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f13299a5a68601afab14cc2a8ad1b202fe02cc84
create/src/Mod/Path/App/AppPathPy.cpp
Markus Lampert 8448b69cf3 Fix Path::Feature object check
2022-10-11 21:43:09 -07:00

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/***************************************************************************
* Copyright (c) 2014 Yorik van Havre <yorik@uncreated.net> *
* *
* This file is part of the FreeCAD CAx development system. *
* *
* This library is free software; you can redistribute it and/or *
* modify it under the terms of the GNU Library General Public *
* License as published by the Free Software Foundation; either *
* version 2 of the License, or (at your option) any later version. *
* *
* This library is distributed in the hope that it will be useful, *
* but WITHOUT ANY WARRANTY; without even the implied warranty of *
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
* GNU Library General Public License for more details. *
* *
* You should have received a copy of the GNU Library General Public *
* License along with this library; see the file COPYING.LIB. If not, *
* write to the Free Software Foundation, Inc., 59 Temple Place, *
* Suite 330, Boston, MA 02111-1307, USA *
* *
***************************************************************************/
#include "PreCompiled.h"
#include <CXX/Extensions.hxx>
#include <CXX/Objects.hxx>
#include <Base/Console.h>
#include <Base/VectorPy.h>
#include <Base/FileInfo.h>
#include <Base/Interpreter.h>
#include <Base/Stream.h>
#include <App/Document.h>
#include <App/DocumentObjectPy.h>
#include <App/Application.h>
#include <Mod/Part/App/OCCError.h>
#include <Mod/Part/App/TopoShape.h>
#include <Mod/Part/App/TopoShapePy.h>
#include <Mod/Part/App/PartPyCXX.h>
#include <TopoDS.hxx>
#include <TopoDS_Shape.hxx>
#include <TopoDS_Edge.hxx>
#include <TopoDS_Vertex.hxx>
#include <TopoDS_Iterator.hxx>
#include <TopExp_Explorer.hxx>
#include <gp_Lin.hxx>
#include <BRep_Tool.hxx>
#include <BRepAdaptor_Curve.hxx>
#include "CommandPy.h"
#include "PathPy.h"
#include "Path.h"
#include "FeaturePath.h"
#include "FeaturePathCompound.h"
#include "Area.h"
#define PATH_CATCH catch (Standard_Failure &e) \
{ \
std::string str; \
Standard_CString msg = e.GetMessageString(); \
str += typeid(e).name(); \
str += " "; \
if (msg) {str += msg;} \
else {str += "No OCCT Exception Message";} \
Base::Console().Error(str.c_str()); \
PyErr_SetString(Part::PartExceptionOCCError,str.c_str()); \
} \
catch(Base::Exception &e) \
{ \
std::string str; \
str += "FreeCAD exception thrown ("; \
str += e.what(); \
str += ")"; \
e.ReportException(); \
PyErr_SetString(Base::PyExc_FC_GeneralError,str.c_str());\
} \
catch(std::exception &e) \
{ \
std::string str; \
str += "STL exception thrown ("; \
str += e.what(); \
str += ")"; \
Base::Console().Error(str.c_str()); \
PyErr_SetString(Base::PyExc_FC_GeneralError,str.c_str());\
} \
catch(const char *e) \
{ \
PyErr_SetString(Base::PyExc_FC_GeneralError,e); \
} throw Py::Exception();
namespace PathApp {
class VoronoiModule : public Py::ExtensionModule<VoronoiModule>
{
public:
VoronoiModule() : Py::ExtensionModule<VoronoiModule>("Voronoi")
{
initialize("Working with Voronoi diagrams and data structures");
}
~VoronoiModule() override {}
};
class Module : public Py::ExtensionModule<Module>
{
VoronoiModule voronoi;
public:
Module() : Py::ExtensionModule<Module>("PathApp")
{
add_varargs_method("write",&Module::write,
"write(object,filename): Exports a given path object to a GCode file"
);
add_varargs_method("read",&Module::read,
"read(filename,[document]): Imports a GCode file into the given document"
);
add_varargs_method("show",&Module::show,
"show(path,[string]): Add the path to the active document or create one if no document exists"
);
add_varargs_method("fromShape",&Module::fromShape,
"fromShape(Shape): Returns a Path object from a Part Shape (deprecated - use fromShapes() instead)"
);
add_keyword_method("fromShapes",&Module::fromShapes,
"fromShapes(shapes, start=Vector(), return_end=False" PARAM_PY_ARGS_DOC(ARG,AREA_PARAMS_PATH) ")\n"
"\nReturns a Path object from a list of shapes\n"
"\n* shapes: input list of shapes.\n"
"\n* start (Vector()): feed start position, and also serves as a hint of path entry.\n"
"\n* return_end (False): if True, returns tuple (path, endPosition).\n"
PARAM_PY_DOC(ARG, AREA_PARAMS_PATH)
);
add_keyword_method("sortWires",&Module::sortWires,
"sortWires(shapes, start=Vector(), "
PARAM_PY_ARGS_DOC(ARG,AREA_PARAMS_ARC_PLANE)
PARAM_PY_ARGS_DOC(ARG,AREA_PARAMS_SORT) ")\n"
"\nReturns (wires,end), where 'wires' is sorted across Z value and with optimized travel distance,\n"
"and 'end' is the ending position of the whole wires. If arc_plane==1, it returns (wires,end,arc_plane),\n"
"where arc_plane is the found plane if any, or unchanged.\n"
"\n* shapes: input shape list\n"
"\n* start (Vector()): optional start position.\n"
PARAM_PY_DOC(ARG, AREA_PARAMS_ARC_PLANE)
PARAM_PY_DOC(ARG, AREA_PARAMS_SORT)
);
initialize("This module is the Path module."); // register with Python
PyModule_AddObject(m_module, "Voronoi", voronoi.module().ptr());
}
~Module() override {}
private:
Py::Object write(const Py::Tuple& args)
{
char* Name;
PyObject* pObj;
if (!PyArg_ParseTuple(args.ptr(), "Oet",&pObj,"utf-8",&Name))
throw Py::Exception();
std::string EncodedName = std::string(Name);
PyMem_Free(Name);
Base::FileInfo file(EncodedName.c_str());
if (PyObject_TypeCheck(pObj, &(App::DocumentObjectPy::Type))) {
App::DocumentObject* obj = static_cast<App::DocumentObjectPy*>(pObj)->getDocumentObjectPtr();
if (obj->getTypeId().isDerivedFrom(Base::Type::fromName("Path::Feature"))) {
const Path::Toolpath& path = static_cast<Path::Feature*>(obj)->Path.getValue();
std::string gcode = path.toGCode();
Base::ofstream ofile(file);
ofile << gcode;
ofile.close();
}
else {
throw Py::RuntimeError("The given file is not a path");
}
}
return Py::None();
}
Py::Object read(const Py::Tuple& args)
{
char* Name;
const char* DocName=nullptr;
if (!PyArg_ParseTuple(args.ptr(), "et|s","utf-8",&Name,&DocName))
throw Py::Exception();
std::string EncodedName = std::string(Name);
PyMem_Free(Name);
Base::FileInfo file(EncodedName.c_str());
if (!file.exists())
throw Py::RuntimeError("File doesn't exist");
App::Document *pcDoc;
if (DocName)
pcDoc = App::GetApplication().getDocument(DocName);
else
pcDoc = App::GetApplication().getActiveDocument();
if (!pcDoc)
pcDoc = App::GetApplication().newDocument(DocName);
try {
// read the gcode file
Base::ifstream filestr(file);
std::stringstream buffer;
buffer << filestr.rdbuf();
std::string gcode = buffer.str();
Path::Toolpath path;
path.setFromGCode(gcode);
Path::Feature *object = static_cast<Path::Feature *>(pcDoc->addObject("Path::Feature",file.fileNamePure().c_str()));
object->Path.setValue(path);
pcDoc->recompute();
}
catch (const Base::Exception& e) {
throw Py::RuntimeError(e.what());
}
return Py::None();
}
Py::Object show(const Py::Tuple& args)
{
PyObject *pcObj;
char *name = "Path";
if (!PyArg_ParseTuple(args.ptr(), "O!|s", &(Path::PathPy::Type), &pcObj, &name))
throw Py::Exception();
try {
App::Document *pcDoc = App::GetApplication().getActiveDocument();
if (!pcDoc)
pcDoc = App::GetApplication().newDocument();
Path::PathPy* pPath = static_cast<Path::PathPy*>(pcObj);
Path::Feature *pcFeature = static_cast<Path::Feature*>(pcDoc->addObject("Path::Feature", name));
Path::Toolpath* pa = pPath->getToolpathPtr();
if (!pa) {
throw Py::Exception(PyExc_ReferenceError, "object doesn't reference a valid path");
}
// copy the data
pcFeature->Path.setValue(*pa);
}
catch (const Base::Exception& e) {
throw Py::RuntimeError(e.what());
}
return Py::None();
}
Py::Object fromShape(const Py::Tuple& args)
{
PyObject *pcObj;
if (!PyArg_ParseTuple(args.ptr(), "O", &pcObj))
throw Py::Exception();
TopoDS_Shape shape;
try {
if (PyObject_TypeCheck(pcObj, &(Part::TopoShapePy::Type))) {
shape = static_cast<Part::TopoShapePy*>(pcObj)->getTopoShapePtr()->getShape();
} else {
throw Py::TypeError("the given object is not a shape");
}
if (!shape.IsNull()) {
if (shape.ShapeType() == TopAbs_WIRE) {
Path::Toolpath result;
bool first = true;
Base::Placement last;
TopExp_Explorer ExpEdges (shape,TopAbs_EDGE);
while (ExpEdges.More()) {
const TopoDS_Edge& edge = TopoDS::Edge(ExpEdges.Current());
TopExp_Explorer ExpVerts(edge,TopAbs_VERTEX);
bool vfirst = true;
while (ExpVerts.More()) {
const TopoDS_Vertex& vert = TopoDS::Vertex(ExpVerts.Current());
gp_Pnt pnt = BRep_Tool::Pnt(vert);
Base::Placement tpl;
tpl.setPosition(Base::Vector3d(pnt.X(),pnt.Y(),pnt.Z()));
if (first) {
// add first point as a G0 move
Path::Command cmd;
std::ostringstream ctxt;
ctxt << "G0 X" << tpl.getPosition().x << " Y" << tpl.getPosition().y << " Z" << tpl.getPosition().z;
cmd.setFromGCode(ctxt.str());
result.addCommand(cmd);
first = false;
vfirst = false;
} else {
if (vfirst)
vfirst = false;
else {
Path::Command cmd;
cmd.setFromPlacement(tpl);
// write arc data if needed
BRepAdaptor_Curve adapt(edge);
if (adapt.GetType() == GeomAbs_Circle) {
gp_Circ circ = adapt.Circle();
gp_Pnt c = circ.Location();
bool clockwise = false;
gp_Dir n = circ.Axis().Direction();
if (n.Z() < 0)
clockwise = true;
Base::Vector3d center = Base::Vector3d(c.X(),c.Y(),c.Z());
// center coords must be relative to last point
center -= last.getPosition();
cmd.setCenter(center,clockwise);
}
result.addCommand(cmd);
}
}
ExpVerts.Next();
last = tpl;
}
ExpEdges.Next();
}
return Py::asObject(new Path::PathPy(new Path::Toolpath(result)));
} else {
throw Py::TypeError("the given shape must be a wire");
}
} else {
throw Py::TypeError("the given shape is empty");
}
}
catch (const Base::Exception& e) {
throw Py::RuntimeError(e.what());
}
}
Py::Object fromShapes(const Py::Tuple& args, const Py::Dict &kwds)
{
PARAM_PY_DECLARE_INIT(PARAM_FARG,AREA_PARAMS_PATH)
PyObject *pShapes=nullptr;
PyObject *start=nullptr;
PyObject *return_end=Py_False;
static char* kwd_list[] = {"shapes", "start", "return_end",
PARAM_FIELD_STRINGS(ARG,AREA_PARAMS_PATH), nullptr};
if (!PyArg_ParseTupleAndKeywords(args.ptr(), kwds.ptr(),
"O|O!O!" PARAM_PY_KWDS(AREA_PARAMS_PATH),
kwd_list, &pShapes, &(Base::VectorPy::Type), &start, &PyBool_Type, &return_end,
PARAM_REF(PARAM_FARG,AREA_PARAMS_PATH)))
throw Py::Exception();
std::list<TopoDS_Shape> shapes;
if (PyObject_TypeCheck(pShapes, &(Part::TopoShapePy::Type)))
shapes.push_back(static_cast<Part::TopoShapePy*>(pShapes)->getTopoShapePtr()->getShape());
else if (PyObject_TypeCheck(pShapes, &(PyList_Type)) ||
PyObject_TypeCheck(pShapes, &(PyTuple_Type)))
{
Py::Sequence shapeSeq(pShapes);
for (Py::Sequence::iterator it = shapeSeq.begin(); it != shapeSeq.end(); ++it) {
PyObject* item = (*it).ptr();
if(!PyObject_TypeCheck(item, &(Part::TopoShapePy::Type))) {
PyErr_SetString(PyExc_TypeError, "non-shape object in sequence");
throw Py::Exception();
}
shapes.push_back(static_cast<Part::TopoShapePy*>(item)->getTopoShapePtr()->getShape());
}
}
gp_Pnt pstart;
if(start) {
Base::Vector3d vec = static_cast<Base::VectorPy*>(start)->value();
pstart.SetCoord(vec.x, vec.y, vec.z);
}
try {
gp_Pnt pend;
std::unique_ptr<Path::Toolpath> path(new Path::Toolpath);
Path::Area::toPath(*path,shapes,start?&pstart:nullptr, &pend,
PARAM_PY_FIELDS(PARAM_FARG,AREA_PARAMS_PATH));
if (!Base::asBoolean(return_end))
return Py::asObject(new Path::PathPy(path.release()));
Py::Tuple tuple(2);
tuple.setItem(0, Py::asObject(new Path::PathPy(path.release())));
tuple.setItem(1, Py::asObject(new Base::VectorPy(Base::Vector3d(pend.X(),pend.Y(),pend.Z()))));
return tuple;
} PATH_CATCH
}
Py::Object sortWires(const Py::Tuple& args, const Py::Dict &kwds)
{
PARAM_PY_DECLARE_INIT(PARAM_FARG,AREA_PARAMS_ARC_PLANE)
PARAM_PY_DECLARE_INIT(PARAM_FARG,AREA_PARAMS_SORT)
PyObject *pShapes=nullptr;
PyObject *start=nullptr;
static char* kwd_list[] = {"shapes", "start",
PARAM_FIELD_STRINGS(ARG,AREA_PARAMS_ARC_PLANE),
PARAM_FIELD_STRINGS(ARG,AREA_PARAMS_SORT), nullptr};
if (!PyArg_ParseTupleAndKeywords(args.ptr(), kwds.ptr(),
"O|O!"
PARAM_PY_KWDS(AREA_PARAMS_ARC_PLANE)
PARAM_PY_KWDS(AREA_PARAMS_SORT),
kwd_list, &pShapes, &(Base::VectorPy::Type), &start,
PARAM_REF(PARAM_FARG,AREA_PARAMS_ARC_PLANE),
PARAM_REF(PARAM_FARG,AREA_PARAMS_SORT)))
throw Py::Exception();
std::list<TopoDS_Shape> shapes;
if (PyObject_TypeCheck(pShapes, &(Part::TopoShapePy::Type))) {
shapes.push_back(static_cast<Part::TopoShapePy*>(pShapes)->getTopoShapePtr()->getShape());
}
else if (PyObject_TypeCheck(pShapes, &(PyList_Type)) ||
PyObject_TypeCheck(pShapes, &(PyTuple_Type))) {
Py::Sequence shapeSeq(pShapes);
for (Py::Sequence::iterator it = shapeSeq.begin(); it != shapeSeq.end(); ++it) {
PyObject* item = (*it).ptr();
if(!PyObject_TypeCheck(item, &(Part::TopoShapePy::Type))) {
PyErr_SetString(PyExc_TypeError, "non-shape object in sequence");
throw Py::Exception();
}
shapes.push_back(static_cast<Part::TopoShapePy*>(item)->getTopoShapePtr()->getShape());
}
}
gp_Pnt pstart,pend;
if(start) {
Base::Vector3d vec = static_cast<Base::VectorPy*>(start)->value();
pstart.SetCoord(vec.x, vec.y, vec.z);
}
try {
bool need_arc_plane = arc_plane == Path::Area::ArcPlaneAuto;
std::list<TopoDS_Shape> wires = Path::Area::sortWires(shapes, start != nullptr, &pstart,
&pend, nullptr, &arc_plane, PARAM_PY_FIELDS(PARAM_FARG,AREA_PARAMS_SORT));
Py::List list;
for(auto &wire : wires) {
list.append(Part::shape2pyshape(TopoDS::Wire(wire)));
}
Py::Tuple ret(need_arc_plane ? 3 : 2);
ret.setItem(0, list);
ret.setItem(1, Py::asObject(new Base::VectorPy(Base::Vector3d(pend.X(),pend.Y(),pend.Z()))));
if (need_arc_plane)
ret.setItem(2, Py::Long(arc_plane));
return ret;
} PATH_CATCH
}
};
PyObject* initModule()
{
return Base::Interpreter().addModule(new Module);
}
} // namespace Path
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