You can use the idea I had for my question here: Generating non-consecutive combinations, essentially requiring that you only solve the M=0 case.

If you want to skip the description, the algorithm is given at the end of the post, which has no unpredictable while loops etc, and is guaranteed to be O(N log N) time (would have been O(N), if not for a sorting step).

**Long Description**

To reduce the general M case to the M=0 case, we map each possible combination (with the "aleast M constraint") to a combination without the "at least M" apart constraint.

If your events were at `T1, T2, .., TN`

such that `T1 <= T2 -M, T2 <= T3 - M ...`

you map them to the events `Q1, Q2, .. QN`

such that

```
Q1 = T1
Q2 = T2 - M
Q3 = T3 - 2M
...
QN = TN - (N-1)M.
```

These Q satisfy the property that `Q1 <= Q2 <= ... <= QN`

, and the mapping is 1 to 1. (From `T`

you can construct the `Q`

, and from `Q`

you can construct the `T`

).

So all you need to do is generate the `Q`

(which is essentially the `M=0`

case), and map them back to the `T`

.

Note that the window for generating `Q`

becomes `[Now, Now+12 - (N-1)M]`

To solve the `M=0`

problem, just generate `N`

random numbers in your window and sort them.

**Final Algorithm**

Thus your whole algorithm will be

```
Step 1) Set Window = [Start, End - (N-1)M]
Step 2) Generate N random numbers in the Window.
Step 3) Sort the numbers generated in Step 2. Call them Q1, Q2, .. , QN
Step 4) Create Ti with the formula Ti = Qi + (i-1)M, for i = 1 to N.
Step 5) Output T1,T2,..,TN
```