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create/src/Mod/TechDraw/App/AppTechDrawPy.cpp
wandererfan a10e93befe [TD]apply review comments
2025-03-21 09:49:14 -04:00

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/***************************************************************************
* Copyright (c) 2002 Jürgen Riegel <juergen.riegel@web.de> *
* Copyright (c) 2016 WandererFan <wandererfan@gmail.com> *
* *
* 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"
#ifndef _PreComp_
# include <BRep_Builder.hxx>
# include <BRepBuilderAPI_Transform.hxx>
# include <gp_Trsf.hxx>
# include <gp_Vec.hxx>
# include <TopoDS.hxx>
# include <TopoDS_Compound.hxx>
# include <TopoDS_Edge.hxx>
# include <TopoDS_Face.hxx>
# include <TopoDS_Wire.hxx>
#endif
#include <boost_regex.hpp>
#include <App/DocumentObject.h>
#include <App/DocumentObjectPy.h>
#include <Base/Console.h>
#include <Base/Exception.h>
#include <Base/PyWrapParseTupleAndKeywords.h>
#include <Base/Vector3D.h>
#include <Base/VectorPy.h>
#include <Mod/Import/App/dxf/ImpExpDxf.h>
#include <Mod/Part/App/OCCError.h>
#include <Mod/Part/App/TopoShape.h>
#include <Mod/Part/App/TopoShapeCompoundPy.h>
#include <Mod/Part/App/TopoShapeEdgePy.h>
#include <Mod/Part/App/TopoShapeFacePy.h>
#include <Mod/Part/App/TopoShapePy.h>
#include <Mod/Part/App/TopoShapeWirePy.h>
#include <Mod/TechDraw/TechDrawGlobal.h>
#include "DimensionGeometry.h"
#include "DrawDimHelper.h"
#include "DrawGeomHatch.h"
#include "DrawPage.h"
#include "DrawPagePy.h"
#include "DrawProjectSplit.h"
#include "DrawProjGroup.h"
#include "DrawProjGroupItem.h"
#include "DrawUtil.h"
#include "DrawViewAnnotation.h"
#include "DrawViewDimension.h"
#include "DrawViewPart.h"
#include "DrawViewPartPy.h"
#include "EdgeWalker.h"
#include "Geometry.h"
#include "GeometryObject.h"
#include "ProjectionAlgos.h"
#include "TechDrawExport.h"
#include "DrawLeaderLinePy.h"
namespace TechDraw {
//module level static C++ functions go here
}
using Part::TopoShape;
using Part::TopoShapePy;
using Part::TopoShapeEdgePy;
using Part::TopoShapeFacePy;
using Part::TopoShapeWirePy;
using Part::TopoShapeCompoundPy;
using Import::ImpExpDxfWrite;
using TechDraw::ProjectionAlgos;
using namespace std;
using namespace Part;
namespace TechDraw {
/** Copies a Python dictionary of Python strings to a C++ container.
*
* After the function call, the key-value pairs of the Python
* dictionary are copied into the target buffer as C++ pairs
* (pair<string, string>).
*
* @param sourceRange is a Python dictionary (Py::Dict). Both, the
* keys and the values must be Python strings.
*
* @param targetIt refers to where the data should be inserted. Must
* be of concept output iterator.
*/
template<typename OutputIt>
void copy(Py::Dict sourceRange, OutputIt targetIt)
{
string key;
string value;
for (const auto& keyPy : sourceRange.keys()) {
key = Py::String(keyPy);
value = Py::String(sourceRange[keyPy]);
*targetIt = {key, value};
++targetIt;
}
}
class Module : public Py::ExtensionModule<Module>
{
public:
Module() : Py::ExtensionModule<Module>("TechDraw")
{
add_varargs_method("edgeWalker", &Module::edgeWalker,
"[wires] = edgeWalker(edgePile, inclBiggest) -- Planar graph traversal finds wires in edge pile."
);
add_varargs_method("findOuterWire", &Module::findOuterWire,
"wire = findOuterWire(edgeList) -- Planar graph traversal finds OuterWire in edge pile."
);
add_varargs_method("findShapeOutline", &Module::findShapeOutline,
"wire = findShapeOutline(shape, scale, direction) -- Project shape in direction and find outer wire of result."
);
add_varargs_method("viewPartAsDxf", &Module::viewPartAsDxf,
"string = viewPartAsDxf(DrawViewPart) -- Return the edges of a DrawViewPart in Dxf format."
);
add_varargs_method("viewPartAsSvg", &Module::viewPartAsSvg,
"string = viewPartAsSvg(DrawViewPart) -- Return the edges of a DrawViewPart in Svg format."
);
add_varargs_method("writeDXFView", &Module::writeDXFView,
"writeDXFView(view, filename): Exports a DrawViewPart to a DXF file."
);
add_varargs_method("writeDXFPage", &Module::writeDXFPage,
"writeDXFPage(page, filename): Exports a DrawPage to a DXF file."
);
add_varargs_method("findCentroid", &Module::findCentroid,
"vector = findCentroid(shape, direction): finds geometric centroid of shape looking in direction."
);
add_varargs_method("makeExtentDim", &Module::makeExtentDim,
"makeExtentDim(DrawViewPart, [edges], direction) -- draw horizontal or vertical extent dimension for edges (or all of DrawViewPart if edge list is empty. direction: 0 - Horizontal, 1 - Vertical."
);
add_varargs_method("makeDistanceDim", &Module::makeDistanceDim,
"makeDistanceDim(DrawViewPart, dimType, fromPoint, toPoint) -- draw a Length dimension between fromPoint to toPoint. FromPoint and toPoint are unscaled 2d View points. dimType is one of ['Distance', 'DistanceX', 'DistanceY'."
);
add_varargs_method("makeDistanceDim3d", &Module::makeDistanceDim3d,
"makeDistanceDim(DrawViewPart, dimType, 3dFromPoint, 3dToPoint) -- draw a Length dimension between fromPoint to toPoint. FromPoint and toPoint are unscaled 3d model points. dimType is one of ['Distance', 'DistanceX', 'DistanceY'."
);
add_varargs_method("makeGeomHatch", &Module::makeGeomHatch,
"makeGeomHatch(face, [patScale], [patName], [patFile]) -- draw a geom hatch on a given face, using optionally the given scale (default 1) and a given pattern name (ex. Diamond) and .pat file (the default pattern name and/or .pat files set in preferences are used if none are given). Returns a Part compound shape."
);
add_varargs_method("project", &Module::project,
"[visiblyG0, visiblyG1, hiddenG0, hiddenG1] = project(TopoShape[, App.Vector Direction, string type])\n"
" -- Project a shape and return the visible/invisible parts of it."
);
add_varargs_method("projectEx", &Module::projectEx,
"[V, V1, VN, VO, VI, H,H1, HN, HO, HI] = projectEx(TopoShape[, App.Vector Direction, string type])\n"
" -- Project a shape and return the all parts of it."
);
add_keyword_method("projectToSVG", &Module::projectToSVG,
"string = projectToSVG(TopoShape[, App.Vector direction, string type, float tolerance, dict vStyle, dict v0Style, dict v1Style, dict hStyle, dict h0Style, dict h1Style])\n"
" -- Project a shape and return the SVG representation as string."
);
add_varargs_method("projectToDXF", &Module::projectToDXF,
"string = projectToDXF(TopoShape[, App.Vector Direction, string type])\n"
" -- Project a shape and return the DXF representation as string."
);
add_varargs_method("removeSvgTags", &Module::removeSvgTags,
"string = removeSvgTags(string) -- Removes the opening and closing svg tags\n"
"and other metatags from a svg code, making it embeddable"
);
add_varargs_method("exportSVGEdges", &Module::exportSVGEdges,
"string = exportSVGEdges(TopoShape) -- export an SVG string of the shape\n"
);
add_varargs_method("build3dCurves", &Module::build3dCurves,
"TopoShape = build3dCurves(TopoShape) -- convert the edges to a 3D curve\n"
"which is useful for shapes obtained Part.HLRBRep.Algo"
);
add_varargs_method("makeCanonicalPoint", &Module::makeCanonicalPoint,
"makeCanonicalPoint(DrawViewPart, Vector3d) - Returns the unscaled, unrotated version of the input point)"
);
add_varargs_method("makeLeader", &Module::makeLeader,
"makeLeader(parent - DrawViewPart, points - [Vector], startSymbol - int, endSymbol - int) - Creates a leader line attached to parent. Points are in page coordinates with (0, 0) at lowerleft.s"
);
initialize("This is a module for making drawings"); // register with Python
}
~Module() override {}
private:
Py::Object invoke_method_varargs(void *method_def, const Py::Tuple &args) override
{
try {
return Py::ExtensionModule<Module>::invoke_method_varargs(method_def, args);
}
catch (const 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("%s\n", str.c_str());
throw Py::Exception(Part::PartExceptionOCCError, str);
}
catch (const Base::Exception &e) {
std::string str;
str += "FreeCAD exception thrown (";
str += e.what();
str += ")";
e.ReportException();
throw Py::RuntimeError(str);
}
catch (const std::exception &e) {
std::string str;
str += "C++ exception thrown (";
str += e.what();
str += ")";
Base::Console().Error("%s\n", str.c_str());
throw Py::RuntimeError(str);
}
}
Py::Object edgeWalker(const Py::Tuple& args)
{
PyObject *pcObj = nullptr;
PyObject *inclBig = Py_True;
if (!PyArg_ParseTuple(args.ptr(), "O!|O", &(PyList_Type), &pcObj, &inclBig)) {
throw Py::TypeError("expected (listofedges, boolean");
}
std::vector<TopoDS_Edge> edgeList;
try {
Py::Sequence list(pcObj);
for (Py::Sequence::iterator it = list.begin(); it != list.end(); ++it) {
if (PyObject_TypeCheck((*it).ptr(), &(Part::TopoShapeEdgePy::Type))) {
const TopoDS_Shape& shape = static_cast<TopoShapePy*>((*it).ptr())->
getTopoShapePtr()->getShape();
const TopoDS_Edge edge = TopoDS::Edge(shape);
edgeList.push_back(edge);
}
}
}
catch (Standard_Failure& e) {
throw Py::Exception(Part::PartExceptionOCCError, e.GetMessageString());
}
if (edgeList.empty()) {
return Py::None();
}
bool biggie = false;
if (inclBig == Py_True) {
biggie = true;
}
Py::List result;
std::vector<TopoDS_Edge> closedEdges;
edgeList = DrawProjectSplit::scrubEdges(edgeList, closedEdges);
// Need to also check closed edges- those are valid wires
edgeList.insert( edgeList.end(), closedEdges.begin(), closedEdges.end() );
std::vector<TopoDS_Wire> sortedWires;
try {
EdgeWalker eWalker;
sortedWires = eWalker.execute(edgeList, biggie);
}
catch (Base::Exception &e) {
e.setPyException();
throw Py::Exception();
}
if (sortedWires.empty()) {
Base::Console().Warning("ATDP::edgeWalker: Wire detection failed\n");
return Py::None();
}
else {
for (auto& w : sortedWires) {
PyObject* wire = new TopoShapeWirePy(new Part::TopoShape(w));
result.append(Py::asObject(wire));
}
}
return result;
}
Py::Object findOuterWire(const Py::Tuple& args)
{
PyObject *pcObj = nullptr;
if (!PyArg_ParseTuple(args.ptr(), "O!", &(PyList_Type), &pcObj)) {
throw Py::TypeError("expected (listofedges)");
}
std::vector<TopoDS_Edge> edgeList;
try {
Py::Sequence list(pcObj);
for (Py::Sequence::iterator it = list.begin(); it != list.end(); ++it) {
if (PyObject_TypeCheck((*it).ptr(), &(Part::TopoShapeEdgePy::Type))) {
const TopoDS_Shape& shape = static_cast<TopoShapePy*>((*it).ptr())->
getTopoShapePtr()->getShape();
const TopoDS_Edge edge = TopoDS::Edge(shape);
edgeList.push_back(edge);
}
}
}
catch (Standard_Failure& e) {
throw Py::Exception(Part::PartExceptionOCCError, e.GetMessageString());
}
if (edgeList.empty()) {
Base::Console().Message("ATDP::findOuterWire: input is empty\n");
return Py::None();
}
std::vector<TopoDS_Edge> closedEdges;
edgeList = DrawProjectSplit::scrubEdges(edgeList, closedEdges);
// Need to also check closed edges, since that may be the outline
edgeList.insert( edgeList.end(), closedEdges.begin(), closedEdges.end() );
PyObject* outerWire = nullptr;
std::vector<TopoDS_Wire> sortedWires;
try {
EdgeWalker eWalker;
sortedWires = eWalker.execute(edgeList);
}
catch (Base::Exception &e) {
e.setPyException();
throw Py::Exception();
}
if(sortedWires.empty()) {
Base::Console().Warning("ATDP::findOuterWire: Outline wire detection failed\n");
return Py::None();
} else {
outerWire = new TopoShapeWirePy(new TopoShape(*sortedWires.begin()));
}
return Py::asObject(outerWire);
}
Py::Object findShapeOutline(const Py::Tuple& args)
{
PyObject *pcObjShape(nullptr);
double scale(1.0);
PyObject *pcObjDir(nullptr);
if (!PyArg_ParseTuple(args.ptr(), "OdO", &pcObjShape,
&scale,
&pcObjDir)) {
throw Py::TypeError("expected (shape, scale, direction");
}
if (!PyObject_TypeCheck(pcObjShape, &(TopoShapePy::Type))) {
throw Py::TypeError("expected arg1 to be 'Shape'");
}
if (!PyObject_TypeCheck(pcObjDir, &(Base::VectorPy::Type))) {
throw Py::TypeError("expected arg3 to be 'Vector'");
}
TopoShapePy* pShape = static_cast<TopoShapePy*>(pcObjShape);
if (!pShape) {
Base::Console().Message("TRACE - AATDP::findShapeOutline - input shape is null\n");
return Py::None();
}
const TopoDS_Shape& shape = pShape->getTopoShapePtr()->getShape();
Base::Vector3d dir = static_cast<Base::VectorPy*>(pcObjDir)->value();
std::vector<TopoDS_Edge> edgeList;
try {
edgeList = DrawProjectSplit::getEdgesForWalker(shape, scale, dir);
}
catch (Standard_Failure& e) {
throw Py::Exception(Part::PartExceptionOCCError, e.GetMessageString());
}
if (edgeList.empty()) {
return Py::None();
}
std::vector<TopoDS_Edge> closedEdges;
edgeList = DrawProjectSplit::scrubEdges(edgeList, closedEdges);
// Need to also check closed edges, since that may be the outline
edgeList.insert( edgeList.end(), closedEdges.begin(), closedEdges.end() );
PyObject* outerWire = nullptr;
std::vector<TopoDS_Wire> sortedWires;
try {
EdgeWalker eWalker;
sortedWires = eWalker.execute(edgeList);
}
catch (Base::Exception &e) {
e.setPyException();
throw Py::Exception();
}
if(sortedWires.empty()) {
Base::Console().Warning("ATDP::findShapeOutline: Outline wire detection failed\n");
return Py::None();
} else {
outerWire = new TopoShapeWirePy(new TopoShape(*sortedWires.begin()));
}
return Py::asObject(outerWire);
}
Py::Object viewPartAsDxf(const Py::Tuple& args)
{
PyObject *viewObj(nullptr);
if (!PyArg_ParseTuple(args.ptr(), "O", &viewObj)) {
throw Py::TypeError("expected (DrawViewPart)");
}
Py::String dxfReturn;
try {
App::DocumentObject* obj = nullptr;
TechDraw::DrawViewPart* dvp = nullptr;
TechDraw::DXFOutput dxfOut;
std::string dxfText;
std::stringstream ss;
if (PyObject_TypeCheck(viewObj, &(TechDraw::DrawViewPartPy::Type))) {
obj = static_cast<App::DocumentObjectPy*>(viewObj)->getDocumentObjectPtr();
dvp = static_cast<TechDraw::DrawViewPart*>(obj);
TechDraw::GeometryObjectPtr gObj = dvp->getGeometryObject();
if (!gObj) {
Base::Console().Message("TechDraw: %s has no geometry object!\n", dvp->Label.getValue());
return Py::String();
}
TopoDS_Shape shape = ShapeUtils::mirrorShape(gObj->getVisHard());
ss << dxfOut.exportEdges(shape);
shape = ShapeUtils::mirrorShape(gObj->getVisOutline());
ss << dxfOut.exportEdges(shape);
if (dvp->SmoothVisible.getValue()) {
shape = ShapeUtils::mirrorShape(gObj->getVisSmooth());
ss << dxfOut.exportEdges(shape);
}
if (dvp->SeamVisible.getValue()) {
shape = ShapeUtils::mirrorShape(gObj->getVisSeam());
ss << dxfOut.exportEdges(shape);
}
if (dvp->HardHidden.getValue()) {
shape = ShapeUtils::mirrorShape(gObj->getHidHard());
ss << dxfOut.exportEdges(shape);
shape = ShapeUtils::mirrorShape(gObj->getHidOutline());
ss << dxfOut.exportEdges(shape);
}
if (dvp->SmoothHidden.getValue()) {
shape = ShapeUtils::mirrorShape(gObj->getHidSmooth());
ss << dxfOut.exportEdges(shape);
}
if (dvp->SeamHidden.getValue()) {
shape = ShapeUtils::mirrorShape(gObj->getHidSeam());
ss << dxfOut.exportEdges(shape);
}
// ss now contains all edges as Dxf
dxfReturn = Py::String(ss.str());
}
}
catch (Base::Exception &e) {
e.setPyException();
throw Py::Exception();
}
return dxfReturn;
}
Py::Object viewPartAsSvg(const Py::Tuple& args)
{
PyObject *viewObj(nullptr);
if (!PyArg_ParseTuple(args.ptr(), "O", &viewObj)) {
throw Py::TypeError("expected (DrawViewPart)");
}
Py::String svgReturn;
std::string grpHead1 = "<g fill=\"none\" stroke=\"#000000\" stroke-opacity=\"1\" stroke-width=\"";
std::string grpHead2 = "\" stroke-linecap=\"butt\" stroke-linejoin=\"miter\" stroke-miterlimit=\"4\">\n";
std::string grpTail = "</g>\n";
try {
App::DocumentObject* obj = nullptr;
TechDraw::DrawViewPart* dvp = nullptr;
TechDraw::SVGOutput svgOut;
std::string svgText;
std::stringstream ss;
if (PyObject_TypeCheck(viewObj, &(TechDraw::DrawViewPartPy::Type))) {
obj = static_cast<App::DocumentObjectPy*>(viewObj)->getDocumentObjectPtr();
dvp = static_cast<TechDraw::DrawViewPart*>(obj);
TechDraw::GeometryObjectPtr gObj = dvp->getGeometryObject();
if (!gObj) {
Base::Console().Message("TechDraw: %s has no geometry object!\n", dvp->Label.getValue());
return Py::String();
}
//visible group begin "<g ... >"
ss << grpHead1;
double thick = DrawUtil::getDefaultLineWeight("Thick");
ss << thick;
ss << grpHead2;
TopoDS_Shape shape = gObj->getVisHard();
ss << svgOut.exportEdges(shape);
shape = gObj->getVisOutline();
ss << svgOut.exportEdges(shape);
if (dvp->SmoothVisible.getValue()) {
shape = gObj->getVisSmooth();
ss << svgOut.exportEdges(shape);
}
if (dvp->SeamVisible.getValue()) {
shape = gObj->getVisSeam();
ss << svgOut.exportEdges(shape);
}
//visible group end "</g>"
ss << grpTail;
if ( dvp->HardHidden.getValue() ||
dvp->SmoothHidden.getValue() ||
dvp->SeamHidden.getValue() ) {
//hidden group begin
ss << grpHead1;
thick = DrawUtil::getDefaultLineWeight("Thin");
ss << thick;
ss << grpHead2;
if (dvp->HardHidden.getValue()) {
shape = gObj->getHidHard();
ss << svgOut.exportEdges(shape);
shape = gObj->getHidOutline();
ss << svgOut.exportEdges(shape);
}
if (dvp->SmoothHidden.getValue()) {
shape = gObj->getHidSmooth();
ss << svgOut.exportEdges(shape);
}
if (dvp->SeamHidden.getValue()) {
shape = gObj->getHidSeam();
ss << svgOut.exportEdges(shape);
}
ss << grpTail;
//hidden group end
}
// ss now contains all edges as Svg
svgReturn = Py::String(ss.str());
}
}
catch (Base::Exception &e) {
e.setPyException();
throw Py::Exception();
}
return svgReturn;
}
void write1ViewDxf( ImpExpDxfWrite& writer, TechDraw::DrawViewPart* dvp, bool alignPage)
{
if(!dvp->hasGeometry()) {
return;
}
TechDraw::GeometryObjectPtr gObj = dvp->getGeometryObject();
if (!gObj) {
// this test might be redundent here since we already checked hasGeometry.
Base::Console().Message("TechDraw: %s has no geometry object!\n", dvp->Label.getValue());
return;
}
TopoDS_Shape shape = ShapeUtils::mirrorShape(gObj->getVisHard());
double offX = 0.0;
double offY = 0.0;
if (dvp->isDerivedFrom<TechDraw::DrawProjGroupItem>()) {
TechDraw::DrawProjGroupItem* dpgi = static_cast<TechDraw::DrawProjGroupItem*>(dvp);
TechDraw::DrawProjGroup* dpg = dpgi->getPGroup();
if (dpg) {
offX = dpg->X.getValue();
offY = dpg->Y.getValue();
}
}
double dvpX(0.0);
double dvpY(0.0);
if (alignPage) {
dvpX = dvp->X.getValue() + offX;
dvpY = dvp->Y.getValue() + offY;
}
gp_Trsf xLate;
xLate.SetTranslation(gp_Vec(dvpX, dvpY, 0.0));
BRepBuilderAPI_Transform mkTrf(shape, xLate);
shape = mkTrf.Shape();
writer.exportShape(shape);
shape = ShapeUtils::mirrorShape(gObj->getVisOutline());
mkTrf.Perform(shape);
shape = mkTrf.Shape();
writer.exportShape(shape);
if (dvp->SmoothVisible.getValue()) {
shape = ShapeUtils::mirrorShape(gObj->getVisSmooth());
mkTrf.Perform(shape);
shape = mkTrf.Shape();
writer.exportShape(shape);
}
if (dvp->SeamVisible.getValue()) {
shape = ShapeUtils::mirrorShape(gObj->getVisSeam());
mkTrf.Perform(shape);
shape = mkTrf.Shape();
writer.exportShape(shape);
}
if (dvp->HardHidden.getValue()) {
shape = ShapeUtils::mirrorShape(gObj->getHidHard());
mkTrf.Perform(shape);
shape = mkTrf.Shape();
writer.exportShape(shape);
shape = ShapeUtils::mirrorShape(gObj->getHidOutline());
mkTrf.Perform(shape);
shape = mkTrf.Shape();
writer.exportShape(shape);
}
if (dvp->SmoothHidden.getValue()) {
shape = ShapeUtils::mirrorShape(gObj->getHidSmooth());
mkTrf.Perform(shape);
shape = mkTrf.Shape();
writer.exportShape(shape);
}
if (dvp->SeamHidden.getValue()) {
shape = ShapeUtils::mirrorShape(gObj->getHidSeam());
mkTrf.Perform(shape);
shape = mkTrf.Shape();
writer.exportShape(shape);
}
//add the cosmetic edges also
std::vector<TechDraw::BaseGeomPtr> geoms = dvp->getEdgeGeometry();
std::vector<TopoDS_Edge> cosmeticEdges;
for (auto& g : geoms) {
if (g->getHlrVisible() && g->getCosmetic()) {
cosmeticEdges.push_back(g->getOCCEdge());
}
}
if (!cosmeticEdges.empty()) {
shape = ShapeUtils::mirrorShape(DrawUtil::vectorToCompound(cosmeticEdges));
mkTrf.Perform(shape);
shape = mkTrf.Shape();
writer.exportShape(shape);
}
}
Py::Object writeDXFView(const Py::Tuple& args)
{
PyObject *viewObj(nullptr);
char* name(nullptr);
PyObject *alignObj = Py_True;
if (!PyArg_ParseTuple(args.ptr(), "Oet|O", &viewObj, "utf-8", &name, &alignObj)) {
throw Py::TypeError("expected (view, path");
}
std::string filePath = std::string(name);
std::string layerName = "none";
PyMem_Free(name);
bool align = false;
if (alignObj == Py_True) {
align = true;
}
try {
ImpExpDxfWrite writer(filePath);
writer.init();
App::DocumentObject* obj = nullptr;
TechDraw::DrawViewPart* dvp = nullptr;
if (PyObject_TypeCheck(viewObj, &(TechDraw::DrawViewPartPy::Type))) {
obj = static_cast<App::DocumentObjectPy*>(viewObj)->getDocumentObjectPtr();
dvp = static_cast<TechDraw::DrawViewPart*>(obj);
layerName = dvp->getNameInDocument();
writer.setLayerName(layerName);
write1ViewDxf(writer, dvp, align);
}
writer.endRun();
}
catch (const Base::Exception& e) {
throw Py::RuntimeError(e.what());
}
return Py::None();
}
Py::Object writeDXFPage(const Py::Tuple& args)
{
PyObject *pageObj(nullptr);
char* name(nullptr);
if (!PyArg_ParseTuple(args.ptr(), "Oet", &pageObj, "utf-8", &name)) {
throw Py::TypeError("expected (page, path");
}
std::string filePath = std::string(name);
std::string layerName = "none";
PyMem_Free(name);
try {
ImpExpDxfWrite writer(filePath);
writer.init();
App::DocumentObject* obj = nullptr;
TechDraw::DrawPage* dPage = nullptr;
if (PyObject_TypeCheck(pageObj, &(TechDraw::DrawPagePy::Type))) {
obj = static_cast<App::DocumentObjectPy*>(pageObj)->getDocumentObjectPtr();
dPage = static_cast<TechDraw::DrawPage*>(obj);
auto views = dPage->getAllViews();
for (auto& view : views) {
if (view->isDerivedFrom<TechDraw::DrawViewPart>()) {
TechDraw::DrawViewPart* dvp = static_cast<TechDraw::DrawViewPart*>(view);
layerName = dvp->getNameInDocument();
writer.setLayerName(layerName);
write1ViewDxf(writer, dvp, true);
} else if (view->isDerivedFrom<TechDraw::DrawViewAnnotation>()) {
TechDraw::DrawViewAnnotation* dva = static_cast<TechDraw::DrawViewAnnotation*>(view);
layerName = dva->getNameInDocument();
writer.setLayerName(layerName);
double height = dva->TextSize.getValue(); //mm
int just = 1; //centered
Base::Vector3d loc(dva->X.getValue(), dva->Y.getValue(), 0.0);
auto lines = dva->Text.getValues();
writer.exportText(lines[0].c_str(), loc, loc, height, just);
} else if (view->isDerivedFrom<TechDraw::DrawViewDimension>()) {
DrawViewDimension* dvd = static_cast<TechDraw::DrawViewDimension*>(view);
TechDraw::DrawViewPart* dvp = dvd->getViewPart();
if (!dvp) {
continue;
}
double grandParentX = 0.0;
double grandParentY = 0.0;
if (dvp->isDerivedFrom<TechDraw::DrawProjGroupItem>()) {
TechDraw::DrawProjGroupItem* dpgi = static_cast<TechDraw::DrawProjGroupItem*>(dvp);
TechDraw::DrawProjGroup* dpg = dpgi->getPGroup();
if (!dpg) {
continue;
}
grandParentX = dpg->X.getValue();
grandParentY = dpg->Y.getValue();
}
double parentX = dvp->X.getValue() + grandParentX;
double parentY = dvp->Y.getValue() + grandParentY;
Base::Vector3d parentPos(parentX, parentY, 0.0);
std::string sDimText;
//this is the same code as in QGIViewDimension::updateDim
if (dvd->isMultiValueSchema()) {
sDimText = dvd->getFormattedDimensionValue(DimensionFormatter::Format::UNALTERED); //don't format multis
} else {
sDimText = dvd->getFormattedDimensionValue(DimensionFormatter::Format::FORMATTED);
}
char* dimText = &sDimText[0u]; //hack for const-ness
float gap = 5.0; //hack. don't know font size here.
layerName = dvd->getNameInDocument();
writer.setLayerName(layerName);
int type = 0; //Aligned/Distance
if ( dvd->Type.isValue("Distance") ||
dvd->Type.isValue("DistanceX") ||
dvd->Type.isValue("DistanceY") ) {
Base::Vector3d textLocn(dvd->X.getValue() + parentX, dvd->Y.getValue() + parentY, 0.0);
Base::Vector3d lineLocn(dvd->X.getValue() + parentX, dvd->Y.getValue() + parentY, 0.0);
pointPair pts = dvd->getLinearPoints();
Base::Vector3d dimLine = pts.first() - pts.second();
Base::Vector3d norm(-dimLine.y, dimLine.x, 0.0);
norm.Normalize();
lineLocn = lineLocn + (norm * gap);
Base::Vector3d extLine1Start = Base::Vector3d(pts.first().x, - pts.first().y, 0.0) +
Base::Vector3d(parentX, parentY, 0.0);
Base::Vector3d extLine2Start = Base::Vector3d(pts.second().x, - pts.second().y, 0.0) +
Base::Vector3d(parentX, parentY, 0.0);
if (dvd->Type.isValue("DistanceX") ) {
type = 1;
} else if (dvd->Type.isValue("DistanceY") ) {
type = 2;
}
writer.exportLinearDim(textLocn, lineLocn, extLine1Start, extLine2Start, dimText, type);
} else if (dvd->Type.isValue("Angle")) {
Base::Vector3d textLocn(dvd->X.getValue() + parentX, dvd->Y.getValue() + parentY, 0.0);
Base::Vector3d lineLocn(dvd->X.getValue() + parentX, dvd->Y.getValue() + parentY, 0.0);
anglePoints pts = dvd->getAnglePoints();
Base::Vector3d end1 = pts.first();
end1.y = -end1.y;
Base::Vector3d end2 = pts.second();
end2.y = -end2.y;
Base::Vector3d apex = pts.vertex();
apex.y = -apex.y;
apex = apex + parentPos;
Base::Vector3d dimLine = end2 - end1;
Base::Vector3d norm(-dimLine.y, dimLine.x, 0.0);
norm.Normalize();
lineLocn = lineLocn + (norm * gap);
end1 = end1 + parentPos;
end2 = end2 + parentPos;
writer.exportAngularDim(textLocn, lineLocn, end1, end2, apex, dimText);
} else if (dvd->Type.isValue("Radius")) {
Base::Vector3d textLocn(dvd->X.getValue() + parentX, dvd->Y.getValue() + parentY, 0.0);
arcPoints pts = dvd->getArcPoints();
pointPair arrowPts = dvd->getArrowPositions();
Base::Vector3d center = pts.center;
center.y = -center.y;
center = center + parentPos;
Base::Vector3d lineDir = (arrowPts.first() - arrowPts.second()).Normalize();
Base::Vector3d arcPoint = center + lineDir * pts.radius;
writer.exportRadialDim(center, textLocn, arcPoint, dimText);
} else if(dvd->Type.isValue("Diameter")){
Base::Vector3d textLocn(dvd->X.getValue() + parentX, dvd->Y.getValue() + parentY, 0.0);
arcPoints pts = dvd->getArcPoints();
pointPair arrowPts = dvd->getArrowPositions();
Base::Vector3d center = pts.center;
center.y = -center.y;
center = center + parentPos;
Base::Vector3d lineDir = (arrowPts.first() - arrowPts.second()).Normalize();
Base::Vector3d end1 = center + lineDir * pts.radius;
Base::Vector3d end2 = center - lineDir * pts.radius;
writer.exportDiametricDim(textLocn, end1, end2, dimText);
}
}
}
}
writer.endRun();
}
catch (const Base::Exception& e) {
throw Py::RuntimeError(e.what());
}
return Py::None();
}
Py::Object findCentroid(const Py::Tuple& args)
{
PyObject *pcObjShape(nullptr);
PyObject *pcObjDir(nullptr);
if (!PyArg_ParseTuple(args.ptr(), "OO", &pcObjShape,
&pcObjDir)) {
throw Py::TypeError("expected (shape, direction");
}
if (!PyObject_TypeCheck(pcObjShape, &(TopoShapePy::Type))) {
throw Py::TypeError("expected arg1 to be 'Shape'");
}
if (!PyObject_TypeCheck(pcObjDir, &(Base::VectorPy::Type))) {
throw Py::TypeError("expected arg2 to be 'Vector'");
}
TopoShapePy* pShape = static_cast<TopoShapePy*>(pcObjShape);
if (!pShape) {
Base::Console().Error("ShapeUtils::findCentroid - input shape is null\n");
return Py::None();
}
const TopoDS_Shape& shape = pShape->getTopoShapePtr()->getShape();
Base::Vector3d dir = static_cast<Base::VectorPy*>(pcObjDir)->value();
Base::Vector3d centroid = ShapeUtils::findCentroidVec(shape, dir);
PyObject* result = new Base::VectorPy(new Base::Vector3d(centroid));
return Py::asObject(result);
}
Py::Object makeExtentDim(const Py::Tuple& args)
{
PyObject* pDvp(nullptr);
PyObject* pEdgeList(nullptr);
int direction = 0; //Horizontal
TechDraw::DrawViewPart* dvp = nullptr;
if (!PyArg_ParseTuple(args.ptr(), "OO!i", &pDvp, &(PyList_Type), &pEdgeList, &direction)) {
throw Py::TypeError("expected (DrawViewPart, listofedgesnames, direction");
}
if (PyObject_TypeCheck(pDvp, &(TechDraw::DrawViewPartPy::Type))) {
App::DocumentObject* obj = static_cast<App::DocumentObjectPy*>(pDvp)->getDocumentObjectPtr();
dvp = static_cast<TechDraw::DrawViewPart*>(obj);
}
std::vector<std::string> edgeList;
try {
Py::Sequence list(pEdgeList);
for (Py::Sequence::iterator it = list.begin(); it != list.end(); ++it) {
if (PyUnicode_Check((*it).ptr())) {
std::string temp = PyUnicode_AsUTF8((*it).ptr());
edgeList.push_back(temp);
}
}
}
catch (Standard_Failure& e) {
throw Py::Exception(Part::PartExceptionOCCError, e.GetMessageString());
}
DrawViewDimension* dvde =
DrawDimHelper::makeExtentDim(dvp,
edgeList,
direction);
if (!dvde){
return Py::None();
}
PyObject* dvdePy = dvde->getPyObject();
return Py::asObject(dvdePy);
}
Py::Object makeDistanceDim(const Py::Tuple& args)
{
//points come in unscaled, but makeDistDim unscales them so we need to prescale here.
//makeDistDim was built for extent dims which work from scaled geometry
PyObject* pDvp(nullptr);
PyObject* pDimType(nullptr);
PyObject* pFrom(nullptr);
PyObject* pTo(nullptr);
TechDraw::DrawViewPart* dvp = nullptr;
std::string dimType;
Base::Vector3d from;
Base::Vector3d to;
if (!PyArg_ParseTuple(args.ptr(), "OOOO", &pDvp, &pDimType, &pFrom, &pTo)) {
throw Py::TypeError("expected (DrawViewPart, dimType, from, to");
}
//TODO: errors for all the type checks
if (PyObject_TypeCheck(pDvp, &(TechDraw::DrawViewPartPy::Type))) {
App::DocumentObject* obj = static_cast<App::DocumentObjectPy*>(pDvp)->getDocumentObjectPtr();
dvp = static_cast<TechDraw::DrawViewPart*>(obj);
}
else {
throw Py::TypeError("expected (DrawViewPart, dimType, from, to");
}
if (PyUnicode_Check(pDimType) ) {
dimType = PyUnicode_AsUTF8(pDimType);
}
if (PyObject_TypeCheck(pFrom, &(Base::VectorPy::Type))) {
from = static_cast<Base::VectorPy*>(pFrom)->value();
}
if (PyObject_TypeCheck(pTo, &(Base::VectorPy::Type))) {
to = static_cast<Base::VectorPy*>(pTo)->value();
}
DrawViewDimension* dvd =
DrawDimHelper::makeDistDim(dvp,
dimType,
DrawUtil::invertY(from),
DrawUtil::invertY(to));
PyObject* dvdPy = dvd->getPyObject();
return Py::asObject(dvdPy);
// return Py::None();
}
Py::Object makeDistanceDim3d(const Py::Tuple& args)
{
PyObject* pDvp;
PyObject* pDimType;
PyObject* pFrom;
PyObject* pTo;
TechDraw::DrawViewPart* dvp = nullptr;
std::string dimType;
Base::Vector3d from;
Base::Vector3d to;
if (!PyArg_ParseTuple(args.ptr(), "OOOO", &pDvp, &pDimType, &pFrom, &pTo)) {
throw Py::TypeError("expected (DrawViewPart, dimType, from, to");
}
//TODO: errors for all the type checks
if (PyObject_TypeCheck(pDvp, &(TechDraw::DrawViewPartPy::Type))) {
App::DocumentObject* obj = static_cast<App::DocumentObjectPy*>(pDvp)->getDocumentObjectPtr();
dvp = static_cast<TechDraw::DrawViewPart*>(obj);
}
else {
throw Py::TypeError("expected (DrawViewPart, dimType, from, to");
}
if (PyUnicode_Check(pDimType)) {
dimType = PyUnicode_AsUTF8(pDimType);
}
if (PyObject_TypeCheck(pFrom, &(Base::VectorPy::Type))) {
from = static_cast<Base::VectorPy*>(pFrom)->value();
}
if (PyObject_TypeCheck(pTo, &(Base::VectorPy::Type))) {
to = static_cast<Base::VectorPy*>(pTo)->value();
}
//3d points are not scaled
from = DrawUtil::invertY(dvp->projectPoint(from));
to = DrawUtil::invertY(dvp->projectPoint(to));
//DrawViewDimension* =
DrawDimHelper::makeDistDim(dvp,
dimType,
from,
to);
return Py::None();
}
Py::Object makeGeomHatch(const Py::Tuple& args)
{
PyObject* pFace(nullptr);
double scale = 1.0;
const char* pPatName = {nullptr};
const char* pPatFile = {nullptr};
TechDraw::DrawViewPart* source = nullptr;
TopoDS_Face face;
if (!PyArg_ParseTuple(args.ptr(), "O|dss", &pFace, &scale, &pPatName, &pPatFile)) {
throw Py::TypeError("expected (face, [scale], [patName], [patFile])");
}
std::string patName = std::string(pPatName);
std::string patFile = std::string(pPatFile);
if (PyObject_TypeCheck(pFace, &(TopoShapeFacePy::Type))) {
const TopoDS_Shape& shape = static_cast<TopoShapePy*>(pFace)->getTopoShapePtr()->getShape();
face = TopoDS::Face(shape);
}
else {
throw Py::TypeError("first argument must be a Part.Face instance");
}
if (patName.empty()) {
patName = TechDraw::DrawGeomHatch::prefGeomHatchName();
}
if (patFile.empty()) {
patFile = TechDraw::DrawGeomHatch::prefGeomHatchFile();
}
Base::FileInfo fi(patFile);
if (!fi.isReadable()) {
Base::Console().Error(".pat File: %s is not readable\n", patFile.c_str());
return Py::None();
}
std::vector<TechDraw::PATLineSpec> specs = TechDraw::DrawGeomHatch::getDecodedSpecsFromFile(patFile, patName);
std::vector<LineSet> lineSets;
for (auto& hLine : specs) {
TechDraw::LineSet lSet;
lSet.setPATLineSpec(hLine);
lineSets.push_back(lSet);
}
std::vector<LineSet> lsresult = TechDraw::DrawGeomHatch::getTrimmedLines(source, lineSets, face, scale);
if (!lsresult.empty()) {
/* below code returns a list of edges, but probably slower to handle
Py::List result;
try {
for (auto& lsr:lsresult) {
std::vector<TopoDS_Edge> edgeList = lsr.getEdges();
for (auto& edge:edgeList) {
PyObject* pyedge = new TopoShapeEdgePy(new TopoShape(edge));
result.append(Py::asObject(pyedge));
}
}
}
catch (Base::Exception &e) {
e.setPyException();
throw Py::Exception();
}
return result;
*/
BRep_Builder builder;
TopoDS_Compound comp;
builder.MakeCompound(comp);
try {
for (auto& lsr : lsresult) {
std::vector<TopoDS_Edge> edgeList = lsr.getEdges();
for (auto& edge : edgeList) {
if (!edge.IsNull()) {
builder.Add(comp, edge);
}
}
}
}
catch (Base::Exception &e) {
e.setPyException();
throw Py::Exception();
}
PyObject* pycomp = new TopoShapeCompoundPy(new TopoShape(comp));
return Py::asObject(pycomp);
}
return Py::None();
}
Py::Object project(const Py::Tuple& args)
{
PyObject *pcObjShape(nullptr);
PyObject *pcObjDir(nullptr);
if (!PyArg_ParseTuple(args.ptr(), "O!|O!",
&(Part::TopoShapePy::Type), &pcObjShape,
&(Base::VectorPy::Type), &pcObjDir))
throw Py::Exception();
Part::TopoShapePy* pShape = static_cast<Part::TopoShapePy*>(pcObjShape);
Base::Vector3d Vector(0, 0,1);
if (pcObjDir)
Vector = *static_cast<Base::VectorPy*>(pcObjDir)->getVectorPtr();
ProjectionAlgos Alg(pShape->getTopoShapePtr()->getShape(), Vector);
Py::List list;
list.append(Py::Object(new Part::TopoShapePy(new Part::TopoShape(Alg.V)) , true));
list.append(Py::Object(new Part::TopoShapePy(new Part::TopoShape(Alg.V1)), true));
list.append(Py::Object(new Part::TopoShapePy(new Part::TopoShape(Alg.H)) , true));
list.append(Py::Object(new Part::TopoShapePy(new Part::TopoShape(Alg.H1)), true));
return list;
}
Py::Object projectEx(const Py::Tuple& args)
{
PyObject *pcObjShape(nullptr);
PyObject *pcObjDir(nullptr);
if (!PyArg_ParseTuple(args.ptr(), "O!|O!",
&(TopoShapePy::Type), &pcObjShape,
&(Base::VectorPy::Type), &pcObjDir))
throw Py::Exception();
TopoShapePy* pShape = static_cast<TopoShapePy*>(pcObjShape);
Base::Vector3d Vector(0, 0,1);
if (pcObjDir)
Vector = *static_cast<Base::VectorPy*>(pcObjDir)->getVectorPtr();
ProjectionAlgos Alg(pShape->getTopoShapePtr()->getShape(), Vector);
Py::List list;
list.append(Py::Object(new TopoShapePy(new TopoShape(Alg.V)) , true));
list.append(Py::Object(new TopoShapePy(new TopoShape(Alg.V1)), true));
list.append(Py::Object(new TopoShapePy(new TopoShape(Alg.VN)), true));
list.append(Py::Object(new TopoShapePy(new TopoShape(Alg.VO)), true));
list.append(Py::Object(new TopoShapePy(new TopoShape(Alg.VI)), true));
list.append(Py::Object(new TopoShapePy(new TopoShape(Alg.H)) , true));
list.append(Py::Object(new TopoShapePy(new TopoShape(Alg.H1)), true));
list.append(Py::Object(new TopoShapePy(new TopoShape(Alg.HN)), true));
list.append(Py::Object(new TopoShapePy(new TopoShape(Alg.HO)), true));
list.append(Py::Object(new TopoShapePy(new TopoShape(Alg.HI)), true));
return list;
}
Py::Object projectToSVG(const Py::Tuple& args, const Py::Dict& keys)
{
static const std::array<const char *, 11> argNames{"topoShape", "direction", "type", "tolerance", "vStyle",
"v0Style", "v1Style", "hStyle", "h0Style", "h1Style",
nullptr};
PyObject *pcObjShape = nullptr;
PyObject *pcObjDir = nullptr;
const char *extractionTypePy = nullptr;
ProjectionAlgos::ExtractionType extractionType = ProjectionAlgos::Plain;
const float tol = 0.1f;
PyObject* vStylePy = nullptr;
ProjectionAlgos::XmlAttributes vStyle;
PyObject* v0StylePy = nullptr;
ProjectionAlgos::XmlAttributes v0Style;
PyObject* v1StylePy = nullptr;
ProjectionAlgos::XmlAttributes v1Style;
PyObject* hStylePy = nullptr;
ProjectionAlgos::XmlAttributes hStyle;
PyObject* h0StylePy = nullptr;
ProjectionAlgos::XmlAttributes h0Style;
PyObject* h1StylePy = nullptr;
ProjectionAlgos::XmlAttributes h1Style;
// Get the arguments
if (!Base::Wrapped_ParseTupleAndKeywords(
args.ptr(), keys.ptr(),
"O!|O!sfOOOOOO",
argNames,
&(TopoShapePy::Type), &pcObjShape,
&(Base::VectorPy::Type), &pcObjDir,
&extractionTypePy, &tol,
&vStylePy, &v0StylePy, &v1StylePy,
&hStylePy, &h0StylePy, &h1StylePy)) {
throw Py::Exception();
}
// Convert all arguments into the right format
TopoShapePy* pShape = static_cast<TopoShapePy*>(pcObjShape);
Base::Vector3d directionVector(0, 0,1);
if (pcObjDir)
directionVector = static_cast<Base::VectorPy*>(pcObjDir)->value();
if (extractionTypePy && std::string(extractionTypePy) == "ShowHiddenLines")
extractionType = ProjectionAlgos::WithHidden;
if (vStylePy)
copy(Py::Dict(vStylePy), inserter(vStyle, vStyle.begin()));
if (v0StylePy)
copy(Py::Dict(v0StylePy), inserter(v0Style, v0Style.begin()));
if (v1StylePy)
copy(Py::Dict(v1StylePy), inserter(v1Style, v1Style.begin()));
if (hStylePy)
copy(Py::Dict(hStylePy), inserter(hStyle, hStyle.begin()));
if (h0StylePy)
copy(Py::Dict(h0StylePy), inserter(h0Style, h0Style.begin()));
if (h1StylePy)
copy(Py::Dict(h1StylePy), inserter(h1Style, h1Style.begin()));
// Execute the SVG generation
ProjectionAlgos Alg(pShape->getTopoShapePtr()->getShape(),
directionVector);
Py::String result(Alg.getSVG(extractionType, tol,
vStyle, v0Style, v1Style,
hStyle, h0Style, h1Style));
return result;
}
Py::Object projectToDXF(const Py::Tuple& args)
{
PyObject *pcObjShape(nullptr);
PyObject *pcObjDir=nullptr;
const char *type=nullptr;
float scale=1.0f;
float tol=0.1f;
if (!PyArg_ParseTuple(args.ptr(), "O!|O!sff",
&(TopoShapePy::Type), &pcObjShape,
&(Base::VectorPy::Type), &pcObjDir, &type, &scale, &tol))
throw Py::Exception();
TopoShapePy* pShape = static_cast<TopoShapePy*>(pcObjShape);
Base::Vector3d Vector(0, 0,1);
if (pcObjDir)
Vector = static_cast<Base::VectorPy*>(pcObjDir)->value();
ProjectionAlgos Alg(pShape->getTopoShapePtr()->getShape(), Vector);
bool hidden = false;
if (type && std::string(type) == "ShowHiddenLines")
hidden = true;
Py::String result(Alg.getDXF(hidden?ProjectionAlgos::WithHidden:ProjectionAlgos::Plain, scale, tol));
return result;
}
Py::Object removeSvgTags(const Py::Tuple& args)
{
const char* svgcode;
if (!PyArg_ParseTuple(args.ptr(), "s", &svgcode))
throw Py::Exception();
std::string svg(svgcode);
std::string empty;
std::string endline = "--endOfLine--";
std::string linebreak = "\\n";
// removing linebreaks for regex to work
boost::regex e1 ("\\n");
svg = boost::regex_replace(svg, e1, endline);
// removing starting xml definition
boost::regex e2 ("<\\?xml.*?\\?>");
svg = boost::regex_replace(svg, e2, empty);
// removing starting svg tag
boost::regex e3 ("<svg.*?>");
svg = boost::regex_replace(svg, e3, empty);
// removing sodipodi tags -- DANGEROUS, some sodipodi tags are single, better leave it
//boost::regex e4 ("<sodipodi.*?>");
//svg = boost::regex_replace(svg, e4, empty);
// removing metadata tags
boost::regex e5 ("<metadata.*?</metadata>");
svg = boost::regex_replace(svg, e5, empty);
// removing closing svg tags
boost::regex e6 ("</svg>");
svg = boost::regex_replace(svg, e6, empty);
// restoring linebreaks
boost::regex e7 ("--endOfLine--");
svg = boost::regex_replace(svg, e7, linebreak);
Py::String result(svg);
return result;
}
Py::Object exportSVGEdges(const Py::Tuple& args)
{
PyObject *pcObjShape(nullptr);
if (!PyArg_ParseTuple(args.ptr(), "O!",
&(TopoShapePy::Type), &pcObjShape))
throw Py::Exception();
TopoShapePy* pShape = static_cast<TopoShapePy*>(pcObjShape);
SVGOutput output;
Py::String result(output.exportEdges(pShape->getTopoShapePtr()->getShape()));
return result;
}
Py::Object build3dCurves(const Py::Tuple& args)
{
PyObject *pcObjShape(nullptr);
if (!PyArg_ParseTuple(args.ptr(), "O!",
&(TopoShapePy::Type), &pcObjShape))
throw Py::Exception();
TopoShapePy* pShape = static_cast<TopoShapePy*>(pcObjShape);
const TopoShape& nShape =
TechDraw::build3dCurves(pShape->getTopoShapePtr()->getShape());
return Py::Object(new TopoShapePy(new TopoShape(nShape)));
}
Py::Object makeCanonicalPoint(const Py::Tuple& args)
{
PyObject* pyDocObj{nullptr};
PyObject* pyPointIn{nullptr};
PyObject *pyUnscale{Py_True};
if (!PyArg_ParseTuple(args.ptr(), "O!O!|O", &(TechDraw::DrawViewPartPy::Type), &pyDocObj,
&(Base::VectorPy::Type), &pyPointIn, &pyUnscale)) {
return Py::None();
}
bool unscale = pyUnscale == Py_True ? true : false;
DrawViewPartPy* pyDvp = static_cast<TechDraw::DrawViewPartPy*>(pyDocObj);
DrawViewPart* dvp = pyDvp->getDrawViewPartPtr();
Base::Vector3d cPoint = static_cast<Base::VectorPy*>(pyPointIn)->value();
cPoint = CosmeticVertex::makeCanonicalPoint(dvp, cPoint, unscale);
return Py::asObject(new Base::VectorPy(cPoint));
}
Py::Object makeLeader(const Py::Tuple& args)
{
PyObject* pDvp(nullptr);
PyObject* pPointList(nullptr);
int iStartSymbol = 0;
int iEndSymbol = 0;
TechDraw::DrawViewPart* dvp = nullptr;
if (!PyArg_ParseTuple(args.ptr(), "OO!|ii", &pDvp, &(PyList_Type), &pPointList, &iStartSymbol, &iEndSymbol)) {
throw Py::TypeError("expected (DrawViewPart, listofpoints, startsymbolindex, endsymbolindex");
}
if (PyObject_TypeCheck(pDvp, &(TechDraw::DrawViewPartPy::Type))) {
App::DocumentObject* obj = static_cast<App::DocumentObjectPy*>(pDvp)->getDocumentObjectPtr();
dvp = static_cast<TechDraw::DrawViewPart*>(obj);
}
std::vector<Base::Vector3d> pointList;
try {
Py::Sequence list(pPointList);
for (Py::Sequence::iterator it = list.begin(); it != list.end(); ++it) {
if (PyObject_TypeCheck((*it).ptr(), &(Base::VectorPy::Type))) {
Base::Vector3d temp = static_cast<Base::VectorPy*>((*it).ptr())->value();
pointList.push_back(temp);
}
}
}
catch (Standard_Failure& e) {
throw Py::Exception(Part::PartExceptionOCCError, e.GetMessageString());
}
auto newLeader = DrawLeaderLine::makeLeader(dvp, pointList, iStartSymbol, iEndSymbol);
// return the new leader as DrawLeaderPy
return Py::asObject(new DrawLeaderLinePy(newLeader));
}
};
PyObject* initModule()
{
return Base::Interpreter().addModule(new Module);
}
} // namespace TechDraw
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