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If I multiply a float and and integer like below, why does all multiplications lead to a differnt result? My expectation was a consistent result. I thought in both cases the int value gets implicitly converted to a float before multiplication. But there seems to be a difference. What is the reason for this differnt handling?

int multiply(float val, int multiplier)
{
    return val * multiplier;
}

int multiply2(float val, int multiplier)
{
    return float(val * multiplier);
}

float val = 1.3f;

int result0 = val * int(10); // 12
int result1 = 1.3f * int(10); // 13
int result3 = multiply(1.3f, 10); //12 
int result4 = multiply2(1.3f, 10); // 13

Thank you Thorsten

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Is this the real code? I get the same results for both and I don't see why it would be different. – Joseph Mansfield Dec 23 '13 at 13:40
2  
The second expression can be evaluated at compile time - what compiler are you using? Look at the byte code it produces. – Floris Dec 23 '13 at 13:40
    
Tried with g++ 4.7.3 on an Ubuntu: both multiplications lead to 13 – gturri Dec 23 '13 at 13:43
    
The compiler is the build in from visual studio 2010. And yes, it is real code =) – Thorsten Dec 23 '13 at 13:52
1  
@Floris: You are correct. The disassembly reveals that for result1 no multiplication is executed. Only the compile time const value is taken. – Thorsten Dec 23 '13 at 14:09

What likely happens for you is:

Assuming IEEE or similar floats, 1.3 can not be represented, and likely is something like 1.299999 which multiplied by 10 is 12.99999 which then truncated to int is 12.

However 1.3 * 10 can be evaluated at compile time, leading most likely to an accurate representation of 13.

Depending on how your code is actually structured, what compiler is used, and which settings it is used with, it could evaluate either one to 12 or 13, depending on whether it does this at run, or compile time.

For completeness, with the following code, I could reproduce it:

extern int result0;
extern int result1;

float val = 1.3f;

void foo( )
{   
 result0 = val * int(10); // 12
 result1 = 1.3f * int(10); // 13
}
share|improve this answer
    
Is the compiler allowed to use a different representation for compile-time computation? – Joseph Mansfield Dec 23 '13 at 13:45
    
@sftrabbit my guess is that is implementation defined – Tim Seguine Dec 23 '13 at 13:47
    
@sftrabbit: I don't have a standard quote at hand, but afaik it is. This is also in the area of the reason for templates not allowing non-type float parameters. – PlasmaHH Dec 23 '13 at 13:48
10  
@sftrabbit It's even allowed to use different representations dynamically. §5/11: "The values of the floating operands and the results of floating expressions may be represented in greater precision and range than that required by the type; the types are not changed thereby". And it's not implementation defined, but unspecified. (E.i. the implementation doesn't have to document what it does, or even do the same thing twice in a row.) In fact, it could very easily change depending on the level of optimization. – James Kanze Dec 23 '13 at 13:53
    
@JamesKanze I think this is constrained by …::is_iec559 and FLT_EVAL_METHOD. A compiler that defines the former to true and the latter to 0 should not do anything of the sort. A compiler that defines FLT_EVAL_METHOD to 1 or 2 should generate programs that compute according to the respective models. – Pascal Cuoq Dec 24 '13 at 0:01

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