# Interview: Remove Loop in linked list - Java

I was asked this question in interview: "How to detect the loop in linked list?", I solved this but immediately the interviewer asked me how do I remove the loop in a linked list. I fumbled.

So any pointers on how to solve this, may be pseudo code, or method definition?

I'm comfortable with Java so I have tagged this question under java.

For Instance this linked list has a loop

`````` 0--->1---->2---->3---->4---->5---->6
▲                 |
|                 ▼
11<—-22<—-12<—-9<—-8
``````
• Can you define what is a loop? Apr 9, 2011 at 19:34
• @Enrique - Probably OP meant a circular list. Apr 9, 2011 at 19:35
• @Enrique : Editing my question for more details , please give me time Apr 9, 2011 at 19:36
• closely related to nomachetejuggling.com/2014/06/24/… Aug 29, 2014 at 16:21

There are two parts to this problem:

1. Detect if there is a loop in the list
2. Identify the start of the loop

Once you know where the loop starts, it's easy to identify the last element in the list since it's the element in the list following the start of the loop that ends up pointing back to the start of the loop. It is then trivial to set the next pointer/reference of this element to `null` to correct the cyclic link list (not circular linked list which is where the last elements points back to the first - this would be a specific instance of cyclic lists).

1. Floyd's cycle detect algorithm, also called the tortoise and hare algorithm as it involves using two pointers/references that move at different speeds, is one way of detecting the cycle. If there is a cycle, the two pointers (say `p1` and `p2`) will end up pointing to the same element after a finite number of steps. Interestingly, it can be proved that the element at which they meet will be the same distance to the start of the loop (continuing to traverse the list in the same, forward direction) as the start of the loop is to the head of the list. That is, if the linear part of the list has `k` elements, the two pointers will meet inside the loop of length `m` at a point `m-k` from the start of the loop or `k` elements to the 'end' of the loop (of course, it's a loop so it has no 'end' - it's just the 'start' once again). And that gives us a way to find the start of the loop:

2. Once a cycle has been detected, let `p2` remain pointing to the element where the loop for the step above terminated but reset `p1` so that it's pointing back to the head of the list. Now, move each pointer one element at a time. Since `p2` began inside the loop, it will continue looping. After `k` steps (equal to the distance of the start of the loop from the head of the list), `p1` and `p2` will meet again. This will give you a reference to the start of the loop.

3. It is now easy to set `p1` (or `p2`) to point to the element starting the loop and traverse the loop until `p1` ends up pointing back to the starting element. At this point `p1` is referencing the 'last' element list and it's next pointer can be set to `null`.

Here's some quick and dirty Java code assuming a linked list of `Node`s where a `Node` has a `next` reference. This could be optimized but it should give you the basic idea:

``````Node slow, fast, start;

//PART I - Detect if a loop exists
while (true)
{
// fast will always fall off the end of the list if it is linear
if (fast == null || fast.next == null)
{
// no loop
return;
}
else if (fast == slow || fast.next == slow)
{
// detected a loop
break;
}
else
{
fast = fast.next.next; // move 2 nodes at at time
slow = slow.next; // move 1 node at a time
}
}

//PART II - Identify the node that is the start of the loop
fast = head; //reset one of the references to head of list

//until both the references are one short of the common element which is the start of the loop
while(fast.next != slow.next)
{
fast = fast.next;
slow = slow.next;
}

start = fast.next;

//PART III - Eliminate the loop by setting the 'next' pointer
//of the last element to null
fast = start;
while(fast.next != start)
{
fast = fast.next;
}

fast.next = null; //break the loop
``````

This explanation might help the why behind Part II:

Assume the length of the cycle is M, and the length of the rest of the linked list is L. Let's figure out what is the position in the cycle when t1/t2 first meet?

Define the first node in the cycle is position 0, following the links we have position 1, 2,..., up to M-1. ( when we walk in the cycle, our current position is (walk_length) mod M, right?) Suppose t1/t2 first meet at position p, then their travel time are the same, (L+k1*M+p)/v = (L+k2*M+p)/2v for some k1

So it concludes that if t1 start from p, t2 start from head and move at the same speed, then will grantee to meet at position 0, the first node of the cycle. QED.

More references:

• I really liked learning from your answer, thanks for the thoroughness as well as the link. Apr 9, 2011 at 20:42
• I don't get this part under "until both the references are one short..." since they move at the same speed now, it seems like `fast.next` may never be `slow.next` (they chase each-other around the cycle forever).
– user166390
Apr 9, 2011 at 20:47
• @no.good.at.coding But if they don't meet where the loop starts then they will never meet. I don't see how it is guaranteed that they do meet there.
– user166390
Apr 9, 2011 at 20:52
• I'm not sure your `k` is guaranteed to be correct, as you cannot be certain where in the loop the hare meets the tortoise. Apr 9, 2011 at 21:03
• @no.good.at.coding Yeah, that was the part I was missing. A +1 for you, sir.
– user166390
Apr 9, 2011 at 21:38

Solution 1 - courtesy of Career Cup and "Cracking the Coding Interview" book:

``````public static LinkedListNode findStartOfLoop(LinkedListNode head) {

// find meeting point using Tortoise and Hare algorithm
// this is just Floyd's cycle detection algorithm
while (n2.next != null) {
n1 = n1.next;
n2 = n2.next.next;
if (n1 == n2) {
break;
}
}

// Error check - there is no meeting point, and therefore no loop
if (n2.next == null) {
return null;
}

/* Move n1 to Head. Keep n2 at Meeting Point.  Each are k steps
/* from the Loop Start. If they move at the same pace, they must
* meet at Loop Start. */
while (n1 != n2) {
n1 = n1.next;
n2 = n2.next;
}
// Now n2 points to the start of the loop.
return n2;
}
``````

The explanation for this solution is straight from the book:

If we move two pointers, one with speed 1 and another with speed 2, they will end up meeting if the linked list has a loop. Why? Think about two cars driving on a track; the faster car will always pass the slower one!

The tricky part here is finding the start of the loop. Imagine, as an analogy, two people racing around a track, one running twice as fast as the other. If they start off at the same place, when will they next meet? They will next meet at the start of the next lap.

Now, let’s suppose Fast Runner had a head start of k meters on an n step lap. When will they next meet? They will meet k meters before the start of the next lap. (Why? Fast Runner would have made k + 2(n - k) steps, including its head start, and Slow Runner would have made n - k steps Both will be k steps before the start of the loop ).

Now, going back to the problem, when Fast Runner (n2) and Slow Runner (n1) are moving around our circular linked list, n2 will have a head start on the loop when n1 enters. Specifically, it will have a head start of k, where k is the number of nodes before the loop. Since n2 has a head start of k nodes, n1 and n2 will meet k nodes before the start of the loop.

So, we now know the following:

1. Head is k nodes from LoopStart (by definition)
2. MeetingPoint for n1 and n2 is k nodes from LoopStart (as shown above)

Thus, if we move n1 back to Head and keep n2 at MeetingPoint, and move them both at the same pace, they will meet at LoopStart

Solution 2 - courtesy of me :)

``````public static LinkedListNode findHeadOfLoop(LinkedListNode head) {

int indexer = 0;
indexer++;

// start walking along the list while putting each node in the HashMap
// if we come to a node that is already in the list,
// then that node is the start of the cycle
while (curr != null) {

if (map.containsKey(curr.next)) {
curr = curr.next;
break;
}
curr = curr.next;
map.put(curr, indexer);
indexer++;
}
return curr;
}
``````

I hope this helps.
Hristo

• I see same problem with this as with no.good.at.coding -- the "while n1 is different than n2" may not terminated because there is no guarantee that n1 and n2 will ever be equal because "n1 starts at head", but n2 "starts somewhere the rabbit and hair met in the cycle". If they don't meet at the loop itself then they will both get stuck in the cycle chasing each-other at the same speed. Because the lead-up to the cycle differs and the cycle-length differs, not sure there is a guarantee that distance head -> cycleNode = distance meetingNode -> cycleNode.
– user166390
Apr 9, 2011 at 21:26
• However, I am failing at coming up with a counter-case, please help! :p (See no.good.at.coding's answer and links which explains why I can't find a counter-case ;-). A +1 for this answer as well. Same reasoning.
– user166390
Apr 9, 2011 at 21:37
• I'm just going to quote the interview book I read and paste their explanation to Solution 1 marked above. Apr 9, 2011 at 21:41
• Your solution (2) seems to only work if the linked list has unique items. Apr 10, 2011 at 7:19
• @Hristo - Your approach relies on the uniqueness of list items so it cannot truly address the existence of a loop or cycle. The only true uniqueness of non-unique item VALUES would be the memory address of the objects representing those items or perhaps an ID of a non-primitive object containing the value. Since Java doesn't allow you to see machine address (I think), you'd have to go with the latter. This is also because (I think) Java's CONTAINS method uses an class's EQUALS method, which compares the hash code of an object and not the memory address. Apr 10, 2011 at 8:14

This response is not meant to compete for the answer, but rather to explain a little more on the meeting of the two nodes in the tortoise and the hare algorithm.

1. Both nodes will eventually enter the loop. Because one moves faster (F) than the other (S), (F) will eventually lap (S).

2. If the loop's start is at the list's head, (F) must meet (S) back at the list's head. This is ONLY because (F)'s speed is 2X (S)'s; if it was 3X this then would not be true. This is true because (F) completes one lap when (S) completes half a lap, so when (S) completes its first lap, (F) has completed two laps - and is back at the start of the loop with (S).

3. If the loop's start is NOT at the list's head, then by the time (S) enters the loop, (F) has had a head start of (k) nodes in the loop. Because (S)'s speed is only one node at a time, it will meet (F) at (k) nodes from the loop's start - as in, (k) more steps before reaching the start, NOT (k) steps AFTER the start. This would NOT be true if (S)'s speed was not one and the speed ratio was not 2:1 between (F) and (S).

3.1. This is where it gets a little tricky to explain. We can agree that (F) will continue lapping (S) until they eventually meet (see 1 above), but why at (k) nodes from the loop's start? Consider the following equation where M is the number of nodes or distance of the loop and k is the head start (F) had; the equation represents distance traveled by (F) given time t on the left in terms of distance traveled by (S) on the right:

d_F(t) = 2 * d_S(t) + k

So when (S) enters the loop and has traveled 0 distance in the loop, (F) has traveled only the (k) distance. By the time d_S = M - k, d_F = 2M - k. Because we also have to use modular math in consideration that M represents the total distance of a single lap in the loop, the POSITION of (F) and (S) at any whole M (no remainder) is 0. So then in terms of POSITION (or the differential), this leaves k (or rather, -k).

And so finally, (S) and (F) will meet at position (0 - k), or (k) nodes away from the start of the loop.

4. Given [3] above, as (k) represents the head start (F) had, and as (F) had traveled 2X the distance (S) traveled to enter the loop from the head of the list, (k) also represents the distance from the list's start, which then represents the start of the loop.

It's a bit late here so I hope I've articulated effectively. Let me know otherwise and I'll try and update my response.

• Bitxwise.. neat, but care to add code, like method definition ? Apr 10, 2011 at 18:30
• @SuperMan - no.good.at.coding's answer includes a code example but he had difficulty explaining why the algorithm actually works (i.e. why the 2 nodes are guaranteed to meet at a particular point that indicates the beginning of the loop). I was merely adding my 2 cents on why/how the tortoise/hare algorithm works. no.good.at.coding's code example could definitely be cleaner and perhaps I can add a cleaner coding example later - but to no.good.at.coding's credit, he, himself, admitted the code example was quick and dirty. Apr 10, 2011 at 20:34

If using an identity hash map (such as IdentityHashMap) is permissible this is terribly easy to solve. It does use more space, though.

Traverse the nodes list. For each node encountered, add it to the identity map. If the node already existed in the identity map then the list has a circular link and the node which was prior to this conflict is known (either check before moving or keep the "last node") -- simply set "next" as appropriate to break the cycle.

Following this simple approach should be a fun exercise: code is left as an exercise for the reader.

Happy coding.

• Maybe finally this will turn out to be the only way. But I just do not want to give up too soon. XD Apr 9, 2011 at 20:54
• @Dante Jiang It's not the only way. no.good.at.coding is onto something and his approach can be adapted. Once the cycle is detected, keep running the rabbit/hair, but this time, build up the list which is the inverse of where the rabbit/hair met the 2nd time (each time), if care is taken to ensure the rabbit/hair don't meet at the same place, this new list will be smaller and will include the cycle node until the list will be a cycle length of one (or two). If two, walk from head until this cycle is intercepted (gives exact node), then keep walking until the node before that node...
– user166390
Apr 9, 2011 at 21:06
• Well, I was wrong. Both the answers with the rabbit/hair cycle detection work. It's a curious property of where they are guaranteed to meet if finding a cycle when both starting from head (try to work out a counter-case like me ;-). In any case, the above solution will still work, even if not ideal for this.
– user166390
Apr 9, 2011 at 21:39
• Can't we we it using a normal HashMap ? Jan 13, 2014 at 7:11
`````` 0--->1---->2---->3---->4---->5---->6
▲                 |
|                 ▼
11<—-22<—-12<—-9<—-8
``````

Insert dummy node after every node of link list and before inserting check that node next to next is dummy or not. If next to next is dummy, insert null in next of that node.

`````` 0-->D->1-->D->2-->D->3->D-->4->D-->5->D-->6
▲                      |
/                         ▼
11<—D<-22<—D<-12<—D<-9<—D<--8

Node(11)->next->next == D
Node(11)->next =null
``````
``````//Find a Loop in Linked List and remove link between node

public void findLoopInList() {
boolean isLoopExist = false;
while (slowNode != null && fastNode != null && fastNode.next != null) {
fastNode = fastNode.next.next;
slowNode = slowNode.next;
if (slowNode == fastNode) {
System.out.print("\n Loop Found");
isLoopExist = true;
break;
}
}
if (isLoopExist) {
Node prevNode = null;
while (slowNode != fastNode) {
prevNode = fastNode;
fastNode = fastNode.next;
slowNode = slowNode.next;
}
System.out.print("Loop Found Node : " + slowNode.mData);
prevNode.next = null; //Remove the Loop
}
}
``````

:)GlbMP

## Easiest and unique way

To solve this problem we just count no of nodes (that's it). I bet you haven't seen this solution till now in any competitive website, because i made it today on my own...

``````void removeTheLoop(Node *root)
{
std :: unordered_set < struct Node * > s;
if(root == NULL)
return ;

s.insert(root);
int before_size = s.size();

while(1)
{
if(root -> next == NULL)
return;
s.insert(root -> next);
if(before_size == s.size())
{
root -> next = NULL;
return;
}
before_size = s.size();
root = root -> next;
}
}
``````

How it works:

TIME COMPLEXITY: O(n)...SPACE COMPLEXITY: O(n)

• It simply counts the no of elements. We will take unordered_set in c++.
• It inserts the element if it is not present in the container and increases its size.
• Now the suspense begins when the node comes that point to the node that already added , so in that case size doesn't increase and we will make next to that as NULL.