# Context

This question is related to this one.

In Julia, I wanted to make a 2-dimensional array of 5 x 5 with the (i, j) element having `[i,j]`

like this:

```
5×5 Matrix{Vector{Int64}}:
[1, 1] [1, 2] [1, 3] [1, 4] [1, 5]
[2, 1] [2, 2] [2, 3] [2, 4] [2, 5]
[3, 1] [3, 2] [3, 3] [3, 4] [3, 5]
[4, 1] [4, 2] [4, 3] [4, 4] [4, 5]
[5, 1] [5, 2] [5, 3] [5, 4] [5, 5]
```

I tried this with using array comprehension:

```
N = 5
L_2 = [[x1,x2] for x1 = 1:N, x2 = 1:N]
```

# What I want to do

I want to generalize this definition for arbitrary dimension `D`

.

```
L_1 = [[x1] for x1 = 1:N] # 1-dimensional
L_2 = [[x1,x2] for x1 = 1:N, x2 = 1:N] # 2-dimensional
L_3 = [[x1,x2,x3] for x1 = 1:N, x2 = 1:N,x3 = 1:N] # 3-dimensional
...
#L_D = ??? # D-dimensional
```

How can I define?

It is okay without using array comprehension.

Any information would be appreciated.

`X`

, then you can just do`CartesianIndices(X)`

. This works for any dimensionality and size.`CartesianIndices(X)`

does the same thing as`CartesianIndices(size(X))`

. All this number crunching is only needed if`X`

doesn't already exist and you need a NxNxNx... array of indices.