Binarytree: Python Library for Studying Binary Trees
Introduction
Are you studying binary trees for your next exam, assignment or technical interview?
Binarytree is a Python library which provides a simple API to generate, visualize, inspect and manipulate binary trees. It allows you to skip the tedious work of setting up test data, and dive straight into practising your algorithms. Heaps and BSTs (binary search trees) are also supported.
Announcements
Requirements
- Python 2.7, 3.4, 3.5 or 3.6.
Installation
To install a stable version from PyPi:
~$ pip install binarytreeTo install the latest version directly from GitHub:
~$ pip install -e [email protected]:joowani/binarytree.git@master#egg=binarytreeYou may need to use sudo depending on your environment.
Getting Started
By default, binarytree uses the following class to represent a node:
class Node(object):
def __init__(self, value, left=None, right=None):
self.value = value # The node value
self.left = left # Left child
self.right = right # Right childGenerate and pretty-print various types of binary trees:
>>> from binarytree import tree, bst, heap
>>>
>>> # Generate a random binary tree and return its root node
>>> my_tree = tree(height=3, is_perfect=False)
>>>
>>> # Generate a random BST and return its root node
>>> my_bst = bst(height=3, is_perfect=True)
>>>
>>> # Generate a random max heap and return its root node
>>> my_heap = heap(height=3, is_max=True, is_perfect=False)
>>>
>>> # Pretty-print the trees in stdout
>>> print(my_tree)
#
# _______1_____
# / \
# 4__ ___3
# / \ / \
# 0 9 13 14
# / \ \
# 7 10 2
#
>>> print(my_bst)
#
# ______7_______
# / \
# __3__ ___11___
# / \ / \
# 1 5 9 _13
# / \ / \ / \ / \
# 0 2 4 6 8 10 12 14
#
>>> print(my_heap)
#
# _____14__
# / \
# ____13__ 9
# / \ / \
# 12 7 3 8
# / \ /
# 0 10 6
#Use the binarytree.Node class to build your own trees:
>>> from binarytree import Node
>>>
>>> root = Node(1)
>>> root.left = Node(2)
>>> root.right = Node(3)
>>> root.left.right = Node(4)
>>>
>>> print(root)
#
# __1
# / \
# 2 3
# \
# 4
#Inspect tree properties:
>>> from binarytree import Node
>>>
>>> root = Node(1)
>>> root.left = Node(2)
>>> root.right = Node(3)
>>> root.left.left = Node(4)
>>> root.left.right = Node(5)
>>>
>>> print(root)
#
# __1
# / \
# 2 3
# / \
# 4 5
#
>>> root.height
2
>>> root.is_balanced
True
>>> root.is_bst
False
>>> root.is_complete
True
>>> root.is_max_heap
False
>>> root.is_min_heap
True
>>> root.is_perfect
False
>>> root.is_strict
True
>>> root.leaf_count
3
>>> root.max_leaf_depth
2
>>> root.max_node_value
5
>>> root.min_leaf_depth
1
>>> root.min_node_value
1
>>> root.size
5
>>> root.properties # To see all at once:
{'height': 2,
'is_balanced': True,
'is_bst': False,
'is_complete': True,
'is_max_heap': False,
'is_min_heap': True,
'is_perfect': False,
'is_strict': True,
'leaf_count': 3,
'max_leaf_depth': 2,
'max_node_value': 5,
'min_leaf_depth': 1,
'min_node_value': 1,
'size': 5}
>>> root.leaves
[Node(3), Node(4), Node(5)]
>>> root.levels
[[Node(1)], [Node(2), Node(3)], [Node(4), Node(5)]]Use level-order (breadth-first) indexes to manipulate nodes:
>>> from binarytree import Node
>>>
>>> root = Node(1) # index: 0, value: 1
>>> root.left = Node(2) # index: 1, value: 2
>>> root.right = Node(3) # index: 2, value: 3
>>> root.left.right = Node(4) # index: 4, value: 4
>>> root.left.right.left = Node(5) # index: 9, value: 5
>>>
>>> print(root)
#
# ____1
# / \
# 2__ 3
# \
# 4
# /
# 5
#
>>> # Use binarytree.Node.pprint instead of print to display indexes
>>> root.pprint(index=True)
#
# _________0-1_
# / \
# 1-2_____ 2-3
# \
# _4-4
# /
# 9-5
#
>>> # Return the node/subtree at index 9
>>> root[9]
Node(5)
>>> # Replace the node/subtree at index 4
>>> root[4] = Node(6, left=Node(7), right=Node(8))
>>> root.pprint(index=True)
#
# ______________0-1_
# / \
# 1-2_____ 2-3
# \
# _4-6_
# / \
# 9-7 10-8
#
>>> # Delete the node/subtree at index 1
>>> del root[1]
>>> root.pprint(index=True)
#
# 0-1_
# \
# 2-3Traverse the trees using different algorithms:
>>> from binarytree import Node
>>>
>>> root = Node(1)
>>> root.left = Node(2)
>>> root.right = Node(3)
>>> root.left.left = Node(4)
>>> root.left.right = Node(5)
>>>
>>> print(root)
#
# __1
# / \
# 2 3
# / \
# 4 5
#
>>> root.inorder
[Node(4), Node(2), Node(5), Node(1), Node(3)]
>>> root.preorder
[Node(1), Node(2), Node(4), Node(5), Node(3)]
>>> root.postorder
[Node(4), Node(5), Node(2), Node(3), Node(1)]
>>> root.levelorder
[Node(1), Node(2), Node(3), Node(4), Node(5)]
>>> list(root) # Equivalent to root.levelorder
[Node(1), Node(2), Node(3), Node(4), Node(5)]List representations are also supported:
>>> from binarytree import build
>>>
>>> # Build a tree from list representation
>>> values = [7, 3, 2, 6, 9, None, 1, 5, 8]
>>> root = build(values)
>>> print(root)
#
# __7
# / \
# __3 2
# / \ \
# 6 9 1
# / \
# 5 8
#
>>> # Convert the tree back to list representation
>>> root.values
[7, 3, 2, 6, 9, None, 1, 5, 8]Check out the documentation for more details!
Contributing
Please have a look at this page before submitting a pull request. Thanks!
React
Typescript
Django
Laravel
Facebook
Microsoft
Google
Alibaba
D3
Tencent