Given the specification for advanced (or "fancy") indexing with integers, the guarantee that `A[nonzero(flag)] == A[flag]`

is also a guarantee that the values are sorted low-to-high in the 1-d case. However, in higher dimensions, the result (while "sorted") has a different structure than you might expect.

In short, given a 1-dimensional array of integers `ind`

and a 1-dimensional array `x`

to be indexed, we have the following for all valid `i`

defined for `ind`

:

```
result[i] = x[ind[i]]
```

`result`

takes the shape of `ind`

, and contains the values of `x`

at the indices indicated by `ind`

. This means that we can deduce that if `x[flag]`

maintains the original order of `x`

, and if `x[nonzero(flag)]`

is the same as `x[flag]`

, then `nonzero(flag)`

must always produce indices in sorted order.

The only catch is that for multidimensional arrays, the indices are stored as distinct arrays for each dimension being indexed. So in other words,

```
x[array([0, 1, 2]), array([0, 0, 0])]
```

is equal to

```
array([x[0, 0], x[1, 0], x[2, 0]])
```

The values are still sorted, but each dimension is broken out into its own array. (You can do interesting things with broadcasting as a result; but that's beyond the scope of this answer.)

The only problem with this line of reasoning is that -- to my great surprise -- I can't find an explicit statement guaranteeing that boolean indexing preserves the original order of the array. Nonetheless, I'm quite certain from experience that it does. More generally, it would be *unbelievably perverse* to have `x[[True, True, True]]`

return a reversed version of `x`

.