module entry; % Entry points for self-loading modules.
% Author: Anthony C. Hearn.
% Using a modified version of the defautoload function of Eric Benson
% and Martin L. Griss.
% Extended for algebraic operators and values by Herbert Melenk.
fluid '(varstack!*);
if getd 'create!-package then create!-package('(entry),'(build));
symbolic procedure safe!-putd(name,type,body);
% So that stubs will not clobber REAL entries preloaded.
if getd name then lprim list("Autoload stub for",name,"not defined")
else putd(name,type,body);
smacro procedure mkfunction u; list('function,u);
symbolic macro procedure defautoload u;
% (defautoload name), (defautoload name loadname),
% (defautoload name loadname fntype), or
% (defautoload name loadname fntype numargs)
% Default is 1 Arg EXPR in module of same name.
begin scalar name,numargs,loadname,fntype;
u := cdr u;
name := car u;
u := cdr u;
if u then <<loadname := car u; u :=cdr u>> else loadname := name;
if eqcar(name, 'quote) then name := cadr name;
if atom loadname then loadname := list loadname
else if car loadname eq 'quote then loadname := cadr loadname;
if u then <<fntype := car u; u := cdr u>> else fntype := 'expr;
if u then numargs := car u else numargs := 1;
u := if numargs=0 then nil
else if numargs=1 then '(x1)
else if numargs=2 then '(x1 x2)
else if numargs=3 then '(x1 x2 x3)
else if numargs=4 then '(x1 x2 x3 x4)
else error(99,list(numargs,"too large in DEFAUTOLOAD"));
name := mkquote name;
return
list('progn,
list('put,name,mkquote 'number!-of!-args,numargs),
list('safe!-putd,
name,
mkquote fntype,
mkfunction
list('lambda, u,
'progn .
aconc(for each j in loadname
collect
list('load!-package,mkquote j),
list('lispapply,name,'list . u)))))
end;
% Autoload support for algebraic operators and values.
%
% defautoload_operator(opname,package);
% defautoload_value(varname,package);
%
symbolic macro procedure defautoload_operator u;
begin scalar name,package;
name := cadr u; package := caddr u;
return subla(list('name.name,'package.package),
'(progn
(flag '(name) 'full)
(put 'name 'simpfn
'(lambda(x)(autoload_operator!* 'name 'package x)))))
end;
symbolic procedure autoload_operator!*(o,p,x);
begin scalar varstack!*;
remflag(list o,'full);
remprop(o,'simpfn);
if pairp p then for each pp in p do load!-package pp
else load!-package p;
return simp x;
end;
symbolic macro procedure defautoload_value u;
begin scalar name,package;
u:=cdr u; name := car u; u:=cdr u; package := car u;
return subla(list('name.name,'package.package),
'(progn
(put 'name 'avalue
'(autoload_value!* name package))))
end;
symbolic procedure autoload_value!*(u,v);
begin scalar name,p,x,varstack!*;
x:=get(u,'avalue);
name := cadr x; p := caddr x;
remprop(name,'avalue);
load!-package p;
return reval1(name,v);
end;
put('autoload_value!*,'evfn,'autoload_value!*);
comment Actual Entry Point Definitions;
% Compiler and LAP entry points.
defautoload(compile,compiler);
if 'csl memq lispsystem!* then defautoload(faslout,compiler)
else defautoload(lap,compiler);
% Cross-reference module entry points.
remd 'crefon; % don't use PSL version
put('cref,'simpfg,'((t (crefon)) (nil (crefoff))));
defautoload(crefon,rcref,expr,0);
% Input editor entry points.
defautoload cedit;
defautoload(display,cedit);
put('display,'stat,'rlis);
defautoload(editdef,cedit);
put('editdef,'stat,'rlis);
% Factorizer module entry points.
switch trfac, trallfac;
remprop('factor,'stat);
defautoload(ezgcdf,ezgcd,expr,2);
defautoload(factorize!-primitive!-polynomial,factor);
defautoload(pfactor,factor,expr,2);
defautoload(simpnprimitive,factor);
put('nprimitive,'simpfn,'simpnprimitive);
put('factor,'stat,'rlis);
% FASL module entry points.
flag('(faslout),'opfn);
flag('(faslout),'noval);
% High energy physics module entry points.
remprop('index,'stat); remprop('mass,'stat);
remprop('mshell,'stat); remprop('vecdim,'stat);
remprop('vector,'stat);
defautoload(index,hephys);
defautoload(mass,hephys);
defautoload(mshell,hephys);
defautoload(vecdim,hephys);
defautoload(vector,hephys);
put('index,'stat,'rlis);
put('mshell,'stat,'rlis);
put('mass,'stat,'rlis);
put('vecdim,'stat,'rlis);
put('vector,'stat,'rlis);
% Integrator module entry points.
fluid '(!*trint);
switch trint;
defautoload(simpint,int);
put('int,'simpfn,'simpint);
put('algint,'simpfg,'((t (load!-package 'algint))));
% Matrix module entry points.
switch cramer;
put('cramer,'simpfg,
'((t (put 'mat 'lnrsolvefn 'clnrsolve)
(put 'mat 'inversefn 'matinv))
(nil (put 'mat 'lnrsolvefn 'lnrsolve)
(put 'mat 'inversefn 'matinverse))));
defautoload(detq,'(matrix)); % Used by high energy physics package.
defautoload(matp,'(matrix));
defautoload(matrix,'(matrix));
put('matrix,'stat,'rlis);
flag('(mat),'struct);
put('mat,'formfn,'formmat);
defautoload(formmat,'(matrix),expr,3);
defautoload(generateident,'(matrix));
defautoload(lnrsolve,'(matrix),expr,2);
defautoload(simpresultant,'(matrix));
defautoload(resultant,'(matrix),expr,3);
put('resultant,'simpfn,'simpresultant);
defautoload(nullspace!-eval,matrix);
put('nullspace,'psopfn,'nullspace!-eval);
% Plot entry point.
put('plot,'psopfn,'(lambda(u) (load!-package 'gnuplot) (ploteval u)));
% Prettyprint module entry point (built into CSL).
if null('csl memq lispsystem!*) then defautoload(prettyprint,pretty);
% Print module entry point.
% defautoload(horner,scope);
% global '(!*horner);
% switch horner;
% Rprint module entry point.
defautoload rprint;
% SOLVE module entry points.
defautoload(solveeval,solve);
defautoload(solve0,solve,expr,2);
% defautoload(solvelnrsys,solve,expr,2); % Used by matrix routines.
% defautoload(!*sf2ex,solve,expr,2); % Used by matrix routines.
put('solve,'psopfn,'solveeval);
switch allbranch,arbvars,fullroots,multiplicities,nonlnr,solvesingular;
% varopt;
% Default values.
!*allbranch := t;
!*arbvars := t;
!*solvesingular := t;
put('arbint,'simpfn,'simpiden);
% Since the following three switches are set on in the solve module,
% they must first load that module if they are initially turned off.
put('nonlnr,'simpfg,'((nil (load!-package 'solve))));
put('allbranch,'simpfg,'((nil (load!-package 'solve))));
put('solvesingular,'simpfg,'((nil (load!-package 'solve))));
% Root finding package entry points.
defautoload roots;
defautoload(gfnewt,roots);
defautoload(gfroot,roots);
defautoload(root_val,roots);
defautoload(firstroot,roots);
defautoload(rlrootno,roots2);
defautoload(realroots,roots2);
defautoload(isolater,roots2);
defautoload(nearestroot,roots2);
defautoload(sturm0,roots2);
defautoload(multroot1,roots2);
for each n in '(roots rlrootno realroots isolater firstroot
nearestroot gfnewt gfroot root_val)
do put(n,'psopfn,n);
put('sturm,'psopfn,'sturm0);
switch trroot,rootmsg;
put('multroot,'psopfn,'multroot1);
switch fullprecision,compxroots;
% Limits entry points.
for each c in '(limit limit!+ limit!-) do
<<put(c,'simpfn,'simplimit);
put(c,'number!-of!-args,3);
flag({c},'full)>>;
defautoload(simplimit,limits);
% Partial fractions entry point.
defautoload(pf,pf,expr,2);
symbolic operator pf;
% Sum entry points.
defautoload(simp!-sum,sum);
defautoload(simp!-sum0,sum,expr,2);
put('sum,'simpfn,'simp!-sum);
defautoload(simp!-prod,sum);
put('prod,'simpfn,'simp!-prod);
switch zeilberg;
% Taylor entry points
put('taylor,'simpfn,'simptaylor);
defautoload(simptaylor,taylor);
% Trigsimp entry points
put('trigsimp,'psopfn,'trigsimp!*);
defautoload(trigsimp!*,trigsimp);
% Specfn entry points
defautoload_operator(besselj,(specfn specbess));
defautoload_operator(bessely,(specfn specbess));
defautoload_operator(besseli,(specfn specbess));
defautoload_operator(besselk,(specfn specbess));
defautoload_operator(hankel1,(specfn specbess));
defautoload_operator(gamma,(specfn sfgamma));
defautoload_operator(binomial,specfn);
% Debug module entry points.
% if not(systemname!* eq 'ibm) then defautoload(embfn,debug,expr,3);
% Specfn entry points.
defautoload_operator(lambert_w,(specfn specbess));
endmodule;
end;