1 //==-- llvm/CodeGen/GlobalISel/RegisterBankInfo.h ----------------*- C++ -*-==// 2 // 3 // The LLVM Compiler Infrastructure 4 // 5 // This file is distributed under the University of Illinois Open Source 6 // License. See LICENSE.TXT for details. 7 // 8 //===----------------------------------------------------------------------===// 9 // 10 /// \file This file declares the API for the register bank info. 11 /// This API is responsible for handling the register banks. 12 // 13 //===----------------------------------------------------------------------===// 14 15 #ifndef LLVM_CODEGEN_GLOBALISEL_REGBANKINFO_H 16 #define LLVM_CODEGEN_GLOBALISEL_REGBANKINFO_H 17 18 #include "llvm/ADT/APInt.h" 19 #include "llvm/ADT/SmallVector.h" 20 #include "llvm/CodeGen/GlobalISel/RegisterBank.h" 21 #include "llvm/CodeGen/MachineValueType.h" // For SimpleValueType. 22 #include "llvm/Support/ErrorHandling.h" 23 24 #include <cassert> 25 #include <memory> // For unique_ptr. 26 27 namespace llvm { 28 class MachineInstr; 29 class MachineRegisterInfo; 30 class TargetInstrInfo; 31 class TargetRegisterInfo; 32 class raw_ostream; 33 34 /// Holds all the information related to register banks. 35 class RegisterBankInfo { 36 public: 37 /// Helper struct that represents how a value is partially mapped 38 /// into a register. 39 /// The StartIdx and Length represent what region of the orginal 40 /// value this partial mapping covers. 41 /// This can be represented as a Mask of contiguous bit starting 42 /// at StartIdx bit and spanning Length bits. 43 /// StartIdx is the number of bits from the less significant bits. 44 struct PartialMapping { 45 /// Number of bits at which this partial mapping starts in the 46 /// original value. The bits are counted from less significant 47 /// bits to most significant bits. 48 unsigned StartIdx; 49 /// Length of this mapping in bits. This is how many bits this 50 /// partial mapping covers in the original value: 51 /// from StartIdx to StartIdx + Length -1. 52 unsigned Length; 53 /// Register bank where the partial value lives. 54 const RegisterBank *RegBank; 55 56 PartialMapping() = default; 57 58 /// Provide a shortcut for quickly building PartialMapping. PartialMappingPartialMapping59 PartialMapping(unsigned StartIdx, unsigned Length, 60 const RegisterBank &RegBank) 61 : StartIdx(StartIdx), Length(Length), RegBank(&RegBank) {} 62 63 /// \return the index of in the original value of the most 64 /// significant bit that this partial mapping covers. getHighBitIdxPartialMapping65 unsigned getHighBitIdx() const { return StartIdx + Length - 1; } 66 67 /// Print this partial mapping on dbgs() stream. 68 void dump() const; 69 70 /// Print this partial mapping on \p OS; 71 void print(raw_ostream &OS) const; 72 73 /// Check that the Mask is compatible with the RegBank. 74 /// Indeed, if the RegBank cannot accomadate the "active bits" of the mask, 75 /// there is no way this mapping is valid. 76 /// 77 /// \note This method does not check anything when assertions are disabled. 78 /// 79 /// \return True is the check was successful. 80 bool verify() const; 81 }; 82 83 /// Helper struct that represents how a value is mapped through 84 /// different register banks. 85 struct ValueMapping { 86 /// How the value is broken down between the different register banks. 87 SmallVector<PartialMapping, 2> BreakDown; 88 89 /// Verify that this mapping makes sense for a value of \p ExpectedBitWidth. 90 /// \note This method does not check anything when assertions are disabled. 91 /// 92 /// \return True is the check was successful. 93 bool verify(unsigned ExpectedBitWidth) const; 94 95 /// Print this on dbgs() stream. 96 void dump() const; 97 98 /// Print this on \p OS; 99 void print(raw_ostream &OS) const; 100 }; 101 102 /// Helper class that represents how the value of an instruction may be 103 /// mapped and what is the related cost of such mapping. 104 class InstructionMapping { 105 /// Identifier of the mapping. 106 /// This is used to communicate between the target and the optimizers 107 /// which mapping should be realized. 108 unsigned ID; 109 /// Cost of this mapping. 110 unsigned Cost; 111 /// Mapping of all the operands. 112 std::unique_ptr<ValueMapping[]> OperandsMapping; 113 /// Number of operands. 114 unsigned NumOperands; 115 getOperandMapping(unsigned i)116 ValueMapping &getOperandMapping(unsigned i) { 117 assert(i < getNumOperands() && "Out of bound operand"); 118 return OperandsMapping[i]; 119 } 120 121 public: 122 /// Constructor for the mapping of an instruction. 123 /// \p NumOperands must be equal to number of all the operands of 124 /// the related instruction. 125 /// The rationale is that it is more efficient for the optimizers 126 /// to be able to assume that the mapping of the ith operand is 127 /// at the index i. 128 /// 129 /// \pre ID != InvalidMappingID InstructionMapping(unsigned ID,unsigned Cost,unsigned NumOperands)130 InstructionMapping(unsigned ID, unsigned Cost, unsigned NumOperands) 131 : ID(ID), Cost(Cost), NumOperands(NumOperands) { 132 assert(getID() != InvalidMappingID && 133 "Use the default constructor for invalid mapping"); 134 OperandsMapping.reset(new ValueMapping[getNumOperands()]); 135 } 136 137 /// Default constructor. 138 /// Use this constructor to express that the mapping is invalid. InstructionMapping()139 InstructionMapping() : ID(InvalidMappingID), Cost(0), NumOperands(0) {} 140 141 /// Get the cost. getCost()142 unsigned getCost() const { return Cost; } 143 144 /// Get the ID. getID()145 unsigned getID() const { return ID; } 146 147 /// Get the number of operands. getNumOperands()148 unsigned getNumOperands() const { return NumOperands; } 149 150 /// Get the value mapping of the ith operand. getOperandMapping(unsigned i)151 const ValueMapping &getOperandMapping(unsigned i) const { 152 return const_cast<InstructionMapping *>(this)->getOperandMapping(i); 153 } 154 155 /// Get the value mapping of the ith operand. setOperandMapping(unsigned i,const ValueMapping & ValMapping)156 void setOperandMapping(unsigned i, const ValueMapping &ValMapping) { 157 getOperandMapping(i) = ValMapping; 158 } 159 160 /// Check whether this object is valid. 161 /// This is a lightweight check for obvious wrong instance. isValid()162 bool isValid() const { return getID() != InvalidMappingID; } 163 164 /// Set the operand mapping for the \p OpIdx-th operand. 165 /// The mapping will consist of only one element in the break down list. 166 /// This element will map to \p RegBank and fully define a mask, whose 167 /// bitwidth matches the size of \p MaskSize. 168 void setOperandMapping(unsigned OpIdx, unsigned MaskSize, 169 const RegisterBank &RegBank); 170 171 /// Verifiy that this mapping makes sense for \p MI. 172 /// \pre \p MI must be connected to a MachineFunction. 173 /// 174 /// \note This method does not check anything when assertions are disabled. 175 /// 176 /// \return True is the check was successful. 177 bool verify(const MachineInstr &MI) const; 178 179 /// Print this on dbgs() stream. 180 void dump() const; 181 182 /// Print this on \p OS; 183 void print(raw_ostream &OS) const; 184 }; 185 186 /// Convenient type to represent the alternatives for mapping an 187 /// instruction. 188 /// \todo When we move to TableGen this should be an array ref. 189 typedef SmallVector<InstructionMapping, 4> InstructionMappings; 190 191 /// Helper class use to get/create the virtual registers that will be used 192 /// to replace the MachineOperand when applying a mapping. 193 class OperandsMapper { 194 /// The OpIdx-th cell contains the index in NewVRegs where the VRegs of the 195 /// OpIdx-th operand starts. -1 means we do not have such mapping yet. 196 std::unique_ptr<int[]> OpToNewVRegIdx; 197 /// Hold the registers that will be used to map MI with InstrMapping. 198 SmallVector<unsigned, 8> NewVRegs; 199 /// Current MachineRegisterInfo, used to create new virtual registers. 200 MachineRegisterInfo &MRI; 201 /// Instruction being remapped. 202 MachineInstr &MI; 203 /// New mapping of the instruction. 204 const InstructionMapping &InstrMapping; 205 206 /// Constant value identifying that the index in OpToNewVRegIdx 207 /// for an operand has not been set yet. 208 static const int DontKnowIdx; 209 210 /// Get the range in NewVRegs to store all the partial 211 /// values for the \p OpIdx-th operand. 212 /// 213 /// \return The iterator range for the space created. 214 // 215 /// \pre getMI().getOperand(OpIdx).isReg() 216 iterator_range<SmallVectorImpl<unsigned>::iterator> 217 getVRegsMem(unsigned OpIdx); 218 219 /// Get the end iterator for a range starting at \p StartIdx and 220 /// spannig \p NumVal in NewVRegs. 221 /// \pre StartIdx + NumVal <= NewVRegs.size() 222 SmallVectorImpl<unsigned>::const_iterator 223 getNewVRegsEnd(unsigned StartIdx, unsigned NumVal) const; 224 SmallVectorImpl<unsigned>::iterator getNewVRegsEnd(unsigned StartIdx, 225 unsigned NumVal); 226 227 public: 228 /// Create an OperandsMapper that will hold the information to apply \p 229 /// InstrMapping to \p MI. 230 /// \pre InstrMapping.verify(MI) 231 OperandsMapper(MachineInstr &MI, const InstructionMapping &InstrMapping, 232 MachineRegisterInfo &MRI); 233 234 /// Getters. 235 /// @{ 236 /// The MachineInstr being remapped. getMI()237 MachineInstr &getMI() const { return MI; } 238 239 /// The final mapping of the instruction. getInstrMapping()240 const InstructionMapping &getInstrMapping() const { return InstrMapping; } 241 /// @} 242 243 /// Create as many new virtual registers as needed for the mapping of the \p 244 /// OpIdx-th operand. 245 /// The number of registers is determined by the number of breakdown for the 246 /// related operand in the instruction mapping. 247 /// 248 /// \pre getMI().getOperand(OpIdx).isReg() 249 /// 250 /// \post All the partial mapping of the \p OpIdx-th operand have been 251 /// assigned a new virtual register. 252 void createVRegs(unsigned OpIdx); 253 254 /// Set the virtual register of the \p PartialMapIdx-th partial mapping of 255 /// the OpIdx-th operand to \p NewVReg. 256 /// 257 /// \pre getMI().getOperand(OpIdx).isReg() 258 /// \pre getInstrMapping().getOperandMapping(OpIdx).BreakDown.size() > 259 /// PartialMapIdx 260 /// \pre NewReg != 0 261 /// 262 /// \post the \p PartialMapIdx-th register of the value mapping of the \p 263 /// OpIdx-th operand has been set. 264 void setVRegs(unsigned OpIdx, unsigned PartialMapIdx, unsigned NewVReg); 265 266 /// Get all the virtual registers required to map the \p OpIdx-th operand of 267 /// the instruction. 268 /// 269 /// This return an empty range when createVRegs or setVRegs has not been 270 /// called. 271 /// The iterator may be invalidated by a call to setVRegs or createVRegs. 272 /// 273 /// When \p ForDebug is true, we will not check that the list of new virtual 274 /// registers does not contain uninitialized values. 275 /// 276 /// \pre getMI().getOperand(OpIdx).isReg() 277 /// \pre ForDebug || All partial mappings have been set a register 278 iterator_range<SmallVectorImpl<unsigned>::const_iterator> 279 getVRegs(unsigned OpIdx, bool ForDebug = false) const; 280 281 /// Print this operands mapper on dbgs() stream. 282 void dump() const; 283 284 /// Print this operands mapper on \p OS stream. 285 void print(raw_ostream &OS, bool ForDebug = false) const; 286 }; 287 288 protected: 289 /// Hold the set of supported register banks. 290 std::unique_ptr<RegisterBank[]> RegBanks; 291 /// Total number of register banks. 292 unsigned NumRegBanks; 293 294 /// Mapping from MVT::SimpleValueType to register banks. 295 std::unique_ptr<const RegisterBank *[]> VTToRegBank; 296 297 /// Create a RegisterBankInfo that can accomodate up to \p NumRegBanks 298 /// RegisterBank instances. 299 /// 300 /// \note For the verify method to succeed all the \p NumRegBanks 301 /// must be initialized by createRegisterBank and updated with 302 /// addRegBankCoverage RegisterBank. 303 RegisterBankInfo(unsigned NumRegBanks); 304 305 /// This constructor is meaningless. 306 /// It just provides a default constructor that can be used at link time 307 /// when GlobalISel is not built. 308 /// That way, targets can still inherit from this class without doing 309 /// crazy gymnastic to avoid link time failures. 310 /// \note That works because the constructor is inlined. RegisterBankInfo()311 RegisterBankInfo() { 312 llvm_unreachable("This constructor should not be executed"); 313 } 314 315 /// Create a new register bank with the given parameter and add it 316 /// to RegBanks. 317 /// \pre \p ID must not already be used. 318 /// \pre \p ID < NumRegBanks. 319 void createRegisterBank(unsigned ID, const char *Name); 320 321 /// Add \p RCId to the set of register class that the register bank, 322 /// identified \p ID, covers. 323 /// This method transitively adds all the sub classes and the subreg-classes 324 /// of \p RCId to the set of covered register classes. 325 /// It also adjusts the size of the register bank to reflect the maximal 326 /// size of a value that can be hold into that register bank. 327 /// 328 /// If \p AddTypeMapping is true, this method also records what types can 329 /// be mapped to \p ID. Although this done by default, targets may want to 330 /// disable it, espicially if a given type may be mapped on different 331 /// register bank. Indeed, in such case, this method only records the 332 /// first register bank where the type matches. 333 /// This information is only used to provide default mapping 334 /// (see getInstrMappingImpl). 335 /// 336 /// \note This method does *not* add the super classes of \p RCId. 337 /// The rationale is if \p ID covers the registers of \p RCId, that 338 /// does not necessarily mean that \p ID covers the set of registers 339 /// of RCId's superclasses. 340 /// This method does *not* add the superreg classes as well for consistents. 341 /// The expected use is to add the coverage top-down with respect to the 342 /// register hierarchy. 343 /// 344 /// \todo TableGen should just generate the BitSet vector for us. 345 void addRegBankCoverage(unsigned ID, unsigned RCId, 346 const TargetRegisterInfo &TRI, 347 bool AddTypeMapping = true); 348 349 /// Get the register bank identified by \p ID. getRegBank(unsigned ID)350 RegisterBank &getRegBank(unsigned ID) { 351 assert(ID < getNumRegBanks() && "Accessing an unknown register bank"); 352 return RegBanks[ID]; 353 } 354 355 /// Get the register bank that has been recorded to cover \p SVT. getRegBankForType(MVT::SimpleValueType SVT)356 const RegisterBank *getRegBankForType(MVT::SimpleValueType SVT) const { 357 if (!VTToRegBank) 358 return nullptr; 359 assert(SVT < MVT::SimpleValueType::LAST_VALUETYPE && "Out-of-bound access"); 360 return VTToRegBank.get()[SVT]; 361 } 362 363 /// Record \p RegBank as the register bank that covers \p SVT. 364 /// If a record was already set for \p SVT, the mapping is not 365 /// updated, unless \p Force == true 366 /// 367 /// \post if getRegBankForType(SVT)\@pre == nullptr then 368 /// getRegBankForType(SVT) == &RegBank 369 /// \post if Force == true then getRegBankForType(SVT) == &RegBank 370 void recordRegBankForType(const RegisterBank &RegBank, 371 MVT::SimpleValueType SVT, bool Force = false) { 372 if (!VTToRegBank) { 373 VTToRegBank.reset( 374 new const RegisterBank *[MVT::SimpleValueType::LAST_VALUETYPE]); 375 std::fill(&VTToRegBank[0], 376 &VTToRegBank[MVT::SimpleValueType::LAST_VALUETYPE], nullptr); 377 } 378 assert(SVT < MVT::SimpleValueType::LAST_VALUETYPE && "Out-of-bound access"); 379 // If we want to override the mapping or the mapping does not exits yet, 380 // set the register bank for SVT. 381 if (Force || !getRegBankForType(SVT)) 382 VTToRegBank.get()[SVT] = &RegBank; 383 } 384 385 /// Try to get the mapping of \p MI. 386 /// See getInstrMapping for more details on what a mapping represents. 387 /// 388 /// Unlike getInstrMapping the returned InstructionMapping may be invalid 389 /// (isValid() == false). 390 /// This means that the target independent code is not smart enough 391 /// to get the mapping of \p MI and thus, the target has to provide the 392 /// information for \p MI. 393 /// 394 /// This implementation is able to get the mapping of: 395 /// - Target specific instructions by looking at the encoding constraints. 396 /// - Any instruction if all the register operands are already been assigned 397 /// a register, a register class, or a register bank. 398 /// - Copies and phis if at least one of the operand has been assigned a 399 /// register, a register class, or a register bank. 400 /// In other words, this method will likely fail to find a mapping for 401 /// any generic opcode that has not been lowered by target specific code. 402 InstructionMapping getInstrMappingImpl(const MachineInstr &MI) const; 403 404 /// Get the register bank for the \p OpIdx-th operand of \p MI form 405 /// the encoding constraints, if any. 406 /// 407 /// \return A register bank that covers the register class of the 408 /// related encoding constraints or nullptr if \p MI did not provide 409 /// enough information to deduce it. 410 const RegisterBank * 411 getRegBankFromConstraints(const MachineInstr &MI, unsigned OpIdx, 412 const TargetInstrInfo &TII, 413 const TargetRegisterInfo &TRI) const; 414 415 /// Helper method to apply something that is like the default mapping. 416 /// Basically, that means that \p OpdMapper.getMI() is left untouched 417 /// aside from the reassignment of the register operand that have been 418 /// remapped. 419 /// If the mapping of one of the operand spans several registers, this 420 /// method will abort as this is not like a default mapping anymore. 421 /// 422 /// \pre For OpIdx in {0..\p OpdMapper.getMI().getNumOperands()) 423 /// the range OpdMapper.getVRegs(OpIdx) is empty or of size 1. 424 static void applyDefaultMapping(const OperandsMapper &OpdMapper); 425 426 /// See ::applyMapping. applyMappingImpl(const OperandsMapper & OpdMapper)427 virtual void applyMappingImpl(const OperandsMapper &OpdMapper) const { 428 llvm_unreachable("The target has to implement that part"); 429 } 430 431 public: ~RegisterBankInfo()432 virtual ~RegisterBankInfo() {} 433 434 /// Get the register bank identified by \p ID. getRegBank(unsigned ID)435 const RegisterBank &getRegBank(unsigned ID) const { 436 return const_cast<RegisterBankInfo *>(this)->getRegBank(ID); 437 } 438 439 /// Get the register bank of \p Reg. 440 /// If Reg has not been assigned a register, a register class, 441 /// or a register bank, then this returns nullptr. 442 /// 443 /// \pre Reg != 0 (NoRegister) 444 const RegisterBank *getRegBank(unsigned Reg, const MachineRegisterInfo &MRI, 445 const TargetRegisterInfo &TRI) const; 446 447 /// Get the total number of register banks. getNumRegBanks()448 unsigned getNumRegBanks() const { return NumRegBanks; } 449 450 /// Get a register bank that covers \p RC. 451 /// 452 /// \pre \p RC is a user-defined register class (as opposed as one 453 /// generated by TableGen). 454 /// 455 /// \note The mapping RC -> RegBank could be built while adding the 456 /// coverage for the register banks. However, we do not do it, because, 457 /// at least for now, we only need this information for register classes 458 /// that are used in the description of instruction. In other words, 459 /// there are just a handful of them and we do not want to waste space. 460 /// 461 /// \todo This should be TableGen'ed. 462 virtual const RegisterBank & getRegBankFromRegClass(const TargetRegisterClass & RC)463 getRegBankFromRegClass(const TargetRegisterClass &RC) const { 464 llvm_unreachable("The target must override this method"); 465 } 466 467 /// Get the cost of a copy from \p B to \p A, or put differently, 468 /// get the cost of A = COPY B. Since register banks may cover 469 /// different size, \p Size specifies what will be the size in bits 470 /// that will be copied around. 471 /// 472 /// \note Since this is a copy, both registers have the same size. copyCost(const RegisterBank & A,const RegisterBank & B,unsigned Size)473 virtual unsigned copyCost(const RegisterBank &A, const RegisterBank &B, 474 unsigned Size) const { 475 // Optimistically assume that copies are coalesced. I.e., when 476 // they are on the same bank, they are free. 477 // Otherwise assume a non-zero cost of 1. The targets are supposed 478 // to override that properly anyway if they care. 479 return &A != &B; 480 } 481 482 /// Identifier used when the related instruction mapping instance 483 /// is generated by target independent code. 484 /// Make sure not to use that identifier to avoid possible collision. 485 static const unsigned DefaultMappingID; 486 487 /// Identifier used when the related instruction mapping instance 488 /// is generated by the default constructor. 489 /// Make sure not to use that identifier. 490 static const unsigned InvalidMappingID; 491 492 /// Get the mapping of the different operands of \p MI 493 /// on the register bank. 494 /// This mapping should be the direct translation of \p MI. 495 /// In other words, when \p MI is mapped with the returned mapping, 496 /// only the register banks of the operands of \p MI need to be updated. 497 /// In particular, neither the opcode or the type of \p MI needs to be 498 /// updated for this direct mapping. 499 /// 500 /// The target independent implementation gives a mapping based on 501 /// the register classes for the target specific opcode. 502 /// It uses the ID RegisterBankInfo::DefaultMappingID for that mapping. 503 /// Make sure you do not use that ID for the alternative mapping 504 /// for MI. See getInstrAlternativeMappings for the alternative 505 /// mappings. 506 /// 507 /// For instance, if \p MI is a vector add, the mapping should 508 /// not be a scalarization of the add. 509 /// 510 /// \post returnedVal.verify(MI). 511 /// 512 /// \note If returnedVal does not verify MI, this would probably mean 513 /// that the target does not support that instruction. 514 virtual InstructionMapping getInstrMapping(const MachineInstr &MI) const; 515 516 /// Get the alternative mappings for \p MI. 517 /// Alternative in the sense different from getInstrMapping. 518 virtual InstructionMappings 519 getInstrAlternativeMappings(const MachineInstr &MI) const; 520 521 /// Get the possible mapping for \p MI. 522 /// A mapping defines where the different operands may live and at what cost. 523 /// For instance, let us consider: 524 /// v0(16) = G_ADD <2 x i8> v1, v2 525 /// The possible mapping could be: 526 /// 527 /// {/*ID*/VectorAdd, /*Cost*/1, /*v0*/{(0xFFFF, VPR)}, /*v1*/{(0xFFFF, VPR)}, 528 /// /*v2*/{(0xFFFF, VPR)}} 529 /// {/*ID*/ScalarAddx2, /*Cost*/2, /*v0*/{(0x00FF, GPR),(0xFF00, GPR)}, 530 /// /*v1*/{(0x00FF, GPR),(0xFF00, GPR)}, 531 /// /*v2*/{(0x00FF, GPR),(0xFF00, GPR)}} 532 /// 533 /// \note The first alternative of the returned mapping should be the 534 /// direct translation of \p MI current form. 535 /// 536 /// \post !returnedVal.empty(). 537 InstructionMappings getInstrPossibleMappings(const MachineInstr &MI) const; 538 539 /// Apply \p OpdMapper.getInstrMapping() to \p OpdMapper.getMI(). 540 /// After this call \p OpdMapper.getMI() may not be valid anymore. 541 /// \p OpdMapper.getInstrMapping().getID() carries the information of 542 /// what has been chosen to map \p OpdMapper.getMI(). This ID is set 543 /// by the various getInstrXXXMapping method. 544 /// 545 /// Therefore, getting the mapping and applying it should be kept in 546 /// sync. applyMapping(const OperandsMapper & OpdMapper)547 void applyMapping(const OperandsMapper &OpdMapper) const { 548 // The only mapping we know how to handle is the default mapping. 549 if (OpdMapper.getInstrMapping().getID() == DefaultMappingID) 550 return applyDefaultMapping(OpdMapper); 551 // For other mapping, the target needs to do the right thing. 552 // If that means calling applyDefaultMapping, fine, but this 553 // must be explicitly stated. 554 applyMappingImpl(OpdMapper); 555 } 556 557 /// Get the size in bits of \p Reg. 558 /// Utility method to get the size of any registers. Unlike 559 /// MachineRegisterInfo::getSize, the register does not need to be a 560 /// virtual register. 561 /// 562 /// \pre \p Reg != 0 (NoRegister). 563 static unsigned getSizeInBits(unsigned Reg, const MachineRegisterInfo &MRI, 564 const TargetRegisterInfo &TRI); 565 566 /// Check that information hold by this instance make sense for the 567 /// given \p TRI. 568 /// 569 /// \note This method does not check anything when assertions are disabled. 570 /// 571 /// \return True is the check was successful. 572 bool verify(const TargetRegisterInfo &TRI) const; 573 }; 574 575 inline raw_ostream & 576 operator<<(raw_ostream &OS, 577 const RegisterBankInfo::PartialMapping &PartMapping) { 578 PartMapping.print(OS); 579 return OS; 580 } 581 582 inline raw_ostream & 583 operator<<(raw_ostream &OS, const RegisterBankInfo::ValueMapping &ValMapping) { 584 ValMapping.print(OS); 585 return OS; 586 } 587 588 inline raw_ostream & 589 operator<<(raw_ostream &OS, 590 const RegisterBankInfo::InstructionMapping &InstrMapping) { 591 InstrMapping.print(OS); 592 return OS; 593 } 594 595 inline raw_ostream & 596 operator<<(raw_ostream &OS, const RegisterBankInfo::OperandsMapper &OpdMapper) { 597 OpdMapper.print(OS, /*ForDebug*/ false); 598 return OS; 599 } 600 } // End namespace llvm. 601 602 #endif 603