x86_64/usr/include/llvm/ADT/GenericCycleInfo.h - manifest_repos/toolchain - Git at Google

 //===- GenericCycleInfo.h - Info for Cycles in any IR ------*- C++ -*------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 ///
 /// \file
 /// \brief Find all cycles in a control-flow graph, including irreducible loops.
 ///
 /// See docs/CycleTerminology.rst for a formal definition of cycles.
 ///
 /// Briefly:
 /// - A cycle is a generalization of a loop which can represent
 ///   irreducible control flow.
 /// - Cycles identified in a program are implementation defined,
 ///   depending on the DFS traversal chosen.
 /// - Cycles are well-nested, and form a forest with a parent-child
 ///   relationship.
 /// - In any choice of DFS, every natural loop L is represented by a
 ///   unique cycle C which is a superset of L.
 /// - In the absence of irreducible control flow, the cycles are
 ///   exactly the natural loops in the program.
 ///
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_ADT_GENERICCYCLEINFO_H
 #define LLVM_ADT_GENERICCYCLEINFO_H

 #include "llvm/ADT/ArrayRef.h"
 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/GenericSSAContext.h"
 #include "llvm/ADT/GraphTraits.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/ADT/iterator.h"
 #include "llvm/Support/Debug.h"
 #include "llvm/Support/Printable.h"
 #include "llvm/Support/raw_ostream.h"
 #include <vector>

 namespace llvm {

 template <typename ContextT> class GenericCycleInfo;
 template <typename ContextT> class GenericCycleInfoCompute;

 /// A possibly irreducible generalization of a \ref Loop.
 template <typename ContextT> class GenericCycle {
 public:
   using BlockT = typename ContextT::BlockT;
   using FunctionT = typename ContextT::FunctionT;
   template <typename> friend class GenericCycleInfo;
   template <typename> friend class GenericCycleInfoCompute;

 private:
   /// The parent cycle. Is null for the root "cycle". Top-level cycles point
   /// at the root.
   GenericCycle *ParentCycle = nullptr;

   /// The entry block(s) of the cycle. The header is the only entry if
   /// this is a loop. Is empty for the root "cycle", to avoid
   /// unnecessary memory use.
   SmallVector<BlockT *, 1> Entries;

   /// Child cycles, if any.
   std::vector<std::unique_ptr<GenericCycle>> Children;

   /// Basic blocks that are contained in the cycle, including entry blocks,
   /// and including blocks that are part of a child cycle.
   std::vector<BlockT *> Blocks;

   /// Depth of the cycle in the tree. The root "cycle" is at depth 0.
   ///
   /// \note Depths are not necessarily contiguous. However, child loops always
   ///       have strictly greater depth than their parents, and sibling loops
   ///       always have the same depth.
   unsigned Depth = 0;

   void clear() {
     Entries.clear();
     Children.clear();
     Blocks.clear();
     Depth = 0;
     ParentCycle = nullptr;
   }

   void appendEntry(BlockT *Block) { Entries.push_back(Block); }
   void appendBlock(BlockT *Block) { Blocks.push_back(Block); }

   GenericCycle(const GenericCycle &) = delete;
   GenericCycle &operator=(const GenericCycle &) = delete;
   GenericCycle(GenericCycle &&Rhs) = delete;
   GenericCycle &operator=(GenericCycle &&Rhs) = delete;

 public:
   GenericCycle() = default;

   /// \brief Whether the cycle is a natural loop.
   bool isReducible() const { return Entries.size() == 1; }

   BlockT *getHeader() const { return Entries[0]; }

   const SmallVectorImpl<BlockT *> & getEntries() const {
     return Entries;
   }

   /// \brief Return whether \p Block is an entry block of the cycle.
   bool isEntry(BlockT *Block) const { return is_contained(Entries, Block); }

   /// \brief Return whether \p Block is contained in the cycle.
   bool contains(const BlockT *Block) const {
     return is_contained(Blocks, Block);
   }

   /// \brief Returns true iff this cycle contains \p C.
   ///
   /// Note: Non-strict containment check, i.e. returns true if C is the
   /// same cycle.
   bool contains(const GenericCycle *C) const;

   const GenericCycle *getParentCycle() const { return ParentCycle; }
   GenericCycle *getParentCycle() { return ParentCycle; }
   unsigned getDepth() const { return Depth; }

   /// Return all of the successor blocks of this cycle.
   ///
   /// These are the blocks _outside of the current cycle_ which are
   /// branched to.
   void getExitBlocks(SmallVectorImpl<BlockT *> &TmpStorage) const;

   /// Return the preheader block for this cycle. Pre-header is well-defined for
   /// reducible cycle in docs/LoopTerminology.rst as: the only one entering
   /// block and its only edge is to the entry block. Return null for irreducible
   /// cycles.
   BlockT *getCyclePreheader() const;

   /// If the cycle has exactly one entry with exactly one predecessor, return
   /// it, otherwise return nullptr.
   BlockT *getCyclePredecessor() const;

   /// Iteration over child cycles.
   //@{
   using const_child_iterator_base =
       typename std::vector<std::unique_ptr<GenericCycle>>::const_iterator;
   struct const_child_iterator
       : iterator_adaptor_base<const_child_iterator, const_child_iterator_base> {
     using Base =
         iterator_adaptor_base<const_child_iterator, const_child_iterator_base>;

     const_child_iterator() = default;
     explicit const_child_iterator(const_child_iterator_base I) : Base(I) {}

     const const_child_iterator_base &wrapped() { return Base::wrapped(); }
     GenericCycle *operator*() const { return Base::I->get(); }
   };

   const_child_iterator child_begin() const {
     return const_child_iterator{Children.begin()};
   }
   const_child_iterator child_end() const {
     return const_child_iterator{Children.end()};
   }
   size_t getNumChildren() const { return Children.size(); }
   iterator_range<const_child_iterator> children() const {
     return llvm::make_range(const_child_iterator{Children.begin()},
                             const_child_iterator{Children.end()});
   }
   //@}

   /// Iteration over blocks in the cycle (including entry blocks).
   //@{
   using const_block_iterator = typename std::vector<BlockT *>::const_iterator;

   const_block_iterator block_begin() const {
     return const_block_iterator{Blocks.begin()};
   }
   const_block_iterator block_end() const {
     return const_block_iterator{Blocks.end()};
   }
   size_t getNumBlocks() const { return Blocks.size(); }
   iterator_range<const_block_iterator> blocks() const {
     return llvm::make_range(block_begin(), block_end());
   }
   //@}

   /// Iteration over entry blocks.
   //@{
   using const_entry_iterator =
       typename SmallVectorImpl<BlockT *>::const_iterator;

   size_t getNumEntries() const { return Entries.size(); }
   iterator_range<const_entry_iterator> entries() const {
     return llvm::make_range(Entries.begin(), Entries.end());
   }
   //@}

   Printable printEntries(const ContextT &Ctx) const {
     return Printable([this, &Ctx](raw_ostream &Out) {
       bool First = true;
       for (auto *Entry : Entries) {
         if (!First)
           Out << ' ';
         First = false;
         Out << Ctx.print(Entry);
       }
     });
   }

   Printable print(const ContextT &Ctx) const {
     return Printable([this, &Ctx](raw_ostream &Out) {
       Out << "depth=" << Depth << ": entries(" << printEntries(Ctx) << ')';

       for (auto *Block : Blocks) {
         if (isEntry(Block))
           continue;

         Out << ' ' << Ctx.print(Block);
       }
     });
   }
 };

 /// \brief Cycle information for a function.
 template <typename ContextT> class GenericCycleInfo {
 public:
   using BlockT = typename ContextT::BlockT;
   using CycleT = GenericCycle<ContextT>;
   using FunctionT = typename ContextT::FunctionT;
   template <typename> friend class GenericCycle;
   template <typename> friend class GenericCycleInfoCompute;

 private:
   ContextT Context;

   /// Map basic blocks to their inner-most containing loop.
   DenseMap<BlockT *, CycleT *> BlockMap;

   /// Outermost cycles discovered by any DFS.
   ///
   /// Note: The implementation treats the nullptr as the parent of
   /// every top-level cycle. See \ref contains for an example.
   std::vector<std::unique_ptr<CycleT>> TopLevelCycles;

 public:
   GenericCycleInfo() = default;
   GenericCycleInfo(GenericCycleInfo &&) = default;
   GenericCycleInfo &operator=(GenericCycleInfo &&) = default;

   void clear();
   void compute(FunctionT &F);

   FunctionT *getFunction() const { return Context.getFunction(); }
   const ContextT &getSSAContext() const { return Context; }

   CycleT *getCycle(const BlockT *Block) const;
   unsigned getCycleDepth(const BlockT *Block) const;
   CycleT *getTopLevelParentCycle(const BlockT *Block) const;

   /// Move \p Child to \p NewParent by manipulating Children vectors.
   ///
   /// Note: This is an incomplete operation that does not update the
   /// list of blocks in the new parent or the depth of the subtree.
   void moveToNewParent(CycleT *NewParent, CycleT *Child);

   /// Methods for debug and self-test.
   //@{
 #ifndef NDEBUG
   bool validateTree() const;
 #endif
   void print(raw_ostream &Out) const;
   void dump() const { print(dbgs()); }
   //@}

   /// Iteration over top-level cycles.
   //@{
   using const_toplevel_iterator_base =
       typename std::vector<std::unique_ptr<CycleT>>::const_iterator;
   struct const_toplevel_iterator
       : iterator_adaptor_base<const_toplevel_iterator,
                               const_toplevel_iterator_base> {
     using Base = iterator_adaptor_base<const_toplevel_iterator,
                                        const_toplevel_iterator_base>;

     const_toplevel_iterator() = default;
     explicit const_toplevel_iterator(const_toplevel_iterator_base I)
         : Base(I) {}

     const const_toplevel_iterator_base &wrapped() { return Base::wrapped(); }
     CycleT *operator*() const { return Base::I->get(); }
   };

   const_toplevel_iterator toplevel_begin() const {
     return const_toplevel_iterator{TopLevelCycles.begin()};
   }
   const_toplevel_iterator toplevel_end() const {
     return const_toplevel_iterator{TopLevelCycles.end()};
   }

   iterator_range<const_toplevel_iterator> toplevel_cycles() const {
     return llvm::make_range(const_toplevel_iterator{TopLevelCycles.begin()},
                             const_toplevel_iterator{TopLevelCycles.end()});
   }
   //@}
 };

 /// \brief GraphTraits for iterating over a sub-tree of the CycleT tree.
 template <typename CycleRefT, typename ChildIteratorT> struct CycleGraphTraits {
   using NodeRef = CycleRefT;

   using nodes_iterator = ChildIteratorT;
   using ChildIteratorType = nodes_iterator;

   static NodeRef getEntryNode(NodeRef Graph) { return Graph; }

   static ChildIteratorType child_begin(NodeRef Ref) {
     return Ref->child_begin();
   }
   static ChildIteratorType child_end(NodeRef Ref) { return Ref->child_end(); }

   // Not implemented:
   // static nodes_iterator nodes_begin(GraphType *G)
   // static nodes_iterator nodes_end  (GraphType *G)
   //    nodes_iterator/begin/end - Allow iteration over all nodes in the graph

   // typedef EdgeRef           - Type of Edge token in the graph, which should
   //                             be cheap to copy.
   // typedef ChildEdgeIteratorType - Type used to iterate over children edges in
   //                             graph, dereference to a EdgeRef.

   // static ChildEdgeIteratorType child_edge_begin(NodeRef)
   // static ChildEdgeIteratorType child_edge_end(NodeRef)
   //     Return iterators that point to the beginning and ending of the
   //     edge list for the given callgraph node.
   //
   // static NodeRef edge_dest(EdgeRef)
   //     Return the destination node of an edge.
   // static unsigned       size       (GraphType *G)
   //    Return total number of nodes in the graph
 };

 template <typename BlockT>
 struct GraphTraits<const GenericCycle<BlockT> *>
     : CycleGraphTraits<const GenericCycle<BlockT> *,
                        typename GenericCycle<BlockT>::const_child_iterator> {};
 template <typename BlockT>
 struct GraphTraits<GenericCycle<BlockT> *>
     : CycleGraphTraits<GenericCycle<BlockT> *,
                        typename GenericCycle<BlockT>::const_child_iterator> {};

 } // namespace llvm

 #endif // LLVM_ADT_GENERICCYCLEINFO_H
	//===- GenericCycleInfo.h - Info for Cycles in any IR ------- C++ -------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	///
	/// \file
	/// \brief Find all cycles in a control-flow graph, including irreducible loops.
	///
	/// See docs/CycleTerminology.rst for a formal definition of cycles.
	///
	/// Briefly:
	/// - A cycle is a generalization of a loop which can represent
	/// irreducible control flow.
	/// - Cycles identified in a program are implementation defined,
	/// depending on the DFS traversal chosen.
	/// - Cycles are well-nested, and form a forest with a parent-child
	/// relationship.
	/// - In any choice of DFS, every natural loop L is represented by a
	/// unique cycle C which is a superset of L.
	/// - In the absence of irreducible control flow, the cycles are
	/// exactly the natural loops in the program.
	///
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_ADT_GENERICCYCLEINFO_H
	#define LLVM_ADT_GENERICCYCLEINFO_H

	#include "llvm/ADT/ArrayRef.h"
	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/GenericSSAContext.h"
	#include "llvm/ADT/GraphTraits.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/ADT/iterator.h"
	#include "llvm/Support/Debug.h"
	#include "llvm/Support/Printable.h"
	#include "llvm/Support/raw_ostream.h"
	#include <vector>

	namespace llvm {

	template <typename ContextT> class GenericCycleInfo;
	template <typename ContextT> class GenericCycleInfoCompute;

	/// A possibly irreducible generalization of a \ref Loop.
	template <typename ContextT> class GenericCycle {
	public:
	using BlockT = typename ContextT::BlockT;
	using FunctionT = typename ContextT::FunctionT;
	template <typename> friend class GenericCycleInfo;
	template <typename> friend class GenericCycleInfoCompute;

	private:
	/// The parent cycle. Is null for the root "cycle". Top-level cycles point
	/// at the root.
	GenericCycle *ParentCycle = nullptr;

	/// The entry block(s) of the cycle. The header is the only entry if
	/// this is a loop. Is empty for the root "cycle", to avoid
	/// unnecessary memory use.
	SmallVector<BlockT *, 1> Entries;

	/// Child cycles, if any.
	std::vector<std::unique_ptr<GenericCycle>> Children;

	/// Basic blocks that are contained in the cycle, including entry blocks,
	/// and including blocks that are part of a child cycle.
	std::vector<BlockT *> Blocks;

	/// Depth of the cycle in the tree. The root "cycle" is at depth 0.
	///
	/// \note Depths are not necessarily contiguous. However, child loops always
	/// have strictly greater depth than their parents, and sibling loops
	/// always have the same depth.
	unsigned Depth = 0;

	void clear() {
	Entries.clear();
	Children.clear();
	Blocks.clear();
	Depth = 0;
	ParentCycle = nullptr;
	}

	void appendEntry(BlockT *Block) { Entries.push_back(Block); }
	void appendBlock(BlockT *Block) { Blocks.push_back(Block); }

	GenericCycle(const GenericCycle &) = delete;
	GenericCycle &operator=(const GenericCycle &) = delete;
	GenericCycle(GenericCycle &&Rhs) = delete;
	GenericCycle &operator=(GenericCycle &&Rhs) = delete;

	public:
	GenericCycle() = default;

	/// \brief Whether the cycle is a natural loop.
	bool isReducible() const { return Entries.size() == 1; }

	BlockT *getHeader() const { return Entries[0]; }

	const SmallVectorImpl<BlockT *> & getEntries() const {
	return Entries;
	}

	/// \brief Return whether \p Block is an entry block of the cycle.
	bool isEntry(BlockT *Block) const { return is_contained(Entries, Block); }

	/// \brief Return whether \p Block is contained in the cycle.
	bool contains(const BlockT *Block) const {
	return is_contained(Blocks, Block);
	}

	/// \brief Returns true iff this cycle contains \p C.
	///
	/// Note: Non-strict containment check, i.e. returns true if C is the
	/// same cycle.
	bool contains(const GenericCycle *C) const;

	const GenericCycle *getParentCycle() const { return ParentCycle; }
	GenericCycle *getParentCycle() { return ParentCycle; }
	unsigned getDepth() const { return Depth; }

	/// Return all of the successor blocks of this cycle.
	///
	/// These are the blocks _outside of the current cycle_ which are
	/// branched to.
	void getExitBlocks(SmallVectorImpl<BlockT *> &TmpStorage) const;

	/// Return the preheader block for this cycle. Pre-header is well-defined for
	/// reducible cycle in docs/LoopTerminology.rst as: the only one entering
	/// block and its only edge is to the entry block. Return null for irreducible
	/// cycles.
	BlockT *getCyclePreheader() const;

	/// If the cycle has exactly one entry with exactly one predecessor, return
	/// it, otherwise return nullptr.
	BlockT *getCyclePredecessor() const;

	/// Iteration over child cycles.
	//@{
	using const_child_iterator_base =
	typename std::vector<std::unique_ptr<GenericCycle>>::const_iterator;
	struct const_child_iterator
	: iterator_adaptor_base<const_child_iterator, const_child_iterator_base> {
	using Base =
	iterator_adaptor_base<const_child_iterator, const_child_iterator_base>;

	const_child_iterator() = default;
	explicit const_child_iterator(const_child_iterator_base I) : Base(I) {}

	const const_child_iterator_base &wrapped() { return Base::wrapped(); }
	GenericCycle operator() const { return Base::I->get(); }
	};

	const_child_iterator child_begin() const {
	return const_child_iterator{Children.begin()};
	}
	const_child_iterator child_end() const {
	return const_child_iterator{Children.end()};
	}
	size_t getNumChildren() const { return Children.size(); }
	iterator_range<const_child_iterator> children() const {
	return llvm::make_range(const_child_iterator{Children.begin()},
	const_child_iterator{Children.end()});
	}
	//@}

	/// Iteration over blocks in the cycle (including entry blocks).
	//@{
	using const_block_iterator = typename std::vector<BlockT *>::const_iterator;

	const_block_iterator block_begin() const {
	return const_block_iterator{Blocks.begin()};
	}
	const_block_iterator block_end() const {
	return const_block_iterator{Blocks.end()};
	}
	size_t getNumBlocks() const { return Blocks.size(); }
	iterator_range<const_block_iterator> blocks() const {
	return llvm::make_range(block_begin(), block_end());
	}
	//@}

	/// Iteration over entry blocks.
	//@{
	using const_entry_iterator =
	typename SmallVectorImpl<BlockT *>::const_iterator;

	size_t getNumEntries() const { return Entries.size(); }
	iterator_range<const_entry_iterator> entries() const {
	return llvm::make_range(Entries.begin(), Entries.end());
	}
	//@}

	Printable printEntries(const ContextT &Ctx) const {
	return Printable([this, &Ctx](raw_ostream &Out) {
	bool First = true;
	for (auto *Entry : Entries) {
	if (!First)
	Out << ' ';
	First = false;
	Out << Ctx.print(Entry);
	}
	});
	}

	Printable print(const ContextT &Ctx) const {
	return Printable([this, &Ctx](raw_ostream &Out) {
	Out << "depth=" << Depth << ": entries(" << printEntries(Ctx) << ')';

	for (auto *Block : Blocks) {
	if (isEntry(Block))
	continue;

	Out << ' ' << Ctx.print(Block);
	}
	});
	}
	};

	/// \brief Cycle information for a function.
	template <typename ContextT> class GenericCycleInfo {
	public:
	using BlockT = typename ContextT::BlockT;
	using CycleT = GenericCycle<ContextT>;
	using FunctionT = typename ContextT::FunctionT;
	template <typename> friend class GenericCycle;
	template <typename> friend class GenericCycleInfoCompute;

	private:
	ContextT Context;

	/// Map basic blocks to their inner-most containing loop.
	DenseMap<BlockT , CycleT > BlockMap;

	/// Outermost cycles discovered by any DFS.
	///
	/// Note: The implementation treats the nullptr as the parent of
	/// every top-level cycle. See \ref contains for an example.
	std::vector<std::unique_ptr<CycleT>> TopLevelCycles;

	public:
	GenericCycleInfo() = default;
	GenericCycleInfo(GenericCycleInfo &&) = default;
	GenericCycleInfo &operator=(GenericCycleInfo &&) = default;

	void clear();
	void compute(FunctionT &F);

	FunctionT *getFunction() const { return Context.getFunction(); }
	const ContextT &getSSAContext() const { return Context; }

	CycleT getCycle(const BlockT Block) const;
	unsigned getCycleDepth(const BlockT *Block) const;
	CycleT getTopLevelParentCycle(const BlockT Block) const;

	/// Move \p Child to \p NewParent by manipulating Children vectors.
	///
	/// Note: This is an incomplete operation that does not update the
	/// list of blocks in the new parent or the depth of the subtree.
	void moveToNewParent(CycleT NewParent, CycleT Child);

	/// Methods for debug and self-test.
	//@{
	#ifndef NDEBUG
	bool validateTree() const;
	#endif
	void print(raw_ostream &Out) const;
	void dump() const { print(dbgs()); }
	//@}

	/// Iteration over top-level cycles.
	//@{
	using const_toplevel_iterator_base =
	typename std::vector<std::unique_ptr<CycleT>>::const_iterator;
	struct const_toplevel_iterator
	: iterator_adaptor_base<const_toplevel_iterator,
	const_toplevel_iterator_base> {
	using Base = iterator_adaptor_base<const_toplevel_iterator,
	const_toplevel_iterator_base>;

	const_toplevel_iterator() = default;
	explicit const_toplevel_iterator(const_toplevel_iterator_base I)
	: Base(I) {}

	const const_toplevel_iterator_base &wrapped() { return Base::wrapped(); }
	CycleT operator() const { return Base::I->get(); }
	};

	const_toplevel_iterator toplevel_begin() const {
	return const_toplevel_iterator{TopLevelCycles.begin()};
	}
	const_toplevel_iterator toplevel_end() const {
	return const_toplevel_iterator{TopLevelCycles.end()};
	}

	iterator_range<const_toplevel_iterator> toplevel_cycles() const {
	return llvm::make_range(const_toplevel_iterator{TopLevelCycles.begin()},
	const_toplevel_iterator{TopLevelCycles.end()});
	}
	//@}
	};

	/// \brief GraphTraits for iterating over a sub-tree of the CycleT tree.
	template <typename CycleRefT, typename ChildIteratorT> struct CycleGraphTraits {
	using NodeRef = CycleRefT;

	using nodes_iterator = ChildIteratorT;
	using ChildIteratorType = nodes_iterator;

	static NodeRef getEntryNode(NodeRef Graph) { return Graph; }

	static ChildIteratorType child_begin(NodeRef Ref) {
	return Ref->child_begin();
	}
	static ChildIteratorType child_end(NodeRef Ref) { return Ref->child_end(); }

	// Not implemented:
	// static nodes_iterator nodes_begin(GraphType *G)
	// static nodes_iterator nodes_end (GraphType *G)
	// nodes_iterator/begin/end - Allow iteration over all nodes in the graph

	// typedef EdgeRef - Type of Edge token in the graph, which should
	// be cheap to copy.
	// typedef ChildEdgeIteratorType - Type used to iterate over children edges in
	// graph, dereference to a EdgeRef.

	// static ChildEdgeIteratorType child_edge_begin(NodeRef)
	// static ChildEdgeIteratorType child_edge_end(NodeRef)
	// Return iterators that point to the beginning and ending of the
	// edge list for the given callgraph node.
	//
	// static NodeRef edge_dest(EdgeRef)
	// Return the destination node of an edge.
	// static unsigned size (GraphType *G)
	// Return total number of nodes in the graph
	};

	template <typename BlockT>
	struct GraphTraits<const GenericCycle<BlockT> *>
	: CycleGraphTraits<const GenericCycle<BlockT> *,
	typename GenericCycle<BlockT>::const_child_iterator> {};
	template <typename BlockT>
	struct GraphTraits<GenericCycle<BlockT> *>
	: CycleGraphTraits<GenericCycle<BlockT> *,
	typename GenericCycle<BlockT>::const_child_iterator> {};

	} // namespace llvm

	#endif // LLVM_ADT_GENERICCYCLEINFO_H