ui/base/models/tree_node_model.h - chromium/src - Git at Google

 // Copyright (c) 2012 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef UI_BASE_MODELS_TREE_NODE_MODEL_H_
 #define UI_BASE_MODELS_TREE_NODE_MODEL_H_

 #include <stddef.h>

 #include <algorithm>
 #include <memory>
 #include <vector>

 #include "base/logging.h"
 #include "base/macros.h"
 #include "base/observer_list.h"
 #include "base/strings/string16.h"
 #include "ui/base/models/tree_model.h"

 namespace ui {

 // TreeNodeModel and TreeNodes provide an implementation of TreeModel around
 // TreeNodes.
 //
 // TreeNodes own their children, so that deleting a node deletes all
 // descendants.
 //
 // TreeNodes do NOT maintain a pointer back to the model. As such, if you
 // are using TreeNodes with a TreeNodeModel you will need to notify the observer
 // yourself any time you make any change directly to the TreeNodes. For example,
 // if you directly invoke set_title on a node it does not notify the observer,
 // you will need to do it yourself. This includes the following methods: Add,
 // Remove and set_title. TreeNodeModel provides cover methods that mutate the
 // TreeNodes and notify the observer. If you are using TreeNodes with a
 // TreeNodeModel use the cover methods to save yourself the headache.
 //
 // The following example creates a TreeNode with two children and then
 // creates a TreeNodeModel from it:
 //
 // std::unique_ptr<TreeNodeWithValue<int>> root =
 //     std::make_unique<TreeNodeWithValue<int>>();
 // root->Add(
 //     std::make_unique<TreeNodeWithValue<int>>(ASCIIToUTF16("child 1"), 0));
 // root->Add(
 //     std::make_unique<TreeNodeWithValue<int>>(ASCIIToUTF16("child 2"), 1));
 // TreeNodeModel<TreeNodeWithValue<int>> model(std::move(root));
 //
 // Two variants of TreeNode are provided here:
 //
 // . TreeNode itself is intended for subclassing. It has one type parameter
 //   that corresponds to the type of the node. When subclassing use your class
 //   name as the type parameter, e.g.:
 //   class MyTreeNode : public TreeNode<MyTreeNode> .
 // . TreeNodeWithValue is a trivial subclass of TreeNode that has one type
 //   type parameter: a value type that is associated with the node.
 //
 // Which you use depends upon the situation. If you want to subclass and add
 // methods, then use TreeNode. If you don't need any extra methods and just
 // want to associate a value with each node, then use TreeNodeWithValue.
 //
 // Regardless of which TreeNode you use, if you are using the nodes with a
 // TreeView take care to notify the observer when mutating the nodes.

 // TreeNode -------------------------------------------------------------------

 // See above for documentation. Example:
 //
 //   class MyNode : public ui::TreeNode<MyNode> {
 //     ...<custom class logic>...
 //   };
 //   using MyModel = ui::TreeNodeModel<MyNode>;
 template <class NodeType>
 class TreeNode : public TreeModelNode {
  public:
   TreeNode() : parent_(nullptr) {}

   explicit TreeNode(const base::string16& title)
       : title_(title), parent_(nullptr) {}

   ~TreeNode() override {}

   // Adds |node| as a child of this node, at |index|. Returns a raw pointer to
   // the node.
   NodeType* Add(std::unique_ptr<NodeType> node, int index) {
     DCHECK(node);
     DCHECK_GE(index, 0);
     DCHECK_LE(index, child_count());
     DCHECK(!node->parent_);
     node->parent_ = static_cast<NodeType*>(this);
     NodeType* node_ptr = node.get();
     children_.insert(children_.begin() + index, std::move(node));
     return node_ptr;
   }

   // Removes the node at the given index. Returns the removed node.
   std::unique_ptr<NodeType> Remove(int index) {
     DCHECK(index >= 0 && index < child_count());
     children_[index]->parent_ = nullptr;
     std::unique_ptr<NodeType> ptr = std::move(children_[index]);
     children_.erase(children_.begin() + index);
     return ptr;
   }

   // Removes the given node. Prefer to remove by index if you know it to avoid
   // the search for the node to remove.
   std::unique_ptr<NodeType> Remove(NodeType* node) {
     auto i = std::find_if(children_.begin(), children_.end(),
                           [node](const std::unique_ptr<NodeType>& ptr) {
                             return ptr.get() == node;
                           });
     DCHECK(i != children_.end());
     return Remove(i - children_.begin());
   }

   // Removes all the children from this node.
   void DeleteAll() { children_.clear(); }

   // Returns the parent node, or nullptr if this is the root node.
   const NodeType* parent() const { return parent_; }
   NodeType* parent() { return parent_; }

   // Returns true if this is the root node.
   bool is_root() const { return parent_ == nullptr; }

   // Returns the number of children.
   int child_count() const { return static_cast<int>(children_.size()); }

   // Returns true if this node has no children.
   bool empty() const { return children_.empty(); }

   // Returns the number of all nodes in the subtree rooted at this node,
   // including this node.
   int GetTotalNodeCount() const {
     int count = 1;  // Start with one to include the node itself.
     for (const auto& child : children_)
       count += child->GetTotalNodeCount();
     return count;
   }

   // Returns the node at |index|.
   const NodeType* GetChild(int index) const {
     DCHECK_GE(index, 0);
     DCHECK_LT(index, child_count());
     return children_[index].get();
   }
   NodeType* GetChild(int index) {
     return const_cast<NodeType*>(
         static_cast<const NodeType&>(*this).GetChild(index));
   }

   // Returns the index of |node|, or -1 if |node| is not a child of this.
   int GetIndexOf(const NodeType* node) const {
     DCHECK(node);
     auto i = std::find_if(children_.begin(), children_.end(),
                           [node](const std::unique_ptr<NodeType>& ptr) {
                             return ptr.get() == node;
                           });
     return i != children_.end() ? static_cast<int>(i - children_.begin()) : -1;
   }

   // Sets the title of the node.
   virtual void SetTitle(const base::string16& title) { title_ = title; }

   // TreeModelNode:
   const base::string16& GetTitle() const override { return title_; }

   // Returns true if this == ancestor, or one of this nodes parents is
   // ancestor.
   bool HasAncestor(const NodeType* ancestor) const {
     if (ancestor == this)
       return true;
     if (!ancestor)
       return false;
     return parent_ ? parent_->HasAncestor(ancestor) : false;
   }

  protected:
   std::vector<std::unique_ptr<NodeType>>& children() { return children_; }

  private:
   // Title displayed in the tree.
   base::string16 title_;

   // This node's parent.
   NodeType* parent_;

   // This node's children.
   typename std::vector<std::unique_ptr<NodeType>> children_;

   DISALLOW_COPY_AND_ASSIGN(TreeNode);
 };

 // TreeNodeWithValue ----------------------------------------------------------

 // See top of file for documentation. Example:
 //
 //  using MyNode = ui::TreeNodeWithValue<MyData>;
 //  using MyModel = ui::TreeNodeModel<MyNode>;
 template <class ValueType>
 class TreeNodeWithValue : public TreeNode<TreeNodeWithValue<ValueType>> {
  public:
   TreeNodeWithValue() {}

   explicit TreeNodeWithValue(const ValueType& value)
       : ParentType(base::string16()), value(value) {}

   TreeNodeWithValue(const base::string16& title, const ValueType& value)
       : ParentType(title), value(value) {}

   ValueType value;

  private:
   using ParentType = TreeNode<TreeNodeWithValue<ValueType>>;

   DISALLOW_COPY_AND_ASSIGN(TreeNodeWithValue);
 };

 // TreeNodeModel --------------------------------------------------------------

 // TreeModel implementation intended to be used with TreeNodes.
 template <class NodeType>
 class TreeNodeModel : public TreeModel {
  public:
   // Creates a TreeNodeModel with the specified root node.
   explicit TreeNodeModel(std::unique_ptr<NodeType> root)
       : root_(std::move(root)) {}
   virtual ~TreeNodeModel() override {}

   NodeType* AsNode(TreeModelNode* model_node) {
     return static_cast<NodeType*>(model_node);
   }

   NodeType* Add(NodeType* parent, std::unique_ptr<NodeType> node, int index) {
     DCHECK(parent && node);
     NodeType* node_ptr = parent->Add(std::move(node), index);
     NotifyObserverTreeNodesAdded(parent, index, 1);
     return node_ptr;
   }

   std::unique_ptr<NodeType> Remove(NodeType* parent, int index) {
     DCHECK(parent);
     std::unique_ptr<NodeType> owned_node = parent->Remove(index);
     NotifyObserverTreeNodesRemoved(parent, index, 1);
     return owned_node;
   }

   std::unique_ptr<NodeType> Remove(NodeType* parent, NodeType* node) {
     DCHECK(parent);
     return Remove(parent, parent->GetIndexOf(node));
   }

   void NotifyObserverTreeNodesAdded(NodeType* parent, int start, int count) {
     for (TreeModelObserver& observer : observer_list_)
       observer.TreeNodesAdded(this, parent, start, count);
   }

   void NotifyObserverTreeNodesRemoved(NodeType* parent, int start, int count) {
     for (TreeModelObserver& observer : observer_list_)
       observer.TreeNodesRemoved(this, parent, start, count);
   }

   void NotifyObserverTreeNodeChanged(TreeModelNode* node) {
     for (TreeModelObserver& observer : observer_list_)
       observer.TreeNodeChanged(this, node);
   }

   // TreeModel:

   // C++ allows one to override a base class' virtual function with one that
   // returns a different type, as long as that type implements the base class'
   // return type. This is convenient because it allows callers with references
   // to the specific TreeNodeModel to get the proper return type without
   // casting.
   //
   // However, this does require that the NodeType be defined when this is
   // parsed (normally one could forward define this).
   NodeType* GetRoot() override {
     return root_.get();
   }

   int GetChildCount(TreeModelNode* parent) override {
     DCHECK(parent);
     return AsNode(parent)->child_count();
   }

   NodeType* GetChild(TreeModelNode* parent, int index) override {
     DCHECK(parent);
     return AsNode(parent)->GetChild(index);
   }

   int GetIndexOf(TreeModelNode* parent, TreeModelNode* child) override {
     DCHECK(parent);
     return AsNode(parent)->GetIndexOf(AsNode(child));
   }

   TreeModelNode* GetParent(TreeModelNode* node) override {
     DCHECK(node);
     return AsNode(node)->parent();
   }

   void AddObserver(TreeModelObserver* observer) override {
     observer_list_.AddObserver(observer);
   }

   void RemoveObserver(TreeModelObserver* observer) override {
     observer_list_.RemoveObserver(observer);
   }

   void SetTitle(TreeModelNode* node,
                 const base::string16& title) override {
     DCHECK(node);
     AsNode(node)->SetTitle(title);
     NotifyObserverTreeNodeChanged(node);
   }

  private:
   // The observers.
   base::ObserverList<TreeModelObserver> observer_list_;

   // The root.
   std::unique_ptr<NodeType> root_;

   DISALLOW_COPY_AND_ASSIGN(TreeNodeModel);
 };

 }  // namespace ui

 #endif  // UI_BASE_MODELS_TREE_NODE_MODEL_H_
	// Copyright (c) 2012 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef UI_BASE_MODELS_TREE_NODE_MODEL_H_
	#define UI_BASE_MODELS_TREE_NODE_MODEL_H_

	#include <stddef.h>

	#include <algorithm>
	#include <memory>
	#include <vector>

	#include "base/logging.h"
	#include "base/macros.h"
	#include "base/observer_list.h"
	#include "base/strings/string16.h"
	#include "ui/base/models/tree_model.h"

	namespace ui {

	// TreeNodeModel and TreeNodes provide an implementation of TreeModel around
	// TreeNodes.
	//
	// TreeNodes own their children, so that deleting a node deletes all
	// descendants.
	//
	// TreeNodes do NOT maintain a pointer back to the model. As such, if you
	// are using TreeNodes with a TreeNodeModel you will need to notify the observer
	// yourself any time you make any change directly to the TreeNodes. For example,
	// if you directly invoke set_title on a node it does not notify the observer,
	// you will need to do it yourself. This includes the following methods: Add,
	// Remove and set_title. TreeNodeModel provides cover methods that mutate the
	// TreeNodes and notify the observer. If you are using TreeNodes with a
	// TreeNodeModel use the cover methods to save yourself the headache.
	//
	// The following example creates a TreeNode with two children and then
	// creates a TreeNodeModel from it:
	//
	// std::unique_ptr<TreeNodeWithValue<int>> root =
	// std::make_unique<TreeNodeWithValue<int>>();
	// root->Add(
	// std::make_unique<TreeNodeWithValue<int>>(ASCIIToUTF16("child 1"), 0));
	// root->Add(
	// std::make_unique<TreeNodeWithValue<int>>(ASCIIToUTF16("child 2"), 1));
	// TreeNodeModel<TreeNodeWithValue<int>> model(std::move(root));
	//
	// Two variants of TreeNode are provided here:
	//
	// . TreeNode itself is intended for subclassing. It has one type parameter
	// that corresponds to the type of the node. When subclassing use your class
	// name as the type parameter, e.g.:
	// class MyTreeNode : public TreeNode<MyTreeNode> .
	// . TreeNodeWithValue is a trivial subclass of TreeNode that has one type
	// type parameter: a value type that is associated with the node.
	//
	// Which you use depends upon the situation. If you want to subclass and add
	// methods, then use TreeNode. If you don't need any extra methods and just
	// want to associate a value with each node, then use TreeNodeWithValue.
	//
	// Regardless of which TreeNode you use, if you are using the nodes with a
	// TreeView take care to notify the observer when mutating the nodes.

	// TreeNode -------------------------------------------------------------------

	// See above for documentation. Example:
	//
	// class MyNode : public ui::TreeNode<MyNode> {
	// ...<custom class logic>...
	// };
	// using MyModel = ui::TreeNodeModel<MyNode>;
	template <class NodeType>
	class TreeNode : public TreeModelNode {
	public:
	TreeNode() : parent_(nullptr) {}

	explicit TreeNode(const base::string16& title)
	: title_(title), parent_(nullptr) {}

	~TreeNode() override {}

	// Adds \|node\| as a child of this node, at \|index\|. Returns a raw pointer to
	// the node.
	NodeType* Add(std::unique_ptr<NodeType> node, int index) {
	DCHECK(node);
	DCHECK_GE(index, 0);
	DCHECK_LE(index, child_count());
	DCHECK(!node->parent_);
	node->parent_ = static_cast<NodeType*>(this);
	NodeType* node_ptr = node.get();
	children_.insert(children_.begin() + index, std::move(node));
	return node_ptr;
	}

	// Removes the node at the given index. Returns the removed node.
	std::unique_ptr<NodeType> Remove(int index) {
	DCHECK(index >= 0 && index < child_count());
	children_[index]->parent_ = nullptr;
	std::unique_ptr<NodeType> ptr = std::move(children_[index]);
	children_.erase(children_.begin() + index);
	return ptr;
	}

	// Removes the given node. Prefer to remove by index if you know it to avoid
	// the search for the node to remove.
	std::unique_ptr<NodeType> Remove(NodeType* node) {
	auto i = std::find_if(children_.begin(), children_.end(),
	[node](const std::unique_ptr<NodeType>& ptr) {
	return ptr.get() == node;
	});
	DCHECK(i != children_.end());
	return Remove(i - children_.begin());
	}

	// Removes all the children from this node.
	void DeleteAll() { children_.clear(); }

	// Returns the parent node, or nullptr if this is the root node.
	const NodeType* parent() const { return parent_; }
	NodeType* parent() { return parent_; }

	// Returns true if this is the root node.
	bool is_root() const { return parent_ == nullptr; }

	// Returns the number of children.
	int child_count() const { return static_cast<int>(children_.size()); }

	// Returns true if this node has no children.
	bool empty() const { return children_.empty(); }

	// Returns the number of all nodes in the subtree rooted at this node,
	// including this node.
	int GetTotalNodeCount() const {
	int count = 1; // Start with one to include the node itself.
	for (const auto& child : children_)
	count += child->GetTotalNodeCount();
	return count;
	}

	// Returns the node at \|index\|.
	const NodeType* GetChild(int index) const {
	DCHECK_GE(index, 0);
	DCHECK_LT(index, child_count());
	return children_[index].get();
	}
	NodeType* GetChild(int index) {
	return const_cast<NodeType*>(
	static_cast<const NodeType&>(*this).GetChild(index));
	}

	// Returns the index of \|node\|, or -1 if \|node\| is not a child of this.
	int GetIndexOf(const NodeType* node) const {
	DCHECK(node);
	auto i = std::find_if(children_.begin(), children_.end(),
	[node](const std::unique_ptr<NodeType>& ptr) {
	return ptr.get() == node;
	});
	return i != children_.end() ? static_cast<int>(i - children_.begin()) : -1;
	}

	// Sets the title of the node.
	virtual void SetTitle(const base::string16& title) { title_ = title; }

	// TreeModelNode:
	const base::string16& GetTitle() const override { return title_; }

	// Returns true if this == ancestor, or one of this nodes parents is
	// ancestor.
	bool HasAncestor(const NodeType* ancestor) const {
	if (ancestor == this)
	return true;
	if (!ancestor)
	return false;
	return parent_ ? parent_->HasAncestor(ancestor) : false;
	}

	protected:
	std::vector<std::unique_ptr<NodeType>>& children() { return children_; }

	private:
	// Title displayed in the tree.
	base::string16 title_;

	// This node's parent.
	NodeType* parent_;

	// This node's children.
	typename std::vector<std::unique_ptr<NodeType>> children_;

	DISALLOW_COPY_AND_ASSIGN(TreeNode);
	};

	// TreeNodeWithValue ----------------------------------------------------------

	// See top of file for documentation. Example:
	//
	// using MyNode = ui::TreeNodeWithValue<MyData>;
	// using MyModel = ui::TreeNodeModel<MyNode>;
	template <class ValueType>
	class TreeNodeWithValue : public TreeNode<TreeNodeWithValue<ValueType>> {
	public:
	TreeNodeWithValue() {}

	explicit TreeNodeWithValue(const ValueType& value)
	: ParentType(base::string16()), value(value) {}

	TreeNodeWithValue(const base::string16& title, const ValueType& value)
	: ParentType(title), value(value) {}

	ValueType value;

	private:
	using ParentType = TreeNode<TreeNodeWithValue<ValueType>>;

	DISALLOW_COPY_AND_ASSIGN(TreeNodeWithValue);
	};

	// TreeNodeModel --------------------------------------------------------------

	// TreeModel implementation intended to be used with TreeNodes.
	template <class NodeType>
	class TreeNodeModel : public TreeModel {
	public:
	// Creates a TreeNodeModel with the specified root node.
	explicit TreeNodeModel(std::unique_ptr<NodeType> root)
	: root_(std::move(root)) {}
	virtual ~TreeNodeModel() override {}

	NodeType* AsNode(TreeModelNode* model_node) {
	return static_cast<NodeType*>(model_node);
	}

	NodeType* Add(NodeType* parent, std::unique_ptr<NodeType> node, int index) {
	DCHECK(parent && node);
	NodeType* node_ptr = parent->Add(std::move(node), index);
	NotifyObserverTreeNodesAdded(parent, index, 1);
	return node_ptr;
	}

	std::unique_ptr<NodeType> Remove(NodeType* parent, int index) {
	DCHECK(parent);
	std::unique_ptr<NodeType> owned_node = parent->Remove(index);
	NotifyObserverTreeNodesRemoved(parent, index, 1);
	return owned_node;
	}

	std::unique_ptr<NodeType> Remove(NodeType* parent, NodeType* node) {
	DCHECK(parent);
	return Remove(parent, parent->GetIndexOf(node));
	}

	void NotifyObserverTreeNodesAdded(NodeType* parent, int start, int count) {
	for (TreeModelObserver& observer : observer_list_)
	observer.TreeNodesAdded(this, parent, start, count);
	}

	void NotifyObserverTreeNodesRemoved(NodeType* parent, int start, int count) {
	for (TreeModelObserver& observer : observer_list_)
	observer.TreeNodesRemoved(this, parent, start, count);
	}

	void NotifyObserverTreeNodeChanged(TreeModelNode* node) {
	for (TreeModelObserver& observer : observer_list_)
	observer.TreeNodeChanged(this, node);
	}

	// TreeModel:

	// C++ allows one to override a base class' virtual function with one that
	// returns a different type, as long as that type implements the base class'
	// return type. This is convenient because it allows callers with references
	// to the specific TreeNodeModel to get the proper return type without
	// casting.
	//
	// However, this does require that the NodeType be defined when this is
	// parsed (normally one could forward define this).
	NodeType* GetRoot() override {
	return root_.get();
	}

	int GetChildCount(TreeModelNode* parent) override {
	DCHECK(parent);
	return AsNode(parent)->child_count();
	}

	NodeType* GetChild(TreeModelNode* parent, int index) override {
	DCHECK(parent);
	return AsNode(parent)->GetChild(index);
	}

	int GetIndexOf(TreeModelNode* parent, TreeModelNode* child) override {
	DCHECK(parent);
	return AsNode(parent)->GetIndexOf(AsNode(child));
	}

	TreeModelNode* GetParent(TreeModelNode* node) override {
	DCHECK(node);
	return AsNode(node)->parent();
	}

	void AddObserver(TreeModelObserver* observer) override {
	observer_list_.AddObserver(observer);
	}

	void RemoveObserver(TreeModelObserver* observer) override {
	observer_list_.RemoveObserver(observer);
	}

	void SetTitle(TreeModelNode* node,
	const base::string16& title) override {
	DCHECK(node);
	AsNode(node)->SetTitle(title);
	NotifyObserverTreeNodeChanged(node);
	}

	private:
	// The observers.
	base::ObserverList<TreeModelObserver> observer_list_;

	// The root.
	std::unique_ptr<NodeType> root_;

	DISALLOW_COPY_AND_ASSIGN(TreeNodeModel);
	};

	} // namespace ui

	#endif // UI_BASE_MODELS_TREE_NODE_MODEL_H_