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.

If `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);
```

or:

```
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.

`3.6 * 3 * 86400 == 933120.000000000116415321826934814453125`

with IEEE754`double`

s. Are you perhaps using`3.6f`

(the product is`933119.9375`

for IEEE754`float`

s)? Otherwise, it could be computed at greater precision than`double`

has and that may again produce a smaller result. – Daniel Fischer Jun 19 '13 at 15:59`%lu`

coulduse an integer of greater size than`uint32_t`

. So recommend either`printf("%lu", (unsigned long)(3.6 ...`

or`printf("%" PRIu32, (uint32_t)(3.6 ...`

– chux Jun 19 '13 at 18:37