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# Extremely fast hash function with collisions allowed

My key is a 64 bit address and the output is a 1 byte number (0-255). Collisions are allowed but the probability of them occurring should be low. Also, assume that number of elements to be inserted are low, lets say not more than 255, as to minimize the pigeon hole effect.

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what's the distribution of your addresses? it's going to help with the answers, what addresses are they? – talkol Jan 31 '13 at 16:38
Talkol - Addresses of the functions in the program – pythonic Jan 31 '13 at 16:40
If your hash has 256 values possible, the number of elements should be far less than 256 if you want to avoid collisions. With 255 elements, collisions will be numerous. – AProgrammer Jan 31 '13 at 17:00
This isn't well-defined at the moment. What's the distribution? What collision rate is tolerable? – Oliver Charlesworth Jan 31 '13 at 17:02
Should the hash be secure against predicting the output of a given input (on multiple iterations of the same program)? – Alex Chamberlain Jan 31 '13 at 17:04

``````uint64_t addr = ...
uint8_t hash = addr & 0xFF;
``````

I think that meets all of your requirements.

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it all depends on the distribution of the addresses, it could easily turn out to be horrible – talkol Jan 31 '13 at 16:39
Trying to hash 255 keys to 256 values will probably be horrible in any case. This seems like the fastest possible solution. – iamnotmaynard Jan 31 '13 at 16:42
addresses do not distribute uniformly, I'm pretty sure a function address can't be odd, probably has to be divisible by 4 – talkol Jan 31 '13 at 16:44
newer gcc will lay out functions so they're aligned on 16 byte boundaries – nos Jan 31 '13 at 16:54
And malloc() blocks are almost always 16 byte aligned on 64 bit platforms. But Alex is right, the requirements are such that a "fancy" hash function is probably overkill -- it doesn't take much work at all to get even distribution over 256 possible values. Just pick some middle bits then: `(((long)addr)>>5) & 0xff` – Andy Ross Jan 31 '13 at 17:07

I would XOR together the 2 LSB (least significant bytes), if this distribues badly, then add a 3rd one, and so forth

The rationale behind this is the following: function addresses do not distribute uniformly. The problem normally lies in the lower (lsb) bits. Functions usually need to begin in addresses divisible by 4/8/16 so the 2-4 lsb are probably meaningless. By XORing with the next byte, you should get rid of most of these problems and it's still pretty fast.

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Xxxxxxxxxxx xxxxxx – R.. Jan 31 '13 at 17:09
XORin with the higher byte achieves the same effect, is as quick, and is a bit simpler since you're not sure how many bits to shift right anyways.. because the lower "good" bits provide the most variation so you won't want to throw them out if you don't have to – talkol Jan 31 '13 at 17:11

Function addresses are, I think, quite likely to be aligned (see this question, for instance). That seems to indicate that you want to skip least significant bits, depending on the alignment.

So, perhaps take the 8 bits starting from bit 3, i.e. skipping the least significant 3 bits (bits 0 through 2):

``````const uint8_t hash = (address >> 3);
``````

This should be obvious from inspection of your set of addresses. In hex, watch the rightmost digit.

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If the functions are all in the same dso or all in the main program, the high bits will all be the same too. I suspect just bits 4-18 are significant. – R.. Jan 31 '13 at 17:22

``````uint64_t data = 0x12131212121211B12;

uint32_t d1 = (data >> 32) ^ (uint32_t)(data);
uint16_t d2 = (d1 >> 16) ^ (uint16_t)(d1);
uint8_t  d3 = (d2 >> 8) ^ (uint8_t)(d2);

return d3;
``````

It combined all bits of your 8 bytes with 3 shifts and three xor instructions.

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very nice :) but a bit overkill – talkol Jan 31 '13 at 17:25