nwinkler's algorithm (which is in fact what would be generated by Eclipse when using the Source > Generate hashcode and equals... functionality) is similar to what Joshua Bloch describes in Effective Java (as referenced in Puce's answer).

The idea is to combine hashcodes computed for significant fields. The use of the odd prime number 31 can result in a jvm optimization of the multiplication (into a shift + substraction). Note that you **must** exclude fields that are not used in equals() from this hashcode computation. You *may* exclude fields whose values are computed from fields included in the computation.

The suggested hashcode computation for an Object field is simply to recursively call its hashcode method, provided it is not null (in which case we use 0) and the object's equals() method is itself recursively called in our equals() method. If the latter is not the case (equals does a more complex comparison on our object field), suggested approach is to construct a canonical representation and compute an hashcode for it.

To compute an hashcode for primitive fields, following methods are suggested (note that they must still be combined into the result by doing result = result * prime + fieldHashCode):

- float:
`Float.floatToIntBits(f)`

- int, byte, char, short:
`(int) f`

- long =>
`(int) (f ^ (f>>>32))`

- boolean:
`(f?1:0)`

- double:
`longHash= Double.doubleToLongBits(f)`

then use `(int) (longHash^(longHash>>>32))`

- arrays: in java 1.5, some hashCode methods where introduced in the Arrays class. you can also apply previous rules recursively on the elements of the array as if they were fields themselves.