1 //===- InstructionCombining.cpp - Combine multiple instructions -----------===// 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 // InstructionCombining - Combine instructions to form fewer, simple 11 // instructions. This pass does not modify the CFG. This pass is where 12 // algebraic simplification happens. 13 // 14 // This pass combines things like: 15 // %Y = add i32 %X, 1 16 // %Z = add i32 %Y, 1 17 // into: 18 // %Z = add i32 %X, 2 19 // 20 // This is a simple worklist driven algorithm. 21 // 22 // This pass guarantees that the following canonicalizations are performed on 23 // the program: 24 // 1. If a binary operator has a constant operand, it is moved to the RHS 25 // 2. Bitwise operators with constant operands are always grouped so that 26 // shifts are performed first, then or's, then and's, then xor's. 27 // 3. Compare instructions are converted from <,>,<=,>= to ==,!= if possible 28 // 4. All cmp instructions on boolean values are replaced with logical ops 29 // 5. add X, X is represented as (X*2) => (X << 1) 30 // 6. Multiplies with a power-of-two constant argument are transformed into 31 // shifts. 32 // ... etc. 33 // 34 //===----------------------------------------------------------------------===// 35 36 #include "llvm/Transforms/InstCombine/InstCombine.h" 37 #include "InstCombineInternal.h" 38 #include "llvm-c/Initialization.h" 39 #include "llvm/ADT/SmallPtrSet.h" 40 #include "llvm/ADT/Statistic.h" 41 #include "llvm/ADT/StringSwitch.h" 42 #include "llvm/Analysis/AliasAnalysis.h" 43 #include "llvm/Analysis/AssumptionCache.h" 44 #include "llvm/Analysis/BasicAliasAnalysis.h" 45 #include "llvm/Analysis/CFG.h" 46 #include "llvm/Analysis/ConstantFolding.h" 47 #include "llvm/Analysis/EHPersonalities.h" 48 #include "llvm/Analysis/GlobalsModRef.h" 49 #include "llvm/Analysis/InstructionSimplify.h" 50 #include "llvm/Analysis/LoopInfo.h" 51 #include "llvm/Analysis/MemoryBuiltins.h" 52 #include "llvm/Analysis/TargetLibraryInfo.h" 53 #include "llvm/Analysis/ValueTracking.h" 54 #include "llvm/IR/CFG.h" 55 #include "llvm/IR/DataLayout.h" 56 #include "llvm/IR/Dominators.h" 57 #include "llvm/IR/GetElementPtrTypeIterator.h" 58 #include "llvm/IR/IntrinsicInst.h" 59 #include "llvm/IR/PatternMatch.h" 60 #include "llvm/IR/ValueHandle.h" 61 #include "llvm/Support/CommandLine.h" 62 #include "llvm/Support/Debug.h" 63 #include "llvm/Support/raw_ostream.h" 64 #include "llvm/Transforms/Scalar.h" 65 #include "llvm/Transforms/Utils/Local.h" 66 #include <algorithm> 67 #include <climits> 68 using namespace llvm; 69 using namespace llvm::PatternMatch; 70 71 #define DEBUG_TYPE "instcombine" 72 73 STATISTIC(NumCombined , "Number of insts combined"); 74 STATISTIC(NumConstProp, "Number of constant folds"); 75 STATISTIC(NumDeadInst , "Number of dead inst eliminated"); 76 STATISTIC(NumSunkInst , "Number of instructions sunk"); 77 STATISTIC(NumExpand, "Number of expansions"); 78 STATISTIC(NumFactor , "Number of factorizations"); 79 STATISTIC(NumReassoc , "Number of reassociations"); 80 81 static cl::opt<bool> 82 EnableExpensiveCombines("expensive-combines", 83 cl::desc("Enable expensive instruction combines")); 84 85 static cl::opt<unsigned> 86 MaxArraySize("instcombine-maxarray-size", cl::init(1024), 87 cl::desc("Maximum array size considered when doing a combine")); 88 89 Value *InstCombiner::EmitGEPOffset(User *GEP) { 90 return llvm::EmitGEPOffset(Builder, DL, GEP); 91 } 92 93 /// Return true if it is desirable to convert an integer computation from a 94 /// given bit width to a new bit width. 95 /// We don't want to convert from a legal to an illegal type or from a smaller 96 /// to a larger illegal type. A width of '1' is always treated as a legal type 97 /// because i1 is a fundamental type in IR, and there are many specialized 98 /// optimizations for i1 types. 99 bool InstCombiner::shouldChangeType(unsigned FromWidth, 100 unsigned ToWidth) const { 101 bool FromLegal = FromWidth == 1 || DL.isLegalInteger(FromWidth); 102 bool ToLegal = ToWidth == 1 || DL.isLegalInteger(ToWidth); 103 104 // If this is a legal integer from type, and the result would be an illegal 105 // type, don't do the transformation. 106 if (FromLegal && !ToLegal) 107 return false; 108 109 // Otherwise, if both are illegal, do not increase the size of the result. We 110 // do allow things like i160 -> i64, but not i64 -> i160. 111 if (!FromLegal && !ToLegal && ToWidth > FromWidth) 112 return false; 113 114 return true; 115 } 116 117 /// Return true if it is desirable to convert a computation from 'From' to 'To'. 118 /// We don't want to convert from a legal to an illegal type or from a smaller 119 /// to a larger illegal type. i1 is always treated as a legal type because it is 120 /// a fundamental type in IR, and there are many specialized optimizations for 121 /// i1 types. 122 bool InstCombiner::shouldChangeType(Type *From, Type *To) const { 123 assert(From->isIntegerTy() && To->isIntegerTy()); 124 125 unsigned FromWidth = From->getPrimitiveSizeInBits(); 126 unsigned ToWidth = To->getPrimitiveSizeInBits(); 127 return shouldChangeType(FromWidth, ToWidth); 128 } 129 130 // Return true, if No Signed Wrap should be maintained for I. 131 // The No Signed Wrap flag can be kept if the operation "B (I.getOpcode) C", 132 // where both B and C should be ConstantInts, results in a constant that does 133 // not overflow. This function only handles the Add and Sub opcodes. For 134 // all other opcodes, the function conservatively returns false. 135 static bool MaintainNoSignedWrap(BinaryOperator &I, Value *B, Value *C) { 136 OverflowingBinaryOperator *OBO = dyn_cast<OverflowingBinaryOperator>(&I); 137 if (!OBO || !OBO->hasNoSignedWrap()) 138 return false; 139 140 // We reason about Add and Sub Only. 141 Instruction::BinaryOps Opcode = I.getOpcode(); 142 if (Opcode != Instruction::Add && Opcode != Instruction::Sub) 143 return false; 144 145 const APInt *BVal, *CVal; 146 if (!match(B, m_APInt(BVal)) || !match(C, m_APInt(CVal))) 147 return false; 148 149 bool Overflow = false; 150 if (Opcode == Instruction::Add) 151 BVal->sadd_ov(*CVal, Overflow); 152 else 153 BVal->ssub_ov(*CVal, Overflow); 154 155 return !Overflow; 156 } 157 158 /// Conservatively clears subclassOptionalData after a reassociation or 159 /// commutation. We preserve fast-math flags when applicable as they can be 160 /// preserved. 161 static void ClearSubclassDataAfterReassociation(BinaryOperator &I) { 162 FPMathOperator *FPMO = dyn_cast<FPMathOperator>(&I); 163 if (!FPMO) { 164 I.clearSubclassOptionalData(); 165 return; 166 } 167 168 FastMathFlags FMF = I.getFastMathFlags(); 169 I.clearSubclassOptionalData(); 170 I.setFastMathFlags(FMF); 171 } 172 173 /// Combine constant operands of associative operations either before or after a 174 /// cast to eliminate one of the associative operations: 175 /// (op (cast (op X, C2)), C1) --> (cast (op X, op (C1, C2))) 176 /// (op (cast (op X, C2)), C1) --> (op (cast X), op (C1, C2)) 177 static bool simplifyAssocCastAssoc(BinaryOperator *BinOp1) { 178 auto *Cast = dyn_cast<CastInst>(BinOp1->getOperand(0)); 179 if (!Cast || !Cast->hasOneUse()) 180 return false; 181 182 // TODO: Enhance logic for other casts and remove this check. 183 auto CastOpcode = Cast->getOpcode(); 184 if (CastOpcode != Instruction::ZExt) 185 return false; 186 187 // TODO: Enhance logic for other BinOps and remove this check. 188 if (!BinOp1->isBitwiseLogicOp()) 189 return false; 190 191 auto AssocOpcode = BinOp1->getOpcode(); 192 auto *BinOp2 = dyn_cast<BinaryOperator>(Cast->getOperand(0)); 193 if (!BinOp2 || !BinOp2->hasOneUse() || BinOp2->getOpcode() != AssocOpcode) 194 return false; 195 196 Constant *C1, *C2; 197 if (!match(BinOp1->getOperand(1), m_Constant(C1)) || 198 !match(BinOp2->getOperand(1), m_Constant(C2))) 199 return false; 200 201 // TODO: This assumes a zext cast. 202 // Eg, if it was a trunc, we'd cast C1 to the source type because casting C2 203 // to the destination type might lose bits. 204 205 // Fold the constants together in the destination type: 206 // (op (cast (op X, C2)), C1) --> (op (cast X), FoldedC) 207 Type *DestTy = C1->getType(); 208 Constant *CastC2 = ConstantExpr::getCast(CastOpcode, C2, DestTy); 209 Constant *FoldedC = ConstantExpr::get(AssocOpcode, C1, CastC2); 210 Cast->setOperand(0, BinOp2->getOperand(0)); 211 BinOp1->setOperand(1, FoldedC); 212 return true; 213 } 214 215 /// This performs a few simplifications for operators that are associative or 216 /// commutative: 217 /// 218 /// Commutative operators: 219 /// 220 /// 1. Order operands such that they are listed from right (least complex) to 221 /// left (most complex). This puts constants before unary operators before 222 /// binary operators. 223 /// 224 /// Associative operators: 225 /// 226 /// 2. Transform: "(A op B) op C" ==> "A op (B op C)" if "B op C" simplifies. 227 /// 3. Transform: "A op (B op C)" ==> "(A op B) op C" if "A op B" simplifies. 228 /// 229 /// Associative and commutative operators: 230 /// 231 /// 4. Transform: "(A op B) op C" ==> "(C op A) op B" if "C op A" simplifies. 232 /// 5. Transform: "A op (B op C)" ==> "B op (C op A)" if "C op A" simplifies. 233 /// 6. Transform: "(A op C1) op (B op C2)" ==> "(A op B) op (C1 op C2)" 234 /// if C1 and C2 are constants. 235 bool InstCombiner::SimplifyAssociativeOrCommutative(BinaryOperator &I) { 236 Instruction::BinaryOps Opcode = I.getOpcode(); 237 bool Changed = false; 238 239 do { 240 // Order operands such that they are listed from right (least complex) to 241 // left (most complex). This puts constants before unary operators before 242 // binary operators. 243 if (I.isCommutative() && getComplexity(I.getOperand(0)) < 244 getComplexity(I.getOperand(1))) 245 Changed = !I.swapOperands(); 246 247 BinaryOperator *Op0 = dyn_cast<BinaryOperator>(I.getOperand(0)); 248 BinaryOperator *Op1 = dyn_cast<BinaryOperator>(I.getOperand(1)); 249 250 if (I.isAssociative()) { 251 // Transform: "(A op B) op C" ==> "A op (B op C)" if "B op C" simplifies. 252 if (Op0 && Op0->getOpcode() == Opcode) { 253 Value *A = Op0->getOperand(0); 254 Value *B = Op0->getOperand(1); 255 Value *C = I.getOperand(1); 256 257 // Does "B op C" simplify? 258 if (Value *V = SimplifyBinOp(Opcode, B, C, DL)) { 259 // It simplifies to V. Form "A op V". 260 I.setOperand(0, A); 261 I.setOperand(1, V); 262 // Conservatively clear the optional flags, since they may not be 263 // preserved by the reassociation. 264 if (MaintainNoSignedWrap(I, B, C) && 265 (!Op0 || (isa<BinaryOperator>(Op0) && Op0->hasNoSignedWrap()))) { 266 // Note: this is only valid because SimplifyBinOp doesn't look at 267 // the operands to Op0. 268 I.clearSubclassOptionalData(); 269 I.setHasNoSignedWrap(true); 270 } else { 271 ClearSubclassDataAfterReassociation(I); 272 } 273 274 Changed = true; 275 ++NumReassoc; 276 continue; 277 } 278 } 279 280 // Transform: "A op (B op C)" ==> "(A op B) op C" if "A op B" simplifies. 281 if (Op1 && Op1->getOpcode() == Opcode) { 282 Value *A = I.getOperand(0); 283 Value *B = Op1->getOperand(0); 284 Value *C = Op1->getOperand(1); 285 286 // Does "A op B" simplify? 287 if (Value *V = SimplifyBinOp(Opcode, A, B, DL)) { 288 // It simplifies to V. Form "V op C". 289 I.setOperand(0, V); 290 I.setOperand(1, C); 291 // Conservatively clear the optional flags, since they may not be 292 // preserved by the reassociation. 293 ClearSubclassDataAfterReassociation(I); 294 Changed = true; 295 ++NumReassoc; 296 continue; 297 } 298 } 299 } 300 301 if (I.isAssociative() && I.isCommutative()) { 302 if (simplifyAssocCastAssoc(&I)) { 303 Changed = true; 304 ++NumReassoc; 305 continue; 306 } 307 308 // Transform: "(A op B) op C" ==> "(C op A) op B" if "C op A" simplifies. 309 if (Op0 && Op0->getOpcode() == Opcode) { 310 Value *A = Op0->getOperand(0); 311 Value *B = Op0->getOperand(1); 312 Value *C = I.getOperand(1); 313 314 // Does "C op A" simplify? 315 if (Value *V = SimplifyBinOp(Opcode, C, A, DL)) { 316 // It simplifies to V. Form "V op B". 317 I.setOperand(0, V); 318 I.setOperand(1, B); 319 // Conservatively clear the optional flags, since they may not be 320 // preserved by the reassociation. 321 ClearSubclassDataAfterReassociation(I); 322 Changed = true; 323 ++NumReassoc; 324 continue; 325 } 326 } 327 328 // Transform: "A op (B op C)" ==> "B op (C op A)" if "C op A" simplifies. 329 if (Op1 && Op1->getOpcode() == Opcode) { 330 Value *A = I.getOperand(0); 331 Value *B = Op1->getOperand(0); 332 Value *C = Op1->getOperand(1); 333 334 // Does "C op A" simplify? 335 if (Value *V = SimplifyBinOp(Opcode, C, A, DL)) { 336 // It simplifies to V. Form "B op V". 337 I.setOperand(0, B); 338 I.setOperand(1, V); 339 // Conservatively clear the optional flags, since they may not be 340 // preserved by the reassociation. 341 ClearSubclassDataAfterReassociation(I); 342 Changed = true; 343 ++NumReassoc; 344 continue; 345 } 346 } 347 348 // Transform: "(A op C1) op (B op C2)" ==> "(A op B) op (C1 op C2)" 349 // if C1 and C2 are constants. 350 if (Op0 && Op1 && 351 Op0->getOpcode() == Opcode && Op1->getOpcode() == Opcode && 352 isa<Constant>(Op0->getOperand(1)) && 353 isa<Constant>(Op1->getOperand(1)) && 354 Op0->hasOneUse() && Op1->hasOneUse()) { 355 Value *A = Op0->getOperand(0); 356 Constant *C1 = cast<Constant>(Op0->getOperand(1)); 357 Value *B = Op1->getOperand(0); 358 Constant *C2 = cast<Constant>(Op1->getOperand(1)); 359 360 Constant *Folded = ConstantExpr::get(Opcode, C1, C2); 361 BinaryOperator *New = BinaryOperator::Create(Opcode, A, B); 362 if (isa<FPMathOperator>(New)) { 363 FastMathFlags Flags = I.getFastMathFlags(); 364 Flags &= Op0->getFastMathFlags(); 365 Flags &= Op1->getFastMathFlags(); 366 New->setFastMathFlags(Flags); 367 } 368 InsertNewInstWith(New, I); 369 New->takeName(Op1); 370 I.setOperand(0, New); 371 I.setOperand(1, Folded); 372 // Conservatively clear the optional flags, since they may not be 373 // preserved by the reassociation. 374 ClearSubclassDataAfterReassociation(I); 375 376 Changed = true; 377 continue; 378 } 379 } 380 381 // No further simplifications. 382 return Changed; 383 } while (1); 384 } 385 386 /// Return whether "X LOp (Y ROp Z)" is always equal to 387 /// "(X LOp Y) ROp (X LOp Z)". 388 static bool LeftDistributesOverRight(Instruction::BinaryOps LOp, 389 Instruction::BinaryOps ROp) { 390 switch (LOp) { 391 default: 392 return false; 393 394 case Instruction::And: 395 // And distributes over Or and Xor. 396 switch (ROp) { 397 default: 398 return false; 399 case Instruction::Or: 400 case Instruction::Xor: 401 return true; 402 } 403 404 case Instruction::Mul: 405 // Multiplication distributes over addition and subtraction. 406 switch (ROp) { 407 default: 408 return false; 409 case Instruction::Add: 410 case Instruction::Sub: 411 return true; 412 } 413 414 case Instruction::Or: 415 // Or distributes over And. 416 switch (ROp) { 417 default: 418 return false; 419 case Instruction::And: 420 return true; 421 } 422 } 423 } 424 425 /// Return whether "(X LOp Y) ROp Z" is always equal to 426 /// "(X ROp Z) LOp (Y ROp Z)". 427 static bool RightDistributesOverLeft(Instruction::BinaryOps LOp, 428 Instruction::BinaryOps ROp) { 429 if (Instruction::isCommutative(ROp)) 430 return LeftDistributesOverRight(ROp, LOp); 431 432 switch (LOp) { 433 default: 434 return false; 435 // (X >> Z) & (Y >> Z) -> (X&Y) >> Z for all shifts. 436 // (X >> Z) | (Y >> Z) -> (X|Y) >> Z for all shifts. 437 // (X >> Z) ^ (Y >> Z) -> (X^Y) >> Z for all shifts. 438 case Instruction::And: 439 case Instruction::Or: 440 case Instruction::Xor: 441 switch (ROp) { 442 default: 443 return false; 444 case Instruction::Shl: 445 case Instruction::LShr: 446 case Instruction::AShr: 447 return true; 448 } 449 } 450 // TODO: It would be nice to handle division, aka "(X + Y)/Z = X/Z + Y/Z", 451 // but this requires knowing that the addition does not overflow and other 452 // such subtleties. 453 return false; 454 } 455 456 /// This function returns identity value for given opcode, which can be used to 457 /// factor patterns like (X * 2) + X ==> (X * 2) + (X * 1) ==> X * (2 + 1). 458 static Value *getIdentityValue(Instruction::BinaryOps OpCode, Value *V) { 459 if (isa<Constant>(V)) 460 return nullptr; 461 462 if (OpCode == Instruction::Mul) 463 return ConstantInt::get(V->getType(), 1); 464 465 // TODO: We can handle other cases e.g. Instruction::And, Instruction::Or etc. 466 467 return nullptr; 468 } 469 470 /// This function factors binary ops which can be combined using distributive 471 /// laws. This function tries to transform 'Op' based TopLevelOpcode to enable 472 /// factorization e.g for ADD(SHL(X , 2), MUL(X, 5)), When this function called 473 /// with TopLevelOpcode == Instruction::Add and Op = SHL(X, 2), transforms 474 /// SHL(X, 2) to MUL(X, 4) i.e. returns Instruction::Mul with LHS set to 'X' and 475 /// RHS to 4. 476 static Instruction::BinaryOps 477 getBinOpsForFactorization(Instruction::BinaryOps TopLevelOpcode, 478 BinaryOperator *Op, Value *&LHS, Value *&RHS) { 479 if (!Op) 480 return Instruction::BinaryOpsEnd; 481 482 LHS = Op->getOperand(0); 483 RHS = Op->getOperand(1); 484 485 switch (TopLevelOpcode) { 486 default: 487 return Op->getOpcode(); 488 489 case Instruction::Add: 490 case Instruction::Sub: 491 if (Op->getOpcode() == Instruction::Shl) { 492 if (Constant *CST = dyn_cast<Constant>(Op->getOperand(1))) { 493 // The multiplier is really 1 << CST. 494 RHS = ConstantExpr::getShl(ConstantInt::get(Op->getType(), 1), CST); 495 return Instruction::Mul; 496 } 497 } 498 return Op->getOpcode(); 499 } 500 501 // TODO: We can add other conversions e.g. shr => div etc. 502 } 503 504 /// This tries to simplify binary operations by factorizing out common terms 505 /// (e. g. "(A*B)+(A*C)" -> "A*(B+C)"). 506 static Value *tryFactorization(InstCombiner::BuilderTy *Builder, 507 const DataLayout &DL, BinaryOperator &I, 508 Instruction::BinaryOps InnerOpcode, Value *A, 509 Value *B, Value *C, Value *D) { 510 511 // If any of A, B, C, D are null, we can not factor I, return early. 512 // Checking A and C should be enough. 513 if (!A || !C || !B || !D) 514 return nullptr; 515 516 Value *V = nullptr; 517 Value *SimplifiedInst = nullptr; 518 Value *LHS = I.getOperand(0), *RHS = I.getOperand(1); 519 Instruction::BinaryOps TopLevelOpcode = I.getOpcode(); 520 521 // Does "X op' Y" always equal "Y op' X"? 522 bool InnerCommutative = Instruction::isCommutative(InnerOpcode); 523 524 // Does "X op' (Y op Z)" always equal "(X op' Y) op (X op' Z)"? 525 if (LeftDistributesOverRight(InnerOpcode, TopLevelOpcode)) 526 // Does the instruction have the form "(A op' B) op (A op' D)" or, in the 527 // commutative case, "(A op' B) op (C op' A)"? 528 if (A == C || (InnerCommutative && A == D)) { 529 if (A != C) 530 std::swap(C, D); 531 // Consider forming "A op' (B op D)". 532 // If "B op D" simplifies then it can be formed with no cost. 533 V = SimplifyBinOp(TopLevelOpcode, B, D, DL); 534 // If "B op D" doesn't simplify then only go on if both of the existing 535 // operations "A op' B" and "C op' D" will be zapped as no longer used. 536 if (!V && LHS->hasOneUse() && RHS->hasOneUse()) 537 V = Builder->CreateBinOp(TopLevelOpcode, B, D, RHS->getName()); 538 if (V) { 539 SimplifiedInst = Builder->CreateBinOp(InnerOpcode, A, V); 540 } 541 } 542 543 // Does "(X op Y) op' Z" always equal "(X op' Z) op (Y op' Z)"? 544 if (!SimplifiedInst && RightDistributesOverLeft(TopLevelOpcode, InnerOpcode)) 545 // Does the instruction have the form "(A op' B) op (C op' B)" or, in the 546 // commutative case, "(A op' B) op (B op' D)"? 547 if (B == D || (InnerCommutative && B == C)) { 548 if (B != D) 549 std::swap(C, D); 550 // Consider forming "(A op C) op' B". 551 // If "A op C" simplifies then it can be formed with no cost. 552 V = SimplifyBinOp(TopLevelOpcode, A, C, DL); 553 554 // If "A op C" doesn't simplify then only go on if both of the existing 555 // operations "A op' B" and "C op' D" will be zapped as no longer used. 556 if (!V && LHS->hasOneUse() && RHS->hasOneUse()) 557 V = Builder->CreateBinOp(TopLevelOpcode, A, C, LHS->getName()); 558 if (V) { 559 SimplifiedInst = Builder->CreateBinOp(InnerOpcode, V, B); 560 } 561 } 562 563 if (SimplifiedInst) { 564 ++NumFactor; 565 SimplifiedInst->takeName(&I); 566 567 // Check if we can add NSW flag to SimplifiedInst. If so, set NSW flag. 568 // TODO: Check for NUW. 569 if (BinaryOperator *BO = dyn_cast<BinaryOperator>(SimplifiedInst)) { 570 if (isa<OverflowingBinaryOperator>(SimplifiedInst)) { 571 bool HasNSW = false; 572 if (isa<OverflowingBinaryOperator>(&I)) 573 HasNSW = I.hasNoSignedWrap(); 574 575 if (auto *LOBO = dyn_cast<OverflowingBinaryOperator>(LHS)) 576 HasNSW &= LOBO->hasNoSignedWrap(); 577 578 if (auto *ROBO = dyn_cast<OverflowingBinaryOperator>(RHS)) 579 HasNSW &= ROBO->hasNoSignedWrap(); 580 581 // We can propagate 'nsw' if we know that 582 // %Y = mul nsw i16 %X, C 583 // %Z = add nsw i16 %Y, %X 584 // => 585 // %Z = mul nsw i16 %X, C+1 586 // 587 // iff C+1 isn't INT_MIN 588 const APInt *CInt; 589 if (TopLevelOpcode == Instruction::Add && 590 InnerOpcode == Instruction::Mul) 591 if (match(V, m_APInt(CInt)) && !CInt->isMinSignedValue()) 592 BO->setHasNoSignedWrap(HasNSW); 593 } 594 } 595 } 596 return SimplifiedInst; 597 } 598 599 /// This tries to simplify binary operations which some other binary operation 600 /// distributes over either by factorizing out common terms 601 /// (eg "(A*B)+(A*C)" -> "A*(B+C)") or expanding out if this results in 602 /// simplifications (eg: "A & (B | C) -> (A&B) | (A&C)" if this is a win). 603 /// Returns the simplified value, or null if it didn't simplify. 604 Value *InstCombiner::SimplifyUsingDistributiveLaws(BinaryOperator &I) { 605 Value *LHS = I.getOperand(0), *RHS = I.getOperand(1); 606 BinaryOperator *Op0 = dyn_cast<BinaryOperator>(LHS); 607 BinaryOperator *Op1 = dyn_cast<BinaryOperator>(RHS); 608 609 // Factorization. 610 Value *A = nullptr, *B = nullptr, *C = nullptr, *D = nullptr; 611 auto TopLevelOpcode = I.getOpcode(); 612 auto LHSOpcode = getBinOpsForFactorization(TopLevelOpcode, Op0, A, B); 613 auto RHSOpcode = getBinOpsForFactorization(TopLevelOpcode, Op1, C, D); 614 615 // The instruction has the form "(A op' B) op (C op' D)". Try to factorize 616 // a common term. 617 if (LHSOpcode == RHSOpcode) { 618 if (Value *V = tryFactorization(Builder, DL, I, LHSOpcode, A, B, C, D)) 619 return V; 620 } 621 622 // The instruction has the form "(A op' B) op (C)". Try to factorize common 623 // term. 624 if (Value *V = tryFactorization(Builder, DL, I, LHSOpcode, A, B, RHS, 625 getIdentityValue(LHSOpcode, RHS))) 626 return V; 627 628 // The instruction has the form "(B) op (C op' D)". Try to factorize common 629 // term. 630 if (Value *V = tryFactorization(Builder, DL, I, RHSOpcode, LHS, 631 getIdentityValue(RHSOpcode, LHS), C, D)) 632 return V; 633 634 // Expansion. 635 if (Op0 && RightDistributesOverLeft(Op0->getOpcode(), TopLevelOpcode)) { 636 // The instruction has the form "(A op' B) op C". See if expanding it out 637 // to "(A op C) op' (B op C)" results in simplifications. 638 Value *A = Op0->getOperand(0), *B = Op0->getOperand(1), *C = RHS; 639 Instruction::BinaryOps InnerOpcode = Op0->getOpcode(); // op' 640 641 // Do "A op C" and "B op C" both simplify? 642 if (Value *L = SimplifyBinOp(TopLevelOpcode, A, C, DL)) 643 if (Value *R = SimplifyBinOp(TopLevelOpcode, B, C, DL)) { 644 // They do! Return "L op' R". 645 ++NumExpand; 646 // If "L op' R" equals "A op' B" then "L op' R" is just the LHS. 647 if ((L == A && R == B) || 648 (Instruction::isCommutative(InnerOpcode) && L == B && R == A)) 649 return Op0; 650 // Otherwise return "L op' R" if it simplifies. 651 if (Value *V = SimplifyBinOp(InnerOpcode, L, R, DL)) 652 return V; 653 // Otherwise, create a new instruction. 654 C = Builder->CreateBinOp(InnerOpcode, L, R); 655 C->takeName(&I); 656 return C; 657 } 658 } 659 660 if (Op1 && LeftDistributesOverRight(TopLevelOpcode, Op1->getOpcode())) { 661 // The instruction has the form "A op (B op' C)". See if expanding it out 662 // to "(A op B) op' (A op C)" results in simplifications. 663 Value *A = LHS, *B = Op1->getOperand(0), *C = Op1->getOperand(1); 664 Instruction::BinaryOps InnerOpcode = Op1->getOpcode(); // op' 665 666 // Do "A op B" and "A op C" both simplify? 667 if (Value *L = SimplifyBinOp(TopLevelOpcode, A, B, DL)) 668 if (Value *R = SimplifyBinOp(TopLevelOpcode, A, C, DL)) { 669 // They do! Return "L op' R". 670 ++NumExpand; 671 // If "L op' R" equals "B op' C" then "L op' R" is just the RHS. 672 if ((L == B && R == C) || 673 (Instruction::isCommutative(InnerOpcode) && L == C && R == B)) 674 return Op1; 675 // Otherwise return "L op' R" if it simplifies. 676 if (Value *V = SimplifyBinOp(InnerOpcode, L, R, DL)) 677 return V; 678 // Otherwise, create a new instruction. 679 A = Builder->CreateBinOp(InnerOpcode, L, R); 680 A->takeName(&I); 681 return A; 682 } 683 } 684 685 // (op (select (a, c, b)), (select (a, d, b))) -> (select (a, (op c, d), 0)) 686 // (op (select (a, b, c)), (select (a, b, d))) -> (select (a, 0, (op c, d))) 687 if (auto *SI0 = dyn_cast<SelectInst>(LHS)) { 688 if (auto *SI1 = dyn_cast<SelectInst>(RHS)) { 689 if (SI0->getCondition() == SI1->getCondition()) { 690 Value *SI = nullptr; 691 if (Value *V = SimplifyBinOp(TopLevelOpcode, SI0->getFalseValue(), 692 SI1->getFalseValue(), DL, &TLI, &DT, &AC)) 693 SI = Builder->CreateSelect(SI0->getCondition(), 694 Builder->CreateBinOp(TopLevelOpcode, 695 SI0->getTrueValue(), 696 SI1->getTrueValue()), 697 V); 698 if (Value *V = SimplifyBinOp(TopLevelOpcode, SI0->getTrueValue(), 699 SI1->getTrueValue(), DL, &TLI, &DT, &AC)) 700 SI = Builder->CreateSelect( 701 SI0->getCondition(), V, 702 Builder->CreateBinOp(TopLevelOpcode, SI0->getFalseValue(), 703 SI1->getFalseValue())); 704 if (SI) { 705 SI->takeName(&I); 706 return SI; 707 } 708 } 709 } 710 } 711 712 return nullptr; 713 } 714 715 /// Given a 'sub' instruction, return the RHS of the instruction if the LHS is a 716 /// constant zero (which is the 'negate' form). 717 Value *InstCombiner::dyn_castNegVal(Value *V) const { 718 if (BinaryOperator::isNeg(V)) 719 return BinaryOperator::getNegArgument(V); 720 721 // Constants can be considered to be negated values if they can be folded. 722 if (ConstantInt *C = dyn_cast<ConstantInt>(V)) 723 return ConstantExpr::getNeg(C); 724 725 if (ConstantDataVector *C = dyn_cast<ConstantDataVector>(V)) 726 if (C->getType()->getElementType()->isIntegerTy()) 727 return ConstantExpr::getNeg(C); 728 729 return nullptr; 730 } 731 732 /// Given a 'fsub' instruction, return the RHS of the instruction if the LHS is 733 /// a constant negative zero (which is the 'negate' form). 734 Value *InstCombiner::dyn_castFNegVal(Value *V, bool IgnoreZeroSign) const { 735 if (BinaryOperator::isFNeg(V, IgnoreZeroSign)) 736 return BinaryOperator::getFNegArgument(V); 737 738 // Constants can be considered to be negated values if they can be folded. 739 if (ConstantFP *C = dyn_cast<ConstantFP>(V)) 740 return ConstantExpr::getFNeg(C); 741 742 if (ConstantDataVector *C = dyn_cast<ConstantDataVector>(V)) 743 if (C->getType()->getElementType()->isFloatingPointTy()) 744 return ConstantExpr::getFNeg(C); 745 746 return nullptr; 747 } 748 749 static Value *foldOperationIntoSelectOperand(Instruction &I, Value *SO, 750 InstCombiner *IC) { 751 if (auto *Cast = dyn_cast<CastInst>(&I)) 752 return IC->Builder->CreateCast(Cast->getOpcode(), SO, I.getType()); 753 754 assert(I.isBinaryOp() && "Unexpected opcode for select folding"); 755 756 // Figure out if the constant is the left or the right argument. 757 bool ConstIsRHS = isa<Constant>(I.getOperand(1)); 758 Constant *ConstOperand = cast<Constant>(I.getOperand(ConstIsRHS)); 759 760 if (auto *SOC = dyn_cast<Constant>(SO)) { 761 if (ConstIsRHS) 762 return ConstantExpr::get(I.getOpcode(), SOC, ConstOperand); 763 return ConstantExpr::get(I.getOpcode(), ConstOperand, SOC); 764 } 765 766 Value *Op0 = SO, *Op1 = ConstOperand; 767 if (!ConstIsRHS) 768 std::swap(Op0, Op1); 769 770 auto *BO = cast<BinaryOperator>(&I); 771 Value *RI = IC->Builder->CreateBinOp(BO->getOpcode(), Op0, Op1, 772 SO->getName() + ".op"); 773 auto *FPInst = dyn_cast<Instruction>(RI); 774 if (FPInst && isa<FPMathOperator>(FPInst)) 775 FPInst->copyFastMathFlags(BO); 776 return RI; 777 } 778 779 Instruction *InstCombiner::FoldOpIntoSelect(Instruction &Op, SelectInst *SI) { 780 // Don't modify shared select instructions. 781 if (!SI->hasOneUse()) 782 return nullptr; 783 784 Value *TV = SI->getTrueValue(); 785 Value *FV = SI->getFalseValue(); 786 if (!(isa<Constant>(TV) || isa<Constant>(FV))) 787 return nullptr; 788 789 // Bool selects with constant operands can be folded to logical ops. 790 if (SI->getType()->getScalarType()->isIntegerTy(1)) 791 return nullptr; 792 793 // If it's a bitcast involving vectors, make sure it has the same number of 794 // elements on both sides. 795 if (auto *BC = dyn_cast<BitCastInst>(&Op)) { 796 VectorType *DestTy = dyn_cast<VectorType>(BC->getDestTy()); 797 VectorType *SrcTy = dyn_cast<VectorType>(BC->getSrcTy()); 798 799 // Verify that either both or neither are vectors. 800 if ((SrcTy == nullptr) != (DestTy == nullptr)) 801 return nullptr; 802 803 // If vectors, verify that they have the same number of elements. 804 if (SrcTy && SrcTy->getNumElements() != DestTy->getNumElements()) 805 return nullptr; 806 } 807 808 // Test if a CmpInst instruction is used exclusively by a select as 809 // part of a minimum or maximum operation. If so, refrain from doing 810 // any other folding. This helps out other analyses which understand 811 // non-obfuscated minimum and maximum idioms, such as ScalarEvolution 812 // and CodeGen. And in this case, at least one of the comparison 813 // operands has at least one user besides the compare (the select), 814 // which would often largely negate the benefit of folding anyway. 815 if (auto *CI = dyn_cast<CmpInst>(SI->getCondition())) { 816 if (CI->hasOneUse()) { 817 Value *Op0 = CI->getOperand(0), *Op1 = CI->getOperand(1); 818 if ((SI->getOperand(1) == Op0 && SI->getOperand(2) == Op1) || 819 (SI->getOperand(2) == Op0 && SI->getOperand(1) == Op1)) 820 return nullptr; 821 } 822 } 823 824 Value *NewTV = foldOperationIntoSelectOperand(Op, TV, this); 825 Value *NewFV = foldOperationIntoSelectOperand(Op, FV, this); 826 return SelectInst::Create(SI->getCondition(), NewTV, NewFV, "", nullptr, SI); 827 } 828 829 Instruction *InstCombiner::FoldOpIntoPhi(Instruction &I) { 830 PHINode *PN = cast<PHINode>(I.getOperand(0)); 831 unsigned NumPHIValues = PN->getNumIncomingValues(); 832 if (NumPHIValues == 0) 833 return nullptr; 834 835 // We normally only transform phis with a single use. However, if a PHI has 836 // multiple uses and they are all the same operation, we can fold *all* of the 837 // uses into the PHI. 838 if (!PN->hasOneUse()) { 839 // Walk the use list for the instruction, comparing them to I. 840 for (User *U : PN->users()) { 841 Instruction *UI = cast<Instruction>(U); 842 if (UI != &I && !I.isIdenticalTo(UI)) 843 return nullptr; 844 } 845 // Otherwise, we can replace *all* users with the new PHI we form. 846 } 847 848 // Check to see if all of the operands of the PHI are simple constants 849 // (constantint/constantfp/undef). If there is one non-constant value, 850 // remember the BB it is in. If there is more than one or if *it* is a PHI, 851 // bail out. We don't do arbitrary constant expressions here because moving 852 // their computation can be expensive without a cost model. 853 BasicBlock *NonConstBB = nullptr; 854 for (unsigned i = 0; i != NumPHIValues; ++i) { 855 Value *InVal = PN->getIncomingValue(i); 856 if (isa<Constant>(InVal) && !isa<ConstantExpr>(InVal)) 857 continue; 858 859 if (isa<PHINode>(InVal)) return nullptr; // Itself a phi. 860 if (NonConstBB) return nullptr; // More than one non-const value. 861 862 NonConstBB = PN->getIncomingBlock(i); 863 864 // If the InVal is an invoke at the end of the pred block, then we can't 865 // insert a computation after it without breaking the edge. 866 if (InvokeInst *II = dyn_cast<InvokeInst>(InVal)) 867 if (II->getParent() == NonConstBB) 868 return nullptr; 869 870 // If the incoming non-constant value is in I's block, we will remove one 871 // instruction, but insert another equivalent one, leading to infinite 872 // instcombine. 873 if (isPotentiallyReachable(I.getParent(), NonConstBB, &DT, LI)) 874 return nullptr; 875 } 876 877 // If there is exactly one non-constant value, we can insert a copy of the 878 // operation in that block. However, if this is a critical edge, we would be 879 // inserting the computation on some other paths (e.g. inside a loop). Only 880 // do this if the pred block is unconditionally branching into the phi block. 881 if (NonConstBB != nullptr) { 882 BranchInst *BI = dyn_cast<BranchInst>(NonConstBB->getTerminator()); 883 if (!BI || !BI->isUnconditional()) return nullptr; 884 } 885 886 // Okay, we can do the transformation: create the new PHI node. 887 PHINode *NewPN = PHINode::Create(I.getType(), PN->getNumIncomingValues()); 888 InsertNewInstBefore(NewPN, *PN); 889 NewPN->takeName(PN); 890 891 // If we are going to have to insert a new computation, do so right before the 892 // predecessor's terminator. 893 if (NonConstBB) 894 Builder->SetInsertPoint(NonConstBB->getTerminator()); 895 896 // Next, add all of the operands to the PHI. 897 if (SelectInst *SI = dyn_cast<SelectInst>(&I)) { 898 // We only currently try to fold the condition of a select when it is a phi, 899 // not the true/false values. 900 Value *TrueV = SI->getTrueValue(); 901 Value *FalseV = SI->getFalseValue(); 902 BasicBlock *PhiTransBB = PN->getParent(); 903 for (unsigned i = 0; i != NumPHIValues; ++i) { 904 BasicBlock *ThisBB = PN->getIncomingBlock(i); 905 Value *TrueVInPred = TrueV->DoPHITranslation(PhiTransBB, ThisBB); 906 Value *FalseVInPred = FalseV->DoPHITranslation(PhiTransBB, ThisBB); 907 Value *InV = nullptr; 908 // Beware of ConstantExpr: it may eventually evaluate to getNullValue, 909 // even if currently isNullValue gives false. 910 Constant *InC = dyn_cast<Constant>(PN->getIncomingValue(i)); 911 // For vector constants, we cannot use isNullValue to fold into 912 // FalseVInPred versus TrueVInPred. When we have individual nonzero 913 // elements in the vector, we will incorrectly fold InC to 914 // `TrueVInPred`. 915 if (InC && !isa<ConstantExpr>(InC) && isa<ConstantInt>(InC)) 916 InV = InC->isNullValue() ? FalseVInPred : TrueVInPred; 917 else 918 InV = Builder->CreateSelect(PN->getIncomingValue(i), 919 TrueVInPred, FalseVInPred, "phitmp"); 920 NewPN->addIncoming(InV, ThisBB); 921 } 922 } else if (CmpInst *CI = dyn_cast<CmpInst>(&I)) { 923 Constant *C = cast<Constant>(I.getOperand(1)); 924 for (unsigned i = 0; i != NumPHIValues; ++i) { 925 Value *InV = nullptr; 926 if (Constant *InC = dyn_cast<Constant>(PN->getIncomingValue(i))) 927 InV = ConstantExpr::getCompare(CI->getPredicate(), InC, C); 928 else if (isa<ICmpInst>(CI)) 929 InV = Builder->CreateICmp(CI->getPredicate(), PN->getIncomingValue(i), 930 C, "phitmp"); 931 else 932 InV = Builder->CreateFCmp(CI->getPredicate(), PN->getIncomingValue(i), 933 C, "phitmp"); 934 NewPN->addIncoming(InV, PN->getIncomingBlock(i)); 935 } 936 } else if (I.getNumOperands() == 2) { 937 Constant *C = cast<Constant>(I.getOperand(1)); 938 for (unsigned i = 0; i != NumPHIValues; ++i) { 939 Value *InV = nullptr; 940 if (Constant *InC = dyn_cast<Constant>(PN->getIncomingValue(i))) 941 InV = ConstantExpr::get(I.getOpcode(), InC, C); 942 else 943 InV = Builder->CreateBinOp(cast<BinaryOperator>(I).getOpcode(), 944 PN->getIncomingValue(i), C, "phitmp"); 945 NewPN->addIncoming(InV, PN->getIncomingBlock(i)); 946 } 947 } else { 948 CastInst *CI = cast<CastInst>(&I); 949 Type *RetTy = CI->getType(); 950 for (unsigned i = 0; i != NumPHIValues; ++i) { 951 Value *InV; 952 if (Constant *InC = dyn_cast<Constant>(PN->getIncomingValue(i))) 953 InV = ConstantExpr::getCast(CI->getOpcode(), InC, RetTy); 954 else 955 InV = Builder->CreateCast(CI->getOpcode(), 956 PN->getIncomingValue(i), I.getType(), "phitmp"); 957 NewPN->addIncoming(InV, PN->getIncomingBlock(i)); 958 } 959 } 960 961 for (auto UI = PN->user_begin(), E = PN->user_end(); UI != E;) { 962 Instruction *User = cast<Instruction>(*UI++); 963 if (User == &I) continue; 964 replaceInstUsesWith(*User, NewPN); 965 eraseInstFromFunction(*User); 966 } 967 return replaceInstUsesWith(I, NewPN); 968 } 969 970 Instruction *InstCombiner::foldOpWithConstantIntoOperand(BinaryOperator &I) { 971 assert(isa<Constant>(I.getOperand(1)) && "Unexpected operand type"); 972 973 if (auto *Sel = dyn_cast<SelectInst>(I.getOperand(0))) { 974 if (Instruction *NewSel = FoldOpIntoSelect(I, Sel)) 975 return NewSel; 976 } else if (isa<PHINode>(I.getOperand(0))) { 977 if (Instruction *NewPhi = FoldOpIntoPhi(I)) 978 return NewPhi; 979 } 980 return nullptr; 981 } 982 983 /// Given a pointer type and a constant offset, determine whether or not there 984 /// is a sequence of GEP indices into the pointed type that will land us at the 985 /// specified offset. If so, fill them into NewIndices and return the resultant 986 /// element type, otherwise return null. 987 Type *InstCombiner::FindElementAtOffset(PointerType *PtrTy, int64_t Offset, 988 SmallVectorImpl<Value *> &NewIndices) { 989 Type *Ty = PtrTy->getElementType(); 990 if (!Ty->isSized()) 991 return nullptr; 992 993 // Start with the index over the outer type. Note that the type size 994 // might be zero (even if the offset isn't zero) if the indexed type 995 // is something like [0 x {int, int}] 996 Type *IntPtrTy = DL.getIntPtrType(PtrTy); 997 int64_t FirstIdx = 0; 998 if (int64_t TySize = DL.getTypeAllocSize(Ty)) { 999 FirstIdx = Offset/TySize; 1000 Offset -= FirstIdx*TySize; 1001 1002 // Handle hosts where % returns negative instead of values [0..TySize). 1003 if (Offset < 0) { 1004 --FirstIdx; 1005 Offset += TySize; 1006 assert(Offset >= 0); 1007 } 1008 assert((uint64_t)Offset < (uint64_t)TySize && "Out of range offset"); 1009 } 1010 1011 NewIndices.push_back(ConstantInt::get(IntPtrTy, FirstIdx)); 1012 1013 // Index into the types. If we fail, set OrigBase to null. 1014 while (Offset) { 1015 // Indexing into tail padding between struct/array elements. 1016 if (uint64_t(Offset * 8) >= DL.getTypeSizeInBits(Ty)) 1017 return nullptr; 1018 1019 if (StructType *STy = dyn_cast<StructType>(Ty)) { 1020 const StructLayout *SL = DL.getStructLayout(STy); 1021 assert(Offset < (int64_t)SL->getSizeInBytes() && 1022 "Offset must stay within the indexed type"); 1023 1024 unsigned Elt = SL->getElementContainingOffset(Offset); 1025 NewIndices.push_back(ConstantInt::get(Type::getInt32Ty(Ty->getContext()), 1026 Elt)); 1027 1028 Offset -= SL->getElementOffset(Elt); 1029 Ty = STy->getElementType(Elt); 1030 } else if (ArrayType *AT = dyn_cast<ArrayType>(Ty)) { 1031 uint64_t EltSize = DL.getTypeAllocSize(AT->getElementType()); 1032 assert(EltSize && "Cannot index into a zero-sized array"); 1033 NewIndices.push_back(ConstantInt::get(IntPtrTy,Offset/EltSize)); 1034 Offset %= EltSize; 1035 Ty = AT->getElementType(); 1036 } else { 1037 // Otherwise, we can't index into the middle of this atomic type, bail. 1038 return nullptr; 1039 } 1040 } 1041 1042 return Ty; 1043 } 1044 1045 static bool shouldMergeGEPs(GEPOperator &GEP, GEPOperator &Src) { 1046 // If this GEP has only 0 indices, it is the same pointer as 1047 // Src. If Src is not a trivial GEP too, don't combine 1048 // the indices. 1049 if (GEP.hasAllZeroIndices() && !Src.hasAllZeroIndices() && 1050 !Src.hasOneUse()) 1051 return false; 1052 return true; 1053 } 1054 1055 /// Return a value X such that Val = X * Scale, or null if none. 1056 /// If the multiplication is known not to overflow, then NoSignedWrap is set. 1057 Value *InstCombiner::Descale(Value *Val, APInt Scale, bool &NoSignedWrap) { 1058 assert(isa<IntegerType>(Val->getType()) && "Can only descale integers!"); 1059 assert(cast<IntegerType>(Val->getType())->getBitWidth() == 1060 Scale.getBitWidth() && "Scale not compatible with value!"); 1061 1062 // If Val is zero or Scale is one then Val = Val * Scale. 1063 if (match(Val, m_Zero()) || Scale == 1) { 1064 NoSignedWrap = true; 1065 return Val; 1066 } 1067 1068 // If Scale is zero then it does not divide Val. 1069 if (Scale.isMinValue()) 1070 return nullptr; 1071 1072 // Look through chains of multiplications, searching for a constant that is 1073 // divisible by Scale. For example, descaling X*(Y*(Z*4)) by a factor of 4 1074 // will find the constant factor 4 and produce X*(Y*Z). Descaling X*(Y*8) by 1075 // a factor of 4 will produce X*(Y*2). The principle of operation is to bore 1076 // down from Val: 1077 // 1078 // Val = M1 * X || Analysis starts here and works down 1079 // M1 = M2 * Y || Doesn't descend into terms with more 1080 // M2 = Z * 4 \/ than one use 1081 // 1082 // Then to modify a term at the bottom: 1083 // 1084 // Val = M1 * X 1085 // M1 = Z * Y || Replaced M2 with Z 1086 // 1087 // Then to work back up correcting nsw flags. 1088 1089 // Op - the term we are currently analyzing. Starts at Val then drills down. 1090 // Replaced with its descaled value before exiting from the drill down loop. 1091 Value *Op = Val; 1092 1093 // Parent - initially null, but after drilling down notes where Op came from. 1094 // In the example above, Parent is (Val, 0) when Op is M1, because M1 is the 1095 // 0'th operand of Val. 1096 std::pair<Instruction*, unsigned> Parent; 1097 1098 // Set if the transform requires a descaling at deeper levels that doesn't 1099 // overflow. 1100 bool RequireNoSignedWrap = false; 1101 1102 // Log base 2 of the scale. Negative if not a power of 2. 1103 int32_t logScale = Scale.exactLogBase2(); 1104 1105 for (;; Op = Parent.first->getOperand(Parent.second)) { // Drill down 1106 1107 if (ConstantInt *CI = dyn_cast<ConstantInt>(Op)) { 1108 // If Op is a constant divisible by Scale then descale to the quotient. 1109 APInt Quotient(Scale), Remainder(Scale); // Init ensures right bitwidth. 1110 APInt::sdivrem(CI->getValue(), Scale, Quotient, Remainder); 1111 if (!Remainder.isMinValue()) 1112 // Not divisible by Scale. 1113 return nullptr; 1114 // Replace with the quotient in the parent. 1115 Op = ConstantInt::get(CI->getType(), Quotient); 1116 NoSignedWrap = true; 1117 break; 1118 } 1119 1120 if (BinaryOperator *BO = dyn_cast<BinaryOperator>(Op)) { 1121 1122 if (BO->getOpcode() == Instruction::Mul) { 1123 // Multiplication. 1124 NoSignedWrap = BO->hasNoSignedWrap(); 1125 if (RequireNoSignedWrap && !NoSignedWrap) 1126 return nullptr; 1127 1128 // There are three cases for multiplication: multiplication by exactly 1129 // the scale, multiplication by a constant different to the scale, and 1130 // multiplication by something else. 1131 Value *LHS = BO->getOperand(0); 1132 Value *RHS = BO->getOperand(1); 1133 1134 if (ConstantInt *CI = dyn_cast<ConstantInt>(RHS)) { 1135 // Multiplication by a constant. 1136 if (CI->getValue() == Scale) { 1137 // Multiplication by exactly the scale, replace the multiplication 1138 // by its left-hand side in the parent. 1139 Op = LHS; 1140 break; 1141 } 1142 1143 // Otherwise drill down into the constant. 1144 if (!Op->hasOneUse()) 1145 return nullptr; 1146 1147 Parent = std::make_pair(BO, 1); 1148 continue; 1149 } 1150 1151 // Multiplication by something else. Drill down into the left-hand side 1152 // since that's where the reassociate pass puts the good stuff. 1153 if (!Op->hasOneUse()) 1154 return nullptr; 1155 1156 Parent = std::make_pair(BO, 0); 1157 continue; 1158 } 1159 1160 if (logScale > 0 && BO->getOpcode() == Instruction::Shl && 1161 isa<ConstantInt>(BO->getOperand(1))) { 1162 // Multiplication by a power of 2. 1163 NoSignedWrap = BO->hasNoSignedWrap(); 1164 if (RequireNoSignedWrap && !NoSignedWrap) 1165 return nullptr; 1166 1167 Value *LHS = BO->getOperand(0); 1168 int32_t Amt = cast<ConstantInt>(BO->getOperand(1))-> 1169 getLimitedValue(Scale.getBitWidth()); 1170 // Op = LHS << Amt. 1171 1172 if (Amt == logScale) { 1173 // Multiplication by exactly the scale, replace the multiplication 1174 // by its left-hand side in the parent. 1175 Op = LHS; 1176 break; 1177 } 1178 if (Amt < logScale || !Op->hasOneUse()) 1179 return nullptr; 1180 1181 // Multiplication by more than the scale. Reduce the multiplying amount 1182 // by the scale in the parent. 1183 Parent = std::make_pair(BO, 1); 1184 Op = ConstantInt::get(BO->getType(), Amt - logScale); 1185 break; 1186 } 1187 } 1188 1189 if (!Op->hasOneUse()) 1190 return nullptr; 1191 1192 if (CastInst *Cast = dyn_cast<CastInst>(Op)) { 1193 if (Cast->getOpcode() == Instruction::SExt) { 1194 // Op is sign-extended from a smaller type, descale in the smaller type. 1195 unsigned SmallSize = Cast->getSrcTy()->getPrimitiveSizeInBits(); 1196 APInt SmallScale = Scale.trunc(SmallSize); 1197 // Suppose Op = sext X, and we descale X as Y * SmallScale. We want to 1198 // descale Op as (sext Y) * Scale. In order to have 1199 // sext (Y * SmallScale) = (sext Y) * Scale 1200 // some conditions need to hold however: SmallScale must sign-extend to 1201 // Scale and the multiplication Y * SmallScale should not overflow. 1202 if (SmallScale.sext(Scale.getBitWidth()) != Scale) 1203 // SmallScale does not sign-extend to Scale. 1204 return nullptr; 1205 assert(SmallScale.exactLogBase2() == logScale); 1206 // Require that Y * SmallScale must not overflow. 1207 RequireNoSignedWrap = true; 1208 1209 // Drill down through the cast. 1210 Parent = std::make_pair(Cast, 0); 1211 Scale = SmallScale; 1212 continue; 1213 } 1214 1215 if (Cast->getOpcode() == Instruction::Trunc) { 1216 // Op is truncated from a larger type, descale in the larger type. 1217 // Suppose Op = trunc X, and we descale X as Y * sext Scale. Then 1218 // trunc (Y * sext Scale) = (trunc Y) * Scale 1219 // always holds. However (trunc Y) * Scale may overflow even if 1220 // trunc (Y * sext Scale) does not, so nsw flags need to be cleared 1221 // from this point up in the expression (see later). 1222 if (RequireNoSignedWrap) 1223 return nullptr; 1224 1225 // Drill down through the cast. 1226 unsigned LargeSize = Cast->getSrcTy()->getPrimitiveSizeInBits(); 1227 Parent = std::make_pair(Cast, 0); 1228 Scale = Scale.sext(LargeSize); 1229 if (logScale + 1 == (int32_t)Cast->getType()->getPrimitiveSizeInBits()) 1230 logScale = -1; 1231 assert(Scale.exactLogBase2() == logScale); 1232 continue; 1233 } 1234 } 1235 1236 // Unsupported expression, bail out. 1237 return nullptr; 1238 } 1239 1240 // If Op is zero then Val = Op * Scale. 1241 if (match(Op, m_Zero())) { 1242 NoSignedWrap = true; 1243 return Op; 1244 } 1245 1246 // We know that we can successfully descale, so from here on we can safely 1247 // modify the IR. Op holds the descaled version of the deepest term in the 1248 // expression. NoSignedWrap is 'true' if multiplying Op by Scale is known 1249 // not to overflow. 1250 1251 if (!Parent.first) 1252 // The expression only had one term. 1253 return Op; 1254 1255 // Rewrite the parent using the descaled version of its operand. 1256 assert(Parent.first->hasOneUse() && "Drilled down when more than one use!"); 1257 assert(Op != Parent.first->getOperand(Parent.second) && 1258 "Descaling was a no-op?"); 1259 Parent.first->setOperand(Parent.second, Op); 1260 Worklist.Add(Parent.first); 1261 1262 // Now work back up the expression correcting nsw flags. The logic is based 1263 // on the following observation: if X * Y is known not to overflow as a signed 1264 // multiplication, and Y is replaced by a value Z with smaller absolute value, 1265 // then X * Z will not overflow as a signed multiplication either. As we work 1266 // our way up, having NoSignedWrap 'true' means that the descaled value at the 1267 // current level has strictly smaller absolute value than the original. 1268 Instruction *Ancestor = Parent.first; 1269 do { 1270 if (BinaryOperator *BO = dyn_cast<BinaryOperator>(Ancestor)) { 1271 // If the multiplication wasn't nsw then we can't say anything about the 1272 // value of the descaled multiplication, and we have to clear nsw flags 1273 // from this point on up. 1274 bool OpNoSignedWrap = BO->hasNoSignedWrap(); 1275 NoSignedWrap &= OpNoSignedWrap; 1276 if (NoSignedWrap != OpNoSignedWrap) { 1277 BO->setHasNoSignedWrap(NoSignedWrap); 1278 Worklist.Add(Ancestor); 1279 } 1280 } else if (Ancestor->getOpcode() == Instruction::Trunc) { 1281 // The fact that the descaled input to the trunc has smaller absolute 1282 // value than the original input doesn't tell us anything useful about 1283 // the absolute values of the truncations. 1284 NoSignedWrap = false; 1285 } 1286 assert((Ancestor->getOpcode() != Instruction::SExt || NoSignedWrap) && 1287 "Failed to keep proper track of nsw flags while drilling down?"); 1288 1289 if (Ancestor == Val) 1290 // Got to the top, all done! 1291 return Val; 1292 1293 // Move up one level in the expression. 1294 assert(Ancestor->hasOneUse() && "Drilled down when more than one use!"); 1295 Ancestor = Ancestor->user_back(); 1296 } while (1); 1297 } 1298 1299 /// \brief Creates node of binary operation with the same attributes as the 1300 /// specified one but with other operands. 1301 static Value *CreateBinOpAsGiven(BinaryOperator &Inst, Value *LHS, Value *RHS, 1302 InstCombiner::BuilderTy *B) { 1303 Value *BO = B->CreateBinOp(Inst.getOpcode(), LHS, RHS); 1304 // If LHS and RHS are constant, BO won't be a binary operator. 1305 if (BinaryOperator *NewBO = dyn_cast<BinaryOperator>(BO)) 1306 NewBO->copyIRFlags(&Inst); 1307 return BO; 1308 } 1309 1310 /// \brief Makes transformation of binary operation specific for vector types. 1311 /// \param Inst Binary operator to transform. 1312 /// \return Pointer to node that must replace the original binary operator, or 1313 /// null pointer if no transformation was made. 1314 Value *InstCombiner::SimplifyVectorOp(BinaryOperator &Inst) { 1315 if (!Inst.getType()->isVectorTy()) return nullptr; 1316 1317 // It may not be safe to reorder shuffles and things like div, urem, etc. 1318 // because we may trap when executing those ops on unknown vector elements. 1319 // See PR20059. 1320 if (!isSafeToSpeculativelyExecute(&Inst)) 1321 return nullptr; 1322 1323 unsigned VWidth = cast<VectorType>(Inst.getType())->getNumElements(); 1324 Value *LHS = Inst.getOperand(0), *RHS = Inst.getOperand(1); 1325 assert(cast<VectorType>(LHS->getType())->getNumElements() == VWidth); 1326 assert(cast<VectorType>(RHS->getType())->getNumElements() == VWidth); 1327 1328 // If both arguments of the binary operation are shuffles that use the same 1329 // mask and shuffle within a single vector, move the shuffle after the binop: 1330 // Op(shuffle(v1, m), shuffle(v2, m)) -> shuffle(Op(v1, v2), m) 1331 auto *LShuf = dyn_cast<ShuffleVectorInst>(LHS); 1332 auto *RShuf = dyn_cast<ShuffleVectorInst>(RHS); 1333 if (LShuf && RShuf && LShuf->getMask() == RShuf->getMask() && 1334 isa<UndefValue>(LShuf->getOperand(1)) && 1335 isa<UndefValue>(RShuf->getOperand(1)) && 1336 LShuf->getOperand(0)->getType() == RShuf->getOperand(0)->getType()) { 1337 Value *NewBO = CreateBinOpAsGiven(Inst, LShuf->getOperand(0), 1338 RShuf->getOperand(0), Builder); 1339 return Builder->CreateShuffleVector( 1340 NewBO, UndefValue::get(NewBO->getType()), LShuf->getMask()); 1341 } 1342 1343 // If one argument is a shuffle within one vector, the other is a constant, 1344 // try moving the shuffle after the binary operation. 1345 ShuffleVectorInst *Shuffle = nullptr; 1346 Constant *C1 = nullptr; 1347 if (isa<ShuffleVectorInst>(LHS)) Shuffle = cast<ShuffleVectorInst>(LHS); 1348 if (isa<ShuffleVectorInst>(RHS)) Shuffle = cast<ShuffleVectorInst>(RHS); 1349 if (isa<Constant>(LHS)) C1 = cast<Constant>(LHS); 1350 if (isa<Constant>(RHS)) C1 = cast<Constant>(RHS); 1351 if (Shuffle && C1 && 1352 (isa<ConstantVector>(C1) || isa<ConstantDataVector>(C1)) && 1353 isa<UndefValue>(Shuffle->getOperand(1)) && 1354 Shuffle->getType() == Shuffle->getOperand(0)->getType()) { 1355 SmallVector<int, 16> ShMask = Shuffle->getShuffleMask(); 1356 // Find constant C2 that has property: 1357 // shuffle(C2, ShMask) = C1 1358 // If such constant does not exist (example: ShMask=<0,0> and C1=<1,2>) 1359 // reorder is not possible. 1360 SmallVector<Constant*, 16> C2M(VWidth, 1361 UndefValue::get(C1->getType()->getScalarType())); 1362 bool MayChange = true; 1363 for (unsigned I = 0; I < VWidth; ++I) { 1364 if (ShMask[I] >= 0) { 1365 assert(ShMask[I] < (int)VWidth); 1366 if (!isa<UndefValue>(C2M[ShMask[I]])) { 1367 MayChange = false; 1368 break; 1369 } 1370 C2M[ShMask[I]] = C1->getAggregateElement(I); 1371 } 1372 } 1373 if (MayChange) { 1374 Constant *C2 = ConstantVector::get(C2M); 1375 Value *NewLHS = isa<Constant>(LHS) ? C2 : Shuffle->getOperand(0); 1376 Value *NewRHS = isa<Constant>(LHS) ? Shuffle->getOperand(0) : C2; 1377 Value *NewBO = CreateBinOpAsGiven(Inst, NewLHS, NewRHS, Builder); 1378 return Builder->CreateShuffleVector(NewBO, 1379 UndefValue::get(Inst.getType()), Shuffle->getMask()); 1380 } 1381 } 1382 1383 return nullptr; 1384 } 1385 1386 Instruction *InstCombiner::visitGetElementPtrInst(GetElementPtrInst &GEP) { 1387 SmallVector<Value*, 8> Ops(GEP.op_begin(), GEP.op_end()); 1388 1389 if (Value *V = 1390 SimplifyGEPInst(GEP.getSourceElementType(), Ops, DL, &TLI, &DT, &AC)) 1391 return replaceInstUsesWith(GEP, V); 1392 1393 Value *PtrOp = GEP.getOperand(0); 1394 1395 // Eliminate unneeded casts for indices, and replace indices which displace 1396 // by multiples of a zero size type with zero. 1397 bool MadeChange = false; 1398 Type *IntPtrTy = 1399 DL.getIntPtrType(GEP.getPointerOperandType()->getScalarType()); 1400 1401 gep_type_iterator GTI = gep_type_begin(GEP); 1402 for (User::op_iterator I = GEP.op_begin() + 1, E = GEP.op_end(); I != E; 1403 ++I, ++GTI) { 1404 // Skip indices into struct types. 1405 if (GTI.isStruct()) 1406 continue; 1407 1408 // Index type should have the same width as IntPtr 1409 Type *IndexTy = (*I)->getType(); 1410 Type *NewIndexType = IndexTy->isVectorTy() ? 1411 VectorType::get(IntPtrTy, IndexTy->getVectorNumElements()) : IntPtrTy; 1412 1413 // If the element type has zero size then any index over it is equivalent 1414 // to an index of zero, so replace it with zero if it is not zero already. 1415 Type *EltTy = GTI.getIndexedType(); 1416 if (EltTy->isSized() && DL.getTypeAllocSize(EltTy) == 0) 1417 if (!isa<Constant>(*I) || !cast<Constant>(*I)->isNullValue()) { 1418 *I = Constant::getNullValue(NewIndexType); 1419 MadeChange = true; 1420 } 1421 1422 if (IndexTy != NewIndexType) { 1423 // If we are using a wider index than needed for this platform, shrink 1424 // it to what we need. If narrower, sign-extend it to what we need. 1425 // This explicit cast can make subsequent optimizations more obvious. 1426 *I = Builder->CreateIntCast(*I, NewIndexType, true); 1427 MadeChange = true; 1428 } 1429 } 1430 if (MadeChange) 1431 return &GEP; 1432 1433 // Check to see if the inputs to the PHI node are getelementptr instructions. 1434 if (PHINode *PN = dyn_cast<PHINode>(PtrOp)) { 1435 GetElementPtrInst *Op1 = dyn_cast<GetElementPtrInst>(PN->getOperand(0)); 1436 if (!Op1) 1437 return nullptr; 1438 1439 // Don't fold a GEP into itself through a PHI node. This can only happen 1440 // through the back-edge of a loop. Folding a GEP into itself means that 1441 // the value of the previous iteration needs to be stored in the meantime, 1442 // thus requiring an additional register variable to be live, but not 1443 // actually achieving anything (the GEP still needs to be executed once per 1444 // loop iteration). 1445 if (Op1 == &GEP) 1446 return nullptr; 1447 1448 int DI = -1; 1449 1450 for (auto I = PN->op_begin()+1, E = PN->op_end(); I !=E; ++I) { 1451 GetElementPtrInst *Op2 = dyn_cast<GetElementPtrInst>(*I); 1452 if (!Op2 || Op1->getNumOperands() != Op2->getNumOperands()) 1453 return nullptr; 1454 1455 // As for Op1 above, don't try to fold a GEP into itself. 1456 if (Op2 == &GEP) 1457 return nullptr; 1458 1459 // Keep track of the type as we walk the GEP. 1460 Type *CurTy = nullptr; 1461 1462 for (unsigned J = 0, F = Op1->getNumOperands(); J != F; ++J) { 1463 if (Op1->getOperand(J)->getType() != Op2->getOperand(J)->getType()) 1464 return nullptr; 1465 1466 if (Op1->getOperand(J) != Op2->getOperand(J)) { 1467 if (DI == -1) { 1468 // We have not seen any differences yet in the GEPs feeding the 1469 // PHI yet, so we record this one if it is allowed to be a 1470 // variable. 1471 1472 // The first two arguments can vary for any GEP, the rest have to be 1473 // static for struct slots 1474 if (J > 1 && CurTy->isStructTy()) 1475 return nullptr; 1476 1477 DI = J; 1478 } else { 1479 // The GEP is different by more than one input. While this could be 1480 // extended to support GEPs that vary by more than one variable it 1481 // doesn't make sense since it greatly increases the complexity and 1482 // would result in an R+R+R addressing mode which no backend 1483 // directly supports and would need to be broken into several 1484 // simpler instructions anyway. 1485 return nullptr; 1486 } 1487 } 1488 1489 // Sink down a layer of the type for the next iteration. 1490 if (J > 0) { 1491 if (J == 1) { 1492 CurTy = Op1->getSourceElementType(); 1493 } else if (CompositeType *CT = dyn_cast<CompositeType>(CurTy)) { 1494 CurTy = CT->getTypeAtIndex(Op1->getOperand(J)); 1495 } else { 1496 CurTy = nullptr; 1497 } 1498 } 1499 } 1500 } 1501 1502 // If not all GEPs are identical we'll have to create a new PHI node. 1503 // Check that the old PHI node has only one use so that it will get 1504 // removed. 1505 if (DI != -1 && !PN->hasOneUse()) 1506 return nullptr; 1507 1508 GetElementPtrInst *NewGEP = cast<GetElementPtrInst>(Op1->clone()); 1509 if (DI == -1) { 1510 // All the GEPs feeding the PHI are identical. Clone one down into our 1511 // BB so that it can be merged with the current GEP. 1512 GEP.getParent()->getInstList().insert( 1513 GEP.getParent()->getFirstInsertionPt(), NewGEP); 1514 } else { 1515 // All the GEPs feeding the PHI differ at a single offset. Clone a GEP 1516 // into the current block so it can be merged, and create a new PHI to 1517 // set that index. 1518 PHINode *NewPN; 1519 { 1520 IRBuilderBase::InsertPointGuard Guard(*Builder); 1521 Builder->SetInsertPoint(PN); 1522 NewPN = Builder->CreatePHI(Op1->getOperand(DI)->getType(), 1523 PN->getNumOperands()); 1524 } 1525 1526 for (auto &I : PN->operands()) 1527 NewPN->addIncoming(cast<GEPOperator>(I)->getOperand(DI), 1528 PN->getIncomingBlock(I)); 1529 1530 NewGEP->setOperand(DI, NewPN); 1531 GEP.getParent()->getInstList().insert( 1532 GEP.getParent()->getFirstInsertionPt(), NewGEP); 1533 NewGEP->setOperand(DI, NewPN); 1534 } 1535 1536 GEP.setOperand(0, NewGEP); 1537 PtrOp = NewGEP; 1538 } 1539 1540 // Combine Indices - If the source pointer to this getelementptr instruction 1541 // is a getelementptr instruction, combine the indices of the two 1542 // getelementptr instructions into a single instruction. 1543 // 1544 if (GEPOperator *Src = dyn_cast<GEPOperator>(PtrOp)) { 1545 if (!shouldMergeGEPs(*cast<GEPOperator>(&GEP), *Src)) 1546 return nullptr; 1547 1548 // Note that if our source is a gep chain itself then we wait for that 1549 // chain to be resolved before we perform this transformation. This 1550 // avoids us creating a TON of code in some cases. 1551 if (GEPOperator *SrcGEP = 1552 dyn_cast<GEPOperator>(Src->getOperand(0))) 1553 if (SrcGEP->getNumOperands() == 2 && shouldMergeGEPs(*Src, *SrcGEP)) 1554 return nullptr; // Wait until our source is folded to completion. 1555 1556 SmallVector<Value*, 8> Indices; 1557 1558 // Find out whether the last index in the source GEP is a sequential idx. 1559 bool EndsWithSequential = false; 1560 for (gep_type_iterator I = gep_type_begin(*Src), E = gep_type_end(*Src); 1561 I != E; ++I) 1562 EndsWithSequential = I.isSequential(); 1563 1564 // Can we combine the two pointer arithmetics offsets? 1565 if (EndsWithSequential) { 1566 // Replace: gep (gep %P, long B), long A, ... 1567 // With: T = long A+B; gep %P, T, ... 1568 // 1569 Value *SO1 = Src->getOperand(Src->getNumOperands()-1); 1570 Value *GO1 = GEP.getOperand(1); 1571 1572 // If they aren't the same type, then the input hasn't been processed 1573 // by the loop above yet (which canonicalizes sequential index types to 1574 // intptr_t). Just avoid transforming this until the input has been 1575 // normalized. 1576 if (SO1->getType() != GO1->getType()) 1577 return nullptr; 1578 1579 Value* Sum = SimplifyAddInst(GO1, SO1, false, false, DL, &TLI, &DT, &AC); 1580 // Only do the combine when we are sure the cost after the 1581 // merge is never more than that before the merge. 1582 if (Sum == nullptr) 1583 return nullptr; 1584 1585 // Update the GEP in place if possible. 1586 if (Src->getNumOperands() == 2) { 1587 GEP.setOperand(0, Src->getOperand(0)); 1588 GEP.setOperand(1, Sum); 1589 return &GEP; 1590 } 1591 Indices.append(Src->op_begin()+1, Src->op_end()-1); 1592 Indices.push_back(Sum); 1593 Indices.append(GEP.op_begin()+2, GEP.op_end()); 1594 } else if (isa<Constant>(*GEP.idx_begin()) && 1595 cast<Constant>(*GEP.idx_begin())->isNullValue() && 1596 Src->getNumOperands() != 1) { 1597 // Otherwise we can do the fold if the first index of the GEP is a zero 1598 Indices.append(Src->op_begin()+1, Src->op_end()); 1599 Indices.append(GEP.idx_begin()+1, GEP.idx_end()); 1600 } 1601 1602 if (!Indices.empty()) 1603 return GEP.isInBounds() && Src->isInBounds() 1604 ? GetElementPtrInst::CreateInBounds( 1605 Src->getSourceElementType(), Src->getOperand(0), Indices, 1606 GEP.getName()) 1607 : GetElementPtrInst::Create(Src->getSourceElementType(), 1608 Src->getOperand(0), Indices, 1609 GEP.getName()); 1610 } 1611 1612 if (GEP.getNumIndices() == 1) { 1613 unsigned AS = GEP.getPointerAddressSpace(); 1614 if (GEP.getOperand(1)->getType()->getScalarSizeInBits() == 1615 DL.getPointerSizeInBits(AS)) { 1616 Type *Ty = GEP.getSourceElementType(); 1617 uint64_t TyAllocSize = DL.getTypeAllocSize(Ty); 1618 1619 bool Matched = false; 1620 uint64_t C; 1621 Value *V = nullptr; 1622 if (TyAllocSize == 1) { 1623 V = GEP.getOperand(1); 1624 Matched = true; 1625 } else if (match(GEP.getOperand(1), 1626 m_AShr(m_Value(V), m_ConstantInt(C)))) { 1627 if (TyAllocSize == 1ULL << C) 1628 Matched = true; 1629 } else if (match(GEP.getOperand(1), 1630 m_SDiv(m_Value(V), m_ConstantInt(C)))) { 1631 if (TyAllocSize == C) 1632 Matched = true; 1633 } 1634 1635 if (Matched) { 1636 // Canonicalize (gep i8* X, -(ptrtoint Y)) 1637 // to (inttoptr (sub (ptrtoint X), (ptrtoint Y))) 1638 // The GEP pattern is emitted by the SCEV expander for certain kinds of 1639 // pointer arithmetic. 1640 if (match(V, m_Neg(m_PtrToInt(m_Value())))) { 1641 Operator *Index = cast<Operator>(V); 1642 Value *PtrToInt = Builder->CreatePtrToInt(PtrOp, Index->getType()); 1643 Value *NewSub = Builder->CreateSub(PtrToInt, Index->getOperand(1)); 1644 return CastInst::Create(Instruction::IntToPtr, NewSub, GEP.getType()); 1645 } 1646 // Canonicalize (gep i8* X, (ptrtoint Y)-(ptrtoint X)) 1647 // to (bitcast Y) 1648 Value *Y; 1649 if (match(V, m_Sub(m_PtrToInt(m_Value(Y)), 1650 m_PtrToInt(m_Specific(GEP.getOperand(0)))))) { 1651 return CastInst::CreatePointerBitCastOrAddrSpaceCast(Y, 1652 GEP.getType()); 1653 } 1654 } 1655 } 1656 } 1657 1658 // We do not handle pointer-vector geps here. 1659 if (GEP.getType()->isVectorTy()) 1660 return nullptr; 1661 1662 // Handle gep(bitcast x) and gep(gep x, 0, 0, 0). 1663 Value *StrippedPtr = PtrOp->stripPointerCasts(); 1664 PointerType *StrippedPtrTy = cast<PointerType>(StrippedPtr->getType()); 1665 1666 if (StrippedPtr != PtrOp) { 1667 bool HasZeroPointerIndex = false; 1668 if (ConstantInt *C = dyn_cast<ConstantInt>(GEP.getOperand(1))) 1669 HasZeroPointerIndex = C->isZero(); 1670 1671 // Transform: GEP (bitcast [10 x i8]* X to [0 x i8]*), i32 0, ... 1672 // into : GEP [10 x i8]* X, i32 0, ... 1673 // 1674 // Likewise, transform: GEP (bitcast i8* X to [0 x i8]*), i32 0, ... 1675 // into : GEP i8* X, ... 1676 // 1677 // This occurs when the program declares an array extern like "int X[];" 1678 if (HasZeroPointerIndex) { 1679 if (ArrayType *CATy = 1680 dyn_cast<ArrayType>(GEP.getSourceElementType())) { 1681 // GEP (bitcast i8* X to [0 x i8]*), i32 0, ... ? 1682 if (CATy->getElementType() == StrippedPtrTy->getElementType()) { 1683 // -> GEP i8* X, ... 1684 SmallVector<Value*, 8> Idx(GEP.idx_begin()+1, GEP.idx_end()); 1685 GetElementPtrInst *Res = GetElementPtrInst::Create( 1686 StrippedPtrTy->getElementType(), StrippedPtr, Idx, GEP.getName()); 1687 Res->setIsInBounds(GEP.isInBounds()); 1688 if (StrippedPtrTy->getAddressSpace() == GEP.getAddressSpace()) 1689 return Res; 1690 // Insert Res, and create an addrspacecast. 1691 // e.g., 1692 // GEP (addrspacecast i8 addrspace(1)* X to [0 x i8]*), i32 0, ... 1693 // -> 1694 // %0 = GEP i8 addrspace(1)* X, ... 1695 // addrspacecast i8 addrspace(1)* %0 to i8* 1696 return new AddrSpaceCastInst(Builder->Insert(Res), GEP.getType()); 1697 } 1698 1699 if (ArrayType *XATy = 1700 dyn_cast<ArrayType>(StrippedPtrTy->getElementType())){ 1701 // GEP (bitcast [10 x i8]* X to [0 x i8]*), i32 0, ... ? 1702 if (CATy->getElementType() == XATy->getElementType()) { 1703 // -> GEP [10 x i8]* X, i32 0, ... 1704 // At this point, we know that the cast source type is a pointer 1705 // to an array of the same type as the destination pointer 1706 // array. Because the array type is never stepped over (there 1707 // is a leading zero) we can fold the cast into this GEP. 1708 if (StrippedPtrTy->getAddressSpace() == GEP.getAddressSpace()) { 1709 GEP.setOperand(0, StrippedPtr); 1710 GEP.setSourceElementType(XATy); 1711 return &GEP; 1712 } 1713 // Cannot replace the base pointer directly because StrippedPtr's 1714 // address space is different. Instead, create a new GEP followed by 1715 // an addrspacecast. 1716 // e.g., 1717 // GEP (addrspacecast [10 x i8] addrspace(1)* X to [0 x i8]*), 1718 // i32 0, ... 1719 // -> 1720 // %0 = GEP [10 x i8] addrspace(1)* X, ... 1721 // addrspacecast i8 addrspace(1)* %0 to i8* 1722 SmallVector<Value*, 8> Idx(GEP.idx_begin(), GEP.idx_end()); 1723 Value *NewGEP = GEP.isInBounds() 1724 ? Builder->CreateInBoundsGEP( 1725 nullptr, StrippedPtr, Idx, GEP.getName()) 1726 : Builder->CreateGEP(nullptr, StrippedPtr, Idx, 1727 GEP.getName()); 1728 return new AddrSpaceCastInst(NewGEP, GEP.getType()); 1729 } 1730 } 1731 } 1732 } else if (GEP.getNumOperands() == 2) { 1733 // Transform things like: 1734 // %t = getelementptr i32* bitcast ([2 x i32]* %str to i32*), i32 %V 1735 // into: %t1 = getelementptr [2 x i32]* %str, i32 0, i32 %V; bitcast 1736 Type *SrcElTy = StrippedPtrTy->getElementType(); 1737 Type *ResElTy = GEP.getSourceElementType(); 1738 if (SrcElTy->isArrayTy() && 1739 DL.getTypeAllocSize(SrcElTy->getArrayElementType()) == 1740 DL.getTypeAllocSize(ResElTy)) { 1741 Type *IdxType = DL.getIntPtrType(GEP.getType()); 1742 Value *Idx[2] = { Constant::getNullValue(IdxType), GEP.getOperand(1) }; 1743 Value *NewGEP = 1744 GEP.isInBounds() 1745 ? Builder->CreateInBoundsGEP(nullptr, StrippedPtr, Idx, 1746 GEP.getName()) 1747 : Builder->CreateGEP(nullptr, StrippedPtr, Idx, GEP.getName()); 1748 1749 // V and GEP are both pointer types --> BitCast 1750 return CastInst::CreatePointerBitCastOrAddrSpaceCast(NewGEP, 1751 GEP.getType()); 1752 } 1753 1754 // Transform things like: 1755 // %V = mul i64 %N, 4 1756 // %t = getelementptr i8* bitcast (i32* %arr to i8*), i32 %V 1757 // into: %t1 = getelementptr i32* %arr, i32 %N; bitcast 1758 if (ResElTy->isSized() && SrcElTy->isSized()) { 1759 // Check that changing the type amounts to dividing the index by a scale 1760 // factor. 1761 uint64_t ResSize = DL.getTypeAllocSize(ResElTy); 1762 uint64_t SrcSize = DL.getTypeAllocSize(SrcElTy); 1763 if (ResSize && SrcSize % ResSize == 0) { 1764 Value *Idx = GEP.getOperand(1); 1765 unsigned BitWidth = Idx->getType()->getPrimitiveSizeInBits(); 1766 uint64_t Scale = SrcSize / ResSize; 1767 1768 // Earlier transforms ensure that the index has type IntPtrType, which 1769 // considerably simplifies the logic by eliminating implicit casts. 1770 assert(Idx->getType() == DL.getIntPtrType(GEP.getType()) && 1771 "Index not cast to pointer width?"); 1772 1773 bool NSW; 1774 if (Value *NewIdx = Descale(Idx, APInt(BitWidth, Scale), NSW)) { 1775 // Successfully decomposed Idx as NewIdx * Scale, form a new GEP. 1776 // If the multiplication NewIdx * Scale may overflow then the new 1777 // GEP may not be "inbounds". 1778 Value *NewGEP = 1779 GEP.isInBounds() && NSW 1780 ? Builder->CreateInBoundsGEP(nullptr, StrippedPtr, NewIdx, 1781 GEP.getName()) 1782 : Builder->CreateGEP(nullptr, StrippedPtr, NewIdx, 1783 GEP.getName()); 1784 1785 // The NewGEP must be pointer typed, so must the old one -> BitCast 1786 return CastInst::CreatePointerBitCastOrAddrSpaceCast(NewGEP, 1787 GEP.getType()); 1788 } 1789 } 1790 } 1791 1792 // Similarly, transform things like: 1793 // getelementptr i8* bitcast ([100 x double]* X to i8*), i32 %tmp 1794 // (where tmp = 8*tmp2) into: 1795 // getelementptr [100 x double]* %arr, i32 0, i32 %tmp2; bitcast 1796 if (ResElTy->isSized() && SrcElTy->isSized() && SrcElTy->isArrayTy()) { 1797 // Check that changing to the array element type amounts to dividing the 1798 // index by a scale factor. 1799 uint64_t ResSize = DL.getTypeAllocSize(ResElTy); 1800 uint64_t ArrayEltSize = 1801 DL.getTypeAllocSize(SrcElTy->getArrayElementType()); 1802 if (ResSize && ArrayEltSize % ResSize == 0) { 1803 Value *Idx = GEP.getOperand(1); 1804 unsigned BitWidth = Idx->getType()->getPrimitiveSizeInBits(); 1805 uint64_t Scale = ArrayEltSize / ResSize; 1806 1807 // Earlier transforms ensure that the index has type IntPtrType, which 1808 // considerably simplifies the logic by eliminating implicit casts. 1809 assert(Idx->getType() == DL.getIntPtrType(GEP.getType()) && 1810 "Index not cast to pointer width?"); 1811 1812 bool NSW; 1813 if (Value *NewIdx = Descale(Idx, APInt(BitWidth, Scale), NSW)) { 1814 // Successfully decomposed Idx as NewIdx * Scale, form a new GEP. 1815 // If the multiplication NewIdx * Scale may overflow then the new 1816 // GEP may not be "inbounds". 1817 Value *Off[2] = { 1818 Constant::getNullValue(DL.getIntPtrType(GEP.getType())), 1819 NewIdx}; 1820 1821 Value *NewGEP = GEP.isInBounds() && NSW 1822 ? Builder->CreateInBoundsGEP( 1823 SrcElTy, StrippedPtr, Off, GEP.getName()) 1824 : Builder->CreateGEP(SrcElTy, StrippedPtr, Off, 1825 GEP.getName()); 1826 // The NewGEP must be pointer typed, so must the old one -> BitCast 1827 return CastInst::CreatePointerBitCastOrAddrSpaceCast(NewGEP, 1828 GEP.getType()); 1829 } 1830 } 1831 } 1832 } 1833 } 1834 1835 // addrspacecast between types is canonicalized as a bitcast, then an 1836 // addrspacecast. To take advantage of the below bitcast + struct GEP, look 1837 // through the addrspacecast. 1838 if (AddrSpaceCastInst *ASC = dyn_cast<AddrSpaceCastInst>(PtrOp)) { 1839 // X = bitcast A addrspace(1)* to B addrspace(1)* 1840 // Y = addrspacecast A addrspace(1)* to B addrspace(2)* 1841 // Z = gep Y, <...constant indices...> 1842 // Into an addrspacecasted GEP of the struct. 1843 if (BitCastInst *BC = dyn_cast<BitCastInst>(ASC->getOperand(0))) 1844 PtrOp = BC; 1845 } 1846 1847 /// See if we can simplify: 1848 /// X = bitcast A* to B* 1849 /// Y = gep X, <...constant indices...> 1850 /// into a gep of the original struct. This is important for SROA and alias 1851 /// analysis of unions. If "A" is also a bitcast, wait for A/X to be merged. 1852 if (BitCastInst *BCI = dyn_cast<BitCastInst>(PtrOp)) { 1853 Value *Operand = BCI->getOperand(0); 1854 PointerType *OpType = cast<PointerType>(Operand->getType()); 1855 unsigned OffsetBits = DL.getPointerTypeSizeInBits(GEP.getType()); 1856 APInt Offset(OffsetBits, 0); 1857 if (!isa<BitCastInst>(Operand) && 1858 GEP.accumulateConstantOffset(DL, Offset)) { 1859 1860 // If this GEP instruction doesn't move the pointer, just replace the GEP 1861 // with a bitcast of the real input to the dest type. 1862 if (!Offset) { 1863 // If the bitcast is of an allocation, and the allocation will be 1864 // converted to match the type of the cast, don't touch this. 1865 if (isa<AllocaInst>(Operand) || isAllocationFn(Operand, &TLI)) { 1866 // See if the bitcast simplifies, if so, don't nuke this GEP yet. 1867 if (Instruction *I = visitBitCast(*BCI)) { 1868 if (I != BCI) { 1869 I->takeName(BCI); 1870 BCI->getParent()->getInstList().insert(BCI->getIterator(), I); 1871 replaceInstUsesWith(*BCI, I); 1872 } 1873 return &GEP; 1874 } 1875 } 1876 1877 if (Operand->getType()->getPointerAddressSpace() != GEP.getAddressSpace()) 1878 return new AddrSpaceCastInst(Operand, GEP.getType()); 1879 return new BitCastInst(Operand, GEP.getType()); 1880 } 1881 1882 // Otherwise, if the offset is non-zero, we need to find out if there is a 1883 // field at Offset in 'A's type. If so, we can pull the cast through the 1884 // GEP. 1885 SmallVector<Value*, 8> NewIndices; 1886 if (FindElementAtOffset(OpType, Offset.getSExtValue(), NewIndices)) { 1887 Value *NGEP = 1888 GEP.isInBounds() 1889 ? Builder->CreateInBoundsGEP(nullptr, Operand, NewIndices) 1890 : Builder->CreateGEP(nullptr, Operand, NewIndices); 1891 1892 if (NGEP->getType() == GEP.getType()) 1893 return replaceInstUsesWith(GEP, NGEP); 1894 NGEP->takeName(&GEP); 1895 1896 if (NGEP->getType()->getPointerAddressSpace() != GEP.getAddressSpace()) 1897 return new AddrSpaceCastInst(NGEP, GEP.getType()); 1898 return new BitCastInst(NGEP, GEP.getType()); 1899 } 1900 } 1901 } 1902 1903 if (!GEP.isInBounds()) { 1904 unsigned PtrWidth = 1905 DL.getPointerSizeInBits(PtrOp->getType()->getPointerAddressSpace()); 1906 APInt BasePtrOffset(PtrWidth, 0); 1907 Value *UnderlyingPtrOp = 1908 PtrOp->stripAndAccumulateInBoundsConstantOffsets(DL, 1909 BasePtrOffset); 1910 if (auto *AI = dyn_cast<AllocaInst>(UnderlyingPtrOp)) { 1911 if (GEP.accumulateConstantOffset(DL, BasePtrOffset) && 1912 BasePtrOffset.isNonNegative()) { 1913 APInt AllocSize(PtrWidth, DL.getTypeAllocSize(AI->getAllocatedType())); 1914 if (BasePtrOffset.ule(AllocSize)) { 1915 return GetElementPtrInst::CreateInBounds( 1916 PtrOp, makeArrayRef(Ops).slice(1), GEP.getName()); 1917 } 1918 } 1919 } 1920 } 1921 1922 return nullptr; 1923 } 1924 1925 static bool isNeverEqualToUnescapedAlloc(Value *V, const TargetLibraryInfo *TLI, 1926 Instruction *AI) { 1927 if (isa<ConstantPointerNull>(V)) 1928 return true; 1929 if (auto *LI = dyn_cast<LoadInst>(V)) 1930 return isa<GlobalVariable>(LI->getPointerOperand()); 1931 // Two distinct allocations will never be equal. 1932 // We rely on LookThroughBitCast in isAllocLikeFn being false, since looking 1933 // through bitcasts of V can cause 1934 // the result statement below to be true, even when AI and V (ex: 1935 // i8* ->i32* ->i8* of AI) are the same allocations. 1936 return isAllocLikeFn(V, TLI) && V != AI; 1937 } 1938 1939 static bool 1940 isAllocSiteRemovable(Instruction *AI, SmallVectorImpl<WeakVH> &Users, 1941 const TargetLibraryInfo *TLI) { 1942 SmallVector<Instruction*, 4> Worklist; 1943 Worklist.push_back(AI); 1944 1945 do { 1946 Instruction *PI = Worklist.pop_back_val(); 1947 for (User *U : PI->users()) { 1948 Instruction *I = cast<Instruction>(U); 1949 switch (I->getOpcode()) { 1950 default: 1951 // Give up the moment we see something we can't handle. 1952 return false; 1953 1954 case Instruction::BitCast: 1955 case Instruction::GetElementPtr: 1956 Users.emplace_back(I); 1957 Worklist.push_back(I); 1958 continue; 1959 1960 case Instruction::ICmp: { 1961 ICmpInst *ICI = cast<ICmpInst>(I); 1962 // We can fold eq/ne comparisons with null to false/true, respectively. 1963 // We also fold comparisons in some conditions provided the alloc has 1964 // not escaped (see isNeverEqualToUnescapedAlloc). 1965 if (!ICI->isEquality()) 1966 return false; 1967 unsigned OtherIndex = (ICI->getOperand(0) == PI) ? 1 : 0; 1968 if (!isNeverEqualToUnescapedAlloc(ICI->getOperand(OtherIndex), TLI, AI)) 1969 return false; 1970 Users.emplace_back(I); 1971 continue; 1972 } 1973 1974 case Instruction::Call: 1975 // Ignore no-op and store intrinsics. 1976 if (IntrinsicInst *II = dyn_cast<IntrinsicInst>(I)) { 1977 switch (II->getIntrinsicID()) { 1978 default: 1979 return false; 1980 1981 case Intrinsic::memmove: 1982 case Intrinsic::memcpy: 1983 case Intrinsic::memset: { 1984 MemIntrinsic *MI = cast<MemIntrinsic>(II); 1985 if (MI->isVolatile() || MI->getRawDest() != PI) 1986 return false; 1987 LLVM_FALLTHROUGH; 1988 } 1989 case Intrinsic::dbg_declare: 1990 case Intrinsic::dbg_value: 1991 case Intrinsic::invariant_start: 1992 case Intrinsic::invariant_end: 1993 case Intrinsic::lifetime_start: 1994 case Intrinsic::lifetime_end: 1995 case Intrinsic::objectsize: 1996 Users.emplace_back(I); 1997 continue; 1998 } 1999 } 2000 2001 if (isFreeCall(I, TLI)) { 2002 Users.emplace_back(I); 2003 continue; 2004 } 2005 return false; 2006 2007 case Instruction::Store: { 2008 StoreInst *SI = cast<StoreInst>(I); 2009 if (SI->isVolatile() || SI->getPointerOperand() != PI) 2010 return false; 2011 Users.emplace_back(I); 2012 continue; 2013 } 2014 } 2015 llvm_unreachable("missing a return?"); 2016 } 2017 } while (!Worklist.empty()); 2018 return true; 2019 } 2020 2021 Instruction *InstCombiner::visitAllocSite(Instruction &MI) { 2022 // If we have a malloc call which is only used in any amount of comparisons 2023 // to null and free calls, delete the calls and replace the comparisons with 2024 // true or false as appropriate. 2025 SmallVector<WeakVH, 64> Users; 2026 if (isAllocSiteRemovable(&MI, Users, &TLI)) { 2027 for (unsigned i = 0, e = Users.size(); i != e; ++i) { 2028 // Lowering all @llvm.objectsize calls first because they may 2029 // use a bitcast/GEP of the alloca we are removing. 2030 if (!Users[i]) 2031 continue; 2032 2033 Instruction *I = cast<Instruction>(&*Users[i]); 2034 2035 if (IntrinsicInst *II = dyn_cast<IntrinsicInst>(I)) { 2036 if (II->getIntrinsicID() == Intrinsic::objectsize) { 2037 ConstantInt *Result = lowerObjectSizeCall(II, DL, &TLI, 2038 /*MustSucceed=*/true); 2039 replaceInstUsesWith(*I, Result); 2040 eraseInstFromFunction(*I); 2041 Users[i] = nullptr; // Skip examining in the next loop. 2042 } 2043 } 2044 } 2045 for (unsigned i = 0, e = Users.size(); i != e; ++i) { 2046 if (!Users[i]) 2047 continue; 2048 2049 Instruction *I = cast<Instruction>(&*Users[i]); 2050 2051 if (ICmpInst *C = dyn_cast<ICmpInst>(I)) { 2052 replaceInstUsesWith(*C, 2053 ConstantInt::get(Type::getInt1Ty(C->getContext()), 2054 C->isFalseWhenEqual())); 2055 } else if (isa<BitCastInst>(I) || isa<GetElementPtrInst>(I)) { 2056 replaceInstUsesWith(*I, UndefValue::get(I->getType())); 2057 } 2058 eraseInstFromFunction(*I); 2059 } 2060 2061 if (InvokeInst *II = dyn_cast<InvokeInst>(&MI)) { 2062 // Replace invoke with a NOP intrinsic to maintain the original CFG 2063 Module *M = II->getModule(); 2064 Function *F = Intrinsic::getDeclaration(M, Intrinsic::donothing); 2065 InvokeInst::Create(F, II->getNormalDest(), II->getUnwindDest(), 2066 None, "", II->getParent()); 2067 } 2068 return eraseInstFromFunction(MI); 2069 } 2070 return nullptr; 2071 } 2072 2073 /// \brief Move the call to free before a NULL test. 2074 /// 2075 /// Check if this free is accessed after its argument has been test 2076 /// against NULL (property 0). 2077 /// If yes, it is legal to move this call in its predecessor block. 2078 /// 2079 /// The move is performed only if the block containing the call to free 2080 /// will be removed, i.e.: 2081 /// 1. it has only one predecessor P, and P has two successors 2082 /// 2. it contains the call and an unconditional branch 2083 /// 3. its successor is the same as its predecessor's successor 2084 /// 2085 /// The profitability is out-of concern here and this function should 2086 /// be called only if the caller knows this transformation would be 2087 /// profitable (e.g., for code size). 2088 static Instruction * 2089 tryToMoveFreeBeforeNullTest(CallInst &FI) { 2090 Value *Op = FI.getArgOperand(0); 2091 BasicBlock *FreeInstrBB = FI.getParent(); 2092 BasicBlock *PredBB = FreeInstrBB->getSinglePredecessor(); 2093 2094 // Validate part of constraint #1: Only one predecessor 2095 // FIXME: We can extend the number of predecessor, but in that case, we 2096 // would duplicate the call to free in each predecessor and it may 2097 // not be profitable even for code size. 2098 if (!PredBB) 2099 return nullptr; 2100 2101 // Validate constraint #2: Does this block contains only the call to 2102 // free and an unconditional branch? 2103 // FIXME: We could check if we can speculate everything in the 2104 // predecessor block 2105 if (FreeInstrBB->size() != 2) 2106 return nullptr; 2107 BasicBlock *SuccBB; 2108 if (!match(FreeInstrBB->getTerminator(), m_UnconditionalBr(SuccBB))) 2109 return nullptr; 2110 2111 // Validate the rest of constraint #1 by matching on the pred branch. 2112 TerminatorInst *TI = PredBB->getTerminator(); 2113 BasicBlock *TrueBB, *FalseBB; 2114 ICmpInst::Predicate Pred; 2115 if (!match(TI, m_Br(m_ICmp(Pred, m_Specific(Op), m_Zero()), TrueBB, FalseBB))) 2116 return nullptr; 2117 if (Pred != ICmpInst::ICMP_EQ && Pred != ICmpInst::ICMP_NE) 2118 return nullptr; 2119 2120 // Validate constraint #3: Ensure the null case just falls through. 2121 if (SuccBB != (Pred == ICmpInst::ICMP_EQ ? TrueBB : FalseBB)) 2122 return nullptr; 2123 assert(FreeInstrBB == (Pred == ICmpInst::ICMP_EQ ? FalseBB : TrueBB) && 2124 "Broken CFG: missing edge from predecessor to successor"); 2125 2126 FI.moveBefore(TI); 2127 return &FI; 2128 } 2129 2130 2131 Instruction *InstCombiner::visitFree(CallInst &FI) { 2132 Value *Op = FI.getArgOperand(0); 2133 2134 // free undef -> unreachable. 2135 if (isa<UndefValue>(Op)) { 2136 // Insert a new store to null because we cannot modify the CFG here. 2137 Builder->CreateStore(ConstantInt::getTrue(FI.getContext()), 2138 UndefValue::get(Type::getInt1PtrTy(FI.getContext()))); 2139 return eraseInstFromFunction(FI); 2140 } 2141 2142 // If we have 'free null' delete the instruction. This can happen in stl code 2143 // when lots of inlining happens. 2144 if (isa<ConstantPointerNull>(Op)) 2145 return eraseInstFromFunction(FI); 2146 2147 // If we optimize for code size, try to move the call to free before the null 2148 // test so that simplify cfg can remove the empty block and dead code 2149 // elimination the branch. I.e., helps to turn something like: 2150 // if (foo) free(foo); 2151 // into 2152 // free(foo); 2153 if (MinimizeSize) 2154 if (Instruction *I = tryToMoveFreeBeforeNullTest(FI)) 2155 return I; 2156 2157 return nullptr; 2158 } 2159 2160 Instruction *InstCombiner::visitReturnInst(ReturnInst &RI) { 2161 if (RI.getNumOperands() == 0) // ret void 2162 return nullptr; 2163 2164 Value *ResultOp = RI.getOperand(0); 2165 Type *VTy = ResultOp->getType(); 2166 if (!VTy->isIntegerTy()) 2167 return nullptr; 2168 2169 // There might be assume intrinsics dominating this return that completely 2170 // determine the value. If so, constant fold it. 2171 unsigned BitWidth = VTy->getPrimitiveSizeInBits(); 2172 APInt KnownZero(BitWidth, 0), KnownOne(BitWidth, 0); 2173 computeKnownBits(ResultOp, KnownZero, KnownOne, 0, &RI); 2174 if ((KnownZero|KnownOne).isAllOnesValue()) 2175 RI.setOperand(0, Constant::getIntegerValue(VTy, KnownOne)); 2176 2177 return nullptr; 2178 } 2179 2180 Instruction *InstCombiner::visitBranchInst(BranchInst &BI) { 2181 // Change br (not X), label True, label False to: br X, label False, True 2182 Value *X = nullptr; 2183 BasicBlock *TrueDest; 2184 BasicBlock *FalseDest; 2185 if (match(&BI, m_Br(m_Not(m_Value(X)), TrueDest, FalseDest)) && 2186 !isa<Constant>(X)) { 2187 // Swap Destinations and condition... 2188 BI.setCondition(X); 2189 BI.swapSuccessors(); 2190 return &BI; 2191 } 2192 2193 // If the condition is irrelevant, remove the use so that other 2194 // transforms on the condition become more effective. 2195 if (BI.isConditional() && 2196 BI.getSuccessor(0) == BI.getSuccessor(1) && 2197 !isa<UndefValue>(BI.getCondition())) { 2198 BI.setCondition(UndefValue::get(BI.getCondition()->getType())); 2199 return &BI; 2200 } 2201 2202 // Canonicalize fcmp_one -> fcmp_oeq 2203 FCmpInst::Predicate FPred; Value *Y; 2204 if (match(&BI, m_Br(m_FCmp(FPred, m_Value(X), m_Value(Y)), 2205 TrueDest, FalseDest)) && 2206 BI.getCondition()->hasOneUse()) 2207 if (FPred == FCmpInst::FCMP_ONE || FPred == FCmpInst::FCMP_OLE || 2208 FPred == FCmpInst::FCMP_OGE) { 2209 FCmpInst *Cond = cast<FCmpInst>(BI.getCondition()); 2210 Cond->setPredicate(FCmpInst::getInversePredicate(FPred)); 2211 2212 // Swap Destinations and condition. 2213 BI.swapSuccessors(); 2214 Worklist.Add(Cond); 2215 return &BI; 2216 } 2217 2218 // Canonicalize icmp_ne -> icmp_eq 2219 ICmpInst::Predicate IPred; 2220 if (match(&BI, m_Br(m_ICmp(IPred, m_Value(X), m_Value(Y)), 2221 TrueDest, FalseDest)) && 2222 BI.getCondition()->hasOneUse()) 2223 if (IPred == ICmpInst::ICMP_NE || IPred == ICmpInst::ICMP_ULE || 2224 IPred == ICmpInst::ICMP_SLE || IPred == ICmpInst::ICMP_UGE || 2225 IPred == ICmpInst::ICMP_SGE) { 2226 ICmpInst *Cond = cast<ICmpInst>(BI.getCondition()); 2227 Cond->setPredicate(ICmpInst::getInversePredicate(IPred)); 2228 // Swap Destinations and condition. 2229 BI.swapSuccessors(); 2230 Worklist.Add(Cond); 2231 return &BI; 2232 } 2233 2234 return nullptr; 2235 } 2236 2237 Instruction *InstCombiner::visitSwitchInst(SwitchInst &SI) { 2238 Value *Cond = SI.getCondition(); 2239 Value *Op0; 2240 ConstantInt *AddRHS; 2241 if (match(Cond, m_Add(m_Value(Op0), m_ConstantInt(AddRHS)))) { 2242 // Change 'switch (X+4) case 1:' into 'switch (X) case -3'. 2243 for (SwitchInst::CaseIt CaseIter : SI.cases()) { 2244 Constant *NewCase = ConstantExpr::getSub(CaseIter.getCaseValue(), AddRHS); 2245 assert(isa<ConstantInt>(NewCase) && 2246 "Result of expression should be constant"); 2247 CaseIter.setValue(cast<ConstantInt>(NewCase)); 2248 } 2249 SI.setCondition(Op0); 2250 return &SI; 2251 } 2252 2253 unsigned BitWidth = cast<IntegerType>(Cond->getType())->getBitWidth(); 2254 APInt KnownZero(BitWidth, 0), KnownOne(BitWidth, 0); 2255 computeKnownBits(Cond, KnownZero, KnownOne, 0, &SI); 2256 unsigned LeadingKnownZeros = KnownZero.countLeadingOnes(); 2257 unsigned LeadingKnownOnes = KnownOne.countLeadingOnes(); 2258 2259 // Compute the number of leading bits we can ignore. 2260 // TODO: A better way to determine this would use ComputeNumSignBits(). 2261 for (auto &C : SI.cases()) { 2262 LeadingKnownZeros = std::min( 2263 LeadingKnownZeros, C.getCaseValue()->getValue().countLeadingZeros()); 2264 LeadingKnownOnes = std::min( 2265 LeadingKnownOnes, C.getCaseValue()->getValue().countLeadingOnes()); 2266 } 2267 2268 unsigned NewWidth = BitWidth - std::max(LeadingKnownZeros, LeadingKnownOnes); 2269 2270 // Shrink the condition operand if the new type is smaller than the old type. 2271 // This may produce a non-standard type for the switch, but that's ok because 2272 // the backend should extend back to a legal type for the target. 2273 if (NewWidth > 0 && NewWidth < BitWidth) { 2274 IntegerType *Ty = IntegerType::get(SI.getContext(), NewWidth); 2275 Builder->SetInsertPoint(&SI); 2276 Value *NewCond = Builder->CreateTrunc(Cond, Ty, "trunc"); 2277 SI.setCondition(NewCond); 2278 2279 for (SwitchInst::CaseIt CaseIter : SI.cases()) { 2280 APInt TruncatedCase = CaseIter.getCaseValue()->getValue().trunc(NewWidth); 2281 CaseIter.setValue(ConstantInt::get(SI.getContext(), TruncatedCase)); 2282 } 2283 return &SI; 2284 } 2285 2286 return nullptr; 2287 } 2288 2289 Instruction *InstCombiner::visitExtractValueInst(ExtractValueInst &EV) { 2290 Value *Agg = EV.getAggregateOperand(); 2291 2292 if (!EV.hasIndices()) 2293 return replaceInstUsesWith(EV, Agg); 2294 2295 if (Value *V = 2296 SimplifyExtractValueInst(Agg, EV.getIndices(), DL, &TLI, &DT, &AC)) 2297 return replaceInstUsesWith(EV, V); 2298 2299 if (InsertValueInst *IV = dyn_cast<InsertValueInst>(Agg)) { 2300 // We're extracting from an insertvalue instruction, compare the indices 2301 const unsigned *exti, *exte, *insi, *inse; 2302 for (exti = EV.idx_begin(), insi = IV->idx_begin(), 2303 exte = EV.idx_end(), inse = IV->idx_end(); 2304 exti != exte && insi != inse; 2305 ++exti, ++insi) { 2306 if (*insi != *exti) 2307 // The insert and extract both reference distinctly different elements. 2308 // This means the extract is not influenced by the insert, and we can 2309 // replace the aggregate operand of the extract with the aggregate 2310 // operand of the insert. i.e., replace 2311 // %I = insertvalue { i32, { i32 } } %A, { i32 } { i32 42 }, 1 2312 // %E = extractvalue { i32, { i32 } } %I, 0 2313 // with 2314 // %E = extractvalue { i32, { i32 } } %A, 0 2315 return ExtractValueInst::Create(IV->getAggregateOperand(), 2316 EV.getIndices()); 2317 } 2318 if (exti == exte && insi == inse) 2319 // Both iterators are at the end: Index lists are identical. Replace 2320 // %B = insertvalue { i32, { i32 } } %A, i32 42, 1, 0 2321 // %C = extractvalue { i32, { i32 } } %B, 1, 0 2322 // with "i32 42" 2323 return replaceInstUsesWith(EV, IV->getInsertedValueOperand()); 2324 if (exti == exte) { 2325 // The extract list is a prefix of the insert list. i.e. replace 2326 // %I = insertvalue { i32, { i32 } } %A, i32 42, 1, 0 2327 // %E = extractvalue { i32, { i32 } } %I, 1 2328 // with 2329 // %X = extractvalue { i32, { i32 } } %A, 1 2330 // %E = insertvalue { i32 } %X, i32 42, 0 2331 // by switching the order of the insert and extract (though the 2332 // insertvalue should be left in, since it may have other uses). 2333 Value *NewEV = Builder->CreateExtractValue(IV->getAggregateOperand(), 2334 EV.getIndices()); 2335 return InsertValueInst::Create(NewEV, IV->getInsertedValueOperand(), 2336 makeArrayRef(insi, inse)); 2337 } 2338 if (insi == inse) 2339 // The insert list is a prefix of the extract list 2340 // We can simply remove the common indices from the extract and make it 2341 // operate on the inserted value instead of the insertvalue result. 2342 // i.e., replace 2343 // %I = insertvalue { i32, { i32 } } %A, { i32 } { i32 42 }, 1 2344 // %E = extractvalue { i32, { i32 } } %I, 1, 0 2345 // with 2346 // %E extractvalue { i32 } { i32 42 }, 0 2347 return ExtractValueInst::Create(IV->getInsertedValueOperand(), 2348 makeArrayRef(exti, exte)); 2349 } 2350 if (IntrinsicInst *II = dyn_cast<IntrinsicInst>(Agg)) { 2351 // We're extracting from an intrinsic, see if we're the only user, which 2352 // allows us to simplify multiple result intrinsics to simpler things that 2353 // just get one value. 2354 if (II->hasOneUse()) { 2355 // Check if we're grabbing the overflow bit or the result of a 'with 2356 // overflow' intrinsic. If it's the latter we can remove the intrinsic 2357 // and replace it with a traditional binary instruction. 2358 switch (II->getIntrinsicID()) { 2359 case Intrinsic::uadd_with_overflow: 2360 case Intrinsic::sadd_with_overflow: 2361 if (*EV.idx_begin() == 0) { // Normal result. 2362 Value *LHS = II->getArgOperand(0), *RHS = II->getArgOperand(1); 2363 replaceInstUsesWith(*II, UndefValue::get(II->getType())); 2364 eraseInstFromFunction(*II); 2365 return BinaryOperator::CreateAdd(LHS, RHS); 2366 } 2367 2368 // If the normal result of the add is dead, and the RHS is a constant, 2369 // we can transform this into a range comparison. 2370 // overflow = uadd a, -4 --> overflow = icmp ugt a, 3 2371 if (II->getIntrinsicID() == Intrinsic::uadd_with_overflow) 2372 if (ConstantInt *CI = dyn_cast<ConstantInt>(II->getArgOperand(1))) 2373 return new ICmpInst(ICmpInst::ICMP_UGT, II->getArgOperand(0), 2374 ConstantExpr::getNot(CI)); 2375 break; 2376 case Intrinsic::usub_with_overflow: 2377 case Intrinsic::ssub_with_overflow: 2378 if (*EV.idx_begin() == 0) { // Normal result. 2379 Value *LHS = II->getArgOperand(0), *RHS = II->getArgOperand(1); 2380 replaceInstUsesWith(*II, UndefValue::get(II->getType())); 2381 eraseInstFromFunction(*II); 2382 return BinaryOperator::CreateSub(LHS, RHS); 2383 } 2384 break; 2385 case Intrinsic::umul_with_overflow: 2386 case Intrinsic::smul_with_overflow: 2387 if (*EV.idx_begin() == 0) { // Normal result. 2388 Value *LHS = II->getArgOperand(0), *RHS = II->getArgOperand(1); 2389 replaceInstUsesWith(*II, UndefValue::get(II->getType())); 2390 eraseInstFromFunction(*II); 2391 return BinaryOperator::CreateMul(LHS, RHS); 2392 } 2393 break; 2394 default: 2395 break; 2396 } 2397 } 2398 } 2399 if (LoadInst *L = dyn_cast<LoadInst>(Agg)) 2400 // If the (non-volatile) load only has one use, we can rewrite this to a 2401 // load from a GEP. This reduces the size of the load. If a load is used 2402 // only by extractvalue instructions then this either must have been 2403 // optimized before, or it is a struct with padding, in which case we 2404 // don't want to do the transformation as it loses padding knowledge. 2405 if (L->isSimple() && L->hasOneUse()) { 2406 // extractvalue has integer indices, getelementptr has Value*s. Convert. 2407 SmallVector<Value*, 4> Indices; 2408 // Prefix an i32 0 since we need the first element. 2409 Indices.push_back(Builder->getInt32(0)); 2410 for (ExtractValueInst::idx_iterator I = EV.idx_begin(), E = EV.idx_end(); 2411 I != E; ++I) 2412 Indices.push_back(Builder->getInt32(*I)); 2413 2414 // We need to insert these at the location of the old load, not at that of 2415 // the extractvalue. 2416 Builder->SetInsertPoint(L); 2417 Value *GEP = Builder->CreateInBoundsGEP(L->getType(), 2418 L->getPointerOperand(), Indices); 2419 // Returning the load directly will cause the main loop to insert it in 2420 // the wrong spot, so use replaceInstUsesWith(). 2421 return replaceInstUsesWith(EV, Builder->CreateLoad(GEP)); 2422 } 2423 // We could simplify extracts from other values. Note that nested extracts may 2424 // already be simplified implicitly by the above: extract (extract (insert) ) 2425 // will be translated into extract ( insert ( extract ) ) first and then just 2426 // the value inserted, if appropriate. Similarly for extracts from single-use 2427 // loads: extract (extract (load)) will be translated to extract (load (gep)) 2428 // and if again single-use then via load (gep (gep)) to load (gep). 2429 // However, double extracts from e.g. function arguments or return values 2430 // aren't handled yet. 2431 return nullptr; 2432 } 2433 2434 /// Return 'true' if the given typeinfo will match anything. 2435 static bool isCatchAll(EHPersonality Personality, Constant *TypeInfo) { 2436 switch (Personality) { 2437 case EHPersonality::GNU_C: 2438 case EHPersonality::GNU_C_SjLj: 2439 case EHPersonality::Rust: 2440 // The GCC C EH and Rust personality only exists to support cleanups, so 2441 // it's not clear what the semantics of catch clauses are. 2442 return false; 2443 case EHPersonality::Unknown: 2444 return false; 2445 case EHPersonality::GNU_Ada: 2446 // While __gnat_all_others_value will match any Ada exception, it doesn't 2447 // match foreign exceptions (or didn't, before gcc-4.7). 2448 return false; 2449 case EHPersonality::GNU_CXX: 2450 case EHPersonality::GNU_CXX_SjLj: 2451 case EHPersonality::GNU_ObjC: 2452 case EHPersonality::MSVC_X86SEH: 2453 case EHPersonality::MSVC_Win64SEH: 2454 case EHPersonality::MSVC_CXX: 2455 case EHPersonality::CoreCLR: 2456 return TypeInfo->isNullValue(); 2457 } 2458 llvm_unreachable("invalid enum"); 2459 } 2460 2461 static bool shorter_filter(const Value *LHS, const Value *RHS) { 2462 return 2463 cast<ArrayType>(LHS->getType())->getNumElements() 2464 < 2465 cast<ArrayType>(RHS->getType())->getNumElements(); 2466 } 2467 2468 Instruction *InstCombiner::visitLandingPadInst(LandingPadInst &LI) { 2469 // The logic here should be correct for any real-world personality function. 2470 // However if that turns out not to be true, the offending logic can always 2471 // be conditioned on the personality function, like the catch-all logic is. 2472 EHPersonality Personality = 2473 classifyEHPersonality(LI.getParent()->getParent()->getPersonalityFn()); 2474 2475 // Simplify the list of clauses, eg by removing repeated catch clauses 2476 // (these are often created by inlining). 2477 bool MakeNewInstruction = false; // If true, recreate using the following: 2478 SmallVector<Constant *, 16> NewClauses; // - Clauses for the new instruction; 2479 bool CleanupFlag = LI.isCleanup(); // - The new instruction is a cleanup. 2480 2481 SmallPtrSet<Value *, 16> AlreadyCaught; // Typeinfos known caught already. 2482 for (unsigned i = 0, e = LI.getNumClauses(); i != e; ++i) { 2483 bool isLastClause = i + 1 == e; 2484 if (LI.isCatch(i)) { 2485 // A catch clause. 2486 Constant *CatchClause = LI.getClause(i); 2487 Constant *TypeInfo = CatchClause->stripPointerCasts(); 2488 2489 // If we already saw this clause, there is no point in having a second 2490 // copy of it. 2491 if (AlreadyCaught.insert(TypeInfo).second) { 2492 // This catch clause was not already seen. 2493 NewClauses.push_back(CatchClause); 2494 } else { 2495 // Repeated catch clause - drop the redundant copy. 2496 MakeNewInstruction = true; 2497 } 2498 2499 // If this is a catch-all then there is no point in keeping any following 2500 // clauses or marking the landingpad as having a cleanup. 2501 if (isCatchAll(Personality, TypeInfo)) { 2502 if (!isLastClause) 2503 MakeNewInstruction = true; 2504 CleanupFlag = false; 2505 break; 2506 } 2507 } else { 2508 // A filter clause. If any of the filter elements were already caught 2509 // then they can be dropped from the filter. It is tempting to try to 2510 // exploit the filter further by saying that any typeinfo that does not 2511 // occur in the filter can't be caught later (and thus can be dropped). 2512 // However this would be wrong, since typeinfos can match without being 2513 // equal (for example if one represents a C++ class, and the other some 2514 // class derived from it). 2515 assert(LI.isFilter(i) && "Unsupported landingpad clause!"); 2516 Constant *FilterClause = LI.getClause(i); 2517 ArrayType *FilterType = cast<ArrayType>(FilterClause->getType()); 2518 unsigned NumTypeInfos = FilterType->getNumElements(); 2519 2520 // An empty filter catches everything, so there is no point in keeping any 2521 // following clauses or marking the landingpad as having a cleanup. By 2522 // dealing with this case here the following code is made a bit simpler. 2523 if (!NumTypeInfos) { 2524 NewClauses.push_back(FilterClause); 2525 if (!isLastClause) 2526 MakeNewInstruction = true; 2527 CleanupFlag = false; 2528 break; 2529 } 2530 2531 bool MakeNewFilter = false; // If true, make a new filter. 2532 SmallVector<Constant *, 16> NewFilterElts; // New elements. 2533 if (isa<ConstantAggregateZero>(FilterClause)) { 2534 // Not an empty filter - it contains at least one null typeinfo. 2535 assert(NumTypeInfos > 0 && "Should have handled empty filter already!"); 2536 Constant *TypeInfo = 2537 Constant::getNullValue(FilterType->getElementType()); 2538 // If this typeinfo is a catch-all then the filter can never match. 2539 if (isCatchAll(Personality, TypeInfo)) { 2540 // Throw the filter away. 2541 MakeNewInstruction = true; 2542 continue; 2543 } 2544 2545 // There is no point in having multiple copies of this typeinfo, so 2546 // discard all but the first copy if there is more than one. 2547 NewFilterElts.push_back(TypeInfo); 2548 if (NumTypeInfos > 1) 2549 MakeNewFilter = true; 2550 } else { 2551 ConstantArray *Filter = cast<ConstantArray>(FilterClause); 2552 SmallPtrSet<Value *, 16> SeenInFilter; // For uniquing the elements. 2553 NewFilterElts.reserve(NumTypeInfos); 2554 2555 // Remove any filter elements that were already caught or that already 2556 // occurred in the filter. While there, see if any of the elements are 2557 // catch-alls. If so, the filter can be discarded. 2558 bool SawCatchAll = false; 2559 for (unsigned j = 0; j != NumTypeInfos; ++j) { 2560 Constant *Elt = Filter->getOperand(j); 2561 Constant *TypeInfo = Elt->stripPointerCasts(); 2562 if (isCatchAll(Personality, TypeInfo)) { 2563 // This element is a catch-all. Bail out, noting this fact. 2564 SawCatchAll = true; 2565 break; 2566 } 2567 2568 // Even if we've seen a type in a catch clause, we don't want to 2569 // remove it from the filter. An unexpected type handler may be 2570 // set up for a call site which throws an exception of the same 2571 // type caught. In order for the exception thrown by the unexpected 2572 // handler to propagate correctly, the filter must be correctly 2573 // described for the call site. 2574 // 2575 // Example: 2576 // 2577 // void unexpected() { throw 1;} 2578 // void foo() throw (int) { 2579 // std::set_unexpected(unexpected); 2580 // try { 2581 // throw 2.0; 2582 // } catch (int i) {} 2583 // } 2584 2585 // There is no point in having multiple copies of the same typeinfo in 2586 // a filter, so only add it if we didn't already. 2587 if (SeenInFilter.insert(TypeInfo).second) 2588 NewFilterElts.push_back(cast<Constant>(Elt)); 2589 } 2590 // A filter containing a catch-all cannot match anything by definition. 2591 if (SawCatchAll) { 2592 // Throw the filter away. 2593 MakeNewInstruction = true; 2594 continue; 2595 } 2596 2597 // If we dropped something from the filter, make a new one. 2598 if (NewFilterElts.size() < NumTypeInfos) 2599 MakeNewFilter = true; 2600 } 2601 if (MakeNewFilter) { 2602 FilterType = ArrayType::get(FilterType->getElementType(), 2603 NewFilterElts.size()); 2604 FilterClause = ConstantArray::get(FilterType, NewFilterElts); 2605 MakeNewInstruction = true; 2606 } 2607 2608 NewClauses.push_back(FilterClause); 2609 2610 // If the new filter is empty then it will catch everything so there is 2611 // no point in keeping any following clauses or marking the landingpad 2612 // as having a cleanup. The case of the original filter being empty was 2613 // already handled above. 2614 if (MakeNewFilter && !NewFilterElts.size()) { 2615 assert(MakeNewInstruction && "New filter but not a new instruction!"); 2616 CleanupFlag = false; 2617 break; 2618 } 2619 } 2620 } 2621 2622 // If several filters occur in a row then reorder them so that the shortest 2623 // filters come first (those with the smallest number of elements). This is 2624 // advantageous because shorter filters are more likely to match, speeding up 2625 // unwinding, but mostly because it increases the effectiveness of the other 2626 // filter optimizations below. 2627 for (unsigned i = 0, e = NewClauses.size(); i + 1 < e; ) { 2628 unsigned j; 2629 // Find the maximal 'j' s.t. the range [i, j) consists entirely of filters. 2630 for (j = i; j != e; ++j) 2631 if (!isa<ArrayType>(NewClauses[j]->getType())) 2632 break; 2633 2634 // Check whether the filters are already sorted by length. We need to know 2635 // if sorting them is actually going to do anything so that we only make a 2636 // new landingpad instruction if it does. 2637 for (unsigned k = i; k + 1 < j; ++k) 2638 if (shorter_filter(NewClauses[k+1], NewClauses[k])) { 2639 // Not sorted, so sort the filters now. Doing an unstable sort would be 2640 // correct too but reordering filters pointlessly might confuse users. 2641 std::stable_sort(NewClauses.begin() + i, NewClauses.begin() + j, 2642 shorter_filter); 2643 MakeNewInstruction = true; 2644 break; 2645 } 2646 2647 // Look for the next batch of filters. 2648 i = j + 1; 2649 } 2650 2651 // If typeinfos matched if and only if equal, then the elements of a filter L 2652 // that occurs later than a filter F could be replaced by the intersection of 2653 // the elements of F and L. In reality two typeinfos can match without being 2654 // equal (for example if one represents a C++ class, and the other some class 2655 // derived from it) so it would be wrong to perform this transform in general. 2656 // However the transform is correct and useful if F is a subset of L. In that 2657 // case L can be replaced by F, and thus removed altogether since repeating a 2658 // filter is pointless. So here we look at all pairs of filters F and L where 2659 // L follows F in the list of clauses, and remove L if every element of F is 2660 // an element of L. This can occur when inlining C++ functions with exception 2661 // specifications. 2662 for (unsigned i = 0; i + 1 < NewClauses.size(); ++i) { 2663 // Examine each filter in turn. 2664 Value *Filter = NewClauses[i]; 2665 ArrayType *FTy = dyn_cast<ArrayType>(Filter->getType()); 2666 if (!FTy) 2667 // Not a filter - skip it. 2668 continue; 2669 unsigned FElts = FTy->getNumElements(); 2670 // Examine each filter following this one. Doing this backwards means that 2671 // we don't have to worry about filters disappearing under us when removed. 2672 for (unsigned j = NewClauses.size() - 1; j != i; --j) { 2673 Value *LFilter = NewClauses[j]; 2674 ArrayType *LTy = dyn_cast<ArrayType>(LFilter->getType()); 2675 if (!LTy) 2676 // Not a filter - skip it. 2677 continue; 2678 // If Filter is a subset of LFilter, i.e. every element of Filter is also 2679 // an element of LFilter, then discard LFilter. 2680 SmallVectorImpl<Constant *>::iterator J = NewClauses.begin() + j; 2681 // If Filter is empty then it is a subset of LFilter. 2682 if (!FElts) { 2683 // Discard LFilter. 2684 NewClauses.erase(J); 2685 MakeNewInstruction = true; 2686 // Move on to the next filter. 2687 continue; 2688 } 2689 unsigned LElts = LTy->getNumElements(); 2690 // If Filter is longer than LFilter then it cannot be a subset of it. 2691 if (FElts > LElts) 2692 // Move on to the next filter. 2693 continue; 2694 // At this point we know that LFilter has at least one element. 2695 if (isa<ConstantAggregateZero>(LFilter)) { // LFilter only contains zeros. 2696 // Filter is a subset of LFilter iff Filter contains only zeros (as we 2697 // already know that Filter is not longer than LFilter). 2698 if (isa<ConstantAggregateZero>(Filter)) { 2699 assert(FElts <= LElts && "Should have handled this case earlier!"); 2700 // Discard LFilter. 2701 NewClauses.erase(J); 2702 MakeNewInstruction = true; 2703 } 2704 // Move on to the next filter. 2705 continue; 2706 } 2707 ConstantArray *LArray = cast<ConstantArray>(LFilter); 2708 if (isa<ConstantAggregateZero>(Filter)) { // Filter only contains zeros. 2709 // Since Filter is non-empty and contains only zeros, it is a subset of 2710 // LFilter iff LFilter contains a zero. 2711 assert(FElts > 0 && "Should have eliminated the empty filter earlier!"); 2712 for (unsigned l = 0; l != LElts; ++l) 2713 if (LArray->getOperand(l)->isNullValue()) { 2714 // LFilter contains a zero - discard it. 2715 NewClauses.erase(J); 2716 MakeNewInstruction = true; 2717 break; 2718 } 2719 // Move on to the next filter. 2720 continue; 2721 } 2722 // At this point we know that both filters are ConstantArrays. Loop over 2723 // operands to see whether every element of Filter is also an element of 2724 // LFilter. Since filters tend to be short this is probably faster than 2725 // using a method that scales nicely. 2726 ConstantArray *FArray = cast<ConstantArray>(Filter); 2727 bool AllFound = true; 2728 for (unsigned f = 0; f != FElts; ++f) { 2729 Value *FTypeInfo = FArray->getOperand(f)->stripPointerCasts(); 2730 AllFound = false; 2731 for (unsigned l = 0; l != LElts; ++l) { 2732 Value *LTypeInfo = LArray->getOperand(l)->stripPointerCasts(); 2733 if (LTypeInfo == FTypeInfo) { 2734 AllFound = true; 2735 break; 2736 } 2737 } 2738 if (!AllFound) 2739 break; 2740 } 2741 if (AllFound) { 2742 // Discard LFilter. 2743 NewClauses.erase(J); 2744 MakeNewInstruction = true; 2745 } 2746 // Move on to the next filter. 2747 } 2748 } 2749 2750 // If we changed any of the clauses, replace the old landingpad instruction 2751 // with a new one. 2752 if (MakeNewInstruction) { 2753 LandingPadInst *NLI = LandingPadInst::Create(LI.getType(), 2754 NewClauses.size()); 2755 for (unsigned i = 0, e = NewClauses.size(); i != e; ++i) 2756 NLI->addClause(NewClauses[i]); 2757 // A landing pad with no clauses must have the cleanup flag set. It is 2758 // theoretically possible, though highly unlikely, that we eliminated all 2759 // clauses. If so, force the cleanup flag to true. 2760 if (NewClauses.empty()) 2761 CleanupFlag = true; 2762 NLI->setCleanup(CleanupFlag); 2763 return NLI; 2764 } 2765 2766 // Even if none of the clauses changed, we may nonetheless have understood 2767 // that the cleanup flag is pointless. Clear it if so. 2768 if (LI.isCleanup() != CleanupFlag) { 2769 assert(!CleanupFlag && "Adding a cleanup, not removing one?!"); 2770 LI.setCleanup(CleanupFlag); 2771 return &LI; 2772 } 2773 2774 return nullptr; 2775 } 2776 2777 /// Try to move the specified instruction from its current block into the 2778 /// beginning of DestBlock, which can only happen if it's safe to move the 2779 /// instruction past all of the instructions between it and the end of its 2780 /// block. 2781 static bool TryToSinkInstruction(Instruction *I, BasicBlock *DestBlock) { 2782 assert(I->hasOneUse() && "Invariants didn't hold!"); 2783 2784 // Cannot move control-flow-involving, volatile loads, vaarg, etc. 2785 if (isa<PHINode>(I) || I->isEHPad() || I->mayHaveSideEffects() || 2786 isa<TerminatorInst>(I)) 2787 return false; 2788 2789 // Do not sink alloca instructions out of the entry block. 2790 if (isa<AllocaInst>(I) && I->getParent() == 2791 &DestBlock->getParent()->getEntryBlock()) 2792 return false; 2793 2794 // Do not sink into catchswitch blocks. 2795 if (isa<CatchSwitchInst>(DestBlock->getTerminator())) 2796 return false; 2797 2798 // Do not sink convergent call instructions. 2799 if (auto *CI = dyn_cast<CallInst>(I)) { 2800 if (CI->isConvergent()) 2801 return false; 2802 } 2803 // We can only sink load instructions if there is nothing between the load and 2804 // the end of block that could change the value. 2805 if (I->mayReadFromMemory()) { 2806 for (BasicBlock::iterator Scan = I->getIterator(), 2807 E = I->getParent()->end(); 2808 Scan != E; ++Scan) 2809 if (Scan->mayWriteToMemory()) 2810 return false; 2811 } 2812 2813 BasicBlock::iterator InsertPos = DestBlock->getFirstInsertionPt(); 2814 I->moveBefore(&*InsertPos); 2815 ++NumSunkInst; 2816 return true; 2817 } 2818 2819 bool InstCombiner::run() { 2820 while (!Worklist.isEmpty()) { 2821 Instruction *I = Worklist.RemoveOne(); 2822 if (I == nullptr) continue; // skip null values. 2823 2824 // Check to see if we can DCE the instruction. 2825 if (isInstructionTriviallyDead(I, &TLI)) { 2826 DEBUG(dbgs() << "IC: DCE: " << *I << '\n'); 2827 eraseInstFromFunction(*I); 2828 ++NumDeadInst; 2829 MadeIRChange = true; 2830 continue; 2831 } 2832 2833 // Instruction isn't dead, see if we can constant propagate it. 2834 if (!I->use_empty() && 2835 (I->getNumOperands() == 0 || isa<Constant>(I->getOperand(0)))) { 2836 if (Constant *C = ConstantFoldInstruction(I, DL, &TLI)) { 2837 DEBUG(dbgs() << "IC: ConstFold to: " << *C << " from: " << *I << '\n'); 2838 2839 // Add operands to the worklist. 2840 replaceInstUsesWith(*I, C); 2841 ++NumConstProp; 2842 if (isInstructionTriviallyDead(I, &TLI)) 2843 eraseInstFromFunction(*I); 2844 MadeIRChange = true; 2845 continue; 2846 } 2847 } 2848 2849 // In general, it is possible for computeKnownBits to determine all bits in 2850 // a value even when the operands are not all constants. 2851 Type *Ty = I->getType(); 2852 if (ExpensiveCombines && !I->use_empty() && Ty->isIntOrIntVectorTy()) { 2853 unsigned BitWidth = Ty->getScalarSizeInBits(); 2854 APInt KnownZero(BitWidth, 0); 2855 APInt KnownOne(BitWidth, 0); 2856 computeKnownBits(I, KnownZero, KnownOne, /*Depth*/0, I); 2857 if ((KnownZero | KnownOne).isAllOnesValue()) { 2858 Constant *C = ConstantInt::get(Ty, KnownOne); 2859 DEBUG(dbgs() << "IC: ConstFold (all bits known) to: " << *C << 2860 " from: " << *I << '\n'); 2861 2862 // Add operands to the worklist. 2863 replaceInstUsesWith(*I, C); 2864 ++NumConstProp; 2865 if (isInstructionTriviallyDead(I, &TLI)) 2866 eraseInstFromFunction(*I); 2867 MadeIRChange = true; 2868 continue; 2869 } 2870 } 2871 2872 // See if we can trivially sink this instruction to a successor basic block. 2873 if (I->hasOneUse()) { 2874 BasicBlock *BB = I->getParent(); 2875 Instruction *UserInst = cast<Instruction>(*I->user_begin()); 2876 BasicBlock *UserParent; 2877 2878 // Get the block the use occurs in. 2879 if (PHINode *PN = dyn_cast<PHINode>(UserInst)) 2880 UserParent = PN->getIncomingBlock(*I->use_begin()); 2881 else 2882 UserParent = UserInst->getParent(); 2883 2884 if (UserParent != BB) { 2885 bool UserIsSuccessor = false; 2886 // See if the user is one of our successors. 2887 for (succ_iterator SI = succ_begin(BB), E = succ_end(BB); SI != E; ++SI) 2888 if (*SI == UserParent) { 2889 UserIsSuccessor = true; 2890 break; 2891 } 2892 2893 // If the user is one of our immediate successors, and if that successor 2894 // only has us as a predecessors (we'd have to split the critical edge 2895 // otherwise), we can keep going. 2896 if (UserIsSuccessor && UserParent->getUniquePredecessor()) { 2897 // Okay, the CFG is simple enough, try to sink this instruction. 2898 if (TryToSinkInstruction(I, UserParent)) { 2899 DEBUG(dbgs() << "IC: Sink: " << *I << '\n'); 2900 MadeIRChange = true; 2901 // We'll add uses of the sunk instruction below, but since sinking 2902 // can expose opportunities for it's *operands* add them to the 2903 // worklist 2904 for (Use &U : I->operands()) 2905 if (Instruction *OpI = dyn_cast<Instruction>(U.get())) 2906 Worklist.Add(OpI); 2907 } 2908 } 2909 } 2910 } 2911 2912 // Now that we have an instruction, try combining it to simplify it. 2913 Builder->SetInsertPoint(I); 2914 Builder->SetCurrentDebugLocation(I->getDebugLoc()); 2915 2916 #ifndef NDEBUG 2917 std::string OrigI; 2918 #endif 2919 DEBUG(raw_string_ostream SS(OrigI); I->print(SS); OrigI = SS.str();); 2920 DEBUG(dbgs() << "IC: Visiting: " << OrigI << '\n'); 2921 2922 if (Instruction *Result = visit(*I)) { 2923 ++NumCombined; 2924 // Should we replace the old instruction with a new one? 2925 if (Result != I) { 2926 DEBUG(dbgs() << "IC: Old = " << *I << '\n' 2927 << " New = " << *Result << '\n'); 2928 2929 if (I->getDebugLoc()) 2930 Result->setDebugLoc(I->getDebugLoc()); 2931 // Everything uses the new instruction now. 2932 I->replaceAllUsesWith(Result); 2933 2934 // Move the name to the new instruction first. 2935 Result->takeName(I); 2936 2937 // Push the new instruction and any users onto the worklist. 2938 Worklist.AddUsersToWorkList(*Result); 2939 Worklist.Add(Result); 2940 2941 // Insert the new instruction into the basic block... 2942 BasicBlock *InstParent = I->getParent(); 2943 BasicBlock::iterator InsertPos = I->getIterator(); 2944 2945 // If we replace a PHI with something that isn't a PHI, fix up the 2946 // insertion point. 2947 if (!isa<PHINode>(Result) && isa<PHINode>(InsertPos)) 2948 InsertPos = InstParent->getFirstInsertionPt(); 2949 2950 InstParent->getInstList().insert(InsertPos, Result); 2951 2952 eraseInstFromFunction(*I); 2953 } else { 2954 DEBUG(dbgs() << "IC: Mod = " << OrigI << '\n' 2955 << " New = " << *I << '\n'); 2956 2957 // If the instruction was modified, it's possible that it is now dead. 2958 // if so, remove it. 2959 if (isInstructionTriviallyDead(I, &TLI)) { 2960 eraseInstFromFunction(*I); 2961 } else { 2962 Worklist.AddUsersToWorkList(*I); 2963 Worklist.Add(I); 2964 } 2965 } 2966 MadeIRChange = true; 2967 } 2968 } 2969 2970 Worklist.Zap(); 2971 return MadeIRChange; 2972 } 2973 2974 /// Walk the function in depth-first order, adding all reachable code to the 2975 /// worklist. 2976 /// 2977 /// This has a couple of tricks to make the code faster and more powerful. In 2978 /// particular, we constant fold and DCE instructions as we go, to avoid adding 2979 /// them to the worklist (this significantly speeds up instcombine on code where 2980 /// many instructions are dead or constant). Additionally, if we find a branch 2981 /// whose condition is a known constant, we only visit the reachable successors. 2982 /// 2983 static bool AddReachableCodeToWorklist(BasicBlock *BB, const DataLayout &DL, 2984 SmallPtrSetImpl<BasicBlock *> &Visited, 2985 InstCombineWorklist &ICWorklist, 2986 const TargetLibraryInfo *TLI) { 2987 bool MadeIRChange = false; 2988 SmallVector<BasicBlock*, 256> Worklist; 2989 Worklist.push_back(BB); 2990 2991 SmallVector<Instruction*, 128> InstrsForInstCombineWorklist; 2992 DenseMap<Constant *, Constant *> FoldedConstants; 2993 2994 do { 2995 BB = Worklist.pop_back_val(); 2996 2997 // We have now visited this block! If we've already been here, ignore it. 2998 if (!Visited.insert(BB).second) 2999 continue; 3000 3001 for (BasicBlock::iterator BBI = BB->begin(), E = BB->end(); BBI != E; ) { 3002 Instruction *Inst = &*BBI++; 3003 3004 // DCE instruction if trivially dead. 3005 if (isInstructionTriviallyDead(Inst, TLI)) { 3006 ++NumDeadInst; 3007 DEBUG(dbgs() << "IC: DCE: " << *Inst << '\n'); 3008 Inst->eraseFromParent(); 3009 continue; 3010 } 3011 3012 // ConstantProp instruction if trivially constant. 3013 if (!Inst->use_empty() && 3014 (Inst->getNumOperands() == 0 || isa<Constant>(Inst->getOperand(0)))) 3015 if (Constant *C = ConstantFoldInstruction(Inst, DL, TLI)) { 3016 DEBUG(dbgs() << "IC: ConstFold to: " << *C << " from: " 3017 << *Inst << '\n'); 3018 Inst->replaceAllUsesWith(C); 3019 ++NumConstProp; 3020 if (isInstructionTriviallyDead(Inst, TLI)) 3021 Inst->eraseFromParent(); 3022 continue; 3023 } 3024 3025 // See if we can constant fold its operands. 3026 for (Use &U : Inst->operands()) { 3027 if (!isa<ConstantVector>(U) && !isa<ConstantExpr>(U)) 3028 continue; 3029 3030 auto *C = cast<Constant>(U); 3031 Constant *&FoldRes = FoldedConstants[C]; 3032 if (!FoldRes) 3033 FoldRes = ConstantFoldConstant(C, DL, TLI); 3034 if (!FoldRes) 3035 FoldRes = C; 3036 3037 if (FoldRes != C) { 3038 DEBUG(dbgs() << "IC: ConstFold operand of: " << *Inst 3039 << "\n Old = " << *C 3040 << "\n New = " << *FoldRes << '\n'); 3041 U = FoldRes; 3042 MadeIRChange = true; 3043 } 3044 } 3045 3046 InstrsForInstCombineWorklist.push_back(Inst); 3047 } 3048 3049 // Recursively visit successors. If this is a branch or switch on a 3050 // constant, only visit the reachable successor. 3051 TerminatorInst *TI = BB->getTerminator(); 3052 if (BranchInst *BI = dyn_cast<BranchInst>(TI)) { 3053 if (BI->isConditional() && isa<ConstantInt>(BI->getCondition())) { 3054 bool CondVal = cast<ConstantInt>(BI->getCondition())->getZExtValue(); 3055 BasicBlock *ReachableBB = BI->getSuccessor(!CondVal); 3056 Worklist.push_back(ReachableBB); 3057 continue; 3058 } 3059 } else if (SwitchInst *SI = dyn_cast<SwitchInst>(TI)) { 3060 if (ConstantInt *Cond = dyn_cast<ConstantInt>(SI->getCondition())) { 3061 // See if this is an explicit destination. 3062 for (SwitchInst::CaseIt i = SI->case_begin(), e = SI->case_end(); 3063 i != e; ++i) 3064 if (i.getCaseValue() == Cond) { 3065 BasicBlock *ReachableBB = i.getCaseSuccessor(); 3066 Worklist.push_back(ReachableBB); 3067 continue; 3068 } 3069 3070 // Otherwise it is the default destination. 3071 Worklist.push_back(SI->getDefaultDest()); 3072 continue; 3073 } 3074 } 3075 3076 for (BasicBlock *SuccBB : TI->successors()) 3077 Worklist.push_back(SuccBB); 3078 } while (!Worklist.empty()); 3079 3080 // Once we've found all of the instructions to add to instcombine's worklist, 3081 // add them in reverse order. This way instcombine will visit from the top 3082 // of the function down. This jives well with the way that it adds all uses 3083 // of instructions to the worklist after doing a transformation, thus avoiding 3084 // some N^2 behavior in pathological cases. 3085 ICWorklist.AddInitialGroup(InstrsForInstCombineWorklist); 3086 3087 return MadeIRChange; 3088 } 3089 3090 /// \brief Populate the IC worklist from a function, and prune any dead basic 3091 /// blocks discovered in the process. 3092 /// 3093 /// This also does basic constant propagation and other forward fixing to make 3094 /// the combiner itself run much faster. 3095 static bool prepareICWorklistFromFunction(Function &F, const DataLayout &DL, 3096 TargetLibraryInfo *TLI, 3097 InstCombineWorklist &ICWorklist) { 3098 bool MadeIRChange = false; 3099 3100 // Do a depth-first traversal of the function, populate the worklist with 3101 // the reachable instructions. Ignore blocks that are not reachable. Keep 3102 // track of which blocks we visit. 3103 SmallPtrSet<BasicBlock *, 32> Visited; 3104 MadeIRChange |= 3105 AddReachableCodeToWorklist(&F.front(), DL, Visited, ICWorklist, TLI); 3106 3107 // Do a quick scan over the function. If we find any blocks that are 3108 // unreachable, remove any instructions inside of them. This prevents 3109 // the instcombine code from having to deal with some bad special cases. 3110 for (BasicBlock &BB : F) { 3111 if (Visited.count(&BB)) 3112 continue; 3113 3114 unsigned NumDeadInstInBB = removeAllNonTerminatorAndEHPadInstructions(&BB); 3115 MadeIRChange |= NumDeadInstInBB > 0; 3116 NumDeadInst += NumDeadInstInBB; 3117 } 3118 3119 return MadeIRChange; 3120 } 3121 3122 static bool 3123 combineInstructionsOverFunction(Function &F, InstCombineWorklist &Worklist, 3124 AliasAnalysis *AA, AssumptionCache &AC, 3125 TargetLibraryInfo &TLI, DominatorTree &DT, 3126 bool ExpensiveCombines = true, 3127 LoopInfo *LI = nullptr) { 3128 auto &DL = F.getParent()->getDataLayout(); 3129 ExpensiveCombines |= EnableExpensiveCombines; 3130 3131 /// Builder - This is an IRBuilder that automatically inserts new 3132 /// instructions into the worklist when they are created. 3133 IRBuilder<TargetFolder, IRBuilderCallbackInserter> Builder( 3134 F.getContext(), TargetFolder(DL), 3135 IRBuilderCallbackInserter([&Worklist, &AC](Instruction *I) { 3136 Worklist.Add(I); 3137 3138 using namespace llvm::PatternMatch; 3139 if (match(I, m_Intrinsic<Intrinsic::assume>())) 3140 AC.registerAssumption(cast<CallInst>(I)); 3141 })); 3142 3143 // Lower dbg.declare intrinsics otherwise their value may be clobbered 3144 // by instcombiner. 3145 bool DbgDeclaresChanged = LowerDbgDeclare(F); 3146 3147 // Iterate while there is work to do. 3148 int Iteration = 0; 3149 for (;;) { 3150 ++Iteration; 3151 DEBUG(dbgs() << "\n\nINSTCOMBINE ITERATION #" << Iteration << " on " 3152 << F.getName() << "\n"); 3153 3154 bool Changed = prepareICWorklistFromFunction(F, DL, &TLI, Worklist); 3155 3156 InstCombiner IC(Worklist, &Builder, F.optForMinSize(), ExpensiveCombines, 3157 AA, AC, TLI, DT, DL, LI); 3158 IC.MaxArraySizeForCombine = MaxArraySize; 3159 Changed |= IC.run(); 3160 3161 if (!Changed) 3162 break; 3163 } 3164 3165 return DbgDeclaresChanged || Iteration > 1; 3166 } 3167 3168 PreservedAnalyses InstCombinePass::run(Function &F, 3169 FunctionAnalysisManager &AM) { 3170 auto &AC = AM.getResult<AssumptionAnalysis>(F); 3171 auto &DT = AM.getResult<DominatorTreeAnalysis>(F); 3172 auto &TLI = AM.getResult<TargetLibraryAnalysis>(F); 3173 3174 auto *LI = AM.getCachedResult<LoopAnalysis>(F); 3175 3176 // FIXME: The AliasAnalysis is not yet supported in the new pass manager 3177 if (!combineInstructionsOverFunction(F, Worklist, nullptr, AC, TLI, DT, 3178 ExpensiveCombines, LI)) 3179 // No changes, all analyses are preserved. 3180 return PreservedAnalyses::all(); 3181 3182 // Mark all the analyses that instcombine updates as preserved. 3183 PreservedAnalyses PA; 3184 PA.preserveSet<CFGAnalyses>(); 3185 PA.preserve<AAManager>(); 3186 PA.preserve<GlobalsAA>(); 3187 return PA; 3188 } 3189 3190 void InstructionCombiningPass::getAnalysisUsage(AnalysisUsage &AU) const { 3191 AU.setPreservesCFG(); 3192 AU.addRequired<AAResultsWrapperPass>(); 3193 AU.addRequired<AssumptionCacheTracker>(); 3194 AU.addRequired<TargetLibraryInfoWrapperPass>(); 3195 AU.addRequired<DominatorTreeWrapperPass>(); 3196 AU.addPreserved<DominatorTreeWrapperPass>(); 3197 AU.addPreserved<AAResultsWrapperPass>(); 3198 AU.addPreserved<BasicAAWrapperPass>(); 3199 AU.addPreserved<GlobalsAAWrapperPass>(); 3200 } 3201 3202 bool InstructionCombiningPass::runOnFunction(Function &F) { 3203 if (skipFunction(F)) 3204 return false; 3205 3206 // Required analyses. 3207 auto AA = &getAnalysis<AAResultsWrapperPass>().getAAResults(); 3208 auto &AC = getAnalysis<AssumptionCacheTracker>().getAssumptionCache(F); 3209 auto &TLI = getAnalysis<TargetLibraryInfoWrapperPass>().getTLI(); 3210 auto &DT = getAnalysis<DominatorTreeWrapperPass>().getDomTree(); 3211 3212 // Optional analyses. 3213 auto *LIWP = getAnalysisIfAvailable<LoopInfoWrapperPass>(); 3214 auto *LI = LIWP ? &LIWP->getLoopInfo() : nullptr; 3215 3216 return combineInstructionsOverFunction(F, Worklist, AA, AC, TLI, DT, 3217 ExpensiveCombines, LI); 3218 } 3219 3220 char InstructionCombiningPass::ID = 0; 3221 INITIALIZE_PASS_BEGIN(InstructionCombiningPass, "instcombine", 3222 "Combine redundant instructions", false, false) 3223 INITIALIZE_PASS_DEPENDENCY(AssumptionCacheTracker) 3224 INITIALIZE_PASS_DEPENDENCY(TargetLibraryInfoWrapperPass) 3225 INITIALIZE_PASS_DEPENDENCY(DominatorTreeWrapperPass) 3226 INITIALIZE_PASS_DEPENDENCY(AAResultsWrapperPass) 3227 INITIALIZE_PASS_DEPENDENCY(GlobalsAAWrapperPass) 3228 INITIALIZE_PASS_END(InstructionCombiningPass, "instcombine", 3229 "Combine redundant instructions", false, false) 3230 3231 // Initialization Routines 3232 void llvm::initializeInstCombine(PassRegistry &Registry) { 3233 initializeInstructionCombiningPassPass(Registry); 3234 } 3235 3236 void LLVMInitializeInstCombine(LLVMPassRegistryRef R) { 3237 initializeInstructionCombiningPassPass(*unwrap(R)); 3238 } 3239 3240 FunctionPass *llvm::createInstructionCombiningPass(bool ExpensiveCombines) { 3241 return new InstructionCombiningPass(ExpensiveCombines); 3242 } 3243