# Loop invariant of linear search

As seen on Introduction to Algorithms (http://mitpress.mit.edu/algorithms), the exercise states the following:

Input: Array A[1...n]

Write a pseudocode for LINEAR-SEARCH, which scans through the sequence, looking for v. Using a loop invariant, prove that your algorithm is correct. (Make sure that your loop invariant fulﬁlls the three necessary properties – initialization, maintenance, terminantion.)

I have no problem creating the algorithm, but what I don't get is how can I decide what's my loop invariant. I think I understood the concept of loop invariant, that is, a condition that is always true before the beginning of the loop, at the end/beginning of each iteration and still true when the loop ends. This is usually the goal, so for example, at insertion sort, itearting over j, starting at j=2, the [1, j-1] elements are always sorted. This makes sense for me. But for a linear search? I can't think of anything, it just sounds too simple to think of a loop invariant. Did I understand something wrong? I can only think of something obvious like (it's either NIL or between 0 and n). Thanks a lot in advance!

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After you have looked at index `i`, and not found `v` yet, what can you say about `v` with regard to the part of the array before `i` and with regard to the part of the array after `i`?

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v is not from 1 to i but could be after i, can this be a loop invariant? –  Clash Apr 7 '11 at 17:31
ok, that wouldnt make sense... how about, v is not from [1...i], but this wouldn't be valid for the initialization of the loop, as i=1 and I cannot guarantee that v is not the first element. But I can't use negative bounds either, right? –  Clash Apr 7 '11 at 17:37
Clash, take a look at my answer below. –  Larry Watanabe Apr 7 '11 at 17:44
@Clash: Your exercise text seems to imply a 1-based array. `i` then goes from `1` to `n`. If you initialize `i` to `1`, then check `A[i]`, and finally increase `i`, your loop invariant holds for any array index smaller than `i`. If there is no valid array index smaller than `i`, it trivially holds&mdash;anything is true for the empty set. –  Svante Apr 7 '11 at 22:49
@Clash: that's not really a problem. Remember, this is pseudocode and math, not actual code on actual machines. If you assume the notation A[l...u] represents `{ A[i], ∀i i>=l ∧ i <= u }`, then A[0...-1] would represent an empty set. Saying that v is not on the empty set is true, so it holds at the beginning. –  R. Martinho Fernandes Apr 8 '11 at 8:52

You can find solution for your question here: http://www4.ncsu.edu/~aszanto/MA522/HW1Sol.pdf

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Please answer the question, don't just reference some external material. –  Svante Jan 31 '14 at 11:31

Loop invariant would be

forevery 0 <= i < k, where k is the current value of the loop iteration variable, A[i] != v

On loop termination:

if A[k] == v, then the loop terminates and outputs k

if A[k] != v, and k + 1 == n (size of list) then loop terminates with value nil

Proof of Correctness: left as an exercise

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Does this hold true for the initialization? 0 <= i < k would mean that i at the initialization is empty, null or something like that? –  Clash Apr 7 '11 at 18:19
I can't prove it because I don't have your code. But, I would have an if-then-else statement inside my loop saying something like if A[i[ == v, return i. Then I could prove the initialization case for my code: k = 0. Either A[i] == v, in which case my loop terminatees and outputs k. Conversely, if A[i] != v, the for all 0 <= i <= 0, A[i] != v. –  Larry Watanabe Apr 7 '11 at 22:56