Cross Reference: /gem5/src/cpu/base_dyn_inst.hh

Deleted Added

sdiff udiff text old ( 10934:5af8f40d8f2c ) new ( 10935:acd48ddd725f )

full compact

base_dyn_inst.hh (10934:5af8f40d8f2c)	base_dyn_inst.hh (10935:acd48ddd725f)
1/* 2 * Copyright (c) 2011,2013 ARM Limited 3 * Copyright (c) 2013 Advanced Micro Devices, Inc. 4 * All rights reserved. 5 * 6 * The license below extends only to copyright in the software and shall 7 * not be construed as granting a license to any other intellectual 8 * property including but not limited to intellectual property relating 9 * to a hardware implementation of the functionality of the software 10 * licensed hereunder. You may use the software subject to the license 11 * terms below provided that you ensure that this notice is replicated 12 * unmodified and in its entirety in all distributions of the software, 13 * modified or unmodified, in source code or in binary form. 14 * 15 * Copyright (c) 2004-2006 The Regents of The University of Michigan 16 * Copyright (c) 2009 The University of Edinburgh 17 * All rights reserved. 18 * 19 * Redistribution and use in source and binary forms, with or without 20 * modification, are permitted provided that the following conditions are 21 * met: redistributions of source code must retain the above copyright 22 * notice, this list of conditions and the following disclaimer; 23 * redistributions in binary form must reproduce the above copyright 24 * notice, this list of conditions and the following disclaimer in the 25 * documentation and/or other materials provided with the distribution; 26 * neither the name of the copyright holders nor the names of its 27 * contributors may be used to endorse or promote products derived from 28 * this software without specific prior written permission. 29 * 30 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 31 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 32 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR 33 * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT 34 * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 35 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT 36 * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 37 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 38 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 39 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE 40 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 41 * 42 * Authors: Kevin Lim 43 * Timothy M. Jones 44 / 45 46#ifndef __CPU_BASE_DYN_INST_HH__ 47#define __CPU_BASE_DYN_INST_HH__ 48 49#include <array> 50#include <bitset> 51#include <list> 52#include <string> 53#include <queue> 54 55#include "arch/generic/tlb.hh" 56#include "arch/utility.hh" 57#include "base/trace.hh" 58#include "config/the_isa.hh" 59#include "cpu/checker/cpu.hh" 60#include "cpu/o3/comm.hh" 61#include "cpu/exec_context.hh" 62#include "cpu/exetrace.hh" 63#include "cpu/inst_seq.hh" 64#include "cpu/op_class.hh" 65#include "cpu/static_inst.hh" 66#include "cpu/translation.hh" 67#include "mem/packet.hh" 68#include "sim/byteswap.hh" 69#include "sim/system.hh" 70 71/* 72 * @file 73 * Defines a dynamic instruction context. 74 / 75 76template <class Impl> 77class BaseDynInst : public ExecContext, public RefCounted 78{ 79 public: 80 // Typedef for the CPU. 81 typedef typename Impl::CPUType ImplCPU; 82 typedef typename ImplCPU::ImplState ImplState; 83 84 // Logical register index type. 85 typedef TheISA::RegIndex RegIndex; 86 87 // The DynInstPtr type. 88 typedef typename Impl::DynInstPtr DynInstPtr; 89 typedef RefCountingPtr<BaseDynInst<Impl> > BaseDynInstPtr; 90 91 // The list of instructions iterator type. 92 typedef typename std::list<DynInstPtr>::iterator ListIt; 93 94 enum { 95 MaxInstSrcRegs = TheISA::MaxInstSrcRegs, /// Max source regs 96 MaxInstDestRegs = TheISA::MaxInstDestRegs /// Max dest regs 97 }; 98 99 union Result { 100* uint64_t integer; 101 double dbl;	1/* 2 * Copyright (c) 2011,2013 ARM Limited 3 * Copyright (c) 2013 Advanced Micro Devices, Inc. 4 * All rights reserved. 5 * 6 * The license below extends only to copyright in the software and shall 7 * not be construed as granting a license to any other intellectual 8 * property including but not limited to intellectual property relating 9 * to a hardware implementation of the functionality of the software 10 * licensed hereunder. You may use the software subject to the license 11 * terms below provided that you ensure that this notice is replicated 12 * unmodified and in its entirety in all distributions of the software, 13 * modified or unmodified, in source code or in binary form. 14 * 15 * Copyright (c) 2004-2006 The Regents of The University of Michigan 16 * Copyright (c) 2009 The University of Edinburgh 17 * All rights reserved. 18 * 19 * Redistribution and use in source and binary forms, with or without 20 * modification, are permitted provided that the following conditions are 21 * met: redistributions of source code must retain the above copyright 22 * notice, this list of conditions and the following disclaimer; 23 * redistributions in binary form must reproduce the above copyright 24 * notice, this list of conditions and the following disclaimer in the 25 * documentation and/or other materials provided with the distribution; 26 * neither the name of the copyright holders nor the names of its 27 * contributors may be used to endorse or promote products derived from 28 * this software without specific prior written permission. 29 * 30 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 31 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 32 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR 33 * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT 34 * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 35 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT 36 * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 37 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 38 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 39 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE 40 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 41 * 42 * Authors: Kevin Lim 43 * Timothy M. Jones 44 / 45 46#ifndef __CPU_BASE_DYN_INST_HH__ 47#define __CPU_BASE_DYN_INST_HH__ 48 49#include <array> 50#include <bitset> 51#include <list> 52#include <string> 53#include <queue> 54 55#include "arch/generic/tlb.hh" 56#include "arch/utility.hh" 57#include "base/trace.hh" 58#include "config/the_isa.hh" 59#include "cpu/checker/cpu.hh" 60#include "cpu/o3/comm.hh" 61#include "cpu/exec_context.hh" 62#include "cpu/exetrace.hh" 63#include "cpu/inst_seq.hh" 64#include "cpu/op_class.hh" 65#include "cpu/static_inst.hh" 66#include "cpu/translation.hh" 67#include "mem/packet.hh" 68#include "sim/byteswap.hh" 69#include "sim/system.hh" 70 71/* 72 * @file 73 * Defines a dynamic instruction context. 74 / 75 76template <class Impl> 77class BaseDynInst : public ExecContext, public RefCounted 78{ 79 public: 80 // Typedef for the CPU. 81 typedef typename Impl::CPUType ImplCPU; 82 typedef typename ImplCPU::ImplState ImplState; 83 84 // Logical register index type. 85 typedef TheISA::RegIndex RegIndex; 86 87 // The DynInstPtr type. 88 typedef typename Impl::DynInstPtr DynInstPtr; 89 typedef RefCountingPtr<BaseDynInst<Impl> > BaseDynInstPtr; 90 91 // The list of instructions iterator type. 92 typedef typename std::list<DynInstPtr>::iterator ListIt; 93 94 enum { 95 MaxInstSrcRegs = TheISA::MaxInstSrcRegs, /// Max source regs 96 MaxInstDestRegs = TheISA::MaxInstDestRegs /// Max dest regs 97 }; 98 99 union Result { 100* uint64_t integer; 101 double dbl;
102 103 // I am assuming that vector register type is different from the two 104 // types used above. Else it seems useless to have a separate typedef 105 // for vector registers. 106 VectorReg vector; 107
108 void set(uint64_t i) { integer = i; } 109 void set(double d) { dbl = d; }	102 void set(uint64_t i) { integer = i; } 103 void set(double d) { dbl = d; }
110 void set(const VectorReg &v) { vector = v; } 111
112 void get(uint64_t& i) { i = integer; } 113 void get(double& d) { d = dbl; }	104 void get(uint64_t& i) { i = integer; } 105 void get(double& d) { d = dbl; }
114 void get(VectorReg& v) { v = vector; }
115 }; 116 117 protected: 118 enum Status { 119 IqEntry, /// Instruction is in the IQ 120 RobEntry, /// Instruction is in the ROB 121 LsqEntry, /// Instruction is in the LSQ 122 Completed, /// Instruction has completed 123 ResultReady, /// Instruction has its result 124 CanIssue, /// Instruction can issue and execute 125 Issued, /// Instruction has issued 126 Executed, /// Instruction has executed 127 CanCommit, /// Instruction can commit 128 AtCommit, /// Instruction has reached commit 129 Committed, /// Instruction has committed 130 Squashed, /// Instruction is squashed 131 SquashedInIQ, /// Instruction is squashed in the IQ 132 SquashedInLSQ, /// Instruction is squashed in the LSQ 133 SquashedInROB, /// Instruction is squashed in the ROB 134 RecoverInst, /// Is a recover instruction 135 BlockingInst, /// Is a blocking instruction 136 ThreadsyncWait, /// Is a thread synchronization instruction 137 SerializeBefore, /// Needs to serialize on 138 /// instructions ahead of it 139 SerializeAfter, /// Needs to serialize instructions behind it 140 SerializeHandled, /// Serialization has been handled 141 NumStatus 142 }; 143 144 enum Flags { 145 TranslationStarted, 146 TranslationCompleted, 147 PossibleLoadViolation, 148 HitExternalSnoop, 149 EffAddrValid, 150 RecordResult, 151 Predicate, 152 PredTaken, 153 /** Whether or not the effective address calculation is completed. 154 * @todo: Consider if this is necessary or not. 155 / 156* EACalcDone, 157 IsStrictlyOrdered, 158 ReqMade, 159 MemOpDone, 160 MaxFlags 161 }; 162 163 public: 164 /** The sequence number of the instruction. / 165* InstSeqNum seqNum; 166 167 /** The StaticInst used by this BaseDynInst. / 168* const StaticInstPtr staticInst; 169 170 /** Pointer to the Impl's CPU object. / 171* ImplCPU cpu; 172* 173 BaseCPU getCpuPtr() { return cpu; } 174* 175 /** Pointer to the thread state. / 176* ImplState thread; 177* 178 /** The kind of fault this instruction has generated. / 179* Fault fault; 180 181 /** InstRecord that tracks this instructions. / 182* Trace::InstRecord traceData; 183* 184 protected: 185 /** The result of the instruction; assumes an instruction can have many 186 * destination registers. 187 / 188* std::queue<Result> instResult; 189 190 /** PC state for this instruction. / 191* TheISA::PCState pc; 192 193 /* An amalgamation of a lot of boolean values into one / 194* std::bitset<MaxFlags> instFlags; 195 196 /** The status of this BaseDynInst. Several bits can be set. / 197* std::bitset<NumStatus> status; 198 199 /** Whether or not the source register is ready. 200 * @todo: Not sure this should be here vs the derived class. 201 / 202* std::bitset<MaxInstSrcRegs> _readySrcRegIdx; 203 204 public: 205 /** The thread this instruction is from. / 206* ThreadID threadNumber; 207 208 /** Iterator pointing to this BaseDynInst in the list of all insts. / 209* ListIt instListIt; 210 211 ////////////////////// Branch Data /////////////// 212 /** Predicted PC state after this instruction. / 213* TheISA::PCState predPC; 214 215 /** The Macroop if one exists / 216* const StaticInstPtr macroop; 217 218 /** How many source registers are ready. / 219* uint8_t readyRegs; 220 221 public: 222 /////////////////////// Load Store Data ////////////////////// 223 /** The effective virtual address (lds & stores only). / 224* Addr effAddr; 225 226 /** The effective physical address. / 227* Addr physEffAddr; 228 229 /** The memory request flags (from translation). / 230* unsigned memReqFlags; 231 232 /** data address space ID, for loads & stores. / 233* short asid; 234 235 /** The size of the request / 236* uint8_t effSize; 237 238 /** Pointer to the data for the memory access. / 239* uint8_t memData; 240* 241 /** Load queue index. / 242* int16_t lqIdx; 243 244 /** Store queue index. / 245* int16_t sqIdx; 246 247 248 /////////////////////// TLB Miss ////////////////////// 249 /** 250 * Saved memory requests (needed when the DTB address translation is 251 * delayed due to a hw page table walk). 252 / 253* RequestPtr savedReq; 254 RequestPtr savedSreqLow; 255 RequestPtr savedSreqHigh; 256 257 /////////////////////// Checker ////////////////////// 258 // Need a copy of main request pointer to verify on writes. 259 RequestPtr reqToVerify; 260 261 private: 262 /** Instruction effective address. 263 * @todo: Consider if this is necessary or not. 264 / 265* Addr instEffAddr; 266 267 protected: 268 /** Flattened register index of the destination registers of this 269 * instruction. 270 / 271* std::array<TheISA::RegIndex, TheISA::MaxInstDestRegs> _flatDestRegIdx; 272 273 /** Physical register index of the destination registers of this 274 * instruction. 275 / 276* std::array<PhysRegIndex, TheISA::MaxInstDestRegs> _destRegIdx; 277 278 /** Physical register index of the source registers of this 279 * instruction. 280 / 281* std::array<PhysRegIndex, TheISA::MaxInstSrcRegs> _srcRegIdx; 282 283 /** Physical register index of the previous producers of the 284 * architected destinations. 285 / 286* std::array<PhysRegIndex, TheISA::MaxInstDestRegs> _prevDestRegIdx; 287 288 289 public: 290 /** Records changes to result? / 291* void recordResult(bool f) { instFlags[RecordResult] = f; } 292 293 /** Is the effective virtual address valid. / 294* bool effAddrValid() const { return instFlags[EffAddrValid]; } 295 296 /** Whether or not the memory operation is done. / 297* bool memOpDone() const { return instFlags[MemOpDone]; } 298 void memOpDone(bool f) { instFlags[MemOpDone] = f; } 299 300 301 //////////////////////////////////////////// 302 // 303 // INSTRUCTION EXECUTION 304 // 305 //////////////////////////////////////////// 306 307 void demapPage(Addr vaddr, uint64_t asn) 308 { 309 cpu->demapPage(vaddr, asn); 310 } 311 void demapInstPage(Addr vaddr, uint64_t asn) 312 { 313 cpu->demapPage(vaddr, asn); 314 } 315 void demapDataPage(Addr vaddr, uint64_t asn) 316 { 317 cpu->demapPage(vaddr, asn); 318 } 319 320 Fault readMem(Addr addr, uint8_t data, unsigned size, unsigned flags); 321* 322 Fault writeMem(uint8_t data, unsigned size, 323* Addr addr, unsigned flags, uint64_t res); 324* 325 /** Splits a request in two if it crosses a dcache block. / 326* void splitRequest(RequestPtr req, RequestPtr &sreqLow, 327 RequestPtr &sreqHigh); 328 329 /** Initiate a DTB address translation. / 330* void initiateTranslation(RequestPtr req, RequestPtr sreqLow, 331 RequestPtr sreqHigh, uint64_t res, 332* BaseTLB::Mode mode); 333 334 /** Finish a DTB address translation. / 335* void finishTranslation(WholeTranslationState state); 336* 337 /** True if the DTB address translation has started. / 338* bool translationStarted() const { return instFlags[TranslationStarted]; } 339 void translationStarted(bool f) { instFlags[TranslationStarted] = f; } 340 341 /** True if the DTB address translation has completed. / 342* bool translationCompleted() const { return instFlags[TranslationCompleted]; } 343 void translationCompleted(bool f) { instFlags[TranslationCompleted] = f; } 344 345 /** True if this address was found to match a previous load and they issued 346 * out of order. If that happend, then it's only a problem if an incoming 347 * snoop invalidate modifies the line, in which case we need to squash. 348 * If nothing modified the line the order doesn't matter. 349 / 350* bool possibleLoadViolation() const { return instFlags[PossibleLoadViolation]; } 351 void possibleLoadViolation(bool f) { instFlags[PossibleLoadViolation] = f; } 352 353 /** True if the address hit a external snoop while sitting in the LSQ. 354 * If this is true and a older instruction sees it, this instruction must 355 * reexecute 356 / 357* bool hitExternalSnoop() const { return instFlags[HitExternalSnoop]; } 358 void hitExternalSnoop(bool f) { instFlags[HitExternalSnoop] = f; } 359 360 /** 361 * Returns true if the DTB address translation is being delayed due to a hw 362 * page table walk. 363 / 364* bool isTranslationDelayed() const 365 { 366 return (translationStarted() && !translationCompleted()); 367 } 368 369 public: 370#ifdef DEBUG 371 void dumpSNList(); 372#endif 373 374 /** Returns the physical register index of the i'th destination 375 * register. 376 / 377* PhysRegIndex renamedDestRegIdx(int idx) const 378 { 379 return _destRegIdx[idx]; 380 } 381 382 /** Returns the physical register index of the i'th source register. / 383* PhysRegIndex renamedSrcRegIdx(int idx) const 384 { 385 assert(TheISA::MaxInstSrcRegs > idx); 386 return _srcRegIdx[idx]; 387 } 388 389 /** Returns the flattened register index of the i'th destination 390 * register. 391 / 392* TheISA::RegIndex flattenedDestRegIdx(int idx) const 393 { 394 return _flatDestRegIdx[idx]; 395 } 396 397 /** Returns the physical register index of the previous physical register 398 * that remapped to the same logical register index. 399 / 400* PhysRegIndex prevDestRegIdx(int idx) const 401 { 402 return _prevDestRegIdx[idx]; 403 } 404 405 /** Renames a destination register to a physical register. Also records 406 * the previous physical register that the logical register mapped to. 407 / 408* void renameDestReg(int idx, 409 PhysRegIndex renamed_dest, 410 PhysRegIndex previous_rename) 411 { 412 _destRegIdx[idx] = renamed_dest; 413 _prevDestRegIdx[idx] = previous_rename; 414 } 415 416 /** Renames a source logical register to the physical register which 417 * has/will produce that logical register's result. 418 * @todo: add in whether or not the source register is ready. 419 / 420* void renameSrcReg(int idx, PhysRegIndex renamed_src) 421 { 422 _srcRegIdx[idx] = renamed_src; 423 } 424 425 /** Flattens a destination architectural register index into a logical 426 * index. 427 / 428* void flattenDestReg(int idx, TheISA::RegIndex flattened_dest) 429 { 430 _flatDestRegIdx[idx] = flattened_dest; 431 } 432 /** BaseDynInst constructor given a binary instruction. 433 * @param staticInst A StaticInstPtr to the underlying instruction. 434 * @param pc The PC state for the instruction. 435 * @param predPC The predicted next PC state for the instruction. 436 * @param seq_num The sequence number of the instruction. 437 * @param cpu Pointer to the instruction's CPU. 438 / 439* BaseDynInst(const StaticInstPtr &staticInst, const StaticInstPtr &macroop, 440 TheISA::PCState pc, TheISA::PCState predPC, 441 InstSeqNum seq_num, ImplCPU cpu); 442* 443 /** BaseDynInst constructor given a StaticInst pointer. 444 * @param _staticInst The StaticInst for this BaseDynInst. 445 / 446* BaseDynInst(const StaticInstPtr &staticInst, const StaticInstPtr &macroop); 447 448 /** BaseDynInst destructor. / 449* ~BaseDynInst(); 450 451 private: 452 /** Function to initialize variables in the constructors. / 453* void initVars(); 454 455 public: 456 /** Dumps out contents of this BaseDynInst. / 457* void dump(); 458 459 /** Dumps out contents of this BaseDynInst into given string. / 460* void dump(std::string &outstring); 461 462 /** Read this CPU's ID. / 463* int cpuId() const { return cpu->cpuId(); } 464 465 /** Read this CPU's Socket ID. / 466* uint32_t socketId() const { return cpu->socketId(); } 467 468 /** Read this CPU's data requestor ID / 469* MasterID masterId() const { return cpu->dataMasterId(); } 470 471 / Read this context's system-wide ID / 472 int contextId() const { return thread->contextId(); } 473 474 /** Returns the fault type. / 475* Fault getFault() const { return fault; } 476 477 /** Checks whether or not this instruction has had its branch target 478 * calculated yet. For now it is not utilized and is hacked to be 479 * always false. 480 * @todo: Actually use this instruction. 481 / 482* bool doneTargCalc() { return false; } 483 484 /** Set the predicted target of this current instruction. / 485* void setPredTarg(const TheISA::PCState &_predPC) 486 { 487 predPC = _predPC; 488 } 489 490 const TheISA::PCState &readPredTarg() { return predPC; } 491 492 /** Returns the predicted PC immediately after the branch. / 493* Addr predInstAddr() { return predPC.instAddr(); } 494 495 /** Returns the predicted PC two instructions after the branch / 496* Addr predNextInstAddr() { return predPC.nextInstAddr(); } 497 498 /** Returns the predicted micro PC after the branch / 499* Addr predMicroPC() { return predPC.microPC(); } 500 501 /** Returns whether the instruction was predicted taken or not. / 502* bool readPredTaken() 503 { 504 return instFlags[PredTaken]; 505 } 506 507 void setPredTaken(bool predicted_taken) 508 { 509 instFlags[PredTaken] = predicted_taken; 510 } 511 512 /** Returns whether the instruction mispredicted. / 513* bool mispredicted() 514 { 515 TheISA::PCState tempPC = pc; 516 TheISA::advancePC(tempPC, staticInst); 517 return !(tempPC == predPC); 518 } 519 520 // 521 // Instruction types. Forward checks to StaticInst object. 522 // 523 bool isNop() const { return staticInst->isNop(); } 524 bool isMemRef() const { return staticInst->isMemRef(); } 525 bool isLoad() const { return staticInst->isLoad(); } 526 bool isStore() const { return staticInst->isStore(); } 527 bool isStoreConditional() const 528 { return staticInst->isStoreConditional(); } 529 bool isInstPrefetch() const { return staticInst->isInstPrefetch(); } 530 bool isDataPrefetch() const { return staticInst->isDataPrefetch(); } 531 bool isInteger() const { return staticInst->isInteger(); } 532 bool isFloating() const { return staticInst->isFloating(); }	106 }; 107 108 protected: 109 enum Status { 110 IqEntry, /// Instruction is in the IQ 111 RobEntry, /// Instruction is in the ROB 112 LsqEntry, /// Instruction is in the LSQ 113 Completed, /// Instruction has completed 114 ResultReady, /// Instruction has its result 115 CanIssue, /// Instruction can issue and execute 116 Issued, /// Instruction has issued 117 Executed, /// Instruction has executed 118 CanCommit, /// Instruction can commit 119 AtCommit, /// Instruction has reached commit 120 Committed, /// Instruction has committed 121 Squashed, /// Instruction is squashed 122 SquashedInIQ, /// Instruction is squashed in the IQ 123 SquashedInLSQ, /// Instruction is squashed in the LSQ 124 SquashedInROB, /// Instruction is squashed in the ROB 125 RecoverInst, /// Is a recover instruction 126 BlockingInst, /// Is a blocking instruction 127 ThreadsyncWait, /// Is a thread synchronization instruction 128 SerializeBefore, /// Needs to serialize on 129 /// instructions ahead of it 130 SerializeAfter, /// Needs to serialize instructions behind it 131 SerializeHandled, /// Serialization has been handled 132 NumStatus 133 }; 134 135 enum Flags { 136 TranslationStarted, 137 TranslationCompleted, 138 PossibleLoadViolation, 139 HitExternalSnoop, 140 EffAddrValid, 141 RecordResult, 142 Predicate, 143 PredTaken, 144 /** Whether or not the effective address calculation is completed. 145 * @todo: Consider if this is necessary or not. 146 / 147* EACalcDone, 148 IsStrictlyOrdered, 149 ReqMade, 150 MemOpDone, 151 MaxFlags 152 }; 153 154 public: 155 /** The sequence number of the instruction. / 156* InstSeqNum seqNum; 157 158 /** The StaticInst used by this BaseDynInst. / 159* const StaticInstPtr staticInst; 160 161 /** Pointer to the Impl's CPU object. / 162* ImplCPU cpu; 163* 164 BaseCPU getCpuPtr() { return cpu; } 165* 166 /** Pointer to the thread state. / 167* ImplState thread; 168* 169 /** The kind of fault this instruction has generated. / 170* Fault fault; 171 172 /** InstRecord that tracks this instructions. / 173* Trace::InstRecord traceData; 174* 175 protected: 176 /** The result of the instruction; assumes an instruction can have many 177 * destination registers. 178 / 179* std::queue<Result> instResult; 180 181 /** PC state for this instruction. / 182* TheISA::PCState pc; 183 184 /* An amalgamation of a lot of boolean values into one / 185* std::bitset<MaxFlags> instFlags; 186 187 /** The status of this BaseDynInst. Several bits can be set. / 188* std::bitset<NumStatus> status; 189 190 /** Whether or not the source register is ready. 191 * @todo: Not sure this should be here vs the derived class. 192 / 193* std::bitset<MaxInstSrcRegs> _readySrcRegIdx; 194 195 public: 196 /** The thread this instruction is from. / 197* ThreadID threadNumber; 198 199 /** Iterator pointing to this BaseDynInst in the list of all insts. / 200* ListIt instListIt; 201 202 ////////////////////// Branch Data /////////////// 203 /** Predicted PC state after this instruction. / 204* TheISA::PCState predPC; 205 206 /** The Macroop if one exists / 207* const StaticInstPtr macroop; 208 209 /** How many source registers are ready. / 210* uint8_t readyRegs; 211 212 public: 213 /////////////////////// Load Store Data ////////////////////// 214 /** The effective virtual address (lds & stores only). / 215* Addr effAddr; 216 217 /** The effective physical address. / 218* Addr physEffAddr; 219 220 /** The memory request flags (from translation). / 221* unsigned memReqFlags; 222 223 /** data address space ID, for loads & stores. / 224* short asid; 225 226 /** The size of the request / 227* uint8_t effSize; 228 229 /** Pointer to the data for the memory access. / 230* uint8_t memData; 231* 232 /** Load queue index. / 233* int16_t lqIdx; 234 235 /** Store queue index. / 236* int16_t sqIdx; 237 238 239 /////////////////////// TLB Miss ////////////////////// 240 /** 241 * Saved memory requests (needed when the DTB address translation is 242 * delayed due to a hw page table walk). 243 / 244* RequestPtr savedReq; 245 RequestPtr savedSreqLow; 246 RequestPtr savedSreqHigh; 247 248 /////////////////////// Checker ////////////////////// 249 // Need a copy of main request pointer to verify on writes. 250 RequestPtr reqToVerify; 251 252 private: 253 /** Instruction effective address. 254 * @todo: Consider if this is necessary or not. 255 / 256* Addr instEffAddr; 257 258 protected: 259 /** Flattened register index of the destination registers of this 260 * instruction. 261 / 262* std::array<TheISA::RegIndex, TheISA::MaxInstDestRegs> _flatDestRegIdx; 263 264 /** Physical register index of the destination registers of this 265 * instruction. 266 / 267* std::array<PhysRegIndex, TheISA::MaxInstDestRegs> _destRegIdx; 268 269 /** Physical register index of the source registers of this 270 * instruction. 271 / 272* std::array<PhysRegIndex, TheISA::MaxInstSrcRegs> _srcRegIdx; 273 274 /** Physical register index of the previous producers of the 275 * architected destinations. 276 / 277* std::array<PhysRegIndex, TheISA::MaxInstDestRegs> _prevDestRegIdx; 278 279 280 public: 281 /** Records changes to result? / 282* void recordResult(bool f) { instFlags[RecordResult] = f; } 283 284 /** Is the effective virtual address valid. / 285* bool effAddrValid() const { return instFlags[EffAddrValid]; } 286 287 /** Whether or not the memory operation is done. / 288* bool memOpDone() const { return instFlags[MemOpDone]; } 289 void memOpDone(bool f) { instFlags[MemOpDone] = f; } 290 291 292 //////////////////////////////////////////// 293 // 294 // INSTRUCTION EXECUTION 295 // 296 //////////////////////////////////////////// 297 298 void demapPage(Addr vaddr, uint64_t asn) 299 { 300 cpu->demapPage(vaddr, asn); 301 } 302 void demapInstPage(Addr vaddr, uint64_t asn) 303 { 304 cpu->demapPage(vaddr, asn); 305 } 306 void demapDataPage(Addr vaddr, uint64_t asn) 307 { 308 cpu->demapPage(vaddr, asn); 309 } 310 311 Fault readMem(Addr addr, uint8_t data, unsigned size, unsigned flags); 312* 313 Fault writeMem(uint8_t data, unsigned size, 314* Addr addr, unsigned flags, uint64_t res); 315* 316 /** Splits a request in two if it crosses a dcache block. / 317* void splitRequest(RequestPtr req, RequestPtr &sreqLow, 318 RequestPtr &sreqHigh); 319 320 /** Initiate a DTB address translation. / 321* void initiateTranslation(RequestPtr req, RequestPtr sreqLow, 322 RequestPtr sreqHigh, uint64_t res, 323* BaseTLB::Mode mode); 324 325 /** Finish a DTB address translation. / 326* void finishTranslation(WholeTranslationState state); 327* 328 /** True if the DTB address translation has started. / 329* bool translationStarted() const { return instFlags[TranslationStarted]; } 330 void translationStarted(bool f) { instFlags[TranslationStarted] = f; } 331 332 /** True if the DTB address translation has completed. / 333* bool translationCompleted() const { return instFlags[TranslationCompleted]; } 334 void translationCompleted(bool f) { instFlags[TranslationCompleted] = f; } 335 336 /** True if this address was found to match a previous load and they issued 337 * out of order. If that happend, then it's only a problem if an incoming 338 * snoop invalidate modifies the line, in which case we need to squash. 339 * If nothing modified the line the order doesn't matter. 340 / 341* bool possibleLoadViolation() const { return instFlags[PossibleLoadViolation]; } 342 void possibleLoadViolation(bool f) { instFlags[PossibleLoadViolation] = f; } 343 344 /** True if the address hit a external snoop while sitting in the LSQ. 345 * If this is true and a older instruction sees it, this instruction must 346 * reexecute 347 / 348* bool hitExternalSnoop() const { return instFlags[HitExternalSnoop]; } 349 void hitExternalSnoop(bool f) { instFlags[HitExternalSnoop] = f; } 350 351 /** 352 * Returns true if the DTB address translation is being delayed due to a hw 353 * page table walk. 354 / 355* bool isTranslationDelayed() const 356 { 357 return (translationStarted() && !translationCompleted()); 358 } 359 360 public: 361#ifdef DEBUG 362 void dumpSNList(); 363#endif 364 365 /** Returns the physical register index of the i'th destination 366 * register. 367 / 368* PhysRegIndex renamedDestRegIdx(int idx) const 369 { 370 return _destRegIdx[idx]; 371 } 372 373 /** Returns the physical register index of the i'th source register. / 374* PhysRegIndex renamedSrcRegIdx(int idx) const 375 { 376 assert(TheISA::MaxInstSrcRegs > idx); 377 return _srcRegIdx[idx]; 378 } 379 380 /** Returns the flattened register index of the i'th destination 381 * register. 382 / 383* TheISA::RegIndex flattenedDestRegIdx(int idx) const 384 { 385 return _flatDestRegIdx[idx]; 386 } 387 388 /** Returns the physical register index of the previous physical register 389 * that remapped to the same logical register index. 390 / 391* PhysRegIndex prevDestRegIdx(int idx) const 392 { 393 return _prevDestRegIdx[idx]; 394 } 395 396 /** Renames a destination register to a physical register. Also records 397 * the previous physical register that the logical register mapped to. 398 / 399* void renameDestReg(int idx, 400 PhysRegIndex renamed_dest, 401 PhysRegIndex previous_rename) 402 { 403 _destRegIdx[idx] = renamed_dest; 404 _prevDestRegIdx[idx] = previous_rename; 405 } 406 407 /** Renames a source logical register to the physical register which 408 * has/will produce that logical register's result. 409 * @todo: add in whether or not the source register is ready. 410 / 411* void renameSrcReg(int idx, PhysRegIndex renamed_src) 412 { 413 _srcRegIdx[idx] = renamed_src; 414 } 415 416 /** Flattens a destination architectural register index into a logical 417 * index. 418 / 419* void flattenDestReg(int idx, TheISA::RegIndex flattened_dest) 420 { 421 _flatDestRegIdx[idx] = flattened_dest; 422 } 423 /** BaseDynInst constructor given a binary instruction. 424 * @param staticInst A StaticInstPtr to the underlying instruction. 425 * @param pc The PC state for the instruction. 426 * @param predPC The predicted next PC state for the instruction. 427 * @param seq_num The sequence number of the instruction. 428 * @param cpu Pointer to the instruction's CPU. 429 / 430* BaseDynInst(const StaticInstPtr &staticInst, const StaticInstPtr &macroop, 431 TheISA::PCState pc, TheISA::PCState predPC, 432 InstSeqNum seq_num, ImplCPU cpu); 433* 434 /** BaseDynInst constructor given a StaticInst pointer. 435 * @param _staticInst The StaticInst for this BaseDynInst. 436 / 437* BaseDynInst(const StaticInstPtr &staticInst, const StaticInstPtr &macroop); 438 439 /** BaseDynInst destructor. / 440* ~BaseDynInst(); 441 442 private: 443 /** Function to initialize variables in the constructors. / 444* void initVars(); 445 446 public: 447 /** Dumps out contents of this BaseDynInst. / 448* void dump(); 449 450 /** Dumps out contents of this BaseDynInst into given string. / 451* void dump(std::string &outstring); 452 453 /** Read this CPU's ID. / 454* int cpuId() const { return cpu->cpuId(); } 455 456 /** Read this CPU's Socket ID. / 457* uint32_t socketId() const { return cpu->socketId(); } 458 459 /** Read this CPU's data requestor ID / 460* MasterID masterId() const { return cpu->dataMasterId(); } 461 462 / Read this context's system-wide ID / 463 int contextId() const { return thread->contextId(); } 464 465 /** Returns the fault type. / 466* Fault getFault() const { return fault; } 467 468 /** Checks whether or not this instruction has had its branch target 469 * calculated yet. For now it is not utilized and is hacked to be 470 * always false. 471 * @todo: Actually use this instruction. 472 / 473* bool doneTargCalc() { return false; } 474 475 /** Set the predicted target of this current instruction. / 476* void setPredTarg(const TheISA::PCState &_predPC) 477 { 478 predPC = _predPC; 479 } 480 481 const TheISA::PCState &readPredTarg() { return predPC; } 482 483 /** Returns the predicted PC immediately after the branch. / 484* Addr predInstAddr() { return predPC.instAddr(); } 485 486 /** Returns the predicted PC two instructions after the branch / 487* Addr predNextInstAddr() { return predPC.nextInstAddr(); } 488 489 /** Returns the predicted micro PC after the branch / 490* Addr predMicroPC() { return predPC.microPC(); } 491 492 /** Returns whether the instruction was predicted taken or not. / 493* bool readPredTaken() 494 { 495 return instFlags[PredTaken]; 496 } 497 498 void setPredTaken(bool predicted_taken) 499 { 500 instFlags[PredTaken] = predicted_taken; 501 } 502 503 /** Returns whether the instruction mispredicted. / 504* bool mispredicted() 505 { 506 TheISA::PCState tempPC = pc; 507 TheISA::advancePC(tempPC, staticInst); 508 return !(tempPC == predPC); 509 } 510 511 // 512 // Instruction types. Forward checks to StaticInst object. 513 // 514 bool isNop() const { return staticInst->isNop(); } 515 bool isMemRef() const { return staticInst->isMemRef(); } 516 bool isLoad() const { return staticInst->isLoad(); } 517 bool isStore() const { return staticInst->isStore(); } 518 bool isStoreConditional() const 519 { return staticInst->isStoreConditional(); } 520 bool isInstPrefetch() const { return staticInst->isInstPrefetch(); } 521 bool isDataPrefetch() const { return staticInst->isDataPrefetch(); } 522 bool isInteger() const { return staticInst->isInteger(); } 523 bool isFloating() const { return staticInst->isFloating(); }
533 bool isVector() const { return staticInst->isVector(); } 534 bool isCC() const { return staticInst->isCC(); } 535
536 bool isControl() const { return staticInst->isControl(); } 537 bool isCall() const { return staticInst->isCall(); } 538 bool isReturn() const { return staticInst->isReturn(); } 539 bool isDirectCtrl() const { return staticInst->isDirectCtrl(); } 540 bool isIndirectCtrl() const { return staticInst->isIndirectCtrl(); } 541 bool isCondCtrl() const { return staticInst->isCondCtrl(); } 542 bool isUncondCtrl() const { return staticInst->isUncondCtrl(); } 543 bool isCondDelaySlot() const { return staticInst->isCondDelaySlot(); } 544 bool isThreadSync() const { return staticInst->isThreadSync(); } 545 bool isSerializing() const { return staticInst->isSerializing(); } 546 bool isSerializeBefore() const 547 { return staticInst->isSerializeBefore() \|\| status[SerializeBefore]; } 548 bool isSerializeAfter() const 549 { return staticInst->isSerializeAfter() \|\| status[SerializeAfter]; } 550 bool isSquashAfter() const { return staticInst->isSquashAfter(); } 551 bool isMemBarrier() const { return staticInst->isMemBarrier(); } 552 bool isWriteBarrier() const { return staticInst->isWriteBarrier(); } 553 bool isNonSpeculative() const { return staticInst->isNonSpeculative(); } 554 bool isQuiesce() const { return staticInst->isQuiesce(); } 555 bool isIprAccess() const { return staticInst->isIprAccess(); } 556 bool isUnverifiable() const { return staticInst->isUnverifiable(); } 557 bool isSyscall() const { return staticInst->isSyscall(); } 558 bool isMacroop() const { return staticInst->isMacroop(); } 559 bool isMicroop() const { return staticInst->isMicroop(); } 560 bool isDelayedCommit() const { return staticInst->isDelayedCommit(); } 561 bool isLastMicroop() const { return staticInst->isLastMicroop(); } 562 bool isFirstMicroop() const { return staticInst->isFirstMicroop(); } 563 bool isMicroBranch() const { return staticInst->isMicroBranch(); } 564	524 bool isControl() const { return staticInst->isControl(); } 525 bool isCall() const { return staticInst->isCall(); } 526 bool isReturn() const { return staticInst->isReturn(); } 527 bool isDirectCtrl() const { return staticInst->isDirectCtrl(); } 528 bool isIndirectCtrl() const { return staticInst->isIndirectCtrl(); } 529 bool isCondCtrl() const { return staticInst->isCondCtrl(); } 530 bool isUncondCtrl() const { return staticInst->isUncondCtrl(); } 531 bool isCondDelaySlot() const { return staticInst->isCondDelaySlot(); } 532 bool isThreadSync() const { return staticInst->isThreadSync(); } 533 bool isSerializing() const { return staticInst->isSerializing(); } 534 bool isSerializeBefore() const 535 { return staticInst->isSerializeBefore() \|\| status[SerializeBefore]; } 536 bool isSerializeAfter() const 537 { return staticInst->isSerializeAfter() \|\| status[SerializeAfter]; } 538 bool isSquashAfter() const { return staticInst->isSquashAfter(); } 539 bool isMemBarrier() const { return staticInst->isMemBarrier(); } 540 bool isWriteBarrier() const { return staticInst->isWriteBarrier(); } 541 bool isNonSpeculative() const { return staticInst->isNonSpeculative(); } 542 bool isQuiesce() const { return staticInst->isQuiesce(); } 543 bool isIprAccess() const { return staticInst->isIprAccess(); } 544 bool isUnverifiable() const { return staticInst->isUnverifiable(); } 545 bool isSyscall() const { return staticInst->isSyscall(); } 546 bool isMacroop() const { return staticInst->isMacroop(); } 547 bool isMicroop() const { return staticInst->isMicroop(); } 548 bool isDelayedCommit() const { return staticInst->isDelayedCommit(); } 549 bool isLastMicroop() const { return staticInst->isLastMicroop(); } 550 bool isFirstMicroop() const { return staticInst->isFirstMicroop(); } 551 bool isMicroBranch() const { return staticInst->isMicroBranch(); } 552
565 void printFlags(std::ostream &outs, const std::string &separator) const 566 { staticInst->printFlags(outs, separator); } 567 568 std::string getName() const { return staticInst->getName(); } 569
570 /** Temporarily sets this instruction as a serialize before instruction. / 571* void setSerializeBefore() { status.set(SerializeBefore); } 572 573 /** Clears the serializeBefore part of this instruction. / 574* void clearSerializeBefore() { status.reset(SerializeBefore); } 575 576 /** Checks if this serializeBefore is only temporarily set. / 577* bool isTempSerializeBefore() { return status[SerializeBefore]; } 578 579 /** Temporarily sets this instruction as a serialize after instruction. / 580* void setSerializeAfter() { status.set(SerializeAfter); } 581 582 /** Clears the serializeAfter part of this instruction./ 583* void clearSerializeAfter() { status.reset(SerializeAfter); } 584 585 /** Checks if this serializeAfter is only temporarily set. / 586* bool isTempSerializeAfter() { return status[SerializeAfter]; } 587 588 /** Sets the serialization part of this instruction as handled. / 589* void setSerializeHandled() { status.set(SerializeHandled); } 590 591 /** Checks if the serialization part of this instruction has been 592 * handled. This does not apply to the temporary serializing 593 * state; it only applies to this instruction's own permanent 594 * serializing state. 595 / 596* bool isSerializeHandled() { return status[SerializeHandled]; } 597 598 /** Returns the opclass of this instruction. / 599* OpClass opClass() const { return staticInst->opClass(); } 600 601 /** Returns the branch target address. / 602* TheISA::PCState branchTarget() const 603 { return staticInst->branchTarget(pc); } 604 605 /** Returns the number of source registers. / 606* int8_t numSrcRegs() const { return staticInst->numSrcRegs(); } 607 608 /** Returns the number of destination registers. / 609* int8_t numDestRegs() const { return staticInst->numDestRegs(); } 610 611 // the following are used to track physical register usage 612 // for machines with separate int & FP reg files 613 int8_t numFPDestRegs() const { return staticInst->numFPDestRegs(); } 614 int8_t numIntDestRegs() const { return staticInst->numIntDestRegs(); } 615 int8_t numCCDestRegs() const { return staticInst->numCCDestRegs(); }	553 /** Temporarily sets this instruction as a serialize before instruction. / 554* void setSerializeBefore() { status.set(SerializeBefore); } 555 556 /** Clears the serializeBefore part of this instruction. / 557* void clearSerializeBefore() { status.reset(SerializeBefore); } 558 559 /** Checks if this serializeBefore is only temporarily set. / 560* bool isTempSerializeBefore() { return status[SerializeBefore]; } 561 562 /** Temporarily sets this instruction as a serialize after instruction. / 563* void setSerializeAfter() { status.set(SerializeAfter); } 564 565 /** Clears the serializeAfter part of this instruction./ 566* void clearSerializeAfter() { status.reset(SerializeAfter); } 567 568 /** Checks if this serializeAfter is only temporarily set. / 569* bool isTempSerializeAfter() { return status[SerializeAfter]; } 570 571 /** Sets the serialization part of this instruction as handled. / 572* void setSerializeHandled() { status.set(SerializeHandled); } 573 574 /** Checks if the serialization part of this instruction has been 575 * handled. This does not apply to the temporary serializing 576 * state; it only applies to this instruction's own permanent 577 * serializing state. 578 / 579* bool isSerializeHandled() { return status[SerializeHandled]; } 580 581 /** Returns the opclass of this instruction. / 582* OpClass opClass() const { return staticInst->opClass(); } 583 584 /** Returns the branch target address. / 585* TheISA::PCState branchTarget() const 586 { return staticInst->branchTarget(pc); } 587 588 /** Returns the number of source registers. / 589* int8_t numSrcRegs() const { return staticInst->numSrcRegs(); } 590 591 /** Returns the number of destination registers. / 592* int8_t numDestRegs() const { return staticInst->numDestRegs(); } 593 594 // the following are used to track physical register usage 595 // for machines with separate int & FP reg files 596 int8_t numFPDestRegs() const { return staticInst->numFPDestRegs(); } 597 int8_t numIntDestRegs() const { return staticInst->numIntDestRegs(); } 598 int8_t numCCDestRegs() const { return staticInst->numCCDestRegs(); }
616 int8_t numVectorDestRegs() const 617 { return staticInst->numVectorDestRegs(); }
618 619 /** Returns the logical register index of the i'th destination register. / 620* RegIndex destRegIdx(int i) const { return staticInst->destRegIdx(i); } 621 622 /** Returns the logical register index of the i'th source register. / 623* RegIndex srcRegIdx(int i) const { return staticInst->srcRegIdx(i); } 624 625 /** Pops a result off the instResult queue / 626* template <class T> 627 void popResult(T& t) 628 { 629 if (!instResult.empty()) { 630 instResult.front().get(t); 631 instResult.pop(); 632 } 633 } 634 635 /** Read the most recent result stored by this instruction / 636* template <class T> 637 void readResult(T& t) 638 { 639 instResult.back().get(t); 640 } 641 642 /** Pushes a result onto the instResult queue / 643* template <class T> 644 void setResult(T t) 645 { 646 if (instFlags[RecordResult]) { 647 Result instRes; 648 instRes.set(t); 649 instResult.push(instRes); 650 } 651 } 652 653 /** Records an integer register being set to a value. / 654* void setIntRegOperand(const StaticInst si, int idx, IntReg val) 655* { 656 setResult<uint64_t>(val); 657 } 658 659 /** Records a CC register being set to a value. / 660* void setCCRegOperand(const StaticInst si, int idx, CCReg val) 661* { 662 setResult<uint64_t>(val); 663 } 664 665 /** Records an fp register being set to a value. / 666* void setFloatRegOperand(const StaticInst si, int idx, FloatReg val) 667* { 668 setResult<double>(val); 669 } 670 671 /** Records an fp register being set to an integer value. / 672* void setFloatRegOperandBits(const StaticInst si, int idx, FloatRegBits val) 673* { 674 setResult<uint64_t>(val); 675 } 676	599 600 /** Returns the logical register index of the i'th destination register. / 601* RegIndex destRegIdx(int i) const { return staticInst->destRegIdx(i); } 602 603 /** Returns the logical register index of the i'th source register. / 604* RegIndex srcRegIdx(int i) const { return staticInst->srcRegIdx(i); } 605 606 /** Pops a result off the instResult queue / 607* template <class T> 608 void popResult(T& t) 609 { 610 if (!instResult.empty()) { 611 instResult.front().get(t); 612 instResult.pop(); 613 } 614 } 615 616 /** Read the most recent result stored by this instruction / 617* template <class T> 618 void readResult(T& t) 619 { 620 instResult.back().get(t); 621 } 622 623 /** Pushes a result onto the instResult queue / 624* template <class T> 625 void setResult(T t) 626 { 627 if (instFlags[RecordResult]) { 628 Result instRes; 629 instRes.set(t); 630 instResult.push(instRes); 631 } 632 } 633 634 /** Records an integer register being set to a value. / 635* void setIntRegOperand(const StaticInst si, int idx, IntReg val) 636* { 637 setResult<uint64_t>(val); 638 } 639 640 /** Records a CC register being set to a value. / 641* void setCCRegOperand(const StaticInst si, int idx, CCReg val) 642* { 643 setResult<uint64_t>(val); 644 } 645 646 /** Records an fp register being set to a value. / 647* void setFloatRegOperand(const StaticInst si, int idx, FloatReg val) 648* { 649 setResult<double>(val); 650 } 651 652 /** Records an fp register being set to an integer value. / 653* void setFloatRegOperandBits(const StaticInst si, int idx, FloatRegBits val) 654* { 655 setResult<uint64_t>(val); 656 } 657
677 /** Records a vector register being set to a value. / 678* void setVectorRegOperand(const StaticInst si, int idx, 679* const VectorReg &val) 680 { 681 setResult<const VectorReg &>(val); 682 } 683
684 /** Records that one of the source registers is ready. / 685* void markSrcRegReady(); 686 687 /** Marks a specific register as ready. / 688* void markSrcRegReady(RegIndex src_idx); 689 690 /** Returns if a source register is ready. / 691* bool isReadySrcRegIdx(int idx) const 692 { 693 return this->_readySrcRegIdx[idx]; 694 } 695 696 /** Sets this instruction as completed. / 697* void setCompleted() { status.set(Completed); } 698 699 /** Returns whether or not this instruction is completed. / 700* bool isCompleted() const { return status[Completed]; } 701 702 /** Marks the result as ready. / 703* void setResultReady() { status.set(ResultReady); } 704 705 /** Returns whether or not the result is ready. / 706* bool isResultReady() const { return status[ResultReady]; } 707 708 /** Sets this instruction as ready to issue. / 709* void setCanIssue() { status.set(CanIssue); } 710 711 /** Returns whether or not this instruction is ready to issue. / 712* bool readyToIssue() const { return status[CanIssue]; } 713 714 /** Clears this instruction being able to issue. / 715* void clearCanIssue() { status.reset(CanIssue); } 716 717 /** Sets this instruction as issued from the IQ. / 718* void setIssued() { status.set(Issued); } 719 720 /** Returns whether or not this instruction has issued. / 721* bool isIssued() const { return status[Issued]; } 722 723 /** Clears this instruction as being issued. / 724* void clearIssued() { status.reset(Issued); } 725 726 /** Sets this instruction as executed. / 727* void setExecuted() { status.set(Executed); } 728 729 /** Returns whether or not this instruction has executed. / 730* bool isExecuted() const { return status[Executed]; } 731 732 /** Sets this instruction as ready to commit. / 733* void setCanCommit() { status.set(CanCommit); } 734 735 /** Clears this instruction as being ready to commit. / 736* void clearCanCommit() { status.reset(CanCommit); } 737 738 /** Returns whether or not this instruction is ready to commit. / 739* bool readyToCommit() const { return status[CanCommit]; } 740 741 void setAtCommit() { status.set(AtCommit); } 742 743 bool isAtCommit() { return status[AtCommit]; } 744 745 /** Sets this instruction as committed. / 746* void setCommitted() { status.set(Committed); } 747 748 /** Returns whether or not this instruction is committed. / 749* bool isCommitted() const { return status[Committed]; } 750 751 /** Sets this instruction as squashed. / 752* void setSquashed() { status.set(Squashed); } 753 754 /** Returns whether or not this instruction is squashed. / 755* bool isSquashed() const { return status[Squashed]; } 756 757 //Instruction Queue Entry 758 //----------------------- 759 /** Sets this instruction as a entry the IQ. / 760* void setInIQ() { status.set(IqEntry); } 761 762 /** Sets this instruction as a entry the IQ. / 763* void clearInIQ() { status.reset(IqEntry); } 764 765 /** Returns whether or not this instruction has issued. / 766* bool isInIQ() const { return status[IqEntry]; } 767 768 /** Sets this instruction as squashed in the IQ. / 769* void setSquashedInIQ() { status.set(SquashedInIQ); status.set(Squashed);} 770 771 /** Returns whether or not this instruction is squashed in the IQ. / 772* bool isSquashedInIQ() const { return status[SquashedInIQ]; } 773 774 775 //Load / Store Queue Functions 776 //----------------------- 777 /** Sets this instruction as a entry the LSQ. / 778* void setInLSQ() { status.set(LsqEntry); } 779 780 /** Sets this instruction as a entry the LSQ. / 781* void removeInLSQ() { status.reset(LsqEntry); } 782 783 /** Returns whether or not this instruction is in the LSQ. / 784* bool isInLSQ() const { return status[LsqEntry]; } 785 786 /** Sets this instruction as squashed in the LSQ. / 787* void setSquashedInLSQ() { status.set(SquashedInLSQ);} 788 789 /** Returns whether or not this instruction is squashed in the LSQ. / 790* bool isSquashedInLSQ() const { return status[SquashedInLSQ]; } 791 792 793 //Reorder Buffer Functions 794 //----------------------- 795 /** Sets this instruction as a entry the ROB. / 796* void setInROB() { status.set(RobEntry); } 797 798 /** Sets this instruction as a entry the ROB. / 799* void clearInROB() { status.reset(RobEntry); } 800 801 /** Returns whether or not this instruction is in the ROB. / 802* bool isInROB() const { return status[RobEntry]; } 803 804 /** Sets this instruction as squashed in the ROB. / 805* void setSquashedInROB() { status.set(SquashedInROB); } 806 807 /** Returns whether or not this instruction is squashed in the ROB. / 808* bool isSquashedInROB() const { return status[SquashedInROB]; } 809 810 /** Read the PC state of this instruction. / 811* TheISA::PCState pcState() const { return pc; } 812 813 /** Set the PC state of this instruction. / 814* void pcState(const TheISA::PCState &val) { pc = val; } 815 816 /** Read the PC of this instruction. / 817* const Addr instAddr() const { return pc.instAddr(); } 818 819 /** Read the PC of the next instruction. / 820* const Addr nextInstAddr() const { return pc.nextInstAddr(); } 821 822 /*Read the micro PC of this instruction. / 823 const Addr microPC() const { return pc.microPC(); } 824 825 bool readPredicate() 826 { 827 return instFlags[Predicate]; 828 } 829 830 void setPredicate(bool val) 831 { 832 instFlags[Predicate] = val; 833 834 if (traceData) { 835 traceData->setPredicate(val); 836 } 837 } 838 839 /** Sets the ASID. / 840* void setASID(short addr_space_id) { asid = addr_space_id; } 841 842 /** Sets the thread id. / 843* void setTid(ThreadID tid) { threadNumber = tid; } 844 845 /** Sets the pointer to the thread state. / 846* void setThreadState(ImplState state) { thread = state; } 847* 848 /** Returns the thread context. / 849* ThreadContext tcBase() { return thread->getTC(); } 850* 851 public: 852 /** Sets the effective address. / 853* void setEA(Addr ea) { instEffAddr = ea; instFlags[EACalcDone] = true; } 854 855 /** Returns the effective address. / 856* Addr getEA() const { return instEffAddr; } 857 858 /** Returns whether or not the eff. addr. calculation has been completed. / 859* bool doneEACalc() { return instFlags[EACalcDone]; } 860 861 /** Returns whether or not the eff. addr. source registers are ready. / 862* bool eaSrcsReady(); 863 864 /** Is this instruction's memory access strictly ordered? / 865* bool strictlyOrdered() const { return instFlags[IsStrictlyOrdered]; } 866 867 /** Has this instruction generated a memory request. / 868* bool hasRequest() { return instFlags[ReqMade]; } 869 870 /** Returns iterator to this instruction in the list of all insts. / 871* ListIt &getInstListIt() { return instListIt; } 872 873 /** Sets iterator for this instruction in the list of all insts. / 874* void setInstListIt(ListIt _instListIt) { instListIt = _instListIt; } 875 876 public: 877 /** Returns the number of consecutive store conditional failures. / 878* unsigned int readStCondFailures() const 879 { return thread->storeCondFailures; } 880 881 /** Sets the number of consecutive store conditional failures. / 882* void setStCondFailures(unsigned int sc_failures) 883 { thread->storeCondFailures = sc_failures; } 884 885 public: 886 // monitor/mwait funtions 887 void armMonitor(Addr address) { cpu->armMonitor(address); } 888 bool mwait(PacketPtr pkt) { return cpu->mwait(pkt); } 889 void mwaitAtomic(ThreadContext tc) 890* { return cpu->mwaitAtomic(tc, cpu->dtb); } 891 AddressMonitor getAddrMonitor() { return cpu->getCpuAddrMonitor(); } 892}; 893* 894template<class Impl> 895Fault 896BaseDynInst<Impl>::readMem(Addr addr, uint8_t data, 897* unsigned size, unsigned flags) 898{ 899 instFlags[ReqMade] = true; 900 Request req = NULL; 901* Request sreqLow = NULL; 902* Request sreqHigh = NULL; 903* 904 if (instFlags[ReqMade] && translationStarted()) { 905 req = savedReq; 906 sreqLow = savedSreqLow; 907 sreqHigh = savedSreqHigh; 908 } else { 909 req = new Request(asid, addr, size, flags, masterId(), this->pc.instAddr(), 910 thread->contextId(), threadNumber); 911 912 req->taskId(cpu->taskId()); 913 914 // Only split the request if the ISA supports unaligned accesses. 915 if (TheISA::HasUnalignedMemAcc) { 916 splitRequest(req, sreqLow, sreqHigh); 917 } 918 initiateTranslation(req, sreqLow, sreqHigh, NULL, BaseTLB::Read); 919 } 920 921 if (translationCompleted()) { 922 if (fault == NoFault) { 923 effAddr = req->getVaddr(); 924 effSize = size; 925 instFlags[EffAddrValid] = true; 926 927 if (cpu->checker) { 928 if (reqToVerify != NULL) { 929 delete reqToVerify; 930 } 931 reqToVerify = new Request(req); 932* } 933 fault = cpu->read(req, sreqLow, sreqHigh, data, lqIdx); 934 } else { 935 // Commit will have to clean up whatever happened. Set this 936 // instruction as executed. 937 this->setExecuted(); 938 } 939 940 if (fault != NoFault) { 941 // Return a fixed value to keep simulation deterministic even 942 // along misspeculated paths. 943 if (data) 944 bzero(data, size); 945 } 946 } 947 948 if (traceData) 949 traceData->setMem(addr, size, flags); 950 951 return fault; 952} 953 954template<class Impl> 955Fault 956BaseDynInst<Impl>::writeMem(uint8_t data, unsigned size, 957* Addr addr, unsigned flags, uint64_t res) 958{ 959* if (traceData) 960 traceData->setMem(addr, size, flags); 961 962 instFlags[ReqMade] = true; 963 Request req = NULL; 964* Request sreqLow = NULL; 965* Request sreqHigh = NULL; 966* 967 if (instFlags[ReqMade] && translationStarted()) { 968 req = savedReq; 969 sreqLow = savedSreqLow; 970 sreqHigh = savedSreqHigh; 971 } else { 972 req = new Request(asid, addr, size, flags, masterId(), this->pc.instAddr(), 973 thread->contextId(), threadNumber); 974 975 req->taskId(cpu->taskId()); 976 977 // Only split the request if the ISA supports unaligned accesses. 978 if (TheISA::HasUnalignedMemAcc) { 979 splitRequest(req, sreqLow, sreqHigh); 980 } 981 initiateTranslation(req, sreqLow, sreqHigh, res, BaseTLB::Write); 982 } 983 984 if (fault == NoFault && translationCompleted()) { 985 effAddr = req->getVaddr(); 986 effSize = size; 987 instFlags[EffAddrValid] = true; 988 989 if (cpu->checker) { 990 if (reqToVerify != NULL) { 991 delete reqToVerify; 992 } 993 reqToVerify = new Request(req); 994* } 995 fault = cpu->write(req, sreqLow, sreqHigh, data, sqIdx); 996 } 997 998 return fault; 999} 1000 1001template<class Impl> 1002inline void 1003BaseDynInst<Impl>::splitRequest(RequestPtr req, RequestPtr &sreqLow, 1004 RequestPtr &sreqHigh) 1005{ 1006 // Check to see if the request crosses the next level block boundary. 1007 unsigned block_size = cpu->cacheLineSize(); 1008 Addr addr = req->getVaddr(); 1009 Addr split_addr = roundDown(addr + req->getSize() - 1, block_size); 1010 assert(split_addr <= addr \|\| split_addr - addr < block_size); 1011 1012 // Spans two blocks. 1013 if (split_addr > addr) { 1014 req->splitOnVaddr(split_addr, sreqLow, sreqHigh); 1015 } 1016} 1017 1018template<class Impl> 1019inline void 1020BaseDynInst<Impl>::initiateTranslation(RequestPtr req, RequestPtr sreqLow, 1021 RequestPtr sreqHigh, uint64_t res, 1022* BaseTLB::Mode mode) 1023{ 1024 translationStarted(true); 1025 1026 if (!TheISA::HasUnalignedMemAcc \|\| sreqLow == NULL) { 1027 WholeTranslationState state = 1028* new WholeTranslationState(req, NULL, res, mode); 1029 1030 // One translation if the request isn't split. 1031 DataTranslation<BaseDynInstPtr> trans = 1032* new DataTranslation<BaseDynInstPtr>(this, state); 1033 1034 cpu->dtb->translateTiming(req, thread->getTC(), trans, mode); 1035 1036 if (!translationCompleted()) { 1037 // The translation isn't yet complete, so we can't possibly have a 1038 // fault. Overwrite any existing fault we might have from a previous 1039 // execution of this instruction (e.g. an uncachable load that 1040 // couldn't execute because it wasn't at the head of the ROB). 1041 fault = NoFault; 1042 1043 // Save memory requests. 1044 savedReq = state->mainReq; 1045 savedSreqLow = state->sreqLow; 1046 savedSreqHigh = state->sreqHigh; 1047 } 1048 } else { 1049 WholeTranslationState state = 1050* new WholeTranslationState(req, sreqLow, sreqHigh, NULL, res, mode); 1051 1052 // Two translations when the request is split. 1053 DataTranslation<BaseDynInstPtr> stransLow = 1054* new DataTranslation<BaseDynInstPtr>(this, state, 0); 1055 DataTranslation<BaseDynInstPtr> stransHigh = 1056* new DataTranslation<BaseDynInstPtr>(this, state, 1); 1057 1058 cpu->dtb->translateTiming(sreqLow, thread->getTC(), stransLow, mode); 1059 cpu->dtb->translateTiming(sreqHigh, thread->getTC(), stransHigh, mode); 1060 1061 if (!translationCompleted()) { 1062 // The translation isn't yet complete, so we can't possibly have a 1063 // fault. Overwrite any existing fault we might have from a previous 1064 // execution of this instruction (e.g. an uncachable load that 1065 // couldn't execute because it wasn't at the head of the ROB). 1066 fault = NoFault; 1067 1068 // Save memory requests. 1069 savedReq = state->mainReq; 1070 savedSreqLow = state->sreqLow; 1071 savedSreqHigh = state->sreqHigh; 1072 } 1073 } 1074} 1075 1076template<class Impl> 1077inline void 1078BaseDynInst<Impl>::finishTranslation(WholeTranslationState state) 1079{ 1080* fault = state->getFault(); 1081 1082 instFlags[IsStrictlyOrdered] = state->isStrictlyOrdered(); 1083 1084 if (fault == NoFault) { 1085 physEffAddr = state->getPaddr(); 1086 memReqFlags = state->getFlags(); 1087 1088 if (state->mainReq->isCondSwap()) { 1089 assert(state->res); 1090 state->mainReq->setExtraData(state->res); 1091* } 1092 1093 } else { 1094 state->deleteReqs(); 1095 } 1096 delete state; 1097 1098 translationCompleted(true); 1099} 1100 1101#endif // __CPU_BASE_DYN_INST_HH__	658 /** Records that one of the source registers is ready. / 659* void markSrcRegReady(); 660 661 /** Marks a specific register as ready. / 662* void markSrcRegReady(RegIndex src_idx); 663 664 /** Returns if a source register is ready. / 665* bool isReadySrcRegIdx(int idx) const 666 { 667 return this->_readySrcRegIdx[idx]; 668 } 669 670 /** Sets this instruction as completed. / 671* void setCompleted() { status.set(Completed); } 672 673 /** Returns whether or not this instruction is completed. / 674* bool isCompleted() const { return status[Completed]; } 675 676 /** Marks the result as ready. / 677* void setResultReady() { status.set(ResultReady); } 678 679 /** Returns whether or not the result is ready. / 680* bool isResultReady() const { return status[ResultReady]; } 681 682 /** Sets this instruction as ready to issue. / 683* void setCanIssue() { status.set(CanIssue); } 684 685 /** Returns whether or not this instruction is ready to issue. / 686* bool readyToIssue() const { return status[CanIssue]; } 687 688 /** Clears this instruction being able to issue. / 689* void clearCanIssue() { status.reset(CanIssue); } 690 691 /** Sets this instruction as issued from the IQ. / 692* void setIssued() { status.set(Issued); } 693 694 /** Returns whether or not this instruction has issued. / 695* bool isIssued() const { return status[Issued]; } 696 697 /** Clears this instruction as being issued. / 698* void clearIssued() { status.reset(Issued); } 699 700 /** Sets this instruction as executed. / 701* void setExecuted() { status.set(Executed); } 702 703 /** Returns whether or not this instruction has executed. / 704* bool isExecuted() const { return status[Executed]; } 705 706 /** Sets this instruction as ready to commit. / 707* void setCanCommit() { status.set(CanCommit); } 708 709 /** Clears this instruction as being ready to commit. / 710* void clearCanCommit() { status.reset(CanCommit); } 711 712 /** Returns whether or not this instruction is ready to commit. / 713* bool readyToCommit() const { return status[CanCommit]; } 714 715 void setAtCommit() { status.set(AtCommit); } 716 717 bool isAtCommit() { return status[AtCommit]; } 718 719 /** Sets this instruction as committed. / 720* void setCommitted() { status.set(Committed); } 721 722 /** Returns whether or not this instruction is committed. / 723* bool isCommitted() const { return status[Committed]; } 724 725 /** Sets this instruction as squashed. / 726* void setSquashed() { status.set(Squashed); } 727 728 /** Returns whether or not this instruction is squashed. / 729* bool isSquashed() const { return status[Squashed]; } 730 731 //Instruction Queue Entry 732 //----------------------- 733 /** Sets this instruction as a entry the IQ. / 734* void setInIQ() { status.set(IqEntry); } 735 736 /** Sets this instruction as a entry the IQ. / 737* void clearInIQ() { status.reset(IqEntry); } 738 739 /** Returns whether or not this instruction has issued. / 740* bool isInIQ() const { return status[IqEntry]; } 741 742 /** Sets this instruction as squashed in the IQ. / 743* void setSquashedInIQ() { status.set(SquashedInIQ); status.set(Squashed);} 744 745 /** Returns whether or not this instruction is squashed in the IQ. / 746* bool isSquashedInIQ() const { return status[SquashedInIQ]; } 747 748 749 //Load / Store Queue Functions 750 //----------------------- 751 /** Sets this instruction as a entry the LSQ. / 752* void setInLSQ() { status.set(LsqEntry); } 753 754 /** Sets this instruction as a entry the LSQ. / 755* void removeInLSQ() { status.reset(LsqEntry); } 756 757 /** Returns whether or not this instruction is in the LSQ. / 758* bool isInLSQ() const { return status[LsqEntry]; } 759 760 /** Sets this instruction as squashed in the LSQ. / 761* void setSquashedInLSQ() { status.set(SquashedInLSQ);} 762 763 /** Returns whether or not this instruction is squashed in the LSQ. / 764* bool isSquashedInLSQ() const { return status[SquashedInLSQ]; } 765 766 767 //Reorder Buffer Functions 768 //----------------------- 769 /** Sets this instruction as a entry the ROB. / 770* void setInROB() { status.set(RobEntry); } 771 772 /** Sets this instruction as a entry the ROB. / 773* void clearInROB() { status.reset(RobEntry); } 774 775 /** Returns whether or not this instruction is in the ROB. / 776* bool isInROB() const { return status[RobEntry]; } 777 778 /** Sets this instruction as squashed in the ROB. / 779* void setSquashedInROB() { status.set(SquashedInROB); } 780 781 /** Returns whether or not this instruction is squashed in the ROB. / 782* bool isSquashedInROB() const { return status[SquashedInROB]; } 783 784 /** Read the PC state of this instruction. / 785* TheISA::PCState pcState() const { return pc; } 786 787 /** Set the PC state of this instruction. / 788* void pcState(const TheISA::PCState &val) { pc = val; } 789 790 /** Read the PC of this instruction. / 791* const Addr instAddr() const { return pc.instAddr(); } 792 793 /** Read the PC of the next instruction. / 794* const Addr nextInstAddr() const { return pc.nextInstAddr(); } 795 796 /*Read the micro PC of this instruction. / 797 const Addr microPC() const { return pc.microPC(); } 798 799 bool readPredicate() 800 { 801 return instFlags[Predicate]; 802 } 803 804 void setPredicate(bool val) 805 { 806 instFlags[Predicate] = val; 807 808 if (traceData) { 809 traceData->setPredicate(val); 810 } 811 } 812 813 /** Sets the ASID. / 814* void setASID(short addr_space_id) { asid = addr_space_id; } 815 816 /** Sets the thread id. / 817* void setTid(ThreadID tid) { threadNumber = tid; } 818 819 /** Sets the pointer to the thread state. / 820* void setThreadState(ImplState state) { thread = state; } 821* 822 /** Returns the thread context. / 823* ThreadContext tcBase() { return thread->getTC(); } 824* 825 public: 826 /** Sets the effective address. / 827* void setEA(Addr ea) { instEffAddr = ea; instFlags[EACalcDone] = true; } 828 829 /** Returns the effective address. / 830* Addr getEA() const { return instEffAddr; } 831 832 /** Returns whether or not the eff. addr. calculation has been completed. / 833* bool doneEACalc() { return instFlags[EACalcDone]; } 834 835 /** Returns whether or not the eff. addr. source registers are ready. / 836* bool eaSrcsReady(); 837 838 /** Is this instruction's memory access strictly ordered? / 839* bool strictlyOrdered() const { return instFlags[IsStrictlyOrdered]; } 840 841 /** Has this instruction generated a memory request. / 842* bool hasRequest() { return instFlags[ReqMade]; } 843 844 /** Returns iterator to this instruction in the list of all insts. / 845* ListIt &getInstListIt() { return instListIt; } 846 847 /** Sets iterator for this instruction in the list of all insts. / 848* void setInstListIt(ListIt _instListIt) { instListIt = _instListIt; } 849 850 public: 851 /** Returns the number of consecutive store conditional failures. / 852* unsigned int readStCondFailures() const 853 { return thread->storeCondFailures; } 854 855 /** Sets the number of consecutive store conditional failures. / 856* void setStCondFailures(unsigned int sc_failures) 857 { thread->storeCondFailures = sc_failures; } 858 859 public: 860 // monitor/mwait funtions 861 void armMonitor(Addr address) { cpu->armMonitor(address); } 862 bool mwait(PacketPtr pkt) { return cpu->mwait(pkt); } 863 void mwaitAtomic(ThreadContext tc) 864* { return cpu->mwaitAtomic(tc, cpu->dtb); } 865 AddressMonitor getAddrMonitor() { return cpu->getCpuAddrMonitor(); } 866}; 867* 868template<class Impl> 869Fault 870BaseDynInst<Impl>::readMem(Addr addr, uint8_t data, 871* unsigned size, unsigned flags) 872{ 873 instFlags[ReqMade] = true; 874 Request req = NULL; 875* Request sreqLow = NULL; 876* Request sreqHigh = NULL; 877* 878 if (instFlags[ReqMade] && translationStarted()) { 879 req = savedReq; 880 sreqLow = savedSreqLow; 881 sreqHigh = savedSreqHigh; 882 } else { 883 req = new Request(asid, addr, size, flags, masterId(), this->pc.instAddr(), 884 thread->contextId(), threadNumber); 885 886 req->taskId(cpu->taskId()); 887 888 // Only split the request if the ISA supports unaligned accesses. 889 if (TheISA::HasUnalignedMemAcc) { 890 splitRequest(req, sreqLow, sreqHigh); 891 } 892 initiateTranslation(req, sreqLow, sreqHigh, NULL, BaseTLB::Read); 893 } 894 895 if (translationCompleted()) { 896 if (fault == NoFault) { 897 effAddr = req->getVaddr(); 898 effSize = size; 899 instFlags[EffAddrValid] = true; 900 901 if (cpu->checker) { 902 if (reqToVerify != NULL) { 903 delete reqToVerify; 904 } 905 reqToVerify = new Request(req); 906* } 907 fault = cpu->read(req, sreqLow, sreqHigh, data, lqIdx); 908 } else { 909 // Commit will have to clean up whatever happened. Set this 910 // instruction as executed. 911 this->setExecuted(); 912 } 913 914 if (fault != NoFault) { 915 // Return a fixed value to keep simulation deterministic even 916 // along misspeculated paths. 917 if (data) 918 bzero(data, size); 919 } 920 } 921 922 if (traceData) 923 traceData->setMem(addr, size, flags); 924 925 return fault; 926} 927 928template<class Impl> 929Fault 930BaseDynInst<Impl>::writeMem(uint8_t data, unsigned size, 931* Addr addr, unsigned flags, uint64_t res) 932{ 933* if (traceData) 934 traceData->setMem(addr, size, flags); 935 936 instFlags[ReqMade] = true; 937 Request req = NULL; 938* Request sreqLow = NULL; 939* Request sreqHigh = NULL; 940* 941 if (instFlags[ReqMade] && translationStarted()) { 942 req = savedReq; 943 sreqLow = savedSreqLow; 944 sreqHigh = savedSreqHigh; 945 } else { 946 req = new Request(asid, addr, size, flags, masterId(), this->pc.instAddr(), 947 thread->contextId(), threadNumber); 948 949 req->taskId(cpu->taskId()); 950 951 // Only split the request if the ISA supports unaligned accesses. 952 if (TheISA::HasUnalignedMemAcc) { 953 splitRequest(req, sreqLow, sreqHigh); 954 } 955 initiateTranslation(req, sreqLow, sreqHigh, res, BaseTLB::Write); 956 } 957 958 if (fault == NoFault && translationCompleted()) { 959 effAddr = req->getVaddr(); 960 effSize = size; 961 instFlags[EffAddrValid] = true; 962 963 if (cpu->checker) { 964 if (reqToVerify != NULL) { 965 delete reqToVerify; 966 } 967 reqToVerify = new Request(req); 968* } 969 fault = cpu->write(req, sreqLow, sreqHigh, data, sqIdx); 970 } 971 972 return fault; 973} 974 975template<class Impl> 976inline void 977BaseDynInst<Impl>::splitRequest(RequestPtr req, RequestPtr &sreqLow, 978 RequestPtr &sreqHigh) 979{ 980 // Check to see if the request crosses the next level block boundary. 981 unsigned block_size = cpu->cacheLineSize(); 982 Addr addr = req->getVaddr(); 983 Addr split_addr = roundDown(addr + req->getSize() - 1, block_size); 984 assert(split_addr <= addr \|\| split_addr - addr < block_size); 985 986 // Spans two blocks. 987 if (split_addr > addr) { 988 req->splitOnVaddr(split_addr, sreqLow, sreqHigh); 989 } 990} 991 992template<class Impl> 993inline void 994BaseDynInst<Impl>::initiateTranslation(RequestPtr req, RequestPtr sreqLow, 995 RequestPtr sreqHigh, uint64_t res, 996* BaseTLB::Mode mode) 997{ 998 translationStarted(true); 999 1000 if (!TheISA::HasUnalignedMemAcc \|\| sreqLow == NULL) { 1001 WholeTranslationState state = 1002* new WholeTranslationState(req, NULL, res, mode); 1003 1004 // One translation if the request isn't split. 1005 DataTranslation<BaseDynInstPtr> trans = 1006* new DataTranslation<BaseDynInstPtr>(this, state); 1007 1008 cpu->dtb->translateTiming(req, thread->getTC(), trans, mode); 1009 1010 if (!translationCompleted()) { 1011 // The translation isn't yet complete, so we can't possibly have a 1012 // fault. Overwrite any existing fault we might have from a previous 1013 // execution of this instruction (e.g. an uncachable load that 1014 // couldn't execute because it wasn't at the head of the ROB). 1015 fault = NoFault; 1016 1017 // Save memory requests. 1018 savedReq = state->mainReq; 1019 savedSreqLow = state->sreqLow; 1020 savedSreqHigh = state->sreqHigh; 1021 } 1022 } else { 1023 WholeTranslationState state = 1024* new WholeTranslationState(req, sreqLow, sreqHigh, NULL, res, mode); 1025 1026 // Two translations when the request is split. 1027 DataTranslation<BaseDynInstPtr> stransLow = 1028* new DataTranslation<BaseDynInstPtr>(this, state, 0); 1029 DataTranslation<BaseDynInstPtr> stransHigh = 1030* new DataTranslation<BaseDynInstPtr>(this, state, 1); 1031 1032 cpu->dtb->translateTiming(sreqLow, thread->getTC(), stransLow, mode); 1033 cpu->dtb->translateTiming(sreqHigh, thread->getTC(), stransHigh, mode); 1034 1035 if (!translationCompleted()) { 1036 // The translation isn't yet complete, so we can't possibly have a 1037 // fault. Overwrite any existing fault we might have from a previous 1038 // execution of this instruction (e.g. an uncachable load that 1039 // couldn't execute because it wasn't at the head of the ROB). 1040 fault = NoFault; 1041 1042 // Save memory requests. 1043 savedReq = state->mainReq; 1044 savedSreqLow = state->sreqLow; 1045 savedSreqHigh = state->sreqHigh; 1046 } 1047 } 1048} 1049 1050template<class Impl> 1051inline void 1052BaseDynInst<Impl>::finishTranslation(WholeTranslationState state) 1053{ 1054* fault = state->getFault(); 1055 1056 instFlags[IsStrictlyOrdered] = state->isStrictlyOrdered(); 1057 1058 if (fault == NoFault) { 1059 physEffAddr = state->getPaddr(); 1060 memReqFlags = state->getFlags(); 1061 1062 if (state->mainReq->isCondSwap()) { 1063 assert(state->res); 1064 state->mainReq->setExtraData(state->res); 1065* } 1066 1067 } else { 1068 state->deleteReqs(); 1069 } 1070 delete state; 1071 1072 translationCompleted(true); 1073} 1074 1075#endif // __CPU_BASE_DYN_INST_HH__