third_party/LLVM/include/llvm/CodeGen/MachineRegisterInfo.h - SwiftShader - Git at Google

 //===-- llvm/CodeGen/MachineRegisterInfo.h ----------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines the MachineRegisterInfo class.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CODEGEN_MACHINEREGISTERINFO_H
 #define LLVM_CODEGEN_MACHINEREGISTERINFO_H

 #include "llvm/Target/TargetRegisterInfo.h"
 #include "llvm/ADT/BitVector.h"
 #include "llvm/ADT/IndexedMap.h"
 #include <vector>

 namespace llvm {

 /// MachineRegisterInfo - Keep track of information for virtual and physical
 /// registers, including vreg register classes, use/def chains for registers,
 /// etc.
 class MachineRegisterInfo {
   const TargetRegisterInfo *const TRI;

   /// IsSSA - True when the machine function is in SSA form and virtual
   /// registers have a single def.
   bool IsSSA;

   /// VRegInfo - Information we keep for each virtual register.
   ///
   /// Each element in this list contains the register class of the vreg and the
   /// start of the use/def list for the register.
   IndexedMap<std::pair<const TargetRegisterClass*, MachineOperand*>,
              VirtReg2IndexFunctor> VRegInfo;

   /// RegAllocHints - This vector records register allocation hints for virtual
   /// registers. For each virtual register, it keeps a register and hint type
   /// pair making up the allocation hint. Hint type is target specific except
   /// for the value 0 which means the second value of the pair is the preferred
   /// register for allocation. For example, if the hint is <0, 1024>, it means
   /// the allocator should prefer the physical register allocated to the virtual
   /// register of the hint.
   IndexedMap<std::pair<unsigned, unsigned>, VirtReg2IndexFunctor> RegAllocHints;

   /// PhysRegUseDefLists - This is an array of the head of the use/def list for
   /// physical registers.
   MachineOperand **PhysRegUseDefLists;

   /// UsedPhysRegs - This is a bit vector that is computed and set by the
   /// register allocator, and must be kept up to date by passes that run after
   /// register allocation (though most don't modify this).  This is used
   /// so that the code generator knows which callee save registers to save and
   /// for other target specific uses.
   BitVector UsedPhysRegs;

   /// LiveIns/LiveOuts - Keep track of the physical registers that are
   /// livein/liveout of the function.  Live in values are typically arguments in
   /// registers, live out values are typically return values in registers.
   /// LiveIn values are allowed to have virtual registers associated with them,
   /// stored in the second element.
   std::vector<std::pair<unsigned, unsigned> > LiveIns;
   std::vector<unsigned> LiveOuts;

   MachineRegisterInfo(const MachineRegisterInfo&); // DO NOT IMPLEMENT
   void operator=(const MachineRegisterInfo&);      // DO NOT IMPLEMENT
 public:
   explicit MachineRegisterInfo(const TargetRegisterInfo &TRI);
   ~MachineRegisterInfo();

   //===--------------------------------------------------------------------===//
   // Function State
   //===--------------------------------------------------------------------===//

   // isSSA - Returns true when the machine function is in SSA form. Early
   // passes require the machine function to be in SSA form where every virtual
   // register has a single defining instruction.
   //
   // The TwoAddressInstructionPass and PHIElimination passes take the machine
   // function out of SSA form when they introduce multiple defs per virtual
   // register.
   bool isSSA() const { return IsSSA; }

   // leaveSSA - Indicates that the machine function is no longer in SSA form.
   void leaveSSA() { IsSSA = false; }

   //===--------------------------------------------------------------------===//
   // Register Info
   //===--------------------------------------------------------------------===//

   /// reg_begin/reg_end - Provide iteration support to walk over all definitions
   /// and uses of a register within the MachineFunction that corresponds to this
   /// MachineRegisterInfo object.
   template<bool Uses, bool Defs, bool SkipDebug>
   class defusechain_iterator;

   /// reg_iterator/reg_begin/reg_end - Walk all defs and uses of the specified
   /// register.
   typedef defusechain_iterator<true,true,false> reg_iterator;
   reg_iterator reg_begin(unsigned RegNo) const {
     return reg_iterator(getRegUseDefListHead(RegNo));
   }
   static reg_iterator reg_end() { return reg_iterator(0); }

   /// reg_empty - Return true if there are no instructions using or defining the
   /// specified register (it may be live-in).
   bool reg_empty(unsigned RegNo) const { return reg_begin(RegNo) == reg_end(); }

   /// reg_nodbg_iterator/reg_nodbg_begin/reg_nodbg_end - Walk all defs and uses
   /// of the specified register, skipping those marked as Debug.
   typedef defusechain_iterator<true,true,true> reg_nodbg_iterator;
   reg_nodbg_iterator reg_nodbg_begin(unsigned RegNo) const {
     return reg_nodbg_iterator(getRegUseDefListHead(RegNo));
   }
   static reg_nodbg_iterator reg_nodbg_end() { return reg_nodbg_iterator(0); }

   /// reg_nodbg_empty - Return true if the only instructions using or defining
   /// Reg are Debug instructions.
   bool reg_nodbg_empty(unsigned RegNo) const {
     return reg_nodbg_begin(RegNo) == reg_nodbg_end();
   }

   /// def_iterator/def_begin/def_end - Walk all defs of the specified register.
   typedef defusechain_iterator<false,true,false> def_iterator;
   def_iterator def_begin(unsigned RegNo) const {
     return def_iterator(getRegUseDefListHead(RegNo));
   }
   static def_iterator def_end() { return def_iterator(0); }

   /// def_empty - Return true if there are no instructions defining the
   /// specified register (it may be live-in).
   bool def_empty(unsigned RegNo) const { return def_begin(RegNo) == def_end(); }

   /// use_iterator/use_begin/use_end - Walk all uses of the specified register.
   typedef defusechain_iterator<true,false,false> use_iterator;
   use_iterator use_begin(unsigned RegNo) const {
     return use_iterator(getRegUseDefListHead(RegNo));
   }
   static use_iterator use_end() { return use_iterator(0); }

   /// use_empty - Return true if there are no instructions using the specified
   /// register.
   bool use_empty(unsigned RegNo) const { return use_begin(RegNo) == use_end(); }

   /// hasOneUse - Return true if there is exactly one instruction using the
   /// specified register.
   bool hasOneUse(unsigned RegNo) const;

   /// use_nodbg_iterator/use_nodbg_begin/use_nodbg_end - Walk all uses of the
   /// specified register, skipping those marked as Debug.
   typedef defusechain_iterator<true,false,true> use_nodbg_iterator;
   use_nodbg_iterator use_nodbg_begin(unsigned RegNo) const {
     return use_nodbg_iterator(getRegUseDefListHead(RegNo));
   }
   static use_nodbg_iterator use_nodbg_end() { return use_nodbg_iterator(0); }

   /// use_nodbg_empty - Return true if there are no non-Debug instructions
   /// using the specified register.
   bool use_nodbg_empty(unsigned RegNo) const {
     return use_nodbg_begin(RegNo) == use_nodbg_end();
   }

   /// hasOneNonDBGUse - Return true if there is exactly one non-Debug
   /// instruction using the specified register.
   bool hasOneNonDBGUse(unsigned RegNo) const;

   /// replaceRegWith - Replace all instances of FromReg with ToReg in the
   /// machine function.  This is like llvm-level X->replaceAllUsesWith(Y),
   /// except that it also changes any definitions of the register as well.
   void replaceRegWith(unsigned FromReg, unsigned ToReg);

   /// getRegUseDefListHead - Return the head pointer for the register use/def
   /// list for the specified virtual or physical register.
   MachineOperand *&getRegUseDefListHead(unsigned RegNo) {
     if (TargetRegisterInfo::isVirtualRegister(RegNo))
       return VRegInfo[RegNo].second;
     return PhysRegUseDefLists[RegNo];
   }

   MachineOperand *getRegUseDefListHead(unsigned RegNo) const {
     if (TargetRegisterInfo::isVirtualRegister(RegNo))
       return VRegInfo[RegNo].second;
     return PhysRegUseDefLists[RegNo];
   }

   /// getVRegDef - Return the machine instr that defines the specified virtual
   /// register or null if none is found.  This assumes that the code is in SSA
   /// form, so there should only be one definition.
   MachineInstr *getVRegDef(unsigned Reg) const;

   /// clearKillFlags - Iterate over all the uses of the given register and
   /// clear the kill flag from the MachineOperand. This function is used by
   /// optimization passes which extend register lifetimes and need only
   /// preserve conservative kill flag information.
   void clearKillFlags(unsigned Reg) const;

 #ifndef NDEBUG
   void dumpUses(unsigned RegNo) const;
 #endif

   //===--------------------------------------------------------------------===//
   // Virtual Register Info
   //===--------------------------------------------------------------------===//

   /// getRegClass - Return the register class of the specified virtual register.
   ///
   const TargetRegisterClass *getRegClass(unsigned Reg) const {
     return VRegInfo[Reg].first;
   }

   /// setRegClass - Set the register class of the specified virtual register.
   ///
   void setRegClass(unsigned Reg, const TargetRegisterClass *RC);

   /// constrainRegClass - Constrain the register class of the specified virtual
   /// register to be a common subclass of RC and the current register class,
   /// but only if the new class has at least MinNumRegs registers.  Return the
   /// new register class, or NULL if no such class exists.
   /// This should only be used when the constraint is known to be trivial, like
   /// GR32 -> GR32_NOSP. Beware of increasing register pressure.
   ///
   const TargetRegisterClass *constrainRegClass(unsigned Reg,
                                                const TargetRegisterClass *RC,
                                                unsigned MinNumRegs = 0);

   /// recomputeRegClass - Try to find a legal super-class of Reg's register
   /// class that still satisfies the constraints from the instructions using
   /// Reg.  Returns true if Reg was upgraded.
   ///
   /// This method can be used after constraints have been removed from a
   /// virtual register, for example after removing instructions or splitting
   /// the live range.
   ///
   bool recomputeRegClass(unsigned Reg, const TargetMachine&);

   /// createVirtualRegister - Create and return a new virtual register in the
   /// function with the specified register class.
   ///
   unsigned createVirtualRegister(const TargetRegisterClass *RegClass);

   /// getNumVirtRegs - Return the number of virtual registers created.
   ///
   unsigned getNumVirtRegs() const { return VRegInfo.size(); }

   /// setRegAllocationHint - Specify a register allocation hint for the
   /// specified virtual register.
   void setRegAllocationHint(unsigned Reg, unsigned Type, unsigned PrefReg) {
     RegAllocHints[Reg].first  = Type;
     RegAllocHints[Reg].second = PrefReg;
   }

   /// getRegAllocationHint - Return the register allocation hint for the
   /// specified virtual register.
   std::pair<unsigned, unsigned>
   getRegAllocationHint(unsigned Reg) const {
     return RegAllocHints[Reg];
   }

   /// getSimpleHint - Return the preferred register allocation hint, or 0 if a
   /// standard simple hint (Type == 0) is not set.
   unsigned getSimpleHint(unsigned Reg) const {
     std::pair<unsigned, unsigned> Hint = getRegAllocationHint(Reg);
     return Hint.first ? 0 : Hint.second;
   }


   //===--------------------------------------------------------------------===//
   // Physical Register Use Info
   //===--------------------------------------------------------------------===//

   /// isPhysRegUsed - Return true if the specified register is used in this
   /// function.  This only works after register allocation.
   bool isPhysRegUsed(unsigned Reg) const { return UsedPhysRegs[Reg]; }

   /// setPhysRegUsed - Mark the specified register used in this function.
   /// This should only be called during and after register allocation.
   void setPhysRegUsed(unsigned Reg) { UsedPhysRegs[Reg] = true; }

   /// addPhysRegsUsed - Mark the specified registers used in this function.
   /// This should only be called during and after register allocation.
   void addPhysRegsUsed(const BitVector &Regs) { UsedPhysRegs |= Regs; }

   /// setPhysRegUnused - Mark the specified register unused in this function.
   /// This should only be called during and after register allocation.
   void setPhysRegUnused(unsigned Reg) { UsedPhysRegs[Reg] = false; }

   /// closePhysRegsUsed - Expand UsedPhysRegs to its transitive closure over
   /// subregisters. That means that if R is used, so are all subregisters.
   void closePhysRegsUsed(const TargetRegisterInfo&);

   //===--------------------------------------------------------------------===//
   // LiveIn/LiveOut Management
   //===--------------------------------------------------------------------===//

   /// addLiveIn/Out - Add the specified register as a live in/out.  Note that it
   /// is an error to add the same register to the same set more than once.
   void addLiveIn(unsigned Reg, unsigned vreg = 0) {
     LiveIns.push_back(std::make_pair(Reg, vreg));
   }
   void addLiveOut(unsigned Reg) { LiveOuts.push_back(Reg); }

   // Iteration support for live in/out sets.  These sets are kept in sorted
   // order by their register number.
   typedef std::vector<std::pair<unsigned,unsigned> >::const_iterator
   livein_iterator;
   typedef std::vector<unsigned>::const_iterator liveout_iterator;
   livein_iterator livein_begin() const { return LiveIns.begin(); }
   livein_iterator livein_end()   const { return LiveIns.end(); }
   bool            livein_empty() const { return LiveIns.empty(); }
   liveout_iterator liveout_begin() const { return LiveOuts.begin(); }
   liveout_iterator liveout_end()   const { return LiveOuts.end(); }
   bool             liveout_empty() const { return LiveOuts.empty(); }

   bool isLiveIn(unsigned Reg) const;
   bool isLiveOut(unsigned Reg) const;

   /// getLiveInPhysReg - If VReg is a live-in virtual register, return the
   /// corresponding live-in physical register.
   unsigned getLiveInPhysReg(unsigned VReg) const;

   /// getLiveInVirtReg - If PReg is a live-in physical register, return the
   /// corresponding live-in physical register.
   unsigned getLiveInVirtReg(unsigned PReg) const;

   /// EmitLiveInCopies - Emit copies to initialize livein virtual registers
   /// into the given entry block.
   void EmitLiveInCopies(MachineBasicBlock *EntryMBB,
                         const TargetRegisterInfo &TRI,
                         const TargetInstrInfo &TII);

 private:
   void HandleVRegListReallocation();

 public:
   /// defusechain_iterator - This class provides iterator support for machine
   /// operands in the function that use or define a specific register.  If
   /// ReturnUses is true it returns uses of registers, if ReturnDefs is true it
   /// returns defs.  If neither are true then you are silly and it always
   /// returns end().  If SkipDebug is true it skips uses marked Debug
   /// when incrementing.
   template<bool ReturnUses, bool ReturnDefs, bool SkipDebug>
   class defusechain_iterator
     : public std::iterator<std::forward_iterator_tag, MachineInstr, ptrdiff_t> {
     MachineOperand *Op;
     explicit defusechain_iterator(MachineOperand *op) : Op(op) {
       // If the first node isn't one we're interested in, advance to one that
       // we are interested in.
       if (op) {
         if ((!ReturnUses && op->isUse()) ||
             (!ReturnDefs && op->isDef()) ||
             (SkipDebug && op->isDebug()))
           ++*this;
       }
     }
     friend class MachineRegisterInfo;
   public:
     typedef std::iterator<std::forward_iterator_tag,
                           MachineInstr, ptrdiff_t>::reference reference;
     typedef std::iterator<std::forward_iterator_tag,
                           MachineInstr, ptrdiff_t>::pointer pointer;

     defusechain_iterator(const defusechain_iterator &I) : Op(I.Op) {}
     defusechain_iterator() : Op(0) {}

     bool operator==(const defusechain_iterator &x) const {
       return Op == x.Op;
     }
     bool operator!=(const defusechain_iterator &x) const {
       return !operator==(x);
     }

     /// atEnd - return true if this iterator is equal to reg_end() on the value.
     bool atEnd() const { return Op == 0; }

     // Iterator traversal: forward iteration only
     defusechain_iterator &operator++() {          // Preincrement
       assert(Op && "Cannot increment end iterator!");
       Op = Op->getNextOperandForReg();

       // If this is an operand we don't care about, skip it.
       while (Op && ((!ReturnUses && Op->isUse()) ||
                     (!ReturnDefs && Op->isDef()) ||
                     (SkipDebug && Op->isDebug())))
         Op = Op->getNextOperandForReg();

       return *this;
     }
     defusechain_iterator operator++(int) {        // Postincrement
       defusechain_iterator tmp = *this; ++*this; return tmp;
     }

     /// skipInstruction - move forward until reaching a different instruction.
     /// Return the skipped instruction that is no longer pointed to, or NULL if
     /// already pointing to end().
     MachineInstr *skipInstruction() {
       if (!Op) return 0;
       MachineInstr *MI = Op->getParent();
       do ++*this;
       while (Op && Op->getParent() == MI);
       return MI;
     }

     MachineOperand &getOperand() const {
       assert(Op && "Cannot dereference end iterator!");
       return *Op;
     }

     /// getOperandNo - Return the operand # of this MachineOperand in its
     /// MachineInstr.
     unsigned getOperandNo() const {
       assert(Op && "Cannot dereference end iterator!");
       return Op - &Op->getParent()->getOperand(0);
     }

     // Retrieve a reference to the current operand.
     MachineInstr &operator*() const {
       assert(Op && "Cannot dereference end iterator!");
       return *Op->getParent();
     }

     MachineInstr *operator->() const {
       assert(Op && "Cannot dereference end iterator!");
       return Op->getParent();
     }
   };

 };

 } // End llvm namespace

 #endif
	//===-- llvm/CodeGen/MachineRegisterInfo.h ----------------------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines the MachineRegisterInfo class.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CODEGEN_MACHINEREGISTERINFO_H
	#define LLVM_CODEGEN_MACHINEREGISTERINFO_H

	#include "llvm/Target/TargetRegisterInfo.h"
	#include "llvm/ADT/BitVector.h"
	#include "llvm/ADT/IndexedMap.h"
	#include <vector>

	namespace llvm {

	/// MachineRegisterInfo - Keep track of information for virtual and physical
	/// registers, including vreg register classes, use/def chains for registers,
	/// etc.
	class MachineRegisterInfo {
	const TargetRegisterInfo *const TRI;

	/// IsSSA - True when the machine function is in SSA form and virtual
	/// registers have a single def.
	bool IsSSA;

	/// VRegInfo - Information we keep for each virtual register.
	///
	/// Each element in this list contains the register class of the vreg and the
	/// start of the use/def list for the register.
	IndexedMap<std::pair<const TargetRegisterClass, MachineOperand>,
	VirtReg2IndexFunctor> VRegInfo;

	/// RegAllocHints - This vector records register allocation hints for virtual
	/// registers. For each virtual register, it keeps a register and hint type
	/// pair making up the allocation hint. Hint type is target specific except
	/// for the value 0 which means the second value of the pair is the preferred
	/// register for allocation. For example, if the hint is <0, 1024>, it means
	/// the allocator should prefer the physical register allocated to the virtual
	/// register of the hint.
	IndexedMap<std::pair<unsigned, unsigned>, VirtReg2IndexFunctor> RegAllocHints;

	/// PhysRegUseDefLists - This is an array of the head of the use/def list for
	/// physical registers.
	MachineOperand **PhysRegUseDefLists;

	/// UsedPhysRegs - This is a bit vector that is computed and set by the
	/// register allocator, and must be kept up to date by passes that run after
	/// register allocation (though most don't modify this). This is used
	/// so that the code generator knows which callee save registers to save and
	/// for other target specific uses.
	BitVector UsedPhysRegs;

	/// LiveIns/LiveOuts - Keep track of the physical registers that are
	/// livein/liveout of the function. Live in values are typically arguments in
	/// registers, live out values are typically return values in registers.
	/// LiveIn values are allowed to have virtual registers associated with them,
	/// stored in the second element.
	std::vector<std::pair<unsigned, unsigned> > LiveIns;
	std::vector<unsigned> LiveOuts;

	MachineRegisterInfo(const MachineRegisterInfo&); // DO NOT IMPLEMENT
	void operator=(const MachineRegisterInfo&); // DO NOT IMPLEMENT
	public:
	explicit MachineRegisterInfo(const TargetRegisterInfo &TRI);
	~MachineRegisterInfo();

	//===--------------------------------------------------------------------===//
	// Function State
	//===--------------------------------------------------------------------===//

	// isSSA - Returns true when the machine function is in SSA form. Early
	// passes require the machine function to be in SSA form where every virtual
	// register has a single defining instruction.
	//
	// The TwoAddressInstructionPass and PHIElimination passes take the machine
	// function out of SSA form when they introduce multiple defs per virtual
	// register.
	bool isSSA() const { return IsSSA; }

	// leaveSSA - Indicates that the machine function is no longer in SSA form.
	void leaveSSA() { IsSSA = false; }

	//===--------------------------------------------------------------------===//
	// Register Info
	//===--------------------------------------------------------------------===//

	/// reg_begin/reg_end - Provide iteration support to walk over all definitions
	/// and uses of a register within the MachineFunction that corresponds to this
	/// MachineRegisterInfo object.
	template<bool Uses, bool Defs, bool SkipDebug>
	class defusechain_iterator;

	/// reg_iterator/reg_begin/reg_end - Walk all defs and uses of the specified
	/// register.
	typedef defusechain_iterator<true,true,false> reg_iterator;
	reg_iterator reg_begin(unsigned RegNo) const {
	return reg_iterator(getRegUseDefListHead(RegNo));
	}
	static reg_iterator reg_end() { return reg_iterator(0); }

	/// reg_empty - Return true if there are no instructions using or defining the
	/// specified register (it may be live-in).
	bool reg_empty(unsigned RegNo) const { return reg_begin(RegNo) == reg_end(); }

	/// reg_nodbg_iterator/reg_nodbg_begin/reg_nodbg_end - Walk all defs and uses
	/// of the specified register, skipping those marked as Debug.
	typedef defusechain_iterator<true,true,true> reg_nodbg_iterator;
	reg_nodbg_iterator reg_nodbg_begin(unsigned RegNo) const {
	return reg_nodbg_iterator(getRegUseDefListHead(RegNo));
	}
	static reg_nodbg_iterator reg_nodbg_end() { return reg_nodbg_iterator(0); }

	/// reg_nodbg_empty - Return true if the only instructions using or defining
	/// Reg are Debug instructions.
	bool reg_nodbg_empty(unsigned RegNo) const {
	return reg_nodbg_begin(RegNo) == reg_nodbg_end();
	}

	/// def_iterator/def_begin/def_end - Walk all defs of the specified register.
	typedef defusechain_iterator<false,true,false> def_iterator;
	def_iterator def_begin(unsigned RegNo) const {
	return def_iterator(getRegUseDefListHead(RegNo));
	}
	static def_iterator def_end() { return def_iterator(0); }

	/// def_empty - Return true if there are no instructions defining the
	/// specified register (it may be live-in).
	bool def_empty(unsigned RegNo) const { return def_begin(RegNo) == def_end(); }

	/// use_iterator/use_begin/use_end - Walk all uses of the specified register.
	typedef defusechain_iterator<true,false,false> use_iterator;
	use_iterator use_begin(unsigned RegNo) const {
	return use_iterator(getRegUseDefListHead(RegNo));
	}
	static use_iterator use_end() { return use_iterator(0); }

	/// use_empty - Return true if there are no instructions using the specified
	/// register.
	bool use_empty(unsigned RegNo) const { return use_begin(RegNo) == use_end(); }

	/// hasOneUse - Return true if there is exactly one instruction using the
	/// specified register.
	bool hasOneUse(unsigned RegNo) const;

	/// use_nodbg_iterator/use_nodbg_begin/use_nodbg_end - Walk all uses of the
	/// specified register, skipping those marked as Debug.
	typedef defusechain_iterator<true,false,true> use_nodbg_iterator;
	use_nodbg_iterator use_nodbg_begin(unsigned RegNo) const {
	return use_nodbg_iterator(getRegUseDefListHead(RegNo));
	}
	static use_nodbg_iterator use_nodbg_end() { return use_nodbg_iterator(0); }

	/// use_nodbg_empty - Return true if there are no non-Debug instructions
	/// using the specified register.
	bool use_nodbg_empty(unsigned RegNo) const {
	return use_nodbg_begin(RegNo) == use_nodbg_end();
	}

	/// hasOneNonDBGUse - Return true if there is exactly one non-Debug
	/// instruction using the specified register.
	bool hasOneNonDBGUse(unsigned RegNo) const;

	/// replaceRegWith - Replace all instances of FromReg with ToReg in the
	/// machine function. This is like llvm-level X->replaceAllUsesWith(Y),
	/// except that it also changes any definitions of the register as well.
	void replaceRegWith(unsigned FromReg, unsigned ToReg);

	/// getRegUseDefListHead - Return the head pointer for the register use/def
	/// list for the specified virtual or physical register.
	MachineOperand *&getRegUseDefListHead(unsigned RegNo) {
	if (TargetRegisterInfo::isVirtualRegister(RegNo))
	return VRegInfo[RegNo].second;
	return PhysRegUseDefLists[RegNo];
	}

	MachineOperand *getRegUseDefListHead(unsigned RegNo) const {
	if (TargetRegisterInfo::isVirtualRegister(RegNo))
	return VRegInfo[RegNo].second;
	return PhysRegUseDefLists[RegNo];
	}

	/// getVRegDef - Return the machine instr that defines the specified virtual
	/// register or null if none is found. This assumes that the code is in SSA
	/// form, so there should only be one definition.
	MachineInstr *getVRegDef(unsigned Reg) const;

	/// clearKillFlags - Iterate over all the uses of the given register and
	/// clear the kill flag from the MachineOperand. This function is used by
	/// optimization passes which extend register lifetimes and need only
	/// preserve conservative kill flag information.
	void clearKillFlags(unsigned Reg) const;

	#ifndef NDEBUG
	void dumpUses(unsigned RegNo) const;
	#endif

	//===--------------------------------------------------------------------===//
	// Virtual Register Info
	//===--------------------------------------------------------------------===//

	/// getRegClass - Return the register class of the specified virtual register.
	///
	const TargetRegisterClass *getRegClass(unsigned Reg) const {
	return VRegInfo[Reg].first;
	}

	/// setRegClass - Set the register class of the specified virtual register.
	///
	void setRegClass(unsigned Reg, const TargetRegisterClass *RC);

	/// constrainRegClass - Constrain the register class of the specified virtual
	/// register to be a common subclass of RC and the current register class,
	/// but only if the new class has at least MinNumRegs registers. Return the
	/// new register class, or NULL if no such class exists.
	/// This should only be used when the constraint is known to be trivial, like
	/// GR32 -> GR32_NOSP. Beware of increasing register pressure.
	///
	const TargetRegisterClass *constrainRegClass(unsigned Reg,
	const TargetRegisterClass *RC,
	unsigned MinNumRegs = 0);

	/// recomputeRegClass - Try to find a legal super-class of Reg's register
	/// class that still satisfies the constraints from the instructions using
	/// Reg. Returns true if Reg was upgraded.
	///
	/// This method can be used after constraints have been removed from a
	/// virtual register, for example after removing instructions or splitting
	/// the live range.
	///
	bool recomputeRegClass(unsigned Reg, const TargetMachine&);

	/// createVirtualRegister - Create and return a new virtual register in the
	/// function with the specified register class.
	///
	unsigned createVirtualRegister(const TargetRegisterClass *RegClass);

	/// getNumVirtRegs - Return the number of virtual registers created.
	///
	unsigned getNumVirtRegs() const { return VRegInfo.size(); }

	/// setRegAllocationHint - Specify a register allocation hint for the
	/// specified virtual register.
	void setRegAllocationHint(unsigned Reg, unsigned Type, unsigned PrefReg) {
	RegAllocHints[Reg].first = Type;
	RegAllocHints[Reg].second = PrefReg;
	}

	/// getRegAllocationHint - Return the register allocation hint for the
	/// specified virtual register.
	std::pair<unsigned, unsigned>
	getRegAllocationHint(unsigned Reg) const {
	return RegAllocHints[Reg];
	}

	/// getSimpleHint - Return the preferred register allocation hint, or 0 if a
	/// standard simple hint (Type == 0) is not set.
	unsigned getSimpleHint(unsigned Reg) const {
	std::pair<unsigned, unsigned> Hint = getRegAllocationHint(Reg);
	return Hint.first ? 0 : Hint.second;
	}


	//===--------------------------------------------------------------------===//
	// Physical Register Use Info
	//===--------------------------------------------------------------------===//

	/// isPhysRegUsed - Return true if the specified register is used in this
	/// function. This only works after register allocation.
	bool isPhysRegUsed(unsigned Reg) const { return UsedPhysRegs[Reg]; }

	/// setPhysRegUsed - Mark the specified register used in this function.
	/// This should only be called during and after register allocation.
	void setPhysRegUsed(unsigned Reg) { UsedPhysRegs[Reg] = true; }

	/// addPhysRegsUsed - Mark the specified registers used in this function.
	/// This should only be called during and after register allocation.
	void addPhysRegsUsed(const BitVector &Regs) { UsedPhysRegs \|= Regs; }

	/// setPhysRegUnused - Mark the specified register unused in this function.
	/// This should only be called during and after register allocation.
	void setPhysRegUnused(unsigned Reg) { UsedPhysRegs[Reg] = false; }

	/// closePhysRegsUsed - Expand UsedPhysRegs to its transitive closure over
	/// subregisters. That means that if R is used, so are all subregisters.
	void closePhysRegsUsed(const TargetRegisterInfo&);

	//===--------------------------------------------------------------------===//
	// LiveIn/LiveOut Management
	//===--------------------------------------------------------------------===//

	/// addLiveIn/Out - Add the specified register as a live in/out. Note that it
	/// is an error to add the same register to the same set more than once.
	void addLiveIn(unsigned Reg, unsigned vreg = 0) {
	LiveIns.push_back(std::make_pair(Reg, vreg));
	}
	void addLiveOut(unsigned Reg) { LiveOuts.push_back(Reg); }

	// Iteration support for live in/out sets. These sets are kept in sorted
	// order by their register number.
	typedef std::vector<std::pair<unsigned,unsigned> >::const_iterator
	livein_iterator;
	typedef std::vector<unsigned>::const_iterator liveout_iterator;
	livein_iterator livein_begin() const { return LiveIns.begin(); }
	livein_iterator livein_end() const { return LiveIns.end(); }
	bool livein_empty() const { return LiveIns.empty(); }
	liveout_iterator liveout_begin() const { return LiveOuts.begin(); }
	liveout_iterator liveout_end() const { return LiveOuts.end(); }
	bool liveout_empty() const { return LiveOuts.empty(); }

	bool isLiveIn(unsigned Reg) const;
	bool isLiveOut(unsigned Reg) const;

	/// getLiveInPhysReg - If VReg is a live-in virtual register, return the
	/// corresponding live-in physical register.
	unsigned getLiveInPhysReg(unsigned VReg) const;

	/// getLiveInVirtReg - If PReg is a live-in physical register, return the
	/// corresponding live-in physical register.
	unsigned getLiveInVirtReg(unsigned PReg) const;

	/// EmitLiveInCopies - Emit copies to initialize livein virtual registers
	/// into the given entry block.
	void EmitLiveInCopies(MachineBasicBlock *EntryMBB,
	const TargetRegisterInfo &TRI,
	const TargetInstrInfo &TII);

	private:
	void HandleVRegListReallocation();

	public:
	/// defusechain_iterator - This class provides iterator support for machine
	/// operands in the function that use or define a specific register. If
	/// ReturnUses is true it returns uses of registers, if ReturnDefs is true it
	/// returns defs. If neither are true then you are silly and it always
	/// returns end(). If SkipDebug is true it skips uses marked Debug
	/// when incrementing.
	template<bool ReturnUses, bool ReturnDefs, bool SkipDebug>
	class defusechain_iterator
	: public std::iterator<std::forward_iterator_tag, MachineInstr, ptrdiff_t> {
	MachineOperand *Op;
	explicit defusechain_iterator(MachineOperand *op) : Op(op) {
	// If the first node isn't one we're interested in, advance to one that
	// we are interested in.
	if (op) {
	if ((!ReturnUses && op->isUse()) \|\|
	(!ReturnDefs && op->isDef()) \|\|
	(SkipDebug && op->isDebug()))
	++*this;
	}
	}
	friend class MachineRegisterInfo;
	public:
	typedef std::iterator<std::forward_iterator_tag,
	MachineInstr, ptrdiff_t>::reference reference;
	typedef std::iterator<std::forward_iterator_tag,
	MachineInstr, ptrdiff_t>::pointer pointer;

	defusechain_iterator(const defusechain_iterator &I) : Op(I.Op) {}
	defusechain_iterator() : Op(0) {}

	bool operator==(const defusechain_iterator &x) const {
	return Op == x.Op;
	}
	bool operator!=(const defusechain_iterator &x) const {
	return !operator==(x);
	}

	/// atEnd - return true if this iterator is equal to reg_end() on the value.
	bool atEnd() const { return Op == 0; }

	// Iterator traversal: forward iteration only
	defusechain_iterator &operator++() { // Preincrement
	assert(Op && "Cannot increment end iterator!");
	Op = Op->getNextOperandForReg();

	// If this is an operand we don't care about, skip it.
	while (Op && ((!ReturnUses && Op->isUse()) \|\|
	(!ReturnDefs && Op->isDef()) \|\|
	(SkipDebug && Op->isDebug())))
	Op = Op->getNextOperandForReg();

	return *this;
	}
	defusechain_iterator operator++(int) { // Postincrement
	defusechain_iterator tmp = this; ++this; return tmp;
	}

	/// skipInstruction - move forward until reaching a different instruction.
	/// Return the skipped instruction that is no longer pointed to, or NULL if
	/// already pointing to end().
	MachineInstr *skipInstruction() {
	if (!Op) return 0;
	MachineInstr *MI = Op->getParent();
	do ++*this;
	while (Op && Op->getParent() == MI);
	return MI;
	}

	MachineOperand &getOperand() const {
	assert(Op && "Cannot dereference end iterator!");
	return *Op;
	}

	/// getOperandNo - Return the operand # of this MachineOperand in its
	/// MachineInstr.
	unsigned getOperandNo() const {
	assert(Op && "Cannot dereference end iterator!");
	return Op - &Op->getParent()->getOperand(0);
	}

	// Retrieve a reference to the current operand.
	MachineInstr &operator*() const {
	assert(Op && "Cannot dereference end iterator!");
	return *Op->getParent();
	}

	MachineInstr *operator->() const {
	assert(Op && "Cannot dereference end iterator!");
	return Op->getParent();
	}
	};

	};

	} // End llvm namespace

	#endif