1 //===- NewGVN.cpp - Global Value Numbering Pass ---------------------------===//
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 /// \file
10 /// This file implements the new LLVM's Global Value Numbering pass.
11 /// GVN partitions values computed by a function into congruence classes.
12 /// Values ending up in the same congruence class are guaranteed to be the same
13 /// for every execution of the program. In that respect, congruency is a
14 /// compile-time approximation of equivalence of values at runtime.
15 /// The algorithm implemented here uses a sparse formulation and it's based
16 /// on the ideas described in the paper:
17 /// "A Sparse Algorithm for Predicated Global Value Numbering" from
18 /// Karthik Gargi.
19 ///
20 /// A brief overview of the algorithm: The algorithm is essentially the same as
21 /// the standard RPO value numbering algorithm (a good reference is the paper
22 /// "SCC based value numbering" by L. Taylor Simpson) with one major difference:
23 /// The RPO algorithm proceeds, on every iteration, to process every reachable
24 /// block and every instruction in that block.  This is because the standard RPO
25 /// algorithm does not track what things have the same value number, it only
26 /// tracks what the value number of a given operation is (the mapping is
27 /// operation -> value number).  Thus, when a value number of an operation
28 /// changes, it must reprocess everything to ensure all uses of a value number
29 /// get updated properly.  In constrast, the sparse algorithm we use *also*
30 /// tracks what operations have a given value number (IE it also tracks the
31 /// reverse mapping from value number -> operations with that value number), so
32 /// that it only needs to reprocess the instructions that are affected when
33 /// something's value number changes.  The vast majority of complexity and code
34 /// in this file is devoted to tracking what value numbers could change for what
35 /// instructions when various things happen.  The rest of the algorithm is
36 /// devoted to performing symbolic evaluation, forward propagation, and
37 /// simplification of operations based on the value numbers deduced so far
38 ///
39 /// In order to make the GVN mostly-complete, we use a technique derived from
40 /// "Detection of Redundant Expressions: A Complete and Polynomial-time
41 /// Algorithm in SSA" by R.R. Pai.  The source of incompleteness in most SSA
42 /// based GVN algorithms is related to their inability to detect equivalence
43 /// between phi of ops (IE phi(a+b, c+d)) and op of phis (phi(a,c) + phi(b, d)).
44 /// We resolve this issue by generating the equivalent "phi of ops" form for
45 /// each op of phis we see, in a way that only takes polynomial time to resolve.
46 ///
47 /// We also do not perform elimination by using any published algorithm.  All
48 /// published algorithms are O(Instructions). Instead, we use a technique that
49 /// is O(number of operations with the same value number), enabling us to skip
50 /// trying to eliminate things that have unique value numbers.
51 //
52 //===----------------------------------------------------------------------===//
53 
54 #include "llvm/Transforms/Scalar/NewGVN.h"
55 #include "llvm/ADT/ArrayRef.h"
56 #include "llvm/ADT/BitVector.h"
57 #include "llvm/ADT/DenseMap.h"
58 #include "llvm/ADT/DenseMapInfo.h"
59 #include "llvm/ADT/DenseSet.h"
60 #include "llvm/ADT/DepthFirstIterator.h"
61 #include "llvm/ADT/GraphTraits.h"
62 #include "llvm/ADT/Hashing.h"
63 #include "llvm/ADT/PointerIntPair.h"
64 #include "llvm/ADT/PostOrderIterator.h"
65 #include "llvm/ADT/SmallPtrSet.h"
66 #include "llvm/ADT/SmallVector.h"
67 #include "llvm/ADT/SparseBitVector.h"
68 #include "llvm/ADT/Statistic.h"
69 #include "llvm/ADT/iterator_range.h"
70 #include "llvm/Analysis/AliasAnalysis.h"
71 #include "llvm/Analysis/AssumptionCache.h"
72 #include "llvm/Analysis/CFGPrinter.h"
73 #include "llvm/Analysis/ConstantFolding.h"
74 #include "llvm/Analysis/GlobalsModRef.h"
75 #include "llvm/Analysis/InstructionSimplify.h"
76 #include "llvm/Analysis/MemoryBuiltins.h"
77 #include "llvm/Analysis/MemorySSA.h"
78 #include "llvm/Analysis/TargetLibraryInfo.h"
79 #include "llvm/IR/Argument.h"
80 #include "llvm/IR/BasicBlock.h"
81 #include "llvm/IR/Constant.h"
82 #include "llvm/IR/Constants.h"
83 #include "llvm/IR/Dominators.h"
84 #include "llvm/IR/Function.h"
85 #include "llvm/IR/InstrTypes.h"
86 #include "llvm/IR/Instruction.h"
87 #include "llvm/IR/Instructions.h"
88 #include "llvm/IR/IntrinsicInst.h"
89 #include "llvm/IR/Intrinsics.h"
90 #include "llvm/IR/LLVMContext.h"
91 #include "llvm/IR/PatternMatch.h"
92 #include "llvm/IR/Type.h"
93 #include "llvm/IR/Use.h"
94 #include "llvm/IR/User.h"
95 #include "llvm/IR/Value.h"
96 #include "llvm/InitializePasses.h"
97 #include "llvm/Pass.h"
98 #include "llvm/Support/Allocator.h"
99 #include "llvm/Support/ArrayRecycler.h"
100 #include "llvm/Support/Casting.h"
101 #include "llvm/Support/CommandLine.h"
102 #include "llvm/Support/Debug.h"
103 #include "llvm/Support/DebugCounter.h"
104 #include "llvm/Support/ErrorHandling.h"
105 #include "llvm/Support/PointerLikeTypeTraits.h"
106 #include "llvm/Support/raw_ostream.h"
107 #include "llvm/Transforms/Scalar.h"
108 #include "llvm/Transforms/Scalar/GVNExpression.h"
109 #include "llvm/Transforms/Utils/AssumeBundleBuilder.h"
110 #include "llvm/Transforms/Utils/Local.h"
111 #include "llvm/Transforms/Utils/PredicateInfo.h"
112 #include "llvm/Transforms/Utils/VNCoercion.h"
113 #include <algorithm>
114 #include <cassert>
115 #include <cstdint>
116 #include <iterator>
117 #include <map>
118 #include <memory>
119 #include <set>
120 #include <string>
121 #include <tuple>
122 #include <utility>
123 #include <vector>
124 
125 using namespace llvm;
126 using namespace llvm::GVNExpression;
127 using namespace llvm::VNCoercion;
128 using namespace llvm::PatternMatch;
129 
130 #define DEBUG_TYPE "newgvn"
131 
132 STATISTIC(NumGVNInstrDeleted, "Number of instructions deleted");
133 STATISTIC(NumGVNBlocksDeleted, "Number of blocks deleted");
134 STATISTIC(NumGVNOpsSimplified, "Number of Expressions simplified");
135 STATISTIC(NumGVNPhisAllSame, "Number of PHIs whos arguments are all the same");
136 STATISTIC(NumGVNMaxIterations,
137           "Maximum Number of iterations it took to converge GVN");
138 STATISTIC(NumGVNLeaderChanges, "Number of leader changes");
139 STATISTIC(NumGVNSortedLeaderChanges, "Number of sorted leader changes");
140 STATISTIC(NumGVNAvoidedSortedLeaderChanges,
141           "Number of avoided sorted leader changes");
142 STATISTIC(NumGVNDeadStores, "Number of redundant/dead stores eliminated");
143 STATISTIC(NumGVNPHIOfOpsCreated, "Number of PHI of ops created");
144 STATISTIC(NumGVNPHIOfOpsEliminations,
145           "Number of things eliminated using PHI of ops");
146 DEBUG_COUNTER(VNCounter, "newgvn-vn",
147               "Controls which instructions are value numbered");
148 DEBUG_COUNTER(PHIOfOpsCounter, "newgvn-phi",
149               "Controls which instructions we create phi of ops for");
150 // Currently store defining access refinement is too slow due to basicaa being
151 // egregiously slow.  This flag lets us keep it working while we work on this
152 // issue.
153 static cl::opt<bool> EnableStoreRefinement("enable-store-refinement",
154                                            cl::init(false), cl::Hidden);
155 
156 /// Currently, the generation "phi of ops" can result in correctness issues.
157 static cl::opt<bool> EnablePhiOfOps("enable-phi-of-ops", cl::init(true),
158                                     cl::Hidden);
159 
160 //===----------------------------------------------------------------------===//
161 //                                GVN Pass
162 //===----------------------------------------------------------------------===//
163 
164 // Anchor methods.
165 namespace llvm {
166 namespace GVNExpression {
167 
168 Expression::~Expression() = default;
169 BasicExpression::~BasicExpression() = default;
170 CallExpression::~CallExpression() = default;
171 LoadExpression::~LoadExpression() = default;
172 StoreExpression::~StoreExpression() = default;
173 AggregateValueExpression::~AggregateValueExpression() = default;
174 PHIExpression::~PHIExpression() = default;
175 
176 } // end namespace GVNExpression
177 } // end namespace llvm
178 
179 namespace {
180 
181 // Tarjan's SCC finding algorithm with Nuutila's improvements
182 // SCCIterator is actually fairly complex for the simple thing we want.
183 // It also wants to hand us SCC's that are unrelated to the phi node we ask
184 // about, and have us process them there or risk redoing work.
185 // Graph traits over a filter iterator also doesn't work that well here.
186 // This SCC finder is specialized to walk use-def chains, and only follows
187 // instructions,
188 // not generic values (arguments, etc).
189 struct TarjanSCC {
190   TarjanSCC() : Components(1) {}
191 
192   void Start(const Instruction *Start) {
193     if (Root.lookup(Start) == 0)
194       FindSCC(Start);
195   }
196 
197   const SmallPtrSetImpl<const Value *> &getComponentFor(const Value *V) const {
198     unsigned ComponentID = ValueToComponent.lookup(V);
199 
200     assert(ComponentID > 0 &&
201            "Asking for a component for a value we never processed");
202     return Components[ComponentID];
203   }
204 
205 private:
206   void FindSCC(const Instruction *I) {
207     Root[I] = ++DFSNum;
208     // Store the DFS Number we had before it possibly gets incremented.
209     unsigned int OurDFS = DFSNum;
210     for (auto &Op : I->operands()) {
211       if (auto *InstOp = dyn_cast<Instruction>(Op)) {
212         if (Root.lookup(Op) == 0)
213           FindSCC(InstOp);
214         if (!InComponent.count(Op))
215           Root[I] = std::min(Root.lookup(I), Root.lookup(Op));
216       }
217     }
218     // See if we really were the root of a component, by seeing if we still have
219     // our DFSNumber.  If we do, we are the root of the component, and we have
220     // completed a component. If we do not, we are not the root of a component,
221     // and belong on the component stack.
222     if (Root.lookup(I) == OurDFS) {
223       unsigned ComponentID = Components.size();
224       Components.resize(Components.size() + 1);
225       auto &Component = Components.back();
226       Component.insert(I);
227       LLVM_DEBUG(dbgs() << "Component root is " << *I << "\n");
228       InComponent.insert(I);
229       ValueToComponent[I] = ComponentID;
230       // Pop a component off the stack and label it.
231       while (!Stack.empty() && Root.lookup(Stack.back()) >= OurDFS) {
232         auto *Member = Stack.back();
233         LLVM_DEBUG(dbgs() << "Component member is " << *Member << "\n");
234         Component.insert(Member);
235         InComponent.insert(Member);
236         ValueToComponent[Member] = ComponentID;
237         Stack.pop_back();
238       }
239     } else {
240       // Part of a component, push to stack
241       Stack.push_back(I);
242     }
243   }
244 
245   unsigned int DFSNum = 1;
246   SmallPtrSet<const Value *, 8> InComponent;
247   DenseMap<const Value *, unsigned int> Root;
248   SmallVector<const Value *, 8> Stack;
249 
250   // Store the components as vector of ptr sets, because we need the topo order
251   // of SCC's, but not individual member order
252   SmallVector<SmallPtrSet<const Value *, 8>, 8> Components;
253 
254   DenseMap<const Value *, unsigned> ValueToComponent;
255 };
256 
257 // Congruence classes represent the set of expressions/instructions
258 // that are all the same *during some scope in the function*.
259 // That is, because of the way we perform equality propagation, and
260 // because of memory value numbering, it is not correct to assume
261 // you can willy-nilly replace any member with any other at any
262 // point in the function.
263 //
264 // For any Value in the Member set, it is valid to replace any dominated member
265 // with that Value.
266 //
267 // Every congruence class has a leader, and the leader is used to symbolize
268 // instructions in a canonical way (IE every operand of an instruction that is a
269 // member of the same congruence class will always be replaced with leader
270 // during symbolization).  To simplify symbolization, we keep the leader as a
271 // constant if class can be proved to be a constant value.  Otherwise, the
272 // leader is the member of the value set with the smallest DFS number.  Each
273 // congruence class also has a defining expression, though the expression may be
274 // null.  If it exists, it can be used for forward propagation and reassociation
275 // of values.
276 
277 // For memory, we also track a representative MemoryAccess, and a set of memory
278 // members for MemoryPhis (which have no real instructions). Note that for
279 // memory, it seems tempting to try to split the memory members into a
280 // MemoryCongruenceClass or something.  Unfortunately, this does not work
281 // easily.  The value numbering of a given memory expression depends on the
282 // leader of the memory congruence class, and the leader of memory congruence
283 // class depends on the value numbering of a given memory expression.  This
284 // leads to wasted propagation, and in some cases, missed optimization.  For
285 // example: If we had value numbered two stores together before, but now do not,
286 // we move them to a new value congruence class.  This in turn will move at one
287 // of the memorydefs to a new memory congruence class.  Which in turn, affects
288 // the value numbering of the stores we just value numbered (because the memory
289 // congruence class is part of the value number).  So while theoretically
290 // possible to split them up, it turns out to be *incredibly* complicated to get
291 // it to work right, because of the interdependency.  While structurally
292 // slightly messier, it is algorithmically much simpler and faster to do what we
293 // do here, and track them both at once in the same class.
294 // Note: The default iterators for this class iterate over values
295 class CongruenceClass {
296 public:
297   using MemberType = Value;
298   using MemberSet = SmallPtrSet<MemberType *, 4>;
299   using MemoryMemberType = MemoryPhi;
300   using MemoryMemberSet = SmallPtrSet<const MemoryMemberType *, 2>;
301 
302   explicit CongruenceClass(unsigned ID) : ID(ID) {}
303   CongruenceClass(unsigned ID, Value *Leader, const Expression *E)
304       : ID(ID), RepLeader(Leader), DefiningExpr(E) {}
305 
306   unsigned getID() const { return ID; }
307 
308   // True if this class has no members left.  This is mainly used for assertion
309   // purposes, and for skipping empty classes.
310   bool isDead() const {
311     // If it's both dead from a value perspective, and dead from a memory
312     // perspective, it's really dead.
313     return empty() && memory_empty();
314   }
315 
316   // Leader functions
317   Value *getLeader() const { return RepLeader; }
318   void setLeader(Value *Leader) { RepLeader = Leader; }
319   const std::pair<Value *, unsigned int> &getNextLeader() const {
320     return NextLeader;
321   }
322   void resetNextLeader() { NextLeader = {nullptr, ~0}; }
323   void addPossibleNextLeader(std::pair<Value *, unsigned int> LeaderPair) {
324     if (LeaderPair.second < NextLeader.second)
325       NextLeader = LeaderPair;
326   }
327 
328   Value *getStoredValue() const { return RepStoredValue; }
329   void setStoredValue(Value *Leader) { RepStoredValue = Leader; }
330   const MemoryAccess *getMemoryLeader() const { return RepMemoryAccess; }
331   void setMemoryLeader(const MemoryAccess *Leader) { RepMemoryAccess = Leader; }
332 
333   // Forward propagation info
334   const Expression *getDefiningExpr() const { return DefiningExpr; }
335 
336   // Value member set
337   bool empty() const { return Members.empty(); }
338   unsigned size() const { return Members.size(); }
339   MemberSet::const_iterator begin() const { return Members.begin(); }
340   MemberSet::const_iterator end() const { return Members.end(); }
341   void insert(MemberType *M) { Members.insert(M); }
342   void erase(MemberType *M) { Members.erase(M); }
343   void swap(MemberSet &Other) { Members.swap(Other); }
344 
345   // Memory member set
346   bool memory_empty() const { return MemoryMembers.empty(); }
347   unsigned memory_size() const { return MemoryMembers.size(); }
348   MemoryMemberSet::const_iterator memory_begin() const {
349     return MemoryMembers.begin();
350   }
351   MemoryMemberSet::const_iterator memory_end() const {
352     return MemoryMembers.end();
353   }
354   iterator_range<MemoryMemberSet::const_iterator> memory() const {
355     return make_range(memory_begin(), memory_end());
356   }
357 
358   void memory_insert(const MemoryMemberType *M) { MemoryMembers.insert(M); }
359   void memory_erase(const MemoryMemberType *M) { MemoryMembers.erase(M); }
360 
361   // Store count
362   unsigned getStoreCount() const { return StoreCount; }
363   void incStoreCount() { ++StoreCount; }
364   void decStoreCount() {
365     assert(StoreCount != 0 && "Store count went negative");
366     --StoreCount;
367   }
368 
369   // True if this class has no memory members.
370   bool definesNoMemory() const { return StoreCount == 0 && memory_empty(); }
371 
372   // Return true if two congruence classes are equivalent to each other. This
373   // means that every field but the ID number and the dead field are equivalent.
374   bool isEquivalentTo(const CongruenceClass *Other) const {
375     if (!Other)
376       return false;
377     if (this == Other)
378       return true;
379 
380     if (std::tie(StoreCount, RepLeader, RepStoredValue, RepMemoryAccess) !=
381         std::tie(Other->StoreCount, Other->RepLeader, Other->RepStoredValue,
382                  Other->RepMemoryAccess))
383       return false;
384     if (DefiningExpr != Other->DefiningExpr)
385       if (!DefiningExpr || !Other->DefiningExpr ||
386           *DefiningExpr != *Other->DefiningExpr)
387         return false;
388 
389     if (Members.size() != Other->Members.size())
390       return false;
391 
392     return all_of(Members,
393                   [&](const Value *V) { return Other->Members.count(V); });
394   }
395 
396 private:
397   unsigned ID;
398 
399   // Representative leader.
400   Value *RepLeader = nullptr;
401 
402   // The most dominating leader after our current leader, because the member set
403   // is not sorted and is expensive to keep sorted all the time.
404   std::pair<Value *, unsigned int> NextLeader = {nullptr, ~0U};
405 
406   // If this is represented by a store, the value of the store.
407   Value *RepStoredValue = nullptr;
408 
409   // If this class contains MemoryDefs or MemoryPhis, this is the leading memory
410   // access.
411   const MemoryAccess *RepMemoryAccess = nullptr;
412 
413   // Defining Expression.
414   const Expression *DefiningExpr = nullptr;
415 
416   // Actual members of this class.
417   MemberSet Members;
418 
419   // This is the set of MemoryPhis that exist in the class. MemoryDefs and
420   // MemoryUses have real instructions representing them, so we only need to
421   // track MemoryPhis here.
422   MemoryMemberSet MemoryMembers;
423 
424   // Number of stores in this congruence class.
425   // This is used so we can detect store equivalence changes properly.
426   int StoreCount = 0;
427 };
428 
429 } // end anonymous namespace
430 
431 namespace llvm {
432 
433 struct ExactEqualsExpression {
434   const Expression &E;
435 
436   explicit ExactEqualsExpression(const Expression &E) : E(E) {}
437 
438   hash_code getComputedHash() const { return E.getComputedHash(); }
439 
440   bool operator==(const Expression &Other) const {
441     return E.exactlyEquals(Other);
442   }
443 };
444 
445 template <> struct DenseMapInfo<const Expression *> {
446   static const Expression *getEmptyKey() {
447     auto Val = static_cast<uintptr_t>(-1);
448     Val <<= PointerLikeTypeTraits<const Expression *>::NumLowBitsAvailable;
449     return reinterpret_cast<const Expression *>(Val);
450   }
451 
452   static const Expression *getTombstoneKey() {
453     auto Val = static_cast<uintptr_t>(~1U);
454     Val <<= PointerLikeTypeTraits<const Expression *>::NumLowBitsAvailable;
455     return reinterpret_cast<const Expression *>(Val);
456   }
457 
458   static unsigned getHashValue(const Expression *E) {
459     return E->getComputedHash();
460   }
461 
462   static unsigned getHashValue(const ExactEqualsExpression &E) {
463     return E.getComputedHash();
464   }
465 
466   static bool isEqual(const ExactEqualsExpression &LHS, const Expression *RHS) {
467     if (RHS == getTombstoneKey() || RHS == getEmptyKey())
468       return false;
469     return LHS == *RHS;
470   }
471 
472   static bool isEqual(const Expression *LHS, const Expression *RHS) {
473     if (LHS == RHS)
474       return true;
475     if (LHS == getTombstoneKey() || RHS == getTombstoneKey() ||
476         LHS == getEmptyKey() || RHS == getEmptyKey())
477       return false;
478     // Compare hashes before equality.  This is *not* what the hashtable does,
479     // since it is computing it modulo the number of buckets, whereas we are
480     // using the full hash keyspace.  Since the hashes are precomputed, this
481     // check is *much* faster than equality.
482     if (LHS->getComputedHash() != RHS->getComputedHash())
483       return false;
484     return *LHS == *RHS;
485   }
486 };
487 
488 } // end namespace llvm
489 
490 namespace {
491 
492 class NewGVN {
493   Function &F;
494   DominatorTree *DT = nullptr;
495   const TargetLibraryInfo *TLI = nullptr;
496   AliasAnalysis *AA = nullptr;
497   MemorySSA *MSSA = nullptr;
498   MemorySSAWalker *MSSAWalker = nullptr;
499   AssumptionCache *AC = nullptr;
500   const DataLayout &DL;
501   std::unique_ptr<PredicateInfo> PredInfo;
502 
503   // These are the only two things the create* functions should have
504   // side-effects on due to allocating memory.
505   mutable BumpPtrAllocator ExpressionAllocator;
506   mutable ArrayRecycler<Value *> ArgRecycler;
507   mutable TarjanSCC SCCFinder;
508   const SimplifyQuery SQ;
509 
510   // Number of function arguments, used by ranking
511   unsigned int NumFuncArgs = 0;
512 
513   // RPOOrdering of basic blocks
514   DenseMap<const DomTreeNode *, unsigned> RPOOrdering;
515 
516   // Congruence class info.
517 
518   // This class is called INITIAL in the paper. It is the class everything
519   // startsout in, and represents any value. Being an optimistic analysis,
520   // anything in the TOP class has the value TOP, which is indeterminate and
521   // equivalent to everything.
522   CongruenceClass *TOPClass = nullptr;
523   std::vector<CongruenceClass *> CongruenceClasses;
524   unsigned NextCongruenceNum = 0;
525 
526   // Value Mappings.
527   DenseMap<Value *, CongruenceClass *> ValueToClass;
528   DenseMap<Value *, const Expression *> ValueToExpression;
529 
530   // Value PHI handling, used to make equivalence between phi(op, op) and
531   // op(phi, phi).
532   // These mappings just store various data that would normally be part of the
533   // IR.
534   SmallPtrSet<const Instruction *, 8> PHINodeUses;
535 
536   DenseMap<const Value *, bool> OpSafeForPHIOfOps;
537 
538   // Map a temporary instruction we created to a parent block.
539   DenseMap<const Value *, BasicBlock *> TempToBlock;
540 
541   // Map between the already in-program instructions and the temporary phis we
542   // created that they are known equivalent to.
543   DenseMap<const Value *, PHINode *> RealToTemp;
544 
545   // In order to know when we should re-process instructions that have
546   // phi-of-ops, we track the set of expressions that they needed as
547   // leaders. When we discover new leaders for those expressions, we process the
548   // associated phi-of-op instructions again in case they have changed.  The
549   // other way they may change is if they had leaders, and those leaders
550   // disappear.  However, at the point they have leaders, there are uses of the
551   // relevant operands in the created phi node, and so they will get reprocessed
552   // through the normal user marking we perform.
553   mutable DenseMap<const Value *, SmallPtrSet<Value *, 2>> AdditionalUsers;
554   DenseMap<const Expression *, SmallPtrSet<Instruction *, 2>>
555       ExpressionToPhiOfOps;
556 
557   // Map from temporary operation to MemoryAccess.
558   DenseMap<const Instruction *, MemoryUseOrDef *> TempToMemory;
559 
560   // Set of all temporary instructions we created.
561   // Note: This will include instructions that were just created during value
562   // numbering.  The way to test if something is using them is to check
563   // RealToTemp.
564   DenseSet<Instruction *> AllTempInstructions;
565 
566   // This is the set of instructions to revisit on a reachability change.  At
567   // the end of the main iteration loop it will contain at least all the phi of
568   // ops instructions that will be changed to phis, as well as regular phis.
569   // During the iteration loop, it may contain other things, such as phi of ops
570   // instructions that used edge reachability to reach a result, and so need to
571   // be revisited when the edge changes, independent of whether the phi they
572   // depended on changes.
573   DenseMap<BasicBlock *, SparseBitVector<>> RevisitOnReachabilityChange;
574 
575   // Mapping from predicate info we used to the instructions we used it with.
576   // In order to correctly ensure propagation, we must keep track of what
577   // comparisons we used, so that when the values of the comparisons change, we
578   // propagate the information to the places we used the comparison.
579   mutable DenseMap<const Value *, SmallPtrSet<Instruction *, 2>>
580       PredicateToUsers;
581 
582   // the same reasoning as PredicateToUsers.  When we skip MemoryAccesses for
583   // stores, we no longer can rely solely on the def-use chains of MemorySSA.
584   mutable DenseMap<const MemoryAccess *, SmallPtrSet<MemoryAccess *, 2>>
585       MemoryToUsers;
586 
587   // A table storing which memorydefs/phis represent a memory state provably
588   // equivalent to another memory state.
589   // We could use the congruence class machinery, but the MemoryAccess's are
590   // abstract memory states, so they can only ever be equivalent to each other,
591   // and not to constants, etc.
592   DenseMap<const MemoryAccess *, CongruenceClass *> MemoryAccessToClass;
593 
594   // We could, if we wanted, build MemoryPhiExpressions and
595   // MemoryVariableExpressions, etc, and value number them the same way we value
596   // number phi expressions.  For the moment, this seems like overkill.  They
597   // can only exist in one of three states: they can be TOP (equal to
598   // everything), Equivalent to something else, or unique.  Because we do not
599   // create expressions for them, we need to simulate leader change not just
600   // when they change class, but when they change state.  Note: We can do the
601   // same thing for phis, and avoid having phi expressions if we wanted, We
602   // should eventually unify in one direction or the other, so this is a little
603   // bit of an experiment in which turns out easier to maintain.
604   enum MemoryPhiState { MPS_Invalid, MPS_TOP, MPS_Equivalent, MPS_Unique };
605   DenseMap<const MemoryPhi *, MemoryPhiState> MemoryPhiState;
606 
607   enum InstCycleState { ICS_Unknown, ICS_CycleFree, ICS_Cycle };
608   mutable DenseMap<const Instruction *, InstCycleState> InstCycleState;
609 
610   // Expression to class mapping.
611   using ExpressionClassMap = DenseMap<const Expression *, CongruenceClass *>;
612   ExpressionClassMap ExpressionToClass;
613 
614   // We have a single expression that represents currently DeadExpressions.
615   // For dead expressions we can prove will stay dead, we mark them with
616   // DFS number zero.  However, it's possible in the case of phi nodes
617   // for us to assume/prove all arguments are dead during fixpointing.
618   // We use DeadExpression for that case.
619   DeadExpression *SingletonDeadExpression = nullptr;
620 
621   // Which values have changed as a result of leader changes.
622   SmallPtrSet<Value *, 8> LeaderChanges;
623 
624   // Reachability info.
625   using BlockEdge = BasicBlockEdge;
626   DenseSet<BlockEdge> ReachableEdges;
627   SmallPtrSet<const BasicBlock *, 8> ReachableBlocks;
628 
629   // This is a bitvector because, on larger functions, we may have
630   // thousands of touched instructions at once (entire blocks,
631   // instructions with hundreds of uses, etc).  Even with optimization
632   // for when we mark whole blocks as touched, when this was a
633   // SmallPtrSet or DenseSet, for some functions, we spent >20% of all
634   // the time in GVN just managing this list.  The bitvector, on the
635   // other hand, efficiently supports test/set/clear of both
636   // individual and ranges, as well as "find next element" This
637   // enables us to use it as a worklist with essentially 0 cost.
638   BitVector TouchedInstructions;
639 
640   DenseMap<const BasicBlock *, std::pair<unsigned, unsigned>> BlockInstRange;
641 
642 #ifndef NDEBUG
643   // Debugging for how many times each block and instruction got processed.
644   DenseMap<const Value *, unsigned> ProcessedCount;
645 #endif
646 
647   // DFS info.
648   // This contains a mapping from Instructions to DFS numbers.
649   // The numbering starts at 1. An instruction with DFS number zero
650   // means that the instruction is dead.
651   DenseMap<const Value *, unsigned> InstrDFS;
652 
653   // This contains the mapping DFS numbers to instructions.
654   SmallVector<Value *, 32> DFSToInstr;
655 
656   // Deletion info.
657   SmallPtrSet<Instruction *, 8> InstructionsToErase;
658 
659 public:
660   NewGVN(Function &F, DominatorTree *DT, AssumptionCache *AC,
661          TargetLibraryInfo *TLI, AliasAnalysis *AA, MemorySSA *MSSA,
662          const DataLayout &DL)
663       : F(F), DT(DT), TLI(TLI), AA(AA), MSSA(MSSA), AC(AC), DL(DL),
664         PredInfo(std::make_unique<PredicateInfo>(F, *DT, *AC)),
665         SQ(DL, TLI, DT, AC, /*CtxI=*/nullptr, /*UseInstrInfo=*/false,
666            /*CanUseUndef=*/false) {}
667 
668   bool runGVN();
669 
670 private:
671   // Expression handling.
672   const Expression *createExpression(Instruction *) const;
673   const Expression *createBinaryExpression(unsigned, Type *, Value *, Value *,
674                                            Instruction *) const;
675 
676   // Our canonical form for phi arguments is a pair of incoming value, incoming
677   // basic block.
678   using ValPair = std::pair<Value *, BasicBlock *>;
679 
680   PHIExpression *createPHIExpression(ArrayRef<ValPair>, const Instruction *,
681                                      BasicBlock *, bool &HasBackEdge,
682                                      bool &OriginalOpsConstant) const;
683   const DeadExpression *createDeadExpression() const;
684   const VariableExpression *createVariableExpression(Value *) const;
685   const ConstantExpression *createConstantExpression(Constant *) const;
686   const Expression *createVariableOrConstant(Value *V) const;
687   const UnknownExpression *createUnknownExpression(Instruction *) const;
688   const StoreExpression *createStoreExpression(StoreInst *,
689                                                const MemoryAccess *) const;
690   LoadExpression *createLoadExpression(Type *, Value *, LoadInst *,
691                                        const MemoryAccess *) const;
692   const CallExpression *createCallExpression(CallInst *,
693                                              const MemoryAccess *) const;
694   const AggregateValueExpression *
695   createAggregateValueExpression(Instruction *) const;
696   bool setBasicExpressionInfo(Instruction *, BasicExpression *) const;
697 
698   // Congruence class handling.
699   CongruenceClass *createCongruenceClass(Value *Leader, const Expression *E) {
700     auto *result = new CongruenceClass(NextCongruenceNum++, Leader, E);
701     CongruenceClasses.emplace_back(result);
702     return result;
703   }
704 
705   CongruenceClass *createMemoryClass(MemoryAccess *MA) {
706     auto *CC = createCongruenceClass(nullptr, nullptr);
707     CC->setMemoryLeader(MA);
708     return CC;
709   }
710 
711   CongruenceClass *ensureLeaderOfMemoryClass(MemoryAccess *MA) {
712     auto *CC = getMemoryClass(MA);
713     if (CC->getMemoryLeader() != MA)
714       CC = createMemoryClass(MA);
715     return CC;
716   }
717 
718   CongruenceClass *createSingletonCongruenceClass(Value *Member) {
719     CongruenceClass *CClass = createCongruenceClass(Member, nullptr);
720     CClass->insert(Member);
721     ValueToClass[Member] = CClass;
722     return CClass;
723   }
724 
725   void initializeCongruenceClasses(Function &F);
726   const Expression *makePossiblePHIOfOps(Instruction *,
727                                          SmallPtrSetImpl<Value *> &);
728   Value *findLeaderForInst(Instruction *ValueOp,
729                            SmallPtrSetImpl<Value *> &Visited,
730                            MemoryAccess *MemAccess, Instruction *OrigInst,
731                            BasicBlock *PredBB);
732   bool OpIsSafeForPHIOfOpsHelper(Value *V, const BasicBlock *PHIBlock,
733                                  SmallPtrSetImpl<const Value *> &Visited,
734                                  SmallVectorImpl<Instruction *> &Worklist);
735   bool OpIsSafeForPHIOfOps(Value *Op, const BasicBlock *PHIBlock,
736                            SmallPtrSetImpl<const Value *> &);
737   void addPhiOfOps(PHINode *Op, BasicBlock *BB, Instruction *ExistingValue);
738   void removePhiOfOps(Instruction *I, PHINode *PHITemp);
739 
740   // Value number an Instruction or MemoryPhi.
741   void valueNumberMemoryPhi(MemoryPhi *);
742   void valueNumberInstruction(Instruction *);
743 
744   // Symbolic evaluation.
745   const Expression *checkSimplificationResults(Expression *, Instruction *,
746                                                Value *) const;
747   const Expression *performSymbolicEvaluation(Value *,
748                                               SmallPtrSetImpl<Value *> &) const;
749   const Expression *performSymbolicLoadCoercion(Type *, Value *, LoadInst *,
750                                                 Instruction *,
751                                                 MemoryAccess *) const;
752   const Expression *performSymbolicLoadEvaluation(Instruction *) const;
753   const Expression *performSymbolicStoreEvaluation(Instruction *) const;
754   const Expression *performSymbolicCallEvaluation(Instruction *) const;
755   void sortPHIOps(MutableArrayRef<ValPair> Ops) const;
756   const Expression *performSymbolicPHIEvaluation(ArrayRef<ValPair>,
757                                                  Instruction *I,
758                                                  BasicBlock *PHIBlock) const;
759   const Expression *performSymbolicAggrValueEvaluation(Instruction *) const;
760   const Expression *performSymbolicCmpEvaluation(Instruction *) const;
761   const Expression *performSymbolicPredicateInfoEvaluation(Instruction *) const;
762 
763   // Congruence finding.
764   bool someEquivalentDominates(const Instruction *, const Instruction *) const;
765   Value *lookupOperandLeader(Value *) const;
766   CongruenceClass *getClassForExpression(const Expression *E) const;
767   void performCongruenceFinding(Instruction *, const Expression *);
768   void moveValueToNewCongruenceClass(Instruction *, const Expression *,
769                                      CongruenceClass *, CongruenceClass *);
770   void moveMemoryToNewCongruenceClass(Instruction *, MemoryAccess *,
771                                       CongruenceClass *, CongruenceClass *);
772   Value *getNextValueLeader(CongruenceClass *) const;
773   const MemoryAccess *getNextMemoryLeader(CongruenceClass *) const;
774   bool setMemoryClass(const MemoryAccess *From, CongruenceClass *To);
775   CongruenceClass *getMemoryClass(const MemoryAccess *MA) const;
776   const MemoryAccess *lookupMemoryLeader(const MemoryAccess *) const;
777   bool isMemoryAccessTOP(const MemoryAccess *) const;
778 
779   // Ranking
780   unsigned int getRank(const Value *) const;
781   bool shouldSwapOperands(const Value *, const Value *) const;
782 
783   // Reachability handling.
784   void updateReachableEdge(BasicBlock *, BasicBlock *);
785   void processOutgoingEdges(Instruction *, BasicBlock *);
786   Value *findConditionEquivalence(Value *) const;
787 
788   // Elimination.
789   struct ValueDFS;
790   void convertClassToDFSOrdered(const CongruenceClass &,
791                                 SmallVectorImpl<ValueDFS> &,
792                                 DenseMap<const Value *, unsigned int> &,
793                                 SmallPtrSetImpl<Instruction *> &) const;
794   void convertClassToLoadsAndStores(const CongruenceClass &,
795                                     SmallVectorImpl<ValueDFS> &) const;
796 
797   bool eliminateInstructions(Function &);
798   void replaceInstruction(Instruction *, Value *);
799   void markInstructionForDeletion(Instruction *);
800   void deleteInstructionsInBlock(BasicBlock *);
801   Value *findPHIOfOpsLeader(const Expression *, const Instruction *,
802                             const BasicBlock *) const;
803 
804   // New instruction creation.
805   void handleNewInstruction(Instruction *) {}
806 
807   // Various instruction touch utilities
808   template <typename Map, typename KeyType, typename Func>
809   void for_each_found(Map &, const KeyType &, Func);
810   template <typename Map, typename KeyType>
811   void touchAndErase(Map &, const KeyType &);
812   void markUsersTouched(Value *);
813   void markMemoryUsersTouched(const MemoryAccess *);
814   void markMemoryDefTouched(const MemoryAccess *);
815   void markPredicateUsersTouched(Instruction *);
816   void markValueLeaderChangeTouched(CongruenceClass *CC);
817   void markMemoryLeaderChangeTouched(CongruenceClass *CC);
818   void markPhiOfOpsChanged(const Expression *E);
819   void addPredicateUsers(const PredicateBase *, Instruction *) const;
820   void addMemoryUsers(const MemoryAccess *To, MemoryAccess *U) const;
821   void addAdditionalUsers(Value *To, Value *User) const;
822 
823   // Main loop of value numbering
824   void iterateTouchedInstructions();
825 
826   // Utilities.
827   void cleanupTables();
828   std::pair<unsigned, unsigned> assignDFSNumbers(BasicBlock *, unsigned);
829   void updateProcessedCount(const Value *V);
830   void verifyMemoryCongruency() const;
831   void verifyIterationSettled(Function &F);
832   void verifyStoreExpressions() const;
833   bool singleReachablePHIPath(SmallPtrSet<const MemoryAccess *, 8> &,
834                               const MemoryAccess *, const MemoryAccess *) const;
835   BasicBlock *getBlockForValue(Value *V) const;
836   void deleteExpression(const Expression *E) const;
837   MemoryUseOrDef *getMemoryAccess(const Instruction *) const;
838   MemoryAccess *getDefiningAccess(const MemoryAccess *) const;
839   MemoryPhi *getMemoryAccess(const BasicBlock *) const;
840   template <class T, class Range> T *getMinDFSOfRange(const Range &) const;
841 
842   unsigned InstrToDFSNum(const Value *V) const {
843     assert(isa<Instruction>(V) && "This should not be used for MemoryAccesses");
844     return InstrDFS.lookup(V);
845   }
846 
847   unsigned InstrToDFSNum(const MemoryAccess *MA) const {
848     return MemoryToDFSNum(MA);
849   }
850 
851   Value *InstrFromDFSNum(unsigned DFSNum) { return DFSToInstr[DFSNum]; }
852 
853   // Given a MemoryAccess, return the relevant instruction DFS number.  Note:
854   // This deliberately takes a value so it can be used with Use's, which will
855   // auto-convert to Value's but not to MemoryAccess's.
856   unsigned MemoryToDFSNum(const Value *MA) const {
857     assert(isa<MemoryAccess>(MA) &&
858            "This should not be used with instructions");
859     return isa<MemoryUseOrDef>(MA)
860                ? InstrToDFSNum(cast<MemoryUseOrDef>(MA)->getMemoryInst())
861                : InstrDFS.lookup(MA);
862   }
863 
864   bool isCycleFree(const Instruction *) const;
865   bool isBackedge(BasicBlock *From, BasicBlock *To) const;
866 
867   // Debug counter info.  When verifying, we have to reset the value numbering
868   // debug counter to the same state it started in to get the same results.
869   int64_t StartingVNCounter = 0;
870 };
871 
872 } // end anonymous namespace
873 
874 template <typename T>
875 static bool equalsLoadStoreHelper(const T &LHS, const Expression &RHS) {
876   if (!isa<LoadExpression>(RHS) && !isa<StoreExpression>(RHS))
877     return false;
878   return LHS.MemoryExpression::equals(RHS);
879 }
880 
881 bool LoadExpression::equals(const Expression &Other) const {
882   return equalsLoadStoreHelper(*this, Other);
883 }
884 
885 bool StoreExpression::equals(const Expression &Other) const {
886   if (!equalsLoadStoreHelper(*this, Other))
887     return false;
888   // Make sure that store vs store includes the value operand.
889   if (const auto *S = dyn_cast<StoreExpression>(&Other))
890     if (getStoredValue() != S->getStoredValue())
891       return false;
892   return true;
893 }
894 
895 // Determine if the edge From->To is a backedge
896 bool NewGVN::isBackedge(BasicBlock *From, BasicBlock *To) const {
897   return From == To ||
898          RPOOrdering.lookup(DT->getNode(From)) >=
899              RPOOrdering.lookup(DT->getNode(To));
900 }
901 
902 #ifndef NDEBUG
903 static std::string getBlockName(const BasicBlock *B) {
904   return DOTGraphTraits<DOTFuncInfo *>::getSimpleNodeLabel(B, nullptr);
905 }
906 #endif
907 
908 // Get a MemoryAccess for an instruction, fake or real.
909 MemoryUseOrDef *NewGVN::getMemoryAccess(const Instruction *I) const {
910   auto *Result = MSSA->getMemoryAccess(I);
911   return Result ? Result : TempToMemory.lookup(I);
912 }
913 
914 // Get a MemoryPhi for a basic block. These are all real.
915 MemoryPhi *NewGVN::getMemoryAccess(const BasicBlock *BB) const {
916   return MSSA->getMemoryAccess(BB);
917 }
918 
919 // Get the basic block from an instruction/memory value.
920 BasicBlock *NewGVN::getBlockForValue(Value *V) const {
921   if (auto *I = dyn_cast<Instruction>(V)) {
922     auto *Parent = I->getParent();
923     if (Parent)
924       return Parent;
925     Parent = TempToBlock.lookup(V);
926     assert(Parent && "Every fake instruction should have a block");
927     return Parent;
928   }
929 
930   auto *MP = dyn_cast<MemoryPhi>(V);
931   assert(MP && "Should have been an instruction or a MemoryPhi");
932   return MP->getBlock();
933 }
934 
935 // Delete a definitely dead expression, so it can be reused by the expression
936 // allocator.  Some of these are not in creation functions, so we have to accept
937 // const versions.
938 void NewGVN::deleteExpression(const Expression *E) const {
939   assert(isa<BasicExpression>(E));
940   auto *BE = cast<BasicExpression>(E);
941   const_cast<BasicExpression *>(BE)->deallocateOperands(ArgRecycler);
942   ExpressionAllocator.Deallocate(E);
943 }
944 
945 // If V is a predicateinfo copy, get the thing it is a copy of.
946 static Value *getCopyOf(const Value *V) {
947   if (auto *II = dyn_cast<IntrinsicInst>(V))
948     if (II->getIntrinsicID() == Intrinsic::ssa_copy)
949       return II->getOperand(0);
950   return nullptr;
951 }
952 
953 // Return true if V is really PN, even accounting for predicateinfo copies.
954 static bool isCopyOfPHI(const Value *V, const PHINode *PN) {
955   return V == PN || getCopyOf(V) == PN;
956 }
957 
958 static bool isCopyOfAPHI(const Value *V) {
959   auto *CO = getCopyOf(V);
960   return CO && isa<PHINode>(CO);
961 }
962 
963 // Sort PHI Operands into a canonical order.  What we use here is an RPO
964 // order. The BlockInstRange numbers are generated in an RPO walk of the basic
965 // blocks.
966 void NewGVN::sortPHIOps(MutableArrayRef<ValPair> Ops) const {
967   llvm::sort(Ops, [&](const ValPair &P1, const ValPair &P2) {
968     return BlockInstRange.lookup(P1.second).first <
969            BlockInstRange.lookup(P2.second).first;
970   });
971 }
972 
973 // Return true if V is a value that will always be available (IE can
974 // be placed anywhere) in the function.  We don't do globals here
975 // because they are often worse to put in place.
976 static bool alwaysAvailable(Value *V) {
977   return isa<Constant>(V) || isa<Argument>(V);
978 }
979 
980 // Create a PHIExpression from an array of {incoming edge, value} pairs.  I is
981 // the original instruction we are creating a PHIExpression for (but may not be
982 // a phi node). We require, as an invariant, that all the PHIOperands in the
983 // same block are sorted the same way. sortPHIOps will sort them into a
984 // canonical order.
985 PHIExpression *NewGVN::createPHIExpression(ArrayRef<ValPair> PHIOperands,
986                                            const Instruction *I,
987                                            BasicBlock *PHIBlock,
988                                            bool &HasBackedge,
989                                            bool &OriginalOpsConstant) const {
990   unsigned NumOps = PHIOperands.size();
991   auto *E = new (ExpressionAllocator) PHIExpression(NumOps, PHIBlock);
992 
993   E->allocateOperands(ArgRecycler, ExpressionAllocator);
994   E->setType(PHIOperands.begin()->first->getType());
995   E->setOpcode(Instruction::PHI);
996 
997   // Filter out unreachable phi operands.
998   auto Filtered = make_filter_range(PHIOperands, [&](const ValPair &P) {
999     auto *BB = P.second;
1000     if (auto *PHIOp = dyn_cast<PHINode>(I))
1001       if (isCopyOfPHI(P.first, PHIOp))
1002         return false;
1003     if (!ReachableEdges.count({BB, PHIBlock}))
1004       return false;
1005     // Things in TOPClass are equivalent to everything.
1006     if (ValueToClass.lookup(P.first) == TOPClass)
1007       return false;
1008     OriginalOpsConstant = OriginalOpsConstant && isa<Constant>(P.first);
1009     HasBackedge = HasBackedge || isBackedge(BB, PHIBlock);
1010     return lookupOperandLeader(P.first) != I;
1011   });
1012   std::transform(Filtered.begin(), Filtered.end(), op_inserter(E),
1013                  [&](const ValPair &P) -> Value * {
1014                    return lookupOperandLeader(P.first);
1015                  });
1016   return E;
1017 }
1018 
1019 // Set basic expression info (Arguments, type, opcode) for Expression
1020 // E from Instruction I in block B.
1021 bool NewGVN::setBasicExpressionInfo(Instruction *I, BasicExpression *E) const {
1022   bool AllConstant = true;
1023   if (auto *GEP = dyn_cast<GetElementPtrInst>(I))
1024     E->setType(GEP->getSourceElementType());
1025   else
1026     E->setType(I->getType());
1027   E->setOpcode(I->getOpcode());
1028   E->allocateOperands(ArgRecycler, ExpressionAllocator);
1029 
1030   // Transform the operand array into an operand leader array, and keep track of
1031   // whether all members are constant.
1032   std::transform(I->op_begin(), I->op_end(), op_inserter(E), [&](Value *O) {
1033     auto Operand = lookupOperandLeader(O);
1034     AllConstant = AllConstant && isa<Constant>(Operand);
1035     return Operand;
1036   });
1037 
1038   return AllConstant;
1039 }
1040 
1041 const Expression *NewGVN::createBinaryExpression(unsigned Opcode, Type *T,
1042                                                  Value *Arg1, Value *Arg2,
1043                                                  Instruction *I) const {
1044   auto *E = new (ExpressionAllocator) BasicExpression(2);
1045 
1046   E->setType(T);
1047   E->setOpcode(Opcode);
1048   E->allocateOperands(ArgRecycler, ExpressionAllocator);
1049   if (Instruction::isCommutative(Opcode)) {
1050     // Ensure that commutative instructions that only differ by a permutation
1051     // of their operands get the same value number by sorting the operand value
1052     // numbers.  Since all commutative instructions have two operands it is more
1053     // efficient to sort by hand rather than using, say, std::sort.
1054     if (shouldSwapOperands(Arg1, Arg2))
1055       std::swap(Arg1, Arg2);
1056   }
1057   E->op_push_back(lookupOperandLeader(Arg1));
1058   E->op_push_back(lookupOperandLeader(Arg2));
1059 
1060   Value *V = SimplifyBinOp(Opcode, E->getOperand(0), E->getOperand(1), SQ);
1061   if (const Expression *SimplifiedE = checkSimplificationResults(E, I, V))
1062     return SimplifiedE;
1063   return E;
1064 }
1065 
1066 // Take a Value returned by simplification of Expression E/Instruction
1067 // I, and see if it resulted in a simpler expression. If so, return
1068 // that expression.
1069 const Expression *NewGVN::checkSimplificationResults(Expression *E,
1070                                                      Instruction *I,
1071                                                      Value *V) const {
1072   if (!V)
1073     return nullptr;
1074   if (auto *C = dyn_cast<Constant>(V)) {
1075     if (I)
1076       LLVM_DEBUG(dbgs() << "Simplified " << *I << " to "
1077                         << " constant " << *C << "\n");
1078     NumGVNOpsSimplified++;
1079     assert(isa<BasicExpression>(E) &&
1080            "We should always have had a basic expression here");
1081     deleteExpression(E);
1082     return createConstantExpression(C);
1083   } else if (isa<Argument>(V) || isa<GlobalVariable>(V)) {
1084     if (I)
1085       LLVM_DEBUG(dbgs() << "Simplified " << *I << " to "
1086                         << " variable " << *V << "\n");
1087     deleteExpression(E);
1088     return createVariableExpression(V);
1089   }
1090 
1091   CongruenceClass *CC = ValueToClass.lookup(V);
1092   if (CC) {
1093     if (CC->getLeader() && CC->getLeader() != I) {
1094       // If we simplified to something else, we need to communicate
1095       // that we're users of the value we simplified to.
1096       if (I != V) {
1097         // Don't add temporary instructions to the user lists.
1098         if (!AllTempInstructions.count(I))
1099           addAdditionalUsers(V, I);
1100       }
1101       return createVariableOrConstant(CC->getLeader());
1102     }
1103     if (CC->getDefiningExpr()) {
1104       // If we simplified to something else, we need to communicate
1105       // that we're users of the value we simplified to.
1106       if (I != V) {
1107         // Don't add temporary instructions to the user lists.
1108         if (!AllTempInstructions.count(I))
1109           addAdditionalUsers(V, I);
1110       }
1111 
1112       if (I)
1113         LLVM_DEBUG(dbgs() << "Simplified " << *I << " to "
1114                           << " expression " << *CC->getDefiningExpr() << "\n");
1115       NumGVNOpsSimplified++;
1116       deleteExpression(E);
1117       return CC->getDefiningExpr();
1118     }
1119   }
1120 
1121   return nullptr;
1122 }
1123 
1124 // Create a value expression from the instruction I, replacing operands with
1125 // their leaders.
1126 
1127 const Expression *NewGVN::createExpression(Instruction *I) const {
1128   auto *E = new (ExpressionAllocator) BasicExpression(I->getNumOperands());
1129 
1130   bool AllConstant = setBasicExpressionInfo(I, E);
1131 
1132   if (I->isCommutative()) {
1133     // Ensure that commutative instructions that only differ by a permutation
1134     // of their operands get the same value number by sorting the operand value
1135     // numbers.  Since all commutative instructions have two operands it is more
1136     // efficient to sort by hand rather than using, say, std::sort.
1137     assert(I->getNumOperands() == 2 && "Unsupported commutative instruction!");
1138     if (shouldSwapOperands(E->getOperand(0), E->getOperand(1)))
1139       E->swapOperands(0, 1);
1140   }
1141   // Perform simplification.
1142   if (auto *CI = dyn_cast<CmpInst>(I)) {
1143     // Sort the operand value numbers so x<y and y>x get the same value
1144     // number.
1145     CmpInst::Predicate Predicate = CI->getPredicate();
1146     if (shouldSwapOperands(E->getOperand(0), E->getOperand(1))) {
1147       E->swapOperands(0, 1);
1148       Predicate = CmpInst::getSwappedPredicate(Predicate);
1149     }
1150     E->setOpcode((CI->getOpcode() << 8) | Predicate);
1151     // TODO: 25% of our time is spent in SimplifyCmpInst with pointer operands
1152     assert(I->getOperand(0)->getType() == I->getOperand(1)->getType() &&
1153            "Wrong types on cmp instruction");
1154     assert((E->getOperand(0)->getType() == I->getOperand(0)->getType() &&
1155             E->getOperand(1)->getType() == I->getOperand(1)->getType()));
1156     Value *V =
1157         SimplifyCmpInst(Predicate, E->getOperand(0), E->getOperand(1), SQ);
1158     if (const Expression *SimplifiedE = checkSimplificationResults(E, I, V))
1159       return SimplifiedE;
1160   } else if (isa<SelectInst>(I)) {
1161     if (isa<Constant>(E->getOperand(0)) ||
1162         E->getOperand(1) == E->getOperand(2)) {
1163       assert(E->getOperand(1)->getType() == I->getOperand(1)->getType() &&
1164              E->getOperand(2)->getType() == I->getOperand(2)->getType());
1165       Value *V = SimplifySelectInst(E->getOperand(0), E->getOperand(1),
1166                                     E->getOperand(2), SQ);
1167       if (const Expression *SimplifiedE = checkSimplificationResults(E, I, V))
1168         return SimplifiedE;
1169     }
1170   } else if (I->isBinaryOp()) {
1171     Value *V =
1172         SimplifyBinOp(E->getOpcode(), E->getOperand(0), E->getOperand(1), SQ);
1173     if (const Expression *SimplifiedE = checkSimplificationResults(E, I, V))
1174       return SimplifiedE;
1175   } else if (auto *CI = dyn_cast<CastInst>(I)) {
1176     Value *V =
1177         SimplifyCastInst(CI->getOpcode(), E->getOperand(0), CI->getType(), SQ);
1178     if (const Expression *SimplifiedE = checkSimplificationResults(E, I, V))
1179       return SimplifiedE;
1180   } else if (isa<GetElementPtrInst>(I)) {
1181     Value *V = SimplifyGEPInst(
1182         E->getType(), ArrayRef<Value *>(E->op_begin(), E->op_end()), SQ);
1183     if (const Expression *SimplifiedE = checkSimplificationResults(E, I, V))
1184       return SimplifiedE;
1185   } else if (AllConstant) {
1186     // We don't bother trying to simplify unless all of the operands
1187     // were constant.
1188     // TODO: There are a lot of Simplify*'s we could call here, if we
1189     // wanted to.  The original motivating case for this code was a
1190     // zext i1 false to i8, which we don't have an interface to
1191     // simplify (IE there is no SimplifyZExt).
1192 
1193     SmallVector<Constant *, 8> C;
1194     for (Value *Arg : E->operands())
1195       C.emplace_back(cast<Constant>(Arg));
1196 
1197     if (Value *V = ConstantFoldInstOperands(I, C, DL, TLI))
1198       if (const Expression *SimplifiedE = checkSimplificationResults(E, I, V))
1199         return SimplifiedE;
1200   }
1201   return E;
1202 }
1203 
1204 const AggregateValueExpression *
1205 NewGVN::createAggregateValueExpression(Instruction *I) const {
1206   if (auto *II = dyn_cast<InsertValueInst>(I)) {
1207     auto *E = new (ExpressionAllocator)
1208         AggregateValueExpression(I->getNumOperands(), II->getNumIndices());
1209     setBasicExpressionInfo(I, E);
1210     E->allocateIntOperands(ExpressionAllocator);
1211     std::copy(II->idx_begin(), II->idx_end(), int_op_inserter(E));
1212     return E;
1213   } else if (auto *EI = dyn_cast<ExtractValueInst>(I)) {
1214     auto *E = new (ExpressionAllocator)
1215         AggregateValueExpression(I->getNumOperands(), EI->getNumIndices());
1216     setBasicExpressionInfo(EI, E);
1217     E->allocateIntOperands(ExpressionAllocator);
1218     std::copy(EI->idx_begin(), EI->idx_end(), int_op_inserter(E));
1219     return E;
1220   }
1221   llvm_unreachable("Unhandled type of aggregate value operation");
1222 }
1223 
1224 const DeadExpression *NewGVN::createDeadExpression() const {
1225   // DeadExpression has no arguments and all DeadExpression's are the same,
1226   // so we only need one of them.
1227   return SingletonDeadExpression;
1228 }
1229 
1230 const VariableExpression *NewGVN::createVariableExpression(Value *V) const {
1231   auto *E = new (ExpressionAllocator) VariableExpression(V);
1232   E->setOpcode(V->getValueID());
1233   return E;
1234 }
1235 
1236 const Expression *NewGVN::createVariableOrConstant(Value *V) const {
1237   if (auto *C = dyn_cast<Constant>(V))
1238     return createConstantExpression(C);
1239   return createVariableExpression(V);
1240 }
1241 
1242 const ConstantExpression *NewGVN::createConstantExpression(Constant *C) const {
1243   auto *E = new (ExpressionAllocator) ConstantExpression(C);
1244   E->setOpcode(C->getValueID());
1245   return E;
1246 }
1247 
1248 const UnknownExpression *NewGVN::createUnknownExpression(Instruction *I) const {
1249   auto *E = new (ExpressionAllocator) UnknownExpression(I);
1250   E->setOpcode(I->getOpcode());
1251   return E;
1252 }
1253 
1254 const CallExpression *
1255 NewGVN::createCallExpression(CallInst *CI, const MemoryAccess *MA) const {
1256   // FIXME: Add operand bundles for calls.
1257   // FIXME: Allow commutative matching for intrinsics.
1258   auto *E =
1259       new (ExpressionAllocator) CallExpression(CI->getNumOperands(), CI, MA);
1260   setBasicExpressionInfo(CI, E);
1261   return E;
1262 }
1263 
1264 // Return true if some equivalent of instruction Inst dominates instruction U.
1265 bool NewGVN::someEquivalentDominates(const Instruction *Inst,
1266                                      const Instruction *U) const {
1267   auto *CC = ValueToClass.lookup(Inst);
1268    // This must be an instruction because we are only called from phi nodes
1269   // in the case that the value it needs to check against is an instruction.
1270 
1271   // The most likely candidates for dominance are the leader and the next leader.
1272   // The leader or nextleader will dominate in all cases where there is an
1273   // equivalent that is higher up in the dom tree.
1274   // We can't *only* check them, however, because the
1275   // dominator tree could have an infinite number of non-dominating siblings
1276   // with instructions that are in the right congruence class.
1277   //       A
1278   // B C D E F G
1279   // |
1280   // H
1281   // Instruction U could be in H,  with equivalents in every other sibling.
1282   // Depending on the rpo order picked, the leader could be the equivalent in
1283   // any of these siblings.
1284   if (!CC)
1285     return false;
1286   if (alwaysAvailable(CC->getLeader()))
1287     return true;
1288   if (DT->dominates(cast<Instruction>(CC->getLeader()), U))
1289     return true;
1290   if (CC->getNextLeader().first &&
1291       DT->dominates(cast<Instruction>(CC->getNextLeader().first), U))
1292     return true;
1293   return llvm::any_of(*CC, [&](const Value *Member) {
1294     return Member != CC->getLeader() &&
1295            DT->dominates(cast<Instruction>(Member), U);
1296   });
1297 }
1298 
1299 // See if we have a congruence class and leader for this operand, and if so,
1300 // return it. Otherwise, return the operand itself.
1301 Value *NewGVN::lookupOperandLeader(Value *V) const {
1302   CongruenceClass *CC = ValueToClass.lookup(V);
1303   if (CC) {
1304     // Everything in TOP is represented by undef, as it can be any value.
1305     // We do have to make sure we get the type right though, so we can't set the
1306     // RepLeader to undef.
1307     if (CC == TOPClass)
1308       return UndefValue::get(V->getType());
1309     return CC->getStoredValue() ? CC->getStoredValue() : CC->getLeader();
1310   }
1311 
1312   return V;
1313 }
1314 
1315 const MemoryAccess *NewGVN::lookupMemoryLeader(const MemoryAccess *MA) const {
1316   auto *CC = getMemoryClass(MA);
1317   assert(CC->getMemoryLeader() &&
1318          "Every MemoryAccess should be mapped to a congruence class with a "
1319          "representative memory access");
1320   return CC->getMemoryLeader();
1321 }
1322 
1323 // Return true if the MemoryAccess is really equivalent to everything. This is
1324 // equivalent to the lattice value "TOP" in most lattices.  This is the initial
1325 // state of all MemoryAccesses.
1326 bool NewGVN::isMemoryAccessTOP(const MemoryAccess *MA) const {
1327   return getMemoryClass(MA) == TOPClass;
1328 }
1329 
1330 LoadExpression *NewGVN::createLoadExpression(Type *LoadType, Value *PointerOp,
1331                                              LoadInst *LI,
1332                                              const MemoryAccess *MA) const {
1333   auto *E =
1334       new (ExpressionAllocator) LoadExpression(1, LI, lookupMemoryLeader(MA));
1335   E->allocateOperands(ArgRecycler, ExpressionAllocator);
1336   E->setType(LoadType);
1337 
1338   // Give store and loads same opcode so they value number together.
1339   E->setOpcode(0);
1340   E->op_push_back(PointerOp);
1341 
1342   // TODO: Value number heap versions. We may be able to discover
1343   // things alias analysis can't on it's own (IE that a store and a
1344   // load have the same value, and thus, it isn't clobbering the load).
1345   return E;
1346 }
1347 
1348 const StoreExpression *
1349 NewGVN::createStoreExpression(StoreInst *SI, const MemoryAccess *MA) const {
1350   auto *StoredValueLeader = lookupOperandLeader(SI->getValueOperand());
1351   auto *E = new (ExpressionAllocator)
1352       StoreExpression(SI->getNumOperands(), SI, StoredValueLeader, MA);
1353   E->allocateOperands(ArgRecycler, ExpressionAllocator);
1354   E->setType(SI->getValueOperand()->getType());
1355 
1356   // Give store and loads same opcode so they value number together.
1357   E->setOpcode(0);
1358   E->op_push_back(lookupOperandLeader(SI->getPointerOperand()));
1359 
1360   // TODO: Value number heap versions. We may be able to discover
1361   // things alias analysis can't on it's own (IE that a store and a
1362   // load have the same value, and thus, it isn't clobbering the load).
1363   return E;
1364 }
1365 
1366 const Expression *NewGVN::performSymbolicStoreEvaluation(Instruction *I) const {
1367   // Unlike loads, we never try to eliminate stores, so we do not check if they
1368   // are simple and avoid value numbering them.
1369   auto *SI = cast<StoreInst>(I);
1370   auto *StoreAccess = getMemoryAccess(SI);
1371   // Get the expression, if any, for the RHS of the MemoryDef.
1372   const MemoryAccess *StoreRHS = StoreAccess->getDefiningAccess();
1373   if (EnableStoreRefinement)
1374     StoreRHS = MSSAWalker->getClobberingMemoryAccess(StoreAccess);
1375   // If we bypassed the use-def chains, make sure we add a use.
1376   StoreRHS = lookupMemoryLeader(StoreRHS);
1377   if (StoreRHS != StoreAccess->getDefiningAccess())
1378     addMemoryUsers(StoreRHS, StoreAccess);
1379   // If we are defined by ourselves, use the live on entry def.
1380   if (StoreRHS == StoreAccess)
1381     StoreRHS = MSSA->getLiveOnEntryDef();
1382 
1383   if (SI->isSimple()) {
1384     // See if we are defined by a previous store expression, it already has a
1385     // value, and it's the same value as our current store. FIXME: Right now, we
1386     // only do this for simple stores, we should expand to cover memcpys, etc.
1387     const auto *LastStore = createStoreExpression(SI, StoreRHS);
1388     const auto *LastCC = ExpressionToClass.lookup(LastStore);
1389     // We really want to check whether the expression we matched was a store. No
1390     // easy way to do that. However, we can check that the class we found has a
1391     // store, which, assuming the value numbering state is not corrupt, is
1392     // sufficient, because we must also be equivalent to that store's expression
1393     // for it to be in the same class as the load.
1394     if (LastCC && LastCC->getStoredValue() == LastStore->getStoredValue())
1395       return LastStore;
1396     // Also check if our value operand is defined by a load of the same memory
1397     // location, and the memory state is the same as it was then (otherwise, it
1398     // could have been overwritten later. See test32 in
1399     // transforms/DeadStoreElimination/simple.ll).
1400     if (auto *LI = dyn_cast<LoadInst>(LastStore->getStoredValue()))
1401       if ((lookupOperandLeader(LI->getPointerOperand()) ==
1402            LastStore->getOperand(0)) &&
1403           (lookupMemoryLeader(getMemoryAccess(LI)->getDefiningAccess()) ==
1404            StoreRHS))
1405         return LastStore;
1406     deleteExpression(LastStore);
1407   }
1408 
1409   // If the store is not equivalent to anything, value number it as a store that
1410   // produces a unique memory state (instead of using it's MemoryUse, we use
1411   // it's MemoryDef).
1412   return createStoreExpression(SI, StoreAccess);
1413 }
1414 
1415 // See if we can extract the value of a loaded pointer from a load, a store, or
1416 // a memory instruction.
1417 const Expression *
1418 NewGVN::performSymbolicLoadCoercion(Type *LoadType, Value *LoadPtr,
1419                                     LoadInst *LI, Instruction *DepInst,
1420                                     MemoryAccess *DefiningAccess) const {
1421   assert((!LI || LI->isSimple()) && "Not a simple load");
1422   if (auto *DepSI = dyn_cast<StoreInst>(DepInst)) {
1423     // Can't forward from non-atomic to atomic without violating memory model.
1424     // Also don't need to coerce if they are the same type, we will just
1425     // propagate.
1426     if (LI->isAtomic() > DepSI->isAtomic() ||
1427         LoadType == DepSI->getValueOperand()->getType())
1428       return nullptr;
1429     int Offset = analyzeLoadFromClobberingStore(LoadType, LoadPtr, DepSI, DL);
1430     if (Offset >= 0) {
1431       if (auto *C = dyn_cast<Constant>(
1432               lookupOperandLeader(DepSI->getValueOperand()))) {
1433         LLVM_DEBUG(dbgs() << "Coercing load from store " << *DepSI
1434                           << " to constant " << *C << "\n");
1435         return createConstantExpression(
1436             getConstantStoreValueForLoad(C, Offset, LoadType, DL));
1437       }
1438     }
1439   } else if (auto *DepLI = dyn_cast<LoadInst>(DepInst)) {
1440     // Can't forward from non-atomic to atomic without violating memory model.
1441     if (LI->isAtomic() > DepLI->isAtomic())
1442       return nullptr;
1443     int Offset = analyzeLoadFromClobberingLoad(LoadType, LoadPtr, DepLI, DL);
1444     if (Offset >= 0) {
1445       // We can coerce a constant load into a load.
1446       if (auto *C = dyn_cast<Constant>(lookupOperandLeader(DepLI)))
1447         if (auto *PossibleConstant =
1448                 getConstantLoadValueForLoad(C, Offset, LoadType, DL)) {
1449           LLVM_DEBUG(dbgs() << "Coercing load from load " << *LI
1450                             << " to constant " << *PossibleConstant << "\n");
1451           return createConstantExpression(PossibleConstant);
1452         }
1453     }
1454   } else if (auto *DepMI = dyn_cast<MemIntrinsic>(DepInst)) {
1455     int Offset = analyzeLoadFromClobberingMemInst(LoadType, LoadPtr, DepMI, DL);
1456     if (Offset >= 0) {
1457       if (auto *PossibleConstant =
1458               getConstantMemInstValueForLoad(DepMI, Offset, LoadType, DL)) {
1459         LLVM_DEBUG(dbgs() << "Coercing load from meminst " << *DepMI
1460                           << " to constant " << *PossibleConstant << "\n");
1461         return createConstantExpression(PossibleConstant);
1462       }
1463     }
1464   }
1465 
1466   // All of the below are only true if the loaded pointer is produced
1467   // by the dependent instruction.
1468   if (LoadPtr != lookupOperandLeader(DepInst) &&
1469       !AA->isMustAlias(LoadPtr, DepInst))
1470     return nullptr;
1471   // If this load really doesn't depend on anything, then we must be loading an
1472   // undef value.  This can happen when loading for a fresh allocation with no
1473   // intervening stores, for example.  Note that this is only true in the case
1474   // that the result of the allocation is pointer equal to the load ptr.
1475   if (isa<AllocaInst>(DepInst) || isMallocLikeFn(DepInst, TLI) ||
1476       isAlignedAllocLikeFn(DepInst, TLI)) {
1477     return createConstantExpression(UndefValue::get(LoadType));
1478   }
1479   // If this load occurs either right after a lifetime begin,
1480   // then the loaded value is undefined.
1481   else if (auto *II = dyn_cast<IntrinsicInst>(DepInst)) {
1482     if (II->getIntrinsicID() == Intrinsic::lifetime_start)
1483       return createConstantExpression(UndefValue::get(LoadType));
1484   }
1485   // If this load follows a calloc (which zero initializes memory),
1486   // then the loaded value is zero
1487   else if (isCallocLikeFn(DepInst, TLI)) {
1488     return createConstantExpression(Constant::getNullValue(LoadType));
1489   }
1490 
1491   return nullptr;
1492 }
1493 
1494 const Expression *NewGVN::performSymbolicLoadEvaluation(Instruction *I) const {
1495   auto *LI = cast<LoadInst>(I);
1496 
1497   // We can eliminate in favor of non-simple loads, but we won't be able to
1498   // eliminate the loads themselves.
1499   if (!LI->isSimple())
1500     return nullptr;
1501 
1502   Value *LoadAddressLeader = lookupOperandLeader(LI->getPointerOperand());
1503   // Load of undef is undef.
1504   if (isa<UndefValue>(LoadAddressLeader))
1505     return createConstantExpression(UndefValue::get(LI->getType()));
1506   MemoryAccess *OriginalAccess = getMemoryAccess(I);
1507   MemoryAccess *DefiningAccess =
1508       MSSAWalker->getClobberingMemoryAccess(OriginalAccess);
1509 
1510   if (!MSSA->isLiveOnEntryDef(DefiningAccess)) {
1511     if (auto *MD = dyn_cast<MemoryDef>(DefiningAccess)) {
1512       Instruction *DefiningInst = MD->getMemoryInst();
1513       // If the defining instruction is not reachable, replace with undef.
1514       if (!ReachableBlocks.count(DefiningInst->getParent()))
1515         return createConstantExpression(UndefValue::get(LI->getType()));
1516       // This will handle stores and memory insts.  We only do if it the
1517       // defining access has a different type, or it is a pointer produced by
1518       // certain memory operations that cause the memory to have a fixed value
1519       // (IE things like calloc).
1520       if (const auto *CoercionResult =
1521               performSymbolicLoadCoercion(LI->getType(), LoadAddressLeader, LI,
1522                                           DefiningInst, DefiningAccess))
1523         return CoercionResult;
1524     }
1525   }
1526 
1527   const auto *LE = createLoadExpression(LI->getType(), LoadAddressLeader, LI,
1528                                         DefiningAccess);
1529   // If our MemoryLeader is not our defining access, add a use to the
1530   // MemoryLeader, so that we get reprocessed when it changes.
1531   if (LE->getMemoryLeader() != DefiningAccess)
1532     addMemoryUsers(LE->getMemoryLeader(), OriginalAccess);
1533   return LE;
1534 }
1535 
1536 const Expression *
1537 NewGVN::performSymbolicPredicateInfoEvaluation(Instruction *I) const {
1538   auto *PI = PredInfo->getPredicateInfoFor(I);
1539   if (!PI)
1540     return nullptr;
1541 
1542   LLVM_DEBUG(dbgs() << "Found predicate info from instruction !\n");
1543 
1544   const Optional<PredicateConstraint> &Constraint = PI->getConstraint();
1545   if (!Constraint)
1546     return nullptr;
1547 
1548   CmpInst::Predicate Predicate = Constraint->Predicate;
1549   Value *CmpOp0 = I->getOperand(0);
1550   Value *CmpOp1 = Constraint->OtherOp;
1551 
1552   Value *FirstOp = lookupOperandLeader(CmpOp0);
1553   Value *SecondOp = lookupOperandLeader(CmpOp1);
1554   Value *AdditionallyUsedValue = CmpOp0;
1555 
1556   // Sort the ops.
1557   if (shouldSwapOperands(FirstOp, SecondOp)) {
1558     std::swap(FirstOp, SecondOp);
1559     Predicate = CmpInst::getSwappedPredicate(Predicate);
1560     AdditionallyUsedValue = CmpOp1;
1561   }
1562 
1563   if (Predicate == CmpInst::ICMP_EQ) {
1564     addPredicateUsers(PI, I);
1565     addAdditionalUsers(AdditionallyUsedValue, I);
1566     return createVariableOrConstant(FirstOp);
1567   }
1568 
1569   // Handle the special case of floating point.
1570   if (Predicate == CmpInst::FCMP_OEQ && isa<ConstantFP>(FirstOp) &&
1571       !cast<ConstantFP>(FirstOp)->isZero()) {
1572     addPredicateUsers(PI, I);
1573     addAdditionalUsers(AdditionallyUsedValue, I);
1574     return createConstantExpression(cast<Constant>(FirstOp));
1575   }
1576 
1577   return nullptr;
1578 }
1579 
1580 // Evaluate read only and pure calls, and create an expression result.
1581 const Expression *NewGVN::performSymbolicCallEvaluation(Instruction *I) const {
1582   auto *CI = cast<CallInst>(I);
1583   if (auto *II = dyn_cast<IntrinsicInst>(I)) {
1584     // Intrinsics with the returned attribute are copies of arguments.
1585     if (auto *ReturnedValue = II->getReturnedArgOperand()) {
1586       if (II->getIntrinsicID() == Intrinsic::ssa_copy)
1587         if (const auto *Result = performSymbolicPredicateInfoEvaluation(I))
1588           return Result;
1589       return createVariableOrConstant(ReturnedValue);
1590     }
1591   }
1592   if (AA->doesNotAccessMemory(CI)) {
1593     return createCallExpression(CI, TOPClass->getMemoryLeader());
1594   } else if (AA->onlyReadsMemory(CI)) {
1595     if (auto *MA = MSSA->getMemoryAccess(CI)) {
1596       auto *DefiningAccess = MSSAWalker->getClobberingMemoryAccess(MA);
1597       return createCallExpression(CI, DefiningAccess);
1598     } else // MSSA determined that CI does not access memory.
1599       return createCallExpression(CI, TOPClass->getMemoryLeader());
1600   }
1601   return nullptr;
1602 }
1603 
1604 // Retrieve the memory class for a given MemoryAccess.
1605 CongruenceClass *NewGVN::getMemoryClass(const MemoryAccess *MA) const {
1606   auto *Result = MemoryAccessToClass.lookup(MA);
1607   assert(Result && "Should have found memory class");
1608   return Result;
1609 }
1610 
1611 // Update the MemoryAccess equivalence table to say that From is equal to To,
1612 // and return true if this is different from what already existed in the table.
1613 bool NewGVN::setMemoryClass(const MemoryAccess *From,
1614                             CongruenceClass *NewClass) {
1615   assert(NewClass &&
1616          "Every MemoryAccess should be getting mapped to a non-null class");
1617   LLVM_DEBUG(dbgs() << "Setting " << *From);
1618   LLVM_DEBUG(dbgs() << " equivalent to congruence class ");
1619   LLVM_DEBUG(dbgs() << NewClass->getID()
1620                     << " with current MemoryAccess leader ");
1621   LLVM_DEBUG(dbgs() << *NewClass->getMemoryLeader() << "\n");
1622 
1623   auto LookupResult = MemoryAccessToClass.find(From);
1624   bool Changed = false;
1625   // If it's already in the table, see if the value changed.
1626   if (LookupResult != MemoryAccessToClass.end()) {
1627     auto *OldClass = LookupResult->second;
1628     if (OldClass != NewClass) {
1629       // If this is a phi, we have to handle memory member updates.
1630       if (auto *MP = dyn_cast<MemoryPhi>(From)) {
1631         OldClass->memory_erase(MP);
1632         NewClass->memory_insert(MP);
1633         // This may have killed the class if it had no non-memory members
1634         if (OldClass->getMemoryLeader() == From) {
1635           if (OldClass->definesNoMemory()) {
1636             OldClass->setMemoryLeader(nullptr);
1637           } else {
1638             OldClass->setMemoryLeader(getNextMemoryLeader(OldClass));
1639             LLVM_DEBUG(dbgs() << "Memory class leader change for class "
1640                               << OldClass->getID() << " to "
1641                               << *OldClass->getMemoryLeader()
1642                               << " due to removal of a memory member " << *From
1643                               << "\n");
1644             markMemoryLeaderChangeTouched(OldClass);
1645           }
1646         }
1647       }
1648       // It wasn't equivalent before, and now it is.
1649       LookupResult->second = NewClass;
1650       Changed = true;
1651     }
1652   }
1653 
1654   return Changed;
1655 }
1656 
1657 // Determine if a instruction is cycle-free.  That means the values in the
1658 // instruction don't depend on any expressions that can change value as a result
1659 // of the instruction.  For example, a non-cycle free instruction would be v =
1660 // phi(0, v+1).
1661 bool NewGVN::isCycleFree(const Instruction *I) const {
1662   // In order to compute cycle-freeness, we do SCC finding on the instruction,
1663   // and see what kind of SCC it ends up in.  If it is a singleton, it is
1664   // cycle-free.  If it is not in a singleton, it is only cycle free if the
1665   // other members are all phi nodes (as they do not compute anything, they are
1666   // copies).
1667   auto ICS = InstCycleState.lookup(I);
1668   if (ICS == ICS_Unknown) {
1669     SCCFinder.Start(I);
1670     auto &SCC = SCCFinder.getComponentFor(I);
1671     // It's cycle free if it's size 1 or the SCC is *only* phi nodes.
1672     if (SCC.size() == 1)
1673       InstCycleState.insert({I, ICS_CycleFree});
1674     else {
1675       bool AllPhis = llvm::all_of(SCC, [](const Value *V) {
1676         return isa<PHINode>(V) || isCopyOfAPHI(V);
1677       });
1678       ICS = AllPhis ? ICS_CycleFree : ICS_Cycle;
1679       for (auto *Member : SCC)
1680         if (auto *MemberPhi = dyn_cast<PHINode>(Member))
1681           InstCycleState.insert({MemberPhi, ICS});
1682     }
1683   }
1684   if (ICS == ICS_Cycle)
1685     return false;
1686   return true;
1687 }
1688 
1689 // Evaluate PHI nodes symbolically and create an expression result.
1690 const Expression *
1691 NewGVN::performSymbolicPHIEvaluation(ArrayRef<ValPair> PHIOps,
1692                                      Instruction *I,
1693                                      BasicBlock *PHIBlock) const {
1694   // True if one of the incoming phi edges is a backedge.
1695   bool HasBackedge = false;
1696   // All constant tracks the state of whether all the *original* phi operands
1697   // This is really shorthand for "this phi cannot cycle due to forward
1698   // change in value of the phi is guaranteed not to later change the value of
1699   // the phi. IE it can't be v = phi(undef, v+1)
1700   bool OriginalOpsConstant = true;
1701   auto *E = cast<PHIExpression>(createPHIExpression(
1702       PHIOps, I, PHIBlock, HasBackedge, OriginalOpsConstant));
1703   // We match the semantics of SimplifyPhiNode from InstructionSimplify here.
1704   // See if all arguments are the same.
1705   // We track if any were undef because they need special handling.
1706   bool HasUndef = false;
1707   auto Filtered = make_filter_range(E->operands(), [&](Value *Arg) {
1708     if (isa<UndefValue>(Arg)) {
1709       HasUndef = true;
1710       return false;
1711     }
1712     return true;
1713   });
1714   // If we are left with no operands, it's dead.
1715   if (Filtered.empty()) {
1716     // If it has undef at this point, it means there are no-non-undef arguments,
1717     // and thus, the value of the phi node must be undef.
1718     if (HasUndef) {
1719       LLVM_DEBUG(
1720           dbgs() << "PHI Node " << *I
1721                  << " has no non-undef arguments, valuing it as undef\n");
1722       return createConstantExpression(UndefValue::get(I->getType()));
1723     }
1724 
1725     LLVM_DEBUG(dbgs() << "No arguments of PHI node " << *I << " are live\n");
1726     deleteExpression(E);
1727     return createDeadExpression();
1728   }
1729   Value *AllSameValue = *(Filtered.begin());
1730   ++Filtered.begin();
1731   // Can't use std::equal here, sadly, because filter.begin moves.
1732   if (llvm::all_of(Filtered, [&](Value *Arg) { return Arg == AllSameValue; })) {
1733     // In LLVM's non-standard representation of phi nodes, it's possible to have
1734     // phi nodes with cycles (IE dependent on other phis that are .... dependent
1735     // on the original phi node), especially in weird CFG's where some arguments
1736     // are unreachable, or uninitialized along certain paths.  This can cause
1737     // infinite loops during evaluation. We work around this by not trying to
1738     // really evaluate them independently, but instead using a variable
1739     // expression to say if one is equivalent to the other.
1740     // We also special case undef, so that if we have an undef, we can't use the
1741     // common value unless it dominates the phi block.
1742     if (HasUndef) {
1743       // If we have undef and at least one other value, this is really a
1744       // multivalued phi, and we need to know if it's cycle free in order to
1745       // evaluate whether we can ignore the undef.  The other parts of this are
1746       // just shortcuts.  If there is no backedge, or all operands are
1747       // constants, it also must be cycle free.
1748       if (HasBackedge && !OriginalOpsConstant &&
1749           !isa<UndefValue>(AllSameValue) && !isCycleFree(I))
1750         return E;
1751 
1752       // Only have to check for instructions
1753       if (auto *AllSameInst = dyn_cast<Instruction>(AllSameValue))
1754         if (!someEquivalentDominates(AllSameInst, I))
1755           return E;
1756     }
1757     // Can't simplify to something that comes later in the iteration.
1758     // Otherwise, when and if it changes congruence class, we will never catch
1759     // up. We will always be a class behind it.
1760     if (isa<Instruction>(AllSameValue) &&
1761         InstrToDFSNum(AllSameValue) > InstrToDFSNum(I))
1762       return E;
1763     NumGVNPhisAllSame++;
1764     LLVM_DEBUG(dbgs() << "Simplified PHI node " << *I << " to " << *AllSameValue
1765                       << "\n");
1766     deleteExpression(E);
1767     return createVariableOrConstant(AllSameValue);
1768   }
1769   return E;
1770 }
1771 
1772 const Expression *
1773 NewGVN::performSymbolicAggrValueEvaluation(Instruction *I) const {
1774   if (auto *EI = dyn_cast<ExtractValueInst>(I)) {
1775     auto *WO = dyn_cast<WithOverflowInst>(EI->getAggregateOperand());
1776     if (WO && EI->getNumIndices() == 1 && *EI->idx_begin() == 0)
1777       // EI is an extract from one of our with.overflow intrinsics. Synthesize
1778       // a semantically equivalent expression instead of an extract value
1779       // expression.
1780       return createBinaryExpression(WO->getBinaryOp(), EI->getType(),
1781                                     WO->getLHS(), WO->getRHS(), I);
1782   }
1783 
1784   return createAggregateValueExpression(I);
1785 }
1786 
1787 const Expression *NewGVN::performSymbolicCmpEvaluation(Instruction *I) const {
1788   assert(isa<CmpInst>(I) && "Expected a cmp instruction.");
1789 
1790   auto *CI = cast<CmpInst>(I);
1791   // See if our operands are equal to those of a previous predicate, and if so,
1792   // if it implies true or false.
1793   auto Op0 = lookupOperandLeader(CI->getOperand(0));
1794   auto Op1 = lookupOperandLeader(CI->getOperand(1));
1795   auto OurPredicate = CI->getPredicate();
1796   if (shouldSwapOperands(Op0, Op1)) {
1797     std::swap(Op0, Op1);
1798     OurPredicate = CI->getSwappedPredicate();
1799   }
1800 
1801   // Avoid processing the same info twice.
1802   const PredicateBase *LastPredInfo = nullptr;
1803   // See if we know something about the comparison itself, like it is the target
1804   // of an assume.
1805   auto *CmpPI = PredInfo->getPredicateInfoFor(I);
1806   if (dyn_cast_or_null<PredicateAssume>(CmpPI))
1807     return createConstantExpression(ConstantInt::getTrue(CI->getType()));
1808 
1809   if (Op0 == Op1) {
1810     // This condition does not depend on predicates, no need to add users
1811     if (CI->isTrueWhenEqual())
1812       return createConstantExpression(ConstantInt::getTrue(CI->getType()));
1813     else if (CI->isFalseWhenEqual())
1814       return createConstantExpression(ConstantInt::getFalse(CI->getType()));
1815   }
1816 
1817   // NOTE: Because we are comparing both operands here and below, and using
1818   // previous comparisons, we rely on fact that predicateinfo knows to mark
1819   // comparisons that use renamed operands as users of the earlier comparisons.
1820   // It is *not* enough to just mark predicateinfo renamed operands as users of
1821   // the earlier comparisons, because the *other* operand may have changed in a
1822   // previous iteration.
1823   // Example:
1824   // icmp slt %a, %b
1825   // %b.0 = ssa.copy(%b)
1826   // false branch:
1827   // icmp slt %c, %b.0
1828 
1829   // %c and %a may start out equal, and thus, the code below will say the second
1830   // %icmp is false.  c may become equal to something else, and in that case the
1831   // %second icmp *must* be reexamined, but would not if only the renamed
1832   // %operands are considered users of the icmp.
1833 
1834   // *Currently* we only check one level of comparisons back, and only mark one
1835   // level back as touched when changes happen.  If you modify this code to look
1836   // back farther through comparisons, you *must* mark the appropriate
1837   // comparisons as users in PredicateInfo.cpp, or you will cause bugs.  See if
1838   // we know something just from the operands themselves
1839 
1840   // See if our operands have predicate info, so that we may be able to derive
1841   // something from a previous comparison.
1842   for (const auto &Op : CI->operands()) {
1843     auto *PI = PredInfo->getPredicateInfoFor(Op);
1844     if (const auto *PBranch = dyn_cast_or_null<PredicateBranch>(PI)) {
1845       if (PI == LastPredInfo)
1846         continue;
1847       LastPredInfo = PI;
1848       // In phi of ops cases, we may have predicate info that we are evaluating
1849       // in a different context.
1850       if (!DT->dominates(PBranch->To, getBlockForValue(I)))
1851         continue;
1852       // TODO: Along the false edge, we may know more things too, like
1853       // icmp of
1854       // same operands is false.
1855       // TODO: We only handle actual comparison conditions below, not
1856       // and/or.
1857       auto *BranchCond = dyn_cast<CmpInst>(PBranch->Condition);
1858       if (!BranchCond)
1859         continue;
1860       auto *BranchOp0 = lookupOperandLeader(BranchCond->getOperand(0));
1861       auto *BranchOp1 = lookupOperandLeader(BranchCond->getOperand(1));
1862       auto BranchPredicate = BranchCond->getPredicate();
1863       if (shouldSwapOperands(BranchOp0, BranchOp1)) {
1864         std::swap(BranchOp0, BranchOp1);
1865         BranchPredicate = BranchCond->getSwappedPredicate();
1866       }
1867       if (BranchOp0 == Op0 && BranchOp1 == Op1) {
1868         if (PBranch->TrueEdge) {
1869           // If we know the previous predicate is true and we are in the true
1870           // edge then we may be implied true or false.
1871           if (CmpInst::isImpliedTrueByMatchingCmp(BranchPredicate,
1872                                                   OurPredicate)) {
1873             addPredicateUsers(PI, I);
1874             return createConstantExpression(
1875                 ConstantInt::getTrue(CI->getType()));
1876           }
1877 
1878           if (CmpInst::isImpliedFalseByMatchingCmp(BranchPredicate,
1879                                                    OurPredicate)) {
1880             addPredicateUsers(PI, I);
1881             return createConstantExpression(
1882                 ConstantInt::getFalse(CI->getType()));
1883           }
1884         } else {
1885           // Just handle the ne and eq cases, where if we have the same
1886           // operands, we may know something.
1887           if (BranchPredicate == OurPredicate) {
1888             addPredicateUsers(PI, I);
1889             // Same predicate, same ops,we know it was false, so this is false.
1890             return createConstantExpression(
1891                 ConstantInt::getFalse(CI->getType()));
1892           } else if (BranchPredicate ==
1893                      CmpInst::getInversePredicate(OurPredicate)) {
1894             addPredicateUsers(PI, I);
1895             // Inverse predicate, we know the other was false, so this is true.
1896             return createConstantExpression(
1897                 ConstantInt::getTrue(CI->getType()));
1898           }
1899         }
1900       }
1901     }
1902   }
1903   // Create expression will take care of simplifyCmpInst
1904   return createExpression(I);
1905 }
1906 
1907 // Substitute and symbolize the value before value numbering.
1908 const Expression *
1909 NewGVN::performSymbolicEvaluation(Value *V,
1910                                   SmallPtrSetImpl<Value *> &Visited) const {
1911   const Expression *E = nullptr;
1912   if (auto *C = dyn_cast<Constant>(V))
1913     E = createConstantExpression(C);
1914   else if (isa<Argument>(V) || isa<GlobalVariable>(V)) {
1915     E = createVariableExpression(V);
1916   } else {
1917     // TODO: memory intrinsics.
1918     // TODO: Some day, we should do the forward propagation and reassociation
1919     // parts of the algorithm.
1920     auto *I = cast<Instruction>(V);
1921     switch (I->getOpcode()) {
1922     case Instruction::ExtractValue:
1923     case Instruction::InsertValue:
1924       E = performSymbolicAggrValueEvaluation(I);
1925       break;
1926     case Instruction::PHI: {
1927       SmallVector<ValPair, 3> Ops;
1928       auto *PN = cast<PHINode>(I);
1929       for (unsigned i = 0; i < PN->getNumOperands(); ++i)
1930         Ops.push_back({PN->getIncomingValue(i), PN->getIncomingBlock(i)});
1931       // Sort to ensure the invariant createPHIExpression requires is met.
1932       sortPHIOps(Ops);
1933       E = performSymbolicPHIEvaluation(Ops, I, getBlockForValue(I));
1934     } break;
1935     case Instruction::Call:
1936       E = performSymbolicCallEvaluation(I);
1937       break;
1938     case Instruction::Store:
1939       E = performSymbolicStoreEvaluation(I);
1940       break;
1941     case Instruction::Load:
1942       E = performSymbolicLoadEvaluation(I);
1943       break;
1944     case Instruction::BitCast:
1945     case Instruction::AddrSpaceCast:
1946       E = createExpression(I);
1947       break;
1948     case Instruction::ICmp:
1949     case Instruction::FCmp:
1950       E = performSymbolicCmpEvaluation(I);
1951       break;
1952     case Instruction::FNeg:
1953     case Instruction::Add:
1954     case Instruction::FAdd:
1955     case Instruction::Sub:
1956     case Instruction::FSub:
1957     case Instruction::Mul:
1958     case Instruction::FMul:
1959     case Instruction::UDiv:
1960     case Instruction::SDiv:
1961     case Instruction::FDiv:
1962     case Instruction::URem:
1963     case Instruction::SRem:
1964     case Instruction::FRem:
1965     case Instruction::Shl:
1966     case Instruction::LShr:
1967     case Instruction::AShr:
1968     case Instruction::And:
1969     case Instruction::Or:
1970     case Instruction::Xor:
1971     case Instruction::Trunc:
1972     case Instruction::ZExt:
1973     case Instruction::SExt:
1974     case Instruction::FPToUI:
1975     case Instruction::FPToSI:
1976     case Instruction::UIToFP:
1977     case Instruction::SIToFP:
1978     case Instruction::FPTrunc:
1979     case Instruction::FPExt:
1980     case Instruction::PtrToInt:
1981     case Instruction::IntToPtr:
1982     case Instruction::Select:
1983     case Instruction::ExtractElement:
1984     case Instruction::InsertElement:
1985     case Instruction::GetElementPtr:
1986       E = createExpression(I);
1987       break;
1988     case Instruction::ShuffleVector:
1989       // FIXME: Add support for shufflevector to createExpression.
1990       return nullptr;
1991     default:
1992       return nullptr;
1993     }
1994   }
1995   return E;
1996 }
1997 
1998 // Look up a container in a map, and then call a function for each thing in the
1999 // found container.
2000 template <typename Map, typename KeyType, typename Func>
2001 void NewGVN::for_each_found(Map &M, const KeyType &Key, Func F) {
2002   const auto Result = M.find_as(Key);
2003   if (Result != M.end())
2004     for (typename Map::mapped_type::value_type Mapped : Result->second)
2005       F(Mapped);
2006 }
2007 
2008 // Look up a container of values/instructions in a map, and touch all the
2009 // instructions in the container.  Then erase value from the map.
2010 template <typename Map, typename KeyType>
2011 void NewGVN::touchAndErase(Map &M, const KeyType &Key) {
2012   const auto Result = M.find_as(Key);
2013   if (Result != M.end()) {
2014     for (const typename Map::mapped_type::value_type Mapped : Result->second)
2015       TouchedInstructions.set(InstrToDFSNum(Mapped));
2016     M.erase(Result);
2017   }
2018 }
2019 
2020 void NewGVN::addAdditionalUsers(Value *To, Value *User) const {
2021   assert(User && To != User);
2022   if (isa<Instruction>(To))
2023     AdditionalUsers[To].insert(User);
2024 }
2025 
2026 void NewGVN::markUsersTouched(Value *V) {
2027   // Now mark the users as touched.
2028   for (auto *User : V->users()) {
2029     assert(isa<Instruction>(User) && "Use of value not within an instruction?");
2030     TouchedInstructions.set(InstrToDFSNum(User));
2031   }
2032   touchAndErase(AdditionalUsers, V);
2033 }
2034 
2035 void NewGVN::addMemoryUsers(const MemoryAccess *To, MemoryAccess *U) const {
2036   LLVM_DEBUG(dbgs() << "Adding memory user " << *U << " to " << *To << "\n");
2037   MemoryToUsers[To].insert(U);
2038 }
2039 
2040 void NewGVN::markMemoryDefTouched(const MemoryAccess *MA) {
2041   TouchedInstructions.set(MemoryToDFSNum(MA));
2042 }
2043 
2044 void NewGVN::markMemoryUsersTouched(const MemoryAccess *MA) {
2045   if (isa<MemoryUse>(MA))
2046     return;
2047   for (auto U : MA->users())
2048     TouchedInstructions.set(MemoryToDFSNum(U));
2049   touchAndErase(MemoryToUsers, MA);
2050 }
2051 
2052 // Add I to the set of users of a given predicate.
2053 void NewGVN::addPredicateUsers(const PredicateBase *PB, Instruction *I) const {
2054   // Don't add temporary instructions to the user lists.
2055   if (AllTempInstructions.count(I))
2056     return;
2057 
2058   if (auto *PBranch = dyn_cast<PredicateBranch>(PB))
2059     PredicateToUsers[PBranch->Condition].insert(I);
2060   else if (auto *PAssume = dyn_cast<PredicateAssume>(PB))
2061     PredicateToUsers[PAssume->Condition].insert(I);
2062 }
2063 
2064 // Touch all the predicates that depend on this instruction.
2065 void NewGVN::markPredicateUsersTouched(Instruction *I) {
2066   touchAndErase(PredicateToUsers, I);
2067 }
2068 
2069 // Mark users affected by a memory leader change.
2070 void NewGVN::markMemoryLeaderChangeTouched(CongruenceClass *CC) {
2071   for (auto M : CC->memory())
2072     markMemoryDefTouched(M);
2073 }
2074 
2075 // Touch the instructions that need to be updated after a congruence class has a
2076 // leader change, and mark changed values.
2077 void NewGVN::markValueLeaderChangeTouched(CongruenceClass *CC) {
2078   for (auto M : *CC) {
2079     if (auto *I = dyn_cast<Instruction>(M))
2080       TouchedInstructions.set(InstrToDFSNum(I));
2081     LeaderChanges.insert(M);
2082   }
2083 }
2084 
2085 // Give a range of things that have instruction DFS numbers, this will return
2086 // the member of the range with the smallest dfs number.
2087 template <class T, class Range>
2088 T *NewGVN::getMinDFSOfRange(const Range &R) const {
2089   std::pair<T *, unsigned> MinDFS = {nullptr, ~0U};
2090   for (const auto X : R) {
2091     auto DFSNum = InstrToDFSNum(X);
2092     if (DFSNum < MinDFS.second)
2093       MinDFS = {X, DFSNum};
2094   }
2095   return MinDFS.first;
2096 }
2097 
2098 // This function returns the MemoryAccess that should be the next leader of
2099 // congruence class CC, under the assumption that the current leader is going to
2100 // disappear.
2101 const MemoryAccess *NewGVN::getNextMemoryLeader(CongruenceClass *CC) const {
2102   // TODO: If this ends up to slow, we can maintain a next memory leader like we
2103   // do for regular leaders.
2104   // Make sure there will be a leader to find.
2105   assert(!CC->definesNoMemory() && "Can't get next leader if there is none");
2106   if (CC->getStoreCount() > 0) {
2107     if (auto *NL = dyn_cast_or_null<StoreInst>(CC->getNextLeader().first))
2108       return getMemoryAccess(NL);
2109     // Find the store with the minimum DFS number.
2110     auto *V = getMinDFSOfRange<Value>(make_filter_range(
2111         *CC, [&](const Value *V) { return isa<StoreInst>(V); }));
2112     return getMemoryAccess(cast<StoreInst>(V));
2113   }
2114   assert(CC->getStoreCount() == 0);
2115 
2116   // Given our assertion, hitting this part must mean
2117   // !OldClass->memory_empty()
2118   if (CC->memory_size() == 1)
2119     return *CC->memory_begin();
2120   return getMinDFSOfRange<const MemoryPhi>(CC->memory());
2121 }
2122 
2123 // This function returns the next value leader of a congruence class, under the
2124 // assumption that the current leader is going away.  This should end up being
2125 // the next most dominating member.
2126 Value *NewGVN::getNextValueLeader(CongruenceClass *CC) const {
2127   // We don't need to sort members if there is only 1, and we don't care about
2128   // sorting the TOP class because everything either gets out of it or is
2129   // unreachable.
2130 
2131   if (CC->size() == 1 || CC == TOPClass) {
2132     return *(CC->begin());
2133   } else if (CC->getNextLeader().first) {
2134     ++NumGVNAvoidedSortedLeaderChanges;
2135     return CC->getNextLeader().first;
2136   } else {
2137     ++NumGVNSortedLeaderChanges;
2138     // NOTE: If this ends up to slow, we can maintain a dual structure for
2139     // member testing/insertion, or keep things mostly sorted, and sort only
2140     // here, or use SparseBitVector or ....
2141     return getMinDFSOfRange<Value>(*CC);
2142   }
2143 }
2144 
2145 // Move a MemoryAccess, currently in OldClass, to NewClass, including updates to
2146 // the memory members, etc for the move.
2147 //
2148 // The invariants of this function are:
2149 //
2150 // - I must be moving to NewClass from OldClass
2151 // - The StoreCount of OldClass and NewClass is expected to have been updated
2152 //   for I already if it is a store.
2153 // - The OldClass memory leader has not been updated yet if I was the leader.
2154 void NewGVN::moveMemoryToNewCongruenceClass(Instruction *I,
2155                                             MemoryAccess *InstMA,
2156                                             CongruenceClass *OldClass,
2157                                             CongruenceClass *NewClass) {
2158   // If the leader is I, and we had a representative MemoryAccess, it should
2159   // be the MemoryAccess of OldClass.
2160   assert((!InstMA || !OldClass->getMemoryLeader() ||
2161           OldClass->getLeader() != I ||
2162           MemoryAccessToClass.lookup(OldClass->getMemoryLeader()) ==
2163               MemoryAccessToClass.lookup(InstMA)) &&
2164          "Representative MemoryAccess mismatch");
2165   // First, see what happens to the new class
2166   if (!NewClass->getMemoryLeader()) {
2167     // Should be a new class, or a store becoming a leader of a new class.
2168     assert(NewClass->size() == 1 ||
2169            (isa<StoreInst>(I) && NewClass->getStoreCount() == 1));
2170     NewClass->setMemoryLeader(InstMA);
2171     // Mark it touched if we didn't just create a singleton
2172     LLVM_DEBUG(dbgs() << "Memory class leader change for class "
2173                       << NewClass->getID()
2174                       << " due to new memory instruction becoming leader\n");
2175     markMemoryLeaderChangeTouched(NewClass);
2176   }
2177   setMemoryClass(InstMA, NewClass);
2178   // Now, fixup the old class if necessary
2179   if (OldClass->getMemoryLeader() == InstMA) {
2180     if (!OldClass->definesNoMemory()) {
2181       OldClass->setMemoryLeader(getNextMemoryLeader(OldClass));
2182       LLVM_DEBUG(dbgs() << "Memory class leader change for class "
2183                         << OldClass->getID() << " to "
2184                         << *OldClass->getMemoryLeader()
2185                         << " due to removal of old leader " << *InstMA << "\n");
2186       markMemoryLeaderChangeTouched(OldClass);
2187     } else
2188       OldClass->setMemoryLeader(nullptr);
2189   }
2190 }
2191 
2192 // Move a value, currently in OldClass, to be part of NewClass
2193 // Update OldClass and NewClass for the move (including changing leaders, etc).
2194 void NewGVN::moveValueToNewCongruenceClass(Instruction *I, const Expression *E,
2195                                            CongruenceClass *OldClass,
2196                                            CongruenceClass *NewClass) {
2197   if (I == OldClass->getNextLeader().first)
2198     OldClass->resetNextLeader();
2199 
2200   OldClass->erase(I);
2201   NewClass->insert(I);
2202 
2203   if (NewClass->getLeader() != I)
2204     NewClass->addPossibleNextLeader({I, InstrToDFSNum(I)});
2205   // Handle our special casing of stores.
2206   if (auto *SI = dyn_cast<StoreInst>(I)) {
2207     OldClass->decStoreCount();
2208     // Okay, so when do we want to make a store a leader of a class?
2209     // If we have a store defined by an earlier load, we want the earlier load
2210     // to lead the class.
2211     // If we have a store defined by something else, we want the store to lead
2212     // the class so everything else gets the "something else" as a value.
2213     // If we have a store as the single member of the class, we want the store
2214     // as the leader
2215     if (NewClass->getStoreCount() == 0 && !NewClass->getStoredValue()) {
2216       // If it's a store expression we are using, it means we are not equivalent
2217       // to something earlier.
2218       if (auto *SE = dyn_cast<StoreExpression>(E)) {
2219         NewClass->setStoredValue(SE->getStoredValue());
2220         markValueLeaderChangeTouched(NewClass);
2221         // Shift the new class leader to be the store
2222         LLVM_DEBUG(dbgs() << "Changing leader of congruence class "
2223                           << NewClass->getID() << " from "
2224                           << *NewClass->getLeader() << " to  " << *SI
2225                           << " because store joined class\n");
2226         // If we changed the leader, we have to mark it changed because we don't
2227         // know what it will do to symbolic evaluation.
2228         NewClass->setLeader(SI);
2229       }
2230       // We rely on the code below handling the MemoryAccess change.
2231     }
2232     NewClass->incStoreCount();
2233   }
2234   // True if there is no memory instructions left in a class that had memory
2235   // instructions before.
2236 
2237   // If it's not a memory use, set the MemoryAccess equivalence
2238   auto *InstMA = dyn_cast_or_null<MemoryDef>(getMemoryAccess(I));
2239   if (InstMA)
2240     moveMemoryToNewCongruenceClass(I, InstMA, OldClass, NewClass);
2241   ValueToClass[I] = NewClass;
2242   // See if we destroyed the class or need to swap leaders.
2243   if (OldClass->empty() && OldClass != TOPClass) {
2244     if (OldClass->getDefiningExpr()) {
2245       LLVM_DEBUG(dbgs() << "Erasing expression " << *OldClass->getDefiningExpr()
2246                         << " from table\n");
2247       // We erase it as an exact expression to make sure we don't just erase an
2248       // equivalent one.
2249       auto Iter = ExpressionToClass.find_as(
2250           ExactEqualsExpression(*OldClass->getDefiningExpr()));
2251       if (Iter != ExpressionToClass.end())
2252         ExpressionToClass.erase(Iter);
2253 #ifdef EXPENSIVE_CHECKS
2254       assert(
2255           (*OldClass->getDefiningExpr() != *E || ExpressionToClass.lookup(E)) &&
2256           "We erased the expression we just inserted, which should not happen");
2257 #endif
2258     }
2259   } else if (OldClass->getLeader() == I) {
2260     // When the leader changes, the value numbering of
2261     // everything may change due to symbolization changes, so we need to
2262     // reprocess.
2263     LLVM_DEBUG(dbgs() << "Value class leader change for class "
2264                       << OldClass->getID() << "\n");
2265     ++NumGVNLeaderChanges;
2266     // Destroy the stored value if there are no more stores to represent it.
2267     // Note that this is basically clean up for the expression removal that
2268     // happens below.  If we remove stores from a class, we may leave it as a
2269     // class of equivalent memory phis.
2270     if (OldClass->getStoreCount() == 0) {
2271       if (OldClass->getStoredValue())
2272         OldClass->setStoredValue(nullptr);
2273     }
2274     OldClass->setLeader(getNextValueLeader(OldClass));
2275     OldClass->resetNextLeader();
2276     markValueLeaderChangeTouched(OldClass);
2277   }
2278 }
2279 
2280 // For a given expression, mark the phi of ops instructions that could have
2281 // changed as a result.
2282 void NewGVN::markPhiOfOpsChanged(const Expression *E) {
2283   touchAndErase(ExpressionToPhiOfOps, E);
2284 }
2285 
2286 // Perform congruence finding on a given value numbering expression.
2287 void NewGVN::performCongruenceFinding(Instruction *I, const Expression *E) {
2288   // This is guaranteed to return something, since it will at least find
2289   // TOP.
2290 
2291   CongruenceClass *IClass = ValueToClass.lookup(I);
2292   assert(IClass && "Should have found a IClass");
2293   // Dead classes should have been eliminated from the mapping.
2294   assert(!IClass->isDead() && "Found a dead class");
2295 
2296   CongruenceClass *EClass = nullptr;
2297   if (const auto *VE = dyn_cast<VariableExpression>(E)) {
2298     EClass = ValueToClass.lookup(VE->getVariableValue());
2299   } else if (isa<DeadExpression>(E)) {
2300     EClass = TOPClass;
2301   }
2302   if (!EClass) {
2303     auto lookupResult = ExpressionToClass.insert({E, nullptr});
2304 
2305     // If it's not in the value table, create a new congruence class.
2306     if (lookupResult.second) {
2307       CongruenceClass *NewClass = createCongruenceClass(nullptr, E);
2308       auto place = lookupResult.first;
2309       place->second = NewClass;
2310 
2311       // Constants and variables should always be made the leader.
2312       if (const auto *CE = dyn_cast<ConstantExpression>(E)) {
2313         NewClass->setLeader(CE->getConstantValue());
2314       } else if (const auto *SE = dyn_cast<StoreExpression>(E)) {
2315         StoreInst *SI = SE->getStoreInst();
2316         NewClass->setLeader(SI);
2317         NewClass->setStoredValue(SE->getStoredValue());
2318         // The RepMemoryAccess field will be filled in properly by the
2319         // moveValueToNewCongruenceClass call.
2320       } else {
2321         NewClass->setLeader(I);
2322       }
2323       assert(!isa<VariableExpression>(E) &&
2324              "VariableExpression should have been handled already");
2325 
2326       EClass = NewClass;
2327       LLVM_DEBUG(dbgs() << "Created new congruence class for " << *I
2328                         << " using expression " << *E << " at "
2329                         << NewClass->getID() << " and leader "
2330                         << *(NewClass->getLeader()));
2331       if (NewClass->getStoredValue())
2332         LLVM_DEBUG(dbgs() << " and stored value "
2333                           << *(NewClass->getStoredValue()));
2334       LLVM_DEBUG(dbgs() << "\n");
2335     } else {
2336       EClass = lookupResult.first->second;
2337       if (isa<ConstantExpression>(E))
2338         assert((isa<Constant>(EClass->getLeader()) ||
2339                 (EClass->getStoredValue() &&
2340                  isa<Constant>(EClass->getStoredValue()))) &&
2341                "Any class with a constant expression should have a "
2342                "constant leader");
2343 
2344       assert(EClass && "Somehow don't have an eclass");
2345 
2346       assert(!EClass->isDead() && "We accidentally looked up a dead class");
2347     }
2348   }
2349   bool ClassChanged = IClass != EClass;
2350   bool LeaderChanged = LeaderChanges.erase(I);
2351   if (ClassChanged || LeaderChanged) {
2352     LLVM_DEBUG(dbgs() << "New class " << EClass->getID() << " for expression "
2353                       << *E << "\n");
2354     if (ClassChanged) {
2355       moveValueToNewCongruenceClass(I, E, IClass, EClass);
2356       markPhiOfOpsChanged(E);
2357     }
2358 
2359     markUsersTouched(I);
2360     if (MemoryAccess *MA = getMemoryAccess(I))
2361       markMemoryUsersTouched(MA);
2362     if (auto *CI = dyn_cast<CmpInst>(I))
2363       markPredicateUsersTouched(CI);
2364   }
2365   // If we changed the class of the store, we want to ensure nothing finds the
2366   // old store expression.  In particular, loads do not compare against stored
2367   // value, so they will find old store expressions (and associated class
2368   // mappings) if we leave them in the table.
2369   if (ClassChanged && isa<StoreInst>(I)) {
2370     auto *OldE = ValueToExpression.lookup(I);
2371     // It could just be that the old class died. We don't want to erase it if we
2372     // just moved classes.
2373     if (OldE && isa<StoreExpression>(OldE) && *E != *OldE) {
2374       // Erase this as an exact expression to ensure we don't erase expressions
2375       // equivalent to it.
2376       auto Iter = ExpressionToClass.find_as(ExactEqualsExpression(*OldE));
2377       if (Iter != ExpressionToClass.end())
2378         ExpressionToClass.erase(Iter);
2379     }
2380   }
2381   ValueToExpression[I] = E;
2382 }
2383 
2384 // Process the fact that Edge (from, to) is reachable, including marking
2385 // any newly reachable blocks and instructions for processing.
2386 void NewGVN::updateReachableEdge(BasicBlock *From, BasicBlock *To) {
2387   // Check if the Edge was reachable before.
2388   if (ReachableEdges.insert({From, To}).second) {
2389     // If this block wasn't reachable before, all instructions are touched.
2390     if (ReachableBlocks.insert(To).second) {
2391       LLVM_DEBUG(dbgs() << "Block " << getBlockName(To)
2392                         << " marked reachable\n");
2393       const auto &InstRange = BlockInstRange.lookup(To);
2394       TouchedInstructions.set(InstRange.first, InstRange.second);
2395     } else {
2396       LLVM_DEBUG(dbgs() << "Block " << getBlockName(To)
2397                         << " was reachable, but new edge {"
2398                         << getBlockName(From) << "," << getBlockName(To)
2399                         << "} to it found\n");
2400 
2401       // We've made an edge reachable to an existing block, which may
2402       // impact predicates. Otherwise, only mark the phi nodes as touched, as
2403       // they are the only thing that depend on new edges. Anything using their
2404       // values will get propagated to if necessary.
2405       if (MemoryAccess *MemPhi = getMemoryAccess(To))
2406         TouchedInstructions.set(InstrToDFSNum(MemPhi));
2407 
2408       // FIXME: We should just add a union op on a Bitvector and
2409       // SparseBitVector.  We can do it word by word faster than we are doing it
2410       // here.
2411       for (auto InstNum : RevisitOnReachabilityChange[To])
2412         TouchedInstructions.set(InstNum);
2413     }
2414   }
2415 }
2416 
2417 // Given a predicate condition (from a switch, cmp, or whatever) and a block,
2418 // see if we know some constant value for it already.
2419 Value *NewGVN::findConditionEquivalence(Value *Cond) const {
2420   auto Result = lookupOperandLeader(Cond);
2421   return isa<Constant>(Result) ? Result : nullptr;
2422 }
2423 
2424 // Process the outgoing edges of a block for reachability.
2425 void NewGVN::processOutgoingEdges(Instruction *TI, BasicBlock *B) {
2426   // Evaluate reachability of terminator instruction.
2427   Value *Cond;
2428   BasicBlock *TrueSucc, *FalseSucc;
2429   if (match(TI, m_Br(m_Value(Cond), TrueSucc, FalseSucc))) {
2430     Value *CondEvaluated = findConditionEquivalence(Cond);
2431     if (!CondEvaluated) {
2432       if (auto *I = dyn_cast<Instruction>(Cond)) {
2433         const Expression *E = createExpression(I);
2434         if (const auto *CE = dyn_cast<ConstantExpression>(E)) {
2435           CondEvaluated = CE->getConstantValue();
2436         }
2437       } else if (isa<ConstantInt>(Cond)) {
2438         CondEvaluated = Cond;
2439       }
2440     }
2441     ConstantInt *CI;
2442     if (CondEvaluated && (CI = dyn_cast<ConstantInt>(CondEvaluated))) {
2443       if (CI->isOne()) {
2444         LLVM_DEBUG(dbgs() << "Condition for Terminator " << *TI
2445                           << " evaluated to true\n");
2446         updateReachableEdge(B, TrueSucc);
2447       } else if (CI->isZero()) {
2448         LLVM_DEBUG(dbgs() << "Condition for Terminator " << *TI
2449                           << " evaluated to false\n");
2450         updateReachableEdge(B, FalseSucc);
2451       }
2452     } else {
2453       updateReachableEdge(B, TrueSucc);
2454       updateReachableEdge(B, FalseSucc);
2455     }
2456   } else if (auto *SI = dyn_cast<SwitchInst>(TI)) {
2457     // For switches, propagate the case values into the case
2458     // destinations.
2459 
2460     Value *SwitchCond = SI->getCondition();
2461     Value *CondEvaluated = findConditionEquivalence(SwitchCond);
2462     // See if we were able to turn this switch statement into a constant.
2463     if (CondEvaluated && isa<ConstantInt>(CondEvaluated)) {
2464       auto *CondVal = cast<ConstantInt>(CondEvaluated);
2465       // We should be able to get case value for this.
2466       auto Case = *SI->findCaseValue(CondVal);
2467       if (Case.getCaseSuccessor() == SI->getDefaultDest()) {
2468         // We proved the value is outside of the range of the case.
2469         // We can't do anything other than mark the default dest as reachable,
2470         // and go home.
2471         updateReachableEdge(B, SI->getDefaultDest());
2472         return;
2473       }
2474       // Now get where it goes and mark it reachable.
2475       BasicBlock *TargetBlock = Case.getCaseSuccessor();
2476       updateReachableEdge(B, TargetBlock);
2477     } else {
2478       for (unsigned i = 0, e = SI->getNumSuccessors(); i != e; ++i) {
2479         BasicBlock *TargetBlock = SI->getSuccessor(i);
2480         updateReachableEdge(B, TargetBlock);
2481       }
2482     }
2483   } else {
2484     // Otherwise this is either unconditional, or a type we have no
2485     // idea about. Just mark successors as reachable.
2486     for (unsigned i = 0, e = TI->getNumSuccessors(); i != e; ++i) {
2487       BasicBlock *TargetBlock = TI->getSuccessor(i);
2488       updateReachableEdge(B, TargetBlock);
2489     }
2490 
2491     // This also may be a memory defining terminator, in which case, set it
2492     // equivalent only to itself.
2493     //
2494     auto *MA = getMemoryAccess(TI);
2495     if (MA && !isa<MemoryUse>(MA)) {
2496       auto *CC = ensureLeaderOfMemoryClass(MA);
2497       if (setMemoryClass(MA, CC))
2498         markMemoryUsersTouched(MA);
2499     }
2500   }
2501 }
2502 
2503 // Remove the PHI of Ops PHI for I
2504 void NewGVN::removePhiOfOps(Instruction *I, PHINode *PHITemp) {
2505   InstrDFS.erase(PHITemp);
2506   // It's still a temp instruction. We keep it in the array so it gets erased.
2507   // However, it's no longer used by I, or in the block
2508   TempToBlock.erase(PHITemp);
2509   RealToTemp.erase(I);
2510   // We don't remove the users from the phi node uses. This wastes a little
2511   // time, but such is life.  We could use two sets to track which were there
2512   // are the start of NewGVN, and which were added, but right nowt he cost of
2513   // tracking is more than the cost of checking for more phi of ops.
2514 }
2515 
2516 // Add PHI Op in BB as a PHI of operations version of ExistingValue.
2517 void NewGVN::addPhiOfOps(PHINode *Op, BasicBlock *BB,
2518                          Instruction *ExistingValue) {
2519   InstrDFS[Op] = InstrToDFSNum(ExistingValue);
2520   AllTempInstructions.insert(Op);
2521   TempToBlock[Op] = BB;
2522   RealToTemp[ExistingValue] = Op;
2523   // Add all users to phi node use, as they are now uses of the phi of ops phis
2524   // and may themselves be phi of ops.
2525   for (auto *U : ExistingValue->users())
2526     if (auto *UI = dyn_cast<Instruction>(U))
2527       PHINodeUses.insert(UI);
2528 }
2529 
2530 static bool okayForPHIOfOps(const Instruction *I) {
2531   if (!EnablePhiOfOps)
2532     return false;
2533   return isa<BinaryOperator>(I) || isa<SelectInst>(I) || isa<CmpInst>(I) ||
2534          isa<LoadInst>(I);
2535 }
2536 
2537 bool NewGVN::OpIsSafeForPHIOfOpsHelper(
2538     Value *V, const BasicBlock *PHIBlock,
2539     SmallPtrSetImpl<const Value *> &Visited,
2540     SmallVectorImpl<Instruction *> &Worklist) {
2541 
2542   if (!isa<Instruction>(V))
2543     return true;
2544   auto OISIt = OpSafeForPHIOfOps.find(V);
2545   if (OISIt != OpSafeForPHIOfOps.end())
2546     return OISIt->second;
2547 
2548   // Keep walking until we either dominate the phi block, or hit a phi, or run
2549   // out of things to check.
2550   if (DT->properlyDominates(getBlockForValue(V), PHIBlock)) {
2551     OpSafeForPHIOfOps.insert({V, true});
2552     return true;
2553   }
2554   // PHI in the same block.
2555   if (isa<PHINode>(V) && getBlockForValue(V) == PHIBlock) {
2556     OpSafeForPHIOfOps.insert({V, false});
2557     return false;
2558   }
2559 
2560   auto *OrigI = cast<Instruction>(V);
2561   for (auto *Op : OrigI->operand_values()) {
2562     if (!isa<Instruction>(Op))
2563       continue;
2564     // Stop now if we find an unsafe operand.
2565     auto OISIt = OpSafeForPHIOfOps.find(OrigI);
2566     if (OISIt != OpSafeForPHIOfOps.end()) {
2567       if (!OISIt->second) {
2568         OpSafeForPHIOfOps.insert({V, false});
2569         return false;
2570       }
2571       continue;
2572     }
2573     if (!Visited.insert(Op).second)
2574       continue;
2575     Worklist.push_back(cast<Instruction>(Op));
2576   }
2577   return true;
2578 }
2579 
2580 // Return true if this operand will be safe to use for phi of ops.
2581 //
2582 // The reason some operands are unsafe is that we are not trying to recursively
2583 // translate everything back through phi nodes.  We actually expect some lookups
2584 // of expressions to fail.  In particular, a lookup where the expression cannot
2585 // exist in the predecessor.  This is true even if the expression, as shown, can
2586 // be determined to be constant.
2587 bool NewGVN::OpIsSafeForPHIOfOps(Value *V, const BasicBlock *PHIBlock,
2588                                  SmallPtrSetImpl<const Value *> &Visited) {
2589   SmallVector<Instruction *, 4> Worklist;
2590   if (!OpIsSafeForPHIOfOpsHelper(V, PHIBlock, Visited, Worklist))
2591     return false;
2592   while (!Worklist.empty()) {
2593     auto *I = Worklist.pop_back_val();
2594     if (!OpIsSafeForPHIOfOpsHelper(I, PHIBlock, Visited, Worklist))
2595       return false;
2596   }
2597   OpSafeForPHIOfOps.insert({V, true});
2598   return true;
2599 }
2600 
2601 // Try to find a leader for instruction TransInst, which is a phi translated
2602 // version of something in our original program.  Visited is used to ensure we
2603 // don't infinite loop during translations of cycles.  OrigInst is the
2604 // instruction in the original program, and PredBB is the predecessor we
2605 // translated it through.
2606 Value *NewGVN::findLeaderForInst(Instruction *TransInst,
2607                                  SmallPtrSetImpl<Value *> &Visited,
2608                                  MemoryAccess *MemAccess, Instruction *OrigInst,
2609                                  BasicBlock *PredBB) {
2610   unsigned IDFSNum = InstrToDFSNum(OrigInst);
2611   // Make sure it's marked as a temporary instruction.
2612   AllTempInstructions.insert(TransInst);
2613   // and make sure anything that tries to add it's DFS number is
2614   // redirected to the instruction we are making a phi of ops
2615   // for.
2616   TempToBlock.insert({TransInst, PredBB});
2617   InstrDFS.insert({TransInst, IDFSNum});
2618 
2619   const Expression *E = performSymbolicEvaluation(TransInst, Visited);
2620   InstrDFS.erase(TransInst);
2621   AllTempInstructions.erase(TransInst);
2622   TempToBlock.erase(TransInst);
2623   if (MemAccess)
2624     TempToMemory.erase(TransInst);
2625   if (!E)
2626     return nullptr;
2627   auto *FoundVal = findPHIOfOpsLeader(E, OrigInst, PredBB);
2628   if (!FoundVal) {
2629     ExpressionToPhiOfOps[E].insert(OrigInst);
2630     LLVM_DEBUG(dbgs() << "Cannot find phi of ops operand for " << *TransInst
2631                       << " in block " << getBlockName(PredBB) << "\n");
2632     return nullptr;
2633   }
2634   if (auto *SI = dyn_cast<StoreInst>(FoundVal))
2635     FoundVal = SI->getValueOperand();
2636   return FoundVal;
2637 }
2638 
2639 // When we see an instruction that is an op of phis, generate the equivalent phi
2640 // of ops form.
2641 const Expression *
2642 NewGVN::makePossiblePHIOfOps(Instruction *I,
2643                              SmallPtrSetImpl<Value *> &Visited) {
2644   if (!okayForPHIOfOps(I))
2645     return nullptr;
2646 
2647   if (!Visited.insert(I).second)
2648     return nullptr;
2649   // For now, we require the instruction be cycle free because we don't
2650   // *always* create a phi of ops for instructions that could be done as phi
2651   // of ops, we only do it if we think it is useful.  If we did do it all the
2652   // time, we could remove the cycle free check.
2653   if (!isCycleFree(I))
2654     return nullptr;
2655 
2656   SmallPtrSet<const Value *, 8> ProcessedPHIs;
2657   // TODO: We don't do phi translation on memory accesses because it's
2658   // complicated. For a load, we'd need to be able to simulate a new memoryuse,
2659   // which we don't have a good way of doing ATM.
2660   auto *MemAccess = getMemoryAccess(I);
2661   // If the memory operation is defined by a memory operation this block that
2662   // isn't a MemoryPhi, transforming the pointer backwards through a scalar phi
2663   // can't help, as it would still be killed by that memory operation.
2664   if (MemAccess && !isa<MemoryPhi>(MemAccess->getDefiningAccess()) &&
2665       MemAccess->getDefiningAccess()->getBlock() == I->getParent())
2666     return nullptr;
2667 
2668   // Convert op of phis to phi of ops
2669   SmallPtrSet<const Value *, 10> VisitedOps;
2670   SmallVector<Value *, 4> Ops(I->operand_values());
2671   BasicBlock *SamePHIBlock = nullptr;
2672   PHINode *OpPHI = nullptr;
2673   if (!DebugCounter::shouldExecute(PHIOfOpsCounter))
2674     return nullptr;
2675   for (auto *Op : Ops) {
2676     if (!isa<PHINode>(Op)) {
2677       auto *ValuePHI = RealToTemp.lookup(Op);
2678       if (!ValuePHI)
2679         continue;
2680       LLVM_DEBUG(dbgs() << "Found possible dependent phi of ops\n");
2681       Op = ValuePHI;
2682     }
2683     OpPHI = cast<PHINode>(Op);
2684     if (!SamePHIBlock) {
2685       SamePHIBlock = getBlockForValue(OpPHI);
2686     } else if (SamePHIBlock != getBlockForValue(OpPHI)) {
2687       LLVM_DEBUG(
2688           dbgs()
2689           << "PHIs for operands are not all in the same block, aborting\n");
2690       return nullptr;
2691     }
2692     // No point in doing this for one-operand phis.
2693     if (OpPHI->getNumOperands() == 1) {
2694       OpPHI = nullptr;
2695       continue;
2696     }
2697   }
2698 
2699   if (!OpPHI)
2700     return nullptr;
2701 
2702   SmallVector<ValPair, 4> PHIOps;
2703   SmallPtrSet<Value *, 4> Deps;
2704   auto *PHIBlock = getBlockForValue(OpPHI);
2705   RevisitOnReachabilityChange[PHIBlock].reset(InstrToDFSNum(I));
2706   for (unsigned PredNum = 0; PredNum < OpPHI->getNumOperands(); ++PredNum) {
2707     auto *PredBB = OpPHI->getIncomingBlock(PredNum);
2708     Value *FoundVal = nullptr;
2709     SmallPtrSet<Value *, 4> CurrentDeps;
2710     // We could just skip unreachable edges entirely but it's tricky to do
2711     // with rewriting existing phi nodes.
2712     if (ReachableEdges.count({PredBB, PHIBlock})) {
2713       // Clone the instruction, create an expression from it that is
2714       // translated back into the predecessor, and see if we have a leader.
2715       Instruction *ValueOp = I->clone();
2716       if (MemAccess)
2717         TempToMemory.insert({ValueOp, MemAccess});
2718       bool SafeForPHIOfOps = true;
2719       VisitedOps.clear();
2720       for (auto &Op : ValueOp->operands()) {
2721         auto *OrigOp = &*Op;
2722         // When these operand changes, it could change whether there is a
2723         // leader for us or not, so we have to add additional users.
2724         if (isa<PHINode>(Op)) {
2725           Op = Op->DoPHITranslation(PHIBlock, PredBB);
2726           if (Op != OrigOp && Op != I)
2727             CurrentDeps.insert(Op);
2728         } else if (auto *ValuePHI = RealToTemp.lookup(Op)) {
2729           if (getBlockForValue(ValuePHI) == PHIBlock)
2730             Op = ValuePHI->getIncomingValueForBlock(PredBB);
2731         }
2732         // If we phi-translated the op, it must be safe.
2733         SafeForPHIOfOps =
2734             SafeForPHIOfOps &&
2735             (Op != OrigOp || OpIsSafeForPHIOfOps(Op, PHIBlock, VisitedOps));
2736       }
2737       // FIXME: For those things that are not safe we could generate
2738       // expressions all the way down, and see if this comes out to a
2739       // constant.  For anything where that is true, and unsafe, we should
2740       // have made a phi-of-ops (or value numbered it equivalent to something)
2741       // for the pieces already.
2742       FoundVal = !SafeForPHIOfOps ? nullptr
2743                                   : findLeaderForInst(ValueOp, Visited,
2744                                                       MemAccess, I, PredBB);
2745       ValueOp->deleteValue();
2746       if (!FoundVal) {
2747         // We failed to find a leader for the current ValueOp, but this might
2748         // change in case of the translated operands change.
2749         if (SafeForPHIOfOps)
2750           for (auto Dep : CurrentDeps)
2751             addAdditionalUsers(Dep, I);
2752 
2753         return nullptr;
2754       }
2755       Deps.insert(CurrentDeps.begin(), CurrentDeps.end());
2756     } else {
2757       LLVM_DEBUG(dbgs() << "Skipping phi of ops operand for incoming block "
2758                         << getBlockName(PredBB)
2759                         << " because the block is unreachable\n");
2760       FoundVal = UndefValue::get(I->getType());
2761       RevisitOnReachabilityChange[PHIBlock].set(InstrToDFSNum(I));
2762     }
2763 
2764     PHIOps.push_back({FoundVal, PredBB});
2765     LLVM_DEBUG(dbgs() << "Found phi of ops operand " << *FoundVal << " in "
2766                       << getBlockName(PredBB) << "\n");
2767   }
2768   for (auto Dep : Deps)
2769     addAdditionalUsers(Dep, I);
2770   sortPHIOps(PHIOps);
2771   auto *E = performSymbolicPHIEvaluation(PHIOps, I, PHIBlock);
2772   if (isa<ConstantExpression>(E) || isa<VariableExpression>(E)) {
2773     LLVM_DEBUG(
2774         dbgs()
2775         << "Not creating real PHI of ops because it simplified to existing "
2776            "value or constant\n");
2777     return E;
2778   }
2779   auto *ValuePHI = RealToTemp.lookup(I);
2780   bool NewPHI = false;
2781   if (!ValuePHI) {
2782     ValuePHI =
2783         PHINode::Create(I->getType(), OpPHI->getNumOperands(), "phiofops");
2784     addPhiOfOps(ValuePHI, PHIBlock, I);
2785     NewPHI = true;
2786     NumGVNPHIOfOpsCreated++;
2787   }
2788   if (NewPHI) {
2789     for (auto PHIOp : PHIOps)
2790       ValuePHI->addIncoming(PHIOp.first, PHIOp.second);
2791   } else {
2792     TempToBlock[ValuePHI] = PHIBlock;
2793     unsigned int i = 0;
2794     for (auto PHIOp : PHIOps) {
2795       ValuePHI->setIncomingValue(i, PHIOp.first);
2796       ValuePHI->setIncomingBlock(i, PHIOp.second);
2797       ++i;
2798     }
2799   }
2800   RevisitOnReachabilityChange[PHIBlock].set(InstrToDFSNum(I));
2801   LLVM_DEBUG(dbgs() << "Created phi of ops " << *ValuePHI << " for " << *I
2802                     << "\n");
2803 
2804   return E;
2805 }
2806 
2807 // The algorithm initially places the values of the routine in the TOP
2808 // congruence class. The leader of TOP is the undetermined value `undef`.
2809 // When the algorithm has finished, values still in TOP are unreachable.
2810 void NewGVN::initializeCongruenceClasses(Function &F) {
2811   NextCongruenceNum = 0;
2812 
2813   // Note that even though we use the live on entry def as a representative
2814   // MemoryAccess, it is *not* the same as the actual live on entry def. We
2815   // have no real equivalemnt to undef for MemoryAccesses, and so we really
2816   // should be checking whether the MemoryAccess is top if we want to know if it
2817   // is equivalent to everything.  Otherwise, what this really signifies is that
2818   // the access "it reaches all the way back to the beginning of the function"
2819 
2820   // Initialize all other instructions to be in TOP class.
2821   TOPClass = createCongruenceClass(nullptr, nullptr);
2822   TOPClass->setMemoryLeader(MSSA->getLiveOnEntryDef());
2823   //  The live on entry def gets put into it's own class
2824   MemoryAccessToClass[MSSA->getLiveOnEntryDef()] =
2825       createMemoryClass(MSSA->getLiveOnEntryDef());
2826 
2827   for (auto DTN : nodes(DT)) {
2828     BasicBlock *BB = DTN->getBlock();
2829     // All MemoryAccesses are equivalent to live on entry to start. They must
2830     // be initialized to something so that initial changes are noticed. For
2831     // the maximal answer, we initialize them all to be the same as
2832     // liveOnEntry.
2833     auto *MemoryBlockDefs = MSSA->getBlockDefs(BB);
2834     if (MemoryBlockDefs)
2835       for (const auto &Def : *MemoryBlockDefs) {
2836         MemoryAccessToClass[&Def] = TOPClass;
2837         auto *MD = dyn_cast<MemoryDef>(&Def);
2838         // Insert the memory phis into the member list.
2839         if (!MD) {
2840           const MemoryPhi *MP = cast<MemoryPhi>(&Def);
2841           TOPClass->memory_insert(MP);
2842           MemoryPhiState.insert({MP, MPS_TOP});
2843         }
2844 
2845         if (MD && isa<StoreInst>(MD->getMemoryInst()))
2846           TOPClass->incStoreCount();
2847       }
2848 
2849     // FIXME: This is trying to discover which instructions are uses of phi
2850     // nodes.  We should move this into one of the myriad of places that walk
2851     // all the operands already.
2852     for (auto &I : *BB) {
2853       if (isa<PHINode>(&I))
2854         for (auto *U : I.users())
2855           if (auto *UInst = dyn_cast<Instruction>(U))
2856             if (InstrToDFSNum(UInst) != 0 && okayForPHIOfOps(UInst))
2857               PHINodeUses.insert(UInst);
2858       // Don't insert void terminators into the class. We don't value number
2859       // them, and they just end up sitting in TOP.
2860       if (I.isTerminator() && I.getType()->isVoidTy())
2861         continue;
2862       TOPClass->insert(&I);
2863       ValueToClass[&I] = TOPClass;
2864     }
2865   }
2866 
2867   // Initialize arguments to be in their own unique congruence classes
2868   for (auto &FA : F.args())
2869     createSingletonCongruenceClass(&FA);
2870 }
2871 
2872 void NewGVN::cleanupTables() {
2873   for (unsigned i = 0, e = CongruenceClasses.size(); i != e; ++i) {
2874     LLVM_DEBUG(dbgs() << "Congruence class " << CongruenceClasses[i]->getID()
2875                       << " has " << CongruenceClasses[i]->size()
2876                       << " members\n");
2877     // Make sure we delete the congruence class (probably worth switching to
2878     // a unique_ptr at some point.
2879     delete CongruenceClasses[i];
2880     CongruenceClasses[i] = nullptr;
2881   }
2882 
2883   // Destroy the value expressions
2884   SmallVector<Instruction *, 8> TempInst(AllTempInstructions.begin(),
2885                                          AllTempInstructions.end());
2886   AllTempInstructions.clear();
2887 
2888   // We have to drop all references for everything first, so there are no uses
2889   // left as we delete them.
2890   for (auto *I : TempInst) {
2891     I->dropAllReferences();
2892   }
2893 
2894   while (!TempInst.empty()) {
2895     auto *I = TempInst.back();
2896     TempInst.pop_back();
2897     I->deleteValue();
2898   }
2899 
2900   ValueToClass.clear();
2901   ArgRecycler.clear(ExpressionAllocator);
2902   ExpressionAllocator.Reset();
2903   CongruenceClasses.clear();
2904   ExpressionToClass.clear();
2905   ValueToExpression.clear();
2906   RealToTemp.clear();
2907   AdditionalUsers.clear();
2908   ExpressionToPhiOfOps.clear();
2909   TempToBlock.clear();
2910   TempToMemory.clear();
2911   PHINodeUses.clear();
2912   OpSafeForPHIOfOps.clear();
2913   ReachableBlocks.clear();
2914   ReachableEdges.clear();
2915 #ifndef NDEBUG
2916   ProcessedCount.clear();
2917 #endif
2918   InstrDFS.clear();
2919   InstructionsToErase.clear();
2920   DFSToInstr.clear();
2921   BlockInstRange.clear();
2922   TouchedInstructions.clear();
2923   MemoryAccessToClass.clear();
2924   PredicateToUsers.clear();
2925   MemoryToUsers.clear();
2926   RevisitOnReachabilityChange.clear();
2927 }
2928 
2929 // Assign local DFS number mapping to instructions, and leave space for Value
2930 // PHI's.
2931 std::pair<unsigned, unsigned> NewGVN::assignDFSNumbers(BasicBlock *B,
2932                                                        unsigned Start) {
2933   unsigned End = Start;
2934   if (MemoryAccess *MemPhi = getMemoryAccess(B)) {
2935     InstrDFS[MemPhi] = End++;
2936     DFSToInstr.emplace_back(MemPhi);
2937   }
2938 
2939   // Then the real block goes next.
2940   for (auto &I : *B) {
2941     // There's no need to call isInstructionTriviallyDead more than once on
2942     // an instruction. Therefore, once we know that an instruction is dead
2943     // we change its DFS number so that it doesn't get value numbered.
2944     if (isInstructionTriviallyDead(&I, TLI)) {
2945       InstrDFS[&I] = 0;
2946       LLVM_DEBUG(dbgs() << "Skipping trivially dead instruction " << I << "\n");
2947       markInstructionForDeletion(&I);
2948       continue;
2949     }
2950     if (isa<PHINode>(&I))
2951       RevisitOnReachabilityChange[B].set(End);
2952     InstrDFS[&I] = End++;
2953     DFSToInstr.emplace_back(&I);
2954   }
2955 
2956   // All of the range functions taken half-open ranges (open on the end side).
2957   // So we do not subtract one from count, because at this point it is one
2958   // greater than the last instruction.
2959   return std::make_pair(Start, End);
2960 }
2961 
2962 void NewGVN::updateProcessedCount(const Value *V) {
2963 #ifndef NDEBUG
2964   if (ProcessedCount.count(V) == 0) {
2965     ProcessedCount.insert({V, 1});
2966   } else {
2967     ++ProcessedCount[V];
2968     assert(ProcessedCount[V] < 100 &&
2969            "Seem to have processed the same Value a lot");
2970   }
2971 #endif
2972 }
2973 
2974 // Evaluate MemoryPhi nodes symbolically, just like PHI nodes
2975 void NewGVN::valueNumberMemoryPhi(MemoryPhi *MP) {
2976   // If all the arguments are the same, the MemoryPhi has the same value as the
2977   // argument.  Filter out unreachable blocks and self phis from our operands.
2978   // TODO: We could do cycle-checking on the memory phis to allow valueizing for
2979   // self-phi checking.
2980   const BasicBlock *PHIBlock = MP->getBlock();
2981   auto Filtered = make_filter_range(MP->operands(), [&](const Use &U) {
2982     return cast<MemoryAccess>(U) != MP &&
2983            !isMemoryAccessTOP(cast<MemoryAccess>(U)) &&
2984            ReachableEdges.count({MP->getIncomingBlock(U), PHIBlock});
2985   });
2986   // If all that is left is nothing, our memoryphi is undef. We keep it as
2987   // InitialClass.  Note: The only case this should happen is if we have at
2988   // least one self-argument.
2989   if (Filtered.begin() == Filtered.end()) {
2990     if (setMemoryClass(MP, TOPClass))
2991       markMemoryUsersTouched(MP);
2992     return;
2993   }
2994 
2995   // Transform the remaining operands into operand leaders.
2996   // FIXME: mapped_iterator should have a range version.
2997   auto LookupFunc = [&](const Use &U) {
2998     return lookupMemoryLeader(cast<MemoryAccess>(U));
2999   };
3000   auto MappedBegin = map_iterator(Filtered.begin(), LookupFunc);
3001   auto MappedEnd = map_iterator(Filtered.end(), LookupFunc);
3002 
3003   // and now check if all the elements are equal.
3004   // Sadly, we can't use std::equals since these are random access iterators.
3005   const auto *AllSameValue = *MappedBegin;
3006   ++MappedBegin;
3007   bool AllEqual = std::all_of(
3008       MappedBegin, MappedEnd,
3009       [&AllSameValue](const MemoryAccess *V) { return V == AllSameValue; });
3010 
3011   if (AllEqual)
3012     LLVM_DEBUG(dbgs() << "Memory Phi value numbered to " << *AllSameValue
3013                       << "\n");
3014   else
3015     LLVM_DEBUG(dbgs() << "Memory Phi value numbered to itself\n");
3016   // If it's equal to something, it's in that class. Otherwise, it has to be in
3017   // a class where it is the leader (other things may be equivalent to it, but
3018   // it needs to start off in its own class, which means it must have been the
3019   // leader, and it can't have stopped being the leader because it was never
3020   // removed).
3021   CongruenceClass *CC =
3022       AllEqual ? getMemoryClass(AllSameValue) : ensureLeaderOfMemoryClass(MP);
3023   auto OldState = MemoryPhiState.lookup(MP);
3024   assert(OldState != MPS_Invalid && "Invalid memory phi state");
3025   auto NewState = AllEqual ? MPS_Equivalent : MPS_Unique;
3026   MemoryPhiState[MP] = NewState;
3027   if (setMemoryClass(MP, CC) || OldState != NewState)
3028     markMemoryUsersTouched(MP);
3029 }
3030 
3031 // Value number a single instruction, symbolically evaluating, performing
3032 // congruence finding, and updating mappings.
3033 void NewGVN::valueNumberInstruction(Instruction *I) {
3034   LLVM_DEBUG(dbgs() << "Processing instruction " << *I << "\n");
3035   if (!I->isTerminator()) {
3036     const Expression *Symbolized = nullptr;
3037     SmallPtrSet<Value *, 2> Visited;
3038     if (DebugCounter::shouldExecute(VNCounter)) {
3039       Symbolized = performSymbolicEvaluation(I, Visited);
3040       // Make a phi of ops if necessary
3041       if (Symbolized && !isa<ConstantExpression>(Symbolized) &&
3042           !isa<VariableExpression>(Symbolized) && PHINodeUses.count(I)) {
3043         auto *PHIE = makePossiblePHIOfOps(I, Visited);
3044         // If we created a phi of ops, use it.
3045         // If we couldn't create one, make sure we don't leave one lying around
3046         if (PHIE) {
3047           Symbolized = PHIE;
3048         } else if (auto *Op = RealToTemp.lookup(I)) {
3049           removePhiOfOps(I, Op);
3050         }
3051       }
3052     } else {
3053       // Mark the instruction as unused so we don't value number it again.
3054       InstrDFS[I] = 0;
3055     }
3056     // If we couldn't come up with a symbolic expression, use the unknown
3057     // expression
3058     if (Symbolized == nullptr)
3059       Symbolized = createUnknownExpression(I);
3060     performCongruenceFinding(I, Symbolized);
3061   } else {
3062     // Handle terminators that return values. All of them produce values we
3063     // don't currently understand.  We don't place non-value producing
3064     // terminators in a class.
3065     if (!I->getType()->isVoidTy()) {
3066       auto *Symbolized = createUnknownExpression(I);
3067       performCongruenceFinding(I, Symbolized);
3068     }
3069     processOutgoingEdges(I, I->getParent());
3070   }
3071 }
3072 
3073 // Check if there is a path, using single or equal argument phi nodes, from
3074 // First to Second.
3075 bool NewGVN::singleReachablePHIPath(
3076     SmallPtrSet<const MemoryAccess *, 8> &Visited, const MemoryAccess *First,
3077     const MemoryAccess *Second) const {
3078   if (First == Second)
3079     return true;
3080   if (MSSA->isLiveOnEntryDef(First))
3081     return false;
3082 
3083   // This is not perfect, but as we're just verifying here, we can live with
3084   // the loss of precision. The real solution would be that of doing strongly
3085   // connected component finding in this routine, and it's probably not worth
3086   // the complexity for the time being. So, we just keep a set of visited
3087   // MemoryAccess and return true when we hit a cycle.
3088   if (Visited.count(First))
3089     return true;
3090   Visited.insert(First);
3091 
3092   const auto *EndDef = First;
3093   for (auto *ChainDef : optimized_def_chain(First)) {
3094     if (ChainDef == Second)
3095       return true;
3096     if (MSSA->isLiveOnEntryDef(ChainDef))
3097       return false;
3098     EndDef = ChainDef;
3099   }
3100   auto *MP = cast<MemoryPhi>(EndDef);
3101   auto ReachableOperandPred = [&](const Use &U) {
3102     return ReachableEdges.count({MP->getIncomingBlock(U), MP->getBlock()});
3103   };
3104   auto FilteredPhiArgs =
3105       make_filter_range(MP->operands(), ReachableOperandPred);
3106   SmallVector<const Value *, 32> OperandList;
3107   llvm::copy(FilteredPhiArgs, std::back_inserter(OperandList));
3108   bool Okay = is_splat(OperandList);
3109   if (Okay)
3110     return singleReachablePHIPath(Visited, cast<MemoryAccess>(OperandList[0]),
3111                                   Second);
3112   return false;
3113 }
3114 
3115 // Verify the that the memory equivalence table makes sense relative to the
3116 // congruence classes.  Note that this checking is not perfect, and is currently
3117 // subject to very rare false negatives. It is only useful for
3118 // testing/debugging.
3119 void NewGVN::verifyMemoryCongruency() const {
3120 #ifndef NDEBUG
3121   // Verify that the memory table equivalence and memory member set match
3122   for (const auto *CC : CongruenceClasses) {
3123     if (CC == TOPClass || CC->isDead())
3124       continue;
3125     if (CC->getStoreCount() != 0) {
3126       assert((CC->getStoredValue() || !isa<StoreInst>(CC->getLeader())) &&
3127              "Any class with a store as a leader should have a "
3128              "representative stored value");
3129       assert(CC->getMemoryLeader() &&
3130              "Any congruence class with a store should have a "
3131              "representative access");
3132     }
3133 
3134     if (CC->getMemoryLeader())
3135       assert(MemoryAccessToClass.lookup(CC->getMemoryLeader()) == CC &&
3136              "Representative MemoryAccess does not appear to be reverse "
3137              "mapped properly");
3138     for (auto M : CC->memory())
3139       assert(MemoryAccessToClass.lookup(M) == CC &&
3140              "Memory member does not appear to be reverse mapped properly");
3141   }
3142 
3143   // Anything equivalent in the MemoryAccess table should be in the same
3144   // congruence class.
3145 
3146   // Filter out the unreachable and trivially dead entries, because they may
3147   // never have been updated if the instructions were not processed.
3148   auto ReachableAccessPred =
3149       [&](const std::pair<const MemoryAccess *, CongruenceClass *> Pair) {
3150         bool Result = ReachableBlocks.count(Pair.first->getBlock());
3151         if (!Result || MSSA->isLiveOnEntryDef(Pair.first) ||
3152             MemoryToDFSNum(Pair.first) == 0)
3153           return false;
3154         if (auto *MemDef = dyn_cast<MemoryDef>(Pair.first))
3155           return !isInstructionTriviallyDead(MemDef->getMemoryInst());
3156 
3157         // We could have phi nodes which operands are all trivially dead,
3158         // so we don't process them.
3159         if (auto *MemPHI = dyn_cast<MemoryPhi>(Pair.first)) {
3160           for (auto &U : MemPHI->incoming_values()) {
3161             if (auto *I = dyn_cast<Instruction>(&*U)) {
3162               if (!isInstructionTriviallyDead(I))
3163                 return true;
3164             }
3165           }
3166           return false;
3167         }
3168 
3169         return true;
3170       };
3171 
3172   auto Filtered = make_filter_range(MemoryAccessToClass, ReachableAccessPred);
3173   for (auto KV : Filtered) {
3174     if (auto *FirstMUD = dyn_cast<MemoryUseOrDef>(KV.first)) {
3175       auto *SecondMUD = dyn_cast<MemoryUseOrDef>(KV.second->getMemoryLeader());
3176       if (FirstMUD && SecondMUD) {
3177         SmallPtrSet<const MemoryAccess *, 8> VisitedMAS;
3178         assert((singleReachablePHIPath(VisitedMAS, FirstMUD, SecondMUD) ||
3179                 ValueToClass.lookup(FirstMUD->getMemoryInst()) ==
3180                     ValueToClass.lookup(SecondMUD->getMemoryInst())) &&
3181                "The instructions for these memory operations should have "
3182                "been in the same congruence class or reachable through"
3183                "a single argument phi");
3184       }
3185     } else if (auto *FirstMP = dyn_cast<MemoryPhi>(KV.first)) {
3186       // We can only sanely verify that MemoryDefs in the operand list all have
3187       // the same class.
3188       auto ReachableOperandPred = [&](const Use &U) {
3189         return ReachableEdges.count(
3190                    {FirstMP->getIncomingBlock(U), FirstMP->getBlock()}) &&
3191                isa<MemoryDef>(U);
3192 
3193       };
3194       // All arguments should in the same class, ignoring unreachable arguments
3195       auto FilteredPhiArgs =
3196           make_filter_range(FirstMP->operands(), ReachableOperandPred);
3197       SmallVector<const CongruenceClass *, 16> PhiOpClasses;
3198       std::transform(FilteredPhiArgs.begin(), FilteredPhiArgs.end(),
3199                      std::back_inserter(PhiOpClasses), [&](const Use &U) {
3200                        const MemoryDef *MD = cast<MemoryDef>(U);
3201                        return ValueToClass.lookup(MD->getMemoryInst());
3202                      });
3203       assert(is_splat(PhiOpClasses) &&
3204              "All MemoryPhi arguments should be in the same class");
3205     }
3206   }
3207 #endif
3208 }
3209 
3210 // Verify that the sparse propagation we did actually found the maximal fixpoint
3211 // We do this by storing the value to class mapping, touching all instructions,
3212 // and redoing the iteration to see if anything changed.
3213 void NewGVN::verifyIterationSettled(Function &F) {
3214 #ifndef NDEBUG
3215   LLVM_DEBUG(dbgs() << "Beginning iteration verification\n");
3216   if (DebugCounter::isCounterSet(VNCounter))
3217     DebugCounter::setCounterValue(VNCounter, StartingVNCounter);
3218 
3219   // Note that we have to store the actual classes, as we may change existing
3220   // classes during iteration.  This is because our memory iteration propagation
3221   // is not perfect, and so may waste a little work.  But it should generate
3222   // exactly the same congruence classes we have now, with different IDs.
3223   std::map<const Value *, CongruenceClass> BeforeIteration;
3224 
3225   for (auto &KV : ValueToClass) {
3226     if (auto *I = dyn_cast<Instruction>(KV.first))
3227       // Skip unused/dead instructions.
3228       if (InstrToDFSNum(I) == 0)
3229         continue;
3230     BeforeIteration.insert({KV.first, *KV.second});
3231   }
3232 
3233   TouchedInstructions.set();
3234   TouchedInstructions.reset(0);
3235   iterateTouchedInstructions();
3236   DenseSet<std::pair<const CongruenceClass *, const CongruenceClass *>>
3237       EqualClasses;
3238   for (const auto &KV : ValueToClass) {
3239     if (auto *I = dyn_cast<Instruction>(KV.first))
3240       // Skip unused/dead instructions.
3241       if (InstrToDFSNum(I) == 0)
3242         continue;
3243     // We could sink these uses, but i think this adds a bit of clarity here as
3244     // to what we are comparing.
3245     auto *BeforeCC = &BeforeIteration.find(KV.first)->second;
3246     auto *AfterCC = KV.second;
3247     // Note that the classes can't change at this point, so we memoize the set
3248     // that are equal.
3249     if (!EqualClasses.count({BeforeCC, AfterCC})) {
3250       assert(BeforeCC->isEquivalentTo(AfterCC) &&
3251              "Value number changed after main loop completed!");
3252       EqualClasses.insert({BeforeCC, AfterCC});
3253     }
3254   }
3255 #endif
3256 }
3257 
3258 // Verify that for each store expression in the expression to class mapping,
3259 // only the latest appears, and multiple ones do not appear.
3260 // Because loads do not use the stored value when doing equality with stores,
3261 // if we don't erase the old store expressions from the table, a load can find
3262 // a no-longer valid StoreExpression.
3263 void NewGVN::verifyStoreExpressions() const {
3264 #ifndef NDEBUG
3265   // This is the only use of this, and it's not worth defining a complicated
3266   // densemapinfo hash/equality function for it.
3267   std::set<
3268       std::pair<const Value *,
3269                 std::tuple<const Value *, const CongruenceClass *, Value *>>>
3270       StoreExpressionSet;
3271   for (const auto &KV : ExpressionToClass) {
3272     if (auto *SE = dyn_cast<StoreExpression>(KV.first)) {
3273       // Make sure a version that will conflict with loads is not already there
3274       auto Res = StoreExpressionSet.insert(
3275           {SE->getOperand(0), std::make_tuple(SE->getMemoryLeader(), KV.second,
3276                                               SE->getStoredValue())});
3277       bool Okay = Res.second;
3278       // It's okay to have the same expression already in there if it is
3279       // identical in nature.
3280       // This can happen when the leader of the stored value changes over time.
3281       if (!Okay)
3282         Okay = (std::get<1>(Res.first->second) == KV.second) &&
3283                (lookupOperandLeader(std::get<2>(Res.first->second)) ==
3284                 lookupOperandLeader(SE->getStoredValue()));
3285       assert(Okay && "Stored expression conflict exists in expression table");
3286       auto *ValueExpr = ValueToExpression.lookup(SE->getStoreInst());
3287       assert(ValueExpr && ValueExpr->equals(*SE) &&
3288              "StoreExpression in ExpressionToClass is not latest "
3289              "StoreExpression for value");
3290     }
3291   }
3292 #endif
3293 }
3294 
3295 // This is the main value numbering loop, it iterates over the initial touched
3296 // instruction set, propagating value numbers, marking things touched, etc,
3297 // until the set of touched instructions is completely empty.
3298 void NewGVN::iterateTouchedInstructions() {
3299   unsigned int Iterations = 0;
3300   // Figure out where touchedinstructions starts
3301   int FirstInstr = TouchedInstructions.find_first();
3302   // Nothing set, nothing to iterate, just return.
3303   if (FirstInstr == -1)
3304     return;
3305   const BasicBlock *LastBlock = getBlockForValue(InstrFromDFSNum(FirstInstr));
3306   while (TouchedInstructions.any()) {
3307     ++Iterations;
3308     // Walk through all the instructions in all the blocks in RPO.
3309     // TODO: As we hit a new block, we should push and pop equalities into a
3310     // table lookupOperandLeader can use, to catch things PredicateInfo
3311     // might miss, like edge-only equivalences.
3312     for (unsigned InstrNum : TouchedInstructions.set_bits()) {
3313 
3314       // This instruction was found to be dead. We don't bother looking
3315       // at it again.
3316       if (InstrNum == 0) {
3317         TouchedInstructions.reset(InstrNum);
3318         continue;
3319       }
3320 
3321       Value *V = InstrFromDFSNum(InstrNum);
3322       const BasicBlock *CurrBlock = getBlockForValue(V);
3323 
3324       // If we hit a new block, do reachability processing.
3325       if (CurrBlock != LastBlock) {
3326         LastBlock = CurrBlock;
3327         bool BlockReachable = ReachableBlocks.count(CurrBlock);
3328         const auto &CurrInstRange = BlockInstRange.lookup(CurrBlock);
3329 
3330         // If it's not reachable, erase any touched instructions and move on.
3331         if (!BlockReachable) {
3332           TouchedInstructions.reset(CurrInstRange.first, CurrInstRange.second);
3333           LLVM_DEBUG(dbgs() << "Skipping instructions in block "
3334                             << getBlockName(CurrBlock)
3335                             << " because it is unreachable\n");
3336           continue;
3337         }
3338         updateProcessedCount(CurrBlock);
3339       }
3340       // Reset after processing (because we may mark ourselves as touched when
3341       // we propagate equalities).
3342       TouchedInstructions.reset(InstrNum);
3343 
3344       if (auto *MP = dyn_cast<MemoryPhi>(V)) {
3345         LLVM_DEBUG(dbgs() << "Processing MemoryPhi " << *MP << "\n");
3346         valueNumberMemoryPhi(MP);
3347       } else if (auto *I = dyn_cast<Instruction>(V)) {
3348         valueNumberInstruction(I);
3349       } else {
3350         llvm_unreachable("Should have been a MemoryPhi or Instruction");
3351       }
3352       updateProcessedCount(V);
3353     }
3354   }
3355   NumGVNMaxIterations = std::max(NumGVNMaxIterations.getValue(), Iterations);
3356 }
3357 
3358 // This is the main transformation entry point.
3359 bool NewGVN::runGVN() {
3360   if (DebugCounter::isCounterSet(VNCounter))
3361     StartingVNCounter = DebugCounter::getCounterValue(VNCounter);
3362   bool Changed = false;
3363   NumFuncArgs = F.arg_size();
3364   MSSAWalker = MSSA->getWalker();
3365   SingletonDeadExpression = new (ExpressionAllocator) DeadExpression();
3366 
3367   // Count number of instructions for sizing of hash tables, and come
3368   // up with a global dfs numbering for instructions.
3369   unsigned ICount = 1;
3370   // Add an empty instruction to account for the fact that we start at 1
3371   DFSToInstr.emplace_back(nullptr);
3372   // Note: We want ideal RPO traversal of the blocks, which is not quite the
3373   // same as dominator tree order, particularly with regard whether backedges
3374   // get visited first or second, given a block with multiple successors.
3375   // If we visit in the wrong order, we will end up performing N times as many
3376   // iterations.
3377   // The dominator tree does guarantee that, for a given dom tree node, it's
3378   // parent must occur before it in the RPO ordering. Thus, we only need to sort
3379   // the siblings.
3380   ReversePostOrderTraversal<Function *> RPOT(&F);
3381   unsigned Counter = 0;
3382   for (auto &B : RPOT) {
3383     auto *Node = DT->getNode(B);
3384     assert(Node && "RPO and Dominator tree should have same reachability");
3385     RPOOrdering[Node] = ++Counter;
3386   }
3387   // Sort dominator tree children arrays into RPO.
3388   for (auto &B : RPOT) {
3389     auto *Node = DT->getNode(B);
3390     if (Node->getNumChildren() > 1)
3391       llvm::sort(Node->begin(), Node->end(),
3392                  [&](const DomTreeNode *A, const DomTreeNode *B) {
3393                    return RPOOrdering[A] < RPOOrdering[B];
3394                  });
3395   }
3396 
3397   // Now a standard depth first ordering of the domtree is equivalent to RPO.
3398   for (auto DTN : depth_first(DT->getRootNode())) {
3399     BasicBlock *B = DTN->getBlock();
3400     const auto &BlockRange = assignDFSNumbers(B, ICount);
3401     BlockInstRange.insert({B, BlockRange});
3402     ICount += BlockRange.second - BlockRange.first;
3403   }
3404   initializeCongruenceClasses(F);
3405 
3406   TouchedInstructions.resize(ICount);
3407   // Ensure we don't end up resizing the expressionToClass map, as
3408   // that can be quite expensive. At most, we have one expression per
3409   // instruction.
3410   ExpressionToClass.reserve(ICount);
3411 
3412   // Initialize the touched instructions to include the entry block.
3413   const auto &InstRange = BlockInstRange.lookup(&F.getEntryBlock());
3414   TouchedInstructions.set(InstRange.first, InstRange.second);
3415   LLVM_DEBUG(dbgs() << "Block " << getBlockName(&F.getEntryBlock())
3416                     << " marked reachable\n");
3417   ReachableBlocks.insert(&F.getEntryBlock());
3418 
3419   iterateTouchedInstructions();
3420   verifyMemoryCongruency();
3421   verifyIterationSettled(F);
3422   verifyStoreExpressions();
3423 
3424   Changed |= eliminateInstructions(F);
3425 
3426   // Delete all instructions marked for deletion.
3427   for (Instruction *ToErase : InstructionsToErase) {
3428     if (!ToErase->use_empty())
3429       ToErase->replaceAllUsesWith(UndefValue::get(ToErase->getType()));
3430 
3431     assert(ToErase->getParent() &&
3432            "BB containing ToErase deleted unexpectedly!");
3433     ToErase->eraseFromParent();
3434   }
3435   Changed |= !InstructionsToErase.empty();
3436 
3437   // Delete all unreachable blocks.
3438   auto UnreachableBlockPred = [&](const BasicBlock &BB) {
3439     return !ReachableBlocks.count(&BB);
3440   };
3441 
3442   for (auto &BB : make_filter_range(F, UnreachableBlockPred)) {
3443     LLVM_DEBUG(dbgs() << "We believe block " << getBlockName(&BB)
3444                       << " is unreachable\n");
3445     deleteInstructionsInBlock(&BB);
3446     Changed = true;
3447   }
3448 
3449   cleanupTables();
3450   return Changed;
3451 }
3452 
3453 struct NewGVN::ValueDFS {
3454   int DFSIn = 0;
3455   int DFSOut = 0;
3456   int LocalNum = 0;
3457 
3458   // Only one of Def and U will be set.
3459   // The bool in the Def tells us whether the Def is the stored value of a
3460   // store.
3461   PointerIntPair<Value *, 1, bool> Def;
3462   Use *U = nullptr;
3463 
3464   bool operator<(const ValueDFS &Other) const {
3465     // It's not enough that any given field be less than - we have sets
3466     // of fields that need to be evaluated together to give a proper ordering.
3467     // For example, if you have;
3468     // DFS (1, 3)
3469     // Val 0
3470     // DFS (1, 2)
3471     // Val 50
3472     // We want the second to be less than the first, but if we just go field
3473     // by field, we will get to Val 0 < Val 50 and say the first is less than
3474     // the second. We only want it to be less than if the DFS orders are equal.
3475     //
3476     // Each LLVM instruction only produces one value, and thus the lowest-level
3477     // differentiator that really matters for the stack (and what we use as as a
3478     // replacement) is the local dfs number.
3479     // Everything else in the structure is instruction level, and only affects
3480     // the order in which we will replace operands of a given instruction.
3481     //
3482     // For a given instruction (IE things with equal dfsin, dfsout, localnum),
3483     // the order of replacement of uses does not matter.
3484     // IE given,
3485     //  a = 5
3486     //  b = a + a
3487     // When you hit b, you will have two valuedfs with the same dfsin, out, and
3488     // localnum.
3489     // The .val will be the same as well.
3490     // The .u's will be different.
3491     // You will replace both, and it does not matter what order you replace them
3492     // in (IE whether you replace operand 2, then operand 1, or operand 1, then
3493     // operand 2).
3494     // Similarly for the case of same dfsin, dfsout, localnum, but different
3495     // .val's
3496     //  a = 5
3497     //  b  = 6
3498     //  c = a + b
3499     // in c, we will a valuedfs for a, and one for b,with everything the same
3500     // but .val  and .u.
3501     // It does not matter what order we replace these operands in.
3502     // You will always end up with the same IR, and this is guaranteed.
3503     return std::tie(DFSIn, DFSOut, LocalNum, Def, U) <
3504            std::tie(Other.DFSIn, Other.DFSOut, Other.LocalNum, Other.Def,
3505                     Other.U);
3506   }
3507 };
3508 
3509 // This function converts the set of members for a congruence class from values,
3510 // to sets of defs and uses with associated DFS info.  The total number of
3511 // reachable uses for each value is stored in UseCount, and instructions that
3512 // seem
3513 // dead (have no non-dead uses) are stored in ProbablyDead.
3514 void NewGVN::convertClassToDFSOrdered(
3515     const CongruenceClass &Dense, SmallVectorImpl<ValueDFS> &DFSOrderedSet,
3516     DenseMap<const Value *, unsigned int> &UseCounts,
3517     SmallPtrSetImpl<Instruction *> &ProbablyDead) const {
3518   for (auto D : Dense) {
3519     // First add the value.
3520     BasicBlock *BB = getBlockForValue(D);
3521     // Constants are handled prior to ever calling this function, so
3522     // we should only be left with instructions as members.
3523     assert(BB && "Should have figured out a basic block for value");
3524     ValueDFS VDDef;
3525     DomTreeNode *DomNode = DT->getNode(BB);
3526     VDDef.DFSIn = DomNode->getDFSNumIn();
3527     VDDef.DFSOut = DomNode->getDFSNumOut();
3528     // If it's a store, use the leader of the value operand, if it's always
3529     // available, or the value operand.  TODO: We could do dominance checks to
3530     // find a dominating leader, but not worth it ATM.
3531     if (auto *SI = dyn_cast<StoreInst>(D)) {
3532       auto Leader = lookupOperandLeader(SI->getValueOperand());
3533       if (alwaysAvailable(Leader)) {
3534         VDDef.Def.setPointer(Leader);
3535       } else {
3536         VDDef.Def.setPointer(SI->getValueOperand());
3537         VDDef.Def.setInt(true);
3538       }
3539     } else {
3540       VDDef.Def.setPointer(D);
3541     }
3542     assert(isa<Instruction>(D) &&
3543            "The dense set member should always be an instruction");
3544     Instruction *Def = cast<Instruction>(D);
3545     VDDef.LocalNum = InstrToDFSNum(D);
3546     DFSOrderedSet.push_back(VDDef);
3547     // If there is a phi node equivalent, add it
3548     if (auto *PN = RealToTemp.lookup(Def)) {
3549       auto *PHIE =
3550           dyn_cast_or_null<PHIExpression>(ValueToExpression.lookup(Def));
3551       if (PHIE) {
3552         VDDef.Def.setInt(false);
3553         VDDef.Def.setPointer(PN);
3554         VDDef.LocalNum = 0;
3555         DFSOrderedSet.push_back(VDDef);
3556       }
3557     }
3558 
3559     unsigned int UseCount = 0;
3560     // Now add the uses.
3561     for (auto &U : Def->uses()) {
3562       if (auto *I = dyn_cast<Instruction>(U.getUser())) {
3563         // Don't try to replace into dead uses
3564         if (InstructionsToErase.count(I))
3565           continue;
3566         ValueDFS VDUse;
3567         // Put the phi node uses in the incoming block.
3568         BasicBlock *IBlock;
3569         if (auto *P = dyn_cast<PHINode>(I)) {
3570           IBlock = P->getIncomingBlock(U);
3571           // Make phi node users appear last in the incoming block
3572           // they are from.
3573           VDUse.LocalNum = InstrDFS.size() + 1;
3574         } else {
3575           IBlock = getBlockForValue(I);
3576           VDUse.LocalNum = InstrToDFSNum(I);
3577         }
3578 
3579         // Skip uses in unreachable blocks, as we're going
3580         // to delete them.
3581         if (ReachableBlocks.count(IBlock) == 0)
3582           continue;
3583 
3584         DomTreeNode *DomNode = DT->getNode(IBlock);
3585         VDUse.DFSIn = DomNode->getDFSNumIn();
3586         VDUse.DFSOut = DomNode->getDFSNumOut();
3587         VDUse.U = &U;
3588         ++UseCount;
3589         DFSOrderedSet.emplace_back(VDUse);
3590       }
3591     }
3592 
3593     // If there are no uses, it's probably dead (but it may have side-effects,
3594     // so not definitely dead. Otherwise, store the number of uses so we can
3595     // track if it becomes dead later).
3596     if (UseCount == 0)
3597       ProbablyDead.insert(Def);
3598     else
3599       UseCounts[Def] = UseCount;
3600   }
3601 }
3602 
3603 // This function converts the set of members for a congruence class from values,
3604 // to the set of defs for loads and stores, with associated DFS info.
3605 void NewGVN::convertClassToLoadsAndStores(
3606     const CongruenceClass &Dense,
3607     SmallVectorImpl<ValueDFS> &LoadsAndStores) const {
3608   for (auto D : Dense) {
3609     if (!isa<LoadInst>(D) && !isa<StoreInst>(D))
3610       continue;
3611 
3612     BasicBlock *BB = getBlockForValue(D);
3613     ValueDFS VD;
3614     DomTreeNode *DomNode = DT->getNode(BB);
3615     VD.DFSIn = DomNode->getDFSNumIn();
3616     VD.DFSOut = DomNode->getDFSNumOut();
3617     VD.Def.setPointer(D);
3618 
3619     // If it's an instruction, use the real local dfs number.
3620     if (auto *I = dyn_cast<Instruction>(D))
3621       VD.LocalNum = InstrToDFSNum(I);
3622     else
3623       llvm_unreachable("Should have been an instruction");
3624 
3625     LoadsAndStores.emplace_back(VD);
3626   }
3627 }
3628 
3629 static void patchAndReplaceAllUsesWith(Instruction *I, Value *Repl) {
3630   patchReplacementInstruction(I, Repl);
3631   I->replaceAllUsesWith(Repl);
3632 }
3633 
3634 void NewGVN::deleteInstructionsInBlock(BasicBlock *BB) {
3635   LLVM_DEBUG(dbgs() << "  BasicBlock Dead:" << *BB);
3636   ++NumGVNBlocksDeleted;
3637 
3638   // Delete the instructions backwards, as it has a reduced likelihood of having
3639   // to update as many def-use and use-def chains. Start after the terminator.
3640   auto StartPoint = BB->rbegin();
3641   ++StartPoint;
3642   // Note that we explicitly recalculate BB->rend() on each iteration,
3643   // as it may change when we remove the first instruction.
3644   for (BasicBlock::reverse_iterator I(StartPoint); I != BB->rend();) {
3645     Instruction &Inst = *I++;
3646     if (!Inst.use_empty())
3647       Inst.replaceAllUsesWith(UndefValue::get(Inst.getType()));
3648     if (isa<LandingPadInst>(Inst))
3649       continue;
3650     salvageKnowledge(&Inst, AC);
3651 
3652     Inst.eraseFromParent();
3653     ++NumGVNInstrDeleted;
3654   }
3655   // Now insert something that simplifycfg will turn into an unreachable.
3656   Type *Int8Ty = Type::getInt8Ty(BB->getContext());
3657   new StoreInst(UndefValue::get(Int8Ty),
3658                 Constant::getNullValue(Int8Ty->getPointerTo()),
3659                 BB->getTerminator());
3660 }
3661 
3662 void NewGVN::markInstructionForDeletion(Instruction *I) {
3663   LLVM_DEBUG(dbgs() << "Marking " << *I << " for deletion\n");
3664   InstructionsToErase.insert(I);
3665 }
3666 
3667 void NewGVN::replaceInstruction(Instruction *I, Value *V) {
3668   LLVM_DEBUG(dbgs() << "Replacing " << *I << " with " << *V << "\n");
3669   patchAndReplaceAllUsesWith(I, V);
3670   // We save the actual erasing to avoid invalidating memory
3671   // dependencies until we are done with everything.
3672   markInstructionForDeletion(I);
3673 }
3674 
3675 namespace {
3676 
3677 // This is a stack that contains both the value and dfs info of where
3678 // that value is valid.
3679 class ValueDFSStack {
3680 public:
3681   Value *back() const { return ValueStack.back(); }
3682   std::pair<int, int> dfs_back() const { return DFSStack.back(); }
3683 
3684   void push_back(Value *V, int DFSIn, int DFSOut) {
3685     ValueStack.emplace_back(V);
3686     DFSStack.emplace_back(DFSIn, DFSOut);
3687   }
3688 
3689   bool empty() const { return DFSStack.empty(); }
3690 
3691   bool isInScope(int DFSIn, int DFSOut) const {
3692     if (empty())
3693       return false;
3694     return DFSIn >= DFSStack.back().first && DFSOut <= DFSStack.back().second;
3695   }
3696 
3697   void popUntilDFSScope(int DFSIn, int DFSOut) {
3698 
3699     // These two should always be in sync at this point.
3700     assert(ValueStack.size() == DFSStack.size() &&
3701            "Mismatch between ValueStack and DFSStack");
3702     while (
3703         !DFSStack.empty() &&
3704         !(DFSIn >= DFSStack.back().first && DFSOut <= DFSStack.back().second)) {
3705       DFSStack.pop_back();
3706       ValueStack.pop_back();
3707     }
3708   }
3709 
3710 private:
3711   SmallVector<Value *, 8> ValueStack;
3712   SmallVector<std::pair<int, int>, 8> DFSStack;
3713 };
3714 
3715 } // end anonymous namespace
3716 
3717 // Given an expression, get the congruence class for it.
3718 CongruenceClass *NewGVN::getClassForExpression(const Expression *E) const {
3719   if (auto *VE = dyn_cast<VariableExpression>(E))
3720     return ValueToClass.lookup(VE->getVariableValue());
3721   else if (isa<DeadExpression>(E))
3722     return TOPClass;
3723   return ExpressionToClass.lookup(E);
3724 }
3725 
3726 // Given a value and a basic block we are trying to see if it is available in,
3727 // see if the value has a leader available in that block.
3728 Value *NewGVN::findPHIOfOpsLeader(const Expression *E,
3729                                   const Instruction *OrigInst,
3730                                   const BasicBlock *BB) const {
3731   // It would already be constant if we could make it constant
3732   if (auto *CE = dyn_cast<ConstantExpression>(E))
3733     return CE->getConstantValue();
3734   if (auto *VE = dyn_cast<VariableExpression>(E)) {
3735     auto *V = VE->getVariableValue();
3736     if (alwaysAvailable(V) || DT->dominates(getBlockForValue(V), BB))
3737       return VE->getVariableValue();
3738   }
3739 
3740   auto *CC = getClassForExpression(E);
3741   if (!CC)
3742     return nullptr;
3743   if (alwaysAvailable(CC->getLeader()))
3744     return CC->getLeader();
3745 
3746   for (auto Member : *CC) {
3747     auto *MemberInst = dyn_cast<Instruction>(Member);
3748     if (MemberInst == OrigInst)
3749       continue;
3750     // Anything that isn't an instruction is always available.
3751     if (!MemberInst)
3752       return Member;
3753     if (DT->dominates(getBlockForValue(MemberInst), BB))
3754       return Member;
3755   }
3756   return nullptr;
3757 }
3758 
3759 bool NewGVN::eliminateInstructions(Function &F) {
3760   // This is a non-standard eliminator. The normal way to eliminate is
3761   // to walk the dominator tree in order, keeping track of available
3762   // values, and eliminating them.  However, this is mildly
3763   // pointless. It requires doing lookups on every instruction,
3764   // regardless of whether we will ever eliminate it.  For
3765   // instructions part of most singleton congruence classes, we know we
3766   // will never eliminate them.
3767 
3768   // Instead, this eliminator looks at the congruence classes directly, sorts
3769   // them into a DFS ordering of the dominator tree, and then we just
3770   // perform elimination straight on the sets by walking the congruence
3771   // class member uses in order, and eliminate the ones dominated by the
3772   // last member.   This is worst case O(E log E) where E = number of
3773   // instructions in a single congruence class.  In theory, this is all
3774   // instructions.   In practice, it is much faster, as most instructions are
3775   // either in singleton congruence classes or can't possibly be eliminated
3776   // anyway (if there are no overlapping DFS ranges in class).
3777   // When we find something not dominated, it becomes the new leader
3778   // for elimination purposes.
3779   // TODO: If we wanted to be faster, We could remove any members with no
3780   // overlapping ranges while sorting, as we will never eliminate anything
3781   // with those members, as they don't dominate anything else in our set.
3782 
3783   bool AnythingReplaced = false;
3784 
3785   // Since we are going to walk the domtree anyway, and we can't guarantee the
3786   // DFS numbers are updated, we compute some ourselves.
3787   DT->updateDFSNumbers();
3788 
3789   // Go through all of our phi nodes, and kill the arguments associated with
3790   // unreachable edges.
3791   auto ReplaceUnreachablePHIArgs = [&](PHINode *PHI, BasicBlock *BB) {
3792     for (auto &Operand : PHI->incoming_values())
3793       if (!ReachableEdges.count({PHI->getIncomingBlock(Operand), BB})) {
3794         LLVM_DEBUG(dbgs() << "Replacing incoming value of " << PHI
3795                           << " for block "
3796                           << getBlockName(PHI->getIncomingBlock(Operand))
3797                           << " with undef due to it being unreachable\n");
3798         Operand.set(UndefValue::get(PHI->getType()));
3799       }
3800   };
3801   // Replace unreachable phi arguments.
3802   // At this point, RevisitOnReachabilityChange only contains:
3803   //
3804   // 1. PHIs
3805   // 2. Temporaries that will convert to PHIs
3806   // 3. Operations that are affected by an unreachable edge but do not fit into
3807   // 1 or 2 (rare).
3808   // So it is a slight overshoot of what we want. We could make it exact by
3809   // using two SparseBitVectors per block.
3810   DenseMap<const BasicBlock *, unsigned> ReachablePredCount;
3811   for (auto &KV : ReachableEdges)
3812     ReachablePredCount[KV.getEnd()]++;
3813   for (auto &BBPair : RevisitOnReachabilityChange) {
3814     for (auto InstNum : BBPair.second) {
3815       auto *Inst = InstrFromDFSNum(InstNum);
3816       auto *PHI = dyn_cast<PHINode>(Inst);
3817       PHI = PHI ? PHI : dyn_cast_or_null<PHINode>(RealToTemp.lookup(Inst));
3818       if (!PHI)
3819         continue;
3820       auto *BB = BBPair.first;
3821       if (ReachablePredCount.lookup(BB) != PHI->getNumIncomingValues())
3822         ReplaceUnreachablePHIArgs(PHI, BB);
3823     }
3824   }
3825 
3826   // Map to store the use counts
3827   DenseMap<const Value *, unsigned int> UseCounts;
3828   for (auto *CC : reverse(CongruenceClasses)) {
3829     LLVM_DEBUG(dbgs() << "Eliminating in congruence class " << CC->getID()
3830                       << "\n");
3831     // Track the equivalent store info so we can decide whether to try
3832     // dead store elimination.
3833     SmallVector<ValueDFS, 8> PossibleDeadStores;
3834     SmallPtrSet<Instruction *, 8> ProbablyDead;
3835     if (CC->isDead() || CC->empty())
3836       continue;
3837     // Everything still in the TOP class is unreachable or dead.
3838     if (CC == TOPClass) {
3839       for (auto M : *CC) {
3840         auto *VTE = ValueToExpression.lookup(M);
3841         if (VTE && isa<DeadExpression>(VTE))
3842           markInstructionForDeletion(cast<Instruction>(M));
3843         assert((!ReachableBlocks.count(cast<Instruction>(M)->getParent()) ||
3844                 InstructionsToErase.count(cast<Instruction>(M))) &&
3845                "Everything in TOP should be unreachable or dead at this "
3846                "point");
3847       }
3848       continue;
3849     }
3850 
3851     assert(CC->getLeader() && "We should have had a leader");
3852     // If this is a leader that is always available, and it's a
3853     // constant or has no equivalences, just replace everything with
3854     // it. We then update the congruence class with whatever members
3855     // are left.
3856     Value *Leader =
3857         CC->getStoredValue() ? CC->getStoredValue() : CC->getLeader();
3858     if (alwaysAvailable(Leader)) {
3859       CongruenceClass::MemberSet MembersLeft;
3860       for (auto M : *CC) {
3861         Value *Member = M;
3862         // Void things have no uses we can replace.
3863         if (Member == Leader || !isa<Instruction>(Member) ||
3864             Member->getType()->isVoidTy()) {
3865           MembersLeft.insert(Member);
3866           continue;
3867         }
3868         LLVM_DEBUG(dbgs() << "Found replacement " << *(Leader) << " for "
3869                           << *Member << "\n");
3870         auto *I = cast<Instruction>(Member);
3871         assert(Leader != I && "About to accidentally remove our leader");
3872         replaceInstruction(I, Leader);
3873         AnythingReplaced = true;
3874       }
3875       CC->swap(MembersLeft);
3876     } else {
3877       // If this is a singleton, we can skip it.
3878       if (CC->size() != 1 || RealToTemp.count(Leader)) {
3879         // This is a stack because equality replacement/etc may place
3880         // constants in the middle of the member list, and we want to use
3881         // those constant values in preference to the current leader, over
3882         // the scope of those constants.
3883         ValueDFSStack EliminationStack;
3884 
3885         // Convert the members to DFS ordered sets and then merge them.
3886         SmallVector<ValueDFS, 8> DFSOrderedSet;
3887         convertClassToDFSOrdered(*CC, DFSOrderedSet, UseCounts, ProbablyDead);
3888 
3889         // Sort the whole thing.
3890         llvm::sort(DFSOrderedSet);
3891         for (auto &VD : DFSOrderedSet) {
3892           int MemberDFSIn = VD.DFSIn;
3893           int MemberDFSOut = VD.DFSOut;
3894           Value *Def = VD.Def.getPointer();
3895           bool FromStore = VD.Def.getInt();
3896           Use *U = VD.U;
3897           // We ignore void things because we can't get a value from them.
3898           if (Def && Def->getType()->isVoidTy())
3899             continue;
3900           auto *DefInst = dyn_cast_or_null<Instruction>(Def);
3901           if (DefInst && AllTempInstructions.count(DefInst)) {
3902             auto *PN = cast<PHINode>(DefInst);
3903 
3904             // If this is a value phi and that's the expression we used, insert
3905             // it into the program
3906             // remove from temp instruction list.
3907             AllTempInstructions.erase(PN);
3908             auto *DefBlock = getBlockForValue(Def);
3909             LLVM_DEBUG(dbgs() << "Inserting fully real phi of ops" << *Def
3910                               << " into block "
3911                               << getBlockName(getBlockForValue(Def)) << "\n");
3912             PN->insertBefore(&DefBlock->front());
3913             Def = PN;
3914             NumGVNPHIOfOpsEliminations++;
3915           }
3916 
3917           if (EliminationStack.empty()) {
3918             LLVM_DEBUG(dbgs() << "Elimination Stack is empty\n");
3919           } else {
3920             LLVM_DEBUG(dbgs() << "Elimination Stack Top DFS numbers are ("
3921                               << EliminationStack.dfs_back().first << ","
3922                               << EliminationStack.dfs_back().second << ")\n");
3923           }
3924 
3925           LLVM_DEBUG(dbgs() << "Current DFS numbers are (" << MemberDFSIn << ","
3926                             << MemberDFSOut << ")\n");
3927           // First, we see if we are out of scope or empty.  If so,
3928           // and there equivalences, we try to replace the top of
3929           // stack with equivalences (if it's on the stack, it must
3930           // not have been eliminated yet).
3931           // Then we synchronize to our current scope, by
3932           // popping until we are back within a DFS scope that
3933           // dominates the current member.
3934           // Then, what happens depends on a few factors
3935           // If the stack is now empty, we need to push
3936           // If we have a constant or a local equivalence we want to
3937           // start using, we also push.
3938           // Otherwise, we walk along, processing members who are
3939           // dominated by this scope, and eliminate them.
3940           bool ShouldPush = Def && EliminationStack.empty();
3941           bool OutOfScope =
3942               !EliminationStack.isInScope(MemberDFSIn, MemberDFSOut);
3943 
3944           if (OutOfScope || ShouldPush) {
3945             // Sync to our current scope.
3946             EliminationStack.popUntilDFSScope(MemberDFSIn, MemberDFSOut);
3947             bool ShouldPush = Def && EliminationStack.empty();
3948             if (ShouldPush) {
3949               EliminationStack.push_back(Def, MemberDFSIn, MemberDFSOut);
3950             }
3951           }
3952 
3953           // Skip the Def's, we only want to eliminate on their uses.  But mark
3954           // dominated defs as dead.
3955           if (Def) {
3956             // For anything in this case, what and how we value number
3957             // guarantees that any side-effets that would have occurred (ie
3958             // throwing, etc) can be proven to either still occur (because it's
3959             // dominated by something that has the same side-effects), or never
3960             // occur.  Otherwise, we would not have been able to prove it value
3961             // equivalent to something else. For these things, we can just mark
3962             // it all dead.  Note that this is different from the "ProbablyDead"
3963             // set, which may not be dominated by anything, and thus, are only
3964             // easy to prove dead if they are also side-effect free. Note that
3965             // because stores are put in terms of the stored value, we skip
3966             // stored values here. If the stored value is really dead, it will
3967             // still be marked for deletion when we process it in its own class.
3968             if (!EliminationStack.empty() && Def != EliminationStack.back() &&
3969                 isa<Instruction>(Def) && !FromStore)
3970               markInstructionForDeletion(cast<Instruction>(Def));
3971             continue;
3972           }
3973           // At this point, we know it is a Use we are trying to possibly
3974           // replace.
3975 
3976           assert(isa<Instruction>(U->get()) &&
3977                  "Current def should have been an instruction");
3978           assert(isa<Instruction>(U->getUser()) &&
3979                  "Current user should have been an instruction");
3980 
3981           // If the thing we are replacing into is already marked to be dead,
3982           // this use is dead.  Note that this is true regardless of whether
3983           // we have anything dominating the use or not.  We do this here
3984           // because we are already walking all the uses anyway.
3985           Instruction *InstUse = cast<Instruction>(U->getUser());
3986           if (InstructionsToErase.count(InstUse)) {
3987             auto &UseCount = UseCounts[U->get()];
3988             if (--UseCount == 0) {
3989               ProbablyDead.insert(cast<Instruction>(U->get()));
3990             }
3991           }
3992 
3993           // If we get to this point, and the stack is empty we must have a use
3994           // with nothing we can use to eliminate this use, so just skip it.
3995           if (EliminationStack.empty())
3996             continue;
3997 
3998           Value *DominatingLeader = EliminationStack.back();
3999 
4000           auto *II = dyn_cast<IntrinsicInst>(DominatingLeader);
4001           bool isSSACopy = II && II->getIntrinsicID() == Intrinsic::ssa_copy;
4002           if (isSSACopy)
4003             DominatingLeader = II->getOperand(0);
4004 
4005           // Don't replace our existing users with ourselves.
4006           if (U->get() == DominatingLeader)
4007             continue;
4008           LLVM_DEBUG(dbgs()
4009                      << "Found replacement " << *DominatingLeader << " for "
4010                      << *U->get() << " in " << *(U->getUser()) << "\n");
4011 
4012           // If we replaced something in an instruction, handle the patching of
4013           // metadata.  Skip this if we are replacing predicateinfo with its
4014           // original operand, as we already know we can just drop it.
4015           auto *ReplacedInst = cast<Instruction>(U->get());
4016           auto *PI = PredInfo->getPredicateInfoFor(ReplacedInst);
4017           if (!PI || DominatingLeader != PI->OriginalOp)
4018             patchReplacementInstruction(ReplacedInst, DominatingLeader);
4019           U->set(DominatingLeader);
4020           // This is now a use of the dominating leader, which means if the
4021           // dominating leader was dead, it's now live!
4022           auto &LeaderUseCount = UseCounts[DominatingLeader];
4023           // It's about to be alive again.
4024           if (LeaderUseCount == 0 && isa<Instruction>(DominatingLeader))
4025             ProbablyDead.erase(cast<Instruction>(DominatingLeader));
4026           // For copy instructions, we use their operand as a leader,
4027           // which means we remove a user of the copy and it may become dead.
4028           if (isSSACopy) {
4029             unsigned &IIUseCount = UseCounts[II];
4030             if (--IIUseCount == 0)
4031               ProbablyDead.insert(II);
4032           }
4033           ++LeaderUseCount;
4034           AnythingReplaced = true;
4035         }
4036       }
4037     }
4038 
4039     // At this point, anything still in the ProbablyDead set is actually dead if
4040     // would be trivially dead.
4041     for (auto *I : ProbablyDead)
4042       if (wouldInstructionBeTriviallyDead(I))
4043         markInstructionForDeletion(I);
4044 
4045     // Cleanup the congruence class.
4046     CongruenceClass::MemberSet MembersLeft;
4047     for (auto *Member : *CC)
4048       if (!isa<Instruction>(Member) ||
4049           !InstructionsToErase.count(cast<Instruction>(Member)))
4050         MembersLeft.insert(Member);
4051     CC->swap(MembersLeft);
4052 
4053     // If we have possible dead stores to look at, try to eliminate them.
4054     if (CC->getStoreCount() > 0) {
4055       convertClassToLoadsAndStores(*CC, PossibleDeadStores);
4056       llvm::sort(PossibleDeadStores);
4057       ValueDFSStack EliminationStack;
4058       for (auto &VD : PossibleDeadStores) {
4059         int MemberDFSIn = VD.DFSIn;
4060         int MemberDFSOut = VD.DFSOut;
4061         Instruction *Member = cast<Instruction>(VD.Def.getPointer());
4062         if (EliminationStack.empty() ||
4063             !EliminationStack.isInScope(MemberDFSIn, MemberDFSOut)) {
4064           // Sync to our current scope.
4065           EliminationStack.popUntilDFSScope(MemberDFSIn, MemberDFSOut);
4066           if (EliminationStack.empty()) {
4067             EliminationStack.push_back(Member, MemberDFSIn, MemberDFSOut);
4068             continue;
4069           }
4070         }
4071         // We already did load elimination, so nothing to do here.
4072         if (isa<LoadInst>(Member))
4073           continue;
4074         assert(!EliminationStack.empty());
4075         Instruction *Leader = cast<Instruction>(EliminationStack.back());
4076         (void)Leader;
4077         assert(DT->dominates(Leader->getParent(), Member->getParent()));
4078         // Member is dominater by Leader, and thus dead
4079         LLVM_DEBUG(dbgs() << "Marking dead store " << *Member
4080                           << " that is dominated by " << *Leader << "\n");
4081         markInstructionForDeletion(Member);
4082         CC->erase(Member);
4083         ++NumGVNDeadStores;
4084       }
4085     }
4086   }
4087   return AnythingReplaced;
4088 }
4089 
4090 // This function provides global ranking of operations so that we can place them
4091 // in a canonical order.  Note that rank alone is not necessarily enough for a
4092 // complete ordering, as constants all have the same rank.  However, generally,
4093 // we will simplify an operation with all constants so that it doesn't matter
4094 // what order they appear in.
4095 unsigned int NewGVN::getRank(const Value *V) const {
4096   // Prefer constants to undef to anything else
4097   // Undef is a constant, have to check it first.
4098   // Prefer smaller constants to constantexprs
4099   if (isa<ConstantExpr>(V))
4100     return 2;
4101   if (isa<UndefValue>(V))
4102     return 1;
4103   if (isa<Constant>(V))
4104     return 0;
4105   else if (auto *A = dyn_cast<Argument>(V))
4106     return 3 + A->getArgNo();
4107 
4108   // Need to shift the instruction DFS by number of arguments + 3 to account for
4109   // the constant and argument ranking above.
4110   unsigned Result = InstrToDFSNum(V);
4111   if (Result > 0)
4112     return 4 + NumFuncArgs + Result;
4113   // Unreachable or something else, just return a really large number.
4114   return ~0;
4115 }
4116 
4117 // This is a function that says whether two commutative operations should
4118 // have their order swapped when canonicalizing.
4119 bool NewGVN::shouldSwapOperands(const Value *A, const Value *B) const {
4120   // Because we only care about a total ordering, and don't rewrite expressions
4121   // in this order, we order by rank, which will give a strict weak ordering to
4122   // everything but constants, and then we order by pointer address.
4123   return std::make_pair(getRank(A), A) > std::make_pair(getRank(B), B);
4124 }
4125 
4126 namespace {
4127 
4128 class NewGVNLegacyPass : public FunctionPass {
4129 public:
4130   // Pass identification, replacement for typeid.
4131   static char ID;
4132 
4133   NewGVNLegacyPass() : FunctionPass(ID) {
4134     initializeNewGVNLegacyPassPass(*PassRegistry::getPassRegistry());
4135   }
4136 
4137   bool runOnFunction(Function &F) override;
4138 
4139 private:
4140   void getAnalysisUsage(AnalysisUsage &AU) const override {
4141     AU.addRequired<AssumptionCacheTracker>();
4142     AU.addRequired<DominatorTreeWrapperPass>();
4143     AU.addRequired<TargetLibraryInfoWrapperPass>();
4144     AU.addRequired<MemorySSAWrapperPass>();
4145     AU.addRequired<AAResultsWrapperPass>();
4146     AU.addPreserved<DominatorTreeWrapperPass>();
4147     AU.addPreserved<GlobalsAAWrapperPass>();
4148   }
4149 };
4150 
4151 } // end anonymous namespace
4152 
4153 bool NewGVNLegacyPass::runOnFunction(Function &F) {
4154   if (skipFunction(F))
4155     return false;
4156   return NewGVN(F, &getAnalysis<DominatorTreeWrapperPass>().getDomTree(),
4157                 &getAnalysis<AssumptionCacheTracker>().getAssumptionCache(F),
4158                 &getAnalysis<TargetLibraryInfoWrapperPass>().getTLI(F),
4159                 &getAnalysis<AAResultsWrapperPass>().getAAResults(),
4160                 &getAnalysis<MemorySSAWrapperPass>().getMSSA(),
4161                 F.getParent()->getDataLayout())
4162       .runGVN();
4163 }
4164 
4165 char NewGVNLegacyPass::ID = 0;
4166 
4167 INITIALIZE_PASS_BEGIN(NewGVNLegacyPass, "newgvn", "Global Value Numbering",
4168                       false, false)
4169 INITIALIZE_PASS_DEPENDENCY(AssumptionCacheTracker)
4170 INITIALIZE_PASS_DEPENDENCY(MemorySSAWrapperPass)
4171 INITIALIZE_PASS_DEPENDENCY(DominatorTreeWrapperPass)
4172 INITIALIZE_PASS_DEPENDENCY(TargetLibraryInfoWrapperPass)
4173 INITIALIZE_PASS_DEPENDENCY(AAResultsWrapperPass)
4174 INITIALIZE_PASS_DEPENDENCY(GlobalsAAWrapperPass)
4175 INITIALIZE_PASS_END(NewGVNLegacyPass, "newgvn", "Global Value Numbering", false,
4176                     false)
4177 
4178 // createGVNPass - The public interface to this file.
4179 FunctionPass *llvm::createNewGVNPass() { return new NewGVNLegacyPass(); }
4180 
4181 PreservedAnalyses NewGVNPass::run(Function &F, AnalysisManager<Function> &AM) {
4182   // Apparently the order in which we get these results matter for
4183   // the old GVN (see Chandler's comment in GVN.cpp). I'll keep
4184   // the same order here, just in case.
4185   auto &AC = AM.getResult<AssumptionAnalysis>(F);
4186   auto &DT = AM.getResult<DominatorTreeAnalysis>(F);
4187   auto &TLI = AM.getResult<TargetLibraryAnalysis>(F);
4188   auto &AA = AM.getResult<AAManager>(F);
4189   auto &MSSA = AM.getResult<MemorySSAAnalysis>(F).getMSSA();
4190   bool Changed =
4191       NewGVN(F, &DT, &AC, &TLI, &AA, &MSSA, F.getParent()->getDataLayout())
4192           .runGVN();
4193   if (!Changed)
4194     return PreservedAnalyses::all();
4195   PreservedAnalyses PA;
4196   PA.preserve<DominatorTreeAnalysis>();
4197   PA.preserve<GlobalsAA>();
4198   return PA;
4199 }
4200