iew_impl.hh revision 2873
1/* 2 * Copyright (c) 2004-2006 The Regents of The University of Michigan 3 * All rights reserved. 4 * 5 * Redistribution and use in source and binary forms, with or without 6 * modification, are permitted provided that the following conditions are 7 * met: redistributions of source code must retain the above copyright 8 * notice, this list of conditions and the following disclaimer; 9 * redistributions in binary form must reproduce the above copyright 10 * notice, this list of conditions and the following disclaimer in the 11 * documentation and/or other materials provided with the distribution; 12 * neither the name of the copyright holders nor the names of its 13 * contributors may be used to endorse or promote products derived from 14 * this software without specific prior written permission. 15 * 16 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 17 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 18 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR 19 * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT 20 * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 21 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT 22 * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 23 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 24 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 25 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE 26 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 27 * 28 * Authors: Kevin Lim 29 */ 30 31// @todo: Fix the instantaneous communication among all the stages within 32// iew. There's a clear delay between issue and execute, yet backwards 33// communication happens simultaneously. 34 35#include <queue> 36 37#include "base/timebuf.hh" 38#include "cpu/o3/fu_pool.hh" 39#include "cpu/o3/iew.hh" 40 41using namespace std; 42 43template<class Impl> 44DefaultIEW<Impl>::DefaultIEW(Params *params) 45 : issueToExecQueue(params->backComSize, params->forwardComSize), 46 instQueue(params), 47 ldstQueue(params), 48 fuPool(params->fuPool), 49 commitToIEWDelay(params->commitToIEWDelay), 50 renameToIEWDelay(params->renameToIEWDelay), 51 issueToExecuteDelay(params->issueToExecuteDelay), 52 dispatchWidth(params->dispatchWidth), 53 issueWidth(params->issueWidth), 54 wbOutstanding(0), 55 wbWidth(params->wbWidth), 56 numThreads(params->numberOfThreads), 57 switchedOut(false) 58{ 59 _status = Active; 60 exeStatus = Running; 61 wbStatus = Idle; 62 63 // Setup wire to read instructions coming from issue. 64 fromIssue = issueToExecQueue.getWire(-issueToExecuteDelay); 65 66 // Instruction queue needs the queue between issue and execute. 67 instQueue.setIssueToExecuteQueue(&issueToExecQueue); 68 69 instQueue.setIEW(this); 70 ldstQueue.setIEW(this); 71 72 for (int i=0; i < numThreads; i++) { 73 dispatchStatus[i] = Running; 74 stalls[i].commit = false; 75 fetchRedirect[i] = false; 76 } 77 78 wbMax = wbWidth * params->wbDepth; 79 80 updateLSQNextCycle = false; 81 82 ableToIssue = true; 83 84 skidBufferMax = (3 * (renameToIEWDelay * params->renameWidth)) + issueWidth; 85} 86 87template <class Impl> 88std::string 89DefaultIEW<Impl>::name() const 90{ 91 return cpu->name() + ".iew"; 92} 93 94template <class Impl> 95void 96DefaultIEW<Impl>::regStats() 97{ 98 using namespace Stats; 99 100 instQueue.regStats(); 101 ldstQueue.regStats(); 102 103 iewIdleCycles 104 .name(name() + ".iewIdleCycles") 105 .desc("Number of cycles IEW is idle"); 106 107 iewSquashCycles 108 .name(name() + ".iewSquashCycles") 109 .desc("Number of cycles IEW is squashing"); 110 111 iewBlockCycles 112 .name(name() + ".iewBlockCycles") 113 .desc("Number of cycles IEW is blocking"); 114 115 iewUnblockCycles 116 .name(name() + ".iewUnblockCycles") 117 .desc("Number of cycles IEW is unblocking"); 118 119 iewDispatchedInsts 120 .name(name() + ".iewDispatchedInsts") 121 .desc("Number of instructions dispatched to IQ"); 122 123 iewDispSquashedInsts 124 .name(name() + ".iewDispSquashedInsts") 125 .desc("Number of squashed instructions skipped by dispatch"); 126 127 iewDispLoadInsts 128 .name(name() + ".iewDispLoadInsts") 129 .desc("Number of dispatched load instructions"); 130 131 iewDispStoreInsts 132 .name(name() + ".iewDispStoreInsts") 133 .desc("Number of dispatched store instructions"); 134 135 iewDispNonSpecInsts 136 .name(name() + ".iewDispNonSpecInsts") 137 .desc("Number of dispatched non-speculative instructions"); 138 139 iewIQFullEvents 140 .name(name() + ".iewIQFullEvents") 141 .desc("Number of times the IQ has become full, causing a stall"); 142 143 iewLSQFullEvents 144 .name(name() + ".iewLSQFullEvents") 145 .desc("Number of times the LSQ has become full, causing a stall"); 146 147 memOrderViolationEvents 148 .name(name() + ".memOrderViolationEvents") 149 .desc("Number of memory order violations"); 150 151 predictedTakenIncorrect 152 .name(name() + ".predictedTakenIncorrect") 153 .desc("Number of branches that were predicted taken incorrectly"); 154 155 predictedNotTakenIncorrect 156 .name(name() + ".predictedNotTakenIncorrect") 157 .desc("Number of branches that were predicted not taken incorrectly"); 158 159 branchMispredicts 160 .name(name() + ".branchMispredicts") 161 .desc("Number of branch mispredicts detected at execute"); 162 163 branchMispredicts = predictedTakenIncorrect + predictedNotTakenIncorrect; 164 165 iewExecutedInsts 166 .name(name() + ".EXEC:insts") 167 .desc("Number of executed instructions"); 168 169 iewExecLoadInsts 170 .init(cpu->number_of_threads) 171 .name(name() + ".EXEC:loads") 172 .desc("Number of load instructions executed") 173 .flags(total); 174 175 iewExecSquashedInsts 176 .name(name() + ".EXEC:squashedInsts") 177 .desc("Number of squashed instructions skipped in execute"); 178 179 iewExecutedSwp 180 .init(cpu->number_of_threads) 181 .name(name() + ".EXEC:swp") 182 .desc("number of swp insts executed") 183 .flags(total); 184 185 iewExecutedNop 186 .init(cpu->number_of_threads) 187 .name(name() + ".EXEC:nop") 188 .desc("number of nop insts executed") 189 .flags(total); 190 191 iewExecutedRefs 192 .init(cpu->number_of_threads) 193 .name(name() + ".EXEC:refs") 194 .desc("number of memory reference insts executed") 195 .flags(total); 196 197 iewExecutedBranches 198 .init(cpu->number_of_threads) 199 .name(name() + ".EXEC:branches") 200 .desc("Number of branches executed") 201 .flags(total); 202 203 iewExecStoreInsts 204 .name(name() + ".EXEC:stores") 205 .desc("Number of stores executed") 206 .flags(total); 207 iewExecStoreInsts = iewExecutedRefs - iewExecLoadInsts; 208 209 iewExecRate 210 .name(name() + ".EXEC:rate") 211 .desc("Inst execution rate") 212 .flags(total); 213 214 iewExecRate = iewExecutedInsts / cpu->numCycles; 215 216 iewInstsToCommit 217 .init(cpu->number_of_threads) 218 .name(name() + ".WB:sent") 219 .desc("cumulative count of insts sent to commit") 220 .flags(total); 221 222 writebackCount 223 .init(cpu->number_of_threads) 224 .name(name() + ".WB:count") 225 .desc("cumulative count of insts written-back") 226 .flags(total); 227 228 producerInst 229 .init(cpu->number_of_threads) 230 .name(name() + ".WB:producers") 231 .desc("num instructions producing a value") 232 .flags(total); 233 234 consumerInst 235 .init(cpu->number_of_threads) 236 .name(name() + ".WB:consumers") 237 .desc("num instructions consuming a value") 238 .flags(total); 239 240 wbPenalized 241 .init(cpu->number_of_threads) 242 .name(name() + ".WB:penalized") 243 .desc("number of instrctions required to write to 'other' IQ") 244 .flags(total); 245 246 wbPenalizedRate 247 .name(name() + ".WB:penalized_rate") 248 .desc ("fraction of instructions written-back that wrote to 'other' IQ") 249 .flags(total); 250 251 wbPenalizedRate = wbPenalized / writebackCount; 252 253 wbFanout 254 .name(name() + ".WB:fanout") 255 .desc("average fanout of values written-back") 256 .flags(total); 257 258 wbFanout = producerInst / consumerInst; 259 260 wbRate 261 .name(name() + ".WB:rate") 262 .desc("insts written-back per cycle") 263 .flags(total); 264 wbRate = writebackCount / cpu->numCycles; 265} 266 267template<class Impl> 268void 269DefaultIEW<Impl>::initStage() 270{ 271 for (int tid=0; tid < numThreads; tid++) { 272 toRename->iewInfo[tid].usedIQ = true; 273 toRename->iewInfo[tid].freeIQEntries = 274 instQueue.numFreeEntries(tid); 275 276 toRename->iewInfo[tid].usedLSQ = true; 277 toRename->iewInfo[tid].freeLSQEntries = 278 ldstQueue.numFreeEntries(tid); 279 } 280} 281 282template<class Impl> 283void 284DefaultIEW<Impl>::setCPU(O3CPU *cpu_ptr) 285{ 286 DPRINTF(IEW, "Setting CPU pointer.\n"); 287 cpu = cpu_ptr; 288 289 instQueue.setCPU(cpu_ptr); 290 ldstQueue.setCPU(cpu_ptr); 291 292 cpu->activateStage(O3CPU::IEWIdx); 293} 294 295template<class Impl> 296void 297DefaultIEW<Impl>::setTimeBuffer(TimeBuffer<TimeStruct> *tb_ptr) 298{ 299 DPRINTF(IEW, "Setting time buffer pointer.\n"); 300 timeBuffer = tb_ptr; 301 302 // Setup wire to read information from time buffer, from commit. 303 fromCommit = timeBuffer->getWire(-commitToIEWDelay); 304 305 // Setup wire to write information back to previous stages. 306 toRename = timeBuffer->getWire(0); 307 308 toFetch = timeBuffer->getWire(0); 309 310 // Instruction queue also needs main time buffer. 311 instQueue.setTimeBuffer(tb_ptr); 312} 313 314template<class Impl> 315void 316DefaultIEW<Impl>::setRenameQueue(TimeBuffer<RenameStruct> *rq_ptr) 317{ 318 DPRINTF(IEW, "Setting rename queue pointer.\n"); 319 renameQueue = rq_ptr; 320 321 // Setup wire to read information from rename queue. 322 fromRename = renameQueue->getWire(-renameToIEWDelay); 323} 324 325template<class Impl> 326void 327DefaultIEW<Impl>::setIEWQueue(TimeBuffer<IEWStruct> *iq_ptr) 328{ 329 DPRINTF(IEW, "Setting IEW queue pointer.\n"); 330 iewQueue = iq_ptr; 331 332 // Setup wire to write instructions to commit. 333 toCommit = iewQueue->getWire(0); 334} 335 336template<class Impl> 337void 338DefaultIEW<Impl>::setActiveThreads(list<unsigned> *at_ptr) 339{ 340 DPRINTF(IEW, "Setting active threads list pointer.\n"); 341 activeThreads = at_ptr; 342 343 ldstQueue.setActiveThreads(at_ptr); 344 instQueue.setActiveThreads(at_ptr); 345} 346 347template<class Impl> 348void 349DefaultIEW<Impl>::setScoreboard(Scoreboard *sb_ptr) 350{ 351 DPRINTF(IEW, "Setting scoreboard pointer.\n"); 352 scoreboard = sb_ptr; 353} 354 355template <class Impl> 356bool 357DefaultIEW<Impl>::drain() 358{ 359 // IEW is ready to drain at any time. 360 cpu->signalDrained(); 361 return true; 362} 363 364template <class Impl> 365void 366DefaultIEW<Impl>::resume() 367{ 368} 369 370template <class Impl> 371void 372DefaultIEW<Impl>::switchOut() 373{ 374 // Clear any state. 375 switchedOut = true; 376 377 instQueue.switchOut(); 378 ldstQueue.switchOut(); 379 fuPool->switchOut(); 380 381 for (int i = 0; i < numThreads; i++) { 382 while (!insts[i].empty()) 383 insts[i].pop(); 384 while (!skidBuffer[i].empty()) 385 skidBuffer[i].pop(); 386 } 387} 388 389template <class Impl> 390void 391DefaultIEW<Impl>::takeOverFrom() 392{ 393 // Reset all state. 394 _status = Active; 395 exeStatus = Running; 396 wbStatus = Idle; 397 switchedOut = false; 398 399 instQueue.takeOverFrom(); 400 ldstQueue.takeOverFrom(); 401 fuPool->takeOverFrom(); 402 403 initStage(); 404 cpu->activityThisCycle(); 405 406 for (int i=0; i < numThreads; i++) { 407 dispatchStatus[i] = Running; 408 stalls[i].commit = false; 409 fetchRedirect[i] = false; 410 } 411 412 updateLSQNextCycle = false; 413 414 // @todo: Fix hardcoded number 415 for (int i = 0; i < issueToExecQueue.getSize(); ++i) { 416 issueToExecQueue.advance(); 417 } 418} 419 420template<class Impl> 421void 422DefaultIEW<Impl>::squash(unsigned tid) 423{ 424 DPRINTF(IEW, "[tid:%i]: Squashing all instructions.\n", 425 tid); 426 427 // Tell the IQ to start squashing. 428 instQueue.squash(tid); 429 430 // Tell the LDSTQ to start squashing. 431 ldstQueue.squash(fromCommit->commitInfo[tid].doneSeqNum, tid); 432 433 updatedQueues = true; 434 435 // Clear the skid buffer in case it has any data in it. 436 while (!skidBuffer[tid].empty()) { 437 438 if (skidBuffer[tid].front()->isLoad() || 439 skidBuffer[tid].front()->isStore() ) { 440 toRename->iewInfo[tid].dispatchedToLSQ++; 441 } 442 443 toRename->iewInfo[tid].dispatched++; 444 445 skidBuffer[tid].pop(); 446 } 447 448 emptyRenameInsts(tid); 449} 450 451template<class Impl> 452void 453DefaultIEW<Impl>::squashDueToBranch(DynInstPtr &inst, unsigned tid) 454{ 455 DPRINTF(IEW, "[tid:%i]: Squashing from a specific instruction, PC: %#x " 456 "[sn:%i].\n", tid, inst->readPC(), inst->seqNum); 457 458 toCommit->squash[tid] = true; 459 toCommit->squashedSeqNum[tid] = inst->seqNum; 460 toCommit->mispredPC[tid] = inst->readPC(); 461 toCommit->nextPC[tid] = inst->readNextPC(); 462 toCommit->branchMispredict[tid] = true; 463 toCommit->branchTaken[tid] = inst->readNextPC() != 464 (inst->readPC() + sizeof(TheISA::MachInst)); 465 466 toCommit->includeSquashInst[tid] = false; 467 468 wroteToTimeBuffer = true; 469} 470 471template<class Impl> 472void 473DefaultIEW<Impl>::squashDueToMemOrder(DynInstPtr &inst, unsigned tid) 474{ 475 DPRINTF(IEW, "[tid:%i]: Squashing from a specific instruction, " 476 "PC: %#x [sn:%i].\n", tid, inst->readPC(), inst->seqNum); 477 478 toCommit->squash[tid] = true; 479 toCommit->squashedSeqNum[tid] = inst->seqNum; 480 toCommit->nextPC[tid] = inst->readNextPC(); 481 482 toCommit->includeSquashInst[tid] = false; 483 484 wroteToTimeBuffer = true; 485} 486 487template<class Impl> 488void 489DefaultIEW<Impl>::squashDueToMemBlocked(DynInstPtr &inst, unsigned tid) 490{ 491 DPRINTF(IEW, "[tid:%i]: Memory blocked, squashing load and younger insts, " 492 "PC: %#x [sn:%i].\n", tid, inst->readPC(), inst->seqNum); 493 494 toCommit->squash[tid] = true; 495 toCommit->squashedSeqNum[tid] = inst->seqNum; 496 toCommit->nextPC[tid] = inst->readPC(); 497 498 // Must include the broadcasted SN in the squash. 499 toCommit->includeSquashInst[tid] = true; 500 501 ldstQueue.setLoadBlockedHandled(tid); 502 503 wroteToTimeBuffer = true; 504} 505 506template<class Impl> 507void 508DefaultIEW<Impl>::block(unsigned tid) 509{ 510 DPRINTF(IEW, "[tid:%u]: Blocking.\n", tid); 511 512 if (dispatchStatus[tid] != Blocked && 513 dispatchStatus[tid] != Unblocking) { 514 toRename->iewBlock[tid] = true; 515 wroteToTimeBuffer = true; 516 } 517 518 // Add the current inputs to the skid buffer so they can be 519 // reprocessed when this stage unblocks. 520 skidInsert(tid); 521 522 dispatchStatus[tid] = Blocked; 523} 524 525template<class Impl> 526void 527DefaultIEW<Impl>::unblock(unsigned tid) 528{ 529 DPRINTF(IEW, "[tid:%i]: Reading instructions out of the skid " 530 "buffer %u.\n",tid, tid); 531 532 // If the skid bufffer is empty, signal back to previous stages to unblock. 533 // Also switch status to running. 534 if (skidBuffer[tid].empty()) { 535 toRename->iewUnblock[tid] = true; 536 wroteToTimeBuffer = true; 537 DPRINTF(IEW, "[tid:%i]: Done unblocking.\n",tid); 538 dispatchStatus[tid] = Running; 539 } 540} 541 542template<class Impl> 543void 544DefaultIEW<Impl>::wakeDependents(DynInstPtr &inst) 545{ 546 instQueue.wakeDependents(inst); 547} 548 549template<class Impl> 550void 551DefaultIEW<Impl>::rescheduleMemInst(DynInstPtr &inst) 552{ 553 instQueue.rescheduleMemInst(inst); 554} 555 556template<class Impl> 557void 558DefaultIEW<Impl>::replayMemInst(DynInstPtr &inst) 559{ 560 instQueue.replayMemInst(inst); 561} 562 563template<class Impl> 564void 565DefaultIEW<Impl>::instToCommit(DynInstPtr &inst) 566{ 567 // First check the time slot that this instruction will write 568 // to. If there are free write ports at the time, then go ahead 569 // and write the instruction to that time. If there are not, 570 // keep looking back to see where's the first time there's a 571 // free slot. 572 while ((*iewQueue)[wbCycle].insts[wbNumInst]) { 573 ++wbNumInst; 574 if (wbNumInst == wbWidth) { 575 ++wbCycle; 576 wbNumInst = 0; 577 } 578 579 assert((wbCycle * wbWidth + wbNumInst) < wbMax); 580 } 581 582 // Add finished instruction to queue to commit. 583 (*iewQueue)[wbCycle].insts[wbNumInst] = inst; 584 (*iewQueue)[wbCycle].size++; 585} 586 587template <class Impl> 588unsigned 589DefaultIEW<Impl>::validInstsFromRename() 590{ 591 unsigned inst_count = 0; 592 593 for (int i=0; i<fromRename->size; i++) { 594 if (!fromRename->insts[i]->isSquashed()) 595 inst_count++; 596 } 597 598 return inst_count; 599} 600 601template<class Impl> 602void 603DefaultIEW<Impl>::skidInsert(unsigned tid) 604{ 605 DynInstPtr inst = NULL; 606 607 while (!insts[tid].empty()) { 608 inst = insts[tid].front(); 609 610 insts[tid].pop(); 611 612 DPRINTF(Decode,"[tid:%i]: Inserting [sn:%lli] PC:%#x into " 613 "dispatch skidBuffer %i\n",tid, inst->seqNum, 614 inst->readPC(),tid); 615 616 skidBuffer[tid].push(inst); 617 } 618 619 assert(skidBuffer[tid].size() <= skidBufferMax && 620 "Skidbuffer Exceeded Max Size"); 621} 622 623template<class Impl> 624int 625DefaultIEW<Impl>::skidCount() 626{ 627 int max=0; 628 629 list<unsigned>::iterator threads = (*activeThreads).begin(); 630 631 while (threads != (*activeThreads).end()) { 632 unsigned thread_count = skidBuffer[*threads++].size(); 633 if (max < thread_count) 634 max = thread_count; 635 } 636 637 return max; 638} 639 640template<class Impl> 641bool 642DefaultIEW<Impl>::skidsEmpty() 643{ 644 list<unsigned>::iterator threads = (*activeThreads).begin(); 645 646 while (threads != (*activeThreads).end()) { 647 if (!skidBuffer[*threads++].empty()) 648 return false; 649 } 650 651 return true; 652} 653 654template <class Impl> 655void 656DefaultIEW<Impl>::updateStatus() 657{ 658 bool any_unblocking = false; 659 660 list<unsigned>::iterator threads = (*activeThreads).begin(); 661 662 threads = (*activeThreads).begin(); 663 664 while (threads != (*activeThreads).end()) { 665 unsigned tid = *threads++; 666 667 if (dispatchStatus[tid] == Unblocking) { 668 any_unblocking = true; 669 break; 670 } 671 } 672 673 // If there are no ready instructions waiting to be scheduled by the IQ, 674 // and there's no stores waiting to write back, and dispatch is not 675 // unblocking, then there is no internal activity for the IEW stage. 676 if (_status == Active && !instQueue.hasReadyInsts() && 677 !ldstQueue.willWB() && !any_unblocking) { 678 DPRINTF(IEW, "IEW switching to idle\n"); 679 680 deactivateStage(); 681 682 _status = Inactive; 683 } else if (_status == Inactive && (instQueue.hasReadyInsts() || 684 ldstQueue.willWB() || 685 any_unblocking)) { 686 // Otherwise there is internal activity. Set to active. 687 DPRINTF(IEW, "IEW switching to active\n"); 688 689 activateStage(); 690 691 _status = Active; 692 } 693} 694 695template <class Impl> 696void 697DefaultIEW<Impl>::resetEntries() 698{ 699 instQueue.resetEntries(); 700 ldstQueue.resetEntries(); 701} 702 703template <class Impl> 704void 705DefaultIEW<Impl>::readStallSignals(unsigned tid) 706{ 707 if (fromCommit->commitBlock[tid]) { 708 stalls[tid].commit = true; 709 } 710 711 if (fromCommit->commitUnblock[tid]) { 712 assert(stalls[tid].commit); 713 stalls[tid].commit = false; 714 } 715} 716 717template <class Impl> 718bool 719DefaultIEW<Impl>::checkStall(unsigned tid) 720{ 721 bool ret_val(false); 722 723 if (stalls[tid].commit) { 724 DPRINTF(IEW,"[tid:%i]: Stall from Commit stage detected.\n",tid); 725 ret_val = true; 726 } else if (instQueue.isFull(tid)) { 727 DPRINTF(IEW,"[tid:%i]: Stall: IQ is full.\n",tid); 728 ret_val = true; 729 } else if (ldstQueue.isFull(tid)) { 730 DPRINTF(IEW,"[tid:%i]: Stall: LSQ is full\n",tid); 731 732 if (ldstQueue.numLoads(tid) > 0 ) { 733 734 DPRINTF(IEW,"[tid:%i]: LSQ oldest load: [sn:%i] \n", 735 tid,ldstQueue.getLoadHeadSeqNum(tid)); 736 } 737 738 if (ldstQueue.numStores(tid) > 0) { 739 740 DPRINTF(IEW,"[tid:%i]: LSQ oldest store: [sn:%i] \n", 741 tid,ldstQueue.getStoreHeadSeqNum(tid)); 742 } 743 744 ret_val = true; 745 } else if (ldstQueue.isStalled(tid)) { 746 DPRINTF(IEW,"[tid:%i]: Stall: LSQ stall detected.\n",tid); 747 ret_val = true; 748 } 749 750 return ret_val; 751} 752 753template <class Impl> 754void 755DefaultIEW<Impl>::checkSignalsAndUpdate(unsigned tid) 756{ 757 // Check if there's a squash signal, squash if there is 758 // Check stall signals, block if there is. 759 // If status was Blocked 760 // if so then go to unblocking 761 // If status was Squashing 762 // check if squashing is not high. Switch to running this cycle. 763 764 readStallSignals(tid); 765 766 if (fromCommit->commitInfo[tid].squash) { 767 squash(tid); 768 769 if (dispatchStatus[tid] == Blocked || 770 dispatchStatus[tid] == Unblocking) { 771 toRename->iewUnblock[tid] = true; 772 wroteToTimeBuffer = true; 773 } 774 775 dispatchStatus[tid] = Squashing; 776 777 fetchRedirect[tid] = false; 778 return; 779 } 780 781 if (fromCommit->commitInfo[tid].robSquashing) { 782 DPRINTF(IEW, "[tid:%i]: ROB is still squashing.\n", tid); 783 784 dispatchStatus[tid] = Squashing; 785 786 emptyRenameInsts(tid); 787 wroteToTimeBuffer = true; 788 return; 789 } 790 791 if (checkStall(tid)) { 792 block(tid); 793 dispatchStatus[tid] = Blocked; 794 return; 795 } 796 797 if (dispatchStatus[tid] == Blocked) { 798 // Status from previous cycle was blocked, but there are no more stall 799 // conditions. Switch over to unblocking. 800 DPRINTF(IEW, "[tid:%i]: Done blocking, switching to unblocking.\n", 801 tid); 802 803 dispatchStatus[tid] = Unblocking; 804 805 unblock(tid); 806 807 return; 808 } 809 810 if (dispatchStatus[tid] == Squashing) { 811 // Switch status to running if rename isn't being told to block or 812 // squash this cycle. 813 DPRINTF(IEW, "[tid:%i]: Done squashing, switching to running.\n", 814 tid); 815 816 dispatchStatus[tid] = Running; 817 818 return; 819 } 820} 821 822template <class Impl> 823void 824DefaultIEW<Impl>::sortInsts() 825{ 826 int insts_from_rename = fromRename->size; 827#ifdef DEBUG 828 for (int i = 0; i < numThreads; i++) 829 assert(insts[i].empty()); 830#endif 831 for (int i = 0; i < insts_from_rename; ++i) { 832 insts[fromRename->insts[i]->threadNumber].push(fromRename->insts[i]); 833 } 834} 835 836template <class Impl> 837void 838DefaultIEW<Impl>::emptyRenameInsts(unsigned tid) 839{ 840 while (!insts[tid].empty()) { 841 if (insts[tid].front()->isLoad() || 842 insts[tid].front()->isStore() ) { 843 toRename->iewInfo[tid].dispatchedToLSQ++; 844 } 845 846 toRename->iewInfo[tid].dispatched++; 847 848 insts[tid].pop(); 849 } 850} 851 852template <class Impl> 853void 854DefaultIEW<Impl>::wakeCPU() 855{ 856 cpu->wakeCPU(); 857} 858 859template <class Impl> 860void 861DefaultIEW<Impl>::activityThisCycle() 862{ 863 DPRINTF(Activity, "Activity this cycle.\n"); 864 cpu->activityThisCycle(); 865} 866 867template <class Impl> 868inline void 869DefaultIEW<Impl>::activateStage() 870{ 871 DPRINTF(Activity, "Activating stage.\n"); 872 cpu->activateStage(O3CPU::IEWIdx); 873} 874 875template <class Impl> 876inline void 877DefaultIEW<Impl>::deactivateStage() 878{ 879 DPRINTF(Activity, "Deactivating stage.\n"); 880 cpu->deactivateStage(O3CPU::IEWIdx); 881} 882 883template<class Impl> 884void 885DefaultIEW<Impl>::dispatch(unsigned tid) 886{ 887 // If status is Running or idle, 888 // call dispatchInsts() 889 // If status is Unblocking, 890 // buffer any instructions coming from rename 891 // continue trying to empty skid buffer 892 // check if stall conditions have passed 893 894 if (dispatchStatus[tid] == Blocked) { 895 ++iewBlockCycles; 896 897 } else if (dispatchStatus[tid] == Squashing) { 898 ++iewSquashCycles; 899 } 900 901 // Dispatch should try to dispatch as many instructions as its bandwidth 902 // will allow, as long as it is not currently blocked. 903 if (dispatchStatus[tid] == Running || 904 dispatchStatus[tid] == Idle) { 905 DPRINTF(IEW, "[tid:%i] Not blocked, so attempting to run " 906 "dispatch.\n", tid); 907 908 dispatchInsts(tid); 909 } else if (dispatchStatus[tid] == Unblocking) { 910 // Make sure that the skid buffer has something in it if the 911 // status is unblocking. 912 assert(!skidsEmpty()); 913 914 // If the status was unblocking, then instructions from the skid 915 // buffer were used. Remove those instructions and handle 916 // the rest of unblocking. 917 dispatchInsts(tid); 918 919 ++iewUnblockCycles; 920 921 if (validInstsFromRename() && dispatchedAllInsts) { 922 // Add the current inputs to the skid buffer so they can be 923 // reprocessed when this stage unblocks. 924 skidInsert(tid); 925 } 926 927 unblock(tid); 928 } 929} 930 931template <class Impl> 932void 933DefaultIEW<Impl>::dispatchInsts(unsigned tid) 934{ 935 dispatchedAllInsts = true; 936 937 // Obtain instructions from skid buffer if unblocking, or queue from rename 938 // otherwise. 939 std::queue<DynInstPtr> &insts_to_dispatch = 940 dispatchStatus[tid] == Unblocking ? 941 skidBuffer[tid] : insts[tid]; 942 943 int insts_to_add = insts_to_dispatch.size(); 944 945 DynInstPtr inst; 946 bool add_to_iq = false; 947 int dis_num_inst = 0; 948 949 // Loop through the instructions, putting them in the instruction 950 // queue. 951 for ( ; dis_num_inst < insts_to_add && 952 dis_num_inst < dispatchWidth; 953 ++dis_num_inst) 954 { 955 inst = insts_to_dispatch.front(); 956 957 if (dispatchStatus[tid] == Unblocking) { 958 DPRINTF(IEW, "[tid:%i]: Issue: Examining instruction from skid " 959 "buffer\n", tid); 960 } 961 962 // Make sure there's a valid instruction there. 963 assert(inst); 964 965 DPRINTF(IEW, "[tid:%i]: Issue: Adding PC %#x [sn:%lli] [tid:%i] to " 966 "IQ.\n", 967 tid, inst->readPC(), inst->seqNum, inst->threadNumber); 968 969 // Be sure to mark these instructions as ready so that the 970 // commit stage can go ahead and execute them, and mark 971 // them as issued so the IQ doesn't reprocess them. 972 973 // Check for squashed instructions. 974 if (inst->isSquashed()) { 975 DPRINTF(IEW, "[tid:%i]: Issue: Squashed instruction encountered, " 976 "not adding to IQ.\n", tid); 977 978 ++iewDispSquashedInsts; 979 980 insts_to_dispatch.pop(); 981 982 //Tell Rename That An Instruction has been processed 983 if (inst->isLoad() || inst->isStore()) { 984 toRename->iewInfo[tid].dispatchedToLSQ++; 985 } 986 toRename->iewInfo[tid].dispatched++; 987 988 continue; 989 } 990 991 // Check for full conditions. 992 if (instQueue.isFull(tid)) { 993 DPRINTF(IEW, "[tid:%i]: Issue: IQ has become full.\n", tid); 994 995 // Call function to start blocking. 996 block(tid); 997 998 // Set unblock to false. Special case where we are using 999 // skidbuffer (unblocking) instructions but then we still 1000 // get full in the IQ. 1001 toRename->iewUnblock[tid] = false; 1002 1003 dispatchedAllInsts = false; 1004 1005 ++iewIQFullEvents; 1006 break; 1007 } else if (ldstQueue.isFull(tid)) { 1008 DPRINTF(IEW, "[tid:%i]: Issue: LSQ has become full.\n",tid); 1009 1010 // Call function to start blocking. 1011 block(tid); 1012 1013 // Set unblock to false. Special case where we are using 1014 // skidbuffer (unblocking) instructions but then we still 1015 // get full in the IQ. 1016 toRename->iewUnblock[tid] = false; 1017 1018 dispatchedAllInsts = false; 1019 1020 ++iewLSQFullEvents; 1021 break; 1022 } 1023 1024 // Otherwise issue the instruction just fine. 1025 if (inst->isLoad()) { 1026 DPRINTF(IEW, "[tid:%i]: Issue: Memory instruction " 1027 "encountered, adding to LSQ.\n", tid); 1028 1029 // Reserve a spot in the load store queue for this 1030 // memory access. 1031 ldstQueue.insertLoad(inst); 1032 1033 ++iewDispLoadInsts; 1034 1035 add_to_iq = true; 1036 1037 toRename->iewInfo[tid].dispatchedToLSQ++; 1038 } else if (inst->isStore()) { 1039 DPRINTF(IEW, "[tid:%i]: Issue: Memory instruction " 1040 "encountered, adding to LSQ.\n", tid); 1041 1042 ldstQueue.insertStore(inst); 1043 1044 ++iewDispStoreInsts; 1045 1046 if (inst->isStoreConditional()) { 1047 // Store conditionals need to be set as "canCommit()" 1048 // so that commit can process them when they reach the 1049 // head of commit. 1050 // @todo: This is somewhat specific to Alpha. 1051 inst->setCanCommit(); 1052 instQueue.insertNonSpec(inst); 1053 add_to_iq = false; 1054 1055 ++iewDispNonSpecInsts; 1056 } else { 1057 add_to_iq = true; 1058 } 1059 1060 toRename->iewInfo[tid].dispatchedToLSQ++; 1061#if FULL_SYSTEM 1062 } else if (inst->isMemBarrier() || inst->isWriteBarrier()) { 1063 // Same as non-speculative stores. 1064 inst->setCanCommit(); 1065 instQueue.insertBarrier(inst); 1066 add_to_iq = false; 1067#endif 1068 } else if (inst->isNonSpeculative()) { 1069 DPRINTF(IEW, "[tid:%i]: Issue: Nonspeculative instruction " 1070 "encountered, skipping.\n", tid); 1071 1072 // Same as non-speculative stores. 1073 inst->setCanCommit(); 1074 1075 // Specifically insert it as nonspeculative. 1076 instQueue.insertNonSpec(inst); 1077 1078 ++iewDispNonSpecInsts; 1079 1080 add_to_iq = false; 1081 } else if (inst->isNop()) { 1082 DPRINTF(IEW, "[tid:%i]: Issue: Nop instruction encountered, " 1083 "skipping.\n", tid); 1084 1085 inst->setIssued(); 1086 inst->setExecuted(); 1087 inst->setCanCommit(); 1088 1089 instQueue.recordProducer(inst); 1090 1091 iewExecutedNop[tid]++; 1092 1093 add_to_iq = false; 1094 } else if (inst->isExecuted()) { 1095 assert(0 && "Instruction shouldn't be executed.\n"); 1096 DPRINTF(IEW, "Issue: Executed branch encountered, " 1097 "skipping.\n"); 1098 1099 inst->setIssued(); 1100 inst->setCanCommit(); 1101 1102 instQueue.recordProducer(inst); 1103 1104 add_to_iq = false; 1105 } else { 1106 add_to_iq = true; 1107 } 1108 1109 // If the instruction queue is not full, then add the 1110 // instruction. 1111 if (add_to_iq) { 1112 instQueue.insert(inst); 1113 } 1114 1115 insts_to_dispatch.pop(); 1116 1117 toRename->iewInfo[tid].dispatched++; 1118 1119 ++iewDispatchedInsts; 1120 } 1121 1122 if (!insts_to_dispatch.empty()) { 1123 DPRINTF(IEW,"[tid:%i]: Issue: Bandwidth Full. Blocking.\n"); 1124 block(tid); 1125 toRename->iewUnblock[tid] = false; 1126 } 1127 1128 if (dispatchStatus[tid] == Idle && dis_num_inst) { 1129 dispatchStatus[tid] = Running; 1130 1131 updatedQueues = true; 1132 } 1133 1134 dis_num_inst = 0; 1135} 1136 1137template <class Impl> 1138void 1139DefaultIEW<Impl>::printAvailableInsts() 1140{ 1141 int inst = 0; 1142 1143 cout << "Available Instructions: "; 1144 1145 while (fromIssue->insts[inst]) { 1146 1147 if (inst%3==0) cout << "\n\t"; 1148 1149 cout << "PC: " << fromIssue->insts[inst]->readPC() 1150 << " TN: " << fromIssue->insts[inst]->threadNumber 1151 << " SN: " << fromIssue->insts[inst]->seqNum << " | "; 1152 1153 inst++; 1154 1155 } 1156 1157 cout << "\n"; 1158} 1159 1160template <class Impl> 1161void 1162DefaultIEW<Impl>::executeInsts() 1163{ 1164 wbNumInst = 0; 1165 wbCycle = 0; 1166 1167 list<unsigned>::iterator threads = (*activeThreads).begin(); 1168 1169 while (threads != (*activeThreads).end()) { 1170 unsigned tid = *threads++; 1171 fetchRedirect[tid] = false; 1172 } 1173 1174 // Uncomment this if you want to see all available instructions. 1175// printAvailableInsts(); 1176 1177 // Execute/writeback any instructions that are available. 1178 int insts_to_execute = fromIssue->size; 1179 int inst_num = 0; 1180 for (; inst_num < insts_to_execute; 1181 ++inst_num) { 1182 1183 DPRINTF(IEW, "Execute: Executing instructions from IQ.\n"); 1184 1185 DynInstPtr inst = instQueue.getInstToExecute(); 1186 1187 DPRINTF(IEW, "Execute: Processing PC %#x, [tid:%i] [sn:%i].\n", 1188 inst->readPC(), inst->threadNumber,inst->seqNum); 1189 1190 // Check if the instruction is squashed; if so then skip it 1191 if (inst->isSquashed()) { 1192 DPRINTF(IEW, "Execute: Instruction was squashed.\n"); 1193 1194 // Consider this instruction executed so that commit can go 1195 // ahead and retire the instruction. 1196 inst->setExecuted(); 1197 1198 // Not sure if I should set this here or just let commit try to 1199 // commit any squashed instructions. I like the latter a bit more. 1200 inst->setCanCommit(); 1201 1202 ++iewExecSquashedInsts; 1203 1204 decrWb(inst->seqNum); 1205 continue; 1206 } 1207 1208 Fault fault = NoFault; 1209 1210 // Execute instruction. 1211 // Note that if the instruction faults, it will be handled 1212 // at the commit stage. 1213 if (inst->isMemRef() && 1214 (!inst->isDataPrefetch() && !inst->isInstPrefetch())) { 1215 DPRINTF(IEW, "Execute: Calculating address for memory " 1216 "reference.\n"); 1217 1218 // Tell the LDSTQ to execute this instruction (if it is a load). 1219 if (inst->isLoad()) { 1220 // Loads will mark themselves as executed, and their writeback 1221 // event adds the instruction to the queue to commit 1222 fault = ldstQueue.executeLoad(inst); 1223 } else if (inst->isStore()) { 1224 ldstQueue.executeStore(inst); 1225 1226 // If the store had a fault then it may not have a mem req 1227 if (inst->req && !(inst->req->getFlags() & LOCKED)) { 1228 inst->setExecuted(); 1229 1230 instToCommit(inst); 1231 } 1232 1233 // Store conditionals will mark themselves as 1234 // executed, and their writeback event will add the 1235 // instruction to the queue to commit. 1236 } else { 1237 panic("Unexpected memory type!\n"); 1238 } 1239 1240 } else { 1241 inst->execute(); 1242 1243 inst->setExecuted(); 1244 1245 instToCommit(inst); 1246 } 1247 1248 updateExeInstStats(inst); 1249 1250 // Check if branch prediction was correct, if not then we need 1251 // to tell commit to squash in flight instructions. Only 1252 // handle this if there hasn't already been something that 1253 // redirects fetch in this group of instructions. 1254 1255 // This probably needs to prioritize the redirects if a different 1256 // scheduler is used. Currently the scheduler schedules the oldest 1257 // instruction first, so the branch resolution order will be correct. 1258 unsigned tid = inst->threadNumber; 1259 1260 if (!fetchRedirect[tid]) { 1261 1262 if (inst->mispredicted()) { 1263 fetchRedirect[tid] = true; 1264 1265 DPRINTF(IEW, "Execute: Branch mispredict detected.\n"); 1266 DPRINTF(IEW, "Execute: Redirecting fetch to PC: %#x.\n", 1267 inst->nextPC); 1268 1269 // If incorrect, then signal the ROB that it must be squashed. 1270 squashDueToBranch(inst, tid); 1271 1272 if (inst->predTaken()) { 1273 predictedTakenIncorrect++; 1274 } else { 1275 predictedNotTakenIncorrect++; 1276 } 1277 } else if (ldstQueue.violation(tid)) { 1278 fetchRedirect[tid] = true; 1279 1280 // If there was an ordering violation, then get the 1281 // DynInst that caused the violation. Note that this 1282 // clears the violation signal. 1283 DynInstPtr violator; 1284 violator = ldstQueue.getMemDepViolator(tid); 1285 1286 DPRINTF(IEW, "LDSTQ detected a violation. Violator PC: " 1287 "%#x, inst PC: %#x. Addr is: %#x.\n", 1288 violator->readPC(), inst->readPC(), inst->physEffAddr); 1289 1290 // Tell the instruction queue that a violation has occured. 1291 instQueue.violation(inst, violator); 1292 1293 // Squash. 1294 squashDueToMemOrder(inst,tid); 1295 1296 ++memOrderViolationEvents; 1297 } else if (ldstQueue.loadBlocked(tid) && 1298 !ldstQueue.isLoadBlockedHandled(tid)) { 1299 fetchRedirect[tid] = true; 1300 1301 DPRINTF(IEW, "Load operation couldn't execute because the " 1302 "memory system is blocked. PC: %#x [sn:%lli]\n", 1303 inst->readPC(), inst->seqNum); 1304 1305 squashDueToMemBlocked(inst, tid); 1306 } 1307 } 1308 } 1309 1310 // Update and record activity if we processed any instructions. 1311 if (inst_num) { 1312 if (exeStatus == Idle) { 1313 exeStatus = Running; 1314 } 1315 1316 updatedQueues = true; 1317 1318 cpu->activityThisCycle(); 1319 } 1320 1321 // Need to reset this in case a writeback event needs to write into the 1322 // iew queue. That way the writeback event will write into the correct 1323 // spot in the queue. 1324 wbNumInst = 0; 1325} 1326 1327template <class Impl> 1328void 1329DefaultIEW<Impl>::writebackInsts() 1330{ 1331 // Loop through the head of the time buffer and wake any 1332 // dependents. These instructions are about to write back. Also 1333 // mark scoreboard that this instruction is finally complete. 1334 // Either have IEW have direct access to scoreboard, or have this 1335 // as part of backwards communication. 1336 for (int inst_num = 0; inst_num < issueWidth && 1337 toCommit->insts[inst_num]; inst_num++) { 1338 DynInstPtr inst = toCommit->insts[inst_num]; 1339 int tid = inst->threadNumber; 1340 1341 DPRINTF(IEW, "Sending instructions to commit, [sn:%lli] PC %#x.\n", 1342 inst->seqNum, inst->readPC()); 1343 1344 iewInstsToCommit[tid]++; 1345 1346 // Some instructions will be sent to commit without having 1347 // executed because they need commit to handle them. 1348 // E.g. Uncached loads have not actually executed when they 1349 // are first sent to commit. Instead commit must tell the LSQ 1350 // when it's ready to execute the uncached load. 1351 if (!inst->isSquashed() && inst->isExecuted()) { 1352 int dependents = instQueue.wakeDependents(inst); 1353 1354 for (int i = 0; i < inst->numDestRegs(); i++) { 1355 //mark as Ready 1356 DPRINTF(IEW,"Setting Destination Register %i\n", 1357 inst->renamedDestRegIdx(i)); 1358 scoreboard->setReg(inst->renamedDestRegIdx(i)); 1359 } 1360 1361 if (dependents) { 1362 producerInst[tid]++; 1363 consumerInst[tid]+= dependents; 1364 } 1365 writebackCount[tid]++; 1366 } 1367 1368 decrWb(inst->seqNum); 1369 } 1370} 1371 1372template<class Impl> 1373void 1374DefaultIEW<Impl>::tick() 1375{ 1376 wbNumInst = 0; 1377 wbCycle = 0; 1378 1379 wroteToTimeBuffer = false; 1380 updatedQueues = false; 1381 1382 sortInsts(); 1383 1384 // Free function units marked as being freed this cycle. 1385 fuPool->processFreeUnits(); 1386 1387 list<unsigned>::iterator threads = (*activeThreads).begin(); 1388 1389 // Check stall and squash signals, dispatch any instructions. 1390 while (threads != (*activeThreads).end()) { 1391 unsigned tid = *threads++; 1392 1393 DPRINTF(IEW,"Issue: Processing [tid:%i]\n",tid); 1394 1395 checkSignalsAndUpdate(tid); 1396 dispatch(tid); 1397 } 1398 1399 if (exeStatus != Squashing) { 1400 executeInsts(); 1401 1402 writebackInsts(); 1403 1404 // Have the instruction queue try to schedule any ready instructions. 1405 // (In actuality, this scheduling is for instructions that will 1406 // be executed next cycle.) 1407 instQueue.scheduleReadyInsts(); 1408 1409 // Also should advance its own time buffers if the stage ran. 1410 // Not the best place for it, but this works (hopefully). 1411 issueToExecQueue.advance(); 1412 } 1413 1414 bool broadcast_free_entries = false; 1415 1416 if (updatedQueues || exeStatus == Running || updateLSQNextCycle) { 1417 exeStatus = Idle; 1418 updateLSQNextCycle = false; 1419 1420 broadcast_free_entries = true; 1421 } 1422 1423 // Writeback any stores using any leftover bandwidth. 1424 ldstQueue.writebackStores(); 1425 1426 // Check the committed load/store signals to see if there's a load 1427 // or store to commit. Also check if it's being told to execute a 1428 // nonspeculative instruction. 1429 // This is pretty inefficient... 1430 1431 threads = (*activeThreads).begin(); 1432 while (threads != (*activeThreads).end()) { 1433 unsigned tid = (*threads++); 1434 1435 DPRINTF(IEW,"Processing [tid:%i]\n",tid); 1436 1437 // Update structures based on instructions committed. 1438 if (fromCommit->commitInfo[tid].doneSeqNum != 0 && 1439 !fromCommit->commitInfo[tid].squash && 1440 !fromCommit->commitInfo[tid].robSquashing) { 1441 1442 ldstQueue.commitStores(fromCommit->commitInfo[tid].doneSeqNum,tid); 1443 1444 ldstQueue.commitLoads(fromCommit->commitInfo[tid].doneSeqNum,tid); 1445 1446 updateLSQNextCycle = true; 1447 instQueue.commit(fromCommit->commitInfo[tid].doneSeqNum,tid); 1448 } 1449 1450 if (fromCommit->commitInfo[tid].nonSpecSeqNum != 0) { 1451 1452 //DPRINTF(IEW,"NonspecInst from thread %i",tid); 1453 if (fromCommit->commitInfo[tid].uncached) { 1454 instQueue.replayMemInst(fromCommit->commitInfo[tid].uncachedLoad); 1455 } else { 1456 instQueue.scheduleNonSpec( 1457 fromCommit->commitInfo[tid].nonSpecSeqNum); 1458 } 1459 } 1460 1461 if (broadcast_free_entries) { 1462 toFetch->iewInfo[tid].iqCount = 1463 instQueue.getCount(tid); 1464 toFetch->iewInfo[tid].ldstqCount = 1465 ldstQueue.getCount(tid); 1466 1467 toRename->iewInfo[tid].usedIQ = true; 1468 toRename->iewInfo[tid].freeIQEntries = 1469 instQueue.numFreeEntries(); 1470 toRename->iewInfo[tid].usedLSQ = true; 1471 toRename->iewInfo[tid].freeLSQEntries = 1472 ldstQueue.numFreeEntries(tid); 1473 1474 wroteToTimeBuffer = true; 1475 } 1476 1477 DPRINTF(IEW, "[tid:%i], Dispatch dispatched %i instructions.\n", 1478 tid, toRename->iewInfo[tid].dispatched); 1479 } 1480 1481 DPRINTF(IEW, "IQ has %i free entries (Can schedule: %i). " 1482 "LSQ has %i free entries.\n", 1483 instQueue.numFreeEntries(), instQueue.hasReadyInsts(), 1484 ldstQueue.numFreeEntries()); 1485 1486 updateStatus(); 1487 1488 if (wroteToTimeBuffer) { 1489 DPRINTF(Activity, "Activity this cycle.\n"); 1490 cpu->activityThisCycle(); 1491 } 1492} 1493 1494template <class Impl> 1495void 1496DefaultIEW<Impl>::updateExeInstStats(DynInstPtr &inst) 1497{ 1498 int thread_number = inst->threadNumber; 1499 1500 // 1501 // Pick off the software prefetches 1502 // 1503#ifdef TARGET_ALPHA 1504 if (inst->isDataPrefetch()) 1505 iewExecutedSwp[thread_number]++; 1506 else 1507 iewIewExecutedcutedInsts++; 1508#else 1509 iewExecutedInsts++; 1510#endif 1511 1512 // 1513 // Control operations 1514 // 1515 if (inst->isControl()) 1516 iewExecutedBranches[thread_number]++; 1517 1518 // 1519 // Memory operations 1520 // 1521 if (inst->isMemRef()) { 1522 iewExecutedRefs[thread_number]++; 1523 1524 if (inst->isLoad()) { 1525 iewExecLoadInsts[thread_number]++; 1526 } 1527 } 1528} 1529