Let's break the proof down.

## Setup

First, some background.

With a hash table, we define a *probe sequence* `P`

. For any item `q`

, following `P`

will eventually lead to the right item in the hash table. The probe sequence is just a series of functions `{h_0, ..., h_M-1}`

where `h_i`

is a hash function.

To insert an item `q`

into the table, we look at `h_0(q)`

, `h_1(q)`

, and so on, until we find an empty spot. To find `q`

later, we examine the same sequence of locations.

In general, the probe sequence is of the form `h_i(q) = [h(q) + c(i)] mod M`

, for a hash table of size `M`

, where `M`

is a prime number. The function `c(i)`

is the collision-resolution strategy, which must have two properties:

First, `c(0) = 0`

. This means that the first probe in the sequence must be equal to just performing the hash.

Second, the values `{c(0) mod M, ..., c(M-1) mod M}`

must contain every integer between 0 and M-1. This means that if you keep trying to find empty spots, the probe sequence will eventually probe every array position.

## Applying quadratic probing

Okay, we've got the setup of how the hash table works. Let's look at quadratic probing. This just means that for our `c(i)`

we're using a general quadratic equation of the form `ai^2 + bi + c`

, though for most implementations you'll usually just see `c(i) = i^2`

(that is, `b, c = 0`

).

Does quadratic probing meet the two properties we talked about before? Well, it's certainly true that `c(0) = 0`

here, since `(0)^2`

is indeed `0`

, so it meets the first property. What about the second property?

It turns out that in general, the answer is no.

**Theorem.** When quadratic probing is used in a hash table of size `M`

, where `M`

is a prime number, only the first `floor[M/2]`

probes in the probe sequence are distinct.

Let's see why this is the case, using a proof by contradiction.

Say that the theorem is wrong. Then that means there are two values `a`

and `b`

such that `0 <= a < b < floor[M/2]`

that probe the same position.

`h_a(q)`

and `h_b(q)`

must probe the same position, by (1), so `h_a(q) = h_b(q)`

.

`h_a(q) = h_b(q) ==> h(q) + c(a) = h(q) + c(b)`

, `mod M`

.

The `h(q)`

on both sides cancel. Our `c(i)`

is just `c(i) = i^2`

, so we have `a^2 = b^2`

.

Solving the quadratic equation in (4) gives us `a^2 - b^2 = 0`

, mod M. This is a **difference of two squares**, so the solution is `(a - b)(a + b) = 0`

, `mod M`

.

But remember, we said `M`

was a prime number. The only way that `(a - b)(a + b)`

can be zero `mod M`

is if [**case I**] (a - b) is zero, or [**case II**] (a + b) is zero `mod M`

.

Case I can't be right, because we said that `a != b`

, so `a - b`

must be something other than zero.

The only way for `(a + b)`

to be zero `mod M`

is for `a + b`

to be equal to be a multiple of `M`

or zero. They clearly can't be zero, since they're both bigger than zero. And since they're both less than `floor[M/2]`

, their sum must be less than `M`

. So case II can't be right either.

Thus, if the theorem were wrong, one of two quantities must be zero, neither of which can possibly be zero -- a contradiction! QED: quadratic probing doesn't satisfy property two once your table is more than half full and if your table size is a prime number. The proof is complete!