# all builtin function of empty list

Can anybody explain why in python builtin buinction `all` return `True` in this case `all([])`?

``````In [33]: all([])
Out[33]: True

In [34]: all([0])
Out[34]: False

In [35]: __builtins__.all([])
Out[35]: True
``````
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`all(l)` is equivalent to `l[0] and l[1] and ...` and the `and` of no things is true. –  katrielalex Dec 6 '12 at 9:14

I'm not convinced that any of the other answers have really address the question of why this should be the case.

The definition for Python's `all()` comes from boolean logic. If for example we say that "all swans are white" then a single black swan disproves the statement. However, if we say that "all unicorns are pink" logicians would take that as a true statement simply because there are no non-pink unicorns. Or in other words "all " is vacuously true.

Practically it gives us a useful invariant. If `all(A)` and `all(B)` are both true then the combination of `all(A + B)` is also true. If `all({})` was false we should have a less useful situation because combining two expressions one of which is false suddenly gives an unexpected true result.

So Python takes `all([]) == True` from boolean logic, and for consistency with other languages with a similar construct.

Taking that back into Python, in many cases the vacuous truth makes algorithms simpler. For example, if we have a tree and want to validate all of the nodes we might say a node is valid if it meets some conditions and all of its children are valid. With the alternative definition of `all()` this becomes more complex as we have to say it is valid if it meets the conditions and either has no children or all its children are valid.

``````class Node:
def isValid(self):
return some_condition(self) and all(child.isValid for child in self.children)
``````
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Good explanation. I'd add a few words about `any` and why "some unicorns are pink" is false. –  georg Dec 6 '12 at 9:41

From the docs:

Return True if all elements of the iterable are true (or if the iterable is empty).

So, roughly, it's simply defined this way.

You can get around that by using

``````list = []
if list and all(list):
pass
``````
-

As the docs say, `all` is equivalent to:

``````def all(iterable):
for element in iterable:
if not element:
return False
return True
``````

For an empty `iterable` the loop body is never executed, so `True` is immediately returned.

-

Another explanation for this is that `all` and `any` are generalisations of the binary operators `and` and `or` for arbitrarily long numbers of parameters. Thus, `all` and `any` can be defined as:

``````def all(xs):
return reduce(lambda x,y: x and y, xs, True)

def any(xs):
return reduce(lambda x,y: x or y, xs, False)
``````

The `True` and `False` parameters show that `all([]) == True` and `any([]) == False`.

-

Any expression with `all` can be rewritten by `any` and vice versa:

``````not all(iterable)
# is the same as:
any(not x for x in iterable)
``````

and symmetrically

``````not any(iterable)
# is the same as:
all(not x for x in iterable)
``````

These rules require that `all([]) == True`.

The function `all` is very useful for readable asserts:

``````assert all(required_condition(x) for x in some_results_being_verified)
``````