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How can I get a random System.Decimal? System.Random doesn't support it directly.

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2  
would it not just be easier to generate a random integer between, say, 1 and 999, and divide the result by 100? ex. random number 1 would be 0.01 and 999 would be 9.99 –  Stefan Z Camilleri Apr 19 '12 at 10:47
    
@StefanZCamilleri Depends on what you need the random decimal for. Have a read through some of the answers below. The complete range of possible Decimal values that can be represented is really large and some thought is required to get random ints to feed into the Decimal constructor. Then there is the problem of how uniform the random distribution of generated decimal values is. –  Daniel Ballinger Apr 20 '12 at 1:05

8 Answers 8

up vote 21 down vote accepted

EDIT: Removed old version

This is similar to Daniel's version, but will give the complete range. It also introduces a new extension method to get a random "any integer" value, which I think is handy.

Note that the distribution of decimals here is not uniform.

/// <summary>
/// Returns an Int32 with a random value across the entire range of
/// possible values.
/// </summary>
public static int NextInt32(this Random rng)
{
     unchecked
     {
         int firstBits = rng.Next(0, 1 << 4) << 28;
         int lastBits = rng.Next(0, 1 << 28);
         return firstBits | lastBits;
     }
}

public static decimal NextDecimal(this Random rng)
{
     byte scale = (byte) rng.Next(29);
     bool sign = rng.Next(2) == 1;
     return new decimal(rng.NextInt32(), 
                        rng.NextInt32(),
                        rng.NextInt32(),
                        sign,
                        scale);
}
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I wondered about this and/or the ctor that takes a byte[] - but are all the byte[] permutations legal? –  Marc Gravell Mar 4 '09 at 7:20
    
@Marc: My recollection is that they are, and the other bits are just ignored. I haven't checked though. –  Jon Skeet Mar 4 '09 at 7:23
    
I did, it's just passed through a private ctor as if it was legal. You should try that and see if it makes sense. The implementation is hidden (InternalCall) and that junk data could corrupt calculations. –  John Leidegren Mar 4 '09 at 7:31
    
@John: Right. Will check it out some time. I prefer my revised version anyway. I do like making it an extension method though... –  Jon Skeet Mar 4 '09 at 7:35
2  
@Hosam: It's absolutely non-uniform in terms of magnitude of decimal. It's uniform in terms of each bit pattern having the same probability of occurring. For a uniform pattern, we'd be better off generating a number between 0 and 1. –  Jon Skeet Mar 4 '09 at 19:27
static decimal GetRandomDecimal()
    {

        int[] DataInts = new int[4];
        byte[] DataBytes = new byte[DataInts.Length * 4];

        // Use cryptographic random number generator to get 16 bytes random data
        RNGCryptoServiceProvider rng = new RNGCryptoServiceProvider();

        do
        {
            rng.GetBytes(DataBytes);

            // Convert 16 bytes into 4 ints
            for (int index = 0; index < DataInts.Length; index++)
            {
                DataInts[index] = BitConverter.ToInt32(DataBytes, index * 4);
            }

            // Mask out all bits except sign bit 31 and scale bits 16 to 20 (value 0-31)
            DataInts[3] = DataInts[3] & (unchecked((int)2147483648u | 2031616));

          // Start over if scale > 28 to avoid bias 
        } while (((DataInts[3] & 1835008) == 1835008) && ((DataInts[3] & 196608) != 0));

        return new decimal(DataInts);
    }
    //end
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Check out the following link for ready-made implementations that should help:

MathNet.Numerics, Random Numbers and Probability Distributions

The extensive distributions are especially of interest, built on top of the Random Number Generators (MersenneTwister, etc.) directly derived from System.Random, all providing handy extension methods (e.g. NextFullRangeInt32, NextFullRangeInt64, NextDecimal, etc.). You can, of course, just use the default SystemRandomSource, which is simply System.Random embellished with the extension methods.

Oh, and you can create your RNG instances as thread safe if you need it.

Very handy indeed!

This is an old question, but for those who are just reading it, why re-invent the wheel?

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Here is Decimal random with Range implementation that works fine for me.

public static decimal NextDecimal(this Random rnd, decimal from, decimal to)
{
    byte fromScale = new System.Data.SqlTypes.SqlDecimal(from).Scale;
    byte toScale = new System.Data.SqlTypes.SqlDecimal(to).Scale;

    byte scale = (byte)(fromScale + toScale);
    if (scale > 28)
        scale = 28;

    decimal r = new decimal(rnd.Next(), rnd.Next(), rnd.Next(), false, scale);
    if (Math.Sign(from) == Math.Sign(to) || from == 0 || to == 0)
        return decimal.Remainder(r, to - from) + from;

    bool getFromNegativeRange = (double)from + rnd.NextDouble() * ((double)to - (double)from) < 0;
    return getFromNegativeRange ? decimal.Remainder(r, -from) + from : decimal.Remainder(r, to);
}
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You would normally expect from a random-number-generator that it not only generated random numbers, but that the numbers were uniformly randomly generated.

There are two definitions of uniformly random: discrete uniformly random and continuous uniformly random.

Discretely uniformly random makes sense for a random number generator that has a finite number of different possible outcomes. For example generating an integer between 1 and 10. You would then expect that the probability of getting 4 is the same as getting 7.

Continuously uniformly random makes sense when the random number generator generates numbers in a range. For example a generator that generates a real number between 0 and 1. You would then expect that the probability of getting a number between 0 and 0.5 is the same as getting a number between 0.5 and 1.

When a random number generator generates floating-point numbers (which is basically what a System.Decimal is - it is just floating-point which base 10), it is arguable what the proper definition of uniformly random is:

On one hand, since the floating-point number is being represented by a fixed number of bits in a computer, it is obvious that there are a finite number of possible outcomes. So one could argue that the proper distribution is a discrete continuous distribution with each representable number having the same probability. That is basically what Jon Skeet's and John Leidegren's implementation does.

On the other hand, one might argue that since a floating-point number is supposed to be an approximation to a real number, we would be better off by trying to approximate the behavior of a continuous random number generator - even though are actual RNG is actually discrete. This is the behavior you get from Random.NextDouble(), where - even though there are approximately as many representable numbers in the range 0.00001-0.00002 as there are in the range 0.8-0.9, you are a thousand times more likely to get a number in the second range - as you would expect.

So a proper implementation of a Random.NextDecimal() should probably be continuously uniformly distributed.

Here is a simple variation of Jon Skeet's answer that is uniformly distributed between 0 and 1 (I reuse his NextInt32() extension method):

public static decimal NextDecimal(this Random rng)
{
     return new decimal(rng.NextInt32(), 
                        rng.NextInt32(),
                        rng.Next(0x204FCE5E),
                        false,
                        0);
}

You could also discuss how to get an uniform distribution over the entire range of decimals. There is probably an easier way to do this, but this slight modification of John Leidegren's answer should produce a relatively uniform distribution:

private static int GetDecimalScale(Random r)
{
  for(int i=0;i<=28;i++){
    if(r.NextDouble() >= 0.1)
      return i;
  }
  return 0;
}

public static decimal NextDecimal(this Random r)
{
    var s = GetDecimalScale(r);
    var a = (int)(uint.MaxValue * r.NextDouble());
    var b = (int)(uint.MaxValue * r.NextDouble());
    var c = (int)(uint.MaxValue * r.NextDouble());
    var n = r.NextDouble() >= 0.5;
    return new Decimal(a, b, c, n, s);
}

Basically, we make sure that values of scale are chosen proportionally to the size of the corresponding range.

That means that we should get a scale of 0 90% of the time - since that range contains 90% of the possible range - a scale of 1 9% of the time, etc.

There are still some problems with the implementation, since it does take into account that some numbers have multiple representations - but it should be much closer to a uniform distribution than the other implementations.

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Why is your scale ratio 0.1? It doesn't seem uniform to me. Perhaps 1.0/28 is more uniform. –  Hosam Aly Mar 4 '09 at 12:41
    
And how is this different from 28 * r.NextDouble()? –  Hosam Aly Mar 4 '09 at 12:42
    
That's quite interesting, because we're totally just putting in garbage. Supposedly you would wanna have a nice uniform distribution between 0 and 1 and then you would scale that with what ever range you require. Though I fail to see how this accomplish that? –  John Leidegren Mar 4 '09 at 13:58
    
@Hosam Aly I have tried to explain in more depth what I am doing. Basically, you want to get scale=28 90% of the time, since that contains the largest range of numbers. 28*r.NextDouble() makes it as likely to get a number between 0.1 and 0.2 as it is to get a number between 100000000 and 200000000. –  Rasmus Faber Mar 5 '09 at 8:18
    
@John Leidegren: Yes, it usually would be easier to start off with a uniform distribution between 0 and 1 and just scale that. I think I will make an answer that provides that. –  Rasmus Faber Mar 5 '09 at 8:20

here you go... uses the crypt library to generate a couple of random bytes, then convertes them to a decimal value... see MSDN for the decimal constructor

using System.Security.Cryptography;

public static decimal Next(decimal max)
{
    // Create a int array to hold the random values.
    Byte[] randomNumber = new Byte[] { 0,0 };

    RNGCryptoServiceProvider Gen = new RNGCryptoServiceProvider();

    // Fill the array with a random value.
    Gen.GetBytes(randomNumber);

    // convert the bytes to a decimal
    return new decimal(new int[] 
    { 
               0,                   // not used, must be 0
               randomNumber[0] % 29,// must be between 0 and 28
               0,                   // not used, must be 0
               randomNumber[1] % 2  // sign --> 0 == positive, 1 == negative
    } ) % (max+1);
}

revised to use a different decimal constructor to give a better range of numbers

public static decimal Next(decimal max)
{
    // Create a int array to hold the random values.
    Byte[] bytes= new Byte[] { 0,0,0,0 };

    RNGCryptoServiceProvider Gen = new RNGCryptoServiceProvider();

    // Fill the array with a random value.
    Gen.GetBytes(bytes);
    bytes[3] %= 29; // this must be between 0 and 28 (inclusive)
    decimal d = new decimal( (int)bytes[0], (int)bytes[1], (int)bytes[2], false, bytes[3]);

        return d % (max+1);
    }
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That does mean we're limited to 65536 values out of the huge possible range though, doesn't it? –  Jon Skeet Mar 4 '09 at 9:15
    
yeah, it does. :-( –  Muad'Dib Mar 4 '09 at 13:54
    
Are we living in the days of 16-bit computing? What's the meaning of this? –  John Leidegren Mar 4 '09 at 13:59

I puzzled with this for a bit. This is the best I could come up with:

public class DecimalRandom : Random
    {
        public override decimal NextDecimal()
        {
            //The low 32 bits of a 96-bit integer. 
            int lo = this.Next(int.MinValue, int.MaxValue);
            //The middle 32 bits of a 96-bit integer. 
            int mid = this.Next(int.MinValue, int.MaxValue);
            //The high 32 bits of a 96-bit integer. 
            int hi = this.Next(int.MinValue, int.MaxValue);
            //The sign of the number; 1 is negative, 0 is positive. 
            bool isNegative = (this.Next(2) == 0);
            //A power of 10 ranging from 0 to 28. 
            byte scale = Convert.ToByte(this.Next(29));

            Decimal randomDecimal = new Decimal(lo, mid, hi, isNegative, scale);

            return randomDecimal;
        }
    }

Edit: As noted in the comments lo, mid and hi can never contain int.MaxValue so the complete range of Decimals isn't possible.

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That'll do it... –  Marc Gravell Mar 4 '09 at 7:09
    
Not quite... Random.Next(int.MinValue, int.MaxValue) will never return int.MaxValue. I've got an answer, but I think I can improve on it. –  Jon Skeet Mar 4 '09 at 7:13
    
Statistics is not my strong point, so I'm probably wrong, but I'd worry that the distribution might not be very uniform. –  Michael Burr Mar 4 '09 at 7:14

I like Jon Skeet's second approach, here's a third alternative. Never mind my subclassing trick, this should be written as an extension method. The protected Sample() method is exposed by the public NextDouble() method (which internally, when you specify a custom range, is being used to generate the numbers).

public static decimal NextDecimal(this Random r)
{
    var a = (int)(uint.MaxValue * r.NextDouble());
    var b = (int)(uint.MaxValue * r.NextDouble());
    var c = (int)(uint.MaxValue * r.NextDouble());
    var n = r.NextDouble() > 0.5;
    var s = (byte)(29 * r.NextDouble());
    return new Decimal(a, b, c, n, s);
}
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I don't like the bit which works out the scale in the last line, because it won't give a random distribution of scales. It's taking (0-127) % 29, which favours 0-11 over 12-28 if my maths is right. –  Jon Skeet Mar 4 '09 at 7:37
    
(Of course the desired distribution hasn't been specified, but this would seem a somewhat odd distribution.) –  Jon Skeet Mar 4 '09 at 7:37
    
@Jon: Very true, I didn't really care about that. I believe that pseudo-randomness is just that. Fake, but you would probably expect less biased distribution. –  John Leidegren Mar 4 '09 at 7:57
    
@Jon: I fixed that and instead subclass the Random class because it has a Sample() method. Still, I blame the Random class for poor extendability. –  John Leidegren Mar 4 '09 at 7:59

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