mapnik/src/wkb.cpp
artemp 274fbf8f7a + ensure 'close path' handled correcly
(currenlty SEG_CLOSE command must have valid x,y)
+ implement real_policies in wkt and geojson generators
2012-12-18 11:44:35 +00:00

485 lines
14 KiB
C++

/*****************************************************************************
*
* This file is part of Mapnik (c++ mapping toolkit)
*
* Copyright (C) 2011 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 <mapnik/debug.hpp>
#include <mapnik/global.hpp>
#include <mapnik/wkb.hpp>
#include <mapnik/coord_array.hpp>
#include <mapnik/geom_util.hpp>
#include <mapnik/feature.hpp>
#include <mapnik/noncopyable.hpp>
// boost
#include <boost/format.hpp>
namespace mapnik
{
typedef coord_array<coord2d> CoordinateArray;
struct wkb_reader : mapnik::noncopyable
{
private:
enum wkbByteOrder {
wkbXDR=0,
wkbNDR=1
};
const char* wkb_;
unsigned size_;
unsigned pos_;
wkbByteOrder byteOrder_;
bool needSwap_;
wkbFormat format_;
public:
enum wkbGeometryType {
wkbPoint=1,
wkbLineString=2,
wkbPolygon=3,
wkbMultiPoint=4,
wkbMultiLineString=5,
wkbMultiPolygon=6,
wkbGeometryCollection=7,
wkbPointZ=1001,
wkbLineStringZ=1002,
wkbPolygonZ=1003,
wkbMultiPointZ=1004,
wkbMultiLineStringZ=1005,
wkbMultiPolygonZ=1006,
wkbGeometryCollectionZ=1007
};
wkb_reader(const char* wkb, unsigned size, wkbFormat format)
: wkb_(wkb),
size_(size),
pos_(0),
format_(format)
{
// try to determine WKB format automatically
if (format_ == wkbAuto)
{
if (size_ >= 44
&& (unsigned char)(wkb_[0]) == (unsigned char)(0x00)
&& (unsigned char)(wkb_[38]) == (unsigned char)(0x7C))
{
format_ = wkbSpatiaLite;
}
else
{
format_ = wkbGeneric;
}
}
switch (format_)
{
case wkbSpatiaLite:
byteOrder_ = (wkbByteOrder) wkb_[1];
pos_ = 39;
break;
case wkbGeneric:
default:
byteOrder_ = (wkbByteOrder) wkb_[0];
pos_ = 1;
break;
}
#ifndef MAPNIK_BIG_ENDIAN
needSwap_ = byteOrder_ ? wkbXDR : wkbNDR;
#else
needSwap_ = byteOrder_ ? wkbNDR : wkbXDR;
#endif
}
void read(boost::ptr_vector<geometry_type> & paths)
{
int type = read_integer();
switch (type)
{
case wkbPoint:
read_point(paths);
break;
case wkbLineString:
read_linestring(paths);
break;
case wkbPolygon:
read_polygon(paths);
break;
case wkbMultiPoint:
read_multipoint(paths);
break;
case wkbMultiLineString:
read_multilinestring(paths);
break;
case wkbMultiPolygon:
read_multipolygon(paths);
break;
case wkbGeometryCollection:
read_collection(paths);
break;
case wkbPointZ:
read_point_xyz(paths);
break;
case wkbLineStringZ:
read_linestring_xyz(paths);
break;
case wkbPolygonZ:
read_polygon_xyz(paths);
break;
case wkbMultiPointZ:
read_multipoint_xyz(paths);
break;
case wkbMultiLineStringZ:
read_multilinestring_xyz(paths);
break;
case wkbMultiPolygonZ:
read_multipolygon_xyz(paths);
break;
case wkbGeometryCollectionZ:
read_collection(paths);
break;
default:
break;
}
}
private:
int read_integer()
{
boost::int32_t n;
if (needSwap_)
{
read_int32_xdr(wkb_ + pos_, n);
}
else
{
read_int32_ndr(wkb_ + pos_, n);
}
pos_ += 4;
return n;
}
double read_double()
{
double d;
if (needSwap_)
{
read_double_xdr(wkb_ + pos_, d);
}
else
{
read_double_ndr(wkb_ + pos_, d);
}
pos_ += 8;
return d;
}
void read_coords(CoordinateArray& ar)
{
if (! needSwap_)
{
for (unsigned i = 0; i < ar.size(); ++i)
{
read_double_ndr(wkb_ + pos_, ar[i].x);
read_double_ndr(wkb_ + pos_ + 8, ar[i].y);
pos_ += 16; // skip XY
}
}
else
{
for (unsigned i=0;i<ar.size();++i)
{
read_double_xdr(wkb_ + pos_, ar[i].x);
read_double_xdr(wkb_ + pos_ + 8, ar[i].y);
pos_ += 16; // skip XY
}
}
}
void read_coords_xyz(CoordinateArray& ar)
{
if (! needSwap_)
{
for (unsigned i = 0; i < ar.size(); ++i)
{
read_double_ndr(wkb_ + pos_, ar[i].x);
read_double_ndr(wkb_ + pos_ + 8, ar[i].y);
pos_ += 24; // skip XYZ
}
}
else
{
for (unsigned i = 0; i < ar.size(); ++i)
{
read_double_xdr(wkb_ + pos_, ar[i].x);
read_double_xdr(wkb_ + pos_ + 8, ar[i].y);
pos_ += 24; // skip XYZ
}
}
}
void read_point(boost::ptr_vector<geometry_type> & paths)
{
double x = read_double();
double y = read_double();
std::auto_ptr<geometry_type> pt(new geometry_type(Point));
pt->move_to(x, y);
paths.push_back(pt);
}
void read_multipoint(boost::ptr_vector<geometry_type> & paths)
{
int num_points = read_integer();
for (int i = 0; i < num_points; ++i)
{
pos_ += 5;
read_point(paths);
}
}
void read_point_xyz(boost::ptr_vector<geometry_type> & paths)
{
double x = read_double();
double y = read_double();
std::auto_ptr<geometry_type> pt(new geometry_type(Point));
pos_ += 8; // double z = read_double();
pt->move_to(x, y);
paths.push_back(pt);
}
void read_multipoint_xyz(boost::ptr_vector<geometry_type> & paths)
{
int num_points = read_integer();
for (int i = 0; i < num_points; ++i)
{
pos_ += 5;
read_point_xyz(paths);
}
}
void read_linestring(boost::ptr_vector<geometry_type> & paths)
{
int num_points = read_integer();
if (num_points > 0)
{
CoordinateArray ar(num_points);
read_coords(ar);
std::auto_ptr<geometry_type> line(new geometry_type(LineString));
line->move_to(ar[0].x, ar[0].y);
for (int i = 1; i < num_points; ++i)
{
line->line_to(ar[i].x, ar[i].y);
}
paths.push_back(line);
}
}
void read_multilinestring(boost::ptr_vector<geometry_type> & paths)
{
int num_lines = read_integer();
for (int i = 0; i < num_lines; ++i)
{
pos_ += 5;
read_linestring(paths);
}
}
void read_linestring_xyz(boost::ptr_vector<geometry_type> & paths)
{
int num_points = read_integer();
if (num_points > 0)
{
CoordinateArray ar(num_points);
read_coords_xyz(ar);
std::auto_ptr<geometry_type> line(new geometry_type(LineString));
line->move_to(ar[0].x, ar[0].y);
for (int i = 1; i < num_points; ++i)
{
line->line_to(ar[i].x, ar[i].y);
}
paths.push_back(line);
}
}
void read_multilinestring_xyz(boost::ptr_vector<geometry_type> & paths)
{
int num_lines = read_integer();
for (int i = 0; i < num_lines; ++i)
{
pos_ += 5;
read_linestring_xyz(paths);
}
}
void read_polygon(boost::ptr_vector<geometry_type> & paths)
{
int num_rings = read_integer();
if (num_rings > 0)
{
std::auto_ptr<geometry_type> poly(new geometry_type(Polygon));
for (int i = 0; i < num_rings; ++i)
{
int num_points = read_integer();
if (num_points > 0)
{
CoordinateArray ar(num_points);
read_coords(ar);
poly->move_to(ar[0].x, ar[0].y);
for (int j = 1; j < num_points - 1; ++j)
{
poly->line_to(ar[j].x, ar[j].y);
}
if (ar[0].x == ar[num_points-1].x &&
ar[0].y == ar[num_points-1].y)
{
poly->close(ar[num_points-1].x, ar[num_points-1].y);
}
else
{
// leave un-closed polygon intact - don't attempt to close them
poly->line_to(ar[num_points-1].x, ar[num_points-1].y);
}
poly->set_close();
}
}
if (poly->size() > 2) // ignore if polygon has less than 3 vertices
paths.push_back(poly);
}
}
void read_multipolygon(boost::ptr_vector<geometry_type> & paths)
{
int num_polys = read_integer();
for (int i = 0; i < num_polys; ++i)
{
pos_ += 5;
read_polygon(paths);
}
}
void read_polygon_xyz(boost::ptr_vector<geometry_type> & paths)
{
int num_rings = read_integer();
if (num_rings > 0)
{
std::auto_ptr<geometry_type> poly(new geometry_type(Polygon));
for (int i = 0; i < num_rings; ++i)
{
int num_points = read_integer();
if (num_points > 0)
{
CoordinateArray ar(num_points);
read_coords_xyz(ar);
poly->move_to(ar[0].x, ar[0].y);
for (int j = 1; j < num_points - 1; ++j)
{
poly->line_to(ar[j].x, ar[j].y);
}
if (ar[0].x == ar[num_points-1].x &&
ar[0].y == ar[num_points-1].y)
{
poly->close(ar[num_points-1].x, ar[num_points-1].y);
}
else
{
// leave un-closed polygon intact- don't attempt to close them
poly->line_to(ar[num_points-1].x, ar[num_points-1].y);
}
}
}
if (poly->size() > 2) // ignore if polygon has less than 3 vertices
paths.push_back(poly);
}
}
void read_multipolygon_xyz(boost::ptr_vector<geometry_type> & paths)
{
int num_polys = read_integer();
for (int i = 0; i < num_polys; ++i)
{
pos_ += 5;
read_polygon_xyz(paths);
}
}
void read_collection(boost::ptr_vector<geometry_type> & paths)
{
int num_geometries = read_integer();
for (int i = 0; i < num_geometries; ++i)
{
pos_ += 1; // skip byte order
read(paths);
}
}
std::string wkb_geometry_type_string(int type)
{
std::stringstream s;
switch (type)
{
case wkbPoint: s << "Point"; break;
case wkbLineString: s << "LineString"; break;
case wkbPolygon: s << "Polygon"; break;
case wkbMultiPoint: s << "MultiPoint"; break;
case wkbMultiLineString: s << "MultiLineString"; break;
case wkbMultiPolygon: s << "MultiPolygon"; break;
case wkbGeometryCollection: s << "GeometryCollection"; break;
case wkbPointZ: s << "PointZ"; break;
case wkbLineStringZ: s << "LineStringZ"; break;
case wkbPolygonZ: s << "PolygonZ"; break;
case wkbMultiPointZ: s << "MultiPointZ"; break;
case wkbMultiLineStringZ: s << "MultiLineStringZ"; break;
case wkbMultiPolygonZ: s << "MultiPolygonZ"; break;
case wkbGeometryCollectionZ: s << "GeometryCollectionZ"; break;
default: s << "wkbUknown(" << type << ")"; break;
}
return s.str();
}
};
bool geometry_utils::from_wkb(boost::ptr_vector<geometry_type>& paths,
const char* wkb,
unsigned size,
wkbFormat format)
{
unsigned geom_count = paths.size();
wkb_reader reader(wkb, size, format);
reader.read(paths);
if (paths.size() > geom_count)
return true;
return false;
}
}