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I'm required to hold, in memory, and look-up through one million uniformly distributed integers. My workload is extremely look-up intensive.
My current implementation uses a HashSet (Java). I see good look-up performance, but the memory usage is not ideal (dozens of MB).
Could you think of a more efficient (memory) data structure?
Edit: The solution will need to support a small amount additions to the data stracture.

The Integers problem stated above is a simplification of the following problem:
I have a set of one million Strings (my "Dictionary"), and I want to tell whether the Dictionary contains a given string, or not.
The Dictionary is too large to fit in memory, so I'm willing to sacrifice a tiny bit of accuracy to reduce memory footprint. I'll do that by switching to a Dictionary containing each String's Hashcode value (integer), instead of the actual chars. I'm Assuming that the chance of a collision, per string, is only 1M/2^32.

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Could be a job for a Bloom filter? –  Gareth Rees Mar 17 '12 at 21:28
do you need an insert operation or is the dictionary built once and never modified any more during the lookups ? –  Andre Holzner Mar 17 '12 at 21:34
@Gareth Rees: why don't you post that as an answer so it can be upvoted? –  meriton Mar 17 '12 at 21:47
@meriton: Done. –  Gareth Rees Mar 18 '12 at 10:21
@Andre - Thank you for being a careful reader. I did made the mistake of not explicitly stating that The solution will need to support a small amount additions to the data structure. –  Gili Nachum Mar 19 '12 at 22:34

5 Answers 5

While Jon Skeet's answer gives good savings for a small investment, I think you can do better. Since your numbers are fairly even distributed, you can use an interpolating search for faster lookups (roughly O(log log N) instead of O(log N)). For a million items, you can probably plan on around 4 comparisons instead of around 20.

If you want to do just a little more work to cut the memory (roughly) in half again, you could build it as a two-level lookup table, basically a sort of simple version of a trie.

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You'd break your (presumably) 32-bit integer into two 16-bit pieces. You'd use the first 16 bits as an index into the first level of the lookup table. At this level, you'd have 65536 pointers, one for each possible 16-bit value for that part of your integer. That would take you to the second level of the table. For this part, we'd do a binary or interpolation search between the chosen pointer, and the next one up -- i.e., all the values in the second level that had that same value in the first 16 bits.

When we look in the second table, however, we already know 16 bits of the value -- so instead of storing all 32 bits of the value, we only have to store the other 16 bits of the value.

That means instead of the second level occupying 4 megabytes, we've reduced it to 2 megabytes. Along with that we need the first level table, but it's only 65536x4=256K bytes.

This will almost certainly improve speed over a binary search of the entire data set. In the worst case (using a binary search for the second level) we could have as many as 17 comparisons (1 + log2 65536). The average will be better than that though -- since we have only a million items, there can only be an average of 1_000_000/65536 = ~15 items in each second-level "partition", giving approximately 1 + log2(16) = 5 comparisons. Using an interpolating search at the second level might reduce that a little further, but when you're only starting with 5 comparisons, you don't have much room left for really dramatic improvements. Given an average of only ~15 items at the second level, the type of search you use won't make much difference -- even a linear search is going to be pretty fast.

Of course, if you wanted to you could go a step further and use a 4-level table instead (one for each byte in the integer). It may be open to question, however, whether that would save you enough more to be worth the trouble. At least right off, my immediate guess is that you'd be doing a fair amount of extra work for fairly minimal savings (just storing the final bytes of the million integers obviously occupies 1 megabyte, and three levels of table leading to that would clearly occupy a fair amount more, so you'd double the number of levels to save something like half a megabyte. If you're in a situation where saving just a little more would make a big difference, go for it -- but otherwise, I doubt whether the return will justify the extra investment.

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nice optimization indeed. I guess it will come in handy once I'll have one/two orders of magnitude more data. –  Gili Nachum Mar 19 '12 at 22:42

Sounds like you could just keep a sorted int[] and then do a binary search. With a million values, that's ~20 comparisons to get to any value - would that be fast enough?

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But this should have the same memory footprint as a HashSet, no? –  user949300 Mar 17 '12 at 21:22
@user949300: No, because a HashSet will have to allocate an Integer object for each value (massive difference in size!), and it won't be densely populated like I'm suggesting, and it will have to keep the hash code for each value and it will have an Entry object for each value (which will contain the hash code, of course, so that's somewhat double counting). All of this busts the cache more as well as taking more memory, of course. –  Jon Skeet Mar 17 '12 at 21:25
@user949300 No, the HashSet is backed by a HashMap and has quite a few empty cells, depending on the actual values you store. –  Jochen Mar 17 '12 at 21:25
Some of the smaller Integers are already cached (no memory alloc) but yes, it would be allocating a bunch of the large ones. So your idea has a roughly 4X space savings, not even counting the Entry object, which I forgot about. I'm apparently focusing too much on my fantasy baseball team this afternoon. :-) –  user949300 Mar 17 '12 at 21:34
@GiliNachum: Nope, that sounds like the best you're likely to manage. As you say, keep a large int[] and a HashSet<Integer> - only merge the set into the array when it starts getting large. –  Jon Skeet Mar 19 '12 at 22:42

If you are willing to accept a small chance of a false positive in return for a large reduction in memory usage, then a Bloom filter may be just what you need.

A Bloom filter consists of k hash functions and a table of n bits, initially empty. To add an item to the table, feed it to each of the k hash functions (getting a number between 0 and n−1) and set the corresponding bit. To check if an item is in the table, feed it to each of the k hash functions and see if all corresponding k bits are set.

A Bloom filter with a 1% false positive rate requires about 10 bits per item; the false positive rate decreases rapidly as you add more bits per item.

Here's an open-source implementation in Java.

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There are some IntHashSet implementations for primitives available.

Quick googling got me this one. There is also an apache [open source] implementation of IntHashSet. I'd prefer the apache implementation, though it has some overhead [it is implemented as a IntToIntMap]

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You might want to take a look at a BitSet The one used in Lucene is even faster as the standard Java implementation since it neglects some standard boundary checks.

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My first response wqas a Bitset, but then realized that since hashCodes go up to 2^31 the size could be huge, if both very low values (near 0) and large (near MAXINT) were included. Alsom, you'd need two Bitsets, one for the positives, one for the negatives –  user949300 Mar 18 '12 at 3:04
@user949300 if you need two BitSets then each will hold half the bits, and to store 2^32 bits requires 2^29 bytes - large but not impossible. I think the Bloom Filter from a different answer would be a better solution, since it can achieve lower memory usage with a higher rejection of false positives. –  Mark Ransom Dec 17 '14 at 22:19

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