(In this post, let `np`

be shorthand for `numpy`

.)

Suppose `a`

is a (*n* + *k*)‑dimensional `np.ndarray`

object, for some integers *n* > 1 and *k* > 1. (IOW, *n* + *k* > 3 is the value of `a.ndim`

). I want to enumerate `a`

over its first *n* dimensions; this means that, at each iteration, the enumerator/iterator produces a pair whose first element is a tuple `ii`

of *n* indices, and second element is the *k*‑dimensional sub-`ndarray`

at `a[ii]`

.

Granted, it is not difficult to code a function to do this (in fact, I give an example of such a function below), but I want to know this:

does

`numpy`

provide any special syntax or functions for carrying out this type of "partial" enumeration?

(Normally, when I want to iterate over an multidimensional `np.ndarray`

object, I use `np.ndenumerate`

, but it wouldn't help here, because (as far as I can tell) `np.ndenumerate`

would iterate over *all* *n* + *k* dimensions.)

Assuming that the answer to the question above is yes, then there's this follow-up:

what about the case where the

ndimensions to iterate over are not contiguous?

(In this case, the first element of the pair returned at each iteration by the enumerator/iterator would be a tuple of *r* > *n* elements, some of which would be a special value denoting "all", e.g. `slice(None)`

; the second element of this pair would still be an `ndarray`

of length *k*.)

Thanks!

The code below hopefully clarifies the problem specification. The function `partial_enumerate`

does what I would like to do using any special `numpy`

constructs available for the purpose. Following the definition of `partial_enumerate`

is a simple example for the case *n* = *k* = 2.

```
import numpy as np
import itertools as it
def partial_enumerate(nda, n):
"""Enumerate over the first N dimensions of the numpy.ndarray NDA.
Returns an iterator of pairs. The first element of each pair is a tuple
of N integers, corresponding to a partial index I into NDA; the second element
is the subarray of NDA at I.
"""
# ERROR CHECKING & HANDLING OMITTED
for ii in it.product(*[range(d) for d in nda.shape[:n]]):
yield ii, nda[ii]
a = np.zeros((2, 3, 4, 5))
for ii, vv in partial_enumerate(a, 2):
print ii, vv.shape
```

Each line of the output is a "pair of tuples", where the first tuple represents a partial set of *n* coordinates in `a`

, and the second one represents the shape of the *k*‑dimensional subarray of `a`

at those partial coordinates; (the value of this second pair is the same for all lines, as expected from the regularity of the array):

```
(0, 0) (4, 5)
(0, 1) (4, 5)
(0, 2) (4, 5)
(1, 0) (4, 5)
(1, 1) (4, 5)
(1, 2) (4, 5)
```

In contrast, iterating over `np.ndenumerate(a)`

in this case would result in `a.size`

iterations, each visiting an individual cell of `a`

.

`[row.shape for row in a]`

=`[1,2,1,3, ...]`

? – Hooked Mar 5 '12 at 16:29