runtime/platform/splay-tree.h - sdk.git - Git at Google

 // Copyright (c) 2010, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.
 //
 // The original file can be found at:
 // https://github.com/v8/v8/blob/master/src/splay-tree.h

 #ifndef RUNTIME_PLATFORM_SPLAY_TREE_H_
 #define RUNTIME_PLATFORM_SPLAY_TREE_H_

 #include "platform/allocation.h"

 namespace dart {

 // A splay tree.  The config type parameter encapsulates the different
 // configurations of a concrete splay tree:
 //
 //   typedef Key: the key type
 //   typedef Value: the value type
 //   static const Key kNoKey: the dummy key used when no key is set
 //   static Value kNoValue(): the dummy value used to initialize nodes
 //   static int (Compare)(Key& a, Key& b) -> {-1, 0, 1}: comparison function
 //
 // The tree is also parameterized by an allocation policy
 // (Allocator). The policy is used for allocating lists in the C free
 // store or the zone; see zone.h.

 template <typename Config, class B, class Allocator>
 class SplayTree : public B {
  public:
   typedef typename Config::Key Key;
   typedef typename Config::Value Value;

   class Locator;

   explicit SplayTree(Allocator* allocator)
       : root_(nullptr), allocator_(allocator) {}
   ~SplayTree();

   Allocator* allocator() { return allocator_; }

   // Checks if there is a mapping for the key.
   bool Contains(const Key& key);

   // Inserts the given key in this tree with the given value.  Returns
   // true if a node was inserted, otherwise false.  If found the locator
   // is enabled and provides access to the mapping for the key.
   bool Insert(const Key& key, Locator* locator);

   // Looks up the key in this tree and returns true if it was found,
   // otherwise false.  If the node is found the locator is enabled and
   // provides access to the mapping for the key.
   bool Find(const Key& key, Locator* locator);

   // Finds the mapping with the greatest key less than or equal to the
   // given key.
   bool FindGreatestLessThan(const Key& key, Locator* locator);

   // Find the mapping with the greatest key in this tree.
   bool FindGreatest(Locator* locator);

   // Finds the mapping with the least key greater than or equal to the
   // given key.
   bool FindLeastGreaterThan(const Key& key, Locator* locator);

   // Find the mapping with the least key in this tree.
   bool FindLeast(Locator* locator);

   // Move the node from one key to another.
   bool Move(const Key& old_key, const Key& new_key);

   // Remove the node with the given key from the tree.
   bool Remove(const Key& key);

   // Remove all keys from the tree.
   void Clear() { ResetRoot(); }

   bool is_empty() { return root_ == nullptr; }

   // Perform the splay operation for the given key. Moves the node with
   // the given key to the top of the tree.  If no node has the given
   // key, the last node on the search path is moved to the top of the
   // tree.
   void Splay(const Key& key);

   class Node : public B {
    public:
     Node(const Key& key, const Value& value)
         : key_(key), value_(value), left_(nullptr), right_(nullptr) {}

     Key key() { return key_; }
     Value value() { return value_; }
     Node* left() { return left_; }
     Node* right() { return right_; }

    private:
     friend class SplayTree;
     friend class Locator;
     Key key_;
     Value value_;
     Node* left_;
     Node* right_;
   };

   // A locator provides access to a node in the tree without actually
   // exposing the node.
   class Locator : public B {
    public:
     explicit Locator(Node* node) : node_(node) {}
     Locator() : node_(nullptr) {}
     const Key& key() { return node_->key_; }
     Value& value() { return node_->value_; }
     void set_value(const Value& value) { node_->value_ = value; }
     inline void bind(Node* node) { node_ = node; }

    private:
     Node* node_;
   };

   template <class Callback>
   void ForEach(Callback* callback);

  protected:
   // Resets tree root. Existing nodes become unreachable.
   void ResetRoot() { root_ = nullptr; }

  private:
   // Search for a node with a given key. If found, root_ points
   // to the node.
   bool FindInternal(const Key& key);

   // Inserts a node assuming that root_ is already set up.
   void InsertInternal(int cmp, Node* node);

   // Removes root_ node.
   void RemoveRootNode(const Key& key);

   template <class Callback>
   class NodeToPairAdaptor : public B {
    public:
     explicit NodeToPairAdaptor(Callback* callback) : callback_(callback) {}
     void Call(Node* node) { callback_->Call(node->key(), node->value()); }

    private:
     Callback* callback_;

     DISALLOW_COPY_AND_ASSIGN(NodeToPairAdaptor);
   };

   class NodeDeleter : public B {
    public:
     NodeDeleter() = default;
     void Call(Node* node) { delete node; }

    private:
     DISALLOW_COPY_AND_ASSIGN(NodeDeleter);
   };

   template <class Callback>
   void ForEachNode(Callback* callback);

   Node* root_;
   Allocator* allocator_;

   DISALLOW_COPY_AND_ASSIGN(SplayTree);
 };

 }  // namespace dart

 #endif  // RUNTIME_PLATFORM_SPLAY_TREE_H_
	// Copyright (c) 2010, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.
	//
	// The original file can be found at:
	// https://github.com/v8/v8/blob/master/src/splay-tree.h

	#ifndef RUNTIME_PLATFORM_SPLAY_TREE_H_
	#define RUNTIME_PLATFORM_SPLAY_TREE_H_

	#include "platform/allocation.h"

	namespace dart {

	// A splay tree. The config type parameter encapsulates the different
	// configurations of a concrete splay tree:
	//
	// typedef Key: the key type
	// typedef Value: the value type
	// static const Key kNoKey: the dummy key used when no key is set
	// static Value kNoValue(): the dummy value used to initialize nodes
	// static int (Compare)(Key& a, Key& b) -> {-1, 0, 1}: comparison function
	//
	// The tree is also parameterized by an allocation policy
	// (Allocator). The policy is used for allocating lists in the C free
	// store or the zone; see zone.h.

	template <typename Config, class B, class Allocator>
	class SplayTree : public B {
	public:
	typedef typename Config::Key Key;
	typedef typename Config::Value Value;

	class Locator;

	explicit SplayTree(Allocator* allocator)
	: root_(nullptr), allocator_(allocator) {}
	~SplayTree();

	Allocator* allocator() { return allocator_; }

	// Checks if there is a mapping for the key.
	bool Contains(const Key& key);

	// Inserts the given key in this tree with the given value. Returns
	// true if a node was inserted, otherwise false. If found the locator
	// is enabled and provides access to the mapping for the key.
	bool Insert(const Key& key, Locator* locator);

	// Looks up the key in this tree and returns true if it was found,
	// otherwise false. If the node is found the locator is enabled and
	// provides access to the mapping for the key.
	bool Find(const Key& key, Locator* locator);

	// Finds the mapping with the greatest key less than or equal to the
	// given key.
	bool FindGreatestLessThan(const Key& key, Locator* locator);

	// Find the mapping with the greatest key in this tree.
	bool FindGreatest(Locator* locator);

	// Finds the mapping with the least key greater than or equal to the
	// given key.
	bool FindLeastGreaterThan(const Key& key, Locator* locator);

	// Find the mapping with the least key in this tree.
	bool FindLeast(Locator* locator);

	// Move the node from one key to another.
	bool Move(const Key& old_key, const Key& new_key);

	// Remove the node with the given key from the tree.
	bool Remove(const Key& key);

	// Remove all keys from the tree.
	void Clear() { ResetRoot(); }

	bool is_empty() { return root_ == nullptr; }

	// Perform the splay operation for the given key. Moves the node with
	// the given key to the top of the tree. If no node has the given
	// key, the last node on the search path is moved to the top of the
	// tree.
	void Splay(const Key& key);

	class Node : public B {
	public:
	Node(const Key& key, const Value& value)
	: key_(key), value_(value), left_(nullptr), right_(nullptr) {}

	Key key() { return key_; }
	Value value() { return value_; }
	Node* left() { return left_; }
	Node* right() { return right_; }

	private:
	friend class SplayTree;
	friend class Locator;
	Key key_;
	Value value_;
	Node* left_;
	Node* right_;
	};

	// A locator provides access to a node in the tree without actually
	// exposing the node.
	class Locator : public B {
	public:
	explicit Locator(Node* node) : node_(node) {}
	Locator() : node_(nullptr) {}
	const Key& key() { return node_->key_; }
	Value& value() { return node_->value_; }
	void set_value(const Value& value) { node_->value_ = value; }
	inline void bind(Node* node) { node_ = node; }

	private:
	Node* node_;
	};

	template <class Callback>
	void ForEach(Callback* callback);

	protected:
	// Resets tree root. Existing nodes become unreachable.
	void ResetRoot() { root_ = nullptr; }

	private:
	// Search for a node with a given key. If found, root_ points
	// to the node.
	bool FindInternal(const Key& key);

	// Inserts a node assuming that root_ is already set up.
	void InsertInternal(int cmp, Node* node);

	// Removes root_ node.
	void RemoveRootNode(const Key& key);

	template <class Callback>
	class NodeToPairAdaptor : public B {
	public:
	explicit NodeToPairAdaptor(Callback* callback) : callback_(callback) {}
	void Call(Node* node) { callback_->Call(node->key(), node->value()); }

	private:
	Callback* callback_;

	DISALLOW_COPY_AND_ASSIGN(NodeToPairAdaptor);
	};

	class NodeDeleter : public B {
	public:
	NodeDeleter() = default;
	void Call(Node* node) { delete node; }

	private:
	DISALLOW_COPY_AND_ASSIGN(NodeDeleter);
	};

	template <class Callback>
	void ForEachNode(Callback* callback);

	Node* root_;
	Allocator* allocator_;

	DISALLOW_COPY_AND_ASSIGN(SplayTree);
	};

	} // namespace dart

	#endif // RUNTIME_PLATFORM_SPLAY_TREE_H_