There've been a couple of experimental approaches; here's a proof that `C = 1 - ε`

, where `ε`

is machine epsilon (that is, the distance between `1`

and the smallest representable number greater than `1`

.)

We know that `C < 1`

, of course, so it makes sense to try `C = 1 - ε/2`

because it's the next representable number smaller than `1`

. (The `ε/2`

is because `C`

is in the `[0.5, 1)`

bucket of representable numbers.) Let's see if it works for all `A`

.

I'm going to assume in this paragraph that `1 <= A < 2`

. If both `A`

and `AC`

are in the "normal" region then it doesn't really matter what the exponent is, the situation will be the same with the exponent `2^0`

. Now, that choice of `C`

obviously works for `A=1`

, so we are left with the region `1 < A < 2`

. Looking at `A = 1 + ε`

, we see that `AC`

(the exact value, not the rounded result) is already greater than 1; and for `A = 2 - ε`

we see that it's less than 2. That's important, because if `AC`

is between 1 and 2, we know that the distance between `AC`

and `round(AC)`

(that is, rounding it to the nearest representable value) is at most `ε/2`

. Now, if `A - AC < ε/2`

, then `round(AC) = A`

which we *don't* want. (If `A - AC = ε/2`

then it *might* round to `A`

given the "ties to even" part of the normal FP rounding rules, but let's see if we can do better.) Since we've chosen `C = 1 - ε/2`

, we can see that `A - AC = A - A(1 - ε/2) = A * ε/2`

. Since that's greater than `ε/2`

(remember, `A>1`

), it's far enough away from `A`

to round away from it.

BUT! The one other value of `A`

we have to check is the minimum representable normal value, since there `AC`

is *not* in the normal range and so our "relative distance to nearest" rule doesn't apply. And what we find is that in that case `A-AC`

is exactly half of machine epsilon in the region. "Round to nearest, *ties to even*" kicks in and the product rounds back up to equal `A`

. Drat.

Going through the same thing with `C = 1 - ε`

, we see that `round(AC) < A`

, and that nothing else even comes close to rounding towards `A`

(we end up asking whether `A * ε > ε/2`

, which of course it is). So the punchline is that `C = 1-ε/2`

*almost* works but the boundary between normals and denormals screws us up, and `C = 1-ε`

gets us into the end zone.

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