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Is there a method like isiterable? The only solution I have found so far is to call

hasattr(myObj, '__iter__')

But I am not sure how fool-proof this is.

share|improve this question
5  
__getitem__ is also sufficient to make an object iterable – Kos Jul 2 '12 at 14:58
1  
FWIW: iter(myObj) succeeds if isinstance(myObj, dict), so if you're looking at a myObj that could be a sequence of dicts or a single dict, you'll succeed in both cases. A subtlety that is important if you want to know what's a sequence and what isn't. (in Python 2) – Ben Mosher Jul 25 '14 at 15:10

13 Answers 13

up vote 427 down vote accepted
  1. Checking for __iter__ works on sequence types, but it would fail on e.g. strings. I would like to know the right answer too, until then, here is one possibility (which would work on strings, too):

    try:
        some_object_iterator = iter(some_object)
    except TypeError, te:
        print some_object, 'is not iterable'
    

    The iter built-in checks for the __iter__ method or in the case of strings the __getitem__ method. To check if an object is "list like" and not "string like" then the key is the attributes __getitem__ and __iter__:

     In [9]: hasattr([1,2,3,4], '__iter__')
     Out[9]: True
     In [11]: hasattr((1,2,3,4), '__iter__')
     Out[11]: True
     In [12]: hasattr(u"hello", '__iter__')
     Out[12]: False
     In [14]: hasattr(u"hello", '__getitem__')
     Out[14]: True
    
  2. Another general pythonic approach is to assume an iterable, then fail gracefully if it does not work on the given object. The python glossary:

    Pythonic programming style that determines an object's type by inspection of its method or attribute signature rather than by explicit relationship to some type object ("If it looks like a duck and quacks like a duck, it must be a duck.") By emphasizing interfaces rather than specific types, well-designed code improves its flexibility by allowing polymorphic substitution. Duck-typing avoids tests using type() or isinstance(). Instead, it typically employs the EAFP (Easier to Ask Forgiveness than Permission) style of programming.

    ...

    try:
       _ = (e for e in my_object)
    except TypeError:
       print my_object, 'is not iterable'
    
  3. The collections module provides some abstract base classes, which allow to ask classes or instances if they provide particular functionality, for example:

    import collections
    
    if isinstance(e, collections.Iterable):
        # e is iterable
    
share|improve this answer
15  
[e for e in my_object] can raise an exception for other reasons, ie my_object is undefined or possible bugs in my_object implementation. – Nick Dandoulakis Dec 23 '09 at 12:39
21  
A string is a sequence (isinstance('', Sequence) == True) and as any sequence it is iterable (isinstance('', Iterable)). Though hasattr('', '__iter__') == False and it might be confusing. – J.F. Sebastian Dec 24 '09 at 0:11
59  
If my_object is very large (say, infinite like itertools.count()) your list comprehension will take up a lot of time/memory. Better to make a generator, which will never try to build a (potentially infinite) list. – Chris Lutz Dec 24 '09 at 3:42
10  
What if some_object throws TypeError caused by other reason(bugs etc.) too? How can we tell it from the "Not iterable TypeError"? – Shaung Sep 13 '11 at 7:34
22  
Note that in Python 3: hasattr(u"hello", '__iter__') returns True – Carlos Apr 21 '14 at 2:27

Duck typing

try:
    iterator = iter(theElement)
except TypeError:
    # not iterable
else:
    # iterable

# for obj in iterator:
#     pass

Type checking

Use the Abstract Base Classes. They need at least Python 2.6 and work only for new-style classes.

import collections

if isinstance(theElement, collections.Iterable):
    # iterable
else:
    # not iterable
share|improve this answer
12  
Is iter() guaranteed to never throw a TypeError for any other reason?? – mehaase May 24 '12 at 15:23
2  
@mehaase: The docs are not completely unambiguous, but I'm fairly sure that's the case. – Georg Schölly May 25 '12 at 9:38
3  
@mehaase, don't listen to Georg. iter(x) invokes x.__iter__() and will propagate any exception it throws to the caller. See [example]( melpon.org/wandbox/permlink/J39itbseL2ZsZ1J9). P.S. Just in case someone reading this doesn't know yet: if x.__iter__() can't be found iter() falls back to using x.__getitem__(). see docs. – Андрей Беньковский Dec 19 '15 at 20:45
1  
@АндрейБеньковский: I stand corrected. Thanks for pointing this out. – Georg Schölly Dec 24 '15 at 22:33

This isn't sufficient: the object returned by __iter__ must implement the iteration protocol (i.e. next method). See the relevant section in the documentation.

In Python, a good practice is to " try and see " instead of "checking".

share|improve this answer
6  
"duck typing" I believe? :) – willem Dec 23 '09 at 12:25
6  
@willem: or "don't ask for permission but for forgiveness" ;-) – jldupont Dec 23 '09 at 12:29
10  
@willem Both "permission" and "forgiveness" styles qualify as duck typing. If you ask what an object can do rather than what it is, that's duck typing. If you use introspection, that's "permission"; if you just try to do it and see if it works or not, that's "forgiveness". – Mark Reed Nov 12 '13 at 1:44
try:
  #treat object as iterable
except TypeError, e:
  #object is not actually iterable

Don't run checks to see if your duck really is a duck to see if it is iterable or not, treat it as if it was and complain if it wasn't.

share|improve this answer
3  
Technically, during iteration your computation might throw a TypeError and throw you off here, but basically yes. – Chris Lutz Dec 23 '09 at 12:22
    
I know in .NET it was a bad idea to have exceptions handle program flow, as exceptions were slow. How quickly does python handle exceptions? – willem Dec 23 '09 at 12:26
5  
@willem: Please use timeit to perform a benchmark. Python exceptions are often faster than if-statements. They can take a slightly shorter path through the interpreter. – S.Lott Dec 23 '09 at 14:24
2  
@willem: IronPython has slow (compared to CPython) exceptions. – J.F. Sebastian Dec 24 '09 at 0:01
1  
A working try: statement is really fast. So if you have few exceptions, try-except is fast. If you expect many exceptions, “if” can be faster. – Arne Babenhauserheide Jun 22 '12 at 10:04

The best solution I've found so far:

hasattr(obj, '__contains__')

which basically checks if the object implements the in operator.

Advantages (none of the other solutions has all three):

  • it is an expression (works as a lambda, as opposed to the try...catch variant)
  • it is (should be) implemented by all iterables, including strings (as opposed to __iter__)
  • works on any Python >= 2.5

Notes:

  • the Python philosophy of "ask for forgiveness, not permission" doesn't work well when e.g. in a list you have both iterables and non-iterables and you need to treat each element differently according to it's type (treating iterables on try and non-iterables on except would work, but it would look butt-ugly and misleading)
  • solutions to this problem which attempt to actually iterate over the object (e.g. [x for x in obj]) to check if it's iterable may induce significant performance penalties for large iterables (especially if you just need the first few elements of the iterable, for example) and should be avoided
share|improve this answer
2  
Nice, but why not use the collections module as proposed in stackoverflow.com/questions/1952464/…? Seems more expressive to me. – Dave Abrahams May 3 '11 at 4:10
1  
It's shorter (and doesn't require additional imports) without losing any clarity: having a "contains" method feels like a natural way to check if something is a collection of objects. – Vlad Nov 25 '11 at 12:04
36  
Just because something can contain something doesn't necessarily mean it's iterable. For example, a user can check if a point is in a 3D cube, but how would you iterate through this object? – Darthfett May 18 '12 at 14:52
8  
This is incorrect. An iterable itself does not support contains, at least with Python 3.4. – Peter Shinners Jan 21 '15 at 5:39

You could try this:

def iterable(a):
    try:
        (x for x in a)
        return True
    except TypeError:
        return False

If we can make a generator that iterates over it (but never use the generator so it doesn't take up space), it's iterable. Seems like a "duh" kind of thing. Why do you need to determine if a variable is iterable in the first place?

share|improve this answer
    
What about iterable(itertools.repeat(0))? :) – badp Dec 23 '09 at 12:24
4  
@badp, the (x for x in a) just creates a generator, it doesn't do any iteration on a. – catchmeifyoutry Dec 23 '09 at 12:31
5  
Is trying (x for x in a) precisely equivalent to trying iterator = iter(a)? Or there are some cases where the two are different? – max Dec 15 '12 at 20:05
    
Isn't for _ in a: break more straightforward ? Is it slower ? – Mr_and_Mrs_D Oct 23 '15 at 22:16

Found a nice solution here:

isiterable = lambda obj: isinstance(obj, basestring) \
    or getattr(obj, '__iter__', False)
share|improve this answer

On python <= 2.5, you can't and shouldn't - iterable was an "informal" interface.

But since python2.6 and 3.0 you can leverage the new ABC (abstract base class) infrastructure along with some builtin ABCs which are available in the collections module:

from collections import Iterable

class MyObject(object):
    pass

mo = MyObject()
print isinstance(mo, Iterable)
Iterable.register(MyObject)
print isinstance(mo, Iterable)

print isinstance("abc", Iterable)

Now, whether this is desiderable or actually works, is just a matter of conventions. As you can see, you can register a non-iterable object as Iterable - and it will raise an exception at runtime. Hence, isinstance acquires a "new" meaning - it just checks for "declared" type compatibility, which is a good way to go in Python.

On the other hand, if your object does not satifsy the interface you need, what are you going to do? take the following example:

from collections import Iterable
from traceback import print_exc

def check_and_raise(x):
    if not isinstance(x, Iterable):
        raise TypeError, "%s is not iterable" % x
    else:
        for i in x:
            print i

def just_iter(x):
    for i in x:
        print i


class NotIterable(object):
    pass

if __name__ == "__main__":
    try:
        check_and_raise(5)
    except:
        print_exc()
        print

    try:
        just_iter(5)
    except:
        print_exc()
        print



    try:
        Iterable.register(NotIterable)
        ni = NotIterable()
        check_and_raise(ni)
    except:
        print_exc()
        print

If the object doesn't satifsy what you expect, you just throw a TypeError, but if the proper ABC has been registered, your check is unuseful. On the contrary, if the __iter__ method is available python will automatically recognize object of that class as being Iterable.

So, if you just expect an iterable, iterate over it and forget it. On the other hand, if you need to do different things depending on input type, you might find the ABC infrastracture pretty useful.

share|improve this answer
11  
don't use bare except: in the example code for beginners. It promotes bad practice. – J.F. Sebastian Dec 23 '09 at 23:59
    
J.F.S: I wouldn't, but I needed to go through multiple exception-raising code and I didn't want to catch the specific exception... I think the purpose of this code is pretty clear. – Alan Franzoni Dec 24 '09 at 17:17

I'd like to shed a little bit more light on the interplay of iter, __iter__ and __getitem__ and what happens behind the curtains. Armed with that knowledge, you will be able to understand why the best you can do is

try:
    iter(maybe_iterable)
    print('iteration will probably work')
except TypeError:
    print('not iterable')

I will list the facts first and then follow up with a quick reminder of what happens when you employ a for loop in python, followed by a discussion to illustrate the facts.

Facts

  1. You can get an iterator from any object o by calling iter(o) if at least one of the following conditions holds true:

    a) o has an __iter__ method which returns an iterator object. An iterator is any object with an __iter__ and a __next__ (Python 2: next) method.

    b) o has a __getitem__ method.

  2. Checking for an instance of Iterable or Sequence, or checking for the attribute __iter__ is not enough.

  3. If an object o implements only __getitem__, but not __iter__, iter(o) will construct an iterator that tries to fetch items from o by integer index, starting at index 0. The iterator will catch any IndexError (but no other errors) that is raised and then raises StopIteration itself.

  4. In the most general sense, there's no way to check whether the iterator returned by iter is sane other than to try it out.

  5. If an object o implements __iter__, the iter function will make sure that the object returned by __iter__ is an iterator. There is no sanity check if an object only implements __getitem__.

  6. __iter__ wins. If an object o implements both __iter__ and __getitem__, iter(o) will call __iter__.

  7. If you want to make your own objects iterable, always implement the __iter__ method.

for loops

In order to follow along, you need an understanding of what happens when you employ a for loop in Python. Feel free to skip right to the next section if you already know.

When you use for item in o for some iterable object o, Python calls iter(o) and expects an iterator object as the return value. An iterator is any object which implements a __next__ (or next in Python 2) method and an __iter__ method.

By convention, the __iter__ method of an iterator should return the object itself (i.e. return self). Python then calls next on the iterator until StopIteration is raised. All of this happens implicitly, but the following demonstration makes it visible:

import random

class DemoIterable(object):
    def __iter__(self):
        print('__iter__ called')
        return DemoIterator()

class DemoIterator(object):
    def __iter__(self):
        return self

    def __next__(self):
        print('__next__ called')
        r = random.randint(1, 10)
        if r == 5:
            print('raising StopIteration')
            raise StopIteration
        return r

Iteration over a DemoIterable:

>>> di = DemoIterable()
>>> for x in di:
...     print(x)
...
__iter__ called
__next__ called
9
__next__ called
8
__next__ called
10
__next__ called
3
__next__ called
10
__next__ called
raising StopIteration

Discussion and illustrations

On point 1 and 2: getting an iterator and unreliable checks

Consider the following class:

class BasicIterable(object):
    def __getitem__(self, item):
        if item == 3:
            raise IndexError
        return item

Calling iter with an instance of BasicIterable will return an iterator without any problems because BasicIterable implements __getitem__.

>>> b = BasicIterable()
>>> iter(b)
<iterator object at 0x7f1ab216e320>

However, it is important to note that b does not have the __iter__ attribute and is not considered an instance of Iterable or Sequence:

>>> from collections import Iterable, Sequence
>>> hasattr(b, '__iter__')
False
>>> isinstance(b, Iterable)
False
>>> isinstance(b, Sequence)
False

This is why Fluent Python by Luciano Ramalho recommends calling iter and handling the potential TypeError as the most accurate way to check whether an object is iterable. Quoting directly from the book:

As of Python 3.4, the most accurate way to check whether an object x is iterable is to call iter(x) and handle a TypeError exception if it isn’t. This is more accurate than using isinstance(x, abc.Iterable) , because iter(x) also considers the legacy __getitem__ method, while the Iterable ABC does not.

On point 3: Iterating over objects which only provide __getitem__, but not __iter__

Iterating over an instance of BasicIterable works as expected: Python constructs an iterator that tries to fetch items by index, starting at zero, until an IndexError is raised. The demo object's __getitem__ method simply returns the item which was supplied as the argument to __getitem__(self, item) by the iterator returned by iter.

>>> b = BasicIterable()
>>> it = iter(b)
>>> next(it)
0
>>> next(it)
1
>>> next(it)
2
>>> next(it)
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
StopIteration

Note that the iterator raises StopIteration when it cannot return the next item and that the IndexError which is raised for item == 3 is handled internally. This is why looping over a BasicIterable with a for loop works as expected:

>>> for x in b:
...     print(x)
...
0
1
2

Here's another example in order to drive home the concept of how the iterator returned by iter tries to access items by index. WrappedDict does not inherit from dict, which means instances won't have an __iter__ method.

class WrappedDict(object): # note: no inheritance from dict!
    def __init__(self, dic):
        self._dict = dic

    def __getitem__(self, item):
        try:
            return self._dict[item] # delegate to dict.__getitem__
        except KeyError:
            raise IndexError

Note that calls to __getitem__ are delegated to dict.__getitem__ for which the square bracket notation is simply a shorthand.

>>> w = WrappedDict({-1: 'not printed',
...                   0: 'hi', 1: 'StackOverflow', 2: '!',
...                   4: 'not printed', 
...                   'x': 'not printed'})
>>> for x in w:
...     print(x)
... 
hi
StackOverflow
!

On point 4 and 5: iter checks for an iterator when it calls __iter__:

When iter(o) is called for an object o, iter will make sure that the return value of __iter__, if the method is present, is an iterator. This means that the returned object must implement __next__ (or next in Python 2) and __iter__. iter cannot perform any sanity checks for objects which only provide __getitem__, because it has no way to check whether the items of the object are accessible by integer index.

class FailIterIterable(object):
    def __iter__(self):
        return object() # not an iterator

class FailGetitemIterable(object):
    def __getitem__(self, item):
        raise Exception

Note that constructing an iterator from FailIterIterable instances fails immediately, while constructing an iterator from FailGetItemIterable succeeds, but will throw an Exception on the first call to __next__.

>>> fii = FailIterIterable()
>>> iter(fii)
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
TypeError: iter() returned non-iterator of type 'object'
>>>
>>> fgi = FailGetitemIterable()
>>> it = iter(fgi)
>>> next(it)
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
  File "/path/iterdemo.py", line 42, in __getitem__
    raise Exception
Exception

On point 6: __iter__ wins

This one is straightforward. If an object implements __iter__ and __getitem__, iter will call __iter__. Consider the following class

class IterWinsDemo(object):
    def __iter__(self):
        return iter(['__iter__', 'wins'])

    def __getitem__(self, item):
        return ['__getitem__', 'wins'][item]

and the output when looping over an instance:

>>> iwd = IterWinsDemo()
>>> for x in iwd:
...     print(x)
...
__iter__
wins

On point 7: your iterable classes should implement __iter__

You might ask yourself why most builtin sequences like list implement an __iter__ method when __getitem__ would be sufficient.

class WrappedList(object): # note: no inheritance from list!
    def __init__(self, lst):
        self._list = lst

    def __getitem__(self, item):
        return self._list[item]

After all, iteration over instances of the class above, which delegates calls to __getitem__ to list.__getitem__ (using the square bracket notation), will work fine:

>>> wl = WrappedList(['A', 'B', 'C'])
>>> for x in wl:
...     print(x)
... 
A
B
C

The reasons your custom iterables should implement __iter__ are as follows:

  1. If you implement __iter__, instances will be considered iterables, and isinstance(o, collections.Iterable) will return True.
  2. If the the object returned by __iter__ is not an iterator, iter will fail immediately and raise a TypeError.
  3. The special handling of __getitem__ exists for backwards compatibility reasons. Quoting again from Fluent Python:

That is why any Python sequence is iterable: they all implement __getitem__ . In fact, the standard sequences also implement __iter__, and yours should too, because the special handling of __getitem__ exists for backward compatibility reasons and may be gone in the future (although it is not deprecated as I write this).

share|improve this answer

I often find convenient, inside my scripts, to define an iterable function. (Now incorporates Alfe's suggested simplification):

import collections

def iterable(obj):
    return isinstance(obj, collections.Iterable):

so you can test if any object is iterable in the very readable form

if iterable(obj):
    # act on iterable
else:
    # not iterable

as you would do with thecallable function

EDIT: if you have numpy installed, you can simply do: from numpy import iterable, which is simply something like

def iterable(obj):
    try: iter(obj)
    except: return False
    return True

If you do not have numpy, you can simply implement this code, or the one above.

share|improve this answer
2  
Whenever you do sth like if x: return True else: return False (with x being boolean) you can write this as return x. In your case return isinstance(…) without any if. – Alfe May 7 '13 at 21:34
    
Since you acknowledge that Alfe's solution is better, why didn't you edit your answer to simply say that? Instead, you now have BOTH versions in your answer. Unnecessary verbosity. Submitting an edit to fix this. – ToolmakerSteve Dec 12 '13 at 23:21
1  
You should catch "TypeError" in the ` except: return False ` line. Catching everything is a bad pattern. – Mariusz Jamro Jul 3 '14 at 7:51
    
Know that. I translated that piece of code from the NumPy library, which uses the generic exception. – fmonegaglia Aug 25 '14 at 13:51

According to the Python 2 Glossary, iterables are

all sequence types (such as list, str, and tuple) and some non-sequence types like dict and file and objects of any classes you define with an __iter__() or __getitem__() method. Iterables can be used in a for loop and in many other places where a sequence is needed (zip(), map(), ...). When an iterable object is passed as an argument to the built-in function iter(), it returns an iterator for the object.

Of course, given the general coding style for Python based on the fact that it's “Easier to ask for forgiveness than permission.”, the general expectation is to use

try:
    for i in object_in_question:
        do_something
except TypeError:
    do_something_for_non_iterable

But if you need to check it explicitly, you can test for an iterable by hasattr(object_in_question, "__iter__") or hasattr(object_in_question, "__getitem__"). You need to check for both, because strs don't have an __iter__ method (at least not in Python 2, in Python 3 they do) and because generator objects don't have a __getitem__ method.

share|improve this answer

The easiest way, respecting the python's duck typing, is to catch the error (Python knows perfectly what does it expect from an object to become an iterator):

class A(object):
    def __getitem__(self, item):
        return something

class B(object):
    def __iter__(self):
        # return a compliant iterator. just an example
        return iter([])

class C(object):
    def __iter__(self):
        # return crap
        return 1

class D(object): pass

def iterable(obj):
    try:
        iter(obj)
        return True
    except:
        return False

assert iterable(A())
assert iterable(B())
assert iterable(C())
assert not iterable(D())

Notes:

  1. It is irrelevant the distinction whether the object is not iterable, or a buggy __iter__ has been implemented, if the exception type is the same: anyway you will not be able to iterate the object.
  2. I think I understand your concern: How does callable exists as a check if I could also rely on duck typing to raise an AttributeError if __call__ is not defined for my object, but that's not the case for iterable checking? Don't know the answer, but you can either implement the function I (and other users) gave, or just catch the exception in your code (your implementation in that part will be like the function I wrote - Just ensure you isolate the iterator creation from the rest of the code so you can capture the exception and distinguish it from another TypeError.
share|improve this answer
def is_iterable(x):
    try:
        0 in x
    except TypeError:
        return False
    else:
        return True

This will say yes to all manner of iterable objects, but it will say no to strings. (That's what I want for example when a recursive function could take a string or a container of strings. In that situation, asking forgiveness may lead to obfuscode, and it's better to ask permission first.)

import numpy

class Yes:
    def __iter__(self):
        yield 1;
        yield 2;
        yield 3;

class No:
    pass

class Nope:
    def __iter__(self):
        return 'nonsense'

assert is_iterable(Yes())
assert is_iterable(range(3))
assert is_iterable((1,2,3))   # tuple
assert is_iterable([1,2,3])   # list
assert is_iterable({1,2,3})   # set
assert is_iterable({1:'one', 2:'two', 3:'three'})   # dictionary
assert is_iterable(numpy.array([1,2,3]))
assert is_iterable(bytearray("not really a string", 'utf-8'))

assert not is_iterable(No())
assert not is_iterable(Nope())
assert not is_iterable("string")
assert not is_iterable(42)
assert not is_iterable(True)
assert not is_iterable(None)

Many other strategies here will say yes to strings. Use them if that's what you want.

import collections
import numpy

assert isinstance("string", collections.Iterable)
assert isinstance("string", collections.Sequence)
assert numpy.iterable("string")
assert iter("string")
assert hasattr("string", '__getitem__')

The O.P. hasattr(x, '__iter__') approach will also say no to strings, but thanks @LuisMasuelli for noticing it will let you down on a buggy __iter__.

Note, in Python 3 True == is_iterable(b"string") and True == is_iterable("string".encode('utf-8')).

share|improve this answer

protected by jamylak Apr 10 '13 at 11:35

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