A compact way to write that function is to use
any and a generator expression:
conditions = (cond1, cond2, cond3)
return not any(cond(val) for cond in conditions)
all functions short-circuit, so they'll stop testing as soon as they have a definite result, i.e.,
any stops as soon as it hits a True-ish value,
all stops as soon as it hits a False-ish value, so this form of testing is quite efficient.
I should also mention that it's much more efficient to pass a generator expression like this to
any than a list comprehension. Because
any stop testing as soon as they get a valid result, if you feed them from a generator then the generator will stop too, thus in the above code if
cond(val) evaluates to a True-ish value no further conditions will be tested. But if you pass
any a list comprehension, eg
any([cond(val) for cond in conditions]) the whole list has to be be built before
any can even start testing.
You haven't shown us the internal structure of your
cond functions, but you did mention
assert in your question, so I feel that the following remarks are in order here.
As I mentioned in the comments,
assert should not be used to validate data, it's used to validate program logic. (Also, assertion-handling can be disabled via an -O command line option). The correct Exception to use for data with invalid values is
ValueError, and for objects that are the wrong type, use
TypeError. But bear in mind that exceptions are designed to handle situations that are exceptional.
If you expect a lot of malformed data then it's generally more efficient to use
if based logic than exceptions. Python exception-handling is quite fast if the exception isn't actually raised, in fact it's faster than the equivalent
if based code. However, if the exception is raised say more than 5-10% of the time, then the
try...except based code will be noticeably slower than the
if based equivalent.
Of course, sometimes using exceptions is the only sensible option, even though the situation isn't all that exceptional. A classic example is when you're converting a collection of numeric strings to actual numeric objects, so that strings that represent integers get converted to integer objects, other numeric strings get converted to floats, and other strings get left as strings. The standard way to do this in Python involves using exceptions. For example:
''' Convert s to int or float, if possible '''
data = ['42', 'spam', '2.99792458E8']
out = [convert(u) for u in data]
print([type(u) for u in out])
[42, 'spam', 299792458.0]
[<class 'int'>, <class 'str'>, <class 'float'>]
Using "Look Before You Leap" logic here is possible here, but it makes the code more complicated because you need to deal with possible minus signs and scientific notation.