This is a question that's been lingering in my mind for some time ...

Suppose I have a list of items and an equivalence relation on them, and comparing two items takes constant time. I want to return a partition of the items, e.g. a list of linked lists, each containing all equivalent items.

One way of doing this is to extend the equivalence to an ordering on the items and order them (with a sorting algorithm); then all equivalent items will be adjacent.

But can it be done more efficiently than with sorting? Is the time complexity of this problem lower than that of sorting? If not, why not?

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You seem to be asking two different questions at one go here.

1) If allowing only equality checks, does it make partition easier than if we had some ordering? The answer is, no. You require Omega(n^2) comparisons to determine the partitioning in the worst case (all different for instance).

2) If allowing ordering, is partitioning easier than sorting? The answer again is no. This is because of the Element Distinctness Problem. Which says that in order to even determine if all objects are distinct, you require Omega(nlogn) comparisons. Since sorting can be done in O(nlogn) time (and also have Omega(nlogn) lower bounds) and solves the partition problem, asymptotically they are equally hard.

If you pick an arbitrary hash function, equal objects need not have the same hash, in which case you haven't done any useful work by putting them in a hashtable.

Even if you do come up with such a hash (equal objects guaranteed to have the same hash), the time complexity is expected O(n) for good hashes, and worst case is Omega(n^2).

Whether to use hashing or sorting completely depends on other constraints not available in the question.

The other answers also seem to be forgetting that your question is (mainly) about comparing partitioning and sorting!

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    Any hash value which does not yield equal hashes for equal objects is broken. Part of the definition of a hash function (indeed, practically the only requirement) is that equal values must yield equal hashes. – supercat Jul 15 '10 at 15:48
  • The latter is exactly what I was looking for. Thanks! – reinierpost Jul 15 '10 at 15:51
  • @supercat: If we had such a hash would we even be having this question posted? My guess is no. Given an arbitrary equality/compare function on objects, it might be hard to come up with such a hash and solving that might well involve solving the partition problem. So just claiming that hashing is a solution is not really helpful. – Aryabhatta Jul 15 '10 at 16:06
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    @supercat: "Any hash value which does not yield equal hashes for equal objects is broken." -- that's true, but in this case the hash also needs to yield equal hashes for equivalent objects. There's a difference between equivalence and equality. "John Smith" is not equal to "Fred Smith" but they may be equivalent if you have defined equivalence to only consider last names. – Dan Jul 15 '10 at 18:04
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    @Dimi: Without even knowing if a suitable hash function exists you want to suggest hashing to a question whose title is "Is Partitioning easier than Sorting"!? No one is claiming sorting is better (I am repeating myself here) than hashing in practice. If you have a decent hash function sure, use it. If you notice, the question was a theoretical one and the better or worse was only in terms of the worst case complexity. My answer does mention that hashing is expected O(n) with a decent hash. If you see the answer I linked to earlier, I hope you will agree that sorting might be better there. – Aryabhatta Jul 16 '10 at 18:06

If you can define a hash function for the items as well as an equivalence relation, then you should be able to do the partition in linear time -- assuming computing the hash is constant time. The hash function must map equivalent items to the same hash value.

Without a hash function, you would have to compare every new item to be inserted into the partitioned lists against the head of each existing list. The efficiency of that strategy depends on how many partitions there will eventually be.

Let's say you have 100 items, and they will eventually be partitioned into 3 lists. Then each item would have to be compared against at most 3 other items before inserting it into one of the lists.

However, if those 100 items would eventually be partitioned into 90 lists (i.e., very few equivalent items), it's a different story. Now your runtime is closer to quadratic than linear.

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    Adding to a hash table is essentially just this, where the equivalence relation is (hash maps to same bucket). You haven't simplified the problem at all. – Anthony Williams Jul 15 '10 at 14:40
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    @Anthony: you still need the equivalence relation to check for hash collision. – Dan Jul 15 '10 at 14:43
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    Unless the hash value cleanly maps to the equivalence classes (i.e. equal hashes implies the values belong in the same partition) then hashing doesn't help. – Anthony Williams Jul 15 '10 at 16:02
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    @supercat: No one is disputing the benefits of a good, applicable hash function. If you read the question again, it is clear that OP is looking to compare partitioning with sorting under the constraint of using a comparison function. The talk of hashing, is just noise, especially when there are no guarantees of finding a good hash function (we don't even know what objects/compare functions OP has in mind) more easily than solving partitioning. – Aryabhatta Jul 15 '10 at 16:54
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    @Dan: Yes, but given an arbitrary equivalence relation, defining such a hash is the hardest part of the problem. (I don't think it's possible in o(n log n) time... and may be even harder depending on how the equivalence is given.) So you've not simplified the problem at all, just restated it (or assumed that the equivalence relation is something sufficiently trivial that defining a hash is trivial). – ShreevatsaR Jul 15 '10 at 18:18

If you don't care about the final ordering of the equivalence sets, then partitioning into equivalence sets could be quicker. However, it depends on the algorithm and the numbers of elements in each set.

If there are very few items in each set, then you might as well just sort the elements and then find the adjacent equal elements. A good sorting algorithm is O(n log n) for n elements.

If there are a few sets with lots of elements in each then you can take each element, and compare to the existing sets. If it belongs in one of them then add it, otherwise create a new set. This will be O(n*m) where n is the number of elements, and m is the number of equivalence sets, which is less then O(n log n) for large n and small m, but worse as m tends to n.

A combined sorting/partitioning algorithm may be quicker.

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    Using hashing, the problem can almost certainly be solved in O(N) time, though a good hash function may take long enough to compute that an O(NlgN) algorithm could be faster. Storing observed keys in a tree and discarding duplicates would yield a time of O(NlgM), where N is the number of elements and M is the number of distinct ones. – supercat Jul 15 '10 at 16:06
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    Only if the hash function helps identify the equivalence classes (i.e. non-equal but equivalent values have the same hash) – Anthony Williams Jul 15 '10 at 16:45

If a comparator must be used, then the lower bound is Ω(n log n) comparisons for sorting or partitioning. The reason is all elements must be inspected Ω(n), and a comparator must perform log n comparisons for each element to uniquely identify or place that element in relation to the others (each comparison divides the space in 2, and so for a space of size n, log n comparisons are needed.)

If each element can be associated with a unique key which is derived in constant time, then the lowerbound is Ω(n), for sorting ant partitioning (c.f. RadixSort)

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    That's not a great explanation of the lower bound. Sorting requires Ω(n log n) comparisons because it takes log(n!) = Ω(n log n) bits to describe one of n! permutations. Information-theoretically, partitioning is as hard as sorting because if an adversary chooses comparison results as though there are n distinct partitions, it can change its mind at any point prior to the input having been sorted by putting two adjacent elements whose order is not known into one partition. – user382751 Jul 15 '10 at 14:58
  • I was going for the intuitive angle. For example, compare adding n items to self-balancing tree or skiplist. It then requires n log n comparisons, and the result is a sorted collection. Given that partitioning can be recast as a sorting problem, surely partitioning is no harder than sorting, and the complexity depends upon how items are compared, either by hashing or by comparison. Given that the lower bound for radix sort is linear, then partitioning in that case can be no more efficient than that. – mdma Jul 15 '10 at 15:12
  • @mdma: Please use Omega instead of bigOh when talking about lower bounds. – Aryabhatta Jul 15 '10 at 16:26
  • Sure, I was unsure how to format it. I'll paste in the nice omega sign from the comment above. – mdma Jul 15 '10 at 16:39
  • @mdma: You can always use Omega :-) I wish there was some latex like support here. – Aryabhatta Jul 15 '10 at 17:28

Comparison based sorting generally has a lower bound of O(n log n).

Assume you iterate over your set of items and put them in buckets with items with the same comparative value, for example in a set of lists (say using a hash set). This operation is clearly O(n), even after retreiving the list of lists from the set.

--- EDIT: ---

This of course requires two assumptions:

  • There exists a constant time hash-algorithm for each element to be partitioned.
  • The number of buckets does not depend on the amount of input.

Thus, the lower bound of partitioning is O(n).

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  • This assumes the items have a "getHashCode" method available, or some other way of associating all items that equal each other with a unique key. – Peter Recore Jul 15 '10 at 14:40
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    This is not O(n). It is O(n*bucket count). – Anthony Williams Jul 15 '10 at 14:42
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    @Anthony Williams So you're saying that O(N) is not equivalent to O(N * some constant )!? – wheaties Jul 15 '10 at 14:48
  • @Anthony: But O(n*constant value) = O(n). – JAB Jul 15 '10 at 14:49
  • @JAB. Anthony is right. bucket count could very well be n/2 here. What makes you think it is a constant? – Aryabhatta Jul 15 '10 at 14:58

Partitioning is faster than sorting, in general, because you don't have to compare each element to each potentially-equivalent already-sorted element, you only have to compare it to the already-established keys of your partitioning. Take a close look at radix sort. The first step of radix sort is to partition the input based on some part of the key. Radix sort is O(kN). If your data set has keys bounded by a given length k, you can radix sort it O(n). If your data are comparable and don't have a bounded key, but you choose a bounded key with which to partition the set, the complexity of sorting the set would be O(n log n) and the partitioning would be O(n).

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  • Big-O aside, it should be noted that the choice of key will have a big effect on speed, whether partitioning or radix sorting, with respect to a particular data set. Also, sets with few equivalent elements will favor sorting and sets with many equivalent elements will favor partitioning. – Eric Mickelsen Jul 15 '10 at 14:50
  • Doing a radix sort on a hash (which is essentially what one would get from recursively hashing into buckets) is apt to be much faster than radix sorting on typical keys, because the distribution will be much better. A typical radix sort scenario with 256 bins might end up with some bins containing 10% or more of the input records; a hash radix sort with 256 bins would be very unlikely to end up with a bin holding more than 1-2% of the input records unless more than 1% of the input records had identical keys. – supercat Jul 15 '10 at 16:00
  • @supercat: Wouldn't a hash with only 256 bins have a ridiculously high number of hash collisions (except for tiny sets), thus counter-acting the benefit of more uniform distribution? I'm not sure there really is such a thing as a "hash radix sort." Could you provide a reference to support your claim? – Eric Mickelsen Jul 15 '10 at 17:19
  • The number 256 is arbitrary; my point was that dividing items into bins based upon a hash function will result in all the bins being much more uniformly filled than would dividing them into bins using a typical radix-sort function. I'm unaware of such a thing as a "hash radix sort" per se, but one could use a radix sort on the output of a hash function just as well as one could use one on anything else. – supercat Jul 19 '10 at 21:34

This is a classic problem in data structures, and yes, it is easier than sorting. If you want to also quickly be able to look up which set each element belongs to, what you want is the disjoint set data structure, together with the union-find operation. See here: http://en.wikipedia.org/wiki/Disjoint-set_data_structure

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  • How is it easier than sorting? – reinierpost May 25 '16 at 8:10

The time required to perform a possibly-imperfect partition using a hash function will be O(n+bucketcount) [not O(n*bucketcount)]. Making the bucket count large enough to avoid all collisions will be expensive, but if the hash function works at all well there should be a small number of distinct values in each bucket. If one can easily generate multiple statistically-independent hash functions, one could take each bucket whose keys don't all match the first one and use another hash function to partition the contents of that bucket.

Assuming a constant number of buckets on each step, the time is going to be O(NlgN), but if one sets the number of buckets to something like sqrt(N), the average number of passes should be O(1) and the work in each pass O(n).

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