Wow, this is one of the hardest functions to figure out among all the different SDKs I have used up to now. Therefore, I used the F*ck word many times during " my journey of understanding the permute function" . Here are some examples to prevent you from suffering a similar excruciating pain:

First, let's remember the dimensions' names of matrix in matlab: `A = zeros(4,5,7)`

, matrix A has 4 rows, 5 columns and 7 pages. And if you don't specify a dimension, its default count is set to 1. ( i.e. `B=zeros(10,3)`

has 10 rows, 3 columns and 1 page, **this order is important!**)

`order`

argument passed to `permute`

swap these dimensions in the matrix and produce an awkward combination of arrays, I think `permute`

is a misnomer for this effect.

Now let's move to the examples, Finally:

```
% A has 4 rows, 2 columns and 1 page
A =[ 5 6
8 2
2 2
1 3];
% (numbers in the order argument of permute function indicates dimensions,
% 3 = page , 2 = column and 1 = row dimensions):
B = permute(A,[3,2,1]); % [3,2,1] means [ page,column,row]
C = permute(A,[3,1,2]); % [3,1,2] means [ page,row,column]
D = permute(A,[1,3,2]); % [1,3,2] means [ row,page,column]
E = permute(A,[2,3,1]); % [2,3,1] means [ column,page,row]
F = permute(A,[2,1,3]); % [2,1,3] means [ column,row,page]
G = permute(A,[1,2,3]); % [1,2,3] means [ row,column,page]
```

*EXPLANATIONS:*

```
B = permute(A,[3,2,1]);
```

1x2x4 ( page(3) dimension of A = 1, column(2) dimension of A = 2, row(1) dimension of A = 4; 1 is row dimension, 2 is column dimension and 4 is page dimension for the generated B. Keep reading here until you understand)
So, there will be 4 1x2 (1x2x4) row matrixes. As in:

```
ans(:,:,1) =
5 6
ans(:,:,2) =
8 2
ans(:,:,3) =
2 2
ans(:,:,4) =
1 3
```

*

```
C = permute(A,[3,1,2]);
```

1x4x2 ( page(3) dimension of A = 1, row(1) dimension of A = 4, column(2) dimension of A = 2; 1 is row dimension, 4 is column dimension and 2 is page dimension for the generated C)
So, there will be 2 1x4 (1x4x2) row matrixes. As in:

```
ans(:,:,1) =
5 8 2 1
ans(:,:,2) =
6 2 2 3
```

*

```
D = permute(A,[1,3,2]);
```

4x1x2 ( row(1) dimension of A = 4, page(3) dimension of A = 1, column(2) dimension of A = 2; 4 is row dimension, 1 is column dimension and 2 is page dimension for the generated D)
So, there will be 2 4x1 (4x1x2) column matrixes. As in:

```
ans(:,:,1) =
5
8
2
1
ans(:,:,2) =
6
2
2
3
```

*

```
E = permute(A,[2,3,1]);
```

2x1x4 ( column(2) dimension of A = 2, page(3) dimension of A = 1, row(1) dimension of A = 4; 2 is row dimension, 1 is column dimension and 4 is page dimension for the generated E)
So, there will be 4 2x1 (2x1x4) column matrixes. As in:

```
ans(:,:,1) =
5
6
ans(:,:,2) =
8
2
ans(:,:,3) =
2
2
ans(:,:,4) =
1
3
```

*

```
F = permute(A,[2,1,3]); % this is transpose and same as [2,1]
```

2x4x1 ( column(2) dimension of A = 2, row(1) dimension of A = 4, page(3) dimension of A = 1; 2 is row dimension, 4 is column dimension and 1 is page dimension for the generated F)
So, there will be 1 2x4 (2x4x1) matrix. As in:

```
ans =
5 8 2 1
6 2 2 3
```

*

```
G = permute(A,[1,2,3]); % this makes no difference, using to show the reasoning
```

4x2x1 ( row(1) dimension of A = 4, column(2) dimension of A = 2, page(3) dimension of A = 1; 4 is row dimension, 2 is column dimension and 1 is page dimension for the generated G)
So, there will be 1 4x2 (4x2x1) matrix(itself!). As in:

```
ans =
5 6
8 2
2 2
1 3
```

Yes, this looks hard and it is indeed hard! To check if you understand thoroughly, try predicting a square Matrix's similar different permutations. Have fun, I mean have less pain :)