Updating configure.ac with new version number

[maxima/cygwin.git] / demo / manual.demo

 /* 
   This file is to be run by the EXAMPLE command, and may not 
   otherwise work.
   The following are either acceptable lines to Maxima, or they are
   two successive '&' characters 
   and then followed by the name of the section of examples, and then followed by
   a sequence of Maxima forms, e.g.
   
   '&'& topic               (without the quotes)
   
      /* This is a comment */
      <Maxima form 1>;
      <Maxima form 2>;
      ...
*/

&& additive
   
   declare(f,additive);
   f(2*a+3*b);

&& algsys

   f1:2*x*(1-l1)-2*(x-1)*l2$
   f2:l2-l1$
   f3:l1*(1-x**2-y)$
   f4:l2*(y-(x-1)**2)$
   algsys([f1,f2,f3,f4],[x,y,l1,l2]);
   f1:x**2-y**2$
   f2:x**2-x+2*y**2-y-1$
   algsys([f1,f2],[x,y]);

&& allroots

   (2*x+1)^3=13.5*(x^5+1);
   allroots(%);
   
&& antisymmetric
 
   declare(h,antisymmetric);
   h(x,z,y);

&& append

   append([y+x,0,-3.2],[2.5e20,x]);
   
&& arrayinfo

   b[1,x]:1$
   array(f,2,3);
   arrayinfo(b);
   arrayinfo(f);

&& arrays
  
   a[n]:=n*a[n-1];
   a[0]:1$
   a[5];
   a[n]:=n$
   a[6];
   a[4];

&& at 

   atvalue(f(x,y),[x=0,y=1],a^2);
   atvalue('diff(f(x,y),x),x=0,y+1);
   printprops(all,atvalue);
   diff(4*f(x,y)^2-u(x,y)^2,x);
   at(%,[x=0,y=1]);

&& atvalue
      
   kill(f,x,a,u,g);
   atvalue(f(x,y),[x=0,y=1],a^2)$
   atvalue('diff(f(x,y),x),x=0,y+1);
   printprops(all,atvalue);
   diff(4*f(x,y)^2-u(x,y)^2,x);
   at(%,[x=0,y=1]);

&& augcoefmatrix  
   
   [2*x-(a-1)*y=5*b,a*x+b*y+c=0]$
   augcoefmatrix(%,[x,y]);

&& bezout

   bezout(a*y+x^2+1,y^2+x*y+b,x);
   expand(determinant(%));
   %-expand(resultant(a*y+x^2+1,y^2+x*y+b,x));
   
&& block

   kill(f);
   hessian(f):=block([dfxx,dfxy,dfxz,dfyy,dfyz,dfzz],
         dfxx:diff(f,x,2),dfxy:diff(f,x,1,y,1),
         dfxz:diff(f,x,1,z,1),dfyy:diff(f,y,2),
         dfyz:diff(f,y,1,z,1),dfzz:diff(f,z,2),
         determinant(matrix([dfxx,dfxy,dfxz],[dfxy,dfyy,dfyz],
                 [dfxz,dfyz,dfzz])))$
   kill(x,y,z);
   hessian(x^3-3*a*x*y*z+y^3);
   subst(1,z,quotient(%,-54*a^2));
   f(x):=block([y,use_fast_arrays:false], local(a), y:4, a[y]:x, display(a[y]))$
   y:2$
   a[y+2]:0$
   f(9);
   ff(x):=block([y,a,use_fast_arrays:true], y:4, a[y]:x, display(a[y]))$
   ff(10);
   a[y+2];

&& bothcoeff  
   
   islinear(exp,var):=block([c],
               c:bothcoef(rat(exp,var),var),
               is(freeof(var,c) and c[1]#0))$
   islinear((r^2-(x-r)^2)/x,x);
   
&& catch
   
   g(l):=catch(map(lambda([x],if x<0 then throw(x) else f(x)),l))$
   g([1,2,3,7]);
   g([1,2,-3,7]);

&& cf
  
   cf([1,2,-3]+[1,-2,1]);
   cfdisrep(%);
   cflength:4$
   cf(sqrt(3));
   cfexpand(%);
   ev(%[1,2]/%[2,2],numer);

&& cfdisrep  
      
   cf([1,2,-3]+[1,-2,1]);
   cfdisrep(%);

&& cfexpand
  
   cflength:4$
   cf(sqrt(3));
   cfexpand(%);
   ev(%[1,2]/%[2,2],numer);

&& changevar  
   
   'integrate(%e^(sqrt(a)*sqrt(y)),y,0,4);
   changevar(%,y-z^2/a,z,y);

   sum(a[k]*x^(N-1-k), k, 0, N - 1);
   changevar(%, m = N - 1 - k, m, k);
&& charpoly  

   a:matrix([3,1],[2,4]);
   expand(charpoly(a,lambda));
   (programmode:true,solve(%));
   matrix([x1],[x2]);
   ev(a.%-lambda*%,%th(2)[1]);
   %[1,1]=0;
   x1^2+x2^2=1;
   solve([%th(2),%],[x1,x2]);

&& coeff
   
   coeff(2*a*tan(x)+tan(x)+b=5*tan(x)+3,tan(x));
   coeff(y+x*%e^x+1,x,0);

&& combine
   
   combine(a/x+b/x+a/y+b/y);
   
&& commutative 
   
   declare(h,commutative);
   h(x,z,y);

&& complex  
   
   (sqrt(-4)+sqrt(2.25))^2;
   expand(%);
   expand(sqrt(2*%i));
   
&& content  
   
   content(2*x*y+4*x^2*y^2,y);

&& defmatch  
   
   nonzeroandfreeof(x,e):=is(e#0 and freeof(x,e));
   matchdeclare(a,nonzeroandfreeof(x),b,freeof(x));
   defmatch(linear,a*x+b,x);
   linear(3*z+(y+1)*z+y**2,z);
   matchdeclare([a,f],true);
   constinterval(l,h):=constantp(h-l)$
   matchdeclare(b,constinterval(a))$
   matchdeclare(x,atom)$
   block(remove(integrate,outative),
         defmatch(checklimits,'integrate(f,x,a,b)),
         declare(integrate,outative))$
   'integrate(sin(t),t,x+%pi,x+2*%pi)$
   checklimits(%);
   'integrate(sin(t),t,0,x)$
   checklimits(%);
   remvalue(a,b,f,x)$
   
&& deftaylor
  
   deftaylor(f(x),x^2+sum(x^i/(2^i*i!^2),i,4,inf));
   taylor(%e^sqrt(f(x)),x,0,4);

&& delete  
   
   delete(sin(x),x+sin(x)+y);

&& depends
  
   kill(a,x,f,y,t);
   depends(a,x);
   diff(a.a,x);
   depends(f,[x,y],[x,y],t);
   diff(f,t);

&& derivdegree  
   
   'diff(y,x,2)+'diff(y,z,3)*2+'diff(y,x)*x^2;
   derivdegree(%,y,x);

&& desolve  
   
   eqn1:'diff(f(x),x)='diff(g(x),x)+sin(x);
   eqn2:'diff(g(x),x,2)='diff(f(x),x)-cos(x);
   atvalue('diff(g(x),x),x=0,a);
   atvalue(f(x),x=0,1);
   desolve([eqn1,eqn2],[f(x),g(x)]);
   /* verification */
   [eqn1,eqn2],%,diff;

&& diff
  
   kill(f,g,h,x,y);
   diff(sin(x)+x^3+2*x^2,x);
   diff(sin(x)*cos(x),x);
   diff(sin(x)*cos(x),x,2);
   derivabbrev:true$
   diff(exp(f(x)),x,2);
   'integrate(f(x,y),y,g(x),h(x));
   diff(%,x);

&& display  
   
   display(b[1,2]);

&& divide  

   divide(x+y,x-y,x);
   divide(x+y,x-y);
   
&& do
  
   for a:-3 thru 26 step 7 do ldisplay(a)$
   s:0$
   for i:1 while i<=10 do s:s+i;
   s;
   series:1$
   term:exp(sin(x))$
   for p:1 unless p>7 do
             (term:diff(term,x)/p,
             series:series+subst(x=0,term)*x^p)$
   series;
   poly:0$
   for i:1 thru 5 do
           for j:i step -1 thru 1 do
              poly:poly+i*x^j$
   poly;
   guess:-3.0$
   for i thru 10 do (guess:subst(guess,x,0.5*(x+10/x)),
            if abs(guess^2-10)<0.00005 then return(guess));
   for count:2 next 3*count thru 20
            do ldisplay(count)$
   x:1000;
   thru 10 while x#0 do x:0.5*(x+5/x)$
   x;
   remvalue(x);
   newton(f,guess):=block([numer,y],local(f,df,x,guess),
         numer:true,
           define(df(x),diff(f(x),x)),
        do (y:df(guess), if y=0 then error(
             "derivative at",guess,"is zero"),
            guess:guess-f(guess)/y,
            if abs(f(guess))<5.0e-6 then return(guess)))$
   sqr(x):=x^2-5.0$
   newton(sqr,1000);
   for f in [log, rho, atan] do ldisp(f(1.0))$
   ev(concat(e,linenum-1),numer);
   
&& dotscrules  

   declare(l,scalar,[m1,m2,m3],nonscalar);
   expand((1-l*m1).(1-l*m2).(1-l*m3));
   %,dotscrules;
   rat(%,l);

&& dpart

   dpart(x+y/z^2,1,2,1);
   expand((b+a)^4);
   (b+a)^2*(y+x)^2;
   expand(%);
   %th(3)/%;
   factor(%);
   dpart(%th(2),2,4);
   part(%th(3),2,4);
   
&& echelon  
   
   matrix([2,1-a,-5*b],[a,b,c]);
   echelon(%);

&& eliminate  
   
   exp1:2*x^2+y*x+z;
   exp2:3*x+5*y-z-1;
   exp3:z^2+x-y^2+5;
   eliminate([exp3,exp2,exp1],[y,z]);

&& entermatrix  
   
   entermatrix(2,1);
   
&& equations  
   
   x+1=y^2;
   x-1=2*y+1$
   %th(2)+%;
   %th(3)/y;
   1/%;

&& ev

   kill(y,x,w);
   sin(x)+cos(y)+(w+1)^2+'diff(sin(w),w);
   ev(%,sin,expand,diff,x=2,y=1);
   ev(x+y,x:a+y,y:2);
   'diff(y^2+x*y+x^2,x,2,y,1);
    
   ev(%,diff);
   2*x-3*y=3$
   -3*x+2*y=-4$
   solve([%th(2),%]);
   ev(%th(3),%);
   x+1/x>gamma(1/2);
   ev(%,numer,x=1/2);
   ev(%,pred);
   
&& evaluation  

   diff(x*f(x),x);
   f(x):=sin(x)$
   ev(%th(2),diff);
   x;
   x:3$
   x;
   'x;
   f(x):=x^2;
   'f(2);
   ev(%,f);
   '(f(2));
   ''%;
   sum(i!,i,1,4);
   'sum(i!,i,1,4);
   remvalue(x);
   'integrate(f(x),x,a,b);
   for i thru 5 do s:s+i^2;
   s;
   ev(%,s:0);
   ev(%th(2));
   'sum(g(i),i,0,n);
   z*%e^z;
   ev(%,z:x^2);
   subst(x^2,z,%th(3));
   a:%;
   a+1;
   kill(a,y);
   a;
   /* declare(integrate,noun)$ */
   integrate(y^2,y);
   ''integrate(y^2,y);
   f(y):=diff(y*log(y),y,2);
   f(y):=''(diff(y*log(y),y,2));
   ''(concat(c,linenum-1));
   (x+y)^3$
   diff(%,x);
   y:x^2+1$
   ''(concat(c,linenum-2));

&& evenfun
 
   declare(g,evenfun);
   g(-x);

&& exp
  
   ev(%e^x*sin(x)^2,exponentialize);
   kill(x);
   integrate(%,x);
   ev(%,demoivre);
   ans:ev(%,ratexpand);
   ev(%,x:1,numer)-ev(%,x:0,numer);
   integrate(%e^x*sin(x)^2,x);
   trigreduce(%);
   %-ans;
   ev(sin(x),%emode);

&& expand  
   
   (1/(x+y)^4-3/(y+z)^3)^2;
   expand(%,2,0);
   expand(a.(b+c.(d+e)+f));
   expand((x+1)^3);
   (x+1)^7;
   expand(%);
   expand(%th(2),7,7);
   ev(a*(b+c)+a*(b+c)^2,expop:1);

&& factcomb

   (n+1)^2*n!^2;
   factcomb(%);

&& factor
  
   factor(2^63-1);
   factor(z^2*(x+2*y)-4*x-8*y);
   x^2*y^2+2*x*y^2+y^2-x^2-2*x-1;
   block([dontfactor:[x]],factor(%/36/(y^2+2*y+1)));
   factor(%e^(3*x)+1);
   factor(x^4+1,a^2-2);
   factor(x^3+x^2*y^2-x*z^2-y^2*z^2);
   (x+2)/(x+3)/(x+b)/(x+c)^2;
   ratsimp(%);
   partfrac(%,x);
   map('factor,%);
   ratsimp((x^5-1)/(x-1));
   subst(a,x,%);
   factor(%th(2),%);
   factor(x^12+1);
   factor(x^99+1);
   
&& factorsum  
   
   ev((x+1)*((u+v)^2+a*(w+z)^2),expand);
   factorsum(%);

&& featurep 

   declare(j,even)$
   featurep(j,integer);

&& freeof
  
   freeof(y,sin(x+2*y));
   freeof(cos(y),"*",sin(y)+cos(x));

&& fullmap  
   
   fullmap(g,a+b*c);
   map(g,a+b*c);

&& fullmapl
  
   fullmapl("+",[3,[4,5]],[[a,1],[0,-1.5]]);

&& funcsolve
   
   funcsolve((n+1)*f(n)-(n+3)*f(n+1)/(n+1)=(n-1)/(n+2),f(n));

&& functions
   
   kill(x,y,f,g,h);
   f(x):=x^2+y;
   f(2);
   ev(f(2),y:7);
   f(x):=sin(x)^2+1;
   f(x+1);
   g(y,z):=f(z)+3*y;
   ev(g(2*y+z,-0.5),y:7);
   h(n):=sum(i*x^i,i,0,n);
   functions;
   t[n](x):=ratexpand(2*x*t[n-1](x)-t[n-2](x));
   t[0](x):=1$
   t[1](x):=x$
   t[4](y);
   g[n](x):=sum(ev(x),i,n,n+2);
   h(n,x):=sum(ev(x),i,n,n+2);
   g[2](i^2);
   h(2,i^2);
   p[n](x):=ratsimp(1/(2^n*n!)*diff((x^2-1)^n,x,n));
   q(n,x):=ratsimp(1/(2^n*n!)*diff((x^2-1)^n,x,n));
   p[2];
   p[2](y+1);
   q(2,y);
   p[2](5);
   f[i,j](x,y):=x^i+y^j;
   g(fun,a,b):=print(fun," applied to ",a," and ",b," is ",fun(a,b))$
   g(f[2,1],sin(%pi),2*c);

&& genmatrix
  
   h[i,j]:=1/(i+j-1)$
   genmatrix(h,3,3);

&& get
  
   put(%e,transcendental,type);
   put(%pi,transcendental,type)$
   put(%i,algebraic,type)$
   typeof(x):=block([q], if numberp(x)
               then return(algebraic),
               if not atom(x)
               then return(maplist(typeof,x)),
               q:get(x,type), if q=false then
               error("not numeric") else q)$
   errcatch(typeof(2*%e+x*%pi));
   typeof(2*%e+%pi);

&& gfactor  
   
   gfactor(x^4-1);

&& gradef
  
   depends(y,x);
   kill(f,g,j);
   gradef(f(x,y),x^2,g(x,y));
   diff(f(x,y),x);
   gradef(j(n,z),'diff(j(n,z),n),
        j(n-1,z)-n/z*j(n,z))$
   ratsimp(diff(j(2,x),x,2));
   
&& horner  
   
   poly:1.0e-20*x^2-5.5*x+5.2e20;
   errcatch(ev(%,x=1.0e20));
   horner(poly,x),keepfloat;
   ev(%,x=1.0e20);
   
&& if
  
   fib[n]:=if n=1 or n=2 then 1 else fib[n-1]+fib[n-2];
   fib[1]+fib[2];
   fib[3];
   fib[5];
   eta(mu,nu):=if mu=nu then mu else if mu>nu then mu-nu else mu+nu;
   eta(5,6);
   eta(eta(7,7),eta(1,2));
   if not 5>=2 and 6<=5 or 4+1>3 then a else b;
   
&& ilt  
   
   'integrate(sinh(a*x)*f(t-x),x,0,t)+b*f(t)=t^2;
   laplace(%,t,s);
   linsolve([%],['laplace(f(t),t,s)]);
   ilt(ev(%[1]),s,t);

&& inpart  
   
   x+y+w*z;
   inpart(%,3,2);
   'limit(f(x)^g(x+1),x,0,minus);
   inpart(%,1,2);

&& integrate
   
   test(f):=block([u],u:integrate(f,x),ratsimp(f-diff(u,x)));
   test(sin(x));
   test(1/(1+x));
   test(1/(1+x^2));
   integrate(sin(x)^3,x);
   kill(q)$
   integrate(%e^x/(%e^x+2),x);
   integrate(1/(x*log(x)),x);
   integrate(sin(2*x+3),x);
   integrate(%e^x*erf(x),x);
   integrate(x/(x^3+1),x);
   diff(%,x);
   ratsimp(%);
   integrate(x^(5/4)/(x+1)^(5/2),x,0,inf);
   gradef(q(x),sin(x^2));
   diff(log(q(r(x))),x);
   integrate(%,x);

&& is  
   
   is(x^2>=2*x-1);
   assume(a>1);
   is(log(log(a+1)+1)>0 and a^2+1>2*a);
   
&& isolate  
   
   (a+b)^4*(1+x*(2*x+(c+d)^2));
   isolate(%,x);
   ratexpand(%)$
   ev(%);
   (a+b)*(x+a+b)^2*%e^(x^2+a*x+b);
   isolate(%,x),exptisolate:true;
  
&& lambda
  
   lambda([x,y,z],x^2+y^2+z^2);
   %(1,2,a);
   "+"(1,2,a);
   
&& laplace
  
   laplace(%e^(2*t+a)*sin(t)*t,t,s);

&& lassociative 
   
   declare(g,lassociative);
   g(g(a,b),g(c,d));
   g(g(a,b),g(c,d))-g(a,g(b,g(c,d)));

&& let  
   
   matchdeclare([a,a1,a2],true);
   oneless(x,y):=is(x=y-1)$
   let(a1*a2!,a1!,oneless,a2,a1);
   let(a1!/a1,(a1-1)!),letrat;
   letsimp(n*m!*(n-1)!/m),letrat;
   let(sin(a)^2,1-cos(a)^2);
   sin(x)^4;
   letsimp(%);
   
&& letrules  
   
   matchdeclare([a,a1,a2],true);
   oneless(x,y):=is(x=y-1)$
   let(a1*a2!,a1!,oneless,a2,a1);
   let(a1!/a1,(a1-1)!),letrat;
   letsimp(n*m!*(n-1)!/m),letrat;
   let(sin(a)^2,1-cos(a)^2);
   sin(x)^4;
   letsimp(%);

&& limit  
   
   limit(x*log(x),x,0,plus);
   limit((1+x)^(1/x),x,0);
   limit(%e^x/x,x,inf);
   limit(sin(1/x),x,0);
   
&& linear 

   declare(f,linear);
   f(2*a+3*b);
   f(2*x+y,x);
   
&& linsolve  
   
   x+z=y$
   2*a*x-y=2*a^2$
   y-2*z=2$
   linsolve([%th(3),%th(2),%],[x,y,z]),globalsolve;

&& listofvars  
   
   listofvars(f(x[1]+y)/g^(2+a));

&& lists  
   
   [x^2,y/3,-2];
   %[1]*x;
   [a,%th(2),%];
   
&& logcontract  
   
   2*(a*log(x) + 2*a*log(y));
   logcontract(%);
   logcontract(log(sqrt(x+1)+sqrt(x)) + log(sqrt(x+1)-sqrt(x)));

&& map  
   
   map(f,x+a*y+b*z);
   map(lambda([u],partfrac(u,x)),x+1/(x^3+4*x^2+5*x+2));
   map(ratsimp, x/(x^2+x)+(y^2+y)/y);
   map("=",[a,b],[-0.5,3]);

&& matchdeclare  
   
   matchdeclare(a,true)$
   tellsimp(sin(a)^2,1-cos(a)^2)$
   sin(y)^2;
   kill(rules);
   nonzeroandfreeof(x,e):=is(e#0 and freeof(x,e));
   matchdeclare(a,nonzeroandfreeof(x),b,freeof(x));
   defmatch(linear,a*x+b,x);
   linear(3*z+(y+1)*z+y**2,z);
   matchdeclare([a,f],true);
   constinterval(l,h):=constantp(h-l)$
   matchdeclare(b,constinterval(a))$
   matchdeclare(x,atom)$
   block(remove(integrate,outative),
         defmatch(checklimits,'integrate(f,x,a,b)),
         declare(integrate,outative))$
   'integrate(sin(t),t,x+%pi,x+2*%pi)$
   checklimits(%);
   'integrate(sin(t),t,0,x)$
   checklimits(%);
   
&& matrices  

   m:matrix([a,0],[b,1]);
   m^2;
   m.m;
   m[1,1]*m;
   %-%th(2)+1;
   m^^-1;
   [x,y].m;
   matrix([a,b,c],[d,e,f],[g,h,i]);
   %^^2;
   
&& minfactorial  

   n!/(n+1)!;
   minfactorial(%);
   
&& multiplicative 

   declare(f,multiplicative);
   f(2*a*b);
   
&& multthru  

   x/(x-y)^2-1/(x-y)-f(x)/(x-y)^3;
   multthru((x-y)^3,%);
   ratexpand(%);
   ((a+b)^10*s^2+2*a*b*s+(a*b)^2)/(a*b*s^2);
   multthru(%);
   multthru(a.(b+c.(d+e)+f));
   
&& nary 

   declare(j,nary);
   j(j(a,b),j(c,d));
   
&& nounify  
   'limit(f(x)^g(x+1),x,0,minus);
   is(inpart(%,0)=nounify(limit));
   
&& nroots  

   x^10-2*x^4+1/2;
   nroots(%,-6,9.1);
   
&& numfactor  

   gamma(7/2);
   numfactor(%);
   
&& nusum  

   nusum(n*n!,n,0,n);
   nusum(n^4*4^n/binomial(2*n,n),n,0,n);
   unsum(%,n);
   unsum(prod(i^2,i,1,n),n);
   nusum(%,n,1,n);
   
&& oddfun 

   declare(f,oddfun);
   f(-x);
   
&& ode2  

   x^2*'diff(y,x) + 3*x*y = sin(x)/x;
   soln1:ode2(%,y,x);
   ic1(soln1,x=%pi,y=0);
   'diff(y,x,2) + y*'diff(y,x)^3 = 0;
   soln2:ode2(%,y,x);
   ratsimp(ic2(soln2,x=0,y=0,'diff(y,x)=2));
   bc2(soln2,x=0,y=1,x=1,y=3);
   
&& optimize  

   diff(exp(x^2+y)/(x+y),x,2);
   optimize(%);
   
&& ordergreat  
   
   a^2+b*x;
   ordergreat(a);
   a^2+b*x;
   %-%th(3);
   unorder();
   
&& orderless  

   y^2+b*x;
   orderless(y);
   y^2+b*x;
   %-%th(3);
   unorder();
   
&& outative 

   declare(f,outative);
   f(2*a);
   
&& part  

   x+y/z^2;
   part(%,1,2,2);
   remvalue(x);
   'integrate(f(x),x,a,b)+x;
   part(%,1,1);
   x^2+2*x=y^2;
   %+1;
   lhs(%);
   part(%th(2),2);
   part(%,1);
   27*y^3+54*x*y^2+36*x^2*y+y+8*x^3+x+1;
   part(%,2,[1,3]);
   sqrt(piece/54);
   
&& partfrac  

   2/(x+2)-2/(x+1)+1/(x+1)^2;
   ratsimp(%);
   partfrac(%,x);
   
&& partition  

   partition(2*a*x*f(x),x);
   partition(a+b,x);
   
&& pickapart  

   integrate(1/(x^3+2),x)$
   pickapart(%,1);
   
&& poissimp  

   pfeformat:true$
   poissimp(sin(x)^2);
   (2*a^2-b)*cos(x+2*y)-(a*b+5)*sin(u-4*x);
   poisexpt(%,2)$
   printpois(%);
   poisint(%th(2),y)$
   poissimp(%);
   poissimp(sin(x)^5+cos(x)^5);
   pfeformat:false$
   
&& polarform  

   rectform(sin(2*%i+x));
   polarform(%);
   rectform(log(3+4*%i));
   polarform(%);
   rectform((2+3.5*%i)^0.25),numer;
   polarform(%);
   
&& poly_discriminant  

   factor(poly_discriminant((x-a)*(x-b)*(x-c),x));
   
&& posfun 

   declare(f,posfun);
   is(f(x)>0);
   
&& powerseries  

   powerseries(log(sin(x)/x),x,0);
   
&& printprops 

   gradef(r,x,x/r)$
   gradef(r,y,y/r)$
   printprops(r,atomgrad);
   propvars(atomgrad);
   
&& product  

   product(x+i*(i+1)/2,i,1,4);

&& properties 

   properties(cons);
   assume(var1>0);
   properties(var1);
   var2:2$
   properties(var2);
   
&& propvars 

   gradef(r,x,x/r)$
   gradef(r,y,y/r)$
   printprops(r,atomgrad);
   propvars(atomgrad);
   
&& qunit  

   qunit(17);
   expand(%*(sqrt(17)-4));
   
&& radcan  

   (log(x^2+x)-log(x))^a/log(x+1)^(a/2);
   radcan(%);
   log(a^(2*x)+2*a^x+1)/log(a^x+1);
   radcan(%);
   (%e^x-1)/(%e^(x/2)+1);
   radcan(%);
   
&& rank  

   matrix([2,1-a,-5*b],[a,b,c]);
   rank(%);
   
&& rassociative 

   declare(g,rassociative);
   g(g(a,b),g(c,d));
   g(g(a,b),g(c,d))-g(a,g(b,g(c,d)));
   
&& rat  

   rat(x^2);
   diff(f(%),x);
   ((x-2*y)^4/(x^2-4*y^2)^2+1)*(y+a)*(2*y+x)/(4*y^2+x^2);
   rat(%,y,a,x);
   (x+3)^20;
   rat(%);
   diff(%,x);
   factor(%);
   
&& ratcoeff  

   a*x+b*x+5$
   ratcoef(%,a+b);
   
&& ratdiff  

   (4*x^3+10*x-11)/(x^5+5);
   polymod(%),modulus:3;
   ratdiff(%th(2),x);
   
&& ratexpand  

   ratexpand((2*x-3*y)^3);
   (x-1)/(x+1)^2+1/(x-1);
   expand(%);
   ratexpand(%th(2));
   
&& ratsimp  

   sin(x/(x^2+x))=%e^((log(x)+1)^2-log(x)^2);
   ratsimp(%);
   b*(a/b-x)+b*x+a;
   ratsimp(%);
   ((x-1)^(3/2)-(x+1)*sqrt(x-1))/sqrt(x-1)/sqrt(x+1);
   ratsimp(%);
   x^(a+1/a),ratsimpexpons;
   
&& ratsubst  

   ratsubst(a,x*y^2,x^4*y^8+x^4*y^3);
   1 + cos(x) + cos(x)^2 + cos(x)^3 + cos(x)^4;
   ratsubst(1-sin(x)^2,cos(x)^2,%);
   ratsubst(1-cos(x)^2,sin(x)^2,sin(x)^4);
   
&& ratweight  

   ratweight(a,1,b,1);
   rat(a+b+1);
   %^2;
   ev(%th(2)^2,ratwtlvl:1);
   
&& realpart  

   (%i*v+u)/(f+%i*e)+%e^(%i*alpha);
   realpart(%);
   
&& realroots  

   realroots(x^5-x-1,5.0e-6);
   %[1],float;
   x^5-x-1,%;
   
&& residue  

   residue(s/(s^2+a^2),s,a*%i);
   residue(sin(a*x)/x^4,x,0);
   
&& resultant  

   resultant(a*y+x^2+1,y^2+x*y+b,x);
   
&& reveal  

   integrate(1/(x^3+2),x)$
   reveal(%,2);
   reveal(%th(2),3);
   
&& reverse  
   
   union({a,b,1,1/2,x^2},{-x^2,a,y,1/2});
   bernpoly(x,5);
   maplist(numfactor,%);
   apply(min,%);
   
&& risch
  
   risch(x^2*erf(x),x);
   diff(%,x),ratsimp;
   
&& rootscontract 

   rootsconmode:false$
   rootscontract(x^(1/2)*y^(3/2));
   rootscontract(x^(1/2)*y^(1/4));
   rootsconmode:true$
   rootscontract(x^(1/2)*y^(1/4));
   rootscontract(x^(1/2)*y^(1/3));
   rootsconmode:all$
   rootscontract(x^(1/2)*y^(1/4));
   rootscontract(x^(1/2)*y^(1/3));
   rootsconmode:false$
   rootscontract(sqrt(sqrt(x+1)+sqrt(x))*sqrt(sqrt(x+1)-sqrt(x))); 
   rootsconmode:true$
   rootscontract(sqrt(sqrt(5)+5)-5^(1/4)*sqrt(sqrt(5)+1));
   
&& scanmap  

   (a^2+2*a+1)*y+x^2;
   scanmap(factor,%);
   scanmap(factor,expand(%th(2)));
   u*v^(a*x+b)+c;
   scanmap('f,%);
   
&& scsimp  

   exp:k^2*n^2+k^2*m^2*n^2-k^2*l^2*n^2-k^2*l^2*m^2*n^2;
   eq1:k^2+l^2=1;
   eq2:n^2-m^2=1;
   scsimp(exp,eq1,eq2);
   exq:(k1*k4-k1*k2-k2*k3)/k3^2;
   eq3:k1*k4-k2*k3=0;
   eq4:k1*k2+k3*k4=0;
   scsimp(exq,eq3,eq4);
   
&& solve  

   solve(asin(cos(3*x))*(f(x)-1),x);
   solve(5^f(x)=125,f(x)),solveradcan;
   [4*x^2-y^2=12,x*y-x=2];
   solve(%,[x,y]);
   solve(x^3+a*x+1,x);
   solve(x^3-1);
   solve(x^6-1);
   ev(x^6-1,%[1]);
   expand(%);
   x^2-1;
   solve(%,x);
   %th(2),%[1];
   
&& specint  

   assume(p>0,a>0)$
   /* a laplace transform */
   t^(1/2)*%e^(-a*t/4)*%e^(-p*t);
   specint(%,t);
   /* a bessel function */
   t^(1/2)*%j[1](2*a^(1/2)*t^(1/2))*%e^(-p*t);
   specint(%,t);
   forget(p>0,a>0)$
   
&& sqfr  

   sqfr(4*x^4+4*x^3-3*x^2-4*x-1);
   
&& substinpart  

   x.'diff(f(x),x,2);
   substinpart(d^2,%,2);
   substinpart(f1,f[1](x+1),0);
   
&& substitute  

   subst(a,x+y,x+(x+y)^2+y);
   subst(-%i,%i,a+b*%i);
   subst(x,y,x+y);
   subst(x=0,diff(sin(x),x));
   errcatch(ev(diff(sin(x),x),x=0));
   integrate(x^i,x),i=-1;
   errcatch(subst(-1,i,integrate(x^i,x)));
   matrix([a,b],[c,d]);
   subst("[",matrix,%);

&& substpart  

   1/(x^2+2);
   substpart(3/2,%,2,1,2);
   27*y^3+54*x*y^2+36*x^2*y+y+8*x^3+x+1;
   substpart(factor(piece),%,[1,2,3,5]);
   1/x+y/x-1/z;
   substpart(xthru(piece),%,[2,3]);
   substpart("+",%,1,0);
   ratsimp((k^2*x^2-1)*(cos(x)+eps)/(3*k+n[1])/(5*k-n[2]));
   factor(%);
   substpart(ratsimp(piece),%,1,[1,2]);
   -substpart(-piece,%,1,1);
   a+b/(x*(y+(a+b)*x)+1);
   substpart(multthru(piece),%,1,2,1);

&& sum

   sum(i^2+2^i,i,0,n),simpsum;
   sum(3^(-i),i,1,inf),simpsum;
   sum(i^2,i,1,4)*sum(1/i^2,i,1,inf),simpsum;
   sum(i^2,i,1,5);

&& symmetric 

   declare(h,symmetric);
   h(x,z,y);

&& syntax  

   matchfix("@{","@}");
   infix("|");
   @{x|x>0@};
   @{x|x<2@};
   infix(".u.")$
   infix(".i.")$
   %th(4).u.%th(3);
   %th(5).u.%th(4);
   @{1,2,3@}$
   @{3,4,5@}$
   %th(2).u.%th(2).u.%;
   infix(".u.",100,100)$
   infix(".i.",120,120)$
   %th(5).u.%th(5).u.%;
   remove(".u.",operator)$
   errcatch(%th(7).u.%th(3));
   remove(["@{","@}",".i.",".u."],operator)$

&& taylor

   taylor(sqrt(1+a*x+sin(x)),x,0,3);
   %^2;
   taylor(sqrt(1+x),x,0,5);
   %^2;
   product((x^i+1)^2.5,i,1,inf)/(x^2+1);
   taylor(%,x,0,3),keepfloat;
   taylor(1/log(1+x),x,0,3);
   taylor(cos(x)-sec(x),x,0,5);
   taylor((cos(x)-sec(x))^3,x,0,5);
   taylor((cos(x)-sec(x))^-3,x,0,5);
   taylor(sqrt(1-k^2*sin(x)^2),x,0,6);
   taylor((1+x)^n,x,0,4);
   taylor(sin(x+y),x,0,3,y,0,3);
   taylor(sin(x+y),[x,y],0,3);
   taylor(1/sin(x+y),x,0,3,y,0,3);
   taylor(1/sin(x+y),[x,y],0,3);

&& taytorat  

   taylor(1+x,[x,0,3]);
   1/%;
   taylor(1+x+y+z,[x,0,3],[y,1,2],[z,2,1]);
   1/%;
   taylor(1+x+y+z,[x,0,3],[y,0,3],[z,0,3]);
   1/%;

&& tellrat  

   10*(1+%i)/(3^(1/3)+%i);
   ratdisrep(rat(%)),algebraic;
   tellrat(a^2+a+1);
   a/(sqrt(2)+sqrt(3))+1/(a*sqrt(2)-1);
   ratdisrep(rat(%)),algebraic;
   tellrat(y^2=x^2);

&& tellsimp  

   matchdeclare(x,freeof(%i))$
   %iargs:false$
   tellsimp(sin(%i*x),%i*sinh(x));
   trigexpand(sin(x+%i*y));
   %iargs:true$
   errcatch(0^0);
   tellsimp(0^0,1),simp:false;
   0^0;
   remrule("^",%th(2)[1]);
   tellsimp(sin(x)^2,1-cos(x)^2)$
   (sin(x)+1)^2;
   expand(%);
   sin(x)^2;
   kill(rules);
   matchdeclare(a,true)$
   tellsimp(sin(a)^2,1-cos(a)^2)$
   sin(y)^2;
   kill(rules);

&& triangularize  

   matrix([2,1-a,-5*b],[a,b,c]);
   triangularize(%);

&& trig  

   sin(%pi/12)+tan(%pi/6);
   ev(%,numer);
   sin(1);
   sin(1),numer;
   beta(1/2,2/5);
   ev(%,numer);
   diff(atanh(sqrt(x)),x);
   fpprec:25$
   sin(0.5b0);
   cos(x)^2-sin(x)^2;
   ev(%,x:%pi/3);
   diff(%th(2),x);
   integrate(%th(3),x);
   expand(%);
   trigexpand(%);
   trigreduce(%);
   sech(x)^2*sinh(x)*tanh(x)/coth(x)^2 + cosh(x)^2*sech(x)^2*tanh(x)/coth(x)^2
        + sech(x)^2*tanh(x)/coth(x)^2;
   trigsimp(%);
   ev(sin(x),exponentialize);
   taylor(sin(x)/x,x,0,4);
   ev(cos(x)^2-sin(x)^2,sin(x)^2=1-cos(x)^2);

&& trigexpand  

   x+sin(3*x)/sin(x),trigexpand,expand;
   trigexpand(sin(10*x+y));

&& trigreduce  
   
   -sin(x)^2+3*cos(x)^2+x;
   expand(trigreduce(%));
   declare(j,integer,e,even,o,odd);
   sin(x+(e+1/2)*%pi);
   sin(x+(o+1/2)*%pi);

&& unorder  

   a^2+b*x;
   ordergreat(a);
   a^2+b*x;
   %-%th(3);
   unorder();

&& xthru  

   ((x+2)^20-2*y)/(x+y)^20+(x+y)^-19-x/(x+y)^20;
   xthru(%);
 
&& zeroequiv  
   
   zeroequiv(sin(2*x)-2*sin(x)*cos(x),x);
   zeroequiv(%e^x+x,x);
   zeroequiv(log(a*b)-log(a)-log(b),a);