def main():
linknode1 = LinkedNode()
value_list = np.sort(np.random.randint(1, 7, 6))
for i in value_list:
node = Node(i)
linknode1.add(node)
print('The LinkedNode1 is: ' + linknode1.__str__())
linknode2 = LinkedNode()
value_list = np.sort(np.random.randint(1, 10, 6))
for i in value_list:
node = Node(i)
linknode2.add(node)
print('The LinkedNode2 is: ' + linknode2.__str__())
linknode3 = Solution_25()
result = linknode3.merge(linknode1.head, linknode2.head)
print('After merge the two LinkedNode:')
while result.next is not None:
print(result.data, end=', ')
result = result.next
print(result.data, end=', ')
def test_insert():
list = LinkedNode(10)
list += 30
list += 40
list += 50
assert repr(list) == '10'
assert repr(list.next_node.key) == '30'
assert print_list(list) == '10, 30, 40, 50'
def main():
linkedtable = LinkedNode()
for i in np.random.randint(2, 15, 10).tolist():
node = Node(i)
linkedtable.add(node)
print('The linked node before modified is: ' + linkedtable.__str__())
delete_duplication(linkedtable)
print('The linked node after modified is: ' + linkedtable.__str__())
def main():
ls1 = [1, 2, 3, 4, 5, 6, 7, 8]
# ls2 = [0, 5, 6, 7, 8]
ls2 = [9, 10, 11, 12]
# 创建链表
link1 = LinkedNode()
link2 = LinkedNode()
for i in ls1:
link1.add(i)
for j in ls2:
link2.add(j)
# print(link2.listofnode())
commom_node = Solution_52().find_first_common_node(link1.head, link2.head)
if commom_node:
print('Two list node\'s commom node are %d.' % commom_node.data)
else:
print('Two list node have not commom node.')
def main():
linknode = LinkedNode()
value_list = np.random.randint(1, 7, 6).tolist()
for i in value_list:
node = Node(i)
linknode.add(node)
print('The LinkedNode is: ' + linknode.__str__())
k = value_list[np.random.randint(1, 6)]
print('The number to be deleted is: ' + str(k))
outputnode = Solution_22()
outputnode.output_k_node_in_linkednode(linknode, k)
def main():
linkedtable = LinkedNode()
for i in np.random.randint(2, 15, 10).tolist():
node = Node(i)
linkedtable.add(node)
print('The linked node before modified is: ' + linkedtable.__str__())
listofnode = linkedtable.listofnode()
print('The list of node is: ', listofnode)
tobedeletednode = listofnode[9]
deletenode(linkedtable, tobedeletednode)
# print('The value of node to be deleted is %d, and the value of the next closing node is %s' % (tobedeletednode.data, tobedeletednode.next.data))
print('The linked node after modified is: ' + linkedtable.__str__())
def test_delete():
list = LinkedNode(10)
list += 20
list += 30
list += 40
list = delete_item(list, 30)
assert print_list(list) == '10, 20, 40'
list = delete_item(list, 10)
assert print_list(list) == '20, 40'
list = delete_item(list, 50)
assert print_list(list) == '20, 40'
list = delete_item(list, 40)
assert print_list(list) == '20'
list = delete_item(list, 20)
assert type(list) == NoneType
def main():
linknode = LinkedNode()
value_list = np.random.randint(1, 7, 6).tolist()
for i in value_list:
node = Node(i)
linknode.add(node)
print('The LinkedNode is: ' + linknode.__str__())
reverselinkednode = Solution_24()
reversenode = reverselinkednode.reverse_linkednode(linknode.head)
reversehead = reversenode
while reversehead.next is not None:
print(reversehead.data, end=', ')
reversehead = reversehead.next
print(reversehead.data, end=', ')
def test_create_empty():
list = LinkedNode(10)
assert list.key == 10
def parse(data):
initNode = None
prevNode = None
curNode = None
lowerBound = {}
upperBound = {}
y_min = [float("inf") for _ in range(len(data[2].strip().split()))]
y_max = [float("-inf") for _ in range(len(data[2].strip().split()))]
for line in data:
# This is a mode indicator
if ',' in line or '->' in line or line.strip().isalpha() or len(
line.strip()) == 1:
insertData(curNode, lowerBound, upperBound)
# There is new a transition
if '->' in line:
modeList = line.strip().split('->')
prevNode = initNode
for i in range(1, len(modeList) - 1):
prevNode = prevNode.child[modeList[i]]
curNode = prevNode.child.setdefault(
modeList[-1], LinkedNode(modeList[-1], line))
else:
curNode = LinkedNode(line.strip(), line)
if not initNode:
initNode = curNode
else:
curNode = initNode
# Using dictionary becasue we want to concat data
lowerBound = {}
upperBound = {}
LOWER = True
else:
line = map(float, line.strip().split())
if len(line) <= 1:
continue
if LOWER:
LOWER = False
# This data appered in lowerBound before, concat the data
if line[0] in lowerBound:
for i in range(1, len(line)):
lowerBound[line[0]][i] = min(lowerBound[line[0]][i],
line[i])
else:
lowerBound[line[0]] = line
for i in range(len(line)):
y_min[i] = min(y_min[i], line[i])
else:
LOWER = True
if line[0] in upperBound:
for i in range(1, len(line)):
upperBound[line[0]][i] = max(upperBound[line[0]][i],
line[i])
else:
upperBound[line[0]] = line
for i in range(len(line)):
y_max[i] = max(y_max[i], line[i])
insertData(curNode, lowerBound, upperBound)
return initNode, y_min, y_max