Make three sweeps through the array. First from `j=2`

up, filling an auxiliary array `a`

with *minimal* element so far. Then, do the sweep from the top `i=n-1`

down, filling (also from the top down) another auxiliary array, `b`

, with *maximal* element so far (from the top). Now do the sweep of the both auxiliary arrays, looking for a maximal difference of `b[i]-a[i]`

.

That will be the answer. `O(n)`

in total. You could say it's a dynamic programming algorithm.

**edit:** As an optimization, you can eliminate the third sweep and the second array, and find the answer in the second sweep by maintaining two loop variables, *max-so-far-from-the-top* and *max-difference*.

As for "pointers" about how to solve such problems in general, you usually try some general methods just like you wrote - divide and conquer, memoization/dynamic programming, etc. First of all look closely at your problem and concepts involved. Here, it's maximum/minimum. Take these concepts apart and see how these parts combine in the context of the problem, possibly changing order in which they're calculated. Another one is looking for hidden order/symmetries in your problem.

Specifically, fixing an *arbitrary* inner point `k`

along the list, this problem is reduced to finding the difference between the minimal element among all `j`

s such that `1<j<=k`

, and the maximal element among `i`

s: `k<=i<n`

. You see divide-and-conquer here, as well as taking apart the concepts of max/min (i.e. their *progressive* calculation), and the interaction between the parts. The hidden order is revealed (`k`

goes along the array), and memoization helps save the interim results for max/min values.

The fixing of arbitrary point `k`

could be seen as solving a smaller sub-problem first ("for a given `k`

..."), and seeing whether there is anything special about it and it can be abolished - *generalized* - *abstracted* over.

There is a technique of trying to formulate and solve a bigger problem first, such that an original problem is a part of this bigger one. Here, we think of find *all* the differences for each k, and then finding the maximal one from them.

The *double use* for interim results (used both in comparison for specific `k`

point, and in calculating the *next* interim result each in its direction) usually mean some considerable savings. So,

- divide-and-conquer
- memoization / dynamic programing
- hidden order / symmetries
- taking concepts apart - seeing how the parts combine
- double use - find parts with double use and memoize them
- solving a bigger problem
- trying arbitrary sub-problem and abstracting over it

`std::max_element`

and`std::min_element`

respectively. – chris May 29 '12 at 4:33`std::minmax_element`

? – Blastfurnace May 29 '12 at 5:00