First of all we are talking about an *open addressing* (or *closed hashing*) approach. You need to handle collisions calculating a new hashcode if the previous one is already used by another one, this because every bucket of the hashamap can contain at most 1 element.

So you have an hashing function with two parameters:

`v`

, the value of the object used to compute hashcode.
`t`

, it's `i*f`

where `i`

, called *stepsize*, is what you add everytime to you hash function if a collision occur and `f`

is the number of collisions reached so far.

Starting from this you have two possible functions:

```
H(v, t) = (H(v) + t) % n
H(v, t) = (H(v) + c*t + d*t*t) % n
```

First one is a *linear function*, while second is a *quadratic one* (here it comes the names of this tecnique).. where you should know what `% n`

is, `c`

and `d`

are chosen constants to have a better hashfunction..

Practically speaking for linear probing:

- you caculate
`H(x, 0)`

- if cell is free place the element there

- if cell is occupied calculate
`H(x, i)`

- if cell is free place the element in the new address

- if cell is occupied then calculate
`H(x, i+i)`

- continue until you find an empty cell

for the *quadratic probing* what you do is identical, you start from `H(x,0)`

, then `H(x,i)`

then `H(x,i+i)`

, what differs is the hashing function involved which will give a different weight to the step size.