lib/Analysis/MemorySSAUpdater.cpp - llvm - Git at Google

 //===-- MemorySSAUpdater.cpp - Memory SSA Updater--------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------===//
 //
 // This file implements the MemorySSAUpdater class.
 //
 //===----------------------------------------------------------------===//
 #include "llvm/Analysis/MemorySSAUpdater.h"
 #include "llvm/ADT/STLExtras.h"
 #include "llvm/ADT/SmallPtrSet.h"
 #include "llvm/ADT/SmallSet.h"
 #include "llvm/Analysis/MemorySSA.h"
 #include "llvm/IR/DataLayout.h"
 #include "llvm/IR/Dominators.h"
 #include "llvm/IR/GlobalVariable.h"
 #include "llvm/IR/IRBuilder.h"
 #include "llvm/IR/IntrinsicInst.h"
 #include "llvm/IR/LLVMContext.h"
 #include "llvm/IR/Metadata.h"
 #include "llvm/IR/Module.h"
 #include "llvm/Support/Debug.h"
 #include "llvm/Support/FormattedStream.h"
 #include <algorithm>

 #define DEBUG_TYPE "memoryssa"
 using namespace llvm;

 // This is the marker algorithm from "Simple and Efficient Construction of
 // Static Single Assignment Form"
 // The simple, non-marker algorithm places phi nodes at any join
 // Here, we place markers, and only place phi nodes if they end up necessary.
 // They are only necessary if they break a cycle (IE we recursively visit
 // ourselves again), or we discover, while getting the value of the operands,
 // that there are two or more definitions needing to be merged.
 // This still will leave non-minimal form in the case of irreducible control
 // flow, where phi nodes may be in cycles with themselves, but unnecessary.
 MemoryAccess *MemorySSAUpdater::getPreviousDefRecursive(BasicBlock *BB) {
   // Single predecessor case, just recurse, we can only have one definition.
   if (BasicBlock *Pred = BB->getSinglePredecessor()) {
     return getPreviousDefFromEnd(Pred);
   } else if (VisitedBlocks.count(BB)) {
     // We hit our node again, meaning we had a cycle, we must insert a phi
     // node to break it so we have an operand. The only case this will
     // insert useless phis is if we have irreducible control flow.
     return MSSA->createMemoryPhi(BB);
   } else if (VisitedBlocks.insert(BB).second) {
     // Mark us visited so we can detect a cycle
     SmallVector<MemoryAccess *, 8> PhiOps;

     // Recurse to get the values in our predecessors for placement of a
     // potential phi node. This will insert phi nodes if we cycle in order to
     // break the cycle and have an operand.
     for (auto *Pred : predecessors(BB))
       PhiOps.push_back(getPreviousDefFromEnd(Pred));

     // Now try to simplify the ops to avoid placing a phi.
     // This may return null if we never created a phi yet, that's okay
     MemoryPhi *Phi = dyn_cast_or_null<MemoryPhi>(MSSA->getMemoryAccess(BB));
     bool PHIExistsButNeedsUpdate = false;
     // See if the existing phi operands match what we need.
     // Unlike normal SSA, we only allow one phi node per block, so we can't just
     // create a new one.
     if (Phi && Phi->getNumOperands() != 0)
       if (!std::equal(Phi->op_begin(), Phi->op_end(), PhiOps.begin())) {
         PHIExistsButNeedsUpdate = true;
       }

     // See if we can avoid the phi by simplifying it.
     auto *Result = tryRemoveTrivialPhi(Phi, PhiOps);
     // If we couldn't simplify, we may have to create a phi
     if (Result == Phi) {
       if (!Phi)
         Phi = MSSA->createMemoryPhi(BB);

       // These will have been filled in by the recursive read we did above.
       if (PHIExistsButNeedsUpdate) {
         std::copy(PhiOps.begin(), PhiOps.end(), Phi->op_begin());
         std::copy(pred_begin(BB), pred_end(BB), Phi->block_begin());
       } else {
         unsigned i = 0;
         for (auto *Pred : predecessors(BB))
           Phi->addIncoming(PhiOps[i++], Pred);
         InsertedPHIs.push_back(Phi);
       }
       Result = Phi;
     }

     // Set ourselves up for the next variable by resetting visited state.
     VisitedBlocks.erase(BB);
     return Result;
   }
   llvm_unreachable("Should have hit one of the three cases above");
 }

 // This starts at the memory access, and goes backwards in the block to find the
 // previous definition. If a definition is not found the block of the access,
 // it continues globally, creating phi nodes to ensure we have a single
 // definition.
 MemoryAccess *MemorySSAUpdater::getPreviousDef(MemoryAccess *MA) {
   auto *LocalResult = getPreviousDefInBlock(MA);

   return LocalResult ? LocalResult : getPreviousDefRecursive(MA->getBlock());
 }

 // This starts at the memory access, and goes backwards in the block to the find
 // the previous definition. If the definition is not found in the block of the
 // access, it returns nullptr.
 MemoryAccess *MemorySSAUpdater::getPreviousDefInBlock(MemoryAccess *MA) {
   auto *Defs = MSSA->getWritableBlockDefs(MA->getBlock());

   // It's possible there are no defs, or we got handed the first def to start.
   if (Defs) {
     // If this is a def, we can just use the def iterators.
     if (!isa<MemoryUse>(MA)) {
       auto Iter = MA->getReverseDefsIterator();
       ++Iter;
       if (Iter != Defs->rend())
         return &*Iter;
     } else {
       // Otherwise, have to walk the all access iterator.
       auto End = MSSA->getWritableBlockAccesses(MA->getBlock())->rend();
       for (auto &U : make_range(++MA->getReverseIterator(), End))
         if (!isa<MemoryUse>(U))
           return cast<MemoryAccess>(&U);
       // Note that if MA comes before Defs->begin(), we won't hit a def.
       return nullptr;
     }
   }
   return nullptr;
 }

 // This starts at the end of block
 MemoryAccess *MemorySSAUpdater::getPreviousDefFromEnd(BasicBlock *BB) {
   auto *Defs = MSSA->getWritableBlockDefs(BB);

   if (Defs)
     return &*Defs->rbegin();

   return getPreviousDefRecursive(BB);
 }
 // Recurse over a set of phi uses to eliminate the trivial ones
 MemoryAccess *MemorySSAUpdater::recursePhi(MemoryAccess *Phi) {
   if (!Phi)
     return nullptr;
   TrackingVH<MemoryAccess> Res(Phi);
   SmallVector<TrackingVH<Value>, 8> Uses;
   std::copy(Phi->user_begin(), Phi->user_end(), std::back_inserter(Uses));
   for (auto &U : Uses) {
     if (MemoryPhi *UsePhi = dyn_cast<MemoryPhi>(&*U)) {
       auto OperRange = UsePhi->operands();
       tryRemoveTrivialPhi(UsePhi, OperRange);
     }
   }
   return Res;
 }

 // Eliminate trivial phis
 // Phis are trivial if they are defined either by themselves, or all the same
 // argument.
 // IE phi(a, a) or b = phi(a, b) or c = phi(a, a, c)
 // We recursively try to remove them.
 template <class RangeType>
 MemoryAccess *MemorySSAUpdater::tryRemoveTrivialPhi(MemoryPhi *Phi,
                                                     RangeType &Operands) {
   // Detect equal or self arguments
   MemoryAccess *Same = nullptr;
   for (auto &Op : Operands) {
     // If the same or self, good so far
     if (Op == Phi || Op == Same)
       continue;
     // not the same, return the phi since it's not eliminatable by us
     if (Same)
       return Phi;
     Same = cast<MemoryAccess>(Op);
   }
   // Never found a non-self reference, the phi is undef
   if (Same == nullptr)
     return MSSA->getLiveOnEntryDef();
   if (Phi) {
     Phi->replaceAllUsesWith(Same);
     removeMemoryAccess(Phi);
   }

   // We should only end up recursing in case we replaced something, in which
   // case, we may have made other Phis trivial.
   return recursePhi(Same);
 }

 void MemorySSAUpdater::insertUse(MemoryUse *MU) {
   InsertedPHIs.clear();
   MU->setDefiningAccess(getPreviousDef(MU));
   // Unlike for defs, there is no extra work to do.  Because uses do not create
   // new may-defs, there are only two cases:
   //
   // 1. There was a def already below us, and therefore, we should not have
   // created a phi node because it was already needed for the def.
   //
   // 2. There is no def below us, and therefore, there is no extra renaming work
   // to do.
 }

 // Set every incoming edge {BB, MP->getBlock()} of MemoryPhi MP to NewDef.
 static void setMemoryPhiValueForBlock(MemoryPhi *MP, const BasicBlock *BB,
                                       MemoryAccess *NewDef) {
   // Replace any operand with us an incoming block with the new defining
   // access.
   int i = MP->getBasicBlockIndex(BB);
   assert(i != -1 && "Should have found the basic block in the phi");
   // We can't just compare i against getNumOperands since one is signed and the
   // other not. So use it to index into the block iterator.
   for (auto BBIter = MP->block_begin() + i; BBIter != MP->block_end();
        ++BBIter) {
     if (*BBIter != BB)
       break;
     MP->setIncomingValue(i, NewDef);
     ++i;
   }
 }

 // A brief description of the algorithm:
 // First, we compute what should define the new def, using the SSA
 // construction algorithm.
 // Then, we update the defs below us (and any new phi nodes) in the graph to
 // point to the correct new defs, to ensure we only have one variable, and no
 // disconnected stores.
 void MemorySSAUpdater::insertDef(MemoryDef *MD, bool RenameUses) {
   InsertedPHIs.clear();

   // See if we had a local def, and if not, go hunting.
   MemoryAccess *DefBefore = getPreviousDefInBlock(MD);
   bool DefBeforeSameBlock = DefBefore != nullptr;
   if (!DefBefore)
     DefBefore = getPreviousDefRecursive(MD->getBlock());

   // There is a def before us, which means we can replace any store/phi uses
   // of that thing with us, since we are in the way of whatever was there
   // before.
   // We now define that def's memorydefs and memoryphis
   if (DefBeforeSameBlock) {
     for (auto UI = DefBefore->use_begin(), UE = DefBefore->use_end();
          UI != UE;) {
       Use &U = *UI++;
       // Leave the uses alone
       if (isa<MemoryUse>(U.getUser()))
         continue;
       U.set(MD);
     }
   }

   // and that def is now our defining access.
   // We change them in this order otherwise we will appear in the use list
   // above and reset ourselves.
   MD->setDefiningAccess(DefBefore);

   SmallVector<MemoryAccess *, 8> FixupList(InsertedPHIs.begin(),
                                            InsertedPHIs.end());
   if (!DefBeforeSameBlock) {
     // If there was a local def before us, we must have the same effect it
     // did. Because every may-def is the same, any phis/etc we would create, it
     // would also have created.  If there was no local def before us, we
     // performed a global update, and have to search all successors and make
     // sure we update the first def in each of them (following all paths until
     // we hit the first def along each path). This may also insert phi nodes.
     // TODO: There are other cases we can skip this work, such as when we have a
     // single successor, and only used a straight line of single pred blocks
     // backwards to find the def.  To make that work, we'd have to track whether
     // getDefRecursive only ever used the single predecessor case.  These types
     // of paths also only exist in between CFG simplifications.
     FixupList.push_back(MD);
   }

   while (!FixupList.empty()) {
     unsigned StartingPHISize = InsertedPHIs.size();
     fixupDefs(FixupList);
     FixupList.clear();
     // Put any new phis on the fixup list, and process them
     FixupList.append(InsertedPHIs.end() - StartingPHISize, InsertedPHIs.end());
   }
   // Now that all fixups are done, rename all uses if we are asked.
   if (RenameUses) {
     SmallPtrSet<BasicBlock *, 16> Visited;
     BasicBlock *StartBlock = MD->getBlock();
     // We are guaranteed there is a def in the block, because we just got it
     // handed to us in this function.
     MemoryAccess *FirstDef = &*MSSA->getWritableBlockDefs(StartBlock)->begin();
     // Convert to incoming value if it's a memorydef. A phi *is* already an
     // incoming value.
     if (auto *MD = dyn_cast<MemoryDef>(FirstDef))
       FirstDef = MD->getDefiningAccess();

     MSSA->renamePass(MD->getBlock(), FirstDef, Visited);
     // We just inserted a phi into this block, so the incoming value will become
     // the phi anyway, so it does not matter what we pass.
     for (auto *MP : InsertedPHIs)
       MSSA->renamePass(MP->getBlock(), nullptr, Visited);
   }
 }

 void MemorySSAUpdater::fixupDefs(const SmallVectorImpl<MemoryAccess *> &Vars) {
   SmallPtrSet<const BasicBlock *, 8> Seen;
   SmallVector<const BasicBlock *, 16> Worklist;
   for (auto *NewDef : Vars) {
     // First, see if there is a local def after the operand.
     auto *Defs = MSSA->getWritableBlockDefs(NewDef->getBlock());
     auto DefIter = NewDef->getDefsIterator();

     // If there is a local def after us, we only have to rename that.
     if (++DefIter != Defs->end()) {
       cast<MemoryDef>(DefIter)->setDefiningAccess(NewDef);
       continue;
     }

     // Otherwise, we need to search down through the CFG.
     // For each of our successors, handle it directly if their is a phi, or
     // place on the fixup worklist.
     for (const auto *S : successors(NewDef->getBlock())) {
       if (auto *MP = MSSA->getMemoryAccess(S))
         setMemoryPhiValueForBlock(MP, NewDef->getBlock(), NewDef);
       else
         Worklist.push_back(S);
     }

     while (!Worklist.empty()) {
       const BasicBlock *FixupBlock = Worklist.back();
       Worklist.pop_back();

       // Get the first def in the block that isn't a phi node.
       if (auto *Defs = MSSA->getWritableBlockDefs(FixupBlock)) {
         auto *FirstDef = &*Defs->begin();
         // The loop above and below should have taken care of phi nodes
         assert(!isa<MemoryPhi>(FirstDef) &&
                "Should have already handled phi nodes!");
         // We are now this def's defining access, make sure we actually dominate
         // it
         assert(MSSA->dominates(NewDef, FirstDef) &&
                "Should have dominated the new access");

         // This may insert new phi nodes, because we are not guaranteed the
         // block we are processing has a single pred, and depending where the
         // store was inserted, it may require phi nodes below it.
         cast<MemoryDef>(FirstDef)->setDefiningAccess(getPreviousDef(FirstDef));
         return;
       }
       // We didn't find a def, so we must continue.
       for (const auto *S : successors(FixupBlock)) {
         // If there is a phi node, handle it.
         // Otherwise, put the block on the worklist
         if (auto *MP = MSSA->getMemoryAccess(S))
           setMemoryPhiValueForBlock(MP, FixupBlock, NewDef);
         else {
           // If we cycle, we should have ended up at a phi node that we already
           // processed.  FIXME: Double check this
           if (!Seen.insert(S).second)
             continue;
           Worklist.push_back(S);
         }
       }
     }
   }
 }

 // Move What before Where in the MemorySSA IR.
 template <class WhereType>
 void MemorySSAUpdater::moveTo(MemoryUseOrDef *What, BasicBlock *BB,
                               WhereType Where) {
   // Replace all our users with our defining access.
   What->replaceAllUsesWith(What->getDefiningAccess());

   // Let MemorySSA take care of moving it around in the lists.
   MSSA->moveTo(What, BB, Where);

   // Now reinsert it into the IR and do whatever fixups needed.
   if (auto *MD = dyn_cast<MemoryDef>(What))
     insertDef(MD);
   else
     insertUse(cast<MemoryUse>(What));
 }

 // Move What before Where in the MemorySSA IR.
 void MemorySSAUpdater::moveBefore(MemoryUseOrDef *What, MemoryUseOrDef *Where) {
   moveTo(What, Where->getBlock(), Where->getIterator());
 }

 // Move What after Where in the MemorySSA IR.
 void MemorySSAUpdater::moveAfter(MemoryUseOrDef *What, MemoryUseOrDef *Where) {
   moveTo(What, Where->getBlock(), ++Where->getIterator());
 }

 void MemorySSAUpdater::moveToPlace(MemoryUseOrDef *What, BasicBlock *BB,
                                    MemorySSA::InsertionPlace Where) {
   return moveTo(What, BB, Where);
 }

 /// \brief If all arguments of a MemoryPHI are defined by the same incoming
 /// argument, return that argument.
 static MemoryAccess *onlySingleValue(MemoryPhi *MP) {
   MemoryAccess *MA = nullptr;

   for (auto &Arg : MP->operands()) {
     if (!MA)
       MA = cast<MemoryAccess>(Arg);
     else if (MA != Arg)
       return nullptr;
   }
   return MA;
 }

 void MemorySSAUpdater::removeMemoryAccess(MemoryAccess *MA) {
   assert(!MSSA->isLiveOnEntryDef(MA) &&
          "Trying to remove the live on entry def");
   // We can only delete phi nodes if they have no uses, or we can replace all
   // uses with a single definition.
   MemoryAccess *NewDefTarget = nullptr;
   if (MemoryPhi *MP = dyn_cast<MemoryPhi>(MA)) {
     // Note that it is sufficient to know that all edges of the phi node have
     // the same argument.  If they do, by the definition of dominance frontiers
     // (which we used to place this phi), that argument must dominate this phi,
     // and thus, must dominate the phi's uses, and so we will not hit the assert
     // below.
     NewDefTarget = onlySingleValue(MP);
     assert((NewDefTarget || MP->use_empty()) &&
            "We can't delete this memory phi");
   } else {
     NewDefTarget = cast<MemoryUseOrDef>(MA)->getDefiningAccess();
   }

   // Re-point the uses at our defining access
   if (!isa<MemoryUse>(MA) && !MA->use_empty()) {
     // Reset optimized on users of this store, and reset the uses.
     // A few notes:
     // 1. This is a slightly modified version of RAUW to avoid walking the
     // uses twice here.
     // 2. If we wanted to be complete, we would have to reset the optimized
     // flags on users of phi nodes if doing the below makes a phi node have all
     // the same arguments. Instead, we prefer users to removeMemoryAccess those
     // phi nodes, because doing it here would be N^3.
     if (MA->hasValueHandle())
       ValueHandleBase::ValueIsRAUWd(MA, NewDefTarget);
     // Note: We assume MemorySSA is not used in metadata since it's not really
     // part of the IR.

     while (!MA->use_empty()) {
       Use &U = *MA->use_begin();
       if (auto *MUD = dyn_cast<MemoryUseOrDef>(U.getUser()))
         MUD->resetOptimized();
       U.set(NewDefTarget);
     }
   }

   // The call below to erase will destroy MA, so we can't change the order we
   // are doing things here
   MSSA->removeFromLookups(MA);
   MSSA->removeFromLists(MA);
 }

 MemoryAccess *MemorySSAUpdater::createMemoryAccessInBB(
     Instruction *I, MemoryAccess *Definition, const BasicBlock *BB,
     MemorySSA::InsertionPlace Point) {
   MemoryUseOrDef *NewAccess = MSSA->createDefinedAccess(I, Definition);
   MSSA->insertIntoListsForBlock(NewAccess, BB, Point);
   return NewAccess;
 }

 MemoryUseOrDef *MemorySSAUpdater::createMemoryAccessBefore(
     Instruction *I, MemoryAccess *Definition, MemoryUseOrDef *InsertPt) {
   assert(I->getParent() == InsertPt->getBlock() &&
          "New and old access must be in the same block");
   MemoryUseOrDef *NewAccess = MSSA->createDefinedAccess(I, Definition);
   MSSA->insertIntoListsBefore(NewAccess, InsertPt->getBlock(),
                               InsertPt->getIterator());
   return NewAccess;
 }

 MemoryUseOrDef *MemorySSAUpdater::createMemoryAccessAfter(
     Instruction *I, MemoryAccess *Definition, MemoryAccess *InsertPt) {
   assert(I->getParent() == InsertPt->getBlock() &&
          "New and old access must be in the same block");
   MemoryUseOrDef *NewAccess = MSSA->createDefinedAccess(I, Definition);
   MSSA->insertIntoListsBefore(NewAccess, InsertPt->getBlock(),
                               ++InsertPt->getIterator());
   return NewAccess;
 }
	//===-- MemorySSAUpdater.cpp - Memory SSA Updater--------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------===//
	//
	// This file implements the MemorySSAUpdater class.
	//
	//===----------------------------------------------------------------===//
	#include "llvm/Analysis/MemorySSAUpdater.h"
	#include "llvm/ADT/STLExtras.h"
	#include "llvm/ADT/SmallPtrSet.h"
	#include "llvm/ADT/SmallSet.h"
	#include "llvm/Analysis/MemorySSA.h"
	#include "llvm/IR/DataLayout.h"
	#include "llvm/IR/Dominators.h"
	#include "llvm/IR/GlobalVariable.h"
	#include "llvm/IR/IRBuilder.h"
	#include "llvm/IR/IntrinsicInst.h"
	#include "llvm/IR/LLVMContext.h"
	#include "llvm/IR/Metadata.h"
	#include "llvm/IR/Module.h"
	#include "llvm/Support/Debug.h"
	#include "llvm/Support/FormattedStream.h"
	#include <algorithm>

	#define DEBUG_TYPE "memoryssa"
	using namespace llvm;

	// This is the marker algorithm from "Simple and Efficient Construction of
	// Static Single Assignment Form"
	// The simple, non-marker algorithm places phi nodes at any join
	// Here, we place markers, and only place phi nodes if they end up necessary.
	// They are only necessary if they break a cycle (IE we recursively visit
	// ourselves again), or we discover, while getting the value of the operands,
	// that there are two or more definitions needing to be merged.
	// This still will leave non-minimal form in the case of irreducible control
	// flow, where phi nodes may be in cycles with themselves, but unnecessary.
	MemoryAccess MemorySSAUpdater::getPreviousDefRecursive(BasicBlock BB) {
	// Single predecessor case, just recurse, we can only have one definition.
	if (BasicBlock *Pred = BB->getSinglePredecessor()) {
	return getPreviousDefFromEnd(Pred);
	} else if (VisitedBlocks.count(BB)) {
	// We hit our node again, meaning we had a cycle, we must insert a phi
	// node to break it so we have an operand. The only case this will
	// insert useless phis is if we have irreducible control flow.
	return MSSA->createMemoryPhi(BB);
	} else if (VisitedBlocks.insert(BB).second) {
	// Mark us visited so we can detect a cycle
	SmallVector<MemoryAccess *, 8> PhiOps;

	// Recurse to get the values in our predecessors for placement of a
	// potential phi node. This will insert phi nodes if we cycle in order to
	// break the cycle and have an operand.
	for (auto *Pred : predecessors(BB))
	PhiOps.push_back(getPreviousDefFromEnd(Pred));

	// Now try to simplify the ops to avoid placing a phi.
	// This may return null if we never created a phi yet, that's okay
	MemoryPhi *Phi = dyn_cast_or_null<MemoryPhi>(MSSA->getMemoryAccess(BB));
	bool PHIExistsButNeedsUpdate = false;
	// See if the existing phi operands match what we need.
	// Unlike normal SSA, we only allow one phi node per block, so we can't just
	// create a new one.
	if (Phi && Phi->getNumOperands() != 0)
	if (!std::equal(Phi->op_begin(), Phi->op_end(), PhiOps.begin())) {
	PHIExistsButNeedsUpdate = true;
	}

	// See if we can avoid the phi by simplifying it.
	auto *Result = tryRemoveTrivialPhi(Phi, PhiOps);
	// If we couldn't simplify, we may have to create a phi
	if (Result == Phi) {
	if (!Phi)
	Phi = MSSA->createMemoryPhi(BB);

	// These will have been filled in by the recursive read we did above.
	if (PHIExistsButNeedsUpdate) {
	std::copy(PhiOps.begin(), PhiOps.end(), Phi->op_begin());
	std::copy(pred_begin(BB), pred_end(BB), Phi->block_begin());
	} else {
	unsigned i = 0;
	for (auto *Pred : predecessors(BB))
	Phi->addIncoming(PhiOps[i++], Pred);
	InsertedPHIs.push_back(Phi);
	}
	Result = Phi;
	}

	// Set ourselves up for the next variable by resetting visited state.
	VisitedBlocks.erase(BB);
	return Result;
	}
	llvm_unreachable("Should have hit one of the three cases above");
	}

	// This starts at the memory access, and goes backwards in the block to find the
	// previous definition. If a definition is not found the block of the access,
	// it continues globally, creating phi nodes to ensure we have a single
	// definition.
	MemoryAccess MemorySSAUpdater::getPreviousDef(MemoryAccess MA) {
	auto *LocalResult = getPreviousDefInBlock(MA);

	return LocalResult ? LocalResult : getPreviousDefRecursive(MA->getBlock());
	}

	// This starts at the memory access, and goes backwards in the block to the find
	// the previous definition. If the definition is not found in the block of the
	// access, it returns nullptr.
	MemoryAccess MemorySSAUpdater::getPreviousDefInBlock(MemoryAccess MA) {
	auto *Defs = MSSA->getWritableBlockDefs(MA->getBlock());

	// It's possible there are no defs, or we got handed the first def to start.
	if (Defs) {
	// If this is a def, we can just use the def iterators.
	if (!isa<MemoryUse>(MA)) {
	auto Iter = MA->getReverseDefsIterator();
	++Iter;
	if (Iter != Defs->rend())
	return &*Iter;
	} else {
	// Otherwise, have to walk the all access iterator.
	auto End = MSSA->getWritableBlockAccesses(MA->getBlock())->rend();
	for (auto &U : make_range(++MA->getReverseIterator(), End))
	if (!isa<MemoryUse>(U))
	return cast<MemoryAccess>(&U);
	// Note that if MA comes before Defs->begin(), we won't hit a def.
	return nullptr;
	}
	}
	return nullptr;
	}

	// This starts at the end of block
	MemoryAccess MemorySSAUpdater::getPreviousDefFromEnd(BasicBlock BB) {
	auto *Defs = MSSA->getWritableBlockDefs(BB);

	if (Defs)
	return &*Defs->rbegin();

	return getPreviousDefRecursive(BB);
	}
	// Recurse over a set of phi uses to eliminate the trivial ones
	MemoryAccess MemorySSAUpdater::recursePhi(MemoryAccess Phi) {
	if (!Phi)
	return nullptr;
	TrackingVH<MemoryAccess> Res(Phi);
	SmallVector<TrackingVH<Value>, 8> Uses;
	std::copy(Phi->user_begin(), Phi->user_end(), std::back_inserter(Uses));
	for (auto &U : Uses) {
	if (MemoryPhi UsePhi = dyn_cast<MemoryPhi>(&U)) {
	auto OperRange = UsePhi->operands();
	tryRemoveTrivialPhi(UsePhi, OperRange);
	}
	}
	return Res;
	}

	// Eliminate trivial phis
	// Phis are trivial if they are defined either by themselves, or all the same
	// argument.
	// IE phi(a, a) or b = phi(a, b) or c = phi(a, a, c)
	// We recursively try to remove them.
	template <class RangeType>
	MemoryAccess MemorySSAUpdater::tryRemoveTrivialPhi(MemoryPhi Phi,
	RangeType &Operands) {
	// Detect equal or self arguments
	MemoryAccess *Same = nullptr;
	for (auto &Op : Operands) {
	// If the same or self, good so far
	if (Op == Phi \|\| Op == Same)
	continue;
	// not the same, return the phi since it's not eliminatable by us
	if (Same)
	return Phi;
	Same = cast<MemoryAccess>(Op);
	}
	// Never found a non-self reference, the phi is undef
	if (Same == nullptr)
	return MSSA->getLiveOnEntryDef();
	if (Phi) {
	Phi->replaceAllUsesWith(Same);
	removeMemoryAccess(Phi);
	}

	// We should only end up recursing in case we replaced something, in which
	// case, we may have made other Phis trivial.
	return recursePhi(Same);
	}

	void MemorySSAUpdater::insertUse(MemoryUse *MU) {
	InsertedPHIs.clear();
	MU->setDefiningAccess(getPreviousDef(MU));
	// Unlike for defs, there is no extra work to do. Because uses do not create
	// new may-defs, there are only two cases:
	//
	// 1. There was a def already below us, and therefore, we should not have
	// created a phi node because it was already needed for the def.
	//
	// 2. There is no def below us, and therefore, there is no extra renaming work
	// to do.
	}

	// Set every incoming edge {BB, MP->getBlock()} of MemoryPhi MP to NewDef.
	static void setMemoryPhiValueForBlock(MemoryPhi MP, const BasicBlock BB,
	MemoryAccess *NewDef) {
	// Replace any operand with us an incoming block with the new defining
	// access.
	int i = MP->getBasicBlockIndex(BB);
	assert(i != -1 && "Should have found the basic block in the phi");
	// We can't just compare i against getNumOperands since one is signed and the
	// other not. So use it to index into the block iterator.
	for (auto BBIter = MP->block_begin() + i; BBIter != MP->block_end();
	++BBIter) {
	if (*BBIter != BB)
	break;
	MP->setIncomingValue(i, NewDef);
	++i;
	}
	}

	// A brief description of the algorithm:
	// First, we compute what should define the new def, using the SSA
	// construction algorithm.
	// Then, we update the defs below us (and any new phi nodes) in the graph to
	// point to the correct new defs, to ensure we only have one variable, and no
	// disconnected stores.
	void MemorySSAUpdater::insertDef(MemoryDef *MD, bool RenameUses) {
	InsertedPHIs.clear();

	// See if we had a local def, and if not, go hunting.
	MemoryAccess *DefBefore = getPreviousDefInBlock(MD);
	bool DefBeforeSameBlock = DefBefore != nullptr;
	if (!DefBefore)
	DefBefore = getPreviousDefRecursive(MD->getBlock());

	// There is a def before us, which means we can replace any store/phi uses
	// of that thing with us, since we are in the way of whatever was there
	// before.
	// We now define that def's memorydefs and memoryphis
	if (DefBeforeSameBlock) {
	for (auto UI = DefBefore->use_begin(), UE = DefBefore->use_end();
	UI != UE;) {
	Use &U = *UI++;
	// Leave the uses alone
	if (isa<MemoryUse>(U.getUser()))
	continue;
	U.set(MD);
	}
	}

	// and that def is now our defining access.
	// We change them in this order otherwise we will appear in the use list
	// above and reset ourselves.
	MD->setDefiningAccess(DefBefore);

	SmallVector<MemoryAccess *, 8> FixupList(InsertedPHIs.begin(),
	InsertedPHIs.end());
	if (!DefBeforeSameBlock) {
	// If there was a local def before us, we must have the same effect it
	// did. Because every may-def is the same, any phis/etc we would create, it
	// would also have created. If there was no local def before us, we
	// performed a global update, and have to search all successors and make
	// sure we update the first def in each of them (following all paths until
	// we hit the first def along each path). This may also insert phi nodes.
	// TODO: There are other cases we can skip this work, such as when we have a
	// single successor, and only used a straight line of single pred blocks
	// backwards to find the def. To make that work, we'd have to track whether
	// getDefRecursive only ever used the single predecessor case. These types
	// of paths also only exist in between CFG simplifications.
	FixupList.push_back(MD);
	}

	while (!FixupList.empty()) {
	unsigned StartingPHISize = InsertedPHIs.size();
	fixupDefs(FixupList);
	FixupList.clear();
	// Put any new phis on the fixup list, and process them
	FixupList.append(InsertedPHIs.end() - StartingPHISize, InsertedPHIs.end());
	}
	// Now that all fixups are done, rename all uses if we are asked.
	if (RenameUses) {
	SmallPtrSet<BasicBlock *, 16> Visited;
	BasicBlock *StartBlock = MD->getBlock();
	// We are guaranteed there is a def in the block, because we just got it
	// handed to us in this function.
	MemoryAccess FirstDef = &MSSA->getWritableBlockDefs(StartBlock)->begin();
	// Convert to incoming value if it's a memorydef. A phi is already an
	// incoming value.
	if (auto *MD = dyn_cast<MemoryDef>(FirstDef))
	FirstDef = MD->getDefiningAccess();

	MSSA->renamePass(MD->getBlock(), FirstDef, Visited);
	// We just inserted a phi into this block, so the incoming value will become
	// the phi anyway, so it does not matter what we pass.
	for (auto *MP : InsertedPHIs)
	MSSA->renamePass(MP->getBlock(), nullptr, Visited);
	}
	}

	void MemorySSAUpdater::fixupDefs(const SmallVectorImpl<MemoryAccess *> &Vars) {
	SmallPtrSet<const BasicBlock *, 8> Seen;
	SmallVector<const BasicBlock *, 16> Worklist;
	for (auto *NewDef : Vars) {
	// First, see if there is a local def after the operand.
	auto *Defs = MSSA->getWritableBlockDefs(NewDef->getBlock());
	auto DefIter = NewDef->getDefsIterator();

	// If there is a local def after us, we only have to rename that.
	if (++DefIter != Defs->end()) {
	cast<MemoryDef>(DefIter)->setDefiningAccess(NewDef);
	continue;
	}

	// Otherwise, we need to search down through the CFG.
	// For each of our successors, handle it directly if their is a phi, or
	// place on the fixup worklist.
	for (const auto *S : successors(NewDef->getBlock())) {
	if (auto *MP = MSSA->getMemoryAccess(S))
	setMemoryPhiValueForBlock(MP, NewDef->getBlock(), NewDef);
	else
	Worklist.push_back(S);
	}

	while (!Worklist.empty()) {
	const BasicBlock *FixupBlock = Worklist.back();
	Worklist.pop_back();

	// Get the first def in the block that isn't a phi node.
	if (auto *Defs = MSSA->getWritableBlockDefs(FixupBlock)) {
	auto FirstDef = &Defs->begin();
	// The loop above and below should have taken care of phi nodes
	assert(!isa<MemoryPhi>(FirstDef) &&
	"Should have already handled phi nodes!");
	// We are now this def's defining access, make sure we actually dominate
	// it
	assert(MSSA->dominates(NewDef, FirstDef) &&
	"Should have dominated the new access");

	// This may insert new phi nodes, because we are not guaranteed the
	// block we are processing has a single pred, and depending where the
	// store was inserted, it may require phi nodes below it.
	cast<MemoryDef>(FirstDef)->setDefiningAccess(getPreviousDef(FirstDef));
	return;
	}
	// We didn't find a def, so we must continue.
	for (const auto *S : successors(FixupBlock)) {
	// If there is a phi node, handle it.
	// Otherwise, put the block on the worklist
	if (auto *MP = MSSA->getMemoryAccess(S))
	setMemoryPhiValueForBlock(MP, FixupBlock, NewDef);
	else {
	// If we cycle, we should have ended up at a phi node that we already
	// processed. FIXME: Double check this
	if (!Seen.insert(S).second)
	continue;
	Worklist.push_back(S);
	}
	}
	}
	}
	}

	// Move What before Where in the MemorySSA IR.
	template <class WhereType>
	void MemorySSAUpdater::moveTo(MemoryUseOrDef What, BasicBlock BB,
	WhereType Where) {
	// Replace all our users with our defining access.
	What->replaceAllUsesWith(What->getDefiningAccess());

	// Let MemorySSA take care of moving it around in the lists.
	MSSA->moveTo(What, BB, Where);

	// Now reinsert it into the IR and do whatever fixups needed.
	if (auto *MD = dyn_cast<MemoryDef>(What))
	insertDef(MD);
	else
	insertUse(cast<MemoryUse>(What));
	}

	// Move What before Where in the MemorySSA IR.
	void MemorySSAUpdater::moveBefore(MemoryUseOrDef What, MemoryUseOrDef Where) {
	moveTo(What, Where->getBlock(), Where->getIterator());
	}

	// Move What after Where in the MemorySSA IR.
	void MemorySSAUpdater::moveAfter(MemoryUseOrDef What, MemoryUseOrDef Where) {
	moveTo(What, Where->getBlock(), ++Where->getIterator());
	}

	void MemorySSAUpdater::moveToPlace(MemoryUseOrDef What, BasicBlock BB,
	MemorySSA::InsertionPlace Where) {
	return moveTo(What, BB, Where);
	}

	/// \brief If all arguments of a MemoryPHI are defined by the same incoming
	/// argument, return that argument.
	static MemoryAccess onlySingleValue(MemoryPhi MP) {
	MemoryAccess *MA = nullptr;

	for (auto &Arg : MP->operands()) {
	if (!MA)
	MA = cast<MemoryAccess>(Arg);
	else if (MA != Arg)
	return nullptr;
	}
	return MA;
	}

	void MemorySSAUpdater::removeMemoryAccess(MemoryAccess *MA) {
	assert(!MSSA->isLiveOnEntryDef(MA) &&
	"Trying to remove the live on entry def");
	// We can only delete phi nodes if they have no uses, or we can replace all
	// uses with a single definition.
	MemoryAccess *NewDefTarget = nullptr;
	if (MemoryPhi *MP = dyn_cast<MemoryPhi>(MA)) {
	// Note that it is sufficient to know that all edges of the phi node have
	// the same argument. If they do, by the definition of dominance frontiers
	// (which we used to place this phi), that argument must dominate this phi,
	// and thus, must dominate the phi's uses, and so we will not hit the assert
	// below.
	NewDefTarget = onlySingleValue(MP);
	assert((NewDefTarget \|\| MP->use_empty()) &&
	"We can't delete this memory phi");
	} else {
	NewDefTarget = cast<MemoryUseOrDef>(MA)->getDefiningAccess();
	}

	// Re-point the uses at our defining access
	if (!isa<MemoryUse>(MA) && !MA->use_empty()) {
	// Reset optimized on users of this store, and reset the uses.
	// A few notes:
	// 1. This is a slightly modified version of RAUW to avoid walking the
	// uses twice here.
	// 2. If we wanted to be complete, we would have to reset the optimized
	// flags on users of phi nodes if doing the below makes a phi node have all
	// the same arguments. Instead, we prefer users to removeMemoryAccess those
	// phi nodes, because doing it here would be N^3.
	if (MA->hasValueHandle())
	ValueHandleBase::ValueIsRAUWd(MA, NewDefTarget);
	// Note: We assume MemorySSA is not used in metadata since it's not really
	// part of the IR.

	while (!MA->use_empty()) {
	Use &U = *MA->use_begin();
	if (auto *MUD = dyn_cast<MemoryUseOrDef>(U.getUser()))
	MUD->resetOptimized();
	U.set(NewDefTarget);
	}
	}

	// The call below to erase will destroy MA, so we can't change the order we
	// are doing things here
	MSSA->removeFromLookups(MA);
	MSSA->removeFromLists(MA);
	}

	MemoryAccess *MemorySSAUpdater::createMemoryAccessInBB(
	Instruction I, MemoryAccess Definition, const BasicBlock *BB,
	MemorySSA::InsertionPlace Point) {
	MemoryUseOrDef *NewAccess = MSSA->createDefinedAccess(I, Definition);
	MSSA->insertIntoListsForBlock(NewAccess, BB, Point);
	return NewAccess;
	}

	MemoryUseOrDef *MemorySSAUpdater::createMemoryAccessBefore(
	Instruction I, MemoryAccess Definition, MemoryUseOrDef *InsertPt) {
	assert(I->getParent() == InsertPt->getBlock() &&
	"New and old access must be in the same block");
	MemoryUseOrDef *NewAccess = MSSA->createDefinedAccess(I, Definition);
	MSSA->insertIntoListsBefore(NewAccess, InsertPt->getBlock(),
	InsertPt->getIterator());
	return NewAccess;
	}

	MemoryUseOrDef *MemorySSAUpdater::createMemoryAccessAfter(
	Instruction I, MemoryAccess Definition, MemoryAccess *InsertPt) {
	assert(I->getParent() == InsertPt->getBlock() &&
	"New and old access must be in the same block");
	MemoryUseOrDef *NewAccess = MSSA->createDefinedAccess(I, Definition);
	MSSA->insertIntoListsBefore(NewAccess, InsertPt->getBlock(),
	++InsertPt->getIterator());
	return NewAccess;
	}