postgis/liblwgeom/lwsegmentize.c

/**********************************************************************
 * $Id$
 *
 * PostGIS - Spatial Types for PostgreSQL
 * http://postgis.refractions.net
 * Copyright 2001-2006 Refractions Research Inc.
 *
 * This is free software; you can redistribute and/or modify it under
 * the terms of the GNU General Public Licence. See the COPYING file.
 *
 **********************************************************************/

#include <stdio.h>
#include <stdlib.h>
#include <stdarg.h>
#include <string.h>
#include <math.h>

#include "liblwgeom.h"


double interpolate_arc(double angle, double zm1, double a1, double zm2, double a2);
POINTARRAY *lwcircle_segmentize(POINT4D *p1, POINT4D *p2, POINT4D *p3, uint32 perQuad);
LWLINE *lwcurve_segmentize(LWCIRCSTRING *icurve, uint32 perQuad);
LWLINE *lwcompound_segmentize(LWCOMPOUND *icompound, uint32 perQuad);
LWPOLY *lwcurvepoly_segmentize(LWCURVEPOLY *curvepoly, uint32 perQuad);
LWMLINE *lwmcurve_segmentize(LWMCURVE *mcurve, uint32 perQuad);
LWMPOLY *lwmsurface_segmentize(LWMSURFACE *msurface, uint32 perQuad);
LWCOLLECTION *lwcollection_segmentize(LWCOLLECTION *collection, uint32 perQuad);
LWGEOM *append_segment(LWGEOM *geom, POINTARRAY *pts, int type, int SRID);
LWGEOM *pta_desegmentize(POINTARRAY *points, int type, int SRID);
LWGEOM *lwline_desegmentize(LWLINE *line);
LWGEOM *lwpolygon_desegmentize(LWPOLY *poly);
LWGEOM *lwmline_desegmentize(LWMLINE *mline);
LWGEOM *lwmpolygon_desegmentize(LWMPOLY *mpoly);
LWGEOM *lwgeom_desegmentize(LWGEOM *geom);



/*
 * Tolerance used to determine equality.
 */
#define EPSILON_SQLMM 1e-8

/*
 * Determines (recursively in the case of collections) whether the geometry
 * contains at least on arc geometry or segment.
 */
int
has_arc(const LWGEOM *geom)
{
	LWCOLLECTION *col;
	int i;

	LWDEBUG(2, "has_arc called.");

	switch (lwgeom_getType(geom->type))
	{
	case POINTTYPE:
	case LINETYPE:
	case POLYGONTYPE:
	case MULTIPOINTTYPE:
	case MULTILINETYPE:
	case MULTIPOLYGONTYPE:
		return 0;
	case CIRCSTRINGTYPE:
		return 1;
		/* It's a collection that MAY contain an arc */
	default:
		col = (LWCOLLECTION *)geom;
		for (i=0; i<col->ngeoms; i++)
		{
			if (has_arc(col->geoms[i]) == 1) return 1;
		}
		return 0;
	}
}

/*
 * Determines the center of the circle defined by the three given points.
 * In the event the circle is complete, the midpoint of the segment defined
 * by the first and second points is returned.  If the points are colinear,
 * as determined by equal slopes, then NULL is returned.  If the interior
 * point is coincident with either end point, they are taken as colinear.
 */
double
lwcircle_center(POINT4D *p1, POINT4D *p2, POINT4D *p3, POINT4D **result)
{
	POINT4D *c;
	double cx, cy, cr;
	double temp, bc, cd, det;

	LWDEBUGF(2, "lwcircle_center called (%.16f, %.16f), (%.16f, %.16f), (%.16f, %.16f).", p1->x, p1->y, p2->x, p2->y, p3->x, p3->y);

	/* Closed circle */
	if (fabs(p1->x - p3->x) < EPSILON_SQLMM
	        && fabs(p1->y - p3->y) < EPSILON_SQLMM)
	{
		cx = p1->x + (p2->x - p1->x) / 2.0;
		cy = p1->y + (p2->y - p1->y) / 2.0;
		c = lwalloc(sizeof(POINT2D));
		c->x = cx;
		c->y = cy;
		*result = c;
		cr = sqrt((cx-p1->x)*(cx-p1->x)+(cy-p1->y)*(cy-p1->y));
		return cr;
	}

	temp = p2->x*p2->x + p2->y*p2->y;
	bc = (p1->x*p1->x + p1->y*p1->y - temp) / 2.0;
	cd = (temp - p3->x*p3->x - p3->y*p3->y) / 2.0;
	det = (p1->x - p2->x)*(p2->y - p3->y)-(p2->x - p3->x)*(p1->y - p2->y);

	/* Check colinearity */
	if (fabs(det) < EPSILON_SQLMM)
	{
		*result = NULL;
		return -1.0;
	}

	det = 1.0 / det;
	cx = (bc*(p2->y - p3->y)-cd*(p1->y - p2->y))*det;
	cy = ((p1->x - p2->x)*cd-(p2->x - p3->x)*bc)*det;
	c = lwalloc(sizeof(POINT4D));
	c->x = cx;
	c->y = cy;
	*result = c;
	cr = sqrt((cx-p1->x)*(cx-p1->x)+(cy-p1->y)*(cy-p1->y));
	return cr;
}

double
interpolate_arc(double angle, double zm1, double a1, double zm2, double a2)
{
	double frac = fabs((angle - a1) / (a2 - a1));
	double result = frac * (zm2 - zm1) + zm1;

	LWDEBUG(2, "interpolate_arc called.");

	LWDEBUGF(3, "interpolate_arc: angle=%.16f, a1=%.16f, a2=%.16f, z1=%.16f, z2=%.16f, frac=%.16f, result=%.16f", angle, a1, a2, zm1, zm2, frac, result);

	return result;
}

/*******************************************************************************
 * Begin curve segmentize functions
 ******************************************************************************/

POINTARRAY *
lwcircle_segmentize(POINT4D *p1, POINT4D *p2, POINT4D *p3, uint32 perQuad)
{
	POINTARRAY *result;
	POINT4D pbuf;
	size_t ptsize = sizeof(POINT4D);
	uint32 ptcount;
	uchar *pt;

	POINT4D *center;
	double radius = 0.0,
	       sweep = 0.0,
	       angle = 0.0,
	       increment = 0.0;
	double a1, a2, a3, i;

	LWDEBUG(2, "lwcircle_segmentize called. ");

	radius = lwcircle_center(p1, p2, p3, &center);
	if (radius < 0)
	{
		/* No center because points are colinear */
		LWDEBUGF(3, "lwcircle_segmentize, (NULL) radius=%.16f", radius);

		return NULL;
	}

	LWDEBUGF(3, "lwcircle_segmentize, (%.16f, %.16f) radius=%.16f", center->x, center->y, radius);

	a1 = atan2(p1->y - center->y, p1->x - center->x);
	a2 = atan2(p2->y - center->y, p2->x - center->x);
	a3 = atan2(p3->y - center->y, p3->x - center->x);

	LWDEBUGF(3, "a1 = %.16f, a2 = %.16f, a3 = %.16f", a1, a2, a3);

	if (fabs(p1->x - p3->x) < EPSILON_SQLMM
	        && fabs(p1->y - p3->y) < EPSILON_SQLMM)
	{
		sweep = 2*M_PI;
	}
	/* Clockwise */
	else if (a1 > a2 && a2 > a3)
	{
		sweep = a3 - a1;
	}
	/* Counter-clockwise */
	else if (a1 < a2 && a2 < a3)
	{
		sweep = a3 - a1;
	}
	/* Clockwise, wrap */
	else if ((a1 < a2 && a1 > a3) || (a2 < a3 && a1 > a3))
	{
		sweep = a3 - a1 + 2*M_PI;
	}
	/* Counter-clockwise, wrap */
	else if ((a1 > a2 && a1 < a3) || (a2 > a3 && a1 < a3))
	{
		sweep = a3 - a1 - 2*M_PI;
	}
	else
	{
		sweep = 0.0;
	}

	ptcount = ceil(fabs(perQuad * sweep / M_PI_2));

	result = ptarray_construct(1, 1, ptcount);

	increment = M_PI_2 / perQuad;
	if (sweep < 0) increment *= -1.0;
	angle = a1;

	LWDEBUGF(3, "ptcount: %d, perQuad: %d, sweep: %.16f, increment: %.16f", ptcount, perQuad, sweep, increment);

	for (i = 0; i < ptcount - 1; i++)
	{
		pt = getPoint_internal(result, i);
		angle += increment;
		if (increment > 0.0 && angle > M_PI) angle -= 2*M_PI;
		if (increment < 0.0 && angle < -1*M_PI) angle -= 2*M_PI;
		pbuf.x = center->x + radius*cos(angle);
		pbuf.y = center->y + radius*sin(angle);
		if ((sweep > 0 && angle < a2) || (sweep < 0 && angle > a2))
		{
			if ((sweep > 0 && a1 < a2) || (sweep < 0 && a1 > a2))
			{
				pbuf.z = interpolate_arc(angle, p1->z, a1, p2->z, a2);
				pbuf.m = interpolate_arc(angle, p1->m, a1, p2->m, a2);
			}
			else
			{
				if (sweep > 0)
				{
					pbuf.z = interpolate_arc(angle, p1->z, a1-(2*M_PI), p2->z, a2);
					pbuf.m = interpolate_arc(angle, p1->m, a1-(2*M_PI), p2->m, a2);
				}
				else
				{
					pbuf.z = interpolate_arc(angle, p1->z, a1+(2*M_PI), p2->z, a2);
					pbuf.m = interpolate_arc(angle, p1->m, a1+(2*M_PI), p2->m, a2);
				}
			}
		}
		else
		{
			if ((sweep > 0 && a2 < a3) || (sweep < 0 && a2 > a3))
			{
				pbuf.z = interpolate_arc(angle, p2->z, a2, p3->z, a3);
				pbuf.m = interpolate_arc(angle, p2->m, a2, p3->m, a3);
			}
			else
			{
				if (sweep > 0)
				{
					pbuf.z = interpolate_arc(angle, p2->z, a2-(2*M_PI), p3->z, a3);
					pbuf.m = interpolate_arc(angle, p2->m, a2-(2*M_PI), p3->m, a3);
				}
				else
				{
					pbuf.z = interpolate_arc(angle, p2->z, a2+(2*M_PI), p3->z, a3);
					pbuf.m = interpolate_arc(angle, p2->m, a2+(2*M_PI), p3->m, a3);
				}
			}
		}
		memcpy(pt, (uchar *)&pbuf, ptsize);
	}

	pt = getPoint_internal(result, ptcount - 1);
	memcpy(pt, (uchar *)p3, ptsize);

	lwfree(center);

	return result;
}

LWLINE *
lwcurve_segmentize(LWCIRCSTRING *icurve, uint32 perQuad)
{
	LWLINE *oline;
	DYNPTARRAY *ptarray;
	POINTARRAY *tmp;
	uint32 i, j;
	POINT4D *p1 = lwalloc(sizeof(POINT4D));
	POINT4D *p2 = lwalloc(sizeof(POINT4D));
	POINT4D *p3 = lwalloc(sizeof(POINT4D));
	POINT4D *p4 = lwalloc(sizeof(POINT4D));


	LWDEBUGF(2, "lwcurve_segmentize called., dim = %d", icurve->points->dims);

	ptarray = dynptarray_create(icurve->points->npoints, icurve->points->dims);
	if (!getPoint4d_p(icurve->points, 0, p4))
	{
		lwerror("lwcurve_segmentize: Cannot extract point.");
	}
	dynptarray_addPoint4d(ptarray, p4, 1);

	for (i = 2; i < icurve->points->npoints; i+=2)
	{
		LWDEBUGF(3, "lwcurve_segmentize: arc ending at point %d", i);

		getPoint4d_p(icurve->points, i - 2, p1);
		getPoint4d_p(icurve->points, i - 1, p2);
		getPoint4d_p(icurve->points, i, p3);
		tmp = lwcircle_segmentize(p1, p2, p3, perQuad);

		if (tmp)
		{
			LWDEBUGF(3, "lwcurve_segmentize: generated %d points", tmp->npoints);

			for (j = 0; j < tmp->npoints; j++)
			{
				getPoint4d_p(tmp, j, p4);
				dynptarray_addPoint4d(ptarray, p4, 1);
			}
			lwfree(tmp);
		}
		else
		{
			LWDEBUG(3, "lwcurve_segmentize: points are colinear, returning curve points as line");

			for (j = i - 1 ; j <= i ; j++)
			{
				getPoint4d_p(icurve->points, j, p4);
				dynptarray_addPoint4d(ptarray, p4, 1);
			}
		}

	}
	oline = lwline_construct(icurve->SRID, NULL, ptarray_clone(ptarray->pa));

	lwfree(p1);
	lwfree(p2);
	lwfree(p3);
	lwfree(p4);
	lwfree(ptarray);
	return oline;
}

LWLINE *
lwcompound_segmentize(LWCOMPOUND *icompound, uint32 perQuad)
{
	LWLINE *oline;
	LWGEOM *geom;
	DYNPTARRAY *ptarray = NULL;
	LWLINE *tmp = NULL;
	uint32 i, j;
	POINT4D *p = NULL;

	LWDEBUG(2, "lwcompound_segmentize called.");

	p = lwalloc(sizeof(POINT4D));

	ptarray = dynptarray_create(2, ((POINTARRAY *)icompound->geoms[0]->data)->dims);

	for (i = 0; i < icompound->ngeoms; i++)
	{
		geom = icompound->geoms[i];
		if (lwgeom_getType(geom->type) == CIRCSTRINGTYPE)
		{
			tmp = lwcurve_segmentize((LWCIRCSTRING *)geom, perQuad);
			for (j = 0; j < tmp->points->npoints; j++)
			{
				getPoint4d_p(tmp->points, j, p);
				dynptarray_addPoint4d(ptarray, p, 0);
			}
			lwfree(tmp);
		}
		else if (lwgeom_getType(geom->type) == LINETYPE)
		{
			tmp = (LWLINE *)geom;
			for (j = 0; j < tmp->points->npoints; j++)
			{
				getPoint4d_p(tmp->points, j, p);
				dynptarray_addPoint4d(ptarray, p, 0);
			}
		}
		else
		{
			lwerror("Unsupported geometry type %d found.",
				lwgeom_getType(geom->type), lwtype_name(lwgeom_getType(geom->type)));
			return NULL;
		}
	}
	oline = lwline_construct(icompound->SRID, NULL, ptarray_clone(ptarray->pa));
	lwfree(ptarray);
	lwfree(p);
	return oline;
}

LWPOLY *
lwcurvepoly_segmentize(LWCURVEPOLY *curvepoly, uint32 perQuad)
{
	LWPOLY *ogeom;
	LWGEOM *tmp;
	LWLINE *line;
	POINTARRAY **ptarray;
	int i;

	LWDEBUG(2, "lwcurvepoly_segmentize called.");

	ptarray = lwalloc(sizeof(POINTARRAY *)*curvepoly->nrings);

	for (i = 0; i < curvepoly->nrings; i++)
	{
		tmp = curvepoly->rings[i];
		if (lwgeom_getType(tmp->type) == CIRCSTRINGTYPE)
		{
			line = lwcurve_segmentize((LWCIRCSTRING *)tmp, perQuad);
			ptarray[i] = ptarray_clone(line->points);
			lwfree(line);
		}
		else if (lwgeom_getType(tmp->type) == LINETYPE)
		{
			line = (LWLINE *)tmp;
			ptarray[i] = ptarray_clone(line->points);
		}
		else if (lwgeom_getType(tmp->type) == COMPOUNDTYPE)
		{
			line = lwcompound_segmentize((LWCOMPOUND *)tmp, perQuad);
			ptarray[i] = ptarray_clone(line->points);
			lwfree(line);
		}
		else
		{
			lwerror("Invalid ring type found in CurvePoly.");
			return NULL;
		}
	}

	ogeom = lwpoly_construct(curvepoly->SRID, NULL, curvepoly->nrings, ptarray);
	return ogeom;
}

LWMLINE *
lwmcurve_segmentize(LWMCURVE *mcurve, uint32 perQuad)
{
	LWMLINE *ogeom;
	LWGEOM *tmp;
	LWGEOM **lines;
	int i;

	LWDEBUGF(2, "lwmcurve_segmentize called, geoms=%d, dim=%d.", mcurve->ngeoms, TYPE_NDIMS(mcurve->type));

	lines = lwalloc(sizeof(LWGEOM *)*mcurve->ngeoms);

	for (i = 0; i < mcurve->ngeoms; i++)
	{
		tmp = mcurve->geoms[i];
		if (lwgeom_getType(tmp->type) == CIRCSTRINGTYPE)
		{
			lines[i] = (LWGEOM *)lwcurve_segmentize((LWCIRCSTRING *)tmp, perQuad);
		}
		else if (lwgeom_getType(tmp->type) == LINETYPE)
		{
			lines[i] = (LWGEOM *)lwline_construct(mcurve->SRID, NULL, ptarray_clone(((LWLINE *)tmp)->points));
		}
		else
		{
			lwerror("Unsupported geometry found in MultiCurve.");
			return NULL;
		}
	}

	ogeom = (LWMLINE *)lwcollection_construct(MULTILINETYPE, mcurve->SRID, NULL, mcurve->ngeoms, lines);
	return ogeom;
}

LWMPOLY *
lwmsurface_segmentize(LWMSURFACE *msurface, uint32 perQuad)
{
	LWMPOLY *ogeom;
	LWGEOM *tmp;
	LWPOLY *poly;
	LWGEOM **polys;
	POINTARRAY **ptarray;
	int i, j;

	LWDEBUG(2, "lwmsurface_segmentize called.");

	polys = lwalloc(sizeof(LWGEOM *)*msurface->ngeoms);

	for (i = 0; i < msurface->ngeoms; i++)
	{
		tmp = msurface->geoms[i];
		if (lwgeom_getType(tmp->type) == CURVEPOLYTYPE)
		{
			polys[i] = (LWGEOM *)lwcurvepoly_segmentize((LWCURVEPOLY *)tmp, perQuad);
		}
		else if (lwgeom_getType(tmp->type) == POLYGONTYPE)
		{
			poly = (LWPOLY *)tmp;
			ptarray = lwalloc(sizeof(POINTARRAY *)*poly->nrings);
			for (j = 0; j < poly->nrings; j++)
			{
				ptarray[j] = ptarray_clone(poly->rings[j]);
			}
			polys[i] = (LWGEOM *)lwpoly_construct(msurface->SRID, NULL, poly->nrings, ptarray);
		}
	}
	ogeom = (LWMPOLY *)lwcollection_construct(MULTIPOLYGONTYPE, msurface->SRID, NULL, msurface->ngeoms, polys);
	return ogeom;
}

LWCOLLECTION *
lwcollection_segmentize(LWCOLLECTION *collection, uint32 perQuad)
{
	LWCOLLECTION *ocol;
	LWGEOM *tmp;
	LWGEOM **geoms;
	int i;

	LWDEBUG(2, "lwcollection_segmentize called.");

	geoms = lwalloc(sizeof(LWGEOM *)*collection->ngeoms);

	for (i=0; i<collection->ngeoms; i++)
	{
		tmp = collection->geoms[i];
		switch (lwgeom_getType(tmp->type))
		{
		case CIRCSTRINGTYPE:
			geoms[i] = (LWGEOM *)lwcurve_segmentize((LWCIRCSTRING *)tmp, perQuad);
			break;
		case COMPOUNDTYPE:
			geoms[i] = (LWGEOM *)lwcompound_segmentize((LWCOMPOUND *)tmp, perQuad);
			break;
		case CURVEPOLYTYPE:
			geoms[i] = (LWGEOM *)lwcurvepoly_segmentize((LWCURVEPOLY *)tmp, perQuad);
			break;
		case COLLECTIONTYPE:
			geoms[i] = (LWGEOM *)lwcollection_segmentize((LWCOLLECTION *)tmp, perQuad);
			break;
		default:
			geoms[i] = lwgeom_clone(tmp);
			break;
		}
	}
	ocol = lwcollection_construct(COLLECTIONTYPE, collection->SRID, NULL, collection->ngeoms, geoms);
	return ocol;
}

LWGEOM *
lwgeom_segmentize(LWGEOM *geom, uint32 perQuad)
{
	LWGEOM * ogeom = NULL;
	switch (lwgeom_getType(geom->type))
	{
	case CIRCSTRINGTYPE:
		ogeom = (LWGEOM *)lwcurve_segmentize((LWCIRCSTRING *)geom, perQuad);
		break;
	case COMPOUNDTYPE:
		ogeom = (LWGEOM *)lwcompound_segmentize((LWCOMPOUND *)geom, perQuad);
		break;
	case CURVEPOLYTYPE:
		ogeom = (LWGEOM *)lwcurvepoly_segmentize((LWCURVEPOLY *)geom, perQuad);
		break;
	case MULTICURVETYPE:
		ogeom = (LWGEOM *)lwmcurve_segmentize((LWMCURVE *)geom, perQuad);
		break;
	case MULTISURFACETYPE:
		ogeom = (LWGEOM *)lwmsurface_segmentize((LWMSURFACE *)geom, perQuad);
		break;
	case COLLECTIONTYPE:
		ogeom = (LWGEOM *)lwcollection_segmentize((LWCOLLECTION *)geom, perQuad);
		break;
	default:
		ogeom = lwgeom_clone(geom);
	}
	return ogeom;
}

/*******************************************************************************
 * End curve segmentize functions
 ******************************************************************************/
LWGEOM *
append_segment(LWGEOM *geom, POINTARRAY *pts, int type, int SRID)
{
	LWGEOM *result;
	int currentType, i;

	LWDEBUGF(2, "append_segment called %p, %p, %d, %d", geom, pts, type, SRID);

	if (geom == NULL)
	{
		if (type == LINETYPE)
		{
			LWDEBUG(3, "append_segment: line to NULL");

			return (LWGEOM *)lwline_construct(SRID, NULL, pts);
		}
		else if (type == CIRCSTRINGTYPE)
		{
#if POSTGIS_DEBUG_LEVEL >= 4
			POINT4D tmp;

			LWDEBUGF(4, "append_segment: curve to NULL %d", pts->npoints);

			for (i=0; i<pts->npoints; i++)
			{
				getPoint4d_p(pts, i, &tmp);
				LWDEBUGF(4, "new point: (%.16f,%.16f)",tmp.x,tmp.y);
			}
#endif
			return (LWGEOM *)lwcircstring_construct(SRID, NULL, pts);
		}
		else
		{
			lwerror("Invalid segment type %d - %s.", type, lwtype_name(type));
		}
	}

	currentType = lwgeom_getType(geom->type);
	if (currentType == LINETYPE && type == LINETYPE)
	{
		POINTARRAY *newPoints;
		POINT4D pt;
		LWLINE *line = (LWLINE *)geom;

		LWDEBUG(3, "append_segment: line to line");

		newPoints = ptarray_construct(TYPE_HASZ(pts->dims), TYPE_HASM(pts->dims), pts->npoints + line->points->npoints - 1);
		for (i=0; i<line->points->npoints; i++)
		{
			getPoint4d_p(line->points, i, &pt);
			LWDEBUGF(5, "copying to %p [%d]", newPoints, i);
			setPoint4d(newPoints, i, &pt);
		}
		for (i=1; i<pts->npoints; i++)
		{
			getPoint4d_p(pts, i, &pt);
			setPoint4d(newPoints, i + line->points->npoints - 1, &pt);
		}
		result = (LWGEOM *)lwline_construct(SRID, NULL, newPoints);
		lwgeom_release(geom);
		return result;
	}
	else if (currentType == CIRCSTRINGTYPE && type == CIRCSTRINGTYPE)
	{
		POINTARRAY *newPoints;
		POINT4D pt;
		LWCIRCSTRING *curve = (LWCIRCSTRING *)geom;

		LWDEBUG(3, "append_segment: circularstring to circularstring");

		newPoints = ptarray_construct(TYPE_HASZ(pts->dims), TYPE_HASM(pts->dims), pts->npoints + curve->points->npoints - 1);

		LWDEBUGF(3, "New array length: %d", pts->npoints + curve->points->npoints - 1);

		for (i=0; i<curve->points->npoints; i++)
		{
			getPoint4d_p(curve->points, i, &pt);

			LWDEBUGF(3, "orig point %d: (%.16f,%.16f)", i, pt.x, pt.y);

			setPoint4d(newPoints, i, &pt);
		}
		for (i=1; i<pts->npoints; i++)
		{
			getPoint4d_p(pts, i, &pt);

			LWDEBUGF(3, "new point %d: (%.16f,%.16f)", i + curve->points->npoints - 1, pt.x, pt.y);

			setPoint4d(newPoints, i + curve->points->npoints - 1, &pt);
		}
		result = (LWGEOM *)lwcircstring_construct(SRID, NULL, newPoints);
		lwgeom_release(geom);
		return result;
	}
	else if (currentType == CIRCSTRINGTYPE && type == LINETYPE)
	{
		LWLINE *line;
		LWGEOM **geomArray;

		LWDEBUG(3, "append_segment: line to curve");

		geomArray = lwalloc(sizeof(LWGEOM *)*2);
		geomArray[0] = lwgeom_clone(geom);

		line = lwline_construct(SRID, NULL, pts);
		geomArray[1] = lwgeom_clone((LWGEOM *)line);

		result = (LWGEOM *)lwcollection_construct(COMPOUNDTYPE, SRID, NULL, 2, geomArray);
		lwfree((LWGEOM *)line);
		lwgeom_release(geom);
		return result;
	}
	else if (currentType == LINETYPE && type == CIRCSTRINGTYPE)
	{
		LWCIRCSTRING *curve;
		LWGEOM **geomArray;

		LWDEBUG(3, "append_segment: circularstring to line");

		geomArray = lwalloc(sizeof(LWGEOM *)*2);
		geomArray[0] = lwgeom_clone(geom);

		curve = lwcircstring_construct(SRID, NULL, pts);
		geomArray[1] = lwgeom_clone((LWGEOM *)curve);

		result = (LWGEOM *)lwcollection_construct(COMPOUNDTYPE, SRID, NULL, 2, geomArray);
		lwfree((LWGEOM *)curve);
		lwgeom_release(geom);
		return result;
	}
	else if (currentType == COMPOUNDTYPE)
	{
		LWGEOM *newGeom;
		LWCOMPOUND *compound;
		int count;
		LWGEOM **geomArray;

		compound = (LWCOMPOUND *)geom;
		count = compound->ngeoms + 1;
		geomArray = lwalloc(sizeof(LWGEOM *)*count);
		for (i=0; i<compound->ngeoms; i++)
		{
			geomArray[i] = lwgeom_clone(compound->geoms[i]);
		}
		if (type == LINETYPE)
		{
			LWDEBUG(3, "append_segment: line to compound");

			newGeom = (LWGEOM *)lwline_construct(SRID, NULL, pts);
		}
		else if (type == CIRCSTRINGTYPE)
		{
			LWDEBUG(3, "append_segment: circularstring to compound");

			newGeom = (LWGEOM *)lwcircstring_construct(SRID, NULL, pts);
		}
		else
		{
			lwerror("Invalid segment type %d - %s.", type, lwtype_name(type));
			return NULL;
		}
		geomArray[compound->ngeoms] = lwgeom_clone(newGeom);

		result = (LWGEOM *)lwcollection_construct(COMPOUNDTYPE, SRID, NULL, count, geomArray);
		lwfree(newGeom);
		lwgeom_release(geom);
		return result;
	}
	lwerror("Invalid state [%d] %s - [%d] %s",
		currentType, lwtype_name(currentType), type, lwtype_name(type));
	return NULL;
}

LWGEOM *
pta_desegmentize(POINTARRAY *points, int type, int SRID)
{
	int i, j, commit, isline, count;
	double last_angle, last_length;
	double dxab, dyab, dxbc, dybc, theta, length;
	POINT4D a, b, c, tmp;
	POINTARRAY *pts;
	LWGEOM *geom = NULL;

	LWDEBUG(2, "pta_desegmentize called.");

	getPoint4d_p(points, 0, &a);
	getPoint4d_p(points, 1, &b);
	getPoint4d_p(points, 2, &c);

	dxab = b.x - a.x;
	dyab = b.y - a.y;
	dxbc = c.x - b.x;
	dybc = c.y - b.y;

	theta = atan2(dyab, dxab);
	last_angle = theta - atan2(dybc, dxbc);
	last_length = sqrt(dxbc*dxbc+dybc*dybc);
	length = sqrt(dxab*dxab+dyab*dyab);
	if ((last_length - length) < EPSILON_SQLMM)
	{
		isline = -1;
		LWDEBUG(3, "Starting as unknown.");
	}
	else
	{
		isline = 1;
		LWDEBUG(3, "Starting as line.");
	}

	commit = 0;
	for (i=3; i<points->npoints; i++)
	{
		getPoint4d_p(points, i-2, &a);
		getPoint4d_p(points, i-1, &b);
		getPoint4d_p(points, i, &c);

		dxab = b.x - a.x;
		dyab = b.y - a.y;
		dxbc = c.x - b.x;
		dybc = c.y - b.y;

		LWDEBUGF(3, "(dxab, dyab, dxbc, dybc) (%.16f, %.16f, %.16f, %.16f)", dxab, dyab, dxbc, dybc);

		theta = atan2(dyab, dxab);
		theta = theta - atan2(dybc, dxbc);
		length = sqrt(dxbc*dxbc+dybc*dybc);

		LWDEBUGF(3, "Last/current length and angle %.16f/%.16f, %.16f/%.16f", last_angle, theta, last_length, length);

		/* Found a line segment */
		if (fabs(length - last_length) > EPSILON_SQLMM ||
		        fabs(theta - last_angle) > EPSILON_SQLMM)
		{
			last_length = length;
			last_angle = theta;
			/* We are tracking a line, keep going */
			if (isline > 0)
				{}
			/* We were tracking a circularstring, commit it and start line*/
			else if (isline == 0)
			{
				LWDEBUGF(3, "Building circularstring, %d - %d", commit, i);

				count = i - commit;
				pts = ptarray_construct(
				          TYPE_HASZ(type),
				          TYPE_HASM(type),
				          3);
				getPoint4d_p(points, commit, &tmp);
				setPoint4d(pts, 0, &tmp);
				getPoint4d_p(points,
				             commit + count/2, &tmp);
				setPoint4d(pts, 1, &tmp);
				getPoint4d_p(points, i - 1, &tmp);
				setPoint4d(pts, 2, &tmp);

				commit = i-1;
				geom = append_segment(geom, pts, CIRCSTRINGTYPE, SRID);
				isline = -1;

				/*
				 * We now need to move ahead one point to
				 * determine if it's a potential new curve,
				 * since the last_angle value is corrupt.
				 *
				 * Note we can only look ahead one point if
				 * we are not already at the end of our
				 * set of points.
				 */
				if (i < points->npoints - 1)
				{
					i++;

					getPoint4d_p(points, i-2, &a);
					getPoint4d_p(points, i-1, &b);
					getPoint4d_p(points, i, &c);

					dxab = b.x - a.x;
					dyab = b.y - a.y;
					dxbc = c.x - b.x;
					dybc = c.y - b.y;

					theta = atan2(dyab, dxab);
					last_angle = theta - atan2(dybc, dxbc);
					last_length = sqrt(dxbc*dxbc+dybc*dybc);
					length = sqrt(dxab*dxab+dyab*dyab);
					if ((last_length - length) < EPSILON_SQLMM)
					{
						isline = -1;
						LWDEBUG(3, "Restarting as unknown.");
					}
					else
					{
						isline = 1;
						LWDEBUG(3, "Restarting as line.");
					}
				}
				else
				{
					/* Indicate that we have tracked a CIRCSTRING */
					isline = 0;
				}
			}
			/* We didn't know what we were tracking, now we do. */
			else
			{
				LWDEBUG(3, "It's a line");
				isline = 1;
			}
		}
		/* Found a circularstring segment */
		else
		{
			/* We were tracking a circularstring, commit it and start line */
			if (isline > 0)
			{
				LWDEBUGF(3, "Building line, %d - %d", commit, i-2);

				count = i - commit - 2;

				pts = ptarray_construct(
				          TYPE_HASZ(type),
				          TYPE_HASM(type),
				          count);
				for (j=commit; j<i-2; j++)
				{
					getPoint4d_p(points, j, &tmp);
					setPoint4d(pts, j-commit, &tmp);
				}

				commit = i-3;
				geom = append_segment(geom, pts, LINETYPE, SRID);
				isline = -1;
			}
			/* We are tracking a circularstring, keep going */
			else if (isline == 0)
			{
				;
			}
			/* We didn't know what we were tracking, now we do */
			else
			{
				LWDEBUG(3, "It's a circularstring");
				isline = 0;
			}
		}
	}
	count = i - commit;
	if (isline == 0 && count > 2)
	{
		LWDEBUGF(3, "Finishing circularstring %d,%d.", commit, i);

		pts = ptarray_construct(
		          TYPE_HASZ(type),
		          TYPE_HASM(type),
		          3);
		getPoint4d_p(points, commit, &tmp);
		setPoint4d(pts, 0, &tmp);
		getPoint4d_p(points, commit + count/2, &tmp);
		setPoint4d(pts, 1, &tmp);
		getPoint4d_p(points, i - 1, &tmp);
		setPoint4d(pts, 2, &tmp);

		geom = append_segment(geom, pts, CIRCSTRINGTYPE, SRID);
	}
	else
	{
		LWDEBUGF(3, "Finishing line %d,%d.", commit, i);

		pts = ptarray_construct(
		          TYPE_HASZ(type),
		          TYPE_HASM(type),
		          count);
		for (j=commit; j<i; j++)
		{
			getPoint4d_p(points, j, &tmp);
			setPoint4d(pts, j-commit, &tmp);
		}
		geom = append_segment(geom, pts, LINETYPE, SRID);
	}
	return geom;
}

LWGEOM *
lwline_desegmentize(LWLINE *line)
{
	LWDEBUG(2, "lwline_desegmentize called.");

	return pta_desegmentize(line->points, line->type, line->SRID);
}

LWGEOM *
lwpolygon_desegmentize(LWPOLY *poly)
{
	LWGEOM **geoms;
	int i, hascurve = 0;

	LWDEBUG(2, "lwpolygon_desegmentize called.");

	geoms = lwalloc(sizeof(LWGEOM *)*poly->nrings);
	for (i=0; i<poly->nrings; i++)
	{
		geoms[i] = pta_desegmentize(poly->rings[i], poly->type, poly->SRID);
		if (lwgeom_getType(geoms[i]->type) == CIRCSTRINGTYPE ||
		        lwgeom_getType(geoms[i]->type) == COMPOUNDTYPE)
		{
			hascurve = 1;
		}
	}
	if (hascurve == 0)
	{
		for (i=0; i<poly->nrings; i++)
		{
			lwfree(geoms[i]);
		}
		return lwgeom_clone((LWGEOM *)poly);
	}

	return (LWGEOM *)lwcollection_construct(CURVEPOLYTYPE, poly->SRID, NULL, poly->nrings, geoms);
}

LWGEOM *
lwmline_desegmentize(LWMLINE *mline)
{
	LWGEOM **geoms;
	int i, hascurve = 0;

	LWDEBUG(2, "lwmline_desegmentize called.");

	geoms = lwalloc(sizeof(LWGEOM *)*mline->ngeoms);
	for (i=0; i<mline->ngeoms; i++)
	{
		geoms[i] = lwline_desegmentize((LWLINE *)mline->geoms[i]);
		if (lwgeom_getType(geoms[i]->type) == CIRCSTRINGTYPE ||
		        lwgeom_getType(geoms[i]->type) == COMPOUNDTYPE)
		{
			hascurve = 1;
		}
	}
	if (hascurve == 0)
	{
		for (i=0; i<mline->ngeoms; i++)
		{
			lwfree(geoms[i]);
		}
		return lwgeom_clone((LWGEOM *)mline);
	}
	return (LWGEOM *)lwcollection_construct(MULTICURVETYPE, mline->SRID, NULL, mline->ngeoms, geoms);
}

LWGEOM *
lwmpolygon_desegmentize(LWMPOLY *mpoly)
{
	LWGEOM **geoms;
	int i, hascurve = 0;

	LWDEBUG(2, "lwmpoly_desegmentize called.");

	geoms = lwalloc(sizeof(LWGEOM *)*mpoly->ngeoms);
	for (i=0; i<mpoly->ngeoms; i++)
	{
		geoms[i] = lwpolygon_desegmentize((LWPOLY *)mpoly->geoms[i]);
		if (lwgeom_getType(geoms[i]->type) == CURVEPOLYTYPE)
		{
			hascurve = 1;
		}
	}
	if (hascurve == 0)
	{
		for (i=0; i<mpoly->ngeoms; i++)
		{
			lwfree(geoms[i]);
		}
		return lwgeom_clone((LWGEOM *)mpoly);
	}
	return (LWGEOM *)lwcollection_construct(MULTISURFACETYPE, mpoly->SRID, NULL, mpoly->ngeoms, geoms);
}

LWGEOM *
lwgeom_desegmentize(LWGEOM *geom)
{
	int type = lwgeom_getType(geom->type);

	LWDEBUG(2, "lwgeom_desegmentize called.");

	switch (type)
	{
	case LINETYPE:
		return lwline_desegmentize((LWLINE *)geom);
	case POLYGONTYPE:
		return lwpolygon_desegmentize((LWPOLY *)geom);
	case MULTILINETYPE:
		return lwmline_desegmentize((LWMLINE *)geom);
	case MULTIPOLYGONTYPE:
		return lwmpolygon_desegmentize((LWMPOLY *)geom);
	default:
		return lwgeom_clone(geom);
	}
}