Given two lists sorted in increasing order, create and return a new list representing the intersection of the two lists. The new list should be made with its own memory — the original lists should not be changed.
Example:
Input: First linked list: 1->2->3->4->6 Second linked list be 2->4->6->8, Output: 2->4->6. The elements 2, 4, 6 are common in both the list so they appear in the intersection list. Input: First linked list: 1->2->3->4->5 Second linked list be 2->3->4, Output: 2->3->4 The elements 2, 3, 4 are common in both the list so they appear in the intersection list.
Method: Using Dummy Node.
Approach:
The idea is to use a temporary dummy node at the start of the result list. The pointer tail always points to the last node in the result list, so new nodes can be added easily. The dummy node initially gives the tail a memory space to point to. This dummy node is efficient, since it is only temporary, and it is allocated in the stack. The loop proceeds, removing one node from either ‘a’ or ‘b’ and adding it to the tail. When the given lists are traversed the result is in dummy. next, as the values are allocated from next node of the dummy. If both the elements are equal then remove both and insert the element to the tail. Else remove the smaller element among both the lists.
Below is the implementation of the above approach:
Python3
# Python program to implement # the above approach # Link list node class Node: def __init__( self ): self .data = 0 self . next = None ''' This solution uses the temporary dummy to build up the result list ''' def sortedIntersect(a, b): dummy = Node() tail = dummy; dummy. next = None ; ''' Once one or the other list runs out -- we're done ''' while (a ! = None and b ! = None ): if (a.data = = b.data): tail. next = push((tail. next ), a.data); tail = tail. next ; a = a. next ; b = b. next ; # Advance the smaller list elif (a.data < b.data): a = a. next ; else : b = b. next ; return (dummy. next ); ''' UTILITY FUNCTIONS ''' ''' Function to insert a node at the beginning of the linked list ''' def push(head_ref, new_data): # Allocate node new_node = Node() # Put in the data new_node.data = new_data; # Link the old list off the new node new_node. next = (head_ref); # Move the head to point to the # new node (head_ref) = new_node; return head_ref ''' Function to print nodes in a given linked list ''' def printList(node): while (node ! = None ): print (node.data, end = ' ' ) node = node. next ; # Driver code if __name__ = = '__main__' : # Start with the empty lists a = None ; b = None ; intersect = None ; ''' Let us create the first sorted linked list to test the functions Created linked list will be 1.2.3.4.5.6 ''' a = push(a, 6 ); a = push(a, 5 ); a = push(a, 4 ); a = push(a, 3 ); a = push(a, 2 ); a = push(a, 1 ); ''' Let us create the second sorted linked list. Created linked list will be 2.4.6.8 ''' b = push(b, 8 ); b = push(b, 6 ); b = push(b, 4 ); b = push(b, 2 ); # Find the intersection two linked lists intersect = sortedIntersect(a, b); print ( "Linked list containing common items of a & b " ); printList(intersect); # This code is contributed by rutvik_56. |
Output:
Linked list containing common items of a & b 2 4 6
Complexity Analysis:
- Time Complexity: O(m+n) where m and n are number of nodes in first and second linked lists respectively.
Only one traversal of the lists are needed. - Auxiliary Space: O(min(m, n)).
The output list can store at most min(m,n) nodes .
Please refer complete article on Intersection of two Sorted Linked Lists for more details!
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