From: Olivier Courtin Date: Sun, 15 Nov 2009 20:39:17 +0000 (+0000) Subject: Split reference.xml on several sub files (upon sect1). Use entity to avoid redundant... X-Git-Tag: 1.5.0b1~243 X-Git-Url: https://granicus.if.org/sourcecode?a=commitdiff_plain;h=fa1b7f8382af3f17f0fd59cc03ffb7ac07d40a4b;p=postgis Split reference.xml on several sub files (upon sect1). Use entity to avoid redundant compliant/support text (SFS, SQL/MM, Z/M dimensions, Curve support) git-svn-id: http://svn.osgeo.org/postgis/trunk@4817 b70326c6-7e19-0410-871a-916f4a2858ee --- diff --git a/doc/postgis.xml b/doc/postgis.xml index 23762c8bd..a2d5309a7 100644 --- a/doc/postgis.xml +++ b/doc/postgis.xml @@ -9,13 +9,62 @@ + + + + This method implements the OpenGIS Simple Features + Implementation Specification for SQL 1.1."> + + + + + + This method implements the SQL/MM specification."> + + + + + This method supports Circular Strings and Curves"> + + + + + + + This function supports 3d and will not drop the z-index."> + + + + + + + This function supports M coordinates."> + + - + + + + + + + + + + + + @@ -55,9 +104,39 @@ &using_postgis_dataman; &using_postgis_app; &performance_tips; - &reference; + + + + PostGIS Reference + The functions given below are the ones which a user of PostGIS is + likely to need. There are other functions which are required support + functions to the PostGIS objects which are not of use to a general + user. + + + PostGIS has begun a transition from the existing naming convention + to an SQL-MM-centric convention. As a result, most of the functions that + you know and love have been renamed using the standard spatial type (ST) + prefix. Previous functions are still available, though are not listed in + this document where updated functions are equivalent. These will be + deprecated in a future release. + + + &reference_management; + &reference_constructor; + &reference_accessor; + &reference_editor; + &reference_output; + &reference_operator; + &reference_measure; + &reference_processing; + &reference_lrs; + &reference_transaction; + &reference_misc; + &reference_exception; + + &postgis_aggs_mm; &reporting; &release_notes; - diff --git a/doc/reference.xml b/doc/reference.xml deleted file mode 100644 index b6d95b53d..000000000 --- a/doc/reference.xml +++ /dev/null @@ -1,16254 +0,0 @@ - - - PostGIS Reference - - The functions given below are the ones which a user of PostGIS is - likely to need. There are other functions which are required support - functions to the PostGIS objects which are not of use to a general - user. - - - PostGIS has begun a transition from the existing naming convention - to an SQL-MM-centric convention. As a result, most of the functions that - you know and love have been renamed using the standard spatial type (ST) - prefix. Previous functions are still available, though are not listed in - this document where updated functions are equivalent. These will be - deprecated in a future release. - - - - Management Functions - - - - AddGeometryColumn - - Adds a geometry column to an existing table of - attributes. - - - - - - text AddGeometryColumn - - varchar - table_name - - varchar - column_name - - integer - srid - - varchar - type - - integer - dimension - - - - text AddGeometryColumn - - varchar - schema_name - - varchar - table_name - - varchar - column_name - - integer - srid - - varchar - type - - integer - dimension - - - - text AddGeometryColumn - - varchar - catalog_name - - varchar - schema_name - - varchar - table_name - - varchar - column_name - - integer - srid - - varchar - type - - integer - dimension - - - - - - Description - - Adds a geometry column to an existing table of attributes. The - schema_name is the name of the table schema (unused - for pre-schema PostgreSQL installations). The srid - must be an integer value reference to an entry in the SPATIAL_REF_SYS - table. The type must be an uppercase string - corresponding to the geometry type, eg, 'POLYGON' or - 'MULTILINESTRING'. An error is thrown if the schemaname doesn't exist - (or not visible in the current search_path) or the specified SRID, - geometry type, or dimension is invalid. - - - Views and derivatively created spatial tables will need to be registered in geometry_columns manually, - since AddGeometryColumn also adds a spatial column which is not needed when you already have a spatial column. Refer to . - - - - - - This method implements the - OpenGIS Simple - Features Implementation Specification for SQL. - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - Examples - - --- Create a new simple PostgreSQL table -postgis=# CREATE TABLE my_schema.my_spatial_table (id serial); - --- Describing the table shows a simple table with a single "id" column. -postgis=# \d my_schema.my_spatial_table - Table "my_schema.my_spatial_table" - Column | Type | Modifiers ---------+---------+------------------------------------------------------------------------- - id | integer | not null default nextval('my_schema.my_spatial_table_id_seq'::regclass) - --- Add a spatial column to the table -postgis=# SELECT AddGeometryColumn ('my_schema','my_spatial_table','the_geom',4326,'POINT',2); - ---Add a curvepolygon -SELECT AddGeometryColumn ('my_schema','my_spatial_table','the_geomcp',4326,'CURVEPOLYGON',2); - --- Describe the table again reveals the addition of a new "the_geom" column. -postgis=# \d my_schema.my_spatial_table - Column | Type | Modifiers - -------------+----------+------------------------------------------------------------------------- - id | integer | not null default nextval('my_schema.my_spatial_table_id_seq'::regclass) - the_geom | geometry | - the_geomcp | geometry | -Check constraints: - "enforce_dims_the_geom" CHECK (ndims(the_geom) = 2) - "enforce_dims_the_geomcp" CHECK (ndims(the_geomcp) = 2) - "enforce_geotype_the_geom" CHECK (geometrytype(the_geom) = 'POINT'::text OR -the_geom IS NULL) - "enforce_geotype_the_geomcp" CHECK (geometrytype(the_geomcp) = 'CURVEPOLYGON -'::text OR the_geomcp IS NULL) - "enforce_srid_the_geom" CHECK (srid(the_geom) = 4326) - "enforce_srid_the_geomcp" CHECK (srid(the_geomcp) = 4326) - - - - See Also - - , , - - - - - - DropGeometryColumn - - Removes a geometry column from a spatial - table. - - - - - - text DropGeometryColumn - - varchar - table_name - - varchar - column_name - - - - text DropGeometryColumn - - varchar - schema_name - - varchar - table_name - - varchar - column_name - - - - text DropGeometryColumn - - varchar - catalog_name - - varchar - schema_name - - varchar - table_name - - varchar - column_name - - - - - - Description - - Removes a geometry column from a spatial table. Note that - schema_name will need to match the f_table_schema field of the table's - row in the geometry_columns table. - - - - This method implements the - OpenGIS Simple - Features Implementation Specification for SQL. - - - - - - - This function supports 3d geometry fields. - - - - - - This method supports Circular Strings and Curves - - - Examples - - - SELECT DropGeometryColumn ('my_schema','my_spatial_table','the_geomcp'); - ----RESULT output --- - my_schema.my_spatial_table.the_geomcp effectively removed. - - - - See Also - - , - - - - - - DropGeometryTable - - Drops a table and all its references in - geometry_columns. - - - - - - boolean DropGeometryTable - - varchar - table_name - - - - boolean DropGeometryTable - - varchar - schema_name - - varchar - table_name - - - - boolean DropGeometryTable - varchar - catalog_name - varchar - schema_name - varchar - table_name - - - - - - Description - - Drops a table and all its references in geometry_columns. Note: - uses current_schema() on schema-aware pgsql installations if schema is - not provided. - - - - Examples - - - SELECT DropGeometryTable ('my_schema','my_spatial_table'); - ----RESULT output --- - my_schema.my_spatial_table dropped. - - - - See Also - - , - - - - - - - PostGIS_Full_Version - - Reports full postgis version and build configuration - infos. - - - - - - text PostGIS_Full_Version - - - - - - - - Description - - Reports full postgis version and build configuration - infos. - - - - Examples - - SELECT PostGIS_Full_Version(); - postgis_full_version ----------------------------------------------------------------------------------- - POSTGIS="1.3.3" GEOS="3.1.0-CAPI-1.5.0" PROJ="Rel. 4.4.9, 29 Oct 2004" USE_STATS -(1 row) - - - - See Also - - , , , - - - - - - PostGIS_GEOS_Version - - Returns the version number of the GEOS - library. - - - - - - text PostGIS_GEOS_Version - - - - - - - - Description - - Returns the version number of the GEOS library, or - NULL if GEOS support is not enabled. - - - - Examples - - SELECT PostGIS_GEOS_Version(); - postgis_geos_version ----------------------- - 3.1.0-CAPI-1.5.0 -(1 row) - - - - See Also - - , , , - - - - - - PostGIS_Lib_Build_Date - - Returns build date of the PostGIS library. - - - - - - text PostGIS_Lib_Build_Date - - - - - - - - Description - - Returns build date of the PostGIS library. - - - - Examples - - SELECT PostGIS_Lib_Build_Date(); - postgis_lib_build_date ------------------------- - 2008-06-21 17:53:21 -(1 row) - - - - - - PostGIS_Lib_Version - - Returns the version number of the PostGIS - library. - - - - - - text PostGIS_Lib_Version - - - - - - - - Description - - Returns the version number of the PostGIS library. - - - - Examples - - SELECT PostGIS_Lib_Version(); - postgis_lib_version ---------------------- - 1.3.3 -(1 row) - - - - See Also - - , , , - - - - - - PostGIS_PROJ_Version - - Returns the version number of the PROJ4 - library. - - - - - - text PostGIS_PROJ_Version - - - - - - - - Description - - Returns the version number of the PROJ4 library, or - NULL if PROJ4 support is not enabled. - - - - Examples - - SELECT PostGIS_PROJ_Version(); - postgis_proj_version -------------------------- - Rel. 4.4.9, 29 Oct 2004 -(1 row) - - - - See Also - - , , , - - - - - - PostGIS_Scripts_Build_Date - - Returns build date of the PostGIS scripts. - - - - - - text PostGIS_Scripts_Build_Date - - - - - - - - Description - - Returns build date of the PostGIS scripts. - - Availability: 1.0.0RC1 - - - - Examples - - SELECT PostGIS_Scripts_Build_Date(); - postgis_scripts_build_date -------------------------- - 2007-08-18 09:09:26 -(1 row) - - - - See Also - - , , , - - - - - - PostGIS_Scripts_Installed - - Returns version of the postgis scripts installed in this - database. - - - - - - text PostGIS_Scripts_Installed - - - - - - - - Description - - Returns version of the postgis scripts installed in this - database. - - - If the output of this function doesn't match the output of - - you probably missed to properly upgrade an existing database. - See the Upgrading section for - more info. - - - Availability: 0.9.0 - - - - Examples - - SELECT PostGIS_Scripts_Installed(); - postgis_scripts_installed -------------------------- - 1.5.0SVN -(1 row) - - - - See Also - - , , - - - - - - PostGIS_Scripts_Released - - Returns the version number of the postgis.sql script - released with the installed postgis lib. - - - - - - text PostGIS_Scripts_Released - - - - - - - - Description - - Returns the version number of the postgis.sql script - released with the installed postgis lib. - - - Starting with version 1.1.0 this function returns the same - value of . Kept - for backward compatibility. - - - Availability: 0.9.0 - - - - Examples - - SELECT PostGIS_Scripts_Released(); - postgis_scripts_released -------------------------- - 1.3.4SVN -(1 row) - - - - See Also - - , , - - - - - - PostGIS_Uses_Stats - - Returns TRUE if STATS usage has been - enabled. - - - - - - text PostGIS_Uses_Stats - - - - - - - - Description - - Returns TRUE if STATS usage has been enabled, - FALSE otherwise. - - - - Examples - - SELECT PostGIS_Uses_Stats(); - postgis_uses_stats --------------------- - t -(1 row) - - - - See Also - - - - - - - - PostGIS_Version - - Returns PostGIS version number and compile-time - options. - - - - - - text PostGIS_Version - - - - - - - - Description - - Returns PostGIS version number and compile-time options. - - - - Examples - - SELECT PostGIS_Version(); - postgis_version ---------------------------------------- - 1.3 USE_GEOS=1 USE_PROJ=1 USE_STATS=1 -(1 row) - - - - See Also - - , ,, - - - - - - Populate_Geometry_Columns - - Ensures geometry columns have appropriate spatial constraints - and exist in the geometry_columns table. - - - - - - text Populate_Geometry_Columns - - - - - - int Populate_Geometry_Columns - - oid relation_oid - - - - - - Description - - Ensures geometry columns have appropriate spatial constraints and - exist in the geometry_columns table. In particular, - this means that every geometry column belonging to a table has at least - three constraints: - - - - enforce_dims_the_geom - ensures every - geometry has the same dimension (see ) - - - - enforce_geotype_the_geom - ensures every - geometry is of the same type (see ) - - - - enforce_srid_the_geom - ensures every - geometry is in the same projection (see ) - - - - If a table oid is provided, this function - tries to determine the srid, dimension, and geometry type of all - geometry columns in the table, adding contraints as necessary. If - successful, an appropriate row is inserted into the geometry_columns - table, otherwise, the exception is caught and an error notice is raised - describing the problem. - - If the oid of a view is provided, as with a - table oid, this function tries to determine the srid, dimension, and - type of all the geometries in the view, inserting appropriate entries - into the geometry_columns table, but nothing is done - to enforce contraints. - - The parameterless variant is a simple wrapper for the parameterized - variant that first truncates and repopulates the geometry_columns table - for every spatial table and view in the database, adding spatial - contraints to tables where appropriate. It returns a summary of the - number of geometry columns detected in the database and the number that - were inserted into the geometry_columns table. The - parameterized version simply returns the number of rows inserted into - the geometry_columns table. - Availability: 1.4.0 - - - - Examples - - SELECT Populate_Geometry_Columns('public.myspatial_table'::regclass); - - - - See Also - - - - - - - - Probe_Geometry_Columns - - Scans all tables with PostGIS geometry constraints and adds them to the geometry_columns - table if they are not there. - - - - - - text Probe_Geometry_Columns - - - - - - - Description - - Scans all tables with PostGIS geometry constraints and adds them to the geometry_columns - table if they are not there. Also give stats on number of inserts and already present or possibly obsolete. - This will usually only pick up records added by AddGeometryColumn() function. It will not scan views so views - will need to be manually added to geometry_columns table. - - - - Examples - - SELECT Probe_Geometry_Columns(); - probe_geometry_columns ---------------------------------------- -probed:6 inserted:0 conflicts:6 stale:0 -(1 row) - - - - See Also - - - - - - - - - UpdateGeometrySRID - - Updates the SRID of all features in a geometry - column, geometry_columns metadata and srid table constraint - - - - - - text UpdateGeometrySRID - - varchar - table_name - - varchar - column_name - - integer - srid - - - - text UpdateGeometrySRID - - varchar - schema_name - - varchar - table_name - - varchar - column_name - - integer - srid - - - - text UpdateGeometrySRID - - varchar - catalog_name - - varchar - schema_name - - varchar - table_name - - varchar - column_name - - integer - srid - - - - - - Description - - Updates the SRID of all features in a geometry column, updating - constraints and reference in geometry_columns. Note: uses - current_schema() on schema-aware pgsql installations if schema is not - provided. - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - See Also - - - - - - - - Geometry Constructors - - - ST_BdPolyFromText - - Construct a Polygon given an arbitrary collection of closed - linestrings as a MultiLineString Well-Known text representation. - - - - - - geometry ST_BdPolyFromText - text WKT - integer srid - - - - - - Description - - Construct a Polygon given an arbitrary collection of closed - linestrings as a MultiLineString Well-Known text representation. - - - - Throws an error if WKT is not a MULTILINESTRING. Throws an - error if output is a MULTIPOLYGON; use ST_BdMPolyFromText in that case, or - see ST_BuildArea() for a - postgis-specific approach. - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SFSQL 1.1 - 3.2.6.2 - - Availability: 1.1.0 - requires GEOS >= 2.1.0. - - - - Examples - - Forthcoming - - - - See Also - , - - - - - - ST_BdMPolyFromText - Construct a MultiPolygon given an arbitrary collection of - closed linestrings as a MultiLineString text - representation Well-Known text representation. - - - - - - geometry ST_BdMPolyFromText - text WKT - integer srid - - - - - - Description - - Construct a Polygon given an arbitrary collection of closed - linestrings, polygons, MultiLineStrings as Well-Known text representation. - - - - Throws an error if WKT is not a MULTILINESTRING. Forces - MULTIPOLYGON output even when result is really only composed by a - single POLYGON; use ST_BdPolyFromText if you're sure a - single POLYGON will result from operation, or see ST_BuildArea() for a postgis-specific - approach. - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SFSQL 1.1 - 3.2.6.2 - - Availability: 1.1.0 - requires GEOS >= 2.1.0. - - - - Examples - - Forthcoming - - - - See Also - , - - - - - - ST_GeographyFromText - Return a specified geography value from Well-Known Text representation or extended (WKT). - - - - - geography ST_GeographyFromText - text EWKT - - - - - Description - Returns a geography object from the well-known text representation. SRID 4326 is assumed. - - - - See Also - - - - - - - - ST_GeomCollFromText - - Makes a collection Geometry from collection WKT with the given SRID. If SRID is - not give, it defaults to -1. - - - - - - geometry ST_GeomCollFromText - text WKT - integer srid - - - - geometry ST_GeomCollFromText - text WKT - - - - - - - Description - - Makes a collection Geometry from the Well-Known-Text (WKT) representation with the given SRID. If SRID is - not give, it defaults to -1. - - OGC SPEC 3.2.6.2 - option SRID is from the conformance suite - - Returns null if the WKT is not a GEOMETRYCOLLECTION - - If you are absolutely sure all your WKT geometries are collections, don't use this function. - It is slower than ST_GeomFromText since it adds an additional validation step. - - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC 3.2.6.2 - - - - - - - This method implements the SQL/MM specification: ? - - - - - - Examples - - SELECT ST_GeomCollFromText('GEOMETRYCOLLECTION(POINT(1 2),LINESTRING(1 2, 3 4))'); - - - - - - See Also - - , - - - - - - - ST_GeomFromEWKB - Return a specified ST_Geometry value from Extended Well-Known Binary representation (EWKB). - - - - - - geometry ST_GeomFromEWKB - bytea EWKB - - - - - - Description - Constructs a PostGIS ST_Geometry object from the OGC Extended Well-Known binary (EWKT) representation. - - The EWKB format is not an OGC standard, but a PostGIS specific format that includes the spatial reference system (SRID) - identifier - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and curves - - - - Examples - line string binary rep 0f - LINESTRING(-71.160281 42.258729,-71.160837 42.259113,-71.161144 42.25932) in NAD 83 long lat (4269). - NOTE: Even though byte arrays are delimited with \ and may have ', we need to escape both out with \ and ''. So it does not - look exactly like its AsEWKB representation. - SELECT ST_GeomFromEWKB(E'\\001\\002\\000\\000 \\255\\020\\000\\000\\003\\000\\000\\000\\344J= -\\013B\\312Q\\300n\\303(\\010\\036!E@''\\277E''K -\\312Q\\300\\366{b\\235*!E@\\225|\\354.P\\312Q -\\300p\\231\\323e1!E@'); - - - See Also - , , - - - - - - ST_GeomFromEWKT - Return a specified ST_Geometry value from Extended Well-Known Text representation (EWKT). - - - - - - geometry ST_GeomFromEWKT - text EWKT - - - - - - Description - Constructs a PostGIS ST_Geometry object from the OGC Extended Well-Known text (EWKT) representation. - - The EWKT format is not an OGC standard, but an PostGIS specific format that includes the spatial reference system (SRID) - identifier - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - Examples - SELECT ST_GeomFromEWKT('SRID=4269;LINESTRING(-71.160281 42.258729,-71.160837 42.259113,-71.161144 42.25932)'); -SELECT ST_GeomFromEWKT('SRID=4269;MULTILINESTRING((-71.160281 42.258729,-71.160837 42.259113,-71.161144 42.25932))'); - -SELECT ST_GeomFromEWKT('SRID=4269;POINT(-71.064544 42.28787)'); - -SELECT ST_GeomFromEWKT('SRID=4269;POLYGON((-71.1776585052917 42.3902909739571,-71.1776820268866 42.3903701743239, --71.1776063012595 42.3903825660754,-71.1775826583081 42.3903033653531,-71.1776585052917 42.3902909739571))'); - -SELECT ST_GeomFromEWKT('SRID=4269;MULTIPOLYGON(((-71.1031880899493 42.3152774590236, --71.1031627617667 42.3152960829043,-71.102923838298 42.3149156848307, --71.1023097974109 42.3151969047397,-71.1019285062273 42.3147384934248, --71.102505233663 42.3144722937587,-71.10277487471 42.3141658254797, --71.103113945163 42.3142739188902,-71.10324876416 42.31402489987, --71.1033002961013 42.3140393340215,-71.1033488797549 42.3139495090772, --71.103396240451 42.3138632439557,-71.1041521907712 42.3141153348029, --71.1041411411543 42.3141545014533,-71.1041287795912 42.3142114839058, --71.1041188134329 42.3142693656241,-71.1041112482575 42.3143272556118, --71.1041072845732 42.3143851580048,-71.1041057218871 42.3144430686681, --71.1041065602059 42.3145009876017,-71.1041097995362 42.3145589148055, --71.1041166403905 42.3146168544148,-71.1041258822717 42.3146748022936, --71.1041375307579 42.3147318674446,-71.1041492906949 42.3147711126569, --71.1041598612795 42.314808571739,-71.1042515013869 42.3151287620809, --71.1041173835118 42.3150739481917,-71.1040809891419 42.3151344119048, --71.1040438678912 42.3151191367447,-71.1040194562988 42.3151832057859, --71.1038734225584 42.3151140942995,-71.1038446938243 42.3151006300338, --71.1038315271889 42.315094347535,-71.1037393329282 42.315054824985, --71.1035447555574 42.3152608696313,-71.1033436658644 42.3151648370544, --71.1032580383161 42.3152269126061,-71.103223066939 42.3152517403219, --71.1031880899493 42.3152774590236)), -((-71.1043632495873 42.315113108546,-71.1043583974082 42.3151211109857, --71.1043443253471 42.3150676015829,-71.1043850704575 42.3150793250568,-71.1043632495873 42.315113108546)))'); - ---3d circular string -SELECT ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)'); - - - - See Also - , , - - - - - ST_GeometryFromText - Return a specified ST_Geometry value from Well-Known Text representation (WKT). This is an alias name for ST_GeomFromText - - - - - geometry ST_GeometryFromText - text WKT - - - geometry ST_GeometryFromText - text WKT - integer srid - - - - - Description - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.40 - - - See Also - - - - - - - ST_GeomFromGML - Takes as input GML representation of geometry and outputs a PostGIS geometry object - - - - - - geometry ST_GeomFromGML - text geomgml - - - - - - Description - Constructs a PostGIS ST_Geometry object from the OGC GML representation. - - Requires compilation with libxml2 2.5+ - - ST_GeomFromGML works only for GML Geometry fragments. It throws an error if you try to use it on a whole GML document. - - OGC GML versions supported: - - - GML 3.2.1 Namespace - - - GML 3.1.1 Simple Features profile SF-2 (with GML 3.1.0 and 3.0.0 backward compatibility) - - - GML 2.1.2 - - - OGC GML standards, cf: http://www.opengeospatial.org/standards/gml: - - - Availability: 1.5 - requires libxml2 >= 2.5+ - - - - - - This function supports 3d and will not drop the z-index. - GML allow mixed dimensions (2D and 3D inside the same MultiGeometry for instance). As PostGIS geometries don't, ST_GeomFromGML convert the whole geometry to 2D if a missing Z dimension is found once. - - GML support mixed SRS inside the same MultiGeometry. As PostGIS geometries don't, ST_GeomFromGML, in this case, reproject all subgeometries to the SRS root node. If no srsName attribute available for the GML root node, the function throw an error. - - ST_GeomFromGML function is not pedantic about an explicit GML namespace. You could avoid to mention it explicitly for common usages. But you need it if you want to use XLink feature inside GML. - - ST_GeomFromGML function not support SQL/MM curves geometries. - - - - - - Examples - A single geometry with srsName - SELECT ST_GeomFromGML(' - - -71.16028,42.258729 -71.160837,42.259112 -71.161143,42.25932 - - ']]>); - - - - - Examples - XLink usage - - - 42.258729 -71.16028 - - 42.259112 -71.160837 - - - - ');]]>); - - - - - See Also - - - - - - - - ST_GeomFromKML - Takes as input KML representation of geometry and outputs a PostGIS geometry object - - - - - - geometry ST_GeomFromKML - text geomkml - - - - - - Description - Constructs a PostGIS ST_Geometry object from the OGC KML representation. - - Requires compilation with libxml2 2.5+ - - ST_GeomFromKML works only for KML Geometry fragments. It throws an error if you try to use it on a whole KML document. - - OGC KML versions supported: - - - KML 2.2.0 Namespace - - - OGC KML standards, cf: http://www.opengeospatial.org/standards/kml: - - - Availability: 1.5 - requires libxml2 >= 2.5+ - - - - - - This function supports 3d and will not drop the z-index. - - ST_GeomFromKML function not support SQL/MM curves geometries. - - - - - - Examples - A single geometry with srsName - SELECT ST_GeomFromKML(' - -71.1663,42.2614 - -71.1667,42.2616 - ']]>); - - - - - See Also - - - - - - - ST_GMLToSQL - Return a specified ST_Geometry value from GML representation. This is an alias name for ST_GeomFromGML - - - - - geometry ST_GMLToSQL - text geomgml - - - - - Description - - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.50 (except for curves support). - - - See Also - - - - - - - - ST_GeomFromText - Return a specified ST_Geometry value from Well-Known Text representation (WKT). - - - - - geometry ST_GeomFromText - text WKT - - - geometry ST_GeomFromText - text WKT - integer srid - - - - - - Description - - Constructs a PostGIS ST_Geometry object from the OGC Well-Known text representation. - - - - There are 2 variants of ST_GeomFromText function, the first takes no SRID and returns a geometry - with no defined spatial reference system. The second takes a spatial reference id as the second argument - and returns an ST_Geometry that includes this srid as part of its meta-data. The srid must be defined - in the spatial_ref_sys table. - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - OGC SPEC 3.2.6.2 - option SRID is from the conformance suite. - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.40 - - - - - - - This method supports Circular Strings and Curves - - - - Examples - SELECT ST_GeomFromText('LINESTRING(-71.160281 42.258729,-71.160837 42.259113,-71.161144 42.25932)'); -SELECT ST_GeomFromText('LINESTRING(-71.160281 42.258729,-71.160837 42.259113,-71.161144 42.25932)',4269); - -SELECT ST_GeomFromText('MULTILINESTRING((-71.160281 42.258729,-71.160837 42.259113,-71.161144 42.25932))'); - -SELECT ST_GeomFromText('POINT(-71.064544 42.28787)'); - -SELECT ST_GeomFromText('POLYGON((-71.1776585052917 42.3902909739571,-71.1776820268866 42.3903701743239, --71.1776063012595 42.3903825660754,-71.1775826583081 42.3903033653531,-71.1776585052917 42.3902909739571))'); - -SELECT ST_GeomFromText('MULTIPOLYGON(((-71.1031880899493 42.3152774590236, --71.1031627617667 42.3152960829043,-71.102923838298 42.3149156848307, --71.1023097974109 42.3151969047397,-71.1019285062273 42.3147384934248, --71.102505233663 42.3144722937587,-71.10277487471 42.3141658254797, --71.103113945163 42.3142739188902,-71.10324876416 42.31402489987, --71.1033002961013 42.3140393340215,-71.1033488797549 42.3139495090772, --71.103396240451 42.3138632439557,-71.1041521907712 42.3141153348029, --71.1041411411543 42.3141545014533,-71.1041287795912 42.3142114839058, --71.1041188134329 42.3142693656241,-71.1041112482575 42.3143272556118, --71.1041072845732 42.3143851580048,-71.1041057218871 42.3144430686681, --71.1041065602059 42.3145009876017,-71.1041097995362 42.3145589148055, --71.1041166403905 42.3146168544148,-71.1041258822717 42.3146748022936, --71.1041375307579 42.3147318674446,-71.1041492906949 42.3147711126569, --71.1041598612795 42.314808571739,-71.1042515013869 42.3151287620809, --71.1041173835118 42.3150739481917,-71.1040809891419 42.3151344119048, --71.1040438678912 42.3151191367447,-71.1040194562988 42.3151832057859, --71.1038734225584 42.3151140942995,-71.1038446938243 42.3151006300338, --71.1038315271889 42.315094347535,-71.1037393329282 42.315054824985, --71.1035447555574 42.3152608696313,-71.1033436658644 42.3151648370544, --71.1032580383161 42.3152269126061,-71.103223066939 42.3152517403219, --71.1031880899493 42.3152774590236)), -((-71.1043632495873 42.315113108546,-71.1043583974082 42.3151211109857, --71.1043443253471 42.3150676015829,-71.1043850704575 42.3150793250568,-71.1043632495873 42.315113108546)))',4326); - -SELECT ST_GeomFromText('CIRCULARSTRING(220268 150415,220227 150505,220227 150406)'); - - - - See Also - , , - - - - - - ST_GeomFromWKB - Creates a geometry instance from a Well-Known Binary geometry - representation (WKB) and optional SRID. - - - - - - geometry ST_GeomFromWKB - bytea geom - - - - geometry ST_GeomFromWKB - bytea geom - integer srid - - - - - - Description - - The ST_GeomFromWKB function, takes a well-known - binary representation of a geometry and a Spatial Reference System ID - (SRID) and creates an instance of the appropriate - geometry type. This function plays the role of the Geometry Factory in - SQL. This is an alternate name for ST_WKBToSQL. - - If SRID is not specified, it defaults to -1 (Unknown). - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC 3.2.7.2 - the optional SRID is from the conformance suite - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.41 - - ` - - - - - This method supports Circular Strings and curves - - - - - Examples - - --Although bytea rep contains single \, these need to be escaped when inserting into a table -SELECT ST_AsEWKT( -ST_GeomFromWKB(E'\\001\\002\\000\\000\\000\\002\\000\\000\\000\\037\\205\\353Q\\270~\\\\\\300\\323Mb\\020X\\231C@\\020X9\\264\\310~\\\\\\300)\\\\\\217\\302\\365\\230C@',4326) -); - st_asewkt ------------------------------------------------------- - SRID=4326;LINESTRING(-113.98 39.198,-113.981 39.195) -(1 row) - -SELECT - ST_AsText( - ST_GeomFromWKB( - ST_AsEWKB('POINT(2 5)'::geometry) - ) - ); - st_astext ------------- - POINT(2 5) -(1 row) - - - - - See Also - - , , - - - - - - ST_LineFromMultiPoint - - Creates a LineString from a MultiPoint geometry. - - - - - - geometry ST_LineFromMultiPoint - geometry aMultiPoint - - - - - - Description - - Creates a LineString from a MultiPoint geometry. - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - - ---Create a 3d line string from a 3d multipoint -SELECT ST_AsEWKT(ST_LineFromMultiPoint(ST_GeomFromEWKT('MULTIPOINT(1 2 3, 4 5 6, 7 8 9)'))); ---result-- -LINESTRING(1 2 3,4 5 6,7 8 9) - - - - - - See Also - - , , - - - - - - ST_LineFromText - - Makes a Geometry from WKT representation with the given SRID. If SRID is - not given, it defaults to -1. - - - - - - geometry ST_LineFromText - text WKT - - - - geometry ST_LineFromText - text WKT - integer srid - - - - - - Description - - Makes a Geometry from WKT with the given SRID. If SRID is - not give, it defaults to -1. If WKT passed in is not a LINESTRING, then null is returned. - - - OGC SPEC 3.2.6.2 - option SRID is from the conformance - suite. - - - - If you know all your geometries are LINESTRINGS, its more efficient to just use ST_GeomFromText. - This just calls ST_GeomFromText and adds additional validation that it returns a linestring. - - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC 3.2.6.2 - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 7.2.8 - - - - - - Examples - - SELECT ST_LineFromText('LINESTRING(1 2, 3 4)') AS aline, ST_LineFromText('POINT(1 2)') AS null_return; -aline | null_return ------------------------------------------------- -010200000002000000000000000000F ... | t - - - - - - See Also - - - - - - - - ST_LineFromWKB - - Makes a LINESTRING from WKB with the given SRID - - - - - - geometry ST_LineFromWKB - bytea WKB - - - - geometry ST_LineFromWKB - bytea WKB - integer srid - - - - - - Description - - The ST_LineFromWKB function, takes a well-known binary - representation of geometry and a Spatial Reference System ID (SRID) - and creates an instance of the appropriate geometry type - in this case, a - LINESTRING geometry. This function plays the role of the Geometry - Factory in SQL. - - If an SRID is not specified, it defaults to -1. NULL is - returned if the input bytea - does not represent a LINESTRING. - - - OGC SPEC 3.2.6.2 - option SRID is from the conformance - suite. - - - - If you know all your geometries are LINESTRINGs, its more - efficient to just use . This function just - calls and adds additional validation that - it returns a linestring. - - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC 3.2.6.2 - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 7.2.9 - - - - - - Examples - - SELECT ST_LineFromWKB(ST_AsBinary(ST_GeomFromText('LINESTRING(1 2, 3 4)'))) AS aline, - ST_LineFromWKB(ST_AsBinary(ST_GeomFromText('POINT(1 2)'))) IS NULL AS null_return; -aline | null_return ------------------------------------------------- -010200000002000000000000000000F ... | t - - - - - - See Also - - , - - - - - - ST_LinestringFromWKB - - Makes a geometry from WKB with the given SRID. - - - - - - geometry ST_LinestringFromWKB - bytea WKB - - - - geometry ST_LinestringFromWKB - bytea WKB - integer srid - - - - - - Description - - The ST_LinestringFromWKB function, takes a well-known binary - representation of geometry and a Spatial Reference System ID (SRID) - and creates an instance of the appropriate geometry type - in this case, a - LINESTRING geometry. This function plays the role of the Geometry - Factory in SQL. - - If an SRID is not specified, it defaults to -1. NULL is - returned if the input bytea does not represent a - LINESTRING geometry. This an alias for . - - - OGC SPEC 3.2.6.2 - optional SRID is from the conformance suite. - - - - If you know all your geometries are LINESTRINGs, it's more - efficient to just use . This function just calls - and adds additional validation that it returns a - LINESTRING. - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC 3.2.6.2 - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 7.2.9 - - - - Examples - - SELECT - ST_LineStringFromWKB( - ST_AsBinary(ST_GeomFromText('LINESTRING(1 2, 3 4)')) - ) AS aline, - ST_LinestringFromWKB( - ST_AsBinary(ST_GeomFromText('POINT(1 2)')) - ) IS NULL AS null_return; - aline | null_return ------------------------------------------------- -010200000002000000000000000000F ... | t - - - - - See Also - - , - - - - - - ST_MakeBox2D - - Creates a BOX2D defined by the given point - geometries. - - - - - - box2d ST_MakeBox2D - geometry pointLowLeft - geometry pointUpRight - - - - - - Description - - Creates a BOX2D defined by the given point - geometries. This is useful for doing range queries - - - - - Examples - - ---Return all features that fall reside or partly reside in a US national atlas coordinate bounding box ---It is assumed here that the geometries are stored with SRID = 2163 (US National atlas equal area) -SELECT feature_id, feature_name, the_geom -FROM features -WHERE the_geom && ST_SetSRID(ST_MakeBox2D(ST_Point(-989502.1875, 528439.5625), - ST_Point(-987121.375 ,529933.1875)),2163) - - - - - See Also - - , , , - - - - - - ST_MakeBox3D - - Creates a BOX3D defined by the given 3d point - geometries. - - - - - - box3d ST_MakeBox3D - geometry point3DLowLeftBottom - geometry point3DUpRightTop - - - - - - Description - - Creates a BOX3D defined by the given 2 3D point - geometries. - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - - -SELECT ST_MakeBox3D(ST_MakePoint(-989502.1875, 528439.5625, 10), - ST_MakePoint(-987121.375 ,529933.1875, 10)) As abb3d - ---bb3d-- --------- -BOX3D(-989502.1875 528439.5625 10,-987121.375 529933.1875 10) - - - - - - See Also - - , , - - - - - - ST_MakeLine - - Creates a Linestring from point geometries. - - - - - - geometry ST_MakeLine - geometry set pointfield - - - - geometry ST_MakeLine - geometry point1 - geometry point2 - - - - geometry ST_MakeLine - geometry[] point_array - - - - - - Description - - ST_MakeLine comes in 3 forms: a spatial aggregate that takes - rows of point geometries and returns a line string, a function that takes an array of points, and a regular function that takes two point geometries. You - might want to use a subselect to order points before feeding them - to the aggregate version of this function. - - - - - - - This function supports 3d and will not drop the z-index. - - Availability: 1.4.0 - ST_MakeLine(geomarray) was introduced. ST_MakeLine aggregate functions was enhanced to handle more points faster. - - - - Examples: Spatial Aggregate version - This example takes a sequence of GPS points and creates one record for each - gps travel where the geometry field is a line string composed of the gps points - in the order of the travel. - - -SELECT gps.gps_track, ST_MakeLine(gps.the_geom) As newgeom - FROM (SELECT gps_track,gps_time, the_geom - FROM gps_points ORDER BY gps_track, gps_time) As gps - GROUP BY gps.gps_track - - - Examples: Non-Spatial Aggregate version - - First example is a simple one off line string composed of 2 points. The second formulates - line strings from 2 points a user draws. The third is a one-off that joins 2 3d points to create a line in 3d space. - -SELECT ST_AsText(ST_MakeLine(ST_MakePoint(1,2), ST_MakePoint(3,4))); - st_astext ---------------------- - LINESTRING(1 2,3 4) - -SELECT userpoints.id, ST_MakeLine(startpoint, endpoint) As drawn_line - FROM userpoints ; - -SELECT ST_AsEWKT(ST_MakeLine(ST_MakePoint(1,2,3), ST_MakePoint(3,4,5))); - st_asewkt -------------------------- - LINESTRING(1 2 3,3 4 5) - - - - - Examples: Using Array version - - -SELECT ST_MakeLine(ARRAY(SELECT ST_Centroid(the_geom) FROM visit_locations ORDER BY visit_time)); - ---Making a 3d line with 3 3-d points -SELECT ST_AsEWKT(ST_MakeLine(ARRAY[ST_MakePoint(1,2,3), - ST_MakePoint(3,4,5), ST_MakePoint(6,6,6)])); - st_asewkt -------------------------- -LINESTRING(1 2 3,3 4 5,6 6 6) - - - - See Also - , , , - - - - - - ST_MakePolygon - - Creates a Polygon formed by the given shell. Input - geometries must be closed LINESTRINGS. - - - - - - geometry ST_MakePolygon - geometry linestring - - - - - geometry ST_MakePolygon - geometry outerlinestring - geometry[] interiorlinestrings - - - - - - Description - - Creates a Polygon formed by the given shell. Input - geometries must be closed LINESTRINGS. Comes in 2 variants. - Variant 1: takes one closed linestring. - Variant 2: Creates a Polygon formed by the given shell and array of - holes. You can construct a geometry array using ST_Accum or the PostgreSQL ARRAY[] and - ARRAY() constructs. Input geometries must be closed LINESTRINGS. - - This function will not accept a MULTILINESTRING. Use or to generate line strings. - - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples: Single closed LINESTRING - ---2d line -SELECT ST_MakePolygon(ST_GeomFromText('LINESTRING(75.15 29.53,77 29,77.6 29.5, 75.15 29.53)')); ---If linestring is not closed ---you can add the start point to close it -SELECT ST_MakePolygon(ST_AddPoint(foo.open_line, ST_StartPoint(foo.open_line))) -FROM ( -SELECT ST_GeomFromText('LINESTRING(75.15 29.53,77 29,77.6 29.5)') As open_line) As foo; - ---3d closed line -SELECT ST_MakePolygon(ST_GeomFromText('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)) - ---measured line -- -SELECT ST_MakePolygon(ST_GeomFromText('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)) - - - - Examples: Outter shell with inner shells - - Build a donut with an ant hole - -SELECT ST_MakePolygon( - ST_ExteriorRing(ST_Buffer(foo.line,10)), - ARRAY[ST_Translate(foo.line,1,1), - ST_ExteriorRing(ST_Buffer(ST_MakePoint(20,20),1)) ] - ) -FROM - (SELECT ST_ExteriorRing(ST_Buffer(ST_MakePoint(10,10),10,10)) - As line ) - As foo; - - Build province boundaries with holes - representing lakes in the province from a set of - province polygons/multipolygons and water line strings - this is an example of using PostGIS ST_Accum - The use of CASE because feeding a null array into - ST_MakePolygon results in NULL - the use of left join to guarantee we get all provinces back even if they have no lakes - - SELECT p.gid, p.province_name, - CASE WHEN - ST_Accum(w.the_geom) IS NULL THEN p.the_geom - ELSE ST_MakePolygon(ST_LineMerge(ST_Boundary(p.the_geom)), ST_Accum(w.the_geom)) END - FROM - provinces p LEFT JOIN waterlines w - ON (ST_Within(w.the_geom, p.the_geom) AND ST_IsClosed(w.the_geom)) - GROUP BY p.gid, p.province_name, p.the_geom; - - --Same example above but utilizing a correlated subquery - --and PostgreSQL built-in ARRAY() function that converts a row set to an array - - SELECT p.gid, p.province_name, CASE WHEN - EXISTS(SELECT w.the_geom - FROM waterlines w - WHERE ST_Within(w.the_geom, p.the_geom) - AND ST_IsClosed(w.the_geom)) - THEN - ST_MakePolygon(ST_LineMerge(ST_Boundary(p.the_geom)), - ARRAY(SELECT w.the_geom - FROM waterlines w - WHERE ST_Within(w.the_geom, p.the_geom) - AND ST_IsClosed(w.the_geom))) - ELSE p.the_geom END As the_geom - FROM - provinces p; - - - - See Also - , , , , - - - - - - ST_MakePoint - - Creates a 2D,3DZ or 4D point geometry. - - - - - - geometry ST_MakePoint - double precision x - double precision y - - - - - geometry ST_MakePoint - double precision x - double precision y - double precision z - - - - - geometry ST_MakePoint - double precision x - double precision y - double precision z - double precision m - - - - - - Description - - Creates a 2D,3DZ or 4D point geometry (geometry with measure). - ST_MakePoint while not being OGC compliant is - generally faster and more precise than - and . It is also easier to use if - you have raw coordinates rather than WKT. - - Note x is longitude and y is latitude - - - - - - - This function supports 3d and will not drop the z-index. - - - - Examples - --Return point with unknown SRID -SELECT ST_MakePoint(-71.1043443253471, 42.3150676015829); - ---Return point marked as WGS 84 long lat -SELECT ST_SetSRID(ST_MakePoint(-71.1043443253471, 42.3150676015829),4326); - ---Return a 3D point (e.g. has altitude) -SELECT ST_MakePoint(1, 2,1.5); - ---Get z of point -SELECT ST_Z(ST_MakePoint(1, 2,1.5)); -result -------- -1.5 - - - See Also - , , - - - - - - ST_MakePointM - - Creates a point geometry with an x y and m coordinate. - - - - - - geometry ST_MakePointM - float x - float y - float m - - - - - - Description - - Creates a point with x, y and measure coordinates. - Note x is longitude and y is latitude. - - - - Examples - We use ST_AsEWKT in these examples to show the text representation instead of ST_AsText because ST_AsText does not - support returning M. - ---Return EWKT representation of point with unknown SRID -SELECT ST_AsEWKT(ST_MakePointM(-71.1043443253471, 42.3150676015829, 10)); - ---result - st_asewkt ------------------------------------------------ - POINTM(-71.1043443253471 42.3150676015829 10) - ---Return EWKT representation of point with measure marked as WGS 84 long lat -SELECT ST_AsEWKT(ST_SetSRID(ST_MakePointM(-71.1043443253471, 42.3150676015829,10),4326)); - - st_asewkt ---------------------------------------------------------- -SRID=4326;POINTM(-71.1043443253471 42.3150676015829 10) - ---Return a 3d point (e.g. has altitude) -SELECT ST_MakePoint(1, 2,1.5); - ---Get m of point -SELECT ST_M(ST_MakePointM(-71.1043443253471, 42.3150676015829,10)); -result -------- -10 - - - - See Also - , , - - - - - - ST_MLineFromText - - Return a specified ST_MultiLineString value from WKT representation. - - - - - - geometry ST_MLineFromText - text WKT - integer srid - - - - geometry ST_MLineFromText - text WKT - - - - - - - Description - - Makes a Geometry from Well-Known-Text (WKT) with the given SRID. If SRID is - not give, it defaults to -1. - - OGC SPEC 3.2.6.2 - option SRID is from the conformance - suite - - Returns null if the WKT is not a MULTILINESTRING - - - If you are absolutely sure all your WKT geometries are points, don't use this function. - It is slower than ST_GeomFromText since it adds an additional validation step. - - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC 3.2.6.2 - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 9.4.4 - - - - - - Examples - - SELECT ST_MLineFromText('MULTILINESTRING((1 2, 3 4), (4 5, 6 7))'); - - - - - See Also - - - - - - - - ST_MPointFromText - - Makes a Geometry from WKT with the given SRID. If SRID is - not give, it defaults to -1. - - - - - - geometry ST_MPointFromText - text WKT - integer srid - - - - geometry ST_MPointFromText - text WKT - - - - - - - Description - - Makes a Geometry from WKT with the given SRID. If SRID is - not give, it defaults to -1. - - OGC SPEC 3.2.6.2 - option SRID is from the conformance - suite - - Returns null if the WKT is not a MULTIPOINT - - - If you are absolutely sure all your WKT geometries are points, don't use this function. - It is slower than ST_GeomFromText since it adds an additional validation step. - - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC 3.2.6.2 - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 9.2.4 - - - - - - Examples - - SELECT ST_MPointFromText('MULTIPOINT(1 2, 3 4)'); -SELECT ST_MPointFromText('MULTIPOINT(-70.9590 42.1180, -70.9611 42.1223)', 4326); - - - - - See Also - - - - - - - - ST_MPolyFromText - - Makes a MultiPolygon Geometry from WKT with the given SRID. If SRID is - not give, it defaults to -1. - - - - - - geometry ST_MPolyFromText - text WKT - integer srid - - - - geometry ST_MPolyFromText - text WKT - - - - - - - Description - - Makes a MultiPolygon from WKT with the given SRID. If SRID is - not give, it defaults to -1. - - OGC SPEC 3.2.6.2 - option SRID is from the conformance suite - - - Throws an error if the WKT is not a MULTIPOLYGON - - - If you are absolutely sure all your WKT geometries are multipolygons, don't use this function. - It is slower than ST_GeomFromText since it adds an additional validation step. - - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC 3.2.6.2 - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 9.6.4 - - - - - - Examples - - SELECT ST_MPolyFromText('MULTIPOLYGON(((0 0 1,20 0 1,20 20 1,0 20 1,0 0 1),(5 5 3,5 7 3,7 7 3,7 5 3,5 5 3)))'); -SELECt ST_MPolyFromText('MULTIPOLYGON(((-70.916 42.1002,-70.9468 42.0946,-70.9765 42.0872,-70.9754 42.0875,-70.9749 42.0879,-70.9752 42.0881,-70.9754 42.0891,-70.9758 42.0894,-70.9759 42.0897,-70.9759 42.0899,-70.9754 42.0902,-70.9756 42.0906,-70.9753 42.0907,-70.9753 42.0917,-70.9757 42.0924,-70.9755 42.0928,-70.9755 42.0942,-70.9751 42.0948,-70.9755 42.0953,-70.9751 42.0958,-70.9751 42.0962,-70.9759 42.0983,-70.9767 42.0987,-70.9768 42.0991,-70.9771 42.0997,-70.9771 42.1003,-70.9768 42.1005,-70.977 42.1011,-70.9766 42.1019,-70.9768 42.1026,-70.9769 42.1033,-70.9775 42.1042,-70.9773 42.1043,-70.9776 42.1043,-70.9778 42.1048,-70.9773 42.1058,-70.9774 42.1061,-70.9779 42.1065,-70.9782 42.1078,-70.9788 42.1085,-70.9798 42.1087,-70.9806 42.109,-70.9807 42.1093,-70.9806 42.1099,-70.9809 42.1109,-70.9808 42.1112,-70.9798 42.1116,-70.9792 42.1127,-70.979 42.1129,-70.9787 42.1134,-70.979 42.1139,-70.9791 42.1141,-70.9987 42.1116,-71.0022 42.1273, - -70.9408 42.1513,-70.9315 42.1165,-70.916 42.1002)))',4326); - - - - - - See Also - - , - - - - - - ST_Point - - Returns an ST_Point with the given coordinate values. OGC alias for ST_MakePoint. - - - - - - geometry ST_Point - float x_lon - float y_lat - - - - - - Description - - Returns an ST_Point with the given coordinate values. MM compliant alias for ST_MakePoint that takes just an x and y. - - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 6.1.2 - - - - - - Examples - - SELECT ST_SetSRID(ST_Point(-71.1043443253471, 42.3150676015829),4326) - - - - - See Also - - , - - - - - - ST_PointFromText - Makes a point Geometry from WKT with the given SRID. If SRID is - not given, it defaults to unknown. - - - - - geometry ST_PointFromText - text WKT - - - geometry ST_PointFromText - text WKT - integer srid - - - - - - Description - - Constructs a PostGIS ST_Geometry point object from the OGC Well-Known text representation. If SRID is - not give, it defaults to unknown (currently -1). If geometry is not a WKT point representation, returns null. - If completely invalid WKT, then throws an error. - - - - There are 2 variants of ST_PointFromText function, the first takes no SRID and returns a geometry - with no defined spatial reference system. The second takes a spatial reference id as the second argument - and returns an ST_Geometry that includes this srid as part of its meta-data. The srid must be defined - in the spatial_ref_sys table. - - - - If you are absolutely sure all your WKT geometries are points, don't use this function. - It is slower than ST_GeomFromText since it adds an additional validation step. If you are building points from long lat coordinates and care more about performance and accuracy than OGC compliance, use or OGC compliant alias . - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - OGC SPEC 3.2.6.2 - option SRID is from the conformance suite. - - - - - This method implements the SQL/MM specification:SQL-MM 3: 6.1.8 - - - - Examples - -SELECT ST_PointFromText('POINT(-71.064544 42.28787)'); -SELECT ST_PointFromText('POINT(-71.064544 42.28787)', 4326); - - - - See Also - , , , - - - - - - ST_PointFromWKB - - Makes a geometry from WKB with the given SRID - - - - - - geometry ST_GeomFromWKB - bytea geom - - - - geometry ST_GeomFromWKB - bytea geom - integer srid - - - - - - Description - - The ST_PointFromWKB function, takes a well-known binary - representation of geometry and a Spatial Reference System ID (SRID) - and creates an instance of the appropriate geometry type - in this case, a - POINT geometry. This function plays the role of the Geometry - Factory in SQL. - - If an SRID is not specified, it defaults to -1. NULL is - returned if the input bytea does not represent a - POINT geometry. - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. 3.2.7.2 - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 6.1.9 - - - - - - - - This function supports 3D - - - - - - - This method supports Circular Strings and Curves - - - - Examples - - SELECT - ST_AsText( - ST_PointFromWKB( - ST_AsEWKB('POINT(2 5)'::geometry) - ) - ); - st_astext ------------- - POINT(2 5) -(1 row) - -SELECT - ST_AsText( - ST_PointFromWKB( - ST_AsEWKB('LINESTRING(2 5, 2 6)'::geometry) - ) - ); - st_astext ------------ - -(1 row) - - - - - See Also - - , - - - - - - ST_Polygon - - Returns a polygon built from the specified linestring and SRID. - - - - - - geometry ST_Polygon - geometry aLineString - integer srid - - - - - - Description - - Returns a polygon built from the specified linestring and SRID. - - - - ST_Polygon is similar to first version oST_MakePolygon except it also sets the spatial ref sys (SRID) of the polygon. Will not work with MULTILINESTRINGS - so use LineMerge to merge multilines. Also does not create polygons with holes. Use ST_MakePolygon for that. - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 8.3.2 - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - - ---a 2d polygon -SELECT ST_Polygon(ST_GeomFromText('LINESTRING(75.15 29.53,77 29,77.6 29.5, 75.15 29.53)'), 4326); - ---result-- -POLYGON((75.15 29.53,77 29,77.6 29.5,75.15 29.53)) ---a 3d polygon -SELECT ST_AsEWKT(ST_Polygon(ST_GeomFromEWKT('LINESTRING(75.15 29.53 1,77 29 1,77.6 29.5 1, 75.15 29.53 1)'), 4326)); - -result ------- -SRID=4326;POLYGON((75.15 29.53 1,77 29 1,77.6 29.5 1,75.15 29.53 1)) - - - - - - See Also - - , , , , , - - - - - - ST_PolygonFromText - - Makes a Geometry from WKT with the given SRID. If SRID is - not give, it defaults to -1. - - - - - - geometry ST_PolygonFromText - text WKT - - - geometry ST_PolygonFromText - text WKT - integer srid - - - - - - Description - - Makes a Geometry from WKT with the given SRID. If SRID is - not give, it defaults to -1. Returns null if WKT is not a polygon. - - - OGC SPEC 3.2.6.2 - option SRID is from the conformance - suite - - If you are absolutely sure all your WKT geometries are polygons, don't use this function. - It is slower than ST_GeomFromText since it adds an additional validation step. - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC 3.2.6.2 - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 8.3.6 - - - - - Examples - - SELECT ST_PolygonFromText('POLYGON((-71.1776585052917 42.3902909739571,-71.1776820268866 42.3903701743239, --71.1776063012595 42.3903825660754,-71.1775826583081 42.3903033653531,-71.1776585052917 42.3902909739571))'); -st_polygonfromtext ------------------- -010300000001000000050000006... - - -SELECT ST_PolygonFromText('POINT(1 2)') IS NULL as point_is_notpoly; - -point_is_not_poly ----------- -t - - - - - - See Also - - - - - - - - ST_WKBToSQL - Return a specified ST_Geometry value from Well-Known Binary representation (WKB). This is an alias name for ST_GeomFromWKB that takes no srid - - - - - geometry ST_WKBToSQL - bytea WKB - - - - - Description - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.36 - - - See Also - - - - - - - ST_WKTToSQL - Return a specified ST_Geometry value from Well-Known Text representation (WKT). This is an alias name for ST_GeomFromText - - - - - geometry ST_WKTToSQL - text WKT - - - - - Description - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.34 - - - See Also - - - - - - - Geometry Accessors - - - - GeometryType - - Returns the type of the geometry as a string. Eg: - 'LINESTRING', 'POLYGON', 'MULTIPOINT', etc. - - - - - - text GeometryType - geometry geomA - - - - - - Description - - Returns the type of the geometry as a string. Eg: - 'LINESTRING', 'POLYGON', 'MULTIPOINT', etc. - - OGC SPEC s2.1.1.1 - Returns the name of the instantiable - subtype of Geometry of which this Geometry instance is a member. - The name of the instantiable subtype of Geometry is returned as a - string. - - - This function also indicates if the geometry is measured, - by returning a string of the form 'POINTM'. - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - - This method supports Circular Strings and Curves - - - - - - Examples - - SELECT GeometryType(ST_GeomFromText('LINESTRING(77.29 29.07,77.42 29.26,77.27 29.31,77.29 29.07)')); - geometrytype --------------- - LINESTRING - - - - - - See Also - - - - - - ST_Boundary - - Returns the closure of the combinatorial boundary of this - Geometry. - - - - - - geometry ST_Boundary - - geometry geomA - - - - - - Description - - Returns the closure of the combinatorial boundary of this - Geometry. The combinatorial boundary is defined as described in - section 3.12.3.2 of the OGC SPEC. Because the result of this - function is a closure, and hence topologically closed, the - resulting boundary can be represented using representational - geometry primitives as discussed in the OGC SPEC, section - 3.12.2. - Performed by the GEOS module - - Do not call with a GEOMETRYCOLLECTION as an argument - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC s2.1.1.1 - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.14 - - - - - - - This function supports 3d and will not drop the z-index. - - - - Examples - - SELECT ST_AsText(ST_Boundary(ST_GeomFromText('LINESTRING(1 1,0 0, -1 1)'))); -st_astext ------------ -MULTIPOINT(1 1,-1 1) - -SELECT ST_AsText(ST_Boundary(ST_GeomFromText('POLYGON((1 1,0 0, -1 1, 1 1))'))); -st_astext ----------- -LINESTRING(1 1,0 0,-1 1,1 1) - ---Using a 3d polygon -SELECT ST_AsEWKT(ST_Boundary(ST_GeomFromEWKT('POLYGON((1 1 1,0 0 1, -1 1 1, 1 1 1))'))); - -st_asewkt ------------------------------------ -LINESTRING(1 1 1,0 0 1,-1 1 1,1 1 1) - ---Using a 3d multilinestring -SELECT ST_AsEWKT(ST_Boundary(ST_GeomFromEWKT('MULTILINESTRING((1 1 1,0 0 0.5, -1 1 1),(1 1 0.5,0 0 0.5, -1 1 0.5, 1 1 0.5) )'))); - -st_asewkt ----------- -MULTIPOINT(-1 1 1,1 1 0.75) - - - - See Also - - , - - - - - - ST_CoordDim - - Return the coordinate dimension of the ST_Geometry value. - - - - - - integer ST_CoordDim - geometry geomA - - - - - - Description - - Return the coordinate dimension of the ST_Geometry value. - - This is the MM compliant alias name for - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.3 - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - This method supports Circular Strings and curves - - - - - Examples - - SELECT ST_CoordDim('CIRCULARSTRING(1 2 3, 1 3 4, 5 6 7, 8 9 10, 11 12 13)'); - ---result-- - 3 - - SELECT ST_CoordDim(ST_Point(1,2)); - --result-- - 2 - - - - - - - See Also - - - - - - - - ST_Dimension - - The inherent dimension of this Geometry object, which must - be less than or equal to the coordinate dimension. - - - - - - integer ST_Dimension - - geometry g - - - - - - Description - - The inherent dimension of this Geometry object, which must - be less than or equal to the coordinate dimension. OGC SPEC - s2.1.1.1 - returns 0 for POINT, 1 for LINESTRING, 2 for POLYGON, and - the largest dimension of the components of a - GEOMETRYCOLLECTION. - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.2 - - - - - - Examples - - SELECT ST_Dimension('GEOMETRYCOLLECTION(LINESTRING(1 1,0 0),POINT(0 0))'); -ST_Dimension ------------ -1 - - - - See Also - - - - - - - - ST_EndPoint - - Returns the last point of a LINESTRING - geometry as a POINT. - - - - - - boolean ST_EndPoint - - geometry g - - - - - - Description - - Returns the last point of a LINESTRING geometry - as a POINT or NULL if the input - parameter is not a LINESTRING. - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 7.1.4 - - - - - - - This function supports 3d and will not drop the z-index. - - - - Examples - - postgis=# SELECT ST_AsText(ST_EndPoint('LINESTRING(1 1, 2 2, 3 3)'::geometry)); - st_astext ------------- - POINT(3 3) -(1 row) - -postgis=# SELECT ST_EndPoint('POINT(1 1)'::geometry) IS NULL AS is_null; - is_null ----------- - t -(1 row) - ---3d endpoint -SELECT ST_AsEWKT(ST_EndPoint('LINESTRING(1 1 2, 1 2 3, 0 0 5)')); - st_asewkt --------------- - POINT(0 0 5) -(1 row) - - - - - See Also - - , - - - - - - ST_Envelope - - Returns a geometry representing the bounding box of the - supplied geometry. - - - - - - boolean ST_Envelope - - geometry g1 - - - - - - Description - - Returns the minimum bounding box for the supplied geometry, as a geometry. - The polygon is defined by the corner points of the bounding box - ((MINX, MINY), - (MINX, MAXY), - (MAXX, MAXY), - (MAXX, MINY), - (MINX, MINY)). (PostGIS will add a - ZMIN/ZMAX coordinate as - well). - - Degenerate cases (vertical lines, points) will return a geometry of - lower dimension than POLYGON, ie. - POINT or LINESTRING. - - - In PostGIS, the bounding box of a geometry is represented internally using - float4s instead of float8s that are used - to store geometries. The bounding box coordinates are floored, guarenteeing - that the geometry is contained entirely within its bounds. This has the - advantage that a geometry's bounding box is half the size as the minimum - bounding rectangle, which means significantly faster indexes and general performance. - But it also means that the bounding box is NOT the same as the minimum bounding - rectangle that bounds the geometry. - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL: v1.1: s2.1.1.1 - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.15 - - - - Examples - - - SELECT ST_AsText(ST_Envelope('POINT(1 3)'::geometry)); - st_astext - ------------ - POINT(1 3) - (1 row) - - - SELECT ST_AsText(ST_Envelope('LINESTRING(0 0, 1 3)'::geometry)); - st_astext - -------------------------------- - POLYGON((0 0,0 3,1 3,1 0,0 0)) - (1 row) - - - SELECT ST_AsText(ST_Envelope('POLYGON((0 0, 0 1, 1.0000001 1, 1.0000001 0, 0 0))'::geometry)); - st_astext - -------------------------------------------------------------- - POLYGON((0 0,0 1,1.00000011920929 1,1.00000011920929 0,0 0)) - (1 row) - SELECT ST_AsText(ST_Envelope('POLYGON((0 0, 0 1, 1.0000000001 1, 1.0000000001 0, 0 0))'::geometry)); - st_astext - -------------------------------------------------------------- - POLYGON((0 0,0 1,1.00000011920929 1,1.00000011920929 0,0 0)) - (1 row) - - - - - - ST_ExteriorRing - - Returns a line string representing the exterior ring of the POLYGON geometry. Return - NULL if the geometry is not a polygon. Will not work with MULTIPOLYGON - - - - - - geometry ST_ExteriorRing - - geometry a_polygon - - - - - - Description - - Returns a line string representing the exterior ring of the POLYGON geometry. Return - NULL if the geometry is not a polygon. - - Only works with POLYGON geometry types - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SFSQL 1.1 - - 2.1.5.1 - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 8.2.3, 8.3.3 - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - ---If you have a table of polygons -SELECT gid, ST_ExteriorRing(the_geom) AS ering -FROM sometable; - ---If you have a table of MULTIPOLYGONs ---and want to return a MULTILINESTRING composed of the exterior rings of each polygon -SELECT gid, ST_Collect(ST_ExteriorRing(the_geom)) AS erings - FROM (SELECT gid, (ST_Dump(the_geom)).geom As the_geom - FROM sometable) As foo -GROUP BY gid; - ---3d Example -SELECT ST_AsEWKT( - ST_ExteriorRing( - ST_GeomFromEWKT('POLYGON((0 0 1, 1 1 1, 1 2 1, 1 1 1, 0 0 1))') - ) -); - -st_asewkt ---------- -LINESTRING(0 0 1,1 1 1,1 2 1,1 1 1,0 0 1) - - - - - See Also - - , - - - - - - ST_GeometryN - - Return the 1-based Nth geometry if the geometry is a - GEOMETRYCOLLECTION, MULTIPOINT, MULTILINESTRING, MULTICURVE or MULTIPOLYGON. - Otherwise, return NULL. - - - - - - geometry ST_GeometryN - geometry geomA - integer n - - - - - - Description - - Return the 1-based Nth geometry if the geometry is a - GEOMETRYCOLLECTION, MULTIPOINT, MULTILINESTRING, MULTICURVE or MULTIPOLYGON. - Otherwise, return NULL. - - - Index is 1-based as for OGC specs since version 0.8.0. - Previous versions implemented this as 0-based instead. - - - - If you want to extract all geometries, of a geometry, ST_Dump is more efficient and will also work for singular geoms. - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 9.1.5 - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - ---Extracting a subset of points from a 3d multipoint -SELECT n, ST_AsEWKT(ST_GeometryN(the_geom, n)) As geomewkt -FROM ( -VALUES (ST_GeomFromEWKT('MULTIPOINT(1 2 7, 3 4 7, 5 6 7, 8 9 10)') ), -( ST_GeomFromEWKT('MULTICURVE(CIRCULARSTRING(2.5 2.5,4.5 2.5, 3.5 3.5), (10 11, 12 11))') ) - )As foo(the_geom) - CROSS JOIN generate_series(1,100) n -WHERE n <= ST_NumGeometries(the_geom); - - n | geomewkt ----+----------------------------------------- - 1 | POINT(1 2 7) - 2 | POINT(3 4 7) - 3 | POINT(5 6 7) - 4 | POINT(8 9 10) - 1 | CIRCULARSTRING(2.5 2.5,4.5 2.5,3.5 3.5) - 2 | LINESTRING(10 11,12 11) - - ---Extracting all geometries (useful when you want to assign an id) -SELECT gid, n, ST_GeometryN(the_geom, n) -FROM sometable CROSS JOIN generate_series(1,100) n -WHERE n <= ST_NumGeometries(the_geom); - - - - - - - - See Also - - , - - - - - - ST_GeometryType - Return the geometry type of the ST_Geometry value. - - - - - - text ST_GeometryType - geometry g1 - - - - - Description - - Returns the type of the geometry as a string. EG: 'ST_Linestring', 'ST_Polygon','ST_MultiPolygon' etc. This function differs from GeometryType(geometry) in the case of the string and ST in front that is returned, as well as the fact that it will not indicate whether the geometry is measured. - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.4 - - - - - Examples - - SELECT ST_GeometryType(ST_GeomFromText('LINESTRING(77.29 29.07,77.42 29.26,77.27 29.31,77.29 29.07)')); - --result - ST_LineString - - - - See Also - - - - - - - - - - ST_InteriorRingN - - Return the Nth interior linestring ring of the polygon geometry. - Return NULL if the geometry is not a polygon or the given N is out - of range. - - - - - - geometry ST_InteriorRingN - geometry a_polygon - integer n - - - - - - Description - - Return the Nth interior linestring ring of the polygon geometry. - Return NULL if the geometry is not a polygon or the given N is out - of range. index starts at 1. - - - - This will not work for MULTIPOLYGONs. Use in conjunction with ST_Dump for MULTIPOLYGONS - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 8.2.6, 8.3.5 - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - - -SELECT ST_AsText(ST_InteriorRingN(the_geom, 1)) As the_geom -FROM (SELECT ST_BuildArea( - ST_Collect(ST_Buffer(ST_Point(1,2), 20,3), - ST_Buffer(ST_Point(1, 2), 10,3))) As the_geom - ) as foo - - - - - - See Also - - , , , , - - - - - - ST_IsClosed - - Returns TRUE if the - LINESTRING's start and end points are coincident. - - - - - - - boolean ST_IsClosed - - geometry g - - - - - - Description - - Returns TRUE if the LINESTRING's - start and end points are coincident. - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 7.1.5, 9.3.3 - - - SQL-MM defines the result of - ST_IsClosed(NULL) to be 0, while - PostGIS returns NULL. - - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - Examples - - postgis=# SELECT ST_IsClosed('LINESTRING(0 0, 1 1)'::geometry); - st_isclosed -------------- - f -(1 row) - -postgis=# SELECT ST_IsClosed('LINESTRING(0 0, 0 1, 1 1, 0 0)'::geometry); - st_isclosed -------------- - t -(1 row) - -postgis=# SELECT ST_IsClosed('MULTILINESTRING((0 0, 0 1, 1 1, 0 0),(0 0, 1 1))'::geometry); - st_isclosed -------------- - f -(1 row) - -postgis=# SELECT ST_IsClosed('POINT(0 0)'::geometry); - st_isclosed -------------- - t -(1 row) - -postgis=# SELECT ST_IsClosed('MULTIPOINT((0 0), (1 1))'::geometry); - st_isclosed -------------- - t -(1 row) - - - - See Also - - - - - - - - ST_IsEmpty - - Returns true if this Geometry is an empty geometry . If - true, then this Geometry represents the empty point set - i.e. - GEOMETRYCOLLECTION(EMPTY). - - - - - - - boolean ST_IsEmpty - geometry geomA - - - - - - Description - - Returns true if this Geometry is an empty geometry . If - true, then this Geometry represents an empty geometry collection, polygon, point etc. - - SQL-MM defines the result of ST_IsEmpty(NULL) to be 0, while - PostGIS returns NULL. - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC s2.1.1.1 - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.7 - - - - - - - This method supports Circular Strings and Curves - - - - - - Examples - - -SELECT ST_IsEmpty('GEOMETRYCOLLECTION(EMPTY)'); - st_isempty ------------- - t -(1 row) - - SELECT ST_IsEmpty(ST_GeomFromText('POLYGON EMPTY')); - st_isempty ------------- - t -(1 row) - -SELECT ST_IsEmpty(ST_GeomFromText('POLYGON((1 2, 3 4, 5 6, 1 2))')); - - st_isempty ------------- - f -(1 row) - - SELECT ST_IsEmpty(ST_GeomFromText('POLYGON((1 2, 3 4, 5 6, 1 2))')) = false; - ?column? ----------- - t -(1 row) - - SELECT ST_IsEmpty(ST_GeomFromText('CIRCULARSTRING EMPTY')); - st_isempty ------------- - t -(1 row) - - - - - - - - - - ST_IsRing - - Returns TRUE if this - LINESTRING is both closed and simple. - - - - - - boolean ST_IsRing - - geometry g - - - - - - Description - - Returns TRUE if this - LINESTRING is both - (ST_StartPoint(g) - ~= - ST_Endpoint(g)) and (does not self intersect). - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SFSQL 1.1 - - 2.1.5.1 - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 7.1.6 - - - SQL-MM defines the result of - ST_IsRing(NULL) to be 0, while - PostGIS returns NULL. - - - - - Examples - - SELECT ST_IsRing(the_geom), ST_IsClosed(the_geom), ST_IsSimple(the_geom) -FROM (SELECT 'LINESTRING(0 0, 0 1, 1 1, 1 0, 0 0)'::geometry AS the_geom) AS foo; - st_isring | st_isclosed | st_issimple ------------+-------------+------------- - t | t | t -(1 row) - -SELECT ST_IsRing(the_geom), ST_IsClosed(the_geom), ST_IsSimple(the_geom) -FROM (SELECT 'LINESTRING(0 0, 0 1, 1 0, 1 1, 0 0)'::geometry AS the_geom) AS foo; - st_isring | st_isclosed | st_issimple ------------+-------------+------------- - f | t | f -(1 row) - - - - See Also - - , , , - - - - - - - - ST_IsSimple - - Returns (TRUE) if this Geometry has no anomalous geometric - points, such as self intersection or self tangency. - - - - - - boolean ST_IsSimple - geometry geomA - - - - - - Description - - Returns true if this Geometry has no anomalous geometric - points, such as self intersection or self tangency. For more - information on the OGC's definition of geometry simplicity and validity, refer - to "Ensuring OpenGIS compliancy of geometries" - - - SQL-MM defines the result of ST_IsSimple(NULL) to be 0, - while PostGIS returns NULL. - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC s2.1.1.1 - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.8 - - - - - - This function supports 3d and will not drop the z-index. - - - - Examples - - SELECT ST_IsSimple(ST_GeomFromText('POLYGON((1 2, 3 4, 5 6, 1 2))')); - st_issimple -------------- - t -(1 row) - - SELECT ST_IsSimple(ST_GeomFromText('LINESTRING(1 1,2 2,2 3.5,1 3,1 2,2 1)')); - st_issimple -------------- - f -(1 row) - - - - See Also - - - - - - - - ST_IsValid - - Returns true if the - ST_Geometry is well formed. - - - - - - - boolean ST_IsValid - - geometry g - - - - - - Description - - Test if an ST_Geometry value is well formed. For geometries that are invalid, - the PostgreSQL NOTICE will provide details of why it is not valid. For more - information on the OGC's definition of geometry simplicity and validity, refer - to "Ensuring OpenGIS compliancy of geometries" - - SQL-MM defines the result of ST_IsValid(NULL) to be 0, while - PostGIS returns NULL. - - - - - - - This method implements the concept of validity expressed in the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.9 - - - - - Examples - - SELECT ST_IsValid(ST_GeomFromText('LINESTRING(0 0, 1 1)')) As good_line, - ST_IsValid(ST_GeomFromText('POLYGON((0 0, 1 1, 1 2, 1 1, 0 0))')) As bad_poly ---results -NOTICE: Self-intersection at or near point 0 0 - good_line | bad_poly ------------+---------- - t | f - - - - - See Also - - , , - - - - - - ST_IsValidReason - - Returns text stating if a geometry is valid or not and if not valid, a reason why. - - - - - - text ST_IsValidReason - geometry geomA - - - - - - Description - - Returns text stating if a geometry is valid or not an if not valid, a reason why. - - Useful in combination with ST_IsValid to generate a detailed report of invalid geometries and reasons. - Availability: 1.4 - requires GEOS >= 3.1.0. - - - - - - Examples - - ---First 3 Rejects from a successful quintuplet experiment -SELECT gid, ST_IsValidReason(the_geom) as validity_info -FROM -(SELECT ST_MakePolygon(ST_ExteriorRing(e.buff), ST_Accum(f.line)) As the_geom, gid -FROM (SELECT ST_Buffer(ST_MakePoint(x1*10,y1), z1) As buff, x1*10 + y1*100 + z1*1000 As gid - FROM generate_series(-4,6) x1 - CROSS JOIN generate_series(2,5) y1 - CROSS JOIN generate_series(1,8) z1 - WHERE x1 > y1*0.5 AND z1 < x1*y1) As e - INNER JOIN (SELECT ST_Translate(ST_ExteriorRing(ST_Buffer(ST_MakePoint(x1*10,y1), z1)),y1*1, z1*2) As line - FROM generate_series(-3,6) x1 - CROSS JOIN generate_series(2,5) y1 - CROSS JOIN generate_series(1,10) z1 - WHERE x1 > y1*0.75 AND z1 < x1*y1) As f -ON (ST_Area(e.buff) > 78 AND ST_Contains(e.buff, f.line)) -GROUP BY gid, e.buff) As quintuplet_experiment -WHERE ST_IsValid(the_geom) = false -ORDER BY gid -LIMIT 3; - - gid | validity_info -------+-------------------------- - 5330 | Self-intersection [32 5] - 5340 | Self-intersection [42 5] - 5350 | Self-intersection [52 5] - - --simple example -SELECT ST_IsValidReason('LINESTRING(220227 150406,2220227 150407,222020 150410)'); - - st_isvalidreason ------------------- - Valid Geometry - - - - - - - See Also - - , - - - - - - ST_M - - Return the M coordinate of the point, or NULL if not - available. Input must be a point. - - - - - - float ST_M - geometry a_point - - - - - - Description - - Return the M coordinate of the point, or NULL if not - available. Input must be a point. - - - This is not (yet) part of the OGC spec, but is listed here - to complete the point coordinate extractor function list. - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3 New standard: ? - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - SELECT ST_M(ST_GeomFromEWKT('POINT(1 2 3 4)')); - st_m ------- - 4 -(1 row) - - - - - - - See Also - - , , , - - - - - - ST_NDims - Returns coordinate dimension of the geometry as a small int. - Values are: 2,3 or 4. - - - - - - integer ST_NDims - geometry g1 - - - - - - Description - - Returns the coordinate dimension of the geometry. PostGIS supports 2 - (x,y) , - 3 - (x,y,z) or 2D with measure - x,y,m, and 4 - 3D with measure space x,y,z,m - - - - - - - This function supports 3d and will not drop the z-index. - - - - Examples - - SELECT ST_NDims(ST_GeomFromText('POINT(1 1)')) As d2point, - ST_NDims(ST_GeomFromEWKT('POINT(1 1 2)')) As d3point, - ST_NDims(ST_GeomFromEWKT('POINTM(1 1 0.5)')) As d2pointm; - - d2point | d3point | d2pointm ----------+---------+---------- - 2 | 3 | 3 - - - - See Also - , , - - - - - - ST_NPoints - Return the number of points (vertexes) in a geometry. - - - - - - integer ST_NPoints - geometry g1 - - - - - - Description - - Return the number of points in a geometry. Works for all geometries. - Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - - - Examples - -SELECT ST_NPoints(ST_GeomFromText('LINESTRING(77.29 29.07,77.42 29.26,77.27 29.31,77.29 29.07)')); ---result -4 - ---Polygon in 3D space -SELECT ST_NPoints(ST_GeomFromEWKT('LINESTRING(77.29 29.07 1,77.42 29.26 0,77.27 29.31 -1,77.29 29.07 3)')) ---result -4 - - - See Also - - - - - - - - ST_NRings - If the geometry is a polygon or multi-polygon returns the number of rings. - - - - - - integer ST_NRings - geometry geomA - - - - - - Description - - If the geometry is a polygon or multi-polygon returns the number of rings. Unlike NumInteriorRings, it counts - the outer rings as well. - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - Examples - - SELECT ST_NRings(the_geom) As Nrings, ST_NumInteriorRings(the_geom) As ninterrings - FROM (SELECT ST_GeomFromText('POLYGON((1 2, 3 4, 5 6, 1 2))') As the_geom) As foo; - nrings | ninterrings ---------+------------- - 1 | 0 -(1 row) - - - - - - See Also - - - - - - - - ST_NumGeometries - If geometry is a GEOMETRYCOLLECTION (or MULTI*) return the - number of geometries, otherwise return NULL. - - - - - - integer ST_NumGeometries - geometry a_multi_or_geomcollection - - - - - - Description - - Returns the number of Geometries. If geometry is a GEOMETRYCOLLECTION (or MULTI*) return the - number of geometries, otherwise return NULL. - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 9.1.4 - - - - - Examples - - ---Although ST_NumGeometries will return null when passed a single, you can wrap in ST_Multi to force 1 or more for all geoms -SELECT ST_NumGeometries(ST_Multi(ST_GeomFromText('LINESTRING(77.29 29.07,77.42 29.26,77.27 29.31,77.29 29.07)'))); ---result -1 - ---Geometry Collection Example - multis count as one geom in a collection -SELECT ST_NumGeometries(ST_GeomFromEWKT('GEOMETRYCOLLECTION(MULTIPOINT(-2 3 , -2 2), -LINESTRING(5 5 ,10 10), -POLYGON((-7 4.2,-7.1 5,-7.1 4.3,-7 4.2)))')); ---result -3 - - - - See Also - - , - - - - - - ST_NumInteriorRings - Return the number of interior rings of the first polygon in - the geometry. This will work with both POLYGON and MULTIPOLYGON types but only looks at the first polygon. - Return NULL if there is no polygon in the - geometry. - - - - - - integer ST_NumInteriorRings - geometry a_polygon - - - - - - Description - - Return the number of interior rings of the first polygon in - the geometry. This will work with both POLYGON and MULTIPOLYGON types but only looks at the first polygon. - Return NULL if there is no polygon in the - geometry. - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 8.2.5 - - - - Examples - - ---If you have a regular polygon -SELECT gid, field1, field2, ST_NumInteriorRings(the_geom) AS numholes -FROM sometable; - ---If you have multipolygons ---And you want to know the total number of interior rings in the MULTIPOLYGON -SELECT gid, field1, field2, SUM(ST_NumInteriorRings(the_geom)) AS numholes -FROM (SELECT gid, field1, field2, (ST_Dump(the_geom)).geom As the_geom - FROM sometable) As foo -GROUP BY gid, field1,field2; - - - - See Also - - - - - - - - ST_NumInteriorRing - Return the number of interior rings of the first polygon in - the geometry. Synonym to ST_NumInteriorRings. - - - - - - integer ST_NumInteriorRing - geometry a_polygon - - - - - - Description - - Return the number of interior rings of the first polygon in - the geometry. Synonym to ST_NumInteriorRings. The OpenGIS specs are - ambiguous about the exact function naming, so we provide both - spellings. - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 8.2.5 - - - - See Also - - - - - - - - ST_NumPoints - Return the number of points in an ST_LineString or - ST_CircularString value. - - - - - - integer ST_NumPoints - geometry g1 - - - - - - Description - - Return the number of points in an ST_LineString or - ST_CircularString value. Prior to 1.4 only works with Linestrings as the specs state. From 1.4 forward this is an alias for ST_NPoints which returns number of vertexes for - not just line strings. - Consider using ST_NPoints instead which is multi-purpose - and works with many geometry types. - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 7.2.4 - - - - Examples - - SELECT ST_NumPoints(ST_GeomFromText('LINESTRING(77.29 29.07,77.42 29.26,77.27 29.31,77.29 29.07)')); - --result - 4 - - - - See Also - - - - - - - - ST_PointN - - Return the Nth point in the first linestring or circular linestring in the - geometry. Return NULL if there is no linestring in the - geometry. - - - - - - geometry ST_PointN - geometry a_linestring - integer n - - - - - - Description - - Return the Nth point in the first linestring or circular linestring in the - geometry. Return NULL if there is no linestring in the - geometry. - - - Index is 1-based as for OGC specs since version 0.8.0. - Previous versions implemented this as 0-based instead. - - - - If you want to get the nth point of each line string in a multilinestring, use in conjunction - with ST_Dump - - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 7.2.5, 7.3.5 - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - -- Extract all POINTs from a LINESTRING -SELECT ST_AsText( - ST_PointN( - column1, - generate_series(1, ST_NPoints(column1)) - )) -FROM ( VALUES ('LINESTRING(0 0, 1 1, 2 2)'::geometry) ) AS foo; - - st_astext ------------- - POINT(0 0) - POINT(1 1) - POINT(2 2) -(3 rows) - ---Example circular string -SELECT ST_AsText(ST_PointN(ST_GeomFromText('CIRCULARSTRING(1 2, 3 2, 1 2)'),2)); - -st_astext ----------- -POINT(3 2) - - - - - See Also - - - - - - - - ST_SRID - Returns the spatial reference identifier for the ST_Geometry as defined in spatial_ref_sys table. - - - - - - integer ST_SRID - geometry g1 - - - - - - Description - - Returns the spatial reference identifier for the ST_Geometry as defined in spatial_ref_sys table. - spatial_ref_sys - table is a table that catalogs all spatial reference systems known to PostGIS and is used for transformations from one spatial - reference system to another. So verifying you have the right spatial reference system identifier is important if you plan to ever transform your geometries. - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - OGC SPEC s2.1.1.1 - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.5 - - - - - - - This method supports Circular Strings and Curves - - - - Examples - - SELECT ST_SRID(ST_GeomFromText('POINT(-71.1043 42.315)',4326)); - --result - 4326 - - - - See Also - - ,, , - - - - - - ST_StartPoint - - Returns the first point of a LINESTRING - geometry as a POINT. - - - - - - geometry ST_StartPoint - - geometry geomA - - - - - - Description - - Returns the first point of a LINESTRING geometry - as a POINT or NULL if the input - parameter is not a LINESTRING. - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 7.1.3 - - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - - SELECT ST_AsText(ST_StartPoint('LINESTRING(0 1, 0 2)'::geometry)); - st_astext ------------- - POINT(0 1) -(1 row) - -SELECT ST_StartPoint('POINT(0 1)'::geometry) IS NULL AS is_null; - is_null ----------- - t -(1 row) - ---3d line -SELECT ST_AsEWKT(ST_StartPoint('LINESTRING(0 1 1, 0 2 2)'::geometry)); - st_asewkt ------------- - POINT(0 1 1) -(1 row) - - - - - - See Also - - , - - - - - ST_Summary - - Returns a text summary of the contents of the - ST_Geometry. - - - - - - - text ST_Summary - - geometry g - - - - - - Description - - Returns a text summary of the contents of the geometry. - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - Examples - - SELECT ST_Summary(ST_GeomFromText('LINESTRING(0 0, 1 1)')) As good_line, - ST_Summary(ST_GeomFromText('POLYGON((0 0, 1 1, 1 2, 1 1, 0 0))')) As bad_poly ---results - good_line | bad_poly -----------------------+------------------------- - | -Line[B] with 2 points : Polygon[B] with 1 rings - : ring 0 has 5 points - : - ---3d polygon -SELECT ST_Summary(ST_GeomFromEWKT('LINESTRING(0 0 1, 1 1 1)')) As good_line, - ST_Summary(ST_GeomFromEWKT('POLYGON((0 0 1, 1 1 2, 1 2 3, 1 1 1, 0 0 1))')) As poly - ---results - good_line | poly -----------------------+------------------------- - | -Line[ZB] with 2 points : Polygon[ZB] with 1 rings - : ring 0 has 5 points - : - - - - - - See Also - - , - - - - - - ST_X - - Return the X coordinate of the point, or NULL if not - available. Input must be a point. - - - - - - float ST_X - geometry a_point - - - - - - Description - - Return the X coordinate of the point, or NULL if not - available. Input must be a point. - - If you want to get the max min x values of any geometry look at ST_XMin, ST_XMax functions. - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3 standard: SQL-MM 3: 6.1.3 - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - SELECT ST_X(ST_GeomFromEWKT('POINT(1 2 3 4)')); - st_x ------- - 1 -(1 row) - -SELECT ST_Y(ST_Centroid(ST_GeomFromEWKT('LINESTRING(1 2 3 4, 1 1 1 1)'))); - st_y ------- - 1.5 -(1 row) - - - - - - - See Also - - , , , , , , - - - - - - ST_Y - - Return the Y coordinate of the point, or NULL if not - available. Input must be a point. - - - - - - float ST_Y - geometry a_point - - - - - - Description - - Return the Y coordinate of the point, or NULL if not - available. Input must be a point. - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3 standard: SQL-MM 3: 6.1.4 - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - SELECT ST_Y(ST_GeomFromEWKT('POINT(1 2 3 4)')); - st_y ------- - 2 -(1 row) - -SELECT ST_Y(ST_Centroid(ST_GeomFromEWKT('LINESTRING(1 2 3 4, 1 1 1 1)'))); - st_y ------- - 1.5 -(1 row) - - - - - - - - See Also - - , , , , , , - - - - - - ST_Z - - Return the Z coordinate of the point, or NULL if not - available. Input must be a point. - - - - - - float ST_Z - geometry a_point - - - - - - Description - - Return the Z coordinate of the point, or NULL if not - available. Input must be a point. - - - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3 standard New Spec: ? - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - SELECT ST_Z(ST_GeomFromEWKT('POINT(1 2 3 4)')); - st_z ------- - 3 -(1 row) - - - - - - - See Also - - , , , , , - - - - - - ST_Zmflag - - Returns ZM (dimension semantic) flag of the geometries as a - small int. Values are: 0=2d, 1=3dm, 2=3dz, 3=4d. - - - - - - smallint ST_Zmflag - geometry geomA - - - - - - Description - - Returns ZM (dimension semantic) flag of the geometries as a - small int. Values are: 0=2d, 1=3dm, 2=3dz, 3=4d. - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - SELECT ST_Zmflag(ST_GeomFromEWKT('LINESTRING(1 2, 3 4)')); - st_zmflag ------------ - 0 - -SELECT ST_Zmflag(ST_GeomFromEWKT('LINESTRINGM(1 2 3, 3 4 3)')); - st_zmflag ------------ - 1 - -SELECT ST_Zmflag(ST_GeomFromEWKT('CIRCULARSTRING(1 2 3, 3 4 3, 5 6 3)')); - st_zmflag ------------ - 2 -SELECT ST_Zmflag(ST_GeomFromEWKT('POINT(1 2 3 4)')); - st_zmflag ------------ - 3 - - - - - - See Also - - , , - - - - - - - - Geometry Editors - - - - ST_AddPoint - Adds a point to a LineString before point <position> - (0-based index). - - - - - geometry ST_AddPoint - geometry linestring - geometry point - - - - - geometry ST_AddPoint - geometry linestring - geometry point - integer position - - - - - - Description - - Adds a point to a LineString before point <position> - (0-based index). Third parameter can be omitted or set to -1 for - appending. - Availability: 1.1.0 - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - - --guarantee all linestrings in a table are closed - --by adding the start point of each linestring to the end of the line string - --only for those that are not closed - UPDATE sometable - SET the_geom = ST_AddPoint(the_geom, ST_StartPoint(the_geom)) - FROM sometable - WHERE ST_IsClosed(the_geom) = false; - - --Adding point to a 3-d line - SELECT ST_AsEWKT(ST_AddPoint(ST_GeomFromEWKT('LINESTRING(0 0 1, 1 1 1)'), ST_MakePoint(1, 2, 3))); - - --result - st_asewkt - ---------- - LINESTRING(0 0 1,1 1 1,1 2 3) - - - - See Also - , - - - - - - ST_Affine - - Applies a 3d affine transformation to the geometry to do things like translate, rotate, scale in one step. - - - - - - geometry ST_Affine - geometry geomA - float a - float b - float c - float d - float e - float f - float g - float h - float i - float xoff - float yoff - float zoff - - - - geometry ST_Affine - geometry geomA - float a - float b - float d - float e> - float xoff - float yoff - - - - - - Description - - Applies a 3d affine transformation to the geometry to do things like translate, rotate, scale in one step. - - Version 1: The - call ST_Affine(geom, a, b, c, d, e, f, g, h, i, xoff, yoff, zoff) - represents the transformation matrix / a b c xoff \ -| d e f yoff | -| g h i zoff | -\ 0 0 0 1 / and the vertices are transformed as - follows: x' = a*x + b*y + c*z + xoff -y' = d*x + e*y + f*z + yoff -z' = g*x + h*y + i*z + zoff All of the translate / scale - functions below are expressed via such an affine - transformation. - Version 2: Applies a 2d affine transformation to the geometry. The - call ST_Affine(geom, a, b, d, e, xoff, yoff) - represents the transformation matrix / a b 0 xoff \ / a b xoff \ -| d e 0 yoff | rsp. | d e yoff | -| 0 0 1 0 | \ 0 0 1 / -\ 0 0 0 1 / and the vertices are transformed as - follows: x' = a*x + b*y + xoff -y' = d*x + e*y + yoff -z' = z This method is a subcase of the 3D method - above. - - Availability: 1.1.2. Name changed from Affine to ST_Affine in 1.2.2 - Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - ---Rotate a 3d line 180 degrees about the z axis. Note this is long-hand for doing ST_RotateZ(); - SELECT ST_AsEWKT(ST_Affine(the_geom, cos(pi()), -sin(pi()), 0, sin(pi()), cos(pi()), 0, 0, 0, 1, 0, 0, 0)) As using_affine, - ST_AsEWKT(ST_RotateZ(the_geom, pi())) As using_rotatez - FROM (SELECT ST_GeomFromEWKT('LINESTRING(1 2 3, 1 4 3)') As the_geom) As foo; - using_affine | using_rotatez ------------------------------+----------------------------- - LINESTRING(-1 -2 3,-1 -4 3) | LINESTRING(-1 -2 3,-1 -4 3) -(1 row) - ---Rotate a 3d line 180 degrees in both the x and z axis -SELECT ST_AsEWKT(ST_Affine(the_geom, cos(pi()), -sin(pi()), 0, sin(pi()), cos(pi()), -sin(pi()), 0, sin(pi()), cos(pi()), 0, 0, 0)) - FROM (SELECT ST_GeomFromEWKT('LINESTRING(1 2 3, 1 4 3)') As the_geom) As foo; - st_asewkt -------------------------------- - LINESTRING(-1 -2 -3,-1 -4 -3) -(1 row) - - - - - - - See Also - - , , , - - - - - - ST_Force_2D - - Forces the geometries into a "2-dimensional mode" so that - all output representations will only have the X and Y coordinates. - - - - - - geometry ST_Force_2D - geometry geomA - - - - - - Description - - Forces the geometries into a "2-dimensional mode" so that - all output representations will only have the X and Y coordinates. - This is useful for force OGC-compliant output (since OGC only - specifies 2-D geometries). - - - - - - - - This method supports Circular Strings and curves - - - - - Examples - - SELECT ST_AsEWKT(ST_Force_2D(ST_GeomFromEWKT('CIRCULARSTRING(1 1 2, 2 3 2, 4 5 2, 6 7 2, 5 6 2)'))); - st_asewkt -------------------------------------- -CIRCULARSTRING(1 1,2 3,4 5,6 7,5 6) - -SELECT ST_AsEWKT(ST_Force_2D('POLYGON((0 0 2,0 5 2,5 0 2,0 0 2),(1 1 2,3 1 2,1 3 2,1 1 2))')); - - st_asewkt ----------------------------------------------- - POLYGON((0 0,0 5,5 0,0 0),(1 1,3 1,1 3,1 1)) - - - - - - - See Also - - - - - - - - ST_Force_3D - - Forces the geometries into XYZ mode. This is an alias for ST_Force_3DZ. - - - - - - geometry ST_Force_3D - geometry geomA - - - - - - Description - - Forces the geometries into XYZ mode. This is an alias for ST_Force_3DZ. If a geometry has no Z component, then a 0 Z coordinate is tacked on. - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - This method supports Circular Strings and curves - - - - - Examples - - - --Nothing happens to an already 3D geometry - SELECT ST_AsEWKT(ST_Force_3D(ST_GeomFromEWKT('CIRCULARSTRING(1 1 2, 2 3 2, 4 5 2, 6 7 2, 5 6 2)'))); - st_asewkt ------------------------------------------------ - CIRCULARSTRING(1 1 2,2 3 2,4 5 2,6 7 2,5 6 2) - - -SELECT ST_AsEWKT(ST_Force_3D('POLYGON((0 0,0 5,5 0,0 0),(1 1,3 1,1 3,1 1))')); - - st_asewkt --------------------------------------------------------------- - POLYGON((0 0 0,0 5 0,5 0 0,0 0 0),(1 1 0,3 1 0,1 3 0,1 1 0)) - - - - - - See Also - - , , , - - - - - - ST_Force_3DZ - - Forces the geometries into XYZ mode. This is a synonym for ST_Force_3D. - - - - - - geometry ST_Force_3DZ - geometry geomA - - - - - - Description - - Forces the geometries into XYZ mode. This is a synonym for ST_Force_3DZ. If a geometry has no Z component, then a 0 Z coordinate is tacked on. - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - This method supports Circular Strings and curves - - - - - Examples - - ---Nothing happens to an already 3D geometry -SELECT ST_AsEWKT(ST_Force_3DZ(ST_GeomFromEWKT('CIRCULARSTRING(1 1 2, 2 3 2, 4 5 2, 6 7 2, 5 6 2)'))); - st_asewkt ------------------------------------------------ - CIRCULARSTRING(1 1 2,2 3 2,4 5 2,6 7 2,5 6 2) - - -SELECT ST_AsEWKT(ST_Force_3DZ('POLYGON((0 0,0 5,5 0,0 0),(1 1,3 1,1 3,1 1))')); - - st_asewkt --------------------------------------------------------------- - POLYGON((0 0 0,0 5 0,5 0 0,0 0 0),(1 1 0,3 1 0,1 3 0,1 1 0)) - - - - - - See Also - - , , , - - - - - - ST_Force_3DM - - Forces the geometries into XYM mode. - - - - - - geometry ST_Force_3DM - geometry geomA - - - - - - Description - - Forces the geometries into XYM mode. If a geometry has no M component, then a 0 M coordinate is tacked on. If it has a Z component, then Z is removed - - - - - - - - This method supports Circular Strings and curves - - - - - Examples - - ---Nothing happens to an already 3D geometry -SELECT ST_AsEWKT(ST_Force_3DM(ST_GeomFromEWKT('CIRCULARSTRING(1 1 2, 2 3 2, 4 5 2, 6 7 2, 5 6 2)'))); - st_asewkt ------------------------------------------------- - CIRCULARSTRINGM(1 1 0,2 3 0,4 5 0,6 7 0,5 6 0) - - -SELECT ST_AsEWKT(ST_Force_3DM('POLYGON((0 0 1,0 5 1,5 0 1,0 0 1),(1 1 1,3 1 1,1 3 1,1 1 1))')); - - st_asewkt ---------------------------------------------------------------- - POLYGONM((0 0 0,0 5 0,5 0 0,0 0 0),(1 1 0,3 1 0,1 3 0,1 1 0)) - - - - - - - See Also - - , , , , - - - - - - ST_Force_4D - - Forces the geometries into XYZM mode. - - - - - - geometry ST_Force_4D - geometry geomA - - - - - - Description - - Forces the geometries into XYZM mode. 0 is tacked on for missing Z and M dimensions. - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - This method supports Circular Strings and curves - - - - - Examples - - ---Nothing happens to an already 3D geometry -SELECT ST_AsEWKT(ST_Force_4D(ST_GeomFromEWKT('CIRCULARSTRING(1 1 2, 2 3 2, 4 5 2, 6 7 2, 5 6 2)'))); - st_asewkt ---------------------------------------------------------- - CIRCULARSTRING(1 1 2 0,2 3 2 0,4 5 2 0,6 7 2 0,5 6 2 0) - - - -SELECT ST_AsEWKT(ST_Force_4D('MULTILINESTRINGM((0 0 1,0 5 2,5 0 3,0 0 4),(1 1 1,3 1 1,1 3 1,1 1 1))')); - - st_asewkt --------------------------------------------------------------------------------------- - MULTILINESTRING((0 0 0 1,0 5 0 2,5 0 0 3,0 0 0 4),(1 1 0 1,3 1 0 1,1 3 0 1,1 1 0 1)) - - - - - - - See Also - - , , , - - - - - - ST_Force_Collection - - Converts the geometry into a GEOMETRYCOLLECTION. - - - - - - geometry ST_Force_Collection - geometry geomA - - - - - - Description - - Converts the geometry into a GEOMETRYCOLLECTION. This is - useful for simplifying the WKB representation. - - Availability: 1.2.2, prior to 1.3.4 this function will crash with Curves. This is fixed in 1.3.4+ - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - - -SELECT ST_AsEWKT(ST_Force_Collection('POLYGON((0 0 1,0 5 1,5 0 1,0 0 1),(1 1 1,3 1 1,1 3 1,1 1 1))')); - - st_asewkt ----------------------------------------------------------------------------------- - GEOMETRYCOLLECTION(POLYGON((0 0 1,0 5 1,5 0 1,0 0 1),(1 1 1,3 1 1,1 3 1,1 1 1))) - - - SELECT ST_AsText(ST_Force_Collection('CIRCULARSTRING(220227 150406,2220227 150407,220227 150406)')); - st_astext --------------------------------------------------------------------------------- - GEOMETRYCOLLECTION(CIRCULARSTRING(220227 150406,2220227 150407,220227 150406)) -(1 row) - - - - - - - See Also - - , , , , - - - - - - - ST_ForceRHR - - Forces the orientation of the vertices in a polygon to follow the - Right-Hand-Rule. - - - - - - boolean - ST_ForceRHR - geometry g - - - - - - Description - - Forces the orientation of the vertices in a polygon to follow the - Right-Hand-Rule. In GIS terminology, this means that the area that is bounded by the - polygon is to the right of the boundary. In particular, the exterior ring is - orientated in a clockwise direction and the interior rings in a counter-clockwise - direction. - - - - - - This function supports 3d in that it will not drop the - z-index. - - - - Examples - - SELECT ST_AsEWKT( - ST_ForceRHR( - 'POLYGON((0 0 2, 5 0 2, 0 5 2, 0 0 2),(1 1 2, 1 3 2, 3 1 2, 1 1 2))' - ) -); - st_asewkt --------------------------------------------------------------- - POLYGON((0 0 2,0 5 2,5 0 2,0 0 2),(1 1 2,3 1 2,1 3 2,1 1 2)) -(1 row) - - - - See Also - - , - , - - - - - - - ST_LineMerge - - Returns a (set of) LineString(s) formed by sewing together - a MULTILINESTRING. - - - - - - geometry ST_LineMerge - geometry amultilinestring - - - - - - Description - - Returns a (set of) LineString(s) formed by sewing together - the constituent line work of a MULTILINESTRING. - Only use with MULTILINESTRING/LINESTRINGs. If you feed a polygon or geometry collection into this function, it - will return an empty GEOMETRYCOLLECTION - - Availability: 1.1.0 - requires GEOS >= 2.1.0 - - - - Examples - - SELECT ST_AsText(ST_LineMerge( -ST_GeomFromText('MULTILINESTRING((-29 -27,-30 -29.7,-36 -31,-45 -33),(-45 -33,-46 -32))') - ) -); -st_astext --------------------------------------------------------------------------------------------------- -LINESTRING(-29 -27,-30 -29.7,-36 -31,-45 -33,-46 -32) -(1 row) - ---If can't be merged - original MULTILINESTRING is returned -SELECT ST_AsText(ST_LineMerge( -ST_GeomFromText('MULTILINESTRING((-29 -27,-30 -29.7,-36 -31,-45 -33),(-45.2 -33.2,-46 -32))') -) -); -st_astext ----------------- -MULTILINESTRING((-45.2 -33.2,-46 -32),(-29 -27,-30 -29.7,-36 -31,-45 -33)) - - - - See Also - , - - - - - - ST_Multi - - Returns the geometry as a MULTI* geometry. If the geometry - is already a MULTI*, it is returned unchanged. - - - - - - geometry ST_Multi - geometry g1 - - - - - - Description - - Returns the geometry as a MULTI* geometry. If the geometry - is already a MULTI*, it is returned unchanged. - - - - - Examples - - SELECT ST_AsText(ST_Multi(ST_GeomFromText('POLYGON((743238 2967416,743238 2967450, - 743265 2967450,743265.625 2967416,743238 2967416))'))); - st_astext - -------------------------------------------------------------------------------------------------- - MULTIPOLYGON(((743238 2967416,743238 2967450,743265 2967450,743265.625 2967416, - 743238 2967416))) - (1 row) - - - - See Also - - - - - - - ST_RemovePoint - Removes point from a linestring. Offset is 0-based. - - - - - geometry ST_RemovePoint - geometry linestring - integer offset - - - - - - Description - - Removes point from a linestring. Useful for turning a closed ring into an open line string - Availability: 1.1.0 - - - - - - This function supports 3d and will not drop the z-index. - - - - Examples - ---guarantee no LINESTRINGS are closed ---by removing the end point. The below assumes the_geom is of type LINESTRING -UPDATE sometable - SET the_geom = ST_RemovePoint(the_geom, ST_NPoints(the_geom) - 1) - FROM sometable - WHERE ST_IsClosed(the_geom) = true; - - - - See Also - , , - - - - - - ST_Reverse - Returns the geometry with vertex order reversed. - - - - - - geometry ST_Reverse - geometry g1 - - - - - - Description - - Can be used on any geometry and reverses the order of the vertexes. - - - - Examples - -SELECT ST_AsText(the_geom) as line, ST_AsText(ST_Reverse(the_geom)) As reverseline -FROM -(SELECT ST_MakeLine(ST_MakePoint(1,2), - ST_MakePoint(1,10)) As the_geom) as foo; ---result - line | reverseline ----------------------+---------------------- -LINESTRING(1 2,1 10) | LINESTRING(1 10,1 2) - - - - - - - ST_Rotate - - This is a synonym for ST_RotateZ - - - - - - geometry ST_Rotate - geometry geomA - float rotZRadians - - - - - - Description - - This is a synonym for ST_RotateZ.. Rotates geometry rotZRadians about the Z-axis. - - Availability: 1.1.2. Name changed from Rotate to ST_Rotate in 1.2.2 - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - - - - - - See Also - - , , , - - - - - - ST_RotateX - - Rotate a geometry rotRadians about the X axis. - - - - - - geometry ST_RotateX - geometry geomA - float rotRadians - - - - - - Description - - Rotate a geometry geomA - rotRadians about the X axis. - - ST_RotateX(geomA, rotRadians) - is short-hand for ST_Affine(geomA, 1, 0, 0, 0, cos(rotRadians), -sin(rotRadians), 0, sin(rotRadians), cos(rotRadians), 0, 0, 0). - - Availability: 1.1.2. Name changed from RotateX to ST_RotateX in 1.2.2 - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - - ---Rotate a line 90 degrees along x-axis -SELECT ST_AsEWKT(ST_RotateX(ST_GeomFromEWKT('LINESTRING(1 2 3, 1 1 1)'), pi()/2)); - st_asewkt ---------------------------- - LINESTRING(1 -3 2,1 -1 1) - - - - - - See Also - - , , - - - - - - ST_RotateY - - Rotate a geometry rotRadians about the Y axis. - - - - - - geometry ST_RotateY - geometry geomA - float rotRadians - - - - - - Description - - Rotate a geometry geomA - rotRadians about the y axis. - - ST_RotateY(geomA, rotRadians) - is short-hand for ST_Affine(geomA, cos(rotRadians), 0, sin(rotRadians), 0, 1, 0, -sin(rotRadians), 0, cos(rotRadians), 0, 0, 0). - - Availability: 1.1.2. Name changed from RotateY to ST_RotateY in 1.2.2 - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - - ---Rotate a line 90 degrees along y-axis - SELECT ST_AsEWKT(ST_RotateY(ST_GeomFromEWKT('LINESTRING(1 2 3, 1 1 1)'), pi()/2)); - st_asewkt ---------------------------- - LINESTRING(3 2 -1,1 1 -1) - - - - - - See Also - - , , , Rotate around Point, Create Ellipse functions - - - - - - ST_RotateZ - - Rotate a geometry rotRadians about the Z axis. - - - - - - geometry ST_RotateZ - geometry geomA - float rotRadians - - - - - - Description - - Rotate a geometry geomA - rotRadians about the Z axis. - - ST_RotateZ(geomA, rotRadians) - is short-hand for SELECT ST_Affine(geomA, cos(rotRadians), -sin(rotRadians), 0, sin(rotRadians), cos(rotRadians), 0, 0, 0, 1, 0, 0, 0). - - Availability: 1.1.2. Name changed from RotateZ to ST_RotateZ in 1.2.2 - Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - - - Examples - - ---Rotate a line 90 degrees along z-axis -SELECT ST_AsEWKT(ST_RotateZ(ST_GeomFromEWKT('LINESTRING(1 2 3, 1 1 1)'), pi()/2)); - st_asewkt ---------------------------- - LINESTRING(-2 1 3,-1 1 1) - - --Rotate a curved circle around z-axis -SELECT ST_AsEWKT(ST_RotateZ(the_geom, pi()/2)) -FROM (SELECT ST_LineToCurve(ST_Buffer(ST_GeomFromText('POINT(234 567)'), 3)) As the_geom) As foo; - - st_asewkt ----------------------------------------------------------------------------------------------------------------------------- - CURVEPOLYGON(CIRCULARSTRING(-567 237,-564.87867965644 236.12132034356,-564 234,-569.12132034356 231.87867965644,-567 237)) - - - - - - - See Also - - , , , Rotate around Point, Create Ellipse functions - - - - - - ST_Scale - - Scales the geometry to a new size by multiplying the - ordinates with the parameters. Ie: ST_Scale(geom, Xfactor, Yfactor, - Zfactor). - - - - - - - geometry ST_Scale - geometry geomA - float XFactor - float YFactor - float ZFactor - - - - geometry ST_Scale - geometry geomA - float XFactor - float YFactor - - - - - - Description - - Scales the geometry to a new size by multiplying the - ordinates with the parameters. Ie: ST_Scale(geom, Xfactor, Yfactor, - Zfactor). - - ST_Scale(geomA, XFactor, YFactor, ZFactor) - is short-hand for ST_Affine(geomA, XFactor, 0, 0, 0, YFactor, 0, 0, 0, ZFactor, 0, 0, 0). - - Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ - - - Availability: 1.1.0. - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - --Version 1: scale X, Y, Z -SELECT ST_AsEWKT(ST_Scale(ST_GeomFromEWKT('LINESTRING(1 2 3, 1 1 1)'), 0.5, 0.75, 0.8)); - st_asewkt --------------------------------------- - LINESTRING(0.5 1.5 2.4,0.5 0.75 0.8) - ---Version 2: Scale X Y - SELECT ST_AsEWKT(ST_Scale(ST_GeomFromEWKT('LINESTRING(1 2 3, 1 1 1)'), 0.5, 0.75)); - st_asewkt ----------------------------------- - LINESTRING(0.5 1.5 3,0.5 0.75 1) - - - - - - - - See Also - - , - - - - - - ST_Segmentize - - Return a modified geometry having no segment longer than the - given distance. Distance computation is performed in 2d - only. - - - - - - geometry ST_Segmentize - geometry geomA - float max_length - - - - - - Description - - Returns a modified geometry having no segment longer than the - given distance. Distance computation is performed in 2d - only. - Availability: 1.2.2 - This will only increase segments. It will not lengthen segments shorter than - max length - - - - Examples - - SELECT ST_AsText(ST_Segmentize( -ST_GeomFromText('MULTILINESTRING((-29 -27,-30 -29.7,-36 -31,-45 -33),(-45 -33,-46 -32))') - ,5) -); -st_astext --------------------------------------------------------------------------------------------------- -MULTILINESTRING((-29 -27,-30 -29.7,-34.886615700134 -30.758766735029,-36 -31, --40.8809353009198 -32.0846522890933,-45 -33), -(-45 -33,-46 -32)) -(1 row) - -SELECT ST_AsText(ST_Segmentize(ST_GeomFromText('POLYGON((-29 28, -30 40, -29 28))'),10)); -st_astext ------------------------ -POLYGON((-29 28,-29.8304547985374 37.9654575824488,-30 40,-29.1695452014626 30.0345424175512,-29 28)) -(1 row) - - - - - See Also - - - - - - - ST_SetPoint - Replace point N of linestring with given point. Index is - 0-based. - - - - - geometry ST_SetPoint - geometry linestring - integer zerobasedposition - geometry point - - - - - - Description - - Replace point N of linestring with given point. Index is - 0-based. - This is especially useful in triggers when trying to maintain relationship of joints when one vertex moves. - Availability: 1.1.0 - - - - - - - This function supports 3d and will not drop the z-index. - - - - Examples - ---Change first point in line string from -1 3 to -1 1 -SELECT ST_AsText(ST_SetPoint('LINESTRING(-1 2,-1 3)', 0, 'POINT(-1 1)')); - st_astext ------------------------ - LINESTRING(-1 1,-1 3) - ----Change last point in a line string (lets play with 3d linestring this time) -SELECT ST_AsEWKT(ST_SetPoint(foo.the_geom, ST_NumPoints(foo.the_geom) - 1, ST_GeomFromEWKT('POINT(-1 1 3)'))) -FROM (SELECT ST_GeomFromEWKT('LINESTRING(-1 2 3,-1 3 4, 5 6 7)') As the_geom) As foo; - st_asewkt ------------------------ -LINESTRING(-1 2 3,-1 3 4,-1 1 3) - - - - See Also - ,, , - - - - - - ST_SetSRID - - Sets the SRID on a geometry to a particular integer - value. - - - - - - geometry ST_SetSRID - - geometry - geom - - integer - srid - - - - - - Description - - Sets the SRID on a geometry to a particular integer value. - Useful in constructing bounding boxes for queries. - - - This function does not transform the geometry is any way - - it simply sets the projection the geometry that it's currently in. - Use if you want to transform the - geometry into a new projection. - - - - - This method implements the - OpenGIS Simple - Features Implementation Specification for SQL. - - - - - - - - This method supports Circular Strings and Curves - - - - See Also - - , , , - - - - - - - ST_SnapToGrid - - Snap all points of the input geometry to the grid defined by - its origin and cell size. Remove consecutive points falling on the - same cell, eventually returning NULL if output points are not - enough to define a geometry of the given type. Collapsed - geometries in a collection are stripped from it. Useful for reducing precision. - - - - - - geometry ST_SnapToGrid - geometry geomA - float originX - float originY - float sizeX - float sizeY - - - - geometry ST_SnapToGrid - geometry geomA - float sizeX - float sizeY - - - - geometry ST_SnapToGrid - geometry geomA - float size - - - - geometry ST_SnapToGrid - geometry geomA - geometry pointOrigin - float sizeX - float sizeY - float sizeZ - float sizeM - - - - - - Description - - Variant 1,2,3: Snap all points of the input geometry to the grid defined by - its origin and cell size. Remove consecutive points falling on the - same cell, eventually returning NULL if output points are not - enough to define a geometry of the given type. Collapsed - geometries in a collection are stripped from it. - - - Variant 4: Introduced 1.1.0 - Snap all points of the input geometry to the grid defined by - its origin (the second argument, must be a point) and cell sizes. - Specify 0 as size for any dimension you don't want to snap to a - grid. - - - The returned geometry might loose its simplicity (see - ). - - - - Before release 1.1.0 this function always returned a 2d - geometry. Starting at 1.1.0 the returned geometry will have same - dimensionality as the input one with higher dimension values - untouched. Use the version taking a second geometry argument to - define all grid dimensions. - - - Availability: 1.0.0RC1 - Availability: 1.1.0 - Z and M support - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - - ---Snap your geometries to a precision grid of 10^-3 -UPDATE mytable - SET the_geom = ST_SnapToGrid(the_geom, 0.001); - -SELECT ST_AsText(ST_SnapToGrid( - ST_GeomFromText('LINESTRING(1.1115678 2.123, 4.111111 3.2374897, 4.11112 3.23748667)'), - 0.001) - ); - st_astext -------------------------------------- - LINESTRING(1.112 2.123,4.111 3.237) - --Snap a 4d geometry -SELECT ST_AsEWKT(ST_SnapToGrid( - ST_GeomFromEWKT('LINESTRING(-1.1115678 2.123 2.3456 1.11111, - 4.111111 3.2374897 3.1234 1.1111, -1.11111112 2.123 2.3456 1.1111112)'), - ST_GeomFromEWKT('POINT(1.12 2.22 3.2 4.4444)'), - 0.1, 0.1, 0.1, 0.01) ); - st_asewkt ------------------------------------------------------------------------------- - LINESTRING(-1.08 2.12 2.3 1.1144,4.12 3.22 3.1 1.1144,-1.08 2.12 2.3 1.1144) - - ---With a 4d geometry - the ST_SnapToGrid(geom,size) only touches x and y coords but keeps m and z the same -SELECT ST_AsEWKT(ST_SnapToGrid(ST_GeomFromEWKT('LINESTRING(-1.1115678 2.123 3 2.3456, - 4.111111 3.2374897 3.1234 1.1111)'), - 0.01) ); - st_asewkt ---------------------------------------------------------- - LINESTRING(-1.11 2.12 3 2.3456,4.11 3.24 3.1234 1.1111) - - - - - - - See Also - - , , , , - - - - - - ST_Transform - - Returns a new geometry with its coordinates transformed to - the SRID referenced by the integer parameter. - - - - - - geometry ST_Transform - geometry g1 - integer srid - - - - - - Description - - Returns a new geometry with its coordinates transformed to - spatial reference system referenced by the SRID integer parameter. The destination SRID - must exist in the SPATIAL_REF_SYS table. - ST_Transform is often confused with ST_SetSRID(). ST_Transform actually changes the coordinates - of a geometry from one spatial reference system to another, while ST_SetSRID() simply changes the SRID identifier of - the geometry - - - Requires PostGIS be compiled with Proj support. Use to confirm you have proj support compiled in. - - - - If using more than one transformation, it is useful to have a functional index on the commonly used - transformations to take advantage of index usage. - - - Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.6 - - - - - - - This method supports Circular Strings and Curves - - - - Examples - Change Mass state plane US feet geometry to WGS 84 long lat - -SELECT ST_AsText(ST_Transform(ST_GeomFromText('POLYGON((743238 2967416,743238 2967450, - 743265 2967450,743265.625 2967416,743238 2967416))',2249),4326)) As wgs_geom; - - wgs_geom ---------------------------- - POLYGON((-71.1776848522251 42.3902896512902,-71.1776843766326 42.3903829478009, --71.1775844305465 42.3903826677917,-71.1775825927231 42.3902893647987,-71.177684 -8522251 42.3902896512902)); -(1 row) - ---3D Circular String example -SELECT ST_AsEWKT(ST_Transform(ST_GeomFromEWKT('SRID=2249;CIRCULARSTRING(743238 2967416 1,743238 2967450 2,743265 2967450 3,743265.625 2967416 3,743238 2967416 4)'),4326)); - - st_asewkt --------------------------------------------------------------------------------------- - SRID=4326;CIRCULARSTRING(-71.1776848522251 42.3902896512902 1,-71.1776843766326 42.3903829478009 2, - -71.1775844305465 42.3903826677917 3, - -71.1775825927231 42.3902893647987 3,-71.1776848522251 42.3902896512902 4) - - - Example of creating a partial functional index. For tables where you are not sure all the geometries - will be filled in, its best to use a partial index that leaves out null geometries which will both conserve space and make your index smaller and more efficient. - -CREATE INDEX idx_the_geom_26986_parcels - ON parcels - USING gist - (ST_Transform(the_geom, 26986)) - WHERE the_geom IS NOT NULL; - - - - - Configuring transformation behaviour - Sometimes coordinate transformation involving a grid-shift can fail, for example if PROJ.4 has not been built with grid-shift files or the coordinate does not lie within the range for which the grid shift is defined. By default, PostGIS will throw an error if a grid shift file is not present, but this behaviour can be configured on a per-SRID basis by altering the proj4text value within the spatial_ref_sys table. - For example, the proj4text parameter +datum=NAD87 is a shorthand form for the following +nadgrids parameter: - +nadgrids=@conus,@alaska,@ntv2_0.gsb,@ntv1_can.dat - The @ prefix means no error is reported if the files are not present, but if the end of the list is reached with no file having been appropriate (ie. found and overlapping) then an error is issued. - If, conversely, you wanted to ensure that at least the standard files were present, but that if all files were scanned without a hit a null transformation is applied you could use: - +nadgrids=@conus,@alaska,@ntv2_0.gsb,@ntv1_can.dat,null - The null grid shift file is a valid grid shift file covering the whole world and applying no shift. So for a complete example, if you wanted to alter PostGIS so that transformations to SRID 4267 that didn't lie within the correct range did not throw an ERROR, you would use the following: - UPDATE spatial_ref_sys SET proj4text = '+proj=longlat +ellps=clrk66 +nadgrids=@conus,@alaska,@ntv2_0.gsb,@ntv1_can.dat,null +no_defs' WHERE srid = 4267; - - - - - See Also - - , , , - - - - - - ST_Translate - - Translates the geometry to a new location using the numeric - parameters as offsets. Ie: ST_Translate(geom, X, Y) or ST_Translate(geom, X, Y,Z). - - - - - - geometry ST_Translate - geometry g1 - float deltax - float deltay - - - geometry ST_Translate - geometry g1 - float deltax - float deltay - float deltaz - - - - - - Description - - Returns a new geometry whose coordinates are translated delta x,delta y,delta z units. Units are - based on the units defined in spatial reference (SRID) for this geometry. - - Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ - - Availability: 1.2.2 - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - Examples - Move a point 1 degree longitude - - SELECT ST_AsText(ST_Translate(ST_GeomFromText('POINT(-71.01 42.37)',4326),1,0)) As wgs_transgeomtxt; - - wgs_transgeomtxt - --------------------- - POINT(-70.01 42.37) - - Move a linestring 1 degree longitude and 1/2 degree latitude - SELECT ST_AsText(ST_Translate(ST_GeomFromText('LINESTRING(-71.01 42.37,-71.11 42.38)',4326),1,0.5)) As wgs_transgeomtxt; - wgs_transgeomtxt - --------------------------------------- - LINESTRING(-70.01 42.87,-70.11 42.88) - - Move a 3d point - SELECT ST_AsEWKT(ST_Translate(CAST('POINT(0 0 0)' As geometry), 5, 12,3)); - st_asewkt - --------- - POINT(5 12 3) - - Move a curve and a point -SELECT ST_AsText(ST_Translate(ST_Collect('CURVEPOLYGON(CIRCULARSTRING(4 3,3.12 0.878,1 0,-1.121 5.1213,6 7, 8 9,4 3))','POINT(1 3)'),1,2)); - st_astext ------------------------------------------------------------------------------------------------------------- - GEOMETRYCOLLECTION(CURVEPOLYGON(CIRCULARSTRING(5 5,4.12 2.878,2 2,-0.121 7.1213,7 9,9 11,5 5)),POINT(2 5)) - - - - - - See Also - , , - - - - - - ST_TransScale - - Translates the geometry using the deltaX and deltaY args, - then scales it using the XFactor, YFactor args, working in 2D only. - - - - - - - geometry ST_TransScale - geometry geomA - float deltaX - float deltaY - float XFactor - float YFactor - - - - - - Description - - Translates the geometry using the deltaX and deltaY args, - then scales it using the XFactor, YFactor args, working in 2D only. - - ST_TransScale(geomA, deltaX, deltaY, XFactor, YFactor) - is short-hand for ST_Affine(geomA, XFactor, 0, 0, 0, YFactor, 0, - 0, 0, 1, deltaX*XFactor, deltaY*YFactor, 0). - - Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ - - - Availability: 1.1.0. - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - SELECT ST_AsEWKT(ST_TransScale(ST_GeomFromEWKT('LINESTRING(1 2 3, 1 1 1)'), 0.5, 1, 1, 2)); - st_asewkt ------------------------------ - LINESTRING(1.5 6 3,1.5 4 1) - - ---Buffer a point to get an approximation of a circle, convert to curve and then translate 1,2 and scale it 3,4 - SELECT ST_AsText(ST_Transscale(ST_LineToCurve(ST_Buffer('POINT(234 567)', 3)),1,2,3,4)); - st_astext ------------------------------------------------------------------------------------------------------------------------------- - CURVEPOLYGON(CIRCULARSTRING(714 2276,711.363961030679 2267.51471862576,705 2264,698.636038969321 2284.48528137424,714 2276)) - - - - - - - See Also - - , - - - - - - - - - Geometry Outputs - - - ST_AsBinary - Return the Well-Known Binary (WKB) representation of the geometry/geography without SRID meta data. - - - - - - bytea ST_AsBinary - geometry g1 - - - bytea ST_AsBinary - geography g1 - - - bytea ST_AsBinary - geometry g1 - text NDR_or_XDR - - - - - - Description - - Returns the Well-Known Binary representation of the geometry. There are 2 variants of the function. The first - variant takes no endian encoding paramater and defaults to little endian. The second variant takes a second argument - denoting the encoding - using little-endian ('NDR') or big-endian ('XDR') encoding. - This is useful in binary cursors to pull data out of the - database without converting it to a string representation. - - - The WKB spec does not include the SRID. To get the OGC WKB with SRID format use ST_AsEWKB - - - ST_AsBinary is the reverse of for geometry. Use to convert to a postgis geometry from ST_AsBinary representation. - - - Availability: 1.5.0 geography support was introduced. - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC s2.1.1.1 - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.37 - - - - - - - Examples - - SELECT ST_AsBinary(ST_GeomFromText('POLYGON((0 0,0 1,1 1,1 0,0 0))',4326)); - - st_asbinary --------------------------------- -\001\003\000\000\000\001\000\000\000\005 -\000\000\000\000\000\000\000\000\000\000 -\000\000\000\000\000\000\000\000\000\000 -\000\000\000\000\000\000\000\000\000\000 -\000\000\000\360?\000\000\000\000\000\000 -\360?\000\000\000\000\000\000\360?\000\000 -\000\000\000\000\360?\000\000\000\000\000 -\000\000\000\000\000\000\000\000\000\000\000 -\000\000\000\000\000\000\000\000 -(1 row) - SELECT ST_AsBinary(ST_GeomFromText('POLYGON((0 0,0 1,1 1,1 0,0 0))',4326), 'XDR'); - st_asbinary --------------------------------- -\000\000\000\000\003\000\000\000\001\000\000\000\005\000\000\000\000\000 -\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000 -\000?\360\000\000\000\000\000\000?\360\000\000\000\000\000\000?\360\000\000 -\000\000\000\000?\360\000\000\000\000\000\000\000\000\000\000\000\000\000\000 -\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000 -(1 row) - - - - - See Also - , , , - - - - - ST_AsEWKB - Return the Well-Known Binary (WKB) representation of the geometry with SRID meta data. - - - - - - bytea ST_AsEWKB - geometry g1 - - - bytea ST_AsEWKB - geometry g1 - text NDR_or_XDR - - - - - - Description - Returns the Well-Known Binary representation of the geometry with SRID metadata. There are 2 variants of the function. The first - variant takes no endian encoding paramater and defaults to little endian. The second variant takes a second argument - denoting the encoding - using little-endian ('NDR') or big-endian ('XDR') encoding. - This is useful in binary cursors to pull data out of the - database without converting it to a string representation. - - The WKB spec does not include the SRID. To get the OGC WKB format use ST_AsBinary - - - ST_AsEWKB is the reverse of ST_GeomFromEWKB. Use ST_GeomFromEWKB to convert to a postgis geometry from ST_AsEWKB representation. - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - SELECT ST_AsEWKB(ST_GeomFromText('POLYGON((0 0,0 1,1 1,1 0,0 0))',4326)); - - st_asewkb --------------------------------- -\001\003\000\000 \346\020\000\000\001\000 -\000\000\005\000\000\000\000 -\000\000\000\000\000\000\000\000 -\000\000\000\000\000\000\000\000\000 -\000\000\000\000\000\000\000\000\000\000 -\000\000\360?\000\000\000\000\000\000\360? -\000\000\000\000\000\000\360?\000\000\000\000\000 -\000\360?\000\000\000\000\000\000\000\000\000\000\000 -\000\000\000\000\000\000\000\000\000\000\000\000\000 -(1 row) - - SELECT ST_AsEWKB(ST_GeomFromText('POLYGON((0 0,0 1,1 1,1 0,0 0))',4326), 'XDR'); - st_asewkb --------------------------------- -\000 \000\000\003\000\000\020\346\000\000\000\001\000\000\000\005\000\000\000\000\ -000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000? -\360\000\000\000\000\000\000?\360\000\000\000\000\000\000?\360\000\000\000\000 -\000\000?\360\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000 -\000\000\000\000\000\000\000\000\000\000\000\000\000 - - - - - - See Also - , , , , - - - - - ST_AsEWKT - Return the Well-Known Text (WKT) representation of the geometry with SRID meta data. - - - - - - text ST_AsEWKT - geometry g1 - - - - - - Description - - Returns the Well-Known Text representation of the geometry prefixed with the SRID. - - - The WKT spec does not include the SRID. To get the OGC WKT format use ST_AsText - - - WKT format does not maintain precision so to prevent floating truncation, use ST_AsBinary or ST_AsEWKB format for transport. - - - ST_AsEWKT is the reverse of . Use to convert to a postgis geometry from ST_AsEWKT representation. - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - SELECT ST_AsEWKT('0103000020E61000000100000005000000000000 - 000000000000000000000000000000000000000000000000000000 - F03F000000000000F03F000000000000F03F000000000000F03 - F000000000000000000000000000000000000000000000000'::geometry); - - st_asewkt --------------------------------- -SRID=4326;POLYGON((0 0,0 1,1 1,1 0,0 0)) -(1 row) - -SELECT ST_AsEWKT('0108000080030000000000000060E30A4100000000785C0241000000000000F03F0000000018 -E20A4100000000485F024100000000000000400000000018 -E20A4100000000305C02410000000000000840') - ---st_asewkt--- -CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3) - - - - - - See Also - , - - - - - ST_AsGeoJSON - - Return the geometry as a GeoJSON element. - - - - - - text ST_AsGeoJSON - geometry g1 - - - text ST_AsGeoJSON - geography g1 - - - text ST_AsGeoJSON - geometry g1 - integer max_decimal_digits - - - text ST_AsGeoJSON - geography g1 - integer max_decimal_digits - - - text ST_AsGeoJSON - geometry g1 - integer max_decimal_digits - integer options - - - text ST_AsGeoJSON - geography g1 - integer max_decimal_digits - integer options - - - text ST_AsGeoJSON - integer version - geometry g1 - - - text ST_AsGeoJSON - integer version - geography g1 - - - text ST_AsGeoJSON - integer version - geometry g1 - integer max_decimal_digits - - - text ST_AsGeoJSON - integer version - geography g1 - integer max_decimal_digits - - - text ST_AsGeoJSON - integer version - geometry g1 - integer max_decimal_digits - integer options - - - text ST_AsGeoJSON - integer version - geography g1 - integer max_decimal_digits - integer options - - - - - - Description - - Return the geometry as a Geometry Javascript Object Notation (GeoJSON) element. (Cf GeoJSON - specifications 1.0). 2D and 3D Geometries are both - supported. GeoJSON only support SFS 1.1 geometry type (no curve - support for example). - - The version parameter, if specified, must be 1. - - The third argument may be used to reduce the maximum number - of decimal places used in output (defaults to 15). - - The last 'options' argument could be used to add Bbox or Crs - in GeoJSON output: - - - 0: means no option (default value) - - - - 1: GeoJSON Bbox - - - - 2: GeoJSON Short CRS (e.g EPSG:4326) - - - - 4: GeoJSON Long CRS (e.g urn:ogc:def:crs:EPSG:4326) - - - - Version 1: ST_AsGeoJSON(geom) / precision=15 version=1 options=0 - Version 2: ST_AsGeoJSON(geom, precision) / version=1 options=0 - Version 3: ST_AsGeoJSON(geom, precision, options) / version=1 - Version 4: ST_AsGeoJSON(version, geom) / precision=15 options=0 - Version 5: ST_AsGeoJSON(version, geom, precision) /options=0 - Version 6: ST_AsGeoJSON(version, geom, precision,options) - - Availability: 1.3.4 - Availability: 1.5.0 geography support was introduced. - - - - - - This function supports 3d and will not drop the z-index. - - - - Examples - GeoJSON format is generally more efficient than other formats for use in ajax mapping. - One popular javascript client that supports this is Open Layers. - Example of its use is OpenLayers GeoJSON Example - - SELECT ST_AsGeoJSON(the_geom) from fe_edges limit 1; - st_asgeojson ------------------------------------------------------------------------------------------------------------ - -{"type":"MultiLineString","coordinates":[[[-89.734634999999997,31.492072000000000], -[-89.734955999999997,31.492237999999997]]]} -(1 row) ---3d point -SELECT ST_AsGeoJSON('LINESTRING(1 2 3, 4 5 6)'); - -st_asgeojson ------------------------------------------------------------------------------------------ - {"type":"LineString","coordinates":[[1,2,3],[4,5,6]]} - - - - - - - ST_AsGML - Return the geometry as a GML version 2 or 3 element. - - - - - - text ST_AsGML - geometry g1 - - - text ST_AsGML - geography g1 - - - text ST_AsGML - geometry g1 - integer precision - - - text ST_AsGML - geography g1 - integer precision - - - text ST_AsGML - integer version - geometry g1 - - - text ST_AsGML - integer version - geography g1 - - - text ST_AsGML - integer version - geometry g1 - integer precision - - - text ST_AsGML - integer version - geography g1 - integer precision - - - text ST_AsGML - integer version - geometry g1 - integer precision - integer options - - - text ST_AsGML - integer version - geography g1 - integer precision - integer options - - - - - - Description - - Return the geometry as a Geography Markup Language (GML) element. The version parameter, - if specified, may be either 2 or 3. If no version parameter is - specified then the default is assumed to be 2. The third argument - may be used to reduce the maximum number of decimal places - used in output (defaults to 15). - GML 2 refer to 2.1.2 version, GML 3 to 3.1.1 version - The last 'options' argument is a bitfield. It could be used to define CRS output type - in GML output, and to declare data as lat/lon: - - - 0: GML Short CRS (e.g EPSG:4326), default value - - - - 1: GML Long CRS (e.g urn:ogc:def:crs:EPSG:4326) - - - - 16: Declare that datas are lat/lon (e.g srid=4326). Default is to assume that data are planars. This option is usefull for GML 3.1.1 output only, related to axis order. - - - - - - - - Availability: 1.3.2 - Availability: 1.5.0 geography support was introduced. - - - - - - - - This function supports 3d and will not drop the z-index. - - - - Examples - 0,0 0,1 1,1 1,0 0,0]]> - - 6.34535 5.23423]]> - - - - - - See Also - - - - - - - - - ST_AsHEXEWKB - - Returns a Geometry in HEXEWKB format (as text) using either - little-endian (NDR) or big-endian (XDR) encoding. - - - - - - text ST_AsHEXEWKB - geometry g1 - text NDRorXDR - - - - text ST_AsHEXEWKB - geometry g1 - - - - - - Description - - Returns a Geometry in HEXEWKB format (as text) using either - little-endian (NDR) or big-endian (XDR) encoding. If no encoding is specified, then NDR is used. - - - Availability: 1.2.2 - - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - This method supports Circular Strings and Curves - - - - Examples - SELECT ST_AsHEXEWKB(ST_GeomFromText('POLYGON((0 0,0 1,1 1,1 0,0 0))',4326)); - which gives same answer as - - SELECT ST_GeomFromText('POLYGON((0 0,0 1,1 1,1 0,0 0))',4326)::text; - - st_ashexewkb - -------- - 0103000020E6100000010000000500 - 00000000000000000000000000000000 - 00000000000000000000000000000000F03F - 000000000000F03F000000000000F03F000000000000F03 - F000000000000000000000000000000000000000000000000 - - - - - - ST_AsKML - - Return the geometry as a KML element. Several variants. Default version=2, default precision=15 - - - - - - text ST_AsKML - geometry g1 - - - text ST_AsKML - geography g1 - - - text ST_AsKML - geometry g1 - integer precision - - - text ST_AsKML - geography g1 - integer precision - - - text ST_AsKML - integer version - geometry geom1 - - - text ST_AsKML - integer version - geography geom1 - - - text ST_AsKML - integer version - geometry geom1 - integer precision - - - text ST_AsKML - integer version - geography geom1 - integer precision - - - - - - Description - - Return the geometry as a Keyhole Markup Language (KML) element. There are several variants of this function. - maximum number of decimal places used in - output (defaults to 15) and version default to 2. - - Version 1: ST_AsKML(geom) / version=2 precision=15 - Version 2: ST_AsKML(geom, max_sig_digits) / version=2 - Version 3: ST_AsKML(version, geom) / precision=15 - Version 4: ST_AsKML(version, geom, precision) - - - Requires PostGIS be compiled with Proj support. Use to confirm you have proj support compiled in. - - - - Availability: 1.2.2 - later variants that include version param came in 1.3.2 - - - - AsKML output will not work with geometries that do not have an SRID - - - - - - - - This function supports 3d and will not drop the z-index. - - - - Examples - 0,0 0,1 1,1 1,0 0,0 - - --3d linestring - SELECT ST_AsKML('SRID=4326;LINESTRING(1 2 3, 4 5 6)'); - 1,2,3 4,5,6 - ]]> - - - - See Also - - , - - - - - ST_AsSVG - - Returns a Geometry in SVG path data given a geometry or geography object. - - - - - - text ST_AsSVG - geometry g1 - - - text ST_AsSVG - geography g1 - - - text ST_AsSVG - geometry g1 - integer rel - - - text ST_AsSVG - geography g1 - integer rel - - - text ST_AsSVG - geometry g1 - integer rel - integer maxdecimaldigits - - - text ST_AsSVG - geography g1 - integer rel - integer maxdecimaldigits - - - - - - Description - - Return the geometry as Scalar Vector Graphics (SVG) path data. Use 1 as second - argument to have the path data implemented in terms of relative - moves, the default (or 0) uses absolute moves. Third argument may - be used to reduce the maximum number of decimal digits used in - output (defaults to 15). Point geometries will be rendered as - cx/cy when 'rel' arg is 0, x/y when 'rel' is 1. Multipoint - geometries are delimited by commas (","), GeometryCollection - geometries are delimited by semicolons (";"). - - - Availability: 1.2.2 . Availability: 1.4.0 Changed in PostGIS 1.4.0 to include L command in absolute path to conform to http://www.w3.org/TR/SVG/paths.html#PathDataBNF - - - - - Examples - SELECT ST_AsSVG(ST_GeomFromText('POLYGON((0 0,0 1,1 1,1 0,0 0))',4326)); - - st_assvg - -------- - M 0 0 L 0 -1 1 -1 1 0 Z - - - - - - - ST_GeoHash - - Return a GeoHash representation (geohash.org) of the geometry. - - - - - - text ST_GeoHash - geometry g1 - - - text ST_GeoHash - geometry g1 - integer precision - - - - - - Description - - Return a GeoHash representation (geohash.org) of the geometry. A GeoHash encodes a point into a text form that is sortable and searchable based on prefixing. A shorter GeoHash is a less precise representation of a point. It can also be thought of as a box, that contains the actual point. - - The one-parameter variant of ST_GeoHash returns a GeoHash based on the input geometry type. Points return a GeoHash with 20 characters of precision (about enough to hold the full double precision of the input). Other types return a GeoHash with a variable amount of precision, based on the size of the feature. Larger features are represented with less precision, smaller features with more precision. The idea is that the box implied by the GeoHash will always contain the input feature. - - The two-parameter variant of ST_GeoHash returns a GeoHash with a requested precision. For non-points, the starting point of the calculation is the center of the bounding box of the geometry. - - Availability: 1.4.0 - - - ST_GeoHash will not work with geometries that are not in geographic (lon/lat) coordinates. - - - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - - - - See Also - - - - - - - - - ST_AsText - Return the Well-Known Text (WKT) representation of the geometry/geography without SRID metadata. - - - - - - text ST_AsText - geometry g1 - - - text ST_AsText - geography g1 - - - - - - Description - - Returns the Well-Known Text representation of the geometry/geography. - - - The WKT spec does not include the SRID. To get the SRID as part of the data, use the non-standard - PostGIS - - - WKT format does not maintain precision so to prevent floating truncation, use ST_AsBinary or ST_AsEWKB format for transport. - - - ST_AsText is the reverse of . Use to convert to a postgis geometry from ST_AsText representation. - - - Availability: 1.5 - support for geography was introduced. - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC s2.1.1.1 - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.25 - - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - SELECT ST_AsText('01030000000100000005000000000000000000 -000000000000000000000000000000000000000000000000 -F03F000000000000F03F000000000000F03F000000000000F03 -F000000000000000000000000000000000000000000000000'); - - st_astext --------------------------------- - POLYGON((0 0,0 1,1 1,1 0,0 0)) -(1 row) - - - - - See Also - - , , , - - - - - - - Operators - - - && - - Returns TRUE if A's bounding box overlaps B's. - - - - - - - boolean && - - - geometry - - A - - - - geometry - - B - - - - boolean && - - - geography - - A - - - - geography - - B - - - - - - - Description - - The && operator returns TRUE if the bounding box of geometry A overlaps the bounding box of geometry B. - - This operand will make use of any indexes that may be available on the - geometries. - - Availability: 1.5.0 support for geography was introduced. - - - - Examples - - SELECT tbl1.column1, tbl2.column1, tbl1.column2 && tbl2.column2 AS overlaps -FROM ( VALUES - (1, 'LINESTRING(0 0, 3 3)'::geometry), - (2, 'LINESTRING(0 1, 0 5)'::geometry)) AS tbl1, -( VALUES - (3, 'LINESTRING(1 2, 4 6)'::geometry)) AS tbl2; - - column1 | column1 | overlaps ----------+---------+---------- - 1 | 3 | t - 2 | 3 | f -(2 rows) - - - - - See Also - - - , - , - , - , - , - - - - - - - &< - - Returns TRUE if A's bounding box overlaps or is to the left of B's. - - - - - - - boolean &< - - - geometry - - A - - - - geometry - - B - - - - - - - Description - - The &< operator returns TRUE if the bounding box of geometry A - overlaps or is to the left of the bounding box of geometry B, or more accurately, overlaps or is NOT to the right - of the bounding box of geometry B. - - This operand will make use of any indexes that may be available on the - geometries. - - - - Examples - - SELECT tbl1.column1, tbl2.column1, tbl1.column2 &< tbl2.column2 AS overleft -FROM - ( VALUES - (1, 'LINESTRING(1 2, 4 6)'::geometry)) AS tbl1, - ( VALUES - (2, 'LINESTRING(0 0, 3 3)'::geometry), - (3, 'LINESTRING(0 1, 0 5)'::geometry), - (4, 'LINESTRING(6 0, 6 1)'::geometry)) AS tbl2; - - column1 | column1 | overleft ----------+---------+---------- - 1 | 2 | f - 1 | 3 | f - 1 | 4 | t -(3 rows) - - - - See Also - - - , - , - , - - - - - - - &<| - - Returns TRUE if A's bounding box overlaps or is below B's. - - - - - - - boolean &<| - - - geometry - - A - - - - geometry - - B - - - - - - - Description - - The &<| operator returns TRUE if the bounding box of geometry A - overlaps or is below of the bounding box of geometry B, or more accurately, overlaps or is NOT above the bounding - box of geometry B. - - This operand will make use of any indexes that may be available on the - geometries. - - - - Examples - - SELECT tbl1.column1, tbl2.column1, tbl1.column2 &<| tbl2.column2 AS overbelow -FROM - ( VALUES - (1, 'LINESTRING(6 0, 6 4)'::geometry)) AS tbl1, - ( VALUES - (2, 'LINESTRING(0 0, 3 3)'::geometry), - (3, 'LINESTRING(0 1, 0 5)'::geometry), - (4, 'LINESTRING(1 2, 4 6)'::geometry)) AS tbl2; - - column1 | column1 | overbelow ----------+---------+----------- - 1 | 2 | f - 1 | 3 | t - 1 | 4 | t -(3 rows) - - - - See Also - - - , - , - , - - - - - - - &> - - Returns TRUE if A' bounding box overlaps or is to the right of B's. - - - - - - - boolean &> - - - geometry - - A - - - - geometry - - B - - - - - - - Description - - The &> operator returns TRUE if the bounding box of geometry A - overlaps or is to the right of the bounding box of geometry B, or more accurately, overlaps or is NOT to the left - of the bounding box of geometry B. - - This operand will make use of any indexes that may be available on the - geometries. - - - - Examples - - SELECT tbl1.column1, tbl2.column1, tbl1.column2 &> tbl2.column2 AS overright -FROM - ( VALUES - (1, 'LINESTRING(1 2, 4 6)'::geometry)) AS tbl1, - ( VALUES - (2, 'LINESTRING(0 0, 3 3)'::geometry), - (3, 'LINESTRING(0 1, 0 5)'::geometry), - (4, 'LINESTRING(6 0, 6 1)'::geometry)) AS tbl2; - - column1 | column1 | overright ----------+---------+----------- - 1 | 2 | t - 1 | 3 | t - 1 | 4 | f -(3 rows) - - - - See Also - - - , - , - , - - - - - - - << - - Returns TRUE if A's bounding box is strictly to the left of B's. - - - - - - - boolean << - - - geometry - - A - - - - geometry - - B - - - - - - - Description - - The << operator returns TRUE if the bounding box of geometry A - is strictly to the left of the bounding box of geometry B. - - This operand will make use of any indexes that may be available on the - geometries. - - - - Examples - - SELECT tbl1.column1, tbl2.column1, tbl1.column2 << tbl2.column2 AS left -FROM - ( VALUES - (1, 'LINESTRING (1 2, 1 5)'::geometry)) AS tbl1, - ( VALUES - (2, 'LINESTRING (0 0, 4 3)'::geometry), - (3, 'LINESTRING (6 0, 6 5)'::geometry), - (4, 'LINESTRING (2 2, 5 6)'::geometry)) AS tbl2; - - column1 | column1 | left ----------+---------+------ - 1 | 2 | f - 1 | 3 | t - 1 | 4 | t -(3 rows) - - - - See Also - - , , - - - - - - <<| - - Returns TRUE if A's bounding box is strictly below B's. - - - - - - - boolean <<| - - - geometry - - A - - - - geometry - - B - - - - - - - Description - - The <<| operator returns TRUE if the bounding box of geometry A - is strictly below the bounding box of geometry B. - - This operand will make use of any indexes that may be available on the - geometries. - - - - Examples - - SELECT tbl1.column1, tbl2.column1, tbl1.column2 <<| tbl2.column2 AS below -FROM - ( VALUES - (1, 'LINESTRING (0 0, 4 3)'::geometry)) AS tbl1, - ( VALUES - (2, 'LINESTRING (1 4, 1 7)'::geometry), - (3, 'LINESTRING (6 1, 6 5)'::geometry), - (4, 'LINESTRING (2 3, 5 6)'::geometry)) AS tbl2; - - column1 | column1 | below ----------+---------+------- - 1 | 2 | t - 1 | 3 | f - 1 | 4 | f -(3 rows) - - - - See Also - - , , - - - - - - = - - Returns TRUE if A's bounding box is the same as B's. - - - - - - - boolean = - - - geometry - - A - - - - geometry - - B - - - - - - - Description - - The = operator returns TRUE if the bounding box of geometry A - is the same as the bounding box of geometry B. PostgreSQL uses the =, <, and > operators defined for geometries to - perform internal orderings and comparison of geometries (ie. in a GROUP BY or ORDER BY clause). - - - This is cause for a lot of confusion. When you compare geometryA = - geometryB it will return true even when the geometries are clearly - different IF their bounding boxes are the same. To check for true - equality use or - - - This operand will NOT make use of any indexes that may be available on the - geometries. - - - - - Examples - - SELECT 'LINESTRING(0 0, 0 1, 1 0)'::geometry = 'LINESTRING(1 1, 0 0)'::geometry; - ?column? ----------- - t -(1 row) - -SELECT ST_AsText(column1) -FROM ( VALUES - ('LINESTRING(0 0, 1 1)'::geometry), - ('LINESTRING(1 1, 0 0)'::geometry)) AS foo; - st_astext ---------------------- - LINESTRING(0 0,1 1) - LINESTRING(1 1,0 0) -(2 rows) - --- Note: the GROUP BY uses the "=" to compare for geometry equivalency. -SELECT ST_AsText(column1) -FROM ( VALUES - ('LINESTRING(0 0, 1 1)'::geometry), - ('LINESTRING(1 1, 0 0)'::geometry)) AS foo -GROUP BY column1; - st_astext ---------------------- - LINESTRING(0 0,1 1) -(1 row) - - - - See Also - - , , - - - - - - - >> - - Returns TRUE if A's bounding box is strictly to the right of B's. - - - - - - - boolean >> - - - geometry - - A - - - - geometry - - B - - - - - - - Description - - The >> operator returns TRUE if the bounding box of geometry A - is strictly to the right of the bounding box of geometry B. - - This operand will make use of any indexes that may be available on the - geometries. - - - - Examples - - SELECT tbl1.column1, tbl2.column1, tbl1.column2 >> tbl2.column2 AS right -FROM - ( VALUES - (1, 'LINESTRING (2 3, 5 6)'::geometry)) AS tbl1, - ( VALUES - (2, 'LINESTRING (1 4, 1 7)'::geometry), - (3, 'LINESTRING (6 1, 6 5)'::geometry), - (4, 'LINESTRING (0 0, 4 3)'::geometry)) AS tbl2; - - column1 | column1 | right ----------+---------+------- - 1 | 2 | t - 1 | 3 | f - 1 | 4 | f -(3 rows) - - - - See Also - - , , - - - - - - @ - - Returns TRUE if A's bounding box is contained by B's. - - - - - - - boolean ~= - - - geometry - - A - - - - geometry - - B - - - - - - - Description - - The @ operator returns TRUE if the bounding box of geometry A is completely - contained by the bounding box of geometry B. - - - This operand will make use of any indexes that may be available on the - geometries. - - - - - Examples - - SELECT tbl1.column1, tbl2.column1, tbl1.column2 @ tbl2.column2 AS contained -FROM - ( VALUES - (1, 'LINESTRING (1 1, 3 3)'::geometry)) AS tbl1, - ( VALUES - (2, 'LINESTRING (0 0, 4 4)'::geometry), - (3, 'LINESTRING (2 2, 4 4)'::geometry), - (4, 'LINESTRING (1 1, 3 3)'::geometry)) AS tbl2; - - column1 | column1 | contained ----------+---------+----------- - 1 | 2 | t - 1 | 3 | f - 1 | 4 | t -(3 rows) - - - - See Also - - , - - - - - - |&> - - Returns TRUE if A's bounding box overlaps or is above B's. - - - - - - - boolean |&> - - - geometry - - A - - - - geometry - - B - - - - - - - Description - - The |&> operator returns TRUE if the bounding box of geometry A - overlaps or is above the bounding box of geometry B, or more accurately, overlaps or is NOT below - the bounding box of geometry B. - - This operand will make use of any indexes that may be available on the - geometries. - - - - Examples - - SELECT tbl1.column1, tbl2.column1, tbl1.column2 |&> tbl2.column2 AS overabove -FROM - ( VALUES - (1, 'LINESTRING(6 0, 6 4)'::geometry)) AS tbl1, - ( VALUES - (2, 'LINESTRING(0 0, 3 3)'::geometry), - (3, 'LINESTRING(0 1, 0 5)'::geometry), - (4, 'LINESTRING(1 2, 4 6)'::geometry)) AS tbl2; - - column1 | column1 | overabove ----------+---------+----------- - 1 | 2 | t - 1 | 3 | f - 1 | 4 | f -(3 rows) - - - - See Also - - - , - , - , - - - - - - - |>> - - Returns TRUE if A's bounding box is strictly above B's. - - - - - - - boolean |>> - - - geometry - - A - - - - geometry - - B - - - - - - - Description - - The |>> operator returns TRUE if the bounding box of geometry A - is strictly to the right of the bounding box of geometry B. - - This operand will make use of any indexes that may be available on the - geometries. - - - - Examples - - SELECT tbl1.column1, tbl2.column1, tbl1.column2 |>> tbl2.column2 AS above -FROM - ( VALUES - (1, 'LINESTRING (1 4, 1 7)'::geometry)) AS tbl1, - ( VALUES - (2, 'LINESTRING (0 0, 4 2)'::geometry), - (3, 'LINESTRING (6 1, 6 5)'::geometry), - (4, 'LINESTRING (2 3, 5 6)'::geometry)) AS tbl2; - - column1 | column1 | above ----------+---------+------- - 1 | 2 | t - 1 | 3 | f - 1 | 4 | f -(3 rows) - - - - See Also - - , , - - - - - - ~ - - Returns TRUE if A's bounding box contains B's. - - - - - - - boolean ~ - - - geometry - - A - - - - geometry - - B - - - - - - - Description - - The ~ operator returns TRUE if the bounding box of geometry A completely - contains the bounding box of geometry B. - - This operand will make use of any indexes that may be available on the - geometries. - - - - Examples - - SELECT tbl1.column1, tbl2.column1, tbl1.column2 ~ tbl2.column2 AS contains -FROM - ( VALUES - (1, 'LINESTRING (0 0, 3 3)'::geometry)) AS tbl1, - ( VALUES - (2, 'LINESTRING (0 0, 4 4)'::geometry), - (3, 'LINESTRING (1 1, 2 2)'::geometry), - (4, 'LINESTRING (0 0, 3 3)'::geometry)) AS tbl2; - - column1 | column1 | contains ----------+---------+---------- - 1 | 2 | f - 1 | 3 | t - 1 | 4 | t -(3 rows) - - - - See Also - - , - - - - - - ~= - - Returns TRUE if the geometry A is the same as B. - - - - - - - boolean ~= - - - geometry - - A - - - - geometry - - B - - - - boolean ~= - - - geography - - A - - - - geography - - B - - - - - - - Description - - The ~= operator returns TRUE if geometry A is the same as geometry B. - It tests actual geometric equality of two features. So if A and B are the same feature, vertex-by-vertex, the - operator returns TRUE. - - This operand will make use of any indexes that may be available on the - geometries. - - Availability: 1.5.0 support for geography was introduced. - - - - Examples - - SELECT tbl1.column1, tbl2.column1, tbl1.column2 ~= tbl2.column2 AS same -FROM - ( VALUES - (1, 'LINESTRING (0 0, 2 2)'::geometry)) AS tbl1, - ( VALUES - (2, 'LINESTRING (0 0, 1 1, 2 2)'::geometry), - (3, 'LINESTRING (2 2, 0 0)'::geometry), - (4, 'LINESTRING (0 0, 2 2)'::geometry)) AS tbl2; - - column1 | column1 | same ----------+---------+------ - 1 | 2 | f - 1 | 3 | f - 1 | 4 | t -(3 rows) - - - - See Also - - , , - - - - - - - - Spatial Relationships and Measurements - - - ST_Area - - Returns the area of the surface if it is a polygon or - multi-polygon. For "geometry" type area is in SRID units. For "geography" area is in square meters. - - - - - float ST_Area - geometry g1 - - - - float ST_Area - geography g1 - - - - float ST_Area - geography g1 - boolean use_spheroid - - - - - Description - - Returns the area of the geometry if it is a polygon or - multi-polygon. Return the area measurement of an ST_Surface or - ST_MultiSurface value. For geometry Area is in the units of the srid. For geography area is in square meters and defaults to measuring about the spheroid of the geography (currently only WGS84). - To measure around the faster but less accurate sphere -- ST_Area(geog,false). - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 8.1.2, 9.5.3 - - - - Examples - Return area in square feet for a plot of Massachusetts land and multiply by conversion to get square meters. - Note this is in square feet because 2249 is - Mass State Plane Feet - -SELECT ST_Area(the_geom) As sqft, ST_Area(the_geom)*POWER(0.3048,2) As sqm - FROM (SELECT - ST_GeomFromText('POLYGON((743238 2967416,743238 2967450, - 743265 2967450,743265.625 2967416,743238 2967416))',2249) ) As foo(the_geom); - sqft | sqm ----------+------------- - 928.625 | 86.27208552 - -Return area square feet and transform to Massachusetts state plane meters (26986) to get square meters. - Note this is in square feet because 2249 is - Mass State Plane Feet and transformed area is in square meters since 26986 is state plane mass meters - - -SELECT ST_Area(the_geom) As sqft, ST_Area(ST_Transform(the_geom,26986)) As sqm - FROM (SELECT - ST_GeomFromText('POLYGON((743238 2967416,743238 2967450, - 743265 2967450,743265.625 2967416,743238 2967416))',2249) ) As foo(the_geom); - sqft | sqm ----------+------------------ - 928.625 | 86.2724304199219 - - -Return area square feet and square meters using Geography data type. Note that we transform to our geometry to geography - (before you can do that make sure your geometry is in WGS 84 long lat 4326). Geography always measures in meters. - This is just for demonstration to compare. Normally your table will be stored in geography data type already. - - -SELECT ST_Area(the_geog)/POWER(0.3048,2) As sqft_spheroid, ST_Area(the_geog,false)/POWER(0.3048,2) As sqft_sphere, ST_Area(the_geog) As sqm_spheroid - FROM (SELECT - geography( - ST_Transform( - ST_GeomFromText('POLYGON((743238 2967416,743238 2967450,743265 2967450,743265.625 2967416,743238 2967416))', - 2249 - ) ,4326 - ) - ) - ) As foo(the_geog); - sqft_spheroid | sqft_sphere | sqm_spheroid ------------------+------------------+------------------ -928.684405217197 | 927.186481558724 | 86.2776044452694 - - --if your data is in geography already - SELECT ST_Area(the_geog)/POWER(0.3048,2) As sqft, ST_Area(the_geog) As sqm - FROM somegeogtable; - - - - See Also - , , , - - - - - - - ST_Azimuth - - Returns the angle in radians from the horizontal of the vector defined by pointA and pointB - - - - - float ST_Azimuth - geometry pointA - geometry pointB - - - - - Description - - Returns the azimuth of the segment defined by the given - Point geometries, or NULL if the two points are coincident. Return - value is in radians. - - The Azimuth is mathematical concept defined as the angle, in this case measured in radian, between a reference plane - and a point - - Availability: 1.1.0 - Azimuth is especially useful in conjunction with ST_Translate for shifting an object along its perpendicular axis. See - upgis_lineshift Plpgsqlfunctions PostGIS wiki section for example of this. - - - - Examples - --Azimuth in degrees - -SELECT ST_Azimuth(ST_MakePoint(1,2), ST_MakePoint(3,4))/(2*pi())*360 as degAz, - ST_Azimuth(ST_MakePoint(3,4), ST_MakePoint(1,2))/(2*pi())*360 As degAzrev - -degaz degazrev ------- --------- -45 225 - - - - See Also - , - - - - - - - ST_Centroid - - Returns the geometric center of a geometry. - - - - - - geometry ST_Centroid - - geometry - g1 - - - - - - Description - - Computes the geometric center of a geometry, or equivalently, - the center of mass of the geometry as a POINT. For - [MULTI]POINTs, this is computed - as the arithmetric mean of the input coordinates. For - [MULTI]LINESTRINGs, this is - computed as the weighted length of each line segment. For - [MULTI]POLYGONs, "weight" is - thought in terms of area. If an empty geometry is supplied, an empty - GEOMETRYCOLLECTION is returned. If - NULL is supplied, NULL is - returned. - - The centroid is equal to the centroid of the set of component - Geometries of highest dimension (since the lower-dimension geometries - contribute zero "weight" to the centroid). - - Computation will be more accurate if performed by the GEOS - module (enabled at compile time). - - - - - - This method implements the OpenGIS Simple - Features Implementation Specification for SQL. - - - - - - This method implements the SQL/MM - specification: SQL-MM 3: 8.1.4, 9.5.5 - - - - Examples - - In each of the following illustrations, the blue dot represents - the centroid of the source geometry. - - - - - - - - - - - - Centroid of a - MULTIPOINT - - - - - - - - - - Centroid of a - LINESTRING - - - - - - - - - - - - Centroid of a - POLYGON - - - - - - - - - - Centroid of a - GEOMETRYCOLLECTION - - - - - - - - SELECT ST_AsText(ST_Centroid('MULTIPOINT ( -1 0, -1 2, -1 3, -1 4, -1 7, 0 1, 0 3, 1 1, 2 0, 6 0, 7 8, 9 8, 10 6 )')); - st_astext ------------------------------------------- - POINT(2.30769230769231 3.30769230769231) -(1 row) - - - - See Also - - - - - - - - ST_Contains - - Returns true if and only if no points of B lie in the exterior of A, and at least one point of the interior of B lies in the interior of A. - - - - - - boolean ST_Contains - - geometry - geomA - - geometry - geomB - - - - - - Description - - Geometry A contains Geometry B if and only if no points of B lie in the exterior of A, and at least one point of the interior of B lies in the interior of A. - An important subtlety of this definition is that A does not contain its boundary, but A does contain itself. Contrast that to where geometry - A does not Contain Properly itself. - - Returns TRUE if geometry B is completely inside geometry A. For this function to make - sense, the source geometries must both be of the same coordinate projection, - having the same SRID. ST_Contains is the inverse of ST_Within. So ST_Contains(A,B) implies ST_Within(B,A) except in the case of - invalid geometries where the result is always false regardless or not defined. - - Performed by the GEOS module - - - Do not call with a GEOMETRYCOLLECTION as an argument - - - - Do not use this function with invalid geometries. You will get unexpected results. - - - This function call will automatically include a bounding box - comparison that will make use of any indexes that are available on - the geometries. To avoid index use, use the function - _ST_Contains. - - NOTE: this is the "allowable" version that returns a - boolean, not an integer. - - - - - - - This method implements the - OpenGIS Simple Features - Implementation Specification for SQL. - OGC SPEC s2.1.1.2 // s2.1.13.3 - same as within(geometry B, - geometry A) - - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.31 - - There are certain subtleties to ST_Contains and ST_Within that are not intuitively obvious. - For details check out Subtleties of OGC Covers, Contains, Within - - - - Examples - - The ST_Contains predicate returns TRUE in all the following illustrations. - - - - - - - - - - - - LINESTRING / MULTIPOINT - - - - - - - - - - POLYGON / POINT - - - - - - - - - - - POLYGON / LINESTRING - - - - - - - - - - POLYGON / POLYGON - - - - - - - - The ST_Contains predicate returns FALSE in all the following illustrations. - - - - - - - - - - - - POLYGON / MULTIPOINT - - - - - - - - - - POLYGON / LINESTRING - - - - - - - - --- A circle within a circle -SELECT ST_Contains(smallc, bigc) As smallcontainsbig, - ST_Contains(bigc,smallc) As bigcontainssmall, - ST_Contains(bigc, ST_Union(smallc, bigc)) as bigcontainsunion, - ST_Equals(bigc, ST_Union(smallc, bigc)) as bigisunion, - ST_Covers(bigc, ST_ExteriorRing(bigc)) As bigcoversexterior, - ST_Contains(bigc, ST_ExteriorRing(bigc)) As bigcontainsexterior -FROM (SELECT ST_Buffer(ST_GeomFromText('POINT(1 2)'), 10) As smallc, - ST_Buffer(ST_GeomFromText('POINT(1 2)'), 20) As bigc) As foo; - --- Result - smallcontainsbig | bigcontainssmall | bigcontainsunion | bigisunion | bigcoversexterior | bigcontainsexterior -------------------+------------------+------------------+------------+-------------------+--------------------- - f | t | t | t | t | f - --- Example demonstrating difference between contains and contains properly -SELECT ST_GeometryType(geomA) As geomtype, ST_Contains(geomA,geomA) AS acontainsa, ST_ContainsProperly(geomA, geomA) AS acontainspropa, - ST_Contains(geomA, ST_Boundary(geomA)) As acontainsba, ST_ContainsProperly(geomA, ST_Boundary(geomA)) As acontainspropba -FROM (VALUES ( ST_Buffer(ST_Point(1,1), 5,1) ), - ( ST_MakeLine(ST_Point(1,1), ST_Point(-1,-1) ) ), - ( ST_Point(1,1) ) - ) As foo(geomA); - - geomtype | acontainsa | acontainspropa | acontainsba | acontainspropba ---------------+------------+----------------+-------------+----------------- -ST_Polygon | t | f | f | f -ST_LineString | t | f | f | f -ST_Point | t | t | f | f - - - - - - See Also - , , ,, , - - - - - - ST_ContainsProperly - - Returns true if B intersects the interior of A but not the boundary (or exterior). A does not contain properly itself, but does contain itself. - - - - - - boolean ST_ContainsProperly - - geometry - geomA - - geometry - geomB - - - - - - Description - - Returns true if B intersects the interior of A but not the boundary (or exterior). - - A does not contain properly itself, but does contain itself. - Every point of the other geometry is a point of this geometry's interior. The DE-9IM Intersection Matrix for the two geometries matches - [T**FF*FF*] used in - - - From JTS docs slightly reworded: The advantage to using this predicate over and is that it can be computed - efficiently, with no need to compute topology at individual points. - - An example use case for this predicate is computing the intersections - of a set of geometries with a large polygonal geometry. - Since intersection is a fairly slow operation, it can be more efficient - to use containsProperly to filter out test geometries which lie - wholly inside the area. In these cases the intersection is - known a priori to be exactly the original test geometry. - - - - Availability: 1.4.0 - requires GEOS >= 3.1.0. - - - Do not call with a GEOMETRYCOLLECTION as an argument - - - - Do not use this function with invalid geometries. You will get unexpected results. - - - This function call will automatically include a bounding box - comparison that will make use of any indexes that are available on - the geometries. To avoid index use, use the function - _ST_ContainsProperly. - - - - - Examples - - --a circle within a circle - SELECT ST_ContainsProperly(smallc, bigc) As smallcontainspropbig, - ST_ContainsProperly(bigc,smallc) As bigcontainspropsmall, - ST_ContainsProperly(bigc, ST_Union(smallc, bigc)) as bigcontainspropunion, - ST_Equals(bigc, ST_Union(smallc, bigc)) as bigisunion, - ST_Covers(bigc, ST_ExteriorRing(bigc)) As bigcoversexterior, - ST_ContainsProperly(bigc, ST_ExteriorRing(bigc)) As bigcontainsexterior - FROM (SELECT ST_Buffer(ST_GeomFromText('POINT(1 2)'), 10) As smallc, - ST_Buffer(ST_GeomFromText('POINT(1 2)'), 20) As bigc) As foo; - --Result - smallcontainspropbig | bigcontainspropsmall | bigcontainspropunion | bigisunion | bigcoversexterior | bigcontainsexterior -------------------+------------------+------------------+------------+-------------------+--------------------- - f | t | f | t | t | f - - --example demonstrating difference between contains and contains properly - SELECT ST_GeometryType(geomA) As geomtype, ST_Contains(geomA,geomA) AS acontainsa, ST_ContainsProperly(geomA, geomA) AS acontainspropa, - ST_Contains(geomA, ST_Boundary(geomA)) As acontainsba, ST_ContainsProperly(geomA, ST_Boundary(geomA)) As acontainspropba - FROM (VALUES ( ST_Buffer(ST_Point(1,1), 5,1) ), - ( ST_MakeLine(ST_Point(1,1), ST_Point(-1,-1) ) ), - ( ST_Point(1,1) ) - ) As foo(geomA); - - geomtype | acontainsa | acontainspropa | acontainsba | acontainspropba ---------------+------------+----------------+-------------+----------------- -ST_Polygon | t | f | f | f -ST_LineString | t | f | f | f -ST_Point | t | t | f | f - - - - - See Also - , , , ,, ,, - - - - - - ST_Covers - - Returns 1 (TRUE) if no point in Geometry B is outside - Geometry A - - - - - - boolean ST_Covers - - geometry - geomA - - geometry - geomB - - - boolean ST_Covers - - geography - geogpolyA - - geography - geogpointB - - - - - - Description - - Returns 1 (TRUE) if no point in Geometry/Geography B is outside - Geometry/Geography A - - Performed by the GEOS module - - - Do not call with a GEOMETRYCOLLECTION as an argument - - - - For geography only Polygon covers point is supported. - - - - Do not use this function with invalid geometries. You will get unexpected results. - - - This function call will automatically include a bounding box - comparison that will make use of any indexes that are available on - the geometries. To avoid index use, use the function - _ST_Covers. - - Availability: 1.2.2 - requires GEOS >= 3.0 - Availability: 1.5 - support for geography was introduced. - - NOTE: this is the "allowable" version that returns a - boolean, not an integer. - - Not an OGC standard, but Oracle has it too. - There are certain subtleties to ST_Contains and ST_Within that are not intuitively obvious. - For details check out Subtleties of OGC Covers, Contains, Within - - - - Examples - Geometry example - - --a circle covering a circle -SELECT ST_Covers(smallc,smallc) As smallinsmall, - ST_Covers(smallc, bigc) As smallcoversbig, - ST_Covers(bigc, ST_ExteriorRing(bigc)) As bigcoversexterior, - ST_Contains(bigc, ST_ExteriorRing(bigc)) As bigcontainsexterior -FROM (SELECT ST_Buffer(ST_GeomFromText('POINT(1 2)'), 10) As smallc, - ST_Buffer(ST_GeomFromText('POINT(1 2)'), 20) As bigc) As foo; - --Result - smallinsmall | smallcoversbig | bigcoversexterior | bigcontainsexterior ---------------+----------------+-------------------+--------------------- - t | f | t | f -(1 row) - Geeography Example - - - - - - - See Also - , , - - - - - - ST_CoveredBy - - Returns 1 (TRUE) if no point in Geometry A is outside - Geometry B - - - - - - boolean ST_CoveredBy - - geometry - geomA - - geometry - geomB - - - - - - Description - - Returns 1 (TRUE) if no point in Geometry A is outside - Geometry B - - Performed by the GEOS module - - - Do not call with a GEOMETRYCOLLECTION as an argument - - - - Do not use this function with invalid geometries. You will get unexpected results. - - Availability: 1.2.2 - requires GEOS >= 3.0 - This function call will automatically include a bounding box - comparison that will make use of any indexes that are available on - the geometries. To avoid index use, use the function - _ST_CoveredBy. - - NOTE: this is the "allowable" version that returns a - boolean, not an integer. - - Not an OGC standard, but Oracle has it too. - There are certain subtleties to ST_Contains and ST_Within that are not intuitively obvious. - For details check out Subtleties of OGC Covers, Contains, Within - - - - Examples - - --a circle coveredby a circle -SELECT ST_CoveredBy(smallc,smallc) As smallinsmall, - ST_CoveredBy(smallc, bigc) As smallcoveredbybig, - ST_CoveredBy(ST_ExteriorRing(bigc), bigc) As exteriorcoveredbybig, - ST_Within(ST_ExteriorRing(bigc),bigc) As exeriorwithinbig -FROM (SELECT ST_Buffer(ST_GeomFromText('POINT(1 2)'), 10) As smallc, - ST_Buffer(ST_GeomFromText('POINT(1 2)'), 20) As bigc) As foo; - --Result - smallinsmall | smallcoveredbybig | exteriorcoveredbybig | exeriorwithinbig ---------------+-------------------+----------------------+------------------ - t | t | t | f -(1 row) - - - - See Also - , , , - - - - - - ST_Crosses - - Returns TRUE if the supplied geometries have some, but not all, - interior points in common. - - - - - - boolean ST_Crosses - - geometry g1 - - geometry g2 - - - - - - Description - - ST_Crosses takes two geometry objects and - returns TRUE if their intersection "spatially cross", that is, the - geometries have some, but not all interior points in common. The - intersection of the interiors of the geometries must not be the empty - set and must have a dimensionality less than the the maximum dimension - of the two input geometries. Additionally, the intersection of the two - geometries must not equal either of the source geometries. Otherwise, it - returns FALSE. - - In mathematical terms, this is expressed as: - - TODO: Insert appropriate MathML markup here or use a gif. - Simple HTML markup does not work well in both IE and Firefox. - - - - - - - - - - The DE-9IM Intersection Matrix for the two geometries is: - - - - T*T****** (for Point/Line, Point/Area, and - Line/Area situations) - - - - T*****T** (for Line/Point, Area/Point, and - Area/Line situations) - - - - 0******** (for Line/Line situations) - - - - For any other combination of dimensions this predicate returns - false. - - The OpenGIS Simple Features Specification defines this predicate - only for Point/Line, Point/Area, Line/Line, and Line/Area situations. - JTS / GEOS extends the definition to apply to Line/Point, Area/Point and - Area/Line situations as well. This makes the relation - symmetric. - - - Do not call with a GEOMETRYCOLLECTION as an argument - - - - This function call will automatically include a bounding box - comparison that will make use of any indexes that are available on the - geometries. - - - - - This method implements the - OpenGIS Simple - Features Implementation Specification for SQL: 1.1: s2.1.13.3 - - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.29 - - - - - Examples - - The following illustrations all return TRUE. - - - - - - - - - - - - MULTIPOINT / LINESTRING - - - - - - - - - - MULTIPOINT / POLYGON - - - - - - - - - - - - LINESTRING / POLYGON - - - - - - - - - - LINESTRING / LINESTRING - - - - - - - - Consider a situation where a user has two tables: a table of roads - and a table of highways. - - - - - - - CREATE TABLE roads ( - id serial NOT NULL, - the_geom geometry, - CONSTRAINT roads_pkey PRIMARY KEY (road_id) -); - - - - CREATE TABLE highways ( - id serial NOT NULL, - the_gem geometry, - CONSTRAINT roads_pkey PRIMARY KEY (road_id) -); - - - - - - - To determine a list of roads that cross a highway, use a query - similiar to: - - - SELECT roads.id -FROM roads, highways -WHERE ST_Crosses(roads.the_geom, highways.the_geom); - - - - - - - ST_LineCrossingDirection - - Given 2 linestrings, returns a number between -3 and 3 denoting what kind of crossing behavior. 0 is no crossing. - - - - - - integer ST_LineCrossingDirection - geometry linestringA - geometry linestringB - - - - - - Description - - Given 2 linestrings, returns a number between -3 and 3 denoting what kind of crossing behavior. 0 is no crossing. This is only supported for LINESTRING - Definition of integer constants is as follows: - - - 0: LINE NO CROSS - - - -1: LINE CROSS LEFT - - - 1: LINE CROSS RIGHT - - - -2: LINE MULTICROSS END LEFT - - - 2: LINE MULTICROSS END RIGHT - - - -3: LINE MULTICROSS END SAME FIRST LEFT - - - 3: LINE MULTICROSS END SAME FIRST RIGHT - - - - Availability: 1.4 - - - - - - - Examples - - - - - - - - - - - Line 1 (green), Line 2 ball is start point, - triangle are end points. Query below. - - - -SELECT ST_LineCrossingDirection(foo.line1, foo.line2) As l1_cross_l2 , - ST_LineCrossingDirection(foo.line2, foo.line1) As l2_cross_l1 -FROM ( -SELECT - ST_GeomFromText('LINESTRING(25 169,89 114,40 70,86 43)') As line1, - ST_GeomFromText('LINESTRING(171 154,20 140,71 74,161 53)') As line2 - ) As foo; - - l1_cross_l2 | l2_cross_l1 --------------+------------- - 3 | -3 - - - - - - - - - - - Line 1 (green), Line 2 (blue) ball is start point, - triangle are end points. Query below. - - - -SELECT ST_LineCrossingDirection(foo.line1, foo.line2) As l1_cross_l2 , - ST_LineCrossingDirection(foo.line2, foo.line1) As l2_cross_l1 -FROM ( - SELECT - ST_GeomFromText('LINESTRING(25 169,89 114,40 70,86 43)') As line1, - ST_GeomFromText('LINESTRING (171 154, 20 140, 71 74, 2.99 90.16)') As line2 -) As foo; - - l1_cross_l2 | l2_cross_l1 --------------+------------- - 2 | -2 - - - - - - - - - - - Line 1 (green), Line 2 (blue) ball is start point, - triangle are end points. Query below. - - - -SELECT - ST_LineCrossingDirection(foo.line1, foo.line2) As l1_cross_l2 , - ST_LineCrossingDirection(foo.line2, foo.line1) As l2_cross_l1 -FROM ( - SELECT - ST_GeomFromText('LINESTRING(25 169,89 114,40 70,86 43)') As line1, - ST_GeomFromText('LINESTRING (20 140, 71 74, 161 53)') As line2 - ) As foo; - - l1_cross_l2 | l2_cross_l1 --------------+------------- - -1 | 1 - - - - - - - - - - - Line 1 (green), Line 2 (blue) ball is start point, - triangle are end points. Query below. - - - -SELECT ST_LineCrossingDirection(foo.line1, foo.line2) As l1_cross_l2 , - ST_LineCrossingDirection(foo.line2, foo.line1) As l2_cross_l1 -FROM (SELECT - ST_GeomFromText('LINESTRING(25 169,89 114,40 70,86 43)') As line1, - ST_GeomFromText('LINESTRING(2.99 90.16,71 74,20 140,171 154)') As line2 - ) As foo; - - l1_cross_l2 | l2_cross_l1 --------------+------------- - -2 | 2 - - - - - - - - - -SELECT s1.gid, s2.gid, ST_LineCrossingDirection(s1.the_geom, s2.the_geom) - FROM streets s1 CROSS JOIN streets s2 ON (s1.gid != s2.gid AND s1.the_geom && s2.the_geom ) -WHERE ST_CrossingDirection(s1.the_geom, s2.the_geom) > 0; - - - - - - See Also - - - - - - - - ST_Disjoint - - Returns TRUE if the Geometries do not "spatially - intersect" - if they do not share any space together. - - - - - - boolean ST_Disjoint - - geometry - A - - - geometry - B - - - - - - Description - Overlaps, Touches, Within all imply geometries are not spatially disjoint. If any of the aforementioned - returns true, then the geometries are not spatially disjoint. - Disjoint implies false for spatial intersection. - - - Do not call with a GEOMETRYCOLLECTION as an argument - - - Performed by the GEOS module - - This function call does not use indexes - - - - NOTE: this is the "allowable" version that returns a - boolean, not an integer. - - - - This method implements the - OGC SPEC s2.1.1.2 //s2.1.13.3 - a.Relate(b, - 'FF*FF****') - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.26 - - - Examples - - SELECT ST_Disjoint('POINT(0 0)'::geometry, 'LINESTRING ( 2 0, 0 2 )'::geometry); - st_disjoint ---------------- - t -(1 row) -SELECT ST_Disjoint('POINT(0 0)'::geometry, 'LINESTRING ( 0 0, 0 2 )'::geometry); - st_disjoint ---------------- - f -(1 row) - - - - - See Also - ST_Intersects - - - - - - ST_Distance - - For geometry type Returns the 2-dimensional cartesian minimum distance (based on spatial ref) between two geometries in - projected units. For geography type defaults to return spheroidal minimum distance between two geographies in meters. - - - - - float ST_Distance - - geometry - g1 - - geometry - g2 - - - float ST_Distance - - geography - gg1 - - geography - gg2 - - - - float ST_Distance - - geography - gg1 - - geography - gg2 - - boolean - use_spheroid - - - - - - Description - - For geometry type returns the 2-dimensional minimum cartesian distance between two geometries in - projected units (spatial ref units). For geography type defaults to return the minimum distance around WGS 84 spheroid between two geographies in meters. Pass in - false to return answer in sphere instead of spheroid. - - - - This method implements the - OpenGIS Simple - Features Implementation Specification for SQL. - - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.23 - - - Availability: 1.5.0 geography support was introduced in 1.5. - - - - Examples - - ---Geometry example - units in planar degrees 4326 is WGS 84 long lat unit=degrees -SELECT ST_Distance( - ST_GeomFromText('POINT(-72.1235 42.3521)',4326), - ST_GeomFromText('LINESTRING(-72.1260 42.45, -72.123 42.1546)', 4326) - ); -st_distance ------------------ -0.00150567726382282 - --- Geometry example - units in meters (SRID: 26986 Massachusetts state plane meters) (most accurate for Massachusetts) -SELECT ST_Distance( - ST_Transform(ST_GeomFromText('POINT(-72.1235 42.3521)',4326),26986), - ST_Transform(ST_GeomFromText('LINESTRING(-72.1260 42.45, -72.123 42.1546)', 4326),26986) - ); -st_distance ------------------ -123.797937878454 - --- Geometry example - units in meters (SRID: 2163 US National Atlas Equal area) (least accurate) -SELECT ST_Distance( - ST_Transform(ST_GeomFromText('POINT(-72.1235 42.3521)',4326),2163), - ST_Transform(ST_GeomFromText('LINESTRING(-72.1260 42.45, -72.123 42.1546)', 4326),2163) - ); - -st_distance ------------------- -126.664256056812 - --- Geography example -- same but note units in meters - use sphere for slightly faster less accurate -SELECT ST_Distance(gg1, gg2) As spheroid_dist, ST_Distance(gg1, gg2, false) As sphere_dist -FROM (SELECT - ST_GeographyFromText('SRID=4326;POINT(-72.1235 42.3521)') As gg1, - ST_GeographyFromText('SRID=4326;LINESTRING(-72.1260 42.45, -72.123 42.1546)') As gg2 - ) As foo ; - - spheroid_dist | sphere_dist -------------------+------------------ - 123.802076746848 | 123.475736916397 - - - - - - See Also - - , , , , - - - - - - ST_HausdorffDistance - - Returns the Hausdorff distance between two geometries. Basically a measure of how similar or dissimilar 2 geometries are. Units are in the units of the spatial - reference system of the geometries. - - - - - - float ST_HausdorffDistance - - geometry - g1 - - geometry - g2 - - - float ST_HausdorffDistance - - geometry - g1 - - geometry - g2 - - float - densifyFrac - - - - - - Description - - Implements algorithm for computing a distance metric which can be thought of as the "Discrete Hausdorff Distance". -This is the Hausdorff distance restricted to discrete points for one of the geometries. Wikipedia article on Hausdorff distance - Martin Davis note on how Hausdorff Distance calculation was used to prove correctness of the CascadePolygonUnion approach. - -When densifyFrac is specified, this function performs a segment densification before computing the discrete hausdorff distance. The densifyFrac parameter sets the fraction by which to densify each segment. Each segment will be split into a number of equal-length subsegments, whose fraction of the total length is closest to the given fraction. - - - - -The current implementation supports only vertices as the discrete locations. This could be extended to allow an arbitrary density of points to be used. - - - - - This algorithm is NOT equivalent to the standard Hausdorff distance. However, it computes an approximation that is correct for a large subset of useful cases. - One important part of this subset is Linestrings that are roughly parallel to each other, and roughly equal in length. This is a useful metric for line matching. - - - Availability: 1.5 - requires GEOS >= 3.2.0 - - - - - Examples - - postgis=# SELECT st_HausdorffDistance( - 'LINESTRING (0 0, 2 0)'::geometry, - 'MULTIPOINT (0 1, 1 0, 2 1)'::geometry); - st_hausdorffdistance - ---------------------- - 1 -(1 row) - - postgis=# SELECT st_hausdorffdistance('LINESTRING (130 0, 0 0, 0 150)'::geometry, 'LINESTRING (10 10, 10 150, 130 10)'::geometry, 0.5); - st_hausdorffdistance - ---------------------- - 70 -(1 row) - - - - - - - - ST_Distance_Sphere - - Returns minimum distance in meters between two lon/lat - geometries. Uses a spherical earth and radius of 6370986 meters. - Faster than ST_Distance_Spheroid, but less - accurate. PostGIS versions prior to 1.5 only implemented for points. - - - - - - float ST_Distance_Sphere - geometry geomlonlatA - geometry geomlonlatB - - - - - - Description - - Returns minimum distance in meters between two lon/lat - points. Uses a spherical earth and radius of 6370986 meters. - Faster than , but less - accurate. PostGIS Versions prior to 1.5 only implemented for points. - - This function currently does not look at the SRID of a geometry and will always assume its in WGS 84 long lat. Prior versions of this function only support points. - - - Availability: 1.5 - support for other geometry types besides points was introduced. Prior versions only work with points. - - - - - Examples - - SELECT round(CAST(ST_Distance_Sphere(ST_Centroid(the_geom), ST_GeomFromText('POINT(-118 38)',4326)) As numeric),2) As dist_meters, -round(CAST(ST_Distance(ST_Transform(ST_Centroid(the_geom),32611), - ST_Transform(ST_GeomFromText('POINT(-118 38)', 4326),32611)) As numeric),2) As dist_utm11_meters, -round(CAST(ST_Distance(ST_Centroid(the_geom), ST_GeomFromText('POINT(-118 38)', 4326)) As numeric),5) As dist_degrees, -round(CAST(ST_Distance(ST_Transform(the_geom,32611), - ST_Transform(ST_GeomFromText('POINT(-118 38)', 4326),32611)) As numeric),2) As min_dist_line_point_meters -FROM - (SELECT ST_GeomFromText('LINESTRING(-118.584 38.374,-118.583 38.5)', 4326) As the_geom) as foo; - dist_meters | dist_utm11_meters | dist_degrees | min_dist_line_point_meters - -------------+-------------------+--------------+---------------------------- - 70424.47 | 70438.00 | 0.72900 | 65871.18 - - - - - - - See Also - - , - - - - - - ST_Distance_Spheroid - - Returns the minimum distance between two lon/lat geometries given a - particular spheroid. - PostGIS versions prior to 1.5 only support points. - - - - - - float ST_Distance_Spheroid - geometry geomlonlatA - geometry geomlonlatB - spheroid measurement_spheroid - - - - - - Description - - Returns minimum distance in meters between two lon/lat - geometries given a particular spheroid. See the explanation of spheroids given for - . PostGIS version prior to 1.5 only support points. - - This function currently does not look at the SRID of a geometry and will always assume its in WGS 80 long lat. Prior versions of this function only support points. - - - Availability: 1.5 - support for other geometry types besides points was introduced. Prior versions only work with points. - - - - - Examples - - SELECT round(CAST( - ST_Distance_Spheroid(ST_Centroid(the_geom), ST_GeomFromText('POINT(-118 38)',4326), 'SPHEROID["WGS 84",6378137,298.257223563]') - As numeric),2) As dist_meters_spheroid, - round(CAST(ST_Distance_Sphere(ST_Centroid(the_geom), ST_GeomFromText('POINT(-118 38)',4326)) As numeric),2) As dist_meters_sphere, -round(CAST(ST_Distance(ST_Transform(ST_Centroid(the_geom),32611), - ST_Transform(ST_GeomFromText('POINT(-118 38)', 4326),32611)) As numeric),2) As dist_utm11_meters -FROM - (SELECT ST_GeomFromText('LINESTRING(-118.584 38.374,-118.583 38.5)', 4326) As the_geom) as foo; - dist_meters_spheroid | dist_meters_sphere | dist_utm11_meters -----------------------+--------------------+------------------- - 70454.92 | 70424.47 | 70438.00 - - - - - - - See Also - - , - - - - - - ST_DWithin - - Returns true if the geometries are within the specified - distance of one another. For geometry units are in those of spatial reference and For geography units are in meters and measurement is - defaulted to use_spheroid=true (measure around spheroid), for faster check, use_spheroid=false to measure along sphere. - - - - - - boolean ST_DWithin - geometry - g1 - - geometry - g2 - - double precision - distance_of_srid - - - - boolean ST_DWithin - geography - gg1 - - geography - gg2 - - double precision - distance_meters - - - - boolean ST_DWithin - geography - gg1 - - geography - gg2 - - double precision - distance_meters - - boolean - use_spheroid - - - - - - Description - - Returns true if the geometries are within the specified distance - of one another. - For Geometries: The distance is specified in units defined by the - spatial reference system of the geometries. For this function to make - sense, the source geometries must both be of the same coorindate projection, - having the same SRID. - - For geography units are in meters and measurement is - defaulted to use_spheroid=true (measure around WGS 84 spheroid), for faster check, use_spheroid=false to measure along sphere. - - - This function call will automatically include a bounding box - comparison that will make use of any indexes that are available on - the geometries. - - - - Prior to 1.3, ST_Expand was commonly used in conjunction with && and ST_Distance to - achieve the same effect and in pre-1.3.4 this function was basically short-hand for that construct. - From 1.3.4, ST_DWithin uses a more short-circuit distance function which should make it more efficient - than prior versions for larger buffer regions. - - - - - This method implements the - OpenGIS Simple - Features Implementation Specification for SQL. - - - Availability: 1.5.0 support for geography was introduced - - - - Examples - ---Find the nearest hospital to each school ---that is within 3000 units of the school. --- We do an ST_DWithin search to utilize indexes to limit our search list --- that the non-indexable ST_Distance needs to process ---If the units of the spatial reference is meters then units would be meters -SELECT DISTINCT ON (s.gid) s.gid, s.school_name, s.the_geom, h.hospital_name - FROM schools s - LEFT JOIN hospitals h ON ST_DWithin(s.the_geom, h.the_geom, 3000) - ORDER BY s.gid, ST_Distance(s.the_geom, h.the_geom); - ---The schools with no close hospitals ---Find all schools with no hospital within 3000 units ---away from the school. Units is in units of spatial ref (e.g. meters, feet, degrees) -SELECT s.gid, s.school_name - FROM schools s - LEFT JOIN hospitals h ON ST_DWithin(s.the_geom, h.the_geom, 3000) - WHERE h.gid IS NULL; - - - - - See Also - - , - - - - - - ST_Equals - - Returns true if the given geometries represent the same geometry. Directionality - is ignored. - - - - - - boolean ST_Equals - geometry A - geometry B - - - - - - Description - - Returns TRUE if the given Geometries are "spatially - equal". Use this for a 'better' answer than '='. - Note by spatially equal we mean ST_Within(A,B) = true and ST_Within(B,A) = true and - also mean ordering of points can be different but - represent the same geometry structure. To verify the order of points is consistent, use - ST_OrderingEquals (it must be noted ST_OrderingEquals is a little more stringent than simply verifying order of - points are the same). - - - This function will return false if either geometry is invalid even if they are binary equal. - - - - - This method implements the - OpenGIS Simple - Features Implementation Specification for SQL OGC SPEC s2.1.1.2 - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.24 - - - - - - Examples - - SELECT ST_Equals(ST_GeomFromText('LINESTRING(0 0, 10 10)'), - ST_GeomFromText('LINESTRING(0 0, 5 5, 10 10)')); - st_equals ------------ - t -(1 row) - -SELECT ST_Equals(ST_Reverse(ST_GeomFromText('LINESTRING(0 0, 10 10)')), - ST_GeomFromText('LINESTRING(0 0, 5 5, 10 10)')); - st_equals ------------ - t -(1 row) - - - - - See Also - - , , , - - - - - - - ST_HasArc - - Returns true if a geometry or geometry collection contains a circular string - - - - - - boolean ST_HasArc - geometry geomA - - - - - - Description - - Returns true if a geometry or geometry collection contains a circular string - - Availability: 1.2.3? - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - SELECT ST_HasArc(ST_Collect('LINESTRING(1 2, 3 4, 5 6)', 'CIRCULARSTRING(1 1, 2 3, 4 5, 6 7, 5 6)')); - st_hasarc - -------- - t - - - - - - See Also - - , - - - - - - ST_Intersects - - Returns TRUE if the Geometries/Geography "spatially - intersect" - (share any portion of space) and FALSE if they don't (they are Disjoint). - For geography -- tolerance is 0.00001 meters (so any points that close are considered to intersect) - - - - - - boolean ST_Intersects - - geometry - geomA - - - geometry - geomB - - - - boolean ST_Intersects - - geography - geogA - - - geography - geogB - - - - - - Description - Overlaps, Touches, Within all imply spatial intersection. If any of the aforementioned - returns true, then the geometries also spatially intersect. - Disjoint implies false for spatial intersection. - - - Do not call with a GEOMETRYCOLLECTION as an argument for geometry version. The geography - version supports GEOMETRYCOLLECTION since its a thin wrapper around distance implementation. - - - Performed by the GEOS module (for geometry), geography is native - Availability: 1.5 support for geography was introduced. - - This function call will automatically include a bounding box - comparison that will make use of any indexes that are available on the - geometries. - - - For geography, this function has a distance tolerance of about 0.00001 meters and uses the sphere rather - than spheroid calculation. - - - NOTE: this is the "allowable" version that returns a - boolean, not an integer. - - - - This method implements the - OpenGIS Simple - Features Implementation Specification for SQL - OGC SPEC s2.1.1.2 //s2.1.13.3 - ST_Intersects(g1, g2 ) --> - Not (ST_Disjoint(g1, g2 )) - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.27 - - - Geometry Examples -SELECT ST_Intersects('POINT(0 0)'::geometry, 'LINESTRING ( 2 0, 0 2 )'::geometry); - st_intersects ---------------- - f -(1 row) -SELECT ST_Intersects('POINT(0 0)'::geometry, 'LINESTRING ( 0 0, 0 2 )'::geometry); - st_intersects ---------------- - t -(1 row) - - - - Geography Examples -SELECT ST_Intersects( - ST_GeographyFromText('SRID=4326;LINESTRING(-43.23456 72.4567,-43.23456 72.4568)'), - ST_GeographyFromText('SRID=4326;POINT(-43.23456 72.4567772)') - ); - - st_intersects ---------------- -t - - - - See Also - - - - - - ST_Length - - Returns the 2d length of the geometry if it is a linestring or multilinestring. geometry are in units of spatial reference and geography are in meters (default spheroid) - - - - - float ST_Length - geometry a_2dlinestring - - - float ST_Length - geography gg - - - float ST_Length - geography gg - boolean use_spheroid - - - - - Description - - For geometry: Returns the cartesian 2D length of the geometry if it is a linestring, multilinestring, ST_Curve, ST_MultiCurve. 0 is returned for - areal geometries. For areal geometries use ST_Perimeter. Geometry: Measurements are in the units of the - spatial reference system of the geometry. Geography: Units are in meters and also acts as a Perimeter function for areal geogs. - - Currently for geometry this is an alias for ST_Length2D, but this may change to support higher dimensions. - Currently applying this to a MULTI/POLYGON of type geography will give you the perimeter of the POLYGON/MULTIPOLYGON. This is not the - case with the geometry implementation. - For geography measurement defaults spheroid measurement. To use the faster less accurate sphere use ST_Length(gg,false); - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC 2.1.5.1 - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 7.1.2, 9.3.4 - - Availability: 1.5.0 geography support was introduced in 1.5. - - - - Geometry Examples - Return length in feet for line string. Note this is in feet because 2249 is - Mass State Plane Feet - -SELECT ST_Length(ST_GeomFromText('LINESTRING(743238 2967416,743238 2967450,743265 2967450, -743265.625 2967416,743238 2967416)',2249)); -st_length ---------- - 122.630744000095 - - ---Transforming WGS 84 linestring to Massachusetts state plane meters -SELECT ST_Length( - ST_Transform( - ST_GeomFromEWKT('SRID=4326;LINESTRING(-72.1260 42.45, -72.1240 42.45666, -72.123 42.1546)'), - 26986 - ) -); -st_length ---------- -34309.4563576191 - - - - Geography Examples - Return length of WGS 84 geography line - - -- default calculation is using a sphere rather than spheroid -SELECT ST_Length(the_geog) As length_spheroid, ST_Length(the_geog,false) As length_sphere -FROM (SELECT ST_GeographyFromText( -'SRID=4326;LINESTRING(-72.1260 42.45, -72.1240 42.45666, -72.123 42.1546)') As the_geog) - As foo; - length_spheroid | length_sphere -------------------+------------------ - 34310.5703627305 | 34346.2060960742 -(1 row) - - - - See Also - , , , , - - - - - - ST_Length2D - - Returns the 2-dimensional length of the geometry if it is a - linestring or multi-linestring. This is an alias for ST_Length - - - - - - float ST_Length2D - geometry a_2dlinestring - - - - - - Description - - Returns the 2-dimensional length of the geometry if it is a - linestring or multi-linestring. This is an alias for ST_Length - - - - - - See Also - - , - - - - - - ST_Length3D - - Returns the 3-dimensional or 2-dimensional length of the geometry if it is a - linestring or multi-linestring. - - - - - - float ST_Length3D - geometry a_3dlinestring - - - - - - Description - - Returns the 3-dimensional or 2-dimensional length of the geometry if it is a - linestring or multi-linestring. For 2-d lines it will just return the 2-d length (same as ST_Length and ST_Length2D) - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - - Return length in feet for a 3D cable. Note this is in feet because 2249 is - Mass State Plane Feet - -SELECT ST_Length3D(ST_GeomFromText('LINESTRING(743238 2967416 1,743238 2967450 1,743265 2967450 3, -743265.625 2967416 3,743238 2967416 3)',2249)); -st_length3d ------------ -122.704716741457 - - - - - - See Also - - , - - - - - - ST_Length_Spheroid - - Calculates the 2D or 3D length of a linestring/multilinestring on an ellipsoid. This - is useful if the coordinates of the geometry are in - longitude/latitude and a length is desired without reprojection. - - - - - - float ST_Length_Spheroid - geometry a_linestring - spheroid a_spheroid - - - - - - Description - - Calculates the length of a geometry on an ellipsoid. This - is useful if the coordinates of the geometry are in - longitude/latitude and a length is desired without reprojection. - The ellipsoid is a separate database type and can be constructed - as follows: - - SPHEROID[<NAME>,<SEMI-MAJOR - AXIS>,<INVERSE FLATTENING>] - - - SPHEROID["GRS_1980",6378137,298.257222101] - Will return 0 for anything that is not a MULTILINESTRING or LINESTRING - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - Examples - - SELECT ST_Length_Spheroid( geometry_column, - 'SPHEROID["GRS_1980",6378137,298.257222101]' ) - FROM geometry_table; - -SELECT ST_Length_Spheroid( the_geom, sph_m ) As tot_len, -ST_Length_Spheroid(ST_GeometryN(the_geom,1), sph_m) As len_line1, -ST_Length_Spheroid(ST_GeometryN(the_geom,2), sph_m) As len_line2 - FROM (SELECT ST_GeomFromText('MULTILINESTRING((-118.584 38.374,-118.583 38.5), - (-71.05957 42.3589 , -71.061 43))') As the_geom, -CAST('SPHEROID["GRS_1980",6378137,298.257222101]' As spheroid) As sph_m) as foo; - tot_len | len_line1 | len_line2 -------------------+------------------+------------------ - 85204.5207562955 | 13986.8725229309 | 71217.6482333646 - - --3D -SELECT ST_Length_Spheroid( the_geom, sph_m ) As tot_len, -ST_Length_Spheroid(ST_GeometryN(the_geom,1), sph_m) As len_line1, -ST_Length_Spheroid(ST_GeometryN(the_geom,2), sph_m) As len_line2 - FROM (SELECT ST_GeomFromEWKT('MULTILINESTRING((-118.584 38.374 20,-118.583 38.5 30), - (-71.05957 42.3589 75, -71.061 43 90))') As the_geom, -CAST('SPHEROID["GRS_1980",6378137,298.257222101]' As spheroid) As sph_m) as foo; - - tot_len | len_line1 | len_line2 -------------------+-----------------+------------------ - 85204.5259107402 | 13986.876097711 | 71217.6498130292 - - - - - - - See Also - - , , - - - - - - ST_Length2D_Spheroid - - Calculates the 2D length of a linestring/multilinestring on an ellipsoid. This - is useful if the coordinates of the geometry are in - longitude/latitude and a length is desired without reprojection. - - - - - - float ST_Length2D_Spheroid - geometry a_linestring - spheroid a_spheroid - - - - - - Description - - Calculates the 2D length of a geometry on an ellipsoid. This - is useful if the coordinates of the geometry are in - longitude/latitude and a length is desired without reprojection. - The ellipsoid is a separate database type and can be constructed - as follows: - - SPHEROID[<NAME>,<SEMI-MAJOR - AXIS>,<INVERSE FLATTENING>] - - - SPHEROID["GRS_1980",6378137,298.257222101] - Will return 0 for anything that is not a MULTILINESTRING or LINESTRING - This is much like and except it will throw away the Z coordinate in calculations. - - - - - - Examples - - SELECT ST_Length2D_Spheroid( geometry_column, - 'SPHEROID["GRS_1980",6378137,298.257222101]' ) - FROM geometry_table; - -SELECT ST_Length2D_Spheroid( the_geom, sph_m ) As tot_len, -ST_Length2D_Spheroid(ST_GeometryN(the_geom,1), sph_m) As len_line1, -ST_Length2D_Spheroid(ST_GeometryN(the_geom,2), sph_m) As len_line2 - FROM (SELECT ST_GeomFromText('MULTILINESTRING((-118.584 38.374,-118.583 38.5), - (-71.05957 42.3589 , -71.061 43))') As the_geom, -CAST('SPHEROID["GRS_1980",6378137,298.257222101]' As spheroid) As sph_m) as foo; - tot_len | len_line1 | len_line2 -------------------+------------------+------------------ - 85204.5207562955 | 13986.8725229309 | 71217.6482333646 - - --3D Observe same answer -SELECT ST_Length2D_Spheroid( the_geom, sph_m ) As tot_len, -ST_Length2D_Spheroid(ST_GeometryN(the_geom,1), sph_m) As len_line1, -ST_Length2D_Spheroid(ST_GeometryN(the_geom,2), sph_m) As len_line2 - FROM (SELECT ST_GeomFromEWKT('MULTILINESTRING((-118.584 38.374 20,-118.583 38.5 30), - (-71.05957 42.3589 75, -71.061 43 90))') As the_geom, -CAST('SPHEROID["GRS_1980",6378137,298.257222101]' As spheroid) As sph_m) as foo; - - tot_len | len_line1 | len_line2 -------------------+------------------+------------------ - 85204.5207562955 | 13986.8725229309 | 71217.6482333646 - - - - - - - See Also - - , , - - - - - - ST_Length3D_Spheroid - - Calculates the length of a geometry on an ellipsoid, - taking the elevation into account. This is just an alias for ST_Length_Spheroid. - - - - - - float ST_Length3D_Spheroid - geometry a_linestring - spheroid a_spheroid - - - - - - Description - - Calculates the length of a geometry on an ellipsoid, - taking the elevation into account. This is just an alias - for ST_Length_Spheroid. - - Will return 0 for anything that is not a MULTILINESTRING or LINESTRING - This functionis just an alias for ST_Length_Spheroid. - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - - See ST_Length_Spheroid - - - - - See Also - - , , - - - - - - - - - ST_Max_Distance - - Returns the 2-dimensional largest distance between two geometries in - projected units. - - - - - - float ST_Max_Distance - - geometry - g1 - - geometry - g2 - - - - - - Description - - Returns the 2-dimensional maximum cartesian distance between two linestrings in - projected units. - - - - - Examples - - --ALL EXAMPLES current throw NOT YET IMPLEMENTED - - - - See Also - - - - - - - - - ST_OrderingEquals - - Returns true if the given geometries represent the same geometry - and points are in the same directional order. - - - - - - boolean ST_OrderingEquals - geometry A - geometry B - - - - - - Description - - ST_OrderingEquals compares two geometries and t (TRUE) if the - geometries are equal and the coordinates are in the same order; - otherwise it returns f (FALSE). - - - This function is implemented as per the ArcSDE SQL - specification rather than SQL-MM. - http://edndoc.esri.com/arcsde/9.1/sql_api/sqlapi3.htm#ST_OrderingEquals - - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.43 - - - - - - Examples - - SELECT ST_OrderingEquals(ST_GeomFromText('LINESTRING(0 0, 10 10)'), - ST_GeomFromText('LINESTRING(0 0, 5 5, 10 10)')); - st_orderingequals ------------ - f -(1 row) - -SELECT ST_OrderingEquals(ST_GeomFromText('LINESTRING(0 0, 10 10)'), - ST_GeomFromText('LINESTRING(0 0, 0 0, 10 10)')); - st_orderingequals ------------ - t -(1 row) - -SELECT ST_OrderingEquals(ST_Reverse(ST_GeomFromText('LINESTRING(0 0, 10 10)')), - ST_GeomFromText('LINESTRING(0 0, 0 0, 10 10)')); - st_orderingequals ------------ - f -(1 row) - - - - See Also - , - - - - - - ST_Overlaps - - Returns TRUE if the Geometries share space, are of the same dimension, but are not completely contained by each other. - - - - - - boolean ST_Overlaps - geometry A - geometry B - - - - - - Description - - Returns TRUE if the Geometries "spatially - overlap". By that we mean they intersect, but one does not completely contain another. - - Performed by the GEOS module - - Do not call with a GeometryCollection as an argument - - This function call will automatically include a bounding box - comparison that will make use of any indexes that are available on - the geometries. To avoid index use, use the function - _ST_Overlaps. - - NOTE: this is the "allowable" version that returns a - boolean, not an integer. - - OGC SPEC s2.1.1.2 // s2.1.13.3 - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.32 - - - - - - Examples - - --a point on a line is contained by the line and is of a lower dimension, and therefore does not overlap the line - nor crosses - -SELECT ST_Overlaps(a,b) As a_overlap_b, - ST_Crosses(a,b) As a_crosses_b, - ST_Intersects(a, b) As a_intersects_b, ST_Contains(b,a) As b_contains_a -FROM (SELECT ST_GeomFromText('POINT(1 0.5)') As a, ST_GeomFromText('LINESTRING(1 0, 1 1, 3 5)') As b) - As foo - -a_overlap_b | a_crosses_b | a_intersects_b | b_contains_a -------------+-------------+----------------+-------------- -f | f | t | t - ---a line that is partly contained by circle, but not fully is defined as intersecting and crossing, --- but since of different dimension it does not overlap -SELECT ST_Overlaps(a,b) As a_overlap_b, ST_Crosses(a,b) As a_crosses_b, - ST_Intersects(a, b) As a_intersects_b, - ST_Contains(a,b) As a_contains_b -FROM (SELECT ST_Buffer(ST_GeomFromText('POINT(1 0.5)'), 3) As a, ST_GeomFromText('LINESTRING(1 0, 1 1, 3 5)') As b) - As foo; - - a_overlap_b | a_crosses_b | a_intersects_b | a_contains_b --------------+-------------+----------------+-------------- - f | t | t | f - - -- a 2-dimensional bent hot dog (aka puffered line string) that intersects a circle, - -- but is not fully contained by the circle is defined as overlapping since they are of the same dimension, --- but it does not cross, because the intersection of the 2 is of the same dimension --- as the maximum dimension of the 2 - -SELECT ST_Overlaps(a,b) As a_overlap_b, ST_Crosses(a,b) As a_crosses_b, ST_Intersects(a, b) As a_intersects_b, -ST_Contains(b,a) As b_contains_a, -ST_Dimension(a) As dim_a, ST_Dimension(b) as dim_b, ST_Dimension(ST_Intersection(a,b)) As dima_intersection_b -FROM (SELECT ST_Buffer(ST_GeomFromText('POINT(1 0.5)'), 3) As a, - ST_Buffer(ST_GeomFromText('LINESTRING(1 0, 1 1, 3 5)'),0.5) As b) - As foo; - - a_overlap_b | a_crosses_b | a_intersects_b | b_contains_a | dim_a | dim_b | dima_intersection_b --------------+-------------+----------------+--------------+-------+-------+--------------------- - t | f | t | f | 2 | 2 | 2 - - - - - See Also - - , , , - - - - - ST_Perimeter - - Return the length measurement of the boundary of an ST_Surface - or ST_MultiSurface value. (Polygon, Multipolygon) - - - - - float ST_Perimeter - geometry g1 - - - - - Description - - Returns the 2D perimeter of the geometry if it is a ST_Surface, ST_MultiSurface (Polygon, Multipolygon). 0 is returned for - non-areal geometries. For linestrings use ST_Length. Measurements are in the units of the - spatial reference system of the geometry. - - Currently this is an alias for ST_Perimeter2D, but this may change to support higher dimensions. - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC 2.1.5.1 - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 8.1.3, 9.5.4 - - - - Examples - Return perimeter in feet for polygon and multipolygon. Note this is in feet because 2249 is - Mass State Plane Feet - -SELECT ST_Perimeter(ST_GeomFromText('POLYGON((743238 2967416,743238 2967450,743265 2967450, -743265.625 2967416,743238 2967416))', 2249)); -st_perimeter ---------- - 122.630744000095 -(1 row) - -SELECT ST_Perimeter(ST_GeomFromText('MULTIPOLYGON(((763104.471273676 2949418.44119003, -763104.477769673 2949418.42538203, -763104.189609677 2949418.22343004,763104.471273676 2949418.44119003)), -((763104.471273676 2949418.44119003,763095.804579742 2949436.33850239, -763086.132105649 2949451.46730207,763078.452329651 2949462.11549407, -763075.354136904 2949466.17407812,763064.362142565 2949477.64291974, -763059.953961626 2949481.28983009,762994.637609571 2949532.04103014, -762990.568508415 2949535.06640477,762986.710889563 2949539.61421415, -763117.237897679 2949709.50493431,763235.236617789 2949617.95619822, -763287.718121842 2949562.20592617,763111.553321674 2949423.91664605, -763104.471273676 2949418.44119003)))', 2249)); -st_perimeter ---------- - 845.227713366825 -(1 row) - - - - See Also - - - - - - - ST_Perimeter2D - - Returns the 2-dimensional perimeter of the geometry, if it - is a polygon or multi-polygon. This is currently an alias for ST_Perimeter. - - - - - - float ST_Perimeter2D - geometry geomA - - - - - - Description - - Returns the 2-dimensional perimeter of the geometry, if it - is a polygon or multi-polygon. - - - - This is currently an alias for ST_Perimeter. In future versions ST_Perimeter may return the highest dimension perimeter for a geometry. This is still under consideration - - - - - - See Also - - - - - - - - ST_Perimeter3D - - Returns the 3-dimensional perimeter of the geometry, if it - is a polygon or multi-polygon. - - - - - - float ST_Perimeter3D - geometry geomA - - - - - - Description - - Returns the 3-dimensional perimeter of the geometry, if it - is a polygon or multi-polygon. If the geometry is 2-dimensional, then the 2-dimensional perimeter is returned. - - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - Perimeter of a slightly elevated polygon in the air in Massachusetts state plane feet - SELECT ST_Perimeter3D(the_geom), ST_Perimeter2d(the_geom), ST_Perimeter(the_geom) FROM - (SELECT ST_GeomFromEWKT('SRID=2249;POLYGON((743238 2967416 2,743238 2967450 1, -743265.625 2967416 1,743238 2967416 2))') As the_geom) As foo; - - st_perimeter3d | st_perimeter2d | st_perimeter -------------------+------------------+------------------ - 105.465793597674 | 105.432997272188 | 105.432997272188 - - - - - - - See Also - - , , - - - - - - ST_PointOnSurface - - Returns a POINT guaranteed to lie on the surface. - - - - - - geometry ST_PointOnSurface - - geometry - g1 - - - - - - Description - - Returns a POINT guaranteed to intersect a surface. - - - - - - This method implements the OpenGIS Simple - Features Implementation Specification for SQL: 3.2.14.2, 3.2.18.2 - - - - - - This method implements the SQL/MM - specification: SQL-MM 3: 8.1.5, 9.5.6. - According to the specs, ST_PointOnSurface works for surface geometries (POLYGONs, MULTIPOLYGONS, CURVED POLYGONS). So PostGIS seems to be extending what - the spec allows here. Most databases Oracle,DB II, ESRI SDE seem to only support this function for surfaces. SQL Server 2008 like PostGIS supports for all common geometries. - - - - - - - - This function supports 3d (only for POINT,MULTIPOINT, LINESTRING, MULTILINESTRING) and will not drop the z-index. - - - - Examples - - SELECT ST_AsText(ST_PointOnSurface('POINT(0 5)'::geometry)); - st_astext ------------- - POINT(0 5) -(1 row) - -SELECT ST_AsText(ST_PointOnSurface('LINESTRING(0 5, 0 10)'::geometry)); - st_astext ------------- - POINT(0 5) -(1 row) - -SELECT ST_AsText(ST_PointOnSurface('POLYGON((0 0, 0 5, 5 5, 5 0, 0 0))'::geometry)); - st_astext ----------------- - POINT(2.5 2.5) -(1 row) - -SELECT ST_AsEWKT(ST_PointOnSurface(ST_GeomFromEWKT('LINESTRING(0 5 1, 0 0 1, 0 10 2)'))); - st_asewkt ----------------- - POINT(0 0 1) -(1 row) - - - - - See Also - - , - - - - - - ST_Relate - - Returns true if this Geometry is spatially related to - anotherGeometry, by testing for intersections between the - Interior, Boundary and Exterior of the two geometries as specified - by the values in the intersectionMatrixPattern. If no intersectionMatrixPattern - is passed in, then returns the maximum intersectionMatrixPattern that relates the 2 geometries. - - - - - - boolean ST_Relate - geometry geomA - geometry geomB - text intersectionMatrixPattern - - - - text ST_Relate - geometry geomA - geometry geomB - - - - - - - Description - - Version 1: Takes geomA, geomB, intersectionMatrix and Returns 1 (TRUE) if this Geometry is spatially related to - anotherGeometry, by testing for intersections between the - Interior, Boundary and Exterior of the two geometries as specified - by the values in the intersectionMatrixPattern. - - This is especially useful for testing compound checks of intersection, crosses, etc in one step. - Do not call with a GeometryCollection as an argument - - This is the "allowable" version that returns a - boolean, not an integer. This is defined in OGC spec - - This DOES NOT automagically include an index call. The reason for that - is some relationships are anti e.g. Disjoint. If you are - using a relationship pattern that requires intersection, then include the && - index call. - - Version 2: Takes geomA and geomB and returns the DE-9IM (dimensionally extended nine-intersection - matrix) - - Do not call with a GeometryCollection as an argument - - not in OGC spec, but implied. see s2.1.13.2 - - Both Performed by the GEOS module - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC s2.1.1.2 // s2.1.13.3 - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.25 - - - - - - Examples - ---Find all compounds that intersect and not touch a poly (interior intersects) -SELECT l.* , b.name As poly_name -FROM polys As b - INNER JOIN compounds As l - ON (p.the_geom && b.the_geom - AND ST_Relate(l.the_geom, b.the_geom,'T********')); - -SELECT ST_Relate(ST_GeometryFromText('POINT(1 2)'), ST_Buffer(ST_GeometryFromText('POINT(1 2)'),2)); - st_relate ------------ - 0FFFFF212 - -SELECT ST_Relate(ST_GeometryFromText('LINESTRING(1 2, 3 4)'), ST_GeometryFromText('LINESTRING(5 6, 7 8)')); - st_relate ------------ - FF1FF0102 - - -SELECT ST_Relate(ST_GeometryFromText('POINT(1 2)'), ST_Buffer(ST_GeometryFromText('POINT(1 2)'),2), '0FFFFF212'); - st_relate ------------ - t - -SELECT ST_Relate(ST_GeometryFromText('POINT(1 2)'), ST_Buffer(ST_GeometryFromText('POINT(1 2)'),2), '*FF*FF212'); - st_relate ------------ - t - - - - - - See Also - - , , , - - - - - - ST_Touches - - Returns TRUE if the geometries have at least one point in common, - but their interiors do not intersect. - - - - - - boolean ST_Touches - - geometry - g1 - - geometry - g2 - - - - - - Description - - Returns TRUE if the only points in common between - g1 and g2 lie in the union of the - boundaries of g1 and g2. - The ST_Touches relation applies - to all Area/Area, Line/Line, Line/Area, Point/Area and Point/Line pairs of relationships, - but not to the Point/Point pair. - - In mathematical terms, this predicate is expressed as: - - TODO: Insert appropriate MathML markup here or use a gif. - Simple HTML markup does not work well in both IE and Firefox. - - - - - - - - - - The allowable DE-9IM Intersection Matrices for the two geometries are: - - - - FT******* - - - - F**T***** - - - - F***T**** - - - - - Do not call with a GEOMETRYCOLLECTION as an argument - - - - This function call will automatically include a bounding box - comparison that will make use of any indexes that are available on - the geometries. To avoid using an index, use _ST_Touches instead. - - - - - - - This method implements the OpenGIS Simple - Features Implementation Specification for SQL: 2.1.1.2, 2.1.13.3 - - - - - - This method implements the SQL/MM - specification: SQL-MM 3: 5.1.28 - - - - Examples - - The ST_Touches predicate returns TRUE in all the following illustrations. - - - - - - - - - - - POLYGON / POLYGON - - - - - - - - - - POLYGON / POLYGON - - - - - - - - - - POLYGON / LINESTRING - - - - - - - - - - - LINESTRING / LINESTRING - - - - - - - - - - LINESTRING / LINESTRING - - - - - - - - - - POLYGON / POINT - - - - - - - - SELECT ST_Touches('LINESTRING(0 0, 1 1, 0 2)'::geometry, 'POINT(1 1)'::geometry); - st_touches ------------- - f -(1 row) - -SELECT ST_Touches('LINESTRING(0 0, 1 1, 0 2)'::geometry, 'POINT(0 2)'::geometry); - st_touches ------------- - t -(1 row) - - - - - - ST_Within - - Returns true if the geometry A is completely inside geometry B - - - - - - boolean ST_Within - - geometry - A - - geometry - B - - - - - - Description - - Returns TRUE if geometry A is completely inside geometry B. For this function to make - sense, the source geometries must both be of the same coordinate projection, - having the same SRID. It is a given that if ST_Within(A,B) is true and ST_Within(B,A) is true, then - the two geometries are considered spatially equal. - - Performed by the GEOS module - - - Do not call with a GEOMETRYCOLLECTION as an argument - - - - Do not use this function with invalid geometries. You will get unexpected results. - - - This function call will automatically include a bounding box - comparison that will make use of any indexes that are available on - the geometries. To avoid index use, use the function - _ST_Within. - - NOTE: this is the "allowable" version that returns a - boolean, not an integer. - - - - - - - This method implements the - OpenGIS Simple Features - Implementation Specification for SQL. - OGC SPEC s2.1.1.2 // s2.1.13.3 - a.Relate(b, - 'T*F**F***') - - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.30 - - - - Examples - ---a circle within a circle -SELECT ST_Within(smallc,smallc) As smallinsmall, - ST_Within(smallc, bigc) As smallinbig, - ST_Within(bigc,smallc) As biginsmall, - ST_Within(ST_Union(smallc, bigc), bigc) as unioninbig, - ST_Within(bigc, ST_Union(smallc, bigc)) as biginunion, - ST_Equals(bigc, ST_Union(smallc, bigc)) as bigisunion -FROM -( -SELECT ST_Buffer(ST_GeomFromText('POINT(50 50)'), 20) As smallc, - ST_Buffer(ST_GeomFromText('POINT(50 50)'), 40) As bigc) As foo; ---Result - smallinsmall | smallinbig | biginsmall | unioninbig | biginunion | bigisunion ---------------+------------+------------+------------+------------+------------ - t | t | f | t | t | t -(1 row) - - - - - - - - - - - See Also - , , - - - - - - Geometry Processing Functions - - - ST_Buffer - - (T) For geometry: Returns a geometry that represents all points whose distance - from this Geometry is less than or equal to distance. Calculations - are in the Spatial Reference System of this Geometry. For geography: Uses a planar transform wrapper. Introduced in 1.5 support for - different end cap and mitre settings to control shape. buffer_style options: quad_segs=#,endcap=round|flat|square,join=round|mitre|bevel,mitre_limit=#.# - - - - - - - geometry ST_Buffer - geometry g1 - float radius_of_buffer - - - - geometry ST_Buffer - geometry g1 - float radius_of_buffer - integer num_seg_quarter_circle - - - - geometry ST_Buffer - geometry g1 - float radius_of_buffer - text buffer_style_parameters - - - - geography ST_Buffer - geography g1 - float radius_of_buffer_in_meters - - - - - - - Description - - Returns a geometry/geography that represents all points whose distance - from this Geometry/geography is less than or equal to distance. - Geometry: Calculations - are in the Spatial Reference System of the geometry. Introduced in 1.5 support for - different end cap and mitre settings to control shape. - Geography: For geography this is really a thin wrapper around the geometry implementation. It first determines the best SRID that - fits the bounding box of the geography object (favoring UTM, polar stereographic and falling back on mercator in worst case scenario) and then buffers in that planar spatial ref and retransforms back to WGS84 geography. - - For geography this may not behave as expected if object is sufficiently large that it falls between two UTM zones or crosses the dateline - Availability: 1.5 - ST_Buffer was enhanced to support different endcaps and join types. These are useful for example to convert road linestrings - into polygon roads with flat or square edges instead of rounded edges. Thin wrapper for geography was added. - requires GEOS >= 3.2 to take advantage of advanced geometry functionality. - - -The optional third parameter (currently only applies to geometry) can either specify number of segments used to approximate a quarter circle (integer case, defaults to 8) or a list of blank-separated key=value pairs (string case) to tweak operations as follows: - - -'quad_segs=#' : number of segments used to approximate a quarter circle (defaults to 8). - - -'endcap=round|flat|square' : endcap style (defaults to "round", needs GEOS-3.2 or higher for a different value). 'butt' is also accepted as a synonym for 'flat'. - - -'join=round|mitre|bevel' : join style (defaults to "round", needs GEOS-3.2 or higher for a different value). 'miter' is also accepted as a synonym for 'mitre'. - - -'mitre_limit=#.#' : mitre ratio limit (only affects mitred join style). 'miter_limit' is also accepted as a synonym for 'mitre_limit'. - - - - - Units of radius are measured in units of the spatial reference system. - The inputs can be POINTS, MULTIPOINTS, LINESTRINGS, MULTILINESTRINGS, POLYGONS, MULTIPOLYGONS, and GeometryCollections. - This function ignores the third dimension (z) and will always give a 2-d buffer even when presented with a 3d-geometry. - - Performed by the GEOS module. - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - OGC SPEC s2.1.1.3 - - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.17 - - People often make the mistake of using this function to try to do radius searches. Creating a - buffer to to a radius search is slow and pointless. Use instead. - - - - Examples - - - - - - - - - - - quad_segs=8 (default) - - - -SELECT ST_Buffer( - ST_GeomFromText('POINT(100 90)'), - 50, 'quad_segs=8'); - - - - - - - - - quad_segs=2 (lame) - - - -SELECT ST_Buffer( - ST_GeomFromText('POINT(100 90)'), - 50, 'quad_segs=2'); - - - - - - - - - - endcap=round join=round (default) - - - -SELECT ST_Buffer( - ST_GeomFromText( - 'LINESTRING(50 50,150 150,150 50)' - ), 10, 'endcap=round join=round'); - - - - - - - - - endcap=square - - - -SELECT ST_Buffer( - ST_GeomFromText( - 'LINESTRING(50 50,150 150,150 50)' - ), 10, 'endcap=square join=round'); - - - - - - - - - endcap=flat - - - -SELECT ST_Buffer( - ST_GeomFromText( - 'LINESTRING(50 50,150 150,150 50)' - ), 10, 'endcap=flat join=round'); - - - - - - - - - - join=bevel - - - -SELECT ST_Buffer( - ST_GeomFromText( - 'LINESTRING(50 50,150 150,150 50)' - ), 10, 'join=bevel'); - - - - - - - - - join=mitre mitre_limit=5.0 (default mitre limit) - - - -SELECT ST_Buffer( - ST_GeomFromText( - 'LINESTRING(50 50,150 150,150 50)' - ), 10, 'join=mitre mitre_limit=5.0'); - - - - - - - - - join=mitre mitre_limit=1 - - - -SELECT ST_Buffer( - ST_GeomFromText( - 'LINESTRING(50 50,150 150,150 50)' - ), 10, 'join=mitre mitre_limit=1.0'); - - - - - - - ---A buffered point approximates a circle --- A buffered point forcing approximation of (see diagram) --- 2 points per circle is poly with 8 sides (see diagram) -SELECT ST_NPoints(ST_Buffer(ST_GeomFromText('POINT(100 90)'), 50)) As promisingcircle_pcount, -ST_NPoints(ST_Buffer(ST_GeomFromText('POINT(100 90)'), 50, 2)) As lamecircle_pcount; - -promisingcircle_pcount | lamecircle_pcount -------------------------+------------------- - 33 | 9 - ---A lighter but lamer circle --- only 2 points per quarter circle is an octagon ---Below is a 100 meter octagon --- Note coordinates are in NAD 83 long lat which we transform -to Mass state plane meter and then buffer to get measurements in meters; -SELECT ST_AsText(ST_Buffer( -ST_Transform( -ST_SetSRID(ST_MakePoint(-71.063526, 42.35785),4269), 26986) -,100,2)) As octagon; ----------------------- -POLYGON((236057.59057465 900908.759918696,236028.301252769 900838.049240578,235 -957.59057465 900808.759918696,235886.879896532 900838.049240578,235857.59057465 -900908.759918696,235886.879896532 900979.470596815,235957.59057465 901008.759918 -696,236028.301252769 900979.470596815,236057.59057465 900908.759918696)) - ---Buffer is often also used as a poor man's polygon fixer or a sometimes speedier unioner ---Sometimes able to fix invalid polygons - using below --- using below on anything but a polygon will result in empty geometry --- and for geometry collections kill anything in the collection that is not a polygon ---Poor man's bad poly fixer -SELECT ST_IsValid(foo.invalidpoly) as isvalid, ST_IsValid(ST_Buffer(foo.invalidpoly,0.0)) as bufferisvalid, -ST_AsText(ST_Buffer(foo.invalidpoly,0.0)) As newpolytextrep -FROM (SELECT ST_GeomFromText('POLYGON((-1 2, 3 4, 5 6, -1 2, 5 6, -1 2))') as invalidpoly) As foo -NOTICE: Self-intersection at or near point -1 2 -isvalid | bufferisvalid | newpolytextrep ----------+---------------+------------------------------ -f | t | POLYGON((-1 2,5 6,3 4,-1 2)) - ---Poor man's polygon unioner -SELECT ST_AsText(the_geom) as textorig, ST_AsText(ST_Buffer(foo.the_geom,0.0)) As textbuffer -FROM (SELECT ST_Collect('POLYGON((-1 2, 3 4, 5 6, -1 2))', 'POLYGON((-1 2, 2 3, 5 6, -1 2))') As the_geom) as foo; - textorig | textbuffer ------------------------------------------------------------+-------------------- -MULTIPOLYGON(((-1 2,3 4,5 6,-1 2)),((-1 2,2 3,5 6,-1 2))) | POLYGON((-1 2,5 6,3 4,2 3,-1 2)) - - - - - - - See Also - - , , , , - - - - - - ST_BuildArea - - Creates an areal geometry formed by the constituent linework - of given geometry - - - - - - geometry ST_BuildArea - geometry A - - - - - - Description - - Creates an areal geometry formed by the constituent linework - of given geometry. The return type can be a Polygon or - MultiPolygon, depending on input. If the input lineworks do not - form polygons NULL is returned. The inputs can be LINESTRINGS, MULTILINESTRINGS, POLYGONS, MULTIPOLYGONS, and GeometryCollections. - - This function will assume all inner geometries represent holes - Availability: 1.1.0 - requires GEOS >= 2.1.0. - - - - Examples - - - - - - - - - - This will create a donut - - - -SELECT ST_BuildArea(ST_Collect(smallc,bigc)) -FROM (SELECT - ST_Buffer( - ST_GeomFromText('POINT(100 90)'), 25) As smallc, - ST_Buffer(ST_GeomFromText('POINT(100 90)'), 50) As bigc) As foo; - - - - - - - - - - This will create a gaping hole inside the circle with prongs sticking out - - - -SELECT ST_BuildArea(ST_Collect(line,circle)) -FROM (SELECT - ST_Buffer( - ST_MakeLine(ST_MakePoint(10, 10),ST_MakePoint(190, 190)), - 5) As line, - ST_Buffer(ST_GeomFromText('POINT(100 90)'), 50) As circle) As foo; - ---this creates the same gaping hole ---but using linestrings instead of polygons -SELECT ST_BuildArea( - ST_Collect(ST_ExteriorRing(line),ST_ExteriorRing(circle)) - ) -FROM (SELECT ST_Buffer( - ST_MakeLine(ST_MakePoint(10, 10),ST_MakePoint(190, 190)) - ,5) As line, - ST_Buffer(ST_GeomFromText('POINT(100 90)'), 50) As circle) As foo; - - - - - - - - - - - See Also - - - , - wrappers to - this function with standard OGC interface - - - - - ST_Collect - Return a specified ST_Geometry value from a collection of other geometries. - - - - - - geometry ST_Collect - geometry set g1field - - - geometry ST_Collect - geometry g1 - geometry g2 - - - geometry ST_Collect - geometry[] g1_array - - - - - - Description - Output type can be a MULTI* or a - GEOMETRYCOLLECTION. Comes in 2 variants. Variant 1 collects 2 geometries. Variant 2 is an aggregate function that takes a set of geometries and collects - them into a single ST_Geometry. - - Aggregate version: This function returns a GEOMETRYCOLLECTION or a MULTI object - from a set of geometries. The ST_Collect() function is an "aggregate" - function in the terminology of PostgreSQL. That means that it - operates on rows of data, in the same way the SUM() and AVG() - functions do. For example, "SELECT ST_Collect(GEOM) FROM GEOMTABLE - GROUP BY ATTRCOLUMN" will return a separate GEOMETRYCOLLECTION for - each distinct value of ATTRCOLUMN. - - Non-Aggregate version: This function returns a geometry being a collection of two - input geometries. Output type can be a MULTI* or a - GEOMETRYCOLLECTION. - - ST_Collect and ST_Union are often interchangeable. - ST_Collect is in general orders of magnitude faster than ST_Union - because it does not try to dissolve boundaries or validate that a constructed MultiPolgon doesn't - have overlapping regions. It merely rolls up - single geometries into MULTI and MULTI or mixed geometry types - into Geometry Collections. Unfortunately geometry collections are - not well-supported by GIS tools. To prevent ST_Collect from - returning a Geometry Collection when collecting MULTI geometries, - one can use the below trick that utilizes to expand the - MULTIs out to singles and then regroup them. - - Availability: 1.4.0 - ST_Collect(geomarray) was introduced. ST_Collect was enhanced to handle more geometries faster. - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves, - but will never return a MULTICURVE or MULTI as one would expect and PostGIS does not currently support those. - - - - Examples - Aggregate example - Thread ref: http://postgis.refractions.net/pipermail/postgis-users/2008-June/020331.html -SELECT stusps, - ST_Multi(ST_Collect(f.the_geom)) as singlegeom - FROM (SELECT stusps, (ST_Dump(the_geom)).geom As the_geom - FROM - somestatetable ) As f -GROUP BY stusps - Non-Aggregate example - Thread ref: http://postgis.refractions.net/pipermail/postgis-users/2008-June/020331.html -SELECT ST_AsText(ST_Collect(ST_GeomFromText('POINT(1 2)'), - ST_GeomFromText('POINT(-2 3)') )); - -st_astext ----------- -MULTIPOINT(1 2,-2 3) - ---Collect 2 d points -SELECT ST_AsText(ST_Collect(ST_GeomFromText('POINT(1 2)'), - ST_GeomFromText('POINT(1 2)') ) ); - -st_astext ----------- -MULTIPOINT(1 2,1 2) - ---Collect 3d points -SELECT ST_AsEWKT(ST_Collect(ST_GeomFromEWKT('POINT(1 2 3)'), - ST_GeomFromEWKT('POINT(1 2 4)') ) ); - - st_asewkt -------------------------- - MULTIPOINT(1 2 3,1 2 4) - - --Example with curves -SELECT ST_AsText(ST_Collect(ST_GeomFromText('CIRCULARSTRING(220268 150415,220227 150505,220227 150406)'), -ST_GeomFromText('CIRCULARSTRING(220227 150406,2220227 150407,220227 150406)'))); - st_astext ------------------------------------------------------------------------------------- - GEOMETRYCOLLECTION(CIRCULARSTRING(220268 150415,220227 150505,220227 150406), - CIRCULARSTRING(220227 150406,2220227 150407,220227 150406)) - ---New ST_Collect array construct -SELECT ST_Collect(ARRAY(SELECT the_geom FROM sometable)); - -SELECT ST_AsText(ST_Collect(ARRAY[ST_GeomFromText('LINESTRING(1 2, 3 4)'), - ST_GeomFromText('LINESTRING(3 4, 4 5)')])) As wktcollect; - ---wkt collect -- -MULTILINESTRING((1 2,3 4),(3 4,4 5)) - - - - - See Also - , - - - - - - ST_ConvexHull - The convex hull of a geometry represents the minimum convex - geometry that encloses all geometries within the set. - - - - - - geometry ST_ConvexHull - geometry geomA - - - - - - Description - The convex hull of a geometry represents the minimum convex - geometry that encloses all geometries within the set. - - One can think of the convex hull as the geometry you get by wrapping an elastic - band around a set of geometries. This is different from a concave hull (not currently supported) - which is analogous to shrink-wrapping your geometries. - - It is usually used with MULTI and Geometry Collections. - Although it is not an aggregate - you can use it in conjunction - with ST_Collect to get the convex hull of a set of points. - ST_ConvexHull(ST_Collect(somepointfield)). - - It is often used to - determine an affected area based on a set of point - observations. - - Performed by the GEOS module - - - - This method implements the - OpenGIS Simple - Features Implementation Specification for SQL OGC SPEC s2.1.1.3 - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.16 - - - - - Examples - ---Get estimate of infected area based on point observations -SELECT d.disease_type, - ST_ConvexHull(ST_Collect(d.the_geom)) As the_geom - FROM disease_obs As d - GROUP BY d.disease_type; - - - - - - - - - Convex Hull of a MultiLinestring and a MultiPoint seen together with the MultiLinestring and MultiPoint - - - -SELECT ST_AsText(ST_ConvexHull( - ST_Collect( - ST_GeomFromText('MULTILINESTRING((100 190,10 8),(150 10, 20 30))'), - ST_GeomFromText('MULTIPOINT(50 5, 150 30, 50 10, 10 10)') - )) ); ----st_astext-- -POLYGON((50 5,10 8,10 10,100 190,150 30,150 10,50 5)) - - - - - See Also - , - - - - - - ST_CurveToLine - - Converts a CIRCULARSTRING/CURVEDPOLYGON to a LINESTRING/POLYGON - - - - - - geometry ST_CurveToLine - geometry curveGeom - - - geometry ST_CurveToLine - geometry curveGeom - integer segments_per_qtr_circle - - - - - - Description - - Converst a CIRCULAR STRING to regular LINESTRING or CURVEPOLYGON to POLYGON. Useful for outputting to devices that can't support CIRCULARSTRING geometry types - Converts a given geometry to a linear geometry. - Each curved geometry or segment is converted into a linear approximation using the default value of 32 segments per quarter circle - Availability: 1.2.2? - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 7.1.7 - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - SELECT ST_AsText(ST_CurveToLine(ST_GeomFromText('CIRCULARSTRING(220268 150415,220227 150505,220227 150406)'))); - ---Result -- - LINESTRING(220268 150415,220269.95064912 150416.539364228,220271.823415575 150418.17258804,220273.613787707 150419.895736857, - 220275.317452352 150421.704659462,220276.930305234 150423.594998003,220278.448460847 150425.562198489, - 220279.868261823 150427.60152176,220281.186287736 150429.708054909,220282.399363347 150431.876723113, - 220283.50456625 150434.10230186,220284.499233914 150436.379429536,220285.380970099 150438.702620341,220286.147650624 150441.066277505, - 220286.797428488 150443.464706771,220287.328738321 150445.892130112,220287.740300149 150448.342699654, - 220288.031122486 150450.810511759,220288.200504713 150453.289621251,220288.248038775 150455.77405574, - 220288.173610157 150458.257830005,220287.977398166 150460.734960415,220287.659875492 150463.199479347, - 220287.221807076 150465.64544956,220286.664248262 150468.066978495,220285.988542259 150470.458232479,220285.196316903 150472.81345077, - 220284.289480732 150475.126959442,220283.270218395 150477.39318505,220282.140985384 150479.606668057, - 220280.90450212 150481.762075989,220279.5637474 150483.85421628,220278.12195122 150485.87804878, - 220276.582586992 150487.828697901,220274.949363179 150489.701464356,220273.226214362 150491.491836488, - 220271.417291757 150493.195501133,220269.526953216 150494.808354014,220267.559752731 150496.326509628, - 220265.520429459 150497.746310603,220263.41389631 150499.064336517,220261.245228106 150500.277412127, - 220259.019649359 150501.38261503,220256.742521683 150502.377282695,220254.419330878 150503.259018879, - 220252.055673714 150504.025699404,220249.657244448 150504.675477269,220247.229821107 150505.206787101, - 220244.779251566 150505.61834893,220242.311439461 150505.909171266,220239.832329968 150506.078553494, - 220237.347895479 150506.126087555,220234.864121215 150506.051658938,220232.386990804 150505.855446946, - 220229.922471872 150505.537924272,220227.47650166 150505.099855856,220225.054972724 150504.542297043, - 220222.663718741 150503.86659104,220220.308500449 150503.074365683, - 220217.994991777 150502.167529512,220215.72876617 150501.148267175, - 220213.515283163 150500.019034164,220211.35987523 150498.7825509, - 220209.267734939 150497.441796181,220207.243902439 150496, - 220205.293253319 150494.460635772,220203.420486864 150492.82741196,220201.630114732 150491.104263143, - 220199.926450087 150489.295340538,220198.313597205 150487.405001997,220196.795441592 150485.437801511, - 220195.375640616 150483.39847824,220194.057614703 150481.291945091,220192.844539092 150479.123276887,220191.739336189 150476.89769814, - 220190.744668525 150474.620570464,220189.86293234 150472.297379659,220189.096251815 150469.933722495, - 220188.446473951 150467.535293229,220187.915164118 150465.107869888,220187.50360229 150462.657300346, - 220187.212779953 150460.189488241,220187.043397726 150457.710378749,220186.995863664 150455.22594426, - 220187.070292282 150452.742169995,220187.266504273 150450.265039585,220187.584026947 150447.800520653, - 220188.022095363 150445.35455044,220188.579654177 150442.933021505,220189.25536018 150440.541767521, - 220190.047585536 150438.18654923,220190.954421707 150435.873040558,220191.973684044 150433.60681495, - 220193.102917055 150431.393331943,220194.339400319 150429.237924011,220195.680155039 150427.14578372,220197.12195122 150425.12195122, - 220198.661315447 150423.171302099,220200.29453926 150421.298535644,220202.017688077 150419.508163512,220203.826610682 150417.804498867, - 220205.716949223 150416.191645986,220207.684149708 150414.673490372,220209.72347298 150413.253689397,220211.830006129 150411.935663483, - 220213.998674333 150410.722587873,220216.22425308 150409.61738497,220218.501380756 150408.622717305,220220.824571561 150407.740981121, - 220223.188228725 150406.974300596,220225.586657991 150406.324522731,220227 150406) - ---3d example -SELECT ST_AsEWKT(ST_CurveToLine(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)'))); -Output ------- - LINESTRING(220268 150415 1,220269.95064912 150416.539364228 1.0181172856673, - 220271.823415575 150418.17258804 1.03623457133459,220273.613787707 150419.895736857 1.05435185700189,....AD INFINITUM .... - 220225.586657991 150406.324522731 1.32611114201132,220227 150406 3) - ---use only 2 segments to approximate quarter circle -SELECT ST_AsText(ST_CurveToLine(ST_GeomFromText('CIRCULARSTRING(220268 150415,220227 150505,220227 150406)'),2)); -st_astext ------------------------------- - LINESTRING(220268 150415,220287.740300149 150448.342699654,220278.12195122 150485.87804878, - 220244.779251566 150505.61834893,220207.243902439 150496,220187.50360229 150462.657300346, - 220197.12195122 150425.12195122,220227 150406) - - - - - - - - See Also - - - - - - - - ST_Difference - - Returns a geometry that represents that part of geometry A - that does not intersect with geometry B. - - - - - - geometry ST_Difference - geometry geomA - geometry geomB - - - - - - Description - - Returns a geometry that represents that part of geometry A - that does not intersect with geometry B. One can think of this as GeometryA - ST_Intersection(A,B). If A is completely contained in B - then an empty geometry collection is returned. - Note - order matters. B - A will always return a portion of B - - Performed by the GEOS module - - Do not call with a GeometryCollection as an argument - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC s2.1.1.3 - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.20 - - - - - - - This function supports 3d and will not drop the z-index. - However it seems to only consider x y when doing the difference and tacks back on the Z-Index - - - - - Examples - - - - - - - - - - - - The original linestrings shown together. - - - - - - - - - - - - The difference of the two linestrings - - - - - - - - - ---Safe for 2d. This is same geometries as what is shown for st_symdifference -SELECT ST_AsText( - ST_Difference( - ST_GeomFromText('LINESTRING(50 100, 50 200)'), - ST_GeomFromText('LINESTRING(50 50, 50 150)') - ) - ); - -st_astext ---------- -LINESTRING(50 150,50 200) - - - - ---When used in 3d doesn't quite do the right thing -SELECT ST_AsEWKT(ST_Difference(ST_GeomFromEWKT('MULTIPOINT(-118.58 38.38 5,-118.60 38.329 6,-118.614 38.281 7)'), ST_GeomFromEWKT('POINT(-118.614 38.281 5)'))); -st_asewkt ---------- -MULTIPOINT(-118.6 38.329 6,-118.58 38.38 5) - - - - - - See Also - - - - - - - - ST_Dump - Returns a set of geometry_dump (geom,path) rows, that make up a geometry g1. - - - - - - geometry_dump[]ST_Dump - geometry g1 - - - - - - Description - This is a set-returning function (SRF). It returns a set of - geometry_dump rows, formed by a geometry (geom) and an array of - integers (path). When the input geometry is a simple type - (POINT,LINESTRING,POLYGON) a single record will be returned with - an empty path array and the input geometry as geom. When the input - geometry is a collection or multi it will return a record for each - of the collection components, and the path will express the - position of the component inside the collection. - - ST_Dump is useful for expanding geometries. It is the - reverse of a GROUP BY in that it creates new rows. For example it - can be use to expand MULTIPOLYGONS into POLYGONS. - - Availability: PostGIS 1.0.0RC1. Requires PostgreSQL 7.3 or higher. - Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and Curves - - - - Examples - SELECT sometable.field1, sometable.field1, - (ST_Dump(sometable.the_geom)).geom As the_geom -FROM sometable; - ---Break a compound curve into its constituent linestrings and circularstrings -SELECT ST_AsEWKT(a.geom), ST_HasArc(a.geom) - FROM ( SELECT (ST_Dump(p_geom)).geom as geom - FROM (SELECT ST_GeomFromEWKT('COMPOUNDCURVE(CIRCULARSTRING(0 0, 1 1, 1 0),(1 0, 0 1))') as p_geom) as b - ) as a; - st_asewkt | st_hasarc ------------------------------+---------- - CIRCULARSTRING(0 0,1 1,1 0) | t - LINESTRING(1 0,0 1) | f -(2 rows) - - - - - - See Also - , - - - - - - ST_DumpRings - - Returns a set of geometry_dump rows, representing - the exterior and interior rings of a polygon. - - - - - - geometry_dump[] ST_DumpRings - geometry a_polygon - - - - - - Description - - This is a set-returning function (SRF). It returns a set of - geometry_dump rows, defined as an integer[] - and a geometry, aliased "path" and "geom" respectively. - The "path" field holds the polygon ring index containing a single integer: 0 for the shell, >0 for holes. - The "geom" field contains the corresponding ring as a polygon. - - Availability: PostGIS 1.1.3. Requires PostgreSQL 7.3 or higher. - This only works for POLYGON geometries. It will not work for MULTIPOLYGONS - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - - SELECT sometable.field1, sometable.field1, - (ST_DumpRings(sometable.the_geom)).geom As the_geom -FROM sometableOfpolys; - -SELECT ST_AsEWKT(geom) As the_geom, path - FROM ST_DumpRings( - ST_GeomFromEWKT('POLYGON((-8149064 5133092 1,-8149064 5132986 1,-8148996 5132839 1,-8148972 5132767 1,-8148958 5132508 1,-8148941 5132466 1,-8148924 5132394 1, - -8148903 5132210 1,-8148930 5131967 1,-8148992 5131978 1,-8149237 5132093 1,-8149404 5132211 1,-8149647 5132310 1,-8149757 5132394 1, - -8150305 5132788 1,-8149064 5133092 1), - (-8149362 5132394 1,-8149446 5132501 1,-8149548 5132597 1,-8149695 5132675 1,-8149362 5132394 1))') - ) as foo; - path | the_geom ----------------------------------------------------------------------------------------------------------------- - {0} | POLYGON((-8149064 5133092 1,-8149064 5132986 1,-8148996 5132839 1,-8148972 5132767 1,-8148958 5132508 1, - | -8148941 5132466 1,-8148924 5132394 1, - | -8148903 5132210 1,-8148930 5131967 1, - | -8148992 5131978 1,-8149237 5132093 1, - | -8149404 5132211 1,-8149647 5132310 1,-8149757 5132394 1,-8150305 5132788 1,-8149064 5133092 1)) - {1} | POLYGON((-8149362 5132394 1,-8149446 5132501 1, - | -8149548 5132597 1,-8149695 5132675 1,-8149362 5132394 1)) - - - - - See Also - - , , - - - - - - ST_Intersection - - (T) Returns a geometry that represents the shared portion of geomA and geomB. The geography implementation - does a transform to geometry to do the intersection and then transform back to WGS84. - - - - - - geometry ST_Intersection - - geometry - geomA - - - geometry - geomB - - - - geography ST_Intersection - - geography - geogA - - - geography - geogB - - - - - - Description - Returns a geometry that represents the point set - intersection of the Geometries. - - In other words - that portion of geometry A and geometry B - that is shared between the two geometries. - - If the geometries do not share any space (are disjoint), then an empty geometry collection - is returned. - ST_Intersection in conjunction with ST_Intersects is very useful for clipping geometries such as in bounding box, buffer, region - queries where you only want to return that portion of a geometry that sits in a country or region of interest. - - - Geography: For geography this is really a thin wrapper around the geometry implementation. It first determines the best SRID that - fits the bounding box of the geography object (favoring UTM, polar stereographic and falling back on mercator in worst case scenario) and then buffers in that planar spatial ref and retransforms back to WGS84 geography. - - Do not call with a GEOMETRYCOLLECTION as an argument - - - Performed by the GEOS module - - Availability: 1.5 support for geography data type was introduced. - - - - - This method implements the - OpenGIS Simple - Features Implementation Specification for SQL OGC SPEC s2.1.1.3 - - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.18 - - - Examples -SELECT ST_AsText(ST_Intersection('POINT(0 0)'::geometry, 'LINESTRING ( 2 0, 0 2 )'::geometry)); - st_astext ---------------- -GEOMETRYCOLLECTION EMPTY -(1 row) -SELECT ST_AsText(ST_Intersection('POINT(0 0)'::geometry, 'LINESTRING ( 0 0, 0 2 )'::geometry)); - st_astext ---------------- -POINT(0 0) -(1 row) - ----Clip all lines (trails) by country (here we assume country geom are POLYGON or MULTIPOLYGONS) --- NOTE: we are only keeping intersections that result in a LINESTRING or MULTILINESTRING because we don't --- care about trails that just share a point --- the dump is needed to expand a geometry collection into individual single MULT* parts --- the below is fairly generic and will work for polys, etc. by just changing the where clause -SELECT clipped.gid, clipped.f_name, clipped_geom -FROM (SELECT trails.gid, trails.f_name, (ST_Dump(ST_Intersection(country.the_geom, trails.the_geom))).geom As clipped_geom -FROM country - INNER JOIN trails - ON ST_Intersects(country.the_geom, trails.the_geom)) As clipped - WHERE ST_Dimension(clipped.clipped_geom) = 1 ; - ---For polys e.g. polygon landmarks, you can also use the sometimes faster hack that buffering anything by 0.0 --- except a polygon results in an empty geometry collection ---(so a geometry collection containing polys, lines and points) --- buffered by 0.0 would only leave the polygons and dissolve the collection shell -SELECT poly.gid, ST_Multi(ST_Buffer( - ST_Intersection(country.the_geom, poly.the_geom), - 0.0) - ) As clipped_geom -FROM country - INNER JOIN poly - ON ST_Intersects(country.the_geom, poly.the_geom) - WHERE Not ST_IsEmpty(ST_Buffer(ST_Intersection(country.the_geom, poly.the_geom),0.0)); - - - - See Also - , , , - - - - - - ST_LineToCurve - - Converts a LINESTRING/POLYGON to a CIRCULARSTRING, CURVED POLYGON - - - - - - geometry ST_LineToCurve - geometry geomANoncircular - - - - - - Description - - Converts plain LINESTRING/POLYGONS to CIRCULAR STRINGs and Curved Polygons. Note much fewer points are needed to describe the curved equivalent. - - Availability: 1.2.2? - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - This method supports Circular Strings and Curves - - - - - Examples - - -SELECT ST_AsText(ST_LineToCurve(foo.the_geom)) As curvedastext,ST_AsText(foo.the_geom) As non_curvedastext - FROM (SELECT ST_Buffer('POINT(1 3)'::geometry, 3) As the_geom) As foo; - -curvedatext non_curvedastext -------------------------------------------------------------------| ----------------------------------------------------------------- -CURVEPOLYGON(CIRCULARSTRING(4 3,3.12132034355964 0.878679656440359, | POLYGON((4 3,3.94235584120969 2.41472903395162,3.77163859753386 1.85194970290473 -1 0,-1.12132034355965 5.12132034355963,4 3)) | ,3.49440883690764 1.33328930094119,3.12132034355964 0.878679656440359, - | 2.66671069905881 0.505591163092366,2.14805029709527 0.228361402466141, - | 1.58527096604839 0.0576441587903094,1 0, - | 0.414729033951621 0.0576441587903077,-0.148050297095264 0.228361402466137, - | -0.666710699058802 0.505591163092361,-1.12132034355964 0.878679656440353, - | -1.49440883690763 1.33328930094119,-1.77163859753386 1.85194970290472 - | --ETC-- ,3.94235584120969 3.58527096604839,4 3)) ---3D example -SELECT ST_AsEWKT(ST_LineToCurve(ST_GeomFromEWKT('LINESTRING(1 2 3, 3 4 8, 5 6 4, 7 8 4, 9 10 4)'))); - - st_asewkt ------------------------------------- - CIRCULARSTRING(1 2 3,5 6 4,9 10 4) - - - - - - - See Also - - - - - - - - ST_MemUnion - - Same as ST_Union, only memory-friendly (uses less memory - and more processor time). - - - - - - geometry ST_MemUnion - geometry set geomfield - - - - - - - Description - - Some useful description here. - - - - Same as ST_Union, only memory-friendly (uses less memory - and more processor time). This aggregate function works by unioning the geometries one at a time to previous result as opposed to - ST_Union aggregate which first creates an array and then unions - - - - - - - - This function supports 3d and will not drop the z-index, but sometimes does strange things with 3d. - - - - - Examples - - See ST_Union - - - - - See Also - - - - - - - - ST_MinimumBoundingCircle - Returns the smallest circle polygon that can fully contain a geometry. Default - uses 48 segments per quarter circle. - - - - - - geometry ST_MinimumBoundingCircle - geometry geomA - - - geometry ST_MinimumBoundingCircle - geometry geomA - integer num_segs_per_qt_circ - - - - - - Description - Returns the smallest circle polygon that can fully contain a geometry. - The circle is approximated by a polygon with a default of 48 segments per quarter circle. This number can be increased with little performance penalty to obtain a more accurate result. - - It is often used with MULTI and Geometry Collections. - Although it is not an aggregate - you can use it in conjunction - with ST_Collect to get the minimum bounding cirlce of a set of geometries. - ST_MinimumBoundingCircle(ST_Collect(somepointfield)). - - The ratio of the area of a polygon divided by the area of its Minimum Bounding Circle is often referred to as the Roeck test. - - Availability: 1.4.0 - requires GEOS - - - - - - Examples -SELECT d.disease_type, - ST_MinimumBoundingCircle(ST_Collect(d.the_geom)) As the_geom - FROM disease_obs As d - GROUP BY d.disease_type; - - - - - - - Minimum bounding circle of a point and linestring. Using 8 segs to approximate a quarter circle - - - -SELECT ST_AsText(ST_MinimumBoundingCircle( - ST_Collect( - ST_GeomFromEWKT('LINESTRING(55 75,125 150)'), - ST_Point(20, 80)), 8 - )) As wktmbc; -wktmbc ------------ -POLYGON((135.59714732062 115,134.384753327498 102.690357210921,130.79416296937 90.8537670908995,124.963360620072 79.9451031602111,117.116420743937 70.3835792560632,107.554896839789 62.5366393799277,96.6462329091006 56.70583703063,84.8096427890789 53.115246672502,72.5000000000001 51.9028526793802,60.1903572109213 53.1152466725019,48.3537670908996 56.7058370306299,37.4451031602112 62.5366393799276,27.8835792560632 70.383579256063,20.0366393799278 79.9451031602109,14.20583703063 90.8537670908993,10.615246672502 102.690357210921,9.40285267938019 115,10.6152466725019 127.309642789079,14.2058370306299 139.1462329091,20.0366393799275 150.054896839789,27.883579256063 159.616420743937, -37.4451031602108 167.463360620072,48.3537670908992 173.29416296937,60.190357210921 176.884753327498, -72.4999999999998 178.09714732062,84.8096427890786 176.884753327498,96.6462329091003 173.29416296937,107.554896839789 167.463360620072, -117.116420743937 159.616420743937,124.963360620072 150.054896839789,130.79416296937 139.146232909101,134.384753327498 127.309642789079,135.59714732062 115)) - - - - See Also - , - - - - - - ST_Polygonize - - Aggregate. Creates a GeometryCollection containing possible - polygons formed from the constituent linework of a set of - geometries. - - - - - - geometry ST_Polygonize - geometry set geomfield - - - - - - Description - - Creates a GeometryCollection containing possible - polygons formed from the constituent linework of a set of - geometries. - - - Geometry Collections are often difficult to deal with with third party tools, so use ST_Polygonize in conjunction with to dump the polygons - out into individual polygons. - - Availability: 1.0.0RC1 - requires GEOS >= 2.1.0. - - - - Examples: Polygonizing single linestrings - -SELECT ST_AsEWKT(ST_Polygonize(the_geom_4269)) As geomtextrep -FROM (SELECT the_geom_4269 FROM ma.suffolk_edges ORDER BY tlid LIMIT 45) As foo; - -geomtextrep -------------------------------------- - SRID=4269;GEOMETRYCOLLECTION(POLYGON((-71.040878 42.285678,-71.040943 42.2856,-71.04096 42.285752,-71.040878 42.285678)), - POLYGON((-71.17166 42.353675,-71.172026 42.354044,-71.17239 42.354358,-71.171794 42.354971,-71.170511 42.354855, - -71.17112 42.354238,-71.17166 42.353675))) -(1 row) - ---Use ST_Dump to dump out the polygonize geoms into individual polygons -SELECT ST_AsEWKT((ST_Dump(foofoo.polycoll)).geom) As geomtextrep -FROM (SELECT ST_Polygonize(the_geom_4269) As polycoll - FROM (SELECT the_geom_4269 FROM ma.suffolk_edges - ORDER BY tlid LIMIT 45) As foo) As foofoo; - -geomtextrep ------------------------- - SRID=4269;POLYGON((-71.040878 42.285678,-71.040943 42.2856,-71.04096 42.285752, --71.040878 42.285678)) - SRID=4269;POLYGON((-71.17166 42.353675,-71.172026 42.354044,-71.17239 42.354358 -,-71.171794 42.354971,-71.170511 42.354855,-71.17112 42.354238,-71.17166 42.353675)) -(2 rows) - - - - - - See Also - - - - - - - ST_Shift_Longitude - - Reads every point/vertex in every component of every feature - in a geometry, and if the longitude coordinate is <0, adds 360 - to it. The result would be a 0-360 version of the data to be - plotted in a 180 centric map - - - - - - geometry ST_Shift_Longitude - geometry geomA - - - - - - Description - - Reads every point/vertex in every component of every feature - in a geometry, and if the longitude coordinate is <0, adds 360 - to it. The result would be a 0-360 version of the data to be - plotted in a 180 centric map - This is only useful for data in long lat e.g. 4326 (WGS 84 long lat) - - - Pre-1.3.4 bug prevented this from working for MULTIPOINT. 1.3.4+ works with MULTIPOINT as well. - - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - - --3d points -SELECT ST_AsEWKT(ST_Shift_Longitude(ST_GeomFromEWKT('SRID=4326;POINT(-118.58 38.38 10)'))) As geomA, - ST_AsEWKT(ST_Shift_Longitude(ST_GeomFromEWKT('SRID=4326;POINT(241.42 38.38 10)'))) As geomb -geomA geomB ----------- ----------- -SRID=4326;POINT(241.42 38.38 10) SRID=4326;POINT(-118.58 38.38 10) - ---regular line string -SELECT ST_AsText(ST_Shift_Longitude(ST_GeomFromText('LINESTRING(-118.58 38.38, -118.20 38.45)'))) - -st_astext ----------- -LINESTRING(241.42 38.38,241.8 38.45) - - - - - - See Also - , , - - - - - - ST_Simplify - Returns a "simplified" version of the given geometry using - the Douglas-Peuker algorithm. - - - - - - geometry ST_Simplify - geometry geomA - float tolerance - - - - - - Description - Returns a "simplified" version of the given geometry using - the Douglas-Peuker algorithm. Will actually do something only with - (multi)lines and (multi)polygons but you can safely call it with - any kind of geometry. Since simplification occurs on a - object-by-object basis you can also feed a GeometryCollection to - this function. - - Note that returned geometry might loose its - simplicity (see ) - Note topology may not be preserved and may result in invalid geometries. Use (see ) to preserve topology. - - Performed by the GEOS module. - Availability: 1.2.2 - - - - Examples - A circle simplified too much becomes a triangle, medium an octagon, - -SELECT ST_Npoints(the_geom) As np_before, ST_NPoints(ST_Simplify(the_geom,0.1)) As np01_notbadcircle, ST_NPoints(ST_Simplify(the_geom,0.5)) As np05_notquitecircle, -ST_NPoints(ST_Simplify(the_geom,1)) As np1_octagon, ST_NPoints(ST_Simplify(the_geom,10)) As np10_triangle, -(ST_Simplify(the_geom,100) is null) As np100_geometrygoesaway -FROM (SELECT ST_Buffer('POINT(1 3)', 10,12) As the_geom) As foo; --result - np_before | np01_notbadcircle | np05_notquitecircle | np1_octagon | np10_triangle | np100_geometrygoesaway ------------+-------------------+---------------------+-------------+---------------+------------------------ - 49 | 33 | 17 | 9 | 4 | t - - - - - See Also - , - - - - - - ST_SimplifyPreserveTopology - Returns a "simplified" version of the given geometry using - the Douglas-Peuker algorithm. Will avoid creating derived - geometries (polygons in particular) that are invalid. - - - - - - geometry ST_SimplifyPreserveTopology - geometry geomA - float tolerance - - - - - - Description - Returns a "simplified" version of the given geometry using - the Douglas-Peuker algorithm. Will avoid creating derived - geometries (polygons in particular) that are invalid. Will actually do something only with - (multi)lines and (multi)polygons but you can safely call it with - any kind of geometry. Since simplification occurs on a - object-by-object basis you can also feed a GeometryCollection to - this function. - - Performed by the GEOS module. - Requires GEOS 3.0.0+ - Availability: 1.3.3 - - - - Examples - Same example as Simplify, but we see Preserve Topology prevents oversimplification. The circle can at most become a square. - -SELECT ST_Npoints(the_geom) As np_before, ST_NPoints(ST_SimplifyPreserveTopology(the_geom,0.1)) As np01_notbadcircle, ST_NPoints(ST_SimplifyPreserveTopology(the_geom,0.5)) As np05_notquitecircle, -ST_NPoints(ST_SimplifyPreserveTopology(the_geom,1)) As np1_octagon, ST_NPoints(ST_SimplifyPreserveTopology(the_geom,10)) As np10_square, -ST_NPoints(ST_SimplifyPreserveTopology(the_geom,100)) As np100_stillsquare -FROM (SELECT ST_Buffer('POINT(1 3)', 10,12) As the_geom) As foo; - ---result-- - np_before | np01_notbadcircle | np05_notquitecircle | np1_octagon | np10_square | np100_stillsquare ------------+-------------------+---------------------+-------------+---------------+------------------- - 49 | 33 | 17 | 9 | 5 | 5 - - - - See Also - - - - - - - ST_SymDifference - - Returns a geometry that represents the portions of A and B - that do not intersect. It is called a symmetric difference because - ST_SymDifference(A,B) = ST_SymDifference(B,A). - - - - - - geometry ST_SymDifference - geometry geomA - geometry geomB - - - - - - Description - - Returns a geometry that represents the portions of A and B - that do not intersect. It is called a symmetric difference because - ST_SymDifference(A,B) = ST_SymDifference(B,A). One can think of this as ST_Union(geomA,geomB) - ST_Intersection(A,B). - - - Performed by the GEOS module - - Do not call with a GeometryCollection as an argument - - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL. OGC SPEC s2.1.1.3 - - - - - - - This method implements the SQL/MM specification: SQL-MM 3: 5.1.21 - - - - - - - This function supports 3d and will not drop the z-index. - However it seems to only consider x y when doing the difference and tacks back on the Z-Index - - - - - Examples - - - - - - - - - - - - - The original linestrings shown together - - - - - - - - - - - - The symmetric difference of the two linestrings - - - - - - - - - ---Safe for 2d - symmetric difference of 2 linestrings -SELECT ST_AsText( - ST_SymDifference( - ST_GeomFromText('LINESTRING(50 100, 50 200)'), - ST_GeomFromText('LINESTRING(50 50, 50 150)') - ) -); - -st_astext ---------- -MULTILINESTRING((50 150,50 200),(50 50,50 100)) - - - - ---When used in 3d doesn't quite do the right thing -SELECT ST_AsEWKT(ST_SymDifference(ST_GeomFromEWKT('LINESTRING(1 2 1, 1 4 2)'), - ST_GeomFromEWKT('LINESTRING(1 1 3, 1 3 4)'))) - -st_astext ------------- -MULTILINESTRING((1 3 2.75,1 4 2),(1 1 3,1 2 2.25)) - - - - - - See Also - - , , - - - - - - - ST_Union - Returns a geometry that represents the point set union of - the Geometries. - - - - - - geometry ST_Union - geometry set g1field - - - geometry ST_Union - geometry g1 - geometry g2 - - - geometry ST_Union - geometry[] g1_array - - - - - - Description - Output type can be a MULTI* , single geometry, or Geometry Collection. Comes in 2 variants. Variant 1 unions 2 geometries resulting in a new geomety with no intersecting regions. - Variant 2 is an aggregate function that takes a set of geometries and unions - them into a single ST_Geometry resulting in no intersecting regions. - - Aggregate version: This function returns a MULTI geometry or NON-MULTI geometry - from a set of geometries. The ST_Union() function is an "aggregate" - function in the terminology of PostgreSQL. That means that it - operates on rows of data, in the same way the SUM() and AVG() - functions do. - - Non-Aggregate version: This function returns a geometry being a union of two - input geometries. Output type can be a MULTI* ,NON-MULTI or - GEOMETRYCOLLECTION. - - ST_Collect and ST_Union are often interchangeable. - ST_Union is in general orders of magnitude slower than ST_Collect - because it tries to dissolve boundaries and reorder geometries to ensure that a constructed Multi* doesn't - have intersecting regions. - - Performed by the GEOS module. - NOTE: this function was formerly called GeomUnion(), which - was renamed from "Union" because UNION is an SQL reserved - word. - Availability: 1.4.0 - ST_Union was enhanced. ST_Union(geomarray) was introduced and also faster aggregate collection in PostgreSQL. If you are using GEOS 3.1.0+ - ST_Union will use the faster Cascaded Union algorithm described in - http://blog.cleverelephant.ca/2009/01/must-faster-unions-in-postgis-14.html - - - - - - This method implements the OpenGIS Simple Features - Implementation Specification for SQL: OGC SPEC s2.1.1.3 - - - - - - This method implements the SQL/MM specification: - SQL-MM 3: 5.1.19 - - Aggregate version is not explicitly defined in OGC SPEC. - - - - - - - This function supports 3d and will not drop the z-index, but sometimes does something goofy with - the z-index (elevation) when polygons are involved. - - - - Examples - Aggregate example - -SELECT stusps, - ST_Multi(ST_Union(f.the_geom)) as singlegeom - FROM sometable As f -GROUP BY stusps - - Non-Aggregate example - -SELECT ST_AsText(ST_Union(ST_GeomFromText('POINT(1 2)'), - ST_GeomFromText('POINT(-2 3)') ) ) - -st_astext ----------- -MULTIPOINT(-2 3,1 2) - - -SELECT ST_AsText(ST_Union(ST_GeomFromText('POINT(1 2)'), - ST_GeomFromText('POINT(1 2)') ) ); -st_astext ----------- -POINT(1 2) - ---3d example - sort of supports 3d (and with mixed dimensions!) -SELECT ST_AsEWKT(st_union(the_geom)) -FROM -(SELECT ST_GeomFromEWKT('POLYGON((-7 4.2,-7.1 4.2,-7.1 4.3, --7 4.2))') as the_geom -UNION ALL -SELECT ST_GeomFromEWKT('POINT(5 5 5)') as the_geom -UNION ALL - SELECT ST_GeomFromEWKT('POINT(-2 3 1)') as the_geom -UNION ALL -SELECT ST_GeomFromEWKT('LINESTRING(5 5 5, 10 10 10)') as the_geom ) as foo; - -st_asewkt ---------- -GEOMETRYCOLLECTION(POINT(-2 3 1),LINESTRING(5 5 5,10 10 10),POLYGON((-7 4.2 5,-7.1 4.2 5,-7.1 4.3 5,-7 4.2 5))); - ---3d example not mixing dimensions -SELECT ST_AsEWKT(st_union(the_geom)) -FROM -(SELECT ST_GeomFromEWKT('POLYGON((-7 4.2 2,-7.1 4.2 3,-7.1 4.3 2, --7 4.2 2))') as the_geom -UNION ALL -SELECT ST_GeomFromEWKT('POINT(5 5 5)') as the_geom -UNION ALL - SELECT ST_GeomFromEWKT('POINT(-2 3 1)') as the_geom -UNION ALL -SELECT ST_GeomFromEWKT('LINESTRING(5 5 5, 10 10 10)') as the_geom ) as foo; - -st_asewkt ---------- -GEOMETRYCOLLECTION(POINT(-2 3 1),LINESTRING(5 5 5,10 10 10),POLYGON((-7 4.2 2,-7.1 4.2 3,-7.1 4.3 2,-7 4.2 2))) - ---Examples using new Array construct -SELECT ST_Union(ARRAY(SELECT the_geom FROM sometable)); - -SELECT ST_AsText(ST_Union(ARRAY[ST_GeomFromText('LINESTRING(1 2, 3 4)'), - ST_GeomFromText('LINESTRING(3 4, 4 5)')])) As wktunion; - ---wktunion--- -MULTILINESTRING((3 4,4 5),(1 2,3 4)) - - - - - See Also - - - - - - - Linear Referencing - - - ST_Line_Interpolate_Point - - Returns a point interpolated along a line. Second argument is a float8 between 0 and 1 - representing fraction of total length of linestring the point has to be located. - - - - - - geometry ST_Line_Interpolate_Point - geometry a_linestring - float a_fraction - - - - - - Description - - Returns a point interpolated along a line. First argument - must be a LINESTRING. Second argument is a float8 between 0 and 1 - representing fraction of total linestring length the point has to be located. - - See for - computing the line location nearest to a Point. - - - Since release 1.1.1 this function also interpolates M and - Z values (when present), while prior releases set them to - 0.0. - - Availability: 0.8.2, Z and M supported added in 1.1.1 - - - - - - - This function supports 3d and will not drop the z-index. - - - - - Examples - - - - - - A linestring with the interpolated point at 20% position (0.20) - - - --Return point 20% along 2d line -SELECT ST_AsEWKT(ST_Line_Interpolate_Point(the_line, 0.20)) - FROM (SELECT ST_GeomFromEWKT('LINESTRING(25 50, 100 125, 150 190)') as the_line) As foo; - st_asewkt ----------------- - POINT(51.5974135047432 76.5974135047432) - - - ---Return point mid-way of 3d line -SELECT ST_AsEWKT(ST_Line_Interpolate_Point(the_line, 0.5)) - FROM (SELECT ST_GeomFromEWKT('LINESTRING(1 2 3, 4 5 6, 6 7 8)') as the_line) As foo; - - st_asewkt --------------------- - POINT(3.5 4.5 5.5) - - ---find closest point on a line to a point or other geometry - SELECT ST_AsText(ST_Line_Interpolate_Point(foo.the_line, ST_Line_Locate_Point(foo.the_line, ST_GeomFromText('POINT(4 3)')))) -FROM (SELECT ST_GeomFromText('LINESTRING(1 2, 4 5, 6 7)') As the_line) As foo; - st_astext ----------------- - POINT(3 4) - - - - - - - See Also - - ,,, - - - - - - ST_Line_Locate_Point - - Returns a float between 0 and 1 representing the location of - the closest point on LineString to the given Point, as a fraction - of total 2d line length. - - - - - - float ST_Line_Locate_Point - geometry a_linestring - geometry a_point - - - - - - Description - - Returns a float between 0 and 1 representing the location of - the closest point on LineString to the given Point, as a fraction - of total 2d line length. - - You can use the returned location to extract a Point () or - a substring (). - - This is useful for approximating numbers of addresses - - Availability: 1.1.0 - - - - - - Examples - - ---Rough approximation of finding the street number of a point along the street ---Note the whole foo thing is just to generate dummy data that looks ---like house centroids and street ---We use ST_DWithin to exclude ---houses too far away from the street to be considered on the street -SELECT ST_AsText(house_loc) As as_text_house_loc, - startstreet_num + - CAST( (endstreet_num - startstreet_num) - * ST_Line_Locate_Point(street_line, house_loc) As integer) As street_num -FROM -(SELECT ST_GeomFromText('LINESTRING(1 2, 3 4)') As street_line, - ST_MakePoint(x*1.01,y*1.03) As house_loc, 10 As startstreet_num, - 20 As endstreet_num -FROM generate_series(1,3) x CROSS JOIN generate_series(2,4) As y) -As foo -WHERE ST_DWithin(street_line, house_loc, 0.2); - - as_text_house_loc | street_num --------------------+------------ - POINT(1.01 2.06) | 10 - POINT(2.02 3.09) | 15 - POINT(3.03 4.12) | 20 - - --find closest point on a line to a point or other geometry - SELECT ST_AsText(ST_Line_Interpolate_Point(foo.the_line, ST_Line_Locate_Point(foo.the_line, ST_GeomFromText('POINT(4 3)')))) -FROM (SELECT ST_GeomFromText('LINESTRING(1 2, 4 5, 6 7)') As the_line) As foo; - st_astext ----------------- - POINT(3 4) - - - - - - - See Also - - , , , - - - - - - ST_Line_Substring - - Return a linestring being a substring of the input one - starting and ending at the given fractions of total 2d length. - Second and third arguments are float8 values between 0 and - 1. - - - - - - geometry ST_Line_Substring - geometry a_linestring - float startfraction - float endfraction - - - - - - Description - - Return a linestring being a substring of the input one - starting and ending at the given fractions of total 2d length. - Second and third arguments are float8 values between 0 and - 1. This only works with LINESTRINGs. - To use with contiguous MULTILINESTRINGs use in conjunction with ST_LineMerge. - - If 'start' and 'end' have the same value this is equivalent - to . - - See for - computing the line location nearest to a Point. - - - Since release 1.1.1 this function also interpolates M and - Z values (when present), while prior releases set them to - unspecified values. - - - Availability: 1.1.0 , Z and M supported added in 1.1.1 - - - - - - - This function supports 3d and will not drop the z-index. - - - - Examples - - - - - - A linestring seen with 1/3 midrange overlaid (0.333, 0.666) - - - ---Return the approximate 1/3 mid-range part of a linestring -SELECT ST_AsText(ST_Line_SubString(ST_GeomFromText('LINESTRING(25 50, 100 125, 150 190)'), 0.333, 0.666)); - - st_astext ------------------------------------------------------------------------------------------------- -LINESTRING(69.2846934853974 94.2846934853974,100 125,111.700356260683 140.210463138888) - ---The below example simulates a while loop in ---SQL using PostgreSQL generate_series() to cut all ---linestrings in a table to 100 unit segments --- of which no segment is longer than 100 units --- units are measured in the SRID units of measurement --- It also assumes all geometries are LINESTRING or contiguous MULTILINESTRING ---and no geometry is longer than 100 units*10000 ---for better performance you can reduce the 10000 ---to match max number of segments you expect - -SELECT field1, field2, ST_Line_Substring(the_geom, 100.00*n/length, - CASE - WHEN 100.00*(n+1) < length THEN 100.00*(n+1)/length - ELSE 1 - END) As the_geom -FROM - (SELECT sometable.field1, sometable.field2, - ST_LineMerge(sometable.the_geom) AS the_geom, - ST_Length(sometable.the_geom) As length - FROM sometable - ) AS t -CROSS JOIN generate_series(0,10000) AS n -WHERE n*100.00/length < 1; - - - - - - See Also - - , , - - - - - - ST_Locate_Along_Measure - - Return a derived geometry collection value with elements - that match the specified measure. Polygonal elements are not - supported. - - - - - - geometry ST_Locate_Along_Measure - geometry ageom_with_measure - float a_measure - - - - - - Description - - Return a derived geometry collection value with elements - that match the specified measure. Polygonal elements are not - supported. - - Semantic is specified by: ISO/IEC CD 13249-3:200x(E) - Text - for Continuation CD Editing Meeting - - Availability: 1.1.0 - Use this function only for geometries with an M component - - - - - - - This function supports M coordinate. - - - - - Examples - SELECT ST_AsEWKT(the_geom) - FROM - (SELECT ST_Locate_Along_Measure( - ST_GeomFromEWKT('MULTILINESTRINGM((1 2 3, 3 4 2, 9 4 3), - (1 2 3, 5 4 5))'),3) As the_geom) As foo; - - st_asewkt ------------------------------------------------------------ - GEOMETRYCOLLECTIONM(MULTIPOINT(1 2 3,9 4 3),POINT(1 2 3)) - ---Geometry collections are difficult animals so dump them ---to make them more digestable -SELECT ST_AsEWKT((ST_Dump(the_geom)).geom) - FROM - (SELECT ST_Locate_Along_Measure( - ST_GeomFromEWKT('MULTILINESTRINGM((1 2 3, 3 4 2, 9 4 3), - (1 2 3, 5 4 5))'),3) As the_geom) As foo; - - st_asewkt ---------------- - POINTM(1 2 3) - POINTM(9 4 3) - POINTM(1 2 3) - - - - - - See Also - - , - - - - - - ST_Locate_Between_Measures - - Return a derived geometry collection value with elements - that match the specified range of measures inclusively. Polygonal - elements are not supported. - - - - - - geometry ST_Locate_Between_Measures - geometry geomA - float measure_start - float measure_end - - - - - - - Description - - Return a derived geometry collection value with elements - that match the specified range of measures inclusively. Polygonal - elements are not supported. - - Semantic is specified by: ISO/IEC CD 13249-3:200x(E) - Text - for Continuation CD Editing Meeting - - Availability: 1.1.0 - - - - - - - This function supports M coordinate. - - - - Examples - - SELECT ST_AsEWKT(the_geom) - FROM - (SELECT ST_Locate_Between_Measures( - ST_GeomFromEWKT('MULTILINESTRINGM((1 2 3, 3 4 2, 9 4 3), - (1 2 3, 5 4 5))'),1.5, 3) As the_geom) As foo; - - st_asewkt ------------------------------------------------------------------ - GEOMETRYCOLLECTIONM(LINESTRING(1 2 3,3 4 2,9 4 3),POINT(1 2 3)) - ---Geometry collections are difficult animals so dump them ---to make them more digestable -SELECT ST_AsEWKT((ST_Dump(the_geom)).geom) - FROM - (SELECT ST_Locate_Between_Measures( - ST_GeomFromEWKT('MULTILINESTRINGM((1 2 3, 3 4 2, 9 4 3), - (1 2 3, 5 4 5))'),1.5, 3) As the_geom) As foo; - - st_asewkt --------------------------------- - LINESTRINGM(1 2 3,3 4 2,9 4 3) - POINTM(1 2 3) - - - - - See Also - - , - - - - - - ST_LocateBetweenElevations - - Return a derived geometry (collection) value with elements - that intersect the specified range of elevations inclusively. Only 3D, 4D LINESTRINGS and MULTILINESTRINGS - are supported. - - - - - - geometry ST_LocateBetweenElevations - geometry geom_mline - float elevation_start - float elevation_end - - - - - - - Description - - Return a derived geometry (collection) value with elements - that intersect the specified range of elevations inclusively. Only 3D, 3DM LINESTRINGS and MULTILINESTRINGS - are supported. - - Availability: 1.4.0 - - - - - - - This function supports 3d and will not drop the z-index. - - - - Examples - - SELECT ST_AsEWKT(ST_LocateBetweenElevations( - ST_GeomFromEWKT('LINESTRING(1 2 3, 4 5 6)'),2,4)) As ewelev; - ewelev ----------------------------------------------------------------- - MULTILINESTRING((1 2 3,2 3 4)) - -SELECT ST_AsEWKT(ST_LocateBetweenElevations( - ST_GeomFromEWKT('LINESTRING(1 2 6, 4 5 -1, 7 8 9)'),6,9)) As ewelev; - - ewelev ----------------------------------------------------------------- -GEOMETRYCOLLECTION(POINT(1 2 6),LINESTRING(6.1 7.1 6,7 8 9)) - ---Geometry collections are difficult animals so dump them ---to make them more digestable -SELECT ST_AsEWKT((ST_Dump(the_geom)).geom) - FROM - (SELECT ST_LocateBetweenElevations( - ST_GeomFromEWKT('LINESTRING(1 2 6, 4 5 -1, 7 8 9)'),6,9) As the_geom) As foo; - - st_asewkt --------------------------------- -POINT(1 2 6) -LINESTRING(6.1 7.1 6,7 8 9) - - - - - - See Also - - - - - - - - Long Transactions Support - - This module and associated pl/pgsql functions have been - implemented to provide long locking support required by Web Feature Service specification. - - - Users must use serializable - transaction level otherwise locking mechanism would - break. - - - - - AddAuth - - Add an authorization token to be used in current transaction. - - - - - - boolean AddAuth - text auth_token - - - - - - Description - - Add an authorization token to be used in current transaction. - - Creates/adds to a temp table called temp_lock_have_table the current transaction identifier - and authorization token key. - - Availability: 1.1.3 - - - - - Examples - - - SELECT LockRow('towns', '353', 'priscilla'); - BEGIN TRANSACTION; - SELECT AddAuth('joey'); - UPDATE towns SET the_geom = ST_Translate(the_geom,2,2) WHERE gid = 353; - COMMIT; - - - ---Error-- - ERROR: UPDATE where "gid" = '353' requires authorization 'priscilla' - - - - - - See Also - - - - - - - - CheckAuth - - Creates trigger on a table to prevent/allow updates and deletes of rows based on authorization token. - - - - - - integer CheckAuth - text a_schema_name - text a_table_name - text a_key_column_name - - - - integer CheckAuth - text a_table_name - text a_key_column_name - - - - - - Description - - Creates trigger on a table to prevent/allow updates and deletes of rows based on authorization token. Identify rows using <rowid_col> column. - - If a_schema_name is not passed in, then searches for table in current schema. - If an authorization trigger already exists on this table function errors. - If Transaction support is not enabled, function throws an exception. - - - Availability: 1.1.3 - - - - - - Examples - - - SELECT CheckAuth('public', 'towns', 'gid'); - result - ------ - 0 - - - - - - See Also - - - - - - - - DisableLongTransactions - - Disable long transaction support. This function removes the - long transaction support metadata tables, and drops all triggers - attached to lock-checked tables. - - - - - - text DisableLongTransactions - - - - - - Description - - Disable long transaction support. This function removes the - long transaction support metadata tables, and drops all triggers - attached to lock-checked tables. - Drops meta table called authorization_table and a view called authorized_tables - and all triggers called checkauthtrigger - - Availability: 1.1.3 - - - - - - Examples - - SELECT DisableLongTransactions(); ---result-- -Long transactions support disabled - - - - - - See Also - - - - - - - - EnableLongTransactions - - Enable long transaction support. This function creates the - required metadata tables, needs to be called once before using the - other functions in this section. Calling it twice is - harmless. - - - - - - text EnableLongTransactions - - - - - - Description - - Enable long transaction support. This function creates the - required metadata tables, needs to be called once before using the - other functions in this section. Calling it twice is - harmless. - Creates a meta table called authorization_table and a view called authorized_tables - - Availability: 1.1.3 - - - - - - Examples - - SELECT EnableLongTransactions(); ---result-- -Long transactions support enabled - - - - - - See Also - - - - - - - - LockRow - - Set lock/authorization for specific row in table - - - - - - integer LockRow - text a_schema_name - text a_table_name - text a_row_key - text an_auth_token - timestamp expire_dt - - - - integer LockRow - text a_table_name - text a_row_key - text an_auth_token - timestamp expire_dt - - - - integer LockRow - text a_table_name - text a_row_key - text an_auth_token - - - - - - - Description - - Set lock/authorization for specific row in table - <authid> is a text value, <expires> is a timestamp - defaulting to now()+1hour. Returns 1 if lock has been assigned, 0 - otherwise (already locked by other auth) - - Availability: 1.1.3 - - - - - Examples - - SELECT LockRow('public', 'towns', '2', 'joey'); -LockRow -------- -1 - ---Joey has already locked the record and Priscilla is out of luck -SELECT LockRow('public', 'towns', '2', 'priscilla'); -LockRow -------- -0 - - - - - - - See Also - - - - - - - - UnlockRows - - Remove all locks held by specified authorization id. Returns - the number of locks released. - - - - - - integer UnlockRows - text auth_token - - - - - - Description - - Remove all locks held by specified authorization id. Returns - the number of locks released. - - Availability: 1.1.3 - - - - - Examples - - - SELECT LockRow('towns', '353', 'priscilla'); - SELECT LockRow('towns', '2', 'priscilla'); - SELECT UnLockRows('priscilla'); - UnLockRows - ------------ - 2 - - - - - - See Also - - - - - - - - Miscellaneous Functions - - - - ST_Accum - - Aggregate. Constructs an array of geometries. - - - - - - geometry[] ST_Accum - geometry set geomfield - - - - - - Description - - Aggregate. Constructs an array of geometries. - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and curves - - - - - Examples - - SELECT (ST_Accum(the_geom)) As all_em, ST_AsText((ST_Accum(the_geom))[1]) As grabone, -(ST_Accum(the_geom))[2:4] as grab_rest - FROM (SELECT ST_MakePoint(a*CAST(random()*10 As integer), a*CAST(random()*10 As integer), a*CAST(random()*10 As integer)) As the_geom - FROM generate_series(1,4) a) As foo; - -all_em|grabone | grab_rest - --------------------------------------------------------------------------------+ - - {0101000080000000000000144000000000000024400000000000001040: - 0101000080000000000 -00018400000000000002C400000000000003040: -0101000080000000000000354000000000000038400000000000001840: -010100008000000000000040400000000000003C400000000000003040} | - POINT(5 10) | {010100008000000000000018400000000000002C400000000000003040: - 0101000080000000000000354000000000000038400000000000001840: - 010100008000000000000040400000000000003C400000000000003040} -(1 row) - - - - - - See Also - - - - - - - - Box2D - - Returns a BOX2D representing the maximum extents of the geometry. - - - - - - box2d Box2D - geometry geomA - - - - - - Description - - Returns a BOX2D representing the maximum extents of the geometry. - - - - - - - This method supports Circular Strings and curves - - - - - Examples - - SELECT Box2D(ST_GeomFromText('LINESTRING(1 2, 3 4, 5 6)')); - box2d - --------- - BOX(1 2,5 6) - - SELECT Box2D(ST_GeomFromText('CIRCULARSTRING(220268 150415,220227 150505,220227 150406)')); - box2d - -------- - BOX(220186.984375 150406,220288.25 150506.140625) - - - - - - See Also - - , - - - - - - Box3D - - Returns a BOX3D representing the maximum extents of the geometry. - - - - - - box3d Box3D - geometry geomA - - - - - - Description - - Returns a BOX3D representing the maximum extents of the geometry. - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and curves - - - - - Examples - - SELECT Box3D(ST_GeomFromEWKT('LINESTRING(1 2 3, 3 4 5, 5 6 5)')); - box3d - --------- - BOX3D(1 2 3,5 6 5) - - SELECT Box3D(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 1,220227 150406 1)')); - box3d - -------- - BOX3D(220227 150406 1,220268 150415 1) - - - - - - See Also - - , - - - - - - ST_Estimated_Extent - - Return the 'estimated' extent of the given spatial table. - The estimated is taken from the geometry column's statistics. The - current schema will be used if not specified. - - - - - - box2d ST_Estimated_Extent - text schema_name - text table_name - text geocolumn_name - - - - box2d ST_Estimated_Extent - text table_name - text geocolumn_name - - - - - - Description - - Return the 'estimated' extent of the given spatial table. - The estimated is taken from the geometry column's statistics. The - current schema will be used if not specified. - - For PostgreSQL>=8.0.0 statistics are gathered by VACUUM - ANALYZE and resulting extent will be about 95% of the real - one. - - For PostgreSQL<8.0.0 statistics are gathered by - update_geometry_stats() and resulting extent will be exact. - - - - - - - This method supports Circular Strings and curves - - - - - Examples - - SELECT ST_Estimated_extent('ny', 'edges', 'the_geom'); ---result-- -BOX(-8877653 4912316,-8010225.5 5589284) - -SELECT ST_Estimated_Extent('feature_poly', 'the_geom'); ---result-- -BOX(-124.659652709961 24.6830825805664,-67.7798080444336 49.0012092590332) - - - - - - See Also - - - - - - - ST_Expand - Returns bounding box expanded in all directions from the bounding box of the input geometry - - - - - - geometry ST_Expand - geometry g1 - float units_to_expand - - - - box2d ST_Expand - box2d g1 - float units_to_expand - - - - box3d ST_Expand - box3d g1 - float units_to_expand - - - - - - Description - - This function returns a bounding box expanded in all - directions from the bounding box of the input geometry, by an - amount specified in the second argument. Very useful for - distance() queries, or bounding box queries to add an index filter to the query. - There are 3 variants of this. The one that takes a geometry will return a POLYGON geometry representation - of the bounding box and is the most commonly used variant. - ST_Expand is similar in concept to ST_Buffer except while buffer expands the geometry in all directions, - ST_Expand expands the bounding box an x,y,z unit amount. - Units are in the units of the spatial reference system in use denoted by the SRID - - - Pre 1.3, ST_Expand was used in conjunction with distance to do indexable queries. Something of the form - the_geom && ST_Expand('POINT(10 20)', 10) AND ST_Distance(the_geom, 'POINT(10 20)') < 10 - Post 1.2, this was replaced with the easier ST_DWithin construct. - - - - Bounding boxes of all geometries are currently 2-d even if they are 3-dimensional geometries. - - - - - - Examples - Examples below use US National Atlas Equal Area (SRID=2163) which is a meter projection - ---10 meter expanded box around bbox of a linestring -SELECT CAST(ST_Expand(ST_GeomFromText('LINESTRING(2312980 110676,2312923 110701,2312892 110714)', 2163),10) As box2d); - st_expand ------------------------------------- - BOX(2312882 110666,2312990 110724) - ---10 meter expanded 3d box of a 3d box -SELECT ST_Expand(CAST('BOX3D(778783 2951741 1,794875 2970042.61545891 10)' As box3d),10) - st_expand ------------------------------------------------------ - BOX3D(778773 2951731 -9,794885 2970052.61545891 20) - - --10 meter geometry astext rep of a expand box around a point geometry - SELECT ST_AsEWKT(ST_Expand(ST_GeomFromEWKT('SRID=2163;POINT(2312980 110676)'),10)); - st_asewkt -------------------------------------------------------------------------------------------------- - SRID=2163;POLYGON((2312970 110666,2312970 110686,2312990 110686,2312990 110666,2312970 110666)) - - - - - - See Also - , , , ,, - - - - - - ST_Extent - an aggregate function that returns the bounding box that bounds rows of geometries. - - - - - - box2d ST_Extent - geometry set geomfield - - - - - - Description - - ST_Extent returns a bounding box that encloses a set of geometries. The ST_Extent function is an "aggregate" function in the - terminology of SQL. That means that it operates on lists - of data, in the same way the SUM() and AVG() functions do. - Since it returns a bounding box, the spatial Units are in the units of the spatial reference system in use denoted by the SRID - ST_Extent is similar in concept to Oracle Spatial/Locator's SDO_AGGR_MBR - - Since ST_Extent returns a bounding box, the SRID meta-data is lost. Use ST_SetSRID to force it back into - a geometry with SRID meta data. The coordinates are in the units of the spatial ref of the orginal geometries. - - - - Bounding boxes of all geometries are currently 2-d even if they are 3-dimensional geometries. - - - - - - Examples - Examples below use Massachusetts State Plane ft (SRID=2249) - - -SELECT ST_Extent(the_geom) as bextent FROM sometable; - st_bextent ------------------------------------- -BOX(739651.875 2908247.25,794875.8125 2970042.75) - - ---Return extent of each category of geometries -SELECT ST_Extent(the_geom) as bextent -FROM sometable -GROUP BY category ORDER BY category; - - bextent | name -----------------------------------------------------+---------------- - BOX(778783.5625 2951741.25,794875.8125 2970042.75) | A - BOX(751315.8125 2919164.75,765202.6875 2935417.25) | B - BOX(739651.875 2917394.75,756688.375 2935866) | C - - --Force back into a geometry - -- and render the extended text representation of that geometry -SELECT ST_SetSRID(ST_Extent(the_geom),2249) as bextent FROM sometable; - - bextent --------------------------------------------------------------------------------- - SRID=2249;POLYGON((739651.875 2908247.25,739651.875 2970042.75,794875.8125 2970042.75, - 794875.8125 2908247.25,739651.875 2908247.25)) - - - - - See Also - , , - - - - - - ST_Extent3D - an aggregate function that returns the box3D bounding box that bounds rows of geometries. - - - - - - box3d ST_Extent3D - geometry set geomfield - - - - - - Description - - ST_Extent3D returns a box3d (includes Z coordinate) bounding box that encloses a set of geometries. The ST_Extent3D function is an "aggregate" function in the - terminology of SQL. That means that it operates on lists - of data, in the same way the SUM() and AVG() functions do. - Since it returns a bounding box, the spatial Units are in the units of the spatial reference system in use denoted by the SRID - - - Since ST_Extent3D returns a bounding box, the SRID meta-data is lost. Use ST_SetSRID to force it back into - a geometry with SRID meta data. The coordinates are in the units of the spatial ref of the orginal geometries. - - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - - This method supports Circular Strings and curves - - - - - Examples - -SELECT ST_Extent3D(foo.the_geom) As b3extent -FROM (SELECT ST_MakePoint(x,y,z) As the_geom - FROM generate_series(1,3) As x - CROSS JOIN generate_series(1,2) As y - CROSS JOIN generate_series(0,2) As Z) As foo; - b3extent --------------------- - BOX3D(1 1 0,3 2 2) - ---Get the extent of various elevated circular strings -SELECT ST_Extent3D(foo.the_geom) As b3extent -FROM (SELECT ST_Translate(ST_Force_3DZ(ST_LineToCurve(ST_Buffer(ST_MakePoint(x,y),1))),0,0,z) As the_geom - FROM generate_series(1,3) As x - CROSS JOIN generate_series(1,2) As y - CROSS JOIN generate_series(0,2) As Z) As foo; - - b3extent --------------------- - BOX3D(1 0 0,4 2 2) - - - - - See Also - , - - - - - - - Find_SRID - - The syntax is find_srid(<db/schema>, <table>, - <column>) and the function returns the integer SRID of the - specified column by searching through the GEOMETRY_COLUMNS table. - - - - - - integer Find_SRID - varchar a_schema_name - varchar a_table_name - varchar a_geomfield_name - - - - - - Description - - The syntax is find_srid(<db/schema>, <table>, - <column>) and the function returns the integer SRID of the - specified column by searching through the GEOMETRY_COLUMNS table. - If the geometry column has not been properly added with the - AddGeometryColumns() function, this function will not work - either. - - - - - Examples - - SELECT Find_SRID('public', 'tiger_us_state_2007', 'the_geom_4269'); -find_srid ----------- -4269 - - - - - - See Also - - - - - - - - ST_Mem_Size - - Returns the amount of space (in bytes) the geometry takes. - - - - - - integer ST_Mem_Size - geometry geomA - - - - - - Description - - Returns the amount of space (in bytes) the geometry takes. - This is a nice compliment to PostgreSQL built in functions pg_size_pretty, pg_relation_size, pg_total_relation_size. - pg_relation_size which gives the byte size of a table may return byte size lower than ST_Mem_Size. This is because - pg_relation_size does not add toasted table contribution and large geometries are stored in TOAST tables. - pg_total_relation_size - includes, the table, the toasted tables, and the indexes. - - - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - This method supports Circular Strings and curves - - - - - Examples - - ---Return how much byte space Boston takes up in our Mass data set -SELECT pg_size_pretty(SUM(ST_Mem_Size(the_geom))) as totgeomsum, -pg_size_pretty(SUM(CASE WHEN town = 'BOSTON' THEN st_mem_size(the_geom) ELSE 0 END)) As bossum, -CAST(SUM(CASE WHEN town = 'BOSTON' THEN st_mem_size(the_geom) ELSE 0 END)*1.00 / - SUM(st_mem_size(the_geom))*100 As numeric(10,2)) As perbos -FROM towns; - -totgeomsum bossum perbos ----------- ------ ------ -1522 kB 30 kB 1.99 - - -SELECT ST_Mem_Size(ST_GeomFromText('CIRCULARSTRING(220268 150415,220227 150505,220227 150406)')); - ---- -73 - ---What percentage of our table is taken up by just the geometry -SELECT pg_total_relation_size('public.neighborhoods') As fulltable_size, sum(ST_Mem_Size(the_geom)) As geomsize, -sum(ST_Mem_Size(the_geom))*1.00/pg_total_relation_size('public.neighborhoods')*100 As pergeom -FROM neighborhoods; -fulltable_size geomsize pergeom ------------------------------------------------- -262144 96238 36.71188354492187500000 - - - - - - See Also - - - - - - - - ST_Point_Inside_Circle - - Is the point geometry insert circle defined by center_x, center_y , radius - - - - - - boolean ST_Point_Inside_Circle - geometry a_point - float center_x - float center_y - float radius - - - - - - Description - - The syntax for this functions is - point_inside_circle(<geometry>,<circle_center_x>,<circle_center_y>,<radius>). - Returns the true if the geometry is a point and is inside the - circle. Returns false otherwise. - This only works for points as the name suggests - - - - - Examples - - SELECT ST_Point_Inside_Circle(ST_Point(1,2), 0.5, 2, 3); - st_point_inside_circle ------------------------- - t - - - - - - See Also - - - - - - - - ST_XMax - - Returns X maxima of a bounding box 2d or 3d or a geometry. - - - - - - float ST_XMax - box3d aGeomorBox2DorBox3D - - - - - - Description - - Returns X maxima of a bounding box 2d or 3d or a geometry. - - - Although this function is only defined for box3d, it will work for box2d and geometry because of the auto-casting behavior - defined for geometries and box2d. However you can not feed it a geometry or box2d text represenation, since that will not auto-cast. - - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - This method supports Circular Strings and curves - - - - - Examples - - SELECT ST_XMax('BOX3D(1 2 3, 4 5 6)'); -st_xmax -------- -4 - -SELECT ST_XMax(ST_GeomFromText('LINESTRING(1 3 4, 5 6 7)')); -st_xmax -------- -5 - -SELECT ST_XMax(CAST('BOX(-3 2, 3 4)' As box2d)); -st_xmax -------- -3 ---Observe THIS DOES NOT WORK because it will try to autocast the string representation to a BOX3D -SELECT ST_XMax('LINESTRING(1 3, 5 6)'); - ---ERROR: BOX3D parser - doesnt start with BOX3D( - -SELECT ST_XMax(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)')); -st_xmax --------- -220288.248780547 - - - - - - See Also - - , , , , - - - - - - ST_XMin - - Returns X minima of a bounding box 2d or 3d or a geometry. - - - - - - float ST_XMin - box3d aGeomorBox2DorBox3D - - - - - - Description - - Returns X minima of a bounding box 2d or 3d or a geometry. - - - Although this function is only defined for box3d, it will work for box2d and geometry because of the auto-casting behavior - defined for geometries and box2d. However you can not feed it a geometry or box2d text represenation, since that will not auto-cast. - - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - This method supports Circular Strings and curves - - - - - Examples - - SELECT ST_XMin('BOX3D(1 2 3, 4 5 6)'); -st_xmin -------- -1 - -SELECT ST_XMin(ST_GeomFromText('LINESTRING(1 3 4, 5 6 7)')); -st_xmin -------- -1 - -SELECT ST_XMin(CAST('BOX(-3 2, 3 4)' As box2d)); -st_xmin -------- --3 ---Observe THIS DOES NOT WORK because it will try to autocast the string representation to a BOX3D -SELECT ST_XMin('LINESTRING(1 3, 5 6)'); - ---ERROR: BOX3D parser - doesnt start with BOX3D( - -SELECT ST_XMin(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)')); -st_xmin --------- -220186.995121892 - - - - - - See Also - - , , , , - - - - - - ST_YMax - - Returns Y maxima of a bounding box 2d or 3d or a geometry. - - - - - - float ST_YMax - box3d aGeomorBox2DorBox3D - - - - - - Description - - Returns Y maxima of a bounding box 2d or 3d or a geometry. - - - Although this function is only defined for box3d, it will work for box2d and geometry because of the auto-casting behavior - defined for geometries and box2d. However you can not feed it a geometry or box2d text represenation, since that will not auto-cast. - - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - This method supports Circular Strings and curves - - - - - Examples - - SELECT ST_YMax('BOX3D(1 2 3, 4 5 6)'); -st_ymax -------- -5 - -SELECT ST_YMax(ST_GeomFromText('LINESTRING(1 3 4, 5 6 7)')); -st_ymax -------- -6 - -SELECT ST_YMax(CAST('BOX(-3 2, 3 4)' As box2d)); -st_ymax -------- -4 ---Observe THIS DOES NOT WORK because it will try to autocast the string representation to a BOX3D -SELECT ST_YMax('LINESTRING(1 3, 5 6)'); - ---ERROR: BOX3D parser - doesnt start with BOX3D( - -SELECT ST_YMax(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)')); -st_ymax --------- -150506.126829327 - - - - - - See Also - - , , , , - - - - - - ST_YMin - - Returns Y minima of a bounding box 2d or 3d or a geometry. - - - - - - float ST_YMin - box3d aGeomorBox2DorBox3D - - - - - - Description - - Returns Y minima of a bounding box 2d or 3d or a geometry. - - - Although this function is only defined for box3d, it will work for box2d and geometry because of the auto-casting behavior - defined for geometries and box2d. However you can not feed it a geometry or box2d text represenation, since that will not auto-cast. - - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - This method supports Circular Strings and curves - - - - - Examples - - SELECT ST_YMin('BOX3D(1 2 3, 4 5 6)'); -st_ymin -------- -2 - -SELECT ST_YMin(ST_GeomFromText('LINESTRING(1 3 4, 5 6 7)')); -st_ymin -------- -3 - -SELECT ST_YMin(CAST('BOX(-3 2, 3 4)' As box2d)); -st_ymin -------- -2 ---Observe THIS DOES NOT WORK because it will try to autocast the string representation to a BOX3D -SELECT ST_YMin('LINESTRING(1 3, 5 6)'); - ---ERROR: BOX3D parser - doesnt start with BOX3D( - -SELECT ST_YMin(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)')); -st_ymin --------- -150406 - - - - - - See Also - - , , , , , - - - - - - ST_ZMax - - Returns Z minima of a bounding box 2d or 3d or a geometry. - - - - - - float ST_ZMax - box3d aGeomorBox2DorBox3D - - - - - - Description - - Returns Z maxima of a bounding box 2d or 3d or a geometry. - - - Although this function is only defined for box3d, it will work for box2d and geometry because of the auto-casting behavior - defined for geometries and box2d. However you can not feed it a geometry or box2d text represenation, since that will not auto-cast. - - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - This method supports Circular Strings and curves - - - - - Examples - - SELECT ST_ZMax('BOX3D(1 2 3, 4 5 6)'); -st_zmax -------- -6 - -SELECT ST_ZMax(ST_GeomFromEWKT('LINESTRING(1 3 4, 5 6 7)')); -st_zmax -------- -7 - -SELECT ST_ZMax('BOX3D(-3 2 1, 3 4 1)' ); -st_zmax -------- -1 ---Observe THIS DOES NOT WORK because it will try to autocast the string representation to a BOX3D -SELECT ST_ZMax('LINESTRING(1 3 4, 5 6 7)'); - ---ERROR: BOX3D parser - doesnt start with BOX3D( - -SELECT ST_ZMax(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)')); -st_zmax --------- -3 - - - - - - See Also - - , , , , , - - - - - - ST_ZMin - - Returns Z minima of a bounding box 2d or 3d or a geometry. - - - - - - float ST_ZMin - box3d aGeomorBox2DorBox3D - - - - - - Description - - Returns Z minima of a bounding box 2d or 3d or a geometry. - - - Although this function is only defined for box3d, it will work for box2d and geometry because of the auto-casting behavior - defined for geometries and box2d. However you can not feed it a geometry or box2d text represenation, since that will not auto-cast. - - - - - - - - This function supports 3d and will not drop the z-index. - - - - - - This method supports Circular Strings and curves - - - - - Examples - - SELECT ST_ZMin('BOX3D(1 2 3, 4 5 6)'); -st_zmin -------- -3 - -SELECT ST_ZMin(ST_GeomFromEWKT('LINESTRING(1 3 4, 5 6 7)')); -st_zmin -------- -4 - -SELECT ST_ZMin('BOX3D(-3 2 1, 3 4 1)' ); -st_zmin -------- -1 ---Observe THIS DOES NOT WORK because it will try to autocast the string representation to a BOX3D -SELECT ST_ZMin('LINESTRING(1 3 4, 5 6 7)'); - ---ERROR: BOX3D parser - doesnt start with BOX3D( - -SELECT ST_ZMin(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)')); -st_zmin --------- -1 - - - - - - See Also - - , , , , , , - - - - - - Exceptional Functions - These functions are rarely used functions that should only be used if your data is corrupted in someway. They are used for troubleshooting corruption - and also fixing things that should under normal circumstances, never happen. - - - - PostGIS_AddBBox - - Add bounding box to the geometry. - - - - - - geometry PostGIS_AddBBox - geometry geomA - - - - - - Description - - Add bounding box to the geometry. This would make bounding - box based queries faster, but will increase the size of the - geometry. - - - Bounding boxes are automatically added to geometries so in general this is not needed - unless the generated bounding box somehow becomes corrupted or you have an old install that is lacking bounding boxes. Then you need to drop the old and readd. - - - - - - - - This method supports Circular Strings and curves - - - - - Examples - - UPDATE sometable - SET the_geom = ST_AddBBox(the_geom) - WHERE ST_HasBBox(the_geom) = false; - - - - - See Also - - , - - - - - - PostGIS_DropBBox - - Drop the bounding box cache from the geometry. - - - - - - geometry PostGIS_DropBBox - geometry geomA - - - - - - Description - - Drop the bounding box cache from the geometry. This reduces - geometry size, but makes bounding-box based queries slower. It is also used to drop a corrupt bounding box. A tale-tell sign of a corrupt cached bounding box - is when your ST_Intersects and other relation queries leave out geometries that rightfully should return true. - - - Bounding boxes are automatically added to geometries and improve speed of queries so in general this is not needed - unless the generated bounding box somehow becomes corrupted or you have an old install that is lacking bounding boxes. - Then you need to drop the old and readd. This kind of corruption has been observed in 8.3-8.3.6 series whereby cached bboxes were not always recalculated when a geometry changed and upgrading to a newer version without a dump reload will not - correct already corrupted boxes. So one can manually correct using below and readd the bbox or do a dump reload. - - - - - - - - This method supports Circular Strings and curves - - - - - Examples - - --This example drops bounding boxes where the cached box is not correct - --The force to ST_AsBinary before applying Box2D forces a recalculation of the box, and Box2D applied to the table geometry always - -- returns the cached bounding box. - UPDATE sometable - SET the_geom = PostGIS_DropBBox(the_geom) - WHERE Not (Box2D(ST_AsBinary(the_geom)) = Box2D(the_geom)); - - UPDATE sometable - SET the_geom = PostGIS_AddBBox(the_geom) - WHERE Not PostGIS_HasBBOX(the_geom); - - - - - - - - See Also - - , , - - - - - - - PostGIS_HasBBox - - Returns TRUE if the bbox of this geometry is cached, FALSE otherwise. - - - - - - boolean PostGIS_HasBBox - geometry geomA - - - - - - Description - - Returns TRUE if the bbox of this geometry is cached, FALSE - otherwise. Use and to control caching. - - - - - - - - This method supports Circular Strings and curves - - - - - Examples - - SELECT the_geom -FROM sometable WHERE PostGIS_HasBBox(the_geom) = false; - - - - - See Also - - , - - - - - - diff --git a/doc/reference_accessor.xml b/doc/reference_accessor.xml new file mode 100644 index 000000000..09e06afc3 --- /dev/null +++ b/doc/reference_accessor.xml @@ -0,0 +1,1865 @@ + + + + Geometry Accessors + + + + GeometryType + + Returns the type of the geometry as a string. Eg: + 'LINESTRING', 'POLYGON', 'MULTIPOINT', etc. + + + + + + text GeometryType + geometry geomA + + + + + + Description + + Returns the type of the geometry as a string. Eg: + 'LINESTRING', 'POLYGON', 'MULTIPOINT', etc. + + OGC SPEC s2.1.1.1 - Returns the name of the instantiable + subtype of Geometry of which this Geometry instance is a member. + The name of the instantiable subtype of Geometry is returned as a + string. + + + This function also indicates if the geometry is measured, + by returning a string of the form 'POINTM'. + + + &sfs_compliant; + &curve_support; + + + + + + Examples + + SELECT GeometryType(ST_GeomFromText('LINESTRING(77.29 29.07,77.42 29.26,77.27 29.31,77.29 29.07)')); + geometrytype +-------------- + LINESTRING + + + + + + See Also + + + + + + ST_Boundary + + Returns the closure of the combinatorial boundary of this + Geometry. + + + + + + geometry ST_Boundary + + geometry geomA + + + + + + Description + + Returns the closure of the combinatorial boundary of this + Geometry. The combinatorial boundary is defined as described in + section 3.12.3.2 of the OGC SPEC. Because the result of this + function is a closure, and hence topologically closed, the + resulting boundary can be represented using representational + geometry primitives as discussed in the OGC SPEC, section + 3.12.2. + Performed by the GEOS module + + Do not call with a GEOMETRYCOLLECTION as an argument + + + &sfs_compliant; OGC SPEC s2.1.1.1 + &sqlmm_compliant; SQL-MM 3: 5.1.14 + &Z_support; + + + + Examples + + SELECT ST_AsText(ST_Boundary(ST_GeomFromText('LINESTRING(1 1,0 0, -1 1)'))); +st_astext +----------- +MULTIPOINT(1 1,-1 1) + +SELECT ST_AsText(ST_Boundary(ST_GeomFromText('POLYGON((1 1,0 0, -1 1, 1 1))'))); +st_astext +---------- +LINESTRING(1 1,0 0,-1 1,1 1) + +--Using a 3d polygon +SELECT ST_AsEWKT(ST_Boundary(ST_GeomFromEWKT('POLYGON((1 1 1,0 0 1, -1 1 1, 1 1 1))'))); + +st_asewkt +----------------------------------- +LINESTRING(1 1 1,0 0 1,-1 1 1,1 1 1) + +--Using a 3d multilinestring +SELECT ST_AsEWKT(ST_Boundary(ST_GeomFromEWKT('MULTILINESTRING((1 1 1,0 0 0.5, -1 1 1),(1 1 0.5,0 0 0.5, -1 1 0.5, 1 1 0.5) )'))); + +st_asewkt +---------- +MULTIPOINT(-1 1 1,1 1 0.75) + + + + See Also + + , + + + + + + ST_CoordDim + + Return the coordinate dimension of the ST_Geometry value. + + + + + + integer ST_CoordDim + geometry geomA + + + + + + Description + + Return the coordinate dimension of the ST_Geometry value. + + This is the MM compliant alias name for + + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 5.1.3 + &curve_support; + &Z_support; + + + + + + Examples + + SELECT ST_CoordDim('CIRCULARSTRING(1 2 3, 1 3 4, 5 6 7, 8 9 10, 11 12 13)'); + ---result-- + 3 + + SELECT ST_CoordDim(ST_Point(1,2)); + --result-- + 2 + + + + + + + See Also + + + + + + + + ST_Dimension + + The inherent dimension of this Geometry object, which must + be less than or equal to the coordinate dimension. + + + + + + integer ST_Dimension + + geometry g + + + + + + Description + + The inherent dimension of this Geometry object, which must + be less than or equal to the coordinate dimension. OGC SPEC + s2.1.1.1 - returns 0 for POINT, 1 for LINESTRING, 2 for POLYGON, and + the largest dimension of the components of a + GEOMETRYCOLLECTION. + + &sqlmm_compliant; SQL-MM 3: 5.1.2 + + + + + Examples + + SELECT ST_Dimension('GEOMETRYCOLLECTION(LINESTRING(1 1,0 0),POINT(0 0))'); +ST_Dimension +----------- +1 + + + + See Also + + + + + + + + ST_EndPoint + + Returns the last point of a LINESTRING + geometry as a POINT. + + + + + + boolean ST_EndPoint + + geometry g + + + + + + Description + + Returns the last point of a LINESTRING geometry + as a POINT or NULL if the input + parameter is not a LINESTRING. + + &sqlmm_compliant; SQL-MM 3: 7.1.4 + &Z_support; + + + + + Examples + + postgis=# SELECT ST_AsText(ST_EndPoint('LINESTRING(1 1, 2 2, 3 3)'::geometry)); + st_astext +------------ + POINT(3 3) +(1 row) + +postgis=# SELECT ST_EndPoint('POINT(1 1)'::geometry) IS NULL AS is_null; + is_null +---------- + t +(1 row) + +--3d endpoint +SELECT ST_AsEWKT(ST_EndPoint('LINESTRING(1 1 2, 1 2 3, 0 0 5)')); + st_asewkt +-------------- + POINT(0 0 5) +(1 row) + + + + + See Also + + , + + + + + + ST_Envelope + + Returns a geometry representing the bounding box of the + supplied geometry. + + + + + + boolean ST_Envelope + + geometry g1 + + + + + + Description + + Returns the minimum bounding box for the supplied geometry, as a geometry. + The polygon is defined by the corner points of the bounding box + ((MINX, MINY), + (MINX, MAXY), + (MAXX, MAXY), + (MAXX, MINY), + (MINX, MINY)). (PostGIS will add a + ZMIN/ZMAX coordinate as + well). + + Degenerate cases (vertical lines, points) will return a geometry of + lower dimension than POLYGON, ie. + POINT or LINESTRING. + + + In PostGIS, the bounding box of a geometry is represented internally using + float4s instead of float8s that are used + to store geometries. The bounding box coordinates are floored, guarenteeing + that the geometry is contained entirely within its bounds. This has the + advantage that a geometry's bounding box is half the size as the minimum + bounding rectangle, which means significantly faster indexes and general performance. + But it also means that the bounding box is NOT the same as the minimum bounding + rectangle that bounds the geometry. + + + &sfs_compliant; s2.1.1.1 + &sqlmm_compliant; SQL-MM 3: 5.1.15 + + + + Examples + + + SELECT ST_AsText(ST_Envelope('POINT(1 3)'::geometry)); + st_astext + ------------ + POINT(1 3) + (1 row) + + + SELECT ST_AsText(ST_Envelope('LINESTRING(0 0, 1 3)'::geometry)); + st_astext + -------------------------------- + POLYGON((0 0,0 3,1 3,1 0,0 0)) + (1 row) + + + SELECT ST_AsText(ST_Envelope('POLYGON((0 0, 0 1, 1.0000001 1, 1.0000001 0, 0 0))'::geometry)); + st_astext + -------------------------------------------------------------- + POLYGON((0 0,0 1,1.00000011920929 1,1.00000011920929 0,0 0)) + (1 row) + SELECT ST_AsText(ST_Envelope('POLYGON((0 0, 0 1, 1.0000000001 1, 1.0000000001 0, 0 0))'::geometry)); + st_astext + -------------------------------------------------------------- + POLYGON((0 0,0 1,1.00000011920929 1,1.00000011920929 0,0 0)) + (1 row) + + + + + + ST_ExteriorRing + + Returns a line string representing the exterior ring of the POLYGON geometry. Return + NULL if the geometry is not a polygon. Will not work with MULTIPOLYGON + + + + + + geometry ST_ExteriorRing + + geometry a_polygon + + + + + + Description + + Returns a line string representing the exterior ring of the POLYGON geometry. Return + NULL if the geometry is not a polygon. + + Only works with POLYGON geometry types + + &sfs_compliant; 2.1.5.1 + &sqlmm_compliant; SQL-MM 3: 8.2.3, 8.3.3 + &Z_support; + + + + + Examples + +--If you have a table of polygons +SELECT gid, ST_ExteriorRing(the_geom) AS ering +FROM sometable; + +--If you have a table of MULTIPOLYGONs +--and want to return a MULTILINESTRING composed of the exterior rings of each polygon +SELECT gid, ST_Collect(ST_ExteriorRing(the_geom)) AS erings + FROM (SELECT gid, (ST_Dump(the_geom)).geom As the_geom + FROM sometable) As foo +GROUP BY gid; + +--3d Example +SELECT ST_AsEWKT( + ST_ExteriorRing( + ST_GeomFromEWKT('POLYGON((0 0 1, 1 1 1, 1 2 1, 1 1 1, 0 0 1))') + ) +); + +st_asewkt +--------- +LINESTRING(0 0 1,1 1 1,1 2 1,1 1 1,0 0 1) + + + + + See Also + + , + + + + + + ST_GeometryN + + Return the 1-based Nth geometry if the geometry is a + GEOMETRYCOLLECTION, MULTIPOINT, MULTILINESTRING, MULTICURVE or MULTIPOLYGON. + Otherwise, return NULL. + + + + + + geometry ST_GeometryN + geometry geomA + integer n + + + + + + Description + + Return the 1-based Nth geometry if the geometry is a + GEOMETRYCOLLECTION, MULTIPOINT, MULTILINESTRING, MULTICURVE or MULTIPOLYGON. + Otherwise, return NULL. + + + Index is 1-based as for OGC specs since version 0.8.0. + Previous versions implemented this as 0-based instead. + + + + If you want to extract all geometries, of a geometry, ST_Dump is more efficient and will also work for singular geoms. + + + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 9.1.5 + &Z_support; + &curve_support; + + + + + + Examples + + +--Extracting a subset of points from a 3d multipoint +SELECT n, ST_AsEWKT(ST_GeometryN(the_geom, n)) As geomewkt +FROM ( +VALUES (ST_GeomFromEWKT('MULTIPOINT(1 2 7, 3 4 7, 5 6 7, 8 9 10)') ), +( ST_GeomFromEWKT('MULTICURVE(CIRCULARSTRING(2.5 2.5,4.5 2.5, 3.5 3.5), (10 11, 12 11))') ) + )As foo(the_geom) + CROSS JOIN generate_series(1,100) n +WHERE n <= ST_NumGeometries(the_geom); + + n | geomewkt +---+----------------------------------------- + 1 | POINT(1 2 7) + 2 | POINT(3 4 7) + 3 | POINT(5 6 7) + 4 | POINT(8 9 10) + 1 | CIRCULARSTRING(2.5 2.5,4.5 2.5,3.5 3.5) + 2 | LINESTRING(10 11,12 11) + + +--Extracting all geometries (useful when you want to assign an id) +SELECT gid, n, ST_GeometryN(the_geom, n) +FROM sometable CROSS JOIN generate_series(1,100) n +WHERE n <= ST_NumGeometries(the_geom); + + + + + + + + See Also + + , + + + + + + ST_GeometryType + Return the geometry type of the ST_Geometry value. + + + + + + text ST_GeometryType + geometry g1 + + + + + Description + + Returns the type of the geometry as a string. EG: 'ST_Linestring', 'ST_Polygon','ST_MultiPolygon' etc. This function differs from GeometryType(geometry) in the case of the string and ST in front that is returned, as well as the fact that it will not indicate whether the geometry is measured. + + &sqlmm_compliant; SQL-MM 3: 5.1.4 + + + + + Examples + + SELECT ST_GeometryType(ST_GeomFromText('LINESTRING(77.29 29.07,77.42 29.26,77.27 29.31,77.29 29.07)')); + --result + ST_LineString + + + + See Also + + + + + + + + + + ST_InteriorRingN + + Return the Nth interior linestring ring of the polygon geometry. + Return NULL if the geometry is not a polygon or the given N is out + of range. + + + + + + geometry ST_InteriorRingN + geometry a_polygon + integer n + + + + + + Description + + Return the Nth interior linestring ring of the polygon geometry. + Return NULL if the geometry is not a polygon or the given N is out + of range. index starts at 1. + + + + This will not work for MULTIPOLYGONs. Use in conjunction with ST_Dump for MULTIPOLYGONS + + + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 8.2.6, 8.3.5 + &Z_support; + + + + + + Examples + + +SELECT ST_AsText(ST_InteriorRingN(the_geom, 1)) As the_geom +FROM (SELECT ST_BuildArea( + ST_Collect(ST_Buffer(ST_Point(1,2), 20,3), + ST_Buffer(ST_Point(1, 2), 10,3))) As the_geom + ) as foo + + + + + + See Also + + , , , , + + + + + + ST_IsClosed + + Returns TRUE if the + LINESTRING's start and end points are coincident. + + + + + + + boolean ST_IsClosed + + geometry g + + + + + + Description + + Returns TRUE if the LINESTRING's + start and end points are coincident. + + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 7.1.5, 9.3.3 + + SQL-MM defines the result of + ST_IsClosed(NULL) to be 0, while + PostGIS returns NULL. + + + &Z_support; + &curve_support; + + + + + Examples + + postgis=# SELECT ST_IsClosed('LINESTRING(0 0, 1 1)'::geometry); + st_isclosed +------------- + f +(1 row) + +postgis=# SELECT ST_IsClosed('LINESTRING(0 0, 0 1, 1 1, 0 0)'::geometry); + st_isclosed +------------- + t +(1 row) + +postgis=# SELECT ST_IsClosed('MULTILINESTRING((0 0, 0 1, 1 1, 0 0),(0 0, 1 1))'::geometry); + st_isclosed +------------- + f +(1 row) + +postgis=# SELECT ST_IsClosed('POINT(0 0)'::geometry); + st_isclosed +------------- + t +(1 row) + +postgis=# SELECT ST_IsClosed('MULTIPOINT((0 0), (1 1))'::geometry); + st_isclosed +------------- + t +(1 row) + + + + See Also + + + + + + + + ST_IsEmpty + + Returns true if this Geometry is an empty geometry . If + true, then this Geometry represents the empty point set - i.e. + GEOMETRYCOLLECTION(EMPTY). + + + + + + + boolean ST_IsEmpty + geometry geomA + + + + + + Description + + Returns true if this Geometry is an empty geometry . If + true, then this Geometry represents an empty geometry collection, polygon, point etc. + + SQL-MM defines the result of ST_IsEmpty(NULL) to be 0, while + PostGIS returns NULL. + + + &sfs_compliant; s2.1.1.1 + &sqlmm_compliant; SQL-MM 3: 5.1.7 + &curve_support; + + + + + + Examples + + +SELECT ST_IsEmpty('GEOMETRYCOLLECTION(EMPTY)'); + st_isempty +------------ + t +(1 row) + + SELECT ST_IsEmpty(ST_GeomFromText('POLYGON EMPTY')); + st_isempty +------------ + t +(1 row) + +SELECT ST_IsEmpty(ST_GeomFromText('POLYGON((1 2, 3 4, 5 6, 1 2))')); + + st_isempty +------------ + f +(1 row) + + SELECT ST_IsEmpty(ST_GeomFromText('POLYGON((1 2, 3 4, 5 6, 1 2))')) = false; + ?column? +---------- + t +(1 row) + + SELECT ST_IsEmpty(ST_GeomFromText('CIRCULARSTRING EMPTY')); + st_isempty +------------ + t +(1 row) + + + + + + + + + + ST_IsRing + + Returns TRUE if this + LINESTRING is both closed and simple. + + + + + + boolean ST_IsRing + + geometry g + + + + + + Description + + Returns TRUE if this + LINESTRING is both + (ST_StartPoint(g) + ~= + ST_Endpoint(g)) and (does not self intersect). + + &sfs_compliant; 2.1.5.1 + &sqlmm_compliant; SQL-MM 3: 7.1.6 + + SQL-MM defines the result of + ST_IsRing(NULL) to be 0, while + PostGIS returns NULL. + + + + + Examples + + SELECT ST_IsRing(the_geom), ST_IsClosed(the_geom), ST_IsSimple(the_geom) +FROM (SELECT 'LINESTRING(0 0, 0 1, 1 1, 1 0, 0 0)'::geometry AS the_geom) AS foo; + st_isring | st_isclosed | st_issimple +-----------+-------------+------------- + t | t | t +(1 row) + +SELECT ST_IsRing(the_geom), ST_IsClosed(the_geom), ST_IsSimple(the_geom) +FROM (SELECT 'LINESTRING(0 0, 0 1, 1 0, 1 1, 0 0)'::geometry AS the_geom) AS foo; + st_isring | st_isclosed | st_issimple +-----------+-------------+------------- + f | t | f +(1 row) + + + + See Also + + , , , + + + + + + + + ST_IsSimple + + Returns (TRUE) if this Geometry has no anomalous geometric + points, such as self intersection or self tangency. + + + + + + boolean ST_IsSimple + geometry geomA + + + + + + Description + + Returns true if this Geometry has no anomalous geometric + points, such as self intersection or self tangency. For more + information on the OGC's definition of geometry simplicity and validity, refer + to "Ensuring OpenGIS compliancy of geometries" + + + SQL-MM defines the result of ST_IsSimple(NULL) to be 0, + while PostGIS returns NULL. + + + &sfs_compliant; s2.1.1.1 + &sqlmm_compliant; SQL-MM 3: 5.1.8 + &Z_support; + + + + + Examples + + SELECT ST_IsSimple(ST_GeomFromText('POLYGON((1 2, 3 4, 5 6, 1 2))')); + st_issimple +------------- + t +(1 row) + + SELECT ST_IsSimple(ST_GeomFromText('LINESTRING(1 1,2 2,2 3.5,1 3,1 2,2 1)')); + st_issimple +------------- + f +(1 row) + + + + See Also + + + + + + + + ST_IsValid + + Returns true if the + ST_Geometry is well formed. + + + + + + + boolean ST_IsValid + + geometry g + + + + + + Description + + Test if an ST_Geometry value is well formed. For geometries that are invalid, + the PostgreSQL NOTICE will provide details of why it is not valid. For more + information on the OGC's definition of geometry simplicity and validity, refer + to "Ensuring OpenGIS compliancy of geometries" + + SQL-MM defines the result of ST_IsValid(NULL) to be 0, while + PostGIS returns NULL. + + + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 5.1.9 + + + + + Examples + + SELECT ST_IsValid(ST_GeomFromText('LINESTRING(0 0, 1 1)')) As good_line, + ST_IsValid(ST_GeomFromText('POLYGON((0 0, 1 1, 1 2, 1 1, 0 0))')) As bad_poly +--results +NOTICE: Self-intersection at or near point 0 0 + good_line | bad_poly +-----------+---------- + t | f + + + + + See Also + + , , + + + + + + ST_IsValidReason + + Returns text stating if a geometry is valid or not and if not valid, a reason why. + + + + + + text ST_IsValidReason + geometry geomA + + + + + + Description + + Returns text stating if a geometry is valid or not an if not valid, a reason why. + + Useful in combination with ST_IsValid to generate a detailed report of invalid geometries and reasons. + Availability: 1.4 - requires GEOS >= 3.1.0. + + + + + + Examples + + +--First 3 Rejects from a successful quintuplet experiment +SELECT gid, ST_IsValidReason(the_geom) as validity_info +FROM +(SELECT ST_MakePolygon(ST_ExteriorRing(e.buff), ST_Accum(f.line)) As the_geom, gid +FROM (SELECT ST_Buffer(ST_MakePoint(x1*10,y1), z1) As buff, x1*10 + y1*100 + z1*1000 As gid + FROM generate_series(-4,6) x1 + CROSS JOIN generate_series(2,5) y1 + CROSS JOIN generate_series(1,8) z1 + WHERE x1 > y1*0.5 AND z1 < x1*y1) As e + INNER JOIN (SELECT ST_Translate(ST_ExteriorRing(ST_Buffer(ST_MakePoint(x1*10,y1), z1)),y1*1, z1*2) As line + FROM generate_series(-3,6) x1 + CROSS JOIN generate_series(2,5) y1 + CROSS JOIN generate_series(1,10) z1 + WHERE x1 > y1*0.75 AND z1 < x1*y1) As f +ON (ST_Area(e.buff) > 78 AND ST_Contains(e.buff, f.line)) +GROUP BY gid, e.buff) As quintuplet_experiment +WHERE ST_IsValid(the_geom) = false +ORDER BY gid +LIMIT 3; + + gid | validity_info +------+-------------------------- + 5330 | Self-intersection [32 5] + 5340 | Self-intersection [42 5] + 5350 | Self-intersection [52 5] + + --simple example +SELECT ST_IsValidReason('LINESTRING(220227 150406,2220227 150407,222020 150410)'); + + st_isvalidreason +------------------ + Valid Geometry + + + + + + + See Also + + , + + + + + + ST_M + + Return the M coordinate of the point, or NULL if not + available. Input must be a point. + + + + + + float ST_M + geometry a_point + + + + + + Description + + Return the M coordinate of the point, or NULL if not + available. Input must be a point. + + + This is not (yet) part of the OGC spec, but is listed here + to complete the point coordinate extractor function list. + + &sfs_compliant; + &sqlmm_compliant; + &Z_support; + + + + + + Examples + SELECT ST_M(ST_GeomFromEWKT('POINT(1 2 3 4)')); + st_m +------ + 4 +(1 row) + + + + + + + See Also + + , , , + + + + + + ST_NDims + Returns coordinate dimension of the geometry as a small int. + Values are: 2,3 or 4. + + + + + + integer ST_NDims + geometry g1 + + + + + + Description + + Returns the coordinate dimension of the geometry. PostGIS supports 2 - (x,y) , + 3 - (x,y,z) or 2D with measure - x,y,m, and 4 - 3D with measure space x,y,z,m + + &Z_support; + + + + Examples + + SELECT ST_NDims(ST_GeomFromText('POINT(1 1)')) As d2point, + ST_NDims(ST_GeomFromEWKT('POINT(1 1 2)')) As d3point, + ST_NDims(ST_GeomFromEWKT('POINTM(1 1 0.5)')) As d2pointm; + + d2point | d3point | d2pointm +---------+---------+---------- + 2 | 3 | 3 + + + + See Also + , , + + + + + + ST_NPoints + Return the number of points (vertexes) in a geometry. + + + + + + integer ST_NPoints + geometry g1 + + + + + + Description + + Return the number of points in a geometry. Works for all geometries. + Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ + &Z_support; + &curve_support; + + + + + Examples + +SELECT ST_NPoints(ST_GeomFromText('LINESTRING(77.29 29.07,77.42 29.26,77.27 29.31,77.29 29.07)')); +--result +4 + +--Polygon in 3D space +SELECT ST_NPoints(ST_GeomFromEWKT('LINESTRING(77.29 29.07 1,77.42 29.26 0,77.27 29.31 -1,77.29 29.07 3)')) +--result +4 + + + See Also + + + + + + + + ST_NRings + If the geometry is a polygon or multi-polygon returns the number of rings. + + + + + + integer ST_NRings + geometry geomA + + + + + + Description + + If the geometry is a polygon or multi-polygon returns the number of rings. Unlike NumInteriorRings, it counts + the outer rings as well. + &Z_support; + &curve_support; + + + + + Examples + + SELECT ST_NRings(the_geom) As Nrings, ST_NumInteriorRings(the_geom) As ninterrings + FROM (SELECT ST_GeomFromText('POLYGON((1 2, 3 4, 5 6, 1 2))') As the_geom) As foo; + nrings | ninterrings +--------+------------- + 1 | 0 +(1 row) + + + + + + See Also + + + + + + + + ST_NumGeometries + If geometry is a GEOMETRYCOLLECTION (or MULTI*) return the + number of geometries, otherwise return NULL. + + + + + + integer ST_NumGeometries + geometry a_multi_or_geomcollection + + + + + + Description + + Returns the number of Geometries. If geometry is a GEOMETRYCOLLECTION (or MULTI*) return the + number of geometries, otherwise return NULL. + + &sqlmm_compliant; SQL-MM 3: 9.1.4 + + + + + Examples + + +--Although ST_NumGeometries will return null when passed a single, you can wrap in ST_Multi to force 1 or more for all geoms +SELECT ST_NumGeometries(ST_Multi(ST_GeomFromText('LINESTRING(77.29 29.07,77.42 29.26,77.27 29.31,77.29 29.07)'))); +--result +1 + +--Geometry Collection Example - multis count as one geom in a collection +SELECT ST_NumGeometries(ST_GeomFromEWKT('GEOMETRYCOLLECTION(MULTIPOINT(-2 3 , -2 2), +LINESTRING(5 5 ,10 10), +POLYGON((-7 4.2,-7.1 5,-7.1 4.3,-7 4.2)))')); +--result +3 + + + + See Also + + , + + + + + + ST_NumInteriorRings + Return the number of interior rings of the first polygon in + the geometry. This will work with both POLYGON and MULTIPOLYGON types but only looks at the first polygon. + Return NULL if there is no polygon in the + geometry. + + + + + + integer ST_NumInteriorRings + geometry a_polygon + + + + + + Description + + Return the number of interior rings of the first polygon in + the geometry. This will work with both POLYGON and MULTIPOLYGON types but only looks at the first polygon. + Return NULL if there is no polygon in the + geometry. + + &sqlmm_compliant; SQL-MM 3: 8.2.5 + + + + Examples + + +--If you have a regular polygon +SELECT gid, field1, field2, ST_NumInteriorRings(the_geom) AS numholes +FROM sometable; + +--If you have multipolygons +--And you want to know the total number of interior rings in the MULTIPOLYGON +SELECT gid, field1, field2, SUM(ST_NumInteriorRings(the_geom)) AS numholes +FROM (SELECT gid, field1, field2, (ST_Dump(the_geom)).geom As the_geom + FROM sometable) As foo +GROUP BY gid, field1,field2; + + + + See Also + + + + + + + + ST_NumInteriorRing + Return the number of interior rings of the first polygon in + the geometry. Synonym to ST_NumInteriorRings. + + + + + + integer ST_NumInteriorRing + geometry a_polygon + + + + + + Description + + Return the number of interior rings of the first polygon in + the geometry. Synonym to ST_NumInteriorRings. The OpenGIS specs are + ambiguous about the exact function naming, so we provide both + spellings. + + &sqlmm_compliant; SQL-MM 3: 8.2.5 + + + + See Also + + + + + + + + ST_NumPoints + Return the number of points in an ST_LineString or + ST_CircularString value. + + + + + + integer ST_NumPoints + geometry g1 + + + + + + Description + + Return the number of points in an ST_LineString or + ST_CircularString value. Prior to 1.4 only works with Linestrings as the specs state. From 1.4 forward this is an alias for ST_NPoints which returns number of vertexes for + not just line strings. + Consider using ST_NPoints instead which is multi-purpose + and works with many geometry types. + + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 7.2.4 + + + + Examples + + SELECT ST_NumPoints(ST_GeomFromText('LINESTRING(77.29 29.07,77.42 29.26,77.27 29.31,77.29 29.07)')); + --result + 4 + + + + See Also + + + + + + + + ST_PointN + + Return the Nth point in the first linestring or circular linestring in the + geometry. Return NULL if there is no linestring in the + geometry. + + + + + + geometry ST_PointN + geometry a_linestring + integer n + + + + + + Description + + Return the Nth point in the first linestring or circular linestring in the + geometry. Return NULL if there is no linestring in the + geometry. + + + Index is 1-based as for OGC specs since version 0.8.0. + Previous versions implemented this as 0-based instead. + + + + If you want to get the nth point of each line string in a multilinestring, use in conjunction + with ST_Dump + + + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 7.2.5, 7.3.5 + &Z_support; + &curve_support; + + + + + + Examples + + -- Extract all POINTs from a LINESTRING +SELECT ST_AsText( + ST_PointN( + column1, + generate_series(1, ST_NPoints(column1)) + )) +FROM ( VALUES ('LINESTRING(0 0, 1 1, 2 2)'::geometry) ) AS foo; + + st_astext +------------ + POINT(0 0) + POINT(1 1) + POINT(2 2) +(3 rows) + +--Example circular string +SELECT ST_AsText(ST_PointN(ST_GeomFromText('CIRCULARSTRING(1 2, 3 2, 1 2)'),2)); + +st_astext +---------- +POINT(3 2) + + + + + See Also + + + + + + + + ST_SRID + Returns the spatial reference identifier for the ST_Geometry as defined in spatial_ref_sys table. + + + + + + integer ST_SRID + geometry g1 + + + + + + Description + + Returns the spatial reference identifier for the ST_Geometry as defined in spatial_ref_sys table. + spatial_ref_sys + table is a table that catalogs all spatial reference systems known to PostGIS and is used for transformations from one spatial + reference system to another. So verifying you have the right spatial reference system identifier is important if you plan to ever transform your geometries. + &sfs_compliant; s2.1.1.1 + &sqlmm_compliant; SQL-MM 3: 5.1.5 + &curve_support; + + + + + Examples + + SELECT ST_SRID(ST_GeomFromText('POINT(-71.1043 42.315)',4326)); + --result + 4326 + + + + See Also + + ,, , + + + + + + ST_StartPoint + + Returns the first point of a LINESTRING + geometry as a POINT. + + + + + + geometry ST_StartPoint + + geometry geomA + + + + + + Description + + Returns the first point of a LINESTRING geometry + as a POINT or NULL if the input + parameter is not a LINESTRING. + + &sqlmm_compliant; SQL-MM 3: 7.1.3 + &Z_support; + + + + + Examples + + SELECT ST_AsText(ST_StartPoint('LINESTRING(0 1, 0 2)'::geometry)); + st_astext +------------ + POINT(0 1) +(1 row) + +SELECT ST_StartPoint('POINT(0 1)'::geometry) IS NULL AS is_null; + is_null +---------- + t +(1 row) + +--3d line +SELECT ST_AsEWKT(ST_StartPoint('LINESTRING(0 1 1, 0 2 2)'::geometry)); + st_asewkt +------------ + POINT(0 1 1) +(1 row) + + + + + + See Also + + , + + + + + ST_Summary + + Returns a text summary of the contents of the + ST_Geometry. + + + + + + + text ST_Summary + + geometry g + + + + + + Description + + Returns a text summary of the contents of the geometry. + &Z_support; + + + + + Examples + + SELECT ST_Summary(ST_GeomFromText('LINESTRING(0 0, 1 1)')) As good_line, + ST_Summary(ST_GeomFromText('POLYGON((0 0, 1 1, 1 2, 1 1, 0 0))')) As bad_poly +--results + good_line | bad_poly +----------------------+------------------------- + | +Line[B] with 2 points : Polygon[B] with 1 rings + : ring 0 has 5 points + : + +--3d polygon +SELECT ST_Summary(ST_GeomFromEWKT('LINESTRING(0 0 1, 1 1 1)')) As good_line, + ST_Summary(ST_GeomFromEWKT('POLYGON((0 0 1, 1 1 2, 1 2 3, 1 1 1, 0 0 1))')) As poly + +--results + good_line | poly +----------------------+------------------------- + | +Line[ZB] with 2 points : Polygon[ZB] with 1 rings + : ring 0 has 5 points + : + + + + + + See Also + + , + + + + + + ST_X + + Return the X coordinate of the point, or NULL if not + available. Input must be a point. + + + + + + float ST_X + geometry a_point + + + + + + Description + + Return the X coordinate of the point, or NULL if not + available. Input must be a point. + + If you want to get the max min x values of any geometry look at ST_XMin, ST_XMax functions. + + &sqlmm_compliant; SQL-MM 3: 6.1.3 + &Z_support; + + + + + + Examples + SELECT ST_X(ST_GeomFromEWKT('POINT(1 2 3 4)')); + st_x +------ + 1 +(1 row) + +SELECT ST_Y(ST_Centroid(ST_GeomFromEWKT('LINESTRING(1 2 3 4, 1 1 1 1)'))); + st_y +------ + 1.5 +(1 row) + + + + + + + See Also + + , , , , , , + + + + + + ST_Y + + Return the Y coordinate of the point, or NULL if not + available. Input must be a point. + + + + + + float ST_Y + geometry a_point + + + + + + Description + + Return the Y coordinate of the point, or NULL if not + available. Input must be a point. + + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 6.1.4 + &Z_support; + + + + + + Examples + SELECT ST_Y(ST_GeomFromEWKT('POINT(1 2 3 4)')); + st_y +------ + 2 +(1 row) + +SELECT ST_Y(ST_Centroid(ST_GeomFromEWKT('LINESTRING(1 2 3 4, 1 1 1 1)'))); + st_y +------ + 1.5 +(1 row) + + + + + + + + See Also + + , , , , , , + + + + + + ST_Z + + Return the Z coordinate of the point, or NULL if not + available. Input must be a point. + + + + + + float ST_Z + geometry a_point + + + + + + Description + + Return the Z coordinate of the point, or NULL if not + available. Input must be a point. + + + + &sqlmm_compliant; + &Z_support; + + + + + Examples + SELECT ST_Z(ST_GeomFromEWKT('POINT(1 2 3 4)')); + st_z +------ + 3 +(1 row) + + + + + + + See Also + + , , , , , + + + + + + ST_Zmflag + + Returns ZM (dimension semantic) flag of the geometries as a + small int. Values are: 0=2d, 1=3dm, 2=3dz, 3=4d. + + + + + + smallint ST_Zmflag + geometry geomA + + + + + + Description + + Returns ZM (dimension semantic) flag of the geometries as a + small int. Values are: 0=2d, 1=3dm, 2=3dz, 3=4d. + + &Z_support; + &curve_support; + + + + + Examples + + SELECT ST_Zmflag(ST_GeomFromEWKT('LINESTRING(1 2, 3 4)')); + st_zmflag +----------- + 0 + +SELECT ST_Zmflag(ST_GeomFromEWKT('LINESTRINGM(1 2 3, 3 4 3)')); + st_zmflag +----------- + 1 + +SELECT ST_Zmflag(ST_GeomFromEWKT('CIRCULARSTRING(1 2 3, 3 4 3, 5 6 3)')); + st_zmflag +----------- + 2 +SELECT ST_Zmflag(ST_GeomFromEWKT('POINT(1 2 3 4)')); + st_zmflag +----------- + 3 + + + + + + See Also + + , , + + + + + diff --git a/doc/reference_constructor.xml b/doc/reference_constructor.xml new file mode 100644 index 000000000..2228dc9d5 --- /dev/null +++ b/doc/reference_constructor.xml @@ -0,0 +1,1885 @@ + + + Geometry Constructors + + + ST_BdPolyFromText + + Construct a Polygon given an arbitrary collection of closed + linestrings as a MultiLineString Well-Known text representation. + + + + + + geometry ST_BdPolyFromText + text WKT + integer srid + + + + + + Description + + Construct a Polygon given an arbitrary collection of closed + linestrings as a MultiLineString Well-Known text representation. + + + + Throws an error if WKT is not a MULTILINESTRING. Throws an + error if output is a MULTIPOLYGON; use ST_BdMPolyFromText in that case, or + see ST_BuildArea() for a + postgis-specific approach. + + + &sfs_compliant; s3.2.6.2 + + Availability: 1.1.0 - requires GEOS >= 2.1.0. + + + + Examples + + Forthcoming + + + + See Also + , + + + + + + ST_BdMPolyFromText + Construct a MultiPolygon given an arbitrary collection of + closed linestrings as a MultiLineString text + representation Well-Known text representation. + + + + + + geometry ST_BdMPolyFromText + text WKT + integer srid + + + + + + Description + + Construct a Polygon given an arbitrary collection of closed + linestrings, polygons, MultiLineStrings as Well-Known text representation. + + + + Throws an error if WKT is not a MULTILINESTRING. Forces + MULTIPOLYGON output even when result is really only composed by a + single POLYGON; use ST_BdPolyFromText if you're sure a + single POLYGON will result from operation, or see ST_BuildArea() for a postgis-specific + approach. + + + &sfs_compliant; s3.2.6.2 + + Availability: 1.1.0 - requires GEOS >= 2.1.0. + + + + Examples + + Forthcoming + + + + See Also + , + + + + + + ST_GeographyFromText + Return a specified geography value from Well-Known Text representation or extended (WKT). + + + + + geography ST_GeographyFromText + text EWKT + + + + + Description + Returns a geography object from the well-known text representation. SRID 4326 is assumed. + + + + See Also + + + + + + + + ST_GeomCollFromText + + Makes a collection Geometry from collection WKT with the given SRID. If SRID is + not give, it defaults to -1. + + + + + + geometry ST_GeomCollFromText + text WKT + integer srid + + + + geometry ST_GeomCollFromText + text WKT + + + + + + + Description + + Makes a collection Geometry from the Well-Known-Text (WKT) representation with the given SRID. If SRID is + not give, it defaults to -1. + + OGC SPEC 3.2.6.2 - option SRID is from the conformance suite + + Returns null if the WKT is not a GEOMETRYCOLLECTION + + If you are absolutely sure all your WKT geometries are collections, don't use this function. + It is slower than ST_GeomFromText since it adds an additional validation step. + + + + &sfs_compliant; s3.2.6.2 + &sqlmm_compliant; + + + + + + Examples + + SELECT ST_GeomCollFromText('GEOMETRYCOLLECTION(POINT(1 2),LINESTRING(1 2, 3 4))'); + + + + + + See Also + + , + + + + + + + ST_GeomFromEWKB + Return a specified ST_Geometry value from Extended Well-Known Binary representation (EWKB). + + + + + + geometry ST_GeomFromEWKB + bytea EWKB + + + + + + Description + Constructs a PostGIS ST_Geometry object from the OGC Extended Well-Known binary (EWKT) representation. + + The EWKB format is not an OGC standard, but a PostGIS specific format that includes the spatial reference system (SRID) + identifier + + &Z_support; + &curve_support; + + + + Examples + line string binary rep 0f + LINESTRING(-71.160281 42.258729,-71.160837 42.259113,-71.161144 42.25932) in NAD 83 long lat (4269). + NOTE: Even though byte arrays are delimited with \ and may have ', we need to escape both out with \ and ''. So it does not + look exactly like its AsEWKB representation. + SELECT ST_GeomFromEWKB(E'\\001\\002\\000\\000 \\255\\020\\000\\000\\003\\000\\000\\000\\344J= +\\013B\\312Q\\300n\\303(\\010\\036!E@''\\277E''K +\\312Q\\300\\366{b\\235*!E@\\225|\\354.P\\312Q +\\300p\\231\\323e1!E@'); + + + See Also + , , + + + + + + ST_GeomFromEWKT + Return a specified ST_Geometry value from Extended Well-Known Text representation (EWKT). + + + + + + geometry ST_GeomFromEWKT + text EWKT + + + + + + Description + Constructs a PostGIS ST_Geometry object from the OGC Extended Well-Known text (EWKT) representation. + + The EWKT format is not an OGC standard, but an PostGIS specific format that includes the spatial reference system (SRID) + identifier + + &Z_support; + &curve_support; + + + + Examples + SELECT ST_GeomFromEWKT('SRID=4269;LINESTRING(-71.160281 42.258729,-71.160837 42.259113,-71.161144 42.25932)'); +SELECT ST_GeomFromEWKT('SRID=4269;MULTILINESTRING((-71.160281 42.258729,-71.160837 42.259113,-71.161144 42.25932))'); + +SELECT ST_GeomFromEWKT('SRID=4269;POINT(-71.064544 42.28787)'); + +SELECT ST_GeomFromEWKT('SRID=4269;POLYGON((-71.1776585052917 42.3902909739571,-71.1776820268866 42.3903701743239, +-71.1776063012595 42.3903825660754,-71.1775826583081 42.3903033653531,-71.1776585052917 42.3902909739571))'); + +SELECT ST_GeomFromEWKT('SRID=4269;MULTIPOLYGON(((-71.1031880899493 42.3152774590236, +-71.1031627617667 42.3152960829043,-71.102923838298 42.3149156848307, +-71.1023097974109 42.3151969047397,-71.1019285062273 42.3147384934248, +-71.102505233663 42.3144722937587,-71.10277487471 42.3141658254797, +-71.103113945163 42.3142739188902,-71.10324876416 42.31402489987, +-71.1033002961013 42.3140393340215,-71.1033488797549 42.3139495090772, +-71.103396240451 42.3138632439557,-71.1041521907712 42.3141153348029, +-71.1041411411543 42.3141545014533,-71.1041287795912 42.3142114839058, +-71.1041188134329 42.3142693656241,-71.1041112482575 42.3143272556118, +-71.1041072845732 42.3143851580048,-71.1041057218871 42.3144430686681, +-71.1041065602059 42.3145009876017,-71.1041097995362 42.3145589148055, +-71.1041166403905 42.3146168544148,-71.1041258822717 42.3146748022936, +-71.1041375307579 42.3147318674446,-71.1041492906949 42.3147711126569, +-71.1041598612795 42.314808571739,-71.1042515013869 42.3151287620809, +-71.1041173835118 42.3150739481917,-71.1040809891419 42.3151344119048, +-71.1040438678912 42.3151191367447,-71.1040194562988 42.3151832057859, +-71.1038734225584 42.3151140942995,-71.1038446938243 42.3151006300338, +-71.1038315271889 42.315094347535,-71.1037393329282 42.315054824985, +-71.1035447555574 42.3152608696313,-71.1033436658644 42.3151648370544, +-71.1032580383161 42.3152269126061,-71.103223066939 42.3152517403219, +-71.1031880899493 42.3152774590236)), +((-71.1043632495873 42.315113108546,-71.1043583974082 42.3151211109857, +-71.1043443253471 42.3150676015829,-71.1043850704575 42.3150793250568,-71.1043632495873 42.315113108546)))'); + +--3d circular string +SELECT ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)'); + + + + See Also + , , + + + + + ST_GeometryFromText + Return a specified ST_Geometry value from Well-Known Text representation (WKT). This is an alias name for ST_GeomFromText + + + + + geometry ST_GeometryFromText + text WKT + + + geometry ST_GeometryFromText + text WKT + integer srid + + + + + Description + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 5.1.40 + + + See Also + + + + + + + ST_GeomFromGML + Takes as input GML representation of geometry and outputs a PostGIS geometry object + + + + + + geometry ST_GeomFromGML + text geomgml + + + + + + Description + Constructs a PostGIS ST_Geometry object from the OGC GML representation. + + Requires compilation with libxml2 2.5+ + + ST_GeomFromGML works only for GML Geometry fragments. It throws an error if you try to use it on a whole GML document. + + OGC GML versions supported: + + + GML 3.2.1 Namespace + + + GML 3.1.1 Simple Features profile SF-2 (with GML 3.1.0 and 3.0.0 backward compatibility) + + + GML 2.1.2 + + + OGC GML standards, cf: http://www.opengeospatial.org/standards/gml: + + + Availability: 1.5 - requires libxml2 >= 2.5+ + &Z_support; + GML allow mixed dimensions (2D and 3D inside the same MultiGeometry for instance). As PostGIS geometries don't, ST_GeomFromGML convert the whole geometry to 2D if a missing Z dimension is found once. + + GML support mixed SRS inside the same MultiGeometry. As PostGIS geometries don't, ST_GeomFromGML, in this case, reproject all subgeometries to the SRS root node. If no srsName attribute available for the GML root node, the function throw an error. + + ST_GeomFromGML function is not pedantic about an explicit GML namespace. You could avoid to mention it explicitly for common usages. But you need it if you want to use XLink feature inside GML. + + ST_GeomFromGML function not support SQL/MM curves geometries. + + + + + + Examples - A single geometry with srsName + SELECT ST_GeomFromGML(' + + -71.16028,42.258729 -71.160837,42.259112 -71.161143,42.25932 + + ']]>); + + + + + Examples - XLink usage + + + 42.258729 -71.16028 + + 42.259112 -71.160837 + + + + ');]]>); + + + + + See Also + + + + + + + + ST_GeomFromKML + Takes as input KML representation of geometry and outputs a PostGIS geometry object + + + + + + geometry ST_GeomFromKML + text geomkml + + + + + + Description + Constructs a PostGIS ST_Geometry object from the OGC KML representation. + + Requires compilation with libxml2 2.5+ + + ST_GeomFromKML works only for KML Geometry fragments. It throws an error if you try to use it on a whole KML document. + + OGC KML versions supported: + + + KML 2.2.0 Namespace + + + OGC KML standards, cf: http://www.opengeospatial.org/standards/kml: + + + Availability: 1.5 - requires libxml2 >= 2.5+ + &Z_support; + + ST_GeomFromKML function not support SQL/MM curves geometries. + + + + + + Examples - A single geometry with srsName + SELECT ST_GeomFromKML(' + -71.1663,42.2614 + -71.1667,42.2616 + ']]>); + + + + + See Also + + + + + + + ST_GMLToSQL + Return a specified ST_Geometry value from GML representation. This is an alias name for ST_GeomFromGML + + + + + geometry ST_GMLToSQL + text geomgml + + + + + Description + &sqlmm_compliant; SQL-MM 3: 5.1.50 (except for curves support). + + + See Also + + + + + + + + ST_GeomFromText + Return a specified ST_Geometry value from Well-Known Text representation (WKT). + + + + + geometry ST_GeomFromText + text WKT + + + geometry ST_GeomFromText + text WKT + integer srid + + + + + + Description + + Constructs a PostGIS ST_Geometry object from the OGC Well-Known text representation. + + + + There are 2 variants of ST_GeomFromText function, the first takes no SRID and returns a geometry + with no defined spatial reference system. The second takes a spatial reference id as the second argument + and returns an ST_Geometry that includes this srid as part of its meta-data. The srid must be defined + in the spatial_ref_sys table. + + + &sfs_compliant; s3.2.6.2 - option SRID is from the conformance suite. + &sqlmm_compliant; SQL-MM 3: 5.1.40 + &curve_support; + + + + + Examples + SELECT ST_GeomFromText('LINESTRING(-71.160281 42.258729,-71.160837 42.259113,-71.161144 42.25932)'); +SELECT ST_GeomFromText('LINESTRING(-71.160281 42.258729,-71.160837 42.259113,-71.161144 42.25932)',4269); + +SELECT ST_GeomFromText('MULTILINESTRING((-71.160281 42.258729,-71.160837 42.259113,-71.161144 42.25932))'); + +SELECT ST_GeomFromText('POINT(-71.064544 42.28787)'); + +SELECT ST_GeomFromText('POLYGON((-71.1776585052917 42.3902909739571,-71.1776820268866 42.3903701743239, +-71.1776063012595 42.3903825660754,-71.1775826583081 42.3903033653531,-71.1776585052917 42.3902909739571))'); + +SELECT ST_GeomFromText('MULTIPOLYGON(((-71.1031880899493 42.3152774590236, +-71.1031627617667 42.3152960829043,-71.102923838298 42.3149156848307, +-71.1023097974109 42.3151969047397,-71.1019285062273 42.3147384934248, +-71.102505233663 42.3144722937587,-71.10277487471 42.3141658254797, +-71.103113945163 42.3142739188902,-71.10324876416 42.31402489987, +-71.1033002961013 42.3140393340215,-71.1033488797549 42.3139495090772, +-71.103396240451 42.3138632439557,-71.1041521907712 42.3141153348029, +-71.1041411411543 42.3141545014533,-71.1041287795912 42.3142114839058, +-71.1041188134329 42.3142693656241,-71.1041112482575 42.3143272556118, +-71.1041072845732 42.3143851580048,-71.1041057218871 42.3144430686681, +-71.1041065602059 42.3145009876017,-71.1041097995362 42.3145589148055, +-71.1041166403905 42.3146168544148,-71.1041258822717 42.3146748022936, +-71.1041375307579 42.3147318674446,-71.1041492906949 42.3147711126569, +-71.1041598612795 42.314808571739,-71.1042515013869 42.3151287620809, +-71.1041173835118 42.3150739481917,-71.1040809891419 42.3151344119048, +-71.1040438678912 42.3151191367447,-71.1040194562988 42.3151832057859, +-71.1038734225584 42.3151140942995,-71.1038446938243 42.3151006300338, +-71.1038315271889 42.315094347535,-71.1037393329282 42.315054824985, +-71.1035447555574 42.3152608696313,-71.1033436658644 42.3151648370544, +-71.1032580383161 42.3152269126061,-71.103223066939 42.3152517403219, +-71.1031880899493 42.3152774590236)), +((-71.1043632495873 42.315113108546,-71.1043583974082 42.3151211109857, +-71.1043443253471 42.3150676015829,-71.1043850704575 42.3150793250568,-71.1043632495873 42.315113108546)))',4326); + +SELECT ST_GeomFromText('CIRCULARSTRING(220268 150415,220227 150505,220227 150406)'); + + + + See Also + , , + + + + + + ST_GeomFromWKB + Creates a geometry instance from a Well-Known Binary geometry + representation (WKB) and optional SRID. + + + + + + geometry ST_GeomFromWKB + bytea geom + + + + geometry ST_GeomFromWKB + bytea geom + integer srid + + + + + + Description + + The ST_GeomFromWKB function, takes a well-known + binary representation of a geometry and a Spatial Reference System ID + (SRID) and creates an instance of the appropriate + geometry type. This function plays the role of the Geometry Factory in + SQL. This is an alternate name for ST_WKBToSQL. + + If SRID is not specified, it defaults to -1 (Unknown). + + &sfs_compliant; s3.2.7.2 - the optional SRID is from the conformance suite + + &sqlmm_compliant; SQL-MM 3: 5.1.41 + &curve_support; + + + + + + Examples + + --Although bytea rep contains single \, these need to be escaped when inserting into a table +SELECT ST_AsEWKT( +ST_GeomFromWKB(E'\\001\\002\\000\\000\\000\\002\\000\\000\\000\\037\\205\\353Q\\270~\\\\\\300\\323Mb\\020X\\231C@\\020X9\\264\\310~\\\\\\300)\\\\\\217\\302\\365\\230C@',4326) +); + st_asewkt +------------------------------------------------------ + SRID=4326;LINESTRING(-113.98 39.198,-113.981 39.195) +(1 row) + +SELECT + ST_AsText( + ST_GeomFromWKB( + ST_AsEWKB('POINT(2 5)'::geometry) + ) + ); + st_astext +------------ + POINT(2 5) +(1 row) + + + + + See Also + + , , + + + + + + ST_LineFromMultiPoint + + Creates a LineString from a MultiPoint geometry. + + + + + + geometry ST_LineFromMultiPoint + geometry aMultiPoint + + + + + + Description + + Creates a LineString from a MultiPoint geometry. + &Z_support; + + + + + Examples + + +--Create a 3d line string from a 3d multipoint +SELECT ST_AsEWKT(ST_LineFromMultiPoint(ST_GeomFromEWKT('MULTIPOINT(1 2 3, 4 5 6, 7 8 9)'))); +--result-- +LINESTRING(1 2 3,4 5 6,7 8 9) + + + + + + See Also + + , , + + + + + + ST_LineFromText + + Makes a Geometry from WKT representation with the given SRID. If SRID is + not given, it defaults to -1. + + + + + + geometry ST_LineFromText + text WKT + + + + geometry ST_LineFromText + text WKT + integer srid + + + + + + Description + + Makes a Geometry from WKT with the given SRID. If SRID is + not give, it defaults to -1. If WKT passed in is not a LINESTRING, then null is returned. + + + OGC SPEC 3.2.6.2 - option SRID is from the conformance + suite. + + + + If you know all your geometries are LINESTRINGS, its more efficient to just use ST_GeomFromText. + This just calls ST_GeomFromText and adds additional validation that it returns a linestring. + + + + &sfs_compliant; s3.2.6.2 + &sqlmm_compliant; SQL-MM 3: 7.2.8 + + + + + + Examples + + SELECT ST_LineFromText('LINESTRING(1 2, 3 4)') AS aline, ST_LineFromText('POINT(1 2)') AS null_return; +aline | null_return +------------------------------------------------ +010200000002000000000000000000F ... | t + + + + + + See Also + + + + + + + + ST_LineFromWKB + + Makes a LINESTRING from WKB with the given SRID + + + + + + geometry ST_LineFromWKB + bytea WKB + + + + geometry ST_LineFromWKB + bytea WKB + integer srid + + + + + + Description + + The ST_LineFromWKB function, takes a well-known binary + representation of geometry and a Spatial Reference System ID (SRID) + and creates an instance of the appropriate geometry type - in this case, a + LINESTRING geometry. This function plays the role of the Geometry + Factory in SQL. + + If an SRID is not specified, it defaults to -1. NULL is + returned if the input bytea + does not represent a LINESTRING. + + + OGC SPEC 3.2.6.2 - option SRID is from the conformance + suite. + + + + If you know all your geometries are LINESTRINGs, its more + efficient to just use . This function just + calls and adds additional validation that + it returns a linestring. + + + + &sfs_compliant; s3.2.6.2 + &sqlmm_compliant; SQL-MM 3: 7.2.9 + + + + + + Examples + + SELECT ST_LineFromWKB(ST_AsBinary(ST_GeomFromText('LINESTRING(1 2, 3 4)'))) AS aline, + ST_LineFromWKB(ST_AsBinary(ST_GeomFromText('POINT(1 2)'))) IS NULL AS null_return; +aline | null_return +------------------------------------------------ +010200000002000000000000000000F ... | t + + + + + + See Also + + , + + + + + + ST_LinestringFromWKB + + Makes a geometry from WKB with the given SRID. + + + + + + geometry ST_LinestringFromWKB + bytea WKB + + + + geometry ST_LinestringFromWKB + bytea WKB + integer srid + + + + + + Description + + The ST_LinestringFromWKB function, takes a well-known binary + representation of geometry and a Spatial Reference System ID (SRID) + and creates an instance of the appropriate geometry type - in this case, a + LINESTRING geometry. This function plays the role of the Geometry + Factory in SQL. + + If an SRID is not specified, it defaults to -1. NULL is + returned if the input bytea does not represent a + LINESTRING geometry. This an alias for . + + + OGC SPEC 3.2.6.2 - optional SRID is from the conformance suite. + + + + If you know all your geometries are LINESTRINGs, it's more + efficient to just use . This function just calls + and adds additional validation that it returns a + LINESTRING. + + + &sfs_compliant; s3.2.6.2 + &sqlmm_compliant; SQL-MM 3: 7.2.9 + + + + Examples + + SELECT + ST_LineStringFromWKB( + ST_AsBinary(ST_GeomFromText('LINESTRING(1 2, 3 4)')) + ) AS aline, + ST_LinestringFromWKB( + ST_AsBinary(ST_GeomFromText('POINT(1 2)')) + ) IS NULL AS null_return; + aline | null_return +------------------------------------------------ +010200000002000000000000000000F ... | t + + + + + See Also + + , + + + + + + ST_MakeBox2D + + Creates a BOX2D defined by the given point + geometries. + + + + + + box2d ST_MakeBox2D + geometry pointLowLeft + geometry pointUpRight + + + + + + Description + + Creates a BOX2D defined by the given point + geometries. This is useful for doing range queries + + + + + Examples + + +--Return all features that fall reside or partly reside in a US national atlas coordinate bounding box +--It is assumed here that the geometries are stored with SRID = 2163 (US National atlas equal area) +SELECT feature_id, feature_name, the_geom +FROM features +WHERE the_geom && ST_SetSRID(ST_MakeBox2D(ST_Point(-989502.1875, 528439.5625), + ST_Point(-987121.375 ,529933.1875)),2163) + + + + + See Also + + , , , + + + + + + ST_MakeBox3D + + Creates a BOX3D defined by the given 3d point + geometries. + + + + + + box3d ST_MakeBox3D + geometry point3DLowLeftBottom + geometry point3DUpRightTop + + + + + + Description + + Creates a BOX3D defined by the given 2 3D point + geometries. + + + + + + + This function supports 3d and will not drop the z-index. + + + + + Examples + + +SELECT ST_MakeBox3D(ST_MakePoint(-989502.1875, 528439.5625, 10), + ST_MakePoint(-987121.375 ,529933.1875, 10)) As abb3d + +--bb3d-- +-------- +BOX3D(-989502.1875 528439.5625 10,-987121.375 529933.1875 10) + + + + + + See Also + + , , + + + + + + ST_MakeLine + + Creates a Linestring from point geometries. + + + + + + geometry ST_MakeLine + geometry set pointfield + + + + geometry ST_MakeLine + geometry point1 + geometry point2 + + + + geometry ST_MakeLine + geometry[] point_array + + + + + + Description + + ST_MakeLine comes in 3 forms: a spatial aggregate that takes + rows of point geometries and returns a line string, a function that takes an array of points, and a regular function that takes two point geometries. You + might want to use a subselect to order points before feeding them + to the aggregate version of this function. + + &Z_support; + Availability: 1.4.0 - ST_MakeLine(geomarray) was introduced. ST_MakeLine aggregate functions was enhanced to handle more points faster. + + + + Examples: Spatial Aggregate version + This example takes a sequence of GPS points and creates one record for each + gps travel where the geometry field is a line string composed of the gps points + in the order of the travel. + + +SELECT gps.gps_track, ST_MakeLine(gps.the_geom) As newgeom + FROM (SELECT gps_track,gps_time, the_geom + FROM gps_points ORDER BY gps_track, gps_time) As gps + GROUP BY gps.gps_track + + + Examples: Non-Spatial Aggregate version + + First example is a simple one off line string composed of 2 points. The second formulates + line strings from 2 points a user draws. The third is a one-off that joins 2 3d points to create a line in 3d space. + +SELECT ST_AsText(ST_MakeLine(ST_MakePoint(1,2), ST_MakePoint(3,4))); + st_astext +--------------------- + LINESTRING(1 2,3 4) + +SELECT userpoints.id, ST_MakeLine(startpoint, endpoint) As drawn_line + FROM userpoints ; + +SELECT ST_AsEWKT(ST_MakeLine(ST_MakePoint(1,2,3), ST_MakePoint(3,4,5))); + st_asewkt +------------------------- + LINESTRING(1 2 3,3 4 5) + + + + + Examples: Using Array version + + +SELECT ST_MakeLine(ARRAY(SELECT ST_Centroid(the_geom) FROM visit_locations ORDER BY visit_time)); + +--Making a 3d line with 3 3-d points +SELECT ST_AsEWKT(ST_MakeLine(ARRAY[ST_MakePoint(1,2,3), + ST_MakePoint(3,4,5), ST_MakePoint(6,6,6)])); + st_asewkt +------------------------- +LINESTRING(1 2 3,3 4 5,6 6 6) + + + + See Also + , , , + + + + + + ST_MakePolygon + + Creates a Polygon formed by the given shell. Input + geometries must be closed LINESTRINGS. + + + + + + geometry ST_MakePolygon + geometry linestring + + + + + geometry ST_MakePolygon + geometry outerlinestring + geometry[] interiorlinestrings + + + + + + Description + + Creates a Polygon formed by the given shell. Input + geometries must be closed LINESTRINGS. Comes in 2 variants. + Variant 1: takes one closed linestring. + Variant 2: Creates a Polygon formed by the given shell and array of + holes. You can construct a geometry array using ST_Accum or the PostgreSQL ARRAY[] and + ARRAY() constructs. Input geometries must be closed LINESTRINGS. + + This function will not accept a MULTILINESTRING. Use or to generate line strings. + + + &Z_support; + + + + Examples: Single closed LINESTRING + +--2d line +SELECT ST_MakePolygon(ST_GeomFromText('LINESTRING(75.15 29.53,77 29,77.6 29.5, 75.15 29.53)')); +--If linestring is not closed +--you can add the start point to close it +SELECT ST_MakePolygon(ST_AddPoint(foo.open_line, ST_StartPoint(foo.open_line))) +FROM ( +SELECT ST_GeomFromText('LINESTRING(75.15 29.53,77 29,77.6 29.5)') As open_line) As foo; + +--3d closed line +SELECT ST_MakePolygon(ST_GeomFromText('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)) + +--measured line -- +SELECT ST_MakePolygon(ST_GeomFromText('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)) + + + + Examples: Outter shell with inner shells + + Build a donut with an ant hole + +SELECT ST_MakePolygon( + ST_ExteriorRing(ST_Buffer(foo.line,10)), + ARRAY[ST_Translate(foo.line,1,1), + ST_ExteriorRing(ST_Buffer(ST_MakePoint(20,20),1)) ] + ) +FROM + (SELECT ST_ExteriorRing(ST_Buffer(ST_MakePoint(10,10),10,10)) + As line ) + As foo; + + Build province boundaries with holes + representing lakes in the province from a set of + province polygons/multipolygons and water line strings + this is an example of using PostGIS ST_Accum + The use of CASE because feeding a null array into + ST_MakePolygon results in NULL + the use of left join to guarantee we get all provinces back even if they have no lakes + + SELECT p.gid, p.province_name, + CASE WHEN + ST_Accum(w.the_geom) IS NULL THEN p.the_geom + ELSE ST_MakePolygon(ST_LineMerge(ST_Boundary(p.the_geom)), ST_Accum(w.the_geom)) END + FROM + provinces p LEFT JOIN waterlines w + ON (ST_Within(w.the_geom, p.the_geom) AND ST_IsClosed(w.the_geom)) + GROUP BY p.gid, p.province_name, p.the_geom; + + --Same example above but utilizing a correlated subquery + --and PostgreSQL built-in ARRAY() function that converts a row set to an array + + SELECT p.gid, p.province_name, CASE WHEN + EXISTS(SELECT w.the_geom + FROM waterlines w + WHERE ST_Within(w.the_geom, p.the_geom) + AND ST_IsClosed(w.the_geom)) + THEN + ST_MakePolygon(ST_LineMerge(ST_Boundary(p.the_geom)), + ARRAY(SELECT w.the_geom + FROM waterlines w + WHERE ST_Within(w.the_geom, p.the_geom) + AND ST_IsClosed(w.the_geom))) + ELSE p.the_geom END As the_geom + FROM + provinces p; + + + + See Also + , , , , + + + + + + ST_MakePoint + + Creates a 2D,3DZ or 4D point geometry. + + + + + + geometry ST_MakePoint + double precision x + double precision y + + + + + geometry ST_MakePoint + double precision x + double precision y + double precision z + + + + + geometry ST_MakePoint + double precision x + double precision y + double precision z + double precision m + + + + + + Description + + Creates a 2D,3DZ or 4D point geometry (geometry with measure). + ST_MakePoint while not being OGC compliant is + generally faster and more precise than + and . It is also easier to use if + you have raw coordinates rather than WKT. + + Note x is longitude and y is latitude + &Z_support; + + + + + Examples + --Return point with unknown SRID +SELECT ST_MakePoint(-71.1043443253471, 42.3150676015829); + +--Return point marked as WGS 84 long lat +SELECT ST_SetSRID(ST_MakePoint(-71.1043443253471, 42.3150676015829),4326); + +--Return a 3D point (e.g. has altitude) +SELECT ST_MakePoint(1, 2,1.5); + +--Get z of point +SELECT ST_Z(ST_MakePoint(1, 2,1.5)); +result +------- +1.5 + + + See Also + , , + + + + + + ST_MakePointM + + Creates a point geometry with an x y and m coordinate. + + + + + + geometry ST_MakePointM + float x + float y + float m + + + + + + Description + + Creates a point with x, y and measure coordinates. + Note x is longitude and y is latitude. + + + + Examples + We use ST_AsEWKT in these examples to show the text representation instead of ST_AsText because ST_AsText does not + support returning M. + +--Return EWKT representation of point with unknown SRID +SELECT ST_AsEWKT(ST_MakePointM(-71.1043443253471, 42.3150676015829, 10)); + +--result + st_asewkt +----------------------------------------------- + POINTM(-71.1043443253471 42.3150676015829 10) + +--Return EWKT representation of point with measure marked as WGS 84 long lat +SELECT ST_AsEWKT(ST_SetSRID(ST_MakePointM(-71.1043443253471, 42.3150676015829,10),4326)); + + st_asewkt +--------------------------------------------------------- +SRID=4326;POINTM(-71.1043443253471 42.3150676015829 10) + +--Return a 3d point (e.g. has altitude) +SELECT ST_MakePoint(1, 2,1.5); + +--Get m of point +SELECT ST_M(ST_MakePointM(-71.1043443253471, 42.3150676015829,10)); +result +------- +10 + + + + See Also + , , + + + + + + ST_MLineFromText + + Return a specified ST_MultiLineString value from WKT representation. + + + + + + geometry ST_MLineFromText + text WKT + integer srid + + + + geometry ST_MLineFromText + text WKT + + + + + + + Description + + Makes a Geometry from Well-Known-Text (WKT) with the given SRID. If SRID is + not give, it defaults to -1. + + OGC SPEC 3.2.6.2 - option SRID is from the conformance + suite + + Returns null if the WKT is not a MULTILINESTRING + + + If you are absolutely sure all your WKT geometries are points, don't use this function. + It is slower than ST_GeomFromText since it adds an additional validation step. + + + + &sfs_compliant; s3.2.6.2 + &sqlmm_compliant;SQL-MM 3: 9.4.4 + + + + + + Examples + + SELECT ST_MLineFromText('MULTILINESTRING((1 2, 3 4), (4 5, 6 7))'); + + + + + See Also + + + + + + + + ST_MPointFromText + + Makes a Geometry from WKT with the given SRID. If SRID is + not give, it defaults to -1. + + + + + + geometry ST_MPointFromText + text WKT + integer srid + + + + geometry ST_MPointFromText + text WKT + + + + + + + Description + + Makes a Geometry from WKT with the given SRID. If SRID is + not give, it defaults to -1. + + OGC SPEC 3.2.6.2 - option SRID is from the conformance + suite + + Returns null if the WKT is not a MULTIPOINT + + + If you are absolutely sure all your WKT geometries are points, don't use this function. + It is slower than ST_GeomFromText since it adds an additional validation step. + + + + &sfs_compliant; 3.2.6.2 + &sqlmm_compliant; SQL-MM 3: 9.2.4 + + + + + + Examples + + SELECT ST_MPointFromText('MULTIPOINT(1 2, 3 4)'); +SELECT ST_MPointFromText('MULTIPOINT(-70.9590 42.1180, -70.9611 42.1223)', 4326); + + + + + See Also + + + + + + + + ST_MPolyFromText + + Makes a MultiPolygon Geometry from WKT with the given SRID. If SRID is + not give, it defaults to -1. + + + + + + geometry ST_MPolyFromText + text WKT + integer srid + + + + geometry ST_MPolyFromText + text WKT + + + + + + + Description + + Makes a MultiPolygon from WKT with the given SRID. If SRID is + not give, it defaults to -1. + + OGC SPEC 3.2.6.2 - option SRID is from the conformance suite + + + Throws an error if the WKT is not a MULTIPOLYGON + + + If you are absolutely sure all your WKT geometries are multipolygons, don't use this function. + It is slower than ST_GeomFromText since it adds an additional validation step. + + + + &sfs_compliant; s3.2.6.2 + &sqlmm_compliant; SQL-MM 3: 9.6.4 + + + + + + Examples + + SELECT ST_MPolyFromText('MULTIPOLYGON(((0 0 1,20 0 1,20 20 1,0 20 1,0 0 1),(5 5 3,5 7 3,7 7 3,7 5 3,5 5 3)))'); +SELECt ST_MPolyFromText('MULTIPOLYGON(((-70.916 42.1002,-70.9468 42.0946,-70.9765 42.0872,-70.9754 42.0875,-70.9749 42.0879,-70.9752 42.0881,-70.9754 42.0891,-70.9758 42.0894,-70.9759 42.0897,-70.9759 42.0899,-70.9754 42.0902,-70.9756 42.0906,-70.9753 42.0907,-70.9753 42.0917,-70.9757 42.0924,-70.9755 42.0928,-70.9755 42.0942,-70.9751 42.0948,-70.9755 42.0953,-70.9751 42.0958,-70.9751 42.0962,-70.9759 42.0983,-70.9767 42.0987,-70.9768 42.0991,-70.9771 42.0997,-70.9771 42.1003,-70.9768 42.1005,-70.977 42.1011,-70.9766 42.1019,-70.9768 42.1026,-70.9769 42.1033,-70.9775 42.1042,-70.9773 42.1043,-70.9776 42.1043,-70.9778 42.1048,-70.9773 42.1058,-70.9774 42.1061,-70.9779 42.1065,-70.9782 42.1078,-70.9788 42.1085,-70.9798 42.1087,-70.9806 42.109,-70.9807 42.1093,-70.9806 42.1099,-70.9809 42.1109,-70.9808 42.1112,-70.9798 42.1116,-70.9792 42.1127,-70.979 42.1129,-70.9787 42.1134,-70.979 42.1139,-70.9791 42.1141,-70.9987 42.1116,-71.0022 42.1273, + -70.9408 42.1513,-70.9315 42.1165,-70.916 42.1002)))',4326); + + + + + + See Also + + , + + + + + + ST_Point + + Returns an ST_Point with the given coordinate values. OGC alias for ST_MakePoint. + + + + + + geometry ST_Point + float x_lon + float y_lat + + + + + + Description + + Returns an ST_Point with the given coordinate values. MM compliant alias for ST_MakePoint that takes just an x and y. + + + &sqlmm_compliant; SQL-MM 3: 6.1.2 + + + + + + Examples + + SELECT ST_SetSRID(ST_Point(-71.1043443253471, 42.3150676015829),4326) + + + + + See Also + + , + + + + + + ST_PointFromText + Makes a point Geometry from WKT with the given SRID. If SRID is + not given, it defaults to unknown. + + + + + geometry ST_PointFromText + text WKT + + + geometry ST_PointFromText + text WKT + integer srid + + + + + + Description + + Constructs a PostGIS ST_Geometry point object from the OGC Well-Known text representation. If SRID is + not give, it defaults to unknown (currently -1). If geometry is not a WKT point representation, returns null. + If completely invalid WKT, then throws an error. + + + + There are 2 variants of ST_PointFromText function, the first takes no SRID and returns a geometry + with no defined spatial reference system. The second takes a spatial reference id as the second argument + and returns an ST_Geometry that includes this srid as part of its meta-data. The srid must be defined + in the spatial_ref_sys table. + + + + If you are absolutely sure all your WKT geometries are points, don't use this function. + It is slower than ST_GeomFromText since it adds an additional validation step. If you are building points from long lat coordinates and care more about performance and accuracy than OGC compliance, use or OGC compliant alias . + + + &sfs_compliant; s3.2.6.2 - option SRID is from the conformance suite. + &sqlmm_compliant; SQL-MM 3: 6.1.8 + + + + Examples + +SELECT ST_PointFromText('POINT(-71.064544 42.28787)'); +SELECT ST_PointFromText('POINT(-71.064544 42.28787)', 4326); + + + + See Also + , , , + + + + + + ST_PointFromWKB + + Makes a geometry from WKB with the given SRID + + + + + + geometry ST_GeomFromWKB + bytea geom + + + + geometry ST_GeomFromWKB + bytea geom + integer srid + + + + + + Description + + The ST_PointFromWKB function, takes a well-known binary + representation of geometry and a Spatial Reference System ID (SRID) + and creates an instance of the appropriate geometry type - in this case, a + POINT geometry. This function plays the role of the Geometry + Factory in SQL. + + If an SRID is not specified, it defaults to -1. NULL is + returned if the input bytea does not represent a + POINT geometry. + + &sfs_compliant; s3.2.7.2 + &sqlmm_compliant; SQL-MM 3: 6.1.9 + &Z_support; + &curve_support; + + + + + Examples + + SELECT + ST_AsText( + ST_PointFromWKB( + ST_AsEWKB('POINT(2 5)'::geometry) + ) + ); + st_astext +------------ + POINT(2 5) +(1 row) + +SELECT + ST_AsText( + ST_PointFromWKB( + ST_AsEWKB('LINESTRING(2 5, 2 6)'::geometry) + ) + ); + st_astext +----------- + +(1 row) + + + + + See Also + + , + + + + + + ST_Polygon + + Returns a polygon built from the specified linestring and SRID. + + + + + + geometry ST_Polygon + geometry aLineString + integer srid + + + + + + Description + + Returns a polygon built from the specified linestring and SRID. + + + + ST_Polygon is similar to first version oST_MakePolygon except it also sets the spatial ref sys (SRID) of the polygon. Will not work with MULTILINESTRINGS + so use LineMerge to merge multilines. Also does not create polygons with holes. Use ST_MakePolygon for that. + + + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 8.3.2 + &Z_support; + + + + + + Examples + + +--a 2d polygon +SELECT ST_Polygon(ST_GeomFromText('LINESTRING(75.15 29.53,77 29,77.6 29.5, 75.15 29.53)'), 4326); + +--result-- +POLYGON((75.15 29.53,77 29,77.6 29.5,75.15 29.53)) +--a 3d polygon +SELECT ST_AsEWKT(ST_Polygon(ST_GeomFromEWKT('LINESTRING(75.15 29.53 1,77 29 1,77.6 29.5 1, 75.15 29.53 1)'), 4326)); + +result +------ +SRID=4326;POLYGON((75.15 29.53 1,77 29 1,77.6 29.5 1,75.15 29.53 1)) + + + + + + See Also + + , , , , , + + + + + + ST_PolygonFromText + + Makes a Geometry from WKT with the given SRID. If SRID is + not give, it defaults to -1. + + + + + + geometry ST_PolygonFromText + text WKT + + + geometry ST_PolygonFromText + text WKT + integer srid + + + + + + Description + + Makes a Geometry from WKT with the given SRID. If SRID is + not give, it defaults to -1. Returns null if WKT is not a polygon. + + + OGC SPEC 3.2.6.2 - option SRID is from the conformance + suite + + If you are absolutely sure all your WKT geometries are polygons, don't use this function. + It is slower than ST_GeomFromText since it adds an additional validation step. + &sfs_compliant; s3.2.6.2 + &sqlmm_compliant; SQL-MM 3: 8.3.6 + + + + Examples + + SELECT ST_PolygonFromText('POLYGON((-71.1776585052917 42.3902909739571,-71.1776820268866 42.3903701743239, +-71.1776063012595 42.3903825660754,-71.1775826583081 42.3903033653531,-71.1776585052917 42.3902909739571))'); +st_polygonfromtext +------------------ +010300000001000000050000006... + + +SELECT ST_PolygonFromText('POINT(1 2)') IS NULL as point_is_notpoly; + +point_is_not_poly +---------- +t + + + + + + See Also + + + + + + + + ST_WKBToSQL + Return a specified ST_Geometry value from Well-Known Binary representation (WKB). This is an alias name for ST_GeomFromWKB that takes no srid + + + + + geometry ST_WKBToSQL + bytea WKB + + + + + Description + &sqlmm_compliant; SQL-MM 3: 5.1.36 + + + See Also + + + + + + + ST_WKTToSQL + Return a specified ST_Geometry value from Well-Known Text representation (WKT). This is an alias name for ST_GeomFromText + + + + + geometry ST_WKTToSQL + text WKT + + + + + Description + &sqlmm_compliant; SQL-MM 3: 5.1.34 + + + See Also + + + + diff --git a/doc/reference_editor.xml b/doc/reference_editor.xml new file mode 100644 index 000000000..ae9941875 --- /dev/null +++ b/doc/reference_editor.xml @@ -0,0 +1,1537 @@ + + + Geometry Editors + + + + ST_AddPoint + Adds a point to a LineString before point <position> + (0-based index). + + + + + geometry ST_AddPoint + geometry linestring + geometry point + + + + + geometry ST_AddPoint + geometry linestring + geometry point + integer position + + + + + + Description + + Adds a point to a LineString before point <position> + (0-based index). Third parameter can be omitted or set to -1 for + appending. + Availability: 1.1.0 + &Z_support; + + + + Examples + + --guarantee all linestrings in a table are closed + --by adding the start point of each linestring to the end of the line string + --only for those that are not closed + UPDATE sometable + SET the_geom = ST_AddPoint(the_geom, ST_StartPoint(the_geom)) + FROM sometable + WHERE ST_IsClosed(the_geom) = false; + + --Adding point to a 3-d line + SELECT ST_AsEWKT(ST_AddPoint(ST_GeomFromEWKT('LINESTRING(0 0 1, 1 1 1)'), ST_MakePoint(1, 2, 3))); + + --result + st_asewkt + ---------- + LINESTRING(0 0 1,1 1 1,1 2 3) + + + + See Also + , + + + + + + ST_Affine + + Applies a 3d affine transformation to the geometry to do things like translate, rotate, scale in one step. + + + + + + geometry ST_Affine + geometry geomA + float a + float b + float c + float d + float e + float f + float g + float h + float i + float xoff + float yoff + float zoff + + + + geometry ST_Affine + geometry geomA + float a + float b + float d + float e> + float xoff + float yoff + + + + + + Description + + Applies a 3d affine transformation to the geometry to do things like translate, rotate, scale in one step. + + Version 1: The + call ST_Affine(geom, a, b, c, d, e, f, g, h, i, xoff, yoff, zoff) + represents the transformation matrix / a b c xoff \ +| d e f yoff | +| g h i zoff | +\ 0 0 0 1 / and the vertices are transformed as + follows: x' = a*x + b*y + c*z + xoff +y' = d*x + e*y + f*z + yoff +z' = g*x + h*y + i*z + zoff All of the translate / scale + functions below are expressed via such an affine + transformation. + Version 2: Applies a 2d affine transformation to the geometry. The + call ST_Affine(geom, a, b, d, e, xoff, yoff) + represents the transformation matrix / a b 0 xoff \ / a b xoff \ +| d e 0 yoff | rsp. | d e yoff | +| 0 0 1 0 | \ 0 0 1 / +\ 0 0 0 1 / and the vertices are transformed as + follows: x' = a*x + b*y + xoff +y' = d*x + e*y + yoff +z' = z This method is a subcase of the 3D method + above. + + Availability: 1.1.2. Name changed from Affine to ST_Affine in 1.2.2 + Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ + + &Z_support; + &curve_support; + + + + + Examples + + +--Rotate a 3d line 180 degrees about the z axis. Note this is long-hand for doing ST_RotateZ(); + SELECT ST_AsEWKT(ST_Affine(the_geom, cos(pi()), -sin(pi()), 0, sin(pi()), cos(pi()), 0, 0, 0, 1, 0, 0, 0)) As using_affine, + ST_AsEWKT(ST_RotateZ(the_geom, pi())) As using_rotatez + FROM (SELECT ST_GeomFromEWKT('LINESTRING(1 2 3, 1 4 3)') As the_geom) As foo; + using_affine | using_rotatez +-----------------------------+----------------------------- + LINESTRING(-1 -2 3,-1 -4 3) | LINESTRING(-1 -2 3,-1 -4 3) +(1 row) + +--Rotate a 3d line 180 degrees in both the x and z axis +SELECT ST_AsEWKT(ST_Affine(the_geom, cos(pi()), -sin(pi()), 0, sin(pi()), cos(pi()), -sin(pi()), 0, sin(pi()), cos(pi()), 0, 0, 0)) + FROM (SELECT ST_GeomFromEWKT('LINESTRING(1 2 3, 1 4 3)') As the_geom) As foo; + st_asewkt +------------------------------- + LINESTRING(-1 -2 -3,-1 -4 -3) +(1 row) + + + + + + + See Also + + , , , + + + + + + ST_Force_2D + + Forces the geometries into a "2-dimensional mode" so that + all output representations will only have the X and Y coordinates. + + + + + + geometry ST_Force_2D + geometry geomA + + + + + + Description + + Forces the geometries into a "2-dimensional mode" so that + all output representations will only have the X and Y coordinates. + This is useful for force OGC-compliant output (since OGC only + specifies 2-D geometries). + + &curve_support; + + + + + Examples + + SELECT ST_AsEWKT(ST_Force_2D(ST_GeomFromEWKT('CIRCULARSTRING(1 1 2, 2 3 2, 4 5 2, 6 7 2, 5 6 2)'))); + st_asewkt +------------------------------------- +CIRCULARSTRING(1 1,2 3,4 5,6 7,5 6) + +SELECT ST_AsEWKT(ST_Force_2D('POLYGON((0 0 2,0 5 2,5 0 2,0 0 2),(1 1 2,3 1 2,1 3 2,1 1 2))')); + + st_asewkt +---------------------------------------------- + POLYGON((0 0,0 5,5 0,0 0),(1 1,3 1,1 3,1 1)) + + + + + + + See Also + + + + + + + + ST_Force_3D + + Forces the geometries into XYZ mode. This is an alias for ST_Force_3DZ. + + + + + + geometry ST_Force_3D + geometry geomA + + + + + + Description + + Forces the geometries into XYZ mode. This is an alias for ST_Force_3DZ. If a geometry has no Z component, then a 0 Z coordinate is tacked on. + + &Z_support; + &curve_support; + + + + + Examples + + + --Nothing happens to an already 3D geometry + SELECT ST_AsEWKT(ST_Force_3D(ST_GeomFromEWKT('CIRCULARSTRING(1 1 2, 2 3 2, 4 5 2, 6 7 2, 5 6 2)'))); + st_asewkt +----------------------------------------------- + CIRCULARSTRING(1 1 2,2 3 2,4 5 2,6 7 2,5 6 2) + + +SELECT ST_AsEWKT(ST_Force_3D('POLYGON((0 0,0 5,5 0,0 0),(1 1,3 1,1 3,1 1))')); + + st_asewkt +-------------------------------------------------------------- + POLYGON((0 0 0,0 5 0,5 0 0,0 0 0),(1 1 0,3 1 0,1 3 0,1 1 0)) + + + + + + See Also + + , , , + + + + + + ST_Force_3DZ + + Forces the geometries into XYZ mode. This is a synonym for ST_Force_3D. + + + + + + geometry ST_Force_3DZ + geometry geomA + + + + + + Description + + Forces the geometries into XYZ mode. This is a synonym for ST_Force_3DZ. If a geometry has no Z component, then a 0 Z coordinate is tacked on. + + &Z_support; + &curve_support; + + + + + Examples + + +--Nothing happens to an already 3D geometry +SELECT ST_AsEWKT(ST_Force_3DZ(ST_GeomFromEWKT('CIRCULARSTRING(1 1 2, 2 3 2, 4 5 2, 6 7 2, 5 6 2)'))); + st_asewkt +----------------------------------------------- + CIRCULARSTRING(1 1 2,2 3 2,4 5 2,6 7 2,5 6 2) + + +SELECT ST_AsEWKT(ST_Force_3DZ('POLYGON((0 0,0 5,5 0,0 0),(1 1,3 1,1 3,1 1))')); + + st_asewkt +-------------------------------------------------------------- + POLYGON((0 0 0,0 5 0,5 0 0,0 0 0),(1 1 0,3 1 0,1 3 0,1 1 0)) + + + + + + See Also + + , , , + + + + + + ST_Force_3DM + + Forces the geometries into XYM mode. + + + + + + geometry ST_Force_3DM + geometry geomA + + + + + + Description + + Forces the geometries into XYM mode. If a geometry has no M component, then a 0 M coordinate is tacked on. If it has a Z component, then Z is removed + + + &curve_support; + + + + + Examples + + +--Nothing happens to an already 3D geometry +SELECT ST_AsEWKT(ST_Force_3DM(ST_GeomFromEWKT('CIRCULARSTRING(1 1 2, 2 3 2, 4 5 2, 6 7 2, 5 6 2)'))); + st_asewkt +------------------------------------------------ + CIRCULARSTRINGM(1 1 0,2 3 0,4 5 0,6 7 0,5 6 0) + + +SELECT ST_AsEWKT(ST_Force_3DM('POLYGON((0 0 1,0 5 1,5 0 1,0 0 1),(1 1 1,3 1 1,1 3 1,1 1 1))')); + + st_asewkt +--------------------------------------------------------------- + POLYGONM((0 0 0,0 5 0,5 0 0,0 0 0),(1 1 0,3 1 0,1 3 0,1 1 0)) + + + + + + + See Also + + , , , , + + + + + + ST_Force_4D + + Forces the geometries into XYZM mode. + + + + + + geometry ST_Force_4D + geometry geomA + + + + + + Description + + Forces the geometries into XYZM mode. 0 is tacked on for missing Z and M dimensions. + + &Z_support; + &curve_support; + + + + + Examples + + +--Nothing happens to an already 3D geometry +SELECT ST_AsEWKT(ST_Force_4D(ST_GeomFromEWKT('CIRCULARSTRING(1 1 2, 2 3 2, 4 5 2, 6 7 2, 5 6 2)'))); + st_asewkt +--------------------------------------------------------- + CIRCULARSTRING(1 1 2 0,2 3 2 0,4 5 2 0,6 7 2 0,5 6 2 0) + + + +SELECT ST_AsEWKT(ST_Force_4D('MULTILINESTRINGM((0 0 1,0 5 2,5 0 3,0 0 4),(1 1 1,3 1 1,1 3 1,1 1 1))')); + + st_asewkt +-------------------------------------------------------------------------------------- + MULTILINESTRING((0 0 0 1,0 5 0 2,5 0 0 3,0 0 0 4),(1 1 0 1,3 1 0 1,1 3 0 1,1 1 0 1)) + + + + + + + See Also + + , , , + + + + + + ST_Force_Collection + + Converts the geometry into a GEOMETRYCOLLECTION. + + + + + + geometry ST_Force_Collection + geometry geomA + + + + + + Description + + Converts the geometry into a GEOMETRYCOLLECTION. This is + useful for simplifying the WKB representation. + + Availability: 1.2.2, prior to 1.3.4 this function will crash with Curves. This is fixed in 1.3.4+ + &Z_support; + &curve_support; + + + + + Examples + + + +SELECT ST_AsEWKT(ST_Force_Collection('POLYGON((0 0 1,0 5 1,5 0 1,0 0 1),(1 1 1,3 1 1,1 3 1,1 1 1))')); + + st_asewkt +---------------------------------------------------------------------------------- + GEOMETRYCOLLECTION(POLYGON((0 0 1,0 5 1,5 0 1,0 0 1),(1 1 1,3 1 1,1 3 1,1 1 1))) + + + SELECT ST_AsText(ST_Force_Collection('CIRCULARSTRING(220227 150406,2220227 150407,220227 150406)')); + st_astext +-------------------------------------------------------------------------------- + GEOMETRYCOLLECTION(CIRCULARSTRING(220227 150406,2220227 150407,220227 150406)) +(1 row) + + + + + + + See Also + + , , , , + + + + + + + ST_ForceRHR + + Forces the orientation of the vertices in a polygon to follow the + Right-Hand-Rule. + + + + + + boolean + ST_ForceRHR + geometry g + + + + + + Description + + Forces the orientation of the vertices in a polygon to follow the + Right-Hand-Rule. In GIS terminology, this means that the area that is bounded by the + polygon is to the right of the boundary. In particular, the exterior ring is + orientated in a clockwise direction and the interior rings in a counter-clockwise + direction. + + &Z_support; + + + + Examples + + SELECT ST_AsEWKT( + ST_ForceRHR( + 'POLYGON((0 0 2, 5 0 2, 0 5 2, 0 0 2),(1 1 2, 1 3 2, 3 1 2, 1 1 2))' + ) +); + st_asewkt +-------------------------------------------------------------- + POLYGON((0 0 2,0 5 2,5 0 2,0 0 2),(1 1 2,3 1 2,1 3 2,1 1 2)) +(1 row) + + + + See Also + + , + , + + + + + + + ST_LineMerge + + Returns a (set of) LineString(s) formed by sewing together + a MULTILINESTRING. + + + + + + geometry ST_LineMerge + geometry amultilinestring + + + + + + Description + + Returns a (set of) LineString(s) formed by sewing together + the constituent line work of a MULTILINESTRING. + Only use with MULTILINESTRING/LINESTRINGs. If you feed a polygon or geometry collection into this function, it + will return an empty GEOMETRYCOLLECTION + + Availability: 1.1.0 + requires GEOS >= 2.1.0 + + + + Examples + + SELECT ST_AsText(ST_LineMerge( +ST_GeomFromText('MULTILINESTRING((-29 -27,-30 -29.7,-36 -31,-45 -33),(-45 -33,-46 -32))') + ) +); +st_astext +-------------------------------------------------------------------------------------------------- +LINESTRING(-29 -27,-30 -29.7,-36 -31,-45 -33,-46 -32) +(1 row) + +--If can't be merged - original MULTILINESTRING is returned +SELECT ST_AsText(ST_LineMerge( +ST_GeomFromText('MULTILINESTRING((-29 -27,-30 -29.7,-36 -31,-45 -33),(-45.2 -33.2,-46 -32))') +) +); +st_astext +---------------- +MULTILINESTRING((-45.2 -33.2,-46 -32),(-29 -27,-30 -29.7,-36 -31,-45 -33)) + + + + See Also + , + + + + + + ST_Multi + + Returns the geometry as a MULTI* geometry. If the geometry + is already a MULTI*, it is returned unchanged. + + + + + + geometry ST_Multi + geometry g1 + + + + + + Description + + Returns the geometry as a MULTI* geometry. If the geometry + is already a MULTI*, it is returned unchanged. + + + + + Examples + + SELECT ST_AsText(ST_Multi(ST_GeomFromText('POLYGON((743238 2967416,743238 2967450, + 743265 2967450,743265.625 2967416,743238 2967416))'))); + st_astext + -------------------------------------------------------------------------------------------------- + MULTIPOLYGON(((743238 2967416,743238 2967450,743265 2967450,743265.625 2967416, + 743238 2967416))) + (1 row) + + + + See Also + + + + + + + ST_RemovePoint + Removes point from a linestring. Offset is 0-based. + + + + + geometry ST_RemovePoint + geometry linestring + integer offset + + + + + + Description + + Removes point from a linestring. Useful for turning a closed ring into an open line string + Availability: 1.1.0 + &Z_support; + + + + Examples + +--guarantee no LINESTRINGS are closed +--by removing the end point. The below assumes the_geom is of type LINESTRING +UPDATE sometable + SET the_geom = ST_RemovePoint(the_geom, ST_NPoints(the_geom) - 1) + FROM sometable + WHERE ST_IsClosed(the_geom) = true; + + + + See Also + , , + + + + + + ST_Reverse + Returns the geometry with vertex order reversed. + + + + + + geometry ST_Reverse + geometry g1 + + + + + + Description + + Can be used on any geometry and reverses the order of the vertexes. + + + + Examples + +SELECT ST_AsText(the_geom) as line, ST_AsText(ST_Reverse(the_geom)) As reverseline +FROM +(SELECT ST_MakeLine(ST_MakePoint(1,2), + ST_MakePoint(1,10)) As the_geom) as foo; +--result + line | reverseline +---------------------+---------------------- +LINESTRING(1 2,1 10) | LINESTRING(1 10,1 2) + + + + + + + ST_Rotate + + This is a synonym for ST_RotateZ + + + + + + geometry ST_Rotate + geometry geomA + float rotZRadians + + + + + + Description + + This is a synonym for ST_RotateZ.. Rotates geometry rotZRadians about the Z-axis. + + Availability: 1.1.2. Name changed from Rotate to ST_Rotate in 1.2.2 + &Z_support; + &curve_support; + + + + + Examples + + + + + + + See Also + + , , , + + + + + + ST_RotateX + + Rotate a geometry rotRadians about the X axis. + + + + + + geometry ST_RotateX + geometry geomA + float rotRadians + + + + + + Description + + Rotate a geometry geomA - rotRadians about the X axis. + + ST_RotateX(geomA, rotRadians) + is short-hand for ST_Affine(geomA, 1, 0, 0, 0, cos(rotRadians), -sin(rotRadians), 0, sin(rotRadians), cos(rotRadians), 0, 0, 0). + + Availability: 1.1.2. Name changed from RotateX to ST_RotateX in 1.2.2 + + &Z_support; + + + + + Examples + + +--Rotate a line 90 degrees along x-axis +SELECT ST_AsEWKT(ST_RotateX(ST_GeomFromEWKT('LINESTRING(1 2 3, 1 1 1)'), pi()/2)); + st_asewkt +--------------------------- + LINESTRING(1 -3 2,1 -1 1) + + + + + + See Also + + , , + + + + + + ST_RotateY + + Rotate a geometry rotRadians about the Y axis. + + + + + + geometry ST_RotateY + geometry geomA + float rotRadians + + + + + + Description + + Rotate a geometry geomA - rotRadians about the y axis. + + ST_RotateY(geomA, rotRadians) + is short-hand for ST_Affine(geomA, cos(rotRadians), 0, sin(rotRadians), 0, 1, 0, -sin(rotRadians), 0, cos(rotRadians), 0, 0, 0). + + Availability: 1.1.2. Name changed from RotateY to ST_RotateY in 1.2.2 + + &Z_support; + + + + + Examples + + +--Rotate a line 90 degrees along y-axis + SELECT ST_AsEWKT(ST_RotateY(ST_GeomFromEWKT('LINESTRING(1 2 3, 1 1 1)'), pi()/2)); + st_asewkt +--------------------------- + LINESTRING(3 2 -1,1 1 -1) + + + + + + See Also + + , , , Rotate around Point, Create Ellipse functions + + + + + + ST_RotateZ + + Rotate a geometry rotRadians about the Z axis. + + + + + + geometry ST_RotateZ + geometry geomA + float rotRadians + + + + + + Description + + Rotate a geometry geomA - rotRadians about the Z axis. + + ST_RotateZ(geomA, rotRadians) + is short-hand for SELECT ST_Affine(geomA, cos(rotRadians), -sin(rotRadians), 0, sin(rotRadians), cos(rotRadians), 0, 0, 0, 1, 0, 0, 0). + + Availability: 1.1.2. Name changed from RotateZ to ST_RotateZ in 1.2.2 + Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ + + &Z_support; + &curve_support; + + + + + Examples + + +--Rotate a line 90 degrees along z-axis +SELECT ST_AsEWKT(ST_RotateZ(ST_GeomFromEWKT('LINESTRING(1 2 3, 1 1 1)'), pi()/2)); + st_asewkt +--------------------------- + LINESTRING(-2 1 3,-1 1 1) + + --Rotate a curved circle around z-axis +SELECT ST_AsEWKT(ST_RotateZ(the_geom, pi()/2)) +FROM (SELECT ST_LineToCurve(ST_Buffer(ST_GeomFromText('POINT(234 567)'), 3)) As the_geom) As foo; + + st_asewkt +---------------------------------------------------------------------------------------------------------------------------- + CURVEPOLYGON(CIRCULARSTRING(-567 237,-564.87867965644 236.12132034356,-564 234,-569.12132034356 231.87867965644,-567 237)) + + + + + + + See Also + + , , , Rotate around Point, Create Ellipse functions + + + + + + ST_Scale + + Scales the geometry to a new size by multiplying the + ordinates with the parameters. Ie: ST_Scale(geom, Xfactor, Yfactor, + Zfactor). + + + + + + + geometry ST_Scale + geometry geomA + float XFactor + float YFactor + float ZFactor + + + + geometry ST_Scale + geometry geomA + float XFactor + float YFactor + + + + + + Description + + Scales the geometry to a new size by multiplying the + ordinates with the parameters. Ie: ST_Scale(geom, Xfactor, Yfactor, + Zfactor). + + ST_Scale(geomA, XFactor, YFactor, ZFactor) + is short-hand for ST_Affine(geomA, XFactor, 0, 0, 0, YFactor, 0, 0, 0, ZFactor, 0, 0, 0). + + Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ + + + Availability: 1.1.0. + &Z_support; + &curve_support; + + + + + Examples + + --Version 1: scale X, Y, Z +SELECT ST_AsEWKT(ST_Scale(ST_GeomFromEWKT('LINESTRING(1 2 3, 1 1 1)'), 0.5, 0.75, 0.8)); + st_asewkt +-------------------------------------- + LINESTRING(0.5 1.5 2.4,0.5 0.75 0.8) + +--Version 2: Scale X Y + SELECT ST_AsEWKT(ST_Scale(ST_GeomFromEWKT('LINESTRING(1 2 3, 1 1 1)'), 0.5, 0.75)); + st_asewkt +---------------------------------- + LINESTRING(0.5 1.5 3,0.5 0.75 1) + + + + + + + + See Also + + , + + + + + + ST_Segmentize + + Return a modified geometry having no segment longer than the + given distance. Distance computation is performed in 2d + only. + + + + + + geometry ST_Segmentize + geometry geomA + float max_length + + + + + + Description + + Returns a modified geometry having no segment longer than the + given distance. Distance computation is performed in 2d + only. + Availability: 1.2.2 + This will only increase segments. It will not lengthen segments shorter than + max length + + + + Examples + + SELECT ST_AsText(ST_Segmentize( +ST_GeomFromText('MULTILINESTRING((-29 -27,-30 -29.7,-36 -31,-45 -33),(-45 -33,-46 -32))') + ,5) +); +st_astext +-------------------------------------------------------------------------------------------------- +MULTILINESTRING((-29 -27,-30 -29.7,-34.886615700134 -30.758766735029,-36 -31, +-40.8809353009198 -32.0846522890933,-45 -33), +(-45 -33,-46 -32)) +(1 row) + +SELECT ST_AsText(ST_Segmentize(ST_GeomFromText('POLYGON((-29 28, -30 40, -29 28))'),10)); +st_astext +----------------------- +POLYGON((-29 28,-29.8304547985374 37.9654575824488,-30 40,-29.1695452014626 30.0345424175512,-29 28)) +(1 row) + + + + + See Also + + + + + + + ST_SetPoint + Replace point N of linestring with given point. Index is + 0-based. + + + + + geometry ST_SetPoint + geometry linestring + integer zerobasedposition + geometry point + + + + + + Description + + Replace point N of linestring with given point. Index is + 0-based. + This is especially useful in triggers when trying to maintain relationship of joints when one vertex moves. + Availability: 1.1.0 + + &Z_support; + + + + Examples + +--Change first point in line string from -1 3 to -1 1 +SELECT ST_AsText(ST_SetPoint('LINESTRING(-1 2,-1 3)', 0, 'POINT(-1 1)')); + st_astext +----------------------- + LINESTRING(-1 1,-1 3) + +---Change last point in a line string (lets play with 3d linestring this time) +SELECT ST_AsEWKT(ST_SetPoint(foo.the_geom, ST_NumPoints(foo.the_geom) - 1, ST_GeomFromEWKT('POINT(-1 1 3)'))) +FROM (SELECT ST_GeomFromEWKT('LINESTRING(-1 2 3,-1 3 4, 5 6 7)') As the_geom) As foo; + st_asewkt +----------------------- +LINESTRING(-1 2 3,-1 3 4,-1 1 3) + + + + See Also + ,, , + + + + + + ST_SetSRID + + Sets the SRID on a geometry to a particular integer + value. + + + + + + geometry ST_SetSRID + + geometry + geom + + integer + srid + + + + + + Description + + Sets the SRID on a geometry to a particular integer value. + Useful in constructing bounding boxes for queries. + + + This function does not transform the geometry is any way - + it simply sets the projection the geometry that it's currently in. + Use if you want to transform the + geometry into a new projection. + + &sfs_compliant; + &curve_support; + + + + See Also + + , , , + + + + + + + ST_SnapToGrid + + Snap all points of the input geometry to the grid defined by + its origin and cell size. Remove consecutive points falling on the + same cell, eventually returning NULL if output points are not + enough to define a geometry of the given type. Collapsed + geometries in a collection are stripped from it. Useful for reducing precision. + + + + + + geometry ST_SnapToGrid + geometry geomA + float originX + float originY + float sizeX + float sizeY + + + + geometry ST_SnapToGrid + geometry geomA + float sizeX + float sizeY + + + + geometry ST_SnapToGrid + geometry geomA + float size + + + + geometry ST_SnapToGrid + geometry geomA + geometry pointOrigin + float sizeX + float sizeY + float sizeZ + float sizeM + + + + + + Description + + Variant 1,2,3: Snap all points of the input geometry to the grid defined by + its origin and cell size. Remove consecutive points falling on the + same cell, eventually returning NULL if output points are not + enough to define a geometry of the given type. Collapsed + geometries in a collection are stripped from it. + + + Variant 4: Introduced 1.1.0 - Snap all points of the input geometry to the grid defined by + its origin (the second argument, must be a point) and cell sizes. + Specify 0 as size for any dimension you don't want to snap to a + grid. + + + The returned geometry might loose its simplicity (see + ). + + + + Before release 1.1.0 this function always returned a 2d + geometry. Starting at 1.1.0 the returned geometry will have same + dimensionality as the input one with higher dimension values + untouched. Use the version taking a second geometry argument to + define all grid dimensions. + + + Availability: 1.0.0RC1 + Availability: 1.1.0 - Z and M support + + &Z_support; + + + + + Examples + + +--Snap your geometries to a precision grid of 10^-3 +UPDATE mytable + SET the_geom = ST_SnapToGrid(the_geom, 0.001); + +SELECT ST_AsText(ST_SnapToGrid( + ST_GeomFromText('LINESTRING(1.1115678 2.123, 4.111111 3.2374897, 4.11112 3.23748667)'), + 0.001) + ); + st_astext +------------------------------------- + LINESTRING(1.112 2.123,4.111 3.237) + --Snap a 4d geometry +SELECT ST_AsEWKT(ST_SnapToGrid( + ST_GeomFromEWKT('LINESTRING(-1.1115678 2.123 2.3456 1.11111, + 4.111111 3.2374897 3.1234 1.1111, -1.11111112 2.123 2.3456 1.1111112)'), + ST_GeomFromEWKT('POINT(1.12 2.22 3.2 4.4444)'), + 0.1, 0.1, 0.1, 0.01) ); + st_asewkt +------------------------------------------------------------------------------ + LINESTRING(-1.08 2.12 2.3 1.1144,4.12 3.22 3.1 1.1144,-1.08 2.12 2.3 1.1144) + + +--With a 4d geometry - the ST_SnapToGrid(geom,size) only touches x and y coords but keeps m and z the same +SELECT ST_AsEWKT(ST_SnapToGrid(ST_GeomFromEWKT('LINESTRING(-1.1115678 2.123 3 2.3456, + 4.111111 3.2374897 3.1234 1.1111)'), + 0.01) ); + st_asewkt +--------------------------------------------------------- + LINESTRING(-1.11 2.12 3 2.3456,4.11 3.24 3.1234 1.1111) + + + + + + + See Also + + , , , , + + + + + + ST_Transform + + Returns a new geometry with its coordinates transformed to + the SRID referenced by the integer parameter. + + + + + + geometry ST_Transform + geometry g1 + integer srid + + + + + + Description + + Returns a new geometry with its coordinates transformed to + spatial reference system referenced by the SRID integer parameter. The destination SRID + must exist in the SPATIAL_REF_SYS table. + ST_Transform is often confused with ST_SetSRID(). ST_Transform actually changes the coordinates + of a geometry from one spatial reference system to another, while ST_SetSRID() simply changes the SRID identifier of + the geometry + + + Requires PostGIS be compiled with Proj support. Use to confirm you have proj support compiled in. + + + + If using more than one transformation, it is useful to have a functional index on the commonly used + transformations to take advantage of index usage. + + + Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ + + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 5.1.6 + &curve_support; + + + + + Examples + Change Mass state plane US feet geometry to WGS 84 long lat + +SELECT ST_AsText(ST_Transform(ST_GeomFromText('POLYGON((743238 2967416,743238 2967450, + 743265 2967450,743265.625 2967416,743238 2967416))',2249),4326)) As wgs_geom; + + wgs_geom +--------------------------- + POLYGON((-71.1776848522251 42.3902896512902,-71.1776843766326 42.3903829478009, +-71.1775844305465 42.3903826677917,-71.1775825927231 42.3902893647987,-71.177684 +8522251 42.3902896512902)); +(1 row) + +--3D Circular String example +SELECT ST_AsEWKT(ST_Transform(ST_GeomFromEWKT('SRID=2249;CIRCULARSTRING(743238 2967416 1,743238 2967450 2,743265 2967450 3,743265.625 2967416 3,743238 2967416 4)'),4326)); + + st_asewkt +-------------------------------------------------------------------------------------- + SRID=4326;CIRCULARSTRING(-71.1776848522251 42.3902896512902 1,-71.1776843766326 42.3903829478009 2, + -71.1775844305465 42.3903826677917 3, + -71.1775825927231 42.3902893647987 3,-71.1776848522251 42.3902896512902 4) + + + Example of creating a partial functional index. For tables where you are not sure all the geometries + will be filled in, its best to use a partial index that leaves out null geometries which will both conserve space and make your index smaller and more efficient. + +CREATE INDEX idx_the_geom_26986_parcels + ON parcels + USING gist + (ST_Transform(the_geom, 26986)) + WHERE the_geom IS NOT NULL; + + + + + Configuring transformation behaviour + Sometimes coordinate transformation involving a grid-shift can fail, for example if PROJ.4 has not been built with grid-shift files or the coordinate does not lie within the range for which the grid shift is defined. By default, PostGIS will throw an error if a grid shift file is not present, but this behaviour can be configured on a per-SRID basis by altering the proj4text value within the spatial_ref_sys table. + For example, the proj4text parameter +datum=NAD87 is a shorthand form for the following +nadgrids parameter: + +nadgrids=@conus,@alaska,@ntv2_0.gsb,@ntv1_can.dat + The @ prefix means no error is reported if the files are not present, but if the end of the list is reached with no file having been appropriate (ie. found and overlapping) then an error is issued. + If, conversely, you wanted to ensure that at least the standard files were present, but that if all files were scanned without a hit a null transformation is applied you could use: + +nadgrids=@conus,@alaska,@ntv2_0.gsb,@ntv1_can.dat,null + The null grid shift file is a valid grid shift file covering the whole world and applying no shift. So for a complete example, if you wanted to alter PostGIS so that transformations to SRID 4267 that didn't lie within the correct range did not throw an ERROR, you would use the following: + UPDATE spatial_ref_sys SET proj4text = '+proj=longlat +ellps=clrk66 +nadgrids=@conus,@alaska,@ntv2_0.gsb,@ntv1_can.dat,null +no_defs' WHERE srid = 4267; + + + + + See Also + + , , , + + + + + + ST_Translate + + Translates the geometry to a new location using the numeric + parameters as offsets. Ie: ST_Translate(geom, X, Y) or ST_Translate(geom, X, Y,Z). + + + + + + geometry ST_Translate + geometry g1 + float deltax + float deltay + + + geometry ST_Translate + geometry g1 + float deltax + float deltay + float deltaz + + + + + + Description + + Returns a new geometry whose coordinates are translated delta x,delta y,delta z units. Units are + based on the units defined in spatial reference (SRID) for this geometry. + + Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ + + Availability: 1.2.2 + &Z_support; + &curve_support; + + + + Examples + Move a point 1 degree longitude + + SELECT ST_AsText(ST_Translate(ST_GeomFromText('POINT(-71.01 42.37)',4326),1,0)) As wgs_transgeomtxt; + + wgs_transgeomtxt + --------------------- + POINT(-70.01 42.37) + + Move a linestring 1 degree longitude and 1/2 degree latitude + SELECT ST_AsText(ST_Translate(ST_GeomFromText('LINESTRING(-71.01 42.37,-71.11 42.38)',4326),1,0.5)) As wgs_transgeomtxt; + wgs_transgeomtxt + --------------------------------------- + LINESTRING(-70.01 42.87,-70.11 42.88) + + Move a 3d point + SELECT ST_AsEWKT(ST_Translate(CAST('POINT(0 0 0)' As geometry), 5, 12,3)); + st_asewkt + --------- + POINT(5 12 3) + + Move a curve and a point +SELECT ST_AsText(ST_Translate(ST_Collect('CURVEPOLYGON(CIRCULARSTRING(4 3,3.12 0.878,1 0,-1.121 5.1213,6 7, 8 9,4 3))','POINT(1 3)'),1,2)); + st_astext +------------------------------------------------------------------------------------------------------------ + GEOMETRYCOLLECTION(CURVEPOLYGON(CIRCULARSTRING(5 5,4.12 2.878,2 2,-0.121 7.1213,7 9,9 11,5 5)),POINT(2 5)) + + + + + + See Also + , , + + + + + + ST_TransScale + + Translates the geometry using the deltaX and deltaY args, + then scales it using the XFactor, YFactor args, working in 2D only. + + + + + + + geometry ST_TransScale + geometry geomA + float deltaX + float deltaY + float XFactor + float YFactor + + + + + + Description + + Translates the geometry using the deltaX and deltaY args, + then scales it using the XFactor, YFactor args, working in 2D only. + + ST_TransScale(geomA, deltaX, deltaY, XFactor, YFactor) + is short-hand for ST_Affine(geomA, XFactor, 0, 0, 0, YFactor, 0, + 0, 0, 1, deltaX*XFactor, deltaY*YFactor, 0). + + Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ + + + Availability: 1.1.0. + &Z_support; + &curve_support; + + + + + Examples + + SELECT ST_AsEWKT(ST_TransScale(ST_GeomFromEWKT('LINESTRING(1 2 3, 1 1 1)'), 0.5, 1, 1, 2)); + st_asewkt +----------------------------- + LINESTRING(1.5 6 3,1.5 4 1) + + +--Buffer a point to get an approximation of a circle, convert to curve and then translate 1,2 and scale it 3,4 + SELECT ST_AsText(ST_Transscale(ST_LineToCurve(ST_Buffer('POINT(234 567)', 3)),1,2,3,4)); + st_astext +------------------------------------------------------------------------------------------------------------------------------ + CURVEPOLYGON(CIRCULARSTRING(714 2276,711.363961030679 2267.51471862576,705 2264,698.636038969321 2284.48528137424,714 2276)) + + + + + + + See Also + + , + + + + + + diff --git a/doc/reference_exception.xml b/doc/reference_exception.xml new file mode 100644 index 000000000..31f07d4e7 --- /dev/null +++ b/doc/reference_exception.xml @@ -0,0 +1,157 @@ + + + Exceptional Functions + These functions are rarely used functions that should only be used if your data is corrupted in someway. They are used for troubleshooting corruption + and also fixing things that should under normal circumstances, never happen. + + + + PostGIS_AddBBox + + Add bounding box to the geometry. + + + + + + geometry PostGIS_AddBBox + geometry geomA + + + + + + Description + + Add bounding box to the geometry. This would make bounding + box based queries faster, but will increase the size of the + geometry. + + + Bounding boxes are automatically added to geometries so in general this is not needed + unless the generated bounding box somehow becomes corrupted or you have an old install that is lacking bounding boxes. Then you need to drop the old and readd. + + + &curve_support; + + + + + Examples + + UPDATE sometable + SET the_geom = ST_AddBBox(the_geom) + WHERE ST_HasBBox(the_geom) = false; + + + + + See Also + + , + + + + + + PostGIS_DropBBox + + Drop the bounding box cache from the geometry. + + + + + + geometry PostGIS_DropBBox + geometry geomA + + + + + + Description + + Drop the bounding box cache from the geometry. This reduces + geometry size, but makes bounding-box based queries slower. It is also used to drop a corrupt bounding box. A tale-tell sign of a corrupt cached bounding box + is when your ST_Intersects and other relation queries leave out geometries that rightfully should return true. + + + Bounding boxes are automatically added to geometries and improve speed of queries so in general this is not needed + unless the generated bounding box somehow becomes corrupted or you have an old install that is lacking bounding boxes. + Then you need to drop the old and readd. This kind of corruption has been observed in 8.3-8.3.6 series whereby cached bboxes were not always recalculated when a geometry changed and upgrading to a newer version without a dump reload will not + correct already corrupted boxes. So one can manually correct using below and readd the bbox or do a dump reload. + + + &curve_support; + + + + + Examples + + --This example drops bounding boxes where the cached box is not correct + --The force to ST_AsBinary before applying Box2D forces a recalculation of the box, and Box2D applied to the table geometry always + -- returns the cached bounding box. + UPDATE sometable + SET the_geom = PostGIS_DropBBox(the_geom) + WHERE Not (Box2D(ST_AsBinary(the_geom)) = Box2D(the_geom)); + + UPDATE sometable + SET the_geom = PostGIS_AddBBox(the_geom) + WHERE Not PostGIS_HasBBOX(the_geom); + + + + + + + + See Also + + , , + + + + + + + PostGIS_HasBBox + + Returns TRUE if the bbox of this geometry is cached, FALSE otherwise. + + + + + + boolean PostGIS_HasBBox + geometry geomA + + + + + + Description + + Returns TRUE if the bbox of this geometry is cached, FALSE + otherwise. Use and to control caching. + + &curve_support; + + + + + Examples + + SELECT the_geom +FROM sometable WHERE PostGIS_HasBBox(the_geom) = false; + + + + + See Also + + , + + + + diff --git a/doc/reference_lrs.xml b/doc/reference_lrs.xml new file mode 100644 index 000000000..afa328e6b --- /dev/null +++ b/doc/reference_lrs.xml @@ -0,0 +1,480 @@ + + + Linear Referencing + + + ST_Line_Interpolate_Point + + Returns a point interpolated along a line. Second argument is a float8 between 0 and 1 + representing fraction of total length of linestring the point has to be located. + + + + + + geometry ST_Line_Interpolate_Point + geometry a_linestring + float a_fraction + + + + + + Description + + Returns a point interpolated along a line. First argument + must be a LINESTRING. Second argument is a float8 between 0 and 1 + representing fraction of total linestring length the point has to be located. + + See for + computing the line location nearest to a Point. + + + Since release 1.1.1 this function also interpolates M and + Z values (when present), while prior releases set them to + 0.0. + + Availability: 0.8.2, Z and M supported added in 1.1.1 + &Z_support; + + + + + Examples + + + + + + A linestring with the interpolated point at 20% position (0.20) + + + --Return point 20% along 2d line +SELECT ST_AsEWKT(ST_Line_Interpolate_Point(the_line, 0.20)) + FROM (SELECT ST_GeomFromEWKT('LINESTRING(25 50, 100 125, 150 190)') as the_line) As foo; + st_asewkt +---------------- + POINT(51.5974135047432 76.5974135047432) + + + +--Return point mid-way of 3d line +SELECT ST_AsEWKT(ST_Line_Interpolate_Point(the_line, 0.5)) + FROM (SELECT ST_GeomFromEWKT('LINESTRING(1 2 3, 4 5 6, 6 7 8)') as the_line) As foo; + + st_asewkt +-------------------- + POINT(3.5 4.5 5.5) + + +--find closest point on a line to a point or other geometry + SELECT ST_AsText(ST_Line_Interpolate_Point(foo.the_line, ST_Line_Locate_Point(foo.the_line, ST_GeomFromText('POINT(4 3)')))) +FROM (SELECT ST_GeomFromText('LINESTRING(1 2, 4 5, 6 7)') As the_line) As foo; + st_astext +---------------- + POINT(3 4) + + + + + + + See Also + + ,,, + + + + + + ST_Line_Locate_Point + + Returns a float between 0 and 1 representing the location of + the closest point on LineString to the given Point, as a fraction + of total 2d line length. + + + + + + float ST_Line_Locate_Point + geometry a_linestring + geometry a_point + + + + + + Description + + Returns a float between 0 and 1 representing the location of + the closest point on LineString to the given Point, as a fraction + of total 2d line length. + + You can use the returned location to extract a Point () or + a substring (). + + This is useful for approximating numbers of addresses + + Availability: 1.1.0 + + + + + + Examples + + +--Rough approximation of finding the street number of a point along the street +--Note the whole foo thing is just to generate dummy data that looks +--like house centroids and street +--We use ST_DWithin to exclude +--houses too far away from the street to be considered on the street +SELECT ST_AsText(house_loc) As as_text_house_loc, + startstreet_num + + CAST( (endstreet_num - startstreet_num) + * ST_Line_Locate_Point(street_line, house_loc) As integer) As street_num +FROM +(SELECT ST_GeomFromText('LINESTRING(1 2, 3 4)') As street_line, + ST_MakePoint(x*1.01,y*1.03) As house_loc, 10 As startstreet_num, + 20 As endstreet_num +FROM generate_series(1,3) x CROSS JOIN generate_series(2,4) As y) +As foo +WHERE ST_DWithin(street_line, house_loc, 0.2); + + as_text_house_loc | street_num +-------------------+------------ + POINT(1.01 2.06) | 10 + POINT(2.02 3.09) | 15 + POINT(3.03 4.12) | 20 + + --find closest point on a line to a point or other geometry + SELECT ST_AsText(ST_Line_Interpolate_Point(foo.the_line, ST_Line_Locate_Point(foo.the_line, ST_GeomFromText('POINT(4 3)')))) +FROM (SELECT ST_GeomFromText('LINESTRING(1 2, 4 5, 6 7)') As the_line) As foo; + st_astext +---------------- + POINT(3 4) + + + + + + + See Also + + , , , + + + + + + ST_Line_Substring + + Return a linestring being a substring of the input one + starting and ending at the given fractions of total 2d length. + Second and third arguments are float8 values between 0 and + 1. + + + + + + geometry ST_Line_Substring + geometry a_linestring + float startfraction + float endfraction + + + + + + Description + + Return a linestring being a substring of the input one + starting and ending at the given fractions of total 2d length. + Second and third arguments are float8 values between 0 and + 1. This only works with LINESTRINGs. + To use with contiguous MULTILINESTRINGs use in conjunction with ST_LineMerge. + + If 'start' and 'end' have the same value this is equivalent + to . + + See for + computing the line location nearest to a Point. + + + Since release 1.1.1 this function also interpolates M and + Z values (when present), while prior releases set them to + unspecified values. + + + Availability: 1.1.0 , Z and M supported added in 1.1.1 + &Z_support; + + + + Examples + + + + + + A linestring seen with 1/3 midrange overlaid (0.333, 0.666) + + + +--Return the approximate 1/3 mid-range part of a linestring +SELECT ST_AsText(ST_Line_SubString(ST_GeomFromText('LINESTRING(25 50, 100 125, 150 190)'), 0.333, 0.666)); + + st_astext +------------------------------------------------------------------------------------------------ +LINESTRING(69.2846934853974 94.2846934853974,100 125,111.700356260683 140.210463138888) + +--The below example simulates a while loop in +--SQL using PostgreSQL generate_series() to cut all +--linestrings in a table to 100 unit segments +-- of which no segment is longer than 100 units +-- units are measured in the SRID units of measurement +-- It also assumes all geometries are LINESTRING or contiguous MULTILINESTRING +--and no geometry is longer than 100 units*10000 +--for better performance you can reduce the 10000 +--to match max number of segments you expect + +SELECT field1, field2, ST_Line_Substring(the_geom, 100.00*n/length, + CASE + WHEN 100.00*(n+1) < length THEN 100.00*(n+1)/length + ELSE 1 + END) As the_geom +FROM + (SELECT sometable.field1, sometable.field2, + ST_LineMerge(sometable.the_geom) AS the_geom, + ST_Length(sometable.the_geom) As length + FROM sometable + ) AS t +CROSS JOIN generate_series(0,10000) AS n +WHERE n*100.00/length < 1; + + + + + + See Also + + , , + + + + + + ST_Locate_Along_Measure + + Return a derived geometry collection value with elements + that match the specified measure. Polygonal elements are not + supported. + + + + + + geometry ST_Locate_Along_Measure + geometry ageom_with_measure + float a_measure + + + + + + Description + + Return a derived geometry collection value with elements + that match the specified measure. Polygonal elements are not + supported. + + Semantic is specified by: ISO/IEC CD 13249-3:200x(E) - Text + for Continuation CD Editing Meeting + + Availability: 1.1.0 + Use this function only for geometries with an M component + + &M_support; + + + + + Examples + SELECT ST_AsEWKT(the_geom) + FROM + (SELECT ST_Locate_Along_Measure( + ST_GeomFromEWKT('MULTILINESTRINGM((1 2 3, 3 4 2, 9 4 3), + (1 2 3, 5 4 5))'),3) As the_geom) As foo; + + st_asewkt +----------------------------------------------------------- + GEOMETRYCOLLECTIONM(MULTIPOINT(1 2 3,9 4 3),POINT(1 2 3)) + +--Geometry collections are difficult animals so dump them +--to make them more digestable +SELECT ST_AsEWKT((ST_Dump(the_geom)).geom) + FROM + (SELECT ST_Locate_Along_Measure( + ST_GeomFromEWKT('MULTILINESTRINGM((1 2 3, 3 4 2, 9 4 3), + (1 2 3, 5 4 5))'),3) As the_geom) As foo; + + st_asewkt +--------------- + POINTM(1 2 3) + POINTM(9 4 3) + POINTM(1 2 3) + + + + + + See Also + + , + + + + + + ST_Locate_Between_Measures + + Return a derived geometry collection value with elements + that match the specified range of measures inclusively. Polygonal + elements are not supported. + + + + + + geometry ST_Locate_Between_Measures + geometry geomA + float measure_start + float measure_end + + + + + + + Description + + Return a derived geometry collection value with elements + that match the specified range of measures inclusively. Polygonal + elements are not supported. + + Semantic is specified by: ISO/IEC CD 13249-3:200x(E) - Text + for Continuation CD Editing Meeting + + Availability: 1.1.0 + + &M_support; + + + + Examples + + SELECT ST_AsEWKT(the_geom) + FROM + (SELECT ST_Locate_Between_Measures( + ST_GeomFromEWKT('MULTILINESTRINGM((1 2 3, 3 4 2, 9 4 3), + (1 2 3, 5 4 5))'),1.5, 3) As the_geom) As foo; + + st_asewkt +----------------------------------------------------------------- + GEOMETRYCOLLECTIONM(LINESTRING(1 2 3,3 4 2,9 4 3),POINT(1 2 3)) + +--Geometry collections are difficult animals so dump them +--to make them more digestable +SELECT ST_AsEWKT((ST_Dump(the_geom)).geom) + FROM + (SELECT ST_Locate_Between_Measures( + ST_GeomFromEWKT('MULTILINESTRINGM((1 2 3, 3 4 2, 9 4 3), + (1 2 3, 5 4 5))'),1.5, 3) As the_geom) As foo; + + st_asewkt +-------------------------------- + LINESTRINGM(1 2 3,3 4 2,9 4 3) + POINTM(1 2 3) + + + + + See Also + + , + + + + + + ST_LocateBetweenElevations + + Return a derived geometry (collection) value with elements + that intersect the specified range of elevations inclusively. Only 3D, 4D LINESTRINGS and MULTILINESTRINGS + are supported. + + + + + + geometry ST_LocateBetweenElevations + geometry geom_mline + float elevation_start + float elevation_end + + + + + + + Description + + Return a derived geometry (collection) value with elements + that intersect the specified range of elevations inclusively. Only 3D, 3DM LINESTRINGS and MULTILINESTRINGS + are supported. + + Availability: 1.4.0 + + &Z_support; + + + + Examples + + SELECT ST_AsEWKT(ST_LocateBetweenElevations( + ST_GeomFromEWKT('LINESTRING(1 2 3, 4 5 6)'),2,4)) As ewelev; + ewelev +---------------------------------------------------------------- + MULTILINESTRING((1 2 3,2 3 4)) + +SELECT ST_AsEWKT(ST_LocateBetweenElevations( + ST_GeomFromEWKT('LINESTRING(1 2 6, 4 5 -1, 7 8 9)'),6,9)) As ewelev; + + ewelev +---------------------------------------------------------------- +GEOMETRYCOLLECTION(POINT(1 2 6),LINESTRING(6.1 7.1 6,7 8 9)) + +--Geometry collections are difficult animals so dump them +--to make them more digestable +SELECT ST_AsEWKT((ST_Dump(the_geom)).geom) + FROM + (SELECT ST_LocateBetweenElevations( + ST_GeomFromEWKT('LINESTRING(1 2 6, 4 5 -1, 7 8 9)'),6,9) As the_geom) As foo; + + st_asewkt +-------------------------------- +POINT(1 2 6) +LINESTRING(6.1 7.1 6,7 8 9) + + + + + + See Also + + + + + diff --git a/doc/reference_management.xml b/doc/reference_management.xml new file mode 100644 index 000000000..c5a1b2c5f --- /dev/null +++ b/doc/reference_management.xml @@ -0,0 +1,950 @@ + + + Management Functions + + + + AddGeometryColumn + + Adds a geometry column to an existing table of + attributes. + + + + + + text AddGeometryColumn + + varchar + table_name + + varchar + column_name + + integer + srid + + varchar + type + + integer + dimension + + + + text AddGeometryColumn + + varchar + schema_name + + varchar + table_name + + varchar + column_name + + integer + srid + + varchar + type + + integer + dimension + + + + text AddGeometryColumn + + varchar + catalog_name + + varchar + schema_name + + varchar + table_name + + varchar + column_name + + integer + srid + + varchar + type + + integer + dimension + + + + + + Description + + Adds a geometry column to an existing table of attributes. The + schema_name is the name of the table schema (unused + for pre-schema PostgreSQL installations). The srid + must be an integer value reference to an entry in the SPATIAL_REF_SYS + table. The type must be an uppercase string + corresponding to the geometry type, eg, 'POLYGON' or + 'MULTILINESTRING'. An error is thrown if the schemaname doesn't exist + (or not visible in the current search_path) or the specified SRID, + geometry type, or dimension is invalid. + + + Views and derivatively created spatial tables will need to be registered in geometry_columns manually, + since AddGeometryColumn also adds a spatial column which is not needed when you already have a spatial column. Refer to . + + + &sfs_compliant; + &Z_support; + &curve_support; + + + + Examples + + +-- Create a new simple PostgreSQL table +postgis=# CREATE TABLE my_schema.my_spatial_table (id serial); + +-- Describing the table shows a simple table with a single "id" column. +postgis=# \d my_schema.my_spatial_table + Table "my_schema.my_spatial_table" + Column | Type | Modifiers +--------+---------+------------------------------------------------------------------------- + id | integer | not null default nextval('my_schema.my_spatial_table_id_seq'::regclass) + +-- Add a spatial column to the table +postgis=# SELECT AddGeometryColumn ('my_schema','my_spatial_table','the_geom',4326,'POINT',2); + +--Add a curvepolygon +SELECT AddGeometryColumn ('my_schema','my_spatial_table','the_geomcp',4326,'CURVEPOLYGON',2); + +-- Describe the table again reveals the addition of a new "the_geom" column. +postgis=# \d my_schema.my_spatial_table + Column | Type | Modifiers + +------------+----------+------------------------------------------------------------------------- + id | integer | not null default nextval('my_schema.my_spatial_table_id_seq'::regclass) + the_geom | geometry | + the_geomcp | geometry | +Check constraints: + "enforce_dims_the_geom" CHECK (ndims(the_geom) = 2) + "enforce_dims_the_geomcp" CHECK (ndims(the_geomcp) = 2) + "enforce_geotype_the_geom" CHECK (geometrytype(the_geom) = 'POINT'::text OR +the_geom IS NULL) + "enforce_geotype_the_geomcp" CHECK (geometrytype(the_geomcp) = 'CURVEPOLYGON +'::text OR the_geomcp IS NULL) + "enforce_srid_the_geom" CHECK (srid(the_geom) = 4326) + "enforce_srid_the_geomcp" CHECK (srid(the_geomcp) = 4326) + + + + See Also + + , , + + + + + + DropGeometryColumn + + Removes a geometry column from a spatial + table. + + + + + + text DropGeometryColumn + + varchar + table_name + + varchar + column_name + + + + text DropGeometryColumn + + varchar + schema_name + + varchar + table_name + + varchar + column_name + + + + text DropGeometryColumn + + varchar + catalog_name + + varchar + schema_name + + varchar + table_name + + varchar + column_name + + + + + + Description + + Removes a geometry column from a spatial table. Note that + schema_name will need to match the f_table_schema field of the table's + row in the geometry_columns table. + + &sfs_compliant; + &Z_support; + &curve_support; + + + Examples + + + SELECT DropGeometryColumn ('my_schema','my_spatial_table','the_geomcp'); + ----RESULT output --- + my_schema.my_spatial_table.the_geomcp effectively removed. + + + + See Also + + , + + + + + + DropGeometryTable + + Drops a table and all its references in + geometry_columns. + + + + + + boolean DropGeometryTable + + varchar + table_name + + + + boolean DropGeometryTable + + varchar + schema_name + + varchar + table_name + + + + boolean DropGeometryTable + varchar + catalog_name + varchar + schema_name + varchar + table_name + + + + + + Description + + Drops a table and all its references in geometry_columns. Note: + uses current_schema() on schema-aware pgsql installations if schema is + not provided. + + + + Examples + + + SELECT DropGeometryTable ('my_schema','my_spatial_table'); + ----RESULT output --- + my_schema.my_spatial_table dropped. + + + + See Also + + , + + + + + + + PostGIS_Full_Version + + Reports full postgis version and build configuration + infos. + + + + + + text PostGIS_Full_Version + + + + + + + + Description + + Reports full postgis version and build configuration + infos. + + + + Examples + + SELECT PostGIS_Full_Version(); + postgis_full_version +---------------------------------------------------------------------------------- + POSTGIS="1.3.3" GEOS="3.1.0-CAPI-1.5.0" PROJ="Rel. 4.4.9, 29 Oct 2004" USE_STATS +(1 row) + + + + See Also + + , , , + + + + + + PostGIS_GEOS_Version + + Returns the version number of the GEOS + library. + + + + + + text PostGIS_GEOS_Version + + + + + + + + Description + + Returns the version number of the GEOS library, or + NULL if GEOS support is not enabled. + + + + Examples + + SELECT PostGIS_GEOS_Version(); + postgis_geos_version +---------------------- + 3.1.0-CAPI-1.5.0 +(1 row) + + + + See Also + + , , , + + + + + + PostGIS_Lib_Build_Date + + Returns build date of the PostGIS library. + + + + + + text PostGIS_Lib_Build_Date + + + + + + + + Description + + Returns build date of the PostGIS library. + + + + Examples + + SELECT PostGIS_Lib_Build_Date(); + postgis_lib_build_date +------------------------ + 2008-06-21 17:53:21 +(1 row) + + + + + + PostGIS_Lib_Version + + Returns the version number of the PostGIS + library. + + + + + + text PostGIS_Lib_Version + + + + + + + + Description + + Returns the version number of the PostGIS library. + + + + Examples + + SELECT PostGIS_Lib_Version(); + postgis_lib_version +--------------------- + 1.3.3 +(1 row) + + + + See Also + + , , , + + + + + + PostGIS_PROJ_Version + + Returns the version number of the PROJ4 + library. + + + + + + text PostGIS_PROJ_Version + + + + + + + + Description + + Returns the version number of the PROJ4 library, or + NULL if PROJ4 support is not enabled. + + + + Examples + + SELECT PostGIS_PROJ_Version(); + postgis_proj_version +------------------------- + Rel. 4.4.9, 29 Oct 2004 +(1 row) + + + + See Also + + , , , + + + + + + PostGIS_Scripts_Build_Date + + Returns build date of the PostGIS scripts. + + + + + + text PostGIS_Scripts_Build_Date + + + + + + + + Description + + Returns build date of the PostGIS scripts. + + Availability: 1.0.0RC1 + + + + Examples + + SELECT PostGIS_Scripts_Build_Date(); + postgis_scripts_build_date +------------------------- + 2007-08-18 09:09:26 +(1 row) + + + + See Also + + , , , + + + + + + PostGIS_Scripts_Installed + + Returns version of the postgis scripts installed in this + database. + + + + + + text PostGIS_Scripts_Installed + + + + + + + + Description + + Returns version of the postgis scripts installed in this + database. + + + If the output of this function doesn't match the output of + + you probably missed to properly upgrade an existing database. + See the Upgrading section for + more info. + + + Availability: 0.9.0 + + + + Examples + + SELECT PostGIS_Scripts_Installed(); + postgis_scripts_installed +------------------------- + 1.5.0SVN +(1 row) + + + + See Also + + , , + + + + + + PostGIS_Scripts_Released + + Returns the version number of the postgis.sql script + released with the installed postgis lib. + + + + + + text PostGIS_Scripts_Released + + + + + + + + Description + + Returns the version number of the postgis.sql script + released with the installed postgis lib. + + + Starting with version 1.1.0 this function returns the same + value of . Kept + for backward compatibility. + + + Availability: 0.9.0 + + + + Examples + + SELECT PostGIS_Scripts_Released(); + postgis_scripts_released +------------------------- + 1.3.4SVN +(1 row) + + + + See Also + + , , + + + + + + PostGIS_Uses_Stats + + Returns TRUE if STATS usage has been + enabled. + + + + + + text PostGIS_Uses_Stats + + + + + + + + Description + + Returns TRUE if STATS usage has been enabled, + FALSE otherwise. + + + + Examples + + SELECT PostGIS_Uses_Stats(); + postgis_uses_stats +-------------------- + t +(1 row) + + + + See Also + + + + + + + + PostGIS_Version + + Returns PostGIS version number and compile-time + options. + + + + + + text PostGIS_Version + + + + + + + + Description + + Returns PostGIS version number and compile-time options. + + + + Examples + + SELECT PostGIS_Version(); + postgis_version +--------------------------------------- + 1.3 USE_GEOS=1 USE_PROJ=1 USE_STATS=1 +(1 row) + + + + See Also + + , ,, + + + + + + Populate_Geometry_Columns + + Ensures geometry columns have appropriate spatial constraints + and exist in the geometry_columns table. + + + + + + text Populate_Geometry_Columns + + + + + + int Populate_Geometry_Columns + + oid relation_oid + + + + + + Description + + Ensures geometry columns have appropriate spatial constraints and + exist in the geometry_columns table. In particular, + this means that every geometry column belonging to a table has at least + three constraints: + + + + enforce_dims_the_geom - ensures every + geometry has the same dimension (see ) + + + + enforce_geotype_the_geom - ensures every + geometry is of the same type (see ) + + + + enforce_srid_the_geom - ensures every + geometry is in the same projection (see ) + + + + If a table oid is provided, this function + tries to determine the srid, dimension, and geometry type of all + geometry columns in the table, adding contraints as necessary. If + successful, an appropriate row is inserted into the geometry_columns + table, otherwise, the exception is caught and an error notice is raised + describing the problem. + + If the oid of a view is provided, as with a + table oid, this function tries to determine the srid, dimension, and + type of all the geometries in the view, inserting appropriate entries + into the geometry_columns table, but nothing is done + to enforce contraints. + + The parameterless variant is a simple wrapper for the parameterized + variant that first truncates and repopulates the geometry_columns table + for every spatial table and view in the database, adding spatial + contraints to tables where appropriate. It returns a summary of the + number of geometry columns detected in the database and the number that + were inserted into the geometry_columns table. The + parameterized version simply returns the number of rows inserted into + the geometry_columns table. + Availability: 1.4.0 + + + + Examples + + SELECT Populate_Geometry_Columns('public.myspatial_table'::regclass); + + + + See Also + + + + + + + + Probe_Geometry_Columns + + Scans all tables with PostGIS geometry constraints and adds them to the geometry_columns + table if they are not there. + + + + + + text Probe_Geometry_Columns + + + + + + + Description + + Scans all tables with PostGIS geometry constraints and adds them to the geometry_columns + table if they are not there. Also give stats on number of inserts and already present or possibly obsolete. + This will usually only pick up records added by AddGeometryColumn() function. It will not scan views so views + will need to be manually added to geometry_columns table. + + + + Examples + + SELECT Probe_Geometry_Columns(); + probe_geometry_columns +--------------------------------------- +probed:6 inserted:0 conflicts:6 stale:0 +(1 row) + + + + See Also + + + + + + + + + UpdateGeometrySRID + + Updates the SRID of all features in a geometry + column, geometry_columns metadata and srid table constraint + + + + + + text UpdateGeometrySRID + + varchar + table_name + + varchar + column_name + + integer + srid + + + + text UpdateGeometrySRID + + varchar + schema_name + + varchar + table_name + + varchar + column_name + + integer + srid + + + + text UpdateGeometrySRID + + varchar + catalog_name + + varchar + schema_name + + varchar + table_name + + varchar + column_name + + integer + srid + + + + + + Description + + Updates the SRID of all features in a geometry column, updating + constraints and reference in geometry_columns. Note: uses + current_schema() on schema-aware pgsql installations if schema is not + provided. + &Z_support; + &curve_support; + + + + See Also + + + + + diff --git a/doc/reference_measure.xml b/doc/reference_measure.xml new file mode 100644 index 000000000..1e27045c4 --- /dev/null +++ b/doc/reference_measure.xml @@ -0,0 +1,2912 @@ + + + Spatial Relationships and Measurements + + + ST_Area + + Returns the area of the surface if it is a polygon or + multi-polygon. For "geometry" type area is in SRID units. For "geography" area is in square meters. + + + + + float ST_Area + geometry g1 + + + + float ST_Area + geography g1 + + + + float ST_Area + geography g1 + boolean use_spheroid + + + + + Description + + Returns the area of the geometry if it is a polygon or + multi-polygon. Return the area measurement of an ST_Surface or + ST_MultiSurface value. For geometry Area is in the units of the srid. For geography area is in square meters and defaults to measuring about the spheroid of the geography (currently only WGS84). + To measure around the faster but less accurate sphere -- ST_Area(geog,false). + + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 8.1.2, 9.5.3 + + + + Examples + Return area in square feet for a plot of Massachusetts land and multiply by conversion to get square meters. + Note this is in square feet because 2249 is + Mass State Plane Feet + +SELECT ST_Area(the_geom) As sqft, ST_Area(the_geom)*POWER(0.3048,2) As sqm + FROM (SELECT + ST_GeomFromText('POLYGON((743238 2967416,743238 2967450, + 743265 2967450,743265.625 2967416,743238 2967416))',2249) ) As foo(the_geom); + sqft | sqm +---------+------------- + 928.625 | 86.27208552 + +Return area square feet and transform to Massachusetts state plane meters (26986) to get square meters. + Note this is in square feet because 2249 is + Mass State Plane Feet and transformed area is in square meters since 26986 is state plane mass meters + + +SELECT ST_Area(the_geom) As sqft, ST_Area(ST_Transform(the_geom,26986)) As sqm + FROM (SELECT + ST_GeomFromText('POLYGON((743238 2967416,743238 2967450, + 743265 2967450,743265.625 2967416,743238 2967416))',2249) ) As foo(the_geom); + sqft | sqm +---------+------------------ + 928.625 | 86.2724304199219 + + +Return area square feet and square meters using Geography data type. Note that we transform to our geometry to geography + (before you can do that make sure your geometry is in WGS 84 long lat 4326). Geography always measures in meters. + This is just for demonstration to compare. Normally your table will be stored in geography data type already. + + +SELECT ST_Area(the_geog)/POWER(0.3048,2) As sqft_spheroid, ST_Area(the_geog,false)/POWER(0.3048,2) As sqft_sphere, ST_Area(the_geog) As sqm_spheroid + FROM (SELECT + geography( + ST_Transform( + ST_GeomFromText('POLYGON((743238 2967416,743238 2967450,743265 2967450,743265.625 2967416,743238 2967416))', + 2249 + ) ,4326 + ) + ) + ) As foo(the_geog); + sqft_spheroid | sqft_sphere | sqm_spheroid +-----------------+------------------+------------------ +928.684405217197 | 927.186481558724 | 86.2776044452694 + + --if your data is in geography already + SELECT ST_Area(the_geog)/POWER(0.3048,2) As sqft, ST_Area(the_geog) As sqm + FROM somegeogtable; + + + + See Also + , , , + + + + + + + ST_Azimuth + + Returns the angle in radians from the horizontal of the vector defined by pointA and pointB + + + + + float ST_Azimuth + geometry pointA + geometry pointB + + + + + Description + + Returns the azimuth of the segment defined by the given + Point geometries, or NULL if the two points are coincident. Return + value is in radians. + + The Azimuth is mathematical concept defined as the angle, in this case measured in radian, between a reference plane + and a point + + Availability: 1.1.0 + Azimuth is especially useful in conjunction with ST_Translate for shifting an object along its perpendicular axis. See + upgis_lineshift Plpgsqlfunctions PostGIS wiki section for example of this. + + + + Examples + --Azimuth in degrees + +SELECT ST_Azimuth(ST_MakePoint(1,2), ST_MakePoint(3,4))/(2*pi())*360 as degAz, + ST_Azimuth(ST_MakePoint(3,4), ST_MakePoint(1,2))/(2*pi())*360 As degAzrev + +degaz degazrev +------ --------- +45 225 + + + + See Also + , + + + + + + + ST_Centroid + + Returns the geometric center of a geometry. + + + + + + geometry ST_Centroid + + geometry + g1 + + + + + + Description + + Computes the geometric center of a geometry, or equivalently, + the center of mass of the geometry as a POINT. For + [MULTI]POINTs, this is computed + as the arithmetric mean of the input coordinates. For + [MULTI]LINESTRINGs, this is + computed as the weighted length of each line segment. For + [MULTI]POLYGONs, "weight" is + thought in terms of area. If an empty geometry is supplied, an empty + GEOMETRYCOLLECTION is returned. If + NULL is supplied, NULL is + returned. + + The centroid is equal to the centroid of the set of component + Geometries of highest dimension (since the lower-dimension geometries + contribute zero "weight" to the centroid). + + Computation will be more accurate if performed by the GEOS + module (enabled at compile time). + + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 8.1.4, 9.5.5 + + + + Examples + + In each of the following illustrations, the blue dot represents + the centroid of the source geometry. + + + + + + + + + + + + Centroid of a + MULTIPOINT + + + + + + + + + + Centroid of a + LINESTRING + + + + + + + + + + + + Centroid of a + POLYGON + + + + + + + + + + Centroid of a + GEOMETRYCOLLECTION + + + + + + + + SELECT ST_AsText(ST_Centroid('MULTIPOINT ( -1 0, -1 2, -1 3, -1 4, -1 7, 0 1, 0 3, 1 1, 2 0, 6 0, 7 8, 9 8, 10 6 )')); + st_astext +------------------------------------------ + POINT(2.30769230769231 3.30769230769231) +(1 row) + + + + See Also + + + + + + + + ST_Contains + + Returns true if and only if no points of B lie in the exterior of A, and at least one point of the interior of B lies in the interior of A. + + + + + + boolean ST_Contains + + geometry + geomA + + geometry + geomB + + + + + + Description + + Geometry A contains Geometry B if and only if no points of B lie in the exterior of A, and at least one point of the interior of B lies in the interior of A. + An important subtlety of this definition is that A does not contain its boundary, but A does contain itself. Contrast that to where geometry + A does not Contain Properly itself. + + Returns TRUE if geometry B is completely inside geometry A. For this function to make + sense, the source geometries must both be of the same coordinate projection, + having the same SRID. ST_Contains is the inverse of ST_Within. So ST_Contains(A,B) implies ST_Within(B,A) except in the case of + invalid geometries where the result is always false regardless or not defined. + + Performed by the GEOS module + + + Do not call with a GEOMETRYCOLLECTION as an argument + + + + Do not use this function with invalid geometries. You will get unexpected results. + + + This function call will automatically include a bounding box + comparison that will make use of any indexes that are available on + the geometries. To avoid index use, use the function + _ST_Contains. + + NOTE: this is the "allowable" version that returns a + boolean, not an integer. + + &sfs_compliant; s2.1.1.2 // s2.1.13.3 + - same as within(geometry B, geometry A) + &sqlmm_compliant; SQL-MM 3: 5.1.31 + + There are certain subtleties to ST_Contains and ST_Within that are not intuitively obvious. + For details check out Subtleties of OGC Covers, Contains, Within + + + + Examples + + The ST_Contains predicate returns TRUE in all the following illustrations. + + + + + + + + + + + + LINESTRING / MULTIPOINT + + + + + + + + + + POLYGON / POINT + + + + + + + + + + + POLYGON / LINESTRING + + + + + + + + + + POLYGON / POLYGON + + + + + + + + The ST_Contains predicate returns FALSE in all the following illustrations. + + + + + + + + + + + + POLYGON / MULTIPOINT + + + + + + + + + + POLYGON / LINESTRING + + + + + + + + +-- A circle within a circle +SELECT ST_Contains(smallc, bigc) As smallcontainsbig, + ST_Contains(bigc,smallc) As bigcontainssmall, + ST_Contains(bigc, ST_Union(smallc, bigc)) as bigcontainsunion, + ST_Equals(bigc, ST_Union(smallc, bigc)) as bigisunion, + ST_Covers(bigc, ST_ExteriorRing(bigc)) As bigcoversexterior, + ST_Contains(bigc, ST_ExteriorRing(bigc)) As bigcontainsexterior +FROM (SELECT ST_Buffer(ST_GeomFromText('POINT(1 2)'), 10) As smallc, + ST_Buffer(ST_GeomFromText('POINT(1 2)'), 20) As bigc) As foo; + +-- Result + smallcontainsbig | bigcontainssmall | bigcontainsunion | bigisunion | bigcoversexterior | bigcontainsexterior +------------------+------------------+------------------+------------+-------------------+--------------------- + f | t | t | t | t | f + +-- Example demonstrating difference between contains and contains properly +SELECT ST_GeometryType(geomA) As geomtype, ST_Contains(geomA,geomA) AS acontainsa, ST_ContainsProperly(geomA, geomA) AS acontainspropa, + ST_Contains(geomA, ST_Boundary(geomA)) As acontainsba, ST_ContainsProperly(geomA, ST_Boundary(geomA)) As acontainspropba +FROM (VALUES ( ST_Buffer(ST_Point(1,1), 5,1) ), + ( ST_MakeLine(ST_Point(1,1), ST_Point(-1,-1) ) ), + ( ST_Point(1,1) ) + ) As foo(geomA); + + geomtype | acontainsa | acontainspropa | acontainsba | acontainspropba +--------------+------------+----------------+-------------+----------------- +ST_Polygon | t | f | f | f +ST_LineString | t | f | f | f +ST_Point | t | t | f | f + + + + + + See Also + , , ,, , + + + + + + ST_ContainsProperly + + Returns true if B intersects the interior of A but not the boundary (or exterior). A does not contain properly itself, but does contain itself. + + + + + + boolean ST_ContainsProperly + + geometry + geomA + + geometry + geomB + + + + + + Description + + Returns true if B intersects the interior of A but not the boundary (or exterior). + + A does not contain properly itself, but does contain itself. + Every point of the other geometry is a point of this geometry's interior. The DE-9IM Intersection Matrix for the two geometries matches + [T**FF*FF*] used in + + + From JTS docs slightly reworded: The advantage to using this predicate over and is that it can be computed + efficiently, with no need to compute topology at individual points. + + An example use case for this predicate is computing the intersections + of a set of geometries with a large polygonal geometry. + Since intersection is a fairly slow operation, it can be more efficient + to use containsProperly to filter out test geometries which lie + wholly inside the area. In these cases the intersection is + known a priori to be exactly the original test geometry. + + + + Availability: 1.4.0 - requires GEOS >= 3.1.0. + + + Do not call with a GEOMETRYCOLLECTION as an argument + + + + Do not use this function with invalid geometries. You will get unexpected results. + + + This function call will automatically include a bounding box + comparison that will make use of any indexes that are available on + the geometries. To avoid index use, use the function + _ST_ContainsProperly. + + + + + Examples + + --a circle within a circle + SELECT ST_ContainsProperly(smallc, bigc) As smallcontainspropbig, + ST_ContainsProperly(bigc,smallc) As bigcontainspropsmall, + ST_ContainsProperly(bigc, ST_Union(smallc, bigc)) as bigcontainspropunion, + ST_Equals(bigc, ST_Union(smallc, bigc)) as bigisunion, + ST_Covers(bigc, ST_ExteriorRing(bigc)) As bigcoversexterior, + ST_ContainsProperly(bigc, ST_ExteriorRing(bigc)) As bigcontainsexterior + FROM (SELECT ST_Buffer(ST_GeomFromText('POINT(1 2)'), 10) As smallc, + ST_Buffer(ST_GeomFromText('POINT(1 2)'), 20) As bigc) As foo; + --Result + smallcontainspropbig | bigcontainspropsmall | bigcontainspropunion | bigisunion | bigcoversexterior | bigcontainsexterior +------------------+------------------+------------------+------------+-------------------+--------------------- + f | t | f | t | t | f + + --example demonstrating difference between contains and contains properly + SELECT ST_GeometryType(geomA) As geomtype, ST_Contains(geomA,geomA) AS acontainsa, ST_ContainsProperly(geomA, geomA) AS acontainspropa, + ST_Contains(geomA, ST_Boundary(geomA)) As acontainsba, ST_ContainsProperly(geomA, ST_Boundary(geomA)) As acontainspropba + FROM (VALUES ( ST_Buffer(ST_Point(1,1), 5,1) ), + ( ST_MakeLine(ST_Point(1,1), ST_Point(-1,-1) ) ), + ( ST_Point(1,1) ) + ) As foo(geomA); + + geomtype | acontainsa | acontainspropa | acontainsba | acontainspropba +--------------+------------+----------------+-------------+----------------- +ST_Polygon | t | f | f | f +ST_LineString | t | f | f | f +ST_Point | t | t | f | f + + + + + See Also + , , , ,, ,, + + + + + + ST_Covers + + Returns 1 (TRUE) if no point in Geometry B is outside + Geometry A + + + + + + boolean ST_Covers + + geometry + geomA + + geometry + geomB + + + boolean ST_Covers + + geography + geogpolyA + + geography + geogpointB + + + + + + Description + + Returns 1 (TRUE) if no point in Geometry/Geography B is outside + Geometry/Geography A + + Performed by the GEOS module + + + Do not call with a GEOMETRYCOLLECTION as an argument + + + + For geography only Polygon covers point is supported. + + + + Do not use this function with invalid geometries. You will get unexpected results. + + + This function call will automatically include a bounding box + comparison that will make use of any indexes that are available on + the geometries. To avoid index use, use the function + _ST_Covers. + + Availability: 1.2.2 - requires GEOS >= 3.0 + Availability: 1.5 - support for geography was introduced. + + NOTE: this is the "allowable" version that returns a + boolean, not an integer. + + Not an OGC standard, but Oracle has it too. + There are certain subtleties to ST_Contains and ST_Within that are not intuitively obvious. + For details check out Subtleties of OGC Covers, Contains, Within + + + + Examples + Geometry example + + --a circle covering a circle +SELECT ST_Covers(smallc,smallc) As smallinsmall, + ST_Covers(smallc, bigc) As smallcoversbig, + ST_Covers(bigc, ST_ExteriorRing(bigc)) As bigcoversexterior, + ST_Contains(bigc, ST_ExteriorRing(bigc)) As bigcontainsexterior +FROM (SELECT ST_Buffer(ST_GeomFromText('POINT(1 2)'), 10) As smallc, + ST_Buffer(ST_GeomFromText('POINT(1 2)'), 20) As bigc) As foo; + --Result + smallinsmall | smallcoversbig | bigcoversexterior | bigcontainsexterior +--------------+----------------+-------------------+--------------------- + t | f | t | f +(1 row) + Geeography Example + + + + + + + See Also + , , + + + + + + ST_CoveredBy + + Returns 1 (TRUE) if no point in Geometry A is outside + Geometry B + + + + + + boolean ST_CoveredBy + + geometry + geomA + + geometry + geomB + + + + + + Description + + Returns 1 (TRUE) if no point in Geometry A is outside + Geometry B + + Performed by the GEOS module + + + Do not call with a GEOMETRYCOLLECTION as an argument + + + + Do not use this function with invalid geometries. You will get unexpected results. + + Availability: 1.2.2 - requires GEOS >= 3.0 + This function call will automatically include a bounding box + comparison that will make use of any indexes that are available on + the geometries. To avoid index use, use the function + _ST_CoveredBy. + + NOTE: this is the "allowable" version that returns a + boolean, not an integer. + + Not an OGC standard, but Oracle has it too. + There are certain subtleties to ST_Contains and ST_Within that are not intuitively obvious. + For details check out Subtleties of OGC Covers, Contains, Within + + + + Examples + + --a circle coveredby a circle +SELECT ST_CoveredBy(smallc,smallc) As smallinsmall, + ST_CoveredBy(smallc, bigc) As smallcoveredbybig, + ST_CoveredBy(ST_ExteriorRing(bigc), bigc) As exteriorcoveredbybig, + ST_Within(ST_ExteriorRing(bigc),bigc) As exeriorwithinbig +FROM (SELECT ST_Buffer(ST_GeomFromText('POINT(1 2)'), 10) As smallc, + ST_Buffer(ST_GeomFromText('POINT(1 2)'), 20) As bigc) As foo; + --Result + smallinsmall | smallcoveredbybig | exteriorcoveredbybig | exeriorwithinbig +--------------+-------------------+----------------------+------------------ + t | t | t | f +(1 row) + + + + See Also + , , , + + + + + + ST_Crosses + + Returns TRUE if the supplied geometries have some, but not all, + interior points in common. + + + + + + boolean ST_Crosses + + geometry g1 + + geometry g2 + + + + + + Description + + ST_Crosses takes two geometry objects and + returns TRUE if their intersection "spatially cross", that is, the + geometries have some, but not all interior points in common. The + intersection of the interiors of the geometries must not be the empty + set and must have a dimensionality less than the the maximum dimension + of the two input geometries. Additionally, the intersection of the two + geometries must not equal either of the source geometries. Otherwise, it + returns FALSE. + + In mathematical terms, this is expressed as: + + TODO: Insert appropriate MathML markup here or use a gif. + Simple HTML markup does not work well in both IE and Firefox. + + + + + + + + + + The DE-9IM Intersection Matrix for the two geometries is: + + + + T*T****** (for Point/Line, Point/Area, and + Line/Area situations) + + + + T*****T** (for Line/Point, Area/Point, and + Area/Line situations) + + + + 0******** (for Line/Line situations) + + + + For any other combination of dimensions this predicate returns + false. + + The OpenGIS Simple Features Specification defines this predicate + only for Point/Line, Point/Area, Line/Line, and Line/Area situations. + JTS / GEOS extends the definition to apply to Line/Point, Area/Point and + Area/Line situations as well. This makes the relation + symmetric. + + + Do not call with a GEOMETRYCOLLECTION as an argument + + + + This function call will automatically include a bounding box + comparison that will make use of any indexes that are available on the + geometries. + + + &sfs_compliant; s2.1.13.3 + &sqlmm_compliant; SQL-MM 3: 5.1.29 + + + + Examples + + The following illustrations all return TRUE. + + + + + + + + + + + + MULTIPOINT / LINESTRING + + + + + + + + + + MULTIPOINT / POLYGON + + + + + + + + + + + + LINESTRING / POLYGON + + + + + + + + + + LINESTRING / LINESTRING + + + + + + + + Consider a situation where a user has two tables: a table of roads + and a table of highways. + + + + + + + CREATE TABLE roads ( + id serial NOT NULL, + the_geom geometry, + CONSTRAINT roads_pkey PRIMARY KEY (road_id) +); + + + + CREATE TABLE highways ( + id serial NOT NULL, + the_gem geometry, + CONSTRAINT roads_pkey PRIMARY KEY (road_id) +); + + + + + + + To determine a list of roads that cross a highway, use a query + similiar to: + + + SELECT roads.id +FROM roads, highways +WHERE ST_Crosses(roads.the_geom, highways.the_geom); + + + + + + + ST_LineCrossingDirection + + Given 2 linestrings, returns a number between -3 and 3 denoting what kind of crossing behavior. 0 is no crossing. + + + + + + integer ST_LineCrossingDirection + geometry linestringA + geometry linestringB + + + + + + Description + + Given 2 linestrings, returns a number between -3 and 3 denoting what kind of crossing behavior. 0 is no crossing. This is only supported for LINESTRING + Definition of integer constants is as follows: + + + 0: LINE NO CROSS + + + -1: LINE CROSS LEFT + + + 1: LINE CROSS RIGHT + + + -2: LINE MULTICROSS END LEFT + + + 2: LINE MULTICROSS END RIGHT + + + -3: LINE MULTICROSS END SAME FIRST LEFT + + + 3: LINE MULTICROSS END SAME FIRST RIGHT + + + + Availability: 1.4 + + + + + + + Examples + + + + + + + + + + + Line 1 (green), Line 2 ball is start point, + triangle are end points. Query below. + + + +SELECT ST_LineCrossingDirection(foo.line1, foo.line2) As l1_cross_l2 , + ST_LineCrossingDirection(foo.line2, foo.line1) As l2_cross_l1 +FROM ( +SELECT + ST_GeomFromText('LINESTRING(25 169,89 114,40 70,86 43)') As line1, + ST_GeomFromText('LINESTRING(171 154,20 140,71 74,161 53)') As line2 + ) As foo; + + l1_cross_l2 | l2_cross_l1 +-------------+------------- + 3 | -3 + + + + + + + + + + + Line 1 (green), Line 2 (blue) ball is start point, + triangle are end points. Query below. + + + +SELECT ST_LineCrossingDirection(foo.line1, foo.line2) As l1_cross_l2 , + ST_LineCrossingDirection(foo.line2, foo.line1) As l2_cross_l1 +FROM ( + SELECT + ST_GeomFromText('LINESTRING(25 169,89 114,40 70,86 43)') As line1, + ST_GeomFromText('LINESTRING (171 154, 20 140, 71 74, 2.99 90.16)') As line2 +) As foo; + + l1_cross_l2 | l2_cross_l1 +-------------+------------- + 2 | -2 + + + + + + + + + + + Line 1 (green), Line 2 (blue) ball is start point, + triangle are end points. Query below. + + + +SELECT + ST_LineCrossingDirection(foo.line1, foo.line2) As l1_cross_l2 , + ST_LineCrossingDirection(foo.line2, foo.line1) As l2_cross_l1 +FROM ( + SELECT + ST_GeomFromText('LINESTRING(25 169,89 114,40 70,86 43)') As line1, + ST_GeomFromText('LINESTRING (20 140, 71 74, 161 53)') As line2 + ) As foo; + + l1_cross_l2 | l2_cross_l1 +-------------+------------- + -1 | 1 + + + + + + + + + + + Line 1 (green), Line 2 (blue) ball is start point, + triangle are end points. Query below. + + + +SELECT ST_LineCrossingDirection(foo.line1, foo.line2) As l1_cross_l2 , + ST_LineCrossingDirection(foo.line2, foo.line1) As l2_cross_l1 +FROM (SELECT + ST_GeomFromText('LINESTRING(25 169,89 114,40 70,86 43)') As line1, + ST_GeomFromText('LINESTRING(2.99 90.16,71 74,20 140,171 154)') As line2 + ) As foo; + + l1_cross_l2 | l2_cross_l1 +-------------+------------- + -2 | 2 + + + + + + + + + +SELECT s1.gid, s2.gid, ST_LineCrossingDirection(s1.the_geom, s2.the_geom) + FROM streets s1 CROSS JOIN streets s2 ON (s1.gid != s2.gid AND s1.the_geom && s2.the_geom ) +WHERE ST_CrossingDirection(s1.the_geom, s2.the_geom) > 0; + + + + + + See Also + + + + + + + + ST_Disjoint + + Returns TRUE if the Geometries do not "spatially + intersect" - if they do not share any space together. + + + + + + boolean ST_Disjoint + + geometry + A + + + geometry + B + + + + + + Description + Overlaps, Touches, Within all imply geometries are not spatially disjoint. If any of the aforementioned + returns true, then the geometries are not spatially disjoint. + Disjoint implies false for spatial intersection. + + + Do not call with a GEOMETRYCOLLECTION as an argument + + + Performed by the GEOS module + + This function call does not use indexes + + + + NOTE: this is the "allowable" version that returns a + boolean, not an integer. + + &sfs_compliant; s2.1.1.2 //s2.1.13.3 + - a.Relate(b, 'FF*FF****') + &sqlmm_compliant; SQL-MM 3: 5.1.26 + + + Examples + + SELECT ST_Disjoint('POINT(0 0)'::geometry, 'LINESTRING ( 2 0, 0 2 )'::geometry); + st_disjoint +--------------- + t +(1 row) +SELECT ST_Disjoint('POINT(0 0)'::geometry, 'LINESTRING ( 0 0, 0 2 )'::geometry); + st_disjoint +--------------- + f +(1 row) + + + + + See Also + ST_Intersects + + + + + + ST_Distance + + For geometry type Returns the 2-dimensional cartesian minimum distance (based on spatial ref) between two geometries in + projected units. For geography type defaults to return spheroidal minimum distance between two geographies in meters. + + + + + float ST_Distance + + geometry + g1 + + geometry + g2 + + + float ST_Distance + + geography + gg1 + + geography + gg2 + + + + float ST_Distance + + geography + gg1 + + geography + gg2 + + boolean + use_spheroid + + + + + + Description + + For geometry type returns the 2-dimensional minimum cartesian distance between two geometries in + projected units (spatial ref units). For geography type defaults to return the minimum distance around WGS 84 spheroid between two geographies in meters. Pass in + false to return answer in sphere instead of spheroid. + + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 5.1.23 + + Availability: 1.5.0 geography support was introduced in 1.5. + + + + Examples + + +--Geometry example - units in planar degrees 4326 is WGS 84 long lat unit=degrees +SELECT ST_Distance( + ST_GeomFromText('POINT(-72.1235 42.3521)',4326), + ST_GeomFromText('LINESTRING(-72.1260 42.45, -72.123 42.1546)', 4326) + ); +st_distance +----------------- +0.00150567726382282 + +-- Geometry example - units in meters (SRID: 26986 Massachusetts state plane meters) (most accurate for Massachusetts) +SELECT ST_Distance( + ST_Transform(ST_GeomFromText('POINT(-72.1235 42.3521)',4326),26986), + ST_Transform(ST_GeomFromText('LINESTRING(-72.1260 42.45, -72.123 42.1546)', 4326),26986) + ); +st_distance +----------------- +123.797937878454 + +-- Geometry example - units in meters (SRID: 2163 US National Atlas Equal area) (least accurate) +SELECT ST_Distance( + ST_Transform(ST_GeomFromText('POINT(-72.1235 42.3521)',4326),2163), + ST_Transform(ST_GeomFromText('LINESTRING(-72.1260 42.45, -72.123 42.1546)', 4326),2163) + ); + +st_distance +------------------ +126.664256056812 + +-- Geography example -- same but note units in meters - use sphere for slightly faster less accurate +SELECT ST_Distance(gg1, gg2) As spheroid_dist, ST_Distance(gg1, gg2, false) As sphere_dist +FROM (SELECT + ST_GeographyFromText('SRID=4326;POINT(-72.1235 42.3521)') As gg1, + ST_GeographyFromText('SRID=4326;LINESTRING(-72.1260 42.45, -72.123 42.1546)') As gg2 + ) As foo ; + + spheroid_dist | sphere_dist +------------------+------------------ + 123.802076746848 | 123.475736916397 + + + + + + See Also + + , , , , + + + + + + ST_HausdorffDistance + + Returns the Hausdorff distance between two geometries. Basically a measure of how similar or dissimilar 2 geometries are. Units are in the units of the spatial + reference system of the geometries. + + + + + + float ST_HausdorffDistance + + geometry + g1 + + geometry + g2 + + + float ST_HausdorffDistance + + geometry + g1 + + geometry + g2 + + float + densifyFrac + + + + + + Description + + Implements algorithm for computing a distance metric which can be thought of as the "Discrete Hausdorff Distance". +This is the Hausdorff distance restricted to discrete points for one of the geometries. Wikipedia article on Hausdorff distance + Martin Davis note on how Hausdorff Distance calculation was used to prove correctness of the CascadePolygonUnion approach. + +When densifyFrac is specified, this function performs a segment densification before computing the discrete hausdorff distance. The densifyFrac parameter sets the fraction by which to densify each segment. Each segment will be split into a number of equal-length subsegments, whose fraction of the total length is closest to the given fraction. + + + + +The current implementation supports only vertices as the discrete locations. This could be extended to allow an arbitrary density of points to be used. + + + + + This algorithm is NOT equivalent to the standard Hausdorff distance. However, it computes an approximation that is correct for a large subset of useful cases. + One important part of this subset is Linestrings that are roughly parallel to each other, and roughly equal in length. This is a useful metric for line matching. + + + Availability: 1.5 - requires GEOS >= 3.2.0 + + + + + Examples + + postgis=# SELECT st_HausdorffDistance( + 'LINESTRING (0 0, 2 0)'::geometry, + 'MULTIPOINT (0 1, 1 0, 2 1)'::geometry); + st_hausdorffdistance + ---------------------- + 1 +(1 row) + + postgis=# SELECT st_hausdorffdistance('LINESTRING (130 0, 0 0, 0 150)'::geometry, 'LINESTRING (10 10, 10 150, 130 10)'::geometry, 0.5); + st_hausdorffdistance + ---------------------- + 70 +(1 row) + + + + + + + + ST_Distance_Sphere + + Returns minimum distance in meters between two lon/lat + geometries. Uses a spherical earth and radius of 6370986 meters. + Faster than ST_Distance_Spheroid, but less + accurate. PostGIS versions prior to 1.5 only implemented for points. + + + + + + float ST_Distance_Sphere + geometry geomlonlatA + geometry geomlonlatB + + + + + + Description + + Returns minimum distance in meters between two lon/lat + points. Uses a spherical earth and radius of 6370986 meters. + Faster than , but less + accurate. PostGIS Versions prior to 1.5 only implemented for points. + + This function currently does not look at the SRID of a geometry and will always assume its in WGS 84 long lat. Prior versions of this function only support points. + + + Availability: 1.5 - support for other geometry types besides points was introduced. Prior versions only work with points. + + + + + Examples + + SELECT round(CAST(ST_Distance_Sphere(ST_Centroid(the_geom), ST_GeomFromText('POINT(-118 38)',4326)) As numeric),2) As dist_meters, +round(CAST(ST_Distance(ST_Transform(ST_Centroid(the_geom),32611), + ST_Transform(ST_GeomFromText('POINT(-118 38)', 4326),32611)) As numeric),2) As dist_utm11_meters, +round(CAST(ST_Distance(ST_Centroid(the_geom), ST_GeomFromText('POINT(-118 38)', 4326)) As numeric),5) As dist_degrees, +round(CAST(ST_Distance(ST_Transform(the_geom,32611), + ST_Transform(ST_GeomFromText('POINT(-118 38)', 4326),32611)) As numeric),2) As min_dist_line_point_meters +FROM + (SELECT ST_GeomFromText('LINESTRING(-118.584 38.374,-118.583 38.5)', 4326) As the_geom) as foo; + dist_meters | dist_utm11_meters | dist_degrees | min_dist_line_point_meters + -------------+-------------------+--------------+---------------------------- + 70424.47 | 70438.00 | 0.72900 | 65871.18 + + + + + + + See Also + + , + + + + + + ST_Distance_Spheroid + + Returns the minimum distance between two lon/lat geometries given a + particular spheroid. + PostGIS versions prior to 1.5 only support points. + + + + + + float ST_Distance_Spheroid + geometry geomlonlatA + geometry geomlonlatB + spheroid measurement_spheroid + + + + + + Description + + Returns minimum distance in meters between two lon/lat + geometries given a particular spheroid. See the explanation of spheroids given for + . PostGIS version prior to 1.5 only support points. + + This function currently does not look at the SRID of a geometry and will always assume its in WGS 80 long lat. Prior versions of this function only support points. + + + Availability: 1.5 - support for other geometry types besides points was introduced. Prior versions only work with points. + + + + + Examples + + SELECT round(CAST( + ST_Distance_Spheroid(ST_Centroid(the_geom), ST_GeomFromText('POINT(-118 38)',4326), 'SPHEROID["WGS 84",6378137,298.257223563]') + As numeric),2) As dist_meters_spheroid, + round(CAST(ST_Distance_Sphere(ST_Centroid(the_geom), ST_GeomFromText('POINT(-118 38)',4326)) As numeric),2) As dist_meters_sphere, +round(CAST(ST_Distance(ST_Transform(ST_Centroid(the_geom),32611), + ST_Transform(ST_GeomFromText('POINT(-118 38)', 4326),32611)) As numeric),2) As dist_utm11_meters +FROM + (SELECT ST_GeomFromText('LINESTRING(-118.584 38.374,-118.583 38.5)', 4326) As the_geom) as foo; + dist_meters_spheroid | dist_meters_sphere | dist_utm11_meters +----------------------+--------------------+------------------- + 70454.92 | 70424.47 | 70438.00 + + + + + + + See Also + + , + + + + + + ST_DWithin + + Returns true if the geometries are within the specified + distance of one another. For geometry units are in those of spatial reference and For geography units are in meters and measurement is + defaulted to use_spheroid=true (measure around spheroid), for faster check, use_spheroid=false to measure along sphere. + + + + + + boolean ST_DWithin + geometry + g1 + + geometry + g2 + + double precision + distance_of_srid + + + + boolean ST_DWithin + geography + gg1 + + geography + gg2 + + double precision + distance_meters + + + + boolean ST_DWithin + geography + gg1 + + geography + gg2 + + double precision + distance_meters + + boolean + use_spheroid + + + + + + Description + + Returns true if the geometries are within the specified distance + of one another. + For Geometries: The distance is specified in units defined by the + spatial reference system of the geometries. For this function to make + sense, the source geometries must both be of the same coorindate projection, + having the same SRID. + + For geography units are in meters and measurement is + defaulted to use_spheroid=true (measure around WGS 84 spheroid), for faster check, use_spheroid=false to measure along sphere. + + + This function call will automatically include a bounding box + comparison that will make use of any indexes that are available on + the geometries. + + + + Prior to 1.3, ST_Expand was commonly used in conjunction with && and ST_Distance to + achieve the same effect and in pre-1.3.4 this function was basically short-hand for that construct. + From 1.3.4, ST_DWithin uses a more short-circuit distance function which should make it more efficient + than prior versions for larger buffer regions. + + + &sfs_compliant; + Availability: 1.5.0 support for geography was introduced + + + + Examples + +--Find the nearest hospital to each school +--that is within 3000 units of the school. +-- We do an ST_DWithin search to utilize indexes to limit our search list +-- that the non-indexable ST_Distance needs to process +--If the units of the spatial reference is meters then units would be meters +SELECT DISTINCT ON (s.gid) s.gid, s.school_name, s.the_geom, h.hospital_name + FROM schools s + LEFT JOIN hospitals h ON ST_DWithin(s.the_geom, h.the_geom, 3000) + ORDER BY s.gid, ST_Distance(s.the_geom, h.the_geom); + +--The schools with no close hospitals +--Find all schools with no hospital within 3000 units +--away from the school. Units is in units of spatial ref (e.g. meters, feet, degrees) +SELECT s.gid, s.school_name + FROM schools s + LEFT JOIN hospitals h ON ST_DWithin(s.the_geom, h.the_geom, 3000) + WHERE h.gid IS NULL; + + + + + See Also + + , + + + + + + ST_Equals + + Returns true if the given geometries represent the same geometry. Directionality + is ignored. + + + + + + boolean ST_Equals + geometry A + geometry B + + + + + + Description + + Returns TRUE if the given Geometries are "spatially + equal". Use this for a 'better' answer than '='. + Note by spatially equal we mean ST_Within(A,B) = true and ST_Within(B,A) = true and + also mean ordering of points can be different but + represent the same geometry structure. To verify the order of points is consistent, use + ST_OrderingEquals (it must be noted ST_OrderingEquals is a little more stringent than simply verifying order of + points are the same). + + + This function will return false if either geometry is invalid even if they are binary equal. + + + &sfs_compliant; s2.1.1.2 + &sqlmm_compliant; SQL-MM 3: 5.1.24 + + + + Examples + + SELECT ST_Equals(ST_GeomFromText('LINESTRING(0 0, 10 10)'), + ST_GeomFromText('LINESTRING(0 0, 5 5, 10 10)')); + st_equals +----------- + t +(1 row) + +SELECT ST_Equals(ST_Reverse(ST_GeomFromText('LINESTRING(0 0, 10 10)')), + ST_GeomFromText('LINESTRING(0 0, 5 5, 10 10)')); + st_equals +----------- + t +(1 row) + + + + + See Also + + , , , + + + + + + + ST_HasArc + + Returns true if a geometry or geometry collection contains a circular string + + + + + + boolean ST_HasArc + geometry geomA + + + + + + Description + + Returns true if a geometry or geometry collection contains a circular string + + Availability: 1.2.3? + &Z_support; + &curve_support; + + + + + Examples + + SELECT ST_HasArc(ST_Collect('LINESTRING(1 2, 3 4, 5 6)', 'CIRCULARSTRING(1 1, 2 3, 4 5, 6 7, 5 6)')); + st_hasarc + -------- + t + + + + + + See Also + + , + + + + + + ST_Intersects + + Returns TRUE if the Geometries/Geography "spatially + intersect" - (share any portion of space) and FALSE if they don't (they are Disjoint). + For geography -- tolerance is 0.00001 meters (so any points that close are considered to intersect) + + + + + + boolean ST_Intersects + + geometry + geomA + + + geometry + geomB + + + + boolean ST_Intersects + + geography + geogA + + + geography + geogB + + + + + + Description + Overlaps, Touches, Within all imply spatial intersection. If any of the aforementioned + returns true, then the geometries also spatially intersect. + Disjoint implies false for spatial intersection. + + + Do not call with a GEOMETRYCOLLECTION as an argument for geometry version. The geography + version supports GEOMETRYCOLLECTION since its a thin wrapper around distance implementation. + + + Performed by the GEOS module (for geometry), geography is native + Availability: 1.5 support for geography was introduced. + + This function call will automatically include a bounding box + comparison that will make use of any indexes that are available on the + geometries. + + + For geography, this function has a distance tolerance of about 0.00001 meters and uses the sphere rather + than spheroid calculation. + + + NOTE: this is the "allowable" version that returns a + boolean, not an integer. + + &sfs_compliant; s2.1.1.2 //s2.1.13.3 + - ST_Intersects(g1, g2 ) --> Not (ST_Disjoint(g1, g2 )) + + &sqlmm_compliant; SQL-MM 3: 5.1.27 + + + Geometry Examples +SELECT ST_Intersects('POINT(0 0)'::geometry, 'LINESTRING ( 2 0, 0 2 )'::geometry); + st_intersects +--------------- + f +(1 row) +SELECT ST_Intersects('POINT(0 0)'::geometry, 'LINESTRING ( 0 0, 0 2 )'::geometry); + st_intersects +--------------- + t +(1 row) + + + + Geography Examples +SELECT ST_Intersects( + ST_GeographyFromText('SRID=4326;LINESTRING(-43.23456 72.4567,-43.23456 72.4568)'), + ST_GeographyFromText('SRID=4326;POINT(-43.23456 72.4567772)') + ); + + st_intersects +--------------- +t + + + + See Also + + + + + + ST_Length + + Returns the 2d length of the geometry if it is a linestring or multilinestring. geometry are in units of spatial reference and geography are in meters (default spheroid) + + + + + float ST_Length + geometry a_2dlinestring + + + float ST_Length + geography gg + + + float ST_Length + geography gg + boolean use_spheroid + + + + + Description + + For geometry: Returns the cartesian 2D length of the geometry if it is a linestring, multilinestring, ST_Curve, ST_MultiCurve. 0 is returned for + areal geometries. For areal geometries use ST_Perimeter. Geometry: Measurements are in the units of the + spatial reference system of the geometry. Geography: Units are in meters and also acts as a Perimeter function for areal geogs. + + Currently for geometry this is an alias for ST_Length2D, but this may change to support higher dimensions. + Currently applying this to a MULTI/POLYGON of type geography will give you the perimeter of the POLYGON/MULTIPOLYGON. This is not the + case with the geometry implementation. + For geography measurement defaults spheroid measurement. To use the faster less accurate sphere use ST_Length(gg,false); + &sfs_compliant; s2.1.5.1 + &sqlmm_compliant; SQL-MM 3: 7.1.2, 9.3.4 + Availability: 1.5.0 geography support was introduced in 1.5. + + + + Geometry Examples + Return length in feet for line string. Note this is in feet because 2249 is + Mass State Plane Feet + +SELECT ST_Length(ST_GeomFromText('LINESTRING(743238 2967416,743238 2967450,743265 2967450, +743265.625 2967416,743238 2967416)',2249)); +st_length +--------- + 122.630744000095 + + +--Transforming WGS 84 linestring to Massachusetts state plane meters +SELECT ST_Length( + ST_Transform( + ST_GeomFromEWKT('SRID=4326;LINESTRING(-72.1260 42.45, -72.1240 42.45666, -72.123 42.1546)'), + 26986 + ) +); +st_length +--------- +34309.4563576191 + + + + Geography Examples + Return length of WGS 84 geography line + + -- default calculation is using a sphere rather than spheroid +SELECT ST_Length(the_geog) As length_spheroid, ST_Length(the_geog,false) As length_sphere +FROM (SELECT ST_GeographyFromText( +'SRID=4326;LINESTRING(-72.1260 42.45, -72.1240 42.45666, -72.123 42.1546)') As the_geog) + As foo; + length_spheroid | length_sphere +------------------+------------------ + 34310.5703627305 | 34346.2060960742 +(1 row) + + + + See Also + , , , , + + + + + + ST_Length2D + + Returns the 2-dimensional length of the geometry if it is a + linestring or multi-linestring. This is an alias for ST_Length + + + + + + float ST_Length2D + geometry a_2dlinestring + + + + + + Description + + Returns the 2-dimensional length of the geometry if it is a + linestring or multi-linestring. This is an alias for ST_Length + + + + + + See Also + + , + + + + + + ST_Length3D + + Returns the 3-dimensional or 2-dimensional length of the geometry if it is a + linestring or multi-linestring. + + + + + + float ST_Length3D + geometry a_3dlinestring + + + + + + Description + + Returns the 3-dimensional or 2-dimensional length of the geometry if it is a + linestring or multi-linestring. For 2-d lines it will just return the 2-d length (same as ST_Length and ST_Length2D) + + &Z_support; + + + + + Examples + + Return length in feet for a 3D cable. Note this is in feet because 2249 is + Mass State Plane Feet + +SELECT ST_Length3D(ST_GeomFromText('LINESTRING(743238 2967416 1,743238 2967450 1,743265 2967450 3, +743265.625 2967416 3,743238 2967416 3)',2249)); +st_length3d +----------- +122.704716741457 + + + + + + See Also + + , + + + + + + ST_Length_Spheroid + + Calculates the 2D or 3D length of a linestring/multilinestring on an ellipsoid. This + is useful if the coordinates of the geometry are in + longitude/latitude and a length is desired without reprojection. + + + + + + float ST_Length_Spheroid + geometry a_linestring + spheroid a_spheroid + + + + + + Description + + Calculates the length of a geometry on an ellipsoid. This + is useful if the coordinates of the geometry are in + longitude/latitude and a length is desired without reprojection. + The ellipsoid is a separate database type and can be constructed + as follows: + + SPHEROID[<NAME>,<SEMI-MAJOR + AXIS>,<INVERSE FLATTENING>] + + + SPHEROID["GRS_1980",6378137,298.257222101] + Will return 0 for anything that is not a MULTILINESTRING or LINESTRING + + &Z_support; + + + + + Examples + + SELECT ST_Length_Spheroid( geometry_column, + 'SPHEROID["GRS_1980",6378137,298.257222101]' ) + FROM geometry_table; + +SELECT ST_Length_Spheroid( the_geom, sph_m ) As tot_len, +ST_Length_Spheroid(ST_GeometryN(the_geom,1), sph_m) As len_line1, +ST_Length_Spheroid(ST_GeometryN(the_geom,2), sph_m) As len_line2 + FROM (SELECT ST_GeomFromText('MULTILINESTRING((-118.584 38.374,-118.583 38.5), + (-71.05957 42.3589 , -71.061 43))') As the_geom, +CAST('SPHEROID["GRS_1980",6378137,298.257222101]' As spheroid) As sph_m) as foo; + tot_len | len_line1 | len_line2 +------------------+------------------+------------------ + 85204.5207562955 | 13986.8725229309 | 71217.6482333646 + + --3D +SELECT ST_Length_Spheroid( the_geom, sph_m ) As tot_len, +ST_Length_Spheroid(ST_GeometryN(the_geom,1), sph_m) As len_line1, +ST_Length_Spheroid(ST_GeometryN(the_geom,2), sph_m) As len_line2 + FROM (SELECT ST_GeomFromEWKT('MULTILINESTRING((-118.584 38.374 20,-118.583 38.5 30), + (-71.05957 42.3589 75, -71.061 43 90))') As the_geom, +CAST('SPHEROID["GRS_1980",6378137,298.257222101]' As spheroid) As sph_m) as foo; + + tot_len | len_line1 | len_line2 +------------------+-----------------+------------------ + 85204.5259107402 | 13986.876097711 | 71217.6498130292 + + + + + + + See Also + + , , + + + + + + ST_Length2D_Spheroid + + Calculates the 2D length of a linestring/multilinestring on an ellipsoid. This + is useful if the coordinates of the geometry are in + longitude/latitude and a length is desired without reprojection. + + + + + + float ST_Length2D_Spheroid + geometry a_linestring + spheroid a_spheroid + + + + + + Description + + Calculates the 2D length of a geometry on an ellipsoid. This + is useful if the coordinates of the geometry are in + longitude/latitude and a length is desired without reprojection. + The ellipsoid is a separate database type and can be constructed + as follows: + + SPHEROID[<NAME>,<SEMI-MAJOR + AXIS>,<INVERSE FLATTENING>] + + + SPHEROID["GRS_1980",6378137,298.257222101] + Will return 0 for anything that is not a MULTILINESTRING or LINESTRING + This is much like and except it will throw away the Z coordinate in calculations. + + + + + + Examples + + SELECT ST_Length2D_Spheroid( geometry_column, + 'SPHEROID["GRS_1980",6378137,298.257222101]' ) + FROM geometry_table; + +SELECT ST_Length2D_Spheroid( the_geom, sph_m ) As tot_len, +ST_Length2D_Spheroid(ST_GeometryN(the_geom,1), sph_m) As len_line1, +ST_Length2D_Spheroid(ST_GeometryN(the_geom,2), sph_m) As len_line2 + FROM (SELECT ST_GeomFromText('MULTILINESTRING((-118.584 38.374,-118.583 38.5), + (-71.05957 42.3589 , -71.061 43))') As the_geom, +CAST('SPHEROID["GRS_1980",6378137,298.257222101]' As spheroid) As sph_m) as foo; + tot_len | len_line1 | len_line2 +------------------+------------------+------------------ + 85204.5207562955 | 13986.8725229309 | 71217.6482333646 + + --3D Observe same answer +SELECT ST_Length2D_Spheroid( the_geom, sph_m ) As tot_len, +ST_Length2D_Spheroid(ST_GeometryN(the_geom,1), sph_m) As len_line1, +ST_Length2D_Spheroid(ST_GeometryN(the_geom,2), sph_m) As len_line2 + FROM (SELECT ST_GeomFromEWKT('MULTILINESTRING((-118.584 38.374 20,-118.583 38.5 30), + (-71.05957 42.3589 75, -71.061 43 90))') As the_geom, +CAST('SPHEROID["GRS_1980",6378137,298.257222101]' As spheroid) As sph_m) as foo; + + tot_len | len_line1 | len_line2 +------------------+------------------+------------------ + 85204.5207562955 | 13986.8725229309 | 71217.6482333646 + + + + + + + See Also + + , , + + + + + + ST_Length3D_Spheroid + + Calculates the length of a geometry on an ellipsoid, + taking the elevation into account. This is just an alias for ST_Length_Spheroid. + + + + + + float ST_Length3D_Spheroid + geometry a_linestring + spheroid a_spheroid + + + + + + Description + + Calculates the length of a geometry on an ellipsoid, + taking the elevation into account. This is just an alias + for ST_Length_Spheroid. + + Will return 0 for anything that is not a MULTILINESTRING or LINESTRING + This functionis just an alias for ST_Length_Spheroid. + + &Z_support; + + + + + Examples + + See ST_Length_Spheroid + + + + + See Also + + , , + + + + + + + + + ST_Max_Distance + + Returns the 2-dimensional largest distance between two geometries in + projected units. + + + + + + float ST_Max_Distance + + geometry + g1 + + geometry + g2 + + + + + + Description + + Returns the 2-dimensional maximum cartesian distance between two linestrings in + projected units. + + + + + Examples + + --ALL EXAMPLES current throw NOT YET IMPLEMENTED + + + + See Also + + + + + + + + + ST_OrderingEquals + + Returns true if the given geometries represent the same geometry + and points are in the same directional order. + + + + + + boolean ST_OrderingEquals + geometry A + geometry B + + + + + + Description + + ST_OrderingEquals compares two geometries and t (TRUE) if the + geometries are equal and the coordinates are in the same order; + otherwise it returns f (FALSE). + + + This function is implemented as per the ArcSDE SQL + specification rather than SQL-MM. + http://edndoc.esri.com/arcsde/9.1/sql_api/sqlapi3.htm#ST_OrderingEquals + + &sqlmm_compliant; SQL-MM 3: 5.1.43 + + + + Examples + + SELECT ST_OrderingEquals(ST_GeomFromText('LINESTRING(0 0, 10 10)'), + ST_GeomFromText('LINESTRING(0 0, 5 5, 10 10)')); + st_orderingequals +----------- + f +(1 row) + +SELECT ST_OrderingEquals(ST_GeomFromText('LINESTRING(0 0, 10 10)'), + ST_GeomFromText('LINESTRING(0 0, 0 0, 10 10)')); + st_orderingequals +----------- + t +(1 row) + +SELECT ST_OrderingEquals(ST_Reverse(ST_GeomFromText('LINESTRING(0 0, 10 10)')), + ST_GeomFromText('LINESTRING(0 0, 0 0, 10 10)')); + st_orderingequals +----------- + f +(1 row) + + + + See Also + , + + + + + + ST_Overlaps + + Returns TRUE if the Geometries share space, are of the same dimension, but are not completely contained by each other. + + + + + + boolean ST_Overlaps + geometry A + geometry B + + + + + + Description + + Returns TRUE if the Geometries "spatially + overlap". By that we mean they intersect, but one does not completely contain another. + + Performed by the GEOS module + + Do not call with a GeometryCollection as an argument + + This function call will automatically include a bounding box + comparison that will make use of any indexes that are available on + the geometries. To avoid index use, use the function + _ST_Overlaps. + + NOTE: this is the "allowable" version that returns a + boolean, not an integer. + + &sfs_compliant; s2.1.1.2 // s2.1.13.3 + &sqlmm_compliant; SQL-MM 3: 5.1.32 + + + + Examples + + --a point on a line is contained by the line and is of a lower dimension, and therefore does not overlap the line + nor crosses + +SELECT ST_Overlaps(a,b) As a_overlap_b, + ST_Crosses(a,b) As a_crosses_b, + ST_Intersects(a, b) As a_intersects_b, ST_Contains(b,a) As b_contains_a +FROM (SELECT ST_GeomFromText('POINT(1 0.5)') As a, ST_GeomFromText('LINESTRING(1 0, 1 1, 3 5)') As b) + As foo + +a_overlap_b | a_crosses_b | a_intersects_b | b_contains_a +------------+-------------+----------------+-------------- +f | f | t | t + +--a line that is partly contained by circle, but not fully is defined as intersecting and crossing, +-- but since of different dimension it does not overlap +SELECT ST_Overlaps(a,b) As a_overlap_b, ST_Crosses(a,b) As a_crosses_b, + ST_Intersects(a, b) As a_intersects_b, + ST_Contains(a,b) As a_contains_b +FROM (SELECT ST_Buffer(ST_GeomFromText('POINT(1 0.5)'), 3) As a, ST_GeomFromText('LINESTRING(1 0, 1 1, 3 5)') As b) + As foo; + + a_overlap_b | a_crosses_b | a_intersects_b | a_contains_b +-------------+-------------+----------------+-------------- + f | t | t | f + + -- a 2-dimensional bent hot dog (aka puffered line string) that intersects a circle, + -- but is not fully contained by the circle is defined as overlapping since they are of the same dimension, +-- but it does not cross, because the intersection of the 2 is of the same dimension +-- as the maximum dimension of the 2 + +SELECT ST_Overlaps(a,b) As a_overlap_b, ST_Crosses(a,b) As a_crosses_b, ST_Intersects(a, b) As a_intersects_b, +ST_Contains(b,a) As b_contains_a, +ST_Dimension(a) As dim_a, ST_Dimension(b) as dim_b, ST_Dimension(ST_Intersection(a,b)) As dima_intersection_b +FROM (SELECT ST_Buffer(ST_GeomFromText('POINT(1 0.5)'), 3) As a, + ST_Buffer(ST_GeomFromText('LINESTRING(1 0, 1 1, 3 5)'),0.5) As b) + As foo; + + a_overlap_b | a_crosses_b | a_intersects_b | b_contains_a | dim_a | dim_b | dima_intersection_b +-------------+-------------+----------------+--------------+-------+-------+--------------------- + t | f | t | f | 2 | 2 | 2 + + + + + See Also + + , , , + + + + + ST_Perimeter + + Return the length measurement of the boundary of an ST_Surface + or ST_MultiSurface value. (Polygon, Multipolygon) + + + + + float ST_Perimeter + geometry g1 + + + + + Description + + Returns the 2D perimeter of the geometry if it is a ST_Surface, ST_MultiSurface (Polygon, Multipolygon). 0 is returned for + non-areal geometries. For linestrings use ST_Length. Measurements are in the units of the + spatial reference system of the geometry. + + Currently this is an alias for ST_Perimeter2D, but this may change to support higher dimensions. + + &sfs_compliant; s2.1.5.1 + &sqlmm_compliant; SQL-MM 3: 8.1.3, 9.5.4 + + + + Examples + Return perimeter in feet for polygon and multipolygon. Note this is in feet because 2249 is + Mass State Plane Feet + +SELECT ST_Perimeter(ST_GeomFromText('POLYGON((743238 2967416,743238 2967450,743265 2967450, +743265.625 2967416,743238 2967416))', 2249)); +st_perimeter +--------- + 122.630744000095 +(1 row) + +SELECT ST_Perimeter(ST_GeomFromText('MULTIPOLYGON(((763104.471273676 2949418.44119003, +763104.477769673 2949418.42538203, +763104.189609677 2949418.22343004,763104.471273676 2949418.44119003)), +((763104.471273676 2949418.44119003,763095.804579742 2949436.33850239, +763086.132105649 2949451.46730207,763078.452329651 2949462.11549407, +763075.354136904 2949466.17407812,763064.362142565 2949477.64291974, +763059.953961626 2949481.28983009,762994.637609571 2949532.04103014, +762990.568508415 2949535.06640477,762986.710889563 2949539.61421415, +763117.237897679 2949709.50493431,763235.236617789 2949617.95619822, +763287.718121842 2949562.20592617,763111.553321674 2949423.91664605, +763104.471273676 2949418.44119003)))', 2249)); +st_perimeter +--------- + 845.227713366825 +(1 row) + + + + See Also + + + + + + + ST_Perimeter2D + + Returns the 2-dimensional perimeter of the geometry, if it + is a polygon or multi-polygon. This is currently an alias for ST_Perimeter. + + + + + + float ST_Perimeter2D + geometry geomA + + + + + + Description + + Returns the 2-dimensional perimeter of the geometry, if it + is a polygon or multi-polygon. + + + + This is currently an alias for ST_Perimeter. In future versions ST_Perimeter may return the highest dimension perimeter for a geometry. This is still under consideration + + + + + + See Also + + + + + + + + ST_Perimeter3D + + Returns the 3-dimensional perimeter of the geometry, if it + is a polygon or multi-polygon. + + + + + + float ST_Perimeter3D + geometry geomA + + + + + + Description + + Returns the 3-dimensional perimeter of the geometry, if it + is a polygon or multi-polygon. If the geometry is 2-dimensional, then the 2-dimensional perimeter is returned. + + &Z_support; + + + + + Examples + Perimeter of a slightly elevated polygon in the air in Massachusetts state plane feet + SELECT ST_Perimeter3D(the_geom), ST_Perimeter2d(the_geom), ST_Perimeter(the_geom) FROM + (SELECT ST_GeomFromEWKT('SRID=2249;POLYGON((743238 2967416 2,743238 2967450 1, +743265.625 2967416 1,743238 2967416 2))') As the_geom) As foo; + + st_perimeter3d | st_perimeter2d | st_perimeter +------------------+------------------+------------------ + 105.465793597674 | 105.432997272188 | 105.432997272188 + + + + + + + See Also + + , , + + + + + + ST_PointOnSurface + + Returns a POINT guaranteed to lie on the surface. + + + + + + geometry ST_PointOnSurface + + geometry + g1 + + + + + + Description + + Returns a POINT guaranteed to intersect a surface. + + &sfs_compliant; s3.2.14.2 // s3.2.18.2 + &sqlmm_compliant; SQL-MM 3: 8.1.5, 9.5.6. + According to the specs, ST_PointOnSurface works for surface geometries (POLYGONs, MULTIPOLYGONS, CURVED POLYGONS). So PostGIS seems to be extending what + the spec allows here. Most databases Oracle,DB II, ESRI SDE seem to only support this function for surfaces. SQL Server 2008 like PostGIS supports for all common geometries. + &Z_support; + + + + Examples + + SELECT ST_AsText(ST_PointOnSurface('POINT(0 5)'::geometry)); + st_astext +------------ + POINT(0 5) +(1 row) + +SELECT ST_AsText(ST_PointOnSurface('LINESTRING(0 5, 0 10)'::geometry)); + st_astext +------------ + POINT(0 5) +(1 row) + +SELECT ST_AsText(ST_PointOnSurface('POLYGON((0 0, 0 5, 5 5, 5 0, 0 0))'::geometry)); + st_astext +---------------- + POINT(2.5 2.5) +(1 row) + +SELECT ST_AsEWKT(ST_PointOnSurface(ST_GeomFromEWKT('LINESTRING(0 5 1, 0 0 1, 0 10 2)'))); + st_asewkt +---------------- + POINT(0 0 1) +(1 row) + + + + + See Also + + , + + + + + + ST_Relate + + Returns true if this Geometry is spatially related to + anotherGeometry, by testing for intersections between the + Interior, Boundary and Exterior of the two geometries as specified + by the values in the intersectionMatrixPattern. If no intersectionMatrixPattern + is passed in, then returns the maximum intersectionMatrixPattern that relates the 2 geometries. + + + + + + boolean ST_Relate + geometry geomA + geometry geomB + text intersectionMatrixPattern + + + + text ST_Relate + geometry geomA + geometry geomB + + + + + + + Description + + Version 1: Takes geomA, geomB, intersectionMatrix and Returns 1 (TRUE) if this Geometry is spatially related to + anotherGeometry, by testing for intersections between the + Interior, Boundary and Exterior of the two geometries as specified + by the values in the intersectionMatrixPattern. + + This is especially useful for testing compound checks of intersection, crosses, etc in one step. + Do not call with a GeometryCollection as an argument + + This is the "allowable" version that returns a + boolean, not an integer. This is defined in OGC spec + + This DOES NOT automagically include an index call. The reason for that + is some relationships are anti e.g. Disjoint. If you are + using a relationship pattern that requires intersection, then include the && + index call. + + Version 2: Takes geomA and geomB and returns the DE-9IM (dimensionally extended nine-intersection + matrix) + + Do not call with a GeometryCollection as an argument + + not in OGC spec, but implied. see s2.1.13.2 + + Both Performed by the GEOS module + + &sfs_compliant; s2.1.1.2 // s2.1.13.3 + &sqlmm_compliant; SQL-MM 3: 5.1.25 + + + + + Examples + +--Find all compounds that intersect and not touch a poly (interior intersects) +SELECT l.* , b.name As poly_name +FROM polys As b + INNER JOIN compounds As l + ON (p.the_geom && b.the_geom + AND ST_Relate(l.the_geom, b.the_geom,'T********')); + +SELECT ST_Relate(ST_GeometryFromText('POINT(1 2)'), ST_Buffer(ST_GeometryFromText('POINT(1 2)'),2)); + st_relate +----------- + 0FFFFF212 + +SELECT ST_Relate(ST_GeometryFromText('LINESTRING(1 2, 3 4)'), ST_GeometryFromText('LINESTRING(5 6, 7 8)')); + st_relate +----------- + FF1FF0102 + + +SELECT ST_Relate(ST_GeometryFromText('POINT(1 2)'), ST_Buffer(ST_GeometryFromText('POINT(1 2)'),2), '0FFFFF212'); + st_relate +----------- + t + +SELECT ST_Relate(ST_GeometryFromText('POINT(1 2)'), ST_Buffer(ST_GeometryFromText('POINT(1 2)'),2), '*FF*FF212'); + st_relate +----------- + t + + + + + + See Also + + , , , + + + + + + ST_Touches + + Returns TRUE if the geometries have at least one point in common, + but their interiors do not intersect. + + + + + + boolean ST_Touches + + geometry + g1 + + geometry + g2 + + + + + + Description + + Returns TRUE if the only points in common between + g1 and g2 lie in the union of the + boundaries of g1 and g2. + The ST_Touches relation applies + to all Area/Area, Line/Line, Line/Area, Point/Area and Point/Line pairs of relationships, + but not to the Point/Point pair. + + In mathematical terms, this predicate is expressed as: + + TODO: Insert appropriate MathML markup here or use a gif. + Simple HTML markup does not work well in both IE and Firefox. + + + + + + + + + + The allowable DE-9IM Intersection Matrices for the two geometries are: + + + + FT******* + + + + F**T***** + + + + F***T**** + + + + + Do not call with a GEOMETRYCOLLECTION as an argument + + + + This function call will automatically include a bounding box + comparison that will make use of any indexes that are available on + the geometries. To avoid using an index, use _ST_Touches instead. + + + &sfs_compliant; s2.1.1.2 // s2.1.13.3 + &sqlmm_compliant; SQL-MM 3: 5.1.28 + + + + Examples + + The ST_Touches predicate returns TRUE in all the following illustrations. + + + + + + + + + + + POLYGON / POLYGON + + + + + + + + + + POLYGON / POLYGON + + + + + + + + + + POLYGON / LINESTRING + + + + + + + + + + + LINESTRING / LINESTRING + + + + + + + + + + LINESTRING / LINESTRING + + + + + + + + + + POLYGON / POINT + + + + + + + + SELECT ST_Touches('LINESTRING(0 0, 1 1, 0 2)'::geometry, 'POINT(1 1)'::geometry); + st_touches +------------ + f +(1 row) + +SELECT ST_Touches('LINESTRING(0 0, 1 1, 0 2)'::geometry, 'POINT(0 2)'::geometry); + st_touches +------------ + t +(1 row) + + + + + + ST_Within + + Returns true if the geometry A is completely inside geometry B + + + + + + boolean ST_Within + + geometry + A + + geometry + B + + + + + + Description + + Returns TRUE if geometry A is completely inside geometry B. For this function to make + sense, the source geometries must both be of the same coordinate projection, + having the same SRID. It is a given that if ST_Within(A,B) is true and ST_Within(B,A) is true, then + the two geometries are considered spatially equal. + + Performed by the GEOS module + + + Do not call with a GEOMETRYCOLLECTION as an argument + + + + Do not use this function with invalid geometries. You will get unexpected results. + + + This function call will automatically include a bounding box + comparison that will make use of any indexes that are available on + the geometries. To avoid index use, use the function + _ST_Within. + + NOTE: this is the "allowable" version that returns a + boolean, not an integer. + + &sfs_compliant; s2.1.1.2 // s2.1.13.3 + - a.Relate(b, 'T*F**F***') + + &sqlmm_compliant; SQL-MM 3: 5.1.30 + + + + Examples + +--a circle within a circle +SELECT ST_Within(smallc,smallc) As smallinsmall, + ST_Within(smallc, bigc) As smallinbig, + ST_Within(bigc,smallc) As biginsmall, + ST_Within(ST_Union(smallc, bigc), bigc) as unioninbig, + ST_Within(bigc, ST_Union(smallc, bigc)) as biginunion, + ST_Equals(bigc, ST_Union(smallc, bigc)) as bigisunion +FROM +( +SELECT ST_Buffer(ST_GeomFromText('POINT(50 50)'), 20) As smallc, + ST_Buffer(ST_GeomFromText('POINT(50 50)'), 40) As bigc) As foo; +--Result + smallinsmall | smallinbig | biginsmall | unioninbig | biginunion | bigisunion +--------------+------------+------------+------------+------------+------------ + t | t | f | t | t | t +(1 row) + + + + + + + + + + + See Also + , , + + + diff --git a/doc/reference_misc.xml b/doc/reference_misc.xml new file mode 100644 index 000000000..52fe55766 --- /dev/null +++ b/doc/reference_misc.xml @@ -0,0 +1,1018 @@ + + + Miscellaneous Functions + + + + ST_Accum + + Aggregate. Constructs an array of geometries. + + + + + + geometry[] ST_Accum + geometry set geomfield + + + + + + Description + + Aggregate. Constructs an array of geometries. + &Z_support; + &curve_support; + + + + + Examples + + SELECT (ST_Accum(the_geom)) As all_em, ST_AsText((ST_Accum(the_geom))[1]) As grabone, +(ST_Accum(the_geom))[2:4] as grab_rest + FROM (SELECT ST_MakePoint(a*CAST(random()*10 As integer), a*CAST(random()*10 As integer), a*CAST(random()*10 As integer)) As the_geom + FROM generate_series(1,4) a) As foo; + +all_em|grabone | grab_rest + +-------------------------------------------------------------------------------+ + + {0101000080000000000000144000000000000024400000000000001040: + 0101000080000000000 +00018400000000000002C400000000000003040: +0101000080000000000000354000000000000038400000000000001840: +010100008000000000000040400000000000003C400000000000003040} | + POINT(5 10) | {010100008000000000000018400000000000002C400000000000003040: + 0101000080000000000000354000000000000038400000000000001840: + 010100008000000000000040400000000000003C400000000000003040} +(1 row) + + + + + + See Also + + + + + + + + Box2D + + Returns a BOX2D representing the maximum extents of the geometry. + + + + + + box2d Box2D + geometry geomA + + + + + + Description + + Returns a BOX2D representing the maximum extents of the geometry. + &curve_support; + + + + + Examples + + SELECT Box2D(ST_GeomFromText('LINESTRING(1 2, 3 4, 5 6)')); + box2d + --------- + BOX(1 2,5 6) + + SELECT Box2D(ST_GeomFromText('CIRCULARSTRING(220268 150415,220227 150505,220227 150406)')); + box2d + -------- + BOX(220186.984375 150406,220288.25 150506.140625) + + + + + + See Also + + , + + + + + + Box3D + + Returns a BOX3D representing the maximum extents of the geometry. + + + + + + box3d Box3D + geometry geomA + + + + + + Description + + Returns a BOX3D representing the maximum extents of the geometry. + &Z_support; + &curve_support; + + + + + Examples + + SELECT Box3D(ST_GeomFromEWKT('LINESTRING(1 2 3, 3 4 5, 5 6 5)')); + box3d + --------- + BOX3D(1 2 3,5 6 5) + + SELECT Box3D(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 1,220227 150406 1)')); + box3d + -------- + BOX3D(220227 150406 1,220268 150415 1) + + + + + + See Also + + , + + + + + + ST_Estimated_Extent + + Return the 'estimated' extent of the given spatial table. + The estimated is taken from the geometry column's statistics. The + current schema will be used if not specified. + + + + + + box2d ST_Estimated_Extent + text schema_name + text table_name + text geocolumn_name + + + + box2d ST_Estimated_Extent + text table_name + text geocolumn_name + + + + + + Description + + Return the 'estimated' extent of the given spatial table. + The estimated is taken from the geometry column's statistics. The + current schema will be used if not specified. + + For PostgreSQL>=8.0.0 statistics are gathered by VACUUM + ANALYZE and resulting extent will be about 95% of the real + one. + + For PostgreSQL<8.0.0 statistics are gathered by + update_geometry_stats() and resulting extent will be exact. + + &curve_support; + + + + + Examples + + SELECT ST_Estimated_extent('ny', 'edges', 'the_geom'); +--result-- +BOX(-8877653 4912316,-8010225.5 5589284) + +SELECT ST_Estimated_Extent('feature_poly', 'the_geom'); +--result-- +BOX(-124.659652709961 24.6830825805664,-67.7798080444336 49.0012092590332) + + + + + + See Also + + + + + + + ST_Expand + Returns bounding box expanded in all directions from the bounding box of the input geometry + + + + + + geometry ST_Expand + geometry g1 + float units_to_expand + + + + box2d ST_Expand + box2d g1 + float units_to_expand + + + + box3d ST_Expand + box3d g1 + float units_to_expand + + + + + + Description + + This function returns a bounding box expanded in all + directions from the bounding box of the input geometry, by an + amount specified in the second argument. Very useful for + distance() queries, or bounding box queries to add an index filter to the query. + There are 3 variants of this. The one that takes a geometry will return a POLYGON geometry representation + of the bounding box and is the most commonly used variant. + ST_Expand is similar in concept to ST_Buffer except while buffer expands the geometry in all directions, + ST_Expand expands the bounding box an x,y,z unit amount. + Units are in the units of the spatial reference system in use denoted by the SRID + + + Pre 1.3, ST_Expand was used in conjunction with distance to do indexable queries. Something of the form + the_geom && ST_Expand('POINT(10 20)', 10) AND ST_Distance(the_geom, 'POINT(10 20)') < 10 + Post 1.2, this was replaced with the easier ST_DWithin construct. + + + + Bounding boxes of all geometries are currently 2-d even if they are 3-dimensional geometries. + + + + + + Examples + Examples below use US National Atlas Equal Area (SRID=2163) which is a meter projection + +--10 meter expanded box around bbox of a linestring +SELECT CAST(ST_Expand(ST_GeomFromText('LINESTRING(2312980 110676,2312923 110701,2312892 110714)', 2163),10) As box2d); + st_expand +------------------------------------ + BOX(2312882 110666,2312990 110724) + +--10 meter expanded 3d box of a 3d box +SELECT ST_Expand(CAST('BOX3D(778783 2951741 1,794875 2970042.61545891 10)' As box3d),10) + st_expand +----------------------------------------------------- + BOX3D(778773 2951731 -9,794885 2970052.61545891 20) + + --10 meter geometry astext rep of a expand box around a point geometry + SELECT ST_AsEWKT(ST_Expand(ST_GeomFromEWKT('SRID=2163;POINT(2312980 110676)'),10)); + st_asewkt +------------------------------------------------------------------------------------------------- + SRID=2163;POLYGON((2312970 110666,2312970 110686,2312990 110686,2312990 110666,2312970 110666)) + + + + + + See Also + , , , ,, + + + + + + ST_Extent + an aggregate function that returns the bounding box that bounds rows of geometries. + + + + + + box2d ST_Extent + geometry set geomfield + + + + + + Description + + ST_Extent returns a bounding box that encloses a set of geometries. The ST_Extent function is an "aggregate" function in the + terminology of SQL. That means that it operates on lists + of data, in the same way the SUM() and AVG() functions do. + Since it returns a bounding box, the spatial Units are in the units of the spatial reference system in use denoted by the SRID + ST_Extent is similar in concept to Oracle Spatial/Locator's SDO_AGGR_MBR + + Since ST_Extent returns a bounding box, the SRID meta-data is lost. Use ST_SetSRID to force it back into + a geometry with SRID meta data. The coordinates are in the units of the spatial ref of the orginal geometries. + + + + Bounding boxes of all geometries are currently 2-d even if they are 3-dimensional geometries. + + + + + + Examples + Examples below use Massachusetts State Plane ft (SRID=2249) + + +SELECT ST_Extent(the_geom) as bextent FROM sometable; + st_bextent +------------------------------------ +BOX(739651.875 2908247.25,794875.8125 2970042.75) + + +--Return extent of each category of geometries +SELECT ST_Extent(the_geom) as bextent +FROM sometable +GROUP BY category ORDER BY category; + + bextent | name +----------------------------------------------------+---------------- + BOX(778783.5625 2951741.25,794875.8125 2970042.75) | A + BOX(751315.8125 2919164.75,765202.6875 2935417.25) | B + BOX(739651.875 2917394.75,756688.375 2935866) | C + + --Force back into a geometry + -- and render the extended text representation of that geometry +SELECT ST_SetSRID(ST_Extent(the_geom),2249) as bextent FROM sometable; + + bextent +-------------------------------------------------------------------------------- + SRID=2249;POLYGON((739651.875 2908247.25,739651.875 2970042.75,794875.8125 2970042.75, + 794875.8125 2908247.25,739651.875 2908247.25)) + + + + + See Also + , , + + + + + + ST_Extent3D + an aggregate function that returns the box3D bounding box that bounds rows of geometries. + + + + + + box3d ST_Extent3D + geometry set geomfield + + + + + + Description + + ST_Extent3D returns a box3d (includes Z coordinate) bounding box that encloses a set of geometries. The ST_Extent3D function is an "aggregate" function in the + terminology of SQL. That means that it operates on lists + of data, in the same way the SUM() and AVG() functions do. + Since it returns a bounding box, the spatial Units are in the units of the spatial reference system in use denoted by the SRID + + + Since ST_Extent3D returns a bounding box, the SRID meta-data is lost. Use ST_SetSRID to force it back into + a geometry with SRID meta data. The coordinates are in the units of the spatial ref of the orginal geometries. + + + &Z_support; + &curve_support; + + + + Examples + +SELECT ST_Extent3D(foo.the_geom) As b3extent +FROM (SELECT ST_MakePoint(x,y,z) As the_geom + FROM generate_series(1,3) As x + CROSS JOIN generate_series(1,2) As y + CROSS JOIN generate_series(0,2) As Z) As foo; + b3extent +-------------------- + BOX3D(1 1 0,3 2 2) + +--Get the extent of various elevated circular strings +SELECT ST_Extent3D(foo.the_geom) As b3extent +FROM (SELECT ST_Translate(ST_Force_3DZ(ST_LineToCurve(ST_Buffer(ST_MakePoint(x,y),1))),0,0,z) As the_geom + FROM generate_series(1,3) As x + CROSS JOIN generate_series(1,2) As y + CROSS JOIN generate_series(0,2) As Z) As foo; + + b3extent +-------------------- + BOX3D(1 0 0,4 2 2) + + + + + See Also + , + + + + + + + Find_SRID + + The syntax is find_srid(<db/schema>, <table>, + <column>) and the function returns the integer SRID of the + specified column by searching through the GEOMETRY_COLUMNS table. + + + + + + integer Find_SRID + varchar a_schema_name + varchar a_table_name + varchar a_geomfield_name + + + + + + Description + + The syntax is find_srid(<db/schema>, <table>, + <column>) and the function returns the integer SRID of the + specified column by searching through the GEOMETRY_COLUMNS table. + If the geometry column has not been properly added with the + AddGeometryColumns() function, this function will not work + either. + + + + + Examples + + SELECT Find_SRID('public', 'tiger_us_state_2007', 'the_geom_4269'); +find_srid +---------- +4269 + + + + + + See Also + + + + + + + + ST_Mem_Size + + Returns the amount of space (in bytes) the geometry takes. + + + + + + integer ST_Mem_Size + geometry geomA + + + + + + Description + + Returns the amount of space (in bytes) the geometry takes. + This is a nice compliment to PostgreSQL built in functions pg_size_pretty, pg_relation_size, pg_total_relation_size. + pg_relation_size which gives the byte size of a table may return byte size lower than ST_Mem_Size. This is because + pg_relation_size does not add toasted table contribution and large geometries are stored in TOAST tables. + pg_total_relation_size - includes, the table, the toasted tables, and the indexes. + + + &Z_support; + &curve_support; + + + + + Examples + + +--Return how much byte space Boston takes up in our Mass data set +SELECT pg_size_pretty(SUM(ST_Mem_Size(the_geom))) as totgeomsum, +pg_size_pretty(SUM(CASE WHEN town = 'BOSTON' THEN st_mem_size(the_geom) ELSE 0 END)) As bossum, +CAST(SUM(CASE WHEN town = 'BOSTON' THEN st_mem_size(the_geom) ELSE 0 END)*1.00 / + SUM(st_mem_size(the_geom))*100 As numeric(10,2)) As perbos +FROM towns; + +totgeomsum bossum perbos +---------- ------ ------ +1522 kB 30 kB 1.99 + + +SELECT ST_Mem_Size(ST_GeomFromText('CIRCULARSTRING(220268 150415,220227 150505,220227 150406)')); + +--- +73 + +--What percentage of our table is taken up by just the geometry +SELECT pg_total_relation_size('public.neighborhoods') As fulltable_size, sum(ST_Mem_Size(the_geom)) As geomsize, +sum(ST_Mem_Size(the_geom))*1.00/pg_total_relation_size('public.neighborhoods')*100 As pergeom +FROM neighborhoods; +fulltable_size geomsize pergeom +------------------------------------------------ +262144 96238 36.71188354492187500000 + + + + + + See Also + + + + + + + + ST_Point_Inside_Circle + + Is the point geometry insert circle defined by center_x, center_y , radius + + + + + + boolean ST_Point_Inside_Circle + geometry a_point + float center_x + float center_y + float radius + + + + + + Description + + The syntax for this functions is + point_inside_circle(<geometry>,<circle_center_x>,<circle_center_y>,<radius>). + Returns the true if the geometry is a point and is inside the + circle. Returns false otherwise. + This only works for points as the name suggests + + + + + Examples + + SELECT ST_Point_Inside_Circle(ST_Point(1,2), 0.5, 2, 3); + st_point_inside_circle +------------------------ + t + + + + + + See Also + + + + + + + + ST_XMax + + Returns X maxima of a bounding box 2d or 3d or a geometry. + + + + + + float ST_XMax + box3d aGeomorBox2DorBox3D + + + + + + Description + + Returns X maxima of a bounding box 2d or 3d or a geometry. + + + Although this function is only defined for box3d, it will work for box2d and geometry because of the auto-casting behavior + defined for geometries and box2d. However you can not feed it a geometry or box2d text represenation, since that will not auto-cast. + + + &Z_support; + &curve_support; + + + + + Examples + + SELECT ST_XMax('BOX3D(1 2 3, 4 5 6)'); +st_xmax +------- +4 + +SELECT ST_XMax(ST_GeomFromText('LINESTRING(1 3 4, 5 6 7)')); +st_xmax +------- +5 + +SELECT ST_XMax(CAST('BOX(-3 2, 3 4)' As box2d)); +st_xmax +------- +3 +--Observe THIS DOES NOT WORK because it will try to autocast the string representation to a BOX3D +SELECT ST_XMax('LINESTRING(1 3, 5 6)'); + +--ERROR: BOX3D parser - doesnt start with BOX3D( + +SELECT ST_XMax(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)')); +st_xmax +-------- +220288.248780547 + + + + + + See Also + + , , , , + + + + + + ST_XMin + + Returns X minima of a bounding box 2d or 3d or a geometry. + + + + + + float ST_XMin + box3d aGeomorBox2DorBox3D + + + + + + Description + + Returns X minima of a bounding box 2d or 3d or a geometry. + + + Although this function is only defined for box3d, it will work for box2d and geometry because of the auto-casting behavior + defined for geometries and box2d. However you can not feed it a geometry or box2d text represenation, since that will not auto-cast. + + + &Z_support; + &curve_support; + + + + + Examples + + SELECT ST_XMin('BOX3D(1 2 3, 4 5 6)'); +st_xmin +------- +1 + +SELECT ST_XMin(ST_GeomFromText('LINESTRING(1 3 4, 5 6 7)')); +st_xmin +------- +1 + +SELECT ST_XMin(CAST('BOX(-3 2, 3 4)' As box2d)); +st_xmin +------- +-3 +--Observe THIS DOES NOT WORK because it will try to autocast the string representation to a BOX3D +SELECT ST_XMin('LINESTRING(1 3, 5 6)'); + +--ERROR: BOX3D parser - doesnt start with BOX3D( + +SELECT ST_XMin(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)')); +st_xmin +-------- +220186.995121892 + + + + + + See Also + + , , , , + + + + + + ST_YMax + + Returns Y maxima of a bounding box 2d or 3d or a geometry. + + + + + + float ST_YMax + box3d aGeomorBox2DorBox3D + + + + + + Description + + Returns Y maxima of a bounding box 2d or 3d or a geometry. + + + Although this function is only defined for box3d, it will work for box2d and geometry because of the auto-casting behavior + defined for geometries and box2d. However you can not feed it a geometry or box2d text represenation, since that will not auto-cast. + + + &Z_support; + &curve_support; + + + + + Examples + + SELECT ST_YMax('BOX3D(1 2 3, 4 5 6)'); +st_ymax +------- +5 + +SELECT ST_YMax(ST_GeomFromText('LINESTRING(1 3 4, 5 6 7)')); +st_ymax +------- +6 + +SELECT ST_YMax(CAST('BOX(-3 2, 3 4)' As box2d)); +st_ymax +------- +4 +--Observe THIS DOES NOT WORK because it will try to autocast the string representation to a BOX3D +SELECT ST_YMax('LINESTRING(1 3, 5 6)'); + +--ERROR: BOX3D parser - doesnt start with BOX3D( + +SELECT ST_YMax(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)')); +st_ymax +-------- +150506.126829327 + + + + + + See Also + + , , , , + + + + + + ST_YMin + + Returns Y minima of a bounding box 2d or 3d or a geometry. + + + + + + float ST_YMin + box3d aGeomorBox2DorBox3D + + + + + + Description + + Returns Y minima of a bounding box 2d or 3d or a geometry. + + + Although this function is only defined for box3d, it will work for box2d and geometry because of the auto-casting behavior + defined for geometries and box2d. However you can not feed it a geometry or box2d text represenation, since that will not auto-cast. + + + &Z_support; + &curve_support; + + + + + Examples + + SELECT ST_YMin('BOX3D(1 2 3, 4 5 6)'); +st_ymin +------- +2 + +SELECT ST_YMin(ST_GeomFromText('LINESTRING(1 3 4, 5 6 7)')); +st_ymin +------- +3 + +SELECT ST_YMin(CAST('BOX(-3 2, 3 4)' As box2d)); +st_ymin +------- +2 +--Observe THIS DOES NOT WORK because it will try to autocast the string representation to a BOX3D +SELECT ST_YMin('LINESTRING(1 3, 5 6)'); + +--ERROR: BOX3D parser - doesnt start with BOX3D( + +SELECT ST_YMin(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)')); +st_ymin +-------- +150406 + + + + + + See Also + + , , , , , + + + + + + ST_ZMax + + Returns Z minima of a bounding box 2d or 3d or a geometry. + + + + + + float ST_ZMax + box3d aGeomorBox2DorBox3D + + + + + + Description + + Returns Z maxima of a bounding box 2d or 3d or a geometry. + + + Although this function is only defined for box3d, it will work for box2d and geometry because of the auto-casting behavior + defined for geometries and box2d. However you can not feed it a geometry or box2d text represenation, since that will not auto-cast. + + + &Z_support; + &curve_support; + + + + + Examples + + SELECT ST_ZMax('BOX3D(1 2 3, 4 5 6)'); +st_zmax +------- +6 + +SELECT ST_ZMax(ST_GeomFromEWKT('LINESTRING(1 3 4, 5 6 7)')); +st_zmax +------- +7 + +SELECT ST_ZMax('BOX3D(-3 2 1, 3 4 1)' ); +st_zmax +------- +1 +--Observe THIS DOES NOT WORK because it will try to autocast the string representation to a BOX3D +SELECT ST_ZMax('LINESTRING(1 3 4, 5 6 7)'); + +--ERROR: BOX3D parser - doesnt start with BOX3D( + +SELECT ST_ZMax(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)')); +st_zmax +-------- +3 + + + + + + See Also + + , , , , , + + + + + + ST_ZMin + + Returns Z minima of a bounding box 2d or 3d or a geometry. + + + + + + float ST_ZMin + box3d aGeomorBox2DorBox3D + + + + + + Description + + Returns Z minima of a bounding box 2d or 3d or a geometry. + + + Although this function is only defined for box3d, it will work for box2d and geometry because of the auto-casting behavior + defined for geometries and box2d. However you can not feed it a geometry or box2d text represenation, since that will not auto-cast. + + + &Z_support; + &curve_support; + + + + + Examples + + SELECT ST_ZMin('BOX3D(1 2 3, 4 5 6)'); +st_zmin +------- +3 + +SELECT ST_ZMin(ST_GeomFromEWKT('LINESTRING(1 3 4, 5 6 7)')); +st_zmin +------- +4 + +SELECT ST_ZMin('BOX3D(-3 2 1, 3 4 1)' ); +st_zmin +------- +1 +--Observe THIS DOES NOT WORK because it will try to autocast the string representation to a BOX3D +SELECT ST_ZMin('LINESTRING(1 3 4, 5 6 7)'); + +--ERROR: BOX3D parser - doesnt start with BOX3D( + +SELECT ST_ZMin(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)')); +st_zmin +-------- +1 + + + + + + See Also + + , , , , , , + + + + diff --git a/doc/reference_operator.xml b/doc/reference_operator.xml new file mode 100644 index 000000000..4911a7304 --- /dev/null +++ b/doc/reference_operator.xml @@ -0,0 +1,957 @@ + + + Operators + + + && + + Returns TRUE if A's bounding box overlaps B's. + + + + + + + boolean && + + + geometry + + A + + + + geometry + + B + + + + boolean && + + + geography + + A + + + + geography + + B + + + + + + + Description + + The && operator returns TRUE if the bounding box of geometry A overlaps the bounding box of geometry B. + + This operand will make use of any indexes that may be available on the + geometries. + + Availability: 1.5.0 support for geography was introduced. + + + + Examples + + SELECT tbl1.column1, tbl2.column1, tbl1.column2 && tbl2.column2 AS overlaps +FROM ( VALUES + (1, 'LINESTRING(0 0, 3 3)'::geometry), + (2, 'LINESTRING(0 1, 0 5)'::geometry)) AS tbl1, +( VALUES + (3, 'LINESTRING(1 2, 4 6)'::geometry)) AS tbl2; + + column1 | column1 | overlaps +---------+---------+---------- + 1 | 3 | t + 2 | 3 | f +(2 rows) + + + + + See Also + + + , + , + , + , + , + + + + + + + &< + + Returns TRUE if A's bounding box overlaps or is to the left of B's. + + + + + + + boolean &< + + + geometry + + A + + + + geometry + + B + + + + + + + Description + + The &< operator returns TRUE if the bounding box of geometry A + overlaps or is to the left of the bounding box of geometry B, or more accurately, overlaps or is NOT to the right + of the bounding box of geometry B. + + This operand will make use of any indexes that may be available on the + geometries. + + + + Examples + + SELECT tbl1.column1, tbl2.column1, tbl1.column2 &< tbl2.column2 AS overleft +FROM + ( VALUES + (1, 'LINESTRING(1 2, 4 6)'::geometry)) AS tbl1, + ( VALUES + (2, 'LINESTRING(0 0, 3 3)'::geometry), + (3, 'LINESTRING(0 1, 0 5)'::geometry), + (4, 'LINESTRING(6 0, 6 1)'::geometry)) AS tbl2; + + column1 | column1 | overleft +---------+---------+---------- + 1 | 2 | f + 1 | 3 | f + 1 | 4 | t +(3 rows) + + + + See Also + + + , + , + , + + + + + + + &<| + + Returns TRUE if A's bounding box overlaps or is below B's. + + + + + + + boolean &<| + + + geometry + + A + + + + geometry + + B + + + + + + + Description + + The &<| operator returns TRUE if the bounding box of geometry A + overlaps or is below of the bounding box of geometry B, or more accurately, overlaps or is NOT above the bounding + box of geometry B. + + This operand will make use of any indexes that may be available on the + geometries. + + + + Examples + + SELECT tbl1.column1, tbl2.column1, tbl1.column2 &<| tbl2.column2 AS overbelow +FROM + ( VALUES + (1, 'LINESTRING(6 0, 6 4)'::geometry)) AS tbl1, + ( VALUES + (2, 'LINESTRING(0 0, 3 3)'::geometry), + (3, 'LINESTRING(0 1, 0 5)'::geometry), + (4, 'LINESTRING(1 2, 4 6)'::geometry)) AS tbl2; + + column1 | column1 | overbelow +---------+---------+----------- + 1 | 2 | f + 1 | 3 | t + 1 | 4 | t +(3 rows) + + + + See Also + + + , + , + , + + + + + + + &> + + Returns TRUE if A' bounding box overlaps or is to the right of B's. + + + + + + + boolean &> + + + geometry + + A + + + + geometry + + B + + + + + + + Description + + The &> operator returns TRUE if the bounding box of geometry A + overlaps or is to the right of the bounding box of geometry B, or more accurately, overlaps or is NOT to the left + of the bounding box of geometry B. + + This operand will make use of any indexes that may be available on the + geometries. + + + + Examples + + SELECT tbl1.column1, tbl2.column1, tbl1.column2 &> tbl2.column2 AS overright +FROM + ( VALUES + (1, 'LINESTRING(1 2, 4 6)'::geometry)) AS tbl1, + ( VALUES + (2, 'LINESTRING(0 0, 3 3)'::geometry), + (3, 'LINESTRING(0 1, 0 5)'::geometry), + (4, 'LINESTRING(6 0, 6 1)'::geometry)) AS tbl2; + + column1 | column1 | overright +---------+---------+----------- + 1 | 2 | t + 1 | 3 | t + 1 | 4 | f +(3 rows) + + + + See Also + + + , + , + , + + + + + + + << + + Returns TRUE if A's bounding box is strictly to the left of B's. + + + + + + + boolean << + + + geometry + + A + + + + geometry + + B + + + + + + + Description + + The << operator returns TRUE if the bounding box of geometry A + is strictly to the left of the bounding box of geometry B. + + This operand will make use of any indexes that may be available on the + geometries. + + + + Examples + + SELECT tbl1.column1, tbl2.column1, tbl1.column2 << tbl2.column2 AS left +FROM + ( VALUES + (1, 'LINESTRING (1 2, 1 5)'::geometry)) AS tbl1, + ( VALUES + (2, 'LINESTRING (0 0, 4 3)'::geometry), + (3, 'LINESTRING (6 0, 6 5)'::geometry), + (4, 'LINESTRING (2 2, 5 6)'::geometry)) AS tbl2; + + column1 | column1 | left +---------+---------+------ + 1 | 2 | f + 1 | 3 | t + 1 | 4 | t +(3 rows) + + + + See Also + + , , + + + + + + <<| + + Returns TRUE if A's bounding box is strictly below B's. + + + + + + + boolean <<| + + + geometry + + A + + + + geometry + + B + + + + + + + Description + + The <<| operator returns TRUE if the bounding box of geometry A + is strictly below the bounding box of geometry B. + + This operand will make use of any indexes that may be available on the + geometries. + + + + Examples + + SELECT tbl1.column1, tbl2.column1, tbl1.column2 <<| tbl2.column2 AS below +FROM + ( VALUES + (1, 'LINESTRING (0 0, 4 3)'::geometry)) AS tbl1, + ( VALUES + (2, 'LINESTRING (1 4, 1 7)'::geometry), + (3, 'LINESTRING (6 1, 6 5)'::geometry), + (4, 'LINESTRING (2 3, 5 6)'::geometry)) AS tbl2; + + column1 | column1 | below +---------+---------+------- + 1 | 2 | t + 1 | 3 | f + 1 | 4 | f +(3 rows) + + + + See Also + + , , + + + + + + = + + Returns TRUE if A's bounding box is the same as B's. + + + + + + + boolean = + + + geometry + + A + + + + geometry + + B + + + + + + + Description + + The = operator returns TRUE if the bounding box of geometry A + is the same as the bounding box of geometry B. PostgreSQL uses the =, <, and > operators defined for geometries to + perform internal orderings and comparison of geometries (ie. in a GROUP BY or ORDER BY clause). + + + This is cause for a lot of confusion. When you compare geometryA = + geometryB it will return true even when the geometries are clearly + different IF their bounding boxes are the same. To check for true + equality use or + + + This operand will NOT make use of any indexes that may be available on the + geometries. + + + + + Examples + + SELECT 'LINESTRING(0 0, 0 1, 1 0)'::geometry = 'LINESTRING(1 1, 0 0)'::geometry; + ?column? +---------- + t +(1 row) + +SELECT ST_AsText(column1) +FROM ( VALUES + ('LINESTRING(0 0, 1 1)'::geometry), + ('LINESTRING(1 1, 0 0)'::geometry)) AS foo; + st_astext +--------------------- + LINESTRING(0 0,1 1) + LINESTRING(1 1,0 0) +(2 rows) + +-- Note: the GROUP BY uses the "=" to compare for geometry equivalency. +SELECT ST_AsText(column1) +FROM ( VALUES + ('LINESTRING(0 0, 1 1)'::geometry), + ('LINESTRING(1 1, 0 0)'::geometry)) AS foo +GROUP BY column1; + st_astext +--------------------- + LINESTRING(0 0,1 1) +(1 row) + + + + See Also + + , , + + + + + + + >> + + Returns TRUE if A's bounding box is strictly to the right of B's. + + + + + + + boolean >> + + + geometry + + A + + + + geometry + + B + + + + + + + Description + + The >> operator returns TRUE if the bounding box of geometry A + is strictly to the right of the bounding box of geometry B. + + This operand will make use of any indexes that may be available on the + geometries. + + + + Examples + + SELECT tbl1.column1, tbl2.column1, tbl1.column2 >> tbl2.column2 AS right +FROM + ( VALUES + (1, 'LINESTRING (2 3, 5 6)'::geometry)) AS tbl1, + ( VALUES + (2, 'LINESTRING (1 4, 1 7)'::geometry), + (3, 'LINESTRING (6 1, 6 5)'::geometry), + (4, 'LINESTRING (0 0, 4 3)'::geometry)) AS tbl2; + + column1 | column1 | right +---------+---------+------- + 1 | 2 | t + 1 | 3 | f + 1 | 4 | f +(3 rows) + + + + See Also + + , , + + + + + + @ + + Returns TRUE if A's bounding box is contained by B's. + + + + + + + boolean ~= + + + geometry + + A + + + + geometry + + B + + + + + + + Description + + The @ operator returns TRUE if the bounding box of geometry A is completely + contained by the bounding box of geometry B. + + + This operand will make use of any indexes that may be available on the + geometries. + + + + + Examples + + SELECT tbl1.column1, tbl2.column1, tbl1.column2 @ tbl2.column2 AS contained +FROM + ( VALUES + (1, 'LINESTRING (1 1, 3 3)'::geometry)) AS tbl1, + ( VALUES + (2, 'LINESTRING (0 0, 4 4)'::geometry), + (3, 'LINESTRING (2 2, 4 4)'::geometry), + (4, 'LINESTRING (1 1, 3 3)'::geometry)) AS tbl2; + + column1 | column1 | contained +---------+---------+----------- + 1 | 2 | t + 1 | 3 | f + 1 | 4 | t +(3 rows) + + + + See Also + + , + + + + + + |&> + + Returns TRUE if A's bounding box overlaps or is above B's. + + + + + + + boolean |&> + + + geometry + + A + + + + geometry + + B + + + + + + + Description + + The |&> operator returns TRUE if the bounding box of geometry A + overlaps or is above the bounding box of geometry B, or more accurately, overlaps or is NOT below + the bounding box of geometry B. + + This operand will make use of any indexes that may be available on the + geometries. + + + + Examples + + SELECT tbl1.column1, tbl2.column1, tbl1.column2 |&> tbl2.column2 AS overabove +FROM + ( VALUES + (1, 'LINESTRING(6 0, 6 4)'::geometry)) AS tbl1, + ( VALUES + (2, 'LINESTRING(0 0, 3 3)'::geometry), + (3, 'LINESTRING(0 1, 0 5)'::geometry), + (4, 'LINESTRING(1 2, 4 6)'::geometry)) AS tbl2; + + column1 | column1 | overabove +---------+---------+----------- + 1 | 2 | t + 1 | 3 | f + 1 | 4 | f +(3 rows) + + + + See Also + + + , + , + , + + + + + + + |>> + + Returns TRUE if A's bounding box is strictly above B's. + + + + + + + boolean |>> + + + geometry + + A + + + + geometry + + B + + + + + + + Description + + The |>> operator returns TRUE if the bounding box of geometry A + is strictly to the right of the bounding box of geometry B. + + This operand will make use of any indexes that may be available on the + geometries. + + + + Examples + + SELECT tbl1.column1, tbl2.column1, tbl1.column2 |>> tbl2.column2 AS above +FROM + ( VALUES + (1, 'LINESTRING (1 4, 1 7)'::geometry)) AS tbl1, + ( VALUES + (2, 'LINESTRING (0 0, 4 2)'::geometry), + (3, 'LINESTRING (6 1, 6 5)'::geometry), + (4, 'LINESTRING (2 3, 5 6)'::geometry)) AS tbl2; + + column1 | column1 | above +---------+---------+------- + 1 | 2 | t + 1 | 3 | f + 1 | 4 | f +(3 rows) + + + + See Also + + , , + + + + + + ~ + + Returns TRUE if A's bounding box contains B's. + + + + + + + boolean ~ + + + geometry + + A + + + + geometry + + B + + + + + + + Description + + The ~ operator returns TRUE if the bounding box of geometry A completely + contains the bounding box of geometry B. + + This operand will make use of any indexes that may be available on the + geometries. + + + + Examples + + SELECT tbl1.column1, tbl2.column1, tbl1.column2 ~ tbl2.column2 AS contains +FROM + ( VALUES + (1, 'LINESTRING (0 0, 3 3)'::geometry)) AS tbl1, + ( VALUES + (2, 'LINESTRING (0 0, 4 4)'::geometry), + (3, 'LINESTRING (1 1, 2 2)'::geometry), + (4, 'LINESTRING (0 0, 3 3)'::geometry)) AS tbl2; + + column1 | column1 | contains +---------+---------+---------- + 1 | 2 | f + 1 | 3 | t + 1 | 4 | t +(3 rows) + + + + See Also + + , + + + + + + ~= + + Returns TRUE if the geometry A is the same as B. + + + + + + + boolean ~= + + + geometry + + A + + + + geometry + + B + + + + boolean ~= + + + geography + + A + + + + geography + + B + + + + + + + Description + + The ~= operator returns TRUE if geometry A is the same as geometry B. + It tests actual geometric equality of two features. So if A and B are the same feature, vertex-by-vertex, the + operator returns TRUE. + + This operand will make use of any indexes that may be available on the + geometries. + + Availability: 1.5.0 support for geography was introduced. + + + + Examples + + SELECT tbl1.column1, tbl2.column1, tbl1.column2 ~= tbl2.column2 AS same +FROM + ( VALUES + (1, 'LINESTRING (0 0, 2 2)'::geometry)) AS tbl1, + ( VALUES + (2, 'LINESTRING (0 0, 1 1, 2 2)'::geometry), + (3, 'LINESTRING (2 2, 0 0)'::geometry), + (4, 'LINESTRING (0 0, 2 2)'::geometry)) AS tbl2; + + column1 | column1 | same +---------+---------+------ + 1 | 2 | f + 1 | 3 | f + 1 | 4 | t +(3 rows) + + + + See Also + + , , + + + + diff --git a/doc/reference_output.xml b/doc/reference_output.xml new file mode 100644 index 000000000..b17682b12 --- /dev/null +++ b/doc/reference_output.xml @@ -0,0 +1,842 @@ + + + + Geometry Outputs + + + ST_AsBinary + Return the Well-Known Binary (WKB) representation of the geometry/geography without SRID meta data. + + + + + + bytea ST_AsBinary + geometry g1 + + + bytea ST_AsBinary + geography g1 + + + bytea ST_AsBinary + geometry g1 + text NDR_or_XDR + + + + + + Description + + Returns the Well-Known Binary representation of the geometry. There are 2 variants of the function. The first + variant takes no endian encoding paramater and defaults to little endian. The second variant takes a second argument + denoting the encoding - using little-endian ('NDR') or big-endian ('XDR') encoding. + This is useful in binary cursors to pull data out of the + database without converting it to a string representation. + + + The WKB spec does not include the SRID. To get the OGC WKB with SRID format use ST_AsEWKB + + + ST_AsBinary is the reverse of for geometry. Use to convert to a postgis geometry from ST_AsBinary representation. + + + Availability: 1.5.0 geography support was introduced. + &sfs_compliant; s2.1.1.1 + &sqlmm_compliant; SQL-MM 3: 5.1.37 + + + + + Examples + + SELECT ST_AsBinary(ST_GeomFromText('POLYGON((0 0,0 1,1 1,1 0,0 0))',4326)); + + st_asbinary +-------------------------------- +\001\003\000\000\000\001\000\000\000\005 +\000\000\000\000\000\000\000\000\000\000 +\000\000\000\000\000\000\000\000\000\000 +\000\000\000\000\000\000\000\000\000\000 +\000\000\000\360?\000\000\000\000\000\000 +\360?\000\000\000\000\000\000\360?\000\000 +\000\000\000\000\360?\000\000\000\000\000 +\000\000\000\000\000\000\000\000\000\000\000 +\000\000\000\000\000\000\000\000 +(1 row) + SELECT ST_AsBinary(ST_GeomFromText('POLYGON((0 0,0 1,1 1,1 0,0 0))',4326), 'XDR'); + st_asbinary +-------------------------------- +\000\000\000\000\003\000\000\000\001\000\000\000\005\000\000\000\000\000 +\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000 +\000?\360\000\000\000\000\000\000?\360\000\000\000\000\000\000?\360\000\000 +\000\000\000\000?\360\000\000\000\000\000\000\000\000\000\000\000\000\000\000 +\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000 +(1 row) + + + + + See Also + , , , + + + + + ST_AsEWKB + Return the Well-Known Binary (WKB) representation of the geometry with SRID meta data. + + + + + + bytea ST_AsEWKB + geometry g1 + + + bytea ST_AsEWKB + geometry g1 + text NDR_or_XDR + + + + + + Description + Returns the Well-Known Binary representation of the geometry with SRID metadata. There are 2 variants of the function. The first + variant takes no endian encoding paramater and defaults to little endian. The second variant takes a second argument + denoting the encoding - using little-endian ('NDR') or big-endian ('XDR') encoding. + This is useful in binary cursors to pull data out of the + database without converting it to a string representation. + + The WKB spec does not include the SRID. To get the OGC WKB format use ST_AsBinary + + + ST_AsEWKB is the reverse of ST_GeomFromEWKB. Use ST_GeomFromEWKB to convert to a postgis geometry from ST_AsEWKB representation. + + &Z_support; + &curve_support; + + + + + Examples + + SELECT ST_AsEWKB(ST_GeomFromText('POLYGON((0 0,0 1,1 1,1 0,0 0))',4326)); + + st_asewkb +-------------------------------- +\001\003\000\000 \346\020\000\000\001\000 +\000\000\005\000\000\000\000 +\000\000\000\000\000\000\000\000 +\000\000\000\000\000\000\000\000\000 +\000\000\000\000\000\000\000\000\000\000 +\000\000\360?\000\000\000\000\000\000\360? +\000\000\000\000\000\000\360?\000\000\000\000\000 +\000\360?\000\000\000\000\000\000\000\000\000\000\000 +\000\000\000\000\000\000\000\000\000\000\000\000\000 +(1 row) + + SELECT ST_AsEWKB(ST_GeomFromText('POLYGON((0 0,0 1,1 1,1 0,0 0))',4326), 'XDR'); + st_asewkb +-------------------------------- +\000 \000\000\003\000\000\020\346\000\000\000\001\000\000\000\005\000\000\000\000\ +000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000? +\360\000\000\000\000\000\000?\360\000\000\000\000\000\000?\360\000\000\000\000 +\000\000?\360\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000 +\000\000\000\000\000\000\000\000\000\000\000\000\000 + + + + + + See Also + , , , , + + + + + ST_AsEWKT + Return the Well-Known Text (WKT) representation of the geometry with SRID meta data. + + + + + + text ST_AsEWKT + geometry g1 + + + + + + Description + + Returns the Well-Known Text representation of the geometry prefixed with the SRID. + + + The WKT spec does not include the SRID. To get the OGC WKT format use ST_AsText + + + WKT format does not maintain precision so to prevent floating truncation, use ST_AsBinary or ST_AsEWKB format for transport. + + + ST_AsEWKT is the reverse of . Use to convert to a postgis geometry from ST_AsEWKT representation. + + &Z_support; + &curve_support; + + + + + Examples + + SELECT ST_AsEWKT('0103000020E61000000100000005000000000000 + 000000000000000000000000000000000000000000000000000000 + F03F000000000000F03F000000000000F03F000000000000F03 + F000000000000000000000000000000000000000000000000'::geometry); + + st_asewkt +-------------------------------- +SRID=4326;POLYGON((0 0,0 1,1 1,1 0,0 0)) +(1 row) + +SELECT ST_AsEWKT('0108000080030000000000000060E30A4100000000785C0241000000000000F03F0000000018 +E20A4100000000485F024100000000000000400000000018 +E20A4100000000305C02410000000000000840') + +--st_asewkt--- +CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3) + + + + + + See Also + , + + + + + ST_AsGeoJSON + + Return the geometry as a GeoJSON element. + + + + + + text ST_AsGeoJSON + geometry g1 + + + text ST_AsGeoJSON + geography g1 + + + text ST_AsGeoJSON + geometry g1 + integer max_decimal_digits + + + text ST_AsGeoJSON + geography g1 + integer max_decimal_digits + + + text ST_AsGeoJSON + geometry g1 + integer max_decimal_digits + integer options + + + text ST_AsGeoJSON + geography g1 + integer max_decimal_digits + integer options + + + text ST_AsGeoJSON + integer version + geometry g1 + + + text ST_AsGeoJSON + integer version + geography g1 + + + text ST_AsGeoJSON + integer version + geometry g1 + integer max_decimal_digits + + + text ST_AsGeoJSON + integer version + geography g1 + integer max_decimal_digits + + + text ST_AsGeoJSON + integer version + geometry g1 + integer max_decimal_digits + integer options + + + text ST_AsGeoJSON + integer version + geography g1 + integer max_decimal_digits + integer options + + + + + + Description + + Return the geometry as a Geometry Javascript Object Notation (GeoJSON) element. (Cf GeoJSON + specifications 1.0). 2D and 3D Geometries are both + supported. GeoJSON only support SFS 1.1 geometry type (no curve + support for example). + + The version parameter, if specified, must be 1. + + The third argument may be used to reduce the maximum number + of decimal places used in output (defaults to 15). + + The last 'options' argument could be used to add Bbox or Crs + in GeoJSON output: + + + 0: means no option (default value) + + + + 1: GeoJSON Bbox + + + + 2: GeoJSON Short CRS (e.g EPSG:4326) + + + + 4: GeoJSON Long CRS (e.g urn:ogc:def:crs:EPSG:4326) + + + + Version 1: ST_AsGeoJSON(geom) / precision=15 version=1 options=0 + Version 2: ST_AsGeoJSON(geom, precision) / version=1 options=0 + Version 3: ST_AsGeoJSON(geom, precision, options) / version=1 + Version 4: ST_AsGeoJSON(version, geom) / precision=15 options=0 + Version 5: ST_AsGeoJSON(version, geom, precision) /options=0 + Version 6: ST_AsGeoJSON(version, geom, precision,options) + + Availability: 1.3.4 + Availability: 1.5.0 geography support was introduced. + &Z_support; + + + + Examples + GeoJSON format is generally more efficient than other formats for use in ajax mapping. + One popular javascript client that supports this is Open Layers. + Example of its use is OpenLayers GeoJSON Example + + SELECT ST_AsGeoJSON(the_geom) from fe_edges limit 1; + st_asgeojson +----------------------------------------------------------------------------------------------------------- + +{"type":"MultiLineString","coordinates":[[[-89.734634999999997,31.492072000000000], +[-89.734955999999997,31.492237999999997]]]} +(1 row) +--3d point +SELECT ST_AsGeoJSON('LINESTRING(1 2 3, 4 5 6)'); + +st_asgeojson +----------------------------------------------------------------------------------------- + {"type":"LineString","coordinates":[[1,2,3],[4,5,6]]} + + + + + + + ST_AsGML + Return the geometry as a GML version 2 or 3 element. + + + + + + text ST_AsGML + geometry g1 + + + text ST_AsGML + geography g1 + + + text ST_AsGML + geometry g1 + integer precision + + + text ST_AsGML + geography g1 + integer precision + + + text ST_AsGML + integer version + geometry g1 + + + text ST_AsGML + integer version + geography g1 + + + text ST_AsGML + integer version + geometry g1 + integer precision + + + text ST_AsGML + integer version + geography g1 + integer precision + + + text ST_AsGML + integer version + geometry g1 + integer precision + integer options + + + text ST_AsGML + integer version + geography g1 + integer precision + integer options + + + + + + Description + + Return the geometry as a Geography Markup Language (GML) element. The version parameter, + if specified, may be either 2 or 3. If no version parameter is + specified then the default is assumed to be 2. The third argument + may be used to reduce the maximum number of decimal places + used in output (defaults to 15). + GML 2 refer to 2.1.2 version, GML 3 to 3.1.1 version + The last 'options' argument is a bitfield. It could be used to define CRS output type + in GML output, and to declare data as lat/lon: + + + 0: GML Short CRS (e.g EPSG:4326), default value + + + + 1: GML Long CRS (e.g urn:ogc:def:crs:EPSG:4326) + + + + 16: Declare that datas are lat/lon (e.g srid=4326). Default is to assume that data are planars. This option is usefull for GML 3.1.1 output only, related to axis order. + + + + + + + + Availability: 1.3.2 + Availability: 1.5.0 geography support was introduced. + + + &Z_support; + + + + Examples + 0,0 0,1 1,1 1,0 0,0]]> + + 6.34535 5.23423]]> + + + + + + See Also + + + + + + + + + ST_AsHEXEWKB + + Returns a Geometry in HEXEWKB format (as text) using either + little-endian (NDR) or big-endian (XDR) encoding. + + + + + + text ST_AsHEXEWKB + geometry g1 + text NDRorXDR + + + + text ST_AsHEXEWKB + geometry g1 + + + + + + Description + + Returns a Geometry in HEXEWKB format (as text) using either + little-endian (NDR) or big-endian (XDR) encoding. If no encoding is specified, then NDR is used. + + + Availability: 1.2.2 + + &Z_support; + &curve_support; + + + + Examples + SELECT ST_AsHEXEWKB(ST_GeomFromText('POLYGON((0 0,0 1,1 1,1 0,0 0))',4326)); + which gives same answer as + + SELECT ST_GeomFromText('POLYGON((0 0,0 1,1 1,1 0,0 0))',4326)::text; + + st_ashexewkb + -------- + 0103000020E6100000010000000500 + 00000000000000000000000000000000 + 00000000000000000000000000000000F03F + 000000000000F03F000000000000F03F000000000000F03 + F000000000000000000000000000000000000000000000000 + + + + + + ST_AsKML + + Return the geometry as a KML element. Several variants. Default version=2, default precision=15 + + + + + + text ST_AsKML + geometry g1 + + + text ST_AsKML + geography g1 + + + text ST_AsKML + geometry g1 + integer precision + + + text ST_AsKML + geography g1 + integer precision + + + text ST_AsKML + integer version + geometry geom1 + + + text ST_AsKML + integer version + geography geom1 + + + text ST_AsKML + integer version + geometry geom1 + integer precision + + + text ST_AsKML + integer version + geography geom1 + integer precision + + + + + + Description + + Return the geometry as a Keyhole Markup Language (KML) element. There are several variants of this function. + maximum number of decimal places used in + output (defaults to 15) and version default to 2. + + Version 1: ST_AsKML(geom) / version=2 precision=15 + Version 2: ST_AsKML(geom, max_sig_digits) / version=2 + Version 3: ST_AsKML(version, geom) / precision=15 + Version 4: ST_AsKML(version, geom, precision) + + + Requires PostGIS be compiled with Proj support. Use to confirm you have proj support compiled in. + + + + Availability: 1.2.2 - later variants that include version param came in 1.3.2 + + + + AsKML output will not work with geometries that do not have an SRID + + + &Z_support; + + + + Examples + 0,0 0,1 1,1 1,0 0,0 + + --3d linestring + SELECT ST_AsKML('SRID=4326;LINESTRING(1 2 3, 4 5 6)'); + 1,2,3 4,5,6 + ]]> + + + + See Also + + , + + + + + ST_AsSVG + + Returns a Geometry in SVG path data given a geometry or geography object. + + + + + + text ST_AsSVG + geometry g1 + + + text ST_AsSVG + geography g1 + + + text ST_AsSVG + geometry g1 + integer rel + + + text ST_AsSVG + geography g1 + integer rel + + + text ST_AsSVG + geometry g1 + integer rel + integer maxdecimaldigits + + + text ST_AsSVG + geography g1 + integer rel + integer maxdecimaldigits + + + + + + Description + + Return the geometry as Scalar Vector Graphics (SVG) path data. Use 1 as second + argument to have the path data implemented in terms of relative + moves, the default (or 0) uses absolute moves. Third argument may + be used to reduce the maximum number of decimal digits used in + output (defaults to 15). Point geometries will be rendered as + cx/cy when 'rel' arg is 0, x/y when 'rel' is 1. Multipoint + geometries are delimited by commas (","), GeometryCollection + geometries are delimited by semicolons (";"). + + + Availability: 1.2.2 . Availability: 1.4.0 Changed in PostGIS 1.4.0 to include L command in absolute path to conform to http://www.w3.org/TR/SVG/paths.html#PathDataBNF + + + + + Examples + SELECT ST_AsSVG(ST_GeomFromText('POLYGON((0 0,0 1,1 1,1 0,0 0))',4326)); + + st_assvg + -------- + M 0 0 L 0 -1 1 -1 1 0 Z + + + + + + + ST_GeoHash + + Return a GeoHash representation (geohash.org) of the geometry. + + + + + + text ST_GeoHash + geometry g1 + + + text ST_GeoHash + geometry g1 + integer precision + + + + + + Description + + Return a GeoHash representation (geohash.org) of the geometry. A GeoHash encodes a point into a text form that is sortable and searchable based on prefixing. A shorter GeoHash is a less precise representation of a point. It can also be thought of as a box, that contains the actual point. + + The one-parameter variant of ST_GeoHash returns a GeoHash based on the input geometry type. Points return a GeoHash with 20 characters of precision (about enough to hold the full double precision of the input). Other types return a GeoHash with a variable amount of precision, based on the size of the feature. Larger features are represented with less precision, smaller features with more precision. The idea is that the box implied by the GeoHash will always contain the input feature. + + The two-parameter variant of ST_GeoHash returns a GeoHash with a requested precision. For non-points, the starting point of the calculation is the center of the bounding box of the geometry. + + Availability: 1.4.0 + + + ST_GeoHash will not work with geometries that are not in geographic (lon/lat) coordinates. + + + &curve_support; + + + + Examples + + + + + See Also + + + + + + + + + ST_AsText + Return the Well-Known Text (WKT) representation of the geometry/geography without SRID metadata. + + + + + + text ST_AsText + geometry g1 + + + text ST_AsText + geography g1 + + + + + + Description + + Returns the Well-Known Text representation of the geometry/geography. + + + The WKT spec does not include the SRID. To get the SRID as part of the data, use the non-standard + PostGIS + + + WKT format does not maintain precision so to prevent floating truncation, use ST_AsBinary or ST_AsEWKB format for transport. + + + ST_AsText is the reverse of . Use to convert to a postgis geometry from ST_AsText representation. + + + Availability: 1.5 - support for geography was introduced. + &sfs_compliant; s2.1.1.1 + &sqlmm_compliant; SQL-MM 3: 5.1.25 + &curve_support; + + + + + Examples + + SELECT ST_AsText('01030000000100000005000000000000000000 +000000000000000000000000000000000000000000000000 +F03F000000000000F03F000000000000F03F000000000000F03 +F000000000000000000000000000000000000000000000000'); + + st_astext +-------------------------------- + POLYGON((0 0,0 1,1 1,1 0,0 0)) +(1 row) + + + + + See Also + + , , , + + + + diff --git a/doc/reference_processing.xml b/doc/reference_processing.xml new file mode 100644 index 000000000..34863c385 --- /dev/null +++ b/doc/reference_processing.xml @@ -0,0 +1,1685 @@ + + + Geometry Processing Functions + + + ST_Buffer + + (T) For geometry: Returns a geometry that represents all points whose distance + from this Geometry is less than or equal to distance. Calculations + are in the Spatial Reference System of this Geometry. For geography: Uses a planar transform wrapper. Introduced in 1.5 support for + different end cap and mitre settings to control shape. buffer_style options: quad_segs=#,endcap=round|flat|square,join=round|mitre|bevel,mitre_limit=#.# + + + + + + + geometry ST_Buffer + geometry g1 + float radius_of_buffer + + + + geometry ST_Buffer + geometry g1 + float radius_of_buffer + integer num_seg_quarter_circle + + + + geometry ST_Buffer + geometry g1 + float radius_of_buffer + text buffer_style_parameters + + + + geography ST_Buffer + geography g1 + float radius_of_buffer_in_meters + + + + + + + Description + + Returns a geometry/geography that represents all points whose distance + from this Geometry/geography is less than or equal to distance. + Geometry: Calculations + are in the Spatial Reference System of the geometry. Introduced in 1.5 support for + different end cap and mitre settings to control shape. + Geography: For geography this is really a thin wrapper around the geometry implementation. It first determines the best SRID that + fits the bounding box of the geography object (favoring UTM, polar stereographic and falling back on mercator in worst case scenario) and then buffers in that planar spatial ref and retransforms back to WGS84 geography. + + For geography this may not behave as expected if object is sufficiently large that it falls between two UTM zones or crosses the dateline + Availability: 1.5 - ST_Buffer was enhanced to support different endcaps and join types. These are useful for example to convert road linestrings + into polygon roads with flat or square edges instead of rounded edges. Thin wrapper for geography was added. - requires GEOS >= 3.2 to take advantage of advanced geometry functionality. + + +The optional third parameter (currently only applies to geometry) can either specify number of segments used to approximate a quarter circle (integer case, defaults to 8) or a list of blank-separated key=value pairs (string case) to tweak operations as follows: + + +'quad_segs=#' : number of segments used to approximate a quarter circle (defaults to 8). + + +'endcap=round|flat|square' : endcap style (defaults to "round", needs GEOS-3.2 or higher for a different value). 'butt' is also accepted as a synonym for 'flat'. + + +'join=round|mitre|bevel' : join style (defaults to "round", needs GEOS-3.2 or higher for a different value). 'miter' is also accepted as a synonym for 'mitre'. + + +'mitre_limit=#.#' : mitre ratio limit (only affects mitred join style). 'miter_limit' is also accepted as a synonym for 'mitre_limit'. + + + + + Units of radius are measured in units of the spatial reference system. + The inputs can be POINTS, MULTIPOINTS, LINESTRINGS, MULTILINESTRINGS, POLYGONS, MULTIPOLYGONS, and GeometryCollections. + This function ignores the third dimension (z) and will always give a 2-d buffer even when presented with a 3d-geometry. + + Performed by the GEOS module. + &sfs_compliant; s2.1.1.3 + &sqlmm_compliant; SQL-MM 3: 5.1.17 + + People often make the mistake of using this function to try to do radius searches. Creating a + buffer to to a radius search is slow and pointless. Use instead. + + + + Examples + + + + + + + + + + + quad_segs=8 (default) + + + +SELECT ST_Buffer( + ST_GeomFromText('POINT(100 90)'), + 50, 'quad_segs=8'); + + + + + + + + + quad_segs=2 (lame) + + + +SELECT ST_Buffer( + ST_GeomFromText('POINT(100 90)'), + 50, 'quad_segs=2'); + + + + + + + + + + endcap=round join=round (default) + + + +SELECT ST_Buffer( + ST_GeomFromText( + 'LINESTRING(50 50,150 150,150 50)' + ), 10, 'endcap=round join=round'); + + + + + + + + + endcap=square + + + +SELECT ST_Buffer( + ST_GeomFromText( + 'LINESTRING(50 50,150 150,150 50)' + ), 10, 'endcap=square join=round'); + + + + + + + + + endcap=flat + + + +SELECT ST_Buffer( + ST_GeomFromText( + 'LINESTRING(50 50,150 150,150 50)' + ), 10, 'endcap=flat join=round'); + + + + + + + + + + join=bevel + + + +SELECT ST_Buffer( + ST_GeomFromText( + 'LINESTRING(50 50,150 150,150 50)' + ), 10, 'join=bevel'); + + + + + + + + + join=mitre mitre_limit=5.0 (default mitre limit) + + + +SELECT ST_Buffer( + ST_GeomFromText( + 'LINESTRING(50 50,150 150,150 50)' + ), 10, 'join=mitre mitre_limit=5.0'); + + + + + + + + + join=mitre mitre_limit=1 + + + +SELECT ST_Buffer( + ST_GeomFromText( + 'LINESTRING(50 50,150 150,150 50)' + ), 10, 'join=mitre mitre_limit=1.0'); + + + + + + + +--A buffered point approximates a circle +-- A buffered point forcing approximation of (see diagram) +-- 2 points per circle is poly with 8 sides (see diagram) +SELECT ST_NPoints(ST_Buffer(ST_GeomFromText('POINT(100 90)'), 50)) As promisingcircle_pcount, +ST_NPoints(ST_Buffer(ST_GeomFromText('POINT(100 90)'), 50, 2)) As lamecircle_pcount; + +promisingcircle_pcount | lamecircle_pcount +------------------------+------------------- + 33 | 9 + +--A lighter but lamer circle +-- only 2 points per quarter circle is an octagon +--Below is a 100 meter octagon +-- Note coordinates are in NAD 83 long lat which we transform +to Mass state plane meter and then buffer to get measurements in meters; +SELECT ST_AsText(ST_Buffer( +ST_Transform( +ST_SetSRID(ST_MakePoint(-71.063526, 42.35785),4269), 26986) +,100,2)) As octagon; +---------------------- +POLYGON((236057.59057465 900908.759918696,236028.301252769 900838.049240578,235 +957.59057465 900808.759918696,235886.879896532 900838.049240578,235857.59057465 +900908.759918696,235886.879896532 900979.470596815,235957.59057465 901008.759918 +696,236028.301252769 900979.470596815,236057.59057465 900908.759918696)) + +--Buffer is often also used as a poor man's polygon fixer or a sometimes speedier unioner +--Sometimes able to fix invalid polygons - using below +-- using below on anything but a polygon will result in empty geometry +-- and for geometry collections kill anything in the collection that is not a polygon +--Poor man's bad poly fixer +SELECT ST_IsValid(foo.invalidpoly) as isvalid, ST_IsValid(ST_Buffer(foo.invalidpoly,0.0)) as bufferisvalid, +ST_AsText(ST_Buffer(foo.invalidpoly,0.0)) As newpolytextrep +FROM (SELECT ST_GeomFromText('POLYGON((-1 2, 3 4, 5 6, -1 2, 5 6, -1 2))') as invalidpoly) As foo +NOTICE: Self-intersection at or near point -1 2 +isvalid | bufferisvalid | newpolytextrep +---------+---------------+------------------------------ +f | t | POLYGON((-1 2,5 6,3 4,-1 2)) + +--Poor man's polygon unioner +SELECT ST_AsText(the_geom) as textorig, ST_AsText(ST_Buffer(foo.the_geom,0.0)) As textbuffer +FROM (SELECT ST_Collect('POLYGON((-1 2, 3 4, 5 6, -1 2))', 'POLYGON((-1 2, 2 3, 5 6, -1 2))') As the_geom) as foo; + textorig | textbuffer +-----------------------------------------------------------+-------------------- +MULTIPOLYGON(((-1 2,3 4,5 6,-1 2)),((-1 2,2 3,5 6,-1 2))) | POLYGON((-1 2,5 6,3 4,2 3,-1 2)) + + + + + + + See Also + + , , , , + + + + + + ST_BuildArea + + Creates an areal geometry formed by the constituent linework + of given geometry + + + + + + geometry ST_BuildArea + geometry A + + + + + + Description + + Creates an areal geometry formed by the constituent linework + of given geometry. The return type can be a Polygon or + MultiPolygon, depending on input. If the input lineworks do not + form polygons NULL is returned. The inputs can be LINESTRINGS, MULTILINESTRINGS, POLYGONS, MULTIPOLYGONS, and GeometryCollections. + + This function will assume all inner geometries represent holes + Availability: 1.1.0 - requires GEOS >= 2.1.0. + + + + Examples + + + + + + + + + + This will create a donut + + + +SELECT ST_BuildArea(ST_Collect(smallc,bigc)) +FROM (SELECT + ST_Buffer( + ST_GeomFromText('POINT(100 90)'), 25) As smallc, + ST_Buffer(ST_GeomFromText('POINT(100 90)'), 50) As bigc) As foo; + + + + + + + + + + This will create a gaping hole inside the circle with prongs sticking out + + + +SELECT ST_BuildArea(ST_Collect(line,circle)) +FROM (SELECT + ST_Buffer( + ST_MakeLine(ST_MakePoint(10, 10),ST_MakePoint(190, 190)), + 5) As line, + ST_Buffer(ST_GeomFromText('POINT(100 90)'), 50) As circle) As foo; + +--this creates the same gaping hole +--but using linestrings instead of polygons +SELECT ST_BuildArea( + ST_Collect(ST_ExteriorRing(line),ST_ExteriorRing(circle)) + ) +FROM (SELECT ST_Buffer( + ST_MakeLine(ST_MakePoint(10, 10),ST_MakePoint(190, 190)) + ,5) As line, + ST_Buffer(ST_GeomFromText('POINT(100 90)'), 50) As circle) As foo; + + + + + + + + + + + See Also + + + , + wrappers to + this function with standard OGC interface + + + + + ST_Collect + Return a specified ST_Geometry value from a collection of other geometries. + + + + + + geometry ST_Collect + geometry set g1field + + + geometry ST_Collect + geometry g1 + geometry g2 + + + geometry ST_Collect + geometry[] g1_array + + + + + + Description + Output type can be a MULTI* or a + GEOMETRYCOLLECTION. Comes in 2 variants. Variant 1 collects 2 geometries. Variant 2 is an aggregate function that takes a set of geometries and collects + them into a single ST_Geometry. + + Aggregate version: This function returns a GEOMETRYCOLLECTION or a MULTI object + from a set of geometries. The ST_Collect() function is an "aggregate" + function in the terminology of PostgreSQL. That means that it + operates on rows of data, in the same way the SUM() and AVG() + functions do. For example, "SELECT ST_Collect(GEOM) FROM GEOMTABLE + GROUP BY ATTRCOLUMN" will return a separate GEOMETRYCOLLECTION for + each distinct value of ATTRCOLUMN. + + Non-Aggregate version: This function returns a geometry being a collection of two + input geometries. Output type can be a MULTI* or a + GEOMETRYCOLLECTION. + + ST_Collect and ST_Union are often interchangeable. + ST_Collect is in general orders of magnitude faster than ST_Union + because it does not try to dissolve boundaries or validate that a constructed MultiPolgon doesn't + have overlapping regions. It merely rolls up + single geometries into MULTI and MULTI or mixed geometry types + into Geometry Collections. Unfortunately geometry collections are + not well-supported by GIS tools. To prevent ST_Collect from + returning a Geometry Collection when collecting MULTI geometries, + one can use the below trick that utilizes to expand the + MULTIs out to singles and then regroup them. + + Availability: 1.4.0 - ST_Collect(geomarray) was introduced. ST_Collect was enhanced to handle more geometries faster. + &Z_support; + &curve_support; This method supports Circular Strings + and Curves, but will never return a MULTICURVE or MULTI as one + would expect and PostGIS does not currently support those. + + + + Examples + Aggregate example + Thread ref: http://postgis.refractions.net/pipermail/postgis-users/2008-June/020331.html +SELECT stusps, + ST_Multi(ST_Collect(f.the_geom)) as singlegeom + FROM (SELECT stusps, (ST_Dump(the_geom)).geom As the_geom + FROM + somestatetable ) As f +GROUP BY stusps + Non-Aggregate example + Thread ref: http://postgis.refractions.net/pipermail/postgis-users/2008-June/020331.html +SELECT ST_AsText(ST_Collect(ST_GeomFromText('POINT(1 2)'), + ST_GeomFromText('POINT(-2 3)') )); + +st_astext +---------- +MULTIPOINT(1 2,-2 3) + +--Collect 2 d points +SELECT ST_AsText(ST_Collect(ST_GeomFromText('POINT(1 2)'), + ST_GeomFromText('POINT(1 2)') ) ); + +st_astext +---------- +MULTIPOINT(1 2,1 2) + +--Collect 3d points +SELECT ST_AsEWKT(ST_Collect(ST_GeomFromEWKT('POINT(1 2 3)'), + ST_GeomFromEWKT('POINT(1 2 4)') ) ); + + st_asewkt +------------------------- + MULTIPOINT(1 2 3,1 2 4) + + --Example with curves +SELECT ST_AsText(ST_Collect(ST_GeomFromText('CIRCULARSTRING(220268 150415,220227 150505,220227 150406)'), +ST_GeomFromText('CIRCULARSTRING(220227 150406,2220227 150407,220227 150406)'))); + st_astext +------------------------------------------------------------------------------------ + GEOMETRYCOLLECTION(CIRCULARSTRING(220268 150415,220227 150505,220227 150406), + CIRCULARSTRING(220227 150406,2220227 150407,220227 150406)) + +--New ST_Collect array construct +SELECT ST_Collect(ARRAY(SELECT the_geom FROM sometable)); + +SELECT ST_AsText(ST_Collect(ARRAY[ST_GeomFromText('LINESTRING(1 2, 3 4)'), + ST_GeomFromText('LINESTRING(3 4, 4 5)')])) As wktcollect; + +--wkt collect -- +MULTILINESTRING((1 2,3 4),(3 4,4 5)) + + + + + See Also + , + + + + + + ST_ConvexHull + The convex hull of a geometry represents the minimum convex + geometry that encloses all geometries within the set. + + + + + + geometry ST_ConvexHull + geometry geomA + + + + + + Description + The convex hull of a geometry represents the minimum convex + geometry that encloses all geometries within the set. + + One can think of the convex hull as the geometry you get by wrapping an elastic + band around a set of geometries. This is different from a concave hull (not currently supported) + which is analogous to shrink-wrapping your geometries. + + It is usually used with MULTI and Geometry Collections. + Although it is not an aggregate - you can use it in conjunction + with ST_Collect to get the convex hull of a set of points. + ST_ConvexHull(ST_Collect(somepointfield)). + + It is often used to + determine an affected area based on a set of point + observations. + + Performed by the GEOS module + + &sfs_compliant; s2.1.1.3 + &sqlmm_compliant; SQL-MM 3: 5.1.16 + &Z_support; + + + + Examples + +--Get estimate of infected area based on point observations +SELECT d.disease_type, + ST_ConvexHull(ST_Collect(d.the_geom)) As the_geom + FROM disease_obs As d + GROUP BY d.disease_type; + + + + + + + + + Convex Hull of a MultiLinestring and a MultiPoint seen together with the MultiLinestring and MultiPoint + + + +SELECT ST_AsText(ST_ConvexHull( + ST_Collect( + ST_GeomFromText('MULTILINESTRING((100 190,10 8),(150 10, 20 30))'), + ST_GeomFromText('MULTIPOINT(50 5, 150 30, 50 10, 10 10)') + )) ); +---st_astext-- +POLYGON((50 5,10 8,10 10,100 190,150 30,150 10,50 5)) + + + + + See Also + , + + + + + + ST_CurveToLine + + Converts a CIRCULARSTRING/CURVEDPOLYGON to a LINESTRING/POLYGON + + + + + + geometry ST_CurveToLine + geometry curveGeom + + + geometry ST_CurveToLine + geometry curveGeom + integer segments_per_qtr_circle + + + + + + Description + + Converst a CIRCULAR STRING to regular LINESTRING or CURVEPOLYGON to POLYGON. Useful for outputting to devices that can't support CIRCULARSTRING geometry types + Converts a given geometry to a linear geometry. + Each curved geometry or segment is converted into a linear approximation using the default value of 32 segments per quarter circle + Availability: 1.2.2? + &sfs_compliant; + &sqlmm_compliant; SQL-MM 3: 7.1.7 + &Z_support; + &curve_support; + + + + + Examples + + SELECT ST_AsText(ST_CurveToLine(ST_GeomFromText('CIRCULARSTRING(220268 150415,220227 150505,220227 150406)'))); + +--Result -- + LINESTRING(220268 150415,220269.95064912 150416.539364228,220271.823415575 150418.17258804,220273.613787707 150419.895736857, + 220275.317452352 150421.704659462,220276.930305234 150423.594998003,220278.448460847 150425.562198489, + 220279.868261823 150427.60152176,220281.186287736 150429.708054909,220282.399363347 150431.876723113, + 220283.50456625 150434.10230186,220284.499233914 150436.379429536,220285.380970099 150438.702620341,220286.147650624 150441.066277505, + 220286.797428488 150443.464706771,220287.328738321 150445.892130112,220287.740300149 150448.342699654, + 220288.031122486 150450.810511759,220288.200504713 150453.289621251,220288.248038775 150455.77405574, + 220288.173610157 150458.257830005,220287.977398166 150460.734960415,220287.659875492 150463.199479347, + 220287.221807076 150465.64544956,220286.664248262 150468.066978495,220285.988542259 150470.458232479,220285.196316903 150472.81345077, + 220284.289480732 150475.126959442,220283.270218395 150477.39318505,220282.140985384 150479.606668057, + 220280.90450212 150481.762075989,220279.5637474 150483.85421628,220278.12195122 150485.87804878, + 220276.582586992 150487.828697901,220274.949363179 150489.701464356,220273.226214362 150491.491836488, + 220271.417291757 150493.195501133,220269.526953216 150494.808354014,220267.559752731 150496.326509628, + 220265.520429459 150497.746310603,220263.41389631 150499.064336517,220261.245228106 150500.277412127, + 220259.019649359 150501.38261503,220256.742521683 150502.377282695,220254.419330878 150503.259018879, + 220252.055673714 150504.025699404,220249.657244448 150504.675477269,220247.229821107 150505.206787101, + 220244.779251566 150505.61834893,220242.311439461 150505.909171266,220239.832329968 150506.078553494, + 220237.347895479 150506.126087555,220234.864121215 150506.051658938,220232.386990804 150505.855446946, + 220229.922471872 150505.537924272,220227.47650166 150505.099855856,220225.054972724 150504.542297043, + 220222.663718741 150503.86659104,220220.308500449 150503.074365683, + 220217.994991777 150502.167529512,220215.72876617 150501.148267175, + 220213.515283163 150500.019034164,220211.35987523 150498.7825509, + 220209.267734939 150497.441796181,220207.243902439 150496, + 220205.293253319 150494.460635772,220203.420486864 150492.82741196,220201.630114732 150491.104263143, + 220199.926450087 150489.295340538,220198.313597205 150487.405001997,220196.795441592 150485.437801511, + 220195.375640616 150483.39847824,220194.057614703 150481.291945091,220192.844539092 150479.123276887,220191.739336189 150476.89769814, + 220190.744668525 150474.620570464,220189.86293234 150472.297379659,220189.096251815 150469.933722495, + 220188.446473951 150467.535293229,220187.915164118 150465.107869888,220187.50360229 150462.657300346, + 220187.212779953 150460.189488241,220187.043397726 150457.710378749,220186.995863664 150455.22594426, + 220187.070292282 150452.742169995,220187.266504273 150450.265039585,220187.584026947 150447.800520653, + 220188.022095363 150445.35455044,220188.579654177 150442.933021505,220189.25536018 150440.541767521, + 220190.047585536 150438.18654923,220190.954421707 150435.873040558,220191.973684044 150433.60681495, + 220193.102917055 150431.393331943,220194.339400319 150429.237924011,220195.680155039 150427.14578372,220197.12195122 150425.12195122, + 220198.661315447 150423.171302099,220200.29453926 150421.298535644,220202.017688077 150419.508163512,220203.826610682 150417.804498867, + 220205.716949223 150416.191645986,220207.684149708 150414.673490372,220209.72347298 150413.253689397,220211.830006129 150411.935663483, + 220213.998674333 150410.722587873,220216.22425308 150409.61738497,220218.501380756 150408.622717305,220220.824571561 150407.740981121, + 220223.188228725 150406.974300596,220225.586657991 150406.324522731,220227 150406) + +--3d example +SELECT ST_AsEWKT(ST_CurveToLine(ST_GeomFromEWKT('CIRCULARSTRING(220268 150415 1,220227 150505 2,220227 150406 3)'))); +Output +------ + LINESTRING(220268 150415 1,220269.95064912 150416.539364228 1.0181172856673, + 220271.823415575 150418.17258804 1.03623457133459,220273.613787707 150419.895736857 1.05435185700189,....AD INFINITUM .... + 220225.586657991 150406.324522731 1.32611114201132,220227 150406 3) + +--use only 2 segments to approximate quarter circle +SELECT ST_AsText(ST_CurveToLine(ST_GeomFromText('CIRCULARSTRING(220268 150415,220227 150505,220227 150406)'),2)); +st_astext +------------------------------ + LINESTRING(220268 150415,220287.740300149 150448.342699654,220278.12195122 150485.87804878, + 220244.779251566 150505.61834893,220207.243902439 150496,220187.50360229 150462.657300346, + 220197.12195122 150425.12195122,220227 150406) + + + + + + + + See Also + + + + + + + + ST_Difference + + Returns a geometry that represents that part of geometry A + that does not intersect with geometry B. + + + + + + geometry ST_Difference + geometry geomA + geometry geomB + + + + + + Description + + Returns a geometry that represents that part of geometry A + that does not intersect with geometry B. One can think of this as GeometryA - ST_Intersection(A,B). If A is completely contained in B + then an empty geometry collection is returned. + Note - order matters. B - A will always return a portion of B + + Performed by the GEOS module + + Do not call with a GeometryCollection as an argument + + &sfs_compliant; s2.1.1.3 + &sqlmm_compliant; SQL-MM 3: 5.1.20 + &Z_support; However it seems to only consider x y when + doing the difference and tacks back on the Z-Index + + + + Examples + + + + + + + + + + + + The original linestrings shown together. + + + + + + + + + + + + The difference of the two linestrings + + + + + + + + + +--Safe for 2d. This is same geometries as what is shown for st_symdifference +SELECT ST_AsText( + ST_Difference( + ST_GeomFromText('LINESTRING(50 100, 50 200)'), + ST_GeomFromText('LINESTRING(50 50, 50 150)') + ) + ); + +st_astext +--------- +LINESTRING(50 150,50 200) + + + + +--When used in 3d doesn't quite do the right thing +SELECT ST_AsEWKT(ST_Difference(ST_GeomFromEWKT('MULTIPOINT(-118.58 38.38 5,-118.60 38.329 6,-118.614 38.281 7)'), ST_GeomFromEWKT('POINT(-118.614 38.281 5)'))); +st_asewkt +--------- +MULTIPOINT(-118.6 38.329 6,-118.58 38.38 5) + + + + + + See Also + + + + + + + + ST_Dump + Returns a set of geometry_dump (geom,path) rows, that make up a geometry g1. + + + + + + geometry_dump[]ST_Dump + geometry g1 + + + + + + Description + This is a set-returning function (SRF). It returns a set of + geometry_dump rows, formed by a geometry (geom) and an array of + integers (path). When the input geometry is a simple type + (POINT,LINESTRING,POLYGON) a single record will be returned with + an empty path array and the input geometry as geom. When the input + geometry is a collection or multi it will return a record for each + of the collection components, and the path will express the + position of the component inside the collection. + + ST_Dump is useful for expanding geometries. It is the + reverse of a GROUP BY in that it creates new rows. For example it + can be use to expand MULTIPOLYGONS into POLYGONS. + + Availability: PostGIS 1.0.0RC1. Requires PostgreSQL 7.3 or higher. + Prior to 1.3.4, this function crashes if used with geometries that contain CURVES. This is fixed in 1.3.4+ + + Z_support; + curve_support; + + + + Examples + SELECT sometable.field1, sometable.field1, + (ST_Dump(sometable.the_geom)).geom As the_geom +FROM sometable; + +--Break a compound curve into its constituent linestrings and circularstrings +SELECT ST_AsEWKT(a.geom), ST_HasArc(a.geom) + FROM ( SELECT (ST_Dump(p_geom)).geom as geom + FROM (SELECT ST_GeomFromEWKT('COMPOUNDCURVE(CIRCULARSTRING(0 0, 1 1, 1 0),(1 0, 0 1))') as p_geom) as b + ) as a; + st_asewkt | st_hasarc +-----------------------------+---------- + CIRCULARSTRING(0 0,1 1,1 0) | t + LINESTRING(1 0,0 1) | f +(2 rows) + + + + + + See Also + , + + + + + + ST_DumpRings + + Returns a set of geometry_dump rows, representing + the exterior and interior rings of a polygon. + + + + + + geometry_dump[] ST_DumpRings + geometry a_polygon + + + + + + Description + + This is a set-returning function (SRF). It returns a set of + geometry_dump rows, defined as an integer[] + and a geometry, aliased "path" and "geom" respectively. + The "path" field holds the polygon ring index containing a single integer: 0 for the shell, >0 for holes. + The "geom" field contains the corresponding ring as a polygon. + + Availability: PostGIS 1.1.3. Requires PostgreSQL 7.3 or higher. + This only works for POLYGON geometries. It will not work for MULTIPOLYGONS + &Z_support; + + + + + Examples + + SELECT sometable.field1, sometable.field1, + (ST_DumpRings(sometable.the_geom)).geom As the_geom +FROM sometableOfpolys; + +SELECT ST_AsEWKT(geom) As the_geom, path + FROM ST_DumpRings( + ST_GeomFromEWKT('POLYGON((-8149064 5133092 1,-8149064 5132986 1,-8148996 5132839 1,-8148972 5132767 1,-8148958 5132508 1,-8148941 5132466 1,-8148924 5132394 1, + -8148903 5132210 1,-8148930 5131967 1,-8148992 5131978 1,-8149237 5132093 1,-8149404 5132211 1,-8149647 5132310 1,-8149757 5132394 1, + -8150305 5132788 1,-8149064 5133092 1), + (-8149362 5132394 1,-8149446 5132501 1,-8149548 5132597 1,-8149695 5132675 1,-8149362 5132394 1))') + ) as foo; + path | the_geom +---------------------------------------------------------------------------------------------------------------- + {0} | POLYGON((-8149064 5133092 1,-8149064 5132986 1,-8148996 5132839 1,-8148972 5132767 1,-8148958 5132508 1, + | -8148941 5132466 1,-8148924 5132394 1, + | -8148903 5132210 1,-8148930 5131967 1, + | -8148992 5131978 1,-8149237 5132093 1, + | -8149404 5132211 1,-8149647 5132310 1,-8149757 5132394 1,-8150305 5132788 1,-8149064 5133092 1)) + {1} | POLYGON((-8149362 5132394 1,-8149446 5132501 1, + | -8149548 5132597 1,-8149695 5132675 1,-8149362 5132394 1)) + + + + + See Also + + , , + + + + + + ST_Intersection + + (T) Returns a geometry that represents the shared portion of geomA and geomB. The geography implementation + does a transform to geometry to do the intersection and then transform back to WGS84. + + + + + + geometry ST_Intersection + + geometry + geomA + + + geometry + geomB + + + + geography ST_Intersection + + geography + geogA + + + geography + geogB + + + + + + Description + Returns a geometry that represents the point set + intersection of the Geometries. + + In other words - that portion of geometry A and geometry B + that is shared between the two geometries. + + If the geometries do not share any space (are disjoint), then an empty geometry collection + is returned. + ST_Intersection in conjunction with ST_Intersects is very useful for clipping geometries such as in bounding box, buffer, region + queries where you only want to return that portion of a geometry that sits in a country or region of interest. + + + Geography: For geography this is really a thin wrapper around the geometry implementation. It first determines the best SRID that + fits the bounding box of the geography object (favoring UTM, polar stereographic and falling back on mercator in worst case scenario) and then buffers in that planar spatial ref and retransforms back to WGS84 geography. + + Do not call with a GEOMETRYCOLLECTION as an argument + + + Performed by the GEOS module + + Availability: 1.5 support for geography data type was introduced. + + &sfs_compliant; s2.1.1.3 + &sqlmm_compliant; SQL-MM 3: 5.1.18 + + + Examples +SELECT ST_AsText(ST_Intersection('POINT(0 0)'::geometry, 'LINESTRING ( 2 0, 0 2 )'::geometry)); + st_astext +--------------- +GEOMETRYCOLLECTION EMPTY +(1 row) +SELECT ST_AsText(ST_Intersection('POINT(0 0)'::geometry, 'LINESTRING ( 0 0, 0 2 )'::geometry)); + st_astext +--------------- +POINT(0 0) +(1 row) + +---Clip all lines (trails) by country (here we assume country geom are POLYGON or MULTIPOLYGONS) +-- NOTE: we are only keeping intersections that result in a LINESTRING or MULTILINESTRING because we don't +-- care about trails that just share a point +-- the dump is needed to expand a geometry collection into individual single MULT* parts +-- the below is fairly generic and will work for polys, etc. by just changing the where clause +SELECT clipped.gid, clipped.f_name, clipped_geom +FROM (SELECT trails.gid, trails.f_name, (ST_Dump(ST_Intersection(country.the_geom, trails.the_geom))).geom As clipped_geom +FROM country + INNER JOIN trails + ON ST_Intersects(country.the_geom, trails.the_geom)) As clipped + WHERE ST_Dimension(clipped.clipped_geom) = 1 ; + +--For polys e.g. polygon landmarks, you can also use the sometimes faster hack that buffering anything by 0.0 +-- except a polygon results in an empty geometry collection +--(so a geometry collection containing polys, lines and points) +-- buffered by 0.0 would only leave the polygons and dissolve the collection shell +SELECT poly.gid, ST_Multi(ST_Buffer( + ST_Intersection(country.the_geom, poly.the_geom), + 0.0) + ) As clipped_geom +FROM country + INNER JOIN poly + ON ST_Intersects(country.the_geom, poly.the_geom) + WHERE Not ST_IsEmpty(ST_Buffer(ST_Intersection(country.the_geom, poly.the_geom),0.0)); + + + + See Also + , , , + + + + + + ST_LineToCurve + + Converts a LINESTRING/POLYGON to a CIRCULARSTRING, CURVED POLYGON + + + + + + geometry ST_LineToCurve + geometry geomANoncircular + + + + + + Description + + Converts plain LINESTRING/POLYGONS to CIRCULAR STRINGs and Curved Polygons. Note much fewer points are needed to describe the curved equivalent. + + Availability: 1.2.2? + Z_support; + curve_support; + + + + + Examples + + +SELECT ST_AsText(ST_LineToCurve(foo.the_geom)) As curvedastext,ST_AsText(foo.the_geom) As non_curvedastext + FROM (SELECT ST_Buffer('POINT(1 3)'::geometry, 3) As the_geom) As foo; + +curvedatext non_curvedastext +------------------------------------------------------------------| ----------------------------------------------------------------- +CURVEPOLYGON(CIRCULARSTRING(4 3,3.12132034355964 0.878679656440359, | POLYGON((4 3,3.94235584120969 2.41472903395162,3.77163859753386 1.85194970290473 +1 0,-1.12132034355965 5.12132034355963,4 3)) | ,3.49440883690764 1.33328930094119,3.12132034355964 0.878679656440359, + | 2.66671069905881 0.505591163092366,2.14805029709527 0.228361402466141, + | 1.58527096604839 0.0576441587903094,1 0, + | 0.414729033951621 0.0576441587903077,-0.148050297095264 0.228361402466137, + | -0.666710699058802 0.505591163092361,-1.12132034355964 0.878679656440353, + | -1.49440883690763 1.33328930094119,-1.77163859753386 1.85194970290472 + | --ETC-- ,3.94235584120969 3.58527096604839,4 3)) +--3D example +SELECT ST_AsEWKT(ST_LineToCurve(ST_GeomFromEWKT('LINESTRING(1 2 3, 3 4 8, 5 6 4, 7 8 4, 9 10 4)'))); + + st_asewkt +------------------------------------ + CIRCULARSTRING(1 2 3,5 6 4,9 10 4) + + + + + + + See Also + + + + + + + + ST_MemUnion + + Same as ST_Union, only memory-friendly (uses less memory + and more processor time). + + + + + + geometry ST_MemUnion + geometry set geomfield + + + + + + + Description + + Some useful description here. + + + + Same as ST_Union, only memory-friendly (uses less memory + and more processor time). This aggregate function works by unioning the geometries one at a time to previous result as opposed to + ST_Union aggregate which first creates an array and then unions + + + &Z_support; + + + + + Examples + + See ST_Union + + + + + See Also + + + + + + + + ST_MinimumBoundingCircle + Returns the smallest circle polygon that can fully contain a geometry. Default + uses 48 segments per quarter circle. + + + + + + geometry ST_MinimumBoundingCircle + geometry geomA + + + geometry ST_MinimumBoundingCircle + geometry geomA + integer num_segs_per_qt_circ + + + + + + Description + Returns the smallest circle polygon that can fully contain a geometry. + The circle is approximated by a polygon with a default of 48 segments per quarter circle. This number can be increased with little performance penalty to obtain a more accurate result. + + It is often used with MULTI and Geometry Collections. + Although it is not an aggregate - you can use it in conjunction + with ST_Collect to get the minimum bounding cirlce of a set of geometries. + ST_MinimumBoundingCircle(ST_Collect(somepointfield)). + + The ratio of the area of a polygon divided by the area of its Minimum Bounding Circle is often referred to as the Roeck test. + + Availability: 1.4.0 - requires GEOS + + + + + + Examples +SELECT d.disease_type, + ST_MinimumBoundingCircle(ST_Collect(d.the_geom)) As the_geom + FROM disease_obs As d + GROUP BY d.disease_type; + + + + + + + Minimum bounding circle of a point and linestring. Using 8 segs to approximate a quarter circle + + + +SELECT ST_AsText(ST_MinimumBoundingCircle( + ST_Collect( + ST_GeomFromEWKT('LINESTRING(55 75,125 150)'), + ST_Point(20, 80)), 8 + )) As wktmbc; +wktmbc +----------- +POLYGON((135.59714732062 115,134.384753327498 102.690357210921,130.79416296937 90.8537670908995,124.963360620072 79.9451031602111,117.116420743937 70.3835792560632,107.554896839789 62.5366393799277,96.6462329091006 56.70583703063,84.8096427890789 53.115246672502,72.5000000000001 51.9028526793802,60.1903572109213 53.1152466725019,48.3537670908996 56.7058370306299,37.4451031602112 62.5366393799276,27.8835792560632 70.383579256063,20.0366393799278 79.9451031602109,14.20583703063 90.8537670908993,10.615246672502 102.690357210921,9.40285267938019 115,10.6152466725019 127.309642789079,14.2058370306299 139.1462329091,20.0366393799275 150.054896839789,27.883579256063 159.616420743937, +37.4451031602108 167.463360620072,48.3537670908992 173.29416296937,60.190357210921 176.884753327498, +72.4999999999998 178.09714732062,84.8096427890786 176.884753327498,96.6462329091003 173.29416296937,107.554896839789 167.463360620072, +117.116420743937 159.616420743937,124.963360620072 150.054896839789,130.79416296937 139.146232909101,134.384753327498 127.309642789079,135.59714732062 115)) + + + + See Also + , + + + + + + ST_Polygonize + + Aggregate. Creates a GeometryCollection containing possible + polygons formed from the constituent linework of a set of + geometries. + + + + + + geometry ST_Polygonize + geometry set geomfield + + + + + + Description + + Creates a GeometryCollection containing possible + polygons formed from the constituent linework of a set of + geometries. + + + Geometry Collections are often difficult to deal with with third party tools, so use ST_Polygonize in conjunction with to dump the polygons + out into individual polygons. + + Availability: 1.0.0RC1 - requires GEOS >= 2.1.0. + + + + Examples: Polygonizing single linestrings + +SELECT ST_AsEWKT(ST_Polygonize(the_geom_4269)) As geomtextrep +FROM (SELECT the_geom_4269 FROM ma.suffolk_edges ORDER BY tlid LIMIT 45) As foo; + +geomtextrep +------------------------------------- + SRID=4269;GEOMETRYCOLLECTION(POLYGON((-71.040878 42.285678,-71.040943 42.2856,-71.04096 42.285752,-71.040878 42.285678)), + POLYGON((-71.17166 42.353675,-71.172026 42.354044,-71.17239 42.354358,-71.171794 42.354971,-71.170511 42.354855, + -71.17112 42.354238,-71.17166 42.353675))) +(1 row) + +--Use ST_Dump to dump out the polygonize geoms into individual polygons +SELECT ST_AsEWKT((ST_Dump(foofoo.polycoll)).geom) As geomtextrep +FROM (SELECT ST_Polygonize(the_geom_4269) As polycoll + FROM (SELECT the_geom_4269 FROM ma.suffolk_edges + ORDER BY tlid LIMIT 45) As foo) As foofoo; + +geomtextrep +------------------------ + SRID=4269;POLYGON((-71.040878 42.285678,-71.040943 42.2856,-71.04096 42.285752, +-71.040878 42.285678)) + SRID=4269;POLYGON((-71.17166 42.353675,-71.172026 42.354044,-71.17239 42.354358 +,-71.171794 42.354971,-71.170511 42.354855,-71.17112 42.354238,-71.17166 42.353675)) +(2 rows) + + + + + + See Also + + + + + + + ST_Shift_Longitude + + Reads every point/vertex in every component of every feature + in a geometry, and if the longitude coordinate is <0, adds 360 + to it. The result would be a 0-360 version of the data to be + plotted in a 180 centric map + + + + + + geometry ST_Shift_Longitude + geometry geomA + + + + + + Description + + Reads every point/vertex in every component of every feature + in a geometry, and if the longitude coordinate is <0, adds 360 + to it. The result would be a 0-360 version of the data to be + plotted in a 180 centric map + This is only useful for data in long lat e.g. 4326 (WGS 84 long lat) + + + Pre-1.3.4 bug prevented this from working for MULTIPOINT. 1.3.4+ works with MULTIPOINT as well. + + + &Z_support; + + + + + Examples + + --3d points +SELECT ST_AsEWKT(ST_Shift_Longitude(ST_GeomFromEWKT('SRID=4326;POINT(-118.58 38.38 10)'))) As geomA, + ST_AsEWKT(ST_Shift_Longitude(ST_GeomFromEWKT('SRID=4326;POINT(241.42 38.38 10)'))) As geomb +geomA geomB +---------- ----------- +SRID=4326;POINT(241.42 38.38 10) SRID=4326;POINT(-118.58 38.38 10) + +--regular line string +SELECT ST_AsText(ST_Shift_Longitude(ST_GeomFromText('LINESTRING(-118.58 38.38, -118.20 38.45)'))) + +st_astext +---------- +LINESTRING(241.42 38.38,241.8 38.45) + + + + + + See Also + , , + + + + + + ST_Simplify + Returns a "simplified" version of the given geometry using + the Douglas-Peuker algorithm. + + + + + + geometry ST_Simplify + geometry geomA + float tolerance + + + + + + Description + Returns a "simplified" version of the given geometry using + the Douglas-Peuker algorithm. Will actually do something only with + (multi)lines and (multi)polygons but you can safely call it with + any kind of geometry. Since simplification occurs on a + object-by-object basis you can also feed a GeometryCollection to + this function. + + Note that returned geometry might loose its + simplicity (see ) + Note topology may not be preserved and may result in invalid geometries. Use (see ) to preserve topology. + + Performed by the GEOS module. + Availability: 1.2.2 + + + + Examples + A circle simplified too much becomes a triangle, medium an octagon, + +SELECT ST_Npoints(the_geom) As np_before, ST_NPoints(ST_Simplify(the_geom,0.1)) As np01_notbadcircle, ST_NPoints(ST_Simplify(the_geom,0.5)) As np05_notquitecircle, +ST_NPoints(ST_Simplify(the_geom,1)) As np1_octagon, ST_NPoints(ST_Simplify(the_geom,10)) As np10_triangle, +(ST_Simplify(the_geom,100) is null) As np100_geometrygoesaway +FROM (SELECT ST_Buffer('POINT(1 3)', 10,12) As the_geom) As foo; +-result + np_before | np01_notbadcircle | np05_notquitecircle | np1_octagon | np10_triangle | np100_geometrygoesaway +-----------+-------------------+---------------------+-------------+---------------+------------------------ + 49 | 33 | 17 | 9 | 4 | t + + + + + See Also + , + + + + + + ST_SimplifyPreserveTopology + Returns a "simplified" version of the given geometry using + the Douglas-Peuker algorithm. Will avoid creating derived + geometries (polygons in particular) that are invalid. + + + + + + geometry ST_SimplifyPreserveTopology + geometry geomA + float tolerance + + + + + + Description + Returns a "simplified" version of the given geometry using + the Douglas-Peuker algorithm. Will avoid creating derived + geometries (polygons in particular) that are invalid. Will actually do something only with + (multi)lines and (multi)polygons but you can safely call it with + any kind of geometry. Since simplification occurs on a + object-by-object basis you can also feed a GeometryCollection to + this function. + + Performed by the GEOS module. + Requires GEOS 3.0.0+ + Availability: 1.3.3 + + + + Examples + Same example as Simplify, but we see Preserve Topology prevents oversimplification. The circle can at most become a square. + +SELECT ST_Npoints(the_geom) As np_before, ST_NPoints(ST_SimplifyPreserveTopology(the_geom,0.1)) As np01_notbadcircle, ST_NPoints(ST_SimplifyPreserveTopology(the_geom,0.5)) As np05_notquitecircle, +ST_NPoints(ST_SimplifyPreserveTopology(the_geom,1)) As np1_octagon, ST_NPoints(ST_SimplifyPreserveTopology(the_geom,10)) As np10_square, +ST_NPoints(ST_SimplifyPreserveTopology(the_geom,100)) As np100_stillsquare +FROM (SELECT ST_Buffer('POINT(1 3)', 10,12) As the_geom) As foo; + +--result-- + np_before | np01_notbadcircle | np05_notquitecircle | np1_octagon | np10_square | np100_stillsquare +-----------+-------------------+---------------------+-------------+---------------+------------------- + 49 | 33 | 17 | 9 | 5 | 5 + + + + See Also + + + + + + + ST_SymDifference + + Returns a geometry that represents the portions of A and B + that do not intersect. It is called a symmetric difference because + ST_SymDifference(A,B) = ST_SymDifference(B,A). + + + + + + geometry ST_SymDifference + geometry geomA + geometry geomB + + + + + + Description + + Returns a geometry that represents the portions of A and B + that do not intersect. It is called a symmetric difference because + ST_SymDifference(A,B) = ST_SymDifference(B,A). One can think of this as ST_Union(geomA,geomB) - ST_Intersection(A,B). + + + Performed by the GEOS module + + Do not call with a GeometryCollection as an argument + + &sfs_compliant; s2.1.1.3 + &sqlmm_compliant; SQL-MM 3: 5.1.21 + &Z_support; However it seems to only consider x y when + doing the difference and tacks back on the Z-Index + + + + + Examples + + + + + + + + + + + + + The original linestrings shown together + + + + + + + + + + + + The symmetric difference of the two linestrings + + + + + + + + + +--Safe for 2d - symmetric difference of 2 linestrings +SELECT ST_AsText( + ST_SymDifference( + ST_GeomFromText('LINESTRING(50 100, 50 200)'), + ST_GeomFromText('LINESTRING(50 50, 50 150)') + ) +); + +st_astext +--------- +MULTILINESTRING((50 150,50 200),(50 50,50 100)) + + + + +--When used in 3d doesn't quite do the right thing +SELECT ST_AsEWKT(ST_SymDifference(ST_GeomFromEWKT('LINESTRING(1 2 1, 1 4 2)'), + ST_GeomFromEWKT('LINESTRING(1 1 3, 1 3 4)'))) + +st_astext +------------ +MULTILINESTRING((1 3 2.75,1 4 2),(1 1 3,1 2 2.25)) + + + + + + See Also + + , , + + + + + + + ST_Union + Returns a geometry that represents the point set union of + the Geometries. + + + + + + geometry ST_Union + geometry set g1field + + + geometry ST_Union + geometry g1 + geometry g2 + + + geometry ST_Union + geometry[] g1_array + + + + + + Description + Output type can be a MULTI* , single geometry, or Geometry Collection. Comes in 2 variants. Variant 1 unions 2 geometries resulting in a new geomety with no intersecting regions. + Variant 2 is an aggregate function that takes a set of geometries and unions + them into a single ST_Geometry resulting in no intersecting regions. + + Aggregate version: This function returns a MULTI geometry or NON-MULTI geometry + from a set of geometries. The ST_Union() function is an "aggregate" + function in the terminology of PostgreSQL. That means that it + operates on rows of data, in the same way the SUM() and AVG() + functions do. + + Non-Aggregate version: This function returns a geometry being a union of two + input geometries. Output type can be a MULTI* ,NON-MULTI or + GEOMETRYCOLLECTION. + + ST_Collect and ST_Union are often interchangeable. + ST_Union is in general orders of magnitude slower than ST_Collect + because it tries to dissolve boundaries and reorder geometries to ensure that a constructed Multi* doesn't + have intersecting regions. + + Performed by the GEOS module. + NOTE: this function was formerly called GeomUnion(), which + was renamed from "Union" because UNION is an SQL reserved + word. + Availability: 1.4.0 - ST_Union was enhanced. ST_Union(geomarray) was introduced and also faster aggregate collection in PostgreSQL. If you are using GEOS 3.1.0+ + ST_Union will use the faster Cascaded Union algorithm described in + http://blog.cleverelephant.ca/2009/01/must-faster-unions-in-postgis-14.html + + &sfs_compliant; s2.1.1.3 + Aggregate version is not explicitly defined in OGC SPEC. + &sqlmm_compliant; SQL-MM 3: 5.1.19 + the z-index (elevation) when polygons are involved. + + + + Examples + Aggregate example + +SELECT stusps, + ST_Multi(ST_Union(f.the_geom)) as singlegeom + FROM sometable As f +GROUP BY stusps + + Non-Aggregate example + +SELECT ST_AsText(ST_Union(ST_GeomFromText('POINT(1 2)'), + ST_GeomFromText('POINT(-2 3)') ) ) + +st_astext +---------- +MULTIPOINT(-2 3,1 2) + + +SELECT ST_AsText(ST_Union(ST_GeomFromText('POINT(1 2)'), + ST_GeomFromText('POINT(1 2)') ) ); +st_astext +---------- +POINT(1 2) + +--3d example - sort of supports 3d (and with mixed dimensions!) +SELECT ST_AsEWKT(st_union(the_geom)) +FROM +(SELECT ST_GeomFromEWKT('POLYGON((-7 4.2,-7.1 4.2,-7.1 4.3, +-7 4.2))') as the_geom +UNION ALL +SELECT ST_GeomFromEWKT('POINT(5 5 5)') as the_geom +UNION ALL + SELECT ST_GeomFromEWKT('POINT(-2 3 1)') as the_geom +UNION ALL +SELECT ST_GeomFromEWKT('LINESTRING(5 5 5, 10 10 10)') as the_geom ) as foo; + +st_asewkt +--------- +GEOMETRYCOLLECTION(POINT(-2 3 1),LINESTRING(5 5 5,10 10 10),POLYGON((-7 4.2 5,-7.1 4.2 5,-7.1 4.3 5,-7 4.2 5))); + +--3d example not mixing dimensions +SELECT ST_AsEWKT(st_union(the_geom)) +FROM +(SELECT ST_GeomFromEWKT('POLYGON((-7 4.2 2,-7.1 4.2 3,-7.1 4.3 2, +-7 4.2 2))') as the_geom +UNION ALL +SELECT ST_GeomFromEWKT('POINT(5 5 5)') as the_geom +UNION ALL + SELECT ST_GeomFromEWKT('POINT(-2 3 1)') as the_geom +UNION ALL +SELECT ST_GeomFromEWKT('LINESTRING(5 5 5, 10 10 10)') as the_geom ) as foo; + +st_asewkt +--------- +GEOMETRYCOLLECTION(POINT(-2 3 1),LINESTRING(5 5 5,10 10 10),POLYGON((-7 4.2 2,-7.1 4.2 3,-7.1 4.3 2,-7 4.2 2))) + +--Examples using new Array construct +SELECT ST_Union(ARRAY(SELECT the_geom FROM sometable)); + +SELECT ST_AsText(ST_Union(ARRAY[ST_GeomFromText('LINESTRING(1 2, 3 4)'), + ST_GeomFromText('LINESTRING(3 4, 4 5)')])) As wktunion; + +--wktunion--- +MULTILINESTRING((3 4,4 5),(1 2,3 4)) + + + + + See Also + + + + diff --git a/doc/reference_transaction.xml b/doc/reference_transaction.xml new file mode 100644 index 000000000..c35313ace --- /dev/null +++ b/doc/reference_transaction.xml @@ -0,0 +1,343 @@ + + + Long Transactions Support + + This module and associated pl/pgsql functions have been + implemented to provide long locking support required by Web Feature Service specification. + + + Users must use serializable + transaction level otherwise locking mechanism would + break. + + + + + AddAuth + + Add an authorization token to be used in current transaction. + + + + + + boolean AddAuth + text auth_token + + + + + + Description + + Add an authorization token to be used in current transaction. + + Creates/adds to a temp table called temp_lock_have_table the current transaction identifier + and authorization token key. + + Availability: 1.1.3 + + + + + Examples + + + SELECT LockRow('towns', '353', 'priscilla'); + BEGIN TRANSACTION; + SELECT AddAuth('joey'); + UPDATE towns SET the_geom = ST_Translate(the_geom,2,2) WHERE gid = 353; + COMMIT; + + + ---Error-- + ERROR: UPDATE where "gid" = '353' requires authorization 'priscilla' + + + + + + See Also + + + + + + + + CheckAuth + + Creates trigger on a table to prevent/allow updates and deletes of rows based on authorization token. + + + + + + integer CheckAuth + text a_schema_name + text a_table_name + text a_key_column_name + + + + integer CheckAuth + text a_table_name + text a_key_column_name + + + + + + Description + + Creates trigger on a table to prevent/allow updates and deletes of rows based on authorization token. Identify rows using <rowid_col> column. + + If a_schema_name is not passed in, then searches for table in current schema. + If an authorization trigger already exists on this table function errors. + If Transaction support is not enabled, function throws an exception. + + + Availability: 1.1.3 + + + + + + Examples + + + SELECT CheckAuth('public', 'towns', 'gid'); + result + ------ + 0 + + + + + + See Also + + + + + + + + DisableLongTransactions + + Disable long transaction support. This function removes the + long transaction support metadata tables, and drops all triggers + attached to lock-checked tables. + + + + + + text DisableLongTransactions + + + + + + Description + + Disable long transaction support. This function removes the + long transaction support metadata tables, and drops all triggers + attached to lock-checked tables. + Drops meta table called authorization_table and a view called authorized_tables + and all triggers called checkauthtrigger + + Availability: 1.1.3 + + + + + + Examples + + SELECT DisableLongTransactions(); +--result-- +Long transactions support disabled + + + + + + See Also + + + + + + + + EnableLongTransactions + + Enable long transaction support. This function creates the + required metadata tables, needs to be called once before using the + other functions in this section. Calling it twice is + harmless. + + + + + + text EnableLongTransactions + + + + + + Description + + Enable long transaction support. This function creates the + required metadata tables, needs to be called once before using the + other functions in this section. Calling it twice is + harmless. + Creates a meta table called authorization_table and a view called authorized_tables + + Availability: 1.1.3 + + + + + + Examples + + SELECT EnableLongTransactions(); +--result-- +Long transactions support enabled + + + + + + See Also + + + + + + + + LockRow + + Set lock/authorization for specific row in table + + + + + + integer LockRow + text a_schema_name + text a_table_name + text a_row_key + text an_auth_token + timestamp expire_dt + + + + integer LockRow + text a_table_name + text a_row_key + text an_auth_token + timestamp expire_dt + + + + integer LockRow + text a_table_name + text a_row_key + text an_auth_token + + + + + + + Description + + Set lock/authorization for specific row in table + <authid> is a text value, <expires> is a timestamp + defaulting to now()+1hour. Returns 1 if lock has been assigned, 0 + otherwise (already locked by other auth) + + Availability: 1.1.3 + + + + + Examples + + SELECT LockRow('public', 'towns', '2', 'joey'); +LockRow +------- +1 + +--Joey has already locked the record and Priscilla is out of luck +SELECT LockRow('public', 'towns', '2', 'priscilla'); +LockRow +------- +0 + + + + + + + See Also + + + + + + + + UnlockRows + + Remove all locks held by specified authorization id. Returns + the number of locks released. + + + + + + integer UnlockRows + text auth_token + + + + + + Description + + Remove all locks held by specified authorization id. Returns + the number of locks released. + + Availability: 1.1.3 + + + + + Examples + + + SELECT LockRow('towns', '353', 'priscilla'); + SELECT LockRow('towns', '2', 'priscilla'); + SELECT UnLockRows('priscilla'); + UnLockRows + ------------ + 2 + + + + + + See Also + + + + +