+
+
+void test_HYDROData_LandCoverMap::test_merge_faces_circles()
+{
+ TopoDS_Shape ff1, ff2, ff3;
+ BRep_Builder BB;
+ BRepTools::Read(ff1, (REF_DATA_PATH + "/ff1.brep").toStdString().c_str(), BB);
+ BRepTools::Read(ff2, (REF_DATA_PATH + "/ff2.brep").toStdString().c_str(), BB);
+ BRepTools::Read(ff3, (REF_DATA_PATH + "/ff3.brep").toStdString().c_str(), BB);
+
+ CPPUNIT_ASSERT(!ff1.IsNull());
+ CPPUNIT_ASSERT(!ff2.IsNull());
+ CPPUNIT_ASSERT(!ff3.IsNull());
+
+ //Test mergeFaces() func // circles // USD == true
+ {
+ TopTools_ListOfShape Faces;
+ Faces.Append(ff1);
+ Faces.Append(ff2);
+ TopoDS_Shape aMergedFace = HYDROData_LandCoverMap::MergeFaces( Faces, true );
+ TestViewer::show( aMergedFace, AIS_Shaded, true, "merge_faces_circles_11" );
+ CPPUNIT_ASSERT_IMAGES
+ CPPUNIT_ASSERT(aMergedFace.ShapeType() == TopAbs_FACE);
+ }
+ {
+ TopTools_ListOfShape Faces;
+ Faces.Append(ff1);
+ Faces.Append(ff3);
+ TopoDS_Shape aMergedFace = HYDROData_LandCoverMap::MergeFaces( Faces, true );
+ TestViewer::show( aMergedFace, AIS_Shaded, true, "merge_faces_circles_12" );
+ CPPUNIT_ASSERT_IMAGES
+ CPPUNIT_ASSERT(aMergedFace.ShapeType() == TopAbs_SHELL);
+ }
+ {
+ TopTools_ListOfShape Faces;
+ Faces.Append(ff1);
+ Faces.Append(ff2);
+ Faces.Append(ff3);
+ TopoDS_Shape aMergedFace = HYDROData_LandCoverMap::MergeFaces( Faces, true );
+ TestViewer::show( aMergedFace, AIS_Shaded, true, "merge_faces_circles_13" );
+ CPPUNIT_ASSERT_IMAGES
+ CPPUNIT_ASSERT(aMergedFace.ShapeType() == TopAbs_SHELL);
+ }
+ {
+ TopTools_ListOfShape Faces;
+ Faces.Append(ff1);
+ Faces.Append(ff3);
+ Faces.Append(ff2);
+ TopoDS_Shape aMergedFace = HYDROData_LandCoverMap::MergeFaces( Faces, true );
+ TestViewer::show( aMergedFace, AIS_Shaded, true, "merge_faces_circles_14" );
+ CPPUNIT_ASSERT_IMAGES
+ CPPUNIT_ASSERT(aMergedFace.ShapeType() == TopAbs_SHELL);
+ }
+ //
+
+ //Test mergeFaces() func // circles // USD == false
+ {
+ TopTools_ListOfShape Faces;
+ Faces.Append(ff1);
+ Faces.Append(ff2);
+ TopoDS_Shape aMergedFace = HYDROData_LandCoverMap::MergeFaces( Faces, false );
+ TestViewer::show( aMergedFace, AIS_Shaded, true, "merge_faces_circles_21" );
+ CPPUNIT_ASSERT_IMAGES
+ CPPUNIT_ASSERT(aMergedFace.ShapeType() == TopAbs_SHELL);
+ }
+ {
+ TopTools_ListOfShape Faces;
+ Faces.Append(ff1);
+ Faces.Append(ff3);
+ TopoDS_Shape aMergedFace = HYDROData_LandCoverMap::MergeFaces( Faces, false );
+ TestViewer::show( aMergedFace, AIS_Shaded, true, "merge_faces_circles_22" );
+ CPPUNIT_ASSERT_IMAGES
+ CPPUNIT_ASSERT(aMergedFace.ShapeType() == TopAbs_SHELL);
+ }
+ {
+ TopTools_ListOfShape Faces;
+ Faces.Append(ff1);
+ Faces.Append(ff2);
+ Faces.Append(ff3);
+ TopoDS_Shape aMergedFace = HYDROData_LandCoverMap::MergeFaces( Faces, false );
+ TestViewer::show( aMergedFace, AIS_Shaded, true, "merge_faces_circles_23" );
+ CPPUNIT_ASSERT_IMAGES
+ CPPUNIT_ASSERT(aMergedFace.ShapeType() == TopAbs_SHELL);
+ }
+ {
+ TopTools_ListOfShape Faces;
+ Faces.Append(ff1);
+ Faces.Append(ff3);
+ Faces.Append(ff2);
+ TopoDS_Shape aMergedFace = HYDROData_LandCoverMap::MergeFaces( Faces, false );
+ TestViewer::show( aMergedFace, AIS_Shaded, true, "merge_faces_circles_24" );
+ CPPUNIT_ASSERT_IMAGES
+ CPPUNIT_ASSERT(aMergedFace.ShapeType() == TopAbs_SHELL);
+ }
+
+}
+
+void test_HYDROData_LandCoverMap::test_import_dbf()
+{
+ Handle(HYDROData_Document) aDoc = HYDROData_Document::Document(1);
+
+ Handle(HYDROData_LandCoverMap) aMap =
+ Handle(HYDROData_LandCoverMap)::DownCast( aDoc->CreateObject( KIND_LAND_COVER_MAP ) );
+
+ CPPUNIT_ASSERT_EQUAL( KIND_LAND_COVER_MAP, aMap->GetKind() );
+ QString aFileName = REF_DATA_PATH + "/t1.dbf";
+ QStringList aDBFV;
+ QStringList aST;
+ aDBFV.append("100");
+ aDBFV.append("200");
+ aDBFV.append("300");
+ aST.append("water");
+ aST.append("forest");
+ aST.append("road");
+ // aST.size() == aDBFV.size()!!
+ Handle(HYDROData_PolylineXY) aPolyline =
+ Handle(HYDROData_PolylineXY)::DownCast( aDoc->CreateObject( KIND_POLYLINEXY ) );
+ TopoDS_Wire aWire = Wire( QList<double>() << 10 << 40 << 30 << 10 << 40 << 10 << 60 << 10 );
+ aPolyline->SetShape( aWire );
+ for (int i = 0; i < 3; i++)
+ aMap->Add(aPolyline, "");
+ TopoDS_Face aLC1 = Face( QList<double>() << 10 << 10 << 50 << 20 << 30 << 50 << 15 << 30 );
+ CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC1, "test1" ) );
+
+ CPPUNIT_ASSERT_EQUAL( true, aMap->Split( aPolyline ) );
+ QList<int> Inds = QList<int>() << 1 << 2 << 3;
+ aMap->ImportDBF(aFileName, "TESTFIELD1", aDBFV, aST, Inds);
+ HYDROData_LandCoverMap::Iterator anIt( aMap );
+
+ CPPUNIT_ASSERT_EQUAL( QString( "forest" ), anIt.StricklerType() );
+ anIt.Next();
+ CPPUNIT_ASSERT_EQUAL( QString( "road" ), anIt.StricklerType() );
+}
+
+void test_HYDROData_LandCoverMap::test_land_cover_prs_by_types()
+{
+ Handle(HYDROData_Document) aDoc = HYDROData_Document::Document(1);
+
+ Handle(HYDROData_StricklerTable) aTable =
+ Handle(HYDROData_StricklerTable)::DownCast( aDoc->CreateObject( KIND_STRICKLER_TABLE ) );
+ CPPUNIT_ASSERT_EQUAL( true, aTable->Import( DEF_STR_PATH ) );
+
+ Handle(HYDROData_LandCoverMap) aMap =
+ Handle(HYDROData_LandCoverMap)::DownCast( aDoc->CreateObject( KIND_LAND_COVER_MAP ) );
+
+ TopoDS_Face aLC1 = Face( QList<double>() << 12 << 19 << 82 << 9 << 126 << 53 << 107 << 80 << 29 << 75 );
+ CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC1, "Zones de champs cultivé à végétation basse" ) );
+
+ TopoDS_Face aLC2 = Face( QList<double>() << 21 << 34 << 24 << 25 << 37 << 37 << 40 << 61 <<
+ 44 << 95 << 85 << 100 << 104 << 66 << 107 << 33 <<
+ 128 << 18 << 140 << 50 << 131 << 89 << 104 << 111 <<
+ 31 << 114 );
+ CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC2, "Zones de champs cultivé à végétation haute" ) );
+
+ TopoDS_Face aLC3 = Face( QList<double>() << 4 << 54 << 1 << 47 << 51 << 45 <<
+ 127 << 42 << 145 << 43 << 148 << 60 << 90 << 65 );
+ CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC3, "Zones de champs, prairies, sans cultures" ) );
+
+ // build presentation object
+ Handle(HYDROGUI_LandCoverMapPrs) aPrs = new HYDROGUI_LandCoverMapPrs( aMap );
+ aPrs->SetTable( aTable );
+ // show presentation in viewer
+ TestViewer::show( aPrs, AIS_Shaded, 4, true, "LandCoverMap_PrsByTypes" );
+ // select one of faces (first)
+ TestViewer::select( 200, 300 );
+ CPPUNIT_ASSERT_IMAGES
+
+ aDoc->Close();
+}
+
+void test_HYDROData_LandCoverMap::test_land_cover_prs_by_coeff()
+{
+ Handle(HYDROData_Document) aDoc = HYDROData_Document::Document(1);
+
+ Handle(HYDROData_StricklerTable) aTable =
+ Handle(HYDROData_StricklerTable)::DownCast( aDoc->CreateObject( KIND_STRICKLER_TABLE ) );
+ CPPUNIT_ASSERT_EQUAL( true, aTable->Import( DEF_STR_PATH ) );
+
+ Handle(HYDROData_LandCoverMap) aMap =
+ Handle(HYDROData_LandCoverMap)::DownCast( aDoc->CreateObject( KIND_LAND_COVER_MAP ) );
+
+ TopoDS_Face aLC1 = Face( QList<double>() << 12 << 19 << 82 << 9 << 126 << 53 << 107 << 80 << 29 << 75 );
+ CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC1, "Zones de champs cultivé à végétation basse" ) );
+
+ TopoDS_Face aLC2 = Face( QList<double>() << 21 << 34 << 24 << 25 << 37 << 37 << 40 << 61 <<
+ 44 << 95 << 85 << 100 << 104 << 66 << 107 << 33 <<
+ 128 << 18 << 140 << 50 << 131 << 89 << 104 << 111 <<
+ 31 << 114 );
+ CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC2, "Zones de champs cultivé à végétation haute" ) );
+
+ TopoDS_Face aLC3 = Face( QList<double>() << 4 << 54 << 1 << 47 << 51 << 45 <<
+ 127 << 42 << 145 << 43 << 148 << 60 << 90 << 65 );
+ CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC3, "Zones de champs, prairies, sans cultures" ) );
+
+ Handle(HYDROGUI_LandCoverMapPrs) aPrs = new HYDROGUI_LandCoverMapPrs( aMap );
+ aPrs->SetTable( aTable );
+ aPrs->SetColorScale( TestViewer::showColorScale( true ) );
+ TestViewer::show( aPrs, AIS_Shaded, 4, true, "LandCoverMap_PrsByCoeff" );
+ CPPUNIT_ASSERT_IMAGES
+
+ TestViewer::showColorScale( false );
+ aDoc->Close();
+}
+
+void test_HYDROData_LandCoverMap::test_dump_python()
+{
+ Handle(HYDROData_Document) aDoc = HYDROData_Document::Document(1);
+
+ Handle(HYDROData_LandCoverMap) aMap =
+ Handle(HYDROData_LandCoverMap)::DownCast( aDoc->CreateObject( KIND_LAND_COVER_MAP ) );
+ aMap->SetName( "test_LCM" );
+
+ CPPUNIT_ASSERT_EQUAL( KIND_LAND_COVER_MAP, aMap->GetKind() );
+
+ TopoDS_Face aLC1 = Face( QList<double>() << 12 << 19 << 82 << 9 << 126 << 53 << 107 << 80 << 29 << 75 );
+
+ CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC1, "test1" ) );
+
+ TopoDS_Face aLC2 = Face( QList<double>() << 21 << 34 << 24 << 25 << 37 << 37 << 40 << 61 <<
+ 44 << 95 << 85 << 100 << 104 << 66 << 107 << 33 <<
+ 128 << 18 << 140 << 50 << 131 << 89 << 104 << 111 <<
+ 31 << 114 );
+ CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC2, "test2" ) );
+
+ TopoDS_Face aLC3 = Face( QList<double>() << 4 << 54 << 1 << 47 << 51 << 45 <<
+ 127 << 42 << 145 << 43 << 148 << 60 << 90 << 65 );
+ CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC3, "test3" ) );
+
+ QString aTmpPath = QDir::tempPath() + "/lc_dump.py";
+ CPPUNIT_ASSERT_EQUAL( true, aDoc->DumpToPython( aTmpPath, false ) );
+
+ //TODO: compare files
+}
+
+void test_HYDROData_LandCoverMap::test_transparent_prs()
+{
+ Handle(HYDROData_Document) aDoc = HYDROData_Document::Document(1);
+
+ Handle(HYDROData_StricklerTable) aTable =
+ Handle(HYDROData_StricklerTable)::DownCast( aDoc->CreateObject( KIND_STRICKLER_TABLE ) );
+ CPPUNIT_ASSERT_EQUAL( true, aTable->Import( DEF_STR_PATH ) );
+
+ Handle(HYDROData_PolylineXY) aPoly =
+ Handle(HYDROData_PolylineXY)::DownCast( aDoc->CreateObject( KIND_POLYLINEXY ) );
+ aPoly->AddSection( "", HYDROData_PolylineXY::SECTION_SPLINE, true );
+ aPoly->AddPoint( 0, gp_XY( 0, 0 ) );
+ aPoly->AddPoint( 0, gp_XY( 20, 0 ) );
+ aPoly->AddPoint( 0, gp_XY( 10, 10 ) );
+ aPoly->Update();
+
+ Handle(HYDROData_ImmersibleZone) aZone =
+ Handle(HYDROData_ImmersibleZone)::DownCast( aDoc->CreateObject( KIND_IMMERSIBLE_ZONE ) );
+ aZone->SetPolyline( aPoly );
+ aZone->Update();
+
+ Handle(HYDROData_LandCoverMap) aMap =
+ Handle(HYDROData_LandCoverMap)::DownCast( aDoc->CreateObject( KIND_LAND_COVER_MAP ) );
+ aMap->LocalPartition( Face( QList<double>() << 1 << 1 << 10 << 10 << 10 << 20 ), "Zones de champs cultivé à végétation haute" );
+ aMap->LocalPartition( Face( QList<double>() << 5 << 5 << 10 << 5 << 10 << 8 << 5 << 12 << 5 << 8 ), "Zones de champs cultivé à végétation haute" );
+ aMap->SetName( "test_LCM" );
+
+ TestViewer::show( aZone->GetTopShape(), AIS_Shaded, true, "LandCoverMap_TransparentPrs" );
+
+ Handle(HYDROGUI_LandCoverMapPrs) aPrs = new HYDROGUI_LandCoverMapPrs( aMap );
+ aPrs->SetTable( aTable );
+ aPrs->SetTransparency( 0.5 );
+ TestViewer::show( aPrs, AIS_Shaded, 0, true, "" );
+
+ CPPUNIT_ASSERT_IMAGES
+}