# Return the indexes of a sub-array in an array

I use Python with `numpy`.

I have a numpy array `may_a`:

``````may_a = numpy.array([False, True, False, True, True, False, True, False, True, True, False])
``````

I have a numpy array `may_b`:

``````may_b = numpy.array([False,True,True,False])
``````

I need to find array `may_b` in array `may_a`.

In the output I need to get indexes of occurrences.

``````out_index=[2,7]
``````

Can someone please suggest, how do I get `out_index`?

-
Did you mean `out_index=[2,6]` ? – Konfle Dolex Feb 15 '13 at 7:48
@Konfle Dolex, out_index=[2,7] – Olga Feb 15 '13 at 7:50
@Olga Ah. I misread your question. – Konfle Dolex Feb 15 '13 at 7:51
@Robin, no, it is search of the optimum decision – Olga Feb 15 '13 at 7:52

EDIT The following code does allow to perform a convolution based check of equality. It maps `True` to `1` and `False` to `-1`. It also reverses `b`, which is needed for it to work properly:

``````def search(a, b) :
return np.where(np.round(fftconvolve(a * 2 - 1, (b * 2 - 1)[::-1],
mode='valid') - len(b)) == 0)[0]
``````

I have checked that it gives the same output as the `as_strided` method for a variety of random inputs, which it does. I have also timed both approached, and convolution only starts paying off with largish search tokens of around 256 items.

It seems like a little overkill, but with boolean data you can use (abuse?) convolution:

``````In [8]: np.where(np.convolve(may_a, may_b.astype(int),
...:                      mode='valid') == may_b.sum())[0]
Out[8]: array([2, 7])
``````

For larger datasets it may be faster to go with `scipy.signal.fftconvolve`:

``````In [13]: np.where(scipy.signal.fftconvolve(may_a, may_b,
....:                                   mode='valid') == may_b.sum())[0]
Out[13]: array([2, 7])
``````

You have to be careful though, because the output now is floating point, and rounding may spoil the equality check:

``````In [14]: scipy.signal.fftconvolve(may_a, may_b, mode='valid')
Out[14]: array([ 1.,  1.,  2.,  1.,  1.,  1.,  1.,  2.])
``````

So you may be better off with something along the lines of:

``````In [15]: np.where(np.round(scipy.signal.fftconvolve(may_a, may_b, mode='valid') -
....:                   may_b.sum()) == 0)[0]
Out[15]: array([2, 7])
``````
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With This convolution you'll match anything that is `[*, True, True, *]` where `*` is a wildcard. – Bi Rico Feb 15 '13 at 17:51
@BiRico Oops, you are absolutely right! There may be a chance to salvage the method, by mapping the `True`'s and the `False`'s to some integer value, possibly `+1` and `-1`. – Jaime Feb 15 '13 at 18:16
@Jaime `>>> may_a = np.array([True,True,True,True]) >>> out_ind = np.where(np.convolve(may_a, may_b.astype(int),mode='valid') == may_b.sum())[0] >>> out_ind -> array([0])` it is incorrect( – Olga Feb 18 '13 at 11:14
@Olga Yes, that's what BiRico was saying. But the method in my edit at the top of the answer works fine: `out_ind = np.where(np.convolve(may_a * 2 - 1, (may_b * 2 - 1)[::-1], mode='valid') == len(may_b))` – Jaime Feb 18 '13 at 12:55
@Jaime thank! it works. – Olga Feb 19 '13 at 5:15

A much cooler approach, which may not perform a well, but which works for any dtype, is to use `as_strided`:

``````In [2]: from numpy.lib.stride_tricks import as_strided

In [3]: may_a = numpy.array([False, True, False, True, True, False,
...:                      True, False, True, True, False])

In [4]: may_b = numpy.array([False,True,True,False])

In [5]: a = len(may_a)

In [6]: b = len(may_b)

In [7]: a_view = as_strided(may_a, shape=(a - b + 1, b),
...:                     strides=(may_a.dtype.itemsize,) * 2)

In [8]: a_view
Out[8]:
array([[False,  True, False,  True],
[ True, False,  True,  True],
[False,  True,  True, False],
[ True,  True, False,  True],
[ True, False,  True, False],
[False,  True, False,  True],
[ True, False,  True,  True],
[False,  True,  True, False]], dtype=bool)

In [9]: numpy.where(numpy.all(a_view == may_b, axis=1))[0]
Out[9]: array([2, 7])
``````

You have to be careful though, because even though `a_view` is a view of `may_a`'s data, when comparing it with `may_b` a temporary array of `(a - b + 1) * b` is created, which may be a problem with large `a`s and `b`s.

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Maybe you appreciate pointing out small things... Not using `.itemsize` but `.strides[0]` is a bit less prone to failure, in case the array was sliced previously. – seberg Feb 15 '13 at 10:38

This should also work with other that boolean data:

``````In [1]: import numpy as np

In [2]: a = np.array([False, True, False, True, True, False, True, False, True, True, False])

In [3]: b = np.array([False,True,True,False])

In [4]: def get_indices(a, b):
...:     window = len(b)
...:     shape = a.shape[:-1] + (a.shape[-1] - window + 1, window)
...:     strides = a.strides + (a.strides[-1],)
...:     w = np.lib.stride_tricks.as_strided(a, shape=shape, strides=strides)
...:     return np.where(np.all(np.equal(w,b),1) == True)[0]

In [5]: get_indices(a,b)
Out[5]: array([2, 7])
``````
-
I changed an array `a`. `>>> a=np.array([False,False]) >>> b=np.array([False,True,True,False]) >>> get_indices(a,b)` `>>> Out: ValueError: negative dimensions are not allowed` – Olga Feb 20 '13 at 8:03
@Olga -- Yes, `shape` will be `(-1, 4)`, you can add `if len(a) < len(b): return np.array([])` to prevent that as in that case `b` cannot possibly be a subarray of `a`. – root Feb 20 '13 at 8:33
Thanks for the help – Olga Feb 20 '13 at 9:33

This looks very similar to a string search problem. If you want to avoid implementing one these string search algorithms, you could abuse pythons built in string search, which is very fast, by doing something like:

``````# I've added [True, True, True] at the end.
may_a = numpy.array([False, True, False, True, True, False, True, False, True, True, False, True, True, True])
may_b = numpy.array([False,True,True,False])

may_a_str = may_a.tostring()
may_b_str = may_b.tostring()

idx = may_a_str.find(may_b_str)
out_index = []
while idx >= 0:
out_index.append(idx)
idx = may_a_str.find(may_b_str, idx+1)
``````

This should work fine for boolean arrays. If you want to use this approach for another array type, you'll need to make sure the strides of the two arrays match and divide out_index by that stride.

You could also use the regular expression module instead of the loop to do the string search.

-
Thanks for the help! – Olga Feb 28 '13 at 12:16

I am not sure whether numpy provide a function for that. If it does not, here is a solution:

``````import numpy

def searchListIndexs(array, target):
ret = []
iLimit = len(array)-len(target)+1
jLimit = len(target)
for i in range(iLimit):
for j in range(jLimit):
if array[i+j] != target[j]:
break
else:
ret.append(i)
return ret

may_a = numpy.array([False, True, False, True, True, False, True, False, True, True, False])
may_b = numpy.array([False,True,True,False])
out_index = searchListIndexs(may_a, may_b)
print out_index #If you are using Python 3, then use print(out_index) instead.
``````
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Konfle Dolex, thanks, it is a solution, but It will work at data bulk slowly.. – Olga Feb 15 '13 at 8:12
Yep. :( This is a limitation of this approach. – Konfle Dolex Feb 15 '13 at 8:14
BTW, I guess that these is no faster algorithm than this. I guess it is necessary to iterate through the entire array because no sorting is possible in this case. – Konfle Dolex Feb 15 '13 at 8:16