The ratings are stored in the numpy matrix `ratings`

, where rows correspond to users (index `u`

), while columns correspond to items (index `i`

). Since you want to calculate `sim(u, u')`

, i.e., the similarity between users, let's assume below that `kind = 'user'`

.

Now, let's have a look first on `r_{ui}r_{u'i}`

without the square-root scaling factors. This expression is summed over `i`

which can be interpreted as matrix multiplication of `r`

with the transpose of `r`

, i.e.:

```
\sum_i r_{ui}r_{u'i} = \sum_i r_{ui}(r^T)_{iu'} =: s_{uu'}
```

As done already above, let's denote the resulting matrix as `s`

(variable `sim`

in the code). This matrix is by definition symmetric and its rows/columns are labeled with the "user" indices `u/u'`

.

Now, the scaling "factor" `f_{u} := \sqrt\sum_i r^2_{ui}`

is in fact a vector indexed with `u`

(each item of which is the Euclidean norm of the corresponding row of the matrix `r`

). However, having constructed `s_{uu'}`

, we can see that `f_{u}`

is nothing else than `\sqrt s_{uu}`

.

Finally, the similarity factor of interest is `s_{uu'}/f{u}/f{u'}`

. The posted code calculates this for all indices `u/u'`

and returns the result as a matrix. To this end, it:

- calculates
`sim`

(the matrix `s`

above) as `ratings.dot(ratings.T)`

- gets the square root of its diagonal (the vector
`f`

above) as `np.sqrt(np.diagonal(sim))`

- to do the row/column scaling of
`s`

in an efficient way, this is then expressed as a two-dimensional array `norms = np.array([np.sqrt(np.diagonal(sim))])`

(note the missing `[]`

in your post)
- finally, the matrix
`s_{uu'}/f{u}/f{u'}`

is calculated as `sim / norms / norms.T`

. Here, since `norms`

has shape `(1, num_of_users)`

, the first division does the column scaling, while the division with `norms.T`

scales the rows.