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Stack Using Linked List

A stack is a linear data structure which is based on the principle that the elements in a stack are added and removed only from one end, which is called the TOP. Hence, a stack is called a LIFO (Last-In-First-Out) data structure, as the element that was inserted last is the first one to be taken out. Stack supports two basic operations: push and pop.

Algorithm

Push

A push operation is used to insert an element into the stack. The new element is added at the topmost position of the stack.

  • Create a NEW_NODE with given value.
  • Check whether stack is EMPTY (TOP == NULL)
  • If it is EMPTY, then set NEW_NODE → NEXT = NULL.
  • If it is NOT EMPTY, then set NEW_NODE → NEXT = TOP.
  • Finally, set TOP = NEW_NODE.

Pop

The pop operation is used to delete the topmost element from the stack and returns the deleted element. But before deleting element we must check if TOP=NULL, because if this is the case, then it means that the stack is empty and no more deletions can be done and stack is Underflow.

  • Check whether STACK is EMPTY (TOP == NULL).
  • If it is EMPTY, then display "Stack Underflow ! and terminate the function
  • If it is NOT EMPTY, then define a NODE pointer 'TEMP' and set it to 'TOP'.
  • Then set 'TOP = TOP → NEXT'.
  • Finally, delete 'TEMP'. (FREE(TEMP))

Pseudocodes

Structure of Stack

typedef struct node
{
  int data;
  struct node *next;
}node;

Push Operation

Step 1: Allocate memory for the new node and name it as NEW_NODE
Step 2: SET NEW_NODE-->DATA = VAL
Step 3: IF TOP == NULL
            SET NEW_NODE--> NEXT = NULL
            SET TOP = NEW_NODE
        ELSE
            SET NEW_NODE-->NEXT = TOP
            SET TOP = NEW_NODE
        [END OF IF]
Step 4: END

Pop Operation

Step 1: IF TOP == NULL
            PRINT "UNDERFLOW !!"
            Goto Step 5
        [END OF IF]
Step 2: SET TEMP = TOP
Step 3: SET TOP = TOP-->NEXT
Step 4: FREE TEMP
Step 5: END

Complexity

Time Complexity:

  • Push : O(1)
  • Pop : O(1)

Space Complexity : O(n)

Implementation