I thought this was an interesting problem and have modeled a proof-of-concept-version in MiniZinc (a very high level Constraint Programming system) which seems to be correct. I'm not sure if it's of any use, and to be honest I'm not sure if it's powerful for very largest problem instances.

The first problem instance has - according to this model - 4 solutions:

```
B A _
E D C
B A C
----------
B A _
D E C
B A C
----------
A B _
E D C
A B C
----------
A B _
D E C
A B C
```

The second example is considered unsatisfiable (as it should).

The complete model is here: http://www.hakank.org/minizinc/ordering_a_list_of_lists.mzn

The basic approach is to use matrices, where shorter rows are filled with a null value (here 0, zero). The problem instance is the matrix "matrix"; the resulting solution is in the matrix "x" (the decision variables, as integers which are then translated to strings in the output). Then there is a helper matrix, "perms" which are used to ensure that each row in "x" is a permutation of the corresponding row in "matrix", done with the predicate "permutation3". There are some other helper arrays/sets which simplifies the constraints.

The main MiniZinc model (sans output) is show below.

Here are some comments/assumptions which might make the model useless:

this is just a proof-of-concept model since I thought it was an interesting
problem.

I assume that the rows in the matrix (the problem data) is already ordered
by size (lower triangular). This should be easy to do as a preprocessing step
where Constraint Programming is not needed.

the shorter lists are filled with 0 (zero) so we can work with matrices.

since MiniZinc is a strongly typed language and don't support
symbols, we just define integers 1..5 to represent the letters A..E.
Working with integers is also beneficial when using traditional
Constraint Programming systems.

% The MiniZinc model (sans output)
include "globals.mzn";
int: rows = 3;
int: cols = 3;
int: A = 1;
int: B = 2;
int: C = 3;
int: D = 4;
int: E = 5;
int: max_int = E;
array[0..max_int] of string: str = array1d(0..max_int, ["_", "A","B","C","D","E"]);
% problem A (satifiable)
array[1..rows, 1..cols] of int: matrix =
array2d(1..rows, 1..cols,
[
A,B,0, % fill this shorter array with "0"
E,D,C,
A,B,C,
]);
% the valid values (we skip 0, zero)
set of int: values = {A,B,C,D,E};
% identify which rows a specific values are.
% E.g. for problem A:
% value_rows: [{1, 3}, {1, 3}, 2..3, 2..2, 2..2]
array[1..max_int] of set of int: value_rows =
[ {i | i in 1..rows, j in 1..cols where matrix[i,j] = v} | v in values];
% decision variables
% The resulting matrix
array[1..rows, 1..cols] of var 0..max_int: x;
% the permutations from matrix to x
array[1..rows, 1..cols] of var 0..max_int: perms;
%
% permutation3(a,p,b)
%
% get the permutation from a b using the permutation p.
%
predicate permutation3(array[int] of var int: a,
array[int] of var int: p,
array[int] of var int: b) =
forall(i in index_set(a)) (
b[i] = a[p[i]]
)
;
solve satisfy;
constraint
forall(i in 1..rows) (
% ensure unicity of the values in the rows in x and perms (except for 0)
alldifferent_except_0([x[i,j] | j in 1..cols]) /\
alldifferent_except_0([perms[i,j] | j in 1..cols]) /\
permutation3([matrix[i,j] | j in 1..cols], [perms[i,j] | j in 1..cols], [x[i,j] | j in 1..cols])
)
/\ % zeros in x are where there zeros are in matrix
forall(i in 1..rows, j in 1..cols) (
if matrix[i,j] = 0 then
x[i,j] = 0
else
true
endif
)
/\ % ensure that same values are in the same column:
% - for each of the values
% - ensure that it is positioned in one column c
forall(k in 1..max_int where k in values) (
exists(j in 1..cols) (
forall(i in value_rows[k]) (
x[i,j] = k
)
)
)
;
% the output
% ...