# Are constant expressions calculated at compile time if they also need type conversion?

Say I have an assignment like this:

``````int i = 3.6 * 3 * 3600;
``````

Will the compiler evaluate this at compile time using floating point maths and convert the result to an integer? Will it get the right result (i.e. not convert 3.6 to an int first)?

Context: I want to count coulombs. Since 1As = 1C we can see that 1uAs = 3.6mC. I want to #define a constant for 1uAs and then further define the power consumption of a particular event as "1uAs * microampres measured * length in seconds".

I tried some code:

``````printf("%lu", (uint32_t)(3.6 * 3 * 86400UL));
``````

It prints "933119", off by one (correct answer is 933120). The compiler does indeed calculate this value at compile time, but it is slightly wrong. I am using AVR-GCC 3.4.2. Maybe I'll try on the desktop tomorrow.

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Does it matter to you if it's calculated at compile time (which it will be in all likelihood)? The second part of the question has an obvious answer: if the compiler manages to make the program not work as stipulated by the standard it's buggy. Of course it will get the right result. –  Jon Jun 19 '13 at 15:35
Okay, quick update. It does appear to both calculate at run time and calculate correctly, less a weird off-by-one bug (3.6 * 3 * 86400 == 933119 according to what comes out of printf()). –  MoJo Jun 19 '13 at 15:51
`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
Uhh??? floating point arithmetic apart, isn't 3.6C = 1mAh rather than 1uAs? 1uAs=1uC which is approximately and inexactly 1.0e-6C in floating point, no? And after 1 day, with 3 mA, the charge should be 3.6*3*24 C, and with 3 uA, 3.6*3.e-3*24? –  aka.nice Jun 19 '13 at 17:27
BTW: `%lu` could use 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

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.

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+1 You are absolutely right on the precision required by the standard. As far as a recommended expression is concerned, I'd be even more radical, and use `38880` in place of `3.6 * 3 * 3600`: this should go a long way toward eliminating the possible confusion :-) –  dasblinkenlight Jun 19 '13 at 16:34
Tangentially, behaviorally unobservable (as long as the programmer uses `FENV_ACCESS` as appropriate) optimizations do not alter a compiler's quality, but differing floating-point evaluation strategies between compile- and run-time are distasteful and definitely make a compiler inferior. The standard defines only one `FLT_EVAL_METHOD`, which should apply similarly to both compile- and run-time evaluation. Cross-compilers are particularly guilty of this. –  Pascal Cuoq Jun 19 '13 at 21:10
Thanks for the detailed answer. Interestingly the Windows calculator gets the correct result. It looks like AVR-GCC is using Intel 80 bit floats for the calculation, where as the on the AVR itself compiled code uses fixed point 32 bit numbers for both float and double. As Pascal points out this means you get a different results depending on when the calculation takes place. –  MoJo Jun 19 '13 at 22:28
@MoJo: The Windows calculator uses an arbitrary-precision engine so it will always arrive at a result equal to or more precise than any compiler will. –  Jon Jun 20 '13 at 13:59