# Algorithm - Partition two numbers about a power-of-two

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

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).

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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