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 --- 8 unchanged lines hidden (view full) --- 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 |
29#ifndef __CPU_O3_IEW_HH__ 30#define __CPU_O3_IEW_HH__ |
31 |
32#include <queue> 33 |
34#include "base/statistics.hh" 35#include "base/timebuf.hh" |
36#include "config/full_system.hh" |
37#include "cpu/o3/comm.hh" |
38#include "cpu/o3/scoreboard.hh" 39#include "cpu/o3/lsq.hh" |
40 |
41class FUPool; 42 43/** 44 * DefaultIEW handles both single threaded and SMT IEW 45 * (issue/execute/writeback). It handles the dispatching of 46 * instructions to the LSQ/IQ as part of the issue stage, and has the 47 * IQ try to issue instructions each cycle. The execute latency is 48 * actually tied into the issue latency to allow the IQ to be able to 49 * do back-to-back scheduling without having to speculatively schedule 50 * instructions. This happens by having the IQ have access to the 51 * functional units, and the IQ gets the execution latencies from the 52 * FUs when it issues instructions. Instructions reach the execute 53 * stage on the last cycle of their execution, which is when the IQ 54 * knows to wake up any dependent instructions, allowing back to back 55 * scheduling. The execute portion of IEW separates memory 56 * instructions from non-memory instructions, either telling the LSQ 57 * to execute the instruction, or executing the instruction directly. 58 * The writeback portion of IEW completes the instructions by waking 59 * up any dependents, and marking the register ready on the 60 * scoreboard. 61 */ |
62template<class Impl> |
63class DefaultIEW |
64{ 65 private: 66 //Typedefs from Impl 67 typedef typename Impl::CPUPol CPUPol; 68 typedef typename Impl::DynInstPtr DynInstPtr; 69 typedef typename Impl::FullCPU FullCPU; 70 typedef typename Impl::Params Params; 71 72 typedef typename CPUPol::IQ IQ; 73 typedef typename CPUPol::RenameMap RenameMap; |
74 typedef typename CPUPol::LSQ LSQ; |
75 76 typedef typename CPUPol::TimeStruct TimeStruct; 77 typedef typename CPUPol::IEWStruct IEWStruct; 78 typedef typename CPUPol::RenameStruct RenameStruct; 79 typedef typename CPUPol::IssueStruct IssueStruct; 80 81 friend class Impl::FullCPU; |
82 friend class CPUPol::IQ; 83 |
84 public: |
85 /** Overall IEW stage status. Used to determine if the CPU can 86 * deschedule itself due to a lack of activity. 87 */ |
88 enum Status { |
89 Active, 90 Inactive 91 }; 92 93 /** Status for Issue, Execute, and Writeback stages. */ 94 enum StageStatus { |
95 Running, 96 Blocked, 97 Idle, |
98 StartSquash, |
99 Squashing, 100 Unblocking 101 }; 102 103 private: |
104 /** Overall stage status. */ |
105 Status _status; |
106 /** Dispatch status. */ 107 StageStatus dispatchStatus[Impl::MaxThreads]; 108 /** Execute status. */ 109 StageStatus exeStatus; 110 /** Writeback status. */ 111 StageStatus wbStatus; |
112 113 public: |
114 /** Constructs a DefaultIEW with the given parameters. */ 115 DefaultIEW(Params *params); |
116 |
117 /** Returns the name of the DefaultIEW stage. */ 118 std::string name() const; |
119 |
120 /** Registers statistics. */ |
121 void regStats(); 122 |
123 /** Initializes stage; sends back the number of free IQ and LSQ entries. */ 124 void initStage(); 125 126 /** Sets CPU pointer for IEW, IQ, and LSQ. */ |
127 void setCPU(FullCPU *cpu_ptr); 128 |
129 /** Sets main time buffer used for backwards communication. */ |
130 void setTimeBuffer(TimeBuffer<TimeStruct> *tb_ptr); 131 |
132 /** Sets time buffer for getting instructions coming from rename. */ |
133 void setRenameQueue(TimeBuffer<RenameStruct> *rq_ptr); 134 |
135 /** Sets time buffer to pass on instructions to commit. */ |
136 void setIEWQueue(TimeBuffer<IEWStruct> *iq_ptr); 137 |
138 /** Sets pointer to list of active threads. */ 139 void setActiveThreads(std::list<unsigned> *at_ptr); |
140 |
141 /** Sets pointer to the scoreboard. */ 142 void setScoreboard(Scoreboard *sb_ptr); |
143 |
144 void switchOut(); |
145 |
146 void doSwitchOut(); |
147 |
148 void takeOverFrom(); |
149 |
150 bool isSwitchedOut() { return switchedOut; } |
151 |
152 /** Sets page table pointer within LSQ. */ 153// void setPageTable(PageTable *pt_ptr); 154 155 /** Squashes instructions in IEW for a specific thread. */ 156 void squash(unsigned tid); 157 158 /** Wakes all dependents of a completed instruction. */ |
159 void wakeDependents(DynInstPtr &inst); 160 |
161 /** Tells memory dependence unit that a memory instruction needs to be 162 * rescheduled. It will re-execute once replayMemInst() is called. 163 */ 164 void rescheduleMemInst(DynInstPtr &inst); 165 166 /** Re-executes all rescheduled memory instructions. */ 167 void replayMemInst(DynInstPtr &inst); 168 169 /** Sends an instruction to commit through the time buffer. */ |
170 void instToCommit(DynInstPtr &inst); 171 |
172 /** Inserts unused instructions of a thread into the skid buffer. */ 173 void skidInsert(unsigned tid); 174 175 /** Returns the max of the number of entries in all of the skid buffers. */ 176 int skidCount(); 177 178 /** Returns if all of the skid buffers are empty. */ 179 bool skidsEmpty(); 180 181 /** Updates overall IEW status based on all of the stages' statuses. */ 182 void updateStatus(); 183 184 /** Resets entries of the IQ and the LSQ. */ 185 void resetEntries(); 186 187 /** Tells the CPU to wakeup if it has descheduled itself due to no 188 * activity. Used mainly by the LdWritebackEvent. 189 */ 190 void wakeCPU(); 191 192 /** Reports to the CPU that there is activity this cycle. */ 193 void activityThisCycle(); 194 195 /** Tells CPU that the IEW stage is active and running. */ 196 inline void activateStage(); 197 198 /** Tells CPU that the IEW stage is inactive and idle. */ 199 inline void deactivateStage(); 200 201 /** Returns if the LSQ has any stores to writeback. */ 202 bool hasStoresToWB() { return ldstQueue.hasStoresToWB(); } 203 |
204 private: |
205 /** Sends commit proper information for a squash due to a branch 206 * mispredict. 207 */ 208 void squashDueToBranch(DynInstPtr &inst, unsigned thread_id); |
209 |
210 /** Sends commit proper information for a squash due to a memory order 211 * violation. 212 */ 213 void squashDueToMemOrder(DynInstPtr &inst, unsigned thread_id); 214 215 /** Sends commit proper information for a squash due to memory becoming 216 * blocked (younger issued instructions must be retried). 217 */ 218 void squashDueToMemBlocked(DynInstPtr &inst, unsigned thread_id); 219 220 /** Sets Dispatch to blocked, and signals back to other stages to block. */ 221 void block(unsigned thread_id); 222 223 /** Unblocks Dispatch if the skid buffer is empty, and signals back to 224 * other stages to unblock. 225 */ 226 void unblock(unsigned thread_id); 227 228 /** Determines proper actions to take given Dispatch's status. */ 229 void dispatch(unsigned tid); 230 231 /** Dispatches instructions to IQ and LSQ. */ 232 void dispatchInsts(unsigned tid); 233 234 /** Executes instructions. In the case of memory operations, it informs the 235 * LSQ to execute the instructions. Also handles any redirects that occur 236 * due to the executed instructions. 237 */ |
238 void executeInsts(); 239 |
240 /** Writebacks instructions. In our model, the instruction's execute() 241 * function atomically reads registers, executes, and writes registers. 242 * Thus this writeback only wakes up dependent instructions, and informs 243 * the scoreboard of registers becoming ready. 244 */ 245 void writebackInsts(); 246 247 /** Returns the number of valid, non-squashed instructions coming from 248 * rename to dispatch. 249 */ 250 unsigned validInstsFromRename(); 251 252 /** Reads the stall signals. */ 253 void readStallSignals(unsigned tid); 254 255 /** Checks if any of the stall conditions are currently true. */ 256 bool checkStall(unsigned tid); 257 258 /** Processes inputs and changes state accordingly. */ 259 void checkSignalsAndUpdate(unsigned tid); 260 261 /** Sorts instructions coming from rename into lists separated by thread. */ 262 void sortInsts(); 263 |
264 public: |
265 /** Ticks IEW stage, causing Dispatch, the IQ, the LSQ, Execute, and 266 * Writeback to run for one cycle. 267 */ |
268 void tick(); 269 |
270 private: 271 void updateExeInstStats(DynInstPtr &inst); |
272 |
273 /** Pointer to main time buffer used for backwards communication. */ |
274 TimeBuffer<TimeStruct> *timeBuffer; 275 |
276 /** Wire to write information heading to previous stages. */ 277 typename TimeBuffer<TimeStruct>::wire toFetch; 278 |
279 /** Wire to get commit's output from backwards time buffer. */ 280 typename TimeBuffer<TimeStruct>::wire fromCommit; 281 282 /** Wire to write information heading to previous stages. */ 283 typename TimeBuffer<TimeStruct>::wire toRename; 284 285 /** Rename instruction queue interface. */ 286 TimeBuffer<RenameStruct> *renameQueue; --- 11 unchanged lines hidden (view full) --- 298 * IEW stage time buffer. Holds ROB indices of instructions that 299 * can be marked as completed. 300 */ 301 TimeBuffer<IEWStruct> *iewQueue; 302 303 /** Wire to write infromation heading to commit. */ 304 typename TimeBuffer<IEWStruct>::wire toCommit; 305 |
306 /** Queue of all instructions coming from rename this cycle. */ 307 std::queue<DynInstPtr> insts[Impl::MaxThreads]; 308 |
309 /** Skid buffer between rename and IEW. */ |
310 std::queue<DynInstPtr> skidBuffer[Impl::MaxThreads]; |
311 |
312 /** Scoreboard pointer. */ 313 Scoreboard* scoreboard; 314 315 public: |
316 /** Instruction queue. */ 317 IQ instQueue; 318 |
319 /** Load / store queue. */ 320 LSQ ldstQueue; |
321 |
322 /** Pointer to the functional unit pool. */ 323 FUPool *fuPool; |
324 325 private: |
326 /** CPU pointer. */ 327 FullCPU *cpu; 328 329 /** Records if IEW has written to the time buffer this cycle, so that the 330 * CPU can deschedule itself if there is no activity. |
331 */ |
332 bool wroteToTimeBuffer; |
333 |
334 /** Source of possible stalls. */ 335 struct Stalls { 336 bool commit; 337 }; |
338 |
339 /** Stages that are telling IEW to stall. */ 340 Stalls stalls[Impl::MaxThreads]; 341 342 /** Debug function to print instructions that are issued this cycle. */ 343 void printAvailableInsts(); 344 345 public: 346 /** Records if the LSQ needs to be updated on the next cycle, so that 347 * IEW knows if there will be activity on the next cycle. 348 */ 349 bool updateLSQNextCycle; 350 |
351 private: |
352 /** Records if there is a fetch redirect on this cycle for each thread. */ 353 bool fetchRedirect[Impl::MaxThreads]; 354 355 /** Used to track if all instructions have been dispatched this cycle. 356 * If they have not, then blocking must have occurred, and the instructions 357 * would already be added to the skid buffer. 358 * @todo: Fix this hack. 359 */ 360 bool dispatchedAllInsts; 361 362 /** Records if the queues have been changed (inserted or issued insts), 363 * so that IEW knows to broadcast the updated amount of free entries. 364 */ 365 bool updatedQueues; 366 |
367 /** Commit to IEW delay, in ticks. */ 368 unsigned commitToIEWDelay; 369 370 /** Rename to IEW delay, in ticks. */ 371 unsigned renameToIEWDelay; 372 373 /** 374 * Issue to execute delay, in ticks. What this actually represents is --- 11 unchanged lines hidden (view full) --- 386 /** Width of issue, in instructions. */ 387 unsigned issueWidth; 388 389 /** Width of execute, in instructions. Might make more sense to break 390 * down into FP vs int. 391 */ 392 unsigned executeWidth; 393 |
394 /** Index into queue of instructions being written back. */ 395 unsigned wbNumInst; 396 397 /** Cycle number within the queue of instructions being written back. 398 * Used in case there are too many instructions writing back at the current 399 * cycle and writesbacks need to be scheduled for the future. See comments 400 * in instToCommit(). |
401 */ |
402 unsigned wbCycle; |
403 |
404 /** Number of active threads. */ 405 unsigned numThreads; 406 407 /** Pointer to list of active threads. */ 408 std::list<unsigned> *activeThreads; 409 410 /** Maximum size of the skid buffer. */ 411 unsigned skidBufferMax; 412 413 bool switchedOut; 414 415 /** Stat for total number of idle cycles. */ |
416 Stats::Scalar<> iewIdleCycles; |
417 /** Stat for total number of squashing cycles. */ |
418 Stats::Scalar<> iewSquashCycles; |
419 /** Stat for total number of blocking cycles. */ |
420 Stats::Scalar<> iewBlockCycles; |
421 /** Stat for total number of unblocking cycles. */ |
422 Stats::Scalar<> iewUnblockCycles; |
423 /** Stat for total number of instructions dispatched. */ |
424 Stats::Scalar<> iewDispatchedInsts; |
425 /** Stat for total number of squashed instructions dispatch skips. */ |
426 Stats::Scalar<> iewDispSquashedInsts; |
427 /** Stat for total number of dispatched load instructions. */ |
428 Stats::Scalar<> iewDispLoadInsts; |
429 /** Stat for total number of dispatched store instructions. */ |
430 Stats::Scalar<> iewDispStoreInsts; |
431 /** Stat for total number of dispatched non speculative instructions. */ |
432 Stats::Scalar<> iewDispNonSpecInsts; |
433 /** Stat for number of times the IQ becomes full. */ |
434 Stats::Scalar<> iewIQFullEvents; |
435 /** Stat for number of times the LSQ becomes full. */ 436 Stats::Scalar<> iewLSQFullEvents; 437 /** Stat for total number of executed instructions. */ |
438 Stats::Scalar<> iewExecutedInsts; |
439 /** Stat for total number of executed load instructions. */ 440 Stats::Vector<> iewExecLoadInsts; 441 /** Stat for total number of executed store instructions. */ 442// Stats::Scalar<> iewExecStoreInsts; 443 /** Stat for total number of squashed instructions skipped at execute. */ |
444 Stats::Scalar<> iewExecSquashedInsts; |
445 /** Stat for total number of memory ordering violation events. */ |
446 Stats::Scalar<> memOrderViolationEvents; |
447 /** Stat for total number of incorrect predicted taken branches. */ |
448 Stats::Scalar<> predictedTakenIncorrect; |
449 /** Stat for total number of incorrect predicted not taken branches. */ 450 Stats::Scalar<> predictedNotTakenIncorrect; 451 /** Stat for total number of mispredicted branches detected at execute. */ 452 Stats::Formula branchMispredicts; 453 454 Stats::Vector<> exeSwp; 455 Stats::Vector<> exeNop; 456 Stats::Vector<> exeRefs; 457 Stats::Vector<> exeBranches; 458 459// Stats::Vector<> issued_ops; 460/* 461 Stats::Vector<> stat_fu_busy; 462 Stats::Vector2d<> stat_fuBusy; 463 Stats::Vector<> dist_unissued; 464 Stats::Vector2d<> stat_issued_inst_type; 465*/ 466 Stats::Formula issueRate; 467 Stats::Formula iewExecStoreInsts; 468// Stats::Formula issue_op_rate; 469// Stats::Formula fu_busy_rate; 470 471 Stats::Vector<> iewInstsToCommit; 472 Stats::Vector<> writebackCount; 473 Stats::Vector<> producerInst; 474 Stats::Vector<> consumerInst; 475 Stats::Vector<> wbPenalized; 476 477 Stats::Formula wbRate; 478 Stats::Formula wbFanout; 479 Stats::Formula wbPenalizedRate; |
480}; 481 |
482#endif // __CPU_O3_IEW_HH__ |