From a test of a (in)famous coding-site: given a zero-indexed array of integers `A[N]`

, we can define a "pit" (of this array) a triplet of integers `(P,Q,R)`

such that they follow these rules:

`0 ≤ P < Q < R < N`

`A[P] > A[P+1] > ... > A[Q]`

(strictly decreasing) and

`A[Q] < A[Q+1] < ... < A[R]`

(strictly increasing).

We can also define the depth of this pit as the number

`min{A[P] − A[Q], A[R] − A[Q]}`

.

You should write a Java method (function) `deepest_pit(int[] A)`

which returns the depth of the deepest pit in array `A`

or `-1`

if it does not exit.

Costraints: `N`

is an integer within the range `[1..1,000,000];`

each element of array `A`

is an integer within the range `[−100,000,000..100,000,000]`

.

I have written a "brute force" function with three "for" loops, and even if each inner loop runs on a subset of items and you might skip every non-compliant triplet, surely it is not the best solution. I feel there is something about trees (Cartesian?) and stacks, for sure. The solution complexity should be O(N).

UPDATE

My attempt after @Matzi hints:

```
public static int dp(int[] A) {
int N = A.length;
int depth = -1;
int P, Q, R;
int i = 0, j, k;
while (i < N - 2) {
P = A[i];
j = i + 1;
int p = P;
while (j < N - 1 && A[j] < p) {
p = A[j++];
}
if (j == N - 1) {
break;
}
if (j > i + 1) {
Q = A[j - 1];
} else {
i++;
continue;
}
k = j;
int q = Q;
while (k < N && A[k] > q) {
q = A[k++];
}
if (k > j) {
R = A[k - 1];
depth = Math.max(depth, Math.min(P - Q, R - Q));
i = k - 1;
} else {
i = j - 1;
}
}
return Math.max(depth, -1);
}
```