# design a stack such that getMinimum( ) should be O(1)

This is an interview question.

You need to design a stack which holds an integer value such that `getMinimum()` function should return the minimum element in the stack.

For example:

case #1

5 ← TOP
1
4
6
2

When getMinimum() is called it should return 1, which is the minimum element in the stack.

case #2

`stack.pop()`
`stack.pop()`

Note: Both 5 and 1 are popped out of the stack. So after this, the stack looks like

4 ← TOP
6
2

When `getMinimum()` is called it should return 2 which is the minimum in the stack.

Constraints:

1. getMinimum should return the minimum value in O(1)
2. Space constraint also has to be considered while designing it and if you use extra space, it should be of constant space.

EDIT: This fails the "constant space" constraint - it basically doubles the space required. I very much doubt that there's a solution which doesn't do that though, without wrecking the runtime complexity somewhere (e.g. making push/pop O(n)). Note that this doesn't change the complexity of the space required, e.g. if you've got a stack with O(n) space requirements, this will still be O(n) just with a different constant factor.

Non-constant-space solution

Keep a "duplicate" stack of "minimum of all values lower in the stack". When you pop the main stack, pop the min stack too. When you push the main stack, push either the new element or the current min, whichever is lower. `getMinimum()` is then implemented as just `minStack.peek()`.

So using your example, we'd have:

``````Real stack        Min stack

5  --> TOP        1
1                 1
4                 2
6                 2
2                 2
``````

After popping twice you get:

``````Real stack        Min stack

4                 2
6                 2
2                 2
``````

Please let me know if this isn't enough information. It's simple when you grok it, but it might take a bit of head-scratching at first :)

(The downside of course is that it doubles the space requirement. Execution time doesn't suffer significantly though - i.e. it's still the same complexity.)

EDIT: There's a variation which is slightly more fiddly, but has better space in general. We still have the min stack, but we only pop from it when the value we pop from the main stack is equal to the one on the min stack. We only push to the min stack when the value being pushed onto the main stack is less than or equal to the current min value. This allows duplicate min values. `getMinimum()` is still just a peek operation. For example, taking the original version and pushing 1 again, we'd get:

``````Real stack        Min stack

1  --> TOP        1
5                 1
1                 2
4
6
2
``````

Popping from the above pops from both stacks because 1 == 1, leaving:

``````Real stack        Min stack

5  --> TOP        1
1                 2
4
6
2
``````

Popping again only pops from the main stack, because 5 > 1:

``````Real stack        Min stack

1                 1
4                 2
6
2
``````

Popping again pops both stacks because 1 == 1:

``````Real stack        Min stack

4                 2
6
2
``````

This ends up with the same worst case space complexity (double the original stack) but much better space usage if we rarely get a "new minimum or equal".

EDIT: Here's an implementation of Pete's evil scheme. I haven't tested it thoroughly, but I think it's okay :)

``````using System.Collections.Generic;

public class FastMinStack<T>
{
private readonly Stack<T> stack = new Stack<T>();
// Could pass this in to the constructor
private readonly IComparer<T> comparer = Comparer<T>.Default;

private T currentMin;

public T Minimum
{
get { return currentMin; }
}

public void Push(T element)
{
if (stack.Count == 0 ||
comparer.Compare(element, currentMin) <= 0)
{
stack.Push(currentMin);
stack.Push(element);
currentMin = element;
}
else
{
stack.Push(element);
}
}

public T Pop()
{
T ret = stack.Pop();
if (comparer.Compare(ret, currentMin) == 0)
{
currentMin = stack.Pop();
}
return ret;
}
}
``````
• Clever! @Ganesh: Why would the runtime be a problem? It will take only twice as long as a single stack, i.e. it's still O(1) time for push() and pop() as well as for getMinimum() -- that's excellent performance! Commented Mar 26, 2009 at 9:40
• If you have a single variable, what happens when you pop the "1" in your example? It's got to work out that the previous minimum was "2" - which it can't without scanning through everything. Commented Mar 26, 2009 at 9:47
• @Ganesh: Won't you then need to find the new minimum using an O(n) search whenever you pop()? Commented Mar 26, 2009 at 9:47
• Just reading your other comments, when you say "in the stack design itself" do you mean "in each element"? If so, you're still potentially nearly doubling the memory requirements, depending on the size of the element type. It's conceptually the same as two stacks. Commented Mar 26, 2009 at 10:09
• @Ganesh: Unfortunately having no extra stack means we can't make the space-saving optimisation I've included above. Keeping "minimum and element" together is probably more efficient than two stacks of the same size (fewer overheads - arrays, list nodes etc) although it will depend on language. Commented Mar 26, 2009 at 10:30

Add a field to hold the minimum value and update it during Pop() and Push(). That way getMinimum() will be O(1), but Pop() and Push() will have to do a little more work.

If minimum value is popped, Pop() will be O(n), otherwise they will still both be O(1). When resizing Push() becomes O(n) as per the Stack implementation.

Here's a quick implementation

``````public sealed class MinStack {
private int MinimumValue;
private readonly Stack<int> Stack = new Stack<int>();

public int GetMinimum() {
if (IsEmpty) {
throw new InvalidOperationException("Stack is empty");
}
return MinimumValue;
}

public int Pop() {
var value = Stack.Pop();
if (value == MinimumValue) {
MinimumValue = Stack.Min();
}
return value;
}

public void Push(int value) {
if (IsEmpty || value < MinimumValue) {
MinimumValue = value;
}
Stack.Push(value);
}

private bool IsEmpty { get { return Stack.Count() == 0; } }
}
``````
• sorry I didnt understand why does pop() and push() will suffer ? Commented Mar 26, 2009 at 9:34
• In pop() the "new" minimum element has to be found, which takes O(n). Push() won't suffer, as this operation is still O(1). Commented Mar 26, 2009 at 9:43
• @sigjuice: correct. I think I will change the word "suffer" to something less dramatic :) Commented Mar 26, 2009 at 9:53
• @Ganesh M "the elements addition field" if you have an additional field in your N elements, it's not constant space, but O(N) extra. Commented Mar 26, 2009 at 10:01
• If the minimum value is popped out of the stack during an operation, then how is the next minimum value found ? This method does not support that scenario... Commented Mar 6, 2012 at 2:34
``````public class StackWithMin {
int min;
int size;
int[] data = new int[1024];

public void push ( int val ) {
if ( size == 0 ) {
data[size] = val;
min = val;
} else if ( val < min) {
data[size] = 2 * val - min;
min = val;

assert (data[size] < min);
} else {
data[size] = val;
}

++size;

// check size and grow array
}

public int getMin () {
return min;
}

public int pop () {
--size;

int val = data[size];

if ( ( size > 0 ) && ( val < min ) ) {
int prevMin = min;
min += min - val;
return prevMin;
} else {
return val;
}
}

public boolean isEmpty () {
return size == 0;
}

public static void main (String...args) {
StackWithMin stack = new StackWithMin();

for ( String arg: args )
stack.push( Integer.parseInt( arg ) );

while ( ! stack.isEmpty() ) {
int min = stack.getMin();
int val = stack.pop();

System.out.println( val + " " + min );
}

System.out.println();
}

}
``````

It stores the current minimum explicitly, and if the minimum changes, instead of pushing the value, it pushes a value the same difference the other side of the new minimum ( if min = 7 and you push 5, it pushes 3 instead ( 5-|7-5| = 3) and sets min to 5; if you then pop 3 when min is 5 it sees that the popped value is less than min, so reverses the procedure to get 7 for the new min, then returns the previous min). As any value which doesn't cause a change the current minimum is greater than the current minimum, you have something that can be used to differentiate between values which change the minimum and ones which don't.

In languages which use fixed size integers, you're borrowing a bit of space from the representation of the values, so it may underflow and the assert will fail. But otherwise, it's constant extra space and all operations are still O(1).

Stacks which are based instead on linked lists have other places you can borrow a bit from, for example in C the least significant bit of the next pointer, or in Java the type of the objects in the linked list. For Java this does mean there's more space used compared to a contiguous stack, as you have the object overhead per link:

``````public class LinkedStackWithMin {
final int value;

this.value = value;
this.next = next;
}

int pop ( LinkedStackWithMin stack ) {
stack.top = next;
return value;
}
}

super( value, next );
}

int pop ( LinkedStackWithMin stack ) {
stack.top = next;
int prevMin = stack.min;
stack.min = value;
return prevMin;
}
}

int min;

}

public void push ( int val ) {
if ( ( top == null ) || ( val < min ) ) {
min = val;
} else {
}
}

public int pop () {
}

public int getMin () {
return min;
}

public boolean isEmpty () {
}
``````

In C, the overhead isn't there, and you can borrow the lsb of the next pointer:

``````typedef struct _stack_link stack_with_min;

size_t  next;
int     value;
};

{
return ( stack_link * )( link -> next & ~ ( size_t ) 1 );
}

{
return ( link -> next & 1 ) ! = 0;
}

void push ( stack_with_min* stack, int value )
{

link -> next = ( size_t ) stack -> next;

if ( (stack -> next == 0) || ( value == stack -> value ) ) {
link -> value = stack -> value;
link -> next |= 1; // mark as min
} else {
}

}

etc.;
``````

However, none of these are truly O(1). They don't require any more space in practice, because they exploit holes in the representations of numbers, objects or pointers in these languages. But a theoretical machine which used a more compact representation would require an extra bit to be added to that representation in each case.

• +1 very elegant indeed... trivially ported C++ version running at ideone here. Cheers. Commented Jul 30, 2014 at 8:54
• In Java, this will produce the wrong result for `pop()` if the last pushed value was `Integer.MIN_VALUE` (e.g. push 1, push Integer.MIN_VALUE, pop). This is due to underflow as mentioned above. Otherwise works for all integer values.
– Theo
Commented Feb 18, 2019 at 18:41
• Kudos for mentioning the one bit added in storing the difference. Commented Mar 28, 2021 at 14:01

I found a solution that satisfies all the constraints mentioned (constant time operations) and constant extra space.

The idea is to store the difference between min value and the input number, and update the min value if it is no longer the minimum.

The code is as follows:

``````public class MinStack {
long min;
Stack<Long> stack;

public MinStack(){
stack = new Stack<>();
}

public void push(int x) {
if (stack.isEmpty()) {
stack.push(0L);
min = x;
} else {
stack.push(x - min); //Could be negative if min value needs to change
if (x < min) min = x;
}
}

public int pop() {
if (stack.isEmpty()) return;

long pop = stack.pop();

if (pop < 0) {
long ret = min
min = min - pop; //If negative, increase the min value
return (int)ret;
}
return (int)(pop + min);

}

public int top() {
long top = stack.peek();
if (top < 0) {
return (int)min;
} else {
return (int)(top + min);
}
}

public int getMin() {
return (int)min;
}
}
``````
• This one works. I tried with negative numbers in the stack as well. And simple enough to remember too. Thanks. Commented Aug 28, 2019 at 11:00

Well, what are the runtime constraints of `push` and `pop`? If they are not required to be constant, then just calculate the minimum value in those two operations (making them O(n)). Otherwise, I don't see how this can be done with constant additional space.

• +1, hehe... The old "bend the rules" trick... In a similar way, I know of a sorting algorithm that sorts any size array in O(1) time, but the first access to any element of the result incurs O(nlog n) overhead... :) Commented Mar 26, 2009 at 9:43
• In Haskell, everything is constant time! (except if you want to print the result)
– Henk
Commented Mar 27, 2009 at 4:56
• +1 for noting the poor problem specification. "I don't see how this can be done" - neither did I, but Pete Kirkham's solution does it very elegantly.... Commented Jul 30, 2014 at 8:58

Let's assume the stack which we will be working on is this :

``````6 , minvalue=2
2 , minvalue=2
5 , minvalue=3
3 , minvalue=3
9 , minvalue=7
7 , minvalue=7
8 , minvalue=8
``````

In the above representation the stack is only built by left value's the right value's [minvalue] is written only for illustration purpose which will be stored in one variable.

The actual problem is when the value which is the minimum value gets removed: At that point how can we know what is the next minimum element without iterating over the stack.

Like for example in our stack when 6 gets popped we know that, this is not the minimum element because the minimum element is 2, so we can safely remove this without updating our min value.

But when we pop 2, we can see that the minimum value is 2 right now and if this gets popped out then we need to update the minimum value to 3.

Point1:

Now if you observe carefully we need to generate minvalue=3 from this particular state [2 , minvalue=2].
Or if you go deeper in the stack we need to generate minvalue=7 from this particular state [3 , minvalue=3]
or if you go deeper still in the stack then we need to generate minvalue=8 from this particular state [7 , minvalue=7]

Did you notice something in common in all of the above three cases? The value which we need to generate depends upon two variable which are both equal. Correct.
Why is this happening because when we push some element smaller then the current minvalue, then we basically push that element in the stack and updated the same number in minvalue also.

Point2:

So we are basically storing duplicate of the same number once in stack and once in minvalue variable.
We need to focus on avoiding this duplication and store something useful data in the stack or the minvalue to generate the previous minimum as shown in CASES above.

Let's focus on what should we store in stack when the value to store in push is less than the minimum value. Let's name this variable y, so now our stack will look something like this:

``````6 , minvalue=2
y1 , minvalue=2
5 , minvalue=3
y2 , minvalue=3
9 , minvalue=7
y3 , minvalue=7
8 , minvalue=8
``````

I have renamed them as y1,y2,y3 to avoid confusion that all of them will have same value.

Point3:

Now let's try to find some constraint's over y1, y2 and y3. Do you remember when exactly we need to update the minvalue while doing pop(), only when we have popped the element which is equal to the minvalue.
If we pop something greater than the minvalue then we don't have to update minvalue.
So to trigger the update of minvalue, y1,y2&y3 should be smaller than there corresponding minvalue. [We are avoiding equality to avoid duplicate[Point2]]
so the constrain is [ y < minValue ].

Now let's come back to populate y, we need to generate some value and put y at the time of push, remember.
Let's take the value which is coming for push to be x which is less that the prevMinvalue, and the value which we will actually push in stack to be y.
So one thing is obvious that the newMinValue=x, and y < newMinvalue.

Now we need to calculate y(remember y can be any number which is less than newMinValue(x) so we need to find some number which can fulfil our constraint) with the help of prevMinvalue and x(newMinvalue).

``````Let's do the math:
x < prevMinvalue [Given]
x - prevMinvalue < 0
x - prevMinValue + x < 0 + x [Add x on both side]
2*x - prevMinValue < x
this is the y which we were looking for less than x(newMinValue).
y = 2*x - prevMinValue. 'or' y = 2*newMinValue - prevMinValue 'or' y = 2*curMinValue - prevMinValue [taking curMinValue=newMinValue].
``````

So at the time of pushing x if it is less than prevMinvalue then we push y[2*x-prevMinValue] and update newMinValue = x .

And at the time of pop if the stack contains something less than the minValue then that's our trigger to update the minValue. We have to calculate prevMinValue from the curMinValue and y.
y = 2*curMinValue - prevMinValue [Proved]
prevMinValue = 2*curMinvalue - y .

2*curMinValue - y is the number which we need to update now to the prevMinValue.

Code for the same logic is shared below with O(1) time and O(1) space complexity.

``````// C++ program to implement a stack that supports
// getMinimum() in O(1) time and O(1) extra space.
#include <bits/stdc++.h>
using namespace std;

// A user defined stack that supports getMin() in
// addition to push() and pop()
struct MyStack
{
stack<int> s;
int minEle;

// Prints minimum element of MyStack
void getMin()
{
if (s.empty())
cout << "Stack is empty\n";

// variable minEle stores the minimum element
// in the stack.
else
cout <<"Minimum Element in the stack is: "
<< minEle << "\n";
}

// Prints top element of MyStack
void peek()
{
if (s.empty())
{
cout << "Stack is empty ";
return;
}

int t = s.top(); // Top element.

cout << "Top Most Element is: ";

// If t < minEle means minEle stores
// value of t.
(t < minEle)? cout << minEle: cout << t;
}

// Remove the top element from MyStack
void pop()
{
if (s.empty())
{
cout << "Stack is empty\n";
return;
}

cout << "Top Most Element Removed: ";
int t = s.top();
s.pop();

// Minimum will change as the minimum element
// of the stack is being removed.
if (t < minEle)
{
cout << minEle << "\n";
minEle = 2*minEle - t;
}

else
cout << t << "\n";
}

// Removes top element from MyStack
void push(int x)
{
// Insert new number into the stack
if (s.empty())
{
minEle = x;
s.push(x);
cout <<  "Number Inserted: " << x << "\n";
return;
}

// If new number is less than minEle
if (x < minEle)
{
s.push(2*x - minEle);
minEle = x;
}

else
s.push(x);

cout <<  "Number Inserted: " << x << "\n";
}
};

// Driver Code
int main()
{
MyStack s;
s.push(3);
s.push(5);
s.getMin();
s.push(2);
s.push(1);
s.getMin();
s.pop();
s.getMin();
s.pop();
s.peek();

return 0;
}
``````

We can do this in O(n) time and O(1) space complexity, like so:

``````class MinStackOptimized:
def __init__(self):
self.stack = []
self.min = None

def push(self, x):
if not self.stack:
# stack is empty therefore directly add
self.stack.append(x)
self.min = x
else:
"""
Directly add (x-self.min) to the stack. This also ensures anytime we have a
negative number on the stack is when x was less than existing minimum
recorded thus far.
"""
self.stack.append(x-self.min)
if x < self.min:
# Update x to new min
self.min = x

def pop(self):
x = self.stack.pop()
if x < 0:
"""
if popped element was negative therefore this was the minimum
element, whose actual value is in self.min but stored value is what
contributes to get the next min. (this is one of the trick we use to ensure
we are able to get old minimum once current minimum gets popped proof is given
below in pop method), value stored during push was:
(x - self.old_min) and self.min = x therefore we need to backtrack
these steps self.min(current) - stack_value(x) actually implies to
x (self.min) - (x - self.old_min)
which therefore gives old_min back and therefore can now be set
back as current self.min.
"""
self.min = self.min - x

def top(self):
x = self.stack[-1]
if x < 0:
"""
As discussed above anytime there is a negative value on stack, this
is the min value so far and therefore actual value is in self.min,
current stack value is just for getting the next min at the time
this gets popped.
"""
return self.min
else:
"""
if top element of the stack was positive then it's simple, it was
not the minimum at the time of pushing it and therefore what we did
was x(actual) - self.min(min element at current stage) let's say `y`
therefore we just need to reverse the process to get the actual
value. Therefore self.min + y, which would translate to
self.min + x(actual) - self.min, thereby giving x(actual) back
as desired.
"""
return x + self.min

def getMin(self):
# Always self.min variable holds the minimum so for so easy peezy.
return self.min
``````
• Pity about the docstrings - one of which should mention this to be for non-negative numbers, only. Commented Mar 28, 2021 at 16:22

Here is my version of implementation.

``` struct MyStack {
int element;
};

void Push(int value)
{
// Create you structure and populate the value
MyStack S = new MyStack();
S->element = value;

if(Stack.Empty())
{
// Since the stack is empty, point CurrentMiniAddress to itself

}
else
{
// Stack is not empty

// Retrieve the top element. No Pop()
MyStack *TopElement = Stack.Top();

// Remember Always the TOP element points to the
// minimum element in ths whole stack
{
// If the current value is the minimum in the whole stack
// then S points to itself
}
else
{
// So this is not the minimum in the whole stack
// No worries, TOP is holding the minimum element
}

}
}

void Pop()
{
if(!Stack.Empty())
{
Stack.Pop();
}
}

int GetMinimum(Stack &stack)
{
if(!stack.Empty())
{
MyStack *Top  = stack.top();
// Top always points to the minimumx
}
}
```
• I Agree, this requires an additional element in your struct. But this eliminates finding the minimum whenever we pop an element. Commented Mar 26, 2009 at 10:45
• So, having failed to meet the constraints of the question, did you get the job? Commented Mar 26, 2009 at 11:33

Here is my Code which runs with O(1). The previous code which I posted had problem when the minimum element gets popped. I modified my code. This one uses another Stack that maintains minimum element present in stack above the current pushed element.

`````` class StackDemo
{
int[] stk = new int[100];
int top;
public StackDemo()
{
top = -1;
}
public void Push(int value)
{
if (top == 100)
Console.WriteLine("Stack Overflow");
else
stk[++top] = value;
}
public bool IsEmpty()
{
if (top == -1)
return true;
else
return false;
}
public int Pop()
{
if (IsEmpty())
{
Console.WriteLine("Stack Underflow");
return 0;
}
else
return stk[top--];
}
public void Display()
{
for (int i = top; i >= 0; i--)
Console.WriteLine(stk[i]);
}
}
class MinStack : StackDemo
{
int top;
int[] stack = new int[100];
StackDemo s1; int min;
public MinStack()
{
top = -1;
s1 = new StackDemo();
}
public void PushElement(int value)
{
s1.Push(value);
if (top == 100)
Console.WriteLine("Stack Overflow");
if (top == -1)
{
stack[++top] = value;
stack[++top] = value;
}
else
{
//  stack[++top]=value;
int ele = PopElement();
stack[++top] = ele;
int a = MininmumElement(min, value);
stack[++top] = min;

stack[++top] = value;
stack[++top] = a;

}
}
public int PopElement()
{

if (top == -1)
return 1000;
else
{
min = stack[top--];
return stack[top--];
}

}
public int PopfromStack()
{
if (top == -1)
return 1000;
else
{
s1.Pop();
return PopElement();
}
}
public int MininmumElement(int a,int b)
{
if (a > b)
return b;
else
return a;
}
public int StackTop()
{
return stack[top];
}
public void DisplayMinStack()
{
for (int i = top; i >= 0; i--)
Console.WriteLine(stack[i]);
}
}
class Program
{
static void Main(string[] args)
{
MinStack ms = new MinStack();
ms.PushElement(15);
ms.PushElement(2);
ms.PushElement(1);
ms.PushElement(13);
ms.PushElement(5);
ms.PushElement(21);
Console.WriteLine("Min Stack");
ms.DisplayMinStack();
Console.WriteLine("Minimum Element:"+ms.StackTop());
ms.PopfromStack();
ms.PopfromStack();
ms.PopfromStack();
ms.PopfromStack();

Console.WriteLine("Min Stack");
ms.DisplayMinStack();
Console.WriteLine("Minimum Element:" + ms.StackTop());
}
}
``````
• Please mention the programming language used here to write code. It helps potential visitors clue as what's going on based on syntax. I assume it C# but what if someone doesn't? Commented Feb 19, 2014 at 1:30
• This one uses another Stack This fails constant extra space. Commented Mar 28, 2021 at 13:51

I used a different kind of stack. Here is the implementation.

``````//
//  main.cpp
//  Eighth
//
//  Created by chaitanya on 4/11/13.
//

#include <iostream>
#include <limits>
using namespace std;
struct stack
{
int num;
int minnum;
}a[100];

void push(int n,int m,int &top)
{

top++;
if (top>=100) {
cout<<"Stack Full";
cout<<endl;
}
else{
a[top].num = n;
a[top].minnum = m;
}

}

void pop(int &top)
{
if (top<0) {
cout<<"Stack Empty";
cout<<endl;
}
else{
top--;
}

}
void print(int &top)
{
cout<<"Stack: "<<endl;
for (int j = 0; j<=top ; j++) {
cout<<"("<<a[j].num<<","<<a[j].minnum<<")"<<endl;
}
}

void get_min(int &top)
{
if (top < 0)
{
cout<<"Empty Stack";
}
else{
cout<<"Minimum element is: "<<a[top].minnum;
}
cout<<endl;
}

int main()
{

int top = -1,min = numeric_limits<int>::min(),num;
cout<<"Enter the list to push (-1 to stop): ";
cin>>num;
while (num!=-1) {
if (top == -1) {
min = num;
push(num, min, top);
}
else{
if (num < min) {
min = num;
}
push(num, min, top);
}
cin>>num;
}
print(top);
get_min(top);
return 0;
}
``````

Output:

``````Enter the list to push (-1 to stop): 5
1
4
6
2
-1
Stack:
(5,5)
(1,1)
(4,1)
(6,1)
(2,1)
Minimum element is: 1
``````

Try it. I think it answers the question. The second element of every pair gives the minimum value seen when that element was inserted.

I am posting the complete code here to find min and max in a given stack.

Time complexity will be O(1)..

``````package com.java.util.collection.advance.datastructure;

/**
*
* @author vsinha
*
*/
public abstract interface Stack<E> {

/**
* Placing a data item on the top of the stack is called pushing it
* @param element
*
*/
public abstract void push(E element);

/**
* Removing it from the top of the stack is called popping it
* @return the top element
*/
public abstract E pop();

/**
* Get it top element from the stack and it
* but the item is not removed from the stack, which remains unchanged
* @return the top element
*/
public abstract E peek();

/**
* Get the current size of the stack.
* @return
*/
public abstract int size();

/**
* Check whether stack is empty of not.
* @return true if stack is empty, false if stack is not empty
*/
public abstract boolean empty();

}

@SuppressWarnings("hiding")
public abstract interface MinMaxStack<Integer> extends Stack<Integer> {

public abstract int min();

public abstract int max();

}

import java.util.Arrays;

/**
*
* @author vsinha
*
* @param <E>
*/
public class MyStack<E> implements Stack<E> {

private E[] elements =null;
private int size = 0;
private int top = -1;
private final static int DEFAULT_INTIAL_CAPACITY = 10;

public MyStack(){
// If you don't specify the size of stack. By default, Stack size will be 10
this(DEFAULT_INTIAL_CAPACITY);
}

@SuppressWarnings("unchecked")
public MyStack(int intialCapacity){
if(intialCapacity <=0){
throw new IllegalArgumentException("initial capacity can't be negative or zero");
}
// Can't create generic type array
elements =(E[]) new Object[intialCapacity];
}

@Override
public void push(E element) {
ensureCapacity();
elements[++top] = element;
++size;
}

@Override
public E pop() {
E element = null;
if(!empty()) {
element=elements[top];
// Nullify the reference
elements[top] =null;
--top;
--size;
}
return element;
}

@Override
public E peek() {
E element = null;
if(!empty()) {
element=elements[top];
}
return element;
}

@Override
public int size() {
return size;
}

@Override
public boolean empty() {
return size == 0;
}

/**
* Increases the capacity of this <tt>Stack by double of its current length</tt> instance,
* if stack is full
*/
private void ensureCapacity() {
if(size != elements.length) {
// Don't do anything. Stack has space.
} else{
elements = Arrays.copyOf(elements, size *2);
}
}

@Override
public String toString() {
return "MyStack [elements=" + Arrays.toString(elements) + ", size="
+ size + ", top=" + top + "]";
}

}

/**
* Time complexity will be O(1) to find min and max in a given stack.
* @author vsinha
*
*/
public class MinMaxStackFinder extends MyStack<Integer> implements MinMaxStack<Integer> {

private MyStack<Integer> minStack;

private MyStack<Integer> maxStack;

public MinMaxStackFinder (int intialCapacity){
super(intialCapacity);
minStack =new MyStack<Integer>();
maxStack =new MyStack<Integer>();

}
public void push(Integer element) {
// Current element is lesser or equal than min() value, Push the current element in min stack also.
if(!minStack.empty()) {
if(min() >= element) {
minStack.push(element);
}
} else{
minStack.push(element);
}
// Current element is greater or equal than max() value, Push the current element in max stack also.
if(!maxStack.empty()) {
if(max() <= element) {
maxStack.push(element);
}
} else{
maxStack.push(element);
}
super.push(element);
}

public Integer pop(){
Integer curr = super.pop();
if(curr !=null) {
if(min() == curr) {
minStack.pop();
}

if(max() == curr){
maxStack.pop();
}
}
return curr;
}

@Override
public int min() {
return minStack.peek();
}

@Override
public int max() {
return maxStack.peek();
}

@Override
public String toString() {
return super.toString()+"\nMinMaxStackFinder [minStack=" + minStack + "\n maxStack="
+ maxStack + "]" ;
}

}

// You can use the below program to execute it.

import java.util.Random;

public class MinMaxStackFinderApp {

public static void main(String[] args) {
MinMaxStack<Integer> stack =new MinMaxStackFinder(10);
Random random =new Random();
for(int i =0; i< 10; i++){
stack.push(random.nextInt(100));
}
System.out.println(stack);
System.out.println("MAX :"+stack.max());
System.out.println("MIN :"+stack.min());

stack.pop();
stack.pop();
stack.pop();
stack.pop();
stack.pop();

System.out.println(stack);
System.out.println("MAX :"+stack.max());
System.out.println("MIN :"+stack.min());
}
}
``````

Let me know if you are facing any issue

Thanks, Vikash

• Kudos for introducing an `interface`. Alas, this fails constant extra space. Commented Mar 28, 2021 at 13:48
``````class FastStack {

private static class StackNode {
private Integer data;
private StackNode nextMin;

public StackNode(Integer data) {
this.data = data;
}

public Integer getData() {
return data;
}

public void setData(Integer data) {
this.data = data;
}

public StackNode getNextMin() {
return nextMin;
}

public void setNextMin(StackNode nextMin) {
this.nextMin = nextMin;
}

}

private StackNode currentMin = null;

public void push(Integer item) {
StackNode node = new StackNode(item);
if (currentMin == null) {
currentMin = node;
node.setNextMin(null);
} else if (item < currentMin.getData()) {
StackNode oldMinNode = currentMin;
node.setNextMin(oldMinNode);
currentMin = node;
}

}

public Integer pop() {
if (stack.isEmpty()) {
throw new EmptyStackException();
}
StackNode node = stack.peek();
if (currentMin == node) {
currentMin = node.getNextMin();
}
stack.removeFirst();
return node.getData();
}

public Integer getMinimum() {
if (stack.isEmpty()) {
throw new NoSuchElementException("Stack is empty");
}
return currentMin.getData();
}
}
``````

Here is my Code which runs with O(1). Here I used vector pair which contain the value which pushed and also contain the minimum value up to this pushed value.

Here is my version of C++ implementation.

``````vector<pair<int,int> >A;
int sz=0; // to keep track of the size of vector

class MinStack
{
public:
MinStack()
{
A.clear();
sz=0;
}

void push(int x)
{
int mn=(sz==0)?x: min(A[sz-1].second,x); //find the minimum value upto this pushed value
A.push_back(make_pair(x,mn));
sz++; // increment the size
}

void pop()
{
if(sz==0) return;
A.pop_back(); // pop the last inserted element
sz--;  // decrement size
}

int top()
{
if(sz==0)   return -1;  // if stack empty return -1
return A[sz-1].first;  // return the top element
}

int getMin()
{
if(sz==0) return -1;
return A[sz-1].second; // return the minimum value at sz-1
}
};
``````
``````    **The task can be acheived by creating two stacks:**

import java.util.Stack;
/*
*
* Find min in stack using O(n) Space Complexity
*/
public class DeleteMinFromStack {

void createStack(Stack<Integer> primary, Stack<Integer> minStack, int[] arr) {
/* Create main Stack and in parallel create the stack which contains the minimum seen so far while creating main Stack */
primary.push(arr[0]);
minStack.push(arr[0]);

for (int i = 1; i < arr.length; i++) {
primary.push(arr[i]);
if (arr[i] <= minStack.peek())// Condition to check to push the value in minimum stack only when this urrent value is less than value seen at top of this stack */
minStack.push(arr[i]);
}

}

int findMin(Stack<Integer> secStack) {
return secStack.peek();
}

public static void main(String args[]) {

Stack<Integer> primaryStack = new Stack<Integer>();
Stack<Integer> minStack = new Stack<Integer>();

DeleteMinFromStack deleteMinFromStack = new DeleteMinFromStack();

int[] arr = { 5, 5, 6, 8, 13, 1, 11, 6, 12 };
deleteMinFromStack.createStack(primaryStack, minStack, arr);
int mimElement = deleteMinFromStack.findMin(primaryStack, minStack);
/** This check for algorithm when the main Stack Shrinks by size say i as in loop below */
for (int i = 0; i < 2; i++) {
primaryStack.pop();
}

System.out.println(" Minimum element is " + mimElement);
}

}
/*
here in have tried to add for loop wherin the main tack can be shrinked/expaned so we can check the algorithm */
``````
• What does this add to, say, Jon Skeet's answer? How much space does this use for n towards infinity (see question or the answer linked)? With a programming language claiming to support OO, it seems more appropriate to create a (not so abstract) data type/(generic) `Class` - `MinStack`? Oracle's Java documentation advises to use `Deque`. Commented Sep 28, 2016 at 12:21
• (Thanks for taking hints. (Code comments should explain the what-for, how, and why - mentioning that a condition is a condition is not helpful. The first one or two lines better not be indented, it is achieved, current, wherein, shrunk and expanded…)) Commented Sep 28, 2016 at 12:22

A practical implementation for finding minimum in a Stack of User Designed Object, named: School

The Stack is going to store the Schools in Stack based on the rank assigned to a school in specific region, say, findMin() gives the School where we get the maximum number of applications for Admissions, which in turn is to be defined by the comparator which uses rank associated with the schools in previous season .

``````The Code for same is below:

package com.practical;

import java.util.Collections;
import java.util.Iterator;
import java.util.List;
import java.util.Stack;

public class CognitaStack {

public School findMin(Stack<School> stack, Stack<School> minStack) {

if (!stack.empty() && !minStack.isEmpty())
return (School) minStack.peek();
return null;
}

public School removeSchool(Stack<School> stack, Stack<School> minStack) {

if (stack.isEmpty())
return null;
School temp = stack.peek();
if (temp != null) {
// if(temp.compare(stack.peek(), minStack.peek())<0){
stack.pop();
minStack.pop();
// }

// stack.pop();
}
return stack.peek();
}

public static void main(String args[]) {

Stack<School> stack = new Stack<School>();
Stack<School> minStack = new Stack<School>();

School s1 = new School("Polam School", "London", 3);
School s2 = new School("AKELEY WOOD SENIOR SCHOOL", "BUCKINGHAM", 4);
School s3 = new School("QUINTON HOUSE SCHOOL", "NORTHAMPTON", 2);
School s4 = new School("OAKLEIGH HOUSE SCHOOL", " SWANSEA", 5);
School s5 = new School("OAKLEIGH-OAK HIGH SCHOOL", "Devon", 1);
School s6 = new School("BritishInter2", "Devon", 7);

Iterator<School> itr = lst.iterator();
while (itr.hasNext()) {
School temp = itr.next();
if ((minStack.isEmpty()) || (temp.compare(temp, minStack.peek()) < 0)) { // minStack.peek().equals(temp)
stack.push(temp);
minStack.push(temp);
} else {
minStack.push(minStack.peek());
stack.push(temp);
}

}

CognitaStack cogStack = new CognitaStack();
System.out.println(" Minimum in Stack is " + cogStack.findMin(stack, minStack).name);
cogStack.removeSchool(stack, minStack);
cogStack.removeSchool(stack, minStack);

System.out.println(" Minimum in Stack is "
+ ((cogStack.findMin(stack, minStack) != null) ? cogStack.findMin(stack, minStack).name : "Empty"));
}

}
``````

Also the School Object is as follows:

``````package com.practical;

import java.util.Comparator;

public class School implements Comparator<School> {

String name;
String location;
int rank;

public School(String name, String location, int rank) {
super();
this.name = name;
this.location = location;
this.rank = rank;
}

@Override
public int hashCode() {
final int prime = 31;
int result = 1;
result = prime * result + ((location == null) ? 0 : location.hashCode());
result = prime * result + ((name == null) ? 0 : name.hashCode());
result = prime * result + rank;
return result;
}

@Override
public boolean equals(Object obj) {
if (this == obj)
return true;
if (obj == null)
return false;
if (getClass() != obj.getClass())
return false;
School other = (School) obj;
if (location == null) {
if (other.location != null)
return false;
} else if (!location.equals(other.location))
return false;
if (name == null) {
if (other.name != null)
return false;
} else if (!name.equals(other.name))
return false;
if (rank != other.rank)
return false;
return true;
}

public String getName() {
return name;
}

public void setName(String name) {
this.name = name;
}

public String getLocation() {
return location;
}

public void setLocation(String location) {
this.location = location;
}

public int getRank() {
return rank;
}

public void setRank(int rank) {
this.rank = rank;
}

public int compare(School o1, School o2) {
// TODO Auto-generated method stub
return o1.rank - o2.rank;
}

}

class SchoolComparator implements Comparator<School> {

public int compare(School o1, School o2) {
return o1.rank - o2.rank;
}

}
``````

This Example covers the following: 1. Implementation of Stack for User defined Objects, here, School 2. Implementation for the hashcode() and equals() method using all fields of Objects to be compared 3. A practical implementation for the scenario where we rqeuire to get the Stack contains operation to be in order of O(1)

• There is no language tag to this question (quite the contrary: `language-agnostic`): please specify what you use for the code (and remove the blanks before `The Code for same is below:`.) How does this support `stack.pop()`? (and `push()`?) Commented Oct 8, 2016 at 5:09

Here's the PHP implementation of what explained in Jon Skeet's answer as the slightly better space complexity implementation to get the maximum of stack in O(1).

``````<?php

/**
* An ordinary stack implementation.
*
* In real life we could just extend the built-in "SplStack" class.
*/
class BaseIntegerStack
{
/**
* Stack main storage.
*
* @var array
*/
private \$storage = [];

// ------------------------------------------------------------------------
// Public API
// ------------------------------------------------------------------------

/**
* Pushes to stack.
*
* @param  int \$value New item.
*
* @return bool
*/
public function push(\$value)
{
return is_integer(\$value)
? (bool) array_push(\$this->storage, \$value)
: false;
}

/**
* Pops an element off the stack.
*
* @return int
*/
public function pop()
{
return array_pop(\$this->storage);
}

/**
* See what's on top of the stack.
*
* @return int|bool
*/
public function top()
{
return empty(\$this->storage)
? false
: end(\$this->storage);
}

// ------------------------------------------------------------------------
// Magic methods
// ------------------------------------------------------------------------

/**
* String representation of the stack.
*
* @return string
*/
public function __toString()
{
return implode('|', \$this->storage);
}
} // End of BaseIntegerStack class

/**
* The stack implementation with getMax() method in O(1).
*/
class Stack extends BaseIntegerStack
{
/**
* Internal stack to keep track of main stack max values.
*
* @var BaseIntegerStack
*/
private \$maxStack;

/**
* Stack class constructor.
*
* Dependencies are injected.
*
* @param BaseIntegerStack \$stack Internal stack.
*
* @return void
*/
public function __construct(BaseIntegerStack \$stack)
{
\$this->maxStack = \$stack;
}

// ------------------------------------------------------------------------
// Public API
// ------------------------------------------------------------------------

/**
* Prepends an item into the stack maintaining max values.
*
* @param  int \$value New item to push to the stack.
*
* @return bool
*/
public function push(\$value)
{
if (\$this->isNewMax(\$value)) {
\$this->maxStack->push(\$value);
}

parent::push(\$value);
}

/**
* Pops an element off the stack maintaining max values.
*
* @return int
*/
public function pop()
{
\$popped = parent::pop();

if (\$popped == \$this->maxStack->top()) {
\$this->maxStack->pop();
}

return \$popped;
}

/**
* Finds the maximum of stack in O(1).
*
* @return int
* @see push()
*/
public function getMax()
{
return \$this->maxStack->top();
}

// ------------------------------------------------------------------------
// Internal helpers
// ------------------------------------------------------------------------

/**
* Checks that passing value is a new stack max or not.
*
* @param  int \$new New integer to check.
*
* @return boolean
*/
private function isNewMax(\$new)
{
return empty(\$this->maxStack) OR \$new > \$this->maxStack->top();
}

} // End of Stack class

// ------------------------------------------------------------------------
// Stack Consumption and Test
// ------------------------------------------------------------------------
\$stack = new Stack(
new BaseIntegerStack
);

\$stack->push(9);
\$stack->push(4);
\$stack->push(237);
\$stack->push(5);
\$stack->push(556);
\$stack->push(15);

print "Stack: \$stack\n";
print "Max: {\$stack->getMax()}\n\n";

print "Pop: {\$stack->pop()}\n";
print "Pop: {\$stack->pop()}\n\n";

print "Stack: \$stack\n";
print "Max: {\$stack->getMax()}\n\n";

print "Pop: {\$stack->pop()}\n";
print "Pop: {\$stack->pop()}\n\n";

print "Stack: \$stack\n";
print "Max: {\$stack->getMax()}\n";

// Here's the sample output:
//
// Stack: 9|4|237|5|556|15
// Max: 556
//
// Pop: 15
// Pop: 556
//
// Stack: 9|4|237|5
// Max: 237
//
// Pop: 5
// Pop: 237
//
// Stack: 9|4
// Max: 9
``````

Here is the C++ implementation of Jon Skeets Answer. It might not be the most optimal way of implementing it, but it does exactly what it's supposed to.

``````class Stack {
private:
struct stack_node {
int val;
stack_node *next;
};
stack_node *top;
stack_node *min_top;
public:
Stack() {
top = nullptr;
min_top = nullptr;
}
void push(int num) {
stack_node *new_node = nullptr;
new_node = new stack_node;
new_node->val = num;

if (is_empty()) {
top = new_node;
new_node->next = nullptr;

min_top = new_node;
new_node->next = nullptr;
} else {
new_node->next = top;
top = new_node;

if (new_node->val <= min_top->val) {
new_node->next = min_top;
min_top = new_node;
}
}
}

void pop(int &num) {
stack_node *tmp_node = nullptr;
stack_node *min_tmp = nullptr;

if (is_empty()) {
std::cout << "It's empty\n";
} else {
num = top->val;
if (top->val == min_top->val) {
min_tmp = min_top->next;
delete min_top;
min_top = min_tmp;
}
tmp_node = top->next;
delete top;
top = tmp_node;
}
}

bool is_empty() const {
return !top;
}

void get_min(int &item) {
item = min_top->val;
}
};
``````

And here is the driver for the class

``````int main() {
int pop, min_el;
Stack my_stack;

my_stack.push(4);
my_stack.push(6);
my_stack.push(88);
my_stack.push(1);
my_stack.push(234);
my_stack.push(2);

my_stack.get_min(min_el);
cout << "Min: " << min_el << endl;

my_stack.pop(pop);
cout << "Popped stock element: " << pop << endl;

my_stack.pop(pop);
cout << "Popped stock element: " << pop << endl;

my_stack.pop(pop);
cout << "Popped stock element: " << pop << endl;

my_stack.get_min(min_el);
cout << "Min: " << min_el << endl;

return 0;
}
``````

Output:

``````Min: 1
Popped stock element: 2
Popped stock element: 234
Popped stock element: 1
Min: 4
``````

You could extend your original stack class and just add the min tracking to it. Let the original parent class handle everything else as usual.

``````public class StackWithMin extends Stack<Integer> {

private Stack<Integer> min;

public StackWithMin() {
min = new Stack<>();
}

public void push(int num) {
if (super.isEmpty()) {
min.push(num);
} else if (num <= min.peek()) {
min.push(num);
}
super.push(num);
}

public int min() {
return min.peek();
}

public Integer pop() {
if (super.peek() == min.peek()) {
min.pop();
}
return super.pop();
}
}
``````
• This solution is also using extra space in terms of Stack<Integer> min. Commented Jun 5, 2018 at 7:10

I think you can simply use a LinkedList in your stack implementation.

First time you push a value, you put this value as the linkedlist head.

then each time you push a value, if the new value < head.data, make a prepand operation ( which means the head becomes the new value )

if not, then make an append operation.

Here is my code.

``````public class Stack {

int[] elements;
int top;

public Stack(int n) {
elements = new int[n];
top = 0;
}

public void realloc(int n) {
int[] tab = new int[n];
for (int i = 0; i < top; i++) {
tab[i] = elements[i];
}

elements = tab;
}

public void push(int x) {
if (top == elements.length) {
realloc(elements.length * 2);
}
if (top == 0) {
min.pre(x);
} else if (x < min.head.data) {
min.pre(x);
} else {
min.app(x);
}
elements[top++] = x;
}

public int pop() {

int x = elements[--top];
if (top == 0) {

}
if (this.getMin() == x) {
}
elements[top] = 0;
if (4 * top < elements.length) {
realloc((elements.length + 1) / 2);
}

return x;
}

public void display() {
for (Object x : elements) {
System.out.print(x + " ");
}

}

public int getMin() {
if (top == 0) {
return 0;
}
}

public static void main(String[] args) {
Stack stack = new Stack(4);
stack.push(2);
stack.push(3);
stack.push(1);
stack.push(4);
stack.push(5);
stack.pop();
stack.pop();
stack.pop();
stack.push(1);
stack.pop();
stack.pop();
stack.pop();
stack.push(2);
System.out.println(stack.getMin());
stack.display();

}

}
``````
• Have a sequence of numbers. In a loop, if the number is even, pop two items. Push the number and print the minimum. Commented Feb 26, 2017 at 9:13
• ? I don't understand your comment
– Zok
Commented Feb 26, 2017 at 9:19
• We can adjust the pop() method to check if the top value ==0, if so, we erase the linked list by making min.head=null, min.head.next=null
– Zok
Commented Feb 26, 2017 at 9:28

Here is my solution in java using liked list.

``````class Stack{
int min;
Node top;
static class Node{
private int data;
private Node next;
private int min;

Node(int data, int min){
this.data = data;
this.min = min;
this.next = null;
}
}

void push(int data){
Node temp;
if(top == null){
temp = new Node(data,data);
top = temp;
top.min = data;
}
if(top.min > data){
temp = new Node(data,data);
temp.next = top;
top = temp;
} else {
temp = new Node(data, top.min);
temp.next = top;
top = temp;
}
}

void pop(){
if(top != null){
top = top.next;
}
}

int min(){
}
``````

}

``````public class MinStack<E>{

private final Comparator<E> comparator;

public MinStack(Comparator<E> comparator)
{
this.comparator = comparator;
}

/**
* Pushes an element onto the stack.
*
*
* @param e the element to push
*/
public void push(E e) {
mainStack.push(e);
if(minStack.isEmpty())
{
minStack.push(e);
}
else if(comparator.compare(e, minStack.peek())<=0)
{
minStack.push(e);
}
else
{
minStack.push(minStack.peek());
}
}

/**
* Pops an element from the stack.
*
*
* @throws NoSuchElementException if this stack is empty
*/
public E pop() {
minStack.pop();
return  mainStack.pop();
}

/**
* Returns but not remove smallest element from the stack. Return null if stack is empty.
*
*/
public E getMinimum()
{
return minStack.peek();
}

@Override
public String toString() {
StringBuilder sb = new StringBuilder();
sb.append("Main stack{");
for (E e : mainStack) {
sb.append(e.toString()).append(",");
}
sb.append("}");

sb.append(" Min stack{");
for (E e : minStack) {
sb.append(e.toString()).append(",");
}
sb.append("}");

sb.append(" Minimum = ").append(getMinimum());
return sb.toString();
}

public static void main(String[] args) {
MinStack<Integer> st = new MinStack<Integer>(Comparators.INTEGERS);

st.push(2);
Assert.assertTrue("2 is min in stack {2}", st.getMinimum().equals(2));
System.out.println(st);

st.push(6);
Assert.assertTrue("2 is min in stack {2,6}", st.getMinimum().equals(2));
System.out.println(st);

st.push(4);
Assert.assertTrue("2 is min in stack {2,6,4}", st.getMinimum().equals(2));
System.out.println(st);

st.push(1);
Assert.assertTrue("1 is min in stack {2,6,4,1}", st.getMinimum().equals(1));
System.out.println(st);

st.push(5);
Assert.assertTrue("1 is min in stack {2,6,4,1,5}", st.getMinimum().equals(1));
System.out.println(st);

st.pop();
Assert.assertTrue("1 is min in stack {2,6,4,1}", st.getMinimum().equals(1));
System.out.println(st);

st.pop();
Assert.assertTrue("2 is min in stack {2,6,4}", st.getMinimum().equals(2));
System.out.println(st);

st.pop();
Assert.assertTrue("2 is min in stack {2,6}", st.getMinimum().equals(2));
System.out.println(st);

st.pop();
Assert.assertTrue("2 is min in stack {2}", st.getMinimum().equals(2));
System.out.println(st);

st.pop();
Assert.assertTrue("null is min in stack {}", st.getMinimum()==null);
System.out.println(st);
}
}
``````
``````using System;
using System.Collections.Generic;
using System.IO;
using System.Linq;

namespace Solution
{
public class MinStack
{
public MinStack()
{
MainStack=new Stack<int>();
Min=new Stack<int>();
}

static Stack<int> MainStack;
static Stack<int> Min;

public void Push(int item)
{
MainStack.Push(item);

if(Min.Count==0 || item<Min.Peek())
Min.Push(item);
}

public void Pop()
{
if(Min.Peek()==MainStack.Peek())
Min.Pop();
MainStack.Pop();
}
public int Peek()
{
return MainStack.Peek();
}

public int GetMin()
{
if(Min.Count==0)
throw new System.InvalidOperationException("Stack Empty");
return Min.Peek();
}
}
}
``````

Saw a brilliant solution here: https://www.geeksforgeeks.org/design-a-stack-that-supports-getmin-in-o1-time-and-o1-extra-space/

Bellow is the python code I wrote by following the algorithm:

``````class Node:
def __init__(self, value):
self.value = value
self.next = None

class MinStack:
def __init__(self):
self.min = float('inf')

# @param x, an integer
def push(self, x):
self.min = x
else:
if x >= self.min:
n = Node(x)
else:
v = 2 * x - self.min
n = Node(v)
self.min = x

# @return nothing
def pop(self):
self.min = self.min * 2 - self.head.value

# @return an integer
def top(self):
self.min = self.min * 2 - self.head.value
return self.min
else:
else:
return -1

# @return an integer
def getMin(self):
return self.min
else:
return -1
``````

To getMin elements from Stack. We have to use Two stack .i.e Stack s1 and Stack s2.

1. Initially, both stacks are empty, so add elements to both stacks

---------------------Recursively call Step 2 to 4-----------------------

1. if New element added to stack s1.Then pop elements from stack s2

2. compare new elments with s2. which one is smaller , push to s2.

3. pop from stack s2(which contains min element)

Code looks like:

``````package Stack;
import java.util.Stack;
public class  getMin
{

Stack<Integer> s1= new Stack<Integer>();
Stack<Integer> s2 = new Stack<Integer>();

void push(int x)
{
if(s1.isEmpty() || s2.isEmpty())

{
s1.push(x);
s2.push(x);
}
else
{

s1. push(x);
int y = (Integer) s2.pop();
s2.push(y);
if(x < y)
s2.push(x);
}
}
public Integer pop()
{
int x;
x=(Integer) s1.pop();
s2.pop();
return x;

}
public  int getmin()
{
int x1;
x1= (Integer)s2.pop();
s2.push(x1);
return x1;
}

public static void main(String[] args) {
getMin s = new getMin();
s.push(10);
s.push(20);
s.push(30);
System.out.println(s.getmin());
s.push(1);
System.out.println(s.getmin());
}

}
``````

I have better solution, with O(1) time and with no extra space, You need to push element as String as <original_value,minimum_value>. For example find this stack of string.

|-1,-1 |

| 1,1 |

| 2,2 |

| 5,3 |

| 3,3 |

Now u can always find min value at current instance by just using peek and checking what is min value at the given instance. this is O(1) time without extra space

• Better than what, and by what measure? Few would agree your value manipulation does not use extra space - linear in the number of stacked items, at that. Commented Mar 28, 2021 at 13:29
``````class MyStackImplementation{
private final int capacity = 4;
int min;
int arr[] = new int[capacity];
int top = -1;

public void push ( int val ) {
top++;
if(top <= capacity-1){
if(top == 0){
min = val;
arr[top] = val;
}
else if(val < min){
arr[top] = arr[top]+min;
min = arr[top]-min;
arr[top] = arr[top]-min;
}
else {
arr[top] = val;
}
System.out.println("element is pushed");
}
else System.out.println("stack is full");
}

public void pop () {
top--;
if(top > -1){
min = arr[top];
}
else {min=0; System.out.println("stack is under flow");}
}

public int min(){
return min;
}

public boolean isEmpty () {
}

public static void main(String...s){
MyStackImplementation msi = new MyStackImplementation();
msi.push(1);
msi.push(4);
msi.push(2);
msi.push(10);
System.out.println(msi.min);
msi.pop();
msi.pop();
msi.pop();
msi.pop();
msi.pop();
System.out.println(msi.min);
}
}
``````

I think only push operation suffers, is enough. My implementation includes a stack of nodes. Each node contain the data item and also the minimum on that moment. This minimum is updated each time a push operation is done.

Here are some points for understanding:

• I implemented the stack using Linked List.

• A pointer top always points to the last pushed item. When there is no item in that stack top is NULL.

• When an item is pushed a new node is allocated which has a next pointer that points to the previous stack and top is updated to point to this new node.

Only difference with normal stack implementation is that during push it updates a member min for the new node.

Please have a look at code which is implemented in C++ for demonstration purpose.

``````/*
*  Implementation of Stack that can give minimum in O(1) time all the time
*  This solution uses same data structure for minimum variable, it could be implemented using pointers but that will be more space consuming
*/

#include <iostream>
using namespace std;

typedef struct stackLLNodeType stackLLNode;

struct stackLLNodeType {
int item;
int min;
stackLLNode *next;
};

class DynamicStack {
private:
int stackSize;
stackLLNode *top;

public:
DynamicStack();
~DynamicStack();
void push(int x);
int pop();
int getMin();
int size() { return stackSize; }
};

void pushOperation(DynamicStack& p_stackObj, int item);
void popOperation(DynamicStack& p_stackObj);

int main () {
DynamicStack stackObj;

pushOperation(stackObj, 3);
pushOperation(stackObj, 1);
pushOperation(stackObj, 2);
popOperation(stackObj);
popOperation(stackObj);
popOperation(stackObj);
popOperation(stackObj);
pushOperation(stackObj, 4);
pushOperation(stackObj, 7);
pushOperation(stackObj, 6);
popOperation(stackObj);
popOperation(stackObj);
popOperation(stackObj);
popOperation(stackObj);

return 0;
}

DynamicStack::DynamicStack() {
// initialization
stackSize = 0;
top = NULL;
}

DynamicStack::~DynamicStack() {
stackLLNode* tmp;
// chain memory deallocation to avoid memory leak
while (top) {
tmp = top;
top = top->next;
delete tmp;
}
}

void DynamicStack::push(int x) {
// allocate memory for new node assign to top
if (top==NULL) {
top = new stackLLNode;
top->item = x;
top->next = NULL;
top->min = top->item;
}
else {
// allocation of memory
stackLLNode *tmp = new stackLLNode;
// assign the new item
tmp->item = x;
tmp->next = top;

// store the minimum so that it does not get lost after pop operation of later minimum
if (x < top->min)
tmp->min = x;
else
tmp->min = top->min;

// update top to new node
top = tmp;
}
stackSize++;
}

int DynamicStack::pop() {
// check if stack is empty
if (top == NULL)
return -1;

stackLLNode* tmp = top;
int curItem = top->item;
top = top->next;
delete tmp;
stackSize--;
return curItem;
}

int DynamicStack::getMin() {
if (top == NULL)
return -1;
}
void pushOperation(DynamicStack& p_stackObj, int item) {
cout<<"Just pushed: "<<item<<endl;
p_stackObj.push(item);
cout<<"Current stack min: "<<p_stackObj.getMin()<<endl;
cout<<"Current stack size: "<<p_stackObj.size()<<endl<<endl;
}

void popOperation(DynamicStack& p_stackObj) {
int popItem = -1;
if ((popItem = p_stackObj.pop()) == -1 )
cout<<"Cannot pop. Stack is empty."<<endl;
else {
cout<<"Just popped: "<<popItem<<endl;
if (p_stackObj.getMin() == -1)
cout<<"No minimum. Stack is empty."<<endl;
else
cout<<"Current stack min: "<<p_stackObj.getMin()<<endl;
cout<<"Current stack size: "<<p_stackObj.size()<<endl<<endl;
}
}
``````

And the output of the program looks like this:

``````Just pushed: 3
Current stack min: 3
Current stack size: 1

Just pushed: 1
Current stack min: 1
Current stack size: 2

Just pushed: 2
Current stack min: 1
Current stack size: 3

Just popped: 2
Current stack min: 1
Current stack size: 2

Just popped: 1
Current stack min: 3
Current stack size: 1

Just popped: 3
No minimum. Stack is empty.
Current stack size: 0

Cannot pop. Stack is empty.
Just pushed: 4
Current stack min: 4
Current stack size: 1

Just pushed: 7
Current stack min: 4
Current stack size: 2

Just pushed: 6
Current stack min: 4
Current stack size: 3

Just popped: 6
Current stack min: 4
Current stack size: 2

Just popped: 7
Current stack min: 4
Current stack size: 1

Just popped: 4
No minimum. Stack is empty.
Current stack size: 0

Cannot pop. Stack is empty.
``````
``````#include<stdio.h>
struct stack
{
int data;
int mindata;
}a[100];

void push(int *tos,int input)
{
if (*tos > 100)
{
printf("overflow");
return;
}
(*tos)++;
a[(*tos)].data=input;
if (0 == *tos)
a[*tos].mindata=input;
else if (a[*tos -1].mindata < input)
a[*tos].mindata=a[*tos -1].mindata;
else
a[*tos].mindata=input;
}

int pop(int * tos)
{
if (*tos <= -1)
{
printf("underflow");
return -1;
}
return(a[(*tos)--].data);
}
void display(int tos)
{
while (tos > -1)
{
printf("%d:%d\t",a[tos].data,a[tos].mindata);
tos--;
}
}

int min(int tos)
{
return(a[tos].mindata);
}
int main()
{
int tos=-1,x,choice;
while(1)
{
printf("press 1-push,2-pop,3-mindata,4-display,5-exit ");
scanf("%d",&choice);
switch(choice)
{
case 1: printf("enter data to push");
scanf("%d",&x);
push(&tos,x);
break;
case 2: printf("the poped out data=%d ",pop(&tos));
break;
case 3: printf("The min peeped data:%d",min(tos));
break;
case 4: printf("The elements of stack \n");
display(tos);
break;
default: exit(0);
}
}
``````
• What does this answer add over, say, Ganesh M's? Commented Mar 28, 2021 at 13:31

I found this solution here

``````struct StackGetMin {
void push(int x) {
elements.push(x);
if (minStack.empty() || x <= minStack.top())
minStack.push(x);
}
bool pop() {
if (elements.empty()) return false;
if (elements.top() == minStack.top())
minStack.pop();
elements.pop();
return true;
}
bool getMin(int &min) {
if (minStack.empty()) {
return false;
} else {
min = minStack.top();
return true;
}
}
stack<int> elements;
stack<int> minStack;
};
``````
• This fails constant extra space. Commented Mar 28, 2021 at 13:34
• @greybeard and it there an answer which does not fail the constant extra space constraint ? Commented Mar 29, 2021 at 9:30
• Well, there are several hiding one bit per each stacked number, starting with Pete Kirkham's. And those increasing the cost of pop, but genuinely O(1) additional space, like Brian Rasmussen's. Problem statements on GeeksforGeeks and LeetCode, if memory serves, specify push&pop in O(1) time in addition to `getMinimum()`. Commented Mar 29, 2021 at 11:07
``````struct Node {
let data: Int
init(_ d:Int){
data = d
}
}

struct Stack {
private var backingStore = [Node]()
private var minArray = [Int]()

mutating func push(n:Node) {
backingStore.append(n)
minArray.append(n.data)
minArray.sort(>)
minArray
}

mutating func pop() -> Node? {
if(backingStore.isEmpty){
return nil
}

let n = backingStore.removeLast()

var found = false
minArray = minArray.filter{
if (!found && \$0 == n.data) {
found = true
return false
}
return true
}
return n
}

func min() -> Int? {
return minArray.last
}
}
``````