# Hash function for floats

I'm currently implementing a hash table in C++ and I'm trying to make a hash function for floats...

I was going to treat floats as integers by padding the decimal numbers, but then I realized that I would probably reach the overflow with big numbers...

Is there a good way to hash floats?

You don't have to give me the function directly, but I'd like to see/understand different concepts...

Notes:

1. I don't need it to be really fast, just evenly distributed if possible.

2. I've read that floats should not be hashed because of the speed of computation, can someone confirm/explain this and give me other reasons why floats should not be hashed? I don't really understand why (besides the speed)

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It depends on the application but most of time floats should not be hashed because hashing is used for fast lookup for exact matches and most floats are the result of calculations that produce a float which is only an approximation to the correct answer. The usually way to check for floating equality is to check if it is within some delta (in absolute value) of the correct answer. This type of check does not lend itself to hashed lookup tables.

EDIT:

Normally, because of rounding errors and inherent limitations of floating point arithmetic, if you expect that floating point numbers `a` and `b` should be equal to each other because the math says so, you need to pick some relatively small `delta > 0`, and then you declare `a` and `b` to be equal if `abs(a-b) < delta`, where `abs` is the absolute value function. For more detail, see this article.

Here is a small example that demonstrates the problem:

``````float x = 1.0f;
x = x / 41;
x = x * 41;
if (x != 1.0f)
{
std::cout << "ooops...\n";
}
``````

Depending on your platform, compiler and optimization levels, this may print `ooops...` to your screen, meaning that the mathematical equation `x / y * y = x` does not necessarily hold on your computer.

There are cases where floating point arithmetic produces exact results, e.g. reasonably sized integers and rationals with power-of-2 denominators.

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Could you please explain a little more? "The usually way to check for floating equality is to check if it is within some delta (in absolute value) of the correct answer." – Pacane Nov 21 '10 at 17:30
+1 -- The answer is not to do it in the first place. Don't use floats as keys in maps or hash-tables; you'll run into problems sooner or later. – Leo Davidson Nov 21 '10 at 18:11
@Leo Davidson I know I'll run in troubles, the goal of this exercise is to find when exactly ;-) – Pacane Nov 21 '10 at 20:10
Downvote because it doesn't answer the question. I am here because I need non-exact hashes. Advice on dangers is all nice and well, but answering the question is better. – xcut Nov 9 '12 at 16:00
It is often a disservice to the questioner to simply answer questions as asked. I speak from experience on this forum. Someone asking to hash floats is probably pursuing a wrong course, especially considering the question as asked. If you want to ask a question about fuzzy lookups, about equivalence classes of floating point numbers, and so on that is a different question. – James K Polk Nov 9 '12 at 21:46

If your hash function did the following you'd get some degree of fuzziness on the hash lookup

``````unsigned int Hash( float f )
{
unsigned int ui;
memcpy( &ui, &f, sizeof( float ) );
return ui & 0xfffff000;
}
``````

This way you'll mask off the 12 least significant bits allowing for a degree of uncertainty ... It really depends on yout application however.

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No, `0xfffff000` masks off 3 nibbles, which is 12 bits. Probably a little too much. If you want to mask off 3 bits, use `0xfffffff8`. – fredoverflow Nov 21 '10 at 14:06
@FredOverflow: No .. you are right .. I didn't mean 3 ... mind failure there. changed – Goz Nov 21 '10 at 14:10
@Goz: this depends on the internal representation of `float` on the target machine though, since you assume here than the mantissa is located in the least significant bits, and is stored in little-endian fashion. Though the idea of fuzziness is definitely the way to go. – Matthieu M. Nov 21 '10 at 17:22
You're still going to end up with pairs of numbers with a very small relative difference that end up in different bins. – Ben Voigt Nov 21 '10 at 18:01
@Ben: Of course you will. If you are bucketing, which a hash algorithm necessarily does, you will always have this issue. imagine buckets at every 0.1 that go to 0.05 either side. that means that 1.4999999 goes in 1 bucket and 1.5 goes in another. You just have to live with that or ditch any form of bucketing ... – Goz Nov 21 '10 at 18:44
``````unsigned hash(float x)
{
union
{
float f;
unsigned u;
};
f = x;
return u;
}
``````

Technically undefined behavior, but most compilers support this. Alternative solution:

``````unsigned hash(float x)
{
return (unsigned&)x;
}
``````

Both solutions depend on the endianness of your machine, so for example on x86 and SPARC, they will produce different results. If that doesn't bother you, just use one of these solutions.

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Aren't there some standard functions that can be used to grab the mantissa and exponent? I'm not a float kind of guy, or much of C++ guy either, so I was just wondering ... – James K Polk Nov 21 '10 at 13:54
@GregS: Not as far as I know. Why would you want to grab the mantissa and exponent, anyway? A float is 32 bit, why not simply interpret that as an unsigned? As long as you avoid NaNs, you should be fine... – fredoverflow Nov 21 '10 at 13:56
@FredOverflow: I was just guessing that grabbing the mantissa and exponent separately would produce less machine- and compiler-dependent results. I would still depend on the sizes of the mantissa and the exponent which might turn out to be just as compiler and machine dependent. – James K Polk Nov 21 '10 at 14:04
@Pacane: Are you referring to the variable `u`? The union hack is based upon the assumption that `f` and `u` share the same memory, hence `u` is "initialized" by writing to `f`. Yes, this is highly implementation-specific, but it usually works. The second way is a reference-cast. It introduces another way to access the object `x` (of type float) as if it were an object of type unsigned. – fredoverflow Nov 21 '10 at 17:39
@Pacane: What do you mean by "pad"? There is no value conversion going on whatsoever, if that's what you think. For example, `hash(3.14f)` does not yield 3, but 1078523331, because both values are represented by the machine word `0x4048f5c3`. Of course this assumes that int and float both are 32 bit types, which is highly implementation-specific etc. (You can think of the reference cast as basically shorthand for `*(unsigned*)&x`.) – fredoverflow Nov 21 '10 at 17:54

You can of course represent a float as an int type of the same size to hash it, however this naive approach has some pitfalls you need to be careful of...

Simply converting to a binary representation is error prone since values which are equal wont necessarily have the same binary representation.

An obvious case: `-0.0` wont match `0.0` for example. *

Further, simply converting to an `int` of the same size wont give very even distribution, which is often important (implementing a hash/set that uses buckets for example).

Suggested steps for implementation:

• filter out non-finite cases (`nan`, `inf`) and (`0.0`, `-0.0` whether you need to do this explicitly or not depends on the method used).
• convert to an int of the same size.
• re-distribute the bits, (intentionally vague here!), this is basically a speed vs quality tradeoff. But if you have many values in a small range you probably don't want them to in a similar range too.

*: You may wan't to check for (`nan` and `-nan`) too. How to handle those exactly depends on your use case (you may want to ignore sign for all `nan`'s as CPython does).

Python's `_Py_HashDouble` is a good reference for how you might hash a float, in production code (ignore the `-1` check at the end, since thats a special value for Python).

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The obvious case of “-0.0 wont match 0.0 for example” is the only example of a pair of floating-point values that are equal for `==` and have differing representations, so I am not sure why you make a generality out of it. Infinities certainly do not need to be filtered out. Some have (seriously) recommended to return a random integer for `hash(NaN)`, but it seems more sound to simply treat the use of `NaN` as key in a hashtable as an error: research.swtch.com/randhash – Pascal Cuoq Feb 16 '15 at 23:46
PS: the blog post I linked to was posted on April 1st. I didn't realize this because I read it from the archives. It may not be serious, but at the same time, a random result for hash(NaN) means the binding(s) with NaN as key are present in the hashtable and can be iterated on, so it is actually a good solution for some usecases. – Pascal Cuoq Feb 16 '15 at 23:49
@Pascal Cuoq - Exactly how you deal with `!finite` values is up to your own implementation, I'm simply stating you should be aware of them when hashing floats, and simply converting a float to an int as is suggested in other answers is overlooking rather a lot. re: `-0 vs 0` - there is `-nan` / `nan` but how to class these may depend on your own preference (you may want to ignore the sign of a `nan` as Python does). Updated the answer. – ideasman42 Feb 17 '15 at 1:41
Note, would strongly suggest NOT to return a random integer from `nan`. that was suggested as a joke for a reason. keep the hash function deterministic, or use some kind of error is more a implementation detail. – ideasman42 Feb 17 '15 at 5:26
It does not seem like a joke to me. “Deterministic” means that `x == y` implies `hash(x) == hash(y)`, which remains true for `NaN` and `NaN` even if `hash(NaN)` is defined as random. The reasons why it is desirable not to return the same value very time are much stronger than some misconception about “deterministic” and are explained in the blog post. – Pascal Cuoq Feb 17 '15 at 6:42