def test_construct():
seq1 = [1, 2, 4, 7, 3, 5, 6, 8]
seq2 = [4, 7, 2, 1, 5, 3, 8, 6]
btree = construct(seq1, seq2)
print('*', btree)
tmp = BinTree()
tmp.preorder_trav(btree)
def test_find_path():
btree = BinTree()
btree.add(10)
btree.add(5)
btree.add(12)
btree.add(4)
btree.add(7)
find_path(btree.root, 22)
find_path(btree.root, 17)
def construct_core(preorder, start_preorder, end_preorder, inorder,
start_inorder, end_inorder):
"""
先根据前序遍历序列的第一个数字创建根结点,接下来在中序遍历序列中找到根结点的位置,
这样就能确定左、右子树结点的数量。在前序遍历和中序遍历的序列中划分了左、右子树结
点的值之后,就可以递归地去分别构建它的左右子树。
:param preorder:
:param start_preorder:
:param end_preorder:
:param inorder:
:param start_inorder:
:param end_inorder:
:return:
"""
# 前序遍历的第一个数字是根结点的值
root_value = preorder[start_preorder]
root = BinTree(root=root_value)
root.left = root.right = None
root.data = root.root
if start_preorder == end_preorder:
if start_inorder == end_inorder and inorder[start_inorder] == inorder[
end_inorder]:
return root
else:
raise Exception("错误的输入")
# 在中序遍历中找到根结点的值
root_inorder = start_inorder
while root_inorder <= end_inorder and inorder[root_inorder] != root_value:
root_inorder += 1
# 如果两个序列不匹配
if root_inorder == end_inorder and inorder[root_inorder] != root_value:
raise Exception("两个序列不匹配!", root_value, inorder[root_value])
left_length = root_inorder - start_inorder
left_preorder_end = start_preorder + left_length
# 构建左子树
if left_length > 0:
root.left = construct_core(preorder, start_preorder + 1,
left_preorder_end, inorder, start_inorder,
root_inorder - 1)
# 构建右子树
if left_length < end_preorder - start_preorder:
# root.right = construct_core(preorder, left_preorder_end + 1, end_preorder, inorder, root_inorder + 1,
# end_inorder)
root.right = construct_core(preorder, left_preorder_end + 1,
end_preorder, inorder, root_inorder + 1,
end_inorder)
return root
def test_has_subtree():
node_list = [
{
'data': 'A',
'left': 'B',
'right': 'C',
'is_root': True
},
{
'data': 'B',
'left': 'D',
'right': 'E',
'is_root': False
},
{
'data': 'D',
'left': None,
'right': None,
'is_root': False
},
{
'data': 'E',
'left': 'H',
'right': None,
'is_root': False
},
{
'data': 'H',
'left': None,
'right': None,
'is_root': False
},
{
'data': 'C',
'left': 'F',
'right': 'G',
'is_root': False
},
{
'data': 'F',
'left': None,
'right': None,
'is_root': False
},
{
'data': 'G',
'left': 'I',
'right': 'J',
'is_root': False
},
{
'data': 'I',
'left': None,
'right': None,
'is_root': False
},
{
'data': 'J',
'left': None,
'right': None,
'is_root': False
},
]
btree1 = BinTree.build_from(node_list)
node_list2 = [
{
'data': 'A',
'left': 'B',
'right': 'D',
'is_root': True
},
{
'data': 'B',
'left': None,
'right': None,
'is_root': False
},
{
'data': 'D',
'left': None,
'right': None,
'is_root': False
},
]
btree2 = BinTree.build_from(node_list2)
print(has_subtree(btree1.root, btree2.root))
"""
Author: Novanator 2012
Program: Translation3
"""
import random
from btree import Node
from btree import BinTree
file = open ("list.txt", "r")
contents = file.read ()
words = contents.split ()
random.shuffle(words)
tree=BinTree()
for i in words:
tree.put(i)
l=[]
for x in words:
if tree.exists(x[::-1]) and x not in l:
l.append(x)
l2=[]
for x in l:
if x not in l2:
l2.append(x)
l2.append(x[::-1])
for i in range (0,len(l2),2):
def test_print_from_top_to_bottom():
# 空树
btree = BinTree()
print_from_top_to_bottom(btree.root)
# 单结点树
btree = BinTree()
btree.add(8)
print_from_top_to_bottom(btree.root)
# 多结点树
btree = BinTree()
btree.add(8)
btree.add(6)
btree.add(10)
btree.add(5)
btree.add(7)
btree.add(9)
# btree.add(11)
print_from_top_to_bottom(btree.root)
if (lista[0] + x + lista[2]) == endword:
writeChain(b)
return True
if (lista[0] + lista[1] + x) == endword:
writeChain(c)
return True
return False
endword = input("Write the end word:")
f = open("list.txt", "r")
contents = f.read()
words = contents.split()
tree = BinTree()
for i in words:
tree.put(i)
random.shuffle(words)
letter = [
"a", "b", "c", "d", "e", "f", "g", "h", "i", "j", "k", "l", "m", "n", "o",
"p", "q", "r", "s", "t", "u", "v", "x", "y", "z", "å", "ä", "ö"
]
plista = []
for x in words:
klist = []
oldwords = BinTree()
q = Queue()
def test_convert():
btree = BinTree()
btree.add(10)
btree.add(6)
btree.add(14)
btree.add(4)
btree.add(8)
btree.add(12)
btree.add(16)
convert(btree.root)
"""
Author: Novanator 2012
Program: Translation3
"""
import random
from btree import Node
from btree import BinTree
file = open("list.txt", "r")
contents = file.read()
words = contents.split()
random.shuffle(words)
tree = BinTree()
for i in words:
tree.put(i)
l = []
for x in words:
if tree.exists(x[::-1]) and x not in l:
l.append(x)
l2 = []
for x in l:
if x not in l2:
l2.append(x)
l2.append(x[::-1])
for i in range(0, len(l2), 2):
def test_mirror_use_stack():
# 空结点树
tree = BinTree()
print(mirror_use_stack(tree.root))
# 一个结点的树
tree = BinTree()
tree.add('A')
mirror_use_stack(tree.root)
tree.preorder_trav(tree.root)
# 多结点树
tree = BinTree()
tree.add('A')
tree.add('B')
tree.add('C')
tree.add('D')
tree.add('E')
tree.add('F')
tree.add('G')
print("-------------------镜像前-------------------")
tree.preorder_trav(tree.root)
mirror_use_stack(tree.root)
print("-------------------镜像后-------------------")
tree.preorder_trav(tree.root)
if (lista[0]+x+lista[2])==endword:
writeChain(b)
return True
if (lista[0]+lista[1]+x)==endword:
writeChain(c)
return True
return False
endword = input("Write the end word:" )
f=open("list.txt","r")
contents = f.read ()
words = contents.split ()
tree=BinTree()
for i in words:
tree.put(i)
random.shuffle(words)
letter=["a","b","c","d","e","f","g","h","i","j","k","l","m","n","o","p","q","r","s","t","u","v","x","y","z","å","ä","ö"]
plista=[]
for x in words:
klist=[]
oldwords=BinTree()
q=Queue()
startword = Nodeson(x)
q.put(startword)
