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

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


 #include "SparcInternals.h"
 #include "llvm/Target/Sparc.h"
 #include "llvm/CodeGen/InstrScheduling.h"
 #include "llvm/CodeGen/InstrSelection.h"
 #include "llvm/CodeGen/MachineCodeForInstruction.h"
 #include "llvm/CodeGen/MachineCodeForMethod.h"
 #include "llvm/CodeGen/RegisterAllocation.h"
 #include "llvm/CodeGen/MachineInstr.h"
 #include "llvm/Method.h"
 #include "llvm/PassManager.h"
 #include <iostream>
 using std::cerr;

 // Build the MachineInstruction Description Array...
 const MachineInstrDescriptor SparcMachineInstrDesc[] = {
 #define I(ENUM, OPCODESTRING, NUMOPERANDS, RESULTPOS, MAXIMM, IMMSE, \
           NUMDELAYSLOTS, LATENCY, SCHEDCLASS, INSTFLAGS)             \
   { OPCODESTRING, NUMOPERANDS, RESULTPOS, MAXIMM, IMMSE,             \
           NUMDELAYSLOTS, LATENCY, SCHEDCLASS, INSTFLAGS },
 #include "SparcInstr.def"
 };

 //----------------------------------------------------------------------------
 // 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 InsertPrologEpilogCode
 //
 // Insert SAVE/RESTORE instructions for the method
 //
 // Insert prolog code at the unique method entry point.
 // Insert epilog code at each method exit point.
 // InsertPrologEpilog invokes these only if the method is not compiled
 // with the leaf method optimization.
 //
 //---------------------------------------------------------------------------
 static MachineInstr* minstrVec[MAX_INSTR_PER_VMINSTR];

 class InsertPrologEpilogCode : public MethodPass {
   TargetMachine &Target;
 public:
   inline InsertPrologEpilogCode(TargetMachine &T) : Target(T) {}
   bool runOnMethod(Method *M) {
     MachineCodeForMethod &mcodeInfo = MachineCodeForMethod::get(M);
     if (!mcodeInfo.isCompiledAsLeafMethod()) {
       InsertPrologCode(M);
       InsertEpilogCode(M);
     }
     return false;
   }

   void InsertPrologCode(Method *M);
   void InsertEpilogCode(Method *M);
 };

 void InsertPrologEpilogCode::InsertPrologCode(Method* method)
 {
   BasicBlock* entryBB = method->getEntryNode();
   unsigned N = GetInstructionsForProlog(entryBB, Target, minstrVec);
   assert(N <= MAX_INSTR_PER_VMINSTR);
   MachineCodeForBasicBlock& bbMvec = entryBB->getMachineInstrVec();
   bbMvec.insert(bbMvec.begin(), minstrVec, minstrVec+N);
 }


 void InsertPrologEpilogCode::InsertEpilogCode(Method* method)
 {
   for (Method::iterator I=method->begin(), E=method->end(); I != E; ++I)
     if ((*I)->getTerminator()->getOpcode() == Instruction::Ret)
       {
         BasicBlock* exitBB = *I;
         unsigned N = GetInstructionsForEpilog(exitBB, Target, minstrVec);

         MachineCodeForBasicBlock& bbMvec = exitBB->getMachineInstrVec();
         MachineCodeForInstruction &termMvec =
           MachineCodeForInstruction::get(exitBB->getTerminator());

         // Remove the NOPs in the delay slots of the return instruction
         const MachineInstrInfo &mii = Target.getInstrInfo();
         unsigned numNOPs = 0;
         while (termMvec.back()->getOpCode() == NOP)
           {
             assert( termMvec.back() == bbMvec.back());
             termMvec.pop_back();
             bbMvec.pop_back();
             ++numNOPs;
           }
         assert(termMvec.back() == bbMvec.back());

         // Check that we found the right number of NOPs and have the right
         // number of instructions to replace them.
         unsigned ndelays = mii.getNumDelaySlots(termMvec.back()->getOpCode());
         assert(numNOPs == ndelays && "Missing NOPs in delay slots?");
         assert(N == ndelays && "Cannot use epilog code for delay slots?");

         // Append the epilog code to the end of the basic block.
         bbMvec.push_back(minstrVec[0]);
       }
 }


 //---------------------------------------------------------------------------
 // class UltraSparcFrameInfo
 //
 // Purpose:
 //   Interface to stack frame layout info for the UltraSPARC.
 //   Starting offsets for each area of the stack frame are aligned at
 //   a multiple of getStackFrameSizeAlignment().
 //---------------------------------------------------------------------------

 int
 UltraSparcFrameInfo::getFirstAutomaticVarOffset(MachineCodeForMethod& ,
                                                 bool& pos) const
 {
   pos = false;                          // static stack area grows downwards
   return StaticAreaOffsetFromFP;
 }

 int
 UltraSparcFrameInfo::getRegSpillAreaOffset(MachineCodeForMethod& mcInfo,
                                            bool& pos) const
 {
   pos = false;                          // static stack area grows downwards
   unsigned int autoVarsSize = mcInfo.getAutomaticVarsSize();
   if (int mod = autoVarsSize % getStackFrameSizeAlignment())
     autoVarsSize += (getStackFrameSizeAlignment() - mod);
   return StaticAreaOffsetFromFP - autoVarsSize;
 }

 int
 UltraSparcFrameInfo::getTmpAreaOffset(MachineCodeForMethod& mcInfo,
                                       bool& pos) const
 {
   pos = false;                          // static stack area grows downwards
   unsigned int autoVarsSize = mcInfo.getAutomaticVarsSize();
   unsigned int spillAreaSize = mcInfo.getRegSpillsSize();
   int offset = autoVarsSize + spillAreaSize;
   if (int mod = offset % getStackFrameSizeAlignment())
     offset += (getStackFrameSizeAlignment() - mod);
   return StaticAreaOffsetFromFP - offset;
 }

 int
 UltraSparcFrameInfo::getDynamicAreaOffset(MachineCodeForMethod& mcInfo,
                                           bool& pos) const
 {
   // dynamic stack area grows downwards starting at top of opt-args area
   unsigned int optArgsSize = mcInfo.getMaxOptionalArgsSize();
   int offset = optArgsSize + FirstOptionalOutgoingArgOffsetFromSP;
   assert(offset % getStackFrameSizeAlignment() == 0);
   return offset;
 }


 //---------------------------------------------------------------------------
 // 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"),
     instrInfo(*this),
     schedInfo(*this),
     regInfo(*this),
     frameInfo(*this),
     cacheInfo(*this)
 {
   optSizeForSubWordData = 4;
   minMemOpWordSize = 8;
   maxAtomicMemOpWordSize = 8;
 }


 //===---------------------------------------------------------------------===//
 // GenerateCodeForTarget Pass
 //
 // Native code generation for a specified target.
 //===---------------------------------------------------------------------===//

 class ConstructMachineCodeForMethod : public MethodPass {
   TargetMachine &Target;
 public:
   inline ConstructMachineCodeForMethod(TargetMachine &T) : Target(T) {}
   bool runOnMethod(Method *M) {
     MachineCodeForMethod::construct(M, Target);
     return false;
   }
 };

 class InstructionSelection : public MethodPass {
   TargetMachine &Target;
 public:
   inline InstructionSelection(TargetMachine &T) : Target(T) {}
   bool runOnMethod(Method *M) {
     if (SelectInstructionsForMethod(M, Target))
       cerr << "Instr selection failed for method " << M->getName() << "\n";
     return false;
   }
 };

 class InstructionScheduling : public MethodPass {
   TargetMachine &Target;
 public:
   inline InstructionScheduling(TargetMachine &T) : Target(T) {}
   bool runOnMethod(Method *M) {
     if (ScheduleInstructionsWithSSA(M, Target))
       cerr << "Instr scheduling failed for method " << M->getName() << "\n\n";
     return false;
   }
 };

 struct FreeMachineCodeForMethod : public MethodPass {
   static void freeMachineCode(Instruction *I) {
     MachineCodeForInstruction::destroy(I);
   }

   bool runOnMethod(Method *M) {
     for_each(M->inst_begin(), M->inst_end(), freeMachineCode);
     // Don't destruct MachineCodeForMethod - The global printer needs it
     //MachineCodeForMethod::destruct(M);
     return false;
   }
 };


 // addPassesToEmitAssembly - This method controls the entire code generation
 // process for the ultra sparc.
 //
 void UltraSparc::addPassesToEmitAssembly(PassManager &PM, std::ostream &Out) {
   // Construct and initialize the MachineCodeForMethod object for this method.
   PM.add(new ConstructMachineCodeForMethod(*this));

   PM.add(new InstructionSelection(*this));

   //PM.add(new InstructionScheduling(*this));

   PM.add(new RegisterAllocation(*this));

   //PM.add(new OptimizeLeafProcedures());
   //PM.add(new DeleteFallThroughBranches());
   //PM.add(new RemoveChainedBranches());    // should be folded with previous
   //PM.add(new RemoveRedundantOps());       // operations with %g0, NOP, etc.

   PM.add(new InsertPrologEpilogCode(*this));

   // Output assembly language to the .s file.  Assembly emission is split into
   // two parts: Method output and Global value output.  This is because method
   // output is pipelined with all of the rest of code generation stuff,
   // allowing machine code representations for methods to be free'd after the
   // method has been emitted.
   //
   PM.add(getMethodAsmPrinterPass(PM, Out));
   PM.add(new FreeMachineCodeForMethod());  // Free stuff no longer needed

   // Emit Module level assembly after all of the methods have been processed.
   PM.add(getModuleAsmPrinterPass(PM, Out));
 }
	// $Id$
	//***************************************************************************
	// File:
	// Sparc.cpp
	//
	// Purpose:
	//
	// History:
	// 7/15/01 - Vikram Adve - Created
	//**************************************************************************/


	#include "SparcInternals.h"
	#include "llvm/Target/Sparc.h"
	#include "llvm/CodeGen/InstrScheduling.h"
	#include "llvm/CodeGen/InstrSelection.h"
	#include "llvm/CodeGen/MachineCodeForInstruction.h"
	#include "llvm/CodeGen/MachineCodeForMethod.h"
	#include "llvm/CodeGen/RegisterAllocation.h"
	#include "llvm/CodeGen/MachineInstr.h"
	#include "llvm/Method.h"
	#include "llvm/PassManager.h"
	#include <iostream>
	using std::cerr;

	// Build the MachineInstruction Description Array...
	const MachineInstrDescriptor SparcMachineInstrDesc[] = {
	#define I(ENUM, OPCODESTRING, NUMOPERANDS, RESULTPOS, MAXIMM, IMMSE, \
	NUMDELAYSLOTS, LATENCY, SCHEDCLASS, INSTFLAGS) \
	{ OPCODESTRING, NUMOPERANDS, RESULTPOS, MAXIMM, IMMSE, \
	NUMDELAYSLOTS, LATENCY, SCHEDCLASS, INSTFLAGS },
	#include "SparcInstr.def"
	};

	//----------------------------------------------------------------------------
	// 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 InsertPrologEpilogCode
	//
	// Insert SAVE/RESTORE instructions for the method
	//
	// Insert prolog code at the unique method entry point.
	// Insert epilog code at each method exit point.
	// InsertPrologEpilog invokes these only if the method is not compiled
	// with the leaf method optimization.
	//
	//---------------------------------------------------------------------------
	static MachineInstr* minstrVec[MAX_INSTR_PER_VMINSTR];

	class InsertPrologEpilogCode : public MethodPass {
	TargetMachine &Target;
	public:
	inline InsertPrologEpilogCode(TargetMachine &T) : Target(T) {}
	bool runOnMethod(Method *M) {
	MachineCodeForMethod &mcodeInfo = MachineCodeForMethod::get(M);
	if (!mcodeInfo.isCompiledAsLeafMethod()) {
	InsertPrologCode(M);
	InsertEpilogCode(M);
	}
	return false;
	}

	void InsertPrologCode(Method *M);
	void InsertEpilogCode(Method *M);
	};

	void InsertPrologEpilogCode::InsertPrologCode(Method* method)
	{
	BasicBlock* entryBB = method->getEntryNode();
	unsigned N = GetInstructionsForProlog(entryBB, Target, minstrVec);
	assert(N <= MAX_INSTR_PER_VMINSTR);
	MachineCodeForBasicBlock& bbMvec = entryBB->getMachineInstrVec();
	bbMvec.insert(bbMvec.begin(), minstrVec, minstrVec+N);
	}


	void InsertPrologEpilogCode::InsertEpilogCode(Method* method)
	{
	for (Method::iterator I=method->begin(), E=method->end(); I != E; ++I)
	if ((*I)->getTerminator()->getOpcode() == Instruction::Ret)
	{
	BasicBlock* exitBB = *I;
	unsigned N = GetInstructionsForEpilog(exitBB, Target, minstrVec);

	MachineCodeForBasicBlock& bbMvec = exitBB->getMachineInstrVec();
	MachineCodeForInstruction &termMvec =
	MachineCodeForInstruction::get(exitBB->getTerminator());

	// Remove the NOPs in the delay slots of the return instruction
	const MachineInstrInfo &mii = Target.getInstrInfo();
	unsigned numNOPs = 0;
	while (termMvec.back()->getOpCode() == NOP)
	{
	assert( termMvec.back() == bbMvec.back());
	termMvec.pop_back();
	bbMvec.pop_back();
	++numNOPs;
	}
	assert(termMvec.back() == bbMvec.back());

	// Check that we found the right number of NOPs and have the right
	// number of instructions to replace them.
	unsigned ndelays = mii.getNumDelaySlots(termMvec.back()->getOpCode());
	assert(numNOPs == ndelays && "Missing NOPs in delay slots?");
	assert(N == ndelays && "Cannot use epilog code for delay slots?");

	// Append the epilog code to the end of the basic block.
	bbMvec.push_back(minstrVec[0]);
	}
	}


	//---------------------------------------------------------------------------
	// class UltraSparcFrameInfo
	//
	// Purpose:
	// Interface to stack frame layout info for the UltraSPARC.
	// Starting offsets for each area of the stack frame are aligned at
	// a multiple of getStackFrameSizeAlignment().
	//---------------------------------------------------------------------------

	int
	UltraSparcFrameInfo::getFirstAutomaticVarOffset(MachineCodeForMethod& ,
	bool& pos) const
	{
	pos = false; // static stack area grows downwards
	return StaticAreaOffsetFromFP;
	}

	int
	UltraSparcFrameInfo::getRegSpillAreaOffset(MachineCodeForMethod& mcInfo,
	bool& pos) const
	{
	pos = false; // static stack area grows downwards
	unsigned int autoVarsSize = mcInfo.getAutomaticVarsSize();
	if (int mod = autoVarsSize % getStackFrameSizeAlignment())
	autoVarsSize += (getStackFrameSizeAlignment() - mod);
	return StaticAreaOffsetFromFP - autoVarsSize;
	}

	int
	UltraSparcFrameInfo::getTmpAreaOffset(MachineCodeForMethod& mcInfo,
	bool& pos) const
	{
	pos = false; // static stack area grows downwards
	unsigned int autoVarsSize = mcInfo.getAutomaticVarsSize();
	unsigned int spillAreaSize = mcInfo.getRegSpillsSize();
	int offset = autoVarsSize + spillAreaSize;
	if (int mod = offset % getStackFrameSizeAlignment())
	offset += (getStackFrameSizeAlignment() - mod);
	return StaticAreaOffsetFromFP - offset;
	}

	int
	UltraSparcFrameInfo::getDynamicAreaOffset(MachineCodeForMethod& mcInfo,
	bool& pos) const
	{
	// dynamic stack area grows downwards starting at top of opt-args area
	unsigned int optArgsSize = mcInfo.getMaxOptionalArgsSize();
	int offset = optArgsSize + FirstOptionalOutgoingArgOffsetFromSP;
	assert(offset % getStackFrameSizeAlignment() == 0);
	return offset;
	}


	//---------------------------------------------------------------------------
	// 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"),
	instrInfo(*this),
	schedInfo(*this),
	regInfo(*this),
	frameInfo(*this),
	cacheInfo(*this)
	{
	optSizeForSubWordData = 4;
	minMemOpWordSize = 8;
	maxAtomicMemOpWordSize = 8;
	}



	//===---------------------------------------------------------------------===//
	// GenerateCodeForTarget Pass
	//
	// Native code generation for a specified target.
	//===---------------------------------------------------------------------===//

	class ConstructMachineCodeForMethod : public MethodPass {
	TargetMachine &Target;
	public:
	inline ConstructMachineCodeForMethod(TargetMachine &T) : Target(T) {}
	bool runOnMethod(Method *M) {
	MachineCodeForMethod::construct(M, Target);
	return false;
	}
	};

	class InstructionSelection : public MethodPass {
	TargetMachine &Target;
	public:
	inline InstructionSelection(TargetMachine &T) : Target(T) {}
	bool runOnMethod(Method *M) {
	if (SelectInstructionsForMethod(M, Target))
	cerr << "Instr selection failed for method " << M->getName() << "\n";
	return false;
	}
	};

	class InstructionScheduling : public MethodPass {
	TargetMachine &Target;
	public:
	inline InstructionScheduling(TargetMachine &T) : Target(T) {}
	bool runOnMethod(Method *M) {
	if (ScheduleInstructionsWithSSA(M, Target))
	cerr << "Instr scheduling failed for method " << M->getName() << "\n\n";
	return false;
	}
	};

	struct FreeMachineCodeForMethod : public MethodPass {
	static void freeMachineCode(Instruction *I) {
	MachineCodeForInstruction::destroy(I);
	}

	bool runOnMethod(Method *M) {
	for_each(M->inst_begin(), M->inst_end(), freeMachineCode);
	// Don't destruct MachineCodeForMethod - The global printer needs it
	//MachineCodeForMethod::destruct(M);
	return false;
	}
	};



	// addPassesToEmitAssembly - This method controls the entire code generation
	// process for the ultra sparc.
	//
	void UltraSparc::addPassesToEmitAssembly(PassManager &PM, std::ostream &Out) {
	// Construct and initialize the MachineCodeForMethod object for this method.
	PM.add(new ConstructMachineCodeForMethod(*this));

	PM.add(new InstructionSelection(*this));

	//PM.add(new InstructionScheduling(*this));

	PM.add(new RegisterAllocation(*this));

	//PM.add(new OptimizeLeafProcedures());
	//PM.add(new DeleteFallThroughBranches());
	//PM.add(new RemoveChainedBranches()); // should be folded with previous
	//PM.add(new RemoveRedundantOps()); // operations with %g0, NOP, etc.

	PM.add(new InsertPrologEpilogCode(*this));

	// Output assembly language to the .s file. Assembly emission is split into
	// two parts: Method output and Global value output. This is because method
	// output is pipelined with all of the rest of code generation stuff,
	// allowing machine code representations for methods to be free'd after the
	// method has been emitted.
	//
	PM.add(getMethodAsmPrinterPass(PM, Out));
	PM.add(new FreeMachineCodeForMethod()); // Free stuff no longer needed

	// Emit Module level assembly after all of the methods have been processed.
	PM.add(getModuleAsmPrinterPass(PM, Out));
	}