# Best way to generate a random float in C#

What is the best way to generate a random float in C#?

Update: I want random floating point numbers from float.Minvalue to float.Maxvalue. I am using these numbers in unit testing of some mathematical methods.

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4.0 - random chosen by fair floating-point dice roll. –  Jesse C. Slicer Jul 29 '10 at 19:23

Best approach, no crazed values, distributed with respect to the representable intervals on the floating-point number line (removed "uniform" as with respect to a continuous number line it is decidedly non-uniform):

``````static float NextFloat(Random random)
{
double mantissa = (random.NextDouble() * 2.0) - 1.0;
double exponent = Math.Pow(2.0, random.Next(-126, 128));
return (float)(mantissa * exponent);
}
``````

Another approach which will give you some crazed values (uniform distribution of bit patterns), potentially useful for fuzzing:

``````static float NextFloat(Random random)
{
var buffer = new byte[4];
random.NextBytes(buffer);
return BitConverter.ToSingle(buffer,0);
}
``````

Least useful approach:

``````static float NextFloat(Random random)
{
// Not a uniform distribution w.r.t. the binary floating-point number line
// which makes sense given that NextDouble is uniform from 0.0 to 1.0.
// Uniform w.r.t. a continuous number line.
//
// The range produced by this method is 6.8e38.
//
// Therefore if NextDouble produces values in the range of 0.0 to 0.1
// 10% of the time, we will only produce numbers less than 1e38 about
// 10% of the time, which does not make sense.
var result = (random.NextDouble()
* (Single.MaxValue - (double)Single.MinValue))
+ Single.MinValue;
return (float)result;
}
``````

Floating point number line from: Intel Architecture Software Developer's Manual Volume 1: Basic Architecture. The Y-axis is logarithmic (base-2) because consecutive binary floating point numbers do not differ linearly.

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There doesn't seem to be a BitConverter.GetSingle method. Do you mean ToSingle? –  KrisTrip Jul 29 '10 at 17:39
That would be what I mean... –  user7116 Jul 29 '10 at 17:40
Using random bytes can easily end up with a NaN value, and the distribution may well be non-uniform. (I wouldn't like to predict the distribution.) –  Jon Skeet Jul 29 '10 at 17:43
Agreed, the second one is useful for testing the range of potential floating point values including NaN. It appears this method produces about 0.25%-0.4% NaN. –  user7116 Jul 29 '10 at 17:53
@sixlettervariables: The reason yours looks prettier that way is because you've given a logarithmic scale. On a linear scale, I believe NextDouble * range will be uniform. –  Jon Skeet Jul 29 '10 at 18:27

Any reason not to use `Random.NextDouble` and then cast to `float`? That will give you a float between 0 and 1.

If you want a different form of "best" you'll need to specify your requirements. Note that `Random` shouldn't be used for sensitive matters such as finance or security - and you should generally reuse an existing instance throughout your application, or one per thread (as `Random` isn't thread-safe).

EDIT: As suggested in comments, to convert this to a range of `float.MinValue`, `float.MaxValue`:

``````// Perform arithmetic in double type to avoid overflowing
double range = (double) float.MaxValue - (double) float.MinValue;
double sample = rng.NextDouble();
double scaled = (sample * range) + float.MinValue;
float f = (float) scaled;
``````

EDIT: Now you've mentioned that this is for unit testing, I'm not sure it's an ideal approach. You should probably test with concrete values instead - making sure you test with samples in each of the relevant categories - infinities, NaNs, denormal numbers, very large numbers, zero, etc.

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I think NextDouble just provides values from 0.0 to 1.0 and I want more range than that (like from float.MinValue to float.MaxValue). Guess I should have specified :) –  KrisTrip Jul 29 '10 at 17:31
Just multiply it by (MaxValue-MinValue) and add MinValue to it? So something like Random.NextDouble *(float.MaxValue-float.MinValue) + float.MinValue –  Xzhsh Jul 29 '10 at 17:35
The distribution of values that produces is bimodal, I believe it has to do with how large the values are in the range. –  user7116 Jul 29 '10 at 18:13
I've finally reasoned out why this method does not produce the expected distribution of values for a binary floating point number. If NextDouble() returns a uniform distribution between 0 and 1, only 10% of the values would be between 0 and 0.1. So only 10% of the time the numbers will be less than 1e37, which is not the expected distribution. –  user7116 Jul 29 '10 at 19:34
@sixlettervariables: Where is this "expected distribution" specified? The distribution I expected was a uniform one, and I see no reason to believe that's not happening here. –  Jon Skeet Jul 29 '10 at 19:54

Another solution is to do this:

``````static float NextFloat(Random random)
{
float f;
do
{
byte[] bytes = new byte[4];
random.NextBytes(bytes);
f = BitConverter.ToSingle(bytes, 0);
}
while (float.IsInfinity(f) || float.IsNaN(f));
return f;
}
``````
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``````static float NextFloat(Random random)
{
return (float)rand.Next() / 2147483648;
}
``````

I think this...

• will be fast since 2147483648 is a power of 2.
• is evenly distributed
• greater than or equal to 0.0, and less than 1.0. (same as NextDouble())

Slightly less readable but you can just inline the following in your code as well...

``````((float)rand.Next() / 2147483648)
``````
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I took a slightly different approach than others

``````static float NextFloat(Random random)
{
double val = random.NextDouble(); // range 0.0 to 1.0
val -= 0.5; // expected range now -0.5 to +0.5
val *= 2; // expected range now -1.0 to +1.0
return float.MaxValue * (float)val;
}
``````

The comments explain what I'm doing. Get the next double, convert that number to a value between -1 and 1 and then multiply that with `float.MaxValue`.

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