--DO NOT MODIFY THIS FILE, IT IS GENERATED AUTOMATICALLY FROM SOURCES -- Complain if script is sourced in psql, rather than via CREATE EXTENSION \echo Use "CREATE EXTENSION observatory" to load this file. \quit -- Version number of the extension release CREATE OR REPLACE FUNCTION cdb_observatory_version() RETURNS text AS $$ SELECT '1.3.2'::text; $$ language 'sql' STABLE STRICT; -- Internal identifier of the installed extension instence -- e.g. 'dev' for current development version CREATE OR REPLACE FUNCTION _cdb_observatory_internal_version() RETURNS text AS $$ SELECT installed_version FROM pg_available_extensions where name='observatory' and pg_available_extensions IS NOT NULL; $$ language 'sql' STABLE STRICT; -- Returns the table name with geoms for the given geometry_id -- TODO probably needs to take in the column_id array to get the relevant -- table where there is multiple sources for a column from multiple -- geometries. CREATE OR REPLACE FUNCTION cdb_observatory._OBS_GeomTable( geom geometry(Geometry, 4326), geometry_id text, time_span text DEFAULT NULL ) RETURNS TEXT AS $$ DECLARE result text; BEGIN EXECUTE ' SELECT tablename FROM observatory.OBS_table WHERE id IN ( SELECT table_id FROM observatory.OBS_table tab, observatory.OBS_column_table coltable, observatory.OBS_column col WHERE type ILIKE ''geometry'' AND coltable.column_id = col.id AND coltable.table_id = tab.id AND col.id = $1 AND CASE WHEN $3::TEXT IS NOT NULL THEN timespan ILIKE $3::TEXT ELSE TRUE END ORDER BY timespan DESC LIMIT 1 ) ' USING geometry_id, geom, time_span INTO result; return result; END; $$ LANGUAGE plpgsql; -- A function that gets the column data for multiple columns -- Old: OBS_GetColumnData CREATE OR REPLACE FUNCTION cdb_observatory._OBS_GetColumnData( geometry_id text, column_ids text[], timespan text ) RETURNS SETOF JSON AS $$ BEGIN -- figure out highest-weight geometry_id/timespan pair for the first data column -- TODO this should be done for each data column separately IF geometry_id IS NULL OR timespan IS NULL THEN EXECUTE ' SELECT data_t.timespan timespan, geom_c.id boundary_id FROM observatory.obs_table data_t, observatory.obs_column_table data_ct, observatory.obs_column data_c, observatory.obs_column_table geoid_ct, observatory.obs_column_to_column c2c, observatory.obs_column geom_c WHERE data_c.id = $2 AND data_ct.column_id = data_c.id AND data_ct.table_id = data_t.id AND geoid_ct.table_id = data_t.id AND geoid_ct.column_id = c2c.source_id AND c2c.reltype = ''geom_ref'' AND geom_c.id = c2c.target_id AND CASE WHEN $3 IS NULL THEN True ELSE $3 = timespan END AND CASE WHEN $1 IS NULL THEN True ELSE $1 = geom_c.id END ORDER BY geom_c.weight DESC, data_t.timespan DESC LIMIT 1 ' INTO timespan, geometry_id USING geometry_id, (column_ids)[1], timespan; END IF; RETURN QUERY EXECUTE ' WITH geomref AS ( SELECT ct.table_id id FROM observatory.OBS_column_to_column c2c, observatory.OBS_column_table ct WHERE c2c.reltype = ''geom_ref'' AND c2c.target_id = $1 AND c2c.source_id = ct.column_id ), column_ids as ( select row_number() over () as no, a.column_id as column_id from (select unnest($2) as column_id) a ) SELECT row_to_json(a) from ( select colname, tablename, aggregate, name, type, c.description, $1 AS boundary_id FROM column_ids, observatory.OBS_column c, observatory.OBS_column_table ct, observatory.OBS_table t WHERE column_ids.column_id = c.id AND c.id = ct.column_id AND t.id = ct.table_id AND t.timespan = $3 AND t.id in (SELECT id FROM geomref) order by column_ids.no ) a ' USING geometry_id, column_ids, timespan RETURN; END; $$ LANGUAGE plpgsql; --Test point cause Stuart always seems to make random points in the water CREATE OR REPLACE FUNCTION cdb_observatory._TestPoint() RETURNS geometry(Point, 4326) AS $$ BEGIN -- new york city RETURN ST_SetSRID(ST_Point( -73.936669, 40.704512), 4326); END; $$ LANGUAGE plpgsql; --Test polygon cause Stuart always seems to make random points in the water -- TODO: remove as it's not used anywhere? CREATE OR REPLACE FUNCTION cdb_observatory._TestArea() RETURNS geometry(Geometry, 4326) AS $$ BEGIN -- Buffer NYC point by 500 meters RETURN ST_Buffer(cdb_observatory._TestPoint()::geography, 500)::geometry; END; $$ LANGUAGE plpgsql; --Problematic test area that tends to cause errors CREATE OR REPLACE FUNCTION cdb_observatory._ProblemTestArea() RETURNS geometry(Geometry, 4326) AS $$ BEGIN RETURN 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4326), -73.9366690032303 - -104.729102126902, 40.7045120351809 - 39.620441302097); END; $$ LANGUAGE plpgsql; --Used to expand a column based response to a table based one. Give it the desired --columns and it will return a partial query for rolling them out to a table. CREATE OR REPLACE FUNCTION cdb_observatory._OBS_BuildSnapshotQuery(names text[]) RETURNS TEXT AS $$ DECLARE q text; i numeric; BEGIN q := 'SELECT '; FOR i IN 1..array_upper(names,1) LOOP q = q || format(' vals[%s] As %I', i, names[i]); IF i < array_upper(names, 1) THEN q= q || ','; END IF; END LOOP; RETURN q; END; $$ LANGUAGE plpgsql; -- Function that replaces all non digits or letters with _ trims and lowercases the -- passed measure name CREATE OR REPLACE FUNCTION cdb_observatory._OBS_StandardizeMeasureName(measure_name text) RETURNS text AS $$ DECLARE result text; BEGIN -- Turn non letter or digits to _ result = regexp_replace(measure_name, '[^\dA-Za-z]+','_', 'g'); -- Remove duplicate _'s result = regexp_replace(result,'_{2,}','_', 'g'); -- Trim _'s from beginning and end result = trim(both '_' from result); result = lower(result); RETURN result; END; $$ LANGUAGE plpgsql; -- Function that returns the currently deployed obs_dump_version from the -- remote table of the same name. CREATE OR REPLACE FUNCTION cdb_observatory.OBS_DumpVersion( ) RETURNS TEXT AS $$ DECLARE result text; BEGIN EXECUTE ' SELECT MAX(dump_id) FROM observatory.obs_dump_version ' INTO result; RETURN result; END; $$ LANGUAGE plpgsql; -- Function we can call to raise an exception in the midst of a SQL statement CREATE OR REPLACE FUNCTION cdb_observatory._OBS_RaiseNotice( message TEXT ) RETURNS TEXT AS $$ BEGIN RAISE NOTICE '%', message; RETURN NULL; END; $$ LANGUAGE plpgsql; -- Create a function that always returns the first non-NULL item CREATE OR REPLACE FUNCTION cdb_observatory.first_agg ( anyelement, anyelement ) RETURNS anyelement LANGUAGE SQL IMMUTABLE STRICT AS $$ SELECT $1; $$; DROP AGGREGATE IF EXISTS cdb_observatory.FIRST (anyelement); -- And then wrap an aggregate around it CREATE AGGREGATE cdb_observatory.FIRST ( sfunc = cdb_observatory.first_agg, basetype = anyelement, stype = anyelement ); --Functions for augmenting specific tables -------------------------------------------------------------------------------- -- Creates a table of demographic snapshot CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetDemographicSnapshot(geom geometry(Geometry, 4326), timespan text DEFAULT NULL, boundary_id text DEFAULT NULL ) RETURNS SETOF JSON AS $$ DECLARE meta JSON; BEGIN boundary_id = COALESCE(boundary_id, 'us.census.tiger.census_tract'); EXECUTE $query$ SELECT cdb_observatory.OBS_GetMeta($1, ('[ ' || '{"numer_id": "us.census.acs.B01003001", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B01001002", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B01001026", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B01002001", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B03002003", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B03002004", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B03002006", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B03002012", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B03002005", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B03002008", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B03002009", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B03002002", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B11001001", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B15003001", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B15003017", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B15003019", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B15003020", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B15003021", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B15003022", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B15003023", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19013001", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19083001", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19301001", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B25001001", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B25002003", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B25004002", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B25004004", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B25058001", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B25071001", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B25075001", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B25075025", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B25081002", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B08134001", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B08134002", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B08134003", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B08134004", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B08134005", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B08134006", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B08134007", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B08134008", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B08134009", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B08134010", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B08135001", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001002", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001003", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001004", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001005", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001006", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001007", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001008", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001009", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001010", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001011", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001012", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001013", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001014", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001015", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001016", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '},' || '{"numer_id": "us.census.acs.B19001017", "numer_timespan": ' || $2 || ', "geom_id": ' || $3 || '}' || ']')::JSON) $query$ INTO meta USING geom, COALESCE('"' || timespan || '"', 'null'), COALESCE('"' || boundary_id || '"', 'null'); RETURN QUERY EXECUTE $query$ WITH vals AS (SELECT JSON_Array_Elements(data)->'value' val, JSON_Array_Elements($2) meta FROM cdb_observatory.OBS_GetData( ARRAY[($1, 1)::geomval], $2)) SELECT JSON_Build_Object( 'value', val, 'id', meta->'numer_id', 'name', meta->'numer_name', 'type', meta->'numer_type', 'description', meta->'numer_description' ) FROM vals $query$ USING geom, meta RETURN; END; $$ LANGUAGE plpgsql; CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetMeta( geom geometry(Geometry, 4326), params JSON, max_timespan_rank INTEGER DEFAULT NULL, -- cutoff for timespan ranks when there's ambiguity max_score_rank INTEGER DEFAULT NULL, -- cutoff for geom ranks when there's ambiguity target_geoms INTEGER DEFAULT NULL ) RETURNS JSON AS $$ DECLARE numer_filters TEXT[]; geom_filters TEXT[]; meta_filter_clause TEXT; scores_clause TEXT; result JSON; BEGIN IF max_timespan_rank IS NULL THEN max_timespan_rank := 1; END IF; IF max_score_rank IS NULL THEN max_score_rank := 1; END IF; numer_filters := (SELECT Array_Agg(val) FILTER (WHERE val IS NOT NULL) FROM (SELECT (JSON_Array_Elements(params))->>'numer_id' val) foo); geom_filters := (SELECT Array_Agg(val) FILTER (WHERE val IS NOT NULL) FROM (SELECT (JSON_Array_Elements(params))->>'geom_id' val) bar); meta_filter_clause := '(m.numer_id = ANY ($6) OR m.geom_id = ANY ($7))'; scores_clause := 'SELECT * FROM cdb_observatory._OBS_GetGeometryScores($1, (SELECT Array_Agg(geom_id) FROM meta), $2) scores '; IF JSON_Array_Length(params) = 1 THEN IF numer_filters IS NULL AND geom_filters IS NOT NULL THEN meta_filter_clause := 'm.geom_id = ($7)[1]'; ELSIF geom_filters IS NULL AND numer_filters IS NOT NULL THEN meta_filter_clause := 'm.numer_id = ($6)[1]'; ELSIF numer_filters IS NOT NULL AND geom_filters IS NOT NULL THEN meta_filter_clause := 'm.numer_id = ($6)[1] AND m.geom_id = ($7)[1]'; ELSE RAISE EXCEPTION 'Must pass either numer_id or geom_id to every key in GetMeta'; END IF; IF geom_filters IS NOT NULL AND numer_filters IS NOT NULL THEN scores_clause := 'SELECT 1 score, null, geom_tid table_id, geom_id column_id, null, null, null, null, null, null FROM meta '; END IF; END IF; EXECUTE format($string$ WITH _filters AS (SELECT generate_series(1, array_length($3, 1)) id, (unnest($3))->>'numer_id' numer_id, (unnest($3))->>'denom_id' denom_id, (unnest($3))->>'geom_id' geom_id, (unnest($3))->>'numer_timespan' numer_timespan, (unnest($3))->>'geom_timespan' geom_timespan, (unnest($3))->>'normalization' normalization ), meta AS (SELECT id, f.numer_id, CASE WHEN f.numer_id IS NULL THEN NULL ELSE numer_aggregate END numer_aggregate, CASE WHEN f.numer_id IS NULL THEN NULL ELSE numer_colname END numer_colname, CASE WHEN f.numer_id IS NULL THEN NULL ELSE numer_geomref_colname END numer_geomref_colname, CASE WHEN f.numer_id IS NULL THEN NULL ELSE numer_tablename END numer_tablename, CASE WHEN f.numer_id IS NULL THEN NULL ELSE numer_type END numer_type, CASE WHEN f.numer_id IS NULL THEN NULL ELSE numer_name END numer_name, CASE WHEN f.numer_id IS NULL THEN NULL ELSE m.numer_timespan END numer_timespan, CASE WHEN f.numer_id IS NULL THEN NULL ELSE m.denom_id END denom_id, CASE WHEN f.numer_id IS NULL THEN NULL ELSE denom_aggregate END denom_aggregate, CASE WHEN f.numer_id IS NULL THEN NULL ELSE denom_colname END denom_colname, CASE WHEN f.numer_id IS NULL THEN NULL ELSE denom_geomref_colname END denom_geomref_colname, CASE WHEN f.numer_id IS NULL THEN NULL ELSE denom_tablename END denom_tablename, CASE WHEN f.numer_id IS NULL THEN NULL ELSE denom_name END denom_name, CASE WHEN f.numer_id IS NULL THEN NULL ELSE denom_type END denom_type, CASE WHEN f.numer_id IS NULL THEN NULL ELSE denom_reltype END denom_reltype, m.geom_id, m.geom_timespan, geom_colname, geom_tid, geom_geomref_colname, geom_tablename, geom_name, geom_type, normalization FROM observatory.obs_meta m JOIN _filters f ON CASE WHEN f.numer_id IS NULL THEN m.geom_id ELSE m.numer_id END = CASE WHEN f.numer_id IS NULL THEN f.geom_id ELSE f.numer_id END WHERE %s AND (m.numer_id = f.numer_id OR COALESCE(f.numer_id, '') = '') AND (m.denom_id = f.denom_id OR COALESCE(f.denom_id, '') = '') AND (m.geom_id = f.geom_id OR COALESCE(f.geom_id, '') = '') AND (m.geom_timespan = f.geom_timespan OR COALESCE(f.geom_timespan, '') = '') AND (m.numer_timespan = f.numer_timespan OR COALESCE(f.numer_timespan, '') = '') ), scores AS ( %s ), groups AS (SELECT id, scores.score, numer_timespan, dense_rank() OVER (PARTITION BY id ORDER BY numer_timespan DESC) timespan_rank, dense_rank() OVER (PARTITION BY id ORDER BY score DESC) score_rank, json_build_object( 'id', id, 'numer_id', numer_id, 'timespan_rank', dense_rank() OVER (PARTITION BY id ORDER BY numer_timespan DESC), 'score_rank', dense_rank() OVER (PARTITION BY id ORDER BY score DESC), 'score', scores.score, 'numer_aggregate', cdb_observatory.FIRST(meta.numer_aggregate), 'numer_colname', cdb_observatory.FIRST(meta.numer_colname), 'numer_geomref_colname', cdb_observatory.FIRST(meta.numer_geomref_colname), 'numer_tablename', cdb_observatory.FIRST(meta.numer_tablename), 'numer_type', cdb_observatory.FIRST(meta.numer_type), --'numer_description', cdb_observatory.FIRST(meta.numer_description), --'numer_t_description', cdb_observatory.FIRST(meta.numer_t_description), 'denom_aggregate', cdb_observatory.FIRST(meta.denom_aggregate), 'denom_colname', cdb_observatory.FIRST(denom_colname), 'denom_geomref_colname', cdb_observatory.FIRST(denom_geomref_colname), 'denom_tablename', cdb_observatory.FIRST(denom_tablename), 'denom_type', cdb_observatory.FIRST(meta.denom_type), 'denom_reltype', cdb_observatory.FIRST(meta.denom_reltype), --'denom_description', cdb_observatory.FIRST(meta.denom_description), --'denom_t_description', cdb_observatory.FIRST(meta.denom_t_description), 'geom_colname', cdb_observatory.FIRST(geom_colname), 'geom_geomref_colname', cdb_observatory.FIRST(geom_geomref_colname), 'geom_tablename', cdb_observatory.FIRST(geom_tablename), 'geom_type', cdb_observatory.FIRST(meta.geom_type), 'geom_timespan', cdb_observatory.FIRST(meta.geom_timespan), --'geom_description', cdb_observatory.FIRST(meta.geom_description), --'geom_t_description', cdb_observatory.FIRST(meta.geom_t_description), 'numer_timespan', cdb_observatory.FIRST(numer_timespan), 'numer_name', cdb_observatory.FIRST(numer_name), 'denom_name', cdb_observatory.FIRST(denom_name), 'geom_name', cdb_observatory.FIRST(geom_name), 'normalization', cdb_observatory.FIRST(normalization), 'denom_id', denom_id, 'geom_id', meta.geom_id ) metadata FROM meta, scores WHERE meta.geom_id = scores.column_id AND meta.geom_tid = scores.table_id GROUP BY id, score, numer_id, denom_id, geom_id, numer_timespan ) SELECT JSON_AGG(metadata ORDER BY id) FROM groups WHERE timespan_rank <= $4 AND score_rank <= $5 $string$, meta_filter_clause, scores_clause) INTO result USING CASE WHEN ST_GeometryType(geom) = 'ST_Point' THEN ST_Buffer(geom::geography, 200)::geometry(geometry, 4326) ELSE geom END, target_geoms, (SELECT ARRAY(SELECT json_array_elements_text(params))::json[]), max_timespan_rank, max_score_rank, numer_filters, geom_filters ; RETURN result; END; $$ LANGUAGE plpgsql IMMUTABLE; CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetMeasure( geom geometry(Geometry, 4326), measure_id TEXT, normalize TEXT DEFAULT NULL, boundary_id TEXT DEFAULT NULL, time_span TEXT DEFAULT NULL, simplification NUMERIC DEFAULT 0.00001 ) RETURNS NUMERIC AS $$ DECLARE geom_type TEXT; params JSON; map_type TEXT; result Numeric; numer_aggregate TEXT; BEGIN IF geom IS NULL THEN RETURN NULL; END IF; IF simplification IS NOT NULL THEN geom := ST_Simplify(geom, simplification); END IF; IF ST_GeometryType(geom) = 'ST_Point' THEN geom_type := 'point'; ELSIF ST_GeometryType(geom) IN ('ST_Polygon', 'ST_MultiPolygon') THEN geom_type := 'polygon'; geom := ST_CollectionExtract(ST_MakeValid(geom), 3); ELSE RAISE EXCEPTION 'Invalid geometry type (%), can only handle ''ST_Point'', ''ST_Polygon'', and ''ST_MultiPolygon''', ST_GeometryType(geom); END IF; params := (SELECT cdb_observatory.OBS_GetMeta( geom, JSON_Build_Array(JSON_Build_Object('numer_id', measure_id, 'geom_id', boundary_id, 'numer_timespan', time_span )), 1, 1, 500)); numer_aggregate := params->0->>'numer_aggregate'; IF normalize ILIKE 'area%' AND numer_aggregate ILIKE 'sum' THEN map_type := 'areaNormalized'; ELSIF normalize ILIKE 'denom%' THEN map_type := 'denominated'; ELSIF normalize ILIKE 'pre%' THEN map_type := 'predenominated'; ELSE -- defaults: area normalization for point if it's possible and none for -- polygon or non-summable point IF geom_type = 'point' AND numer_aggregate ILIKE 'sum' THEN map_type := 'areaNormalized'; ELSE map_type := 'predenominated'; END IF; END IF; params := JSON_Build_Array(JSONB_Set((params::JSONB)->0, '{normalization}', to_jsonb(map_type))::JSON); IF params->0->>'geom_id' IS NULL THEN RAISE NOTICE 'No boundary found for geom'; RETURN NULL; ELSE RAISE NOTICE 'Using boundary %', params->0->>'geom_id'; END IF; EXECUTE $query$ SELECT (data->0->>'value')::Numeric FROM cdb_observatory.OBS_GetData(ARRAY[($1, 1)::geomval], $2) $query$ INTO result USING geom, params; RETURN result; END; $$ LANGUAGE plpgsql IMMUTABLE; CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetMeasureById( geom_ref TEXT, measure_id TEXT, boundary_id TEXT, time_span TEXT DEFAULT NULL ) RETURNS NUMERIC AS $$ DECLARE result NUMERIC; BEGIN IF geom_ref IS NULL THEN RETURN NULL; ELSIF boundary_id IS NULL THEN RETURN NULL; END IF; EXECUTE $query$ SELECT data->0->>'value' FROM cdb_observatory.OBS_GetData(Array[$1], cdb_observatory.OBS_GetMeta(ST_MakeEnvelope(-180, -90, 180, 90, 4326), JSON_Build_Array(JSON_Build_Object( 'numer_id', $2, 'geom_id', $3, 'numer_timespan', $4, 'normalization', 'predenominated' )))) $query$ INTO result USING geom_ref, measure_id, boundary_id, time_span; RETURN result; END; $$ LANGUAGE plpgsql; -- GetData that obtains data from array of geomrefs CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetData( geomrefs text[], params JSON ) RETURNS TABLE ( id TEXT, data JSON ) AS $$ DECLARE colspecs TEXT; tables TEXT; obs_wheres TEXT; user_wheres TEXT; q text; BEGIN IF params IS NULL OR JSON_ARRAY_LENGTH(params) = 0 THEN RETURN QUERY EXECUTE $query$ SELECT NULL::TEXT, NULL::JSON LIMIT 0 $query$; RETURN; END IF; EXECUTE $query$ WITH _meta AS (SELECT generate_series(1, array_length($1, 1)) colid, (unnest($1))->>'id' id, (unnest($1))->>'numer_id' numer_id, (unnest($1))->>'numer_aggregate' numer_aggregate, (unnest($1))->>'numer_colname' numer_colname, (unnest($1))->>'numer_geomref_colname' numer_geomref_colname, (unnest($1))->>'numer_tablename' numer_tablename, (unnest($1))->>'numer_type' numer_type, (unnest($1))->>'denom_id' denom_id, (unnest($1))->>'denom_aggregate' denom_aggregate, (unnest($1))->>'denom_colname' denom_colname, (unnest($1))->>'denom_geomref_colname' denom_geomref_colname, (unnest($1))->>'denom_tablename' denom_tablename, (unnest($1))->>'denom_type' denom_type, (unnest($1))->>'denom_reltype' denom_reltype, (unnest($1))->>'geom_id' geom_id, (unnest($1))->>'geom_colname' geom_colname, (unnest($1))->>'geom_geomref_colname' geom_geomref_colname, (unnest($1))->>'geom_tablename' geom_tablename, (unnest($1))->>'geom_type' geom_type, (unnest($1))->>'geom_timespan' geom_timespan, (unnest($1))->>'numer_timespan' numer_timespan, (unnest($1))->>'normalization' normalization, (unnest($1))->>'api_method' api_method, (unnest($1))->'api_args' api_args ) SELECT String_Agg( -- numeric 'JSON_Build_Object(' || CASE WHEN api_method IS NOT NULL THEN '''value'', ' || 'cdb_observatory.FIRST( ' || api_method || '.' || numer_colname || ')::' || numer_type -- numeric internal values WHEN LOWER(numer_type) LIKE 'numeric' THEN '''value'', ' || CASE -- denominated WHEN LOWER(normalization) LIKE 'denom%' OR (normalization IS NULL AND denom_id IS NOT NULL) THEN 'cdb_observatory.FIRST(' || numer_tablename || '.' || numer_colname || ' / NullIf(' || denom_tablename || '.' || denom_colname || ', 0))' -- areaNormalized WHEN LOWER(normalization) LIKE 'area%' OR (normalization IS NULL AND numer_aggregate ILIKE 'sum') THEN 'cdb_observatory.FIRST(' || numer_tablename || '.' || numer_colname || ' / (ST_Area(' || geom_tablename || '.' || geom_colname || '::Geography)/1000000))' -- prenormalized ELSE 'cdb_observatory.FIRST(' || numer_tablename || '.' || numer_colname || ')' END || ':: ' || numer_type -- categorical/text WHEN LOWER(numer_type) LIKE 'text' THEN '''value'', ' || 'cdb_observatory.FIRST(' || numer_tablename || '.' || numer_colname || ') ' -- geometry WHEN numer_id IS NULL THEN '''geomref'', ' || 'cdb_observatory.FIRST(' || geom_tablename || '.' || geom_geomref_colname || '), ' || '''value'', ' || 'cdb_observatory.FIRST(' || geom_tablename || '.' || geom_colname || ')' ELSE '' END || ')', ', ') AS colspecs, (SELECT String_Agg(DISTINCT CASE -- External API WHEN tablename LIKE 'cdb_observatory.%' THEN 'LATERAL (SELECT * FROM ' || tablename || ') ' || REPLACE(split_part(tablename, '(', 1), 'cdb_observatory.', '') -- Internal obs_ table ELSE 'observatory.' || tablename END, ', ') FROM ( SELECT DISTINCT UNNEST(tablenames_ary) tablename FROM ( SELECT ARRAY_AGG(numer_tablename) || ARRAY_AGG(denom_tablename) || ARRAY_AGG(geom_tablename) || ARRAY_AGG('cdb_observatory.' || api_method || '(_geomrefs.id' || COALESCE(', ' || (SELECT STRING_AGG(REPLACE(val::text, '"', ''''), ', ') FROM (SELECT json_array_elements(api_args) as val) as vals), '') || ')') tablenames_ary ) tablenames_inner ) tablenames_outer) tablenames, String_Agg(numer_tablename || '.' || numer_geomref_colname || ' = ' || geom_tablename || '.' || geom_geomref_colname || Coalesce(' AND ' || numer_tablename || '.' || numer_geomref_colname || ' = ' || denom_tablename || '.' || denom_geomref_colname, ''), ' AND ') AS obs_wheres, String_Agg(geom_tablename || '.' || geom_geomref_colname || ' = ' || '_geomrefs.id', ' AND ') AS user_wheres FROM _meta ; $query$ INTO colspecs, tables, obs_wheres, user_wheres USING (SELECT ARRAY(SELECT json_array_elements_text(params))::json[]); RETURN QUERY EXECUTE format($query$ WITH _geomrefs AS (SELECT UNNEST($1) as id) SELECT _geomrefs.id, Array_to_JSON(ARRAY[%s]::JSON[]) FROM _geomrefs, %s %s GROUP BY _geomrefs.id ORDER BY _geomrefs.id $query$, colspecs, tables, 'WHERE ' || NULLIF(ARRAY_TO_STRING(ARRAY[obs_wheres, user_wheres], ' AND '), '')) USING geomrefs; RETURN; END; $$ LANGUAGE plpgsql; -- GetData that obtains data from array of (geom, id) geomvals. CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetData( geomvals geomval[], params JSON, merge BOOLEAN DEFAULT True ) RETURNS TABLE ( id INT, data JSON ) AS $$ DECLARE colspecs TEXT; geomrefs TEXT; tables TEXT; obs_wheres TEXT; user_wheres TEXT; BEGIN IF params IS NULL OR JSON_ARRAY_LENGTH(params) = 0 THEN RETURN QUERY EXECUTE $query$ SELECT NULL::INT, NULL::JSON LIMIT 0 $query$; RETURN; END IF; EXECUTE $query$ WITH _meta AS (SELECT generate_series(1, array_length($1, 1)) colid, (unnest($1))->>'id' id, (unnest($1))->>'numer_id' numer_id, (unnest($1))->>'numer_aggregate' numer_aggregate, (unnest($1))->>'numer_colname' numer_colname, (unnest($1))->>'numer_geomref_colname' numer_geomref_colname, (unnest($1))->>'numer_tablename' numer_tablename, (unnest($1))->>'numer_type' numer_type, (unnest($1))->>'denom_id' denom_id, (unnest($1))->>'denom_aggregate' denom_aggregate, (unnest($1))->>'denom_colname' denom_colname, (unnest($1))->>'denom_geomref_colname' denom_geomref_colname, (unnest($1))->>'denom_tablename' denom_tablename, (unnest($1))->>'denom_type' denom_type, (unnest($1))->>'denom_reltype' denom_reltype, (unnest($1))->>'geom_id' geom_id, (unnest($1))->>'geom_colname' geom_colname, (unnest($1))->>'geom_geomref_colname' geom_geomref_colname, (unnest($1))->>'geom_tablename' geom_tablename, (unnest($1))->>'geom_type' geom_type, (unnest($1))->>'numer_timespan' numer_timespan, (unnest($1))->>'geom_timespan' geom_timespan, (unnest($1))->>'normalization' normalization, (unnest($1))->>'api_method' api_method, (unnest($1))->'api_args' api_args ) SELECT String_Agg( 'JSON_Build_Object(' || CASE -- api-delivered values WHEN api_method IS NOT NULL THEN '''value'', ' || 'cdb_observatory.FIRST( ' || api_method || '.' || numer_colname || ')::' || numer_type -- numeric internal values WHEN LOWER(numer_type) LIKE 'numeric' THEN '''value'', ' || CASE -- denominated WHEN LOWER(normalization) LIKE 'denom%' OR (normalization IS NULL AND LOWER(denom_reltype) LIKE 'denominator') THEN ' CASE ' || -- denominated point-in-poly or user polygon is same as OBS polygon ' WHEN ST_GeometryType(cdb_observatory.FIRST(_geoms.geom)) = ''ST_Point'' ' || ' OR cdb_observatory.FIRST(_geoms.geom = ' || geom_tablename || '.' || geom_colname || ')' || ' THEN cdb_observatory.FIRST(' || numer_tablename || '.' || numer_colname || ' / NullIf(' || denom_tablename || '.' || denom_colname || ', 0))' || -- denominated polygon interpolation -- SUM (numer * (% OBS geom in user geom)) / SUM (denom * (% OBS geom in user geom)) ' ELSE ' || ' SUM(' || numer_tablename || '.' || numer_colname || ' ' || ' * CASE WHEN ST_Within(_geoms.geom, ' || geom_tablename || '.' || geom_colname || ') ' || ' THEN ST_Area(_geoms.geom) / ST_Area(' || geom_tablename || '.' || geom_colname || ') ' || ' WHEN ST_Within(' || geom_tablename || '.' || geom_colname || ', _geoms.geom) ' || ' THEN 1 ' || ' ELSE (ST_Area(ST_Intersection(_geoms.geom, ' || geom_tablename || '.' || geom_colname || ')) ' || ' / ST_Area(' || geom_tablename || '.' || geom_colname || '))' || ' END) / ' ' NULLIF(SUM(' || denom_tablename || '.' || denom_colname || ' ' || ' * CASE WHEN ST_Within(_geoms.geom, ' || geom_tablename || '.' || geom_colname || ') ' || ' THEN ST_Area(_geoms.geom) / ST_Area(' || geom_tablename || '.' || geom_colname || ') ' || ' WHEN ST_Within(' || geom_tablename || '.' || geom_colname || ', _geoms.geom) ' || ' THEN 1 ' || ' ELSE (ST_Area(ST_Intersection(_geoms.geom, ' || geom_tablename || '.' || geom_colname || ')) ' || ' / ST_Area(' || geom_tablename || '.' || geom_colname || '))' || ' END), 0) ' || ' / (COUNT(*) / COUNT(distinct ' || geom_tablename || '.' || geom_geomref_colname || ')) ' || ' END ' -- areaNormalized WHEN LOWER(normalization) LIKE 'area%' OR (normalization IS NULL AND numer_aggregate ILIKE 'sum') THEN ' CASE ' || -- areaNormalized point-in-poly or user polygon is the same as OBS polygon ' WHEN ST_GeometryType(cdb_observatory.FIRST(_geoms.geom)) = ''ST_Point'' ' || ' OR cdb_observatory.FIRST(_geoms.geom = ' || geom_tablename || '.' || geom_colname || ')' || ' THEN cdb_observatory.FIRST(' || numer_tablename || '.' || numer_colname || ' / (ST_Area(' || geom_tablename || '.' || geom_colname || '::Geography)/1000000)) ' || -- areaNormalized polygon interpolation -- SUM (numer * (% OBS geom in user geom)) / area of big geom ' ELSE ' || --' NULL END ' ' SUM((' || numer_tablename || '.' || numer_colname || ') ' || ' * CASE WHEN ST_Within(_geoms.geom, ' || geom_tablename || '.' || geom_colname || ') THEN 1 ' || ' WHEN ST_Within(' || geom_tablename || '.' || geom_colname || ', _geoms.geom) THEN ' || ' ST_Area(' || geom_tablename || '.' || geom_colname || ') ' || ' / ST_Area(_geoms.geom)' || ' ELSE (ST_Area(ST_Intersection(_geoms.geom, ' || geom_tablename || '.' || geom_colname || ')) ' || ' / ST_Area(_geoms.geom))' || ' END / (ST_Area(' || geom_tablename || '.' || geom_colname || '::Geography) / 1000000)) ' || ' / (COUNT(*) / COUNT(distinct ' || geom_tablename || '.' || geom_geomref_colname || ')) ' || ' END ' -- median/average measures with universe WHEN LOWER(numer_aggregate) IN ('median', 'average') AND denom_reltype ILIKE 'universe' AND (normalization IS NULL OR LOWER(normalization) LIKE 'pre%') THEN ' CASE ' || -- predenominated point-in-poly or user polygon is the same as OBS- polygon ' WHEN ST_GeometryType(cdb_observatory.FIRST(_geoms.geom)) = ''ST_Point'' ' || ' OR cdb_observatory.FIRST(_geoms.geom = ' || geom_tablename || '.' || geom_colname || ')' || ' THEN cdb_observatory.FIRST(' || numer_tablename || '.' || numer_colname || ') ' || ' ELSE ' || -- predenominated polygon interpolation weighted by universe -- SUM (numer * denom * (% user geom in OBS geom)) / SUM (denom * (% user geom in OBS geom)) -- (10 * 1000 * 1) / (1000 * 1) = 10 -- (10 * 1000 * 1 + 50 * 10 * 1) / (1000 + 10) = 10500 / 10000 = 10.5 ' SUM(' || numer_tablename || '.' || numer_colname || ' * ' || denom_tablename || '.' || denom_colname || ' * CASE WHEN ST_Within(_geoms.geom, ' || geom_tablename || '.' || geom_colname || ') ' || ' THEN ST_Area(_geoms.geom) / ST_Area(' || geom_tablename || '.' || geom_colname || ') ' || ' WHEN ST_Within(' || geom_tablename || '.' || geom_colname || ', _geoms.geom) ' || ' THEN 1 ' || ' ELSE (ST_Area(ST_Intersection(_geoms.geom, ' || geom_tablename || '.' || geom_colname || ')) ' || ' / ST_Area(' || geom_tablename || '.' || geom_colname || '))' || ' END) ' || ' / SUM(' || denom_tablename || '.' || denom_colname || ' * CASE WHEN ST_Within(_geoms.geom, ' || geom_tablename || '.' || geom_colname || ') ' || ' THEN ST_Area(_geoms.geom) / ST_Area(' || geom_tablename || '.' || geom_colname || ') ' || ' WHEN ST_Within(' || geom_tablename || '.' || geom_colname || ', _geoms.geom) ' || ' THEN 1 ' || ' ELSE (ST_Area(ST_Intersection(_geoms.geom, ' || geom_tablename || '.' || geom_colname || ')) ' || ' / ST_Area(' || geom_tablename || '.' || geom_colname || '))' || ' END) ' || ' / (COUNT(*) / COUNT(distinct ' || geom_tablename || '.' || geom_geomref_colname || ')) ' || 'END ' -- prenormalized for summable measures. point or summable only! WHEN numer_aggregate ILIKE 'sum' AND (normalization IS NULL OR LOWER(normalization) LIKE 'pre%') THEN ' CASE ' || -- predenominated point-in-poly or user polygon is the same as OBS- polygon ' WHEN ST_GeometryType(cdb_observatory.FIRST(_geoms.geom)) = ''ST_Point'' ' || ' OR cdb_observatory.FIRST(_geoms.geom = ' || geom_tablename || '.' || geom_colname || ')' || ' THEN cdb_observatory.FIRST(' || numer_tablename || '.' || numer_colname || ') ' || ' ELSE ' || -- predenominated polygon interpolation -- SUM (numer * (% user geom in OBS geom)) ' SUM(' || numer_tablename || '.' || numer_colname || ' ' || ' * CASE WHEN ST_Within(_geoms.geom, ' || geom_tablename || '.' || geom_colname || ') ' || ' THEN ST_Area(_geoms.geom) / ST_Area(' || geom_tablename || '.' || geom_colname || ') ' || ' WHEN ST_Within(' || geom_tablename || '.' || geom_colname || ', _geoms.geom) ' || ' THEN 1 ' || ' ELSE (ST_Area(ST_Intersection(_geoms.geom, ' || geom_tablename || '.' || geom_colname || ')) ' || ' / ST_Area(' || geom_tablename || '.' || geom_colname || '))' || ' END) ' || ' / (COUNT(*) / COUNT(distinct ' || geom_tablename || '.' || geom_geomref_colname || ')) ' || 'END ' -- Everything else. Point only! ELSE ' CASE ' || ' WHEN ST_GeometryType(cdb_observatory.FIRST(_geoms.geom)) = ''ST_Point'' ' || ' OR cdb_observatory.FIRST(_geoms.geom = ' || geom_tablename || '.' || geom_colname || ')' || ' THEN cdb_observatory.FIRST(' || numer_tablename || '.' || numer_colname || ') ' || ' ELSE cdb_observatory._OBS_RaiseNotice(''Cannot perform calculation over polygon for ' || numer_id || '/' || coalesce(denom_id, '') || '/' || geom_id || '/' || numer_timespan || ''')::Numeric ' || ' END ' END || ':: ' || numer_type -- categorical/text WHEN LOWER(numer_type) LIKE 'text' THEN '''value'', ' || 'MODE() WITHIN GROUP (ORDER BY ' || numer_tablename || '.' || numer_colname || ') ' -- geometry WHEN numer_id IS NULL THEN '''geomref'', ' || geom_tablename || '.' || geom_geomref_colname || ', ' || '''value'', ' || 'cdb_observatory.FIRST(' || geom_tablename || '.' || geom_colname || ')::TEXT' -- code below will return the intersection of the user's geom and the -- OBS geom --'"value": "'' || ' || 'cdb_observatory.FIRST(ST_Intersection(_geoms.geom, ' || geom_tablename || -- '.' || geom_colname || '))::TEXT || ''"''' ELSE '' END || ')', ', ') AS colspecs, -- geomrefs, used to separate out rows in case we don't want to merge -- results by user input IDs -- -- api_method and geom_tablename are interchangeable since when an -- api_method is passed, geom_tablename is ignored STRING_AGG(COALESCE(geom_tablename, api_method) || '.' || geom_geomref_colname, ', ') AS geomrefs, (SELECT String_Agg(DISTINCT CASE -- External API WHEN tablename LIKE 'cdb_observatory.%' THEN 'LATERAL (SELECT * FROM ' || tablename || ') ' || REPLACE(split_part(tablename, '(', 1), 'cdb_observatory.', '') -- Internal obs_ table ELSE 'observatory.' || tablename END, ', ') FROM ( SELECT DISTINCT UNNEST(tablenames_ary) tablename FROM ( SELECT ARRAY_AGG(numer_tablename) || ARRAY_AGG(denom_tablename) || ARRAY_AGG(geom_tablename) || ARRAY_AGG('cdb_observatory.' || api_method || '(_geoms.geom' || COALESCE(', ' || (SELECT STRING_AGG(REPLACE(val::text, '"', ''''), ', ') FROM (SELECT json_array_elements(api_args) as val) as vals), '') || ')') tablenames_ary ) tablenames_inner ) tablenames_outer) tablenames, String_Agg(DISTINCT numer_tablename || '.' || numer_geomref_colname || ' = ' || geom_tablename || '.' || geom_geomref_colname || Coalesce(' AND ' || numer_tablename || '.' || numer_geomref_colname || ' = ' || denom_tablename || '.' || denom_geomref_colname, ''), ' AND ') AS obs_wheres, String_Agg('ST_Intersects(' || geom_tablename || '.' || geom_colname || ', _geoms.geom)', ' AND ') AS user_wheres FROM _meta ; $query$ INTO colspecs, geomrefs, tables, obs_wheres, user_wheres USING (SELECT ARRAY(SELECT json_array_elements_text(params))::json[]); RETURN QUERY EXECUTE format($query$ WITH _raw_geoms AS (SELECT (UNNEST($1)).val as id, (UNNEST($1)).geom AS geom), _geoms AS (SELECT id, CASE WHEN (ST_NPoints(geom) > 500) THEN ST_CollectionExtract(ST_MakeValid(ST_SimplifyVW(geom, 0.0001)), 3) ELSE geom END geom FROM _raw_geoms) SELECT _geoms.id::INT, Array_to_JSON(ARRAY[%s]::JSON[]) FROM _geoms, %s %s GROUP BY _geoms.id %s ORDER BY _geoms.id $query$, colspecs, tables, 'WHERE ' || NULLIF(ARRAY_TO_STRING(ARRAY[obs_wheres, user_wheres], ' AND '), ''), CASE WHEN merge IS False THEN ', ' || geomrefs ELSE '' END) USING geomvals; RETURN; END; $$ LANGUAGE plpgsql; CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetCategory( geom geometry(Geometry, 4326), category_id TEXT, boundary_id TEXT DEFAULT NULL, time_span TEXT DEFAULT NULL, simplification NUMERIC DEFAULT 0.00001 ) RETURNS TEXT AS $$ DECLARE geom_type TEXT; params JSON; map_type TEXT; result TEXT; BEGIN IF geom IS NULL THEN RETURN NULL; END IF; IF simplification IS NOT NULL THEN geom := ST_Simplify(geom, simplification); END IF; IF ST_GeometryType(geom) = 'ST_Point' THEN geom_type := 'point'; ELSIF ST_GeometryType(geom) IN ('ST_Polygon', 'ST_MultiPolygon') THEN geom_type := 'polygon'; geom := ST_CollectionExtract(ST_MakeValid(geom), 3); ELSE RAISE EXCEPTION 'Invalid geometry type (%), can only handle ''ST_Point'', ''ST_Polygon'', and ''ST_MultiPolygon''', ST_GeometryType(geom); END IF; params := (SELECT cdb_observatory.OBS_GetMeta( geom, JSON_Build_Array(JSON_Build_Object('numer_id', category_id, 'geom_id', boundary_id, 'numer_timespan', time_span )), 1, 1, 500)); IF params->0->>'geom_id' IS NULL THEN RAISE NOTICE 'No boundary found for geom'; RETURN NULL; ELSE RAISE NOTICE 'Using boundary %', params->0->>'geom_id'; END IF; EXECUTE $query$ SELECT data->0->>'value' FROM cdb_observatory.OBS_GetData(ARRAY[($1, 1)::geomval], $2) $query$ INTO result USING geom, params; RETURN result; END; $$ LANGUAGE plpgsql; CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetUSCensusMeasure( geom geometry(Geometry, 4326), name TEXT, normalize TEXT DEFAULT NULL, boundary_id TEXT DEFAULT NULL, time_span TEXT DEFAULT NULL ) RETURNS NUMERIC AS $$ DECLARE standardized_name text; measure_id text; result Numeric; BEGIN standardized_name = cdb_observatory._OBS_StandardizeMeasureName(name); EXECUTE $string$ SELECT c.id FROM observatory.obs_column c JOIN observatory.obs_column_tag ct ON c.id = ct.column_id WHERE cdb_observatory._OBS_StandardizeMeasureName(c.name) = $1 AND ct.tag_id ILIKE 'us.census%' $string$ INTO measure_id USING standardized_name; EXECUTE 'SELECT cdb_observatory.OBS_GetMeasure($1, $2, $3, $4, $5)' INTO result USING geom, measure_id, normalize, boundary_id, time_span; RETURN result; END; $$ LANGUAGE plpgsql; CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetUSCensusCategory( geom geometry(Geometry, 4326), name TEXT, boundary_id TEXT DEFAULT NULL, time_span TEXT DEFAULT NULL ) RETURNS TEXT AS $$ DECLARE standardized_name TEXT; category_id TEXT; result TEXT; BEGIN standardized_name = cdb_observatory._OBS_StandardizeMeasureName(name); EXECUTE $string$ SELECT c.id FROM observatory.obs_column c --JOIN observatory.obs_column_tag ct -- ON c.id = ct.column_id WHERE cdb_observatory._OBS_StandardizeMeasureName(c.name) = $1 AND c.type ILIKE 'TEXT' AND c.id ILIKE 'us.census%' -- TODO this should be done by tag --AND ct.tag_id = 'us.census.acs.demographics' $string$ INTO category_id USING standardized_name; EXECUTE 'SELECT cdb_observatory.OBS_GetCategory($1, $2, $3, $4)' INTO result USING geom, category_id, boundary_id, time_span; RETURN result; END; $$ LANGUAGE plpgsql; CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetPopulation( geom geometry(Geometry, 4326), normalize TEXT DEFAULT NULL, boundary_id TEXT DEFAULT NULL, time_span TEXT DEFAULT NULL ) RETURNS NUMERIC AS $$ DECLARE population_measure_id TEXT; result Numeric; BEGIN -- TODO use a super-column for global pop population_measure_id := 'us.census.acs.B01003001'; EXECUTE $query$ SELECT cdb_observatory.OBS_GetMeasure( $1, $2, $3, $4, $5 ) LIMIT 1 $query$ INTO result USING geom, population_measure_id, normalize, boundary_id, time_span; RETURN result; END; $$ LANGUAGE plpgsql; CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetSegmentSnapshot( geom geometry(Geometry, 4326), boundary_id text DEFAULT NULL ) RETURNS JSON AS $$ DECLARE meta JSON; data JSON; result JSON; BEGIN boundary_id = COALESCE(boundary_id, 'us.census.tiger.census_tract'); EXECUTE $query$ SELECT cdb_observatory.OBS_GetMeta($1, ('[ ' || '{"numer_id": "us.census.acs.B01003001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B01001002_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B01001026_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B01002001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B03002003_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B03002004_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B03002006_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B03002012_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B05001006_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B08006001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B08006002_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B08301010_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B08006009_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B08006011_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B08006015_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B08006017_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B09001001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B11001001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B14001001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B14001002_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B14001005_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B14001006_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B14001007_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B14001008_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B15003001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B15003017_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B15003022_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B15003023_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B16001001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B16001002_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B16001003_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B17001001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B17001002_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B19013001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B19083001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B19301001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B25001001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B25002003_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B25004002_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B25004004_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B25058001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B25071001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B25075001_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.acs.B25075025_quantile", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.spielman_singleton_segments.X10", "geom_id": ' || $2 || '},' || '{"numer_id": "us.census.spielman_singleton_segments.X55", "geom_id": ' || $2 || '}' || ']')::JSON) $query$ INTO meta USING geom, COALESCE('"' || boundary_id || '"', 'null'); EXECUTE $query$ SELECT data FROM cdb_observatory.OBS_GetData( ARRAY[($1, 1)::geomval], $2) $query$ INTO data USING geom, meta; EXECUTE $query$ WITH els AS (SELECT REPLACE(REPLACE(JSON_Array_Elements($1)->>'numer_id', 'us.census.spielman_singleton_segments.X55', 'x55_segment'), 'us.census.spielman_singleton_segments.X10', 'x10_segment') k, JSON_Array_Elements($2)->>'value' v) SELECT JSON_Object_Agg(k, v) FROM els $query$ INTO result USING meta, data; RETURN result; END; $$ LANGUAGE plpgsql; -- TODO: implement search for timespan CREATE OR REPLACE FUNCTION cdb_observatory._OBS_SearchTables( search_term text, time_span text DEFAULT NULL ) RETURNS table(tablename text, timespan text) As $$ DECLARE out_var text[]; BEGIN IF time_span IS NULL THEN RETURN QUERY EXECUTE 'SELECT tablename::text, timespan::text FROM observatory.obs_table t JOIN observatory.obs_column_table ct ON ct.table_id = t.id JOIN observatory.obs_column c ON ct.column_id = c.id WHERE c.type ILIKE ''geometry'' AND c.id = $1' USING search_term; RETURN; ELSE RETURN QUERY EXECUTE 'SELECT tablename::text, timespan::text FROM observatory.obs_table t JOIN observatory.obs_column_table ct ON ct.table_id = t.id JOIN observatory.obs_column c ON ct.column_id = c.id WHERE c.type ILIKE ''geometry'' AND c.id = $1 AND t.timespan = $2' USING search_term, time_span; RETURN; END IF; END; $$ LANGUAGE plpgsql IMMUTABLE; -- Functions used to search the observatory for measures -------------------------------------------------------------------------------- -- TODO allow the user to specify the boundary to search for measures -- CREATE OR REPLACE FUNCTION cdb_observatory.OBS_Search( search_term text, relevant_boundary text DEFAULT null ) RETURNS TABLE(id text, description text, name text, aggregate text, source text) as $$ DECLARE boundary_term text; BEGIN IF relevant_boundary then boundary_term = ''; else boundary_term = ''; END IF; RETURN QUERY EXECUTE format($string$ SELECT id::text, description::text, name::text, aggregate::text, NULL::TEXT source -- TODO use tags FROM observatory.OBS_column where name ilike '%%' || %L || '%%' or description ilike '%%' || %L || '%%' %s $string$, search_term, search_term,boundary_term); RETURN; END $$ LANGUAGE plpgsql; -- Functions to return the geometry levels that a point is part of -------------------------------------------------------------------------------- -- TODO add test response CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetAvailableBoundaries( geom geometry(Geometry, 4326), timespan text DEFAULT null) RETURNS TABLE(boundary_id text, description text, time_span text, tablename text) as $$ DECLARE timespan_query TEXT DEFAULT ''; BEGIN IF timespan != NULL THEN timespan_query = format('AND timespan = %L', timespan); END IF; RETURN QUERY EXECUTE $string$ SELECT column_id::text As column_id, obs_column.description::text As description, timespan::text As timespan, tablename::text As tablename FROM observatory.OBS_table, observatory.OBS_column_table, observatory.OBS_column WHERE observatory.OBS_column_table.column_id = observatory.obs_column.id AND observatory.OBS_column_table.table_id = observatory.obs_table.id AND observatory.OBS_column.type = 'Geometry' AND ST_Intersects($1, st_setsrid(observatory.obs_table.the_geom, 4326)) $string$ || timespan_query USING geom; RETURN; END $$ LANGUAGE plpgsql; -- Functions the interface works from to identify available numerators, -- denominators, geometries, and timespans CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetAvailableNumerators( bounds GEOMETRY DEFAULT NULL, filter_tags TEXT[] DEFAULT NULL, denom_id TEXT DEFAULT NULL, geom_id TEXT DEFAULT NULL, timespan TEXT DEFAULT NULL ) RETURNS TABLE ( numer_id TEXT, numer_name TEXT, numer_description TEXT, numer_weight NUMERIC, numer_license TEXT, numer_source TEXT, numer_type TEXT, numer_aggregate TEXT, numer_extra JSONB, numer_tags JSONB, valid_denom BOOLEAN, valid_geom BOOLEAN, valid_timespan BOOLEAN ) AS $$ DECLARE geom_clause TEXT; BEGIN filter_tags := COALESCE(filter_tags, (ARRAY[])::TEXT[]); denom_id := COALESCE(denom_id, ''); geom_id := COALESCE(geom_id, ''); timespan := COALESCE(timespan, ''); IF bounds IS NULL THEN geom_clause := ''; ELSE geom_clause := 'ST_Intersects(the_geom, $5) AND'; END IF; RETURN QUERY EXECUTE format($string$ SELECT numer_id::TEXT, numer_name::TEXT, numer_description::TEXT, numer_weight::NUMERIC, NULL::TEXT license, NULL::TEXT source, numer_type numer_type, numer_aggregate numer_aggregate, numer_extra::JSONB numer_extra, numer_tags numer_tags, $1 = ANY(denoms) valid_denom, $2 = ANY(geoms) valid_geom, $3 = ANY(timespans) valid_timespan FROM observatory.obs_meta_numer WHERE %s (numer_tags ?& $4 OR CARDINALITY($4) = 0) $string$, geom_clause) USING denom_id, geom_id, timespan, filter_tags, bounds; RETURN; END $$ LANGUAGE plpgsql; CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetAvailableDenominators( bounds GEOMETRY DEFAULT NULL, filter_tags TEXT[] DEFAULT NULL, numer_id TEXT DEFAULT NULL, geom_id TEXT DEFAULT NULL, timespan TEXT DEFAULT NULL ) RETURNS TABLE ( denom_id TEXT, denom_name TEXT, denom_description TEXT, denom_weight NUMERIC, denom_license TEXT, denom_source TEXT, denom_type TEXT, denom_aggregate TEXT, denom_extra JSONB, denom_tags JSONB, valid_numer BOOLEAN, valid_geom BOOLEAN, valid_timespan BOOLEAN ) AS $$ DECLARE geom_clause TEXT; BEGIN filter_tags := COALESCE(filter_tags, (ARRAY[])::TEXT[]); numer_id := COALESCE(numer_id, ''); geom_id := COALESCE(geom_id, ''); timespan := COALESCE(timespan, ''); IF bounds IS NULL THEN geom_clause := ''; ELSE geom_clause := 'ST_Intersects(the_geom, $5) AND'; END IF; RETURN QUERY EXECUTE format($string$ SELECT denom_id::TEXT, denom_name::TEXT, denom_description::TEXT, denom_weight::NUMERIC, NULL::TEXT license, NULL::TEXT source, denom_type::TEXT, denom_aggregate::TEXT, denom_extra::JSONB, denom_tags::JSONB, $1 = ANY(numers) valid_numer, $2 = ANY(geoms) valid_geom, $3 = ANY(timespans) valid_timespan FROM observatory.obs_meta_denom WHERE %s (denom_tags ?& $4 OR CARDINALITY($4) = 0) $string$, geom_clause) USING numer_id, geom_id, timespan, filter_tags, bounds; RETURN; END $$ LANGUAGE plpgsql; CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetAvailableGeometries( bounds GEOMETRY DEFAULT NULL, filter_tags TEXT[] DEFAULT NULL, numer_id TEXT DEFAULT NULL, denom_id TEXT DEFAULT NULL, timespan TEXT DEFAULT NULL ) RETURNS TABLE ( geom_id TEXT, geom_name TEXT, geom_description TEXT, geom_weight NUMERIC, geom_aggregate TEXT, geom_license TEXT, geom_source TEXT, valid_numer BOOLEAN, valid_denom BOOLEAN, valid_timespan BOOLEAN, score NUMERIC, numtiles BIGINT, notnull_percent NUMERIC, numgeoms NUMERIC, percentfill NUMERIC, estnumgeoms NUMERIC, meanmediansize NUMERIC ) AS $$ DECLARE geom_clause TEXT; BEGIN filter_tags := COALESCE(filter_tags, (ARRAY[])::TEXT[]); numer_id := COALESCE(numer_id, ''); denom_id := COALESCE(denom_id, ''); timespan := COALESCE(timespan, ''); IF bounds IS NULL THEN geom_clause := ''; ELSE geom_clause := 'ST_Intersects(the_geom, $5) AND'; END IF; RETURN QUERY EXECUTE format($string$ WITH available_geoms AS ( SELECT geom_id::TEXT, geom_name::TEXT, geom_description::TEXT, geom_weight::NUMERIC, NULL::TEXT geom_aggregate, NULL::TEXT license, NULL::TEXT source, $1 = ANY(numers) valid_numer, $2 = ANY(denoms) valid_denom, $3 = ANY(timespans) valid_timespan FROM observatory.obs_meta_geom WHERE %s (geom_tags ?& $4 OR CARDINALITY($4) = 0) ), scores AS ( SELECT * FROM cdb_observatory._OBS_GetGeometryScores($5, (SELECT ARRAY_AGG(geom_id) FROM available_geoms) ) ) SELECT available_geoms.*, score, numtiles, notnull_percent, numgeoms, percentfill, estnumgeoms, meanmediansize FROM available_geoms, scores WHERE available_geoms.geom_id = scores.column_id $string$, geom_clause) USING numer_id, denom_id, timespan, filter_tags, bounds; RETURN; END $$ LANGUAGE plpgsql; CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetAvailableTimespans( bounds GEOMETRY DEFAULT NULL, filter_tags TEXT[] DEFAULT NULL, numer_id TEXT DEFAULT NULL, denom_id TEXT DEFAULT NULL, geom_id TEXT DEFAULT NULL ) RETURNS TABLE ( timespan_id TEXT, timespan_name TEXT, timespan_description TEXT, timespan_weight NUMERIC, timespan_aggregate TEXT, timespan_license TEXT, timespan_source TEXT, valid_numer BOOLEAN, valid_denom BOOLEAN, valid_geom BOOLEAN ) AS $$ DECLARE geom_clause TEXT; BEGIN filter_tags := COALESCE(filter_tags, (ARRAY[])::TEXT[]); numer_id := COALESCE(numer_id, ''); denom_id := COALESCE(denom_id, ''); geom_id := COALESCE(geom_id, ''); IF bounds IS NULL THEN geom_clause := ''; ELSE geom_clause := 'ST_Intersects(the_geom, $5) AND'; END IF; RETURN QUERY EXECUTE format($string$ SELECT timespan_id::TEXT, timespan_name::TEXT, timespan_description::TEXT, timespan_weight::NUMERIC, NULL::TEXT timespan_aggregate, NULL::TEXT license, NULL::TEXT source, $1 = ANY(numers) valid_numer, $2 = ANY(denoms) valid_denom, $3 = ANY(geoms) valid_geom_id FROM observatory.obs_meta_timespan WHERE %s (timespan_tags ?& $4 OR CARDINALITY($4) = 0) $string$, geom_clause) USING numer_id, denom_id, geom_id, filter_tags, bounds; RETURN; END $$ LANGUAGE plpgsql; -- Function below should replace SQL in -- https://github.com/CartoDB/cartodb/blob/ab465cb2918c917940e955963b0cd8a050c06600/lib/assets/javascripts/cartodb3/editor/layers/layer-content-views/analyses/data-observatory-metadata.js CREATE OR REPLACE FUNCTION cdb_observatory.OBS_LegacyBuilderMetadata( aggregate_type TEXT DEFAULT NULL ) RETURNS TABLE ( name TEXT, subsection JSONB ) AS $$ DECLARE aggregate_condition TEXT DEFAULT ''; BEGIN IF LOWER(aggregate_type) ILIKE 'sum' THEN aggregate_condition := ' AND numer_aggregate IN (''sum'', ''median'', ''average'') '; ELSIF aggregate_type IS NOT NULL THEN aggregate_condition := format(' AND numer_aggregate ILIKE %L ', aggregate_type); END IF; RETURN QUERY EXECUTE format($string$ WITH expanded AS ( SELECT JSONB_Build_Object('id', numer_id, 'name', numer_name) "column", SUBSTR((sections).key, 9) section_id, (sections).value section_name, SUBSTR((subsections).key, 12) subsection_id, (subsections).value subsection_name FROM ( SELECT numer_id, numer_name, jsonb_each_text(numer_tags) as sections, jsonb_each_text as subsections FROM (SELECT numer_id, numer_name, numer_tags, jsonb_each_text(numer_tags) FROM cdb_observatory.obs_getavailablenumerators() WHERE numer_weight > 0 %s ) foo ) bar WHERE (sections).key LIKE 'section/%%' AND (subsections).key LIKE 'subsection/%%' ), grouped_by_subsections AS ( SELECT JSONB_Agg(JSONB_Build_Object('f1', "column")) AS columns, section_id, section_name, subsection_id, subsection_name FROM expanded GROUP BY section_id, section_name, subsection_id, subsection_name ) SELECT section_name as name, JSONB_Agg( JSONB_Build_Object( 'f1', JSONB_Build_Object( 'name', subsection_name, 'id', subsection_id, 'columns', columns ) ) ) as subsection FROM grouped_by_subsections GROUP BY section_name $string$, aggregate_condition); RETURN; END $$ LANGUAGE plpgsql; CREATE OR REPLACE FUNCTION cdb_observatory._OBS_GetGeometryScores( bounds Geometry(Geometry, 4326) DEFAULT NULL, filter_geom_ids TEXT[] DEFAULT NULL, desired_num_geoms INTEGER DEFAULT NULL ) RETURNS TABLE ( score NUMERIC, numtiles BIGINT, table_id TEXT, column_id TEXT, notnull_percent NUMERIC, numgeoms NUMERIC, percentfill NUMERIC, estnumgeoms NUMERIC, meanmediansize NUMERIC ) AS $$ BEGIN IF desired_num_geoms IS NULL THEN desired_num_geoms := 3000; END IF; filter_geom_ids := COALESCE(filter_geom_ids, (ARRAY[])::TEXT[]); -- Very complex geometries simply fail. For a boundary check, we can -- comfortably get away with the simplicity of an envelope IF ST_Npoints(bounds) > 10000 THEN bounds := ST_Envelope(bounds); END IF; RETURN QUERY EXECUTE $string$ WITH clipped_geom AS ( SELECT column_id, table_id , CASE WHEN $1 IS NOT NULL THEN ST_Clip(tile, $1, True) -- -20 ELSE tile END clipped_tile , tile FROM observatory.obs_column_table_tile_simple WHERE ($1 IS NULL OR ST_Intersects($1, tile)) AND (column_id = ANY($2) OR cardinality($2) = 0) ), clipped_geom_countagg AS ( SELECT column_id, table_id , BOOL_AND(ST_BandIsNoData(clipped_tile, 1)) nodata , ST_CountAgg(clipped_tile, 1, False)::Numeric pixels -- -10 FROM clipped_geom GROUP BY column_id, table_id ), clipped_geom_reagg AS ( SELECT COUNT(*)::BIGINT cnt, a.column_id, a.table_id, cdb_observatory.FIRST(nodata) first_nodata, cdb_observatory.FIRST(pixels) first_pixel, cdb_observatory.FIRST(tile) first_tile, (ST_SummaryStatsAgg(clipped_tile, 1, False)).sum::Numeric sum_geoms, -- ND (ST_SummaryStatsAgg(clipped_tile, 2, False)).mean::Numeric / 255 mean_fill --ND FROM clipped_geom_countagg a, clipped_geom b WHERE a.table_id = b.table_id AND a.column_id = b.column_id GROUP BY a.column_id, a.table_id ), final AS ( SELECT cnt, table_id, column_id , NULL::Numeric AS notnull_percent , (CASE WHEN first_nodata IS FALSE THEN sum_geoms ELSE COALESCE(ST_Value(first_tile, 1, ST_PointOnSurface($1)), 0) * (ST_Area($1) / ST_Area(ST_PixelAsPolygon(first_tile, 0, 0)) * first_pixel) -- -20 END)::Numeric AS numgeoms , (CASE WHEN first_nodata IS FALSE THEN mean_fill ELSE COALESCE(ST_Value(first_tile, 2, ST_PointOnSurface($1))::Numeric / 255, 0) -- -2 END)::Numeric AS percentfill , null::numeric estnumgeoms , null::numeric meanmediansize FROM clipped_geom_reagg ) SELECT ((100.0 / (1+abs(log(0.0001 + $3) - log(0.0001 + numgeoms::Numeric)))) * percentfill)::Numeric AS score, * FROM final $string$ USING bounds, filter_geom_ids, desired_num_geoms; RETURN; END $$ LANGUAGE plpgsql IMMUTABLE; -- Data Observatory -- Welcome to the Future -- These Data Observatory functions provide access to boundary polyons (and -- their ids) such as those available through the US Census Tiger, Who's on -- First, the Spanish Census, and so on -- OBS_GetBoundary -- -- Returns the boundary polygon(s) that overlap with the input point geometry. -- From an input point geometry, find the boundary which intersects with the -- centroid of the input geometry -- Inputs: -- geom geometry: input point geometry -- boundary_id text: source id of boundaries -- see function OBS_ListGeomColumns for all avaiable -- boundary ids -- time_span text: time span that the geometries were collected (optional) -- -- Output: -- boundary geometry: geometry boundary that intersects with geom, is at the -- resolution requested with boundary_id, and time_span -- CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetBoundary( geom geometry(Point, 4326), boundary_id text, time_span text DEFAULT NULL) RETURNS geometry(Geometry, 4326) AS $$ DECLARE boundary geometry(Geometry, 4326); target_table text; BEGIN -- TODO: Check if SRID = 4326, if not transform? -- if not a point, raise error IF ST_GeometryType(geom) != 'ST_Point' THEN RAISE EXCEPTION 'Invalid geometry type (%), expecting ''ST_Point''', ST_GeometryType(geom); END IF; -- return the first boundary in intersections EXECUTE $query$ SELECT * FROM cdb_observatory._OBS_GetBoundariesByGeometry($1, $2, $3) LIMIT 1 $query$ INTO boundary USING geom, boundary_id, time_span; RETURN boundary; END; $$ LANGUAGE plpgsql; -- OBS_GetBoundaryId -- -- retrieves the boundary identifier (e.g., '36047' = Kings County/Brooklyn, NY) -- corresponding to the location geom and boundary types (e.g., -- us.census.tiger.county) -- Inputs: -- geom geometry: location where the boundary is requested to overlap with -- boundary_id text: source id of boundaries (e.g., us.census.tiger.county) -- see function OBS_ListGeomColumns for all avaiable -- boundary ids -- time_span text: time span that the geometries were collected (optional) -- -- Output: -- geometry_id text: identifier of the geometry which overlaps with the input -- point geom in the table corresponding to boundary_id and -- time_span -- CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetBoundaryId( geom geometry(Point, 4326), boundary_id text, time_span text DEFAULT NULL ) RETURNS text AS $$ DECLARE result TEXT; BEGIN EXECUTE $query$ SELECT geom_refs FROM cdb_observatory._OBS_GetBoundariesByGeometry( $1, $2, $3) LIMIT 1 $query$ INTO result USING geom, boundary_id, time_span; RETURN result; END; $$ LANGUAGE plpgsql; -- OBS_GetBoundaryById -- -- Given a geometry reference (e.g., geoid for US Census), and it's geometry -- level (see OBS_ListGeomColumns() for all available boundary ids), give back -- the boundary that corresponds to that geometry_id, boundary_id, and -- time_span -- Inputs: -- geometry_id text: geometry id of the requested boundary -- boundary_id text: source id of boundaries (e.g., us.census.tiger.county) -- see function OBS_ListGeomColumns for all avaiable -- boundary ids -- time_span text: time span that the geometries were collected (optional) -- -- Output: -- boundary geometry: geometry boundary that matches geometry_id, is at the -- resolution requested with boundary_id, and time_span -- CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetBoundaryById( geometry_id text, -- ex: '36047' boundary_id text, -- ex: 'us.census.tiger.county' time_span text DEFAULT NULL -- ex: '2009' ) RETURNS geometry(geometry, 4326) AS $$ DECLARE result GEOMETRY; BEGIN EXECUTE $query$ SELECT (data->0->>'value')::Geometry FROM cdb_observatory.OBS_GetData( ARRAY[$1], cdb_observatory.OBS_GetMeta( ST_MakeEnvelope(-180, -90, 180, 90, 4326), ('[{"geom_id": "' || $2 || '"}]')::JSON)) $query$ INTO result USING geometry_id, boundary_id; RETURN result; END; $$ LANGUAGE plpgsql; -- _OBS_GetBoundariesByGeometry -- internal function for retrieving geometries based on an input geometry -- see OBS_GetBoundariesByGeometry or OBS_GetBoundariesByPointAndRadius for -- more information CREATE OR REPLACE FUNCTION cdb_observatory._OBS_GetBoundariesByGeometry( geom geometry(Geometry, 4326), boundary_id text, time_span text DEFAULT NULL, overlap_type text DEFAULT NULL) RETURNS TABLE ( the_geom geometry, geom_refs text ) AS $$ DECLARE meta JSON; BEGIN overlap_type := COALESCE(overlap_type, 'intersects'); -- check inputs IF lower(overlap_type) NOT IN ('contains', 'intersects', 'within') THEN -- recognized overlap type (map to ST_Contains, ST_Intersects, and ST_Within) RAISE EXCEPTION 'Overlap type ''%'' is not an accepted type (choose intersects, within, or contains)', overlap_type; END IF; EXECUTE $query$ SELECT cdb_observatory.OBS_GetMeta($1, JSON_Build_Array(JSON_Build_Object( 'geom_id', $2, 'geom_timespan', $3))) $query$ INTO meta USING geom, boundary_id, time_span; IF meta->0->>'geom_id' IS NULL THEN RETURN QUERY EXECUTE 'SELECT NULL::Geometry, NULL::Text LIMIT 0'; RETURN; END IF; -- return first boundary in intersections RETURN QUERY EXECUTE $query$ SELECT (data->0->>'value')::Geometry the_geom, data->0->>'geomref' geom_refs FROM cdb_observatory.OBS_GetData( ARRAY[($1, 1)::geomval], $2, False ) $query$ USING geom, meta; RETURN; END; $$ LANGUAGE plpgsql; -- OBS_GetBoundariesByGeometry -- -- Given a bounding box (or a polygon), and it's geometry level (see -- OBS_ListGeomColumns() for all available boundary ids), give back the -- boundaries that are contained within the bounding box polygon and the -- associated geometry ids -- Inputs: -- geom geometry: bounding box (or polygon) of the region of interest -- boundary_id text: source id of boundaries (e.g., us.census.tiger.county) -- see function OBS_ListGeomColumns for all avaiable -- boundary ids -- time_span text: time span that the geometries were collected (optional) -- -- Output: -- table with the following columns -- boundary geometry: geometry boundary that is contained within the input -- bounding box at the requested geometry level -- with boundary_id, and time_span -- geom_refs text: geometry identifiers (e.g., geoid for the US Census) -- CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetBoundariesByGeometry( geom geometry(Geometry, 4326), boundary_id text, time_span text DEFAULT NULL, overlap_type text DEFAULT NULL) RETURNS TABLE(the_geom geometry, geom_refs text) AS $$ BEGIN RETURN QUERY SELECT * FROM cdb_observatory._OBS_GetBoundariesByGeometry( geom, boundary_id, time_span, overlap_type ); RETURN; END; $$ LANGUAGE plpgsql; -- OBS_GetBoundariesByPointAndRadius -- -- Given a point and radius, and it's geometry level (see -- OBS_ListGeomColumns() for all available boundary ids), give back the -- boundaries that are contained within the point buffered by radius meters and -- the associated geometry ids -- Inputs: -- geom geometry: point geometry centered on area of interest -- radius numeric: radius (in meters) of a circle centered on geom for -- selecting polygons -- boundary_id text: source id of boundaries (e.g., us.census.tiger.county) -- see function OBS_ListGeomColumns for all avaiable -- boundary ids -- time_span text: time span that the geometries were collected (optional) -- -- Output: -- table with the following columns -- boundary geometry: geometry boundary that is contained within the input -- bounding box at the requested geometry level -- with boundary_id, and time_span -- geom_refs text: geometry identifiers (e.g., geoid for the US Census) -- -- TODO: move to ST_DWithin instead of buffer + intersects? CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetBoundariesByPointAndRadius( geom geometry(Point, 4326), -- point radius numeric, -- radius in meters boundary_id text, time_span text DEFAULT NULL, overlap_type text DEFAULT NULL) RETURNS TABLE(the_geom geometry, geom_refs text) AS $$ DECLARE circle_boundary geometry(Geometry, 4326); BEGIN IF ST_GeometryType(geom) != 'ST_Point' THEN RAISE EXCEPTION 'Input geometry ''%'' is not a point', ST_AsText(geom); ELSE circle_boundary := ST_Buffer(geom::geography, radius)::geometry; END IF; RETURN QUERY SELECT * FROM cdb_observatory._OBS_GetBoundariesByGeometry( circle_boundary, boundary_id, time_span, overlap_type); RETURN; END; $$ LANGUAGE plpgsql; -- _OBS_GetPointsByGeometry CREATE OR REPLACE FUNCTION cdb_observatory._OBS_GetPointsByGeometry( geom geometry(Geometry, 4326), boundary_id text, time_span text DEFAULT NULL, overlap_type text DEFAULT NULL) RETURNS TABLE(the_geom geometry, geom_refs text) AS $$ DECLARE boundary geometry(Geometry, 4326); geom_colname text; geoid_colname text; target_table text; BEGIN overlap_type := COALESCE(overlap_type, 'intersects'); IF lower(overlap_type) NOT IN ('contains', 'within', 'intersects') THEN RAISE EXCEPTION 'Overlap type ''%'' is not an accepted type (choose intersects, within, or contains)', overlap_type; ELSIF ST_GeometryType(geom) NOT IN ('ST_Polygon', 'ST_MultiPolygon') THEN RAISE EXCEPTION 'Invalid geometry type (%), expecting ''ST_MultiPolygon'' or ''ST_Polygon''', ST_GeometryType(geom); END IF; -- return first boundary in intersections RETURN QUERY EXECUTE $query$ SELECT ST_PointOnSurface(the_geom), geom_refs FROM cdb_observatory._OBS_GetBoundariesByGeometry($1, $2) $query$ USING geom, boundary_id; RETURN; END; $$ LANGUAGE plpgsql; -- OBS_GetPointsByGeometry -- -- Given a polygon, and it's geometry level (see -- OBS_ListGeomColumns() for all available boundary ids), give back a point -- which lies in a boundary from the requested geometry level that is contained -- within the bounding box polygon and the associated geometry ids -- -- Inputs: -- geom geometry: bounding box (or polygon) of the region of interest -- boundary_id text: source id of boundaries (e.g., us.census.tiger.county) -- see function OBS_ListGeomColumns for all avaiable -- boundary ids -- time_span text: time span that the geometries were collected (optional) -- -- Output: -- table with the following columns -- boundary geometry: point that lies on a boundary that is contained within -- the input bounding box at the requested geometry -- level with boundary_id, and time_span -- geom_refs text: geometry identifiers (e.g., geoid for the US Census) -- CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetPointsByGeometry( geom geometry(Geometry, 4326), boundary_id text, time_span text DEFAULT NULL, overlap_type text DEFAULT NULL) RETURNS TABLE(the_geom geometry, geom_refs text) AS $$ BEGIN RETURN QUERY SELECT * FROM cdb_observatory._OBS_GetPointsByGeometry( geom, boundary_id, time_span, overlap_type); RETURN; END; $$ LANGUAGE plpgsql; -- OBS_GetBoundariesByPointAndRadius -- -- Given a point and radius, and it's geometry level (see -- OBS_ListGeomColumns() for all available boundary ids), give back the -- boundaries that are contained within the point buffered by radius meters and -- the associated geometry ids -- Inputs: -- geom geometry: point geometry centered on area of interest -- radius numeric: radius (in meters) of a circle centered on geom for -- selecting polygons -- boundary_id text: source id of boundaries (e.g., us.census.tiger.county) -- see function OBS_ListGeomColumns for all avaiable -- boundary ids -- time_span text: time span that the geometries were collected (optional) -- -- Output: -- table with the following columns -- boundary geometry: geometry boundary that is contained within the input -- bounding box at the requested geometry level -- with boundary_id, and time_span -- geom_refs text: geometry identifiers (e.g., geoid for the US Census) -- CREATE OR REPLACE FUNCTION cdb_observatory.OBS_GetPointsByPointAndRadius( geom geometry(Point, 4326), -- point radius numeric, -- radius in meters boundary_id text, time_span text DEFAULT NULL, overlap_type text DEFAULT NULL) RETURNS TABLE(the_geom geometry, geom_refs text) AS $$ DECLARE circle_boundary geometry(Geometry, 4326); BEGIN IF ST_GeometryType(geom) != 'ST_Point' THEN RAISE EXCEPTION 'Input geometry ''%'' is not a point', ST_AsText(geom); ELSE circle_boundary := ST_Buffer(geom::geography, radius)::geometry; END IF; RETURN QUERY SELECT * FROM cdb_observatory._OBS_GetPointsByGeometry( ST_Buffer(geom::geography, radius)::geometry, boundary_id, time_span, overlap_type); RETURN; END; $$ LANGUAGE plpgsql; -- Placeholder for permission tweaks at creation time. -- Make sure by default there are no permissions for publicuser -- NOTE: this happens at extension creation time, as part of an implicit transaction. -- REVOKE ALL PRIVILEGES ON SCHEMA cdb_observatory FROM PUBLIC, publicuser CASCADE; -- Grant permissions on the schema to publicuser (but just the schema) -- GRANT USAGE ON SCHEMA cdb_crankshaft TO publicuser; -- Revoke execute permissions on all functions in the schema by default -- REVOKE EXECUTE ON ALL FUNCTIONS IN SCHEMA cdb_observatory FROM PUBLIC, publicuser;