Apart from the fact that your hashing function is not a very good one^{ *}, the biggest problem with your code is not that it returns a different number depending on the version of .NET, but that in both cases it returns an entirely meaningless number: the correct answer to the problem is

49^{103} mod 143 = is 114. (link to Wolfram Alpha)

You can use this code to compute this answer:

```
private static int PowMod(int a, int b, int mod) {
if (b == 0) {
return 1;
}
var tmp = PowMod(a, b/2, mod);
tmp *= tmp;
if (b%2 != 0) {
tmp *= a;
}
return tmp%mod;
}
```

The reason why your computation produces a different result is that in order to produce an answer, you use an intermediate value that drops most of the significant digits of the 49^{103} number: only the first 16 of its 175 digits are correct!

```
1230824813134842807283798520430636310264067713738977819859474030746648511411697029659004340261471771152928833391663821316264359104254030819694748088798262075483562075061997649
```

The remaining 159 digits are all wrong. The mod operation, however, seeks a result that requires every single digit to be correct, including the very last ones. Therefore, even the tiniest improvement to the precision of `Math.Pow`

that may have been implemented in .NET 4, would result in a drastic difference of your calculation, which essentially produces an arbitrary result.

^{ *} Since this question talks about raising integers to high powers in the context of password hashing, it may be a very good idea to read this answer_{link} before deciding if your current approach should be changed for a potentially better one.

nota duplicate. – dasblinkenlight Jan 31 at 13:57`%`

with floating-point numbers. – Ben Voigt Jan 31 at 17:21