# What is a loop invariant?

I'm reading "Introduction to Algorithm" CLRS. and the authors are talking about loop invariants, in chapter 2 (Insertion Sort). I don't have any idea of what it means.

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It was a simple google: en.wikipedia.org/wiki/Loop_invariant –  Mitch Wheat Jul 11 '10 at 2:09
This seems pretty good at explaining: cs.miami.edu/~burt/learning/Math120.1/Notes/LoopInvar.html –  Tom Gullen Jul 11 '10 at 2:11
check this link it explained loop invariant with a good example: cs.unm.edu/~saia/361-spring2004/lec/ho-lec8.pdf –  user1789104 Oct 31 '12 at 15:47

In simple words, a loop invariant is some predicate (condition) that holds for every iteration of the loop. For example, let's look at a simple `for` loop that looks like this:

``````int j = 9;
for(int i=0; i<10; i++)
j--;
``````

In this example it is true (for every iteration) that `i + j == 9`. A weaker invariant that is also true is that
`i >= 0 && i < 10` (because this is the termination condition!) or that `j <= 9 && j >= 0`.

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This is an excellent example. Many times when I've heard an instructor describe the loop invariant, it has simply been 'the loop condition', or something similar. Your example shows that the invariant can be much more. –  Brian S Jul 11 '10 at 2:17
I don't see this a good example because the loop invariant should be somewhat the goal of the loop... CLRS uses it to proove the correctness of a sorting algorithm. For insertion sort, supposing the loop is iterating with i, at the end of each loop, the array is ordered until the i-th element. –  Clash Apr 7 '11 at 16:23
yeah, this example is not wrong, but just not enough. I back @Clash up, as loop invariant should present the goal, not just for itself. –  Jack Oct 19 '11 at 9:52
@Tomas Petricek - when the loop terminates, i = 10 and j = -1; so the weaker invariant example you gave may not be correct (?) –  Raja Apr 7 '12 at 22:47
Although I agree with the comments above, I've upvoted this answer because ... the goal is not defined here. Define any goal that fits in, and the example is great. –  Flavius Jan 3 at 20:21

a loop invariant is condition that holds true before a loop start to execute, remains true during execution and is still true at the point that the loop terminates. the following code segment will help to illustrate this:

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Where is the code segment? –  Ashish Nitin Patil Dec 12 at 21:34

There is one thing that many people don't realize right away when dealing with loops and invariants. They get confused between the loop invariant, and the loop conditional ( the condition which controls termination of the loop ).

As people point out, the loop invariant must be true

1. before the loop starts
2. before each iteration of the loop
3. after the loop terminates

( although it can temporarily be false during the body of the loop ). On the other hand the loop conditional must be false after the loop terminates, otherwise the loop would never terminate.

Thus the loop invariant and the loop conditional must be different conditions.

A good example of a complex loop invariant is for binary search.

``````bsearch(type A[], type a) {
start = 1, end = length(A)

while ( start <= end ) {
mid = floor(start + end / 2)

if ( A[mid] == a ) return mid
if ( A[mid] > a ) end = mid - 1
if ( A[mid] < a ) start = mid + 1

}
return -1

}
``````

So the loop conditional seems pretty straight forward - when start > end the loop terminates. But why is the loop correct? What is the loop invariant which proves it's correctness?

The invariant is the logical statement:

``````if ( A[mid] == a ) then ( start <= mid <= end )
``````

This statement is a logical tautology - it is always true in the context of the specific loop / algorithm we are trying to prove. And it provides useful information about the correctness of the loop after it terminates.

If we return because we found the element in the array then the statement is clearly true, since if `A[mid] == a` then `a` is in the array and `mid` must be between start and end. And if the loop terminates because `start > end` then there can be no number such that `start <= mid` and `mid <= end` and therefore we know that the statement `A[mid] == a` must be false. However, as a result the overall logical statement is still true in the null sense. ( In logic the statement if ( false ) then ( something ) is always true. )

Now what about what I said about the loop conditional necessarily being false when the loop terminates? It looks like when the element is found in the array then the loop conditional is true when the loop terminates!? It's actually not, because the implied loop conditional is really `while ( A[mid] != a && start <= end )` but we shorten the actual test since the first part is implied. This conditional is clearly false after the loop regardless of how the loop terminates.

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Beside all of the good answers, I guess a great example from How to Think About Algorithms, by Jeff Edmonds can illustrate the concept very well:

EXAMPLE 1.2.1 "The Find-Max Two-Finger Algorithm"

1) Specifications: An input instance consists of a list L(1..n) of elements. The output consists of an index i such that L(i) has maximum value. If there are multiple entries with this same value, then any one of them is returned.

2) Basic Steps: You decide on the two-finger method. Your right finger runs down the list.

3) Measure of Progress: The measure of progress is how far along the list your right finger is.

4) The Loop Invariant: The loop invariant states that your left finger points to one of the largest entries encountered so far by your right finger.

5) Main Steps: Each iteration, you move your right finger down one entry in the list. If your right finger is now pointing at an entry that is larger then the left finger’s entry, then move your left finger to be with your right finger.

6) Make Progress: You make progress because your right finger moves one entry.

7) Maintain Loop Invariant: You know that the loop invariant has been maintained as follows. For each step, the new left finger element is Max(old left finger element, new element). By the loop invariant, this is Max(Max(shorter list), new element). Mathe- matically, this is Max(longer list).

8) Establishing the Loop Invariant: You initially establish the loop invariant by point- ing both fingers to the first element.

9) Exit Condition: You are done when your right finger has finished traversing the list.

10) Ending: In the end, we know the problem is solved as follows. By the exit condi- tion, your right finger has encountered all of the entries. By the loop invariant, your left finger points at the maximum of these. Return this entry.

11) Termination and Running Time: The time required is some constant times the length of the list.

12) Special Cases: Check what happens when there are multiple entries with the same value or when n = 0 or n = 1.

13) Coding and Implementation Details: ...

14) Formal Proof: The correctness of the algorithm follows from the above steps.

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Formal finger proof? –  kdazzle Dec 12 '12 at 22:29
It's just an example, not a proof. If I understood you correctly.. –  Vahid Rafiei Dec 14 '12 at 1:11
``````int j = 9;
for(int i=0; i<10; i++)
j--;
``````

can the loop invariant for that also be 9-(i-j)? Through every iteration of the loop, that equation holds til termination. I also know that you can use Hoare's logic to deduct the loop invariant. Correct me if I'm wrong.

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This should be a comment on the answer you're referring to, not a separate answer. –  agweber Nov 14 '12 at 18:29
It is not possible to comment with low reputation. –  karatedog Dec 5 at 0:02

It should be noted that a Loop Invariant can help in the design of iterative algorithms when considered an assertion that expresses important relationships among the variables that must be true at the start of every iteration and when the loop terminates. If this holds, the computation is on the road to effectiveness. If false, then the algorithm has failed.

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In the simplest terms, it's something that will not change at any point in a given loop. They're useful because, since they don't change within the loop they can often be moved outside the loop to reduce the computation done each loop, thus improving execution speed. It's a pretty common optimisation technique used by most compilers.

A very contrived example:

``````for (int i = 0; i < 10; i++)
{
...
int value = 1 + 2 + 3 + 4;
...
doSomething (value, i);
...
}
``````

optimised to:

``````int value = 1 + 2 + 3 + 4;
for (int i = 0; i < 10; i++)
{
...
doSomething (value, i);
...
}
``````

saving computation of `value` each time through the loop.

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this is actually false, I don't know why it was upvoted... the loop invariant is only true before the loop and at the end of each cycle of the loop... it does not need to be true at any given point of the loop –  Clash Apr 7 '11 at 16:19

I like this very simple definition:

A loop invariant is a condition [among program variables] that is necessarily true immediately before and immediately after each iteration of a loop. (Note that this says nothing about its truth or falsity part way through an iteration.)

By itself, a loop invariant doesn't do much. However, given an appropriate invariant, it can be used to help prove the correctness of an algorithm. The simple example in CLRS probably has to do with sorting. For example, let your loop invariant be something like, at the start of the loop, the first `i` entries of this array are sorted. If you can prove that this is indeed a loop invariant (i.e. that it holds before and after every loop iteration), you can use this to prove the correctness of a sorting algorithm: at the termination of the loop, the loop invariant is still satisfied, and the counter `i` is the length of the array. Therefore, the first `i` entries are sorted means the entire array is sorted.

An even simpler example is shown at http://academic.evergreen.edu/curricular/dsa01/loops.html.

The way I understand a loop invariant is as a systematic, formal tool to reason about programs. We make a single statement that we focus on proving true, and we call it the loop invariant. This organizes our logic. While we can just as well argue informally about the correctness of some algorithm, using a loop invariant forces us to think very carefully and ensures our reasoning is airtight.

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It should be pointed out that "immediately after each iteration" includes after the loop terminates - regardless of how it terminated. –  Robert S. Barnes Mar 12 at 9:28