You could use np.lexsort:

numpy.lexsort(keys, axis=-1)

Perform an indirect sort using a sequence of keys.

Given multiple sorting keys, which can be interpreted as columns in a
spreadsheet, lexsort returns an array of integer indices that
describes the sort order by multiple columns.

```
In [13]: data = np.matrix(np.arange(10)[::-1].reshape(-1,2))
In [14]: data
Out[14]:
matrix([[9, 8],
[7, 6],
[5, 4],
[3, 2],
[1, 0]])
In [15]: temp = data.view(np.ndarray)
In [16]: np.lexsort((temp[:, 1], ))
Out[16]: array([4, 3, 2, 1, 0])
In [17]: temp[np.lexsort((temp[:, 1], ))]
Out[17]:
array([[1, 0],
[3, 2],
[5, 4],
[7, 6],
[9, 8]])
```

Note if you pass more than one key to `np.lexsort`

, the *last* key is the primary key. The next to last key is the second key, and so on.

Using `np.lexsort`

as I show above requires the use of a temporary array because `np.lexsort`

does not work on numpy matrices. Since
`temp = data.view(np.ndarray)`

creates a view, rather than a copy of `data`

, it does not require much extra memory. However,

```
temp[np.lexsort((temp[:, 1], ))]
```

is a new array, which does require more memory.

There is also a way to sort by columns *in-place*. The idea is to view the array as a structured array with two columns. Unlike plain ndarrays, structured arrays have a `sort`

method which allows you to specify columns as keys:

```
In [65]: data.dtype
Out[65]: dtype('int32')
In [66]: temp2 = data.ravel().view('int32, int32')
In [67]: temp2.sort(order = ['f1', 'f0'])
```

Notice that since `temp2`

is a *view* of `data`

, it does not require allocating new memory and copying the array. Also, sorting `temp2`

modifies `data`

at the same time:

```
In [69]: data
Out[69]:
matrix([[1, 0],
[3, 2],
[5, 4],
[7, 6],
[9, 8]])
```