This is guaranteed by the construction of IEEE-754 numbers. (To be clear: C does not guarantee IEEE-754, but the following analysis holds for all other floating-point formats with which I am familiar as well; the crucial property is that all sufficiently large numbers in the format are integers).
Recall that a normal IEEE-754 number has the form
±1.xxx...xxx * 2^n, where the width of the significand field (the
xxx...xxx part) is defined by the type of the number (23 binary digits for single precision, 52 binary digits for double precision). All such numbers with an exponent (
n) within the allowed range are representable.
Assume WLOG that
v is positive (if
v were negative, we could swap
floor in the following analysis).
k significant bits, and write
v out as a binary fixed point number; there are three possibilities:
Case 1: All significand bits are integral. When we write out
v, it looks like this
v is an integer, and so
ceil(v) = floor(v) = v, and so both are trivially representable.
Case 2: All significand bits are fractional. When we write out
v, it looks like
v is in the range [0,1), and so
floor(v) = 0, which is representable, and
ceil(v) is either zero or one, both of which are representable.
v contains both integral and fractional significand bits:
floor(v) is just:
because we have thrown away at least one fractional bit,
floor(v) has at most
k-1 significant bits, and the same exponent as
v, so it is representable.
v is an integer, then
ceil(v) = floor(v) = v, so
ceil(v) is representable. Otherwise,
ceil(v) = floor(v) + 1, and so also has at most
k-1 significant bits and is also representable.