Looks like there is a lot of repetition here. One optimization is to reduce the amount of duplicate effort. Using pen and paper, I'm showing the `matBigger`

"i" index iterating as:

```
[0 + 0], [0 + 1], [0 + 2], ..., [0 + 19],
[1 + 0], [1 + 1], ..., [1 + 18], [1 + 19]
[2 + 0], ..., [2 + 17], [2 + 18], [2 + 19]
```

As you can see there are locations that are accessed many times.
Also, multiplying the iteration counts indicate that the inner content is accessed: 20 * 20 * 5000 * 5000, or 10000000000 (10E+9) times. That's a lot!

So rather than trying to speed up the execution of 10E9 instructions (such as execution (pipeline) cache or data cache optimization), try reducing the number of iterations.

The code is searcing the matrix for a number that is within a range: larger than a minimal value and less than the maximum range value.

Based on this, try a different approach:

- Find and remember all coordinates where the search value is greater
than the low value. Let us call these anchor points.
- For each anchor point, find the coordinates of the first value after
the anchor point that is outside the range.

The objective is to reduce the number of duplicate accesses. Anchor points allow for a one pass scan and allow other decisions such as finding a range or determining an MxN matrix that contains the anchor value.

Another idea is to create new data structures containing the `matBigger`

and `matSmaller`

that are more optimized for searching.

For example, create a {value, coordinate list} entry for each unique value in `matSmaller`

:

```
Value coordinate list
26 -> (2,3), (6,5), ..., (1007, 75)
31 -> (4,7), (2634, 5), ...
```

Now you can use this data structure to find values in `matSmaller`

and immediately know their locations. So you could search `matBigger`

for each unique value in this data structure. This again reduces the number of access to the matrices.