There is an other way, though it has a different kind of loop if you look closely.. anyway, it can be solved like this:

```
y*known_number ≡ 81 (mod 145)
y ≡ 81 * known_number ^ -1 (mod 145)
```

Which works iff `known_number`

indeed *has* a modular multiplicative inverse modulo 145, which happens when the GCD between the known number and the modulus is 1 (`gcd(7, 145) = 1`

so in this case it would work). Here the inverse is 83, so we compute `y = 81 * 83 % 145 = 53`

.

In general you may find that inverse by using the Extended Euclidean Algorithm, but also through various other methods, for example `pow(known_number, 111, 145)`

, where 111 is `totient(145) - 1`

. Computing a totient is not easy unless you have the prime-factorization of the number. The `pow`

function hides a loop, but a much shorter loop than brute-forcing the equation.