## Division Method

"When using the division method, we usually avoid certain values of m
(table size). For example, m should not be a power of `2`

, since if m =
`2`^{p}

, then `h(k)`

is just the `p`

lowest-order bits of `k`

."

--CLRS

To understand why `m = 2`^{p}

uses only the `p`

lowest bits of `k`

, you must first understand the modulo hash function `h(k) = k % m`

.

The key can be written in terms of a quotient `q`

, and remainder `r`

.

```
k = nq + r
```

Choosing the quotient to be `q = m`

allows us to write `k % m`

simply as the remainder in the above equation:

```
k % m = r = k - nm, where r < m
```

Therefore, `k % m`

is equivalent to continuously subtracting `m`

a total of `n`

times (until `r < m`

):

```
k % m = k - m - m - ... - m, until r < m
```

Lets try hashing the key `k = 91`

with `m = 2`^{4} = 16

.

```
91 = 0101 1011
- 16 = 0001 0000
----------------
75 = 0100 1011
- 16 = 0001 0000
----------------
59 = 0011 1011
- 16 = 0001 0000
----------------
43 = 0010 1011
- 16 = 0001 0000
----------------
27 = 0001 1011
- 16 = 0001 0000
----------------
11 = 0000 1011
```

Thus, `91 % 2`^{4} = 11

is just the binary form of `91`

with only the `p=4`

lowest bits remaining.

**Important Distinction:**

This pertains specifically to the *division method* of hashing. In fact, the converse is true for the *multiplication method* as stated in CLRS:

"An advantage of the multiplication method is that the value of m is not critical... We typically choose [m] to be a power of 2 since we can then easily implement the function on most computers."

`> PS: I am aware of: Hash table: why size should be prime?`

- then read it again, or link through to this one – sehe May 8 '11 at 20:25`n!`

). But that is not the generic science behind hashing. – sehe May 8 '11 at 21:31`Clash`

is a very nice screen name to use when talking about hash collisions :) – sehe May 8 '11 at 21:31