static void aten_read_block( PIA *pi, char * buf, int count )
{ int k, a, b, c, d;
switch (pi->mode) {
case 0: w0(0x48); w2(0xe); w2(6);
for (k=0;k<count/2;k++) {
w2(7); w2(6); w2(2);
a = r1(); w0(0x58); b = r1();
w2(0); d = r1(); w0(0x48); c = r1();
buf[2*k] = j44(c,d);
buf[2*k+1] = j44(a,b);
}
w2(0xc);
break;
case 1: w0(0x58); w2(0xe); w2(6);
for (k=0;k<count/2;k++) {
w2(0x27); w2(0x26); w2(0x22);
a = r0(); w2(0x20); b = r0();
buf[2*k] = b; buf[2*k+1] = a;
}
w2(0x26); w2(0xc);
break;
}
}
SEXP kx_r_execute_with_params(SEXP connection, SEXP query, SEXP param)
{
K result;
SEXP s;
kx_connection = INTEGER_VALUE(connection);
int i, n = length(param);
K vector = ktn(KF,n);
for (i = 0; i < n; i++) {
kF(vector)[i] = REAL(param)[i];
}
result = k(kx_connection, (char*) CHARACTER_VALUE(query), vector, (K)0);
if (0 == result) {
error("Error: not connected to kdb+ server\n");
}
else if (-128 == result->t) {
char *e = calloc(strlen(result->s) + 1, 1);
strcpy(e, result->s);
r0(result);
error("Error from kdb+: `%s\n", e);
}
s = from_any_kobject(result);
r0(result);
return s;
}
KDB_API K K_DECL testSerial(K a) {
K k = kpn("000001.SZ", 9);
//K s = b9(-1, k);
K s = b9(1, k);
for (G* i = kG(s); i < kG(s) + s->n; ++i) {
std::cout << std::setiosflags(std::ios::uppercase) << std::setfill('0') << std::setw(2)
<< std::hex << static_cast<int>(*i) << ',';
}
std::cout << std::endl;
# if KX_HAS_OKX
std::cout << "okx = " << okx(s) << std::endl;
# endif
if (a->g) {
r0(s);
return k;
}
else {
r0(k);
return s;
}
}
K recieve_data(I x)
{
static char buf[BUFFER_SIZE];
read_bytes(sizeof(int), &buf);
int tnamesize = 0;
memcpy(&tnamesize, buf, sizeof(int));
read_bytes(tnamesize, &buf);
buf[tnamesize] = '\0';
K tname = ks(buf);
read_bytes(sizeof(J), &buf);
J size = 0;
memcpy(&size, buf, sizeof(J));
read_bytes(size, &buf);
K bytes = ktn(KG, size);
memcpy(kG(bytes), &buf, (size_t) size);
K result = k(0, ".u.upd", tname, d9(bytes), (K) 0);
r0(bytes);
if (result != 0) {
r0(result);
}
return (K) 0;
}
void Dirac_DomainWall_4D::
BprojCore_dag(double* f1,double* fN,const double* f) const{
// f1 = f5(0), fN = f5(N5_-1)
for(int c=0; c<NC_; ++c){
double fup_r = 0.5*(f[r0(c)] +f[r2(c)]);
double fup_i = 0.5*(f[i0(c)] +f[i2(c)]);
double fdn_r = 0.5*(f[r1(c)] +f[r3(c)]);
double fdn_i = 0.5*(f[i1(c)] +f[i3(c)]);
fN[r0(c)] = fup_r; fN[i0(c)] = fup_i;
fN[r1(c)] = fdn_r; fN[i1(c)] = fdn_i;
fN[r2(c)] = fup_r; fN[i2(c)] = fup_i;
fN[r3(c)] = fdn_r; fN[i3(c)] = fdn_i;
fup_r -= f[r2(c)]; //0.5*(f[r0(c)] -f[r2(c)])
fup_i -= f[i2(c)]; //0.5*(f[i0(c)] -f[i2(c)])
fdn_r -= f[r3(c)]; //0.5*(f[r1(c)] -f[r3(c)])
fdn_i -= f[i3(c)]; //0.5*(f[i1(c)] -f[i3(c)])
f1[r0(c)] = fup_r; f1[i0(c)] = fup_i;
f1[r1(c)] = fdn_r; f1[i1(c)] = fdn_i;
f1[r2(c)] =-fup_r; f1[i2(c)] =-fup_i;
f1[r3(c)] =-fdn_r; f1[i3(c)] =-fdn_i;
}
}
int main(int argc,char*argv[])
{
K flip,result,columnNames,columnData;
int row,col,nCols,nRows;
int handle=khpu("localhost",1234,"user:password");
if(handle<0) exit(1);
result = k(handle,"`asc",(K)0);
std::string str = "([]a:til 10;b:reverse til 10;c:10#01010101010b;d:`a)";
result = k(handle,str.c_str(),(K)0);
if(!result) printf("Network Error\n"),perror("Network"),exit(1);
if(result->t==-128) printf("Server Error %s\n",result->s),kclose(handle),exit(1);
// kclose(handle);
if(result->t!=99&&result->t!=98)
{
printf("type %d\n",result->t);
r0(result);
exit(1);
}
flip = ktd(result); // if keyed table, unkey it. ktd decrements ref count of arg.
// table (flip) is column names!list of columns (data)
columnNames = kK(flip->k)[0];
columnData = kK(flip->k)[1];
nCols = columnNames->n;
nRows = kK(columnData)[0]->n;
for(row=0;row<nRows;row++)
{
if(0==row)
{
for(col=0;col<nCols;col++)
{
if(col>0)printf(",");
printf("%s",kS(columnNames)[col]);
}
printf("\n");
}
for(col=0;col<nCols;col++)
{
K obj=kK(columnData)[col];
if(col>0)printf(",");
switch(obj->t)
{
case(1):{printf("%d",kG(obj)[row]);}break;
case(4):{printf("%d",kG(obj)[row]);}break;
case(5):{printf("%d",kH(obj)[row]);}break;
case(6):{printf("%d",kI(obj)[row]);}break;
case(7):{printf("%lld",kJ(obj)[row]);}break;
case(8):{printf("%f",kE(obj)[row]);}break;
case(9):{printf("%f",kF(obj)[row]);}break;
case(11):{printf("%s",kS(obj)[row]);}break;
default:{printf("unknown type");}break;
}
}
printf("\n");
}
r0(flip);
return 0;
}
void DiracWilsonLike::gamma5core(double* w,const double* f)const{
for(int c=0; c<N; ++c){
w[r0(c)] = f[r2(c)]; w[i0(c)] = f[i2(c)];
w[r1(c)] = f[r3(c)]; w[i1(c)] = f[i3(c)];
w[r2(c)] = f[r0(c)]; w[i2(c)] = f[i0(c)];
w[r3(c)] = f[r1(c)]; w[i3(c)] = f[i1(c)];
}
}
void GammaMatrix::isigma24core(double* w,const double* f)const{
for(int c=0; c<Ncol_; ++c){
w[r0(c)] = f[r3(c)]; w[i0(c)] = f[i3(c)];
w[r1(c)] =-f[r2(c)]; w[i1(c)] =-f[i2(c)];
w[r2(c)] = f[r1(c)]; w[i2(c)] = f[i1(c)];
w[r3(c)] =-f[r0(c)]; w[i3(c)] =-f[i0(c)];
}
}
static void kbic_read_block( PIA *pi, char * buf, int count )
{ int k, a, b;
switch (pi->mode) {
case 0: w0(0x98); w2(4); w2(6); w2(4);
for (k=0;k<count/2;k++) {
w2(1); w0(8); a = r1();
w0(0x28); b = r1();
buf[2*k] = j44(a,b);
w2(5); b = r1();
w0(8); a = r1();
buf[2*k+1] = j44(a,b);
w2(4);
}
break;
case 1: w0(0xb8); w2(4); w2(6); w2(4);
for (k=0;k<count/4;k++) {
w0(0xb8);
w2(4); w2(5);
w0(8); buf[4*k] = j53(r12w());
w0(0xb8); buf[4*k+1] = j53(r12w());
w2(4); w2(5);
buf[4*k+3] = j53(r12w());
w0(8); buf[4*k+2] = j53(r12w());
}
w2(4);
break;
case 2: w0(0x88); w2(4); w2(6); w2(4);
for (k=0;k<count/2;k++) {
w2(0xa0); w2(0xa1); buf[2*k] = r0();
w2(0xa5); buf[2*k+1] = r0();
}
w2(4);
break;
case 3: w0(0xa0); w2(4); w2(6); w2(4); w3(0);
for (k=0;k<count;k++) buf[k] = r4();
w2(4); w2(0); w2(4);
break;
case 4: w0(0xa0); w2(4); w2(6); w2(4); w3(0);
for (k=0;k<count/2;k++) ((u16 *)buf)[k] = r4w();
w2(4); w2(0); w2(4);
break;
case 5: w0(0xa0); w2(4); w2(6); w2(4); w3(0);
for (k=0;k<count/4;k++) ((u32 *)buf)[k] = r4l();
w2(4); w2(0); w2(4);
break;
}
}
void GammaMatrix::projMcore(double* w,const double* f)const{
for(int c=0; c<Ncol_; ++c){
double fup_r = 0.5*(f[r0(c)] -f[r2(c)]);
double fup_i = 0.5*(f[i0(c)] -f[i2(c)]);
double fdn_r = 0.5*(f[r1(c)] -f[r3(c)]);
double fdn_i = 0.5*(f[i1(c)] -f[i3(c)]);
w[r0(c)] = fup_r; w[i0(c)] = fup_i;
w[r1(c)] = fdn_r; w[i1(c)] = fdn_i;
w[r2(c)] =-fup_r; w[i2(c)] =-fup_i;
w[r3(c)] =-fdn_r; w[i3(c)] =-fdn_i;
}
}
void DiracWilsonLike::projMcore(double* w,const double* f)const{
for(int c=0; c<N; ++c){
double fup_r = 0.5*(f[r0(c)] -f[r2(c)]);
double fup_i = 0.5*(f[i0(c)] -f[i2(c)]);
double fdn_r = 0.5*(f[r1(c)] -f[r3(c)]);
double fdn_i = 0.5*(f[i1(c)] -f[i3(c)]);
w[r0(c)] = fup_r; w[i0(c)] = fup_i;
w[r1(c)] = fdn_r; w[i1(c)] = fdn_i;
w[r2(c)] =-fup_r; w[i2(c)] =-fup_i;
w[r3(c)] =-fdn_r; w[i3(c)] =-fdn_i;
}
}
static void on26_read_block( PIA *pi, char * buf, int count )
{ int k, a, b;
switch (pi->mode) {
case 0: w0(1); P1; w0(1); P2; w0(2); P1; w0(0x18); P2; w0(0); P1;
udelay(10);
for (k=0;k<count;k++) {
w2(6); a = r1();
w2(4); b = r1();
buf[k] = j44(a,b);
}
w0(2); P1; w0(8); P2;
break;
case 1: w0(1); P1; w0(1); P2; w0(2); P1; w0(0x19); P2; w0(0); P1;
udelay(10);
for (k=0;k<count/2;k++) {
w2(0x26); buf[2*k] = r0();
w2(0x24); buf[2*k+1] = r0();
}
w0(2); P1; w0(9); P2;
break;
case 2: w3(1); w3(1); w2(5); w4(1); w2(4);
w3(0); w3(0); w2(0x24);
udelay(10);
for (k=0;k<count;k++) buf[k] = r4();
w2(4);
break;
case 3: w3(1); w3(1); w2(5); w4(1); w2(4);
w3(0); w3(0); w2(0x24);
udelay(10);
for (k=0;k<count/2;k++) ((u16 *)buf)[k] = r4w();
w2(4);
break;
case 4: w3(1); w3(1); w2(5); w4(1); w2(4);
w3(0); w3(0); w2(0x24);
udelay(10);
for (k=0;k<count/4;k++) ((u32 *)buf)[k] = r4l();
w2(4);
break;
}
}
static int epat_read_regr( PIA *pi, int cont, int regr )
{ int a, b, r;
r = regr + cont_map[cont];
switch (pi->mode) {
case 0: w0(r); w2(1); w2(3);
a = r1(); w2(4); b = r1();
return j44(a,b);
case 1: w0(0x40+r); w2(1); w2(4);
a = r1(); b = r2(); w0(0xff);
return j53(a,b);
case 2: w0(0x20+r); w2(1); w2(0x25);
a = r0(); w2(4);
return a;
case 3:
case 4:
case 5: w3(r); w2(0x24); a = r4(); w2(4);
return a;
}
return -1; /* never gets here */
}
static void epat_connect ( PIA *pi )
{ pi->saved_r0 = r0();
pi->saved_r2 = r2();
/* Initialize the chip */
CPP(0);
if (epatc8) {
CPP(0x40);CPP(0xe0);
w0(0);w2(1);w2(4);
WR(0x8,0x12);WR(0xc,0x14);WR(0x12,0x10);
WR(0xe,0xf);WR(0xf,4);
/* WR(0xe,0xa);WR(0xf,4); */
WR(0xe,0xd);WR(0xf,0);
/* CPP(0x30); */
}
/* Connect to the chip */
CPP(0xe0);
w0(0);w2(1);w2(4); /* Idle into SPP */
if (pi->mode >= 3) {
w0(0);w2(1);w2(4);w2(0xc);
/* Request EPP */
w0(0x40);w2(6);w2(7);w2(4);w2(0xc);w2(4);
}
if (!epatc8) {
WR(8,0x10); WR(0xc,0x14); WR(0xa,0x38); WR(0x12,0x10);
}
}
static void epat_connect ( PIA *pi )
{ pi->saved_r0 = r0();
pi->saved_r2 = r2();
#ifdef CONFIG_PARIDE_EPATC8
/* Initialize the chip */
CPP(0);CPP(0x40);CPP(0xe0);
w0(0);w2(1);w2(4);
WR(0x8,0x12);WR(0xc,0x14);WR(0x12,0x10);
WR(0xe,0xf);WR(0xf,4);
/* WR(0xe,0xa);WR(0xf,4); */
WR(0xe,0xd);WR(0xf,0);
/* CPP(0x30); */
/* Connect to the chip */
CPP(0xe0);
w0(0);w2(1);w2(4); /* Idle into SPP */
if (pi->mode >= 3) {
w0(0);w2(1);w2(4);w2(0xc);
/* Request EPP */
w0(0x40);w2(6);w2(7);w2(4);w2(0xc);w2(4);
}
#else
CPP(0); CPP(0xe0);
w0(0); w2(1); w2(4);
if (pi->mode >= 3) {
w0(0); w2(1); w2(4); w2(0xc);
w0(0x40); w2(6); w2(7); w2(4); w2(0xc); w2(4);
}
WR(8,0x10); WR(0xc,0x14); WR(0xa,0x38); WR(0x12,0x10);
#endif
}
static int comm_read_regr( PIA *pi, int cont, int regr )
{ int l, h, r;
r = regr + cont_map[cont];
switch (pi->mode) {
case 0: w0(r); P1; w0(0);
w2(6); l = r1(); w0(0x80); h = r1(); w2(4);
return j44(l,h);
case 1: w0(r+0x20); P1;
w0(0); w2(0x26); h = r0(); w2(4);
return h;
case 2:
case 3:
case 4: w3(r+0x20); (void)r1();
w2(0x24); h = r4(); w2(4);
return h;
}
return -1;
}
static int kbic_read_regr( PIA *pi, int cont, int regr )
{ int a, b, s;
s = cont_map[cont];
switch (pi->mode) {
case 0: w0(regr|0x18|s); w2(4); w2(6); w2(4); w2(1); w0(8);
a = r1(); w0(0x28); b = r1(); w2(4);
return j44(a,b);
case 1: w0(regr|0x38|s); w2(4); w2(6); w2(4); w2(5); w0(8);
a = r12w(); w2(4);
return j53(a);
case 2: w0(regr|0x08|s); w2(4); w2(6); w2(4); w2(0xa5); w2(0xa1);
a = r0(); w2(4);
return a;
case 3:
case 4:
case 5: w0(0x20|s); w2(4); w2(6); w2(4); w3(regr);
a = r4(); b = r4(); w2(4); w2(0); w2(4);
return a;
}
return -1;
}
/*
* Make the matrix orthonormal in place using an iterative method.
* It is potentially slower if the matrix is far from orthonormal (i.e. if
* the row basis vectors are close to colinear) but in the common case
* of near-orthonormality it should be just as fast.
*
* The translation part is left intact. If the translation is represented as
* a homogenous coordinate (i.e. a non-unity lower right corner), it is divided
* out.
*/
bool
GfMatrix4f::Orthonormalize(bool issueWarning)
{
// orthogonalize and normalize row vectors
GfVec3d r0(_mtx[0][0],_mtx[0][1],_mtx[0][2]);
GfVec3d r1(_mtx[1][0],_mtx[1][1],_mtx[1][2]);
GfVec3d r2(_mtx[2][0],_mtx[2][1],_mtx[2][2]);
bool result = GfVec3d::OrthogonalizeBasis(&r0, &r1, &r2, true);
_mtx[0][0] = r0[0];
_mtx[0][1] = r0[1];
_mtx[0][2] = r0[2];
_mtx[1][0] = r1[0];
_mtx[1][1] = r1[1];
_mtx[1][2] = r1[2];
_mtx[2][0] = r2[0];
_mtx[2][1] = r2[1];
_mtx[2][2] = r2[2];
// divide out any homogeneous coordinate - unless it's zero
if (_mtx[3][3] != 1.0 && !GfIsClose(_mtx[3][3], 0.0, GF_MIN_VECTOR_LENGTH))
{
_mtx[3][0] /= _mtx[3][3];
_mtx[3][1] /= _mtx[3][3];
_mtx[3][2] /= _mtx[3][3];
_mtx[3][3] = 1.0;
}
if (!result && issueWarning)
TF_WARN("OrthogonalizeBasis did not converge, matrix may not be "
"orthonormal.");
return result;
}
void MSNewton::Fixed::submit_constraints(const NewtonJoint* joint, dgFloat32 timestep, int thread_index) {
JointData* joint_data = (JointData*)NewtonJointGetUserData(joint);
// Calculate position of pivot points and Jacobian direction vectors in global space.
dMatrix matrix0, matrix1, matrix2;
MSNewton::Joint::c_calculate_global_matrix(joint_data, matrix0, matrix1, matrix2);
const dVector& p0 = matrix0.m_posit;
const dVector& p1 = matrix1.m_posit;
// Get a point along the pin axis at some reasonable large distance from the pivot.
dVector q0(p0 + matrix0.m_right.Scale(MIN_JOINT_PIN_LENGTH));
dVector q1(p1 + matrix1.m_right.Scale(MIN_JOINT_PIN_LENGTH));
// Get the ankle point.
dVector r0(p0 + matrix0.m_front.Scale(MIN_JOINT_PIN_LENGTH));
dVector r1(p1 + matrix1.m_front.Scale(MIN_JOINT_PIN_LENGTH));
// Restrict movement on the pivot point along all three orthonormal directions
NewtonUserJointAddLinearRow(joint, &p0[0], &p1[0], &matrix0.m_front[0]);
if (joint_data->ctype == CT_FLEXIBLE)
NewtonUserJointSetRowSpringDamperAcceleration(joint, Joint::LINEAR_STIFF, Joint::LINEAR_DAMP);
else if (joint_data->ctype == CT_ROBUST)
NewtonUserJointSetRowAcceleration(joint, NewtonUserCalculateRowZeroAccelaration(joint));
NewtonUserJointSetRowStiffness(joint, joint_data->stiffness);
NewtonUserJointAddLinearRow(joint, &p0[0], &p1[0], &matrix0.m_up[0]);
if (joint_data->ctype == CT_FLEXIBLE)
NewtonUserJointSetRowSpringDamperAcceleration(joint, Joint::LINEAR_STIFF, Joint::LINEAR_DAMP);
else if (joint_data->ctype == CT_ROBUST)
NewtonUserJointSetRowAcceleration(joint, NewtonUserCalculateRowZeroAccelaration(joint));
NewtonUserJointSetRowStiffness(joint, joint_data->stiffness);
NewtonUserJointAddLinearRow(joint, &p0[0], &p1[0], &matrix0.m_right[0]);
if (joint_data->ctype == CT_FLEXIBLE)
NewtonUserJointSetRowSpringDamperAcceleration(joint, Joint::LINEAR_STIFF, Joint::LINEAR_DAMP);
else if (joint_data->ctype == CT_ROBUST)
NewtonUserJointSetRowAcceleration(joint, NewtonUserCalculateRowZeroAccelaration(joint));
NewtonUserJointSetRowStiffness(joint, joint_data->stiffness);
// Restrict rotation along all three orthonormal directions
NewtonUserJointAddLinearRow(joint, &q0[0], &q1[0], &matrix0.m_front[0]);
if (joint_data->ctype == CT_FLEXIBLE)
NewtonUserJointSetRowSpringDamperAcceleration(joint, Joint::LINEAR_STIFF, Joint::LINEAR_DAMP);
else if (joint_data->ctype == CT_ROBUST)
NewtonUserJointSetRowAcceleration(joint, NewtonUserCalculateRowZeroAccelaration(joint));
NewtonUserJointSetRowStiffness(joint, joint_data->stiffness);
NewtonUserJointAddLinearRow(joint, &q0[0], &q1[0], &matrix0.m_up[0]);
if (joint_data->ctype == CT_FLEXIBLE)
NewtonUserJointSetRowSpringDamperAcceleration(joint, Joint::LINEAR_STIFF, Joint::LINEAR_DAMP);
else if (joint_data->ctype == CT_ROBUST)
NewtonUserJointSetRowAcceleration(joint, NewtonUserCalculateRowZeroAccelaration(joint));
NewtonUserJointSetRowStiffness(joint, joint_data->stiffness);
NewtonUserJointAddLinearRow(joint, &r0[0], &r1[0], &matrix0.m_up[0]);
if (joint_data->ctype == CT_FLEXIBLE)
NewtonUserJointSetRowSpringDamperAcceleration(joint, Joint::LINEAR_STIFF, Joint::LINEAR_DAMP);
else if (joint_data->ctype == CT_ROBUST)
NewtonUserJointSetRowAcceleration(joint, NewtonUserCalculateRowZeroAccelaration(joint));
NewtonUserJointSetRowStiffness(joint, joint_data->stiffness);
}
int sc_main(int argc, char* argv[])
{
sc_signal<bool> t_a0;
sc_signal<bool> t_a1;
sc_signal<bool> t_a2;
sc_signal<bool> t_a3;
sc_signal<bool> t_b0;
sc_signal<bool> t_b1;
sc_signal<bool> t_b2;
sc_signal<bool> t_b3;
sc_signal<bool> t_c0;
sc_signal<bool> t_s0;
sc_signal<bool> t_s1;
sc_signal<bool> t_s2;
sc_signal<bool> t_s3;
sc_signal<bool> t_c4;
ripple_adder r0("r0");
r0.a0(t_a0);
r0.a1(t_a1);
r0.a2(t_a2);
r0.a3(t_a3);
r0.b0(t_b0);
r0.b1(t_b1);
r0.b2(t_b2);
r0.b3(t_b3);
r0.c0(t_c0);
r0.s0(t_s0);
r0.s1(t_s1);
r0.s2(t_s2);
r0.s3(t_s3);
r0.c4(t_c4);
ripple_adder_driver d0("d0");
d0.d_a0(t_a0);
d0.d_a1(t_a1);
d0.d_a2(t_a2);
d0.d_a3(t_a3);
d0.d_b0(t_b0);
d0.d_b1(t_b1);
d0.d_b2(t_b2);
d0.d_b3(t_b3);
d0.d_c0(t_c0);
ripple_adder_monitor m0("m0");
m0.m_a0(t_a0);
m0.m_a1(t_a1);
m0.m_a2(t_a2);
m0.m_a3(t_a3);
m0.m_b0(t_b0);
m0.m_b1(t_b1);
m0.m_b2(t_b2);
m0.m_b3(t_b3);
m0.m_c0(t_c0);
m0.m_s0(t_s0);
m0.m_s1(t_s1);
m0.m_s2(t_s2);
m0.m_s3(t_s3);
m0.m_c4(t_c4);
// simulate for max 1000 ns
sc_start(1, SC_SEC);
return 0;
}
UIntT num_replications(RealT eps, RealT s0, RealT level=0.95, UIntT max_trials=::std::numeric_limits<UIntT>::max())
{
UIntT r0(0);
r0 = num_replications_initial<RealT,UIntT>(eps, s0, level);
return num_replications(eps, r0, s0, level, max_trials);
}
static int dstr_read_regr( PIA *pi, int cont, int regr )
{ int a, b, r;
r = regr + cont_map[cont];
w0(0x81); P1;
if (pi->mode) { w0(0x11); } else { w0(1); }
P2; w0(r); P1;
switch (pi->mode) {
case 0: w2(6); a = r1(); w2(4); w2(6); b = r1(); w2(4);
return j44(a,b);
case 1: w0(0); w2(0x26); a = r0(); w2(4);
return a;
case 2:
case 3:
case 4: w2(0x24); a = r4(); w2(4);
return a;
}
return -1;
}
DEF_TEST(Data, reporter) {
const char* str = "We the people, in order to form a more perfect union.";
const int N = 10;
SkAutoTUnref<SkData> r0(SkData::NewEmpty());
SkAutoTUnref<SkData> r1(SkData::NewWithCopy(str, strlen(str)));
SkAutoTUnref<SkData> r2(SkData::NewWithProc(new int[N], N*sizeof(int),
delete_int_proc, gGlobal));
SkAutoTUnref<SkData> r3(SkData::NewSubset(r1, 7, 6));
assert_len(reporter, r0, 0);
assert_len(reporter, r1, strlen(str));
assert_len(reporter, r2, N * sizeof(int));
assert_len(reporter, r3, 6);
assert_data(reporter, r1, str, strlen(str));
assert_data(reporter, r3, "people", 6);
SkData* tmp = SkData::NewSubset(r1, strlen(str), 10);
assert_len(reporter, tmp, 0);
tmp->unref();
tmp = SkData::NewSubset(r1, 0, 0);
assert_len(reporter, tmp, 0);
tmp->unref();
test_cstring(reporter);
test_files(reporter);
}
void
vec4_gs_visitor::emit_thread_end()
{
if (c->control_data_header_size_bits > 0) {
/* During shader execution, we only ever call emit_control_data_bits()
* just prior to outputting a vertex. Therefore, the control data bits
* corresponding to the most recently output vertex still need to be
* emitted.
*/
current_annotation = "thread end: emit control data bits";
emit_control_data_bits();
}
/* MRF 0 is reserved for the debugger, so start with message header
* in MRF 1.
*/
int base_mrf = 1;
current_annotation = "thread end";
dst_reg mrf_reg(MRF, base_mrf);
src_reg r0(retype(brw_vec8_grf(0, 0), BRW_REGISTER_TYPE_UD));
vec4_instruction *inst = emit(MOV(mrf_reg, r0));
inst->force_writemask_all = true;
emit(GS_OPCODE_SET_VERTEX_COUNT, mrf_reg, this->vertex_count);
if (INTEL_DEBUG & DEBUG_SHADER_TIME)
emit_shader_time_end();
inst = emit(GS_OPCODE_THREAD_END);
inst->base_mrf = base_mrf;
inst->mlen = 1;
}
static void k971_connect ( PIA *pi )
{ pi->saved_r0 = r0();
pi->saved_r2 = r2();
CCP(0x20);
w2(4);
}
static int epia_read_regr( PIA *pi, int cont, int regr )
{ int a, b, r;
regr += cont_map[cont];
switch (pi->mode) {
case 0: r = regr^0x39;
w0(r); w2(1); w2(3); w0(r);
a = r1(); w2(1); b = r1(); w2(4);
return j44(a,b);
case 1: r = regr^0x31;
w0(r); w2(1); w0(r&0x37);
w2(3); w2(5); w0(r|0xf0);
a = r1(); b = r2(); w2(4);
return j53(a,b);
case 2: r = regr^0x29;
w0(r); w2(1); w2(0X21); w2(0x23);
a = r0(); w2(4);
return a;
case 3:
case 4:
case 5: w3(regr); w2(0x24); a = r4(); w2(4);
return a;
}
return -1;
}
static int fit3_read_regr( PIA *pi, int cont, int regr )
{ int a, b;
if (cont) {
if (regr != 6) return 0xff;
regr = 7;
}
switch (pi->mode) {
case 0: w2(0xc); w0(regr + 0x10); w2(0x8); w2(0xc);
w2(0xd); a = r1();
w2(0xf); b = r1();
w2(0xc);
return j44(a,b);
case 1: w2(0xc); w0(regr + 0x90); w2(0x8); w2(0xc);
w2(0xec); w2(0xee); w2(0xef); a = r0();
w2(0xc);
return a;
case 2: w2(0xc); w0(regr + 0x90); w2(0x8); w2(0xc);
w2(0xec);
a = r4(); b = r4();
w2(0xc);
return a;
}
return -1;
}
static int on26_read_regr( PIA *pi, int cont, int regr )
{ int a, b, r;
r = (regr<<2) + 1 + cont;
switch (pi->mode) {
case 0: w0(1); P1; w0(r); P2; w0(0); P1;
w2(6); a = r1(); w2(4);
w2(6); b = r1(); w2(4);
w2(6); w2(4); w2(6); w2(4);
return j44(a,b);
case 1: w0(1); P1; w0(r); P2; w0(0); P1;
w2(0x26); a = r0(); w2(4); w2(0x26); w2(4);
return a;
case 2:
case 3:
case 4: w3(1); w3(1); w2(5); w4(r); w2(4);
w3(0); w3(0); w2(0x24); a = r4(); w2(4);
w2(0x24); r4(); w2(4);
return a;
}
return -1;
}
/* @param beta current estimates
* @return t(beta) * matrixB * beta
*/
STK::Real FusedLassoPenalty::penaltyTerm(STK::VectorX const& beta) const
{
STK::Real pen = lambda1_ * beta.abs().sum();
STK::Range r0(beta.begin(), beta.size()-1), r1(beta.begin()+1, beta.size()-1);
pen += lambda2_ * (beta.sub(r0) - beta.sub(r1)).abs().sum();
return pen;
}
int main()
{
try {
std::shared_ptr<gal::verb::VerbosityRegistry> vr(
new gal::verb::VerbosityRegistry);
vr->reg<gal::mng::managed_process>( "gal managed_process");
vr->reg<gal::mng::managed_object>( "gal managed_object");
vr->reg<gal::registry_base>( "gal registry_base");
vr->reg<gal::mng::registry_process>("gal registry_process");
vr->reg<gal::mng::registry_object>( "gal registry_object");
typedef gal::mng::registry_object R1;
typedef std::shared_ptr<R1> S_R1;
typedef gal::mng::registry_process R0;
typedef std::shared_ptr<R0> S_R0;
// process registry
S_R0 r0(new R0);
r0->VERB::init_verb(vr);
r0->init();
// object registry
S_R1 r1(new R1);
r1->VERB::init_verb(vr);
r0->reg(r1);
r1->init();
typedef std::shared_ptr<foo> S_F;
S_F f0(new foo);
S_F f1(new foo);
S_F f2(new foo);
f0->init_verb(vr);
f1->init_verb(vr);
f2->init_verb(vr);
r1->reg(f0);
r1->reg(f1);
r1->reg(f2);
gal::object_index i0 = f0->get_index();
r1->get(i0);
} catch(std::exception & e) {
printf("%s\n", e.what());
}
}
