Simple question: Will the conversion from an int, say 100, to a double "round" up or down to the next double or will it always round to the nearest one (smallest delta)?

e.g. for static_cast<double>(100):

Casting from int to double

Which way will it cast if d2 < d1?

Bonus question: Can I somehow force the processor to "round" down or up to the closes double using special functions? As I see it, there's no floor<double> or ceil<double> unfortunately.

  • 6
    assuming int is 32-bit it will always convert to an exact double value (again assuming a 64-bit IEEE-754 double). See Real floating-integer conversions for the rules in other cases Mar 8, 2023 at 7:53
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    For values smaller than ~2^53 (9007199254740992) there's no issue - they can be exactly represented in double (see here: stackoverflow.com/questions/1848700/…). The question remains however for values bigger than that (you'll need a 64bit integer).
    – wohlstad
    Mar 8, 2023 at 8:03
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    @wohlstad I think you mean by "exactly represented" that a round trip conversion will yield the exact same integer value. Only powers of 2 can be represented exactly in a floating point type.
    – glades
    Mar 8, 2023 at 8:07
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    @glades why do you think only powers of 2 can be represented exactly ? A double typically has 53 bits of mantisa. You can have an exact representation for at least around 2^53 values, not only powers of 2 (e.g. by setting the exponent to 2^0).
    – wohlstad
    Mar 8, 2023 at 8:12
  • 7
    No, any integer up to 2^53 can be represented exactly, not just powers of 2, then it's ever other integer up to 2^54, every 4 up to 2^55 etc. Mar 8, 2023 at 8:12

1 Answer 1


Note that a 32-bit int can be represented exactly by a 64-bit IEEE 754 double (it can actually represent up to 53-bit integers precisely).

If you're using an integer that is larger than can be represented by your floating point type then the rules at Real floating-integer conversions apply:

  • if the value can be represented, but cannot be represented exactly, the result is the nearest higher or the nearest lower value (in other words, rounding direction is implementation-defined), although if IEEE arithmetic is supported, rounding is to nearest. It is unspecified whether FE_INEXACT is raised in this case.
  • if the value cannot be represented, the behavior is undefined, although if IEEE arithmetic is supported, FE_INVALID is raised and the result value is unspecified.

There is no c++ standard function to control the rounding mode, most implementations will use the IEEE round to nearest.

  • The parenthetical note on the first bullet point is does not mean the same as the preceding text. The preceding text would accommodate the possibility that an implementation might choose in Unspecified fashion between yielding the next higher or next lower value, which might allow some optimizations in cases where both values would work equally well.
    – supercat
    Mar 8, 2023 at 19:39
  • @supercat not sure what you mean? The quote is directly from cppreference Mar 8, 2023 at 19:54
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    @AlanBirtles: It's sloppy writing, wherever it came from. The phrase "in other words" is supposed to appear between pieces of text that mean the same thing, but in different words. If the preceding and following text. If implementations are required to document in all cases how they will choose the rounding direction, the text should say something like "Additionally, the choice of whether to round up or down must be made in implementation-defined fashion", and if implementations are not required to document things that precisely, the choice is Unspecified and the statement that it's...
    – supercat
    Mar 8, 2023 at 20:17
  • ... "implementation-defined" would be erroneous.
    – supercat
    Mar 8, 2023 at 20:18
  • @supercat, the way I'm reading it is that if IEEE arithmetic is used, then rounding is to the nearest value using the IEEE rules. If IEEE arithmetic is not used, then the implementation can pick either the nearest higher value or the nearest lower value based on whatever rules seem appropriate.
    – Mark
    Mar 8, 2023 at 23:17

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