# Random generation with very low chances

I'm trying to get a random bool in C# for a scientific project. The problem is that the chance of the bool being true must be around 10^-12 to 10^-14; the default random function only generates ints and a value between 0 and [u]int.max is far to small.

How can I generate a random boolean value with such a low chance of being true?

• You can get a larger value range if you use `NextBytes` May 7, 2014 at 16:06

EDIT

# Random.NextDouble() will not give the expected results!

As Kyle suggests in the comments below, the implementation of `Random.NextDouble()` maps an `int` to the interval [0.0 , 1.0), effectively making my code equivalent to `r.Next( 0, Int32.MaxValue ) == 0`. Adding more zeroes to will not affect the probability of the result being false.

Use one of the other answers, or use this code to generate a ulong (range 0-18446744073709551615) from `System.Random`.

``````var r = new Random();
var bytes = new byte;
r.NextBytes(bytes);
ulong result = BitConverter.ToUInt64(bytes, 0);
``````

Warning: will not work as expected, do not use! Provided merely for context.

Use `Random.NextDouble()` instead: the result is a double between 0.0 and 1.0

``````var r = new Random();
var probablyFalseBool = r.NextDouble() < 0.0000000000001;
``````

Vary the number of zeroes if necessary.

• Took this answer because it's the shortest way. You'll be mentioned in the sources section, thanks ;)
– Sebb
May 7, 2014 at 16:12
• I don't think this will work how you expect. Based on the source code for System.Random in .NET 4.5, the given code here would result in the same thing as `var probablyFalseBool = r.Next( 0, Int32.MaxValue ) == 0` since `Random.Next` calls the same protected `Sample` method that `Random.NextDouble` calls.
– Kyle
May 7, 2014 at 16:52
• I agree with @Kyle, the `NextDouble` method has a resolution of `1/Int32.MaxValue` (~1 / 2billion), and therefore is insufficient to use at a resolution you need. May 7, 2014 at 17:19
• @Kyle good catch! I edited my answer to steer future users away from using `NextDouble()` for this purpose.
– Rik
May 8, 2014 at 8:23
• @Rik Thanks for testing + editing, couldn't check it right now :)
– Sebb
May 8, 2014 at 8:34

Try combining more than one random selection:

``````if(rnd.Next(0,10000) == 0 && rnd.Next(0,10000) == 0 && rnd.Next(0,10000) == 0){
}
``````

Not sure if the C# syntax is correct, but this enter the if block with a probability of 10^-12.

• Beat me by 12 seconds. May 7, 2014 at 15:59
• I believe Rik's answer is the easiest and more optimized method. Combining this solution multiple times is not very pretty, nor very optimized. May 7, 2014 at 16:03
• No reason to do this, you can use `NextBytes` to get a larger sample May 7, 2014 at 16:05
• @PanagiotisKanavos, then it became a "bit" complicated to extract values based on a probability in base ten. May 7, 2014 at 16:07
• @NathanA BTW, unless OP has some kind of super computer, I doubt he will see any outcome with probability 10^-14. May 7, 2014 at 16:10

You can use the `NextBytes` method to get large random numbers.

For example, this will give you the probability of 2.842e-14 that the boolean is `true`:

``````Random r = new Random();
byte[] buffer = new byte; // make an array with 48 bits
r.NextBytes(buffer);
buffer &= 0xf8; // mask out three bits to make it 45
bool occured = buffer.Sum(b => b) == 0;
``````

As Nathan suggests, you can use the `Next` method to specify the range of results.

You can then use the `&&` operator to ensure it meets your precision.

``````// 1 in a million
var result = random.Next(0, 1000) == 0 && random.Next(0, 1000) == 0;
``````

You can then change them to give you your desired rates.

You can easily control the odds like this:

``````var result = rnd.Next(0,100) == 0;
``````

This would make the odds of `result` being true 1 in 100. You can easily adjust the values to whatever odds you want.

• I don't think that the `Next` method on its own has the appropriate precision. May 7, 2014 at 15:56
• This doesn't seem to meet the 1/10,000,000,000,000 odds. May 7, 2014 at 15:56
• his requirements specifically state why he can't do this May 7, 2014 at 15:58
• @paqogomez The 100 is exclusive, so the value is 0-99, meaning 1 in 100 changes. May 7, 2014 at 15:58
• @NathanA What people are saying is that the `Next()` method does not contain the precision necessary - the parameter types are not large enough to hold the value 10,000,000,000,000. May 7, 2014 at 15:58

Go multidimensional! A normal random number is in a single dimension (i.e. along a line). By multiplying two random numbers together you are using two dimensions and so on.

If you take 6 random integers between 1 and 100, then multiply them together the odds of getting the result 1 is 1 in 10^12. Same with four random integers between 1 and 1000, or 3 random integers between 1 and 10000.

If you want something like 30 in 10^12 then use two random numbers between 1 and 1,000,000 and you want one to be 1 and the other 30 or less.

If you want something x (<1,000,000) in 10^12 then use two random numbers between 1 and 1,000,000 and you want one to be 1 and the other x or less.

Instead of `Round.Next` you can use Round.NextDouble or Round.NextBytes to get a much wider range.

With `NextBytes` you can use a buffer of 4-5 bytes to get the range you need. Very roughly, you could do something like this:

``````var buffer=new byte;
rnd.NextBytes(buffer);
return buffer.All(b=>b>0);
``````

You probably can make this faster by using a BitArray

With `NextDouble` you would need to check that the result is less than 1/10^12.

Generate two ints in a row representing

``````(target_value div int_max, target_value mod int_max)
``````

Check the larger for being `0`, the second for being less than `desired_precison * int_max`.

if you have doubt about introducing a bias, randomize the order of the two ints in the pair before testing.

This standalone code illustrates the technique (tested here):

``````using System.IO;
using System;

class Program
{
static void Main(string[] args)
{
bool   flip, strike;
int    eps, lo, hi;
Random rnd;

eps = Int32.Parse(args); // whatever is appropriate

rnd = new Random();
lo = rnd.Next(Int32.MaxValue);
hi = rnd.Next(Int32.MaxValue);
flip = (rnd.Next() > 0.5);
if (flip) { int swap; swap = lo; lo = hi; hi = swap; }

strike = (hi == 0) && (lo < eps);

Console.Write("[hi lo] = ");
Console.Write(hi);
Console.WriteLine(lo);
if (strike) {
Console.WriteLine("strike");
}
}
}
``````
• Nice idea, but it's performance is bad. Took 38807 ms to execute a billion times, nearly two times as much as the marked approach (19630 ms).
– Sebb
May 7, 2014 at 17:49
• yes, the calls to the prng should dominate the execution time. May 7, 2014 at 17:53
• Nope, must be somewhere else as the 4-times random function is still two times faster. I removed the console outputs and the variable declarations, still not better. The src for the test is here.
– Sebb
May 7, 2014 at 18:01
• in your test code the suggested method fires with probability of about 1 / 2^-(31+31-4) ~ 3.5*10^-18; thus you are about 2 magnitudes below your target threshold! May 7, 2014 at 18:14
• Yep, but it's only test code. I'm gonna use this in a big framework with dynamic chance computation, the actual code is `chance = 2.5 * Math.Pow(10, -12) * (((tdx21+tdx12)/2)*(30/3.6)) + ((2949768/(5.1*(Math.Pow(10, -14))))*(157766400^-1)) * (((tdx21+tdx12)/2)*(30/3.6));` ; unfitting for the benchmark.
– Sebb
May 7, 2014 at 18:19