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Given two floating point numbers, p and q where 0 < p < q I am interested in writing a function partition(p,q) that finds the 'simplest' number r that is between p and q. For example:

partition(3.0, 4.1) = 4.0 (2^2)
partition(4.2, 7.0) = 6.0 (2^2 + 2^1)
partition(2.0, 4.0) = 3.0 (2^1 + 2^0)
partition(0.3, 0.6) = 0.5 (2^-1)
partition(1.0, 10.0) = 8.0 (2^3)

In the last instance I am interested in the largest number (so 8 as opposed to 4 or 2).

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What's the simplest number definition? – Saeed Amiri Oct 22 '11 at 15:10
It must be an integer? – akappa Oct 22 '11 at 15:11
Isn't this simply resolved via one or more of {truncation(), ceiling(), floor()} operations on the binary representation? – Iterator Oct 22 '11 at 15:14
Yes, a straightforward manipulation on the binary representation should be enough implement this. – Patrick Oct 22 '11 at 15:18
It's not very clear, but you want a number 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
up vote 3 down vote accepted

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 ... qnthe 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).

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'zeroing the mantissa': to be clear, this assumes IEEE 754 (or something very similar), and in particular that the bits being set to zero don't include the implicit hidden '1' bit, right? – Mark Dickinson Oct 22 '11 at 15:50
@Mark Dickinson Yes, I was using the verb "zeroing" thinking of the IEEE 754 representation with implicit leading 1. I said I was assuming q to be normalized, though, so if we are not using IEEE 754, the idea stands, just do not zero the leading 1. – Pascal Cuoq Oct 22 '11 at 15:54
Ok, thanks. Perhaps you could make it clearer that your use of 'mantissa' in this context doesn't include the leading 1. (After all, in some floating-point formats, like the outdated IEEE 754-1985 80-bit extended precision format, that 1 is included explicitly in the bit representation of the number.) – Mark Dickinson Oct 22 '11 at 16:03
  • Write the numbers in binary (terminating if possible, so 1 is written as 1.0000..., not 0.1111...),
  • Scan from left to right, "keeping" all digits at which the two numbers are equal
  • At the first digit where the two numbers differ, p must be 0 and q must be 1 since p < q:
    • If q has any more 1 digits after this point, then put a 1 at this point and you're done.
    • If q has no more 1 digits after this point, then doing that would result in r == q, which is forbidden, so instead append a 0 digit. Follow that by a 1 digit unless doing so would result in r == p, in which case append another 0 and then a 1.

Basically, we truncate q down to the first place at which p and q differ, then jigger it a bit if necessary to avoid r == p or r == q. The result is certainly less than q and greater than p. It is "simplest" (has the least possible number of 1 digits) since any number between p and q must share their common initial sequence. We have added only one 1 digit to that sequence, which is necessary since the initial sequence alone is <= p, so no value in range (p,q) has fewer 1 digits. We've chosen the "largest" solution because we always place our extra 1 at the first (biggest) possible place.

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It sounds like you just want to convert the binary representation of the largest integer strictly less than your largest argument to the corresponding sum of powers of two.

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This feels like more of a comment than an answer. – Pascal Cuoq Oct 22 '11 at 15:14
It is both a comment and an answer. But the more I read the original question, the more I realize it makes no sense. – ObscureRobot Oct 22 '11 at 15:16
but what's the solution of Partition(2.7, 2.8) then? 2.75? 2.79? e? – akappa Oct 22 '11 at 15:19
Either 17 or 42. – ObscureRobot Oct 22 '11 at 15:29

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