Well, this is basically a `template-matching problem`

that comes up in image-processing a lot. Listed in this post are two approaches: Pure NumPy based and OpenCV (cv2) based.

**Approach #1:** With NumPy, one can create a `2D`

array of sliding indices across the entire length of the input array. Thus, each row would be a sliding window of elements. Next, match up each row with the input sequence, which will bring in `broadcasting`

for a vectorized solution. We look for all `True`

rows indicating those are the ones that are the perfect matches and as such would be the starting indices of the matches. Finally, using those indices, create a range of indices extending up to the length of the sequence, to give us the desired output. The implementation would be -

```
def search_sequence_numpy(arr,seq):
""" Find sequence in an array using NumPy only.
Parameters
----------
arr : input 1D array
seq : input 1D array
Output
------
Output : 1D Array of indices in the input array that satisfy the
matching of input sequence in the input array.
In case of no match, an empty list is returned.
"""
# Store sizes of input array and sequence
Na, Nseq = arr.size, seq.size
# Range of sequence
r_seq = np.arange(Nseq)
# Create a 2D array of sliding indices across the entire length of input array.
# Match up with the input sequence & get the matching starting indices.
M = (arr[np.arange(Na-Nseq+1)[:,None] + r_seq] == seq).all(1)
# Get the range of those indices as final output
if M.any() >0:
return np.where(np.convolve(M,np.ones((Nseq),dtype=int))>0)[0]
else:
return [] # No match found
```

**Approach #2:** With OpenCV (cv2), we have a built-in function for `template-matching`

: `cv2.matchTemplate`

. Using this, we would have the starting matching indices. Rest of the steps would be same as for the previous approach. Here's the implementation with `cv2`

:

```
from cv2 import matchTemplate as cv2m
def search_sequence_cv2(arr,seq):
""" Find sequence in an array using cv2.
"""
# Run a template match with input sequence as the template across
# the entire length of the input array and get scores.
S = cv2m(arr.astype('uint8'),seq.astype('uint8'),cv2.TM_SQDIFF)
# Now, with floating point array cases, the matching scores might not be
# exactly zeros, but would be very small numbers as compared to others.
# So, for that use a very small to be used to threshold the scorees
# against and decide for matches.
thresh = 1e-5 # Would depend on elements in seq. So, be careful setting this.
# Find the matching indices
idx = np.where(S.ravel() < thresh)[0]
# Get the range of those indices as final output
if len(idx)>0:
return np.unique((idx[:,None] + np.arange(seq.size)).ravel())
else:
return [] # No match found
```

**Sample run**

```
In [512]: arr = np.array([2, 0, 0, 0, 0, 1, 0, 1, 0, 0])
In [513]: seq = np.array([0,0])
In [514]: search_sequence_numpy(arr,seq)
Out[514]: array([1, 2, 3, 4, 8, 9])
In [515]: search_sequence_cv2(arr,seq)
Out[515]: array([1, 2, 3, 4, 8, 9])
```

**Runtime test**

```
In [477]: arr = np.random.randint(0,9,(100000))
...: seq = np.array([3,6,8,4])
...:
In [478]: np.allclose(search_sequence_numpy(arr,seq),search_sequence_cv2(arr,seq))
Out[478]: True
In [479]: %timeit search_sequence_numpy(arr,seq)
100 loops, best of 3: 11.8 ms per loop
In [480]: %timeit search_sequence_cv2(arr,seq)
10 loops, best of 3: 20.6 ms per loop
```

Seems like the Pure NumPy based one is the safest and fastest!

`array([2, 0, 0,0, 1, 0, 1, 0, 0])`

?