module newtok; % Functions for introducing infix tokens to the system.
% Author: Anthony C. Hearn.
% Copyright (c) 1987 The RAND Corporation. All rights reserved.
fluid '(!*msg !*redeflg!*);
global '(preclis!* fixedpreclis!*);
% Several operators in REDUCE are used in an infix form (e.g., +,- ).
% The internal alphanumeric names associated with these operators are
% introduced by the function NEWTOK defined below. This association,
% and the precedence of each infix operator, is initialized in this
% section. We also associate printing characters with each internal
% alphanumeric name as well.
fixedpreclis!* := '(where !*comma!* setq);
preclis!*:= '(or and member memq equal neq eq geq greaterp leq % not
lessp freeof plus difference times quotient expt cons);
deflist ('(
% (not not)
(plus plus)
(difference minus)
(minus minus)
(times times)
(quotient recip)
(recip recip)
), 'unary);
flag ('(and or !*comma!* plus times),'nary);
flag ('(cons setq plus times),'right);
deflist ('((minus plus) (recip times)),'alt);
symbolic procedure mkprec;
begin scalar x,y,z;
x := append(fixedpreclis!*,preclis!*);
y := 1;
a: if null x then return nil;
put(car x,'infix,y);
put(car x,'op,list list(y,y)); % for RPRINT.
if z := get(car x,'unary) then put(z,'infix,y);
if and(z,null flagp(z,'nary)) then put(z,'op,list(nil,y));
x := cdr x;
y := add1 y;
go to a
end;
mkprec();
symbolic procedure newtok u;
begin scalar !*redeflg!*,x,y;
if atom u or atom car u or null idp caar u
then typerr(u,"NEWTOK argument");
% set up SWITCH* property.
put(caar u,'switch!*,
cdr newtok1(car u,cadr u,get(caar u,'switch!*)));
% set up PRTCH property.
y := intern compress consescc car u;
if !*redeflg!* then lprim list(y,"redefined");
put(cadr u,'prtch,y);
if x := get(cadr u,'unary) then put(x,'prtch,y)
end;
symbolic procedure newtok1(charlist,name,propy);
if null propy then lstchr(charlist,name)
else if null cdr charlist
then begin
if cdr propy and !*msg then !*redeflg!* := t;
return list(car charlist,car propy,name)
end
else car charlist . newtok2(cdr charlist,name,car propy)
. cdr propy;
symbolic procedure newtok2(charlist,name,assoclist);
if null assoclist then list lstchr(charlist,name)
else if car charlist eq caar assoclist
then newtok1(charlist,name,cdar assoclist) . cdr assoclist
else car assoclist . newtok2(charlist,name,cdr assoclist);
symbolic procedure consescc u;
if null u then nil else '!! . car u . consescc cdr u;
symbolic procedure lstchr(u,v);
if null cdr u then list(car u,nil,v)
else list(car u,list lstchr(cdr u,v));
newtok '((!$) !*semicol!*);
newtok '((!;) !*semicol!*);
newtok '((!+) plus);
newtok '((!-) difference);
newtok '((!*) times);
newtok '((!^) expt);
newtok '((!* !*) expt);
newtok '((!/) quotient);
newtok '((!=) equal);
newtok '((!,) !*comma!*);
newtok '((!() !*lpar!*);
newtok '((!)) !*rpar!*);
newtok '((!:) !*colon!*);
newtok '((!: !=) setq);
newtok '((!.) cons);
newtok '((!<) lessp);
newtok '((!< !=) leq);
newtok '((!< !<) !*lsqbkt!*);
newtok '((!>) greaterp);
newtok '((!> !=) geq);
newtok '((!> !>) !*rsqbkt!*);
put('expt,'prtch,'!*!*); % To ensure that FORTRAN output is correct.
flag('(difference minus plus setq),'spaced);
flag('(newtok),'eval);
endmodule;
end;