To come up with an "longer" answer than my previous:

You already linked the implementation, it looks like:

```
public long nextLong(){
return ((long) next(32) << 32) + next(32);
}
```

So, obviously, ONE random number calls 2 times `next(32)`

.
That means, 2 random numbers will be equal, if `next(32)`

results
in 4 times THE SAME number because the rest of the function is "hardcoded".

Looking at the `next()`

function, we can see the following:

```
protected synchronized int next(int bits){
seed = (seed * 0x5DEECE66DL + 0xBL) & ((1L << 48) - 1);
return (int) (seed >>> (48 - bits));
}
```

The return part can be simply ignored, because again: SAME seed would lead
to the SAME return value - otherwhise your CPU is broken.

So, in total: We only need to focus on the line

```
seed = (seed * 0x5DEECE66DL + 0xBL) & ((1L << 48) - 1);
```

if that will result in the SAME seed, for **four times**, 2 random numbers have been generated,
that are equal.

(*Note: Sequences like a,b,a,b can be excluded to produce the same result. Post is long enough, i skip that part.)*

First, lets eliminate the `<< 48`

part. What does that mean? The Number given (1) will be shifted left
48 times. So the binary `0...01`

will turn into `1000000000000000000000000000000000000000000000000`

(48 zeros)
then, one is subtracted, so what you will get is `0111111111111111111111111111111111111111111111111`

(47 ones)

Lets have a look at the first part of that equation:

```
(seed * 0x5DEECE66D[L] + 0xB[L])
```

**Note, that the ending [L] will only cause it to be a long value instead of a integer.**

so, in binary words, that means:

```
seed * 10111011110111011001110011001101101 + 1011
```

After all, the function looks like

```
seed = (seed * 10111011110111011001110011001101101 + 1011) & (0111111111111111111111111111111111111111111111111)
```

(I left out the leading zeros on the first values)

So, what does `& (0111111111111111111111111111111111111111111111111)`

do ?

The bitwise-and-operator and basically compares EVERY position of two binary numbers. And only if BOTH of them are "1", the position in the resulting binary number will be 1.

this said, EVERY bit of the equation `(seed * 10111011110111011001110011001101101 + 1011)`

with a position GREATER than 48 from the RIGHT will be **ignored**.

The 49th bit equals `2^49`

or `562949953421312 decimal`

- meaning that & `(0111111111111111111111111111111111111111111111111)`

basically just says
that the **MAXIMUM** result can be `562949953421312 - 1`

.
So, instead of the result `562949953421312`

- it would produce 0 again, `562949953421313`

would produce 1 and so on.

**All the stuff I wrote above could be easily verified:**

While the following code will produce the random **seed** **11**:

```
private Long seed = 0L;
protected synchronized int next(int bits){
seed = (seed * 0x5DEECE66DL + 0xBL) & ((1L << 48) - 1);
System.out.println(seed);
return (int) (seed >>> (48 - bits));
}
```

One can reverse engineer the seed and ALSO gets the seed 11 from a non-0 seed, using the number `562949953421312L`

.

```
private Long seed = 562949953421312L - 0xBL / 0x5DEECE66DL;
protected synchronized int next(int bits){
seed = (seed * 0x5DEECE66DL + 0xBL) & ((1L << 48) - 1);
System.out.println(seed);
return (int) (seed >>> (48 - bits));
}
```

So, you see: **Seed 562949953421312 equals Seed 0**.

Easier proof:

```
Random r = new Random(0L);
Random r2 = new Random(562949953421312L);
if (r.nextLong()==r2.nextLong()){
System.out.println("Equal"); //You WILL get this!
}
```

it continous of course:

```
Random r3 = new Random(1L);
Random r4 = new Random(562949953421313L);
if (r3.nextLong()==r4.nextLong()){
System.out.println("Equal");
}
```

Why is this "magic number" (`562949953421312L`

) important?

Assuming, we are starting with Seed 0.

The the first new-seed will be: `0 * 10111011110111011001110011001101101 + 1011 = 1011 (dec: 11)`

The next seed would be: `1011 * 10111011110111011001110011001101101 + 1011 = 100000010010100001011011110011010111010 (dec: 277363943098)`

The next seed (call 3) would be: `100000010010100001011011110011010111010 * 10111011110111011001110011001101101 + 1011 = 10000100101000000010101010100001010100010011100101100100111101 (dec 2389171320405252413)`

So, the maximum number of `562949953421312L`

is exceeded, which will cause the random number to be SMALLER than the above calculated value.

Also, adding `1011`

will cause the result to alternate between odd and even numbers. (Not sure about the *real* meaning - adding 1 could have worked as well, imho)

So, generating 2 seeds (NOT random numbers) ensures, that they are NOT equal, because a specific "overflow" point has been selected - and adding the MAXIMUM value (562949953421312L) is NOT enough to hit the same number within 2 generations.

And when 2 times the same seed is impossible, 4 times is also impossible, which means, that the nextLong() function could never return the same value for n and n+1 generations.

**I have to say, that I wanted to proof the opposite. From a statistical point of view, 2 times the same number is possible - but maybe that's why it's called Pseudorandomness :)**

pseudorandom number generator, and if the long value is essentially the main value stored internal to the generator, it will never repeat, for the cycle time of the pseudo-random algorithm. I suspect that he isprobablyright, though one would need to inspect the innards of the algorithm to be sure. – Hot Licks Feb 7 '14 at 18:16`seed`

wasn't carried over for some reason, but the value persists through each call to`next()`

. In this case, I do believe it is impossible to generate the same value twice, unless there was a literal single value that fit into that seed equation that would spit out the same value. – Deactivator2 Feb 7 '14 at 18:23`seed`

, generating the next value from the previous one. A long value is produced from two successive 32-bit values, however, and the 32-bit values are produced from what are apparently 48-bit values with (hopefully) a cycle time of about 2**48. So there's in theory a chance that the algorithm could produce two values whose low-order 32 bits are the same in quick succession (though I suspect that the specifics of the algorithm prevent this). IOW, a mathematician might be able to prove a chance of repeat, but no mortal programmer could. – Hot Licks Feb 7 '14 at 18:30