In theory, the bounds for nextGaussian are meant to be positive and negative infinity. But since Random.nextDouble, which is used to calculate the Gaussian random number, doesn't come infinitely close to 0 and 1, there is a practical limit to nextGaussian. And Random.next is also not a perfectly uniform distribution.

It was theorised that the maximum should be about 2.2042*10^17 and related to the 53 bit shift of nextDouble (reference), but that is likely just an upper bound.

The answer probably depends on the distribution of Random.next and the exact implementation of StrictMath.sqrt and StrictMath.log. I couldn't find much information about either.

And yes, I know that the outer values are extremely unlikely, but it can be relevant, for example in the context of RNG manipulation in games.

  • 2
    Interesting question. Have you looked at the Java source code for these methods? That will probably give you the answer. – Hovercraft Full Of Eels Feb 15 '19 at 16:01
  • For the Random class, yes, for the StrictMath class there's no source code where I looked (docs.oracle.com/javase/7/docs/api/java/lang/StrictMath.html). Also, it doesn't just give the answer, it needs quite a bit of analysis, not all parts I understand. – Fabian Röling Feb 15 '19 at 16:12
  • 4
    This is investigated by Daniel Jelinski in his blog (part 1, part 2). He said: "The lowest value found was: -7.844680087923773 (on second call to nextGaussian with seed = 994892). The highest value found was: 7.995084298635286 (on first call to nextGaussian with seed = 14005843). These are the real maximum & minimum values returned by Oracle Java 8 implementation of nextGaussian." – Wai Ha Lee Feb 18 '19 at 11:40

Random Implementation

The most important thing you will have to know for this answer is the implementation of Random.nextGaussian:

synchronized public double nextGaussian() {
    // See Knuth, ACP, Section 3.4.1 Algorithm C.
    if (haveNextNextGaussian) {
        haveNextNextGaussian = false;
        return nextNextGaussian;
    } else {
        double v1, v2, s;
        do {
            v1 = 2 * nextDouble() - 1; // between -1 and 1
            v2 = 2 * nextDouble() - 1; // between -1 and 1
            s = v1 * v1 + v2 * v2;
        } while (s >= 1 || s == 0);
        double multiplier = StrictMath.sqrt(-2 * StrictMath.log(s)/s);
        nextNextGaussian = v2 * multiplier;
        haveNextNextGaussian = true;
        return v1 * multiplier;

And the implementation of Random.nextDouble:

public double nextDouble() {
    return (double) (((long)(next(26)) << 27) + next(27)) / (1L << 53);

First, I want to draw your attention to the fact that nextGaussian generates 2 values at a time, and that depending on whether you know how many nextGaussian calls have passed since the last time the seed was set, you may be able to use a slightly lower max value for odd vs even numbers of calls. From now on, I'm going to call the two maximums v1_max and v2_max, referring to whether the value was generated by v1 * multiplier or v2 * multiplier.

The Answer

With that out of the way let's cut straight to the chase and explain later:

|      |Value             |Seed*          |
|v1_max|7.995084298635286 |97128757896197 |
|v2_max|7.973782613935931 |10818416657590 |
|v2_min|-7.844680087923773|10300138714312 |
* Seeds for v2 need to have nextGaussian called twice before you see the value listed.

A Closer Look at nextGaussian

The answers by @KaptainWutax and @Marco13 have already gone into detail about the same things, but I think seeing things on a graph makes things clearer. Let's focus on v1_max, the other three values hold very similar logic. I'm going to plot v1 on the x-axis, v2 on the y-axis and v1 * multiplier on the z-axis.


Our eyes immediately jump to the maximum point at v1 = 0, v2 = 0, v1 * multiplier = infinity. But if you notice in the do-while loop, it explicitly disallows this situation. Therefore, it's clear from the graph that the actual v1_max must have a slightly higher v1 value, but not much higher. Also noteworthy is that for any v1 value > 0, the maximum v1 * multiplier is at v2 = 0.

Our method to find v1_max will be to count up v1 from zero (or, more specifically, counting the nextDouble which generated it up from 0.5, incrementing in steps of 2^-53, as per the implementation of nextDouble). But, just knowing v1, how do we get the other variables, and the v1 * multiplier for that v1?

Reversing nextDouble

It turns out that knowing the output of a nextDouble call is enough to determine the seed of the Random object that generated it at the time. Intuitively, this is because looking at the nextDouble implementation, it "looks like" there should be 2^54 possible outputs - but the seed of Random is only 48-bit. Furthermore, it's possible to recover this seed in much faster time than brute force.

I initially tried a naive approach based on using next(27) directly to get bits of the seed then brute-forcing the remaining 21 bits, but this proved too slow to be useful. Then SicksonFSJoe gave me a much faster method to extract a seed from a single nextDouble call. Note that to understand the details of this method you will have to know the implementation of Random.next, and a little modular arithmetic.

private static long getSeed(double val) {
    long lval = (long) (val * (1L << 53));
    // let t = first seed (generating the high bits of this double)
    // let u = second seed (generating the low bits of this double)
    long a = lval >> 27; // a is the high 26 bits of t
    long b = lval & ((1 << 27) - 1); // b is the high 27 bits of u

    // ((a << 22) + c) * 0x5deece66d + 0xb = (b << 21) + d (mod 2**48)
    // after rearranging this gives
    // (b << 21) - 11 - (a << 22) * 0x5deece66d = c * 0x5deece66d - d (mod 2**48)
    // and because modular arithmetic
    // (b << 21) - 11 - (a << 22) * 0x5deece66d + (k << 48) = c * 0x5deece66d - d
    long lhs = ((b << 21) - 0xb - (a << 22) * 0x5deece66dL) & 0xffffffffffffL;

    // c * 0x5deece66d is 56 bits max, which gives a max k of 375
    // also check k = 65535 because the rhs can be negative
    for (long k = 65535; k != 376; k = k == 65535 ? 0 : k + 1) {
        // calculate the value of d
        long rem = (0x5deece66dL - (lhs + (k << 48))) % 0x5deece66dL;
        long d = (rem + 0x5deece66dL) % 0x5deece66dL; // force positive
        if (d < (1 << 21)) {
            // rearrange the formula to get c
            long c = lhs + d;
            c *= 0xdfe05bcb1365L; // = 0x5deece66d**-1 (mod 2**48)
            c &= 0xffffffffffffL;
            if (c < (1 << 22)) {
                long seed = (a << 22) + c;
                seed = ((seed - 0xb) * 0xdfe05bcb1365L) & 0xffffffffffffL; // run the LCG forwards one step
                return seed;

    return Long.MAX_VALUE; // no seed

Now we can get the seed from a nextDouble, it makes sense that we can iterate over v1 values rather than seeds.

Bringing it All Together

An outline of the algorithm is as follows:

  1. Initialize nd1 (stands for nextDouble 1) to 0.5
  2. While the upper bound and our current v1_max haven't crossed, repeat steps 3-7
  3. Increment nd1 by 2^-53
  4. Compute seed from nd1 (if it exists), and generate nd2, v1, v2 and s
  5. Check the validity of s
  6. Generate a gaussian, compare with v1_max
  7. Set a new upper bound by assuming v2 = 0

And here is a Java implementation. You can verify the values I gave above for yourself if you want.

public static void main(String[] args) {
    double upperBound;
    double nd1 = 0.5, nd2;
    double maxGaussian = Double.MIN_VALUE;
    long maxSeed = 0;
    Random rand = new Random();
    long seed;
    int i = 0;
    do {
        nd1 += 0x1.0p-53;
        seed = getSeed(nd1);

        double v1, v2, s;
        v1 = 2 * nd1 - 1;

        if (seed != Long.MAX_VALUE) { // not no seed
            rand.setSeed(seed ^ 0x5deece66dL);
            rand.nextDouble(); // nd1
            nd2 = rand.nextDouble();

            v2 = 2 * nd2 - 1;
            s = v1 * v1 + v2 * v2;
            if (s < 1 && s != 0) { // if not, another seed will catch it
                double gaussian = v1 * StrictMath.sqrt(-2 * StrictMath.log(s) / s);
                if (gaussian > maxGaussian) {
                    maxGaussian = gaussian;
                    maxSeed = seed;

        upperBound = v1 * StrictMath.sqrt(-2 * StrictMath.log(v1 * v1) / (v1 * v1));
        if (i++ % 100000 == 0)
            System.out.println(maxGaussian + " " + upperBound);
    } while (upperBound > maxGaussian);
    System.out.println(maxGaussian + " " + maxSeed);

One final catch to watch out for, this algorithm will get you the internal seeds for the Random. To use it in setSeed, you have to xor them with the Random's multiplier, 0x5deece66dL (which has already been done for you in the table above).

| improve this answer | |
  • I wonder why nextGaussian generates two numbers at a time. I can imagine that this can cause quite the headache when setting a seed and expecting it to be applied on the next call. – Fabian Röling Feb 18 '19 at 7:23
  • 1
    @FabianRöling you will always get the same value from nextGaussian after setting the same seed, since the haveNextNextGaussian flag is set to false when setting the seed. – Earthcomputer Feb 18 '19 at 11:06
  • 1
    Also a great answer, I'd still have to allocate more time in order to read (i.e. "understand") it more thoroughly. But one important point: Please don't call it v1-max. This looks like a subtraction. Calling it v1max or maxV1 or so would make much clearer that this is only a single value. – Marco13 Feb 18 '19 at 11:22

So everything I will say here is purely theoretical, and I am still working on a GPU program to scan the whole seed base.

The nextGaussian() method is implemented as such.

private double nextNextGaussian;
private boolean haveNextNextGaussian = false;

 public double nextGaussian() {

   if (haveNextNextGaussian) {

     haveNextNextGaussian = false;
     return nextNextGaussian;

   } else {

     double v1, v2, s;

     do {
       v1 = 2 * nextDouble() - 1;   // between -1.0 and 1.0
       v2 = 2 * nextDouble() - 1;   // between -1.0 and 1.0
       s = v1 * v1 + v2 * v2;
     } while (s >= 1 || s == 0);

     double multiplier = StrictMath.sqrt(-2 * StrictMath.log(s)/s);
     nextNextGaussian = v2 * multiplier;
     haveNextNextGaussian = true;
     return v1 * multiplier;



The most interesting part has to be at the end, [return v1 * multiplier]. Because v1 cannot be larger than 1.0D, we need to find a way to increase the size of the multiplier, which is implemented as follows.

double multiplier = StrictMath.sqrt(-2 * StrictMath.log(s)/s);

The only variable being "s", it is safe to establish that the lower "s" is, the bigger the multiplier will get. All good? Let's keep going.

 do {
   v1 = 2 * nextDouble() - 1;   // between -1.0 and 1.0
   v2 = 2 * nextDouble() - 1;   // between -1.0 and 1.0
   s = v1 * v1 + v2 * v2;
 } while (s >= 1 || s == 0);

This tells us that "s" has to belong to the ]0,1[ number set and that the lowest value we're looking for is just a little bigger than zero. "S" is declared with the sum of squares of "v1" and "v2". To get the smallest theoretical value, v2 needs to be zero and v1 needs to be as small as it can possibly get. Why "theoretical"? Because they are generated from nextDouble() calls. There is no guarantee that the seed base contains those 2 consecutive numbers.

Let's have fun now!

Lowest value "v1" can hold is the double's epsilon, which is 2^(-1022). Making our way back, to get such a number, nextDouble would need to generate (2^(-1022) + 1) / 2.

That is...very very very disturbing. I'm not an expert, but I am pretty sure many bits are gonna get lost, and floating-point errors are to be expected.

It is probably(most definitely) impossible for a nextDouble to generate such a value, but the goal is to find a value as close as possible to that number.

Just for the fun of it, let's do the full math to find the answer. StrictMath.log() is implemented as the natural log. I haven't looked into it's precision, but let's assume there was no limitations on that level. The highest nextGaussian would be calculated as...

= (-2 * ln(v1 * v1) / (v1 * v1)) * v1 
= (-2 * ln(EPSILON^2) / (EPSILON^2)) * EPSILON

where EPSILON is equal to 2^(-1022).

Believe it or not, I could barely find any calculator that accepted such small numbers, but I finally opted for this high precision calculator.

By plugging in this equation,

(-2 * ln((2^(-1022))^2) / ((2^(-1022))^2)) * (2^(-1022))

I got,


Pretty big huh? Well...it's definitely not going to be that big...but it's nice to take into account. Hope my reasoning makes sense and don't be shy to point out any mistake I made.

As I said at the start, I am working on a program to bruteforce all seeds and find the actual lowest value. I'll keep you updated.


Sorry for the late response. After bruteforcing 2^48 seeds in about 10 hours, I found the EXACT same answers as Earthcomputer.

| improve this answer | |
  • 2
    What an amazing first post for this account. :D And on the first try even (no edits)! I won't mark it as accepted for now, since that's just an upper bound. Considering wither skulls, I guess an upper bound of 10^311 doesn't really help much in proving a design to be 100% reliable. If that's a motion value or something like that, it would fly to the farlands in less than a frame. To everyone else reading this, being probably very confused: We're both in the same chat where this question originated from. It all makes sense in context. – Fabian Röling Feb 15 '19 at 22:23
  • Haha, thank you! :D <3 I think it's much better to talk about it here. I couldn't find any post of anyone attempting to find the actual upper bound even though I'm pretty sure a bunch of people want to know. Also, there are way smarter people around who could probably help. – KaptainWutax Feb 15 '19 at 22:33
  • Indeed, a great answer. But it will take some more investigation to find the final truth here. You said "To get the smallest theoretical value, v2 needs to be zero and v1 needs to be as small as it can possibly get.". The point is: When v1 is small, then the final result will also be small. The actual maximum will pobably have to be fought out between the log(s)/s part and the v1 * ... part, and this is where it gets complicated... – Marco13 Feb 16 '19 at 15:22
  • You should not worry about that. While v1 gets linearly smaller, log(s)/s gets exponentially bigger. v1's value is not a big deal. – KaptainWutax Feb 16 '19 at 15:54
  • Yes, I also noticed that (mentioned in my answer as well). However, the mutual influences here are not trivial, and my answer has to be considered to be no more than a "reasonable guess". Let's see whether someone finds a line of argumentation where a value larger than ~12 can be achieved. – Marco13 Feb 16 '19 at 16:12

My bet is on 12.00727336061225.

The reasoning behind that is roughly along the lines of the answer by KaptainWutax : Considering the log(s)/s part for the multiplier, the goal must be to make s as small as possible. This comes with the additional constraint that v1 will be part of the result. So essentially

  • v1 has to be small, so that s is small
  • v1 has to be large, so that the final result is large

But since the division by s will grow exponentially as s approaches zero, this will overweigh contribution of the factor v1.

So to summarize that line of thought:

The essential part of the implementation of Random#nextGaussian is that one:

double nextGaussian() {
    double v1, v2, s;
    do {
        v1 = 2 * nextDouble() - 1; // between -1 and 1
        v2 = 2 * nextDouble() - 1; // between -1 and 1
        s = v1 * v1 + v2 * v2;
    } while (s >= 1 || s == 0);
    double multiplier = StrictMath.sqrt(-2 * StrictMath.log(s)/s);
    return v1 * multiplier;

The Random#nextDouble method is implemented like this:

double nextDouble() {
    return (((long)next(26) << 27) + next(27)) / (double)(1L << 53);

where next(n) returns an integer where the lowest n bits are set randomly.

In order to maximize the value of nextGaussian, one can argue:

  • The value of s must be as close as possible to 0.0 (but just not 0.0)
  • Therefore, the "best" value for v2 will be 0.0, and the "best" value for v1 will be the smallest value that can be the result of 2 * nextDouble() - 1
  • In order to have v2==0.0, we assume that the random bits in the nextDouble call are 0b10000000000000000000000000000000000000000000000000000L - in this case, nextDouble will return 0.5, and v2 will be 0.0
  • The bits that would cause the smallest valid value for v1 would then be 0b10000000000000000000000000000000000000000000000000001L - just one annoying bit at the end, causing nextDouble to return 0.5000000000000001, yielding a value of 2.220446049250313E-16 for v1
  • Given these values, s will be 4.930380657631324E-32, the multiplier will be 5.4075951832589016E16, and the final result will be


Here is an example where you can play around with the bit combinations that might be returned by the Random#next calls that are the basis for the whole computation here. Maybe someone finds a combination that yields a higher value...?

public class LargestNextGaussian
    public static void main(String[] args)
        // Random#nextDouble is implemented as 
        //   (((long)next(26) << 27) + next(27)) / (double)(1L << 53)
        // The "baseValue" here refers to the value that
        // is obtained by combining the results of the 
        // two calls to "next"

        long baseValueForV1 = 
        double valueForV1 = 
            baseValueForV1 / (double)(1L << 53);

        long baseValueForV2 = 
        double valueForV2 = 
            baseValueForV2 / (double)(1L << 53);

        // As of Random#nextGaussian:
        double v1, v2, s;
        do {
            v1 = 2 * valueForV1 - 1;
            v2 = 2 * valueForV2 - 1;
            s = v1 * v1 + v2 * v2;
        } while (s >= 1 || s == 0);
        double multiplier = StrictMath.sqrt(-2 * StrictMath.log(s)/s);
        double result = v1 * multiplier;

        System.out.println("baseValueForV1 " + Long.toBinaryString(baseValueForV1));
        System.out.println("baseValueForV2 " + Long.toBinaryString(baseValueForV2));
        System.out.println("valueForV1     " + valueForV1);
        System.out.println("valueForV2     " + valueForV2);
        System.out.println("v1             " + v1);
        System.out.println("v2             " + v2);
        System.out.println("s              " + s);
        System.out.println("multiplier     " + multiplier);
        System.out.println("result         " + result);

The output is, as summarized above:

baseValueForV1 10000000000000000000000000000000000000000000000000001
baseValueForV2 10000000000000000000000000000000000000000000000000000
valueForV1     0.5000000000000001
valueForV2     0.5
v1             2.220446049250313E-16
v2             0.0
s              4.930380657631324E-32
multiplier     5.4075951832589016E16
result         12.00727336061225
| improve this answer | |
  • Thanks for the more detailed explanation, I really underestimated how quick it grows. It makes perfect sense for it to be 12. – KaptainWutax Feb 16 '19 at 16:35

here ya go:

long seed=97128757896197L; Random r= new Random(seed ); System.out.println(r.nextGaussian()); System.out.println(r.nextGaussian());

7.995084298635286 0.8744239748619776

| improve this answer | |
  • 2
    Nice to know that that number is possible, I guess, but that doesn't say if it's the maximum. – Fabian Röling Feb 17 '19 at 23:04
  • lets wait for earth essay then we will see ^_^ – neil pop Feb 18 '19 at 0:41

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.