Why do doubles have
-0 as well as
+0? What is the background and significance?
If we consider the same case with a positive number, we will receive our good old
* Here's a case where using
This makes sense if we consider the function
This illustrates one significant difference between
Here are some relevant resources, some of which have been brought up already. I've included them for the sake of completeness:
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When you have a floating-point operation that produces a results that is a negative floating-point number close to zero, but that can not be represented (in computing) it is produce a "-0.0". For example -
This distinguish, in
What's the difference between -0.0 and 0.0?
In reality both are represent 0. Furthermore, (-0.0 == 0.0) returns true. Nevertheless:
Mandatory reading "What Every Computer Scientist Should Know About Floating-Point Arithmetic" (suggest in the comments).
See the section on "Signed Zero" in What Every Computer Scientist Should Know About Floating-Point Arithmetic
Zeros in Java float and double do not just represent true zero. They are also used as the result for any calculation whose exact result has too small a magnitude to be represented. There is a big difference, in many contexts, between underflow of a negative number and underflow of a positive number. For example, if
The canonical reference for the usefulness of signed zeros in floating-point is Kahan's paper "Branch Cuts for Complex Elementary Functions, or Much Ado About Nothing's Sign Bit" (and some of his talks on the subject).
The short version is that in reasonably common engineering applications, the sign information that is preserved by having signed zero is necessary to get correct solutions from numerical methods. The sign of zero has little meaning for most real operations, but when complex-valued functions are considered, or conformal mappings are used, the sign of zero may suddenly become quite critical.
It's also worth noting that the original (1985)