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#include "config/full_system.hh" 32#include "config/use_checker.hh" 33 34#include <algorithm> 35#include <string> 36 37#include "base/loader/symtab.hh" 38#include "base/timebuf.hh" 39#include "cpu/exetrace.hh" 40#include "cpu/o3/commit.hh" 41#include "cpu/o3/thread_state.hh" 42 43#if USE_CHECKER 44#include "cpu/checker/cpu.hh" 45#endif 46 47using namespace std; 48 49template <class Impl> 50DefaultCommit<Impl>::TrapEvent::TrapEvent(DefaultCommit<Impl> *_commit, 51 unsigned _tid) 52 : Event(&mainEventQueue, CPU_Tick_Pri), commit(_commit), tid(_tid) 53{ 54 this->setFlags(Event::AutoDelete); 55} 56 57template <class Impl> 58void 59DefaultCommit<Impl>::TrapEvent::process() 60{ 61 // This will get reset by commit if it was switched out at the 62 // time of this event processing. 63 commit->trapSquash[tid] = true; 64} 65 66template <class Impl> 67const char * 68DefaultCommit<Impl>::TrapEvent::description() 69{ 70 return "Trap event"; 71} 72 73template <class Impl> 74DefaultCommit<Impl>::DefaultCommit(Params *params) 75 : squashCounter(0), 76 iewToCommitDelay(params->iewToCommitDelay), 77 commitToIEWDelay(params->commitToIEWDelay), 78 renameToROBDelay(params->renameToROBDelay), 79 fetchToCommitDelay(params->commitToFetchDelay), 80 renameWidth(params->renameWidth), 81 commitWidth(params->commitWidth), 82 numThreads(params->numberOfThreads), 83 drainPending(false), 84 switchedOut(false), 85 trapLatency(params->trapLatency), 86 fetchTrapLatency(params->fetchTrapLatency) 87{ 88 _status = Active; 89 _nextStatus = Inactive; 90 string policy = params->smtCommitPolicy; 91 92 //Convert string to lowercase 93 std::transform(policy.begin(), policy.end(), policy.begin(), 94 (int(*)(int)) tolower); 95 96 //Assign commit policy 97 if (policy == "aggressive"){ 98 commitPolicy = Aggressive; 99 100 DPRINTF(Commit,"Commit Policy set to Aggressive."); 101 } else if (policy == "roundrobin"){ 102 commitPolicy = RoundRobin; 103 104 //Set-Up Priority List 105 for (int tid=0; tid < numThreads; tid++) { 106 priority_list.push_back(tid); 107 } 108 109 DPRINTF(Commit,"Commit Policy set to Round Robin."); 110 } else if (policy == "oldestready"){ 111 commitPolicy = OldestReady; 112 113 DPRINTF(Commit,"Commit Policy set to Oldest Ready."); 114 } else { 115 assert(0 && "Invalid SMT Commit Policy. Options Are: {Aggressive," 116 "RoundRobin,OldestReady}"); 117 } 118 119 for (int i=0; i < numThreads; i++) { 120 commitStatus[i] = Idle; 121 changedROBNumEntries[i] = false; 122 trapSquash[i] = false; 123 tcSquash[i] = false; 124 PC[i] = nextPC[i] = 0; 125 } 126 127 fetchFaultTick = 0; 128 fetchTrapWait = 0; 129} 130 131template <class Impl> 132std::string 133DefaultCommit<Impl>::name() const 134{ 135 return cpu->name() + ".commit"; 136} 137 138template <class Impl> 139void 140DefaultCommit<Impl>::regStats() 141{ 142 using namespace Stats; 143 commitCommittedInsts 144 .name(name() + ".commitCommittedInsts") 145 .desc("The number of committed instructions") 146 .prereq(commitCommittedInsts); 147 commitSquashedInsts 148 .name(name() + ".commitSquashedInsts") 149 .desc("The number of squashed insts skipped by commit") 150 .prereq(commitSquashedInsts); 151 commitSquashEvents 152 .name(name() + ".commitSquashEvents") 153 .desc("The number of times commit is told to squash") 154 .prereq(commitSquashEvents); 155 commitNonSpecStalls 156 .name(name() + ".commitNonSpecStalls") 157 .desc("The number of times commit has been forced to stall to " 158 "communicate backwards") 159 .prereq(commitNonSpecStalls); 160 branchMispredicts 161 .name(name() + ".branchMispredicts") 162 .desc("The number of times a branch was mispredicted") 163 .prereq(branchMispredicts); 164 numCommittedDist 165 .init(0,commitWidth,1) 166 .name(name() + ".COM:committed_per_cycle") 167 .desc("Number of insts commited each cycle") 168 .flags(Stats::pdf) 169 ; 170 171 statComInst 172 .init(cpu->number_of_threads) 173 .name(name() + ".COM:count") 174 .desc("Number of instructions committed") 175 .flags(total) 176 ; 177 178 statComSwp 179 .init(cpu->number_of_threads) 180 .name(name() + ".COM:swp_count") 181 .desc("Number of s/w prefetches committed") 182 .flags(total) 183 ; 184 185 statComRefs 186 .init(cpu->number_of_threads) 187 .name(name() + ".COM:refs") 188 .desc("Number of memory references committed") 189 .flags(total) 190 ; 191 192 statComLoads 193 .init(cpu->number_of_threads) 194 .name(name() + ".COM:loads") 195 .desc("Number of loads committed") 196 .flags(total) 197 ; 198 199 statComMembars 200 .init(cpu->number_of_threads) 201 .name(name() + ".COM:membars") 202 .desc("Number of memory barriers committed") 203 .flags(total) 204 ; 205 206 statComBranches 207 .init(cpu->number_of_threads) 208 .name(name() + ".COM:branches") 209 .desc("Number of branches committed") 210 .flags(total) 211 ; 212 213 commitEligible 214 .init(cpu->number_of_threads) 215 .name(name() + ".COM:bw_limited") 216 .desc("number of insts not committed due to BW limits") 217 .flags(total) 218 ; 219 220 commitEligibleSamples 221 .name(name() + ".COM:bw_lim_events") 222 .desc("number cycles where commit BW limit reached") 223 ; 224} 225 226template <class Impl> 227void 228DefaultCommit<Impl>::setCPU(O3CPU *cpu_ptr) 229{ 230 DPRINTF(Commit, "Commit: Setting CPU pointer.\n"); 231 cpu = cpu_ptr; 232 233 // Commit must broadcast the number of free entries it has at the start of 234 // the simulation, so it starts as active. 235 cpu->activateStage(O3CPU::CommitIdx); 236 237 trapLatency = cpu->cycles(trapLatency); 238 fetchTrapLatency = cpu->cycles(fetchTrapLatency); 239} 240 241template <class Impl> 242void 243DefaultCommit<Impl>::setThreads(vector<Thread *> &threads) 244{ 245 thread = threads; 246} 247 248template <class Impl> 249void 250DefaultCommit<Impl>::setTimeBuffer(TimeBuffer<TimeStruct> *tb_ptr) 251{ 252 DPRINTF(Commit, "Commit: Setting time buffer pointer.\n"); 253 timeBuffer = tb_ptr; 254 255 // Setup wire to send information back to IEW. 256 toIEW = timeBuffer->getWire(0); 257 258 // Setup wire to read data from IEW (for the ROB). 259 robInfoFromIEW = timeBuffer->getWire(-iewToCommitDelay); 260} 261 262template <class Impl> 263void 264DefaultCommit<Impl>::setFetchQueue(TimeBuffer<FetchStruct> *fq_ptr) 265{ 266 DPRINTF(Commit, "Commit: Setting fetch queue pointer.\n"); 267 fetchQueue = fq_ptr; 268 269 // Setup wire to get instructions from rename (for the ROB). 270 fromFetch = fetchQueue->getWire(-fetchToCommitDelay); 271} 272 273template <class Impl> 274void 275DefaultCommit<Impl>::setRenameQueue(TimeBuffer<RenameStruct> *rq_ptr) 276{ 277 DPRINTF(Commit, "Commit: Setting rename queue pointer.\n"); 278 renameQueue = rq_ptr; 279 280 // Setup wire to get instructions from rename (for the ROB). 281 fromRename = renameQueue->getWire(-renameToROBDelay); 282} 283 284template <class Impl> 285void 286DefaultCommit<Impl>::setIEWQueue(TimeBuffer<IEWStruct> *iq_ptr) 287{ 288 DPRINTF(Commit, "Commit: Setting IEW queue pointer.\n"); 289 iewQueue = iq_ptr; 290 291 // Setup wire to get instructions from IEW. 292 fromIEW = iewQueue->getWire(-iewToCommitDelay); 293} 294 295template <class Impl> 296void 297DefaultCommit<Impl>::setFetchStage(Fetch *fetch_stage) 298{ 299 fetchStage = fetch_stage; 300} 301 302template <class Impl> 303void 304DefaultCommit<Impl>::setIEWStage(IEW *iew_stage) 305{ 306 iewStage = iew_stage; 307} 308 309template<class Impl> 310void 311DefaultCommit<Impl>::setActiveThreads(list<unsigned> *at_ptr) 312{ 313 DPRINTF(Commit, "Commit: Setting active threads list pointer.\n"); 314 activeThreads = at_ptr; 315} 316 317template <class Impl> 318void 319DefaultCommit<Impl>::setRenameMap(RenameMap rm_ptr[]) 320{ 321 DPRINTF(Commit, "Setting rename map pointers.\n"); 322 323 for (int i=0; i < numThreads; i++) { 324 renameMap[i] = &rm_ptr[i]; 325 } 326} 327 328template <class Impl> 329void 330DefaultCommit<Impl>::setROB(ROB *rob_ptr) 331{ 332 DPRINTF(Commit, "Commit: Setting ROB pointer.\n"); 333 rob = rob_ptr; 334} 335 336template <class Impl> 337void 338DefaultCommit<Impl>::initStage() 339{ 340 rob->setActiveThreads(activeThreads); 341 rob->resetEntries(); 342 343 // Broadcast the number of free entries. 344 for (int i=0; i < numThreads; i++) { 345 toIEW->commitInfo[i].usedROB = true; 346 toIEW->commitInfo[i].freeROBEntries = rob->numFreeEntries(i); 347 } 348 349 cpu->activityThisCycle(); 350} 351 352template <class Impl>
| 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#include "config/full_system.hh" 32#include "config/use_checker.hh" 33 34#include <algorithm> 35#include <string> 36 37#include "base/loader/symtab.hh" 38#include "base/timebuf.hh" 39#include "cpu/exetrace.hh" 40#include "cpu/o3/commit.hh" 41#include "cpu/o3/thread_state.hh" 42 43#if USE_CHECKER 44#include "cpu/checker/cpu.hh" 45#endif 46 47using namespace std; 48 49template <class Impl> 50DefaultCommit<Impl>::TrapEvent::TrapEvent(DefaultCommit<Impl> *_commit, 51 unsigned _tid) 52 : Event(&mainEventQueue, CPU_Tick_Pri), commit(_commit), tid(_tid) 53{ 54 this->setFlags(Event::AutoDelete); 55} 56 57template <class Impl> 58void 59DefaultCommit<Impl>::TrapEvent::process() 60{ 61 // This will get reset by commit if it was switched out at the 62 // time of this event processing. 63 commit->trapSquash[tid] = true; 64} 65 66template <class Impl> 67const char * 68DefaultCommit<Impl>::TrapEvent::description() 69{ 70 return "Trap event"; 71} 72 73template <class Impl> 74DefaultCommit<Impl>::DefaultCommit(Params *params) 75 : squashCounter(0), 76 iewToCommitDelay(params->iewToCommitDelay), 77 commitToIEWDelay(params->commitToIEWDelay), 78 renameToROBDelay(params->renameToROBDelay), 79 fetchToCommitDelay(params->commitToFetchDelay), 80 renameWidth(params->renameWidth), 81 commitWidth(params->commitWidth), 82 numThreads(params->numberOfThreads), 83 drainPending(false), 84 switchedOut(false), 85 trapLatency(params->trapLatency), 86 fetchTrapLatency(params->fetchTrapLatency) 87{ 88 _status = Active; 89 _nextStatus = Inactive; 90 string policy = params->smtCommitPolicy; 91 92 //Convert string to lowercase 93 std::transform(policy.begin(), policy.end(), policy.begin(), 94 (int(*)(int)) tolower); 95 96 //Assign commit policy 97 if (policy == "aggressive"){ 98 commitPolicy = Aggressive; 99 100 DPRINTF(Commit,"Commit Policy set to Aggressive."); 101 } else if (policy == "roundrobin"){ 102 commitPolicy = RoundRobin; 103 104 //Set-Up Priority List 105 for (int tid=0; tid < numThreads; tid++) { 106 priority_list.push_back(tid); 107 } 108 109 DPRINTF(Commit,"Commit Policy set to Round Robin."); 110 } else if (policy == "oldestready"){ 111 commitPolicy = OldestReady; 112 113 DPRINTF(Commit,"Commit Policy set to Oldest Ready."); 114 } else { 115 assert(0 && "Invalid SMT Commit Policy. Options Are: {Aggressive," 116 "RoundRobin,OldestReady}"); 117 } 118 119 for (int i=0; i < numThreads; i++) { 120 commitStatus[i] = Idle; 121 changedROBNumEntries[i] = false; 122 trapSquash[i] = false; 123 tcSquash[i] = false; 124 PC[i] = nextPC[i] = 0; 125 } 126 127 fetchFaultTick = 0; 128 fetchTrapWait = 0; 129} 130 131template <class Impl> 132std::string 133DefaultCommit<Impl>::name() const 134{ 135 return cpu->name() + ".commit"; 136} 137 138template <class Impl> 139void 140DefaultCommit<Impl>::regStats() 141{ 142 using namespace Stats; 143 commitCommittedInsts 144 .name(name() + ".commitCommittedInsts") 145 .desc("The number of committed instructions") 146 .prereq(commitCommittedInsts); 147 commitSquashedInsts 148 .name(name() + ".commitSquashedInsts") 149 .desc("The number of squashed insts skipped by commit") 150 .prereq(commitSquashedInsts); 151 commitSquashEvents 152 .name(name() + ".commitSquashEvents") 153 .desc("The number of times commit is told to squash") 154 .prereq(commitSquashEvents); 155 commitNonSpecStalls 156 .name(name() + ".commitNonSpecStalls") 157 .desc("The number of times commit has been forced to stall to " 158 "communicate backwards") 159 .prereq(commitNonSpecStalls); 160 branchMispredicts 161 .name(name() + ".branchMispredicts") 162 .desc("The number of times a branch was mispredicted") 163 .prereq(branchMispredicts); 164 numCommittedDist 165 .init(0,commitWidth,1) 166 .name(name() + ".COM:committed_per_cycle") 167 .desc("Number of insts commited each cycle") 168 .flags(Stats::pdf) 169 ; 170 171 statComInst 172 .init(cpu->number_of_threads) 173 .name(name() + ".COM:count") 174 .desc("Number of instructions committed") 175 .flags(total) 176 ; 177 178 statComSwp 179 .init(cpu->number_of_threads) 180 .name(name() + ".COM:swp_count") 181 .desc("Number of s/w prefetches committed") 182 .flags(total) 183 ; 184 185 statComRefs 186 .init(cpu->number_of_threads) 187 .name(name() + ".COM:refs") 188 .desc("Number of memory references committed") 189 .flags(total) 190 ; 191 192 statComLoads 193 .init(cpu->number_of_threads) 194 .name(name() + ".COM:loads") 195 .desc("Number of loads committed") 196 .flags(total) 197 ; 198 199 statComMembars 200 .init(cpu->number_of_threads) 201 .name(name() + ".COM:membars") 202 .desc("Number of memory barriers committed") 203 .flags(total) 204 ; 205 206 statComBranches 207 .init(cpu->number_of_threads) 208 .name(name() + ".COM:branches") 209 .desc("Number of branches committed") 210 .flags(total) 211 ; 212 213 commitEligible 214 .init(cpu->number_of_threads) 215 .name(name() + ".COM:bw_limited") 216 .desc("number of insts not committed due to BW limits") 217 .flags(total) 218 ; 219 220 commitEligibleSamples 221 .name(name() + ".COM:bw_lim_events") 222 .desc("number cycles where commit BW limit reached") 223 ; 224} 225 226template <class Impl> 227void 228DefaultCommit<Impl>::setCPU(O3CPU *cpu_ptr) 229{ 230 DPRINTF(Commit, "Commit: Setting CPU pointer.\n"); 231 cpu = cpu_ptr; 232 233 // Commit must broadcast the number of free entries it has at the start of 234 // the simulation, so it starts as active. 235 cpu->activateStage(O3CPU::CommitIdx); 236 237 trapLatency = cpu->cycles(trapLatency); 238 fetchTrapLatency = cpu->cycles(fetchTrapLatency); 239} 240 241template <class Impl> 242void 243DefaultCommit<Impl>::setThreads(vector<Thread *> &threads) 244{ 245 thread = threads; 246} 247 248template <class Impl> 249void 250DefaultCommit<Impl>::setTimeBuffer(TimeBuffer<TimeStruct> *tb_ptr) 251{ 252 DPRINTF(Commit, "Commit: Setting time buffer pointer.\n"); 253 timeBuffer = tb_ptr; 254 255 // Setup wire to send information back to IEW. 256 toIEW = timeBuffer->getWire(0); 257 258 // Setup wire to read data from IEW (for the ROB). 259 robInfoFromIEW = timeBuffer->getWire(-iewToCommitDelay); 260} 261 262template <class Impl> 263void 264DefaultCommit<Impl>::setFetchQueue(TimeBuffer<FetchStruct> *fq_ptr) 265{ 266 DPRINTF(Commit, "Commit: Setting fetch queue pointer.\n"); 267 fetchQueue = fq_ptr; 268 269 // Setup wire to get instructions from rename (for the ROB). 270 fromFetch = fetchQueue->getWire(-fetchToCommitDelay); 271} 272 273template <class Impl> 274void 275DefaultCommit<Impl>::setRenameQueue(TimeBuffer<RenameStruct> *rq_ptr) 276{ 277 DPRINTF(Commit, "Commit: Setting rename queue pointer.\n"); 278 renameQueue = rq_ptr; 279 280 // Setup wire to get instructions from rename (for the ROB). 281 fromRename = renameQueue->getWire(-renameToROBDelay); 282} 283 284template <class Impl> 285void 286DefaultCommit<Impl>::setIEWQueue(TimeBuffer<IEWStruct> *iq_ptr) 287{ 288 DPRINTF(Commit, "Commit: Setting IEW queue pointer.\n"); 289 iewQueue = iq_ptr; 290 291 // Setup wire to get instructions from IEW. 292 fromIEW = iewQueue->getWire(-iewToCommitDelay); 293} 294 295template <class Impl> 296void 297DefaultCommit<Impl>::setFetchStage(Fetch *fetch_stage) 298{ 299 fetchStage = fetch_stage; 300} 301 302template <class Impl> 303void 304DefaultCommit<Impl>::setIEWStage(IEW *iew_stage) 305{ 306 iewStage = iew_stage; 307} 308 309template<class Impl> 310void 311DefaultCommit<Impl>::setActiveThreads(list<unsigned> *at_ptr) 312{ 313 DPRINTF(Commit, "Commit: Setting active threads list pointer.\n"); 314 activeThreads = at_ptr; 315} 316 317template <class Impl> 318void 319DefaultCommit<Impl>::setRenameMap(RenameMap rm_ptr[]) 320{ 321 DPRINTF(Commit, "Setting rename map pointers.\n"); 322 323 for (int i=0; i < numThreads; i++) { 324 renameMap[i] = &rm_ptr[i]; 325 } 326} 327 328template <class Impl> 329void 330DefaultCommit<Impl>::setROB(ROB *rob_ptr) 331{ 332 DPRINTF(Commit, "Commit: Setting ROB pointer.\n"); 333 rob = rob_ptr; 334} 335 336template <class Impl> 337void 338DefaultCommit<Impl>::initStage() 339{ 340 rob->setActiveThreads(activeThreads); 341 rob->resetEntries(); 342 343 // Broadcast the number of free entries. 344 for (int i=0; i < numThreads; i++) { 345 toIEW->commitInfo[i].usedROB = true; 346 toIEW->commitInfo[i].freeROBEntries = rob->numFreeEntries(i); 347 } 348 349 cpu->activityThisCycle(); 350} 351 352template <class Impl>
|
357} 358 359template <class Impl> 360void 361DefaultCommit<Impl>::switchOut() 362{ 363 switchedOut = true; 364 drainPending = false; 365 rob->switchOut(); 366} 367 368template <class Impl> 369void 370DefaultCommit<Impl>::resume() 371{ 372} 373 374template <class Impl> 375void 376DefaultCommit<Impl>::takeOverFrom() 377{ 378 switchedOut = false; 379 _status = Active; 380 _nextStatus = Inactive; 381 for (int i=0; i < numThreads; i++) { 382 commitStatus[i] = Idle; 383 changedROBNumEntries[i] = false; 384 trapSquash[i] = false; 385 tcSquash[i] = false; 386 } 387 squashCounter = 0; 388 rob->takeOverFrom(); 389} 390 391template <class Impl> 392void 393DefaultCommit<Impl>::updateStatus() 394{ 395 // reset ROB changed variable 396 list<unsigned>::iterator threads = (*activeThreads).begin(); 397 while (threads != (*activeThreads).end()) { 398 unsigned tid = *threads++; 399 changedROBNumEntries[tid] = false; 400 401 // Also check if any of the threads has a trap pending 402 if (commitStatus[tid] == TrapPending || 403 commitStatus[tid] == FetchTrapPending) { 404 _nextStatus = Active; 405 } 406 } 407 408 if (_nextStatus == Inactive && _status == Active) { 409 DPRINTF(Activity, "Deactivating stage.\n"); 410 cpu->deactivateStage(O3CPU::CommitIdx); 411 } else if (_nextStatus == Active && _status == Inactive) { 412 DPRINTF(Activity, "Activating stage.\n"); 413 cpu->activateStage(O3CPU::CommitIdx); 414 } 415 416 _status = _nextStatus; 417} 418 419template <class Impl> 420void 421DefaultCommit<Impl>::setNextStatus() 422{ 423 int squashes = 0; 424 425 list<unsigned>::iterator threads = (*activeThreads).begin(); 426 427 while (threads != (*activeThreads).end()) { 428 unsigned tid = *threads++; 429 430 if (commitStatus[tid] == ROBSquashing) { 431 squashes++; 432 } 433 } 434 435 squashCounter = squashes; 436 437 // If commit is currently squashing, then it will have activity for the 438 // next cycle. Set its next status as active. 439 if (squashCounter) { 440 _nextStatus = Active; 441 } 442} 443 444template <class Impl> 445bool 446DefaultCommit<Impl>::changedROBEntries() 447{ 448 list<unsigned>::iterator threads = (*activeThreads).begin(); 449 450 while (threads != (*activeThreads).end()) { 451 unsigned tid = *threads++; 452 453 if (changedROBNumEntries[tid]) { 454 return true; 455 } 456 } 457 458 return false; 459} 460 461template <class Impl> 462unsigned 463DefaultCommit<Impl>::numROBFreeEntries(unsigned tid) 464{ 465 return rob->numFreeEntries(tid); 466} 467 468template <class Impl> 469void 470DefaultCommit<Impl>::generateTrapEvent(unsigned tid) 471{ 472 DPRINTF(Commit, "Generating trap event for [tid:%i]\n", tid); 473 474 TrapEvent *trap = new TrapEvent(this, tid); 475 476 trap->schedule(curTick + trapLatency); 477 478 thread[tid]->trapPending = true; 479} 480 481template <class Impl> 482void 483DefaultCommit<Impl>::generateTCEvent(unsigned tid) 484{ 485 DPRINTF(Commit, "Generating TC squash event for [tid:%i]\n", tid); 486 487 tcSquash[tid] = true; 488} 489 490template <class Impl> 491void 492DefaultCommit<Impl>::squashAll(unsigned tid) 493{ 494 // If we want to include the squashing instruction in the squash, 495 // then use one older sequence number. 496 // Hopefully this doesn't mess things up. Basically I want to squash 497 // all instructions of this thread. 498 InstSeqNum squashed_inst = rob->isEmpty() ? 499 0 : rob->readHeadInst(tid)->seqNum - 1;; 500 501 // All younger instructions will be squashed. Set the sequence 502 // number as the youngest instruction in the ROB (0 in this case. 503 // Hopefully nothing breaks.) 504 youngestSeqNum[tid] = 0; 505 506 rob->squash(squashed_inst, tid); 507 changedROBNumEntries[tid] = true; 508 509 // Send back the sequence number of the squashed instruction. 510 toIEW->commitInfo[tid].doneSeqNum = squashed_inst; 511 512 // Send back the squash signal to tell stages that they should 513 // squash. 514 toIEW->commitInfo[tid].squash = true; 515 516 // Send back the rob squashing signal so other stages know that 517 // the ROB is in the process of squashing. 518 toIEW->commitInfo[tid].robSquashing = true; 519 520 toIEW->commitInfo[tid].branchMispredict = false; 521 522 toIEW->commitInfo[tid].nextPC = PC[tid]; 523} 524 525template <class Impl> 526void 527DefaultCommit<Impl>::squashFromTrap(unsigned tid) 528{ 529 squashAll(tid); 530 531 DPRINTF(Commit, "Squashing from trap, restarting at PC %#x\n", PC[tid]); 532 533 thread[tid]->trapPending = false; 534 thread[tid]->inSyscall = false; 535 536 trapSquash[tid] = false; 537 538 commitStatus[tid] = ROBSquashing; 539 cpu->activityThisCycle(); 540} 541 542template <class Impl> 543void 544DefaultCommit<Impl>::squashFromTC(unsigned tid) 545{ 546 squashAll(tid); 547 548 DPRINTF(Commit, "Squashing from TC, restarting at PC %#x\n", PC[tid]); 549 550 thread[tid]->inSyscall = false; 551 assert(!thread[tid]->trapPending); 552 553 commitStatus[tid] = ROBSquashing; 554 cpu->activityThisCycle(); 555 556 tcSquash[tid] = false; 557} 558 559template <class Impl> 560void 561DefaultCommit<Impl>::tick() 562{ 563 wroteToTimeBuffer = false; 564 _nextStatus = Inactive; 565 566 if (drainPending && rob->isEmpty() && !iewStage->hasStoresToWB()) { 567 cpu->signalDrained(); 568 drainPending = false; 569 return; 570 } 571 572 list<unsigned>::iterator threads = (*activeThreads).begin(); 573 574 // Check if any of the threads are done squashing. Change the 575 // status if they are done. 576 while (threads != (*activeThreads).end()) { 577 unsigned tid = *threads++; 578 579 if (commitStatus[tid] == ROBSquashing) { 580 581 if (rob->isDoneSquashing(tid)) { 582 commitStatus[tid] = Running; 583 } else { 584 DPRINTF(Commit,"[tid:%u]: Still Squashing, cannot commit any" 585 "insts this cycle.\n", tid); 586 rob->doSquash(tid); 587 toIEW->commitInfo[tid].robSquashing = true; 588 wroteToTimeBuffer = true; 589 } 590 } 591 } 592 593 commit(); 594 595 markCompletedInsts(); 596 597 threads = (*activeThreads).begin(); 598 599 while (threads != (*activeThreads).end()) { 600 unsigned tid = *threads++; 601 602 if (!rob->isEmpty(tid) && rob->readHeadInst(tid)->readyToCommit()) { 603 // The ROB has more instructions it can commit. Its next status 604 // will be active. 605 _nextStatus = Active; 606 607 DynInstPtr inst = rob->readHeadInst(tid); 608 609 DPRINTF(Commit,"[tid:%i]: Instruction [sn:%lli] PC %#x is head of" 610 " ROB and ready to commit\n", 611 tid, inst->seqNum, inst->readPC()); 612 613 } else if (!rob->isEmpty(tid)) { 614 DynInstPtr inst = rob->readHeadInst(tid); 615 616 DPRINTF(Commit,"[tid:%i]: Can't commit, Instruction [sn:%lli] PC " 617 "%#x is head of ROB and not ready\n", 618 tid, inst->seqNum, inst->readPC()); 619 } 620 621 DPRINTF(Commit, "[tid:%i]: ROB has %d insts & %d free entries.\n", 622 tid, rob->countInsts(tid), rob->numFreeEntries(tid)); 623 } 624 625 626 if (wroteToTimeBuffer) { 627 DPRINTF(Activity, "Activity This Cycle.\n"); 628 cpu->activityThisCycle(); 629 } 630 631 updateStatus(); 632} 633 634template <class Impl> 635void 636DefaultCommit<Impl>::commit() 637{ 638 639 ////////////////////////////////////// 640 // Check for interrupts 641 ////////////////////////////////////// 642 643#if FULL_SYSTEM 644 // Process interrupts if interrupts are enabled, not in PAL mode, 645 // and no other traps or external squashes are currently pending. 646 // @todo: Allow other threads to handle interrupts. 647 if (cpu->checkInterrupts && 648 cpu->check_interrupts() && 649 !cpu->inPalMode(readPC()) && 650 !trapSquash[0] && 651 !tcSquash[0]) { 652 // Tell fetch that there is an interrupt pending. This will 653 // make fetch wait until it sees a non PAL-mode PC, at which 654 // point it stops fetching instructions. 655 toIEW->commitInfo[0].interruptPending = true; 656 657 // Wait until the ROB is empty and all stores have drained in 658 // order to enter the interrupt. 659 if (rob->isEmpty() && !iewStage->hasStoresToWB()) { 660 // Not sure which thread should be the one to interrupt. For now 661 // always do thread 0. 662 assert(!thread[0]->inSyscall); 663 thread[0]->inSyscall = true; 664 665 // CPU will handle implementation of the interrupt. 666 cpu->processInterrupts(); 667 668 // Now squash or record that I need to squash this cycle. 669 commitStatus[0] = TrapPending; 670 671 // Exit state update mode to avoid accidental updating. 672 thread[0]->inSyscall = false; 673 674 // Generate trap squash event. 675 generateTrapEvent(0); 676 677 toIEW->commitInfo[0].clearInterrupt = true; 678 679 DPRINTF(Commit, "Interrupt detected.\n"); 680 } else { 681 DPRINTF(Commit, "Interrupt pending, waiting for ROB to empty.\n"); 682 } 683 } 684#endif // FULL_SYSTEM 685 686 //////////////////////////////////// 687 // Check for any possible squashes, handle them first 688 //////////////////////////////////// 689 690 list<unsigned>::iterator threads = (*activeThreads).begin(); 691 692 while (threads != (*activeThreads).end()) { 693 unsigned tid = *threads++; 694 695 // Not sure which one takes priority. I think if we have 696 // both, that's a bad sign. 697 if (trapSquash[tid] == true) { 698 assert(!tcSquash[tid]); 699 squashFromTrap(tid); 700 } else if (tcSquash[tid] == true) { 701 squashFromTC(tid); 702 } 703 704 // Squashed sequence number must be older than youngest valid 705 // instruction in the ROB. This prevents squashes from younger 706 // instructions overriding squashes from older instructions. 707 if (fromIEW->squash[tid] && 708 commitStatus[tid] != TrapPending && 709 fromIEW->squashedSeqNum[tid] <= youngestSeqNum[tid]) { 710 711 DPRINTF(Commit, "[tid:%i]: Squashing due to PC %#x [sn:%i]\n", 712 tid, 713 fromIEW->mispredPC[tid], 714 fromIEW->squashedSeqNum[tid]); 715 716 DPRINTF(Commit, "[tid:%i]: Redirecting to PC %#x\n", 717 tid, 718 fromIEW->nextPC[tid]); 719 720 commitStatus[tid] = ROBSquashing; 721 722 // If we want to include the squashing instruction in the squash, 723 // then use one older sequence number. 724 InstSeqNum squashed_inst = fromIEW->squashedSeqNum[tid]; 725 726 if (fromIEW->includeSquashInst[tid] == true) 727 squashed_inst--; 728 729 // All younger instructions will be squashed. Set the sequence 730 // number as the youngest instruction in the ROB. 731 youngestSeqNum[tid] = squashed_inst; 732 733 rob->squash(squashed_inst, tid); 734 changedROBNumEntries[tid] = true; 735 736 toIEW->commitInfo[tid].doneSeqNum = squashed_inst; 737 738 toIEW->commitInfo[tid].squash = true; 739 740 // Send back the rob squashing signal so other stages know that 741 // the ROB is in the process of squashing. 742 toIEW->commitInfo[tid].robSquashing = true; 743 744 toIEW->commitInfo[tid].branchMispredict = 745 fromIEW->branchMispredict[tid]; 746 747 toIEW->commitInfo[tid].branchTaken = 748 fromIEW->branchTaken[tid]; 749 750 toIEW->commitInfo[tid].nextPC = fromIEW->nextPC[tid]; 751 752 toIEW->commitInfo[tid].mispredPC = fromIEW->mispredPC[tid]; 753 754 if (toIEW->commitInfo[tid].branchMispredict) { 755 ++branchMispredicts; 756 } 757 } 758 759 } 760 761 setNextStatus(); 762 763 if (squashCounter != numThreads) { 764 // If we're not currently squashing, then get instructions. 765 getInsts(); 766 767 // Try to commit any instructions. 768 commitInsts(); 769 } 770 771 //Check for any activity 772 threads = (*activeThreads).begin(); 773 774 while (threads != (*activeThreads).end()) { 775 unsigned tid = *threads++; 776 777 if (changedROBNumEntries[tid]) { 778 toIEW->commitInfo[tid].usedROB = true; 779 toIEW->commitInfo[tid].freeROBEntries = rob->numFreeEntries(tid); 780 781 if (rob->isEmpty(tid)) { 782 toIEW->commitInfo[tid].emptyROB = true; 783 } 784 785 wroteToTimeBuffer = true; 786 changedROBNumEntries[tid] = false; 787 } 788 } 789} 790 791template <class Impl> 792void 793DefaultCommit<Impl>::commitInsts() 794{ 795 //////////////////////////////////// 796 // Handle commit 797 // Note that commit will be handled prior to putting new 798 // instructions in the ROB so that the ROB only tries to commit 799 // instructions it has in this current cycle, and not instructions 800 // it is writing in during this cycle. Can't commit and squash 801 // things at the same time... 802 //////////////////////////////////// 803 804 DPRINTF(Commit, "Trying to commit instructions in the ROB.\n"); 805 806 unsigned num_committed = 0; 807 808 DynInstPtr head_inst; 809 810 // Commit as many instructions as possible until the commit bandwidth 811 // limit is reached, or it becomes impossible to commit any more. 812 while (num_committed < commitWidth) { 813 int commit_thread = getCommittingThread(); 814 815 if (commit_thread == -1 || !rob->isHeadReady(commit_thread)) 816 break; 817 818 head_inst = rob->readHeadInst(commit_thread); 819 820 int tid = head_inst->threadNumber; 821 822 assert(tid == commit_thread); 823 824 DPRINTF(Commit, "Trying to commit head instruction, [sn:%i] [tid:%i]\n", 825 head_inst->seqNum, tid); 826 827 // If the head instruction is squashed, it is ready to retire 828 // (be removed from the ROB) at any time. 829 if (head_inst->isSquashed()) { 830 831 DPRINTF(Commit, "Retiring squashed instruction from " 832 "ROB.\n"); 833 834 rob->retireHead(commit_thread); 835 836 ++commitSquashedInsts; 837 838 // Record that the number of ROB entries has changed. 839 changedROBNumEntries[tid] = true; 840 } else { 841 PC[tid] = head_inst->readPC(); 842 nextPC[tid] = head_inst->readNextPC(); 843 844 // Increment the total number of non-speculative instructions 845 // executed. 846 // Hack for now: it really shouldn't happen until after the 847 // commit is deemed to be successful, but this count is needed 848 // for syscalls. 849 thread[tid]->funcExeInst++; 850 851 // Try to commit the head instruction. 852 bool commit_success = commitHead(head_inst, num_committed); 853 854 if (commit_success) { 855 ++num_committed; 856 857 changedROBNumEntries[tid] = true; 858 859 // Set the doneSeqNum to the youngest committed instruction. 860 toIEW->commitInfo[tid].doneSeqNum = head_inst->seqNum; 861 862 ++commitCommittedInsts; 863 864 // To match the old model, don't count nops and instruction 865 // prefetches towards the total commit count. 866 if (!head_inst->isNop() && !head_inst->isInstPrefetch()) { 867 cpu->instDone(tid); 868 } 869 870 PC[tid] = nextPC[tid]; 871 nextPC[tid] = nextPC[tid] + sizeof(TheISA::MachInst); 872#if FULL_SYSTEM 873 int count = 0; 874 Addr oldpc; 875 do { 876 // Debug statement. Checks to make sure we're not 877 // currently updating state while handling PC events. 878 if (count == 0) 879 assert(!thread[tid]->inSyscall && 880 !thread[tid]->trapPending); 881 oldpc = PC[tid]; 882 cpu->system->pcEventQueue.service( 883 thread[tid]->getTC()); 884 count++; 885 } while (oldpc != PC[tid]); 886 if (count > 1) { 887 DPRINTF(Commit, "PC skip function event, stopping commit\n"); 888 break; 889 } 890#endif 891 } else { 892 DPRINTF(Commit, "Unable to commit head instruction PC:%#x " 893 "[tid:%i] [sn:%i].\n", 894 head_inst->readPC(), tid ,head_inst->seqNum); 895 break; 896 } 897 } 898 } 899 900 DPRINTF(CommitRate, "%i\n", num_committed); 901 numCommittedDist.sample(num_committed); 902 903 if (num_committed == commitWidth) { 904 commitEligibleSamples++; 905 } 906} 907 908template <class Impl> 909bool 910DefaultCommit<Impl>::commitHead(DynInstPtr &head_inst, unsigned inst_num) 911{ 912 assert(head_inst); 913 914 int tid = head_inst->threadNumber; 915 916 // If the instruction is not executed yet, then it will need extra 917 // handling. Signal backwards that it should be executed. 918 if (!head_inst->isExecuted()) { 919 // Keep this number correct. We have not yet actually executed 920 // and committed this instruction. 921 thread[tid]->funcExeInst--; 922 923 head_inst->setAtCommit(); 924 925 if (head_inst->isNonSpeculative() || 926 head_inst->isStoreConditional() || 927 head_inst->isMemBarrier() || 928 head_inst->isWriteBarrier()) { 929 930 DPRINTF(Commit, "Encountered a barrier or non-speculative " 931 "instruction [sn:%lli] at the head of the ROB, PC %#x.\n", 932 head_inst->seqNum, head_inst->readPC()); 933 934#if !FULL_SYSTEM 935 // Hack to make sure syscalls/memory barriers/quiesces 936 // aren't executed until all stores write back their data. 937 // This direct communication shouldn't be used for 938 // anything other than this. 939 if (inst_num > 0 || iewStage->hasStoresToWB()) 940#else 941 if ((head_inst->isMemBarrier() || head_inst->isWriteBarrier() || 942 head_inst->isQuiesce()) && 943 iewStage->hasStoresToWB()) 944#endif 945 { 946 DPRINTF(Commit, "Waiting for all stores to writeback.\n"); 947 return false; 948 } 949 950 toIEW->commitInfo[tid].nonSpecSeqNum = head_inst->seqNum; 951 952 // Change the instruction so it won't try to commit again until 953 // it is executed. 954 head_inst->clearCanCommit(); 955 956 ++commitNonSpecStalls; 957 958 return false; 959 } else if (head_inst->isLoad()) { 960 DPRINTF(Commit, "[sn:%lli]: Uncached load, PC %#x.\n", 961 head_inst->seqNum, head_inst->readPC()); 962 963 // Send back the non-speculative instruction's sequence 964 // number. Tell the lsq to re-execute the load. 965 toIEW->commitInfo[tid].nonSpecSeqNum = head_inst->seqNum; 966 toIEW->commitInfo[tid].uncached = true; 967 toIEW->commitInfo[tid].uncachedLoad = head_inst; 968 969 head_inst->clearCanCommit(); 970 971 return false; 972 } else { 973 panic("Trying to commit un-executed instruction " 974 "of unknown type!\n"); 975 } 976 } 977 978 if (head_inst->isThreadSync()) { 979 // Not handled for now. 980 panic("Thread sync instructions are not handled yet.\n"); 981 } 982 983 // Stores mark themselves as completed. 984 if (!head_inst->isStore()) { 985 head_inst->setCompleted(); 986 } 987 988#if USE_CHECKER 989 // Use checker prior to updating anything due to traps or PC 990 // based events. 991 if (cpu->checker) { 992 cpu->checker->verify(head_inst); 993 } 994#endif 995 996 // Check if the instruction caused a fault. If so, trap. 997 Fault inst_fault = head_inst->getFault(); 998 999 if (inst_fault != NoFault) { 1000 head_inst->setCompleted(); 1001 DPRINTF(Commit, "Inst [sn:%lli] PC %#x has a fault\n", 1002 head_inst->seqNum, head_inst->readPC()); 1003 1004 if (iewStage->hasStoresToWB() || inst_num > 0) { 1005 DPRINTF(Commit, "Stores outstanding, fault must wait.\n"); 1006 return false; 1007 } 1008 1009#if USE_CHECKER 1010 if (cpu->checker && head_inst->isStore()) { 1011 cpu->checker->verify(head_inst); 1012 } 1013#endif 1014 1015 assert(!thread[tid]->inSyscall); 1016 1017 // Mark that we're in state update mode so that the trap's 1018 // execution doesn't generate extra squashes. 1019 thread[tid]->inSyscall = true; 1020 1021 // DTB will sometimes need the machine instruction for when 1022 // faults happen. So we will set it here, prior to the DTB 1023 // possibly needing it for its fault. 1024 thread[tid]->setInst( 1025 static_cast<TheISA::MachInst>(head_inst->staticInst->machInst)); 1026 1027 // Execute the trap. Although it's slightly unrealistic in 1028 // terms of timing (as it doesn't wait for the full timing of 1029 // the trap event to complete before updating state), it's 1030 // needed to update the state as soon as possible. This 1031 // prevents external agents from changing any specific state 1032 // that the trap need. 1033 cpu->trap(inst_fault, tid); 1034 1035 // Exit state update mode to avoid accidental updating. 1036 thread[tid]->inSyscall = false; 1037 1038 commitStatus[tid] = TrapPending; 1039 1040 // Generate trap squash event. 1041 generateTrapEvent(tid); 1042 1043 return false; 1044 } 1045 1046 updateComInstStats(head_inst); 1047 1048 if (head_inst->traceData) { 1049 head_inst->traceData->setFetchSeq(head_inst->seqNum); 1050 head_inst->traceData->setCPSeq(thread[tid]->numInst); 1051 head_inst->traceData->finalize(); 1052 head_inst->traceData = NULL; 1053 } 1054 1055 // Update the commit rename map 1056 for (int i = 0; i < head_inst->numDestRegs(); i++) { 1057 renameMap[tid]->setEntry(head_inst->destRegIdx(i), 1058 head_inst->renamedDestRegIdx(i)); 1059 } 1060 1061 // Finally clear the head ROB entry. 1062 rob->retireHead(tid); 1063 1064 // Return true to indicate that we have committed an instruction. 1065 return true; 1066} 1067 1068template <class Impl> 1069void 1070DefaultCommit<Impl>::getInsts() 1071{ 1072 // Read any renamed instructions and place them into the ROB. 1073 int insts_to_process = min((int)renameWidth, fromRename->size); 1074 1075 for (int inst_num = 0; inst_num < insts_to_process; ++inst_num) 1076 { 1077 DynInstPtr inst = fromRename->insts[inst_num]; 1078 int tid = inst->threadNumber; 1079 1080 if (!inst->isSquashed() && 1081 commitStatus[tid] != ROBSquashing) { 1082 changedROBNumEntries[tid] = true; 1083 1084 DPRINTF(Commit, "Inserting PC %#x [sn:%i] [tid:%i] into ROB.\n", 1085 inst->readPC(), inst->seqNum, tid); 1086 1087 rob->insertInst(inst); 1088 1089 assert(rob->getThreadEntries(tid) <= rob->getMaxEntries(tid)); 1090 1091 youngestSeqNum[tid] = inst->seqNum; 1092 } else { 1093 DPRINTF(Commit, "Instruction PC %#x [sn:%i] [tid:%i] was " 1094 "squashed, skipping.\n", 1095 inst->readPC(), inst->seqNum, tid); 1096 } 1097 } 1098} 1099 1100template <class Impl> 1101void 1102DefaultCommit<Impl>::markCompletedInsts() 1103{ 1104 // Grab completed insts out of the IEW instruction queue, and mark 1105 // instructions completed within the ROB. 1106 for (int inst_num = 0; 1107 inst_num < fromIEW->size && fromIEW->insts[inst_num]; 1108 ++inst_num) 1109 { 1110 if (!fromIEW->insts[inst_num]->isSquashed()) { 1111 DPRINTF(Commit, "[tid:%i]: Marking PC %#x, [sn:%lli] ready " 1112 "within ROB.\n", 1113 fromIEW->insts[inst_num]->threadNumber, 1114 fromIEW->insts[inst_num]->readPC(), 1115 fromIEW->insts[inst_num]->seqNum); 1116 1117 // Mark the instruction as ready to commit. 1118 fromIEW->insts[inst_num]->setCanCommit(); 1119 } 1120 } 1121} 1122 1123template <class Impl> 1124bool 1125DefaultCommit<Impl>::robDoneSquashing() 1126{ 1127 list<unsigned>::iterator threads = (*activeThreads).begin(); 1128 1129 while (threads != (*activeThreads).end()) { 1130 unsigned tid = *threads++; 1131 1132 if (!rob->isDoneSquashing(tid)) 1133 return false; 1134 } 1135 1136 return true; 1137} 1138 1139template <class Impl> 1140void 1141DefaultCommit<Impl>::updateComInstStats(DynInstPtr &inst) 1142{ 1143 unsigned thread = inst->threadNumber; 1144 1145 // 1146 // Pick off the software prefetches 1147 // 1148#ifdef TARGET_ALPHA 1149 if (inst->isDataPrefetch()) { 1150 statComSwp[thread]++; 1151 } else { 1152 statComInst[thread]++; 1153 } 1154#else 1155 statComInst[thread]++; 1156#endif 1157 1158 // 1159 // Control Instructions 1160 // 1161 if (inst->isControl()) 1162 statComBranches[thread]++; 1163 1164 // 1165 // Memory references 1166 // 1167 if (inst->isMemRef()) { 1168 statComRefs[thread]++; 1169 1170 if (inst->isLoad()) { 1171 statComLoads[thread]++; 1172 } 1173 } 1174 1175 if (inst->isMemBarrier()) { 1176 statComMembars[thread]++; 1177 } 1178} 1179 1180//////////////////////////////////////// 1181// // 1182// SMT COMMIT POLICY MAINTAINED HERE // 1183// // 1184//////////////////////////////////////// 1185template <class Impl> 1186int 1187DefaultCommit<Impl>::getCommittingThread() 1188{ 1189 if (numThreads > 1) { 1190 switch (commitPolicy) { 1191 1192 case Aggressive: 1193 //If Policy is Aggressive, commit will call 1194 //this function multiple times per 1195 //cycle 1196 return oldestReady(); 1197 1198 case RoundRobin: 1199 return roundRobin(); 1200 1201 case OldestReady: 1202 return oldestReady(); 1203 1204 default: 1205 return -1; 1206 } 1207 } else { 1208 int tid = (*activeThreads).front(); 1209 1210 if (commitStatus[tid] == Running || 1211 commitStatus[tid] == Idle || 1212 commitStatus[tid] == FetchTrapPending) { 1213 return tid; 1214 } else { 1215 return -1; 1216 } 1217 } 1218} 1219 1220template<class Impl> 1221int 1222DefaultCommit<Impl>::roundRobin() 1223{ 1224 list<unsigned>::iterator pri_iter = priority_list.begin(); 1225 list<unsigned>::iterator end = priority_list.end(); 1226 1227 while (pri_iter != end) { 1228 unsigned tid = *pri_iter; 1229 1230 if (commitStatus[tid] == Running || 1231 commitStatus[tid] == Idle || 1232 commitStatus[tid] == FetchTrapPending) { 1233 1234 if (rob->isHeadReady(tid)) { 1235 priority_list.erase(pri_iter); 1236 priority_list.push_back(tid); 1237 1238 return tid; 1239 } 1240 } 1241 1242 pri_iter++; 1243 } 1244 1245 return -1; 1246} 1247 1248template<class Impl> 1249int 1250DefaultCommit<Impl>::oldestReady() 1251{ 1252 unsigned oldest = 0; 1253 bool first = true; 1254 1255 list<unsigned>::iterator threads = (*activeThreads).begin(); 1256 1257 while (threads != (*activeThreads).end()) { 1258 unsigned tid = *threads++; 1259 1260 if (!rob->isEmpty(tid) && 1261 (commitStatus[tid] == Running || 1262 commitStatus[tid] == Idle || 1263 commitStatus[tid] == FetchTrapPending)) { 1264 1265 if (rob->isHeadReady(tid)) { 1266 1267 DynInstPtr head_inst = rob->readHeadInst(tid); 1268 1269 if (first) { 1270 oldest = tid; 1271 first = false; 1272 } else if (head_inst->seqNum < oldest) { 1273 oldest = tid; 1274 } 1275 } 1276 } 1277 } 1278 1279 if (!first) { 1280 return oldest; 1281 } else { 1282 return -1; 1283 } 1284}
| 365} 366 367template <class Impl> 368void 369DefaultCommit<Impl>::switchOut() 370{ 371 switchedOut = true; 372 drainPending = false; 373 rob->switchOut(); 374} 375 376template <class Impl> 377void 378DefaultCommit<Impl>::resume() 379{ 380} 381 382template <class Impl> 383void 384DefaultCommit<Impl>::takeOverFrom() 385{ 386 switchedOut = false; 387 _status = Active; 388 _nextStatus = Inactive; 389 for (int i=0; i < numThreads; i++) { 390 commitStatus[i] = Idle; 391 changedROBNumEntries[i] = false; 392 trapSquash[i] = false; 393 tcSquash[i] = false; 394 } 395 squashCounter = 0; 396 rob->takeOverFrom(); 397} 398 399template <class Impl> 400void 401DefaultCommit<Impl>::updateStatus() 402{ 403 // reset ROB changed variable 404 list<unsigned>::iterator threads = (*activeThreads).begin(); 405 while (threads != (*activeThreads).end()) { 406 unsigned tid = *threads++; 407 changedROBNumEntries[tid] = false; 408 409 // Also check if any of the threads has a trap pending 410 if (commitStatus[tid] == TrapPending || 411 commitStatus[tid] == FetchTrapPending) { 412 _nextStatus = Active; 413 } 414 } 415 416 if (_nextStatus == Inactive && _status == Active) { 417 DPRINTF(Activity, "Deactivating stage.\n"); 418 cpu->deactivateStage(O3CPU::CommitIdx); 419 } else if (_nextStatus == Active && _status == Inactive) { 420 DPRINTF(Activity, "Activating stage.\n"); 421 cpu->activateStage(O3CPU::CommitIdx); 422 } 423 424 _status = _nextStatus; 425} 426 427template <class Impl> 428void 429DefaultCommit<Impl>::setNextStatus() 430{ 431 int squashes = 0; 432 433 list<unsigned>::iterator threads = (*activeThreads).begin(); 434 435 while (threads != (*activeThreads).end()) { 436 unsigned tid = *threads++; 437 438 if (commitStatus[tid] == ROBSquashing) { 439 squashes++; 440 } 441 } 442 443 squashCounter = squashes; 444 445 // If commit is currently squashing, then it will have activity for the 446 // next cycle. Set its next status as active. 447 if (squashCounter) { 448 _nextStatus = Active; 449 } 450} 451 452template <class Impl> 453bool 454DefaultCommit<Impl>::changedROBEntries() 455{ 456 list<unsigned>::iterator threads = (*activeThreads).begin(); 457 458 while (threads != (*activeThreads).end()) { 459 unsigned tid = *threads++; 460 461 if (changedROBNumEntries[tid]) { 462 return true; 463 } 464 } 465 466 return false; 467} 468 469template <class Impl> 470unsigned 471DefaultCommit<Impl>::numROBFreeEntries(unsigned tid) 472{ 473 return rob->numFreeEntries(tid); 474} 475 476template <class Impl> 477void 478DefaultCommit<Impl>::generateTrapEvent(unsigned tid) 479{ 480 DPRINTF(Commit, "Generating trap event for [tid:%i]\n", tid); 481 482 TrapEvent *trap = new TrapEvent(this, tid); 483 484 trap->schedule(curTick + trapLatency); 485 486 thread[tid]->trapPending = true; 487} 488 489template <class Impl> 490void 491DefaultCommit<Impl>::generateTCEvent(unsigned tid) 492{ 493 DPRINTF(Commit, "Generating TC squash event for [tid:%i]\n", tid); 494 495 tcSquash[tid] = true; 496} 497 498template <class Impl> 499void 500DefaultCommit<Impl>::squashAll(unsigned tid) 501{ 502 // If we want to include the squashing instruction in the squash, 503 // then use one older sequence number. 504 // Hopefully this doesn't mess things up. Basically I want to squash 505 // all instructions of this thread. 506 InstSeqNum squashed_inst = rob->isEmpty() ? 507 0 : rob->readHeadInst(tid)->seqNum - 1;; 508 509 // All younger instructions will be squashed. Set the sequence 510 // number as the youngest instruction in the ROB (0 in this case. 511 // Hopefully nothing breaks.) 512 youngestSeqNum[tid] = 0; 513 514 rob->squash(squashed_inst, tid); 515 changedROBNumEntries[tid] = true; 516 517 // Send back the sequence number of the squashed instruction. 518 toIEW->commitInfo[tid].doneSeqNum = squashed_inst; 519 520 // Send back the squash signal to tell stages that they should 521 // squash. 522 toIEW->commitInfo[tid].squash = true; 523 524 // Send back the rob squashing signal so other stages know that 525 // the ROB is in the process of squashing. 526 toIEW->commitInfo[tid].robSquashing = true; 527 528 toIEW->commitInfo[tid].branchMispredict = false; 529 530 toIEW->commitInfo[tid].nextPC = PC[tid]; 531} 532 533template <class Impl> 534void 535DefaultCommit<Impl>::squashFromTrap(unsigned tid) 536{ 537 squashAll(tid); 538 539 DPRINTF(Commit, "Squashing from trap, restarting at PC %#x\n", PC[tid]); 540 541 thread[tid]->trapPending = false; 542 thread[tid]->inSyscall = false; 543 544 trapSquash[tid] = false; 545 546 commitStatus[tid] = ROBSquashing; 547 cpu->activityThisCycle(); 548} 549 550template <class Impl> 551void 552DefaultCommit<Impl>::squashFromTC(unsigned tid) 553{ 554 squashAll(tid); 555 556 DPRINTF(Commit, "Squashing from TC, restarting at PC %#x\n", PC[tid]); 557 558 thread[tid]->inSyscall = false; 559 assert(!thread[tid]->trapPending); 560 561 commitStatus[tid] = ROBSquashing; 562 cpu->activityThisCycle(); 563 564 tcSquash[tid] = false; 565} 566 567template <class Impl> 568void 569DefaultCommit<Impl>::tick() 570{ 571 wroteToTimeBuffer = false; 572 _nextStatus = Inactive; 573 574 if (drainPending && rob->isEmpty() && !iewStage->hasStoresToWB()) { 575 cpu->signalDrained(); 576 drainPending = false; 577 return; 578 } 579 580 list<unsigned>::iterator threads = (*activeThreads).begin(); 581 582 // Check if any of the threads are done squashing. Change the 583 // status if they are done. 584 while (threads != (*activeThreads).end()) { 585 unsigned tid = *threads++; 586 587 if (commitStatus[tid] == ROBSquashing) { 588 589 if (rob->isDoneSquashing(tid)) { 590 commitStatus[tid] = Running; 591 } else { 592 DPRINTF(Commit,"[tid:%u]: Still Squashing, cannot commit any" 593 "insts this cycle.\n", tid); 594 rob->doSquash(tid); 595 toIEW->commitInfo[tid].robSquashing = true; 596 wroteToTimeBuffer = true; 597 } 598 } 599 } 600 601 commit(); 602 603 markCompletedInsts(); 604 605 threads = (*activeThreads).begin(); 606 607 while (threads != (*activeThreads).end()) { 608 unsigned tid = *threads++; 609 610 if (!rob->isEmpty(tid) && rob->readHeadInst(tid)->readyToCommit()) { 611 // The ROB has more instructions it can commit. Its next status 612 // will be active. 613 _nextStatus = Active; 614 615 DynInstPtr inst = rob->readHeadInst(tid); 616 617 DPRINTF(Commit,"[tid:%i]: Instruction [sn:%lli] PC %#x is head of" 618 " ROB and ready to commit\n", 619 tid, inst->seqNum, inst->readPC()); 620 621 } else if (!rob->isEmpty(tid)) { 622 DynInstPtr inst = rob->readHeadInst(tid); 623 624 DPRINTF(Commit,"[tid:%i]: Can't commit, Instruction [sn:%lli] PC " 625 "%#x is head of ROB and not ready\n", 626 tid, inst->seqNum, inst->readPC()); 627 } 628 629 DPRINTF(Commit, "[tid:%i]: ROB has %d insts & %d free entries.\n", 630 tid, rob->countInsts(tid), rob->numFreeEntries(tid)); 631 } 632 633 634 if (wroteToTimeBuffer) { 635 DPRINTF(Activity, "Activity This Cycle.\n"); 636 cpu->activityThisCycle(); 637 } 638 639 updateStatus(); 640} 641 642template <class Impl> 643void 644DefaultCommit<Impl>::commit() 645{ 646 647 ////////////////////////////////////// 648 // Check for interrupts 649 ////////////////////////////////////// 650 651#if FULL_SYSTEM 652 // Process interrupts if interrupts are enabled, not in PAL mode, 653 // and no other traps or external squashes are currently pending. 654 // @todo: Allow other threads to handle interrupts. 655 if (cpu->checkInterrupts && 656 cpu->check_interrupts() && 657 !cpu->inPalMode(readPC()) && 658 !trapSquash[0] && 659 !tcSquash[0]) { 660 // Tell fetch that there is an interrupt pending. This will 661 // make fetch wait until it sees a non PAL-mode PC, at which 662 // point it stops fetching instructions. 663 toIEW->commitInfo[0].interruptPending = true; 664 665 // Wait until the ROB is empty and all stores have drained in 666 // order to enter the interrupt. 667 if (rob->isEmpty() && !iewStage->hasStoresToWB()) { 668 // Not sure which thread should be the one to interrupt. For now 669 // always do thread 0. 670 assert(!thread[0]->inSyscall); 671 thread[0]->inSyscall = true; 672 673 // CPU will handle implementation of the interrupt. 674 cpu->processInterrupts(); 675 676 // Now squash or record that I need to squash this cycle. 677 commitStatus[0] = TrapPending; 678 679 // Exit state update mode to avoid accidental updating. 680 thread[0]->inSyscall = false; 681 682 // Generate trap squash event. 683 generateTrapEvent(0); 684 685 toIEW->commitInfo[0].clearInterrupt = true; 686 687 DPRINTF(Commit, "Interrupt detected.\n"); 688 } else { 689 DPRINTF(Commit, "Interrupt pending, waiting for ROB to empty.\n"); 690 } 691 } 692#endif // FULL_SYSTEM 693 694 //////////////////////////////////// 695 // Check for any possible squashes, handle them first 696 //////////////////////////////////// 697 698 list<unsigned>::iterator threads = (*activeThreads).begin(); 699 700 while (threads != (*activeThreads).end()) { 701 unsigned tid = *threads++; 702 703 // Not sure which one takes priority. I think if we have 704 // both, that's a bad sign. 705 if (trapSquash[tid] == true) { 706 assert(!tcSquash[tid]); 707 squashFromTrap(tid); 708 } else if (tcSquash[tid] == true) { 709 squashFromTC(tid); 710 } 711 712 // Squashed sequence number must be older than youngest valid 713 // instruction in the ROB. This prevents squashes from younger 714 // instructions overriding squashes from older instructions. 715 if (fromIEW->squash[tid] && 716 commitStatus[tid] != TrapPending && 717 fromIEW->squashedSeqNum[tid] <= youngestSeqNum[tid]) { 718 719 DPRINTF(Commit, "[tid:%i]: Squashing due to PC %#x [sn:%i]\n", 720 tid, 721 fromIEW->mispredPC[tid], 722 fromIEW->squashedSeqNum[tid]); 723 724 DPRINTF(Commit, "[tid:%i]: Redirecting to PC %#x\n", 725 tid, 726 fromIEW->nextPC[tid]); 727 728 commitStatus[tid] = ROBSquashing; 729 730 // If we want to include the squashing instruction in the squash, 731 // then use one older sequence number. 732 InstSeqNum squashed_inst = fromIEW->squashedSeqNum[tid]; 733 734 if (fromIEW->includeSquashInst[tid] == true) 735 squashed_inst--; 736 737 // All younger instructions will be squashed. Set the sequence 738 // number as the youngest instruction in the ROB. 739 youngestSeqNum[tid] = squashed_inst; 740 741 rob->squash(squashed_inst, tid); 742 changedROBNumEntries[tid] = true; 743 744 toIEW->commitInfo[tid].doneSeqNum = squashed_inst; 745 746 toIEW->commitInfo[tid].squash = true; 747 748 // Send back the rob squashing signal so other stages know that 749 // the ROB is in the process of squashing. 750 toIEW->commitInfo[tid].robSquashing = true; 751 752 toIEW->commitInfo[tid].branchMispredict = 753 fromIEW->branchMispredict[tid]; 754 755 toIEW->commitInfo[tid].branchTaken = 756 fromIEW->branchTaken[tid]; 757 758 toIEW->commitInfo[tid].nextPC = fromIEW->nextPC[tid]; 759 760 toIEW->commitInfo[tid].mispredPC = fromIEW->mispredPC[tid]; 761 762 if (toIEW->commitInfo[tid].branchMispredict) { 763 ++branchMispredicts; 764 } 765 } 766 767 } 768 769 setNextStatus(); 770 771 if (squashCounter != numThreads) { 772 // If we're not currently squashing, then get instructions. 773 getInsts(); 774 775 // Try to commit any instructions. 776 commitInsts(); 777 } 778 779 //Check for any activity 780 threads = (*activeThreads).begin(); 781 782 while (threads != (*activeThreads).end()) { 783 unsigned tid = *threads++; 784 785 if (changedROBNumEntries[tid]) { 786 toIEW->commitInfo[tid].usedROB = true; 787 toIEW->commitInfo[tid].freeROBEntries = rob->numFreeEntries(tid); 788 789 if (rob->isEmpty(tid)) { 790 toIEW->commitInfo[tid].emptyROB = true; 791 } 792 793 wroteToTimeBuffer = true; 794 changedROBNumEntries[tid] = false; 795 } 796 } 797} 798 799template <class Impl> 800void 801DefaultCommit<Impl>::commitInsts() 802{ 803 //////////////////////////////////// 804 // Handle commit 805 // Note that commit will be handled prior to putting new 806 // instructions in the ROB so that the ROB only tries to commit 807 // instructions it has in this current cycle, and not instructions 808 // it is writing in during this cycle. Can't commit and squash 809 // things at the same time... 810 //////////////////////////////////// 811 812 DPRINTF(Commit, "Trying to commit instructions in the ROB.\n"); 813 814 unsigned num_committed = 0; 815 816 DynInstPtr head_inst; 817 818 // Commit as many instructions as possible until the commit bandwidth 819 // limit is reached, or it becomes impossible to commit any more. 820 while (num_committed < commitWidth) { 821 int commit_thread = getCommittingThread(); 822 823 if (commit_thread == -1 || !rob->isHeadReady(commit_thread)) 824 break; 825 826 head_inst = rob->readHeadInst(commit_thread); 827 828 int tid = head_inst->threadNumber; 829 830 assert(tid == commit_thread); 831 832 DPRINTF(Commit, "Trying to commit head instruction, [sn:%i] [tid:%i]\n", 833 head_inst->seqNum, tid); 834 835 // If the head instruction is squashed, it is ready to retire 836 // (be removed from the ROB) at any time. 837 if (head_inst->isSquashed()) { 838 839 DPRINTF(Commit, "Retiring squashed instruction from " 840 "ROB.\n"); 841 842 rob->retireHead(commit_thread); 843 844 ++commitSquashedInsts; 845 846 // Record that the number of ROB entries has changed. 847 changedROBNumEntries[tid] = true; 848 } else { 849 PC[tid] = head_inst->readPC(); 850 nextPC[tid] = head_inst->readNextPC(); 851 852 // Increment the total number of non-speculative instructions 853 // executed. 854 // Hack for now: it really shouldn't happen until after the 855 // commit is deemed to be successful, but this count is needed 856 // for syscalls. 857 thread[tid]->funcExeInst++; 858 859 // Try to commit the head instruction. 860 bool commit_success = commitHead(head_inst, num_committed); 861 862 if (commit_success) { 863 ++num_committed; 864 865 changedROBNumEntries[tid] = true; 866 867 // Set the doneSeqNum to the youngest committed instruction. 868 toIEW->commitInfo[tid].doneSeqNum = head_inst->seqNum; 869 870 ++commitCommittedInsts; 871 872 // To match the old model, don't count nops and instruction 873 // prefetches towards the total commit count. 874 if (!head_inst->isNop() && !head_inst->isInstPrefetch()) { 875 cpu->instDone(tid); 876 } 877 878 PC[tid] = nextPC[tid]; 879 nextPC[tid] = nextPC[tid] + sizeof(TheISA::MachInst); 880#if FULL_SYSTEM 881 int count = 0; 882 Addr oldpc; 883 do { 884 // Debug statement. Checks to make sure we're not 885 // currently updating state while handling PC events. 886 if (count == 0) 887 assert(!thread[tid]->inSyscall && 888 !thread[tid]->trapPending); 889 oldpc = PC[tid]; 890 cpu->system->pcEventQueue.service( 891 thread[tid]->getTC()); 892 count++; 893 } while (oldpc != PC[tid]); 894 if (count > 1) { 895 DPRINTF(Commit, "PC skip function event, stopping commit\n"); 896 break; 897 } 898#endif 899 } else { 900 DPRINTF(Commit, "Unable to commit head instruction PC:%#x " 901 "[tid:%i] [sn:%i].\n", 902 head_inst->readPC(), tid ,head_inst->seqNum); 903 break; 904 } 905 } 906 } 907 908 DPRINTF(CommitRate, "%i\n", num_committed); 909 numCommittedDist.sample(num_committed); 910 911 if (num_committed == commitWidth) { 912 commitEligibleSamples++; 913 } 914} 915 916template <class Impl> 917bool 918DefaultCommit<Impl>::commitHead(DynInstPtr &head_inst, unsigned inst_num) 919{ 920 assert(head_inst); 921 922 int tid = head_inst->threadNumber; 923 924 // If the instruction is not executed yet, then it will need extra 925 // handling. Signal backwards that it should be executed. 926 if (!head_inst->isExecuted()) { 927 // Keep this number correct. We have not yet actually executed 928 // and committed this instruction. 929 thread[tid]->funcExeInst--; 930 931 head_inst->setAtCommit(); 932 933 if (head_inst->isNonSpeculative() || 934 head_inst->isStoreConditional() || 935 head_inst->isMemBarrier() || 936 head_inst->isWriteBarrier()) { 937 938 DPRINTF(Commit, "Encountered a barrier or non-speculative " 939 "instruction [sn:%lli] at the head of the ROB, PC %#x.\n", 940 head_inst->seqNum, head_inst->readPC()); 941 942#if !FULL_SYSTEM 943 // Hack to make sure syscalls/memory barriers/quiesces 944 // aren't executed until all stores write back their data. 945 // This direct communication shouldn't be used for 946 // anything other than this. 947 if (inst_num > 0 || iewStage->hasStoresToWB()) 948#else 949 if ((head_inst->isMemBarrier() || head_inst->isWriteBarrier() || 950 head_inst->isQuiesce()) && 951 iewStage->hasStoresToWB()) 952#endif 953 { 954 DPRINTF(Commit, "Waiting for all stores to writeback.\n"); 955 return false; 956 } 957 958 toIEW->commitInfo[tid].nonSpecSeqNum = head_inst->seqNum; 959 960 // Change the instruction so it won't try to commit again until 961 // it is executed. 962 head_inst->clearCanCommit(); 963 964 ++commitNonSpecStalls; 965 966 return false; 967 } else if (head_inst->isLoad()) { 968 DPRINTF(Commit, "[sn:%lli]: Uncached load, PC %#x.\n", 969 head_inst->seqNum, head_inst->readPC()); 970 971 // Send back the non-speculative instruction's sequence 972 // number. Tell the lsq to re-execute the load. 973 toIEW->commitInfo[tid].nonSpecSeqNum = head_inst->seqNum; 974 toIEW->commitInfo[tid].uncached = true; 975 toIEW->commitInfo[tid].uncachedLoad = head_inst; 976 977 head_inst->clearCanCommit(); 978 979 return false; 980 } else { 981 panic("Trying to commit un-executed instruction " 982 "of unknown type!\n"); 983 } 984 } 985 986 if (head_inst->isThreadSync()) { 987 // Not handled for now. 988 panic("Thread sync instructions are not handled yet.\n"); 989 } 990 991 // Stores mark themselves as completed. 992 if (!head_inst->isStore()) { 993 head_inst->setCompleted(); 994 } 995 996#if USE_CHECKER 997 // Use checker prior to updating anything due to traps or PC 998 // based events. 999 if (cpu->checker) { 1000 cpu->checker->verify(head_inst); 1001 } 1002#endif 1003 1004 // Check if the instruction caused a fault. If so, trap. 1005 Fault inst_fault = head_inst->getFault(); 1006 1007 if (inst_fault != NoFault) { 1008 head_inst->setCompleted(); 1009 DPRINTF(Commit, "Inst [sn:%lli] PC %#x has a fault\n", 1010 head_inst->seqNum, head_inst->readPC()); 1011 1012 if (iewStage->hasStoresToWB() || inst_num > 0) { 1013 DPRINTF(Commit, "Stores outstanding, fault must wait.\n"); 1014 return false; 1015 } 1016 1017#if USE_CHECKER 1018 if (cpu->checker && head_inst->isStore()) { 1019 cpu->checker->verify(head_inst); 1020 } 1021#endif 1022 1023 assert(!thread[tid]->inSyscall); 1024 1025 // Mark that we're in state update mode so that the trap's 1026 // execution doesn't generate extra squashes. 1027 thread[tid]->inSyscall = true; 1028 1029 // DTB will sometimes need the machine instruction for when 1030 // faults happen. So we will set it here, prior to the DTB 1031 // possibly needing it for its fault. 1032 thread[tid]->setInst( 1033 static_cast<TheISA::MachInst>(head_inst->staticInst->machInst)); 1034 1035 // Execute the trap. Although it's slightly unrealistic in 1036 // terms of timing (as it doesn't wait for the full timing of 1037 // the trap event to complete before updating state), it's 1038 // needed to update the state as soon as possible. This 1039 // prevents external agents from changing any specific state 1040 // that the trap need. 1041 cpu->trap(inst_fault, tid); 1042 1043 // Exit state update mode to avoid accidental updating. 1044 thread[tid]->inSyscall = false; 1045 1046 commitStatus[tid] = TrapPending; 1047 1048 // Generate trap squash event. 1049 generateTrapEvent(tid); 1050 1051 return false; 1052 } 1053 1054 updateComInstStats(head_inst); 1055 1056 if (head_inst->traceData) { 1057 head_inst->traceData->setFetchSeq(head_inst->seqNum); 1058 head_inst->traceData->setCPSeq(thread[tid]->numInst); 1059 head_inst->traceData->finalize(); 1060 head_inst->traceData = NULL; 1061 } 1062 1063 // Update the commit rename map 1064 for (int i = 0; i < head_inst->numDestRegs(); i++) { 1065 renameMap[tid]->setEntry(head_inst->destRegIdx(i), 1066 head_inst->renamedDestRegIdx(i)); 1067 } 1068 1069 // Finally clear the head ROB entry. 1070 rob->retireHead(tid); 1071 1072 // Return true to indicate that we have committed an instruction. 1073 return true; 1074} 1075 1076template <class Impl> 1077void 1078DefaultCommit<Impl>::getInsts() 1079{ 1080 // Read any renamed instructions and place them into the ROB. 1081 int insts_to_process = min((int)renameWidth, fromRename->size); 1082 1083 for (int inst_num = 0; inst_num < insts_to_process; ++inst_num) 1084 { 1085 DynInstPtr inst = fromRename->insts[inst_num]; 1086 int tid = inst->threadNumber; 1087 1088 if (!inst->isSquashed() && 1089 commitStatus[tid] != ROBSquashing) { 1090 changedROBNumEntries[tid] = true; 1091 1092 DPRINTF(Commit, "Inserting PC %#x [sn:%i] [tid:%i] into ROB.\n", 1093 inst->readPC(), inst->seqNum, tid); 1094 1095 rob->insertInst(inst); 1096 1097 assert(rob->getThreadEntries(tid) <= rob->getMaxEntries(tid)); 1098 1099 youngestSeqNum[tid] = inst->seqNum; 1100 } else { 1101 DPRINTF(Commit, "Instruction PC %#x [sn:%i] [tid:%i] was " 1102 "squashed, skipping.\n", 1103 inst->readPC(), inst->seqNum, tid); 1104 } 1105 } 1106} 1107 1108template <class Impl> 1109void 1110DefaultCommit<Impl>::markCompletedInsts() 1111{ 1112 // Grab completed insts out of the IEW instruction queue, and mark 1113 // instructions completed within the ROB. 1114 for (int inst_num = 0; 1115 inst_num < fromIEW->size && fromIEW->insts[inst_num]; 1116 ++inst_num) 1117 { 1118 if (!fromIEW->insts[inst_num]->isSquashed()) { 1119 DPRINTF(Commit, "[tid:%i]: Marking PC %#x, [sn:%lli] ready " 1120 "within ROB.\n", 1121 fromIEW->insts[inst_num]->threadNumber, 1122 fromIEW->insts[inst_num]->readPC(), 1123 fromIEW->insts[inst_num]->seqNum); 1124 1125 // Mark the instruction as ready to commit. 1126 fromIEW->insts[inst_num]->setCanCommit(); 1127 } 1128 } 1129} 1130 1131template <class Impl> 1132bool 1133DefaultCommit<Impl>::robDoneSquashing() 1134{ 1135 list<unsigned>::iterator threads = (*activeThreads).begin(); 1136 1137 while (threads != (*activeThreads).end()) { 1138 unsigned tid = *threads++; 1139 1140 if (!rob->isDoneSquashing(tid)) 1141 return false; 1142 } 1143 1144 return true; 1145} 1146 1147template <class Impl> 1148void 1149DefaultCommit<Impl>::updateComInstStats(DynInstPtr &inst) 1150{ 1151 unsigned thread = inst->threadNumber; 1152 1153 // 1154 // Pick off the software prefetches 1155 // 1156#ifdef TARGET_ALPHA 1157 if (inst->isDataPrefetch()) { 1158 statComSwp[thread]++; 1159 } else { 1160 statComInst[thread]++; 1161 } 1162#else 1163 statComInst[thread]++; 1164#endif 1165 1166 // 1167 // Control Instructions 1168 // 1169 if (inst->isControl()) 1170 statComBranches[thread]++; 1171 1172 // 1173 // Memory references 1174 // 1175 if (inst->isMemRef()) { 1176 statComRefs[thread]++; 1177 1178 if (inst->isLoad()) { 1179 statComLoads[thread]++; 1180 } 1181 } 1182 1183 if (inst->isMemBarrier()) { 1184 statComMembars[thread]++; 1185 } 1186} 1187 1188//////////////////////////////////////// 1189// // 1190// SMT COMMIT POLICY MAINTAINED HERE // 1191// // 1192//////////////////////////////////////// 1193template <class Impl> 1194int 1195DefaultCommit<Impl>::getCommittingThread() 1196{ 1197 if (numThreads > 1) { 1198 switch (commitPolicy) { 1199 1200 case Aggressive: 1201 //If Policy is Aggressive, commit will call 1202 //this function multiple times per 1203 //cycle 1204 return oldestReady(); 1205 1206 case RoundRobin: 1207 return roundRobin(); 1208 1209 case OldestReady: 1210 return oldestReady(); 1211 1212 default: 1213 return -1; 1214 } 1215 } else { 1216 int tid = (*activeThreads).front(); 1217 1218 if (commitStatus[tid] == Running || 1219 commitStatus[tid] == Idle || 1220 commitStatus[tid] == FetchTrapPending) { 1221 return tid; 1222 } else { 1223 return -1; 1224 } 1225 } 1226} 1227 1228template<class Impl> 1229int 1230DefaultCommit<Impl>::roundRobin() 1231{ 1232 list<unsigned>::iterator pri_iter = priority_list.begin(); 1233 list<unsigned>::iterator end = priority_list.end(); 1234 1235 while (pri_iter != end) { 1236 unsigned tid = *pri_iter; 1237 1238 if (commitStatus[tid] == Running || 1239 commitStatus[tid] == Idle || 1240 commitStatus[tid] == FetchTrapPending) { 1241 1242 if (rob->isHeadReady(tid)) { 1243 priority_list.erase(pri_iter); 1244 priority_list.push_back(tid); 1245 1246 return tid; 1247 } 1248 } 1249 1250 pri_iter++; 1251 } 1252 1253 return -1; 1254} 1255 1256template<class Impl> 1257int 1258DefaultCommit<Impl>::oldestReady() 1259{ 1260 unsigned oldest = 0; 1261 bool first = true; 1262 1263 list<unsigned>::iterator threads = (*activeThreads).begin(); 1264 1265 while (threads != (*activeThreads).end()) { 1266 unsigned tid = *threads++; 1267 1268 if (!rob->isEmpty(tid) && 1269 (commitStatus[tid] == Running || 1270 commitStatus[tid] == Idle || 1271 commitStatus[tid] == FetchTrapPending)) { 1272 1273 if (rob->isHeadReady(tid)) { 1274 1275 DynInstPtr head_inst = rob->readHeadInst(tid); 1276 1277 if (first) { 1278 oldest = tid; 1279 first = false; 1280 } else if (head_inst->seqNum < oldest) { 1281 oldest = tid; 1282 } 1283 } 1284 } 1285 } 1286 1287 if (!first) { 1288 return oldest; 1289 } else { 1290 return -1; 1291 } 1292}
|