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# What should itertools.product() yield when supplied an empty list?

I guess it's an academic question, but the second result does not make sense to me. Shouldn't it be as thoroughly empty as the first? What is the rationale for this behavior?

``````from itertools import product

one_empty = [ [1,2], [] ]
all_empty = []

print [ t for t in product(*one_empty) ]  # []
print [ t for t in product(*all_empty) ]  # [()]
``````

Thanks for all of the answers -- very informative.

Wikipedia's discussion of the Nullary Cartesian Product provides a definitive statement:

The Cartesian product of no sets ... is the singleton set containing the empty tuple.

And here is some code you can use to work through the insightful answer from sth:

``````from itertools import product

def tproduct(*xss):
return ( sum(rs, ()) for rs in product(*xss) )

def tup(x):
return (x,)

xs = [ [1, 2],     [3, 4, 5]       ]
ys = [ ['a', 'b'], ['c', 'd', 'e'] ]

txs = [ map(tup, x) for x in xs ]  # [[(1,), (2,)], [(3,), (4,), (5,)]]
tys = [ map(tup, y) for y in ys ]  # [[('a',), ('b',)], [('c',), ('d',), ('e',)]]

a = [ p for p in tproduct( *(txs + tys) )                   ]
b = [ p for p in tproduct( tproduct(*txs), tproduct(*tys) ) ]

assert a == b
``````
-

From a mathematical point of view the product over no elements should yield the neutral element of the operation product, whatever that is.

For example on integers the neutral element of multiplication is 1, since 1 ⋅ a = a for all integers a. So an empty product of integers should be 1. When implementing a python function that returns the product of a list of numbers, this happens naturally:

``````def iproduct(lst):
result = 1
for i in lst:
result *= i
return result
``````

For the correct result to be calculated with this algorithm, `result` needs to be initialized with `1`. This leads to a return value of `1` when the function is called on an empty list.

This return value is also very reasonable for the purpose of the function. With a good product function it shouldn't matter if you first concat two lists and then build the product of the elements, or if you first build the product of both individual lists and then multiply the results:

``````iproduct(xs + ys) == iproduct(xs) * iproduct(ys)
``````

If `xs` or `ys` is empty that only works if `iproduct([]) == 1`.

Now the more complicated `product()` on iterators. Here also, from a mathematical point of view, `product([])` should return the neutral element of that operation, whatever that is. It is not `[]` since `product([], xs) == []`, while for the neutral elements `product([], xs) == xs` should hold. It turns out, though, that `[()]` also isn't a neutral element:

``````>>> list(product([()], [1,2,3]))
[((), 1), ((), 2), ((), 3)]
``````

In fact, `product()` is not really a very nice mathematical product at all, since this above equation doesn't hold:

``````product(*(xs + ys)) != product(product(*xs), product(*ys))
``````

Each application of product generates an additional layer of tuples and there is no way around that, so there can't even be a real neutral element. `[()]` comes pretty close though, it doesn't add or remove any elements, it just adds an empty tuple to each.

`[()]`would in fact be the neutral element of this slightly adapted product function that only operates on lists of tuples, but doesn't add additional tuple layers on each application:

``````def tproduct(*xss):
# the parameters have to be lists of tuples
return (sum(rs, ()) for rs in product(*xss))
``````

For this function the above product equation holds:

``````def tup(x): return (x,)
txs = [map(tup, x) for x in xs]
tys = [map(tup, y) for y in ys]
tproduct(*(txs + tys)) == tproduct(tproduct(*txs), tproduct(*tys))
``````

With the additional preprocessing step of packing the input lists into tuples, `tproduct()` gives the same result as `product()`, but behaves nicer from a mathematical point of view. Also its neutral element is `[()]`,

So `[()]` makes some sense as the neutral element of this kind of list multiplication. Even if it doesn't exactly fit `product()` it is a good choice for this function since it for example allows to define `tproduct()` without the need to introduce a special case for empty input.

-
In mathematics, there are many product and multiplication functions where there is no "neutral element". For a broad class with several examples, see en.wikipedia.org/wiki/Direct_product – Daniel Stutzbach Jul 1 '10 at 3:37
+1. Beautiful answer. You can make your product equality work with a slight modification: define a `flatten` function by: `flatten = lambda tups: sum(tups, ())`. Then `list(product(*(xs+ys)))` is equivalent to `map(flatten, product(product(*xs), product(*ys)))`. Moreover, the result of `itertools.product()` (with no args) is the correct one to make this equivalence continue to hold when either `xs` or `ys` (or both) is empty. – Mark Dickinson Jul 1 '10 at 9:10
Ah; now I see that that's pretty much exactly what you did, with your `tproduct` function. Sorry for the noise. :) – Mark Dickinson Jul 1 '10 at 9:17
Thanks, I learned a lot from this. – FMc Jul 3 '10 at 14:04

As @sth already indicated, this behaviour is correct from a mathematical viewpoint. All you really need to convince yourself of is that `list(itertools.product())` should have exactly one element, since once you know that it's clear what that element should be: it's got to be (for consistency) a tuple of length 0, and there's only one of those.

But the number of elements of `itertools.product(l1, l2, l3, ...)` should just be the product of the lengths of `l1`, `l2`, `l3`, ... . So the number of elements of `itertools.product()` should be the size of the empty product, and there's no shortage of internet sources that should persuade you that the empty product is 1.

I just wanted to point out that this is the correct practical definition as well as the correct mathematical one; that is, it's the definition that's most likely to 'just work' in boundary cases. For an example, suppose that you want to generate all strings of length `n` consisting of decimal digits, with the first digit nonzero. You might do something like:

``````import itertools

def decimal_strings(n):
"""Generate all digit strings of length n that don't start with 0."""
for tail in itertools.product('0123456789', repeat=n-1):
``````

What should this produce when `n = 1`? Well, in that case, you end up calling `itertools.product` with an empty product (`repeat = 0`). If it returned nothing, then the body of the inner `for` loop above would never be executed, so `decimal_strings(1)` would be an empty iterator; almost certainly not what you want. But since `itertools.product('0123456789', repeat=0)` returns a single tuple, you get the expected result:

``````>>> list(decimal_strings(1))
['1', '2', '3', '4', '5', '6', '7', '8', '9']
``````

(When `n = 0`, of course, this function correctly raises a ValueError.)

So in short, the definition is mathematically sound, and more often that not it's also what you want. It's definitely not a Python bug!

-
+1 for the link to the Empty Product. It specifically mentions that for the Cartesian Product, the empty product is the singleton set containing the empty set. – Daniel Stutzbach Jul 1 '10 at 12:51
Great answer, both for the Empty Product reference and for the practical illustration. – FMc Jul 3 '10 at 14:07