Triggers
trigger
This chapter provides general information about writing trigger functions.
Trigger functions can be written in most of the available procedural
languages, including
PL/pgSQL (),
PL/Tcl (),
PL/Perl (), and
PL/Python ().
After reading this chapter, you should consult the chapter for
your favorite procedural language to find out the language-specific
details of writing a trigger in it.
It is also possible to write a trigger function in C, although
most people find it easier to use one of the procedural languages.
It is not currently possible to write a trigger function in the
plain SQL function language.
Overview of Trigger Behavior
A trigger is a specification that the database should automatically
execute a particular function whenever a certain type of operation is
performed. Triggers can be attached to tables (partitioned or not),
views, and foreign tables.
On tables and foreign tables, triggers can be defined to execute either
before or after any INSERT, UPDATE,
or DELETE operation, either once per modified row,
or once per SQL statement.
UPDATE triggers can moreover be set to fire only if
certain columns are mentioned in the SET clause of
the UPDATE statement. Triggers can also fire
for TRUNCATE statements. If a trigger event occurs,
the trigger's function is called at the appropriate time to handle the
event.
On views, triggers can be defined to execute instead of
INSERT, UPDATE, or
DELETE operations.
Such INSTEAD OF triggers
are fired once for each row that needs to be modified in the view.
It is the responsibility of the
trigger's function to perform the necessary modifications to the view's
underlying base table(s) and, where appropriate, return the modified
row as it will appear in the view. Triggers on views can also be defined
to execute once per SQL statement, before or after
INSERT, UPDATE, or
DELETE operations.
However, such triggers are fired only if there is also
an INSTEAD OF trigger on the view. Otherwise,
any statement targeting the view must be rewritten into a statement
affecting its underlying base table(s), and then the triggers
that will be fired are the ones attached to the base table(s).
The trigger function must be defined before the trigger itself can be
created. The trigger function must be declared as a
function taking no arguments and returning type trigger.
(The trigger function receives its input through a specially-passed
TriggerData structure, not in the form of ordinary function
arguments.)
Once a suitable trigger function has been created, the trigger is
established with
.
The same trigger function can be used for multiple triggers.
PostgreSQL offers both per-row
triggers and per-statement triggers. With a per-row
trigger, the trigger function
is invoked once for each row that is affected by the statement
that fired the trigger. In contrast, a per-statement trigger is
invoked only once when an appropriate statement is executed,
regardless of the number of rows affected by that statement. In
particular, a statement that affects zero rows will still result
in the execution of any applicable per-statement triggers. These
two types of triggers are sometimes called row-level
triggers and statement-level triggers,
respectively. Triggers on TRUNCATE may only be
defined at statement level, not per-row.
Triggers are also classified according to whether they fire
before, after, or
instead of the operation. These are referred to
as BEFORE triggers, AFTER triggers, and
INSTEAD OF triggers respectively.
Statement-level BEFORE triggers naturally fire before the
statement starts to do anything, while statement-level AFTER
triggers fire at the very end of the statement. These types of
triggers may be defined on tables, views, or foreign tables. Row-level
BEFORE triggers fire immediately before a particular row is
operated on, while row-level AFTER triggers fire at the end of
the statement (but before any statement-level AFTER triggers).
These types of triggers may only be defined on tables and
foreign tables, not views.
INSTEAD OF triggers may only be
defined on views, and only at row level; they fire immediately as each
row in the view is identified as needing to be operated on.
The execution of an AFTER trigger can be deferred
to the end of the transaction, rather than the end of the statement,
if it was defined as a constraint trigger.
In all cases, a trigger is executed as part of the same transaction as
the statement that triggered it, so if either the statement or the
trigger causes an error, the effects of both will be rolled back.
A statement that targets a parent table in an inheritance or partitioning
hierarchy does not cause the statement-level triggers of affected child
tables to be fired; only the parent table's statement-level triggers are
fired. However, row-level triggers of any affected child tables will be
fired.
If an INSERT contains an ON CONFLICT
DO UPDATE clause, it is possible that the effects of
row-level BEFORE INSERT triggers and
row-level BEFORE UPDATE triggers can
both be applied in a way that is apparent from the final state of
the updated row, if an EXCLUDED column is referenced.
There need not be an EXCLUDED column reference for
both sets of row-level BEFORE triggers to execute,
though. The
possibility of surprising outcomes should be considered when there
are both BEFORE INSERT and
BEFORE UPDATE row-level triggers
that change a row being inserted/updated (this can be
problematic even if the modifications are more or less equivalent, if
they're not also idempotent). Note that statement-level
UPDATE triggers are executed when ON
CONFLICT DO UPDATE is specified, regardless of whether or not
any rows were affected by the UPDATE (and
regardless of whether the alternative UPDATE
path was ever taken). An INSERT with an
ON CONFLICT DO UPDATE clause will execute
statement-level BEFORE INSERT
triggers first, then statement-level BEFORE
UPDATE triggers, followed by statement-level
AFTER UPDATE triggers and finally
statement-level AFTER INSERT
triggers.
If an UPDATE on a partitioned table causes a row to move
to another partition, it will be performed as a DELETE
from the original partition followed by an INSERT into
the new partition. In this case, all row-level BEFORE
UPDATE triggers and all row-level
BEFORE DELETE triggers are fired on
the original partition. Then all row-level BEFORE
INSERT triggers are fired on the destination partition.
The possibility of surprising outcomes should be considered when all these
triggers affect the row being moved. As far as AFTER ROW
triggers are concerned, AFTER DELETE
and AFTER INSERT triggers are
applied; but AFTER UPDATE triggers
are not applied because the UPDATE has been converted to
a DELETE and an INSERT. As far as
statement-level triggers are concerned, none of the
DELETE or INSERT triggers are fired,
even if row movement occurs; only the UPDATE triggers
defined on the target table used in the UPDATE statement
will be fired.
No separate triggers are defined for MERGE. Instead,
statement-level or row-level UPDATE,
DELETE, and INSERT triggers are fired
depending on (for statement-level triggers) what actions are specified in
the MERGE query and (for row-level triggers) what
actions are performed.
While running a MERGE command, statement-level
BEFORE and AFTER triggers are
fired for events specified in the actions of the MERGE
command, irrespective of whether or not the action is ultimately performed.
This is the same as an UPDATE statement that updates
no rows, yet statement-level triggers are fired.
The row-level triggers are fired only when a row is actually updated,
inserted or deleted. So it's perfectly legal that while statement-level
triggers are fired for certain types of action, no row-level triggers
are fired for the same kind of action.
Trigger functions invoked by per-statement triggers should always
return NULL. Trigger functions invoked by per-row
triggers can return a table row (a value of
type HeapTuple) to the calling executor,
if they choose. A row-level trigger fired before an operation has
the following choices:
It can return NULL to skip the operation for the
current row. This instructs the executor to not perform the
row-level operation that invoked the trigger (the insertion,
modification, or deletion of a particular table row).
For row-level INSERT
and UPDATE triggers only, the returned row
becomes the row that will be inserted or will replace the row
being updated. This allows the trigger function to modify the
row being inserted or updated.
A row-level BEFORE trigger that does not intend to cause
either of these behaviors must be careful to return as its result the same
row that was passed in (that is, the NEW row
for INSERT and UPDATE
triggers, the OLD row for
DELETE triggers).
A row-level INSTEAD OF trigger should either return
NULL to indicate that it did not modify any data from
the view's underlying base tables, or it should return the view
row that was passed in (the NEW row
for INSERT and UPDATE
operations, or the OLD row for
DELETE operations). A nonnull return value is
used to signal that the trigger performed the necessary data
modifications in the view. This will cause the count of the number
of rows affected by the command to be incremented. For
INSERT and UPDATE operations only, the trigger
may modify the NEW row before returning it. This will
change the data returned by
INSERT RETURNING or UPDATE RETURNING,
and is useful when the view will not show exactly the same data
that was provided.
The return value is ignored for row-level triggers fired after an
operation, and so they can return NULL.
Some considerations apply for generated
columns.generated columnin
triggers Stored generated columns are computed after
BEFORE triggers and before AFTER
triggers. Therefore, the generated value can be inspected in
AFTER triggers. In BEFORE triggers,
the OLD row contains the old generated value, as one
would expect, but the NEW row does not yet contain the
new generated value and should not be accessed. In the C language
interface, the content of the column is undefined at this point; a
higher-level programming language should prevent access to a stored
generated column in the NEW row in a
BEFORE trigger. Changes to the value of a generated
column in a BEFORE trigger are ignored and will be
overwritten.
If more than one trigger is defined for the same event on the same
relation, the triggers will be fired in alphabetical order by
trigger name. In the case of BEFORE and
INSTEAD OF triggers, the possibly-modified row returned by
each trigger becomes the input to the next trigger. If any
BEFORE or INSTEAD OF trigger returns
NULL, the operation is abandoned for that row and subsequent
triggers are not fired (for that row).
A trigger definition can also specify a Boolean WHEN
condition, which will be tested to see whether the trigger should
be fired. In row-level triggers the WHEN condition can
examine the old and/or new values of columns of the row. (Statement-level
triggers can also have WHEN conditions, although the feature
is not so useful for them.) In a BEFORE trigger, the
WHEN
condition is evaluated just before the function is or would be executed,
so using WHEN is not materially different from testing the
same condition at the beginning of the trigger function. However, in
an AFTER trigger, the WHEN condition is evaluated
just after the row update occurs, and it determines whether an event is
queued to fire the trigger at the end of statement. So when an
AFTER trigger's
WHEN condition does not return true, it is not necessary
to queue an event nor to re-fetch the row at end of statement. This
can result in significant speedups in statements that modify many
rows, if the trigger only needs to be fired for a few of the rows.
INSTEAD OF triggers do not support
WHEN conditions.
Typically, row-level BEFORE triggers are used for checking or
modifying the data that will be inserted or updated. For example,
a BEFORE trigger might be used to insert the current time into a
timestamp column, or to check that two elements of the row are
consistent. Row-level AFTER triggers are most sensibly
used to propagate the updates to other tables, or make consistency
checks against other tables. The reason for this division of labor is
that an AFTER trigger can be certain it is seeing the final
value of the row, while a BEFORE trigger cannot; there might
be other BEFORE triggers firing after it. If you have no
specific reason to make a trigger BEFORE or
AFTER, the BEFORE case is more efficient, since
the information about
the operation doesn't have to be saved until end of statement.
If a trigger function executes SQL commands then these
commands might fire triggers again. This is known as cascading
triggers. There is no direct limitation on the number of cascade
levels. It is possible for cascades to cause a recursive invocation
of the same trigger; for example, an INSERT
trigger might execute a command that inserts an additional row
into the same table, causing the INSERT trigger
to be fired again. It is the trigger programmer's responsibility
to avoid infinite recursion in such scenarios.
trigger
arguments for trigger functions
When a trigger is being defined, arguments can be specified for
it. The purpose of including arguments in the
trigger definition is to allow different triggers with similar
requirements to call the same function. As an example, there
could be a generalized trigger function that takes as its
arguments two column names and puts the current user in one and
the current time stamp in the other. Properly written, this
trigger function would be independent of the specific table it is
triggering on. So the same function could be used for
INSERT events on any table with suitable
columns, to automatically track creation of records in a
transaction table for example. It could also be used to track
last-update events if defined as an UPDATE
trigger.
Each programming language that supports triggers has its own method
for making the trigger input data available to the trigger function.
This input data includes the type of trigger event (e.g.,
INSERT or UPDATE) as well as any
arguments that were listed in CREATE TRIGGER.
For a row-level trigger, the input data also includes the
NEW row for INSERT and
UPDATE triggers, and/or the OLD row
for UPDATE and DELETE triggers.
By default, statement-level triggers do not have any way to examine the
individual row(s) modified by the statement. But an AFTER
STATEMENT trigger can request that transition tables
be created to make the sets of affected rows available to the trigger.
AFTER ROW triggers can also request transition tables, so
that they can see the total changes in the table as well as the change in
the individual row they are currently being fired for. The method for
examining the transition tables again depends on the programming language
that is being used, but the typical approach is to make the transition
tables act like read-only temporary tables that can be accessed by SQL
commands issued within the trigger function.
Visibility of Data Changes
If you execute SQL commands in your trigger function, and these
commands access the table that the trigger is for, then
you need to be aware of the data visibility rules, because they determine
whether these SQL commands will see the data change that the trigger
is fired for. Briefly:
Statement-level triggers follow simple visibility rules: none of
the changes made by a statement are visible to statement-level
BEFORE triggers, whereas all
modifications are visible to statement-level AFTER
triggers.
The data change (insertion, update, or deletion) causing the
trigger to fire is naturally not visible
to SQL commands executed in a row-level BEFORE trigger,
because it hasn't happened yet.
However, SQL commands executed in a row-level BEFORE
trigger will see the effects of data
changes for rows previously processed in the same outer
command. This requires caution, since the ordering of these
change events is not in general predictable; an SQL command that
affects multiple rows can visit the rows in any order.
Similarly, a row-level INSTEAD OF trigger will see the
effects of data changes made by previous firings of INSTEAD
OF triggers in the same outer command.
When a row-level AFTER trigger is fired, all data
changes made
by the outer command are already complete, and are visible to
the invoked trigger function.
If your trigger function is written in any of the standard procedural
languages, then the above statements apply only if the function is
declared VOLATILE. Functions that are declared
STABLE or IMMUTABLE will not see changes made by
the calling command in any case.
Further information about data visibility rules can be found in
. The example in contains a demonstration of these rules.
Writing Trigger Functions in C
trigger
in C
transition tables
referencing from C trigger
This section describes the low-level details of the interface to a
trigger function. This information is only needed when writing
trigger functions in C. If you are using a higher-level language then
these details are handled for you. In most cases you should consider
using a procedural language before writing your triggers in C. The
documentation of each procedural language explains how to write a
trigger in that language.
Trigger functions must use the version 1
function manager
interface.
When a function is called by the trigger manager, it is not passed
any normal arguments, but it is passed a context
pointer pointing to a TriggerData structure. C
functions can check whether they were called from the trigger
manager or not by executing the macro:
CALLED_AS_TRIGGER(fcinfo)
which expands to:
((fcinfo)->context != NULL && IsA((fcinfo)->context, TriggerData))
If this returns true, then it is safe to cast
fcinfo->context to type TriggerData
* and make use of the pointed-to
TriggerData structure. The function must
not alter the TriggerData
structure or any of the data it points to.
struct TriggerData is defined in
commands/trigger.h:
typedef struct TriggerData
{
NodeTag type;
TriggerEvent tg_event;
Relation tg_relation;
HeapTuple tg_trigtuple;
HeapTuple tg_newtuple;
Trigger *tg_trigger;
TupleTableSlot *tg_trigslot;
TupleTableSlot *tg_newslot;
Tuplestorestate *tg_oldtable;
Tuplestorestate *tg_newtable;
const Bitmapset *tg_updatedcols;
} TriggerData;
where the members are defined as follows:
type
Always T_TriggerData.
tg_event
Describes the event for which the function is called. You can use the
following macros to examine tg_event:
TRIGGER_FIRED_BEFORE(tg_event)
Returns true if the trigger fired before the operation.
TRIGGER_FIRED_AFTER(tg_event)
Returns true if the trigger fired after the operation.
TRIGGER_FIRED_INSTEAD(tg_event)
Returns true if the trigger fired instead of the operation.
TRIGGER_FIRED_FOR_ROW(tg_event)
Returns true if the trigger fired for a row-level event.
TRIGGER_FIRED_FOR_STATEMENT(tg_event)
Returns true if the trigger fired for a statement-level event.
TRIGGER_FIRED_BY_INSERT(tg_event)
Returns true if the trigger was fired by an INSERT command.
TRIGGER_FIRED_BY_UPDATE(tg_event)
Returns true if the trigger was fired by an UPDATE command.
TRIGGER_FIRED_BY_DELETE(tg_event)
Returns true if the trigger was fired by a DELETE command.
TRIGGER_FIRED_BY_TRUNCATE(tg_event)
Returns true if the trigger was fired by a TRUNCATE command.
tg_relation
A pointer to a structure describing the relation that the trigger fired for.
Look at utils/rel.h for details about
this structure. The most interesting things are
tg_relation->rd_att (descriptor of the relation
tuples) and tg_relation->rd_rel->relname
(relation name; the type is not char* but
NameData; use
SPI_getrelname(tg_relation) to get a char* if you
need a copy of the name).
tg_trigtuple
A pointer to the row for which the trigger was fired. This is
the row being inserted, updated, or deleted. If this trigger
was fired for an INSERT or
DELETE then this is what you should return
from the function if you don't want to replace the row with
a different one (in the case of INSERT) or
skip the operation. For triggers on foreign tables, values of system
columns herein are unspecified.
tg_newtuple
A pointer to the new version of the row, if the trigger was
fired for an UPDATE, and NULL if
it is for an INSERT or a
DELETE. This is what you have to return
from the function if the event is an UPDATE
and you don't want to replace this row by a different one or
skip the operation. For triggers on foreign tables, values of system
columns herein are unspecified.
tg_trigger
A pointer to a structure of type Trigger,
defined in utils/reltrigger.h:
typedef struct Trigger
{
Oid tgoid;
char *tgname;
Oid tgfoid;
int16 tgtype;
char tgenabled;
bool tgisinternal;
bool tgisclone;
Oid tgconstrrelid;
Oid tgconstrindid;
Oid tgconstraint;
bool tgdeferrable;
bool tginitdeferred;
int16 tgnargs;
int16 tgnattr;
int16 *tgattr;
char **tgargs;
char *tgqual;
char *tgoldtable;
char *tgnewtable;
} Trigger;
where tgname is the trigger's name,
tgnargs is the number of arguments in
tgargs, and tgargs is an array of
pointers to the arguments specified in the CREATE
TRIGGER statement. The other members are for internal use
only.
tg_trigslot
The slot containing tg_trigtuple,
or a NULL pointer if there is no such tuple.
tg_newslot
The slot containing tg_newtuple,
or a NULL pointer if there is no such tuple.
tg_oldtable
A pointer to a structure of type Tuplestorestate
containing zero or more rows in the format specified by
tg_relation, or a NULL pointer
if there is no OLD TABLE transition relation.
tg_newtable
A pointer to a structure of type Tuplestorestate
containing zero or more rows in the format specified by
tg_relation, or a NULL pointer
if there is no NEW TABLE transition relation.
tg_updatedcols
For UPDATE triggers, a bitmap set indicating the
columns that were updated by the triggering command. Generic trigger
functions can use this to optimize actions by not having to deal with
columns that were not changed.
As an example, to determine whether a column with attribute number
attnum (1-based) is a member of this bitmap set,
call bms_is_member(attnum -
FirstLowInvalidHeapAttributeNumber,
trigdata->tg_updatedcols)).
For triggers other than UPDATE triggers, this will
be NULL.
To allow queries issued through SPI to reference transition tables, see
.
A trigger function must return either a
HeapTuple pointer or a NULL pointer
(not an SQL null value, that is, do not set isNull true).
Be careful to return either
tg_trigtuple or tg_newtuple,
as appropriate, if you don't want to modify the row being operated on.
A Complete Trigger Example
Here is a very simple example of a trigger function written in C.
(Examples of triggers written in procedural languages can be found
in the documentation of the procedural languages.)
The function trigf reports the number of rows in the
table ttest and skips the actual operation if the
command attempts to insert a null value into the column
x. (So the trigger acts as a not-null constraint but
doesn't abort the transaction.)
First, the table definition:
CREATE TABLE ttest (
x integer
);
This is the source code of the trigger function:
context;
TupleDesc tupdesc;
HeapTuple rettuple;
char *when;
bool checknull = false;
bool isnull;
int ret, i;
/* make sure it's called as a trigger at all */
if (!CALLED_AS_TRIGGER(fcinfo))
elog(ERROR, "trigf: not called by trigger manager");
/* tuple to return to executor */
if (TRIGGER_FIRED_BY_UPDATE(trigdata->tg_event))
rettuple = trigdata->tg_newtuple;
else
rettuple = trigdata->tg_trigtuple;
/* check for null values */
if (!TRIGGER_FIRED_BY_DELETE(trigdata->tg_event)
&& TRIGGER_FIRED_BEFORE(trigdata->tg_event))
checknull = true;
if (TRIGGER_FIRED_BEFORE(trigdata->tg_event))
when = "before";
else
when = "after ";
tupdesc = trigdata->tg_relation->rd_att;
/* connect to SPI manager */
if ((ret = SPI_connect()) < 0)
elog(ERROR, "trigf (fired %s): SPI_connect returned %d", when, ret);
/* get number of rows in table */
ret = SPI_exec("SELECT count(*) FROM ttest", 0);
if (ret < 0)
elog(ERROR, "trigf (fired %s): SPI_exec returned %d", when, ret);
/* count(*) returns int8, so be careful to convert */
i = DatumGetInt64(SPI_getbinval(SPI_tuptable->vals[0],
SPI_tuptable->tupdesc,
1,
&isnull));
elog (INFO, "trigf (fired %s): there are %d rows in ttest", when, i);
SPI_finish();
if (checknull)
{
SPI_getbinval(rettuple, tupdesc, 1, &isnull);
if (isnull)
rettuple = NULL;
}
return PointerGetDatum(rettuple);
}
]]>
After you have compiled the source code (see ), declare the function and the triggers:
CREATE FUNCTION trigf() RETURNS trigger
AS 'filename'
LANGUAGE C;
CREATE TRIGGER tbefore BEFORE INSERT OR UPDATE OR DELETE ON ttest
FOR EACH ROW EXECUTE FUNCTION trigf();
CREATE TRIGGER tafter AFTER INSERT OR UPDATE OR DELETE ON ttest
FOR EACH ROW EXECUTE FUNCTION trigf();
Now you can test the operation of the trigger:
=> INSERT INTO ttest VALUES (NULL);
INFO: trigf (fired before): there are 0 rows in ttest
INSERT 0 0
-- Insertion skipped and AFTER trigger is not fired
=> SELECT * FROM ttest;
x
---
(0 rows)
=> INSERT INTO ttest VALUES (1);
INFO: trigf (fired before): there are 0 rows in ttest
INFO: trigf (fired after ): there are 1 rows in ttest
^^^^^^^^
remember what we said about visibility.
INSERT 167793 1
vac=> SELECT * FROM ttest;
x
---
1
(1 row)
=> INSERT INTO ttest SELECT x * 2 FROM ttest;
INFO: trigf (fired before): there are 1 rows in ttest
INFO: trigf (fired after ): there are 2 rows in ttest
^^^^^^
remember what we said about visibility.
INSERT 167794 1
=> SELECT * FROM ttest;
x
---
1
2
(2 rows)
=> UPDATE ttest SET x = NULL WHERE x = 2;
INFO: trigf (fired before): there are 2 rows in ttest
UPDATE 0
=> UPDATE ttest SET x = 4 WHERE x = 2;
INFO: trigf (fired before): there are 2 rows in ttest
INFO: trigf (fired after ): there are 2 rows in ttest
UPDATE 1
vac=> SELECT * FROM ttest;
x
---
1
4
(2 rows)
=> DELETE FROM ttest;
INFO: trigf (fired before): there are 2 rows in ttest
INFO: trigf (fired before): there are 1 rows in ttest
INFO: trigf (fired after ): there are 0 rows in ttest
INFO: trigf (fired after ): there are 0 rows in ttest
^^^^^^
remember what we said about visibility.
DELETE 2
=> SELECT * FROM ttest;
x
---
(0 rows)
There are more complex examples in
src/test/regress/regress.c and
in .