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r37/packages/poly/gint.red
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module gint; % Support for gaussian integers (complex numbers). % Author: Eberhard Schruefer. global '(domainlist!*); fluid '(!*complex !*gcd); switch complex; domainlist!* := union('(!:gi!:),domainlist!*); symbolic procedure setcmpxmode(u,bool); % Sets polynomial domain mode in complex case. begin scalar x,y; x := get(u,'tag); if u eq 'complex then if null dmode!* then return if null bool then nil else <<put('i,'idvalfn,'mkdgi); setdmode1('complex,bool)>> else if null bool then return if null !*complex then nil else if get(dmode!*,'dname) eq 'complex then <<remprop('i,'idvalfn); setdmode1('complex,nil)>> else <<remprop('i,'idvalfn); setdmode1(get(get(dmode!*,'realtype),'dname), t)>> else if dmode!* eq '!:gi!: or get(dmode!*,'realtype) then return nil else if not (y := get(dmode!*,'cmpxtype)) then dmoderr(dmode!*,x) else <<put('i,'idvalfn,get(y,'ivalue)); return setdmode1(get(y,'dname),bool)>> else if null bool then if u eq (y := get(get(dmode!*,'realtype),'dname)) then <<put('i,'idvalfn,'mkdgi); return setdmode1('complex,t)>> else if null y then return nil else offmoderr(u,y) else <<u := get(u,'tag); y := get(u,'cmpxtype); if null y then dmoderr(u,'!:gi!:); put('i,'idvalfn,get(y,'ivalue)); return setdmode1(get(y,'dname),bool)>> end; % Used by gcdk. symbolic procedure intgcdd(u,v); if null u then v else if atom u then if atom v then gcdn(u,v) else gcdn(cadr v,gcdn(cddr v,u)) else if atom v then intgcdd(v,u) else intgcdd(cadr u,intgcdd(cddr u,v)); put('complex,'tag,'!:gi!:); put('!:gi!:,'dname,'complex); put('!:gi!:,'i2d,'!*i2gi); put('!:gi!:,'minusp,'giminusp!:); put('!:gi!:,'zerop,'gizerop!:); put('!:gi!:,'onep,'gionep!:); put('!:gi!:,'plus,'giplus!:); put('!:gi!:,'difference,'gidifference!:); put('!:gi!:,'times,'gitimes!:); put('!:gi!:,'quotient,'giquotient!:); put('!:gi!:,'divide,'gidivide!:); put('!:gi!:,'gcd,'gigcd!:); put('!:gi!:,'factorfn,'gifactor!:); % put('!:gi!:,'rationalizefn,'girationalize!:); put('!:gi!:,'prepfn,'giprep!:); put('!:gi!:,'intequivfn,'gintequiv!:); put('!:gi!:,'specprn,'giprn!:); put('!:gi!:,'prifn,'giprn!:); put('!:gi!:,'cmpxfn,'mkgi); put('!:gi!:,'unitsfn,'!:gi!:unitconv); symbolic procedure !:gi!:unitconv(u,v); unitconv(u,v,get('!:gi!:,'units)); put('!:gi!:,'units,'(((!:gi!: 0 . 1) . (!:gi!: 0 . -1)) ((!:gi!: 0 . -1) . (!:gi!: 0 . 1)))); symbolic procedure unitconv(u,v,w); begin scalar z; a: if null w then return u; z := quotf1(v,caar w); if null z or not fixp z then <<w := cdr w; go to a>>; z := multf(denr u,cdar w); w := multf(numr u,cdar w); if minusf z then <<w := negf w; z := negf z>>; return w ./ z end; symbolic procedure !*i2gi u; '!:gi!: . (u . 0); symbolic procedure giminusp!: u; %*** this is rather a test for u being in a canonical form! ***; if cadr u = 0 then minusp cddr u else minusp cadr u; symbolic procedure gizerop!: u; cadr u = 0 and cddr u = 0; symbolic procedure gionep!: u; cadr u=1 and cddr u=0; symbolic procedure gintequiv!: u; if cddr u=0 then cadr u else nil; symbolic procedure mkdgi u; ('!:gi!: . (0 . 1)) ./ 1; symbolic procedure mkgi(re,im); '!:gi!: . (re . im); symbolic procedure giplus!:(u,v); mkgi(cadr u+cadr v,cddr u+cddr v); symbolic procedure gidifference!:(u,v); mkgi(cadr u-cadr v,cddr u-cddr v); symbolic procedure gitimes!:(u,v); (lambda r1,i1,r2,i2; mkgi(r1*r2-i1*i2,r1*i2+r2*i1)) (cadr u,cddr u,cadr v,cddr v); symbolic procedure giquotient!:(u,v); begin integer r1,i1,r2,i2,d; scalar rr,ii; r1 := cadr u; i1 := cddr u; r2 := cadr v; i2 := cddr v; d := r2*r2+i2*i2; rr := divide(r1*r2+i1*i2,d); ii := divide(i1*r2-i2*r1,d); return if cdr ii=0 and cdr rr=0 then mkgi(car rr,car ii) else '!:gi!: . (0 . 0) end; symbolic procedure gidivide!:(u,v); begin integer r1,i1,r2,i2,d,rr,ir,rq,iq; r1 := cadr u; i1 := cddr u; r2 := cadr v; i2 := cddr v; d := r2*r2+i2*i2; rq := r1*r2+i1*i2; iq := i1*r2-i2*r1; rq := car divide(2*rq+if rq<0 then -d else d,2*d); iq := car divide(2*iq+if iq<0 then -d else d,2*d); rr := r1-(rq*r2-iq*i2); ir := i1-(iq*r2+rq*i2); return mkgi(rq,iq) . mkgi(rr,ir) end; symbolic procedure giremainder(u,v); begin integer r1,i1,r2,i2,d,rr,ir,rq,iq; r1 := cadr u; i1 := cddr u; r2 := cadr v; i2 := cddr v; d := r2*r2+i2*i2; rq := r1*r2+i1*i2; iq := i1*r2-i2*r1; rq := car divide(2*rq+if rq<0 then -d else d,2*d); iq := car divide(2*iq+if iq<0 then -d else d,2*d); rr := r1-(rq*r2-iq*i2); ir := i1-(iq*r2+rq*i2); return '!:gi!: . (rr . ir) end; symbolic procedure gigcd!:(u,v); % Straightforward Euclidean algorithm. if gizerop!: v then fqa u else gigcd!:(v,giremainder(u,v)); symbolic procedure fqa u; %calculates the unique first-quadrant associate of u; if cddr u=0 then abs cadr u else if cadr u=0 then '!:gi!: . (abs cddr u . 0) else if (cadr u*cddr u)>0 then '!:gi!: . (abs cadr u . abs cddr u) else '!:gi!: . (abs cddr u . abs cadr u); symbolic procedure gifactor!: u; % Trager's modified version of Van der Waerdens algorithm. begin scalar x,y,norm,aftrs,ftrs,mvu,dmode!*,!*exp,w,z,l,bool; integer s; !*exp := t; if realp u then u := cdr factorf u else u := list(u . 1); w := 1; for each f in u do begin u := car f; dmode!* := '!:gi!:; mvu := power!-sort powers u; bool := contains!-oddpower mvu; if realp u and bool then <<u := normalize!-lcgi u; w := multd(car u,w); aftrs := (cdr u . 1) . aftrs; return>>; mvu := caar mvu; y := u; go to b; a: l := list(mvu . prepf addf(!*k2f mvu,multd(s,!*k2f 'i))); u := numr subf1(y,l); b: if realp u then if bool then <<y := normalize!-lcgi y; w := multd(car y,w); aftrs := (cdr y . 1) . aftrs; return>> else <<s := s-1; go to a>>; norm := multf(u,conjgd u); if not sqfrp norm then <<s := s-1; go to a>>; dmode!* := nil; ftrs := factorf norm; dmode!* := '!:gi!:; if null cddr ftrs then <<y := normalize!-lcgi y; w := multd(car y,w); aftrs := (cdr y . 1) . aftrs; return>>; w := car ftrs; l := if s=0 then nil else list(mvu . prepf addf(!*k2f mvu, negf multd(s,!*k2f 'i))); for each j in cdr ftrs do <<x := gcdf!*(car j,u); u := quotf!*(u,x); z := if l then numr subf1(x,l) else x; z := normalize!-lcgi z; w := multd(car z,w); aftrs := (cdr z . 1) . aftrs>>; w := multf(u,w) end; return w . aftrs end; symbolic procedure normalize!-lcgi u; % Normalize lnc by using units as canonsq would do it. begin scalar l,x,y; l := lnc u; if numberp l then return if minusp l then (-1) . negf u else 1 . u; x := get('!:gi!:,'units); a: if null x then return 1 . u; y := quotf1(l,caar x); if null y or null fixp y then <<x := cdr x; go to a>>; u := multd(cdar x,u); return if minusf u then negf caar x . negf u else caar x . u end; symbolic procedure contains!-oddpower u; if null u then nil else if evenp cdar u then contains!-oddpower cdr u else t; symbolic procedure power!-sort u; begin scalar x,y; while u do <<x := maxdeg(cdr u,car u); u := delallasc(car x,u); y := x . y>>; return y end; symbolic procedure sqfrp u; % Squarefree test for poly u over the integers. It gives the user % control over which gcd to use, i.e. 'on ezgcd' has an effect. % Still needs changes to gcd and facform modules before to work. begin scalar dmode!*; return domainp gcdf!*(u,diff(u,mvar u)) end; symbolic procedure realp u; if domainp u then atom u or not get(car u,'cmpxfn) or cddr u = cddr apply1(get(car u,'i2d),1) else realp lc u and realp red u; symbolic procedure fd2f u; if atom u then u else if car u eq '!:gi!: then addf(!*n2f cadr u,multf(!*k2f 'i,!*n2f cddr u)) else addf(multf(!*p2f lpow u,fd2f lc u),fd2f red u); % symbolic procedure giprep!: u; %giprep1 cdr u; % prepsq!* addsq(!*n2f cadr u ./ 1, % multsq(!*n2f cddr u ./ 1, !*k2q 'i)); % symbolic procedure giprep1 u; %not used now; % if cdr u=0 then car u % else if car u=0 then retimes list(cdr u,'i) % else begin scalar gn; % gn := gcdn(car u,cdr u); % return retimes list(gn, % replus list(car u/gn,retimes list(cdr u/gn,'i))) % end; symbolic procedure giprep!: u; <<if im=0 then rl else if rl=0 then giprim im else if im<0 then list('difference,rl,giprim(minus im)) else list('plus,rl,giprim im)>> where rl=cadr u,im=cddr u; symbolic procedure giprim im; if im=1 then 'i else list('times,im,'i); symbolic procedure giprn!: v; (lambda u; if atom u or (car u eq 'times) then maprin u else <<prin2!* "("; maprin u; prin2!* ")" >>) giprep!: v; % symbolic procedure girationalize!: u; % %Rationalizes standard quotient u over the gaussian integers. % begin scalar x,y,z; % y := denr u; % z := conjgd y; % if y=z then return u; % x := multf(numr u,z); % y := multf(y,z); % return x ./ y % end; symbolic procedure girationalize!: u; % Rationalizes standard quotient u over the gaussian integers. begin scalar y,z,!*gcd; !*gcd := t; if y=(z := conjgd(y := denr u)) then return u; % Remove from z any real polynomial factors of y and z. z := quotf(z,quotf( gcdf(addf(y,z),multf(addf(z,negf y),'!:gi!: . (0 . 1))),2)); % The following subs2 can undo the above if !*match is non-NIL. % return subs2 gigcdsq(multf(numr u,z),multf(y,z)) return gigcdsq(multf(numr u,z),multf(y,z)) end; symbolic procedure gigcdsq(x,y); % remove integer common factor. <<if x then (<<if d neq 1 and (d := giintgcd(x,d)) neq 1 then <<x := quotf(x,d); y := quotf(y,d)>> >> where d=giintgcd(y,0)); x ./ y >>; symbolic procedure giintgcd(u,d); if d=1 then 1 else if null u then d else if atom u then gcdn(u,d) else if eqcar(u,'!:gi!:) then gcdn(cadr u,gcdn(cddr u,d)) else giintgcd(lc u,giintgcd(red u,d)); symbolic procedure conjgd u; begin scalar x; return if atom u then u else if domainp u and (x := get(car u,'cmpxfn)) then apply2(x,cadr u, if numberp cddr u then -cddr u % Allow for tagged parts of complex object. else if domainp cddr u and not numberp caddr u then !:minus cddr u else cdr !:minus (get(car u,'realtype).cddr u)) else if domainp u then u % Should be a real number now. else addf(multpf(lpow u,conjgd lc u),conjgd red u) end; initdmode 'complex; endmodule; end;