Postgres-XC 1.0.3 Documentation | ||||
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Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
This section explains differences between Postgres-XC's PL/pgSQL language and Oracle's PL/SQL language, to help developers who port applications from Oracle® to Postgres-XC.
PL/pgSQL is similar to PL/SQL in many aspects. It is a block-structured, imperative language, and all variables have to be declared. Assignments, loops, conditionals are similar. The main differences you should keep in mind when porting from PL/SQL to PL/pgSQL are:
If a name used in a SQL command could be either a column name of a table or a reference to a variable of the function, PL/SQL treats it as a column name. This corresponds to PL/pgSQL's plpgsql.variable_conflict = use_column behavior, which is not the default, as explained in Section 38.10.1. It's often best to avoid such ambiguities in the first place, but if you have to port a large amount of code that depends on this behavior, setting variable_conflict may be the best solution.
In Postgres-XC the function body must be written as a string literal. Therefore you need to use dollar quoting or escape single quotes in the function body. (See Section 38.11.1.)
Instead of packages, use schemas to organize your functions into groups.
Since there are no packages, there are no package-level variables either. This is somewhat annoying. You can keep per-session state in temporary tables instead.
Integer FOR loops with REVERSE work differently: PL/SQL counts down from the second number to the first, while PL/pgSQL counts down from the first number to the second, requiring the loop bounds to be swapped when porting. This incompatibility is unfortunate but is unlikely to be changed. (See Section 38.6.3.5.)
FOR loops over queries (other than cursors) also work differently: the target variable(s) must have been declared, whereas PL/SQL always declares them implicitly. An advantage of this is that the variable values are still accessible after the loop exits.
There are various notational differences for the use of cursor variables.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Example 38-7 shows how to port a simple function from PL/SQL to PL/pgSQL.
Example 38-7. Porting a Simple Function from PL/SQL to PL/pgSQL
Here is an Oracle PL/SQL function:
CREATE OR REPLACE FUNCTION cs_fmt_browser_version(v_name varchar, v_version varchar) RETURN varchar IS BEGIN IF v_version IS NULL THEN RETURN v_name; END IF; RETURN v_name || '/' || v_version; END; / show errors;
Let's go through this function and see the differences compared to PL/pgSQL:
The RETURN key word in the function prototype (not the function body) becomes RETURNS in Postgres-XC. Also, IS becomes AS, and you need to add a LANGUAGE clause because PL/pgSQL is not the only possible function language.
In Postgres-XC, the function body is considered to be a string literal, so you need to use quote marks or dollar quotes around it. This substitutes for the terminating / in the Oracle approach.
The show errors command does not exist in Postgres-XC, and is not needed since errors are reported automatically.
This is how this function would look when ported to Postgres-XC:
CREATE OR REPLACE FUNCTION cs_fmt_browser_version(v_name varchar, v_version varchar) RETURNS varchar AS $$ BEGIN IF v_version IS NULL THEN RETURN v_name; END IF; RETURN v_name || '/' || v_version; END; $$ LANGUAGE plpgsql;
Example 38-8 shows how to port a function that creates another function and how to handle the ensuing quoting problems.
Example 38-8. Porting a Function that Creates Another Function from PL/SQL to PL/pgSQL
The following procedure grabs rows from a SELECT statement and builds a large function with the results in IF statements, for the sake of efficiency.
This is the Oracle version:
CREATE OR REPLACE PROCEDURE cs_update_referrer_type_proc IS CURSOR referrer_keys IS SELECT * FROM cs_referrer_keys ORDER BY try_order; func_cmd VARCHAR(4000); BEGIN func_cmd := 'CREATE OR REPLACE FUNCTION cs_find_referrer_type(v_host IN VARCHAR, v_domain IN VARCHAR, v_url IN VARCHAR) RETURN VARCHAR IS BEGIN'; FOR referrer_key IN referrer_keys LOOP func_cmd := func_cmd || ' IF v_' || referrer_key.kind || ' LIKE ''' || referrer_key.key_string || ''' THEN RETURN ''' || referrer_key.referrer_type || '''; END IF;'; END LOOP; func_cmd := func_cmd || ' RETURN NULL; END;'; EXECUTE IMMEDIATE func_cmd; END; / show errors;
Here is how this function would end up in Postgres-XC:
CREATE OR REPLACE FUNCTION cs_update_referrer_type_proc() RETURNS void AS $func$ DECLARE referrer_keys CURSOR IS SELECT * FROM cs_referrer_keys ORDER BY try_order; func_body text; func_cmd text; BEGIN func_body := 'BEGIN'; FOR referrer_key IN referrer_keys LOOP func_body := func_body || ' IF v_' || referrer_key.kind || ' LIKE ' || quote_literal(referrer_key.key_string) || ' THEN RETURN ' || quote_literal(referrer_key.referrer_type) || '; END IF;' ; END LOOP; func_body := func_body || ' RETURN NULL; END;'; func_cmd := 'CREATE OR REPLACE FUNCTION cs_find_referrer_type(v_host varchar, v_domain varchar, v_url varchar) RETURNS varchar AS ' || quote_literal(func_body) || ' LANGUAGE plpgsql;' ; EXECUTE func_cmd; END; $func$ LANGUAGE plpgsql;
Notice how the body of the function is built separately and passed through quote_literal to double any quote marks in it. This technique is needed because we cannot safely use dollar quoting for defining the new function: we do not know for sure what strings will be interpolated from the referrer_key.key_string field. (We are assuming here that referrer_key.kind can be trusted to always be host, domain, or url, but referrer_key.key_string might be anything, in particular it might contain dollar signs.) This function is actually an improvement on the Oracle original, because it will not generate broken code when referrer_key.key_string or referrer_key.referrer_type contain quote marks.
Example 38-9 shows how to port a function
with OUT parameters and string manipulation.
Postgres-XC does not have a built-in
instr
function, but you can create one
using a combination of other
functions. In Section 38.12.3 there is a
PL/pgSQL implementation of
instr
that you can use to make your porting
easier.
Example 38-9. Porting a Procedure With String Manipulation and OUT Parameters from PL/SQL to PL/pgSQL
The following Oracle PL/SQL procedure is used to parse a URL and return several elements (host, path, and query).
This is the Oracle version:
CREATE OR REPLACE PROCEDURE cs_parse_url( v_url IN VARCHAR, v_host OUT VARCHAR, -- This will be passed back v_path OUT VARCHAR, -- This one too v_query OUT VARCHAR) -- And this one IS a_pos1 INTEGER; a_pos2 INTEGER; BEGIN v_host := NULL; v_path := NULL; v_query := NULL; a_pos1 := instr(v_url, '//'); IF a_pos1 = 0 THEN RETURN; END IF; a_pos2 := instr(v_url, '/', a_pos1 + 2); IF a_pos2 = 0 THEN v_host := substr(v_url, a_pos1 + 2); v_path := '/'; RETURN; END IF; v_host := substr(v_url, a_pos1 + 2, a_pos2 - a_pos1 - 2); a_pos1 := instr(v_url, '?', a_pos2 + 1); IF a_pos1 = 0 THEN v_path := substr(v_url, a_pos2); RETURN; END IF; v_path := substr(v_url, a_pos2, a_pos1 - a_pos2); v_query := substr(v_url, a_pos1 + 1); END; / show errors;
Here is a possible translation into PL/pgSQL:
CREATE OR REPLACE FUNCTION cs_parse_url( v_url IN VARCHAR, v_host OUT VARCHAR, -- This will be passed back v_path OUT VARCHAR, -- This one too v_query OUT VARCHAR) -- And this one AS $$ DECLARE a_pos1 INTEGER; a_pos2 INTEGER; BEGIN v_host := NULL; v_path := NULL; v_query := NULL; a_pos1 := instr(v_url, '//'); IF a_pos1 = 0 THEN RETURN; END IF; a_pos2 := instr(v_url, '/', a_pos1 + 2); IF a_pos2 = 0 THEN v_host := substr(v_url, a_pos1 + 2); v_path := '/'; RETURN; END IF; v_host := substr(v_url, a_pos1 + 2, a_pos2 - a_pos1 - 2); a_pos1 := instr(v_url, '?', a_pos2 + 1); IF a_pos1 = 0 THEN v_path := substr(v_url, a_pos2); RETURN; END IF; v_path := substr(v_url, a_pos2, a_pos1 - a_pos2); v_query := substr(v_url, a_pos1 + 1); END; $$ LANGUAGE plpgsql;
This function could be used like this:
SELECT * FROM cs_parse_url('http://foobar.com/query.cgi?baz');
Example 38-10 shows how to port a procedure that uses numerous features that are specific to Oracle.
Example 38-10. Porting a Procedure from PL/SQL to PL/pgSQL
The Oracle version:
CREATE OR REPLACE PROCEDURE cs_create_job(v_job_id IN INTEGER) IS a_running_job_count INTEGER; PRAGMA AUTONOMOUS_TRANSACTION;(1) BEGIN LOCK TABLE cs_jobs IN EXCLUSIVE MODE;(2) SELECT count(*) INTO a_running_job_count FROM cs_jobs WHERE end_stamp IS NULL; IF a_running_job_count > 0 THEN COMMIT; -- free lock(3) raise_application_error(-20000, 'Unable to create a new job: a job is currently running.'); END IF; DELETE FROM cs_active_job; INSERT INTO cs_active_job(job_id) VALUES (v_job_id); BEGIN INSERT INTO cs_jobs (job_id, start_stamp) VALUES (v_job_id, sysdate); EXCEPTION WHEN dup_val_on_index THEN NULL; -- don't worry if it already exists END; COMMIT; END; / show errors
Procedures like this can easily be converted into Postgres-XC functions returning void. This procedure in particular is interesting because it can teach us some things:
This is how we could port this procedure to PL/pgSQL:
CREATE OR REPLACE FUNCTION cs_create_job(v_job_id integer) RETURNS void AS $$ DECLARE a_running_job_count integer; BEGIN LOCK TABLE cs_jobs IN EXCLUSIVE MODE; SELECT count(*) INTO a_running_job_count FROM cs_jobs WHERE end_stamp IS NULL; IF a_running_job_count > 0 THEN RAISE EXCEPTION 'Unable to create a new job: a job is currently running';(1) END IF; DELETE FROM cs_active_job; INSERT INTO cs_active_job(job_id) VALUES (v_job_id); BEGIN INSERT INTO cs_jobs (job_id, start_stamp) VALUES (v_job_id, now()); EXCEPTION WHEN unique_violation THEN (2) -- don't worry if it already exists END; END; $$ LANGUAGE plpgsql;
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
This section explains a few other things to watch for when porting Oracle PL/SQL functions to Postgres-XC.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
In PL/pgSQL, when an exception is caught by an EXCEPTION clause, all database changes since the block's BEGIN are automatically rolled back. That is, the behavior is equivalent to what you'd get in Oracle with:
BEGIN SAVEPOINT s1; ... code here ... EXCEPTION WHEN ... THEN ROLLBACK TO s1; ... code here ... WHEN ... THEN ROLLBACK TO s1; ... code here ... END;
If you are translating an Oracle procedure that uses SAVEPOINT and ROLLBACK TO in this style, your task is easy: just omit the SAVEPOINT and ROLLBACK TO. If you have a procedure that uses SAVEPOINT and ROLLBACK TO in a different way then some actual thought will be required.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
The PL/pgSQL version of
EXECUTE works similarly to the
PL/SQL version, but you have to remember to use
quote_literal
and
quote_ident
as described in Section 38.5.4. Constructs of the
type EXECUTE 'SELECT * FROM $1'; will not work
reliably unless you use these functions.
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
Postgres-XC gives you two function creation modifiers to optimize execution: "volatility" (whether the function always returns the same result when given the same arguments) and "strictness" (whether the function returns null if any argument is null). Consult the CREATE FUNCTION reference page for details.
When making use of these optimization attributes, your CREATE FUNCTION statement might look something like this:
CREATE FUNCTION foo(...) RETURNS integer AS $$ ... $$ LANGUAGE plpgsql STRICT IMMUTABLE;
Note: The following description applies both to Postgres-XC and PostgreSQL if not described explicitly.
This section contains the code for a set of Oracle-compatible
instr
functions that you can use to simplify
your porting efforts.
-- -- instr functions that mimic Oracle's counterpart -- Syntax: instr(string1, string2, [n], [m]) where [] denotes optional parameters. -- -- Searches string1 beginning at the nth character for the mth occurrence -- of string2. If n is negative, search backwards. If m is not passed, -- assume 1 (search starts at first character). -- CREATE FUNCTION instr(varchar, varchar) RETURNS integer AS $$ DECLARE pos integer; BEGIN pos:= instr($1, $2, 1); RETURN pos; END; $$ LANGUAGE plpgsql STRICT IMMUTABLE; CREATE FUNCTION instr(string varchar, string_to_search varchar, beg_index integer) RETURNS integer AS $$ DECLARE pos integer NOT NULL DEFAULT 0; temp_str varchar; beg integer; length integer; ss_length integer; BEGIN IF beg_index > 0 THEN temp_str := substring(string FROM beg_index); pos := position(string_to_search IN temp_str); IF pos = 0 THEN RETURN 0; ELSE RETURN pos + beg_index - 1; END IF; ELSE ss_length := char_length(string_to_search); length := char_length(string); beg := length + beg_index - ss_length + 2; WHILE beg > 0 LOOP temp_str := substring(string FROM beg FOR ss_length); pos := position(string_to_search IN temp_str); IF pos > 0 THEN RETURN beg; END IF; beg := beg - 1; END LOOP; RETURN 0; END IF; END; $$ LANGUAGE plpgsql STRICT IMMUTABLE; CREATE FUNCTION instr(string varchar, string_to_search varchar, beg_index integer, occur_index integer) RETURNS integer AS $$ DECLARE pos integer NOT NULL DEFAULT 0; occur_number integer NOT NULL DEFAULT 0; temp_str varchar; beg integer; i integer; length integer; ss_length integer; BEGIN IF beg_index > 0 THEN beg := beg_index; temp_str := substring(string FROM beg_index); FOR i IN 1..occur_index LOOP pos := position(string_to_search IN temp_str); IF i = 1 THEN beg := beg + pos - 1; ELSE beg := beg + pos; END IF; temp_str := substring(string FROM beg + 1); END LOOP; IF pos = 0 THEN RETURN 0; ELSE RETURN beg; END IF; ELSE ss_length := char_length(string_to_search); length := char_length(string); beg := length + beg_index - ss_length + 2; WHILE beg > 0 LOOP temp_str := substring(string FROM beg FOR ss_length); pos := position(string_to_search IN temp_str); IF pos > 0 THEN occur_number := occur_number + 1; IF occur_number = occur_index THEN RETURN beg; END IF; END IF; beg := beg - 1; END LOOP; RETURN 0; END IF; END; $$ LANGUAGE plpgsql STRICT IMMUTABLE;