Minimum and maximum of signed zero

I am concerned about the following cases

``````min(-0.0,0.0)
max(-0.0,0.0)
minmag(-x,x)
maxmag(-x,x)
``````

According to Wikipedia IEEE 754-2008 says in regards to min and max

The min and max operations are defined but leave some leeway for the case where the inputs are equal in value but differ in representation. In particular:

min(+0,−0) or min(−0,+0) must produce something with a value of zero but may always return the first argument.

I did some tests compare `fmin`, `fmax`, min and max as defined below

``````#define max(a,b) \
({ __typeof__ (a) _a = (a); \
__typeof__ (b) _b = (b); \
_a > _b ? _a : _b; })
#define min(a,b) \
({ __typeof__ (a) _a = (a); \
__typeof__ (b) _b = (b); \
_a < _b ? _a : _b; })
``````

and `_mm_min_ps` and `_mm_max_ps` which call the SSE `minps` and `maxps` instruction.

Here are the results (the code I used to test this is posted below)

``````fmin(-0.0,0.0)       = -0.0
fmax(-0.0,0.0)       =  0.0
min(-0.0,0.0)        =  0.0
max(-0.0,0.0)        =  0.0
_mm_min_ps(-0.0,0.0) =  0.0
_mm_max_ps(-0.0,0.0) = -0.0
``````

As you can see each case returns different results. So my main question is what does the C and C++ standard libraries say? Does `fmin(-0.0,0.0)` have to equal `-0.0` and `fmax(-0.0,0.0)` have to equal `0.0` or are different implementations allowed to define it differently? If it's implementation defined does this mean that to insure the code is compatible with different implementation of the C standard library (.e.g from different compilers) that checks must be done to determine how they implement min and max?

What about `minmag(-x,x)` and `maxmag(-x,x)`? These are both defined in IEEE 754-2008. Are these implementation defined at least in IEEE 754-2008? I infer from Wikepdia's comment on min and max that these are implementation defined. But the C standard library does not define these functions as far as I know. In OpenCL these functions are defined as

maxmag Returns x if | x| > |y|, or y if |y| > |x|, otherwise fmax(x, y).

minmag Returns x if |x| < |y|, or y if |y| < |x|, otherwise fmin(x, y).

The x86 instruction set has no minmag and maxmag instructions so I had to implement them. But in my case I need performance and creating a branch for the case when the magnitudes are equal is not efficient.

The Itaninum instruction set has minmag and maxmag instructions (`famin` and `famax`) and in this case as far as I can tell (from reading) in this case it returns the second argument. That's not what `minps` and `maxps` appear to be doing though. It's strange that `_mm_min_ps(-0.0,0.0) = 0.0` and `_mm_max_ps(-0.0,0.0) = -0.0`. I would have expected them to either return the first argument in both cases or the second. Why are the `minps` and `maxps` instructions defined this way?

``````#include <stdio.h>
#include <x86intrin.h>
#include <math.h>

#define max(a,b) \
({ __typeof__ (a) _a = (a); \
__typeof__ (b) _b = (b); \
_a > _b ? _a : _b; })

#define min(a,b) \
({ __typeof__ (a) _a = (a); \
__typeof__ (b) _b = (b); \
_a < _b ? _a : _b; })

int main(void) {
float a[4] = {-0.0, -1.0, -2.0, -3.0};
float b[4] = {0.0, 1.0, 2.0, 3.0};
__m128 a4 = _mm_load_ps(a);
__m128 b4 = _mm_load_ps(b);
__m128 c4 = _mm_min_ps(a4,b4);
__m128 d4 = _mm_max_ps(a4,b4);
{ float c[4]; _mm_store_ps(c,c4); printf("%f %f %f %f\n", c[0], c[1], c[2], c[3]); }
{ float c[4]; _mm_store_ps(c,d4); printf("%f %f %f %f\n", c[0], c[1], c[2], c[3]); }

printf("%f %f %f %f\n", fmin(a[0],b[0]), fmin(a[1],b[1]), fmin(a[2],b[2]), fmin(a[3],b[3]));
printf("%f %f %f %f\n", fmax(a[0],b[0]), fmax(a[1],b[1]), fmax(a[2],b[2]), fmax(a[3],b[3]));

printf("%f %f %f %f\n", min(a[0],b[0]), min(a[1],b[1]), min(a[2],b[2]), min(a[3],b[3]));
printf("%f %f %f %f\n", max(a[0],b[0]), max(a[1],b[1]), max(a[2],b[2]), max(a[3],b[3]));
}
//_mm_min_ps: 0.000000, -1.000000, -2.000000, -3.000000
//_mm_max_ps: -0.000000, 1.000000, 2.000000, 3.000000
//fmin: -0.000000, -1.000000, -2.000000, -3.000000
//fmax: 0.000000, 1.000000, 2.000000, 3.000000
//min: 0.000000, -1.000000, -2.000000, -3.000000
//max: 0.000000, 1.000000, 2.000000, 3.000000
``````

Edit:

In regards to C++ I tested `std::min(-0.0,0.0)` and `std::max(-0.0,0.0)` and the both return `-0.0`. Which shows that that `std::min` is not the same as `fmin` and `std::max` is not the same as `fmax`.

• Don't you think your question deserves a better title? – Sourav Ghosh Jun 18 '15 at 11:22
• I'm not sure this question belongs here actually. It is more a discussion that a particular question. And the answer why CPU instructions have been implemented either way is deefinitively better placed at the developer - Intel. There are actually three different questions included. Would that not better be split? – too honest for this site Jun 18 '15 at 12:12
• While its an interesting question, I wonder in what situation it would actually matter whether a function returns +0.0 or -0.0. – MikeMB Jun 18 '15 at 12:24
• @Zboson: Not sure the +/- 0 case matters nearly as much as the +/- 3 case. Your results are obviously garbage if you compute 3 + (-3) = 6. (I'm not sure what relevance the sign bit of nothing has in double-double computation.) – tmyklebu Jun 18 '15 at 13:26
• @MikeMB: Kahan has an interesting paper/rant called "Branch Cuts for Complex Elementary Functions, or Much Ado About Nothing's Sign Bit." One point it makes is that, since the imaginary part of a real written as a complex number can have either sign bit, there need not be any complex number for which `sqrt` isn't defined; sqrt(-1.0 + 0.0i) can be +i and sqrt(-1.0 - 0.0i) can be -i. This is actually how C99's `csqrt` works. Another point the paper makes is that this "usually makes programs work better." – tmyklebu Jun 18 '15 at 13:35

2 Answers

Why not read the standard yourself? The Wikipedia article for IEEE contains links to the standard.

Note: The C standard document is not available freely. But the final draft is (that's what I linked, search to find the pdf version). However, I've not seen the final document being cited here and AFAIK there had mostly been some typos corrected; nothing changed. IEEE is, however, available for free.

Note that a compiler need not stick to the standards (some embedded compilers/versions for instance do not implement IEEE-conforming floating point values, but are still C-conforming - just read the standard for details). So see the compiler documentation to see the compatibility. MS-VC for instance is not even compatible to C99 (and will never ben), while gcc and clang/llvm are (mostly) compatible to C11 in the current versions (gcc since 4.9.2 at least, in parts since 4.7).

In general, when using MS-VC, check if it actually does support that all standard features used. It is actually not fully compliant to the current standard, nor C99.

• I just search through the draft it and a footnote says "Ideally, fmax would be sensitive to the sign of zero, for example fmax(-0.0, +0.0) would return +0; however, implementation in software might be impractical." – Z boson Jun 18 '15 at 11:44
• Are `fmin` and `fmax` defined in C++? – Z boson Jun 18 '15 at 11:44
• This is for C. C++ is a different language. Please find the answer yourself or open a new question. (please serach yourself first) – too honest for this site Jun 18 '15 at 11:45
• I think many people are familiar with both languages and they overlap far more than they disagree. Since they agree more then they disagree isn't it a bit pedantic to say they are different when in most cases they the same. Doing a bit of search shows `fmin` and `fmax` are define exactly the same in both languages but I'm not expert. – Z boson Jun 18 '15 at 11:53
• I will not discuss this issue here. Just note that they differ in much more places some "experts" might think (according to the C++ questions with C tag) - and, yes, I do know both. Here, the differerentiation is well accepted and enforced- unless you can prove the opposite. Note: just that you can program C-like in C++ does not make them "almost" identical. That would have to be bijective for most features. So, leave it at that! – too honest for this site Jun 18 '15 at 12:01

The fundamental issue in this case is the actual underlying mathematics, ignoring representational issues. There are several implications in your question that I believe are erroneous. -0.0 < 0.0 is false. -0.0 is a negative number is false. 0.0 is a positive number is false. In fact, there's no such thing as -0.0, though there is an IEEE 754 representation of zero with a sign bit set.

In addition, the behavior of min/max functions is only a small slice of legal floating-point operations that can yield zeros with different sign bits. Since floating point units are free to return (-)0.0 for expressions like -7 - -7, you'd also have to figure out what to do with that. I'd also like to point out that |0.0| could in fact return 0.0 with the sign bit set, since -0.0 is an absolute value of 0.0. Put simply, as far as mathematics is concerned 0.0 is -0.0. They are the same thing.

The only way that you can test for 0.0 with a set sign bit is to abandon mathematical expressions and instead examine the binary representation of such values. But what's the point of that? There's only one legitimate case I can think of: the generation of binary data from two different machines that are required to be bit-for-bit identical. In this case, you'll need to also worry about signaling and quiet NaN values, since there are very many more aliases of these values (10^22-1 SNaN's and 10^22 QNaN's for single-precision floats, and about 10^51 values of each for double-precision).

In these situations where binary representation is critical (it's absolutely NOT for mathematical computation), then you'll have to write code to condition all floats on write (zeros, quiet NaN's, and signaling NaN's).

For any computational purpose, it's useless to worry about whether the sign bit is set or clear when the value is zero.

• You're forgetting operations that are mathematically undefined on zero, but have separate limits when approaching zero from the positive end and when approaching it from the negative end. This applies to some of the standard math library functions, and to a lesser extent to division: in floating-point arithmetic, division by zero produces infinity, with a sign depending on that of the zero. – user743382 Jun 30 '15 at 19:14
• Agree, "-0.0 is a negative number is false" is supported by `sqrt(-0.0)` does not cause an exception, per IEEE 754. I think it even returns `-0.0`. (zero with sign bit set.). Concerning "computational purpose, it's useless to worry about whether the sign bit is set or clear", consider What operations and functions on +0.0 and -0.0 give different arithmetic results? – chux Jun 30 '15 at 20:34
• @hvd: As far as I know, division by zero is undefined behavior in c and c++. – MikeMB Jul 1 '15 at 8:46
• @MikeMB Yes and no. It's explicitly undefined for both integer and floating point division in the mandatory parts of the specification, but it gets defined for floating point division in an optional part of the specification, and that optional part of the specification has a feature detection macro. Because of that, it's possible for a strictly conforming program that uses that feature detection macro to divide by zero. – user743382 Jul 1 '15 at 9:09
• @hvd: Didn't know that, thanks! – MikeMB Jul 1 '15 at 9:11