# What exactly are hashtables?

• What are they and how do they work?
• Where are they used?
• When should I (not) use them?

I've heard the word over and over again, yet I don't know its exact meaning.

What I heard is that they allow associative arrays by sending the array key through a hash function that converts it into an int and then uses a regular array. Am I right with that?

(Notice: This is not my homework; I go too school but they teach us only the BASICs in informatics)

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I suspect they won't tell you very much about hash tables. They're actually quite hard to analyze (you need a probabilistic normal-case argument, not a worst-case argument) and depend on a lot of magic. Most teachers of Algorithms classes prefer to use more theoretically beautiful constructs like balanced trees, as they show off recursive arguments. Practical code uses hash tables though; it just works so well. – Donal Fellows Apr 12 '10 at 21:32

Wikipedia seems to have a pretty nice answer to what they are.

You should use them when you want to look up values by some index.

As for when you shouldn't use them... when you don't want to look up values by some index (for example, if all you want to ever do is iterate over them.)

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How in gods name can there be a hash function that always outputs the right integers like 0 1 2 3 when receiving "abc" "myCatIsFat" or "101010" as input?! – keg Apr 12 '10 at 20:32
@keg Hash functions usually return a more or less random-looking value, not sequential integers. Why are you asking? – Matti Virkkunen Apr 12 '10 at 20:37
@key That would be the perfect hash function as described in the wiki article. Read it to get why this function is hard to find and how to make the things at least semi-optimal. – PeterMmm Apr 12 '10 at 20:40
It's very very hard to write a good hash function. It's very easy to write a bad one, and the literature is not great (it's much more extensive on cryptographic hash functions). The input language matters a lot too, and some hash functions are theoretically great but slow in practice. – Donal Fellows Apr 12 '10 at 20:55
@keg as an example, a hash function that, say, just returned the length of the string representation of the input would return integers for arbitrary input. Not a very good hash function mind you, see @PeterMmm comment – Brabster Apr 12 '10 at 20:55

You've about got it. They're a very good way of mapping from arbitrary things (keys) to arbitrary things (values). The idea is that you apply a function (a hash function) that translates the key to an index into the array where you store the values; the hash function's speed is typically linear in the size of the key, which is great when key sizes are much smaller than the number of entries (i.e., the typical case).

The tricky bit is that hash functions are usually imperfect. (Perfect hash functions exist, but tend to be very specific to particular applications and particular datasets; they're hardly ever worthwhile.) There are two approaches to dealing with this, and each requires storing the key with the value: one (open addressing) is to use a pre-determined pattern to look onward from the location in the array with the hash for somewhere that is free, the other (chaining) is to store a linked list hanging off each entry in the array (so you do a linear lookup over what is hopefully a short list). The cases of production code where I've read the source code have all used chaining with dynamic rebuilding of the hash table when the load factor is excessive.

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+1 nice explanation – Brabster Apr 12 '10 at 20:58

Good hash functions are one way functions that allow you to create a distributed value from any given input. Therefore, you will get somewhat unique values for each input value. They are also repeatable, such that any input will always generate the same output.

An example of a good hash function is SHA1 or SHA256.

Let's say that you have a database table of users. The columns are `id`, `last_name`, `first_name`, `telephone_number`, and `address`.

While any of these columns could have duplicates, let's assume that no rows are exactly the same.

In this case, `id` is simply a unique primary key of our making (a surrogate key). The id field doesn't actually contain any user data because we couldn't find a natural key that was unique for users, but we use the id field for building foreign key relationships with other tables.

We could look up the user record like this from our database:

``````SELECT * FROM users
AND first_name = 'Marcus'
AND address = '1234 Main St'
AND telephone_number = '555-1212';
``````

We have to search through 4 different columns, using 4 different indexes, to find my record.

However, you could create a new "hash" column, and store the hash value of all four columns combined.

``````String myHash = myHashFunction("Marcus" + "Adams" + "1234 Main St" + "555-1212");
``````

You might get a hash value like `AE32ABC31234CAD984EA8`.

You store this hash value as a column in the database and index on that. You now only have to search one index.

``````SELECT * FROM users