Tree: Difference between revisions

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[https://www.youtube.com/watch?v=qH6yxkw0u78  This video provides a basic introduction to trees. It also summarizes, very nicely, other data structures.] Please keep in mind the example at the beginning is not a [[binary tree]], but binary trees are discussed later.  Ignore the discussion about cousins and uncles. It's ridiculous. But the rest of the video is really good.
[https://www.youtube.com/watch?v=qH6yxkw0u78  This video provides a basic introduction to trees. It also summarizes, very nicely, other data structures.] Please keep in mind the example at the beginning is not a [[binary tree]], but binary trees are discussed later.  Ignore the discussion about cousins and uncles. It's ridiculous. But the rest of the video is really good.
== code sample ==
<syntaxhighlight lang="python">
class Node:
    def __init__(self, data):
        self.data = data
        self.children = []
    def add_child(self, child):
        self.children.append(child)
    def __repr__(self):
        return f"Node({self.data})"
class Tree:
    def __init__(self, root_data):
        self.root = Node(root_data)
    def add_node(self, parent_data, child_data):
        parent_node = self.find_node(parent_data)
        if parent_node:
            parent_node.add_child(Node(child_data))
        else:
            print(f"Parent node with data '{parent_data}' not found.")
    def find_node(self, target_data, current_node=None):
        if current_node is None:
            current_node = self.root
        if current_node.data == target_data:
            return current_node
        for child in current_node.children:
            result = self.find_node(target_data, child)
            if result:
                return result
        return None
    def display(self, current_node=None, level=0):
        if current_node is None:
            current_node = self.root
        print(' ' * 4 * level + '|-- ' + str(current_node.data))
        for child in current_node.children:
            self.display(child, level + 1)
    def __repr__(self):
        return f"Tree({self.root})"
# Create a tree with root node data 'A'
tree = Tree('A')
# Add nodes to the tree
tree.add_node('A', 'B')
tree.add_node('A', 'C')
tree.add_node('B', 'D')
tree.add_node('B', 'E')
tree.add_node('C', 'F')
tree.add_node('C', 'G')
# Find a node in the tree
found_node = tree.find_node('F')
print(found_node)  # Output: Node(F)
# Try to add a node with a nonexistent parent
tree.add_node('X', 'Y')  # Output: Parent node with data 'X' not found.
# Display the tree using simple ASCII art
tree.display()
</syntaxhighlight>


== Standards ==  
== Standards ==  

Latest revision as of 06:28, 26 April 2023

Programming basics[1]

In computer science, a tree is a widely used abstract data type (ADT)—or data structure implementing this ADT—that simulates a hierarchical tree structure, with a root value and subtrees of children with a parent node, represented as a set of linked nodes.

A tree data structure can be defined recursively (locally) as a collection of nodes (starting at a root node), where each node is a data structure consisting of a value, together with a list of references to nodes (the "children"), with the constraints that no reference is duplicated, and none points to the root.[2]


Image of a tree[edit]

Binary tree.svg.png

tree vocabulary[edit]

  • root node
  • parent node
  • child node
  • leaf node

Practical applications of a tree[edit]

  • Trees can be used to store data that has an inherent hierarchical structure. For example, an operating system may use a tree for directories, files and folders in its file management system.
  • They are dynamic, which means that it is easy to add and delete nodes.
  • They are easy to search and sort using standard traversal algorithms.
  • They can be used to process the syntax of statements in natural and programming languages so are commonly used when compiling programming code.

Tree - video example[edit]

This video provides a basic introduction to trees. It also summarizes, very nicely, other data structures. Please keep in mind the example at the beginning is not a binary tree, but binary trees are discussed later. Ignore the discussion about cousins and uncles. It's ridiculous. But the rest of the video is really good.


code sample[edit]

class Node:
    def __init__(self, data):
        self.data = data
        self.children = []

    def add_child(self, child):
        self.children.append(child)

    def __repr__(self):
        return f"Node({self.data})"

class Tree:
    def __init__(self, root_data):
        self.root = Node(root_data)

    def add_node(self, parent_data, child_data):
        parent_node = self.find_node(parent_data)
        if parent_node:
            parent_node.add_child(Node(child_data))
        else:
            print(f"Parent node with data '{parent_data}' not found.")

    def find_node(self, target_data, current_node=None):
        if current_node is None:
            current_node = self.root

        if current_node.data == target_data:
            return current_node

        for child in current_node.children:
            result = self.find_node(target_data, child)
            if result:
                return result

        return None

    def display(self, current_node=None, level=0):
        if current_node is None:
            current_node = self.root

        print(' ' * 4 * level + '|-- ' + str(current_node.data))
        for child in current_node.children:
            self.display(child, level + 1)



    def __repr__(self):
        return f"Tree({self.root})"

# Create a tree with root node data 'A'
tree = Tree('A')

# Add nodes to the tree
tree.add_node('A', 'B')
tree.add_node('A', 'C')
tree.add_node('B', 'D')
tree.add_node('B', 'E')
tree.add_node('C', 'F')
tree.add_node('C', 'G')

# Find a node in the tree
found_node = tree.find_node('F')
print(found_node)  # Output: Node(F)

# Try to add a node with a nonexistent parent
tree.add_node('X', 'Y')  # Output: Parent node with data 'X' not found.

# Display the tree using simple ASCII art
tree.display()

Standards[edit]

  • Describe how trees operate logically (both binary and non-binary).
  • Define the terms: parent, left-child, right-child, subtree, root and leaf.
  • State the result of inorder, postorder and preorder tree traversal.
  • Sketch binary trees.

See Also[edit]

External Links[edit]

high level discussion of binary trees

References[edit]