The first time around, log(n)/log(2)
is computed and the result is very close to 6 but slightly less. This is just how floating point computation works: neither log(64) nor log(2) have an infinitely precise representation in binary floating point, so you can expect the result of dividing one by the other to be slightly off from the true mathematical value. Depending on the implementation you can expect to get 5 or 6.
In the second computation:
n = 64;
c = (log(n) / log(2));
The value assigned to c
can be inferred to be a compile-time constant and can be computed by the compiler. The compiler does the computation in a different environment than the program while it runs, so you can expect to get slightly different results from computations performed at compile-time and at runtime.
For example, a compiler generating code for x86 may choose to use x87 floating point instructions that use 80bit floating point arithmetic, while the compiler itself uses standard 64bit floating point arithmetic to compute compile-time constants.
Check the assembler output from your compiler to confirm this. Using GCC 4.8 I get 6 from both computations.
scanf
line:if (n == 64) { cout << "64 as expected!"; } else { cout << "Wtf?! " << n; }
cmath
instead ofmath.h
andcin
instead ofscanf
if you are using C++.scanf("%d", &n)
even succeed?