Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am trying to generate non-sequential human readable order codes derived from (lets say) a unsigned 32bit internal id that starts at 1 and is auto incremented for each new order.

In my example code below, will every $hash be unique? (I plan to base34 encode the $hash to make it human readable.)

<?php
function int_hash($key) {
  $key = ($key^0x47cb8a8c) ^ ($key<<12);
  $key = ($key^0x61a988bc) ^ ($key>>19);
  $key = ($key^0x78d2a3c8) ^ ($key<<5);
  $key = ($key^0x5972b1be) ^ ($key<<9);
  $key = ($key^0x2ea72dfe) ^ ($key<<3);
  $key = ($key^0x5ff1057d) ^ ($key>>16);
  return $key;
}

for($order_id = 1; $order_id <= PHP_INT_MAX; ++$order_id) {
  $hash = int_hash($order_id);
}
?>

If not, are there any suggestions on how to replace int_hash?

The result of say, base34 encoding a md5($order_id) is too long for my liking.

share|improve this question
    
What makes you think that they will be unique? (aka "Why this particular algorithm?"). –  Oliver Charlesworth Mar 4 '12 at 0:18
    
I was more hoping it would be. Perhaps I should have just straight out asked how I would go about creating a perfect hash function for a unsigned 32-bit int. I was hoping since they are just numbers that there would be a set of simple mathematical operations I could apply to them which would produce a 1:1 mapping. –  brightemo Mar 4 '12 at 0:22
    
All you need is a bit more than 8GiB of space (and of course some time) to answer your question. –  Ignacio Vazquez-Abrams Mar 4 '12 at 0:37
    
Possible duplicate of php short hash –  Leigh Mar 4 '12 at 1:11
    
@Leigh Thank you, a link in that question was quite helpful. I also came across Skip32 (a 32-bit block cipher based on Skipjack) during my own research which would seem to be suitable also. –  brightemo Mar 4 '12 at 1:23

1 Answer 1

up vote 9 down vote accepted

In my example code below, will every $hash be unique?

Almost. (Which, I guess, means "no, but in a way that's easily fixed".) Your function consists of a sequence of independent steps; the overall function is bijective (reversible) if and only if every single one of those steps is. (Do you see why?)

Now, each step has one of the following forms:

  $key = ($key ^ CONSTANT) ^ ($key >> NUM_BITS);
  $key = ($key ^ CONSTANT) ^ ($key << NUM_BITS);

with NUM_BITS != 0.

We can actually treat these as variants of a single form, by viewing the former as almost equivalent to this:

  $key = invert_order_of_bits($key); # clearly bijective
  $constant = invert_order_of_bits(CONSTANT);
  $key = ($key ^ $constant) ^ ($key << NUM_BITS);
  $key = invert_order_of_bits($key); # clearly bijective

So all we need is to show that this:

  $key = ($key ^ CONSTANT) ^ ($key << NUM_BITS);

is bijective. Now, XOR is commutative and associative, so the above is equivalent to this:

  $key = $key ^ ($key << NUM_BITS);
  $key = $key ^ CONSTANT;

and (x ^ y) ^ y == x ^ (y ^ y) == x ^ 0 == x, so clearly XOR-ing with a constant value is reversible (by re-XOR-ing with the same value); so all we have to show is that this is bijective:

  $key = $key ^ ($key << NUM_BITS);

whenever NUM_BITS != 0.

Now, I'm not writing a rigorous proof, so I'll just give a single reasoned-out example of how to reverse this. Suppose that $key ^ ($key << 9) is

0010 1010 1101 1110 0010 0101 0000 1100

How do we obtain $key? Well, we know that the last nine bits of $key << 9 are all zeroes, so we know that the last nine bits of $key ^ ($key << 9) are the same as the last nine bits of $key. So $key looks like

bbbb bbbb bbbb bbbb bbbb bbb1 0000 1100

so $key << 9 looks like

bbbb bbbb bbbb bb10 0001 1000 0000 0000

so $key looks like

bbbb bbbb bbbb bb00 0011 1101 0000 1100

(by XOR-ing $key ^ ($key << 9) with $key << 9), so $key << 9 looks like

bbbb b000 0111 1010 0001 1000 0000 0000

so $key looks like

bbbb b010 1010 0100 0011 1101 0000 1100

so $key << 9 looks like

0101 1000 0111 1010 0001 1000 0000 0000

so $key looks like

0111 0010 1010 0100 0011 1101 0000 1100

So . . . why do I say "almost" rather than "yes"? Why is your hash-function not perfectly bijective? It's because in PHP, the bitwise shift operators >> and << are not quite symmetric, and while $key = $key ^ ($key << NUM_BITS) is completely reversible, $key = $key ^ ($key >> NUM_BITS) is not. (Above, when I wrote that the two types of steps were "almost equivalent", I really meant that "almost". It makes a difference!) You see, whereas << treats the sign bit just like any other bit, and shifts it out of existence (bringing in a zero-bit on the right), >> treats the sign bit specially, and "extends" it: the bit that it brings in on the left is equal to the sign bit. (N.B. Your question mentions "unsigned 32bit" values, but PHP doesn't actually support that; its bitwise operations are always on signed integers.)

Due to this sign extension, if $key starts with a 0, then $key >> NUM_BITS starts with a 0, and if $key starts with a 1, then $key >> NUM_BITS also starts with a 1. In either case, $key ^ ($key >> NUM_BITS) will start with a 0. You've lost exactly one bit of entropy. If you give me $key ^ ($key >> 9), and don't tell me whether $key is negative, then the best I can do is compute two possible values for $key: one negative, one positive-or-zero.

You perform two steps that use right-shift instead of left-shift, so you lose two bits of entropy. (I'm hand-waving slightly — all I've actually demonstrated is that you lose at least one bit and at most two bits — but I'm confident that, due to the nature of the steps between those right-shift steps, you do actually lose two full bits.) For any given output value, there are exactly four distinct input-values that could yield it. So it's not unique, but it's almost unique; and it's easily fixed, by either:

  • changing the two right-shift steps to use left-shifts instead; or
  • moving both of the right-shift steps to the start of the function, before any left-shift steps, and saying that outputs are unique for inputs between 0 and 231−1 rather than inputs between 0 and 232−1.
share|improve this answer
1  
An impressive answer indeed. Although I got slightly lost in the 2nd from last paragraph. Might want to slip a line break or two in there :) –  Leigh Mar 4 '12 at 2:01
    
@Leigh: Thanks! I've now done so. :-) –  ruakh Mar 4 '12 at 2:13
    
Thank you, that was very helpful! My brain keeps telling me that it can not possibly be unique, it is just too simple. (Other solutions I have seen are using some form of encryption, lookup tables, or multiplication by prime numbers, see link). –  brightemo Mar 4 '12 at 2:20
    
@brightemo: You're welcome! I was also really surprised. At first, when I'd just started working through the logic, I completely expected to find a way to generate collisions, rather than to find an argument for why there aren't any. :-P –  ruakh Mar 4 '12 at 2:25

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.