# Find index positions where 3D-array meets MULTIPLE conditions

I have a 3D-array consisting of several numbers within each band. Is there a function that returns the index positions where the array meets MULTIPLE conditions?

I tried the following:

``````index_pos = numpy.where(
array[:,:,0]==10 and array[:,:,1]==15 and array[:,:,2]==30)
``````

It returns the error:

``````ValueError: The truth value of an array with more than one element is ambiguous.
Use a.any() or a.all()
``````

You actually have a special case where it would be simpler and more efficient to do the following:

Create the data:

``````>>> arr
array([[[ 6,  9,  4],
[ 5,  2,  1],
[10, 15, 30]],

[[ 9,  0,  1],
[ 4,  6,  4],
[ 8,  3,  9]],

[[ 6,  7,  4],
[ 0,  1,  6],
[ 4,  0,  1]]])
``````

The expected value:

``````>>> index_pos = np.where((arr[:,:,0]==10) & (arr[:,:,1]==15) & (arr[:,:,2]==30))
>>> index_pos
(array([0]), array([2]))
``````

Use broadcasting to do this simultaneously:

``````>>> arr == np.array([10,15,30])
array([[[False, False, False],
[False, False, False],
[ True,  True,  True]],

[[False, False, False],
[False, False, False],
[False, False, False]],

[[False, False, False],
[False, False, False],
[False, False, False]]], dtype=bool)

>>> np.where( np.all(arr == np.array([10,15,30]), axis=-1) )
(array([0]), array([2]))
``````

If the indices you want are not contiguous you can do something like this:

``````ind_vals = np.array([0,2])
``````

Spurred by @Jamie's comment, some interesting things to consider:

``````arr = np.random.randint(0,100,(5000,5000,3))

%timeit np.all(arr == np.array([10,15,30]), axis=-1)
1 loops, best of 3: 614 ms per loop

%timeit ((arr[:,:,0]==10) & (arr[:,:,1]==15) & (arr[:,:,2]==30))
1 loops, best of 3: 217 ms per loop

%timeit tmp = (arr == np.array([10,15,30])); (tmp[:,:,0] & tmp[:,:,1] & tmp[:,:,2])
1 loops, best of 3: 368 ms per loop
``````

The question becomes, why is this?:

First off examine:

``````%timeit (arr[:,:,0]==10)
10 loops, best of 3: 51.2 ms per loop

%timeit (arr == np.array([10,15,30]))
1 loops, best of 3: 300 ms per loop
``````

One would expect that `arr == np.array([10,15,30])` would be at worse case 1/3 the speed of `arr[:,:,0]==10`. Anyone have an idea why this is not the case?

Then when combining the final axis there are many ways to accomplish this.

``````tmp = (arr == np.array([10,15,30]))

method1 = np.all(tmp,axis=-1)
method2 = (tmp[:,:,0] & tmp[:,:,1] & tmp[:,:,2])
method3 = np.einsum('ij,ij,ij->ij',tmp[:,:,0] , tmp[:,:,1] , tmp[:,:,2])

np.allclose(method1,method2)
True
np.allclose(method1,method3)
True

%timeit np.all(tmp,axis=-1)
1 loops, best of 3: 318 ms per loop

%timeit (tmp[:,:,0] & tmp[:,:,1] & tmp[:,:,2])
10 loops, best of 3: 68.2 ms per loop

%timeit np.einsum('ij,ij,ij->ij',tmp[:,:,0] , tmp[:,:,1] , tmp[:,:,2])
10 loops, best of 3: 38 ms per loop
``````

The einsum speed up is well defined elsewhere, but it seems odd to me that there is such a difference between `all` and consecutive `&`'s.

• With very large arrays it may be slower to create your single boolean array, rather than three of one third the size, but it definitely looks much cleaner. You can, by the way, let the ufunc do the conversion of the list to an array: `arr = [10, 15, 30]` works just the same. – Jaime Nov 4 '13 at 16:16
• @Jamie Please view my edits, your comment is very interesting and I do not quite understand why it is so much slower. The `np.array(...)` comes from habit- there are a few places where the ufunc does not call `np.asarray` and it makes me nervous. – Daniel Nov 4 '13 at 17:38
• I think the speed in building the boolean arrays is a memory cache thing. The 3 to 1 speed ratio you mention only holds for tiny arrays like `(10, 10, 3)`, I'm guessing that here they both fit in cache. It goes up to 10 to 1 for intermediate arrays like `(100, 100, 3)`, probably because one fits in cache and the other doesn't. And apparently starts going down again for larger arrays like you `(5000, 5000, 3)`, probably since both now require out of cache reads. – Jaime Nov 4 '13 at 18:29
• @EMS I agree that it is a comment that is worth making, and a good point (it is why I up voted the comment). However, saying that the bitwise portion is irrelevant strikes me as a bit heavy handed. Especially when bitwise operations are explicitly useful in the example provided. – Daniel Nov 4 '13 at 19:25
• I guess I see it as the reverse of your comment. The bitwise approach would be fine as a one-off comment that's like "hey, you can also do it with this bitwise symbol, but be careful of some pitfalls." The bitwise approach is misleading here if it's treated as the main or preferred answer. The bitwise approach is useful, but not the right tool for the job. – ely Nov 4 '13 at 19:36

The `and` operator won't work in this case.

``````index_pos = numpy.where(array[:,:,0]==10 and array[:,:,1]==15 and array[:,:,2]==30)
``````

Give this a try:

``````index_pos = numpy.where((array[:,:,0]==10) & (array[:,:,1]==15) & (array[:,:,2]==30))
``````
• Note that using `&` is equivalent to using `np.bitwise_and` and it will do what you expect for boolean arrays: an elementwise and, as in the example, because bools are single bits. However, it still is bitwise, so `np.array([1,2]) & np.array([0,1])` won't give the same as `np.logical_and(np.array([1,2]), np.array([0,1]))`. – askewchan Nov 4 '13 at 16:32

The problem is the use of the native Python `and` keyword, which doesn't behave the way you'd like on arrays.

Instead, try using the `numpy.logical_and` function.

``````cond1 = np.logical_and(array[:,:,0]==10, array[:,:,1]==15)
cond2 = np.logical_and(cond1, array[:,:,2]==30)
index_pos = numpy.where(cond2)
``````

You might even create your own version of `logical_and` that accepts arbitrary number of conditions:

``````def my_logical_and(*args):
return reduce(np.logical_and, args)

condition_locs_and_vals = [(0, 10), (1, 15), (2, 30)]
conditions = [array[:,:,x] == y for x,y in conditition_locs_and_vals]
my_logical_and(*conditions)
``````

Using bitwise-and (`&`) works but only by coincidence. The bitwise-and is for comparing bits or `bool` types. Using it to compare the truth value of numeric arrays is not robust (for instance, if you suddenly need to index on locations where an entry evaluates to `True` rather than actually first converting to a `bool` array). `logical_and` really should be used instead of `&` (even if it comes with a speed penalty).

Also, chaining together arbitrary lists of conditions with `&` can be painful both to read and type. And for re-usability of the code, so that later programmers don't have to change around a bunch of the subordinate clauses to the `&` operator, it might be better to store the individual conditions separately, and then use a function like the one above to combine them.

• Nice answer. Incidentally, `np.logical_and` has a `reduce` method, which is identical to your `my_logical_and` as far as I can tell: `np.logical_and.reduce(*conditions)`. You could also do this with `np.all(conditions, axis=0)`. – askewchan Nov 4 '13 at 21:21