Why do lots of (old) programs use floor(0.5 + input) instead of round(input)?

The differences reside in the returned value giving inputs around tie-breaking I believe, such as this code:

``````int main()
{
std::cout.precision(100);

double input = std::nextafter(0.05, 0.0) / 0.1;
double x1 = floor(0.5 + input);
double x2 = round(input);

std::cout << x1 << std::endl;
std::cout << x2 << std::endl;
}
``````

which outputs:

``````1
0
``````

But they are just different results in the end, one chooses its preferred one. I see lots of "old" C/C++ programs using `floor(0.5 + input)` instead of `round(input)`.

Is there any historic reason? Cheapest on the CPU?

• std::round moves halfway cases away from zero. That's not mathematically uniform, like floor(f + .5), where the halfway cases always go towards the upper side. The reason for using the floor method is that it's required for proper rounding in the engineering world. – Michaël Roy Nov 15 '17 at 10:46
• As noted in round() for float in C++ pre-C++11 we did not have round. As I noted in my answer writing your own round correctly is a hard problem. – Shafik Yaghmour Nov 15 '17 at 13:48
• @Arne Using std::round() the distance between the rounded values of -0.5 and +0.5 is 2. using floor, it is 1. Only happens when the two values have opposite signs. Very irritating when trying to draw straight lines, or makes you pick the wrong texture pixel. – Michaël Roy Nov 15 '17 at 14:31
• Some programming languages and environments (including .NET) use a deceiving thing called Banker's Rounding, in which x.5 rounds to the nearest EVEN number. So 0.5 rounds to 0 while 1.5 rounds to 2. You can imagine the confusion this can cause when debugging. I think the solution to this evil 'feature' is to not have a .Round() function at all, and instead have .RoundBankers(), .RoundHalfUp(), .RoundHalfDown(), etc (or .BankersRound(), etc but intellisense would work better with .RoundBankers()). At least that way you would be forced to know what to expect. – user3685427 Nov 15 '17 at 19:33
• @user3685427: Banker's Rounding is necessary in financial and statistical applications that require elimination of the subtle and systemic upward bias introduced by away from zero rounding. It is almost impossible to implement without actual knowledge of the hardware floating point implementation, hence it's selection as the default in C#. – Pieter Geerkens Nov 16 '17 at 10:54

`std::round` is introduced in C++11. Before that, only `std::floor` was available so programmers were using it.

• Nothing. But its older than C++11. I thought logical that C++ got it before 11. That's all ;) – markzzz Nov 15 '17 at 8:44
• @markzzz - The C++ standard library doesn't automatically inherit C's standard library. There's careful picking and choosing going on. It took them 12 years to sync to C99. – StoryTeller Nov 15 '17 at 8:45
• @haccks: Indeed. IMHO C was ahead of C++ in terms of mathematical functions up to C++11. – Bathsheba Nov 15 '17 at 8:55
• Important to note that the method being used breaks for some inputs and also that C++11 relies on C99 while C++03 relied on C90 which kind of goes to @markzzz point. – Shafik Yaghmour Nov 15 '17 at 14:03
• @markzzz: Your remark is spot on (despite critics). The thing is, there was a long gap without C++ standards, the first C++ standard was C++98 and the first major revision was C++11. There was a minor update, C++03, but as the Wikipedia page notes it was mostly a "bug fix" release. Therefore, C++11 was the first opportunity to catch up to the C standard library, after 13 years of iatus. – Matthieu M. Nov 16 '17 at 11:49

There is no historic reason whatsoever. This kind of deviance has been around since year dot. Folk do this when they are feeling very, very naughty. It's a serious abuse of floating point arithmetic, and many experienced professional programmers fall for it. Even the Java bods did up to version 1.7. Funny guys.

My conjecture is that a decent out-of-the-box German rounding function was not formally available until C++11 (despite C getting theirs in C99), but that really is no excuse for adopting the so-called alternative.

Here's the thing: `floor(0.5 + input)` does not always recover the same result as the corresponding `std::round` call!

The reason is quite subtle: the cutoff point for a German rounding, `a.5` for an integer `a` is, by a coincidental property of the universe, a dyadic rational. As this can be represented exactly in an IEEE754 floating point up to the 52nd power of 2, and thereafter rounding is a no-op anyway, `std::round` always works properly. For other floating point schemes, consult the documentation.

But adding `0.5` to a `double` can introduce imprecision causing a slight under or overshoot for some values. If you think about it, adding two `double` values together - that are the inception of unwitting denary conversions - and applying a function that is a very strong function of the input (such as a rounding function), is bound to end in tears.

Don't do it.

• Comments are not for extended discussion; this conversation has been moved to chat. – Andy Nov 16 '17 at 3:52
• `nearbyint()` is usually a better choice than `round()`, because `nearbyint` uses the current rounding mode instead of the funky tiebreak away from zero of `round()` (which x86 doesn't even have hardware support for, although ARM does). Both were added to C++ in C++11. – Peter Cordes Nov 17 '17 at 3:26

I think this is where you err:

But they are just different results in the end, one chooses its preferred one. I see lots of "old" C/C++ programs using floor(0.5 + input) instead of round(input).

That is not the case. You must select the right rounding scheme for the domain. In a financial application, you'll round using banker's rules (not using float by the way). When sampling, however, rounding up using `static_cast<int>(floor(f + .5))` yields less sampling noise, this increments the dynamic range. When aligning pixels, i.e. converting a position to screen coordinates, using any other rounding method will yield holes, gaps, and other artifacts.

• "this increments the dynamic range" - looks like meaningless extra text; copy-pasted from somewhere by mistake? Might want to delete it. – anatolyg Nov 16 '17 at 22:46
• No. Decreasing the sampling noise decreases the noise floor and that does indeed increase the dynamic range. – Michaël Roy Nov 17 '17 at 2:55

A simple reason could be that there are different methods of rounding numbers so unless you knew the method used, you could different results.

With floor(), you can be consistent with the results. If the float is .5 or greater, adding it will bump up to the next int. But .49999 will just drop the decimal.

• +1 This answer's point is made by the very comments on the question, wherein there is disagreement about what `round()` does. – Loduwijk Nov 15 '17 at 20:34
• @Aaron The answer is wrong about what `floor(x + 0.5)` does though. – EOF Nov 15 '17 at 20:36
• Oh, hah! Good catch then. That is ironic. "Use the better known X since we are not in agreement or full knowledge about Y." So what do you do when the same applies to X? – Loduwijk Nov 15 '17 at 21:35
• @Aaron Easy. You do the only sane thing and use `nearbyint(x)`, which uses sane (to nearest even) rounding, provided you haven't messed with the floating point environment. – EOF Nov 15 '17 at 23:08
• @EOF : Your rounding choice is not sane. A rounding function that does not have period 1 in the nonlinear component is insane. – Eric Towers Nov 16 '17 at 17:51

Many programmers adapt idioms that they learned when programming with other languages. Not all languages have a `round()` function, and in those languages it's normal to use `floor(x + 0.5)` as a substitute. When these programmers start using C++, they don't always realize that there's a built-in `round()`, they continue to use the style they're used to.

In other words, just because you see lots of code that does something, it doesn't mean there's a good reason to do it. You can find examples of this in every programming language. Remember Sturgeon's Law:

ninety percent of everything is crap