Example #1
0
/* private */
std::auto_ptr<geom::Geometry>
GeometryNoder::toGeometry(SegmentString::NonConstVect& nodedEdges)
{
  const geom::GeometryFactory *geomFact = argGeom.getFactory();

  std::set< OrientedCoordinateArray > ocas;

  // Create a geometry out of the noded substrings.
  std::vector< geom::Geometry* >* lines = new std::vector< geom::Geometry * >();
  lines->reserve(nodedEdges.size());
  for ( unsigned int i = 0, n = nodedEdges.size(); i < n; ++i )
  {
    SegmentString* ss = nodedEdges [i];

    const geom::CoordinateSequence* coords = ss->getCoordinates();

    // Check if an equivalent edge is known 
    OrientedCoordinateArray oca1( *coords );
    if ( ocas.insert(oca1).second ) {
      geom::Geometry* tmp = geomFact->createLineString( coords->clone() );
      lines->push_back( tmp );
    }
  }

  std::auto_ptr<geom::Geometry> noded ( geomFact->createMultiLineString( lines ) );

  return noded;
}
Example #2
0
/*private*/
void
ScaledNoder::scale(SegmentString::NonConstVect& segStrings) const
{
	Scaler scaler(*this);
	for (SegmentString::NonConstVect::const_iterator
		i0=segStrings.begin(), i0End=segStrings.end();
			i0!=i0End; ++i0)
	{
		SegmentString* ss=*i0;

		CoordinateSequence* cs=ss->getCoordinates();

#ifndef NDEBUG
		size_t npts = cs->size();
#endif
		cs->apply_rw(&scaler);
		assert(cs->size() == npts);

		// Actually, we should be creating *new*
		// SegmentStrings here, but who's going
		// to delete them then ? And is it worth
		// the memory cost ?
		cs->removeRepeatedPoints();

	}
}
Example #3
0
/* public */
std::auto_ptr<geom::Geometry> 
GeometryNoder::getNoded()
{
  SegmentString::NonConstVect lineList;
  extractSegmentStrings(argGeom, lineList);

  Noder& noder = getNoder();
  SegmentString::NonConstVect* nodedEdges = 0;

  try {
    noder.computeNodes( &lineList );
    nodedEdges = noder.getNodedSubstrings();
  }
  catch (const std::exception& ex)
  {
    for (size_t i=0, n=lineList.size(); i<n; ++i)
      delete lineList[i];
    throw ex;
  }

  std::auto_ptr<geom::Geometry> noded = toGeometry(*nodedEdges);

  for ( unsigned int i = 0, n = nodedEdges->size(); i < n; ++i )
    delete ( *nodedEdges )[i];
  delete nodedEdges;

  for (size_t i=0, n=lineList.size(); i<n; ++i)
    delete lineList[i];

  return noded;
}
Example #4
0
/*public*/
void
MCIndexSnapRounder::computeVertexSnaps(SegmentString::NonConstVect& edges)
{
	SegmentString::NonConstVect::iterator i=edges.begin(), e=edges.end();
	for (; i!=e; ++i)
	{
		NodedSegmentString* edge0 =
			dynamic_cast<NodedSegmentString*>(*i);
		assert(edge0);
		computeVertexSnaps(edge0);
	}
}
Example #5
0
/*private*/
void
SimpleSnapRounder::computeSnaps(const SegmentString::NonConstVect& segStrings,
		vector<Coordinate>& snapPts)
{
	for (SegmentString::NonConstVect::const_iterator
			i=segStrings.begin(), iEnd=segStrings.end();
			i!=iEnd; ++i)
	{
		NodedSegmentString* ss = dynamic_cast<NodedSegmentString*>(*i);

		computeSnaps(ss, snapPts);
	}
}
Example #6
0
/* public static */
void
NodedSegmentString::getNodedSubstrings(
	const SegmentString::NonConstVect& segStrings,
	SegmentString::NonConstVect *resultEdgeList)
{
	assert(resultEdgeList);
	for ( SegmentString::NonConstVect::const_iterator
		i=segStrings.begin(), iEnd=segStrings.end();
		i != iEnd; ++i )
	{
		NodedSegmentString* ss = dynamic_cast<NodedSegmentString*>(*i);
		assert(ss);
		ss->getNodeList().addSplitEdges(resultEdgeList);
	}
}
Example #7
0
/*private*/
void
ScaledNoder::rescale(SegmentString::NonConstVect& segStrings) const
{
	ReScaler rescaler(*this);
	for (SegmentString::NonConstVect::const_iterator
		i0=segStrings.begin(), i0End=segStrings.end();
			i0!=i0End; ++i0)
	{

		SegmentString* ss=*i0;

		ss->getCoordinates()->apply_rw(&rescaler);

	}
}
Example #8
0
/*public*/
void
SimpleSnapRounder::computeVertexSnaps(const SegmentString::NonConstVect& edges)
{
	for (SegmentString::NonConstVect::const_iterator
			i0=edges.begin(), i0End=edges.end();
			i0!=i0End; ++i0)
	{
		NodedSegmentString* edge0 = dynamic_cast<NodedSegmentString*>(*i0);
		assert(edge0);
		for (SegmentString::NonConstVect::const_iterator
				i1=edges.begin(), i1End=edges.end();
				i1!=i1End; ++i1)
		{
			NodedSegmentString* edge1 = dynamic_cast<NodedSegmentString*>(*i1);
			assert(edge1);
			computeVertexSnaps(edge0, edge1);
		}
	}
}
/* private */
void
BufferBuilder::computeNodedEdges(SegmentString::NonConstVect& bufferSegStrList,
		const PrecisionModel *precisionModel) // throw(GEOSException)
{
	Noder* noder = getNoder( precisionModel );

	noder->computeNodes(&bufferSegStrList);

	SegmentString::NonConstVect* nodedSegStrings = \
			noder->getNodedSubstrings();


	for (SegmentString::NonConstVect::iterator
		i=nodedSegStrings->begin(), e=nodedSegStrings->end();
		i!=e;
		++i)
	{
		SegmentString* segStr = *i;
		const Label* oldLabel = static_cast<const Label*>(segStr->getData());

		CoordinateSequence* cs = CoordinateSequence::removeRepeatedPoints(segStr->getCoordinates());
		if ( cs->size() < 2 ) 
		{
			delete cs; // we need to take care of the memory here as cs is a new sequence
			return; // don't insert collapsed edges
		}
		// we need to clone SegmentString coordinates
		// as Edge will take ownership of them
		// TODO: find a way to transfer ownership instead
		// Who will own the edge ? FIXME: find out and handle that!
		Edge* edge = new Edge(cs, new Label(*oldLabel));

		// will take care of the Edge ownership
		insertUniqueEdge(edge);
	}

	if ( nodedSegStrings != &bufferSegStrList )
	{
		delete nodedSegStrings;
	}

	if ( noder != workingNoder ) delete noder;
}
Example #10
0
/* private */
void
NodingValidator::checkEndPtVertexIntersections(const Coordinate& testPt,
		const SegmentString::NonConstVect& segStrings) const
{
	for (SegmentString::NonConstVect::const_iterator
		it = segStrings.begin(), itEnd = segStrings.end();
		it != itEnd;
		++it)
	{
		const SegmentString* ss0 = *it;
		const CoordinateSequence& pts = *(ss0->getCoordinates());
		for (unsigned int j=1, n=pts.size()-1; j<n; ++j)
		{
			if (pts[j].equals(testPt))
			{
				stringstream s;
				s<<"found endpt/interior pt intersection ";
				s<<"at index "<<j<<" :pt "<<testPt;
				throw util::TopologyException(s.str());
			}
		}
	}
}
Example #11
0
/*private*/
void
SimpleSnapRounder::checkCorrectness(
		SegmentString::NonConstVect& inputSegmentStrings)
{
  SegmentString::NonConstVect resultSegStrings;
  NodedSegmentString::getNodedSubstrings(
    inputSegmentStrings.begin(), inputSegmentStrings.end(), &resultSegStrings
  );

  NodingValidator nv(resultSegStrings);

  try {
    nv.checkValid();
  }

  catch (const std::exception &ex) {

    for ( SegmentString::NonConstVect::iterator i=resultSegStrings.begin(),
                                                e=resultSegStrings.end();
          i!=e; ++i )
    {
      delete *i;
    }

    std::cerr << ex.what() << std::endl;
    throw;
  }

  for ( SegmentString::NonConstVect::iterator i=resultSegStrings.begin(),
                                              e=resultSegStrings.end();
        i!=e; ++i )
  {
    delete *i;
  }
 
}
Example #12
0
/*public*/
void
MCIndexSnapRounder::computeVertexSnaps(SegmentString::NonConstVect& edges)
{
	for_each(edges.begin(), edges.end(), bind1st(mem_fun(&MCIndexSnapRounder::computeEdgeVertexSnaps), this));
}
/*public*/
Geometry*
BufferBuilder::bufferLineSingleSided( const Geometry* g, double distance,
                                      bool leftSide )
{
   // Returns the line used to create a single-sided buffer.
   // Input requirement: Must be a LineString.
   const LineString* l = dynamic_cast< const LineString* >( g );
   if ( !l ) throw util::IllegalArgumentException("BufferBuilder::bufferLineSingleSided only accept linestrings");

   // Get geometry factory and precision model.
   const PrecisionModel* precisionModel = workingPrecisionModel;
   if ( !precisionModel ) precisionModel = l->getPrecisionModel();

   assert( precisionModel );
   assert( l );

   geomFact = l->getFactory();

   // First, generate the two-sided buffer using a butt-cap.
   BufferParameters modParams = bufParams;
   modParams.setEndCapStyle(BufferParameters::CAP_FLAT); 
   Geometry* buf = 0;

   // This is a (temp?) hack to workaround the fact that
   // BufferBuilder BufferParamaters are immutable after
   // construction, while we want to force the end cap
   // style to FLAT for single-sided buffering
   {
      BufferBuilder tmp(modParams);
      buf = tmp.buffer( l, distance );
   }

   // Create MultiLineStrings from this polygon.
   Geometry* bufLineString = buf->getBoundary();

#ifdef GEOS_DEBUG_SSB
   std::cerr << "input|" << *l << std::endl;
   std::cerr << "buffer|" << *bufLineString << std::endl;
#endif

   // Then, get the raw (i.e. unnoded) single sided offset curve.
   OffsetCurveBuilder curveBuilder( precisionModel, modParams );
   std::vector< CoordinateSequence* > lineList;

   std::auto_ptr< CoordinateSequence > coords ( g->getCoordinates() );
   curveBuilder.getSingleSidedLineCurve( coords.get(), distance,
                                         lineList, leftSide, !leftSide );
   coords.reset();

   // Create a SegmentString from these coordinates.
   SegmentString::NonConstVect curveList;
   for ( unsigned int i = 0; i < lineList.size(); ++i )
   {
      CoordinateSequence* seq = lineList[i];

      SegmentString* ss = new NodedSegmentString(seq, NULL);
      curveList.push_back( ss );
   }

   // Node these SegmentStrings.
   Noder* noder = getNoder( precisionModel );
   noder->computeNodes( &curveList );
   SegmentString::NonConstVect* nodedEdges = noder->getNodedSubstrings();

   // Create a geometry out of the noded substrings.
   std::vector< Geometry* >* singleSidedNodedEdges =
      new std::vector< Geometry * >();
   for ( unsigned int i = 0, n = nodedEdges->size(); i < n; ++i )
   {
      SegmentString* ss = ( *nodedEdges )[i];

      Geometry* tmp = geomFact->createLineString(
                        ss->getCoordinates()->clone()
                      );
      singleSidedNodedEdges->push_back( tmp );
   }

   if ( nodedEdges != &curveList ) delete nodedEdges;

   for (size_t i=0, n=curveList.size(); i<n; ++i) delete curveList[i];
   curveList.clear();

   for (size_t i=0, n=lineList.size(); i<n; ++i) delete lineList[i];
   lineList.clear();


   Geometry* singleSided = geomFact->createMultiLineString(
      singleSidedNodedEdges );

#ifdef GEOS_DEBUG_SSB
     std::cerr << "edges|" << *singleSided << std::endl;
#endif

   // Use the boolean operation intersect to obtain the line segments lying
   // on both the butt-cap buffer and this multi-line.
   //Geometry* intersectedLines = singleSided->intersection( bufLineString );
   // NOTE: we use Snapped overlay because the actual buffer boundary might
   //       diverge from original offset curves due to the addition of
   //       intersections with caps and joins curves
   using geos::operation::overlay::snap::SnapOverlayOp;
   Geometry* intersectedLines = SnapOverlayOp::overlayOp(*singleSided, *bufLineString, OverlayOp::opINTERSECTION).release();

#ifdef GEOS_DEBUG_SSB
     std::cerr << "intersection" << "|" << *intersectedLines << std::endl;
#endif

   // Merge result lines together.
   LineMerger lineMerge;
   lineMerge.add( intersectedLines );
   std::auto_ptr< std::vector< LineString* > > mergedLines (
	lineMerge.getMergedLineStrings() );

   // Convert the result into a std::vector< Geometry* >.
   std::vector< Geometry* >* mergedLinesGeom = new std::vector< Geometry* >();
   const Coordinate& startPoint = l->getCoordinatesRO()->front();
   const Coordinate& endPoint = l->getCoordinatesRO()->back();
   while( !mergedLines->empty() )
   {
      // Remove end points if they are a part of the original line to be
      // buffered.
      CoordinateSequence::AutoPtr coords(mergedLines->back()->getCoordinates());
      if ( NULL != coords.get() )
      {
         // Use 98% of the buffer width as the point-distance requirement - this
         // is to ensure that the point that is "distance" +/- epsilon is not
         // included.
         const double ptDistAllowance = 0.98 * distance;
         // Use 102% of the buffer width as the line-length requirement - this
         // is to ensure that line segments that is length "distance" +/-
         // epsilon is removed.
         const double segLengthAllowance = 1.02 * distance;

         // Clean up the front of the list.
         // Loop until the line's end is not inside the buffer width from
         // the startPoint.
         while ( coords->size() > 1 && 
                 coords->front().distance( startPoint ) < ptDistAllowance )
         {
            // Record the end segment length.
            double segLength = coords->front().distance( ( *coords )[1] );
            // Stop looping if there are no more points, or if the segment
            // length is larger than the buffer width.
            if ( coords->size() <= 1 || segLength > segLengthAllowance )
            {
               break;
            }
            // If the first point is less than buffer width away from the
            // reference point, then delete the point.
            coords->deleteAt( 0 );
         }
         while ( coords->size() > 1 && 
                 coords->front().distance( endPoint ) < ptDistAllowance )
         {
            double segLength = coords->front().distance( ( *coords )[1] );
            if ( coords->size() <= 1 || segLength > segLengthAllowance )
            {
               break;
            }
            coords->deleteAt( 0 );
         }

         // Clean up the back of the list.
         while ( coords->size() > 1 &&
                 coords->back().distance( startPoint ) < ptDistAllowance )
         {
            double segLength = coords->back().distance(
               ( *coords )[coords->size()-2] );
            if ( coords->size() <= 1 || segLength > segLengthAllowance )
            {
               break;
            }
            coords->deleteAt( coords->size()-1 );
         }
         while ( coords->size() > 1 &&
                 coords->back().distance( endPoint ) < ptDistAllowance )
         {
            double segLength = coords->back().distance(
               ( *coords )[coords->size()-2] );
            if ( coords->size() <= 1 || segLength > segLengthAllowance )
            {
               break;
            }
            coords->deleteAt( coords->size()-1 );
         }

         // Add the coordinates to the resultant line string.
         if ( coords->size() > 1 )
         {
            mergedLinesGeom->push_back( geomFact->createLineString( coords.release() ) );
         }
      }

      geomFact->destroyGeometry( mergedLines->back() );
      mergedLines->pop_back();
   }

   // Clean up.
   if ( noder != workingNoder ) delete noder;
   geomFact->destroyGeometry( buf );
   geomFact->destroyGeometry( bufLineString );
   geomFact->destroyGeometry( singleSided );
   geomFact->destroyGeometry( intersectedLines );

   if ( mergedLinesGeom->size() > 1 ) return geomFact->createMultiLineString( mergedLinesGeom );
   else
   {
      // Must be a single line
      Geometry* single = (*mergedLinesGeom)[0];
      delete mergedLinesGeom;
      return single;
   }
}