This can be solved in `O(M + N)`

, trivially as follows. First, model your `Operation`

like this:

```
class Operation {
final int p;
final int q;
final int r;
Operation(int p, int q, int r) {
this.p = p;
this.q = q;
this.r = r;
}
}
```

Then, create an array where you add `+op.r`

at position `op.p`

and `-op.r`

at position `op.q + 1`

for inclusive upper bounds (or `op.q`

for exclusive upper bounds). This is the loop over `M`

:

```
int[] array = new int[10];
Operation[] ops = {
new Operation(1, 7, 2),
new Operation(2, 5, 3),
new Operation(1, 3, 1)
};
for (Operation op : ops) {
int lo = op.p;
int hi = op.q + 1;
if (lo >= 0)
array[lo] = array[lo] + op.r;
if (hi < array.length)
array[hi] = array[hi] - op.r;
}
```

Finally, run through the array of size `N`

and find the max by cumulating each previously registered value of `+/- op.r`

```
int maxIndex = Integer.MIN_VALUE;
int maxR = Integer.MIN_VALUE;
int r = 0;
for (int i = 0; i < array.length; i++) {
r = r + array[i];
System.out.println(i + ":" + r);
if (r > maxR) {
maxIndex = i;
maxR = r;
}
}
System.out.println("---");
System.out.println(maxIndex + ":" + maxR);
```

My example yields:

```
0:0
1:3
2:6
3:6
4:5
5:5
6:2
7:2
8:0
9:0
---
2:6
```

### Java 8 parallel version

If you have tons of cores, you can parallelise the previous algorithm using Java 8 API as such:

```
// Finally a use-case for this weird new Java 8 function!
Arrays.parallelPrefix(array, Integer::sum);
System.out.println(Arrays.stream(array).parallel().max());
```

This is probably faster than the previous sequential solution for very large numbers of `N`

and for a sufficient number of cores.