from __future__ import annotations
from typing import Generic, TypeVar
T = TypeVar("T")
class StackOverflowError(BaseException):
pass
class StackUnderflowError(BaseException):
pass
class Stack(Generic[T]):
"""A stack is an abstract data type that serves as a collection of
elements with two principal operations: push() and pop(). push() adds an
element to the top of the stack, and pop() removes an element from the top
of a stack. The order in which elements come off of a stack are
Last In, First Out (LIFO).
https://en.wikipedia.org/wiki/Stack_(abstract_data_type)
"""
def __init__(self, limit: int = 10):
self.stack: list[T] = []
self.limit = limit
def __bool__(self) -> bool:
return bool(self.stack)
def __str__(self) -> str:
return str(self.stack)
def push(self, data: T) -> None:
"""
Push an element to the top of the stack.
>>> S = Stack(2) # stack size = 2
>>> S.push(10)
>>> S.push(20)
>>> print(S)
[10, 20]
>>> S = Stack(1) # stack size = 1
>>> S.push(10)
>>> S.push(20)
Traceback (most recent call last):
...
data_structures.stacks.stack.StackOverflowError
"""
if len(self.stack) >= self.limit:
raise StackOverflowError
self.stack.append(data)
def pop(self) -> T:
"""
Pop an element off of the top of the stack.
>>> S = Stack()
>>> S.push(-5)
>>> S.push(10)
>>> S.pop()
10
>>> Stack().pop()
Traceback (most recent call last):
...
data_structures.stacks.stack.StackUnderflowError
"""
if not self.stack:
raise StackUnderflowError
return self.stack.pop()
def peek(self) -> T:
"""
Peek at the top-most element of the stack.
>>> S = Stack()
>>> S.push(-5)
>>> S.push(10)
>>> S.peek()
10
>>> Stack().peek()
Traceback (most recent call last):
...
data_structures.stacks.stack.StackUnderflowError
"""
if not self.stack:
raise StackUnderflowError
return self.stack[-1]
def is_empty(self) -> bool:
"""
Check if a stack is empty.
>>> S = Stack()
>>> S.is_empty()
True
>>> S = Stack()
>>> S.push(10)
>>> S.is_empty()
False
"""
return not bool(self.stack)
def is_full(self) -> bool:
"""
>>> S = Stack()
>>> S.is_full()
False
>>> S = Stack(1)
>>> S.push(10)
>>> S.is_full()
True
"""
return self.size() == self.limit
def size(self) -> int:
"""
Return the size of the stack.
>>> S = Stack(3)
>>> S.size()
0
>>> S = Stack(3)
>>> S.push(10)
>>> S.size()
1
>>> S = Stack(3)
>>> S.push(10)
>>> S.push(20)
>>> S.size()
2
"""
return len(self.stack)
def __contains__(self, item: T) -> bool:
"""
Check if item is in stack
>>> S = Stack(3)
>>> S.push(10)
>>> 10 in S
True
>>> S = Stack(3)
>>> S.push(10)
>>> 20 in S
False
"""
return item in self.stack
def test_stack() -> None:
"""
>>> test_stack()
"""
stack: Stack[int] = Stack(10)
assert bool(stack) is False
assert stack.is_empty() is True
assert stack.is_full() is False
assert str(stack) == "[]"
try:
_ = stack.pop()
raise AssertionError # This should not happen
except StackUnderflowError:
assert True # This should happen
try:
_ = stack.peek()
raise AssertionError # This should not happen
except StackUnderflowError:
assert True # This should happen
for i in range(10):
assert stack.size() == i
stack.push(i)
assert bool(stack)
assert not stack.is_empty()
assert stack.is_full()
assert str(stack) == str(list(range(10)))
assert stack.pop() == 9
assert stack.peek() == 8
stack.push(100)
assert str(stack) == str([0, 1, 2, 3, 4, 5, 6, 7, 8, 100])
try:
stack.push(200)
raise AssertionError # This should not happen
except StackOverflowError:
assert True # This should happen
assert not stack.is_empty()
assert stack.size() == 10
assert 5 in stack
assert 55 not in stack
if __name__ == "__main__":
test_stack()
import doctest
doctest.testmod()
A stack is a basic linear data structure that follows an order in which objects are accessed. The order is called LIFO(Last In First Out)or FILO(First in Last Out). A perfect example of stacks would be plates in a canteen, a pile of books, or a box of Pringles,etc. Stacks are used to implement parsers and evaluation expressions and backtracking algorithms. basic operations are pushing an element into the stack and popping the element out of the stack. We can make use of linked lists or arrays of lists. The stack contains only one pointer "top pointer" which points to the topmost elements of the stack. Insertion and deletion only occurs at one end of the stack.
A pointer called TOP is used to keep track of the top element in the stack. When initializing the stack, we set its value to -1 so that we can check if the stack is empty by comparing TOP == -1. On pushing an element, we increase the value of TOP and place the new element in the position pointed to by TOP. On popping an element, we return the element pointed to by TOP and reduce its value. Before pushing, we check if the stack is already full before popping, we check if the stack is already empty.