# negative zero in python

I encountered negative zero in output from python; it's created for example as follows:

``````k = 0.0
print(-k)
``````

The output will be `-0.0`.

However, when I compare the `-k` to 0.0 for equality, it yields True. Is there any difference between `0.0` and `-0.0` (I don't care that they presumably have different internal representation; I only care about their behavior in a program.) Is there any hidden traps I should be aware of?

• It does not give negative value with python 2.5.4 Nov 3, 2010 at 10:51
• The real hidden trap is when you start testing for equality with floating point values. They're inexact and prone to weird round-off discrepancies. Nov 3, 2010 at 21:52
• But it does print negative value on Python 2.7.1. Mar 4, 2013 at 21:30
• This problem came up in a real life gps application; longitude just slightly west of the meridian was being reported as zero degrees and x minutes, when it should have been minus zero degrees and x minutes. But python can't represent integer negative zero. Sep 1, 2016 at 9:20

Check out −0 (number) in Wikipedia

Basically IEEE does actually define a negative zero.

And by this definition for all purposes:

``````-0.0 == +0.0 == 0
``````

I agree with aaronasterling that `-0.0` and `+0.0` are different objects. Making them equal (equality operator) makes sure that subtle bugs are not introduced in the code.
Think of `a * b == c * d`

``````>>> a = 3.4
>>> b =4.4
>>> c = -0.0
>>> d = +0.0
>>> a*c
-0.0
>>> b*d
0.0
>>> a*c == b*d
True
>>>
``````

When I said for all practical purposes, I had chosen the word rather hastily. I meant standard equality comparison.

As the reference says, the IEEE standard defines comparison so that `+0 = -0`, rather than `-0 < +0`. Although it would be possible always to ignore the sign of zero, the IEEE standard does not do so. When a multiplication or division involves a signed zero, the usual sign rules apply in computing the sign of the answer.

Operations like `divmod` and `atan2` exhibit this behavior. In fact, `atan2` complies with the IEEE definition as does the underlying "C" lib.

``````>>> divmod(-0.0,100)
(-0.0, 0.0)
>>> divmod(+0.0,100)
(0.0, 0.0)

>>> math.atan2(0.0, 0.0) == math.atan2(-0.0, 0.0)
True
>>> math.atan2(0.0, -0.0) == math.atan2(-0.0, -0.0)
False
``````

One way is to find out through the documentation, if the implementation complies with IEEE behavior . It also seems from the discussion that there are subtle platform variations too.

However this aspect (IEEE definition compliance) has not been respected everywhere. See the rejection of PEP 754 due to disinterest! I am not sure if this was picked up later.

• @aaronasterling: Why did you remove your answer? Thats was a valuable addition to information here. I just upvoted it. Nov 3, 2010 at 2:49
• because I was wrong about the last part of it and the rest of it wasn't really unique to my post. Nov 3, 2010 at 4:05
• If it's "equal for all purposes" how does it explain the difference in `atan2` in Craig McQueen's answer? I agree that it returns True when compared for equality, but if the two numbers' behavior may varies, I would like to know when.
– max
Nov 3, 2010 at 18:41
• @max Note that the arctangent function is basically looking for the slope (and direction) of the provided arguments, so internally it's dividing by zero leading to discontinuities that should not be surprising. Furthermore, the function output is cyclic with a period of 2π, +π and -π are the "same". Mar 10, 2014 at 21:19

`math.copysign()` treats `-0.0` and `+0.0` differently, unless you are running Python on a weird platform:

`math.`copysign(x, y)
Return x with the sign of y. On a platform that supports signed zeros, `copysign(1.0, -0.0)` returns `-1.0`.

``````>>> import math
>>> math.copysign(1, -0.0)
-1.0
>>> math.copysign(1, 0.0)
1.0
``````
• numpy also has a copysign. Yay! Jun 18, 2018 at 8:42

It makes a difference in the `atan2()` function (at least, in some implementations). In my Python 3.1 and 3.2 on Windows (which is based on the underlying C implementation, according to the note CPython implementation detail near the bottom of the Python `math` module documentation):

``````>>> import math
>>> math.atan2(0.0, 0.0)
0.0
>>> math.atan2(-0.0, 0.0)
-0.0
>>> math.atan2(0.0, -0.0)
3.141592653589793
>>> math.atan2(-0.0, -0.0)
-3.141592653589793
``````

Yes, there is a difference between 0.0 and -0.0 (though Python won't let me reproduce it :-P). If you divide a positive number by 0.0, you get positive infinity; if you divide that same number by -0.0 you get negative infinity.

Beyond that, though, there is no practical difference between the two values.

• You can't divide by 0. If you're talking about talking limits, -0 makes even less sense. Nov 3, 2010 at 1:04
• -1 You can't divide a number 0 since you get a ZeroDivisonError. That means that there is no difference. Nov 3, 2010 at 1:04
• @Falmarri: In Python, you can't; in other languages, you very well can. I was addressing the distinction between 0.0 and -0.0 in a general floating-point processing sense. Nov 3, 2010 at 1:04
• +1 to cancel out the downvotes. Chris is correct that, e.g., in C, floating point division by 0.0 is defined to produce infinity with the sign of (numerator and denominator have same sign) ? positive : negative. Nov 3, 2010 at 1:10
• @DMan: It's important that (a) they exist and (b) there's an implementation. (Even if it's partial.) Because you (and I) don't see the complex mathematical subtleties doesn't mean anything. They still exist. I don't understand partial differential equations, and see no practical value. Some people do. I see limited practical value in the standard. That's not the point. My humble opinion on "practical" has no merit. It still exists, and it still has meaning, and it's still partially implemented. Nov 4, 2010 at 21:10

Same values, yet different numbers

``````>>> Decimal('0').compare(Decimal('-0'))        # Compare value
Decimal('0')                                   # Represents equality

>>> Decimal('0').compare_total(Decimal('-0'))  # Compare using abstract representation
Decimal('1')                                   # Represents a > b
``````

If you are ever concerned about running into a -0.0 condition, just add + 0. to the equation. It does not influence the results but forces the zeros to a positive float.

``````import math

math.atan2(-0.0, 0.0)
Out[2]: -0.0

math.atan2(-0.0, 0.0) + 0.
Out[3]: 0.0
``````

To generalise or summarise the other answers, the difference in practice seems to come from calculating functions that are discontinued at 0 where the discontinuity is coming from a 0 division. Yet, python defines a 0 division as an error. So if anything is calculated with python operators, you can simply consider -0.0 as +0.0 and nothing to worry from. On the contrary, if the function is calculated by a built in function or a library that is written in another language, such as C, the 0 division may be defined otherwise in that language and may give different answers for -0.0 and 0.0.