First of all how this algorithm works? It is based on the Extended Euclidean algorithm for computation of the GCD. In short the idea is following: if we can find some integer coefficients `m`

and `n`

such that

```
a*m + b*n = 1
```

then `m`

will be the answer for the modular inverse problem. It is easy to see because

```
a*m + b*n = a*m (mod b)
```

Luckily the Extended Euclidean algorithm does exactly that: if `a`

and `b`

are co-prime, it finds such `m`

and `n`

. It works in the following way: for each iteration track two triplets `(ai, xai, yai)`

and `(bi, xbi, ybi)`

such that at every step

```
ai = a0*xai + b0*yai
bi = a0*xbi + b0*ybi
```

so when finally the algorithm stops at the state of `ai = 0`

and `bi = GCD(a0,b0)`

, then

```
1 = GCD(a0,b0) = a0*xbi + b0*ybi
```

It is done using more explicit way to calculate modulo: if

```
q = a / b
r = a % b
```

then

```
r = a - q * b
```

Another important thing is that it can be proven that for positive `a`

and `b`

at every step `|xai|,|xbi| <= b`

and `|yai|,|ybi| <= a`

. This means there can be no overflow during calculation of those coefficients. Unfortunately negative values are possible, moreover, on every step after the first one in each equation one is positive and the other is negative.

What the code in your question does is a reduced version of the same algorithm: since all we are interested in is the `x[a/b]`

coefficients, it tracks only them and ignores the `y[a/b]`

ones. The simplest way to make that code work for `uint64_t`

is to track the sign explicitly in a separate field like this:

```
typedef struct tag_uint64AndSign {
uint64_t value;
bool isNegative;
} uint64AndSign;
uint64_t mul_inv(uint64_t a, uint64_t b)
{
if (b <= 1)
return 0;
uint64_t b0 = b;
uint64AndSign x0 = { 0, false }; // b = 1*b + 0*a
uint64AndSign x1 = { 1, false }; // a = 0*b + 1*a
while (a > 1)
{
if (b == 0) // means original A and B were not co-prime so there is no answer
return 0;
uint64_t q = a / b;
// (b, a) := (a % b, b)
// which is the same as
// (b, a) := (a - q * b, b)
uint64_t t = b; b = a % b; a = t;
// (x0, x1) := (x1 - q * x0, x0)
uint64AndSign t2 = x0;
uint64_t qx0 = q * x0.value;
if (x0.isNegative != x1.isNegative)
{
x0.value = x1.value + qx0;
x0.isNegative = x1.isNegative;
}
else
{
x0.value = (x1.value > qx0) ? x1.value - qx0 : qx0 - x1.value;
x0.isNegative = (x1.value > qx0) ? x1.isNegative : !x0.isNegative;
}
x1 = t2;
}
return x1.isNegative ? (b0 - x1.value) : x1.value;
}
```

Note that if `a`

and `b`

are not co-prime or when `b`

is 0 or 1, this problem has no solution. In all those cases my code returns `0`

which is an impossible value for any real solution.

Note also that although the calculated value is really the modular inverse, simple multiplication will not always produce 1 because of the overflow at multiplication over `uint64_t`

. For example for `a = 688231346938900684`

and `b = 2499104367272547425`

the result is `inv = 1080632715106266389`

```
a * inv = 688231346938900684 * 1080632715106266389 =
= 743725309063827045302080239318310076 =
= 2499104367272547425 * 297596738576991899 + 1 =
= b * 297596738576991899 + 1
```

But if you do a naive multiplication of those `a`

and `inv`

of type `uint64_t`

, you'll get `4042520075082636476`

so `(a*inv)%b`

will be `1543415707810089051`

rather than expected `1`

.

`pX`

can be less than zero, whereas in modular setting it is not and the usual way is to do`if (pX < 0) pX += b`

. But that is signed and unsigned addition which can (or cannot?) overflow. Ideally, for modular calculations there would be no`static_cast<S>`

. But thanks again for writing the article, if you are the author.