1 //===- LazyValueInfo.cpp - Value constraint analysis ------------*- C++ -*-===// 2 // 3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. 4 // See https://llvm.org/LICENSE.txt for license information. 5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception 6 // 7 //===----------------------------------------------------------------------===// 8 // 9 // This file defines the interface for lazy computation of value constraint 10 // information. 11 // 12 //===----------------------------------------------------------------------===// 13 14 #include "llvm/Analysis/LazyValueInfo.h" 15 #include "llvm/ADT/DenseSet.h" 16 #include "llvm/ADT/Optional.h" 17 #include "llvm/ADT/STLExtras.h" 18 #include "llvm/Analysis/AssumptionCache.h" 19 #include "llvm/Analysis/ConstantFolding.h" 20 #include "llvm/Analysis/InstructionSimplify.h" 21 #include "llvm/Analysis/TargetLibraryInfo.h" 22 #include "llvm/Analysis/ValueLattice.h" 23 #include "llvm/Analysis/ValueTracking.h" 24 #include "llvm/IR/AssemblyAnnotationWriter.h" 25 #include "llvm/IR/CFG.h" 26 #include "llvm/IR/ConstantRange.h" 27 #include "llvm/IR/Constants.h" 28 #include "llvm/IR/DataLayout.h" 29 #include "llvm/IR/Dominators.h" 30 #include "llvm/IR/Instructions.h" 31 #include "llvm/IR/IntrinsicInst.h" 32 #include "llvm/IR/Intrinsics.h" 33 #include "llvm/IR/LLVMContext.h" 34 #include "llvm/IR/PatternMatch.h" 35 #include "llvm/IR/ValueHandle.h" 36 #include "llvm/InitializePasses.h" 37 #include "llvm/Support/Debug.h" 38 #include "llvm/Support/FormattedStream.h" 39 #include "llvm/Support/KnownBits.h" 40 #include "llvm/Support/raw_ostream.h" 41 #include <map> 42 using namespace llvm; 43 using namespace PatternMatch; 44 45 #define DEBUG_TYPE "lazy-value-info" 46 47 // This is the number of worklist items we will process to try to discover an 48 // answer for a given value. 49 static const unsigned MaxProcessedPerValue = 500; 50 51 char LazyValueInfoWrapperPass::ID = 0; 52 LazyValueInfoWrapperPass::LazyValueInfoWrapperPass() : FunctionPass(ID) { 53 initializeLazyValueInfoWrapperPassPass(*PassRegistry::getPassRegistry()); 54 } 55 INITIALIZE_PASS_BEGIN(LazyValueInfoWrapperPass, "lazy-value-info", 56 "Lazy Value Information Analysis", false, true) 57 INITIALIZE_PASS_DEPENDENCY(AssumptionCacheTracker) 58 INITIALIZE_PASS_DEPENDENCY(TargetLibraryInfoWrapperPass) 59 INITIALIZE_PASS_END(LazyValueInfoWrapperPass, "lazy-value-info", 60 "Lazy Value Information Analysis", false, true) 61 62 namespace llvm { 63 FunctionPass *createLazyValueInfoPass() { return new LazyValueInfoWrapperPass(); } 64 } 65 66 AnalysisKey LazyValueAnalysis::Key; 67 68 /// Returns true if this lattice value represents at most one possible value. 69 /// This is as precise as any lattice value can get while still representing 70 /// reachable code. 71 static bool hasSingleValue(const ValueLatticeElement &Val) { 72 if (Val.isConstantRange() && 73 Val.getConstantRange().isSingleElement()) 74 // Integer constants are single element ranges 75 return true; 76 if (Val.isConstant()) 77 // Non integer constants 78 return true; 79 return false; 80 } 81 82 /// Combine two sets of facts about the same value into a single set of 83 /// facts. Note that this method is not suitable for merging facts along 84 /// different paths in a CFG; that's what the mergeIn function is for. This 85 /// is for merging facts gathered about the same value at the same location 86 /// through two independent means. 87 /// Notes: 88 /// * This method does not promise to return the most precise possible lattice 89 /// value implied by A and B. It is allowed to return any lattice element 90 /// which is at least as strong as *either* A or B (unless our facts 91 /// conflict, see below). 92 /// * Due to unreachable code, the intersection of two lattice values could be 93 /// contradictory. If this happens, we return some valid lattice value so as 94 /// not confuse the rest of LVI. Ideally, we'd always return Undefined, but 95 /// we do not make this guarantee. TODO: This would be a useful enhancement. 96 static ValueLatticeElement intersect(const ValueLatticeElement &A, 97 const ValueLatticeElement &B) { 98 // Undefined is the strongest state. It means the value is known to be along 99 // an unreachable path. 100 if (A.isUnknown()) 101 return A; 102 if (B.isUnknown()) 103 return B; 104 105 // If we gave up for one, but got a useable fact from the other, use it. 106 if (A.isOverdefined()) 107 return B; 108 if (B.isOverdefined()) 109 return A; 110 111 // Can't get any more precise than constants. 112 if (hasSingleValue(A)) 113 return A; 114 if (hasSingleValue(B)) 115 return B; 116 117 // Could be either constant range or not constant here. 118 if (!A.isConstantRange() || !B.isConstantRange()) { 119 // TODO: Arbitrary choice, could be improved 120 return A; 121 } 122 123 // Intersect two constant ranges 124 ConstantRange Range = 125 A.getConstantRange().intersectWith(B.getConstantRange()); 126 // Note: An empty range is implicitly converted to unknown or undef depending 127 // on MayIncludeUndef internally. 128 return ValueLatticeElement::getRange( 129 std::move(Range), /*MayIncludeUndef=*/A.isConstantRangeIncludingUndef() | 130 B.isConstantRangeIncludingUndef()); 131 } 132 133 //===----------------------------------------------------------------------===// 134 // LazyValueInfoCache Decl 135 //===----------------------------------------------------------------------===// 136 137 namespace { 138 /// A callback value handle updates the cache when values are erased. 139 class LazyValueInfoCache; 140 struct LVIValueHandle final : public CallbackVH { 141 LazyValueInfoCache *Parent; 142 143 LVIValueHandle(Value *V, LazyValueInfoCache *P = nullptr) 144 : CallbackVH(V), Parent(P) { } 145 146 void deleted() override; 147 void allUsesReplacedWith(Value *V) override { 148 deleted(); 149 } 150 }; 151 } // end anonymous namespace 152 153 namespace { 154 using NonNullPointerSet = SmallDenseSet<AssertingVH<Value>, 2>; 155 156 /// This is the cache kept by LazyValueInfo which 157 /// maintains information about queries across the clients' queries. 158 class LazyValueInfoCache { 159 /// This is all of the cached information for one basic block. It contains 160 /// the per-value lattice elements, as well as a separate set for 161 /// overdefined values to reduce memory usage. Additionally pointers 162 /// dereferenced in the block are cached for nullability queries. 163 struct BlockCacheEntry { 164 SmallDenseMap<AssertingVH<Value>, ValueLatticeElement, 4> LatticeElements; 165 SmallDenseSet<AssertingVH<Value>, 4> OverDefined; 166 // None indicates that the nonnull pointers for this basic block 167 // block have not been computed yet. 168 Optional<NonNullPointerSet> NonNullPointers; 169 }; 170 171 /// Cached information per basic block. 172 DenseMap<PoisoningVH<BasicBlock>, std::unique_ptr<BlockCacheEntry>> 173 BlockCache; 174 /// Set of value handles used to erase values from the cache on deletion. 175 DenseSet<LVIValueHandle, DenseMapInfo<Value *>> ValueHandles; 176 177 const BlockCacheEntry *getBlockEntry(BasicBlock *BB) const { 178 auto It = BlockCache.find_as(BB); 179 if (It == BlockCache.end()) 180 return nullptr; 181 return It->second.get(); 182 } 183 184 BlockCacheEntry *getOrCreateBlockEntry(BasicBlock *BB) { 185 auto It = BlockCache.find_as(BB); 186 if (It == BlockCache.end()) 187 It = BlockCache.insert({ BB, std::make_unique<BlockCacheEntry>() }) 188 .first; 189 190 return It->second.get(); 191 } 192 193 void addValueHandle(Value *Val) { 194 auto HandleIt = ValueHandles.find_as(Val); 195 if (HandleIt == ValueHandles.end()) 196 ValueHandles.insert({ Val, this }); 197 } 198 199 public: 200 void insertResult(Value *Val, BasicBlock *BB, 201 const ValueLatticeElement &Result) { 202 BlockCacheEntry *Entry = getOrCreateBlockEntry(BB); 203 204 // Insert over-defined values into their own cache to reduce memory 205 // overhead. 206 if (Result.isOverdefined()) 207 Entry->OverDefined.insert(Val); 208 else 209 Entry->LatticeElements.insert({ Val, Result }); 210 211 addValueHandle(Val); 212 } 213 214 Optional<ValueLatticeElement> getCachedValueInfo(Value *V, 215 BasicBlock *BB) const { 216 const BlockCacheEntry *Entry = getBlockEntry(BB); 217 if (!Entry) 218 return None; 219 220 if (Entry->OverDefined.count(V)) 221 return ValueLatticeElement::getOverdefined(); 222 223 auto LatticeIt = Entry->LatticeElements.find_as(V); 224 if (LatticeIt == Entry->LatticeElements.end()) 225 return None; 226 227 return LatticeIt->second; 228 } 229 230 bool isNonNullAtEndOfBlock( 231 Value *V, BasicBlock *BB, 232 function_ref<NonNullPointerSet(BasicBlock *)> InitFn) { 233 BlockCacheEntry *Entry = getOrCreateBlockEntry(BB); 234 if (!Entry->NonNullPointers) { 235 Entry->NonNullPointers = InitFn(BB); 236 for (Value *V : *Entry->NonNullPointers) 237 addValueHandle(V); 238 } 239 240 return Entry->NonNullPointers->count(V); 241 } 242 243 /// clear - Empty the cache. 244 void clear() { 245 BlockCache.clear(); 246 ValueHandles.clear(); 247 } 248 249 /// Inform the cache that a given value has been deleted. 250 void eraseValue(Value *V); 251 252 /// This is part of the update interface to inform the cache 253 /// that a block has been deleted. 254 void eraseBlock(BasicBlock *BB); 255 256 /// Updates the cache to remove any influence an overdefined value in 257 /// OldSucc might have (unless also overdefined in NewSucc). This just 258 /// flushes elements from the cache and does not add any. 259 void threadEdgeImpl(BasicBlock *OldSucc,BasicBlock *NewSucc); 260 }; 261 } 262 263 void LazyValueInfoCache::eraseValue(Value *V) { 264 for (auto &Pair : BlockCache) { 265 Pair.second->LatticeElements.erase(V); 266 Pair.second->OverDefined.erase(V); 267 if (Pair.second->NonNullPointers) 268 Pair.second->NonNullPointers->erase(V); 269 } 270 271 auto HandleIt = ValueHandles.find_as(V); 272 if (HandleIt != ValueHandles.end()) 273 ValueHandles.erase(HandleIt); 274 } 275 276 void LVIValueHandle::deleted() { 277 // This erasure deallocates *this, so it MUST happen after we're done 278 // using any and all members of *this. 279 Parent->eraseValue(*this); 280 } 281 282 void LazyValueInfoCache::eraseBlock(BasicBlock *BB) { 283 BlockCache.erase(BB); 284 } 285 286 void LazyValueInfoCache::threadEdgeImpl(BasicBlock *OldSucc, 287 BasicBlock *NewSucc) { 288 // When an edge in the graph has been threaded, values that we could not 289 // determine a value for before (i.e. were marked overdefined) may be 290 // possible to solve now. We do NOT try to proactively update these values. 291 // Instead, we clear their entries from the cache, and allow lazy updating to 292 // recompute them when needed. 293 294 // The updating process is fairly simple: we need to drop cached info 295 // for all values that were marked overdefined in OldSucc, and for those same 296 // values in any successor of OldSucc (except NewSucc) in which they were 297 // also marked overdefined. 298 std::vector<BasicBlock*> worklist; 299 worklist.push_back(OldSucc); 300 301 const BlockCacheEntry *Entry = getBlockEntry(OldSucc); 302 if (!Entry || Entry->OverDefined.empty()) 303 return; // Nothing to process here. 304 SmallVector<Value *, 4> ValsToClear(Entry->OverDefined.begin(), 305 Entry->OverDefined.end()); 306 307 // Use a worklist to perform a depth-first search of OldSucc's successors. 308 // NOTE: We do not need a visited list since any blocks we have already 309 // visited will have had their overdefined markers cleared already, and we 310 // thus won't loop to their successors. 311 while (!worklist.empty()) { 312 BasicBlock *ToUpdate = worklist.back(); 313 worklist.pop_back(); 314 315 // Skip blocks only accessible through NewSucc. 316 if (ToUpdate == NewSucc) continue; 317 318 // If a value was marked overdefined in OldSucc, and is here too... 319 auto OI = BlockCache.find_as(ToUpdate); 320 if (OI == BlockCache.end() || OI->second->OverDefined.empty()) 321 continue; 322 auto &ValueSet = OI->second->OverDefined; 323 324 bool changed = false; 325 for (Value *V : ValsToClear) { 326 if (!ValueSet.erase(V)) 327 continue; 328 329 // If we removed anything, then we potentially need to update 330 // blocks successors too. 331 changed = true; 332 } 333 334 if (!changed) continue; 335 336 worklist.insert(worklist.end(), succ_begin(ToUpdate), succ_end(ToUpdate)); 337 } 338 } 339 340 341 namespace { 342 /// An assembly annotator class to print LazyValueCache information in 343 /// comments. 344 class LazyValueInfoImpl; 345 class LazyValueInfoAnnotatedWriter : public AssemblyAnnotationWriter { 346 LazyValueInfoImpl *LVIImpl; 347 // While analyzing which blocks we can solve values for, we need the dominator 348 // information. 349 DominatorTree &DT; 350 351 public: 352 LazyValueInfoAnnotatedWriter(LazyValueInfoImpl *L, DominatorTree &DTree) 353 : LVIImpl(L), DT(DTree) {} 354 355 void emitBasicBlockStartAnnot(const BasicBlock *BB, 356 formatted_raw_ostream &OS) override; 357 358 void emitInstructionAnnot(const Instruction *I, 359 formatted_raw_ostream &OS) override; 360 }; 361 } 362 namespace { 363 // The actual implementation of the lazy analysis and update. Note that the 364 // inheritance from LazyValueInfoCache is intended to be temporary while 365 // splitting the code and then transitioning to a has-a relationship. 366 class LazyValueInfoImpl { 367 368 /// Cached results from previous queries 369 LazyValueInfoCache TheCache; 370 371 /// This stack holds the state of the value solver during a query. 372 /// It basically emulates the callstack of the naive 373 /// recursive value lookup process. 374 SmallVector<std::pair<BasicBlock*, Value*>, 8> BlockValueStack; 375 376 /// Keeps track of which block-value pairs are in BlockValueStack. 377 DenseSet<std::pair<BasicBlock*, Value*> > BlockValueSet; 378 379 /// Push BV onto BlockValueStack unless it's already in there. 380 /// Returns true on success. 381 bool pushBlockValue(const std::pair<BasicBlock *, Value *> &BV) { 382 if (!BlockValueSet.insert(BV).second) 383 return false; // It's already in the stack. 384 385 LLVM_DEBUG(dbgs() << "PUSH: " << *BV.second << " in " 386 << BV.first->getName() << "\n"); 387 BlockValueStack.push_back(BV); 388 return true; 389 } 390 391 AssumptionCache *AC; ///< A pointer to the cache of @llvm.assume calls. 392 const DataLayout &DL; ///< A mandatory DataLayout 393 394 /// Declaration of the llvm.experimental.guard() intrinsic, 395 /// if it exists in the module. 396 Function *GuardDecl; 397 398 Optional<ValueLatticeElement> getBlockValue(Value *Val, BasicBlock *BB); 399 Optional<ValueLatticeElement> getEdgeValue(Value *V, BasicBlock *F, 400 BasicBlock *T, Instruction *CxtI = nullptr); 401 402 // These methods process one work item and may add more. A false value 403 // returned means that the work item was not completely processed and must 404 // be revisited after going through the new items. 405 bool solveBlockValue(Value *Val, BasicBlock *BB); 406 Optional<ValueLatticeElement> solveBlockValueImpl(Value *Val, BasicBlock *BB); 407 Optional<ValueLatticeElement> solveBlockValueNonLocal(Value *Val, 408 BasicBlock *BB); 409 Optional<ValueLatticeElement> solveBlockValuePHINode(PHINode *PN, 410 BasicBlock *BB); 411 Optional<ValueLatticeElement> solveBlockValueSelect(SelectInst *S, 412 BasicBlock *BB); 413 Optional<ConstantRange> getRangeFor(Value *V, Instruction *CxtI, 414 BasicBlock *BB); 415 Optional<ValueLatticeElement> solveBlockValueBinaryOpImpl( 416 Instruction *I, BasicBlock *BB, 417 std::function<ConstantRange(const ConstantRange &, 418 const ConstantRange &)> OpFn); 419 Optional<ValueLatticeElement> solveBlockValueBinaryOp(BinaryOperator *BBI, 420 BasicBlock *BB); 421 Optional<ValueLatticeElement> solveBlockValueCast(CastInst *CI, 422 BasicBlock *BB); 423 Optional<ValueLatticeElement> solveBlockValueOverflowIntrinsic( 424 WithOverflowInst *WO, BasicBlock *BB); 425 Optional<ValueLatticeElement> solveBlockValueIntrinsic(IntrinsicInst *II, 426 BasicBlock *BB); 427 Optional<ValueLatticeElement> solveBlockValueExtractValue( 428 ExtractValueInst *EVI, BasicBlock *BB); 429 bool isNonNullAtEndOfBlock(Value *Val, BasicBlock *BB); 430 void intersectAssumeOrGuardBlockValueConstantRange(Value *Val, 431 ValueLatticeElement &BBLV, 432 Instruction *BBI); 433 434 void solve(); 435 436 public: 437 /// This is the query interface to determine the lattice 438 /// value for the specified Value* at the end of the specified block. 439 ValueLatticeElement getValueInBlock(Value *V, BasicBlock *BB, 440 Instruction *CxtI = nullptr); 441 442 /// This is the query interface to determine the lattice 443 /// value for the specified Value* at the specified instruction (generally 444 /// from an assume intrinsic). 445 ValueLatticeElement getValueAt(Value *V, Instruction *CxtI); 446 447 /// This is the query interface to determine the lattice 448 /// value for the specified Value* that is true on the specified edge. 449 ValueLatticeElement getValueOnEdge(Value *V, BasicBlock *FromBB, 450 BasicBlock *ToBB, 451 Instruction *CxtI = nullptr); 452 453 /// Complete flush all previously computed values 454 void clear() { 455 TheCache.clear(); 456 } 457 458 /// Printing the LazyValueInfo Analysis. 459 void printLVI(Function &F, DominatorTree &DTree, raw_ostream &OS) { 460 LazyValueInfoAnnotatedWriter Writer(this, DTree); 461 F.print(OS, &Writer); 462 } 463 464 /// This is part of the update interface to inform the cache 465 /// that a block has been deleted. 466 void eraseBlock(BasicBlock *BB) { 467 TheCache.eraseBlock(BB); 468 } 469 470 /// This is the update interface to inform the cache that an edge from 471 /// PredBB to OldSucc has been threaded to be from PredBB to NewSucc. 472 void threadEdge(BasicBlock *PredBB,BasicBlock *OldSucc,BasicBlock *NewSucc); 473 474 LazyValueInfoImpl(AssumptionCache *AC, const DataLayout &DL, 475 Function *GuardDecl) 476 : AC(AC), DL(DL), GuardDecl(GuardDecl) {} 477 }; 478 } // end anonymous namespace 479 480 481 void LazyValueInfoImpl::solve() { 482 SmallVector<std::pair<BasicBlock *, Value *>, 8> StartingStack( 483 BlockValueStack.begin(), BlockValueStack.end()); 484 485 unsigned processedCount = 0; 486 while (!BlockValueStack.empty()) { 487 processedCount++; 488 // Abort if we have to process too many values to get a result for this one. 489 // Because of the design of the overdefined cache currently being per-block 490 // to avoid naming-related issues (IE it wants to try to give different 491 // results for the same name in different blocks), overdefined results don't 492 // get cached globally, which in turn means we will often try to rediscover 493 // the same overdefined result again and again. Once something like 494 // PredicateInfo is used in LVI or CVP, we should be able to make the 495 // overdefined cache global, and remove this throttle. 496 if (processedCount > MaxProcessedPerValue) { 497 LLVM_DEBUG( 498 dbgs() << "Giving up on stack because we are getting too deep\n"); 499 // Fill in the original values 500 while (!StartingStack.empty()) { 501 std::pair<BasicBlock *, Value *> &e = StartingStack.back(); 502 TheCache.insertResult(e.second, e.first, 503 ValueLatticeElement::getOverdefined()); 504 StartingStack.pop_back(); 505 } 506 BlockValueSet.clear(); 507 BlockValueStack.clear(); 508 return; 509 } 510 std::pair<BasicBlock *, Value *> e = BlockValueStack.back(); 511 assert(BlockValueSet.count(e) && "Stack value should be in BlockValueSet!"); 512 513 if (solveBlockValue(e.second, e.first)) { 514 // The work item was completely processed. 515 assert(BlockValueStack.back() == e && "Nothing should have been pushed!"); 516 #ifndef NDEBUG 517 Optional<ValueLatticeElement> BBLV = 518 TheCache.getCachedValueInfo(e.second, e.first); 519 assert(BBLV && "Result should be in cache!"); 520 LLVM_DEBUG( 521 dbgs() << "POP " << *e.second << " in " << e.first->getName() << " = " 522 << *BBLV << "\n"); 523 #endif 524 525 BlockValueStack.pop_back(); 526 BlockValueSet.erase(e); 527 } else { 528 // More work needs to be done before revisiting. 529 assert(BlockValueStack.back() != e && "Stack should have been pushed!"); 530 } 531 } 532 } 533 534 Optional<ValueLatticeElement> LazyValueInfoImpl::getBlockValue(Value *Val, 535 BasicBlock *BB) { 536 // If already a constant, there is nothing to compute. 537 if (Constant *VC = dyn_cast<Constant>(Val)) 538 return ValueLatticeElement::get(VC); 539 540 if (Optional<ValueLatticeElement> OptLatticeVal = 541 TheCache.getCachedValueInfo(Val, BB)) 542 return OptLatticeVal; 543 544 // We have hit a cycle, assume overdefined. 545 if (!pushBlockValue({ BB, Val })) 546 return ValueLatticeElement::getOverdefined(); 547 548 // Yet to be resolved. 549 return None; 550 } 551 552 static ValueLatticeElement getFromRangeMetadata(Instruction *BBI) { 553 switch (BBI->getOpcode()) { 554 default: break; 555 case Instruction::Load: 556 case Instruction::Call: 557 case Instruction::Invoke: 558 if (MDNode *Ranges = BBI->getMetadata(LLVMContext::MD_range)) 559 if (isa<IntegerType>(BBI->getType())) { 560 return ValueLatticeElement::getRange( 561 getConstantRangeFromMetadata(*Ranges)); 562 } 563 break; 564 }; 565 // Nothing known - will be intersected with other facts 566 return ValueLatticeElement::getOverdefined(); 567 } 568 569 bool LazyValueInfoImpl::solveBlockValue(Value *Val, BasicBlock *BB) { 570 assert(!isa<Constant>(Val) && "Value should not be constant"); 571 assert(!TheCache.getCachedValueInfo(Val, BB) && 572 "Value should not be in cache"); 573 574 // Hold off inserting this value into the Cache in case we have to return 575 // false and come back later. 576 Optional<ValueLatticeElement> Res = solveBlockValueImpl(Val, BB); 577 if (!Res) 578 // Work pushed, will revisit 579 return false; 580 581 TheCache.insertResult(Val, BB, *Res); 582 return true; 583 } 584 585 Optional<ValueLatticeElement> LazyValueInfoImpl::solveBlockValueImpl( 586 Value *Val, BasicBlock *BB) { 587 Instruction *BBI = dyn_cast<Instruction>(Val); 588 if (!BBI || BBI->getParent() != BB) 589 return solveBlockValueNonLocal(Val, BB); 590 591 if (PHINode *PN = dyn_cast<PHINode>(BBI)) 592 return solveBlockValuePHINode(PN, BB); 593 594 if (auto *SI = dyn_cast<SelectInst>(BBI)) 595 return solveBlockValueSelect(SI, BB); 596 597 // If this value is a nonnull pointer, record it's range and bailout. Note 598 // that for all other pointer typed values, we terminate the search at the 599 // definition. We could easily extend this to look through geps, bitcasts, 600 // and the like to prove non-nullness, but it's not clear that's worth it 601 // compile time wise. The context-insensitive value walk done inside 602 // isKnownNonZero gets most of the profitable cases at much less expense. 603 // This does mean that we have a sensitivity to where the defining 604 // instruction is placed, even if it could legally be hoisted much higher. 605 // That is unfortunate. 606 PointerType *PT = dyn_cast<PointerType>(BBI->getType()); 607 if (PT && isKnownNonZero(BBI, DL)) 608 return ValueLatticeElement::getNot(ConstantPointerNull::get(PT)); 609 610 if (BBI->getType()->isIntegerTy()) { 611 if (auto *CI = dyn_cast<CastInst>(BBI)) 612 return solveBlockValueCast(CI, BB); 613 614 if (BinaryOperator *BO = dyn_cast<BinaryOperator>(BBI)) 615 return solveBlockValueBinaryOp(BO, BB); 616 617 if (auto *EVI = dyn_cast<ExtractValueInst>(BBI)) 618 return solveBlockValueExtractValue(EVI, BB); 619 620 if (auto *II = dyn_cast<IntrinsicInst>(BBI)) 621 return solveBlockValueIntrinsic(II, BB); 622 } 623 624 LLVM_DEBUG(dbgs() << " compute BB '" << BB->getName() 625 << "' - unknown inst def found.\n"); 626 return getFromRangeMetadata(BBI); 627 } 628 629 static void AddNonNullPointer(Value *Ptr, NonNullPointerSet &PtrSet) { 630 // TODO: Use NullPointerIsDefined instead. 631 if (Ptr->getType()->getPointerAddressSpace() == 0) 632 PtrSet.insert(getUnderlyingObject(Ptr)); 633 } 634 635 static void AddNonNullPointersByInstruction( 636 Instruction *I, NonNullPointerSet &PtrSet) { 637 if (LoadInst *L = dyn_cast<LoadInst>(I)) { 638 AddNonNullPointer(L->getPointerOperand(), PtrSet); 639 } else if (StoreInst *S = dyn_cast<StoreInst>(I)) { 640 AddNonNullPointer(S->getPointerOperand(), PtrSet); 641 } else if (MemIntrinsic *MI = dyn_cast<MemIntrinsic>(I)) { 642 if (MI->isVolatile()) return; 643 644 // FIXME: check whether it has a valuerange that excludes zero? 645 ConstantInt *Len = dyn_cast<ConstantInt>(MI->getLength()); 646 if (!Len || Len->isZero()) return; 647 648 AddNonNullPointer(MI->getRawDest(), PtrSet); 649 if (MemTransferInst *MTI = dyn_cast<MemTransferInst>(MI)) 650 AddNonNullPointer(MTI->getRawSource(), PtrSet); 651 } 652 } 653 654 bool LazyValueInfoImpl::isNonNullAtEndOfBlock(Value *Val, BasicBlock *BB) { 655 if (NullPointerIsDefined(BB->getParent(), 656 Val->getType()->getPointerAddressSpace())) 657 return false; 658 659 Val = getUnderlyingObject(Val); 660 return TheCache.isNonNullAtEndOfBlock(Val, BB, [](BasicBlock *BB) { 661 NonNullPointerSet NonNullPointers; 662 for (Instruction &I : *BB) 663 AddNonNullPointersByInstruction(&I, NonNullPointers); 664 return NonNullPointers; 665 }); 666 } 667 668 Optional<ValueLatticeElement> LazyValueInfoImpl::solveBlockValueNonLocal( 669 Value *Val, BasicBlock *BB) { 670 ValueLatticeElement Result; // Start Undefined. 671 672 // If this is the entry block, we must be asking about an argument. The 673 // value is overdefined. 674 if (BB == &BB->getParent()->getEntryBlock()) { 675 assert(isa<Argument>(Val) && "Unknown live-in to the entry block"); 676 return ValueLatticeElement::getOverdefined(); 677 } 678 679 // Loop over all of our predecessors, merging what we know from them into 680 // result. If we encounter an unexplored predecessor, we eagerly explore it 681 // in a depth first manner. In practice, this has the effect of discovering 682 // paths we can't analyze eagerly without spending compile times analyzing 683 // other paths. This heuristic benefits from the fact that predecessors are 684 // frequently arranged such that dominating ones come first and we quickly 685 // find a path to function entry. TODO: We should consider explicitly 686 // canonicalizing to make this true rather than relying on this happy 687 // accident. 688 for (pred_iterator PI = pred_begin(BB), E = pred_end(BB); PI != E; ++PI) { 689 Optional<ValueLatticeElement> EdgeResult = getEdgeValue(Val, *PI, BB); 690 if (!EdgeResult) 691 // Explore that input, then return here 692 return None; 693 694 Result.mergeIn(*EdgeResult); 695 696 // If we hit overdefined, exit early. The BlockVals entry is already set 697 // to overdefined. 698 if (Result.isOverdefined()) { 699 LLVM_DEBUG(dbgs() << " compute BB '" << BB->getName() 700 << "' - overdefined because of pred (non local).\n"); 701 return Result; 702 } 703 } 704 705 // Return the merged value, which is more precise than 'overdefined'. 706 assert(!Result.isOverdefined()); 707 return Result; 708 } 709 710 Optional<ValueLatticeElement> LazyValueInfoImpl::solveBlockValuePHINode( 711 PHINode *PN, BasicBlock *BB) { 712 ValueLatticeElement Result; // Start Undefined. 713 714 // Loop over all of our predecessors, merging what we know from them into 715 // result. See the comment about the chosen traversal order in 716 // solveBlockValueNonLocal; the same reasoning applies here. 717 for (unsigned i = 0, e = PN->getNumIncomingValues(); i != e; ++i) { 718 BasicBlock *PhiBB = PN->getIncomingBlock(i); 719 Value *PhiVal = PN->getIncomingValue(i); 720 // Note that we can provide PN as the context value to getEdgeValue, even 721 // though the results will be cached, because PN is the value being used as 722 // the cache key in the caller. 723 Optional<ValueLatticeElement> EdgeResult = 724 getEdgeValue(PhiVal, PhiBB, BB, PN); 725 if (!EdgeResult) 726 // Explore that input, then return here 727 return None; 728 729 Result.mergeIn(*EdgeResult); 730 731 // If we hit overdefined, exit early. The BlockVals entry is already set 732 // to overdefined. 733 if (Result.isOverdefined()) { 734 LLVM_DEBUG(dbgs() << " compute BB '" << BB->getName() 735 << "' - overdefined because of pred (local).\n"); 736 737 return Result; 738 } 739 } 740 741 // Return the merged value, which is more precise than 'overdefined'. 742 assert(!Result.isOverdefined() && "Possible PHI in entry block?"); 743 return Result; 744 } 745 746 static ValueLatticeElement getValueFromCondition(Value *Val, Value *Cond, 747 bool isTrueDest = true); 748 749 // If we can determine a constraint on the value given conditions assumed by 750 // the program, intersect those constraints with BBLV 751 void LazyValueInfoImpl::intersectAssumeOrGuardBlockValueConstantRange( 752 Value *Val, ValueLatticeElement &BBLV, Instruction *BBI) { 753 BBI = BBI ? BBI : dyn_cast<Instruction>(Val); 754 if (!BBI) 755 return; 756 757 BasicBlock *BB = BBI->getParent(); 758 for (auto &AssumeVH : AC->assumptionsFor(Val)) { 759 if (!AssumeVH) 760 continue; 761 762 // Only check assumes in the block of the context instruction. Other 763 // assumes will have already been taken into account when the value was 764 // propagated from predecessor blocks. 765 auto *I = cast<CallInst>(AssumeVH); 766 if (I->getParent() != BB || !isValidAssumeForContext(I, BBI)) 767 continue; 768 769 BBLV = intersect(BBLV, getValueFromCondition(Val, I->getArgOperand(0))); 770 } 771 772 // If guards are not used in the module, don't spend time looking for them 773 if (GuardDecl && !GuardDecl->use_empty() && 774 BBI->getIterator() != BB->begin()) { 775 for (Instruction &I : make_range(std::next(BBI->getIterator().getReverse()), 776 BB->rend())) { 777 Value *Cond = nullptr; 778 if (match(&I, m_Intrinsic<Intrinsic::experimental_guard>(m_Value(Cond)))) 779 BBLV = intersect(BBLV, getValueFromCondition(Val, Cond)); 780 } 781 } 782 783 if (BBLV.isOverdefined()) { 784 // Check whether we're checking at the terminator, and the pointer has 785 // been dereferenced in this block. 786 PointerType *PTy = dyn_cast<PointerType>(Val->getType()); 787 if (PTy && BB->getTerminator() == BBI && 788 isNonNullAtEndOfBlock(Val, BB)) 789 BBLV = ValueLatticeElement::getNot(ConstantPointerNull::get(PTy)); 790 } 791 } 792 793 Optional<ValueLatticeElement> LazyValueInfoImpl::solveBlockValueSelect( 794 SelectInst *SI, BasicBlock *BB) { 795 // Recurse on our inputs if needed 796 Optional<ValueLatticeElement> OptTrueVal = 797 getBlockValue(SI->getTrueValue(), BB); 798 if (!OptTrueVal) 799 return None; 800 ValueLatticeElement &TrueVal = *OptTrueVal; 801 802 // If we hit overdefined, don't ask more queries. We want to avoid poisoning 803 // extra slots in the table if we can. 804 if (TrueVal.isOverdefined()) 805 return ValueLatticeElement::getOverdefined(); 806 807 Optional<ValueLatticeElement> OptFalseVal = 808 getBlockValue(SI->getFalseValue(), BB); 809 if (!OptFalseVal) 810 return None; 811 ValueLatticeElement &FalseVal = *OptFalseVal; 812 813 // If we hit overdefined, don't ask more queries. We want to avoid poisoning 814 // extra slots in the table if we can. 815 if (FalseVal.isOverdefined()) 816 return ValueLatticeElement::getOverdefined(); 817 818 if (TrueVal.isConstantRange() && FalseVal.isConstantRange()) { 819 const ConstantRange &TrueCR = TrueVal.getConstantRange(); 820 const ConstantRange &FalseCR = FalseVal.getConstantRange(); 821 Value *LHS = nullptr; 822 Value *RHS = nullptr; 823 SelectPatternResult SPR = matchSelectPattern(SI, LHS, RHS); 824 // Is this a min specifically of our two inputs? (Avoid the risk of 825 // ValueTracking getting smarter looking back past our immediate inputs.) 826 if (SelectPatternResult::isMinOrMax(SPR.Flavor) && 827 LHS == SI->getTrueValue() && RHS == SI->getFalseValue()) { 828 ConstantRange ResultCR = [&]() { 829 switch (SPR.Flavor) { 830 default: 831 llvm_unreachable("unexpected minmax type!"); 832 case SPF_SMIN: /// Signed minimum 833 return TrueCR.smin(FalseCR); 834 case SPF_UMIN: /// Unsigned minimum 835 return TrueCR.umin(FalseCR); 836 case SPF_SMAX: /// Signed maximum 837 return TrueCR.smax(FalseCR); 838 case SPF_UMAX: /// Unsigned maximum 839 return TrueCR.umax(FalseCR); 840 }; 841 }(); 842 return ValueLatticeElement::getRange( 843 ResultCR, TrueVal.isConstantRangeIncludingUndef() | 844 FalseVal.isConstantRangeIncludingUndef()); 845 } 846 847 if (SPR.Flavor == SPF_ABS) { 848 if (LHS == SI->getTrueValue()) 849 return ValueLatticeElement::getRange( 850 TrueCR.abs(), TrueVal.isConstantRangeIncludingUndef()); 851 if (LHS == SI->getFalseValue()) 852 return ValueLatticeElement::getRange( 853 FalseCR.abs(), FalseVal.isConstantRangeIncludingUndef()); 854 } 855 856 if (SPR.Flavor == SPF_NABS) { 857 ConstantRange Zero(APInt::getNullValue(TrueCR.getBitWidth())); 858 if (LHS == SI->getTrueValue()) 859 return ValueLatticeElement::getRange( 860 Zero.sub(TrueCR.abs()), FalseVal.isConstantRangeIncludingUndef()); 861 if (LHS == SI->getFalseValue()) 862 return ValueLatticeElement::getRange( 863 Zero.sub(FalseCR.abs()), FalseVal.isConstantRangeIncludingUndef()); 864 } 865 } 866 867 // Can we constrain the facts about the true and false values by using the 868 // condition itself? This shows up with idioms like e.g. select(a > 5, a, 5). 869 // TODO: We could potentially refine an overdefined true value above. 870 Value *Cond = SI->getCondition(); 871 TrueVal = intersect(TrueVal, 872 getValueFromCondition(SI->getTrueValue(), Cond, true)); 873 FalseVal = intersect(FalseVal, 874 getValueFromCondition(SI->getFalseValue(), Cond, false)); 875 876 // Handle clamp idioms such as: 877 // %24 = constantrange<0, 17> 878 // %39 = icmp eq i32 %24, 0 879 // %40 = add i32 %24, -1 880 // %siv.next = select i1 %39, i32 16, i32 %40 881 // %siv.next = constantrange<0, 17> not <-1, 17> 882 // In general, this can handle any clamp idiom which tests the edge 883 // condition via an equality or inequality. 884 if (auto *ICI = dyn_cast<ICmpInst>(Cond)) { 885 ICmpInst::Predicate Pred = ICI->getPredicate(); 886 Value *A = ICI->getOperand(0); 887 if (ConstantInt *CIBase = dyn_cast<ConstantInt>(ICI->getOperand(1))) { 888 auto addConstants = [](ConstantInt *A, ConstantInt *B) { 889 assert(A->getType() == B->getType()); 890 return ConstantInt::get(A->getType(), A->getValue() + B->getValue()); 891 }; 892 // See if either input is A + C2, subject to the constraint from the 893 // condition that A != C when that input is used. We can assume that 894 // that input doesn't include C + C2. 895 ConstantInt *CIAdded; 896 switch (Pred) { 897 default: break; 898 case ICmpInst::ICMP_EQ: 899 if (match(SI->getFalseValue(), m_Add(m_Specific(A), 900 m_ConstantInt(CIAdded)))) { 901 auto ResNot = addConstants(CIBase, CIAdded); 902 FalseVal = intersect(FalseVal, 903 ValueLatticeElement::getNot(ResNot)); 904 } 905 break; 906 case ICmpInst::ICMP_NE: 907 if (match(SI->getTrueValue(), m_Add(m_Specific(A), 908 m_ConstantInt(CIAdded)))) { 909 auto ResNot = addConstants(CIBase, CIAdded); 910 TrueVal = intersect(TrueVal, 911 ValueLatticeElement::getNot(ResNot)); 912 } 913 break; 914 }; 915 } 916 } 917 918 ValueLatticeElement Result = TrueVal; 919 Result.mergeIn(FalseVal); 920 return Result; 921 } 922 923 Optional<ConstantRange> LazyValueInfoImpl::getRangeFor(Value *V, 924 Instruction *CxtI, 925 BasicBlock *BB) { 926 Optional<ValueLatticeElement> OptVal = getBlockValue(V, BB); 927 if (!OptVal) 928 return None; 929 930 ValueLatticeElement &Val = *OptVal; 931 intersectAssumeOrGuardBlockValueConstantRange(V, Val, CxtI); 932 if (Val.isConstantRange()) 933 return Val.getConstantRange(); 934 935 const unsigned OperandBitWidth = DL.getTypeSizeInBits(V->getType()); 936 return ConstantRange::getFull(OperandBitWidth); 937 } 938 939 Optional<ValueLatticeElement> LazyValueInfoImpl::solveBlockValueCast( 940 CastInst *CI, BasicBlock *BB) { 941 // Without knowing how wide the input is, we can't analyze it in any useful 942 // way. 943 if (!CI->getOperand(0)->getType()->isSized()) 944 return ValueLatticeElement::getOverdefined(); 945 946 // Filter out casts we don't know how to reason about before attempting to 947 // recurse on our operand. This can cut a long search short if we know we're 948 // not going to be able to get any useful information anways. 949 switch (CI->getOpcode()) { 950 case Instruction::Trunc: 951 case Instruction::SExt: 952 case Instruction::ZExt: 953 case Instruction::BitCast: 954 break; 955 default: 956 // Unhandled instructions are overdefined. 957 LLVM_DEBUG(dbgs() << " compute BB '" << BB->getName() 958 << "' - overdefined (unknown cast).\n"); 959 return ValueLatticeElement::getOverdefined(); 960 } 961 962 // Figure out the range of the LHS. If that fails, we still apply the 963 // transfer rule on the full set since we may be able to locally infer 964 // interesting facts. 965 Optional<ConstantRange> LHSRes = getRangeFor(CI->getOperand(0), CI, BB); 966 if (!LHSRes.hasValue()) 967 // More work to do before applying this transfer rule. 968 return None; 969 const ConstantRange &LHSRange = LHSRes.getValue(); 970 971 const unsigned ResultBitWidth = CI->getType()->getIntegerBitWidth(); 972 973 // NOTE: We're currently limited by the set of operations that ConstantRange 974 // can evaluate symbolically. Enhancing that set will allows us to analyze 975 // more definitions. 976 return ValueLatticeElement::getRange(LHSRange.castOp(CI->getOpcode(), 977 ResultBitWidth)); 978 } 979 980 Optional<ValueLatticeElement> LazyValueInfoImpl::solveBlockValueBinaryOpImpl( 981 Instruction *I, BasicBlock *BB, 982 std::function<ConstantRange(const ConstantRange &, 983 const ConstantRange &)> OpFn) { 984 // Figure out the ranges of the operands. If that fails, use a 985 // conservative range, but apply the transfer rule anyways. This 986 // lets us pick up facts from expressions like "and i32 (call i32 987 // @foo()), 32" 988 Optional<ConstantRange> LHSRes = getRangeFor(I->getOperand(0), I, BB); 989 Optional<ConstantRange> RHSRes = getRangeFor(I->getOperand(1), I, BB); 990 if (!LHSRes.hasValue() || !RHSRes.hasValue()) 991 // More work to do before applying this transfer rule. 992 return None; 993 994 const ConstantRange &LHSRange = LHSRes.getValue(); 995 const ConstantRange &RHSRange = RHSRes.getValue(); 996 return ValueLatticeElement::getRange(OpFn(LHSRange, RHSRange)); 997 } 998 999 Optional<ValueLatticeElement> LazyValueInfoImpl::solveBlockValueBinaryOp( 1000 BinaryOperator *BO, BasicBlock *BB) { 1001 assert(BO->getOperand(0)->getType()->isSized() && 1002 "all operands to binary operators are sized"); 1003 if (BO->getOpcode() == Instruction::Xor) { 1004 // Xor is the only operation not supported by ConstantRange::binaryOp(). 1005 LLVM_DEBUG(dbgs() << " compute BB '" << BB->getName() 1006 << "' - overdefined (unknown binary operator).\n"); 1007 return ValueLatticeElement::getOverdefined(); 1008 } 1009 1010 if (auto *OBO = dyn_cast<OverflowingBinaryOperator>(BO)) { 1011 unsigned NoWrapKind = 0; 1012 if (OBO->hasNoUnsignedWrap()) 1013 NoWrapKind |= OverflowingBinaryOperator::NoUnsignedWrap; 1014 if (OBO->hasNoSignedWrap()) 1015 NoWrapKind |= OverflowingBinaryOperator::NoSignedWrap; 1016 1017 return solveBlockValueBinaryOpImpl( 1018 BO, BB, 1019 [BO, NoWrapKind](const ConstantRange &CR1, const ConstantRange &CR2) { 1020 return CR1.overflowingBinaryOp(BO->getOpcode(), CR2, NoWrapKind); 1021 }); 1022 } 1023 1024 return solveBlockValueBinaryOpImpl( 1025 BO, BB, [BO](const ConstantRange &CR1, const ConstantRange &CR2) { 1026 return CR1.binaryOp(BO->getOpcode(), CR2); 1027 }); 1028 } 1029 1030 Optional<ValueLatticeElement> 1031 LazyValueInfoImpl::solveBlockValueOverflowIntrinsic(WithOverflowInst *WO, 1032 BasicBlock *BB) { 1033 return solveBlockValueBinaryOpImpl( 1034 WO, BB, [WO](const ConstantRange &CR1, const ConstantRange &CR2) { 1035 return CR1.binaryOp(WO->getBinaryOp(), CR2); 1036 }); 1037 } 1038 1039 Optional<ValueLatticeElement> LazyValueInfoImpl::solveBlockValueIntrinsic( 1040 IntrinsicInst *II, BasicBlock *BB) { 1041 if (!ConstantRange::isIntrinsicSupported(II->getIntrinsicID())) { 1042 LLVM_DEBUG(dbgs() << " compute BB '" << BB->getName() 1043 << "' - overdefined (unknown intrinsic).\n"); 1044 return ValueLatticeElement::getOverdefined(); 1045 } 1046 1047 SmallVector<ConstantRange, 2> OpRanges; 1048 for (Value *Op : II->args()) { 1049 Optional<ConstantRange> Range = getRangeFor(Op, II, BB); 1050 if (!Range) 1051 return None; 1052 OpRanges.push_back(*Range); 1053 } 1054 1055 return ValueLatticeElement::getRange( 1056 ConstantRange::intrinsic(II->getIntrinsicID(), OpRanges)); 1057 } 1058 1059 Optional<ValueLatticeElement> LazyValueInfoImpl::solveBlockValueExtractValue( 1060 ExtractValueInst *EVI, BasicBlock *BB) { 1061 if (auto *WO = dyn_cast<WithOverflowInst>(EVI->getAggregateOperand())) 1062 if (EVI->getNumIndices() == 1 && *EVI->idx_begin() == 0) 1063 return solveBlockValueOverflowIntrinsic(WO, BB); 1064 1065 // Handle extractvalue of insertvalue to allow further simplification 1066 // based on replaced with.overflow intrinsics. 1067 if (Value *V = SimplifyExtractValueInst( 1068 EVI->getAggregateOperand(), EVI->getIndices(), 1069 EVI->getModule()->getDataLayout())) 1070 return getBlockValue(V, BB); 1071 1072 LLVM_DEBUG(dbgs() << " compute BB '" << BB->getName() 1073 << "' - overdefined (unknown extractvalue).\n"); 1074 return ValueLatticeElement::getOverdefined(); 1075 } 1076 1077 static bool matchICmpOperand(const APInt *&Offset, Value *LHS, Value *Val, 1078 ICmpInst::Predicate Pred) { 1079 if (LHS == Val) 1080 return true; 1081 1082 // Handle range checking idiom produced by InstCombine. We will subtract the 1083 // offset from the allowed range for RHS in this case. 1084 if (match(LHS, m_Add(m_Specific(Val), m_APInt(Offset)))) 1085 return true; 1086 1087 // If (x | y) < C, then (x < C) && (y < C). 1088 if (match(LHS, m_c_Or(m_Specific(Val), m_Value())) && 1089 (Pred == ICmpInst::ICMP_ULT || Pred == ICmpInst::ICMP_ULE)) 1090 return true; 1091 1092 // If (x & y) > C, then (x > C) && (y > C). 1093 if (match(LHS, m_c_And(m_Specific(Val), m_Value())) && 1094 (Pred == ICmpInst::ICMP_UGT || Pred == ICmpInst::ICMP_UGE)) 1095 return true; 1096 1097 return false; 1098 } 1099 1100 /// Get value range for a "(Val + Offset) Pred RHS" condition. 1101 static ValueLatticeElement getValueFromSimpleICmpCondition( 1102 CmpInst::Predicate Pred, Value *RHS, const APInt *Offset) { 1103 ConstantRange RHSRange(RHS->getType()->getIntegerBitWidth(), 1104 /*isFullSet=*/true); 1105 if (ConstantInt *CI = dyn_cast<ConstantInt>(RHS)) 1106 RHSRange = ConstantRange(CI->getValue()); 1107 else if (Instruction *I = dyn_cast<Instruction>(RHS)) 1108 if (auto *Ranges = I->getMetadata(LLVMContext::MD_range)) 1109 RHSRange = getConstantRangeFromMetadata(*Ranges); 1110 1111 ConstantRange TrueValues = 1112 ConstantRange::makeAllowedICmpRegion(Pred, RHSRange); 1113 1114 if (Offset) 1115 TrueValues = TrueValues.subtract(*Offset); 1116 1117 return ValueLatticeElement::getRange(std::move(TrueValues)); 1118 } 1119 1120 static ValueLatticeElement getValueFromICmpCondition(Value *Val, ICmpInst *ICI, 1121 bool isTrueDest) { 1122 Value *LHS = ICI->getOperand(0); 1123 Value *RHS = ICI->getOperand(1); 1124 1125 // Get the predicate that must hold along the considered edge. 1126 CmpInst::Predicate EdgePred = 1127 isTrueDest ? ICI->getPredicate() : ICI->getInversePredicate(); 1128 1129 if (isa<Constant>(RHS)) { 1130 if (ICI->isEquality() && LHS == Val) { 1131 if (EdgePred == ICmpInst::ICMP_EQ) 1132 return ValueLatticeElement::get(cast<Constant>(RHS)); 1133 else if (!isa<UndefValue>(RHS)) 1134 return ValueLatticeElement::getNot(cast<Constant>(RHS)); 1135 } 1136 } 1137 1138 if (!Val->getType()->isIntegerTy()) 1139 return ValueLatticeElement::getOverdefined(); 1140 1141 const APInt *Offset = nullptr; 1142 if (matchICmpOperand(Offset, LHS, Val, EdgePred)) 1143 return getValueFromSimpleICmpCondition(EdgePred, RHS, Offset); 1144 1145 CmpInst::Predicate SwappedPred = CmpInst::getSwappedPredicate(EdgePred); 1146 if (matchICmpOperand(Offset, RHS, Val, SwappedPred)) 1147 return getValueFromSimpleICmpCondition(SwappedPred, LHS, Offset); 1148 1149 // If (Val & Mask) == C then all the masked bits are known and we can compute 1150 // a value range based on that. 1151 const APInt *Mask, *C; 1152 if (EdgePred == ICmpInst::ICMP_EQ && 1153 match(LHS, m_And(m_Specific(Val), m_APInt(Mask))) && 1154 match(RHS, m_APInt(C))) { 1155 KnownBits Known; 1156 Known.Zero = ~*C & *Mask; 1157 Known.One = *C & *Mask; 1158 return ValueLatticeElement::getRange( 1159 ConstantRange::fromKnownBits(Known, /*IsSigned*/ false)); 1160 } 1161 1162 return ValueLatticeElement::getOverdefined(); 1163 } 1164 1165 // Handle conditions of the form 1166 // extractvalue(op.with.overflow(%x, C), 1). 1167 static ValueLatticeElement getValueFromOverflowCondition( 1168 Value *Val, WithOverflowInst *WO, bool IsTrueDest) { 1169 // TODO: This only works with a constant RHS for now. We could also compute 1170 // the range of the RHS, but this doesn't fit into the current structure of 1171 // the edge value calculation. 1172 const APInt *C; 1173 if (WO->getLHS() != Val || !match(WO->getRHS(), m_APInt(C))) 1174 return ValueLatticeElement::getOverdefined(); 1175 1176 // Calculate the possible values of %x for which no overflow occurs. 1177 ConstantRange NWR = ConstantRange::makeExactNoWrapRegion( 1178 WO->getBinaryOp(), *C, WO->getNoWrapKind()); 1179 1180 // If overflow is false, %x is constrained to NWR. If overflow is true, %x is 1181 // constrained to it's inverse (all values that might cause overflow). 1182 if (IsTrueDest) 1183 NWR = NWR.inverse(); 1184 return ValueLatticeElement::getRange(NWR); 1185 } 1186 1187 static ValueLatticeElement 1188 getValueFromCondition(Value *Val, Value *Cond, bool isTrueDest, 1189 SmallDenseMap<Value*, ValueLatticeElement> &Visited); 1190 1191 static ValueLatticeElement 1192 getValueFromConditionImpl(Value *Val, Value *Cond, bool isTrueDest, 1193 SmallDenseMap<Value*, ValueLatticeElement> &Visited) { 1194 if (ICmpInst *ICI = dyn_cast<ICmpInst>(Cond)) 1195 return getValueFromICmpCondition(Val, ICI, isTrueDest); 1196 1197 if (auto *EVI = dyn_cast<ExtractValueInst>(Cond)) 1198 if (auto *WO = dyn_cast<WithOverflowInst>(EVI->getAggregateOperand())) 1199 if (EVI->getNumIndices() == 1 && *EVI->idx_begin() == 1) 1200 return getValueFromOverflowCondition(Val, WO, isTrueDest); 1201 1202 // Handle conditions in the form of (cond1 && cond2), we know that on the 1203 // true dest path both of the conditions hold. Similarly for conditions of 1204 // the form (cond1 || cond2), we know that on the false dest path neither 1205 // condition holds. 1206 BinaryOperator *BO = dyn_cast<BinaryOperator>(Cond); 1207 if (!BO || (isTrueDest && BO->getOpcode() != BinaryOperator::And) || 1208 (!isTrueDest && BO->getOpcode() != BinaryOperator::Or)) 1209 return ValueLatticeElement::getOverdefined(); 1210 1211 // Prevent infinite recursion if Cond references itself as in this example: 1212 // Cond: "%tmp4 = and i1 %tmp4, undef" 1213 // BL: "%tmp4 = and i1 %tmp4, undef" 1214 // BR: "i1 undef" 1215 Value *BL = BO->getOperand(0); 1216 Value *BR = BO->getOperand(1); 1217 if (BL == Cond || BR == Cond) 1218 return ValueLatticeElement::getOverdefined(); 1219 1220 return intersect(getValueFromCondition(Val, BL, isTrueDest, Visited), 1221 getValueFromCondition(Val, BR, isTrueDest, Visited)); 1222 } 1223 1224 static ValueLatticeElement 1225 getValueFromCondition(Value *Val, Value *Cond, bool isTrueDest, 1226 SmallDenseMap<Value*, ValueLatticeElement> &Visited) { 1227 auto I = Visited.find(Cond); 1228 if (I != Visited.end()) 1229 return I->second; 1230 1231 auto Result = getValueFromConditionImpl(Val, Cond, isTrueDest, Visited); 1232 Visited[Cond] = Result; 1233 return Result; 1234 } 1235 1236 ValueLatticeElement getValueFromCondition(Value *Val, Value *Cond, 1237 bool isTrueDest) { 1238 assert(Cond && "precondition"); 1239 SmallDenseMap<Value*, ValueLatticeElement> Visited; 1240 return getValueFromCondition(Val, Cond, isTrueDest, Visited); 1241 } 1242 1243 // Return true if Usr has Op as an operand, otherwise false. 1244 static bool usesOperand(User *Usr, Value *Op) { 1245 return find(Usr->operands(), Op) != Usr->op_end(); 1246 } 1247 1248 // Return true if the instruction type of Val is supported by 1249 // constantFoldUser(). Currently CastInst, BinaryOperator and FreezeInst only. 1250 // Call this before calling constantFoldUser() to find out if it's even worth 1251 // attempting to call it. 1252 static bool isOperationFoldable(User *Usr) { 1253 return isa<CastInst>(Usr) || isa<BinaryOperator>(Usr) || isa<FreezeInst>(Usr); 1254 } 1255 1256 // Check if Usr can be simplified to an integer constant when the value of one 1257 // of its operands Op is an integer constant OpConstVal. If so, return it as an 1258 // lattice value range with a single element or otherwise return an overdefined 1259 // lattice value. 1260 static ValueLatticeElement constantFoldUser(User *Usr, Value *Op, 1261 const APInt &OpConstVal, 1262 const DataLayout &DL) { 1263 assert(isOperationFoldable(Usr) && "Precondition"); 1264 Constant* OpConst = Constant::getIntegerValue(Op->getType(), OpConstVal); 1265 // Check if Usr can be simplified to a constant. 1266 if (auto *CI = dyn_cast<CastInst>(Usr)) { 1267 assert(CI->getOperand(0) == Op && "Operand 0 isn't Op"); 1268 if (auto *C = dyn_cast_or_null<ConstantInt>( 1269 SimplifyCastInst(CI->getOpcode(), OpConst, 1270 CI->getDestTy(), DL))) { 1271 return ValueLatticeElement::getRange(ConstantRange(C->getValue())); 1272 } 1273 } else if (auto *BO = dyn_cast<BinaryOperator>(Usr)) { 1274 bool Op0Match = BO->getOperand(0) == Op; 1275 bool Op1Match = BO->getOperand(1) == Op; 1276 assert((Op0Match || Op1Match) && 1277 "Operand 0 nor Operand 1 isn't a match"); 1278 Value *LHS = Op0Match ? OpConst : BO->getOperand(0); 1279 Value *RHS = Op1Match ? OpConst : BO->getOperand(1); 1280 if (auto *C = dyn_cast_or_null<ConstantInt>( 1281 SimplifyBinOp(BO->getOpcode(), LHS, RHS, DL))) { 1282 return ValueLatticeElement::getRange(ConstantRange(C->getValue())); 1283 } 1284 } else if (isa<FreezeInst>(Usr)) { 1285 assert(cast<FreezeInst>(Usr)->getOperand(0) == Op && "Operand 0 isn't Op"); 1286 return ValueLatticeElement::getRange(ConstantRange(OpConstVal)); 1287 } 1288 return ValueLatticeElement::getOverdefined(); 1289 } 1290 1291 /// Compute the value of Val on the edge BBFrom -> BBTo. Returns false if 1292 /// Val is not constrained on the edge. Result is unspecified if return value 1293 /// is false. 1294 static Optional<ValueLatticeElement> getEdgeValueLocal(Value *Val, 1295 BasicBlock *BBFrom, 1296 BasicBlock *BBTo) { 1297 // TODO: Handle more complex conditionals. If (v == 0 || v2 < 1) is false, we 1298 // know that v != 0. 1299 if (BranchInst *BI = dyn_cast<BranchInst>(BBFrom->getTerminator())) { 1300 // If this is a conditional branch and only one successor goes to BBTo, then 1301 // we may be able to infer something from the condition. 1302 if (BI->isConditional() && 1303 BI->getSuccessor(0) != BI->getSuccessor(1)) { 1304 bool isTrueDest = BI->getSuccessor(0) == BBTo; 1305 assert(BI->getSuccessor(!isTrueDest) == BBTo && 1306 "BBTo isn't a successor of BBFrom"); 1307 Value *Condition = BI->getCondition(); 1308 1309 // If V is the condition of the branch itself, then we know exactly what 1310 // it is. 1311 if (Condition == Val) 1312 return ValueLatticeElement::get(ConstantInt::get( 1313 Type::getInt1Ty(Val->getContext()), isTrueDest)); 1314 1315 // If the condition of the branch is an equality comparison, we may be 1316 // able to infer the value. 1317 ValueLatticeElement Result = getValueFromCondition(Val, Condition, 1318 isTrueDest); 1319 if (!Result.isOverdefined()) 1320 return Result; 1321 1322 if (User *Usr = dyn_cast<User>(Val)) { 1323 assert(Result.isOverdefined() && "Result isn't overdefined"); 1324 // Check with isOperationFoldable() first to avoid linearly iterating 1325 // over the operands unnecessarily which can be expensive for 1326 // instructions with many operands. 1327 if (isa<IntegerType>(Usr->getType()) && isOperationFoldable(Usr)) { 1328 const DataLayout &DL = BBTo->getModule()->getDataLayout(); 1329 if (usesOperand(Usr, Condition)) { 1330 // If Val has Condition as an operand and Val can be folded into a 1331 // constant with either Condition == true or Condition == false, 1332 // propagate the constant. 1333 // eg. 1334 // ; %Val is true on the edge to %then. 1335 // %Val = and i1 %Condition, true. 1336 // br %Condition, label %then, label %else 1337 APInt ConditionVal(1, isTrueDest ? 1 : 0); 1338 Result = constantFoldUser(Usr, Condition, ConditionVal, DL); 1339 } else { 1340 // If one of Val's operand has an inferred value, we may be able to 1341 // infer the value of Val. 1342 // eg. 1343 // ; %Val is 94 on the edge to %then. 1344 // %Val = add i8 %Op, 1 1345 // %Condition = icmp eq i8 %Op, 93 1346 // br i1 %Condition, label %then, label %else 1347 for (unsigned i = 0; i < Usr->getNumOperands(); ++i) { 1348 Value *Op = Usr->getOperand(i); 1349 ValueLatticeElement OpLatticeVal = 1350 getValueFromCondition(Op, Condition, isTrueDest); 1351 if (Optional<APInt> OpConst = OpLatticeVal.asConstantInteger()) { 1352 Result = constantFoldUser(Usr, Op, OpConst.getValue(), DL); 1353 break; 1354 } 1355 } 1356 } 1357 } 1358 } 1359 if (!Result.isOverdefined()) 1360 return Result; 1361 } 1362 } 1363 1364 // If the edge was formed by a switch on the value, then we may know exactly 1365 // what it is. 1366 if (SwitchInst *SI = dyn_cast<SwitchInst>(BBFrom->getTerminator())) { 1367 Value *Condition = SI->getCondition(); 1368 if (!isa<IntegerType>(Val->getType())) 1369 return None; 1370 bool ValUsesConditionAndMayBeFoldable = false; 1371 if (Condition != Val) { 1372 // Check if Val has Condition as an operand. 1373 if (User *Usr = dyn_cast<User>(Val)) 1374 ValUsesConditionAndMayBeFoldable = isOperationFoldable(Usr) && 1375 usesOperand(Usr, Condition); 1376 if (!ValUsesConditionAndMayBeFoldable) 1377 return None; 1378 } 1379 assert((Condition == Val || ValUsesConditionAndMayBeFoldable) && 1380 "Condition != Val nor Val doesn't use Condition"); 1381 1382 bool DefaultCase = SI->getDefaultDest() == BBTo; 1383 unsigned BitWidth = Val->getType()->getIntegerBitWidth(); 1384 ConstantRange EdgesVals(BitWidth, DefaultCase/*isFullSet*/); 1385 1386 for (auto Case : SI->cases()) { 1387 APInt CaseValue = Case.getCaseValue()->getValue(); 1388 ConstantRange EdgeVal(CaseValue); 1389 if (ValUsesConditionAndMayBeFoldable) { 1390 User *Usr = cast<User>(Val); 1391 const DataLayout &DL = BBTo->getModule()->getDataLayout(); 1392 ValueLatticeElement EdgeLatticeVal = 1393 constantFoldUser(Usr, Condition, CaseValue, DL); 1394 if (EdgeLatticeVal.isOverdefined()) 1395 return None; 1396 EdgeVal = EdgeLatticeVal.getConstantRange(); 1397 } 1398 if (DefaultCase) { 1399 // It is possible that the default destination is the destination of 1400 // some cases. We cannot perform difference for those cases. 1401 // We know Condition != CaseValue in BBTo. In some cases we can use 1402 // this to infer Val == f(Condition) is != f(CaseValue). For now, we 1403 // only do this when f is identity (i.e. Val == Condition), but we 1404 // should be able to do this for any injective f. 1405 if (Case.getCaseSuccessor() != BBTo && Condition == Val) 1406 EdgesVals = EdgesVals.difference(EdgeVal); 1407 } else if (Case.getCaseSuccessor() == BBTo) 1408 EdgesVals = EdgesVals.unionWith(EdgeVal); 1409 } 1410 return ValueLatticeElement::getRange(std::move(EdgesVals)); 1411 } 1412 return None; 1413 } 1414 1415 /// Compute the value of Val on the edge BBFrom -> BBTo or the value at 1416 /// the basic block if the edge does not constrain Val. 1417 Optional<ValueLatticeElement> LazyValueInfoImpl::getEdgeValue( 1418 Value *Val, BasicBlock *BBFrom, BasicBlock *BBTo, Instruction *CxtI) { 1419 // If already a constant, there is nothing to compute. 1420 if (Constant *VC = dyn_cast<Constant>(Val)) 1421 return ValueLatticeElement::get(VC); 1422 1423 ValueLatticeElement LocalResult = getEdgeValueLocal(Val, BBFrom, BBTo) 1424 .getValueOr(ValueLatticeElement::getOverdefined()); 1425 if (hasSingleValue(LocalResult)) 1426 // Can't get any more precise here 1427 return LocalResult; 1428 1429 Optional<ValueLatticeElement> OptInBlock = getBlockValue(Val, BBFrom); 1430 if (!OptInBlock) 1431 return None; 1432 ValueLatticeElement &InBlock = *OptInBlock; 1433 1434 // Try to intersect ranges of the BB and the constraint on the edge. 1435 intersectAssumeOrGuardBlockValueConstantRange(Val, InBlock, 1436 BBFrom->getTerminator()); 1437 // We can use the context instruction (generically the ultimate instruction 1438 // the calling pass is trying to simplify) here, even though the result of 1439 // this function is generally cached when called from the solve* functions 1440 // (and that cached result might be used with queries using a different 1441 // context instruction), because when this function is called from the solve* 1442 // functions, the context instruction is not provided. When called from 1443 // LazyValueInfoImpl::getValueOnEdge, the context instruction is provided, 1444 // but then the result is not cached. 1445 intersectAssumeOrGuardBlockValueConstantRange(Val, InBlock, CxtI); 1446 1447 return intersect(LocalResult, InBlock); 1448 } 1449 1450 ValueLatticeElement LazyValueInfoImpl::getValueInBlock(Value *V, BasicBlock *BB, 1451 Instruction *CxtI) { 1452 LLVM_DEBUG(dbgs() << "LVI Getting block end value " << *V << " at '" 1453 << BB->getName() << "'\n"); 1454 1455 assert(BlockValueStack.empty() && BlockValueSet.empty()); 1456 Optional<ValueLatticeElement> OptResult = getBlockValue(V, BB); 1457 if (!OptResult) { 1458 solve(); 1459 OptResult = getBlockValue(V, BB); 1460 assert(OptResult && "Value not available after solving"); 1461 } 1462 ValueLatticeElement Result = *OptResult; 1463 intersectAssumeOrGuardBlockValueConstantRange(V, Result, CxtI); 1464 1465 LLVM_DEBUG(dbgs() << " Result = " << Result << "\n"); 1466 return Result; 1467 } 1468 1469 ValueLatticeElement LazyValueInfoImpl::getValueAt(Value *V, Instruction *CxtI) { 1470 LLVM_DEBUG(dbgs() << "LVI Getting value " << *V << " at '" << CxtI->getName() 1471 << "'\n"); 1472 1473 if (auto *C = dyn_cast<Constant>(V)) 1474 return ValueLatticeElement::get(C); 1475 1476 ValueLatticeElement Result = ValueLatticeElement::getOverdefined(); 1477 if (auto *I = dyn_cast<Instruction>(V)) 1478 Result = getFromRangeMetadata(I); 1479 intersectAssumeOrGuardBlockValueConstantRange(V, Result, CxtI); 1480 1481 LLVM_DEBUG(dbgs() << " Result = " << Result << "\n"); 1482 return Result; 1483 } 1484 1485 ValueLatticeElement LazyValueInfoImpl:: 1486 getValueOnEdge(Value *V, BasicBlock *FromBB, BasicBlock *ToBB, 1487 Instruction *CxtI) { 1488 LLVM_DEBUG(dbgs() << "LVI Getting edge value " << *V << " from '" 1489 << FromBB->getName() << "' to '" << ToBB->getName() 1490 << "'\n"); 1491 1492 Optional<ValueLatticeElement> Result = getEdgeValue(V, FromBB, ToBB, CxtI); 1493 if (!Result) { 1494 solve(); 1495 Result = getEdgeValue(V, FromBB, ToBB, CxtI); 1496 assert(Result && "More work to do after problem solved?"); 1497 } 1498 1499 LLVM_DEBUG(dbgs() << " Result = " << *Result << "\n"); 1500 return *Result; 1501 } 1502 1503 void LazyValueInfoImpl::threadEdge(BasicBlock *PredBB, BasicBlock *OldSucc, 1504 BasicBlock *NewSucc) { 1505 TheCache.threadEdgeImpl(OldSucc, NewSucc); 1506 } 1507 1508 //===----------------------------------------------------------------------===// 1509 // LazyValueInfo Impl 1510 //===----------------------------------------------------------------------===// 1511 1512 /// This lazily constructs the LazyValueInfoImpl. 1513 static LazyValueInfoImpl &getImpl(void *&PImpl, AssumptionCache *AC, 1514 const Module *M) { 1515 if (!PImpl) { 1516 assert(M && "getCache() called with a null Module"); 1517 const DataLayout &DL = M->getDataLayout(); 1518 Function *GuardDecl = M->getFunction( 1519 Intrinsic::getName(Intrinsic::experimental_guard)); 1520 PImpl = new LazyValueInfoImpl(AC, DL, GuardDecl); 1521 } 1522 return *static_cast<LazyValueInfoImpl*>(PImpl); 1523 } 1524 1525 bool LazyValueInfoWrapperPass::runOnFunction(Function &F) { 1526 Info.AC = &getAnalysis<AssumptionCacheTracker>().getAssumptionCache(F); 1527 Info.TLI = &getAnalysis<TargetLibraryInfoWrapperPass>().getTLI(F); 1528 1529 if (Info.PImpl) 1530 getImpl(Info.PImpl, Info.AC, F.getParent()).clear(); 1531 1532 // Fully lazy. 1533 return false; 1534 } 1535 1536 void LazyValueInfoWrapperPass::getAnalysisUsage(AnalysisUsage &AU) const { 1537 AU.setPreservesAll(); 1538 AU.addRequired<AssumptionCacheTracker>(); 1539 AU.addRequired<TargetLibraryInfoWrapperPass>(); 1540 } 1541 1542 LazyValueInfo &LazyValueInfoWrapperPass::getLVI() { return Info; } 1543 1544 LazyValueInfo::~LazyValueInfo() { releaseMemory(); } 1545 1546 void LazyValueInfo::releaseMemory() { 1547 // If the cache was allocated, free it. 1548 if (PImpl) { 1549 delete &getImpl(PImpl, AC, nullptr); 1550 PImpl = nullptr; 1551 } 1552 } 1553 1554 bool LazyValueInfo::invalidate(Function &F, const PreservedAnalyses &PA, 1555 FunctionAnalysisManager::Invalidator &Inv) { 1556 // We need to invalidate if we have either failed to preserve this analyses 1557 // result directly or if any of its dependencies have been invalidated. 1558 auto PAC = PA.getChecker<LazyValueAnalysis>(); 1559 if (!(PAC.preserved() || PAC.preservedSet<AllAnalysesOn<Function>>())) 1560 return true; 1561 1562 return false; 1563 } 1564 1565 void LazyValueInfoWrapperPass::releaseMemory() { Info.releaseMemory(); } 1566 1567 LazyValueInfo LazyValueAnalysis::run(Function &F, 1568 FunctionAnalysisManager &FAM) { 1569 auto &AC = FAM.getResult<AssumptionAnalysis>(F); 1570 auto &TLI = FAM.getResult<TargetLibraryAnalysis>(F); 1571 1572 return LazyValueInfo(&AC, &F.getParent()->getDataLayout(), &TLI); 1573 } 1574 1575 /// Returns true if we can statically tell that this value will never be a 1576 /// "useful" constant. In practice, this means we've got something like an 1577 /// alloca or a malloc call for which a comparison against a constant can 1578 /// only be guarding dead code. Note that we are potentially giving up some 1579 /// precision in dead code (a constant result) in favour of avoiding a 1580 /// expensive search for a easily answered common query. 1581 static bool isKnownNonConstant(Value *V) { 1582 V = V->stripPointerCasts(); 1583 // The return val of alloc cannot be a Constant. 1584 if (isa<AllocaInst>(V)) 1585 return true; 1586 return false; 1587 } 1588 1589 Constant *LazyValueInfo::getConstant(Value *V, BasicBlock *BB, 1590 Instruction *CxtI) { 1591 // Bail out early if V is known not to be a Constant. 1592 if (isKnownNonConstant(V)) 1593 return nullptr; 1594 1595 ValueLatticeElement Result = 1596 getImpl(PImpl, AC, BB->getModule()).getValueInBlock(V, BB, CxtI); 1597 1598 if (Result.isConstant()) 1599 return Result.getConstant(); 1600 if (Result.isConstantRange()) { 1601 const ConstantRange &CR = Result.getConstantRange(); 1602 if (const APInt *SingleVal = CR.getSingleElement()) 1603 return ConstantInt::get(V->getContext(), *SingleVal); 1604 } 1605 return nullptr; 1606 } 1607 1608 ConstantRange LazyValueInfo::getConstantRange(Value *V, BasicBlock *BB, 1609 Instruction *CxtI, 1610 bool UndefAllowed) { 1611 assert(V->getType()->isIntegerTy()); 1612 unsigned Width = V->getType()->getIntegerBitWidth(); 1613 ValueLatticeElement Result = 1614 getImpl(PImpl, AC, BB->getModule()).getValueInBlock(V, BB, CxtI); 1615 if (Result.isUnknown()) 1616 return ConstantRange::getEmpty(Width); 1617 if (Result.isConstantRange(UndefAllowed)) 1618 return Result.getConstantRange(UndefAllowed); 1619 // We represent ConstantInt constants as constant ranges but other kinds 1620 // of integer constants, i.e. ConstantExpr will be tagged as constants 1621 assert(!(Result.isConstant() && isa<ConstantInt>(Result.getConstant())) && 1622 "ConstantInt value must be represented as constantrange"); 1623 return ConstantRange::getFull(Width); 1624 } 1625 1626 /// Determine whether the specified value is known to be a 1627 /// constant on the specified edge. Return null if not. 1628 Constant *LazyValueInfo::getConstantOnEdge(Value *V, BasicBlock *FromBB, 1629 BasicBlock *ToBB, 1630 Instruction *CxtI) { 1631 Module *M = FromBB->getModule(); 1632 ValueLatticeElement Result = 1633 getImpl(PImpl, AC, M).getValueOnEdge(V, FromBB, ToBB, CxtI); 1634 1635 if (Result.isConstant()) 1636 return Result.getConstant(); 1637 if (Result.isConstantRange()) { 1638 const ConstantRange &CR = Result.getConstantRange(); 1639 if (const APInt *SingleVal = CR.getSingleElement()) 1640 return ConstantInt::get(V->getContext(), *SingleVal); 1641 } 1642 return nullptr; 1643 } 1644 1645 ConstantRange LazyValueInfo::getConstantRangeOnEdge(Value *V, 1646 BasicBlock *FromBB, 1647 BasicBlock *ToBB, 1648 Instruction *CxtI) { 1649 unsigned Width = V->getType()->getIntegerBitWidth(); 1650 Module *M = FromBB->getModule(); 1651 ValueLatticeElement Result = 1652 getImpl(PImpl, AC, M).getValueOnEdge(V, FromBB, ToBB, CxtI); 1653 1654 if (Result.isUnknown()) 1655 return ConstantRange::getEmpty(Width); 1656 if (Result.isConstantRange()) 1657 return Result.getConstantRange(); 1658 // We represent ConstantInt constants as constant ranges but other kinds 1659 // of integer constants, i.e. ConstantExpr will be tagged as constants 1660 assert(!(Result.isConstant() && isa<ConstantInt>(Result.getConstant())) && 1661 "ConstantInt value must be represented as constantrange"); 1662 return ConstantRange::getFull(Width); 1663 } 1664 1665 static LazyValueInfo::Tristate 1666 getPredicateResult(unsigned Pred, Constant *C, const ValueLatticeElement &Val, 1667 const DataLayout &DL, TargetLibraryInfo *TLI) { 1668 // If we know the value is a constant, evaluate the conditional. 1669 Constant *Res = nullptr; 1670 if (Val.isConstant()) { 1671 Res = ConstantFoldCompareInstOperands(Pred, Val.getConstant(), C, DL, TLI); 1672 if (ConstantInt *ResCI = dyn_cast<ConstantInt>(Res)) 1673 return ResCI->isZero() ? LazyValueInfo::False : LazyValueInfo::True; 1674 return LazyValueInfo::Unknown; 1675 } 1676 1677 if (Val.isConstantRange()) { 1678 ConstantInt *CI = dyn_cast<ConstantInt>(C); 1679 if (!CI) return LazyValueInfo::Unknown; 1680 1681 const ConstantRange &CR = Val.getConstantRange(); 1682 if (Pred == ICmpInst::ICMP_EQ) { 1683 if (!CR.contains(CI->getValue())) 1684 return LazyValueInfo::False; 1685 1686 if (CR.isSingleElement()) 1687 return LazyValueInfo::True; 1688 } else if (Pred == ICmpInst::ICMP_NE) { 1689 if (!CR.contains(CI->getValue())) 1690 return LazyValueInfo::True; 1691 1692 if (CR.isSingleElement()) 1693 return LazyValueInfo::False; 1694 } else { 1695 // Handle more complex predicates. 1696 ConstantRange TrueValues = ConstantRange::makeExactICmpRegion( 1697 (ICmpInst::Predicate)Pred, CI->getValue()); 1698 if (TrueValues.contains(CR)) 1699 return LazyValueInfo::True; 1700 if (TrueValues.inverse().contains(CR)) 1701 return LazyValueInfo::False; 1702 } 1703 return LazyValueInfo::Unknown; 1704 } 1705 1706 if (Val.isNotConstant()) { 1707 // If this is an equality comparison, we can try to fold it knowing that 1708 // "V != C1". 1709 if (Pred == ICmpInst::ICMP_EQ) { 1710 // !C1 == C -> false iff C1 == C. 1711 Res = ConstantFoldCompareInstOperands(ICmpInst::ICMP_NE, 1712 Val.getNotConstant(), C, DL, 1713 TLI); 1714 if (Res->isNullValue()) 1715 return LazyValueInfo::False; 1716 } else if (Pred == ICmpInst::ICMP_NE) { 1717 // !C1 != C -> true iff C1 == C. 1718 Res = ConstantFoldCompareInstOperands(ICmpInst::ICMP_NE, 1719 Val.getNotConstant(), C, DL, 1720 TLI); 1721 if (Res->isNullValue()) 1722 return LazyValueInfo::True; 1723 } 1724 return LazyValueInfo::Unknown; 1725 } 1726 1727 return LazyValueInfo::Unknown; 1728 } 1729 1730 /// Determine whether the specified value comparison with a constant is known to 1731 /// be true or false on the specified CFG edge. Pred is a CmpInst predicate. 1732 LazyValueInfo::Tristate 1733 LazyValueInfo::getPredicateOnEdge(unsigned Pred, Value *V, Constant *C, 1734 BasicBlock *FromBB, BasicBlock *ToBB, 1735 Instruction *CxtI) { 1736 Module *M = FromBB->getModule(); 1737 ValueLatticeElement Result = 1738 getImpl(PImpl, AC, M).getValueOnEdge(V, FromBB, ToBB, CxtI); 1739 1740 return getPredicateResult(Pred, C, Result, M->getDataLayout(), TLI); 1741 } 1742 1743 LazyValueInfo::Tristate 1744 LazyValueInfo::getPredicateAt(unsigned Pred, Value *V, Constant *C, 1745 Instruction *CxtI) { 1746 // Is or is not NonNull are common predicates being queried. If 1747 // isKnownNonZero can tell us the result of the predicate, we can 1748 // return it quickly. But this is only a fastpath, and falling 1749 // through would still be correct. 1750 Module *M = CxtI->getModule(); 1751 const DataLayout &DL = M->getDataLayout(); 1752 if (V->getType()->isPointerTy() && C->isNullValue() && 1753 isKnownNonZero(V->stripPointerCastsSameRepresentation(), DL)) { 1754 if (Pred == ICmpInst::ICMP_EQ) 1755 return LazyValueInfo::False; 1756 else if (Pred == ICmpInst::ICMP_NE) 1757 return LazyValueInfo::True; 1758 } 1759 ValueLatticeElement Result = getImpl(PImpl, AC, M).getValueAt(V, CxtI); 1760 Tristate Ret = getPredicateResult(Pred, C, Result, DL, TLI); 1761 if (Ret != Unknown) 1762 return Ret; 1763 1764 // Note: The following bit of code is somewhat distinct from the rest of LVI; 1765 // LVI as a whole tries to compute a lattice value which is conservatively 1766 // correct at a given location. In this case, we have a predicate which we 1767 // weren't able to prove about the merged result, and we're pushing that 1768 // predicate back along each incoming edge to see if we can prove it 1769 // separately for each input. As a motivating example, consider: 1770 // bb1: 1771 // %v1 = ... ; constantrange<1, 5> 1772 // br label %merge 1773 // bb2: 1774 // %v2 = ... ; constantrange<10, 20> 1775 // br label %merge 1776 // merge: 1777 // %phi = phi [%v1, %v2] ; constantrange<1,20> 1778 // %pred = icmp eq i32 %phi, 8 1779 // We can't tell from the lattice value for '%phi' that '%pred' is false 1780 // along each path, but by checking the predicate over each input separately, 1781 // we can. 1782 // We limit the search to one step backwards from the current BB and value. 1783 // We could consider extending this to search further backwards through the 1784 // CFG and/or value graph, but there are non-obvious compile time vs quality 1785 // tradeoffs. 1786 if (CxtI) { 1787 BasicBlock *BB = CxtI->getParent(); 1788 1789 // Function entry or an unreachable block. Bail to avoid confusing 1790 // analysis below. 1791 pred_iterator PI = pred_begin(BB), PE = pred_end(BB); 1792 if (PI == PE) 1793 return Unknown; 1794 1795 // If V is a PHI node in the same block as the context, we need to ask 1796 // questions about the predicate as applied to the incoming value along 1797 // each edge. This is useful for eliminating cases where the predicate is 1798 // known along all incoming edges. 1799 if (auto *PHI = dyn_cast<PHINode>(V)) 1800 if (PHI->getParent() == BB) { 1801 Tristate Baseline = Unknown; 1802 for (unsigned i = 0, e = PHI->getNumIncomingValues(); i < e; i++) { 1803 Value *Incoming = PHI->getIncomingValue(i); 1804 BasicBlock *PredBB = PHI->getIncomingBlock(i); 1805 // Note that PredBB may be BB itself. 1806 Tristate Result = getPredicateOnEdge(Pred, Incoming, C, PredBB, BB, 1807 CxtI); 1808 1809 // Keep going as long as we've seen a consistent known result for 1810 // all inputs. 1811 Baseline = (i == 0) ? Result /* First iteration */ 1812 : (Baseline == Result ? Baseline : Unknown); /* All others */ 1813 if (Baseline == Unknown) 1814 break; 1815 } 1816 if (Baseline != Unknown) 1817 return Baseline; 1818 } 1819 1820 // For a comparison where the V is outside this block, it's possible 1821 // that we've branched on it before. Look to see if the value is known 1822 // on all incoming edges. 1823 if (!isa<Instruction>(V) || 1824 cast<Instruction>(V)->getParent() != BB) { 1825 // For predecessor edge, determine if the comparison is true or false 1826 // on that edge. If they're all true or all false, we can conclude 1827 // the value of the comparison in this block. 1828 Tristate Baseline = getPredicateOnEdge(Pred, V, C, *PI, BB, CxtI); 1829 if (Baseline != Unknown) { 1830 // Check that all remaining incoming values match the first one. 1831 while (++PI != PE) { 1832 Tristate Ret = getPredicateOnEdge(Pred, V, C, *PI, BB, CxtI); 1833 if (Ret != Baseline) break; 1834 } 1835 // If we terminated early, then one of the values didn't match. 1836 if (PI == PE) { 1837 return Baseline; 1838 } 1839 } 1840 } 1841 } 1842 return Unknown; 1843 } 1844 1845 void LazyValueInfo::threadEdge(BasicBlock *PredBB, BasicBlock *OldSucc, 1846 BasicBlock *NewSucc) { 1847 if (PImpl) { 1848 getImpl(PImpl, AC, PredBB->getModule()) 1849 .threadEdge(PredBB, OldSucc, NewSucc); 1850 } 1851 } 1852 1853 void LazyValueInfo::eraseBlock(BasicBlock *BB) { 1854 if (PImpl) { 1855 getImpl(PImpl, AC, BB->getModule()).eraseBlock(BB); 1856 } 1857 } 1858 1859 1860 void LazyValueInfo::printLVI(Function &F, DominatorTree &DTree, raw_ostream &OS) { 1861 if (PImpl) { 1862 getImpl(PImpl, AC, F.getParent()).printLVI(F, DTree, OS); 1863 } 1864 } 1865 1866 // Print the LVI for the function arguments at the start of each basic block. 1867 void LazyValueInfoAnnotatedWriter::emitBasicBlockStartAnnot( 1868 const BasicBlock *BB, formatted_raw_ostream &OS) { 1869 // Find if there are latticevalues defined for arguments of the function. 1870 auto *F = BB->getParent(); 1871 for (auto &Arg : F->args()) { 1872 ValueLatticeElement Result = LVIImpl->getValueInBlock( 1873 const_cast<Argument *>(&Arg), const_cast<BasicBlock *>(BB)); 1874 if (Result.isUnknown()) 1875 continue; 1876 OS << "; LatticeVal for: '" << Arg << "' is: " << Result << "\n"; 1877 } 1878 } 1879 1880 // This function prints the LVI analysis for the instruction I at the beginning 1881 // of various basic blocks. It relies on calculated values that are stored in 1882 // the LazyValueInfoCache, and in the absence of cached values, recalculate the 1883 // LazyValueInfo for `I`, and print that info. 1884 void LazyValueInfoAnnotatedWriter::emitInstructionAnnot( 1885 const Instruction *I, formatted_raw_ostream &OS) { 1886 1887 auto *ParentBB = I->getParent(); 1888 SmallPtrSet<const BasicBlock*, 16> BlocksContainingLVI; 1889 // We can generate (solve) LVI values only for blocks that are dominated by 1890 // the I's parent. However, to avoid generating LVI for all dominating blocks, 1891 // that contain redundant/uninteresting information, we print LVI for 1892 // blocks that may use this LVI information (such as immediate successor 1893 // blocks, and blocks that contain uses of `I`). 1894 auto printResult = [&](const BasicBlock *BB) { 1895 if (!BlocksContainingLVI.insert(BB).second) 1896 return; 1897 ValueLatticeElement Result = LVIImpl->getValueInBlock( 1898 const_cast<Instruction *>(I), const_cast<BasicBlock *>(BB)); 1899 OS << "; LatticeVal for: '" << *I << "' in BB: '"; 1900 BB->printAsOperand(OS, false); 1901 OS << "' is: " << Result << "\n"; 1902 }; 1903 1904 printResult(ParentBB); 1905 // Print the LVI analysis results for the immediate successor blocks, that 1906 // are dominated by `ParentBB`. 1907 for (auto *BBSucc : successors(ParentBB)) 1908 if (DT.dominates(ParentBB, BBSucc)) 1909 printResult(BBSucc); 1910 1911 // Print LVI in blocks where `I` is used. 1912 for (auto *U : I->users()) 1913 if (auto *UseI = dyn_cast<Instruction>(U)) 1914 if (!isa<PHINode>(UseI) || DT.dominates(ParentBB, UseI->getParent())) 1915 printResult(UseI->getParent()); 1916 1917 } 1918 1919 namespace { 1920 // Printer class for LazyValueInfo results. 1921 class LazyValueInfoPrinter : public FunctionPass { 1922 public: 1923 static char ID; // Pass identification, replacement for typeid 1924 LazyValueInfoPrinter() : FunctionPass(ID) { 1925 initializeLazyValueInfoPrinterPass(*PassRegistry::getPassRegistry()); 1926 } 1927 1928 void getAnalysisUsage(AnalysisUsage &AU) const override { 1929 AU.setPreservesAll(); 1930 AU.addRequired<LazyValueInfoWrapperPass>(); 1931 AU.addRequired<DominatorTreeWrapperPass>(); 1932 } 1933 1934 // Get the mandatory dominator tree analysis and pass this in to the 1935 // LVIPrinter. We cannot rely on the LVI's DT, since it's optional. 1936 bool runOnFunction(Function &F) override { 1937 dbgs() << "LVI for function '" << F.getName() << "':\n"; 1938 auto &LVI = getAnalysis<LazyValueInfoWrapperPass>().getLVI(); 1939 auto &DTree = getAnalysis<DominatorTreeWrapperPass>().getDomTree(); 1940 LVI.printLVI(F, DTree, dbgs()); 1941 return false; 1942 } 1943 }; 1944 } 1945 1946 char LazyValueInfoPrinter::ID = 0; 1947 INITIALIZE_PASS_BEGIN(LazyValueInfoPrinter, "print-lazy-value-info", 1948 "Lazy Value Info Printer Pass", false, false) 1949 INITIALIZE_PASS_DEPENDENCY(LazyValueInfoWrapperPass) 1950 INITIALIZE_PASS_END(LazyValueInfoPrinter, "print-lazy-value-info", 1951 "Lazy Value Info Printer Pass", false, false) 1952