**Leverage **`2D`

vectorized `matrix-multiplication`

Here's one with NumPy using matrix-multiplication on 2D data -

```
p1 = mat[:,-1].dot(mat[:,:-1])
p2 = norm(mat[:,:-1],axis=0)*norm(mat[:,-1])
out1 = p1/p2
```

**Explanation :** `p1`

is the vectorized equivalent of looping of `dot(mat[:,i], mat[:,-1])`

. `p2`

is of `(norm(mat[:,i])*norm(mat[:,-1]))`

.

Sample run for verification -

```
In [57]: np.random.seed(0)
...: mat = np.random.rand(149,1001)
In [58]: out = np.empty(mat.shape[1]-1)
...: for i in range(mat.shape[1]-1):
...: out[i] = dot(mat[:,i], mat[:,-1])/(norm(mat[:,i])*norm(mat[:,-1]))
In [59]: p1 = mat[:,-1].dot(mat[:,:-1])
...: p2 = norm(mat[:,:-1],axis=0)*norm(mat[:,-1])
...: out1 = p1/p2
In [60]: np.allclose(out, out1)
Out[60]: True
```

Timings -

```
In [61]: %%timeit
...: out = np.empty(mat.shape[1]-1)
...: for i in range(mat.shape[1]-1):
...: out[i] = dot(mat[:,i], mat[:,-1])/(norm(mat[:,i])*norm(mat[:,-1]))
18.5 ms ± 977 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)
In [62]: %%timeit
...: p1 = mat[:,-1].dot(mat[:,:-1])
...: p2 = norm(mat[:,:-1],axis=0)*norm(mat[:,-1])
...: out1 = p1/p2
939 µs ± 29.2 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)
# @yatu's soln
In [89]: a = mat
In [90]: %timeit cosine_similarity(a[None,:,-1] , a.T[:-1])
2.47 ms ± 461 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)
```

**Further optimize on **`norm`

with `einsum`

Alternatively, we could compute `p2`

with `np.einsum`

.

So, `norm(mat[:,:-1],axis=0)`

could be replaced by :

```
np.sqrt(np.einsum('ij,ij->j',mat[:,:-1],mat[:,:-1]))
```

Hence, giving us a modified `p2`

:

```
p2 = np.sqrt(np.einsum('ij,ij->j',mat[:,:-1],mat[:,:-1]))*norm(mat[:,-1])
```

Timings on same setup as earlier -

```
In [82]: %%timeit
...: p1 = mat[:,-1].dot(mat[:,:-1])
...: p2 = np.sqrt(np.einsum('ij,ij->j',mat[:,:-1],mat[:,:-1]))*norm(mat[:,-1])
...: out1 = p1/p2
607 µs ± 132 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)
```

`30x+`

speedup over loopy one!