doxygen/GVNSink_8cpp_source.html

//===- GVNSink.cpp - sink expressions into successors ---------------------===//

//

// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.

// See https://llvm.org/LICENSE.txt for license information.

// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception

//

//===----------------------------------------------------------------------===//

//

/// \file GVNSink.cpp

/// This pass attempts to sink instructions into successors, reducing static

/// instruction count and enabling if-conversion.

///

/// We use a variant of global value numbering to decide what can be sunk.

/// Consider:

///

/// [ %a1 = add i32 %b, 1  ]   [ %c1 = add i32 %d, 1  ]

/// [ %a2 = xor i32 %a1, 1 ]   [ %c2 = xor i32 %c1, 1 ]

///                  \           /

///            [ %e = phi i32 %a2, %c2 ]

///            [ add i32 %e, 4         ]

///

///

/// GVN would number %a1 and %c1 differently because they compute different

/// results - the VN of an instruction is a function of its opcode and the

/// transitive closure of its operands. This is the key property for hoisting

/// and CSE.

///

/// What we want when sinking however is for a numbering that is a function of

/// the *uses* of an instruction, which allows us to answer the question "if I

/// replace %a1 with %c1, will it contribute in an equivalent way to all

/// successive instructions?". The PostValueTable class in GVN provides this

/// mapping.

//

//===----------------------------------------------------------------------===//


#include "llvm/ADT/ArrayRef.h"

#include "llvm/ADT/DenseMap.h"

#include "llvm/ADT/DenseMapInfo.h"

#include "llvm/ADT/DenseSet.h"

#include "llvm/ADT/Hashing.h"

#include "llvm/ADT/None.h"

#include "llvm/ADT/Optional.h"

#include "llvm/ADT/PostOrderIterator.h"

#include "llvm/ADT/STLExtras.h"

#include "llvm/ADT/SmallPtrSet.h"

#include "llvm/ADT/SmallVector.h"

#include "llvm/ADT/Statistic.h"

#include "llvm/ADT/StringExtras.h"

#include "llvm/Analysis/GlobalsModRef.h"

#include "llvm/IR/BasicBlock.h"

#include "llvm/IR/CFG.h"

#include "llvm/IR/Constants.h"

#include "llvm/IR/Function.h"

#include "llvm/IR/InstrTypes.h"

#include "llvm/IR/Instruction.h"

#include "llvm/IR/Instructions.h"

#include "llvm/IR/PassManager.h"

#include "llvm/IR/Type.h"

#include "llvm/IR/Use.h"

#include "llvm/IR/Value.h"

#include "llvm/InitializePasses.h"

#include "llvm/Pass.h"

#include "llvm/Support/Allocator.h"

#include "llvm/Support/ArrayRecycler.h"

#include "llvm/Support/AtomicOrdering.h"

#include "llvm/Support/Casting.h"

#include "llvm/Support/Compiler.h"

#include "llvm/Support/Debug.h"

#include "llvm/Support/raw_ostream.h"

#include "llvm/Transforms/Scalar.h"

#include "llvm/Transforms/Scalar/GVN.h"

#include "llvm/Transforms/Scalar/GVNExpression.h"

#include "llvm/Transforms/Utils/BasicBlockUtils.h"

#include "llvm/Transforms/Utils/Local.h"

#include <algorithm>

#include <cassert>

#include <cstddef>

#include <cstdint>

#include <iterator>

#include <utility>


using namespace llvm;


#define DEBUG_TYPE "gvn-sink"


STATISTIC(NumRemoved, "Number of instructions removed");


namespace llvm {

namespace GVNExpression {


LLVM_DUMP_METHOD void Expression::dump() const {

  print(dbgs());

  dbgs() << "\n";

}


} // end namespace GVNExpression

} // end namespace llvm


namespace {


static bool isMemoryInst(const Instruction *I) {

  return isa<LoadInst>(I) || isa<StoreInst>(I) ||

         (isa<InvokeInst>(I) && !cast<InvokeInst>(I)->doesNotAccessMemory()) ||

         (isa<CallInst>(I) && !cast<CallInst>(I)->doesNotAccessMemory());

}


/// Iterates through instructions in a set of blocks in reverse order from the

/// first non-terminator. For example (assume all blocks have size n):

///   LockstepReverseIterator I([B1, B2, B3]);

///   *I-- = [B1[n], B2[n], B3[n]];

///   *I-- = [B1[n-1], B2[n-1], B3[n-1]];

///   *I-- = [B1[n-2], B2[n-2], B3[n-2]];

///   ...

///

/// It continues until all blocks have been exhausted. Use \c getActiveBlocks()

/// to

/// determine which blocks are still going and the order they appear in the

/// list returned by operator*.

class LockstepReverseIterator {

  ArrayRef<BasicBlock *> Blocks;

  SmallSetVector<BasicBlock *, 4> ActiveBlocks;

  SmallVector<Instruction *, 4> Insts;

  bool Fail;


public:

  LockstepReverseIterator(ArrayRef<BasicBlock *> Blocks) : Blocks(Blocks) {

    reset();

  }


  void reset() {

    Fail = false;

    ActiveBlocks.clear();

    for (BasicBlock *BB : Blocks)

      ActiveBlocks.insert(BB);

    Insts.clear();

    for (BasicBlock *BB : Blocks) {

      if (BB->size() <= 1) {

        // Block wasn't big enough - only contained a terminator.

        ActiveBlocks.remove(BB);

        continue;

      }

      Insts.push_back(BB->getTerminator()->getPrevNode());

    }

    if (Insts.empty())

      Fail = true;

  }


  bool isValid() const { return !Fail; }

  ArrayRef<Instruction *> operator*() const { return Insts; }


  // Note: This needs to return a SmallSetVector as the elements of

  // ActiveBlocks will be later copied to Blocks using std::copy. The

  // resultant order of elements in Blocks needs to be deterministic.

  // Using SmallPtrSet instead causes non-deterministic order while

  // copying. And we cannot simply sort Blocks as they need to match the

  // corresponding Values.

  SmallSetVector<BasicBlock *, 4> &getActiveBlocks() { return ActiveBlocks; }


  void restrictToBlocks(SmallSetVector<BasicBlock *, 4> &Blocks) {

    for (auto II = Insts.begin(); II != Insts.end();) {

      if (!llvm::is_contained(Blocks, (*II)->getParent())) {

        ActiveBlocks.remove((*II)->getParent());

        II = Insts.erase(II);

      } else {

        ++II;

      }

    }

  }


  void operator--() {

    if (Fail)

      return;

    SmallVector<Instruction *, 4> NewInsts;

    for (auto *Inst : Insts) {

      if (Inst == &Inst->getParent()->front())

        ActiveBlocks.remove(Inst->getParent());

      else

        NewInsts.push_back(Inst->getPrevNode());

    }

    if (NewInsts.empty()) {

      Fail = true;

      return;

    }

    Insts = NewInsts;

  }

};


//===----------------------------------------------------------------------===//


/// Candidate solution for sinking. There may be different ways to

/// sink instructions, differing in the number of instructions sunk,

/// the number of predecessors sunk from and the number of PHIs

/// required.

struct SinkingInstructionCandidate {

  unsigned NumBlocks;

  unsigned NumInstructions;

  unsigned NumPHIs;

  unsigned NumMemoryInsts;

  int Cost = -1;

  SmallVector<BasicBlock *, 4> Blocks;


  void calculateCost(unsigned NumOrigPHIs, unsigned NumOrigBlocks) {

    unsigned NumExtraPHIs = NumPHIs - NumOrigPHIs;

    unsigned SplitEdgeCost = (NumOrigBlocks > NumBlocks) ? 2 : 0;

    Cost = (NumInstructions * (NumBlocks - 1)) -

           (NumExtraPHIs *

            NumExtraPHIs) // PHIs are expensive, so make sure they're worth it.

           - SplitEdgeCost;

  }


  bool operator>(const SinkingInstructionCandidate &Other) const {

    return Cost > Other.Cost;

  }

};


#ifndef NDEBUG

raw_ostream &operator<<(raw_ostream &OS, const SinkingInstructionCandidate &C) {

  OS << "<Candidate Cost=" << C.Cost << " #Blocks=" << C.NumBlocks

     << " #Insts=" << C.NumInstructions << " #PHIs=" << C.NumPHIs << ">";

  return OS;

}

#endif


//===----------------------------------------------------------------------===//


/// Describes a PHI node that may or may not exist. These track the PHIs

/// that must be created if we sunk a sequence of instructions. It provides

/// a hash function for efficient equality comparisons.

class ModelledPHI {

  SmallVector<Value *, 4> Values;

  SmallVector<BasicBlock *, 4> Blocks;


public:

  ModelledPHI() = default;


  ModelledPHI(const PHINode *PN) {

    // BasicBlock comes first so we sort by basic block pointer order, then by value pointer order.

    SmallVector<std::pair<BasicBlock *, Value *>, 4> Ops;

    for (unsigned I = 0, E = PN->getNumIncomingValues(); I != E; ++I)

      Ops.push_back({PN->getIncomingBlock(I), PN->getIncomingValue(I)});

    llvm::sort(Ops);

    for (auto &P : Ops) {

      Blocks.push_back(P.first);

      Values.push_back(P.second);

    }

  }


  /// Create a dummy ModelledPHI that will compare unequal to any other ModelledPHI

  /// without the same ID.

  /// \note This is specifically for DenseMapInfo - do not use this!

  static ModelledPHI createDummy(size_t ID) {

    ModelledPHI M;

    M.Values.push_back(reinterpret_cast<Value*>(ID));

    return M;

  }


  /// Create a PHI from an array of incoming values and incoming blocks.

  template <typename VArray, typename BArray>

  ModelledPHI(const VArray &V, const BArray &B) {

    llvm::copy(V, std::back_inserter(Values));

    llvm::copy(B, std::back_inserter(Blocks));

  }


  /// Create a PHI from [I[OpNum] for I in Insts].

  template <typename BArray>

  ModelledPHI(ArrayRef<Instruction *> Insts, unsigned OpNum, const BArray &B) {

    llvm::copy(B, std::back_inserter(Blocks));

    for (auto *I : Insts)

      Values.push_back(I->getOperand(OpNum));

  }


  /// Restrict the PHI's contents down to only \c NewBlocks.

  /// \c NewBlocks must be a subset of \c this->Blocks.

  void restrictToBlocks(const SmallSetVector<BasicBlock *, 4> &NewBlocks) {

    auto BI = Blocks.begin();

    auto VI = Values.begin();

    while (BI != Blocks.end()) {

      assert(VI != Values.end());

      if (!llvm::is_contained(NewBlocks, *BI)) {

        BI = Blocks.erase(BI);

        VI = Values.erase(VI);

      } else {

        ++BI;

        ++VI;

      }

    }

    assert(Blocks.size() == NewBlocks.size());

  }


  ArrayRef<Value *> getValues() const { return Values; }


  bool areAllIncomingValuesSame() const {

    return llvm::all_of(Values, [&](Value *V) { return V == Values[0]; });

  }


  bool areAllIncomingValuesSameType() const {

    return llvm::all_of(

        Values, [&](Value *V) { return V->getType() == Values[0]->getType(); });

  }


  bool areAnyIncomingValuesConstant() const {

    return llvm::any_of(Values, [&](Value *V) { return isa<Constant>(V); });

  }


  // Hash functor

  unsigned hash() const {

      return (unsigned)hash_combine_range(Values.begin(), Values.end());

  }


  bool operator==(const ModelledPHI &Other) const {

    return Values == Other.Values && Blocks == Other.Blocks;

  }

};


template <typename ModelledPHI> struct DenseMapInfo {

  static inline ModelledPHI &getEmptyKey() {

    static ModelledPHI Dummy = ModelledPHI::createDummy(0);

    return Dummy;

  }


  static inline ModelledPHI &getTombstoneKey() {

    static ModelledPHI Dummy = ModelledPHI::createDummy(1);

    return Dummy;

  }


  static unsigned getHashValue(const ModelledPHI &V) { return V.hash(); }


  static bool isEqual(const ModelledPHI &LHS, const ModelledPHI &RHS) {

    return LHS == RHS;

  }

};


using ModelledPHISet = DenseSet<ModelledPHI, DenseMapInfo<ModelledPHI>>;


//===----------------------------------------------------------------------===//

//                             ValueTable

//===----------------------------------------------------------------------===//

// This is a value number table where the value number is a function of the

// *uses* of a value, rather than its operands. Thus, if VN(A) == VN(B) we know

// that the program would be equivalent if we replaced A with PHI(A, B).

//===----------------------------------------------------------------------===//


/// A GVN expression describing how an instruction is used. The operands

/// field of BasicExpression is used to store uses, not operands.

///

/// This class also contains fields for discriminators used when determining

/// equivalence of instructions with sideeffects.

class InstructionUseExpr : public GVNExpression::BasicExpression {

  unsigned MemoryUseOrder = -1;

  bool Volatile = false;

  ArrayRef<int> ShuffleMask;


public:

  InstructionUseExpr(Instruction *I, ArrayRecycler<Value *> &R,

                     BumpPtrAllocator &A)

      : GVNExpression::BasicExpression(I->getNumUses()) {

    allocateOperands(R, A);

    setOpcode(I->getOpcode());

    setType(I->getType());


    if (ShuffleVectorInst *SVI = dyn_cast<ShuffleVectorInst>(I))

      ShuffleMask = SVI->getShuffleMask().copy(A);


    for (auto &U : I->uses())

      op_push_back(U.getUser());

    llvm::sort(op_begin(), op_end());

  }


  void setMemoryUseOrder(unsigned MUO) { MemoryUseOrder = MUO; }

  void setVolatile(bool V) { Volatile = V; }


  hash_code getHashValue() const override {

    return hash_combine(GVNExpression::BasicExpression::getHashValue(),

                        MemoryUseOrder, Volatile, ShuffleMask);

  }


  template <typename Function> hash_code getHashValue(Function MapFn) {

    hash_code H = hash_combine(getOpcode(), getType(), MemoryUseOrder, Volatile,

                               ShuffleMask);

    for (auto *V : operands())

      H = hash_combine(H, MapFn(V));

    return H;

  }

};


class ValueTable {

  DenseMap<Value *, uint32_t> ValueNumbering;

  DenseMap<GVNExpression::Expression *, uint32_t> ExpressionNumbering;

  DenseMap<size_t, uint32_t> HashNumbering;

  BumpPtrAllocator Allocator;

  ArrayRecycler<Value *> Recycler;

  uint32_t nextValueNumber = 1;


  /// Create an expression for I based on its opcode and its uses. If I

  /// touches or reads memory, the expression is also based upon its memory

  /// order - see \c getMemoryUseOrder().

  InstructionUseExpr *createExpr(Instruction *I) {

    InstructionUseExpr *E =

        new (Allocator) InstructionUseExpr(I, Recycler, Allocator);

    if (isMemoryInst(I))

      E->setMemoryUseOrder(getMemoryUseOrder(I));


    if (CmpInst *C = dyn_cast<CmpInst>(I)) {

      CmpInst::Predicate Predicate = C->getPredicate();

      E->setOpcode((C->getOpcode() << 8) | Predicate);

    }

    return E;

  }


  /// Helper to compute the value number for a memory instruction

  /// (LoadInst/StoreInst), including checking the memory ordering and

  /// volatility.

  template <class Inst> InstructionUseExpr *createMemoryExpr(Inst *I) {

    if (isStrongerThanUnordered(I->getOrdering()) || I->isAtomic())

      return nullptr;

    InstructionUseExpr *E = createExpr(I);

    E->setVolatile(I->isVolatile());

    return E;

  }


public:

  ValueTable() = default;


  /// Returns the value number for the specified value, assigning

  /// it a new number if it did not have one before.

  uint32_t lookupOrAdd(Value *V) {

    auto VI = ValueNumbering.find(V);

    if (VI != ValueNumbering.end())

      return VI->second;


    if (!isa<Instruction>(V)) {

      ValueNumbering[V] = nextValueNumber;

      return nextValueNumber++;

    }


    Instruction *I = cast<Instruction>(V);

    InstructionUseExpr *exp = nullptr;

    switch (I->getOpcode()) {

    case Instruction::Load:

      exp = createMemoryExpr(cast<LoadInst>(I));

      break;

    case Instruction::Store:

      exp = createMemoryExpr(cast<StoreInst>(I));

      break;

    case Instruction::Call:

    case Instruction::Invoke:

    case Instruction::FNeg:

    case Instruction::Add:

    case Instruction::FAdd:

    case Instruction::Sub:

    case Instruction::FSub:

    case Instruction::Mul:

    case Instruction::FMul:

    case Instruction::UDiv:

    case Instruction::SDiv:

    case Instruction::FDiv:

    case Instruction::URem:

    case Instruction::SRem:

    case Instruction::FRem:

    case Instruction::Shl:

    case Instruction::LShr:

    case Instruction::AShr:

    case Instruction::And:

    case Instruction::Or:

    case Instruction::Xor:

    case Instruction::ICmp:

    case Instruction::FCmp:

    case Instruction::Trunc:

    case Instruction::ZExt:

    case Instruction::SExt:

    case Instruction::FPToUI:

    case Instruction::FPToSI:

    case Instruction::UIToFP:

    case Instruction::SIToFP:

    case Instruction::FPTrunc:

    case Instruction::FPExt:

    case Instruction::PtrToInt:

    case Instruction::IntToPtr:

    case Instruction::BitCast:

    case Instruction::AddrSpaceCast:

    case Instruction::Select:

    case Instruction::ExtractElement:

    case Instruction::InsertElement:

    case Instruction::ShuffleVector:

    case Instruction::InsertValue:

    case Instruction::GetElementPtr:

      exp = createExpr(I);

      break;

    default:

      break;

    }


    if (!exp) {

      ValueNumbering[V] = nextValueNumber;

      return nextValueNumber++;

    }


    uint32_t e = ExpressionNumbering[exp];

    if (!e) {

      hash_code H = exp->getHashValue([=](Value *V) { return lookupOrAdd(V); });

      auto I = HashNumbering.find(H);

      if (I != HashNumbering.end()) {

        e = I->second;

      } else {

        e = nextValueNumber++;

        HashNumbering[H] = e;

        ExpressionNumbering[exp] = e;

      }

    }

    ValueNumbering[V] = e;

    return e;

  }


  /// Returns the value number of the specified value. Fails if the value has

  /// not yet been numbered.

  uint32_t lookup(Value *V) const {

    auto VI = ValueNumbering.find(V);

    assert(VI != ValueNumbering.end() && "Value not numbered?");

    return VI->second;

  }


  /// Removes all value numberings and resets the value table.

  void clear() {

    ValueNumbering.clear();

    ExpressionNumbering.clear();

    HashNumbering.clear();

    Recycler.clear(Allocator);

    nextValueNumber = 1;

  }


  /// \c Inst uses or touches memory. Return an ID describing the memory state

  /// at \c Inst such that if getMemoryUseOrder(I1) == getMemoryUseOrder(I2),

  /// the exact same memory operations happen after I1 and I2.

  ///

  /// This is a very hard problem in general, so we use domain-specific

  /// knowledge that we only ever check for equivalence between blocks sharing a

  /// single immediate successor that is common, and when determining if I1 ==

  /// I2 we will have already determined that next(I1) == next(I2). This

  /// inductive property allows us to simply return the value number of the next

  /// instruction that defines memory.

  uint32_t getMemoryUseOrder(Instruction *Inst) {

    auto *BB = Inst->getParent();

    for (auto I = std::next(Inst->getIterator()), E = BB->end();

         I != E && !I->isTerminator(); ++I) {

      if (!isMemoryInst(&*I))

        continue;

      if (isa<LoadInst>(&*I))

        continue;

      CallInst *CI = dyn_cast<CallInst>(&*I);

      if (CI && CI->onlyReadsMemory())

        continue;

      InvokeInst *II = dyn_cast<InvokeInst>(&*I);

      if (II && II->onlyReadsMemory())

        continue;

      return lookupOrAdd(&*I);

    }

    return 0;

  }

};


//===----------------------------------------------------------------------===//


class GVNSink {

public:

  GVNSink() = default;


  bool run(Function &F) {

    LLVM_DEBUG(dbgs() << "GVNSink: running on function @" << F.getName()

                      << "\n");


    unsigned NumSunk = 0;

    ReversePostOrderTraversal<Function*> RPOT(&F);

    for (auto *N : RPOT)

      NumSunk += sinkBB(N);


    return NumSunk > 0;

  }


private:

  ValueTable VN;


  bool shouldAvoidSinkingInstruction(Instruction *I) {

    // These instructions may change or break semantics if moved.

    if (isa<PHINode>(I) || I->isEHPad() || isa<AllocaInst>(I) ||

        I->getType()->isTokenTy())

      return true;

    return false;

  }


  /// The main heuristic function. Analyze the set of instructions pointed to by

  /// LRI and return a candidate solution if these instructions can be sunk, or

  /// None otherwise.

  Optional<SinkingInstructionCandidate> analyzeInstructionForSinking(

      LockstepReverseIterator &LRI, unsigned &InstNum, unsigned &MemoryInstNum,

      ModelledPHISet &NeededPHIs, SmallPtrSetImpl<Value *> &PHIContents);


  /// Create a ModelledPHI for each PHI in BB, adding to PHIs.

  void analyzeInitialPHIs(BasicBlock *BB, ModelledPHISet &PHIs,

                          SmallPtrSetImpl<Value *> &PHIContents) {

    for (PHINode &PN : BB->phis()) {

      auto MPHI = ModelledPHI(&PN);

      PHIs.insert(MPHI);

      for (auto *V : MPHI.getValues())

        PHIContents.insert(V);

    }

  }


  /// The main instruction sinking driver. Set up state and try and sink

  /// instructions into BBEnd from its predecessors.

  unsigned sinkBB(BasicBlock *BBEnd);


  /// Perform the actual mechanics of sinking an instruction from Blocks into

  /// BBEnd, which is their only successor.

  void sinkLastInstruction(ArrayRef<BasicBlock *> Blocks, BasicBlock *BBEnd);


  /// Remove PHIs that all have the same incoming value.

  void foldPointlessPHINodes(BasicBlock *BB) {

    auto I = BB->begin();

    while (PHINode *PN = dyn_cast<PHINode>(I++)) {

      if (!llvm::all_of(PN->incoming_values(), [&](const Value *V) {

            return V == PN->getIncomingValue(0);

          }))

        continue;

      if (PN->getIncomingValue(0) != PN)

        PN->replaceAllUsesWith(PN->getIncomingValue(0));

      else

        PN->replaceAllUsesWith(UndefValue::get(PN->getType()));

      PN->eraseFromParent();

    }

  }

};


Optional<SinkingInstructionCandidate> GVNSink::analyzeInstructionForSinking(

  LockstepReverseIterator &LRI, unsigned &InstNum, unsigned &MemoryInstNum,

  ModelledPHISet &NeededPHIs, SmallPtrSetImpl<Value *> &PHIContents) {

  auto Insts = *LRI;

  LLVM_DEBUG(dbgs() << " -- Analyzing instruction set: [\n"; for (auto *I

                                                                  : Insts) {

    I->dump();

  } dbgs() << " ]\n";);


  DenseMap<uint32_t, unsigned> VNums;

  for (auto *I : Insts) {

    uint32_t N = VN.lookupOrAdd(I);

    LLVM_DEBUG(dbgs() << " VN=" << Twine::utohexstr(N) << " for" << *I << "\n");

    if (N == ~0U)

      return None;

    VNums[N]++;

  }

  unsigned VNumToSink =

      std::max_element(VNums.begin(), VNums.end(),

                       [](const std::pair<uint32_t, unsigned> &I,

                          const std::pair<uint32_t, unsigned> &J) {

                         return I.second < J.second;

                       })

          ->first;


  if (VNums[VNumToSink] == 1)

    // Can't sink anything!

    return None;


  // Now restrict the number of incoming blocks down to only those with

  // VNumToSink.

  auto &ActivePreds = LRI.getActiveBlocks();

  unsigned InitialActivePredSize = ActivePreds.size();

  SmallVector<Instruction *, 4> NewInsts;

  for (auto *I : Insts) {

    if (VN.lookup(I) != VNumToSink)

      ActivePreds.remove(I->getParent());

    else

      NewInsts.push_back(I);

  }

  for (auto *I : NewInsts)

    if (shouldAvoidSinkingInstruction(I))

      return None;


  // If we've restricted the incoming blocks, restrict all needed PHIs also

  // to that set.

  bool RecomputePHIContents = false;

  if (ActivePreds.size() != InitialActivePredSize) {

    ModelledPHISet NewNeededPHIs;

    for (auto P : NeededPHIs) {

      P.restrictToBlocks(ActivePreds);

      NewNeededPHIs.insert(P);

    }

    NeededPHIs = NewNeededPHIs;

    LRI.restrictToBlocks(ActivePreds);

    RecomputePHIContents = true;

  }


  // The sunk instruction's results.

  ModelledPHI NewPHI(NewInsts, ActivePreds);


  // Does sinking this instruction render previous PHIs redundant?

  if (NeededPHIs.erase(NewPHI))

    RecomputePHIContents = true;


  if (RecomputePHIContents) {

    // The needed PHIs have changed, so recompute the set of all needed

    // values.

    PHIContents.clear();

    for (auto &PHI : NeededPHIs)

      PHIContents.insert(PHI.getValues().begin(), PHI.getValues().end());

  }


  // Is this instruction required by a later PHI that doesn't match this PHI?

  // if so, we can't sink this instruction.

  for (auto *V : NewPHI.getValues())

    if (PHIContents.count(V))

      // V exists in this PHI, but the whole PHI is different to NewPHI

      // (else it would have been removed earlier). We cannot continue

      // because this isn't representable.

      return None;


  // Which operands need PHIs?

  // FIXME: If any of these fail, we should partition up the candidates to

  // try and continue making progress.

  Instruction *I0 = NewInsts[0];


  // If all instructions that are going to participate don't have the same

  // number of operands, we can't do any useful PHI analysis for all operands.

  auto hasDifferentNumOperands = [&I0](Instruction *I) {

    return I->getNumOperands() != I0->getNumOperands();

  };

  if (any_of(NewInsts, hasDifferentNumOperands))

    return None;


  for (unsigned OpNum = 0, E = I0->getNumOperands(); OpNum != E; ++OpNum) {

    ModelledPHI PHI(NewInsts, OpNum, ActivePreds);

    if (PHI.areAllIncomingValuesSame())

      continue;

    if (!canReplaceOperandWithVariable(I0, OpNum))

      // We can 't create a PHI from this instruction!

      return None;

    if (NeededPHIs.count(PHI))

      continue;

    if (!PHI.areAllIncomingValuesSameType())

      return None;

    // Don't create indirect calls! The called value is the final operand.

    if ((isa<CallInst>(I0) || isa<InvokeInst>(I0)) && OpNum == E - 1 &&

        PHI.areAnyIncomingValuesConstant())

      return None;


    NeededPHIs.reserve(NeededPHIs.size());

    NeededPHIs.insert(PHI);

    PHIContents.insert(PHI.getValues().begin(), PHI.getValues().end());

  }


  if (isMemoryInst(NewInsts[0]))

    ++MemoryInstNum;


  SinkingInstructionCandidate Cand;

  Cand.NumInstructions = ++InstNum;

  Cand.NumMemoryInsts = MemoryInstNum;

  Cand.NumBlocks = ActivePreds.size();

  Cand.NumPHIs = NeededPHIs.size();

  append_range(Cand.Blocks, ActivePreds);


  return Cand;

}


unsigned GVNSink::sinkBB(BasicBlock *BBEnd) {

  LLVM_DEBUG(dbgs() << "GVNSink: running on basic block ";

             BBEnd->printAsOperand(dbgs()); dbgs() << "\n");

  SmallVector<BasicBlock *, 4> Preds;

  for (auto *B : predecessors(BBEnd)) {

    auto *T = B->getTerminator();

    if (isa<BranchInst>(T) || isa<SwitchInst>(T))

      Preds.push_back(B);

    else

      return 0;

  }

  if (Preds.size() < 2)

    return 0;

  llvm::sort(Preds);


  unsigned NumOrigPreds = Preds.size();

  // We can only sink instructions through unconditional branches.

  for (auto I = Preds.begin(); I != Preds.end();) {

    if ((*I)->getTerminator()->getNumSuccessors() != 1)

      I = Preds.erase(I);

    else

      ++I;

  }


  LockstepReverseIterator LRI(Preds);

  SmallVector<SinkingInstructionCandidate, 4> Candidates;

  unsigned InstNum = 0, MemoryInstNum = 0;

  ModelledPHISet NeededPHIs;

  SmallPtrSet<Value *, 4> PHIContents;

  analyzeInitialPHIs(BBEnd, NeededPHIs, PHIContents);

  unsigned NumOrigPHIs = NeededPHIs.size();


  while (LRI.isValid()) {

    auto Cand = analyzeInstructionForSinking(LRI, InstNum, MemoryInstNum,

                                             NeededPHIs, PHIContents);

    if (!Cand)

      break;

    Cand->calculateCost(NumOrigPHIs, Preds.size());

    Candidates.emplace_back(*Cand);

    --LRI;

  }


  llvm::stable_sort(Candidates, std::greater<SinkingInstructionCandidate>());

  LLVM_DEBUG(dbgs() << " -- Sinking candidates:\n"; for (auto &C

                                                         : Candidates) dbgs()

                                                    << "  " << C << "\n";);


  // Pick the top candidate, as long it is positive!

  if (Candidates.empty() || Candidates.front().Cost <= 0)

    return 0;

  auto C = Candidates.front();


  LLVM_DEBUG(dbgs() << " -- Sinking: " << C << "\n");

  BasicBlock *InsertBB = BBEnd;

  if (C.Blocks.size() < NumOrigPreds) {

    LLVM_DEBUG(dbgs() << " -- Splitting edge to ";

               BBEnd->printAsOperand(dbgs()); dbgs() << "\n");

    InsertBB = SplitBlockPredecessors(BBEnd, C.Blocks, ".gvnsink.split");

    if (!InsertBB) {

      LLVM_DEBUG(dbgs() << " -- FAILED to split edge!\n");

      // Edge couldn't be split.

      return 0;

    }

  }


  for (unsigned I = 0; I < C.NumInstructions; ++I)

    sinkLastInstruction(C.Blocks, InsertBB);


  return C.NumInstructions;

}


void GVNSink::sinkLastInstruction(ArrayRef<BasicBlock *> Blocks,

                                  BasicBlock *BBEnd) {

  SmallVector<Instruction *, 4> Insts;

  for (BasicBlock *BB : Blocks)

    Insts.push_back(BB->getTerminator()->getPrevNode());

  Instruction *I0 = Insts.front();


  SmallVector<Value *, 4> NewOperands;

  for (unsigned O = 0, E = I0->getNumOperands(); O != E; ++O) {

    bool NeedPHI = llvm::any_of(Insts, [&I0, O](const Instruction *I) {

      return I->getOperand(O) != I0->getOperand(O);

    });

    if (!NeedPHI) {

      NewOperands.push_back(I0->getOperand(O));

      continue;

    }


    // Create a new PHI in the successor block and populate it.

    auto *Op = I0->getOperand(O);

    assert(!Op->getType()->isTokenTy() && "Can't PHI tokens!");

    auto *PN = PHINode::Create(Op->getType(), Insts.size(),

                               Op->getName() + ".sink", &BBEnd->front());

    for (auto *I : Insts)

      PN->addIncoming(I->getOperand(O), I->getParent());

    NewOperands.push_back(PN);

  }


  // Arbitrarily use I0 as the new "common" instruction; remap its operands

  // and move it to the start of the successor block.

  for (unsigned O = 0, E = I0->getNumOperands(); O != E; ++O)

    I0->getOperandUse(O).set(NewOperands[O]);

  I0->moveBefore(&*BBEnd->getFirstInsertionPt());


  // Update metadata and IR flags.

  for (auto *I : Insts)

    if (I != I0) {

      combineMetadataForCSE(I0, I, true);

      I0->andIRFlags(I);

    }


  for (auto *I : Insts)

    if (I != I0)

      I->replaceAllUsesWith(I0);

  foldPointlessPHINodes(BBEnd);


  // Finally nuke all instructions apart from the common instruction.

  for (auto *I : Insts)

    if (I != I0)

      I->eraseFromParent();


  NumRemoved += Insts.size() - 1;

}


////////////////////////////////////////////////////////////////////////////////

// Pass machinery / boilerplate


class GVNSinkLegacyPass : public FunctionPass {

public:

  static char ID;


  GVNSinkLegacyPass() : FunctionPass(ID) {

    initializeGVNSinkLegacyPassPass(*PassRegistry::getPassRegistry());

  }


  bool runOnFunction(Function &F) override {

    if (skipFunction(F))

      return false;

    GVNSink G;

    return G.run(F);

  }


  void getAnalysisUsage(AnalysisUsage &AU) const override {

    AU.addPreserved<GlobalsAAWrapperPass>();

  }

};


} // end anonymous namespace


PreservedAnalyses GVNSinkPass::run(Function &F, FunctionAnalysisManager &AM) {

  GVNSink G;

  if (!G.run(F))

    return PreservedAnalyses::all();

  return PreservedAnalyses::none();

}


char GVNSinkLegacyPass::ID = 0;


INITIALIZE_PASS_BEGIN(GVNSinkLegacyPass, "gvn-sink",

                      "Early GVN sinking of Expressions", false, false)

INITIALIZE_PASS_DEPENDENCY(DominatorTreeWrapperPass)

INITIALIZE_PASS_DEPENDENCY(PostDominatorTreeWrapperPass)

INITIALIZE_PASS_END(GVNSinkLegacyPass, "gvn-sink",

                    "Early GVN sinking of Expressions", false, false)


FunctionPass *llvm::createGVNSinkPass() { return new GVNSinkLegacyPass(); }