本篇文章给大家带来的内容是关于Python实现二叉树的算法实例,有一定的参考价值,有需要的朋友可以参考一下,希望对你有所帮助。
节点定义
class Node(object):
def __init__(self, left_child, right_child, value):
self._left_child = left_child
self._right_child = right_child
self._value = value
@property
def left_child(self):
return self._left_child
@property
def right_child(self):
return self._right_child
@left_child.setter
def left_child(self, value):
self._left_child = value
@right_child.setter
def right_child(self, value):
self._right_child = value
@property
def value(self):
return self._value
@value.setter
def value(self, value):
self._value = valueclass Tree(object):
def __init__(self, value):
self._root = Node(None, None, value=value)
@property
def root(self):
return self._root'''
先序遍历,递归方式
'''
def preoder(root):
if not isinstance(root, Node):
return None
preorder_res = []
if root:
preorder_res.append(root.value)
preorder_res += preoder(root.left_child)
preorder_res += preoder(root.right_child)
return preorder_res'''
先序遍历,非递归方式
'''
def pre_order_not_recursion(root):
if not isinstance(root, Node):
return None
stack = [root]
result = []
while stack:
node = stack.pop(-1)
if node:
result.append(node.value)
stack.append(node.right_child)
stack.append(node.left_child)
return result'''
中序遍历,递归方式
'''
def middle_order(root):
if not isinstance(root, Node):
return None
middle_res = []
if root:
middle_res += middle_order(root.left_child)
middle_res.append(root.value)
middle_res += middle_order(root.right_child)
return middle_res'''
中序遍历,非递归方式
'''
def middle_order_bot_recursion(root):
if not isinstance(root, Node):
return None
result = []
stack = [root.right_child, root.value, root.left_child]
while stack:
temp = stack.pop(-1)
if temp:
if isinstance(temp, Node):
stack.append(temp.right_child)
stack.append(temp.value)
stack.append(temp.left_child)
else:
result.append(temp)
return result'''
后序遍历,递归方式
'''
def post_order(root):
if not isinstance(root, Node):
return None
post_res = []
if root:
post_res += post_order(root.left_child)
post_res += post_order(root.right_child)
post_res.append(root.value)
return post_res'''
后序遍历,非递归方式
'''
def post_order_not_recursion(root):
if not isinstance(root, Node):
return None
stack = [root.value, root.right_child, root.left_child]
result = []
while stack:
temp_node = stack.pop(-1)
if temp_node:
if isinstance(temp_node, Node):
stack.append(temp_node.value)
stack.append(temp_node.right_child)
stack.append(temp_node.left_child)
else:
result.append(temp_node)
return result'''
分层遍历,使用队列实现
'''
def layer_order(root):
if not isinstance(root, Node):
return None
queue = [root.value, root.left_child, root.right_child]
result = []
while queue:
temp = queue.pop(0)
if temp:
if isinstance(temp, Node):
queue.append(temp.value)
queue.append(temp.left_child)
queue.append(temp.right_child)
else:
result.append(temp)
return result'''
计算二叉树结点个数,递归方式
NodeCount(root) = NodeCount(root.left_child) + NodeCount(root.right_child)
'''
def node_count(root):
if root and not isinstance(root, Node):
return None
if root:
return node_count(root.left_child) + node_count(root.right_child) + 1
else:
return 0
'''
计算二叉树结点个数,非递归方式
借用分层遍历计算
'''
def node_count_not_recursion(root):
if root and not isinstance(root, Node):
return None
return len(layer_order(root))'''
计算二叉树深度,递归方式
tree_deep(root) = 1 + max(tree_deep(root.left_child), tree_deep(root.right_child))
'''
def tree_deep(root):
if root and not isinstance(root, Node):
return None
if root:
return 1 + max(tree_deep(root.left_child), tree_deep(root.right_child))
else:
return 0
'''
计算二叉树深度,非递归方法
同理参考分层遍历的思想
'''
def tree_deep_not_recursion(root):
if root and not isinstance(root, Node):
return None
result = 0
queue = [(root, 1)]
while queue:
temp_node, temp_layer = queue.pop(0)
if temp_node:
queue.append((temp_node.left_child, temp_layer+1))
queue.append((temp_node.right_child, temp_layer+1))
result = temp_layer + 1
return result-1'''
计算二叉树第k层节点个数,递归方式
kth_node_count(root, k) = kth_node_count(root.left_count, k-1) + kth_node_count(root.right_count, k-1)
'''
def kth_node_count(root, k):
if root and not isinstance(root, Node):
return None
if not root or k <= 0:
return 0
if k == 1:
return 1
return kth_node_count(root.left_child, k-1) + kth_node_count(root.right_child, k-1)
'''
计算二叉树第K层节点个数,非递归方式
'''
def kth_node_count_not_recursion(root, k):
if root and not isinstance(root, Node):
return None
if not root or k <= 0:
return 0
if k == 1:
return 1
queue = [(root, 1)]
result = 0
while queue:
temp_node, temp_layer = queue.pop(0)
if temp_node:
if temp_layer == k:
result += 1
elif temp_layer > k:
return result
else:
queue.append((temp_node.left_child, temp_layer+1))
queue.append((temp_node.right_child, temp_layer+1))
return result'''
计算二叉树叶子节点个数,递归方式
关键点是叶子节点的判断标准,左右孩子皆为None
'''
def leaf_count(root):
if root and not isinstance(root, Node):
return None
if not root:
return 0
if not root.left_child and not root.right_child:
return 1
return leaf_count(root.left_child) + leaf_count(root.right_child)'''
判断两个二叉树是不是相同,递归方式
isSame(root1, root2) = (root1.value == root2.value)
and isSame(root1.left, root2.left)
and isSame(root1.right, root2.right)
'''
def is_same_tree(root1, root2):
if not root1 and not root2:
return True
if root1 and root2:
return (root1.value == root2.value) and \
is_same_tree(root1.left_child, root2.left_child) and \
is_same_tree(root1.right_child, root2.right_child)
else:
return False'''
判断是否为二分查找树BST,递归方式
二分查找树的定义搞清楚,二分查找树的中序遍历结果为递增序列
'''
def is_bst_tree(root):
if root and not isinstance(root, Node):
return None
def is_asc(order):
for i in range(len(order)-1):
if order[i] > order[i+1]:
return False
return True
return is_asc(middle_order_bot_recursion(root))if __name__ == "__main__":
tree = Tree(1)
tree1 = Tree(1)
node6 = Node(None, None, 7)
node5 = Node(None, None, 6)
node4 = Node(None, None, 5)
node3 = Node(None, None, 4)
node2 = Node(node5, node6, 3)
node1 = Node(node3, node4, 2)
tree.root.left_child = node1
tree.root.right_child = node2
tree1.root.left_child = node2
tree1.root.right_child = node2
print(is_bst_tree(tree.root))以上就是Python实现二叉树的算法实例的详细内容,更多请关注php中文网其它相关文章!
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