EntryLo1 >> 2) & 1); 802 newEntry.V1 = (bool)((EntryLo1 >> 1) & 1); 803 newEntry.V0 = (bool)((EntryLo0 >> 1) & 1); 804 newEntry.G = (bool)((EntryLo0 & EntryLo1) & 1); 805 newEntry.C0 = (uint8_t)((EntryLo0 >> 3) & 0x7); 806 newEntry.C1 = (uint8_t)((EntryLo1 >> 3) & 0x7); 807 /* Now, compute the AddrShiftAmount and OffsetMask - 808 TLB optimizations */ 809 /* Addr Shift Amount for 1KB or larger pages */ 810 if ((newEntry.Mask & 0xFFFF) == 3){ 811 newEntry.AddrShiftAmount = 12; 812 } else if ((newEntry.Mask & 0xFFFF) == 0x0000) { 813 newEntry.AddrShiftAmount = 10; 814 } else if ((newEntry.Mask & 0xFFFC) == 0x000C) { 815 newEntry.AddrShiftAmount = 14; 816 } else if ((newEntry.Mask & 0xFFF0) == 0x0030) { 817 newEntry.AddrShiftAmount = 16; 818 } else if ((newEntry.Mask & 0xFFC0) == 0x00C0) { 819 newEntry.AddrShiftAmount = 18; 820 } else if ((newEntry.Mask & 0xFF00) == 0x0300) { 821 newEntry.AddrShiftAmount = 20; 822 } else if ((newEntry.Mask & 0xFC00) == 0x0C00) { 823 newEntry.AddrShiftAmount = 22; 824 } else if ((newEntry.Mask & 0xF000) == 0x3000) { 825 newEntry.AddrShiftAmount = 24; 826 } else if ((newEntry.Mask & 0xC000) == 0xC000) { 827 newEntry.AddrShiftAmount = 26; 828 } else if ((newEntry.Mask & 0x30000) == 0x30000) { 829 newEntry.AddrShiftAmount = 28; 830 } else { 831 fatal("Invalid Mask Pattern Detected!\n"); 832 } 833 newEntry.OffsetMask = 834 (1 << newEntry.AddrShiftAmount) - 1; 835 836 MipsISA::TLB *Ptr = xc->tcBase()->getITBPtr(); 837 Config3Reg config3 = Config3; 838 PageGrainReg pageGrain = PageGrain; 839 int SP = 0; 840 if (bits(config3, config3.sp) == 1 && 841 bits(pageGrain, pageGrain.esp) == 1) { 842 SP = 1; 843 } 844 Ptr->insertAt(newEntry, Random, SP); 845 }}); 846 847 0x08: tlbp({{ 848 Config3Reg config3 = Config3; 849 PageGrainReg pageGrain = PageGrain; 850 EntryHiReg entryHi = EntryHi; 851 int tlbIndex; 852 Addr vpn; 853 if (pageGrain.esp == 1 && config3.sp ==1) { 854 vpn = EntryHi >> 11; 855 } else { 856 // Mask off lower 2 bits 857 vpn = ((EntryHi >> 11) & 0xFFFFFFFC); 858 } 859 tlbIndex = xc->tcBase()->getITBPtr()-> 860 probeEntry(vpn, entryHi.asid); 861 // Check TLB for entry matching EntryHi 862 if (tlbIndex != -1) { 863 Index = tlbIndex; 864 } else { 865 // else, set Index = 1 << 31 866 Index = (1 << 31); 867 } 868 }}); 869 } 870 format CP0Unimpl { 871 0x20: wait(); 872 } 873 default: CP0Unimpl::unknown(); 874 } 875 } 876 877 //Table A-13 MIPS32 COP1 Encoding of rs Field 878 0x1: decode RS_MSB { 879 0x0: decode RS_HI { 880 0x0: decode RS_LO { 881 format CP1Control { 882 0x0: mfc1 ({{ Rt_uw = Fs_uw; }}); 883 884 0x2: cfc1({{ 885 switch (FS) { 886 case 0: 887 Rt = FIR; 888 break; 889 case 25: 890 Rt = (FCSR & 0xFE000000) >> 24 | 891 (FCSR & 0x00800000) >> 23; 892 break; 893 case 26: 894 Rt = (FCSR & 0x0003F07C); 895 break; 896 case 28: 897 Rt = (FCSR & 0x00000F80) | 898 (FCSR & 0x01000000) >> 21 | 899 (FCSR & 0x00000003); 900 break; 901 case 31: 902 Rt = FCSR; 903 break; 904 default: 905 warn("FP Control Value (%d) Not Valid"); 906 } 907 }}); 908 909 0x3: mfhc1({{ Rt_uw = Fs_ud<63:32>; }}); 910 911 0x4: mtc1({{ Fs_uw = Rt_uw; }}); 912 913 0x6: ctc1({{ 914 switch (FS) { 915 case 25: 916 FCSR = (Rt_uw<7:1> << 25) | // move 31-25 917 (FCSR & 0x01000000) | // bit 24 918 (FCSR & 0x004FFFFF); // bit 22-0 919 break; 920 case 26: 921 FCSR = (FCSR & 0xFFFC0000) | // move 31-18 922 Rt_uw<17:12> << 12 | // bit 17-12 923 (FCSR & 0x00000F80) << 7 | // bit 11-7 924 Rt_uw<6:2> << 2 | // bit 6-2 925 (FCSR & 0x00000002); // bit 1-0 926 break; 927 case 28: 928 FCSR = (FCSR & 0xFE000000) | // move 31-25 929 Rt_uw<2:2> << 24 | // bit 24 930 (FCSR & 0x00FFF000) << 23 | // bit 23-12 931 Rt_uw<11:7> << 7 | // bit 24 932 (FCSR & 0x000007E) | 933 Rt_uw<1:0>; // bit 22-0 934 break; 935 case 31: 936 FCSR = Rt_uw; 937 break; 938 939 default: 940 panic("FP Control Value (%d) " 941 "Not Available. Ignoring Access " 942 "to Floating Control Status " 943 "Register", FS); 944 } 945 }}); 946 947 0x7: mthc1({{ 948 uint64_t fs_hi = Rt_uw; 949 uint64_t fs_lo = Fs_ud & 0x0FFFFFFFF; 950 Fs_ud = (fs_hi << 32) | fs_lo; 951 }}); 952 953 } 954 format CP1Unimpl { 955 0x1: dmfc1(); 956 0x5: dmtc1(); 957 } 958 } 959 960 0x1: decode RS_LO { 961 0x0: decode ND { 962 format Branch { 963 0x0: decode TF { 964 0x0: bc1f({{ 965 cond = getCondCode(FCSR, BRANCH_CC) == 0; 966 }}); 967 0x1: bc1t({{ 968 cond = getCondCode(FCSR, BRANCH_CC) == 1; 969 }}); 970 } 971 0x1: decode TF { 972 0x0: bc1fl({{ 973 cond = getCondCode(FCSR, BRANCH_CC) == 0; 974 }}, Likely); 975 0x1: bc1tl({{ 976 cond = getCondCode(FCSR, BRANCH_CC) == 1; 977 }}, Likely); 978 } 979 } 980 } 981 format CP1Unimpl { 982 0x1: bc1any2(); 983 0x2: bc1any4(); 984 default: unknown(); 985 } 986 } 987 } 988 989 0x1: decode RS_HI { 990 0x2: decode RS_LO { 991 //Table A-14 MIPS32 COP1 Encoding of Function Field When 992 //rs=S (( single-precision floating point)) 993 0x0: decode FUNCTION_HI { 994 0x0: decode FUNCTION_LO { 995 format FloatOp { 996 0x0: add_s({{ Fd_sf = Fs_sf + Ft_sf; }}); 997 0x1: sub_s({{ Fd_sf = Fs_sf - Ft_sf; }}); 998 0x2: mul_s({{ Fd_sf = Fs_sf * Ft_sf; }}); 999 0x3: div_s({{ Fd_sf = Fs_sf / Ft_sf; }}); 1000 0x4: sqrt_s({{ Fd_sf = sqrt(Fs_sf); }}); 1001 0x5: abs_s({{ Fd_sf = fabs(Fs_sf); }}); 1002 0x7: neg_s({{ Fd_sf = -Fs_sf; }}); 1003 } 1004 0x6: BasicOp::mov_s({{ Fd_sf = Fs_sf; }}); 1005 } 1006 0x1: decode FUNCTION_LO { 1007 format FloatConvertOp { 1008 0x0: round_l_s({{ val = Fs_sf; }}, 1009 ToLong, Round); 1010 0x1: trunc_l_s({{ val = Fs_sf; }}, 1011 ToLong, Trunc); 1012 0x2: ceil_l_s({{ val = Fs_sf;}}, 1013 ToLong, Ceil); 1014 0x3: floor_l_s({{ val = Fs_sf; }}, 1015 ToLong, Floor); 1016 0x4: round_w_s({{ val = Fs_sf; }}, 1017 ToWord, Round); 1018 0x5: trunc_w_s({{ val = Fs_sf; }}, 1019 ToWord, Trunc); 1020 0x6: ceil_w_s({{ val = Fs_sf; }}, 1021 ToWord, Ceil); 1022 0x7: floor_w_s({{ val = Fs_sf; }}, 1023 ToWord, Floor); 1024 } 1025 } 1026 1027 0x2: decode FUNCTION_LO { 1028 0x1: decode MOVCF { 1029 format BasicOp { 1030 0x0: movf_s({{ 1031 Fd = (getCondCode(FCSR,CC) == 0) ? 1032 Fs : Fd; 1033 }}); 1034 0x1: movt_s({{ 1035 Fd = (getCondCode(FCSR,CC) == 1) ? 1036 Fs : Fd; 1037 }}); 1038 } 1039 } 1040 1041 format BasicOp { 1042 0x2: movz_s({{ Fd = (Rt == 0) ? Fs : Fd; }}); 1043 0x3: movn_s({{ Fd = (Rt != 0) ? Fs : Fd; }}); 1044 } 1045 1046 format FloatOp { 1047 0x5: recip_s({{ Fd = 1 / Fs; }}); 1048 0x6: rsqrt_s({{ Fd = 1 / sqrt(Fs); }}); 1049 } 1050 format CP1Unimpl { 1051 default: unknown(); 1052 } 1053 } 1054 0x3: CP1Unimpl::unknown(); 1055 1056 0x4: decode FUNCTION_LO { 1057 format FloatConvertOp { 1058 0x1: cvt_d_s({{ val = Fs_sf; }}, ToDouble); 1059 0x4: cvt_w_s({{ val = Fs_sf; }}, ToWord); 1060 0x5: cvt_l_s({{ val = Fs_sf; }}, ToLong); 1061 } 1062 1063 0x6: FloatOp::cvt_ps_s({{ 1064 Fd_ud = (uint64_t) Fs_uw << 32 | 1065 (uint64_t) Ft_uw; 1066 }}); 1067 format CP1Unimpl { 1068 default: unknown(); 1069 } 1070 } 1071 0x5: CP1Unimpl::unknown(); 1072 1073 0x6: decode FUNCTION_LO { 1074 format FloatCompareOp { 1075 0x0: c_f_s({{ cond = 0; }}, 1076 SinglePrecision, UnorderedFalse); 1077 0x1: c_un_s({{ cond = 0; }}, 1078 SinglePrecision, UnorderedTrue); 1079 0x2: c_eq_s({{ cond = (Fs_sf == Ft_sf); }}, 1080 UnorderedFalse); 1081 0x3: c_ueq_s({{ cond = (Fs_sf == Ft_sf); }}, 1082 UnorderedTrue); 1083 0x4: c_olt_s({{ cond = (Fs_sf < Ft_sf); }}, 1084 UnorderedFalse); 1085 0x5: c_ult_s({{ cond = (Fs_sf < Ft_sf); }}, 1086 UnorderedTrue); 1087 0x6: c_ole_s({{ cond = (Fs_sf <= Ft_sf); }}, 1088 UnorderedFalse); 1089 0x7: c_ule_s({{ cond = (Fs_sf <= Ft_sf); }}, 1090 UnorderedTrue); 1091 } 1092 } 1093 1094 0x7: decode FUNCTION_LO { 1095 format FloatCompareOp { 1096 0x0: c_sf_s({{ cond = 0; }}, SinglePrecision, 1097 UnorderedFalse, QnanException); 1098 0x1: c_ngle_s({{ cond = 0; }}, SinglePrecision, 1099 UnorderedTrue, QnanException); 1100 0x2: c_seq_s({{ cond = (Fs_sf == Ft_sf); }}, 1101 UnorderedFalse, QnanException); 1102 0x3: c_ngl_s({{ cond = (Fs_sf == Ft_sf); }}, 1103 UnorderedTrue, QnanException); 1104 0x4: c_lt_s({{ cond = (Fs_sf < Ft_sf); }}, 1105 UnorderedFalse, QnanException); 1106 0x5: c_nge_s({{ cond = (Fs_sf < Ft_sf); }}, 1107 UnorderedTrue, QnanException); 1108 0x6: c_le_s({{ cond = (Fs_sf <= Ft_sf); }}, 1109 UnorderedFalse, QnanException); 1110 0x7: c_ngt_s({{ cond = (Fs_sf <= Ft_sf); }}, 1111 UnorderedTrue, QnanException); 1112 } 1113 } 1114 } 1115 1116 //Table A-15 MIPS32 COP1 Encoding of Function Field When 1117 //rs=D 1118 0x1: decode FUNCTION_HI { 1119 0x0: decode FUNCTION_LO { 1120 format FloatOp { 1121 0x0: add_d({{ Fd_df = Fs_df + Ft_df; }}); 1122 0x1: sub_d({{ Fd_df = Fs_df - Ft_df; }}); 1123 0x2: mul_d({{ Fd_df = Fs_df * Ft_df; }}); 1124 0x3: div_d({{ Fd_df = Fs_df / Ft_df; }}); 1125 0x4: sqrt_d({{ Fd_df = sqrt(Fs_df); }}); 1126 0x5: abs_d({{ Fd_df = fabs(Fs_df); }}); 1127 0x7: neg_d({{ Fd_df = -1 * Fs_df; }}); 1128 } 1129 0x6: BasicOp::mov_d({{ Fd_df = Fs_df; }}); 1130 } 1131 1132 0x1: decode FUNCTION_LO { 1133 format FloatConvertOp { 1134 0x0: round_l_d({{ val = Fs_df; }}, 1135 ToLong, Round); 1136 0x1: trunc_l_d({{ val = Fs_df; }}, 1137 ToLong, Trunc); 1138 0x2: ceil_l_d({{ val = Fs_df; }}, 1139 ToLong, Ceil); 1140 0x3: floor_l_d({{ val = Fs_df; }}, 1141 ToLong, Floor); 1142 0x4: round_w_d({{ val = Fs_df; }}, 1143 ToWord, Round); 1144 0x5: trunc_w_d({{ val = Fs_df; }}, 1145 ToWord, Trunc); 1146 0x6: ceil_w_d({{ val = Fs_df; }}, 1147 ToWord, Ceil); 1148 0x7: floor_w_d({{ val = Fs_df; }}, 1149 ToWord, Floor); 1150 } 1151 } 1152 1153 0x2: decode FUNCTION_LO { 1154 0x1: decode MOVCF { 1155 format BasicOp { 1156 0x0: movf_d({{ 1157 Fd_df = (getCondCode(FCSR,CC) == 0) ? 1158 Fs_df : Fd_df; 1159 }}); 1160 0x1: movt_d({{ 1161 Fd_df = (getCondCode(FCSR,CC) == 1) ? 1162 Fs_df : Fd_df; 1163 }}); 1164 } 1165 } 1166 1167 format BasicOp { 1168 0x2: movz_d({{ 1169 Fd_df = (Rt == 0) ? Fs_df : Fd_df; 1170 }}); 1171 0x3: movn_d({{ 1172 Fd_df = (Rt != 0) ? Fs_df : Fd_df; 1173 }}); 1174 } 1175 1176 format FloatOp { 1177 0x5: recip_d({{ Fd_df = 1 / Fs_df; }}); 1178 0x6: rsqrt_d({{ Fd_df = 1 / sqrt(Fs_df); }}); 1179 } 1180 format CP1Unimpl { 1181 default: unknown(); 1182 } 1183 1184 } 1185 0x4: decode FUNCTION_LO { 1186 format FloatConvertOp { 1187 0x0: cvt_s_d({{ val = Fs_df; }}, ToSingle); 1188 0x4: cvt_w_d({{ val = Fs_df; }}, ToWord); 1189 0x5: cvt_l_d({{ val = Fs_df; }}, ToLong); 1190 } 1191 default: CP1Unimpl::unknown(); 1192 } 1193 1194 0x6: decode FUNCTION_LO { 1195 format FloatCompareOp { 1196 0x0: c_f_d({{ cond = 0; }}, 1197 DoublePrecision, UnorderedFalse); 1198 0x1: c_un_d({{ cond = 0; }}, 1199 DoublePrecision, UnorderedTrue); 1200 0x2: c_eq_d({{ cond = (Fs_df == Ft_df); }}, 1201 UnorderedFalse); 1202 0x3: c_ueq_d({{ cond = (Fs_df == Ft_df); }}, 1203 UnorderedTrue); 1204 0x4: c_olt_d({{ cond = (Fs_df < Ft_df); }}, 1205 UnorderedFalse); 1206 0x5: c_ult_d({{ cond = (Fs_df < Ft_df); }}, 1207 UnorderedTrue); 1208 0x6: c_ole_d({{ cond = (Fs_df <= Ft_df); }}, 1209 UnorderedFalse); 1210 0x7: c_ule_d({{ cond = (Fs_df <= Ft_df); }}, 1211 UnorderedTrue); 1212 } 1213 } 1214 1215 0x7: decode FUNCTION_LO { 1216 format FloatCompareOp { 1217 0x0: c_sf_d({{ cond = 0; }}, DoublePrecision, 1218 UnorderedFalse, QnanException); 1219 0x1: c_ngle_d({{ cond = 0; }}, DoublePrecision, 1220 UnorderedTrue, QnanException); 1221 0x2: c_seq_d({{ cond = (Fs_df == Ft_df); }}, 1222 UnorderedFalse, QnanException); 1223 0x3: c_ngl_d({{ cond = (Fs_df == Ft_df); }}, 1224 UnorderedTrue, QnanException); 1225 0x4: c_lt_d({{ cond = (Fs_df < Ft_df); }}, 1226 UnorderedFalse, QnanException); 1227 0x5: c_nge_d({{ cond = (Fs_df < Ft_df); }}, 1228 UnorderedTrue, QnanException); 1229 0x6: c_le_d({{ cond = (Fs_df <= Ft_df); }}, 1230 UnorderedFalse, QnanException); 1231 0x7: c_ngt_d({{ cond = (Fs_df <= Ft_df); }}, 1232 UnorderedTrue, QnanException); 1233 } 1234 } 1235 default: CP1Unimpl::unknown(); 1236 } 1237 0x2: CP1Unimpl::unknown(); 1238 0x3: CP1Unimpl::unknown(); 1239 0x7: CP1Unimpl::unknown(); 1240 1241 //Table A-16 MIPS32 COP1 Encoding of Function 1242 //Field When rs=W 1243 0x4: decode FUNCTION { 1244 format FloatConvertOp { 1245 0x20: cvt_s_w({{ val = Fs_uw; }}, ToSingle); 1246 0x21: cvt_d_w({{ val = Fs_uw; }}, ToDouble); 1247 0x26: CP1Unimpl::cvt_ps_w(); 1248 } 1249 default: CP1Unimpl::unknown(); 1250 } 1251 1252 //Table A-16 MIPS32 COP1 Encoding of Function Field 1253 //When rs=L1 1254 //Note: "1. Format type L is legal only if 64-bit 1255 //floating point operations are enabled." 1256 0x5: decode FUNCTION_HI { 1257 format FloatConvertOp { 1258 0x20: cvt_s_l({{ val = Fs_ud; }}, ToSingle); 1259 0x21: cvt_d_l({{ val = Fs_ud; }}, ToDouble); 1260 0x26: CP1Unimpl::cvt_ps_l(); 1261 } 1262 default: CP1Unimpl::unknown(); 1263 } 1264 1265 //Table A-17 MIPS64 COP1 Encoding of Function Field 1266 //When rs=PS1 1267 //Note: "1. Format type PS is legal only if 64-bit 1268 //floating point operations are enabled. " 1269 0x6: decode FUNCTION_HI { 1270 0x0: decode FUNCTION_LO { 1271 format Float64Op { 1272 0x0: add_ps({{ 1273 Fd1_sf = Fs1_sf + Ft2_sf; 1274 Fd2_sf = Fs2_sf + Ft2_sf; 1275 }}); 1276 0x1: sub_ps({{ 1277 Fd1_sf = Fs1_sf - Ft2_sf; 1278 Fd2_sf = Fs2_sf - Ft2_sf; 1279 }}); 1280 0x2: mul_ps({{ 1281 Fd1_sf = Fs1_sf * Ft2_sf; 1282 Fd2_sf = Fs2_sf * Ft2_sf; 1283 }}); 1284 0x5: abs_ps({{ 1285 Fd1_sf = fabs(Fs1_sf); 1286 Fd2_sf = fabs(Fs2_sf); 1287 }}); 1288 0x6: mov_ps({{ 1289 Fd1_sf = Fs1_sf; 1290 Fd2_sf = Fs2_sf; 1291 }}); 1292 0x7: neg_ps({{ 1293 Fd1_sf = -(Fs1_sf); 1294 Fd2_sf = -(Fs2_sf); 1295 }}); 1296 default: CP1Unimpl::unknown(); 1297 } 1298 } 1299 0x1: CP1Unimpl::unknown(); 1300 0x2: decode FUNCTION_LO { 1301 0x1: decode MOVCF { 1302 format Float64Op { 1303 0x0: movf_ps({{ 1304 Fd1 = (getCondCode(FCSR, CC) == 0) ? 1305 Fs1 : Fd1; 1306 Fd2 = (getCondCode(FCSR, CC+1) == 0) ? 1307 Fs2 : Fd2; 1308 }}); 1309 0x1: movt_ps({{ 1310 Fd2 = (getCondCode(FCSR, CC) == 1) ? 1311 Fs1 : Fd1; 1312 Fd2 = (getCondCode(FCSR, CC+1) == 1) ? 1313 Fs2 : Fd2; 1314 }}); 1315 } 1316 } 1317 1318 format Float64Op { 1319 0x2: movz_ps({{ 1320 Fd1 = (getCondCode(FCSR, CC) == 0) ? 1321 Fs1 : Fd1; 1322 Fd2 = (getCondCode(FCSR, CC) == 0) ? 1323 Fs2 : Fd2; 1324 }}); 1325 0x3: movn_ps({{ 1326 Fd1 = (getCondCode(FCSR, CC) == 1) ? 1327 Fs1 : Fd1; 1328 Fd2 = (getCondCode(FCSR, CC) == 1) ? 1329 Fs2 : Fd2; 1330 }}); 1331 } 1332 default: CP1Unimpl::unknown(); 1333 } 1334 0x3: CP1Unimpl::unknown(); 1335 0x4: decode FUNCTION_LO { 1336 0x0: FloatOp::cvt_s_pu({{ Fd_sf = Fs2_sf; }}); 1337 default: CP1Unimpl::unknown(); 1338 } 1339 1340 0x5: decode FUNCTION_LO { 1341 0x0: FloatOp::cvt_s_pl({{ Fd_sf = Fs1_sf; }}); 1342 format Float64Op { 1343 0x4: pll({{ 1344 Fd_ud = (uint64_t)Fs1_uw << 32 | Ft1_uw; 1345 }}); 1346 0x5: plu({{ 1347 Fd_ud = (uint64_t)Fs1_uw << 32 | Ft2_uw; 1348 }}); 1349 0x6: pul({{ 1350 Fd_ud = (uint64_t)Fs2_uw << 32 | Ft1_uw; 1351 }}); 1352 0x7: puu({{ 1353 Fd_ud = (uint64_t)Fs2_uw << 32 | Ft2_uw; 1354 }}); 1355 } 1356 default: CP1Unimpl::unknown(); 1357 } 1358 1359 0x6: decode FUNCTION_LO { 1360 format FloatPSCompareOp { 1361 0x0: c_f_ps({{ cond1 = 0; }}, {{ cond2 = 0; }}, 1362 UnorderedFalse); 1363 0x1: c_un_ps({{ cond1 = 0; }}, {{ cond2 = 0; }}, 1364 UnorderedTrue); 1365 0x2: c_eq_ps({{ cond1 = (Fs1_sf == Ft1_sf); }}, 1366 {{ cond2 = (Fs2_sf == Ft2_sf); }}, 1367 UnorderedFalse); 1368 0x3: c_ueq_ps({{ cond1 = (Fs1_sf == Ft1_sf); }}, 1369 {{ cond2 = (Fs2_sf == Ft2_sf); }}, 1370 UnorderedTrue); 1371 0x4: c_olt_ps({{ cond1 = (Fs1_sf < Ft1_sf); }}, 1372 {{ cond2 = (Fs2_sf < Ft2_sf); }}, 1373 UnorderedFalse); 1374 0x5: c_ult_ps({{ cond1 = (Fs_sf < Ft_sf); }}, 1375 {{ cond2 = (Fs2_sf < Ft2_sf); }}, 1376 UnorderedTrue); 1377 0x6: c_ole_ps({{ cond1 = (Fs_sf <= Ft_sf); }}, 1378 {{ cond2 = (Fs2_sf <= Ft2_sf); }}, 1379 UnorderedFalse); 1380 0x7: c_ule_ps({{ cond1 = (Fs1_sf <= Ft1_sf); }}, 1381 {{ cond2 = (Fs2_sf <= Ft2_sf); }}, 1382 UnorderedTrue); 1383 } 1384 } 1385 1386 0x7: decode FUNCTION_LO { 1387 format FloatPSCompareOp { 1388 0x0: c_sf_ps({{ cond1 = 0; }}, {{ cond2 = 0; }}, 1389 UnorderedFalse, QnanException); 1390 0x1: c_ngle_ps({{ cond1 = 0; }}, 1391 {{ cond2 = 0; }}, 1392 UnorderedTrue, QnanException); 1393 0x2: c_seq_ps({{ cond1 = (Fs1_sf == Ft1_sf); }}, 1394 {{ cond2 = (Fs2_sf == Ft2_sf); }}, 1395 UnorderedFalse, QnanException); 1396 0x3: c_ngl_ps({{ cond1 = (Fs1_sf == Ft1_sf); }}, 1397 {{ cond2 = (Fs2_sf == Ft2_sf); }}, 1398 UnorderedTrue, QnanException); 1399 0x4: c_lt_ps({{ cond1 = (Fs1_sf < Ft1_sf); }}, 1400 {{ cond2 = (Fs2_sf < Ft2_sf); }}, 1401 UnorderedFalse, QnanException); 1402 0x5: c_nge_ps({{ cond1 = (Fs1_sf < Ft1_sf); }}, 1403 {{ cond2 = (Fs2_sf < Ft2_sf); }}, 1404 UnorderedTrue, QnanException); 1405 0x6: c_le_ps({{ cond1 = (Fs1_sf <= Ft1_sf); }}, 1406 {{ cond2 = (Fs2_sf <= Ft2_sf); }}, 1407 UnorderedFalse, QnanException); 1408 0x7: c_ngt_ps({{ cond1 = (Fs1_sf <= Ft1_sf); }}, 1409 {{ cond2 = (Fs2_sf <= Ft2_sf); }}, 1410 UnorderedTrue, QnanException); 1411 } 1412 } 1413 } 1414 } 1415 default: CP1Unimpl::unknown(); 1416 } 1417 } 1418 1419 //Table A-19 MIPS32 COP2 Encoding of rs Field 1420 0x2: decode RS_MSB { 1421 format CP2Unimpl { 1422 0x0: decode RS_HI { 1423 0x0: decode RS_LO { 1424 0x0: mfc2(); 1425 0x2: cfc2(); 1426 0x3: mfhc2(); 1427 0x4: mtc2(); 1428 0x6: ctc2(); 1429 0x7: mftc2(); 1430 default: unknown(); 1431 } 1432 1433 0x1: decode ND { 1434 0x0: decode TF { 1435 0x0: bc2f(); 1436 0x1: bc2t(); 1437 default: unknown(); 1438 } 1439 1440 0x1: decode TF { 1441 0x0: bc2fl(); 1442 0x1: bc2tl(); 1443 default: unknown(); 1444 } 1445 default: unknown(); 1446 1447 } 1448 default: unknown(); 1449 } 1450 default: unknown(); 1451 } 1452 } 1453 1454 //Table A-20 MIPS64 COP1X Encoding of Function Field 1 1455 //Note: "COP1X instructions are legal only if 64-bit floating point 1456 //operations are enabled." 1457 0x3: decode FUNCTION_HI { 1458 0x0: decode FUNCTION_LO { 1459 format LoadIndexedMemory { 1460 0x0: lwxc1({{ Fd_uw = Mem_uw; }}); 1461 0x1: ldxc1({{ Fd_ud = Mem_ud; }}); 1462 0x5: luxc1({{ Fd_ud = Mem_ud; }}, 1463 {{ EA = (Rs + Rt) & ~7; }}); 1464 } 1465 } 1466 1467 0x1: decode FUNCTION_LO { 1468 format StoreIndexedMemory { 1469 0x0: swxc1({{ Mem_uw = Fs_uw; }}); 1470 0x1: sdxc1({{ Mem_ud = Fs_ud; }}); 1471 0x5: suxc1({{ Mem_ud = Fs_ud; }}, 1472 {{ EA = (Rs + Rt) & ~7; }}); 1473 } 1474 0x7: Prefetch::prefx({{ EA = Rs + Rt; }}); 1475 } 1476 1477 0x3: decode FUNCTION_LO { 1478 0x6: Float64Op::alnv_ps({{ 1479 if (Rs<2:0> == 0) { 1480 Fd_ud = Fs_ud; 1481 } else if (Rs<2:0> == 4) { 1482 if (GuestByteOrder == BigEndianByteOrder) 1483 Fd_ud = Fs_ud<31:0> << 32 | Ft_ud<63:32>; 1484 else 1485 Fd_ud = Ft_ud<31:0> << 32 | Fs_ud<63:32>; 1486 } else { 1487 Fd_ud = Fd_ud; 1488 } 1489 }}); 1490 } 1491 1492 format FloatAccOp { 1493 0x4: decode FUNCTION_LO { 1494 0x0: madd_s({{ Fd_sf = (Fs_sf * Ft_sf) + Fr_sf; }}); 1495 0x1: madd_d({{ Fd_df = (Fs_df * Ft_df) + Fr_df; }}); 1496 0x6: madd_ps({{ 1497 Fd1_sf = (Fs1_df * Ft1_df) + Fr1_df; 1498 Fd2_sf = (Fs2_df * Ft2_df) + Fr2_df; 1499 }}); 1500 } 1501 1502 0x5: decode FUNCTION_LO { 1503 0x0: msub_s({{ Fd_sf = (Fs_sf * Ft_sf) - Fr_sf; }}); 1504 0x1: msub_d({{ Fd_df = (Fs_df * Ft_df) - Fr_df; }}); 1505 0x6: msub_ps({{ 1506 Fd1_sf = (Fs1_df * Ft1_df) - Fr1_df; 1507 Fd2_sf = (Fs2_df * Ft2_df) - Fr2_df; 1508 }}); 1509 } 1510 1511 0x6: decode FUNCTION_LO { 1512 0x0: nmadd_s({{ Fd_sf = (-1 * Fs_sf * Ft_sf) - Fr_sf; }}); 1513 0x1: nmadd_d({{ Fd_df = (-1 * Fs_df * Ft_df) - Fr_df; }}); 1514 0x6: nmadd_ps({{ 1515 Fd1_sf = -((Fs1_df * Ft1_df) + Fr1_df); 1516 Fd2_sf = -((Fs2_df * Ft2_df) + Fr2_df); 1517 }}); 1518 } 1519 1520 0x7: decode FUNCTION_LO { 1521 0x0: nmsub_s({{ Fd_sf = (-1 * Fs_sf * Ft_sf) + Fr_sf; }}); 1522 0x1: nmsub_d({{ Fd_df = (-1 * Fs_df * Ft_df) + Fr_df; }}); 1523 0x6: nmsub_ps({{ 1524 Fd1_sf = -((Fs1_df * Ft1_df) - Fr1_df); 1525 Fd2_sf = -((Fs2_df * Ft2_df) - Fr2_df); 1526 }}); 1527 } 1528 } 1529 } 1530 1531 format Branch { 1532 0x4: beql({{ cond = (Rs_sw == Rt_sw); }}, Likely); 1533 0x5: bnel({{ cond = (Rs_sw != Rt_sw); }}, Likely); 1534 0x6: blezl({{ cond = (Rs_sw <= 0); }}, Likely); 1535 0x7: bgtzl({{ cond = (Rs_sw > 0); }}, Likely); 1536 } 1537 } 1538 1539 0x3: decode OPCODE_LO { 1540 //Table A-5 MIPS32 SPECIAL2 Encoding of Function Field 1541 0x4: decode FUNCTION_HI { 1542 0x0: decode FUNCTION_LO { 1543 0x2: IntOp::mul({{ 1544 int64_t temp1 = Rs_sd * Rt_sd; 1545 Rd_sw = temp1<31:0>; 1546 }}, IntMultOp); 1547 1548 format HiLoRdSelValOp { 1549 0x0: madd({{ 1550 val = ((int64_t)HI_RD_SEL << 32 | LO_RD_SEL) + 1551 (Rs_sd * Rt_sd); 1552 }}, IntMultOp); 1553 0x1: maddu({{ 1554 val = ((uint64_t)HI_RD_SEL << 32 | LO_RD_SEL) + 1555 (Rs_ud * Rt_ud); 1556 }}, IntMultOp); 1557 0x4: msub({{ 1558 val = ((int64_t)HI_RD_SEL << 32 | LO_RD_SEL) - 1559 (Rs_sd * Rt_sd); 1560 }}, IntMultOp); 1561 0x5: msubu({{ 1562 val = ((uint64_t)HI_RD_SEL << 32 | LO_RD_SEL) - 1563 (Rs_ud * Rt_ud); 1564 }}, IntMultOp); 1565 } 1566 } 1567 1568 0x4: decode FUNCTION_LO { 1569 format BasicOp { 1570 0x0: clz({{ 1571 int cnt = 32; 1572 for (int idx = 31; idx >= 0; idx--) { 1573 if (Rs<idx:idx> == 1) { 1574 cnt = 31 - idx; 1575 break; 1576 } 1577 } 1578 Rd_uw = cnt; 1579 }}); 1580 0x1: clo({{ 1581 int cnt = 32; 1582 for (int idx = 31; idx >= 0; idx--) { 1583 if (Rs<idx:idx> == 0) { 1584 cnt = 31 - idx; 1585 break; 1586 } 1587 } 1588 Rd_uw = cnt; 1589 }}); 1590 } 1591 } 1592 1593 0x7: decode FUNCTION_LO { 1594 0x7: FailUnimpl::sdbbp(); 1595 } 1596 } 1597 1598 //Table A-6 MIPS32 SPECIAL3 Encoding of Function Field for Release 2 1599 //of the Architecture 1600 0x7: decode FUNCTION_HI { 1601 0x0: decode FUNCTION_LO { 1602 format BasicOp { 1603 0x0: ext({{ Rt_uw = bits(Rs_uw, MSB+LSB, LSB); }}); 1604 0x4: ins({{ 1605 Rt_uw = bits(Rt_uw, 31, MSB+1) << (MSB+1) | 1606 bits(Rs_uw, MSB-LSB, 0) << LSB | 1607 bits(Rt_uw, LSB-1, 0); 1608 }}); 1609 } 1610 } 1611 1612 0x1: decode FUNCTION_LO { 1613 format MT_Control { 1614 0x0: fork({{ 1615 forkThread(xc->tcBase(), fault, RD, Rs, Rt); 1616 }}, UserMode); 1617 0x1: yield({{ 1618 Rd_sw = yieldThread(xc->tcBase(), fault, Rs_sw, 1619 YQMask); 1620 }}, UserMode); 1621 } 1622 1623 //Table 5-9 MIPS32 LX Encoding of the op Field (DSP ASE MANUAL) 1624 0x2: decode OP_HI { 1625 0x0: decode OP_LO { 1626 format LoadIndexedMemory { 1627 0x0: lwx({{ Rd_sw = Mem_sw; }}); 1628 0x4: lhx({{ Rd_sw = Mem_sh; }}); 1629 0x6: lbux({{ Rd_uw = Mem_ub; }}); 1630 } 1631 } 1632 } 1633 0x4: DspIntOp::insv({{ 1634 int pos = dspctl<5:0>; 1635 int size = dspctl<12:7> - 1; 1636 Rt_uw = insertBits(Rt_uw, pos+size, 1637 pos, Rs_uw<size:0>); 1638 }}); 1639 } 1640 1641 0x2: decode FUNCTION_LO { 1642 1643 //Table 5-5 MIPS32 ADDU.QB Encoding of the op Field 1644 //(DSP ASE MANUAL) 1645 0x0: decode OP_HI { 1646 0x0: decode OP_LO { 1647 format DspIntOp { 1648 0x0: addu_qb({{ 1649 Rd_uw = dspAdd(Rs_uw, Rt_uw, SIMD_FMT_QB, 1650 NOSATURATE, UNSIGNED, &dspctl); 1651 }}); 1652 0x1: subu_qb({{ 1653 Rd_uw = dspSub(Rs_uw, Rt_uw, SIMD_FMT_QB, 1654 NOSATURATE, UNSIGNED, &dspctl); 1655 }}); 1656 0x4: addu_s_qb({{ 1657 Rd_uw = dspAdd(Rs_uw, Rt_uw, SIMD_FMT_QB, 1658 SATURATE, UNSIGNED, &dspctl); 1659 }}); 1660 0x5: subu_s_qb({{ 1661 Rd_uw = dspSub(Rs_uw, Rt_uw, SIMD_FMT_QB, 1662 SATURATE, UNSIGNED, &dspctl); 1663 }}); 1664 0x6: muleu_s_ph_qbl({{ 1665 Rd_uw = dspMuleu(Rs_uw, Rt_uw, 1666 MODE_L, &dspctl); 1667 }}, IntMultOp); 1668 0x7: muleu_s_ph_qbr({{ 1669 Rd_uw = dspMuleu(Rs_uw, Rt_uw, 1670 MODE_R, &dspctl); 1671 }}, IntMultOp); 1672 } 1673 } 1674 0x1: decode OP_LO { 1675 format DspIntOp { 1676 0x0: addu_ph({{ 1677 Rd_uw = dspAdd(Rs_uw, Rt_uw, SIMD_FMT_PH, 1678 NOSATURATE, UNSIGNED, &dspctl); 1679 }}); 1680 0x1: subu_ph({{ 1681 Rd_uw = dspSub(Rs_uw, Rt_uw, SIMD_FMT_PH, 1682 NOSATURATE, UNSIGNED, &dspctl); 1683 }}); 1684 0x2: addq_ph({{ 1685 Rd_uw = dspAdd(Rs_uw, Rt_uw, SIMD_FMT_PH, 1686 NOSATURATE, SIGNED, &dspctl); 1687 }}); 1688 0x3: subq_ph({{ 1689 Rd_uw = dspSub(Rs_uw, Rt_uw, SIMD_FMT_PH, 1690 NOSATURATE, SIGNED, &dspctl); 1691 }}); 1692 0x4: addu_s_ph({{ 1693 Rd_uw = dspAdd(Rs_uw, Rt_uw, SIMD_FMT_PH, 1694 SATURATE, UNSIGNED, &dspctl); 1695 }}); 1696 0x5: subu_s_ph({{ 1697 Rd_uw = dspSub(Rs_uw, Rt_uw, SIMD_FMT_PH, 1698 SATURATE, UNSIGNED, &dspctl); 1699 }}); 1700 0x6: addq_s_ph({{ 1701 Rd_uw = dspAdd(Rs_uw, Rt_uw, SIMD_FMT_PH, 1702 SATURATE, SIGNED, &dspctl); 1703 }}); 1704 0x7: subq_s_ph({{ 1705 Rd_uw = dspSub(Rs_uw, Rt_uw, SIMD_FMT_PH, 1706 SATURATE, SIGNED, &dspctl); 1707 }}); 1708 } 1709 } 1710 0x2: decode OP_LO { 1711 format DspIntOp { 1712 0x0: addsc({{ 1713 int64_t dresult; 1714 dresult = Rs_ud + Rt_ud; 1715 Rd_sw = dresult<31:0>; 1716 dspctl = insertBits(dspctl, 13, 13, 1717 dresult<32:32>); 1718 }}); 1719 0x1: addwc({{ 1720 int64_t dresult; 1721 dresult = Rs_sd + Rt_sd + dspctl<13:13>; 1722 Rd_sw = dresult<31:0>; 1723 if (dresult<32:32> != dresult<31:31>) 1724 dspctl = insertBits(dspctl, 20, 20, 1); 1725 }}); 1726 0x2: modsub({{ 1727 Rd_sw = (Rs_sw == 0) ? Rt_sw<23:8> : 1728 Rs_sw - Rt_sw<7:0>; 1729 }}); 1730 0x4: raddu_w_qb({{ 1731 Rd_uw = Rs_uw<31:24> + Rs_uw<23:16> + 1732 Rs_uw<15:8> + Rs_uw<7:0>; 1733 }}); 1734 0x6: addq_s_w({{ 1735 Rd_sw = dspAdd(Rs_sw, Rt_sw, SIMD_FMT_W, 1736 SATURATE, SIGNED, &dspctl); 1737 }}); 1738 0x7: subq_s_w({{ 1739 Rd_sw = dspSub(Rs_sw, Rt_sw, SIMD_FMT_W, 1740 SATURATE, SIGNED, &dspctl); 1741 }}); 1742 } 1743 } 1744 0x3: decode OP_LO { 1745 format DspIntOp { 1746 0x4: muleq_s_w_phl({{ 1747 Rd_sw = dspMuleq(Rs_sw, Rt_sw, 1748 MODE_L, &dspctl); 1749 }}, IntMultOp); 1750 0x5: muleq_s_w_phr({{ 1751 Rd_sw = dspMuleq(Rs_sw, Rt_sw, 1752 MODE_R, &dspctl); 1753 }}, IntMultOp); 1754 0x6: mulq_s_ph({{ 1755 Rd_sw = dspMulq(Rs_sw, Rt_sw, SIMD_FMT_PH, 1756 SATURATE, NOROUND, &dspctl); 1757 }}, IntMultOp); 1758 0x7: mulq_rs_ph({{ 1759 Rd_sw = dspMulq(Rs_sw, Rt_sw, SIMD_FMT_PH, 1760 SATURATE, ROUND, &dspctl); 1761 }}, IntMultOp); 1762 } 1763 } 1764 } 1765 1766 //Table 5-6 MIPS32 CMPU_EQ_QB Encoding of the op Field 1767 //(DSP ASE MANUAL) 1768 0x1: decode OP_HI { 1769 0x0: decode OP_LO { 1770 format DspIntOp { 1771 0x0: cmpu_eq_qb({{ 1772 dspCmp(Rs_uw, Rt_uw, SIMD_FMT_QB, 1773 UNSIGNED, CMP_EQ, &dspctl); 1774 }}); 1775 0x1: cmpu_lt_qb({{ 1776 dspCmp(Rs_uw, Rt_uw, SIMD_FMT_QB, 1777 UNSIGNED, CMP_LT, &dspctl); 1778 }}); 1779 0x2: cmpu_le_qb({{ 1780 dspCmp(Rs_uw, Rt_uw, SIMD_FMT_QB, 1781 UNSIGNED, CMP_LE, &dspctl); 1782 }}); 1783 0x3: pick_qb({{ 1784 Rd_uw = dspPick(Rs_uw, Rt_uw, 1785 SIMD_FMT_QB, &dspctl); 1786 }}); 1787 0x4: cmpgu_eq_qb({{ 1788 Rd_uw = dspCmpg(Rs_uw, Rt_uw, SIMD_FMT_QB, 1789 UNSIGNED, CMP_EQ ); 1790 }}); 1791 0x5: cmpgu_lt_qb({{ 1792 Rd_uw = dspCmpg(Rs_uw, Rt_uw, SIMD_FMT_QB, 1793 UNSIGNED, CMP_LT); 1794 }}); 1795 0x6: cmpgu_le_qb({{ 1796 Rd_uw = dspCmpg(Rs_uw, Rt_uw, SIMD_FMT_QB, 1797 UNSIGNED, CMP_LE); 1798 }}); 1799 } 1800 } 1801 0x1: decode OP_LO { 1802 format DspIntOp { 1803 0x0: cmp_eq_ph({{ 1804 dspCmp(Rs_uw, Rt_uw, SIMD_FMT_PH, 1805 SIGNED, CMP_EQ, &dspctl); 1806 }}); 1807 0x1: cmp_lt_ph({{ 1808 dspCmp(Rs_uw, Rt_uw, SIMD_FMT_PH, 1809 SIGNED, CMP_LT, &dspctl); 1810 }}); 1811 0x2: cmp_le_ph({{ 1812 dspCmp(Rs_uw, Rt_uw, SIMD_FMT_PH, 1813 SIGNED, CMP_LE, &dspctl); 1814 }}); 1815 0x3: pick_ph({{ 1816 Rd_uw = dspPick(Rs_uw, Rt_uw, 1817 SIMD_FMT_PH, &dspctl); 1818 }}); 1819 0x4: precrq_qb_ph({{ 1820 Rd_uw = Rs_uw<31:24> << 24 | 1821 Rs_uw<15:8> << 16 | 1822 Rt_uw<31:24> << 8 | 1823 Rt_uw<15:8>; 1824 }}); 1825 0x5: precr_qb_ph({{ 1826 Rd_uw = Rs_uw<23:16> << 24 | 1827 Rs_uw<7:0> << 16 | 1828 Rt_uw<23:16> << 8 | 1829 Rt_uw<7:0>; 1830 }}); 1831 0x6: packrl_ph({{ 1832 Rd_uw = dspPack(Rs_uw, Rt_uw, SIMD_FMT_PH); 1833 }}); 1834 0x7: precrqu_s_qb_ph({{ 1835 Rd_uw = dspPrecrqu(Rs_uw, Rt_uw, &dspctl); 1836 }}); 1837 } 1838 } 1839 0x2: decode OP_LO { 1840 format DspIntOp { 1841 0x4: precrq_ph_w({{ 1842 Rd_uw = Rs_uw<31:16> << 16 | Rt_uw<31:16>; 1843 }}); 1844 0x5: precrq_rs_ph_w({{ 1845 Rd_uw = dspPrecrq(Rs_uw, Rt_uw, 1846 SIMD_FMT_W, &dspctl); 1847 }}); 1848 } 1849 } 1850 0x3: decode OP_LO { 1851 format DspIntOp { 1852 0x0: cmpgdu_eq_qb({{ 1853 Rd_uw = dspCmpgd(Rs_uw, Rt_uw, SIMD_FMT_QB, 1854 UNSIGNED, CMP_EQ, &dspctl); 1855 }}); 1856 0x1: cmpgdu_lt_qb({{ 1857 Rd_uw = dspCmpgd(Rs_uw, Rt_uw, SIMD_FMT_QB, 1858 UNSIGNED, CMP_LT, &dspctl); 1859 }}); 1860 0x2: cmpgdu_le_qb({{ 1861 Rd_uw = dspCmpgd(Rs_uw, Rt_uw, SIMD_FMT_QB, 1862 UNSIGNED, CMP_LE, &dspctl); 1863 }}); 1864 0x6: precr_sra_ph_w({{ 1865 Rt_uw = dspPrecrSra(Rt_uw, Rs_uw, RD, 1866 SIMD_FMT_W, NOROUND); 1867 }}); 1868 0x7: precr_sra_r_ph_w({{ 1869 Rt_uw = dspPrecrSra(Rt_uw, Rs_uw, RD, 1870 SIMD_FMT_W, ROUND); 1871 }}); 1872 } 1873 } 1874 } 1875 1876 //Table 5-7 MIPS32 ABSQ_S.PH Encoding of the op Field 1877 //(DSP ASE MANUAL) 1878 0x2: decode OP_HI { 1879 0x0: decode OP_LO { 1880 format DspIntOp { 1881 0x1: absq_s_qb({{ 1882 Rd_sw = dspAbs(Rt_sw, SIMD_FMT_QB, &dspctl); 1883 }}); 1884 0x2: repl_qb({{ 1885 Rd_uw = RS_RT<7:0> << 24 | 1886 RS_RT<7:0> << 16 | 1887 RS_RT<7:0> << 8 | 1888 RS_RT<7:0>; 1889 }}); 1890 0x3: replv_qb({{ 1891 Rd_sw = Rt_uw<7:0> << 24 | 1892 Rt_uw<7:0> << 16 | 1893 Rt_uw<7:0> << 8 | 1894 Rt_uw<7:0>; 1895 }}); 1896 0x4: precequ_ph_qbl({{ 1897 Rd_uw = dspPrece(Rt_uw, SIMD_FMT_QB, UNSIGNED, 1898 SIMD_FMT_PH, SIGNED, MODE_L); 1899 }}); 1900 0x5: precequ_ph_qbr({{ 1901 Rd_uw = dspPrece(Rt_uw, SIMD_FMT_QB, UNSIGNED, 1902 SIMD_FMT_PH, SIGNED, MODE_R); 1903 }}); 1904 0x6: precequ_ph_qbla({{ 1905 Rd_uw = dspPrece(Rt_uw, SIMD_FMT_QB, UNSIGNED, 1906 SIMD_FMT_PH, SIGNED, MODE_LA); 1907 }}); 1908 0x7: precequ_ph_qbra({{ 1909 Rd_uw = dspPrece(Rt_uw, SIMD_FMT_QB, UNSIGNED, 1910 SIMD_FMT_PH, SIGNED, MODE_RA); 1911 }}); 1912 } 1913 } 1914 0x1: decode OP_LO { 1915 format DspIntOp { 1916 0x1: absq_s_ph({{ 1917 Rd_sw = dspAbs(Rt_sw, SIMD_FMT_PH, &dspctl); 1918 }}); 1919 0x2: repl_ph({{ 1920 Rd_uw = (sext<10>(RS_RT))<15:0> << 16 | 1921 (sext<10>(RS_RT))<15:0>; 1922 }}); 1923 0x3: replv_ph({{ 1924 Rd_uw = Rt_uw<15:0> << 16 | 1925 Rt_uw<15:0>; 1926 }}); 1927 0x4: preceq_w_phl({{ 1928 Rd_uw = dspPrece(Rt_uw, SIMD_FMT_PH, SIGNED, 1929 SIMD_FMT_W, SIGNED, MODE_L); 1930 }}); 1931 0x5: preceq_w_phr({{ 1932 Rd_uw = dspPrece(Rt_uw, SIMD_FMT_PH, SIGNED, 1933 SIMD_FMT_W, SIGNED, MODE_R); 1934 }}); 1935 } 1936 } 1937 0x2: decode OP_LO { 1938 format DspIntOp { 1939 0x1: absq_s_w({{ 1940 Rd_sw = dspAbs(Rt_sw, SIMD_FMT_W, &dspctl); 1941 }}); 1942 } 1943 } 1944 0x3: decode OP_LO { 1945 0x3: IntOp::bitrev({{ 1946 Rd_uw = bitrev( Rt_uw<15:0> ); 1947 }}); 1948 format DspIntOp { 1949 0x4: preceu_ph_qbl({{ 1950 Rd_uw = dspPrece(Rt_uw, SIMD_FMT_QB, 1951 UNSIGNED, SIMD_FMT_PH, 1952 UNSIGNED, MODE_L); 1953 }}); 1954 0x5: preceu_ph_qbr({{ 1955 Rd_uw = dspPrece(Rt_uw, SIMD_FMT_QB, 1956 UNSIGNED, SIMD_FMT_PH, 1957 UNSIGNED, MODE_R ); 1958 }}); 1959 0x6: preceu_ph_qbla({{ 1960 Rd_uw = dspPrece(Rt_uw, SIMD_FMT_QB, 1961 UNSIGNED, SIMD_FMT_PH, 1962 UNSIGNED, MODE_LA ); 1963 }}); 1964 0x7: preceu_ph_qbra({{ 1965 Rd_uw = dspPrece(Rt_uw, SIMD_FMT_QB, 1966 UNSIGNED, SIMD_FMT_PH, 1967 UNSIGNED, MODE_RA); 1968 }}); 1969 } 1970 } 1971 } 1972 1973 //Table 5-8 MIPS32 SHLL.QB Encoding of the op Field 1974 //(DSP ASE MANUAL) 1975 0x3: decode OP_HI { 1976 0x0: decode OP_LO { 1977 format DspIntOp { 1978 0x0: shll_qb({{ 1979 Rd_sw = dspShll(Rt_sw, RS, SIMD_FMT_QB, 1980 NOSATURATE, UNSIGNED, &dspctl); 1981 }}); 1982 0x1: shrl_qb({{ 1983 Rd_sw = dspShrl(Rt_sw, RS, SIMD_FMT_QB, 1984 UNSIGNED); 1985 }}); 1986 0x2: shllv_qb({{ 1987 Rd_sw = dspShll(Rt_sw, Rs_sw, SIMD_FMT_QB, 1988 NOSATURATE, UNSIGNED, &dspctl); 1989 }}); 1990 0x3: shrlv_qb({{ 1991 Rd_sw = dspShrl(Rt_sw, Rs_sw, SIMD_FMT_QB, 1992 UNSIGNED); 1993 }}); 1994 0x4: shra_qb({{ 1995 Rd_sw = dspShra(Rt_sw, RS, SIMD_FMT_QB, 1996 NOROUND, SIGNED, &dspctl); 1997 }}); 1998 0x5: shra_r_qb({{ 1999 Rd_sw = dspShra(Rt_sw, RS, SIMD_FMT_QB, 2000 ROUND, SIGNED, &dspctl); 2001 }}); 2002 0x6: shrav_qb({{ 2003 Rd_sw = dspShra(Rt_sw, Rs_sw, SIMD_FMT_QB, 2004 NOROUND, SIGNED, &dspctl); 2005 }}); 2006 0x7: shrav_r_qb({{ 2007 Rd_sw = dspShra(Rt_sw, Rs_sw, SIMD_FMT_QB, 2008 ROUND, SIGNED, &dspctl); 2009 }}); 2010 } 2011 } 2012 0x1: decode OP_LO { 2013 format DspIntOp { 2014 0x0: shll_ph({{ 2015 Rd_uw = dspShll(Rt_uw, RS, SIMD_FMT_PH, 2016 NOSATURATE, SIGNED, &dspctl); 2017 }}); 2018 0x1: shra_ph({{ 2019 Rd_sw = dspShra(Rt_sw, RS, SIMD_FMT_PH, 2020 NOROUND, SIGNED, &dspctl); 2021 }}); 2022 0x2: shllv_ph({{ 2023 Rd_sw = dspShll(Rt_sw, Rs_sw, SIMD_FMT_PH, 2024 NOSATURATE, SIGNED, &dspctl); 2025 }}); 2026 0x3: shrav_ph({{ 2027 Rd_sw = dspShra(Rt_sw, Rs_sw, SIMD_FMT_PH, 2028 NOROUND, SIGNED, &dspctl); 2029 }}); 2030 0x4: shll_s_ph({{ 2031 Rd_sw = dspShll(Rt_sw, RS, SIMD_FMT_PH, 2032 SATURATE, SIGNED, &dspctl); 2033 }}); 2034 0x5: shra_r_ph({{ 2035 Rd_sw = dspShra(Rt_sw, RS, SIMD_FMT_PH, 2036 ROUND, SIGNED, &dspctl); 2037 }}); 2038 0x6: shllv_s_ph({{ 2039 Rd_sw = dspShll(Rt_sw, Rs_sw, SIMD_FMT_PH, 2040 SATURATE, SIGNED, &dspctl); 2041 }}); 2042 0x7: shrav_r_ph({{ 2043 Rd_sw = dspShra(Rt_sw, Rs_sw, SIMD_FMT_PH, 2044 ROUND, SIGNED, &dspctl); 2045 }}); 2046 } 2047 } 2048 0x2: decode OP_LO { 2049 format DspIntOp { 2050 0x4: shll_s_w({{ 2051 Rd_sw = dspShll(Rt_sw, RS, SIMD_FMT_W, 2052 SATURATE, SIGNED, &dspctl); 2053 }}); 2054 0x5: shra_r_w({{ 2055 Rd_sw = dspShra(Rt_sw, RS, SIMD_FMT_W, 2056 ROUND, SIGNED, &dspctl); 2057 }}); 2058 0x6: shllv_s_w({{ 2059 Rd_sw = dspShll(Rt_sw, Rs_sw, SIMD_FMT_W, 2060 SATURATE, SIGNED, &dspctl); 2061 }}); 2062 0x7: shrav_r_w({{ 2063 Rd_sw = dspShra(Rt_sw, Rs_sw, SIMD_FMT_W, 2064 ROUND, SIGNED, &dspctl); 2065 }}); 2066 } 2067 } 2068 0x3: decode OP_LO { 2069 format DspIntOp { 2070 0x1: shrl_ph({{ 2071 Rd_sw = dspShrl(Rt_sw, RS, SIMD_FMT_PH, 2072 UNSIGNED); 2073 }}); 2074 0x3: shrlv_ph({{ 2075 Rd_sw = dspShrl(Rt_sw, Rs_sw, SIMD_FMT_PH, 2076 UNSIGNED); 2077 }}); 2078 } 2079 } 2080 } 2081 } 2082 2083 0x3: decode FUNCTION_LO { 2084 2085 //Table 3.12 MIPS32 ADDUH.QB Encoding of the op Field 2086 //(DSP ASE Rev2 Manual) 2087 0x0: decode OP_HI { 2088 0x0: decode OP_LO { 2089 format DspIntOp { 2090 0x0: adduh_qb({{ 2091 Rd_uw = dspAddh(Rs_sw, Rt_sw, SIMD_FMT_QB, 2092 NOROUND, UNSIGNED); 2093 }}); 2094 0x1: subuh_qb({{ 2095 Rd_uw = dspSubh(Rs_sw, Rt_sw, SIMD_FMT_QB, 2096 NOROUND, UNSIGNED); 2097 }}); 2098 0x2: adduh_r_qb({{ 2099 Rd_uw = dspAddh(Rs_sw, Rt_sw, SIMD_FMT_QB, 2100 ROUND, UNSIGNED); 2101 }}); 2102 0x3: subuh_r_qb({{ 2103 Rd_uw = dspSubh(Rs_sw, Rt_sw, SIMD_FMT_QB, 2104 ROUND, UNSIGNED); 2105 }}); 2106 } 2107 } 2108 0x1: decode OP_LO { 2109 format DspIntOp { 2110 0x0: addqh_ph({{ 2111 Rd_uw = dspAddh(Rs_sw, Rt_sw, SIMD_FMT_PH, 2112 NOROUND, SIGNED); 2113 }}); 2114 0x1: subqh_ph({{ 2115 Rd_uw = dspSubh(Rs_sw, Rt_sw, SIMD_FMT_PH, 2116 NOROUND, SIGNED); 2117 }}); 2118 0x2: addqh_r_ph({{ 2119 Rd_uw = dspAddh(Rs_sw, Rt_sw, SIMD_FMT_PH, 2120 ROUND, SIGNED); 2121 }}); 2122 0x3: subqh_r_ph({{ 2123 Rd_uw = dspSubh(Rs_sw, Rt_sw, SIMD_FMT_PH, 2124 ROUND, SIGNED); 2125 }}); 2126 0x4: mul_ph({{ 2127 Rd_sw = dspMul(Rs_sw, Rt_sw, SIMD_FMT_PH, 2128 NOSATURATE, &dspctl); 2129 }}, IntMultOp); 2130 0x6: mul_s_ph({{ 2131 Rd_sw = dspMul(Rs_sw, Rt_sw, SIMD_FMT_PH, 2132 SATURATE, &dspctl); 2133 }}, IntMultOp); 2134 } 2135 } 2136 0x2: decode OP_LO { 2137 format DspIntOp { 2138 0x0: addqh_w({{ 2139 Rd_uw = dspAddh(Rs_sw, Rt_sw, SIMD_FMT_W, 2140 NOROUND, SIGNED); 2141 }}); 2142 0x1: subqh_w({{ 2143 Rd_uw = dspSubh(Rs_sw, Rt_sw, SIMD_FMT_W, 2144 NOROUND, SIGNED); 2145 }}); 2146 0x2: addqh_r_w({{ 2147 Rd_uw = dspAddh(Rs_sw, Rt_sw, SIMD_FMT_W, 2148 ROUND, SIGNED); 2149 }}); 2150 0x3: subqh_r_w({{ 2151 Rd_uw = dspSubh(Rs_sw, Rt_sw, SIMD_FMT_W, 2152 ROUND, SIGNED); 2153 }}); 2154 0x6: mulq_s_w({{ 2155 Rd_sw = dspMulq(Rs_sw, Rt_sw, SIMD_FMT_W, 2156 SATURATE, NOROUND, &dspctl); 2157 }}, IntMultOp); 2158 0x7: mulq_rs_w({{ 2159 Rd_sw = dspMulq(Rs_sw, Rt_sw, SIMD_FMT_W, 2160 SATURATE, ROUND, &dspctl); 2161 }}, IntMultOp); 2162 } 2163 } 2164 } 2165 } 2166 2167 //Table A-10 MIPS32 BSHFL Encoding of sa Field 2168 0x4: decode SA { 2169 format BasicOp { 2170 0x02: wsbh({{ 2171 Rd_uw = Rt_uw<23:16> << 24 | 2172 Rt_uw<31:24> << 16 | 2173 Rt_uw<7:0> << 8 | 2174 Rt_uw<15:8>; 2175 }}); 2176 0x10: seb({{ Rd_sw = Rt_sb; }}); 2177 0x18: seh({{ Rd_sw = Rt_sh; }}); 2178 } 2179 } 2180 2181 0x6: decode FUNCTION_LO { 2182 2183 //Table 5-10 MIPS32 DPAQ.W.PH Encoding of the op Field 2184 //(DSP ASE MANUAL) 2185 0x0: decode OP_HI { 2186 0x0: decode OP_LO { 2187 format DspHiLoOp { 2188 0x0: dpa_w_ph({{ 2189 dspac = dspDpa(dspac, Rs_sw, Rt_sw, ACDST, 2190 SIMD_FMT_PH, SIGNED, MODE_L); 2191 }}, IntMultOp); 2192 0x1: dps_w_ph({{ 2193 dspac = dspDps(dspac, Rs_sw, Rt_sw, ACDST, 2194 SIMD_FMT_PH, SIGNED, MODE_L); 2195 }}, IntMultOp); 2196 0x2: mulsa_w_ph({{ 2197 dspac = dspMulsa(dspac, Rs_sw, Rt_sw, 2198 ACDST, SIMD_FMT_PH ); 2199 }}, IntMultOp); 2200 0x3: dpau_h_qbl({{ 2201 dspac = dspDpa(dspac, Rs_sw, Rt_sw, ACDST, 2202 SIMD_FMT_QB, UNSIGNED, MODE_L); 2203 }}, IntMultOp); 2204 0x4: dpaq_s_w_ph({{ 2205 dspac = dspDpaq(dspac, Rs_sw, Rt_sw, 2206 ACDST, SIMD_FMT_PH, 2207 SIMD_FMT_W, NOSATURATE, 2208 MODE_L, &dspctl); 2209 }}, IntMultOp); 2210 0x5: dpsq_s_w_ph({{ 2211 dspac = dspDpsq(dspac, Rs_sw, Rt_sw, 2212 ACDST, SIMD_FMT_PH, 2213 SIMD_FMT_W, NOSATURATE, 2214 MODE_L, &dspctl); 2215 }}, IntMultOp); 2216 0x6: mulsaq_s_w_ph({{ 2217 dspac = dspMulsaq(dspac, Rs_sw, Rt_sw, 2218 ACDST, SIMD_FMT_PH, 2219 &dspctl); 2220 }}, IntMultOp); 2221 0x7: dpau_h_qbr({{ 2222 dspac = dspDpa(dspac, Rs_sw, Rt_sw, ACDST, 2223 SIMD_FMT_QB, UNSIGNED, MODE_R); 2224 }}, IntMultOp); 2225 } 2226 } 2227 0x1: decode OP_LO { 2228 format DspHiLoOp { 2229 0x0: dpax_w_ph({{ 2230 dspac = dspDpa(dspac, Rs_sw, Rt_sw, ACDST, 2231 SIMD_FMT_PH, SIGNED, MODE_X); 2232 }}, IntMultOp); 2233 0x1: dpsx_w_ph({{ 2234 dspac = dspDps(dspac, Rs_sw, Rt_sw, ACDST, 2235 SIMD_FMT_PH, SIGNED, MODE_X); 2236 }}, IntMultOp); 2237 0x3: dpsu_h_qbl({{ 2238 dspac = dspDps(dspac, Rs_sw, Rt_sw, ACDST, 2239 SIMD_FMT_QB, UNSIGNED, MODE_L); 2240 }}, IntMultOp); 2241 0x4: dpaq_sa_l_w({{ 2242 dspac = dspDpaq(dspac, Rs_sw, Rt_sw, 2243 ACDST, SIMD_FMT_W, 2244 SIMD_FMT_L, SATURATE, 2245 MODE_L, &dspctl); 2246 }}, IntMultOp); 2247 0x5: dpsq_sa_l_w({{ 2248 dspac = dspDpsq(dspac, Rs_sw, Rt_sw, 2249 ACDST, SIMD_FMT_W, 2250 SIMD_FMT_L, SATURATE, 2251 MODE_L, &dspctl); 2252 }}, IntMultOp); 2253 0x7: dpsu_h_qbr({{ 2254 dspac = dspDps(dspac, Rs_sw, Rt_sw, ACDST, 2255 SIMD_FMT_QB, UNSIGNED, MODE_R); 2256 }}, IntMultOp); 2257 } 2258 } 2259 0x2: decode OP_LO { 2260 format DspHiLoOp { 2261 0x0: maq_sa_w_phl({{ 2262 dspac = dspMaq(dspac, Rs_uw, Rt_uw, 2263 ACDST, SIMD_FMT_PH, 2264 MODE_L, SATURATE, &dspctl); 2265 }}, IntMultOp); 2266 0x2: maq_sa_w_phr({{ 2267 dspac = dspMaq(dspac, Rs_uw, Rt_uw, 2268 ACDST, SIMD_FMT_PH, 2269 MODE_R, SATURATE, &dspctl); 2270 }}, IntMultOp); 2271 0x4: maq_s_w_phl({{ 2272 dspac = dspMaq(dspac, Rs_uw, Rt_uw, 2273 ACDST, SIMD_FMT_PH, 2274 MODE_L, NOSATURATE, &dspctl); 2275 }}, IntMultOp); 2276 0x6: maq_s_w_phr({{ 2277 dspac = dspMaq(dspac, Rs_uw, Rt_uw, 2278 ACDST, SIMD_FMT_PH, 2279 MODE_R, NOSATURATE, &dspctl); 2280 }}, IntMultOp); 2281 } 2282 } 2283 0x3: decode OP_LO { 2284 format DspHiLoOp { 2285 0x0: dpaqx_s_w_ph({{ 2286 dspac = dspDpaq(dspac, Rs_sw, Rt_sw, 2287 ACDST, SIMD_FMT_PH, 2288 SIMD_FMT_W, NOSATURATE, 2289 MODE_X, &dspctl); 2290 }}, IntMultOp); 2291 0x1: dpsqx_s_w_ph({{ 2292 dspac = dspDpsq(dspac, Rs_sw, Rt_sw, 2293 ACDST, SIMD_FMT_PH, 2294 SIMD_FMT_W, NOSATURATE, 2295 MODE_X, &dspctl); 2296 }}, IntMultOp); 2297 0x2: dpaqx_sa_w_ph({{ 2298 dspac = dspDpaq(dspac, Rs_sw, Rt_sw, 2299 ACDST, SIMD_FMT_PH, 2300 SIMD_FMT_W, SATURATE, 2301 MODE_X, &dspctl); 2302 }}, IntMultOp); 2303 0x3: dpsqx_sa_w_ph({{ 2304 dspac = dspDpsq(dspac, Rs_sw, Rt_sw, 2305 ACDST, SIMD_FMT_PH, 2306 SIMD_FMT_W, SATURATE, 2307 MODE_X, &dspctl); 2308 }}, IntMultOp); 2309 } 2310 } 2311 } 2312 2313 //Table 3.3 MIPS32 APPEND Encoding of the op Field 2314 0x1: decode OP_HI { 2315 0x0: decode OP_LO { 2316 format IntOp { 2317 0x0: append({{ 2318 Rt_uw = (Rt_uw << RD) | bits(Rs_uw, RD - 1, 0); 2319 }}); 2320 0x1: prepend({{ 2321 Rt_uw = (Rt_uw >> RD) | 2322 (bits(Rs_uw, RD - 1, 0) << (32 - RD)); 2323 }}); 2324 } 2325 } 2326 0x2: decode OP_LO { 2327 format IntOp { 2328 0x0: balign({{ 2329 Rt_uw = (Rt_uw << (8 * BP)) | 2330 (Rs_uw >> (8 * (4 - BP))); 2331 }}); 2332 } 2333 } 2334 } 2335 2336 } 2337 0x7: decode FUNCTION_LO { 2338 2339 //Table 5-11 MIPS32 EXTR.W Encoding of the op Field 2340 //(DSP ASE MANUAL) 2341 0x0: decode OP_HI { 2342 0x0: decode OP_LO { 2343 format DspHiLoOp { 2344 0x0: extr_w({{ 2345 Rt_uw = dspExtr(dspac, SIMD_FMT_W, RS, 2346 NOROUND, NOSATURATE, &dspctl); 2347 }}); 2348 0x1: extrv_w({{ 2349 Rt_uw = dspExtr(dspac, SIMD_FMT_W, Rs_uw, 2350 NOROUND, NOSATURATE, &dspctl); 2351 }}); 2352 0x2: extp({{ 2353 Rt_uw = dspExtp(dspac, RS, &dspctl); 2354 }}); 2355 0x3: extpv({{ 2356 Rt_uw = dspExtp(dspac, Rs_uw, &dspctl); 2357 }}); 2358 0x4: extr_r_w({{ 2359 Rt_uw = dspExtr(dspac, SIMD_FMT_W, RS, 2360 ROUND, NOSATURATE, &dspctl); 2361 }}); 2362 0x5: extrv_r_w({{ 2363 Rt_uw = dspExtr(dspac, SIMD_FMT_W, Rs_uw, 2364 ROUND, NOSATURATE, &dspctl); 2365 }}); 2366 0x6: extr_rs_w({{ 2367 Rt_uw = dspExtr(dspac, SIMD_FMT_W, RS, 2368 ROUND, SATURATE, &dspctl); 2369 }}); 2370 0x7: extrv_rs_w({{ 2371 Rt_uw = dspExtr(dspac, SIMD_FMT_W, Rs_uw, 2372 ROUND, SATURATE, &dspctl); 2373 }}); 2374 } 2375 } 2376 0x1: decode OP_LO { 2377 format DspHiLoOp { 2378 0x2: extpdp({{ 2379 Rt_uw = dspExtpd(dspac, RS, &dspctl); 2380 }}); 2381 0x3: extpdpv({{ 2382 Rt_uw = dspExtpd(dspac, Rs_uw, &dspctl); 2383 }}); 2384 0x6: extr_s_h({{ 2385 Rt_uw = dspExtr(dspac, SIMD_FMT_PH, RS, 2386 NOROUND, SATURATE, &dspctl); 2387 }}); 2388 0x7: extrv_s_h({{ 2389 Rt_uw = dspExtr(dspac, SIMD_FMT_PH, Rs_uw, 2390 NOROUND, SATURATE, &dspctl); 2391 }}); 2392 } 2393 } 2394 0x2: decode OP_LO { 2395 format DspIntOp { 2396 0x2: rddsp({{ 2397 Rd_uw = readDSPControl(&dspctl, RDDSPMASK); 2398 }}); 2399 0x3: wrdsp({{ 2400 writeDSPControl(&dspctl, Rs_uw, WRDSPMASK); 2401 }}); 2402 } 2403 } 2404 0x3: decode OP_LO { 2405 format DspHiLoOp { 2406 0x2: shilo({{ 2407 if (sext<6>(HILOSA) < 0) { 2408 dspac = (uint64_t)dspac << 2409 -sext<6>(HILOSA); 2410 } else { 2411 dspac = (uint64_t)dspac >> 2412 sext<6>(HILOSA); 2413 } 2414 }}); 2415 0x3: shilov({{ 2416 if (sext<6>(Rs_sw<5:0>) < 0) { 2417 dspac = (uint64_t)dspac << 2418 -sext<6>(Rs_sw<5:0>); 2419 } else { 2420 dspac = (uint64_t)dspac >> 2421 sext<6>(Rs_sw<5:0>); 2422 } 2423 }}); 2424 0x7: mthlip({{ 2425 dspac = dspac << 32; 2426 dspac |= Rs_uw; 2427 dspctl = insertBits(dspctl, 5, 0, 2428 dspctl<5:0> + 32); 2429 }}); 2430 } 2431 } 2432 } 2433 0x3: decode OP default FailUnimpl::rdhwr() { 2434 0x0: decode FULL_SYSTEM { 2435 0: decode RD { 2436 29: BasicOp::rdhwr_se({{ Rt = TpValue; }}); 2437 } 2438 } 2439 } 2440 } 2441 } 2442 } 2443 2444 0x4: decode OPCODE_LO { 2445 format LoadMemory { 2446 0x0: lb({{ Rt_sw = Mem_sb; }}); 2447 0x1: lh({{ Rt_sw = Mem_sh; }}); 2448 0x3: lw({{ Rt_sw = Mem_sw; }}); 2449 0x4: lbu({{ Rt_uw = Mem_ub;}}); 2450 0x5: lhu({{ Rt_uw = Mem_uh; }}); 2451 } 2452 2453 format LoadUnalignedMemory { 2454 0x2: lwl({{ 2455 uint32_t mem_shift = 24 - (8 * byte_offset); 2456 Rt_uw = mem_word << mem_shift | (Rt_uw & mask(mem_shift)); 2457 }}); 2458 0x6: lwr({{ 2459 uint32_t mem_shift = 8 * byte_offset; 2460 Rt_uw = (Rt_uw & (mask(mem_shift) << (32 - mem_shift))) | 2461 (mem_word >> mem_shift); 2462 }}); 2463 } 2464 } 2465 2466 0x5: decode OPCODE_LO { 2467 format StoreMemory { 2468 0x0: sb({{ Mem_ub = Rt<7:0>; }}); 2469 0x1: sh({{ Mem_uh = Rt<15:0>; }}); 2470 0x3: sw({{ Mem_uw = Rt<31:0>; }}); 2471 } 2472 2473 format StoreUnalignedMemory { 2474 0x2: swl({{ 2475 uint32_t reg_shift = 24 - (8 * byte_offset); 2476 uint32_t mem_shift = 32 - reg_shift; 2477 mem_word = (mem_word & (mask(reg_shift) << mem_shift)) | 2478 (Rt_uw >> reg_shift); 2479 }}); 2480 0x6: swr({{ 2481 uint32_t reg_shift = 8 * byte_offset; 2482 mem_word = Rt_uw << reg_shift | 2483 (mem_word & (mask(reg_shift))); 2484 }}); 2485 } 2486 format CP0Control { 2487 0x7: cache({{ 2488 //Addr CacheEA = Rs_uw + OFFSET; 2489 //fault = xc->CacheOp((uint8_t)CACHE_OP,(Addr) CacheEA); 2490 }}); 2491 } 2492 } 2493 2494 0x6: decode OPCODE_LO { 2495 format LoadMemory { 2496 0x0: ll({{ Rt_uw = Mem_uw; }}, mem_flags=LLSC); 2497 0x1: lwc1({{ Ft_uw = Mem_uw; }}); 2498 0x5: ldc1({{ Ft_ud = Mem_ud; }}); 2499 } 2500 0x2: CP2Unimpl::lwc2(); 2501 0x6: CP2Unimpl::ldc2(); 2502 0x3: Prefetch::pref(); 2503 } 2504 2505 2506 0x7: decode OPCODE_LO { 2507 0x0: StoreCond::sc({{ Mem_uw = Rt_uw; }}, 2508 {{ uint64_t tmp = write_result; 2509 Rt_uw = (tmp == 0 || tmp == 1) ? tmp : Rt_uw; 2510 }}, mem_flags=LLSC, 2511 inst_flags = IsStoreConditional); 2512 format StoreMemory { 2513 0x1: swc1({{ Mem_uw = Ft_uw; }}); 2514 0x5: sdc1({{ Mem_ud = Ft_ud; }}); 2515 } 2516 0x2: CP2Unimpl::swc2(); 2517 0x6: CP2Unimpl::sdc2(); 2518 } 2519} 2520 2521 2522