unittests/ADT/TestGraph.h - llvm - Git at Google

 //===- llvm/unittest/ADT/TestGraph.h - Graph for testing ------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // Common graph data structure for testing.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_UNITTESTS_ADT_TEST_GRAPH_H
 #define LLVM_UNITTESTS_ADT_TEST_GRAPH_H

 #include "llvm/ADT/GraphTraits.h"
 #include <cassert>
 #include <climits>
 #include <utility>

 namespace llvm {

 /// Graph<N> - A graph with N nodes.  Note that N can be at most 8.
 template <unsigned N>
 class Graph {
 private:
   // Disable copying.
   Graph(const Graph&);
   Graph& operator=(const Graph&);

   static void ValidateIndex(unsigned Idx) {
     assert(Idx < N && "Invalid node index!");
   }
 public:

   /// NodeSubset - A subset of the graph's nodes.
   class NodeSubset {
     typedef unsigned char BitVector; // Where the limitation N <= 8 comes from.
     BitVector Elements;
     NodeSubset(BitVector e) : Elements(e) {}
   public:
     /// NodeSubset - Default constructor, creates an empty subset.
     NodeSubset() : Elements(0) {
       assert(N <= sizeof(BitVector)*CHAR_BIT && "Graph too big!");
     }

     /// Comparison operators.
     bool operator==(const NodeSubset &other) const {
       return other.Elements == this->Elements;
     }
     bool operator!=(const NodeSubset &other) const {
       return !(*this == other);
     }

     /// AddNode - Add the node with the given index to the subset.
     void AddNode(unsigned Idx) {
       ValidateIndex(Idx);
       Elements |= 1U << Idx;
     }

     /// DeleteNode - Remove the node with the given index from the subset.
     void DeleteNode(unsigned Idx) {
       ValidateIndex(Idx);
       Elements &= ~(1U << Idx);
     }

     /// count - Return true if the node with the given index is in the subset.
     bool count(unsigned Idx) {
       ValidateIndex(Idx);
       return (Elements & (1U << Idx)) != 0;
     }

     /// isEmpty - Return true if this is the empty set.
     bool isEmpty() const {
       return Elements == 0;
     }

     /// isSubsetOf - Return true if this set is a subset of the given one.
     bool isSubsetOf(const NodeSubset &other) const {
       return (this->Elements | other.Elements) == other.Elements;
     }

     /// Complement - Return the complement of this subset.
     NodeSubset Complement() const {
       return ~(unsigned)this->Elements & ((1U << N) - 1);
     }

     /// Join - Return the union of this subset and the given one.
     NodeSubset Join(const NodeSubset &other) const {
       return this->Elements | other.Elements;
     }

     /// Meet - Return the intersection of this subset and the given one.
     NodeSubset Meet(const NodeSubset &other) const {
       return this->Elements & other.Elements;
     }
   };

   /// NodeType - Node index and set of children of the node.
   typedef std::pair<unsigned, NodeSubset> NodeType;

 private:
   /// Nodes - The list of nodes for this graph.
   NodeType Nodes[N];
 public:

   /// Graph - Default constructor.  Creates an empty graph.
   Graph() {
     // Let each node know which node it is.  This allows us to find the start of
     // the Nodes array given a pointer to any element of it.
     for (unsigned i = 0; i != N; ++i)
       Nodes[i].first = i;
   }

   /// AddEdge - Add an edge from the node with index FromIdx to the node with
   /// index ToIdx.
   void AddEdge(unsigned FromIdx, unsigned ToIdx) {
     ValidateIndex(FromIdx);
     Nodes[FromIdx].second.AddNode(ToIdx);
   }

   /// DeleteEdge - Remove the edge (if any) from the node with index FromIdx to
   /// the node with index ToIdx.
   void DeleteEdge(unsigned FromIdx, unsigned ToIdx) {
     ValidateIndex(FromIdx);
     Nodes[FromIdx].second.DeleteNode(ToIdx);
   }

   /// AccessNode - Get a pointer to the node with the given index.
   NodeType *AccessNode(unsigned Idx) const {
     ValidateIndex(Idx);
     // The constant cast is needed when working with GraphTraits, which insists
     // on taking a constant Graph.
     return const_cast<NodeType *>(&Nodes[Idx]);
   }

   /// NodesReachableFrom - Return the set of all nodes reachable from the given
   /// node.
   NodeSubset NodesReachableFrom(unsigned Idx) const {
     // This algorithm doesn't scale, but that doesn't matter given the small
     // size of our graphs.
     NodeSubset Reachable;

     // The initial node is reachable.
     Reachable.AddNode(Idx);
     do {
       NodeSubset Previous(Reachable);

       // Add in all nodes which are children of a reachable node.
       for (unsigned i = 0; i != N; ++i)
         if (Previous.count(i))
           Reachable = Reachable.Join(Nodes[i].second);

       // If nothing changed then we have found all reachable nodes.
       if (Reachable == Previous)
         return Reachable;

       // Rinse and repeat.
     } while (1);
   }

   /// ChildIterator - Visit all children of a node.
   class ChildIterator {
     friend class Graph;

     /// FirstNode - Pointer to first node in the graph's Nodes array.
     NodeType *FirstNode;
     /// Children - Set of nodes which are children of this one and that haven't
     /// yet been visited.
     NodeSubset Children;

     ChildIterator(); // Disable default constructor.
   protected:
     ChildIterator(NodeType *F, NodeSubset C) : FirstNode(F), Children(C) {}

   public:
     /// ChildIterator - Copy constructor.
     ChildIterator(const ChildIterator& other) : FirstNode(other.FirstNode),
       Children(other.Children) {}

     /// Comparison operators.
     bool operator==(const ChildIterator &other) const {
       return other.FirstNode == this->FirstNode &&
         other.Children == this->Children;
     }
     bool operator!=(const ChildIterator &other) const {
       return !(*this == other);
     }

     /// Prefix increment operator.
     ChildIterator& operator++() {
       // Find the next unvisited child node.
       for (unsigned i = 0; i != N; ++i)
         if (Children.count(i)) {
           // Remove that child - it has been visited.  This is the increment!
           Children.DeleteNode(i);
           return *this;
         }
       assert(false && "Incrementing end iterator!");
       return *this; // Avoid compiler warnings.
     }

     /// Postfix increment operator.
     ChildIterator operator++(int) {
       ChildIterator Result(*this);
       ++(*this);
       return Result;
     }

     /// Dereference operator.
     NodeType *operator*() {
       // Find the next unvisited child node.
       for (unsigned i = 0; i != N; ++i)
         if (Children.count(i))
           // Return a pointer to it.
           return FirstNode + i;
       assert(false && "Dereferencing end iterator!");
       return nullptr; // Avoid compiler warning.
     }
   };

   /// child_begin - Return an iterator pointing to the first child of the given
   /// node.
   static ChildIterator child_begin(NodeType *Parent) {
     return ChildIterator(Parent - Parent->first, Parent->second);
   }

   /// child_end - Return the end iterator for children of the given node.
   static ChildIterator child_end(NodeType *Parent) {
     return ChildIterator(Parent - Parent->first, NodeSubset());
   }
 };

 template <unsigned N>
 struct GraphTraits<Graph<N> > {
   typedef typename Graph<N>::NodeType *NodeRef;
   typedef typename Graph<N>::ChildIterator ChildIteratorType;

   static NodeRef getEntryNode(const Graph<N> &G) { return G.AccessNode(0); }
   static ChildIteratorType child_begin(NodeRef Node) {
     return Graph<N>::child_begin(Node);
   }
   static ChildIteratorType child_end(NodeRef Node) {
     return Graph<N>::child_end(Node);
   }
 };

 } // End namespace llvm

 #endif
	//===- llvm/unittest/ADT/TestGraph.h - Graph for testing ------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// Common graph data structure for testing.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_UNITTESTS_ADT_TEST_GRAPH_H
	#define LLVM_UNITTESTS_ADT_TEST_GRAPH_H

	#include "llvm/ADT/GraphTraits.h"
	#include <cassert>
	#include <climits>
	#include <utility>

	namespace llvm {

	/// Graph<N> - A graph with N nodes. Note that N can be at most 8.
	template <unsigned N>
	class Graph {
	private:
	// Disable copying.
	Graph(const Graph&);
	Graph& operator=(const Graph&);

	static void ValidateIndex(unsigned Idx) {
	assert(Idx < N && "Invalid node index!");
	}
	public:

	/// NodeSubset - A subset of the graph's nodes.
	class NodeSubset {
	typedef unsigned char BitVector; // Where the limitation N <= 8 comes from.
	BitVector Elements;
	NodeSubset(BitVector e) : Elements(e) {}
	public:
	/// NodeSubset - Default constructor, creates an empty subset.
	NodeSubset() : Elements(0) {
	assert(N <= sizeof(BitVector)*CHAR_BIT && "Graph too big!");
	}

	/// Comparison operators.
	bool operator==(const NodeSubset &other) const {
	return other.Elements == this->Elements;
	}
	bool operator!=(const NodeSubset &other) const {
	return !(*this == other);
	}

	/// AddNode - Add the node with the given index to the subset.
	void AddNode(unsigned Idx) {
	ValidateIndex(Idx);
	Elements \|= 1U << Idx;
	}

	/// DeleteNode - Remove the node with the given index from the subset.
	void DeleteNode(unsigned Idx) {
	ValidateIndex(Idx);
	Elements &= ~(1U << Idx);
	}

	/// count - Return true if the node with the given index is in the subset.
	bool count(unsigned Idx) {
	ValidateIndex(Idx);
	return (Elements & (1U << Idx)) != 0;
	}

	/// isEmpty - Return true if this is the empty set.
	bool isEmpty() const {
	return Elements == 0;
	}

	/// isSubsetOf - Return true if this set is a subset of the given one.
	bool isSubsetOf(const NodeSubset &other) const {
	return (this->Elements \| other.Elements) == other.Elements;
	}

	/// Complement - Return the complement of this subset.
	NodeSubset Complement() const {
	return ~(unsigned)this->Elements & ((1U << N) - 1);
	}

	/// Join - Return the union of this subset and the given one.
	NodeSubset Join(const NodeSubset &other) const {
	return this->Elements \| other.Elements;
	}

	/// Meet - Return the intersection of this subset and the given one.
	NodeSubset Meet(const NodeSubset &other) const {
	return this->Elements & other.Elements;
	}
	};

	/// NodeType - Node index and set of children of the node.
	typedef std::pair<unsigned, NodeSubset> NodeType;

	private:
	/// Nodes - The list of nodes for this graph.
	NodeType Nodes[N];
	public:

	/// Graph - Default constructor. Creates an empty graph.
	Graph() {
	// Let each node know which node it is. This allows us to find the start of
	// the Nodes array given a pointer to any element of it.
	for (unsigned i = 0; i != N; ++i)
	Nodes[i].first = i;
	}

	/// AddEdge - Add an edge from the node with index FromIdx to the node with
	/// index ToIdx.
	void AddEdge(unsigned FromIdx, unsigned ToIdx) {
	ValidateIndex(FromIdx);
	Nodes[FromIdx].second.AddNode(ToIdx);
	}

	/// DeleteEdge - Remove the edge (if any) from the node with index FromIdx to
	/// the node with index ToIdx.
	void DeleteEdge(unsigned FromIdx, unsigned ToIdx) {
	ValidateIndex(FromIdx);
	Nodes[FromIdx].second.DeleteNode(ToIdx);
	}

	/// AccessNode - Get a pointer to the node with the given index.
	NodeType *AccessNode(unsigned Idx) const {
	ValidateIndex(Idx);
	// The constant cast is needed when working with GraphTraits, which insists
	// on taking a constant Graph.
	return const_cast<NodeType *>(&Nodes[Idx]);
	}

	/// NodesReachableFrom - Return the set of all nodes reachable from the given
	/// node.
	NodeSubset NodesReachableFrom(unsigned Idx) const {
	// This algorithm doesn't scale, but that doesn't matter given the small
	// size of our graphs.
	NodeSubset Reachable;

	// The initial node is reachable.
	Reachable.AddNode(Idx);
	do {
	NodeSubset Previous(Reachable);

	// Add in all nodes which are children of a reachable node.
	for (unsigned i = 0; i != N; ++i)
	if (Previous.count(i))
	Reachable = Reachable.Join(Nodes[i].second);

	// If nothing changed then we have found all reachable nodes.
	if (Reachable == Previous)
	return Reachable;

	// Rinse and repeat.
	} while (1);
	}

	/// ChildIterator - Visit all children of a node.
	class ChildIterator {
	friend class Graph;

	/// FirstNode - Pointer to first node in the graph's Nodes array.
	NodeType *FirstNode;
	/// Children - Set of nodes which are children of this one and that haven't
	/// yet been visited.
	NodeSubset Children;

	ChildIterator(); // Disable default constructor.
	protected:
	ChildIterator(NodeType *F, NodeSubset C) : FirstNode(F), Children(C) {}

	public:
	/// ChildIterator - Copy constructor.
	ChildIterator(const ChildIterator& other) : FirstNode(other.FirstNode),
	Children(other.Children) {}

	/// Comparison operators.
	bool operator==(const ChildIterator &other) const {
	return other.FirstNode == this->FirstNode &&
	other.Children == this->Children;
	}
	bool operator!=(const ChildIterator &other) const {
	return !(*this == other);
	}

	/// Prefix increment operator.
	ChildIterator& operator++() {
	// Find the next unvisited child node.
	for (unsigned i = 0; i != N; ++i)
	if (Children.count(i)) {
	// Remove that child - it has been visited. This is the increment!
	Children.DeleteNode(i);
	return *this;
	}
	assert(false && "Incrementing end iterator!");
	return *this; // Avoid compiler warnings.
	}

	/// Postfix increment operator.
	ChildIterator operator++(int) {
	ChildIterator Result(*this);
	++(*this);
	return Result;
	}

	/// Dereference operator.
	NodeType operator() {
	// Find the next unvisited child node.
	for (unsigned i = 0; i != N; ++i)
	if (Children.count(i))
	// Return a pointer to it.
	return FirstNode + i;
	assert(false && "Dereferencing end iterator!");
	return nullptr; // Avoid compiler warning.
	}
	};

	/// child_begin - Return an iterator pointing to the first child of the given
	/// node.
	static ChildIterator child_begin(NodeType *Parent) {
	return ChildIterator(Parent - Parent->first, Parent->second);
	}

	/// child_end - Return the end iterator for children of the given node.
	static ChildIterator child_end(NodeType *Parent) {
	return ChildIterator(Parent - Parent->first, NodeSubset());
	}
	};

	template <unsigned N>
	struct GraphTraits<Graph<N> > {
	typedef typename Graph<N>::NodeType *NodeRef;
	typedef typename Graph<N>::ChildIterator ChildIteratorType;

	static NodeRef getEntryNode(const Graph<N> &G) { return G.AccessNode(0); }
	static ChildIteratorType child_begin(NodeRef Node) {
	return Graph<N>::child_begin(Node);
	}
	static ChildIteratorType child_end(NodeRef Node) {
	return Graph<N>::child_end(Node);
	}
	};

	} // End namespace llvm

	#endif