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

Input: Array A[1..n] and a value v

Output: Index i, where A[i] = v or NIL if v does not found in A

Write 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, termination.)

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, iterating over j, starting at j = 2, the A[1..j-1] elements are always sorted. This makes sense to 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!

7 Answers 7

1  for i = 1 to A.length
2      if A[i] == ν 
3          return i
4  return NIL 

Loop invariant: at the start of the ith iteration of the for loop (lines 1–4),

∀ k ∈ [1, i) A[k] ≠ ν.  


i == 1 ⟹ [1, i) == Ø ⟹ ∀ k ∈ Ø A[k] ≠ ν,

which is true, as any statement regarding the empty set is true (vacuous truth).

Maintenance: let's suppose the loop invariant is true at the start of the ith iteration of the for loop. If A[i] == ν, the current iteration is the final one (see the termination section), as line 3 is executed; otherwise, if A[i] ≠ ν, we have

∀ k ∈ [1, i) A[k] ≠ ν and A[i] ≠ ν ⟺ ∀ k ∈ [1, i+1) A[k] ≠ ν,

which means that the invariant loop will still be true at the start of the next iteration (the i+1th).

Termination: the for loop may end for two reasons:

  1. return i (line 3), if A[i] == ν;
  2. i == A.length + 1 (last test of the for loop), in which case we are at the beginning of the A.length + 1th iteration, therefore the loop invariant is

    ∀ k ∈ [1, A.length + 1) A[k] ≠ ν ⟺ ∀ k ∈ [1, A.length] A[k] ≠ ν

    and the NIL value is returned (line 4).

In both cases, LINEAR-SEARCH ends as expected.

  • 2
    Beautiful! Mathematically precise and very well exposed. Thank you for this answer! Oct 29, 2019 at 21:28

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?

  • v is not from 1 to i but could be after i, can this be a loop invariant?
    – Clash
    Apr 7, 2011 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, 2011 at 17:37
  • 1
    @Clash: Your first attempt does look sensible. My hint would better be formulated as "Before you look at A[i] ...", so that the invariant holds at the start of the loop.
    – Svante
    Apr 7, 2011 at 17:54
  • 1
    @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—anything is true for the empty set.
    – Svante
    Apr 7, 2011 at 22:49
  • 6
    @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. Apr 8, 2011 at 8:52

In the case of linear search, the loop variant will be the backing store used for saving the index(output) .

Lets name the backing store as index which is initially set to NIL.The loop variant should be in accordance with three conditions :

  • Initialization : This condition holds true for index variable.since, it contains NIL which could be a result outcome and true before the first iteration.
  • Maintenance : index will hold NIL until the item v is located. It is also true before the iteration and after the next iteration.As, it will be set inside the loop after comparison condition succeeds.
  • Termination : index will contain NIL or the array index of the item v.



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

  • 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, 2011 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. Apr 7, 2011 at 22:56
  • 0 <= i < k holds for the initial iteration of the loop since you will get an empty array, which, in fact, does not include v, hence the condition is true before the initial execution of the loop.
    – fnisi
    Jun 5, 2019 at 9:02

Assume that you have an array of length i, indexed from [0...i-1], and the algorithm is checking if v is present in this array. I'm not totally sure, but I think, the loop invariant is as follows: If j is the index of v, then [0..j-1] will be an array that does not have v.

Initialization : Before iterating from 0..i-1, the current array checked (none), does not consist of v.

Maintenance : On finding v at j, array from [0..j-1] will be an array without v.

Termination : As the loop terminates on finding v at j, [0..j-1] will be an array without j.

If the array itself does not have v, then j = i-1, and the above conditions will still hold true.


The invariant for linear search is that every element before i is not equal to the search key. A reasonable invariant for binary search might be for a range [low, high), every element before low is less than the key and every element after high is greater or equal. Note that there are a few variations of binary search with slightly different invariants and properties - this is the invariant for a "lower bound" binary search which returns the lowest index of any element equal to or greater than the key.


Seems correct to me.


The LS algorithm that I wrote is-

  for i=0 to A.length-1
    if(A[i] == v)
      return i
  return NIL

I made my own assumptions for loop invariant for checking correctness of Linear Search:

  1. At Initialisation- at i = 0, we are searching for v at i = 0.

  2. At successive iterations- we are looking for v till i < A.length-1

  3. At termination- i = A.length and till A.length we kept looking for v.

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