//=============================================================================
void zggev_check_value()
{
cout << "############ check zggev value ############" << endl;
srand(time(NULL));
int M(3);
//// make zgematrix A and B ////
CPPL::zgematrix A(M,M), B(M,M);
for(int i=0; i<A.m; i++){ for(int j=0; j<A.n; j++){
A(i,j) =complex<double>(rand()/(RAND_MAX/10), rand()/(RAND_MAX/10));
B(i,j) =complex<double>(rand()/(RAND_MAX/10), rand()/(RAND_MAX/10));
}}
//// make wr wi vr ////
vector< complex<double> > w;
//// make A_original and B_original ////
CPPL::zgematrix A_original(A);
CPPL::zgematrix B_original(B);
//// zggev ////
A.zggev(w);
//// print ////
cout << "A_original=\n" << A_original << endl;
cout << "B_original=\n" << B_original << endl;
for(int i=0; i<A.m; i++){
cout << "#### " << i << "th eigen ####" << endl;
cout << "wr=" << wr[i] <<endl;
cout << "wi=" << wi[i] <<endl;
}
}
//=============================================================================
void zggev_check_right()
{
cout << "############ check zggev right ############" << endl;
srand(time(NULL));
int M(3);
//// make zgematrix A and B ////
CPPL::zgematrix A(M,M), B(M,M);
for(int i=0; i<A.m; i++){ for(int j=0; j<A.n; j++){
A(i,j) =complex<double>(rand()/(RAND_MAX/10), rand()/(RAND_MAX/10));
B(i,j) =complex<double>(rand()/(RAND_MAX/10), rand()/(RAND_MAX/10));
}}
//// make wr wi vr ////
vector<double> wr, wi;
vector<CPPL::dcovector> vrr, vri;
//// make A_original and B_original ////
CPPL::zgematrix A_original(A);
CPPL::zgematrix B_original(B);
//// zggev ////
A.zggev(B, wr, wi ,vrr, vri);
//// print ////
cout << "A_original=\n" << A_original << endl;
cout << "B_original=\n" << B_original << endl;
for(int i=0; i<A.m; i++){
cout << "#### " << i << "th eigen ####" << endl;
cout << "wr=" << wr[i] <<endl;
cout << "wi=" << wi[i] <<endl;
cout << "vrr=\n" << vrr[i] <<endl;
cout << "vri=\n" << vri[i] <<endl;
cout << "Real[ [A]*{x} -lambda*[B]*{x} ] = (Should be zeros)\n"
<< A_original*vrr[i]
-(wr[i]*B_original*vrr[i] - wi[i]*B_original*vri[i])
<< endl;
cout << "Imag[ [A]*{x} -lambda*[B]*{x} ] = (Should be zeros)\n"
<< A_original*vri[i]
-(wr[i]*B_original*vri[i] + wi[i]*B_original*vrr[i])
<< endl;
}
}
//=============================================================================
void zggev_check_left()
{
cout << "############ check zggev left ############" << endl;
srand(time(NULL));
int M(3);
//// make zgematrix A and B ////
CPPL::zgematrix A(M,M), B(M,M);
for(int i=0; i<A.m; i++){ for(int j=0; j<A.n; j++){
A(i,j) =complex<double>(rand()/(RAND_MAX/10), rand()/(RAND_MAX/10));
B(i,j) =complex<double>(rand()/(RAND_MAX/10), rand()/(RAND_MAX/10));
}}
//// make wr wi vl ////
vector<double> wr, wi;
vector<CPPL::drovector> vlr, vli;
//// make A_original and B_original ////
CPPL::zgematrix A_original(A);
CPPL::zgematrix B_original(B);
//// zggev ////
A.zggev(B, wr, wi ,vlr, vli);
//// print ////
cout << "A_original=\n" << A_original << endl;
cout << "B_original=\n" << B_original << endl;
for(int i=0; i<A.m; i++){
cout << "#### " << i << "th eigen ####" << endl;
cout << "wr = " << wr[i] << endl;
cout << "wi = " << wi[i] << endl;
cout << "vlr = " << vlr[i];
cout << "vli = " << vli[i] << endl;
cout << "Real[ {x}*[A] -lambda*{x}*[B] ] = (Should be zeros)\n"
<< vlr[i]*A_original
-(wr[i]*vlr[i]*B_original - wi[i]*vli[i]*B_original)
<< endl;
cout << "Imag[ [A]*{x} -lambda*{x}*[B] ] = (Should be zeros)\n"
<< vli[i]*A_original
-(wr[i]*vli[i]*B_original + wi[i]*vlr[i]*B_original)
<< endl;
}
}
