There are various arguments that in some cases, Fortran can be faster than C, for example when it comes to aliasing and I often heard that it does better auto-vectorization than C (see here for some good discussion).

However, for simple functions as calculation the Fibonaci number and the Mandelbrot at some complex number with straight-forward solutions without any tricks and extra hints/keywords to the compiler, I would have expected that they really perform the same.

C implementation:

```
int fib(int n) {
return n < 2 ? n : fib(n-1) + fib(n-2);
}
int mandel(double complex z) {
int maxiter = 80;
double complex c = z;
for (int n=0; n<maxiter; ++n) {
if (cabs(z) > 2.0) {
return n;
}
z = z*z+c;
}
return maxiter;
}
```

Fortran implementation:

```
integer, parameter :: dp=kind(0.d0) ! double precision
integer recursive function fib(n) result(r)
integer, intent(in) :: n
if (n < 2) then
r = n
else
r = fib(n-1) + fib(n-2)
end if
end function
integer function mandel(z0) result(r)
complex(dp), intent(in) :: z0
complex(dp) :: c, z
integer :: n, maxiter
maxiter = 80
z = z0
c = z0
do n = 1, maxiter
if (abs(z) > 2) then
r = n-1
return
end if
z = z**2 + c
end do
r = maxiter
end function
```

Julia implementation:

```
fib(n) = n < 2 ? n : fib(n-1) + fib(n-2)
function mandel(z)
c = z
maxiter = 80
for n = 1:maxiter
if abs(z) > 2
return n-1
end
z = z^2 + c
end
return maxiter
end
```

(The full code including other benchmark functions can be found here.)

According to the Julia homepage, Julia and Fortran (with `-O3`

) perform better than C (with `-O3`

) on these two functions.

How can that be?

`dp`

defined? – Vladimir F Nov 15 '13 at 13:10alwaysget the best time when you are actually running your code (not these "benchmarks"). Therefore, it's better to take an average of a set of numbers that, when combined, more accurately reflect theexpectedrun-times. – Kyle Kanos Nov 15 '13 at 14:19