Thun/thun/thun.pl

%
%    Copyright © 2018 Simon Forman
%
%    This file is part of Thun
%
%    Thun is free software: you can redistribute it and/or modify
%    it under the terms of the GNU General Public License as published by
%    the Free Software Foundation, either version 3 of the License, or
%    (at your option) any later version.
%
%    Thun is distributed in the hope that it will be useful,
%    but WITHOUT ANY WARRANTY; without even the implied warranty of
%    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
%    GNU General Public License for more details.
%
%    You should have received a copy of the GNU General Public License
%    along with Thun.  If not see <http://www.gnu.org/licenses/>.
%
:- use_module(library(clpfd)).
:- use_module(library(dcg/basics)).
:- dynamic func/3.
:- dynamic def/2.


/*
To handle comparision operators the possibility of exceptions due to insufficiently instantiated
arguments must be handled.  First try to make the comparison and set the result to a Boolean atom.
If an exception happens just leave the comparison expression as the result and some other function
or combinator will deal with it.  Example:

    func(>,  [A, B|S], [C|S]) :- catch(
            (B > A -> C=true ; C=false),
            _,
            C=(B>A)  % in case of error.
            ).

To save on conceptual overhead I've defined a term_expansion/2 that sets up the func/3 for each op.
*/

term_expansion(comparison_operator(X), (func(X, [A, B|S], [C|S]) :-
    F =.. [X, B, A], catch((F -> C=true ; C=false), _, C=F))).

% I don't use Prolog-compatible op symbols in all cases.
term_expansion(comparison_operator(X, Y), (func(X, [A, B|S], [C|S]) :-
    F =.. [Y, B, A], catch((F -> C=true ; C=false), _, C=F))).

% Likewise for math operators, try to evaluate, otherwise use the symbolic form.

term_expansion(math_operator(X), (func(X, [A, B|S], [C|S]) :-
    F =.. [X, B, A], catch(C is F, _, C=F))).

term_expansion(math_operator(X, Y), (func(X, [A, B|S], [C|S]) :-
    F =.. [Y, B, A], catch(C is F, _, C=F))).


/*
An entry point.
*/

joy(InputString, StackIn, StackOut) :-
    phrase(joy_parse(Expression), InputString), !,
    thun(Expression, StackIn, StackOut).

/*
Parser

    joy :== number | '[' joy* ']' | atom

*/

joy_parse([T|J]) --> blanks, joy_term(T), blanks, joy_parse(J).
joy_parse([]) --> [].

joy_term(N) --> number(N), !.
joy_term(J) --> "[", !, joy_parse(J), "]".
joy_term(C) --> symbol(C).

symbol(C) --> chars(Chars), !, {Chars \= [61, 61], atom_string(C, Chars)}.

chars([Ch|Rest]) --> char(Ch), chars(Rest).
chars([Ch])      --> char(Ch).

char(Ch) --> [Ch], {Ch \== 91, Ch \== 93, code_type(Ch, graph)}.


/*
Interpreter
thun(Expression, InputStack, OutputStack)
*/

thun([], S, S).
thun(  [Lit|E], Si, So) :- literal(Lit), !, thun(E, [Lit|Si], So).
thun(  [Def|E], Si, So) :- def(Def, Body), !, append(Body, E, Eo), thun(Eo, Si, So).
thun( [Func|E], Si, So) :- func(Func, Si, S), thun(E, S, So).
thun([Combo|E], Si, So) :- combo(Combo, Si, S, E, Eo), thun(Eo, S, So).

% Some error handling.

thun([Unknown|E], Si, So) :-
    damned_thing(Unknown),
    write("wtf? "),
    writeln(Unknown),
    So = [[Unknown|E]|Si].

damned_thing(It) :-
    \+ literal(It),
    \+ def(It, _),
    \+ func(It, _, _),
    \+ combo(It, _, _, _, _).


/*
Literals
*/

literal(V) :- var(V).
literal(I) :- number(I).
literal([]).
literal([_|_]).
literal(true).
literal(false).

% Symbolic math expressions are literals.
literal(_+_).
literal(_-_).
literal(_*_).
literal(_/_).

/*
Functions
*/

func(cons, [A, B|S], [[B|A]|S]).
func(swap, [A, B|S],  [B, A|S]).
func(dup,     [A|S],  [A, A|S]).
func(pop,     [_|S],        S ).

% Symbolic math.  Compute the answer, or derivative, or whatever, later.
math_operator(+).
math_operator(-).
math_operator(*).
math_operator(/).
math_operator(mod).

% Attempt to calculate the value of a symbolic math expression.
func(calc, [A|S], [B|S]) :- B is A.

func(sqrt, [A|S], [sqrt(A)|S]).

func(concat, [A, B|S],   [C|S]) :- append(B, A, C).
func(flatten,   [A|S],   [B|S]) :- flatten(A, B).
func(swaack,    [R|S],   [S|R]).
func(stack,        S ,   [S|S]).
func(clear,        _ ,      []).
func(first, [[X|_]|S],   [X|S]).
func(rest,  [[_|X]|S],   [X|S]).
func(unit,      [X|S], [[X]|S]).

func(rolldown, [A, B, C|S], [B, C, A|S]).
func(dupd,        [A, B|S], [A, B, B|S]).
func(over,        [A, B|S], [B, A, B|S]).
func(tuck,        [A, B|S], [A, B, A|S]).

func(rollup, Si, So) :- func(rolldown, So, Si).
func(uncons, Si, So) :- func(cons, So, Si).

func(bool, [    0|S], [false|S]) :- !.
func(bool, [  0.0|S], [false|S]) :- !.
func(bool, [   []|S], [false|S]) :- !.
func(bool, [   ""|S], [false|S]) :- !.
func(bool, [false|S], [false|S]) :- !.

func(bool, [_|S], [true|S]).

comparison_operator(>).
comparison_operator(<).
comparison_operator(>=).
comparison_operator(<=, =<).
comparison_operator(=, =:=).
comparison_operator(<>, =\=).


/*
Definitions
*/

joy_def(def(Def, Body)) --> symbol(Def), blanks, "==", joy_parse(Body).

joy_defs([Def|Defs]) --> blanks, joy_def(Def), blanks, joy_defs(Defs).
joy_defs([]) --> [].

read_defs(DefsFile, Defs) :-
    read_file_to_codes(DefsFile, Codes, []),
    phrase(joy_defs(Defs), Codes).  

assert_defs(DefsFile) :-
    read_defs(DefsFile, Defs),
    forall(member(Def, Defs), assert_def(Def)).

assert_def(def(Def, Body)) :-
    retractall(def(Def, _)),
    assertz(def(Def, Body)).

:- assert_defs("defs.txt").


/*
Combinators
*/

combo(i,          [P|S], S, Ei, Eo) :- append(P, Ei, Eo).
combo(dip,     [P, X|S], S, Ei, Eo) :- append(P, [X|Ei], Eo).
combo(dipd, [P, X, Y|S], S, Ei, Eo) :- append(P, [Y, X|Ei], Eo).

combo(dupdip, [P, X|S], [X|S], Ei, Eo) :- append(P, [X|Ei], Eo).

combo(branch, [T, _,  true|S], S, Ei, Eo) :- append(T, Ei, Eo).
combo(branch, [_, F, false|S], S, Ei, Eo) :- append(F, Ei, Eo).
combo(branch, [T, F,  Expr|S], S, Ei, Eo) :-
    \+ Expr = true, \+ Expr = false,
    catch(  % Try Expr and do one or the other,
        (Expr -> append(T, Ei, Eo) ; append(F, Ei, Eo)),
        _,  % If Expr don't grok, try both branches.
        (append(T, Ei, Eo) ; append(F, Ei, Eo))
        ).


combo(loop, [_, false|S], S, E,  E ).
combo(loop, [B,  true|S], S, Ei, Eo) :- append(B, [B, loop|Ei], Eo).

combo(step, [_,    []|S],    S,  E,  E ).
combo(step, [P,   [X]|S], [X|S], Ei, Eo) :- !, append(P, Ei, Eo).
combo(step, [P, [X|Z]|S], [X|S], Ei, Eo) :-    append(P, [Z, P, step|Ei], Eo).

combo(times, [_, 0|S], S, E,  E ).
combo(times, [P, 1|S], S, Ei, Eo) :- append(P, Ei, Eo).
combo(times, [P, N|S], S, Ei, Eo) :- N #>= 2, M #= N - 1, append(P, [M, P, times|Ei], Eo).
combo(times, [_, N|S], S, _,  _ ) :- N #< 0, fail.

combo(genrec, [R1, R0, Then, If|S],
              [  Else, Then, If|S], E, [ifte|E]) :-
    Quoted = [If, Then, R0, R1, genrec],
    append(R0, [Quoted|R1], Else).


/*
Compiler
*/

joy_compile(Name, Expression) :- jcmpl(Name, Expression, Rule), asserta(Rule).

show_joy_compile(Name, Expression) :- jcmpl(Name, Expression, Rule), portray_clause(Rule).

jcmpl(Name, Expression, Rule) :-
    call_residue_vars(thun(Expression, Si, So), Term),
    copy_term(Term, Term, Gs),
    Head =.. [func, Name, Si, So],
    rule(Head, Gs, Rule).

rule(Head, [],    Head                        ). 
rule(Head, [A|B], Head :- maplist(call, [A|B])).

sjc(Name, InputString) :- phrase(joy_parse(E), InputString), show_joy_compile(Name, E).


% Simple DCGs to expand/contract definitions.

expando,    Body --> [Def], {def(Def, Body)}.
contracto, [Def] --> {def(Def, Body)}, Body.

% phrase(expando, ExprIn, ExprOut).