# Is a data structure implementation with O(1) search possible without using arrays?

I am currently taking a university course in data structures, and this topic has been bothering me for a while now (this is not a homework assignment, just a purely theoretical question).

Let's assume you want to implement a dictionary. The dictionary should, of course, have a search function, accepting a key and returning a value.

Right now, I can only imagine 2 very general methods of implementing such a thing:

• Using some kind of search tree, which would (always?) give an O(log n) worst case running time for finding the value by the key, or,
• Hashing the key, which essentially returns a natural number which corresponds to an index in an array of values, giving an O(1) worst case running time.

Is O(1) worst case running time possible for a search function, without the use of arrays?

Is random access available only through the use of arrays?
Is it possible through the use of a pointer-based data structure (such as linked lists, search trees, etc.)?

Is it possible when making some specific assumptions, for example, the keys being in some order?

In other words, can you think of an implementation (if one is possible) for the search function and the dictionary that will receive any key in the dictionary and return its value in O(1) time, without using arrays for random access?

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A hashtable is only O(1) in the worst case if you have perfect hashing. In practice, a hashtable is O(1) in the average case and usually O(n) in the worst case. –  Daniel Pryden Apr 15 '11 at 2:11
Interesting insight. I am not very familiar with how hashtables are implemented, aren't they generally implemented like the second method I've suggested? –  GeReV Apr 15 '11 at 2:14
Yes, but in real-world use cases you need to take hash collisions into account. Wikipedia has a simple overview to get you started. –  Daniel Pryden Apr 15 '11 at 2:16
Accounting for hash collisions means that each table entry will potentially hold multiple values, so it has to have an array. Depending on how strictly you interpret the "without arrays" requirement, that could mean that a hash table solution wouldn't be allowed for this question. –  Sherm Pendley Apr 15 '11 at 2:48
@Sherm: The table entries could have linked lists instead, so to be more specific, "without arrays" means without arrays that could be used like the second method in the question - preventing random access with arrays. –  GeReV Apr 15 '11 at 2:54

Here's another answer I made on that general subject. Essentially, algorithms reach their results by processing a certain number of bits of information. The length of time they take depends on how quickly they can do that.

A decision point having only 2 branches cannot process more than 1 bit of information. However, a decision point having n branches can process up to log(n) bits (base 2).

The only mechanism I'm aware of, in computers, that can process more than 1 bit of information, in a single operation, is indexing, whether it is indexing an array or executing a jump table (which is indexing an array).

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Thank you, that's a great answer! –  GeReV Apr 17 '11 at 1:09

you could have a hash implemented with a trie tree. The complexity is O(max(length(string))), if you have strings of limited size, then you could say it runs in O(1), it doesn't depend on the number of strings you have in the structure. http://en.wikipedia.org/wiki/Trie

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Yes but the minimum key size is still proportional to log n. So as n increases, so does the key. Hence this is still a O(log n) structure. –  ThomasMcLeod Apr 15 '11 at 4:31
@ThomasMcLeod, While you are right in theory, this is basically a B-Tree just like a database. With a small amount of hand-waving you can consider it linear time lookup. For instance, if we allow the "string" to have the entire range of values for a byte, then with a length of 5 you have over a trillion possible values. While it's technically O(log n), in reality n is so small you can consider it constant. –  tster Apr 17 '11 at 0:52