You only have fragmentation for the general memory allocation problem, where blocks of arbitrary length are requested. The issue here is that given this memory layout:
@ means in use and
- means free)
You cannot allocate 4 continuous blocks although there are 6 free blocks in total. So you have to increase the total amount of governed space (if possible).
Also in this general scenario deciding which address to pick is not trivial and has several strategies (first fit, worst fit, etc.) that affect the degree of fragmentation.
In your case the problem is significantly easier as you know that the areas you will want to allocate will always be exactly of the size of some integer
k = sizeof(T)).
This means you will always have perfectly fitting blocks which you organise just as you like. Simply deal with the free space as if it was a linked list and always use the very first item in the list to answer memory allocation requests.
Now, if you want to allocate in large blocks to amortise allocations you can keep an extra counter of how many slots are used in one particular block in order to release that block when it's empty (if you want to ever shrink your reservoir of slots!).
If you insist on always handing out new memory blocks from the most used block you can do this by using an additional list that indicates which block is fullest. Since you can always only change the number of used slots by one, you can keep that list sorted in
O(1), simply by swapping adjacent nodes.