/***************************************************************************** * * This file is part of Mapnik (c++ mapping toolkit) * * Copyright (C) 2006 Artem Pavlenko * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA * *****************************************************************************/ // mapnik #include // stl #include #include "shape_featureset.hpp" using mapnik::geometry_type; using mapnik::feature_factory; template shape_featureset::shape_featureset(const filterT& filter, const std::string& shape_file, const std::set& attribute_names, std::string const& encoding, long file_length ) : filter_(filter), //shape_type_(shape_io::shape_null), shape_(shape_file, false), query_ext_(), tr_(new transcoder(encoding)), file_length_(file_length), count_(0) { shape_.shp().skip(100); //attributes typename std::set::const_iterator pos=attribute_names.begin(); while (pos!=attribute_names.end()) { bool found_name = false; for (int i=0;i feature_ptr shape_featureset::next() { std::streampos pos=shape_.shp().pos(); if (pos < std::streampos(file_length_ * 2)) { shape_.move_to(pos); int type=shape_.type(); feature_ptr feature(feature_factory::create(shape_.id_)); if (type == shape_io::shape_point) { double x=shape_.shp().read_double(); double y=shape_.shp().read_double(); geometry_type * point = new geometry_type(mapnik::Point); point->move_to(x,y); feature->add_geometry(point); ++count_; } else if (type == shape_io::shape_pointm) { double x=shape_.shp().read_double(); double y=shape_.shp().read_double(); shape_.shp().skip(8); //m geometry_type * point = new geometry_type(mapnik::Point); point->move_to(x,y); feature->add_geometry(point); ++count_; } else if (type == shape_io::shape_pointz) { double x=shape_.shp().read_double(); double y=shape_.shp().read_double(); // skip z shape_.shp().skip(8); //skip m if exists if ( shape_.reclength_ == 8 + 36) { shape_.shp().skip(8); } geometry_type * point = new geometry_type(mapnik::Point); point->move_to(x,y); feature->add_geometry(point); ++count_; } else { while (!filter_.pass(shape_.current_extent())) { if (!shape_.shp().is_eof()) { std::streampos pos = shape_.shp().pos(); if (shape_.type() != shape_io::shape_null) { pos += std::streampos(2 * shape_.reclength_ - 36); } shape_.move_to(pos); } else { return feature_ptr(); } } switch (type) { case shape_io::shape_multipoint: { int num_points = shape_.shp().read_ndr_integer(); for (int i=0; i< num_points;++i) { double x=shape_.shp().read_double(); double y=shape_.shp().read_double(); geometry_type * point = new geometry_type(mapnik::Point); point->move_to(x,y); feature->add_geometry(point); } ++count_; break; } case shape_io::shape_multipointm: { int num_points = shape_.shp().read_ndr_integer(); for (int i=0; i< num_points;++i) { double x=shape_.shp().read_double(); double y=shape_.shp().read_double(); geometry_type * point = new geometry_type(mapnik::Point); point->move_to(x,y); feature->add_geometry(point); } // skip m shape_.shp().skip(2*8 + 8*num_points); ++count_; break; } case shape_io::shape_multipointz: { unsigned num_points = shape_.shp().read_ndr_integer(); for (unsigned i=0; i< num_points;++i) { double x=shape_.shp().read_double(); double y=shape_.shp().read_double(); geometry_type * point = new geometry_type(mapnik::Point); point->move_to(x,y); feature->add_geometry(point); } // skip z shape_.shp().skip(2*8 + 8*num_points); // check if we have measure data if ( shape_.reclength_ == num_points * 16 + 36) { // skip m shape_.shp().skip(2*8 + 8*num_points); } ++count_; break; } case shape_io::shape_polyline: { geometry_type * line = shape_.read_polyline(); feature->add_geometry(line); ++count_; break; } case shape_io::shape_polylinem: { geometry_type * line = shape_.read_polylinem(); feature->add_geometry(line); ++count_; break; } case shape_io::shape_polylinez: { geometry_type * line = shape_.read_polylinez(); feature->add_geometry(line); ++count_; break; } case shape_io::shape_polygon: { geometry_type * poly = shape_.read_polygon(); feature->add_geometry(poly); ++count_; break; } case shape_io::shape_polygonm: { geometry_type * poly = shape_.read_polygonm(); feature->add_geometry(poly); ++count_; break; } case shape_io::shape_polygonz: { geometry_type * poly = shape_.read_polygonz(); feature->add_geometry(poly); ++count_; break; } } } feature->set_id(shape_.id_); if (attr_ids_.size()) { shape_.dbf().move_to(shape_.id_); std::vector::const_iterator pos=attr_ids_.begin(); std::vector::const_iterator end=attr_ids_.end(); while (pos!=end) { try { shape_.dbf().add_attribute(*pos,*tr_,*feature);//TODO optimize!!! } catch (...) { std::clog << "Shape Plugin: error processing attributes " << std::endl; } ++pos; } } return feature; } else { #ifdef MAPNIK_DEBUG std::clog << "Shape Plugin: total shapes read=" << count_ << std::endl; #endif return feature_ptr(); } } template shape_featureset::~shape_featureset() {} template class shape_featureset; template class shape_featureset;