# Prolog substitution

How can I replace a list with another list that contain the variable to be replaced. for example

``````rep([x, d, e, z, x, z, p], [x=z, z=x, d=c], R).
R = [z, c, e, x, z, x, p]
``````

the x to z and z doesn't change after it has been replaced.

so far I did only the one without the list

``````rep([], _, []).
rep(L1, H1=H2, L2) :-
rep(L1, H1, H2, L2).

rep([],_,_,[]).
rep([H|T], X1, X2, [X2|L]) :-
H=X1,
rep(T,X1,X2,L),
!.
rep([H|T],X1,X2,[H|L]) :-
rep(T,X1,X2,L).
``````
-

I find your code rather confused. For one thing, you have `rep/3` and `rep/4`, but none of them have a list in the second position where you're passing the list of variable bindings. `H1=H2` cannot possibly match a list, and that's the only `rep/3` clause that examines the second argument. If this is a class assignment, it looks like you're a little bit behind and I'd suggest you spend some time on the previous material.

The solution is simpler than you'd think:

``````rep([], _, []).
rep([X|Xs], Vars, [Y|Rest]) :-    member(X=Y, Vars), rep(Xs, Vars, Rest).
rep([X|Xs], Vars, [X|Rest]) :- \+ member(X=_, Vars), rep(Xs, Vars, Rest).
``````

We're using `member/2` to find a "variable binding" in the list (in quotes because these are atoms and not true Prolog variables). If it's in the list, Y is the replacement, otherwise we keep using X. And you see this has the desired effect:

``````?- rep([x, d, e, z, x, z, p], [x=z, z=x, d=c], R).
R = [z, c, e, x, z, x, p] ;
false.
``````

This could be made somewhat more efficient using "or" directly (and save us a choice point):

``````rep([], _, []).
rep([X|Xs], Vars, [Y|Ys]) :-
(member(X=Y, Vars), ! ; X=Y),
rep(Xs, Vars, Ys).
``````

See:

``````?- rep([x, d, e, z, x, z, p], [x=z, z=x, d=c], R).
R = [z, c, e, x, z, x, p].
``````
-

If you use SWI-Prolog, with module lambda.pl found there : http://www.complang.tuwien.ac.at/ulrich/Prolog-inedit/lambda.pl you can write :

``````:- use_module(library(lambda)).

rep(L, Rep, New_L) :-
maplist(\X^Y^(member(X=Z, Rep)
->  Y = Z
;   Y = X), L, New_L).
``````
-

You should attempt to keep the code simpler than possible:

``````rep([], _, []).
rep([X|Xs], Vs, [Y|Ys]) :-
( memberchk(X=V, Vs) -> Y = V ; Y = X ),
rep(Xs, Vs, Ys).
``````

Of course, note the idiomatic way (thru memberchk/2) to check for a variable value.

Still yet a more idiomatic way to do: transforming lists it's a basic building block in several languages, and Prolog is no exception:

``````rep(Xs, Vs, Ys) :- maplist(repv(Vs), Xs, Ys).
repv(Vs, X, Y) :- memberchk(X=V, Vs) -> Y = V ; Y = X .
``````
-
I admit I had to chuckle when I read you wrote: "You should attempt to keep the code simpler than possible". Made my day:) – repeat Jul 14 '15 at 22:02

Here's how you could proceed using `if_/3` and `(=)/3`.

First, we try to find a single `Key` in a list of pairs `K-V`. An extra argument reifies search success.

``````pairs_key_firstvalue_t([]       ,_  ,_    ,false).
pairs_key_firstvalue_t([K-V|KVs],Key,Value,Truth) :-
if_(K=Key,
(V=Value, Truth=true),
pairs_key_firstvalue_t(KVs,Key,Value,Truth)).
``````

``````assoc_key_mapped(Assoc,Key,Value) :-
if_(pairs_key_firstvalue_t(Assoc,Key,Value),
true,
Key=Value).
``````

Last, we put it all together using the `maplist/3`:

``````?- maplist(assoc_key_mapped([x-z,z-x,d-c]), [x,d,e,z,a,z,p], Rs).
Rs = [z,c,e,x,a,x,p].                       % OK, succeeds deterministically
``````
-
looks like a bad abstraction: There might be other cases where the first value is of interest, not only when equality applies. – false Jul 23 '15 at 12:13
@false. How about building `pairs_key_firstvalue_t` on top of that "find-first-item-in-list-suchthat" idiom instead? – repeat Jul 23 '15 at 12:51
@j4nbur53. No, it's not a function, but a predicate that an extra argument (`_t` is short for `_truth` / `_truthvalue`) to reflect success/failure into the atoms `true`/`false`. This argument is then used subsequently by `if_/3` for steering the control flow in the right direction. – repeat Nov 1 '15 at 19:46
@j4nbur53. cool links... I did not quite get the last sentence of your previous comment, please elaborate! p_t may be used with T (the extra argument) being bound or unbound. What you wrote about p_t being the same as a function f_t gets right to the heart of the matter: in p_t(...,T) the var T eventually gets uniquely determined when the instantiation is sufficient. However, this may not be so if p_t is used with non-ground data, so we use don't-know style nondeterminism then (and only then) in order to stay complete. – repeat Nov 1 '15 at 20:44

Let's improve this answer by moving the "recursive part" into `find_first_in_t/4`:

``````:- meta_predicate find_first_in_t(2,?,?,?).
find_first_in_t(P_2,X,Xs,Truth) :-
list_first_suchthat_t(Xs,X,P_2,Truth).

list_first_suchthat_t([]    ,_, _ ,false).
list_first_suchthat_t([E|Es],X,P_2,Truth) :-
if_(call(P_2,E),
(E=X,Truth=true),
list_first_suchthat_t(Es,X,P_2,Truth)).
``````

To fill in the "missing bits and pieces", we define `key_pair_t/3`:

``````key_pair_t(Key,K-_,Truth) :-
=(Key,K,Truth).
``````

Based on `find_first_in_t/4` and `key_pair_t/3`, we can write `assoc_key_mapped/3` like this:

``````assoc_key_mapped(Assoc,Key,Value) :-
if_(find_first_in_t(key_pair_t(Key),_-Value,Assoc),
true,
Key=Value).
``````

So, does the OP's use-case still work?

``````?- maplist(assoc_key_mapped([x-z,z-x,d-c]), [x,d,e,z,a,z,p], Rs).
Rs = [z,c,e,x,a,x,p].                            % OK. same result as before
``````

Building on `find_first_in_t/4`

``````memberd_t(X,Xs,Truth) :-                        % memberd_t/3
find_first_in_t(=(X),_,Xs,Truth).

:- meta_predicate exists_in_t(2,?,?).           % exists_in_t/3
exists_in_t(P_2,Xs,Truth) :-
find_first_in_t(P_2,_,Xs,Truth).
``````
-
`find_`... imperative. Also, unnecessarily weak due to `E=X`. – false Nov 1 '15 at 17:56
@false. Thx! Instead of using `E=X,Truth=true` I could use `=(E,X,Truth)`. While this would work with above def of `memberd_t/3`, it would not with `exists_in_t/3`. Do you have an idea? (Will edit ASAP anyway.) – repeat Nov 1 '15 at 18:20
@false. What do you mean by "weak due to E=X"? Is `(=)/3` better? `exists_in_t/3` uses `_` as `X`, which is bad with `(=)/3`... Help! – repeat Nov 1 '15 at 19:02
Say, `X` cannot influence termination of `P_2`. – false Nov 1 '15 at 19:11
@false. Good point! IMO that is also the answer to `maplistDCG//2`... – repeat Nov 1 '15 at 19:15

An approach that turns connectives or predicates into truth functionals, i.e. for a connective or predicate XX of arity n, the attempt is to make a predicate XX_t of arity n+1, with the last argument from the domain {true,false}, there are severe limitations if this approach is based on the ISO standard.

One typical limitation is that these predicates cannot so easily cut away branches of (;)/2. The normal cut (!) would also affect the surrounding of (;)/2 since (;)/2 is cut transparent.

What would be needed is a local cut (sys_local_cut), which can affect cut transparent predicates locally. So I guess this is the blind spot of all this look see I have a XX_t predicate, but it leaves to many choice points.

The problem is that local cut (sys_local_cut) is not in the ISO standard. But I guess if the developers of XX_t connnectiveswould have such means that would reach the same choice point behaviour as the original XX connnectives.

Bye

-
Which branches of `(;)/2` are you referring to? `if_/3` style predicates typically do not need to cut away choicepoints that were created by using `(;)/2`, as it avoids creating them in the first place. – repeat Nov 1 '15 at 21:24
Fair enough! Thank you for contributing! Would you care to comment on stackoverflow.com/a/33173811/4609915 ? It looks at different "if-then-else" constructs in Prolog, their algebraic properties, and the "efficiency" (measured by the number of useless choicepoints generated in cases that are sufficiently instantiated to allow succeeding deterministically). – repeat Nov 2 '15 at 11:45
I think I get your point. OTOH we actually do not claim "no useless choicepoints for all conceivable uses", but rather the much more pragmatic "none (or almost no) useless choicepoints for common uses of these predicates with ground data and logically sound results when instantiation does not suffice to eliminate the choicepoints right away". What's your stance on that? – repeat Nov 2 '15 at 12:11