Given a linked list and two keys in it, swap nodes for two given keys. Nodes should be swapped by changing links. Swapping data of nodes may be expensive in many situations when data contains many fields.
It may be assumed that all keys in the linked list are distinct.
Examples:
Input : 10->15->12->13->20->14, x = 12, y = 20 Output: 10->15->20->13->12->14 Input : 10->15->12->13->20->14, x = 10, y = 20 Output: 20->15->12->13->10->14 Input : 10->15->12->13->20->14, x = 12, y = 13 Output: 10->15->13->12->20->14
This may look a simple problem, but is an interesting question as it has the following cases to be handled.
- x and y may or may not be adjacent.
- Either x or y may be a head node.
- Either x or y may be the last node.
- x and/or y may not be present in the linked list.
How to write a clean working code that handles all the above possibilities.
The idea is to first search x and y in the given linked list. If any of them is not present, then return. While searching for x and y, keep track of current and previous pointers. First change next of previous pointers, then change next of current pointers.
Below is the implementation of the above approach.
# Python program to swap two given nodes # of a linked list class LinkedList( object ):
def __init__( self ):
self .head = None
# Head of list
class Node( object ):
def __init__( self , d):
self .data = d
self . next = None
# Function to swap Nodes x and y
# in a linked list by changing links
def swapNodes( self , x, y):
# Nothing to do if x and y are
# the same
if x = = y:
return
# Search for x (keep track of
# prevX and CurrX)
prevX = None
currX = self .head
while currX ! = None and currX.data ! = x:
prevX = currX
currX = currX. next
# Search for y (keep track of
# prevY and currY)
prevY = None
currY = self .head
while currY ! = None and currY.data ! = y:
prevY = currY
currY = currY. next
# If either x or y is not present,
# nothing to do
if currX = = None or currY = = None :
return
# If x is not head of linked list
if prevX ! = None :
prevX. next = currY
else : # make y the new head
self .head = currY
# If y is not head of linked list
if prevY ! = None :
prevY. next = currX
else :
# make x the new head
self .head = currX
# Swap next pointers
temp = currX. next
currX. next = currY. next
currY. next = temp
# Function to add Node at beginning
# of list.
def push( self , new_data):
# 1. alloc the Node and put the data
new_Node = self .Node(new_data)
# 2. Make next of new Node as head
new_Node. next = self .head
# 3. Move the head to point to new Node
self .head = new_Node
# This function prints contents of
# linked list starting from the given Node
def printList( self ):
tNode = self .head
while tNode ! = None :
print tNode.data,
tNode = tNode. next
# Driver code llist = LinkedList()
# The constructed linked list is: # 1->2->3->4->5->6->7 llist.push( 7 )
llist.push( 6 )
llist.push( 5 )
llist.push( 4 )
llist.push( 3 )
llist.push( 2 )
llist.push( 1 )
print "Linked list before calling swapNodes() "
llist.printList() llist.swapNodes( 4 , 3 )
print "
Linked list after calling swapNodes() "
llist.printList() # This code is contributed by BHAVYA JAIN |
Output:
Linked list before calling swapNodes() 1 2 3 4 5 6 7 Linked list after calling swapNodes() 1 2 4 3 5 6 7
Time Complexity: O(n)
Auxiliary Space: O(1)
Optimizations: The above code can be optimized to search x and y in single traversal. Two loops are used to keep program simple.
Simpler approach:
# Python3 program to swap two given # nodes of a linked list # A linked list node class class Node:
# constructor
def __init__( self , val = None ,
next1 = None ):
self .data = val
self . next = next1
# Print list from this
# to last till None
def printList( self ):
node = self
while (node ! = None ):
print (node.data, end = " " )
node = node. next
print ( " " )
# Function to add a node # at the beginning of List def push(head_ref, new_data):
# Allocate node
(head_ref) = Node(new_data, head_ref)
return head_ref
def swapNodes(head_ref, x, y):
head = head_ref
# Nothing to do if x and y are same
if (x = = y):
return None
a = None
b = None
# Search for x and y in the linked list
# and store their pointer in a and b
while (head_ref. next ! = None ):
if ((head_ref. next ).data = = x):
a = head_ref
elif ((head_ref. next ).data = = y):
b = head_ref
head_ref = ((head_ref). next )
# If we have found both a and b
# in the linked list swap current
# pointer and next pointer of these
if (a ! = None and b ! = None ):
temp = a. next
a. next = b. next
b. next = temp
temp = a. next . next
a. next . next = b. next . next
b. next . next = temp
return head
# Driver code start = None
# The constructed linked list is: # 1.2.3.4.5.6.7 start = push(start, 7 )
start = push(start, 6 )
start = push(start, 5 )
start = push(start, 4 )
start = push(start, 3 )
start = push(start, 2 )
start = push(start, 1 )
print ( "Linked list before calling swapNodes() " )
start.printList() start = swapNodes(start, 6 , 1 )
print ( "Linked list after calling swapNodes() " )
start.printList() # This code is contributed by Arnab Kundu |
Output:
Linked list before calling swapNodes() 1 2 3 4 5 6 7 Linked list after calling swapNodes() 6 2 3 4 5 1 7
Time Complexity: O(n)
Auxiliary Space: O(1)
Please refer complete article on Swap nodes in a linked list without swapping data for more details!