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my code is quite simple

double d = 405, g = 9.8, v = 63;
double r = d * g / (v * v);

and here is my result

  • g++-mingw32-v4.8.1: LE (the result is EQ indeed)
  • g++ on ubuntu : GT ( this result comes from my friend, just do not have a linux at hand)
  • VC++ 11 : GT
  • C# (.Net 4.5) : GT
  • Python v2.7.3 :GT (this also comes from my friend)
  • Haskell (GHCi v7.6.3) : GT

g++-mingw, vc++, c#, haskell are all running on my machine with an i7-2630QM

The Python-win32 version comes from my friend, he also gets an LE from his g++-mingw-3.4.2.

And the ubuntu version comes from another friend...

Only g++ gives me LE, and the others are all GT.

I just want to know which one is wrong, g++ or the rest.

Or what SHOULD it be, GT or LE, in IEEE 754?

share|improve this question
If this is indeed your code (and not a typo) why do you assign a value to r1 but test the value of r? – Floris Sep 17 '13 at 3:15
Sorry, it's a typo. Fixed, thanks. – sray Sep 17 '13 at 3:17
In fact, it should be neither. 405 * 9.8 is exactly 3969 or 63*63. The fact that conversion to double precision is handled differently in different languages (9.8 doesn't have an exact representation in double) is just a fact of life. If you used d=4050, g = 98, v = 630; you would see they were equal. – Floris Sep 17 '13 at 3:18
Actual answer is (1 > 1 == false) so it looks like g++ is the only one the got it correct :-) (by accident). See: docs.oracle.com/cd/E19957-01/806-3568/ncg_goldberg.html – Loki Astari Sep 17 '13 at 3:26
That suggests that the conversion of 9.8 to floating point and the following multiplication may be being done in Intel 80-bit extended precision. If the 80-bit result of either the multiplication or of the division were rounded to nearest double the division result would be exactly 1.0, and the comparison result would be EQ. – Patricia Shanahan Sep 17 '13 at 16:37
up vote 4 down vote accepted

The IEEE 754 64-bit binary result is GT.

The two exactly representable values bracketing 9.8 are:


The second one is closer to 9.8, so it should be chosen in the normal rounding mode. It is slightly larger than 9.8, resulting in a product that is slightly larger than would have been produced in real number arithmetic, 3969.00000000000045474735088646411895751953125. The conversion of v to double is exact, as is the v*v multiplication. The result is division of a number slightly greater than 3969 by 3969. The rounded result is 1.0000000000000002220446049250313080847263336181640625

share|improve this answer
In addition to the (confirmed here) information that the strict IEEE 754 binary64 interpretation of the program prints GT, since the question is tagged g++, it can be suggested that the OP look at GCC's -msse2 -mfpmath=sse options, which should make GCC generate a binary that computes this. – Pascal Cuoq Sep 17 '13 at 8:55
Excellent answer! Do you have any insights into the algorithm used for converting a decimal to binary? Obviously this is not implemented in the same way in the different languages? Is there a bug report here? – Floris Sep 17 '13 at 11:23
@Floris Whether there is a bug report depends on the language and compiler specifications. Some languages allow more latitude than others. – Patricia Shanahan Sep 17 '13 at 13:10
IEEE 754 does not specify a binding from high-level languages to IEEE 754 operations, so it is imprecise to speak of an “IEEE 754 64-bit binary result” for this code. At most, there is a result that is obtained if the indicated operations are all performed with IEEE 754 64-bit binary operations. The compilers that do not provide this result do not violate the C++ standard (because it grants them leeway about floating-point evaluation) or the IEEE 754 standard (because it does not apply). – Eric Postpischil Sep 17 '13 at 13:55
@Floris Regarding the algorithms used to convert decimal to binary in different languages, check out my blog "Exploring Binary", and these articles in particular: exploringbinary.com/how-strtod-works-and-sometimes-doesnt , exploringbinary.com/… , exploringbinary.com/… – Rick Regan Sep 18 '13 at 13:28

The difference likely occurs when d * g is evaluated, because the mathematical result of that product must be rounded upward to produce a value representable in double, but the long double result is more accurate.

Most compilers convert 405 and 63 to double exactly and convert 9.8 to 9.800000000000000710542735760100185871124267578125, although the C++ standard gives them some leeway. The evaluation of v * v is also generally exact, since the mathematical result is exactly representable.

Commonly, on Intel processors, compilers evaluate d * g in one of two ways: Using double arithmetic or using long double with Intel’s 80-bit floating-point format. When evaluated with double, 405•9.800000000000000710542735760100185871124267578125 produces 3969.00000000000045474735088646411895751953125, and dividing this by 3969 yields a number slightly greater than one.

When evaluated with long double, the product is 3969.000000000000287769807982840575277805328369140625. The product, although greater than 3969, is slightly less, and dividing it by 3969 using long double arithmetic produces 1.000000000000000072533125339280246635098592378199100494384765625. When this value is assigned to r, the compiler is required to convert it to double. (Extra precision may be used only in intermediate expressions, not in assignments or casts.) This value is sufficient close to one that rounding it to double produces one.

You can mitigate some (but not all) of the variation between compilers by using casts or assignments with each individual operation:

double t0 = d * g;
double t1 = v * v;
double r = t0/t1;
share|improve this answer
A compiler that implements d * g as long double multiplication is as likely as not to interpret 9.8 as 9.8L, or approximately 9.80000000000000000017347234759768071. It has the leeway of doing the former without doing the latter, but if its excuse is that it defines is_iec559 as true and FLT_EVAL_METHOD as 2, it has to use a long double conversion of 9.8. – Pascal Cuoq Sep 17 '13 at 17:15
@PascalCuoq: The license of the compiler to use extended precision is for intermediate expressions, not for assignments, casts, or, as I recall, conversion of floating-point constants in source text to floating-point. – Eric Postpischil Sep 17 '13 at 17:18
open-std.org/jtc1/sc22/wg21/docs/papers/2012/n3376.pdf 18.3.3:4 says “The contents are the same as the Standard C library header <float.h>.” C99's says for FLT_EVAL_METHOD=2: “evaluate all operations and constants to the range and precision of the long double type.” In addition, interpreting 9.8 as 9.8L is the interpretation of the standard that Joseph S. Myers chose when he implemented a proper FLT_EVAL_METHOD=2 mode in GCC (which should be available in GCC 2.7 and above with -std=c99) – Pascal Cuoq Sep 17 '13 at 17:23
@PascalCuoq: Regardless, the code in the question initializes a double with 9.8. The same value results whether 9.8 is converted to double or first converted to long double and then converted to double. – Eric Postpischil Sep 17 '13 at 17:27

To answer your question: since the expression ought to evaluate to "equal", the test r>1.0 should be false, and the result printed should be "LE".

In reality you are running into the problem that a number like 9.8 cannot be represented exactly as a floating point number (there a hundreds of good links on the web to explain why this is so). If you need exact math, you have to use integers. Or bigDecimal. Or some such thing.

share|improve this answer
thanks, i know this problem. i have edited my question. i just want to know follow IEEE 754, which result is correct – sray Sep 17 '13 at 3:32
Mostly it is the hardware implementation rather than the language that is the thing that will decide the result. Am I right in thinking that these things were run on different machines - with possibly different processors? I doubt that the language has anything to do with it. – Floris Sep 17 '13 at 3:41
Question updated. Most cases are run on my laptop, I guess it is not cpu's problem. – sray Sep 17 '13 at 3:50
@FLoris Processors that provide floating-point instructions at all have been providing floating-point behaving according the IEEE 754 standard for eight years or so. Programming languages, not hardware, are indeed the last killjoys separating us from reproducible floating-point bliss (and after them, math libraries, but the program in the question does not use any library function). – Pascal Cuoq Sep 17 '13 at 9:02

The conversion from decimal fraction to a binary fraction is precise only if the decimal fraction can be summed up by binary fractions like 0.5, 0.25, ..., etc.

The number 9.8 in your example contains the fraction 0.8, which can not be represented as an exact fraction using binary number system. Thus different compilers will give you different results depending on the precision to represent fractional numbers.

Run your program using the number 9.75, then all the compilers will give you the same result, because

0.75 = 0.25 + 0.125 = 2-2 + 2-3

So the number 9.75 can be represented exactly by using binary fractions.

share|improve this answer
This is not a good explanation. All the compilers that the OP tried use IEEE754's binary64 format for the type double. – Pascal Cuoq Sep 17 '13 at 8:50

I tested the code, this should return GT.

int main() {
    double d = 405.0f, g = 9.8f, v = 63.0f;
    double r = d * g / (v * v);

GCC compiler sees 405 as int, so "double d = 405" is actually "double d = (double) 405".

share|improve this answer
This answer is not helpful. 9.8f is different from 9.8. – Pascal Cuoq Sep 17 '13 at 8:49
what do you mean by "different"? – mugiseyebrows Sep 17 '13 at 9:01
“different” as in “if you replace one by the other in a program the program no longer computes the same thing”, or as in 9.8f != 9.8, or as in question 1 in blog.frama-c.com/index.php?post/2011/11/08/Floating-point-quiz – Pascal Cuoq Sep 17 '13 at 9:06
In this particular case, the closest float, 9.80000019073486328125, does round in the same direction as double, although it is a different value from the closest double. In other cases, they could round in different directions, which would change the answer for the code fragment. – Patricia Shanahan Sep 17 '13 at 11:01

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