The question is strange, and the checks are as well. The problem is that it makes little sense to speak about divisibility of a floating point number because floating point number are represented imprecisely in binary, and divisibility is about *exactitude*.

I encourage you to read this article, by David Goldberg: What Every Computer Scientist Should Know About Floating Point Arithmetic. It is a bit long-winded, so you may appreciate this website, instead: The Floating-Point Guide.

The truth is that `floor(num) == num`

is a strange piece of code.

`num`

is a `double`

`floor(num)`

returns an `double`

, close to an `int`

The trouble is that this does not check what you really wanted. For example, suppose (for the sake of example) that `5`

cannot be represented exactly as a double, therefore, instead of storing `5`

, the computer will store `4.999999999999`

.

```
double num = 5; // 4.999999999999999
double floored = floor(num); // 4.0
assert(num != floored);
```

In general exact comparisons are *meaningless* for floating point numbers, because of rounding errors.

If you insist on using `floor`

, I suggest to use `floor(num + 0.5)`

which is better, though slightly biased. A better rounding method is the Banker's rounding because it is unbiased, and the article references others if you wish. Note that the Banker's rounding is the baked in in `round`

...

As for your question, first you need a `double`

aware modulo: `fmod`

, then you need to remember the *avoid exact comparisons* bit.

A first (naive) attempt:

```
// divisor is deemed non-zero
// epsilon is a constant
double mod = fmod(num, divisor); // divisor will be converted to a double
if (mod <= epsilon) { }
```

Unfortunately it fails one important test: the magnitude of `mod`

depends on the magnitude of `divisor`

, thus if `divisor`

is smaller than `epsilon`

to begin with, it will always be true.

A second attempt:

```
// divisor is deemed non-zero
double const epsilon = divisor / 1000.0;
double mod = fmod(num, divisor);
if (mod <= epsilon) { }
```

Better, but not quite there: `mod`

and `epsilon`

are signed! *Yes, it's a bizarre modulo, th sign of mod is the sign of num*

A third attempt:

```
// divisor is deemed non-zero
double const eps = fabs(divisor / 1000.0);
double mod = fabs(fmod(num, divisor));
if (mod <= eps) { }
```

Much better.

Should work fairly well too if `divisor`

comes from an integer, as there won't be precision issues... or at least not too much.

**EDIT**: fourth attempt, by @ybungalobill

The previous attempt does not deal well with situations where `num/divisor`

errors on the wrong side. Like `1.999/1.000`

--> `0.999`

, it's nearly `divisor`

so we should indicate equality, yet it failed.

```
// divisor is deemed non-zero
mod = fabs(fmod(num/divisor, 1));
if (mod <= 0.001 || fabs(1 - mod) <= 0.001) { }
```

Looks like a never ending task eh ?

There is still cause for troubles though.

`double`

has a limited precision, that is a limited number of digits that is representable (16 I think ?). This precision might be insufficient to represent an integer:

```
Integer n = 12345678901234567890;
double d = n; // 1.234567890123457 * 10^20
```

This *truncation* means it is impossible to map it back to its original value. This should not cause any issue with `double`

and `int`

, for example on my platform `double`

is 8 bytes and `int`

is 4 bytes, so it would work, but changing `double`

to `float`

or `int`

to `long`

could violate this assumption, oh hell!

*Are you sure you really need floating point, by the way ?*

`bananas==true`

to`bananas`

because it is a bool. Just a suggestion but not really any improvement or anything. – Matt Mar 31 '11 at 5:28set`bananas`

to`true`

at some point :-) – Karl Bielefeldt Mar 31 '11 at 5:32`bananas`

altogether... – Matt Mar 31 '11 at 5:38