PostgreSQL 9.2.24 Documentation | ||||
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Generally speaking, the aim of PL/Python is to provide a "natural" mapping between the PostgreSQL and the Python worlds. This informs the data mapping rules described below.
Function arguments are converted from their PostgreSQL type to a corresponding Python type:
PostgreSQL boolean is converted to Python bool.
PostgreSQL smallint and int are converted to Python int. PostgreSQL bigint is converted to long in Python 2 and to int in Python 3.
PostgreSQL real, double, and numeric are converted to Python float. Note that for the numeric this loses information and can lead to incorrect results. This might be fixed in a future release.
PostgreSQL bytea is converted to Python str in Python 2 and to bytes in Python 3. In Python 2, the string should be treated as a byte sequence without any character encoding.
All other data types, including the PostgreSQL character string types, are converted to a Python str. In Python 2, this string will be in the PostgreSQL server encoding; in Python 3, it will be a Unicode string like all strings.
For nonscalar data types, see below.
Function return values are converted to the declared PostgreSQL return data type as follows:
When the PostgreSQL return type is boolean, the return value will be evaluated for truth according to the Python rules. That is, 0 and empty string are false, but notably 'f' is true.
When the PostgreSQL return type is bytea, the return value will be converted to a string (Python 2) or bytes (Python 3) using the respective Python built-ins, with the result being converted bytea.
For all other PostgreSQL return types, the returned Python value is converted to a string using the Python built-in str, and the result is passed to the input function of the PostgreSQL data type.
Strings in Python 2 are required to be in the PostgreSQL server encoding when they are passed to PostgreSQL. Strings that are not valid in the current server encoding will raise an error, but not all encoding mismatches can be detected, so garbage data can still result when this is not done correctly. Unicode strings are converted to the correct encoding automatically, so it can be safer and more convenient to use those. In Python 3, all strings are Unicode strings.
For nonscalar data types, see below.
Note that logical mismatches between the declared PostgreSQL return type and the Python data type of the actual return object are not flagged; the value will be converted in any case.
If an SQL null value is passed to a function, the argument
value will appear as None in Python.
For example, the function definition of pymax
shown in Section 42.2 will return the wrong
answer for null inputs. We could add STRICT to the function definition to make
PostgreSQL do something more
reasonable: if a null value is passed, the function will not be
called at all, but will just return a null result
automatically. Alternatively, we could check for null inputs in
the function body:
CREATE FUNCTION pymax (a integer, b integer) RETURNS integer AS $$ if (a is None) or (b is None): return None if a > b: return a return b $$ LANGUAGE plpythonu;
As shown above, to return an SQL null value from a PL/Python function, return the value None. This can be done whether the function is strict or not.
SQL array values are passed into PL/Python as a Python list. To return an SQL array value out of a PL/Python function, return a Python sequence, for example a list or tuple:
CREATE FUNCTION return_arr() RETURNS int[] AS $$ return (1, 2, 3, 4, 5) $$ LANGUAGE plpythonu; SELECT return_arr(); return_arr ------------- {1,2,3,4,5} (1 row)
Note that in Python, strings are sequences, which can have undesirable effects that might be familiar to Python programmers:
CREATE FUNCTION return_str_arr() RETURNS varchar[] AS $$ return "hello" $$ LANGUAGE plpythonu; SELECT return_str_arr(); return_str_arr ---------------- {h,e,l,l,o} (1 row)
Composite-type arguments are passed to the function as Python mappings. The element names of the mapping are the attribute names of the composite type. If an attribute in the passed row has the null value, it has the value None in the mapping. Here is an example:
CREATE TABLE employee ( name text, salary integer, age integer ); CREATE FUNCTION overpaid (e employee) RETURNS boolean AS $$ if e["salary"] > 200000: return True if (e["age"] < 30) and (e["salary"] > 100000): return True return False $$ LANGUAGE plpythonu;
There are multiple ways to return row or composite types from a Python function. The following examples assume we have:
CREATE TYPE named_value AS ( name text, value integer );
A composite result can be returned as a:
Returned sequence objects must have the same number of items as the composite result type has fields. The item with index 0 is assigned to the first field of the composite type, 1 to the second and so on. For example:
CREATE FUNCTION make_pair (name text, value integer) RETURNS named_value AS $$ return [ name, value ] # or alternatively, as tuple: return ( name, value ) $$ LANGUAGE plpythonu;
To return a SQL null for any column, insert None at the corresponding position.
The value for each result type column is retrieved from the mapping with the column name as key. Example:
CREATE FUNCTION make_pair (name text, value integer) RETURNS named_value AS $$ return { "name": name, "value": value } $$ LANGUAGE plpythonu;
Any extra dictionary key/value pairs are ignored. Missing keys are treated as errors. To return a SQL null value for any column, insert None with the corresponding column name as the key.
This works the same as a mapping. Example:
CREATE FUNCTION make_pair (name text, value integer) RETURNS named_value AS $$ class named_value: def __init__ (self, n, v): self.name = n self.value = v return named_value(name, value) # or simply class nv: pass nv.name = name nv.value = value return nv $$ LANGUAGE plpythonu;
Functions with OUT parameters are also supported. For example:
CREATE FUNCTION multiout_simple(OUT i integer, OUT j integer) AS $$ return (1, 2) $$ LANGUAGE plpythonu; SELECT * FROM multiout_simple();
A PL/Python function can also return sets of scalar or composite types. There are several ways to achieve this because the returned object is internally turned into an iterator. The following examples assume we have composite type:
CREATE TYPE greeting AS ( how text, who text );
A set result can be returned from a:
CREATE FUNCTION greet (how text) RETURNS SETOF greeting AS $$ # return tuple containing lists as composite types # all other combinations work also return ( [ how, "World" ], [ how, "PostgreSQL" ], [ how, "PL/Python" ] ) $$ LANGUAGE plpythonu;
CREATE FUNCTION greet (how text) RETURNS SETOF greeting AS $$ class producer: def __init__ (self, how, who): self.how = how self.who = who self.ndx = -1 def __iter__ (self): return self def next (self): self.ndx += 1 if self.ndx == len(self.who): raise StopIteration return ( self.how, self.who[self.ndx] ) return producer(how, [ "World", "PostgreSQL", "PL/Python" ]) $$ LANGUAGE plpythonu;
CREATE FUNCTION greet (how text) RETURNS SETOF greeting AS $$ for who in [ "World", "PostgreSQL", "PL/Python" ]: yield ( how, who ) $$ LANGUAGE plpythonu;
Warning |
Due to Python bug #1483133, some debug versions of Python 2.4 (configured and compiled with option --with-pydebug) are known to crash the PostgreSQL server when using an iterator to return a set result. Unpatched versions of Fedora 4 contain this bug. It does not happen in production versions of Python or on patched versions of Fedora 4. |
Set-returning functions with OUT parameters (using RETURNS SETOF record) are also supported. For example:
CREATE FUNCTION multiout_simple_setof(n integer, OUT integer, OUT integer) RETURNS SETOF record AS $$ return [(1, 2)] * n $$ LANGUAGE plpythonu; SELECT * FROM multiout_simple_setof(3);