Design a stack that supports push, pop, top, and retrieving the minimum element in constant time.
- push(x) -- Push element x onto stack.
- pop() -- Removes the element on top of the stack.
- top() -- Get the top element.
- getMin() -- Retrieve the minimum element in the stack.
Example:
MinStack minStack = new MinStack(); minStack.push(-2); minStack.push(0); minStack.push(-3); minStack.getMin(); --> Returns -3. minStack.pop(); minStack.top(); --> Returns 0. minStack.getMin(); --> Returns -2.
class MinStack:
def __init__(self):
"""
initialize your data structure here.
"""
self.s = []
self.helper = []
def push(self, x: int) -> None:
self.s.append(x)
element = x if not self.helper or x < self.helper[-1] else self.helper[-1]
self.helper.append(element)
def pop(self) -> None:
self.s.pop()
self.helper.pop()
def top(self) -> int:
return self.s[-1]
def getMin(self) -> int:
return self.helper[-1]
# Your MinStack object will be instantiated and called as such:
# obj = MinStack()
# obj.push(x)
# obj.pop()
# param_3 = obj.top()
# param_4 = obj.getMin()class MinStack {
private Deque<Integer> s;
private Deque<Integer> helper;
/** initialize your data structure here. */
public MinStack() {
s = new ArrayDeque<>();
helper = new ArrayDeque<>();
}
public void push(int x) {
s.push(x);
int element = helper.isEmpty() || x < helper.peek() ? x : helper.peek();
helper.push(element);
}
public void pop() {
s.pop();
helper.pop();
}
public int top() {
return s.peek();
}
public int getMin() {
return helper.peek();
}
}
/**
* Your MinStack object will be instantiated and called as such:
* MinStack obj = new MinStack();
* obj.push(x);
* obj.pop();
* int param_3 = obj.top();
* int param_4 = obj.getMin();
*/