Esempio n. 1
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def reverse(queue: MyQueue, k):
    if queue.size() ==0 or queue.size() < k:
        return None
    s = MyStack()
    for i in range(k):
        s.push(queue.dequeue())
    q1 = MyQueue()
    for i in range(k):
        q1.enqueue(s.pop())
    while queue.is_empty() is False:
        q1.enqueue(queue.dequeue())

    return q1
Esempio n. 2
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def next_greater_element(lst):
    s = MyStack()
    res = [-1] * len(lst)
    for i in range(len(lst) - 1, -1, -1):

        while not s.is_empty() and s.top() < lst[i]:
            s.pop()

        if not s.is_empty():
            res[i] = s.top()

        s.push(lst[i])

    return res
Esempio n. 3
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def insert(stack:MyStack, value):
    if(stack.is_empty() or value < stack.top()):
        stack.push(value)
    else:
        temp=stack.pop()
        insert(stack, value)
        stack.push(temp)
Esempio n. 4
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def evaluate_post_fix(exp):
    stack = MyStack()
    try:
        for c in exp:
            if c.isdigit():
                stack.push(c)
            else:
                right = stack.pop()
                left = stack.pop()
                result = str(eval(left + c + right))
                stack.push(result)

        return stack.pop()
    except TypeError:
        return 'invalid sequence'
Esempio n. 5
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class NewQueue:
    def __init__(self):
        self.main_stack = MyStack()
        self.temp_stack = MyStack()

    def enqueue(self, value):
        self.main_stack.push(value)
        return True

    def dequeue(self):
        if self.temp_stack.is_empty():
            if self.main_stack.is_empty():
                return None
            while self.main_stack.is_empty() is False:
                self.temp_stack.push(self.main_stack.pop())
        temp = self.temp_stack.pop()
        return temp
Esempio n. 6
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def dfs_traversal_helper(g: Graph, source, visited):
    result = ""
    q = MyStack()
    q.push(source)
    visited[source] = True
    while q.is_empty() is False:
        current_node = q.pop()
        result += str(current_node)
        temp: Node = g.array[current_node].head_node
        while temp is not None:
            if visited[temp.data] is False:
                q.push(temp.data)
                visited[temp.data] = True
                temp = temp.next_element
    return result, visited
Esempio n. 7
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def is_balanced(exp):
    s = MyStack()

    for char in exp:
        if char in ['{', '(', '[']:
            s.push(char)
        else:
            char1 = s.pop()
            if char == ']' and char1 != '[':
                return False
            if char == '}' and char1 != '{':
                return False
            if char == ')' and char1 != '(':
                return False
    if s.is_empty() is False:
        return False
    return True
Esempio n. 8
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def sortStack(stack:MyStack):
    tempStack = MyStack()

    while stack.is_empty() is False:
        value = stack.pop()
        if tempStack.top() is not None and value >= int(tempStack.top()):
            tempStack.push(value)
        else:
            while tempStack.is_empty() is False:
                stack.push(tempStack.pop())
            tempStack.push(value)

    while tempStack.is_empty() is False:
        stack.push(tempStack.pop())

    return stack
Esempio n. 9
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def recursive_sort(stack:MyStack):
    if stack.is_empty() is False:
        value = stack.pop()
        recursive_sort(stack)
        insert(stack,value)
Esempio n. 10
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        insert(stack,value)


def insert(stack:MyStack, value):
    if(stack.is_empty() or value < stack.top()):
        stack.push(value)
    else:
        temp=stack.pop()
        insert(stack, value)
        stack.push(temp)





stack = MyStack()

stack.push(2)
stack.push(97)
stack.push(4)
stack.push(42)
stack.push(12)
stack.push(60)
stack.push(23)

print(stack.stack_list)

recursive_sort(stack)

print(stack.stack_list)
Esempio n. 11
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 def __init__(self):
     self.main_stack = MyStack()
     self.temp_stack = MyStack()