# check if there exists a[i] = 2*a[j] in an unsorted array a?

Given a unsorted sequence of a[1,...,n] of integers, give an O(nlogn) runtime algorithm to check there are two indices i and j such that a[i] =2*a[j]. The algorithm should return i=0 and j=2 on input 4,12,8,10 and false on input 4,3,1,11.

I think we have to sort the array anyways which is O(nlogn). I'm not sure what to do after that.

-

You're right that the first step is sorting the array.

Once the array is sorted, you can find out whether a given element is inside the array in O(log n) time. So if for every of the n elements, you check for the inclusion of another element in O(log n) time, you end up with a runtime of O(n log n).

-
I'm choosing this as the right answer because even though @amit answer was elegant it assumes we have twice the space and a hash function of O(1). If I could choose two answers I would have chose Steve answer too. –  Sunil Apr 1 '12 at 23:57
Hey you still need to keep track of the original indices so still need extra space :) –  Victor Parmar Apr 3 '12 at 15:36
@VictorParmar The assignment doesn't say you need to return the indices. "Check whether ..." sounds to me like it's asking for a boolean function (so no need to remember indices). –  sepp2k Apr 3 '12 at 15:42

Note: that can be done on O(n)1 on average, using a hash table.

set <- new hash set
for each x in array:
for each x in array:
if set.contains(x):
return true
return false

Proof:
=>
If there are 2 elements a[i] and a[j] such that a[i] = 2 * a[j], then when iterating first time, we inserted 2*a[j] to the set when we read a[j]. On the second iteration, we find that a[i] == 2* a[j] is in set, and return true.

<=
If the algorithm returned true, then it found a[i] such that a[i] is already in the set in second iteration. So, during first itetation - we inserted a[i]. That only can be done if there is a second element a[j] such that a[i] == 2 * a[j], and we inserted a[i] when reading a[j].

Note:
In order to return the indices of the elemets, one can simply use a hash-map instead of a set, and for each i store 2*a[i] as key and i as value.

Example:
Input = [4,12,8,10]

first insert for each x - 2x to the hash table, and the index. You will get:

hashTable = {(8,0),(24,1),(16,2),(20,3)}

Now, on secod iteration you check for each element if it is in the table:

arr[0]: 4 is not in the table
arr[1]: 12 is not in the table
arr[2]: 8 is in the table - return the current index [2] and the value of 8 in the map, which is 0.

so, final output is 2,0 - as expected.

(1) Complexity notice:
In here, O(n) assumes O(1) hash function. This is not always true. If we do assume O(1) hash function, we can also assume sorting with radix-sort is O(n), and using a post-processing of O(n) [similar to the one suggested by @SteveJessop in his answer], we can also achieve O(n) with sorting-based algorithm.

-
And for that matter, if a hash table is O(n) then sorting is also O(n) using a binary radix sort. –  Steve Jessop Mar 31 '12 at 16:50
@SteveJessop: I assume there is a point in what you are saying, this makes hashing based solution O(nlogk) where k is the possible range of elements, and assuming k >= n [otherwise the answer is trivial from piegeonhole principle], there is no improvement in here. I'll delete this answer in a few minutes [just giving you time to read this comment before I do]. –  amit Mar 31 '12 at 17:03
I think your answer is perfectly reasonable: solves the problem with good performance using tools out of the box. It's just that there's some hair-splitting about the complexity of operations on fixed-size integers that means both the hash set and the binary radix sort are in some sense "cheating" to claim O(n). Or not cheating, in which case you're right that O(n log n) isn't a tight bound. –  Steve Jessop Mar 31 '12 at 17:05
@SteveJessop: Then I accept your suggestion to keep it. Also: assuming range of size k - won't compares based sorting in this case be O(nlognlogk), because each compare OP is also O(logk), and we have O(nlogn) of those? [I might be getting a bit out of scope here]. –  amit Mar 31 '12 at 17:20
Well, k traditionally denotes a Konstant, so you can stick as many log k in there as you like without affecting the complexity class :-) But you're right, if we want to treat k as non-constant we have to do more analysis than people usually bother with. The compare wouldn't be O(1), and we'd have to be more specific about the hash function to determine its exact complexity: for example if it involves multiplication of two k-digit numbers that's not O(k), it's at best O(k^(1 + epsilon)). As you say, probably beyond the scope of the intended question. –  Steve Jessop Mar 31 '12 at 17:27
1. Sort the array (O(n log n), or O(n) if you're willing to stretch a point about arrays of fixed-size integers)
2. Initialise two pointers ("fast" and "slow") at the start of the array (O(1))
3. Repeatedly:
1. increment "fast" until you find an even value >= twice the value at "slow"
2. if the value at "fast" is exactly twice the value at "slow", return true
3. increment "slow" until you find a value >= half the value at fast
4. if the value at "slow" is exactly half the value at "fast", return true
4. if one of the attempts to increment goes past the end, return false

Since each of fast and slow can be incremented at most n times total before reaching the end of the array, the "repeatedly" part is O(n).

-
this is the best answer , should have been accepted. –  aseem Jan 12 '14 at 12:02
1. Create an array of pairs A={(a[0], 0), (a[1], 1), ..., (a[n-1], n-1)}
2. Sort A,
3. For every (a[i], i) in A, do a binary search to see if there's a (a[i] * 2, j) pair or not. We can do this, because A is sorted.

Step 1 is O(n), and step 2 and 3 are O(n * log n).

Also, you can do step 3 in O(n) (there's no need for binary search). Because if the corresponding element for A[i] is at A[j], then then corresponding element for A[i+1] cannot be in A[0..j-1]. So we can keep two pointers, and find the answer in O(n). But anyway, the whole algorithm will be O(n log n) because we still do sorting.

-
Step 1 seems superflous... You are not using the second value of the pairs for anything. –  Alderath Apr 2 '12 at 7:42
I think the algorithm should return the indexes i and j. That's the reason for second element. –  Hadi Moshayedi Apr 4 '12 at 19:31

Sorting the array is a good option - O(nlogn), assuming you don't have some fancy bucket sort option.

Once it's sorted, you need only pass through the array twice - I believe this is O(n)

Create a 'doubles' list which starts empty.

Then, For each element of the array:

• check the element against the first element of the 'doubles' list
• if it is the same, you win
• if the element is higher, ditch the first element of the 'doubles' list and check again
• add its double to the end of the 'doubles' list

• keep going until you find a double, or get to the end of your first list.

-

You can also use a balanced tree, but it uses extra space but also does not harm the array.

Starting at i=0, and incrementing i, insert elements, checking if twice or half the current element is already there in the tree.

One advantage is that it will work in O(M log M) time where M = min [max{i,j}]. You could potentially change your sorting based algorithm to try and do O(M log M) but it could get complicated.

Btw, if you are using comparisons only, there is an Omega(n log n) lower bound, by reducing the element distinctness problem to this:

Duplicate the input array. Use the algorithm for this problem twice. So unless you bring hashing type stuff into the picture, you cannot get a better than Theta(n log n) algorithm!

-