Random number in long range, is this the way?

Can somebody verify this method. I need a long type number inside a range of two longs. I use the .NET Random.Next(min, max) function which return int's. Is my reasoning correct if I simply divide the long by 2, generate the random number and finally multiply it by 2 again? Or am I too enthusiastic... I understand that my random resolution will decrease but are there any other mistakes which will lead to no such a random number.

``````long min = st.MinimumTime.Ticks;    //long is Signed 64-bit integer
long max = st.MaximumTime.Ticks;
int minInt = (int) (min / 2);      //int is Signed 64-bit integer
int maxInt = (int) (max / 2);      //int is Signed 64-bit integer

Random random = new Random();
int randomInt = random.Next(minInt, maxInt);
long randomLong = (randomInt * 2);
``````
-
int is signed 32-bit integer –  Dyppl Jul 11 '11 at 14:25
Make sure that the random is only declared one time. –  dbasnett Jul 11 '11 at 14:52
add comment

8 Answers

Why don't you just generate two random `Int32` values and make one `Int64` out of them?

``````long LongRandom(long min, long max, Random rand) {
long result = rand.Next((Int32)(min >> 32), (Int32)(max >> 32));
result = (result << 32);
result = result | (long)rand.Next((Int32)min, (Int32)max);
return result;
}
``````

Sorry, I forgot to add boundaries the first time. Added `min` and `max` params. You can test it like that:

``````long r = LongRandom(100000000000000000, 100000000000000050, new Random());
``````

Values of `r` will lie in the desired range.

EDIT: the implementation above is flawed. It's probably worth it to generate 4 16-bit integers rather than 2 32-bit ones to avoid signed-unsigned problems. But at this point the solution loses its elegancy, so I think it's best to stick with `Random.NextBytes` version:

``````long LongRandom(long min, long max, Random rand) {
byte[] buf = new byte[8];
rand.NextBytes(buf);
long longRand = BitConverter.ToInt64(buf, 0);

return (Math.Abs(longRand % (max - min)) + min);
}
``````

It looks pretty well in terms of value distribution (judging by very simple tests I ran).

-
Thanks, this looks like a good solution! –  Nick V Jul 12 '11 at 7:36
@user839032: it actually has bugs in it, the snippet above was meant to demonstrate and idea. I'll update the answer later with a robust solution –  Dyppl Jul 12 '11 at 8:09
I implemented it and a first shot looks good. Can it be that the but is here "result = result | (long)rand.Next((Int32)min, (Int32)max);" where the int casts can become negative? –  Nick V Jul 12 '11 at 8:20
@user839032: this is a naive implementation, it will fail at certain samples because Int32 is a signed type so it acts weird when you try to use it as bits of unsigned number. One solution is to make 4 random numbers 16 bytes each, not 2 like in my sample –  Dyppl Jul 12 '11 at 8:23
Doesn't work properly. `LongRandom(long.MinValue, long.MaxValue, new Random())`, always returns `-9223372036854775808`. In any case, `Math.Abs()` destroys one bit, leaving you with 63 random bits. You can't provide a 64-bit random number if you only have 63 random bits. –  Allon Guralnek Mar 15 '12 at 14:48
show 4 more comments

This creates a random Int64 by using random bytes.

Edit: The previous answer was subject to modulo bias. This implementation prevents this by retrying if the number is outside the safe range.

``````static class RandomExtensions
{
public static long RandomLong(this Random rnd)
{
byte[] buffer = new byte[8];
rnd.NextBytes (buffer);
return BitConverter.ToInt64(buffer, 0);
}

public static long RandomLong(this Random rnd, long min, long max)
{
EnsureMinLEQMax(ref min, ref max);
long numbersInRange = unchecked(max - min + 1);
if (numbersInRange < 0)
throw new ArgumentException("Size of range between min and max must be less than or equal to Int64.MaxValue");

long randomOffset = RandomLong(rnd);
if (IsModuloBiased(randomOffset, numbersInRange))
return RandomLong(rnd, min, max); // Try again
else
return min + PositiveModuloOrZero(randomOffset, numbersInRange);
}

static bool IsModuloBiased(long randomOffset, long numbersInRange)
{
long greatestCompleteRange = numbersInRange * (long.MaxValue / numbersInRange);
return randomOffset > greatestCompleteRange;
}

static long PositiveModuloOrZero(long dividend, long divisor)
{
long mod;
Math.DivRem(dividend, divisor, out mod);
if(mod < 0)
mod += divisor;
return mod;
}

static void EnsureMinLEQMax(ref long min, ref long max)
{
if(min <= max)
return;
long temp = min;
min = max;
max = temp;
}
}
``````
-
The direct approach. +1 –  dbasnett Jul 11 '11 at 14:53
OK, but how to keep it within random number in a range, between a min and max long? –  Nick V Jul 12 '11 at 7:35
That has the same issues as @Dyppl's answer –  BlueRaja - Danny Pflughoeft Oct 26 '12 at 21:18
@BlueRaja-DannyPflughoeft, Thanks for the heads up. I have modified the code to fix the modulo bias. This implementation prevents the bias by retrying if the random number is outside the safe range. –  agent-j Oct 26 '12 at 22:20
add comment

Here is a solution that leverages from the other answers using `Random.NextBytes`, but also pays careful attention to boundary cases. I've structured it as a set of extension methods. Also, I've accounted for modulo bias, by sampling another random number it falls out of range.

One of my gripes (at least for the situation I was trying to use it) is that the maximum is usually exclusive so if you want to roll a die, you do something like `Random.Next(0,7)`. However, this means you can never get this overload to return the `.MaxValue` for the datatype (`int`, `long`, `ulong`, what-have-you). Therefore, I've added an `inclusiveUpperBound` flag to toggle this behavior.

``````public static class Extensions
{
//returns a uniformly random ulong between ulong.Min inclusive and ulong.Max inclusive
public static ulong NextULong(this Random Rng)
{
byte[] buf = new byte[8];
Rng.NextBytes(buf);
return BitConverter.ToUInt64(buf, 0);
}

//returns a uniformly random ulong between ulong.Min and Max without modulo bias
public static ulong NextULong(this Random Rng, ulong Max, bool inclusiveUpperBound = false)
{
return Rng.NextULong(ulong.MinValue, Max, inclusiveUpperBound);
}

//returns a uniformly random ulong between Min and Max without modulo bias
public static ulong NextULong(this Random Rng, ulong Min, ulong Max, bool inclusiveUpperBound = false)
{
ulong range = Max - Min;

if (inclusiveUpperBound)
{
if (range == ulong.MaxValue)
{
return Rng.NextULong();
}

range++;
}

if (range <= 0)
{
throw new ArgumentOutOfRangeException("Max must be greater than Min when inclusiveUpperBound is false, and greater than or equal to when true", "Max");
}

ulong limit = ulong.MaxValue - ulong.MaxValue % range;
ulong r;
do
{
r = Rng.NextULong();
} while(r > limit);

return r % range + Min;
}

//returns a uniformly random long between long.Min inclusive and long.Max inclusive
public static long NextLong(this Random Rng)
{
byte[] buf = new byte[8];
Rng.NextBytes(buf);
return BitConverter.ToInt64(buf, 0);
}

//returns a uniformly random long between long.Min and Max without modulo bias
public static long NextLong(this Random Rng, long Max, bool inclusiveUpperBound = false)
{
return Rng.NextLong(long.MinValue, Max, inclusiveUpperBound);
}

//returns a uniformly random long between Min and Max without modulo bias
public static long NextLong(this Random Rng, long Min, long Max, bool inclusiveUpperBound = false)
{
ulong range = (ulong)(Max - Min);

if (inclusiveUpperBound)
{
if (range == ulong.MaxValue)
{
return Rng.NextLong();
}

range++;
}

if (range <= 0)
{
throw new ArgumentOutOfRangeException("Max must be greater than Min when inclusiveUpperBound is false, and greater than or equal to when true", "Max");
}

ulong limit = ulong.MaxValue - ulong.MaxValue % range;
ulong r;
do
{
r = Rng.NextULong();
} while(r > limit);
return (long)(r % range + (ulong)Min);
}
}
``````
-
This works! Even in corner cases such is (long.MinValue, long.MaxValue). –  Nikos Baxevanis Sep 30 '12 at 18:49
add comment

All the above answers have two issues: they all have a modulo bias, and none of them correctly handle values of `max = long.MaxValue` (except for @Martin, but his code is unreasonably slow with large ranges).

The following code will fix all of those issues:

``````//Working with ulong so that modulo works correctly with values > long.MaxValue
ulong uRange = (ulong)(max - min);

//Prevent a modolo bias; see http://stackoverflow.com/a/10984975/238419
//for more information.
//In the worst case, the expected number of calls is 2 (though usually it's
//much closer to 1) so this loop doesn't really hurt performance at all.
ulong ulongRand;
do
{
byte[] buf = new byte[8];
random.NextBytes(buf);
ulongRand = (ulong)BitConverter.ToInt64(buf, 0);
} while (ulongRand > ulong.MaxValue - ((ulong.MaxValue % uRange) + 1) % uRange);

return (long)(ulongRand % uRange) + min;
``````

The following fully-documented class can be dropped into your codebase to implement the above solution easily and brain-free. Like all code on Stackoverflow, it's licensed under CC-attribution, so you can feel free to use to use it for basically whatever you want.

``````using System;

namespace MyNamespace
{
public static class RandomExtensionMethods
{
/// <summary>
/// Returns a random long from min (inclusive) to max (exclusive)
/// </summary>
/// <param name="random">The given random instance</param>
/// <param name="min">The inclusive minimum bound</param>
/// <param name="max">The exclusive maximum bound.  Must be greater than min</param>
public static long NextLong(this Random random, long min, long max)
{
if (max <= min)
throw new ArgumentOutOfRangeException("max", "max must be > min!");

//Working with ulong so that modulo works correctly with values > long.MaxValue
ulong uRange = (ulong)(max - min);

//Prevent a modolo bias; see http://stackoverflow.com/a/10984975/238419
//for more information.
//In the worst case, the expected number of calls is 2 (though usually it's
//much closer to 1) so this loop doesn't really hurt performance at all.
ulong ulongRand;
do
{
byte[] buf = new byte[8];
random.NextBytes(buf);
ulongRand = (ulong)BitConverter.ToInt64(buf, 0);
} while (ulongRand > ulong.MaxValue - ((ulong.MaxValue % uRange) + 1) % uRange);

return (long)(ulongRand % uRange) + min;
}

/// <summary>
/// Returns a random long from 0 (inclusive) to max (exclusive)
/// </summary>
/// <param name="random">The given random instance</param>
/// <param name="max">The exclusive maximum bound.  Must be greater than 0</param>
public static long NextLong(this Random random, long max)
{
return random.NextLong(0, max);
}

/// <summary>
/// Returns a random long over all possible values of long (except long.MaxValue, similar to
/// random.Next())
/// </summary>
/// <param name="random">The given random instance</param>
public static long NextLong(this Random random)
{
return random.NextLong(long.MinValue, long.MaxValue);
}
}
}
``````

Usage:

``````Random random = new Random();
long foobar = random.NextLong(0, 1234567890L);
``````
-
@agent-j: Good catch on `max == min`, I'll fix that now (it actually should not work, since `max` is an exclusive upper-bound; but it was not throwing an exception like it should). However, the bias is already fixed; `ulongRand` is evenly distributed over `0` to `uRange * (int)(ulong.MaxValue / uRange) - 1`, meaning `ulongRange % uRange` is evenly distributed over `0` to `uRange - 1` –  BlueRaja - Danny Pflughoeft Oct 26 '12 at 23:48
There still seems to be a bias for small ranges (though one could argue it's not that very big). The value of `ulong.MaxValue` is `18,446,744,073,709,551,615` (notice that it ends in `615`). If we pick a uRange of size `100`, and `ulongRand` falls the last `15` `(ulong.MaxValue % uRange)`, it should be thrown out, but you are throwing out the last 100 (by subtracting `uRange`), thus giving a tiny bias. Perhaps this is what you need `while (ulongRand >= ulong.MaxValue - (ulong.MaxValue % uRange))` –  agent-j Oct 29 '12 at 16:50
@agent-j: You're right, but that correction still doesn't work quite right (try `ulong.MaxValue = 9, uRange = 5` - every value from 0-9 should be valid, but your solution loops for half the space!). You need to add 1 to `ulong.MaxValue` for it to be correct.. but that still won't work because the value will loop around! So, we need to mod before adding, then mod again (in case we hit `uRange`). The final correction looks like this: `while (ulongRand > ulong.MaxValue - ((ulong.MaxValue % uRange) + 1) % uRange)` –  BlueRaja - Danny Pflughoeft Nov 6 '12 at 21:58
My timings show that my code takes ~210ms for generating 1,000,000 random numbers between `long.MinValue` and `long.MaxValue` and takes yours ~260ms for the same range and number of iterations. Pretty quick either way, I'm just defending that my code is not "unreasonably slow with large ranges" –  Martin Neal Dec 3 '12 at 23:02
Am I the only one who gets the same random long when I use this multiple times in a row? I am trying to generate 5 random longs, all within range `long.MinValue` and `long.MaxValue`. But when I debug, all 5 longs are the same number. What am I missing? –  JohnDubya May 9 '13 at 15:04
show 1 more comment

You're better off taking the difference between minimum and maximum (if it fits in an int), getting a random between 0 and that, and adding it to the minimum.

-
add comment

Your randomLong will always be even and you will have eliminated even more values because you are very far away from the maximum for `long`, The maximum for long is 2^32 * max for int. You should use `Random.NextBytes`.

-
add comment

Start at the minimum, add a random percentage of the difference between the min and the max. Problem with this is that NextDouble returns a number x such that 0 <= x < 1, so there's a chance you'll never hit the max number.

``````long randomLong = min + (long)(random.NextDouble() * (max - min));
``````
-
Based on the number of digits in double's precision, this would exclude a lot of numbers, but still a good method. –  Yuriy Faktorovich Jul 11 '11 at 14:34
I can see that happening if min and max are sufficiently far apart, in which case you'd have to test it millions of times before any problem became apparent. –  Coeffect Jul 11 '11 at 14:44
add comment

Is there anything wrong with using this simple approach?

``````        long min = 10000000000001;
long max = 99999999999999;
Random random = new Random();
long randomNumber = min + random.Next() % (max - min);
``````

d

-
add comment