# Non-trivial Prolog find and replace

So we can easily find and replace an atom with another atom in Prolog by doing something like:

``````replace([],A,B,[]).
replace([H|T],A,B,[B|Result]) :-
H=A,
replace(T,A,B,Result),!.
replace([H|T],A,B,[H|Result]) :-
replace(T,A,B,Result).
``````

I'm sure there are other ways to do this too.

However, I want to do something more complicated in logic in computing. How would you do something like replacing conjunctions like `conj(x,y)` in a logical statement with just (x,y)? So it's like final and replace but not with atoms. So we could have something like `reduce(conj(conj(x,y),z)).` that I would want reducing to `((x,y),z)`.

This is a simple example with only conjunctions but this is what I want to happen in the case of conjunctions. If anyone's interested, this is all about descriptive logic and the tableau method.

What I'm confused about it how you go about doing a find and replace when the input isn't actually a list; it's a structure. I don't see how you can solve this without using the standard `[H|T]` trick with recursion and lists. Has anyone got any ideas?

Many thanks.

• Why not place the cut after the first H=A instead of after the replace/4? Your code will run faster since the Prolog system can then detect that replace/4 is deterministic.
– user502187
Oct 10, 2012 at 9:21

This is done in a straightforward way by writing a meta-interpreter, such as the following:

``````replace(V, V) :-
% pass vars through
var(V), !.
replace(A, A) :-
% pass atoms through
atomic(A), !.
replace([], []) :-
% pass empty lists through
!.
replace([X|Xs], [Y|Ys]) :-
% recursively enter non-empty lists
!,
replace(X, Y),
replace(Xs, Ys).
replace(conj(X,Y), (NX,NY)) :-
% CUSTOM replacement clause for conj/2
!,
replace(X, NX),
replace(Y, NY).
replace(T, NT) :-
% finally, recursively enter any as yet unmatched compound term
T =.. [F|AL],
replace(AL, NAL),
NT =.. [F|NAL].
``````

Note the second last clause, which serves to perform a replacement of your specific case of replacing `conj/2` with conjunction, `,/2`. You can add as many other clauses in the same manner as this to perform term replacement in general, because the rest of the definition (all other clauses of `replace/2`) here will recursively deconstruct any PROLOG term, as we've covered all the types; vars, atoms, and compound terms (including lists explicitly).

Executing this in your case gives us:

``````?- replace(conj(conj(x,y),z), NewTerm).
NewTerm = ((x, y), z).
``````

Note that this definition will perform the correct replacement of any terms nested to arbitrary depth within another term.

• Thank you for this sharky. Clever stuff but... too clever, do you recommend any resources to learn about meta interpreters? Thank you.
– ale
Nov 9, 2010 at 18:12
• Too clever? As a PROLOG programmer, this is a utility predicate I routinely use to do term manipulation, and would be in any professional PROLOG programmer's bag-of-tricks ;) For resources on meta-interpreters, you can look at "Programming In Prolog" by Clocksin and Mellish, and "The art of Prolog" by Leon Sterling and Ehud Shapiro. By 'meta-interpreter', I mean PROLOG code that can understand/interpret PROLOG code, which is particularly suited to your question.
– user206428
Nov 9, 2010 at 22:08

Recall that a list is just a certain kind of structure, so you can easily translate your code to match any other structure as well. It may help you to use a cleaner representation for your data: Just as you use conj/2 to denote conjunctions, you could introduce a functor var/1 to denote variables:

``````reduce(conj(X0,Y0), (X,Y)) :-
reduce(X0, X),
reduce(Y0, Y).
reduce(var(X), X).
``````

Example:

``````?- reduce(conj(conj(var(x),var(y)), var(z)), R).
R = ((x, y), z).
``````

You can turn a general term into a list using `=..`, e.g.

``````?- conj(conj(x,y),z) =.. List.
List = [conj, conj(x, y), z].
``````

Doing this recursively, you can flatten out the complete term.

A general predicate that changes certain nodes in the input term would look something like this:

``````change_term(NodeChanger, Term1, Term3) :-
call(NodeChanger, Term1, Term2),
change_term(NodeChanger, Term2, Term3),
!.

change_term(NodeChanger, Term1, Term2) :-
Term1 =.. [Functor | SubTerms1],
change_termlist(NodeChanger, SubTerms1, SubTerms2),
Term2 =.. [Functor | SubTerms2].

change_termlist(_, [], []).

change_termlist(NodeChanger, [Term1 | Terms1], [Term2 | Terms2]) :-
change_term(NodeChanger, Term1, Term2),
change_termlist(NodeChanger, Terms1, Terms2).
``````

If you now define:

``````conj_changer(conj(X, Y), (X, Y)).
``````

then you can define your reduce-predicate by:

``````reduce(Term1, Term2) :-
change_term(conj_changer, Term1, Term2).
``````

Usage:

``````?- reduce(conj(conj(x,y),z), ReducedTerm).
ReducedTerm = ((x, y), z).
``````

You have to be careful though how you define the `NodeChanger`, certain definitions can make `change_term/3` loop. Maybe somebody can improve on that.