# Rearranging variable_names

How to write in a standard conforming manner `avs_term_rearranged(AVs, T, AVsR)` with given `AVs` and `T` such that `AVsR` is a permutation of `AVs` with the elements arranged in same order as their variables occur in left-to-right order in `T`.

`AVs` is a list of elements of the form `A = V` where `A` is an atom designating a variable name like `'X'` and `V` is a corresponding variable. Such lists are produced by `read_term/2,3` with the read-option `variable_names/1` (7.10.3). Additionally, the precise order of elements is not defined.

``````| ?- read_term(T,[variable_names(AVs)]).
A+B+A+_+C.

AVs = ['A'=A,'B'=B,'C'=C]
T = A+B+A+_+C
``````

`T` is a term that contains all variables of `AVs` plus some more.

Note that in a standard conforming program one cannot rely on the term order for variables (7.2.1):

7.2.1 Variable

If `X` and `Y` are variables which are not identical then `X` term_precedes `Y` shall be implementation dependent except that during the creation of a sorted list (7.1.6.5, 8.10.3.1 j) the ordering shall remain constant.

NOTE — If `X` and `Y` are both anonymous variables then they are not identical terms (see 6.1.2 a).

Consider as an example from 8.4.3.4:

``````sort([f(U),U,U,f(V),f(U),V],L).
Succeeds, unifying L with [U,V,f(U),f(V)] or
[V,U,f(V),f(U)].
[The solution is implementation dependent.]
``````

So there are two possible ways how `sort/2` will work, and one cannot even rely on the success of:

``````sort([f(U),U,U,f(V),f(U),V],L), sort(L, K), L == K.
``````

As an example:

``````?- avs_term_rearranged(['A'=A,'B'=B,'C'=C], A+C+F+B, AVsR).
AVsR = ['A'=A,'C'=C,'B'=B].
``````
• is `T` an arbitrary term or is it of the same form? is it, e.g., also obtained from `read_term`? – Christian Fritz Jan 25 '14 at 0:00
• btw, you are using `T` twice in your question with different meanings. Might help to rename one of them to avoid confusion. – Christian Fritz Jan 25 '14 at 0:02
• @ChristianFritz: I cannot see a difference. Once, `T` is used as an argument for the sought predicate, and once it is used with `read_term` which in this case produces `T` and `AVs` such that they fit to the predicate. – false Jan 25 '14 at 13:58
• Could you then give an example input and expeted output? Is this what you have in mind `avs_term_rearranged(['A'=A,'B'=B,'C'=C], A+C+F+B, ['A'=A,'C'=C,'B'=B])` ? – Christian Fritz Jan 25 '14 at 17:11
• seems that if you can figure out how to use `ream_term/3` to read from a stream that you write to using `write_term/3` then you can get a representation of the variables in `T` that conform with that of `AVs`, and at that point it's a simple matter of discarding from the `T`-variables all those that do not appear in the `AVs` variables. – Christian Fritz Jan 25 '14 at 17:51

``````avs_term_rearranged(AVs, T, AVsR) :-
term_variables(T, Vs),
copy_term(Vs+AVs, Vs1+AVs1),
bind_names(AVs1),
build_vn_list(Vs, Vs1, AVsR).

bind_names([]).
bind_names([N=V|AVs]) :-
N = V,
bind_names(AVs).

build_vn_list([], [], []).
build_vn_list([V|Vs],[N|Ns],NVs) :-
( atom(N) ->
NVs = [N=V|NVs1]
; var(N) ->
NVs = NVs1
),
build_vn_list(Vs, Ns, NVs1).
``````
• Blows my mind. I could have sworn that one needs either something along @JSchimpf's version (limited by `max_arity` and `max_integer`) or that `sort/2` would be needed to associate the variables and their order. In any case, I'm happy I asked, I would have never found that solution. Maybe the mental block was that I hoped to rearrange the existing `(=)/2`, whereas you are "reconstructing" them, procedurally speaking. – false Jan 30 '14 at 22:46
• Going through it step-by-step: After `copy_term/2`: `AVs` can be reclaimed. After `bind_names/2`: `AVs1` can be reclaimed. Prior to `build_vn_list`: Only two lists are present: No pairs at all!! – false Jan 30 '14 at 23:13
• Brilliant! I was wondering whether we have a name for this technique of using a bipartite data structure with pairs of corresponding variables as a "mapper". – jschimpf Feb 1 '14 at 15:59

Use `term_variables/2` on `T` to obtain a list `Xs` with variables in the desired order. Then build a list with the elements of `AVs`, but in that order.

``````avs_term_rearranged(AVs, T, AVRs) :-
term_variables(T, Xs),
pick_in_order(AVs, Xs, AVRs).

pick_in_order([], [], []).
pick_in_order(AVs, [X|Xs], AVRs) :-
( pick(AVs, X, AV, AVs1) ->
AVRs = [AV|AVRs1],
pick_in_order(AVs1, Xs, AVRs1)
;
pick_in_order(AVs, Xs, AVRs)
).

pick([AV|AVs], X, AX, DAVs) :-
(_=V) = AV,
( V==X ->
AX = AV,
DAVs = AVs
;
DAVs = [AV|DAVs1],
pick(AVs, X, AX, DAVs1)
).
``````

Notes:

• this is quadratic because `pick/4` is linear
• `term_variables/2` is not strictly necessary, you could traverse `T` directly

My previous answer had quadratic runtime complexity. If that's a problem, here is a linear alternative. The reason this is a bit tricky is that unbound variables cannot be used as keys for hashing etc.

As before, we basically rearrange the list `AVs` such that its elements have the same order as the variables in the list `Xs` (obtained from `term_variables/2`). The new idea here is to first compute a (ground) description of the required permutation (`APs`), and then construct the permutation of `AV` using this description.

``````avs_term_rearranged(AVs, T, AVRs) :-
term_variables(T, Xs),
copy_term(AVs-Xs, APs-Ps),
ints(Ps, 0, N),
functor(Array, a, N),
distribute(AVs, APs, Array),
gather(1, N, Array, AVRs).

ints([], N, N).
ints([I|Is], I0, N) :- I is I0+1, ints(Is, I, N).

distribute([], [], _).
distribute([AV|AVs], [_=P|APs], Array) :-
nonvar(P),
arg(P, Array, AV),
distribute(AVs, APs, Array).

gather(I, N, Array, AVRs) :-
( I > N ->
AVRs = []
;
arg(I, Array, AV),
I1 is I+1,
( var(AV) -> AVRs=AVRs1 ; AVRs = [AV|AVRs1] ),
gather(I1, N, Array, AVRs1)
).
``````
• Nice but not portable since it requires Array to be a compound term with unbounded arity. A lesser problem is that it requires arbitrary size integers. – Per Mildner Jan 28 '14 at 16:31
• @Per, I honestly think after 30 years it is time to lay arity limits on compound terms to rest. – jschimpf Feb 1 '14 at 16:18
• @Per, I do not understand your comment about "arbitrary size integers". This code has no more requirement for large integers than any code using length/2. In fact, this is one of the few types of program where integers are strictly bounded (to something like 2^30 on 32-bit, or 2^61 on 64-bit machines). – jschimpf Feb 1 '14 at 16:28
• The question was specifically about a standard conforming solution. There is nothing in the standard that requires arbitrary arities of compound terms, or integers large enough to represent the length of a representable list. In practice, the integer size is unlikely to be a problem, this is why I wrote that its size is less of a problem. – Per Mildner Feb 2 '14 at 17:04
• Let me just summarize and clarify: (1) this is a fully standard-conforming program; (2) it does not require arbitrary sized integers; (3) ISO-Prolog implementations vary in the size of problem instances they support; (4) Per's solution is less likely to run into such implementation limits, and generally more elegant, that's why I upvoted and applauded it. – jschimpf Feb 3 '14 at 16:12

This version is very short, using `member/2` (from the Prolog prologue) for the search. It has very low auxiliary memory consumption. Only the list `AVsR` is created. No temporary heap-terms are created (on current implementations). It has quadratic overhead in the length of `AVs`, though.

``````avs_term_rearranged(AVs, T, AVsR) :-
term_variables(T, Vs),
rearrange(Vs, AVs, AVsR).

rearrange([], _, []).
rearrange([V|Vs], AVs, AVsR0) :-
( member(AV, AVs),
AV = (_=Var), V == Var ->
AVsR0 = [AV|AVsR]
;  AVsR0 = AVsR
),
rearrange(Vs, AVs, AVsR).
``````

Another aspect is that the `member(AV, AVs)` goal is inherently non-deterministic, even if only relatively shallow non-determinism is involved, whereas @jschimpf's (first) version does create a choice point only for the `(;)/2` of the if-then-else-implementation. Both versions do not leave any choice points behind.

Here is a version more faithfully simulating @jschimpf's idea. This, however, now creates auxiliary terms that are left on the heap.

``````rearrange_js([], _, []).
rearrange_js([V|Vs], AVs0, AVsR0) :-
( select(AV, AVs0, AVs),
AV = (_=Var), V == Var ->
AVsR0 = [AV|AVsR]
;  AVsR0 = AVsR,
AVs0 = AVs
),
rearrange_js(Vs, AVs, AVsR).
``````