How do I code rec/3 in the presence of a meta_predicate declaration?

Question

I have the following code which works fine without a meta_predicate declaration. I have defined a predicate rec/3 as follows:

:- use_module(library(lambda)).

 rec(F,1,F).
 rec(F,N,\A^B^(call(F,A,H),call(G,H,B))) :- 
      N>1, M is N-1, rec(F,M,G).

The predicate rec/3 basically implements the following higherorder recursion equation:

 F^1 = F
 F^N = F*F^(N-1)      for N>1

Where * is the composition of two relations. It can for example be used to define addition in terms of successor. Successor would be the following relation:

 ?- F = \A^B^(B is A+1), call(F, 2, R).
 R = 3        /* 3 = 2+1 */

Addition can then be done as follows (SWI-Prolog):

 ?- F = \A^B^(B is A+1), rec(F, 8, G), call(G, 3, R).
 R = 11       /* 11 = 3+8 */

Now if a I add a meta_predicate declaration as follows, before the clauses of rec/3:

 :- meta_predicate rec(2,?,2).
 rec(F,1,F).
 rec(F,N,\A^B^(call(F,A,H),call(G,H,B))) :- 
      N>1, M is N-1, rec(F,M,G).

Things don't work anymore (SWI-Prolog):

  ?- F = \A^B^(B is A+1), rec(F, 8, G), call(G, 3, R).
  false

How can I fix the clauses for rec/3 and the query so that they work in the presence of meta_predicate?

Bye

Answer 1

The SWI meta-predicate declarations and modules are similar to those in Quintus, SICStus, and YAP. The fundamental assumption in those systems is that all information is passed through the declared meta-argument using (:)/2. There is no hidden state or context. For the common cases (simple instantiated arguments), the meta-predicate declarations are sufficient to relieve the burden of explicit qualification from the programmer.

However, in more complex situations as the present one, you have to ensure that explicit qualification will be added. Further, you need to ensure to "dereference" the (:)/2 prefixes accordingly. In SWI, there is strip_module/3:

?- strip_module(a:b:c:X,M,G).
X = G,
M = c.

Assume the definition:

rec(_, -1, local).
rec(_,  0, =).
rec(F, 1, F).

local(S0,S) :-
   S is S0+1.

Which now has to be written like so:

:- meta_predicate goal_qualified(:,-).
goal_qualified(G,G).

:- meta_predicate rec(2,+,2).
rec(_, -1, G) :-
    strip_module(G,_,VG),
    goal_qualified(local,VG).
rec(_, 0, G) :-
    strip_module(G,_,VG),
    goal_qualified(=,VG).
rec(F, 1, G) :-
    strip_module(G,_,F).

Many prefer to add module prefixes manually:

:- meta_predicate rec(2,+,2).
rec(_, -1, G) :-
    strip_module(G,_,mymodule:local).
...

And if we restrict ourselves to SWI only, thereby sacrificing compatibility to SICStus or YAP:

:- meta_predicate rec(2,+,2).
rec(_, -1, _:mymodule:local).
rec(_, 0, _:(=)).
rec(F, 1, _:F).

The rule in your question

rec(F,N,\A^B^(call(F,A,H),call(G,H,B))) :- 
      N>1, M is N-1, rec(F,M,G).

is thus translated as:

rec(F, N, MG) :-
   N > 1, M is N - 1,
   strip_module(MG,_,VG),
   goal_qualified(\A^B^(call(F,A,H),call(G,H,B)),VG),
   rec(F, M, G).

Assuming that library(lambda) is imported everywhere this can again be simplified in SWI to:

rec(F, N, _:(\A^B^(call(F,A,H),call(G,H,B)) )) :-
   N > 1, M is N -1,
   rec(F, M, G).

---

My conclusion

1mo: Systems should produce a warning for always failing clauses, like in:

| ?- [user].
% compiling user...
| :- meta_predicate p(0).
| p(1).
% compiled user in module user, 0 msec 2080 bytes
yes
| ?- p(X).
no

2do: Maybe it would be best to use the following auxiliary predicate:

:- meta_predicate cont_to(:,:).
cont_to(MGoal, MVar) :-
   strip_module(MVar, _, Var),
   (  nonvar(Var)
   -> throw(error(uninstantiation_error(Var),_))
   ;  true
   ),
   (  strip_module(MGoal,_,Goal),
      var(Goal)
   -> throw(error(instantiation_error,_))
   ;  true
   ),
   Var = MGoal.

Usage.

rec(_, -1, MV) :-
   cont_to(local, MV).

Or rather: one version for each number of auxiliary arguments, thus

:- meta_predicate cont0_to(0,0).
:- meta_predicate cont1_to(1,1).
:- meta_predicate cont2_to(2,2).
...

The name could be better, an operator would not do, though.

Answer 2

The following straigh-forward solution (only tested on SWI-Prolog but in any case far from the wide portability of the Logtalk-based solution):

:- module(m, [rec/3]).

:- use_module(library(lambda)). 

:- meta_predicate(rec(:,?,-)). 

rec(F, 1, F). 
rec(F, N, \A^B^(call(F,A,H),call(G,H,B))) :- 
    N > 1, M is N -1, 
    rec(F, M, G). 

gives:

?- [mrec].
true.

?- use_module(library(lambda)).
true.

?- F = \A^B^(B is A+1), rec(F,10,G), call(G,0,R).
F = \A^B^ (B is A+1),
G = \_G56^_G59^ (call(user: \A^B^ (...is...), _G56, _G67), call(\_G75^_G78^ (call(..., ..., ...), call(..., ..., ...)), _G67, _G59)),
R = 10 .

without requiring low level hacks (one of the motivations of the meta_predicate/1 directive is to avoid the need of using explicit qualification) or requiring a misleading a meta_predicate/1 directive. After re-reading the post and the comments, I still wonder why you want forcibly to write:

:- meta_predicate(rec(2,?,2)).

The first argument of rec/2 is not going to be used as a closure to which the meta-predicate will append two arguments to construct a goal in order to call it. The third argument is an output argument. In the first argument, "2" means input but for the third argument it means instead output! In neither case the meta-predicate is making any meta-calls! The end result of this breakage of the meaning of long established meta-argument indicators in meta-predicate directives is that a user will no longer know how to interpret a meta-predicate template without looking at the actual code of the meta-predicate.

Answer 3

No problem with a Logtalk version of your code:

:- object(rec).

    :- public(rec/3).
    :- meta_predicate(rec(2,*,*)).
    rec(F, 1, F).
    rec(F, N, [A,B]>>(call(F,A,H),call(G,H,B))) :- 
        N > 1, M is N - 1,
        rec(F, M, G).

    :- public(local/2).
    local(A, B) :-
        B is A + 1.

:- end_object.

I get:

$ swilgt
...
?- {rec}.
% [ /Users/pmoura/Desktop/lgtemp/stackoverflow/rec.lgt loaded ]
% (0 warnings)
true.

?- F = [A,B]>>(B is A+1), rec::rec(F, 8, G), logtalk<<call(G, 3, R).
F = [A, B]>> (B is A+1),
G = [_G88, _G91]>> (call([A, B]>> (B is A+1), _G88, _G99), call([_G108, _G111]>> (call([A, B]>> (B is A+1), _G108, _G119), call([_G128, _G131]>> (call(... >> ..., _G128, _G139), call(... >> ..., _G139, _G131)), _G119, _G111)), _G99, _G91)),
R = 11 ;
false.

?- F = [A,B]>>(rec::local(A,B)), rec::rec(F, 8, G), logtalk<<call(G, 3, R).
F = [A, B]>> (rec<<local(A, B)),
G = [_G2655, _G2658]>> (call([A, B]>> (rec<<local(A, B)), _G2655, _G2666), call([_G2675, _G2678]>> (call([A, B]>> (rec<<local(A, B)), _G2675, _G2686), call([_G2695, _G2698]>> (call(... >> ..., _G2695, _G2706), call(... >> ..., _G2706, _G2698)), _G2686, _G2678)), _G2666, _G2658)),
R = 11 ;
false.

Note the "fix" for the meta_predicate/1 directive. The code for the rec/3 predicate is the same except for the conversion of the lambda expression syntax to the Logtalk syntax. However, in the case of Logtalk, the meta_predicate/1 directive is not required for this example (as all that the rec/3 predicate does is converting a term to a new term) and only serves documentation purposes. You can comment it out and still use the rec::rec/3 predicate, calling it from either user (i.e. from the top-level interpreter) or from a client object.

The call/3 call is made in the context of the logtalk built-in object just to get the Logtalk lambda expression interpreted (Logtalk doesn't make, on purpose, its native lambda expression support available at the Prolog top-level interpreter).