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How can I get a random float value from /dev/urandom?

If I simply use a cast, by saying:

int fd = ::open("/dev/urandom", O_RDONLY);
uint32_t n;
read(fd, &n, sizeof(n));
float f = n;

...I'm not sure if I have a guarantee of portability, because I don't know if large values of n will necessarily be representable as f? Is MAXUINT guaranteed to be representable as a float?

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I have strong doubts that the numbers you build in this fashion will be uniformly distributed -- you should probably stick to an interface such as drand48() for building random floating point numbers. –  sarnold Jun 26 '12 at 22:39
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What range of numbers do you want? The usual way is to do something like this question describes: stackoverflow.com/questions/686353/c-random-float (Using /dev/[u]random, as you suggest, might be better that calling rand(), but the concept is the same.) Using drand48() as @sarnold suggests looks like a good solution, too - maybe better. –  Mike Jun 26 '12 at 22:40
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@Mike: the downside to drand48() is that it uses a linear congruential algorithm -- suitable for scientific and most game uses but not suitable for cryptography-level work. /dev/urandom re-fills an entropy pool during use -- but the format of floating point numbers makes me skeptical about using raw bits to populate every field of the number... –  sarnold Jun 26 '12 at 22:47
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@sarnold: The value of n will be uniformly distributed over the range 0 .. 4294967295. Assigning it to f will probably lose some precision, but it should still be pretty well uniformly distributed. Whether you really want floating-point values in the range 0 .. 4294967295 is another question. –  Keith Thompson Jun 26 '12 at 23:59
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The question cannot be meaningfully answered unless you define what you mean by a "random float value". Uniform distribution or something else? What range? –  Keith Thompson Jun 27 '12 at 0:02
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2 Answers

up vote 5 down vote accepted

You get random bytes from /dev/urandom, but those bytes won't necessarily form a) uniformly distributed floating point values or b) even legal representations of whatever object you treat them as. For example on a platform that has trapping representations of floats or ints then there'll be the possibility that the values you create will be trapping representations, and you won't be able to actually use the random values you create.

You should simply verify that your library's implementation of std::random_device() allows access to /dev/urandom (either by default or by taking a string argument like: std::random_device("/dev/urandom"). Then you have a random number engine that can be used with, for example, std::uniform_real_distribution<float>() in order to get the random number distribution you want.

✓ libstdc++ uses /dev/urandom by default:

✓ libc++ does as well:

✗ Visual Studio's implementation is not even using a non-deterministic RNG:

✓ As of VS2012 MSDN states "the values produced by default are non-deterministic and cryptographically secure," probably via Windows' Cryptographic Services.

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What a surprise. GNU libstdc++ has it right, so does LLVM libc++, but Visual Studio can't even get close. –  Linuxios Jun 26 '12 at 23:05
    
Oh come on; what trap representations are there going to be for a uint32_t? And assigning that to a float isn't going to cause a problem either. Furthermore, assuming /dev/urandom is uniform, then the floating-point values are going to be as uniform as it's possible to get, surely? –  Oli Charlesworth Jun 27 '12 at 0:32
    
@OliCharlesworth There won't be trap representations for uint32_t, but there could be for int. Concatenating uniformly distributed bytes will produce uniformly distributed two's complement or signed magnitude integers, but it will not produce uniformly distributed IEEE 754 floats. Consider that there are the same number of IEEE 754 floating point representations between 1 and 2 as between 2 and 4. If you get an integer and convert it to float you won't have that distortion, but you will have the distortion that ints above a certain value will be 'rounded' to some other integral value. –  bames53 Jun 27 '12 at 0:50
    
Of course, but that's only important if you're reinterpreting the bits as a float. The OP is merely assigning to a float. I can't imagine a way to get a more uniform distribution of floats in the range [-2^32, +2^32). –  Oli Charlesworth Jun 27 '12 at 0:54
    
(By 2^32, I of course mean 2^31...) –  Oli Charlesworth Jun 27 '12 at 1:01
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It is possible to read random bytes directly into a float (e.g. float f; read(fd, &f, sizeof(f));); assuming IEEE-754, all bit-patterns are valid (although there are two infinities and many quiet and signalling NaNs). You can use ieee754.h or fpclassify.h to determine whether you've hit one of those.

Of course, whether this is reasonable depends on what kind of distribution you want. Assuming IEEE-754 float32, you'll get a uniform distribution across and in each range of [0, 2-126) denormals and [2-126, 2-125), [2-125, 2-124), ..., [2127, 2128) normals (and their negations).

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This would give you a highly skewed (and therefore probably totally unusable) distribution. –  Oli Charlesworth Jun 27 '12 at 0:25
    
@OliCharlesworth It gives you a roughly exponential distribution. I explained this in the answer. If you want to cover all the reals, what other kind of distribution do you want? –  ephemient Jun 27 '12 at 1:23
    
"Assuming IEEE-754 float32, you'll get a uniform distribution across and in each range of [0, 2-126) denormals and [2-126, 2-125), [2-125, 2-124), ..., [2127, 2128) normals (and their negations)." and a few NaN and infinities, which could test for if you don't want them –  curiousguy Jun 27 '12 at 14:13
    
@OliCharlesworth "This would give you a highly skewed (and therefore probably totally unusable) distribution" but it's a uniform distribution of IEEE-754 float values (probably not what the OP intended). The question is not well defined anyway. How can this answer get 1 downvote when the meaningless question gets 4 upvotes? That's crazy. –  curiousguy Jun 27 '12 at 14:15
    
@curiousguy: I downvoted both answers, but for different reasons... –  Oli Charlesworth Jun 27 '12 at 14:20
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