I have a question about std::round with signature: double round (double x);

Let's say I have this code:

int i = std::round(0.9);

In this case, std::round should return 1.00000000000, but that's uncomfortably close to 0.9999999999999 and I'm concerned that floating-point errors will end up rounding this down.

I would hope that i == 1, but is this guaranteed?

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    @Mat as far as I can see the only difference is round explicitly does not respect the current rounding mode. The guarantees are otherwise the same. – BoBTFish Nov 7 '17 at 8:32
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    @BoBTFish: the lrint variants return integral values, not integral values in floating point format. Not quite the same (as far as I understand it) – Mat Nov 7 '17 at 8:44
  • Worth mentioning that double can store much larger numbers than int and signed integet overflow is UB (not arbitrary or IB, real UB - I've seen e.g. infinite loops from signed int overflow). – lorro Nov 7 '17 at 10:35
up vote 6 down vote accepted

The std::round function returns a floating point value, "rounding halfway cases away from zero". As with any double to int implicit conversion the compiler will issue a warning:

conversion from 'double' to 'int', possible loss of data

Use std::lround or std::lrint if you want to return an integral value.

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    rint seems to have exactly the same guarantees as round, other than respecting the currently set rounding mode. – BoBTFish Nov 7 '17 at 8:35
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    @BoBTFish I have updated the answer with the std::lrint variant. – Ron Nov 7 '17 at 8:37
  • This does not explicitly answer the question (and neither do the other answers). Floating-point errors do not happen randomly or arbitrarily; a value of exactly 1 returned by std::round is not going to be arbitrarily changed into something else. Technically, the C and C++ standards fail to provide guarantees about various aspects of floating-point behavior, but no normal implementation would have any error in converting the (mathematical) integer result of std::round to an int as long as the result is within range of an int. – Eric Postpischil Nov 7 '17 at 13:58
  • (I am not saying the OP should not be advised to use std::lround or std::lrint in this case, just pointing out that we have not actually answered the explicit question and explained how floating-point works.) – Eric Postpischil Nov 7 '17 at 13:59

Yes. So long as you don't overflow the receiving type.

You have no concerns here: std::round(0.9) will round to exactly 1.0 and so i == 1 is guaranteed

The standard insists on the closest integral value assumable by a double being returned.

Note though that for an IEEE754 double, all values over the 52nd power of 2 are integral values! A corollary of that is that your candidate number for rounding is already an integral value, so the function reduces to a no-op. So the fact, for example, that std::round(4503599627370496.5) will return 4503599627370496 is all to do with the fact that 4503599627370496.5 cannot be represented as a double in the first place.

As final technical point, note that std::round is remarkably well-behaved, due in part to the fact that any number of the form a.5 (which is the cutover point in German rounding) is a dyadic rational and so can be represented exactly in binary floating point. This is why an alternative approach, such as adding 0.5 and truncating, can introduce bugs since joke digits can be introduced if you do that.

The C++ Standard defers to the C Standard for this. In N1570 (~C11), the description of round is as follows:

The round functions round their argument to the nearest integer value in floating-point format, rounding halfway cases away from zero, regardless of the current rounding direction.

However, as Ron pointed out, functions such as lrint do exactly what you want.

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    "Note that this may not be the nearest integer" That's wrong. It will be. If the number is not integer, then both integers around it is available. If it is integer, then there is nothing to do. – geza Nov 7 '17 at 9:13
  • @geza Absolutely correct, of course. Removed that part. – BoBTFish Nov 7 '17 at 9:19

According to cppreference:

Floating–integral conversions

A prvalue of floating-point type can be converted to a prvalue of any integer type. The fractional part is truncated, that is, the fractional part is discarded. If the value cannot fit into the destination type, the behavior is undefined (even when the destination type is unsigned, modulo arithmetic does not apply). If the destination type is bool, this is a boolean conversion (see below).

  • The question seems to be, is it safe to use round then follow with this truncation? I.e. is round guaranteed to return something such that the result of the truncation give mathematically the same value? – BoBTFish Nov 7 '17 at 8:37

how about adding 0.5 and then casting to int (truncating)

if(x < 0) { //number is negative
 return (int) x - 0.5;
} else {
 return (int) x + 0.5;//number is positive

in your example it should return 1 for sure because 1.49999999999 cast to int is 1

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    Very very naughty; this approach fails on some edge cases. Java had this bug up to 1.5. Plus you've messed up your operator precedence; you are casting to an int, then adding the constant! – Bathsheba Nov 7 '17 at 9:21

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