llvm/lib/Transforms/Scalar/GCSE.cpp - toolchain/llvm-project - Gitiles

 //===-- GCSE.cpp - SSA based Global Common Subexpr Elimination ------------===//
 //
 // This pass is designed to be a very quick global transformation that
 // eliminates global common subexpressions from a function.  It does this by
 // examining the SSA value graph of the function, instead of doing slow, dense,
 // bit-vector computations.
 //
 // This pass works best if it is proceeded with a simple constant propogation
 // pass and an instruction combination pass because this pass does not do any
 // value numbering (in order to be speedy).
 //
 // This pass does not attempt to CSE load instructions, because it does not use
 // pointer analysis to determine when it is safe.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/Transforms/Scalar.h"
 #include "llvm/InstrTypes.h"
 #include "llvm/iMemory.h"
 #include "llvm/Analysis/Dominators.h"
 #include "llvm/Support/InstVisitor.h"
 #include "llvm/Support/InstIterator.h"
 #include "llvm/Support/CFG.h"
 #include "Support/StatisticReporter.h"
 #include <algorithm>
 using std::set;
 using std::map;


 static Statistic<> NumInstRemoved("gcse\t\t- Number of instructions removed");
 static Statistic<> NumLoadRemoved("gcse\t\t- Number of loads removed");

 namespace {
   class GCSE : public FunctionPass, public InstVisitor<GCSE, bool> {
     set<Instruction*>       WorkList;
     DominatorSet           *DomSetInfo;
     ImmediateDominators    *ImmDominator;

     // BBContainsStore - Contains a value that indicates whether a basic block
     // has a store or call instruction in it.  This map is demand populated, so
     // not having an entry means that the basic block has not been scanned yet.
     //
     map<BasicBlock*, bool>  BBContainsStore;
   public:
     virtual bool runOnFunction(Function &F);

     // Visitation methods, these are invoked depending on the type of
     // instruction being checked.  They should return true if a common
     // subexpression was folded.
     //
     bool visitBinaryOperator(Instruction &I);
     bool visitGetElementPtrInst(GetElementPtrInst &I);
     bool visitCastInst(CastInst &I);
     bool visitShiftInst(ShiftInst &I) {
       return visitBinaryOperator((Instruction&)I);
     }
     bool visitLoadInst(LoadInst &LI);
     bool visitInstruction(Instruction &) { return false; }

   private:
     void ReplaceInstWithInst(Instruction *First, BasicBlock::iterator SI);
     void CommonSubExpressionFound(Instruction *I, Instruction *Other);

     // TryToRemoveALoad - Try to remove one of L1 or L2.  The problem with
     // removing loads is that intervening stores might make otherwise identical
     // load's yield different values.  To ensure that this is not the case, we
     // check that there are no intervening stores or calls between the
     // instructions.
     //
     bool TryToRemoveALoad(LoadInst *L1, LoadInst *L2);

     // CheckForInvalidatingInst - Return true if BB or any of the predecessors
     // of BB (until DestBB) contain a store (or other invalidating) instruction.
     //
     bool CheckForInvalidatingInst(BasicBlock *BB, BasicBlock *DestBB,
                                   set<BasicBlock*> &VisitedSet);

     // This transformation requires dominator and immediate dominator info
     virtual void getAnalysisUsage(AnalysisUsage &AU) const {
       AU.preservesCFG();
       AU.addRequired<DominatorSet>();
       AU.addRequired<ImmediateDominators>();
     }
   };

   RegisterOpt<GCSE> X("gcse", "Global Common Subexpression Elimination");
 }

 // createGCSEPass - The public interface to this file...
 Pass *createGCSEPass() { return new GCSE(); }


 // GCSE::runOnFunction - This is the main transformation entry point for a
 // function.
 //
 bool GCSE::runOnFunction(Function &F) {
   bool Changed = false;

   DomSetInfo = &getAnalysis<DominatorSet>();
   ImmDominator = &getAnalysis<ImmediateDominators>();

   // Step #1: Add all instructions in the function to the worklist for
   // processing.  All of the instructions are considered to be our
   // subexpressions to eliminate if possible.
   //
   WorkList.insert(inst_begin(F), inst_end(F));

   // Step #2: WorkList processing.  Iterate through all of the instructions,
   // checking to see if there are any additionally defined subexpressions in the
   // program.  If so, eliminate them!
   //
   while (!WorkList.empty()) {
     Instruction &I = **WorkList.begin(); // Get an instruction from the worklist
     WorkList.erase(WorkList.begin());

     // Visit the instruction, dispatching to the correct visit function based on
     // the instruction type.  This does the checking.
     //
     Changed |= visit(I);
   }

   // Clear out data structure so that next function starts fresh
   BBContainsStore.clear();

   // When the worklist is empty, return whether or not we changed anything...
   return Changed;
 }


 // ReplaceInstWithInst - Destroy the instruction pointed to by SI, making all
 // uses of the instruction use First now instead.
 //
 void GCSE::ReplaceInstWithInst(Instruction *First, BasicBlock::iterator SI) {
   Instruction &Second = *SI;

   //cerr << "DEL " << (void*)Second << Second;

   // Add the first instruction back to the worklist
   WorkList.insert(First);

   // Add all uses of the second instruction to the worklist
   for (Value::use_iterator UI = Second.use_begin(), UE = Second.use_end();
        UI != UE; ++UI)
     WorkList.insert(cast<Instruction>(*UI));

   // Make all users of 'Second' now use 'First'
   Second.replaceAllUsesWith(First);

   // Erase the second instruction from the program
   Second.getParent()->getInstList().erase(SI);
 }

 // CommonSubExpressionFound - The two instruction I & Other have been found to
 // be common subexpressions.  This function is responsible for eliminating one
 // of them, and for fixing the worklist to be correct.
 //
 void GCSE::CommonSubExpressionFound(Instruction *I, Instruction *Other) {
   assert(I != Other);

   WorkList.erase(I);
   WorkList.erase(Other); // Other may not actually be on the worklist anymore...

   ++NumInstRemoved;   // Keep track of number of instructions eliminated

   // Handle the easy case, where both instructions are in the same basic block
   BasicBlock *BB1 = I->getParent(), *BB2 = Other->getParent();
   if (BB1 == BB2) {
     // Eliminate the second occuring instruction.  Add all uses of the second
     // instruction to the worklist.
     //
     // Scan the basic block looking for the "first" instruction
     BasicBlock::iterator BI = BB1->begin();
     while (&*BI != I && &*BI != Other) {
       ++BI;
       assert(BI != BB1->end() && "Instructions not found in parent BB!");
     }

     // Keep track of which instructions occurred first & second
     Instruction *First = BI;
     Instruction *Second = I != First ? I : Other; // Get iterator to second inst
     BI = Second;

     // Destroy Second, using First instead.
     ReplaceInstWithInst(First, BI);

     // Otherwise, the two instructions are in different basic blocks.  If one
     // dominates the other instruction, we can simply use it
     //
   } else if (DomSetInfo->dominates(BB1, BB2)) {    // I dom Other?
     ReplaceInstWithInst(I, Other);
   } else if (DomSetInfo->dominates(BB2, BB1)) {    // Other dom I?
     ReplaceInstWithInst(Other, I);
   } else {
     // This code is disabled because it has several problems:
     // One, the actual assumption is wrong, as shown by this code:
     // int "test"(int %X, int %Y) {
     //         %Z = add int %X, %Y
     //         ret int %Z
     // Unreachable:
     //         %Q = add int %X, %Y
     //         ret int %Q
     // }
     //
     // Here there are no shared dominators.  Additionally, this had the habit of
     // moving computations where they were not always computed.  For example, in
     // a cast like this:
     //  if (c) {
     //    if (d)  ...
     //    else ... X+Y ...
     //  } else {
     //    ... X+Y ...
     //  }
     //
     // In thiscase, the expression would be hoisted to outside the 'if' stmt,
     // causing the expression to be evaluated, even for the if (d) path, which
     // could cause problems, if, for example, it caused a divide by zero.  In
     // general the problem this case is trying to solve is better addressed with
     // PRE than GCSE.
     //

 #if 0
     // Handle the most general case now.  In this case, neither I dom Other nor
     // Other dom I.  Because we are in SSA form, we are guaranteed that the
     // operands of the two instructions both dominate the uses, so we _know_
     // that there must exist a block that dominates both instructions (if the
     // operands of the instructions are globals or constants, worst case we
     // would get the entry node of the function).  Search for this block now.
     //

     // Search up the immediate dominator chain of BB1 for the shared dominator
     BasicBlock *SharedDom = (*ImmDominator)[BB1];
     while (!DomSetInfo->dominates(SharedDom, BB2))
       SharedDom = (*ImmDominator)[SharedDom];

     // At this point, shared dom must dominate BOTH BB1 and BB2...
     assert(SharedDom && DomSetInfo->dominates(SharedDom, BB1) &&
            DomSetInfo->dominates(SharedDom, BB2) && "Dominators broken!");

     // Rip 'I' out of BB1, and move it to the end of SharedDom.
     BB1->getInstList().remove(I);
     SharedDom->getInstList().insert(--SharedDom->end(), I);

     // Eliminate 'Other' now.
     ReplaceInstWithInst(I, Other);
 #endif
   }
 }

 //===----------------------------------------------------------------------===//
 //
 // Visitation methods, these are invoked depending on the type of instruction
 // being checked.  They should return true if a common subexpression was folded.
 //
 //===----------------------------------------------------------------------===//

 bool GCSE::visitCastInst(CastInst &CI) {
   Instruction &I = (Instruction&)CI;
   Value *Op = I.getOperand(0);
   Function *F = I.getParent()->getParent();

   for (Value::use_iterator UI = Op->use_begin(), UE = Op->use_end();
        UI != UE; ++UI)
     if (Instruction *Other = dyn_cast<Instruction>(*UI))
       // Check to see if this new cast is not I, but has the same operand...
       if (Other != &I && Other->getOpcode() == I.getOpcode() &&
           Other->getOperand(0) == Op &&     // Is the operand the same?
           // Is it embeded in the same function?  (This could be false if LHS
           // is a constant or global!)
           Other->getParent()->getParent() == F &&

           // Check that the types are the same, since this code handles casts...
           Other->getType() == I.getType()) {

         // These instructions are identical.  Handle the situation.
         CommonSubExpressionFound(&I, Other);
         return true;   // One instruction eliminated!
       }

   return false;
 }

 // isIdenticalBinaryInst - Return true if the two binary instructions are
 // identical.
 //
 static inline bool isIdenticalBinaryInst(const Instruction &I1,
                                          const Instruction *I2) {
   // Is it embeded in the same function?  (This could be false if LHS
   // is a constant or global!)
   if (I1.getOpcode() != I2->getOpcode() ||
       I1.getParent()->getParent() != I2->getParent()->getParent())
     return false;

   // They are identical if both operands are the same!
   if (I1.getOperand(0) == I2->getOperand(0) &&
       I1.getOperand(1) == I2->getOperand(1))
     return true;

   // If the instruction is commutative and associative, the instruction can
   // match if the operands are swapped!
   //
   if ((I1.getOperand(0) == I2->getOperand(1) &&
        I1.getOperand(1) == I2->getOperand(0)) &&
       (I1.getOpcode() == Instruction::Add ||
        I1.getOpcode() == Instruction::Mul ||
        I1.getOpcode() == Instruction::And ||
        I1.getOpcode() == Instruction::Or  ||
        I1.getOpcode() == Instruction::Xor))
     return true;

   return false;
 }

 bool GCSE::visitBinaryOperator(Instruction &I) {
   Value *LHS = I.getOperand(0), *RHS = I.getOperand(1);
   Function *F = I.getParent()->getParent();

   for (Value::use_iterator UI = LHS->use_begin(), UE = LHS->use_end();
        UI != UE; ++UI)
     if (Instruction *Other = dyn_cast<Instruction>(*UI))
       // Check to see if this new binary operator is not I, but same operand...
       if (Other != &I && isIdenticalBinaryInst(I, Other)) {
         // These instructions are identical.  Handle the situation.
         CommonSubExpressionFound(&I, Other);
         return true;   // One instruction eliminated!
       }

   return false;
 }

 // IdenticalComplexInst - Return true if the two instructions are the same, by
 // using a brute force comparison.
 //
 static bool IdenticalComplexInst(const Instruction *I1, const Instruction *I2) {
   assert(I1->getOpcode() == I2->getOpcode());
   // Equal if they are in the same function...
   return I1->getParent()->getParent() == I2->getParent()->getParent() &&
     // And return the same type...
     I1->getType() == I2->getType() &&
     // And have the same number of operands...
     I1->getNumOperands() == I2->getNumOperands() &&
     // And all of the operands are equal.
     std::equal(I1->op_begin(), I1->op_end(), I2->op_begin());
 }

 bool GCSE::visitGetElementPtrInst(GetElementPtrInst &I) {
   Value *Op = I.getOperand(0);
   Function *F = I.getParent()->getParent();

   for (Value::use_iterator UI = Op->use_begin(), UE = Op->use_end();
        UI != UE; ++UI)
     if (GetElementPtrInst *Other = dyn_cast<GetElementPtrInst>(*UI))
       // Check to see if this new getelementptr is not I, but same operand...
       if (Other != &I && IdenticalComplexInst(&I, Other)) {
         // These instructions are identical.  Handle the situation.
         CommonSubExpressionFound(&I, Other);
         return true;   // One instruction eliminated!
       }

   return false;
 }

 bool GCSE::visitLoadInst(LoadInst &LI) {
   Value *Op = LI.getOperand(0);
   Function *F = LI.getParent()->getParent();

   for (Value::use_iterator UI = Op->use_begin(), UE = Op->use_end();
        UI != UE; ++UI)
     if (LoadInst *Other = dyn_cast<LoadInst>(*UI))
       // Check to see if this new load is not LI, but has the same operands...
       if (Other != &LI && IdenticalComplexInst(&LI, Other) &&
           TryToRemoveALoad(&LI, Other))
         return true;   // An instruction was eliminated!

   return false;
 }

 static inline bool isInvalidatingInst(const Instruction &I) {
   return I.getOpcode() == Instruction::Store ||
          I.getOpcode() == Instruction::Call ||
          I.getOpcode() == Instruction::Invoke;
 }

 // TryToRemoveALoad - Try to remove one of L1 or L2.  The problem with removing
 // loads is that intervening stores might make otherwise identical load's yield
 // different values.  To ensure that this is not the case, we check that there
 // are no intervening stores or calls between the instructions.
 //
 bool GCSE::TryToRemoveALoad(LoadInst *L1, LoadInst *L2) {
   // Figure out which load dominates the other one.  If neither dominates the
   // other we cannot eliminate one...
   //
   if (DomSetInfo->dominates(L2, L1))
     std::swap(L1, L2);   // Make L1 dominate L2
   else if (!DomSetInfo->dominates(L1, L2))
     return false;  // Neither instruction dominates the other one...

   BasicBlock *BB1 = L1->getParent(), *BB2 = L2->getParent();

   BasicBlock::iterator L1I = L1;

   // L1 now dominates L2.  Check to see if the intervening instructions between
   // the two loads include a store or call...
   //
   if (BB1 == BB2) {  // In same basic block?
     // In this degenerate case, no checking of global basic blocks has to occur
     // just check the instructions BETWEEN L1 & L2...
     //
     for (++L1I; &*L1I != L2; ++L1I)
       if (isInvalidatingInst(*L1I))
         return false;   // Cannot eliminate load

     ++NumLoadRemoved;
     CommonSubExpressionFound(L1, L2);
     return true;
   } else {
     // Make sure that there are no store instructions between L1 and the end of
     // it's basic block...
     //
     for (++L1I; L1I != BB1->end(); ++L1I)
       if (isInvalidatingInst(*L1I)) {
         BBContainsStore[BB1] = true;
         return false;   // Cannot eliminate load
       }

     // Make sure that there are no store instructions between the start of BB2
     // and the second load instruction...
     //
     for (BasicBlock::iterator II = BB2->begin(); &*II != L2; ++II)
       if (isInvalidatingInst(*II)) {
         BBContainsStore[BB2] = true;
         return false;   // Cannot eliminate load
       }

     // Do a depth first traversal of the inverse CFG starting at L2's block,
     // looking for L1's block.  The inverse CFG is made up of the predecessor
     // nodes of a block... so all of the edges in the graph are "backward".
     //
     set<BasicBlock*> VisitedSet;
     for (pred_iterator PI = pred_begin(BB2), PE = pred_end(BB2); PI != PE; ++PI)
       if (CheckForInvalidatingInst(*PI, BB1, VisitedSet))
         return false;

     ++NumLoadRemoved;
     CommonSubExpressionFound(L1, L2);
     return true;
   }
   return false;
 }

 // CheckForInvalidatingInst - Return true if BB or any of the predecessors of BB
 // (until DestBB) contain a store (or other invalidating) instruction.
 //
 bool GCSE::CheckForInvalidatingInst(BasicBlock *BB, BasicBlock *DestBB,
                                     set<BasicBlock*> &VisitedSet) {
   // Found the termination point!
   if (BB == DestBB || VisitedSet.count(BB)) return false;

   // Avoid infinite recursion!
   VisitedSet.insert(BB);

   // Have we already checked this block?
   map<BasicBlock*, bool>::iterator MI = BBContainsStore.find(BB);

   if (MI != BBContainsStore.end()) {
     // If this block is known to contain a store, exit the recursion early...
     if (MI->second) return true;
     // Otherwise continue checking predecessors...
   } else {
     // We don't know if this basic block contains an invalidating instruction.
     // Check now:
     bool HasStore = std::find_if(BB->begin(), BB->end(),
                                  isInvalidatingInst) != BB->end();
     if ((BBContainsStore[BB] = HasStore))   // Update map
       return true;   // Exit recursion early...
   }

   // Check all of our predecessor blocks...
   for (pred_iterator PI = pred_begin(BB), PE = pred_end(BB); PI != PE; ++PI)
     if (CheckForInvalidatingInst(*PI, DestBB, VisitedSet))
       return true;

   // None of our predecessor blocks contain a store, and we don't either!
   return false;
 }
	//===-- GCSE.cpp - SSA based Global Common Subexpr Elimination ------------===//
	//
	// This pass is designed to be a very quick global transformation that
	// eliminates global common subexpressions from a function. It does this by
	// examining the SSA value graph of the function, instead of doing slow, dense,
	// bit-vector computations.
	//
	// This pass works best if it is proceeded with a simple constant propogation
	// pass and an instruction combination pass because this pass does not do any
	// value numbering (in order to be speedy).
	//
	// This pass does not attempt to CSE load instructions, because it does not use
	// pointer analysis to determine when it is safe.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/Transforms/Scalar.h"
	#include "llvm/InstrTypes.h"
	#include "llvm/iMemory.h"
	#include "llvm/Analysis/Dominators.h"
	#include "llvm/Support/InstVisitor.h"
	#include "llvm/Support/InstIterator.h"
	#include "llvm/Support/CFG.h"
	#include "Support/StatisticReporter.h"
	#include <algorithm>
	using std::set;
	using std::map;


	static Statistic<> NumInstRemoved("gcse\t\t- Number of instructions removed");
	static Statistic<> NumLoadRemoved("gcse\t\t- Number of loads removed");

	namespace {
	class GCSE : public FunctionPass, public InstVisitor<GCSE, bool> {
	set<Instruction*> WorkList;
	DominatorSet *DomSetInfo;
	ImmediateDominators *ImmDominator;

	// BBContainsStore - Contains a value that indicates whether a basic block
	// has a store or call instruction in it. This map is demand populated, so
	// not having an entry means that the basic block has not been scanned yet.
	//
	map<BasicBlock*, bool> BBContainsStore;
	public:
	virtual bool runOnFunction(Function &F);

	// Visitation methods, these are invoked depending on the type of
	// instruction being checked. They should return true if a common
	// subexpression was folded.
	//
	bool visitBinaryOperator(Instruction &I);
	bool visitGetElementPtrInst(GetElementPtrInst &I);
	bool visitCastInst(CastInst &I);
	bool visitShiftInst(ShiftInst &I) {
	return visitBinaryOperator((Instruction&)I);
	}
	bool visitLoadInst(LoadInst &LI);
	bool visitInstruction(Instruction &) { return false; }

	private:
	void ReplaceInstWithInst(Instruction *First, BasicBlock::iterator SI);
	void CommonSubExpressionFound(Instruction I, Instruction Other);

	// TryToRemoveALoad - Try to remove one of L1 or L2. The problem with
	// removing loads is that intervening stores might make otherwise identical
	// load's yield different values. To ensure that this is not the case, we
	// check that there are no intervening stores or calls between the
	// instructions.
	//
	bool TryToRemoveALoad(LoadInst L1, LoadInst L2);

	// CheckForInvalidatingInst - Return true if BB or any of the predecessors
	// of BB (until DestBB) contain a store (or other invalidating) instruction.
	//
	bool CheckForInvalidatingInst(BasicBlock BB, BasicBlock DestBB,
	set<BasicBlock*> &VisitedSet);

	// This transformation requires dominator and immediate dominator info
	virtual void getAnalysisUsage(AnalysisUsage &AU) const {
	AU.preservesCFG();
	AU.addRequired<DominatorSet>();
	AU.addRequired<ImmediateDominators>();
	}
	};

	RegisterOpt<GCSE> X("gcse", "Global Common Subexpression Elimination");
	}

	// createGCSEPass - The public interface to this file...
	Pass *createGCSEPass() { return new GCSE(); }


	// GCSE::runOnFunction - This is the main transformation entry point for a
	// function.
	//
	bool GCSE::runOnFunction(Function &F) {
	bool Changed = false;

	DomSetInfo = &getAnalysis<DominatorSet>();
	ImmDominator = &getAnalysis<ImmediateDominators>();

	// Step #1: Add all instructions in the function to the worklist for
	// processing. All of the instructions are considered to be our
	// subexpressions to eliminate if possible.
	//
	WorkList.insert(inst_begin(F), inst_end(F));

	// Step #2: WorkList processing. Iterate through all of the instructions,
	// checking to see if there are any additionally defined subexpressions in the
	// program. If so, eliminate them!
	//
	while (!WorkList.empty()) {
	Instruction &I = **WorkList.begin(); // Get an instruction from the worklist
	WorkList.erase(WorkList.begin());

	// Visit the instruction, dispatching to the correct visit function based on
	// the instruction type. This does the checking.
	//
	Changed \|= visit(I);
	}

	// Clear out data structure so that next function starts fresh
	BBContainsStore.clear();

	// When the worklist is empty, return whether or not we changed anything...
	return Changed;
	}


	// ReplaceInstWithInst - Destroy the instruction pointed to by SI, making all
	// uses of the instruction use First now instead.
	//
	void GCSE::ReplaceInstWithInst(Instruction *First, BasicBlock::iterator SI) {
	Instruction &Second = *SI;

	//cerr << "DEL " << (void*)Second << Second;

	// Add the first instruction back to the worklist
	WorkList.insert(First);

	// Add all uses of the second instruction to the worklist
	for (Value::use_iterator UI = Second.use_begin(), UE = Second.use_end();
	UI != UE; ++UI)
	WorkList.insert(cast<Instruction>(*UI));

	// Make all users of 'Second' now use 'First'
	Second.replaceAllUsesWith(First);

	// Erase the second instruction from the program
	Second.getParent()->getInstList().erase(SI);
	}

	// CommonSubExpressionFound - The two instruction I & Other have been found to
	// be common subexpressions. This function is responsible for eliminating one
	// of them, and for fixing the worklist to be correct.
	//
	void GCSE::CommonSubExpressionFound(Instruction I, Instruction Other) {
	assert(I != Other);

	WorkList.erase(I);
	WorkList.erase(Other); // Other may not actually be on the worklist anymore...

	++NumInstRemoved; // Keep track of number of instructions eliminated

	// Handle the easy case, where both instructions are in the same basic block
	BasicBlock BB1 = I->getParent(), BB2 = Other->getParent();
	if (BB1 == BB2) {
	// Eliminate the second occuring instruction. Add all uses of the second
	// instruction to the worklist.
	//
	// Scan the basic block looking for the "first" instruction
	BasicBlock::iterator BI = BB1->begin();
	while (&BI != I && &BI != Other) {
	++BI;
	assert(BI != BB1->end() && "Instructions not found in parent BB!");
	}

	// Keep track of which instructions occurred first & second
	Instruction *First = BI;
	Instruction *Second = I != First ? I : Other; // Get iterator to second inst
	BI = Second;

	// Destroy Second, using First instead.
	ReplaceInstWithInst(First, BI);

	// Otherwise, the two instructions are in different basic blocks. If one
	// dominates the other instruction, we can simply use it
	//
	} else if (DomSetInfo->dominates(BB1, BB2)) { // I dom Other?
	ReplaceInstWithInst(I, Other);
	} else if (DomSetInfo->dominates(BB2, BB1)) { // Other dom I?
	ReplaceInstWithInst(Other, I);
	} else {
	// This code is disabled because it has several problems:
	// One, the actual assumption is wrong, as shown by this code:
	// int "test"(int %X, int %Y) {
	// %Z = add int %X, %Y
	// ret int %Z
	// Unreachable:
	// %Q = add int %X, %Y
	// ret int %Q
	// }
	//
	// Here there are no shared dominators. Additionally, this had the habit of
	// moving computations where they were not always computed. For example, in
	// a cast like this:
	// if (c) {
	// if (d) ...
	// else ... X+Y ...
	// } else {
	// ... X+Y ...
	// }
	//
	// In thiscase, the expression would be hoisted to outside the 'if' stmt,
	// causing the expression to be evaluated, even for the if (d) path, which
	// could cause problems, if, for example, it caused a divide by zero. In
	// general the problem this case is trying to solve is better addressed with
	// PRE than GCSE.
	//

	#if 0
	// Handle the most general case now. In this case, neither I dom Other nor
	// Other dom I. Because we are in SSA form, we are guaranteed that the
	// operands of the two instructions both dominate the uses, so we _know_
	// that there must exist a block that dominates both instructions (if the
	// operands of the instructions are globals or constants, worst case we
	// would get the entry node of the function). Search for this block now.
	//

	// Search up the immediate dominator chain of BB1 for the shared dominator
	BasicBlock SharedDom = (ImmDominator)[BB1];
	while (!DomSetInfo->dominates(SharedDom, BB2))
	SharedDom = (*ImmDominator)[SharedDom];

	// At this point, shared dom must dominate BOTH BB1 and BB2...
	assert(SharedDom && DomSetInfo->dominates(SharedDom, BB1) &&
	DomSetInfo->dominates(SharedDom, BB2) && "Dominators broken!");

	// Rip 'I' out of BB1, and move it to the end of SharedDom.
	BB1->getInstList().remove(I);
	SharedDom->getInstList().insert(--SharedDom->end(), I);

	// Eliminate 'Other' now.
	ReplaceInstWithInst(I, Other);
	#endif
	}
	}

	//===----------------------------------------------------------------------===//
	//
	// Visitation methods, these are invoked depending on the type of instruction
	// being checked. They should return true if a common subexpression was folded.
	//
	//===----------------------------------------------------------------------===//

	bool GCSE::visitCastInst(CastInst &CI) {
	Instruction &I = (Instruction&)CI;
	Value *Op = I.getOperand(0);
	Function *F = I.getParent()->getParent();

	for (Value::use_iterator UI = Op->use_begin(), UE = Op->use_end();
	UI != UE; ++UI)
	if (Instruction Other = dyn_cast<Instruction>(UI))
	// Check to see if this new cast is not I, but has the same operand...
	if (Other != &I && Other->getOpcode() == I.getOpcode() &&
	Other->getOperand(0) == Op && // Is the operand the same?
	// Is it embeded in the same function? (This could be false if LHS
	// is a constant or global!)
	Other->getParent()->getParent() == F &&

	// Check that the types are the same, since this code handles casts...
	Other->getType() == I.getType()) {

	// These instructions are identical. Handle the situation.
	CommonSubExpressionFound(&I, Other);
	return true; // One instruction eliminated!
	}

	return false;
	}

	// isIdenticalBinaryInst - Return true if the two binary instructions are
	// identical.
	//
	static inline bool isIdenticalBinaryInst(const Instruction &I1,
	const Instruction *I2) {
	// Is it embeded in the same function? (This could be false if LHS
	// is a constant or global!)
	if (I1.getOpcode() != I2->getOpcode() \|\|
	I1.getParent()->getParent() != I2->getParent()->getParent())
	return false;

	// They are identical if both operands are the same!
	if (I1.getOperand(0) == I2->getOperand(0) &&
	I1.getOperand(1) == I2->getOperand(1))
	return true;

	// If the instruction is commutative and associative, the instruction can
	// match if the operands are swapped!
	//
	if ((I1.getOperand(0) == I2->getOperand(1) &&
	I1.getOperand(1) == I2->getOperand(0)) &&
	(I1.getOpcode() == Instruction::Add \|\|
	I1.getOpcode() == Instruction::Mul \|\|
	I1.getOpcode() == Instruction::And \|\|
	I1.getOpcode() == Instruction::Or \|\|
	I1.getOpcode() == Instruction::Xor))
	return true;

	return false;
	}

	bool GCSE::visitBinaryOperator(Instruction &I) {
	Value LHS = I.getOperand(0), RHS = I.getOperand(1);
	Function *F = I.getParent()->getParent();

	for (Value::use_iterator UI = LHS->use_begin(), UE = LHS->use_end();
	UI != UE; ++UI)
	if (Instruction Other = dyn_cast<Instruction>(UI))
	// Check to see if this new binary operator is not I, but same operand...
	if (Other != &I && isIdenticalBinaryInst(I, Other)) {
	// These instructions are identical. Handle the situation.
	CommonSubExpressionFound(&I, Other);
	return true; // One instruction eliminated!
	}

	return false;
	}

	// IdenticalComplexInst - Return true if the two instructions are the same, by
	// using a brute force comparison.
	//
	static bool IdenticalComplexInst(const Instruction I1, const Instruction I2) {
	assert(I1->getOpcode() == I2->getOpcode());
	// Equal if they are in the same function...
	return I1->getParent()->getParent() == I2->getParent()->getParent() &&
	// And return the same type...
	I1->getType() == I2->getType() &&
	// And have the same number of operands...
	I1->getNumOperands() == I2->getNumOperands() &&
	// And all of the operands are equal.
	std::equal(I1->op_begin(), I1->op_end(), I2->op_begin());
	}

	bool GCSE::visitGetElementPtrInst(GetElementPtrInst &I) {
	Value *Op = I.getOperand(0);
	Function *F = I.getParent()->getParent();

	for (Value::use_iterator UI = Op->use_begin(), UE = Op->use_end();
	UI != UE; ++UI)
	if (GetElementPtrInst Other = dyn_cast<GetElementPtrInst>(UI))
	// Check to see if this new getelementptr is not I, but same operand...
	if (Other != &I && IdenticalComplexInst(&I, Other)) {
	// These instructions are identical. Handle the situation.
	CommonSubExpressionFound(&I, Other);
	return true; // One instruction eliminated!
	}

	return false;
	}

	bool GCSE::visitLoadInst(LoadInst &LI) {
	Value *Op = LI.getOperand(0);
	Function *F = LI.getParent()->getParent();

	for (Value::use_iterator UI = Op->use_begin(), UE = Op->use_end();
	UI != UE; ++UI)
	if (LoadInst Other = dyn_cast<LoadInst>(UI))
	// Check to see if this new load is not LI, but has the same operands...
	if (Other != &LI && IdenticalComplexInst(&LI, Other) &&
	TryToRemoveALoad(&LI, Other))
	return true; // An instruction was eliminated!

	return false;
	}

	static inline bool isInvalidatingInst(const Instruction &I) {
	return I.getOpcode() == Instruction::Store \|\|
	I.getOpcode() == Instruction::Call \|\|
	I.getOpcode() == Instruction::Invoke;
	}

	// TryToRemoveALoad - Try to remove one of L1 or L2. The problem with removing
	// loads is that intervening stores might make otherwise identical load's yield
	// different values. To ensure that this is not the case, we check that there
	// are no intervening stores or calls between the instructions.
	//
	bool GCSE::TryToRemoveALoad(LoadInst L1, LoadInst L2) {
	// Figure out which load dominates the other one. If neither dominates the
	// other we cannot eliminate one...
	//
	if (DomSetInfo->dominates(L2, L1))
	std::swap(L1, L2); // Make L1 dominate L2
	else if (!DomSetInfo->dominates(L1, L2))
	return false; // Neither instruction dominates the other one...

	BasicBlock BB1 = L1->getParent(), BB2 = L2->getParent();

	BasicBlock::iterator L1I = L1;

	// L1 now dominates L2. Check to see if the intervening instructions between
	// the two loads include a store or call...
	//
	if (BB1 == BB2) { // In same basic block?
	// In this degenerate case, no checking of global basic blocks has to occur
	// just check the instructions BETWEEN L1 & L2...
	//
	for (++L1I; &*L1I != L2; ++L1I)
	if (isInvalidatingInst(*L1I))
	return false; // Cannot eliminate load

	++NumLoadRemoved;
	CommonSubExpressionFound(L1, L2);
	return true;
	} else {
	// Make sure that there are no store instructions between L1 and the end of
	// it's basic block...
	//
	for (++L1I; L1I != BB1->end(); ++L1I)
	if (isInvalidatingInst(*L1I)) {
	BBContainsStore[BB1] = true;
	return false; // Cannot eliminate load
	}

	// Make sure that there are no store instructions between the start of BB2
	// and the second load instruction...
	//
	for (BasicBlock::iterator II = BB2->begin(); &*II != L2; ++II)
	if (isInvalidatingInst(*II)) {
	BBContainsStore[BB2] = true;
	return false; // Cannot eliminate load
	}

	// Do a depth first traversal of the inverse CFG starting at L2's block,
	// looking for L1's block. The inverse CFG is made up of the predecessor
	// nodes of a block... so all of the edges in the graph are "backward".
	//
	set<BasicBlock*> VisitedSet;
	for (pred_iterator PI = pred_begin(BB2), PE = pred_end(BB2); PI != PE; ++PI)
	if (CheckForInvalidatingInst(*PI, BB1, VisitedSet))
	return false;

	++NumLoadRemoved;
	CommonSubExpressionFound(L1, L2);
	return true;
	}
	return false;
	}

	// CheckForInvalidatingInst - Return true if BB or any of the predecessors of BB
	// (until DestBB) contain a store (or other invalidating) instruction.
	//
	bool GCSE::CheckForInvalidatingInst(BasicBlock BB, BasicBlock DestBB,
	set<BasicBlock*> &VisitedSet) {
	// Found the termination point!
	if (BB == DestBB \|\| VisitedSet.count(BB)) return false;

	// Avoid infinite recursion!
	VisitedSet.insert(BB);

	// Have we already checked this block?
	map<BasicBlock*, bool>::iterator MI = BBContainsStore.find(BB);

	if (MI != BBContainsStore.end()) {
	// If this block is known to contain a store, exit the recursion early...
	if (MI->second) return true;
	// Otherwise continue checking predecessors...
	} else {
	// We don't know if this basic block contains an invalidating instruction.
	// Check now:
	bool HasStore = std::find_if(BB->begin(), BB->end(),
	isInvalidatingInst) != BB->end();
	if ((BBContainsStore[BB] = HasStore)) // Update map
	return true; // Exit recursion early...
	}

	// Check all of our predecessor blocks...
	for (pred_iterator PI = pred_begin(BB), PE = pred_end(BB); PI != PE; ++PI)
	if (CheckForInvalidatingInst(*PI, DestBB, VisitedSet))
	return true;

	// None of our predecessor blocks contain a store, and we don't either!
	return false;
	}