Let us assume assume that `p`

and `q`

are both normalized and positive, and `p < q`

.

If `p`

and `q`

have differing exponents, it appears that the number you are looking for is the number obtained by zeroing the mantissa of `q`

after the leading (and often implicit) 1. The corner cases are left as an exercise, especially the case where `q`

's mantissa is already made of zeroes after the leading, possibly implicit, `1`

.

If `p`

and `q`

have the same exponent, then we have to look at their mantissas. These mantissas have some bits in common (starting from the most significant end). Let us call `c1 c2 .. ck pk+1 ... pn`

the bits of `p`

's mantissa, `c1 c2 .. ck qk+1 ... qn`

the bits of `q`

's mantissa, where `c1 .. ck`

are common bits and `pk+1`

, `qk+1`

differ. Then `pk+1`

is zero and `qk+1`

is one (because of the hypotheses). The number with the same exponent and mantissa `c1 .. ck 1 0 .. 0`

is in the interval `p .. q`

and is the number you are looking for (again, corner cases left as an exercise).

`{truncation(), ceiling(), floor()}`

operations on the binary representation? – Iterator Oct 22 '11 at 15:14`r`

where the mantissa has the lowest possible popcnt it can get while still being between`p`

and`q`

, right? – harold Oct 22 '11 at 15:20