At each round, you'll sort `floor(X/Y)`

batches of `Y`

elements and one batch of `X mod Y`

elements.

Suppose for simplicity that the input is given as an array `A[1...X]`

.
At the first round, the batches will be `A[1...Y], A[Y+1...2Y], ..., A[(floor(X/Y)-1)Y+1...floor(X/Y)Y], A[floor(X/Y)Y+1...X]`

.
For the second round, shift these ranges right by `Y/2`

places (you can use wrap-around if you like, though for simplicity I will simply assume the first `Y/2`

elements will be left alone in even-numbered iterations). So, the ranges could be `A[Y/2+1...3Y/2], A[3Y/2+1...5Y/2], etc.`

. The next round will repeat the ranges of the first, and the round after that will repeat the ranges of the second, and so on. How many iterations are needed in the worst case to guarantee a fully-sorted list? Well, in the worst case, the maximum element must migrate from the beginning to the end, and since it takes two iterations for an element to migrate one full odd-iteration section (see below) it stands to reason that it takes `2*ceiling(X/Y)`

iterations in total for an element at the front to get to the end.

Example:

```
X=11
Y=3
A = [7, 2, 4, 5, 2, 1, 6, 2, 3, 5, 6]
[7,2,4] [5,2,1] [6,2,3] [5,6] => [2,4,7] [1,2,5] [2,3,6] [5,6]
2 [4,7,1] [2,5,2] [3,6,5] [6] => 2 [1,4,7] [2,2,5] [3,5,6] [6]
[2,1,4] [7,2,2] [5,3,5] [6,6] => [1,2,4] [2,2,7] [3,5,5] [6,6]
1 [2,4,2] [2,7,3] [5,5,6] [6] => 1 [2,2,4] [2,3,7] [5,5,6] [6]
[1,2,2] [4,2,3] [7,5,5] [6,6] => [1,2,2] [2,3,4] [5,5,7] [6,6]
1 [2,2,2] [3,4,5] [5,7,6] [6] => 1 [2,2,2] [3,4,5] [5,6,7] [6]
[1,2,2] [2,3,4] [5,5,6] [7,6] => [1,2,2] [2,3,4] [5,5,6] [6,7]
1 [2,2,2] [3,4,5] [5,6,6] [7] => no change, termination condition
```

This might seem a little silly, but if you have an efficient way to sort small groups and a lot of parallelism available this could be pretty nifty.