I believe the best way to describe your arrays-with-subgroups is using cell arrays:
my_array = {1 [2 3] 4}
my_array =
{[1]} {1×2 double} {[4]}
Then, you can use perms to permute the order of the cells:
my_array_permutations = perms(my_array)
my_array_permutations =
{[ 4]} {1×2 double} {[ 1]}
{[ 4]} {[ 1]} {1×2 double}
{1×2 double} {[ 4]} {[ 1]}
{1×2 double} {[ 1]} {[ 4]}
{[ 1]} {[ 4]} {1×2 double}
{[ 1]} {1×2 double} {[ 4]}
I haven't quite figured out how to get the whole thing back as a normal matrix, but mashing it into cell2mat in the right way is a possibility. This will at least work for individual rows:
cell2mat(my_array_permutations(1,:))
ans = 1×4
4 2 3 1
For the general problem, an easy way to create these sort of cell arrays is by listing the number of elements per subgroup:
A = [ 1 2 3 4 5 6 7 8]
G = [1 3 1 1 2];
A_g = mat2cell(A,1,G)
A_grouped =
{[1]} {1×3 double} {[5]} {[6]} {1×2 double}
A_perms = perms(A_grouped);
Finally, you might want to add a pre-emptive check of whether you can actually handle the number of permutations, since factorials grow very fast (5 subgoups: 120 perms | 10 groups: 3 million perms | 20 groups: 2e18 perms)
