Given your description of the `addUnique/2`

predicate, constraint logic programming can be used to implement a solution. This is *far* from beginner stuff, but I'll post an explanation anyway.

Firstly, it might be worthwhile looking up what constraint logic programming is, and an how to use an implementation (e.g., SWI-PL clpfd). Basically, constraint logic programming (particularly the finite domain solver) will allow you to specify the following constraints over your variables on the input list to `addUnique/2`

:

- How the variables on your input list can bind to certain numeric values (i.e., integers from 0 up to and including a specified value)
- How the different variables on your input list cannot simultaneously bind to the same value (i.e., != where different)
- How the sum of the variables in the input list plus any numbers must add up to a specified value (i.e., the maximum value that variables can take on in 1, above).

Together, these specifications will allow the underlying constraint solver to automatically determine what permissible values the variables can simultaneously take on given the above constraints, giving you your solutions (there may be several, one, or none).

Here is a solution using the aforementioned constraint solver in SWI-PROLOG (the clpfd solver):

```
:- use_module(library(clpfd)). % import and use the constraint solver library
addUnique([A|As], Val) :-
unique_vars([A|As], UVs), % determine all unique variables
UVs ins 0..Val, % (1) domain of all unique variables is 0 to Val
pairwise_inequ(UVs), % (2) all unique variables are pairwise !=
construct_sum_constr(As, Val, A, Program), % (3) construct the sum constraint
Program, % assert the sum constraint
label(UVs). % label domains to enumerate a solution (backtracks)
% predicate to return a list of unique vars, if present
unique_vars([], []).
unique_vars([V|Vs], [V|Uniq]) :-
var(V),
\+ var_memberchk(V, Vs), !,
unique_vars(Vs, Uniq).
unique_vars([_|Vs], Uniq) :-
unique_vars(Vs, Uniq).
% predicate to test if a variable appears in a list (possibly including variables)
var_memberchk(V0, [V1|_]) :-
V0 == V1, !.
var_memberchk(V0, [_|V1s]) :-
var_memberchk(V0, V1s).
% create constraints that assert each in the input list != to each other
pairwise_inequ([]).
pairwise_inequ([V|Vs]) :-
map_inequ(Vs, V),
pairwise_inequ(Vs).
% predicate to pairwise assert inequality between all list members
map_inequ([], _).
map_inequ([V1|V1s], V0) :-
V0 #\= V1, % the inequality constraint
map_inequ(V1s, V0).
% predicate to construct a summation constraint, whereby all variables in the
% input list are constructed into a sum with +/2 and finally equated to a value
construct_sum_constr([], Val, Sum, (Sum #= Val)).
construct_sum_constr([V|Vs], Val, Sum, Program) :-
construct_sum_constr(Vs, Val, (V + Sum), Program).
```

Running this code, e.g., gives you:

```
?- addUnique([A,B,B], 6).
A = 0,
B = 3 ;
A = 4,
B = 1 ;
A = 6,
B = 0.
```

`;`

enumerates the next solution for permissible bindings between variables. Note that `A`

and `B`

never take on the same value, as required, but all occurrences in the input list will always sum to `6`

. Another query:

```
?- addUnique([A,A,A],4).
false.
```

The result is failure here because no single integer could be found to bind to `A`

that, when summed up, totaled `4`

, whereas:

```
?- addUnique([A,A,A,A],4).
A = 1.
```

...as expected. Also, you wanted to try:

```
?- addUnique([A,B,C,D],4).
false.
```

Again, the result is failure here because all the variables `A`

, `B`

, `C`

and `D`

were all asserted to be different, and cannot all bind to `1`

.

**EDIT** ps. ony also wanted to try:

```
?- addUnique([A,A,A,1],4).
A = 1.
```

A simple modification to the code above ensures that only variables are used when calling `ins`

to assert domains (and not any numbers in the input list).