14

I know how to generate a random number between 0 and 1 using the NextDouble method of the pseudo-random number generator.

var rng1 = new System.Random();
var random1 = rng1.NextDouble(); // generates a random double between 0 and 1.0

And I know how to fill a random byte array using the cryptographically secure random number generator.

Byte[] bytes = new Byte[8];
var rng2 = new System.Security.Cryptography.RNGCryptoServiceProvider();
rng2.GetBytes(bytes); // generates 8 random bytes

But how can I convert the byte-array output of RNGCryptoServiceProvider into a random number uniformly distributed between 0 (inclusive) and 1 (exclusive)?

2
  • What distribution do you want? Uniform? – AakashM May 18 '10 at 4:48
  • Yes, uniform distribution. Will update now. – Portman May 18 '10 at 5:01
28

It appears to me that the solutions so far will have uneven distribution due to taking the inverse. For an even distribution I'd think you want something like this.

// Step 1: fill an array with 8 random bytes
var rng = new RNGCryptoServiceProvider();
var bytes = new Byte[8];
rng.GetBytes(bytes);
// Step 2: bit-shift 11 and 53 based on double's mantissa bits
var ul = BitConverter.ToUInt64(bytes, 0) / (1 << 11);
Double d = ul / (Double)(1UL << 53);

Note that you can't just divide the UInt64 into UInt64.MaxValue, because a double doesn't have enough bits, and there's no way to get unique outputs for all your inputs. So you can/must throw some bits away.

4
  • This is great, thank you. Just added the required second param to BitConverter.ToUInt64 and a missing parent on line 2. Testing now to ensure it's an equivalent distribution to Random.NextDouble(). – Portman May 18 '10 at 5:05
  • 1
    Edit #3 is working nicely: after 1 million iterations, minimum of .0000001, maximum of .999999, average of .5000003 after 1 million iterations. Mind if I clean up the edit history? – Portman May 18 '10 at 5:34
  • Why not just grab 53 bits instead of doing weird things with the second-to-last line? (Seriously, it took me a while to understand what exactly you did there). – Joey May 18 '10 at 14:29
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    1. I was in a hurry, that was the first coding that I thought of. 2. Feel free to show us your cleaner code to "grab 53 bits". 3. I actually realized later that "BitConverter.ToUInt64(bytes, 0) >> 11" would be cleaner but I was out of time. – Conrad Albrecht May 18 '10 at 15:47
0

Well, I would not call a 64-bit random number "cryptographically secure" - you'd want a lot more bits than that to be "cryptographically secure". But anyway, you could do something like this:

var bytes = // assume this contains 8 bytes of random numbers

long l = BitConverter.ToInt64(bytes);
double d = Math.Abs(1 / (double)l);
3
  • Might want to add a Math.Abs( l ) to ensure the resulting double is positive. – Paul Alexander May 18 '10 at 4:32
  • 6
    This has a very different distribution compared to NextDouble. It will generate numbers very close to zero almost all the time. – Baffe Boyois May 18 '10 at 4:52
  • Thx for the info on NaN. Didn't know that it was a specific byte sequence. – Thomas May 18 '10 at 5:00

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