If I understand your problem correctly, you are looking for two indices (i, j) in the array with i < j that has the highest ratio A[j]/A[i]. If so, then you can reduce it to **this related problem**, which asks you to find the indices (i, j) with i ≤ j such that A[j] - A[i] is as large as possible. That problem has a very fast O(n)-time, O(1)-space algorithm that can be adapted to this problem as well. The intuition is to solve the problem for the array consisting of just the first element of your array, then for the first two elements, then the first three, etc. Once you've solved the problem for the first n elements of the array, you have an overall solution to the problem.

Let's think about how to do this. Initially, when you consider just the first element of the array, the best percentage increase you can get is 0% by comparing the element with itself. Now, suppose (inductively) that you've solved the problem for the first k array elements and want to see what happens when you look at the next array element. When this happens, one of two conditions holds. First, the maximum percentage increase over the first k elements might also be the maximum percentage increase over the first (k + 1) elements as well. For example, if the (k+1)st array element is an extremely small number, then chances are you can't get a large percentage increase from something in the first k elements to that value. Second, the maximum percentage increase might be from one of the first k elements to the (k + 1)st element. If this is the case, the highest percentage increase would be from the smallest of the first k elements to the (k + 1)st element.

Combining these two cases, we get that the best percentage increase over the first k + 1 elements is the maximum of

- The highest percentage increase of the first k elements, or
- The percentage increase from the smallest of the first k elements to the (k + 1)st element.

You can implement this by iterating across the array elements keeping track of two values - the minimum value you've seen so far and the pair that maximizes the percent increase. As an example, for your original example array of

```
1 2 3 10 1 20 40 60
```

The algorithm would work like this:

```
1 2 3 10 1 20 40 60
min 1 1 1 1 1 1 1 1
best (1,1) (1, 2) (1, 3) (1, 10) (1, 10) (1, 20) (1, 40) (1, 60)
```

and you'd output (1, 60) as the highest percentage increase. On a different array, like this one:

```
3 1 4 2 5
```

then the algorithm would trace out like this:
3 1 4 2 5
min 3 1 1 1 1
best (3,3) (3,3) (1,4) (1,4) (1,5)

and you'd output (1, 5).

This whole algorithm uses only O(1) space and runs in O(n) time, which is an extremely good solution to the problem.

Alternatively, you can think about reducing this problem directly to the maximum single-sell profit problem by taking the logarithm of all of the values in your array. In that case, if you find a pair of values where log A[j] - log A[i] is maximized, this is equivalent (using properties of logarithms) to finding a pair of values where log (A[j] / A[i]) is maximized. Since the log function is monotonically increasing, this means that you have found a pair of values where A[j] / A[i] is maximized, as intended.

`finalValue/initialValue`

? – Nikita Rybak Feb 5 '11 at 1:01`O(n)`

if you allow the space complexity`O(n)`

– Foo Bah Feb 5 '11 at 1:15