The C standard does not guarantee what the result of computing
3.6 * 3 * 86400UL is, either at compile time or at run time, largely because it allows the C implementation a choice of what precision to use. The standard allows implementations to perform arithmetic with more precision than the nominal type requires.
3.6 * 3 * 86400UL is computed by converting
3.6 to the Intel 80-bit floating-point format and performing the remaining arithmetic in that format, the result is 933119.99999999999994315658113919198513031005859375). If it is computed by using the 64-bit floating-point format, the result is 933120.000000000116415321826934814453125.
The difference stems from the fact that 3.6 is not exactly representable in binary floating point. The conversion from a numeral in the source code to a representable number necessarily rounds the value. A good C implementation rounds to the nearest representable value. However, that value may be greater or less than the exact mathematical value. In the case of 80-bit floating-point, the nearest representable value is lower. In the case of 64-bit, it is higher.
Therefore, your source code does not specify operations well enough to control the final value. You can likely obtain the result you desire by using rounding, with either:
int i = round(3.6 * 3 * 3600);
int i = 3.6 * 3 * 3600 + .5;
The latter is more likely to be fully computed at compile time, although the behavior depends on the specific C implementation. A C implementation is free to compute as much of your program at compile time as it wishes. There is no definition of “compile time” in the C standard. A compiler is permitted to evaluate the result of calling defined library routines such as
round or even to execute calls to your own functions and replace the calls with the results (if it can establish that this produces equivalent results to executing the program). So whether a compiler does any of this is a question of compiler quality.