lib/Target/SparcV9/SparcV9TargetMachine.cpp - fp2-dev/platform/external/llvm - Gitiles

 //***************************************************************************
 // File:
 //	Sparc.cpp
 //
 // Purpose:
 //
 // History:
 //	7/15/01	 -  Vikram Adve  -  Created
 //**************************************************************************/

 #include "llvm/Target/Sparc.h"
 #include "SparcInternals.h"
 #include "llvm/Method.h"
 #include "llvm/CodeGen/InstrScheduling.h"
 #include "llvm/CodeGen/InstrSelection.h"

 #include "llvm/Analysis/LiveVar/MethodLiveVarInfo.h"
 #include "llvm/CodeGen/PhyRegAlloc.h"


 // allocateSparcTargetMachine - Allocate and return a subclass of TargetMachine
 // that implements the Sparc backend. (the llvm/CodeGen/Sparc.h interface)
 //
 TargetMachine *allocateSparcTargetMachine() { return new UltraSparc(); }


 //---------------------------------------------------------------------------
 // class UltraSparcInstrInfo
 //
 // Purpose:
 //   Information about individual instructions.
 //   Most information is stored in the SparcMachineInstrDesc array above.
 //   Other information is computed on demand, and most such functions
 //   default to member functions in base class MachineInstrInfo.
 //---------------------------------------------------------------------------

 /*ctor*/
 UltraSparcInstrInfo::UltraSparcInstrInfo()
   : MachineInstrInfo(SparcMachineInstrDesc,
 		     /*descSize = */ NUM_TOTAL_OPCODES,
 		     /*numRealOpCodes = */ NUM_REAL_OPCODES)
 {
 }


 //---------------------------------------------------------------------------
 // class UltraSparcSchedInfo
 //
 // Purpose:
 //   Scheduling information for the UltraSPARC.
 //   Primarily just initializes machine-dependent parameters in
 //   class MachineSchedInfo.
 //---------------------------------------------------------------------------

 /*ctor*/
 UltraSparcSchedInfo::UltraSparcSchedInfo(const MachineInstrInfo* mii)
   : MachineSchedInfo((unsigned int) SPARC_NUM_SCHED_CLASSES,
 		     mii,
 		     SparcRUsageDesc,
 		     SparcInstrUsageDeltas,
 		     SparcInstrIssueDeltas,
 		     sizeof(SparcInstrUsageDeltas)/sizeof(InstrRUsageDelta),
 		     sizeof(SparcInstrIssueDeltas)/sizeof(InstrIssueDelta))
 {
   maxNumIssueTotal = 4;
   longestIssueConflict = 0;		// computed from issuesGaps[]

   branchMispredictPenalty = 4;		// 4 for SPARC IIi
   branchTargetUnknownPenalty = 2;	// 2 for SPARC IIi
   l1DCacheMissPenalty = 8;		// 7 or 9 for SPARC IIi
   l1ICacheMissPenalty = 8;		// ? for SPARC IIi

   inOrderLoads = true;			// true for SPARC IIi
   inOrderIssue = true;			// true for SPARC IIi
   inOrderExec  = false;			// false for most architectures
   inOrderRetire= true;			// true for most architectures

   // must be called after above parameters are initialized.
   this->initializeResources();
 }

 void
 UltraSparcSchedInfo::initializeResources()
 {
   // Compute MachineSchedInfo::instrRUsages and MachineSchedInfo::issueGaps
   MachineSchedInfo::initializeResources();

   // Machine-dependent fixups go here.  None for now.
 }


 //---------------------------------------------------------------------------
 // class UltraSparcRegInfo
 //
 // Purpose:
 //   This class provides info about sparc register classes.
 //--------------------------------------------------------------------------

 #if 0
 UltraSparcRegInfo::UltraSparcRegInfo(const UltraSparc *const USI ) :
                                                       UltraSparcInfo(USI),
                                                       NumOfIntArgRegs(6),
                                                       NumOfFloatArgRegs(6)
   {
     MachineRegClassArr.push_back( new SparcIntRegClass(IntRegClassID) );
     MachineRegClassArr.push_back( new SparcFloatRegClass(FloatRegClassID) );
     MachineRegClassArr.push_back( new SparcIntCCRegClass(IntCCRegClassID) );
     MachineRegClassArr.push_back( new SparcFloatCCRegClass(FloatCCRegClassID));

     assert( SparcFloatRegOrder::StartOfNonVolatileRegs == 6 &&
 	    "6 Float regs are used for float arg passing");
   }

   // ***** TODO  insert deletes for reg classes
 UltraSparcRegInfo::~UltraSparcRegInfo(void) { }    // empty destructor

 #endif

 //---------------------------------------------------------------------------
 // UltraSparcRegInfo
 // Purpose:
 //   This method will color incoming args to a method. If there are more
 //   args than that can fit in regs, code will be inserted to pop them from
 //   stack
 //---------------------------------------------------------------------------


 void UltraSparcRegInfo::colorArgs(const Method *const Meth,
 				  LiveRangeInfo& LRI) const
 {

                                                  // get the argument list
   const Method::ArgumentListType& ArgList = Meth->getArgumentList();
                                                  // get an iterator to arg list
   Method::ArgumentListType::const_iterator ArgIt = ArgList.begin();
   unsigned intArgNo=0;

   // to keep track of which float regs are allocated for argument passing
   bool FloatArgUsedArr[NumOfFloatArgRegs];

   // init float arg used array
   for(unsigned i=0; i < NumOfFloatArgRegs; ++i)
     FloatArgUsedArr[i] = false;

   // for each argument
   for( ; ArgIt != ArgList.end() ; ++ArgIt) {

     // get the LR of arg
     LiveRange *const LR = LRI.getLiveRangeForValue((const Value *) *ArgIt);
     unsigned RegClassID = (LR->getRegClass())->getID();

     // if the arg is in int class - allocate a reg for an int arg
     if( RegClassID == IntRegClassID ) {

       if( intArgNo < NumOfIntArgRegs) {
 	LR->setColor( SparcIntRegOrder::i0 + intArgNo );

 	if( DEBUG_RA) printReg( LR );
       }

       else {
 	// TODO: Insert push code here
 	assert( 0 && "Insert push code here!");
       }
       ++intArgNo;
     }

     // if the arg is float/double
     else if ( RegClassID == FloatRegClassID) {

       if( LR->getTypeID() == Type::DoubleTyID ) {

 	// find the first reg # we can pass a double arg
 	for(unsigned i=0; i < NumOfFloatArgRegs; i+= 2) {
 	  if ( !FloatArgUsedArr[i] && !FloatArgUsedArr[i+1] ) {
 	    LR->setColor( SparcFloatRegOrder::f0 + i );
 	    FloatArgUsedArr[i] = true;
 	    FloatArgUsedArr[i+1] = true;
 	    if( DEBUG_RA) printReg( LR );
 	    break;
 	  }
 	}
 	if( ! LR->hasColor() ) { // if LR was not colored above

 	  assert(0 && "insert push code here for a double");

 	}

       }
       else if( LR->getTypeID() == Type::FloatTyID ) {

 	// find the first reg # we can pass a float arg
 	for(unsigned i=0; i < NumOfFloatArgRegs; ++i) {
 	  if ( !FloatArgUsedArr[i] ) {
 	    LR->setColor( SparcFloatRegOrder::f0 + i );
 	    FloatArgUsedArr[i] = true;
 	    if( DEBUG_RA) printReg( LR );
 	    break;
 	  }
 	}
 	if( ! LR->hasColor() ) { // if LR was not colored above
 	  assert(0 && "insert push code here for a float");
 	}

       }
       else
 	assert(0 && "unknown float type in method arg");

     } // float register class

     else
       assert(0 && "Unknown RegClassID");
   }

 }


 void UltraSparcRegInfo::printReg(const LiveRange *const LR) {

   unsigned RegClassID = (LR->getRegClass())->getID();

   cout << " *Node " << (LR->getUserIGNode())->getIndex();

   if( ! LR->hasColor() ) {
     cout << " - could not find a color" << endl;
     return;
   }

   // if a color is found

   cout << " colored with color "<< LR->getColor();

   if( RegClassID == IntRegClassID ) {

     cout<< " [" << SparcIntRegOrder::getRegName(LR->getColor()) ;
     cout << "]" << endl;
   }
   else if ( RegClassID == FloatRegClassID) {
     cout << "[" << SparcFloatRegOrder::getRegName(LR->getColor());
     if( LR->getTypeID() == Type::DoubleTyID )
       cout << "+" << SparcFloatRegOrder::getRegName(LR->getColor()+1);
     cout << "]" << endl;
   }


 }


 void UltraSparcRegInfo::colorCallArgs(vector<const Instruction *> &
 				      CallInstrList, LiveRangeInfo& LRI,
 				      AddedInstrMapType &AddedInstrMap) const
 {

   vector<const Instruction *>::const_iterator InstIt = CallInstrList.begin();

   for( ; InstIt != CallInstrList.end(); ++InstIt) {

     // Inst = LLVM call instruction
     const Instruction *const CallI = *InstIt;

     MachineCodeForVMInstr &  MInstVec = CallI->getMachineInstrVec();
     MachineCodeForVMInstr::const_iterator MIIt = MInstVec.begin();

     // find the CALL/JMMPL machine instruction
     for( ; MIIt != MInstVec.end() &&
 	   ! getUltraSparcInfo().getInstrInfo().isCall((*MIIt)->getOpCode());
 	 ++MIIt );

     assert( (MIIt != MInstVec.end())  && "CALL/JMPL not found");

     // CallMI = CALL/JMPL machine isntruction
     const MachineInstr *const CallMI = *MIIt;

     Instruction::op_const_iterator OpIt = CallI->op_begin();

     unsigned intArgNo=0;
     //unsigned NumOfCallInterfs = LR->getNumOfCallInterferences();

     // to keep track of which float regs are allocated for argument passing
     bool FloatArgUsedArr[NumOfFloatArgRegs];

     // init float arg used array
     for(unsigned i=0; i < NumOfFloatArgRegs; ++i)
       FloatArgUsedArr[i] = false;

     // go thru all the operands of LLVM instruction
     for( ; OpIt != CallI->op_end(); ++OpIt ) {

       // get the LR of call operand (parameter)
       LiveRange *const LR = LRI.getLiveRangeForValue((const Value *) *OpIt);

       if ( !LR ) {
 	cout << " Warning: In call instr, no LR for arg: " ;
 	printValue(*OpIt);
 	cout << endl;
 	continue;
       }

       unsigned RegClassID = (LR->getRegClass())->getID();

       // if the arg is in int class - allocate a reg for an int arg
       if( RegClassID == IntRegClassID ) {

 	if( intArgNo < NumOfIntArgRegs) {
 	  setCallArgColor( LR, SparcIntRegOrder::o0 + intArgNo );
 	}

 	else {
 	  // TODO: Insert push code here
 	  assert( 0 && "Insert push code here!");

 	  AddedInstrns * AI = AddedInstrMap[ CallMI ];
 	  if( ! AI ) AI = new AddedInstrns();

 	  // AI->InstrnsBefore.push_back( getStackPushInstr(LR) );
 	  AddedInstrMap[ CallMI ] = AI;

 	}
 	++intArgNo;
       }

       // if the arg is float/double
       else if ( RegClassID == FloatRegClassID) {

 	if( LR->getTypeID() == Type::DoubleTyID ) {

 	  // find the first reg # we can pass a double arg
 	  for(unsigned i=0; i < NumOfFloatArgRegs; i+= 2) {
 	    if ( !FloatArgUsedArr[i] && !FloatArgUsedArr[i+1] ) {
 	      setCallArgColor(LR, SparcFloatRegOrder::f0 + i );
 	      FloatArgUsedArr[i] = true;
 	      FloatArgUsedArr[i+1] = true;
 	      //if( DEBUG_RA) printReg( LR );
 	      break;
 	    }
 	  }
 	  if( ! LR->hasColor() ) { // if LR was not colored above

 	    assert(0 && "insert push code here for a double");

 	  }

 	}
 	else if( LR->getTypeID() == Type::FloatTyID ) {

 	  // find the first reg # we can pass a float arg
 	  for(unsigned i=0; i < NumOfFloatArgRegs; ++i) {
 	    if ( !FloatArgUsedArr[i] ) {
 	      setCallArgColor(LR, SparcFloatRegOrder::f0 + i );
 	      FloatArgUsedArr[i] = true;
 	      // LR->setColor( SparcFloatRegOrder::f0 + i );
 	      // if( DEBUG_RA) printReg( LR );
 	      break;
 	    }
 	  }
 	  if( ! LR->hasColor() ) { // if LR was not colored above
 	    assert(0 && "insert push code here for a float");
 	  }

 	}
 	else
 	  assert(0 && "unknown float type in method arg");

       } // float register class

       else
 	assert(0 && "Unknown RegClassID");


     } // for each operand in a call instruction


   } // for all call instrctions in CallInstrList

 }


 void UltraSparcRegInfo::setCallArgColor(LiveRange *const LR,
 					const unsigned RegNo) const {

   // if no call interference and LR is NOT previously colored (e.g., as an
   // incoming arg)
   if( ! LR->getNumOfCallInterferences() && ! LR->hasColor() ) {
     // we can directly allocate a %o register
     LR->setColor( RegNo);
     if( DEBUG_RA) printReg( LR );
   }
   else {                        // there are call interferences

     /*
     // insert a copy machine instr to copy from LR to %o(reg)
     PreMInstrMap[ CallMI ] =
     getNewCopyMInstr( LR->,  SparcIntRegOrder::o0 + intArgNo );
     */
     cout << " $$$ TODO: Insert a copy for call argument!: " << endl;

     // We don't color LR here. It's colored as any other normal LR
   }

 }


 //---------------------------------------------------------------------------
 // class UltraSparcMachine
 //
 // Purpose:
 //   Primary interface to machine description for the UltraSPARC.
 //   Primarily just initializes machine-dependent parameters in
 //   class TargetMachine, and creates machine-dependent subclasses
 //   for classes such as MachineInstrInfo.
 //
 //---------------------------------------------------------------------------

 UltraSparc::UltraSparc() : TargetMachine("UltraSparc-Native"),
 			   InstSchedulingInfo(&InstInfo),
 			   RegInfo( this )  {
   optSizeForSubWordData = 4;
   minMemOpWordSize = 8;
   maxAtomicMemOpWordSize = 8;
   zeroRegNum = 0;			// %g0 always gives 0 on Sparc
 }


 //----------------------------------------------------------------------------
 // Entry point for register allocation for a module
 //----------------------------------------------------------------------------

 void AllocateRegisters(Method *M, TargetMachine &TM)
 {

   if ( (M)->isExternal() )     // don't process prototypes
     return;

   if( DEBUG_RA ) {
     cout << endl << "******************** Method "<< (M)->getName();
     cout <<        " ********************" <<endl;
   }

   MethodLiveVarInfo LVI(M );   // Analyze live varaibles
   LVI.analyze();


   PhyRegAlloc PRA(M, TM , &LVI); // allocate registers
   PRA.allocateRegisters();


   if( DEBUG_RA )  cout << endl << "Register allocation complete!" << endl;

 }


 bool UltraSparc::compileMethod(Method *M) {
   if (SelectInstructionsForMethod(M, *this)) {
     cerr << "Instruction selection failed for method " << M->getName()
        << "\n\n";
     return true;
   }

   if (ScheduleInstructionsWithSSA(M, *this, InstSchedulingInfo)) {
     cerr << "Instruction scheduling before allocation failed for method "
        << M->getName() << "\n\n";
     return true;
   }

   AllocateRegisters(M, *this);    // allocate registers


   return false;
 }
	//***************************************************************************
	// File:
	// Sparc.cpp
	//
	// Purpose:
	//
	// History:
	// 7/15/01 - Vikram Adve - Created
	//**************************************************************************/

	#include "llvm/Target/Sparc.h"
	#include "SparcInternals.h"
	#include "llvm/Method.h"
	#include "llvm/CodeGen/InstrScheduling.h"
	#include "llvm/CodeGen/InstrSelection.h"

	#include "llvm/Analysis/LiveVar/MethodLiveVarInfo.h"
	#include "llvm/CodeGen/PhyRegAlloc.h"


	// allocateSparcTargetMachine - Allocate and return a subclass of TargetMachine
	// that implements the Sparc backend. (the llvm/CodeGen/Sparc.h interface)
	//
	TargetMachine *allocateSparcTargetMachine() { return new UltraSparc(); }


	//---------------------------------------------------------------------------
	// class UltraSparcInstrInfo
	//
	// Purpose:
	// Information about individual instructions.
	// Most information is stored in the SparcMachineInstrDesc array above.
	// Other information is computed on demand, and most such functions
	// default to member functions in base class MachineInstrInfo.
	//---------------------------------------------------------------------------

	/ctor/
	UltraSparcInstrInfo::UltraSparcInstrInfo()
	: MachineInstrInfo(SparcMachineInstrDesc,
	/descSize = / NUM_TOTAL_OPCODES,
	/numRealOpCodes = / NUM_REAL_OPCODES)
	{
	}


	//---------------------------------------------------------------------------
	// class UltraSparcSchedInfo
	//
	// Purpose:
	// Scheduling information for the UltraSPARC.
	// Primarily just initializes machine-dependent parameters in
	// class MachineSchedInfo.
	//---------------------------------------------------------------------------

	/ctor/
	UltraSparcSchedInfo::UltraSparcSchedInfo(const MachineInstrInfo* mii)
	: MachineSchedInfo((unsigned int) SPARC_NUM_SCHED_CLASSES,
	mii,
	SparcRUsageDesc,
	SparcInstrUsageDeltas,
	SparcInstrIssueDeltas,
	sizeof(SparcInstrUsageDeltas)/sizeof(InstrRUsageDelta),
	sizeof(SparcInstrIssueDeltas)/sizeof(InstrIssueDelta))
	{
	maxNumIssueTotal = 4;
	longestIssueConflict = 0; // computed from issuesGaps[]

	branchMispredictPenalty = 4; // 4 for SPARC IIi
	branchTargetUnknownPenalty = 2; // 2 for SPARC IIi
	l1DCacheMissPenalty = 8; // 7 or 9 for SPARC IIi
	l1ICacheMissPenalty = 8; // ? for SPARC IIi

	inOrderLoads = true; // true for SPARC IIi
	inOrderIssue = true; // true for SPARC IIi
	inOrderExec = false; // false for most architectures
	inOrderRetire= true; // true for most architectures

	// must be called after above parameters are initialized.
	this->initializeResources();
	}

	void
	UltraSparcSchedInfo::initializeResources()
	{
	// Compute MachineSchedInfo::instrRUsages and MachineSchedInfo::issueGaps
	MachineSchedInfo::initializeResources();

	// Machine-dependent fixups go here. None for now.
	}



	//---------------------------------------------------------------------------
	// class UltraSparcRegInfo
	//
	// Purpose:
	// This class provides info about sparc register classes.
	//--------------------------------------------------------------------------

	#if 0
	UltraSparcRegInfo::UltraSparcRegInfo(const UltraSparc *const USI ) :
	UltraSparcInfo(USI),
	NumOfIntArgRegs(6),
	NumOfFloatArgRegs(6)
	{
	MachineRegClassArr.push_back( new SparcIntRegClass(IntRegClassID) );
	MachineRegClassArr.push_back( new SparcFloatRegClass(FloatRegClassID) );
	MachineRegClassArr.push_back( new SparcIntCCRegClass(IntCCRegClassID) );
	MachineRegClassArr.push_back( new SparcFloatCCRegClass(FloatCCRegClassID));

	assert( SparcFloatRegOrder::StartOfNonVolatileRegs == 6 &&
	"6 Float regs are used for float arg passing");
	}

	// ***** TODO insert deletes for reg classes
	UltraSparcRegInfo::~UltraSparcRegInfo(void) { } // empty destructor

	#endif

	//---------------------------------------------------------------------------
	// UltraSparcRegInfo
	// Purpose:
	// This method will color incoming args to a method. If there are more
	// args than that can fit in regs, code will be inserted to pop them from
	// stack
	//---------------------------------------------------------------------------


	void UltraSparcRegInfo::colorArgs(const Method *const Meth,
	LiveRangeInfo& LRI) const
	{

	// get the argument list
	const Method::ArgumentListType& ArgList = Meth->getArgumentList();
	// get an iterator to arg list
	Method::ArgumentListType::const_iterator ArgIt = ArgList.begin();
	unsigned intArgNo=0;

	// to keep track of which float regs are allocated for argument passing
	bool FloatArgUsedArr[NumOfFloatArgRegs];

	// init float arg used array
	for(unsigned i=0; i < NumOfFloatArgRegs; ++i)
	FloatArgUsedArr[i] = false;

	// for each argument
	for( ; ArgIt != ArgList.end() ; ++ArgIt) {

	// get the LR of arg
	LiveRange const LR = LRI.getLiveRangeForValue((const Value ) *ArgIt);
	unsigned RegClassID = (LR->getRegClass())->getID();

	// if the arg is in int class - allocate a reg for an int arg
	if( RegClassID == IntRegClassID ) {

	if( intArgNo < NumOfIntArgRegs) {
	LR->setColor( SparcIntRegOrder::i0 + intArgNo );

	if( DEBUG_RA) printReg( LR );
	}

	else {
	// TODO: Insert push code here
	assert( 0 && "Insert push code here!");
	}
	++intArgNo;
	}

	// if the arg is float/double
	else if ( RegClassID == FloatRegClassID) {

	if( LR->getTypeID() == Type::DoubleTyID ) {

	// find the first reg # we can pass a double arg
	for(unsigned i=0; i < NumOfFloatArgRegs; i+= 2) {
	if ( !FloatArgUsedArr[i] && !FloatArgUsedArr[i+1] ) {
	LR->setColor( SparcFloatRegOrder::f0 + i );
	FloatArgUsedArr[i] = true;
	FloatArgUsedArr[i+1] = true;
	if( DEBUG_RA) printReg( LR );
	break;
	}
	}
	if( ! LR->hasColor() ) { // if LR was not colored above

	assert(0 && "insert push code here for a double");

	}

	}
	else if( LR->getTypeID() == Type::FloatTyID ) {

	// find the first reg # we can pass a float arg
	for(unsigned i=0; i < NumOfFloatArgRegs; ++i) {
	if ( !FloatArgUsedArr[i] ) {
	LR->setColor( SparcFloatRegOrder::f0 + i );
	FloatArgUsedArr[i] = true;
	if( DEBUG_RA) printReg( LR );
	break;
	}
	}
	if( ! LR->hasColor() ) { // if LR was not colored above
	assert(0 && "insert push code here for a float");
	}

	}
	else
	assert(0 && "unknown float type in method arg");

	} // float register class

	else
	assert(0 && "Unknown RegClassID");
	}

	}






	void UltraSparcRegInfo::printReg(const LiveRange *const LR) {

	unsigned RegClassID = (LR->getRegClass())->getID();

	cout << " *Node " << (LR->getUserIGNode())->getIndex();

	if( ! LR->hasColor() ) {
	cout << " - could not find a color" << endl;
	return;
	}

	// if a color is found

	cout << " colored with color "<< LR->getColor();

	if( RegClassID == IntRegClassID ) {

	cout<< " [" << SparcIntRegOrder::getRegName(LR->getColor()) ;
	cout << "]" << endl;
	}
	else if ( RegClassID == FloatRegClassID) {
	cout << "[" << SparcFloatRegOrder::getRegName(LR->getColor());
	if( LR->getTypeID() == Type::DoubleTyID )
	cout << "+" << SparcFloatRegOrder::getRegName(LR->getColor()+1);
	cout << "]" << endl;
	}


	}


	void UltraSparcRegInfo::colorCallArgs(vector<const Instruction *> &
	CallInstrList, LiveRangeInfo& LRI,
	AddedInstrMapType &AddedInstrMap) const
	{

	vector<const Instruction *>::const_iterator InstIt = CallInstrList.begin();

	for( ; InstIt != CallInstrList.end(); ++InstIt) {

	// Inst = LLVM call instruction
	const Instruction const CallI = InstIt;

	MachineCodeForVMInstr & MInstVec = CallI->getMachineInstrVec();
	MachineCodeForVMInstr::const_iterator MIIt = MInstVec.begin();

	// find the CALL/JMMPL machine instruction
	for( ; MIIt != MInstVec.end() &&
	! getUltraSparcInfo().getInstrInfo().isCall((*MIIt)->getOpCode());
	++MIIt );

	assert( (MIIt != MInstVec.end()) && "CALL/JMPL not found");

	// CallMI = CALL/JMPL machine isntruction
	const MachineInstr const CallMI = MIIt;

	Instruction::op_const_iterator OpIt = CallI->op_begin();

	unsigned intArgNo=0;
	//unsigned NumOfCallInterfs = LR->getNumOfCallInterferences();

	// to keep track of which float regs are allocated for argument passing
	bool FloatArgUsedArr[NumOfFloatArgRegs];

	// init float arg used array
	for(unsigned i=0; i < NumOfFloatArgRegs; ++i)
	FloatArgUsedArr[i] = false;

	// go thru all the operands of LLVM instruction
	for( ; OpIt != CallI->op_end(); ++OpIt ) {

	// get the LR of call operand (parameter)
	LiveRange const LR = LRI.getLiveRangeForValue((const Value ) *OpIt);

	if ( !LR ) {
	cout << " Warning: In call instr, no LR for arg: " ;
	printValue(*OpIt);
	cout << endl;
	continue;
	}

	unsigned RegClassID = (LR->getRegClass())->getID();

	// if the arg is in int class - allocate a reg for an int arg
	if( RegClassID == IntRegClassID ) {

	if( intArgNo < NumOfIntArgRegs) {
	setCallArgColor( LR, SparcIntRegOrder::o0 + intArgNo );
	}

	else {
	// TODO: Insert push code here
	assert( 0 && "Insert push code here!");

	AddedInstrns * AI = AddedInstrMap[ CallMI ];
	if( ! AI ) AI = new AddedInstrns();

	// AI->InstrnsBefore.push_back( getStackPushInstr(LR) );
	AddedInstrMap[ CallMI ] = AI;

	}
	++intArgNo;
	}

	// if the arg is float/double
	else if ( RegClassID == FloatRegClassID) {

	if( LR->getTypeID() == Type::DoubleTyID ) {

	// find the first reg # we can pass a double arg
	for(unsigned i=0; i < NumOfFloatArgRegs; i+= 2) {
	if ( !FloatArgUsedArr[i] && !FloatArgUsedArr[i+1] ) {
	setCallArgColor(LR, SparcFloatRegOrder::f0 + i );
	FloatArgUsedArr[i] = true;
	FloatArgUsedArr[i+1] = true;
	//if( DEBUG_RA) printReg( LR );
	break;
	}
	}
	if( ! LR->hasColor() ) { // if LR was not colored above

	assert(0 && "insert push code here for a double");

	}

	}
	else if( LR->getTypeID() == Type::FloatTyID ) {

	// find the first reg # we can pass a float arg
	for(unsigned i=0; i < NumOfFloatArgRegs; ++i) {
	if ( !FloatArgUsedArr[i] ) {
	setCallArgColor(LR, SparcFloatRegOrder::f0 + i );
	FloatArgUsedArr[i] = true;
	// LR->setColor( SparcFloatRegOrder::f0 + i );
	// if( DEBUG_RA) printReg( LR );
	break;
	}
	}
	if( ! LR->hasColor() ) { // if LR was not colored above
	assert(0 && "insert push code here for a float");
	}

	}
	else
	assert(0 && "unknown float type in method arg");

	} // float register class

	else
	assert(0 && "Unknown RegClassID");


	} // for each operand in a call instruction




	} // for all call instrctions in CallInstrList

	}


	void UltraSparcRegInfo::setCallArgColor(LiveRange *const LR,
	const unsigned RegNo) const {

	// if no call interference and LR is NOT previously colored (e.g., as an
	// incoming arg)
	if( ! LR->getNumOfCallInterferences() && ! LR->hasColor() ) {
	// we can directly allocate a %o register
	LR->setColor( RegNo);
	if( DEBUG_RA) printReg( LR );
	}
	else { // there are call interferences

	/*
	// insert a copy machine instr to copy from LR to %o(reg)
	PreMInstrMap[ CallMI ] =
	getNewCopyMInstr( LR->, SparcIntRegOrder::o0 + intArgNo );
	*/
	cout << " $$$ TODO: Insert a copy for call argument!: " << endl;

	// We don't color LR here. It's colored as any other normal LR
	}

	}





	//---------------------------------------------------------------------------
	// class UltraSparcMachine
	//
	// Purpose:
	// Primary interface to machine description for the UltraSPARC.
	// Primarily just initializes machine-dependent parameters in
	// class TargetMachine, and creates machine-dependent subclasses
	// for classes such as MachineInstrInfo.
	//
	//---------------------------------------------------------------------------

	UltraSparc::UltraSparc() : TargetMachine("UltraSparc-Native"),
	InstSchedulingInfo(&InstInfo),
	RegInfo( this ) {
	optSizeForSubWordData = 4;
	minMemOpWordSize = 8;
	maxAtomicMemOpWordSize = 8;
	zeroRegNum = 0; // %g0 always gives 0 on Sparc
	}



	//----------------------------------------------------------------------------
	// Entry point for register allocation for a module
	//----------------------------------------------------------------------------

	void AllocateRegisters(Method *M, TargetMachine &TM)
	{

	if ( (M)->isExternal() ) // don't process prototypes
	return;

	if( DEBUG_RA ) {
	cout << endl << "******************** Method "<< (M)->getName();
	cout << " ********************" <<endl;
	}

	MethodLiveVarInfo LVI(M ); // Analyze live varaibles
	LVI.analyze();


	PhyRegAlloc PRA(M, TM , &LVI); // allocate registers
	PRA.allocateRegisters();


	if( DEBUG_RA ) cout << endl << "Register allocation complete!" << endl;

	}





	bool UltraSparc::compileMethod(Method *M) {
	if (SelectInstructionsForMethod(M, *this)) {
	cerr << "Instruction selection failed for method " << M->getName()
	<< "\n\n";
	return true;
	}

	if (ScheduleInstructionsWithSSA(M, *this, InstSchedulingInfo)) {
	cerr << "Instruction scheduling before allocation failed for method "
	<< M->getName() << "\n\n";
	return true;
	}

	AllocateRegisters(M, *this); // allocate registers


	return false;
	}