src/third_party/sqlite/src/tool/genfkey.README - cobalt - Git at Google


 OVERVIEW

   The SQLite library is capable of parsing SQL foreign key constraints
   supplied as part of CREATE TABLE statements, but it does not actually
   implement them. However, most of the features of foreign keys may be
   implemented using SQL triggers, which SQLite does support. This text
   file describes a feature of the SQLite shell tool (sqlite3) that
   extracts foreign key definitions from an existing SQLite database and
   creates the set of CREATE TRIGGER statements required to implement
   the foreign key constraints.

 CAPABILITIES

   An SQL foreign key is a constraint that requires that each row in
   the "child" table corresponds to a row in the "parent" table. For
   example, the following schema:

     CREATE TABLE parent(a, b, c, PRIMARY KEY(a, b));
     CREATE TABLE child(d, e, f, FOREIGN KEY(d, e) REFERENCES parent(a, b));

   implies that for each row in table "child", there must be a row in
   "parent" for which the expression (child.d==parent.a AND child.e==parent.b)
   is true. The columns in the parent table are required to be either the
   primary key columns or subject to a UNIQUE constraint. There is no such
   requirement for the columns of the child table.

   At this time, all foreign keys are implemented as if they were
   "MATCH NONE", even if the declaration specified "MATCH PARTIAL" or
   "MATCH FULL". "MATCH NONE" means that if any of the key columns in
   the child table are NULL, then there is no requirement for a corresponding
   row in the parent table. So, taking this into account, the expression that
   must be true for every row of the child table in the above example is
   actually:

       (child.d IS NULL) OR
       (child.e IS NULL) OR
       (child.d==parent.a AND child.e==parent.b)

   Attempting to insert or update a row in the child table so that the
   affected row violates this constraint results in an exception being
   thrown.

   The effect of attempting to delete or update a row in the parent table
   so that the constraint becomes untrue for one or more rows in the child
   table depends on the "ON DELETE" or "ON UPDATE" actions specified as
   part of the foreign key definition, respectively. Three different actions
   are supported: "RESTRICT" (the default), "CASCADE" and "SET NULL". SQLite
   will also parse the "SET DEFAULT" action, but this is not implemented
   and "RESTRICT" is used instead.

     RESTRICT: Attempting to update or delete a row in the parent table so
               that the constraint becomes untrue for one or more rows in
               the child table is not allowed. An exception is thrown.

     CASCADE:  Instead of throwing an exception, all corresponding child table
               rows are either deleted (if the parent row is being deleted)
               or updated to match the new parent key values (if the parent
               row is being updated).

     SET NULL: Instead of throwing an exception, the foreign key fields of
               all corresponding child table rows are set to NULL.

 LIMITATIONS

   Apart from those limitiations described above:

     * Implicit mapping to composite primary keys is not supported. If
       a parent table has a composite primary key, then any child table
       that refers to it must explicitly map each column. For example, given
       the following definition of table "parent":

         CREATE TABLE parent(a, b, c, PRIMARY KEY(a, b));

       only the first of the following two definitions of table "child"
       is supported:

         CREATE TABLE child(d, e, f, FOREIGN KEY(d, e) REFERENCES parent(a, b));
         CREATE TABLE child(d, e, f, FOREIGN KEY(d, e) REFERENCES parent);

       An implicit reference to a composite primary key is detected as an
       error when the program is run (see below).

     * SQLite does not support recursive triggers, and therefore this program
       does not support recursive CASCADE or SET NULL foreign key
       relationships. If the parent and the child tables of a CASCADE or
       SET NULL foreign key are the same table, the generated triggers will
       malfunction. This is also true if the recursive foreign key constraint
       is indirect (for example if table A references table B which references
       table A with a CASCADE or SET NULL foreign key constraint).

       Recursive CASCADE or SET NULL foreign key relationships are *not*
       detected as errors when the program is run. Buyer beware.

 USAGE

   The functionality is accessed through an sqlite3 shell tool "dot-command":

     .genfkey ?--no-drop? ?--ignore-errors? ?--exec?

   When this command is run, it first checks the schema of the open SQLite
   database for foreign key related errors or inconsistencies. For example,
   a foreign key that refers to a parent table that does not exist, or
   a foreign key that refers to columns in a parent table that are not
   guaranteed to be unique. If such errors are found and the --ignore-errors
   option was not present, a message for each one is printed to stderr and
   no further processing takes place.

   If errors are found and the --ignore-errors option is passed, then
   no error messages are printed. No "CREATE TRIGGER" statements are generated
   for foriegn-key definitions that contained errors, they are silently
   ignored by subsequent processing.

   All triggers generated by this command have names that match the pattern
   "genfkey*". Unless the --no-drop option is specified, then the program
   also generates a "DROP TRIGGER" statement for each trigger that exists
   in the database with a name that matches this pattern. This allows the
   program to be used to upgrade a database schema for which foreign key
   triggers have already been installed (i.e. after new tables are created
   or existing tables dropped).

   Finally, a series of SQL trigger definitions (CREATE TRIGGER statements)
   that implement the foreign key constraints found in the database schema are
   generated.

   If the --exec option was passed, then all generated SQL is immediately
   executed on the database. Otherwise, the generated SQL strings are output
   in the same way as the results of SELECT queries are. Normally, this means
   they will be printed to stdout, but this can be configured using other
   dot-commands (i.e. ".output").

   The simplest way to activate the foriegn key definitions in a database
   is simply to open it using the shell tool and enter the command
   ".genfkey --exec":

     sqlite> .genfkey --exec

	OVERVIEW

	The SQLite library is capable of parsing SQL foreign key constraints
	supplied as part of CREATE TABLE statements, but it does not actually
	implement them. However, most of the features of foreign keys may be
	implemented using SQL triggers, which SQLite does support. This text
	file describes a feature of the SQLite shell tool (sqlite3) that
	extracts foreign key definitions from an existing SQLite database and
	creates the set of CREATE TRIGGER statements required to implement
	the foreign key constraints.

	CAPABILITIES

	An SQL foreign key is a constraint that requires that each row in
	the "child" table corresponds to a row in the "parent" table. For
	example, the following schema:

	CREATE TABLE parent(a, b, c, PRIMARY KEY(a, b));
	CREATE TABLE child(d, e, f, FOREIGN KEY(d, e) REFERENCES parent(a, b));

	implies that for each row in table "child", there must be a row in
	"parent" for which the expression (child.d==parent.a AND child.e==parent.b)
	is true. The columns in the parent table are required to be either the
	primary key columns or subject to a UNIQUE constraint. There is no such
	requirement for the columns of the child table.

	At this time, all foreign keys are implemented as if they were
	"MATCH NONE", even if the declaration specified "MATCH PARTIAL" or
	"MATCH FULL". "MATCH NONE" means that if any of the key columns in
	the child table are NULL, then there is no requirement for a corresponding
	row in the parent table. So, taking this into account, the expression that
	must be true for every row of the child table in the above example is
	actually:

	(child.d IS NULL) OR
	(child.e IS NULL) OR
	(child.d==parent.a AND child.e==parent.b)

	Attempting to insert or update a row in the child table so that the
	affected row violates this constraint results in an exception being
	thrown.

	The effect of attempting to delete or update a row in the parent table
	so that the constraint becomes untrue for one or more rows in the child
	table depends on the "ON DELETE" or "ON UPDATE" actions specified as
	part of the foreign key definition, respectively. Three different actions
	are supported: "RESTRICT" (the default), "CASCADE" and "SET NULL". SQLite
	will also parse the "SET DEFAULT" action, but this is not implemented
	and "RESTRICT" is used instead.

	RESTRICT: Attempting to update or delete a row in the parent table so
	that the constraint becomes untrue for one or more rows in
	the child table is not allowed. An exception is thrown.

	CASCADE: Instead of throwing an exception, all corresponding child table
	rows are either deleted (if the parent row is being deleted)
	or updated to match the new parent key values (if the parent
	row is being updated).

	SET NULL: Instead of throwing an exception, the foreign key fields of
	all corresponding child table rows are set to NULL.

	LIMITATIONS

	Apart from those limitiations described above:

	* Implicit mapping to composite primary keys is not supported. If
	a parent table has a composite primary key, then any child table
	that refers to it must explicitly map each column. For example, given
	the following definition of table "parent":

	CREATE TABLE parent(a, b, c, PRIMARY KEY(a, b));

	only the first of the following two definitions of table "child"
	is supported:

	CREATE TABLE child(d, e, f, FOREIGN KEY(d, e) REFERENCES parent(a, b));
	CREATE TABLE child(d, e, f, FOREIGN KEY(d, e) REFERENCES parent);

	An implicit reference to a composite primary key is detected as an
	error when the program is run (see below).

	* SQLite does not support recursive triggers, and therefore this program
	does not support recursive CASCADE or SET NULL foreign key
	relationships. If the parent and the child tables of a CASCADE or
	SET NULL foreign key are the same table, the generated triggers will
	malfunction. This is also true if the recursive foreign key constraint
	is indirect (for example if table A references table B which references
	table A with a CASCADE or SET NULL foreign key constraint).

	Recursive CASCADE or SET NULL foreign key relationships are not
	detected as errors when the program is run. Buyer beware.

	USAGE

	The functionality is accessed through an sqlite3 shell tool "dot-command":

	.genfkey ?--no-drop? ?--ignore-errors? ?--exec?

	When this command is run, it first checks the schema of the open SQLite
	database for foreign key related errors or inconsistencies. For example,
	a foreign key that refers to a parent table that does not exist, or
	a foreign key that refers to columns in a parent table that are not
	guaranteed to be unique. If such errors are found and the --ignore-errors
	option was not present, a message for each one is printed to stderr and
	no further processing takes place.

	If errors are found and the --ignore-errors option is passed, then
	no error messages are printed. No "CREATE TRIGGER" statements are generated
	for foriegn-key definitions that contained errors, they are silently
	ignored by subsequent processing.

	All triggers generated by this command have names that match the pattern
	"genfkey*". Unless the --no-drop option is specified, then the program
	also generates a "DROP TRIGGER" statement for each trigger that exists
	in the database with a name that matches this pattern. This allows the
	program to be used to upgrade a database schema for which foreign key
	triggers have already been installed (i.e. after new tables are created
	or existing tables dropped).

	Finally, a series of SQL trigger definitions (CREATE TRIGGER statements)
	that implement the foreign key constraints found in the database schema are
	generated.

	If the --exec option was passed, then all generated SQL is immediately
	executed on the database. Otherwise, the generated SQL strings are output
	in the same way as the results of SELECT queries are. Normally, this means
	they will be printed to stdout, but this can be configured using other
	dot-commands (i.e. ".output").

	The simplest way to activate the foriegn key definitions in a database
	is simply to open it using the shell tool and enter the command
	".genfkey --exec":

	sqlite> .genfkey --exec