test/compiler/8005956/PolynomialRoot.java - platform/external/jetbrains/jdk8u_hotspot - Git at Google

 //package com.polytechnik.utils;
 /*
  * (C) Vladislav Malyshkin 2010
  * This file is under GPL version 3.
  *
  */

 /** Polynomial root.
  *  @version $Id: PolynomialRoot.java,v 1.105 2012/08/18 00:00:05 mal Exp $
  *  @author Vladislav Malyshkin mal@gromco.com
  */

 /**
 * @test
 * @bug 8005956
 * @summary C2: assert(!def_outside->member(r)) failed: Use of external LRG overlaps the same LRG defined in this block
 *
 * @run main/timeout=300 PolynomialRoot
 */

 public class PolynomialRoot  {


 public static int findPolynomialRoots(final int n,
               final double [] p,
               final double [] re_root,
               final double [] im_root)
 {
     if(n==4)
     {
   return root4(p,re_root,im_root);
     }
     else if(n==3)
     {
   return root3(p,re_root,im_root);
     }
     else if(n==2)
     {
   return root2(p,re_root,im_root);
     }
     else if(n==1)
     {
   return root1(p,re_root,im_root);
     }
     else
     {
   throw new RuntimeException("n="+n+" is not supported yet");
     }
 }


 static final double SQRT3=Math.sqrt(3.0),SQRT2=Math.sqrt(2.0);


 private static final boolean PRINT_DEBUG=false;

 public static int root4(final double [] p,final double [] re_root,final double [] im_root)
 {
   if(PRINT_DEBUG) System.err.println("=====================root4:p="+java.util.Arrays.toString(p));
   final double vs=p[4];
   if(PRINT_DEBUG) System.err.println("p[4]="+p[4]);
   if(!(Math.abs(vs)>EPS))
   {
       re_root[0]=re_root[1]=re_root[2]=re_root[3]=
     im_root[0]=im_root[1]=im_root[2]=im_root[3]=Double.NaN;
       return -1;
   }

 /* zsolve_quartic.c - finds the complex roots of
  *  x^4 + a x^3 + b x^2 + c x + d = 0
  */
   final double a=p[3]/vs,b=p[2]/vs,c=p[1]/vs,d=p[0]/vs;
   if(PRINT_DEBUG) System.err.println("input a="+a+" b="+b+" c="+c+" d="+d);


   final double r4 = 1.0 / 4.0;
   final double q2 = 1.0 / 2.0, q4 = 1.0 / 4.0, q8 = 1.0 / 8.0;
   final double q1 = 3.0 / 8.0, q3 = 3.0 / 16.0;
   final int mt;

   /* Deal easily with the cases where the quartic is degenerate. The
    * ordering of solutions is done explicitly. */
   if (0 == b && 0 == c)
   {
       if (0 == d)
       {
     re_root[0]=-a;
     im_root[0]=im_root[1]=im_root[2]=im_root[3]=0;
     re_root[1]=re_root[2]=re_root[3]=0;
     return 4;
       }
       else if (0 == a)
       {
     if (d > 0)
     {
         final double sq4 = Math.sqrt(Math.sqrt(d));
         re_root[0]=sq4*SQRT2/2;
         im_root[0]=re_root[0];
         re_root[1]=-re_root[0];
         im_root[1]=re_root[0];
         re_root[2]=-re_root[0];
         im_root[2]=-re_root[0];
         re_root[3]=re_root[0];
         im_root[3]=-re_root[0];
         if(PRINT_DEBUG) System.err.println("Path a=0 d>0");
     }
     else
     {
         final double sq4 = Math.sqrt(Math.sqrt(-d));
         re_root[0]=sq4;
         im_root[0]=0;
         re_root[1]=0;
         im_root[1]=sq4;
         re_root[2]=0;
         im_root[2]=-sq4;
         re_root[3]=-sq4;
         im_root[3]=0;
         if(PRINT_DEBUG) System.err.println("Path a=0 d<0");
     }
     return 4;
       }
   }

   if (0.0 == c && 0.0 == d)
   {
       root2(new double []{p[2],p[3],p[4]},re_root,im_root);
       re_root[2]=im_root[2]=re_root[3]=im_root[3]=0;
       return 4;
   }

   if(PRINT_DEBUG) System.err.println("G Path c="+c+" d="+d);
   final double [] u=new double[3];

   if(PRINT_DEBUG) System.err.println("Generic Path");
   /* For non-degenerate solutions, proceed by constructing and
    * solving the resolvent cubic */
   final double aa = a * a;
   final double pp = b - q1 * aa;
   final double qq = c - q2 * a * (b - q4 * aa);
   final double rr = d - q4 * a * (c - q4 * a * (b - q3 * aa));
   final double rc = q2 * pp , rc3 = rc / 3;
   final double sc = q4 * (q4 * pp * pp - rr);
   final double tc = -(q8 * qq * q8 * qq);
   if(PRINT_DEBUG) System.err.println("aa="+aa+" pp="+pp+" qq="+qq+" rr="+rr+" rc="+rc+" sc="+sc+" tc="+tc);
   final boolean flag_realroots;

   /* This code solves the resolvent cubic in a convenient fashion
    * for this implementation of the quartic. If there are three real
    * roots, then they are placed directly into u[].  If two are
    * complex, then the real root is put into u[0] and the real
    * and imaginary part of the complex roots are placed into
    * u[1] and u[2], respectively. */
   {
       final double qcub = (rc * rc - 3 * sc);
       final double rcub = (rc*(2 * rc * rc - 9 * sc) + 27 * tc);

       final double Q = qcub / 9;
       final double R = rcub / 54;

       final double Q3 = Q * Q * Q;
       final double R2 = R * R;

       final double CR2 = 729 * rcub * rcub;
       final double CQ3 = 2916 * qcub * qcub * qcub;

       if(PRINT_DEBUG) System.err.println("CR2="+CR2+" CQ3="+CQ3+" R="+R+" Q="+Q);

       if (0 == R && 0 == Q)
       {
     flag_realroots=true;
     u[0] = -rc3;
     u[1] = -rc3;
     u[2] = -rc3;
       }
       else if (CR2 == CQ3)
       {
     flag_realroots=true;
     final double sqrtQ = Math.sqrt (Q);
     if (R > 0)
     {
         u[0] = -2 * sqrtQ - rc3;
         u[1] = sqrtQ - rc3;
         u[2] = sqrtQ - rc3;
     }
     else
     {
         u[0] = -sqrtQ - rc3;
         u[1] = -sqrtQ - rc3;
         u[2] = 2 * sqrtQ - rc3;
     }
       }
       else if (R2 < Q3)
       {
     flag_realroots=true;
     final double ratio = (R >= 0?1:-1) * Math.sqrt (R2 / Q3);
     final double theta = Math.acos (ratio);
     final double norm = -2 * Math.sqrt (Q);

     u[0] = norm * Math.cos (theta / 3) - rc3;
     u[1] = norm * Math.cos ((theta + 2.0 * Math.PI) / 3) - rc3;
     u[2] = norm * Math.cos ((theta - 2.0 * Math.PI) / 3) - rc3;
       }
       else
       {
     flag_realroots=false;
     final double A = -(R >= 0?1:-1)*Math.pow(Math.abs(R)+Math.sqrt(R2-Q3),1.0/3.0);
     final double B = Q / A;

     u[0] = A + B - rc3;
     u[1] = -0.5 * (A + B) - rc3;
     u[2] = -(SQRT3*0.5) * Math.abs (A - B);
       }
       if(PRINT_DEBUG) System.err.println("u[0]="+u[0]+" u[1]="+u[1]+" u[2]="+u[2]+" qq="+qq+" disc="+((CR2 - CQ3) / 2125764.0));
   }
   /* End of solution to resolvent cubic */

   /* Combine the square roots of the roots of the cubic
    * resolvent appropriately. Also, calculate 'mt' which
    * designates the nature of the roots:
    * mt=1 : 4 real roots
    * mt=2 : 0 real roots
    * mt=3 : 2 real roots
    */


   final double w1_re,w1_im,w2_re,w2_im,w3_re,w3_im,mod_w1w2,mod_w1w2_squared;
   if (flag_realroots)
   {
       mod_w1w2=-1;
       mt = 2;
       int jmin=0;
       double vmin=Math.abs(u[jmin]);
       for(int j=1;j<3;j++)
       {
     final double vx=Math.abs(u[j]);
     if(vx<vmin)
     {
         vmin=vx;
         jmin=j;
     }
       }
       final double u1=u[(jmin+1)%3],u2=u[(jmin+2)%3];
       mod_w1w2_squared=Math.abs(u1*u2);
       if(u1>=0)
       {
     w1_re=Math.sqrt(u1);
     w1_im=0;
       }
       else
       {
     w1_re=0;
     w1_im=Math.sqrt(-u1);
       }
       if(u2>=0)
       {
     w2_re=Math.sqrt(u2);
     w2_im=0;
       }
       else
       {
     w2_re=0;
     w2_im=Math.sqrt(-u2);
       }
       if(PRINT_DEBUG) System.err.println("u1="+u1+" u2="+u2+" jmin="+jmin);
   }
   else
   {
       mt = 3;
       final double w_mod2_sq=u[1]*u[1]+u[2]*u[2],w_mod2=Math.sqrt(w_mod2_sq),w_mod=Math.sqrt(w_mod2);
       if(w_mod2_sq<=0)
       {
     w1_re=w1_im=0;
       }
       else
       {
     // calculate square root of a complex number (u[1],u[2])
     // the result is in the (w1_re,w1_im)
     final double absu1=Math.abs(u[1]),absu2=Math.abs(u[2]),w;
     if(absu1>=absu2)
     {
         final double t=absu2/absu1;
         w=Math.sqrt(absu1*0.5 * (1.0 + Math.sqrt(1.0 + t * t)));
         if(PRINT_DEBUG) System.err.println(" Path1 ");
     }
     else
     {
         final double t=absu1/absu2;
         w=Math.sqrt(absu2*0.5 * (t + Math.sqrt(1.0 + t * t)));
         if(PRINT_DEBUG) System.err.println(" Path1a ");
     }
     if(u[1]>=0)
     {
         w1_re=w;
         w1_im=u[2]/(2*w);
         if(PRINT_DEBUG) System.err.println(" Path2 ");
     }
     else
     {
         final double vi = (u[2] >= 0) ? w : -w;
         w1_re=u[2]/(2*vi);
         w1_im=vi;
         if(PRINT_DEBUG) System.err.println(" Path2a ");
     }
       }
       final double absu0=Math.abs(u[0]);
       if(w_mod2>=absu0)
       {
     mod_w1w2=w_mod2;
     mod_w1w2_squared=w_mod2_sq;
     w2_re=w1_re;
     w2_im=-w1_im;
       }
       else
       {
     mod_w1w2=-1;
     mod_w1w2_squared=w_mod2*absu0;
     if(u[0]>=0)
     {
         w2_re=Math.sqrt(absu0);
         w2_im=0;
     }
     else
     {
         w2_re=0;
         w2_im=Math.sqrt(absu0);
     }
       }
       if(PRINT_DEBUG) System.err.println("u[0]="+u[0]+"u[1]="+u[1]+" u[2]="+u[2]+" absu0="+absu0+" w_mod="+w_mod+" w_mod2="+w_mod2);
   }

   /* Solve the quadratic in order to obtain the roots
    * to the quartic */
   if(mod_w1w2>0)
   {
       // a shorcut to reduce rounding error
       w3_re=qq/(-8)/mod_w1w2;
       w3_im=0;
   }
   else if(mod_w1w2_squared>0)
   {
       // regular path
       final double mqq8n=qq/(-8)/mod_w1w2_squared;
       w3_re=mqq8n*(w1_re*w2_re-w1_im*w2_im);
       w3_im=-mqq8n*(w1_re*w2_im+w2_re*w1_im);
   }
   else
   {
       // typically occur when qq==0
       w3_re=w3_im=0;
   }

   final double h = r4 * a;
   if(PRINT_DEBUG) System.err.println("w1_re="+w1_re+" w1_im="+w1_im+" w2_re="+w2_re+" w2_im="+w2_im+" w3_re="+w3_re+" w3_im="+w3_im+" h="+h);

   re_root[0]=w1_re+w2_re+w3_re-h;
   im_root[0]=w1_im+w2_im+w3_im;
   re_root[1]=-(w1_re+w2_re)+w3_re-h;
   im_root[1]=-(w1_im+w2_im)+w3_im;
   re_root[2]=w2_re-w1_re-w3_re-h;
   im_root[2]=w2_im-w1_im-w3_im;
   re_root[3]=w1_re-w2_re-w3_re-h;
   im_root[3]=w1_im-w2_im-w3_im;

   return 4;
 }


     static void setRandomP(final double [] p,final int n,java.util.Random r)
     {
   if(r.nextDouble()<0.1)
   {
       // integer coefficiens
       for(int j=0;j<p.length;j++)
       {
     if(j<=n)
     {
         p[j]=(r.nextInt(2)<=0?-1:1)*r.nextInt(10);
     }
     else
     {
         p[j]=0;
     }
       }
   }
   else
   {
       // real coefficiens
       for(int j=0;j<p.length;j++)
       {
     if(j<=n)
     {
         p[j]=-1+2*r.nextDouble();
     }
     else
     {
         p[j]=0;
     }
       }
   }
   if(Math.abs(p[n])<1e-2)
   {
       p[n]=(r.nextInt(2)<=0?-1:1)*(0.1+r.nextDouble());
   }
     }


     static void checkValues(final double [] p,
           final int n,
           final double rex,
           final double imx,
           final double eps,
           final String txt)
     {
   double res=0,ims=0,sabs=0;
   final double xabs=Math.abs(rex)+Math.abs(imx);
   for(int k=n;k>=0;k--)
   {
       final double res1=(res*rex-ims*imx)+p[k];
       final double ims1=(ims*rex+res*imx);
       res=res1;
       ims=ims1;
       sabs+=xabs*sabs+p[k];
   }
   sabs=Math.abs(sabs);
   if(false && sabs>1/eps?
      (!(Math.abs(res/sabs)<=eps)||!(Math.abs(ims/sabs)<=eps))
      :
      (!(Math.abs(res)<=eps)||!(Math.abs(ims)<=eps)))
   {
       throw new RuntimeException(
     getPolinomTXT(p)+"\n"+
     "\t x.r="+rex+" x.i="+imx+"\n"+
     "res/sabs="+(res/sabs)+" ims/sabs="+(ims/sabs)+
     " sabs="+sabs+
     "\nres="+res+" ims="+ims+" n="+n+" eps="+eps+" "+
     " sabs>1/eps="+(sabs>1/eps)+
     " f1="+(!(Math.abs(res/sabs)<=eps)||!(Math.abs(ims/sabs)<=eps))+
     " f2="+(!(Math.abs(res)<=eps)||!(Math.abs(ims)<=eps))+
     " "+txt);
   }
     }

     static String getPolinomTXT(final double [] p)
     {
   final StringBuilder buf=new StringBuilder();
   buf.append("order="+(p.length-1)+"\t");
   for(int k=0;k<p.length;k++)
   {
       buf.append("p["+k+"]="+p[k]+";");
   }
   return buf.toString();
     }

     static String getRootsTXT(int nr,final double [] re,final double [] im)
     {
   final StringBuilder buf=new StringBuilder();
   for(int k=0;k<nr;k++)
   {
       buf.append("x."+k+"("+re[k]+","+im[k]+")\n");
   }
   return buf.toString();
     }

     static void testRoots(final int n,
         final int n_tests,
         final java.util.Random rn,
         final double eps)
     {
   final double [] p=new double [n+1];
   final double [] rex=new double [n],imx=new double [n];
   for(int i=0;i<n_tests;i++)
   {
     for(int dg=n;dg-->-1;)
     {
       for(int dr=3;dr-->0;)
       {
         setRandomP(p,n,rn);
         for(int j=0;j<=dg;j++)
         {
       p[j]=0;
         }
         if(dr==0)
         {
       p[0]=-1+2.0*rn.nextDouble();
         }
         else if(dr==1)
         {
       p[0]=p[1]=0;
         }

         findPolynomialRoots(n,p,rex,imx);

         for(int j=0;j<n;j++)
         {
       //System.err.println("j="+j);
       checkValues(p,n,rex[j],imx[j],eps," t="+i);
         }
       }
     }
   }
   System.err.println("testRoots(): n_tests="+n_tests+" OK, dim="+n);
     }


     static final double EPS=0;

     public static int root1(final double [] p,final double [] re_root,final double [] im_root)
     {
   if(!(Math.abs(p[1])>EPS))
   {
       re_root[0]=im_root[0]=Double.NaN;
       return -1;
   }
   re_root[0]=-p[0]/p[1];
   im_root[0]=0;
   return 1;
     }

     public static int root2(final double [] p,final double [] re_root,final double [] im_root)
     {
   if(!(Math.abs(p[2])>EPS))
   {
       re_root[0]=re_root[1]=im_root[0]=im_root[1]=Double.NaN;
       return -1;
   }
   final double b2=0.5*(p[1]/p[2]),c=p[0]/p[2],d=b2*b2-c;
   if(d>=0)
   {
       final double sq=Math.sqrt(d);
       if(b2<0)
       {
     re_root[1]=-b2+sq;
     re_root[0]=c/re_root[1];
       }
       else if(b2>0)
       {
     re_root[0]=-b2-sq;
     re_root[1]=c/re_root[0];
       }
       else
       {
     re_root[0]=-b2-sq;
     re_root[1]=-b2+sq;
       }
       im_root[0]=im_root[1]=0;
   }
   else
   {
       final double sq=Math.sqrt(-d);
       re_root[0]=re_root[1]=-b2;
       im_root[0]=sq;
       im_root[1]=-sq;
   }
   return 2;
     }

     public static int root3(final double [] p,final double [] re_root,final double [] im_root)
     {
   final double vs=p[3];
   if(!(Math.abs(vs)>EPS))
   {
       re_root[0]=re_root[1]=re_root[2]=
     im_root[0]=im_root[1]=im_root[2]=Double.NaN;
       return -1;
   }
   final double a=p[2]/vs,b=p[1]/vs,c=p[0]/vs;
   /* zsolve_cubic.c - finds the complex roots of x^3 + a x^2 + b x + c = 0
    */
   final double q = (a * a - 3 * b);
   final double r = (a*(2 * a * a - 9 * b) + 27 * c);

   final double Q = q / 9;
   final double R = r / 54;

   final double Q3 = Q * Q * Q;
   final double R2 = R * R;

   final double CR2 = 729 * r * r;
   final double CQ3 = 2916 * q * q * q;
   final double a3=a/3;

   if (R == 0 && Q == 0)
   {
       re_root[0]=re_root[1]=re_root[2]=-a3;
       im_root[0]=im_root[1]=im_root[2]=0;
       return 3;
   }
   else if (CR2 == CQ3)
   {
       /* this test is actually R2 == Q3, written in a form suitable
          for exact computation with integers */

       /* Due to finite precision some double roots may be missed, and
          will be considered to be a pair of complex roots z = x +/-
          epsilon i close to the real axis. */

       final double sqrtQ = Math.sqrt (Q);

       if (R > 0)
       {
     re_root[0] = -2 * sqrtQ - a3;
     re_root[1]=re_root[2]=sqrtQ - a3;
     im_root[0]=im_root[1]=im_root[2]=0;
       }
       else
       {
     re_root[0]=re_root[1] = -sqrtQ - a3;
     re_root[2]=2 * sqrtQ - a3;
     im_root[0]=im_root[1]=im_root[2]=0;
       }
       return 3;
   }
   else if (R2 < Q3)
   {
       final double sgnR = (R >= 0 ? 1 : -1);
       final double ratio = sgnR * Math.sqrt (R2 / Q3);
       final double theta = Math.acos (ratio);
       final double norm = -2 * Math.sqrt (Q);
       final double r0 = norm * Math.cos (theta/3) - a3;
       final double r1 = norm * Math.cos ((theta + 2.0 * Math.PI) / 3) - a3;
       final double r2 = norm * Math.cos ((theta - 2.0 * Math.PI) / 3) - a3;

       re_root[0]=r0;
       re_root[1]=r1;
       re_root[2]=r2;
       im_root[0]=im_root[1]=im_root[2]=0;
       return 3;
   }
   else
   {
       final double sgnR = (R >= 0 ? 1 : -1);
       final double A = -sgnR * Math.pow (Math.abs (R) + Math.sqrt (R2 - Q3), 1.0 / 3.0);
       final double B = Q / A;

       re_root[0]=A + B - a3;
       im_root[0]=0;
       re_root[1]=-0.5 * (A + B) - a3;
       im_root[1]=-(SQRT3*0.5) * Math.abs(A - B);
       re_root[2]=re_root[1];
       im_root[2]=-im_root[1];
       return 3;
   }

     }


     static void root3a(final double [] p,final double [] re_root,final double [] im_root)
     {
   if(Math.abs(p[3])>EPS)
   {
       final double v=p[3],
     a=p[2]/v,b=p[1]/v,c=p[0]/v,
     a3=a/3,a3a=a3*a,
     pd3=(b-a3a)/3,
     qd2=a3*(a3a/3-0.5*b)+0.5*c,
     Q=pd3*pd3*pd3+qd2*qd2;
       if(Q<0)
       {
     // three real roots
     final double SQ=Math.sqrt(-Q);
     final double th=Math.atan2(SQ,-qd2);
     im_root[0]=im_root[1]=im_root[2]=0;
     final double f=2*Math.sqrt(-pd3);
     re_root[0]=f*Math.cos(th/3)-a3;
     re_root[1]=f*Math.cos((th+2*Math.PI)/3)-a3;
     re_root[2]=f*Math.cos((th+4*Math.PI)/3)-a3;
     //System.err.println("3r");
       }
       else
       {
     // one real & two complex roots
     final double SQ=Math.sqrt(Q);
     final double r1=-qd2+SQ,r2=-qd2-SQ;
     final double v1=Math.signum(r1)*Math.pow(Math.abs(r1),1.0/3),
         v2=Math.signum(r2)*Math.pow(Math.abs(r2),1.0/3),
         sv=v1+v2;
     // real root
     re_root[0]=sv-a3;
     im_root[0]=0;
     // complex roots
     re_root[1]=re_root[2]=-0.5*sv-a3;
     im_root[1]=(v1-v2)*(SQRT3*0.5);
     im_root[2]=-im_root[1];
     //System.err.println("1r2c");
       }
   }
   else
   {
       re_root[0]=re_root[1]=re_root[2]=im_root[0]=im_root[1]=im_root[2]=Double.NaN;
   }
     }


     static void printSpecialValues()
     {
   for(int st=0;st<6;st++)
   {
       //final double [] p=new double []{8,1,3,3.6,1};
       final double [] re_root=new double [4],im_root=new double [4];
       final double [] p;
       final int n;
       if(st<=3)
       {
     if(st<=0)
     {
         p=new double []{2,-4,6,-4,1};
         //p=new double []{-6,6,-6,8,-2};
     }
     else if(st==1)
     {
         p=new double []{0,-4,8,3,-9};
     }
     else if(st==2)
     {
         p=new double []{-1,0,2,0,-1};
     }
     else
     {
         p=new double []{-5,2,8,-2,-3};
     }
     root4(p,re_root,im_root);
     n=4;
       }
       else
       {
     p=new double []{0,2,0,1};
     if(st==4)
     {
         p[1]=-p[1];
     }
     root3(p,re_root,im_root);
     n=3;
       }
       System.err.println("======== n="+n);
       for(int i=0;i<=n;i++)
       {
     if(i<n)
     {
         System.err.println(String.valueOf(i)+"\t"+
                p[i]+"\t"+
                re_root[i]+"\t"+
                im_root[i]);
     }
     else
     {
         System.err.println(String.valueOf(i)+"\t"+p[i]+"\t");
     }
       }
   }
     }


     public static void main(final String [] args)
     {
       if (System.getProperty("os.arch").equals("x86") ||
          System.getProperty("os.arch").equals("amd64") ||
          System.getProperty("os.arch").equals("x86_64")){
         final long t0=System.currentTimeMillis();
         final double eps=1e-6;
         //checkRoots();
         final java.util.Random r=new java.util.Random(-1381923);
         printSpecialValues();

         final int n_tests=100000;
         //testRoots(2,n_tests,r,eps);
         //testRoots(3,n_tests,r,eps);
         testRoots(4,n_tests,r,eps);
         final long t1=System.currentTimeMillis();
         System.err.println("PolynomialRoot.main: "+n_tests+" tests OK done in "+(t1-t0)+" milliseconds. ver=$Id: PolynomialRoot.java,v 1.105 2012/08/18 00:00:05 mal Exp $");
         System.out.println("PASSED");
      } else {
        System.out.println("PASS test for non-x86");
      }
    }


 }
	//package com.polytechnik.utils;
	/*
	* (C) Vladislav Malyshkin 2010
	* This file is under GPL version 3.
	*
	*/

	/** Polynomial root.
	* @version $Id: PolynomialRoot.java,v 1.105 2012/08/18 00:00:05 mal Exp $
	* @author Vladislav Malyshkin mal@gromco.com
	*/

	/**
	* @test
	* @bug 8005956
	* @summary C2: assert(!def_outside->member(r)) failed: Use of external LRG overlaps the same LRG defined in this block
	*
	* @run main/timeout=300 PolynomialRoot
	*/

	public class PolynomialRoot {


	public static int findPolynomialRoots(final int n,
	final double [] p,
	final double [] re_root,
	final double [] im_root)
	{
	if(n==4)
	{
	return root4(p,re_root,im_root);
	}
	else if(n==3)
	{
	return root3(p,re_root,im_root);
	}
	else if(n==2)
	{
	return root2(p,re_root,im_root);
	}
	else if(n==1)
	{
	return root1(p,re_root,im_root);
	}
	else
	{
	throw new RuntimeException("n="+n+" is not supported yet");
	}
	}



	static final double SQRT3=Math.sqrt(3.0),SQRT2=Math.sqrt(2.0);


	private static final boolean PRINT_DEBUG=false;

	public static int root4(final double [] p,final double [] re_root,final double [] im_root)
	{
	if(PRINT_DEBUG) System.err.println("=====================root4:p="+java.util.Arrays.toString(p));
	final double vs=p[4];
	if(PRINT_DEBUG) System.err.println("p[4]="+p[4]);
	if(!(Math.abs(vs)>EPS))
	{
	re_root[0]=re_root[1]=re_root[2]=re_root[3]=
	im_root[0]=im_root[1]=im_root[2]=im_root[3]=Double.NaN;
	return -1;
	}

	/* zsolve_quartic.c - finds the complex roots of
	* x^4 + a x^3 + b x^2 + c x + d = 0
	*/
	final double a=p[3]/vs,b=p[2]/vs,c=p[1]/vs,d=p[0]/vs;
	if(PRINT_DEBUG) System.err.println("input a="+a+" b="+b+" c="+c+" d="+d);


	final double r4 = 1.0 / 4.0;
	final double q2 = 1.0 / 2.0, q4 = 1.0 / 4.0, q8 = 1.0 / 8.0;
	final double q1 = 3.0 / 8.0, q3 = 3.0 / 16.0;
	final int mt;

	/* Deal easily with the cases where the quartic is degenerate. The
	* ordering of solutions is done explicitly. */
	if (0 == b && 0 == c)
	{
	if (0 == d)
	{
	re_root[0]=-a;
	im_root[0]=im_root[1]=im_root[2]=im_root[3]=0;
	re_root[1]=re_root[2]=re_root[3]=0;
	return 4;
	}
	else if (0 == a)
	{
	if (d > 0)
	{
	final double sq4 = Math.sqrt(Math.sqrt(d));
	re_root[0]=sq4*SQRT2/2;
	im_root[0]=re_root[0];
	re_root[1]=-re_root[0];
	im_root[1]=re_root[0];
	re_root[2]=-re_root[0];
	im_root[2]=-re_root[0];
	re_root[3]=re_root[0];
	im_root[3]=-re_root[0];
	if(PRINT_DEBUG) System.err.println("Path a=0 d>0");
	}
	else
	{
	final double sq4 = Math.sqrt(Math.sqrt(-d));
	re_root[0]=sq4;
	im_root[0]=0;
	re_root[1]=0;
	im_root[1]=sq4;
	re_root[2]=0;
	im_root[2]=-sq4;
	re_root[3]=-sq4;
	im_root[3]=0;
	if(PRINT_DEBUG) System.err.println("Path a=0 d<0");
	}
	return 4;
	}
	}

	if (0.0 == c && 0.0 == d)
	{
	root2(new double []{p[2],p[3],p[4]},re_root,im_root);
	re_root[2]=im_root[2]=re_root[3]=im_root[3]=0;
	return 4;
	}

	if(PRINT_DEBUG) System.err.println("G Path c="+c+" d="+d);
	final double [] u=new double[3];

	if(PRINT_DEBUG) System.err.println("Generic Path");
	/* For non-degenerate solutions, proceed by constructing and
	* solving the resolvent cubic */
	final double aa = a * a;
	final double pp = b - q1 * aa;
	final double qq = c - q2 * a * (b - q4 * aa);
	final double rr = d - q4 * a * (c - q4 * a * (b - q3 * aa));
	final double rc = q2 * pp , rc3 = rc / 3;
	final double sc = q4 * (q4 * pp * pp - rr);
	final double tc = -(q8 * qq * q8 * qq);
	if(PRINT_DEBUG) System.err.println("aa="+aa+" pp="+pp+" qq="+qq+" rr="+rr+" rc="+rc+" sc="+sc+" tc="+tc);
	final boolean flag_realroots;

	/* This code solves the resolvent cubic in a convenient fashion
	* for this implementation of the quartic. If there are three real
	* roots, then they are placed directly into u[]. If two are
	* complex, then the real root is put into u[0] and the real
	* and imaginary part of the complex roots are placed into
	* u[1] and u[2], respectively. */
	{
	final double qcub = (rc * rc - 3 * sc);
	final double rcub = (rc(2 rc * rc - 9 * sc) + 27 * tc);

	final double Q = qcub / 9;
	final double R = rcub / 54;

	final double Q3 = Q * Q * Q;
	final double R2 = R * R;

	final double CR2 = 729 * rcub * rcub;
	final double CQ3 = 2916 * qcub * qcub * qcub;

	if(PRINT_DEBUG) System.err.println("CR2="+CR2+" CQ3="+CQ3+" R="+R+" Q="+Q);

	if (0 == R && 0 == Q)
	{
	flag_realroots=true;
	u[0] = -rc3;
	u[1] = -rc3;
	u[2] = -rc3;
	}
	else if (CR2 == CQ3)
	{
	flag_realroots=true;
	final double sqrtQ = Math.sqrt (Q);
	if (R > 0)
	{
	u[0] = -2 * sqrtQ - rc3;
	u[1] = sqrtQ - rc3;
	u[2] = sqrtQ - rc3;
	}
	else
	{
	u[0] = -sqrtQ - rc3;
	u[1] = -sqrtQ - rc3;
	u[2] = 2 * sqrtQ - rc3;
	}
	}
	else if (R2 < Q3)
	{
	flag_realroots=true;
	final double ratio = (R >= 0?1:-1) * Math.sqrt (R2 / Q3);
	final double theta = Math.acos (ratio);
	final double norm = -2 * Math.sqrt (Q);

	u[0] = norm * Math.cos (theta / 3) - rc3;
	u[1] = norm * Math.cos ((theta + 2.0 * Math.PI) / 3) - rc3;
	u[2] = norm * Math.cos ((theta - 2.0 * Math.PI) / 3) - rc3;
	}
	else
	{
	flag_realroots=false;
	final double A = -(R >= 0?1:-1)*Math.pow(Math.abs(R)+Math.sqrt(R2-Q3),1.0/3.0);
	final double B = Q / A;

	u[0] = A + B - rc3;
	u[1] = -0.5 * (A + B) - rc3;
	u[2] = -(SQRT30.5) Math.abs (A - B);
	}
	if(PRINT_DEBUG) System.err.println("u[0]="+u[0]+" u[1]="+u[1]+" u[2]="+u[2]+" qq="+qq+" disc="+((CR2 - CQ3) / 2125764.0));
	}
	/* End of solution to resolvent cubic */

	/* Combine the square roots of the roots of the cubic
	* resolvent appropriately. Also, calculate 'mt' which
	* designates the nature of the roots:
	* mt=1 : 4 real roots
	* mt=2 : 0 real roots
	* mt=3 : 2 real roots
	*/


	final double w1_re,w1_im,w2_re,w2_im,w3_re,w3_im,mod_w1w2,mod_w1w2_squared;
	if (flag_realroots)
	{
	mod_w1w2=-1;
	mt = 2;
	int jmin=0;
	double vmin=Math.abs(u[jmin]);
	for(int j=1;j<3;j++)
	{
	final double vx=Math.abs(u[j]);
	if(vx<vmin)
	{
	vmin=vx;
	jmin=j;
	}
	}
	final double u1=u[(jmin+1)%3],u2=u[(jmin+2)%3];
	mod_w1w2_squared=Math.abs(u1*u2);
	if(u1>=0)
	{
	w1_re=Math.sqrt(u1);
	w1_im=0;
	}
	else
	{
	w1_re=0;
	w1_im=Math.sqrt(-u1);
	}
	if(u2>=0)
	{
	w2_re=Math.sqrt(u2);
	w2_im=0;
	}
	else
	{
	w2_re=0;
	w2_im=Math.sqrt(-u2);
	}
	if(PRINT_DEBUG) System.err.println("u1="+u1+" u2="+u2+" jmin="+jmin);
	}
	else
	{
	mt = 3;
	final double w_mod2_sq=u[1]u[1]+u[2]u[2],w_mod2=Math.sqrt(w_mod2_sq),w_mod=Math.sqrt(w_mod2);
	if(w_mod2_sq<=0)
	{
	w1_re=w1_im=0;
	}
	else
	{
	// calculate square root of a complex number (u[1],u[2])
	// the result is in the (w1_re,w1_im)
	final double absu1=Math.abs(u[1]),absu2=Math.abs(u[2]),w;
	if(absu1>=absu2)
	{
	final double t=absu2/absu1;
	w=Math.sqrt(absu10.5 (1.0 + Math.sqrt(1.0 + t * t)));
	if(PRINT_DEBUG) System.err.println(" Path1 ");
	}
	else
	{
	final double t=absu1/absu2;
	w=Math.sqrt(absu20.5 (t + Math.sqrt(1.0 + t * t)));
	if(PRINT_DEBUG) System.err.println(" Path1a ");
	}
	if(u[1]>=0)
	{
	w1_re=w;
	w1_im=u[2]/(2*w);
	if(PRINT_DEBUG) System.err.println(" Path2 ");
	}
	else
	{
	final double vi = (u[2] >= 0) ? w : -w;
	w1_re=u[2]/(2*vi);
	w1_im=vi;
	if(PRINT_DEBUG) System.err.println(" Path2a ");
	}
	}
	final double absu0=Math.abs(u[0]);
	if(w_mod2>=absu0)
	{
	mod_w1w2=w_mod2;
	mod_w1w2_squared=w_mod2_sq;
	w2_re=w1_re;
	w2_im=-w1_im;
	}
	else
	{
	mod_w1w2=-1;
	mod_w1w2_squared=w_mod2*absu0;
	if(u[0]>=0)
	{
	w2_re=Math.sqrt(absu0);
	w2_im=0;
	}
	else
	{
	w2_re=0;
	w2_im=Math.sqrt(absu0);
	}
	}
	if(PRINT_DEBUG) System.err.println("u[0]="+u[0]+"u[1]="+u[1]+" u[2]="+u[2]+" absu0="+absu0+" w_mod="+w_mod+" w_mod2="+w_mod2);
	}

	/* Solve the quadratic in order to obtain the roots
	* to the quartic */
	if(mod_w1w2>0)
	{
	// a shorcut to reduce rounding error
	w3_re=qq/(-8)/mod_w1w2;
	w3_im=0;
	}
	else if(mod_w1w2_squared>0)
	{
	// regular path
	final double mqq8n=qq/(-8)/mod_w1w2_squared;
	w3_re=mqq8n(w1_rew2_re-w1_im*w2_im);
	w3_im=-mqq8n(w1_rew2_im+w2_re*w1_im);
	}
	else
	{
	// typically occur when qq==0
	w3_re=w3_im=0;
	}

	final double h = r4 * a;
	if(PRINT_DEBUG) System.err.println("w1_re="+w1_re+" w1_im="+w1_im+" w2_re="+w2_re+" w2_im="+w2_im+" w3_re="+w3_re+" w3_im="+w3_im+" h="+h);

	re_root[0]=w1_re+w2_re+w3_re-h;
	im_root[0]=w1_im+w2_im+w3_im;
	re_root[1]=-(w1_re+w2_re)+w3_re-h;
	im_root[1]=-(w1_im+w2_im)+w3_im;
	re_root[2]=w2_re-w1_re-w3_re-h;
	im_root[2]=w2_im-w1_im-w3_im;
	re_root[3]=w1_re-w2_re-w3_re-h;
	im_root[3]=w1_im-w2_im-w3_im;

	return 4;
	}



	static void setRandomP(final double [] p,final int n,java.util.Random r)
	{
	if(r.nextDouble()<0.1)
	{
	// integer coefficiens
	for(int j=0;j<p.length;j++)
	{
	if(j<=n)
	{
	p[j]=(r.nextInt(2)<=0?-1:1)*r.nextInt(10);
	}
	else
	{
	p[j]=0;
	}
	}
	}
	else
	{
	// real coefficiens
	for(int j=0;j<p.length;j++)
	{
	if(j<=n)
	{
	p[j]=-1+2*r.nextDouble();
	}
	else
	{
	p[j]=0;
	}
	}
	}
	if(Math.abs(p[n])<1e-2)
	{
	p[n]=(r.nextInt(2)<=0?-1:1)*(0.1+r.nextDouble());
	}
	}


	static void checkValues(final double [] p,
	final int n,
	final double rex,
	final double imx,
	final double eps,
	final String txt)
	{
	double res=0,ims=0,sabs=0;
	final double xabs=Math.abs(rex)+Math.abs(imx);
	for(int k=n;k>=0;k--)
	{
	final double res1=(resrex-imsimx)+p[k];
	final double ims1=(imsrex+resimx);
	res=res1;
	ims=ims1;
	sabs+=xabs*sabs+p[k];
	}
	sabs=Math.abs(sabs);
	if(false && sabs>1/eps?
	(!(Math.abs(res/sabs)<=eps)\|\|!(Math.abs(ims/sabs)<=eps))
	:
	(!(Math.abs(res)<=eps)\|\|!(Math.abs(ims)<=eps)))
	{
	throw new RuntimeException(
	getPolinomTXT(p)+"\n"+
	"\t x.r="+rex+" x.i="+imx+"\n"+
	"res/sabs="+(res/sabs)+" ims/sabs="+(ims/sabs)+
	" sabs="+sabs+
	"\nres="+res+" ims="+ims+" n="+n+" eps="+eps+" "+
	" sabs>1/eps="+(sabs>1/eps)+
	" f1="+(!(Math.abs(res/sabs)<=eps)\|\|!(Math.abs(ims/sabs)<=eps))+
	" f2="+(!(Math.abs(res)<=eps)\|\|!(Math.abs(ims)<=eps))+
	" "+txt);
	}
	}

	static String getPolinomTXT(final double [] p)
	{
	final StringBuilder buf=new StringBuilder();
	buf.append("order="+(p.length-1)+"\t");
	for(int k=0;k<p.length;k++)
	{
	buf.append("p["+k+"]="+p[k]+";");
	}
	return buf.toString();
	}

	static String getRootsTXT(int nr,final double [] re,final double [] im)
	{
	final StringBuilder buf=new StringBuilder();
	for(int k=0;k<nr;k++)
	{
	buf.append("x."+k+"("+re[k]+","+im[k]+")\n");
	}
	return buf.toString();
	}

	static void testRoots(final int n,
	final int n_tests,
	final java.util.Random rn,
	final double eps)
	{
	final double [] p=new double [n+1];
	final double [] rex=new double [n],imx=new double [n];
	for(int i=0;i<n_tests;i++)
	{
	for(int dg=n;dg-->-1;)
	{
	for(int dr=3;dr-->0;)
	{
	setRandomP(p,n,rn);
	for(int j=0;j<=dg;j++)
	{
	p[j]=0;
	}
	if(dr==0)
	{
	p[0]=-1+2.0*rn.nextDouble();
	}
	else if(dr==1)
	{
	p[0]=p[1]=0;
	}

	findPolynomialRoots(n,p,rex,imx);

	for(int j=0;j<n;j++)
	{
	//System.err.println("j="+j);
	checkValues(p,n,rex[j],imx[j],eps," t="+i);
	}
	}
	}
	}
	System.err.println("testRoots(): n_tests="+n_tests+" OK, dim="+n);
	}




	static final double EPS=0;

	public static int root1(final double [] p,final double [] re_root,final double [] im_root)
	{
	if(!(Math.abs(p[1])>EPS))
	{
	re_root[0]=im_root[0]=Double.NaN;
	return -1;
	}
	re_root[0]=-p[0]/p[1];
	im_root[0]=0;
	return 1;
	}

	public static int root2(final double [] p,final double [] re_root,final double [] im_root)
	{
	if(!(Math.abs(p[2])>EPS))
	{
	re_root[0]=re_root[1]=im_root[0]=im_root[1]=Double.NaN;
	return -1;
	}
	final double b2=0.5(p[1]/p[2]),c=p[0]/p[2],d=b2b2-c;
	if(d>=0)
	{
	final double sq=Math.sqrt(d);
	if(b2<0)
	{
	re_root[1]=-b2+sq;
	re_root[0]=c/re_root[1];
	}
	else if(b2>0)
	{
	re_root[0]=-b2-sq;
	re_root[1]=c/re_root[0];
	}
	else
	{
	re_root[0]=-b2-sq;
	re_root[1]=-b2+sq;
	}
	im_root[0]=im_root[1]=0;
	}
	else
	{
	final double sq=Math.sqrt(-d);
	re_root[0]=re_root[1]=-b2;
	im_root[0]=sq;
	im_root[1]=-sq;
	}
	return 2;
	}

	public static int root3(final double [] p,final double [] re_root,final double [] im_root)
	{
	final double vs=p[3];
	if(!(Math.abs(vs)>EPS))
	{
	re_root[0]=re_root[1]=re_root[2]=
	im_root[0]=im_root[1]=im_root[2]=Double.NaN;
	return -1;
	}
	final double a=p[2]/vs,b=p[1]/vs,c=p[0]/vs;
	/* zsolve_cubic.c - finds the complex roots of x^3 + a x^2 + b x + c = 0
	*/
	final double q = (a * a - 3 * b);
	final double r = (a(2 a * a - 9 * b) + 27 * c);

	final double Q = q / 9;
	final double R = r / 54;

	final double Q3 = Q * Q * Q;
	final double R2 = R * R;

	final double CR2 = 729 * r * r;
	final double CQ3 = 2916 * q * q * q;
	final double a3=a/3;

	if (R == 0 && Q == 0)
	{
	re_root[0]=re_root[1]=re_root[2]=-a3;
	im_root[0]=im_root[1]=im_root[2]=0;
	return 3;
	}
	else if (CR2 == CQ3)
	{
	/* this test is actually R2 == Q3, written in a form suitable
	for exact computation with integers */

	/* Due to finite precision some double roots may be missed, and
	will be considered to be a pair of complex roots z = x +/-
	epsilon i close to the real axis. */

	final double sqrtQ = Math.sqrt (Q);

	if (R > 0)
	{
	re_root[0] = -2 * sqrtQ - a3;
	re_root[1]=re_root[2]=sqrtQ - a3;
	im_root[0]=im_root[1]=im_root[2]=0;
	}
	else
	{
	re_root[0]=re_root[1] = -sqrtQ - a3;
	re_root[2]=2 * sqrtQ - a3;
	im_root[0]=im_root[1]=im_root[2]=0;
	}
	return 3;
	}
	else if (R2 < Q3)
	{
	final double sgnR = (R >= 0 ? 1 : -1);
	final double ratio = sgnR * Math.sqrt (R2 / Q3);
	final double theta = Math.acos (ratio);
	final double norm = -2 * Math.sqrt (Q);
	final double r0 = norm * Math.cos (theta/3) - a3;
	final double r1 = norm * Math.cos ((theta + 2.0 * Math.PI) / 3) - a3;
	final double r2 = norm * Math.cos ((theta - 2.0 * Math.PI) / 3) - a3;

	re_root[0]=r0;
	re_root[1]=r1;
	re_root[2]=r2;
	im_root[0]=im_root[1]=im_root[2]=0;
	return 3;
	}
	else
	{
	final double sgnR = (R >= 0 ? 1 : -1);
	final double A = -sgnR * Math.pow (Math.abs (R) + Math.sqrt (R2 - Q3), 1.0 / 3.0);
	final double B = Q / A;

	re_root[0]=A + B - a3;
	im_root[0]=0;
	re_root[1]=-0.5 * (A + B) - a3;
	im_root[1]=-(SQRT30.5) Math.abs(A - B);
	re_root[2]=re_root[1];
	im_root[2]=-im_root[1];
	return 3;
	}

	}


	static void root3a(final double [] p,final double [] re_root,final double [] im_root)
	{
	if(Math.abs(p[3])>EPS)
	{
	final double v=p[3],
	a=p[2]/v,b=p[1]/v,c=p[0]/v,
	a3=a/3,a3a=a3*a,
	pd3=(b-a3a)/3,
	qd2=a3(a3a/3-0.5b)+0.5*c,
	Q=pd3pd3pd3+qd2*qd2;
	if(Q<0)
	{
	// three real roots
	final double SQ=Math.sqrt(-Q);
	final double th=Math.atan2(SQ,-qd2);
	im_root[0]=im_root[1]=im_root[2]=0;
	final double f=2*Math.sqrt(-pd3);
	re_root[0]=f*Math.cos(th/3)-a3;
	re_root[1]=fMath.cos((th+2Math.PI)/3)-a3;
	re_root[2]=fMath.cos((th+4Math.PI)/3)-a3;
	//System.err.println("3r");
	}
	else
	{
	// one real & two complex roots
	final double SQ=Math.sqrt(Q);
	final double r1=-qd2+SQ,r2=-qd2-SQ;
	final double v1=Math.signum(r1)*Math.pow(Math.abs(r1),1.0/3),
	v2=Math.signum(r2)*Math.pow(Math.abs(r2),1.0/3),
	sv=v1+v2;
	// real root
	re_root[0]=sv-a3;
	im_root[0]=0;
	// complex roots
	re_root[1]=re_root[2]=-0.5*sv-a3;
	im_root[1]=(v1-v2)(SQRT30.5);
	im_root[2]=-im_root[1];
	//System.err.println("1r2c");
	}
	}
	else
	{
	re_root[0]=re_root[1]=re_root[2]=im_root[0]=im_root[1]=im_root[2]=Double.NaN;
	}
	}


	static void printSpecialValues()
	{
	for(int st=0;st<6;st++)
	{
	//final double [] p=new double []{8,1,3,3.6,1};
	final double [] re_root=new double [4],im_root=new double [4];
	final double [] p;
	final int n;
	if(st<=3)
	{
	if(st<=0)
	{
	p=new double []{2,-4,6,-4,1};
	//p=new double []{-6,6,-6,8,-2};
	}
	else if(st==1)
	{
	p=new double []{0,-4,8,3,-9};
	}
	else if(st==2)
	{
	p=new double []{-1,0,2,0,-1};
	}
	else
	{
	p=new double []{-5,2,8,-2,-3};
	}
	root4(p,re_root,im_root);
	n=4;
	}
	else
	{
	p=new double []{0,2,0,1};
	if(st==4)
	{
	p[1]=-p[1];
	}
	root3(p,re_root,im_root);
	n=3;
	}
	System.err.println("======== n="+n);
	for(int i=0;i<=n;i++)
	{
	if(i<n)
	{
	System.err.println(String.valueOf(i)+"\t"+
	p[i]+"\t"+
	re_root[i]+"\t"+
	im_root[i]);
	}
	else
	{
	System.err.println(String.valueOf(i)+"\t"+p[i]+"\t");
	}
	}
	}
	}



	public static void main(final String [] args)
	{
	if (System.getProperty("os.arch").equals("x86") \|\|
	System.getProperty("os.arch").equals("amd64") \|\|
	System.getProperty("os.arch").equals("x86_64")){
	final long t0=System.currentTimeMillis();
	final double eps=1e-6;
	//checkRoots();
	final java.util.Random r=new java.util.Random(-1381923);
	printSpecialValues();

	final int n_tests=100000;
	//testRoots(2,n_tests,r,eps);
	//testRoots(3,n_tests,r,eps);
	testRoots(4,n_tests,r,eps);
	final long t1=System.currentTimeMillis();
	System.err.println("PolynomialRoot.main: "+n_tests+" tests OK done in "+(t1-t0)+" milliseconds. ver=$Id: PolynomialRoot.java,v 1.105 2012/08/18 00:00:05 mal Exp $");
	System.out.println("PASSED");
	} else {
	System.out.println("PASS test for non-x86");
	}
	}



	}