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If foo is of float type, is the following expression valid/recommended?

(0.0f == foo * float(0))

Will it have the expected (mathematical) value regardless of foo's value?

Does the C++ standard defines the behavior or is it implementation specific?

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Try to debug it. – rursw1 Oct 12 '10 at 13:24
@rursw1 More interested if there's a guarantee from standard – CsTamas Oct 12 '10 at 13:28
@rursw1: That's not gonna work. – John Dibling Oct 12 '10 at 13:47
Assuming foo is a number (Note: Floats allow for NaN and infinity). Not sure if infinity * 0 is 0 in the mathematical sense: 5/0 = 5/0 => 5/0*0 = 5? – Loki Astari Oct 12 '10 at 14:30
@Martin: Mathematically, infinity*0 is undefined. In IEEE arithmetic, it's NaN. – Mike Seymour Oct 12 '10 at 15:34

Well, first off it isn't really a matter of the C++ standard. Rather what is at issue is your floating-point model standard (most likely IEEE).

For IEEE floats, that is probably safe, as float(0) should result in the same number as 0.0f, and that multiplied by any other number should also be 0.0f.

What isn't really safe is doing other floating point ops (eg: adds and subtracts with non-whole numbers) and checking them against 0.0f.

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Multiplying any finite IEEE value by zero will give zero. If foo is infinity or NaN, then the multiplication result is NaN, and the comparison result is false. – Mike Seymour Oct 12 '10 at 13:41
@Mike Seymour - Good point. Perhaps that line was meant to be a check that foo is a valid float value. – T.E.D. Oct 12 '10 at 14:53

AFAIK, It won't necessarily, it could also end up very close to 0.

It is generally best to compare against an epsilon. I use a function like this for doing such comparisons:

float EpsilonEqual( float a, float b, float epsilon )
    return fabsf( a - b ) < epsilon;
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@Armen: You are quite right its fabsf :) – Goz Oct 12 '10 at 13:32
IEEE 754 mandates that -0.0f == +0.0f, even though the bit values are different. – Michael Borgwardt Oct 12 '10 at 13:35
@Michael: Fair enough. Doesn't detract from the point though. I'll remove the reference however. – Goz Oct 12 '10 at 13:48

NaNs and Infinites can screw up such comparisions, as others have already mentioned.

However, there is further pitfall: in C++ you can not rely on a compile time expression of float type, comparing equal to the same expression evaluated at run time.

The reason for that is that C++ allows extended precision for fp computations, in any willy-nilly way. Example:

#include <iostream>

// This provides sufficent obfuscation so that g++ doesn't just inline results.
bool obfuscatedTrue() { return true; }

int main()
    using namespace std;

    double const    a   = (obfuscatedTrue()? 3.0 : 0.3);
    double const    b   = (obfuscatedTrue()? 7.0 : 0.7);
    double const    c   = a/b;

    cout << (c == a/b? "OK." : "\"Wrong\" comparision result.") << endl;

Results with one particular compiler:

C:\test> g++ --version | find "++"
g++ (TDM-2 mingw32) 4.4.1

C:\test> g++ fp_comparision_problem.cpp & a
"Wrong" comparision result.

C:\test> g++ -O fp_comparision_problem.cpp & a

C:\test> _

Cheers & hth.,

– Alf

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At what higher precision do you fear that the result of foo * float(0) might be different from the result of the multiplication done at the precision of the type? – Pascal Cuoq Jan 31 '14 at 18:28
Is there any usefulness to allowing compilers to produce results other than those which would be produced by coercing the operands of comparison operators to their compile-time types (e.g. allowing someFloat == otherFloat / 3.0f to be evaluated as though it were (double)someFloat == (double)otherFloat / 3.0)? It seems to me that in the vast majority of cases where the latter is "faster", it would also yield useless results. – supercat Feb 5 '14 at 18:59
@PascalCuoq: the asnwer contains a complete exqample, with output. and so the idea that this is something that I "fear" that "might" happen, appears to indicate that you have not read the answer. hence, i suggest that you do. – Cheers and hth. - Alf Feb 5 '14 at 19:57
@supercat: I only know of one way it is useful, namely an architecture where floating point operations are computed asynchronously and at higher precision than the platform's common double type. That might sound esoteric, but it's how ordinary PCs work. They were originally based on a trio of "co-processors": the 8086 main processor, or its 8088 incarnation with 8-bit multiplexed bus; the 8087 "math" co-processor, dealing asynchronously with floating point operations; and the 8089 "i/o" co-processor, which AFAIK were never used. The physical packaging has changed, but not the logical design. – Cheers and hth. - Alf Feb 5 '14 at 20:01
@Cheersandhth.-Alf: I certainly recognize that allowing such freedom may make code "faster"; I fail to see, though, how the expression (phaseOfMoon() ? (float)f1 == (float)(f2 / 3.0f) ? (double)f1 == (double)(f2 / 3.0)) could be useful for much of anything even if it could be computed a thousand times as fast as (float)f1 == (float)(f2 / 3.0f). – supercat Feb 5 '14 at 20:16

With that particular statement, you can be pretty sure the result will be 0 and the comparison be true - I don't think the C++ standard actually prescribes it, but any reasonable implementation of floating point types will have 0 work like that.

However, for most other calculations, the result cannot be expected to be exactly equal to a literal of the mathematically correct result:

Why don’t my numbers, like 0.1 + 0.2 add up to a nice round 0.3, and instead I get a weird result like 0.30000000000000004?

Because internally, computers use a format (binary floating-point) that cannot accurately represent a number like 0.1, 0.2 or 0.3 at all.

When the code is compiled or interpreted, your “0.1” is already rounded to the nearest number in that format, which results in a small rounding error even before the calculation happens.

Read The Floating-Point Guide for detailed explanations and how to do comparisons with expected values correctly.

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I just read this article in msdn about the /fp option in VisualStudio link text

Expression optimizations that are invalid for special values (NaN, +infinity, -infinity, +0, -0) will not be allowed. The optimizations x-x => 0, x*0 => 0, x-0 => x, x+0 => x, and 0-x => -x are all invalid for various reasons (see IEEE 754 and the C99 standard).

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I'm guessing that the comment here is only referring to the fact that x*0 is NaN if x is NaN. – hobbs Oct 12 '10 at 13:52

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