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Consider objects with an order property. Objects will be sorted based on this property.

How would you assign the order property given the following restrictions and operations?

Operations (in order of importance)

push(object): Insert object at index 0.

swap(indexN, indexM): Swap object at index N with object at index M.

remove(object): Remove object. Remaining elements must retain the same order.

insert(object): Insert object with given order.

Restrictions

Changing the order property of an object is expensive. Changes should be minimised.

order can be integral or floating point, as required by the implementation.

If order is kept unique, then operation insert must include a way to fix the order if it already exists, making as few changes as possible. It can be assumed that if an inserted object has the same order than an existing object, there is another criteria to determine which one goes first.

If order allows duplicates, then operation swap must include a way to fix the order of the swapped elements if they have the same value, again making as few changes as possible. Penalising operation insert is preferred.

Most likely this problem has a name and a known solution already but I couldn't find it at first glance.

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could you provide a sample use case? might help understand where you're coming from better. – Claudiu Feb 15 '14 at 1:43
    
Thanks for asking. It's for a list of digital objects that can be manually ordered and can be edited in many devices simultaneously. Thus, it is possible for objects to be added in different devices with the same order. Synching has to deal with this case. – hpique Feb 15 '14 at 1:52
    
hmm ok. how do you want to handle incompatible orderings, e.g. one device has A,B,C,D, the other has it as D,C,B,A, what do you do when you sync? – Claudiu Feb 15 '14 at 2:02
    
It would leave that out of the scope of the question. I prefer to focus on the four primitives push, swap, remove and insert. – hpique Feb 15 '14 at 10:31
    
I don't understand. You can turn ABCD into DCBA via just swapping. what is the user allowed to do and what isn't he? – Claudiu Feb 15 '14 at 10:53
up vote 2 down vote accepted

Use floating point for order

For push, assign the object an order equal to the order of the object that's now at index 1, minus 1 (list[0].order = list[1].order - 1)

For swap, swap the two objects' orders (temp = list[i]; list[i] = list[j]; list[j] = list[i]; temp = list[i].order; list[i].order = list[j].order; list[j].order = temp); if this might introduce consistency problems then ideally you could put a transit flag on the elements to indicate that their order is in the process of being modified, or worst case lock the objects until they're consistent

For remove, do nothing - the objects in the list are still ordered, you've just introduced a gap in the sequence which shouldn't be a problem

insert is the only problematic one. If you're inserting an element at index i, then its order is equal to the average of the orders of the elements at indices i-1 and i+1 (list[i].order = (list[i-1].order + list[i+1].order)/2). Verify that this new order doesn't equal the order at index i-1 or i+1 (list[i].order != list[i-1].order && list[i].order != list[i+1].order) - this would indicate that you've hit machine epsilon. When this occurs (and this should rarely if ever occur) you've got two options:

  1. Bite the bullet and reorder your entire list, i.e. assign an order of 0 at index 0, an order 1 at index 1, ... an order n at index n.
  2. Do a local reorder to try to minimize the cost. Reorder the adjacent elements to list[i-1].order = (list[i-2].order + list[i-1].order)/2 and list[i+1].order = (list[i+2].order + list[i+1].order)/2 before reordering list[i] = (list[i-1] + list[i+1])/2, again verifying that you haven't reached machine episilon at your [i-1] and [i+1] reordering - if you have reached machine epsilon at e.g. [i-1], then first reorder [i-2] to list[i-2].order = (list[i-3].order + list[i-2].order)/2, and then reorder [i-1]. If the [i-2] reorder hits machine epsilon then first reorder [i-3], and so on. (If you reach the end of the list then simply decrement the order of element [0] or increment the order of element [n].) As you can see, in the worst case you've got a cascade reordering that is more expensive than had you simply bit the bullet and reordered the entire list; however, in all likelihood the reordering will remain local. A good compromise is that if you've cascaded too many times (for a reasonable value of "too many") then do a complete reordering.
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+1 Thanks for a the detailed answer Zim-Zam. I think you meant push instead of the first insert. Also, insert is not given an index but an order, so your solution would require searching the whole list to find the index in which it would fit, then replacing its order with the middle of its adjacent objects and then dealing with machine epsilon. Which is fine. Finally, would you use zero or max float as your initial order value? Which one is least likely to produce machine epsilon hits? – hpique Feb 15 '14 at 10:49
    
@hpique To help avoid machine epsilon hits, decrement by a value greater than 1 in the push operation, e.g. decrementVal = 2^10; list[0].order = list[1].order - decrementVal, then to reduce the likelihood that you'll reach MIN_FLOAT during a push your initial order value should be something like MAX_FLOAT - decrementVal^2 - by subtracting decrementVal^2 you simplify the corner case of inserting at the end of the list, allowing you to increment the order of the last list element by decrementVal. – Zim-Zam O'Pootertoot Feb 15 '14 at 15:19

Just to throw it out there, a doubly linked list gives you:

  • push(object): O(1), give it order 1 less than the current head.
  • swap(indexN, indexM): O(n), swap the orders
  • remove(object): O(1), don't touch any orders
  • insert(object): O(n), insert the order so the list is sorted in terms of order

Might not be good since the 2nd most important one has an expensive (change order) operation.

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Correct me if I'm wrong, but remove will be O(n) since you need to find the node to remove first. – Dukeling Feb 15 '14 at 18:15
    
@Dukeling: when you load the objects up, construct a doubly-linked list, associating each object in the list with the fwd + back pointers. so now you have it instantly with just one O(n) at load-time – Claudiu Feb 15 '14 at 19:19

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