# Generating random BigDecimal value from given range

I need to generate random BigDecimal value from given range. How to do it in Java?

``````class BigDecRand {
public static void main(String[] args) {
String range = args[0];
BigDecimal max = new BigDecimal(range + ".0");
BigDecimal randFromDouble = new BigDecimal(Math.random());
BigDecimal actualRandomDec = randFromDouble.divide(max,BigDecimal.ROUND_DOWN);

BigInteger actualRandom = actualRandomDec.toBigInteger();
}
}
``````
• But how to generate a value from range [-0.45,0.6] ? Feb 16, 2011 at 23:37
• Well, you can use that code to find a random number for the range, and then add to it the minValue. `R = min + rand(range)` where `range = max - min`. Feb 16, 2011 at 23:43
• Here an exmaple: `public class BigDecimalGenerator { public static void main(String[] args) { BigDecimal max = new BigDecimal("0.44"); BigDecimal min = new BigDecimal("-0.44"); BigDecimal range = max.subtract(min); BigDecimal result = min .add(range.multiply(new BigDecimal(Math.random()))); System.out.println(result); } }` Feb 17, 2011 at 0:25
• I should note that this is limited in exactly how dynamic it can be. The randomness is limited by `double`s precision between 1 and 0. Hopefully that's random enough :) Feb 17, 2011 at 1:13
• For example, when `BigDecimal max = new BigDecimal("100000000000000000000000000000000"); BigDecimal min = new BigDecimal("-100000000000000000000000000000000"); ` your result looks like this: `88392126894971667638856160920113.3251190185546875000000000000000000000000000000000` Feb 17, 2011 at 1:15

I do this that way

``````public static BigDecimal generateRandomBigDecimalFromRange(BigDecimal min, BigDecimal max) {
return randomBigDecimal.setScale(2,BigDecimal.ROUND_HALF_UP);
}
``````

And the way I run it:

``````BigDecimal random = Application.generateRandomBigDecimalFromRange(
new BigDecimal(-1.21).setScale(2, BigDecimal.ROUND_HALF_UP),
new BigDecimal(21.28).setScale(2, BigDecimal.ROUND_HALF_UP)
);
``````

Previous answers don't address the loss of precision that results from scaling values with arbitrarily large numbers of digits by double precision floating point values with a relatively small number of digits. The following implementation of BigRandom can generate random BigInteger and BigDecimal values at specified precision:

``````// The short version
public static BigDecimal between(BigDecimal min, BigDecimal MAX) {
int digitCount = Math.max(min.precision(), MAX.precision());
int bitCount = (int)(digitCount / Math.log10(2.0));

// convert Random BigInteger to a BigDecimal between 0 and 1
BigDecimal alpha = new BigDecimal(
new BigInteger( bitCount, new Random() )
).movePointLeft(digitCount);

}
``````
``````// Full Implementation
import java.math.BigDecimal;
import java.math.BigInteger;
import java.math.MathContext;
import java.util.Random;

public class BigRandom {

private static Random defaultRandom = new Random();

// Constants:
private static double log2 = Math.log10(2.0);

// Computes number of bits needed to represent an n digit positive integer.

private static int bitCount(int n) {
return (int)( n / log2 );
}

// Static Methods for generating Random BigInteger values:

public static BigInteger nextBigInteger(int precision) {
return nextBigInteger(precision, defaultRandom);
}

public static BigInteger nextBigInteger(int precision, Random r) {
return new BigInteger(bitCount(precision), r);
}

public static BigInteger nextBigInteger(BigInteger norm) {
return nextBigInteger(norm, defaultRandom);
}

public static BigInteger nextBigInteger(BigInteger norm, Random r) {
BigDecimal bdNorm = new BigDecimal(norm);
int precision = bdNorm.precision() - bdNorm.scale();
return bdNorm.multiply(nextBigDecimal(precision, r), new MathContext(precision + 1)).toBigInteger();
}

public static BigInteger between(BigInteger min, BigInteger MAX) {
return between(min, MAX, defaultRandom);
}

public static BigInteger between(BigInteger min, BigInteger MAX, Random r) {
return min.add( nextBigInteger( MAX.subtract(min), r ) );
}

// Static Methods for generating Random BigDecimal values:

public static BigDecimal nextBigDecimal(int scale) {
return nextBigDecimal(scale, defaultRandom);
}

public static BigDecimal nextBigDecimal(int scale, Random r) {
BigInteger bi = nextBigInteger(scale, r);  // generate random BigInteger with a number of digits equal to scale.
BigDecimal bd = new BigDecimal(bi);  // convert BigInteger to a BigDecimal
return bd.movePointLeft(bd.precision());  // move the decimal point all the way to the left
}

public static BigDecimal nextBigDecimal(BigDecimal norm, int scale) {
return nextBigDecimal(norm, scale, defaultRandom);
}

public static BigDecimal nextBigDecimal(BigDecimal norm, int scale, Random r) {
return norm.multiply( nextBigDecimal( scale, r ), new MathContext( (norm.precision() - norm.scale()) + scale) );
}

public static BigDecimal between(BigDecimal min, BigDecimal MAX) {
return between(min, MAX, defaultRandom);
}

public static BigDecimal between(BigDecimal min, BigDecimal MAX, Random r) {
nextBigDecimal(
MAX.subtract(min),
Math.max( min.precision(), MAX.precision() ),
r
)
);
}

public static void main(String[] args) {
// Make a BigInteger independently from this implementation.
int bc = ((150 - defaultRandom.nextInt(50)) * 8) - defaultRandom.nextInt(8);
BigInteger bi = new BigInteger(bc, defaultRandom);
String bistr = bi.toString();
int precision = bistr.length();

System.out.println("Independently generated random BigInteger:\n" + bistr);
System.out.println("\tprecision: " + bistr.length());

System.out.println("\n\n------------------------\n\n");

// demonstrate nextBigInteger(precision)
System.out.println("demonstrate nextBigInteger(precision = " + precision + "):\n");
for (int i = 0; i < 5; i++) {
BigInteger bii = nextBigInteger(precision);
String biistr = bii.toString();
System.out.println("iteration " + i + " nextBigInteger(precision = " + precision + "):\n\t" + biistr);
System.out.println("\tprecision: " + biistr.length() + " == " + precision + " : " + ( biistr.length() == precision ));
}

System.out.println("\n\n------------------------\n\n");

// demonstrate nextBigInteger(norm)
System.out.println("demonstrate nextBigInteger(\n\tnorm = " + bi + "\n):\n");
for (int i = 0; i < 5; i++) {
BigInteger bii = nextBigInteger(bi);
String biistr = bii.toString();
System.out.println("iteration " + i + " nextBigInteger(norm = ... ):\n\t" + biistr);
System.out.println("\tprecision: " + biistr.length() + " <= " + precision + " : " + ( biistr.length() <= precision ));
System.out.println("\t( bii <= bi ) = " + (bii.compareTo(bi) <= 0));
}

BigInteger bin = bi.negate();

System.out.println("\n\n------------------------\n\n");

// demonstrate between(min, MAX)
System.out.println("demonstrate between(\n\tmin = " + bin + ",\n\tMAX = " + bi + "\n):\n");
for (int i = 0; i < 5; i++) {
BigInteger bii = between(bin, bi);
String biistr = bii.toString();
System.out.println("iteration " + i + " between(norm = ... ):\n\t" + biistr);
System.out.println("\tprecision: " + biistr.length() + " <= " + precision + " : " + ( biistr.length() <= precision ));
System.out.println("\t( bii >= -bi ) = " + (bii.compareTo(bin) >= 0));
System.out.println("\t( bii < bi ) = " + (bii.compareTo(bi) < 0));
}

System.out.println("\n\n------------------------\n\n");

// Make a BigDecimal independently from this implementation.
BigDecimal bd = new BigDecimal(Double.MAX_VALUE);
for (int i = 10; i < 50; i = i + 10) {
bd = bd.add( new BigDecimal(defaultRandom.nextDouble()).pow(i) );
}

System.out.println("Independently generated random BigDecimal:\n" + bd);
System.out.println("\tprecision: " + bd.precision() + " scale: " + bd.scale());

System.out.println("\n\n------------------------\n\n");

// demonstrate nextBigDecimal(scale)
System.out.println("demonstrate nextBigDecimal(scale = " + bd.scale() + "):\n");
for (int i = 0; i < 5; i++) {
BigDecimal bdi = nextBigDecimal(bd.scale());
System.out.println("iteration " + i + " nextBigDecimal(scale = " + bd.scale() + "):\n\t" + bdi);
System.out.println("\tprecision: " + bdi.precision() + " scale: " + bdi.scale());
}

System.out.println("\n\n------------------------\n\n");

// demonstrate nextBigDecimal(norm, scale)
System.out.println("demonstrate nextBigDecimal(\n\tnorm = " + bd + ",\n\tscale = " + bd.scale() + "\n):\n");
for (int i = 0; i < 5; i++) {
BigDecimal bdi = nextBigDecimal(bd, bd.scale());
System.out.println("iteration " + i + " nextBigDecimal(norm = ..., scale = " + bd.scale() + "):\n\t" + bdi);
System.out.println("\tprecision: " + bdi.precision() + " scale: " + bdi.scale());
System.out.println("\t( bdi <= bd ) = " + (bdi.compareTo(bd) <= 0));
}

System.out.println("\n\n------------------------\n\n");

// demonstrate between(min, MAX)
BigDecimal bdn = bd.negate();
System.out.println("demonstrate between(\n\tmin = " + bdn + ",\n\tMAX = " + bd + "\n):\n");
for (int i = 0; i < 5; i++) {
BigDecimal bdi = between(bdn, bd);
System.out.println("iteration " + i + " between(-bd, bd):\n\t" + bdi);
System.out.println("\tprecision: " + bdi.precision() + " scale: " + bdi.scale());
System.out.println("\t( bdi >= -bd ) = " + (bdi.compareTo(bdn) >= 0));
System.out.println("\t( bdi < bd ) = " + (bdi.compareTo(bd) < 0));
}

}
}
``````

The following example attempts to clarify the reason why previous answers omit very large intervals of potentially valid random values.

Please consider an arbitrarily small epsilon value:

`e = x 10^(-infinity)`

and an interval:

`[0 + e, 1 + e]`.

As we try to approximate this conceptual range with larger and larger numeric values substituted in place of infinity, the scale of the range's endpoints grows well beyond the scale of `Math.random()` which returns double precision floating point numbers.

Conceptually:

``````BigDecimal e = ...  // arbitrarily small value.

BigDecimal norm = MAX.subtract(min);  // 1.0

norm.multiply(
new BigDecimal(
Math.random()
)
)
); // equivalent to e + (1.0 * Math.random())

``````

If `Math.random()` returns 0, randBigDecimal equals: e; If `Math.random()` returns Double.MIN_VALUE, randBigDecimal equals: `Double.MIN_VALUE + e`.

We can innumerate all possible values of randBigDecimal like so:

``````double d = 0.0;

// Don't actually run this loop!  :)
while (d < 1.0) {
System.out.println(e + d);
d = Math.nextUp(d);
}
``````

The more that the scale of e exceeds the scale of Java's double precision floating point numeric type, i.e. the primary motivation for using BigDecimal, the larger the gaps this algorithm leaves between `e + d` and `e + Math.nextUp(d)`.

In any case, this algorithm always leaves out min + 2e, min + 3e, ..., min + (N-1)e, min + Ne. For all integers [2, N] such that `(new BigDecimal(N).times(new BigDecimal(Double.MIN_VALUE))).scale() > e.scale()`.

Of course, many infinities of numbers exist between e and 2e, but we might like our random BigDecimal algorithm to cover at least all values with the same scale as `Math.max(min.scale(), MAX.scale())`.

• @corsiKa - any comment to this solid approach from Ben Mc Kenneby. BTW Ben - many thanks for your contribution! Apr 6, 2022 at 5:59
• Thanks, Marcin. It turns out that Java's BigInteger has 99.99% of the functionality hidden in: new BigInteger(bitCount, random). Converting that to a BigDecimal between 0 and 1 simply involves moving a decimal point. Apr 6, 2022 at 14:36
• Edited. I added a summary version to the beginning, and corrected a precision issue. Apr 6, 2022 at 15:05
• @BenMcKenneby I tested this for BigDecimals between 0 and 1 but it seems that the precision severly influences the "random" values I get. For example, with a precision of 30 I get 0 out of 1 million values >= 0.7. Why is that, and is there a solution that can help? Dec 13, 2023 at 22:28