Your original `M`

-dimensional container is `A`

.

We want to create a new `N`

-dimensional container `B`

that will hold all content of `A`

.

First we have to figure out a mapping where we can easily find the same element in `A`

and in `B`

.

Let's use some examples to deduce how the mapping could be:

**(1)** M = 2, N = 1

```
A: a * b B: c
we can set the dimension c to be a * b, thus we have
A[i][j] = B[i * c + j]
```

**(2)** M = 3, N = 1

```
A: a * b * c B: d
d = a * b * c
A[i][j][k] = B[(i * b * c) + (j * c) + k]
```

**(3)** M = 3, N = 2

```
A: a * b * c B: d * e
d = a, e = b * c
A[i][j][k] = B[i][j * c + k]
```

**(4)** M = 4, N = 1

```
A: a * b * c * d B: e
e = a * b * c * d
A[i][j][k][l] = B[(i * b * c * d) + (j * c * d) + (k * d) + l]
```

**(5)** M = 5, N = 4

```
A: a * b * c * d * e B: u * v * w * x
u = a, v = b, w = c, x = d * e
A[i][j][k][l][m] = B[i][j][k][(l * e) + m]
```

**(6)** M = 5, N = 2

```
A: a * b * c * d * e B: f * g
f = a, g = b * c * d * e
A[i][j][k][l][m] = B[i][(j * c * d * e) + (k * d * e) + (l * e) + m]
```

If A has M dimensions a1, a2, ..., aM and B has N dimensions b1, b2, ..., bN, we can say that:

if M > N, then for all 0 < i < N, bi = ai and bN = aN * aN+1 * ... * aM.

This way we know how to create B and the size of each dimension of it.

With the mapping function shown in the examples, you can easily convert any `M`

-dimension matrix to a `N`

-dimension matrix.

If `M < N`

, you can do the same thing but in opposite direction.

`std::vector`

that provides X dimensional access should be enough, Only question would be what to do when underltying vector has to be different size. – Slava Jan 29 '20 at 19:103more comments