Note: **that can be done on **`O(n)`

^{1} on average, using a hash table.

```
set <- new hash set
for each x in array:
set.add(2*x)
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.