Some sorting methods guarantee that items which compare equal will appear in the same sequence relative to each other after sorting as they did before sorting, but such a guarantee generally comes with a cost. Very few sorting algorithms can move an item directly from its original position to its final position in a single step (and those which do so are generally slow). Instead, sorting algorithms move items around a few times, and generally don't keep track of where items came from. In the Anthony Hoare's "quicksort" algorithm, a typical step will pick some value and move things around so that everything which compares less than that value will end up in array elements which precede all the items which are greater than that value. If one ignores array elements that precisely equal the "pivot" value, there are four categories of items:
- Items which are less than the pivot value, and started in parts of the array that precede the pivot value's final location.
- Items which are less than the pivot value, but started in parts of the array that follow the pivot value's final location.
- Items which are greater than the pivot value, but started in parts of the array that precede the pivot value's final location.
- Items which are greater than the pivot value, and started in parts of the array that follow the pivot value's final location.
When moving elements to separate those above and below the pivot value, items in the first and fourth categories (i.e. those which started and ended on the same side of the pivot value's final location) generally remain in their original order, but are intermixed with those which started on the other side, which get copied in reverse order. Because the values from each side get intermixed, there's no way the system can restore the sequence of items which crossed from one side of the pivot to the other unless it keeps track of which items those are. Such tracking would require extra time and memory, which
Sort opts not to spend.
If two runs of
Sort on a given list always perform the same sequence of steps, then the final ordering should match. The documentation for
Sort, however, does not specify the exact sequence of steps it performs, and it would be possible that one machine has a version of .NET which does things slightly differently from the other. The essential thing to note is that if you need a "stable" sort [one in which the relative sequence of equal items after sorting is guaranteed to match the sequence before sorting], you will either need to use a sorting method which guarantees such behavior, or else add an additional field to your items which could be preloaded with their initial position in the array, and make your
CompareTo function check that field when items are otherwise equal.