I have a function that takes the argument NBins. I want to make a call to this function with a scalar 50 or an array [0, 10, 20, 30]. How can I identify within the function, what the length of NBins is? or said differently, if it is a scalar or a vector?

I tried this:

>>> N=[2,3,5]
>>> P = 5
>>> len(N)
>>> len(P)
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
TypeError: object of type 'int' has no len()

As you see, I can't apply len to P, since it's not an array.... Is there something like isarray or isscalar in python?


  • 3
    Have you tried testing for it's type? Commented May 29, 2013 at 6:34

16 Answers 16

>>> import collections.abc
>>> isinstance([0, 10, 20, 30], collections.abc.Sequence) and not isinstance([0, 10, 20, 30], (str, unicode))
>>> isinstance(50, collections.abc.Sequence) and not isinstance(50, (str, unicode))

note: isinstance also supports a tuple of classes, check type(x) in (..., ...) should be avoided and is unnecessary.

You may also wanna check not isinstance(x, (str, unicode))

As noted by @2080 and also here this won't work for numpy arrays. eg.

>>> import collections.abc
>>> import numpy as np
>>> isinstance((1, 2, 3), collections.abc.Sequence)
>>> isinstance(np.array([1, 2, 3]), collections.abc.Sequence)

In which case you may try the answer from @jpaddison3:

>>> hasattr(np.array([1, 2, 3]), "__len__")
>>> hasattr([1, 2, 3], "__len__")
>>> hasattr((1, 2, 3), "__len__")

However as noted here, this is not perfect either, and will incorrectly (at least according to me) classify dictionaries as sequences whereas isinstance with collections.abc.Sequence classifies correctly:

>>> hasattr({"a": 1}, "__len__")
>>> from numpy.distutils.misc_util import is_sequence
>>> is_sequence({"a": 1})
>>> isinstance({"a": 1}, collections.abc.Sequence)

You could customise your solution to something like this, add more types to isinstance depending on your needs:

>>> isinstance(np.array([1, 2, 3]), (collections.abc.Sequence, np.ndarray))
>>> isinstance([1, 2, 3], (collections.abc.Sequence, np.ndarray))
  • 3
    thanks, I didn't imagine inverting list to get false for scalars... thanks
    – otmezger
    Commented May 29, 2013 at 6:39
  • 9
    While this is a great answer, collections.Sequence is an ABC for string as well, so that should be taken into account. I'm using something like if type(x) is not str and isinstance(x, collections.Sequence):. This isn't great, but it is reliable.
    – bbenne10
    Commented Aug 4, 2014 at 19:47
  • 3
    @bbenne10 sure, but avoid type, and also check not isinstance(x, (str, unicode)) on Python 2
    – jamylak
    Commented Feb 10, 2015 at 11:04
  • 1
    collections.Sequence --> collections.abc.Sequence may be required in Python 3.9 or 3.10.
    – Bob Stein
    Commented Aug 19, 2020 at 11:15
  • 2
    unfortunately, isinstance(np.array(1), (collections.abc.Sequence, np.ndarray)) (i.e., a numpy scalar) returns True, but np.array(1)[0] is an IndexError
    – scott
    Commented Mar 10, 2023 at 16:01

Previous answers assume that the array is a python standard list. As someone who uses numpy often, I'd recommend a very pythonic test of:

if hasattr(N, "__len__")
  • 29
    strings have a __len__ attribute (so I guess, not technically a scalar type)
    – xofer
    Commented Apr 17, 2014 at 16:49
  • 39
    if hasattr(N, '__len__') and (not isinstance(N, str)) would properly account for strings.
    – apdnu
    Commented Oct 13, 2014 at 19:32
  • 2
    Also account for dict on Python 3 Commented Jan 24, 2016 at 1:06
  • This does not work for Iterators. len(iter([1,2,3])) throws "TypeError: object of type 'list_iterator' has no len()"
    – Him
    Commented Feb 2, 2023 at 19:09

Combining @jamylak and @jpaddison3's answers together, if you need to be robust against numpy arrays as the input and handle them in the same way as lists, you should use

import numpy as np
isinstance(P, (list, tuple, np.ndarray))

This is robust against subclasses of list, tuple and numpy arrays.

And if you want to be robust against all other subclasses of sequence as well (not just list and tuple), use

import collections
import numpy as np
isinstance(P, (collections.Sequence, np.ndarray))

Why should you do things this way with isinstance and not compare type(P) with a target value? Here is an example, where we make and study the behaviour of NewList, a trivial subclass of list.

>>> class NewList(list):
...     isThisAList = '???'
>>> x = NewList([0,1])
>>> y = list([0,1])
>>> print x
[0, 1]
>>> print y
[0, 1]
>>> x==y
>>> type(x)
<class '__main__.NewList'>
>>> type(x) is list
>>> type(y) is list
>>> type(x).__name__
>>> isinstance(x, list)

Despite x and y comparing as equal, handling them by type would result in different behaviour. However, since x is an instance of a subclass of list, using isinstance(x,list) gives the desired behaviour and treats x and y in the same manner.

  • 4
    This is the answer that most suited my needs. I just added set, too. Because I don't want to be robust against dicts. isinstance(P, (list, tuple, set, np.ndarray))
    – Santiago
    Commented Feb 9, 2020 at 15:53

Is there an equivalent to isscalar() in numpy? Yes.

>>> np.isscalar(3.1)
>>> np.isscalar([3.1])
>>> np.isscalar(False)
>>> np.isscalar('abcd')
  • 7
    It would be better and an example :>>> np.isscalar('abcd') returns True. Commented Mar 19, 2016 at 8:03
  • 1
    thanks! this is a much more general example than any of the above and should be preferred. It's also a direct answer to the OP's question. Commented Jun 24, 2018 at 4:28
  • 3
    Nice. Although one gotcha is that isscalar(None) returns False. Numpy implements this as return (isinstance(num, generic) or type(num) in ScalarType or isinstance(num, numbers.Number)) Commented Jan 8, 2019 at 20:24
  • 8
    No, sadly. The numpy.isscalar() function suffers a number of irreconcilable design flaws and will probably be deprecated at some future revision. To paraphrase official documentation: "In almost all cases np.ndim(x) == 0 should be used instead of np.isscaler(x), as the former will also correctly return true for 0d arrays." A robust forward-compatible alternative to numpy.isscalar() would thus be to trivially wrap numpy.ndim(): e.g., def is_scalar(obj): return np.ndim(obj) == 0 Commented Feb 28, 2019 at 3:55
  • Actually this should not be upvoted because np.isscalar is confusing. Official doc suggested using np.array.ndim everywhere, i.e. np.isscalar(np.array(12)) is False while it should be considered as scalar since np.array(12).ndim is 0.
    – knh190
    Commented Jun 4, 2019 at 7:15

While, @jamylak's approach is the better one, here is an alternative approach

>>> N=[2,3,5]
>>> P = 5
>>> type(P) in (tuple, list)
>>> type(N) in (tuple, list)
  • 5
    It would have been great if the person who downvoted the answer would have given a reason too. Commented May 29, 2013 at 9:58
  • i've actually upvoted, but then realized that it deosn't work in 2.7:>>> p=[] >>> type(p) in (list) Traceback (most recent call last): File "<stdin>", line 1, in <module>
    – Oleg Gryb
    Commented Jun 12, 2014 at 1:14
  • @OlegGryb: Try type(p) in (list, ). Commented Jun 12, 2014 at 6:25
  • ah, it's a tuple on the right, not a list, got it, thanks and it works now. I regret, I can't upvote 2 times - the best solution so far :)
    – Oleg Gryb
    Commented Jun 12, 2014 at 17:42

Another alternative approach (use of class name property):

N = [2,3,5]
P = 5

type(N).__name__ == 'list'

type(P).__name__ == 'int'

type(N).__name__ in ('list', 'tuple')

No need to import anything.

  • 2
    There's no advantage to doing this than just type(N) is list or type(N) is int. And as other answers have mentioned, doing a strict type equality check is usually less preferable to an isinstance() check, which can account for subclasses.
    – Aaron D
    Commented Oct 21, 2022 at 10:12
  • Nice! Saves you when strings are fighting with other iterables!
    – Dut A.
    Commented Mar 28 at 17:58

Here is the best approach I have found: Check existence of __len__ and __getitem__.

You may ask why? The reasons includes:

  1. The popular method isinstance(obj, abc.Sequence) fails on some objects including PyTorch's Tensor because they do not implement __contains__.
  2. Unfortunately, there is nothing in Python's collections.abc that checks for only __len__ and __getitem__ which I feel are minimal methods for array-like objects.
  3. It works on list, tuple, ndarray, Tensor etc.

So without further ado:

def is_array_like(obj, string_is_array=False, tuple_is_array=True):
    result = hasattr(obj, "__len__") and hasattr(obj, '__getitem__') 
    if result and not string_is_array and isinstance(obj, (str, abc.ByteString)):
        result = False
    if result and not tuple_is_array and isinstance(obj, tuple):
        result = False
    return result

Note that I've added default parameters because most of the time you might want to consider strings as values, not arrays. Similarly for tuples.

  • This doesn't work well on scalar (TensorFlow) tensors, because they have a len method but raise an error if you try to call it on a scalar tensor: TypeError: Scalar tensor has no len(). Kind of annoying behaviour on the part of TensorFlow...
    – Ben Farmer
    Commented Jul 23, 2020 at 5:12
  • To deal with this I find myself first doing something like if hasattr(obj,"shape") and obj.shape==() to check for these "scalar array" cases.
    – Ben Farmer
    Commented Jul 23, 2020 at 5:37

To answer the question in the title, a direct way to tell if a variable is a scalar is to try to convert it to a float. If you get TypeError, it's not.

N = [1, 2, 3]
except TypeError:
    print('it is not a scalar')
    print('it is a scalar')
  • 3
    Is anything wrong with this answer? The chosen answer fails when doing isinstance(np.arange(10), collections.Sequence).
    – Stefano
    Commented Aug 4, 2020 at 20:43
>>> N=[2,3,5]
>>> P = 5
>>> type(P)==type(0)
>>> type([1,2])==type(N)
>>> type(P)==type([1,2])

I am surprised that such a basic question doesn't seem to have an immediate answer in python. It seems to me that nearly all proposed answers use some kind of type checking, that is usually not advised in python and they seem restricted to a specific case (they fail with different numerical types or generic iteratable objects that are not tuples or lists).

For me, what works better is importing numpy and using array.size, for example:

>>> a=1
>>> np.array(a)
Out[1]: array(1)

>>> np.array(a).size
Out[2]: 1

>>> np.array([1,2]).size
Out[3]: 2

>>> np.array('125')
Out[4]: 1

Note also:

>>> len(np.array([1,2]))

Out[5]: 2


>>> len(np.array(a))
TypeError                                 Traceback (most recent call last)
<ipython-input-40-f5055b93f729> in <module>()
----> 1 len(np.array(a))

TypeError: len() of unsized object
  • 1
    I'm also surprised that none of them seem to deal with generators either.
    – RhysC
    Commented Oct 12, 2016 at 7:41
  • It also doesn't work on mappings: >>> np.array({1:2, 3:4}).size == 1 Commented Nov 6, 2020 at 23:13
  • 1
    these are because the np.array function creates an array of dtype object, with a single element containing the dictionary (or the generator). It is different using np.array(list(a.items())).size or np.array(list(a.keys())).size gives a different result.
    – Vincenzooo
    Commented Nov 8, 2020 at 18:53

You can check data type of variable.

N = [2,3,5]
P = 5

It will give you out put as data type of P.

<type 'int'>

So that you can differentiate that it is an integer or an array.


Simply use size instead of len!

>>> from numpy import size
>>> N = [2, 3, 5]
>>> size(N)
>>> N = array([2, 3, 5])
>>> size(N)
>>> P = 5
>>> size(P)
  • 3
    NameError: name 'size' is not defined
    – thang
    Commented Nov 11, 2016 at 20:43
  • 1
    That's true. I was using numpy size without noticing it. You need: from numpy import size Commented Dec 4, 2016 at 9:55
  • 5
    np.size(5) and np.size([5]) are both == 1, so this doesn't correctly distinguish type (i.e., identify a scalar), which I believe is the goal.
    – michael
    Commented Jan 27, 2017 at 13:14
  • This is an interesting remark. Original question refers to isscalar, which is a Matlab function. In Matlab, there is absolutely no difference between a scalar and an array of size 1, may it be a vector or a N-dim array. IMHO, this is a plus for Matlab. Commented Feb 5, 2017 at 0:18
  • Madness. That would mean {} == {{}}.
    – John P
    Commented May 14, 2021 at 10:17

You can easily use function isinstance(object, classinfo) in Python.

>>> isinstance(5, list)

>>>  isinstance([2, 3, 5], list)

See ducomentation for this function.


Since the general guideline in Python is to ask for forgiveness rather than permission, I think the most pythonic way to detect a string/scalar from a sequence is to check if it contains an integer:

    1 in a
    print('{} is a sequence'.format(a))
except TypeError:
    print('{} is a scalar or string'.format(a))

Determining if something is a scalar is easier (there are fewer ambiguities) than determining if it is a sequence (array/list/vector, etc.).

as @jamylak notes, not numpy.distutils.misc_util.is_sequence will identify scalars well. It simply checks that the input is not a str AND does not have a __len__ attribute.

But just because something is not a scalar does not mean it is a sequence. As @jamylak notes, this also identifies dictionaries as sequences, which differs from collections.abc.Sequence (dict is Iterable, but not a Sequence).

collections.abc.Sequence returns True for a list but not for a numpy array (it also returns True for a str):

issubclass(type(np.array([1])), collections.abc.Sequence) == False

collections.abc.Iterable returns True for a (normal) numpy array, but unfortunately also returns True for a zero-dimensional numpy array:

issubclass(type(np.array(1)), collections.abc.Iterable) == True

which cannot actually be iterated over, indexed into, and does not have a __len__.

As the numpy documentation suggests, numpy.isscalar should not be used. However, their suggested alternative, np.ndim(x) == 0 also doesn't work as I would expect.

It correctly calls np.array(1) a scalar (np.ndim(np.array(1)) == 0), however, as noted in the numpy.isscalar documentation, it also calls almost everything that is not a list or np.array a scalar, including strings, dicts, and other objects.

The only thing I've found that reliably works is

def is_scalar(x):
    return issubclass(type(np.asarray(x)[()]), numbers.Number)

def is_sequence(x):
    if is_scalar(x):
        return False
    return np.ndim(x) > 0
is_scalar(1)               # True
is_scalar(np.array(1))     # True
is_scalar([1])             # False
is_scalar(np.array([1]))   # False
is_scalar('a string')      # False
is_scalar({'key': 10})     # False

is_sequence(1)             # False
is_sequence(np.array(1))   # False
is_sequence([1])           # True
is_sequence(np.array([1])) # True
is_sequence('a string')    # False
is_sequence({'key': 10})   # False

Note how both is_scalar and is_sequence call the str and dict neither a scalar nor a sequence


preds_test[0] is of shape (128,128,1) Lets check its data type using isinstance() function isinstance takes 2 arguments. 1st argument is data 2nd argument is data type isinstance(preds_test[0], np.ndarray) gives Output as True. It means preds_test[0] is an array.

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