# 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 |
|v1_min|-7.799011049744149|119153396299238|
|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:

- Initialize
`nd1`

(stands for `nextDouble`

1) to 0.5
- While the upper bound and our current v1_max haven't crossed, repeat steps 3-7
- Increment
`nd1`

by 2^-53
- Compute
`seed`

from `nd1`

(if it exists), and generate `nd2`

, `v1`

, `v2`

and `s`

- Check the validity of
`s`

- Generate a gaussian, compare with v1_max
- 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).

`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 16:12The 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