The goal of a hashing function is to map the contents of an arbitrary data structure to an integer in such a way that most of the items you're likely to encounter map to different integers, and that the complete set of items you're likely to encounter together spreads out evenly over the set of integers. With such a function in hand, it becomes easy to build a container (such as `unordered_map`

) that looks up arbitrary items very quickly.

I realize that definition is somewhat abstract. More concretely, consider the example you gave above from Wikipedia. It XORs the `i`

, `j`

and `k`

fields of the structure together to form a hash value. This is a valid hashing function (it merged the structure down to a single integer). But, if `i`

, `j`

and `k`

all have similar ranges of values, then it may not be a terribly great hashing function. For example, `(1,2,3)`

and `(3,1,2)`

both will hash to the same value.

An ideal hashing function usually looks more like a random number generator: For predictable inputs, it gives seemingly random outputs. (But remember, the same input must always give the same output.) The best hash function for your data structure really depends on what sort of data you'll be hashing.

This set of lecture notes looks like it covers most of the important points: http://www.cs.cornell.edu/Courses/cs312/2008sp/lectures/lec21.html

You can find others by googling.

`int`

values of the structure, the result being the hash-value of that structure type. What itdoesn'tdo is provide a proper example of a specialization of`std::hash<X>`

, which is the "correct" way of naturally providing custom hashing to a`std::unordered_xxxx`

container. As to why you need a hash function, you'll be hard-pressed to use a hash-based associative container without one. – WhozCraig Dec 7 '13 at 2:36