darwin-x86_64/include/llvm/IR/CFG.h - platform/prebuilts/android-emulator-build/mesa-deps - Git at Google

 //===- CFG.h - Process LLVM structures as graphs ----------------*- 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 specializations of GraphTraits that allow Function and
 // BasicBlock graphs to be treated as proper graphs for generic algorithms.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_IR_CFG_H
 #define LLVM_IR_CFG_H

 #include "llvm/ADT/GraphTraits.h"
 #include "llvm/IR/Function.h"
 #include "llvm/IR/InstrTypes.h"

 namespace llvm {

 //===----------------------------------------------------------------------===//
 // BasicBlock pred_iterator definition
 //===----------------------------------------------------------------------===//

 template <class Ptr, class USE_iterator> // Predecessor Iterator
 class PredIterator : public std::iterator<std::forward_iterator_tag,
                                           Ptr, ptrdiff_t, Ptr*, Ptr*> {
   typedef std::iterator<std::forward_iterator_tag, Ptr, ptrdiff_t, Ptr*,
                                                                     Ptr*> super;
   typedef PredIterator<Ptr, USE_iterator> Self;
   USE_iterator It;

   inline void advancePastNonTerminators() {
     // Loop to ignore non-terminator uses (for example BlockAddresses).
     while (!It.atEnd() && !isa<TerminatorInst>(*It))
       ++It;
   }

 public:
   typedef typename super::pointer pointer;
   typedef typename super::reference reference;

   PredIterator() {}
   explicit inline PredIterator(Ptr *bb) : It(bb->user_begin()) {
     advancePastNonTerminators();
   }
   inline PredIterator(Ptr *bb, bool) : It(bb->user_end()) {}

   inline bool operator==(const Self& x) const { return It == x.It; }
   inline bool operator!=(const Self& x) const { return !operator==(x); }

   inline reference operator*() const {
     assert(!It.atEnd() && "pred_iterator out of range!");
     return cast<TerminatorInst>(*It)->getParent();
   }
   inline pointer *operator->() const { return &operator*(); }

   inline Self& operator++() {   // Preincrement
     assert(!It.atEnd() && "pred_iterator out of range!");
     ++It; advancePastNonTerminators();
     return *this;
   }

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

   /// getOperandNo - Return the operand number in the predecessor's
   /// terminator of the successor.
   unsigned getOperandNo() const {
     return It.getOperandNo();
   }

   /// getUse - Return the operand Use in the predecessor's terminator
   /// of the successor.
   Use &getUse() const {
     return It.getUse();
   }
 };

 typedef PredIterator<BasicBlock, Value::user_iterator> pred_iterator;
 typedef PredIterator<const BasicBlock,
                      Value::const_user_iterator> const_pred_iterator;

 inline pred_iterator pred_begin(BasicBlock *BB) { return pred_iterator(BB); }
 inline const_pred_iterator pred_begin(const BasicBlock *BB) {
   return const_pred_iterator(BB);
 }
 inline pred_iterator pred_end(BasicBlock *BB) { return pred_iterator(BB, true);}
 inline const_pred_iterator pred_end(const BasicBlock *BB) {
   return const_pred_iterator(BB, true);
 }


 //===----------------------------------------------------------------------===//
 // BasicBlock succ_iterator definition
 //===----------------------------------------------------------------------===//

 template <class Term_, class BB_>           // Successor Iterator
 class SuccIterator : public std::iterator<std::random_access_iterator_tag, BB_,
                                           int, BB_ *, BB_ *> {
   typedef std::iterator<std::random_access_iterator_tag, BB_, int, BB_ *, BB_ *>
   super;

 public:
   typedef typename super::pointer pointer;
   typedef typename super::reference reference;

 private:
   const Term_ Term;
   unsigned idx;
   typedef SuccIterator<Term_, BB_> Self;

   inline bool index_is_valid(int idx) {
     return idx >= 0 && (unsigned) idx < Term->getNumSuccessors();
   }

   /// \brief Proxy object to allow write access in operator[]
   class SuccessorProxy {
     Self it;

   public:
     explicit SuccessorProxy(const Self &it) : it(it) {}

     SuccessorProxy &operator=(SuccessorProxy r) {
       *this = reference(r);
       return *this;
     }

     SuccessorProxy &operator=(reference r) {
       it.Term->setSuccessor(it.idx, r);
       return *this;
     }

     operator reference() const { return *it; }
   };

 public:
   explicit inline SuccIterator(Term_ T) : Term(T), idx(0) {// begin iterator
   }
   inline SuccIterator(Term_ T, bool)                       // end iterator
     : Term(T) {
     if (Term)
       idx = Term->getNumSuccessors();
     else
       // Term == NULL happens, if a basic block is not fully constructed and
       // consequently getTerminator() returns NULL. In this case we construct a
       // SuccIterator which describes a basic block that has zero successors.
       // Defining SuccIterator for incomplete and malformed CFGs is especially
       // useful for debugging.
       idx = 0;
   }

   inline const Self &operator=(const Self &I) {
     assert(Term == I.Term &&"Cannot assign iterators to two different blocks!");
     idx = I.idx;
     return *this;
   }

   /// getSuccessorIndex - This is used to interface between code that wants to
   /// operate on terminator instructions directly.
   unsigned getSuccessorIndex() const { return idx; }

   inline bool operator==(const Self& x) const { return idx == x.idx; }
   inline bool operator!=(const Self& x) const { return !operator==(x); }

   inline reference operator*() const { return Term->getSuccessor(idx); }
   inline pointer operator->() const { return operator*(); }

   inline Self& operator++() { ++idx; return *this; } // Preincrement

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

   inline Self& operator--() { --idx; return *this; }  // Predecrement
   inline Self operator--(int) { // Postdecrement
     Self tmp = *this; --*this; return tmp;
   }

   inline bool operator<(const Self& x) const {
     assert(Term == x.Term && "Cannot compare iterators of different blocks!");
     return idx < x.idx;
   }

   inline bool operator<=(const Self& x) const {
     assert(Term == x.Term && "Cannot compare iterators of different blocks!");
     return idx <= x.idx;
   }
   inline bool operator>=(const Self& x) const {
     assert(Term == x.Term && "Cannot compare iterators of different blocks!");
     return idx >= x.idx;
   }

   inline bool operator>(const Self& x) const {
     assert(Term == x.Term && "Cannot compare iterators of different blocks!");
     return idx > x.idx;
   }

   inline Self& operator+=(int Right) {
     unsigned new_idx = idx + Right;
     assert(index_is_valid(new_idx) && "Iterator index out of bound");
     idx = new_idx;
     return *this;
   }

   inline Self operator+(int Right) const {
     Self tmp = *this;
     tmp += Right;
     return tmp;
   }

   inline Self& operator-=(int Right) {
     return operator+=(-Right);
   }

   inline Self operator-(int Right) const {
     return operator+(-Right);
   }

   inline int operator-(const Self& x) const {
     assert(Term == x.Term && "Cannot work on iterators of different blocks!");
     int distance = idx - x.idx;
     return distance;
   }

   inline SuccessorProxy operator[](int offset) {
    Self tmp = *this;
    tmp += offset;
    return SuccessorProxy(tmp);
   }

   /// Get the source BB of this iterator.
   inline BB_ *getSource() {
     assert(Term && "Source not available, if basic block was malformed");
     return Term->getParent();
   }
 };

 typedef SuccIterator<TerminatorInst*, BasicBlock> succ_iterator;
 typedef SuccIterator<const TerminatorInst*,
                      const BasicBlock> succ_const_iterator;

 inline succ_iterator succ_begin(BasicBlock *BB) {
   return succ_iterator(BB->getTerminator());
 }
 inline succ_const_iterator succ_begin(const BasicBlock *BB) {
   return succ_const_iterator(BB->getTerminator());
 }
 inline succ_iterator succ_end(BasicBlock *BB) {
   return succ_iterator(BB->getTerminator(), true);
 }
 inline succ_const_iterator succ_end(const BasicBlock *BB) {
   return succ_const_iterator(BB->getTerminator(), true);
 }

 template <typename T, typename U> struct isPodLike<SuccIterator<T, U> > {
   static const bool value = isPodLike<T>::value;
 };


 //===--------------------------------------------------------------------===//
 // GraphTraits specializations for basic block graphs (CFGs)
 //===--------------------------------------------------------------------===//

 // Provide specializations of GraphTraits to be able to treat a function as a
 // graph of basic blocks...

 template <> struct GraphTraits<BasicBlock*> {
   typedef BasicBlock NodeType;
   typedef succ_iterator ChildIteratorType;

   static NodeType *getEntryNode(BasicBlock *BB) { return BB; }
   static inline ChildIteratorType child_begin(NodeType *N) {
     return succ_begin(N);
   }
   static inline ChildIteratorType child_end(NodeType *N) {
     return succ_end(N);
   }
 };

 template <> struct GraphTraits<const BasicBlock*> {
   typedef const BasicBlock NodeType;
   typedef succ_const_iterator ChildIteratorType;

   static NodeType *getEntryNode(const BasicBlock *BB) { return BB; }

   static inline ChildIteratorType child_begin(NodeType *N) {
     return succ_begin(N);
   }
   static inline ChildIteratorType child_end(NodeType *N) {
     return succ_end(N);
   }
 };

 // Provide specializations of GraphTraits to be able to treat a function as a
 // graph of basic blocks... and to walk it in inverse order.  Inverse order for
 // a function is considered to be when traversing the predecessor edges of a BB
 // instead of the successor edges.
 //
 template <> struct GraphTraits<Inverse<BasicBlock*> > {
   typedef BasicBlock NodeType;
   typedef pred_iterator ChildIteratorType;
   static NodeType *getEntryNode(Inverse<BasicBlock *> G) { return G.Graph; }
   static inline ChildIteratorType child_begin(NodeType *N) {
     return pred_begin(N);
   }
   static inline ChildIteratorType child_end(NodeType *N) {
     return pred_end(N);
   }
 };

 template <> struct GraphTraits<Inverse<const BasicBlock*> > {
   typedef const BasicBlock NodeType;
   typedef const_pred_iterator ChildIteratorType;
   static NodeType *getEntryNode(Inverse<const BasicBlock*> G) {
     return G.Graph;
   }
   static inline ChildIteratorType child_begin(NodeType *N) {
     return pred_begin(N);
   }
   static inline ChildIteratorType child_end(NodeType *N) {
     return pred_end(N);
   }
 };


 //===--------------------------------------------------------------------===//
 // GraphTraits specializations for function basic block graphs (CFGs)
 //===--------------------------------------------------------------------===//

 // Provide specializations of GraphTraits to be able to treat a function as a
 // graph of basic blocks... these are the same as the basic block iterators,
 // except that the root node is implicitly the first node of the function.
 //
 template <> struct GraphTraits<Function*> : public GraphTraits<BasicBlock*> {
   static NodeType *getEntryNode(Function *F) { return &F->getEntryBlock(); }

   // nodes_iterator/begin/end - Allow iteration over all nodes in the graph
   typedef Function::iterator nodes_iterator;
   static nodes_iterator nodes_begin(Function *F) { return F->begin(); }
   static nodes_iterator nodes_end  (Function *F) { return F->end(); }
   static size_t         size       (Function *F) { return F->size(); }
 };
 template <> struct GraphTraits<const Function*> :
   public GraphTraits<const BasicBlock*> {
   static NodeType *getEntryNode(const Function *F) {return &F->getEntryBlock();}

   // nodes_iterator/begin/end - Allow iteration over all nodes in the graph
   typedef Function::const_iterator nodes_iterator;
   static nodes_iterator nodes_begin(const Function *F) { return F->begin(); }
   static nodes_iterator nodes_end  (const Function *F) { return F->end(); }
   static size_t         size       (const Function *F) { return F->size(); }
 };


 // Provide specializations of GraphTraits to be able to treat a function as a
 // graph of basic blocks... and to walk it in inverse order.  Inverse order for
 // a function is considered to be when traversing the predecessor edges of a BB
 // instead of the successor edges.
 //
 template <> struct GraphTraits<Inverse<Function*> > :
   public GraphTraits<Inverse<BasicBlock*> > {
   static NodeType *getEntryNode(Inverse<Function*> G) {
     return &G.Graph->getEntryBlock();
   }
 };
 template <> struct GraphTraits<Inverse<const Function*> > :
   public GraphTraits<Inverse<const BasicBlock*> > {
   static NodeType *getEntryNode(Inverse<const Function *> G) {
     return &G.Graph->getEntryBlock();
   }
 };

 } // End llvm namespace

 #endif
	//===- CFG.h - Process LLVM structures as graphs ----------------- 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 specializations of GraphTraits that allow Function and
	// BasicBlock graphs to be treated as proper graphs for generic algorithms.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_IR_CFG_H
	#define LLVM_IR_CFG_H

	#include "llvm/ADT/GraphTraits.h"
	#include "llvm/IR/Function.h"
	#include "llvm/IR/InstrTypes.h"

	namespace llvm {

	//===----------------------------------------------------------------------===//
	// BasicBlock pred_iterator definition
	//===----------------------------------------------------------------------===//

	template <class Ptr, class USE_iterator> // Predecessor Iterator
	class PredIterator : public std::iterator<std::forward_iterator_tag,
	Ptr, ptrdiff_t, Ptr, Ptr> {
	typedef std::iterator<std::forward_iterator_tag, Ptr, ptrdiff_t, Ptr*,
	Ptr*> super;
	typedef PredIterator<Ptr, USE_iterator> Self;
	USE_iterator It;

	inline void advancePastNonTerminators() {
	// Loop to ignore non-terminator uses (for example BlockAddresses).
	while (!It.atEnd() && !isa<TerminatorInst>(*It))
	++It;
	}

	public:
	typedef typename super::pointer pointer;
	typedef typename super::reference reference;

	PredIterator() {}
	explicit inline PredIterator(Ptr *bb) : It(bb->user_begin()) {
	advancePastNonTerminators();
	}
	inline PredIterator(Ptr *bb, bool) : It(bb->user_end()) {}

	inline bool operator==(const Self& x) const { return It == x.It; }
	inline bool operator!=(const Self& x) const { return !operator==(x); }

	inline reference operator*() const {
	assert(!It.atEnd() && "pred_iterator out of range!");
	return cast<TerminatorInst>(*It)->getParent();
	}
	inline pointer operator->() const { return &operator(); }

	inline Self& operator++() { // Preincrement
	assert(!It.atEnd() && "pred_iterator out of range!");
	++It; advancePastNonTerminators();
	return *this;
	}

	inline Self operator++(int) { // Postincrement
	Self tmp = this; ++this; return tmp;
	}

	/// getOperandNo - Return the operand number in the predecessor's
	/// terminator of the successor.
	unsigned getOperandNo() const {
	return It.getOperandNo();
	}

	/// getUse - Return the operand Use in the predecessor's terminator
	/// of the successor.
	Use &getUse() const {
	return It.getUse();
	}
	};

	typedef PredIterator<BasicBlock, Value::user_iterator> pred_iterator;
	typedef PredIterator<const BasicBlock,
	Value::const_user_iterator> const_pred_iterator;

	inline pred_iterator pred_begin(BasicBlock *BB) { return pred_iterator(BB); }
	inline const_pred_iterator pred_begin(const BasicBlock *BB) {
	return const_pred_iterator(BB);
	}
	inline pred_iterator pred_end(BasicBlock *BB) { return pred_iterator(BB, true);}
	inline const_pred_iterator pred_end(const BasicBlock *BB) {
	return const_pred_iterator(BB, true);
	}



	//===----------------------------------------------------------------------===//
	// BasicBlock succ_iterator definition
	//===----------------------------------------------------------------------===//

	template <class Term_, class BB_> // Successor Iterator
	class SuccIterator : public std::iterator<std::random_access_iterator_tag, BB_,
	int, BB_ , BB_ > {
	typedef std::iterator<std::random_access_iterator_tag, BB_, int, BB_ , BB_ >
	super;

	public:
	typedef typename super::pointer pointer;
	typedef typename super::reference reference;

	private:
	const Term_ Term;
	unsigned idx;
	typedef SuccIterator<Term_, BB_> Self;

	inline bool index_is_valid(int idx) {
	return idx >= 0 && (unsigned) idx < Term->getNumSuccessors();
	}

	/// \brief Proxy object to allow write access in operator[]
	class SuccessorProxy {
	Self it;

	public:
	explicit SuccessorProxy(const Self &it) : it(it) {}

	SuccessorProxy &operator=(SuccessorProxy r) {
	*this = reference(r);
	return *this;
	}

	SuccessorProxy &operator=(reference r) {
	it.Term->setSuccessor(it.idx, r);
	return *this;
	}

	operator reference() const { return *it; }
	};

	public:
	explicit inline SuccIterator(Term_ T) : Term(T), idx(0) {// begin iterator
	}
	inline SuccIterator(Term_ T, bool) // end iterator
	: Term(T) {
	if (Term)
	idx = Term->getNumSuccessors();
	else
	// Term == NULL happens, if a basic block is not fully constructed and
	// consequently getTerminator() returns NULL. In this case we construct a
	// SuccIterator which describes a basic block that has zero successors.
	// Defining SuccIterator for incomplete and malformed CFGs is especially
	// useful for debugging.
	idx = 0;
	}

	inline const Self &operator=(const Self &I) {
	assert(Term == I.Term &&"Cannot assign iterators to two different blocks!");
	idx = I.idx;
	return *this;
	}

	/// getSuccessorIndex - This is used to interface between code that wants to
	/// operate on terminator instructions directly.
	unsigned getSuccessorIndex() const { return idx; }

	inline bool operator==(const Self& x) const { return idx == x.idx; }
	inline bool operator!=(const Self& x) const { return !operator==(x); }

	inline reference operator*() const { return Term->getSuccessor(idx); }
	inline pointer operator->() const { return operator*(); }

	inline Self& operator++() { ++idx; return *this; } // Preincrement

	inline Self operator++(int) { // Postincrement
	Self tmp = this; ++this; return tmp;
	}

	inline Self& operator--() { --idx; return *this; } // Predecrement
	inline Self operator--(int) { // Postdecrement
	Self tmp = this; --this; return tmp;
	}

	inline bool operator<(const Self& x) const {
	assert(Term == x.Term && "Cannot compare iterators of different blocks!");
	return idx < x.idx;
	}

	inline bool operator<=(const Self& x) const {
	assert(Term == x.Term && "Cannot compare iterators of different blocks!");
	return idx <= x.idx;
	}
	inline bool operator>=(const Self& x) const {
	assert(Term == x.Term && "Cannot compare iterators of different blocks!");
	return idx >= x.idx;
	}

	inline bool operator>(const Self& x) const {
	assert(Term == x.Term && "Cannot compare iterators of different blocks!");
	return idx > x.idx;
	}

	inline Self& operator+=(int Right) {
	unsigned new_idx = idx + Right;
	assert(index_is_valid(new_idx) && "Iterator index out of bound");
	idx = new_idx;
	return *this;
	}

	inline Self operator+(int Right) const {
	Self tmp = *this;
	tmp += Right;
	return tmp;
	}

	inline Self& operator-=(int Right) {
	return operator+=(-Right);
	}

	inline Self operator-(int Right) const {
	return operator+(-Right);
	}

	inline int operator-(const Self& x) const {
	assert(Term == x.Term && "Cannot work on iterators of different blocks!");
	int distance = idx - x.idx;
	return distance;
	}

	inline SuccessorProxy operator[](int offset) {
	Self tmp = *this;
	tmp += offset;
	return SuccessorProxy(tmp);
	}

	/// Get the source BB of this iterator.
	inline BB_ *getSource() {
	assert(Term && "Source not available, if basic block was malformed");
	return Term->getParent();
	}
	};

	typedef SuccIterator<TerminatorInst*, BasicBlock> succ_iterator;
	typedef SuccIterator<const TerminatorInst*,
	const BasicBlock> succ_const_iterator;

	inline succ_iterator succ_begin(BasicBlock *BB) {
	return succ_iterator(BB->getTerminator());
	}
	inline succ_const_iterator succ_begin(const BasicBlock *BB) {
	return succ_const_iterator(BB->getTerminator());
	}
	inline succ_iterator succ_end(BasicBlock *BB) {
	return succ_iterator(BB->getTerminator(), true);
	}
	inline succ_const_iterator succ_end(const BasicBlock *BB) {
	return succ_const_iterator(BB->getTerminator(), true);
	}

	template <typename T, typename U> struct isPodLike<SuccIterator<T, U> > {
	static const bool value = isPodLike<T>::value;
	};



	//===--------------------------------------------------------------------===//
	// GraphTraits specializations for basic block graphs (CFGs)
	//===--------------------------------------------------------------------===//

	// Provide specializations of GraphTraits to be able to treat a function as a
	// graph of basic blocks...

	template <> struct GraphTraits<BasicBlock*> {
	typedef BasicBlock NodeType;
	typedef succ_iterator ChildIteratorType;

	static NodeType getEntryNode(BasicBlock BB) { return BB; }
	static inline ChildIteratorType child_begin(NodeType *N) {
	return succ_begin(N);
	}
	static inline ChildIteratorType child_end(NodeType *N) {
	return succ_end(N);
	}
	};

	template <> struct GraphTraits<const BasicBlock*> {
	typedef const BasicBlock NodeType;
	typedef succ_const_iterator ChildIteratorType;

	static NodeType getEntryNode(const BasicBlock BB) { return BB; }

	static inline ChildIteratorType child_begin(NodeType *N) {
	return succ_begin(N);
	}
	static inline ChildIteratorType child_end(NodeType *N) {
	return succ_end(N);
	}
	};

	// Provide specializations of GraphTraits to be able to treat a function as a
	// graph of basic blocks... and to walk it in inverse order. Inverse order for
	// a function is considered to be when traversing the predecessor edges of a BB
	// instead of the successor edges.
	//
	template <> struct GraphTraits<Inverse<BasicBlock*> > {
	typedef BasicBlock NodeType;
	typedef pred_iterator ChildIteratorType;
	static NodeType getEntryNode(Inverse<BasicBlock > G) { return G.Graph; }
	static inline ChildIteratorType child_begin(NodeType *N) {
	return pred_begin(N);
	}
	static inline ChildIteratorType child_end(NodeType *N) {
	return pred_end(N);
	}
	};

	template <> struct GraphTraits<Inverse<const BasicBlock*> > {
	typedef const BasicBlock NodeType;
	typedef const_pred_iterator ChildIteratorType;
	static NodeType getEntryNode(Inverse<const BasicBlock> G) {
	return G.Graph;
	}
	static inline ChildIteratorType child_begin(NodeType *N) {
	return pred_begin(N);
	}
	static inline ChildIteratorType child_end(NodeType *N) {
	return pred_end(N);
	}
	};



	//===--------------------------------------------------------------------===//
	// GraphTraits specializations for function basic block graphs (CFGs)
	//===--------------------------------------------------------------------===//

	// Provide specializations of GraphTraits to be able to treat a function as a
	// graph of basic blocks... these are the same as the basic block iterators,
	// except that the root node is implicitly the first node of the function.
	//
	template <> struct GraphTraits<Function> : public GraphTraits<BasicBlock> {
	static NodeType getEntryNode(Function F) { return &F->getEntryBlock(); }

	// nodes_iterator/begin/end - Allow iteration over all nodes in the graph
	typedef Function::iterator nodes_iterator;
	static nodes_iterator nodes_begin(Function *F) { return F->begin(); }
	static nodes_iterator nodes_end (Function *F) { return F->end(); }
	static size_t size (Function *F) { return F->size(); }
	};
	template <> struct GraphTraits<const Function*> :
	public GraphTraits<const BasicBlock*> {
	static NodeType getEntryNode(const Function F) {return &F->getEntryBlock();}

	// nodes_iterator/begin/end - Allow iteration over all nodes in the graph
	typedef Function::const_iterator nodes_iterator;
	static nodes_iterator nodes_begin(const Function *F) { return F->begin(); }
	static nodes_iterator nodes_end (const Function *F) { return F->end(); }
	static size_t size (const Function *F) { return F->size(); }
	};


	// Provide specializations of GraphTraits to be able to treat a function as a
	// graph of basic blocks... and to walk it in inverse order. Inverse order for
	// a function is considered to be when traversing the predecessor edges of a BB
	// instead of the successor edges.
	//
	template <> struct GraphTraits<Inverse<Function*> > :
	public GraphTraits<Inverse<BasicBlock*> > {
	static NodeType getEntryNode(Inverse<Function> G) {
	return &G.Graph->getEntryBlock();
	}
	};
	template <> struct GraphTraits<Inverse<const Function*> > :
	public GraphTraits<Inverse<const BasicBlock*> > {
	static NodeType getEntryNode(Inverse<const Function > G) {
	return &G.Graph->getEntryBlock();
	}
	};

	} // End llvm namespace

	#endif