# Find an element in an infinite length sorted array

Given an infinite length sorted array having both positive and negative integers. Find an element in it.

EDIT
All the elements in the array are unique and the array in infinite in right direction.

There are two approaches:

# Approach 1:

Set the index at position 100, if the element to be found is less, binary search in the previous 100 items, else set the next index at position 200. In this way, keep on increasing the index by 100 until the item is greater.

# Approach 2:

Set the index in power of 2. First set the index at position 2, then 4, then 8, then 16 and so on. Again do the binary search from position 2^K to 2^(K + 1) where item is in between.

Which of the two approaches will be better both in best case and worst case?

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What does "better" mean when you're dealing with an infinite collection? What sort of asymptotics are you after? Is the array infinite in both directions, or does it have a smallest element? Are the elements unique? –  Kerrek SB Sep 6 '12 at 13:15
Given truly infinite length, it makes no difference -- neither one has any hope of successfully finding an element, except by accident. No matter how you search, the percentage of the array you're able to search is some finite number N / infinity = 0% of the array. –  Jerry Coffin Sep 6 '12 at 13:16
The starting point of the array is known thus making it infinite in right direction. –  Aashish Sep 6 '12 at 13:16
If it helps avoid boggling anybody's mind, maybe replace "infinite sorted array of unique values" with "monotonic increasing function of the natural numbers, computed by a constant-time oracle." –  Steve Jessop Sep 6 '12 at 14:03
Do you want to include in the time complexity calculations that math on the indexes takes more than O(1) time? –  harold Sep 6 '12 at 15:56

The first approach will be linear in the index of the element (`O(k)` where `k` is the index of the element). Actually, you are going to need `k/100` iterations to find the element which is greater then the searched element, which is `O(k)`.

The second approach will be logarithmic in the same index. `O(logk)`. (where `k` is the index of the element). In here, you are going to need `log(k)` iterations until you find the higher element. Then binary search between `2^(i-1)`, `2^i` (where `i` is the iteration number), will be logarithmic as well, totaling in `O(logk)`

Thus, the second is more efficient.

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I have a feeling that both approaches are equal with `O(n)`. Could you please take a look at my answer stackoverflow.com/a/12312488/538514? –  Viktor Stolbin Sep 7 '12 at 5:58
@ViktorStolbin: no, it is `O(logn)` - I commented on your answer why. –  amit Sep 7 '12 at 6:02
@amit, Why is it `O(logn)` if you are going to need `logn` number of iterations with another `logn` number of searches for each `logn` iterations? Wouldn't that be `O(log^2(n))`? –  czchlong Sep 7 '12 at 17:35
@czchlong: The binary search is needed only after the last iteration, There is no point to search for a value until then, because it will not be in this range. The first i-1 iterations are simply checking if `x < arr[2^i]`, and if it is - advance to next iteration, without any binary search. –  amit Sep 7 '12 at 17:39
@amit, Haha I get what you're saying now. Thanks. –  czchlong Sep 7 '12 at 18:17

If the array is well-founded, i.e. has a smallest element (i.e. you have elements x0, x1, ...), and all ele­ments are unique, then here's a simple approach: If you're looking for the number n, you can do a bi­na­ry search over the indices 0, ..., n − x0. Note that we always have the basic inequality xi ≥ i + x0 for all i ≥ 0.

Thus you can find the value n in log2(n − x0) steps.

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And with that upper limit in hand, the array in effect is no longer infinite, and the question becomes more like "which of the following modified binary searches is better?" (1) is (I think) obviously a stupid way to do a search since it's a hybrid linear-binary search dominated by the linear part. (2) might have something to say for it over a plain binary search: if your data is typically sparse (lots of missing elements) then you'd expect the bound to be a big over-estimate, and the target to be near the start, so for sufficiently sparse data (2) does fewer comparisons. –  Steve Jessop Sep 6 '12 at 14:40
@SteveJessop: The crux of the question is that you don't have any a priori bounds on the runtime of the algorithm. The runtime depends on the value of the needle. But indeed, the only thing we can ask is given a needle, what's the most efficient way of finding it in the haystack? –  Kerrek SB Sep 6 '12 at 14:43
True, but the value of the needle is bounded by the size of the non-infinite part of the input data, (2^N, N being the number of bits of input). So it's like any other complexity analysis, we just have to be clear what `n` means when we state `O(f(n))`. See also the confusion when someone says "fantastic news, they've proved that ISPRIME is in P", and someone else says, "what? Obviously it is, sqrt(n) trial divisions" ;-) –  Steve Jessop Sep 6 '12 at 14:45
@SteveJessop: Yes, quite -- that's why I wish the OP had put a bit more care in phrasing the question and describing what he's after. :-) –  Kerrek SB Sep 6 '12 at 15:05
@SteveJessop @KerrekSB: If you want to make it more interesting, assume an infinite sorted array with real numbers that have the non-zino property (for each `n` in `R`, there is finite index `i` such that `arr[i] > n`). I think with this modification the OPs second approach fits better. –  amit Sep 6 '12 at 17:34

You can apply binary search more or less directly with a small modification. This will roughly correspond to your Approach 2.

Basically, pick some number B and set A to 0, then check if the element you're looking for is between A and B. If it is, perform the usual kind of binary search in these boundaries, otherwise set B=A and A=2*A and repeat. This will take O(log(M)), where M is the position of the element you're looking for in the array.

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Just my 2 cents. We have an infinite array thus lets imagine that we are looking for very big number. Did you imagine? Well it's ever much more bigger. Note that length of interval to binary search in is `2^i = 2^(i+1)-2^i` thus it should take `log(2^i)=i` time to find the number. On the other hand it takes `i` time to reach the target interval. So the total time complexity is `O(n)` again. What I'm missing?

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The second approach is `O(logn)`, where `n` is the Index of the desired element. Note that the binary search is indeed done in range `[2^i,2^(i+1)]` and thus `O(i)`, but `i` itself is `O(logn)`, because `2^(i+1) > n => i+1 > logn`, thus `O(i)` is actually `O(logn)` –  amit Sep 7 '12 at 6:02
Yeah, I was confused with `n` meaning. In other words my answer is the same `O(i)` where `i=logn`. Thanks –  Viktor Stolbin Sep 7 '12 at 6:18
You should probably remove this answer, since it is not an answer.. –  amit Sep 7 '12 at 18:12
Since the array is infinite, the indexes are necessarily variable-length. That means that doing math on them is not `O(1)`, which in turn means that "binary search with first a search for an endpoint" has a slightly different time complexity than `O(log(k))`.
The index math done in the search for the endpoint is just a left shift by one, which takes `O(log(k))` because indexes up to `k` need up to `log(k)` bits and shifting left by one is linear in the number of bits.
The index math done in the binary search is all `O(log(k))` as well.
So the actual complexity of both algorithms is `O(log(k)^2)`. The complexity of a linear search would be `O(k log k)`, so it still loses.