test_wktreader_data()
:
pm(1.0),
gf(&pm),
wktreader(&gf)
{
wktwriter.setOutputDimension( 3 );
}
test_wktreader_data()
:
pm(1.0),
gf(geos::geom::GeometryFactory::create(&pm)),
wktreader(gf.get())
{
wktwriter.setOutputDimension( 3 );
}
bool isEqual(const Geom& a, const Geom& b)
{
using std::cout;
using std::endl;
GeomPtr a2 = normalize(a);
GeomPtr b2 = normalize(b);
bool eq = a2->equalsExact(b2.get());
if ( ! eq ) {
cout << "OBTAINED: " << wktwriter.write(b2.get()) << endl;
}
return eq;
}
bool isEqual(const Geom& a, const Geom& b, double tolerance=0)
{
using std::cout;
using std::endl;
bool eq;
// TODO: use HausdorffDistance ?
GeomPtr a2 = normalize(a);
GeomPtr b2 = normalize(b);
eq = a2->equalsExact(b2.get(), tolerance);
if ( ! eq ) {
cout << "OBTAINED: " << wktwriter.write(b2.get()) << endl;
}
return eq;
}
bool compare( T& ex, S& ob)
{
using std::cout;
using std::endl;
if ( ex.size() != ob.size() ) {
cout << "Expected " << ex.size() << " polygons, obtained "
<< ob.size() << endl;
return false;
}
for (typename T::iterator i=ex.begin(), e=ex.end(); i!=e; ++i) {
if ( ! contains(ob, *i) ) {
cout << "Expected " << wktwriter.write(*i)
<< " not found" << endl;
return false;
}
}
return true;
}
test_polygonizetest_data()
: wktreader()
{
wktwriter.setTrim(true);
}
test_shpathop_data()
: gf(), wktreader(&gf), wktwriter()
{
wktwriter.setTrim(true);
}
test_polygonizetest_data()
: gf(),
wktreader(&gf)
{
wktwriter.setTrim(true);
}
test_linesequencer_data()
: gf(), wktreader(&gf), wktwriter()
{
wktwriter.setTrim(true);
}
test_rectangleintersectiontest_data()
: wktreader()
{
wktwriter.setTrim(true);
}
test_unaryuniontest_data()
: gf(),
wktreader(&gf)
{
wktwriter.setTrim(true);
}
void checkExpected(Geometry* result, const Geometry* expected)
{
bool isEqual = result->equalsExact(expected, 1.0e-5);
ensure_equals("Expect: "+writer.write(expected)+" Obtained: "+writer.write(result), isEqual, true);
}
test_unaryuniontest_data()
: gf(GeometryFactory::create()),
wktreader(gf.get())
{
wktwriter.setTrim(true);
}