# What is the possiblity of CRC16 collisions on 20 bytes of data?

I am developing a system which needs to store a hash for a structure 20 bytes maybe less in length. However, in order to optimize the process of looking up the hash in a series of hashes, we want to reduce the size of the hash as much as possible.

So my question is this, is there a relationship between the amount of data we feed into a crc16 hash and the probability of its collision with another entry of the same length? If so, which is the most optimal length for this?

Thanks

18 of the bytes fall within the ascii table (a-z, 0-9), and the remaining range between 0 and 10

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Just to make sure... your hash can handle collisions, right? That is, if you end up with a collision, you store all in the same key and then do a secondary search to resolve ambiguities and indexing? – RonaldBarzell Dec 22 '12 at 0:38
Yes, the has system can handle a collision of hashes. – Jeremy Dec 22 '12 at 0:40
Ok; I know it sounded like a dumb question, but I had to make sure :) – RonaldBarzell Dec 22 '12 at 0:48

The following simple script runs an infinite loop that fetches 2 random 20-byte sequences, calculates CRC16 and checks if there is a collision. Continuous evaluation of this loop de facto estimates collision percentage:

``````#!/usr/bin/env perl

use Digest::CRC qw(crc16);

open(my \$f, '<', '/dev/urandom');
my \$n = 0;
my \$coll = 0;

while (1) {
read \$f, \$randstr1, 20;
read \$f, \$randstr2, 20;
my \$crc1 = crc16(\$randstr1);
my \$crc2 = crc16(\$randstr2);

\$n++;
\$coll++ if \$crc1 == \$crc2;

printf "percent of collisions = %.6f%%\n", \$coll * 100.0 / \$n if (\$n % 100000 == 0);
}
``````

From what I get on my computer, collision percentage seems to be around `0.0016%` (or `1e-5`, or "1 in 100_000"), which is way worse than predicted estimates based on ideal hashing distribution of a 16-bit hash (such as 2^16 / 2^160).

UPDATE: I see you've clarified that 20 bytes are not just fully random bytes, but fall into range of `[a-z0-9]`. Here's the updated version that estimates collisions in that alphabet:

``````#!/usr/bin/env perl

use Digest::CRC qw(crc16);

my \$n = 0;
my \$coll = 0;
my @chars = ('a'..'z', '0'..'9');

sub randstr() {
my \$res;
foreach (1..20) { \$res .= \$chars[rand @chars]; }
return \$res;
}

while (1) {
my \$crc1 = crc16(randstr());
my \$crc2 = crc16(randstr());

\$n++;
\$coll++ if \$crc1 == \$crc2;

printf "percent of collisions = %.4f%%\n", \$coll * 100.0 / \$n if (\$n % 100000 == 0);
}
``````

It yields approximately the same result, about `0.0016%`.

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A good 16-bit hash should have a probability of 2^-16 of collision given two distinct inputs. CRC16 isn't a very good hash, but unless you have an adversary picking the inputs, it should be good enough for your purposes.

Keep in mind the birthday paradox. You'll start to get collisions after you hash about 2^8 items.

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Whether or not you get a likely hash collision depends on the contents of the data, not its quantity. If it's not deliberately chosen to collide, then you should be pretty safe in a situation like this where the size of the data is 10x the size of hash. That said, it's still a 16 bit hash and the likelihood of collisions is quite high by modern standards.

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You are using 16 bits to hash 20x8 = 160 bits, so the probability of collision is 2^16 / 2^160 = 2^(-144) = 4.48 x 10^(-44), or one in 4.48 x 10^44. I would say that's VERY low.

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-1: No, the probability of collision is 2^-16 regardless of input size. – Keith Randall Dec 22 '12 at 0:46
Not if the input size is less than 16 bits it isn't... – Andy Ross Dec 23 '12 at 5:32
By saying `2^16` you're assuming the hash is evenly distributed, which for CRC is not true. – poolie Aug 8 '13 at 5:42