# Why increase pointer by two while finding loop in linked list, why not 3,4,5?

I had a look at question already which talk about algorithm to find loop in a linked list. I have read Floyd's cycle-finding algorithm solution, mentioned at lot of places that we have to take two pointers. One pointer( slower/tortoise ) is increased by one and other pointer( faster/hare ) is increased by 2. When they are equal we find the loop and if faster pointer reaches null there is no loop in the linked list.

Now my question is why we increase faster pointer by 2. Why not something else? Increasing by 2 is necessary or we can increase it by X to get the result. Is it necessary that we will find a loop if we increment faster pointer by 2 or there can be the case where we need to increment by 3 or 5 or x.

-
Unfortunately, articles like the first one you link to (floyd's algorithm) is written by people that aren't too concerned about teaching others how to understand the algorithm. I can accept that the algorithm works, but I've yet to find a good english description of why it works. Hopefully this answer will get that description. –  Lasse V. Karlsen Feb 26 '11 at 22:59
@Lasse same is the case with me, I understand it works but don't understand how and what is the logic behind this. –  GG. Feb 26 '11 at 23:03
Take a look at Brent's algorithm, it is better anyway. –  starblue Jun 9 '12 at 17:18

let us suppose the length of the list which does not contain the loop be s. length of the loop be t. the ratio of fast_pointer_speed : slow_pointer_speed = k;

let the two pointers meet up at a distance j from the start of the loop.

So the distance slow pointer travels = s + j; Distance the fast pointer travels = s + j + m X t But the first pointer would also has traveled a distance k X (s + j) (k times the distance of the slow pointer.)

therefore , we get k X (s + j) = s + j + m X t .

s + j = (m / k-1)t.

Hench from the above equation , length the slow pointer travels is an integer multiple of the loop length.

For greatest efficiency , (m / k-1) = 1 (the slow pointer shouldn't have traveled the loop more than once.)

therefore , m = k - 1 => k = m + 1

Since m is the no.of times the fast pointer has completed the loop , m >= 1 . For greatest efficiency , m = 1.

therefore k = 2.

if we take a value of k > 2 , more the distance the two pointers would have to travel.

Hope the above explanation helps.

-
simple and excellent proof –  starkk92 Dec 4 '14 at 14:44

If the linked list has a loop then a fast pointer with increment of 2 will work better then say increment of 3 or 4 or more because it ensures that once we are inside the loop the pointers will surely collide and there will be no overtaking.

For example if we take increment of 3 and inside the loop lets assume

``````fast pointer --> i
slow         --> i+1
the next iteration
fast pointer --> i+3
slow         --> i+2
``````

whereas such case will never happen with increment of 2.

Also if you are really unlucky then you may end up in a situation where loop length is `L` and you are incrementing the fast pointer by `L+1`. Then you will be stuck infinitely since the difference of the movement fast and slow pointer will always be `L`.

I hope I made myself clear.

-
Even if the loop length is L, it's OK to increment the fast pointer by L+1. It will wind up in the same place each time, but that's not a problem because the slow pointer will catch it. –  j_random_hacker Sep 22 '12 at 5:43
@j_random_hacker .... how can slow pointer ever catch the fast pointer ?? the difference between the two will always be constant ... since it will be like both are incremented by 1. –  ajayg Oct 2 '12 at 3:36
Can't help but comment on this old thread :) They both catch each other the same way seconds and minutes hands have to eventually meet each other on a clock face. –  ivymike May 19 '14 at 14:44

There is no reason that you need to use the number two. Any choice of step size will work (except for one, of course).

To see why this works, let's take a look at why Floyd's algorithm works in the first place. The idea is to think about the sequence x0, x1, x2, ..., xn, ... of the elements of the linked list that you'll visit if you start at the beginning of the list and then keep on walking down it until you reach the end. If the list does not contain a cycle, then all these values are distinct. If it does contain a cycle, though, then this sequence will repeat endlessly.

Here's the theorem that makes Floyd's algorithm work:

The linked list contains a cycle if and only if there is a positive integer j such that for any positive integer k, xj = xjk.

Let's go prove this; it's not that hard. For the "if" case, if such a j exists, pick k = 2. Then we have that for some positive j, xj = x2j and j ≠ 2j, and so the list contains a cycle.

For the other direction, assume that the list contains a cycle of length l starting at position s. Let j be the smallest multiple of l greater than s. Then for any k, if we consider xj and xjk, since j is a multiple of the loop length, we can think of xjk as the element formed by starting at position j in the list, then taking j steps k-1 times. But each of these times you take j steps, you end up right back where you started in the list because j is a multiple of the loop length. Consequently, xj = xjk.

This proof guarantees you that if you take any constant number of steps on each iteration, you will indeed hit the slow pointer. More precisely, if you're taking k steps on each iteration, then you will eventually find the points xj and xkj and will detect the cycle. Intuitively, people tend to pick k = 2 to minimize the runtime, since you take the fewest number of steps on each iteration.

We can analyze the runtime more formally as follows. If the list does not contain a cycle, then the fast pointer will hit the end of the list after n steps for O(n) time, where n is the number of elements in the list. Otherwise, the two pointers will meet after the slow pointer has taken j steps. Remember that j is the smallest multiple of l greater than s. If s ≤ l, then j = l; otherwise if s > l, then j will be at most 2s, and so the value of j is O(s + l). Since l and s can be no greater than the number of elements in the list, this means than j = O(n). However, after the slow pointer has taken j steps, the fast pointer will have taken k steps for each of the j steps taken by the slower pointer so it will have taken O(kj) steps. Since j = O(n), the net runtime is at most O(nk). Notice that this says that the more steps we take with the fast pointer, the longer the algorithm takes to finish (though only proportionally so). Picking k = 2 thus minimizes the overall runtime of the algorithm.

Hope this helps!

-
Doesn't your proof presuppose that you know the length of the cycle that you are trying to find, so that you can choose an appropriate speed for the hare. Whilst this will produce a hare that will always work for that length of cycle, it would not be guaranteed to work for a cycle of a different length (unless you chose speed 2). –  Mike Tunnicliffe Feb 26 '11 at 23:16
@fd This algorithm shows that for every `k` there's a `j` such that after `j` steps both animals meet. –  Nikita Rybak Feb 26 '11 at 23:22
@fd- The proof itself doesn't assume that you know the cycle length; it just says that for any cycle length and cycle starting position there is some position j that has the desired property. If you think about how the modified tortise/hare algorithm would work, it would start advancing the two pointers at rates 1 and k. After taking j steps, the two pointers would be at positions j and jk, which are coincident. You don't need to know what j is in order to reach it. Does this make sense? –  templatetypedef Feb 26 '11 at 23:24
@Nikita Rybak- That's true. The runtime of this algorithm is proportional to the step size, which is why we usually pick 2. –  templatetypedef Feb 26 '11 at 23:25
To whoever downvoted- can you explain what's wrong with this answer? –  templatetypedef Feb 27 '11 at 8:30

Consider a cycle of size L, meaning at the kth element is where the loop is: xk -> xk+1 -> ... -> xk+L-1 -> xk. Suppose one pointer is run at rate r1=1 and the other at r2. When the first pointer reaches xk the second pointer will already be in the loop at some element xk+s where 0 <= s < L. After m further pointer increments the first pointer is at xk+(m mod L) and the second pointer is at xk+((m*r2+s) mod L). Therefore the condition that the two pointers collide can be phrased as the existence of an m satisfying the congruence

m = m*r2 + s (mod L)

This can be simplified with the following steps

m(1-r2) = s (mod L)

m(L+1-r2) = s (mod L)

This is of the form of a linear congruence. It has a solution m if s is divisible by gcd(L+1-r2,L). This will certainly be the case if gcd(L+1-r2,L)=1. If r2=2 then gcd(L+1-r2,L)=gcd(L-1,L)=1 and a solution m always exists.

Thus r2=2 has the good property that for any cycle size L, it satisfies gcd(L+1-r2,L)=1 and thus guarantees that the pointers will eventually collide even if the two pointers start at different locations. Other values of r2 do not have this property.

-
Very interesting that a double-speed hare has this additional "start-anywhere" property. I need to understand modular arithmetic better (I understood everything except for "It has a solution m if s is divisible by gcd(L+1-r2,L)") –  j_random_hacker Sep 22 '12 at 5:33