怎么在python中利用递归建立二叉树-创新互联
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专注于为中小企业提供网站建设、成都网站建设服务,电脑端+手机端+微信端的三站合一,更高效的管理,为中小企业陆良免费做网站提供优质的服务。我们立足成都,凝聚了一批互联网行业人才,有力地推动了上1000家企业的稳健成长,帮助中小企业通过网站建设实现规模扩充和转变。# coding = utf-8 class BinaryTree: def __init__(self, root_obj): self.key = root_obj self.left_child = None self.right_child = None def insert_left(self, new_node): node = BinaryTree(new_node) if self.left_child is None: self.left_child = node else: node.left_child = self.left_child self.left_child = node def insert_right(self, new_node): node = BinaryTree(new_node) if self.right_child is None: self.right_child = node else: node.right_child = self.right_child self.right_child = node def get_right_child(self): return self.right_child def get_left_child(self): return self.left_child def set_root_val(self, obj): self.key = obj def get_root_val(self): return self.key root = BinaryTree('a') print(root.get_root_val()) print(root.get_left_child()) root.insert_left('b') print(root.get_left_child()) print(root.get_left_child().get_root_val()) root.insert_right('c') print(root.get_right_child()) print(root.get_right_child().get_root_val()) root.get_right_child().set_root_val('hello') print(root.get_right_child().get_root_val())
C:\Users\Sahara\.virtualenvs\test\Scripts\python.exe C:/Users/Sahara/PycharmProjects/test/python_search.py a None <__main__.BinaryTree object at 0x00000000024139B0> b <__main__.BinaryTree object at 0x00000000024139E8> c hello Process finished with exit code 0
Python实现二叉树遍历的递归和非递归算法
前序遍历
# -----------前序遍历 ------------ # 递归算法 def pre_order_recursive(self, T): if T == None: return print(T.root, end=' ') self.pre_order_recursive(T.lchild) self.pre_order_recursive(T.rchild) # 非递归算法 def pre_order_non_recursive(self, T): """借助栈实现前驱遍历 """ if T == None: return stack = [] while T or len(stack) > 0: if T: stack.append(T) print(T.root, end=' ') T = T.lchild else: T = stack[-1] stack.pop() T = T.rchild
中序遍历
# -----------中序遍历 ------------ # 递归算法 def mid_order_recursive(self, T): if T == None: return self.mid_order_recursive(T.lchild) print(T.root, end=' ') self.mid_order_recursive(T.rchild) # 非递归算法 def mid_order_non_recursive(self, T): """借助栈实现中序遍历 """ if T == None: return stack = [] while T or len(stack) > 0: if T: stack.append(T) T = T.lchild else: T = stack.pop() print(T.root, end=' ') T = T.rchild
后序遍历
# -----------后序遍历 ------------ # 递归算法 def post_order_recursive(self, T): if T == None: return self.post_order_recursive(T.lchild) self.post_order_recursive(T.rchild) print(T.root, end=' ') # 非递归算法 def post_order_non_recursive(self, T): """借助两个栈实现后序遍历 """ if T == None: return stack1 = [] stack2 = [] stack1.append(T) while stack1: node = stack1.pop() if node.lchild: stack1.append(node.lchild) if node.rchild: stack1.append(node.rchild) stack2.append(node) while stack2: print(stack2.pop().root, end=' ') return
层次遍历
# -----------层次遍历 ------------ def level_order(self, T): """借助队列(其实还是一个栈)实现层次遍历 """ if T == None: return stack = [] stack.append(T) while stack: node = stack.pop(0) # 实现先进先出 print(node.root, end=' ') if node.lchild: stack.append(node.lchild) if node.rchild: stack.append(node.rchild)
完整代码
class NodeTree: def __init__(self, root=None, lchild=None, rchild=None): """创建二叉树 Argument: lchild: BinTree 左子树 rchild: BinTree 右子树 Return: Tree """ self.root = root self.lchild = lchild self.rchild = rchild class BinTree: # -----------前序遍历 ------------ # 递归算法 def pre_order_recursive(self, T): if T == None: return print(T.root, end=' ') self.pre_order_recursive(T.lchild) self.pre_order_recursive(T.rchild) # 非递归算法 def pre_order_non_recursive(self, T): """借助栈实现前驱遍历 """ if T == None: return stack = [] while T or len(stack) > 0: if T: stack.append(T) print(T.root, end=' ') T = T.lchild else: T = stack[-1] stack.pop() T = T.rchild # -----------中序遍历 ------------ # 递归算法 def mid_order_recursive(self, T): if T == None: return self.mid_order_recursive(T.lchild) print(T.root, end=' ') self.mid_order_recursive(T.rchild) # 非递归算法 def mid_order_non_recursive(self, T): """借助栈实现中序遍历 """ if T == None: return stack = [] while T or len(stack) > 0: if T: stack.append(T) T = T.lchild else: T = stack.pop() print(T.root, end=' ') T = T.rchild # -----------后序遍历 ------------ # 递归算法 def post_order_recursive(self, T): if T == None: return self.post_order_recursive(T.lchild) self.post_order_recursive(T.rchild) print(T.root, end=' ') # 非递归算法 def post_order_non_recursive(self, T): """借助两个栈实现后序遍历 """ if T == None: return stack1 = [] stack2 = [] stack1.append(T) while stack1: node = stack1.pop() if node.lchild: stack1.append(node.lchild) if node.rchild: stack1.append(node.rchild) stack2.append(node) while stack2: print(stack2.pop().root, end=' ') return # -----------层次遍历 ------------ def level_order(self, T): """借助队列(其实还是一个栈)实现层次遍历 """ if T == None: return stack = [] stack.append(T) while stack: node = stack.pop(0) # 实现先进先出 print(node.root, end=' ') if node.lchild: stack.append(node.lchild) if node.rchild: stack.append(node.rchild) # ----------- 前序遍历序列、中序遍历序列 —> 重构二叉树 ------------ def tree_by_pre_mid(self, pre, mid): if len(pre) != len(mid) or len(pre) == 0 or len(mid) == 0: return T = NodeTree(pre[0]) index = mid.index(pre[0]) T.lchild = self.tree_by_pre_mid(pre[1:index + 1], mid[:index]) T.rchild = self.tree_by_pre_mid(pre[index + 1:], mid[index + 1:]) return T # ----------- 后序遍历序列、中序遍历序列 —> 重构二叉树 ------------ def tree_by_post_mid(self, post, mid): if len(post) != len(mid) or len(post) == 0 or len(mid) == 0: return T = NodeTree(post[-1]) index = mid.index(post[-1]) T.lchild = self.tree_by_post_mid(post[:index], mid[:index]) T.rchild = self.tree_by_post_mid(post[index:-1], mid[index + 1:]) return T if __name__ == '__main__': # ----------- 测试:前序、中序、后序、层次遍历 ----------- # 创建二叉树 nodeTree = NodeTree(1, lchild=NodeTree(2, lchild=NodeTree(4, rchild=NodeTree(7))), rchild=NodeTree(3, lchild=NodeTree(5), rchild=NodeTree(6))) T = BinTree() print('前序遍历递归\t') T.pre_order_recursive(nodeTree) # 前序遍历-递归 print('\n') print('前序遍历非递归\t') T.pre_order_non_recursive(nodeTree) # 前序遍历-非递归 print('\n') print('中序遍历递归\t') T.mid_order_recursive(nodeTree) # 中序遍历-递归 print('\n') print('中序遍历非递归\t') T.mid_order_non_recursive(nodeTree) # 中序遍历-非递归 print('\n') print('后序遍历递归\t') T.post_order_recursive(nodeTree) # 后序遍历-递归 print('\n') print('后序遍历非递归\t') T.post_order_non_recursive(nodeTree) # 后序遍历-非递归 print('\n') print('层次遍历\t') T.level_order(nodeTree) # 层次遍历 print('\n') print('==========================================================================') # ----------- 测试:由遍历序列构造二叉树 ----------- T = BinTree() pre = ['A', 'B', 'C', 'D', 'E', 'F', 'G', 'H', 'I'] mid = ['B', 'C', 'A', 'E', 'D', 'G', 'H', 'F', 'I'] post = ['C', 'B', 'E', 'H', 'G', 'I', 'F', 'D', 'A'] newT_pre_mid = T.tree_by_pre_mid(pre, mid) # 由前序序列、中序序列构造二叉树 T.post_order_recursive(newT_pre_mid) # 获取后序序列 print('\n') newT_post_mid = T.tree_by_post_mid(post, mid) # 由后序序列、中序序列构造二叉树 T.pre_order_recursive(newT_post_mid) # 获取前序序列
运行结果
前序遍历递归
1 2 4 7 3 5 6前序遍历非递归
1 2 4 7 3 5 6中序遍历递归
4 7 2 1 5 3 6中序遍历非递归
4 7 2 1 5 3 6后序遍历递归
7 4 2 5 6 3 1后序遍历非递归
7 4 2 5 6 3 1层次遍历
1 2 3 4 5 6 7==========================================================================
C B E H G I F D AA B C D E F G H I
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