# Single Linked List is Palindrome or not

I have a Single Linked List. I want to find that Linked List is Palindrome or not. I have implemented it in One way as below.

``````bool palindromeOrNot(node *head) {
node *tailPointer;
int response=1;

while(headLocal != NULL && reverseList!=NULL) {
reverseList=reverseList->next;
}
else
return false;
}

return fasle;
else
return true;
}
``````

I am reversing the original Linked List and then comparing Node by Node. If everything is fine then I will return 1 else return 0.

Is there a better algorithm to solve the problem.

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Not a solution, just a tip: Your function is finding out whether something is or isn't true. So it should return a `bool`, not an `int`. Similarly, calling it `palindromeOrNot` is ambiguous. `isPalindrome` would make more sense. –  Widor Nov 1 '11 at 12:04
Ok.Thanks.BUt can you suggest some answer –  aj983 Nov 1 '11 at 12:06

If your linked list is single-linked, your solution is optimal. Its time is `O(n)` and space `O(n)`.

If your linked list is double-linked, you can improve it by using two pointers, one coming down from the tail, one going up from the head, and comparing the values as you reach them. Break and return `false` if you find differences, return `true` when the pointers meet or pass each other. This would be `O(n)` time and `O(1)` space, as a new list is not generated, and thus more efficient.

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+1 for indicating that the solution is optimal and clearly explaining to the op the differences. –  JonH Nov 1 '11 at 12:20

METHOD 1 (Use a Stack)

A simple solution is to use a stack of list nodes. This mainly involves three steps.

1. Traverse the given list from head to tail and push every visited node to stack.
2. Traverse the list again. For every visited node, pop a node from stack and compare data of popped node with currently visited node.
3. If all nodes matched, then return true, else false.

Time complexity of above method is O(n), but it requires O(n) extra space. Following methods solve this with constant extra space.

METHOD 2 (By reversing the list)

This method takes O(n) time and O(1) extra space.

1. Get the middle of the linked list.
2. Reverse the second half of the linked list.
3. Check if the first half and second half are identical.
4. Construct the original linked list by reversing the second half again and attaching it back to the first half

METHOD 3 (Using Recursion)

Use two pointers left and right. Move right and left using recursion and check for following in each recursive call.

1. Sub-list is palindrome.
2. Value at current left and right are matching.

If both above conditions are true then return true.

The idea is to use function call stack as container. Recursively traverse till the end of list. When we return from last NULL, we will be at last node. The last node to be compared with first node of list.

In order to access first node of list, we need list head to be available in the last call of recursion. Hence we pass head also to the recursive function. If they both match we need to compare (2, n-2) nodes. Again when recursion falls back to (n-2)nd node, we need reference to 2nd node from head. We advance the head pointer in previous call, to refer to next node in the list.

However, the trick in identifying double pointer. Passing single pointer is as good as pass-by-value, and we will pass the same pointer again and again. We need to pass the address of head pointer for reflecting the changes in parent recursive calls.

More: geeksforgeeks

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Note that link-only answers are discouraged, SO answers should be the end-point of a search for a solution (vs. yet another stopover of references, which tend to get stale over time). Please consider adding a stand-alone synopsis here, keeping the link as a reference. –  kleopatra Dec 6 '13 at 15:26

`Whether a single-linked list is Palindrome or not`, can also be checked `without reversing the linked list`

A recursive approach can be approached where a pointer pointing to the start of the linked list, & another pointer returning from the recursion from the last will be compared.

Here is the pseudo code:

``````int isPalindrome(**root,*head)
{
return 1;
else
{

if(res==0)
return 0;
*root=(*root)->next;
return r;
}
}
``````

Call is made like: `isPalindrome(&root,root);`

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What if the list huge ? I'm a bit worried about stack corruption with recursion .. –  Uday Oct 25 '13 at 16:50

When we compare the linked list to the reversed list, we can only actually need to compare the first half of the list. If the first half of the normal list matches the first half if the reverse list, then the second half of the normal list must match the second half of the reversed list.

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Why are you Making it complex. Since this is a home work.i can just give you a simple suggestion. I observe that you are only comparing the id's in your code. let's say your id is a char,why dont you simply traverse the list once and store the char's in an array and then check the for palindrome. your way simply reverses the linked list once and traverse the linked list twice totally there are three traversals in the function.

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space complexity issue i guess –  Uday Oct 25 '13 at 16:50

I think you could get a better solution in terms of having O(1) memory usage and the same O(n) speed. By working with the linked list in place. You don't necessary have to create a reversed copy of the linked list. However this methods destroys the list. You will have to stitch it back into place, but the running time will still be O(n).

The code for the fast version of isPalindrome basically finds the middle of the linked list, then logically chunks the linked list into 2 pieces. It reverses only the first piece in place and compares it with the other piece. The bad part is it destroys the linked list due to the in place reversal on the first linked list chunk. However you can stitch the lists back together in place and still be in O(n) time.

The function to look at is isPalindromeFast. I started but haven't finished stitchlistsbacktogether. You can run the code in Go play here http://play.golang.org/p/3pb4hxdRIp .

Here is full code in Go.

``````package main

import "fmt"

type Node struct {
value string
next  *Node
}

func (n *Node) Next() *Node {
return n.next
}

func (n *Node) Value() string {
return n.value
}

func (n *Node) Length() int {
length := 0
length += 1
}

return length
}

if len(s) == 0 {
return nil
}

for _, v := range s[1:] {
newNode := &Node{string(v), nil}
currentNode.next = newNode
currentNode = newNode
}

}

}
}

func ReverseList(linkedList *Node, endPoint int) *Node {

if endPoint == 1 {
}

lastNode = nil

for i := 0; i < endPoint; i++ {
next = first.Next()
first.next = lastNode
lastNode = first
first = next

}

return lastNode

}

// func StitchListsBackTogether(listA, listB, listC *Node, endOfListA int) *Node {
//  listAFixed := ReverseList(listA, endOfListA)
//  listStart := listAFixed
//  for listAFixed.Next() != nil {
//      listAFixed = listAFixed.Next()
//  }
//  listAFixed.next = listB

//  return listStart

// }

// Uses O(1) space and O(n) time
// However mutates and destroys list, so need to stitch list backtogether.  Initial implementation StitchListsBackTogether

endOfListA := length / 2
endOfListB := length / 2

if length%2 == 0 {
endOfListB += 1
} else {
endOfListB += 2
}

for i := 0; i < endOfListB-1; i++ {
listB = listB.Next()
}

listA = ReverseList(listA, endOfListA)

for listA != nil && listB != nil {
if listA.Value() != listB.Value() {
return false
}
listA = listA.Next()
listB = listB.Next()
}

return true
}

//Uses O(1) space and O(n^2) time

for endPalidrome.Next() != nil {
endPalidrome = endPalidrome.Next()
}

for startPalidrome != endPalidrome {

if startPalidrome.Value() != endPalidrome.Value() {
return false
}

if startPalidrome.Next() == endPalidrome {
return true
}

startPalidrome = startPalidrome.Next()

middlePalidrome := startPalidrome

for middlePalidrome.Next() != endPalidrome {
middlePalidrome = middlePalidrome.Next()
}
endPalidrome = middlePalidrome

}

return true
}

func main() {

fmt.Println("")
fmt.Println("")
fmt.Println("")
fmt.Println("")
fmt.Println("")
fmt.Println("")
fmt.Println("")

}
``````
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Here is my solution to this problem. To test it I used integers instead of chars forexample I used 1,4,1,4,1 instead "adada". You can change int to char and everything should still be working

``````struct Node
{
Node(int in) : data(in) {}
int data;
Node* next;
};

//This function will find recursively call itself until last element and than it will start    //comparing. To compare with correct element from the beginning a paramater called pos is used
bool palindromeStart(Node* first, Node* last, size_t pos, size_t middlePos)
{
if (last->next != NULL)
{
if (palindromeStart(first, last->next, pos + 1, middlePos) == false)
return false;
}

size_t curPos  = middlePos - pos;
while (curPos--)
first = first->next;

if (first->data != last->data)
return false;
return true;
}

{
size_t middlePos = 0;
while (true)
{
if (n2 == nullptr)
{
--middlePos;
break;
}
else if ( n2->next == nullptr)
{
break;
}

n2 = n2->next->next;
n1 = n1->next;
++middlePos;
}  // Until now I just find the middle

}

int main()
{
Node* n = new Node(1);
Node* n1 = new Node(4);
Node* n2 = new Node(4);
Node* n3 = new Node(1);
Node* n4 = new Node(1);

n->next = n1;
n1->next = n2;
n2->next = n3;
n3->next = nullptr;
//n3->next = n4;
//n4->next = nullptr;

std::cout << isPalindrome(n);

}
``````
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Just `reverse` half of the linked list. And start comparing. You don't need to `reverse` the whole linked list.

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I think the optimal solution would be to NOT using extra space, meaning NOT to use a new reversed LL... the idea is to take advantage of the operation stack that recursion uses... because when the recursion had reached the base case, it would start popping the stack from the last inserted node, which is the last node of the LL... I'm actually half way through this and hit a wall.. some how the root and the last node are offset... see my code

``````public LLNode compare(LLNode root) {
//
// base case, popping opr stack,
// this should be the last node on the linked list
if (root.next == null) {
System.out.printf("Poping stack: %d\n", root.data);
return root;
}

//
// push the functions to the opr stack
System.out.printf("pushing %d to the stack\n", root.next.data);
LLNode last = compare(root.next);
System.out.printf("On the way back: %d, root: %d\n", last.data, root.data);

return root;
}
``````

And the output looks like this:

``````The list looks like this:
1 2 3 4 3 2 1
pushing 2 to the stack
pushing 3 to the stack
pushing 4 to the stack
pushing 3 to the stack
pushing 2 to the stack
pushing 1 to the stack
Poping stack: 1
On the way back: 1, root: 2
On the way back: 2, root: 3
On the way back: 3, root: 4
On the way back: 4, root: 3
On the way back: 3, root: 2
On the way back: 2, root: 1
``````

If you can figure it out, please let me know too

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