Well, I think it's perfectly ordered, because position of the elements depends on their hash function, thus if that objects are immutable, then after you put them in the set, their position will remain unchanged. And everytime you, say, print your set you'll have exact the same elements order. Sure, you can't predict their position until their hash function is calculated, but anyway.

The hash function is not (usually) an externally visible or modifiable parameter of a set; moreover, even if you have an implementation where the hash function is known and well characterized, you can't specify the behavior when hash values collide. The usual summary of this is that the implementation of the set may impose an order, but the interface does not. 


To which definition of set are you referring? In my understanding, «set» is a name for a data structure that contains a number of unique elements and usually allows addition and deletion. Everything else is not guaranteed and may be subject to implementation. It doesn't say there is no order, but there is no specific order for every valid implementation. The use of hashtables is common, but using any type of list or tree is also possible. So the order might be through a hashfunction (already lots of possible implementations), or related to order of addition or ... 


Generic / abstract data typeThe definition of set from Aho, Hopcroft, Ullmann: 'Data Structures and Algorithms', AddisonWesely, 1987:
The abstract data type set does not have the characteristic of ordered or unordered. There are some methods defined which operate on a set  but none of them has something to do with ordering (e.g see Martin Richards: 'Data Structures and Algorithms'). Two sets are seen equal, if each element from one set is also inside the other  and there are no additional elements. When you write down a set (and therefore all the elements of a set) you need to write them down in some order. Note that this is just a representation of the appropriate set. Example: A set which contains the elements one, two and three can be written down as {1, 2, 3}, {1, 3, 2}, {3, 1, 2} and so on. These are only different representations of the same set. Specific implementationsIn different programming languages sets are implemented in different ways with different use cases in mind. In some languages (like python, JAVA) the standard set implementations do not expose ordering in their interfaces. In some languages (like C++) the standard set implementation exposes ordering in their interfaces. Example (C++):
(see C++ set). 

