The pow() function is typically implemented in the math library, possibly using special instructions in the target processor, for x86 see How to: pow(real, real) in x86. However, instructions such as `fyl2x`

and `f2xm1`

aren't fast, so the whole thing could take 100 CPU cycles. For performance reasons a compiler like gcc provide "built-in" functions that provide strength reduction to perform computations faster in special cases. When the power `N`

is an integer (as in your case) and small (as in your case) then it is faster to multiply `N`

times than to call the library function.

In order to detect cases where the power is an integer the math library provides overloaded functions, for example `double pow(double,int)`

. You will find that gcc converts

```
double x = std::pow(y,4);
```

internally into 2 multiplications, which is much faster than a library call, and gives the precise integer result you expect when both operands are integers

```
double tmp = y * y;
double x = tmp * tmp;
```

in order to get this type of strength reduction you should

- #include < cmath >
- compile with optimization -O2
- call the pow function in the library explicitly
`std::pow()`

to make sure that's the version you get, and not one from math.h

You will then match the overloaded pow function in < cmath > which looks like this

```
inline double pow(double __x, int __i) { return __builtin_powi(__x, __i); }
```

Notice that this function is implemented with `__builtin_powi`

which knows the strength reduction of pow() to multiplication when the power is a small integer.