# Propagation of NaN through calculations

Normally, NaN (not a number) propagates through calculations, so I don't need to check for NaN in each step. This works almost always, but apparently there are exceptions. For example:

``````>>> nan = float('nan')
>>> pow(nan, 0)
1.0
``````

I found the following comment on this:

The propagation of quiet NaNs through arithmetic operations allows errors to be detected at the end of a sequence of operations without extensive testing during intermediate stages. However, note that depending on the language and the function, NaNs can silently be removed in expressions that would give a constant result for all other floating-point values e.g. NaN^0, which may be defined as 1, so in general a later test for a set INVALID flag is needed to detect all cases where NaNs are introduced.

To satisfy those wishing a more strict interpretation of how the power function should act, the 2008 standard defines two additional power functions; pown(x, n) where the exponent must be an integer, and powr(x, y) which returns a NaN whenever a parameter is a NaN or the exponentiation would give an indeterminate form.

Is there a way to check the INVALID flag mentioned above through Python? Alternatively, is there any other approach to catch cases where NaN does not propagate?

Motivation: I decided to use NaN for missing data. In my application, missing inputs should result in missing result. It works great, with the exception I described.

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I realise that a month has passed since this was asked, but I've come across a similar problem (i.e. `pow(float('nan'), 1)` throws an exception in some Python implementations, e.g. Jython 2.52b2), and I found the above answers weren't quite what I was looking for.

Using a MissingData type as suggested by 6502 seems like the way to go, but I needed a concrete example. I tried Ethan Furman's NullType class but found that that this didn't work with any arithmetic operations as it doesn't coerce data types (see below), and I also didn't like that it explicitly named each arithmetic function that was overriden.

Starting with Ethan's example and tweaking code I found here, I arrived at the class below. Although the class is heavily commented you can see that it actually only has a handful of lines of functional code in it.

The key points are: 1. Use coerce() to return two NoData objects for mixed type (e.g. NoData + float) arithmetic operations, and two strings for string based (e.g. concat) operations. 2. Use getattr() to return a callable NoData() object for all other attribute/method access 3. Use call() to implement all other methods of the NoData() object: by returning a NoData() object

Here's some examples of its use.

``````>>> nd = NoData()
>>> nd + 5
NoData()
>>> pow(nd, 1)
NoData()
>>> math.pow(NoData(), 1)
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
TypeError: nb_float should return float object
>>> nd > 5
NoData()
>>> if nd > 5:
...     print "Yes"
... else:
...     print "No"
...
No
>>> "The answer is " + nd
'The answer is NoData()'
>>> "The answer is %f" % (nd)
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
TypeError: float argument required, not instance
>>> "The answer is %s" % (nd)
'The answer is '
>>> nd.f = 5
>>> nd.f
NoData()
>>> nd.f()
NoData()
``````

I noticed that using pow with NoData() calls the ** operator and hence works with NoData, but using math.pow does not as it first tries to convert the NoData() object to a float. I'm happy using the non math pow - hopefully 6502 etc were using math.pow when they had problems with pow in their comments above.

The other issue I can't think of a way of solving is the use with the format (%f) operator... No methods of NoData are called in this case, the operator just fails if you don't provide a float. Anyway here's the class itself.

``````class NoData():
"""NoData object - any interaction returns NoData()"""
def __str__(self):
#I want '' returned as it represents no data in my output (e.g. csv) files
return ''

def __unicode__(self):
return ''

def __repr__(self):
return 'NoData()'

def __coerce__(self, other_object):
if isinstance(other_object, str) or isinstance(other_object, unicode):
#Return string objects when coerced with another string object.
#This ensures that e.g. concatenation operations produce strings.
return repr(self), other_object
else:
#Otherwise return two NoData objects - these will then be passed to the appropriate
#operator method for NoData, which should then return a NoData object
return self, self

def __nonzero__(self):
#__nonzero__ is the operation that is called whenever, e.g. "if NoData:" occurs
#i.e. as all operations involving NoData return NoData, whenever a
#NoData object propagates to a test in branch statement.
return False

def __hash__(self):
#prevent NoData() from being used as a key for a dict or used in a set
raise TypeError("Unhashable type: " + self.repr())

def __setattr__(self, name, value):
#This is overridden to prevent any attributes from being created on NoData when e.g. "NoData().f = x" is called
return None

def __call__(self, *args, **kwargs):
#if a NoData object is called (i.e. used as a method), return a NoData object
return self

def __getattr__(self,name):
#For all other attribute accesses or method accesses, return a NoData object.
#Remember that the NoData object can be called (__call__), so if a method is called,
#a NoData object is first returned and then called.  This works for operators,
#so e.g. NoData() + 5 will:
# - call NoData().__coerce__, which returns a (NoData, NoData) tuple
# - call __getattr__, which returns a NoData object
# - call the returned NoData object with args (self, NoData)
# - this call (i.e. __call__) returns a NoData object

#For attribute accesses NoData will be returned, and that's it.

#print name #(uncomment this line for debugging purposes i.e. to see that attribute was accessed/method was called)
return self
``````
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I meant Jython 2.5.2b2, not 2.52b2 –  jcdude May 3 '12 at 12:43

Why using `NaN` that already has another semantic instead of using an instance of a class `MissingData` defined by yourself?

Defining operations on `MissingData` instances to get propagation should be easy...

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I can't believe I didn't think of this. Now with ABC, it won't even be that hard to define all the arithmetic operations, right? –  max Apr 5 '12 at 19:27
Or as I suggested in my just-now edit to my own answer, don't even implement any operations on the `MissingData` class. Just let Python raise whatever exception when you try to use one of those objects in a calculation, catch it, and provide the default value. –  kindall Apr 5 '12 at 19:34
I actually want the operations on MissingValue because an exception would have to be caught at every intermediate calculation, which is a bit too much work. It's far better to simply let the MissingValue propagate, and then have MissingValue populate the resulting dataset. –  max Apr 5 '12 at 19:40
Yes, I was assuming that the calculations happen in a block or could easily be arranged to do so. –  kindall Apr 5 '12 at 20:05
Unfortunately it looks like the `pow()` function doesn't actually call the `__pow__()` special method on the class (only `x ** y` will call `x.__pow__()`). So you're probably still going to be rewriting that, and `abs()`, and a fair number of other built-in numeric functions. –  kindall Apr 5 '12 at 20:07

If it's just `pow()` giving you headaches, you can easily redefine it to return `NaN` under whatever circumstances you like.

``````def pow(x, y):
return x ** y if x == x else float("NaN")
``````

If `NaN` can be used as an exponent you'd also want to check for that; this raises a `ValueError` exception except when the base is 1 (apparently on the theory that 1 to any power, even one that's not a number, is 1).

(And of course `pow()` actually takes three operands, the third optional, which omission I'll leave as an exercise...)

Unfortunately the `**` operator has the same behavior, and there's no way to redefine that for built-in numeric types. A possibility to catch this is to write a subclass of `float` that implements `__pow__()` and `__rpow__()` and use that class for your `NaN` values.

Python doesn't seem to provide access to any flags set by calculations; even if it did, it's something you'd have to check after each individual operation.

In fact, on further consideration, I think the best solution might be to simply use an instance of a dummy class for missing values. Python will choke on any operation you try to do with these values, raising an exception, and you can catch the exception and return a default value or whatever. There's no reason to proceed with the rest of the calculation if a needed value is missing, so an exception should be fine.

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I don't see how that works. `NaN != NaN` so your `if` is always going to be true. –  Duncan Apr 5 '12 at 19:18
Just replace `x != NaN` with `x == x`. –  max Apr 5 '12 at 19:19
And I'm not sure; maybe `pow` is the only one, maybe it's not... I guess using `NaN` for missing data, neat as it sounds, is not really practical... :( –  max Apr 5 '12 at 19:20
Good call, forgot about that behavior of `NaN`. –  kindall Apr 5 '12 at 19:21
This doesn't work -- probably because x!=NaN will always evaluate to True. (`nan != nan` according to the IEEE standard). nan does propagate as long as the exponent is not 0...apparently the library takes the approach that x**0=1 no matter what x is... The way that I usually check for nan's is using numpy.isnan(x). –  mgilson Apr 5 '12 at 19:22

To answer your question: No, there is no way to check the flags using normal floats. You can use the Decimal class, however, which provides much more control . . . but is a bit slower.

Your other option is to use an `EmptyData` or `Null` class, such as this one:

``````class NullType(object):
"Null object -- any interaction returns Null"
def _null(self, *args, **kwargs):
return self
__eq__ = __ne__ = __ge__ = __gt__ = __le__ = __lt__ = _null
__sub__ = __isub__ = __rsub__ = _null
__mul__ = __imul__ = __rmul__ = _null
__div__ = __idiv__ = __rdiv__ = _null
__mod__ = __imod__ = __rmod__ = _null
__pow__ = __ipow__ = __rpow__ = _null
__and__ = __iand__ = __rand__ = _null
__xor__ = __ixor__ = __rxor__ = _null
__or__ = __ior__ = __ror__ = _null
__divmod__ = __rdivmod__ = _null
__truediv__ = __itruediv__ = __rtruediv__ = _null
__floordiv__ = __ifloordiv__ = __rfloordiv__ = _null
__lshift__ = __ilshift__ = __rlshift__ = _null
__rshift__ = __irshift__ = __rrshift__ = _null
__neg__ = __pos__ = __abs__ = __invert__ = _null
__call__ = __getattr__ = _null

def __divmod__(self, other):
return self, self
__rdivmod__ = __divmod__

if sys.version_info[:2] >= (2, 6):
__hash__ = None
else:
def __hash__(yo):
raise TypeError("unhashable type: 'Null'")

def __new__(cls):
return cls.null
def __nonzero__(yo):
return False
def __repr__(yo):
return '<null>'
def __setattr__(yo, name, value):
return None
def __setitem___(yo, index, value):
return None
def __str__(yo):
return ''
NullType.null = object.__new__(NullType)
Null = NullType()
``````

You may want to change the `__repr__` and `__str__` methods. Also, be aware that `Null` cannot be used as a dictionary key, nor stored in a set.

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