Iterators are objects that can be iterated upon. In this tutorial, you will learn how iterator works and how you can build your own iterator using iter and next methods.
Iterators in Python
Iterators are everywhere in Python. They are elegantly implemented within
for loops, comprehensions, generators etc. but are hidden in plain sight.
Iterator in Python is simply an object that can be iterated upon. An object which will return data, one element at a time.
Technically speaking, a Python iterator object must implement two special methods,
__next__(), collectively called the iterator protocol.
iter() function (which in turn calls the
__iter__() method) returns an iterator from them.
Iterating Through an Iterator
We use the
next() function to manually iterate through all the items of an iterator. When we reach the end and there is no more data to be returned, it will raise the
StopIteration Exception. Following is an example.
# define a list my_list = [4, 7, 0, 3] # get an iterator using iter() my_iter = iter(my_list) # iterate through it using next() # Output: 4 print(next(my_iter)) # Output: 7 print(next(my_iter)) # next(obj) is same as obj.__next__() # Output: 0 print(my_iter.__next__()) # Output: 3 print(my_iter.__next__()) # This will raise error, no items left next(my_iter)
4 7 0 3 Traceback (most recent call last): File "<string>", line 24, in <module> next(my_iter) StopIteration
A more elegant way of automatically iterating is by using the for loop. Using this, we can iterate over any object that can return an iterator, for example list, string, file etc.
>>> for element in my_list: ... print(element) ... 4 7 0 3
Working of for loop for Iterators
As we see in the above example, the
for loop was able to iterate automatically through the list.
In fact the
for loop can iterate over any iterable. Let’s take a closer look at how the
for loop is actually implemented in Python.
for element in iterable: # do something with element
Is actually implemented as.
# create an iterator object from that iterable iter_obj = iter(iterable) # infinite loop while True: try: # get the next item element = next(iter_obj) # do something with element except StopIteration: # if StopIteration is raised, break from loop break
So internally, the
for loop creates an iterator object,
iter_obj by calling
iter() on the iterable.
for loop is actually an infinite while loop.
Inside the loop, it calls
next() to get the next element and executes the body of the
for loop with this value. After all the items exhaust,
StopIteration is raised which is internally caught and the loop ends. Note that any other kind of exception will pass through.
Building Custom Iterators
Building an iterator from scratch is easy in Python. We just have to implement the
__iter__() and the
__iter__() method returns the iterator object itself. If required, some initialization can be performed.
__next__() method must return the next item in the sequence. On reaching the end, and in subsequent calls, it must raise
Here, we show an example that will give us the next power of 2 in each iteration. Power exponent starts from zero up to a user set number.
If you do not have any idea about object-oriented programming, visit Python Object-Oriented Programming.
class PowTwo: """Class to implement an iterator of powers of two""" def __init__(self, max=0): self.max = max def __iter__(self): self.n = 0 return self def __next__(self): if self.n <= self.max: result = 2 ** self.n self.n += 1 return result else: raise StopIteration # create an object numbers = PowTwo(3) # create an iterable from the object i = iter(numbers) # Using next to get to the next iterator element print(next(i)) print(next(i)) print(next(i)) print(next(i)) print(next(i))
1 2 4 8 Traceback (most recent call last): File "/home/bsoyuj/Desktop/Untitled-1.py", line 32, in <module> print(next(i)) File "<string>", line 18, in __next__ raise StopIteration StopIteration
We can also use a
for loop to iterate over our iterator class.
>>> for i in PowTwo(5): ... print(i) ... 1 2 4 8 16 32
Python Infinite Iterators
It is not necessary that the item in an iterator object has to be exhausted. There can be infinite iterators (which never ends). We must be careful when handling such iterators.
Here is a simple example to demonstrate infinite iterators.
The built-in function
iter() can be called with two arguments where the first argument must be a callable object (function) and second is the sentinel. The iterator calls this function until the returned value is equal to the sentinel.
>>> int() 0 >>> inf = iter(int,1) >>> next(inf) 0 >>> next(inf) 0
We can see that the
int() function always returns 0. So passing it as
iter(int,1) will return an iterator that calls
int() until the returned value equals 1. This never happens and we get an infinite iterator.
We can also build our own infinite iterators. The following iterator will, theoretically, return all the odd numbers.
class InfIter: """Infinite iterator to return all odd numbers""" def __iter__(self): self.num = 1 return self def __next__(self): num = self.num self.num += 2 return num
A sample run would be as follows.
>>> a = iter(InfIter()) >>> next(a) 1 >>> next(a) 3 >>> next(a) 5 >>> next(a) 7
And so on…
Be careful to include a terminating condition, when iterating over these types of infinite iterators.
The advantage of using iterators is that they save resources. Like shown above, we could get all the odd numbers without storing the entire number system in memory. We can have infinite items (theoretically) in finite memory.
There’s an easier way to create iterators in Python. To learn more visit: Python generators using yield.