*
* PostGIS - Spatial Types for PostgreSQL
* http://postgis.net
*
* PostGIS is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 2 of the License, or
* (at your option) any later version.
*
* PostGIS 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with PostGIS. If not, see <http://www.gnu.org/licenses/>.
*
**********************************************************************
*
* Copyright 2011 Nicklas Avén
* Copyright 2019 Darafei Praliaskouski
*
**********************************************************************/
#include <string.h>
#include <stdlib.h>
#include "measures3d.h"
#include "lwrandom.h"
#include "lwgeom_log.h"
static inline int
get_3dvector_from_points(POINT3DZ *p1, POINT3DZ *p2, VECTOR3D *v)
{
v->x = p2->x - p1->x;
v->y = p2->y - p1->y;
v->z = p2->z - p1->z;
return (!FP_IS_ZERO(v->x) || !FP_IS_ZERO(v->y) || !FP_IS_ZERO(v->z));
}
static inline int
get_3dcross_product(VECTOR3D *v1, VECTOR3D *v2, VECTOR3D *v)
{
v->x = (v1->y * v2->z) - (v1->z * v2->y);
v->y = (v1->z * v2->x) - (v1->x * v2->z);
v->z = (v1->x * v2->y) - (v1->y * v2->x);
return (!FP_IS_ZERO(v->x) || !FP_IS_ZERO(v->y) || !FP_IS_ZERO(v->z));
}
This function is used to create a vertical line used for cases where one if the
geometries lacks z-values. The vertical line crosses the 2d point that is closest
and the z-range is from maxz to minz in the geometry that has z values.
*/
static LWGEOM *
create_v_line(const LWGEOM *lwgeom, double x, double y, int32_t srid)
{
LWPOINT *lwpoints[2];
GBOX gbox;
int rv = lwgeom_calculate_gbox(lwgeom, &gbox);
if (rv == LW_FAILURE)
return NULL;
lwpoints[0] = lwpoint_make3dz(srid, x, y, gbox.zmin);
lwpoints[1] = lwpoint_make3dz(srid, x, y, gbox.zmax);
return (LWGEOM *)lwline_from_ptarray(srid, 2, lwpoints);
}
LWGEOM *
lwgeom_closest_line_3d(const LWGEOM *lw1, const LWGEOM *lw2)
{
return lw_dist3d_distanceline(lw1, lw2, lw1->srid, DIST_MIN);
}
LWGEOM *
lwgeom_furthest_line_3d(LWGEOM *lw1, LWGEOM *lw2)
{
return lw_dist3d_distanceline(lw1, lw2, lw1->srid, DIST_MAX);
}
LWGEOM *
lwgeom_closest_point_3d(const LWGEOM *lw1, const LWGEOM *lw2)
{
return lw_dist3d_distancepoint(lw1, lw2, lw1->srid, DIST_MIN);
}
Function initializing 3dshortestline and 3dlongestline calculations.
*/
LWGEOM *
lw_dist3d_distanceline(const LWGEOM *lw1, const LWGEOM *lw2, int32_t srid, int mode)
{
LWDEBUG(2, "lw_dist3d_distanceline is called");
double x1, x2, y1, y2, z1, z2, x, y;
double initdistance = (mode == DIST_MIN ? DBL_MAX : -1.0);
DISTPTS3D thedl;
LWPOINT *lwpoints[2];
LWGEOM *result;
thedl.mode = mode;
thedl.distance = initdistance;
thedl.tolerance = 0.0;
* If not, send it to 2D-calculations which will give the same result
* as an infinite z-value at one or two of the geometries */
if (!lwgeom_has_z(lw1) || !lwgeom_has_z(lw2))
{
lwnotice(
"One or both of the geometries is missing z-value. The unknown z-value will be regarded as \"any value\"");
if (!lwgeom_has_z(lw1) && !lwgeom_has_z(lw2))
return lw_dist2d_distanceline(lw1, lw2, srid, mode);
DISTPTS thedl2d;
thedl2d.mode = mode;
thedl2d.distance = initdistance;
thedl2d.tolerance = 0.0;
if (!lw_dist2d_comp(lw1, lw2, &thedl2d))
{
lwerror("Some unspecified error.");
result = (LWGEOM *)lwcollection_construct_empty(COLLECTIONTYPE, srid, 0, 0);
}
LWGEOM *vertical_line;
if (!lwgeom_has_z(lw1))
{
x = thedl2d.p1.x;
y = thedl2d.p1.y;
vertical_line = create_v_line(lw2, x, y, srid);
if (!lw_dist3d_recursive(vertical_line, lw2, &thedl))
{
lwfree(vertical_line);
lwerror("Some unspecified error.");
result = (LWGEOM *)lwcollection_construct_empty(COLLECTIONTYPE, srid, 0, 0);
}
lwfree(vertical_line);
}
if (!lwgeom_has_z(lw2))
{
x = thedl2d.p2.x;
y = thedl2d.p2.y;
vertical_line = create_v_line(lw1, x, y, srid);
if (!lw_dist3d_recursive(lw1, vertical_line, &thedl))
{
lwfree(vertical_line);
lwerror("Some unspecified error.");
return (LWGEOM *)lwcollection_construct_empty(COLLECTIONTYPE, srid, 0, 0);
}
lwfree(vertical_line);
}
}
else
{
if (!lw_dist3d_recursive(lw1, lw2, &thedl))
{
lwerror("Some unspecified error.");
result = (LWGEOM *)lwcollection_construct_empty(COLLECTIONTYPE, srid, 0, 0);
}
}
if (thedl.distance == initdistance)
{
LWDEBUG(3, "didn't find geometries to measure between, returning null");
result = (LWGEOM *)lwcollection_construct_empty(COLLECTIONTYPE, srid, 0, 0);
}
else
{
x1 = thedl.p1.x;
y1 = thedl.p1.y;
z1 = thedl.p1.z;
x2 = thedl.p2.x;
y2 = thedl.p2.y;
z2 = thedl.p2.z;
lwpoints[0] = lwpoint_make3dz(srid, x1, y1, z1);
lwpoints[1] = lwpoint_make3dz(srid, x2, y2, z2);
result = (LWGEOM *)lwline_from_ptarray(srid, 2, lwpoints);
}
return result;
}
Function initializing 3dclosestpoint calculations.
*/
LWGEOM *
lw_dist3d_distancepoint(const LWGEOM *lw1, const LWGEOM *lw2, int32_t srid, int mode)
{
double x, y, z;
DISTPTS3D thedl;
double initdistance = DBL_MAX;
LWGEOM *result;
thedl.mode = mode;
thedl.distance = initdistance;
thedl.tolerance = 0;
LWDEBUG(2, "lw_dist3d_distancepoint is called");
* If not, send it to 2D-calculations which will give the same result
* as an infinite z-value at one or two of the geometries
*/
if (!lwgeom_has_z(lw1) || !lwgeom_has_z(lw2))
{
lwnotice(
"One or both of the geometries is missing z-value. The unknown z-value will be regarded as \"any value\"");
if (!lwgeom_has_z(lw1) && !lwgeom_has_z(lw2))
return lw_dist2d_distancepoint(lw1, lw2, srid, mode);
DISTPTS thedl2d;
thedl2d.mode = mode;
thedl2d.distance = initdistance;
thedl2d.tolerance = 0.0;
if (!lw_dist2d_comp(lw1, lw2, &thedl2d))
{
lwerror("Some unspecified error.");
return (LWGEOM *)lwcollection_construct_empty(COLLECTIONTYPE, srid, 0, 0);
}
LWGEOM *vertical_line;
if (!lwgeom_has_z(lw1))
{
x = thedl2d.p1.x;
y = thedl2d.p1.y;
vertical_line = create_v_line(lw2, x, y, srid);
if (!lw_dist3d_recursive(vertical_line, lw2, &thedl))
{
lwfree(vertical_line);
lwerror("Some unspecified error.");
return (LWGEOM *)lwcollection_construct_empty(COLLECTIONTYPE, srid, 0, 0);
}
lwfree(vertical_line);
}
if (!lwgeom_has_z(lw2))
{
x = thedl2d.p2.x;
y = thedl2d.p2.y;
vertical_line = create_v_line(lw1, x, y, srid);
if (!lw_dist3d_recursive(lw1, vertical_line, &thedl))
{
lwfree(vertical_line);
lwerror("Some unspecified error.");
result = (LWGEOM *)lwcollection_construct_empty(COLLECTIONTYPE, srid, 0, 0);
}
lwfree(vertical_line);
}
}
else
{
if (!lw_dist3d_recursive(lw1, lw2, &thedl))
{
lwerror("Some unspecified error.");
result = (LWGEOM *)lwcollection_construct_empty(COLLECTIONTYPE, srid, 0, 0);
}
}
if (thedl.distance == initdistance)
{
LWDEBUG(3, "didn't find geometries to measure between, returning null");
result = (LWGEOM *)lwcollection_construct_empty(COLLECTIONTYPE, srid, 0, 0);
}
else
{
x = thedl.p1.x;
y = thedl.p1.y;
z = thedl.p1.z;
result = (LWGEOM *)lwpoint_make3dz(srid, x, y, z);
}
return result;
}
Function initializing 3d max distance calculation
*/
double
lwgeom_maxdistance3d(const LWGEOM *lw1, const LWGEOM *lw2)
{
return lwgeom_maxdistance3d_tolerance(lw1, lw2, 0.0);
}
Function handling 3d max distance calculations and dfullywithin calculations.
The difference is just the tolerance.
*/
double
lwgeom_maxdistance3d_tolerance(const LWGEOM *lw1, const LWGEOM *lw2, double tolerance)
{
if (!lwgeom_has_z(lw1) || !lwgeom_has_z(lw2))
{
lwnotice(
"One or both of the geometries is missing z-value. The unknown z-value will be regarded as \"any value\"");
return lwgeom_maxdistance2d_tolerance(lw1, lw2, tolerance);
}
DISTPTS3D thedl;
LWDEBUG(2, "lwgeom_maxdistance3d_tolerance is called");
thedl.mode = DIST_MAX;
thedl.distance = -1;
thedl.tolerance = tolerance;
if (lw_dist3d_recursive(lw1, lw2, &thedl))
return thedl.distance;
lwerror("Some unspecified error.");
return -1;
}
Function initializing 3d min distance calculation
*/
double
lwgeom_mindistance3d(const LWGEOM *lw1, const LWGEOM *lw2)
{
return lwgeom_mindistance3d_tolerance(lw1, lw2, 0.0);
}
static inline int
gbox_contains_3d(const GBOX *g1, const GBOX *g2)
{
return (g2->xmin >= g1->xmin) && (g2->xmax <= g1->xmax) && (g2->ymin >= g1->ymin) && (g2->ymax <= g1->ymax) &&
(g2->zmin >= g1->zmin) && (g2->zmax <= g1->zmax);
}
static inline int
lwgeom_solid_contains_lwgeom(const LWGEOM *solid, const LWGEOM *g)
{
const GBOX *b1;
const GBOX *b2;
if (!FLAGS_GET_SOLID(solid->flags))
return LW_FALSE;
b1 = lwgeom_get_bbox(solid);
b2 = lwgeom_get_bbox(g);
if (!gbox_contains_3d(b1, b2))
return LW_FALSE;
else
{
POINT4D pt;
LWGEOM *solid_copy = lwgeom_clone_deep(solid);
LWGEOM *g_copy = lwgeom_clone_deep(g);
while (LW_TRUE)
{
uint8_t is_boundary = LW_FALSE;
uint8_t is_inside = LW_FALSE;
if (!lwgeom_startpoint(g_copy, &pt))
return LW_FALSE;
LWCOLLECTION *c = lwgeom_clip_to_ordinate_range(solid_copy, 'Z', pt.z, DBL_MAX, 0);
for (uint32_t i = 0; i < c->ngeoms; i++)
{
if (c->geoms[i]->type == POLYGONTYPE)
{
int t = lwpoly_contains_point((LWPOLY *)c->geoms[i], (POINT2D *)&pt);
if (t == LW_INSIDE)
is_inside = !is_inside;
else if (t == LW_BOUNDARY)
{
is_boundary = LW_TRUE;
break;
}
}
else if (c->geoms[i]->type == TRIANGLETYPE)
{
LWTRIANGLE *tri = (LWTRIANGLE *)c->geoms[i];
int t = ptarray_contains_point(tri->points, (POINT2D *)&pt);
if (t == LW_INSIDE)
is_inside = !is_inside;
else if (t == LW_BOUNDARY)
{
is_boundary = LW_TRUE;
break;
}
}
}
lwcollection_free(c);
lwgeom_free(solid_copy);
lwgeom_free(g_copy);
if (is_boundary)
{
double cx = lwrandom_uniform() - 0.5;
double cy = lwrandom_uniform() - 0.5;
AFFINE aff = {1, 0, cx, 0, 1, cy, 0, 0, 1, 0, 0, 0};
solid_copy = lwgeom_clone_deep(solid);
lwgeom_affine(solid_copy, &aff);
g_copy = lwgeom_clone_deep(g);
lwgeom_affine(g_copy, &aff);
continue;
}
return is_inside;
}
}
}
Function handling 3d min distance calculations and dwithin calculations.
The difference is just the tolerance.
*/
double
lwgeom_mindistance3d_tolerance(const LWGEOM *lw1, const LWGEOM *lw2, double tolerance)
{
assert(tolerance >= 0);
if (!lwgeom_has_z(lw1) || !lwgeom_has_z(lw2))
{
lwnotice(
"One or both of the geometries is missing z-value. The unknown z-value will be regarded as \"any value\"");
return lwgeom_mindistance2d_tolerance(lw1, lw2, tolerance);
}
DISTPTS3D thedl;
thedl.mode = DIST_MIN;
thedl.distance = DBL_MAX;
thedl.tolerance = tolerance;
if (lw_dist3d_recursive(lw1, lw2, &thedl))
{
if (thedl.distance <= tolerance)
return thedl.distance;
if (lwgeom_solid_contains_lwgeom(lw1, lw2) || lwgeom_solid_contains_lwgeom(lw2, lw1))
return 0;
return thedl.distance;
}
lwerror("Some unspecified error.");
return DBL_MAX;
}
End of Initializing functions
--------------------------------------------------------------------------------------------------------------*/
Preprocessing functions
Functions preparing geometries for distance-calculations
--------------------------------------------------------------------------------------------------------------*/
This is a recursive function delivering every possible combination of subgeometries
*/
int
lw_dist3d_recursive(const LWGEOM *lwg1, const LWGEOM *lwg2, DISTPTS3D *dl)
{
int i, j;
int n1 = 1;
int n2 = 1;
LWGEOM *g1 = NULL;
LWGEOM *g2 = NULL;
LWCOLLECTION *c1 = NULL;
LWCOLLECTION *c2 = NULL;
LWDEBUGF(2, "lw_dist3d_recursive is called with type1=%d, type2=%d", lwg1->type, lwg2->type);
if (lwgeom_is_collection(lwg1))
{
LWDEBUG(3, "First geometry is collection");
c1 = lwgeom_as_lwcollection(lwg1);
n1 = c1->ngeoms;
}
if (lwgeom_is_collection(lwg2))
{
LWDEBUG(3, "Second geometry is collection");
c2 = lwgeom_as_lwcollection(lwg2);
n2 = c2->ngeoms;
}
for (i = 0; i < n1; i++)
{
if (lwgeom_is_collection(lwg1))
g1 = c1->geoms[i];
else
g1 = (LWGEOM *)lwg1;
if (lwgeom_is_empty(g1))
return LW_TRUE;
if (lwgeom_is_collection(g1))
{
LWDEBUG(3, "Found collection inside first geometry collection, recursing");
if (!lw_dist3d_recursive(g1, lwg2, dl))
return LW_FALSE;
continue;
}
for (j = 0; j < n2; j++)
{
if (lwgeom_is_collection(lwg2))
g2 = c2->geoms[j];
else
g2 = (LWGEOM *)lwg2;
if (lwgeom_is_collection(g2))
{
LWDEBUG(3, "Found collection inside second geometry collection, recursing");
if (!lw_dist3d_recursive(g1, g2, dl))
return LW_FALSE;
continue;
}
* have stopped the process*/
if (lwgeom_is_empty(g1) || lwgeom_is_empty(g2))
return LW_TRUE;
if (!lw_dist3d_distribute_bruteforce(g1, g2, dl))
return LW_FALSE;
if (dl->distance <= dl->tolerance && dl->mode == DIST_MIN)
return LW_TRUE;
}
}
return LW_TRUE;
}
This function distributes the brute-force for 3D so far the only type, tasks depending on type
*/
int
lw_dist3d_distribute_bruteforce(const LWGEOM *lwg1, const LWGEOM *lwg2, DISTPTS3D *dl)
{
int t1 = lwg1->type;
int t2 = lwg2->type;
LWDEBUGF(2, "lw_dist3d_distribute_bruteforce is called with typ1=%d, type2=%d", lwg1->type, lwg2->type);
if (t1 == POINTTYPE)
{
if (t2 == POINTTYPE)
{
dl->twisted = 1;
return lw_dist3d_point_point((LWPOINT *)lwg1, (LWPOINT *)lwg2, dl);
}
else if (t2 == LINETYPE)
{
dl->twisted = 1;
return lw_dist3d_point_line((LWPOINT *)lwg1, (LWLINE *)lwg2, dl);
}
else if (t2 == POLYGONTYPE)
{
dl->twisted = 1;
return lw_dist3d_point_poly((LWPOINT *)lwg1, (LWPOLY *)lwg2, dl);
}
else if (t2 == TRIANGLETYPE)
{
dl->twisted = 1;
return lw_dist3d_point_tri((LWPOINT *)lwg1, (LWTRIANGLE *)lwg2, dl);
}
else
{
lwerror("%s: Unsupported geometry type: %s", __func__, lwtype_name(t2));
return LW_FALSE;
}
}
else if (t1 == LINETYPE)
{
if (t2 == POINTTYPE)
{
dl->twisted = -1;
return lw_dist3d_point_line((LWPOINT *)lwg2, (LWLINE *)lwg1, dl);
}
else if (t2 == LINETYPE)
{
dl->twisted = 1;
return lw_dist3d_line_line((LWLINE *)lwg1, (LWLINE *)lwg2, dl);
}
else if (t2 == POLYGONTYPE)
{
dl->twisted = 1;
return lw_dist3d_line_poly((LWLINE *)lwg1, (LWPOLY *)lwg2, dl);
}
else if (t2 == TRIANGLETYPE)
{
dl->twisted = 1;
return lw_dist3d_line_tri((LWLINE *)lwg1, (LWTRIANGLE *)lwg2, dl);
}
else
{
lwerror("%s: Unsupported geometry type: %s", __func__, lwtype_name(t2));
return LW_FALSE;
}
}
else if (t1 == POLYGONTYPE)
{
if (t2 == POLYGONTYPE)
{
dl->twisted = 1;
return lw_dist3d_poly_poly((LWPOLY *)lwg1, (LWPOLY *)lwg2, dl);
}
else if (t2 == POINTTYPE)
{
dl->twisted = -1;
return lw_dist3d_point_poly((LWPOINT *)lwg2, (LWPOLY *)lwg1, dl);
}
else if (t2 == LINETYPE)
{
dl->twisted = -1;
return lw_dist3d_line_poly((LWLINE *)lwg2, (LWPOLY *)lwg1, dl);
}
else if (t2 == TRIANGLETYPE)
{
dl->twisted = 1;
return lw_dist3d_poly_tri((LWPOLY *)lwg1, (LWTRIANGLE *)lwg2, dl);
}
else
{
lwerror("%s: Unsupported geometry type: %s", __func__, lwtype_name(t2));
return LW_FALSE;
}
}
else if (t1 == TRIANGLETYPE)
{
if (t2 == POLYGONTYPE)
{
dl->twisted = -1;
return lw_dist3d_poly_tri((LWPOLY *)lwg2, (LWTRIANGLE *)lwg1, dl);
}
else if (t2 == POINTTYPE)
{
dl->twisted = -1;
return lw_dist3d_point_tri((LWPOINT *)lwg2, (LWTRIANGLE *)lwg1, dl);
}
else if (t2 == LINETYPE)
{
dl->twisted = -1;
return lw_dist3d_line_tri((LWLINE *)lwg2, (LWTRIANGLE *)lwg1, dl);
}
else if (t2 == TRIANGLETYPE)
{
dl->twisted = 1;
return lw_dist3d_tri_tri((LWTRIANGLE *)lwg1, (LWTRIANGLE *)lwg2, dl);
}
else
{
lwerror("%s: Unsupported geometry type: %s", __func__, lwtype_name(t2));
return LW_FALSE;
}
}
else
{
lwerror("%s: Unsupported geometry type: %s", __func__, lwtype_name(t1));
return LW_FALSE;
}
}
End of Preprocessing functions
--------------------------------------------------------------------------------------------------------------*/
Brute force functions
So far the only way to do 3D-calculations
--------------------------------------------------------------------------------------------------------------*/
point to point calculation
*/
int
lw_dist3d_point_point(LWPOINT *point1, LWPOINT *point2, DISTPTS3D *dl)
{
POINT3DZ p1;
POINT3DZ p2;
LWDEBUG(2, "lw_dist3d_point_point is called");
getPoint3dz_p(point1->point, 0, &p1);
getPoint3dz_p(point2->point, 0, &p2);
return lw_dist3d_pt_pt(&p1, &p2, dl);
}
point to line calculation
*/
int
lw_dist3d_point_line(LWPOINT *point, LWLINE *line, DISTPTS3D *dl)
{
POINT3DZ p;
POINTARRAY *pa = line->points;
LWDEBUG(2, "lw_dist3d_point_line is called");
getPoint3dz_p(point->point, 0, &p);
return lw_dist3d_pt_ptarray(&p, pa, dl);
}
Computes point to polygon distance
For mindistance that means:
1) find the plane of the polygon
2) projecting the point to the plane of the polygon
3) finding if that projected point is inside the polygon, if so the distance is measured to that projected point
4) if not in polygon above, check the distance against the boundary of the polygon
for max distance it is always point against boundary
*/
int
lw_dist3d_point_poly(LWPOINT *point, LWPOLY *poly, DISTPTS3D *dl)
{
POINT3DZ p, projp;
PLANE3D plane;
LWDEBUG(2, "lw_dist3d_point_poly is called");
getPoint3dz_p(point->point, 0, &p);
if (dl->mode == DIST_MAX)
return lw_dist3d_pt_ptarray(&p, poly->rings[0], dl);
if (!define_plane(poly->rings[0], &plane))
{
return lw_dist3d_pt_ptarray(&p, poly->rings[0], dl);
}
project_point_on_plane(&p, &plane, &projp);
return lw_dist3d_pt_poly(&p, poly, &plane, &projp, dl);
}
int
lw_dist3d_point_tri(LWPOINT *point, LWTRIANGLE *tri, DISTPTS3D *dl)
{
POINT3DZ p, projp;
PLANE3D plane;
getPoint3dz_p(point->point, 0, &p);
if (dl->mode == DIST_MAX)
return lw_dist3d_pt_ptarray(&p, tri->points, dl);
if (!define_plane(tri->points, &plane))
return lw_dist3d_pt_ptarray(&p, tri->points, dl);
project_point_on_plane(&p, &plane, &projp);
return lw_dist3d_pt_tri(&p, tri, &plane, &projp, dl);
}
int
lw_dist3d_line_line(LWLINE *line1, LWLINE *line2, DISTPTS3D *dl)
{
POINTARRAY *pa1 = line1->points;
POINTARRAY *pa2 = line2->points;
LWDEBUG(2, "lw_dist3d_line_line is called");
return lw_dist3d_ptarray_ptarray(pa1, pa2, dl);
}
int
lw_dist3d_line_poly(LWLINE *line, LWPOLY *poly, DISTPTS3D *dl)
{
PLANE3D plane;
LWDEBUG(2, "lw_dist3d_line_poly is called");
if (dl->mode == DIST_MAX)
return lw_dist3d_ptarray_ptarray(line->points, poly->rings[0], dl);
if (!define_plane(poly->rings[0], &plane))
return lw_dist3d_ptarray_ptarray(line->points, poly->rings[0], dl);
return lw_dist3d_ptarray_poly(line->points, poly, &plane, dl);
}
int
lw_dist3d_line_tri(LWLINE *line, LWTRIANGLE *tri, DISTPTS3D *dl)
{
PLANE3D plane;
if (dl->mode == DIST_MAX)
return lw_dist3d_ptarray_ptarray(line->points, tri->points, dl);
if (!define_plane(tri->points, &plane))
return lw_dist3d_ptarray_ptarray(line->points, tri->points, dl);
return lw_dist3d_ptarray_tri(line->points, tri, &plane, dl);
}
int
lw_dist3d_poly_poly(LWPOLY *poly1, LWPOLY *poly2, DISTPTS3D *dl)
{
PLANE3D plane1, plane2;
int planedef1, planedef2;
LWDEBUG(2, "lw_dist3d_poly_poly is called");
if (dl->mode == DIST_MAX)
return lw_dist3d_ptarray_ptarray(poly1->rings[0], poly2->rings[0], dl);
planedef1 = define_plane(poly1->rings[0], &plane1);
planedef2 = define_plane(poly2->rings[0], &plane2);
if (!planedef1 || !planedef2)
{
if (!planedef1 && !planedef2)
return lw_dist3d_ptarray_ptarray(poly1->rings[0], poly2->rings[0], dl);
else if (!planedef1)
return lw_dist3d_ptarray_poly(poly1->rings[0], poly2, &plane2, dl);
else
return lw_dist3d_ptarray_poly(poly2->rings[0], poly1, &plane1, dl);
}
and then take the second boundary comparing with the first polygon */
dl->twisted = 1;
if (!lw_dist3d_ptarray_poly(poly1->rings[0], poly2, &plane2, dl))
return LW_FALSE;
if (dl->distance < dl->tolerance)
return LW_TRUE;
dl->twisted = -1;
right order of points in shortest line. */
return lw_dist3d_ptarray_poly(poly2->rings[0], poly1, &plane1, dl);
}
int
lw_dist3d_poly_tri(LWPOLY *poly, LWTRIANGLE *tri, DISTPTS3D *dl)
{
PLANE3D plane1, plane2;
int planedef1, planedef2;
if (dl->mode == DIST_MAX)
return lw_dist3d_ptarray_ptarray(poly->rings[0], tri->points, dl);
planedef1 = define_plane(poly->rings[0], &plane1);
planedef2 = define_plane(tri->points, &plane2);
if (!planedef1 || !planedef2)
{
if (!planedef1 && !planedef2)
return lw_dist3d_ptarray_ptarray(poly->rings[0], tri->points, dl);
else if (!planedef1)
return lw_dist3d_ptarray_tri(poly->rings[0], tri, &plane2, dl);
else
return lw_dist3d_ptarray_poly(tri->points, poly, &plane1, dl);
}
and then take the second boundary comparing with the first polygon */
dl->twisted = 1;
if (!lw_dist3d_ptarray_tri(poly->rings[0], tri, &plane2, dl))
return LW_FALSE;
if (dl->distance < dl->tolerance)
return LW_TRUE;
dl->twisted = -1;
right order of points in shortest line. */
return lw_dist3d_ptarray_poly(tri->points, poly, &plane1, dl);
}
int
lw_dist3d_tri_tri(LWTRIANGLE *tri1, LWTRIANGLE *tri2, DISTPTS3D *dl)
{
PLANE3D plane1, plane2;
int planedef1, planedef2;
if (dl->mode == DIST_MAX)
return lw_dist3d_ptarray_ptarray(tri1->points, tri2->points, dl);
planedef1 = define_plane(tri1->points, &plane1);
planedef2 = define_plane(tri2->points, &plane2);
if (!planedef1 || !planedef2)
{
if (!planedef1 && !planedef2)
return lw_dist3d_ptarray_ptarray(tri1->points, tri2->points, dl);
else if (!planedef1)
return lw_dist3d_ptarray_tri(tri1->points, tri2, &plane2, dl);
else
return lw_dist3d_ptarray_tri(tri2->points, tri1, &plane1, dl);
}
and then take the second boundary comparing with the first polygon */
dl->twisted = 1;
if (!lw_dist3d_ptarray_tri(tri1->points, tri2, &plane2, dl))
return LW_FALSE;
if (dl->distance < dl->tolerance)
return LW_TRUE;
dl->twisted = -1;
right order of points in shortest line. */
return lw_dist3d_ptarray_tri(tri2->points, tri1, &plane1, dl);
}
* search all the segments of pointarray to see which one is closest to p
* Returns distance between point and pointarray
*/
int
lw_dist3d_pt_ptarray(POINT3DZ *p, POINTARRAY *pa, DISTPTS3D *dl)
{
uint32_t t;
POINT3DZ start, end;
int twist = dl->twisted;
if (!pa)
return LW_FALSE;
getPoint3dz_p(pa, 0, &start);
for (t = 1; t < pa->npoints; t++)
{
dl->twisted = twist;
getPoint3dz_p(pa, t, &end);
if (!lw_dist3d_pt_seg(p, &start, &end, dl))
return LW_FALSE;
if (dl->distance <= dl->tolerance && dl->mode == DIST_MIN)
return LW_TRUE;
start = end;
}
return LW_TRUE;
}
If searching for min distance, this one finds the closest point on segment A-B from p.
if searching for max distance it just sends p-A and p-B to pt-pt calculation
*/
int
lw_dist3d_pt_seg(POINT3DZ *p, POINT3DZ *A, POINT3DZ *B, DISTPTS3D *dl)
{
POINT3DZ c;
double r;
if ((A->x == B->x) && (A->y == B->y) && (A->z == B->z))
{
return lw_dist3d_pt_pt(p, A, dl);
}
r = ((p->x - A->x) * (B->x - A->x) + (p->y - A->y) * (B->y - A->y) + (p->z - A->z) * (B->z - A->z)) /
((B->x - A->x) * (B->x - A->x) + (B->y - A->y) * (B->y - A->y) + (B->z - A->z) * (B->z - A->z));
the maxdistance have to be between two vertexes,
compared to mindistance which can be between
two vertexes vertex.*/
if (dl->mode == DIST_MAX)
{
if (r >= 0.5)
return lw_dist3d_pt_pt(p, A, dl);
if (r < 0.5)
return lw_dist3d_pt_pt(p, B, dl);
}
if (r <= 0)
return lw_dist3d_pt_pt(p, A, dl);
if (r >= 1)
return lw_dist3d_pt_pt(p, B, dl);
then we find that point and send it to lw_dist3d_pt_pt*/
c.x = A->x + r * (B->x - A->x);
c.y = A->y + r * (B->y - A->y);
c.z = A->z + r * (B->z - A->z);
return lw_dist3d_pt_pt(p, &c, dl);
}
double
distance3d_pt_pt(const POINT3D *p1, const POINT3D *p2)
{
double dx = p2->x - p1->x;
double dy = p2->y - p1->y;
double dz = p2->z - p1->z;
return sqrt(dx * dx + dy * dy + dz * dz);
}
Compares incoming points and
stores the points closest to each other
or most far away from each other
depending on dl->mode (max or min)
*/
int
lw_dist3d_pt_pt(POINT3DZ *thep1, POINT3DZ *thep2, DISTPTS3D *dl)
{
double dx = thep2->x - thep1->x;
double dy = thep2->y - thep1->y;
double dz = thep2->z - thep1->z;
double dist = sqrt(dx * dx + dy * dy + dz * dz);
LWDEBUGF(2,
"lw_dist3d_pt_pt called (with points: p1.x=%f, p1.y=%f,p1.z=%f,p2.x=%f, p2.y=%f,p2.z=%f)",
thep1->x,
thep1->y,
thep1->z,
thep2->x,
thep2->y,
thep2->z);
if (((dl->distance - dist) * (dl->mode)) >
0)
{
dl->distance = dist;
if (dl->twisted > 0)
time the order is changed earlier in the chain*/
{
dl->p1 = *thep1;
dl->p2 = *thep2;
}
else
{
dl->p1 = *thep2;
dl->p2 = *thep1;
}
}
return LW_TRUE;
}
Finds all combinations of segments between two pointarrays
*/
int
lw_dist3d_ptarray_ptarray(POINTARRAY *l1, POINTARRAY *l2, DISTPTS3D *dl)
{
uint32_t t, u;
POINT3DZ start, end;
POINT3DZ start2, end2;
int twist = dl->twisted;
LWDEBUGF(2, "lw_dist3d_ptarray_ptarray called (points: %d-%d)", l1->npoints, l2->npoints);
if (dl->mode == DIST_MAX)
the maxdistance have to be between two vertexes*/
{
for (t = 0; t < l1->npoints; t++)
{
getPoint3dz_p(l1, t, &start);
for (u = 0; u < l2->npoints; u++)
{
getPoint3dz_p(l2, u, &start2);
lw_dist3d_pt_pt(&start, &start2, dl);
}
}
}
else
{
getPoint3dz_p(l1, 0, &start);
for (t = 1; t < l1->npoints; t++)
{
getPoint3dz_p(l1, t, &end);
getPoint3dz_p(l2, 0, &start2);
for (u = 1; u < l2->npoints; u++)
{
getPoint3dz_p(l2, u, &end2);
dl->twisted = twist;
lw_dist3d_seg_seg(&start, &end, &start2, &end2, dl);
LWDEBUGF(
4, "mindist_ptarray_ptarray; seg %i * seg %i, dist = %g\n", t, u, dl->distance);
LWDEBUGF(3, " seg%d-seg%d dist: %f, mindist: %f", t, u, dl->distance, dl->tolerance);
if (dl->distance <= dl->tolerance && dl->mode == DIST_MIN)
return LW_TRUE;
start2 = end2;
}
start = end;
}
}
return LW_TRUE;
}
Finds the two closest points on two linesegments
*/
int
lw_dist3d_seg_seg(POINT3DZ *s1p1, POINT3DZ *s1p2, POINT3DZ *s2p1, POINT3DZ *s2p2, DISTPTS3D *dl)
{
VECTOR3D v1, v2, vl;
double s1k, s2k;
between the two lines is perpendicular to both lines*/
POINT3DZ p1, p2;
double a, b, c, d, e, D;
if ((s1p1->x == s1p2->x) && (s1p1->y == s1p2->y) && (s1p1->z == s1p2->z))
{
return lw_dist3d_pt_seg(s1p1, s2p1, s2p2, dl);
}
if ((s2p1->x == s2p2->x) && (s2p1->y == s2p2->y) && (s2p1->z == s2p2->z))
{
dl->twisted = ((dl->twisted) * (-1));
return lw_dist3d_pt_seg(s2p1, s1p1, s1p2, dl);
}
Here we use algorithm from softsurfer.com
that can be found here
http://softsurfer.com/Archive/algorithm_0106/algorithm_0106.htm
*/
if (!get_3dvector_from_points(s1p1, s1p2, &v1))
return LW_FALSE;
if (!get_3dvector_from_points(s2p1, s2p2, &v2))
return LW_FALSE;
if (!get_3dvector_from_points(s2p1, s1p1, &vl))
return LW_FALSE;
a = DOT(v1, v1);
b = DOT(v1, v2);
c = DOT(v2, v2);
d = DOT(v1, vl);
e = DOT(v2, vl);
D = a * c - b * b;
if (D < 0.000000001)
{
s1k =
0.0;
projected point on the second line outside segment 2 it wil be found that s2k is >1 or <0.*/
if (b > c)
s2k = d / b;
else
s2k = e / c;
}
else
{
s1k = (b * e - c * d) / D;
s2k = (a * e - b * d) / D;
}
* combinations with start and end points will be tested*/
if (s1k <= 0.0 || s1k >= 1.0 || s2k <= 0.0 || s2k >= 1.0)
{
if (s1k <= 0.0)
{
if (!lw_dist3d_pt_seg(s1p1, s2p1, s2p2, dl))
return LW_FALSE;
}
if (s1k >= 1.0)
{
if (!lw_dist3d_pt_seg(s1p2, s2p1, s2p2, dl))
return LW_FALSE;
}
if (s2k <= 0.0)
{
dl->twisted = ((dl->twisted) * (-1));
if (!lw_dist3d_pt_seg(s2p1, s1p1, s1p2, dl))
return LW_FALSE;
}
if (s2k >= 1.0)
{
dl->twisted = ((dl->twisted) * (-1));
if (!lw_dist3d_pt_seg(s2p2, s1p1, s1p2, dl))
return LW_FALSE;
}
}
else
{
p1.x = s1p1->x + s1k * (s1p2->x - s1p1->x);
p1.y = s1p1->y + s1k * (s1p2->y - s1p1->y);
p1.z = s1p1->z + s1k * (s1p2->z - s1p1->z);
p2.x = s2p1->x + s2k * (s2p2->x - s2p1->x);
p2.y = s2p1->y + s2k * (s2p2->y - s2p1->y);
p2.z = s2p1->z + s2k * (s2p2->z - s2p1->z);
if (!lw_dist3d_pt_pt(&p1, &p2, dl))
{
return LW_FALSE;
}
}
return LW_TRUE;
}
Checking if the point projected on the plane of the polygon actually is inside that polygon.
If so the mindistance is between that projected point and our original point.
If not we check from original point to the boundary.
If the projected point is inside a hole of the polygon we check the distance to the boundary of that hole.
*/
int
lw_dist3d_pt_poly(POINT3DZ *p, LWPOLY *poly, PLANE3D *plane, POINT3DZ *projp, DISTPTS3D *dl)
{
uint32_t i;
if (pt_in_ring_3d(projp, poly->rings[0], plane))
{
for (i = 1; i < poly->nrings; i++)
{
if (pt_in_ring_3d(projp, poly->rings[i], plane))
return lw_dist3d_pt_ptarray(p, poly->rings[i], dl);
}
* input point */
return lw_dist3d_pt_pt(p, projp, dl);
}
else
* instead */
return lw_dist3d_pt_ptarray(p, poly->rings[0], dl);
return LW_TRUE;
}
int
lw_dist3d_pt_tri(POINT3DZ *p, LWTRIANGLE *tri, PLANE3D *plane, POINT3DZ *projp, DISTPTS3D *dl)
{
if (pt_in_ring_3d(projp, tri->points, plane))
* input point */
return lw_dist3d_pt_pt(p, projp, dl);
else
* instead */
return lw_dist3d_pt_ptarray(p, tri->points, dl);
return LW_TRUE;
}
int
lw_dist3d_ptarray_poly(POINTARRAY *pa, LWPOLY *poly, PLANE3D *plane, DISTPTS3D *dl)
{
uint32_t i, j, k;
double f, s1, s2;
VECTOR3D projp1_projp2;
POINT3DZ p1, p2, projp1, projp2, intersectionp;
getPoint3dz_p(pa, 0, &p1);
s1 = project_point_on_plane(&p1, plane, &projp1);
lw_dist3d_pt_poly(&p1, poly, plane, &projp1, dl);
if ((s1 == 0.0) && (dl->distance < dl->tolerance))
return LW_TRUE;
for (i = 1; i < pa->npoints; i++)
{
int intersects;
getPoint3dz_p(pa, i, &p2);
s2 = project_point_on_plane(&p2, plane, &projp2);
lw_dist3d_pt_poly(&p2, poly, plane, &projp2, dl);
if ((s2 == 0.0) && (dl->distance < dl->tolerance))
return LW_TRUE;
* That means that the edge between the points crosses the plane and might intersect with the polygon */
if ((s1 * s2) < 0)
{
f = fabs(s1) / (fabs(s1) + fabs(s2));
get_3dvector_from_points(&projp1, &projp2, &projp1_projp2);
intersectionp.x = projp1.x + f * projp1_projp2.x;
intersectionp.y = projp1.y + f * projp1_projp2.y;
intersectionp.z = projp1.z + f * projp1_projp2.z;
intersects = LW_TRUE;
if (pt_in_ring_3d(&intersectionp, poly->rings[0], plane))
{
for (k = 1; k < poly->nrings; k++)
{
if (pt_in_ring_3d(&intersectionp, poly->rings[k], plane))
{
intersects = LW_FALSE;
break;
}
}
if (intersects)
{
dl->distance = 0.0;
dl->p1.x = intersectionp.x;
dl->p1.y = intersectionp.y;
dl->p1.z = intersectionp.z;
dl->p2.x = intersectionp.x;
dl->p2.y = intersectionp.y;
dl->p2.z = intersectionp.z;
return LW_TRUE;
}
}
}
projp1 = projp2;
s1 = s2;
p1 = p2;
}
for (j = 0; j < poly->nrings; j++)
lw_dist3d_ptarray_ptarray(pa, poly->rings[j], dl);
return LW_TRUE;
}
int
lw_dist3d_ptarray_tri(POINTARRAY *pa, LWTRIANGLE *tri, PLANE3D *plane, DISTPTS3D *dl)
{
uint32_t i;
double f, s1, s2;
VECTOR3D projp1_projp2;
POINT3DZ p1, p2, projp1, projp2, intersectionp;
getPoint3dz_p(pa, 0, &p1);
s1 = project_point_on_plane(&p1, plane, &projp1);
lw_dist3d_pt_tri(&p1, tri, plane, &projp1, dl);
if ((s1 == 0.0) && (dl->distance < dl->tolerance))
return LW_TRUE;
for (i = 1; i < pa->npoints; i++)
{
int intersects;
getPoint3dz_p(pa, i, &p2);
s2 = project_point_on_plane(&p2, plane, &projp2);
lw_dist3d_pt_tri(&p2, tri, plane, &projp2, dl);
if ((s2 == 0.0) && (dl->distance < dl->tolerance))
return LW_TRUE;
* That means that the edge between the points crosses the plane and might intersect with the triangle
*/
if ((s1 * s2) < 0)
{
f = fabs(s1) / (fabs(s1) + fabs(s2));
get_3dvector_from_points(&projp1, &projp2, &projp1_projp2);
intersectionp.x = projp1.x + f * projp1_projp2.x;
intersectionp.y = projp1.y + f * projp1_projp2.y;
intersectionp.z = projp1.z + f * projp1_projp2.z;
intersects = LW_TRUE;
if (pt_in_ring_3d(&intersectionp, tri->points, plane))
{
if (intersects)
{
dl->distance = 0.0;
dl->p1.x = intersectionp.x;
dl->p1.y = intersectionp.y;
dl->p1.z = intersectionp.z;
dl->p2.x = intersectionp.x;
dl->p2.y = intersectionp.y;
dl->p2.z = intersectionp.z;
return LW_TRUE;
}
}
}
projp1 = projp2;
s1 = s2;
p1 = p2;
}
lw_dist3d_ptarray_ptarray(pa, tri->points, dl);
return LW_TRUE;
}
* the plane is stored as a point in plane (plane.pop) and a normal vector (plane.pv)
*
* We are calculating the average point and using it to break the polygon into
* POL_BREAKS (3) parts. Then we calculate the normal of those 3 vectors and
* use its average to define the normal of the plane.This is done to minimize
* the error introduced by FP precision
* We use [3] breaks to contemplate the special case of 3d triangles
*/
int
define_plane(POINTARRAY *pa, PLANE3D *pl)
{
const uint32_t POL_BREAKS = 3;
assert(pa);
assert(pa->npoints > 3);
if (!pa)
return LW_FALSE;
uint32_t unique_points = pa->npoints - 1;
uint32_t i;
if (pa->npoints < 3)
return LW_FALSE;
pl->pop.x = 0.0;
pl->pop.y = 0.0;
pl->pop.z = 0.0;
for (i = 0; i < unique_points; i++)
{
POINT3DZ p;
getPoint3dz_p(pa, i, &p);
pl->pop.x += p.x;
pl->pop.y += p.y;
pl->pop.z += p.z;
}
pl->pop.x /= unique_points;
pl->pop.y /= unique_points;
pl->pop.z /= unique_points;
pl->pv.x = 0.0;
pl->pv.y = 0.0;
pl->pv.z = 0.0;
for (i = 0; i < POL_BREAKS; i++)
{
POINT3DZ point1, point2;
VECTOR3D v1, v2, vp;
uint32_t n1, n2;
n1 = i * unique_points / POL_BREAKS;
n2 = n1 + unique_points / POL_BREAKS;
if (n1 == n2)
continue;
getPoint3dz_p(pa, n1, &point1);
if (!get_3dvector_from_points(&pl->pop, &point1, &v1))
continue;
getPoint3dz_p(pa, n2, &point2);
if (!get_3dvector_from_points(&pl->pop, &point2, &v2))
continue;
if (get_3dcross_product(&v1, &v2, &vp))
{
* We divide by its lengthsq to normalize the additions */
double vl = vp.x * vp.x + vp.y * vp.y + vp.z * vp.z;
pl->pv.x += vp.x / vl;
pl->pv.y += vp.y / vl;
pl->pv.z += vp.z / vl;
}
}
return (!FP_IS_ZERO(pl->pv.x) || !FP_IS_ZERO(pl->pv.y) || !FP_IS_ZERO(pl->pv.z));
}
Finds a point on a plane from where the original point is perpendicular to the plane
*/
double
project_point_on_plane(POINT3DZ *p, PLANE3D *pl, POINT3DZ *p0)
{
this vector will be parallel to the line between our inputted point above the plane and the point we are
searching for on the plane. So, we already have a direction from p to find p0, but we don't know the distance.
*/
VECTOR3D v1;
double f;
if (!get_3dvector_from_points(&(pl->pop), p, &v1))
return 0.0;
f = DOT(pl->pv, v1);
if (FP_IS_ZERO(f))
{
*p0 = *p;
return 0;
}
f = -f / DOT(pl->pv, pl->pv);
p0->x = p->x + pl->pv.x * f;
p0->y = p->y + pl->pv.y * f;
p0->z = p->z + pl->pv.z * f;
return f;
}
* pt_in_ring_3d(): crossing number test for a point in a polygon
* input: p = a point,
* pa = vertex points of a ring V[n+1] with V[n]=V[0]
* plane=the plane that the vertex points are lying on
* returns: 0 = outside, 1 = inside
*
* Our polygons have first and last point the same,
*
* The difference in 3D variant is that we exclude the dimension that faces the plane least.
* That is the dimension with the highest number in pv
*/
int
pt_in_ring_3d(const POINT3DZ *p, const POINTARRAY *ring, PLANE3D *plane)
{
uint32_t cn = 0;
uint32_t i;
POINT3DZ v1, v2;
POINT3DZ first, last;
getPoint3dz_p(ring, 0, &first);
getPoint3dz_p(ring, ring->npoints - 1, &last);
if (memcmp(&first, &last, sizeof(POINT3DZ)))
{
lwerror("pt_in_ring_3d: V[n] != V[0] (%g %g %g!= %g %g %g)",
first.x,
first.y,
first.z,
last.x,
last.y,
last.z);
return LW_FALSE;
}
LWDEBUGF(2, "pt_in_ring_3d called with point: %g %g %g", p->x, p->y, p->z);
getPoint3dz_p(ring, 0, &v1);
if (fabs(plane->pv.z) >= fabs(plane->pv.x) &&
fabs(plane->pv.z) >= fabs(plane->pv.y))
and y vector we project the ring to the xy-plane*/
{
for (i = 0; i < ring->npoints - 1; i++)
{
double vt;
getPoint3dz_p(ring, i + 1, &v2);
if (
((v1.y <= p->y) && (v2.y > p->y))
|| ((v1.y > p->y) && (v2.y <= p->y)))
{
vt = (double)(p->y - v1.y) / (v2.y - v1.y);
if (p->x < v1.x + vt * (v2.x - v1.x))
{
++cn;
}
}
v1 = v2;
}
}
else if (fabs(plane->pv.y) >= fabs(plane->pv.x) &&
fabs(plane->pv.y) >= fabs(plane->pv.z))
than x and z vector we project the ring to the xz-plane*/
{
for (i = 0; i < ring->npoints - 1; i++)
{
double vt;
getPoint3dz_p(ring, i + 1, &v2);
if (
((v1.z <= p->z) && (v2.z > p->z))
|| ((v1.z > p->z) && (v2.z <= p->z)))
{
vt = (double)(p->z - v1.z) / (v2.z - v1.z);
if (p->x < v1.x + vt * (v2.x - v1.x))
{
++cn;
}
}
v1 = v2;
}
}
else
{
for (i = 0; i < ring->npoints - 1; i++)
{
double vt;
getPoint3dz_p(ring, i + 1, &v2);
if (
((v1.z <= p->z) && (v2.z > p->z))
|| ((v1.z > p->z) && (v2.z <= p->z)))
{
vt = (double)(p->z - v1.z) / (v2.z - v1.z);
if (p->y < v1.y + vt * (v2.y - v1.y))
{
++cn;
}
}
v1 = v2;
}
}
LWDEBUGF(3, "pt_in_ring_3d returning %d", cn & 1);
return (cn & 1);
}
End of Brute force functions
--------------------------------------------------------------------------------------------------------------*/