Java inverse modulo 2**64

Given an odd `long x`, I'm looking for `long y` such that their product modulo `2**64` (i.e., using the normal overflowing arithmetic) equals to 1. To make clear what I mean: This could be computed in a few thousand year this way:

``````for (long y=1; ; y+=2) {
if (x*y == 1) return y;
}
``````

I know that this can be solved quickly using the extended Euclidean algorithm, but it requires the ability to represent all the involved numbers (ranging up to `2**64`, so even unsigned arithmetic wouldn't help). Using `BigInteger` would surely help, but I wonder if there's a simpler way, possibly using the extended Euclidean algorithm implemented for positive longs.

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Hacker's Delight suggests an algorithm for mod 2^32. I'd try some variant of that, though I'd test heavily, of course. (Perhaps that might be worth including in Guava...) –  Louis Wasserman Jul 28 '12 at 16:22
@Louis Wasserman: Nice link... in the meantime I think I've got something 3x faster -- I'll post my results later. Btw., I needed `pow(long, long)` (missing from `LongMath`) for one approach. –  maaartinus Jul 29 '12 at 0:11
`pow(long, long)` is deliberately missing because taking anything to a power that doesn't fit into an `int` is essentially guaranteed to overflow. (Though I guess that's what you want in your case.) –  Louis Wasserman Jul 29 '12 at 8:37
Yes. For things like `checkedPow` or `saturatedPow`, I agree that long exponent makes no sense, for `pow` I do not. I published benchmarks and tests for 6 different solution possibilities. Concerning Guava, I'd suggest including things from linked Math64. –  maaartinus Jul 29 '12 at 13:44
The rule we ended up going with is that we assume you don't want to deliberately cause overflow. The distinction between `pow` and `checkedPow` is not whether or not it's expected to overflow, but whether or not you want to pay the overhead of checking. –  Louis Wasserman Jul 29 '12 at 14:07

Here's one way of doing it. This uses the extended Euclidean algorithm to find an inverse of `abs(x)` modulo 262, and at the end it 'extends' the answer up to an inverse modulo 264 and applies a sign change if necessary:

``````public static long longInverse(long x) {

if (x % 2 == 0) { throw new RuntimeException("must be odd"); }

long power = 1L << 62;

long a = Math.abs(x);
long b = power;
long sign = (x < 0) ? -1 : 1;

long c1 = 1;
long d1 = 0;
long c2 = 0;
long d2 = 1;

// Loop invariants:
// c1 * abs(x) + d1 * 2^62 = a
// c2 * abs(x) + d2 * 2^62 = b

while (b > 0) {
long q = a / b;
long r = a % b;
// r = a - qb.

long c3 = c1 - q*c2;
long d3 = d1 - q*d2;

// Now c3 * abs(x) + d3 * 2^62 = r, with 0 <= r < b.

c1 = c2;
d1 = d2;
c2 = c3;
d2 = d3;
a = b;
b = r;
}

if (a != 1) { throw new RuntimeException("gcd not 1 !"); }

// Extend from modulo 2^62 to modulo 2^64, and incorporate sign change
// if necessary.
for (int i = 0; i < 4; ++i) {
long possinv = sign * (c1 + (i * power));
if (possinv * x == 1L) { return possinv; }
}

throw new RuntimeException("failed");
}
``````

I found it easier to work with 262 than 263, mainly because it avoids problems with negative numbers: 263 as a Java `long` is negative.

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I've accepted your solution since your comment to mine lead to the fastest one, see here. –  maaartinus Jul 29 '12 at 13:46

In the meantime I've recalled/reinvented a very simple solution:

``````public static int inverseOf(int x) {
Preconditions.checkArgument((x&1)!=0, "Only odd numbers have an inverse, got " + x);
int y = 1;
final int product = x * y;
final int delta = product & mask;
y |= delta;
}
return y;
}
``````

It works because of two things:

• in each iteration if the corresponding bit of `product` is `1`, then it's wrong, and the only way to fix is is by changing the corresponding bit of `y`
• no bit of `y` influences any less significant bit of `product`, so no previous work gets undone

I started with `int` since for `long` it must work too, and for `int` I could run an exhaustive test.

Another idea: there must a a number `n>0` such that `x**n == 1`, and therefore `y == x**(n-1)`. This should probably be faster, I just can't recall enough math to compute `n`.

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+1 interesting answer. I think the value of `n` you mention is `2**62`. –  Luke Woodward Jul 28 '12 at 21:19
@Luke Woodward: Using Euler's totient function I get `2**63`, but it seems to work with `2**62` as well. And it seems to lead to the fastest method. –  maaartinus Jul 28 '12 at 23:46