1 //===- GVN.cpp - Eliminate redundant values and loads ---------------------===// 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 // This pass performs global value numbering to eliminate fully redundant 11 // instructions. It also performs simple dead load elimination. 12 // 13 // Note that this pass does the value numbering itself; it does not use the 14 // ValueNumbering analysis passes. 15 // 16 //===----------------------------------------------------------------------===// 17 18 #include "llvm/Transforms/Scalar.h" 19 #include "llvm/ADT/DenseMap.h" 20 #include "llvm/ADT/DepthFirstIterator.h" 21 #include "llvm/ADT/Hashing.h" 22 #include "llvm/ADT/MapVector.h" 23 #include "llvm/ADT/SetVector.h" 24 #include "llvm/ADT/SmallPtrSet.h" 25 #include "llvm/ADT/Statistic.h" 26 #include "llvm/Analysis/AliasAnalysis.h" 27 #include "llvm/Analysis/AssumptionTracker.h" 28 #include "llvm/Analysis/CFG.h" 29 #include "llvm/Analysis/ConstantFolding.h" 30 #include "llvm/Analysis/InstructionSimplify.h" 31 #include "llvm/Analysis/Loads.h" 32 #include "llvm/Analysis/MemoryBuiltins.h" 33 #include "llvm/Analysis/MemoryDependenceAnalysis.h" 34 #include "llvm/Analysis/PHITransAddr.h" 35 #include "llvm/Analysis/ValueTracking.h" 36 #include "llvm/IR/DataLayout.h" 37 #include "llvm/IR/Dominators.h" 38 #include "llvm/IR/GlobalVariable.h" 39 #include "llvm/IR/IRBuilder.h" 40 #include "llvm/IR/IntrinsicInst.h" 41 #include "llvm/IR/LLVMContext.h" 42 #include "llvm/IR/Metadata.h" 43 #include "llvm/IR/PatternMatch.h" 44 #include "llvm/Support/Allocator.h" 45 #include "llvm/Support/CommandLine.h" 46 #include "llvm/Support/Debug.h" 47 #include "llvm/Target/TargetLibraryInfo.h" 48 #include "llvm/Transforms/Utils/BasicBlockUtils.h" 49 #include "llvm/Transforms/Utils/Local.h" 50 #include "llvm/Transforms/Utils/SSAUpdater.h" 51 #include <vector> 52 using namespace llvm; 53 using namespace PatternMatch; 54 55 #define DEBUG_TYPE "gvn" 56 57 STATISTIC(NumGVNInstr, "Number of instructions deleted"); 58 STATISTIC(NumGVNLoad, "Number of loads deleted"); 59 STATISTIC(NumGVNPRE, "Number of instructions PRE'd"); 60 STATISTIC(NumGVNBlocks, "Number of blocks merged"); 61 STATISTIC(NumGVNSimpl, "Number of instructions simplified"); 62 STATISTIC(NumGVNEqProp, "Number of equalities propagated"); 63 STATISTIC(NumPRELoad, "Number of loads PRE'd"); 64 65 static cl::opt<bool> EnablePRE("enable-pre", 66 cl::init(true), cl::Hidden); 67 static cl::opt<bool> EnableLoadPRE("enable-load-pre", cl::init(true)); 68 69 // Maximum allowed recursion depth. 70 static cl::opt<uint32_t> 71 MaxRecurseDepth("max-recurse-depth", cl::Hidden, cl::init(1000), cl::ZeroOrMore, 72 cl::desc("Max recurse depth (default = 1000)")); 73 74 //===----------------------------------------------------------------------===// 75 // ValueTable Class 76 //===----------------------------------------------------------------------===// 77 78 /// This class holds the mapping between values and value numbers. It is used 79 /// as an efficient mechanism to determine the expression-wise equivalence of 80 /// two values. 81 namespace { 82 struct Expression { 83 uint32_t opcode; 84 Type *type; 85 SmallVector<uint32_t, 4> varargs; 86 87 Expression(uint32_t o = ~2U) : opcode(o) { } 88 89 bool operator==(const Expression &other) const { 90 if (opcode != other.opcode) 91 return false; 92 if (opcode == ~0U || opcode == ~1U) 93 return true; 94 if (type != other.type) 95 return false; 96 if (varargs != other.varargs) 97 return false; 98 return true; 99 } 100 101 friend hash_code hash_value(const Expression &Value) { 102 return hash_combine(Value.opcode, Value.type, 103 hash_combine_range(Value.varargs.begin(), 104 Value.varargs.end())); 105 } 106 }; 107 108 class ValueTable { 109 DenseMap<Value*, uint32_t> valueNumbering; 110 DenseMap<Expression, uint32_t> expressionNumbering; 111 AliasAnalysis *AA; 112 MemoryDependenceAnalysis *MD; 113 DominatorTree *DT; 114 115 uint32_t nextValueNumber; 116 117 Expression create_expression(Instruction* I); 118 Expression create_cmp_expression(unsigned Opcode, 119 CmpInst::Predicate Predicate, 120 Value *LHS, Value *RHS); 121 Expression create_extractvalue_expression(ExtractValueInst* EI); 122 uint32_t lookup_or_add_call(CallInst* C); 123 public: 124 ValueTable() : nextValueNumber(1) { } 125 uint32_t lookup_or_add(Value *V); 126 uint32_t lookup(Value *V) const; 127 uint32_t lookup_or_add_cmp(unsigned Opcode, CmpInst::Predicate Pred, 128 Value *LHS, Value *RHS); 129 void add(Value *V, uint32_t num); 130 void clear(); 131 void erase(Value *v); 132 void setAliasAnalysis(AliasAnalysis* A) { AA = A; } 133 AliasAnalysis *getAliasAnalysis() const { return AA; } 134 void setMemDep(MemoryDependenceAnalysis* M) { MD = M; } 135 void setDomTree(DominatorTree* D) { DT = D; } 136 uint32_t getNextUnusedValueNumber() { return nextValueNumber; } 137 void verifyRemoved(const Value *) const; 138 }; 139 } 140 141 namespace llvm { 142 template <> struct DenseMapInfo<Expression> { 143 static inline Expression getEmptyKey() { 144 return ~0U; 145 } 146 147 static inline Expression getTombstoneKey() { 148 return ~1U; 149 } 150 151 static unsigned getHashValue(const Expression e) { 152 using llvm::hash_value; 153 return static_cast<unsigned>(hash_value(e)); 154 } 155 static bool isEqual(const Expression &LHS, const Expression &RHS) { 156 return LHS == RHS; 157 } 158 }; 159 160 } 161 162 //===----------------------------------------------------------------------===// 163 // ValueTable Internal Functions 164 //===----------------------------------------------------------------------===// 165 166 Expression ValueTable::create_expression(Instruction *I) { 167 Expression e; 168 e.type = I->getType(); 169 e.opcode = I->getOpcode(); 170 for (Instruction::op_iterator OI = I->op_begin(), OE = I->op_end(); 171 OI != OE; ++OI) 172 e.varargs.push_back(lookup_or_add(*OI)); 173 if (I->isCommutative()) { 174 // Ensure that commutative instructions that only differ by a permutation 175 // of their operands get the same value number by sorting the operand value 176 // numbers. Since all commutative instructions have two operands it is more 177 // efficient to sort by hand rather than using, say, std::sort. 178 assert(I->getNumOperands() == 2 && "Unsupported commutative instruction!"); 179 if (e.varargs[0] > e.varargs[1]) 180 std::swap(e.varargs[0], e.varargs[1]); 181 } 182 183 if (CmpInst *C = dyn_cast<CmpInst>(I)) { 184 // Sort the operand value numbers so x<y and y>x get the same value number. 185 CmpInst::Predicate Predicate = C->getPredicate(); 186 if (e.varargs[0] > e.varargs[1]) { 187 std::swap(e.varargs[0], e.varargs[1]); 188 Predicate = CmpInst::getSwappedPredicate(Predicate); 189 } 190 e.opcode = (C->getOpcode() << 8) | Predicate; 191 } else if (InsertValueInst *E = dyn_cast<InsertValueInst>(I)) { 192 for (InsertValueInst::idx_iterator II = E->idx_begin(), IE = E->idx_end(); 193 II != IE; ++II) 194 e.varargs.push_back(*II); 195 } 196 197 return e; 198 } 199 200 Expression ValueTable::create_cmp_expression(unsigned Opcode, 201 CmpInst::Predicate Predicate, 202 Value *LHS, Value *RHS) { 203 assert((Opcode == Instruction::ICmp || Opcode == Instruction::FCmp) && 204 "Not a comparison!"); 205 Expression e; 206 e.type = CmpInst::makeCmpResultType(LHS->getType()); 207 e.varargs.push_back(lookup_or_add(LHS)); 208 e.varargs.push_back(lookup_or_add(RHS)); 209 210 // Sort the operand value numbers so x<y and y>x get the same value number. 211 if (e.varargs[0] > e.varargs[1]) { 212 std::swap(e.varargs[0], e.varargs[1]); 213 Predicate = CmpInst::getSwappedPredicate(Predicate); 214 } 215 e.opcode = (Opcode << 8) | Predicate; 216 return e; 217 } 218 219 Expression ValueTable::create_extractvalue_expression(ExtractValueInst *EI) { 220 assert(EI && "Not an ExtractValueInst?"); 221 Expression e; 222 e.type = EI->getType(); 223 e.opcode = 0; 224 225 IntrinsicInst *I = dyn_cast<IntrinsicInst>(EI->getAggregateOperand()); 226 if (I != nullptr && EI->getNumIndices() == 1 && *EI->idx_begin() == 0 ) { 227 // EI might be an extract from one of our recognised intrinsics. If it 228 // is we'll synthesize a semantically equivalent expression instead on 229 // an extract value expression. 230 switch (I->getIntrinsicID()) { 231 case Intrinsic::sadd_with_overflow: 232 case Intrinsic::uadd_with_overflow: 233 e.opcode = Instruction::Add; 234 break; 235 case Intrinsic::ssub_with_overflow: 236 case Intrinsic::usub_with_overflow: 237 e.opcode = Instruction::Sub; 238 break; 239 case Intrinsic::smul_with_overflow: 240 case Intrinsic::umul_with_overflow: 241 e.opcode = Instruction::Mul; 242 break; 243 default: 244 break; 245 } 246 247 if (e.opcode != 0) { 248 // Intrinsic recognized. Grab its args to finish building the expression. 249 assert(I->getNumArgOperands() == 2 && 250 "Expect two args for recognised intrinsics."); 251 e.varargs.push_back(lookup_or_add(I->getArgOperand(0))); 252 e.varargs.push_back(lookup_or_add(I->getArgOperand(1))); 253 return e; 254 } 255 } 256 257 // Not a recognised intrinsic. Fall back to producing an extract value 258 // expression. 259 e.opcode = EI->getOpcode(); 260 for (Instruction::op_iterator OI = EI->op_begin(), OE = EI->op_end(); 261 OI != OE; ++OI) 262 e.varargs.push_back(lookup_or_add(*OI)); 263 264 for (ExtractValueInst::idx_iterator II = EI->idx_begin(), IE = EI->idx_end(); 265 II != IE; ++II) 266 e.varargs.push_back(*II); 267 268 return e; 269 } 270 271 //===----------------------------------------------------------------------===// 272 // ValueTable External Functions 273 //===----------------------------------------------------------------------===// 274 275 /// add - Insert a value into the table with a specified value number. 276 void ValueTable::add(Value *V, uint32_t num) { 277 valueNumbering.insert(std::make_pair(V, num)); 278 } 279 280 uint32_t ValueTable::lookup_or_add_call(CallInst *C) { 281 if (AA->doesNotAccessMemory(C)) { 282 Expression exp = create_expression(C); 283 uint32_t &e = expressionNumbering[exp]; 284 if (!e) e = nextValueNumber++; 285 valueNumbering[C] = e; 286 return e; 287 } else if (AA->onlyReadsMemory(C)) { 288 Expression exp = create_expression(C); 289 uint32_t &e = expressionNumbering[exp]; 290 if (!e) { 291 e = nextValueNumber++; 292 valueNumbering[C] = e; 293 return e; 294 } 295 if (!MD) { 296 e = nextValueNumber++; 297 valueNumbering[C] = e; 298 return e; 299 } 300 301 MemDepResult local_dep = MD->getDependency(C); 302 303 if (!local_dep.isDef() && !local_dep.isNonLocal()) { 304 valueNumbering[C] = nextValueNumber; 305 return nextValueNumber++; 306 } 307 308 if (local_dep.isDef()) { 309 CallInst* local_cdep = cast<CallInst>(local_dep.getInst()); 310 311 if (local_cdep->getNumArgOperands() != C->getNumArgOperands()) { 312 valueNumbering[C] = nextValueNumber; 313 return nextValueNumber++; 314 } 315 316 for (unsigned i = 0, e = C->getNumArgOperands(); i < e; ++i) { 317 uint32_t c_vn = lookup_or_add(C->getArgOperand(i)); 318 uint32_t cd_vn = lookup_or_add(local_cdep->getArgOperand(i)); 319 if (c_vn != cd_vn) { 320 valueNumbering[C] = nextValueNumber; 321 return nextValueNumber++; 322 } 323 } 324 325 uint32_t v = lookup_or_add(local_cdep); 326 valueNumbering[C] = v; 327 return v; 328 } 329 330 // Non-local case. 331 const MemoryDependenceAnalysis::NonLocalDepInfo &deps = 332 MD->getNonLocalCallDependency(CallSite(C)); 333 // FIXME: Move the checking logic to MemDep! 334 CallInst* cdep = nullptr; 335 336 // Check to see if we have a single dominating call instruction that is 337 // identical to C. 338 for (unsigned i = 0, e = deps.size(); i != e; ++i) { 339 const NonLocalDepEntry *I = &deps[i]; 340 if (I->getResult().isNonLocal()) 341 continue; 342 343 // We don't handle non-definitions. If we already have a call, reject 344 // instruction dependencies. 345 if (!I->getResult().isDef() || cdep != nullptr) { 346 cdep = nullptr; 347 break; 348 } 349 350 CallInst *NonLocalDepCall = dyn_cast<CallInst>(I->getResult().getInst()); 351 // FIXME: All duplicated with non-local case. 352 if (NonLocalDepCall && DT->properlyDominates(I->getBB(), C->getParent())){ 353 cdep = NonLocalDepCall; 354 continue; 355 } 356 357 cdep = nullptr; 358 break; 359 } 360 361 if (!cdep) { 362 valueNumbering[C] = nextValueNumber; 363 return nextValueNumber++; 364 } 365 366 if (cdep->getNumArgOperands() != C->getNumArgOperands()) { 367 valueNumbering[C] = nextValueNumber; 368 return nextValueNumber++; 369 } 370 for (unsigned i = 0, e = C->getNumArgOperands(); i < e; ++i) { 371 uint32_t c_vn = lookup_or_add(C->getArgOperand(i)); 372 uint32_t cd_vn = lookup_or_add(cdep->getArgOperand(i)); 373 if (c_vn != cd_vn) { 374 valueNumbering[C] = nextValueNumber; 375 return nextValueNumber++; 376 } 377 } 378 379 uint32_t v = lookup_or_add(cdep); 380 valueNumbering[C] = v; 381 return v; 382 383 } else { 384 valueNumbering[C] = nextValueNumber; 385 return nextValueNumber++; 386 } 387 } 388 389 /// lookup_or_add - Returns the value number for the specified value, assigning 390 /// it a new number if it did not have one before. 391 uint32_t ValueTable::lookup_or_add(Value *V) { 392 DenseMap<Value*, uint32_t>::iterator VI = valueNumbering.find(V); 393 if (VI != valueNumbering.end()) 394 return VI->second; 395 396 if (!isa<Instruction>(V)) { 397 valueNumbering[V] = nextValueNumber; 398 return nextValueNumber++; 399 } 400 401 Instruction* I = cast<Instruction>(V); 402 Expression exp; 403 switch (I->getOpcode()) { 404 case Instruction::Call: 405 return lookup_or_add_call(cast<CallInst>(I)); 406 case Instruction::Add: 407 case Instruction::FAdd: 408 case Instruction::Sub: 409 case Instruction::FSub: 410 case Instruction::Mul: 411 case Instruction::FMul: 412 case Instruction::UDiv: 413 case Instruction::SDiv: 414 case Instruction::FDiv: 415 case Instruction::URem: 416 case Instruction::SRem: 417 case Instruction::FRem: 418 case Instruction::Shl: 419 case Instruction::LShr: 420 case Instruction::AShr: 421 case Instruction::And: 422 case Instruction::Or: 423 case Instruction::Xor: 424 case Instruction::ICmp: 425 case Instruction::FCmp: 426 case Instruction::Trunc: 427 case Instruction::ZExt: 428 case Instruction::SExt: 429 case Instruction::FPToUI: 430 case Instruction::FPToSI: 431 case Instruction::UIToFP: 432 case Instruction::SIToFP: 433 case Instruction::FPTrunc: 434 case Instruction::FPExt: 435 case Instruction::PtrToInt: 436 case Instruction::IntToPtr: 437 case Instruction::BitCast: 438 case Instruction::Select: 439 case Instruction::ExtractElement: 440 case Instruction::InsertElement: 441 case Instruction::ShuffleVector: 442 case Instruction::InsertValue: 443 case Instruction::GetElementPtr: 444 exp = create_expression(I); 445 break; 446 case Instruction::ExtractValue: 447 exp = create_extractvalue_expression(cast<ExtractValueInst>(I)); 448 break; 449 default: 450 valueNumbering[V] = nextValueNumber; 451 return nextValueNumber++; 452 } 453 454 uint32_t& e = expressionNumbering[exp]; 455 if (!e) e = nextValueNumber++; 456 valueNumbering[V] = e; 457 return e; 458 } 459 460 /// lookup - Returns the value number of the specified value. Fails if 461 /// the value has not yet been numbered. 462 uint32_t ValueTable::lookup(Value *V) const { 463 DenseMap<Value*, uint32_t>::const_iterator VI = valueNumbering.find(V); 464 assert(VI != valueNumbering.end() && "Value not numbered?"); 465 return VI->second; 466 } 467 468 /// lookup_or_add_cmp - Returns the value number of the given comparison, 469 /// assigning it a new number if it did not have one before. Useful when 470 /// we deduced the result of a comparison, but don't immediately have an 471 /// instruction realizing that comparison to hand. 472 uint32_t ValueTable::lookup_or_add_cmp(unsigned Opcode, 473 CmpInst::Predicate Predicate, 474 Value *LHS, Value *RHS) { 475 Expression exp = create_cmp_expression(Opcode, Predicate, LHS, RHS); 476 uint32_t& e = expressionNumbering[exp]; 477 if (!e) e = nextValueNumber++; 478 return e; 479 } 480 481 /// clear - Remove all entries from the ValueTable. 482 void ValueTable::clear() { 483 valueNumbering.clear(); 484 expressionNumbering.clear(); 485 nextValueNumber = 1; 486 } 487 488 /// erase - Remove a value from the value numbering. 489 void ValueTable::erase(Value *V) { 490 valueNumbering.erase(V); 491 } 492 493 /// verifyRemoved - Verify that the value is removed from all internal data 494 /// structures. 495 void ValueTable::verifyRemoved(const Value *V) const { 496 for (DenseMap<Value*, uint32_t>::const_iterator 497 I = valueNumbering.begin(), E = valueNumbering.end(); I != E; ++I) { 498 assert(I->first != V && "Inst still occurs in value numbering map!"); 499 } 500 } 501 502 //===----------------------------------------------------------------------===// 503 // GVN Pass 504 //===----------------------------------------------------------------------===// 505 506 namespace { 507 class GVN; 508 struct AvailableValueInBlock { 509 /// BB - The basic block in question. 510 BasicBlock *BB; 511 enum ValType { 512 SimpleVal, // A simple offsetted value that is accessed. 513 LoadVal, // A value produced by a load. 514 MemIntrin, // A memory intrinsic which is loaded from. 515 UndefVal // A UndefValue representing a value from dead block (which 516 // is not yet physically removed from the CFG). 517 }; 518 519 /// V - The value that is live out of the block. 520 PointerIntPair<Value *, 2, ValType> Val; 521 522 /// Offset - The byte offset in Val that is interesting for the load query. 523 unsigned Offset; 524 525 static AvailableValueInBlock get(BasicBlock *BB, Value *V, 526 unsigned Offset = 0) { 527 AvailableValueInBlock Res; 528 Res.BB = BB; 529 Res.Val.setPointer(V); 530 Res.Val.setInt(SimpleVal); 531 Res.Offset = Offset; 532 return Res; 533 } 534 535 static AvailableValueInBlock getMI(BasicBlock *BB, MemIntrinsic *MI, 536 unsigned Offset = 0) { 537 AvailableValueInBlock Res; 538 Res.BB = BB; 539 Res.Val.setPointer(MI); 540 Res.Val.setInt(MemIntrin); 541 Res.Offset = Offset; 542 return Res; 543 } 544 545 static AvailableValueInBlock getLoad(BasicBlock *BB, LoadInst *LI, 546 unsigned Offset = 0) { 547 AvailableValueInBlock Res; 548 Res.BB = BB; 549 Res.Val.setPointer(LI); 550 Res.Val.setInt(LoadVal); 551 Res.Offset = Offset; 552 return Res; 553 } 554 555 static AvailableValueInBlock getUndef(BasicBlock *BB) { 556 AvailableValueInBlock Res; 557 Res.BB = BB; 558 Res.Val.setPointer(nullptr); 559 Res.Val.setInt(UndefVal); 560 Res.Offset = 0; 561 return Res; 562 } 563 564 bool isSimpleValue() const { return Val.getInt() == SimpleVal; } 565 bool isCoercedLoadValue() const { return Val.getInt() == LoadVal; } 566 bool isMemIntrinValue() const { return Val.getInt() == MemIntrin; } 567 bool isUndefValue() const { return Val.getInt() == UndefVal; } 568 569 Value *getSimpleValue() const { 570 assert(isSimpleValue() && "Wrong accessor"); 571 return Val.getPointer(); 572 } 573 574 LoadInst *getCoercedLoadValue() const { 575 assert(isCoercedLoadValue() && "Wrong accessor"); 576 return cast<LoadInst>(Val.getPointer()); 577 } 578 579 MemIntrinsic *getMemIntrinValue() const { 580 assert(isMemIntrinValue() && "Wrong accessor"); 581 return cast<MemIntrinsic>(Val.getPointer()); 582 } 583 584 /// MaterializeAdjustedValue - Emit code into this block to adjust the value 585 /// defined here to the specified type. This handles various coercion cases. 586 Value *MaterializeAdjustedValue(Type *LoadTy, GVN &gvn) const; 587 }; 588 589 class GVN : public FunctionPass { 590 bool NoLoads; 591 MemoryDependenceAnalysis *MD; 592 DominatorTree *DT; 593 const DataLayout *DL; 594 const TargetLibraryInfo *TLI; 595 AssumptionTracker *AT; 596 SetVector<BasicBlock *> DeadBlocks; 597 598 ValueTable VN; 599 600 /// LeaderTable - A mapping from value numbers to lists of Value*'s that 601 /// have that value number. Use findLeader to query it. 602 struct LeaderTableEntry { 603 Value *Val; 604 const BasicBlock *BB; 605 LeaderTableEntry *Next; 606 }; 607 DenseMap<uint32_t, LeaderTableEntry> LeaderTable; 608 BumpPtrAllocator TableAllocator; 609 610 SmallVector<Instruction*, 8> InstrsToErase; 611 612 typedef SmallVector<NonLocalDepResult, 64> LoadDepVect; 613 typedef SmallVector<AvailableValueInBlock, 64> AvailValInBlkVect; 614 typedef SmallVector<BasicBlock*, 64> UnavailBlkVect; 615 616 public: 617 static char ID; // Pass identification, replacement for typeid 618 explicit GVN(bool noloads = false) 619 : FunctionPass(ID), NoLoads(noloads), MD(nullptr) { 620 initializeGVNPass(*PassRegistry::getPassRegistry()); 621 } 622 623 bool runOnFunction(Function &F) override; 624 625 /// markInstructionForDeletion - This removes the specified instruction from 626 /// our various maps and marks it for deletion. 627 void markInstructionForDeletion(Instruction *I) { 628 VN.erase(I); 629 InstrsToErase.push_back(I); 630 } 631 632 const DataLayout *getDataLayout() const { return DL; } 633 DominatorTree &getDominatorTree() const { return *DT; } 634 AliasAnalysis *getAliasAnalysis() const { return VN.getAliasAnalysis(); } 635 MemoryDependenceAnalysis &getMemDep() const { return *MD; } 636 private: 637 /// addToLeaderTable - Push a new Value to the LeaderTable onto the list for 638 /// its value number. 639 void addToLeaderTable(uint32_t N, Value *V, const BasicBlock *BB) { 640 LeaderTableEntry &Curr = LeaderTable[N]; 641 if (!Curr.Val) { 642 Curr.Val = V; 643 Curr.BB = BB; 644 return; 645 } 646 647 LeaderTableEntry *Node = TableAllocator.Allocate<LeaderTableEntry>(); 648 Node->Val = V; 649 Node->BB = BB; 650 Node->Next = Curr.Next; 651 Curr.Next = Node; 652 } 653 654 /// removeFromLeaderTable - Scan the list of values corresponding to a given 655 /// value number, and remove the given instruction if encountered. 656 void removeFromLeaderTable(uint32_t N, Instruction *I, BasicBlock *BB) { 657 LeaderTableEntry* Prev = nullptr; 658 LeaderTableEntry* Curr = &LeaderTable[N]; 659 660 while (Curr->Val != I || Curr->BB != BB) { 661 Prev = Curr; 662 Curr = Curr->Next; 663 } 664 665 if (Prev) { 666 Prev->Next = Curr->Next; 667 } else { 668 if (!Curr->Next) { 669 Curr->Val = nullptr; 670 Curr->BB = nullptr; 671 } else { 672 LeaderTableEntry* Next = Curr->Next; 673 Curr->Val = Next->Val; 674 Curr->BB = Next->BB; 675 Curr->Next = Next->Next; 676 } 677 } 678 } 679 680 // List of critical edges to be split between iterations. 681 SmallVector<std::pair<TerminatorInst*, unsigned>, 4> toSplit; 682 683 // This transformation requires dominator postdominator info 684 void getAnalysisUsage(AnalysisUsage &AU) const override { 685 AU.addRequired<AssumptionTracker>(); 686 AU.addRequired<DominatorTreeWrapperPass>(); 687 AU.addRequired<TargetLibraryInfo>(); 688 if (!NoLoads) 689 AU.addRequired<MemoryDependenceAnalysis>(); 690 AU.addRequired<AliasAnalysis>(); 691 692 AU.addPreserved<DominatorTreeWrapperPass>(); 693 AU.addPreserved<AliasAnalysis>(); 694 } 695 696 697 // Helper fuctions of redundant load elimination 698 bool processLoad(LoadInst *L); 699 bool processNonLocalLoad(LoadInst *L); 700 void AnalyzeLoadAvailability(LoadInst *LI, LoadDepVect &Deps, 701 AvailValInBlkVect &ValuesPerBlock, 702 UnavailBlkVect &UnavailableBlocks); 703 bool PerformLoadPRE(LoadInst *LI, AvailValInBlkVect &ValuesPerBlock, 704 UnavailBlkVect &UnavailableBlocks); 705 706 // Other helper routines 707 bool processInstruction(Instruction *I); 708 bool processBlock(BasicBlock *BB); 709 void dump(DenseMap<uint32_t, Value*> &d); 710 bool iterateOnFunction(Function &F); 711 bool performPRE(Function &F); 712 Value *findLeader(const BasicBlock *BB, uint32_t num); 713 void cleanupGlobalSets(); 714 void verifyRemoved(const Instruction *I) const; 715 bool splitCriticalEdges(); 716 BasicBlock *splitCriticalEdges(BasicBlock *Pred, BasicBlock *Succ); 717 unsigned replaceAllDominatedUsesWith(Value *From, Value *To, 718 const BasicBlockEdge &Root); 719 bool propagateEquality(Value *LHS, Value *RHS, const BasicBlockEdge &Root); 720 bool processFoldableCondBr(BranchInst *BI); 721 void addDeadBlock(BasicBlock *BB); 722 void assignValNumForDeadCode(); 723 }; 724 725 char GVN::ID = 0; 726 } 727 728 // createGVNPass - The public interface to this file... 729 FunctionPass *llvm::createGVNPass(bool NoLoads) { 730 return new GVN(NoLoads); 731 } 732 733 INITIALIZE_PASS_BEGIN(GVN, "gvn", "Global Value Numbering", false, false) 734 INITIALIZE_PASS_DEPENDENCY(AssumptionTracker) 735 INITIALIZE_PASS_DEPENDENCY(MemoryDependenceAnalysis) 736 INITIALIZE_PASS_DEPENDENCY(DominatorTreeWrapperPass) 737 INITIALIZE_PASS_DEPENDENCY(TargetLibraryInfo) 738 INITIALIZE_AG_DEPENDENCY(AliasAnalysis) 739 INITIALIZE_PASS_END(GVN, "gvn", "Global Value Numbering", false, false) 740 741 #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) 742 void GVN::dump(DenseMap<uint32_t, Value*>& d) { 743 errs() << "{\n"; 744 for (DenseMap<uint32_t, Value*>::iterator I = d.begin(), 745 E = d.end(); I != E; ++I) { 746 errs() << I->first << "\n"; 747 I->second->dump(); 748 } 749 errs() << "}\n"; 750 } 751 #endif 752 753 /// IsValueFullyAvailableInBlock - Return true if we can prove that the value 754 /// we're analyzing is fully available in the specified block. As we go, keep 755 /// track of which blocks we know are fully alive in FullyAvailableBlocks. This 756 /// map is actually a tri-state map with the following values: 757 /// 0) we know the block *is not* fully available. 758 /// 1) we know the block *is* fully available. 759 /// 2) we do not know whether the block is fully available or not, but we are 760 /// currently speculating that it will be. 761 /// 3) we are speculating for this block and have used that to speculate for 762 /// other blocks. 763 static bool IsValueFullyAvailableInBlock(BasicBlock *BB, 764 DenseMap<BasicBlock*, char> &FullyAvailableBlocks, 765 uint32_t RecurseDepth) { 766 if (RecurseDepth > MaxRecurseDepth) 767 return false; 768 769 // Optimistically assume that the block is fully available and check to see 770 // if we already know about this block in one lookup. 771 std::pair<DenseMap<BasicBlock*, char>::iterator, char> IV = 772 FullyAvailableBlocks.insert(std::make_pair(BB, 2)); 773 774 // If the entry already existed for this block, return the precomputed value. 775 if (!IV.second) { 776 // If this is a speculative "available" value, mark it as being used for 777 // speculation of other blocks. 778 if (IV.first->second == 2) 779 IV.first->second = 3; 780 return IV.first->second != 0; 781 } 782 783 // Otherwise, see if it is fully available in all predecessors. 784 pred_iterator PI = pred_begin(BB), PE = pred_end(BB); 785 786 // If this block has no predecessors, it isn't live-in here. 787 if (PI == PE) 788 goto SpeculationFailure; 789 790 for (; PI != PE; ++PI) 791 // If the value isn't fully available in one of our predecessors, then it 792 // isn't fully available in this block either. Undo our previous 793 // optimistic assumption and bail out. 794 if (!IsValueFullyAvailableInBlock(*PI, FullyAvailableBlocks,RecurseDepth+1)) 795 goto SpeculationFailure; 796 797 return true; 798 799 // SpeculationFailure - If we get here, we found out that this is not, after 800 // all, a fully-available block. We have a problem if we speculated on this and 801 // used the speculation to mark other blocks as available. 802 SpeculationFailure: 803 char &BBVal = FullyAvailableBlocks[BB]; 804 805 // If we didn't speculate on this, just return with it set to false. 806 if (BBVal == 2) { 807 BBVal = 0; 808 return false; 809 } 810 811 // If we did speculate on this value, we could have blocks set to 1 that are 812 // incorrect. Walk the (transitive) successors of this block and mark them as 813 // 0 if set to one. 814 SmallVector<BasicBlock*, 32> BBWorklist; 815 BBWorklist.push_back(BB); 816 817 do { 818 BasicBlock *Entry = BBWorklist.pop_back_val(); 819 // Note that this sets blocks to 0 (unavailable) if they happen to not 820 // already be in FullyAvailableBlocks. This is safe. 821 char &EntryVal = FullyAvailableBlocks[Entry]; 822 if (EntryVal == 0) continue; // Already unavailable. 823 824 // Mark as unavailable. 825 EntryVal = 0; 826 827 BBWorklist.append(succ_begin(Entry), succ_end(Entry)); 828 } while (!BBWorklist.empty()); 829 830 return false; 831 } 832 833 834 /// CanCoerceMustAliasedValueToLoad - Return true if 835 /// CoerceAvailableValueToLoadType will succeed. 836 static bool CanCoerceMustAliasedValueToLoad(Value *StoredVal, 837 Type *LoadTy, 838 const DataLayout &DL) { 839 // If the loaded or stored value is an first class array or struct, don't try 840 // to transform them. We need to be able to bitcast to integer. 841 if (LoadTy->isStructTy() || LoadTy->isArrayTy() || 842 StoredVal->getType()->isStructTy() || 843 StoredVal->getType()->isArrayTy()) 844 return false; 845 846 // The store has to be at least as big as the load. 847 if (DL.getTypeSizeInBits(StoredVal->getType()) < 848 DL.getTypeSizeInBits(LoadTy)) 849 return false; 850 851 return true; 852 } 853 854 /// CoerceAvailableValueToLoadType - If we saw a store of a value to memory, and 855 /// then a load from a must-aliased pointer of a different type, try to coerce 856 /// the stored value. LoadedTy is the type of the load we want to replace and 857 /// InsertPt is the place to insert new instructions. 858 /// 859 /// If we can't do it, return null. 860 static Value *CoerceAvailableValueToLoadType(Value *StoredVal, 861 Type *LoadedTy, 862 Instruction *InsertPt, 863 const DataLayout &DL) { 864 if (!CanCoerceMustAliasedValueToLoad(StoredVal, LoadedTy, DL)) 865 return nullptr; 866 867 // If this is already the right type, just return it. 868 Type *StoredValTy = StoredVal->getType(); 869 870 uint64_t StoreSize = DL.getTypeSizeInBits(StoredValTy); 871 uint64_t LoadSize = DL.getTypeSizeInBits(LoadedTy); 872 873 // If the store and reload are the same size, we can always reuse it. 874 if (StoreSize == LoadSize) { 875 // Pointer to Pointer -> use bitcast. 876 if (StoredValTy->getScalarType()->isPointerTy() && 877 LoadedTy->getScalarType()->isPointerTy()) 878 return new BitCastInst(StoredVal, LoadedTy, "", InsertPt); 879 880 // Convert source pointers to integers, which can be bitcast. 881 if (StoredValTy->getScalarType()->isPointerTy()) { 882 StoredValTy = DL.getIntPtrType(StoredValTy); 883 StoredVal = new PtrToIntInst(StoredVal, StoredValTy, "", InsertPt); 884 } 885 886 Type *TypeToCastTo = LoadedTy; 887 if (TypeToCastTo->getScalarType()->isPointerTy()) 888 TypeToCastTo = DL.getIntPtrType(TypeToCastTo); 889 890 if (StoredValTy != TypeToCastTo) 891 StoredVal = new BitCastInst(StoredVal, TypeToCastTo, "", InsertPt); 892 893 // Cast to pointer if the load needs a pointer type. 894 if (LoadedTy->getScalarType()->isPointerTy()) 895 StoredVal = new IntToPtrInst(StoredVal, LoadedTy, "", InsertPt); 896 897 return StoredVal; 898 } 899 900 // If the loaded value is smaller than the available value, then we can 901 // extract out a piece from it. If the available value is too small, then we 902 // can't do anything. 903 assert(StoreSize >= LoadSize && "CanCoerceMustAliasedValueToLoad fail"); 904 905 // Convert source pointers to integers, which can be manipulated. 906 if (StoredValTy->getScalarType()->isPointerTy()) { 907 StoredValTy = DL.getIntPtrType(StoredValTy); 908 StoredVal = new PtrToIntInst(StoredVal, StoredValTy, "", InsertPt); 909 } 910 911 // Convert vectors and fp to integer, which can be manipulated. 912 if (!StoredValTy->isIntegerTy()) { 913 StoredValTy = IntegerType::get(StoredValTy->getContext(), StoreSize); 914 StoredVal = new BitCastInst(StoredVal, StoredValTy, "", InsertPt); 915 } 916 917 // If this is a big-endian system, we need to shift the value down to the low 918 // bits so that a truncate will work. 919 if (DL.isBigEndian()) { 920 Constant *Val = ConstantInt::get(StoredVal->getType(), StoreSize-LoadSize); 921 StoredVal = BinaryOperator::CreateLShr(StoredVal, Val, "tmp", InsertPt); 922 } 923 924 // Truncate the integer to the right size now. 925 Type *NewIntTy = IntegerType::get(StoredValTy->getContext(), LoadSize); 926 StoredVal = new TruncInst(StoredVal, NewIntTy, "trunc", InsertPt); 927 928 if (LoadedTy == NewIntTy) 929 return StoredVal; 930 931 // If the result is a pointer, inttoptr. 932 if (LoadedTy->getScalarType()->isPointerTy()) 933 return new IntToPtrInst(StoredVal, LoadedTy, "inttoptr", InsertPt); 934 935 // Otherwise, bitcast. 936 return new BitCastInst(StoredVal, LoadedTy, "bitcast", InsertPt); 937 } 938 939 /// AnalyzeLoadFromClobberingWrite - This function is called when we have a 940 /// memdep query of a load that ends up being a clobbering memory write (store, 941 /// memset, memcpy, memmove). This means that the write *may* provide bits used 942 /// by the load but we can't be sure because the pointers don't mustalias. 943 /// 944 /// Check this case to see if there is anything more we can do before we give 945 /// up. This returns -1 if we have to give up, or a byte number in the stored 946 /// value of the piece that feeds the load. 947 static int AnalyzeLoadFromClobberingWrite(Type *LoadTy, Value *LoadPtr, 948 Value *WritePtr, 949 uint64_t WriteSizeInBits, 950 const DataLayout &DL) { 951 // If the loaded or stored value is a first class array or struct, don't try 952 // to transform them. We need to be able to bitcast to integer. 953 if (LoadTy->isStructTy() || LoadTy->isArrayTy()) 954 return -1; 955 956 int64_t StoreOffset = 0, LoadOffset = 0; 957 Value *StoreBase = GetPointerBaseWithConstantOffset(WritePtr,StoreOffset,&DL); 958 Value *LoadBase = GetPointerBaseWithConstantOffset(LoadPtr, LoadOffset, &DL); 959 if (StoreBase != LoadBase) 960 return -1; 961 962 // If the load and store are to the exact same address, they should have been 963 // a must alias. AA must have gotten confused. 964 // FIXME: Study to see if/when this happens. One case is forwarding a memset 965 // to a load from the base of the memset. 966 #if 0 967 if (LoadOffset == StoreOffset) { 968 dbgs() << "STORE/LOAD DEP WITH COMMON POINTER MISSED:\n" 969 << "Base = " << *StoreBase << "\n" 970 << "Store Ptr = " << *WritePtr << "\n" 971 << "Store Offs = " << StoreOffset << "\n" 972 << "Load Ptr = " << *LoadPtr << "\n"; 973 abort(); 974 } 975 #endif 976 977 // If the load and store don't overlap at all, the store doesn't provide 978 // anything to the load. In this case, they really don't alias at all, AA 979 // must have gotten confused. 980 uint64_t LoadSize = DL.getTypeSizeInBits(LoadTy); 981 982 if ((WriteSizeInBits & 7) | (LoadSize & 7)) 983 return -1; 984 uint64_t StoreSize = WriteSizeInBits >> 3; // Convert to bytes. 985 LoadSize >>= 3; 986 987 988 bool isAAFailure = false; 989 if (StoreOffset < LoadOffset) 990 isAAFailure = StoreOffset+int64_t(StoreSize) <= LoadOffset; 991 else 992 isAAFailure = LoadOffset+int64_t(LoadSize) <= StoreOffset; 993 994 if (isAAFailure) { 995 #if 0 996 dbgs() << "STORE LOAD DEP WITH COMMON BASE:\n" 997 << "Base = " << *StoreBase << "\n" 998 << "Store Ptr = " << *WritePtr << "\n" 999 << "Store Offs = " << StoreOffset << "\n" 1000 << "Load Ptr = " << *LoadPtr << "\n"; 1001 abort(); 1002 #endif 1003 return -1; 1004 } 1005 1006 // If the Load isn't completely contained within the stored bits, we don't 1007 // have all the bits to feed it. We could do something crazy in the future 1008 // (issue a smaller load then merge the bits in) but this seems unlikely to be 1009 // valuable. 1010 if (StoreOffset > LoadOffset || 1011 StoreOffset+StoreSize < LoadOffset+LoadSize) 1012 return -1; 1013 1014 // Okay, we can do this transformation. Return the number of bytes into the 1015 // store that the load is. 1016 return LoadOffset-StoreOffset; 1017 } 1018 1019 /// AnalyzeLoadFromClobberingStore - This function is called when we have a 1020 /// memdep query of a load that ends up being a clobbering store. 1021 static int AnalyzeLoadFromClobberingStore(Type *LoadTy, Value *LoadPtr, 1022 StoreInst *DepSI, 1023 const DataLayout &DL) { 1024 // Cannot handle reading from store of first-class aggregate yet. 1025 if (DepSI->getValueOperand()->getType()->isStructTy() || 1026 DepSI->getValueOperand()->getType()->isArrayTy()) 1027 return -1; 1028 1029 Value *StorePtr = DepSI->getPointerOperand(); 1030 uint64_t StoreSize =DL.getTypeSizeInBits(DepSI->getValueOperand()->getType()); 1031 return AnalyzeLoadFromClobberingWrite(LoadTy, LoadPtr, 1032 StorePtr, StoreSize, DL); 1033 } 1034 1035 /// AnalyzeLoadFromClobberingLoad - This function is called when we have a 1036 /// memdep query of a load that ends up being clobbered by another load. See if 1037 /// the other load can feed into the second load. 1038 static int AnalyzeLoadFromClobberingLoad(Type *LoadTy, Value *LoadPtr, 1039 LoadInst *DepLI, const DataLayout &DL){ 1040 // Cannot handle reading from store of first-class aggregate yet. 1041 if (DepLI->getType()->isStructTy() || DepLI->getType()->isArrayTy()) 1042 return -1; 1043 1044 Value *DepPtr = DepLI->getPointerOperand(); 1045 uint64_t DepSize = DL.getTypeSizeInBits(DepLI->getType()); 1046 int R = AnalyzeLoadFromClobberingWrite(LoadTy, LoadPtr, DepPtr, DepSize, DL); 1047 if (R != -1) return R; 1048 1049 // If we have a load/load clobber an DepLI can be widened to cover this load, 1050 // then we should widen it! 1051 int64_t LoadOffs = 0; 1052 const Value *LoadBase = 1053 GetPointerBaseWithConstantOffset(LoadPtr, LoadOffs, &DL); 1054 unsigned LoadSize = DL.getTypeStoreSize(LoadTy); 1055 1056 unsigned Size = MemoryDependenceAnalysis:: 1057 getLoadLoadClobberFullWidthSize(LoadBase, LoadOffs, LoadSize, DepLI, DL); 1058 if (Size == 0) return -1; 1059 1060 return AnalyzeLoadFromClobberingWrite(LoadTy, LoadPtr, DepPtr, Size*8, DL); 1061 } 1062 1063 1064 1065 static int AnalyzeLoadFromClobberingMemInst(Type *LoadTy, Value *LoadPtr, 1066 MemIntrinsic *MI, 1067 const DataLayout &DL) { 1068 // If the mem operation is a non-constant size, we can't handle it. 1069 ConstantInt *SizeCst = dyn_cast<ConstantInt>(MI->getLength()); 1070 if (!SizeCst) return -1; 1071 uint64_t MemSizeInBits = SizeCst->getZExtValue()*8; 1072 1073 // If this is memset, we just need to see if the offset is valid in the size 1074 // of the memset.. 1075 if (MI->getIntrinsicID() == Intrinsic::memset) 1076 return AnalyzeLoadFromClobberingWrite(LoadTy, LoadPtr, MI->getDest(), 1077 MemSizeInBits, DL); 1078 1079 // If we have a memcpy/memmove, the only case we can handle is if this is a 1080 // copy from constant memory. In that case, we can read directly from the 1081 // constant memory. 1082 MemTransferInst *MTI = cast<MemTransferInst>(MI); 1083 1084 Constant *Src = dyn_cast<Constant>(MTI->getSource()); 1085 if (!Src) return -1; 1086 1087 GlobalVariable *GV = dyn_cast<GlobalVariable>(GetUnderlyingObject(Src, &DL)); 1088 if (!GV || !GV->isConstant()) return -1; 1089 1090 // See if the access is within the bounds of the transfer. 1091 int Offset = AnalyzeLoadFromClobberingWrite(LoadTy, LoadPtr, 1092 MI->getDest(), MemSizeInBits, DL); 1093 if (Offset == -1) 1094 return Offset; 1095 1096 unsigned AS = Src->getType()->getPointerAddressSpace(); 1097 // Otherwise, see if we can constant fold a load from the constant with the 1098 // offset applied as appropriate. 1099 Src = ConstantExpr::getBitCast(Src, 1100 Type::getInt8PtrTy(Src->getContext(), AS)); 1101 Constant *OffsetCst = 1102 ConstantInt::get(Type::getInt64Ty(Src->getContext()), (unsigned)Offset); 1103 Src = ConstantExpr::getGetElementPtr(Src, OffsetCst); 1104 Src = ConstantExpr::getBitCast(Src, PointerType::get(LoadTy, AS)); 1105 if (ConstantFoldLoadFromConstPtr(Src, &DL)) 1106 return Offset; 1107 return -1; 1108 } 1109 1110 1111 /// GetStoreValueForLoad - This function is called when we have a 1112 /// memdep query of a load that ends up being a clobbering store. This means 1113 /// that the store provides bits used by the load but we the pointers don't 1114 /// mustalias. Check this case to see if there is anything more we can do 1115 /// before we give up. 1116 static Value *GetStoreValueForLoad(Value *SrcVal, unsigned Offset, 1117 Type *LoadTy, 1118 Instruction *InsertPt, const DataLayout &DL){ 1119 LLVMContext &Ctx = SrcVal->getType()->getContext(); 1120 1121 uint64_t StoreSize = (DL.getTypeSizeInBits(SrcVal->getType()) + 7) / 8; 1122 uint64_t LoadSize = (DL.getTypeSizeInBits(LoadTy) + 7) / 8; 1123 1124 IRBuilder<> Builder(InsertPt->getParent(), InsertPt); 1125 1126 // Compute which bits of the stored value are being used by the load. Convert 1127 // to an integer type to start with. 1128 if (SrcVal->getType()->getScalarType()->isPointerTy()) 1129 SrcVal = Builder.CreatePtrToInt(SrcVal, 1130 DL.getIntPtrType(SrcVal->getType())); 1131 if (!SrcVal->getType()->isIntegerTy()) 1132 SrcVal = Builder.CreateBitCast(SrcVal, IntegerType::get(Ctx, StoreSize*8)); 1133 1134 // Shift the bits to the least significant depending on endianness. 1135 unsigned ShiftAmt; 1136 if (DL.isLittleEndian()) 1137 ShiftAmt = Offset*8; 1138 else 1139 ShiftAmt = (StoreSize-LoadSize-Offset)*8; 1140 1141 if (ShiftAmt) 1142 SrcVal = Builder.CreateLShr(SrcVal, ShiftAmt); 1143 1144 if (LoadSize != StoreSize) 1145 SrcVal = Builder.CreateTrunc(SrcVal, IntegerType::get(Ctx, LoadSize*8)); 1146 1147 return CoerceAvailableValueToLoadType(SrcVal, LoadTy, InsertPt, DL); 1148 } 1149 1150 /// GetLoadValueForLoad - This function is called when we have a 1151 /// memdep query of a load that ends up being a clobbering load. This means 1152 /// that the load *may* provide bits used by the load but we can't be sure 1153 /// because the pointers don't mustalias. Check this case to see if there is 1154 /// anything more we can do before we give up. 1155 static Value *GetLoadValueForLoad(LoadInst *SrcVal, unsigned Offset, 1156 Type *LoadTy, Instruction *InsertPt, 1157 GVN &gvn) { 1158 const DataLayout &DL = *gvn.getDataLayout(); 1159 // If Offset+LoadTy exceeds the size of SrcVal, then we must be wanting to 1160 // widen SrcVal out to a larger load. 1161 unsigned SrcValSize = DL.getTypeStoreSize(SrcVal->getType()); 1162 unsigned LoadSize = DL.getTypeStoreSize(LoadTy); 1163 if (Offset+LoadSize > SrcValSize) { 1164 assert(SrcVal->isSimple() && "Cannot widen volatile/atomic load!"); 1165 assert(SrcVal->getType()->isIntegerTy() && "Can't widen non-integer load"); 1166 // If we have a load/load clobber an DepLI can be widened to cover this 1167 // load, then we should widen it to the next power of 2 size big enough! 1168 unsigned NewLoadSize = Offset+LoadSize; 1169 if (!isPowerOf2_32(NewLoadSize)) 1170 NewLoadSize = NextPowerOf2(NewLoadSize); 1171 1172 Value *PtrVal = SrcVal->getPointerOperand(); 1173 1174 // Insert the new load after the old load. This ensures that subsequent 1175 // memdep queries will find the new load. We can't easily remove the old 1176 // load completely because it is already in the value numbering table. 1177 IRBuilder<> Builder(SrcVal->getParent(), ++BasicBlock::iterator(SrcVal)); 1178 Type *DestPTy = 1179 IntegerType::get(LoadTy->getContext(), NewLoadSize*8); 1180 DestPTy = PointerType::get(DestPTy, 1181 PtrVal->getType()->getPointerAddressSpace()); 1182 Builder.SetCurrentDebugLocation(SrcVal->getDebugLoc()); 1183 PtrVal = Builder.CreateBitCast(PtrVal, DestPTy); 1184 LoadInst *NewLoad = Builder.CreateLoad(PtrVal); 1185 NewLoad->takeName(SrcVal); 1186 NewLoad->setAlignment(SrcVal->getAlignment()); 1187 1188 DEBUG(dbgs() << "GVN WIDENED LOAD: " << *SrcVal << "\n"); 1189 DEBUG(dbgs() << "TO: " << *NewLoad << "\n"); 1190 1191 // Replace uses of the original load with the wider load. On a big endian 1192 // system, we need to shift down to get the relevant bits. 1193 Value *RV = NewLoad; 1194 if (DL.isBigEndian()) 1195 RV = Builder.CreateLShr(RV, 1196 NewLoadSize*8-SrcVal->getType()->getPrimitiveSizeInBits()); 1197 RV = Builder.CreateTrunc(RV, SrcVal->getType()); 1198 SrcVal->replaceAllUsesWith(RV); 1199 1200 // We would like to use gvn.markInstructionForDeletion here, but we can't 1201 // because the load is already memoized into the leader map table that GVN 1202 // tracks. It is potentially possible to remove the load from the table, 1203 // but then there all of the operations based on it would need to be 1204 // rehashed. Just leave the dead load around. 1205 gvn.getMemDep().removeInstruction(SrcVal); 1206 SrcVal = NewLoad; 1207 } 1208 1209 return GetStoreValueForLoad(SrcVal, Offset, LoadTy, InsertPt, DL); 1210 } 1211 1212 1213 /// GetMemInstValueForLoad - This function is called when we have a 1214 /// memdep query of a load that ends up being a clobbering mem intrinsic. 1215 static Value *GetMemInstValueForLoad(MemIntrinsic *SrcInst, unsigned Offset, 1216 Type *LoadTy, Instruction *InsertPt, 1217 const DataLayout &DL){ 1218 LLVMContext &Ctx = LoadTy->getContext(); 1219 uint64_t LoadSize = DL.getTypeSizeInBits(LoadTy)/8; 1220 1221 IRBuilder<> Builder(InsertPt->getParent(), InsertPt); 1222 1223 // We know that this method is only called when the mem transfer fully 1224 // provides the bits for the load. 1225 if (MemSetInst *MSI = dyn_cast<MemSetInst>(SrcInst)) { 1226 // memset(P, 'x', 1234) -> splat('x'), even if x is a variable, and 1227 // independently of what the offset is. 1228 Value *Val = MSI->getValue(); 1229 if (LoadSize != 1) 1230 Val = Builder.CreateZExt(Val, IntegerType::get(Ctx, LoadSize*8)); 1231 1232 Value *OneElt = Val; 1233 1234 // Splat the value out to the right number of bits. 1235 for (unsigned NumBytesSet = 1; NumBytesSet != LoadSize; ) { 1236 // If we can double the number of bytes set, do it. 1237 if (NumBytesSet*2 <= LoadSize) { 1238 Value *ShVal = Builder.CreateShl(Val, NumBytesSet*8); 1239 Val = Builder.CreateOr(Val, ShVal); 1240 NumBytesSet <<= 1; 1241 continue; 1242 } 1243 1244 // Otherwise insert one byte at a time. 1245 Value *ShVal = Builder.CreateShl(Val, 1*8); 1246 Val = Builder.CreateOr(OneElt, ShVal); 1247 ++NumBytesSet; 1248 } 1249 1250 return CoerceAvailableValueToLoadType(Val, LoadTy, InsertPt, DL); 1251 } 1252 1253 // Otherwise, this is a memcpy/memmove from a constant global. 1254 MemTransferInst *MTI = cast<MemTransferInst>(SrcInst); 1255 Constant *Src = cast<Constant>(MTI->getSource()); 1256 unsigned AS = Src->getType()->getPointerAddressSpace(); 1257 1258 // Otherwise, see if we can constant fold a load from the constant with the 1259 // offset applied as appropriate. 1260 Src = ConstantExpr::getBitCast(Src, 1261 Type::getInt8PtrTy(Src->getContext(), AS)); 1262 Constant *OffsetCst = 1263 ConstantInt::get(Type::getInt64Ty(Src->getContext()), (unsigned)Offset); 1264 Src = ConstantExpr::getGetElementPtr(Src, OffsetCst); 1265 Src = ConstantExpr::getBitCast(Src, PointerType::get(LoadTy, AS)); 1266 return ConstantFoldLoadFromConstPtr(Src, &DL); 1267 } 1268 1269 1270 /// ConstructSSAForLoadSet - Given a set of loads specified by ValuesPerBlock, 1271 /// construct SSA form, allowing us to eliminate LI. This returns the value 1272 /// that should be used at LI's definition site. 1273 static Value *ConstructSSAForLoadSet(LoadInst *LI, 1274 SmallVectorImpl<AvailableValueInBlock> &ValuesPerBlock, 1275 GVN &gvn) { 1276 // Check for the fully redundant, dominating load case. In this case, we can 1277 // just use the dominating value directly. 1278 if (ValuesPerBlock.size() == 1 && 1279 gvn.getDominatorTree().properlyDominates(ValuesPerBlock[0].BB, 1280 LI->getParent())) { 1281 assert(!ValuesPerBlock[0].isUndefValue() && "Dead BB dominate this block"); 1282 return ValuesPerBlock[0].MaterializeAdjustedValue(LI->getType(), gvn); 1283 } 1284 1285 // Otherwise, we have to construct SSA form. 1286 SmallVector<PHINode*, 8> NewPHIs; 1287 SSAUpdater SSAUpdate(&NewPHIs); 1288 SSAUpdate.Initialize(LI->getType(), LI->getName()); 1289 1290 Type *LoadTy = LI->getType(); 1291 1292 for (unsigned i = 0, e = ValuesPerBlock.size(); i != e; ++i) { 1293 const AvailableValueInBlock &AV = ValuesPerBlock[i]; 1294 BasicBlock *BB = AV.BB; 1295 1296 if (SSAUpdate.HasValueForBlock(BB)) 1297 continue; 1298 1299 SSAUpdate.AddAvailableValue(BB, AV.MaterializeAdjustedValue(LoadTy, gvn)); 1300 } 1301 1302 // Perform PHI construction. 1303 Value *V = SSAUpdate.GetValueInMiddleOfBlock(LI->getParent()); 1304 1305 // If new PHI nodes were created, notify alias analysis. 1306 if (V->getType()->getScalarType()->isPointerTy()) { 1307 AliasAnalysis *AA = gvn.getAliasAnalysis(); 1308 1309 for (unsigned i = 0, e = NewPHIs.size(); i != e; ++i) 1310 AA->copyValue(LI, NewPHIs[i]); 1311 1312 // Now that we've copied information to the new PHIs, scan through 1313 // them again and inform alias analysis that we've added potentially 1314 // escaping uses to any values that are operands to these PHIs. 1315 for (unsigned i = 0, e = NewPHIs.size(); i != e; ++i) { 1316 PHINode *P = NewPHIs[i]; 1317 for (unsigned ii = 0, ee = P->getNumIncomingValues(); ii != ee; ++ii) { 1318 unsigned jj = PHINode::getOperandNumForIncomingValue(ii); 1319 AA->addEscapingUse(P->getOperandUse(jj)); 1320 } 1321 } 1322 } 1323 1324 return V; 1325 } 1326 1327 Value *AvailableValueInBlock::MaterializeAdjustedValue(Type *LoadTy, GVN &gvn) const { 1328 Value *Res; 1329 if (isSimpleValue()) { 1330 Res = getSimpleValue(); 1331 if (Res->getType() != LoadTy) { 1332 const DataLayout *DL = gvn.getDataLayout(); 1333 assert(DL && "Need target data to handle type mismatch case"); 1334 Res = GetStoreValueForLoad(Res, Offset, LoadTy, BB->getTerminator(), 1335 *DL); 1336 1337 DEBUG(dbgs() << "GVN COERCED NONLOCAL VAL:\nOffset: " << Offset << " " 1338 << *getSimpleValue() << '\n' 1339 << *Res << '\n' << "\n\n\n"); 1340 } 1341 } else if (isCoercedLoadValue()) { 1342 LoadInst *Load = getCoercedLoadValue(); 1343 if (Load->getType() == LoadTy && Offset == 0) { 1344 Res = Load; 1345 } else { 1346 Res = GetLoadValueForLoad(Load, Offset, LoadTy, BB->getTerminator(), 1347 gvn); 1348 1349 DEBUG(dbgs() << "GVN COERCED NONLOCAL LOAD:\nOffset: " << Offset << " " 1350 << *getCoercedLoadValue() << '\n' 1351 << *Res << '\n' << "\n\n\n"); 1352 } 1353 } else if (isMemIntrinValue()) { 1354 const DataLayout *DL = gvn.getDataLayout(); 1355 assert(DL && "Need target data to handle type mismatch case"); 1356 Res = GetMemInstValueForLoad(getMemIntrinValue(), Offset, 1357 LoadTy, BB->getTerminator(), *DL); 1358 DEBUG(dbgs() << "GVN COERCED NONLOCAL MEM INTRIN:\nOffset: " << Offset 1359 << " " << *getMemIntrinValue() << '\n' 1360 << *Res << '\n' << "\n\n\n"); 1361 } else { 1362 assert(isUndefValue() && "Should be UndefVal"); 1363 DEBUG(dbgs() << "GVN COERCED NONLOCAL Undef:\n";); 1364 return UndefValue::get(LoadTy); 1365 } 1366 return Res; 1367 } 1368 1369 static bool isLifetimeStart(const Instruction *Inst) { 1370 if (const IntrinsicInst* II = dyn_cast<IntrinsicInst>(Inst)) 1371 return II->getIntrinsicID() == Intrinsic::lifetime_start; 1372 return false; 1373 } 1374 1375 void GVN::AnalyzeLoadAvailability(LoadInst *LI, LoadDepVect &Deps, 1376 AvailValInBlkVect &ValuesPerBlock, 1377 UnavailBlkVect &UnavailableBlocks) { 1378 1379 // Filter out useless results (non-locals, etc). Keep track of the blocks 1380 // where we have a value available in repl, also keep track of whether we see 1381 // dependencies that produce an unknown value for the load (such as a call 1382 // that could potentially clobber the load). 1383 unsigned NumDeps = Deps.size(); 1384 for (unsigned i = 0, e = NumDeps; i != e; ++i) { 1385 BasicBlock *DepBB = Deps[i].getBB(); 1386 MemDepResult DepInfo = Deps[i].getResult(); 1387 1388 if (DeadBlocks.count(DepBB)) { 1389 // Dead dependent mem-op disguise as a load evaluating the same value 1390 // as the load in question. 1391 ValuesPerBlock.push_back(AvailableValueInBlock::getUndef(DepBB)); 1392 continue; 1393 } 1394 1395 if (!DepInfo.isDef() && !DepInfo.isClobber()) { 1396 UnavailableBlocks.push_back(DepBB); 1397 continue; 1398 } 1399 1400 if (DepInfo.isClobber()) { 1401 // The address being loaded in this non-local block may not be the same as 1402 // the pointer operand of the load if PHI translation occurs. Make sure 1403 // to consider the right address. 1404 Value *Address = Deps[i].getAddress(); 1405 1406 // If the dependence is to a store that writes to a superset of the bits 1407 // read by the load, we can extract the bits we need for the load from the 1408 // stored value. 1409 if (StoreInst *DepSI = dyn_cast<StoreInst>(DepInfo.getInst())) { 1410 if (DL && Address) { 1411 int Offset = AnalyzeLoadFromClobberingStore(LI->getType(), Address, 1412 DepSI, *DL); 1413 if (Offset != -1) { 1414 ValuesPerBlock.push_back(AvailableValueInBlock::get(DepBB, 1415 DepSI->getValueOperand(), 1416 Offset)); 1417 continue; 1418 } 1419 } 1420 } 1421 1422 // Check to see if we have something like this: 1423 // load i32* P 1424 // load i8* (P+1) 1425 // if we have this, replace the later with an extraction from the former. 1426 if (LoadInst *DepLI = dyn_cast<LoadInst>(DepInfo.getInst())) { 1427 // If this is a clobber and L is the first instruction in its block, then 1428 // we have the first instruction in the entry block. 1429 if (DepLI != LI && Address && DL) { 1430 int Offset = AnalyzeLoadFromClobberingLoad(LI->getType(), Address, 1431 DepLI, *DL); 1432 1433 if (Offset != -1) { 1434 ValuesPerBlock.push_back(AvailableValueInBlock::getLoad(DepBB,DepLI, 1435 Offset)); 1436 continue; 1437 } 1438 } 1439 } 1440 1441 // If the clobbering value is a memset/memcpy/memmove, see if we can 1442 // forward a value on from it. 1443 if (MemIntrinsic *DepMI = dyn_cast<MemIntrinsic>(DepInfo.getInst())) { 1444 if (DL && Address) { 1445 int Offset = AnalyzeLoadFromClobberingMemInst(LI->getType(), Address, 1446 DepMI, *DL); 1447 if (Offset != -1) { 1448 ValuesPerBlock.push_back(AvailableValueInBlock::getMI(DepBB, DepMI, 1449 Offset)); 1450 continue; 1451 } 1452 } 1453 } 1454 1455 UnavailableBlocks.push_back(DepBB); 1456 continue; 1457 } 1458 1459 // DepInfo.isDef() here 1460 1461 Instruction *DepInst = DepInfo.getInst(); 1462 1463 // Loading the allocation -> undef. 1464 if (isa<AllocaInst>(DepInst) || isMallocLikeFn(DepInst, TLI) || 1465 // Loading immediately after lifetime begin -> undef. 1466 isLifetimeStart(DepInst)) { 1467 ValuesPerBlock.push_back(AvailableValueInBlock::get(DepBB, 1468 UndefValue::get(LI->getType()))); 1469 continue; 1470 } 1471 1472 // Loading from calloc (which zero initializes memory) -> zero 1473 if (isCallocLikeFn(DepInst, TLI)) { 1474 ValuesPerBlock.push_back(AvailableValueInBlock::get( 1475 DepBB, Constant::getNullValue(LI->getType()))); 1476 continue; 1477 } 1478 1479 if (StoreInst *S = dyn_cast<StoreInst>(DepInst)) { 1480 // Reject loads and stores that are to the same address but are of 1481 // different types if we have to. 1482 if (S->getValueOperand()->getType() != LI->getType()) { 1483 // If the stored value is larger or equal to the loaded value, we can 1484 // reuse it. 1485 if (!DL || !CanCoerceMustAliasedValueToLoad(S->getValueOperand(), 1486 LI->getType(), *DL)) { 1487 UnavailableBlocks.push_back(DepBB); 1488 continue; 1489 } 1490 } 1491 1492 ValuesPerBlock.push_back(AvailableValueInBlock::get(DepBB, 1493 S->getValueOperand())); 1494 continue; 1495 } 1496 1497 if (LoadInst *LD = dyn_cast<LoadInst>(DepInst)) { 1498 // If the types mismatch and we can't handle it, reject reuse of the load. 1499 if (LD->getType() != LI->getType()) { 1500 // If the stored value is larger or equal to the loaded value, we can 1501 // reuse it. 1502 if (!DL || !CanCoerceMustAliasedValueToLoad(LD, LI->getType(),*DL)) { 1503 UnavailableBlocks.push_back(DepBB); 1504 continue; 1505 } 1506 } 1507 ValuesPerBlock.push_back(AvailableValueInBlock::getLoad(DepBB, LD)); 1508 continue; 1509 } 1510 1511 UnavailableBlocks.push_back(DepBB); 1512 } 1513 } 1514 1515 bool GVN::PerformLoadPRE(LoadInst *LI, AvailValInBlkVect &ValuesPerBlock, 1516 UnavailBlkVect &UnavailableBlocks) { 1517 // Okay, we have *some* definitions of the value. This means that the value 1518 // is available in some of our (transitive) predecessors. Lets think about 1519 // doing PRE of this load. This will involve inserting a new load into the 1520 // predecessor when it's not available. We could do this in general, but 1521 // prefer to not increase code size. As such, we only do this when we know 1522 // that we only have to insert *one* load (which means we're basically moving 1523 // the load, not inserting a new one). 1524 1525 SmallPtrSet<BasicBlock *, 4> Blockers; 1526 for (unsigned i = 0, e = UnavailableBlocks.size(); i != e; ++i) 1527 Blockers.insert(UnavailableBlocks[i]); 1528 1529 // Let's find the first basic block with more than one predecessor. Walk 1530 // backwards through predecessors if needed. 1531 BasicBlock *LoadBB = LI->getParent(); 1532 BasicBlock *TmpBB = LoadBB; 1533 1534 while (TmpBB->getSinglePredecessor()) { 1535 TmpBB = TmpBB->getSinglePredecessor(); 1536 if (TmpBB == LoadBB) // Infinite (unreachable) loop. 1537 return false; 1538 if (Blockers.count(TmpBB)) 1539 return false; 1540 1541 // If any of these blocks has more than one successor (i.e. if the edge we 1542 // just traversed was critical), then there are other paths through this 1543 // block along which the load may not be anticipated. Hoisting the load 1544 // above this block would be adding the load to execution paths along 1545 // which it was not previously executed. 1546 if (TmpBB->getTerminator()->getNumSuccessors() != 1) 1547 return false; 1548 } 1549 1550 assert(TmpBB); 1551 LoadBB = TmpBB; 1552 1553 // Check to see how many predecessors have the loaded value fully 1554 // available. 1555 MapVector<BasicBlock *, Value *> PredLoads; 1556 DenseMap<BasicBlock*, char> FullyAvailableBlocks; 1557 for (unsigned i = 0, e = ValuesPerBlock.size(); i != e; ++i) 1558 FullyAvailableBlocks[ValuesPerBlock[i].BB] = true; 1559 for (unsigned i = 0, e = UnavailableBlocks.size(); i != e; ++i) 1560 FullyAvailableBlocks[UnavailableBlocks[i]] = false; 1561 1562 SmallVector<BasicBlock *, 4> CriticalEdgePred; 1563 for (pred_iterator PI = pred_begin(LoadBB), E = pred_end(LoadBB); 1564 PI != E; ++PI) { 1565 BasicBlock *Pred = *PI; 1566 if (IsValueFullyAvailableInBlock(Pred, FullyAvailableBlocks, 0)) { 1567 continue; 1568 } 1569 1570 if (Pred->getTerminator()->getNumSuccessors() != 1) { 1571 if (isa<IndirectBrInst>(Pred->getTerminator())) { 1572 DEBUG(dbgs() << "COULD NOT PRE LOAD BECAUSE OF INDBR CRITICAL EDGE '" 1573 << Pred->getName() << "': " << *LI << '\n'); 1574 return false; 1575 } 1576 1577 if (LoadBB->isLandingPad()) { 1578 DEBUG(dbgs() 1579 << "COULD NOT PRE LOAD BECAUSE OF LANDING PAD CRITICAL EDGE '" 1580 << Pred->getName() << "': " << *LI << '\n'); 1581 return false; 1582 } 1583 1584 CriticalEdgePred.push_back(Pred); 1585 } else { 1586 // Only add the predecessors that will not be split for now. 1587 PredLoads[Pred] = nullptr; 1588 } 1589 } 1590 1591 // Decide whether PRE is profitable for this load. 1592 unsigned NumUnavailablePreds = PredLoads.size() + CriticalEdgePred.size(); 1593 assert(NumUnavailablePreds != 0 && 1594 "Fully available value should already be eliminated!"); 1595 1596 // If this load is unavailable in multiple predecessors, reject it. 1597 // FIXME: If we could restructure the CFG, we could make a common pred with 1598 // all the preds that don't have an available LI and insert a new load into 1599 // that one block. 1600 if (NumUnavailablePreds != 1) 1601 return false; 1602 1603 // Split critical edges, and update the unavailable predecessors accordingly. 1604 for (BasicBlock *OrigPred : CriticalEdgePred) { 1605 BasicBlock *NewPred = splitCriticalEdges(OrigPred, LoadBB); 1606 assert(!PredLoads.count(OrigPred) && "Split edges shouldn't be in map!"); 1607 PredLoads[NewPred] = nullptr; 1608 DEBUG(dbgs() << "Split critical edge " << OrigPred->getName() << "->" 1609 << LoadBB->getName() << '\n'); 1610 } 1611 1612 // Check if the load can safely be moved to all the unavailable predecessors. 1613 bool CanDoPRE = true; 1614 SmallVector<Instruction*, 8> NewInsts; 1615 for (auto &PredLoad : PredLoads) { 1616 BasicBlock *UnavailablePred = PredLoad.first; 1617 1618 // Do PHI translation to get its value in the predecessor if necessary. The 1619 // returned pointer (if non-null) is guaranteed to dominate UnavailablePred. 1620 1621 // If all preds have a single successor, then we know it is safe to insert 1622 // the load on the pred (?!?), so we can insert code to materialize the 1623 // pointer if it is not available. 1624 PHITransAddr Address(LI->getPointerOperand(), DL, AT); 1625 Value *LoadPtr = nullptr; 1626 LoadPtr = Address.PHITranslateWithInsertion(LoadBB, UnavailablePred, 1627 *DT, NewInsts); 1628 1629 // If we couldn't find or insert a computation of this phi translated value, 1630 // we fail PRE. 1631 if (!LoadPtr) { 1632 DEBUG(dbgs() << "COULDN'T INSERT PHI TRANSLATED VALUE OF: " 1633 << *LI->getPointerOperand() << "\n"); 1634 CanDoPRE = false; 1635 break; 1636 } 1637 1638 PredLoad.second = LoadPtr; 1639 } 1640 1641 if (!CanDoPRE) { 1642 while (!NewInsts.empty()) { 1643 Instruction *I = NewInsts.pop_back_val(); 1644 if (MD) MD->removeInstruction(I); 1645 I->eraseFromParent(); 1646 } 1647 // HINT: Don't revert the edge-splitting as following transformation may 1648 // also need to split these critical edges. 1649 return !CriticalEdgePred.empty(); 1650 } 1651 1652 // Okay, we can eliminate this load by inserting a reload in the predecessor 1653 // and using PHI construction to get the value in the other predecessors, do 1654 // it. 1655 DEBUG(dbgs() << "GVN REMOVING PRE LOAD: " << *LI << '\n'); 1656 DEBUG(if (!NewInsts.empty()) 1657 dbgs() << "INSERTED " << NewInsts.size() << " INSTS: " 1658 << *NewInsts.back() << '\n'); 1659 1660 // Assign value numbers to the new instructions. 1661 for (unsigned i = 0, e = NewInsts.size(); i != e; ++i) { 1662 // FIXME: We really _ought_ to insert these value numbers into their 1663 // parent's availability map. However, in doing so, we risk getting into 1664 // ordering issues. If a block hasn't been processed yet, we would be 1665 // marking a value as AVAIL-IN, which isn't what we intend. 1666 VN.lookup_or_add(NewInsts[i]); 1667 } 1668 1669 for (const auto &PredLoad : PredLoads) { 1670 BasicBlock *UnavailablePred = PredLoad.first; 1671 Value *LoadPtr = PredLoad.second; 1672 1673 Instruction *NewLoad = new LoadInst(LoadPtr, LI->getName()+".pre", false, 1674 LI->getAlignment(), 1675 UnavailablePred->getTerminator()); 1676 1677 // Transfer the old load's AA tags to the new load. 1678 AAMDNodes Tags; 1679 LI->getAAMetadata(Tags); 1680 if (Tags) 1681 NewLoad->setAAMetadata(Tags); 1682 1683 // Transfer DebugLoc. 1684 NewLoad->setDebugLoc(LI->getDebugLoc()); 1685 1686 // Add the newly created load. 1687 ValuesPerBlock.push_back(AvailableValueInBlock::get(UnavailablePred, 1688 NewLoad)); 1689 MD->invalidateCachedPointerInfo(LoadPtr); 1690 DEBUG(dbgs() << "GVN INSERTED " << *NewLoad << '\n'); 1691 } 1692 1693 // Perform PHI construction. 1694 Value *V = ConstructSSAForLoadSet(LI, ValuesPerBlock, *this); 1695 LI->replaceAllUsesWith(V); 1696 if (isa<PHINode>(V)) 1697 V->takeName(LI); 1698 if (V->getType()->getScalarType()->isPointerTy()) 1699 MD->invalidateCachedPointerInfo(V); 1700 markInstructionForDeletion(LI); 1701 ++NumPRELoad; 1702 return true; 1703 } 1704 1705 /// processNonLocalLoad - Attempt to eliminate a load whose dependencies are 1706 /// non-local by performing PHI construction. 1707 bool GVN::processNonLocalLoad(LoadInst *LI) { 1708 // Step 1: Find the non-local dependencies of the load. 1709 LoadDepVect Deps; 1710 AliasAnalysis::Location Loc = VN.getAliasAnalysis()->getLocation(LI); 1711 MD->getNonLocalPointerDependency(Loc, true, LI->getParent(), Deps); 1712 1713 // If we had to process more than one hundred blocks to find the 1714 // dependencies, this load isn't worth worrying about. Optimizing 1715 // it will be too expensive. 1716 unsigned NumDeps = Deps.size(); 1717 if (NumDeps > 100) 1718 return false; 1719 1720 // If we had a phi translation failure, we'll have a single entry which is a 1721 // clobber in the current block. Reject this early. 1722 if (NumDeps == 1 && 1723 !Deps[0].getResult().isDef() && !Deps[0].getResult().isClobber()) { 1724 DEBUG( 1725 dbgs() << "GVN: non-local load "; 1726 LI->printAsOperand(dbgs()); 1727 dbgs() << " has unknown dependencies\n"; 1728 ); 1729 return false; 1730 } 1731 1732 // Step 2: Analyze the availability of the load 1733 AvailValInBlkVect ValuesPerBlock; 1734 UnavailBlkVect UnavailableBlocks; 1735 AnalyzeLoadAvailability(LI, Deps, ValuesPerBlock, UnavailableBlocks); 1736 1737 // If we have no predecessors that produce a known value for this load, exit 1738 // early. 1739 if (ValuesPerBlock.empty()) 1740 return false; 1741 1742 // Step 3: Eliminate fully redundancy. 1743 // 1744 // If all of the instructions we depend on produce a known value for this 1745 // load, then it is fully redundant and we can use PHI insertion to compute 1746 // its value. Insert PHIs and remove the fully redundant value now. 1747 if (UnavailableBlocks.empty()) { 1748 DEBUG(dbgs() << "GVN REMOVING NONLOCAL LOAD: " << *LI << '\n'); 1749 1750 // Perform PHI construction. 1751 Value *V = ConstructSSAForLoadSet(LI, ValuesPerBlock, *this); 1752 LI->replaceAllUsesWith(V); 1753 1754 if (isa<PHINode>(V)) 1755 V->takeName(LI); 1756 if (V->getType()->getScalarType()->isPointerTy()) 1757 MD->invalidateCachedPointerInfo(V); 1758 markInstructionForDeletion(LI); 1759 ++NumGVNLoad; 1760 return true; 1761 } 1762 1763 // Step 4: Eliminate partial redundancy. 1764 if (!EnablePRE || !EnableLoadPRE) 1765 return false; 1766 1767 return PerformLoadPRE(LI, ValuesPerBlock, UnavailableBlocks); 1768 } 1769 1770 1771 static void patchReplacementInstruction(Instruction *I, Value *Repl) { 1772 // Patch the replacement so that it is not more restrictive than the value 1773 // being replaced. 1774 BinaryOperator *Op = dyn_cast<BinaryOperator>(I); 1775 BinaryOperator *ReplOp = dyn_cast<BinaryOperator>(Repl); 1776 if (Op && ReplOp && isa<OverflowingBinaryOperator>(Op) && 1777 isa<OverflowingBinaryOperator>(ReplOp)) { 1778 if (ReplOp->hasNoSignedWrap() && !Op->hasNoSignedWrap()) 1779 ReplOp->setHasNoSignedWrap(false); 1780 if (ReplOp->hasNoUnsignedWrap() && !Op->hasNoUnsignedWrap()) 1781 ReplOp->setHasNoUnsignedWrap(false); 1782 } 1783 if (Instruction *ReplInst = dyn_cast<Instruction>(Repl)) { 1784 // FIXME: If both the original and replacement value are part of the 1785 // same control-flow region (meaning that the execution of one 1786 // guarentees the executation of the other), then we can combine the 1787 // noalias scopes here and do better than the general conservative 1788 // answer used in combineMetadata(). 1789 1790 // In general, GVN unifies expressions over different control-flow 1791 // regions, and so we need a conservative combination of the noalias 1792 // scopes. 1793 unsigned KnownIDs[] = { 1794 LLVMContext::MD_tbaa, 1795 LLVMContext::MD_alias_scope, 1796 LLVMContext::MD_noalias, 1797 LLVMContext::MD_range, 1798 LLVMContext::MD_fpmath, 1799 LLVMContext::MD_invariant_load, 1800 }; 1801 combineMetadata(ReplInst, I, KnownIDs); 1802 } 1803 } 1804 1805 static void patchAndReplaceAllUsesWith(Instruction *I, Value *Repl) { 1806 patchReplacementInstruction(I, Repl); 1807 I->replaceAllUsesWith(Repl); 1808 } 1809 1810 /// processLoad - Attempt to eliminate a load, first by eliminating it 1811 /// locally, and then attempting non-local elimination if that fails. 1812 bool GVN::processLoad(LoadInst *L) { 1813 if (!MD) 1814 return false; 1815 1816 if (!L->isSimple()) 1817 return false; 1818 1819 if (L->use_empty()) { 1820 markInstructionForDeletion(L); 1821 return true; 1822 } 1823 1824 // ... to a pointer that has been loaded from before... 1825 MemDepResult Dep = MD->getDependency(L); 1826 1827 // If we have a clobber and target data is around, see if this is a clobber 1828 // that we can fix up through code synthesis. 1829 if (Dep.isClobber() && DL) { 1830 // Check to see if we have something like this: 1831 // store i32 123, i32* %P 1832 // %A = bitcast i32* %P to i8* 1833 // %B = gep i8* %A, i32 1 1834 // %C = load i8* %B 1835 // 1836 // We could do that by recognizing if the clobber instructions are obviously 1837 // a common base + constant offset, and if the previous store (or memset) 1838 // completely covers this load. This sort of thing can happen in bitfield 1839 // access code. 1840 Value *AvailVal = nullptr; 1841 if (StoreInst *DepSI = dyn_cast<StoreInst>(Dep.getInst())) { 1842 int Offset = AnalyzeLoadFromClobberingStore(L->getType(), 1843 L->getPointerOperand(), 1844 DepSI, *DL); 1845 if (Offset != -1) 1846 AvailVal = GetStoreValueForLoad(DepSI->getValueOperand(), Offset, 1847 L->getType(), L, *DL); 1848 } 1849 1850 // Check to see if we have something like this: 1851 // load i32* P 1852 // load i8* (P+1) 1853 // if we have this, replace the later with an extraction from the former. 1854 if (LoadInst *DepLI = dyn_cast<LoadInst>(Dep.getInst())) { 1855 // If this is a clobber and L is the first instruction in its block, then 1856 // we have the first instruction in the entry block. 1857 if (DepLI == L) 1858 return false; 1859 1860 int Offset = AnalyzeLoadFromClobberingLoad(L->getType(), 1861 L->getPointerOperand(), 1862 DepLI, *DL); 1863 if (Offset != -1) 1864 AvailVal = GetLoadValueForLoad(DepLI, Offset, L->getType(), L, *this); 1865 } 1866 1867 // If the clobbering value is a memset/memcpy/memmove, see if we can forward 1868 // a value on from it. 1869 if (MemIntrinsic *DepMI = dyn_cast<MemIntrinsic>(Dep.getInst())) { 1870 int Offset = AnalyzeLoadFromClobberingMemInst(L->getType(), 1871 L->getPointerOperand(), 1872 DepMI, *DL); 1873 if (Offset != -1) 1874 AvailVal = GetMemInstValueForLoad(DepMI, Offset, L->getType(), L, *DL); 1875 } 1876 1877 if (AvailVal) { 1878 DEBUG(dbgs() << "GVN COERCED INST:\n" << *Dep.getInst() << '\n' 1879 << *AvailVal << '\n' << *L << "\n\n\n"); 1880 1881 // Replace the load! 1882 L->replaceAllUsesWith(AvailVal); 1883 if (AvailVal->getType()->getScalarType()->isPointerTy()) 1884 MD->invalidateCachedPointerInfo(AvailVal); 1885 markInstructionForDeletion(L); 1886 ++NumGVNLoad; 1887 return true; 1888 } 1889 } 1890 1891 // If the value isn't available, don't do anything! 1892 if (Dep.isClobber()) { 1893 DEBUG( 1894 // fast print dep, using operator<< on instruction is too slow. 1895 dbgs() << "GVN: load "; 1896 L->printAsOperand(dbgs()); 1897 Instruction *I = Dep.getInst(); 1898 dbgs() << " is clobbered by " << *I << '\n'; 1899 ); 1900 return false; 1901 } 1902 1903 // If it is defined in another block, try harder. 1904 if (Dep.isNonLocal()) 1905 return processNonLocalLoad(L); 1906 1907 if (!Dep.isDef()) { 1908 DEBUG( 1909 // fast print dep, using operator<< on instruction is too slow. 1910 dbgs() << "GVN: load "; 1911 L->printAsOperand(dbgs()); 1912 dbgs() << " has unknown dependence\n"; 1913 ); 1914 return false; 1915 } 1916 1917 Instruction *DepInst = Dep.getInst(); 1918 if (StoreInst *DepSI = dyn_cast<StoreInst>(DepInst)) { 1919 Value *StoredVal = DepSI->getValueOperand(); 1920 1921 // The store and load are to a must-aliased pointer, but they may not 1922 // actually have the same type. See if we know how to reuse the stored 1923 // value (depending on its type). 1924 if (StoredVal->getType() != L->getType()) { 1925 if (DL) { 1926 StoredVal = CoerceAvailableValueToLoadType(StoredVal, L->getType(), 1927 L, *DL); 1928 if (!StoredVal) 1929 return false; 1930 1931 DEBUG(dbgs() << "GVN COERCED STORE:\n" << *DepSI << '\n' << *StoredVal 1932 << '\n' << *L << "\n\n\n"); 1933 } 1934 else 1935 return false; 1936 } 1937 1938 // Remove it! 1939 L->replaceAllUsesWith(StoredVal); 1940 if (StoredVal->getType()->getScalarType()->isPointerTy()) 1941 MD->invalidateCachedPointerInfo(StoredVal); 1942 markInstructionForDeletion(L); 1943 ++NumGVNLoad; 1944 return true; 1945 } 1946 1947 if (LoadInst *DepLI = dyn_cast<LoadInst>(DepInst)) { 1948 Value *AvailableVal = DepLI; 1949 1950 // The loads are of a must-aliased pointer, but they may not actually have 1951 // the same type. See if we know how to reuse the previously loaded value 1952 // (depending on its type). 1953 if (DepLI->getType() != L->getType()) { 1954 if (DL) { 1955 AvailableVal = CoerceAvailableValueToLoadType(DepLI, L->getType(), 1956 L, *DL); 1957 if (!AvailableVal) 1958 return false; 1959 1960 DEBUG(dbgs() << "GVN COERCED LOAD:\n" << *DepLI << "\n" << *AvailableVal 1961 << "\n" << *L << "\n\n\n"); 1962 } 1963 else 1964 return false; 1965 } 1966 1967 // Remove it! 1968 patchAndReplaceAllUsesWith(L, AvailableVal); 1969 if (DepLI->getType()->getScalarType()->isPointerTy()) 1970 MD->invalidateCachedPointerInfo(DepLI); 1971 markInstructionForDeletion(L); 1972 ++NumGVNLoad; 1973 return true; 1974 } 1975 1976 // If this load really doesn't depend on anything, then we must be loading an 1977 // undef value. This can happen when loading for a fresh allocation with no 1978 // intervening stores, for example. 1979 if (isa<AllocaInst>(DepInst) || isMallocLikeFn(DepInst, TLI)) { 1980 L->replaceAllUsesWith(UndefValue::get(L->getType())); 1981 markInstructionForDeletion(L); 1982 ++NumGVNLoad; 1983 return true; 1984 } 1985 1986 // If this load occurs either right after a lifetime begin, 1987 // then the loaded value is undefined. 1988 if (IntrinsicInst *II = dyn_cast<IntrinsicInst>(DepInst)) { 1989 if (II->getIntrinsicID() == Intrinsic::lifetime_start) { 1990 L->replaceAllUsesWith(UndefValue::get(L->getType())); 1991 markInstructionForDeletion(L); 1992 ++NumGVNLoad; 1993 return true; 1994 } 1995 } 1996 1997 // If this load follows a calloc (which zero initializes memory), 1998 // then the loaded value is zero 1999 if (isCallocLikeFn(DepInst, TLI)) { 2000 L->replaceAllUsesWith(Constant::getNullValue(L->getType())); 2001 markInstructionForDeletion(L); 2002 ++NumGVNLoad; 2003 return true; 2004 } 2005 2006 return false; 2007 } 2008 2009 // findLeader - In order to find a leader for a given value number at a 2010 // specific basic block, we first obtain the list of all Values for that number, 2011 // and then scan the list to find one whose block dominates the block in 2012 // question. This is fast because dominator tree queries consist of only 2013 // a few comparisons of DFS numbers. 2014 Value *GVN::findLeader(const BasicBlock *BB, uint32_t num) { 2015 LeaderTableEntry Vals = LeaderTable[num]; 2016 if (!Vals.Val) return nullptr; 2017 2018 Value *Val = nullptr; 2019 if (DT->dominates(Vals.BB, BB)) { 2020 Val = Vals.Val; 2021 if (isa<Constant>(Val)) return Val; 2022 } 2023 2024 LeaderTableEntry* Next = Vals.Next; 2025 while (Next) { 2026 if (DT->dominates(Next->BB, BB)) { 2027 if (isa<Constant>(Next->Val)) return Next->Val; 2028 if (!Val) Val = Next->Val; 2029 } 2030 2031 Next = Next->Next; 2032 } 2033 2034 return Val; 2035 } 2036 2037 /// replaceAllDominatedUsesWith - Replace all uses of 'From' with 'To' if the 2038 /// use is dominated by the given basic block. Returns the number of uses that 2039 /// were replaced. 2040 unsigned GVN::replaceAllDominatedUsesWith(Value *From, Value *To, 2041 const BasicBlockEdge &Root) { 2042 unsigned Count = 0; 2043 for (Value::use_iterator UI = From->use_begin(), UE = From->use_end(); 2044 UI != UE; ) { 2045 Use &U = *UI++; 2046 2047 if (DT->dominates(Root, U)) { 2048 U.set(To); 2049 ++Count; 2050 } 2051 } 2052 return Count; 2053 } 2054 2055 /// isOnlyReachableViaThisEdge - There is an edge from 'Src' to 'Dst'. Return 2056 /// true if every path from the entry block to 'Dst' passes via this edge. In 2057 /// particular 'Dst' must not be reachable via another edge from 'Src'. 2058 static bool isOnlyReachableViaThisEdge(const BasicBlockEdge &E, 2059 DominatorTree *DT) { 2060 // While in theory it is interesting to consider the case in which Dst has 2061 // more than one predecessor, because Dst might be part of a loop which is 2062 // only reachable from Src, in practice it is pointless since at the time 2063 // GVN runs all such loops have preheaders, which means that Dst will have 2064 // been changed to have only one predecessor, namely Src. 2065 const BasicBlock *Pred = E.getEnd()->getSinglePredecessor(); 2066 const BasicBlock *Src = E.getStart(); 2067 assert((!Pred || Pred == Src) && "No edge between these basic blocks!"); 2068 (void)Src; 2069 return Pred != nullptr; 2070 } 2071 2072 /// propagateEquality - The given values are known to be equal in every block 2073 /// dominated by 'Root'. Exploit this, for example by replacing 'LHS' with 2074 /// 'RHS' everywhere in the scope. Returns whether a change was made. 2075 bool GVN::propagateEquality(Value *LHS, Value *RHS, 2076 const BasicBlockEdge &Root) { 2077 SmallVector<std::pair<Value*, Value*>, 4> Worklist; 2078 Worklist.push_back(std::make_pair(LHS, RHS)); 2079 bool Changed = false; 2080 // For speed, compute a conservative fast approximation to 2081 // DT->dominates(Root, Root.getEnd()); 2082 bool RootDominatesEnd = isOnlyReachableViaThisEdge(Root, DT); 2083 2084 while (!Worklist.empty()) { 2085 std::pair<Value*, Value*> Item = Worklist.pop_back_val(); 2086 LHS = Item.first; RHS = Item.second; 2087 2088 if (LHS == RHS) continue; 2089 assert(LHS->getType() == RHS->getType() && "Equality but unequal types!"); 2090 2091 // Don't try to propagate equalities between constants. 2092 if (isa<Constant>(LHS) && isa<Constant>(RHS)) continue; 2093 2094 // Prefer a constant on the right-hand side, or an Argument if no constants. 2095 if (isa<Constant>(LHS) || (isa<Argument>(LHS) && !isa<Constant>(RHS))) 2096 std::swap(LHS, RHS); 2097 assert((isa<Argument>(LHS) || isa<Instruction>(LHS)) && "Unexpected value!"); 2098 2099 // If there is no obvious reason to prefer the left-hand side over the right- 2100 // hand side, ensure the longest lived term is on the right-hand side, so the 2101 // shortest lived term will be replaced by the longest lived. This tends to 2102 // expose more simplifications. 2103 uint32_t LVN = VN.lookup_or_add(LHS); 2104 if ((isa<Argument>(LHS) && isa<Argument>(RHS)) || 2105 (isa<Instruction>(LHS) && isa<Instruction>(RHS))) { 2106 // Move the 'oldest' value to the right-hand side, using the value number as 2107 // a proxy for age. 2108 uint32_t RVN = VN.lookup_or_add(RHS); 2109 if (LVN < RVN) { 2110 std::swap(LHS, RHS); 2111 LVN = RVN; 2112 } 2113 } 2114 2115 // If value numbering later sees that an instruction in the scope is equal 2116 // to 'LHS' then ensure it will be turned into 'RHS'. In order to preserve 2117 // the invariant that instructions only occur in the leader table for their 2118 // own value number (this is used by removeFromLeaderTable), do not do this 2119 // if RHS is an instruction (if an instruction in the scope is morphed into 2120 // LHS then it will be turned into RHS by the next GVN iteration anyway, so 2121 // using the leader table is about compiling faster, not optimizing better). 2122 // The leader table only tracks basic blocks, not edges. Only add to if we 2123 // have the simple case where the edge dominates the end. 2124 if (RootDominatesEnd && !isa<Instruction>(RHS)) 2125 addToLeaderTable(LVN, RHS, Root.getEnd()); 2126 2127 // Replace all occurrences of 'LHS' with 'RHS' everywhere in the scope. As 2128 // LHS always has at least one use that is not dominated by Root, this will 2129 // never do anything if LHS has only one use. 2130 if (!LHS->hasOneUse()) { 2131 unsigned NumReplacements = replaceAllDominatedUsesWith(LHS, RHS, Root); 2132 Changed |= NumReplacements > 0; 2133 NumGVNEqProp += NumReplacements; 2134 } 2135 2136 // Now try to deduce additional equalities from this one. For example, if the 2137 // known equality was "(A != B)" == "false" then it follows that A and B are 2138 // equal in the scope. Only boolean equalities with an explicit true or false 2139 // RHS are currently supported. 2140 if (!RHS->getType()->isIntegerTy(1)) 2141 // Not a boolean equality - bail out. 2142 continue; 2143 ConstantInt *CI = dyn_cast<ConstantInt>(RHS); 2144 if (!CI) 2145 // RHS neither 'true' nor 'false' - bail out. 2146 continue; 2147 // Whether RHS equals 'true'. Otherwise it equals 'false'. 2148 bool isKnownTrue = CI->isAllOnesValue(); 2149 bool isKnownFalse = !isKnownTrue; 2150 2151 // If "A && B" is known true then both A and B are known true. If "A || B" 2152 // is known false then both A and B are known false. 2153 Value *A, *B; 2154 if ((isKnownTrue && match(LHS, m_And(m_Value(A), m_Value(B)))) || 2155 (isKnownFalse && match(LHS, m_Or(m_Value(A), m_Value(B))))) { 2156 Worklist.push_back(std::make_pair(A, RHS)); 2157 Worklist.push_back(std::make_pair(B, RHS)); 2158 continue; 2159 } 2160 2161 // If we are propagating an equality like "(A == B)" == "true" then also 2162 // propagate the equality A == B. When propagating a comparison such as 2163 // "(A >= B)" == "true", replace all instances of "A < B" with "false". 2164 if (ICmpInst *Cmp = dyn_cast<ICmpInst>(LHS)) { 2165 Value *Op0 = Cmp->getOperand(0), *Op1 = Cmp->getOperand(1); 2166 2167 // If "A == B" is known true, or "A != B" is known false, then replace 2168 // A with B everywhere in the scope. 2169 if ((isKnownTrue && Cmp->getPredicate() == CmpInst::ICMP_EQ) || 2170 (isKnownFalse && Cmp->getPredicate() == CmpInst::ICMP_NE)) 2171 Worklist.push_back(std::make_pair(Op0, Op1)); 2172 2173 // If "A >= B" is known true, replace "A < B" with false everywhere. 2174 CmpInst::Predicate NotPred = Cmp->getInversePredicate(); 2175 Constant *NotVal = ConstantInt::get(Cmp->getType(), isKnownFalse); 2176 // Since we don't have the instruction "A < B" immediately to hand, work out 2177 // the value number that it would have and use that to find an appropriate 2178 // instruction (if any). 2179 uint32_t NextNum = VN.getNextUnusedValueNumber(); 2180 uint32_t Num = VN.lookup_or_add_cmp(Cmp->getOpcode(), NotPred, Op0, Op1); 2181 // If the number we were assigned was brand new then there is no point in 2182 // looking for an instruction realizing it: there cannot be one! 2183 if (Num < NextNum) { 2184 Value *NotCmp = findLeader(Root.getEnd(), Num); 2185 if (NotCmp && isa<Instruction>(NotCmp)) { 2186 unsigned NumReplacements = 2187 replaceAllDominatedUsesWith(NotCmp, NotVal, Root); 2188 Changed |= NumReplacements > 0; 2189 NumGVNEqProp += NumReplacements; 2190 } 2191 } 2192 // Ensure that any instruction in scope that gets the "A < B" value number 2193 // is replaced with false. 2194 // The leader table only tracks basic blocks, not edges. Only add to if we 2195 // have the simple case where the edge dominates the end. 2196 if (RootDominatesEnd) 2197 addToLeaderTable(Num, NotVal, Root.getEnd()); 2198 2199 continue; 2200 } 2201 } 2202 2203 return Changed; 2204 } 2205 2206 /// processInstruction - When calculating availability, handle an instruction 2207 /// by inserting it into the appropriate sets 2208 bool GVN::processInstruction(Instruction *I) { 2209 // Ignore dbg info intrinsics. 2210 if (isa<DbgInfoIntrinsic>(I)) 2211 return false; 2212 2213 // If the instruction can be easily simplified then do so now in preference 2214 // to value numbering it. Value numbering often exposes redundancies, for 2215 // example if it determines that %y is equal to %x then the instruction 2216 // "%z = and i32 %x, %y" becomes "%z = and i32 %x, %x" which we now simplify. 2217 if (Value *V = SimplifyInstruction(I, DL, TLI, DT, AT)) { 2218 I->replaceAllUsesWith(V); 2219 if (MD && V->getType()->getScalarType()->isPointerTy()) 2220 MD->invalidateCachedPointerInfo(V); 2221 markInstructionForDeletion(I); 2222 ++NumGVNSimpl; 2223 return true; 2224 } 2225 2226 if (LoadInst *LI = dyn_cast<LoadInst>(I)) { 2227 if (processLoad(LI)) 2228 return true; 2229 2230 unsigned Num = VN.lookup_or_add(LI); 2231 addToLeaderTable(Num, LI, LI->getParent()); 2232 return false; 2233 } 2234 2235 // For conditional branches, we can perform simple conditional propagation on 2236 // the condition value itself. 2237 if (BranchInst *BI = dyn_cast<BranchInst>(I)) { 2238 if (!BI->isConditional()) 2239 return false; 2240 2241 if (isa<Constant>(BI->getCondition())) 2242 return processFoldableCondBr(BI); 2243 2244 Value *BranchCond = BI->getCondition(); 2245 BasicBlock *TrueSucc = BI->getSuccessor(0); 2246 BasicBlock *FalseSucc = BI->getSuccessor(1); 2247 // Avoid multiple edges early. 2248 if (TrueSucc == FalseSucc) 2249 return false; 2250 2251 BasicBlock *Parent = BI->getParent(); 2252 bool Changed = false; 2253 2254 Value *TrueVal = ConstantInt::getTrue(TrueSucc->getContext()); 2255 BasicBlockEdge TrueE(Parent, TrueSucc); 2256 Changed |= propagateEquality(BranchCond, TrueVal, TrueE); 2257 2258 Value *FalseVal = ConstantInt::getFalse(FalseSucc->getContext()); 2259 BasicBlockEdge FalseE(Parent, FalseSucc); 2260 Changed |= propagateEquality(BranchCond, FalseVal, FalseE); 2261 2262 return Changed; 2263 } 2264 2265 // For switches, propagate the case values into the case destinations. 2266 if (SwitchInst *SI = dyn_cast<SwitchInst>(I)) { 2267 Value *SwitchCond = SI->getCondition(); 2268 BasicBlock *Parent = SI->getParent(); 2269 bool Changed = false; 2270 2271 // Remember how many outgoing edges there are to every successor. 2272 SmallDenseMap<BasicBlock *, unsigned, 16> SwitchEdges; 2273 for (unsigned i = 0, n = SI->getNumSuccessors(); i != n; ++i) 2274 ++SwitchEdges[SI->getSuccessor(i)]; 2275 2276 for (SwitchInst::CaseIt i = SI->case_begin(), e = SI->case_end(); 2277 i != e; ++i) { 2278 BasicBlock *Dst = i.getCaseSuccessor(); 2279 // If there is only a single edge, propagate the case value into it. 2280 if (SwitchEdges.lookup(Dst) == 1) { 2281 BasicBlockEdge E(Parent, Dst); 2282 Changed |= propagateEquality(SwitchCond, i.getCaseValue(), E); 2283 } 2284 } 2285 return Changed; 2286 } 2287 2288 // Instructions with void type don't return a value, so there's 2289 // no point in trying to find redundancies in them. 2290 if (I->getType()->isVoidTy()) return false; 2291 2292 uint32_t NextNum = VN.getNextUnusedValueNumber(); 2293 unsigned Num = VN.lookup_or_add(I); 2294 2295 // Allocations are always uniquely numbered, so we can save time and memory 2296 // by fast failing them. 2297 if (isa<AllocaInst>(I) || isa<TerminatorInst>(I) || isa<PHINode>(I)) { 2298 addToLeaderTable(Num, I, I->getParent()); 2299 return false; 2300 } 2301 2302 // If the number we were assigned was a brand new VN, then we don't 2303 // need to do a lookup to see if the number already exists 2304 // somewhere in the domtree: it can't! 2305 if (Num >= NextNum) { 2306 addToLeaderTable(Num, I, I->getParent()); 2307 return false; 2308 } 2309 2310 // Perform fast-path value-number based elimination of values inherited from 2311 // dominators. 2312 Value *repl = findLeader(I->getParent(), Num); 2313 if (!repl) { 2314 // Failure, just remember this instance for future use. 2315 addToLeaderTable(Num, I, I->getParent()); 2316 return false; 2317 } 2318 2319 // Remove it! 2320 patchAndReplaceAllUsesWith(I, repl); 2321 if (MD && repl->getType()->getScalarType()->isPointerTy()) 2322 MD->invalidateCachedPointerInfo(repl); 2323 markInstructionForDeletion(I); 2324 return true; 2325 } 2326 2327 /// runOnFunction - This is the main transformation entry point for a function. 2328 bool GVN::runOnFunction(Function& F) { 2329 if (skipOptnoneFunction(F)) 2330 return false; 2331 2332 if (!NoLoads) 2333 MD = &getAnalysis<MemoryDependenceAnalysis>(); 2334 DT = &getAnalysis<DominatorTreeWrapperPass>().getDomTree(); 2335 DataLayoutPass *DLP = getAnalysisIfAvailable<DataLayoutPass>(); 2336 DL = DLP ? &DLP->getDataLayout() : nullptr; 2337 AT = &getAnalysis<AssumptionTracker>(); 2338 TLI = &getAnalysis<TargetLibraryInfo>(); 2339 VN.setAliasAnalysis(&getAnalysis<AliasAnalysis>()); 2340 VN.setMemDep(MD); 2341 VN.setDomTree(DT); 2342 2343 bool Changed = false; 2344 bool ShouldContinue = true; 2345 2346 // Merge unconditional branches, allowing PRE to catch more 2347 // optimization opportunities. 2348 for (Function::iterator FI = F.begin(), FE = F.end(); FI != FE; ) { 2349 BasicBlock *BB = FI++; 2350 2351 bool removedBlock = MergeBlockIntoPredecessor(BB, this); 2352 if (removedBlock) ++NumGVNBlocks; 2353 2354 Changed |= removedBlock; 2355 } 2356 2357 unsigned Iteration = 0; 2358 while (ShouldContinue) { 2359 DEBUG(dbgs() << "GVN iteration: " << Iteration << "\n"); 2360 ShouldContinue = iterateOnFunction(F); 2361 Changed |= ShouldContinue; 2362 ++Iteration; 2363 } 2364 2365 if (EnablePRE) { 2366 // Fabricate val-num for dead-code in order to suppress assertion in 2367 // performPRE(). 2368 assignValNumForDeadCode(); 2369 bool PREChanged = true; 2370 while (PREChanged) { 2371 PREChanged = performPRE(F); 2372 Changed |= PREChanged; 2373 } 2374 } 2375 2376 // FIXME: Should perform GVN again after PRE does something. PRE can move 2377 // computations into blocks where they become fully redundant. Note that 2378 // we can't do this until PRE's critical edge splitting updates memdep. 2379 // Actually, when this happens, we should just fully integrate PRE into GVN. 2380 2381 cleanupGlobalSets(); 2382 // Do not cleanup DeadBlocks in cleanupGlobalSets() as it's called for each 2383 // iteration. 2384 DeadBlocks.clear(); 2385 2386 return Changed; 2387 } 2388 2389 2390 bool GVN::processBlock(BasicBlock *BB) { 2391 // FIXME: Kill off InstrsToErase by doing erasing eagerly in a helper function 2392 // (and incrementing BI before processing an instruction). 2393 assert(InstrsToErase.empty() && 2394 "We expect InstrsToErase to be empty across iterations"); 2395 if (DeadBlocks.count(BB)) 2396 return false; 2397 2398 bool ChangedFunction = false; 2399 2400 for (BasicBlock::iterator BI = BB->begin(), BE = BB->end(); 2401 BI != BE;) { 2402 ChangedFunction |= processInstruction(BI); 2403 if (InstrsToErase.empty()) { 2404 ++BI; 2405 continue; 2406 } 2407 2408 // If we need some instructions deleted, do it now. 2409 NumGVNInstr += InstrsToErase.size(); 2410 2411 // Avoid iterator invalidation. 2412 bool AtStart = BI == BB->begin(); 2413 if (!AtStart) 2414 --BI; 2415 2416 for (SmallVectorImpl<Instruction *>::iterator I = InstrsToErase.begin(), 2417 E = InstrsToErase.end(); I != E; ++I) { 2418 DEBUG(dbgs() << "GVN removed: " << **I << '\n'); 2419 if (MD) MD->removeInstruction(*I); 2420 DEBUG(verifyRemoved(*I)); 2421 (*I)->eraseFromParent(); 2422 } 2423 InstrsToErase.clear(); 2424 2425 if (AtStart) 2426 BI = BB->begin(); 2427 else 2428 ++BI; 2429 } 2430 2431 return ChangedFunction; 2432 } 2433 2434 /// performPRE - Perform a purely local form of PRE that looks for diamond 2435 /// control flow patterns and attempts to perform simple PRE at the join point. 2436 bool GVN::performPRE(Function &F) { 2437 bool Changed = false; 2438 SmallVector<std::pair<Value*, BasicBlock*>, 8> predMap; 2439 for (BasicBlock *CurrentBlock : depth_first(&F.getEntryBlock())) { 2440 // Nothing to PRE in the entry block. 2441 if (CurrentBlock == &F.getEntryBlock()) continue; 2442 2443 // Don't perform PRE on a landing pad. 2444 if (CurrentBlock->isLandingPad()) continue; 2445 2446 for (BasicBlock::iterator BI = CurrentBlock->begin(), 2447 BE = CurrentBlock->end(); BI != BE; ) { 2448 Instruction *CurInst = BI++; 2449 2450 if (isa<AllocaInst>(CurInst) || 2451 isa<TerminatorInst>(CurInst) || isa<PHINode>(CurInst) || 2452 CurInst->getType()->isVoidTy() || 2453 CurInst->mayReadFromMemory() || CurInst->mayHaveSideEffects() || 2454 isa<DbgInfoIntrinsic>(CurInst)) 2455 continue; 2456 2457 // Don't do PRE on compares. The PHI would prevent CodeGenPrepare from 2458 // sinking the compare again, and it would force the code generator to 2459 // move the i1 from processor flags or predicate registers into a general 2460 // purpose register. 2461 if (isa<CmpInst>(CurInst)) 2462 continue; 2463 2464 // We don't currently value number ANY inline asm calls. 2465 if (CallInst *CallI = dyn_cast<CallInst>(CurInst)) 2466 if (CallI->isInlineAsm()) 2467 continue; 2468 2469 uint32_t ValNo = VN.lookup(CurInst); 2470 2471 // Look for the predecessors for PRE opportunities. We're 2472 // only trying to solve the basic diamond case, where 2473 // a value is computed in the successor and one predecessor, 2474 // but not the other. We also explicitly disallow cases 2475 // where the successor is its own predecessor, because they're 2476 // more complicated to get right. 2477 unsigned NumWith = 0; 2478 unsigned NumWithout = 0; 2479 BasicBlock *PREPred = nullptr; 2480 predMap.clear(); 2481 2482 for (pred_iterator PI = pred_begin(CurrentBlock), 2483 PE = pred_end(CurrentBlock); PI != PE; ++PI) { 2484 BasicBlock *P = *PI; 2485 // We're not interested in PRE where the block is its 2486 // own predecessor, or in blocks with predecessors 2487 // that are not reachable. 2488 if (P == CurrentBlock) { 2489 NumWithout = 2; 2490 break; 2491 } else if (!DT->isReachableFromEntry(P)) { 2492 NumWithout = 2; 2493 break; 2494 } 2495 2496 Value* predV = findLeader(P, ValNo); 2497 if (!predV) { 2498 predMap.push_back(std::make_pair(static_cast<Value *>(nullptr), P)); 2499 PREPred = P; 2500 ++NumWithout; 2501 } else if (predV == CurInst) { 2502 /* CurInst dominates this predecessor. */ 2503 NumWithout = 2; 2504 break; 2505 } else { 2506 predMap.push_back(std::make_pair(predV, P)); 2507 ++NumWith; 2508 } 2509 } 2510 2511 // Don't do PRE when it might increase code size, i.e. when 2512 // we would need to insert instructions in more than one pred. 2513 if (NumWithout != 1 || NumWith == 0) 2514 continue; 2515 2516 // Don't do PRE across indirect branch. 2517 if (isa<IndirectBrInst>(PREPred->getTerminator())) 2518 continue; 2519 2520 // We can't do PRE safely on a critical edge, so instead we schedule 2521 // the edge to be split and perform the PRE the next time we iterate 2522 // on the function. 2523 unsigned SuccNum = GetSuccessorNumber(PREPred, CurrentBlock); 2524 if (isCriticalEdge(PREPred->getTerminator(), SuccNum)) { 2525 toSplit.push_back(std::make_pair(PREPred->getTerminator(), SuccNum)); 2526 continue; 2527 } 2528 2529 // Instantiate the expression in the predecessor that lacked it. 2530 // Because we are going top-down through the block, all value numbers 2531 // will be available in the predecessor by the time we need them. Any 2532 // that weren't originally present will have been instantiated earlier 2533 // in this loop. 2534 Instruction *PREInstr = CurInst->clone(); 2535 bool success = true; 2536 for (unsigned i = 0, e = CurInst->getNumOperands(); i != e; ++i) { 2537 Value *Op = PREInstr->getOperand(i); 2538 if (isa<Argument>(Op) || isa<Constant>(Op) || isa<GlobalValue>(Op)) 2539 continue; 2540 2541 if (Value *V = findLeader(PREPred, VN.lookup(Op))) { 2542 PREInstr->setOperand(i, V); 2543 } else { 2544 success = false; 2545 break; 2546 } 2547 } 2548 2549 // Fail out if we encounter an operand that is not available in 2550 // the PRE predecessor. This is typically because of loads which 2551 // are not value numbered precisely. 2552 if (!success) { 2553 DEBUG(verifyRemoved(PREInstr)); 2554 delete PREInstr; 2555 continue; 2556 } 2557 2558 PREInstr->insertBefore(PREPred->getTerminator()); 2559 PREInstr->setName(CurInst->getName() + ".pre"); 2560 PREInstr->setDebugLoc(CurInst->getDebugLoc()); 2561 VN.add(PREInstr, ValNo); 2562 ++NumGVNPRE; 2563 2564 // Update the availability map to include the new instruction. 2565 addToLeaderTable(ValNo, PREInstr, PREPred); 2566 2567 // Create a PHI to make the value available in this block. 2568 PHINode* Phi = PHINode::Create(CurInst->getType(), predMap.size(), 2569 CurInst->getName() + ".pre-phi", 2570 CurrentBlock->begin()); 2571 for (unsigned i = 0, e = predMap.size(); i != e; ++i) { 2572 if (Value *V = predMap[i].first) 2573 Phi->addIncoming(V, predMap[i].second); 2574 else 2575 Phi->addIncoming(PREInstr, PREPred); 2576 } 2577 2578 VN.add(Phi, ValNo); 2579 addToLeaderTable(ValNo, Phi, CurrentBlock); 2580 Phi->setDebugLoc(CurInst->getDebugLoc()); 2581 CurInst->replaceAllUsesWith(Phi); 2582 if (Phi->getType()->getScalarType()->isPointerTy()) { 2583 // Because we have added a PHI-use of the pointer value, it has now 2584 // "escaped" from alias analysis' perspective. We need to inform 2585 // AA of this. 2586 for (unsigned ii = 0, ee = Phi->getNumIncomingValues(); ii != ee; 2587 ++ii) { 2588 unsigned jj = PHINode::getOperandNumForIncomingValue(ii); 2589 VN.getAliasAnalysis()->addEscapingUse(Phi->getOperandUse(jj)); 2590 } 2591 2592 if (MD) 2593 MD->invalidateCachedPointerInfo(Phi); 2594 } 2595 VN.erase(CurInst); 2596 removeFromLeaderTable(ValNo, CurInst, CurrentBlock); 2597 2598 DEBUG(dbgs() << "GVN PRE removed: " << *CurInst << '\n'); 2599 if (MD) MD->removeInstruction(CurInst); 2600 DEBUG(verifyRemoved(CurInst)); 2601 CurInst->eraseFromParent(); 2602 Changed = true; 2603 } 2604 } 2605 2606 if (splitCriticalEdges()) 2607 Changed = true; 2608 2609 return Changed; 2610 } 2611 2612 /// Split the critical edge connecting the given two blocks, and return 2613 /// the block inserted to the critical edge. 2614 BasicBlock *GVN::splitCriticalEdges(BasicBlock *Pred, BasicBlock *Succ) { 2615 BasicBlock *BB = SplitCriticalEdge(Pred, Succ, this); 2616 if (MD) 2617 MD->invalidateCachedPredecessors(); 2618 return BB; 2619 } 2620 2621 /// splitCriticalEdges - Split critical edges found during the previous 2622 /// iteration that may enable further optimization. 2623 bool GVN::splitCriticalEdges() { 2624 if (toSplit.empty()) 2625 return false; 2626 do { 2627 std::pair<TerminatorInst*, unsigned> Edge = toSplit.pop_back_val(); 2628 SplitCriticalEdge(Edge.first, Edge.second, this); 2629 } while (!toSplit.empty()); 2630 if (MD) MD->invalidateCachedPredecessors(); 2631 return true; 2632 } 2633 2634 /// iterateOnFunction - Executes one iteration of GVN 2635 bool GVN::iterateOnFunction(Function &F) { 2636 cleanupGlobalSets(); 2637 2638 // Top-down walk of the dominator tree 2639 bool Changed = false; 2640 #if 0 2641 // Needed for value numbering with phi construction to work. 2642 ReversePostOrderTraversal<Function*> RPOT(&F); 2643 for (ReversePostOrderTraversal<Function*>::rpo_iterator RI = RPOT.begin(), 2644 RE = RPOT.end(); RI != RE; ++RI) 2645 Changed |= processBlock(*RI); 2646 #else 2647 // Save the blocks this function have before transformation begins. GVN may 2648 // split critical edge, and hence may invalidate the RPO/DT iterator. 2649 // 2650 std::vector<BasicBlock *> BBVect; 2651 BBVect.reserve(256); 2652 for (DomTreeNode *X : depth_first(DT->getRootNode())) 2653 BBVect.push_back(X->getBlock()); 2654 2655 for (std::vector<BasicBlock *>::iterator I = BBVect.begin(), E = BBVect.end(); 2656 I != E; I++) 2657 Changed |= processBlock(*I); 2658 #endif 2659 2660 return Changed; 2661 } 2662 2663 void GVN::cleanupGlobalSets() { 2664 VN.clear(); 2665 LeaderTable.clear(); 2666 TableAllocator.Reset(); 2667 } 2668 2669 /// verifyRemoved - Verify that the specified instruction does not occur in our 2670 /// internal data structures. 2671 void GVN::verifyRemoved(const Instruction *Inst) const { 2672 VN.verifyRemoved(Inst); 2673 2674 // Walk through the value number scope to make sure the instruction isn't 2675 // ferreted away in it. 2676 for (DenseMap<uint32_t, LeaderTableEntry>::const_iterator 2677 I = LeaderTable.begin(), E = LeaderTable.end(); I != E; ++I) { 2678 const LeaderTableEntry *Node = &I->second; 2679 assert(Node->Val != Inst && "Inst still in value numbering scope!"); 2680 2681 while (Node->Next) { 2682 Node = Node->Next; 2683 assert(Node->Val != Inst && "Inst still in value numbering scope!"); 2684 } 2685 } 2686 } 2687 2688 // BB is declared dead, which implied other blocks become dead as well. This 2689 // function is to add all these blocks to "DeadBlocks". For the dead blocks' 2690 // live successors, update their phi nodes by replacing the operands 2691 // corresponding to dead blocks with UndefVal. 2692 // 2693 void GVN::addDeadBlock(BasicBlock *BB) { 2694 SmallVector<BasicBlock *, 4> NewDead; 2695 SmallSetVector<BasicBlock *, 4> DF; 2696 2697 NewDead.push_back(BB); 2698 while (!NewDead.empty()) { 2699 BasicBlock *D = NewDead.pop_back_val(); 2700 if (DeadBlocks.count(D)) 2701 continue; 2702 2703 // All blocks dominated by D are dead. 2704 SmallVector<BasicBlock *, 8> Dom; 2705 DT->getDescendants(D, Dom); 2706 DeadBlocks.insert(Dom.begin(), Dom.end()); 2707 2708 // Figure out the dominance-frontier(D). 2709 for (SmallVectorImpl<BasicBlock *>::iterator I = Dom.begin(), 2710 E = Dom.end(); I != E; I++) { 2711 BasicBlock *B = *I; 2712 for (succ_iterator SI = succ_begin(B), SE = succ_end(B); SI != SE; SI++) { 2713 BasicBlock *S = *SI; 2714 if (DeadBlocks.count(S)) 2715 continue; 2716 2717 bool AllPredDead = true; 2718 for (pred_iterator PI = pred_begin(S), PE = pred_end(S); PI != PE; PI++) 2719 if (!DeadBlocks.count(*PI)) { 2720 AllPredDead = false; 2721 break; 2722 } 2723 2724 if (!AllPredDead) { 2725 // S could be proved dead later on. That is why we don't update phi 2726 // operands at this moment. 2727 DF.insert(S); 2728 } else { 2729 // While S is not dominated by D, it is dead by now. This could take 2730 // place if S already have a dead predecessor before D is declared 2731 // dead. 2732 NewDead.push_back(S); 2733 } 2734 } 2735 } 2736 } 2737 2738 // For the dead blocks' live successors, update their phi nodes by replacing 2739 // the operands corresponding to dead blocks with UndefVal. 2740 for(SmallSetVector<BasicBlock *, 4>::iterator I = DF.begin(), E = DF.end(); 2741 I != E; I++) { 2742 BasicBlock *B = *I; 2743 if (DeadBlocks.count(B)) 2744 continue; 2745 2746 SmallVector<BasicBlock *, 4> Preds(pred_begin(B), pred_end(B)); 2747 for (SmallVectorImpl<BasicBlock *>::iterator PI = Preds.begin(), 2748 PE = Preds.end(); PI != PE; PI++) { 2749 BasicBlock *P = *PI; 2750 2751 if (!DeadBlocks.count(P)) 2752 continue; 2753 2754 if (isCriticalEdge(P->getTerminator(), GetSuccessorNumber(P, B))) { 2755 if (BasicBlock *S = splitCriticalEdges(P, B)) 2756 DeadBlocks.insert(P = S); 2757 } 2758 2759 for (BasicBlock::iterator II = B->begin(); isa<PHINode>(II); ++II) { 2760 PHINode &Phi = cast<PHINode>(*II); 2761 Phi.setIncomingValue(Phi.getBasicBlockIndex(P), 2762 UndefValue::get(Phi.getType())); 2763 } 2764 } 2765 } 2766 } 2767 2768 // If the given branch is recognized as a foldable branch (i.e. conditional 2769 // branch with constant condition), it will perform following analyses and 2770 // transformation. 2771 // 1) If the dead out-coming edge is a critical-edge, split it. Let 2772 // R be the target of the dead out-coming edge. 2773 // 1) Identify the set of dead blocks implied by the branch's dead outcoming 2774 // edge. The result of this step will be {X| X is dominated by R} 2775 // 2) Identify those blocks which haves at least one dead prodecessor. The 2776 // result of this step will be dominance-frontier(R). 2777 // 3) Update the PHIs in DF(R) by replacing the operands corresponding to 2778 // dead blocks with "UndefVal" in an hope these PHIs will optimized away. 2779 // 2780 // Return true iff *NEW* dead code are found. 2781 bool GVN::processFoldableCondBr(BranchInst *BI) { 2782 if (!BI || BI->isUnconditional()) 2783 return false; 2784 2785 ConstantInt *Cond = dyn_cast<ConstantInt>(BI->getCondition()); 2786 if (!Cond) 2787 return false; 2788 2789 BasicBlock *DeadRoot = Cond->getZExtValue() ? 2790 BI->getSuccessor(1) : BI->getSuccessor(0); 2791 if (DeadBlocks.count(DeadRoot)) 2792 return false; 2793 2794 if (!DeadRoot->getSinglePredecessor()) 2795 DeadRoot = splitCriticalEdges(BI->getParent(), DeadRoot); 2796 2797 addDeadBlock(DeadRoot); 2798 return true; 2799 } 2800 2801 // performPRE() will trigger assert if it comes across an instruction without 2802 // associated val-num. As it normally has far more live instructions than dead 2803 // instructions, it makes more sense just to "fabricate" a val-number for the 2804 // dead code than checking if instruction involved is dead or not. 2805 void GVN::assignValNumForDeadCode() { 2806 for (SetVector<BasicBlock *>::iterator I = DeadBlocks.begin(), 2807 E = DeadBlocks.end(); I != E; I++) { 2808 BasicBlock *BB = *I; 2809 for (BasicBlock::iterator II = BB->begin(), EE = BB->end(); 2810 II != EE; II++) { 2811 Instruction *Inst = &*II; 2812 unsigned ValNum = VN.lookup_or_add(Inst); 2813 addToLeaderTable(ValNum, Inst, BB); 2814 } 2815 } 2816 } 2817