Depending on this question Floating point division vs floating point multiplication. Division is slower than multiplication due to some reasons.

Will the compiler, usually, replace division by multiplication if it is possibe?

For example:

float a;
// During runtime a=5.4f
float b = a/10.f;

Will it be:

float a;
// During runtime a=5.4f
float b = a*0.1f;

If it is considered a compiler dependable question, I am using VS2013 default compiler. However, it would be nice if I got a generic answer (theoretical validity of this optimization)

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    Wouldn't the compiler have to do a division in order to be able to multiply by the reciprocal? – NathanOliver- Reinstate Monica Feb 19 '16 at 13:16
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    This is not case included under "if possible", this is a case where it's not possible unless a loss of accuracy is accepted. So, hopefully only when compiling with a flag that specifically allows it. – harold Feb 19 '16 at 13:16
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    goo.gl/AV8MlT Doesn't look like the compiler would optimize here. – Simon Kraemer Feb 19 '16 at 13:19
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    You can look at assembly output in MSVC++ with fp:fast option: msdn.microsoft.com/en-us/library/e7s85ffb.aspx – Serge Rogatch Feb 19 '16 at 13:29
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    I know this is for VS2013, but for the interest of GCC users: in GCC, the flag that specifically enables this particular optimization is -freciprocal-math, which is also automatically enabled when selecting either -funsafe-math-optimizations, -ffast-math or -Ofast. See gcc.gnu.org/onlinedocs/gcc-4.9.1/gcc/Optimize-Options.html – Pedro Gimeno Nov 26 '18 at 19:56

No, the compiler is not allowed to do that for the general case: the two operations could produce results that are not bit-identical due to the representation error of the reciprocal.

In your example, 0.1 does not have an exact representation as float. This causes the results of multiplication by 0.1 and division by 10 to differ:

float f = 21736517;
float a = f / 10.f;
float b = f * 0.1f;
cout << (a == b) << endl; // Prints zero


Note: As njuffa correctly notes in the comment below, there are situations when the compiler could make some optimizations for a wide set of numbers, as described in this paper. For example, multiplying or dividing by a power of two is equivalent to addition to the exponent portion of the IEEE-754 float representation.

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    Though the compiler will do the transformation if you tell it that you don't care (gcc's -ffast-math, whatever MSVC's equivalent is). – Marc Glisse Feb 19 '16 at 13:25
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    Given how imprecisely C++ defines floating point, I think you are wrong. The compiler is allowed to do that. However, most of them appear to choose not to (preferring to provide more accuracy, at the cost of speed). – Martin Bonner supports Monica Feb 19 '16 at 13:44
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    One has to seperate out cases where a floating-point division can easily be replaced with a multiplication while maintaining bit-identical results. For platforms with IEEE-754 arithmetic, this is true for constant divisors that are a power of 2, when the inverse is representable. I have seen compilers apply this optimization (e.g. division by 2.0 becomes multiply with 0.5). There is a technique applicable to a wider range of other constant divisors, as described in this paper. Sadly, I have not seen any compiler use it. – njuffa Feb 19 '16 at 17:04
  • @njuffa Thank you very much for a great comment! – dasblinkenlight Feb 19 '16 at 17:51
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    I definitely appreciate the difficulty of adopting this technique as a general purpose solution (obvious issues arise when the head and tail of the precomputed reciprocal are of opposite sign, and when the dividend is so small as to cause underflow in the tail computation of the quotient). To be clear, I am only referring to transformations that guarantee bitwise identical results and are thus "safe". There are already plenty of compiler optimization options available for people who don't mind the occasional wrong result :-) – njuffa Feb 19 '16 at 19:19

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