I've got a double
that prints as 0.000000
and I'm trying to compare it to 0.0f
, unsuccessfully. Why is there a difference here? What's the most reliable way to determine if your double is zero?

5Do you want to know if it is exactly zero or if it is sufficiently close to zero that it is 0.000000 to 6 decimal places? In other words, is it important to you if it is nonzero but sufficiently close to zero to print the same as zero?– CB BaileyCommented Aug 10, 2011 at 9:40

5Please show some code, and explain what you mean by "unsuccessfully".– Greg HewgillCommented Aug 10, 2011 at 9:44
4 Answers
To determine whether it's close enough to zero that it will print as 0.000000
to six decimal places, something like:
fabs(d) < 0.0000005
Dealing with small inaccuracies in floatingpoint calculations can get quite complicated in general, though.
If you want a better idea what value you've got, try printing with %g
instead of %f
.

Assuming your compiler support it, you should use DBL_MIN rather than an arbitrary constant. DBL_MIN is (usually?) defined as 2.2250738585072014e308 which is rather a lot less than 0.0000005 and may help eliminate false positives Commented Aug 10, 2011 at 9:53

6@Steve Mallam: If
DBL_MIN
is the smallest representable floating point number, then what would be the purpose of checking for less than that? Commented Aug 10, 2011 at 9:54 
2@Greg: in fact
DBL_MIN
is the smallest normalized double value, the implementation may support denormed values that are smaller. Commented Aug 10, 2011 at 9:58 
2@Steve Mallam: yeah, depends how the questioner is printing it and how small a value they think should count as zero for their purposes. I was assuming to six decimal places although I didn't state that, hence my code.
DBL_MIN
is very small, though, not many calculations that have errors at all, are quite that close. SometimesDBL_EPSILON
, multiplied by the magnitude of the numbers in in the calculation, is good. With%g
, even the exact double value0.0
doesn't print as0.000000
, I don't think any value does. So I don't know exactly what's being asked, this is my best guess,%f
. Commented Aug 10, 2011 at 10:15 
+1 all round, you're both dead right: DBL_EPSILON is the value I intended to suggest! Apologies  guess I commented in haste... Commented Aug 10, 2011 at 10:56
You can do a range. Like 0.00001 <= x <= 0.00001

It will compile, but it doesn't do what you want it to. Try it with
x=0.00002;
or withx=5e6;
. Commented Aug 10, 2011 at 16:04 
3
This is fundamental problem with floating point arithmetic on modern computers. They are by nature imprecise, and cannot be reliably compared. For example, the language ML explicitly disallows equality comparison on real types because it was considered too unsafe. See also the excellent (if a bit long and mathematically oriented) paper by David Goldberg on this topic.
Edit: tl;dr: you might be doing it wrong.
Also, one often overlooked features of floating point number are the denormalized numbers. That's numbers which have the minimal exponent, yet don't fit in the 0.51 range.
Those numbers are lower than FLT_MIN for float, and DBL_MIN for double.
A common mistake with using a threshold is to compare two values, or use FLT_MIN/DBL_MIN as limit.
For example, this would lead unlogical result (if you don't know about denormals):
bool areDifferent(float a, float b) {
if (a == b) return false; // Or also: if ((a  b) == FLT_MIN)
return true;
}
// What is the output of areDifferent(val, val + FLT_MIN * 0.5f) ?
// true, not false, even if adding half the "minimum value".
Denormals also usually implies a performance loss in computation. Yet, you can not disable them, else such code could still produce a DIVIDE BY ZERO floating point exception (if enabled):
float getInverse(float a, float b) {
if (a != b)
return 1.0f / (ab); // With denormals disabled, a != b can be true, but (a  b) can still be denormals, it'll rounded to 0 and throw the exception
return FLT_MAX;
}