2156

Is there a simple way to determine if a variable is a list, dictionary, or something else?

13
  • 50
    While in general I agree with you, there are situations where it is helpful to know. In this particular case I was doing some quick hacking that I eventually rolled back, so you are correct this time. But in some cases - when using reflection, for example - it is important to know what type of object you are dealing with. Feb 9, 2010 at 13:10
  • 71
    @S.Lott I'd disagree with that; by being able to know the type, you can deal with some pretty variant input and still do the right thing. It lets you work around interface issues inherent with relying on pure duck-typing (eg, the .bark() method on a Tree means something entirely different than on a Dog.) For example, you could make a function that does some work on a file that accepts a string (eg, a path), a path object, or a list. All have different interfaces, but the final result is the same: do some operation on that file.
    – Robert P
    Jul 21, 2011 at 21:33
  • 25
    @S.Lott I hoped it would be obvious that it's a contrived example; nonetheless it's a major failing point of duck typing, and one that try doesn't help with. For example, if you knew that a user could pass in a string or an array, both are index-able, but that index means something completely different. Simply relying on a try-catch in those cases will fail in unexpected and strange ways. One solution is to make a separate method, another to add a little type checking. I personally prefer polymorphic behavior over multiple methods that do almost the same thing...but that's just me :)
    – Robert P
    Jul 22, 2011 at 0:57
  • 23
    @S.Lott, what about unit testing? Sometimes you want your tests to verify that a function is returning something of the right type. A very real example is when you have class factory. Sep 24, 2012 at 16:23
  • 18
    For a less contrived example, consider a serializer/deserializer. By definition you are converting between user-supplied objects and a serialized representation. The serializer needs to determine the type of object you passed in, and you may not have adequate information to determine the deserialized type without asking the runtime (or at the very least, you may need it for sanity checking to catch bad data before it enters your system!)
    – Karl
    May 13, 2013 at 2:35

15 Answers 15

2330

There are two built-in functions that help you identify the type of an object. You can use type() if you need the exact type of an object, and isinstance() to check an object’s type against something. Usually, you want to use isinstance() most of the times since it is very robust and also supports type inheritance.


To get the actual type of an object, you use the built-in type() function. Passing an object as the only parameter will return the type object of that object:

>>> type([]) is list
True
>>> type({}) is dict
True
>>> type('') is str
True
>>> type(0) is int
True

This of course also works for custom types:

>>> class Test1 (object):
        pass
>>> class Test2 (Test1):
        pass
>>> a = Test1()
>>> b = Test2()
>>> type(a) is Test1
True
>>> type(b) is Test2
True

Note that type() will only return the immediate type of the object, but won’t be able to tell you about type inheritance.

>>> type(b) is Test1
False

To cover that, you should use the isinstance function. This of course also works for built-in types:

>>> isinstance(b, Test1)
True
>>> isinstance(b, Test2)
True
>>> isinstance(a, Test1)
True
>>> isinstance(a, Test2)
False
>>> isinstance([], list)
True
>>> isinstance({}, dict)
True

isinstance() is usually the preferred way to ensure the type of an object because it will also accept derived types. So unless you actually need the type object (for whatever reason), using isinstance() is preferred over type().

The second parameter of isinstance() also accepts a tuple of types, so it’s possible to check for multiple types at once. isinstance will then return true, if the object is of any of those types:

>>> isinstance([], (tuple, list, set))
True
17
  • 73
    I think it's clearer to use is instead of == as the types are singletons Feb 8, 2010 at 22:01
  • 20
    @gnibbler, In the cases you would be typechecking (which you shouldn't be doing to begin with), isinstance is the preferred form anyhow, so neither == or is need be used. Feb 8, 2010 at 22:50
  • 27
    @Mike Graham, there are times when type is the best answer. There are times when isinstance is the best answer and there are times when duck typing is the best answer. It's important to know all of the options so you can choose which is more appropriate for the situation. Feb 8, 2010 at 23:13
  • 7
    @gnibbler, That may be, though I haven't yet ran into the situation where type(foo) is SomeType would be better than isinstance(foo, SomeType). Feb 9, 2010 at 16:45
  • 6
    @poke: i totally agree about PEP8, but you’re attacking a strawman here: the important part of Sven’s argument wasn’t PEP8, but that you can use isinstance for your usecase (checking for a range of types) as well, and with as clean a syntax as well, which has the great advantage that you can capture subclasses. someone using OrderedDict would hate your code to fail because it just accepts pure dicts. Oct 27, 2012 at 11:12
221

Use type():

>>> a = []
>>> type(a)
<type 'list'>
>>> f = ()
>>> type(f)
<type 'tuple'>
0
45

It might be more Pythonic to use a try...except block. That way, if you have a class which quacks like a list, or quacks like a dict, it will behave properly regardless of what its type really is.

To clarify, the preferred method of "telling the difference" between variable types is with something called duck typing: as long as the methods (and return types) that a variable responds to are what your subroutine expects, treat it like what you expect it to be. For example, if you have a class that overloads the bracket operators with getattr and setattr, but uses some funny internal scheme, it would be appropriate for it to behave as a dictionary if that's what it's trying to emulate.

The other problem with the type(A) is type(B) checking is that if A is a subclass of B, it evaluates to false when, programmatically, you would hope it would be true. If an object is a subclass of a list, it should work like a list: checking the type as presented in the other answer will prevent this. (isinstance will work, however).

2
  • 16
    Duck typing isn't really about telling the difference, though. It is about using a common interface. Nov 18, 2011 at 19:31
  • 6
    Be careful -- most coding style guides recommend not using exception handling as part of the normal control flow of code, usually because it makes code difficult to read. try... except is a good solution when you want to deal with errors, but not when deciding on behavior based on type. Mar 12, 2016 at 12:02
37

On instances of object you also have the:

__class__

attribute. Here is a sample taken from Python 3.3 console

>>> str = "str"
>>> str.__class__
<class 'str'>
>>> i = 2
>>> i.__class__
<class 'int'>
>>> class Test():
...     pass
...
>>> a = Test()
>>> a.__class__
<class '__main__.Test'>

Beware that in python 3.x and in New-Style classes (aviable optionally from Python 2.6) class and type have been merged and this can sometime lead to unexpected results. Mainly for this reason my favorite way of testing types/classes is to the isinstance built in function.

2
  • 2
    Your point at the end is very important. type(obj) is Class wasn't working correctly, but isinstance did the trick. I understand that isinstance is preferred anyway, but it's more beneficial than just checking derived types, as suggested in the accepted answer.
    – mstbaum
    Feb 24, 2016 at 22:58
  • __class__ is mostly OK on Python 2.x, the only objects in Python which don't have __class__ attribute are old-style classes AFAIK. I don't understand your Python 3 concern, by the way - on such version, just every object has a __class__ attribute that points to the proper class. Jun 17, 2016 at 8:38
24

Determine the type of a Python object

Determine the type of an object with type

>>> obj = object()
>>> type(obj)
<class 'object'>

Although it works, avoid double underscore attributes like __class__ - they're not semantically public, and, while perhaps not in this case, the builtin functions usually have better behavior.

>>> obj.__class__ # avoid this!
<class 'object'>

type checking

Is there a simple way to determine if a variable is a list, dictionary, or something else? I am getting an object back that may be either type and I need to be able to tell the difference.

Well that's a different question, don't use type - use isinstance:

def foo(obj):
    """given a string with items separated by spaces, 
    or a list or tuple, 
    do something sensible
    """
    if isinstance(obj, str):
        obj = str.split()
    return _foo_handles_only_lists_or_tuples(obj)

This covers the case where your user might be doing something clever or sensible by subclassing str - according to the principle of Liskov Substitution, you want to be able to use subclass instances without breaking your code - and isinstance supports this.

Use Abstractions

Even better, you might look for a specific Abstract Base Class from collections or numbers:

from collections import Iterable
from numbers import Number

def bar(obj):
    """does something sensible with an iterable of numbers, 
    or just one number
    """
    if isinstance(obj, Number): # make it a 1-tuple
        obj = (obj,)
    if not isinstance(obj, Iterable):
        raise TypeError('obj must be either a number or iterable of numbers')
    return _bar_sensible_with_iterable(obj)

Or Just Don't explicitly Type-check

Or, perhaps best of all, use duck-typing, and don't explicitly type-check your code. Duck-typing supports Liskov Substitution with more elegance and less verbosity.

def baz(obj):
    """given an obj, a dict (or anything with an .items method) 
    do something sensible with each key-value pair
    """
    for key, value in obj.items():
        _baz_something_sensible(key, value)

Conclusion

  • Use type to actually get an instance's class.
  • Use isinstance to explicitly check for actual subclasses or registered abstractions.
  • And just avoid type-checking where it makes sense.
3
  • There's always try/except instead of checking explicitly. Sep 29, 2017 at 20:36
  • Presumably that's what the user will do if they aren't sure about the types they'll be passing in. I don't like to clutter a correct implementation with exception handling unless I have something very good to do with the exception. The exception raised should be enough to inform the user that they need to correct their usage. Sep 29, 2017 at 22:43
  • Lovely reminder here about why not to use __class__, which, when the object is a Mock is the only way I could get the supposed type, as type would just say Mock. There is a much better assertion to be had by using the return_value of the mocked class, BTW.
    – John
    Jul 23, 2022 at 18:01
14

You can use type() or isinstance().

>>> type([]) is list
True

Be warned that you can clobber list or any other type by assigning a variable in the current scope of the same name.

>>> the_d = {}
>>> t = lambda x: "aight" if type(x) is dict else "NOPE"
>>> t(the_d) 'aight'
>>> dict = "dude."
>>> t(the_d) 'NOPE'

Above we see that dict gets reassigned to a string, therefore the test:

type({}) is dict

...fails.

To get around this and use type() more cautiously:

>>> import __builtin__
>>> the_d = {}
>>> type({}) is dict
True
>>> dict =""
>>> type({}) is dict
False
>>> type({}) is __builtin__.dict
True
3
  • 2
    I'm not sure it's necessary to point out that shadowing the name of a builtin data type is bad for this case. Your dict string will also fail for lots of other code, like dict([("key1", "value1"), ("key2", "value2")]). The answer for those kinds of issues is "Then don't do that". Don't shadow builtin type names and expect things to work properly.
    – Blckknght
    May 31, 2014 at 22:12
  • 3
    I agree with you on the "don't do that" part. But indeed to tell someone not to do something you should at least explain why not and I figured this was a relevant opportunity to do just that. I meant for the cautious method to look ugly and illustrate why they might not want to do it, leaving them to decide.
    – deed02392
    Jun 4, 2014 at 15:39
  • type() doesn't work as expected on Python 2.x for classic instances. Jun 17, 2016 at 8:35
10

be careful using isinstance

isinstance(True, bool)
True
>>> isinstance(True, int)
True

but type

type(True) == bool
True
>>> type(True) == int
False
1
  • 1
    A useful remark
    – Say OL
    Mar 18, 2022 at 5:19
8

using type()

x='hello this is a string'
print(type(x))

output

<class 'str'>

to extract only the str use this

x='this is a string'
print(type(x).__name__)#you can use__name__to find class

output

str

if you use type(variable).__name__ it can be read by us

5

While the questions is pretty old, I stumbled across this while finding out a proper way myself, and I think it still needs clarifying, at least for Python 2.x (did not check on Python 3, but since the issue arises with classic classes which are gone on such version, it probably doesn't matter).

Here I'm trying to answer the title's question: how can I determine the type of an arbitrary object? Other suggestions about using or not using isinstance are fine in many comments and answers, but I'm not addressing those concerns.

The main issue with the type() approach is that it doesn't work properly with old-style instances:

class One:
    pass

class Two:
    pass


o = One()
t = Two()

o_type = type(o)
t_type = type(t)

print "Are o and t instances of the same class?", o_type is t_type

Executing this snippet would yield:

Are o and t instances of the same class? True

Which, I argue, is not what most people would expect.

The __class__ approach is the most close to correctness, but it won't work in one crucial case: when the passed-in object is an old-style class (not an instance!), since those objects lack such attribute.

This is the smallest snippet of code I could think of that satisfies such legitimate question in a consistent fashion:

#!/usr/bin/env python
from types import ClassType
#we adopt the null object pattern in the (unlikely) case
#that __class__ is None for some strange reason
_NO_CLASS=object()
def get_object_type(obj):
    obj_type = getattr(obj, "__class__", _NO_CLASS)
    if obj_type is not _NO_CLASS:
        return obj_type
    # AFAIK the only situation where this happens is an old-style class
    obj_type = type(obj)
    if obj_type is not ClassType:
        raise ValueError("Could not determine object '{}' type.".format(obj_type))
    return obj_type
5

In many practical cases instead of using type or isinstance you can also use @functools.singledispatch, which is used to define generic functions (function composed of multiple functions implementing the same operation for different types).

In other words, you would want to use it when you have a code like the following:

def do_something(arg):
    if isinstance(arg, int):
        ... # some code specific to processing integers
    if isinstance(arg, str):
        ... # some code specific to processing strings
    if isinstance(arg, list):
        ... # some code specific to processing lists
    ...  # etc

Here is a small example of how it works:

from functools import singledispatch


@singledispatch
def say_type(arg):
    raise NotImplementedError(f"I don't work with {type(arg)}")


@say_type.register
def _(arg: int):
    print(f"{arg} is an integer")


@say_type.register
def _(arg: bool):
    print(f"{arg} is a boolean")
>>> say_type(0)
0 is an integer
>>> say_type(False)
False is a boolean
>>> say_type(dict())
# long error traceback ending with:
NotImplementedError: I don't work with <class 'dict'>

Additionaly we can use abstract classes to cover several types at once:

from collections.abc import Sequence


@say_type.register
def _(arg: Sequence):
    print(f"{arg} is a sequence!")
>>> say_type([0, 1, 2])
[0, 1, 2] is a sequence!
>>> say_type((1, 2, 3))
(1, 2, 3) is a sequence!
3

As an aside to the previous answers, it's worth mentioning the existence of collections.abc which contains several abstract base classes (ABCs) that complement duck-typing.

For example, instead of explicitly checking if something is a list with:

isinstance(my_obj, list)

you could, if you're only interested in seeing if the object you have allows getting items, use collections.abc.Sequence:

from collections.abc import Sequence
isinstance(my_obj, Sequence) 

if you're strictly interested in objects that allow getting, setting and deleting items (i.e mutable sequences), you'd opt for collections.abc.MutableSequence.

Many other ABCs are defined there, Mapping for objects that can be used as maps, Iterable, Callable, et cetera. A full list of all these can be seen in the documentation for collections.abc.

3
value = 12
print(type(value)) # will return <class 'int'> (means integer)

or you can do something like this

value = 12
print(type(value) == int) # will return true
2

In general you can extract a string from object with the class name,

str_class = object.__class__.__name__

and using it for comparison,

if str_class == 'dict':
    # blablabla..
elif str_class == 'customclass':
    # blebleble..
1

type() is a better solution than isinstance(), particularly for booleans:

True and False are just keywords that mean 1 and 0 in python. Thus,

isinstance(True, int)

and

isinstance(False, int)

both return True. Both booleans are an instance of an integer. type(), however, is more clever:

type(True) == int

returns False.

1

For the sake of completeness, isinstance will not work for type checking of a subtype that is not an instance. While that makes perfect sense, none of the answers (including the accepted one) covers it. Use issubclass for that.

>>> class a(list):
...   pass
... 
>>> isinstance(a, list)
False
>>> issubclass(a, list)
True

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