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I am programming a stored procedure in PostgreSQL. The algorithm should handle a 2 dimensional array of double precision numbers.

As far as I have investigated array operations in Postgres are generic and quite heavy. The simple example I'm trying to prove has an excessive computational cost.

Example:

CREATE OR REPLACE FUNCTION fill_2d_array( rows integer, cols integer) 
  RETURNS integer AS
$BODY$

DECLARE

img double precision[][];

i integer; j integer;
cont integer;

BEGIN

img  := ARRAY( SELECT 0 FROM generate_series(1, filas * columnas) ) ; 
cont:= 0;
For i IN 1..rows LOOP
    For j IN 1..cols LOOP
        img[i * cols + j] := (i * cols + j)::double precision;
        cont := cont + 1;
    END LOOP;
END LOOP;

return cont;
END;
$BODY$
  LANGUAGE plpgsql;

Can someone help me find an alternative path or an improvement to handle two-dimensional arrays?

  • I can't decypher what are you trying to accomplish... Why can't you just use arrayagg() instead of loops? – kworr Sep 30 '13 at 8:09
  • filas and columnas are undefined. I suppose that should be rows and cols? And please describe what trying to do. Since you are only returning an integer, the whole operation seems pointless? – Erwin Brandstetter Oct 1 '13 at 21:58
2

Procedural function

Basic problems

  • Declaring the dimensions of an array variable, like float8[][] for a 2-dimensional array, only serves documentation. Consider details in this related answer:
    mapping postgresql text[][] type and Java type

  • You are confusing 1-dimenstional and 2-dimensional arrays. While declaring a 2-dimenstional array (to no effect), you only make it out to be a 1-dimensional array.

  • To initialize an array, use array_fill():

    img := array_fill(0, ARRAY[rows,cols])
    

    This example produces a 2-dimensional array - as opposed to your faulty statement, producing a 1-dimensional array:

    img  := ARRAY( SELECT 0 FROM generate_series(1, rows* cols) );
  • The displayed array subscripts img[i * cols + j] hardly make sense. The maximum would be twice of what you initialized, resulting in "out-of-bound" errors. I suppose you mean img[i][j]

Working version

Everything put together it could work like this:

CREATE OR REPLACE FUNCTION f_array_fill(rows integer, cols integer
                                                    , OUT img float8[][]) AS
$func$
DECLARE
   i  int;
   j  int;
BEGIN

img := array_fill(0, ARRAY[rows,cols]);

FOR i IN 1 .. rows LOOP
    FOR j IN 1 .. cols LOOP
        img[i][j] := (i * cols + j)::float8;
    END LOOP;
END LOOP;

END
$func$ LANGUAGE plpgsql;

Call:

SELECT f_array_fill(2,3);

Result:

{{4,5,6},{7,8,9}}

To make the function useful, return the produced array. Using an OUT parameter for that.

Superior set-based version

Looping and individual assignments are comparatively slow in plpgsql. Array handling performs particularly poorly as explained by @Craig in this related answer:
Why is PostgreSQL array access so much faster in C than in PL/pgSQL?

I would use a set-based operation instead, much faster with bigger numbers.

Aggregate function for multi-dimensional arrays

To produce multi-dimensional arrays, we need a custom aggregate function. array_agg() or the array constructor only produce 1-dimensional arrays. It's simple enough, as we worked out in this related answer:
Initial array in function to aggregate multi-dimensional array

CREATE AGGREGATE array_agg_mult (anyarray)  (
    SFUNC     = array_cat
   ,STYPE     = anyarray
   ,INITCOND  = '{}'
);

Alternative function

Using this beauty, we can build a simple SQL function doing the the same as the above:

CREATE OR REPLACE FUNCTION f_array_fill_sql(_rows integer, _cols integer)
  RETURNS float8[][] AS
$func$
SELECT array_agg_mult(ARRAY[arr1]) AS arr2
FROM  (
   SELECT array_agg((i * $2 + j)::float8) AS arr1
   FROM   generate_series(1, $1) i
   CROSS  JOIN generate_series(1, $2) j
   GROUP  BY i
   ORDER  BY i
   ) sub
$func$ LANGUAGE sql

Call:

SELECT f_array_fill_sql(3,4);

Result:

{{4,5,6},{7,8,9}}

Compare

For small numbers, the difference in performance is negligible. But the first variant (even though optimized now) deteriorates quickly with bigger numbers. Try:

EXPLAIN ANALYZE SELECT f_array_fill(100,100)
EXPLAIN ANALYZE SELECT f_array_fill_sql(100,100)  -- ~ 50x faster!
  • 1
    A access to array field is relatively fast (not fast as C sure), but array update large array is terribly slow due fact, so (in this moment) a arrays (and all objects in Postgres) are immutable structures. Any update means creating new one. This feature will be fixed (maybe) - patch is in commitfest postgresql.org/message-id/… – Pavel Stehule Oct 10 '13 at 7:14
  • @PavelStehule: I have read about it. Exciting news. Good job! :) – Erwin Brandstetter Oct 10 '13 at 7:22

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