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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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4 Answers 4

up vote 3 down vote accepted

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
    __add__ = __iadd__ = __radd__ = _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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