module polyop; % Functions for algebraic mode operations on polynomials.
% Author: Anthony C. Hearn.
% Modified by: F. Kako, F.J. Wright.
% Copyright (c) 1995 RAND. All rights reserved.
% This code has been modified to be consistent with the rules
% lterm(f,x) = lcof(f,x)*lpower(f,x)
% f = lterm(f,x) + reduct(f,x)
fluid '(!*ratarg gdmode!*);
symbolic procedure deg(u,kern);
<<u := simp!* u; tstpolyarg(denr u,u); numrdeg(numr u,kern)>>
where dmode!* = gdmode!*;
symbolic procedure numrdeg(u,kern);
begin scalar x;
kern := !*a2k kern;
if domainp u then return 0
else if mvar u eq kern then return !*f2a ldeg u;
x := updkorder kern;
u := reorder u;
if not(mvar u eq kern) then u := 0 else u := ldeg u;
setkorder x;
% return !*f2a u
return u
end;
symbolic procedure lcofeval u;
begin scalar kern,x,y;
if null u or null cdr u or not null cddr u
then rerror(poly,280,
"LCOF called with wrong number of arguments");
kern := !*a2k cadr u;
u := simp!* car u;
y := denr u;
tstpolyarg(y,u);
u := numr u;
if domainp u then return if null u then 0 else mk!*sq (u . 1)
else if mvar u eq kern then return !*ff2a(lc u,y);
x := updkorder kern;
u := reorder u;
if mvar u eq kern then u := lc u;
setkorder x;
return if null u then 0 else !*ff2a(u,y)
end;
put('lcof,'psopfn,'lcofeval);
% Note. This is an older definition still used by some packages.
symbolic procedure lcof(u,kern);
begin scalar x,y;
u := simp!* u;
y := denr u;
tstpolyarg(y,u);
u := numr u;
kern := !*a2k kern;
if domainp u then return 0
else if mvar u eq kern then return !*ff2a(lc u,y);
x := updkorder kern;
u := reorder u;
if mvar u eq kern then u := lc u;
setkorder x;
return if null u then 0 else !*ff2a(u,y)
end;
symbolic procedure lpower(u,kern);
begin scalar x,y;
u := simp!* u;
y := denr u;
tstpolyarg(y,u);
u := numr u;
kern := !*a2k kern;
if domainp u then return 1
else if mvar u eq kern then return !*ff2a(lpow u.*1 .+ nil,y);
x := updkorder kern;
u := reorder u;
if mvar u eq kern then u := lpow u.*1 .+ nil else u := 1;
setkorder x;
return !*ff2a(u,y)
end;
symbolic procedure lterm(u,kern);
begin scalar x,y;
u := simp!* u;
y := denr u;
tstpolyarg(y,u);
u := numr u;
kern := !*a2k kern;
if domainp u then return if null u then 0 else u
else if mvar u eq kern then return !*ff2a(lt u .+ nil,y);
x := updkorder kern;
u := reorder u;
% if mvar u eq kern then u := lt u .+ nil else u := nil;
if mvar u eq kern then u := lt u .+ nil;
setkorder x;
u := reorder u;
return !*ff2a(u,y)
end;
% symbolic procedure !*lterm u; lt u .+ nil;
symbolic procedure mainvar u;
if domainp(u := numr simp!* u) then 0
else sfchk(u := mvar u);
symbolic procedure sfchk u; if sfp u then prepf u else u;
symbolic procedure reduct(u,kern);
begin scalar x,y;
u := simp!* u;
y := denr u;
tstpolyarg(y,u);
u := numr u;
kern := !*a2k kern;
% if domainp u then return !*ff2a(u,y)
if domainp u then return 0
else if mvar u eq kern then return !*ff2a(cdr u,y);
x := updkorder kern;
u := reorder u;
% if mvar u eq kern then u := cdr u;
if mvar u eq kern then u := cdr u else u := nil;
setkorder x;
u := reorder u;
return !*ff2a(u,y)
end;
symbolic procedure tstpolyarg(y,u);
null !*ratarg and y neq 1 and typerr(prepsq u,"polynomial");
% symbolic operator deg,lpower,lterm,mainvar,reduct;
flag('(deg lpower lterm mainvar reduct),'opfn); % This way for booting.
endmodule;
end;