Why doesn't iterating work the second time for iterators?
It does "work", in the sense that the
for loop in the examples does run. It simply performs zero iterations. This happens because the iterator is "exhausted"; it has already iterated over all of the elements.
Why does it work for other kinds of iterables?
Because, behind the scenes, a new iterator is created for each loop, based on that iterable. Creating the iterator from scratch means that it starts at the beginning.
This happens because iterating requires an iterable. If an iterable was already provided, it will be used as-is; but otherwise, a conversion is necessary, which creates a new object.
Given an iterator, how can we iterate twice over the data?
By caching the data; starting over with a new iterator (assuming we can re-create the initial condition); or, if the iterator was specifically designed for it, seeking or resetting the iterator. Relatively few iterators offer seeking or resetting.
The only fully general approach is to remember what elements were seen (or determine what elements will be seen) the first time and iterate over them again. The simplest way is by creating a
tuple from the iterator:
elements = list(iterator)
for element in elements:
for element in elements:
list is a non-iterator iterable, each loop will create a new iterable that iterates over all the elements. If the iterator is already "part way through" an iteration when we do this, the
list will only contain the "following" elements:
abstract = (x for x in range(10)) # represents integers from 0 to 9 inclusive
next(abstract) # skips the 0
concrete = list(abstract) # makes a list with the rest
for element in concrete:
print(element) # starts at 1, because the list does
for element in concrete:
print(element) # also starts at 1, because a new iterator is created
A more sophisticated way is using
itertools.tee. This essentially creates a "buffer" of elements from the original source as they're iterated over, and then creates and returns several custom iterators that work by remembering an index, fetching from the buffer if possible, and appending to the buffer (using the original iterable) when necessary. (In the reference implementation of modern Python versions, this does not use native Python code.)
from itertools import tee
concrete = list(range(10)) # `tee` works on any iterable, iterator or not
x, y = tee(concrete, 2) # the second argument is the number of instances.
for element in x:
if element == 3:
for element in y:
print(element) # starts over at 0, taking 0, 1, 2, 3 from a buffer
If we know and can recreate the starting conditions for the iterator when the iteration started, that also solves the problem. This is implicitly what happens when iterating multiple times over a list: the "starting conditions for the iterator" are just the contents of the list, and all the iterators created from it give the same results. For another example, if a generator function does not depend on an external state, we can simply call it again with the same parameters:
def powers_of(base, *range_args):
for i in range(*range_args):
yield base ** i
exhaustible = powers_of(2, 1, 12):
for value in exhaustible:
for value in exhaustible: # no results from here
# Want the same values again? Then use the same generator again:
for value in powers_of(2, 1, 12):
Seekable or resettable iterators
Some specific iterators may make it possible to "reset" iteration to the beginning, or even to "seek" to a specific point in the iteration. In general, iterators need to have some kind of internal state in order to keep track of "where" they are in the iteration. Making an iterator "seekable" or "resettable" simply means allowing external access to, respectively, modify or re-initialize that state.
Nothing in Python disallows this, but in many cases it's not feasible to provide a simple interface; in most other cases, it just isn't supported even though it might be trivial. For generator functions, the internal state in question, on the other hand, the internal state is quite complex, and protects itself against modification.
The classic example of a seekable iterator is an open
file object created using the built-in
open function. The state in question is a position within the underlying file on disk; the
.seek methods allow us to inspect and modify that position value - e.g.
.seek(0) will set the position to the beginning of the file, effectively resetting the iterator. Similarly,
csv.reader is a wrapper around a file; seeking within that file will therefore affect the subsequent results of iteration.
In all but the simplest, deliberately-designed cases, rewinding an iterator will be difficult to impossible. Even if the iterator is designed to be seekable, this leaves the question of figuring out where to seek to - i.e., what the internal state was at the desired point in the iteration. In the case of the
powers_of generator shown above, that's straightforward: just modify
i. For a file, we'd need to know what the file position was at the beginning of the desired line, not just the line number. That's why the file interface provides
.tell as well as
Here's a re-worked example of
powers_of representing an unbound sequence, and designed to be seekable, rewindable and resettable via an
def __init__(self, base):
self._exponent = 0
self._base = base
result = self._base ** self._exponent
self._exponent += 1
def exponent(self, value):
if not isinstance(new_value, int):
raise TypeError("must set with an integer")
if new_value < 0:
raise ValueError("can't set to negative value")
self._exponent = new_value
pot = PowersOf(2)
for i in pot:
if i > 1000:
pot.exponent = 5 # jump to this point in the (unbounded) sequence
print(next(pot)) # 32
print(next(pot)) # 64
Iterators vs. iterables
Recall that, briefly:
- "iteration" means looking at each element in turn, of some abstract, conceptual sequence of values. This can include:
- "iterable" means an object that represents such a sequence. (What the Python documentation calls a "sequence" is in fact more specific than that - basically it also needs to be finite and ordered.). Note that the elements do not need to be "stored" - in memory, disk or anywhere else; it is sufficient that we can determine them during the process of iteration.
- "iterator" means an object that represents a process of iteration; in some sense, it keeps track of "where we are" in the iteration.
Combining the definitions, an iterable is something that represents elements that can be examined in a specified order; an iterator is something that allows us to examine elements in a specified order. Certainly an iterator "represents" those elements - since we can find out what they are, by examining them - and certainly they can be examined in a specified order - since that's what the iterator enables. So, we can conclude that an iterator is a kind of iterable - and Python's definitions agree.
How iteration works
In order to iterate, we need an iterator. When we iterate in Python, an iterator is needed; but in normal cases (i.e. except in poorly written user-defined code), any iterable is permissible. Behind the scenes, Python will convert other iterables to corresponding iterators; the logic for this is available via the built-in
iter function. To iterate, Python repeatedly asks the iterator for a "next element" until the iterator raises a
StopException. The logic for this is available via the built-in
iter is given a single argument that already is an iterator, that same object is returned unchanged. But if it's some other kind of iterable, a new iterator object will be created. This directly leads to the problem in the OP. User-defined types can break both of these rules, but they probably shouldn't.
The iterator protocol
Python roughly defines an "iterator protocol" that specifies how it decides whether a type is an iterable (or specifically an iterator), and how types can provide the iteration functionality. The details have changed a slightly over the years, but the modern setup works like so:
Anything that has an
__iter__ or a
__getitem__ method is an iterable. Anything that defines an
__iter__ method and a
__next__ method is specifically an iterator. (Note in particular that if there is a
__getitem__ and a
__next__ but no
__next__ has no particular meaning, and the object is a non-iterator iterable.)
Given a single argument,
iter will attempt to call the
__iter__ method of that argument, verify that the result has a
__next__ method, and return that result. It does not ensure the presence of an
__iter__ method on the result. Such objects can often be used in places where an iterator is expected, but will fail if e.g.
iter is called on them.) If there is no
__iter__, it will look for
__getitem__, and use that to create an instance of a built-in iterator type. That iterator is roughly equivalent to
def __init__(self, bound_getitem):
self._index = 0
self._bound_getitem = bound_getitem
result = self._bound_getitem(self._index)
self._index += 1
Given a single argument,
next will attempt to call the
__next__ method of that argument, allowing any
StopIteration to propagate.
With all of this machinery in place, it is possible to implement a
for loop in terms of
while. Specifically, a loop like
for element in iterable:
will approximately translate to:
iterator = iter(iterable)
element = next(iterator)
except that the iterator is not actually assigned any name (the syntax here is to emphasize that
iter is only called once, and is called even if there are no iterations of the