double TaskFemConstraintTemperature::get_cflux() const{
Base::Quantity cflux = ui->if_temperature->getQuantity();
double cflux_in_watt = cflux.getValueAs(Base::Quantity::Watt);
return cflux_in_watt;
}
double TaskFemConstraintTemperature::get_temperature() const{
Base::Quantity temperature = ui->if_temperature->getQuantity();
double temperature_in_kelvin = temperature.getValueAs(Base::Quantity::Kelvin);
return temperature_in_kelvin;
}
double TaskFemConstraintPressure::getPressure(void) const
{
Base::Quantity pressure = ui->if_pressure->getQuantity();
double pressure_in_MPa = pressure.getValueAs(Base::Quantity::MegaPascal);
return pressure_in_MPa;
}
// constructor method
int ConstraintPy::PyInit(PyObject* args, PyObject* /*kwd*/)
{
if (PyArg_ParseTuple(args, "")) {
return 0;
}
PyErr_Clear();
char *ConstraintType;
int FirstIndex = Constraint::GeoUndef;
int FirstPos = none;
int SecondIndex= Constraint::GeoUndef;
int SecondPos = none;
int ThirdIndex = Constraint::GeoUndef;
int ThirdPos = none;
double Value = 0;
int intArg1, intArg2, intArg3, intArg4, intArg5;
// Note: In Python 2.x PyArg_ParseTuple prints a warning if a float is given but an integer is expected.
// This means we must use a PyObject and check afterwards if it's a float or integer.
PyObject* index_or_value;
PyObject* oNumArg4;
PyObject* oNumArg5;
int any_index;
// ConstraintType, GeoIndex
if (PyArg_ParseTuple(args, "si", &ConstraintType, &FirstIndex)) {
if (strcmp("Horizontal",ConstraintType) == 0) {
this->getConstraintPtr()->Type = Horizontal;
this->getConstraintPtr()->First = FirstIndex;
return 0;
}
else if (strcmp("Vertical",ConstraintType) == 0) {
this->getConstraintPtr()->Type = Vertical;
this->getConstraintPtr()->First = FirstIndex;
return 0;
}
}
PyErr_Clear();
if (PyArg_ParseTuple(args, "siO", &ConstraintType, &FirstIndex, &index_or_value)) {
// ConstraintType, GeoIndex1, GeoIndex2
if (PyInt_Check(index_or_value)) {
SecondIndex = PyInt_AsLong(index_or_value);
bool valid = false;
if (strcmp("Tangent",ConstraintType) == 0) {
this->getConstraintPtr()->Type = Tangent;
valid = true;
}
else if (strcmp("Parallel",ConstraintType) == 0) {
this->getConstraintPtr()->Type = Parallel;
valid = true;
}
else if (strcmp("Perpendicular",ConstraintType) == 0) {
this->getConstraintPtr()->Type = Perpendicular;
valid = true;
}
else if (strcmp("Equal",ConstraintType) == 0) {
this->getConstraintPtr()->Type = Equal;
valid = true;
}
else if (strstr(ConstraintType,"InternalAlignment") != NULL) {
this->getConstraintPtr()->Type = InternalAlignment;
valid = true;
if(strstr(ConstraintType,"EllipseMajorDiameter") != NULL)
this->getConstraintPtr()->AlignmentType=EllipseMajorDiameter;
else if(strstr(ConstraintType,"EllipseMinorDiameter") != NULL)
this->getConstraintPtr()->AlignmentType=EllipseMinorDiameter;
else {
this->getConstraintPtr()->AlignmentType=Undef;
valid = false;
}
}
if (valid) {
this->getConstraintPtr()->First = FirstIndex;
this->getConstraintPtr()->Second = SecondIndex;
return 0;
}
}
// ConstraintType, GeoIndex, Value
if (PyNumber_Check(index_or_value)) { // can be float or int
Value = PyFloat_AsDouble(index_or_value);
bool valid = false;
if (strcmp("Distance",ConstraintType) == 0 ) {
this->getConstraintPtr()->Type = Distance;
valid = true;
}
else if (strcmp("Angle",ConstraintType) == 0 ) {
if (PyObject_TypeCheck(index_or_value, &(Base::QuantityPy::Type))) {
Base::Quantity q = *(static_cast<Base::QuantityPy*>(index_or_value)->getQuantityPtr());
if (q.getUnit() == Base::Unit::Angle)
Value = q.getValueAs(Base::Quantity::Radian);
}
this->getConstraintPtr()->Type = Angle;
valid = true;
}
else if (strcmp("DistanceX",ConstraintType) == 0) {
this->getConstraintPtr()->Type = DistanceX;
valid = true;
}
else if (strcmp("DistanceY",ConstraintType) == 0) {
this->getConstraintPtr()->Type = DistanceY;
valid = true;
}
else if (strcmp("Radius",ConstraintType) == 0) {
this->getConstraintPtr()->Type = Radius;
// set a value that is out of range of result of atan2
// this value is handled in ViewProviderSketch
this->getConstraintPtr()->LabelPosition = 10;
valid = true;
}
if (valid) {
this->getConstraintPtr()->First = FirstIndex;
this->getConstraintPtr()->setValue(Value);
return 0;
}
}
}
PyErr_Clear();
if (PyArg_ParseTuple(args, "siiO", &ConstraintType, &FirstIndex, &any_index, &index_or_value)) {
// ConstraintType, GeoIndex1, PosIndex1, GeoIndex2
if (PyInt_Check(index_or_value)) {
FirstPos = any_index;
SecondIndex = PyInt_AsLong(index_or_value);
bool valid = false;
if (strcmp("Perpendicular", ConstraintType) == 0) {
this->getConstraintPtr()->Type = Perpendicular;
valid = true;
}
else if (strcmp("Tangent", ConstraintType) == 0) {
this->getConstraintPtr()->Type = Tangent;
valid = true;
}
else if (strcmp("PointOnObject", ConstraintType) == 0) {
this->getConstraintPtr()->Type = PointOnObject;
valid = true;
}
else if (strstr(ConstraintType,"InternalAlignment") != NULL) {
this->getConstraintPtr()->Type = InternalAlignment;
valid = true;
if(strstr(ConstraintType,"EllipseFocus1") != NULL)
this->getConstraintPtr()->AlignmentType=EllipseFocus1;
else if(strstr(ConstraintType,"EllipseFocus2") != NULL)
this->getConstraintPtr()->AlignmentType=EllipseFocus2;
else {
this->getConstraintPtr()->AlignmentType=Undef;
valid = false;
}
}
if (valid) {
this->getConstraintPtr()->First = FirstIndex;
this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) FirstPos;
this->getConstraintPtr()->Second = SecondIndex;
return 0;
}
}
// ConstraintType, GeoIndex1, GeoIndex2, Value
// ConstraintType, GeoIndex, PosIndex, Value
if (PyNumber_Check(index_or_value)) { // can be float or int
SecondIndex = any_index;
Value = PyFloat_AsDouble(index_or_value);
//if (strcmp("Distance",ConstraintType) == 0) {
// this->getConstraintPtr()->Type = Distance;
// this->getConstraintPtr()->First = FirstIndex;
// this->getConstraintPtr()->Second = SecondIndex;
// this->getConstraintPtr()->Value = Value;
// return 0;
//}
//else
if (strcmp("Angle",ConstraintType) == 0) {
if (PyObject_TypeCheck(index_or_value, &(Base::QuantityPy::Type))) {
Base::Quantity q = *(static_cast<Base::QuantityPy*>(index_or_value)->getQuantityPtr());
if (q.getUnit() == Base::Unit::Angle)
Value = q.getValueAs(Base::Quantity::Radian);
}
this->getConstraintPtr()->Type = Angle;
this->getConstraintPtr()->First = FirstIndex;
this->getConstraintPtr()->Second = SecondIndex;
this->getConstraintPtr()->setValue(Value);
return 0;
}
else if (strcmp("DistanceX",ConstraintType) == 0) {
FirstPos = SecondIndex;
SecondIndex = -1;
this->getConstraintPtr()->Type = DistanceX;
this->getConstraintPtr()->First = FirstIndex;
this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) FirstPos;
this->getConstraintPtr()->setValue(Value);
return 0;
}
else if (strcmp("DistanceY",ConstraintType) == 0) {
FirstPos = SecondIndex;
SecondIndex = -1;
this->getConstraintPtr()->Type = DistanceY;
this->getConstraintPtr()->First = FirstIndex;
this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) FirstPos;
this->getConstraintPtr()->setValue(Value);
return 0;
}
}
}
PyErr_Clear();
if (PyArg_ParseTuple(args, "siiiO", &ConstraintType, &intArg1, &intArg2, &intArg3, &oNumArg4)) {
// Value, ConstraintType, GeoIndex1, PosIndex1, GeoIndex2, PosIndex2
if (PyInt_Check(oNumArg4)) {
intArg4 = PyInt_AsLong(oNumArg4);
bool valid = false;
if (strcmp("Coincident", ConstraintType) == 0) {
this->getConstraintPtr()->Type = Coincident;
valid = true;
}
else if (strcmp("Horizontal", ConstraintType) == 0) {
this->getConstraintPtr()->Type = Horizontal;
valid = true;
}
else if (strcmp("Vertical", ConstraintType) == 0) {
this->getConstraintPtr()->Type = Vertical;
valid = true;
}
else if (strcmp("Perpendicular", ConstraintType) == 0) {
this->getConstraintPtr()->Type = Perpendicular;
valid = true;
}
else if (strcmp("Tangent", ConstraintType) == 0) {
this->getConstraintPtr()->Type = Tangent;
valid = true;
}
else if (strcmp("TangentViaPoint", ConstraintType) == 0) {
this->getConstraintPtr()->Type = Tangent;
//valid = true;//non-standard assignment
this->getConstraintPtr()->First = intArg1;
this->getConstraintPtr()->FirstPos = Sketcher::none;
this->getConstraintPtr()->Second = intArg2;
this->getConstraintPtr()->SecondPos = Sketcher::none;
this->getConstraintPtr()->Third = intArg3;
this->getConstraintPtr()->ThirdPos = (Sketcher::PointPos) intArg4;
return 0;
}
else if (strcmp("PerpendicularViaPoint", ConstraintType) == 0) {
this->getConstraintPtr()->Type = Perpendicular;
//valid = true;//non-standard assignment
this->getConstraintPtr()->First = intArg1;
this->getConstraintPtr()->FirstPos = Sketcher::none;
this->getConstraintPtr()->Second = intArg2;
this->getConstraintPtr()->SecondPos = Sketcher::none;
this->getConstraintPtr()->Third = intArg3;
this->getConstraintPtr()->ThirdPos = (Sketcher::PointPos) intArg4;
return 0;
}
if (valid) {
this->getConstraintPtr()->First = intArg1;
this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) intArg2;
this->getConstraintPtr()->Second = intArg3;
this->getConstraintPtr()->SecondPos = (Sketcher::PointPos) intArg4;
return 0;
}
}
// ConstraintType, GeoIndex1, PosIndex1, GeoIndex2, Value
if (PyNumber_Check(oNumArg4)) { // can be float or int
Value = PyFloat_AsDouble(oNumArg4);
if (strcmp("Distance",ConstraintType) == 0 ) {
this->getConstraintPtr()->Type = Distance;
this->getConstraintPtr()->First = intArg1;
this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) intArg2;
this->getConstraintPtr()->Second = intArg3;
this->getConstraintPtr()->setValue(Value);
return 0;
}
}
}
PyErr_Clear();
if (PyArg_ParseTuple(args, "siiiiO", &ConstraintType, &intArg1, &intArg2, &intArg3, &intArg4, &oNumArg5)) {
// ConstraintType, GeoIndex1, PosIndex1, GeoIndex2, PosIndex2, GeoIndex3
if (PyInt_Check(oNumArg5)) {
intArg5 = PyInt_AsLong(oNumArg5);
if (strcmp("Symmetric",ConstraintType) == 0 ) {
this->getConstraintPtr()->Type = Symmetric;
this->getConstraintPtr()->First = intArg1;
this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) intArg2;
this->getConstraintPtr()->Second = intArg3;
this->getConstraintPtr()->SecondPos = (Sketcher::PointPos) intArg4;
this->getConstraintPtr()->Third = intArg5;
return 0;
}
}
// ConstraintType, GeoIndex1, PosIndex1, GeoIndex2, PosIndex2, Value
if (PyNumber_Check(oNumArg5)) { // can be float or int
Value = PyFloat_AsDouble(oNumArg5);
bool valid=false;
if (strcmp("Distance",ConstraintType) == 0 ) {
this->getConstraintPtr()->Type = Distance;
valid = true;
}
else if (strcmp("DistanceX",ConstraintType) == 0) {
this->getConstraintPtr()->Type = DistanceX;
valid = true;
}
else if (strcmp("DistanceY",ConstraintType) == 0) {
this->getConstraintPtr()->Type = DistanceY;
valid = true;
}
else if (strcmp("Angle",ConstraintType) == 0 ) {
if (PyObject_TypeCheck(oNumArg5, &(Base::QuantityPy::Type))) {
Base::Quantity q = *(static_cast<Base::QuantityPy*>(oNumArg5)->getQuantityPtr());
if (q.getUnit() == Base::Unit::Angle)
Value = q.getValueAs(Base::Quantity::Radian);
}
this->getConstraintPtr()->Type = Angle;
valid = true;
}
else if (strcmp("AngleViaPoint",ConstraintType) == 0 ) {
if (PyObject_TypeCheck(oNumArg5, &(Base::QuantityPy::Type))) {
Base::Quantity q = *(static_cast<Base::QuantityPy*>(oNumArg5)->getQuantityPtr());
if (q.getUnit() == Base::Unit::Angle)
Value = q.getValueAs(Base::Quantity::Radian);
}
this->getConstraintPtr()->Type = Angle;
//valid = true;//non-standard assignment
this->getConstraintPtr()->First = intArg1;
this->getConstraintPtr()->FirstPos = Sketcher::none;
this->getConstraintPtr()->Second = intArg2; //let's goof up all the terminology =)
this->getConstraintPtr()->SecondPos = Sketcher::none;
this->getConstraintPtr()->Third = intArg3;
this->getConstraintPtr()->ThirdPos = (Sketcher::PointPos) intArg4;
this->getConstraintPtr()->setValue(Value);
return 0;
}
if (valid) {
this->getConstraintPtr()->First = intArg1;
this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) intArg2;
this->getConstraintPtr()->Second = intArg3;
this->getConstraintPtr()->SecondPos = (Sketcher::PointPos) intArg4;
this->getConstraintPtr()->setValue(Value);
return 0;
}
}
}
PyErr_Clear();
if (PyArg_ParseTuple(args, "siiiiiO", &ConstraintType, &FirstIndex, &FirstPos, &SecondIndex, &SecondPos, &ThirdIndex, &index_or_value)) {
if (PyInt_Check(index_or_value)) {
ThirdPos = PyInt_AsLong(index_or_value);
// ConstraintType, GeoIndex1, PosIndex1, GeoIndex2, PosIndex2, GeoIndex3, PosIndex3
if (strcmp("Symmetric",ConstraintType) == 0 ) {
this->getConstraintPtr()->Type = Symmetric;
this->getConstraintPtr()->First = FirstIndex;
this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) FirstPos;
this->getConstraintPtr()->Second = SecondIndex;
this->getConstraintPtr()->SecondPos = (Sketcher::PointPos) SecondPos;
this->getConstraintPtr()->Third = ThirdIndex;
this->getConstraintPtr()->ThirdPos = (Sketcher::PointPos) ThirdPos;
return 0;
}
}
if (PyNumber_Check(index_or_value)) { // can be float or int
Value = PyFloat_AsDouble(index_or_value);
if (strcmp("SnellsLaw",ConstraintType) == 0 ) {
this->getConstraintPtr()->Type = SnellsLaw;
this->getConstraintPtr()->First = FirstIndex;
this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) FirstPos;
this->getConstraintPtr()->Second = SecondIndex;
this->getConstraintPtr()->SecondPos = (Sketcher::PointPos) SecondPos;
this->getConstraintPtr()->Third = ThirdIndex;
this->getConstraintPtr()->ThirdPos = none;
this->getConstraintPtr()->setValue(Value);
return 0;
}
}
}
std::stringstream str;
str << "Invalid parameters: ";
Py::Tuple tuple(args);
str << tuple.as_string() << std::endl;
str << "Constraint constructor accepts:" << std::endl
<< "-- empty parameter list" << std::endl
<< "-- Constraint type and index" << std::endl;
PyErr_SetString(PyExc_TypeError, str.str().c_str());
return -1;
}
void TaskFemConstraintPressure::onPressureChanged(const Base::Quantity& f)
{
Fem::ConstraintPressure* pcConstraint = static_cast<Fem::ConstraintPressure*>(ConstraintView->getObject());
double val = f.getValueAs(Base::Quantity::MegaPascal);
pcConstraint->Pressure.setValue(val);
}