lib/Analysis/LiveVar/FunctionLiveVarInfo.cpp - llvm - Git at Google

 //===-- FunctionLiveVarInfo.cpp - Live Variable Analysis for a Function ---===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file was developed by the LLVM research group and is distributed under
 // the University of Illinois Open Source License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This is the interface to function level live variable information that is
 // provided by live variable analysis.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/CodeGen/FunctionLiveVarInfo.h"
 #include "llvm/CodeGen/MachineInstr.h"
 #include "llvm/CodeGen/MachineFunction.h"
 #include "llvm/Target/TargetMachine.h"
 #include "llvm/Target/TargetInstrInfo.h"
 #include "llvm/Support/CFG.h"
 #include "Support/PostOrderIterator.h"
 #include "Support/SetOperations.h"
 #include "Support/CommandLine.h"
 #include "BBLiveVar.h"

 static RegisterAnalysis<FunctionLiveVarInfo>
 X("livevar", "Live Variable Analysis");

 LiveVarDebugLevel_t DEBUG_LV;

 static cl::opt<LiveVarDebugLevel_t, true>
 DEBUG_LV_opt("dlivevar", cl::Hidden, cl::location(DEBUG_LV),
              cl::desc("enable live-variable debugging information"),
              cl::values(
 clEnumValN(LV_DEBUG_None   , "n", "disable debug output"),
 clEnumValN(LV_DEBUG_Normal , "y", "enable debug output"),
 clEnumValN(LV_DEBUG_Instr,   "i", "print live-var sets before/after "
            "every machine instrn"),
 clEnumValN(LV_DEBUG_Verbose, "v", "print def, use sets for every instrn also"),
                         0));


 //-----------------------------------------------------------------------------
 // Accessor Functions
 //-----------------------------------------------------------------------------

 // gets OutSet of a BB
 const ValueSet &FunctionLiveVarInfo::getOutSetOfBB(const BasicBlock *BB) const {
   return BBLiveVarInfo.find(BB)->second->getOutSet();
 }
       ValueSet &FunctionLiveVarInfo::getOutSetOfBB(const BasicBlock *BB)       {
   return BBLiveVarInfo[BB]->getOutSet();
 }

 // gets InSet of a BB
 const ValueSet &FunctionLiveVarInfo::getInSetOfBB(const BasicBlock *BB) const {
   return BBLiveVarInfo.find(BB)->second->getInSet();
 }
 ValueSet &FunctionLiveVarInfo::getInSetOfBB(const BasicBlock *BB) {
   return BBLiveVarInfo[BB]->getInSet();
 }


 //-----------------------------------------------------------------------------
 // Performs live var analysis for a function
 //-----------------------------------------------------------------------------

 bool FunctionLiveVarInfo::runOnFunction(Function &F) {
   M = &F;
   if (DEBUG_LV) std::cerr << "Analysing live variables ...\n";

   // create and initialize all the BBLiveVars of the CFG
   constructBBs(M);

   unsigned int iter=0;
   while (doSingleBackwardPass(M, iter++))
     ; // Iterate until we are done.

   if (DEBUG_LV) std::cerr << "Live Variable Analysis complete!\n";
   return false;
 }


 //-----------------------------------------------------------------------------
 // constructs BBLiveVars and init Def and In sets
 //-----------------------------------------------------------------------------

 void FunctionLiveVarInfo::constructBBs(const Function *F) {
   unsigned POId = 0;                // Reverse Depth-first Order ID
   std::map<const BasicBlock*, unsigned> PONumbering;

   for (po_iterator<const Function*> BBI = po_begin(M), BBE = po_end(M);
       BBI != BBE; ++BBI)
     PONumbering[*BBI] = POId++;

   MachineFunction &MF = MachineFunction::get(F);
   for (MachineFunction::iterator I = MF.begin(), E = MF.end(); I != E; ++I) {
     const BasicBlock &BB = *I->getBasicBlock();        // get the current BB
     if (DEBUG_LV) std::cerr << " For BB " << RAV(BB) << ":\n";

     BBLiveVar *LVBB;
     std::map<const BasicBlock*, unsigned>::iterator POI = PONumbering.find(&BB);
     if (POI != PONumbering.end()) {
       // create a new BBLiveVar
       LVBB = new BBLiveVar(BB, *I, POId);
     } else {
       // The PO iterator does not discover unreachable blocks, but the random
       // iterator later may access these blocks.  We must make sure to
       // initialize unreachable blocks as well.  However, LV info is not correct
       // for those blocks (they are not analyzed)
       //
       LVBB = new BBLiveVar(BB, *I, ++POId);
     }
     BBLiveVarInfo[&BB] = LVBB;

     if (DEBUG_LV)
       LVBB->printAllSets();
   }
 }


 //-----------------------------------------------------------------------------
 // do one backward pass over the CFG (for iterative analysis)
 //-----------------------------------------------------------------------------

 bool FunctionLiveVarInfo::doSingleBackwardPass(const Function *M,
                                                unsigned iter) {
   if (DEBUG_LV) std::cerr << "\n After Backward Pass " << iter << "...\n";

   bool NeedAnotherIteration = false;
   for (po_iterator<const Function*> BBI = po_begin(M), BBE = po_end(M);
        BBI != BBE; ++BBI) {
     BBLiveVar *LVBB = BBLiveVarInfo[*BBI];
     assert(LVBB && "BasicBlock information not set for block!");

     if (DEBUG_LV) std::cerr << " For BB " << (*BBI)->getName() << ":\n";

     // InSets are initialized to "GenSet". Recompute only if OutSet changed.
     if(LVBB->isOutSetChanged())
       LVBB->applyTransferFunc();        // apply the Tran Func to calc InSet

     // OutSets are initialized to EMPTY.  Recompute on first iter or if InSet
     // changed.
     if (iter == 0 || LVBB->isInSetChanged())        // to calc Outsets of preds
       NeedAnotherIteration |= LVBB->applyFlowFunc(BBLiveVarInfo);

     if (DEBUG_LV) LVBB->printInOutSets();
   }

   // true if we need to reiterate over the CFG
   return NeedAnotherIteration;
 }


 void FunctionLiveVarInfo::releaseMemory() {
   // First remove all BBLiveVars created in constructBBs().
   if (M) {
     for (Function::const_iterator I = M->begin(), E = M->end(); I != E; ++I)
       delete BBLiveVarInfo[I];
     BBLiveVarInfo.clear();
   }
   M = 0;

   // Then delete all objects of type ValueSet created in calcLiveVarSetsForBB
   // and entered into MInst2LVSetBI and MInst2LVSetAI (these are caches
   // to return ValueSet's before/after a machine instruction quickly).
   // We do not need to free up ValueSets in MInst2LVSetAI because it holds
   // pointers to the same sets as in MInst2LVSetBI (for all instructions
   // except the last one in a BB) or in BBLiveVar (for the last instruction).
   //
   for (hash_map<const MachineInstr*, ValueSet*>::iterator
          MI = MInst2LVSetBI.begin(),
          ME = MInst2LVSetBI.end(); MI != ME; ++MI)
     delete MI->second;           // delete all ValueSets in  MInst2LVSetBI

   MInst2LVSetBI.clear();
   MInst2LVSetAI.clear();
 }


 //-----------------------------------------------------------------------------
 // Following functions will give the LiveVar info for any machine instr in
 // a function. It should be called after a call to analyze().
 //
 // These functions calculate live var info for all the machine instrs in a
 // BB when LVInfo for one inst is requested. Hence, this function is useful
 // when live var info is required for many (or all) instructions in a basic
 // block. Also, the arguments to this function does not require specific
 // iterators.
 //-----------------------------------------------------------------------------

 //-----------------------------------------------------------------------------
 // Gives live variable information before a machine instruction
 //-----------------------------------------------------------------------------

 const ValueSet &
 FunctionLiveVarInfo::getLiveVarSetBeforeMInst(const MachineInstr *MI,
                                               const BasicBlock *BB) {
   ValueSet* &LVSet = MInst2LVSetBI[MI]; // ref. to map entry
   if (LVSet == NULL && BB != NULL) {    // if not found and BB provided
     calcLiveVarSetsForBB(BB);           // calc LVSet for all instrs in BB
     assert(LVSet != NULL);
   }
   return *LVSet;
 }


 //-----------------------------------------------------------------------------
 // Gives live variable information after a machine instruction
 //-----------------------------------------------------------------------------

 const ValueSet &
 FunctionLiveVarInfo::getLiveVarSetAfterMInst(const MachineInstr *MI,
                                              const BasicBlock *BB) {

   ValueSet* &LVSet = MInst2LVSetAI[MI]; // ref. to map entry
   if (LVSet == NULL && BB != NULL) {    // if not found and BB provided
     calcLiveVarSetsForBB(BB);           // calc LVSet for all instrs in BB
     assert(LVSet != NULL);
   }
   return *LVSet;
 }

 // This function applies a machine instr to a live var set (accepts OutSet) and
 // makes necessary changes to it (produces InSet). Note that two for loops are
 // used to first kill all defs and then to add all uses. This is because there
 // can be instructions like Val = Val + 1 since we allow multiple defs to a
 // machine instruction operand.
 //
 static void applyTranferFuncForMInst(ValueSet &LVS, const MachineInstr *MInst) {
   for (MachineInstr::const_val_op_iterator OpI = MInst->begin(),
          OpE = MInst->end(); OpI != OpE; ++OpI) {
     if (OpI.isDefOnly() || OpI.isDefAndUse()) // kill if this operand is a def
       LVS.erase(*OpI);                        // this definition kills any uses
   }

   // do for implicit operands as well
   for (unsigned i=0; i < MInst->getNumImplicitRefs(); ++i) {
     if (MInst->getImplicitOp(i).opIsDefOnly() ||
         MInst->getImplicitOp(i).opIsDefAndUse())
       LVS.erase(MInst->getImplicitRef(i));
   }

   for (MachineInstr::const_val_op_iterator OpI = MInst->begin(),
          OpE = MInst->end(); OpI != OpE; ++OpI) {
     if (!isa<BasicBlock>(*OpI))      // don't process labels
       // add only if this operand is a use
       if (!OpI.isDefOnly() || OpI.isDefAndUse() )
         LVS.insert(*OpI);            // An operand is a use - so add to use set
   }

   // do for implicit operands as well
   for (unsigned i = 0, e = MInst->getNumImplicitRefs(); i != e; ++i)
     if (MInst->getImplicitOp(i).opIsUse() ||
         MInst->getImplicitOp(i).opIsDefAndUse())
       LVS.insert(MInst->getImplicitRef(i));
 }

 //-----------------------------------------------------------------------------
 // This method calculates the live variable information for all the
 // instructions in a basic block and enter the newly constructed live
 // variable sets into a the caches (MInst2LVSetAI, MInst2LVSetBI)
 //-----------------------------------------------------------------------------

 void FunctionLiveVarInfo::calcLiveVarSetsForBB(const BasicBlock *BB) {
   BBLiveVar *BBLV = BBLiveVarInfo[BB];
   assert(BBLV && "BBLiveVar annotation doesn't exist?");
   const MachineBasicBlock &MIVec = BBLV->getMachineBasicBlock();
   const MachineFunction &MF = MachineFunction::get(M);
   const TargetMachine &TM = MF.getTarget();

   if (DEBUG_LV >= LV_DEBUG_Instr)
     std::cerr << "\n======For BB " << BB->getName()
               << ": Live var sets for instructions======\n";

   ValueSet *SetAI = &getOutSetOfBB(BB);         // init SetAI with OutSet
   ValueSet CurSet(*SetAI);                      // CurSet now contains OutSet

   // iterate over all the machine instructions in BB
   for (MachineBasicBlock::const_reverse_iterator MII = MIVec.rbegin(),
          MIE = MIVec.rend(); MII != MIE; ++MII) {
     // MI is cur machine inst
     const MachineInstr *MI = *MII;

     MInst2LVSetAI[MI] = SetAI;                 // record in After Inst map

     applyTranferFuncForMInst(CurSet, MI);      // apply the transfer Func
     ValueSet *NewSet = new ValueSet(CurSet);   // create a new set with a copy
                                                // of the set after T/F
     MInst2LVSetBI[MI] = NewSet;                // record in Before Inst map

     // If the current machine instruction has delay slots, mark values
     // used by this instruction as live before and after each delay slot
     // instruction (After(MI) is the same as Before(MI+1) except for last MI).
     if (unsigned DS = TM.getInstrInfo().getNumDelaySlots(MI->getOpCode())) {
       MachineBasicBlock::const_iterator fwdMII = MII.base(); // ptr to *next* MI
       for (unsigned i = 0; i < DS; ++i, ++fwdMII) {
         assert(fwdMII != MIVec.end() && "Missing instruction in delay slot?");
         MachineInstr* DelaySlotMI = *fwdMII;
         if (! TM.getInstrInfo().isNop(DelaySlotMI->getOpCode())) {
           set_union(*MInst2LVSetBI[DelaySlotMI], *NewSet);
           if (i+1 == DS)
             set_union(*MInst2LVSetAI[DelaySlotMI], *NewSet);
         }
       }
     }

     if (DEBUG_LV >= LV_DEBUG_Instr) {
       std::cerr << "\nLive var sets before/after instruction " << *MI;
       std::cerr << "  Before: ";   printSet(*NewSet);  std::cerr << "\n";
       std::cerr << "  After : ";   printSet(*SetAI);   std::cerr << "\n";
     }

     // SetAI will be used in the next iteration
     SetAI = NewSet;
   }
 }
	//===-- FunctionLiveVarInfo.cpp - Live Variable Analysis for a Function ---===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file was developed by the LLVM research group and is distributed under
	// the University of Illinois Open Source License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This is the interface to function level live variable information that is
	// provided by live variable analysis.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/CodeGen/FunctionLiveVarInfo.h"
	#include "llvm/CodeGen/MachineInstr.h"
	#include "llvm/CodeGen/MachineFunction.h"
	#include "llvm/Target/TargetMachine.h"
	#include "llvm/Target/TargetInstrInfo.h"
	#include "llvm/Support/CFG.h"
	#include "Support/PostOrderIterator.h"
	#include "Support/SetOperations.h"
	#include "Support/CommandLine.h"
	#include "BBLiveVar.h"

	static RegisterAnalysis<FunctionLiveVarInfo>
	X("livevar", "Live Variable Analysis");

	LiveVarDebugLevel_t DEBUG_LV;

	static cl::opt<LiveVarDebugLevel_t, true>
	DEBUG_LV_opt("dlivevar", cl::Hidden, cl::location(DEBUG_LV),
	cl::desc("enable live-variable debugging information"),
	cl::values(
	clEnumValN(LV_DEBUG_None , "n", "disable debug output"),
	clEnumValN(LV_DEBUG_Normal , "y", "enable debug output"),
	clEnumValN(LV_DEBUG_Instr, "i", "print live-var sets before/after "
	"every machine instrn"),
	clEnumValN(LV_DEBUG_Verbose, "v", "print def, use sets for every instrn also"),
	0));



	//-----------------------------------------------------------------------------
	// Accessor Functions
	//-----------------------------------------------------------------------------

	// gets OutSet of a BB
	const ValueSet &FunctionLiveVarInfo::getOutSetOfBB(const BasicBlock *BB) const {
	return BBLiveVarInfo.find(BB)->second->getOutSet();
	}
	ValueSet &FunctionLiveVarInfo::getOutSetOfBB(const BasicBlock *BB) {
	return BBLiveVarInfo[BB]->getOutSet();
	}

	// gets InSet of a BB
	const ValueSet &FunctionLiveVarInfo::getInSetOfBB(const BasicBlock *BB) const {
	return BBLiveVarInfo.find(BB)->second->getInSet();
	}
	ValueSet &FunctionLiveVarInfo::getInSetOfBB(const BasicBlock *BB) {
	return BBLiveVarInfo[BB]->getInSet();
	}


	//-----------------------------------------------------------------------------
	// Performs live var analysis for a function
	//-----------------------------------------------------------------------------

	bool FunctionLiveVarInfo::runOnFunction(Function &F) {
	M = &F;
	if (DEBUG_LV) std::cerr << "Analysing live variables ...\n";

	// create and initialize all the BBLiveVars of the CFG
	constructBBs(M);

	unsigned int iter=0;
	while (doSingleBackwardPass(M, iter++))
	; // Iterate until we are done.

	if (DEBUG_LV) std::cerr << "Live Variable Analysis complete!\n";
	return false;
	}


	//-----------------------------------------------------------------------------
	// constructs BBLiveVars and init Def and In sets
	//-----------------------------------------------------------------------------

	void FunctionLiveVarInfo::constructBBs(const Function *F) {
	unsigned POId = 0; // Reverse Depth-first Order ID
	std::map<const BasicBlock*, unsigned> PONumbering;

	for (po_iterator<const Function*> BBI = po_begin(M), BBE = po_end(M);
	BBI != BBE; ++BBI)
	PONumbering[*BBI] = POId++;

	MachineFunction &MF = MachineFunction::get(F);
	for (MachineFunction::iterator I = MF.begin(), E = MF.end(); I != E; ++I) {
	const BasicBlock &BB = *I->getBasicBlock(); // get the current BB
	if (DEBUG_LV) std::cerr << " For BB " << RAV(BB) << ":\n";

	BBLiveVar *LVBB;
	std::map<const BasicBlock*, unsigned>::iterator POI = PONumbering.find(&BB);
	if (POI != PONumbering.end()) {
	// create a new BBLiveVar
	LVBB = new BBLiveVar(BB, *I, POId);
	} else {
	// The PO iterator does not discover unreachable blocks, but the random
	// iterator later may access these blocks. We must make sure to
	// initialize unreachable blocks as well. However, LV info is not correct
	// for those blocks (they are not analyzed)
	//
	LVBB = new BBLiveVar(BB, *I, ++POId);
	}
	BBLiveVarInfo[&BB] = LVBB;

	if (DEBUG_LV)
	LVBB->printAllSets();
	}
	}


	//-----------------------------------------------------------------------------
	// do one backward pass over the CFG (for iterative analysis)
	//-----------------------------------------------------------------------------

	bool FunctionLiveVarInfo::doSingleBackwardPass(const Function *M,
	unsigned iter) {
	if (DEBUG_LV) std::cerr << "\n After Backward Pass " << iter << "...\n";

	bool NeedAnotherIteration = false;
	for (po_iterator<const Function*> BBI = po_begin(M), BBE = po_end(M);
	BBI != BBE; ++BBI) {
	BBLiveVar LVBB = BBLiveVarInfo[BBI];
	assert(LVBB && "BasicBlock information not set for block!");

	if (DEBUG_LV) std::cerr << " For BB " << (*BBI)->getName() << ":\n";

	// InSets are initialized to "GenSet". Recompute only if OutSet changed.
	if(LVBB->isOutSetChanged())
	LVBB->applyTransferFunc(); // apply the Tran Func to calc InSet

	// OutSets are initialized to EMPTY. Recompute on first iter or if InSet
	// changed.
	if (iter == 0 \|\| LVBB->isInSetChanged()) // to calc Outsets of preds
	NeedAnotherIteration \|= LVBB->applyFlowFunc(BBLiveVarInfo);

	if (DEBUG_LV) LVBB->printInOutSets();
	}

	// true if we need to reiterate over the CFG
	return NeedAnotherIteration;
	}


	void FunctionLiveVarInfo::releaseMemory() {
	// First remove all BBLiveVars created in constructBBs().
	if (M) {
	for (Function::const_iterator I = M->begin(), E = M->end(); I != E; ++I)
	delete BBLiveVarInfo[I];
	BBLiveVarInfo.clear();
	}
	M = 0;

	// Then delete all objects of type ValueSet created in calcLiveVarSetsForBB
	// and entered into MInst2LVSetBI and MInst2LVSetAI (these are caches
	// to return ValueSet's before/after a machine instruction quickly).
	// We do not need to free up ValueSets in MInst2LVSetAI because it holds
	// pointers to the same sets as in MInst2LVSetBI (for all instructions
	// except the last one in a BB) or in BBLiveVar (for the last instruction).
	//
	for (hash_map<const MachineInstr, ValueSet>::iterator
	MI = MInst2LVSetBI.begin(),
	ME = MInst2LVSetBI.end(); MI != ME; ++MI)
	delete MI->second; // delete all ValueSets in MInst2LVSetBI

	MInst2LVSetBI.clear();
	MInst2LVSetAI.clear();
	}




	//-----------------------------------------------------------------------------
	// Following functions will give the LiveVar info for any machine instr in
	// a function. It should be called after a call to analyze().
	//
	// These functions calculate live var info for all the machine instrs in a
	// BB when LVInfo for one inst is requested. Hence, this function is useful
	// when live var info is required for many (or all) instructions in a basic
	// block. Also, the arguments to this function does not require specific
	// iterators.
	//-----------------------------------------------------------------------------

	//-----------------------------------------------------------------------------
	// Gives live variable information before a machine instruction
	//-----------------------------------------------------------------------------

	const ValueSet &
	FunctionLiveVarInfo::getLiveVarSetBeforeMInst(const MachineInstr *MI,
	const BasicBlock *BB) {
	ValueSet* &LVSet = MInst2LVSetBI[MI]; // ref. to map entry
	if (LVSet == NULL && BB != NULL) { // if not found and BB provided
	calcLiveVarSetsForBB(BB); // calc LVSet for all instrs in BB
	assert(LVSet != NULL);
	}
	return *LVSet;
	}


	//-----------------------------------------------------------------------------
	// Gives live variable information after a machine instruction
	//-----------------------------------------------------------------------------

	const ValueSet &
	FunctionLiveVarInfo::getLiveVarSetAfterMInst(const MachineInstr *MI,
	const BasicBlock *BB) {

	ValueSet* &LVSet = MInst2LVSetAI[MI]; // ref. to map entry
	if (LVSet == NULL && BB != NULL) { // if not found and BB provided
	calcLiveVarSetsForBB(BB); // calc LVSet for all instrs in BB
	assert(LVSet != NULL);
	}
	return *LVSet;
	}

	// This function applies a machine instr to a live var set (accepts OutSet) and
	// makes necessary changes to it (produces InSet). Note that two for loops are
	// used to first kill all defs and then to add all uses. This is because there
	// can be instructions like Val = Val + 1 since we allow multiple defs to a
	// machine instruction operand.
	//
	static void applyTranferFuncForMInst(ValueSet &LVS, const MachineInstr *MInst) {
	for (MachineInstr::const_val_op_iterator OpI = MInst->begin(),
	OpE = MInst->end(); OpI != OpE; ++OpI) {
	if (OpI.isDefOnly() \|\| OpI.isDefAndUse()) // kill if this operand is a def
	LVS.erase(*OpI); // this definition kills any uses
	}

	// do for implicit operands as well
	for (unsigned i=0; i < MInst->getNumImplicitRefs(); ++i) {
	if (MInst->getImplicitOp(i).opIsDefOnly() \|\|
	MInst->getImplicitOp(i).opIsDefAndUse())
	LVS.erase(MInst->getImplicitRef(i));
	}

	for (MachineInstr::const_val_op_iterator OpI = MInst->begin(),
	OpE = MInst->end(); OpI != OpE; ++OpI) {
	if (!isa<BasicBlock>(*OpI)) // don't process labels
	// add only if this operand is a use
	if (!OpI.isDefOnly() \|\| OpI.isDefAndUse() )
	LVS.insert(*OpI); // An operand is a use - so add to use set
	}

	// do for implicit operands as well
	for (unsigned i = 0, e = MInst->getNumImplicitRefs(); i != e; ++i)
	if (MInst->getImplicitOp(i).opIsUse() \|\|
	MInst->getImplicitOp(i).opIsDefAndUse())
	LVS.insert(MInst->getImplicitRef(i));
	}

	//-----------------------------------------------------------------------------
	// This method calculates the live variable information for all the
	// instructions in a basic block and enter the newly constructed live
	// variable sets into a the caches (MInst2LVSetAI, MInst2LVSetBI)
	//-----------------------------------------------------------------------------

	void FunctionLiveVarInfo::calcLiveVarSetsForBB(const BasicBlock *BB) {
	BBLiveVar *BBLV = BBLiveVarInfo[BB];
	assert(BBLV && "BBLiveVar annotation doesn't exist?");
	const MachineBasicBlock &MIVec = BBLV->getMachineBasicBlock();
	const MachineFunction &MF = MachineFunction::get(M);
	const TargetMachine &TM = MF.getTarget();

	if (DEBUG_LV >= LV_DEBUG_Instr)
	std::cerr << "\n======For BB " << BB->getName()
	<< ": Live var sets for instructions======\n";

	ValueSet *SetAI = &getOutSetOfBB(BB); // init SetAI with OutSet
	ValueSet CurSet(*SetAI); // CurSet now contains OutSet

	// iterate over all the machine instructions in BB
	for (MachineBasicBlock::const_reverse_iterator MII = MIVec.rbegin(),
	MIE = MIVec.rend(); MII != MIE; ++MII) {
	// MI is cur machine inst
	const MachineInstr MI = MII;

	MInst2LVSetAI[MI] = SetAI; // record in After Inst map

	applyTranferFuncForMInst(CurSet, MI); // apply the transfer Func
	ValueSet *NewSet = new ValueSet(CurSet); // create a new set with a copy
	// of the set after T/F
	MInst2LVSetBI[MI] = NewSet; // record in Before Inst map

	// If the current machine instruction has delay slots, mark values
	// used by this instruction as live before and after each delay slot
	// instruction (After(MI) is the same as Before(MI+1) except for last MI).
	if (unsigned DS = TM.getInstrInfo().getNumDelaySlots(MI->getOpCode())) {
	MachineBasicBlock::const_iterator fwdMII = MII.base(); // ptr to next MI
	for (unsigned i = 0; i < DS; ++i, ++fwdMII) {
	assert(fwdMII != MIVec.end() && "Missing instruction in delay slot?");
	MachineInstr* DelaySlotMI = *fwdMII;
	if (! TM.getInstrInfo().isNop(DelaySlotMI->getOpCode())) {
	set_union(MInst2LVSetBI[DelaySlotMI], NewSet);
	if (i+1 == DS)
	set_union(MInst2LVSetAI[DelaySlotMI], NewSet);
	}
	}
	}

	if (DEBUG_LV >= LV_DEBUG_Instr) {
	std::cerr << "\nLive var sets before/after instruction " << *MI;
	std::cerr << " Before: "; printSet(*NewSet); std::cerr << "\n";
	std::cerr << " After : "; printSet(*SetAI); std::cerr << "\n";
	}

	// SetAI will be used in the next iteration
	SetAI = NewSet;
	}
	}