xref: /freebsd/contrib/llvm-project/llvm/lib/Transforms/IPO/AttributorAttributes.cpp (revision 5e3190f700637fcfc1a52daeaa4a031fdd2557c7)
1 //===- AttributorAttributes.cpp - Attributes for Attributor deduction -----===//
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 // See the Attributor.h file comment and the class descriptions in that file for
10 // more information.
11 //
12 //===----------------------------------------------------------------------===//
13 
14 #include "llvm/Transforms/IPO/Attributor.h"
15 
16 #include "llvm/ADT/APInt.h"
17 #include "llvm/ADT/ArrayRef.h"
18 #include "llvm/ADT/DenseMapInfo.h"
19 #include "llvm/ADT/MapVector.h"
20 #include "llvm/ADT/SCCIterator.h"
21 #include "llvm/ADT/STLExtras.h"
22 #include "llvm/ADT/SetOperations.h"
23 #include "llvm/ADT/SetVector.h"
24 #include "llvm/ADT/SmallPtrSet.h"
25 #include "llvm/ADT/SmallVector.h"
26 #include "llvm/ADT/Statistic.h"
27 #include "llvm/Analysis/AliasAnalysis.h"
28 #include "llvm/Analysis/AssumeBundleQueries.h"
29 #include "llvm/Analysis/AssumptionCache.h"
30 #include "llvm/Analysis/CaptureTracking.h"
31 #include "llvm/Analysis/CycleAnalysis.h"
32 #include "llvm/Analysis/InstructionSimplify.h"
33 #include "llvm/Analysis/LazyValueInfo.h"
34 #include "llvm/Analysis/MemoryBuiltins.h"
35 #include "llvm/Analysis/OptimizationRemarkEmitter.h"
36 #include "llvm/Analysis/ScalarEvolution.h"
37 #include "llvm/Analysis/TargetTransformInfo.h"
38 #include "llvm/Analysis/ValueTracking.h"
39 #include "llvm/IR/Argument.h"
40 #include "llvm/IR/Assumptions.h"
41 #include "llvm/IR/BasicBlock.h"
42 #include "llvm/IR/Constant.h"
43 #include "llvm/IR/Constants.h"
44 #include "llvm/IR/DataLayout.h"
45 #include "llvm/IR/DerivedTypes.h"
46 #include "llvm/IR/GlobalValue.h"
47 #include "llvm/IR/IRBuilder.h"
48 #include "llvm/IR/InlineAsm.h"
49 #include "llvm/IR/InstrTypes.h"
50 #include "llvm/IR/Instruction.h"
51 #include "llvm/IR/Instructions.h"
52 #include "llvm/IR/IntrinsicInst.h"
53 #include "llvm/IR/IntrinsicsAMDGPU.h"
54 #include "llvm/IR/IntrinsicsNVPTX.h"
55 #include "llvm/IR/NoFolder.h"
56 #include "llvm/IR/Value.h"
57 #include "llvm/IR/ValueHandle.h"
58 #include "llvm/Support/Alignment.h"
59 #include "llvm/Support/Casting.h"
60 #include "llvm/Support/CommandLine.h"
61 #include "llvm/Support/ErrorHandling.h"
62 #include "llvm/Support/GraphWriter.h"
63 #include "llvm/Support/MathExtras.h"
64 #include "llvm/Support/raw_ostream.h"
65 #include "llvm/Transforms/Utils/Local.h"
66 #include "llvm/Transforms/Utils/ValueMapper.h"
67 #include <cassert>
68 #include <numeric>
69 #include <optional>
70 
71 using namespace llvm;
72 
73 #define DEBUG_TYPE "attributor"
74 
75 static cl::opt<bool> ManifestInternal(
76     "attributor-manifest-internal", cl::Hidden,
77     cl::desc("Manifest Attributor internal string attributes."),
78     cl::init(false));
79 
80 static cl::opt<int> MaxHeapToStackSize("max-heap-to-stack-size", cl::init(128),
81                                        cl::Hidden);
82 
83 template <>
84 unsigned llvm::PotentialConstantIntValuesState::MaxPotentialValues = 0;
85 
86 template <> unsigned llvm::PotentialLLVMValuesState::MaxPotentialValues = -1;
87 
88 static cl::opt<unsigned, true> MaxPotentialValues(
89     "attributor-max-potential-values", cl::Hidden,
90     cl::desc("Maximum number of potential values to be "
91              "tracked for each position."),
92     cl::location(llvm::PotentialConstantIntValuesState::MaxPotentialValues),
93     cl::init(7));
94 
95 static cl::opt<int> MaxPotentialValuesIterations(
96     "attributor-max-potential-values-iterations", cl::Hidden,
97     cl::desc(
98         "Maximum number of iterations we keep dismantling potential values."),
99     cl::init(64));
100 
101 STATISTIC(NumAAs, "Number of abstract attributes created");
102 
103 // Some helper macros to deal with statistics tracking.
104 //
105 // Usage:
106 // For simple IR attribute tracking overload trackStatistics in the abstract
107 // attribute and choose the right STATS_DECLTRACK_********* macro,
108 // e.g.,:
109 //  void trackStatistics() const override {
110 //    STATS_DECLTRACK_ARG_ATTR(returned)
111 //  }
112 // If there is a single "increment" side one can use the macro
113 // STATS_DECLTRACK with a custom message. If there are multiple increment
114 // sides, STATS_DECL and STATS_TRACK can also be used separately.
115 //
116 #define BUILD_STAT_MSG_IR_ATTR(TYPE, NAME)                                     \
117   ("Number of " #TYPE " marked '" #NAME "'")
118 #define BUILD_STAT_NAME(NAME, TYPE) NumIR##TYPE##_##NAME
119 #define STATS_DECL_(NAME, MSG) STATISTIC(NAME, MSG);
120 #define STATS_DECL(NAME, TYPE, MSG)                                            \
121   STATS_DECL_(BUILD_STAT_NAME(NAME, TYPE), MSG);
122 #define STATS_TRACK(NAME, TYPE) ++(BUILD_STAT_NAME(NAME, TYPE));
123 #define STATS_DECLTRACK(NAME, TYPE, MSG)                                       \
124   {                                                                            \
125     STATS_DECL(NAME, TYPE, MSG)                                                \
126     STATS_TRACK(NAME, TYPE)                                                    \
127   }
128 #define STATS_DECLTRACK_ARG_ATTR(NAME)                                         \
129   STATS_DECLTRACK(NAME, Arguments, BUILD_STAT_MSG_IR_ATTR(arguments, NAME))
130 #define STATS_DECLTRACK_CSARG_ATTR(NAME)                                       \
131   STATS_DECLTRACK(NAME, CSArguments,                                           \
132                   BUILD_STAT_MSG_IR_ATTR(call site arguments, NAME))
133 #define STATS_DECLTRACK_FN_ATTR(NAME)                                          \
134   STATS_DECLTRACK(NAME, Function, BUILD_STAT_MSG_IR_ATTR(functions, NAME))
135 #define STATS_DECLTRACK_CS_ATTR(NAME)                                          \
136   STATS_DECLTRACK(NAME, CS, BUILD_STAT_MSG_IR_ATTR(call site, NAME))
137 #define STATS_DECLTRACK_FNRET_ATTR(NAME)                                       \
138   STATS_DECLTRACK(NAME, FunctionReturn,                                        \
139                   BUILD_STAT_MSG_IR_ATTR(function returns, NAME))
140 #define STATS_DECLTRACK_CSRET_ATTR(NAME)                                       \
141   STATS_DECLTRACK(NAME, CSReturn,                                              \
142                   BUILD_STAT_MSG_IR_ATTR(call site returns, NAME))
143 #define STATS_DECLTRACK_FLOATING_ATTR(NAME)                                    \
144   STATS_DECLTRACK(NAME, Floating,                                              \
145                   ("Number of floating values known to be '" #NAME "'"))
146 
147 // Specialization of the operator<< for abstract attributes subclasses. This
148 // disambiguates situations where multiple operators are applicable.
149 namespace llvm {
150 #define PIPE_OPERATOR(CLASS)                                                   \
151   raw_ostream &operator<<(raw_ostream &OS, const CLASS &AA) {                  \
152     return OS << static_cast<const AbstractAttribute &>(AA);                   \
153   }
154 
155 PIPE_OPERATOR(AAIsDead)
156 PIPE_OPERATOR(AANoUnwind)
157 PIPE_OPERATOR(AANoSync)
158 PIPE_OPERATOR(AANoRecurse)
159 PIPE_OPERATOR(AAWillReturn)
160 PIPE_OPERATOR(AANoReturn)
161 PIPE_OPERATOR(AAReturnedValues)
162 PIPE_OPERATOR(AANonNull)
163 PIPE_OPERATOR(AANoAlias)
164 PIPE_OPERATOR(AADereferenceable)
165 PIPE_OPERATOR(AAAlign)
166 PIPE_OPERATOR(AAInstanceInfo)
167 PIPE_OPERATOR(AANoCapture)
168 PIPE_OPERATOR(AAValueSimplify)
169 PIPE_OPERATOR(AANoFree)
170 PIPE_OPERATOR(AAHeapToStack)
171 PIPE_OPERATOR(AAIntraFnReachability)
172 PIPE_OPERATOR(AAMemoryBehavior)
173 PIPE_OPERATOR(AAMemoryLocation)
174 PIPE_OPERATOR(AAValueConstantRange)
175 PIPE_OPERATOR(AAPrivatizablePtr)
176 PIPE_OPERATOR(AAUndefinedBehavior)
177 PIPE_OPERATOR(AAPotentialConstantValues)
178 PIPE_OPERATOR(AAPotentialValues)
179 PIPE_OPERATOR(AANoUndef)
180 PIPE_OPERATOR(AACallEdges)
181 PIPE_OPERATOR(AAInterFnReachability)
182 PIPE_OPERATOR(AAPointerInfo)
183 PIPE_OPERATOR(AAAssumptionInfo)
184 PIPE_OPERATOR(AAUnderlyingObjects)
185 
186 #undef PIPE_OPERATOR
187 
188 template <>
189 ChangeStatus clampStateAndIndicateChange<DerefState>(DerefState &S,
190                                                      const DerefState &R) {
191   ChangeStatus CS0 =
192       clampStateAndIndicateChange(S.DerefBytesState, R.DerefBytesState);
193   ChangeStatus CS1 = clampStateAndIndicateChange(S.GlobalState, R.GlobalState);
194   return CS0 | CS1;
195 }
196 
197 } // namespace llvm
198 
199 /// Checks if a type could have padding bytes.
200 static bool isDenselyPacked(Type *Ty, const DataLayout &DL) {
201   // There is no size information, so be conservative.
202   if (!Ty->isSized())
203     return false;
204 
205   // If the alloc size is not equal to the storage size, then there are padding
206   // bytes. For x86_fp80 on x86-64, size: 80 alloc size: 128.
207   if (DL.getTypeSizeInBits(Ty) != DL.getTypeAllocSizeInBits(Ty))
208     return false;
209 
210   // FIXME: This isn't the right way to check for padding in vectors with
211   // non-byte-size elements.
212   if (VectorType *SeqTy = dyn_cast<VectorType>(Ty))
213     return isDenselyPacked(SeqTy->getElementType(), DL);
214 
215   // For array types, check for padding within members.
216   if (ArrayType *SeqTy = dyn_cast<ArrayType>(Ty))
217     return isDenselyPacked(SeqTy->getElementType(), DL);
218 
219   if (!isa<StructType>(Ty))
220     return true;
221 
222   // Check for padding within and between elements of a struct.
223   StructType *StructTy = cast<StructType>(Ty);
224   const StructLayout *Layout = DL.getStructLayout(StructTy);
225   uint64_t StartPos = 0;
226   for (unsigned I = 0, E = StructTy->getNumElements(); I < E; ++I) {
227     Type *ElTy = StructTy->getElementType(I);
228     if (!isDenselyPacked(ElTy, DL))
229       return false;
230     if (StartPos != Layout->getElementOffsetInBits(I))
231       return false;
232     StartPos += DL.getTypeAllocSizeInBits(ElTy);
233   }
234 
235   return true;
236 }
237 
238 /// Get pointer operand of memory accessing instruction. If \p I is
239 /// not a memory accessing instruction, return nullptr. If \p AllowVolatile,
240 /// is set to false and the instruction is volatile, return nullptr.
241 static const Value *getPointerOperand(const Instruction *I,
242                                       bool AllowVolatile) {
243   if (!AllowVolatile && I->isVolatile())
244     return nullptr;
245 
246   if (auto *LI = dyn_cast<LoadInst>(I)) {
247     return LI->getPointerOperand();
248   }
249 
250   if (auto *SI = dyn_cast<StoreInst>(I)) {
251     return SI->getPointerOperand();
252   }
253 
254   if (auto *CXI = dyn_cast<AtomicCmpXchgInst>(I)) {
255     return CXI->getPointerOperand();
256   }
257 
258   if (auto *RMWI = dyn_cast<AtomicRMWInst>(I)) {
259     return RMWI->getPointerOperand();
260   }
261 
262   return nullptr;
263 }
264 
265 /// Helper function to create a pointer of type \p ResTy, based on \p Ptr, and
266 /// advanced by \p Offset bytes. To aid later analysis the method tries to build
267 /// getelement pointer instructions that traverse the natural type of \p Ptr if
268 /// possible. If that fails, the remaining offset is adjusted byte-wise, hence
269 /// through a cast to i8*.
270 ///
271 /// TODO: This could probably live somewhere more prominantly if it doesn't
272 ///       already exist.
273 static Value *constructPointer(Type *ResTy, Type *PtrElemTy, Value *Ptr,
274                                int64_t Offset, IRBuilder<NoFolder> &IRB,
275                                const DataLayout &DL) {
276   assert(Offset >= 0 && "Negative offset not supported yet!");
277   LLVM_DEBUG(dbgs() << "Construct pointer: " << *Ptr << " + " << Offset
278                     << "-bytes as " << *ResTy << "\n");
279 
280   if (Offset) {
281     Type *Ty = PtrElemTy;
282     APInt IntOffset(DL.getIndexTypeSizeInBits(Ptr->getType()), Offset);
283     SmallVector<APInt> IntIndices = DL.getGEPIndicesForOffset(Ty, IntOffset);
284 
285     SmallVector<Value *, 4> ValIndices;
286     std::string GEPName = Ptr->getName().str();
287     for (const APInt &Index : IntIndices) {
288       ValIndices.push_back(IRB.getInt(Index));
289       GEPName += "." + std::to_string(Index.getZExtValue());
290     }
291 
292     // Create a GEP for the indices collected above.
293     Ptr = IRB.CreateGEP(PtrElemTy, Ptr, ValIndices, GEPName);
294 
295     // If an offset is left we use byte-wise adjustment.
296     if (IntOffset != 0) {
297       Ptr = IRB.CreateBitCast(Ptr, IRB.getInt8PtrTy());
298       Ptr = IRB.CreateGEP(IRB.getInt8Ty(), Ptr, IRB.getInt(IntOffset),
299                           GEPName + ".b" + Twine(IntOffset.getZExtValue()));
300     }
301   }
302 
303   // Ensure the result has the requested type.
304   Ptr = IRB.CreatePointerBitCastOrAddrSpaceCast(Ptr, ResTy,
305                                                 Ptr->getName() + ".cast");
306 
307   LLVM_DEBUG(dbgs() << "Constructed pointer: " << *Ptr << "\n");
308   return Ptr;
309 }
310 
311 static const Value *
312 stripAndAccumulateOffsets(Attributor &A, const AbstractAttribute &QueryingAA,
313                           const Value *Val, const DataLayout &DL, APInt &Offset,
314                           bool GetMinOffset, bool AllowNonInbounds,
315                           bool UseAssumed = false) {
316 
317   auto AttributorAnalysis = [&](Value &V, APInt &ROffset) -> bool {
318     const IRPosition &Pos = IRPosition::value(V);
319     // Only track dependence if we are going to use the assumed info.
320     const AAValueConstantRange &ValueConstantRangeAA =
321         A.getAAFor<AAValueConstantRange>(QueryingAA, Pos,
322                                          UseAssumed ? DepClassTy::OPTIONAL
323                                                     : DepClassTy::NONE);
324     ConstantRange Range = UseAssumed ? ValueConstantRangeAA.getAssumed()
325                                      : ValueConstantRangeAA.getKnown();
326     if (Range.isFullSet())
327       return false;
328 
329     // We can only use the lower part of the range because the upper part can
330     // be higher than what the value can really be.
331     if (GetMinOffset)
332       ROffset = Range.getSignedMin();
333     else
334       ROffset = Range.getSignedMax();
335     return true;
336   };
337 
338   return Val->stripAndAccumulateConstantOffsets(DL, Offset, AllowNonInbounds,
339                                                 /* AllowInvariant */ true,
340                                                 AttributorAnalysis);
341 }
342 
343 static const Value *
344 getMinimalBaseOfPointer(Attributor &A, const AbstractAttribute &QueryingAA,
345                         const Value *Ptr, int64_t &BytesOffset,
346                         const DataLayout &DL, bool AllowNonInbounds = false) {
347   APInt OffsetAPInt(DL.getIndexTypeSizeInBits(Ptr->getType()), 0);
348   const Value *Base =
349       stripAndAccumulateOffsets(A, QueryingAA, Ptr, DL, OffsetAPInt,
350                                 /* GetMinOffset */ true, AllowNonInbounds);
351 
352   BytesOffset = OffsetAPInt.getSExtValue();
353   return Base;
354 }
355 
356 /// Clamp the information known for all returned values of a function
357 /// (identified by \p QueryingAA) into \p S.
358 template <typename AAType, typename StateType = typename AAType::StateType>
359 static void clampReturnedValueStates(
360     Attributor &A, const AAType &QueryingAA, StateType &S,
361     const IRPosition::CallBaseContext *CBContext = nullptr) {
362   LLVM_DEBUG(dbgs() << "[Attributor] Clamp return value states for "
363                     << QueryingAA << " into " << S << "\n");
364 
365   assert((QueryingAA.getIRPosition().getPositionKind() ==
366               IRPosition::IRP_RETURNED ||
367           QueryingAA.getIRPosition().getPositionKind() ==
368               IRPosition::IRP_CALL_SITE_RETURNED) &&
369          "Can only clamp returned value states for a function returned or call "
370          "site returned position!");
371 
372   // Use an optional state as there might not be any return values and we want
373   // to join (IntegerState::operator&) the state of all there are.
374   std::optional<StateType> T;
375 
376   // Callback for each possibly returned value.
377   auto CheckReturnValue = [&](Value &RV) -> bool {
378     const IRPosition &RVPos = IRPosition::value(RV, CBContext);
379     const AAType &AA =
380         A.getAAFor<AAType>(QueryingAA, RVPos, DepClassTy::REQUIRED);
381     LLVM_DEBUG(dbgs() << "[Attributor] RV: " << RV << " AA: " << AA.getAsStr()
382                       << " @ " << RVPos << "\n");
383     const StateType &AAS = AA.getState();
384     if (!T)
385       T = StateType::getBestState(AAS);
386     *T &= AAS;
387     LLVM_DEBUG(dbgs() << "[Attributor] AA State: " << AAS << " RV State: " << T
388                       << "\n");
389     return T->isValidState();
390   };
391 
392   if (!A.checkForAllReturnedValues(CheckReturnValue, QueryingAA))
393     S.indicatePessimisticFixpoint();
394   else if (T)
395     S ^= *T;
396 }
397 
398 namespace {
399 /// Helper class for generic deduction: return value -> returned position.
400 template <typename AAType, typename BaseType,
401           typename StateType = typename BaseType::StateType,
402           bool PropagateCallBaseContext = false>
403 struct AAReturnedFromReturnedValues : public BaseType {
404   AAReturnedFromReturnedValues(const IRPosition &IRP, Attributor &A)
405       : BaseType(IRP, A) {}
406 
407   /// See AbstractAttribute::updateImpl(...).
408   ChangeStatus updateImpl(Attributor &A) override {
409     StateType S(StateType::getBestState(this->getState()));
410     clampReturnedValueStates<AAType, StateType>(
411         A, *this, S,
412         PropagateCallBaseContext ? this->getCallBaseContext() : nullptr);
413     // TODO: If we know we visited all returned values, thus no are assumed
414     // dead, we can take the known information from the state T.
415     return clampStateAndIndicateChange<StateType>(this->getState(), S);
416   }
417 };
418 
419 /// Clamp the information known at all call sites for a given argument
420 /// (identified by \p QueryingAA) into \p S.
421 template <typename AAType, typename StateType = typename AAType::StateType>
422 static void clampCallSiteArgumentStates(Attributor &A, const AAType &QueryingAA,
423                                         StateType &S) {
424   LLVM_DEBUG(dbgs() << "[Attributor] Clamp call site argument states for "
425                     << QueryingAA << " into " << S << "\n");
426 
427   assert(QueryingAA.getIRPosition().getPositionKind() ==
428              IRPosition::IRP_ARGUMENT &&
429          "Can only clamp call site argument states for an argument position!");
430 
431   // Use an optional state as there might not be any return values and we want
432   // to join (IntegerState::operator&) the state of all there are.
433   std::optional<StateType> T;
434 
435   // The argument number which is also the call site argument number.
436   unsigned ArgNo = QueryingAA.getIRPosition().getCallSiteArgNo();
437 
438   auto CallSiteCheck = [&](AbstractCallSite ACS) {
439     const IRPosition &ACSArgPos = IRPosition::callsite_argument(ACS, ArgNo);
440     // Check if a coresponding argument was found or if it is on not associated
441     // (which can happen for callback calls).
442     if (ACSArgPos.getPositionKind() == IRPosition::IRP_INVALID)
443       return false;
444 
445     const AAType &AA =
446         A.getAAFor<AAType>(QueryingAA, ACSArgPos, DepClassTy::REQUIRED);
447     LLVM_DEBUG(dbgs() << "[Attributor] ACS: " << *ACS.getInstruction()
448                       << " AA: " << AA.getAsStr() << " @" << ACSArgPos << "\n");
449     const StateType &AAS = AA.getState();
450     if (!T)
451       T = StateType::getBestState(AAS);
452     *T &= AAS;
453     LLVM_DEBUG(dbgs() << "[Attributor] AA State: " << AAS << " CSA State: " << T
454                       << "\n");
455     return T->isValidState();
456   };
457 
458   bool UsedAssumedInformation = false;
459   if (!A.checkForAllCallSites(CallSiteCheck, QueryingAA, true,
460                               UsedAssumedInformation))
461     S.indicatePessimisticFixpoint();
462   else if (T)
463     S ^= *T;
464 }
465 
466 /// This function is the bridge between argument position and the call base
467 /// context.
468 template <typename AAType, typename BaseType,
469           typename StateType = typename AAType::StateType>
470 bool getArgumentStateFromCallBaseContext(Attributor &A,
471                                          BaseType &QueryingAttribute,
472                                          IRPosition &Pos, StateType &State) {
473   assert((Pos.getPositionKind() == IRPosition::IRP_ARGUMENT) &&
474          "Expected an 'argument' position !");
475   const CallBase *CBContext = Pos.getCallBaseContext();
476   if (!CBContext)
477     return false;
478 
479   int ArgNo = Pos.getCallSiteArgNo();
480   assert(ArgNo >= 0 && "Invalid Arg No!");
481 
482   const auto &AA = A.getAAFor<AAType>(
483       QueryingAttribute, IRPosition::callsite_argument(*CBContext, ArgNo),
484       DepClassTy::REQUIRED);
485   const StateType &CBArgumentState =
486       static_cast<const StateType &>(AA.getState());
487 
488   LLVM_DEBUG(dbgs() << "[Attributor] Briding Call site context to argument"
489                     << "Position:" << Pos << "CB Arg state:" << CBArgumentState
490                     << "\n");
491 
492   // NOTE: If we want to do call site grouping it should happen here.
493   State ^= CBArgumentState;
494   return true;
495 }
496 
497 /// Helper class for generic deduction: call site argument -> argument position.
498 template <typename AAType, typename BaseType,
499           typename StateType = typename AAType::StateType,
500           bool BridgeCallBaseContext = false>
501 struct AAArgumentFromCallSiteArguments : public BaseType {
502   AAArgumentFromCallSiteArguments(const IRPosition &IRP, Attributor &A)
503       : BaseType(IRP, A) {}
504 
505   /// See AbstractAttribute::updateImpl(...).
506   ChangeStatus updateImpl(Attributor &A) override {
507     StateType S = StateType::getBestState(this->getState());
508 
509     if (BridgeCallBaseContext) {
510       bool Success =
511           getArgumentStateFromCallBaseContext<AAType, BaseType, StateType>(
512               A, *this, this->getIRPosition(), S);
513       if (Success)
514         return clampStateAndIndicateChange<StateType>(this->getState(), S);
515     }
516     clampCallSiteArgumentStates<AAType, StateType>(A, *this, S);
517 
518     // TODO: If we know we visited all incoming values, thus no are assumed
519     // dead, we can take the known information from the state T.
520     return clampStateAndIndicateChange<StateType>(this->getState(), S);
521   }
522 };
523 
524 /// Helper class for generic replication: function returned -> cs returned.
525 template <typename AAType, typename BaseType,
526           typename StateType = typename BaseType::StateType,
527           bool IntroduceCallBaseContext = false>
528 struct AACallSiteReturnedFromReturned : public BaseType {
529   AACallSiteReturnedFromReturned(const IRPosition &IRP, Attributor &A)
530       : BaseType(IRP, A) {}
531 
532   /// See AbstractAttribute::updateImpl(...).
533   ChangeStatus updateImpl(Attributor &A) override {
534     assert(this->getIRPosition().getPositionKind() ==
535                IRPosition::IRP_CALL_SITE_RETURNED &&
536            "Can only wrap function returned positions for call site returned "
537            "positions!");
538     auto &S = this->getState();
539 
540     const Function *AssociatedFunction =
541         this->getIRPosition().getAssociatedFunction();
542     if (!AssociatedFunction)
543       return S.indicatePessimisticFixpoint();
544 
545     CallBase &CBContext = cast<CallBase>(this->getAnchorValue());
546     if (IntroduceCallBaseContext)
547       LLVM_DEBUG(dbgs() << "[Attributor] Introducing call base context:"
548                         << CBContext << "\n");
549 
550     IRPosition FnPos = IRPosition::returned(
551         *AssociatedFunction, IntroduceCallBaseContext ? &CBContext : nullptr);
552     const AAType &AA = A.getAAFor<AAType>(*this, FnPos, DepClassTy::REQUIRED);
553     return clampStateAndIndicateChange(S, AA.getState());
554   }
555 };
556 
557 /// Helper function to accumulate uses.
558 template <class AAType, typename StateType = typename AAType::StateType>
559 static void followUsesInContext(AAType &AA, Attributor &A,
560                                 MustBeExecutedContextExplorer &Explorer,
561                                 const Instruction *CtxI,
562                                 SetVector<const Use *> &Uses,
563                                 StateType &State) {
564   auto EIt = Explorer.begin(CtxI), EEnd = Explorer.end(CtxI);
565   for (unsigned u = 0; u < Uses.size(); ++u) {
566     const Use *U = Uses[u];
567     if (const Instruction *UserI = dyn_cast<Instruction>(U->getUser())) {
568       bool Found = Explorer.findInContextOf(UserI, EIt, EEnd);
569       if (Found && AA.followUseInMBEC(A, U, UserI, State))
570         for (const Use &Us : UserI->uses())
571           Uses.insert(&Us);
572     }
573   }
574 }
575 
576 /// Use the must-be-executed-context around \p I to add information into \p S.
577 /// The AAType class is required to have `followUseInMBEC` method with the
578 /// following signature and behaviour:
579 ///
580 /// bool followUseInMBEC(Attributor &A, const Use *U, const Instruction *I)
581 /// U - Underlying use.
582 /// I - The user of the \p U.
583 /// Returns true if the value should be tracked transitively.
584 ///
585 template <class AAType, typename StateType = typename AAType::StateType>
586 static void followUsesInMBEC(AAType &AA, Attributor &A, StateType &S,
587                              Instruction &CtxI) {
588 
589   // Container for (transitive) uses of the associated value.
590   SetVector<const Use *> Uses;
591   for (const Use &U : AA.getIRPosition().getAssociatedValue().uses())
592     Uses.insert(&U);
593 
594   MustBeExecutedContextExplorer &Explorer =
595       A.getInfoCache().getMustBeExecutedContextExplorer();
596 
597   followUsesInContext<AAType>(AA, A, Explorer, &CtxI, Uses, S);
598 
599   if (S.isAtFixpoint())
600     return;
601 
602   SmallVector<const BranchInst *, 4> BrInsts;
603   auto Pred = [&](const Instruction *I) {
604     if (const BranchInst *Br = dyn_cast<BranchInst>(I))
605       if (Br->isConditional())
606         BrInsts.push_back(Br);
607     return true;
608   };
609 
610   // Here, accumulate conditional branch instructions in the context. We
611   // explore the child paths and collect the known states. The disjunction of
612   // those states can be merged to its own state. Let ParentState_i be a state
613   // to indicate the known information for an i-th branch instruction in the
614   // context. ChildStates are created for its successors respectively.
615   //
616   // ParentS_1 = ChildS_{1, 1} /\ ChildS_{1, 2} /\ ... /\ ChildS_{1, n_1}
617   // ParentS_2 = ChildS_{2, 1} /\ ChildS_{2, 2} /\ ... /\ ChildS_{2, n_2}
618   //      ...
619   // ParentS_m = ChildS_{m, 1} /\ ChildS_{m, 2} /\ ... /\ ChildS_{m, n_m}
620   //
621   // Known State |= ParentS_1 \/ ParentS_2 \/... \/ ParentS_m
622   //
623   // FIXME: Currently, recursive branches are not handled. For example, we
624   // can't deduce that ptr must be dereferenced in below function.
625   //
626   // void f(int a, int c, int *ptr) {
627   //    if(a)
628   //      if (b) {
629   //        *ptr = 0;
630   //      } else {
631   //        *ptr = 1;
632   //      }
633   //    else {
634   //      if (b) {
635   //        *ptr = 0;
636   //      } else {
637   //        *ptr = 1;
638   //      }
639   //    }
640   // }
641 
642   Explorer.checkForAllContext(&CtxI, Pred);
643   for (const BranchInst *Br : BrInsts) {
644     StateType ParentState;
645 
646     // The known state of the parent state is a conjunction of children's
647     // known states so it is initialized with a best state.
648     ParentState.indicateOptimisticFixpoint();
649 
650     for (const BasicBlock *BB : Br->successors()) {
651       StateType ChildState;
652 
653       size_t BeforeSize = Uses.size();
654       followUsesInContext(AA, A, Explorer, &BB->front(), Uses, ChildState);
655 
656       // Erase uses which only appear in the child.
657       for (auto It = Uses.begin() + BeforeSize; It != Uses.end();)
658         It = Uses.erase(It);
659 
660       ParentState &= ChildState;
661     }
662 
663     // Use only known state.
664     S += ParentState;
665   }
666 }
667 } // namespace
668 
669 /// ------------------------ PointerInfo ---------------------------------------
670 
671 namespace llvm {
672 namespace AA {
673 namespace PointerInfo {
674 
675 struct State;
676 
677 } // namespace PointerInfo
678 } // namespace AA
679 
680 /// Helper for AA::PointerInfo::Access DenseMap/Set usage.
681 template <>
682 struct DenseMapInfo<AAPointerInfo::Access> : DenseMapInfo<Instruction *> {
683   using Access = AAPointerInfo::Access;
684   static inline Access getEmptyKey();
685   static inline Access getTombstoneKey();
686   static unsigned getHashValue(const Access &A);
687   static bool isEqual(const Access &LHS, const Access &RHS);
688 };
689 
690 /// Helper that allows RangeTy as a key in a DenseMap.
691 template <> struct DenseMapInfo<AA::RangeTy> {
692   static inline AA::RangeTy getEmptyKey() {
693     auto EmptyKey = DenseMapInfo<int64_t>::getEmptyKey();
694     return AA::RangeTy{EmptyKey, EmptyKey};
695   }
696 
697   static inline AA::RangeTy getTombstoneKey() {
698     auto TombstoneKey = DenseMapInfo<int64_t>::getTombstoneKey();
699     return AA::RangeTy{TombstoneKey, TombstoneKey};
700   }
701 
702   static unsigned getHashValue(const AA::RangeTy &Range) {
703     return detail::combineHashValue(
704         DenseMapInfo<int64_t>::getHashValue(Range.Offset),
705         DenseMapInfo<int64_t>::getHashValue(Range.Size));
706   }
707 
708   static bool isEqual(const AA::RangeTy &A, const AA::RangeTy B) {
709     return A == B;
710   }
711 };
712 
713 /// Helper for AA::PointerInfo::Access DenseMap/Set usage ignoring everythign
714 /// but the instruction
715 struct AccessAsInstructionInfo : DenseMapInfo<Instruction *> {
716   using Base = DenseMapInfo<Instruction *>;
717   using Access = AAPointerInfo::Access;
718   static inline Access getEmptyKey();
719   static inline Access getTombstoneKey();
720   static unsigned getHashValue(const Access &A);
721   static bool isEqual(const Access &LHS, const Access &RHS);
722 };
723 
724 } // namespace llvm
725 
726 /// A type to track pointer/struct usage and accesses for AAPointerInfo.
727 struct AA::PointerInfo::State : public AbstractState {
728   /// Return the best possible representable state.
729   static State getBestState(const State &SIS) { return State(); }
730 
731   /// Return the worst possible representable state.
732   static State getWorstState(const State &SIS) {
733     State R;
734     R.indicatePessimisticFixpoint();
735     return R;
736   }
737 
738   State() = default;
739   State(State &&SIS) = default;
740 
741   const State &getAssumed() const { return *this; }
742 
743   /// See AbstractState::isValidState().
744   bool isValidState() const override { return BS.isValidState(); }
745 
746   /// See AbstractState::isAtFixpoint().
747   bool isAtFixpoint() const override { return BS.isAtFixpoint(); }
748 
749   /// See AbstractState::indicateOptimisticFixpoint().
750   ChangeStatus indicateOptimisticFixpoint() override {
751     BS.indicateOptimisticFixpoint();
752     return ChangeStatus::UNCHANGED;
753   }
754 
755   /// See AbstractState::indicatePessimisticFixpoint().
756   ChangeStatus indicatePessimisticFixpoint() override {
757     BS.indicatePessimisticFixpoint();
758     return ChangeStatus::CHANGED;
759   }
760 
761   State &operator=(const State &R) {
762     if (this == &R)
763       return *this;
764     BS = R.BS;
765     AccessList = R.AccessList;
766     OffsetBins = R.OffsetBins;
767     RemoteIMap = R.RemoteIMap;
768     return *this;
769   }
770 
771   State &operator=(State &&R) {
772     if (this == &R)
773       return *this;
774     std::swap(BS, R.BS);
775     std::swap(AccessList, R.AccessList);
776     std::swap(OffsetBins, R.OffsetBins);
777     std::swap(RemoteIMap, R.RemoteIMap);
778     return *this;
779   }
780 
781   /// Add a new Access to the state at offset \p Offset and with size \p Size.
782   /// The access is associated with \p I, writes \p Content (if anything), and
783   /// is of kind \p Kind. If an Access already exists for the same \p I and same
784   /// \p RemoteI, the two are combined, potentially losing information about
785   /// offset and size. The resulting access must now be moved from its original
786   /// OffsetBin to the bin for its new offset.
787   ///
788   /// \Returns CHANGED, if the state changed, UNCHANGED otherwise.
789   ChangeStatus addAccess(Attributor &A, const AAPointerInfo::RangeList &Ranges,
790                          Instruction &I, std::optional<Value *> Content,
791                          AAPointerInfo::AccessKind Kind, Type *Ty,
792                          Instruction *RemoteI = nullptr);
793 
794   using OffsetBinsTy = DenseMap<RangeTy, SmallSet<unsigned, 4>>;
795 
796   using const_bin_iterator = OffsetBinsTy::const_iterator;
797   const_bin_iterator begin() const { return OffsetBins.begin(); }
798   const_bin_iterator end() const { return OffsetBins.end(); }
799 
800   const AAPointerInfo::Access &getAccess(unsigned Index) const {
801     return AccessList[Index];
802   }
803 
804 protected:
805   // Every memory instruction results in an Access object. We maintain a list of
806   // all Access objects that we own, along with the following maps:
807   //
808   // - OffsetBins: RangeTy -> { Access }
809   // - RemoteIMap: RemoteI x LocalI -> Access
810   //
811   // A RemoteI is any instruction that accesses memory. RemoteI is different
812   // from LocalI if and only if LocalI is a call; then RemoteI is some
813   // instruction in the callgraph starting from LocalI. Multiple paths in the
814   // callgraph from LocalI to RemoteI may produce multiple accesses, but these
815   // are all combined into a single Access object. This may result in loss of
816   // information in RangeTy in the Access object.
817   SmallVector<AAPointerInfo::Access> AccessList;
818   OffsetBinsTy OffsetBins;
819   DenseMap<const Instruction *, SmallVector<unsigned>> RemoteIMap;
820 
821   /// See AAPointerInfo::forallInterferingAccesses.
822   bool forallInterferingAccesses(
823       AA::RangeTy Range,
824       function_ref<bool(const AAPointerInfo::Access &, bool)> CB) const {
825     if (!isValidState())
826       return false;
827 
828     for (const auto &It : OffsetBins) {
829       AA::RangeTy ItRange = It.getFirst();
830       if (!Range.mayOverlap(ItRange))
831         continue;
832       bool IsExact = Range == ItRange && !Range.offsetOrSizeAreUnknown();
833       for (auto Index : It.getSecond()) {
834         auto &Access = AccessList[Index];
835         if (!CB(Access, IsExact))
836           return false;
837       }
838     }
839     return true;
840   }
841 
842   /// See AAPointerInfo::forallInterferingAccesses.
843   bool forallInterferingAccesses(
844       Instruction &I,
845       function_ref<bool(const AAPointerInfo::Access &, bool)> CB,
846       AA::RangeTy &Range) const {
847     if (!isValidState())
848       return false;
849 
850     auto LocalList = RemoteIMap.find(&I);
851     if (LocalList == RemoteIMap.end()) {
852       return true;
853     }
854 
855     for (unsigned Index : LocalList->getSecond()) {
856       for (auto &R : AccessList[Index]) {
857         Range &= R;
858         if (Range.offsetOrSizeAreUnknown())
859           break;
860       }
861     }
862     return forallInterferingAccesses(Range, CB);
863   }
864 
865 private:
866   /// State to track fixpoint and validity.
867   BooleanState BS;
868 };
869 
870 ChangeStatus AA::PointerInfo::State::addAccess(
871     Attributor &A, const AAPointerInfo::RangeList &Ranges, Instruction &I,
872     std::optional<Value *> Content, AAPointerInfo::AccessKind Kind, Type *Ty,
873     Instruction *RemoteI) {
874   RemoteI = RemoteI ? RemoteI : &I;
875 
876   // Check if we have an access for this instruction, if not, simply add it.
877   auto &LocalList = RemoteIMap[RemoteI];
878   bool AccExists = false;
879   unsigned AccIndex = AccessList.size();
880   for (auto Index : LocalList) {
881     auto &A = AccessList[Index];
882     if (A.getLocalInst() == &I) {
883       AccExists = true;
884       AccIndex = Index;
885       break;
886     }
887   }
888 
889   auto AddToBins = [&](const AAPointerInfo::RangeList &ToAdd) {
890     LLVM_DEBUG(
891       if (ToAdd.size())
892         dbgs() << "[AAPointerInfo] Inserting access in new offset bins\n";
893     );
894 
895     for (auto Key : ToAdd) {
896       LLVM_DEBUG(dbgs() << "    key " << Key << "\n");
897       OffsetBins[Key].insert(AccIndex);
898     }
899   };
900 
901   if (!AccExists) {
902     AccessList.emplace_back(&I, RemoteI, Ranges, Content, Kind, Ty);
903     assert((AccessList.size() == AccIndex + 1) &&
904            "New Access should have been at AccIndex");
905     LocalList.push_back(AccIndex);
906     AddToBins(AccessList[AccIndex].getRanges());
907     return ChangeStatus::CHANGED;
908   }
909 
910   // Combine the new Access with the existing Access, and then update the
911   // mapping in the offset bins.
912   AAPointerInfo::Access Acc(&I, RemoteI, Ranges, Content, Kind, Ty);
913   auto &Current = AccessList[AccIndex];
914   auto Before = Current;
915   Current &= Acc;
916   if (Current == Before)
917     return ChangeStatus::UNCHANGED;
918 
919   auto &ExistingRanges = Before.getRanges();
920   auto &NewRanges = Current.getRanges();
921 
922   // Ranges that are in the old access but not the new access need to be removed
923   // from the offset bins.
924   AAPointerInfo::RangeList ToRemove;
925   AAPointerInfo::RangeList::set_difference(ExistingRanges, NewRanges, ToRemove);
926   LLVM_DEBUG(
927     if (ToRemove.size())
928       dbgs() << "[AAPointerInfo] Removing access from old offset bins\n";
929   );
930 
931   for (auto Key : ToRemove) {
932     LLVM_DEBUG(dbgs() << "    key " << Key << "\n");
933     assert(OffsetBins.count(Key) && "Existing Access must be in some bin.");
934     auto &Bin = OffsetBins[Key];
935     assert(Bin.count(AccIndex) &&
936            "Expected bin to actually contain the Access.");
937     Bin.erase(AccIndex);
938   }
939 
940   // Ranges that are in the new access but not the old access need to be added
941   // to the offset bins.
942   AAPointerInfo::RangeList ToAdd;
943   AAPointerInfo::RangeList::set_difference(NewRanges, ExistingRanges, ToAdd);
944   AddToBins(ToAdd);
945   return ChangeStatus::CHANGED;
946 }
947 
948 namespace {
949 
950 /// A helper containing a list of offsets computed for a Use. Ideally this
951 /// list should be strictly ascending, but we ensure that only when we
952 /// actually translate the list of offsets to a RangeList.
953 struct OffsetInfo {
954   using VecTy = SmallVector<int64_t>;
955   using const_iterator = VecTy::const_iterator;
956   VecTy Offsets;
957 
958   const_iterator begin() const { return Offsets.begin(); }
959   const_iterator end() const { return Offsets.end(); }
960 
961   bool operator==(const OffsetInfo &RHS) const {
962     return Offsets == RHS.Offsets;
963   }
964 
965   bool operator!=(const OffsetInfo &RHS) const { return !(*this == RHS); }
966 
967   void insert(int64_t Offset) { Offsets.push_back(Offset); }
968   bool isUnassigned() const { return Offsets.size() == 0; }
969 
970   bool isUnknown() const {
971     if (isUnassigned())
972       return false;
973     if (Offsets.size() == 1)
974       return Offsets.front() == AA::RangeTy::Unknown;
975     return false;
976   }
977 
978   void setUnknown() {
979     Offsets.clear();
980     Offsets.push_back(AA::RangeTy::Unknown);
981   }
982 
983   void addToAll(int64_t Inc) {
984     for (auto &Offset : Offsets) {
985       Offset += Inc;
986     }
987   }
988 
989   /// Copy offsets from \p R into the current list.
990   ///
991   /// Ideally all lists should be strictly ascending, but we defer that to the
992   /// actual use of the list. So we just blindly append here.
993   void merge(const OffsetInfo &R) { Offsets.append(R.Offsets); }
994 };
995 
996 #ifndef NDEBUG
997 static raw_ostream &operator<<(raw_ostream &OS, const OffsetInfo &OI) {
998   ListSeparator LS;
999   OS << "[";
1000   for (auto Offset : OI) {
1001     OS << LS << Offset;
1002   }
1003   OS << "]";
1004   return OS;
1005 }
1006 #endif // NDEBUG
1007 
1008 struct AAPointerInfoImpl
1009     : public StateWrapper<AA::PointerInfo::State, AAPointerInfo> {
1010   using BaseTy = StateWrapper<AA::PointerInfo::State, AAPointerInfo>;
1011   AAPointerInfoImpl(const IRPosition &IRP, Attributor &A) : BaseTy(IRP) {}
1012 
1013   /// See AbstractAttribute::getAsStr().
1014   const std::string getAsStr() const override {
1015     return std::string("PointerInfo ") +
1016            (isValidState() ? (std::string("#") +
1017                               std::to_string(OffsetBins.size()) + " bins")
1018                            : "<invalid>");
1019   }
1020 
1021   /// See AbstractAttribute::manifest(...).
1022   ChangeStatus manifest(Attributor &A) override {
1023     return AAPointerInfo::manifest(A);
1024   }
1025 
1026   bool forallInterferingAccesses(
1027       AA::RangeTy Range,
1028       function_ref<bool(const AAPointerInfo::Access &, bool)> CB)
1029       const override {
1030     return State::forallInterferingAccesses(Range, CB);
1031   }
1032 
1033   bool forallInterferingAccesses(
1034       Attributor &A, const AbstractAttribute &QueryingAA, Instruction &I,
1035       function_ref<bool(const Access &, bool)> UserCB, bool &HasBeenWrittenTo,
1036       AA::RangeTy &Range) const override {
1037     HasBeenWrittenTo = false;
1038 
1039     SmallPtrSet<const Access *, 8> DominatingWrites;
1040     SmallVector<std::pair<const Access *, bool>, 8> InterferingAccesses;
1041 
1042     Function &Scope = *I.getFunction();
1043     const auto &NoSyncAA = A.getAAFor<AANoSync>(
1044         QueryingAA, IRPosition::function(Scope), DepClassTy::OPTIONAL);
1045     const auto *ExecDomainAA = A.lookupAAFor<AAExecutionDomain>(
1046         IRPosition::function(Scope), &QueryingAA, DepClassTy::NONE);
1047     bool AllInSameNoSyncFn = NoSyncAA.isAssumedNoSync();
1048     bool InstIsExecutedByInitialThreadOnly =
1049         ExecDomainAA && ExecDomainAA->isExecutedByInitialThreadOnly(I);
1050     bool InstIsExecutedInAlignedRegion =
1051         ExecDomainAA && ExecDomainAA->isExecutedInAlignedRegion(A, I);
1052     if (InstIsExecutedInAlignedRegion || InstIsExecutedByInitialThreadOnly)
1053       A.recordDependence(*ExecDomainAA, QueryingAA, DepClassTy::OPTIONAL);
1054 
1055     InformationCache &InfoCache = A.getInfoCache();
1056     bool IsThreadLocalObj =
1057         AA::isAssumedThreadLocalObject(A, getAssociatedValue(), *this);
1058 
1059     // Helper to determine if we need to consider threading, which we cannot
1060     // right now. However, if the function is (assumed) nosync or the thread
1061     // executing all instructions is the main thread only we can ignore
1062     // threading. Also, thread-local objects do not require threading reasoning.
1063     // Finally, we can ignore threading if either access is executed in an
1064     // aligned region.
1065     auto CanIgnoreThreadingForInst = [&](const Instruction &I) -> bool {
1066       if (IsThreadLocalObj || AllInSameNoSyncFn)
1067         return true;
1068       const auto *FnExecDomainAA =
1069           I.getFunction() == &Scope
1070               ? ExecDomainAA
1071               : A.lookupAAFor<AAExecutionDomain>(
1072                     IRPosition::function(*I.getFunction()), &QueryingAA,
1073                     DepClassTy::NONE);
1074       if (!FnExecDomainAA)
1075         return false;
1076       if (InstIsExecutedInAlignedRegion ||
1077           FnExecDomainAA->isExecutedInAlignedRegion(A, I)) {
1078         A.recordDependence(*FnExecDomainAA, QueryingAA, DepClassTy::OPTIONAL);
1079         return true;
1080       }
1081       if (InstIsExecutedByInitialThreadOnly &&
1082           FnExecDomainAA->isExecutedByInitialThreadOnly(I)) {
1083         A.recordDependence(*FnExecDomainAA, QueryingAA, DepClassTy::OPTIONAL);
1084         return true;
1085       }
1086       return false;
1087     };
1088 
1089     // Helper to determine if the access is executed by the same thread as the
1090     // given instruction, for now it is sufficient to avoid any potential
1091     // threading effects as we cannot deal with them anyway.
1092     auto CanIgnoreThreading = [&](const Access &Acc) -> bool {
1093       return CanIgnoreThreadingForInst(*Acc.getRemoteInst()) ||
1094              (Acc.getRemoteInst() != Acc.getLocalInst() &&
1095               CanIgnoreThreadingForInst(*Acc.getLocalInst()));
1096     };
1097 
1098     // TODO: Use inter-procedural reachability and dominance.
1099     const auto &NoRecurseAA = A.getAAFor<AANoRecurse>(
1100         QueryingAA, IRPosition::function(Scope), DepClassTy::OPTIONAL);
1101 
1102     const bool FindInterferingWrites = I.mayReadFromMemory();
1103     const bool FindInterferingReads = I.mayWriteToMemory();
1104     const bool UseDominanceReasoning =
1105         FindInterferingWrites && NoRecurseAA.isKnownNoRecurse();
1106     const DominatorTree *DT =
1107         InfoCache.getAnalysisResultForFunction<DominatorTreeAnalysis>(Scope);
1108 
1109     // Helper to check if a value has "kernel lifetime", that is it will not
1110     // outlive a GPU kernel. This is true for shared, constant, and local
1111     // globals on AMD and NVIDIA GPUs.
1112     auto HasKernelLifetime = [&](Value *V, Module &M) {
1113       Triple T(M.getTargetTriple());
1114       if (!(T.isAMDGPU() || T.isNVPTX()))
1115         return false;
1116       switch (AA::GPUAddressSpace(V->getType()->getPointerAddressSpace())) {
1117       case AA::GPUAddressSpace::Shared:
1118       case AA::GPUAddressSpace::Constant:
1119       case AA::GPUAddressSpace::Local:
1120         return true;
1121       default:
1122         return false;
1123       };
1124     };
1125 
1126     // The IsLiveInCalleeCB will be used by the AA::isPotentiallyReachable query
1127     // to determine if we should look at reachability from the callee. For
1128     // certain pointers we know the lifetime and we do not have to step into the
1129     // callee to determine reachability as the pointer would be dead in the
1130     // callee. See the conditional initialization below.
1131     std::function<bool(const Function &)> IsLiveInCalleeCB;
1132 
1133     if (auto *AI = dyn_cast<AllocaInst>(&getAssociatedValue())) {
1134       // If the alloca containing function is not recursive the alloca
1135       // must be dead in the callee.
1136       const Function *AIFn = AI->getFunction();
1137       const auto &NoRecurseAA = A.getAAFor<AANoRecurse>(
1138           *this, IRPosition::function(*AIFn), DepClassTy::OPTIONAL);
1139       if (NoRecurseAA.isAssumedNoRecurse()) {
1140         IsLiveInCalleeCB = [AIFn](const Function &Fn) { return AIFn != &Fn; };
1141       }
1142     } else if (auto *GV = dyn_cast<GlobalValue>(&getAssociatedValue())) {
1143       // If the global has kernel lifetime we can stop if we reach a kernel
1144       // as it is "dead" in the (unknown) callees.
1145       if (HasKernelLifetime(GV, *GV->getParent()))
1146         IsLiveInCalleeCB = [](const Function &Fn) {
1147           return !Fn.hasFnAttribute("kernel");
1148         };
1149     }
1150 
1151     // Set of accesses/instructions that will overwrite the result and are
1152     // therefore blockers in the reachability traversal.
1153     AA::InstExclusionSetTy ExclusionSet;
1154 
1155     auto AccessCB = [&](const Access &Acc, bool Exact) {
1156       if (Exact && Acc.isMustAccess() && Acc.getRemoteInst() != &I) {
1157         if (Acc.isWrite() || (isa<LoadInst>(I) && Acc.isWriteOrAssumption()))
1158           ExclusionSet.insert(Acc.getRemoteInst());
1159       }
1160 
1161       if ((!FindInterferingWrites || !Acc.isWriteOrAssumption()) &&
1162           (!FindInterferingReads || !Acc.isRead()))
1163         return true;
1164 
1165       bool Dominates = FindInterferingWrites && DT && Exact &&
1166                        Acc.isMustAccess() &&
1167                        (Acc.getRemoteInst()->getFunction() == &Scope) &&
1168                        DT->dominates(Acc.getRemoteInst(), &I);
1169       if (Dominates)
1170         DominatingWrites.insert(&Acc);
1171 
1172       // Track if all interesting accesses are in the same `nosync` function as
1173       // the given instruction.
1174       AllInSameNoSyncFn &= Acc.getRemoteInst()->getFunction() == &Scope;
1175 
1176       InterferingAccesses.push_back({&Acc, Exact});
1177       return true;
1178     };
1179     if (!State::forallInterferingAccesses(I, AccessCB, Range))
1180       return false;
1181 
1182     HasBeenWrittenTo = !DominatingWrites.empty();
1183 
1184     // Dominating writes form a chain, find the least/lowest member.
1185     Instruction *LeastDominatingWriteInst = nullptr;
1186     for (const Access *Acc : DominatingWrites) {
1187       if (!LeastDominatingWriteInst) {
1188         LeastDominatingWriteInst = Acc->getRemoteInst();
1189       } else if (DT->dominates(LeastDominatingWriteInst,
1190                                Acc->getRemoteInst())) {
1191         LeastDominatingWriteInst = Acc->getRemoteInst();
1192       }
1193     }
1194 
1195     // Helper to determine if we can skip a specific write access.
1196     auto CanSkipAccess = [&](const Access &Acc, bool Exact) {
1197       if (!CanIgnoreThreading(Acc))
1198         return false;
1199 
1200       // Check read (RAW) dependences and write (WAR) dependences as necessary.
1201       // If we successfully excluded all effects we are interested in, the
1202       // access can be skipped.
1203       bool ReadChecked = !FindInterferingReads;
1204       bool WriteChecked = !FindInterferingWrites;
1205 
1206       // If the instruction cannot reach the access, the former does not
1207       // interfere with what the access reads.
1208       if (!ReadChecked) {
1209         if (!AA::isPotentiallyReachable(A, I, *Acc.getRemoteInst(), QueryingAA,
1210                                         &ExclusionSet, IsLiveInCalleeCB))
1211           ReadChecked = true;
1212       }
1213       // If the instruction cannot be reach from the access, the latter does not
1214       // interfere with what the instruction reads.
1215       if (!WriteChecked) {
1216         if (!AA::isPotentiallyReachable(A, *Acc.getRemoteInst(), I, QueryingAA,
1217                                         &ExclusionSet, IsLiveInCalleeCB))
1218           WriteChecked = true;
1219       }
1220 
1221       // If we still might be affected by the write of the access but there are
1222       // dominating writes in the function of the instruction
1223       // (HasBeenWrittenTo), we can try to reason that the access is overwritten
1224       // by them. This would have happend above if they are all in the same
1225       // function, so we only check the inter-procedural case. Effectively, we
1226       // want to show that there is no call after the dominting write that might
1227       // reach the access, and when it returns reach the instruction with the
1228       // updated value. To this end, we iterate all call sites, check if they
1229       // might reach the instruction without going through another access
1230       // (ExclusionSet) and at the same time might reach the access. However,
1231       // that is all part of AAInterFnReachability.
1232       if (!WriteChecked && HasBeenWrittenTo &&
1233           Acc.getRemoteInst()->getFunction() != &Scope) {
1234 
1235         const auto &FnReachabilityAA = A.getAAFor<AAInterFnReachability>(
1236             QueryingAA, IRPosition::function(Scope), DepClassTy::OPTIONAL);
1237 
1238         // Without going backwards in the call tree, can we reach the access
1239         // from the least dominating write. Do not allow to pass the instruction
1240         // itself either.
1241         bool Inserted = ExclusionSet.insert(&I).second;
1242 
1243         if (!FnReachabilityAA.instructionCanReach(
1244                 A, *LeastDominatingWriteInst,
1245                 *Acc.getRemoteInst()->getFunction(), &ExclusionSet))
1246           WriteChecked = true;
1247 
1248         if (Inserted)
1249           ExclusionSet.erase(&I);
1250       }
1251 
1252       if (ReadChecked && WriteChecked)
1253         return true;
1254 
1255       if (!DT || !UseDominanceReasoning)
1256         return false;
1257       if (!DominatingWrites.count(&Acc))
1258         return false;
1259       return LeastDominatingWriteInst != Acc.getRemoteInst();
1260     };
1261 
1262     // Run the user callback on all accesses we cannot skip and return if
1263     // that succeeded for all or not.
1264     for (auto &It : InterferingAccesses) {
1265       if ((!AllInSameNoSyncFn && !IsThreadLocalObj && !ExecDomainAA) ||
1266           !CanSkipAccess(*It.first, It.second)) {
1267         if (!UserCB(*It.first, It.second))
1268           return false;
1269       }
1270     }
1271     return true;
1272   }
1273 
1274   ChangeStatus translateAndAddStateFromCallee(Attributor &A,
1275                                               const AAPointerInfo &OtherAA,
1276                                               CallBase &CB) {
1277     using namespace AA::PointerInfo;
1278     if (!OtherAA.getState().isValidState() || !isValidState())
1279       return indicatePessimisticFixpoint();
1280 
1281     const auto &OtherAAImpl = static_cast<const AAPointerInfoImpl &>(OtherAA);
1282     bool IsByval = OtherAAImpl.getAssociatedArgument()->hasByValAttr();
1283 
1284     // Combine the accesses bin by bin.
1285     ChangeStatus Changed = ChangeStatus::UNCHANGED;
1286     const auto &State = OtherAAImpl.getState();
1287     for (const auto &It : State) {
1288       for (auto Index : It.getSecond()) {
1289         const auto &RAcc = State.getAccess(Index);
1290         if (IsByval && !RAcc.isRead())
1291           continue;
1292         bool UsedAssumedInformation = false;
1293         AccessKind AK = RAcc.getKind();
1294         auto Content = A.translateArgumentToCallSiteContent(
1295             RAcc.getContent(), CB, *this, UsedAssumedInformation);
1296         AK = AccessKind(AK & (IsByval ? AccessKind::AK_R : AccessKind::AK_RW));
1297         AK = AccessKind(AK | (RAcc.isMayAccess() ? AK_MAY : AK_MUST));
1298 
1299         Changed |= addAccess(A, RAcc.getRanges(), CB, Content, AK,
1300                              RAcc.getType(), RAcc.getRemoteInst());
1301       }
1302     }
1303     return Changed;
1304   }
1305 
1306   ChangeStatus translateAndAddState(Attributor &A, const AAPointerInfo &OtherAA,
1307                                     const OffsetInfo &Offsets, CallBase &CB) {
1308     using namespace AA::PointerInfo;
1309     if (!OtherAA.getState().isValidState() || !isValidState())
1310       return indicatePessimisticFixpoint();
1311 
1312     const auto &OtherAAImpl = static_cast<const AAPointerInfoImpl &>(OtherAA);
1313 
1314     // Combine the accesses bin by bin.
1315     ChangeStatus Changed = ChangeStatus::UNCHANGED;
1316     const auto &State = OtherAAImpl.getState();
1317     for (const auto &It : State) {
1318       for (auto Index : It.getSecond()) {
1319         const auto &RAcc = State.getAccess(Index);
1320         for (auto Offset : Offsets) {
1321           auto NewRanges = Offset == AA::RangeTy::Unknown
1322                                ? AA::RangeTy::getUnknown()
1323                                : RAcc.getRanges();
1324           if (!NewRanges.isUnknown()) {
1325             NewRanges.addToAllOffsets(Offset);
1326           }
1327           Changed |=
1328               addAccess(A, NewRanges, CB, RAcc.getContent(), RAcc.getKind(),
1329                         RAcc.getType(), RAcc.getRemoteInst());
1330         }
1331       }
1332     }
1333     return Changed;
1334   }
1335 
1336   /// Statistic tracking for all AAPointerInfo implementations.
1337   /// See AbstractAttribute::trackStatistics().
1338   void trackPointerInfoStatistics(const IRPosition &IRP) const {}
1339 
1340   /// Dump the state into \p O.
1341   void dumpState(raw_ostream &O) {
1342     for (auto &It : OffsetBins) {
1343       O << "[" << It.first.Offset << "-" << It.first.Offset + It.first.Size
1344         << "] : " << It.getSecond().size() << "\n";
1345       for (auto AccIndex : It.getSecond()) {
1346         auto &Acc = AccessList[AccIndex];
1347         O << "     - " << Acc.getKind() << " - " << *Acc.getLocalInst() << "\n";
1348         if (Acc.getLocalInst() != Acc.getRemoteInst())
1349           O << "     -->                         " << *Acc.getRemoteInst()
1350             << "\n";
1351         if (!Acc.isWrittenValueYetUndetermined()) {
1352           if (Acc.getWrittenValue())
1353             O << "       - c: " << *Acc.getWrittenValue() << "\n";
1354           else
1355             O << "       - c: <unknown>\n";
1356         }
1357       }
1358     }
1359   }
1360 };
1361 
1362 struct AAPointerInfoFloating : public AAPointerInfoImpl {
1363   using AccessKind = AAPointerInfo::AccessKind;
1364   AAPointerInfoFloating(const IRPosition &IRP, Attributor &A)
1365       : AAPointerInfoImpl(IRP, A) {}
1366 
1367   /// Deal with an access and signal if it was handled successfully.
1368   bool handleAccess(Attributor &A, Instruction &I,
1369                     std::optional<Value *> Content, AccessKind Kind,
1370                     SmallVectorImpl<int64_t> &Offsets, ChangeStatus &Changed,
1371                     Type &Ty) {
1372     using namespace AA::PointerInfo;
1373     auto Size = AA::RangeTy::Unknown;
1374     const DataLayout &DL = A.getDataLayout();
1375     TypeSize AccessSize = DL.getTypeStoreSize(&Ty);
1376     if (!AccessSize.isScalable())
1377       Size = AccessSize.getFixedValue();
1378 
1379     // Make a strictly ascending list of offsets as required by addAccess()
1380     llvm::sort(Offsets);
1381     auto *Last = std::unique(Offsets.begin(), Offsets.end());
1382     Offsets.erase(Last, Offsets.end());
1383 
1384     VectorType *VT = dyn_cast<VectorType>(&Ty);
1385     if (!VT || VT->getElementCount().isScalable() ||
1386         !Content.value_or(nullptr) || !isa<Constant>(*Content) ||
1387         (*Content)->getType() != VT ||
1388         DL.getTypeStoreSize(VT->getElementType()).isScalable()) {
1389       Changed = Changed | addAccess(A, {Offsets, Size}, I, Content, Kind, &Ty);
1390     } else {
1391       // Handle vector stores with constant content element-wise.
1392       // TODO: We could look for the elements or create instructions
1393       //       representing them.
1394       // TODO: We need to push the Content into the range abstraction
1395       //       (AA::RangeTy) to allow different content values for different
1396       //       ranges. ranges. Hence, support vectors storing different values.
1397       Type *ElementType = VT->getElementType();
1398       int64_t ElementSize = DL.getTypeStoreSize(ElementType).getFixedValue();
1399       auto *ConstContent = cast<Constant>(*Content);
1400       Type *Int32Ty = Type::getInt32Ty(ElementType->getContext());
1401       SmallVector<int64_t> ElementOffsets(Offsets.begin(), Offsets.end());
1402 
1403       for (int i = 0, e = VT->getElementCount().getFixedValue(); i != e; ++i) {
1404         Value *ElementContent = ConstantExpr::getExtractElement(
1405             ConstContent, ConstantInt::get(Int32Ty, i));
1406 
1407         // Add the element access.
1408         Changed = Changed | addAccess(A, {ElementOffsets, ElementSize}, I,
1409                                       ElementContent, Kind, ElementType);
1410 
1411         // Advance the offsets for the next element.
1412         for (auto &ElementOffset : ElementOffsets)
1413           ElementOffset += ElementSize;
1414       }
1415     }
1416     return true;
1417   };
1418 
1419   /// See AbstractAttribute::updateImpl(...).
1420   ChangeStatus updateImpl(Attributor &A) override;
1421 
1422   /// If the indices to \p GEP can be traced to constants, incorporate all
1423   /// of these into \p UsrOI.
1424   ///
1425   /// \return true iff \p UsrOI is updated.
1426   bool collectConstantsForGEP(Attributor &A, const DataLayout &DL,
1427                               OffsetInfo &UsrOI, const OffsetInfo &PtrOI,
1428                               const GEPOperator *GEP);
1429 
1430   /// See AbstractAttribute::trackStatistics()
1431   void trackStatistics() const override {
1432     AAPointerInfoImpl::trackPointerInfoStatistics(getIRPosition());
1433   }
1434 };
1435 
1436 bool AAPointerInfoFloating::collectConstantsForGEP(Attributor &A,
1437                                                    const DataLayout &DL,
1438                                                    OffsetInfo &UsrOI,
1439                                                    const OffsetInfo &PtrOI,
1440                                                    const GEPOperator *GEP) {
1441   unsigned BitWidth = DL.getIndexTypeSizeInBits(GEP->getType());
1442   MapVector<Value *, APInt> VariableOffsets;
1443   APInt ConstantOffset(BitWidth, 0);
1444 
1445   assert(!UsrOI.isUnknown() && !PtrOI.isUnknown() &&
1446          "Don't look for constant values if the offset has already been "
1447          "determined to be unknown.");
1448 
1449   if (!GEP->collectOffset(DL, BitWidth, VariableOffsets, ConstantOffset)) {
1450     UsrOI.setUnknown();
1451     return true;
1452   }
1453 
1454   LLVM_DEBUG(dbgs() << "[AAPointerInfo] GEP offset is "
1455                     << (VariableOffsets.empty() ? "" : "not") << " constant "
1456                     << *GEP << "\n");
1457 
1458   auto Union = PtrOI;
1459   Union.addToAll(ConstantOffset.getSExtValue());
1460 
1461   // Each VI in VariableOffsets has a set of potential constant values. Every
1462   // combination of elements, picked one each from these sets, is separately
1463   // added to the original set of offsets, thus resulting in more offsets.
1464   for (const auto &VI : VariableOffsets) {
1465     auto &PotentialConstantsAA = A.getAAFor<AAPotentialConstantValues>(
1466         *this, IRPosition::value(*VI.first), DepClassTy::OPTIONAL);
1467     if (!PotentialConstantsAA.isValidState()) {
1468       UsrOI.setUnknown();
1469       return true;
1470     }
1471 
1472     // UndefValue is treated as a zero, which leaves Union as is.
1473     if (PotentialConstantsAA.undefIsContained())
1474       continue;
1475 
1476     // We need at least one constant in every set to compute an actual offset.
1477     // Otherwise, we end up pessimizing AAPointerInfo by respecting offsets that
1478     // don't actually exist. In other words, the absence of constant values
1479     // implies that the operation can be assumed dead for now.
1480     auto &AssumedSet = PotentialConstantsAA.getAssumedSet();
1481     if (AssumedSet.empty())
1482       return false;
1483 
1484     OffsetInfo Product;
1485     for (const auto &ConstOffset : AssumedSet) {
1486       auto CopyPerOffset = Union;
1487       CopyPerOffset.addToAll(ConstOffset.getSExtValue() *
1488                              VI.second.getZExtValue());
1489       Product.merge(CopyPerOffset);
1490     }
1491     Union = Product;
1492   }
1493 
1494   UsrOI = std::move(Union);
1495   return true;
1496 }
1497 
1498 ChangeStatus AAPointerInfoFloating::updateImpl(Attributor &A) {
1499   using namespace AA::PointerInfo;
1500   ChangeStatus Changed = ChangeStatus::UNCHANGED;
1501   const DataLayout &DL = A.getDataLayout();
1502   Value &AssociatedValue = getAssociatedValue();
1503 
1504   DenseMap<Value *, OffsetInfo> OffsetInfoMap;
1505   OffsetInfoMap[&AssociatedValue].insert(0);
1506 
1507   auto HandlePassthroughUser = [&](Value *Usr, Value *CurPtr, bool &Follow) {
1508     // One does not simply walk into a map and assign a reference to a possibly
1509     // new location. That can cause an invalidation before the assignment
1510     // happens, like so:
1511     //
1512     //   OffsetInfoMap[Usr] = OffsetInfoMap[CurPtr]; /* bad idea! */
1513     //
1514     // The RHS is a reference that may be invalidated by an insertion caused by
1515     // the LHS. So we ensure that the side-effect of the LHS happens first.
1516     auto &UsrOI = OffsetInfoMap[Usr];
1517     auto &PtrOI = OffsetInfoMap[CurPtr];
1518     assert(!PtrOI.isUnassigned() &&
1519            "Cannot pass through if the input Ptr was not visited!");
1520     UsrOI = PtrOI;
1521     Follow = true;
1522     return true;
1523   };
1524 
1525   const auto *F = getAnchorScope();
1526   const auto *CI =
1527       F ? A.getInfoCache().getAnalysisResultForFunction<CycleAnalysis>(*F)
1528         : nullptr;
1529   const auto *TLI =
1530       F ? A.getInfoCache().getTargetLibraryInfoForFunction(*F) : nullptr;
1531 
1532   auto UsePred = [&](const Use &U, bool &Follow) -> bool {
1533     Value *CurPtr = U.get();
1534     User *Usr = U.getUser();
1535     LLVM_DEBUG(dbgs() << "[AAPointerInfo] Analyze " << *CurPtr << " in " << *Usr
1536                       << "\n");
1537     assert(OffsetInfoMap.count(CurPtr) &&
1538            "The current pointer offset should have been seeded!");
1539 
1540     if (ConstantExpr *CE = dyn_cast<ConstantExpr>(Usr)) {
1541       if (CE->isCast())
1542         return HandlePassthroughUser(Usr, CurPtr, Follow);
1543       if (CE->isCompare())
1544         return true;
1545       if (!isa<GEPOperator>(CE)) {
1546         LLVM_DEBUG(dbgs() << "[AAPointerInfo] Unhandled constant user " << *CE
1547                           << "\n");
1548         return false;
1549       }
1550     }
1551     if (auto *GEP = dyn_cast<GEPOperator>(Usr)) {
1552       // Note the order here, the Usr access might change the map, CurPtr is
1553       // already in it though.
1554       auto &UsrOI = OffsetInfoMap[Usr];
1555       auto &PtrOI = OffsetInfoMap[CurPtr];
1556 
1557       if (UsrOI.isUnknown())
1558         return true;
1559 
1560       if (PtrOI.isUnknown()) {
1561         Follow = true;
1562         UsrOI.setUnknown();
1563         return true;
1564       }
1565 
1566       Follow = collectConstantsForGEP(A, DL, UsrOI, PtrOI, GEP);
1567       return true;
1568     }
1569     if (isa<PtrToIntInst>(Usr))
1570       return false;
1571     if (isa<CastInst>(Usr) || isa<SelectInst>(Usr) || isa<ReturnInst>(Usr))
1572       return HandlePassthroughUser(Usr, CurPtr, Follow);
1573 
1574     // For PHIs we need to take care of the recurrence explicitly as the value
1575     // might change while we iterate through a loop. For now, we give up if
1576     // the PHI is not invariant.
1577     if (isa<PHINode>(Usr)) {
1578       // Note the order here, the Usr access might change the map, CurPtr is
1579       // already in it though.
1580       bool IsFirstPHIUser = !OffsetInfoMap.count(Usr);
1581       auto &UsrOI = OffsetInfoMap[Usr];
1582       auto &PtrOI = OffsetInfoMap[CurPtr];
1583 
1584       // Check if the PHI operand has already an unknown offset as we can't
1585       // improve on that anymore.
1586       if (PtrOI.isUnknown()) {
1587         LLVM_DEBUG(dbgs() << "[AAPointerInfo] PHI operand offset unknown "
1588                           << *CurPtr << " in " << *Usr << "\n");
1589         Follow = !UsrOI.isUnknown();
1590         UsrOI.setUnknown();
1591         return true;
1592       }
1593 
1594       // Check if the PHI is invariant (so far).
1595       if (UsrOI == PtrOI) {
1596         assert(!PtrOI.isUnassigned() &&
1597                "Cannot assign if the current Ptr was not visited!");
1598         LLVM_DEBUG(dbgs() << "[AAPointerInfo] PHI is invariant (so far)");
1599         return true;
1600       }
1601 
1602       // Check if the PHI operand can be traced back to AssociatedValue.
1603       APInt Offset(
1604           DL.getIndexSizeInBits(CurPtr->getType()->getPointerAddressSpace()),
1605           0);
1606       Value *CurPtrBase = CurPtr->stripAndAccumulateConstantOffsets(
1607           DL, Offset, /* AllowNonInbounds */ true);
1608       auto It = OffsetInfoMap.find(CurPtrBase);
1609       if (It == OffsetInfoMap.end()) {
1610         LLVM_DEBUG(dbgs() << "[AAPointerInfo] PHI operand is too complex "
1611                           << *CurPtr << " in " << *Usr << "\n");
1612         UsrOI.setUnknown();
1613         Follow = true;
1614         return true;
1615       }
1616 
1617       auto mayBeInCycleHeader = [](const CycleInfo *CI, const Instruction *I) {
1618         if (!CI)
1619           return true;
1620         auto *BB = I->getParent();
1621         auto *C = CI->getCycle(BB);
1622         if (!C)
1623           return false;
1624         return BB == C->getHeader();
1625       };
1626 
1627       // Check if the PHI operand is not dependent on the PHI itself. Every
1628       // recurrence is a cyclic net of PHIs in the data flow, and has an
1629       // equivalent Cycle in the control flow. One of those PHIs must be in the
1630       // header of that control flow Cycle. This is independent of the choice of
1631       // Cycles reported by CycleInfo. It is sufficient to check the PHIs in
1632       // every Cycle header; if such a node is marked unknown, this will
1633       // eventually propagate through the whole net of PHIs in the recurrence.
1634       if (mayBeInCycleHeader(CI, cast<Instruction>(Usr))) {
1635         auto BaseOI = It->getSecond();
1636         BaseOI.addToAll(Offset.getZExtValue());
1637         if (IsFirstPHIUser || BaseOI == UsrOI) {
1638           LLVM_DEBUG(dbgs() << "[AAPointerInfo] PHI is invariant " << *CurPtr
1639                             << " in " << *Usr << "\n");
1640           return HandlePassthroughUser(Usr, CurPtr, Follow);
1641         }
1642 
1643         LLVM_DEBUG(
1644             dbgs() << "[AAPointerInfo] PHI operand pointer offset mismatch "
1645                    << *CurPtr << " in " << *Usr << "\n");
1646         UsrOI.setUnknown();
1647         Follow = true;
1648         return true;
1649       }
1650 
1651       UsrOI.merge(PtrOI);
1652       Follow = true;
1653       return true;
1654     }
1655 
1656     if (auto *LoadI = dyn_cast<LoadInst>(Usr)) {
1657       // If the access is to a pointer that may or may not be the associated
1658       // value, e.g. due to a PHI, we cannot assume it will be read.
1659       AccessKind AK = AccessKind::AK_R;
1660       if (getUnderlyingObject(CurPtr) == &AssociatedValue)
1661         AK = AccessKind(AK | AccessKind::AK_MUST);
1662       else
1663         AK = AccessKind(AK | AccessKind::AK_MAY);
1664       if (!handleAccess(A, *LoadI, /* Content */ nullptr, AK,
1665                         OffsetInfoMap[CurPtr].Offsets, Changed,
1666                         *LoadI->getType()))
1667         return false;
1668 
1669       auto IsAssumption = [](Instruction &I) {
1670         if (auto *II = dyn_cast<IntrinsicInst>(&I))
1671           return II->isAssumeLikeIntrinsic();
1672         return false;
1673       };
1674 
1675       auto IsImpactedInRange = [&](Instruction *FromI, Instruction *ToI) {
1676         // Check if the assumption and the load are executed together without
1677         // memory modification.
1678         do {
1679           if (FromI->mayWriteToMemory() && !IsAssumption(*FromI))
1680             return true;
1681           FromI = FromI->getNextNonDebugInstruction();
1682         } while (FromI && FromI != ToI);
1683         return false;
1684       };
1685 
1686       BasicBlock *BB = LoadI->getParent();
1687       auto IsValidAssume = [&](IntrinsicInst &IntrI) {
1688         if (IntrI.getIntrinsicID() != Intrinsic::assume)
1689           return false;
1690         BasicBlock *IntrBB = IntrI.getParent();
1691         if (IntrI.getParent() == BB) {
1692           if (IsImpactedInRange(LoadI->getNextNonDebugInstruction(), &IntrI))
1693             return false;
1694         } else {
1695           auto PredIt = pred_begin(IntrBB);
1696           if ((*PredIt) != BB)
1697             return false;
1698           if (++PredIt != pred_end(IntrBB))
1699             return false;
1700           for (auto *SuccBB : successors(BB)) {
1701             if (SuccBB == IntrBB)
1702               continue;
1703             if (isa<UnreachableInst>(SuccBB->getTerminator()))
1704               continue;
1705             return false;
1706           }
1707           if (IsImpactedInRange(LoadI->getNextNonDebugInstruction(),
1708                                 BB->getTerminator()))
1709             return false;
1710           if (IsImpactedInRange(&IntrBB->front(), &IntrI))
1711             return false;
1712         }
1713         return true;
1714       };
1715 
1716       std::pair<Value *, IntrinsicInst *> Assumption;
1717       for (const Use &LoadU : LoadI->uses()) {
1718         if (auto *CmpI = dyn_cast<CmpInst>(LoadU.getUser())) {
1719           if (!CmpI->isEquality() || !CmpI->isTrueWhenEqual())
1720             continue;
1721           for (const Use &CmpU : CmpI->uses()) {
1722             if (auto *IntrI = dyn_cast<IntrinsicInst>(CmpU.getUser())) {
1723               if (!IsValidAssume(*IntrI))
1724                 continue;
1725               int Idx = CmpI->getOperandUse(0) == LoadU;
1726               Assumption = {CmpI->getOperand(Idx), IntrI};
1727               break;
1728             }
1729           }
1730         }
1731         if (Assumption.first)
1732           break;
1733       }
1734 
1735       // Check if we found an assumption associated with this load.
1736       if (!Assumption.first || !Assumption.second)
1737         return true;
1738 
1739       LLVM_DEBUG(dbgs() << "[AAPointerInfo] Assumption found "
1740                         << *Assumption.second << ": " << *LoadI
1741                         << " == " << *Assumption.first << "\n");
1742 
1743       return handleAccess(
1744           A, *Assumption.second, Assumption.first, AccessKind::AK_ASSUMPTION,
1745           OffsetInfoMap[CurPtr].Offsets, Changed, *LoadI->getType());
1746     }
1747 
1748     auto HandleStoreLike = [&](Instruction &I, Value *ValueOp, Type &ValueTy,
1749                                ArrayRef<Value *> OtherOps, AccessKind AK) {
1750       for (auto *OtherOp : OtherOps) {
1751         if (OtherOp == CurPtr) {
1752           LLVM_DEBUG(
1753               dbgs()
1754               << "[AAPointerInfo] Escaping use in store like instruction " << I
1755               << "\n");
1756           return false;
1757         }
1758       }
1759 
1760       // If the access is to a pointer that may or may not be the associated
1761       // value, e.g. due to a PHI, we cannot assume it will be written.
1762       if (getUnderlyingObject(CurPtr) == &AssociatedValue)
1763         AK = AccessKind(AK | AccessKind::AK_MUST);
1764       else
1765         AK = AccessKind(AK | AccessKind::AK_MAY);
1766       bool UsedAssumedInformation = false;
1767       std::optional<Value *> Content = nullptr;
1768       if (ValueOp)
1769         Content = A.getAssumedSimplified(
1770             *ValueOp, *this, UsedAssumedInformation, AA::Interprocedural);
1771       return handleAccess(A, I, Content, AK, OffsetInfoMap[CurPtr].Offsets,
1772                           Changed, ValueTy);
1773     };
1774 
1775     if (auto *StoreI = dyn_cast<StoreInst>(Usr))
1776       return HandleStoreLike(*StoreI, StoreI->getValueOperand(),
1777                              *StoreI->getValueOperand()->getType(),
1778                              {StoreI->getValueOperand()}, AccessKind::AK_W);
1779     if (auto *RMWI = dyn_cast<AtomicRMWInst>(Usr))
1780       return HandleStoreLike(*RMWI, nullptr, *RMWI->getValOperand()->getType(),
1781                              {RMWI->getValOperand()}, AccessKind::AK_RW);
1782     if (auto *CXI = dyn_cast<AtomicCmpXchgInst>(Usr))
1783       return HandleStoreLike(
1784           *CXI, nullptr, *CXI->getNewValOperand()->getType(),
1785           {CXI->getCompareOperand(), CXI->getNewValOperand()},
1786           AccessKind::AK_RW);
1787 
1788     if (auto *CB = dyn_cast<CallBase>(Usr)) {
1789       if (CB->isLifetimeStartOrEnd())
1790         return true;
1791       if (getFreedOperand(CB, TLI) == U)
1792         return true;
1793       if (CB->isArgOperand(&U)) {
1794         unsigned ArgNo = CB->getArgOperandNo(&U);
1795         const auto &CSArgPI = A.getAAFor<AAPointerInfo>(
1796             *this, IRPosition::callsite_argument(*CB, ArgNo),
1797             DepClassTy::REQUIRED);
1798         Changed = translateAndAddState(A, CSArgPI, OffsetInfoMap[CurPtr], *CB) |
1799                   Changed;
1800         return isValidState();
1801       }
1802       LLVM_DEBUG(dbgs() << "[AAPointerInfo] Call user not handled " << *CB
1803                         << "\n");
1804       // TODO: Allow some call uses
1805       return false;
1806     }
1807 
1808     LLVM_DEBUG(dbgs() << "[AAPointerInfo] User not handled " << *Usr << "\n");
1809     return false;
1810   };
1811   auto EquivalentUseCB = [&](const Use &OldU, const Use &NewU) {
1812     assert(OffsetInfoMap.count(OldU) && "Old use should be known already!");
1813     if (OffsetInfoMap.count(NewU)) {
1814       LLVM_DEBUG({
1815         if (!(OffsetInfoMap[NewU] == OffsetInfoMap[OldU])) {
1816           dbgs() << "[AAPointerInfo] Equivalent use callback failed: "
1817                  << OffsetInfoMap[NewU] << " vs " << OffsetInfoMap[OldU]
1818                  << "\n";
1819         }
1820       });
1821       return OffsetInfoMap[NewU] == OffsetInfoMap[OldU];
1822     }
1823     OffsetInfoMap[NewU] = OffsetInfoMap[OldU];
1824     return true;
1825   };
1826   if (!A.checkForAllUses(UsePred, *this, AssociatedValue,
1827                          /* CheckBBLivenessOnly */ true, DepClassTy::OPTIONAL,
1828                          /* IgnoreDroppableUses */ true, EquivalentUseCB)) {
1829     LLVM_DEBUG(dbgs() << "[AAPointerInfo] Check for all uses failed, abort!\n");
1830     return indicatePessimisticFixpoint();
1831   }
1832 
1833   LLVM_DEBUG({
1834     dbgs() << "Accesses by bin after update:\n";
1835     dumpState(dbgs());
1836   });
1837 
1838   return Changed;
1839 }
1840 
1841 struct AAPointerInfoReturned final : AAPointerInfoImpl {
1842   AAPointerInfoReturned(const IRPosition &IRP, Attributor &A)
1843       : AAPointerInfoImpl(IRP, A) {}
1844 
1845   /// See AbstractAttribute::updateImpl(...).
1846   ChangeStatus updateImpl(Attributor &A) override {
1847     return indicatePessimisticFixpoint();
1848   }
1849 
1850   /// See AbstractAttribute::trackStatistics()
1851   void trackStatistics() const override {
1852     AAPointerInfoImpl::trackPointerInfoStatistics(getIRPosition());
1853   }
1854 };
1855 
1856 struct AAPointerInfoArgument final : AAPointerInfoFloating {
1857   AAPointerInfoArgument(const IRPosition &IRP, Attributor &A)
1858       : AAPointerInfoFloating(IRP, A) {}
1859 
1860   /// See AbstractAttribute::initialize(...).
1861   void initialize(Attributor &A) override {
1862     AAPointerInfoFloating::initialize(A);
1863     if (getAnchorScope()->isDeclaration())
1864       indicatePessimisticFixpoint();
1865   }
1866 
1867   /// See AbstractAttribute::trackStatistics()
1868   void trackStatistics() const override {
1869     AAPointerInfoImpl::trackPointerInfoStatistics(getIRPosition());
1870   }
1871 };
1872 
1873 struct AAPointerInfoCallSiteArgument final : AAPointerInfoFloating {
1874   AAPointerInfoCallSiteArgument(const IRPosition &IRP, Attributor &A)
1875       : AAPointerInfoFloating(IRP, A) {}
1876 
1877   /// See AbstractAttribute::updateImpl(...).
1878   ChangeStatus updateImpl(Attributor &A) override {
1879     using namespace AA::PointerInfo;
1880     // We handle memory intrinsics explicitly, at least the first (=
1881     // destination) and second (=source) arguments as we know how they are
1882     // accessed.
1883     if (auto *MI = dyn_cast_or_null<MemIntrinsic>(getCtxI())) {
1884       ConstantInt *Length = dyn_cast<ConstantInt>(MI->getLength());
1885       int64_t LengthVal = AA::RangeTy::Unknown;
1886       if (Length)
1887         LengthVal = Length->getSExtValue();
1888       unsigned ArgNo = getIRPosition().getCallSiteArgNo();
1889       ChangeStatus Changed = ChangeStatus::UNCHANGED;
1890       if (ArgNo > 1) {
1891         LLVM_DEBUG(dbgs() << "[AAPointerInfo] Unhandled memory intrinsic "
1892                           << *MI << "\n");
1893         return indicatePessimisticFixpoint();
1894       } else {
1895         auto Kind =
1896             ArgNo == 0 ? AccessKind::AK_MUST_WRITE : AccessKind::AK_MUST_READ;
1897         Changed =
1898             Changed | addAccess(A, {0, LengthVal}, *MI, nullptr, Kind, nullptr);
1899       }
1900       LLVM_DEBUG({
1901         dbgs() << "Accesses by bin after update:\n";
1902         dumpState(dbgs());
1903       });
1904 
1905       return Changed;
1906     }
1907 
1908     // TODO: Once we have call site specific value information we can provide
1909     //       call site specific liveness information and then it makes
1910     //       sense to specialize attributes for call sites arguments instead of
1911     //       redirecting requests to the callee argument.
1912     Argument *Arg = getAssociatedArgument();
1913     if (Arg) {
1914       const IRPosition &ArgPos = IRPosition::argument(*Arg);
1915       auto &ArgAA =
1916           A.getAAFor<AAPointerInfo>(*this, ArgPos, DepClassTy::REQUIRED);
1917       if (ArgAA.getState().isValidState())
1918         return translateAndAddStateFromCallee(A, ArgAA,
1919                                               *cast<CallBase>(getCtxI()));
1920       if (!Arg->getParent()->isDeclaration())
1921         return indicatePessimisticFixpoint();
1922     }
1923 
1924     const auto &NoCaptureAA =
1925         A.getAAFor<AANoCapture>(*this, getIRPosition(), DepClassTy::OPTIONAL);
1926 
1927     if (!NoCaptureAA.isAssumedNoCapture())
1928       return indicatePessimisticFixpoint();
1929 
1930     bool IsKnown = false;
1931     if (AA::isAssumedReadNone(A, getIRPosition(), *this, IsKnown))
1932       return ChangeStatus::UNCHANGED;
1933     bool ReadOnly = AA::isAssumedReadOnly(A, getIRPosition(), *this, IsKnown);
1934     auto Kind =
1935         ReadOnly ? AccessKind::AK_MAY_READ : AccessKind::AK_MAY_READ_WRITE;
1936     return addAccess(A, AA::RangeTy::getUnknown(), *getCtxI(), nullptr, Kind,
1937                      nullptr);
1938   }
1939 
1940   /// See AbstractAttribute::trackStatistics()
1941   void trackStatistics() const override {
1942     AAPointerInfoImpl::trackPointerInfoStatistics(getIRPosition());
1943   }
1944 };
1945 
1946 struct AAPointerInfoCallSiteReturned final : AAPointerInfoFloating {
1947   AAPointerInfoCallSiteReturned(const IRPosition &IRP, Attributor &A)
1948       : AAPointerInfoFloating(IRP, A) {}
1949 
1950   /// See AbstractAttribute::trackStatistics()
1951   void trackStatistics() const override {
1952     AAPointerInfoImpl::trackPointerInfoStatistics(getIRPosition());
1953   }
1954 };
1955 } // namespace
1956 
1957 /// -----------------------NoUnwind Function Attribute--------------------------
1958 
1959 namespace {
1960 struct AANoUnwindImpl : AANoUnwind {
1961   AANoUnwindImpl(const IRPosition &IRP, Attributor &A) : AANoUnwind(IRP, A) {}
1962 
1963   const std::string getAsStr() const override {
1964     return getAssumed() ? "nounwind" : "may-unwind";
1965   }
1966 
1967   /// See AbstractAttribute::updateImpl(...).
1968   ChangeStatus updateImpl(Attributor &A) override {
1969     auto Opcodes = {
1970         (unsigned)Instruction::Invoke,      (unsigned)Instruction::CallBr,
1971         (unsigned)Instruction::Call,        (unsigned)Instruction::CleanupRet,
1972         (unsigned)Instruction::CatchSwitch, (unsigned)Instruction::Resume};
1973 
1974     auto CheckForNoUnwind = [&](Instruction &I) {
1975       if (!I.mayThrow())
1976         return true;
1977 
1978       if (const auto *CB = dyn_cast<CallBase>(&I)) {
1979         const auto &NoUnwindAA = A.getAAFor<AANoUnwind>(
1980             *this, IRPosition::callsite_function(*CB), DepClassTy::REQUIRED);
1981         return NoUnwindAA.isAssumedNoUnwind();
1982       }
1983       return false;
1984     };
1985 
1986     bool UsedAssumedInformation = false;
1987     if (!A.checkForAllInstructions(CheckForNoUnwind, *this, Opcodes,
1988                                    UsedAssumedInformation))
1989       return indicatePessimisticFixpoint();
1990 
1991     return ChangeStatus::UNCHANGED;
1992   }
1993 };
1994 
1995 struct AANoUnwindFunction final : public AANoUnwindImpl {
1996   AANoUnwindFunction(const IRPosition &IRP, Attributor &A)
1997       : AANoUnwindImpl(IRP, A) {}
1998 
1999   /// See AbstractAttribute::trackStatistics()
2000   void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(nounwind) }
2001 };
2002 
2003 /// NoUnwind attribute deduction for a call sites.
2004 struct AANoUnwindCallSite final : AANoUnwindImpl {
2005   AANoUnwindCallSite(const IRPosition &IRP, Attributor &A)
2006       : AANoUnwindImpl(IRP, A) {}
2007 
2008   /// See AbstractAttribute::initialize(...).
2009   void initialize(Attributor &A) override {
2010     AANoUnwindImpl::initialize(A);
2011     Function *F = getAssociatedFunction();
2012     if (!F || F->isDeclaration())
2013       indicatePessimisticFixpoint();
2014   }
2015 
2016   /// See AbstractAttribute::updateImpl(...).
2017   ChangeStatus updateImpl(Attributor &A) override {
2018     // TODO: Once we have call site specific value information we can provide
2019     //       call site specific liveness information and then it makes
2020     //       sense to specialize attributes for call sites arguments instead of
2021     //       redirecting requests to the callee argument.
2022     Function *F = getAssociatedFunction();
2023     const IRPosition &FnPos = IRPosition::function(*F);
2024     auto &FnAA = A.getAAFor<AANoUnwind>(*this, FnPos, DepClassTy::REQUIRED);
2025     return clampStateAndIndicateChange(getState(), FnAA.getState());
2026   }
2027 
2028   /// See AbstractAttribute::trackStatistics()
2029   void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(nounwind); }
2030 };
2031 } // namespace
2032 
2033 /// --------------------- Function Return Values -------------------------------
2034 
2035 namespace {
2036 /// "Attribute" that collects all potential returned values and the return
2037 /// instructions that they arise from.
2038 ///
2039 /// If there is a unique returned value R, the manifest method will:
2040 ///   - mark R with the "returned" attribute, if R is an argument.
2041 class AAReturnedValuesImpl : public AAReturnedValues, public AbstractState {
2042 
2043   /// Mapping of values potentially returned by the associated function to the
2044   /// return instructions that might return them.
2045   MapVector<Value *, SmallSetVector<ReturnInst *, 4>> ReturnedValues;
2046 
2047   /// State flags
2048   ///
2049   ///{
2050   bool IsFixed = false;
2051   bool IsValidState = true;
2052   ///}
2053 
2054 public:
2055   AAReturnedValuesImpl(const IRPosition &IRP, Attributor &A)
2056       : AAReturnedValues(IRP, A) {}
2057 
2058   /// See AbstractAttribute::initialize(...).
2059   void initialize(Attributor &A) override {
2060     // Reset the state.
2061     IsFixed = false;
2062     IsValidState = true;
2063     ReturnedValues.clear();
2064 
2065     Function *F = getAssociatedFunction();
2066     if (!F || F->isDeclaration()) {
2067       indicatePessimisticFixpoint();
2068       return;
2069     }
2070     assert(!F->getReturnType()->isVoidTy() &&
2071            "Did not expect a void return type!");
2072 
2073     // The map from instruction opcodes to those instructions in the function.
2074     auto &OpcodeInstMap = A.getInfoCache().getOpcodeInstMapForFunction(*F);
2075 
2076     // Look through all arguments, if one is marked as returned we are done.
2077     for (Argument &Arg : F->args()) {
2078       if (Arg.hasReturnedAttr()) {
2079         auto &ReturnInstSet = ReturnedValues[&Arg];
2080         if (auto *Insts = OpcodeInstMap.lookup(Instruction::Ret))
2081           for (Instruction *RI : *Insts)
2082             ReturnInstSet.insert(cast<ReturnInst>(RI));
2083 
2084         indicateOptimisticFixpoint();
2085         return;
2086       }
2087     }
2088 
2089     if (!A.isFunctionIPOAmendable(*F))
2090       indicatePessimisticFixpoint();
2091   }
2092 
2093   /// See AbstractAttribute::manifest(...).
2094   ChangeStatus manifest(Attributor &A) override;
2095 
2096   /// See AbstractAttribute::getState(...).
2097   AbstractState &getState() override { return *this; }
2098 
2099   /// See AbstractAttribute::getState(...).
2100   const AbstractState &getState() const override { return *this; }
2101 
2102   /// See AbstractAttribute::updateImpl(Attributor &A).
2103   ChangeStatus updateImpl(Attributor &A) override;
2104 
2105   llvm::iterator_range<iterator> returned_values() override {
2106     return llvm::make_range(ReturnedValues.begin(), ReturnedValues.end());
2107   }
2108 
2109   llvm::iterator_range<const_iterator> returned_values() const override {
2110     return llvm::make_range(ReturnedValues.begin(), ReturnedValues.end());
2111   }
2112 
2113   /// Return the number of potential return values, -1 if unknown.
2114   size_t getNumReturnValues() const override {
2115     return isValidState() ? ReturnedValues.size() : -1;
2116   }
2117 
2118   /// Return an assumed unique return value if a single candidate is found. If
2119   /// there cannot be one, return a nullptr. If it is not clear yet, return
2120   /// std::nullopt.
2121   std::optional<Value *> getAssumedUniqueReturnValue(Attributor &A) const;
2122 
2123   /// See AbstractState::checkForAllReturnedValues(...).
2124   bool checkForAllReturnedValuesAndReturnInsts(
2125       function_ref<bool(Value &, const SmallSetVector<ReturnInst *, 4> &)> Pred)
2126       const override;
2127 
2128   /// Pretty print the attribute similar to the IR representation.
2129   const std::string getAsStr() const override;
2130 
2131   /// See AbstractState::isAtFixpoint().
2132   bool isAtFixpoint() const override { return IsFixed; }
2133 
2134   /// See AbstractState::isValidState().
2135   bool isValidState() const override { return IsValidState; }
2136 
2137   /// See AbstractState::indicateOptimisticFixpoint(...).
2138   ChangeStatus indicateOptimisticFixpoint() override {
2139     IsFixed = true;
2140     return ChangeStatus::UNCHANGED;
2141   }
2142 
2143   ChangeStatus indicatePessimisticFixpoint() override {
2144     IsFixed = true;
2145     IsValidState = false;
2146     return ChangeStatus::CHANGED;
2147   }
2148 };
2149 
2150 ChangeStatus AAReturnedValuesImpl::manifest(Attributor &A) {
2151   ChangeStatus Changed = ChangeStatus::UNCHANGED;
2152 
2153   // Bookkeeping.
2154   assert(isValidState());
2155   STATS_DECLTRACK(KnownReturnValues, FunctionReturn,
2156                   "Number of function with known return values");
2157 
2158   // Check if we have an assumed unique return value that we could manifest.
2159   std::optional<Value *> UniqueRV = getAssumedUniqueReturnValue(A);
2160 
2161   if (!UniqueRV || !*UniqueRV)
2162     return Changed;
2163 
2164   // Bookkeeping.
2165   STATS_DECLTRACK(UniqueReturnValue, FunctionReturn,
2166                   "Number of function with unique return");
2167   // If the assumed unique return value is an argument, annotate it.
2168   if (auto *UniqueRVArg = dyn_cast<Argument>(*UniqueRV)) {
2169     if (UniqueRVArg->getType()->canLosslesslyBitCastTo(
2170             getAssociatedFunction()->getReturnType())) {
2171       getIRPosition() = IRPosition::argument(*UniqueRVArg);
2172       Changed = IRAttribute::manifest(A);
2173     }
2174   }
2175   return Changed;
2176 }
2177 
2178 const std::string AAReturnedValuesImpl::getAsStr() const {
2179   return (isAtFixpoint() ? "returns(#" : "may-return(#") +
2180          (isValidState() ? std::to_string(getNumReturnValues()) : "?") + ")";
2181 }
2182 
2183 std::optional<Value *>
2184 AAReturnedValuesImpl::getAssumedUniqueReturnValue(Attributor &A) const {
2185   // If checkForAllReturnedValues provides a unique value, ignoring potential
2186   // undef values that can also be present, it is assumed to be the actual
2187   // return value and forwarded to the caller of this method. If there are
2188   // multiple, a nullptr is returned indicating there cannot be a unique
2189   // returned value.
2190   std::optional<Value *> UniqueRV;
2191   Type *Ty = getAssociatedFunction()->getReturnType();
2192 
2193   auto Pred = [&](Value &RV) -> bool {
2194     UniqueRV = AA::combineOptionalValuesInAAValueLatice(UniqueRV, &RV, Ty);
2195     return UniqueRV != std::optional<Value *>(nullptr);
2196   };
2197 
2198   if (!A.checkForAllReturnedValues(Pred, *this))
2199     UniqueRV = nullptr;
2200 
2201   return UniqueRV;
2202 }
2203 
2204 bool AAReturnedValuesImpl::checkForAllReturnedValuesAndReturnInsts(
2205     function_ref<bool(Value &, const SmallSetVector<ReturnInst *, 4> &)> Pred)
2206     const {
2207   if (!isValidState())
2208     return false;
2209 
2210   // Check all returned values but ignore call sites as long as we have not
2211   // encountered an overdefined one during an update.
2212   for (const auto &It : ReturnedValues) {
2213     Value *RV = It.first;
2214     if (!Pred(*RV, It.second))
2215       return false;
2216   }
2217 
2218   return true;
2219 }
2220 
2221 ChangeStatus AAReturnedValuesImpl::updateImpl(Attributor &A) {
2222   ChangeStatus Changed = ChangeStatus::UNCHANGED;
2223 
2224   SmallVector<AA::ValueAndContext> Values;
2225   bool UsedAssumedInformation = false;
2226   auto ReturnInstCB = [&](Instruction &I) {
2227     ReturnInst &Ret = cast<ReturnInst>(I);
2228     Values.clear();
2229     if (!A.getAssumedSimplifiedValues(IRPosition::value(*Ret.getReturnValue()),
2230                                       *this, Values, AA::Intraprocedural,
2231                                       UsedAssumedInformation))
2232       Values.push_back({*Ret.getReturnValue(), Ret});
2233 
2234     for (auto &VAC : Values) {
2235       assert(AA::isValidInScope(*VAC.getValue(), Ret.getFunction()) &&
2236              "Assumed returned value should be valid in function scope!");
2237       if (ReturnedValues[VAC.getValue()].insert(&Ret))
2238         Changed = ChangeStatus::CHANGED;
2239     }
2240     return true;
2241   };
2242 
2243   // Discover returned values from all live returned instructions in the
2244   // associated function.
2245   if (!A.checkForAllInstructions(ReturnInstCB, *this, {Instruction::Ret},
2246                                  UsedAssumedInformation))
2247     return indicatePessimisticFixpoint();
2248   return Changed;
2249 }
2250 
2251 struct AAReturnedValuesFunction final : public AAReturnedValuesImpl {
2252   AAReturnedValuesFunction(const IRPosition &IRP, Attributor &A)
2253       : AAReturnedValuesImpl(IRP, A) {}
2254 
2255   /// See AbstractAttribute::trackStatistics()
2256   void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(returned) }
2257 };
2258 
2259 /// Returned values information for a call sites.
2260 struct AAReturnedValuesCallSite final : AAReturnedValuesImpl {
2261   AAReturnedValuesCallSite(const IRPosition &IRP, Attributor &A)
2262       : AAReturnedValuesImpl(IRP, A) {}
2263 
2264   /// See AbstractAttribute::initialize(...).
2265   void initialize(Attributor &A) override {
2266     // TODO: Once we have call site specific value information we can provide
2267     //       call site specific liveness information and then it makes
2268     //       sense to specialize attributes for call sites instead of
2269     //       redirecting requests to the callee.
2270     llvm_unreachable("Abstract attributes for returned values are not "
2271                      "supported for call sites yet!");
2272   }
2273 
2274   /// See AbstractAttribute::updateImpl(...).
2275   ChangeStatus updateImpl(Attributor &A) override {
2276     return indicatePessimisticFixpoint();
2277   }
2278 
2279   /// See AbstractAttribute::trackStatistics()
2280   void trackStatistics() const override {}
2281 };
2282 } // namespace
2283 
2284 /// ------------------------ NoSync Function Attribute -------------------------
2285 
2286 bool AANoSync::isAlignedBarrier(const CallBase &CB, bool ExecutedAligned) {
2287   switch (CB.getIntrinsicID()) {
2288   case Intrinsic::nvvm_barrier0:
2289   case Intrinsic::nvvm_barrier0_and:
2290   case Intrinsic::nvvm_barrier0_or:
2291   case Intrinsic::nvvm_barrier0_popc:
2292     return true;
2293   case Intrinsic::amdgcn_s_barrier:
2294     if (ExecutedAligned)
2295       return true;
2296     break;
2297   default:
2298     break;
2299   }
2300   return hasAssumption(CB, KnownAssumptionString("ompx_aligned_barrier"));
2301 }
2302 
2303 bool AANoSync::isNonRelaxedAtomic(const Instruction *I) {
2304   if (!I->isAtomic())
2305     return false;
2306 
2307   if (auto *FI = dyn_cast<FenceInst>(I))
2308     // All legal orderings for fence are stronger than monotonic.
2309     return FI->getSyncScopeID() != SyncScope::SingleThread;
2310   if (auto *AI = dyn_cast<AtomicCmpXchgInst>(I)) {
2311     // Unordered is not a legal ordering for cmpxchg.
2312     return (AI->getSuccessOrdering() != AtomicOrdering::Monotonic ||
2313             AI->getFailureOrdering() != AtomicOrdering::Monotonic);
2314   }
2315 
2316   AtomicOrdering Ordering;
2317   switch (I->getOpcode()) {
2318   case Instruction::AtomicRMW:
2319     Ordering = cast<AtomicRMWInst>(I)->getOrdering();
2320     break;
2321   case Instruction::Store:
2322     Ordering = cast<StoreInst>(I)->getOrdering();
2323     break;
2324   case Instruction::Load:
2325     Ordering = cast<LoadInst>(I)->getOrdering();
2326     break;
2327   default:
2328     llvm_unreachable(
2329         "New atomic operations need to be known in the attributor.");
2330   }
2331 
2332   return (Ordering != AtomicOrdering::Unordered &&
2333           Ordering != AtomicOrdering::Monotonic);
2334 }
2335 
2336 /// Return true if this intrinsic is nosync.  This is only used for intrinsics
2337 /// which would be nosync except that they have a volatile flag.  All other
2338 /// intrinsics are simply annotated with the nosync attribute in Intrinsics.td.
2339 bool AANoSync::isNoSyncIntrinsic(const Instruction *I) {
2340   if (auto *MI = dyn_cast<MemIntrinsic>(I))
2341     return !MI->isVolatile();
2342   return false;
2343 }
2344 
2345 namespace {
2346 struct AANoSyncImpl : AANoSync {
2347   AANoSyncImpl(const IRPosition &IRP, Attributor &A) : AANoSync(IRP, A) {}
2348 
2349   const std::string getAsStr() const override {
2350     return getAssumed() ? "nosync" : "may-sync";
2351   }
2352 
2353   /// See AbstractAttribute::updateImpl(...).
2354   ChangeStatus updateImpl(Attributor &A) override;
2355 };
2356 
2357 ChangeStatus AANoSyncImpl::updateImpl(Attributor &A) {
2358 
2359   auto CheckRWInstForNoSync = [&](Instruction &I) {
2360     return AA::isNoSyncInst(A, I, *this);
2361   };
2362 
2363   auto CheckForNoSync = [&](Instruction &I) {
2364     // At this point we handled all read/write effects and they are all
2365     // nosync, so they can be skipped.
2366     if (I.mayReadOrWriteMemory())
2367       return true;
2368 
2369     // non-convergent and readnone imply nosync.
2370     return !cast<CallBase>(I).isConvergent();
2371   };
2372 
2373   bool UsedAssumedInformation = false;
2374   if (!A.checkForAllReadWriteInstructions(CheckRWInstForNoSync, *this,
2375                                           UsedAssumedInformation) ||
2376       !A.checkForAllCallLikeInstructions(CheckForNoSync, *this,
2377                                          UsedAssumedInformation))
2378     return indicatePessimisticFixpoint();
2379 
2380   return ChangeStatus::UNCHANGED;
2381 }
2382 
2383 struct AANoSyncFunction final : public AANoSyncImpl {
2384   AANoSyncFunction(const IRPosition &IRP, Attributor &A)
2385       : AANoSyncImpl(IRP, A) {}
2386 
2387   /// See AbstractAttribute::trackStatistics()
2388   void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(nosync) }
2389 };
2390 
2391 /// NoSync attribute deduction for a call sites.
2392 struct AANoSyncCallSite final : AANoSyncImpl {
2393   AANoSyncCallSite(const IRPosition &IRP, Attributor &A)
2394       : AANoSyncImpl(IRP, A) {}
2395 
2396   /// See AbstractAttribute::initialize(...).
2397   void initialize(Attributor &A) override {
2398     AANoSyncImpl::initialize(A);
2399     Function *F = getAssociatedFunction();
2400     if (!F || F->isDeclaration())
2401       indicatePessimisticFixpoint();
2402   }
2403 
2404   /// See AbstractAttribute::updateImpl(...).
2405   ChangeStatus updateImpl(Attributor &A) override {
2406     // TODO: Once we have call site specific value information we can provide
2407     //       call site specific liveness information and then it makes
2408     //       sense to specialize attributes for call sites arguments instead of
2409     //       redirecting requests to the callee argument.
2410     Function *F = getAssociatedFunction();
2411     const IRPosition &FnPos = IRPosition::function(*F);
2412     auto &FnAA = A.getAAFor<AANoSync>(*this, FnPos, DepClassTy::REQUIRED);
2413     return clampStateAndIndicateChange(getState(), FnAA.getState());
2414   }
2415 
2416   /// See AbstractAttribute::trackStatistics()
2417   void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(nosync); }
2418 };
2419 } // namespace
2420 
2421 /// ------------------------ No-Free Attributes ----------------------------
2422 
2423 namespace {
2424 struct AANoFreeImpl : public AANoFree {
2425   AANoFreeImpl(const IRPosition &IRP, Attributor &A) : AANoFree(IRP, A) {}
2426 
2427   /// See AbstractAttribute::updateImpl(...).
2428   ChangeStatus updateImpl(Attributor &A) override {
2429     auto CheckForNoFree = [&](Instruction &I) {
2430       const auto &CB = cast<CallBase>(I);
2431       if (CB.hasFnAttr(Attribute::NoFree))
2432         return true;
2433 
2434       const auto &NoFreeAA = A.getAAFor<AANoFree>(
2435           *this, IRPosition::callsite_function(CB), DepClassTy::REQUIRED);
2436       return NoFreeAA.isAssumedNoFree();
2437     };
2438 
2439     bool UsedAssumedInformation = false;
2440     if (!A.checkForAllCallLikeInstructions(CheckForNoFree, *this,
2441                                            UsedAssumedInformation))
2442       return indicatePessimisticFixpoint();
2443     return ChangeStatus::UNCHANGED;
2444   }
2445 
2446   /// See AbstractAttribute::getAsStr().
2447   const std::string getAsStr() const override {
2448     return getAssumed() ? "nofree" : "may-free";
2449   }
2450 };
2451 
2452 struct AANoFreeFunction final : public AANoFreeImpl {
2453   AANoFreeFunction(const IRPosition &IRP, Attributor &A)
2454       : AANoFreeImpl(IRP, A) {}
2455 
2456   /// See AbstractAttribute::trackStatistics()
2457   void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(nofree) }
2458 };
2459 
2460 /// NoFree attribute deduction for a call sites.
2461 struct AANoFreeCallSite final : AANoFreeImpl {
2462   AANoFreeCallSite(const IRPosition &IRP, Attributor &A)
2463       : AANoFreeImpl(IRP, A) {}
2464 
2465   /// See AbstractAttribute::initialize(...).
2466   void initialize(Attributor &A) override {
2467     AANoFreeImpl::initialize(A);
2468     Function *F = getAssociatedFunction();
2469     if (!F || F->isDeclaration())
2470       indicatePessimisticFixpoint();
2471   }
2472 
2473   /// See AbstractAttribute::updateImpl(...).
2474   ChangeStatus updateImpl(Attributor &A) override {
2475     // TODO: Once we have call site specific value information we can provide
2476     //       call site specific liveness information and then it makes
2477     //       sense to specialize attributes for call sites arguments instead of
2478     //       redirecting requests to the callee argument.
2479     Function *F = getAssociatedFunction();
2480     const IRPosition &FnPos = IRPosition::function(*F);
2481     auto &FnAA = A.getAAFor<AANoFree>(*this, FnPos, DepClassTy::REQUIRED);
2482     return clampStateAndIndicateChange(getState(), FnAA.getState());
2483   }
2484 
2485   /// See AbstractAttribute::trackStatistics()
2486   void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(nofree); }
2487 };
2488 
2489 /// NoFree attribute for floating values.
2490 struct AANoFreeFloating : AANoFreeImpl {
2491   AANoFreeFloating(const IRPosition &IRP, Attributor &A)
2492       : AANoFreeImpl(IRP, A) {}
2493 
2494   /// See AbstractAttribute::trackStatistics()
2495   void trackStatistics() const override{STATS_DECLTRACK_FLOATING_ATTR(nofree)}
2496 
2497   /// See Abstract Attribute::updateImpl(...).
2498   ChangeStatus updateImpl(Attributor &A) override {
2499     const IRPosition &IRP = getIRPosition();
2500 
2501     const auto &NoFreeAA = A.getAAFor<AANoFree>(
2502         *this, IRPosition::function_scope(IRP), DepClassTy::OPTIONAL);
2503     if (NoFreeAA.isAssumedNoFree())
2504       return ChangeStatus::UNCHANGED;
2505 
2506     Value &AssociatedValue = getIRPosition().getAssociatedValue();
2507     auto Pred = [&](const Use &U, bool &Follow) -> bool {
2508       Instruction *UserI = cast<Instruction>(U.getUser());
2509       if (auto *CB = dyn_cast<CallBase>(UserI)) {
2510         if (CB->isBundleOperand(&U))
2511           return false;
2512         if (!CB->isArgOperand(&U))
2513           return true;
2514         unsigned ArgNo = CB->getArgOperandNo(&U);
2515 
2516         const auto &NoFreeArg = A.getAAFor<AANoFree>(
2517             *this, IRPosition::callsite_argument(*CB, ArgNo),
2518             DepClassTy::REQUIRED);
2519         return NoFreeArg.isAssumedNoFree();
2520       }
2521 
2522       if (isa<GetElementPtrInst>(UserI) || isa<BitCastInst>(UserI) ||
2523           isa<PHINode>(UserI) || isa<SelectInst>(UserI)) {
2524         Follow = true;
2525         return true;
2526       }
2527       if (isa<StoreInst>(UserI) || isa<LoadInst>(UserI) ||
2528           isa<ReturnInst>(UserI))
2529         return true;
2530 
2531       // Unknown user.
2532       return false;
2533     };
2534     if (!A.checkForAllUses(Pred, *this, AssociatedValue))
2535       return indicatePessimisticFixpoint();
2536 
2537     return ChangeStatus::UNCHANGED;
2538   }
2539 };
2540 
2541 /// NoFree attribute for a call site argument.
2542 struct AANoFreeArgument final : AANoFreeFloating {
2543   AANoFreeArgument(const IRPosition &IRP, Attributor &A)
2544       : AANoFreeFloating(IRP, A) {}
2545 
2546   /// See AbstractAttribute::trackStatistics()
2547   void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(nofree) }
2548 };
2549 
2550 /// NoFree attribute for call site arguments.
2551 struct AANoFreeCallSiteArgument final : AANoFreeFloating {
2552   AANoFreeCallSiteArgument(const IRPosition &IRP, Attributor &A)
2553       : AANoFreeFloating(IRP, A) {}
2554 
2555   /// See AbstractAttribute::updateImpl(...).
2556   ChangeStatus updateImpl(Attributor &A) override {
2557     // TODO: Once we have call site specific value information we can provide
2558     //       call site specific liveness information and then it makes
2559     //       sense to specialize attributes for call sites arguments instead of
2560     //       redirecting requests to the callee argument.
2561     Argument *Arg = getAssociatedArgument();
2562     if (!Arg)
2563       return indicatePessimisticFixpoint();
2564     const IRPosition &ArgPos = IRPosition::argument(*Arg);
2565     auto &ArgAA = A.getAAFor<AANoFree>(*this, ArgPos, DepClassTy::REQUIRED);
2566     return clampStateAndIndicateChange(getState(), ArgAA.getState());
2567   }
2568 
2569   /// See AbstractAttribute::trackStatistics()
2570   void trackStatistics() const override{STATS_DECLTRACK_CSARG_ATTR(nofree)};
2571 };
2572 
2573 /// NoFree attribute for function return value.
2574 struct AANoFreeReturned final : AANoFreeFloating {
2575   AANoFreeReturned(const IRPosition &IRP, Attributor &A)
2576       : AANoFreeFloating(IRP, A) {
2577     llvm_unreachable("NoFree is not applicable to function returns!");
2578   }
2579 
2580   /// See AbstractAttribute::initialize(...).
2581   void initialize(Attributor &A) override {
2582     llvm_unreachable("NoFree is not applicable to function returns!");
2583   }
2584 
2585   /// See AbstractAttribute::updateImpl(...).
2586   ChangeStatus updateImpl(Attributor &A) override {
2587     llvm_unreachable("NoFree is not applicable to function returns!");
2588   }
2589 
2590   /// See AbstractAttribute::trackStatistics()
2591   void trackStatistics() const override {}
2592 };
2593 
2594 /// NoFree attribute deduction for a call site return value.
2595 struct AANoFreeCallSiteReturned final : AANoFreeFloating {
2596   AANoFreeCallSiteReturned(const IRPosition &IRP, Attributor &A)
2597       : AANoFreeFloating(IRP, A) {}
2598 
2599   ChangeStatus manifest(Attributor &A) override {
2600     return ChangeStatus::UNCHANGED;
2601   }
2602   /// See AbstractAttribute::trackStatistics()
2603   void trackStatistics() const override { STATS_DECLTRACK_CSRET_ATTR(nofree) }
2604 };
2605 } // namespace
2606 
2607 /// ------------------------ NonNull Argument Attribute ------------------------
2608 namespace {
2609 static int64_t getKnownNonNullAndDerefBytesForUse(
2610     Attributor &A, const AbstractAttribute &QueryingAA, Value &AssociatedValue,
2611     const Use *U, const Instruction *I, bool &IsNonNull, bool &TrackUse) {
2612   TrackUse = false;
2613 
2614   const Value *UseV = U->get();
2615   if (!UseV->getType()->isPointerTy())
2616     return 0;
2617 
2618   // We need to follow common pointer manipulation uses to the accesses they
2619   // feed into. We can try to be smart to avoid looking through things we do not
2620   // like for now, e.g., non-inbounds GEPs.
2621   if (isa<CastInst>(I)) {
2622     TrackUse = true;
2623     return 0;
2624   }
2625 
2626   if (isa<GetElementPtrInst>(I)) {
2627     TrackUse = true;
2628     return 0;
2629   }
2630 
2631   Type *PtrTy = UseV->getType();
2632   const Function *F = I->getFunction();
2633   bool NullPointerIsDefined =
2634       F ? llvm::NullPointerIsDefined(F, PtrTy->getPointerAddressSpace()) : true;
2635   const DataLayout &DL = A.getInfoCache().getDL();
2636   if (const auto *CB = dyn_cast<CallBase>(I)) {
2637     if (CB->isBundleOperand(U)) {
2638       if (RetainedKnowledge RK = getKnowledgeFromUse(
2639               U, {Attribute::NonNull, Attribute::Dereferenceable})) {
2640         IsNonNull |=
2641             (RK.AttrKind == Attribute::NonNull || !NullPointerIsDefined);
2642         return RK.ArgValue;
2643       }
2644       return 0;
2645     }
2646 
2647     if (CB->isCallee(U)) {
2648       IsNonNull |= !NullPointerIsDefined;
2649       return 0;
2650     }
2651 
2652     unsigned ArgNo = CB->getArgOperandNo(U);
2653     IRPosition IRP = IRPosition::callsite_argument(*CB, ArgNo);
2654     // As long as we only use known information there is no need to track
2655     // dependences here.
2656     auto &DerefAA =
2657         A.getAAFor<AADereferenceable>(QueryingAA, IRP, DepClassTy::NONE);
2658     IsNonNull |= DerefAA.isKnownNonNull();
2659     return DerefAA.getKnownDereferenceableBytes();
2660   }
2661 
2662   std::optional<MemoryLocation> Loc = MemoryLocation::getOrNone(I);
2663   if (!Loc || Loc->Ptr != UseV || !Loc->Size.isPrecise() || I->isVolatile())
2664     return 0;
2665 
2666   int64_t Offset;
2667   const Value *Base =
2668       getMinimalBaseOfPointer(A, QueryingAA, Loc->Ptr, Offset, DL);
2669   if (Base && Base == &AssociatedValue) {
2670     int64_t DerefBytes = Loc->Size.getValue() + Offset;
2671     IsNonNull |= !NullPointerIsDefined;
2672     return std::max(int64_t(0), DerefBytes);
2673   }
2674 
2675   /// Corner case when an offset is 0.
2676   Base = GetPointerBaseWithConstantOffset(Loc->Ptr, Offset, DL,
2677                                           /*AllowNonInbounds*/ true);
2678   if (Base && Base == &AssociatedValue && Offset == 0) {
2679     int64_t DerefBytes = Loc->Size.getValue();
2680     IsNonNull |= !NullPointerIsDefined;
2681     return std::max(int64_t(0), DerefBytes);
2682   }
2683 
2684   return 0;
2685 }
2686 
2687 struct AANonNullImpl : AANonNull {
2688   AANonNullImpl(const IRPosition &IRP, Attributor &A)
2689       : AANonNull(IRP, A),
2690         NullIsDefined(NullPointerIsDefined(
2691             getAnchorScope(),
2692             getAssociatedValue().getType()->getPointerAddressSpace())) {}
2693 
2694   /// See AbstractAttribute::initialize(...).
2695   void initialize(Attributor &A) override {
2696     Value &V = *getAssociatedValue().stripPointerCasts();
2697     if (!NullIsDefined &&
2698         hasAttr({Attribute::NonNull, Attribute::Dereferenceable},
2699                 /* IgnoreSubsumingPositions */ false, &A)) {
2700       indicateOptimisticFixpoint();
2701       return;
2702     }
2703 
2704     if (isa<ConstantPointerNull>(V)) {
2705       indicatePessimisticFixpoint();
2706       return;
2707     }
2708 
2709     AANonNull::initialize(A);
2710 
2711     bool CanBeNull, CanBeFreed;
2712     if (V.getPointerDereferenceableBytes(A.getDataLayout(), CanBeNull,
2713                                          CanBeFreed)) {
2714       if (!CanBeNull) {
2715         indicateOptimisticFixpoint();
2716         return;
2717       }
2718     }
2719 
2720     if (isa<GlobalValue>(V)) {
2721       indicatePessimisticFixpoint();
2722       return;
2723     }
2724 
2725     if (Instruction *CtxI = getCtxI())
2726       followUsesInMBEC(*this, A, getState(), *CtxI);
2727   }
2728 
2729   /// See followUsesInMBEC
2730   bool followUseInMBEC(Attributor &A, const Use *U, const Instruction *I,
2731                        AANonNull::StateType &State) {
2732     bool IsNonNull = false;
2733     bool TrackUse = false;
2734     getKnownNonNullAndDerefBytesForUse(A, *this, getAssociatedValue(), U, I,
2735                                        IsNonNull, TrackUse);
2736     State.setKnown(IsNonNull);
2737     return TrackUse;
2738   }
2739 
2740   /// See AbstractAttribute::getAsStr().
2741   const std::string getAsStr() const override {
2742     return getAssumed() ? "nonnull" : "may-null";
2743   }
2744 
2745   /// Flag to determine if the underlying value can be null and still allow
2746   /// valid accesses.
2747   const bool NullIsDefined;
2748 };
2749 
2750 /// NonNull attribute for a floating value.
2751 struct AANonNullFloating : public AANonNullImpl {
2752   AANonNullFloating(const IRPosition &IRP, Attributor &A)
2753       : AANonNullImpl(IRP, A) {}
2754 
2755   /// See AbstractAttribute::updateImpl(...).
2756   ChangeStatus updateImpl(Attributor &A) override {
2757     const DataLayout &DL = A.getDataLayout();
2758 
2759     bool Stripped;
2760     bool UsedAssumedInformation = false;
2761     SmallVector<AA::ValueAndContext> Values;
2762     if (!A.getAssumedSimplifiedValues(getIRPosition(), *this, Values,
2763                                       AA::AnyScope, UsedAssumedInformation)) {
2764       Values.push_back({getAssociatedValue(), getCtxI()});
2765       Stripped = false;
2766     } else {
2767       Stripped = Values.size() != 1 ||
2768                  Values.front().getValue() != &getAssociatedValue();
2769     }
2770 
2771     DominatorTree *DT = nullptr;
2772     AssumptionCache *AC = nullptr;
2773     InformationCache &InfoCache = A.getInfoCache();
2774     if (const Function *Fn = getAnchorScope()) {
2775       DT = InfoCache.getAnalysisResultForFunction<DominatorTreeAnalysis>(*Fn);
2776       AC = InfoCache.getAnalysisResultForFunction<AssumptionAnalysis>(*Fn);
2777     }
2778 
2779     AANonNull::StateType T;
2780     auto VisitValueCB = [&](Value &V, const Instruction *CtxI) -> bool {
2781       const auto &AA = A.getAAFor<AANonNull>(*this, IRPosition::value(V),
2782                                              DepClassTy::REQUIRED);
2783       if (!Stripped && this == &AA) {
2784         if (!isKnownNonZero(&V, DL, 0, AC, CtxI, DT))
2785           T.indicatePessimisticFixpoint();
2786       } else {
2787         // Use abstract attribute information.
2788         const AANonNull::StateType &NS = AA.getState();
2789         T ^= NS;
2790       }
2791       return T.isValidState();
2792     };
2793 
2794     for (const auto &VAC : Values)
2795       if (!VisitValueCB(*VAC.getValue(), VAC.getCtxI()))
2796         return indicatePessimisticFixpoint();
2797 
2798     return clampStateAndIndicateChange(getState(), T);
2799   }
2800 
2801   /// See AbstractAttribute::trackStatistics()
2802   void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(nonnull) }
2803 };
2804 
2805 /// NonNull attribute for function return value.
2806 struct AANonNullReturned final
2807     : AAReturnedFromReturnedValues<AANonNull, AANonNull> {
2808   AANonNullReturned(const IRPosition &IRP, Attributor &A)
2809       : AAReturnedFromReturnedValues<AANonNull, AANonNull>(IRP, A) {}
2810 
2811   /// See AbstractAttribute::getAsStr().
2812   const std::string getAsStr() const override {
2813     return getAssumed() ? "nonnull" : "may-null";
2814   }
2815 
2816   /// See AbstractAttribute::trackStatistics()
2817   void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(nonnull) }
2818 };
2819 
2820 /// NonNull attribute for function argument.
2821 struct AANonNullArgument final
2822     : AAArgumentFromCallSiteArguments<AANonNull, AANonNullImpl> {
2823   AANonNullArgument(const IRPosition &IRP, Attributor &A)
2824       : AAArgumentFromCallSiteArguments<AANonNull, AANonNullImpl>(IRP, A) {}
2825 
2826   /// See AbstractAttribute::trackStatistics()
2827   void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(nonnull) }
2828 };
2829 
2830 struct AANonNullCallSiteArgument final : AANonNullFloating {
2831   AANonNullCallSiteArgument(const IRPosition &IRP, Attributor &A)
2832       : AANonNullFloating(IRP, A) {}
2833 
2834   /// See AbstractAttribute::trackStatistics()
2835   void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(nonnull) }
2836 };
2837 
2838 /// NonNull attribute for a call site return position.
2839 struct AANonNullCallSiteReturned final
2840     : AACallSiteReturnedFromReturned<AANonNull, AANonNullImpl> {
2841   AANonNullCallSiteReturned(const IRPosition &IRP, Attributor &A)
2842       : AACallSiteReturnedFromReturned<AANonNull, AANonNullImpl>(IRP, A) {}
2843 
2844   /// See AbstractAttribute::trackStatistics()
2845   void trackStatistics() const override { STATS_DECLTRACK_CSRET_ATTR(nonnull) }
2846 };
2847 } // namespace
2848 
2849 /// ------------------------ No-Recurse Attributes ----------------------------
2850 
2851 namespace {
2852 struct AANoRecurseImpl : public AANoRecurse {
2853   AANoRecurseImpl(const IRPosition &IRP, Attributor &A) : AANoRecurse(IRP, A) {}
2854 
2855   /// See AbstractAttribute::getAsStr()
2856   const std::string getAsStr() const override {
2857     return getAssumed() ? "norecurse" : "may-recurse";
2858   }
2859 };
2860 
2861 struct AANoRecurseFunction final : AANoRecurseImpl {
2862   AANoRecurseFunction(const IRPosition &IRP, Attributor &A)
2863       : AANoRecurseImpl(IRP, A) {}
2864 
2865   /// See AbstractAttribute::updateImpl(...).
2866   ChangeStatus updateImpl(Attributor &A) override {
2867 
2868     // If all live call sites are known to be no-recurse, we are as well.
2869     auto CallSitePred = [&](AbstractCallSite ACS) {
2870       const auto &NoRecurseAA = A.getAAFor<AANoRecurse>(
2871           *this, IRPosition::function(*ACS.getInstruction()->getFunction()),
2872           DepClassTy::NONE);
2873       return NoRecurseAA.isKnownNoRecurse();
2874     };
2875     bool UsedAssumedInformation = false;
2876     if (A.checkForAllCallSites(CallSitePred, *this, true,
2877                                UsedAssumedInformation)) {
2878       // If we know all call sites and all are known no-recurse, we are done.
2879       // If all known call sites, which might not be all that exist, are known
2880       // to be no-recurse, we are not done but we can continue to assume
2881       // no-recurse. If one of the call sites we have not visited will become
2882       // live, another update is triggered.
2883       if (!UsedAssumedInformation)
2884         indicateOptimisticFixpoint();
2885       return ChangeStatus::UNCHANGED;
2886     }
2887 
2888     const AAInterFnReachability &EdgeReachability =
2889         A.getAAFor<AAInterFnReachability>(*this, getIRPosition(),
2890                                           DepClassTy::REQUIRED);
2891     if (EdgeReachability.canReach(A, *getAnchorScope()))
2892       return indicatePessimisticFixpoint();
2893     return ChangeStatus::UNCHANGED;
2894   }
2895 
2896   void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(norecurse) }
2897 };
2898 
2899 /// NoRecurse attribute deduction for a call sites.
2900 struct AANoRecurseCallSite final : AANoRecurseImpl {
2901   AANoRecurseCallSite(const IRPosition &IRP, Attributor &A)
2902       : AANoRecurseImpl(IRP, A) {}
2903 
2904   /// See AbstractAttribute::initialize(...).
2905   void initialize(Attributor &A) override {
2906     AANoRecurseImpl::initialize(A);
2907     Function *F = getAssociatedFunction();
2908     if (!F || F->isDeclaration())
2909       indicatePessimisticFixpoint();
2910   }
2911 
2912   /// See AbstractAttribute::updateImpl(...).
2913   ChangeStatus updateImpl(Attributor &A) override {
2914     // TODO: Once we have call site specific value information we can provide
2915     //       call site specific liveness information and then it makes
2916     //       sense to specialize attributes for call sites arguments instead of
2917     //       redirecting requests to the callee argument.
2918     Function *F = getAssociatedFunction();
2919     const IRPosition &FnPos = IRPosition::function(*F);
2920     auto &FnAA = A.getAAFor<AANoRecurse>(*this, FnPos, DepClassTy::REQUIRED);
2921     return clampStateAndIndicateChange(getState(), FnAA.getState());
2922   }
2923 
2924   /// See AbstractAttribute::trackStatistics()
2925   void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(norecurse); }
2926 };
2927 } // namespace
2928 
2929 /// -------------------- Undefined-Behavior Attributes ------------------------
2930 
2931 namespace {
2932 struct AAUndefinedBehaviorImpl : public AAUndefinedBehavior {
2933   AAUndefinedBehaviorImpl(const IRPosition &IRP, Attributor &A)
2934       : AAUndefinedBehavior(IRP, A) {}
2935 
2936   /// See AbstractAttribute::updateImpl(...).
2937   // through a pointer (i.e. also branches etc.)
2938   ChangeStatus updateImpl(Attributor &A) override {
2939     const size_t UBPrevSize = KnownUBInsts.size();
2940     const size_t NoUBPrevSize = AssumedNoUBInsts.size();
2941 
2942     auto InspectMemAccessInstForUB = [&](Instruction &I) {
2943       // Lang ref now states volatile store is not UB, let's skip them.
2944       if (I.isVolatile() && I.mayWriteToMemory())
2945         return true;
2946 
2947       // Skip instructions that are already saved.
2948       if (AssumedNoUBInsts.count(&I) || KnownUBInsts.count(&I))
2949         return true;
2950 
2951       // If we reach here, we know we have an instruction
2952       // that accesses memory through a pointer operand,
2953       // for which getPointerOperand() should give it to us.
2954       Value *PtrOp =
2955           const_cast<Value *>(getPointerOperand(&I, /* AllowVolatile */ true));
2956       assert(PtrOp &&
2957              "Expected pointer operand of memory accessing instruction");
2958 
2959       // Either we stopped and the appropriate action was taken,
2960       // or we got back a simplified value to continue.
2961       std::optional<Value *> SimplifiedPtrOp =
2962           stopOnUndefOrAssumed(A, PtrOp, &I);
2963       if (!SimplifiedPtrOp || !*SimplifiedPtrOp)
2964         return true;
2965       const Value *PtrOpVal = *SimplifiedPtrOp;
2966 
2967       // A memory access through a pointer is considered UB
2968       // only if the pointer has constant null value.
2969       // TODO: Expand it to not only check constant values.
2970       if (!isa<ConstantPointerNull>(PtrOpVal)) {
2971         AssumedNoUBInsts.insert(&I);
2972         return true;
2973       }
2974       const Type *PtrTy = PtrOpVal->getType();
2975 
2976       // Because we only consider instructions inside functions,
2977       // assume that a parent function exists.
2978       const Function *F = I.getFunction();
2979 
2980       // A memory access using constant null pointer is only considered UB
2981       // if null pointer is _not_ defined for the target platform.
2982       if (llvm::NullPointerIsDefined(F, PtrTy->getPointerAddressSpace()))
2983         AssumedNoUBInsts.insert(&I);
2984       else
2985         KnownUBInsts.insert(&I);
2986       return true;
2987     };
2988 
2989     auto InspectBrInstForUB = [&](Instruction &I) {
2990       // A conditional branch instruction is considered UB if it has `undef`
2991       // condition.
2992 
2993       // Skip instructions that are already saved.
2994       if (AssumedNoUBInsts.count(&I) || KnownUBInsts.count(&I))
2995         return true;
2996 
2997       // We know we have a branch instruction.
2998       auto *BrInst = cast<BranchInst>(&I);
2999 
3000       // Unconditional branches are never considered UB.
3001       if (BrInst->isUnconditional())
3002         return true;
3003 
3004       // Either we stopped and the appropriate action was taken,
3005       // or we got back a simplified value to continue.
3006       std::optional<Value *> SimplifiedCond =
3007           stopOnUndefOrAssumed(A, BrInst->getCondition(), BrInst);
3008       if (!SimplifiedCond || !*SimplifiedCond)
3009         return true;
3010       AssumedNoUBInsts.insert(&I);
3011       return true;
3012     };
3013 
3014     auto InspectCallSiteForUB = [&](Instruction &I) {
3015       // Check whether a callsite always cause UB or not
3016 
3017       // Skip instructions that are already saved.
3018       if (AssumedNoUBInsts.count(&I) || KnownUBInsts.count(&I))
3019         return true;
3020 
3021       // Check nonnull and noundef argument attribute violation for each
3022       // callsite.
3023       CallBase &CB = cast<CallBase>(I);
3024       Function *Callee = CB.getCalledFunction();
3025       if (!Callee)
3026         return true;
3027       for (unsigned idx = 0; idx < CB.arg_size(); idx++) {
3028         // If current argument is known to be simplified to null pointer and the
3029         // corresponding argument position is known to have nonnull attribute,
3030         // the argument is poison. Furthermore, if the argument is poison and
3031         // the position is known to have noundef attriubte, this callsite is
3032         // considered UB.
3033         if (idx >= Callee->arg_size())
3034           break;
3035         Value *ArgVal = CB.getArgOperand(idx);
3036         if (!ArgVal)
3037           continue;
3038         // Here, we handle three cases.
3039         //   (1) Not having a value means it is dead. (we can replace the value
3040         //       with undef)
3041         //   (2) Simplified to undef. The argument violate noundef attriubte.
3042         //   (3) Simplified to null pointer where known to be nonnull.
3043         //       The argument is a poison value and violate noundef attribute.
3044         IRPosition CalleeArgumentIRP = IRPosition::callsite_argument(CB, idx);
3045         auto &NoUndefAA =
3046             A.getAAFor<AANoUndef>(*this, CalleeArgumentIRP, DepClassTy::NONE);
3047         if (!NoUndefAA.isKnownNoUndef())
3048           continue;
3049         bool UsedAssumedInformation = false;
3050         std::optional<Value *> SimplifiedVal =
3051             A.getAssumedSimplified(IRPosition::value(*ArgVal), *this,
3052                                    UsedAssumedInformation, AA::Interprocedural);
3053         if (UsedAssumedInformation)
3054           continue;
3055         if (SimplifiedVal && !*SimplifiedVal)
3056           return true;
3057         if (!SimplifiedVal || isa<UndefValue>(**SimplifiedVal)) {
3058           KnownUBInsts.insert(&I);
3059           continue;
3060         }
3061         if (!ArgVal->getType()->isPointerTy() ||
3062             !isa<ConstantPointerNull>(**SimplifiedVal))
3063           continue;
3064         auto &NonNullAA =
3065             A.getAAFor<AANonNull>(*this, CalleeArgumentIRP, DepClassTy::NONE);
3066         if (NonNullAA.isKnownNonNull())
3067           KnownUBInsts.insert(&I);
3068       }
3069       return true;
3070     };
3071 
3072     auto InspectReturnInstForUB = [&](Instruction &I) {
3073       auto &RI = cast<ReturnInst>(I);
3074       // Either we stopped and the appropriate action was taken,
3075       // or we got back a simplified return value to continue.
3076       std::optional<Value *> SimplifiedRetValue =
3077           stopOnUndefOrAssumed(A, RI.getReturnValue(), &I);
3078       if (!SimplifiedRetValue || !*SimplifiedRetValue)
3079         return true;
3080 
3081       // Check if a return instruction always cause UB or not
3082       // Note: It is guaranteed that the returned position of the anchor
3083       //       scope has noundef attribute when this is called.
3084       //       We also ensure the return position is not "assumed dead"
3085       //       because the returned value was then potentially simplified to
3086       //       `undef` in AAReturnedValues without removing the `noundef`
3087       //       attribute yet.
3088 
3089       // When the returned position has noundef attriubte, UB occurs in the
3090       // following cases.
3091       //   (1) Returned value is known to be undef.
3092       //   (2) The value is known to be a null pointer and the returned
3093       //       position has nonnull attribute (because the returned value is
3094       //       poison).
3095       if (isa<ConstantPointerNull>(*SimplifiedRetValue)) {
3096         auto &NonNullAA = A.getAAFor<AANonNull>(
3097             *this, IRPosition::returned(*getAnchorScope()), DepClassTy::NONE);
3098         if (NonNullAA.isKnownNonNull())
3099           KnownUBInsts.insert(&I);
3100       }
3101 
3102       return true;
3103     };
3104 
3105     bool UsedAssumedInformation = false;
3106     A.checkForAllInstructions(InspectMemAccessInstForUB, *this,
3107                               {Instruction::Load, Instruction::Store,
3108                                Instruction::AtomicCmpXchg,
3109                                Instruction::AtomicRMW},
3110                               UsedAssumedInformation,
3111                               /* CheckBBLivenessOnly */ true);
3112     A.checkForAllInstructions(InspectBrInstForUB, *this, {Instruction::Br},
3113                               UsedAssumedInformation,
3114                               /* CheckBBLivenessOnly */ true);
3115     A.checkForAllCallLikeInstructions(InspectCallSiteForUB, *this,
3116                                       UsedAssumedInformation);
3117 
3118     // If the returned position of the anchor scope has noundef attriubte, check
3119     // all returned instructions.
3120     if (!getAnchorScope()->getReturnType()->isVoidTy()) {
3121       const IRPosition &ReturnIRP = IRPosition::returned(*getAnchorScope());
3122       if (!A.isAssumedDead(ReturnIRP, this, nullptr, UsedAssumedInformation)) {
3123         auto &RetPosNoUndefAA =
3124             A.getAAFor<AANoUndef>(*this, ReturnIRP, DepClassTy::NONE);
3125         if (RetPosNoUndefAA.isKnownNoUndef())
3126           A.checkForAllInstructions(InspectReturnInstForUB, *this,
3127                                     {Instruction::Ret}, UsedAssumedInformation,
3128                                     /* CheckBBLivenessOnly */ true);
3129       }
3130     }
3131 
3132     if (NoUBPrevSize != AssumedNoUBInsts.size() ||
3133         UBPrevSize != KnownUBInsts.size())
3134       return ChangeStatus::CHANGED;
3135     return ChangeStatus::UNCHANGED;
3136   }
3137 
3138   bool isKnownToCauseUB(Instruction *I) const override {
3139     return KnownUBInsts.count(I);
3140   }
3141 
3142   bool isAssumedToCauseUB(Instruction *I) const override {
3143     // In simple words, if an instruction is not in the assumed to _not_
3144     // cause UB, then it is assumed UB (that includes those
3145     // in the KnownUBInsts set). The rest is boilerplate
3146     // is to ensure that it is one of the instructions we test
3147     // for UB.
3148 
3149     switch (I->getOpcode()) {
3150     case Instruction::Load:
3151     case Instruction::Store:
3152     case Instruction::AtomicCmpXchg:
3153     case Instruction::AtomicRMW:
3154       return !AssumedNoUBInsts.count(I);
3155     case Instruction::Br: {
3156       auto *BrInst = cast<BranchInst>(I);
3157       if (BrInst->isUnconditional())
3158         return false;
3159       return !AssumedNoUBInsts.count(I);
3160     } break;
3161     default:
3162       return false;
3163     }
3164     return false;
3165   }
3166 
3167   ChangeStatus manifest(Attributor &A) override {
3168     if (KnownUBInsts.empty())
3169       return ChangeStatus::UNCHANGED;
3170     for (Instruction *I : KnownUBInsts)
3171       A.changeToUnreachableAfterManifest(I);
3172     return ChangeStatus::CHANGED;
3173   }
3174 
3175   /// See AbstractAttribute::getAsStr()
3176   const std::string getAsStr() const override {
3177     return getAssumed() ? "undefined-behavior" : "no-ub";
3178   }
3179 
3180   /// Note: The correctness of this analysis depends on the fact that the
3181   /// following 2 sets will stop changing after some point.
3182   /// "Change" here means that their size changes.
3183   /// The size of each set is monotonically increasing
3184   /// (we only add items to them) and it is upper bounded by the number of
3185   /// instructions in the processed function (we can never save more
3186   /// elements in either set than this number). Hence, at some point,
3187   /// they will stop increasing.
3188   /// Consequently, at some point, both sets will have stopped
3189   /// changing, effectively making the analysis reach a fixpoint.
3190 
3191   /// Note: These 2 sets are disjoint and an instruction can be considered
3192   /// one of 3 things:
3193   /// 1) Known to cause UB (AAUndefinedBehavior could prove it) and put it in
3194   ///    the KnownUBInsts set.
3195   /// 2) Assumed to cause UB (in every updateImpl, AAUndefinedBehavior
3196   ///    has a reason to assume it).
3197   /// 3) Assumed to not cause UB. very other instruction - AAUndefinedBehavior
3198   ///    could not find a reason to assume or prove that it can cause UB,
3199   ///    hence it assumes it doesn't. We have a set for these instructions
3200   ///    so that we don't reprocess them in every update.
3201   ///    Note however that instructions in this set may cause UB.
3202 
3203 protected:
3204   /// A set of all live instructions _known_ to cause UB.
3205   SmallPtrSet<Instruction *, 8> KnownUBInsts;
3206 
3207 private:
3208   /// A set of all the (live) instructions that are assumed to _not_ cause UB.
3209   SmallPtrSet<Instruction *, 8> AssumedNoUBInsts;
3210 
3211   // Should be called on updates in which if we're processing an instruction
3212   // \p I that depends on a value \p V, one of the following has to happen:
3213   // - If the value is assumed, then stop.
3214   // - If the value is known but undef, then consider it UB.
3215   // - Otherwise, do specific processing with the simplified value.
3216   // We return std::nullopt in the first 2 cases to signify that an appropriate
3217   // action was taken and the caller should stop.
3218   // Otherwise, we return the simplified value that the caller should
3219   // use for specific processing.
3220   std::optional<Value *> stopOnUndefOrAssumed(Attributor &A, Value *V,
3221                                               Instruction *I) {
3222     bool UsedAssumedInformation = false;
3223     std::optional<Value *> SimplifiedV =
3224         A.getAssumedSimplified(IRPosition::value(*V), *this,
3225                                UsedAssumedInformation, AA::Interprocedural);
3226     if (!UsedAssumedInformation) {
3227       // Don't depend on assumed values.
3228       if (!SimplifiedV) {
3229         // If it is known (which we tested above) but it doesn't have a value,
3230         // then we can assume `undef` and hence the instruction is UB.
3231         KnownUBInsts.insert(I);
3232         return std::nullopt;
3233       }
3234       if (!*SimplifiedV)
3235         return nullptr;
3236       V = *SimplifiedV;
3237     }
3238     if (isa<UndefValue>(V)) {
3239       KnownUBInsts.insert(I);
3240       return std::nullopt;
3241     }
3242     return V;
3243   }
3244 };
3245 
3246 struct AAUndefinedBehaviorFunction final : AAUndefinedBehaviorImpl {
3247   AAUndefinedBehaviorFunction(const IRPosition &IRP, Attributor &A)
3248       : AAUndefinedBehaviorImpl(IRP, A) {}
3249 
3250   /// See AbstractAttribute::trackStatistics()
3251   void trackStatistics() const override {
3252     STATS_DECL(UndefinedBehaviorInstruction, Instruction,
3253                "Number of instructions known to have UB");
3254     BUILD_STAT_NAME(UndefinedBehaviorInstruction, Instruction) +=
3255         KnownUBInsts.size();
3256   }
3257 };
3258 } // namespace
3259 
3260 /// ------------------------ Will-Return Attributes ----------------------------
3261 
3262 namespace {
3263 // Helper function that checks whether a function has any cycle which we don't
3264 // know if it is bounded or not.
3265 // Loops with maximum trip count are considered bounded, any other cycle not.
3266 static bool mayContainUnboundedCycle(Function &F, Attributor &A) {
3267   ScalarEvolution *SE =
3268       A.getInfoCache().getAnalysisResultForFunction<ScalarEvolutionAnalysis>(F);
3269   LoopInfo *LI = A.getInfoCache().getAnalysisResultForFunction<LoopAnalysis>(F);
3270   // If either SCEV or LoopInfo is not available for the function then we assume
3271   // any cycle to be unbounded cycle.
3272   // We use scc_iterator which uses Tarjan algorithm to find all the maximal
3273   // SCCs.To detect if there's a cycle, we only need to find the maximal ones.
3274   if (!SE || !LI) {
3275     for (scc_iterator<Function *> SCCI = scc_begin(&F); !SCCI.isAtEnd(); ++SCCI)
3276       if (SCCI.hasCycle())
3277         return true;
3278     return false;
3279   }
3280 
3281   // If there's irreducible control, the function may contain non-loop cycles.
3282   if (mayContainIrreducibleControl(F, LI))
3283     return true;
3284 
3285   // Any loop that does not have a max trip count is considered unbounded cycle.
3286   for (auto *L : LI->getLoopsInPreorder()) {
3287     if (!SE->getSmallConstantMaxTripCount(L))
3288       return true;
3289   }
3290   return false;
3291 }
3292 
3293 struct AAWillReturnImpl : public AAWillReturn {
3294   AAWillReturnImpl(const IRPosition &IRP, Attributor &A)
3295       : AAWillReturn(IRP, A) {}
3296 
3297   /// See AbstractAttribute::initialize(...).
3298   void initialize(Attributor &A) override {
3299     AAWillReturn::initialize(A);
3300 
3301     if (isImpliedByMustprogressAndReadonly(A, /* KnownOnly */ true)) {
3302       indicateOptimisticFixpoint();
3303       return;
3304     }
3305   }
3306 
3307   /// Check for `mustprogress` and `readonly` as they imply `willreturn`.
3308   bool isImpliedByMustprogressAndReadonly(Attributor &A, bool KnownOnly) {
3309     // Check for `mustprogress` in the scope and the associated function which
3310     // might be different if this is a call site.
3311     if ((!getAnchorScope() || !getAnchorScope()->mustProgress()) &&
3312         (!getAssociatedFunction() || !getAssociatedFunction()->mustProgress()))
3313       return false;
3314 
3315     bool IsKnown;
3316     if (AA::isAssumedReadOnly(A, getIRPosition(), *this, IsKnown))
3317       return IsKnown || !KnownOnly;
3318     return false;
3319   }
3320 
3321   /// See AbstractAttribute::updateImpl(...).
3322   ChangeStatus updateImpl(Attributor &A) override {
3323     if (isImpliedByMustprogressAndReadonly(A, /* KnownOnly */ false))
3324       return ChangeStatus::UNCHANGED;
3325 
3326     auto CheckForWillReturn = [&](Instruction &I) {
3327       IRPosition IPos = IRPosition::callsite_function(cast<CallBase>(I));
3328       const auto &WillReturnAA =
3329           A.getAAFor<AAWillReturn>(*this, IPos, DepClassTy::REQUIRED);
3330       if (WillReturnAA.isKnownWillReturn())
3331         return true;
3332       if (!WillReturnAA.isAssumedWillReturn())
3333         return false;
3334       const auto &NoRecurseAA =
3335           A.getAAFor<AANoRecurse>(*this, IPos, DepClassTy::REQUIRED);
3336       return NoRecurseAA.isAssumedNoRecurse();
3337     };
3338 
3339     bool UsedAssumedInformation = false;
3340     if (!A.checkForAllCallLikeInstructions(CheckForWillReturn, *this,
3341                                            UsedAssumedInformation))
3342       return indicatePessimisticFixpoint();
3343 
3344     return ChangeStatus::UNCHANGED;
3345   }
3346 
3347   /// See AbstractAttribute::getAsStr()
3348   const std::string getAsStr() const override {
3349     return getAssumed() ? "willreturn" : "may-noreturn";
3350   }
3351 };
3352 
3353 struct AAWillReturnFunction final : AAWillReturnImpl {
3354   AAWillReturnFunction(const IRPosition &IRP, Attributor &A)
3355       : AAWillReturnImpl(IRP, A) {}
3356 
3357   /// See AbstractAttribute::initialize(...).
3358   void initialize(Attributor &A) override {
3359     AAWillReturnImpl::initialize(A);
3360 
3361     Function *F = getAnchorScope();
3362     if (!F || F->isDeclaration() || mayContainUnboundedCycle(*F, A))
3363       indicatePessimisticFixpoint();
3364   }
3365 
3366   /// See AbstractAttribute::trackStatistics()
3367   void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(willreturn) }
3368 };
3369 
3370 /// WillReturn attribute deduction for a call sites.
3371 struct AAWillReturnCallSite final : AAWillReturnImpl {
3372   AAWillReturnCallSite(const IRPosition &IRP, Attributor &A)
3373       : AAWillReturnImpl(IRP, A) {}
3374 
3375   /// See AbstractAttribute::initialize(...).
3376   void initialize(Attributor &A) override {
3377     AAWillReturnImpl::initialize(A);
3378     Function *F = getAssociatedFunction();
3379     if (!F || !A.isFunctionIPOAmendable(*F))
3380       indicatePessimisticFixpoint();
3381   }
3382 
3383   /// See AbstractAttribute::updateImpl(...).
3384   ChangeStatus updateImpl(Attributor &A) override {
3385     if (isImpliedByMustprogressAndReadonly(A, /* KnownOnly */ false))
3386       return ChangeStatus::UNCHANGED;
3387 
3388     // TODO: Once we have call site specific value information we can provide
3389     //       call site specific liveness information and then it makes
3390     //       sense to specialize attributes for call sites arguments instead of
3391     //       redirecting requests to the callee argument.
3392     Function *F = getAssociatedFunction();
3393     const IRPosition &FnPos = IRPosition::function(*F);
3394     auto &FnAA = A.getAAFor<AAWillReturn>(*this, FnPos, DepClassTy::REQUIRED);
3395     return clampStateAndIndicateChange(getState(), FnAA.getState());
3396   }
3397 
3398   /// See AbstractAttribute::trackStatistics()
3399   void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(willreturn); }
3400 };
3401 } // namespace
3402 
3403 /// -------------------AAIntraFnReachability Attribute--------------------------
3404 
3405 /// All information associated with a reachability query. This boilerplate code
3406 /// is used by both AAIntraFnReachability and AAInterFnReachability, with
3407 /// different \p ToTy values.
3408 template <typename ToTy> struct ReachabilityQueryInfo {
3409   enum class Reachable {
3410     No,
3411     Yes,
3412   };
3413 
3414   /// Start here,
3415   const Instruction *From = nullptr;
3416   /// reach this place,
3417   const ToTy *To = nullptr;
3418   /// without going through any of these instructions,
3419   const AA::InstExclusionSetTy *ExclusionSet = nullptr;
3420   /// and remember if it worked:
3421   Reachable Result = Reachable::No;
3422 
3423   ReachabilityQueryInfo(const Instruction *From, const ToTy *To)
3424       : From(From), To(To) {}
3425 
3426   /// Constructor replacement to ensure unique and stable sets are used for the
3427   /// cache.
3428   ReachabilityQueryInfo(Attributor &A, const Instruction &From, const ToTy &To,
3429                         const AA::InstExclusionSetTy *ES)
3430       : From(&From), To(&To), ExclusionSet(ES) {
3431 
3432     if (ExclusionSet && !ExclusionSet->empty()) {
3433       ExclusionSet =
3434           A.getInfoCache().getOrCreateUniqueBlockExecutionSet(ExclusionSet);
3435     } else {
3436       ExclusionSet = nullptr;
3437     }
3438   }
3439 
3440   ReachabilityQueryInfo(const ReachabilityQueryInfo &RQI)
3441       : From(RQI.From), To(RQI.To), ExclusionSet(RQI.ExclusionSet) {
3442     assert(RQI.Result == Reachable::No &&
3443            "Didn't expect to copy an explored RQI!");
3444   }
3445 };
3446 
3447 namespace llvm {
3448 template <typename ToTy> struct DenseMapInfo<ReachabilityQueryInfo<ToTy> *> {
3449   using InstSetDMI = DenseMapInfo<const AA::InstExclusionSetTy *>;
3450   using PairDMI = DenseMapInfo<std::pair<const Instruction *, const ToTy *>>;
3451 
3452   static ReachabilityQueryInfo<ToTy> EmptyKey;
3453   static ReachabilityQueryInfo<ToTy> TombstoneKey;
3454 
3455   static inline ReachabilityQueryInfo<ToTy> *getEmptyKey() { return &EmptyKey; }
3456   static inline ReachabilityQueryInfo<ToTy> *getTombstoneKey() {
3457     return &TombstoneKey;
3458   }
3459   static unsigned getHashValue(const ReachabilityQueryInfo<ToTy> *RQI) {
3460     unsigned H = PairDMI ::getHashValue({RQI->From, RQI->To});
3461     H += InstSetDMI::getHashValue(RQI->ExclusionSet);
3462     return H;
3463   }
3464   static bool isEqual(const ReachabilityQueryInfo<ToTy> *LHS,
3465                       const ReachabilityQueryInfo<ToTy> *RHS) {
3466     if (!PairDMI::isEqual({LHS->From, LHS->To}, {RHS->From, RHS->To}))
3467       return false;
3468     return InstSetDMI::isEqual(LHS->ExclusionSet, RHS->ExclusionSet);
3469   }
3470 };
3471 
3472 #define DefineKeys(ToTy)                                                       \
3473   template <>                                                                  \
3474   ReachabilityQueryInfo<ToTy>                                                  \
3475       DenseMapInfo<ReachabilityQueryInfo<ToTy> *>::EmptyKey =                  \
3476           ReachabilityQueryInfo<ToTy>(                                         \
3477               DenseMapInfo<const Instruction *>::getEmptyKey(),                \
3478               DenseMapInfo<const ToTy *>::getEmptyKey());                      \
3479   template <>                                                                  \
3480   ReachabilityQueryInfo<ToTy>                                                  \
3481       DenseMapInfo<ReachabilityQueryInfo<ToTy> *>::TombstoneKey =              \
3482           ReachabilityQueryInfo<ToTy>(                                         \
3483               DenseMapInfo<const Instruction *>::getTombstoneKey(),            \
3484               DenseMapInfo<const ToTy *>::getTombstoneKey());
3485 
3486 DefineKeys(Instruction) DefineKeys(Function)
3487 #undef DefineKeys
3488 
3489 } // namespace llvm
3490 
3491 namespace {
3492 
3493 template <typename BaseTy, typename ToTy>
3494 struct CachedReachabilityAA : public BaseTy {
3495   using RQITy = ReachabilityQueryInfo<ToTy>;
3496 
3497   CachedReachabilityAA<BaseTy, ToTy>(const IRPosition &IRP, Attributor &A)
3498       : BaseTy(IRP, A) {}
3499 
3500   /// See AbstractAttribute::isQueryAA.
3501   bool isQueryAA() const override { return true; }
3502 
3503   /// See AbstractAttribute::updateImpl(...).
3504   ChangeStatus updateImpl(Attributor &A) override {
3505     ChangeStatus Changed = ChangeStatus::UNCHANGED;
3506     InUpdate = true;
3507     for (RQITy *RQI : QueryVector) {
3508       if (RQI->Result == RQITy::Reachable::No && isReachableImpl(A, *RQI))
3509         Changed = ChangeStatus::CHANGED;
3510     }
3511     InUpdate = false;
3512     return Changed;
3513   }
3514 
3515   virtual bool isReachableImpl(Attributor &A, RQITy &RQI) = 0;
3516 
3517   bool rememberResult(Attributor &A, typename RQITy::Reachable Result,
3518                       RQITy &RQI) {
3519     if (Result == RQITy::Reachable::No) {
3520       if (!InUpdate)
3521         A.registerForUpdate(*this);
3522       return false;
3523     }
3524     assert(RQI.Result == RQITy::Reachable::No && "Already reachable?");
3525     RQI.Result = Result;
3526     return true;
3527   }
3528 
3529   const std::string getAsStr() const override {
3530     // TODO: Return the number of reachable queries.
3531     return "#queries(" + std::to_string(QueryVector.size()) + ")";
3532   }
3533 
3534   RQITy *checkQueryCache(Attributor &A, RQITy &StackRQI,
3535                          typename RQITy::Reachable &Result) {
3536     if (!this->getState().isValidState()) {
3537       Result = RQITy::Reachable::Yes;
3538       return nullptr;
3539     }
3540 
3541     auto It = QueryCache.find(&StackRQI);
3542     if (It != QueryCache.end()) {
3543       Result = (*It)->Result;
3544       return nullptr;
3545     }
3546 
3547     RQITy *RQIPtr = new (A.Allocator) RQITy(StackRQI);
3548     QueryVector.push_back(RQIPtr);
3549     QueryCache.insert(RQIPtr);
3550     return RQIPtr;
3551   }
3552 
3553 private:
3554   bool InUpdate = false;
3555   SmallVector<RQITy *> QueryVector;
3556   DenseSet<RQITy *> QueryCache;
3557 };
3558 
3559 struct AAIntraFnReachabilityFunction final
3560     : public CachedReachabilityAA<AAIntraFnReachability, Instruction> {
3561   AAIntraFnReachabilityFunction(const IRPosition &IRP, Attributor &A)
3562       : CachedReachabilityAA<AAIntraFnReachability, Instruction>(IRP, A) {}
3563 
3564   bool isAssumedReachable(
3565       Attributor &A, const Instruction &From, const Instruction &To,
3566       const AA::InstExclusionSetTy *ExclusionSet) const override {
3567     auto *NonConstThis = const_cast<AAIntraFnReachabilityFunction *>(this);
3568     if (&From == &To)
3569       return true;
3570 
3571     RQITy StackRQI(A, From, To, ExclusionSet);
3572     typename RQITy::Reachable Result;
3573     if (RQITy *RQIPtr = NonConstThis->checkQueryCache(A, StackRQI, Result)) {
3574       return NonConstThis->isReachableImpl(A, *RQIPtr);
3575     }
3576     return Result == RQITy::Reachable::Yes;
3577   }
3578 
3579   bool isReachableImpl(Attributor &A, RQITy &RQI) override {
3580     const Instruction *Origin = RQI.From;
3581 
3582     auto WillReachInBlock = [=](const Instruction &From, const Instruction &To,
3583                                 const AA::InstExclusionSetTy *ExclusionSet) {
3584       const Instruction *IP = &From;
3585       while (IP && IP != &To) {
3586         if (ExclusionSet && IP != Origin && ExclusionSet->count(IP))
3587           break;
3588         IP = IP->getNextNode();
3589       }
3590       return IP == &To;
3591     };
3592 
3593     const BasicBlock *FromBB = RQI.From->getParent();
3594     const BasicBlock *ToBB = RQI.To->getParent();
3595     assert(FromBB->getParent() == ToBB->getParent() &&
3596            "Not an intra-procedural query!");
3597 
3598     // Check intra-block reachability, however, other reaching paths are still
3599     // possible.
3600     if (FromBB == ToBB &&
3601         WillReachInBlock(*RQI.From, *RQI.To, RQI.ExclusionSet))
3602       return rememberResult(A, RQITy::Reachable::Yes, RQI);
3603 
3604     SmallPtrSet<const BasicBlock *, 16> ExclusionBlocks;
3605     if (RQI.ExclusionSet)
3606       for (auto *I : *RQI.ExclusionSet)
3607         ExclusionBlocks.insert(I->getParent());
3608 
3609     // Check if we make it out of the FromBB block at all.
3610     if (ExclusionBlocks.count(FromBB) &&
3611         !WillReachInBlock(*RQI.From, *FromBB->getTerminator(),
3612                           RQI.ExclusionSet))
3613       return rememberResult(A, RQITy::Reachable::No, RQI);
3614 
3615     SmallPtrSet<const BasicBlock *, 16> Visited;
3616     SmallVector<const BasicBlock *, 16> Worklist;
3617     Worklist.push_back(FromBB);
3618 
3619     auto &LivenessAA =
3620         A.getAAFor<AAIsDead>(*this, getIRPosition(), DepClassTy::OPTIONAL);
3621     while (!Worklist.empty()) {
3622       const BasicBlock *BB = Worklist.pop_back_val();
3623       if (!Visited.insert(BB).second)
3624         continue;
3625       for (const BasicBlock *SuccBB : successors(BB)) {
3626         if (LivenessAA.isEdgeDead(BB, SuccBB))
3627           continue;
3628         if (SuccBB == ToBB &&
3629             WillReachInBlock(SuccBB->front(), *RQI.To, RQI.ExclusionSet))
3630           return rememberResult(A, RQITy::Reachable::Yes, RQI);
3631         if (ExclusionBlocks.count(SuccBB))
3632           continue;
3633         Worklist.push_back(SuccBB);
3634       }
3635     }
3636 
3637     return rememberResult(A, RQITy::Reachable::No, RQI);
3638   }
3639 
3640   /// See AbstractAttribute::trackStatistics()
3641   void trackStatistics() const override {}
3642 };
3643 } // namespace
3644 
3645 /// ------------------------ NoAlias Argument Attribute ------------------------
3646 
3647 namespace {
3648 struct AANoAliasImpl : AANoAlias {
3649   AANoAliasImpl(const IRPosition &IRP, Attributor &A) : AANoAlias(IRP, A) {
3650     assert(getAssociatedType()->isPointerTy() &&
3651            "Noalias is a pointer attribute");
3652   }
3653 
3654   const std::string getAsStr() const override {
3655     return getAssumed() ? "noalias" : "may-alias";
3656   }
3657 };
3658 
3659 /// NoAlias attribute for a floating value.
3660 struct AANoAliasFloating final : AANoAliasImpl {
3661   AANoAliasFloating(const IRPosition &IRP, Attributor &A)
3662       : AANoAliasImpl(IRP, A) {}
3663 
3664   /// See AbstractAttribute::initialize(...).
3665   void initialize(Attributor &A) override {
3666     AANoAliasImpl::initialize(A);
3667     Value *Val = &getAssociatedValue();
3668     do {
3669       CastInst *CI = dyn_cast<CastInst>(Val);
3670       if (!CI)
3671         break;
3672       Value *Base = CI->getOperand(0);
3673       if (!Base->hasOneUse())
3674         break;
3675       Val = Base;
3676     } while (true);
3677 
3678     if (!Val->getType()->isPointerTy()) {
3679       indicatePessimisticFixpoint();
3680       return;
3681     }
3682 
3683     if (isa<AllocaInst>(Val))
3684       indicateOptimisticFixpoint();
3685     else if (isa<ConstantPointerNull>(Val) &&
3686              !NullPointerIsDefined(getAnchorScope(),
3687                                    Val->getType()->getPointerAddressSpace()))
3688       indicateOptimisticFixpoint();
3689     else if (Val != &getAssociatedValue()) {
3690       const auto &ValNoAliasAA = A.getAAFor<AANoAlias>(
3691           *this, IRPosition::value(*Val), DepClassTy::OPTIONAL);
3692       if (ValNoAliasAA.isKnownNoAlias())
3693         indicateOptimisticFixpoint();
3694     }
3695   }
3696 
3697   /// See AbstractAttribute::updateImpl(...).
3698   ChangeStatus updateImpl(Attributor &A) override {
3699     // TODO: Implement this.
3700     return indicatePessimisticFixpoint();
3701   }
3702 
3703   /// See AbstractAttribute::trackStatistics()
3704   void trackStatistics() const override {
3705     STATS_DECLTRACK_FLOATING_ATTR(noalias)
3706   }
3707 };
3708 
3709 /// NoAlias attribute for an argument.
3710 struct AANoAliasArgument final
3711     : AAArgumentFromCallSiteArguments<AANoAlias, AANoAliasImpl> {
3712   using Base = AAArgumentFromCallSiteArguments<AANoAlias, AANoAliasImpl>;
3713   AANoAliasArgument(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {}
3714 
3715   /// See AbstractAttribute::initialize(...).
3716   void initialize(Attributor &A) override {
3717     Base::initialize(A);
3718     // See callsite argument attribute and callee argument attribute.
3719     if (hasAttr({Attribute::ByVal}))
3720       indicateOptimisticFixpoint();
3721   }
3722 
3723   /// See AbstractAttribute::update(...).
3724   ChangeStatus updateImpl(Attributor &A) override {
3725     // We have to make sure no-alias on the argument does not break
3726     // synchronization when this is a callback argument, see also [1] below.
3727     // If synchronization cannot be affected, we delegate to the base updateImpl
3728     // function, otherwise we give up for now.
3729 
3730     // If the function is no-sync, no-alias cannot break synchronization.
3731     const auto &NoSyncAA =
3732         A.getAAFor<AANoSync>(*this, IRPosition::function_scope(getIRPosition()),
3733                              DepClassTy::OPTIONAL);
3734     if (NoSyncAA.isAssumedNoSync())
3735       return Base::updateImpl(A);
3736 
3737     // If the argument is read-only, no-alias cannot break synchronization.
3738     bool IsKnown;
3739     if (AA::isAssumedReadOnly(A, getIRPosition(), *this, IsKnown))
3740       return Base::updateImpl(A);
3741 
3742     // If the argument is never passed through callbacks, no-alias cannot break
3743     // synchronization.
3744     bool UsedAssumedInformation = false;
3745     if (A.checkForAllCallSites(
3746             [](AbstractCallSite ACS) { return !ACS.isCallbackCall(); }, *this,
3747             true, UsedAssumedInformation))
3748       return Base::updateImpl(A);
3749 
3750     // TODO: add no-alias but make sure it doesn't break synchronization by
3751     // introducing fake uses. See:
3752     // [1] Compiler Optimizations for OpenMP, J. Doerfert and H. Finkel,
3753     //     International Workshop on OpenMP 2018,
3754     //     http://compilers.cs.uni-saarland.de/people/doerfert/par_opt18.pdf
3755 
3756     return indicatePessimisticFixpoint();
3757   }
3758 
3759   /// See AbstractAttribute::trackStatistics()
3760   void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(noalias) }
3761 };
3762 
3763 struct AANoAliasCallSiteArgument final : AANoAliasImpl {
3764   AANoAliasCallSiteArgument(const IRPosition &IRP, Attributor &A)
3765       : AANoAliasImpl(IRP, A) {}
3766 
3767   /// See AbstractAttribute::initialize(...).
3768   void initialize(Attributor &A) override {
3769     // See callsite argument attribute and callee argument attribute.
3770     const auto &CB = cast<CallBase>(getAnchorValue());
3771     if (CB.paramHasAttr(getCallSiteArgNo(), Attribute::NoAlias))
3772       indicateOptimisticFixpoint();
3773     Value &Val = getAssociatedValue();
3774     if (isa<ConstantPointerNull>(Val) &&
3775         !NullPointerIsDefined(getAnchorScope(),
3776                               Val.getType()->getPointerAddressSpace()))
3777       indicateOptimisticFixpoint();
3778   }
3779 
3780   /// Determine if the underlying value may alias with the call site argument
3781   /// \p OtherArgNo of \p ICS (= the underlying call site).
3782   bool mayAliasWithArgument(Attributor &A, AAResults *&AAR,
3783                             const AAMemoryBehavior &MemBehaviorAA,
3784                             const CallBase &CB, unsigned OtherArgNo) {
3785     // We do not need to worry about aliasing with the underlying IRP.
3786     if (this->getCalleeArgNo() == (int)OtherArgNo)
3787       return false;
3788 
3789     // If it is not a pointer or pointer vector we do not alias.
3790     const Value *ArgOp = CB.getArgOperand(OtherArgNo);
3791     if (!ArgOp->getType()->isPtrOrPtrVectorTy())
3792       return false;
3793 
3794     auto &CBArgMemBehaviorAA = A.getAAFor<AAMemoryBehavior>(
3795         *this, IRPosition::callsite_argument(CB, OtherArgNo), DepClassTy::NONE);
3796 
3797     // If the argument is readnone, there is no read-write aliasing.
3798     if (CBArgMemBehaviorAA.isAssumedReadNone()) {
3799       A.recordDependence(CBArgMemBehaviorAA, *this, DepClassTy::OPTIONAL);
3800       return false;
3801     }
3802 
3803     // If the argument is readonly and the underlying value is readonly, there
3804     // is no read-write aliasing.
3805     bool IsReadOnly = MemBehaviorAA.isAssumedReadOnly();
3806     if (CBArgMemBehaviorAA.isAssumedReadOnly() && IsReadOnly) {
3807       A.recordDependence(MemBehaviorAA, *this, DepClassTy::OPTIONAL);
3808       A.recordDependence(CBArgMemBehaviorAA, *this, DepClassTy::OPTIONAL);
3809       return false;
3810     }
3811 
3812     // We have to utilize actual alias analysis queries so we need the object.
3813     if (!AAR)
3814       AAR = A.getInfoCache().getAAResultsForFunction(*getAnchorScope());
3815 
3816     // Try to rule it out at the call site.
3817     bool IsAliasing = !AAR || !AAR->isNoAlias(&getAssociatedValue(), ArgOp);
3818     LLVM_DEBUG(dbgs() << "[NoAliasCSArg] Check alias between "
3819                          "callsite arguments: "
3820                       << getAssociatedValue() << " " << *ArgOp << " => "
3821                       << (IsAliasing ? "" : "no-") << "alias \n");
3822 
3823     return IsAliasing;
3824   }
3825 
3826   bool
3827   isKnownNoAliasDueToNoAliasPreservation(Attributor &A, AAResults *&AAR,
3828                                          const AAMemoryBehavior &MemBehaviorAA,
3829                                          const AANoAlias &NoAliasAA) {
3830     // We can deduce "noalias" if the following conditions hold.
3831     // (i)   Associated value is assumed to be noalias in the definition.
3832     // (ii)  Associated value is assumed to be no-capture in all the uses
3833     //       possibly executed before this callsite.
3834     // (iii) There is no other pointer argument which could alias with the
3835     //       value.
3836 
3837     bool AssociatedValueIsNoAliasAtDef = NoAliasAA.isAssumedNoAlias();
3838     if (!AssociatedValueIsNoAliasAtDef) {
3839       LLVM_DEBUG(dbgs() << "[AANoAlias] " << getAssociatedValue()
3840                         << " is not no-alias at the definition\n");
3841       return false;
3842     }
3843 
3844     auto IsDereferenceableOrNull = [&](Value *O, const DataLayout &DL) {
3845       const auto &DerefAA = A.getAAFor<AADereferenceable>(
3846           *this, IRPosition::value(*O), DepClassTy::OPTIONAL);
3847       return DerefAA.getAssumedDereferenceableBytes();
3848     };
3849 
3850     A.recordDependence(NoAliasAA, *this, DepClassTy::OPTIONAL);
3851 
3852     const IRPosition &VIRP = IRPosition::value(getAssociatedValue());
3853     const Function *ScopeFn = VIRP.getAnchorScope();
3854     auto &NoCaptureAA = A.getAAFor<AANoCapture>(*this, VIRP, DepClassTy::NONE);
3855     // Check whether the value is captured in the scope using AANoCapture.
3856     // Look at CFG and check only uses possibly executed before this
3857     // callsite.
3858     auto UsePred = [&](const Use &U, bool &Follow) -> bool {
3859       Instruction *UserI = cast<Instruction>(U.getUser());
3860 
3861       // If UserI is the curr instruction and there is a single potential use of
3862       // the value in UserI we allow the use.
3863       // TODO: We should inspect the operands and allow those that cannot alias
3864       //       with the value.
3865       if (UserI == getCtxI() && UserI->getNumOperands() == 1)
3866         return true;
3867 
3868       if (ScopeFn) {
3869         if (auto *CB = dyn_cast<CallBase>(UserI)) {
3870           if (CB->isArgOperand(&U)) {
3871 
3872             unsigned ArgNo = CB->getArgOperandNo(&U);
3873 
3874             const auto &NoCaptureAA = A.getAAFor<AANoCapture>(
3875                 *this, IRPosition::callsite_argument(*CB, ArgNo),
3876                 DepClassTy::OPTIONAL);
3877 
3878             if (NoCaptureAA.isAssumedNoCapture())
3879               return true;
3880           }
3881         }
3882 
3883         if (!AA::isPotentiallyReachable(
3884                 A, *UserI, *getCtxI(), *this, /* ExclusionSet */ nullptr,
3885                 [ScopeFn](const Function &Fn) { return &Fn != ScopeFn; }))
3886           return true;
3887       }
3888 
3889       // TODO: We should track the capturing uses in AANoCapture but the problem
3890       //       is CGSCC runs. For those we would need to "allow" AANoCapture for
3891       //       a value in the module slice.
3892       switch (DetermineUseCaptureKind(U, IsDereferenceableOrNull)) {
3893       case UseCaptureKind::NO_CAPTURE:
3894         return true;
3895       case UseCaptureKind::MAY_CAPTURE:
3896         LLVM_DEBUG(dbgs() << "[AANoAliasCSArg] Unknown user: " << *UserI
3897                           << "\n");
3898         return false;
3899       case UseCaptureKind::PASSTHROUGH:
3900         Follow = true;
3901         return true;
3902       }
3903       llvm_unreachable("unknown UseCaptureKind");
3904     };
3905 
3906     if (!NoCaptureAA.isAssumedNoCaptureMaybeReturned()) {
3907       if (!A.checkForAllUses(UsePred, *this, getAssociatedValue())) {
3908         LLVM_DEBUG(
3909             dbgs() << "[AANoAliasCSArg] " << getAssociatedValue()
3910                    << " cannot be noalias as it is potentially captured\n");
3911         return false;
3912       }
3913     }
3914     A.recordDependence(NoCaptureAA, *this, DepClassTy::OPTIONAL);
3915 
3916     // Check there is no other pointer argument which could alias with the
3917     // value passed at this call site.
3918     // TODO: AbstractCallSite
3919     const auto &CB = cast<CallBase>(getAnchorValue());
3920     for (unsigned OtherArgNo = 0; OtherArgNo < CB.arg_size(); OtherArgNo++)
3921       if (mayAliasWithArgument(A, AAR, MemBehaviorAA, CB, OtherArgNo))
3922         return false;
3923 
3924     return true;
3925   }
3926 
3927   /// See AbstractAttribute::updateImpl(...).
3928   ChangeStatus updateImpl(Attributor &A) override {
3929     // If the argument is readnone we are done as there are no accesses via the
3930     // argument.
3931     auto &MemBehaviorAA =
3932         A.getAAFor<AAMemoryBehavior>(*this, getIRPosition(), DepClassTy::NONE);
3933     if (MemBehaviorAA.isAssumedReadNone()) {
3934       A.recordDependence(MemBehaviorAA, *this, DepClassTy::OPTIONAL);
3935       return ChangeStatus::UNCHANGED;
3936     }
3937 
3938     const IRPosition &VIRP = IRPosition::value(getAssociatedValue());
3939     const auto &NoAliasAA =
3940         A.getAAFor<AANoAlias>(*this, VIRP, DepClassTy::NONE);
3941 
3942     AAResults *AAR = nullptr;
3943     if (isKnownNoAliasDueToNoAliasPreservation(A, AAR, MemBehaviorAA,
3944                                                NoAliasAA)) {
3945       LLVM_DEBUG(
3946           dbgs() << "[AANoAlias] No-Alias deduced via no-alias preservation\n");
3947       return ChangeStatus::UNCHANGED;
3948     }
3949 
3950     return indicatePessimisticFixpoint();
3951   }
3952 
3953   /// See AbstractAttribute::trackStatistics()
3954   void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(noalias) }
3955 };
3956 
3957 /// NoAlias attribute for function return value.
3958 struct AANoAliasReturned final : AANoAliasImpl {
3959   AANoAliasReturned(const IRPosition &IRP, Attributor &A)
3960       : AANoAliasImpl(IRP, A) {}
3961 
3962   /// See AbstractAttribute::initialize(...).
3963   void initialize(Attributor &A) override {
3964     AANoAliasImpl::initialize(A);
3965     Function *F = getAssociatedFunction();
3966     if (!F || F->isDeclaration())
3967       indicatePessimisticFixpoint();
3968   }
3969 
3970   /// See AbstractAttribute::updateImpl(...).
3971   ChangeStatus updateImpl(Attributor &A) override {
3972 
3973     auto CheckReturnValue = [&](Value &RV) -> bool {
3974       if (Constant *C = dyn_cast<Constant>(&RV))
3975         if (C->isNullValue() || isa<UndefValue>(C))
3976           return true;
3977 
3978       /// For now, we can only deduce noalias if we have call sites.
3979       /// FIXME: add more support.
3980       if (!isa<CallBase>(&RV))
3981         return false;
3982 
3983       const IRPosition &RVPos = IRPosition::value(RV);
3984       const auto &NoAliasAA =
3985           A.getAAFor<AANoAlias>(*this, RVPos, DepClassTy::REQUIRED);
3986       if (!NoAliasAA.isAssumedNoAlias())
3987         return false;
3988 
3989       const auto &NoCaptureAA =
3990           A.getAAFor<AANoCapture>(*this, RVPos, DepClassTy::REQUIRED);
3991       return NoCaptureAA.isAssumedNoCaptureMaybeReturned();
3992     };
3993 
3994     if (!A.checkForAllReturnedValues(CheckReturnValue, *this))
3995       return indicatePessimisticFixpoint();
3996 
3997     return ChangeStatus::UNCHANGED;
3998   }
3999 
4000   /// See AbstractAttribute::trackStatistics()
4001   void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(noalias) }
4002 };
4003 
4004 /// NoAlias attribute deduction for a call site return value.
4005 struct AANoAliasCallSiteReturned final : AANoAliasImpl {
4006   AANoAliasCallSiteReturned(const IRPosition &IRP, Attributor &A)
4007       : AANoAliasImpl(IRP, A) {}
4008 
4009   /// See AbstractAttribute::initialize(...).
4010   void initialize(Attributor &A) override {
4011     AANoAliasImpl::initialize(A);
4012     Function *F = getAssociatedFunction();
4013     if (!F || F->isDeclaration())
4014       indicatePessimisticFixpoint();
4015   }
4016 
4017   /// See AbstractAttribute::updateImpl(...).
4018   ChangeStatus updateImpl(Attributor &A) override {
4019     // TODO: Once we have call site specific value information we can provide
4020     //       call site specific liveness information and then it makes
4021     //       sense to specialize attributes for call sites arguments instead of
4022     //       redirecting requests to the callee argument.
4023     Function *F = getAssociatedFunction();
4024     const IRPosition &FnPos = IRPosition::returned(*F);
4025     auto &FnAA = A.getAAFor<AANoAlias>(*this, FnPos, DepClassTy::REQUIRED);
4026     return clampStateAndIndicateChange(getState(), FnAA.getState());
4027   }
4028 
4029   /// See AbstractAttribute::trackStatistics()
4030   void trackStatistics() const override { STATS_DECLTRACK_CSRET_ATTR(noalias); }
4031 };
4032 } // namespace
4033 
4034 /// -------------------AAIsDead Function Attribute-----------------------
4035 
4036 namespace {
4037 struct AAIsDeadValueImpl : public AAIsDead {
4038   AAIsDeadValueImpl(const IRPosition &IRP, Attributor &A) : AAIsDead(IRP, A) {}
4039 
4040   /// See AbstractAttribute::initialize(...).
4041   void initialize(Attributor &A) override {
4042     if (auto *Scope = getAnchorScope())
4043       if (!A.isRunOn(*Scope))
4044         indicatePessimisticFixpoint();
4045   }
4046 
4047   /// See AAIsDead::isAssumedDead().
4048   bool isAssumedDead() const override { return isAssumed(IS_DEAD); }
4049 
4050   /// See AAIsDead::isKnownDead().
4051   bool isKnownDead() const override { return isKnown(IS_DEAD); }
4052 
4053   /// See AAIsDead::isAssumedDead(BasicBlock *).
4054   bool isAssumedDead(const BasicBlock *BB) const override { return false; }
4055 
4056   /// See AAIsDead::isKnownDead(BasicBlock *).
4057   bool isKnownDead(const BasicBlock *BB) const override { return false; }
4058 
4059   /// See AAIsDead::isAssumedDead(Instruction *I).
4060   bool isAssumedDead(const Instruction *I) const override {
4061     return I == getCtxI() && isAssumedDead();
4062   }
4063 
4064   /// See AAIsDead::isKnownDead(Instruction *I).
4065   bool isKnownDead(const Instruction *I) const override {
4066     return isAssumedDead(I) && isKnownDead();
4067   }
4068 
4069   /// See AbstractAttribute::getAsStr().
4070   const std::string getAsStr() const override {
4071     return isAssumedDead() ? "assumed-dead" : "assumed-live";
4072   }
4073 
4074   /// Check if all uses are assumed dead.
4075   bool areAllUsesAssumedDead(Attributor &A, Value &V) {
4076     // Callers might not check the type, void has no uses.
4077     if (V.getType()->isVoidTy() || V.use_empty())
4078       return true;
4079 
4080     // If we replace a value with a constant there are no uses left afterwards.
4081     if (!isa<Constant>(V)) {
4082       if (auto *I = dyn_cast<Instruction>(&V))
4083         if (!A.isRunOn(*I->getFunction()))
4084           return false;
4085       bool UsedAssumedInformation = false;
4086       std::optional<Constant *> C =
4087           A.getAssumedConstant(V, *this, UsedAssumedInformation);
4088       if (!C || *C)
4089         return true;
4090     }
4091 
4092     auto UsePred = [&](const Use &U, bool &Follow) { return false; };
4093     // Explicitly set the dependence class to required because we want a long
4094     // chain of N dependent instructions to be considered live as soon as one is
4095     // without going through N update cycles. This is not required for
4096     // correctness.
4097     return A.checkForAllUses(UsePred, *this, V, /* CheckBBLivenessOnly */ false,
4098                              DepClassTy::REQUIRED,
4099                              /* IgnoreDroppableUses */ false);
4100   }
4101 
4102   /// Determine if \p I is assumed to be side-effect free.
4103   bool isAssumedSideEffectFree(Attributor &A, Instruction *I) {
4104     if (!I || wouldInstructionBeTriviallyDead(I))
4105       return true;
4106 
4107     auto *CB = dyn_cast<CallBase>(I);
4108     if (!CB || isa<IntrinsicInst>(CB))
4109       return false;
4110 
4111     const IRPosition &CallIRP = IRPosition::callsite_function(*CB);
4112     const auto &NoUnwindAA =
4113         A.getAndUpdateAAFor<AANoUnwind>(*this, CallIRP, DepClassTy::NONE);
4114     if (!NoUnwindAA.isAssumedNoUnwind())
4115       return false;
4116     if (!NoUnwindAA.isKnownNoUnwind())
4117       A.recordDependence(NoUnwindAA, *this, DepClassTy::OPTIONAL);
4118 
4119     bool IsKnown;
4120     return AA::isAssumedReadOnly(A, CallIRP, *this, IsKnown);
4121   }
4122 };
4123 
4124 struct AAIsDeadFloating : public AAIsDeadValueImpl {
4125   AAIsDeadFloating(const IRPosition &IRP, Attributor &A)
4126       : AAIsDeadValueImpl(IRP, A) {}
4127 
4128   /// See AbstractAttribute::initialize(...).
4129   void initialize(Attributor &A) override {
4130     AAIsDeadValueImpl::initialize(A);
4131 
4132     if (isa<UndefValue>(getAssociatedValue())) {
4133       indicatePessimisticFixpoint();
4134       return;
4135     }
4136 
4137     Instruction *I = dyn_cast<Instruction>(&getAssociatedValue());
4138     if (!isAssumedSideEffectFree(A, I)) {
4139       if (!isa_and_nonnull<StoreInst>(I))
4140         indicatePessimisticFixpoint();
4141       else
4142         removeAssumedBits(HAS_NO_EFFECT);
4143     }
4144   }
4145 
4146   bool isDeadStore(Attributor &A, StoreInst &SI,
4147                    SmallSetVector<Instruction *, 8> *AssumeOnlyInst = nullptr) {
4148     // Lang ref now states volatile store is not UB/dead, let's skip them.
4149     if (SI.isVolatile())
4150       return false;
4151 
4152     // If we are collecting assumes to be deleted we are in the manifest stage.
4153     // It's problematic to collect the potential copies again now so we use the
4154     // cached ones.
4155     bool UsedAssumedInformation = false;
4156     if (!AssumeOnlyInst) {
4157       PotentialCopies.clear();
4158       if (!AA::getPotentialCopiesOfStoredValue(A, SI, PotentialCopies, *this,
4159                                                UsedAssumedInformation)) {
4160         LLVM_DEBUG(
4161             dbgs()
4162             << "[AAIsDead] Could not determine potential copies of store!\n");
4163         return false;
4164       }
4165     }
4166     LLVM_DEBUG(dbgs() << "[AAIsDead] Store has " << PotentialCopies.size()
4167                       << " potential copies.\n");
4168 
4169     InformationCache &InfoCache = A.getInfoCache();
4170     return llvm::all_of(PotentialCopies, [&](Value *V) {
4171       if (A.isAssumedDead(IRPosition::value(*V), this, nullptr,
4172                           UsedAssumedInformation))
4173         return true;
4174       if (auto *LI = dyn_cast<LoadInst>(V)) {
4175         if (llvm::all_of(LI->uses(), [&](const Use &U) {
4176               auto &UserI = cast<Instruction>(*U.getUser());
4177               if (InfoCache.isOnlyUsedByAssume(UserI)) {
4178                 if (AssumeOnlyInst)
4179                   AssumeOnlyInst->insert(&UserI);
4180                 return true;
4181               }
4182               return A.isAssumedDead(U, this, nullptr, UsedAssumedInformation);
4183             })) {
4184           return true;
4185         }
4186       }
4187       LLVM_DEBUG(dbgs() << "[AAIsDead] Potential copy " << *V
4188                         << " is assumed live!\n");
4189       return false;
4190     });
4191   }
4192 
4193   /// See AbstractAttribute::getAsStr().
4194   const std::string getAsStr() const override {
4195     Instruction *I = dyn_cast<Instruction>(&getAssociatedValue());
4196     if (isa_and_nonnull<StoreInst>(I))
4197       if (isValidState())
4198         return "assumed-dead-store";
4199     return AAIsDeadValueImpl::getAsStr();
4200   }
4201 
4202   /// See AbstractAttribute::updateImpl(...).
4203   ChangeStatus updateImpl(Attributor &A) override {
4204     Instruction *I = dyn_cast<Instruction>(&getAssociatedValue());
4205     if (auto *SI = dyn_cast_or_null<StoreInst>(I)) {
4206       if (!isDeadStore(A, *SI))
4207         return indicatePessimisticFixpoint();
4208     } else {
4209       if (!isAssumedSideEffectFree(A, I))
4210         return indicatePessimisticFixpoint();
4211       if (!areAllUsesAssumedDead(A, getAssociatedValue()))
4212         return indicatePessimisticFixpoint();
4213     }
4214     return ChangeStatus::UNCHANGED;
4215   }
4216 
4217   bool isRemovableStore() const override {
4218     return isAssumed(IS_REMOVABLE) && isa<StoreInst>(&getAssociatedValue());
4219   }
4220 
4221   /// See AbstractAttribute::manifest(...).
4222   ChangeStatus manifest(Attributor &A) override {
4223     Value &V = getAssociatedValue();
4224     if (auto *I = dyn_cast<Instruction>(&V)) {
4225       // If we get here we basically know the users are all dead. We check if
4226       // isAssumedSideEffectFree returns true here again because it might not be
4227       // the case and only the users are dead but the instruction (=call) is
4228       // still needed.
4229       if (auto *SI = dyn_cast<StoreInst>(I)) {
4230         SmallSetVector<Instruction *, 8> AssumeOnlyInst;
4231         bool IsDead = isDeadStore(A, *SI, &AssumeOnlyInst);
4232         (void)IsDead;
4233         assert(IsDead && "Store was assumed to be dead!");
4234         A.deleteAfterManifest(*I);
4235         for (size_t i = 0; i < AssumeOnlyInst.size(); ++i) {
4236           Instruction *AOI = AssumeOnlyInst[i];
4237           for (auto *Usr : AOI->users())
4238             AssumeOnlyInst.insert(cast<Instruction>(Usr));
4239           A.deleteAfterManifest(*AOI);
4240         }
4241         return ChangeStatus::CHANGED;
4242       }
4243       if (isAssumedSideEffectFree(A, I) && !isa<InvokeInst>(I)) {
4244         A.deleteAfterManifest(*I);
4245         return ChangeStatus::CHANGED;
4246       }
4247     }
4248     return ChangeStatus::UNCHANGED;
4249   }
4250 
4251   /// See AbstractAttribute::trackStatistics()
4252   void trackStatistics() const override {
4253     STATS_DECLTRACK_FLOATING_ATTR(IsDead)
4254   }
4255 
4256 private:
4257   // The potential copies of a dead store, used for deletion during manifest.
4258   SmallSetVector<Value *, 4> PotentialCopies;
4259 };
4260 
4261 struct AAIsDeadArgument : public AAIsDeadFloating {
4262   AAIsDeadArgument(const IRPosition &IRP, Attributor &A)
4263       : AAIsDeadFloating(IRP, A) {}
4264 
4265   /// See AbstractAttribute::initialize(...).
4266   void initialize(Attributor &A) override {
4267     AAIsDeadFloating::initialize(A);
4268     if (!A.isFunctionIPOAmendable(*getAnchorScope()))
4269       indicatePessimisticFixpoint();
4270   }
4271 
4272   /// See AbstractAttribute::manifest(...).
4273   ChangeStatus manifest(Attributor &A) override {
4274     Argument &Arg = *getAssociatedArgument();
4275     if (A.isValidFunctionSignatureRewrite(Arg, /* ReplacementTypes */ {}))
4276       if (A.registerFunctionSignatureRewrite(
4277               Arg, /* ReplacementTypes */ {},
4278               Attributor::ArgumentReplacementInfo::CalleeRepairCBTy{},
4279               Attributor::ArgumentReplacementInfo::ACSRepairCBTy{})) {
4280         return ChangeStatus::CHANGED;
4281       }
4282     return ChangeStatus::UNCHANGED;
4283   }
4284 
4285   /// See AbstractAttribute::trackStatistics()
4286   void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(IsDead) }
4287 };
4288 
4289 struct AAIsDeadCallSiteArgument : public AAIsDeadValueImpl {
4290   AAIsDeadCallSiteArgument(const IRPosition &IRP, Attributor &A)
4291       : AAIsDeadValueImpl(IRP, A) {}
4292 
4293   /// See AbstractAttribute::initialize(...).
4294   void initialize(Attributor &A) override {
4295     AAIsDeadValueImpl::initialize(A);
4296     if (isa<UndefValue>(getAssociatedValue()))
4297       indicatePessimisticFixpoint();
4298   }
4299 
4300   /// See AbstractAttribute::updateImpl(...).
4301   ChangeStatus updateImpl(Attributor &A) override {
4302     // TODO: Once we have call site specific value information we can provide
4303     //       call site specific liveness information and then it makes
4304     //       sense to specialize attributes for call sites arguments instead of
4305     //       redirecting requests to the callee argument.
4306     Argument *Arg = getAssociatedArgument();
4307     if (!Arg)
4308       return indicatePessimisticFixpoint();
4309     const IRPosition &ArgPos = IRPosition::argument(*Arg);
4310     auto &ArgAA = A.getAAFor<AAIsDead>(*this, ArgPos, DepClassTy::REQUIRED);
4311     return clampStateAndIndicateChange(getState(), ArgAA.getState());
4312   }
4313 
4314   /// See AbstractAttribute::manifest(...).
4315   ChangeStatus manifest(Attributor &A) override {
4316     CallBase &CB = cast<CallBase>(getAnchorValue());
4317     Use &U = CB.getArgOperandUse(getCallSiteArgNo());
4318     assert(!isa<UndefValue>(U.get()) &&
4319            "Expected undef values to be filtered out!");
4320     UndefValue &UV = *UndefValue::get(U->getType());
4321     if (A.changeUseAfterManifest(U, UV))
4322       return ChangeStatus::CHANGED;
4323     return ChangeStatus::UNCHANGED;
4324   }
4325 
4326   /// See AbstractAttribute::trackStatistics()
4327   void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(IsDead) }
4328 };
4329 
4330 struct AAIsDeadCallSiteReturned : public AAIsDeadFloating {
4331   AAIsDeadCallSiteReturned(const IRPosition &IRP, Attributor &A)
4332       : AAIsDeadFloating(IRP, A) {}
4333 
4334   /// See AAIsDead::isAssumedDead().
4335   bool isAssumedDead() const override {
4336     return AAIsDeadFloating::isAssumedDead() && IsAssumedSideEffectFree;
4337   }
4338 
4339   /// See AbstractAttribute::initialize(...).
4340   void initialize(Attributor &A) override {
4341     AAIsDeadFloating::initialize(A);
4342     if (isa<UndefValue>(getAssociatedValue())) {
4343       indicatePessimisticFixpoint();
4344       return;
4345     }
4346 
4347     // We track this separately as a secondary state.
4348     IsAssumedSideEffectFree = isAssumedSideEffectFree(A, getCtxI());
4349   }
4350 
4351   /// See AbstractAttribute::updateImpl(...).
4352   ChangeStatus updateImpl(Attributor &A) override {
4353     ChangeStatus Changed = ChangeStatus::UNCHANGED;
4354     if (IsAssumedSideEffectFree && !isAssumedSideEffectFree(A, getCtxI())) {
4355       IsAssumedSideEffectFree = false;
4356       Changed = ChangeStatus::CHANGED;
4357     }
4358     if (!areAllUsesAssumedDead(A, getAssociatedValue()))
4359       return indicatePessimisticFixpoint();
4360     return Changed;
4361   }
4362 
4363   /// See AbstractAttribute::trackStatistics()
4364   void trackStatistics() const override {
4365     if (IsAssumedSideEffectFree)
4366       STATS_DECLTRACK_CSRET_ATTR(IsDead)
4367     else
4368       STATS_DECLTRACK_CSRET_ATTR(UnusedResult)
4369   }
4370 
4371   /// See AbstractAttribute::getAsStr().
4372   const std::string getAsStr() const override {
4373     return isAssumedDead()
4374                ? "assumed-dead"
4375                : (getAssumed() ? "assumed-dead-users" : "assumed-live");
4376   }
4377 
4378 private:
4379   bool IsAssumedSideEffectFree = true;
4380 };
4381 
4382 struct AAIsDeadReturned : public AAIsDeadValueImpl {
4383   AAIsDeadReturned(const IRPosition &IRP, Attributor &A)
4384       : AAIsDeadValueImpl(IRP, A) {}
4385 
4386   /// See AbstractAttribute::updateImpl(...).
4387   ChangeStatus updateImpl(Attributor &A) override {
4388 
4389     bool UsedAssumedInformation = false;
4390     A.checkForAllInstructions([](Instruction &) { return true; }, *this,
4391                               {Instruction::Ret}, UsedAssumedInformation);
4392 
4393     auto PredForCallSite = [&](AbstractCallSite ACS) {
4394       if (ACS.isCallbackCall() || !ACS.getInstruction())
4395         return false;
4396       return areAllUsesAssumedDead(A, *ACS.getInstruction());
4397     };
4398 
4399     if (!A.checkForAllCallSites(PredForCallSite, *this, true,
4400                                 UsedAssumedInformation))
4401       return indicatePessimisticFixpoint();
4402 
4403     return ChangeStatus::UNCHANGED;
4404   }
4405 
4406   /// See AbstractAttribute::manifest(...).
4407   ChangeStatus manifest(Attributor &A) override {
4408     // TODO: Rewrite the signature to return void?
4409     bool AnyChange = false;
4410     UndefValue &UV = *UndefValue::get(getAssociatedFunction()->getReturnType());
4411     auto RetInstPred = [&](Instruction &I) {
4412       ReturnInst &RI = cast<ReturnInst>(I);
4413       if (!isa<UndefValue>(RI.getReturnValue()))
4414         AnyChange |= A.changeUseAfterManifest(RI.getOperandUse(0), UV);
4415       return true;
4416     };
4417     bool UsedAssumedInformation = false;
4418     A.checkForAllInstructions(RetInstPred, *this, {Instruction::Ret},
4419                               UsedAssumedInformation);
4420     return AnyChange ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED;
4421   }
4422 
4423   /// See AbstractAttribute::trackStatistics()
4424   void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(IsDead) }
4425 };
4426 
4427 struct AAIsDeadFunction : public AAIsDead {
4428   AAIsDeadFunction(const IRPosition &IRP, Attributor &A) : AAIsDead(IRP, A) {}
4429 
4430   /// See AbstractAttribute::initialize(...).
4431   void initialize(Attributor &A) override {
4432     Function *F = getAnchorScope();
4433     if (!F || F->isDeclaration() || !A.isRunOn(*F)) {
4434       indicatePessimisticFixpoint();
4435       return;
4436     }
4437     if (!isAssumedDeadInternalFunction(A)) {
4438       ToBeExploredFrom.insert(&F->getEntryBlock().front());
4439       assumeLive(A, F->getEntryBlock());
4440     }
4441   }
4442 
4443   bool isAssumedDeadInternalFunction(Attributor &A) {
4444     if (!getAnchorScope()->hasLocalLinkage())
4445       return false;
4446     bool UsedAssumedInformation = false;
4447     return A.checkForAllCallSites([](AbstractCallSite) { return false; }, *this,
4448                                   true, UsedAssumedInformation);
4449   }
4450 
4451   /// See AbstractAttribute::getAsStr().
4452   const std::string getAsStr() const override {
4453     return "Live[#BB " + std::to_string(AssumedLiveBlocks.size()) + "/" +
4454            std::to_string(getAnchorScope()->size()) + "][#TBEP " +
4455            std::to_string(ToBeExploredFrom.size()) + "][#KDE " +
4456            std::to_string(KnownDeadEnds.size()) + "]";
4457   }
4458 
4459   /// See AbstractAttribute::manifest(...).
4460   ChangeStatus manifest(Attributor &A) override {
4461     assert(getState().isValidState() &&
4462            "Attempted to manifest an invalid state!");
4463 
4464     ChangeStatus HasChanged = ChangeStatus::UNCHANGED;
4465     Function &F = *getAnchorScope();
4466 
4467     if (AssumedLiveBlocks.empty()) {
4468       A.deleteAfterManifest(F);
4469       return ChangeStatus::CHANGED;
4470     }
4471 
4472     // Flag to determine if we can change an invoke to a call assuming the
4473     // callee is nounwind. This is not possible if the personality of the
4474     // function allows to catch asynchronous exceptions.
4475     bool Invoke2CallAllowed = !mayCatchAsynchronousExceptions(F);
4476 
4477     KnownDeadEnds.set_union(ToBeExploredFrom);
4478     for (const Instruction *DeadEndI : KnownDeadEnds) {
4479       auto *CB = dyn_cast<CallBase>(DeadEndI);
4480       if (!CB)
4481         continue;
4482       const auto &NoReturnAA = A.getAndUpdateAAFor<AANoReturn>(
4483           *this, IRPosition::callsite_function(*CB), DepClassTy::OPTIONAL);
4484       bool MayReturn = !NoReturnAA.isAssumedNoReturn();
4485       if (MayReturn && (!Invoke2CallAllowed || !isa<InvokeInst>(CB)))
4486         continue;
4487 
4488       if (auto *II = dyn_cast<InvokeInst>(DeadEndI))
4489         A.registerInvokeWithDeadSuccessor(const_cast<InvokeInst &>(*II));
4490       else
4491         A.changeToUnreachableAfterManifest(
4492             const_cast<Instruction *>(DeadEndI->getNextNode()));
4493       HasChanged = ChangeStatus::CHANGED;
4494     }
4495 
4496     STATS_DECL(AAIsDead, BasicBlock, "Number of dead basic blocks deleted.");
4497     for (BasicBlock &BB : F)
4498       if (!AssumedLiveBlocks.count(&BB)) {
4499         A.deleteAfterManifest(BB);
4500         ++BUILD_STAT_NAME(AAIsDead, BasicBlock);
4501         HasChanged = ChangeStatus::CHANGED;
4502       }
4503 
4504     return HasChanged;
4505   }
4506 
4507   /// See AbstractAttribute::updateImpl(...).
4508   ChangeStatus updateImpl(Attributor &A) override;
4509 
4510   bool isEdgeDead(const BasicBlock *From, const BasicBlock *To) const override {
4511     assert(From->getParent() == getAnchorScope() &&
4512            To->getParent() == getAnchorScope() &&
4513            "Used AAIsDead of the wrong function");
4514     return isValidState() && !AssumedLiveEdges.count(std::make_pair(From, To));
4515   }
4516 
4517   /// See AbstractAttribute::trackStatistics()
4518   void trackStatistics() const override {}
4519 
4520   /// Returns true if the function is assumed dead.
4521   bool isAssumedDead() const override { return false; }
4522 
4523   /// See AAIsDead::isKnownDead().
4524   bool isKnownDead() const override { return false; }
4525 
4526   /// See AAIsDead::isAssumedDead(BasicBlock *).
4527   bool isAssumedDead(const BasicBlock *BB) const override {
4528     assert(BB->getParent() == getAnchorScope() &&
4529            "BB must be in the same anchor scope function.");
4530 
4531     if (!getAssumed())
4532       return false;
4533     return !AssumedLiveBlocks.count(BB);
4534   }
4535 
4536   /// See AAIsDead::isKnownDead(BasicBlock *).
4537   bool isKnownDead(const BasicBlock *BB) const override {
4538     return getKnown() && isAssumedDead(BB);
4539   }
4540 
4541   /// See AAIsDead::isAssumed(Instruction *I).
4542   bool isAssumedDead(const Instruction *I) const override {
4543     assert(I->getParent()->getParent() == getAnchorScope() &&
4544            "Instruction must be in the same anchor scope function.");
4545 
4546     if (!getAssumed())
4547       return false;
4548 
4549     // If it is not in AssumedLiveBlocks then it for sure dead.
4550     // Otherwise, it can still be after noreturn call in a live block.
4551     if (!AssumedLiveBlocks.count(I->getParent()))
4552       return true;
4553 
4554     // If it is not after a liveness barrier it is live.
4555     const Instruction *PrevI = I->getPrevNode();
4556     while (PrevI) {
4557       if (KnownDeadEnds.count(PrevI) || ToBeExploredFrom.count(PrevI))
4558         return true;
4559       PrevI = PrevI->getPrevNode();
4560     }
4561     return false;
4562   }
4563 
4564   /// See AAIsDead::isKnownDead(Instruction *I).
4565   bool isKnownDead(const Instruction *I) const override {
4566     return getKnown() && isAssumedDead(I);
4567   }
4568 
4569   /// Assume \p BB is (partially) live now and indicate to the Attributor \p A
4570   /// that internal function called from \p BB should now be looked at.
4571   bool assumeLive(Attributor &A, const BasicBlock &BB) {
4572     if (!AssumedLiveBlocks.insert(&BB).second)
4573       return false;
4574 
4575     // We assume that all of BB is (probably) live now and if there are calls to
4576     // internal functions we will assume that those are now live as well. This
4577     // is a performance optimization for blocks with calls to a lot of internal
4578     // functions. It can however cause dead functions to be treated as live.
4579     for (const Instruction &I : BB)
4580       if (const auto *CB = dyn_cast<CallBase>(&I))
4581         if (const Function *F = CB->getCalledFunction())
4582           if (F->hasLocalLinkage())
4583             A.markLiveInternalFunction(*F);
4584     return true;
4585   }
4586 
4587   /// Collection of instructions that need to be explored again, e.g., we
4588   /// did assume they do not transfer control to (one of their) successors.
4589   SmallSetVector<const Instruction *, 8> ToBeExploredFrom;
4590 
4591   /// Collection of instructions that are known to not transfer control.
4592   SmallSetVector<const Instruction *, 8> KnownDeadEnds;
4593 
4594   /// Collection of all assumed live edges
4595   DenseSet<std::pair<const BasicBlock *, const BasicBlock *>> AssumedLiveEdges;
4596 
4597   /// Collection of all assumed live BasicBlocks.
4598   DenseSet<const BasicBlock *> AssumedLiveBlocks;
4599 };
4600 
4601 static bool
4602 identifyAliveSuccessors(Attributor &A, const CallBase &CB,
4603                         AbstractAttribute &AA,
4604                         SmallVectorImpl<const Instruction *> &AliveSuccessors) {
4605   const IRPosition &IPos = IRPosition::callsite_function(CB);
4606 
4607   const auto &NoReturnAA =
4608       A.getAndUpdateAAFor<AANoReturn>(AA, IPos, DepClassTy::OPTIONAL);
4609   if (NoReturnAA.isAssumedNoReturn())
4610     return !NoReturnAA.isKnownNoReturn();
4611   if (CB.isTerminator())
4612     AliveSuccessors.push_back(&CB.getSuccessor(0)->front());
4613   else
4614     AliveSuccessors.push_back(CB.getNextNode());
4615   return false;
4616 }
4617 
4618 static bool
4619 identifyAliveSuccessors(Attributor &A, const InvokeInst &II,
4620                         AbstractAttribute &AA,
4621                         SmallVectorImpl<const Instruction *> &AliveSuccessors) {
4622   bool UsedAssumedInformation =
4623       identifyAliveSuccessors(A, cast<CallBase>(II), AA, AliveSuccessors);
4624 
4625   // First, determine if we can change an invoke to a call assuming the
4626   // callee is nounwind. This is not possible if the personality of the
4627   // function allows to catch asynchronous exceptions.
4628   if (AAIsDeadFunction::mayCatchAsynchronousExceptions(*II.getFunction())) {
4629     AliveSuccessors.push_back(&II.getUnwindDest()->front());
4630   } else {
4631     const IRPosition &IPos = IRPosition::callsite_function(II);
4632     const auto &AANoUnw =
4633         A.getAndUpdateAAFor<AANoUnwind>(AA, IPos, DepClassTy::OPTIONAL);
4634     if (AANoUnw.isAssumedNoUnwind()) {
4635       UsedAssumedInformation |= !AANoUnw.isKnownNoUnwind();
4636     } else {
4637       AliveSuccessors.push_back(&II.getUnwindDest()->front());
4638     }
4639   }
4640   return UsedAssumedInformation;
4641 }
4642 
4643 static bool
4644 identifyAliveSuccessors(Attributor &A, const BranchInst &BI,
4645                         AbstractAttribute &AA,
4646                         SmallVectorImpl<const Instruction *> &AliveSuccessors) {
4647   bool UsedAssumedInformation = false;
4648   if (BI.getNumSuccessors() == 1) {
4649     AliveSuccessors.push_back(&BI.getSuccessor(0)->front());
4650   } else {
4651     std::optional<Constant *> C =
4652         A.getAssumedConstant(*BI.getCondition(), AA, UsedAssumedInformation);
4653     if (!C || isa_and_nonnull<UndefValue>(*C)) {
4654       // No value yet, assume both edges are dead.
4655     } else if (isa_and_nonnull<ConstantInt>(*C)) {
4656       const BasicBlock *SuccBB =
4657           BI.getSuccessor(1 - cast<ConstantInt>(*C)->getValue().getZExtValue());
4658       AliveSuccessors.push_back(&SuccBB->front());
4659     } else {
4660       AliveSuccessors.push_back(&BI.getSuccessor(0)->front());
4661       AliveSuccessors.push_back(&BI.getSuccessor(1)->front());
4662       UsedAssumedInformation = false;
4663     }
4664   }
4665   return UsedAssumedInformation;
4666 }
4667 
4668 static bool
4669 identifyAliveSuccessors(Attributor &A, const SwitchInst &SI,
4670                         AbstractAttribute &AA,
4671                         SmallVectorImpl<const Instruction *> &AliveSuccessors) {
4672   bool UsedAssumedInformation = false;
4673   std::optional<Constant *> C =
4674       A.getAssumedConstant(*SI.getCondition(), AA, UsedAssumedInformation);
4675   if (!C || isa_and_nonnull<UndefValue>(*C)) {
4676     // No value yet, assume all edges are dead.
4677   } else if (isa_and_nonnull<ConstantInt>(*C)) {
4678     for (const auto &CaseIt : SI.cases()) {
4679       if (CaseIt.getCaseValue() == *C) {
4680         AliveSuccessors.push_back(&CaseIt.getCaseSuccessor()->front());
4681         return UsedAssumedInformation;
4682       }
4683     }
4684     AliveSuccessors.push_back(&SI.getDefaultDest()->front());
4685     return UsedAssumedInformation;
4686   } else {
4687     for (const BasicBlock *SuccBB : successors(SI.getParent()))
4688       AliveSuccessors.push_back(&SuccBB->front());
4689   }
4690   return UsedAssumedInformation;
4691 }
4692 
4693 ChangeStatus AAIsDeadFunction::updateImpl(Attributor &A) {
4694   ChangeStatus Change = ChangeStatus::UNCHANGED;
4695 
4696   if (AssumedLiveBlocks.empty()) {
4697     if (isAssumedDeadInternalFunction(A))
4698       return ChangeStatus::UNCHANGED;
4699 
4700     Function *F = getAnchorScope();
4701     ToBeExploredFrom.insert(&F->getEntryBlock().front());
4702     assumeLive(A, F->getEntryBlock());
4703     Change = ChangeStatus::CHANGED;
4704   }
4705 
4706   LLVM_DEBUG(dbgs() << "[AAIsDead] Live [" << AssumedLiveBlocks.size() << "/"
4707                     << getAnchorScope()->size() << "] BBs and "
4708                     << ToBeExploredFrom.size() << " exploration points and "
4709                     << KnownDeadEnds.size() << " known dead ends\n");
4710 
4711   // Copy and clear the list of instructions we need to explore from. It is
4712   // refilled with instructions the next update has to look at.
4713   SmallVector<const Instruction *, 8> Worklist(ToBeExploredFrom.begin(),
4714                                                ToBeExploredFrom.end());
4715   decltype(ToBeExploredFrom) NewToBeExploredFrom;
4716 
4717   SmallVector<const Instruction *, 8> AliveSuccessors;
4718   while (!Worklist.empty()) {
4719     const Instruction *I = Worklist.pop_back_val();
4720     LLVM_DEBUG(dbgs() << "[AAIsDead] Exploration inst: " << *I << "\n");
4721 
4722     // Fast forward for uninteresting instructions. We could look for UB here
4723     // though.
4724     while (!I->isTerminator() && !isa<CallBase>(I))
4725       I = I->getNextNode();
4726 
4727     AliveSuccessors.clear();
4728 
4729     bool UsedAssumedInformation = false;
4730     switch (I->getOpcode()) {
4731     // TODO: look for (assumed) UB to backwards propagate "deadness".
4732     default:
4733       assert(I->isTerminator() &&
4734              "Expected non-terminators to be handled already!");
4735       for (const BasicBlock *SuccBB : successors(I->getParent()))
4736         AliveSuccessors.push_back(&SuccBB->front());
4737       break;
4738     case Instruction::Call:
4739       UsedAssumedInformation = identifyAliveSuccessors(A, cast<CallInst>(*I),
4740                                                        *this, AliveSuccessors);
4741       break;
4742     case Instruction::Invoke:
4743       UsedAssumedInformation = identifyAliveSuccessors(A, cast<InvokeInst>(*I),
4744                                                        *this, AliveSuccessors);
4745       break;
4746     case Instruction::Br:
4747       UsedAssumedInformation = identifyAliveSuccessors(A, cast<BranchInst>(*I),
4748                                                        *this, AliveSuccessors);
4749       break;
4750     case Instruction::Switch:
4751       UsedAssumedInformation = identifyAliveSuccessors(A, cast<SwitchInst>(*I),
4752                                                        *this, AliveSuccessors);
4753       break;
4754     }
4755 
4756     if (UsedAssumedInformation) {
4757       NewToBeExploredFrom.insert(I);
4758     } else if (AliveSuccessors.empty() ||
4759                (I->isTerminator() &&
4760                 AliveSuccessors.size() < I->getNumSuccessors())) {
4761       if (KnownDeadEnds.insert(I))
4762         Change = ChangeStatus::CHANGED;
4763     }
4764 
4765     LLVM_DEBUG(dbgs() << "[AAIsDead] #AliveSuccessors: "
4766                       << AliveSuccessors.size() << " UsedAssumedInformation: "
4767                       << UsedAssumedInformation << "\n");
4768 
4769     for (const Instruction *AliveSuccessor : AliveSuccessors) {
4770       if (!I->isTerminator()) {
4771         assert(AliveSuccessors.size() == 1 &&
4772                "Non-terminator expected to have a single successor!");
4773         Worklist.push_back(AliveSuccessor);
4774       } else {
4775         // record the assumed live edge
4776         auto Edge = std::make_pair(I->getParent(), AliveSuccessor->getParent());
4777         if (AssumedLiveEdges.insert(Edge).second)
4778           Change = ChangeStatus::CHANGED;
4779         if (assumeLive(A, *AliveSuccessor->getParent()))
4780           Worklist.push_back(AliveSuccessor);
4781       }
4782     }
4783   }
4784 
4785   // Check if the content of ToBeExploredFrom changed, ignore the order.
4786   if (NewToBeExploredFrom.size() != ToBeExploredFrom.size() ||
4787       llvm::any_of(NewToBeExploredFrom, [&](const Instruction *I) {
4788         return !ToBeExploredFrom.count(I);
4789       })) {
4790     Change = ChangeStatus::CHANGED;
4791     ToBeExploredFrom = std::move(NewToBeExploredFrom);
4792   }
4793 
4794   // If we know everything is live there is no need to query for liveness.
4795   // Instead, indicating a pessimistic fixpoint will cause the state to be
4796   // "invalid" and all queries to be answered conservatively without lookups.
4797   // To be in this state we have to (1) finished the exploration and (3) not
4798   // discovered any non-trivial dead end and (2) not ruled unreachable code
4799   // dead.
4800   if (ToBeExploredFrom.empty() &&
4801       getAnchorScope()->size() == AssumedLiveBlocks.size() &&
4802       llvm::all_of(KnownDeadEnds, [](const Instruction *DeadEndI) {
4803         return DeadEndI->isTerminator() && DeadEndI->getNumSuccessors() == 0;
4804       }))
4805     return indicatePessimisticFixpoint();
4806   return Change;
4807 }
4808 
4809 /// Liveness information for a call sites.
4810 struct AAIsDeadCallSite final : AAIsDeadFunction {
4811   AAIsDeadCallSite(const IRPosition &IRP, Attributor &A)
4812       : AAIsDeadFunction(IRP, A) {}
4813 
4814   /// See AbstractAttribute::initialize(...).
4815   void initialize(Attributor &A) override {
4816     // TODO: Once we have call site specific value information we can provide
4817     //       call site specific liveness information and then it makes
4818     //       sense to specialize attributes for call sites instead of
4819     //       redirecting requests to the callee.
4820     llvm_unreachable("Abstract attributes for liveness are not "
4821                      "supported for call sites yet!");
4822   }
4823 
4824   /// See AbstractAttribute::updateImpl(...).
4825   ChangeStatus updateImpl(Attributor &A) override {
4826     return indicatePessimisticFixpoint();
4827   }
4828 
4829   /// See AbstractAttribute::trackStatistics()
4830   void trackStatistics() const override {}
4831 };
4832 } // namespace
4833 
4834 /// -------------------- Dereferenceable Argument Attribute --------------------
4835 
4836 namespace {
4837 struct AADereferenceableImpl : AADereferenceable {
4838   AADereferenceableImpl(const IRPosition &IRP, Attributor &A)
4839       : AADereferenceable(IRP, A) {}
4840   using StateType = DerefState;
4841 
4842   /// See AbstractAttribute::initialize(...).
4843   void initialize(Attributor &A) override {
4844     Value &V = *getAssociatedValue().stripPointerCasts();
4845     SmallVector<Attribute, 4> Attrs;
4846     getAttrs({Attribute::Dereferenceable, Attribute::DereferenceableOrNull},
4847              Attrs, /* IgnoreSubsumingPositions */ false, &A);
4848     for (const Attribute &Attr : Attrs)
4849       takeKnownDerefBytesMaximum(Attr.getValueAsInt());
4850 
4851     const IRPosition &IRP = this->getIRPosition();
4852     NonNullAA = &A.getAAFor<AANonNull>(*this, IRP, DepClassTy::NONE);
4853 
4854     bool CanBeNull, CanBeFreed;
4855     takeKnownDerefBytesMaximum(V.getPointerDereferenceableBytes(
4856         A.getDataLayout(), CanBeNull, CanBeFreed));
4857 
4858     bool IsFnInterface = IRP.isFnInterfaceKind();
4859     Function *FnScope = IRP.getAnchorScope();
4860     if (IsFnInterface && (!FnScope || !A.isFunctionIPOAmendable(*FnScope))) {
4861       indicatePessimisticFixpoint();
4862       return;
4863     }
4864 
4865     if (Instruction *CtxI = getCtxI())
4866       followUsesInMBEC(*this, A, getState(), *CtxI);
4867   }
4868 
4869   /// See AbstractAttribute::getState()
4870   /// {
4871   StateType &getState() override { return *this; }
4872   const StateType &getState() const override { return *this; }
4873   /// }
4874 
4875   /// Helper function for collecting accessed bytes in must-be-executed-context
4876   void addAccessedBytesForUse(Attributor &A, const Use *U, const Instruction *I,
4877                               DerefState &State) {
4878     const Value *UseV = U->get();
4879     if (!UseV->getType()->isPointerTy())
4880       return;
4881 
4882     std::optional<MemoryLocation> Loc = MemoryLocation::getOrNone(I);
4883     if (!Loc || Loc->Ptr != UseV || !Loc->Size.isPrecise() || I->isVolatile())
4884       return;
4885 
4886     int64_t Offset;
4887     const Value *Base = GetPointerBaseWithConstantOffset(
4888         Loc->Ptr, Offset, A.getDataLayout(), /*AllowNonInbounds*/ true);
4889     if (Base && Base == &getAssociatedValue())
4890       State.addAccessedBytes(Offset, Loc->Size.getValue());
4891   }
4892 
4893   /// See followUsesInMBEC
4894   bool followUseInMBEC(Attributor &A, const Use *U, const Instruction *I,
4895                        AADereferenceable::StateType &State) {
4896     bool IsNonNull = false;
4897     bool TrackUse = false;
4898     int64_t DerefBytes = getKnownNonNullAndDerefBytesForUse(
4899         A, *this, getAssociatedValue(), U, I, IsNonNull, TrackUse);
4900     LLVM_DEBUG(dbgs() << "[AADereferenceable] Deref bytes: " << DerefBytes
4901                       << " for instruction " << *I << "\n");
4902 
4903     addAccessedBytesForUse(A, U, I, State);
4904     State.takeKnownDerefBytesMaximum(DerefBytes);
4905     return TrackUse;
4906   }
4907 
4908   /// See AbstractAttribute::manifest(...).
4909   ChangeStatus manifest(Attributor &A) override {
4910     ChangeStatus Change = AADereferenceable::manifest(A);
4911     if (isAssumedNonNull() && hasAttr(Attribute::DereferenceableOrNull)) {
4912       removeAttrs({Attribute::DereferenceableOrNull});
4913       return ChangeStatus::CHANGED;
4914     }
4915     return Change;
4916   }
4917 
4918   void getDeducedAttributes(LLVMContext &Ctx,
4919                             SmallVectorImpl<Attribute> &Attrs) const override {
4920     // TODO: Add *_globally support
4921     if (isAssumedNonNull())
4922       Attrs.emplace_back(Attribute::getWithDereferenceableBytes(
4923           Ctx, getAssumedDereferenceableBytes()));
4924     else
4925       Attrs.emplace_back(Attribute::getWithDereferenceableOrNullBytes(
4926           Ctx, getAssumedDereferenceableBytes()));
4927   }
4928 
4929   /// See AbstractAttribute::getAsStr().
4930   const std::string getAsStr() const override {
4931     if (!getAssumedDereferenceableBytes())
4932       return "unknown-dereferenceable";
4933     return std::string("dereferenceable") +
4934            (isAssumedNonNull() ? "" : "_or_null") +
4935            (isAssumedGlobal() ? "_globally" : "") + "<" +
4936            std::to_string(getKnownDereferenceableBytes()) + "-" +
4937            std::to_string(getAssumedDereferenceableBytes()) + ">";
4938   }
4939 };
4940 
4941 /// Dereferenceable attribute for a floating value.
4942 struct AADereferenceableFloating : AADereferenceableImpl {
4943   AADereferenceableFloating(const IRPosition &IRP, Attributor &A)
4944       : AADereferenceableImpl(IRP, A) {}
4945 
4946   /// See AbstractAttribute::updateImpl(...).
4947   ChangeStatus updateImpl(Attributor &A) override {
4948 
4949     bool Stripped;
4950     bool UsedAssumedInformation = false;
4951     SmallVector<AA::ValueAndContext> Values;
4952     if (!A.getAssumedSimplifiedValues(getIRPosition(), *this, Values,
4953                                       AA::AnyScope, UsedAssumedInformation)) {
4954       Values.push_back({getAssociatedValue(), getCtxI()});
4955       Stripped = false;
4956     } else {
4957       Stripped = Values.size() != 1 ||
4958                  Values.front().getValue() != &getAssociatedValue();
4959     }
4960 
4961     const DataLayout &DL = A.getDataLayout();
4962     DerefState T;
4963 
4964     auto VisitValueCB = [&](const Value &V) -> bool {
4965       unsigned IdxWidth =
4966           DL.getIndexSizeInBits(V.getType()->getPointerAddressSpace());
4967       APInt Offset(IdxWidth, 0);
4968       const Value *Base = stripAndAccumulateOffsets(
4969           A, *this, &V, DL, Offset, /* GetMinOffset */ false,
4970           /* AllowNonInbounds */ true);
4971 
4972       const auto &AA = A.getAAFor<AADereferenceable>(
4973           *this, IRPosition::value(*Base), DepClassTy::REQUIRED);
4974       int64_t DerefBytes = 0;
4975       if (!Stripped && this == &AA) {
4976         // Use IR information if we did not strip anything.
4977         // TODO: track globally.
4978         bool CanBeNull, CanBeFreed;
4979         DerefBytes =
4980             Base->getPointerDereferenceableBytes(DL, CanBeNull, CanBeFreed);
4981         T.GlobalState.indicatePessimisticFixpoint();
4982       } else {
4983         const DerefState &DS = AA.getState();
4984         DerefBytes = DS.DerefBytesState.getAssumed();
4985         T.GlobalState &= DS.GlobalState;
4986       }
4987 
4988       // For now we do not try to "increase" dereferenceability due to negative
4989       // indices as we first have to come up with code to deal with loops and
4990       // for overflows of the dereferenceable bytes.
4991       int64_t OffsetSExt = Offset.getSExtValue();
4992       if (OffsetSExt < 0)
4993         OffsetSExt = 0;
4994 
4995       T.takeAssumedDerefBytesMinimum(
4996           std::max(int64_t(0), DerefBytes - OffsetSExt));
4997 
4998       if (this == &AA) {
4999         if (!Stripped) {
5000           // If nothing was stripped IR information is all we got.
5001           T.takeKnownDerefBytesMaximum(
5002               std::max(int64_t(0), DerefBytes - OffsetSExt));
5003           T.indicatePessimisticFixpoint();
5004         } else if (OffsetSExt > 0) {
5005           // If something was stripped but there is circular reasoning we look
5006           // for the offset. If it is positive we basically decrease the
5007           // dereferenceable bytes in a circular loop now, which will simply
5008           // drive them down to the known value in a very slow way which we
5009           // can accelerate.
5010           T.indicatePessimisticFixpoint();
5011         }
5012       }
5013 
5014       return T.isValidState();
5015     };
5016 
5017     for (const auto &VAC : Values)
5018       if (!VisitValueCB(*VAC.getValue()))
5019         return indicatePessimisticFixpoint();
5020 
5021     return clampStateAndIndicateChange(getState(), T);
5022   }
5023 
5024   /// See AbstractAttribute::trackStatistics()
5025   void trackStatistics() const override {
5026     STATS_DECLTRACK_FLOATING_ATTR(dereferenceable)
5027   }
5028 };
5029 
5030 /// Dereferenceable attribute for a return value.
5031 struct AADereferenceableReturned final
5032     : AAReturnedFromReturnedValues<AADereferenceable, AADereferenceableImpl> {
5033   AADereferenceableReturned(const IRPosition &IRP, Attributor &A)
5034       : AAReturnedFromReturnedValues<AADereferenceable, AADereferenceableImpl>(
5035             IRP, A) {}
5036 
5037   /// See AbstractAttribute::trackStatistics()
5038   void trackStatistics() const override {
5039     STATS_DECLTRACK_FNRET_ATTR(dereferenceable)
5040   }
5041 };
5042 
5043 /// Dereferenceable attribute for an argument
5044 struct AADereferenceableArgument final
5045     : AAArgumentFromCallSiteArguments<AADereferenceable,
5046                                       AADereferenceableImpl> {
5047   using Base =
5048       AAArgumentFromCallSiteArguments<AADereferenceable, AADereferenceableImpl>;
5049   AADereferenceableArgument(const IRPosition &IRP, Attributor &A)
5050       : Base(IRP, A) {}
5051 
5052   /// See AbstractAttribute::trackStatistics()
5053   void trackStatistics() const override {
5054     STATS_DECLTRACK_ARG_ATTR(dereferenceable)
5055   }
5056 };
5057 
5058 /// Dereferenceable attribute for a call site argument.
5059 struct AADereferenceableCallSiteArgument final : AADereferenceableFloating {
5060   AADereferenceableCallSiteArgument(const IRPosition &IRP, Attributor &A)
5061       : AADereferenceableFloating(IRP, A) {}
5062 
5063   /// See AbstractAttribute::trackStatistics()
5064   void trackStatistics() const override {
5065     STATS_DECLTRACK_CSARG_ATTR(dereferenceable)
5066   }
5067 };
5068 
5069 /// Dereferenceable attribute deduction for a call site return value.
5070 struct AADereferenceableCallSiteReturned final
5071     : AACallSiteReturnedFromReturned<AADereferenceable, AADereferenceableImpl> {
5072   using Base =
5073       AACallSiteReturnedFromReturned<AADereferenceable, AADereferenceableImpl>;
5074   AADereferenceableCallSiteReturned(const IRPosition &IRP, Attributor &A)
5075       : Base(IRP, A) {}
5076 
5077   /// See AbstractAttribute::trackStatistics()
5078   void trackStatistics() const override {
5079     STATS_DECLTRACK_CS_ATTR(dereferenceable);
5080   }
5081 };
5082 } // namespace
5083 
5084 // ------------------------ Align Argument Attribute ------------------------
5085 
5086 namespace {
5087 static unsigned getKnownAlignForUse(Attributor &A, AAAlign &QueryingAA,
5088                                     Value &AssociatedValue, const Use *U,
5089                                     const Instruction *I, bool &TrackUse) {
5090   // We need to follow common pointer manipulation uses to the accesses they
5091   // feed into.
5092   if (isa<CastInst>(I)) {
5093     // Follow all but ptr2int casts.
5094     TrackUse = !isa<PtrToIntInst>(I);
5095     return 0;
5096   }
5097   if (auto *GEP = dyn_cast<GetElementPtrInst>(I)) {
5098     if (GEP->hasAllConstantIndices())
5099       TrackUse = true;
5100     return 0;
5101   }
5102 
5103   MaybeAlign MA;
5104   if (const auto *CB = dyn_cast<CallBase>(I)) {
5105     if (CB->isBundleOperand(U) || CB->isCallee(U))
5106       return 0;
5107 
5108     unsigned ArgNo = CB->getArgOperandNo(U);
5109     IRPosition IRP = IRPosition::callsite_argument(*CB, ArgNo);
5110     // As long as we only use known information there is no need to track
5111     // dependences here.
5112     auto &AlignAA = A.getAAFor<AAAlign>(QueryingAA, IRP, DepClassTy::NONE);
5113     MA = MaybeAlign(AlignAA.getKnownAlign());
5114   }
5115 
5116   const DataLayout &DL = A.getDataLayout();
5117   const Value *UseV = U->get();
5118   if (auto *SI = dyn_cast<StoreInst>(I)) {
5119     if (SI->getPointerOperand() == UseV)
5120       MA = SI->getAlign();
5121   } else if (auto *LI = dyn_cast<LoadInst>(I)) {
5122     if (LI->getPointerOperand() == UseV)
5123       MA = LI->getAlign();
5124   }
5125 
5126   if (!MA || *MA <= QueryingAA.getKnownAlign())
5127     return 0;
5128 
5129   unsigned Alignment = MA->value();
5130   int64_t Offset;
5131 
5132   if (const Value *Base = GetPointerBaseWithConstantOffset(UseV, Offset, DL)) {
5133     if (Base == &AssociatedValue) {
5134       // BasePointerAddr + Offset = Alignment * Q for some integer Q.
5135       // So we can say that the maximum power of two which is a divisor of
5136       // gcd(Offset, Alignment) is an alignment.
5137 
5138       uint32_t gcd = std::gcd(uint32_t(abs((int32_t)Offset)), Alignment);
5139       Alignment = llvm::PowerOf2Floor(gcd);
5140     }
5141   }
5142 
5143   return Alignment;
5144 }
5145 
5146 struct AAAlignImpl : AAAlign {
5147   AAAlignImpl(const IRPosition &IRP, Attributor &A) : AAAlign(IRP, A) {}
5148 
5149   /// See AbstractAttribute::initialize(...).
5150   void initialize(Attributor &A) override {
5151     SmallVector<Attribute, 4> Attrs;
5152     getAttrs({Attribute::Alignment}, Attrs);
5153     for (const Attribute &Attr : Attrs)
5154       takeKnownMaximum(Attr.getValueAsInt());
5155 
5156     Value &V = *getAssociatedValue().stripPointerCasts();
5157     takeKnownMaximum(V.getPointerAlignment(A.getDataLayout()).value());
5158 
5159     if (getIRPosition().isFnInterfaceKind() &&
5160         (!getAnchorScope() ||
5161          !A.isFunctionIPOAmendable(*getAssociatedFunction()))) {
5162       indicatePessimisticFixpoint();
5163       return;
5164     }
5165 
5166     if (Instruction *CtxI = getCtxI())
5167       followUsesInMBEC(*this, A, getState(), *CtxI);
5168   }
5169 
5170   /// See AbstractAttribute::manifest(...).
5171   ChangeStatus manifest(Attributor &A) override {
5172     ChangeStatus LoadStoreChanged = ChangeStatus::UNCHANGED;
5173 
5174     // Check for users that allow alignment annotations.
5175     Value &AssociatedValue = getAssociatedValue();
5176     for (const Use &U : AssociatedValue.uses()) {
5177       if (auto *SI = dyn_cast<StoreInst>(U.getUser())) {
5178         if (SI->getPointerOperand() == &AssociatedValue)
5179           if (SI->getAlign() < getAssumedAlign()) {
5180             STATS_DECLTRACK(AAAlign, Store,
5181                             "Number of times alignment added to a store");
5182             SI->setAlignment(getAssumedAlign());
5183             LoadStoreChanged = ChangeStatus::CHANGED;
5184           }
5185       } else if (auto *LI = dyn_cast<LoadInst>(U.getUser())) {
5186         if (LI->getPointerOperand() == &AssociatedValue)
5187           if (LI->getAlign() < getAssumedAlign()) {
5188             LI->setAlignment(getAssumedAlign());
5189             STATS_DECLTRACK(AAAlign, Load,
5190                             "Number of times alignment added to a load");
5191             LoadStoreChanged = ChangeStatus::CHANGED;
5192           }
5193       }
5194     }
5195 
5196     ChangeStatus Changed = AAAlign::manifest(A);
5197 
5198     Align InheritAlign =
5199         getAssociatedValue().getPointerAlignment(A.getDataLayout());
5200     if (InheritAlign >= getAssumedAlign())
5201       return LoadStoreChanged;
5202     return Changed | LoadStoreChanged;
5203   }
5204 
5205   // TODO: Provide a helper to determine the implied ABI alignment and check in
5206   //       the existing manifest method and a new one for AAAlignImpl that value
5207   //       to avoid making the alignment explicit if it did not improve.
5208 
5209   /// See AbstractAttribute::getDeducedAttributes
5210   void getDeducedAttributes(LLVMContext &Ctx,
5211                             SmallVectorImpl<Attribute> &Attrs) const override {
5212     if (getAssumedAlign() > 1)
5213       Attrs.emplace_back(
5214           Attribute::getWithAlignment(Ctx, Align(getAssumedAlign())));
5215   }
5216 
5217   /// See followUsesInMBEC
5218   bool followUseInMBEC(Attributor &A, const Use *U, const Instruction *I,
5219                        AAAlign::StateType &State) {
5220     bool TrackUse = false;
5221 
5222     unsigned int KnownAlign =
5223         getKnownAlignForUse(A, *this, getAssociatedValue(), U, I, TrackUse);
5224     State.takeKnownMaximum(KnownAlign);
5225 
5226     return TrackUse;
5227   }
5228 
5229   /// See AbstractAttribute::getAsStr().
5230   const std::string getAsStr() const override {
5231     return "align<" + std::to_string(getKnownAlign().value()) + "-" +
5232            std::to_string(getAssumedAlign().value()) + ">";
5233   }
5234 };
5235 
5236 /// Align attribute for a floating value.
5237 struct AAAlignFloating : AAAlignImpl {
5238   AAAlignFloating(const IRPosition &IRP, Attributor &A) : AAAlignImpl(IRP, A) {}
5239 
5240   /// See AbstractAttribute::updateImpl(...).
5241   ChangeStatus updateImpl(Attributor &A) override {
5242     const DataLayout &DL = A.getDataLayout();
5243 
5244     bool Stripped;
5245     bool UsedAssumedInformation = false;
5246     SmallVector<AA::ValueAndContext> Values;
5247     if (!A.getAssumedSimplifiedValues(getIRPosition(), *this, Values,
5248                                       AA::AnyScope, UsedAssumedInformation)) {
5249       Values.push_back({getAssociatedValue(), getCtxI()});
5250       Stripped = false;
5251     } else {
5252       Stripped = Values.size() != 1 ||
5253                  Values.front().getValue() != &getAssociatedValue();
5254     }
5255 
5256     StateType T;
5257     auto VisitValueCB = [&](Value &V) -> bool {
5258       if (isa<UndefValue>(V) || isa<ConstantPointerNull>(V))
5259         return true;
5260       const auto &AA = A.getAAFor<AAAlign>(*this, IRPosition::value(V),
5261                                            DepClassTy::REQUIRED);
5262       if (!Stripped && this == &AA) {
5263         int64_t Offset;
5264         unsigned Alignment = 1;
5265         if (const Value *Base =
5266                 GetPointerBaseWithConstantOffset(&V, Offset, DL)) {
5267           // TODO: Use AAAlign for the base too.
5268           Align PA = Base->getPointerAlignment(DL);
5269           // BasePointerAddr + Offset = Alignment * Q for some integer Q.
5270           // So we can say that the maximum power of two which is a divisor of
5271           // gcd(Offset, Alignment) is an alignment.
5272 
5273           uint32_t gcd =
5274               std::gcd(uint32_t(abs((int32_t)Offset)), uint32_t(PA.value()));
5275           Alignment = llvm::PowerOf2Floor(gcd);
5276         } else {
5277           Alignment = V.getPointerAlignment(DL).value();
5278         }
5279         // Use only IR information if we did not strip anything.
5280         T.takeKnownMaximum(Alignment);
5281         T.indicatePessimisticFixpoint();
5282       } else {
5283         // Use abstract attribute information.
5284         const AAAlign::StateType &DS = AA.getState();
5285         T ^= DS;
5286       }
5287       return T.isValidState();
5288     };
5289 
5290     for (const auto &VAC : Values) {
5291       if (!VisitValueCB(*VAC.getValue()))
5292         return indicatePessimisticFixpoint();
5293     }
5294 
5295     //  TODO: If we know we visited all incoming values, thus no are assumed
5296     //  dead, we can take the known information from the state T.
5297     return clampStateAndIndicateChange(getState(), T);
5298   }
5299 
5300   /// See AbstractAttribute::trackStatistics()
5301   void trackStatistics() const override { STATS_DECLTRACK_FLOATING_ATTR(align) }
5302 };
5303 
5304 /// Align attribute for function return value.
5305 struct AAAlignReturned final
5306     : AAReturnedFromReturnedValues<AAAlign, AAAlignImpl> {
5307   using Base = AAReturnedFromReturnedValues<AAAlign, AAAlignImpl>;
5308   AAAlignReturned(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {}
5309 
5310   /// See AbstractAttribute::initialize(...).
5311   void initialize(Attributor &A) override {
5312     Base::initialize(A);
5313     Function *F = getAssociatedFunction();
5314     if (!F || F->isDeclaration())
5315       indicatePessimisticFixpoint();
5316   }
5317 
5318   /// See AbstractAttribute::trackStatistics()
5319   void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(aligned) }
5320 };
5321 
5322 /// Align attribute for function argument.
5323 struct AAAlignArgument final
5324     : AAArgumentFromCallSiteArguments<AAAlign, AAAlignImpl> {
5325   using Base = AAArgumentFromCallSiteArguments<AAAlign, AAAlignImpl>;
5326   AAAlignArgument(const IRPosition &IRP, Attributor &A) : Base(IRP, A) {}
5327 
5328   /// See AbstractAttribute::manifest(...).
5329   ChangeStatus manifest(Attributor &A) override {
5330     // If the associated argument is involved in a must-tail call we give up
5331     // because we would need to keep the argument alignments of caller and
5332     // callee in-sync. Just does not seem worth the trouble right now.
5333     if (A.getInfoCache().isInvolvedInMustTailCall(*getAssociatedArgument()))
5334       return ChangeStatus::UNCHANGED;
5335     return Base::manifest(A);
5336   }
5337 
5338   /// See AbstractAttribute::trackStatistics()
5339   void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(aligned) }
5340 };
5341 
5342 struct AAAlignCallSiteArgument final : AAAlignFloating {
5343   AAAlignCallSiteArgument(const IRPosition &IRP, Attributor &A)
5344       : AAAlignFloating(IRP, A) {}
5345 
5346   /// See AbstractAttribute::manifest(...).
5347   ChangeStatus manifest(Attributor &A) override {
5348     // If the associated argument is involved in a must-tail call we give up
5349     // because we would need to keep the argument alignments of caller and
5350     // callee in-sync. Just does not seem worth the trouble right now.
5351     if (Argument *Arg = getAssociatedArgument())
5352       if (A.getInfoCache().isInvolvedInMustTailCall(*Arg))
5353         return ChangeStatus::UNCHANGED;
5354     ChangeStatus Changed = AAAlignImpl::manifest(A);
5355     Align InheritAlign =
5356         getAssociatedValue().getPointerAlignment(A.getDataLayout());
5357     if (InheritAlign >= getAssumedAlign())
5358       Changed = ChangeStatus::UNCHANGED;
5359     return Changed;
5360   }
5361 
5362   /// See AbstractAttribute::updateImpl(Attributor &A).
5363   ChangeStatus updateImpl(Attributor &A) override {
5364     ChangeStatus Changed = AAAlignFloating::updateImpl(A);
5365     if (Argument *Arg = getAssociatedArgument()) {
5366       // We only take known information from the argument
5367       // so we do not need to track a dependence.
5368       const auto &ArgAlignAA = A.getAAFor<AAAlign>(
5369           *this, IRPosition::argument(*Arg), DepClassTy::NONE);
5370       takeKnownMaximum(ArgAlignAA.getKnownAlign().value());
5371     }
5372     return Changed;
5373   }
5374 
5375   /// See AbstractAttribute::trackStatistics()
5376   void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(aligned) }
5377 };
5378 
5379 /// Align attribute deduction for a call site return value.
5380 struct AAAlignCallSiteReturned final
5381     : AACallSiteReturnedFromReturned<AAAlign, AAAlignImpl> {
5382   using Base = AACallSiteReturnedFromReturned<AAAlign, AAAlignImpl>;
5383   AAAlignCallSiteReturned(const IRPosition &IRP, Attributor &A)
5384       : Base(IRP, A) {}
5385 
5386   /// See AbstractAttribute::initialize(...).
5387   void initialize(Attributor &A) override {
5388     Base::initialize(A);
5389     Function *F = getAssociatedFunction();
5390     if (!F || F->isDeclaration())
5391       indicatePessimisticFixpoint();
5392   }
5393 
5394   /// See AbstractAttribute::trackStatistics()
5395   void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(align); }
5396 };
5397 } // namespace
5398 
5399 /// ------------------ Function No-Return Attribute ----------------------------
5400 namespace {
5401 struct AANoReturnImpl : public AANoReturn {
5402   AANoReturnImpl(const IRPosition &IRP, Attributor &A) : AANoReturn(IRP, A) {}
5403 
5404   /// See AbstractAttribute::initialize(...).
5405   void initialize(Attributor &A) override {
5406     AANoReturn::initialize(A);
5407     Function *F = getAssociatedFunction();
5408     if (!F || F->isDeclaration())
5409       indicatePessimisticFixpoint();
5410   }
5411 
5412   /// See AbstractAttribute::getAsStr().
5413   const std::string getAsStr() const override {
5414     return getAssumed() ? "noreturn" : "may-return";
5415   }
5416 
5417   /// See AbstractAttribute::updateImpl(Attributor &A).
5418   ChangeStatus updateImpl(Attributor &A) override {
5419     auto CheckForNoReturn = [](Instruction &) { return false; };
5420     bool UsedAssumedInformation = false;
5421     if (!A.checkForAllInstructions(CheckForNoReturn, *this,
5422                                    {(unsigned)Instruction::Ret},
5423                                    UsedAssumedInformation))
5424       return indicatePessimisticFixpoint();
5425     return ChangeStatus::UNCHANGED;
5426   }
5427 };
5428 
5429 struct AANoReturnFunction final : AANoReturnImpl {
5430   AANoReturnFunction(const IRPosition &IRP, Attributor &A)
5431       : AANoReturnImpl(IRP, A) {}
5432 
5433   /// See AbstractAttribute::trackStatistics()
5434   void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(noreturn) }
5435 };
5436 
5437 /// NoReturn attribute deduction for a call sites.
5438 struct AANoReturnCallSite final : AANoReturnImpl {
5439   AANoReturnCallSite(const IRPosition &IRP, Attributor &A)
5440       : AANoReturnImpl(IRP, A) {}
5441 
5442   /// See AbstractAttribute::initialize(...).
5443   void initialize(Attributor &A) override {
5444     AANoReturnImpl::initialize(A);
5445     if (Function *F = getAssociatedFunction()) {
5446       const IRPosition &FnPos = IRPosition::function(*F);
5447       auto &FnAA = A.getAAFor<AANoReturn>(*this, FnPos, DepClassTy::REQUIRED);
5448       if (!FnAA.isAssumedNoReturn())
5449         indicatePessimisticFixpoint();
5450     }
5451   }
5452 
5453   /// See AbstractAttribute::updateImpl(...).
5454   ChangeStatus updateImpl(Attributor &A) override {
5455     // TODO: Once we have call site specific value information we can provide
5456     //       call site specific liveness information and then it makes
5457     //       sense to specialize attributes for call sites arguments instead of
5458     //       redirecting requests to the callee argument.
5459     Function *F = getAssociatedFunction();
5460     const IRPosition &FnPos = IRPosition::function(*F);
5461     auto &FnAA = A.getAAFor<AANoReturn>(*this, FnPos, DepClassTy::REQUIRED);
5462     return clampStateAndIndicateChange(getState(), FnAA.getState());
5463   }
5464 
5465   /// See AbstractAttribute::trackStatistics()
5466   void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(noreturn); }
5467 };
5468 } // namespace
5469 
5470 /// ----------------------- Instance Info ---------------------------------
5471 
5472 namespace {
5473 /// A class to hold the state of for no-capture attributes.
5474 struct AAInstanceInfoImpl : public AAInstanceInfo {
5475   AAInstanceInfoImpl(const IRPosition &IRP, Attributor &A)
5476       : AAInstanceInfo(IRP, A) {}
5477 
5478   /// See AbstractAttribute::initialize(...).
5479   void initialize(Attributor &A) override {
5480     Value &V = getAssociatedValue();
5481     if (auto *C = dyn_cast<Constant>(&V)) {
5482       if (C->isThreadDependent())
5483         indicatePessimisticFixpoint();
5484       else
5485         indicateOptimisticFixpoint();
5486       return;
5487     }
5488     if (auto *CB = dyn_cast<CallBase>(&V))
5489       if (CB->arg_size() == 0 && !CB->mayHaveSideEffects() &&
5490           !CB->mayReadFromMemory()) {
5491         indicateOptimisticFixpoint();
5492         return;
5493       }
5494   }
5495 
5496   /// See AbstractAttribute::updateImpl(...).
5497   ChangeStatus updateImpl(Attributor &A) override {
5498     ChangeStatus Changed = ChangeStatus::UNCHANGED;
5499 
5500     Value &V = getAssociatedValue();
5501     const Function *Scope = nullptr;
5502     if (auto *I = dyn_cast<Instruction>(&V))
5503       Scope = I->getFunction();
5504     if (auto *A = dyn_cast<Argument>(&V)) {
5505       Scope = A->getParent();
5506       if (!Scope->hasLocalLinkage())
5507         return Changed;
5508     }
5509     if (!Scope)
5510       return indicateOptimisticFixpoint();
5511 
5512     auto &NoRecurseAA = A.getAAFor<AANoRecurse>(
5513         *this, IRPosition::function(*Scope), DepClassTy::OPTIONAL);
5514     if (NoRecurseAA.isAssumedNoRecurse())
5515       return Changed;
5516 
5517     auto UsePred = [&](const Use &U, bool &Follow) {
5518       const Instruction *UserI = dyn_cast<Instruction>(U.getUser());
5519       if (!UserI || isa<GetElementPtrInst>(UserI) || isa<CastInst>(UserI) ||
5520           isa<PHINode>(UserI) || isa<SelectInst>(UserI)) {
5521         Follow = true;
5522         return true;
5523       }
5524       if (isa<LoadInst>(UserI) || isa<CmpInst>(UserI) ||
5525           (isa<StoreInst>(UserI) &&
5526            cast<StoreInst>(UserI)->getValueOperand() != U.get()))
5527         return true;
5528       if (auto *CB = dyn_cast<CallBase>(UserI)) {
5529         // This check is not guaranteeing uniqueness but for now that we cannot
5530         // end up with two versions of \p U thinking it was one.
5531         if (!CB->getCalledFunction() ||
5532             !CB->getCalledFunction()->hasLocalLinkage())
5533           return true;
5534         if (!CB->isArgOperand(&U))
5535           return false;
5536         const auto &ArgInstanceInfoAA = A.getAAFor<AAInstanceInfo>(
5537             *this, IRPosition::callsite_argument(*CB, CB->getArgOperandNo(&U)),
5538             DepClassTy::OPTIONAL);
5539         if (!ArgInstanceInfoAA.isAssumedUniqueForAnalysis())
5540           return false;
5541         // If this call base might reach the scope again we might forward the
5542         // argument back here. This is very conservative.
5543         if (AA::isPotentiallyReachable(
5544                 A, *CB, *Scope, *this, /* ExclusionSet */ nullptr,
5545                 [Scope](const Function &Fn) { return &Fn != Scope; }))
5546           return false;
5547         return true;
5548       }
5549       return false;
5550     };
5551 
5552     auto EquivalentUseCB = [&](const Use &OldU, const Use &NewU) {
5553       if (auto *SI = dyn_cast<StoreInst>(OldU.getUser())) {
5554         auto *Ptr = SI->getPointerOperand()->stripPointerCasts();
5555         if ((isa<AllocaInst>(Ptr) || isNoAliasCall(Ptr)) &&
5556             AA::isDynamicallyUnique(A, *this, *Ptr))
5557           return true;
5558       }
5559       return false;
5560     };
5561 
5562     if (!A.checkForAllUses(UsePred, *this, V, /* CheckBBLivenessOnly */ true,
5563                            DepClassTy::OPTIONAL,
5564                            /* IgnoreDroppableUses */ true, EquivalentUseCB))
5565       return indicatePessimisticFixpoint();
5566 
5567     return Changed;
5568   }
5569 
5570   /// See AbstractState::getAsStr().
5571   const std::string getAsStr() const override {
5572     return isAssumedUniqueForAnalysis() ? "<unique [fAa]>" : "<unknown>";
5573   }
5574 
5575   /// See AbstractAttribute::trackStatistics()
5576   void trackStatistics() const override {}
5577 };
5578 
5579 /// InstanceInfo attribute for floating values.
5580 struct AAInstanceInfoFloating : AAInstanceInfoImpl {
5581   AAInstanceInfoFloating(const IRPosition &IRP, Attributor &A)
5582       : AAInstanceInfoImpl(IRP, A) {}
5583 };
5584 
5585 /// NoCapture attribute for function arguments.
5586 struct AAInstanceInfoArgument final : AAInstanceInfoFloating {
5587   AAInstanceInfoArgument(const IRPosition &IRP, Attributor &A)
5588       : AAInstanceInfoFloating(IRP, A) {}
5589 };
5590 
5591 /// InstanceInfo attribute for call site arguments.
5592 struct AAInstanceInfoCallSiteArgument final : AAInstanceInfoImpl {
5593   AAInstanceInfoCallSiteArgument(const IRPosition &IRP, Attributor &A)
5594       : AAInstanceInfoImpl(IRP, A) {}
5595 
5596   /// See AbstractAttribute::updateImpl(...).
5597   ChangeStatus updateImpl(Attributor &A) override {
5598     // TODO: Once we have call site specific value information we can provide
5599     //       call site specific liveness information and then it makes
5600     //       sense to specialize attributes for call sites arguments instead of
5601     //       redirecting requests to the callee argument.
5602     Argument *Arg = getAssociatedArgument();
5603     if (!Arg)
5604       return indicatePessimisticFixpoint();
5605     const IRPosition &ArgPos = IRPosition::argument(*Arg);
5606     auto &ArgAA =
5607         A.getAAFor<AAInstanceInfo>(*this, ArgPos, DepClassTy::REQUIRED);
5608     return clampStateAndIndicateChange(getState(), ArgAA.getState());
5609   }
5610 };
5611 
5612 /// InstanceInfo attribute for function return value.
5613 struct AAInstanceInfoReturned final : AAInstanceInfoImpl {
5614   AAInstanceInfoReturned(const IRPosition &IRP, Attributor &A)
5615       : AAInstanceInfoImpl(IRP, A) {
5616     llvm_unreachable("InstanceInfo is not applicable to function returns!");
5617   }
5618 
5619   /// See AbstractAttribute::initialize(...).
5620   void initialize(Attributor &A) override {
5621     llvm_unreachable("InstanceInfo is not applicable to function returns!");
5622   }
5623 
5624   /// See AbstractAttribute::updateImpl(...).
5625   ChangeStatus updateImpl(Attributor &A) override {
5626     llvm_unreachable("InstanceInfo is not applicable to function returns!");
5627   }
5628 };
5629 
5630 /// InstanceInfo attribute deduction for a call site return value.
5631 struct AAInstanceInfoCallSiteReturned final : AAInstanceInfoFloating {
5632   AAInstanceInfoCallSiteReturned(const IRPosition &IRP, Attributor &A)
5633       : AAInstanceInfoFloating(IRP, A) {}
5634 };
5635 } // namespace
5636 
5637 /// ----------------------- Variable Capturing ---------------------------------
5638 
5639 namespace {
5640 /// A class to hold the state of for no-capture attributes.
5641 struct AANoCaptureImpl : public AANoCapture {
5642   AANoCaptureImpl(const IRPosition &IRP, Attributor &A) : AANoCapture(IRP, A) {}
5643 
5644   /// See AbstractAttribute::initialize(...).
5645   void initialize(Attributor &A) override {
5646     if (hasAttr(getAttrKind(), /* IgnoreSubsumingPositions */ true)) {
5647       indicateOptimisticFixpoint();
5648       return;
5649     }
5650     Function *AnchorScope = getAnchorScope();
5651     if (isFnInterfaceKind() &&
5652         (!AnchorScope || !A.isFunctionIPOAmendable(*AnchorScope))) {
5653       indicatePessimisticFixpoint();
5654       return;
5655     }
5656 
5657     // You cannot "capture" null in the default address space.
5658     if (isa<ConstantPointerNull>(getAssociatedValue()) &&
5659         getAssociatedValue().getType()->getPointerAddressSpace() == 0) {
5660       indicateOptimisticFixpoint();
5661       return;
5662     }
5663 
5664     const Function *F =
5665         isArgumentPosition() ? getAssociatedFunction() : AnchorScope;
5666 
5667     // Check what state the associated function can actually capture.
5668     if (F)
5669       determineFunctionCaptureCapabilities(getIRPosition(), *F, *this);
5670     else
5671       indicatePessimisticFixpoint();
5672   }
5673 
5674   /// See AbstractAttribute::updateImpl(...).
5675   ChangeStatus updateImpl(Attributor &A) override;
5676 
5677   /// see AbstractAttribute::isAssumedNoCaptureMaybeReturned(...).
5678   void getDeducedAttributes(LLVMContext &Ctx,
5679                             SmallVectorImpl<Attribute> &Attrs) const override {
5680     if (!isAssumedNoCaptureMaybeReturned())
5681       return;
5682 
5683     if (isArgumentPosition()) {
5684       if (isAssumedNoCapture())
5685         Attrs.emplace_back(Attribute::get(Ctx, Attribute::NoCapture));
5686       else if (ManifestInternal)
5687         Attrs.emplace_back(Attribute::get(Ctx, "no-capture-maybe-returned"));
5688     }
5689   }
5690 
5691   /// Set the NOT_CAPTURED_IN_MEM and NOT_CAPTURED_IN_RET bits in \p Known
5692   /// depending on the ability of the function associated with \p IRP to capture
5693   /// state in memory and through "returning/throwing", respectively.
5694   static void determineFunctionCaptureCapabilities(const IRPosition &IRP,
5695                                                    const Function &F,
5696                                                    BitIntegerState &State) {
5697     // TODO: Once we have memory behavior attributes we should use them here.
5698 
5699     // If we know we cannot communicate or write to memory, we do not care about
5700     // ptr2int anymore.
5701     if (F.onlyReadsMemory() && F.doesNotThrow() &&
5702         F.getReturnType()->isVoidTy()) {
5703       State.addKnownBits(NO_CAPTURE);
5704       return;
5705     }
5706 
5707     // A function cannot capture state in memory if it only reads memory, it can
5708     // however return/throw state and the state might be influenced by the
5709     // pointer value, e.g., loading from a returned pointer might reveal a bit.
5710     if (F.onlyReadsMemory())
5711       State.addKnownBits(NOT_CAPTURED_IN_MEM);
5712 
5713     // A function cannot communicate state back if it does not through
5714     // exceptions and doesn not return values.
5715     if (F.doesNotThrow() && F.getReturnType()->isVoidTy())
5716       State.addKnownBits(NOT_CAPTURED_IN_RET);
5717 
5718     // Check existing "returned" attributes.
5719     int ArgNo = IRP.getCalleeArgNo();
5720     if (F.doesNotThrow() && ArgNo >= 0) {
5721       for (unsigned u = 0, e = F.arg_size(); u < e; ++u)
5722         if (F.hasParamAttribute(u, Attribute::Returned)) {
5723           if (u == unsigned(ArgNo))
5724             State.removeAssumedBits(NOT_CAPTURED_IN_RET);
5725           else if (F.onlyReadsMemory())
5726             State.addKnownBits(NO_CAPTURE);
5727           else
5728             State.addKnownBits(NOT_CAPTURED_IN_RET);
5729           break;
5730         }
5731     }
5732   }
5733 
5734   /// See AbstractState::getAsStr().
5735   const std::string getAsStr() const override {
5736     if (isKnownNoCapture())
5737       return "known not-captured";
5738     if (isAssumedNoCapture())
5739       return "assumed not-captured";
5740     if (isKnownNoCaptureMaybeReturned())
5741       return "known not-captured-maybe-returned";
5742     if (isAssumedNoCaptureMaybeReturned())
5743       return "assumed not-captured-maybe-returned";
5744     return "assumed-captured";
5745   }
5746 
5747   /// Check the use \p U and update \p State accordingly. Return true if we
5748   /// should continue to update the state.
5749   bool checkUse(Attributor &A, AANoCapture::StateType &State, const Use &U,
5750                 bool &Follow) {
5751     Instruction *UInst = cast<Instruction>(U.getUser());
5752     LLVM_DEBUG(dbgs() << "[AANoCapture] Check use: " << *U.get() << " in "
5753                       << *UInst << "\n");
5754 
5755     // Deal with ptr2int by following uses.
5756     if (isa<PtrToIntInst>(UInst)) {
5757       LLVM_DEBUG(dbgs() << " - ptr2int assume the worst!\n");
5758       return isCapturedIn(State, /* Memory */ true, /* Integer */ true,
5759                           /* Return */ true);
5760     }
5761 
5762     // For stores we already checked if we can follow them, if they make it
5763     // here we give up.
5764     if (isa<StoreInst>(UInst))
5765       return isCapturedIn(State, /* Memory */ true, /* Integer */ false,
5766                           /* Return */ false);
5767 
5768     // Explicitly catch return instructions.
5769     if (isa<ReturnInst>(UInst)) {
5770       if (UInst->getFunction() == getAnchorScope())
5771         return isCapturedIn(State, /* Memory */ false, /* Integer */ false,
5772                             /* Return */ true);
5773       return isCapturedIn(State, /* Memory */ true, /* Integer */ true,
5774                           /* Return */ true);
5775     }
5776 
5777     // For now we only use special logic for call sites. However, the tracker
5778     // itself knows about a lot of other non-capturing cases already.
5779     auto *CB = dyn_cast<CallBase>(UInst);
5780     if (!CB || !CB->isArgOperand(&U))
5781       return isCapturedIn(State, /* Memory */ true, /* Integer */ true,
5782                           /* Return */ true);
5783 
5784     unsigned ArgNo = CB->getArgOperandNo(&U);
5785     const IRPosition &CSArgPos = IRPosition::callsite_argument(*CB, ArgNo);
5786     // If we have a abstract no-capture attribute for the argument we can use
5787     // it to justify a non-capture attribute here. This allows recursion!
5788     auto &ArgNoCaptureAA =
5789         A.getAAFor<AANoCapture>(*this, CSArgPos, DepClassTy::REQUIRED);
5790     if (ArgNoCaptureAA.isAssumedNoCapture())
5791       return isCapturedIn(State, /* Memory */ false, /* Integer */ false,
5792                           /* Return */ false);
5793     if (ArgNoCaptureAA.isAssumedNoCaptureMaybeReturned()) {
5794       Follow = true;
5795       return isCapturedIn(State, /* Memory */ false, /* Integer */ false,
5796                           /* Return */ false);
5797     }
5798 
5799     // Lastly, we could not find a reason no-capture can be assumed so we don't.
5800     return isCapturedIn(State, /* Memory */ true, /* Integer */ true,
5801                         /* Return */ true);
5802   }
5803 
5804   /// Update \p State according to \p CapturedInMem, \p CapturedInInt, and
5805   /// \p CapturedInRet, then return true if we should continue updating the
5806   /// state.
5807   static bool isCapturedIn(AANoCapture::StateType &State, bool CapturedInMem,
5808                            bool CapturedInInt, bool CapturedInRet) {
5809     LLVM_DEBUG(dbgs() << " - captures [Mem " << CapturedInMem << "|Int "
5810                       << CapturedInInt << "|Ret " << CapturedInRet << "]\n");
5811     if (CapturedInMem)
5812       State.removeAssumedBits(AANoCapture::NOT_CAPTURED_IN_MEM);
5813     if (CapturedInInt)
5814       State.removeAssumedBits(AANoCapture::NOT_CAPTURED_IN_INT);
5815     if (CapturedInRet)
5816       State.removeAssumedBits(AANoCapture::NOT_CAPTURED_IN_RET);
5817     return State.isAssumed(AANoCapture::NO_CAPTURE_MAYBE_RETURNED);
5818   }
5819 };
5820 
5821 ChangeStatus AANoCaptureImpl::updateImpl(Attributor &A) {
5822   const IRPosition &IRP = getIRPosition();
5823   Value *V = isArgumentPosition() ? IRP.getAssociatedArgument()
5824                                   : &IRP.getAssociatedValue();
5825   if (!V)
5826     return indicatePessimisticFixpoint();
5827 
5828   const Function *F =
5829       isArgumentPosition() ? IRP.getAssociatedFunction() : IRP.getAnchorScope();
5830   assert(F && "Expected a function!");
5831   const IRPosition &FnPos = IRPosition::function(*F);
5832 
5833   AANoCapture::StateType T;
5834 
5835   // Readonly means we cannot capture through memory.
5836   bool IsKnown;
5837   if (AA::isAssumedReadOnly(A, FnPos, *this, IsKnown)) {
5838     T.addKnownBits(NOT_CAPTURED_IN_MEM);
5839     if (IsKnown)
5840       addKnownBits(NOT_CAPTURED_IN_MEM);
5841   }
5842 
5843   // Make sure all returned values are different than the underlying value.
5844   // TODO: we could do this in a more sophisticated way inside
5845   //       AAReturnedValues, e.g., track all values that escape through returns
5846   //       directly somehow.
5847   auto CheckReturnedArgs = [&](const AAReturnedValues &RVAA) {
5848     if (!RVAA.getState().isValidState())
5849       return false;
5850     bool SeenConstant = false;
5851     for (const auto &It : RVAA.returned_values()) {
5852       if (isa<Constant>(It.first)) {
5853         if (SeenConstant)
5854           return false;
5855         SeenConstant = true;
5856       } else if (!isa<Argument>(It.first) ||
5857                  It.first == getAssociatedArgument())
5858         return false;
5859     }
5860     return true;
5861   };
5862 
5863   const auto &NoUnwindAA =
5864       A.getAAFor<AANoUnwind>(*this, FnPos, DepClassTy::OPTIONAL);
5865   if (NoUnwindAA.isAssumedNoUnwind()) {
5866     bool IsVoidTy = F->getReturnType()->isVoidTy();
5867     const AAReturnedValues *RVAA =
5868         IsVoidTy ? nullptr
5869                  : &A.getAAFor<AAReturnedValues>(*this, FnPos,
5870 
5871                                                  DepClassTy::OPTIONAL);
5872     if (IsVoidTy || CheckReturnedArgs(*RVAA)) {
5873       T.addKnownBits(NOT_CAPTURED_IN_RET);
5874       if (T.isKnown(NOT_CAPTURED_IN_MEM))
5875         return ChangeStatus::UNCHANGED;
5876       if (NoUnwindAA.isKnownNoUnwind() &&
5877           (IsVoidTy || RVAA->getState().isAtFixpoint())) {
5878         addKnownBits(NOT_CAPTURED_IN_RET);
5879         if (isKnown(NOT_CAPTURED_IN_MEM))
5880           return indicateOptimisticFixpoint();
5881       }
5882     }
5883   }
5884 
5885   auto IsDereferenceableOrNull = [&](Value *O, const DataLayout &DL) {
5886     const auto &DerefAA = A.getAAFor<AADereferenceable>(
5887         *this, IRPosition::value(*O), DepClassTy::OPTIONAL);
5888     return DerefAA.getAssumedDereferenceableBytes();
5889   };
5890 
5891   auto UseCheck = [&](const Use &U, bool &Follow) -> bool {
5892     switch (DetermineUseCaptureKind(U, IsDereferenceableOrNull)) {
5893     case UseCaptureKind::NO_CAPTURE:
5894       return true;
5895     case UseCaptureKind::MAY_CAPTURE:
5896       return checkUse(A, T, U, Follow);
5897     case UseCaptureKind::PASSTHROUGH:
5898       Follow = true;
5899       return true;
5900     }
5901     llvm_unreachable("Unexpected use capture kind!");
5902   };
5903 
5904   if (!A.checkForAllUses(UseCheck, *this, *V))
5905     return indicatePessimisticFixpoint();
5906 
5907   AANoCapture::StateType &S = getState();
5908   auto Assumed = S.getAssumed();
5909   S.intersectAssumedBits(T.getAssumed());
5910   if (!isAssumedNoCaptureMaybeReturned())
5911     return indicatePessimisticFixpoint();
5912   return Assumed == S.getAssumed() ? ChangeStatus::UNCHANGED
5913                                    : ChangeStatus::CHANGED;
5914 }
5915 
5916 /// NoCapture attribute for function arguments.
5917 struct AANoCaptureArgument final : AANoCaptureImpl {
5918   AANoCaptureArgument(const IRPosition &IRP, Attributor &A)
5919       : AANoCaptureImpl(IRP, A) {}
5920 
5921   /// See AbstractAttribute::trackStatistics()
5922   void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(nocapture) }
5923 };
5924 
5925 /// NoCapture attribute for call site arguments.
5926 struct AANoCaptureCallSiteArgument final : AANoCaptureImpl {
5927   AANoCaptureCallSiteArgument(const IRPosition &IRP, Attributor &A)
5928       : AANoCaptureImpl(IRP, A) {}
5929 
5930   /// See AbstractAttribute::initialize(...).
5931   void initialize(Attributor &A) override {
5932     if (Argument *Arg = getAssociatedArgument())
5933       if (Arg->hasByValAttr())
5934         indicateOptimisticFixpoint();
5935     AANoCaptureImpl::initialize(A);
5936   }
5937 
5938   /// See AbstractAttribute::updateImpl(...).
5939   ChangeStatus updateImpl(Attributor &A) override {
5940     // TODO: Once we have call site specific value information we can provide
5941     //       call site specific liveness information and then it makes
5942     //       sense to specialize attributes for call sites arguments instead of
5943     //       redirecting requests to the callee argument.
5944     Argument *Arg = getAssociatedArgument();
5945     if (!Arg)
5946       return indicatePessimisticFixpoint();
5947     const IRPosition &ArgPos = IRPosition::argument(*Arg);
5948     auto &ArgAA = A.getAAFor<AANoCapture>(*this, ArgPos, DepClassTy::REQUIRED);
5949     return clampStateAndIndicateChange(getState(), ArgAA.getState());
5950   }
5951 
5952   /// See AbstractAttribute::trackStatistics()
5953   void trackStatistics() const override{STATS_DECLTRACK_CSARG_ATTR(nocapture)};
5954 };
5955 
5956 /// NoCapture attribute for floating values.
5957 struct AANoCaptureFloating final : AANoCaptureImpl {
5958   AANoCaptureFloating(const IRPosition &IRP, Attributor &A)
5959       : AANoCaptureImpl(IRP, A) {}
5960 
5961   /// See AbstractAttribute::trackStatistics()
5962   void trackStatistics() const override {
5963     STATS_DECLTRACK_FLOATING_ATTR(nocapture)
5964   }
5965 };
5966 
5967 /// NoCapture attribute for function return value.
5968 struct AANoCaptureReturned final : AANoCaptureImpl {
5969   AANoCaptureReturned(const IRPosition &IRP, Attributor &A)
5970       : AANoCaptureImpl(IRP, A) {
5971     llvm_unreachable("NoCapture is not applicable to function returns!");
5972   }
5973 
5974   /// See AbstractAttribute::initialize(...).
5975   void initialize(Attributor &A) override {
5976     llvm_unreachable("NoCapture is not applicable to function returns!");
5977   }
5978 
5979   /// See AbstractAttribute::updateImpl(...).
5980   ChangeStatus updateImpl(Attributor &A) override {
5981     llvm_unreachable("NoCapture is not applicable to function returns!");
5982   }
5983 
5984   /// See AbstractAttribute::trackStatistics()
5985   void trackStatistics() const override {}
5986 };
5987 
5988 /// NoCapture attribute deduction for a call site return value.
5989 struct AANoCaptureCallSiteReturned final : AANoCaptureImpl {
5990   AANoCaptureCallSiteReturned(const IRPosition &IRP, Attributor &A)
5991       : AANoCaptureImpl(IRP, A) {}
5992 
5993   /// See AbstractAttribute::initialize(...).
5994   void initialize(Attributor &A) override {
5995     const Function *F = getAnchorScope();
5996     // Check what state the associated function can actually capture.
5997     determineFunctionCaptureCapabilities(getIRPosition(), *F, *this);
5998   }
5999 
6000   /// See AbstractAttribute::trackStatistics()
6001   void trackStatistics() const override {
6002     STATS_DECLTRACK_CSRET_ATTR(nocapture)
6003   }
6004 };
6005 } // namespace
6006 
6007 /// ------------------ Value Simplify Attribute ----------------------------
6008 
6009 bool ValueSimplifyStateType::unionAssumed(std::optional<Value *> Other) {
6010   // FIXME: Add a typecast support.
6011   SimplifiedAssociatedValue = AA::combineOptionalValuesInAAValueLatice(
6012       SimplifiedAssociatedValue, Other, Ty);
6013   if (SimplifiedAssociatedValue == std::optional<Value *>(nullptr))
6014     return false;
6015 
6016   LLVM_DEBUG({
6017     if (SimplifiedAssociatedValue)
6018       dbgs() << "[ValueSimplify] is assumed to be "
6019              << **SimplifiedAssociatedValue << "\n";
6020     else
6021       dbgs() << "[ValueSimplify] is assumed to be <none>\n";
6022   });
6023   return true;
6024 }
6025 
6026 namespace {
6027 struct AAValueSimplifyImpl : AAValueSimplify {
6028   AAValueSimplifyImpl(const IRPosition &IRP, Attributor &A)
6029       : AAValueSimplify(IRP, A) {}
6030 
6031   /// See AbstractAttribute::initialize(...).
6032   void initialize(Attributor &A) override {
6033     if (getAssociatedValue().getType()->isVoidTy())
6034       indicatePessimisticFixpoint();
6035     if (A.hasSimplificationCallback(getIRPosition()))
6036       indicatePessimisticFixpoint();
6037   }
6038 
6039   /// See AbstractAttribute::getAsStr().
6040   const std::string getAsStr() const override {
6041     LLVM_DEBUG({
6042       dbgs() << "SAV: " << (bool)SimplifiedAssociatedValue << " ";
6043       if (SimplifiedAssociatedValue && *SimplifiedAssociatedValue)
6044         dbgs() << "SAV: " << **SimplifiedAssociatedValue << " ";
6045     });
6046     return isValidState() ? (isAtFixpoint() ? "simplified" : "maybe-simple")
6047                           : "not-simple";
6048   }
6049 
6050   /// See AbstractAttribute::trackStatistics()
6051   void trackStatistics() const override {}
6052 
6053   /// See AAValueSimplify::getAssumedSimplifiedValue()
6054   std::optional<Value *>
6055   getAssumedSimplifiedValue(Attributor &A) const override {
6056     return SimplifiedAssociatedValue;
6057   }
6058 
6059   /// Ensure the return value is \p V with type \p Ty, if not possible return
6060   /// nullptr. If \p Check is true we will only verify such an operation would
6061   /// suceed and return a non-nullptr value if that is the case. No IR is
6062   /// generated or modified.
6063   static Value *ensureType(Attributor &A, Value &V, Type &Ty, Instruction *CtxI,
6064                            bool Check) {
6065     if (auto *TypedV = AA::getWithType(V, Ty))
6066       return TypedV;
6067     if (CtxI && V.getType()->canLosslesslyBitCastTo(&Ty))
6068       return Check ? &V
6069                    : BitCastInst::CreatePointerBitCastOrAddrSpaceCast(&V, &Ty,
6070                                                                       "", CtxI);
6071     return nullptr;
6072   }
6073 
6074   /// Reproduce \p I with type \p Ty or return nullptr if that is not posisble.
6075   /// If \p Check is true we will only verify such an operation would suceed and
6076   /// return a non-nullptr value if that is the case. No IR is generated or
6077   /// modified.
6078   static Value *reproduceInst(Attributor &A,
6079                               const AbstractAttribute &QueryingAA,
6080                               Instruction &I, Type &Ty, Instruction *CtxI,
6081                               bool Check, ValueToValueMapTy &VMap) {
6082     assert(CtxI && "Cannot reproduce an instruction without context!");
6083     if (Check && (I.mayReadFromMemory() ||
6084                   !isSafeToSpeculativelyExecute(&I, CtxI, /* DT */ nullptr,
6085                                                 /* TLI */ nullptr)))
6086       return nullptr;
6087     for (Value *Op : I.operands()) {
6088       Value *NewOp = reproduceValue(A, QueryingAA, *Op, Ty, CtxI, Check, VMap);
6089       if (!NewOp) {
6090         assert(Check && "Manifest of new value unexpectedly failed!");
6091         return nullptr;
6092       }
6093       if (!Check)
6094         VMap[Op] = NewOp;
6095     }
6096     if (Check)
6097       return &I;
6098 
6099     Instruction *CloneI = I.clone();
6100     // TODO: Try to salvage debug information here.
6101     CloneI->setDebugLoc(DebugLoc());
6102     VMap[&I] = CloneI;
6103     CloneI->insertBefore(CtxI);
6104     RemapInstruction(CloneI, VMap);
6105     return CloneI;
6106   }
6107 
6108   /// Reproduce \p V with type \p Ty or return nullptr if that is not posisble.
6109   /// If \p Check is true we will only verify such an operation would suceed and
6110   /// return a non-nullptr value if that is the case. No IR is generated or
6111   /// modified.
6112   static Value *reproduceValue(Attributor &A,
6113                                const AbstractAttribute &QueryingAA, Value &V,
6114                                Type &Ty, Instruction *CtxI, bool Check,
6115                                ValueToValueMapTy &VMap) {
6116     if (const auto &NewV = VMap.lookup(&V))
6117       return NewV;
6118     bool UsedAssumedInformation = false;
6119     std::optional<Value *> SimpleV = A.getAssumedSimplified(
6120         V, QueryingAA, UsedAssumedInformation, AA::Interprocedural);
6121     if (!SimpleV.has_value())
6122       return PoisonValue::get(&Ty);
6123     Value *EffectiveV = &V;
6124     if (*SimpleV)
6125       EffectiveV = *SimpleV;
6126     if (auto *C = dyn_cast<Constant>(EffectiveV))
6127       return C;
6128     if (CtxI && AA::isValidAtPosition(AA::ValueAndContext(*EffectiveV, *CtxI),
6129                                       A.getInfoCache()))
6130       return ensureType(A, *EffectiveV, Ty, CtxI, Check);
6131     if (auto *I = dyn_cast<Instruction>(EffectiveV))
6132       if (Value *NewV = reproduceInst(A, QueryingAA, *I, Ty, CtxI, Check, VMap))
6133         return ensureType(A, *NewV, Ty, CtxI, Check);
6134     return nullptr;
6135   }
6136 
6137   /// Return a value we can use as replacement for the associated one, or
6138   /// nullptr if we don't have one that makes sense.
6139   Value *manifestReplacementValue(Attributor &A, Instruction *CtxI) const {
6140     Value *NewV = SimplifiedAssociatedValue
6141                       ? *SimplifiedAssociatedValue
6142                       : UndefValue::get(getAssociatedType());
6143     if (NewV && NewV != &getAssociatedValue()) {
6144       ValueToValueMapTy VMap;
6145       // First verify we can reprduce the value with the required type at the
6146       // context location before we actually start modifying the IR.
6147       if (reproduceValue(A, *this, *NewV, *getAssociatedType(), CtxI,
6148                          /* CheckOnly */ true, VMap))
6149         return reproduceValue(A, *this, *NewV, *getAssociatedType(), CtxI,
6150                               /* CheckOnly */ false, VMap);
6151     }
6152     return nullptr;
6153   }
6154 
6155   /// Helper function for querying AAValueSimplify and updating candidate.
6156   /// \param IRP The value position we are trying to unify with SimplifiedValue
6157   bool checkAndUpdate(Attributor &A, const AbstractAttribute &QueryingAA,
6158                       const IRPosition &IRP, bool Simplify = true) {
6159     bool UsedAssumedInformation = false;
6160     std::optional<Value *> QueryingValueSimplified = &IRP.getAssociatedValue();
6161     if (Simplify)
6162       QueryingValueSimplified = A.getAssumedSimplified(
6163           IRP, QueryingAA, UsedAssumedInformation, AA::Interprocedural);
6164     return unionAssumed(QueryingValueSimplified);
6165   }
6166 
6167   /// Returns a candidate is found or not
6168   template <typename AAType> bool askSimplifiedValueFor(Attributor &A) {
6169     if (!getAssociatedValue().getType()->isIntegerTy())
6170       return false;
6171 
6172     // This will also pass the call base context.
6173     const auto &AA =
6174         A.getAAFor<AAType>(*this, getIRPosition(), DepClassTy::NONE);
6175 
6176     std::optional<Constant *> COpt = AA.getAssumedConstant(A);
6177 
6178     if (!COpt) {
6179       SimplifiedAssociatedValue = std::nullopt;
6180       A.recordDependence(AA, *this, DepClassTy::OPTIONAL);
6181       return true;
6182     }
6183     if (auto *C = *COpt) {
6184       SimplifiedAssociatedValue = C;
6185       A.recordDependence(AA, *this, DepClassTy::OPTIONAL);
6186       return true;
6187     }
6188     return false;
6189   }
6190 
6191   bool askSimplifiedValueForOtherAAs(Attributor &A) {
6192     if (askSimplifiedValueFor<AAValueConstantRange>(A))
6193       return true;
6194     if (askSimplifiedValueFor<AAPotentialConstantValues>(A))
6195       return true;
6196     return false;
6197   }
6198 
6199   /// See AbstractAttribute::manifest(...).
6200   ChangeStatus manifest(Attributor &A) override {
6201     ChangeStatus Changed = ChangeStatus::UNCHANGED;
6202     for (auto &U : getAssociatedValue().uses()) {
6203       // Check if we need to adjust the insertion point to make sure the IR is
6204       // valid.
6205       Instruction *IP = dyn_cast<Instruction>(U.getUser());
6206       if (auto *PHI = dyn_cast_or_null<PHINode>(IP))
6207         IP = PHI->getIncomingBlock(U)->getTerminator();
6208       if (auto *NewV = manifestReplacementValue(A, IP)) {
6209         LLVM_DEBUG(dbgs() << "[ValueSimplify] " << getAssociatedValue()
6210                           << " -> " << *NewV << " :: " << *this << "\n");
6211         if (A.changeUseAfterManifest(U, *NewV))
6212           Changed = ChangeStatus::CHANGED;
6213       }
6214     }
6215 
6216     return Changed | AAValueSimplify::manifest(A);
6217   }
6218 
6219   /// See AbstractState::indicatePessimisticFixpoint(...).
6220   ChangeStatus indicatePessimisticFixpoint() override {
6221     SimplifiedAssociatedValue = &getAssociatedValue();
6222     return AAValueSimplify::indicatePessimisticFixpoint();
6223   }
6224 };
6225 
6226 struct AAValueSimplifyArgument final : AAValueSimplifyImpl {
6227   AAValueSimplifyArgument(const IRPosition &IRP, Attributor &A)
6228       : AAValueSimplifyImpl(IRP, A) {}
6229 
6230   void initialize(Attributor &A) override {
6231     AAValueSimplifyImpl::initialize(A);
6232     if (!getAnchorScope() || getAnchorScope()->isDeclaration())
6233       indicatePessimisticFixpoint();
6234     if (hasAttr({Attribute::InAlloca, Attribute::Preallocated,
6235                  Attribute::StructRet, Attribute::Nest, Attribute::ByVal},
6236                 /* IgnoreSubsumingPositions */ true))
6237       indicatePessimisticFixpoint();
6238   }
6239 
6240   /// See AbstractAttribute::updateImpl(...).
6241   ChangeStatus updateImpl(Attributor &A) override {
6242     // Byval is only replacable if it is readonly otherwise we would write into
6243     // the replaced value and not the copy that byval creates implicitly.
6244     Argument *Arg = getAssociatedArgument();
6245     if (Arg->hasByValAttr()) {
6246       // TODO: We probably need to verify synchronization is not an issue, e.g.,
6247       //       there is no race by not copying a constant byval.
6248       bool IsKnown;
6249       if (!AA::isAssumedReadOnly(A, getIRPosition(), *this, IsKnown))
6250         return indicatePessimisticFixpoint();
6251     }
6252 
6253     auto Before = SimplifiedAssociatedValue;
6254 
6255     auto PredForCallSite = [&](AbstractCallSite ACS) {
6256       const IRPosition &ACSArgPos =
6257           IRPosition::callsite_argument(ACS, getCallSiteArgNo());
6258       // Check if a coresponding argument was found or if it is on not
6259       // associated (which can happen for callback calls).
6260       if (ACSArgPos.getPositionKind() == IRPosition::IRP_INVALID)
6261         return false;
6262 
6263       // Simplify the argument operand explicitly and check if the result is
6264       // valid in the current scope. This avoids refering to simplified values
6265       // in other functions, e.g., we don't want to say a an argument in a
6266       // static function is actually an argument in a different function.
6267       bool UsedAssumedInformation = false;
6268       std::optional<Constant *> SimpleArgOp =
6269           A.getAssumedConstant(ACSArgPos, *this, UsedAssumedInformation);
6270       if (!SimpleArgOp)
6271         return true;
6272       if (!*SimpleArgOp)
6273         return false;
6274       if (!AA::isDynamicallyUnique(A, *this, **SimpleArgOp))
6275         return false;
6276       return unionAssumed(*SimpleArgOp);
6277     };
6278 
6279     // Generate a answer specific to a call site context.
6280     bool Success;
6281     bool UsedAssumedInformation = false;
6282     if (hasCallBaseContext() &&
6283         getCallBaseContext()->getCalledFunction() == Arg->getParent())
6284       Success = PredForCallSite(
6285           AbstractCallSite(&getCallBaseContext()->getCalledOperandUse()));
6286     else
6287       Success = A.checkForAllCallSites(PredForCallSite, *this, true,
6288                                        UsedAssumedInformation);
6289 
6290     if (!Success)
6291       if (!askSimplifiedValueForOtherAAs(A))
6292         return indicatePessimisticFixpoint();
6293 
6294     // If a candidate was found in this update, return CHANGED.
6295     return Before == SimplifiedAssociatedValue ? ChangeStatus::UNCHANGED
6296                                                : ChangeStatus ::CHANGED;
6297   }
6298 
6299   /// See AbstractAttribute::trackStatistics()
6300   void trackStatistics() const override {
6301     STATS_DECLTRACK_ARG_ATTR(value_simplify)
6302   }
6303 };
6304 
6305 struct AAValueSimplifyReturned : AAValueSimplifyImpl {
6306   AAValueSimplifyReturned(const IRPosition &IRP, Attributor &A)
6307       : AAValueSimplifyImpl(IRP, A) {}
6308 
6309   /// See AAValueSimplify::getAssumedSimplifiedValue()
6310   std::optional<Value *>
6311   getAssumedSimplifiedValue(Attributor &A) const override {
6312     if (!isValidState())
6313       return nullptr;
6314     return SimplifiedAssociatedValue;
6315   }
6316 
6317   /// See AbstractAttribute::updateImpl(...).
6318   ChangeStatus updateImpl(Attributor &A) override {
6319     auto Before = SimplifiedAssociatedValue;
6320 
6321     auto ReturnInstCB = [&](Instruction &I) {
6322       auto &RI = cast<ReturnInst>(I);
6323       return checkAndUpdate(
6324           A, *this,
6325           IRPosition::value(*RI.getReturnValue(), getCallBaseContext()));
6326     };
6327 
6328     bool UsedAssumedInformation = false;
6329     if (!A.checkForAllInstructions(ReturnInstCB, *this, {Instruction::Ret},
6330                                    UsedAssumedInformation))
6331       if (!askSimplifiedValueForOtherAAs(A))
6332         return indicatePessimisticFixpoint();
6333 
6334     // If a candidate was found in this update, return CHANGED.
6335     return Before == SimplifiedAssociatedValue ? ChangeStatus::UNCHANGED
6336                                                : ChangeStatus ::CHANGED;
6337   }
6338 
6339   ChangeStatus manifest(Attributor &A) override {
6340     // We queried AAValueSimplify for the returned values so they will be
6341     // replaced if a simplified form was found. Nothing to do here.
6342     return ChangeStatus::UNCHANGED;
6343   }
6344 
6345   /// See AbstractAttribute::trackStatistics()
6346   void trackStatistics() const override {
6347     STATS_DECLTRACK_FNRET_ATTR(value_simplify)
6348   }
6349 };
6350 
6351 struct AAValueSimplifyFloating : AAValueSimplifyImpl {
6352   AAValueSimplifyFloating(const IRPosition &IRP, Attributor &A)
6353       : AAValueSimplifyImpl(IRP, A) {}
6354 
6355   /// See AbstractAttribute::initialize(...).
6356   void initialize(Attributor &A) override {
6357     AAValueSimplifyImpl::initialize(A);
6358     Value &V = getAnchorValue();
6359 
6360     // TODO: add other stuffs
6361     if (isa<Constant>(V))
6362       indicatePessimisticFixpoint();
6363   }
6364 
6365   /// See AbstractAttribute::updateImpl(...).
6366   ChangeStatus updateImpl(Attributor &A) override {
6367     auto Before = SimplifiedAssociatedValue;
6368     if (!askSimplifiedValueForOtherAAs(A))
6369       return indicatePessimisticFixpoint();
6370 
6371     // If a candidate was found in this update, return CHANGED.
6372     return Before == SimplifiedAssociatedValue ? ChangeStatus::UNCHANGED
6373                                                : ChangeStatus ::CHANGED;
6374   }
6375 
6376   /// See AbstractAttribute::trackStatistics()
6377   void trackStatistics() const override {
6378     STATS_DECLTRACK_FLOATING_ATTR(value_simplify)
6379   }
6380 };
6381 
6382 struct AAValueSimplifyFunction : AAValueSimplifyImpl {
6383   AAValueSimplifyFunction(const IRPosition &IRP, Attributor &A)
6384       : AAValueSimplifyImpl(IRP, A) {}
6385 
6386   /// See AbstractAttribute::initialize(...).
6387   void initialize(Attributor &A) override {
6388     SimplifiedAssociatedValue = nullptr;
6389     indicateOptimisticFixpoint();
6390   }
6391   /// See AbstractAttribute::initialize(...).
6392   ChangeStatus updateImpl(Attributor &A) override {
6393     llvm_unreachable(
6394         "AAValueSimplify(Function|CallSite)::updateImpl will not be called");
6395   }
6396   /// See AbstractAttribute::trackStatistics()
6397   void trackStatistics() const override {
6398     STATS_DECLTRACK_FN_ATTR(value_simplify)
6399   }
6400 };
6401 
6402 struct AAValueSimplifyCallSite : AAValueSimplifyFunction {
6403   AAValueSimplifyCallSite(const IRPosition &IRP, Attributor &A)
6404       : AAValueSimplifyFunction(IRP, A) {}
6405   /// See AbstractAttribute::trackStatistics()
6406   void trackStatistics() const override {
6407     STATS_DECLTRACK_CS_ATTR(value_simplify)
6408   }
6409 };
6410 
6411 struct AAValueSimplifyCallSiteReturned : AAValueSimplifyImpl {
6412   AAValueSimplifyCallSiteReturned(const IRPosition &IRP, Attributor &A)
6413       : AAValueSimplifyImpl(IRP, A) {}
6414 
6415   void initialize(Attributor &A) override {
6416     AAValueSimplifyImpl::initialize(A);
6417     Function *Fn = getAssociatedFunction();
6418     if (!Fn) {
6419       indicatePessimisticFixpoint();
6420       return;
6421     }
6422     for (Argument &Arg : Fn->args()) {
6423       if (Arg.hasReturnedAttr()) {
6424         auto IRP = IRPosition::callsite_argument(*cast<CallBase>(getCtxI()),
6425                                                  Arg.getArgNo());
6426         if (IRP.getPositionKind() == IRPosition::IRP_CALL_SITE_ARGUMENT &&
6427             checkAndUpdate(A, *this, IRP))
6428           indicateOptimisticFixpoint();
6429         else
6430           indicatePessimisticFixpoint();
6431         return;
6432       }
6433     }
6434   }
6435 
6436   /// See AbstractAttribute::updateImpl(...).
6437   ChangeStatus updateImpl(Attributor &A) override {
6438     auto Before = SimplifiedAssociatedValue;
6439     auto &RetAA = A.getAAFor<AAReturnedValues>(
6440         *this, IRPosition::function(*getAssociatedFunction()),
6441         DepClassTy::REQUIRED);
6442     auto PredForReturned =
6443         [&](Value &RetVal, const SmallSetVector<ReturnInst *, 4> &RetInsts) {
6444           bool UsedAssumedInformation = false;
6445           std::optional<Value *> CSRetVal =
6446               A.translateArgumentToCallSiteContent(
6447                   &RetVal, *cast<CallBase>(getCtxI()), *this,
6448                   UsedAssumedInformation);
6449           SimplifiedAssociatedValue = AA::combineOptionalValuesInAAValueLatice(
6450               SimplifiedAssociatedValue, CSRetVal, getAssociatedType());
6451           return SimplifiedAssociatedValue != std::optional<Value *>(nullptr);
6452         };
6453     if (!RetAA.checkForAllReturnedValuesAndReturnInsts(PredForReturned))
6454       if (!askSimplifiedValueForOtherAAs(A))
6455         return indicatePessimisticFixpoint();
6456     return Before == SimplifiedAssociatedValue ? ChangeStatus::UNCHANGED
6457                                                : ChangeStatus ::CHANGED;
6458   }
6459 
6460   void trackStatistics() const override {
6461     STATS_DECLTRACK_CSRET_ATTR(value_simplify)
6462   }
6463 };
6464 
6465 struct AAValueSimplifyCallSiteArgument : AAValueSimplifyFloating {
6466   AAValueSimplifyCallSiteArgument(const IRPosition &IRP, Attributor &A)
6467       : AAValueSimplifyFloating(IRP, A) {}
6468 
6469   /// See AbstractAttribute::manifest(...).
6470   ChangeStatus manifest(Attributor &A) override {
6471     ChangeStatus Changed = ChangeStatus::UNCHANGED;
6472     // TODO: We should avoid simplification duplication to begin with.
6473     auto *FloatAA = A.lookupAAFor<AAValueSimplify>(
6474         IRPosition::value(getAssociatedValue()), this, DepClassTy::NONE);
6475     if (FloatAA && FloatAA->getState().isValidState())
6476       return Changed;
6477 
6478     if (auto *NewV = manifestReplacementValue(A, getCtxI())) {
6479       Use &U = cast<CallBase>(&getAnchorValue())
6480                    ->getArgOperandUse(getCallSiteArgNo());
6481       if (A.changeUseAfterManifest(U, *NewV))
6482         Changed = ChangeStatus::CHANGED;
6483     }
6484 
6485     return Changed | AAValueSimplify::manifest(A);
6486   }
6487 
6488   void trackStatistics() const override {
6489     STATS_DECLTRACK_CSARG_ATTR(value_simplify)
6490   }
6491 };
6492 } // namespace
6493 
6494 /// ----------------------- Heap-To-Stack Conversion ---------------------------
6495 namespace {
6496 struct AAHeapToStackFunction final : public AAHeapToStack {
6497 
6498   struct AllocationInfo {
6499     /// The call that allocates the memory.
6500     CallBase *const CB;
6501 
6502     /// The library function id for the allocation.
6503     LibFunc LibraryFunctionId = NotLibFunc;
6504 
6505     /// The status wrt. a rewrite.
6506     enum {
6507       STACK_DUE_TO_USE,
6508       STACK_DUE_TO_FREE,
6509       INVALID,
6510     } Status = STACK_DUE_TO_USE;
6511 
6512     /// Flag to indicate if we encountered a use that might free this allocation
6513     /// but which is not in the deallocation infos.
6514     bool HasPotentiallyFreeingUnknownUses = false;
6515 
6516     /// Flag to indicate that we should place the new alloca in the function
6517     /// entry block rather than where the call site (CB) is.
6518     bool MoveAllocaIntoEntry = true;
6519 
6520     /// The set of free calls that use this allocation.
6521     SmallSetVector<CallBase *, 1> PotentialFreeCalls{};
6522   };
6523 
6524   struct DeallocationInfo {
6525     /// The call that deallocates the memory.
6526     CallBase *const CB;
6527     /// The value freed by the call.
6528     Value *FreedOp;
6529 
6530     /// Flag to indicate if we don't know all objects this deallocation might
6531     /// free.
6532     bool MightFreeUnknownObjects = false;
6533 
6534     /// The set of allocation calls that are potentially freed.
6535     SmallSetVector<CallBase *, 1> PotentialAllocationCalls{};
6536   };
6537 
6538   AAHeapToStackFunction(const IRPosition &IRP, Attributor &A)
6539       : AAHeapToStack(IRP, A) {}
6540 
6541   ~AAHeapToStackFunction() {
6542     // Ensure we call the destructor so we release any memory allocated in the
6543     // sets.
6544     for (auto &It : AllocationInfos)
6545       It.second->~AllocationInfo();
6546     for (auto &It : DeallocationInfos)
6547       It.second->~DeallocationInfo();
6548   }
6549 
6550   void initialize(Attributor &A) override {
6551     AAHeapToStack::initialize(A);
6552 
6553     const Function *F = getAnchorScope();
6554     const auto *TLI = A.getInfoCache().getTargetLibraryInfoForFunction(*F);
6555 
6556     auto AllocationIdentifierCB = [&](Instruction &I) {
6557       CallBase *CB = dyn_cast<CallBase>(&I);
6558       if (!CB)
6559         return true;
6560       if (Value *FreedOp = getFreedOperand(CB, TLI)) {
6561         DeallocationInfos[CB] = new (A.Allocator) DeallocationInfo{CB, FreedOp};
6562         return true;
6563       }
6564       // To do heap to stack, we need to know that the allocation itself is
6565       // removable once uses are rewritten, and that we can initialize the
6566       // alloca to the same pattern as the original allocation result.
6567       if (isRemovableAlloc(CB, TLI)) {
6568         auto *I8Ty = Type::getInt8Ty(CB->getParent()->getContext());
6569         if (nullptr != getInitialValueOfAllocation(CB, TLI, I8Ty)) {
6570           AllocationInfo *AI = new (A.Allocator) AllocationInfo{CB};
6571           AllocationInfos[CB] = AI;
6572           if (TLI)
6573             TLI->getLibFunc(*CB, AI->LibraryFunctionId);
6574         }
6575       }
6576       return true;
6577     };
6578 
6579     bool UsedAssumedInformation = false;
6580     bool Success = A.checkForAllCallLikeInstructions(
6581         AllocationIdentifierCB, *this, UsedAssumedInformation,
6582         /* CheckBBLivenessOnly */ false,
6583         /* CheckPotentiallyDead */ true);
6584     (void)Success;
6585     assert(Success && "Did not expect the call base visit callback to fail!");
6586 
6587     Attributor::SimplifictionCallbackTy SCB =
6588         [](const IRPosition &, const AbstractAttribute *,
6589            bool &) -> std::optional<Value *> { return nullptr; };
6590     for (const auto &It : AllocationInfos)
6591       A.registerSimplificationCallback(IRPosition::callsite_returned(*It.first),
6592                                        SCB);
6593     for (const auto &It : DeallocationInfos)
6594       A.registerSimplificationCallback(IRPosition::callsite_returned(*It.first),
6595                                        SCB);
6596   }
6597 
6598   const std::string getAsStr() const override {
6599     unsigned NumH2SMallocs = 0, NumInvalidMallocs = 0;
6600     for (const auto &It : AllocationInfos) {
6601       if (It.second->Status == AllocationInfo::INVALID)
6602         ++NumInvalidMallocs;
6603       else
6604         ++NumH2SMallocs;
6605     }
6606     return "[H2S] Mallocs Good/Bad: " + std::to_string(NumH2SMallocs) + "/" +
6607            std::to_string(NumInvalidMallocs);
6608   }
6609 
6610   /// See AbstractAttribute::trackStatistics().
6611   void trackStatistics() const override {
6612     STATS_DECL(
6613         MallocCalls, Function,
6614         "Number of malloc/calloc/aligned_alloc calls converted to allocas");
6615     for (const auto &It : AllocationInfos)
6616       if (It.second->Status != AllocationInfo::INVALID)
6617         ++BUILD_STAT_NAME(MallocCalls, Function);
6618   }
6619 
6620   bool isAssumedHeapToStack(const CallBase &CB) const override {
6621     if (isValidState())
6622       if (AllocationInfo *AI =
6623               AllocationInfos.lookup(const_cast<CallBase *>(&CB)))
6624         return AI->Status != AllocationInfo::INVALID;
6625     return false;
6626   }
6627 
6628   bool isAssumedHeapToStackRemovedFree(CallBase &CB) const override {
6629     if (!isValidState())
6630       return false;
6631 
6632     for (const auto &It : AllocationInfos) {
6633       AllocationInfo &AI = *It.second;
6634       if (AI.Status == AllocationInfo::INVALID)
6635         continue;
6636 
6637       if (AI.PotentialFreeCalls.count(&CB))
6638         return true;
6639     }
6640 
6641     return false;
6642   }
6643 
6644   ChangeStatus manifest(Attributor &A) override {
6645     assert(getState().isValidState() &&
6646            "Attempted to manifest an invalid state!");
6647 
6648     ChangeStatus HasChanged = ChangeStatus::UNCHANGED;
6649     Function *F = getAnchorScope();
6650     const auto *TLI = A.getInfoCache().getTargetLibraryInfoForFunction(*F);
6651 
6652     for (auto &It : AllocationInfos) {
6653       AllocationInfo &AI = *It.second;
6654       if (AI.Status == AllocationInfo::INVALID)
6655         continue;
6656 
6657       for (CallBase *FreeCall : AI.PotentialFreeCalls) {
6658         LLVM_DEBUG(dbgs() << "H2S: Removing free call: " << *FreeCall << "\n");
6659         A.deleteAfterManifest(*FreeCall);
6660         HasChanged = ChangeStatus::CHANGED;
6661       }
6662 
6663       LLVM_DEBUG(dbgs() << "H2S: Removing malloc-like call: " << *AI.CB
6664                         << "\n");
6665 
6666       auto Remark = [&](OptimizationRemark OR) {
6667         LibFunc IsAllocShared;
6668         if (TLI->getLibFunc(*AI.CB, IsAllocShared))
6669           if (IsAllocShared == LibFunc___kmpc_alloc_shared)
6670             return OR << "Moving globalized variable to the stack.";
6671         return OR << "Moving memory allocation from the heap to the stack.";
6672       };
6673       if (AI.LibraryFunctionId == LibFunc___kmpc_alloc_shared)
6674         A.emitRemark<OptimizationRemark>(AI.CB, "OMP110", Remark);
6675       else
6676         A.emitRemark<OptimizationRemark>(AI.CB, "HeapToStack", Remark);
6677 
6678       const DataLayout &DL = A.getInfoCache().getDL();
6679       Value *Size;
6680       std::optional<APInt> SizeAPI = getSize(A, *this, AI);
6681       if (SizeAPI) {
6682         Size = ConstantInt::get(AI.CB->getContext(), *SizeAPI);
6683       } else {
6684         LLVMContext &Ctx = AI.CB->getContext();
6685         ObjectSizeOpts Opts;
6686         ObjectSizeOffsetEvaluator Eval(DL, TLI, Ctx, Opts);
6687         SizeOffsetEvalType SizeOffsetPair = Eval.compute(AI.CB);
6688         assert(SizeOffsetPair != ObjectSizeOffsetEvaluator::unknown() &&
6689                cast<ConstantInt>(SizeOffsetPair.second)->isZero());
6690         Size = SizeOffsetPair.first;
6691       }
6692 
6693       Instruction *IP =
6694           AI.MoveAllocaIntoEntry ? &F->getEntryBlock().front() : AI.CB;
6695 
6696       Align Alignment(1);
6697       if (MaybeAlign RetAlign = AI.CB->getRetAlign())
6698         Alignment = std::max(Alignment, *RetAlign);
6699       if (Value *Align = getAllocAlignment(AI.CB, TLI)) {
6700         std::optional<APInt> AlignmentAPI = getAPInt(A, *this, *Align);
6701         assert(AlignmentAPI && AlignmentAPI->getZExtValue() > 0 &&
6702                "Expected an alignment during manifest!");
6703         Alignment =
6704             std::max(Alignment, assumeAligned(AlignmentAPI->getZExtValue()));
6705       }
6706 
6707       // TODO: Hoist the alloca towards the function entry.
6708       unsigned AS = DL.getAllocaAddrSpace();
6709       Instruction *Alloca =
6710           new AllocaInst(Type::getInt8Ty(F->getContext()), AS, Size, Alignment,
6711                          AI.CB->getName() + ".h2s", IP);
6712 
6713       if (Alloca->getType() != AI.CB->getType())
6714         Alloca = BitCastInst::CreatePointerBitCastOrAddrSpaceCast(
6715             Alloca, AI.CB->getType(), "malloc_cast", AI.CB);
6716 
6717       auto *I8Ty = Type::getInt8Ty(F->getContext());
6718       auto *InitVal = getInitialValueOfAllocation(AI.CB, TLI, I8Ty);
6719       assert(InitVal &&
6720              "Must be able to materialize initial memory state of allocation");
6721 
6722       A.changeAfterManifest(IRPosition::inst(*AI.CB), *Alloca);
6723 
6724       if (auto *II = dyn_cast<InvokeInst>(AI.CB)) {
6725         auto *NBB = II->getNormalDest();
6726         BranchInst::Create(NBB, AI.CB->getParent());
6727         A.deleteAfterManifest(*AI.CB);
6728       } else {
6729         A.deleteAfterManifest(*AI.CB);
6730       }
6731 
6732       // Initialize the alloca with the same value as used by the allocation
6733       // function.  We can skip undef as the initial value of an alloc is
6734       // undef, and the memset would simply end up being DSEd.
6735       if (!isa<UndefValue>(InitVal)) {
6736         IRBuilder<> Builder(Alloca->getNextNode());
6737         // TODO: Use alignment above if align!=1
6738         Builder.CreateMemSet(Alloca, InitVal, Size, std::nullopt);
6739       }
6740       HasChanged = ChangeStatus::CHANGED;
6741     }
6742 
6743     return HasChanged;
6744   }
6745 
6746   std::optional<APInt> getAPInt(Attributor &A, const AbstractAttribute &AA,
6747                                 Value &V) {
6748     bool UsedAssumedInformation = false;
6749     std::optional<Constant *> SimpleV =
6750         A.getAssumedConstant(V, AA, UsedAssumedInformation);
6751     if (!SimpleV)
6752       return APInt(64, 0);
6753     if (auto *CI = dyn_cast_or_null<ConstantInt>(*SimpleV))
6754       return CI->getValue();
6755     return std::nullopt;
6756   }
6757 
6758   std::optional<APInt> getSize(Attributor &A, const AbstractAttribute &AA,
6759                                AllocationInfo &AI) {
6760     auto Mapper = [&](const Value *V) -> const Value * {
6761       bool UsedAssumedInformation = false;
6762       if (std::optional<Constant *> SimpleV =
6763               A.getAssumedConstant(*V, AA, UsedAssumedInformation))
6764         if (*SimpleV)
6765           return *SimpleV;
6766       return V;
6767     };
6768 
6769     const Function *F = getAnchorScope();
6770     const auto *TLI = A.getInfoCache().getTargetLibraryInfoForFunction(*F);
6771     return getAllocSize(AI.CB, TLI, Mapper);
6772   }
6773 
6774   /// Collection of all malloc-like calls in a function with associated
6775   /// information.
6776   MapVector<CallBase *, AllocationInfo *> AllocationInfos;
6777 
6778   /// Collection of all free-like calls in a function with associated
6779   /// information.
6780   MapVector<CallBase *, DeallocationInfo *> DeallocationInfos;
6781 
6782   ChangeStatus updateImpl(Attributor &A) override;
6783 };
6784 
6785 ChangeStatus AAHeapToStackFunction::updateImpl(Attributor &A) {
6786   ChangeStatus Changed = ChangeStatus::UNCHANGED;
6787   const Function *F = getAnchorScope();
6788   const auto *TLI = A.getInfoCache().getTargetLibraryInfoForFunction(*F);
6789 
6790   const auto &LivenessAA =
6791       A.getAAFor<AAIsDead>(*this, IRPosition::function(*F), DepClassTy::NONE);
6792 
6793   MustBeExecutedContextExplorer &Explorer =
6794       A.getInfoCache().getMustBeExecutedContextExplorer();
6795 
6796   bool StackIsAccessibleByOtherThreads =
6797       A.getInfoCache().stackIsAccessibleByOtherThreads();
6798 
6799   LoopInfo *LI =
6800       A.getInfoCache().getAnalysisResultForFunction<LoopAnalysis>(*F);
6801   std::optional<bool> MayContainIrreducibleControl;
6802   auto IsInLoop = [&](BasicBlock &BB) {
6803     if (&F->getEntryBlock() == &BB)
6804       return false;
6805     if (!MayContainIrreducibleControl.has_value())
6806       MayContainIrreducibleControl = mayContainIrreducibleControl(*F, LI);
6807     if (*MayContainIrreducibleControl)
6808       return true;
6809     if (!LI)
6810       return true;
6811     return LI->getLoopFor(&BB) != nullptr;
6812   };
6813 
6814   // Flag to ensure we update our deallocation information at most once per
6815   // updateImpl call and only if we use the free check reasoning.
6816   bool HasUpdatedFrees = false;
6817 
6818   auto UpdateFrees = [&]() {
6819     HasUpdatedFrees = true;
6820 
6821     for (auto &It : DeallocationInfos) {
6822       DeallocationInfo &DI = *It.second;
6823       // For now we cannot use deallocations that have unknown inputs, skip
6824       // them.
6825       if (DI.MightFreeUnknownObjects)
6826         continue;
6827 
6828       // No need to analyze dead calls, ignore them instead.
6829       bool UsedAssumedInformation = false;
6830       if (A.isAssumedDead(*DI.CB, this, &LivenessAA, UsedAssumedInformation,
6831                           /* CheckBBLivenessOnly */ true))
6832         continue;
6833 
6834       // Use the non-optimistic version to get the freed object.
6835       Value *Obj = getUnderlyingObject(DI.FreedOp);
6836       if (!Obj) {
6837         LLVM_DEBUG(dbgs() << "[H2S] Unknown underlying object for free!\n");
6838         DI.MightFreeUnknownObjects = true;
6839         continue;
6840       }
6841 
6842       // Free of null and undef can be ignored as no-ops (or UB in the latter
6843       // case).
6844       if (isa<ConstantPointerNull>(Obj) || isa<UndefValue>(Obj))
6845         continue;
6846 
6847       CallBase *ObjCB = dyn_cast<CallBase>(Obj);
6848       if (!ObjCB) {
6849         LLVM_DEBUG(dbgs() << "[H2S] Free of a non-call object: " << *Obj
6850                           << "\n");
6851         DI.MightFreeUnknownObjects = true;
6852         continue;
6853       }
6854 
6855       AllocationInfo *AI = AllocationInfos.lookup(ObjCB);
6856       if (!AI) {
6857         LLVM_DEBUG(dbgs() << "[H2S] Free of a non-allocation object: " << *Obj
6858                           << "\n");
6859         DI.MightFreeUnknownObjects = true;
6860         continue;
6861       }
6862 
6863       DI.PotentialAllocationCalls.insert(ObjCB);
6864     }
6865   };
6866 
6867   auto FreeCheck = [&](AllocationInfo &AI) {
6868     // If the stack is not accessible by other threads, the "must-free" logic
6869     // doesn't apply as the pointer could be shared and needs to be places in
6870     // "shareable" memory.
6871     if (!StackIsAccessibleByOtherThreads) {
6872       auto &NoSyncAA =
6873           A.getAAFor<AANoSync>(*this, getIRPosition(), DepClassTy::OPTIONAL);
6874       if (!NoSyncAA.isAssumedNoSync()) {
6875         LLVM_DEBUG(
6876             dbgs() << "[H2S] found an escaping use, stack is not accessible by "
6877                       "other threads and function is not nosync:\n");
6878         return false;
6879       }
6880     }
6881     if (!HasUpdatedFrees)
6882       UpdateFrees();
6883 
6884     // TODO: Allow multi exit functions that have different free calls.
6885     if (AI.PotentialFreeCalls.size() != 1) {
6886       LLVM_DEBUG(dbgs() << "[H2S] did not find one free call but "
6887                         << AI.PotentialFreeCalls.size() << "\n");
6888       return false;
6889     }
6890     CallBase *UniqueFree = *AI.PotentialFreeCalls.begin();
6891     DeallocationInfo *DI = DeallocationInfos.lookup(UniqueFree);
6892     if (!DI) {
6893       LLVM_DEBUG(
6894           dbgs() << "[H2S] unique free call was not known as deallocation call "
6895                  << *UniqueFree << "\n");
6896       return false;
6897     }
6898     if (DI->MightFreeUnknownObjects) {
6899       LLVM_DEBUG(
6900           dbgs() << "[H2S] unique free call might free unknown allocations\n");
6901       return false;
6902     }
6903     if (DI->PotentialAllocationCalls.empty())
6904       return true;
6905     if (DI->PotentialAllocationCalls.size() > 1) {
6906       LLVM_DEBUG(dbgs() << "[H2S] unique free call might free "
6907                         << DI->PotentialAllocationCalls.size()
6908                         << " different allocations\n");
6909       return false;
6910     }
6911     if (*DI->PotentialAllocationCalls.begin() != AI.CB) {
6912       LLVM_DEBUG(
6913           dbgs()
6914           << "[H2S] unique free call not known to free this allocation but "
6915           << **DI->PotentialAllocationCalls.begin() << "\n");
6916       return false;
6917     }
6918     Instruction *CtxI = isa<InvokeInst>(AI.CB) ? AI.CB : AI.CB->getNextNode();
6919     if (!Explorer.findInContextOf(UniqueFree, CtxI)) {
6920       LLVM_DEBUG(
6921           dbgs()
6922           << "[H2S] unique free call might not be executed with the allocation "
6923           << *UniqueFree << "\n");
6924       return false;
6925     }
6926     return true;
6927   };
6928 
6929   auto UsesCheck = [&](AllocationInfo &AI) {
6930     bool ValidUsesOnly = true;
6931 
6932     auto Pred = [&](const Use &U, bool &Follow) -> bool {
6933       Instruction *UserI = cast<Instruction>(U.getUser());
6934       if (isa<LoadInst>(UserI))
6935         return true;
6936       if (auto *SI = dyn_cast<StoreInst>(UserI)) {
6937         if (SI->getValueOperand() == U.get()) {
6938           LLVM_DEBUG(dbgs()
6939                      << "[H2S] escaping store to memory: " << *UserI << "\n");
6940           ValidUsesOnly = false;
6941         } else {
6942           // A store into the malloc'ed memory is fine.
6943         }
6944         return true;
6945       }
6946       if (auto *CB = dyn_cast<CallBase>(UserI)) {
6947         if (!CB->isArgOperand(&U) || CB->isLifetimeStartOrEnd())
6948           return true;
6949         if (DeallocationInfos.count(CB)) {
6950           AI.PotentialFreeCalls.insert(CB);
6951           return true;
6952         }
6953 
6954         unsigned ArgNo = CB->getArgOperandNo(&U);
6955 
6956         const auto &NoCaptureAA = A.getAAFor<AANoCapture>(
6957             *this, IRPosition::callsite_argument(*CB, ArgNo),
6958             DepClassTy::OPTIONAL);
6959 
6960         // If a call site argument use is nofree, we are fine.
6961         const auto &ArgNoFreeAA = A.getAAFor<AANoFree>(
6962             *this, IRPosition::callsite_argument(*CB, ArgNo),
6963             DepClassTy::OPTIONAL);
6964 
6965         bool MaybeCaptured = !NoCaptureAA.isAssumedNoCapture();
6966         bool MaybeFreed = !ArgNoFreeAA.isAssumedNoFree();
6967         if (MaybeCaptured ||
6968             (AI.LibraryFunctionId != LibFunc___kmpc_alloc_shared &&
6969              MaybeFreed)) {
6970           AI.HasPotentiallyFreeingUnknownUses |= MaybeFreed;
6971 
6972           // Emit a missed remark if this is missed OpenMP globalization.
6973           auto Remark = [&](OptimizationRemarkMissed ORM) {
6974             return ORM
6975                    << "Could not move globalized variable to the stack. "
6976                       "Variable is potentially captured in call. Mark "
6977                       "parameter as `__attribute__((noescape))` to override.";
6978           };
6979 
6980           if (ValidUsesOnly &&
6981               AI.LibraryFunctionId == LibFunc___kmpc_alloc_shared)
6982             A.emitRemark<OptimizationRemarkMissed>(CB, "OMP113", Remark);
6983 
6984           LLVM_DEBUG(dbgs() << "[H2S] Bad user: " << *UserI << "\n");
6985           ValidUsesOnly = false;
6986         }
6987         return true;
6988       }
6989 
6990       if (isa<GetElementPtrInst>(UserI) || isa<BitCastInst>(UserI) ||
6991           isa<PHINode>(UserI) || isa<SelectInst>(UserI)) {
6992         Follow = true;
6993         return true;
6994       }
6995       // Unknown user for which we can not track uses further (in a way that
6996       // makes sense).
6997       LLVM_DEBUG(dbgs() << "[H2S] Unknown user: " << *UserI << "\n");
6998       ValidUsesOnly = false;
6999       return true;
7000     };
7001     if (!A.checkForAllUses(Pred, *this, *AI.CB))
7002       return false;
7003     return ValidUsesOnly;
7004   };
7005 
7006   // The actual update starts here. We look at all allocations and depending on
7007   // their status perform the appropriate check(s).
7008   for (auto &It : AllocationInfos) {
7009     AllocationInfo &AI = *It.second;
7010     if (AI.Status == AllocationInfo::INVALID)
7011       continue;
7012 
7013     if (Value *Align = getAllocAlignment(AI.CB, TLI)) {
7014       std::optional<APInt> APAlign = getAPInt(A, *this, *Align);
7015       if (!APAlign) {
7016         // Can't generate an alloca which respects the required alignment
7017         // on the allocation.
7018         LLVM_DEBUG(dbgs() << "[H2S] Unknown allocation alignment: " << *AI.CB
7019                           << "\n");
7020         AI.Status = AllocationInfo::INVALID;
7021         Changed = ChangeStatus::CHANGED;
7022         continue;
7023       }
7024       if (APAlign->ugt(llvm::Value::MaximumAlignment) ||
7025           !APAlign->isPowerOf2()) {
7026         LLVM_DEBUG(dbgs() << "[H2S] Invalid allocation alignment: " << APAlign
7027                           << "\n");
7028         AI.Status = AllocationInfo::INVALID;
7029         Changed = ChangeStatus::CHANGED;
7030         continue;
7031       }
7032     }
7033 
7034     std::optional<APInt> Size = getSize(A, *this, AI);
7035     if (MaxHeapToStackSize != -1) {
7036       if (!Size || Size->ugt(MaxHeapToStackSize)) {
7037         LLVM_DEBUG({
7038           if (!Size)
7039             dbgs() << "[H2S] Unknown allocation size: " << *AI.CB << "\n";
7040           else
7041             dbgs() << "[H2S] Allocation size too large: " << *AI.CB << " vs. "
7042                    << MaxHeapToStackSize << "\n";
7043         });
7044 
7045         AI.Status = AllocationInfo::INVALID;
7046         Changed = ChangeStatus::CHANGED;
7047         continue;
7048       }
7049     }
7050 
7051     switch (AI.Status) {
7052     case AllocationInfo::STACK_DUE_TO_USE:
7053       if (UsesCheck(AI))
7054         break;
7055       AI.Status = AllocationInfo::STACK_DUE_TO_FREE;
7056       [[fallthrough]];
7057     case AllocationInfo::STACK_DUE_TO_FREE:
7058       if (FreeCheck(AI))
7059         break;
7060       AI.Status = AllocationInfo::INVALID;
7061       Changed = ChangeStatus::CHANGED;
7062       break;
7063     case AllocationInfo::INVALID:
7064       llvm_unreachable("Invalid allocations should never reach this point!");
7065     };
7066 
7067     // Check if we still think we can move it into the entry block. If the
7068     // alloca comes from a converted __kmpc_alloc_shared then we can usually
7069     // ignore the potential compilations associated with loops.
7070     bool IsGlobalizedLocal =
7071         AI.LibraryFunctionId == LibFunc___kmpc_alloc_shared;
7072     if (AI.MoveAllocaIntoEntry &&
7073         (!Size.has_value() ||
7074          (!IsGlobalizedLocal && IsInLoop(*AI.CB->getParent()))))
7075       AI.MoveAllocaIntoEntry = false;
7076   }
7077 
7078   return Changed;
7079 }
7080 } // namespace
7081 
7082 /// ----------------------- Privatizable Pointers ------------------------------
7083 namespace {
7084 struct AAPrivatizablePtrImpl : public AAPrivatizablePtr {
7085   AAPrivatizablePtrImpl(const IRPosition &IRP, Attributor &A)
7086       : AAPrivatizablePtr(IRP, A), PrivatizableType(std::nullopt) {}
7087 
7088   ChangeStatus indicatePessimisticFixpoint() override {
7089     AAPrivatizablePtr::indicatePessimisticFixpoint();
7090     PrivatizableType = nullptr;
7091     return ChangeStatus::CHANGED;
7092   }
7093 
7094   /// Identify the type we can chose for a private copy of the underlying
7095   /// argument. None means it is not clear yet, nullptr means there is none.
7096   virtual std::optional<Type *> identifyPrivatizableType(Attributor &A) = 0;
7097 
7098   /// Return a privatizable type that encloses both T0 and T1.
7099   /// TODO: This is merely a stub for now as we should manage a mapping as well.
7100   std::optional<Type *> combineTypes(std::optional<Type *> T0,
7101                                      std::optional<Type *> T1) {
7102     if (!T0)
7103       return T1;
7104     if (!T1)
7105       return T0;
7106     if (T0 == T1)
7107       return T0;
7108     return nullptr;
7109   }
7110 
7111   std::optional<Type *> getPrivatizableType() const override {
7112     return PrivatizableType;
7113   }
7114 
7115   const std::string getAsStr() const override {
7116     return isAssumedPrivatizablePtr() ? "[priv]" : "[no-priv]";
7117   }
7118 
7119 protected:
7120   std::optional<Type *> PrivatizableType;
7121 };
7122 
7123 // TODO: Do this for call site arguments (probably also other values) as well.
7124 
7125 struct AAPrivatizablePtrArgument final : public AAPrivatizablePtrImpl {
7126   AAPrivatizablePtrArgument(const IRPosition &IRP, Attributor &A)
7127       : AAPrivatizablePtrImpl(IRP, A) {}
7128 
7129   /// See AAPrivatizablePtrImpl::identifyPrivatizableType(...)
7130   std::optional<Type *> identifyPrivatizableType(Attributor &A) override {
7131     // If this is a byval argument and we know all the call sites (so we can
7132     // rewrite them), there is no need to check them explicitly.
7133     bool UsedAssumedInformation = false;
7134     SmallVector<Attribute, 1> Attrs;
7135     getAttrs({Attribute::ByVal}, Attrs, /* IgnoreSubsumingPositions */ true);
7136     if (!Attrs.empty() &&
7137         A.checkForAllCallSites([](AbstractCallSite ACS) { return true; }, *this,
7138                                true, UsedAssumedInformation))
7139       return Attrs[0].getValueAsType();
7140 
7141     std::optional<Type *> Ty;
7142     unsigned ArgNo = getIRPosition().getCallSiteArgNo();
7143 
7144     // Make sure the associated call site argument has the same type at all call
7145     // sites and it is an allocation we know is safe to privatize, for now that
7146     // means we only allow alloca instructions.
7147     // TODO: We can additionally analyze the accesses in the callee to  create
7148     //       the type from that information instead. That is a little more
7149     //       involved and will be done in a follow up patch.
7150     auto CallSiteCheck = [&](AbstractCallSite ACS) {
7151       IRPosition ACSArgPos = IRPosition::callsite_argument(ACS, ArgNo);
7152       // Check if a coresponding argument was found or if it is one not
7153       // associated (which can happen for callback calls).
7154       if (ACSArgPos.getPositionKind() == IRPosition::IRP_INVALID)
7155         return false;
7156 
7157       // Check that all call sites agree on a type.
7158       auto &PrivCSArgAA =
7159           A.getAAFor<AAPrivatizablePtr>(*this, ACSArgPos, DepClassTy::REQUIRED);
7160       std::optional<Type *> CSTy = PrivCSArgAA.getPrivatizableType();
7161 
7162       LLVM_DEBUG({
7163         dbgs() << "[AAPrivatizablePtr] ACSPos: " << ACSArgPos << ", CSTy: ";
7164         if (CSTy && *CSTy)
7165           (*CSTy)->print(dbgs());
7166         else if (CSTy)
7167           dbgs() << "<nullptr>";
7168         else
7169           dbgs() << "<none>";
7170       });
7171 
7172       Ty = combineTypes(Ty, CSTy);
7173 
7174       LLVM_DEBUG({
7175         dbgs() << " : New Type: ";
7176         if (Ty && *Ty)
7177           (*Ty)->print(dbgs());
7178         else if (Ty)
7179           dbgs() << "<nullptr>";
7180         else
7181           dbgs() << "<none>";
7182         dbgs() << "\n";
7183       });
7184 
7185       return !Ty || *Ty;
7186     };
7187 
7188     if (!A.checkForAllCallSites(CallSiteCheck, *this, true,
7189                                 UsedAssumedInformation))
7190       return nullptr;
7191     return Ty;
7192   }
7193 
7194   /// See AbstractAttribute::updateImpl(...).
7195   ChangeStatus updateImpl(Attributor &A) override {
7196     PrivatizableType = identifyPrivatizableType(A);
7197     if (!PrivatizableType)
7198       return ChangeStatus::UNCHANGED;
7199     if (!*PrivatizableType)
7200       return indicatePessimisticFixpoint();
7201 
7202     // The dependence is optional so we don't give up once we give up on the
7203     // alignment.
7204     A.getAAFor<AAAlign>(*this, IRPosition::value(getAssociatedValue()),
7205                         DepClassTy::OPTIONAL);
7206 
7207     // Avoid arguments with padding for now.
7208     if (!getIRPosition().hasAttr(Attribute::ByVal) &&
7209         !isDenselyPacked(*PrivatizableType, A.getInfoCache().getDL())) {
7210       LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] Padding detected\n");
7211       return indicatePessimisticFixpoint();
7212     }
7213 
7214     // Collect the types that will replace the privatizable type in the function
7215     // signature.
7216     SmallVector<Type *, 16> ReplacementTypes;
7217     identifyReplacementTypes(*PrivatizableType, ReplacementTypes);
7218 
7219     // Verify callee and caller agree on how the promoted argument would be
7220     // passed.
7221     Function &Fn = *getIRPosition().getAnchorScope();
7222     const auto *TTI =
7223         A.getInfoCache().getAnalysisResultForFunction<TargetIRAnalysis>(Fn);
7224     if (!TTI) {
7225       LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] Missing TTI for function "
7226                         << Fn.getName() << "\n");
7227       return indicatePessimisticFixpoint();
7228     }
7229 
7230     auto CallSiteCheck = [&](AbstractCallSite ACS) {
7231       CallBase *CB = ACS.getInstruction();
7232       return TTI->areTypesABICompatible(
7233           CB->getCaller(), CB->getCalledFunction(), ReplacementTypes);
7234     };
7235     bool UsedAssumedInformation = false;
7236     if (!A.checkForAllCallSites(CallSiteCheck, *this, true,
7237                                 UsedAssumedInformation)) {
7238       LLVM_DEBUG(
7239           dbgs() << "[AAPrivatizablePtr] ABI incompatibility detected for "
7240                  << Fn.getName() << "\n");
7241       return indicatePessimisticFixpoint();
7242     }
7243 
7244     // Register a rewrite of the argument.
7245     Argument *Arg = getAssociatedArgument();
7246     if (!A.isValidFunctionSignatureRewrite(*Arg, ReplacementTypes)) {
7247       LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] Rewrite not valid\n");
7248       return indicatePessimisticFixpoint();
7249     }
7250 
7251     unsigned ArgNo = Arg->getArgNo();
7252 
7253     // Helper to check if for the given call site the associated argument is
7254     // passed to a callback where the privatization would be different.
7255     auto IsCompatiblePrivArgOfCallback = [&](CallBase &CB) {
7256       SmallVector<const Use *, 4> CallbackUses;
7257       AbstractCallSite::getCallbackUses(CB, CallbackUses);
7258       for (const Use *U : CallbackUses) {
7259         AbstractCallSite CBACS(U);
7260         assert(CBACS && CBACS.isCallbackCall());
7261         for (Argument &CBArg : CBACS.getCalledFunction()->args()) {
7262           int CBArgNo = CBACS.getCallArgOperandNo(CBArg);
7263 
7264           LLVM_DEBUG({
7265             dbgs()
7266                 << "[AAPrivatizablePtr] Argument " << *Arg
7267                 << "check if can be privatized in the context of its parent ("
7268                 << Arg->getParent()->getName()
7269                 << ")\n[AAPrivatizablePtr] because it is an argument in a "
7270                    "callback ("
7271                 << CBArgNo << "@" << CBACS.getCalledFunction()->getName()
7272                 << ")\n[AAPrivatizablePtr] " << CBArg << " : "
7273                 << CBACS.getCallArgOperand(CBArg) << " vs "
7274                 << CB.getArgOperand(ArgNo) << "\n"
7275                 << "[AAPrivatizablePtr] " << CBArg << " : "
7276                 << CBACS.getCallArgOperandNo(CBArg) << " vs " << ArgNo << "\n";
7277           });
7278 
7279           if (CBArgNo != int(ArgNo))
7280             continue;
7281           const auto &CBArgPrivAA = A.getAAFor<AAPrivatizablePtr>(
7282               *this, IRPosition::argument(CBArg), DepClassTy::REQUIRED);
7283           if (CBArgPrivAA.isValidState()) {
7284             auto CBArgPrivTy = CBArgPrivAA.getPrivatizableType();
7285             if (!CBArgPrivTy)
7286               continue;
7287             if (*CBArgPrivTy == PrivatizableType)
7288               continue;
7289           }
7290 
7291           LLVM_DEBUG({
7292             dbgs() << "[AAPrivatizablePtr] Argument " << *Arg
7293                    << " cannot be privatized in the context of its parent ("
7294                    << Arg->getParent()->getName()
7295                    << ")\n[AAPrivatizablePtr] because it is an argument in a "
7296                       "callback ("
7297                    << CBArgNo << "@" << CBACS.getCalledFunction()->getName()
7298                    << ").\n[AAPrivatizablePtr] for which the argument "
7299                       "privatization is not compatible.\n";
7300           });
7301           return false;
7302         }
7303       }
7304       return true;
7305     };
7306 
7307     // Helper to check if for the given call site the associated argument is
7308     // passed to a direct call where the privatization would be different.
7309     auto IsCompatiblePrivArgOfDirectCS = [&](AbstractCallSite ACS) {
7310       CallBase *DC = cast<CallBase>(ACS.getInstruction());
7311       int DCArgNo = ACS.getCallArgOperandNo(ArgNo);
7312       assert(DCArgNo >= 0 && unsigned(DCArgNo) < DC->arg_size() &&
7313              "Expected a direct call operand for callback call operand");
7314 
7315       LLVM_DEBUG({
7316         dbgs() << "[AAPrivatizablePtr] Argument " << *Arg
7317                << " check if be privatized in the context of its parent ("
7318                << Arg->getParent()->getName()
7319                << ")\n[AAPrivatizablePtr] because it is an argument in a "
7320                   "direct call of ("
7321                << DCArgNo << "@" << DC->getCalledFunction()->getName()
7322                << ").\n";
7323       });
7324 
7325       Function *DCCallee = DC->getCalledFunction();
7326       if (unsigned(DCArgNo) < DCCallee->arg_size()) {
7327         const auto &DCArgPrivAA = A.getAAFor<AAPrivatizablePtr>(
7328             *this, IRPosition::argument(*DCCallee->getArg(DCArgNo)),
7329             DepClassTy::REQUIRED);
7330         if (DCArgPrivAA.isValidState()) {
7331           auto DCArgPrivTy = DCArgPrivAA.getPrivatizableType();
7332           if (!DCArgPrivTy)
7333             return true;
7334           if (*DCArgPrivTy == PrivatizableType)
7335             return true;
7336         }
7337       }
7338 
7339       LLVM_DEBUG({
7340         dbgs() << "[AAPrivatizablePtr] Argument " << *Arg
7341                << " cannot be privatized in the context of its parent ("
7342                << Arg->getParent()->getName()
7343                << ")\n[AAPrivatizablePtr] because it is an argument in a "
7344                   "direct call of ("
7345                << ACS.getInstruction()->getCalledFunction()->getName()
7346                << ").\n[AAPrivatizablePtr] for which the argument "
7347                   "privatization is not compatible.\n";
7348       });
7349       return false;
7350     };
7351 
7352     // Helper to check if the associated argument is used at the given abstract
7353     // call site in a way that is incompatible with the privatization assumed
7354     // here.
7355     auto IsCompatiblePrivArgOfOtherCallSite = [&](AbstractCallSite ACS) {
7356       if (ACS.isDirectCall())
7357         return IsCompatiblePrivArgOfCallback(*ACS.getInstruction());
7358       if (ACS.isCallbackCall())
7359         return IsCompatiblePrivArgOfDirectCS(ACS);
7360       return false;
7361     };
7362 
7363     if (!A.checkForAllCallSites(IsCompatiblePrivArgOfOtherCallSite, *this, true,
7364                                 UsedAssumedInformation))
7365       return indicatePessimisticFixpoint();
7366 
7367     return ChangeStatus::UNCHANGED;
7368   }
7369 
7370   /// Given a type to private \p PrivType, collect the constituates (which are
7371   /// used) in \p ReplacementTypes.
7372   static void
7373   identifyReplacementTypes(Type *PrivType,
7374                            SmallVectorImpl<Type *> &ReplacementTypes) {
7375     // TODO: For now we expand the privatization type to the fullest which can
7376     //       lead to dead arguments that need to be removed later.
7377     assert(PrivType && "Expected privatizable type!");
7378 
7379     // Traverse the type, extract constituate types on the outermost level.
7380     if (auto *PrivStructType = dyn_cast<StructType>(PrivType)) {
7381       for (unsigned u = 0, e = PrivStructType->getNumElements(); u < e; u++)
7382         ReplacementTypes.push_back(PrivStructType->getElementType(u));
7383     } else if (auto *PrivArrayType = dyn_cast<ArrayType>(PrivType)) {
7384       ReplacementTypes.append(PrivArrayType->getNumElements(),
7385                               PrivArrayType->getElementType());
7386     } else {
7387       ReplacementTypes.push_back(PrivType);
7388     }
7389   }
7390 
7391   /// Initialize \p Base according to the type \p PrivType at position \p IP.
7392   /// The values needed are taken from the arguments of \p F starting at
7393   /// position \p ArgNo.
7394   static void createInitialization(Type *PrivType, Value &Base, Function &F,
7395                                    unsigned ArgNo, Instruction &IP) {
7396     assert(PrivType && "Expected privatizable type!");
7397 
7398     IRBuilder<NoFolder> IRB(&IP);
7399     const DataLayout &DL = F.getParent()->getDataLayout();
7400 
7401     // Traverse the type, build GEPs and stores.
7402     if (auto *PrivStructType = dyn_cast<StructType>(PrivType)) {
7403       const StructLayout *PrivStructLayout = DL.getStructLayout(PrivStructType);
7404       for (unsigned u = 0, e = PrivStructType->getNumElements(); u < e; u++) {
7405         Type *PointeeTy = PrivStructType->getElementType(u)->getPointerTo();
7406         Value *Ptr =
7407             constructPointer(PointeeTy, PrivType, &Base,
7408                              PrivStructLayout->getElementOffset(u), IRB, DL);
7409         new StoreInst(F.getArg(ArgNo + u), Ptr, &IP);
7410       }
7411     } else if (auto *PrivArrayType = dyn_cast<ArrayType>(PrivType)) {
7412       Type *PointeeTy = PrivArrayType->getElementType();
7413       Type *PointeePtrTy = PointeeTy->getPointerTo();
7414       uint64_t PointeeTySize = DL.getTypeStoreSize(PointeeTy);
7415       for (unsigned u = 0, e = PrivArrayType->getNumElements(); u < e; u++) {
7416         Value *Ptr = constructPointer(PointeePtrTy, PrivType, &Base,
7417                                       u * PointeeTySize, IRB, DL);
7418         new StoreInst(F.getArg(ArgNo + u), Ptr, &IP);
7419       }
7420     } else {
7421       new StoreInst(F.getArg(ArgNo), &Base, &IP);
7422     }
7423   }
7424 
7425   /// Extract values from \p Base according to the type \p PrivType at the
7426   /// call position \p ACS. The values are appended to \p ReplacementValues.
7427   void createReplacementValues(Align Alignment, Type *PrivType,
7428                                AbstractCallSite ACS, Value *Base,
7429                                SmallVectorImpl<Value *> &ReplacementValues) {
7430     assert(Base && "Expected base value!");
7431     assert(PrivType && "Expected privatizable type!");
7432     Instruction *IP = ACS.getInstruction();
7433 
7434     IRBuilder<NoFolder> IRB(IP);
7435     const DataLayout &DL = IP->getModule()->getDataLayout();
7436 
7437     Type *PrivPtrType = PrivType->getPointerTo();
7438     if (Base->getType() != PrivPtrType)
7439       Base = BitCastInst::CreatePointerBitCastOrAddrSpaceCast(
7440           Base, PrivPtrType, "", ACS.getInstruction());
7441 
7442     // Traverse the type, build GEPs and loads.
7443     if (auto *PrivStructType = dyn_cast<StructType>(PrivType)) {
7444       const StructLayout *PrivStructLayout = DL.getStructLayout(PrivStructType);
7445       for (unsigned u = 0, e = PrivStructType->getNumElements(); u < e; u++) {
7446         Type *PointeeTy = PrivStructType->getElementType(u);
7447         Value *Ptr =
7448             constructPointer(PointeeTy->getPointerTo(), PrivType, Base,
7449                              PrivStructLayout->getElementOffset(u), IRB, DL);
7450         LoadInst *L = new LoadInst(PointeeTy, Ptr, "", IP);
7451         L->setAlignment(Alignment);
7452         ReplacementValues.push_back(L);
7453       }
7454     } else if (auto *PrivArrayType = dyn_cast<ArrayType>(PrivType)) {
7455       Type *PointeeTy = PrivArrayType->getElementType();
7456       uint64_t PointeeTySize = DL.getTypeStoreSize(PointeeTy);
7457       Type *PointeePtrTy = PointeeTy->getPointerTo();
7458       for (unsigned u = 0, e = PrivArrayType->getNumElements(); u < e; u++) {
7459         Value *Ptr = constructPointer(PointeePtrTy, PrivType, Base,
7460                                       u * PointeeTySize, IRB, DL);
7461         LoadInst *L = new LoadInst(PointeeTy, Ptr, "", IP);
7462         L->setAlignment(Alignment);
7463         ReplacementValues.push_back(L);
7464       }
7465     } else {
7466       LoadInst *L = new LoadInst(PrivType, Base, "", IP);
7467       L->setAlignment(Alignment);
7468       ReplacementValues.push_back(L);
7469     }
7470   }
7471 
7472   /// See AbstractAttribute::manifest(...)
7473   ChangeStatus manifest(Attributor &A) override {
7474     if (!PrivatizableType)
7475       return ChangeStatus::UNCHANGED;
7476     assert(*PrivatizableType && "Expected privatizable type!");
7477 
7478     // Collect all tail calls in the function as we cannot allow new allocas to
7479     // escape into tail recursion.
7480     // TODO: Be smarter about new allocas escaping into tail calls.
7481     SmallVector<CallInst *, 16> TailCalls;
7482     bool UsedAssumedInformation = false;
7483     if (!A.checkForAllInstructions(
7484             [&](Instruction &I) {
7485               CallInst &CI = cast<CallInst>(I);
7486               if (CI.isTailCall())
7487                 TailCalls.push_back(&CI);
7488               return true;
7489             },
7490             *this, {Instruction::Call}, UsedAssumedInformation))
7491       return ChangeStatus::UNCHANGED;
7492 
7493     Argument *Arg = getAssociatedArgument();
7494     // Query AAAlign attribute for alignment of associated argument to
7495     // determine the best alignment of loads.
7496     const auto &AlignAA =
7497         A.getAAFor<AAAlign>(*this, IRPosition::value(*Arg), DepClassTy::NONE);
7498 
7499     // Callback to repair the associated function. A new alloca is placed at the
7500     // beginning and initialized with the values passed through arguments. The
7501     // new alloca replaces the use of the old pointer argument.
7502     Attributor::ArgumentReplacementInfo::CalleeRepairCBTy FnRepairCB =
7503         [=](const Attributor::ArgumentReplacementInfo &ARI,
7504             Function &ReplacementFn, Function::arg_iterator ArgIt) {
7505           BasicBlock &EntryBB = ReplacementFn.getEntryBlock();
7506           Instruction *IP = &*EntryBB.getFirstInsertionPt();
7507           const DataLayout &DL = IP->getModule()->getDataLayout();
7508           unsigned AS = DL.getAllocaAddrSpace();
7509           Instruction *AI = new AllocaInst(*PrivatizableType, AS,
7510                                            Arg->getName() + ".priv", IP);
7511           createInitialization(*PrivatizableType, *AI, ReplacementFn,
7512                                ArgIt->getArgNo(), *IP);
7513 
7514           if (AI->getType() != Arg->getType())
7515             AI = BitCastInst::CreatePointerBitCastOrAddrSpaceCast(
7516                 AI, Arg->getType(), "", IP);
7517           Arg->replaceAllUsesWith(AI);
7518 
7519           for (CallInst *CI : TailCalls)
7520             CI->setTailCall(false);
7521         };
7522 
7523     // Callback to repair a call site of the associated function. The elements
7524     // of the privatizable type are loaded prior to the call and passed to the
7525     // new function version.
7526     Attributor::ArgumentReplacementInfo::ACSRepairCBTy ACSRepairCB =
7527         [=, &AlignAA](const Attributor::ArgumentReplacementInfo &ARI,
7528                       AbstractCallSite ACS,
7529                       SmallVectorImpl<Value *> &NewArgOperands) {
7530           // When no alignment is specified for the load instruction,
7531           // natural alignment is assumed.
7532           createReplacementValues(
7533               AlignAA.getAssumedAlign(), *PrivatizableType, ACS,
7534               ACS.getCallArgOperand(ARI.getReplacedArg().getArgNo()),
7535               NewArgOperands);
7536         };
7537 
7538     // Collect the types that will replace the privatizable type in the function
7539     // signature.
7540     SmallVector<Type *, 16> ReplacementTypes;
7541     identifyReplacementTypes(*PrivatizableType, ReplacementTypes);
7542 
7543     // Register a rewrite of the argument.
7544     if (A.registerFunctionSignatureRewrite(*Arg, ReplacementTypes,
7545                                            std::move(FnRepairCB),
7546                                            std::move(ACSRepairCB)))
7547       return ChangeStatus::CHANGED;
7548     return ChangeStatus::UNCHANGED;
7549   }
7550 
7551   /// See AbstractAttribute::trackStatistics()
7552   void trackStatistics() const override {
7553     STATS_DECLTRACK_ARG_ATTR(privatizable_ptr);
7554   }
7555 };
7556 
7557 struct AAPrivatizablePtrFloating : public AAPrivatizablePtrImpl {
7558   AAPrivatizablePtrFloating(const IRPosition &IRP, Attributor &A)
7559       : AAPrivatizablePtrImpl(IRP, A) {}
7560 
7561   /// See AbstractAttribute::initialize(...).
7562   void initialize(Attributor &A) override {
7563     // TODO: We can privatize more than arguments.
7564     indicatePessimisticFixpoint();
7565   }
7566 
7567   ChangeStatus updateImpl(Attributor &A) override {
7568     llvm_unreachable("AAPrivatizablePtr(Floating|Returned|CallSiteReturned)::"
7569                      "updateImpl will not be called");
7570   }
7571 
7572   /// See AAPrivatizablePtrImpl::identifyPrivatizableType(...)
7573   std::optional<Type *> identifyPrivatizableType(Attributor &A) override {
7574     Value *Obj = getUnderlyingObject(&getAssociatedValue());
7575     if (!Obj) {
7576       LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] No underlying object found!\n");
7577       return nullptr;
7578     }
7579 
7580     if (auto *AI = dyn_cast<AllocaInst>(Obj))
7581       if (auto *CI = dyn_cast<ConstantInt>(AI->getArraySize()))
7582         if (CI->isOne())
7583           return AI->getAllocatedType();
7584     if (auto *Arg = dyn_cast<Argument>(Obj)) {
7585       auto &PrivArgAA = A.getAAFor<AAPrivatizablePtr>(
7586           *this, IRPosition::argument(*Arg), DepClassTy::REQUIRED);
7587       if (PrivArgAA.isAssumedPrivatizablePtr())
7588         return PrivArgAA.getPrivatizableType();
7589     }
7590 
7591     LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] Underlying object neither valid "
7592                          "alloca nor privatizable argument: "
7593                       << *Obj << "!\n");
7594     return nullptr;
7595   }
7596 
7597   /// See AbstractAttribute::trackStatistics()
7598   void trackStatistics() const override {
7599     STATS_DECLTRACK_FLOATING_ATTR(privatizable_ptr);
7600   }
7601 };
7602 
7603 struct AAPrivatizablePtrCallSiteArgument final
7604     : public AAPrivatizablePtrFloating {
7605   AAPrivatizablePtrCallSiteArgument(const IRPosition &IRP, Attributor &A)
7606       : AAPrivatizablePtrFloating(IRP, A) {}
7607 
7608   /// See AbstractAttribute::initialize(...).
7609   void initialize(Attributor &A) override {
7610     if (getIRPosition().hasAttr(Attribute::ByVal))
7611       indicateOptimisticFixpoint();
7612   }
7613 
7614   /// See AbstractAttribute::updateImpl(...).
7615   ChangeStatus updateImpl(Attributor &A) override {
7616     PrivatizableType = identifyPrivatizableType(A);
7617     if (!PrivatizableType)
7618       return ChangeStatus::UNCHANGED;
7619     if (!*PrivatizableType)
7620       return indicatePessimisticFixpoint();
7621 
7622     const IRPosition &IRP = getIRPosition();
7623     auto &NoCaptureAA =
7624         A.getAAFor<AANoCapture>(*this, IRP, DepClassTy::REQUIRED);
7625     if (!NoCaptureAA.isAssumedNoCapture()) {
7626       LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] pointer might be captured!\n");
7627       return indicatePessimisticFixpoint();
7628     }
7629 
7630     auto &NoAliasAA = A.getAAFor<AANoAlias>(*this, IRP, DepClassTy::REQUIRED);
7631     if (!NoAliasAA.isAssumedNoAlias()) {
7632       LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] pointer might alias!\n");
7633       return indicatePessimisticFixpoint();
7634     }
7635 
7636     bool IsKnown;
7637     if (!AA::isAssumedReadOnly(A, IRP, *this, IsKnown)) {
7638       LLVM_DEBUG(dbgs() << "[AAPrivatizablePtr] pointer is written!\n");
7639       return indicatePessimisticFixpoint();
7640     }
7641 
7642     return ChangeStatus::UNCHANGED;
7643   }
7644 
7645   /// See AbstractAttribute::trackStatistics()
7646   void trackStatistics() const override {
7647     STATS_DECLTRACK_CSARG_ATTR(privatizable_ptr);
7648   }
7649 };
7650 
7651 struct AAPrivatizablePtrCallSiteReturned final
7652     : public AAPrivatizablePtrFloating {
7653   AAPrivatizablePtrCallSiteReturned(const IRPosition &IRP, Attributor &A)
7654       : AAPrivatizablePtrFloating(IRP, A) {}
7655 
7656   /// See AbstractAttribute::initialize(...).
7657   void initialize(Attributor &A) override {
7658     // TODO: We can privatize more than arguments.
7659     indicatePessimisticFixpoint();
7660   }
7661 
7662   /// See AbstractAttribute::trackStatistics()
7663   void trackStatistics() const override {
7664     STATS_DECLTRACK_CSRET_ATTR(privatizable_ptr);
7665   }
7666 };
7667 
7668 struct AAPrivatizablePtrReturned final : public AAPrivatizablePtrFloating {
7669   AAPrivatizablePtrReturned(const IRPosition &IRP, Attributor &A)
7670       : AAPrivatizablePtrFloating(IRP, A) {}
7671 
7672   /// See AbstractAttribute::initialize(...).
7673   void initialize(Attributor &A) override {
7674     // TODO: We can privatize more than arguments.
7675     indicatePessimisticFixpoint();
7676   }
7677 
7678   /// See AbstractAttribute::trackStatistics()
7679   void trackStatistics() const override {
7680     STATS_DECLTRACK_FNRET_ATTR(privatizable_ptr);
7681   }
7682 };
7683 } // namespace
7684 
7685 /// -------------------- Memory Behavior Attributes ----------------------------
7686 /// Includes read-none, read-only, and write-only.
7687 /// ----------------------------------------------------------------------------
7688 namespace {
7689 struct AAMemoryBehaviorImpl : public AAMemoryBehavior {
7690   AAMemoryBehaviorImpl(const IRPosition &IRP, Attributor &A)
7691       : AAMemoryBehavior(IRP, A) {}
7692 
7693   /// See AbstractAttribute::initialize(...).
7694   void initialize(Attributor &A) override {
7695     intersectAssumedBits(BEST_STATE);
7696     getKnownStateFromValue(getIRPosition(), getState());
7697     AAMemoryBehavior::initialize(A);
7698   }
7699 
7700   /// Return the memory behavior information encoded in the IR for \p IRP.
7701   static void getKnownStateFromValue(const IRPosition &IRP,
7702                                      BitIntegerState &State,
7703                                      bool IgnoreSubsumingPositions = false) {
7704     SmallVector<Attribute, 2> Attrs;
7705     IRP.getAttrs(AttrKinds, Attrs, IgnoreSubsumingPositions);
7706     for (const Attribute &Attr : Attrs) {
7707       switch (Attr.getKindAsEnum()) {
7708       case Attribute::ReadNone:
7709         State.addKnownBits(NO_ACCESSES);
7710         break;
7711       case Attribute::ReadOnly:
7712         State.addKnownBits(NO_WRITES);
7713         break;
7714       case Attribute::WriteOnly:
7715         State.addKnownBits(NO_READS);
7716         break;
7717       default:
7718         llvm_unreachable("Unexpected attribute!");
7719       }
7720     }
7721 
7722     if (auto *I = dyn_cast<Instruction>(&IRP.getAnchorValue())) {
7723       if (!I->mayReadFromMemory())
7724         State.addKnownBits(NO_READS);
7725       if (!I->mayWriteToMemory())
7726         State.addKnownBits(NO_WRITES);
7727     }
7728   }
7729 
7730   /// See AbstractAttribute::getDeducedAttributes(...).
7731   void getDeducedAttributes(LLVMContext &Ctx,
7732                             SmallVectorImpl<Attribute> &Attrs) const override {
7733     assert(Attrs.size() == 0);
7734     if (isAssumedReadNone())
7735       Attrs.push_back(Attribute::get(Ctx, Attribute::ReadNone));
7736     else if (isAssumedReadOnly())
7737       Attrs.push_back(Attribute::get(Ctx, Attribute::ReadOnly));
7738     else if (isAssumedWriteOnly())
7739       Attrs.push_back(Attribute::get(Ctx, Attribute::WriteOnly));
7740     assert(Attrs.size() <= 1);
7741   }
7742 
7743   /// See AbstractAttribute::manifest(...).
7744   ChangeStatus manifest(Attributor &A) override {
7745     if (hasAttr(Attribute::ReadNone, /* IgnoreSubsumingPositions */ true))
7746       return ChangeStatus::UNCHANGED;
7747 
7748     const IRPosition &IRP = getIRPosition();
7749 
7750     // Check if we would improve the existing attributes first.
7751     SmallVector<Attribute, 4> DeducedAttrs;
7752     getDeducedAttributes(IRP.getAnchorValue().getContext(), DeducedAttrs);
7753     if (llvm::all_of(DeducedAttrs, [&](const Attribute &Attr) {
7754           return IRP.hasAttr(Attr.getKindAsEnum(),
7755                              /* IgnoreSubsumingPositions */ true);
7756         }))
7757       return ChangeStatus::UNCHANGED;
7758 
7759     // Clear existing attributes.
7760     IRP.removeAttrs(AttrKinds);
7761 
7762     // Use the generic manifest method.
7763     return IRAttribute::manifest(A);
7764   }
7765 
7766   /// See AbstractState::getAsStr().
7767   const std::string getAsStr() const override {
7768     if (isAssumedReadNone())
7769       return "readnone";
7770     if (isAssumedReadOnly())
7771       return "readonly";
7772     if (isAssumedWriteOnly())
7773       return "writeonly";
7774     return "may-read/write";
7775   }
7776 
7777   /// The set of IR attributes AAMemoryBehavior deals with.
7778   static const Attribute::AttrKind AttrKinds[3];
7779 };
7780 
7781 const Attribute::AttrKind AAMemoryBehaviorImpl::AttrKinds[] = {
7782     Attribute::ReadNone, Attribute::ReadOnly, Attribute::WriteOnly};
7783 
7784 /// Memory behavior attribute for a floating value.
7785 struct AAMemoryBehaviorFloating : AAMemoryBehaviorImpl {
7786   AAMemoryBehaviorFloating(const IRPosition &IRP, Attributor &A)
7787       : AAMemoryBehaviorImpl(IRP, A) {}
7788 
7789   /// See AbstractAttribute::updateImpl(...).
7790   ChangeStatus updateImpl(Attributor &A) override;
7791 
7792   /// See AbstractAttribute::trackStatistics()
7793   void trackStatistics() const override {
7794     if (isAssumedReadNone())
7795       STATS_DECLTRACK_FLOATING_ATTR(readnone)
7796     else if (isAssumedReadOnly())
7797       STATS_DECLTRACK_FLOATING_ATTR(readonly)
7798     else if (isAssumedWriteOnly())
7799       STATS_DECLTRACK_FLOATING_ATTR(writeonly)
7800   }
7801 
7802 private:
7803   /// Return true if users of \p UserI might access the underlying
7804   /// variable/location described by \p U and should therefore be analyzed.
7805   bool followUsersOfUseIn(Attributor &A, const Use &U,
7806                           const Instruction *UserI);
7807 
7808   /// Update the state according to the effect of use \p U in \p UserI.
7809   void analyzeUseIn(Attributor &A, const Use &U, const Instruction *UserI);
7810 };
7811 
7812 /// Memory behavior attribute for function argument.
7813 struct AAMemoryBehaviorArgument : AAMemoryBehaviorFloating {
7814   AAMemoryBehaviorArgument(const IRPosition &IRP, Attributor &A)
7815       : AAMemoryBehaviorFloating(IRP, A) {}
7816 
7817   /// See AbstractAttribute::initialize(...).
7818   void initialize(Attributor &A) override {
7819     intersectAssumedBits(BEST_STATE);
7820     const IRPosition &IRP = getIRPosition();
7821     // TODO: Make IgnoreSubsumingPositions a property of an IRAttribute so we
7822     // can query it when we use has/getAttr. That would allow us to reuse the
7823     // initialize of the base class here.
7824     bool HasByVal =
7825         IRP.hasAttr({Attribute::ByVal}, /* IgnoreSubsumingPositions */ true);
7826     getKnownStateFromValue(IRP, getState(),
7827                            /* IgnoreSubsumingPositions */ HasByVal);
7828 
7829     // Initialize the use vector with all direct uses of the associated value.
7830     Argument *Arg = getAssociatedArgument();
7831     if (!Arg || !A.isFunctionIPOAmendable(*(Arg->getParent())))
7832       indicatePessimisticFixpoint();
7833   }
7834 
7835   ChangeStatus manifest(Attributor &A) override {
7836     // TODO: Pointer arguments are not supported on vectors of pointers yet.
7837     if (!getAssociatedValue().getType()->isPointerTy())
7838       return ChangeStatus::UNCHANGED;
7839 
7840     // TODO: From readattrs.ll: "inalloca parameters are always
7841     //                           considered written"
7842     if (hasAttr({Attribute::InAlloca, Attribute::Preallocated})) {
7843       removeKnownBits(NO_WRITES);
7844       removeAssumedBits(NO_WRITES);
7845     }
7846     return AAMemoryBehaviorFloating::manifest(A);
7847   }
7848 
7849   /// See AbstractAttribute::trackStatistics()
7850   void trackStatistics() const override {
7851     if (isAssumedReadNone())
7852       STATS_DECLTRACK_ARG_ATTR(readnone)
7853     else if (isAssumedReadOnly())
7854       STATS_DECLTRACK_ARG_ATTR(readonly)
7855     else if (isAssumedWriteOnly())
7856       STATS_DECLTRACK_ARG_ATTR(writeonly)
7857   }
7858 };
7859 
7860 struct AAMemoryBehaviorCallSiteArgument final : AAMemoryBehaviorArgument {
7861   AAMemoryBehaviorCallSiteArgument(const IRPosition &IRP, Attributor &A)
7862       : AAMemoryBehaviorArgument(IRP, A) {}
7863 
7864   /// See AbstractAttribute::initialize(...).
7865   void initialize(Attributor &A) override {
7866     // If we don't have an associated attribute this is either a variadic call
7867     // or an indirect call, either way, nothing to do here.
7868     Argument *Arg = getAssociatedArgument();
7869     if (!Arg) {
7870       indicatePessimisticFixpoint();
7871       return;
7872     }
7873     if (Arg->hasByValAttr()) {
7874       addKnownBits(NO_WRITES);
7875       removeKnownBits(NO_READS);
7876       removeAssumedBits(NO_READS);
7877     }
7878     AAMemoryBehaviorArgument::initialize(A);
7879     if (getAssociatedFunction()->isDeclaration())
7880       indicatePessimisticFixpoint();
7881   }
7882 
7883   /// See AbstractAttribute::updateImpl(...).
7884   ChangeStatus updateImpl(Attributor &A) override {
7885     // TODO: Once we have call site specific value information we can provide
7886     //       call site specific liveness liveness information and then it makes
7887     //       sense to specialize attributes for call sites arguments instead of
7888     //       redirecting requests to the callee argument.
7889     Argument *Arg = getAssociatedArgument();
7890     const IRPosition &ArgPos = IRPosition::argument(*Arg);
7891     auto &ArgAA =
7892         A.getAAFor<AAMemoryBehavior>(*this, ArgPos, DepClassTy::REQUIRED);
7893     return clampStateAndIndicateChange(getState(), ArgAA.getState());
7894   }
7895 
7896   /// See AbstractAttribute::trackStatistics()
7897   void trackStatistics() const override {
7898     if (isAssumedReadNone())
7899       STATS_DECLTRACK_CSARG_ATTR(readnone)
7900     else if (isAssumedReadOnly())
7901       STATS_DECLTRACK_CSARG_ATTR(readonly)
7902     else if (isAssumedWriteOnly())
7903       STATS_DECLTRACK_CSARG_ATTR(writeonly)
7904   }
7905 };
7906 
7907 /// Memory behavior attribute for a call site return position.
7908 struct AAMemoryBehaviorCallSiteReturned final : AAMemoryBehaviorFloating {
7909   AAMemoryBehaviorCallSiteReturned(const IRPosition &IRP, Attributor &A)
7910       : AAMemoryBehaviorFloating(IRP, A) {}
7911 
7912   /// See AbstractAttribute::initialize(...).
7913   void initialize(Attributor &A) override {
7914     AAMemoryBehaviorImpl::initialize(A);
7915     Function *F = getAssociatedFunction();
7916     if (!F || F->isDeclaration())
7917       indicatePessimisticFixpoint();
7918   }
7919 
7920   /// See AbstractAttribute::manifest(...).
7921   ChangeStatus manifest(Attributor &A) override {
7922     // We do not annotate returned values.
7923     return ChangeStatus::UNCHANGED;
7924   }
7925 
7926   /// See AbstractAttribute::trackStatistics()
7927   void trackStatistics() const override {}
7928 };
7929 
7930 /// An AA to represent the memory behavior function attributes.
7931 struct AAMemoryBehaviorFunction final : public AAMemoryBehaviorImpl {
7932   AAMemoryBehaviorFunction(const IRPosition &IRP, Attributor &A)
7933       : AAMemoryBehaviorImpl(IRP, A) {}
7934 
7935   /// See AbstractAttribute::updateImpl(Attributor &A).
7936   ChangeStatus updateImpl(Attributor &A) override;
7937 
7938   /// See AbstractAttribute::manifest(...).
7939   ChangeStatus manifest(Attributor &A) override {
7940     // TODO: It would be better to merge this with AAMemoryLocation, so that
7941     // we could determine read/write per location. This would also have the
7942     // benefit of only one place trying to manifest the memory attribute.
7943     Function &F = cast<Function>(getAnchorValue());
7944     MemoryEffects ME = MemoryEffects::unknown();
7945     if (isAssumedReadNone())
7946       ME = MemoryEffects::none();
7947     else if (isAssumedReadOnly())
7948       ME = MemoryEffects::readOnly();
7949     else if (isAssumedWriteOnly())
7950       ME = MemoryEffects::writeOnly();
7951 
7952     // Intersect with existing memory attribute, as we currently deduce the
7953     // location and modref portion separately.
7954     MemoryEffects ExistingME = F.getMemoryEffects();
7955     ME &= ExistingME;
7956     if (ME == ExistingME)
7957       return ChangeStatus::UNCHANGED;
7958 
7959     return IRAttributeManifest::manifestAttrs(
7960         A, getIRPosition(), Attribute::getWithMemoryEffects(F.getContext(), ME),
7961         /*ForceReplace*/ true);
7962   }
7963 
7964   /// See AbstractAttribute::trackStatistics()
7965   void trackStatistics() const override {
7966     if (isAssumedReadNone())
7967       STATS_DECLTRACK_FN_ATTR(readnone)
7968     else if (isAssumedReadOnly())
7969       STATS_DECLTRACK_FN_ATTR(readonly)
7970     else if (isAssumedWriteOnly())
7971       STATS_DECLTRACK_FN_ATTR(writeonly)
7972   }
7973 };
7974 
7975 /// AAMemoryBehavior attribute for call sites.
7976 struct AAMemoryBehaviorCallSite final : AAMemoryBehaviorImpl {
7977   AAMemoryBehaviorCallSite(const IRPosition &IRP, Attributor &A)
7978       : AAMemoryBehaviorImpl(IRP, A) {}
7979 
7980   /// See AbstractAttribute::initialize(...).
7981   void initialize(Attributor &A) override {
7982     AAMemoryBehaviorImpl::initialize(A);
7983     Function *F = getAssociatedFunction();
7984     if (!F || F->isDeclaration())
7985       indicatePessimisticFixpoint();
7986   }
7987 
7988   /// See AbstractAttribute::updateImpl(...).
7989   ChangeStatus updateImpl(Attributor &A) override {
7990     // TODO: Once we have call site specific value information we can provide
7991     //       call site specific liveness liveness information and then it makes
7992     //       sense to specialize attributes for call sites arguments instead of
7993     //       redirecting requests to the callee argument.
7994     Function *F = getAssociatedFunction();
7995     const IRPosition &FnPos = IRPosition::function(*F);
7996     auto &FnAA =
7997         A.getAAFor<AAMemoryBehavior>(*this, FnPos, DepClassTy::REQUIRED);
7998     return clampStateAndIndicateChange(getState(), FnAA.getState());
7999   }
8000 
8001   /// See AbstractAttribute::manifest(...).
8002   ChangeStatus manifest(Attributor &A) override {
8003     // TODO: Deduplicate this with AAMemoryBehaviorFunction.
8004     CallBase &CB = cast<CallBase>(getAnchorValue());
8005     MemoryEffects ME = MemoryEffects::unknown();
8006     if (isAssumedReadNone())
8007       ME = MemoryEffects::none();
8008     else if (isAssumedReadOnly())
8009       ME = MemoryEffects::readOnly();
8010     else if (isAssumedWriteOnly())
8011       ME = MemoryEffects::writeOnly();
8012 
8013     // Intersect with existing memory attribute, as we currently deduce the
8014     // location and modref portion separately.
8015     MemoryEffects ExistingME = CB.getMemoryEffects();
8016     ME &= ExistingME;
8017     if (ME == ExistingME)
8018       return ChangeStatus::UNCHANGED;
8019 
8020     return IRAttributeManifest::manifestAttrs(
8021         A, getIRPosition(),
8022         Attribute::getWithMemoryEffects(CB.getContext(), ME),
8023         /*ForceReplace*/ true);
8024   }
8025 
8026   /// See AbstractAttribute::trackStatistics()
8027   void trackStatistics() const override {
8028     if (isAssumedReadNone())
8029       STATS_DECLTRACK_CS_ATTR(readnone)
8030     else if (isAssumedReadOnly())
8031       STATS_DECLTRACK_CS_ATTR(readonly)
8032     else if (isAssumedWriteOnly())
8033       STATS_DECLTRACK_CS_ATTR(writeonly)
8034   }
8035 };
8036 
8037 ChangeStatus AAMemoryBehaviorFunction::updateImpl(Attributor &A) {
8038 
8039   // The current assumed state used to determine a change.
8040   auto AssumedState = getAssumed();
8041 
8042   auto CheckRWInst = [&](Instruction &I) {
8043     // If the instruction has an own memory behavior state, use it to restrict
8044     // the local state. No further analysis is required as the other memory
8045     // state is as optimistic as it gets.
8046     if (const auto *CB = dyn_cast<CallBase>(&I)) {
8047       const auto &MemBehaviorAA = A.getAAFor<AAMemoryBehavior>(
8048           *this, IRPosition::callsite_function(*CB), DepClassTy::REQUIRED);
8049       intersectAssumedBits(MemBehaviorAA.getAssumed());
8050       return !isAtFixpoint();
8051     }
8052 
8053     // Remove access kind modifiers if necessary.
8054     if (I.mayReadFromMemory())
8055       removeAssumedBits(NO_READS);
8056     if (I.mayWriteToMemory())
8057       removeAssumedBits(NO_WRITES);
8058     return !isAtFixpoint();
8059   };
8060 
8061   bool UsedAssumedInformation = false;
8062   if (!A.checkForAllReadWriteInstructions(CheckRWInst, *this,
8063                                           UsedAssumedInformation))
8064     return indicatePessimisticFixpoint();
8065 
8066   return (AssumedState != getAssumed()) ? ChangeStatus::CHANGED
8067                                         : ChangeStatus::UNCHANGED;
8068 }
8069 
8070 ChangeStatus AAMemoryBehaviorFloating::updateImpl(Attributor &A) {
8071 
8072   const IRPosition &IRP = getIRPosition();
8073   const IRPosition &FnPos = IRPosition::function_scope(IRP);
8074   AAMemoryBehavior::StateType &S = getState();
8075 
8076   // First, check the function scope. We take the known information and we avoid
8077   // work if the assumed information implies the current assumed information for
8078   // this attribute. This is a valid for all but byval arguments.
8079   Argument *Arg = IRP.getAssociatedArgument();
8080   AAMemoryBehavior::base_t FnMemAssumedState =
8081       AAMemoryBehavior::StateType::getWorstState();
8082   if (!Arg || !Arg->hasByValAttr()) {
8083     const auto &FnMemAA =
8084         A.getAAFor<AAMemoryBehavior>(*this, FnPos, DepClassTy::OPTIONAL);
8085     FnMemAssumedState = FnMemAA.getAssumed();
8086     S.addKnownBits(FnMemAA.getKnown());
8087     if ((S.getAssumed() & FnMemAA.getAssumed()) == S.getAssumed())
8088       return ChangeStatus::UNCHANGED;
8089   }
8090 
8091   // The current assumed state used to determine a change.
8092   auto AssumedState = S.getAssumed();
8093 
8094   // Make sure the value is not captured (except through "return"), if
8095   // it is, any information derived would be irrelevant anyway as we cannot
8096   // check the potential aliases introduced by the capture. However, no need
8097   // to fall back to anythign less optimistic than the function state.
8098   const auto &ArgNoCaptureAA =
8099       A.getAAFor<AANoCapture>(*this, IRP, DepClassTy::OPTIONAL);
8100   if (!ArgNoCaptureAA.isAssumedNoCaptureMaybeReturned()) {
8101     S.intersectAssumedBits(FnMemAssumedState);
8102     return (AssumedState != getAssumed()) ? ChangeStatus::CHANGED
8103                                           : ChangeStatus::UNCHANGED;
8104   }
8105 
8106   // Visit and expand uses until all are analyzed or a fixpoint is reached.
8107   auto UsePred = [&](const Use &U, bool &Follow) -> bool {
8108     Instruction *UserI = cast<Instruction>(U.getUser());
8109     LLVM_DEBUG(dbgs() << "[AAMemoryBehavior] Use: " << *U << " in " << *UserI
8110                       << " \n");
8111 
8112     // Droppable users, e.g., llvm::assume does not actually perform any action.
8113     if (UserI->isDroppable())
8114       return true;
8115 
8116     // Check if the users of UserI should also be visited.
8117     Follow = followUsersOfUseIn(A, U, UserI);
8118 
8119     // If UserI might touch memory we analyze the use in detail.
8120     if (UserI->mayReadOrWriteMemory())
8121       analyzeUseIn(A, U, UserI);
8122 
8123     return !isAtFixpoint();
8124   };
8125 
8126   if (!A.checkForAllUses(UsePred, *this, getAssociatedValue()))
8127     return indicatePessimisticFixpoint();
8128 
8129   return (AssumedState != getAssumed()) ? ChangeStatus::CHANGED
8130                                         : ChangeStatus::UNCHANGED;
8131 }
8132 
8133 bool AAMemoryBehaviorFloating::followUsersOfUseIn(Attributor &A, const Use &U,
8134                                                   const Instruction *UserI) {
8135   // The loaded value is unrelated to the pointer argument, no need to
8136   // follow the users of the load.
8137   if (isa<LoadInst>(UserI) || isa<ReturnInst>(UserI))
8138     return false;
8139 
8140   // By default we follow all uses assuming UserI might leak information on U,
8141   // we have special handling for call sites operands though.
8142   const auto *CB = dyn_cast<CallBase>(UserI);
8143   if (!CB || !CB->isArgOperand(&U))
8144     return true;
8145 
8146   // If the use is a call argument known not to be captured, the users of
8147   // the call do not need to be visited because they have to be unrelated to
8148   // the input. Note that this check is not trivial even though we disallow
8149   // general capturing of the underlying argument. The reason is that the
8150   // call might the argument "through return", which we allow and for which we
8151   // need to check call users.
8152   if (U.get()->getType()->isPointerTy()) {
8153     unsigned ArgNo = CB->getArgOperandNo(&U);
8154     const auto &ArgNoCaptureAA = A.getAAFor<AANoCapture>(
8155         *this, IRPosition::callsite_argument(*CB, ArgNo), DepClassTy::OPTIONAL);
8156     return !ArgNoCaptureAA.isAssumedNoCapture();
8157   }
8158 
8159   return true;
8160 }
8161 
8162 void AAMemoryBehaviorFloating::analyzeUseIn(Attributor &A, const Use &U,
8163                                             const Instruction *UserI) {
8164   assert(UserI->mayReadOrWriteMemory());
8165 
8166   switch (UserI->getOpcode()) {
8167   default:
8168     // TODO: Handle all atomics and other side-effect operations we know of.
8169     break;
8170   case Instruction::Load:
8171     // Loads cause the NO_READS property to disappear.
8172     removeAssumedBits(NO_READS);
8173     return;
8174 
8175   case Instruction::Store:
8176     // Stores cause the NO_WRITES property to disappear if the use is the
8177     // pointer operand. Note that while capturing was taken care of somewhere
8178     // else we need to deal with stores of the value that is not looked through.
8179     if (cast<StoreInst>(UserI)->getPointerOperand() == U.get())
8180       removeAssumedBits(NO_WRITES);
8181     else
8182       indicatePessimisticFixpoint();
8183     return;
8184 
8185   case Instruction::Call:
8186   case Instruction::CallBr:
8187   case Instruction::Invoke: {
8188     // For call sites we look at the argument memory behavior attribute (this
8189     // could be recursive!) in order to restrict our own state.
8190     const auto *CB = cast<CallBase>(UserI);
8191 
8192     // Give up on operand bundles.
8193     if (CB->isBundleOperand(&U)) {
8194       indicatePessimisticFixpoint();
8195       return;
8196     }
8197 
8198     // Calling a function does read the function pointer, maybe write it if the
8199     // function is self-modifying.
8200     if (CB->isCallee(&U)) {
8201       removeAssumedBits(NO_READS);
8202       break;
8203     }
8204 
8205     // Adjust the possible access behavior based on the information on the
8206     // argument.
8207     IRPosition Pos;
8208     if (U.get()->getType()->isPointerTy())
8209       Pos = IRPosition::callsite_argument(*CB, CB->getArgOperandNo(&U));
8210     else
8211       Pos = IRPosition::callsite_function(*CB);
8212     const auto &MemBehaviorAA =
8213         A.getAAFor<AAMemoryBehavior>(*this, Pos, DepClassTy::OPTIONAL);
8214     // "assumed" has at most the same bits as the MemBehaviorAA assumed
8215     // and at least "known".
8216     intersectAssumedBits(MemBehaviorAA.getAssumed());
8217     return;
8218   }
8219   };
8220 
8221   // Generally, look at the "may-properties" and adjust the assumed state if we
8222   // did not trigger special handling before.
8223   if (UserI->mayReadFromMemory())
8224     removeAssumedBits(NO_READS);
8225   if (UserI->mayWriteToMemory())
8226     removeAssumedBits(NO_WRITES);
8227 }
8228 } // namespace
8229 
8230 /// -------------------- Memory Locations Attributes ---------------------------
8231 /// Includes read-none, argmemonly, inaccessiblememonly,
8232 /// inaccessiblememorargmemonly
8233 /// ----------------------------------------------------------------------------
8234 
8235 std::string AAMemoryLocation::getMemoryLocationsAsStr(
8236     AAMemoryLocation::MemoryLocationsKind MLK) {
8237   if (0 == (MLK & AAMemoryLocation::NO_LOCATIONS))
8238     return "all memory";
8239   if (MLK == AAMemoryLocation::NO_LOCATIONS)
8240     return "no memory";
8241   std::string S = "memory:";
8242   if (0 == (MLK & AAMemoryLocation::NO_LOCAL_MEM))
8243     S += "stack,";
8244   if (0 == (MLK & AAMemoryLocation::NO_CONST_MEM))
8245     S += "constant,";
8246   if (0 == (MLK & AAMemoryLocation::NO_GLOBAL_INTERNAL_MEM))
8247     S += "internal global,";
8248   if (0 == (MLK & AAMemoryLocation::NO_GLOBAL_EXTERNAL_MEM))
8249     S += "external global,";
8250   if (0 == (MLK & AAMemoryLocation::NO_ARGUMENT_MEM))
8251     S += "argument,";
8252   if (0 == (MLK & AAMemoryLocation::NO_INACCESSIBLE_MEM))
8253     S += "inaccessible,";
8254   if (0 == (MLK & AAMemoryLocation::NO_MALLOCED_MEM))
8255     S += "malloced,";
8256   if (0 == (MLK & AAMemoryLocation::NO_UNKOWN_MEM))
8257     S += "unknown,";
8258   S.pop_back();
8259   return S;
8260 }
8261 
8262 namespace {
8263 struct AAMemoryLocationImpl : public AAMemoryLocation {
8264 
8265   AAMemoryLocationImpl(const IRPosition &IRP, Attributor &A)
8266       : AAMemoryLocation(IRP, A), Allocator(A.Allocator) {
8267     AccessKind2Accesses.fill(nullptr);
8268   }
8269 
8270   ~AAMemoryLocationImpl() {
8271     // The AccessSets are allocated via a BumpPtrAllocator, we call
8272     // the destructor manually.
8273     for (AccessSet *AS : AccessKind2Accesses)
8274       if (AS)
8275         AS->~AccessSet();
8276   }
8277 
8278   /// See AbstractAttribute::initialize(...).
8279   void initialize(Attributor &A) override {
8280     intersectAssumedBits(BEST_STATE);
8281     getKnownStateFromValue(A, getIRPosition(), getState());
8282     AAMemoryLocation::initialize(A);
8283   }
8284 
8285   /// Return the memory behavior information encoded in the IR for \p IRP.
8286   static void getKnownStateFromValue(Attributor &A, const IRPosition &IRP,
8287                                      BitIntegerState &State,
8288                                      bool IgnoreSubsumingPositions = false) {
8289     // For internal functions we ignore `argmemonly` and
8290     // `inaccessiblememorargmemonly` as we might break it via interprocedural
8291     // constant propagation. It is unclear if this is the best way but it is
8292     // unlikely this will cause real performance problems. If we are deriving
8293     // attributes for the anchor function we even remove the attribute in
8294     // addition to ignoring it.
8295     // TODO: A better way to handle this would be to add ~NO_GLOBAL_MEM /
8296     // MemoryEffects::Other as a possible location.
8297     bool UseArgMemOnly = true;
8298     Function *AnchorFn = IRP.getAnchorScope();
8299     if (AnchorFn && A.isRunOn(*AnchorFn))
8300       UseArgMemOnly = !AnchorFn->hasLocalLinkage();
8301 
8302     SmallVector<Attribute, 2> Attrs;
8303     IRP.getAttrs({Attribute::Memory}, Attrs, IgnoreSubsumingPositions);
8304     for (const Attribute &Attr : Attrs) {
8305       // TODO: We can map MemoryEffects to Attributor locations more precisely.
8306       MemoryEffects ME = Attr.getMemoryEffects();
8307       if (ME.doesNotAccessMemory()) {
8308         State.addKnownBits(NO_LOCAL_MEM | NO_CONST_MEM);
8309         continue;
8310       }
8311       if (ME.onlyAccessesInaccessibleMem()) {
8312         State.addKnownBits(inverseLocation(NO_INACCESSIBLE_MEM, true, true));
8313         continue;
8314       }
8315       if (ME.onlyAccessesArgPointees()) {
8316         if (UseArgMemOnly)
8317           State.addKnownBits(inverseLocation(NO_ARGUMENT_MEM, true, true));
8318         else {
8319           // Remove location information, only keep read/write info.
8320           ME = MemoryEffects(ME.getModRef());
8321           IRAttributeManifest::manifestAttrs(
8322               A, IRP,
8323               Attribute::getWithMemoryEffects(IRP.getAnchorValue().getContext(),
8324                                               ME),
8325               /*ForceReplace*/ true);
8326         }
8327         continue;
8328       }
8329       if (ME.onlyAccessesInaccessibleOrArgMem()) {
8330         if (UseArgMemOnly)
8331           State.addKnownBits(inverseLocation(
8332               NO_INACCESSIBLE_MEM | NO_ARGUMENT_MEM, true, true));
8333         else {
8334           // Remove location information, only keep read/write info.
8335           ME = MemoryEffects(ME.getModRef());
8336           IRAttributeManifest::manifestAttrs(
8337               A, IRP,
8338               Attribute::getWithMemoryEffects(IRP.getAnchorValue().getContext(),
8339                                               ME),
8340               /*ForceReplace*/ true);
8341         }
8342         continue;
8343       }
8344     }
8345   }
8346 
8347   /// See AbstractAttribute::getDeducedAttributes(...).
8348   void getDeducedAttributes(LLVMContext &Ctx,
8349                             SmallVectorImpl<Attribute> &Attrs) const override {
8350     // TODO: We can map Attributor locations to MemoryEffects more precisely.
8351     assert(Attrs.size() == 0);
8352     if (getIRPosition().getPositionKind() == IRPosition::IRP_FUNCTION) {
8353       if (isAssumedReadNone())
8354         Attrs.push_back(
8355             Attribute::getWithMemoryEffects(Ctx, MemoryEffects::none()));
8356       else if (isAssumedInaccessibleMemOnly())
8357         Attrs.push_back(Attribute::getWithMemoryEffects(
8358             Ctx, MemoryEffects::inaccessibleMemOnly()));
8359       else if (isAssumedArgMemOnly())
8360         Attrs.push_back(
8361             Attribute::getWithMemoryEffects(Ctx, MemoryEffects::argMemOnly()));
8362       else if (isAssumedInaccessibleOrArgMemOnly())
8363         Attrs.push_back(Attribute::getWithMemoryEffects(
8364             Ctx, MemoryEffects::inaccessibleOrArgMemOnly()));
8365     }
8366     assert(Attrs.size() <= 1);
8367   }
8368 
8369   /// See AbstractAttribute::manifest(...).
8370   ChangeStatus manifest(Attributor &A) override {
8371     // TODO: If AAMemoryLocation and AAMemoryBehavior are merged, we could
8372     // provide per-location modref information here.
8373     const IRPosition &IRP = getIRPosition();
8374 
8375     SmallVector<Attribute, 1> DeducedAttrs;
8376     getDeducedAttributes(IRP.getAnchorValue().getContext(), DeducedAttrs);
8377     if (DeducedAttrs.size() != 1)
8378       return ChangeStatus::UNCHANGED;
8379     MemoryEffects ME = DeducedAttrs[0].getMemoryEffects();
8380 
8381     // Intersect with existing memory attribute, as we currently deduce the
8382     // location and modref portion separately.
8383     SmallVector<Attribute, 1> ExistingAttrs;
8384     IRP.getAttrs({Attribute::Memory}, ExistingAttrs,
8385                  /* IgnoreSubsumingPositions */ true);
8386     if (ExistingAttrs.size() == 1) {
8387       MemoryEffects ExistingME = ExistingAttrs[0].getMemoryEffects();
8388       ME &= ExistingME;
8389       if (ME == ExistingME)
8390         return ChangeStatus::UNCHANGED;
8391     }
8392 
8393     return IRAttributeManifest::manifestAttrs(
8394         A, IRP,
8395         Attribute::getWithMemoryEffects(IRP.getAnchorValue().getContext(), ME),
8396         /*ForceReplace*/ true);
8397   }
8398 
8399   /// See AAMemoryLocation::checkForAllAccessesToMemoryKind(...).
8400   bool checkForAllAccessesToMemoryKind(
8401       function_ref<bool(const Instruction *, const Value *, AccessKind,
8402                         MemoryLocationsKind)>
8403           Pred,
8404       MemoryLocationsKind RequestedMLK) const override {
8405     if (!isValidState())
8406       return false;
8407 
8408     MemoryLocationsKind AssumedMLK = getAssumedNotAccessedLocation();
8409     if (AssumedMLK == NO_LOCATIONS)
8410       return true;
8411 
8412     unsigned Idx = 0;
8413     for (MemoryLocationsKind CurMLK = 1; CurMLK < NO_LOCATIONS;
8414          CurMLK *= 2, ++Idx) {
8415       if (CurMLK & RequestedMLK)
8416         continue;
8417 
8418       if (const AccessSet *Accesses = AccessKind2Accesses[Idx])
8419         for (const AccessInfo &AI : *Accesses)
8420           if (!Pred(AI.I, AI.Ptr, AI.Kind, CurMLK))
8421             return false;
8422     }
8423 
8424     return true;
8425   }
8426 
8427   ChangeStatus indicatePessimisticFixpoint() override {
8428     // If we give up and indicate a pessimistic fixpoint this instruction will
8429     // become an access for all potential access kinds:
8430     // TODO: Add pointers for argmemonly and globals to improve the results of
8431     //       checkForAllAccessesToMemoryKind.
8432     bool Changed = false;
8433     MemoryLocationsKind KnownMLK = getKnown();
8434     Instruction *I = dyn_cast<Instruction>(&getAssociatedValue());
8435     for (MemoryLocationsKind CurMLK = 1; CurMLK < NO_LOCATIONS; CurMLK *= 2)
8436       if (!(CurMLK & KnownMLK))
8437         updateStateAndAccessesMap(getState(), CurMLK, I, nullptr, Changed,
8438                                   getAccessKindFromInst(I));
8439     return AAMemoryLocation::indicatePessimisticFixpoint();
8440   }
8441 
8442 protected:
8443   /// Helper struct to tie together an instruction that has a read or write
8444   /// effect with the pointer it accesses (if any).
8445   struct AccessInfo {
8446 
8447     /// The instruction that caused the access.
8448     const Instruction *I;
8449 
8450     /// The base pointer that is accessed, or null if unknown.
8451     const Value *Ptr;
8452 
8453     /// The kind of access (read/write/read+write).
8454     AccessKind Kind;
8455 
8456     bool operator==(const AccessInfo &RHS) const {
8457       return I == RHS.I && Ptr == RHS.Ptr && Kind == RHS.Kind;
8458     }
8459     bool operator()(const AccessInfo &LHS, const AccessInfo &RHS) const {
8460       if (LHS.I != RHS.I)
8461         return LHS.I < RHS.I;
8462       if (LHS.Ptr != RHS.Ptr)
8463         return LHS.Ptr < RHS.Ptr;
8464       if (LHS.Kind != RHS.Kind)
8465         return LHS.Kind < RHS.Kind;
8466       return false;
8467     }
8468   };
8469 
8470   /// Mapping from *single* memory location kinds, e.g., LOCAL_MEM with the
8471   /// value of NO_LOCAL_MEM, to the accesses encountered for this memory kind.
8472   using AccessSet = SmallSet<AccessInfo, 2, AccessInfo>;
8473   std::array<AccessSet *, llvm::CTLog2<VALID_STATE>()> AccessKind2Accesses;
8474 
8475   /// Categorize the pointer arguments of CB that might access memory in
8476   /// AccessedLoc and update the state and access map accordingly.
8477   void
8478   categorizeArgumentPointerLocations(Attributor &A, CallBase &CB,
8479                                      AAMemoryLocation::StateType &AccessedLocs,
8480                                      bool &Changed);
8481 
8482   /// Return the kind(s) of location that may be accessed by \p V.
8483   AAMemoryLocation::MemoryLocationsKind
8484   categorizeAccessedLocations(Attributor &A, Instruction &I, bool &Changed);
8485 
8486   /// Return the access kind as determined by \p I.
8487   AccessKind getAccessKindFromInst(const Instruction *I) {
8488     AccessKind AK = READ_WRITE;
8489     if (I) {
8490       AK = I->mayReadFromMemory() ? READ : NONE;
8491       AK = AccessKind(AK | (I->mayWriteToMemory() ? WRITE : NONE));
8492     }
8493     return AK;
8494   }
8495 
8496   /// Update the state \p State and the AccessKind2Accesses given that \p I is
8497   /// an access of kind \p AK to a \p MLK memory location with the access
8498   /// pointer \p Ptr.
8499   void updateStateAndAccessesMap(AAMemoryLocation::StateType &State,
8500                                  MemoryLocationsKind MLK, const Instruction *I,
8501                                  const Value *Ptr, bool &Changed,
8502                                  AccessKind AK = READ_WRITE) {
8503 
8504     assert(isPowerOf2_32(MLK) && "Expected a single location set!");
8505     auto *&Accesses = AccessKind2Accesses[llvm::Log2_32(MLK)];
8506     if (!Accesses)
8507       Accesses = new (Allocator) AccessSet();
8508     Changed |= Accesses->insert(AccessInfo{I, Ptr, AK}).second;
8509     State.removeAssumedBits(MLK);
8510   }
8511 
8512   /// Determine the underlying locations kinds for \p Ptr, e.g., globals or
8513   /// arguments, and update the state and access map accordingly.
8514   void categorizePtrValue(Attributor &A, const Instruction &I, const Value &Ptr,
8515                           AAMemoryLocation::StateType &State, bool &Changed);
8516 
8517   /// Used to allocate access sets.
8518   BumpPtrAllocator &Allocator;
8519 };
8520 
8521 void AAMemoryLocationImpl::categorizePtrValue(
8522     Attributor &A, const Instruction &I, const Value &Ptr,
8523     AAMemoryLocation::StateType &State, bool &Changed) {
8524   LLVM_DEBUG(dbgs() << "[AAMemoryLocation] Categorize pointer locations for "
8525                     << Ptr << " ["
8526                     << getMemoryLocationsAsStr(State.getAssumed()) << "]\n");
8527 
8528   auto Pred = [&](Value &Obj) {
8529     // TODO: recognize the TBAA used for constant accesses.
8530     MemoryLocationsKind MLK = NO_LOCATIONS;
8531     if (isa<UndefValue>(&Obj))
8532       return true;
8533     if (isa<Argument>(&Obj)) {
8534       // TODO: For now we do not treat byval arguments as local copies performed
8535       // on the call edge, though, we should. To make that happen we need to
8536       // teach various passes, e.g., DSE, about the copy effect of a byval. That
8537       // would also allow us to mark functions only accessing byval arguments as
8538       // readnone again, arguably their accesses have no effect outside of the
8539       // function, like accesses to allocas.
8540       MLK = NO_ARGUMENT_MEM;
8541     } else if (auto *GV = dyn_cast<GlobalValue>(&Obj)) {
8542       // Reading constant memory is not treated as a read "effect" by the
8543       // function attr pass so we won't neither. Constants defined by TBAA are
8544       // similar. (We know we do not write it because it is constant.)
8545       if (auto *GVar = dyn_cast<GlobalVariable>(GV))
8546         if (GVar->isConstant())
8547           return true;
8548 
8549       if (GV->hasLocalLinkage())
8550         MLK = NO_GLOBAL_INTERNAL_MEM;
8551       else
8552         MLK = NO_GLOBAL_EXTERNAL_MEM;
8553     } else if (isa<ConstantPointerNull>(&Obj) &&
8554                !NullPointerIsDefined(getAssociatedFunction(),
8555                                      Ptr.getType()->getPointerAddressSpace())) {
8556       return true;
8557     } else if (isa<AllocaInst>(&Obj)) {
8558       MLK = NO_LOCAL_MEM;
8559     } else if (const auto *CB = dyn_cast<CallBase>(&Obj)) {
8560       const auto &NoAliasAA = A.getAAFor<AANoAlias>(
8561           *this, IRPosition::callsite_returned(*CB), DepClassTy::OPTIONAL);
8562       if (NoAliasAA.isAssumedNoAlias())
8563         MLK = NO_MALLOCED_MEM;
8564       else
8565         MLK = NO_UNKOWN_MEM;
8566     } else {
8567       MLK = NO_UNKOWN_MEM;
8568     }
8569 
8570     assert(MLK != NO_LOCATIONS && "No location specified!");
8571     LLVM_DEBUG(dbgs() << "[AAMemoryLocation] Ptr value can be categorized: "
8572                       << Obj << " -> " << getMemoryLocationsAsStr(MLK) << "\n");
8573     updateStateAndAccessesMap(getState(), MLK, &I, &Obj, Changed,
8574                               getAccessKindFromInst(&I));
8575 
8576     return true;
8577   };
8578 
8579   const auto &AA = A.getAAFor<AAUnderlyingObjects>(
8580       *this, IRPosition::value(Ptr), DepClassTy::OPTIONAL);
8581   if (!AA.forallUnderlyingObjects(Pred, AA::Intraprocedural)) {
8582     LLVM_DEBUG(
8583         dbgs() << "[AAMemoryLocation] Pointer locations not categorized\n");
8584     updateStateAndAccessesMap(State, NO_UNKOWN_MEM, &I, nullptr, Changed,
8585                               getAccessKindFromInst(&I));
8586     return;
8587   }
8588 
8589   LLVM_DEBUG(
8590       dbgs() << "[AAMemoryLocation] Accessed locations with pointer locations: "
8591              << getMemoryLocationsAsStr(State.getAssumed()) << "\n");
8592 }
8593 
8594 void AAMemoryLocationImpl::categorizeArgumentPointerLocations(
8595     Attributor &A, CallBase &CB, AAMemoryLocation::StateType &AccessedLocs,
8596     bool &Changed) {
8597   for (unsigned ArgNo = 0, E = CB.arg_size(); ArgNo < E; ++ArgNo) {
8598 
8599     // Skip non-pointer arguments.
8600     const Value *ArgOp = CB.getArgOperand(ArgNo);
8601     if (!ArgOp->getType()->isPtrOrPtrVectorTy())
8602       continue;
8603 
8604     // Skip readnone arguments.
8605     const IRPosition &ArgOpIRP = IRPosition::callsite_argument(CB, ArgNo);
8606     const auto &ArgOpMemLocationAA =
8607         A.getAAFor<AAMemoryBehavior>(*this, ArgOpIRP, DepClassTy::OPTIONAL);
8608 
8609     if (ArgOpMemLocationAA.isAssumedReadNone())
8610       continue;
8611 
8612     // Categorize potentially accessed pointer arguments as if there was an
8613     // access instruction with them as pointer.
8614     categorizePtrValue(A, CB, *ArgOp, AccessedLocs, Changed);
8615   }
8616 }
8617 
8618 AAMemoryLocation::MemoryLocationsKind
8619 AAMemoryLocationImpl::categorizeAccessedLocations(Attributor &A, Instruction &I,
8620                                                   bool &Changed) {
8621   LLVM_DEBUG(dbgs() << "[AAMemoryLocation] Categorize accessed locations for "
8622                     << I << "\n");
8623 
8624   AAMemoryLocation::StateType AccessedLocs;
8625   AccessedLocs.intersectAssumedBits(NO_LOCATIONS);
8626 
8627   if (auto *CB = dyn_cast<CallBase>(&I)) {
8628 
8629     // First check if we assume any memory is access is visible.
8630     const auto &CBMemLocationAA = A.getAAFor<AAMemoryLocation>(
8631         *this, IRPosition::callsite_function(*CB), DepClassTy::OPTIONAL);
8632     LLVM_DEBUG(dbgs() << "[AAMemoryLocation] Categorize call site: " << I
8633                       << " [" << CBMemLocationAA << "]\n");
8634 
8635     if (CBMemLocationAA.isAssumedReadNone())
8636       return NO_LOCATIONS;
8637 
8638     if (CBMemLocationAA.isAssumedInaccessibleMemOnly()) {
8639       updateStateAndAccessesMap(AccessedLocs, NO_INACCESSIBLE_MEM, &I, nullptr,
8640                                 Changed, getAccessKindFromInst(&I));
8641       return AccessedLocs.getAssumed();
8642     }
8643 
8644     uint32_t CBAssumedNotAccessedLocs =
8645         CBMemLocationAA.getAssumedNotAccessedLocation();
8646 
8647     // Set the argmemonly and global bit as we handle them separately below.
8648     uint32_t CBAssumedNotAccessedLocsNoArgMem =
8649         CBAssumedNotAccessedLocs | NO_ARGUMENT_MEM | NO_GLOBAL_MEM;
8650 
8651     for (MemoryLocationsKind CurMLK = 1; CurMLK < NO_LOCATIONS; CurMLK *= 2) {
8652       if (CBAssumedNotAccessedLocsNoArgMem & CurMLK)
8653         continue;
8654       updateStateAndAccessesMap(AccessedLocs, CurMLK, &I, nullptr, Changed,
8655                                 getAccessKindFromInst(&I));
8656     }
8657 
8658     // Now handle global memory if it might be accessed. This is slightly tricky
8659     // as NO_GLOBAL_MEM has multiple bits set.
8660     bool HasGlobalAccesses = ((~CBAssumedNotAccessedLocs) & NO_GLOBAL_MEM);
8661     if (HasGlobalAccesses) {
8662       auto AccessPred = [&](const Instruction *, const Value *Ptr,
8663                             AccessKind Kind, MemoryLocationsKind MLK) {
8664         updateStateAndAccessesMap(AccessedLocs, MLK, &I, Ptr, Changed,
8665                                   getAccessKindFromInst(&I));
8666         return true;
8667       };
8668       if (!CBMemLocationAA.checkForAllAccessesToMemoryKind(
8669               AccessPred, inverseLocation(NO_GLOBAL_MEM, false, false)))
8670         return AccessedLocs.getWorstState();
8671     }
8672 
8673     LLVM_DEBUG(
8674         dbgs() << "[AAMemoryLocation] Accessed state before argument handling: "
8675                << getMemoryLocationsAsStr(AccessedLocs.getAssumed()) << "\n");
8676 
8677     // Now handle argument memory if it might be accessed.
8678     bool HasArgAccesses = ((~CBAssumedNotAccessedLocs) & NO_ARGUMENT_MEM);
8679     if (HasArgAccesses)
8680       categorizeArgumentPointerLocations(A, *CB, AccessedLocs, Changed);
8681 
8682     LLVM_DEBUG(
8683         dbgs() << "[AAMemoryLocation] Accessed state after argument handling: "
8684                << getMemoryLocationsAsStr(AccessedLocs.getAssumed()) << "\n");
8685 
8686     return AccessedLocs.getAssumed();
8687   }
8688 
8689   if (const Value *Ptr = getPointerOperand(&I, /* AllowVolatile */ true)) {
8690     LLVM_DEBUG(
8691         dbgs() << "[AAMemoryLocation] Categorize memory access with pointer: "
8692                << I << " [" << *Ptr << "]\n");
8693     categorizePtrValue(A, I, *Ptr, AccessedLocs, Changed);
8694     return AccessedLocs.getAssumed();
8695   }
8696 
8697   LLVM_DEBUG(dbgs() << "[AAMemoryLocation] Failed to categorize instruction: "
8698                     << I << "\n");
8699   updateStateAndAccessesMap(AccessedLocs, NO_UNKOWN_MEM, &I, nullptr, Changed,
8700                             getAccessKindFromInst(&I));
8701   return AccessedLocs.getAssumed();
8702 }
8703 
8704 /// An AA to represent the memory behavior function attributes.
8705 struct AAMemoryLocationFunction final : public AAMemoryLocationImpl {
8706   AAMemoryLocationFunction(const IRPosition &IRP, Attributor &A)
8707       : AAMemoryLocationImpl(IRP, A) {}
8708 
8709   /// See AbstractAttribute::updateImpl(Attributor &A).
8710   ChangeStatus updateImpl(Attributor &A) override {
8711 
8712     const auto &MemBehaviorAA =
8713         A.getAAFor<AAMemoryBehavior>(*this, getIRPosition(), DepClassTy::NONE);
8714     if (MemBehaviorAA.isAssumedReadNone()) {
8715       if (MemBehaviorAA.isKnownReadNone())
8716         return indicateOptimisticFixpoint();
8717       assert(isAssumedReadNone() &&
8718              "AAMemoryLocation was not read-none but AAMemoryBehavior was!");
8719       A.recordDependence(MemBehaviorAA, *this, DepClassTy::OPTIONAL);
8720       return ChangeStatus::UNCHANGED;
8721     }
8722 
8723     // The current assumed state used to determine a change.
8724     auto AssumedState = getAssumed();
8725     bool Changed = false;
8726 
8727     auto CheckRWInst = [&](Instruction &I) {
8728       MemoryLocationsKind MLK = categorizeAccessedLocations(A, I, Changed);
8729       LLVM_DEBUG(dbgs() << "[AAMemoryLocation] Accessed locations for " << I
8730                         << ": " << getMemoryLocationsAsStr(MLK) << "\n");
8731       removeAssumedBits(inverseLocation(MLK, false, false));
8732       // Stop once only the valid bit set in the *not assumed location*, thus
8733       // once we don't actually exclude any memory locations in the state.
8734       return getAssumedNotAccessedLocation() != VALID_STATE;
8735     };
8736 
8737     bool UsedAssumedInformation = false;
8738     if (!A.checkForAllReadWriteInstructions(CheckRWInst, *this,
8739                                             UsedAssumedInformation))
8740       return indicatePessimisticFixpoint();
8741 
8742     Changed |= AssumedState != getAssumed();
8743     return Changed ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED;
8744   }
8745 
8746   /// See AbstractAttribute::trackStatistics()
8747   void trackStatistics() const override {
8748     if (isAssumedReadNone())
8749       STATS_DECLTRACK_FN_ATTR(readnone)
8750     else if (isAssumedArgMemOnly())
8751       STATS_DECLTRACK_FN_ATTR(argmemonly)
8752     else if (isAssumedInaccessibleMemOnly())
8753       STATS_DECLTRACK_FN_ATTR(inaccessiblememonly)
8754     else if (isAssumedInaccessibleOrArgMemOnly())
8755       STATS_DECLTRACK_FN_ATTR(inaccessiblememorargmemonly)
8756   }
8757 };
8758 
8759 /// AAMemoryLocation attribute for call sites.
8760 struct AAMemoryLocationCallSite final : AAMemoryLocationImpl {
8761   AAMemoryLocationCallSite(const IRPosition &IRP, Attributor &A)
8762       : AAMemoryLocationImpl(IRP, A) {}
8763 
8764   /// See AbstractAttribute::initialize(...).
8765   void initialize(Attributor &A) override {
8766     AAMemoryLocationImpl::initialize(A);
8767     Function *F = getAssociatedFunction();
8768     if (!F || F->isDeclaration())
8769       indicatePessimisticFixpoint();
8770   }
8771 
8772   /// See AbstractAttribute::updateImpl(...).
8773   ChangeStatus updateImpl(Attributor &A) override {
8774     // TODO: Once we have call site specific value information we can provide
8775     //       call site specific liveness liveness information and then it makes
8776     //       sense to specialize attributes for call sites arguments instead of
8777     //       redirecting requests to the callee argument.
8778     Function *F = getAssociatedFunction();
8779     const IRPosition &FnPos = IRPosition::function(*F);
8780     auto &FnAA =
8781         A.getAAFor<AAMemoryLocation>(*this, FnPos, DepClassTy::REQUIRED);
8782     bool Changed = false;
8783     auto AccessPred = [&](const Instruction *I, const Value *Ptr,
8784                           AccessKind Kind, MemoryLocationsKind MLK) {
8785       updateStateAndAccessesMap(getState(), MLK, I, Ptr, Changed,
8786                                 getAccessKindFromInst(I));
8787       return true;
8788     };
8789     if (!FnAA.checkForAllAccessesToMemoryKind(AccessPred, ALL_LOCATIONS))
8790       return indicatePessimisticFixpoint();
8791     return Changed ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED;
8792   }
8793 
8794   /// See AbstractAttribute::trackStatistics()
8795   void trackStatistics() const override {
8796     if (isAssumedReadNone())
8797       STATS_DECLTRACK_CS_ATTR(readnone)
8798   }
8799 };
8800 } // namespace
8801 
8802 /// ------------------ Value Constant Range Attribute -------------------------
8803 
8804 namespace {
8805 struct AAValueConstantRangeImpl : AAValueConstantRange {
8806   using StateType = IntegerRangeState;
8807   AAValueConstantRangeImpl(const IRPosition &IRP, Attributor &A)
8808       : AAValueConstantRange(IRP, A) {}
8809 
8810   /// See AbstractAttribute::initialize(..).
8811   void initialize(Attributor &A) override {
8812     if (A.hasSimplificationCallback(getIRPosition())) {
8813       indicatePessimisticFixpoint();
8814       return;
8815     }
8816 
8817     // Intersect a range given by SCEV.
8818     intersectKnown(getConstantRangeFromSCEV(A, getCtxI()));
8819 
8820     // Intersect a range given by LVI.
8821     intersectKnown(getConstantRangeFromLVI(A, getCtxI()));
8822   }
8823 
8824   /// See AbstractAttribute::getAsStr().
8825   const std::string getAsStr() const override {
8826     std::string Str;
8827     llvm::raw_string_ostream OS(Str);
8828     OS << "range(" << getBitWidth() << ")<";
8829     getKnown().print(OS);
8830     OS << " / ";
8831     getAssumed().print(OS);
8832     OS << ">";
8833     return OS.str();
8834   }
8835 
8836   /// Helper function to get a SCEV expr for the associated value at program
8837   /// point \p I.
8838   const SCEV *getSCEV(Attributor &A, const Instruction *I = nullptr) const {
8839     if (!getAnchorScope())
8840       return nullptr;
8841 
8842     ScalarEvolution *SE =
8843         A.getInfoCache().getAnalysisResultForFunction<ScalarEvolutionAnalysis>(
8844             *getAnchorScope());
8845 
8846     LoopInfo *LI = A.getInfoCache().getAnalysisResultForFunction<LoopAnalysis>(
8847         *getAnchorScope());
8848 
8849     if (!SE || !LI)
8850       return nullptr;
8851 
8852     const SCEV *S = SE->getSCEV(&getAssociatedValue());
8853     if (!I)
8854       return S;
8855 
8856     return SE->getSCEVAtScope(S, LI->getLoopFor(I->getParent()));
8857   }
8858 
8859   /// Helper function to get a range from SCEV for the associated value at
8860   /// program point \p I.
8861   ConstantRange getConstantRangeFromSCEV(Attributor &A,
8862                                          const Instruction *I = nullptr) const {
8863     if (!getAnchorScope())
8864       return getWorstState(getBitWidth());
8865 
8866     ScalarEvolution *SE =
8867         A.getInfoCache().getAnalysisResultForFunction<ScalarEvolutionAnalysis>(
8868             *getAnchorScope());
8869 
8870     const SCEV *S = getSCEV(A, I);
8871     if (!SE || !S)
8872       return getWorstState(getBitWidth());
8873 
8874     return SE->getUnsignedRange(S);
8875   }
8876 
8877   /// Helper function to get a range from LVI for the associated value at
8878   /// program point \p I.
8879   ConstantRange
8880   getConstantRangeFromLVI(Attributor &A,
8881                           const Instruction *CtxI = nullptr) const {
8882     if (!getAnchorScope())
8883       return getWorstState(getBitWidth());
8884 
8885     LazyValueInfo *LVI =
8886         A.getInfoCache().getAnalysisResultForFunction<LazyValueAnalysis>(
8887             *getAnchorScope());
8888 
8889     if (!LVI || !CtxI)
8890       return getWorstState(getBitWidth());
8891     return LVI->getConstantRange(&getAssociatedValue(),
8892                                  const_cast<Instruction *>(CtxI));
8893   }
8894 
8895   /// Return true if \p CtxI is valid for querying outside analyses.
8896   /// This basically makes sure we do not ask intra-procedural analysis
8897   /// about a context in the wrong function or a context that violates
8898   /// dominance assumptions they might have. The \p AllowAACtxI flag indicates
8899   /// if the original context of this AA is OK or should be considered invalid.
8900   bool isValidCtxInstructionForOutsideAnalysis(Attributor &A,
8901                                                const Instruction *CtxI,
8902                                                bool AllowAACtxI) const {
8903     if (!CtxI || (!AllowAACtxI && CtxI == getCtxI()))
8904       return false;
8905 
8906     // Our context might be in a different function, neither intra-procedural
8907     // analysis (ScalarEvolution nor LazyValueInfo) can handle that.
8908     if (!AA::isValidInScope(getAssociatedValue(), CtxI->getFunction()))
8909       return false;
8910 
8911     // If the context is not dominated by the value there are paths to the
8912     // context that do not define the value. This cannot be handled by
8913     // LazyValueInfo so we need to bail.
8914     if (auto *I = dyn_cast<Instruction>(&getAssociatedValue())) {
8915       InformationCache &InfoCache = A.getInfoCache();
8916       const DominatorTree *DT =
8917           InfoCache.getAnalysisResultForFunction<DominatorTreeAnalysis>(
8918               *I->getFunction());
8919       return DT && DT->dominates(I, CtxI);
8920     }
8921 
8922     return true;
8923   }
8924 
8925   /// See AAValueConstantRange::getKnownConstantRange(..).
8926   ConstantRange
8927   getKnownConstantRange(Attributor &A,
8928                         const Instruction *CtxI = nullptr) const override {
8929     if (!isValidCtxInstructionForOutsideAnalysis(A, CtxI,
8930                                                  /* AllowAACtxI */ false))
8931       return getKnown();
8932 
8933     ConstantRange LVIR = getConstantRangeFromLVI(A, CtxI);
8934     ConstantRange SCEVR = getConstantRangeFromSCEV(A, CtxI);
8935     return getKnown().intersectWith(SCEVR).intersectWith(LVIR);
8936   }
8937 
8938   /// See AAValueConstantRange::getAssumedConstantRange(..).
8939   ConstantRange
8940   getAssumedConstantRange(Attributor &A,
8941                           const Instruction *CtxI = nullptr) const override {
8942     // TODO: Make SCEV use Attributor assumption.
8943     //       We may be able to bound a variable range via assumptions in
8944     //       Attributor. ex.) If x is assumed to be in [1, 3] and y is known to
8945     //       evolve to x^2 + x, then we can say that y is in [2, 12].
8946     if (!isValidCtxInstructionForOutsideAnalysis(A, CtxI,
8947                                                  /* AllowAACtxI */ false))
8948       return getAssumed();
8949 
8950     ConstantRange LVIR = getConstantRangeFromLVI(A, CtxI);
8951     ConstantRange SCEVR = getConstantRangeFromSCEV(A, CtxI);
8952     return getAssumed().intersectWith(SCEVR).intersectWith(LVIR);
8953   }
8954 
8955   /// Helper function to create MDNode for range metadata.
8956   static MDNode *
8957   getMDNodeForConstantRange(Type *Ty, LLVMContext &Ctx,
8958                             const ConstantRange &AssumedConstantRange) {
8959     Metadata *LowAndHigh[] = {ConstantAsMetadata::get(ConstantInt::get(
8960                                   Ty, AssumedConstantRange.getLower())),
8961                               ConstantAsMetadata::get(ConstantInt::get(
8962                                   Ty, AssumedConstantRange.getUpper()))};
8963     return MDNode::get(Ctx, LowAndHigh);
8964   }
8965 
8966   /// Return true if \p Assumed is included in \p KnownRanges.
8967   static bool isBetterRange(const ConstantRange &Assumed, MDNode *KnownRanges) {
8968 
8969     if (Assumed.isFullSet())
8970       return false;
8971 
8972     if (!KnownRanges)
8973       return true;
8974 
8975     // If multiple ranges are annotated in IR, we give up to annotate assumed
8976     // range for now.
8977 
8978     // TODO:  If there exists a known range which containts assumed range, we
8979     // can say assumed range is better.
8980     if (KnownRanges->getNumOperands() > 2)
8981       return false;
8982 
8983     ConstantInt *Lower =
8984         mdconst::extract<ConstantInt>(KnownRanges->getOperand(0));
8985     ConstantInt *Upper =
8986         mdconst::extract<ConstantInt>(KnownRanges->getOperand(1));
8987 
8988     ConstantRange Known(Lower->getValue(), Upper->getValue());
8989     return Known.contains(Assumed) && Known != Assumed;
8990   }
8991 
8992   /// Helper function to set range metadata.
8993   static bool
8994   setRangeMetadataIfisBetterRange(Instruction *I,
8995                                   const ConstantRange &AssumedConstantRange) {
8996     auto *OldRangeMD = I->getMetadata(LLVMContext::MD_range);
8997     if (isBetterRange(AssumedConstantRange, OldRangeMD)) {
8998       if (!AssumedConstantRange.isEmptySet()) {
8999         I->setMetadata(LLVMContext::MD_range,
9000                        getMDNodeForConstantRange(I->getType(), I->getContext(),
9001                                                  AssumedConstantRange));
9002         return true;
9003       }
9004     }
9005     return false;
9006   }
9007 
9008   /// See AbstractAttribute::manifest()
9009   ChangeStatus manifest(Attributor &A) override {
9010     ChangeStatus Changed = ChangeStatus::UNCHANGED;
9011     ConstantRange AssumedConstantRange = getAssumedConstantRange(A);
9012     assert(!AssumedConstantRange.isFullSet() && "Invalid state");
9013 
9014     auto &V = getAssociatedValue();
9015     if (!AssumedConstantRange.isEmptySet() &&
9016         !AssumedConstantRange.isSingleElement()) {
9017       if (Instruction *I = dyn_cast<Instruction>(&V)) {
9018         assert(I == getCtxI() && "Should not annotate an instruction which is "
9019                                  "not the context instruction");
9020         if (isa<CallInst>(I) || isa<LoadInst>(I))
9021           if (setRangeMetadataIfisBetterRange(I, AssumedConstantRange))
9022             Changed = ChangeStatus::CHANGED;
9023       }
9024     }
9025 
9026     return Changed;
9027   }
9028 };
9029 
9030 struct AAValueConstantRangeArgument final
9031     : AAArgumentFromCallSiteArguments<
9032           AAValueConstantRange, AAValueConstantRangeImpl, IntegerRangeState,
9033           true /* BridgeCallBaseContext */> {
9034   using Base = AAArgumentFromCallSiteArguments<
9035       AAValueConstantRange, AAValueConstantRangeImpl, IntegerRangeState,
9036       true /* BridgeCallBaseContext */>;
9037   AAValueConstantRangeArgument(const IRPosition &IRP, Attributor &A)
9038       : Base(IRP, A) {}
9039 
9040   /// See AbstractAttribute::initialize(..).
9041   void initialize(Attributor &A) override {
9042     if (!getAnchorScope() || getAnchorScope()->isDeclaration()) {
9043       indicatePessimisticFixpoint();
9044     } else {
9045       Base::initialize(A);
9046     }
9047   }
9048 
9049   /// See AbstractAttribute::trackStatistics()
9050   void trackStatistics() const override {
9051     STATS_DECLTRACK_ARG_ATTR(value_range)
9052   }
9053 };
9054 
9055 struct AAValueConstantRangeReturned
9056     : AAReturnedFromReturnedValues<AAValueConstantRange,
9057                                    AAValueConstantRangeImpl,
9058                                    AAValueConstantRangeImpl::StateType,
9059                                    /* PropogateCallBaseContext */ true> {
9060   using Base =
9061       AAReturnedFromReturnedValues<AAValueConstantRange,
9062                                    AAValueConstantRangeImpl,
9063                                    AAValueConstantRangeImpl::StateType,
9064                                    /* PropogateCallBaseContext */ true>;
9065   AAValueConstantRangeReturned(const IRPosition &IRP, Attributor &A)
9066       : Base(IRP, A) {}
9067 
9068   /// See AbstractAttribute::initialize(...).
9069   void initialize(Attributor &A) override {}
9070 
9071   /// See AbstractAttribute::trackStatistics()
9072   void trackStatistics() const override {
9073     STATS_DECLTRACK_FNRET_ATTR(value_range)
9074   }
9075 };
9076 
9077 struct AAValueConstantRangeFloating : AAValueConstantRangeImpl {
9078   AAValueConstantRangeFloating(const IRPosition &IRP, Attributor &A)
9079       : AAValueConstantRangeImpl(IRP, A) {}
9080 
9081   /// See AbstractAttribute::initialize(...).
9082   void initialize(Attributor &A) override {
9083     AAValueConstantRangeImpl::initialize(A);
9084     if (isAtFixpoint())
9085       return;
9086 
9087     Value &V = getAssociatedValue();
9088 
9089     if (auto *C = dyn_cast<ConstantInt>(&V)) {
9090       unionAssumed(ConstantRange(C->getValue()));
9091       indicateOptimisticFixpoint();
9092       return;
9093     }
9094 
9095     if (isa<UndefValue>(&V)) {
9096       // Collapse the undef state to 0.
9097       unionAssumed(ConstantRange(APInt(getBitWidth(), 0)));
9098       indicateOptimisticFixpoint();
9099       return;
9100     }
9101 
9102     if (isa<CallBase>(&V))
9103       return;
9104 
9105     if (isa<BinaryOperator>(&V) || isa<CmpInst>(&V) || isa<CastInst>(&V))
9106       return;
9107 
9108     // If it is a load instruction with range metadata, use it.
9109     if (LoadInst *LI = dyn_cast<LoadInst>(&V))
9110       if (auto *RangeMD = LI->getMetadata(LLVMContext::MD_range)) {
9111         intersectKnown(getConstantRangeFromMetadata(*RangeMD));
9112         return;
9113       }
9114 
9115     // We can work with PHI and select instruction as we traverse their operands
9116     // during update.
9117     if (isa<SelectInst>(V) || isa<PHINode>(V))
9118       return;
9119 
9120     // Otherwise we give up.
9121     indicatePessimisticFixpoint();
9122 
9123     LLVM_DEBUG(dbgs() << "[AAValueConstantRange] We give up: "
9124                       << getAssociatedValue() << "\n");
9125   }
9126 
9127   bool calculateBinaryOperator(
9128       Attributor &A, BinaryOperator *BinOp, IntegerRangeState &T,
9129       const Instruction *CtxI,
9130       SmallVectorImpl<const AAValueConstantRange *> &QuerriedAAs) {
9131     Value *LHS = BinOp->getOperand(0);
9132     Value *RHS = BinOp->getOperand(1);
9133 
9134     // Simplify the operands first.
9135     bool UsedAssumedInformation = false;
9136     const auto &SimplifiedLHS = A.getAssumedSimplified(
9137         IRPosition::value(*LHS, getCallBaseContext()), *this,
9138         UsedAssumedInformation, AA::Interprocedural);
9139     if (!SimplifiedLHS.has_value())
9140       return true;
9141     if (!*SimplifiedLHS)
9142       return false;
9143     LHS = *SimplifiedLHS;
9144 
9145     const auto &SimplifiedRHS = A.getAssumedSimplified(
9146         IRPosition::value(*RHS, getCallBaseContext()), *this,
9147         UsedAssumedInformation, AA::Interprocedural);
9148     if (!SimplifiedRHS.has_value())
9149       return true;
9150     if (!*SimplifiedRHS)
9151       return false;
9152     RHS = *SimplifiedRHS;
9153 
9154     // TODO: Allow non integers as well.
9155     if (!LHS->getType()->isIntegerTy() || !RHS->getType()->isIntegerTy())
9156       return false;
9157 
9158     auto &LHSAA = A.getAAFor<AAValueConstantRange>(
9159         *this, IRPosition::value(*LHS, getCallBaseContext()),
9160         DepClassTy::REQUIRED);
9161     QuerriedAAs.push_back(&LHSAA);
9162     auto LHSAARange = LHSAA.getAssumedConstantRange(A, CtxI);
9163 
9164     auto &RHSAA = A.getAAFor<AAValueConstantRange>(
9165         *this, IRPosition::value(*RHS, getCallBaseContext()),
9166         DepClassTy::REQUIRED);
9167     QuerriedAAs.push_back(&RHSAA);
9168     auto RHSAARange = RHSAA.getAssumedConstantRange(A, CtxI);
9169 
9170     auto AssumedRange = LHSAARange.binaryOp(BinOp->getOpcode(), RHSAARange);
9171 
9172     T.unionAssumed(AssumedRange);
9173 
9174     // TODO: Track a known state too.
9175 
9176     return T.isValidState();
9177   }
9178 
9179   bool calculateCastInst(
9180       Attributor &A, CastInst *CastI, IntegerRangeState &T,
9181       const Instruction *CtxI,
9182       SmallVectorImpl<const AAValueConstantRange *> &QuerriedAAs) {
9183     assert(CastI->getNumOperands() == 1 && "Expected cast to be unary!");
9184     // TODO: Allow non integers as well.
9185     Value *OpV = CastI->getOperand(0);
9186 
9187     // Simplify the operand first.
9188     bool UsedAssumedInformation = false;
9189     const auto &SimplifiedOpV = A.getAssumedSimplified(
9190         IRPosition::value(*OpV, getCallBaseContext()), *this,
9191         UsedAssumedInformation, AA::Interprocedural);
9192     if (!SimplifiedOpV.has_value())
9193       return true;
9194     if (!*SimplifiedOpV)
9195       return false;
9196     OpV = *SimplifiedOpV;
9197 
9198     if (!OpV->getType()->isIntegerTy())
9199       return false;
9200 
9201     auto &OpAA = A.getAAFor<AAValueConstantRange>(
9202         *this, IRPosition::value(*OpV, getCallBaseContext()),
9203         DepClassTy::REQUIRED);
9204     QuerriedAAs.push_back(&OpAA);
9205     T.unionAssumed(
9206         OpAA.getAssumed().castOp(CastI->getOpcode(), getState().getBitWidth()));
9207     return T.isValidState();
9208   }
9209 
9210   bool
9211   calculateCmpInst(Attributor &A, CmpInst *CmpI, IntegerRangeState &T,
9212                    const Instruction *CtxI,
9213                    SmallVectorImpl<const AAValueConstantRange *> &QuerriedAAs) {
9214     Value *LHS = CmpI->getOperand(0);
9215     Value *RHS = CmpI->getOperand(1);
9216 
9217     // Simplify the operands first.
9218     bool UsedAssumedInformation = false;
9219     const auto &SimplifiedLHS = A.getAssumedSimplified(
9220         IRPosition::value(*LHS, getCallBaseContext()), *this,
9221         UsedAssumedInformation, AA::Interprocedural);
9222     if (!SimplifiedLHS.has_value())
9223       return true;
9224     if (!*SimplifiedLHS)
9225       return false;
9226     LHS = *SimplifiedLHS;
9227 
9228     const auto &SimplifiedRHS = A.getAssumedSimplified(
9229         IRPosition::value(*RHS, getCallBaseContext()), *this,
9230         UsedAssumedInformation, AA::Interprocedural);
9231     if (!SimplifiedRHS.has_value())
9232       return true;
9233     if (!*SimplifiedRHS)
9234       return false;
9235     RHS = *SimplifiedRHS;
9236 
9237     // TODO: Allow non integers as well.
9238     if (!LHS->getType()->isIntegerTy() || !RHS->getType()->isIntegerTy())
9239       return false;
9240 
9241     auto &LHSAA = A.getAAFor<AAValueConstantRange>(
9242         *this, IRPosition::value(*LHS, getCallBaseContext()),
9243         DepClassTy::REQUIRED);
9244     QuerriedAAs.push_back(&LHSAA);
9245     auto &RHSAA = A.getAAFor<AAValueConstantRange>(
9246         *this, IRPosition::value(*RHS, getCallBaseContext()),
9247         DepClassTy::REQUIRED);
9248     QuerriedAAs.push_back(&RHSAA);
9249     auto LHSAARange = LHSAA.getAssumedConstantRange(A, CtxI);
9250     auto RHSAARange = RHSAA.getAssumedConstantRange(A, CtxI);
9251 
9252     // If one of them is empty set, we can't decide.
9253     if (LHSAARange.isEmptySet() || RHSAARange.isEmptySet())
9254       return true;
9255 
9256     bool MustTrue = false, MustFalse = false;
9257 
9258     auto AllowedRegion =
9259         ConstantRange::makeAllowedICmpRegion(CmpI->getPredicate(), RHSAARange);
9260 
9261     if (AllowedRegion.intersectWith(LHSAARange).isEmptySet())
9262       MustFalse = true;
9263 
9264     if (LHSAARange.icmp(CmpI->getPredicate(), RHSAARange))
9265       MustTrue = true;
9266 
9267     assert((!MustTrue || !MustFalse) &&
9268            "Either MustTrue or MustFalse should be false!");
9269 
9270     if (MustTrue)
9271       T.unionAssumed(ConstantRange(APInt(/* numBits */ 1, /* val */ 1)));
9272     else if (MustFalse)
9273       T.unionAssumed(ConstantRange(APInt(/* numBits */ 1, /* val */ 0)));
9274     else
9275       T.unionAssumed(ConstantRange(/* BitWidth */ 1, /* isFullSet */ true));
9276 
9277     LLVM_DEBUG(dbgs() << "[AAValueConstantRange] " << *CmpI << " " << LHSAA
9278                       << " " << RHSAA << "\n");
9279 
9280     // TODO: Track a known state too.
9281     return T.isValidState();
9282   }
9283 
9284   /// See AbstractAttribute::updateImpl(...).
9285   ChangeStatus updateImpl(Attributor &A) override {
9286 
9287     IntegerRangeState T(getBitWidth());
9288     auto VisitValueCB = [&](Value &V, const Instruction *CtxI) -> bool {
9289       Instruction *I = dyn_cast<Instruction>(&V);
9290       if (!I || isa<CallBase>(I)) {
9291 
9292         // Simplify the operand first.
9293         bool UsedAssumedInformation = false;
9294         const auto &SimplifiedOpV = A.getAssumedSimplified(
9295             IRPosition::value(V, getCallBaseContext()), *this,
9296             UsedAssumedInformation, AA::Interprocedural);
9297         if (!SimplifiedOpV.has_value())
9298           return true;
9299         if (!*SimplifiedOpV)
9300           return false;
9301         Value *VPtr = *SimplifiedOpV;
9302 
9303         // If the value is not instruction, we query AA to Attributor.
9304         const auto &AA = A.getAAFor<AAValueConstantRange>(
9305             *this, IRPosition::value(*VPtr, getCallBaseContext()),
9306             DepClassTy::REQUIRED);
9307 
9308         // Clamp operator is not used to utilize a program point CtxI.
9309         T.unionAssumed(AA.getAssumedConstantRange(A, CtxI));
9310 
9311         return T.isValidState();
9312       }
9313 
9314       SmallVector<const AAValueConstantRange *, 4> QuerriedAAs;
9315       if (auto *BinOp = dyn_cast<BinaryOperator>(I)) {
9316         if (!calculateBinaryOperator(A, BinOp, T, CtxI, QuerriedAAs))
9317           return false;
9318       } else if (auto *CmpI = dyn_cast<CmpInst>(I)) {
9319         if (!calculateCmpInst(A, CmpI, T, CtxI, QuerriedAAs))
9320           return false;
9321       } else if (auto *CastI = dyn_cast<CastInst>(I)) {
9322         if (!calculateCastInst(A, CastI, T, CtxI, QuerriedAAs))
9323           return false;
9324       } else {
9325         // Give up with other instructions.
9326         // TODO: Add other instructions
9327 
9328         T.indicatePessimisticFixpoint();
9329         return false;
9330       }
9331 
9332       // Catch circular reasoning in a pessimistic way for now.
9333       // TODO: Check how the range evolves and if we stripped anything, see also
9334       //       AADereferenceable or AAAlign for similar situations.
9335       for (const AAValueConstantRange *QueriedAA : QuerriedAAs) {
9336         if (QueriedAA != this)
9337           continue;
9338         // If we are in a stady state we do not need to worry.
9339         if (T.getAssumed() == getState().getAssumed())
9340           continue;
9341         T.indicatePessimisticFixpoint();
9342       }
9343 
9344       return T.isValidState();
9345     };
9346 
9347     if (!VisitValueCB(getAssociatedValue(), getCtxI()))
9348       return indicatePessimisticFixpoint();
9349 
9350     // Ensure that long def-use chains can't cause circular reasoning either by
9351     // introducing a cutoff below.
9352     if (clampStateAndIndicateChange(getState(), T) == ChangeStatus::UNCHANGED)
9353       return ChangeStatus::UNCHANGED;
9354     if (++NumChanges > MaxNumChanges) {
9355       LLVM_DEBUG(dbgs() << "[AAValueConstantRange] performed " << NumChanges
9356                         << " but only " << MaxNumChanges
9357                         << " are allowed to avoid cyclic reasoning.");
9358       return indicatePessimisticFixpoint();
9359     }
9360     return ChangeStatus::CHANGED;
9361   }
9362 
9363   /// See AbstractAttribute::trackStatistics()
9364   void trackStatistics() const override {
9365     STATS_DECLTRACK_FLOATING_ATTR(value_range)
9366   }
9367 
9368   /// Tracker to bail after too many widening steps of the constant range.
9369   int NumChanges = 0;
9370 
9371   /// Upper bound for the number of allowed changes (=widening steps) for the
9372   /// constant range before we give up.
9373   static constexpr int MaxNumChanges = 5;
9374 };
9375 
9376 struct AAValueConstantRangeFunction : AAValueConstantRangeImpl {
9377   AAValueConstantRangeFunction(const IRPosition &IRP, Attributor &A)
9378       : AAValueConstantRangeImpl(IRP, A) {}
9379 
9380   /// See AbstractAttribute::initialize(...).
9381   ChangeStatus updateImpl(Attributor &A) override {
9382     llvm_unreachable("AAValueConstantRange(Function|CallSite)::updateImpl will "
9383                      "not be called");
9384   }
9385 
9386   /// See AbstractAttribute::trackStatistics()
9387   void trackStatistics() const override { STATS_DECLTRACK_FN_ATTR(value_range) }
9388 };
9389 
9390 struct AAValueConstantRangeCallSite : AAValueConstantRangeFunction {
9391   AAValueConstantRangeCallSite(const IRPosition &IRP, Attributor &A)
9392       : AAValueConstantRangeFunction(IRP, A) {}
9393 
9394   /// See AbstractAttribute::trackStatistics()
9395   void trackStatistics() const override { STATS_DECLTRACK_CS_ATTR(value_range) }
9396 };
9397 
9398 struct AAValueConstantRangeCallSiteReturned
9399     : AACallSiteReturnedFromReturned<AAValueConstantRange,
9400                                      AAValueConstantRangeImpl,
9401                                      AAValueConstantRangeImpl::StateType,
9402                                      /* IntroduceCallBaseContext */ true> {
9403   AAValueConstantRangeCallSiteReturned(const IRPosition &IRP, Attributor &A)
9404       : AACallSiteReturnedFromReturned<AAValueConstantRange,
9405                                        AAValueConstantRangeImpl,
9406                                        AAValueConstantRangeImpl::StateType,
9407                                        /* IntroduceCallBaseContext */ true>(IRP,
9408                                                                             A) {
9409   }
9410 
9411   /// See AbstractAttribute::initialize(...).
9412   void initialize(Attributor &A) override {
9413     // If it is a load instruction with range metadata, use the metadata.
9414     if (CallInst *CI = dyn_cast<CallInst>(&getAssociatedValue()))
9415       if (auto *RangeMD = CI->getMetadata(LLVMContext::MD_range))
9416         intersectKnown(getConstantRangeFromMetadata(*RangeMD));
9417 
9418     AAValueConstantRangeImpl::initialize(A);
9419   }
9420 
9421   /// See AbstractAttribute::trackStatistics()
9422   void trackStatistics() const override {
9423     STATS_DECLTRACK_CSRET_ATTR(value_range)
9424   }
9425 };
9426 struct AAValueConstantRangeCallSiteArgument : AAValueConstantRangeFloating {
9427   AAValueConstantRangeCallSiteArgument(const IRPosition &IRP, Attributor &A)
9428       : AAValueConstantRangeFloating(IRP, A) {}
9429 
9430   /// See AbstractAttribute::manifest()
9431   ChangeStatus manifest(Attributor &A) override {
9432     return ChangeStatus::UNCHANGED;
9433   }
9434 
9435   /// See AbstractAttribute::trackStatistics()
9436   void trackStatistics() const override {
9437     STATS_DECLTRACK_CSARG_ATTR(value_range)
9438   }
9439 };
9440 } // namespace
9441 
9442 /// ------------------ Potential Values Attribute -------------------------
9443 
9444 namespace {
9445 struct AAPotentialConstantValuesImpl : AAPotentialConstantValues {
9446   using StateType = PotentialConstantIntValuesState;
9447 
9448   AAPotentialConstantValuesImpl(const IRPosition &IRP, Attributor &A)
9449       : AAPotentialConstantValues(IRP, A) {}
9450 
9451   /// See AbstractAttribute::initialize(..).
9452   void initialize(Attributor &A) override {
9453     if (A.hasSimplificationCallback(getIRPosition()))
9454       indicatePessimisticFixpoint();
9455     else
9456       AAPotentialConstantValues::initialize(A);
9457   }
9458 
9459   bool fillSetWithConstantValues(Attributor &A, const IRPosition &IRP, SetTy &S,
9460                                  bool &ContainsUndef, bool ForSelf) {
9461     SmallVector<AA::ValueAndContext> Values;
9462     bool UsedAssumedInformation = false;
9463     if (!A.getAssumedSimplifiedValues(IRP, *this, Values, AA::Interprocedural,
9464                                       UsedAssumedInformation)) {
9465       // Avoid recursion when the caller is computing constant values for this
9466       // IRP itself.
9467       if (ForSelf)
9468         return false;
9469       if (!IRP.getAssociatedType()->isIntegerTy())
9470         return false;
9471       auto &PotentialValuesAA = A.getAAFor<AAPotentialConstantValues>(
9472           *this, IRP, DepClassTy::REQUIRED);
9473       if (!PotentialValuesAA.getState().isValidState())
9474         return false;
9475       ContainsUndef = PotentialValuesAA.getState().undefIsContained();
9476       S = PotentialValuesAA.getState().getAssumedSet();
9477       return true;
9478     }
9479 
9480     // Copy all the constant values, except UndefValue. ContainsUndef is true
9481     // iff Values contains only UndefValue instances. If there are other known
9482     // constants, then UndefValue is dropped.
9483     ContainsUndef = false;
9484     for (auto &It : Values) {
9485       if (isa<UndefValue>(It.getValue())) {
9486         ContainsUndef = true;
9487         continue;
9488       }
9489       auto *CI = dyn_cast<ConstantInt>(It.getValue());
9490       if (!CI)
9491         return false;
9492       S.insert(CI->getValue());
9493     }
9494     ContainsUndef &= S.empty();
9495 
9496     return true;
9497   }
9498 
9499   /// See AbstractAttribute::getAsStr().
9500   const std::string getAsStr() const override {
9501     std::string Str;
9502     llvm::raw_string_ostream OS(Str);
9503     OS << getState();
9504     return OS.str();
9505   }
9506 
9507   /// See AbstractAttribute::updateImpl(...).
9508   ChangeStatus updateImpl(Attributor &A) override {
9509     return indicatePessimisticFixpoint();
9510   }
9511 };
9512 
9513 struct AAPotentialConstantValuesArgument final
9514     : AAArgumentFromCallSiteArguments<AAPotentialConstantValues,
9515                                       AAPotentialConstantValuesImpl,
9516                                       PotentialConstantIntValuesState> {
9517   using Base = AAArgumentFromCallSiteArguments<AAPotentialConstantValues,
9518                                                AAPotentialConstantValuesImpl,
9519                                                PotentialConstantIntValuesState>;
9520   AAPotentialConstantValuesArgument(const IRPosition &IRP, Attributor &A)
9521       : Base(IRP, A) {}
9522 
9523   /// See AbstractAttribute::initialize(..).
9524   void initialize(Attributor &A) override {
9525     if (!getAnchorScope() || getAnchorScope()->isDeclaration()) {
9526       indicatePessimisticFixpoint();
9527     } else {
9528       Base::initialize(A);
9529     }
9530   }
9531 
9532   /// See AbstractAttribute::trackStatistics()
9533   void trackStatistics() const override {
9534     STATS_DECLTRACK_ARG_ATTR(potential_values)
9535   }
9536 };
9537 
9538 struct AAPotentialConstantValuesReturned
9539     : AAReturnedFromReturnedValues<AAPotentialConstantValues,
9540                                    AAPotentialConstantValuesImpl> {
9541   using Base = AAReturnedFromReturnedValues<AAPotentialConstantValues,
9542                                             AAPotentialConstantValuesImpl>;
9543   AAPotentialConstantValuesReturned(const IRPosition &IRP, Attributor &A)
9544       : Base(IRP, A) {}
9545 
9546   /// See AbstractAttribute::trackStatistics()
9547   void trackStatistics() const override {
9548     STATS_DECLTRACK_FNRET_ATTR(potential_values)
9549   }
9550 };
9551 
9552 struct AAPotentialConstantValuesFloating : AAPotentialConstantValuesImpl {
9553   AAPotentialConstantValuesFloating(const IRPosition &IRP, Attributor &A)
9554       : AAPotentialConstantValuesImpl(IRP, A) {}
9555 
9556   /// See AbstractAttribute::initialize(..).
9557   void initialize(Attributor &A) override {
9558     AAPotentialConstantValuesImpl::initialize(A);
9559     if (isAtFixpoint())
9560       return;
9561 
9562     Value &V = getAssociatedValue();
9563 
9564     if (auto *C = dyn_cast<ConstantInt>(&V)) {
9565       unionAssumed(C->getValue());
9566       indicateOptimisticFixpoint();
9567       return;
9568     }
9569 
9570     if (isa<UndefValue>(&V)) {
9571       unionAssumedWithUndef();
9572       indicateOptimisticFixpoint();
9573       return;
9574     }
9575 
9576     if (isa<BinaryOperator>(&V) || isa<ICmpInst>(&V) || isa<CastInst>(&V))
9577       return;
9578 
9579     if (isa<SelectInst>(V) || isa<PHINode>(V) || isa<LoadInst>(V))
9580       return;
9581 
9582     indicatePessimisticFixpoint();
9583 
9584     LLVM_DEBUG(dbgs() << "[AAPotentialConstantValues] We give up: "
9585                       << getAssociatedValue() << "\n");
9586   }
9587 
9588   static bool calculateICmpInst(const ICmpInst *ICI, const APInt &LHS,
9589                                 const APInt &RHS) {
9590     return ICmpInst::compare(LHS, RHS, ICI->getPredicate());
9591   }
9592 
9593   static APInt calculateCastInst(const CastInst *CI, const APInt &Src,
9594                                  uint32_t ResultBitWidth) {
9595     Instruction::CastOps CastOp = CI->getOpcode();
9596     switch (CastOp) {
9597     default:
9598       llvm_unreachable("unsupported or not integer cast");
9599     case Instruction::Trunc:
9600       return Src.trunc(ResultBitWidth);
9601     case Instruction::SExt:
9602       return Src.sext(ResultBitWidth);
9603     case Instruction::ZExt:
9604       return Src.zext(ResultBitWidth);
9605     case Instruction::BitCast:
9606       return Src;
9607     }
9608   }
9609 
9610   static APInt calculateBinaryOperator(const BinaryOperator *BinOp,
9611                                        const APInt &LHS, const APInt &RHS,
9612                                        bool &SkipOperation, bool &Unsupported) {
9613     Instruction::BinaryOps BinOpcode = BinOp->getOpcode();
9614     // Unsupported is set to true when the binary operator is not supported.
9615     // SkipOperation is set to true when UB occur with the given operand pair
9616     // (LHS, RHS).
9617     // TODO: we should look at nsw and nuw keywords to handle operations
9618     //       that create poison or undef value.
9619     switch (BinOpcode) {
9620     default:
9621       Unsupported = true;
9622       return LHS;
9623     case Instruction::Add:
9624       return LHS + RHS;
9625     case Instruction::Sub:
9626       return LHS - RHS;
9627     case Instruction::Mul:
9628       return LHS * RHS;
9629     case Instruction::UDiv:
9630       if (RHS.isZero()) {
9631         SkipOperation = true;
9632         return LHS;
9633       }
9634       return LHS.udiv(RHS);
9635     case Instruction::SDiv:
9636       if (RHS.isZero()) {
9637         SkipOperation = true;
9638         return LHS;
9639       }
9640       return LHS.sdiv(RHS);
9641     case Instruction::URem:
9642       if (RHS.isZero()) {
9643         SkipOperation = true;
9644         return LHS;
9645       }
9646       return LHS.urem(RHS);
9647     case Instruction::SRem:
9648       if (RHS.isZero()) {
9649         SkipOperation = true;
9650         return LHS;
9651       }
9652       return LHS.srem(RHS);
9653     case Instruction::Shl:
9654       return LHS.shl(RHS);
9655     case Instruction::LShr:
9656       return LHS.lshr(RHS);
9657     case Instruction::AShr:
9658       return LHS.ashr(RHS);
9659     case Instruction::And:
9660       return LHS & RHS;
9661     case Instruction::Or:
9662       return LHS | RHS;
9663     case Instruction::Xor:
9664       return LHS ^ RHS;
9665     }
9666   }
9667 
9668   bool calculateBinaryOperatorAndTakeUnion(const BinaryOperator *BinOp,
9669                                            const APInt &LHS, const APInt &RHS) {
9670     bool SkipOperation = false;
9671     bool Unsupported = false;
9672     APInt Result =
9673         calculateBinaryOperator(BinOp, LHS, RHS, SkipOperation, Unsupported);
9674     if (Unsupported)
9675       return false;
9676     // If SkipOperation is true, we can ignore this operand pair (L, R).
9677     if (!SkipOperation)
9678       unionAssumed(Result);
9679     return isValidState();
9680   }
9681 
9682   ChangeStatus updateWithICmpInst(Attributor &A, ICmpInst *ICI) {
9683     auto AssumedBefore = getAssumed();
9684     Value *LHS = ICI->getOperand(0);
9685     Value *RHS = ICI->getOperand(1);
9686 
9687     bool LHSContainsUndef = false, RHSContainsUndef = false;
9688     SetTy LHSAAPVS, RHSAAPVS;
9689     if (!fillSetWithConstantValues(A, IRPosition::value(*LHS), LHSAAPVS,
9690                                    LHSContainsUndef, /* ForSelf */ false) ||
9691         !fillSetWithConstantValues(A, IRPosition::value(*RHS), RHSAAPVS,
9692                                    RHSContainsUndef, /* ForSelf */ false))
9693       return indicatePessimisticFixpoint();
9694 
9695     // TODO: make use of undef flag to limit potential values aggressively.
9696     bool MaybeTrue = false, MaybeFalse = false;
9697     const APInt Zero(RHS->getType()->getIntegerBitWidth(), 0);
9698     if (LHSContainsUndef && RHSContainsUndef) {
9699       // The result of any comparison between undefs can be soundly replaced
9700       // with undef.
9701       unionAssumedWithUndef();
9702     } else if (LHSContainsUndef) {
9703       for (const APInt &R : RHSAAPVS) {
9704         bool CmpResult = calculateICmpInst(ICI, Zero, R);
9705         MaybeTrue |= CmpResult;
9706         MaybeFalse |= !CmpResult;
9707         if (MaybeTrue & MaybeFalse)
9708           return indicatePessimisticFixpoint();
9709       }
9710     } else if (RHSContainsUndef) {
9711       for (const APInt &L : LHSAAPVS) {
9712         bool CmpResult = calculateICmpInst(ICI, L, Zero);
9713         MaybeTrue |= CmpResult;
9714         MaybeFalse |= !CmpResult;
9715         if (MaybeTrue & MaybeFalse)
9716           return indicatePessimisticFixpoint();
9717       }
9718     } else {
9719       for (const APInt &L : LHSAAPVS) {
9720         for (const APInt &R : RHSAAPVS) {
9721           bool CmpResult = calculateICmpInst(ICI, L, R);
9722           MaybeTrue |= CmpResult;
9723           MaybeFalse |= !CmpResult;
9724           if (MaybeTrue & MaybeFalse)
9725             return indicatePessimisticFixpoint();
9726         }
9727       }
9728     }
9729     if (MaybeTrue)
9730       unionAssumed(APInt(/* numBits */ 1, /* val */ 1));
9731     if (MaybeFalse)
9732       unionAssumed(APInt(/* numBits */ 1, /* val */ 0));
9733     return AssumedBefore == getAssumed() ? ChangeStatus::UNCHANGED
9734                                          : ChangeStatus::CHANGED;
9735   }
9736 
9737   ChangeStatus updateWithSelectInst(Attributor &A, SelectInst *SI) {
9738     auto AssumedBefore = getAssumed();
9739     Value *LHS = SI->getTrueValue();
9740     Value *RHS = SI->getFalseValue();
9741 
9742     bool UsedAssumedInformation = false;
9743     std::optional<Constant *> C = A.getAssumedConstant(
9744         *SI->getCondition(), *this, UsedAssumedInformation);
9745 
9746     // Check if we only need one operand.
9747     bool OnlyLeft = false, OnlyRight = false;
9748     if (C && *C && (*C)->isOneValue())
9749       OnlyLeft = true;
9750     else if (C && *C && (*C)->isZeroValue())
9751       OnlyRight = true;
9752 
9753     bool LHSContainsUndef = false, RHSContainsUndef = false;
9754     SetTy LHSAAPVS, RHSAAPVS;
9755     if (!OnlyRight &&
9756         !fillSetWithConstantValues(A, IRPosition::value(*LHS), LHSAAPVS,
9757                                    LHSContainsUndef, /* ForSelf */ false))
9758       return indicatePessimisticFixpoint();
9759 
9760     if (!OnlyLeft &&
9761         !fillSetWithConstantValues(A, IRPosition::value(*RHS), RHSAAPVS,
9762                                    RHSContainsUndef, /* ForSelf */ false))
9763       return indicatePessimisticFixpoint();
9764 
9765     if (OnlyLeft || OnlyRight) {
9766       // select (true/false), lhs, rhs
9767       auto *OpAA = OnlyLeft ? &LHSAAPVS : &RHSAAPVS;
9768       auto Undef = OnlyLeft ? LHSContainsUndef : RHSContainsUndef;
9769 
9770       if (Undef)
9771         unionAssumedWithUndef();
9772       else {
9773         for (const auto &It : *OpAA)
9774           unionAssumed(It);
9775       }
9776 
9777     } else if (LHSContainsUndef && RHSContainsUndef) {
9778       // select i1 *, undef , undef => undef
9779       unionAssumedWithUndef();
9780     } else {
9781       for (const auto &It : LHSAAPVS)
9782         unionAssumed(It);
9783       for (const auto &It : RHSAAPVS)
9784         unionAssumed(It);
9785     }
9786     return AssumedBefore == getAssumed() ? ChangeStatus::UNCHANGED
9787                                          : ChangeStatus::CHANGED;
9788   }
9789 
9790   ChangeStatus updateWithCastInst(Attributor &A, CastInst *CI) {
9791     auto AssumedBefore = getAssumed();
9792     if (!CI->isIntegerCast())
9793       return indicatePessimisticFixpoint();
9794     assert(CI->getNumOperands() == 1 && "Expected cast to be unary!");
9795     uint32_t ResultBitWidth = CI->getDestTy()->getIntegerBitWidth();
9796     Value *Src = CI->getOperand(0);
9797 
9798     bool SrcContainsUndef = false;
9799     SetTy SrcPVS;
9800     if (!fillSetWithConstantValues(A, IRPosition::value(*Src), SrcPVS,
9801                                    SrcContainsUndef, /* ForSelf */ false))
9802       return indicatePessimisticFixpoint();
9803 
9804     if (SrcContainsUndef)
9805       unionAssumedWithUndef();
9806     else {
9807       for (const APInt &S : SrcPVS) {
9808         APInt T = calculateCastInst(CI, S, ResultBitWidth);
9809         unionAssumed(T);
9810       }
9811     }
9812     return AssumedBefore == getAssumed() ? ChangeStatus::UNCHANGED
9813                                          : ChangeStatus::CHANGED;
9814   }
9815 
9816   ChangeStatus updateWithBinaryOperator(Attributor &A, BinaryOperator *BinOp) {
9817     auto AssumedBefore = getAssumed();
9818     Value *LHS = BinOp->getOperand(0);
9819     Value *RHS = BinOp->getOperand(1);
9820 
9821     bool LHSContainsUndef = false, RHSContainsUndef = false;
9822     SetTy LHSAAPVS, RHSAAPVS;
9823     if (!fillSetWithConstantValues(A, IRPosition::value(*LHS), LHSAAPVS,
9824                                    LHSContainsUndef, /* ForSelf */ false) ||
9825         !fillSetWithConstantValues(A, IRPosition::value(*RHS), RHSAAPVS,
9826                                    RHSContainsUndef, /* ForSelf */ false))
9827       return indicatePessimisticFixpoint();
9828 
9829     const APInt Zero = APInt(LHS->getType()->getIntegerBitWidth(), 0);
9830 
9831     // TODO: make use of undef flag to limit potential values aggressively.
9832     if (LHSContainsUndef && RHSContainsUndef) {
9833       if (!calculateBinaryOperatorAndTakeUnion(BinOp, Zero, Zero))
9834         return indicatePessimisticFixpoint();
9835     } else if (LHSContainsUndef) {
9836       for (const APInt &R : RHSAAPVS) {
9837         if (!calculateBinaryOperatorAndTakeUnion(BinOp, Zero, R))
9838           return indicatePessimisticFixpoint();
9839       }
9840     } else if (RHSContainsUndef) {
9841       for (const APInt &L : LHSAAPVS) {
9842         if (!calculateBinaryOperatorAndTakeUnion(BinOp, L, Zero))
9843           return indicatePessimisticFixpoint();
9844       }
9845     } else {
9846       for (const APInt &L : LHSAAPVS) {
9847         for (const APInt &R : RHSAAPVS) {
9848           if (!calculateBinaryOperatorAndTakeUnion(BinOp, L, R))
9849             return indicatePessimisticFixpoint();
9850         }
9851       }
9852     }
9853     return AssumedBefore == getAssumed() ? ChangeStatus::UNCHANGED
9854                                          : ChangeStatus::CHANGED;
9855   }
9856 
9857   ChangeStatus updateWithInstruction(Attributor &A, Instruction *Inst) {
9858     auto AssumedBefore = getAssumed();
9859     SetTy Incoming;
9860     bool ContainsUndef;
9861     if (!fillSetWithConstantValues(A, IRPosition::value(*Inst), Incoming,
9862                                    ContainsUndef, /* ForSelf */ true))
9863       return indicatePessimisticFixpoint();
9864     if (ContainsUndef) {
9865       unionAssumedWithUndef();
9866     } else {
9867       for (const auto &It : Incoming)
9868         unionAssumed(It);
9869     }
9870     return AssumedBefore == getAssumed() ? ChangeStatus::UNCHANGED
9871                                          : ChangeStatus::CHANGED;
9872   }
9873 
9874   /// See AbstractAttribute::updateImpl(...).
9875   ChangeStatus updateImpl(Attributor &A) override {
9876     Value &V = getAssociatedValue();
9877     Instruction *I = dyn_cast<Instruction>(&V);
9878 
9879     if (auto *ICI = dyn_cast<ICmpInst>(I))
9880       return updateWithICmpInst(A, ICI);
9881 
9882     if (auto *SI = dyn_cast<SelectInst>(I))
9883       return updateWithSelectInst(A, SI);
9884 
9885     if (auto *CI = dyn_cast<CastInst>(I))
9886       return updateWithCastInst(A, CI);
9887 
9888     if (auto *BinOp = dyn_cast<BinaryOperator>(I))
9889       return updateWithBinaryOperator(A, BinOp);
9890 
9891     if (isa<PHINode>(I) || isa<LoadInst>(I))
9892       return updateWithInstruction(A, I);
9893 
9894     return indicatePessimisticFixpoint();
9895   }
9896 
9897   /// See AbstractAttribute::trackStatistics()
9898   void trackStatistics() const override {
9899     STATS_DECLTRACK_FLOATING_ATTR(potential_values)
9900   }
9901 };
9902 
9903 struct AAPotentialConstantValuesFunction : AAPotentialConstantValuesImpl {
9904   AAPotentialConstantValuesFunction(const IRPosition &IRP, Attributor &A)
9905       : AAPotentialConstantValuesImpl(IRP, A) {}
9906 
9907   /// See AbstractAttribute::initialize(...).
9908   ChangeStatus updateImpl(Attributor &A) override {
9909     llvm_unreachable(
9910         "AAPotentialConstantValues(Function|CallSite)::updateImpl will "
9911         "not be called");
9912   }
9913 
9914   /// See AbstractAttribute::trackStatistics()
9915   void trackStatistics() const override {
9916     STATS_DECLTRACK_FN_ATTR(potential_values)
9917   }
9918 };
9919 
9920 struct AAPotentialConstantValuesCallSite : AAPotentialConstantValuesFunction {
9921   AAPotentialConstantValuesCallSite(const IRPosition &IRP, Attributor &A)
9922       : AAPotentialConstantValuesFunction(IRP, A) {}
9923 
9924   /// See AbstractAttribute::trackStatistics()
9925   void trackStatistics() const override {
9926     STATS_DECLTRACK_CS_ATTR(potential_values)
9927   }
9928 };
9929 
9930 struct AAPotentialConstantValuesCallSiteReturned
9931     : AACallSiteReturnedFromReturned<AAPotentialConstantValues,
9932                                      AAPotentialConstantValuesImpl> {
9933   AAPotentialConstantValuesCallSiteReturned(const IRPosition &IRP,
9934                                             Attributor &A)
9935       : AACallSiteReturnedFromReturned<AAPotentialConstantValues,
9936                                        AAPotentialConstantValuesImpl>(IRP, A) {}
9937 
9938   /// See AbstractAttribute::trackStatistics()
9939   void trackStatistics() const override {
9940     STATS_DECLTRACK_CSRET_ATTR(potential_values)
9941   }
9942 };
9943 
9944 struct AAPotentialConstantValuesCallSiteArgument
9945     : AAPotentialConstantValuesFloating {
9946   AAPotentialConstantValuesCallSiteArgument(const IRPosition &IRP,
9947                                             Attributor &A)
9948       : AAPotentialConstantValuesFloating(IRP, A) {}
9949 
9950   /// See AbstractAttribute::initialize(..).
9951   void initialize(Attributor &A) override {
9952     AAPotentialConstantValuesImpl::initialize(A);
9953     if (isAtFixpoint())
9954       return;
9955 
9956     Value &V = getAssociatedValue();
9957 
9958     if (auto *C = dyn_cast<ConstantInt>(&V)) {
9959       unionAssumed(C->getValue());
9960       indicateOptimisticFixpoint();
9961       return;
9962     }
9963 
9964     if (isa<UndefValue>(&V)) {
9965       unionAssumedWithUndef();
9966       indicateOptimisticFixpoint();
9967       return;
9968     }
9969   }
9970 
9971   /// See AbstractAttribute::updateImpl(...).
9972   ChangeStatus updateImpl(Attributor &A) override {
9973     Value &V = getAssociatedValue();
9974     auto AssumedBefore = getAssumed();
9975     auto &AA = A.getAAFor<AAPotentialConstantValues>(
9976         *this, IRPosition::value(V), DepClassTy::REQUIRED);
9977     const auto &S = AA.getAssumed();
9978     unionAssumed(S);
9979     return AssumedBefore == getAssumed() ? ChangeStatus::UNCHANGED
9980                                          : ChangeStatus::CHANGED;
9981   }
9982 
9983   /// See AbstractAttribute::trackStatistics()
9984   void trackStatistics() const override {
9985     STATS_DECLTRACK_CSARG_ATTR(potential_values)
9986   }
9987 };
9988 
9989 /// ------------------------ NoUndef Attribute ---------------------------------
9990 struct AANoUndefImpl : AANoUndef {
9991   AANoUndefImpl(const IRPosition &IRP, Attributor &A) : AANoUndef(IRP, A) {}
9992 
9993   /// See AbstractAttribute::initialize(...).
9994   void initialize(Attributor &A) override {
9995     if (getIRPosition().hasAttr({Attribute::NoUndef})) {
9996       indicateOptimisticFixpoint();
9997       return;
9998     }
9999     Value &V = getAssociatedValue();
10000     if (isa<UndefValue>(V))
10001       indicatePessimisticFixpoint();
10002     else if (isa<FreezeInst>(V))
10003       indicateOptimisticFixpoint();
10004     else if (getPositionKind() != IRPosition::IRP_RETURNED &&
10005              isGuaranteedNotToBeUndefOrPoison(&V))
10006       indicateOptimisticFixpoint();
10007     else
10008       AANoUndef::initialize(A);
10009   }
10010 
10011   /// See followUsesInMBEC
10012   bool followUseInMBEC(Attributor &A, const Use *U, const Instruction *I,
10013                        AANoUndef::StateType &State) {
10014     const Value *UseV = U->get();
10015     const DominatorTree *DT = nullptr;
10016     AssumptionCache *AC = nullptr;
10017     InformationCache &InfoCache = A.getInfoCache();
10018     if (Function *F = getAnchorScope()) {
10019       DT = InfoCache.getAnalysisResultForFunction<DominatorTreeAnalysis>(*F);
10020       AC = InfoCache.getAnalysisResultForFunction<AssumptionAnalysis>(*F);
10021     }
10022     State.setKnown(isGuaranteedNotToBeUndefOrPoison(UseV, AC, I, DT));
10023     bool TrackUse = false;
10024     // Track use for instructions which must produce undef or poison bits when
10025     // at least one operand contains such bits.
10026     if (isa<CastInst>(*I) || isa<GetElementPtrInst>(*I))
10027       TrackUse = true;
10028     return TrackUse;
10029   }
10030 
10031   /// See AbstractAttribute::getAsStr().
10032   const std::string getAsStr() const override {
10033     return getAssumed() ? "noundef" : "may-undef-or-poison";
10034   }
10035 
10036   ChangeStatus manifest(Attributor &A) override {
10037     // We don't manifest noundef attribute for dead positions because the
10038     // associated values with dead positions would be replaced with undef
10039     // values.
10040     bool UsedAssumedInformation = false;
10041     if (A.isAssumedDead(getIRPosition(), nullptr, nullptr,
10042                         UsedAssumedInformation))
10043       return ChangeStatus::UNCHANGED;
10044     // A position whose simplified value does not have any value is
10045     // considered to be dead. We don't manifest noundef in such positions for
10046     // the same reason above.
10047     if (!A.getAssumedSimplified(getIRPosition(), *this, UsedAssumedInformation,
10048                                 AA::Interprocedural)
10049              .has_value())
10050       return ChangeStatus::UNCHANGED;
10051     return AANoUndef::manifest(A);
10052   }
10053 };
10054 
10055 struct AANoUndefFloating : public AANoUndefImpl {
10056   AANoUndefFloating(const IRPosition &IRP, Attributor &A)
10057       : AANoUndefImpl(IRP, A) {}
10058 
10059   /// See AbstractAttribute::initialize(...).
10060   void initialize(Attributor &A) override {
10061     AANoUndefImpl::initialize(A);
10062     if (!getState().isAtFixpoint())
10063       if (Instruction *CtxI = getCtxI())
10064         followUsesInMBEC(*this, A, getState(), *CtxI);
10065   }
10066 
10067   /// See AbstractAttribute::updateImpl(...).
10068   ChangeStatus updateImpl(Attributor &A) override {
10069 
10070     SmallVector<AA::ValueAndContext> Values;
10071     bool UsedAssumedInformation = false;
10072     if (!A.getAssumedSimplifiedValues(getIRPosition(), *this, Values,
10073                                       AA::AnyScope, UsedAssumedInformation)) {
10074       Values.push_back({getAssociatedValue(), getCtxI()});
10075     }
10076 
10077     StateType T;
10078     auto VisitValueCB = [&](Value &V, const Instruction *CtxI) -> bool {
10079       const auto &AA = A.getAAFor<AANoUndef>(*this, IRPosition::value(V),
10080                                              DepClassTy::REQUIRED);
10081       if (this == &AA) {
10082         T.indicatePessimisticFixpoint();
10083       } else {
10084         const AANoUndef::StateType &S =
10085             static_cast<const AANoUndef::StateType &>(AA.getState());
10086         T ^= S;
10087       }
10088       return T.isValidState();
10089     };
10090 
10091     for (const auto &VAC : Values)
10092       if (!VisitValueCB(*VAC.getValue(), VAC.getCtxI()))
10093         return indicatePessimisticFixpoint();
10094 
10095     return clampStateAndIndicateChange(getState(), T);
10096   }
10097 
10098   /// See AbstractAttribute::trackStatistics()
10099   void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(noundef) }
10100 };
10101 
10102 struct AANoUndefReturned final
10103     : AAReturnedFromReturnedValues<AANoUndef, AANoUndefImpl> {
10104   AANoUndefReturned(const IRPosition &IRP, Attributor &A)
10105       : AAReturnedFromReturnedValues<AANoUndef, AANoUndefImpl>(IRP, A) {}
10106 
10107   /// See AbstractAttribute::trackStatistics()
10108   void trackStatistics() const override { STATS_DECLTRACK_FNRET_ATTR(noundef) }
10109 };
10110 
10111 struct AANoUndefArgument final
10112     : AAArgumentFromCallSiteArguments<AANoUndef, AANoUndefImpl> {
10113   AANoUndefArgument(const IRPosition &IRP, Attributor &A)
10114       : AAArgumentFromCallSiteArguments<AANoUndef, AANoUndefImpl>(IRP, A) {}
10115 
10116   /// See AbstractAttribute::trackStatistics()
10117   void trackStatistics() const override { STATS_DECLTRACK_ARG_ATTR(noundef) }
10118 };
10119 
10120 struct AANoUndefCallSiteArgument final : AANoUndefFloating {
10121   AANoUndefCallSiteArgument(const IRPosition &IRP, Attributor &A)
10122       : AANoUndefFloating(IRP, A) {}
10123 
10124   /// See AbstractAttribute::trackStatistics()
10125   void trackStatistics() const override { STATS_DECLTRACK_CSARG_ATTR(noundef) }
10126 };
10127 
10128 struct AANoUndefCallSiteReturned final
10129     : AACallSiteReturnedFromReturned<AANoUndef, AANoUndefImpl> {
10130   AANoUndefCallSiteReturned(const IRPosition &IRP, Attributor &A)
10131       : AACallSiteReturnedFromReturned<AANoUndef, AANoUndefImpl>(IRP, A) {}
10132 
10133   /// See AbstractAttribute::trackStatistics()
10134   void trackStatistics() const override { STATS_DECLTRACK_CSRET_ATTR(noundef) }
10135 };
10136 
10137 struct AACallEdgesImpl : public AACallEdges {
10138   AACallEdgesImpl(const IRPosition &IRP, Attributor &A) : AACallEdges(IRP, A) {}
10139 
10140   const SetVector<Function *> &getOptimisticEdges() const override {
10141     return CalledFunctions;
10142   }
10143 
10144   bool hasUnknownCallee() const override { return HasUnknownCallee; }
10145 
10146   bool hasNonAsmUnknownCallee() const override {
10147     return HasUnknownCalleeNonAsm;
10148   }
10149 
10150   const std::string getAsStr() const override {
10151     return "CallEdges[" + std::to_string(HasUnknownCallee) + "," +
10152            std::to_string(CalledFunctions.size()) + "]";
10153   }
10154 
10155   void trackStatistics() const override {}
10156 
10157 protected:
10158   void addCalledFunction(Function *Fn, ChangeStatus &Change) {
10159     if (CalledFunctions.insert(Fn)) {
10160       Change = ChangeStatus::CHANGED;
10161       LLVM_DEBUG(dbgs() << "[AACallEdges] New call edge: " << Fn->getName()
10162                         << "\n");
10163     }
10164   }
10165 
10166   void setHasUnknownCallee(bool NonAsm, ChangeStatus &Change) {
10167     if (!HasUnknownCallee)
10168       Change = ChangeStatus::CHANGED;
10169     if (NonAsm && !HasUnknownCalleeNonAsm)
10170       Change = ChangeStatus::CHANGED;
10171     HasUnknownCalleeNonAsm |= NonAsm;
10172     HasUnknownCallee = true;
10173   }
10174 
10175 private:
10176   /// Optimistic set of functions that might be called by this position.
10177   SetVector<Function *> CalledFunctions;
10178 
10179   /// Is there any call with a unknown callee.
10180   bool HasUnknownCallee = false;
10181 
10182   /// Is there any call with a unknown callee, excluding any inline asm.
10183   bool HasUnknownCalleeNonAsm = false;
10184 };
10185 
10186 struct AACallEdgesCallSite : public AACallEdgesImpl {
10187   AACallEdgesCallSite(const IRPosition &IRP, Attributor &A)
10188       : AACallEdgesImpl(IRP, A) {}
10189   /// See AbstractAttribute::updateImpl(...).
10190   ChangeStatus updateImpl(Attributor &A) override {
10191     ChangeStatus Change = ChangeStatus::UNCHANGED;
10192 
10193     auto VisitValue = [&](Value &V, const Instruction *CtxI) -> bool {
10194       if (Function *Fn = dyn_cast<Function>(&V)) {
10195         addCalledFunction(Fn, Change);
10196       } else {
10197         LLVM_DEBUG(dbgs() << "[AACallEdges] Unrecognized value: " << V << "\n");
10198         setHasUnknownCallee(true, Change);
10199       }
10200 
10201       // Explore all values.
10202       return true;
10203     };
10204 
10205     SmallVector<AA::ValueAndContext> Values;
10206     // Process any value that we might call.
10207     auto ProcessCalledOperand = [&](Value *V, Instruction *CtxI) {
10208       bool UsedAssumedInformation = false;
10209       Values.clear();
10210       if (!A.getAssumedSimplifiedValues(IRPosition::value(*V), *this, Values,
10211                                         AA::AnyScope, UsedAssumedInformation)) {
10212         Values.push_back({*V, CtxI});
10213       }
10214       for (auto &VAC : Values)
10215         VisitValue(*VAC.getValue(), VAC.getCtxI());
10216     };
10217 
10218     CallBase *CB = cast<CallBase>(getCtxI());
10219 
10220     if (auto *IA = dyn_cast<InlineAsm>(CB->getCalledOperand())) {
10221       if (IA->hasSideEffects() &&
10222           !hasAssumption(*CB->getCaller(), "ompx_no_call_asm") &&
10223           !hasAssumption(*CB, "ompx_no_call_asm")) {
10224         setHasUnknownCallee(false, Change);
10225       }
10226       return Change;
10227     }
10228 
10229     // Process callee metadata if available.
10230     if (auto *MD = getCtxI()->getMetadata(LLVMContext::MD_callees)) {
10231       for (const auto &Op : MD->operands()) {
10232         Function *Callee = mdconst::dyn_extract_or_null<Function>(Op);
10233         if (Callee)
10234           addCalledFunction(Callee, Change);
10235       }
10236       return Change;
10237     }
10238 
10239     // The most simple case.
10240     ProcessCalledOperand(CB->getCalledOperand(), CB);
10241 
10242     // Process callback functions.
10243     SmallVector<const Use *, 4u> CallbackUses;
10244     AbstractCallSite::getCallbackUses(*CB, CallbackUses);
10245     for (const Use *U : CallbackUses)
10246       ProcessCalledOperand(U->get(), CB);
10247 
10248     return Change;
10249   }
10250 };
10251 
10252 struct AACallEdgesFunction : public AACallEdgesImpl {
10253   AACallEdgesFunction(const IRPosition &IRP, Attributor &A)
10254       : AACallEdgesImpl(IRP, A) {}
10255 
10256   /// See AbstractAttribute::updateImpl(...).
10257   ChangeStatus updateImpl(Attributor &A) override {
10258     ChangeStatus Change = ChangeStatus::UNCHANGED;
10259 
10260     auto ProcessCallInst = [&](Instruction &Inst) {
10261       CallBase &CB = cast<CallBase>(Inst);
10262 
10263       auto &CBEdges = A.getAAFor<AACallEdges>(
10264           *this, IRPosition::callsite_function(CB), DepClassTy::REQUIRED);
10265       if (CBEdges.hasNonAsmUnknownCallee())
10266         setHasUnknownCallee(true, Change);
10267       if (CBEdges.hasUnknownCallee())
10268         setHasUnknownCallee(false, Change);
10269 
10270       for (Function *F : CBEdges.getOptimisticEdges())
10271         addCalledFunction(F, Change);
10272 
10273       return true;
10274     };
10275 
10276     // Visit all callable instructions.
10277     bool UsedAssumedInformation = false;
10278     if (!A.checkForAllCallLikeInstructions(ProcessCallInst, *this,
10279                                            UsedAssumedInformation,
10280                                            /* CheckBBLivenessOnly */ true)) {
10281       // If we haven't looked at all call like instructions, assume that there
10282       // are unknown callees.
10283       setHasUnknownCallee(true, Change);
10284     }
10285 
10286     return Change;
10287   }
10288 };
10289 
10290 /// -------------------AAInterFnReachability Attribute--------------------------
10291 
10292 struct AAInterFnReachabilityFunction
10293     : public CachedReachabilityAA<AAInterFnReachability, Function> {
10294   AAInterFnReachabilityFunction(const IRPosition &IRP, Attributor &A)
10295       : CachedReachabilityAA<AAInterFnReachability, Function>(IRP, A) {}
10296 
10297   bool instructionCanReach(
10298       Attributor &A, const Instruction &From, const Function &To,
10299       const AA::InstExclusionSetTy *ExclusionSet,
10300       SmallPtrSet<const Function *, 16> *Visited) const override {
10301     assert(From.getFunction() == getAnchorScope() && "Queried the wrong AA!");
10302     auto *NonConstThis = const_cast<AAInterFnReachabilityFunction *>(this);
10303 
10304     RQITy StackRQI(A, From, To, ExclusionSet);
10305     typename RQITy::Reachable Result;
10306     if (RQITy *RQIPtr = NonConstThis->checkQueryCache(A, StackRQI, Result))
10307       return NonConstThis->isReachableImpl(A, *RQIPtr);
10308     return Result == RQITy::Reachable::Yes;
10309   }
10310 
10311   bool isReachableImpl(Attributor &A, RQITy &RQI) override {
10312     return isReachableImpl(A, RQI, nullptr);
10313   }
10314 
10315   bool isReachableImpl(Attributor &A, RQITy &RQI,
10316                        SmallPtrSet<const Function *, 16> *Visited) {
10317 
10318     SmallPtrSet<const Function *, 16> LocalVisited;
10319     if (!Visited)
10320       Visited = &LocalVisited;
10321 
10322     const auto &IntraFnReachability = A.getAAFor<AAIntraFnReachability>(
10323         *this, IRPosition::function(*RQI.From->getFunction()),
10324         DepClassTy::OPTIONAL);
10325 
10326     // Determine call like instructions that we can reach from the inst.
10327     SmallVector<CallBase *> ReachableCallBases;
10328     auto CheckCallBase = [&](Instruction &CBInst) {
10329       if (IntraFnReachability.isAssumedReachable(A, *RQI.From, CBInst,
10330                                                  RQI.ExclusionSet))
10331         ReachableCallBases.push_back(cast<CallBase>(&CBInst));
10332       return true;
10333     };
10334 
10335     bool UsedAssumedInformation = false;
10336     if (!A.checkForAllCallLikeInstructions(CheckCallBase, *this,
10337                                            UsedAssumedInformation,
10338                                            /* CheckBBLivenessOnly */ true))
10339       return rememberResult(A, RQITy::Reachable::Yes, RQI);
10340 
10341     for (CallBase *CB : ReachableCallBases) {
10342       auto &CBEdges = A.getAAFor<AACallEdges>(
10343           *this, IRPosition::callsite_function(*CB), DepClassTy::OPTIONAL);
10344       if (!CBEdges.getState().isValidState())
10345         return rememberResult(A, RQITy::Reachable::Yes, RQI);
10346       // TODO Check To backwards in this case.
10347       if (CBEdges.hasUnknownCallee())
10348         return rememberResult(A, RQITy::Reachable::Yes, RQI);
10349 
10350       for (Function *Fn : CBEdges.getOptimisticEdges()) {
10351         if (Fn == RQI.To)
10352           return rememberResult(A, RQITy::Reachable::Yes, RQI);
10353         if (!Visited->insert(Fn).second)
10354           continue;
10355         if (Fn->isDeclaration()) {
10356           if (Fn->hasFnAttribute(Attribute::NoCallback))
10357             continue;
10358           // TODO Check To backwards in this case.
10359           return rememberResult(A, RQITy::Reachable::Yes, RQI);
10360         }
10361 
10362         const AAInterFnReachability *InterFnReachability = this;
10363         if (Fn != getAnchorScope())
10364           InterFnReachability = &A.getAAFor<AAInterFnReachability>(
10365               *this, IRPosition::function(*Fn), DepClassTy::OPTIONAL);
10366 
10367         const Instruction &FnFirstInst = Fn->getEntryBlock().front();
10368         if (InterFnReachability->instructionCanReach(A, FnFirstInst, *RQI.To,
10369                                                      RQI.ExclusionSet, Visited))
10370           return rememberResult(A, RQITy::Reachable::Yes, RQI);
10371       }
10372     }
10373 
10374     return rememberResult(A, RQITy::Reachable::No, RQI);
10375   }
10376 
10377   void trackStatistics() const override {}
10378 
10379 private:
10380   SmallVector<RQITy *> QueryVector;
10381   DenseSet<RQITy *> QueryCache;
10382 };
10383 } // namespace
10384 
10385 template <typename AAType>
10386 static std::optional<Constant *>
10387 askForAssumedConstant(Attributor &A, const AbstractAttribute &QueryingAA,
10388                       const IRPosition &IRP, Type &Ty) {
10389   if (!Ty.isIntegerTy())
10390     return nullptr;
10391 
10392   // This will also pass the call base context.
10393   const auto &AA = A.getAAFor<AAType>(QueryingAA, IRP, DepClassTy::NONE);
10394 
10395   std::optional<Constant *> COpt = AA.getAssumedConstant(A);
10396 
10397   if (!COpt.has_value()) {
10398     A.recordDependence(AA, QueryingAA, DepClassTy::OPTIONAL);
10399     return std::nullopt;
10400   }
10401   if (auto *C = *COpt) {
10402     A.recordDependence(AA, QueryingAA, DepClassTy::OPTIONAL);
10403     return C;
10404   }
10405   return nullptr;
10406 }
10407 
10408 Value *AAPotentialValues::getSingleValue(
10409     Attributor &A, const AbstractAttribute &AA, const IRPosition &IRP,
10410     SmallVectorImpl<AA::ValueAndContext> &Values) {
10411   Type &Ty = *IRP.getAssociatedType();
10412   std::optional<Value *> V;
10413   for (auto &It : Values) {
10414     V = AA::combineOptionalValuesInAAValueLatice(V, It.getValue(), &Ty);
10415     if (V.has_value() && !*V)
10416       break;
10417   }
10418   if (!V.has_value())
10419     return UndefValue::get(&Ty);
10420   return *V;
10421 }
10422 
10423 namespace {
10424 struct AAPotentialValuesImpl : AAPotentialValues {
10425   using StateType = PotentialLLVMValuesState;
10426 
10427   AAPotentialValuesImpl(const IRPosition &IRP, Attributor &A)
10428       : AAPotentialValues(IRP, A) {}
10429 
10430   /// See AbstractAttribute::initialize(..).
10431   void initialize(Attributor &A) override {
10432     if (A.hasSimplificationCallback(getIRPosition())) {
10433       indicatePessimisticFixpoint();
10434       return;
10435     }
10436     Value *Stripped = getAssociatedValue().stripPointerCasts();
10437     auto *CE = dyn_cast<ConstantExpr>(Stripped);
10438     if (isa<Constant>(Stripped) &&
10439         (!CE || CE->getOpcode() != Instruction::ICmp)) {
10440       addValue(A, getState(), *Stripped, getCtxI(), AA::AnyScope,
10441                getAnchorScope());
10442       indicateOptimisticFixpoint();
10443       return;
10444     }
10445     AAPotentialValues::initialize(A);
10446   }
10447 
10448   /// See AbstractAttribute::getAsStr().
10449   const std::string getAsStr() const override {
10450     std::string Str;
10451     llvm::raw_string_ostream OS(Str);
10452     OS << getState();
10453     return OS.str();
10454   }
10455 
10456   template <typename AAType>
10457   static std::optional<Value *> askOtherAA(Attributor &A,
10458                                            const AbstractAttribute &AA,
10459                                            const IRPosition &IRP, Type &Ty) {
10460     if (isa<Constant>(IRP.getAssociatedValue()))
10461       return &IRP.getAssociatedValue();
10462     std::optional<Constant *> C = askForAssumedConstant<AAType>(A, AA, IRP, Ty);
10463     if (!C)
10464       return std::nullopt;
10465     if (*C)
10466       if (auto *CC = AA::getWithType(**C, Ty))
10467         return CC;
10468     return nullptr;
10469   }
10470 
10471   void addValue(Attributor &A, StateType &State, Value &V,
10472                 const Instruction *CtxI, AA::ValueScope S,
10473                 Function *AnchorScope) const {
10474 
10475     IRPosition ValIRP = IRPosition::value(V);
10476     if (auto *CB = dyn_cast_or_null<CallBase>(CtxI)) {
10477       for (const auto &U : CB->args()) {
10478         if (U.get() != &V)
10479           continue;
10480         ValIRP = IRPosition::callsite_argument(*CB, CB->getArgOperandNo(&U));
10481         break;
10482       }
10483     }
10484 
10485     Value *VPtr = &V;
10486     if (ValIRP.getAssociatedType()->isIntegerTy()) {
10487       Type &Ty = *getAssociatedType();
10488       std::optional<Value *> SimpleV =
10489           askOtherAA<AAValueConstantRange>(A, *this, ValIRP, Ty);
10490       if (SimpleV.has_value() && !*SimpleV) {
10491         auto &PotentialConstantsAA = A.getAAFor<AAPotentialConstantValues>(
10492             *this, ValIRP, DepClassTy::OPTIONAL);
10493         if (PotentialConstantsAA.isValidState()) {
10494           for (const auto &It : PotentialConstantsAA.getAssumedSet())
10495             State.unionAssumed({{*ConstantInt::get(&Ty, It), nullptr}, S});
10496           if (PotentialConstantsAA.undefIsContained())
10497             State.unionAssumed({{*UndefValue::get(&Ty), nullptr}, S});
10498           return;
10499         }
10500       }
10501       if (!SimpleV.has_value())
10502         return;
10503 
10504       if (*SimpleV)
10505         VPtr = *SimpleV;
10506     }
10507 
10508     if (isa<ConstantInt>(VPtr))
10509       CtxI = nullptr;
10510     if (!AA::isValidInScope(*VPtr, AnchorScope))
10511       S = AA::ValueScope(S | AA::Interprocedural);
10512 
10513     State.unionAssumed({{*VPtr, CtxI}, S});
10514   }
10515 
10516   /// Helper struct to tie a value+context pair together with the scope for
10517   /// which this is the simplified version.
10518   struct ItemInfo {
10519     AA::ValueAndContext I;
10520     AA::ValueScope S;
10521 
10522     bool operator==(const ItemInfo &II) const {
10523       return II.I == I && II.S == S;
10524     };
10525     bool operator<(const ItemInfo &II) const {
10526       if (I == II.I)
10527         return S < II.S;
10528       return I < II.I;
10529     };
10530   };
10531 
10532   bool recurseForValue(Attributor &A, const IRPosition &IRP, AA::ValueScope S) {
10533     SmallMapVector<AA::ValueAndContext, int, 8> ValueScopeMap;
10534     for (auto CS : {AA::Intraprocedural, AA::Interprocedural}) {
10535       if (!(CS & S))
10536         continue;
10537 
10538       bool UsedAssumedInformation = false;
10539       SmallVector<AA::ValueAndContext> Values;
10540       if (!A.getAssumedSimplifiedValues(IRP, this, Values, CS,
10541                                         UsedAssumedInformation))
10542         return false;
10543 
10544       for (auto &It : Values)
10545         ValueScopeMap[It] += CS;
10546     }
10547     for (auto &It : ValueScopeMap)
10548       addValue(A, getState(), *It.first.getValue(), It.first.getCtxI(),
10549                AA::ValueScope(It.second), getAnchorScope());
10550 
10551     return true;
10552   }
10553 
10554   void giveUpOnIntraprocedural(Attributor &A) {
10555     auto NewS = StateType::getBestState(getState());
10556     for (const auto &It : getAssumedSet()) {
10557       if (It.second == AA::Intraprocedural)
10558         continue;
10559       addValue(A, NewS, *It.first.getValue(), It.first.getCtxI(),
10560                AA::Interprocedural, getAnchorScope());
10561     }
10562     assert(!undefIsContained() && "Undef should be an explicit value!");
10563     addValue(A, NewS, getAssociatedValue(), getCtxI(), AA::Intraprocedural,
10564              getAnchorScope());
10565     getState() = NewS;
10566   }
10567 
10568   /// See AbstractState::indicatePessimisticFixpoint(...).
10569   ChangeStatus indicatePessimisticFixpoint() override {
10570     getState() = StateType::getBestState(getState());
10571     getState().unionAssumed({{getAssociatedValue(), getCtxI()}, AA::AnyScope});
10572     AAPotentialValues::indicateOptimisticFixpoint();
10573     return ChangeStatus::CHANGED;
10574   }
10575 
10576   /// See AbstractAttribute::updateImpl(...).
10577   ChangeStatus updateImpl(Attributor &A) override {
10578     return indicatePessimisticFixpoint();
10579   }
10580 
10581   /// See AbstractAttribute::manifest(...).
10582   ChangeStatus manifest(Attributor &A) override {
10583     SmallVector<AA::ValueAndContext> Values;
10584     for (AA::ValueScope S : {AA::Interprocedural, AA::Intraprocedural}) {
10585       Values.clear();
10586       if (!getAssumedSimplifiedValues(A, Values, S))
10587         continue;
10588       Value &OldV = getAssociatedValue();
10589       if (isa<UndefValue>(OldV))
10590         continue;
10591       Value *NewV = getSingleValue(A, *this, getIRPosition(), Values);
10592       if (!NewV || NewV == &OldV)
10593         continue;
10594       if (getCtxI() &&
10595           !AA::isValidAtPosition({*NewV, *getCtxI()}, A.getInfoCache()))
10596         continue;
10597       if (A.changeAfterManifest(getIRPosition(), *NewV))
10598         return ChangeStatus::CHANGED;
10599     }
10600     return ChangeStatus::UNCHANGED;
10601   }
10602 
10603   bool getAssumedSimplifiedValues(Attributor &A,
10604                                   SmallVectorImpl<AA::ValueAndContext> &Values,
10605                                   AA::ValueScope S) const override {
10606     if (!isValidState())
10607       return false;
10608     for (const auto &It : getAssumedSet())
10609       if (It.second & S)
10610         Values.push_back(It.first);
10611     assert(!undefIsContained() && "Undef should be an explicit value!");
10612     return true;
10613   }
10614 };
10615 
10616 struct AAPotentialValuesFloating : AAPotentialValuesImpl {
10617   AAPotentialValuesFloating(const IRPosition &IRP, Attributor &A)
10618       : AAPotentialValuesImpl(IRP, A) {}
10619 
10620   /// See AbstractAttribute::updateImpl(...).
10621   ChangeStatus updateImpl(Attributor &A) override {
10622     auto AssumedBefore = getAssumed();
10623 
10624     genericValueTraversal(A);
10625 
10626     return (AssumedBefore == getAssumed()) ? ChangeStatus::UNCHANGED
10627                                            : ChangeStatus::CHANGED;
10628   }
10629 
10630   /// Helper struct to remember which AAIsDead instances we actually used.
10631   struct LivenessInfo {
10632     const AAIsDead *LivenessAA = nullptr;
10633     bool AnyDead = false;
10634   };
10635 
10636   /// Check if \p Cmp is a comparison we can simplify.
10637   ///
10638   /// We handle multiple cases, one in which at least one operand is an
10639   /// (assumed) nullptr. If so, try to simplify it using AANonNull on the other
10640   /// operand. Return true if successful, in that case Worklist will be updated.
10641   bool handleCmp(Attributor &A, Value &Cmp, Value *LHS, Value *RHS,
10642                  CmpInst::Predicate Pred, ItemInfo II,
10643                  SmallVectorImpl<ItemInfo> &Worklist) {
10644 
10645     // Simplify the operands first.
10646     bool UsedAssumedInformation = false;
10647     const auto &SimplifiedLHS = A.getAssumedSimplified(
10648         IRPosition::value(*LHS, getCallBaseContext()), *this,
10649         UsedAssumedInformation, AA::Intraprocedural);
10650     if (!SimplifiedLHS.has_value())
10651       return true;
10652     if (!*SimplifiedLHS)
10653       return false;
10654     LHS = *SimplifiedLHS;
10655 
10656     const auto &SimplifiedRHS = A.getAssumedSimplified(
10657         IRPosition::value(*RHS, getCallBaseContext()), *this,
10658         UsedAssumedInformation, AA::Intraprocedural);
10659     if (!SimplifiedRHS.has_value())
10660       return true;
10661     if (!*SimplifiedRHS)
10662       return false;
10663     RHS = *SimplifiedRHS;
10664 
10665     LLVMContext &Ctx = LHS->getContext();
10666     // Handle the trivial case first in which we don't even need to think about
10667     // null or non-null.
10668     if (LHS == RHS &&
10669         (CmpInst::isTrueWhenEqual(Pred) || CmpInst::isFalseWhenEqual(Pred))) {
10670       Constant *NewV = ConstantInt::get(Type::getInt1Ty(Ctx),
10671                                         CmpInst::isTrueWhenEqual(Pred));
10672       addValue(A, getState(), *NewV, /* CtxI */ nullptr, II.S,
10673                getAnchorScope());
10674       return true;
10675     }
10676 
10677     // From now on we only handle equalities (==, !=).
10678     if (!CmpInst::isEquality(Pred))
10679       return false;
10680 
10681     bool LHSIsNull = isa<ConstantPointerNull>(LHS);
10682     bool RHSIsNull = isa<ConstantPointerNull>(RHS);
10683     if (!LHSIsNull && !RHSIsNull)
10684       return false;
10685 
10686     // Left is the nullptr ==/!= non-nullptr case. We'll use AANonNull on the
10687     // non-nullptr operand and if we assume it's non-null we can conclude the
10688     // result of the comparison.
10689     assert((LHSIsNull || RHSIsNull) &&
10690            "Expected nullptr versus non-nullptr comparison at this point");
10691 
10692     // The index is the operand that we assume is not null.
10693     unsigned PtrIdx = LHSIsNull;
10694     auto &PtrNonNullAA = A.getAAFor<AANonNull>(
10695         *this, IRPosition::value(*(PtrIdx ? RHS : LHS)), DepClassTy::REQUIRED);
10696     if (!PtrNonNullAA.isAssumedNonNull())
10697       return false;
10698 
10699     // The new value depends on the predicate, true for != and false for ==.
10700     Constant *NewV =
10701         ConstantInt::get(Type::getInt1Ty(Ctx), Pred == CmpInst::ICMP_NE);
10702     addValue(A, getState(), *NewV, /* CtxI */ nullptr, II.S, getAnchorScope());
10703     return true;
10704   }
10705 
10706   bool handleSelectInst(Attributor &A, SelectInst &SI, ItemInfo II,
10707                         SmallVectorImpl<ItemInfo> &Worklist) {
10708     const Instruction *CtxI = II.I.getCtxI();
10709     bool UsedAssumedInformation = false;
10710 
10711     std::optional<Constant *> C =
10712         A.getAssumedConstant(*SI.getCondition(), *this, UsedAssumedInformation);
10713     bool NoValueYet = !C.has_value();
10714     if (NoValueYet || isa_and_nonnull<UndefValue>(*C))
10715       return true;
10716     if (auto *CI = dyn_cast_or_null<ConstantInt>(*C)) {
10717       if (CI->isZero())
10718         Worklist.push_back({{*SI.getFalseValue(), CtxI}, II.S});
10719       else
10720         Worklist.push_back({{*SI.getTrueValue(), CtxI}, II.S});
10721     } else if (&SI == &getAssociatedValue()) {
10722       // We could not simplify the condition, assume both values.
10723       Worklist.push_back({{*SI.getTrueValue(), CtxI}, II.S});
10724       Worklist.push_back({{*SI.getFalseValue(), CtxI}, II.S});
10725     } else {
10726       std::optional<Value *> SimpleV = A.getAssumedSimplified(
10727           IRPosition::inst(SI), *this, UsedAssumedInformation, II.S);
10728       if (!SimpleV.has_value())
10729         return true;
10730       if (*SimpleV) {
10731         addValue(A, getState(), **SimpleV, CtxI, II.S, getAnchorScope());
10732         return true;
10733       }
10734       return false;
10735     }
10736     return true;
10737   }
10738 
10739   bool handleLoadInst(Attributor &A, LoadInst &LI, ItemInfo II,
10740                       SmallVectorImpl<ItemInfo> &Worklist) {
10741     SmallSetVector<Value *, 4> PotentialCopies;
10742     SmallSetVector<Instruction *, 4> PotentialValueOrigins;
10743     bool UsedAssumedInformation = false;
10744     if (!AA::getPotentiallyLoadedValues(A, LI, PotentialCopies,
10745                                         PotentialValueOrigins, *this,
10746                                         UsedAssumedInformation,
10747                                         /* OnlyExact */ true)) {
10748       LLVM_DEBUG(dbgs() << "[AAPotentialValues] Failed to get potentially "
10749                            "loaded values for load instruction "
10750                         << LI << "\n");
10751       return false;
10752     }
10753 
10754     // Do not simplify loads that are only used in llvm.assume if we cannot also
10755     // remove all stores that may feed into the load. The reason is that the
10756     // assume is probably worth something as long as the stores are around.
10757     InformationCache &InfoCache = A.getInfoCache();
10758     if (InfoCache.isOnlyUsedByAssume(LI)) {
10759       if (!llvm::all_of(PotentialValueOrigins, [&](Instruction *I) {
10760             if (!I)
10761               return true;
10762             if (auto *SI = dyn_cast<StoreInst>(I))
10763               return A.isAssumedDead(SI->getOperandUse(0), this,
10764                                      /* LivenessAA */ nullptr,
10765                                      UsedAssumedInformation,
10766                                      /* CheckBBLivenessOnly */ false);
10767             return A.isAssumedDead(*I, this, /* LivenessAA */ nullptr,
10768                                    UsedAssumedInformation,
10769                                    /* CheckBBLivenessOnly */ false);
10770           })) {
10771         LLVM_DEBUG(dbgs() << "[AAPotentialValues] Load is onl used by assumes "
10772                              "and we cannot delete all the stores: "
10773                           << LI << "\n");
10774         return false;
10775       }
10776     }
10777 
10778     // Values have to be dynamically unique or we loose the fact that a
10779     // single llvm::Value might represent two runtime values (e.g.,
10780     // stack locations in different recursive calls).
10781     const Instruction *CtxI = II.I.getCtxI();
10782     bool ScopeIsLocal = (II.S & AA::Intraprocedural);
10783     bool AllLocal = ScopeIsLocal;
10784     bool DynamicallyUnique = llvm::all_of(PotentialCopies, [&](Value *PC) {
10785       AllLocal &= AA::isValidInScope(*PC, getAnchorScope());
10786       return AA::isDynamicallyUnique(A, *this, *PC);
10787     });
10788     if (!DynamicallyUnique) {
10789       LLVM_DEBUG(dbgs() << "[AAPotentialValues] Not all potentially loaded "
10790                            "values are dynamically unique: "
10791                         << LI << "\n");
10792       return false;
10793     }
10794 
10795     for (auto *PotentialCopy : PotentialCopies) {
10796       if (AllLocal) {
10797         Worklist.push_back({{*PotentialCopy, CtxI}, II.S});
10798       } else {
10799         Worklist.push_back({{*PotentialCopy, CtxI}, AA::Interprocedural});
10800       }
10801     }
10802     if (!AllLocal && ScopeIsLocal)
10803       addValue(A, getState(), LI, CtxI, AA::Intraprocedural, getAnchorScope());
10804     return true;
10805   }
10806 
10807   bool handlePHINode(
10808       Attributor &A, PHINode &PHI, ItemInfo II,
10809       SmallVectorImpl<ItemInfo> &Worklist,
10810       SmallMapVector<const Function *, LivenessInfo, 4> &LivenessAAs) {
10811     auto GetLivenessInfo = [&](const Function &F) -> LivenessInfo & {
10812       LivenessInfo &LI = LivenessAAs[&F];
10813       if (!LI.LivenessAA)
10814         LI.LivenessAA = &A.getAAFor<AAIsDead>(*this, IRPosition::function(F),
10815                                               DepClassTy::NONE);
10816       return LI;
10817     };
10818 
10819     if (&PHI == &getAssociatedValue()) {
10820       LivenessInfo &LI = GetLivenessInfo(*PHI.getFunction());
10821       for (unsigned u = 0, e = PHI.getNumIncomingValues(); u < e; u++) {
10822         BasicBlock *IncomingBB = PHI.getIncomingBlock(u);
10823         if (LI.LivenessAA->isEdgeDead(IncomingBB, PHI.getParent())) {
10824           LI.AnyDead = true;
10825           continue;
10826         }
10827         Worklist.push_back(
10828             {{*PHI.getIncomingValue(u), IncomingBB->getTerminator()}, II.S});
10829       }
10830       return true;
10831     }
10832 
10833     bool UsedAssumedInformation = false;
10834     std::optional<Value *> SimpleV = A.getAssumedSimplified(
10835         IRPosition::inst(PHI), *this, UsedAssumedInformation, II.S);
10836     if (!SimpleV.has_value())
10837       return true;
10838     if (!(*SimpleV))
10839       return false;
10840     addValue(A, getState(), **SimpleV, &PHI, II.S, getAnchorScope());
10841     return true;
10842   }
10843 
10844   /// Use the generic, non-optimistic InstSimplfy functionality if we managed to
10845   /// simplify any operand of the instruction \p I. Return true if successful,
10846   /// in that case Worklist will be updated.
10847   bool handleGenericInst(Attributor &A, Instruction &I, ItemInfo II,
10848                          SmallVectorImpl<ItemInfo> &Worklist) {
10849     bool SomeSimplified = false;
10850     bool UsedAssumedInformation = false;
10851 
10852     SmallVector<Value *, 8> NewOps(I.getNumOperands());
10853     int Idx = 0;
10854     for (Value *Op : I.operands()) {
10855       const auto &SimplifiedOp = A.getAssumedSimplified(
10856           IRPosition::value(*Op, getCallBaseContext()), *this,
10857           UsedAssumedInformation, AA::Intraprocedural);
10858       // If we are not sure about any operand we are not sure about the entire
10859       // instruction, we'll wait.
10860       if (!SimplifiedOp.has_value())
10861         return true;
10862 
10863       if (*SimplifiedOp)
10864         NewOps[Idx] = *SimplifiedOp;
10865       else
10866         NewOps[Idx] = Op;
10867 
10868       SomeSimplified |= (NewOps[Idx] != Op);
10869       ++Idx;
10870     }
10871 
10872     // We won't bother with the InstSimplify interface if we didn't simplify any
10873     // operand ourselves.
10874     if (!SomeSimplified)
10875       return false;
10876 
10877     InformationCache &InfoCache = A.getInfoCache();
10878     Function *F = I.getFunction();
10879     const auto *DT =
10880         InfoCache.getAnalysisResultForFunction<DominatorTreeAnalysis>(*F);
10881     const auto *TLI = A.getInfoCache().getTargetLibraryInfoForFunction(*F);
10882     auto *AC = InfoCache.getAnalysisResultForFunction<AssumptionAnalysis>(*F);
10883     OptimizationRemarkEmitter *ORE = nullptr;
10884 
10885     const DataLayout &DL = I.getModule()->getDataLayout();
10886     SimplifyQuery Q(DL, TLI, DT, AC, &I);
10887     Value *NewV = simplifyInstructionWithOperands(&I, NewOps, Q, ORE);
10888     if (!NewV || NewV == &I)
10889       return false;
10890 
10891     LLVM_DEBUG(dbgs() << "Generic inst " << I << " assumed simplified to "
10892                       << *NewV << "\n");
10893     Worklist.push_back({{*NewV, II.I.getCtxI()}, II.S});
10894     return true;
10895   }
10896 
10897   bool simplifyInstruction(
10898       Attributor &A, Instruction &I, ItemInfo II,
10899       SmallVectorImpl<ItemInfo> &Worklist,
10900       SmallMapVector<const Function *, LivenessInfo, 4> &LivenessAAs) {
10901     if (auto *CI = dyn_cast<CmpInst>(&I))
10902       if (handleCmp(A, *CI, CI->getOperand(0), CI->getOperand(1),
10903                     CI->getPredicate(), II, Worklist))
10904         return true;
10905 
10906     switch (I.getOpcode()) {
10907     case Instruction::Select:
10908       return handleSelectInst(A, cast<SelectInst>(I), II, Worklist);
10909     case Instruction::PHI:
10910       return handlePHINode(A, cast<PHINode>(I), II, Worklist, LivenessAAs);
10911     case Instruction::Load:
10912       return handleLoadInst(A, cast<LoadInst>(I), II, Worklist);
10913     default:
10914       return handleGenericInst(A, I, II, Worklist);
10915     };
10916     return false;
10917   }
10918 
10919   void genericValueTraversal(Attributor &A) {
10920     SmallMapVector<const Function *, LivenessInfo, 4> LivenessAAs;
10921 
10922     Value *InitialV = &getAssociatedValue();
10923     SmallSet<ItemInfo, 16> Visited;
10924     SmallVector<ItemInfo, 16> Worklist;
10925     Worklist.push_back({{*InitialV, getCtxI()}, AA::AnyScope});
10926 
10927     int Iteration = 0;
10928     do {
10929       ItemInfo II = Worklist.pop_back_val();
10930       Value *V = II.I.getValue();
10931       assert(V);
10932       const Instruction *CtxI = II.I.getCtxI();
10933       AA::ValueScope S = II.S;
10934 
10935       // Check if we should process the current value. To prevent endless
10936       // recursion keep a record of the values we followed!
10937       if (!Visited.insert(II).second)
10938         continue;
10939 
10940       // Make sure we limit the compile time for complex expressions.
10941       if (Iteration++ >= MaxPotentialValuesIterations) {
10942         LLVM_DEBUG(dbgs() << "Generic value traversal reached iteration limit: "
10943                           << Iteration << "!\n");
10944         addValue(A, getState(), *V, CtxI, S, getAnchorScope());
10945         continue;
10946       }
10947 
10948       // Explicitly look through calls with a "returned" attribute if we do
10949       // not have a pointer as stripPointerCasts only works on them.
10950       Value *NewV = nullptr;
10951       if (V->getType()->isPointerTy()) {
10952         NewV = AA::getWithType(*V->stripPointerCasts(), *V->getType());
10953       } else {
10954         auto *CB = dyn_cast<CallBase>(V);
10955         if (CB && CB->getCalledFunction()) {
10956           for (Argument &Arg : CB->getCalledFunction()->args())
10957             if (Arg.hasReturnedAttr()) {
10958               NewV = CB->getArgOperand(Arg.getArgNo());
10959               break;
10960             }
10961         }
10962       }
10963       if (NewV && NewV != V) {
10964         Worklist.push_back({{*NewV, CtxI}, S});
10965         continue;
10966       }
10967 
10968       if (auto *CE = dyn_cast<ConstantExpr>(V)) {
10969         if (CE->getOpcode() == Instruction::ICmp)
10970           if (handleCmp(A, *CE, CE->getOperand(0), CE->getOperand(1),
10971                         CmpInst::Predicate(CE->getPredicate()), II, Worklist))
10972             continue;
10973       }
10974 
10975       if (auto *I = dyn_cast<Instruction>(V)) {
10976         if (simplifyInstruction(A, *I, II, Worklist, LivenessAAs))
10977           continue;
10978       }
10979 
10980       if (V != InitialV || isa<Argument>(V))
10981         if (recurseForValue(A, IRPosition::value(*V), II.S))
10982           continue;
10983 
10984       // If we haven't stripped anything we give up.
10985       if (V == InitialV && CtxI == getCtxI()) {
10986         indicatePessimisticFixpoint();
10987         return;
10988       }
10989 
10990       addValue(A, getState(), *V, CtxI, S, getAnchorScope());
10991     } while (!Worklist.empty());
10992 
10993     // If we actually used liveness information so we have to record a
10994     // dependence.
10995     for (auto &It : LivenessAAs)
10996       if (It.second.AnyDead)
10997         A.recordDependence(*It.second.LivenessAA, *this, DepClassTy::OPTIONAL);
10998   }
10999 
11000   /// See AbstractAttribute::trackStatistics()
11001   void trackStatistics() const override {
11002     STATS_DECLTRACK_FLOATING_ATTR(potential_values)
11003   }
11004 };
11005 
11006 struct AAPotentialValuesArgument final : AAPotentialValuesImpl {
11007   using Base = AAPotentialValuesImpl;
11008   AAPotentialValuesArgument(const IRPosition &IRP, Attributor &A)
11009       : Base(IRP, A) {}
11010 
11011   /// See AbstractAttribute::initialize(..).
11012   void initialize(Attributor &A) override {
11013     auto &Arg = cast<Argument>(getAssociatedValue());
11014     if (Arg.hasPointeeInMemoryValueAttr())
11015       indicatePessimisticFixpoint();
11016   }
11017 
11018   /// See AbstractAttribute::updateImpl(...).
11019   ChangeStatus updateImpl(Attributor &A) override {
11020     auto AssumedBefore = getAssumed();
11021 
11022     unsigned CSArgNo = getCallSiteArgNo();
11023 
11024     bool UsedAssumedInformation = false;
11025     SmallVector<AA::ValueAndContext> Values;
11026     auto CallSitePred = [&](AbstractCallSite ACS) {
11027       const auto CSArgIRP = IRPosition::callsite_argument(ACS, CSArgNo);
11028       if (CSArgIRP.getPositionKind() == IRP_INVALID)
11029         return false;
11030 
11031       if (!A.getAssumedSimplifiedValues(CSArgIRP, this, Values,
11032                                         AA::Interprocedural,
11033                                         UsedAssumedInformation))
11034         return false;
11035 
11036       return isValidState();
11037     };
11038 
11039     if (!A.checkForAllCallSites(CallSitePred, *this,
11040                                 /* RequireAllCallSites */ true,
11041                                 UsedAssumedInformation))
11042       return indicatePessimisticFixpoint();
11043 
11044     Function *Fn = getAssociatedFunction();
11045     bool AnyNonLocal = false;
11046     for (auto &It : Values) {
11047       if (isa<Constant>(It.getValue())) {
11048         addValue(A, getState(), *It.getValue(), It.getCtxI(), AA::AnyScope,
11049                  getAnchorScope());
11050         continue;
11051       }
11052       if (!AA::isDynamicallyUnique(A, *this, *It.getValue()))
11053         return indicatePessimisticFixpoint();
11054 
11055       if (auto *Arg = dyn_cast<Argument>(It.getValue()))
11056         if (Arg->getParent() == Fn) {
11057           addValue(A, getState(), *It.getValue(), It.getCtxI(), AA::AnyScope,
11058                    getAnchorScope());
11059           continue;
11060         }
11061       addValue(A, getState(), *It.getValue(), It.getCtxI(), AA::Interprocedural,
11062                getAnchorScope());
11063       AnyNonLocal = true;
11064     }
11065     assert(!undefIsContained() && "Undef should be an explicit value!");
11066     if (AnyNonLocal)
11067       giveUpOnIntraprocedural(A);
11068 
11069     return (AssumedBefore == getAssumed()) ? ChangeStatus::UNCHANGED
11070                                            : ChangeStatus::CHANGED;
11071   }
11072 
11073   /// See AbstractAttribute::trackStatistics()
11074   void trackStatistics() const override {
11075     STATS_DECLTRACK_ARG_ATTR(potential_values)
11076   }
11077 };
11078 
11079 struct AAPotentialValuesReturned
11080     : AAReturnedFromReturnedValues<AAPotentialValues, AAPotentialValuesImpl> {
11081   using Base =
11082       AAReturnedFromReturnedValues<AAPotentialValues, AAPotentialValuesImpl>;
11083   AAPotentialValuesReturned(const IRPosition &IRP, Attributor &A)
11084       : Base(IRP, A) {}
11085 
11086   /// See AbstractAttribute::initialize(..).
11087   void initialize(Attributor &A) override {
11088     if (A.hasSimplificationCallback(getIRPosition()))
11089       indicatePessimisticFixpoint();
11090     else
11091       AAPotentialValues::initialize(A);
11092   }
11093 
11094   ChangeStatus manifest(Attributor &A) override {
11095     // We queried AAValueSimplify for the returned values so they will be
11096     // replaced if a simplified form was found. Nothing to do here.
11097     return ChangeStatus::UNCHANGED;
11098   }
11099 
11100   ChangeStatus indicatePessimisticFixpoint() override {
11101     return AAPotentialValues::indicatePessimisticFixpoint();
11102   }
11103 
11104   /// See AbstractAttribute::trackStatistics()
11105   void trackStatistics() const override {
11106     STATS_DECLTRACK_FNRET_ATTR(potential_values)
11107   }
11108 };
11109 
11110 struct AAPotentialValuesFunction : AAPotentialValuesImpl {
11111   AAPotentialValuesFunction(const IRPosition &IRP, Attributor &A)
11112       : AAPotentialValuesImpl(IRP, A) {}
11113 
11114   /// See AbstractAttribute::updateImpl(...).
11115   ChangeStatus updateImpl(Attributor &A) override {
11116     llvm_unreachable("AAPotentialValues(Function|CallSite)::updateImpl will "
11117                      "not be called");
11118   }
11119 
11120   /// See AbstractAttribute::trackStatistics()
11121   void trackStatistics() const override {
11122     STATS_DECLTRACK_FN_ATTR(potential_values)
11123   }
11124 };
11125 
11126 struct AAPotentialValuesCallSite : AAPotentialValuesFunction {
11127   AAPotentialValuesCallSite(const IRPosition &IRP, Attributor &A)
11128       : AAPotentialValuesFunction(IRP, A) {}
11129 
11130   /// See AbstractAttribute::trackStatistics()
11131   void trackStatistics() const override {
11132     STATS_DECLTRACK_CS_ATTR(potential_values)
11133   }
11134 };
11135 
11136 struct AAPotentialValuesCallSiteReturned : AAPotentialValuesImpl {
11137   AAPotentialValuesCallSiteReturned(const IRPosition &IRP, Attributor &A)
11138       : AAPotentialValuesImpl(IRP, A) {}
11139 
11140   /// See AbstractAttribute::updateImpl(...).
11141   ChangeStatus updateImpl(Attributor &A) override {
11142     auto AssumedBefore = getAssumed();
11143 
11144     Function *Callee = getAssociatedFunction();
11145     if (!Callee)
11146       return indicatePessimisticFixpoint();
11147 
11148     bool UsedAssumedInformation = false;
11149     auto *CB = cast<CallBase>(getCtxI());
11150     if (CB->isMustTailCall() &&
11151         !A.isAssumedDead(IRPosition::inst(*CB), this, nullptr,
11152                          UsedAssumedInformation))
11153       return indicatePessimisticFixpoint();
11154 
11155     SmallVector<AA::ValueAndContext> Values;
11156     if (!A.getAssumedSimplifiedValues(IRPosition::returned(*Callee), this,
11157                                       Values, AA::Intraprocedural,
11158                                       UsedAssumedInformation))
11159       return indicatePessimisticFixpoint();
11160 
11161     Function *Caller = CB->getCaller();
11162 
11163     bool AnyNonLocal = false;
11164     for (auto &It : Values) {
11165       Value *V = It.getValue();
11166       std::optional<Value *> CallerV = A.translateArgumentToCallSiteContent(
11167           V, *CB, *this, UsedAssumedInformation);
11168       if (!CallerV.has_value()) {
11169         // Nothing to do as long as no value was determined.
11170         continue;
11171       }
11172       V = *CallerV ? *CallerV : V;
11173       if (AA::isDynamicallyUnique(A, *this, *V) &&
11174           AA::isValidInScope(*V, Caller)) {
11175         if (*CallerV) {
11176           SmallVector<AA::ValueAndContext> ArgValues;
11177           IRPosition IRP = IRPosition::value(*V);
11178           if (auto *Arg = dyn_cast<Argument>(V))
11179             if (Arg->getParent() == CB->getCalledFunction())
11180               IRP = IRPosition::callsite_argument(*CB, Arg->getArgNo());
11181           if (recurseForValue(A, IRP, AA::AnyScope))
11182             continue;
11183         }
11184         addValue(A, getState(), *V, CB, AA::AnyScope, getAnchorScope());
11185       } else {
11186         AnyNonLocal = true;
11187         break;
11188       }
11189     }
11190     if (AnyNonLocal) {
11191       Values.clear();
11192       if (!A.getAssumedSimplifiedValues(IRPosition::returned(*Callee), this,
11193                                         Values, AA::Interprocedural,
11194                                         UsedAssumedInformation))
11195         return indicatePessimisticFixpoint();
11196       AnyNonLocal = false;
11197       getState() = PotentialLLVMValuesState::getBestState();
11198       for (auto &It : Values) {
11199         Value *V = It.getValue();
11200         if (!AA::isDynamicallyUnique(A, *this, *V))
11201           return indicatePessimisticFixpoint();
11202         if (AA::isValidInScope(*V, Caller)) {
11203           addValue(A, getState(), *V, CB, AA::AnyScope, getAnchorScope());
11204         } else {
11205           AnyNonLocal = true;
11206           addValue(A, getState(), *V, CB, AA::Interprocedural,
11207                    getAnchorScope());
11208         }
11209       }
11210       if (AnyNonLocal)
11211         giveUpOnIntraprocedural(A);
11212     }
11213     return (AssumedBefore == getAssumed()) ? ChangeStatus::UNCHANGED
11214                                            : ChangeStatus::CHANGED;
11215   }
11216 
11217   ChangeStatus indicatePessimisticFixpoint() override {
11218     return AAPotentialValues::indicatePessimisticFixpoint();
11219   }
11220 
11221   /// See AbstractAttribute::trackStatistics()
11222   void trackStatistics() const override {
11223     STATS_DECLTRACK_CSRET_ATTR(potential_values)
11224   }
11225 };
11226 
11227 struct AAPotentialValuesCallSiteArgument : AAPotentialValuesFloating {
11228   AAPotentialValuesCallSiteArgument(const IRPosition &IRP, Attributor &A)
11229       : AAPotentialValuesFloating(IRP, A) {}
11230 
11231   /// See AbstractAttribute::trackStatistics()
11232   void trackStatistics() const override {
11233     STATS_DECLTRACK_CSARG_ATTR(potential_values)
11234   }
11235 };
11236 } // namespace
11237 
11238 /// ---------------------- Assumption Propagation ------------------------------
11239 namespace {
11240 struct AAAssumptionInfoImpl : public AAAssumptionInfo {
11241   AAAssumptionInfoImpl(const IRPosition &IRP, Attributor &A,
11242                        const DenseSet<StringRef> &Known)
11243       : AAAssumptionInfo(IRP, A, Known) {}
11244 
11245   bool hasAssumption(const StringRef Assumption) const override {
11246     return isValidState() && setContains(Assumption);
11247   }
11248 
11249   /// See AbstractAttribute::getAsStr()
11250   const std::string getAsStr() const override {
11251     const SetContents &Known = getKnown();
11252     const SetContents &Assumed = getAssumed();
11253 
11254     const std::string KnownStr =
11255         llvm::join(Known.getSet().begin(), Known.getSet().end(), ",");
11256     const std::string AssumedStr =
11257         (Assumed.isUniversal())
11258             ? "Universal"
11259             : llvm::join(Assumed.getSet().begin(), Assumed.getSet().end(), ",");
11260 
11261     return "Known [" + KnownStr + "]," + " Assumed [" + AssumedStr + "]";
11262   }
11263 };
11264 
11265 /// Propagates assumption information from parent functions to all of their
11266 /// successors. An assumption can be propagated if the containing function
11267 /// dominates the called function.
11268 ///
11269 /// We start with a "known" set of assumptions already valid for the associated
11270 /// function and an "assumed" set that initially contains all possible
11271 /// assumptions. The assumed set is inter-procedurally updated by narrowing its
11272 /// contents as concrete values are known. The concrete values are seeded by the
11273 /// first nodes that are either entries into the call graph, or contains no
11274 /// assumptions. Each node is updated as the intersection of the assumed state
11275 /// with all of its predecessors.
11276 struct AAAssumptionInfoFunction final : AAAssumptionInfoImpl {
11277   AAAssumptionInfoFunction(const IRPosition &IRP, Attributor &A)
11278       : AAAssumptionInfoImpl(IRP, A,
11279                              getAssumptions(*IRP.getAssociatedFunction())) {}
11280 
11281   /// See AbstractAttribute::manifest(...).
11282   ChangeStatus manifest(Attributor &A) override {
11283     const auto &Assumptions = getKnown();
11284 
11285     // Don't manifest a universal set if it somehow made it here.
11286     if (Assumptions.isUniversal())
11287       return ChangeStatus::UNCHANGED;
11288 
11289     Function *AssociatedFunction = getAssociatedFunction();
11290 
11291     bool Changed = addAssumptions(*AssociatedFunction, Assumptions.getSet());
11292 
11293     return Changed ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED;
11294   }
11295 
11296   /// See AbstractAttribute::updateImpl(...).
11297   ChangeStatus updateImpl(Attributor &A) override {
11298     bool Changed = false;
11299 
11300     auto CallSitePred = [&](AbstractCallSite ACS) {
11301       const auto &AssumptionAA = A.getAAFor<AAAssumptionInfo>(
11302           *this, IRPosition::callsite_function(*ACS.getInstruction()),
11303           DepClassTy::REQUIRED);
11304       // Get the set of assumptions shared by all of this function's callers.
11305       Changed |= getIntersection(AssumptionAA.getAssumed());
11306       return !getAssumed().empty() || !getKnown().empty();
11307     };
11308 
11309     bool UsedAssumedInformation = false;
11310     // Get the intersection of all assumptions held by this node's predecessors.
11311     // If we don't know all the call sites then this is either an entry into the
11312     // call graph or an empty node. This node is known to only contain its own
11313     // assumptions and can be propagated to its successors.
11314     if (!A.checkForAllCallSites(CallSitePred, *this, true,
11315                                 UsedAssumedInformation))
11316       return indicatePessimisticFixpoint();
11317 
11318     return Changed ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED;
11319   }
11320 
11321   void trackStatistics() const override {}
11322 };
11323 
11324 /// Assumption Info defined for call sites.
11325 struct AAAssumptionInfoCallSite final : AAAssumptionInfoImpl {
11326 
11327   AAAssumptionInfoCallSite(const IRPosition &IRP, Attributor &A)
11328       : AAAssumptionInfoImpl(IRP, A, getInitialAssumptions(IRP)) {}
11329 
11330   /// See AbstractAttribute::initialize(...).
11331   void initialize(Attributor &A) override {
11332     const IRPosition &FnPos = IRPosition::function(*getAnchorScope());
11333     A.getAAFor<AAAssumptionInfo>(*this, FnPos, DepClassTy::REQUIRED);
11334   }
11335 
11336   /// See AbstractAttribute::manifest(...).
11337   ChangeStatus manifest(Attributor &A) override {
11338     // Don't manifest a universal set if it somehow made it here.
11339     if (getKnown().isUniversal())
11340       return ChangeStatus::UNCHANGED;
11341 
11342     CallBase &AssociatedCall = cast<CallBase>(getAssociatedValue());
11343     bool Changed = addAssumptions(AssociatedCall, getAssumed().getSet());
11344 
11345     return Changed ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED;
11346   }
11347 
11348   /// See AbstractAttribute::updateImpl(...).
11349   ChangeStatus updateImpl(Attributor &A) override {
11350     const IRPosition &FnPos = IRPosition::function(*getAnchorScope());
11351     auto &AssumptionAA =
11352         A.getAAFor<AAAssumptionInfo>(*this, FnPos, DepClassTy::REQUIRED);
11353     bool Changed = getIntersection(AssumptionAA.getAssumed());
11354     return Changed ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED;
11355   }
11356 
11357   /// See AbstractAttribute::trackStatistics()
11358   void trackStatistics() const override {}
11359 
11360 private:
11361   /// Helper to initialized the known set as all the assumptions this call and
11362   /// the callee contain.
11363   DenseSet<StringRef> getInitialAssumptions(const IRPosition &IRP) {
11364     const CallBase &CB = cast<CallBase>(IRP.getAssociatedValue());
11365     auto Assumptions = getAssumptions(CB);
11366     if (const Function *F = CB.getCaller())
11367       set_union(Assumptions, getAssumptions(*F));
11368     if (Function *F = IRP.getAssociatedFunction())
11369       set_union(Assumptions, getAssumptions(*F));
11370     return Assumptions;
11371   }
11372 };
11373 } // namespace
11374 
11375 AACallGraphNode *AACallEdgeIterator::operator*() const {
11376   return static_cast<AACallGraphNode *>(const_cast<AACallEdges *>(
11377       &A.getOrCreateAAFor<AACallEdges>(IRPosition::function(**I))));
11378 }
11379 
11380 void AttributorCallGraph::print() { llvm::WriteGraph(outs(), this); }
11381 
11382 /// ------------------------ UnderlyingObjects ---------------------------------
11383 
11384 namespace {
11385 struct AAUnderlyingObjectsImpl
11386     : StateWrapper<BooleanState, AAUnderlyingObjects> {
11387   using BaseTy = StateWrapper<BooleanState, AAUnderlyingObjects>;
11388   AAUnderlyingObjectsImpl(const IRPosition &IRP, Attributor &A) : BaseTy(IRP) {}
11389 
11390   /// See AbstractAttribute::getAsStr().
11391   const std::string getAsStr() const override {
11392     return std::string("UnderlyingObjects ") +
11393            (isValidState()
11394                 ? (std::string("inter #") +
11395                    std::to_string(InterAssumedUnderlyingObjects.size()) +
11396                    " objs" + std::string(", intra #") +
11397                    std::to_string(IntraAssumedUnderlyingObjects.size()) +
11398                    " objs")
11399                 : "<invalid>");
11400   }
11401 
11402   /// See AbstractAttribute::trackStatistics()
11403   void trackStatistics() const override {}
11404 
11405   /// See AbstractAttribute::updateImpl(...).
11406   ChangeStatus updateImpl(Attributor &A) override {
11407     auto &Ptr = getAssociatedValue();
11408 
11409     auto DoUpdate = [&](SmallSetVector<Value *, 8> &UnderlyingObjects,
11410                         AA::ValueScope Scope) {
11411       bool UsedAssumedInformation = false;
11412       SmallPtrSet<Value *, 8> SeenObjects;
11413       SmallVector<AA::ValueAndContext> Values;
11414 
11415       if (!A.getAssumedSimplifiedValues(IRPosition::value(Ptr), *this, Values,
11416                                         Scope, UsedAssumedInformation))
11417         return UnderlyingObjects.insert(&Ptr);
11418 
11419       bool Changed = false;
11420 
11421       for (unsigned I = 0; I < Values.size(); ++I) {
11422         auto &VAC = Values[I];
11423         auto *Obj = VAC.getValue();
11424         Value *UO = getUnderlyingObject(Obj);
11425         if (UO && UO != VAC.getValue() && SeenObjects.insert(UO).second) {
11426           const auto &OtherAA = A.getAAFor<AAUnderlyingObjects>(
11427               *this, IRPosition::value(*UO), DepClassTy::OPTIONAL);
11428           auto Pred = [&Values](Value &V) {
11429             Values.emplace_back(V, nullptr);
11430             return true;
11431           };
11432 
11433           if (!OtherAA.forallUnderlyingObjects(Pred, Scope))
11434             llvm_unreachable(
11435                 "The forall call should not return false at this position");
11436 
11437           continue;
11438         }
11439 
11440         if (isa<SelectInst>(Obj) || isa<PHINode>(Obj)) {
11441           Changed |= handleIndirect(A, *Obj, UnderlyingObjects, Scope);
11442           continue;
11443         }
11444 
11445         Changed |= UnderlyingObjects.insert(Obj);
11446       }
11447 
11448       return Changed;
11449     };
11450 
11451     bool Changed = false;
11452     Changed |= DoUpdate(IntraAssumedUnderlyingObjects, AA::Intraprocedural);
11453     Changed |= DoUpdate(InterAssumedUnderlyingObjects, AA::Interprocedural);
11454 
11455     return Changed ? ChangeStatus::CHANGED : ChangeStatus::UNCHANGED;
11456   }
11457 
11458   bool forallUnderlyingObjects(
11459       function_ref<bool(Value &)> Pred,
11460       AA::ValueScope Scope = AA::Interprocedural) const override {
11461     if (!isValidState())
11462       return Pred(getAssociatedValue());
11463 
11464     auto &AssumedUnderlyingObjects = Scope == AA::Intraprocedural
11465                                          ? IntraAssumedUnderlyingObjects
11466                                          : InterAssumedUnderlyingObjects;
11467     for (Value *Obj : AssumedUnderlyingObjects)
11468       if (!Pred(*Obj))
11469         return false;
11470 
11471     return true;
11472   }
11473 
11474 private:
11475   /// Handle the case where the value is not the actual underlying value, such
11476   /// as a phi node or a select instruction.
11477   bool handleIndirect(Attributor &A, Value &V,
11478                       SmallSetVector<Value *, 8> &UnderlyingObjects,
11479                       AA::ValueScope Scope) {
11480     bool Changed = false;
11481     const auto &AA = A.getAAFor<AAUnderlyingObjects>(
11482         *this, IRPosition::value(V), DepClassTy::OPTIONAL);
11483     auto Pred = [&](Value &V) {
11484       Changed |= UnderlyingObjects.insert(&V);
11485       return true;
11486     };
11487     if (!AA.forallUnderlyingObjects(Pred, Scope))
11488       llvm_unreachable(
11489           "The forall call should not return false at this position");
11490     return Changed;
11491   }
11492 
11493   /// All the underlying objects collected so far via intra procedural scope.
11494   SmallSetVector<Value *, 8> IntraAssumedUnderlyingObjects;
11495   /// All the underlying objects collected so far via inter procedural scope.
11496   SmallSetVector<Value *, 8> InterAssumedUnderlyingObjects;
11497 };
11498 
11499 struct AAUnderlyingObjectsFloating final : AAUnderlyingObjectsImpl {
11500   AAUnderlyingObjectsFloating(const IRPosition &IRP, Attributor &A)
11501       : AAUnderlyingObjectsImpl(IRP, A) {}
11502 };
11503 
11504 struct AAUnderlyingObjectsArgument final : AAUnderlyingObjectsImpl {
11505   AAUnderlyingObjectsArgument(const IRPosition &IRP, Attributor &A)
11506       : AAUnderlyingObjectsImpl(IRP, A) {}
11507 };
11508 
11509 struct AAUnderlyingObjectsCallSite final : AAUnderlyingObjectsImpl {
11510   AAUnderlyingObjectsCallSite(const IRPosition &IRP, Attributor &A)
11511       : AAUnderlyingObjectsImpl(IRP, A) {}
11512 };
11513 
11514 struct AAUnderlyingObjectsCallSiteArgument final : AAUnderlyingObjectsImpl {
11515   AAUnderlyingObjectsCallSiteArgument(const IRPosition &IRP, Attributor &A)
11516       : AAUnderlyingObjectsImpl(IRP, A) {}
11517 };
11518 
11519 struct AAUnderlyingObjectsReturned final : AAUnderlyingObjectsImpl {
11520   AAUnderlyingObjectsReturned(const IRPosition &IRP, Attributor &A)
11521       : AAUnderlyingObjectsImpl(IRP, A) {}
11522 };
11523 
11524 struct AAUnderlyingObjectsCallSiteReturned final : AAUnderlyingObjectsImpl {
11525   AAUnderlyingObjectsCallSiteReturned(const IRPosition &IRP, Attributor &A)
11526       : AAUnderlyingObjectsImpl(IRP, A) {}
11527 };
11528 
11529 struct AAUnderlyingObjectsFunction final : AAUnderlyingObjectsImpl {
11530   AAUnderlyingObjectsFunction(const IRPosition &IRP, Attributor &A)
11531       : AAUnderlyingObjectsImpl(IRP, A) {}
11532 };
11533 }
11534 
11535 const char AAReturnedValues::ID = 0;
11536 const char AANoUnwind::ID = 0;
11537 const char AANoSync::ID = 0;
11538 const char AANoFree::ID = 0;
11539 const char AANonNull::ID = 0;
11540 const char AANoRecurse::ID = 0;
11541 const char AAWillReturn::ID = 0;
11542 const char AAUndefinedBehavior::ID = 0;
11543 const char AANoAlias::ID = 0;
11544 const char AAIntraFnReachability::ID = 0;
11545 const char AANoReturn::ID = 0;
11546 const char AAIsDead::ID = 0;
11547 const char AADereferenceable::ID = 0;
11548 const char AAAlign::ID = 0;
11549 const char AAInstanceInfo::ID = 0;
11550 const char AANoCapture::ID = 0;
11551 const char AAValueSimplify::ID = 0;
11552 const char AAHeapToStack::ID = 0;
11553 const char AAPrivatizablePtr::ID = 0;
11554 const char AAMemoryBehavior::ID = 0;
11555 const char AAMemoryLocation::ID = 0;
11556 const char AAValueConstantRange::ID = 0;
11557 const char AAPotentialConstantValues::ID = 0;
11558 const char AAPotentialValues::ID = 0;
11559 const char AANoUndef::ID = 0;
11560 const char AACallEdges::ID = 0;
11561 const char AAInterFnReachability::ID = 0;
11562 const char AAPointerInfo::ID = 0;
11563 const char AAAssumptionInfo::ID = 0;
11564 const char AAUnderlyingObjects::ID = 0;
11565 
11566 // Macro magic to create the static generator function for attributes that
11567 // follow the naming scheme.
11568 
11569 #define SWITCH_PK_INV(CLASS, PK, POS_NAME)                                     \
11570   case IRPosition::PK:                                                         \
11571     llvm_unreachable("Cannot create " #CLASS " for a " POS_NAME " position!");
11572 
11573 #define SWITCH_PK_CREATE(CLASS, IRP, PK, SUFFIX)                               \
11574   case IRPosition::PK:                                                         \
11575     AA = new (A.Allocator) CLASS##SUFFIX(IRP, A);                              \
11576     ++NumAAs;                                                                  \
11577     break;
11578 
11579 #define CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(CLASS)                 \
11580   CLASS &CLASS::createForPosition(const IRPosition &IRP, Attributor &A) {      \
11581     CLASS *AA = nullptr;                                                       \
11582     switch (IRP.getPositionKind()) {                                           \
11583       SWITCH_PK_INV(CLASS, IRP_INVALID, "invalid")                             \
11584       SWITCH_PK_INV(CLASS, IRP_FLOAT, "floating")                              \
11585       SWITCH_PK_INV(CLASS, IRP_ARGUMENT, "argument")                           \
11586       SWITCH_PK_INV(CLASS, IRP_RETURNED, "returned")                           \
11587       SWITCH_PK_INV(CLASS, IRP_CALL_SITE_RETURNED, "call site returned")       \
11588       SWITCH_PK_INV(CLASS, IRP_CALL_SITE_ARGUMENT, "call site argument")       \
11589       SWITCH_PK_CREATE(CLASS, IRP, IRP_FUNCTION, Function)                     \
11590       SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE, CallSite)                    \
11591     }                                                                          \
11592     return *AA;                                                                \
11593   }
11594 
11595 #define CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(CLASS)                    \
11596   CLASS &CLASS::createForPosition(const IRPosition &IRP, Attributor &A) {      \
11597     CLASS *AA = nullptr;                                                       \
11598     switch (IRP.getPositionKind()) {                                           \
11599       SWITCH_PK_INV(CLASS, IRP_INVALID, "invalid")                             \
11600       SWITCH_PK_INV(CLASS, IRP_FUNCTION, "function")                           \
11601       SWITCH_PK_INV(CLASS, IRP_CALL_SITE, "call site")                         \
11602       SWITCH_PK_CREATE(CLASS, IRP, IRP_FLOAT, Floating)                        \
11603       SWITCH_PK_CREATE(CLASS, IRP, IRP_ARGUMENT, Argument)                     \
11604       SWITCH_PK_CREATE(CLASS, IRP, IRP_RETURNED, Returned)                     \
11605       SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE_RETURNED, CallSiteReturned)   \
11606       SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE_ARGUMENT, CallSiteArgument)   \
11607     }                                                                          \
11608     return *AA;                                                                \
11609   }
11610 
11611 #define CREATE_ALL_ABSTRACT_ATTRIBUTE_FOR_POSITION(CLASS)                      \
11612   CLASS &CLASS::createForPosition(const IRPosition &IRP, Attributor &A) {      \
11613     CLASS *AA = nullptr;                                                       \
11614     switch (IRP.getPositionKind()) {                                           \
11615       SWITCH_PK_INV(CLASS, IRP_INVALID, "invalid")                             \
11616       SWITCH_PK_CREATE(CLASS, IRP, IRP_FUNCTION, Function)                     \
11617       SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE, CallSite)                    \
11618       SWITCH_PK_CREATE(CLASS, IRP, IRP_FLOAT, Floating)                        \
11619       SWITCH_PK_CREATE(CLASS, IRP, IRP_ARGUMENT, Argument)                     \
11620       SWITCH_PK_CREATE(CLASS, IRP, IRP_RETURNED, Returned)                     \
11621       SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE_RETURNED, CallSiteReturned)   \
11622       SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE_ARGUMENT, CallSiteArgument)   \
11623     }                                                                          \
11624     return *AA;                                                                \
11625   }
11626 
11627 #define CREATE_FUNCTION_ONLY_ABSTRACT_ATTRIBUTE_FOR_POSITION(CLASS)            \
11628   CLASS &CLASS::createForPosition(const IRPosition &IRP, Attributor &A) {      \
11629     CLASS *AA = nullptr;                                                       \
11630     switch (IRP.getPositionKind()) {                                           \
11631       SWITCH_PK_INV(CLASS, IRP_INVALID, "invalid")                             \
11632       SWITCH_PK_INV(CLASS, IRP_ARGUMENT, "argument")                           \
11633       SWITCH_PK_INV(CLASS, IRP_FLOAT, "floating")                              \
11634       SWITCH_PK_INV(CLASS, IRP_RETURNED, "returned")                           \
11635       SWITCH_PK_INV(CLASS, IRP_CALL_SITE_RETURNED, "call site returned")       \
11636       SWITCH_PK_INV(CLASS, IRP_CALL_SITE_ARGUMENT, "call site argument")       \
11637       SWITCH_PK_INV(CLASS, IRP_CALL_SITE, "call site")                         \
11638       SWITCH_PK_CREATE(CLASS, IRP, IRP_FUNCTION, Function)                     \
11639     }                                                                          \
11640     return *AA;                                                                \
11641   }
11642 
11643 #define CREATE_NON_RET_ABSTRACT_ATTRIBUTE_FOR_POSITION(CLASS)                  \
11644   CLASS &CLASS::createForPosition(const IRPosition &IRP, Attributor &A) {      \
11645     CLASS *AA = nullptr;                                                       \
11646     switch (IRP.getPositionKind()) {                                           \
11647       SWITCH_PK_INV(CLASS, IRP_INVALID, "invalid")                             \
11648       SWITCH_PK_INV(CLASS, IRP_RETURNED, "returned")                           \
11649       SWITCH_PK_CREATE(CLASS, IRP, IRP_FUNCTION, Function)                     \
11650       SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE, CallSite)                    \
11651       SWITCH_PK_CREATE(CLASS, IRP, IRP_FLOAT, Floating)                        \
11652       SWITCH_PK_CREATE(CLASS, IRP, IRP_ARGUMENT, Argument)                     \
11653       SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE_RETURNED, CallSiteReturned)   \
11654       SWITCH_PK_CREATE(CLASS, IRP, IRP_CALL_SITE_ARGUMENT, CallSiteArgument)   \
11655     }                                                                          \
11656     return *AA;                                                                \
11657   }
11658 
11659 CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoUnwind)
11660 CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoSync)
11661 CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoRecurse)
11662 CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAWillReturn)
11663 CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoReturn)
11664 CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAReturnedValues)
11665 CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAMemoryLocation)
11666 CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AACallEdges)
11667 CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAAssumptionInfo)
11668 
11669 CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANonNull)
11670 CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoAlias)
11671 CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAPrivatizablePtr)
11672 CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AADereferenceable)
11673 CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAAlign)
11674 CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAInstanceInfo)
11675 CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoCapture)
11676 CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAValueConstantRange)
11677 CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAPotentialConstantValues)
11678 CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAPotentialValues)
11679 CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoUndef)
11680 CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAPointerInfo)
11681 
11682 CREATE_ALL_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAValueSimplify)
11683 CREATE_ALL_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAIsDead)
11684 CREATE_ALL_ABSTRACT_ATTRIBUTE_FOR_POSITION(AANoFree)
11685 CREATE_ALL_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAUnderlyingObjects)
11686 
11687 CREATE_FUNCTION_ONLY_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAHeapToStack)
11688 CREATE_FUNCTION_ONLY_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAUndefinedBehavior)
11689 CREATE_FUNCTION_ONLY_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAIntraFnReachability)
11690 CREATE_FUNCTION_ONLY_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAInterFnReachability)
11691 
11692 CREATE_NON_RET_ABSTRACT_ATTRIBUTE_FOR_POSITION(AAMemoryBehavior)
11693 
11694 #undef CREATE_FUNCTION_ONLY_ABSTRACT_ATTRIBUTE_FOR_POSITION
11695 #undef CREATE_FUNCTION_ABSTRACT_ATTRIBUTE_FOR_POSITION
11696 #undef CREATE_NON_RET_ABSTRACT_ATTRIBUTE_FOR_POSITION
11697 #undef CREATE_VALUE_ABSTRACT_ATTRIBUTE_FOR_POSITION
11698 #undef CREATE_ALL_ABSTRACT_ATTRIBUTE_FOR_POSITION
11699 #undef SWITCH_PK_CREATE
11700 #undef SWITCH_PK_INV
11701