2225

How do I get the number of elements in the list items?

items = ["apple", "orange", "banana"]

# There are 3 items.
2
  • 33
    You are obviously asking for the number of elements in the list. If a searcher comes here looking for the size of the object in memory, this is the actual question & answers they are looking for: How do I determine the size of an object in Python? Oct 31, 2016 at 14:37
  • @RussiaMustRemovePutin The title of this question was subsequently edited, so it seems unlikely that people with that question would end up here as it stands. Oct 15, 2022 at 6:35

11 Answers 11

2902

The len() function can be used with several different types in Python - both built-in types and library types. For example:

>>> len([1, 2, 3])
3
0
295

How do I get the length of a list?

To find the number of elements in a list, use the builtin function len:

items = []
items.append("apple")
items.append("orange")
items.append("banana")

And now:

len(items)

returns 3.

Explanation

Everything in Python is an object, including lists. All objects have a header of some sort in the C implementation.

Lists and other similar builtin objects with a "size" in Python, in particular, have an attribute called ob_size, where the number of elements in the object is cached. So checking the number of objects in a list is very fast.

But if you're checking if list size is zero or not, don't use len - instead, put the list in a boolean context - it is treated as False if empty, and True if non-empty.

From the docs

len(s)

Return the length (the number of items) of an object. The argument may be a sequence (such as a string, bytes, tuple, list, or range) or a collection (such as a dictionary, set, or frozen set).

len is implemented with __len__, from the data model docs:

object.__len__(self)

Called to implement the built-in function len(). Should return the length of the object, an integer >= 0. Also, an object that doesn’t define a __nonzero__() [in Python 2 or __bool__() in Python 3] method and whose __len__() method returns zero is considered to be false in a Boolean context.

And we can also see that __len__ is a method of lists:

items.__len__()

returns 3.

Builtin types you can get the len (length) of

And in fact we see we can get this information for all of the described types:

>>> all(hasattr(cls, '__len__') for cls in (str, bytes, tuple, list, 
                                            range, dict, set, frozenset))
True

Do not use len to test for an empty or nonempty list

To test for a specific length, of course, simply test for equality:

if len(items) == required_length:
    ...

But there's a special case for testing for a zero length list or the inverse. In that case, do not test for equality.

Also, do not do:

if len(items): 
    ...

Instead, simply do:

if items:     # Then we have some items, not empty!
    ...

or

if not items: # Then we have an empty list!
    ...

I explain why here but in short, if items or if not items is both more readable and more performant.

0
78

While this may not be useful due to the fact that it'd make a lot more sense as being "out of the box" functionality, a fairly simple hack would be to build a class with a length property:

class slist(list):
    @property
    def length(self):
        return len(self)

You can use it like so:

>>> l = slist(range(10))
>>> l.length
10
>>> print l
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]

Essentially, it's exactly identical to a list object, with the added benefit of having an OOP-friendly length property.

As always, your mileage may vary.

1
  • 26
    just so you know, you can just do length = property(len) and skip the one line wrapper function and keep the documentation / introspection of len with your property. Jun 13, 2016 at 2:17
26

Besides len you can also use operator.length_hint (requires Python 3.4+). For a normal list both are equivalent, but length_hint makes it possible to get the length of a list-iterator, which could be useful in certain circumstances:

>>> from operator import length_hint
>>> l = ["apple", "orange", "banana"]
>>> len(l)
3
>>> length_hint(l)
3

>>> list_iterator = iter(l)
>>> len(list_iterator)
TypeError: object of type 'list_iterator' has no len()
>>> length_hint(list_iterator)
3

But length_hint is by definition only a "hint", so most of the time len is better.

I've seen several answers suggesting accessing __len__. This is all right when dealing with built-in classes like list, but it could lead to problems with custom classes, because len (and length_hint) implement some safety checks. For example, both do not allow negative lengths or lengths that exceed a certain value (the sys.maxsize value). So it's always safer to use the len function instead of the __len__ method!

14

And for completeness (primarily educational), it is possible without using the len() function. I would not condone this as a good option DO NOT PROGRAM LIKE THIS IN PYTHON, but it serves a purpose for learning algorithms.

def count(list):   # list is an iterable object but no type checking here!
    item_count = 0
    for item in list:
        item_count += 1
    return item_count

count([1,2,3,4,5])

(The list object must be iterable, implied by the for..in stanza.)

The lesson here for new programmers is: You can’t get the number of items in a list without counting them at some point. The question becomes: when is a good time to count them? For example, high-performance code like the connect system call for sockets (written in C) connect(int sockfd, const struct sockaddr *addr, socklen_t addrlen);, does not calculate the length of elements (giving that responsibility to the calling code). Notice that the length of the address is passed along to save the step of counting the length first? Another option: computationally, it might make sense to keep track of the number of items as you add them within the object that you pass. Mind that this takes up more space in memory. See Naftuli Kay‘s answer.

Example of keeping track of the length to improve performance while taking up more space in memory. Note that I never use the len() function because the length is tracked:

class MyList(object):
    def __init__(self):
        self._data = []
        self.length = 0 # length tracker that takes up memory but makes length op O(1) time
        

        # the implicit iterator in a list class
    def __iter__(self):
        for elem in self._data:
            yield elem
            
    def add(self, elem):
        self._data.append(elem)
        self.length += 1
            
    def remove(self, elem):
        self._data.remove(elem)
        self.length -= 1
            
mylist = MyList()
mylist.add(1)
mylist.add(2)
mylist.add(3)
print(mylist.length) # 3
mylist.remove(3)
print(mylist.length) # 2
5
  • 2
    Why for item in list[:]:? Why not for item in list:? Also, I'd use += 1 to increment. Apr 30, 2019 at 19:13
  • 4
    If we're going down the rabbit hole of "don't do this but it's fun", I offer length = max(enumerate(list))[0] + 1. Dec 8, 2020 at 21:56
  • 2
    @KirkStrauser Haha, I laughed at this clever avoidance on len() May 15, 2021 at 19:51
  • 1
    @JonathanKomar: The [:] in list[:] is not a "range specifier", that's slicing, which shallow copies the entire list for no reason. If you omitted the [:], it would not perform any such wasteful copies; it's not "beneficial to know it is implied", because it's not implied at all. I have no idea what "A list type [] is inferred as well" is supposed to mean, but there's no inferred types; the objects have types, and anything meeting the duck-typing requirements of what you've done will be accepted (be it list, tuple, str, etc.). Jan 21 at 3:27
  • @ShadowRanger As emphasized, "DO NOT PROGRAM LIKE THIS IN PYTHON [...] purpose for learning algorithms", you shouldn't be analyzing this answer for performance. I am happy you understand what is going on. I'll adjust the answer in this case. Jan 22 at 19:22
10

Answering your question as the examples also given previously:

items = []
items.append("apple")
items.append("orange")
items.append("banana")

print items.__len__()
4
  • 20
    In Python, names that start with underscores are semantically non-public methods and should not be used by users. Oct 26, 2016 at 15:10
  • 3
    1. __foo__: this is just a convention, a way for the Python system to use names that won't conflict with user names. 2. _foo: this is just a convention, a way for the programmer to indicate that the variable is private (whatever that means in Python). 3. __foo: this has real meaning: the interpreter replaces this name with _classname__foo as a way to ensure that the name will not overlap with a similar name in another class. * No other form of underscores have meaning in the Python world. * There's no difference between class, variable, global, etc in these conventions.
    – Shai Alon
    Dec 4, 2016 at 16:30
  • 6
    This Q&A explains why you shouldn't use the special methods directly as a user: stackoverflow.com/q/40272161/541136 Dec 4, 2016 at 18:42
  • @AaronHall but for len function it's almost the same. It might be faster for very large variables. However, I get your point and we should use len(obj) and not obj.__len__().
    – Shai Alon
    Feb 28, 2017 at 11:39
6

You can use the len() function to find the length of an iterable in python.

my_list = [1, 2, 3, 4, 5]
print(len(my_list))  # OUTPUT: 5

The len() function also works with strings:

my_string = "hello"
print(len(my_string))  # OUTPUT: 5

So to conclude, len() works with any sequence or collection (or any sized object that defines __len__).

0
5

There is an inbuilt function called len() in python which will help in these conditions.

>>> a = [1,2,3,4,5,6]
>>> len(a)  # Here the len() function counts the number of items in the list.
6

This will work slightly different in the case of string: it counts the characters.

>>> a = "Hello"
>>> len(a)
5
1
  • Saying it "counts" might be misleading because in most cases, it'll just be retrieving an integer that's already defined on the object, not iterating through and incrementing a number like "counts" implies.
    – wjandrea
    Jan 21 at 19:17
4

There are three ways that you can find the length of the elements in the list. I will compare the 3 methods with performance analysis here.

Method 1: Using len()

items = []
items.append("apple")
items.append("orange")
items.append("banana")

print(len(items))

output:

3

Method 2: Using Naive Counter Method

items = []
items.append("apple")
items.append("orange")
items.append("banana")

counter = 0
for i in items:
    counter = counter + 1

print(counter)

output:

3

Method 3: Using length_hint()

items = []
items.append("apple")
items.append("orange")
items.append("banana")

from operator import length_hint
list_len_hint = length_hint(items)
print(list_len_hint)

output:

3

Performance Analysis – Naive vs len() vs length_hint()

Note: In order to compare, I am changing the input list into a large set that can give a good amount of time difference to compare the methods.

items = list(range(100000000))

# Performance Analysis
from operator import length_hint
import time

# Finding length of list
# using loop
# Initializing counter

start_time_naive = time.time()
counter = 0
for i in items:
    # incrementing counter
    counter = counter + 1
end_time_naive = str(time.time() - start_time_naive)

# Finding length of list
# using len()
start_time_len = time.time()
list_len = len(items)
end_time_len = str(time.time() - start_time_len)

# Finding length of list
# using length_hint()
start_time_hint = time.time()
list_len_hint = length_hint(items)
end_time_hint = str(time.time() - start_time_hint)

# Printing Times of each
print("Time taken using naive method is : " + end_time_naive)
print("Time taken using len() is : " + end_time_len)
print("Time taken using length_hint() is : " + end_time_hint)

Output:

Time taken using naive method is : 7.536813735961914
Time taken using len() is : 0.0
Time taken using length_hint() is : 0.0

Conclusion

It can be clearly seen that time taken for naive is very large compared to the other two methods, hence len() & length_hint() is the best choice to use.

1
  • 1
    This is terrible micro-benchmarking code. A single execution timed with time.time()? Learn to use the timeit module; there are so many confounding variables that it's impossible to draw any conclusions from your test beyond "of course looping and counting is slower". Jan 21 at 3:37
4

To get the number of elements in any sequential objects, your goto method in Python is len() eg.

a = range(1000) # range
b = 'abcdefghijklmnopqrstuvwxyz' # string
c = [10, 20, 30] # List
d = (30, 40, 50, 60, 70) # tuple
e = {11, 21, 31, 41} # set

len() method can work on all the above data types because they are iterable i.e You can iterate over them.

all_var = [a, b, c, d, e] # All variables are stored to a list
for var in all_var:
    print(len(var))

A rough estimate of the len() method

def len(iterable, /):
    total = 0
    for i in iterable:
        total += 1
    return total
5
  • "any iterable" -- That's incorrect. I think you mean "any sequence". Generators, for example: len(x for x in range(8)) -> TypeError: object of type 'generator' has no len().
    – wjandrea
    Jun 24, 2021 at 14:05
  • There is a slight difference between iterator and iterable. All iterators are iterable but not the otherwise. Kindly refer to this article for more explanation geeksforgeeks.org/python-difference-iterable-iterator/amp
    – Comsavvy
    Jul 12, 2022 at 9:36
  • @wjandrea: If we're going to be picky, it's any collection. Works just fine on sets and dicts (neither of which are sequences). Jan 21 at 3:39
  • @ShadowRanger True, good point, though the docs say "The argument may be a sequence or a collection". On the other hand, if we follow collections.abc, then any Sequence is a Collection by definition, but we only need a Sized object to get its length. So I think for the sake of this answer, it'd be beter to say "any object" and avoid overcomplicating things.
    – wjandrea
    Jan 21 at 18:47
  • After the corrections, this answer is still incorrect with regard to iterables. The len() method works on those data types not because they're iterable, but because they have a __len__() method, which is to say they have a size that's known ahead of time, before iteration. And I'm not sure how useful that rough estimate is where it actually does work on any (finite) iterable.
    – wjandrea
    Jan 21 at 18:55
4

Simple: use len(list) or list.__len__()

In terms of how len() actually works, this is its C implementation:

static PyObject *
builtin_len(PyObject *module, PyObject *obj)
/*[clinic end generated code: output=fa7a270d314dfb6c input=bc55598da9e9c9b5]*/
{
    Py_ssize_t res;

    res = PyObject_Size(obj);
    if (res < 0) {
        assert(PyErr_Occurred());
        return NULL;
    }
    return PyLong_FromSsize_t(res);
}

Py_ssize_t is the maximum length that the object can have. PyObject_Size() is a function that returns the size of an object. If it cannot determine the size of an object, it returns -1. In that case, this code block will be executed:

    if (res < 0) {
        assert(PyErr_Occurred());
        return NULL;
    }

And an exception is raised as a result. Otherwise, this code block will be executed:

    return PyLong_FromSsize_t(res);

res which is a C integer, is converted into a Python int (which is still called a "Long" in the C code because Python 2 had two types for storing integers) and returned.

3
  • 5
    Why does knowing, or knowing about the C implementation matter?
    – cs95
    Jun 5, 2019 at 3:37
  • Since this question isn't specific to CPython this answer may be misleading. PyPy, IronPython, ... can and do implement it differently.
    – MSeifert
    Nov 15, 2019 at 8:16
  • This isn't a useful answer, as it's just saying "len calls PyObject_Size()" and doesn't say what that does, which is "PyObject_Size() calls the sq_length or PyMapping_Size on the passed in object." Jan 12, 2021 at 17:12

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