class Stack:
def __init__(self):
self.list = Linked_list()
self.size = 0
def push(self,data):
self.list.add_node_head(data)
self.size += 1
def pop(self):
if self.isEmpty():
return None
else :
data = self.top()
self.list.delete_node(data)
self.size -= 1
return data
def top(self):
if self.isEmpty():
return None
else:
return self.list.get_head().data
def isEmpty(self):
if self.size == 0:
return True
else:
return False
def test_delete_first_item(sef):
ll = Linked_list(array)
item = 1
if item == ll.head.data:
ll.head = ll.head.next
assert (ll.head.data == 2)
def test_replace_implementation(self):
ll = Linked_list(array)
assert ll.replace(8, 1) == 8 #replace first element
assert ll.replace(9, 3) == 9 #replace item in the middle
assert ll.replace(10, 6) == 10 #replace last item
assert ll.replace(0, 45) == None #replace item that doesn't exist
assert ll.size == 6 #size doesn't change
def test_prepend_implementation(self):
ll = Linked_list()
assert ll.prepend(1) == 1
assert ll.prepend(2) == 2
assert ll.head.data == 2
assert ll.tail.data == 1
assert ll.size == 2
def test_find(self):
ll = Linked_list(array)
#pdb.set_trace()
assert ll.find(lambda item: item == 1) == 1
assert ll.find(lambda item: item < 2) == 1
assert ll.find(lambda item: item > 3) == 4
assert ll.find(lambda item: item == 7) is None
def test_delete_implementation(self):
ll = Linked_list(array)
assert ll.delete(1) == 1
assert (ll.delete(4)) == 4
assert (ll.delete(6)) == 6
assert (ll.delete(9)) == None
assert (ll.size == 3)
def test_delete_last_node(self):
ll = Linked_list(array)
item = 6
current_node = ll.head
previous_node = current_node
while current_node is not None:
if current_node is not None and current_node.next is None:
ll.tail = previous_node
previous_node = current_node
current_node = current_node.next
assert (ll.tail.data == 5)
def test_delete_node_in_middle(self):
ll = Linked_list(array)
item = 4
current_node = ll.head
previous_node = current_node
while current_node is not None:
if current_node.data == item:
current_node = current_node.next
previous_node.next = current_node
previous_node = current_node
current_node = current_node.next
assert ll.find(lambda item: item == 4) is None
def split(linked_list):
if linked_list == None or linked_list.head == None:
left_half = linked_list
right_half = None
return left_half,right_half
else:
size = linked_list.size()
mid = size // 2
mid_node = linked_list.node_at_index(mid-1)
left_half = linked_list
right_half = Linked_list()
right_half.head = mid_node.next_Node
mid_node.next_Node = None
return left_half,right_half
class Queue:
def __init__(self):
self.list = Linked_list()
self.size = 0
def poll(self):
if self.isEmpty():
return None
else:
data = self.peek()
# linked list should store last element and delete node in O(1)
self.list.delete_node(data)
self.size -= 1
return data
def peek(self):
if self.isEmpty():
return None
else:
return self.list.get_head().data
def add(self,data):
self.list.add_node(data)
self.size += 1
def isEmpty(self):
if self.size == 0:
return True
else:
return False
def print_queue(self):
self.list.list_print()
def merge(left,right):
merge = Linked_list()
merge.add(0)
current = merge.head
left_head = left.head
right_head = right.head
while left_head or right_head:
if left_head is None:
current.next_Node = right_head
right_head = right_head.next_Node
elif right_head is None:
current.next_Node = left_head
left_head = left_head.next_Node
else:
left_data = left_head.data
right_data = right_head.data
if left_data < right_data :
current.next_Node = left_head
left_head = left_head.next_Node
else:
current.next_Node = right_head
right_head = right_head.next_Node
current = current.next_Node
head = merge.head.next_Node
merge.head = head
return merge
def test_replace(self):
ll = Linked_list(array)
newItem = Node(8)
replaceItem = 6
current = ll.head
previous = current
while current:
if current.data == replaceItem:
current = current.next
previous.next = newItem
newItem.next = current
break
previous = current
current = current.next
assert (ll.find(lambda item: item == 8)) == 8
assert (ll.find(lambda item: item == 6)) == None
def test_delete_none_existing_item(sef):
ll = Linked_list(array)
current_node = ll.head
previous_node = current_node
item = 9
find = False
while current_node is not None:
if current_node.data == item:
current_node = current_node.next
previous_node.next = current_node
find = True
previous_node = current_node
current_node = current_node.next
assert (find == False)
def test_init_array(self):
ll = Linked_list(array)
assert (ll.head.data == 1)
assert (ll.head.next.data == 2)
assert (ll.tail.data == 6)
def push(self, value):
Linked_list.add_to_tail(self, value)
def pop(self):
if self.size == 0:
return None
return_value = Linked_list.remove_from_head(self)
return return_value
def pop_min (self): return Linked_list.remove_from_head(self)
def pop_max (self): return Linked_list.remove_from_tail(self)
def __init__(self):
self.list = Linked_list()
self.size = 0
a_ref = a_curr.next
if b_curr:
b_ref = b_curr.next
if a_curr:
a_curr.next = b_curr
if b_curr:
b_curr.next = a_ref
a_curr = a_ref
b_curr = b_ref
return a_curr
if __name__ == "__main__":
lst1 = Linked_list()
lst2 = Linked_list()
lst3 = Linked_list()
lst1.insert(1)
lst1.append(2)
lst1.append(3)
lst1.append(2)
lst1.append(1)
lst2.insert(2)
lst2.append(4)
lst2.append(6)
lst2.append(8)
lst2.append(10)
lst3.insert(420)
lst3.append(69)
print(lst1.to_string())
def __init__(self):
Linked_list.__init__(self)
from linked_list import Node, Linked_list
def is_cycle(node):
if not node or not node.next:
return False
slow, fast = node
while slow:
if fast.next or fast.next.next:
return False
if slow == fast:
return True
if __name__ == "__main__":
linked_list = Linked_list()
print(linked_list)
from linked_list import Linked_list
linked_list_1 = Linked_list()
linked_list_2 = Linked_list()
linked_list_3 = Linked_list()
linked_list_4 = Linked_list()
elements_1 = [3, 2, 4, 35, 6, 65, 6, 4, 3, 21]
elements_2 = [6, 32, 4, 9, 6, 1, 11, 21, 1]
for i in elements_1:
linked_list_1.append(i)
for i in elements_2:
linked_list_2.append(i)
print(linked_list_1.union(linked_list_2))
print(linked_list_1.intersection(linked_list_2))
elements_3 = [3, 2, 4, 35, 6, 65, 6, 4, 3, 23]
elements_4 = [1, 7, 8, 9, 11, 21, 1]
for i in elements_3:
linked_list_3.append(i)
for i in elements_4:
linked_list_4.append(i)
print(linked_list_3.union(linked_list_4))
print(linked_list_3.intersection(linked_list_4))
def linked_list():
return Linked_list()
from linked_list import Linked_list link_list1 = Linked_list() link_list1.append(0) link_list1.append(1) link_list1.append(2) link_list1.append(3) link_list1.append(4) link_list1.append(5) item = link_list1[3] print(item) print(link_list1) link_list1.delete(3) print(link_list1) link_list1.delete(0) print(link_list1) link_list1.append(6) print(link_list1) link_list1.prepend(0) print(link_list1)
def __init__(self, init_size=8):
"""Initialize this hash table with the given initial size."""
# Create a new list (used as fixed-size array) of empty linked lists
self.buckets = [Linked_list() for _ in range(init_size)]
Search.verify(resulte)
print(f"time of monitor: {(lastTime-StartTime)}")
#--------------------// chack if the List is sorted or not \\--------------------
print("\n--------// chack if the List is sorted or not \\\\-------")
# print(alist)
# print(Sort.verify_sort(alist))
StartTime = time.perf_counter_ns()
sorted_list = Sort.merge_sort(alist)
EndTime = time.perf_counter_ns()
print(f"sorted_list {sorted_list} \ntime of monitor: {(EndTime-StartTime)}ns ")
# print(Sort.verify_sort(sorted_list))
#------------------// sort lkinked list \\-------------------------------------
print("\n--------// sort lkinked list \\\\-------")
l = Linked_list()
l.add(20)
l.add(30)
l.add(10)
l.add(5)
l.add(25)
l.add(40)
print(l)
sorted_link_list = Linked_list_sortition.sort_linked_list(l)
print(sorted_link_list)
#------------------// bogo sort \\-------------------------------------
print("\n-----------//bogo sort \\\\ ----------------")
alist1 = load_numbers("Data_Structures/Files/numers.txt")
StartTime = time.perf_counter_ns()
sorted_bogo = Sort.bogo_sort(alist1)
