def minmax_decision(prob):
global no_of_nodes_mm, memory
def minmax_value(node):
global no_of_nodes_mm
if terminal_test(node.state):
return utility_func(node.state)
elif node.player == 'MAX':
v = -float('inf')
for child in node.expand(prob):
no_of_nodes_mm += 1
v = max(v, minmax_value(child))
return v
else:
v = float('inf')
for child in node.expand(prob):
no_of_nodes_mm += 1
# nstate = prob.nstate(a,state)
v = min(v, minmax_value(child))
return v
node = Node(prob.instate, player='MAX')
values = []
children = node.expand(prob)
for child in children:
no_of_nodes_mm += 1
values.append((child, minmax_value(child)))
result_node = max(values, key=lambda x: x[1])[0]
memory = sys.getsizeof(result_node)
# no_of_nodes_mm += result_node.depth*4
return result_node.action
def add_two_numbers(head1, head2):
result = None
end = result
carry = 0
while head1 or head2:
sum = 0
if head1:
sum += head1.val
head1 = head1.next
if head2:
sum += head2.val
head2 = head2.next
sum += carry
carry = 0
if sum >= 10:
carry = 1
sum -= 10
temp = Node(sum)
if end is None:
result = temp
else:
end.next = temp
end = temp
if carry == 1:
end.next = Node(1)
return result
def stack_sum(h1, h2):
stack1 = list()
stack2 = list()
while h1:
stack1.append(h1.val)
h1 = h1.next
while h2:
stack2.append(h2.val)
h2 = h2.next
prev = None
carry = 0
while stack1 or stack2:
sum = 0
if len(stack1) > 0:
sum += stack1.pop()
if len(stack2) > 0:
sum += stack2.pop()
sum += carry
carry = 0
if sum >= 10:
sum -= 10
carry = 1
temp = Node(sum, prev)
prev = temp
if carry == 1:
temp = Node(1, prev)
prev = temp
return prev
def reverse(head):
y = Node(head.val)
head = head.next
x = y
while head:
temp = Node(head.val, x)
head = head.next
x = temp
return x
def node_generator():
"""Creates nodes for testing functions"""
Node.h_method = 'manhattan'
Node.final_grid = [1,2,3,8,0,4,7,6,5]
Node.size = 3
Node1 = Node(grid = [5, 8, 6, 2, 0, 7, 4, 1, 3])
Node2 = Node(grid = [0, 8, 5, 3, 1, 2, 7, 4, 6])
return [Node1, Node2]
def build_tree(arr):
if arr is None:
return None
elif len(arr) == 1:
temp = Node(arr[0])
return temp
else:
mid = len(arr) // 2
left_child = build_tree(arr[0:mid])
right_child = build_tree(arr[mid + 1:])
node = Node(arr[mid], left_child, right_child)
return node
def build_tree_2(inorder, postorder):
if not inorder:
return
if len(inorder) == 1:
return Node(inorder[0])
root_val = postorder[-1]
left_tree = inorder[:inorder.index(root_val)]
left_node = build_tree_2(left_tree, postorder[:len(left_tree)])
right_node = build_tree_2(inorder[len(left_tree) + 1:],
postorder[len(left_tree):-1])
root_node = Node(root_val, left_node, right_node)
return root_node
def test_clone_linked_list(self):
head = self.creating_list()
new_head = Node.clone_linked_list(head)
# getting the two lists for comparison
old_list = Node.get_linked_list(head)
new_list = Node.get_linked_list(new_head)
self.assertEqual(new_list[1].data, 6)
self.assertEqual(new_list[1].next, new_list[2])
self.assertEqual(new_list[1].rnd, new_list[3])
self.assertEqual(old_list, new_list)
self.assertIsNot(old_list, new_list)
def main():
l1 = Node.test_list()
l2 = Node.test_list_1()
Node.print_list(l1)
Node.print_list(l2)
l = add_two_numbers_2(l1, l2)
Node.print_list(l)
def duplicate_1(head):
dic = dict()
dic[None] = None
p = head
while p:
dic[p] = Node(p.val)
p = p.next
p = head
while p:
dic[p].next = dic[p.next]
dic[p].random = dic[p.random]
p = p.next
return dic[head]
def make_nodes(self):
'''Make a search space for the nodes'''
guid = 0
for i in range(0, self.dimension.x_pos):
for j in range(0, self.dimension.y_pos):
_node = Node(Vector2(i, j), guid)
guid = guid + 1
self.nodes.append(_node)
def insert(self, item, index):
current = self.head
previous = None
counter = self.length() - 1
while counter > index:
previous = current
current = current.getNext()
counter -= 1
temp = Node(item)
if previous is None:
self.head = temp
previous.setNext(temp)
temp.setNext(current)
self.len += 1
def add_tail(self, list_head, val):
endNode = Node(val)
if list_head is None:
list_head = endNode
return
LastNode = list_head
while LastNode.next:
LastNode = LastNode.next
LastNode.next = endNode
def add_tail(self, list_head, val):
endNode = Node(val)
if list_head is None:
list_head = endNode
return
lastNode = list_head
while (lastNode.next):
lastNode = lastNode.next
lastNode.next = endNode
def append(self, item):
current = self.head
while current.getNext():
current = current.getNext()
temp = Node(item)
current.setNext(temp)
self.len += 1
def insert(self, cargo):
node = Node(cargo) ## creates a Node with cargo, no .next
if self.length == 0: ## if this is the first item
self.head = self.last = node ## the node is the first AND last item
else:
last = self.last ## find the last node
last.next = node ## append the new node
self.last = node ## the node is now the last in the Q
self.length += 1
def duplicate(head):
if head is None:
return None
result = Node(head.val)
temp = head.next
temp1 = result
old_to_new = {}
old_to_new[head] = result
while temp:
x = Node(temp.val)
old_to_new[temp] = x
temp1.next = x
temp1 = x
temp = temp.next
temp = head
while temp:
if temp.random:
old_to_new[temp].random = old_to_new[temp.random]
temp = temp.next
return result
def insert(self, cargo):
node = Node(cargo)
if self.head is None:
# If list is empty the new node goes first
self.head = node
else:
# Find the last node in the list
last = self.head
while last.next:
last = last.next
# Append the new node
last.next = node
self.length += 1
def creating_list() -> Node:
# initiating nodes with data
n1, n2, n3, n4 = Node(5), Node(6), Node(7), Node(8)
# connecting each node with its Successor
n1.next, n2.next, n3.next, n4.next = n2, n3, n4, None
# connecting each node with its random node
n1.rnd = n3
n2.rnd = n4
n3.rnd = n2
n4.rnd = n1
# returning linked list head node
return n1
def __init__(self, topic):
self.keyboard = InlineKeyboardMarkup(inline_keyboard=[
[InlineKeyboardButton(text="/list", callback_data='l')],
[InlineKeyboardButton(text="/question", callback_data='q')],
[InlineKeyboardButton(text="/report", callback_data='r')],
[InlineKeyboardButton(text="/start", callback_data='s')],
[InlineKeyboardButton(text="/revision", callback_data='rv')],
[InlineKeyboardButton(text="/change_lang", callback_data='cl')],
[
InlineKeyboardButton(text="/delete_subscription",
callback_data='ds')
]
])
database = Database()
self.students = database.get_stud_ids(topic)
self.teachers = database.get_teach_ids(topic)
self.collaborators = database.get_coll_ids(topic)
self.node = Node(topic)
self.banned_user = database.get_banned_stud(topic)
self.singleton = BotId()
super().__init__(database.get_topic_token(topic), self.message,
self.query)
self.singleton.set_bot(self.node.get_topic_name(), super().get_bot())
self.singleton.reset_key_id(topic)
def main():
parse_data_file_args()
training_set, training_labels, test_set, test_labels = preprocess_train_data(
)
#set up and build dt from imported node class
print("Building decision tree... \n")
n = Node(training_set, training_labels, str(args.impurity),
str(args.nlevels))
dt = n.build_decision_tree(training_set, training_labels,
str(args.impurity), int(str(args.nlevels)),
float(str(args.pthrd)))
#given test data, get classifications from dt
print("Classifying test data... \n")
test_data_classifications = classify(test_set, str(args.pred_file), dt)
#calc and print accuracy of labels
a = accuracy(test_data_classifications, test_labels)
print("Overall classification accuracy: " + str(a))
print("Overall error rate: " + str(1.0 - a) + "\n")
#BONUS: class 1 binary classification calculation method call
a = confusion_matrix(test_data_classifications, test_labels)
def build_tree(data):
lst = return_frequency(data)
nodes_list = []
for node_value in lst:
node = Node(node_value)
nodes_list.append(node)
while len(nodes_list) != 1:
first_node = nodes_list.pop()
second_node = nodes_list.pop()
val1, char1 = first_node.value
val2, char2 = second_node.value
node = Node((val1 + val2, char1 + char2))
node.set_left_child(second_node)
node.set_right_child(first_node)
sort_values(nodes_list, node)
root = nodes_list[0]
tree = Tree()
tree.root = root
return tree
def abprune_decision(pro):
global memory
def abprune_value(node, a, b):
global no_of_nodes
# node = Node(pro.instate,'MAX')
if terminal_test(node.state):
return utility_func(node.state), node
if node.player == 'MAX':
v = -float('inf')
c = []
children = node.expand(pro)
for child in children:
# p = pro(child.state)
no_of_nodes += 1
v = max(v, abprune_value(child, a, b)[0])
c.append((child, v))
a = max(a, v)
if a > b:
break
return v, max(c, key=lambda x: x[1])[0]
elif node.player == 'MIN':
v = float('inf')
c = []
children = node.expand(pro)
for child in children:
no_of_nodes += 1
# c = child
# p = pro(child.state)
v = min(v, abprune_value(child, a, b)[0])
c.append((child, v))
b = min(b, v)
if a > b:
break
return v, min(c, key=lambda x: x[1])[0]
node = Node(pro.instate, 'MAX')
memory = sys.getsizeof(node)
_, c = abprune_value(node, -float('inf'), float('inf'))
return c.action
def put(self, key, value):
if self.item_cache[key]:
temp = self.item_cache[key]
prev = temp.prev
nex = temp.next
prev.next = nex
nex.prev = prev
self.end.next = temp
temp.prev = self.end
self.end = temp
else:
if self.length > 8: # assuming the cache can hold 8 items
self.head.next.prev = None
self.head = self.head.next
temp = Node(value, previous=self.end)
self.item_cache[key] = temp
if self.end:
self.end.next = temp
self.end = temp
self.length += 1
if self.head is None:
self.head = temp
def constructMaximumBinaryTree(nums):
size = len(nums)
if (size != 0):
max_index = max(nums)
root = Node(nums[max_index])
if (max_index > 0):
leftarr = nums[0:max_index]
root.left = constructMaximumBinaryTree(leftarr)
else:
root.left = None
if (max_index < size - 1):
rightarr = nums[max_index + 1:size]
root.right = constructMaximumBinaryTree(rightarr)
else:
root.right = None
return root
return None
def main(grid, args):
grid_size = int(sqrt(len(grid)))
Node.final_grid = create_success_grid(grid_size)
Node.size = grid_size
Node.h_method = args.method
Node.h_algo = args.algo
initial_node = Node(grid=grid, g=0, parent=None)
start = time.time()
if args.algo == 'ida_star':
algo = Idastar()
ida_star(initial_node, algo)
else:
algo = Algo()
search_algo(initial_node, algo)
end = time.time()
algo.time = end - start
if args.visu:
visu = Visu(algo)
visu.play()
else:
print_results(algo, args.detail)
return None
def add(self, item):
current = self.head
previous = None
stop = False
while current is not None and not stop:
if current.getData() > item:
stop = True
else:
previous = current
current = current.getNext()
temp = Node(item)
if previous is None:
temp.setNext(self.head)
self.head = temp
else:
temp.setNext(current)
previous.setNext(temp)
self.len += 1
def add(self, item):
temp = Node(item)
temp.setNext(self.head)
self.head = temp
self.len += 1
from node_class import Node
# defing of all the nodes one by one.
# example:
# node1 = Node('node1', 'C:\\Windows\\Node 10.0.4.86')
node1 = Node('first node', 'path_to_the_node')
# user - is a name of server
user = "******"
# an array of <Node> objects. Do not forget to add them all
list_of_nodes = [
node1,
]
def test_get_linked_list(self):
head = self.creating_list()
result_list = Node.get_linked_list(head)
self.assertEqual(result_list[2].data, 7)
self.assertEqual(result_list[2].next, result_list[3])
self.assertEqual(result_list[2].rnd, result_list[1])
