logical_or function takes no more than two arrays to compare. How can I find the union of more than two arrays? (The same question could be asked with regard to Numpy's
logical_and and obtaining the intersection of more than two arrays.)
If you're asking about
numpy.logical_or, then no, as the docs explicitly say, the only parameters are
x1, x2, and optionally
x1, x2[, out]) =
You can of course chain together multiple
logical_or calls like this:
>>> x = np.array([True, True, False, False]) >>> y = np.array([True, False, True, False]) >>> z = np.array([False, False, False, False]) >>> np.logical_or(np.logical_or(x, y), z) array([ True, True, True, False], dtype=bool)
The way to generalize this kind of chaining in NumPy is with
>>> np.logical_or.reduce((x, y, z)) array([ True, True, True, False], dtype=bool)
And of course this will also work if you have one multi-dimensional array instead of separate arrays—in fact, that's how it's meant to be used:
>>> xyz = np.array((x, y, z)) >>> xyz array([[ True, True, False, False], [ True, False, True, False], [False, False, False, False]], dtype=bool) >>> np.logical_or.reduce(xyz) array([ True, True, True, False], dtype=bool)
But a tuple of three equal-length 1D arrays is an array_like in NumPy terms, and can be used as a 2D array.
Outside of NumPy, you can also use Python's
>>> functools.reduce(np.logical_or, (x, y, z)) array([ True, True, True, False], dtype=bool)
However, unlike NumPy's
reduce, Python's is not often needed. For most cases, there's a simpler way to do things—e.g., to chain together multiple Python
or operators, don't
operator.or_, just use
any. And when there isn't, it's usually more readable to use an explicit loop.
And in fact NumPy's
any can be used for this case as well, although it's not quite as trivial; if you don't explicitly give it an axis, you'll end up with a scalar instead of an array. So:
>>> np.any((x, y, z), axis=0) array([ True, True, True, False], dtype=bool)
What about other operations, like
logical_xor? Again, same deal… except that in this case there is no
any-type function that applies. (What would you call it?
As boolean algebras are both commutative and associative by definition, the following statements or equivalent for boolean values of a, b and c.
a or b or c
(a or b) or c
a or (b or c)
(b or a) or c
So if you have a "logical_or" which is dyadic and you need to pass it three arguments (a, b, and c), you can call
logical_or(logical_or(a, b), c)
logical_or(a, logical_or(b, c))
logical_or(c, logical_or(b, a))
or whatever permutation you like.
Back to python, if you want to test whether a condition (yielded by a function
test that takes a testee and returns a boolean value) applies to a or b or c or any element of list L, you normally use
any(test(x) for x in L)
I use this workaround which can be extended to n arrays:
>>> a = np.array([False, True, False, False]) >>> b = np.array([True, False, False, False]) >>> c = np.array([False, False, False, True]) >>> d = (a + b + c > 0) # That's an "or" between multiple arrays >>> d array([ True, True, False, True], dtype=bool)
I've tried the following three different methods to get the
logical_and of a list l of k arrays of size n:
- Using a recursive
Then I did the same for the
logical_or function. Surprisingly enough, the recursive method is the fastest one.
import numpy import perfplot def and_recursive(*l): if len(l) == 1: return l.astype(bool) elif len(l) == 2: return numpy.logical_and(l,l) elif len(l) > 2: return and_recursive(and_recursive(*l[:2]),and_recursive(*l[2:])) def or_recursive(*l): if len(l) == 1: return l.astype(bool) elif len(l) == 2: return numpy.logical_or(l,l) elif len(l) > 2: return or_recursive(or_recursive(*l[:2]),or_recursive(*l[2:])) def and_reduce(*l): return numpy.logical_and.reduce(l) def or_reduce(*l): return numpy.logical_or.reduce(l) def and_stack(*l): return numpy.vstack(l).all(axis=0) def or_stack(*l): return numpy.vstack(l).any(axis=0) k = 10 # number of arrays to be combined perfplot.plot( setup=lambda n: [numpy.random.choice(a=[False, True], size=n) for j in range(k)], kernels=[ lambda l: and_recursive(*l), lambda l: and_reduce(*l), lambda l: and_stack(*l), lambda l: or_recursive(*l), lambda l: or_reduce(*l), lambda l: or_stack(*l), ], labels = ['and_recursive', 'and_reduce', 'and_stack', 'or_recursive', 'or_reduce', 'or_stack'], n_range=[2 ** j for j in range(20)], logx=True, logy=True, xlabel="len(a)", equality_check=None )
Here below the performances for k = 4.
And here below the performances for k = 10.
It seems that there is an approximately constant time overhead also for higher n.
If you want a short (maybe not optimal) function for performing logical AND on multidimensional boolean masks, you may use this recursive lambda function:
masks_and = lambda *masks : masks if len(masks) == 1 else masks_and(np.logical_and(masks, masks[-1]), *masks[1:-1]) result = masks_and(mask1, mask2, ...)
You can also generalize the lambda function for applying any operator (function of 2 arguments) with distributive property (such as multiplication/AND, sum/OR and so on), assuming the order is also important, to any objects like this:
fn2args_reduce = lambda fn2args, *args : args if len(args) == 1 else fn2args_reduce(fn2args, fn2args(args, args), *args[2:]) result = fn2args_reduce(np.dot, matrix1, matrix2, ... matrixN)
which gives you the same result as if you use
@ numpy operator):
np.dot(...(np.dot(np.dot(matrix1, matrix2), matrix3)...), matrixN)
fn2args_reduce(lambda a,b: a+b, 1,2,3,4,5) gives you 15 - sum of these numbers (of course you have a much more efficient
sum function for this, but I like it).
Even more generalized model for functions of N arguments could look like this:
fnNargs_reduce = lambda fnNargs, N, *args : args if len(args) == 1 else fnNargs_reduce(fnNargs, N, fnNargs(*args[:N]), *args[N:]) fnNargs = lambda x1, x2, x3=neutral, ..., xN=neutral: x1 (?) x2 (?) ... (?) xN
Where neutral means it is neutral element for (?) operator, eg. 0 for +, 1 for * etc.
Why? Just for fun :-)