As a complete Python newbie, it certainly looks that way. Running the following...
x = enumerate(['fee', 'fie', 'foe']) x.next() # Out: (0, 'fee') list(x) # Out: [(1, 'fie'), (2, 'foe')] list(x) # Out: 
... I notice that: (a)
x does have a
next method, as seems to be
required for generators, and (b)
x can only be iterated over once, a
characteristic of generators emphasized in this famous
On the other hand, the two most highly-upvoted answers to this
about how to determine whether an object is a generator would seem to
enumerate() does not return a generator.
import types import inspect x = enumerate(['fee', 'fie', 'foe']) isinstance(x, types.GeneratorType) # Out: False inspect.isgenerator(x) # Out: False
... while a third poorly-upvoted answer to that question would seem to indicate that
enumerate() does in fact return a generator:
def isgenerator(iterable): return hasattr(iterable,'__iter__') and not hasattr(iterable,'__len__') isgenerator(x) # Out: True
So what's going on? Is
x a generator or not? Is it in some sense
"generator-like", but not an actual generator? Does Python's use of
duck-typing mean that the test outlined in the final code block above
is actually the best one?
Rather than continue to write down the possibilities running through my head, I'll just throw this out to those of you who will immediately know the answer.