This is naturally solved, in Prolog. See also Faster implementation of verbal arithmetic in Prolog :

```
%% unique selection from narrowing domain
selectM([A|As],S,Z):- select(A,S,S1),selectM(As,S1,Z).
selectM([],Z,Z).
%% a puzzle
cryp([[C,R,O,S,S]+[R,O,A,D,S]=[D,A,N,G,E,R]]):-
Dom=[0,1,2,3,4,5,6,7,8,9],
selectM([S],Dom,D0),
N1 is S+S, R is N1 mod 10, R=\=0,
selectM([R,D],D0,D1), D=\=0,
N2 is (N1//10)+S+D, E is N2 mod 10,
selectM([E,O,A,G],D1,D2),
N3 is (N2//10)+O+A, G is N3 mod 10,
N4 is (N3//10)+R+O, N is N4 mod 10,
selectM([N,C],D2,_), C=\=0,
N5 is (N4//10)+C+R, A is N5 mod 10,
D is N5//10.
```

The key to efficiency is to choose the instantiations of digits progressively, one by one, testing right away to scrap the invalid choices as soon as possible. I'm sure this can be translated to Mathematica.