Name
ST_MakePolygon — Creates a Polygon from a shell and optional list of holes.
Synopsis
geometry ST_MakePolygon(geometry linestring);
geometry ST_MakePolygon(geometry outerlinestring, geometry[] interiorlinestrings);
Descripción
Crea un polígono formado por el contorno dado. Las geometrías de entrada deben ser LINESTRINGS cerradas.
Variant 1: Accepts one shell LineString.
Variant 2: Accepts a shell LineString and an array of inner (hole) LineStrings. A geometry array can be constructed using the PostgreSQL array_agg(), ARRAY[] or ARRAY() constructs.
![[Note]](../images/note.png)
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Esta función no acepta una MULTILINESTRING. Utiliza ST_LineMerge o ST_Dump para generar una linestring. |
This function supports 3d and will not drop the z-index.
Ejemplos: Utilizando la versión Array
Crea un LineString desde una cadena de polilínea codificada.
SELECT ST_MakePolygon( ST_GeomFromText('LINESTRING(75 29,77 29,77 29, 75 29)'));
Create a Polygon from an open LineString, using ST_StartPoint and ST_AddPoint to close it.
SELECT ST_MakePolygon( ST_AddPoint(foo.open_line, ST_StartPoint(foo.open_line)) )
FROM (
SELECT ST_GeomFromText('LINESTRING(75 29,77 29,77 29, 75 29)') As open_line) As foo;
Crea un LineString desde una cadena de polilínea codificada.
SELECT ST_AsEWKT( ST_MakePolygon( 'LINESTRING(75.15 29.53 1,77 29 1,77.6 29.5 1, 75.15 29.53 1)')); st_asewkt ----------- POLYGON((75.15 29.53 1,77 29 1,77.6 29.5 1,75.15 29.53 1))
Create a Polygon from a LineString with measures
SELECT ST_AsEWKT( ST_MakePolygon( 'LINESTRINGM(75.15 29.53 1,77 29 1,77.6 29.5 2, 75.15 29.53 2)' )); st_asewkt ---------- POLYGONM((75.15 29.53 1,77 29 1,77.6 29.5 2,75.15 29.53 2))
Ejemplos: carcasa exterior con carcasas interiores
Contruye un donut con un agujero de hormiga
SELECT ST_MakePolygon( ST_ExteriorRing( ST_Buffer(ring.line,10)),
ARRAY[ ST_Translate(ring.line, 1, 1),
ST_ExteriorRing(ST_Buffer(ST_Point(20,20),1)) ]
)
FROM (SELECT ST_ExteriorRing(
ST_Buffer(ST_Point(10,10),10,10)) AS line ) AS ring;
Create a set of province boundaries with holes representing lakes. The input is a table of province Polygons/MultiPolygons and a table of water linestrings. Lines forming lakes are determined by using ST_IsClosed. The province linework is extracted by using ST_Boundary. As required by ST_MakePolygon, the boundary is forced to be a single LineString by using ST_LineMerge. (However, note that if a province has more than one region or has islands this will produce an invalid polygon.) Using a LEFT JOIN ensures all provinces are included even if they have no lakes.
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El constructor CASE se utiliza porque la alimentación de una matriz nula en ST_MakePolygon resulta en NULL. |
SELECT p.gid, p.province_name,
CASE WHEN array_agg(w.geom) IS NULL
THEN p.geom
ELSE ST_MakePolygon( ST_LineMerge(ST_Boundary(p.geom)),
array_agg(w.geom)) END
FROM
provinces p LEFT JOIN waterlines w
ON (ST_Within(w.geom, p.geom) AND ST_IsClosed(w.geom))
GROUP BY p.gid, p.province_name, p.geom;
Another technique is to utilize a correlated subquery and the ARRAY() constructor that converts a row set to an array.
SELECT p.gid, p.province_name,
CASE WHEN EXISTS( SELECT w.geom
FROM waterlines w
WHERE ST_Within(w.geom, p.geom)
AND ST_IsClosed(w.geom))
THEN ST_MakePolygon(
ST_LineMerge(ST_Boundary(p.geom)),
ARRAY( SELECT w.geom
FROM waterlines w
WHERE ST_Within(w.geom, p.geom)
AND ST_IsClosed(w.geom)))
ELSE p.geom
END AS geom
FROM provinces p;