`np.unique`

and `np.searchsorted`

could be used together to solve it -

```
def unq_searchsorted(A,B):
# Get unique elements of A and B and the indices based on the uniqueness
unqA,idx1 = np.unique(A,return_inverse=True)
unqB,idx2 = np.unique(B,return_inverse=True)
# Create mask equivalent to np.in1d(A,B) and np.in1d(B,A) for unique elements
mask1 = (np.searchsorted(unqB,unqA,'right') - np.searchsorted(unqB,unqA,'left'))==1
mask2 = (np.searchsorted(unqA,unqB,'right') - np.searchsorted(unqA,unqB,'left'))==1
# Map back to all non-unique indices to get equivalent of np.in1d(A,B),
# np.in1d(B,A) results for non-unique elements
return mask1[idx1],mask2[idx2]
```

Runtime tests and verify results -

```
In [233]: def org_app(A,B):
...: return np.in1d(A,B), np.in1d(B,A)
...:
In [234]: A = np.random.randint(0,10000,(10000))
...: B = np.random.randint(0,10000,(10000))
...:
In [235]: np.allclose(org_app(A,B)[0],unq_searchsorted(A,B)[0])
Out[235]: True
In [236]: np.allclose(org_app(A,B)[1],unq_searchsorted(A,B)[1])
Out[236]: True
In [237]: %timeit org_app(A,B)
100 loops, best of 3: 7.69 ms per loop
In [238]: %timeit unq_searchsorted(A,B)
100 loops, best of 3: 5.56 ms per loop
```

If the two input arrays are already `sorted`

and `unique`

, the performance boost would be substantial. Thus, the solution function would simplify to -

```
def unq_searchsorted_v1(A,B):
out1 = (np.searchsorted(B,A,'right') - np.searchsorted(B,A,'left'))==1
out2 = (np.searchsorted(A,B,'right') - np.searchsorted(A,B,'left'))==1
return out1,out2
```

Subsequent runtime tests -

```
In [275]: A = np.random.randint(0,100000,(20000))
...: B = np.random.randint(0,100000,(20000))
...: A = np.unique(A)
...: B = np.unique(B)
...:
In [276]: np.allclose(org_app(A,B)[0],unq_searchsorted_v1(A,B)[0])
Out[276]: True
In [277]: np.allclose(org_app(A,B)[1],unq_searchsorted_v1(A,B)[1])
Out[277]: True
In [278]: %timeit org_app(A,B)
100 loops, best of 3: 8.83 ms per loop
In [279]: %timeit unq_searchsorted_v1(A,B)
100 loops, best of 3: 4.94 ms per loop
```