static double
c_reader(int mu, int nu, const int pos[NDIM], int a, int b, int re_im, void *e)
{
int xm, xn, d;
for (d = 0, xm = 0; xm < NDIM; xm++) {
for (xn = xm + 1; xn < NDIM; xn++, d++) {
if ((xm == mu) && (xn == nu))
goto found;
}
}
return 0.0;
found:
{
QLA_Real xx;
QLA_ColorMatrix *m = QDP_expose_M(C[d]);
int n = QDP_node_number(pos);
int i = QDP_index(pos);
assert(n == self);
if (re_im == 0) {
QLA_r_eq_Re_c(xx, QLA_elem_M(m[i], a, b));
} else {
QLA_r_eq_Im_c(xx, QLA_elem_M(m[i], a, b));
}
QDP_reset_M(C[d]);
return xx;
}
}
static double
q_CL_f_reader(int mu, int nu, const int p[], int a, int b, int re_im, void *env)
{
QLA_D_Real xx;
QCArgs *args = env;
int i = QDP_index_L(args->lat, p);
int d, xm, xn;
for (d = 0, xm = 0; xm < QOP_CLOVER_DIM; xm++) {
for (xn = xm + 1; xn < QOP_CLOVER_DIM; xn++, d++) {
if ((xn == nu) && (xm == mu))
goto found;
}
}
return 0.0; /* should never happen */
found:
/* NB:m stores F * 8i */
if (re_im == 0) {
QLA_r_eq_Im_c(xx, QLA_elem_M(args->uf[Nu + d][i], a, b));
xx = xx / 8;
} else {
QLA_r_eq_Re_c(xx, QLA_elem_M(args->uf[Nu + d][i], a, b));
xx = -xx / 8;
}
return xx;
}
static void
su2_extract(NCPROT QLA_Real r[4], QLA_ColorMatrix(*m), int i, int j)
{
QLA_Complex *a00, *a01, *a10, *a11;
a00 = &QLA_elem_M(*m, i, i);
a01 = &QLA_elem_M(*m, i, j);
a10 = &QLA_elem_M(*m, j, i);
a11 = &QLA_elem_M(*m, j, j);
r[0] = QLA_real(*a00) + QLA_real(*a11);
r[1] = QLA_imag(*a01) + QLA_imag(*a10);
r[2] = QLA_real(*a01) - QLA_real(*a10);
r[3] = QLA_imag(*a00) - QLA_imag(*a11);
}
static double
u_reader(int dir, const int pos[NDIM], int a, int b, int re_im, void *e)
{
QLA_Real xx;
int n = QDP_node_number(pos);
int i = QDP_index(pos);
QLA_ColorMatrix *m = QDP_expose_M(U[dir]);
assert(n == self);
if (re_im == 0) {
QLA_r_eq_Re_c(xx, QLA_elem_M(m[i], a, b));
} else {
QLA_r_eq_Im_c(xx, QLA_elem_M(m[i], a, b));
}
QDP_reset_M(U[dir]);
return xx;
}
static double
q_CL_u_reader(int d, const int p[], int a, int b, int re_im, void *env)
{
QLA_D_Complex z;
QCArgs *args = env;
int i = QDP_index_L(args->lat, p);
if (p[d] == (args->lattice[d] - 1)) {
QLA_c_eq_c_times_c(z, args->bf[d], QLA_elem_M(args->uf[d][i], a, b));
} else {
QLA_c_eq_c(z, QLA_elem_M(args->uf[d][i], a, b));
}
if (re_im == 0)
return QLA_real(z);
else
return QLA_imag(z);
}
int
main(void)
{
QLA_ColorMatrix x, y, c, f, f2, yt;
for(int i=0; i<QLA_Nc; i++) {
for(int j=0; j<QLA_Nc; j++) {
QLA_c_eq_r_plus_ir(QLA_elem_M(x,i,j), i+1, QLA_Nc*(j+1));
QLA_c_eq_r_plus_ir(QLA_elem_M(c,i,j), QLA_Nc*(j+1), i-1);
//QLA_c_eq_r(QLA_elem_M(x,i,j), 0);
//QLA_c_eq_r(QLA_elem_M(c,i,j), 0);
}
QLA_c_eq_r_plus_ir(QLA_elem_M(x,i,i), 2+1, 1);
QLA_c_eq_r_plus_ir(QLA_elem_M(c,i,i), 0.1, 0.5);
}
QLA_M_eq_sqrt_M(&y, &x);
QLA_M_eq_Ma(&yt, &y);
//sqrt_deriv_site(&f, &y, &x, &c);
sylsolve_site(&f, &y, &y, &c);
printm(&x);
printm(&y);
printm(&c);
printm(&f);
QLA_ColorMatrix dx, dy;
for(int i=0; i<QLA_Nc; i++) {
for(int j=0; j<QLA_Nc; j++) {
QLA_Real eps = 1e-6;
QLA_M_eq_M(&dx, &x);
QLA_c_peq_r(QLA_elem_M(dx,i,j), eps);
QLA_M_eq_sqrt_M(&dy, &dx);
QLA_M_meq_M(&dy, &y);
QLA_Real ieps = 1/eps;
QLA_M_eq_r_times_M(&dy, &ieps, &dy);
//printm(&dy);
QLA_M_eq_M_times_Ma(&f2, &dy, &c);
QLA_Real r;
QLA_R_eq_re_trace_M(&r, &f2);
printf("%g\n", r);
}
}
// printm(&f2);
return 0;
}
void
printm(QLA_ColorMatrix *m)
{
for(int i=0; i<QLA_Nc; i++) {
for(int j=0; j<QLA_Nc; j++) {
QLA_Complex *z = &QLA_elem_M(*m,i,j);
printf("%10g%+10gi ", QLA_real(*z), QLA_imag(*z));
}
printf("\n");
}
}
void
set_M(QLA_ColorMatrix *m, int i)
{
for(int j=0; j<QLA_Nc; j++) {
for(int k=0; k<QLA_Nc; k++) {
QLA_c_eq_r_plus_ir(QLA_elem_M(*m,j,k),
(((j-k+QLA_Nc+1)*(j+k+1))%19)+cos(i),
(((j+4)*(k+1))%17)+sin(i));
}
}
}
static void
randforce(NCPROT QLA_ColorMatrix(*m), int i, void *args)
{
QLA_RandomState *s = (QLA_RandomState*)args + i;
QLA_Real s2 = 0.70710678118654752440; // sqrt(1/2)
QLA_Real s3 = 0.57735026918962576450; // sqrt(1/3)
QLA_Real r3 = s2*QLA_gaussian(s);
QLA_Real r8 = s2*s3*QLA_gaussian(s);
QLA_c_eq_r_plus_ir(QLA_elem_M(*m,0,0), 0, r3+r8);
QLA_c_eq_r_plus_ir(QLA_elem_M(*m,1,1), 0, -r3+r8);
QLA_c_eq_r_plus_ir(QLA_elem_M(*m,2,2), 0, -2*r8);
QLA_Real r01 = s2*QLA_gaussian(s);
QLA_Real r02 = s2*QLA_gaussian(s);
QLA_Real r12 = s2*QLA_gaussian(s);
QLA_Real i01 = s2*QLA_gaussian(s);
QLA_Real i02 = s2*QLA_gaussian(s);
QLA_Real i12 = s2*QLA_gaussian(s);
QLA_c_eq_r_plus_ir(QLA_elem_M(*m,0,1), r01, i01);
QLA_c_eq_r_plus_ir(QLA_elem_M(*m,1,0), -r01, i01);
QLA_c_eq_r_plus_ir(QLA_elem_M(*m,0,2), r02, i02);
QLA_c_eq_r_plus_ir(QLA_elem_M(*m,2,0), -r02, i02);
QLA_c_eq_r_plus_ir(QLA_elem_M(*m,1,2), r12, i12);
QLA_c_eq_r_plus_ir(QLA_elem_M(*m,2,1), -r12, i12);
}
static void
make_herm(NCPROT QLA_ColorMatrix(*m), int idx, void *args)
{
QLA_Complex tr;
QLA_c_eq_r(tr, 0);
for(int i=0; i<QLA_Nc; i++) {
for(int j=i; j<QLA_Nc; j++) {
QLA_Complex t1, t2;
QLA_c_eq_c(t1, QLA_elem_M(*m,i,j));
QLA_c_eq_c(t2, QLA_elem_M(*m,j,i));
QLA_c_peq_ca(t1, t2);
QLA_c_eq_r_times_c(t1, 0.5, t1);
QLA_c_eq_c(QLA_elem_M(*m,i,j), t1);
QLA_c_eq_ca(QLA_elem_M(*m,j,i), t1);
}
QLA_c_peq_c(tr, QLA_elem_M(*m,i,i));
}
QLA_c_eq_r_times_c(tr, 1./QLA_Nc, tr);
for(int i=0; i<QLA_Nc; i++) {
QLA_c_meq_c(QLA_elem_M(*m,i,i), tr);
}
}
/*
void
traceless_herm_M_evalues(QLA_ColorMatrix *Q, double *u, double *w,
double *q1, double *q2, double *q3) {
QLA_Complex c0, c1;
QLA_ColorMatrix Q2;
QLA_M_eq_M_times_M(&Q2, Q, Q);
printf("Q^2 = \n"); printm(&Q2);
QLA_C_eq_det_M (&c0, Q); // c0 = det(Q)
QLA_C_eq_trace_M (&c1, &Q2); // c1 = tr(Q^2)
double athird = 1.0/3.0;
double cc0, cc1, cc0max;
cc0 = QLA_real(c0);
cc1 = 0.5 * QLA_real(c1);
cc0max = 2*sqrt(cc1 * athird)*(cc1 * athird); //c_0^max = 2 * (c1/3)^{3/2}
printf("c0 = %f\n", cc0);
printf("c1 = %f\n", cc1);
printf("c0_max = %f\n", cc0max);
double theta;
theta =acos(cc0/cc0max);
*u = sqrt(athird * cc1) * cos(athird * theta);
*w = sqrt(cc1) * sin(athird * theta);
*q1 = 2 * *u;
*q2 = -*u + *w;
*q3 = -*u - *w;
printf("u = %f, w = %f, q1 = %f, q2 = %f, q3 = %f\n", *u, *w, *q1, *q2, *q3);
}
void
get_f_coeffs(QLA_ColorMatrix *Q, double _Complex *f0, double _Complex *f1, double _Complex *f2){
double u, w, q1, q2, q3;
traceless_herm_M_evalues(Q, &u, &w, &q1, &q2, &q3);
printf("q1=\n"); printc99(&q1);
double _Complex e2iu, e_iu;
e2iu = cexp(2 * _Complex_I * u);
e_iu = cexp(-1.0 * _Complex_I * u);
double u2 = u*u;
double w2 = w*w;
double _Complex zeta0w;
if (fabs(w) > 0.05) {
zeta0w = sin(w)/w;
}
else {
zeta0w = 1 - w2/6. * (1-w2/20. * (1 - w2/42.));
}
double _Complex h0, h1, h2;
h0 = (u2 - w2) * e2iu + e_iu * ( 8 * u2 *cos(w) + 2*_Complex_I*u * (3*u2+w2)*zeta0w);
h1 = 2*u*e2iu - e_iu * (2 * u * cos(w) - _Complex_I * (3*u2-w2)*zeta0w);
h2 = e2iu - e_iu * ( cos(w) + 3*_Complex_I*u * zeta0w);
double fac = 1.0/(9*u2-w2);
*f0 = h0 * fac;
*f1 = h1 * fac;
*f2 = h2 * fac;
}
void
get_Bs(QLA_ColorMatrix *Q, QLA_ColorMatrix *Q2, QLA_ColorMatrix *B1, QLA_ColorMatrix *B2, double _Complex *f0, double _Complex *f1, double _Complex *f2) {
double u, w, q1, q2, q3;
traceless_herm_M_evalues(Q, &u, &w, &q1, &q2, &q3);
printf("q1=\n"); printc99(&q1);
double _Complex e2iu, e_iu;
e2iu = cexp(2 * _Complex_I * u);
e_iu = cexp(-1.0 * _Complex_I * u);
double u2 = u*u;
double w2 = w*w;
double _Complex zeta0w, zeta1w;
if (fabs(w) > 0.05) {
zeta0w = sin(w)/w;
zeta1w = (cos(w)-zeta0w)/w2;
}
else {
zeta0w = 1 - w2/6. * (1-w2/20. * (1 - w2/42.));
zeta1w = -(1 - w2/10. * (1 - w2/28.*(1 - w2/54.)))/3.0;
}
double _Complex h0, h1, h2;
h0 = (u2 - w2) * e2iu + e_iu * ( 8 * u2 *cos(w) + 2*_Complex_I*u * (3*u2+w2)*zeta0w);
h1 = 2*u*e2iu - e_iu * (2 * u * cos(w) - _Complex_I * (3*u2-w2)*zeta0w);
h2 = e2iu - e_iu * ( cos(w) + 3*_Complex_I*u * zeta0w);
double fac = 1.0/(9*u2-w2);
*f0 = h0 * fac;
*f1 = h1 * fac;
*f2 = h2 * fac;
double _Complex r01, r11, r21, r02, r12, r22, iu;
double cosw = cos(w);
iu = _Complex_I * u;
r01 = 2*(u + _Complex_I * (u2 - w2)) * e2iu
+ 2 * e_iu * ( 4*u*(2 - iu) * cosw + _Complex_I * (9 * u2 + w2 - iu * (3*u2 + w2))*zeta0w);
r11 = 2*(1 + 2*iu) * e2iu
+ e_iu * ( -2 * (1-iu) * cosw + _Complex_I * (6*u + _Complex_I * (w2 - 3*u2)) * zeta0w);
r21 = 2 * _Complex_I * e2iu + _Complex_I * e_iu * (cosw - 3*(1-iu)*zeta0w);
r02 = -2 * e2iu + 2 * iu * e_iu * (cosw + (1+4*iu) * zeta0w + 3 * u2 * zeta1w);
r12 = -_Complex_I * e_iu * ( cosw + (1+2*iu) * zeta0w - 3*u2 * zeta1w);
r22 = e_iu * (zeta0w - 3 * iu * zeta1w);
double _Complex b10, b11, b12, b20, b21, b22;
double fac1, fac2, fac3;
double mult = 0.5 * fac * fac;
fac1 = 2 * u;
fac2 = 3*u2 - w2;
fac3 = 2*(15*u2+w2);
b10 = fac1 * r01 + fac2 * r02 - fac3 * (*f0);
b10 *= mult;
b11 = fac1 * r11 + fac2 * r12 - fac3 * (*f1);
b11 *= mult;
b12 = fac1 * r21 + fac2 * r22 - fac3 * (*f2);
b12 *= mult;
fac2 = 3*u;
fac3 = 24*u;
b20 = r01 - fac2 * r02 - fac3 * (*f0);
b20 *= mult;
b21 = r11 - fac2 * r12 - fac3 * (*f1);
b21 *= mult;
b22 = r21 - fac2 * r22 - fac3 * (*f2);
b22 *= mult;
QLA_Complex qb10, qb11, qb12, qb20, qb21, qb22;
QLA_c_eq_c99(qb10, b10);
QLA_c_eq_c99(qb11, b11);
QLA_c_eq_c99(qb12, b12);
QLA_c_eq_c99(qb20, b20);
QLA_c_eq_c99(qb21, b21);
QLA_c_eq_c99(qb22, b22);
QLA_M_eq_c(B1, &qb10);
QLA_M_peq_c_times_M(B1, &qb11, Q);
QLA_M_peq_c_times_M(B1, &qb12, Q2);
QLA_M_eq_c(B2, &qb20);
QLA_M_peq_c_times_M(B2, &qb21, Q);
QLA_M_peq_c_times_M(B2, &qb22, Q2);
}
*/
int
main(void) {
QLA_ColorMatrix O, iQ, matI;
QLA_M_eq_zero(&matI);
for(int i=0; i<QLA_Nc; i++) {
QLA_c_eq_r_plus_ir(QLA_elem_M(matI,i,i), 1.0, 0.0);
}
printm(&matI);
//QLA_Complex tr;
//QLA_Real half = 0.5;
for(int i=0; i<QLA_Nc; i++) {
for(int j=0; j<QLA_Nc; j++) {
QLA_c_eq_r_plus_ir(QLA_elem_M(O,i,j), i+1, QLA_Nc*(j+1));
}
QLA_c_eq_r_plus_ir(QLA_elem_M(O,i,i), 2+1, 1);
}
printm(&O);
#if QDP_Colors == 3
QLA_ColorMatrix A;
QLA_M_eq_zero(&A);
for ( int m = 0; m < QLA_Nc; m++) {
for ( int n = 0; n < QLA_Nc; n++) {
QLA_c_eq_r_plus_ir(QLA_elem_M(A, m, n), 3+m, 2-n);
}
QLA_c_eq_r_plus_ir(QLA_elem_M(A,m,m), 2+1, 1);
}
QLA_M_eq_antiherm_M(&A, &A);
printm(&A);
QLA_M_eq_zero(&A);
QLA_c_eq_r_plus_ir(QLA_elem_M(A,0,0),0,-1);
QLA_c_eq_r_plus_ir(QLA_elem_M(A,1,1),0,0.4);
QLA_c_eq_r_plus_ir(QLA_elem_M(A,2,2),0,0.6);
printm(&A);
QLA_Complex minus_i;
QLA_c_eq_r_plus_ir(minus_i, 0, -1);
QLA_ColorMatrix Q, Q2, expiQ, qla_expA;
QLA_M_eq_C_times_M(&Q, &minus_i, &matI);
QLA_M_eq_M_times_M(&Q2, &Q, &Q);
printf("Q=\n"); printm(&Q);
double _Complex f0, f1, f2;
QLA_ColorMatrix B1, B2;
get_Bs(&Q, &Q2, &B1, &B2, &f0, &f1, &f2);
printf("f0, f1, f2=\n");
printc99(&f0);
printc99(&f1);
printc99(&f2);
QLA_Complex qf0, qf1, qf2;
QLA_c_eq_c99(qf0, f0);
QLA_c_eq_c99(qf1, f1);
QLA_c_eq_c99(qf2, f2);
QLA_M_eq_c(&expiQ, &qf0);
QLA_M_peq_c_times_M(&expiQ, &qf1, &Q);
QLA_M_peq_c_times_M(&expiQ, &qf2, &Q2);
QLA_M_eq_exp_M(&qla_expA, &matI);
printf("my expiQ = \n");
printm(&expiQ);
printf("qla expA = \n");
printm(&qla_expA);
// derivative
QLA_Complex trB1M, trB2M;
QLA_ColorMatrix prod, deriv;
//tr(B_1 M)
QLA_M_eq_M_times_M (&prod, &B1, &matI); //B_1 M
QLA_C_eq_trace_M (&trB1M, &prod);
//tr(B_2 M);
QLA_M_eq_M_times_M (&prod, &B2, &matI); //B_2 M
QLA_C_eq_trace_M (&trB2M, &prod);
// deriv = Tr(B_1 M) Q
QLA_M_eq_c_times_M (&deriv, &trB1M, &Q);
// deriv += Tr(B_2 M) Q^2
QLA_M_peq_c_times_M (&deriv, &trB2M, &Q2);
// deriv += f1 M
QLA_M_peq_c_times_M (&deriv, &qf1, &matI);
// deriv += f2 Q M
QLA_M_eq_M_times_M (&prod, &Q, &matI); // Q M
QLA_M_peq_c_times_M (&deriv, &qf2, &prod);
// deriv += f2 M Q
QLA_M_eq_M_times_M (&prod, &matI, &Q); // M Q
QLA_M_peq_c_times_M (&deriv, &qf2, &prod);
QLA_M_eq_c_times_M (&deriv, &minus_i, &deriv);
printf("M = \n");
printm(&matI);
printf("deriv = \n");
printm(&deriv);
QLA_M_meq_M(&deriv, &expiQ);
printf("diff = \n");
printm(&deriv);
/*
printf("2/3f0 = \n");
f0 *= 2.0/3;
printc99(&f0);
printc(&qf0);
printc(&qf1);
printc(&qf2);
*/
#endif
#if QDP_Colors == 2
QLA_ColorMatrix expO;
QLA_Complex Tr, det;
QLA_c_eq_c_times_c(det, QLA_elem_M(O,0,0),QLA_elem_M(O,1,1));
QLA_c_meq_c_times_c(det, QLA_elem_M(O,0,1), QLA_elem_M(O,1,0));
QLA_C_eq_trace_M(&Tr, &O);
QLA_Complex qs, qt;
QLA_c_eq_r_times_c(qs, 0.5, Tr); // s=TrA/2
QLA_Complex qs2;
QLA_c_eq_c_times_c(qs2, qs, qs); //s2 = s^2
QLA_c_meq_c(qs2, det); //s2 = s^2 - detA
double _Complex t = QLA_real(qs2) + QLA_imag(qs2) * _Complex_I;
t = csqrt(t); // sqrt(s^2 - det A)
QLA_c_eq_r_plus_ir(qt, creal(t), cimag(t)); // t = sqrt(s^2 - det A)
printf(" Matrix O = \n"); printm(&O);
printf("TrO = "); printc(&Tr);
printf("detO = "); printc(&det);
printf("s = "); printc(&qs);
printf("t^2 = "); printc(&qs2);
printf("t = "); printc(&qt);
//use the QLA exp function
QLA_ColorMatrix qla_exp;
QLA_M_eq_exp_M(&qla_exp, &O); //exp(O)
double _Complex exps, cosht, sinht, sinht_t;
double _Complex s = QLA_real(qs) + QLA_imag(qs) * _Complex_I;
exps = cexp(s);
if(creal(t) == 0 && cimag(t) == 0) {
cosht = 1;
sinht = 0;
sinht_t = 1;
} else {
cosht = ccosh(t);
sinht = csinh(t);
sinht_t = sinht/t;
}
double _Complex f0, f1;
f1 = exps * sinht_t;
f0 = exps * cosht - s * f1;;
//derivative of the exponential
double _Complex f0s, f1s, f1t, f0t2, f1t2, t2;
t2 = t*t;
f0s = f0 - f1;
f1s = f1;
if (cabs(t) > 0.05) {
f1t = ((f0-f1) + s*f1)/t;
f1t2 = f1t/t;
}
else { //when |t| < 0.05, the error is O(10^{-14})
f1t = exps * t/3 * (1+t2/10*(1+t2/28));
f1t2 = exps / 3 * (1+t2/10*(1+t2/28));
}
// f0t = t * f1 - s * f1t;
f0t2 = f1 - s * f1t2;
printf("f0 = \n"); printc99(&f0);
printf("f1 = \n"); printc99(&f1);
printf("f0s = \n"); printc99(&f0s);
printf("f1s = \n"); printc99(&f1s);
printf("f1t = \n"); printc99(&f1t);
printf("f0t2 = \n"); printc99(&f0t2);
printf("f1t2 = \n"); printc99(&f1t2);
QLA_Complex qf0, qf1;
QLA_c_eq_r_plus_ir(qf0, creal(f0), cimag(f0));
QLA_c_eq_r_plus_ir(qf1, creal(f1), cimag(f1));
QLA_M_eq_c_times_M(&expO, &qf1, &O);
QLA_M_peq_c(&expO, &qf0);
printf("QLA exp = \n"); printm(&qla_exp);
printf("my expO = \n"); printm(&expO);
/*
QLA_Complex qf0s, qf0t, qf1s, qf1t;
QLA_c_eq_r_plus_ir(qf0s, creal(f0s), cimag(f0s));
QLA_c_eq_r_plus_ir(qf0t, creal(f0t), cimag(f0t));
QLA_c_eq_r_plus_ir(qf1s, creal(f1s), cimag(f1s));
QLA_c_eq_r_plus_ir(qf1t, creal(f1t), cimag(f1t));
*/
QLA_ColorMatrix deriv;
QLA_M_eq_zero(&deriv);
QLA_ColorMatrix B, AB;
QLA_M_eq_M(&B, &matI);
//QLA_c_eq_r_plus_ir(QLA_elem_M(B,1,0), 0.1, 0.2);
//QLA_c_eq_r_plus_ir(QLA_elem_M(B,0,1), 0.2, 0.1);
printf("B=\n"); printm(&B);
QLA_M_eq_M_times_M(&AB, &O, &B);
printf("AB=\n"); printm(&AB);
QLA_M_eq_c_times_M(&deriv, &qf1, &B); //f1 * B
printf("f1 B = \n"); printm(&deriv);
QLA_Complex trB, trAB;
QLA_C_eq_trace_M(&trB, &B);
QLA_C_eq_trace_M(&trAB, &AB);
double _Complex ctrB = QLA_real(trB) + _Complex_I * QLA_imag(trB);
double _Complex ctrAB = QLA_real(trAB) + _Complex_I * QLA_imag(trAB);
double _Complex coeff;
coeff = (f0s - f0t2 * s) * ctrB;
coeff += (f1s - f1t2 * s) * ctrAB;
coeff *= 0.5;
printf("coeff = "); printc99(&coeff);
QLA_Complex qc;
QLA_D_c_eq_c99(qc, coeff);
printc(&qc);
QLA_M_peq_c_times_M(&deriv, &qc, &matI); // f1 * B + () I
printf("f1B+()I=\n"); printm(&deriv);
coeff = 0.5 * (f0t2 * ctrB + f1t2 * ctrAB);
QLA_D_c_eq_c99(qc, coeff);
printc(&qc);
QLA_M_peq_c_times_M(&deriv, &qc, &O);
printm(&deriv);
exp_deriv_site(&deriv, &expO, &O, &B);
printm(&deriv);
#endif
return 0;
}
static void
hb_func(NCPROT1 QLA_ColorMatrix(*m), int site)
{
QLA_RandomState *srs = rs + site;
if(QLA_Nc==1) { // exp(-fac*Re[u*z]) = exp(-fac*|z|*cos(t))
// call Wensley heatbath
QLA_Complex cc;
QLA_Real r, phi, g, theta;
// *m contains r*exp(i*phi), extract r and phi
// extract QLA matrix element as complex number
QLA_c_eq_c(cc, QLA_elem_M(*m,0,0));
// get norm and arg
QLA_R_eq_norm_C( &r, &cc );
QLA_R_eq_arg_C( &phi, &cc );
g = fac*r;
// generate theta with probability P(theta)=exp( g*cos(theta) )
get_hb1( &theta, g, srs );
// convert to real and imag
//QLA_Real vr = cos( theta - phi );
//QLA_Real vi = sin( theta - phi );
// assemble QLA complex number and set QLA U(1) matrix to this
//QLA_c_eq_r_plus_i_r( QLA_elem_M(*m,0,0), vr, vi );
QLA_elem_M(*m,0,0) = QLAP(cexpi)(theta - phi);
} else {
QLA_ColorMatrix(s);
QLA_ColorMatrix(t);
QLA_ColorMatrix(tt);
QLA_Complex one;
QLA_c_eq_r(one, 1);
QLA_M_eq_c(&s, &one);
/* Loop over SU(2) subgroup index */
for(int i=0; i<QLA_Nc; i++) {
for(int j=i+1; j<QLA_Nc; j++) {
QLA_Real a[4], b[4], r[4], rn, rl;
su2_extract(NCARG r, m, i, j);
rn = sqrt( r[0]*r[0] + r[1]*r[1] + r[2]*r[2] + r[3]*r[3] );
rl = fac*rn;
if(rn<1e-10) {
a[0] = 1; a[1] = a[2] = a[3] = 0;
} else {
rn = 1/rn;
a[0] = rn*r[0];
a[1] = -rn*r[1];
a[2] = -rn*r[2];
a[3] = -rn*r[3];
}
get_hb2(b, rl, srs);
//b[0] = 1; b[1] = b[2] = b[3] = 0;
r[0] = b[0]*a[0] - b[1]*a[1] - b[2]*a[2] - b[3]*a[3];
r[1] = b[0]*a[1] + b[1]*a[0] - b[2]*a[3] + b[3]*a[2];
r[2] = b[0]*a[2] + b[2]*a[0] - b[3]*a[1] + b[1]*a[3];
r[3] = b[0]*a[3] + b[3]*a[0] - b[1]*a[2] + b[2]*a[1];
su2_fill(NCARG &t, r, i, j);
QLA_M_eq_M_times_M(&tt, &t, &s);
QLA_M_eq_M(&s, &tt);
QLA_M_eq_M_times_M(&tt, &t, m);
QLA_M_eq_M(m, &tt);
}
}
QLA_M_eq_M(m, &s);
}
}
int
main(void) {
QLA_ColorMatrix O, iQ, tmp, matI;
QLA_M_eq_zero(&matI);
for(int i=0; i<QLA_Nc; i++) {
QLA_c_eq_r_plus_ir(QLA_elem_M(matI,i,i), 1.0, 0.0);
}
printm(&matI);
QLA_Complex tr;
QLA_Real half = 0.5;
for(int i=0; i<QLA_Nc; i++) {
for(int j=0; j<QLA_Nc; j++) {
QLA_c_eq_r_plus_ir(QLA_elem_M(O,i,j), i+1, QLA_Nc*(j+1));
}
QLA_c_eq_r_plus_ir(QLA_elem_M(O,i,i), 2+1, 1);
}
#if QDP_Colors == 3
QLA_Complex ci;
QLA_c_eq_r_plus_ir(ci, 0, 1);
//use my own implementation
QLA_ColorMatrix expiQ;
QLA_ColorMatrix QQ;
QLA_ColorMatrix QQQ;
QLA_M_eq_M_times_M(&QQ, &iQ, &iQ); //-Q^2
QLA_M_eq_M_times_M(&QQQ, &QQ, &iQ); //-iQ^3
QLA_M_eq_c_times_M(&QQQ, &ci, &QQQ); //Q^3
QLA_Complex c0, c1;
QLA_C_eq_trace_M(&c0, &QQQ);
QLA_c_eq_r_times_c(c0, 0.3333333, c0);
QLA_C_eq_trace_M(&c1, &QQ);
QLA_c_eq_r_times_c(c1, -0.5, c1);
double _Complex tf0, tf1, tf2;
getfs(&tf0, &tf1, &tf2, QLA_real(c0), QLA_real(c1));
QLA_Complex f0, f1, f2;
f0 = tf0;
f1 = tf1;
f2 = tf2;
printm(&O);
printf("iQ = \n");
printm(&iQ);
printf("QLA: exp(iQ) = \n");
printm(&qla_exp);
printf("Q^3 = \n");
printm(&QQQ);
printf("c0 = "); printc(&c0);
printf("c1 = "); printc(&c1);
#endif
#if QDP_Colors == 2
QLA_ColorMatrix expO;
QLA_Complex Tr, det;
QLA_c_eq_c_times_c(det, QLA_elem_M(O,0,0),QLA_elem_M(O,1,1));
QLA_c_meq_c_times_c(det, QLA_elem_M(O,0,1), QLA_elem_M(O,1,0));
QLA_C_eq_trace_M(&Tr, &O);
QLA_Complex s, t;
QLA_c_eq_r_times_c(s, 0.5, Tr); // s=TrA/2
QLA_Complex s2;
QLA_c_eq_c_times_c(s2, s, s); //s2 = s^2
QLA_c_meq_c(s2, det); //s2 = s^2 - detA
double _Complex dc_t = QLA_real(s2) + QLA_imag(s2) * _Complex_I;
dc_t = csqrt(dc_t); // sqrt(s^2 - det A)
QLA_c_eq_r_plus_ir(t, creal(dc_t), cimag(dc_t)); // t = sqrt(s^2 - det A)
printf(" Matrix O = \n"); printm(&O);
printf("TrO = "); printc(&Tr);
printf("detO = "); printc(&det);
printf("s = "); printc(&s);
printf("t^2 = "); printc(&s2);
printf("t = "); printc(&t);
//use the QLA exp function
QLA_ColorMatrix qla_exp;
QLA_M_eq_exp_M(&qla_exp, &O); //exp(O)
double _Complex cosht, sinht, sinht_t;
if(QLA_real(t) == 0 && QLA_imag(t) == 0) {
cosht = 1;
sinht = 0;
sinht_t = 1;
} else {
cosht = ccosh(dc_t);
sinht = csinh(dc_t);
sinht_t = sinht/dc_t;
}
double _Complex dc_s = QLA_real(s) + QLA_imag(s) * _Complex_I;
double _Complex dc_f0, dc_f1;
dc_f0 = cexp(dc_s) * (cosht - dc_s * sinht_t);
dc_f1 = cexp(dc_s) * sinht_t;
QLA_Complex f0, f1;
QLA_c_eq_r_plus_ir(f0, creal(dc_f0), cimag(dc_f0));
QLA_c_eq_r_plus_ir(f1, creal(dc_f1), cimag(dc_f1));
QLA_M_eq_c_times_M(&expO, &f1, &O);
QLA_M_peq_c(&expO, &f0);
printf("QLA exp = \n"); printm(&qla_exp);
printf("my expO = \n"); printm(&expO);
#endif
return 0;
}
void
set_M(QLA_ColorMatrix *m, int i)
{
#if 0
static QLA_ColorMatrix t;
for(int j=0; j<QLA_Nc; j++) {
for(int k=0; k<QLA_Nc; k++) {
QLA_c_eq_r_plus_ir(QLA_elem_M(*m,j,k),
(((j-k+QLA_Nc+1)*(j+k+1))%19)+cos(i),
(((j+4)*(k+1))%17)+sin(i));
//QLA_real(QLA_elem_M(*m,j,k)) = 1;
//QLA_imag(QLA_elem_M(*m,j,k)) = 0;
}
}
#endif
for(int j=0; j<QLA_Nc; j++) {
for(int k=0; k<QLA_Nc; k++) {
QLA_c_eq_r(QLA_elem_M(*m,j,k), 0);
}
}
QLA_Real step = 1e-5;
if(Mtype&MtypeNZ) {
for(int j=0; j<QLA_Nc; j++) {
QLA_c_peq_r_plus_ir(QLA_elem_M(*m,j,j), step, -step);
}
}
int ii=i;
if((Mtype&MtypeNN)==0) ii>>=QLA_Nc;
for(int j=0,k=1; ii; ii>>=1,j++) {
if(j>=QLA_Nc) { j=0; k*=2; }
if(ii&1) QLA_c_peq_r_plus_ir(QLA_elem_M(*m,j,j), k*step, -k*step);
}
ii = i;
if((Mtype&MtypeNN)==0) {
for(int j=0; j<QLA_Nc; j++) {
if(ii&1) QLA_c_eqm_c(QLA_elem_M(*m,j,j), QLA_elem_M(*m,j,j));
ii >>= 1;
}
}
if(Mtype&MtypeH) { // make Hermitian
QLA_ColorMatrix m2;
QLA_M_eq_M(&m2, m);
QLA_M_peq_Ma(&m2, m);
QLA_M_eq_M(m, &m2);
}
if((Mtype&MtypeP)&&(Mtype&MtypeH)) { // make positive Hermitian
QLA_ColorMatrix m2;
QLA_M_eq_M_times_Ma(&m2, m, m);
QLA_M_eq_M(m, &m2);
}
if(Mtype&MtypeA) { // make anti-Hermitian
QLA_ColorMatrix m2;
QLA_M_eq_M(&m2, m);
QLA_M_meq_Ma(&m2, m);
QLA_M_eq_M(m, &m2);
}
if((Mtype&MtypeT)&&(Mtype&MtypeA)) { // make traceless anti-Hermitian
QLA_ColorMatrix m2;
QLA_M_eq_antiherm_M(&m2, m);
QLA_M_eq_M(m, &m2);
}
//QLA_Real n2;
//QLA_r_eq_norm2_M(&n2, m);
//printf("%i\t%g\n", i, n2);
}
