#include <TestShape.h>
#include <TopTools_ListOfShape.hxx>
#include <AIS_DisplayMode.hxx>
-#include <Aspect_ColorScale.hxx>
#include <BRepMesh_IncrementalMesh.hxx>
#include <QString>
#include <QColor>
#define _DEVDEBUG_
#include "HYDRO_trace.hxx"
-const QString REF_DATA_PATH = qgetenv( "HYDRO_ROOT_DIR" ) + "/bin/salome/test";
-const QString DEF_STR_PATH = qgetenv( "HYDRO_ROOT_DIR" ) + "/share/salome/resources/hydro/def_strickler_table.txt";
+extern QString REF_DATA_PATH;
+const QString DEF_STR_PATH = qgetenv( "HYDRO_ROOT_DIR" ) + "/share/salome/resources/hydro/def_strickler_table_06.txt";
+extern QString TMP_DIR;
void test_HYDROData_LandCoverMap::test_add_2_objects()
{
CPPUNIT_ASSERT_EQUAL( KIND_LAND_COVER_MAP, aMap->GetKind() );
- TopoDS_Face aLC1 = Face( QList<double>() << 10 << 10 << 50 << 20 << 30 << 50 << 15 << 30 );
+ TopoDS_Face aLC1 = Face2d( QList<double>() << 10 << 10 << 50 << 20 << 30 << 50 << 15 << 30 );
//DEBTRACE("--- ajout test1 " << aLC1);
CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC1, "test1" ) );
- TopoDS_Face aLC2 = Face( QList<double>() << 30 << 20 << 60 << 10 << 70 << 35 << 40 << 40 );
+ TopoDS_Face aLC2 = Face2d( QList<double>() << 30 << 20 << 60 << 10 << 70 << 35 << 40 << 40 );
//DEBTRACE("--- ajout test2 " << aLC2);
CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC2, "test2" ) );
CPPUNIT_ASSERT_EQUAL( KIND_LAND_COVER_MAP, aMap->GetKind() );
- TopoDS_Face aLC = Face( QList<double>() << 10 << 10 << 50 << 20 << 30 << 50 << 15 << 30 );
+ TopoDS_Face aLC = Face2d( QList<double>() << 10 << 10 << 50 << 20 << 30 << 50 << 15 << 30 );
CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC, "test1" ) );
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, false );
+ TopoDS_Wire aWire = Wire2d( QList<double>() << 10 << 40 << 30 << 10 << 40 << 10 << 60 << 10, false );
aPolyline->SetShape( aWire );
CPPUNIT_ASSERT_EQUAL( true, aMap->Split( aPolyline ) );
CPPUNIT_ASSERT_EQUAL( KIND_LAND_COVER_MAP, aMap->GetKind() );
- TopoDS_Face aLC = Face( QList<double>() << 10 << 10 << 50 << 20 << 30 << 50 << 15 << 30 );
+ TopoDS_Face aLC = Face2d( QList<double>() << 10 << 10 << 50 << 20 << 30 << 50 << 15 << 30 );
CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC, "test1" ) );
Handle(HYDROData_PolylineXY) aPolyline =
Handle(HYDROData_PolylineXY)::DownCast( aDoc->CreateObject( KIND_POLYLINEXY ) );
- TopoDS_Wire aWire = Wire( QList<double>() << 10 << 40 << 30 << 10 << 40 << 10, false );
+ TopoDS_Wire aWire = Wire2d( QList<double>() << 10 << 40 << 30 << 10 << 40 << 10, false );
aPolyline->SetShape( aWire );
CPPUNIT_ASSERT_EQUAL( false, aMap->Split( aPolyline ) );
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 );
+ TopoDS_Face aLC1 = Face2d( 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 <<
+ TopoDS_Face aLC2 = Face2d( 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 <<
+ TopoDS_Face aLC3 = Face2d( QList<double>() << 4 << 54 << 1 << 47 << 51 << 45 <<
127 << 42 << 145 << 43 << 148 << 60 << 90 << 65 );
CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC3, "test3" ) );
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 );
+ TopoDS_Face aLC1 = Face2d( 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 <<
+ TopoDS_Face aLC2 = Face2d( 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 <<
+ TopoDS_Face aLC3 = Face2d( QList<double>() << 4 << 54 << 1 << 47 << 51 << 45 <<
127 << 42 << 145 << 43 << 148 << 60 << 90 << 65 );
CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC3, "test3" ) );
// 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 );
+ TopoDS_Wire aWire = Wire2d( 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 );
+ TopoDS_Face aLC1 = Face2d( 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 ) );
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 );
+ TopoDS_Face aLC1 = Face2d( QList<double>() << 12 << 19 << 82 << 9 << 126 << 53 << 107 << 80 << 29 << 75 );
CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC1, QString::fromUtf8("Zones de champs cultivé à végétation basse")) );
- TopoDS_Face aLC2 = Face( QList<double>() << 21 << 34 << 24 << 25 << 37 << 37 << 40 << 61 <<
+ TopoDS_Face aLC2 = Face2d( 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, QString::fromUtf8("Zones de champs cultivé à végétation haute")) );
- TopoDS_Face aLC3 = Face( QList<double>() << 4 << 54 << 1 << 47 << 51 << 45 <<
+ TopoDS_Face aLC3 = Face2d( QList<double>() << 4 << 54 << 1 << 47 << 51 << 45 <<
127 << 42 << 145 << 43 << 148 << 60 << 90 << 65 );
CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC3, QString::fromUtf8("Zones de champs, prairies, sans cultures")) );
// select one of faces (first)
TestViewer::select( 200, 300 );
CPPUNIT_ASSERT_IMAGES
-
+ TestViewer::eraseAll(true, true);
aDoc->Close();
}
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 );
+ TopoDS_Face aLC1 = Face2d( QList<double>() << 12 << 19 << 82 << 9 << 126 << 53 << 107 << 80 << 29 << 75 );
CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC1, QString::fromUtf8("Zones de champs cultivé à végétation basse")) );
- TopoDS_Face aLC2 = Face( QList<double>() << 21 << 34 << 24 << 25 << 37 << 37 << 40 << 61 <<
+ TopoDS_Face aLC2 = Face2d( 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, QString::fromUtf8("Zones de champs cultivé à végétation haute")) );
- TopoDS_Face aLC3 = Face( QList<double>() << 4 << 54 << 1 << 47 << 51 << 45 <<
+ TopoDS_Face aLC3 = Face2d( QList<double>() << 4 << 54 << 1 << 47 << 51 << 45 <<
127 << 42 << 145 << 43 << 148 << 60 << 90 << 65 );
CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC3, QString::fromUtf8("Zones de champs, prairies, sans cultures")) );
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 );
+ TopoDS_Face aLC1 = Face2d( 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 <<
+ TopoDS_Face aLC2 = Face2d( 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 <<
+ TopoDS_Face aLC3 = Face2d( 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 aBaseName = "lc_dump.py";
QString aBaseShp = "lc_dump.shp";
QString aBaseDbf = "lc_dump.dbf";
- QString aTmpPath = QDir::tempPath() + "/" + aBaseName;
+ QString aTmpPath = TMP_DIR + "/" + aBaseName;
CPPUNIT_ASSERT_EQUAL( true, aDoc->DumpToPython( aTmpPath, false ) );
//TODO: CPPUNIT_ASSERT_SCRIPTS_EQUAL( aBaseName, true, false, 20 );
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 ), QString::fromUtf8("Zones de champs cultivé à végétation haute"));
- aMap->LocalPartition( Face( QList<double>() << 5 << 5 << 10 << 5 << 10 << 8 << 5 << 12 << 5 << 8 ), QString::fromUtf8("Zones de champs cultivé à végétation haute"));
+ aMap->LocalPartition( Face2d( QList<double>() << 1 << 1 << 10 << 10 << 10 << 20 ), QString::fromUtf8("Zones de champs cultivé à végétation haute"));
+ aMap->LocalPartition( Face2d( QList<double>() << 5 << 5 << 10 << 5 << 10 << 8 << 5 << 12 << 5 << 8 ), QString::fromUtf8("Zones de champs cultivé à végétation haute"));
aMap->SetName( "test_LCM" );
TestViewer::show( aZone->GetTopShape(), AIS_Shaded, true, "LandCoverMap_TransparentPrs" );
void test_HYDROData_LandCoverMap::test_shp_import_cyp()
{
+ //TestViewer::eraseAll(true);
+
Handle(HYDROData_Document) aDoc = HYDROData_Document::Document(1);
QString aFileName = REF_DATA_PATH + "/cyprus_natural.shp";
HYDROData_ShapeFile anImporter;
Handle(HYDROData_LandCoverMap) LCM = Handle(HYDROData_LandCoverMap)::DownCast( aDoc->CreateObject( KIND_LAND_COVER_MAP ) );
HYDROData_MapOfFaceToStricklerType aMapFace2ST;
- for ( int i = 1; i <= PolygonFaces.Length(); i++ )
+ for ( int i = 1; i <= 20; i++ )
{
TopoDS_Shape aShape = PolygonFaces(i);
if ( aShape.IsNull() )
Handle(HYDROData_LandCoverMap) LCM = Handle(HYDROData_LandCoverMap)::DownCast( aDoc->CreateObject( KIND_LAND_COVER_MAP ) );
HYDROData_MapOfFaceToStricklerType aMapFace2ST;
- for ( int i = 150; i <= 350; i++ )
+ for ( int i = 150; i <= 160; i++ )
{
TopoDS_Shape aShape = PolygonFaces(i);
if ( aShape.IsNull() )
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, QString::fromUtf8("Forêt et végétation arbustive en mutation")) );
+ QStringList types = aTable->GetTypes();
+ //foreach( QString type, types )
+ // std::cout << type.toStdString() << std::endl;
- TopoDS_Face aLC2 = Face( QList<double>() << 21 << 34 << 24 << 25 << 37 << 37 << 40 << 61 <<
+ QString type7 = types[7];
+ QString type8 = types[8];
+ QString type9 = types[9];
+
+ TopoDS_Face aLC1 = Face2d( QList<double>() << 12 << 19 << 82 << 9 << 126 << 53 << 107 << 80 << 29 << 75 );
+ CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC1, type7 ) );
+
+ TopoDS_Face aLC2 = Face2d( 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, QString::fromUtf8("Forêts de conifères")) );
+ CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC2, type8 ) );
- TopoDS_Face aLC3 = Face( QList<double>() << 4 << 54 << 1 << 47 << 51 << 45 <<
+ TopoDS_Face aLC3 = Face2d( QList<double>() << 4 << 54 << 1 << 47 << 51 << 45 <<
127 << 42 << 145 << 43 << 148 << 60 << 90 << 65 );
- CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC3, QString::fromUtf8("Forêts de feuillus")) );
+ CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC3, type9 ) );
QString aTmpFileName = "test.telemac";
- QString aTmpPath = QDir::tempPath() + "/" + aTmpFileName;
- CPPUNIT_ASSERT_EQUAL( true, aMap->ExportTelemac( aTmpPath, 1E-4, aTable ) );
+ QString aTmpPath = TMP_DIR + "/" + aTmpFileName;
+ QString messStat;
+ CPPUNIT_ASSERT_EQUAL( true, aMap->ExportTelemac( aTmpPath, 1E-4, aTable, messStat ) );
CPPUNIT_ASSERT_SCRIPTS_EQUAL( aTmpFileName, true, true, 0 );
aDoc->Close();
Handle(HYDROData_LandCoverMap)::DownCast( aDoc->CreateObject( KIND_LAND_COVER_MAP ) );
aMap->SetName( "map_1" );
- TopoDS_Face aLC1 = Face( QList<double>() << 10 << 10 << 30 << 10 << 20 << 20 );
+ TopoDS_Face aLC1 = Face2d( QList<double>() << 10 << 10 << 30 << 10 << 20 << 20 );
CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC1, QString::fromUtf8("Forêts de conifères")) );
- TopoDS_Face aLC2 = Face( QList<double>() << 110 << 10 << 130 << 10 << 120 << 20 );
+ TopoDS_Face aLC2 = Face2d( QList<double>() << 110 << 10 << 130 << 10 << 120 << 20 );
CPPUNIT_ASSERT_EQUAL( true, aMap->LocalPartition( aLC2, QString::fromUtf8("Forêts de feuillus")) );
Handle(HYDROData_LandCoverMap) aMap2 =
#ifdef NDEBUG
int SI = 100;
- int EI = 300;
+ int EI = 110;
#else
- int SI = 150;
- int EI = 200;
+ int SI = 100;
+ int EI = 110;
#endif
for ( int i = SI; i <= EI; i++ )
LCM->StoreLandCovers(aMapFace2ST);
- std::vector<gp_Pnt2d> pnts;
+ std::vector<gp_XY> pnts;
#ifdef NDEBUG
int N = 1000; //1000*1000 points; uniform distribution for release mode
#else
{
double px = x0 + (x1-x0)*((double)i/(double)N);
double py = y0 + (y1-y0)*((double)j/(double)N);
- pnts.push_back(gp_Pnt2d(px,py));
+ pnts.push_back(gp_XY(px,py));
}
}
OSD_Timer aTimer;
LCM->ClassifyPoints(pnts, TRes);
aTimer.Stop();
#ifdef NDEBUG
- CPPUNIT_ASSERT( aTimer.ElapsedTime() < 1.4);
+ std::cout << "Time: " << aTimer.ElapsedTime() << std::endl;
+ CPPUNIT_ASSERT( aTimer.ElapsedTime() < 6.0);
aTimer.Show();
#endif
}
TopoDS_Shape Sh = LCM->GetShape();
- std::vector<gp_Pnt2d> pnts;
+ std::vector<gp_XY> pnts;
pnts.push_back(gp_XY(0,0));
pnts.push_back(gp_XY(468380, 6382300));
CPPUNIT_ASSERT_EQUAL (coeffs[0], 0.0);
CPPUNIT_ASSERT_EQUAL (coeffs[1], 0.0);
CPPUNIT_ASSERT_EQUAL (coeffs[2], 0.0);
- CPPUNIT_ASSERT_EQUAL (coeffs[3], 1.0522);
- CPPUNIT_ASSERT_EQUAL (coeffs[4], 1.0223);
- CPPUNIT_ASSERT_EQUAL (coeffs[5], 1.0221);
- CPPUNIT_ASSERT_EQUAL (coeffs[6], 1.0522);
+ CPPUNIT_ASSERT_EQUAL (coeffs[3], 98.0);
+ CPPUNIT_ASSERT_EQUAL (coeffs[4], 26.0);
+ CPPUNIT_ASSERT_EQUAL (coeffs[5], 24.0);
+ CPPUNIT_ASSERT_EQUAL (coeffs[6], 98.0);
}
-void test_HYDROData_LandCoverMap::test_add_int_edges_1()
+void test_HYDROData_LandCoverMap::test_lcm_classification()
{
- TopoDS_Shape out;
- TopTools_ListOfShape Wires;
-
- BRep_Builder B;
- TopoDS_Shape InF;
- TopoDS_Shape InP;
- BRepTools::Read(InP, "d:/p2.brep", B); //TODO
- BRepTools::Read(InF, "d:/r2.brep", B);
- Wires.Append(InP);
-
- TopTools_ListOfShape OutSh;
- HYDROData_SplitToZonesTool::CutByEdges(InF, Wires, OutSh);
- TopTools_ListIteratorOfListOfShape it(OutSh);
- for (;it.More();it.Next())
- {
- TopoDS_Shape Sh = it.Value();
- }
+ 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) ContourP = Handle(HYDROData_PolylineXY)::DownCast( aDoc->CreateObject( KIND_POLYLINEXY ) );
+ ContourP->SetName( "Contour" );
+ ContourP->AddSection( "Section_1", HYDROData_PolylineXY::SECTION_POLYLINE, true );
+ ContourP->AddPoint( 0, gp_XY( 89.57, 81.63 ) );
+ ContourP->AddPoint( 0, gp_XY( 479.59, 81.63 ) );
+ ContourP->AddPoint( 0, gp_XY( 472.79, 671.20 ) );
+ ContourP->AddPoint( 0, gp_XY( 69.16, 696.15 ) );
+ ContourP->Update();
+
+ Handle(HYDROData_PolylineXY) Poly_Sens_TrigoP =
+ Handle(HYDROData_PolylineXY)::DownCast( aDoc->CreateObject( KIND_POLYLINEXY ) );
+ Poly_Sens_TrigoP->SetName( "Poly_Sens_Trigo" );
+ Poly_Sens_TrigoP->SetZLevel( 3 );
+ Poly_Sens_TrigoP->AddSection( "Section_1", HYDROData_PolylineXY::SECTION_POLYLINE, 1 );
+ Poly_Sens_TrigoP->AddPoint( 0, gp_XY( 130.46, 223.57 ) );
+ Poly_Sens_TrigoP->AddPoint( 0, gp_XY( 252.16, 239.58 ) );
+ Poly_Sens_TrigoP->AddPoint( 0, gp_XY( 240.95, 498.99 ) );
+ Poly_Sens_TrigoP->AddPoint( 0, gp_XY( 119.26, 510.20 ) );
+ Poly_Sens_TrigoP->AddPoint( 0, gp_XY( 141.67, 378.89 ) );
+ Poly_Sens_TrigoP->Update();
+
+ Handle(HYDROData_PolylineXY) Polyline_Sens_HoraireP =
+ Handle(HYDROData_PolylineXY)::DownCast( aDoc->CreateObject( KIND_POLYLINEXY ) );
+ Polyline_Sens_HoraireP->SetName( "Polyline_Sens_Horaire" );
+ Polyline_Sens_HoraireP->SetZLevel( 4 );
+ Polyline_Sens_HoraireP->AddSection( "Section_1", HYDROData_PolylineXY::SECTION_POLYLINE, 1 );
+ Polyline_Sens_HoraireP->AddPoint( 0, gp_XY( 313.01, 470.16 ) );
+ Polyline_Sens_HoraireP->AddPoint( 0, gp_XY( 313.01, 627.09 ) );
+ Polyline_Sens_HoraireP->AddPoint( 0, gp_XY( 426.70, 633.49 ) );
+ Polyline_Sens_HoraireP->AddPoint( 0, gp_XY( 442.71, 398.11 ) );
+ Polyline_Sens_HoraireP->Update();
+
+
+ Handle(HYDROData_LandCoverMap) Land_cover_map_1 =
+ Handle(HYDROData_LandCoverMap)::DownCast( aDoc->CreateObject( KIND_LAND_COVER_MAP ) );
+ Land_cover_map_1->SetName( "Land cover map_1" );
+ Land_cover_map_1->SetZLevel( 2 );
+ CPPUNIT_ASSERT_EQUAL( true, Land_cover_map_1->Add( ContourP, "Vignobles" ) );
+ CPPUNIT_ASSERT_EQUAL( true, Land_cover_map_1->Add( Poly_Sens_TrigoP, "Oliveraies" ) );
+ CPPUNIT_ASSERT_EQUAL( true, Land_cover_map_1->Add( Polyline_Sens_HoraireP, "Estuaires" ) );
+
+ Handle(HYDROGUI_LandCoverMapPrs) aPrs = new HYDROGUI_LandCoverMapPrs( Land_cover_map_1 );
+ TopoDS_Shape aSh = Land_cover_map_1->GetShape();
+ TestViewer::show( aPrs, AIS_Shaded, 0, true, "Land_cover_map_1" );
+
+ std::vector<gp_XY> pnts;
+ pnts.push_back(gp_XY(90, 90));
+ pnts.push_back(gp_XY(300, 90));
+ pnts.push_back(gp_XY(200, 350));
+ pnts.push_back(gp_XY(400, 500));
+ std::vector<double> theCoeffs;
+ Land_cover_map_1->ClassifyPoints(pnts, aTable, theCoeffs, -1, true );
+ CPPUNIT_ASSERT_EQUAL((int)theCoeffs.size(), 4);
+ CPPUNIT_ASSERT_DOUBLES_EQUAL(theCoeffs[0], 24, 0.0001);
+ CPPUNIT_ASSERT_DOUBLES_EQUAL(theCoeffs[1], 24, 0.0001);
+ CPPUNIT_ASSERT_DOUBLES_EQUAL(theCoeffs[2], 26, 0.0001);
+ CPPUNIT_ASSERT_DOUBLES_EQUAL(theCoeffs[3], 98, 0.0001);
+
+ aDoc->Close();
}
