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

```
public static LinkedListNode findStartOfLoop(LinkedListNode head) {
LinkedListNode n1 = head;
LinkedListNode n2 = 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. */
n1 = head;
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:

- Head is k nodes from LoopStart (by definition)
- 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;
Map<LinkedListNode, Integer> map = new IdentityHashMap<LinkedListNode, Integer>();
map.put(head, indexer);
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
LinkedListNode curr = head;
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