# How to generate a multidimensional array of indexed variables in Maxima?

I want to take a list of non-negative integers `D=[d1,...,dm]` and and generate a multidimensional array of indexed symbols A in the form of:

where `0<=i_j<=d_j`. For example if `D=[2,3]` then A should be

``````[[a_[0,0],a_[0,1],a_[0,2]],
[a_[1,0],a_[1,1],a_[1,2]]]
``````

For this case I could nest two for loops to generate the said array, however `D` does not necessarily have a length of 2 and I don't know how to nest an arbitrary number of for loops!

I would appreciate if you could help me know how I can generate A from `D`.

P.S. What I want to finally achieve is to create a multivariate polynomial as explained here.

• Does `genmatrix` help you? Try `genmatrix(a, 2, 3);` – Eelvex Aug 3 at 11:41
• @Eelvex No I have not. Would you be so kind to share an example below in a post? – Foad Aug 3 at 20:22
• @Eelvex I tested this. this is amazing. Is it also possible to use for generating the X tensor as I have explained here? – Foad Aug 3 at 20:33
• I suppose you could use `genmatrix(lambda ([i,j], x[1]^i*x[2]^j), 2, 3, 0, 0) * genmatrix(a, 2, 3, 0, 0))` and then `list_matrix_entries(%)` and `apply("+", %)`. I don't know if that would be the best way to do it. – Eelvex Aug 4 at 14:34
• @Eelvex Great. I was wondering if you would write this is a post below? – Foad Aug 6 at 7:01

Here's one way to do it. The essential part is that I called `cartesian_product` to construct the list of all combinations of indices, and then `arrayapply` to create the subscripted expressions.

``````(%i11) ii:setify(makelist(i, i, 0, n)), n=2;
(%o11)                      {0, 1, 2}
(%i12) apply (cartesian_product, makelist (ii, m)), m=3;
(%o12) {[0, 0, 0], [0, 0, 1], [0, 0, 2], [0, 1, 0], [0, 1, 1],
[0, 1, 2], [0, 2, 0], [0, 2, 1], [0, 2, 2], [1, 0, 0],
[1, 0, 1], [1, 0, 2], [1, 1, 0], [1, 1, 1], [1, 1, 2],
[1, 2, 0], [1, 2, 1], [1, 2, 2], [2, 0, 0], [2, 0, 1],
[2, 0, 2], [2, 1, 0], [2, 1, 1], [2, 1, 2], [2, 2, 0],
[2, 2, 1], [2, 2, 2]}
(%i13) map (lambda ([l], arrayapply (_a, l)), %);
(%o13) {_a       , _a       , _a       , _a       , _a       ,
0, 0, 0    0, 0, 1    0, 0, 2    0, 1, 0    0, 1, 1
_a       , _a       , _a       , _a       , _a       ,
0, 1, 2    0, 2, 0    0, 2, 1    0, 2, 2    1, 0, 0
_a       , _a       , _a       , _a       , _a       ,
1, 0, 1    1, 0, 2    1, 1, 0    1, 1, 1    1, 1, 2
_a       , _a       , _a       , _a       , _a       ,
1, 2, 0    1, 2, 1    1, 2, 2    2, 0, 0    2, 0, 1
_a       , _a       , _a       , _a       , _a       ,
2, 0, 2    2, 1, 0    2, 1, 1    2, 1, 2    2, 2, 0
_a       , _a       }
2, 2, 1    2, 2, 2
(%i14) grind (%);

{_a[0,0,0],_a[0,0,1],_a[0,0,2],_a[0,1,0],_a[0,1,1],_a[0,1,2],
_a[0,2,0],_a[0,2,1],_a[0,2,2],_a[1,0,0],_a[1,0,1],_a[1,0,2],
_a[1,1,0],_a[1,1,1],_a[1,1,2],_a[1,2,0],_a[1,2,1],_a[1,2,2],
_a[2,0,0],_a[2,0,1],_a[2,0,2],_a[2,1,0],_a[2,1,1],_a[2,1,2],
_a[2,2,0],_a[2,2,1],_a[2,2,2]}\$
(%o14)                        done
``````

This is just working at the top-level interactive prompt; if you need to construct a function, I think you'll see how to do it.

EDIT: Here's a way to create the polynomial.

``````(%i16) S : {[0, 0, 0], [0, 0, 1], [0, 0, 2], [0, 1, 0], [0, 1, 1],
[0, 1, 2], [0, 2, 0], [0, 2, 1], [0, 2, 2], [1, 0, 0],
[1, 0, 1], [1, 0, 2], [1, 1, 0], [1, 1, 1], [1, 1, 2],
[1, 2, 0], [1, 2, 1], [1, 2, 2], [2, 0, 0], [2, 0, 1],
[2, 0, 2], [2, 1, 0], [2, 1, 1], [2, 1, 2], [2, 2, 0],
[2, 2, 1], [2, 2, 2]} \$

(%i17) L : listify (S) \$

(%i18) A : map (lambda ([l], arrayapply (_a, l)), L);
(%o18) [_a       , _a       , _a       , _a       , _a       ,
0, 0, 0    0, 0, 1    0, 0, 2    0, 1, 0    0, 1, 1
_a       , _a       , _a       , _a       , _a       ,
0, 1, 2    0, 2, 0    0, 2, 1    0, 2, 2    1, 0, 0
_a       , _a       , _a       , _a       , _a       ,
1, 0, 1    1, 0, 2    1, 1, 0    1, 1, 1    1, 1, 2
_a       , _a       , _a       , _a       , _a       ,
1, 2, 0    1, 2, 1    1, 2, 2    2, 0, 0    2, 0, 1
_a       , _a       , _a       , _a       , _a       ,
2, 0, 2    2, 1, 0    2, 1, 1    2, 1, 2    2, 2, 0
_a       , _a       ]
2, 2, 1    2, 2, 2
(%i19) U : map (lambda ([l], product (u[i]^l[i], i, 1, length(l))), L);
2                 2   2   2      2  2
(%o19) [1, u , u , u , u  u , u  u , u , u  u , u  u , u ,
3   3   2   2  3   2  3   2   2  3   2  3   1
2                          2      2      2
u  u , u  u , u  u , u  u  u , u  u  u , u  u , u  u  u ,
1  3   1  3   1  2   1  2  3   1  2  3   1  2   1  2  3
2  2   2   2      2  2   2      2         2     2   2  2
u  u  u , u , u  u , u  u , u  u , u  u  u , u  u  u , u  u ,
1  2  3   1   1  3   1  3   1  2   1  2  3   1  2  3   1  2
2  2      2  2  2
u  u  u , u  u  u ]
1  2  3   1  2  3
(%i20) A.U;
2  2            2    2               2    2            2
(%o20) u  u  _a        u  + u  u  _a        u  + u  _a        u
1  2   2, 2, 2  3    1  2   2, 1, 2  3    1   2, 0, 2  3
2  2              2  2                    2
+ u  _a        u  u  + _a        u  u  + u  _a        u  u
1   1, 2, 2  2  3     0, 2, 2  2  3    1   1, 1, 2  2  3
2                 2              2
+ _a        u  u  + u  _a        u  + _a        u
0, 1, 2  2  3    1   1, 0, 2  3     0, 0, 2  3
2  2                 2                    2
+ u  u  _a        u  + u  u  _a        u  + u  _a        u
1  2   2, 2, 1  3    1  2   2, 1, 1  3    1   2, 0, 1  3
2                 2
+ u  _a        u  u  + _a        u  u  + u  _a        u  u
1   1, 2, 1  2  3     0, 2, 1  2  3    1   1, 1, 1  2  3
+ _a        u  u  + u  _a        u  + _a        u
0, 1, 1  2  3    1   1, 0, 1  3     0, 0, 1  3
2  2              2                 2
+ u  u  _a        + u  u  _a        + u  _a
1  2   2, 2, 0    1  2   2, 1, 0    1   2, 0, 0
2              2
+ u  _a        u  + _a        u  + u  _a        u
1   1, 2, 0  2     0, 2, 0  2    1   1, 1, 0  2
+ _a        u  + u  _a        + _a
0, 1, 0  2    1   1, 0, 0     0, 0, 0
``````

Note that the ordering of terms within each product doesn't conform to what humans would consider the usual convention, e.g. `[1]^2*u[2]^2*_a[2,2,2]*u[3]^2` is the first term. Maxima is ordering the terms according to the subscripts, therefore `_a[2,2,2]` comes after `u[1]` and before `u[3]`. In some contexts this coincides with what humans expect, but here it doesn't; in any event, Maxima is consistent in hope of making programmatic manipulation work better.

``````(%i21) grind (%);

u[1]^2*u[2]^2*_a[2,2,2]*u[3]^2+u[1]^2*u[2]*_a[2,1,2]*u[3]^2
+u[1]^2*_a[2,0,2]*u[3]^2
+u[1]*_a[1,2,2]*u[2]^2*u[3]^2
+_a[0,2,2]*u[2]^2*u[3]^2
+u[1]*_a[1,1,2]*u[2]*u[3]^2
+_a[0,1,2]*u[2]*u[3]^2
+u[1]*_a[1,0,2]*u[3]^2
+_a[0,0,2]*u[3]^2
+u[1]^2*u[2]^2*_a[2,2,1]*u[3]
+u[1]^2*u[2]*_a[2,1,1]*u[3]
+u[1]^2*_a[2,0,1]*u[3]
+u[1]*_a[1,2,1]*u[2]^2*u[3]
+_a[0,2,1]*u[2]^2*u[3]
+u[1]*_a[1,1,1]*u[2]*u[3]
+_a[0,1,1]*u[2]*u[3]
+u[1]*_a[1,0,1]*u[3]
+_a[0,0,1]*u[3]
+u[1]^2*u[2]^2*_a[2,2,0]
+u[1]^2*u[2]*_a[2,1,0]
+u[1]^2*_a[2,0,0]
+u[1]*_a[1,2,0]*u[2]^2
+_a[0,2,0]*u[2]^2
+u[1]*_a[1,1,0]*u[2]
+_a[0,1,0]*u[2]+u[1]*_a[1,0,0]
+_a[0,0,0]\$
(%o21)                        done
``````
• Thanks a lot. this is very close to what I want, except it is not a multidimensional array/list. What I want to finally achieve is to create a multivariate polynomial as explained here. and for that I think I need a multidimensional list to perform the Frobenius inner product later. – Foad Aug 2 at 6:54
• @Foad I've edited my answer to include a way to create the polynomial. Let me know if I've misunderstood the goal. – Robert Dodier Aug 2 at 16:44
• you are awesome. I'm gonna first try the code, and then edit my post to fit with the answer you gave me. I was also wondering if you could be so kind to take a look at my follow up question here? – Foad Aug 2 at 18:57