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During an assignment, I was asked to show that a hash table of size m (m>3, m is prime) that is less than half full, and that uses quadratic checking (hash(k, i) = (h(k) + i^2) mod m) we will always find a free spot.

I've checked and arrived to the conclusion that the spots that will be found (when h(k)=0) are 0 mod m, 1 mod m, 4 mod m, 9 mod m, ...
My problem is that I can't figure a way to show that it will always find the free spot. I've tested it myself with different values of m, and also have proven myself that if the hash table is more than half full, we might never find a free spot.

Can anyone please hint me towards the way to solve this?


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up vote 1 down vote accepted

0, 1, 4, ..., ((m-1)/2)^2 are all distinct mod m. Why?

Suppose two numbers from that range, i^2 and j^2, are equivalent mod m.

Then i^2 - j^2 = (i-j)(i+j) = 0 (mod m). Since m is prime, m must divide one of those factors. But the factors are both less than m, so one of them ((i-j)) is 0. That is, i = j.

Since we are starting at 0, more than half the slots that are distinct. If you can only fill less than m/2 of them, at least one remains open.

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From Wikipedia:

For prime m > 2, most choices of c1 and c2 will make h(k,i) distinct for i in [0,(m − 1) / 2]. Such choices include c1 = c2 = 1/2, c1 = c2 = 1, and c1 = 0,c2 = 1. Because there are only about m/2 distinct probes for a given element, it is difficult to guarantee that insertions will succeed when the load factor is > 1/2.

See the quadratic probing section in Data Structures and Algorithms with Object-Oriented Design Patterns in C++ for a proof that m/2 elements are distinct when m is prime.

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Thank you! if only I knew it was called 'probing' in English and not 'testing'... :) – CS n00b Jan 3 '10 at 9:46
Unfortunately, the cited proof is not for the m is prime part, but for the m is a power of 2 part. – CS n00b Jan 3 '10 at 9:50
You're right, I'll remove the link. – Pedro Silva Jan 3 '10 at 10:07

Let's break the proof down.


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.

  1. 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.

  2. h_a(q) and h_b(q) must probe the same position, by (1), so h_a(q) = h_b(q).

  3. h_a(q) = h_b(q) ==> h(q) + c(a) = h(q) + c(b), mod M.

  4. The h(q) on both sides cancel. Our c(i) is just c(i) = i^2, so we have a^2 = b^2.

  5. 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.

  6. 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.

  7. Case I can't be right, because we said that a != b, so a - b must be something other than zero.

  8. 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!

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