16
>>> x = numpy.array([[1, 2],
...                  [3, 4],
...                  [5, 6]])
>>> [1, 7] in x
True
>>> [1, 2] in x
True
>>> [1, 6] in x
True
>>> [2, 6] in x
True
>>> [3, 6] in x
True
>>> [2, 3] in x
False
>>> [2, 1] in x
False
>>> [1, 2, 3] in x
False
>>> [1, 3, 5] in x
False

I have no idea how __contains__ works for ndarrays. I couldn't find the relevant documentation when I looked for it. How does it work? And is it documented anywhere?

  • Look at the source, then. – Marcin Aug 19 '13 at 18:33
  • 4
    @Marcin: The source is buried somewhere in a pile of C that I don't understand the structure to. A big part of it is even autogenerated, and a lot of it is duplicated to handle different dtypes and other differences. I'm not going to dig through all that if I don't have to. – user2357112 Aug 19 '13 at 18:41
  • 3
    mail-archive.com/numpy-discussion@scipy.org/msg31578.html seems to have the answer. – Alok Singhal Aug 19 '13 at 18:47
  • @AlokSinghal: Further experimentation seems to agree with that post. [1, object()] in x and [object(), 4] in x report True, but [2, object()] in x and [object(), 5] in x report False, and iterating over itertools.product(xrange(1, 7), repeat=2) and checking containment for all pairs gives the expected results. I was really hoping for something better than a mailing list archive, but if that's all there is, I'll take it. – user2357112 Aug 19 '13 at 18:59
  • @user2357112 I just posted this as an answer since that's the correct answer and hopefully it will help other people who discover the same issue. – Alok Singhal Aug 19 '13 at 19:02
8

I found the source for ndarray.__contains__, in numpy/core/src/multiarray/sequence.c. As a comment in the source states,

thing in x

is equivalent to

(x == thing).any()

for an ndarray x, regardless of the dimensions of x and thing. This only makes sense when thing is a scalar; the results of broadcasting when thing isn't a scalar cause the weird results I observed, as well as oddities like array([1, 2, 3]) in array(1) that I didn't think to try. The exact source is

static int
array_contains(PyArrayObject *self, PyObject *el)
{
    /* equivalent to (self == el).any() */

    PyObject *res;
    int ret;

    res = PyArray_EnsureAnyArray(PyObject_RichCompare((PyObject *)self,
                                                      el, Py_EQ));
    if (res == NULL) {
        return -1;
    }
    ret = array_any_nonzero((PyArrayObject *)res);
    Py_DECREF(res);
    return ret;
}
5

Seems like numpy's __contains__ is doing something like this for a 2-d case:

def __contains__(self, item):
    for row in self:
        if any(item_value == row_value for item_value, row_value in zip(item, row)):
            return True
    return False

[1,7] works because the 0th element of the first row matches the 0th element of [1,7]. Same with [1,2] etc. With [2,6], the 6 matches the 6 in the last row. With [2,3], none of the elements match a row at the same index. [1, 2, 3] is trivial since the shapes don't match.

See this for more, and also this ticket.

  • It seems to me that all would be more practically useful than any, I wonder why numpy developers chose this implementation of __contains__. – Akavall Aug 20 '13 at 3:13
  • 1
    @Akavall Seems to be for compatibility with Numeric. In Numeric, an array's boolean value was assumed to be True if it contained at least one non-zero element. Numpy raises exceptions when one tries to use an array as a boolean, saying that one should use any() or all(). In this case though, __contains__() API is forcing Numpy to interpret an array in a boolean context, and for this, they decided to go with what Numeric did. But I agree, it's really confusing and I don't know if anyone depends on this behavior of __contains__(). – Alok Singhal Aug 20 '13 at 4:03
  • Good point about compatibility. Thanks. – Akavall Aug 20 '13 at 4:09

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