1447

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 foolproof this is.

4
  • 27
    __getitem__ is also sufficient to make an object iterable
    – Kos
    Commented Jul 2, 2012 at 14:58
  • 4
    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
    Commented Jul 25, 2014 at 15:10
  • 12
    __getitem__ is also sufficient to make an object iterable ... if it starts at zero index. Commented Jul 8, 2017 at 10:16
  • 2
    __getitem__ is sufficient but not necessary. E.g. a generator object is iterable but it does not have the __getitem__.
    – Max
    Commented Jul 5, 2023 at 23:22

25 Answers 25

1062
  1. Checking for __iter__ works on sequence types, but it would fail on e.g. strings in Python 2. 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 as 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.

  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:

    from collections.abc import Iterable
    
    if isinstance(e, Iterable):
        # e is iterable
    

    However, this does not check for classes that are iterable through __getitem__.

22
  • 43
    [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. Commented Dec 23, 2009 at 12:39
  • 42
    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.
    – jfs
    Commented Dec 24, 2009 at 0:11
  • 92
    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
    Commented Dec 24, 2009 at 3:42
  • 17
    What if some_object throws TypeError caused by other reason(bugs etc.) too? How can we tell it from the "Not iterable TypeError"?
    – Shaung
    Commented Sep 13, 2011 at 7:34
  • 66
    Note that in Python 3: hasattr(u"hello", '__iter__') returns True
    – Carlos
    Commented Apr 21, 2014 at 2:27
715

Duck typing

try:
    iterator = iter(the_element)
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.

from collections.abc import Iterable   # import directly from collections for Python < 3.3

if isinstance(the_element, Iterable):
    # iterable
else:
    # not iterable

However, iter() is a bit more reliable as described by the documentation:

Checking isinstance(obj, Iterable) detects classes that are registered as Iterable or that have an __iter__() method, but it does not detect classes that iterate with the __getitem__() method. The only reliable way to determine whether an object is iterable is to call iter(obj).

10
  • 59
    From "Fluent Python" by Luciano Ramalho: 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.
    – Yurkol
    Commented Jun 11, 2017 at 7:11
  • 1
    In case you're thinking "oh I'll just isinstance(x, (collections.Iterable, collections.Sequence)) instead of iter(x)", note that this still won't detect an iterable object that implements only __getitem__ but not __len__. Use iter(x) and catch the exception.
    – Dale
    Commented May 12, 2018 at 19:03
  • 1
    @Hi-Angel sounds like a bug in PyUNO Notice that your error message says issubclass() instead of isinstance(). Commented Jul 23, 2019 at 5:28
  • 4
    Calling iter() over an object can be an expensive operation (see DataLoader in Pytorch, which forks/spawns multiple processes on iter()).
    – szali
    Commented Jul 25, 2019 at 10:04
  • 2
    It seems that enumerate() has the same effect as iter() (Python 3), which may simplify things a bit if the next thing you want to do is enumerating the sequence - no need for explicit iter() beforehand, as enumerate() will raise an appropriate exception by itself if necessary. Commented Nov 22, 2020 at 21:57
228
+50

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.abc.Iterable) will return True.
  2. If 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).

3
  • so it is safe to define a predicate is_iterable by returning True in the try block and False in the except TypeError block? Commented May 1, 2019 at 15:35
  • This is a great answer. I think it highlights the unintuitive and unfortunate nature of the getitem protocol. It should never have been added.
    – Neil G
    Commented Jul 29, 2019 at 2:29
  • can you use def isiterable(x): return hasattr(x, '__iter__') or hasattr(x, '__getitem__') instead? Its a bit faster in my testing Commented Mar 26 at 10:40
108

I've been studying this problem quite a bit lately. Based on that my conclusion is that nowadays this is the best approach:

from collections.abc import Iterable   # drop `.abc` with Python 2.7 or lower

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

The above has been recommended already earlier, but the general consensus has been that using iter() would be better:

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

We've used iter() in our code as well for this purpose, but I've lately started to get more and more annoyed by objects which only have __getitem__ being considered iterable. There are valid reasons to have __getitem__ in a non-iterable object and with them the above code doesn't work well. As a real life example we can use Faker. The above code reports it being iterable but actually trying to iterate it causes an AttributeError (tested with Faker 4.0.2):

>>> from faker import Faker
>>> fake = Faker()
>>> iter(fake)    # No exception, must be iterable
<iterator object at 0x7f1c71db58d0>
>>> list(fake)    # Ooops
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
  File "/home/.../site-packages/faker/proxy.py", line 59, in __getitem__
    return self._factory_map[locale.replace('-', '_')]
AttributeError: 'int' object has no attribute 'replace'

If we'd use insinstance(), we wouldn't accidentally consider Faker instances (or any other objects having only __getitem__) to be iterable:

>>> from collections.abc import Iterable
>>> from faker import Faker
>>> isinstance(Faker(), Iterable)
False

Earlier answers commented that using iter() is safer as the old way to implement iteration in Python was based on __getitem__ and the isinstance() approach wouldn't detect that. This may have been true with old Python versions, but based on my pretty exhaustive testing isinstance() works great nowadays. The only case where isinstance() didn't work but iter() did was with UserDict when using Python 2. If that's relevant, it's possible to use isinstance(item, (Iterable, UserDict)) to get that covered.

4
  • 1
    Also typing.Dict is considered iterable by iter(Dict) but list(Dict) fails with error TypeError: Parameters to generic types must be types. Got 0.. As expected isinstance(Dict, Iterable) returns false. Commented Apr 16, 2020 at 13:02
  • 3
    I came to the same conclusion, but for different reasons. Using iter caused some of our code that used "pre-caching" to slow down unnecessarily. If the __iter__ code is slow, so will calling iter... any time you just want to see if something is iterable.
    – thorwhalen
    Commented May 7, 2020 at 13:19
  • 3
    Would it be worth to add a note to that last bit, noting that Python 2 isn't actively being supported by the devs anymore, and shouldn't be used for new code if Python 3 is an option?
    – Gloweye
    Commented Jul 23, 2020 at 20:02
  • Just found a pretty weird corner case in which isinstance(obj, Iterable) fails: numpy 'arrays' of individual values. If you have 'obj = np.array(int(1)), numpy will happily say obj = array(1). The shape is an empty tuple, and len(obj)` returns TypeError: len() of unsized object. HOWEVER! If you write: isinstance(obj, Iterable) you get...True . Calamity Commented Jan 17, 2022 at 6:31
48

Since Python 3.5 you can use the typing module from the standard library for type related things:

from typing import Iterable

...

if isinstance(my_item, Iterable):
    print(True)
3
  • 1
    This will return True for single, string objects fyi.
    – waydegg
    Commented Jan 30, 2021 at 22:49
  • 5
    @waydegg Yes, strings are iterable.
    – Rotareti
    Commented Jan 31, 2021 at 11:35
  • 7
    In Python 3.6 this code doesn't work. In 3.7 it does work. It looks like it will be deprecated in 3.9. typing is for type-checking tools (e.g. MyPy, PyCharm) and doesn't guarantee this behaviour. I think you meant to import the Iterable class from collections.abc instead.
    – c z
    Commented Feb 26, 2021 at 10:19
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".

4
  • 11
    "duck typing" I believe? :)
    – willem
    Commented Dec 23, 2009 at 12:25
  • 10
    @willem: or "don't ask for permission but for forgiveness" ;-)
    – jldupont
    Commented Dec 23, 2009 at 12:29
  • 14
    @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
    Commented Nov 12, 2013 at 1:44
  • 1
    more about don't ask what Python can do for you, ask what you can do for Python to work
    – mins
    Commented Jun 14, 2021 at 13:39
24

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

But since Python 2.6 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 desirable 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 satisfy 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 satisfy 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 infrastructure pretty useful.

2
  • 14
    don't use bare except: in the example code for beginners. It promotes bad practice.
    – jfs
    Commented Dec 23, 2009 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. Commented Dec 24, 2009 at 17:17
21
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.

8
  • 4
    Technically, during iteration your computation might throw a TypeError and throw you off here, but basically yes.
    – Chris Lutz
    Commented Dec 23, 2009 at 12:22
  • 6
    @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
    Commented Dec 23, 2009 at 14:24
  • 2
    @willem: IronPython has slow (compared to CPython) exceptions.
    – jfs
    Commented Dec 24, 2009 at 0:01
  • 2
    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. Commented Jun 22, 2012 at 10:04
  • 2
    Shouldn't the exception object be caught by adding "as e" after TypeError instead of by adding ", e"? Commented Dec 12, 2016 at 12:53
18

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?

5
  • What about iterable(itertools.repeat(0))? :)
    – badp
    Commented Dec 23, 2009 at 12:24
  • 7
    @badp, the (x for x in a) just creates a generator, it doesn't do any iteration on a. Commented Dec 23, 2009 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
    Commented Dec 15, 2012 at 20:05
  • Isn't for _ in a: break more straightforward ? Is it slower ? Commented Oct 23, 2015 at 22:16
  • 3
    @Mr_and_Mrs_D that's bad if the tested object is an iterator that's iterated over afterwards (it will be 1 item short since it's position can't be reset), creating garbage generators doesn't iterate over the object as they're not iterated over, though I'm not certain that it will 100% raise a TypeError if not iterable.
    – Tcll
    Commented Aug 14, 2018 at 14:40
15

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...except 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
4
  • 3
    Nice, but why not use the collections module as proposed in stackoverflow.com/questions/1952464/…? Seems more expressive to me. Commented May 3, 2011 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
    Commented Nov 25, 2011 at 12:04
  • 50
    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? Commented May 18, 2012 at 14:52
  • 16
    This is incorrect. An iterable itself does not support contains, at least with Python 3.4. Commented Jan 21, 2015 at 5:39
14

I found a nice solution here:

isiterable = lambda obj: isinstance(obj, basestring) \
    or getattr(obj, '__iter__', False)
11

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.

9

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.

5
  • 3
    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
    Commented May 7, 2013 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. Commented Dec 12, 2013 at 23:21
  • 2
    You should catch "TypeError" in the ` except: return False ` line. Catching everything is a bad pattern. Commented Jul 3, 2014 at 7:51
  • Know that. I translated that piece of code from the NumPy library, which uses the generic exception. Commented Aug 25, 2014 at 13:51
  • Just because a code is taken from NumPy doesn't mean it's good... pattern or not, the only time catching everything should be done is if you're explicitly error handling inside your program.
    – Tcll
    Commented Aug 14, 2018 at 15:49
5

has a built-in function like that:

from pandas.util.testing import isiterable
1
  • this however just looks whether there is __iter__ and not really cares about sequences and similar.
    – ead
    Commented Mar 3, 2020 at 8:02
4
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 in Python 2. (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__')

Note: is_iterable() will say yes to strings of type bytes and bytearray.

  • bytes objects in Python 3 are iterable True == is_iterable(b"string") == is_iterable("string".encode('utf-8')) There is no such type in Python 2.
  • bytearray objects in Python 2 and 3 are iterable True == is_iterable(bytearray(b"abc"))

The O.P. hasattr(x, '__iter__') approach will say yes to strings in Python 3 and no in Python 2 (no matter whether '' or b'' or u''). Thanks to @LuisMasuelli for noticing it will also let you down on a buggy __iter__.

4

It's always eluded me as to why python has callable(obj) -> bool but not iterable(obj) -> bool...
surely it's easier to do hasattr(obj,'__call__') even if it is slower.

Since just about every other answer recommends using try/except TypeError, where testing for exceptions is generally considered bad practice among any language, here's an implementation of iterable(obj) -> bool I've grown more fond of and use often:

For python 2's sake, I'll use a lambda just for that extra performance boost...
(in python 3 it doesn't matter what you use for defining the function, def has roughly the same speed as lambda)

iterable = lambda obj: hasattr(obj,'__iter__') or hasattr(obj,'__getitem__')

Note that this function executes faster for objects with __iter__ since it doesn't test for __getitem__.

Most iterable objects should rely on __iter__ where special-case objects fall back to __getitem__, though either is required for an object to be iterable.
(and since this is standard, it affects C objects as well)

7
  • he doesn't provide working code, let alone talk about python performance... although this answer was really just for convenience like I've seen done numerous times on here.
    – Tcll
    Commented Mar 22, 2019 at 1:23
  • "where testing for exceptions is generally considered bad practice among any language" Python is not included in your generalization. Python handles exceptions very efficiently, and idiomatic Python necessitates the use of try...except blocks as part of its duck typing philosophy as mentioned in numerous answers to this question.
    – Bobort
    Commented May 22, 2023 at 16:28
  • "Python handles exceptions very efficiently" I'm afraid I have to heavily disagree, except is one of the slowest, most inefficient, keywords in python, it has it's purpose, but should not be used everywhere, unless you want the lowest performing code imaginable, given except is actually invoked... try is faster than if, but except is much slower than else due to exception lookups.
    – Tcll
    Commented May 23, 2023 at 0:03
  • There is so much literature on the EAFP philosophy employed by Python, even on StackOverflow. Python, when compared to other languages such as C++, handles exceptions more efficiently because it is a higher level language. It's science--the algorithm is cheaper because of the way that Python processes the code. I liked the answer in this question: stackoverflow.com/questions/1835756/using-try-vs-if-in-python
    – Bobort
    Commented May 24, 2023 at 2:52
  • "Python, when compared to other languages such as C++, handles exceptions more efficiently because it is a higher level language" efficiency has nothing to do with being higher level, it has everything to do with how the CPU ultimately executes the bytecode/machine-code, which ultimately yes, python is more efficient since exceptions are PyObject instances in C, where as exceptions in C++ are something completely different, but that still doesn't change the fact that except is the most inefficient keyword in python, and makes your execution incredibly slow if invoked often.
    – Tcll
    Commented May 24, 2023 at 19:36
4

There are a lot of ways to check if an object is iterable:

from collections.abc import Iterable
myobject = 'Roster'
  
if isinstance(myobject , Iterable):
    print(f"{myobject } is iterable") 
else:
   print(f"strong text{myobject } is not iterable")
2

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?

    I 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.

2

The isiterable func at the following code returns True if object is iterable. if it's not iterable returns False

def isiterable(object_):
    return hasattr(type(object_), "__iter__")

example

fruits = ("apple", "banana", "peach")
isiterable(fruits) # returns True

num = 345
isiterable(num) # returns False

isiterable(str) # returns False because str type is type class and it's not iterable.

hello = "hello dude !"
isiterable(hello) # returns True because as you know string objects are iterable
2
  • 3
    so many detailed answers above with many upvotes and you throw in an unexplained answer... meh
    – Nrzonline
    Commented Sep 15, 2017 at 22:12
  • Please do not post bare code. Also include an explanation of what this is doing. Commented Sep 16, 2017 at 1:32
2

In my code I used to check for non iterable objects:

hasattr(myobject,'__trunc__')

This is quite quick and can be used to check for iterables too (use not).

I'm not 100% sure if this solution works for all objects, maybe other can give a some more background on it. __trunc__ method seams to be related to numerical types (all objects that can be rounded to integers needs it). But I didn't found any object that contains __trunc__ together with __iter__ or __getitem__.

1

Instead of checking for the __iter__ attribute, you could check for the __len__ attribute, which is implemented by every python builtin iterable, including strings.

>>> hasattr(1, "__len__")
False
>>> hasattr(1.3, "__len__")
False
>>> hasattr("a", "__len__")
True
>>> hasattr([1,2,3], "__len__")
True
>>> hasattr({1,2}, "__len__")
True
>>> hasattr({"a":1}, "__len__")
True
>>> hasattr(("a", 1), "__len__")
True

None-iterable objects would not implement this for obvious reasons. However, it does not catch user-defined iterables that do not implement it, nor do generator expressions, which iter can deal with. However, this can be done in a line, and adding a simple or expression checking for generators would fix this problem. (Note that writing type(my_generator_expression) == generator would throw a NameError. Refer to this answer instead.)

You can use GeneratorType from types:

>>> import types
>>> types.GeneratorType
<class 'generator'>
>>> gen = (i for i in range(10))
>>> isinstance(gen, types.GeneratorType)
True

--- accepted answer by utdemir

(This makes it useful for checking if you can call len on the object though.)

2
  • unfortunately not all iterable objects use __len__... for this case, it's usually the improper use of calculating distance between 2 objects. where obj.dist() could be easily substituted.
    – Tcll
    Commented Aug 14, 2018 at 16:32
  • Yeah. Most user defined iterables implement iter and getitem but not len. However, built in types do, and if you want to check if you can call len function on it, checking for len is more secure. But you are right. Commented Aug 14, 2018 at 23:18
1

Not really "correct" but can serve as quick check of most common types like strings, tuples, floats, etc...

>>> '__iter__' in dir('sds')
True
>>> '__iter__' in dir(56)
False
>>> '__iter__' in dir([5,6,9,8])
True
>>> '__iter__' in dir({'jh':'ff'})
True
>>> '__iter__' in dir({'jh'})
True
>>> '__iter__' in dir(56.9865)
False
0

Kinda late to the party but I asked myself this question and saw this then thought of an answer. I don't know if someone already posted this. But essentially, I've noticed that all iterable types have __getitem__() in their dict. This is how you would check if an object was an iterable without even trying. (Pun intended)

def is_attr(arg):
    return '__getitem__' in dir(arg)
5
  • 1
    Unfortunately, this is unreliable. Example
    – timgeb
    Commented Jan 26, 2020 at 12:42
  • 1
    Set objects are another counterexample. Commented Apr 13, 2020 at 4:28
  • How is that a pun?
    – Willwsharp
    Commented Jun 25, 2020 at 20:14
  • Maybe write '__iter__' in dir(arg) instead of '__getitem__' in dir(arg) Commented Mar 23, 2023 at 22:49
  • performance is O(n), since dir() returns a list, and set(dir()) is even slower since it's performance is O(n)(1), due to needing to convert the list into a set before calling set.__contains__, which is O(1), but as stated earlier, not all iterables use __getitem__, thus it's unreliable.
    – Tcll
    Commented May 23, 2023 at 0:32
0

After experimenting with various functions, I believe this is the fastest way to reliably tell if an object is iterable, although it involves bare exceptions:

def isiterable(x):
    if  hasattr(x, '__iter__'): return not isinstance(x, type)
    if hasattr(x, '__getitem__'):
        try:
            x[0]
            return True
        except Exception:
            return False
    return False

This is not a perfect solution, but as I explain below, this one is among the most reliable ones. There are two edge cases that I can think of, where this function will fail: first is an non-iterable object that has a __getitem__ method and x[0]. Second is an iterable type object.

If you don't want bare exceptions, there are a few methods I've described below, and they all have different drawbacks.

What can be iterable

In order to be iterable, an object needs either __getitem__ or __iter__ methods.

However some objects with __getitem__ are not iterable, for example:

class Getitem_ButNotIterable:
    def __init__(self): self.dict_ = {"a":1, "b":2}
    def __getitem__(self, item:str): return self.dict_[item]

for i in Getitem_ButNotIterable(): 
    pass

>> KeyError: 0

Worth mentioning that running iter(Getitem_ButNotIterable()) will not raise an exception unless you actually try to iterate over it, so that method isn't fully reliable.

And types can have __iter__ attribute, but they are (usually) not iterable either.

hasattr(list, "__iter__") >> True
for i in list: pass >> TypeError: 'type' object is not iterable

However types can actually be iterable, that is if their metaclass has __iter__ method.

The hardest edge case is this one:

class Getitem_ButNotIterable2:
    def __init__(self): self.dict_ = {0:1, "b":2}
    def __getitem__(self, item:str): return self.dict_[item]

If you try to iterate through this, it will call x[0] which returns 0, but then it will call x[1] which will raise an KeyError, which iter does not catch. Unfortunately I don't think there is an easy way to detect those.

Methods of testing if object is iterable

To test various methods, I created 40 different iterables and non-iterables, and tried a bunch of functions for 1_000_000 times on each iterable/non-iterable, and wrote the total time everything took. Method at the beginning takes 8 seconds for reference.


from collections.abc import Iterable
def is_iterable1(x): 
    return isinstance(x, Iterable)

Took 17 seconds. This checks if object has an __iter__ method, therefore it will fail to recognize iterable objects that only have __getitem__.

Worth mentioning that if you use the deprecated typing.Iterable instead, the time goes up to 50 seconds.


def is_iterable2(x): 
    return hasattr(x, "__iter__")

Took 5 seconds. This is almost equivalent to isinstance(x, Iterable), however are is additional false positives: types, like is_iterable2(list) will return True.


def is_iterable3(x): 
    return hasattr(x, "__iter__") and hasattr(x, "__getitem__")

Took 7 seconds. Unlike above two methods, this will recognize iterable __getitem__ objects, but also give false positives on non-iterable __getitem__ objects, and types with those methods


def is_iterable4(x):
    try:
        iter(x)
        return True
    except TypeError:
       return False
    return True

Took 36 seconds. This will produce a false positive on non-iterable objects that have __getitem__. Changing iter(x) to (i for i in x) is equivalent. This is a good method if you don't want bare exceptions.


def is_iterable5(x):
    try:
        0 in x
    except TypeError:
        return False
    else:
        return True

Took 50 seconds. This will raise an exception on non-iterable objects that have __getitem__.


def is_iterable6(x):
    try: 
        for _ in x: return True
    except Exception: return False
    return True

Took 33 seconds. We are getting into bare exceptions now, but I can't think of any other ways to make it more reliable. There can be some edge cases where you don't want to iterate over some object outside of the usual usage, as this could mess the internal state.


def is_iterable7(x):
    if  hasattr(x.__class__, '__iter__'): return True
    if hasattr(x, '__getitem__'):
        try:
            x[0]
            return True
        except Exception:
            return False
    return False

Took 23 seconds. Correctly evaluates almost everything as it won't give a true negative for types that have __iter__ method. There are still two edge cases: non-iterable object with __getitem__, and iterable classes, ones that have a metaclass with __iter__ method. However I don't think it is possible to get easily more reliable than this,


def is_iterable8(x):
    if  hasattr(x, '__iter__'): return not isinstance(x, type)
    if hasattr(x, '__getitem__'):
        try:
            x[0]
            return True
        except Exception:
            return False
    return False

Took 8 seconds. Should be equivalent to function above, so, unless you expect classes with metaclasses with __iter__, and if you don't mind bare exceptions, this seems to be the best way to tell if an object is iterable.


Bonus:

def super_slow_but_is_almost_definitely_iterable(x):
    try:
        for i,v in enumerate(x):
            if i == 1000:break
        return True
    except Exception: return False

Took just 40 seconds, surprisingly. This is the most reliable way, except it involves iterating so in some edge cases it will mess up the internal state. Also if you have objects that are expensive to iterate through, this will become extremely slow.

-1

Maybe just write hasattr(obj, "__iter__")

Or... something like this might work:

def is_iterable(obj: object) -> bool:
    return hasattr(obj, "__iter__")  

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