To complement Eric Postpischil's answer: Yes, and then again no. It depends on how we're going to interpret `floor(sqrt(n))`

in the case that `n`

is really large.

As in Eric's answer, let's assume IEEE 754 binary64 format floating-point and a correctly-rounded `sqrt`

, with the usual round-ties-to-even rounding mode in effect. I'm also assuming access to an arbitrary precision integer type for `n`

.

First interpretation: suppose that `n`

is allowed to take on any integral value, and that `floor(sqrt(n))`

is to be interpreted as `floor(sqrt(convert_to_double(n)))`

. Then there's immediately a problem for `n >= 2^1024 - 2^970`

, since `convert_to_double`

will overflow at that point. (I'm assuming that `convert_to_double`

is also correctly rounded.) Starting from the other end, Eric's answer already shows that we're good up to but not including `n = (2^53 + 1)^2`

, and as he suggests, `n = (2^53 + 1)^2`

is a problem case: there `convert_to_double(n)`

has value `2^106 + 2^54`

, one less than the true value, and `sqrt(convert_to_double(n))`

will be rounded down to `2^53`

, meaning that your trial division function will miss the factor `2^53 + 1`

. However, given that `2^53 + 1`

is divisible by `3`

and `107`

, the trial division will likely have already discovered other factors by that point, so missing `2^53+1`

may not be an issue. In that case, `n = (2^53 + 5)^2`

should be considered the first problem case. (`2^53 + 5`

is prime.)

Second interpretation: suppose that `n`

is constrained to be a positive integer that's exactly representable as a double. Then a neat fact is that any divisor of `n`

must also be exactly representable as a double: `n`

can be written in the form `m•2^e`

for some nonnegative exponent `e`

and odd integer `m`

with `m < 2^53`

, and any divisor of `n`

can be written in the form `d•2^f`

for some divisor `d`

of `m`

and exponent `f`

with `0 <= f <= e`

. But now if `x`

is a divisor of `n`

that's smaller than the exact square root of `n`

, `x`

is exactly representable as a double, so the *nearest* representable double to the square root of `n`

must be greater than or equal to `x`

. So a trial division routine that goes up to `floor(sqrt(n))`

can't miss `x`

.

And just for fun: here we're only worried about values of `n`

for which `floor(sqrt(n))`

gives a value that's too small. If you're also interested in cases where `floor(sqrt(n))`

gives a value that's too large, the first example occurs *much* earlier, at `n = (2^26 + 1)^2 - 1`

. (Proof left as an exercise.)

Of course, this is all rather academic: if you're doing trial division with numbers larger than `2^106`

, you're going to be waiting a *long* time for any result...

`floor`

rather than`float`

, as in`max = floor(sqrt(REALLY_BIG_N))`

? – Mark Dickinson Oct 16 '13 at 19:51