Based on R.. GitHub STOP HELPING ICE's answer, I came up with the following way of computing fragmentation as a single percentage number:

Where:

`n`

is the total number of free blocks
`FreeSlots(i)`

means how many `i`

-sized slots you can fit in the available free memory space
`IdealFreeSlots(i)`

means how many `i`

-sized slots would fit in a perfectly unfragmented memory of size `n`

. This is a simple calculation: `IdealFreeSlots(i) = floor(n / i)`

.

#### How I came up with this formula:

I was thinking about how I could combine all the `freespace_quality(i)`

values to get a single fragmentation percentage, but I wasn't very happy with the result of this function. Even in an ideal scenario, you could have `freespace_quality(i) != 1`

if the free space size `n`

is not divisible by `i`

. For example, if `n=10`

and `i=3`

, `freespace_quality(3) = 9/10 = 0.9`

.

So, I created a derived function `freespace_relative_quality(i)`

which looks like this:

This would always have the output `1`

in the ideal "perfectly unfragmented" scenario.

After doing the math:

All that's left to do now to get to the final fragmentation formula is to calculate the average freespace quality for all values of `i`

(from `1`

to `n`

), and then invert the range by doing `1 - the average quality`

so that 0 means completely unfragmented (maximum quality) and 1 means most fragmented (minimum quality).