VALUE rgeo_geos_polygons_eql(GEOSContextHandle_t context, const GEOSGeometry* geom1, const GEOSGeometry* geom2, char check_z)
{
VALUE result = Qnil;
if (geom1 && geom2) {
result = rgeo_geos_coordseqs_eql(context, GEOSGetExteriorRing_r(context, geom1), GEOSGetExteriorRing_r(context, geom2), check_z);
if (RTEST(result)) {
int len1 = GEOSGetNumInteriorRings_r(context, geom1);
int len2 = GEOSGetNumInteriorRings_r(context, geom2);
if (len1 >= 0 && len2 >= 0) {
if (len1 == len2) {
int i;
for (i=0; i<len1; ++i) {
result = rgeo_geos_coordseqs_eql(context, GEOSGetInteriorRingN_r(context, geom1, i), GEOSGetInteriorRingN_r(context, geom2, i), check_z);
if (!RTEST(result)) {
break;
}
}
}
else {
result = Qfalse;
}
}
else {
result = Qnil;
}
}
}
return result;
}
BOX3D computeBounds(GEOSContextHandle_t ctx, GEOSGeometry const *geometry)
{
uint32_t numInputDims;
BOX3D output;
GEOSGeometry const* ring = GEOSGetExteriorRing_r(ctx,
geometry);
GEOSCoordSequence const* coords = GEOSGeom_getCoordSeq_r(ctx,
ring);
GEOSCoordSeq_getDimensions_r(ctx, coords, &numInputDims);
uint32_t count(0);
GEOSCoordSeq_getSize_r(ctx, coords, &count);
double x(0.0);
double y(0.0);
double z(0.0);
for (unsigned i = 0; i < count; ++i)
{
GEOSCoordSeq_getOrdinate_r(ctx, coords, i, 0, &x);
GEOSCoordSeq_getOrdinate_r(ctx, coords, i, 1, &y);
if (numInputDims > 2)
GEOSCoordSeq_getOrdinate_r(ctx, coords, i, 2, &z);
output.grow(x, y, z);
}
return output;
}
BOX3D Polygon::bounds() const
{
uint32_t numInputDims;
BOX3D output;
GEOSGeometry* boundary = GEOSGeom_clone_r(m_ctx, m_geom);
// Smash out multi*
if (GEOSGeomTypeId_r(m_ctx, m_geom) > 3)
boundary = GEOSEnvelope_r(m_ctx, m_geom);
GEOSGeometry const* ring = GEOSGetExteriorRing_r(m_ctx, boundary);
GEOSCoordSequence const* coords = GEOSGeom_getCoordSeq_r(m_ctx, ring);
GEOSCoordSeq_getDimensions_r(m_ctx, coords, &numInputDims);
uint32_t count(0);
GEOSCoordSeq_getSize_r(m_ctx, coords, &count);
double x(0.0);
double y(0.0);
double z(0.0);
for (unsigned i = 0; i < count; ++i)
{
GEOSCoordSeq_getOrdinate_r(m_ctx, coords, i, 0, &x);
GEOSCoordSeq_getOrdinate_r(m_ctx, coords, i, 1, &y);
if (numInputDims > 2)
GEOSCoordSeq_getOrdinate_r(m_ctx, coords, i, 2, &z);
output.grow(x, y, z);
}
GEOSGeom_destroy_r(m_ctx, boundary);
return output;
}
// Find holes of each face
static void findFaceHoles( Face **faces, int nfaces )
{
GEOSContextHandle_t handle = QgsGeos::getGEOSHandler();
// We sort by envelope area so that we know holes are only
// after their shells
qsort( faces, nfaces, sizeof( Face * ), compare_by_envarea );
for ( int i = 0; i < nfaces; ++i )
{
Face *f = faces[i];
int nholes = GEOSGetNumInteriorRings_r( handle, f->geom );
for ( int h = 0; h < nholes; ++h )
{
const GEOSGeometry *hole = GEOSGetInteriorRingN_r( handle, f->geom, h );
for ( int j = i + 1; j < nfaces; ++j )
{
Face *f2 = faces[j];
if ( f2->parent )
continue; // hole already assigned
/* TODO: can be optimized as the ring would have the
* same vertices, possibly in different order.
* maybe comparing number of points could already be
* useful.
*/
if ( GEOSEquals_r( handle, GEOSGetExteriorRing_r( handle, f2->geom ), hole ) )
{
f2->parent = f;
break;
}
}
}
}
}
BOX3D Crop::computeBounds(GEOSGeometry const *geometry)
{
uint32_t numInputDims;
BOX3D output;
#ifdef PDAL_HAVE_GEOS
GEOSGeometry const* ring = GEOSGetExteriorRing_r(m_geosEnvironment,
geometry);
GEOSCoordSequence const* coords = GEOSGeom_getCoordSeq_r(m_geosEnvironment,
ring);
GEOSCoordSeq_getDimensions_r(m_geosEnvironment, coords, &numInputDims);
log()->get(LogLevel::Debug) << "Inputted WKT had " << numInputDims <<
" dimensions" <<std::endl;
uint32_t count(0);
GEOSCoordSeq_getSize_r(m_geosEnvironment, coords, &count);
double x(0.0);
double y(0.0);
double z(0.0);
for (unsigned i = 0; i < count; ++i)
{
GEOSCoordSeq_getOrdinate_r(m_geosEnvironment, coords, i, 0, &x);
GEOSCoordSeq_getOrdinate_r(m_geosEnvironment, coords, i, 1, &y);
if (numInputDims > 2)
GEOSCoordSeq_getOrdinate_r(m_geosEnvironment, coords, i, 2, &z);
output.grow(x, y, z);
}
#else
boost::ignore_unused_variable_warning(geometry);
#endif
return output;
}
static VALUE method_polygon_exterior_ring(VALUE self)
{
VALUE result = Qnil;
RGeo_GeometryData* self_data = RGEO_GEOMETRY_DATA_PTR(self);
const GEOSGeometry* self_geom = self_data->geom;
if (self_geom) {
result = rgeo_wrap_geos_geometry_clone(self_data->factory, GEOSGetExteriorRing_r(self_data->geos_context, self_geom), RGEO_FACTORY_DATA_PTR(self_data->factory)->globals->geos_linear_ring);
}
return result;
}
Polygon Polygon::simplify(double distance_tolerance,
double area_tolerance) const
{
GEOSGeometry *smoothed =
GEOSTopologyPreserveSimplify_r(m_ctx, m_geom, distance_tolerance);
if (!smoothed)
throw pdal_error("Unable to simplify input geometry!");
std::vector<GEOSGeometry*> geometries;
int numGeom = GEOSGetNumGeometries_r(m_ctx, smoothed);
for (int n = 0; n < numGeom; ++n)
{
const GEOSGeometry* m = GEOSGetGeometryN_r(m_ctx, smoothed, n);
if (!m)
throw pdal::pdal_error("Unable to Get GeometryN");
const GEOSGeometry* ering = GEOSGetExteriorRing_r(m_ctx, m);
if (!ering)
throw pdal::pdal_error("Unable to Get Exterior Ring");
GEOSGeometry* exterior = GEOSGeom_clone_r(m_ctx,
GEOSGetExteriorRing_r(m_ctx, m));
if (!exterior)
throw pdal::pdal_error("Unable to clone exterior ring!");
std::vector<GEOSGeometry*> keep_rings;
int numRings = GEOSGetNumInteriorRings_r(m_ctx, m);
for (int i = 0; i < numRings; ++i)
{
double area(0.0);
const GEOSGeometry* iring =
GEOSGetInteriorRingN_r(m_ctx, m, i);
if (!iring)
throw pdal::pdal_error("Unable to Get Interior Ring");
GEOSGeometry* cring = GEOSGeom_clone_r(m_ctx, iring);
if (!cring)
throw pdal::pdal_error("Unable to clone interior ring!");
GEOSGeometry* aring = GEOSGeom_createPolygon_r(m_ctx, cring,
NULL, 0);
int errored = GEOSArea_r(m_ctx, aring, &area);
if (errored == 0)
throw pdal::pdal_error("Unable to get area of ring!");
if (area > area_tolerance)
{
keep_rings.push_back(cring);
}
}
GEOSGeometry* p = GEOSGeom_createPolygon_r(m_ctx, exterior,
keep_rings.data(), keep_rings.size());
if (p == NULL) throw
pdal::pdal_error("smooth polygon could not be created!" );
geometries.push_back(p);
}
GEOSGeometry* o = GEOSGeom_createCollection_r(m_ctx, GEOS_MULTIPOLYGON,
geometries.data(), geometries.size());
Polygon p(o, m_srs, m_ctx);
GEOSGeom_destroy_r(m_ctx, smoothed);
GEOSGeom_destroy_r(m_ctx, o);
return p;
}
Q_NOWARN_UNREACHABLE_POP
// Return Nth vertex in GEOSGeometry as a POINT.
// May return NULL if the geometry has NO vertexex.
static GEOSGeometry *LWGEOM_GEOS_getPointN( const GEOSGeometry *g_in, uint32_t n )
{
GEOSContextHandle_t handle = QgsGeos::getGEOSHandler();
uint32_t dims;
const GEOSCoordSequence *seq_in = nullptr;
GEOSCoordSeq seq_out;
double val;
uint32_t sz;
int gn;
GEOSGeometry *ret = nullptr;
switch ( GEOSGeomTypeId_r( handle, g_in ) )
{
case GEOS_MULTIPOINT:
case GEOS_MULTILINESTRING:
case GEOS_MULTIPOLYGON:
case GEOS_GEOMETRYCOLLECTION:
{
for ( gn = 0; gn < GEOSGetNumGeometries_r( handle, g_in ); ++gn )
{
const GEOSGeometry *g = GEOSGetGeometryN_r( handle, g_in, gn );
ret = LWGEOM_GEOS_getPointN( g, n );
if ( ret ) return ret;
}
break;
}
case GEOS_POLYGON:
{
ret = LWGEOM_GEOS_getPointN( GEOSGetExteriorRing_r( handle, g_in ), n );
if ( ret ) return ret;
for ( gn = 0; gn < GEOSGetNumInteriorRings_r( handle, g_in ); ++gn )
{
const GEOSGeometry *g = GEOSGetInteriorRingN_r( handle, g_in, gn );
ret = LWGEOM_GEOS_getPointN( g, n );
if ( ret ) return ret;
}
break;
}
case GEOS_POINT:
case GEOS_LINESTRING:
case GEOS_LINEARRING:
break;
}
seq_in = GEOSGeom_getCoordSeq_r( handle, g_in );
if ( ! seq_in ) return nullptr;
if ( ! GEOSCoordSeq_getSize_r( handle, seq_in, &sz ) ) return nullptr;
if ( ! sz ) return nullptr;
if ( ! GEOSCoordSeq_getDimensions_r( handle, seq_in, &dims ) ) return nullptr;
seq_out = GEOSCoordSeq_create_r( handle, 1, dims );
if ( ! seq_out ) return nullptr;
if ( ! GEOSCoordSeq_getX_r( handle, seq_in, n, &val ) ) return nullptr;
if ( ! GEOSCoordSeq_setX_r( handle, seq_out, n, val ) ) return nullptr;
if ( ! GEOSCoordSeq_getY_r( handle, seq_in, n, &val ) ) return nullptr;
if ( ! GEOSCoordSeq_setY_r( handle, seq_out, n, val ) ) return nullptr;
if ( dims > 2 )
{
if ( ! GEOSCoordSeq_getZ_r( handle, seq_in, n, &val ) ) return nullptr;
if ( ! GEOSCoordSeq_setZ_r( handle, seq_out, n, val ) ) return nullptr;
}
return GEOSGeom_createPoint_r( handle, seq_out );
}
SEXP rgeos_geospolygon2Polygons(SEXP env, GEOSGeom geom, SEXP ID) {
GEOSContextHandle_t GEOShandle = getContextHandle(env);
int pc=0;
int type = GEOSGeomTypeId_r(GEOShandle, geom);
int empty = GEOSisEmpty_r(GEOShandle, geom);
int ngeom = GEOSGetNumGeometries_r(GEOShandle, geom);
ngeom = ngeom ? ngeom : 1;
int npoly = 0;
for (int i=0; i<ngeom; i++) {
GEOSGeom GC = (type == GEOS_MULTIPOLYGON && !empty) ?
(GEOSGeometry *) GEOSGetGeometryN_r(GEOShandle, geom, i) :
geom;
int GCempty = GEOSisEmpty_r(GEOShandle, GC);
int GCpolys = (GCempty) ? 1 :
GEOSGetNumInteriorRings_r(GEOShandle, GC) + 1;
npoly += GCpolys;
}
SEXP polys;
PROTECT(polys = NEW_LIST(npoly)); pc++;
int *comm = (int *) R_alloc((size_t) npoly, sizeof(int));
int *po = (int *) R_alloc((size_t) npoly, sizeof(int));
double *areas = (double *) R_alloc((size_t) npoly, sizeof(double));
double totalarea = 0.0;
int k = 0;
for (int i=0; i<ngeom; i++) {
GEOSGeom GC = (type == GEOS_MULTIPOLYGON && !empty) ?
(GEOSGeometry *) GEOSGetGeometryN_r(GEOShandle, geom, i) :
geom;
if (GEOSisEmpty_r(GEOShandle, GC)) {
SEXP ringDir,area,labpt,hole;
PROTECT(ringDir = NEW_INTEGER(1));
INTEGER_POINTER(ringDir)[0] = 1;
PROTECT(labpt = NEW_NUMERIC(2));
NUMERIC_POINTER(labpt)[0] = NA_REAL;
NUMERIC_POINTER(labpt)[1] = NA_REAL;
PROTECT(area = NEW_NUMERIC(1));
NUMERIC_POINTER(area)[0] = 0.0;
PROTECT(hole = NEW_LOGICAL(1));
LOGICAL_POINTER(hole)[0] = TRUE;
SEXP poly;
PROTECT(poly = NEW_OBJECT(MAKE_CLASS("Polygon")));
SET_SLOT(poly, install("ringDir"), ringDir);
SET_SLOT(poly, install("labpt"), labpt);
SET_SLOT(poly, install("area"), area);
SET_SLOT(poly, install("hole"), hole);
SET_SLOT(poly, install("coords"), R_NilValue);
SET_VECTOR_ELT(polys, k, poly);
UNPROTECT(5);
comm[k] = 0;
areas[k] = 0;
po[k] = k + R_OFFSET;
// modified 131004 RSB
// https://stat.ethz.ch/pipermail/r-sig-geo/2013-October/019470.html
// warning("rgeos_geospolygon2Polygons: empty Polygons object");
error("rgeos_geospolygon2Polygons: empty Polygons object");
k++;
} else {
GEOSGeom lr = (GEOSGeometry *) GEOSGetExteriorRing_r(GEOShandle, GC);
if (lr == NULL)
error("rgeos_geospolygon2Polygons: exterior ring failure");
SET_VECTOR_ELT(polys, k, rgeos_geosring2Polygon(env, lr, FALSE));
comm[k] = 0;
areas[k] = NUMERIC_POINTER( GET_SLOT(VECTOR_ELT(polys,k), install("area")) )[0];
totalarea += areas[k];
po[k] = k + R_OFFSET;
int ownerk = k + R_OFFSET;
k++;
int nirs = GEOSGetNumInteriorRings_r(GEOShandle, GC);
for (int j=0; j<nirs; j++) {
lr = (GEOSGeometry *) GEOSGetInteriorRingN_r(GEOShandle, GC, j);
if (lr == NULL)
error("rgeos_geospolygon2Polygons: interior ring failure");
SET_VECTOR_ELT(polys, k, rgeos_geosring2Polygon(env, lr, TRUE));
comm[k] = ownerk;
areas[k] = NUMERIC_POINTER( GET_SLOT(VECTOR_ELT(polys,k), install("area")) )[0];
po[k] = k + R_OFFSET;
k++;
}
}
}
SEXP plotOrder;
PROTECT(plotOrder = NEW_INTEGER(npoly)); pc++;
revsort(areas, po, npoly);
for (int i=0; i<npoly; i++)
INTEGER_POINTER(plotOrder)[i] = po[i];
SEXP labpt = GET_SLOT(VECTOR_ELT(polys,po[0]-1), install("labpt"));
SEXP area;
PROTECT(area = NEW_NUMERIC(1)); pc++;
NUMERIC_POINTER(area)[0] = totalarea;
SEXP comment;
PROTECT(comment = NEW_CHARACTER(1)); pc++;
char *buf;
int nc;
nc = (int) (ceil(log10(npoly)+1.0))+1;
buf = (char *) R_alloc((size_t) (npoly*nc)+1, sizeof(char));
SP_PREFIX(comm2comment)(buf, (npoly*nc)+1, comm, npoly);
SET_STRING_ELT(comment, 0, mkChar((const char*) buf));
SEXP ans;
PROTECT(ans = NEW_OBJECT(MAKE_CLASS("Polygons"))); pc++;
SET_SLOT(ans, install("Polygons"), polys);
SET_SLOT(ans, install("plotOrder"), plotOrder);
SET_SLOT(ans, install("labpt"), labpt);
SET_SLOT(ans, install("ID"), ID);
SET_SLOT(ans, install("area"), area);
setAttrib(ans, install("comment"), comment);
UNPROTECT(pc);
return(ans);
}