3 DBIx::Class::Manual::Cookbook - Miscellaneous recipes
9 When you expect a large number of results, you can ask L<DBIx::Class> for a
10 paged resultset, which will fetch only a defined number of records at a time:
12 my $rs = $schema->resultset('Artist')->search(
15 page => 1, # page to return (defaults to 1)
16 rows => 10, # number of results per page
20 return $rs->all(); # all records for page 1
22 You can get a L<Data::Page> object for the resultset (suitable for use
23 in e.g. a template) using the C<pager> method:
27 =head2 Complex WHERE clauses
29 Sometimes you need to formulate a query using specific operators:
31 my @albums = $schema->resultset('Album')->search({
32 artist => { 'like', '%Lamb%' },
33 title => { 'like', '%Fear of Fours%' },
36 This results in something like the following C<WHERE> clause:
38 WHERE artist LIKE '%Lamb%' AND title LIKE '%Fear of Fours%'
40 Other queries might require slightly more complex logic:
42 my @albums = $schema->resultset('Album')->search({
45 artist => { 'like', '%Smashing Pumpkins%' },
46 title => 'Siamese Dream',
48 artist => 'Starchildren',
52 This results in the following C<WHERE> clause:
54 WHERE ( artist LIKE '%Smashing Pumpkins%' AND title = 'Siamese Dream' )
55 OR artist = 'Starchildren'
57 For more information on generating complex queries, see
58 L<SQL::Abstract/WHERE CLAUSES>.
60 =head2 Retrieve one and only one row from a resultset
62 Sometimes you need only the first "top" row of a resultset. While this can be
63 easily done with L<< $rs->first|DBIx::Class::ResultSet/first >>, it is suboptimal,
64 as a full blown cursor for the resultset will be created and then immediately
65 destroyed after fetching the first row object.
66 L<< $rs->single|DBIx::Class::ResultSet/single >> is
67 designed specifically for this case - it will grab the first returned result
68 without even instantiating a cursor.
70 Before replacing all your calls to C<first()> with C<single()> please observe the
76 While single() takes a search condition just like search() does, it does
77 _not_ accept search attributes. However one can always chain a single() to
80 my $top_cd = $cd_rs -> search({}, { order_by => 'rating' }) -> single;
84 Since single() is the engine behind find(), it is designed to fetch a
85 single row per database query. Thus a warning will be issued when the
86 underlying SELECT returns more than one row. Sometimes however this usage
87 is valid: i.e. we have an arbitrary number of cd's but only one of them is
88 at the top of the charts at any given time. If you know what you are doing,
89 you can silence the warning by explicitly limiting the resultset size:
91 my $top_cd = $cd_rs -> search ({}, { order_by => 'rating', rows => 1 }) -> single;
95 =head2 Arbitrary SQL through a custom ResultSource
97 Sometimes you have to run arbitrary SQL because your query is too complex
98 (e.g. it contains Unions, Sub-Selects, Stored Procedures, etc.) or has to
99 be optimized for your database in a special way, but you still want to
100 get the results as a L<DBIx::Class::ResultSet>.
101 The recommended way to accomplish this is by defining a separate ResultSource
102 for your query. You can then inject complete SQL statements using a scalar
103 reference (this is a feature of L<SQL::Abstract>).
105 Say you want to run a complex custom query on your user data, here's what
106 you have to add to your User class:
108 package My::Schema::Result::User;
110 use base qw/DBIx::Class/;
112 # ->load_components, ->table, ->add_columns, etc.
114 # Make a new ResultSource based on the User class
115 my $source = __PACKAGE__->result_source_instance();
116 my $new_source = $source->new( $source );
117 $new_source->source_name( 'UserFriendsComplex' );
119 # Hand in your query as a scalar reference
120 # It will be added as a sub-select after FROM,
121 # so pay attention to the surrounding brackets!
122 $new_source->name( \<<SQL );
123 ( SELECT u.* FROM user u
124 INNER JOIN user_friends f ON u.id = f.user_id
125 WHERE f.friend_user_id = ?
127 SELECT u.* FROM user u
128 INNER JOIN user_friends f ON u.id = f.friend_user_id
129 WHERE f.user_id = ? )
132 # Finally, register your new ResultSource with your Schema
133 My::Schema->register_extra_source( 'UserFriendsComplex' => $new_source );
135 Next, you can execute your complex query using bind parameters like this:
137 my $friends = [ $schema->resultset( 'UserFriendsComplex' )->search( {},
139 bind => [ 12345, 12345 ]
143 ... and you'll get back a perfect L<DBIx::Class::ResultSet> (except, of course,
144 that you cannot modify the rows it contains, ie. cannot call L</update>,
145 L</delete>, ... on it).
147 If you prefer to have the definitions of these custom ResultSources in separate
148 files (instead of stuffing all of them into the same resultset class), you can
149 achieve the same with subclassing the resultset class and defining the
152 package My::Schema::Result::UserFriendsComplex;
154 use My::Schema::Result::User;
155 use base qw/My::Schema::Result::User/;
157 __PACKAGE__->table('dummy'); # currently must be called before anything else
159 # Hand in your query as a scalar reference
160 # It will be added as a sub-select after FROM,
161 # so pay attention to the surrounding brackets!
162 __PACKAGE__->name( \<<SQL );
163 ( SELECT u.* FROM user u
164 INNER JOIN user_friends f ON u.id = f.user_id
165 WHERE f.friend_user_id = ?
167 SELECT u.* FROM user u
168 INNER JOIN user_friends f ON u.id = f.friend_user_id
169 WHERE f.user_id = ? )
174 =head2 Using specific columns
176 When you only want specific columns from a table, you can use
177 C<columns> to specify which ones you need. This is useful to avoid
178 loading columns with large amounts of data that you aren't about to
181 my $rs = $schema->resultset('Artist')->search(
184 columns => [qw/ name /]
189 # SELECT artist.name FROM artist
191 This is a shortcut for C<select> and C<as>, see below. C<columns>
192 cannot be used together with C<select> and C<as>.
194 =head2 Using database functions or stored procedures
196 The combination of C<select> and C<as> can be used to return the result of a
197 database function or stored procedure as a column value. You use C<select> to
198 specify the source for your column value (e.g. a column name, function, or
199 stored procedure name). You then use C<as> to set the column name you will use
200 to access the returned value:
202 my $rs = $schema->resultset('Artist')->search(
205 select => [ 'name', { LENGTH => 'name' } ],
206 as => [qw/ name name_length /],
211 # SELECT name name, LENGTH( name )
214 Note that the C< as > attribute has absolutely nothing to with the sql
215 syntax C< SELECT foo AS bar > (see the documentation in
216 L<DBIx::Class::ResultSet/ATTRIBUTES>). If your alias exists as a
217 column in your base class (i.e. it was added with C<add_columns>), you
218 just access it as normal. Our C<Artist> class has a C<name> column, so
219 we just use the C<name> accessor:
221 my $artist = $rs->first();
222 my $name = $artist->name();
224 If on the other hand the alias does not correspond to an existing column, you
225 have to fetch the value using the C<get_column> accessor:
227 my $name_length = $artist->get_column('name_length');
229 If you don't like using C<get_column>, you can always create an accessor for
230 any of your aliases using either of these:
232 # Define accessor manually:
233 sub name_length { shift->get_column('name_length'); }
235 # Or use DBIx::Class::AccessorGroup:
236 __PACKAGE__->mk_group_accessors('column' => 'name_length');
238 =head2 SELECT DISTINCT with multiple columns
240 my $rs = $schema->resultset('Artist')->search(
243 columns => [ qw/artistid name rank/ ],
248 my $rs = $schema->resultset('Artist')->search(
251 columns => [ qw/artistid name rank/ ],
252 group_by => [ qw/artistid name rank/ ],
257 # SELECT me.artistid, me.name, me.rank
259 # GROUP BY artistid, name, rank
261 =head2 SELECT COUNT(DISTINCT colname)
263 my $rs = $schema->resultset('Artist')->search(
266 columns => [ qw/name/ ],
271 my $rs = $schema->resultset('Artist')->search(
274 columns => [ qw/name/ ],
275 group_by => [ qw/name/ ],
279 my $count = $rs->count;
282 # SELECT COUNT( * ) FROM (SELECT me.name FROM artist me GROUP BY me.name) count_subq:
284 =head2 Grouping results
286 L<DBIx::Class> supports C<GROUP BY> as follows:
288 my $rs = $schema->resultset('Artist')->search(
292 select => [ 'name', { count => 'cds.id' } ],
293 as => [qw/ name cd_count /],
294 group_by => [qw/ name /]
299 # SELECT name, COUNT( cd.id ) FROM artist
300 # LEFT JOIN cd ON artist.id = cd.artist
303 Please see L<DBIx::Class::ResultSet/ATTRIBUTES> documentation if you
304 are in any way unsure about the use of the attributes above (C< join
305 >, C< select >, C< as > and C< group_by >).
307 =head2 Subqueries (EXPERIMENTAL)
309 You can write subqueries relatively easily in DBIC.
311 my $inside_rs = $schema->resultset('Artist')->search({
312 name => [ 'Billy Joel', 'Brittany Spears' ],
315 my $rs = $schema->resultset('CD')->search({
316 artist_id => { 'IN' => $inside_rs->get_column('id')->as_query },
319 The usual operators ( =, !=, IN, NOT IN, etc) are supported.
321 B<NOTE>: You have to explicitly use '=' when doing an equality comparison.
322 The following will B<not> work:
324 my $rs = $schema->resultset('CD')->search({
325 artist_id => $inside_rs->get_column('id')->as_query,
330 Subqueries are supported in the where clause (first hashref), and in the
331 from, select, and +select attributes.
333 =head3 Correlated subqueries
335 my $cdrs = $schema->resultset('CD');
336 my $rs = $cdrs->search({
338 '=' => $cdrs->search(
339 { artistid => { '=' => \'me.artistid' } },
341 )->get_column('year')->max_rs->as_query,
345 That creates the following SQL:
347 SELECT me.cdid, me.artist, me.title, me.year, me.genreid, me.single_track
350 SELECT MAX(inner.year)
352 WHERE artistid = me.artistid
357 Please note that subqueries are considered an experimental feature.
359 =head2 Predefined searches
361 You can write your own L<DBIx::Class::ResultSet> class by inheriting from it
362 and define often used searches as methods:
364 package My::DBIC::ResultSet::CD;
367 use base 'DBIx::Class::ResultSet';
369 sub search_cds_ordered {
372 return $self->search(
374 { order_by => 'name DESC' },
380 To use your resultset, first tell DBIx::Class to create an instance of it
381 for you, in your My::DBIC::Schema::CD class:
383 # class definition as normal
384 __PACKAGE__->load_components(qw/ Core /);
385 __PACKAGE__->table('cd');
387 # tell DBIC to use the custom ResultSet class
388 __PACKAGE__->resultset_class('My::DBIC::ResultSet::CD');
390 Note that C<resultset_class> must be called after C<load_components> and C<table>, or you will get errors about missing methods.
392 Then call your new method in your code:
394 my $ordered_cds = $schema->resultset('CD')->search_cds_ordered();
396 =head2 Using SQL functions on the left hand side of a comparison
398 Using SQL functions on the left hand side of a comparison is generally
399 not a good idea since it requires a scan of the entire table. However,
400 it can be accomplished with C<DBIx::Class> when necessary.
402 If you do not have quoting on, simply include the function in your search
403 specification as you would any column:
405 $rs->search({ 'YEAR(date_of_birth)' => 1979 });
407 With quoting on, or for a more portable solution, use the C<where>
410 $rs->search({}, { where => \'YEAR(date_of_birth) = 1979' });
414 (When the bind args ordering bug is fixed, this technique will be better
415 and can replace the one above.)
417 With quoting on, or for a more portable solution, use the C<where> and
421 where => \'YEAR(date_of_birth) = ?',
427 =head1 JOINS AND PREFETCHING
429 =head2 Using joins and prefetch
431 You can use the C<join> attribute to allow searching on, or sorting your
432 results by, one or more columns in a related table. To return all CDs matching
433 a particular artist name:
435 my $rs = $schema->resultset('CD')->search(
437 'artist.name' => 'Bob Marley'
440 join => 'artist', # join the artist table
445 # SELECT cd.* FROM cd
446 # JOIN artist ON cd.artist = artist.id
447 # WHERE artist.name = 'Bob Marley'
449 If required, you can now sort on any column in the related tables by including
450 it in your C<order_by> attribute:
452 my $rs = $schema->resultset('CD')->search(
454 'artist.name' => 'Bob Marley'
458 order_by => [qw/ artist.name /]
463 # SELECT cd.* FROM cd
464 # JOIN artist ON cd.artist = artist.id
465 # WHERE artist.name = 'Bob Marley'
466 # ORDER BY artist.name
468 Note that the C<join> attribute should only be used when you need to search or
469 sort using columns in a related table. Joining related tables when you only
470 need columns from the main table will make performance worse!
472 Now let's say you want to display a list of CDs, each with the name of the
473 artist. The following will work fine:
475 while (my $cd = $rs->next) {
476 print "CD: " . $cd->title . ", Artist: " . $cd->artist->name;
479 There is a problem however. We have searched both the C<cd> and C<artist> tables
480 in our main query, but we have only returned data from the C<cd> table. To get
481 the artist name for any of the CD objects returned, L<DBIx::Class> will go back
484 SELECT artist.* FROM artist WHERE artist.id = ?
486 A statement like the one above will run for each and every CD returned by our
487 main query. Five CDs, five extra queries. A hundred CDs, one hundred extra
490 Thankfully, L<DBIx::Class> has a C<prefetch> attribute to solve this problem.
491 This allows you to fetch results from related tables in advance:
493 my $rs = $schema->resultset('CD')->search(
495 'artist.name' => 'Bob Marley'
499 order_by => [qw/ artist.name /],
500 prefetch => 'artist' # return artist data too!
504 # Equivalent SQL (note SELECT from both "cd" and "artist"):
505 # SELECT cd.*, artist.* FROM cd
506 # JOIN artist ON cd.artist = artist.id
507 # WHERE artist.name = 'Bob Marley'
508 # ORDER BY artist.name
510 The code to print the CD list remains the same:
512 while (my $cd = $rs->next) {
513 print "CD: " . $cd->title . ", Artist: " . $cd->artist->name;
516 L<DBIx::Class> has now prefetched all matching data from the C<artist> table,
517 so no additional SQL statements are executed. You now have a much more
520 Also note that C<prefetch> should only be used when you know you will
521 definitely use data from a related table. Pre-fetching related tables when you
522 only need columns from the main table will make performance worse!
524 =head2 Multiple joins
526 In the examples above, the C<join> attribute was a scalar. If you
527 pass an array reference instead, you can join to multiple tables. In
528 this example, we want to limit the search further, using
531 # Relationships defined elsewhere:
532 # CD->belongs_to('artist' => 'Artist');
533 # CD->has_one('liner_notes' => 'LinerNotes', 'cd');
534 my $rs = $schema->resultset('CD')->search(
536 'artist.name' => 'Bob Marley'
537 'liner_notes.notes' => { 'like', '%some text%' },
540 join => [qw/ artist liner_notes /],
541 order_by => [qw/ artist.name /],
546 # SELECT cd.*, artist.*, liner_notes.* FROM cd
547 # JOIN artist ON cd.artist = artist.id
548 # JOIN liner_notes ON cd.id = liner_notes.cd
549 # WHERE artist.name = 'Bob Marley'
550 # ORDER BY artist.name
552 =head2 Multi-step joins
554 Sometimes you want to join more than one relationship deep. In this example,
555 we want to find all C<Artist> objects who have C<CD>s whose C<LinerNotes>
556 contain a specific string:
558 # Relationships defined elsewhere:
559 # Artist->has_many('cds' => 'CD', 'artist');
560 # CD->has_one('liner_notes' => 'LinerNotes', 'cd');
562 my $rs = $schema->resultset('Artist')->search(
564 'liner_notes.notes' => { 'like', '%some text%' },
568 'cds' => 'liner_notes'
574 # SELECT artist.* FROM artist
575 # LEFT JOIN cd ON artist.id = cd.artist
576 # LEFT JOIN liner_notes ON cd.id = liner_notes.cd
577 # WHERE liner_notes.notes LIKE '%some text%'
579 Joins can be nested to an arbitrary level. So if we decide later that we
580 want to reduce the number of Artists returned based on who wrote the liner
583 # Relationship defined elsewhere:
584 # LinerNotes->belongs_to('author' => 'Person');
586 my $rs = $schema->resultset('Artist')->search(
588 'liner_notes.notes' => { 'like', '%some text%' },
589 'author.name' => 'A. Writer'
594 'liner_notes' => 'author'
601 # SELECT artist.* FROM artist
602 # LEFT JOIN cd ON artist.id = cd.artist
603 # LEFT JOIN liner_notes ON cd.id = liner_notes.cd
604 # LEFT JOIN author ON author.id = liner_notes.author
605 # WHERE liner_notes.notes LIKE '%some text%'
606 # AND author.name = 'A. Writer'
608 =head2 Multi-step and multiple joins
610 With various combinations of array and hash references, you can join
611 tables in any combination you desire. For example, to join Artist to
612 CD and Concert, and join CD to LinerNotes:
614 # Relationships defined elsewhere:
615 # Artist->has_many('concerts' => 'Concert', 'artist');
617 my $rs = $schema->resultset('Artist')->search(
630 # SELECT artist.* FROM artist
631 # LEFT JOIN cd ON artist.id = cd.artist
632 # LEFT JOIN liner_notes ON cd.id = liner_notes.cd
633 # LEFT JOIN concert ON artist.id = concert.artist
635 =head2 Multi-step prefetch
637 C<prefetch> can be nested more than one relationship
638 deep using the same syntax as a multi-step join:
640 my $rs = $schema->resultset('Tag')->search(
650 # SELECT tag.*, cd.*, artist.* FROM tag
651 # JOIN cd ON tag.cd = cd.id
652 # JOIN artist ON cd.artist = artist.id
654 Now accessing our C<cd> and C<artist> relationships does not need additional
657 my $tag = $rs->first;
658 print $tag->cd->artist->name;
660 =head1 ROW-LEVEL OPERATIONS
662 =head2 Retrieving a row object's Schema
664 It is possible to get a Schema object from a row object like so:
666 my $schema = $cd->result_source->schema;
667 # use the schema as normal:
668 my $artist_rs = $schema->resultset('Artist');
670 This can be useful when you don't want to pass around a Schema object to every
673 =head2 Getting the value of the primary key for the last database insert
675 AKA getting last_insert_id
677 Thanks to the core component PK::Auto, this is straightforward:
679 my $foo = $rs->create(\%blah);
681 my $id = $foo->id; # foo->my_primary_key_field will also work.
683 If you are not using autoincrementing primary keys, this will probably
684 not work, but then you already know the value of the last primary key anyway.
686 =head2 Stringification
688 Employ the standard stringification technique by using the C<overload>
691 To make an object stringify itself as a single column, use something
692 like this (replace C<name> with the column/method of your choice):
694 use overload '""' => sub { shift->name}, fallback => 1;
696 For more complex stringification, you can use an anonymous subroutine:
698 use overload '""' => sub { $_[0]->name . ", " .
699 $_[0]->address }, fallback => 1;
701 =head3 Stringification Example
703 Suppose we have two tables: C<Product> and C<Category>. The table
706 Product(id, Description, category)
707 Category(id, Description)
709 C<category> is a foreign key into the Category table.
711 If you have a Product object C<$obj> and write something like
715 things will not work as expected.
717 To obtain, for example, the category description, you should add this
718 method to the class defining the Category table:
720 use overload "" => sub {
723 return $self->Description;
726 =head2 Want to know if find_or_create found or created a row?
728 Just use C<find_or_new> instead, then check C<in_storage>:
730 my $obj = $rs->find_or_new({ blah => 'blarg' });
731 unless ($obj->in_storage) {
733 # do whatever else you wanted if it was a new row
736 =head2 Static sub-classing DBIx::Class result classes
738 AKA adding additional relationships/methods/etc. to a model for a
739 specific usage of the (shared) model.
743 package My::App::Schema;
745 use base DBIx::Class::Schema;
747 # load subclassed classes from My::App::Schema::Result/ResultSet
748 __PACKAGE__->load_namespaces;
750 # load classes from shared model
752 'My::Shared::Model::Result' => [qw/
759 B<Result-Subclass definition>
761 package My::App::Schema::Result::Baz;
765 use base My::Shared::Model::Result::Baz;
767 # WARNING: Make sure you call table() again in your subclass,
768 # otherwise DBIx::Class::ResultSourceProxy::Table will not be called
769 # and the class name is not correctly registered as a source
770 __PACKAGE__->table('baz');
772 sub additional_method {
773 return "I'm an additional method only needed by this app";
778 =head2 Dynamic Sub-classing DBIx::Class proxy classes
780 AKA multi-class object inflation from one table
782 L<DBIx::Class> classes are proxy classes, therefore some different
783 techniques need to be employed for more than basic subclassing. In
784 this example we have a single user table that carries a boolean bit
785 for admin. We would like like to give the admin users
786 objects(L<DBIx::Class::Row>) the same methods as a regular user but
787 also special admin only methods. It doesn't make sense to create two
788 seperate proxy-class files for this. We would be copying all the user
789 methods into the Admin class. There is a cleaner way to accomplish
792 Overriding the C<inflate_result> method within the User proxy-class
793 gives us the effect we want. This method is called by
794 L<DBIx::Class::ResultSet> when inflating a result from storage. So we
795 grab the object being returned, inspect the values we are looking for,
796 bless it if it's an admin object, and then return it. See the example
803 use base qw/DBIx::Class::Schema/;
805 __PACKAGE__->load_namespaces;
810 B<Proxy-Class definitions>
812 package My::Schema::Result::User;
816 use base qw/DBIx::Class/;
818 ### Defined what our admin class is for ensure_class_loaded
819 my $admin_class = __PACKAGE__ . '::Admin';
821 __PACKAGE__->load_components(qw/Core/);
823 __PACKAGE__->table('users');
825 __PACKAGE__->add_columns(qw/user_id email password
826 firstname lastname active
829 __PACKAGE__->set_primary_key('user_id');
833 my $ret = $self->next::method(@_);
834 if( $ret->admin ) {### If this is an admin rebless for extra functions
835 $self->ensure_class_loaded( $admin_class );
836 bless $ret, $admin_class;
842 print "I am a regular user.\n";
849 package My::Schema::Result::User::Admin;
853 use base qw/My::Schema::Result::User/;
857 print "I am an admin.\n";
863 print "I am doing admin stuff\n";
875 my $user_data = { email => 'someguy@place.com',
879 my $admin_data = { email => 'someadmin@adminplace.com',
883 my $schema = My::Schema->connection('dbi:Pg:dbname=test');
885 $schema->resultset('User')->create( $user_data );
886 $schema->resultset('User')->create( $admin_data );
888 ### Now we search for them
889 my $user = $schema->resultset('User')->single( $user_data );
890 my $admin = $schema->resultset('User')->single( $admin_data );
892 print ref $user, "\n";
893 print ref $admin, "\n";
895 print $user->password , "\n"; # pass1
896 print $admin->password , "\n";# pass2; inherited from User
897 print $user->hello , "\n";# I am a regular user.
898 print $admin->hello, "\n";# I am an admin.
900 ### The statement below will NOT print
901 print "I can do admin stuff\n" if $user->can('do_admin_stuff');
902 ### The statement below will print
903 print "I can do admin stuff\n" if $admin->can('do_admin_stuff');
905 =head2 Skip row object creation for faster results
907 DBIx::Class is not built for speed, it's built for convenience and
908 ease of use, but sometimes you just need to get the data, and skip the
911 To do this simply use L<DBIx::Class::ResultClass::HashRefInflator>.
913 my $rs = $schema->resultset('CD');
915 $rs->result_class('DBIx::Class::ResultClass::HashRefInflator');
917 my $hash_ref = $rs->find(1);
921 Beware, changing the Result class using
922 L<DBIx::Class::ResultSet/result_class> will replace any existing class
923 completely including any special components loaded using
924 load_components, eg L<DBIx::Class::InflateColumn::DateTime>.
926 =head2 Get raw data for blindingly fast results
928 If the L<HashRefInflator|DBIx::Class::ResultClass::HashRefInflator> solution
929 above is not fast enough for you, you can use a DBIx::Class to return values
930 exactly as they come out of the database with none of the convenience methods
933 This is used like so:
935 my $cursor = $rs->cursor
936 while (my @vals = $cursor->next) {
937 # use $val[0..n] here
940 You will need to map the array offsets to particular columns (you can
941 use the L<DBIx::Class::ResultSet/select> attribute of L<DBIx::Class::ResultSet/search> to force ordering).
943 =head1 RESULTSET OPERATIONS
945 =head2 Getting Schema from a ResultSet
947 To get the L<DBIx::Class::Schema> object from a ResultSet, do the following:
949 $rs->result_source->schema
951 =head2 Getting Columns Of Data
955 If you want to find the sum of a particular column there are several
956 ways, the obvious one is to use search:
958 my $rs = $schema->resultset('Items')->search(
961 select => [ { sum => 'Cost' } ],
962 as => [ 'total_cost' ], # remember this 'as' is for DBIx::Class::ResultSet not SQL
965 my $tc = $rs->first->get_column('total_cost');
967 Or, you can use the L<DBIx::Class::ResultSetColumn>, which gets
968 returned when you ask the C<ResultSet> for a column using
971 my $cost = $schema->resultset('Items')->get_column('Cost');
974 With this you can also do:
976 my $minvalue = $cost->min;
977 my $maxvalue = $cost->max;
979 Or just iterate through the values of this column only:
981 while ( my $c = $cost->next ) {
985 foreach my $c ($cost->all) {
989 C<ResultSetColumn> only has a limited number of built-in functions, if
990 you need one that it doesn't have, then you can use the C<func> method
993 my $avg = $cost->func('AVERAGE');
995 This will cause the following SQL statement to be run:
997 SELECT AVERAGE(Cost) FROM Items me
999 Which will of course only work if your database supports this function.
1000 See L<DBIx::Class::ResultSetColumn> for more documentation.
1002 =head2 Creating a result set from a set of rows
1004 Sometimes you have a (set of) row objects that you want to put into a
1005 resultset without the need to hit the DB again. You can do that by using the
1006 L<set_cache|DBIx::Class::Resultset/set_cache> method:
1008 my @uploadable_groups;
1009 while (my $group = $groups->next) {
1010 if ($group->can_upload($self)) {
1011 push @uploadable_groups, $group;
1014 my $new_rs = $self->result_source->resultset;
1015 $new_rs->set_cache(\@uploadable_groups);
1019 =head1 USING RELATIONSHIPS
1021 =head2 Create a new row in a related table
1023 my $author = $book->create_related('author', { name => 'Fred'});
1025 =head2 Search in a related table
1027 Only searches for books named 'Titanic' by the author in $author.
1029 my $books_rs = $author->search_related('books', { name => 'Titanic' });
1031 =head2 Delete data in a related table
1033 Deletes only the book named Titanic by the author in $author.
1035 $author->delete_related('books', { name => 'Titanic' });
1037 =head2 Ordering a relationship result set
1039 If you always want a relation to be ordered, you can specify this when you
1040 create the relationship.
1042 To order C<< $book->pages >> by descending page_number, create the relation
1045 __PACKAGE__->has_many('pages' => 'Page', 'book', { order_by => \'page_number DESC'} );
1047 =head2 Filtering a relationship result set
1049 If you want to get a filtered result set, you can just add add to $attr as follows:
1051 __PACKAGE__->has_many('pages' => 'Page', 'book', { where => { scrap => 0 } } );
1053 =head2 Many-to-many relationships
1055 This is straightforward using L<ManyToMany|DBIx::Class::Relationship/many_to_many>:
1058 use base 'DBIx::Class';
1059 __PACKAGE__->load_components('Core');
1060 __PACKAGE__->table('user');
1061 __PACKAGE__->add_columns(qw/id name/);
1062 __PACKAGE__->set_primary_key('id');
1063 __PACKAGE__->has_many('user_address' => 'My::UserAddress', 'user');
1064 __PACKAGE__->many_to_many('addresses' => 'user_address', 'address');
1066 package My::UserAddress;
1067 use base 'DBIx::Class';
1068 __PACKAGE__->load_components('Core');
1069 __PACKAGE__->table('user_address');
1070 __PACKAGE__->add_columns(qw/user address/);
1071 __PACKAGE__->set_primary_key(qw/user address/);
1072 __PACKAGE__->belongs_to('user' => 'My::User');
1073 __PACKAGE__->belongs_to('address' => 'My::Address');
1075 package My::Address;
1076 use base 'DBIx::Class';
1077 __PACKAGE__->load_components('Core');
1078 __PACKAGE__->table('address');
1079 __PACKAGE__->add_columns(qw/id street town area_code country/);
1080 __PACKAGE__->set_primary_key('id');
1081 __PACKAGE__->has_many('user_address' => 'My::UserAddress', 'address');
1082 __PACKAGE__->many_to_many('users' => 'user_address', 'user');
1084 $rs = $user->addresses(); # get all addresses for a user
1085 $rs = $address->users(); # get all users for an address
1087 =head2 Relationships across DB schemas
1089 Mapping relationships across L<DB schemas|DBIx::Class::Manual::Glossary/DB schema>
1090 is easy as long as the schemas themselves are all accessible via the same DBI
1091 connection. In most cases, this means that they are on the same database host
1092 as each other and your connecting database user has the proper permissions to them.
1094 To accomplish this one only needs to specify the DB schema name in the table
1095 declaration, like so...
1097 package MyDatabase::Main::Artist;
1098 use base qw/DBIx::Class/;
1099 __PACKAGE__->load_components(qw/PK::Auto Core/);
1101 __PACKAGE__->table('database1.artist'); # will use "database1.artist" in FROM clause
1103 __PACKAGE__->add_columns(qw/ artistid name /);
1104 __PACKAGE__->set_primary_key('artistid');
1105 __PACKAGE__->has_many('cds' => 'MyDatabase::Main::Cd');
1109 Whatever string you specify there will be used to build the "FROM" clause in SQL
1112 The big drawback to this is you now have DB schema names hardcoded in your
1113 class files. This becomes especially troublesome if you have multiple instances
1114 of your application to support a change lifecycle (e.g. DEV, TEST, PROD) and
1115 the DB schemas are named based on the environment (e.g. database1_dev).
1117 However, one can dynamically "map" to the proper DB schema by overriding the
1118 L<connection|DBIx::Class::Schama/connection> method in your Schema class and
1119 building a renaming facility, like so:
1121 package MyDatabase::Schema;
1124 extends 'DBIx::Class::Schema';
1126 around connection => sub {
1127 my ( $inner, $self, $dsn, $username, $pass, $attr ) = ( shift, @_ );
1129 my $postfix = delete $attr->{schema_name_postfix};
1134 $self->append_db_name($postfix);
1138 sub append_db_name {
1139 my ( $self, $postfix ) = @_;
1143 { $_->name =~ /^\w+\./mx }
1145 { $self->source($_) }
1148 foreach my $source (@sources_with_db) {
1149 my $name = $source->name;
1150 $name =~ s{^(\w+)\.}{${1}${postfix}\.}mx;
1152 $source->name($name);
1158 By overridding the L<connection|DBIx::Class::Schama/connection>
1159 method and extracting a custom option from the provided \%attr hashref one can
1160 then simply iterate over all the Schema's ResultSources, renaming them as
1163 To use this facility, simply add or modify the \%attr hashref that is passed to
1164 L<connection|DBIx::Class::Schama/connect>, as follows:
1167 = MyDatabase::Schema->connect(
1172 schema_name_postfix => '_dev'
1173 # ... Other options as desired ...
1176 Obviously, one could accomplish even more advanced mapping via a hash map or a
1181 As of version 0.04001, there is improved transaction support in
1182 L<DBIx::Class::Storage> and L<DBIx::Class::Schema>. Here is an
1183 example of the recommended way to use it:
1185 my $genus = $schema->resultset('Genus')->find(12);
1187 my $coderef2 = sub {
1192 my $coderef1 = sub {
1193 $genus->add_to_species({ name => 'troglodyte' });
1196 $schema->txn_do($coderef2); # Can have a nested transaction. Only the outer will actualy commit
1197 return $genus->species;
1202 $rs = $schema->txn_do($coderef1);
1205 if ($@) { # Transaction failed
1206 die "the sky is falling!" #
1207 if ($@ =~ /Rollback failed/); # Rollback failed
1209 deal_with_failed_transaction();
1212 Nested transactions will work as expected. That is, only the outermost
1213 transaction will actually issue a commit to the $dbh, and a rollback
1214 at any level of any transaction will cause the entire nested
1215 transaction to fail. Support for savepoints and for true nested
1216 transactions (for databases that support them) will hopefully be added
1221 =head2 Creating Schemas From An Existing Database
1223 L<DBIx::Class::Schema::Loader> will connect to a database and create a
1224 L<DBIx::Class::Schema> and associated sources by examining the database.
1226 The recommend way of achieving this is to use the
1227 L<make_schema_at|DBIx::Class::Schema::Loader/make_schema_at> method:
1229 perl -MDBIx::Class::Schema::Loader=make_schema_at,dump_to_dir:./lib \
1230 -e 'make_schema_at("My::Schema", { debug => 1 }, [ "dbi:Pg:dbname=foo","postgres" ])'
1232 This will create a tree of files rooted at C<./lib/My/Schema/> containing
1233 source definitions for all the tables found in the C<foo> database.
1235 =head2 Creating DDL SQL
1237 The following functionality requires you to have L<SQL::Translator>
1238 (also known as "SQL Fairy") installed.
1240 To create a set of database-specific .sql files for the above schema:
1242 my $schema = My::Schema->connect($dsn);
1243 $schema->create_ddl_dir(['MySQL', 'SQLite', 'PostgreSQL'],
1248 By default this will create schema files in the current directory, for
1249 MySQL, SQLite and PostgreSQL, using the $VERSION from your Schema.pm.
1251 To create a new database using the schema:
1253 my $schema = My::Schema->connect($dsn);
1254 $schema->deploy({ add_drop_tables => 1});
1256 To import created .sql files using the mysql client:
1258 mysql -h "host" -D "database" -u "user" -p < My_Schema_1.0_MySQL.sql
1260 To create C<ALTER TABLE> conversion scripts to update a database to a
1261 newer version of your schema at a later point, first set a new
1262 C<$VERSION> in your Schema file, then:
1264 my $schema = My::Schema->connect($dsn);
1265 $schema->create_ddl_dir(['MySQL', 'SQLite', 'PostgreSQL'],
1271 This will produce new database-specific .sql files for the new version
1272 of the schema, plus scripts to convert from version 0.1 to 0.2. This
1273 requires that the files for 0.1 as created above are available in the
1274 given directory to diff against.
1276 =head2 Select from dual
1278 Dummy tables are needed by some databases to allow calling functions
1279 or expressions that aren't based on table content, for examples of how
1280 this applies to various database types, see:
1281 L<http://troels.arvin.dk/db/rdbms/#other-dummy_table>.
1283 Note: If you're using Oracles dual table don't B<ever> do anything
1284 other than a select, if you CRUD on your dual table you *will* break
1287 Make a table class as you would for any other table
1289 package MyAppDB::Dual;
1292 use base 'DBIx::Class';
1293 __PACKAGE__->load_components("Core");
1294 __PACKAGE__->table("Dual");
1295 __PACKAGE__->add_columns(
1297 { data_type => "VARCHAR2", is_nullable => 0, size => 1 },
1300 Once you've loaded your table class select from it using C<select>
1301 and C<as> instead of C<columns>
1303 my $rs = $schema->resultset('Dual')->search(undef,
1304 { select => [ 'sydate' ],
1309 All you have to do now is be careful how you access your resultset, the below
1310 will not work because there is no column called 'now' in the Dual table class
1312 while (my $dual = $rs->next) {
1313 print $dual->now."\n";
1315 # Can't locate object method "now" via package "MyAppDB::Dual" at headshot.pl line 23.
1317 You could of course use 'dummy' in C<as> instead of 'now', or C<add_columns> to
1318 your Dual class for whatever you wanted to select from dual, but that's just
1319 silly, instead use C<get_column>
1321 while (my $dual = $rs->next) {
1322 print $dual->get_column('now')."\n";
1327 my $cursor = $rs->cursor;
1328 while (my @vals = $cursor->next) {
1329 print $vals[0]."\n";
1332 In case you're going to use this "trick" together with L<DBIx::Class::Schema/deploy> or
1333 L<DBIx::Class::Schema/create_ddl_dir> a table called "dual" will be created in your
1334 current schema. This would overlap "sys.dual" and you could not fetch "sysdate" or
1335 "sequence.nextval" anymore from dual. To avoid this problem, just tell
1336 L<SQL::Translator> to not create table dual:
1339 add_drop_table => 1,
1340 parser_args => { sources => [ grep $_ ne 'Dual', schema->sources ] },
1342 $schema->create_ddl_dir( [qw/Oracle/], undef, './sql', undef, $sqlt_args );
1344 Or use L<DBIx::Class::ResultClass::HashRefInflator>
1346 $rs->result_class('DBIx::Class::ResultClass::HashRefInflator');
1347 while ( my $dual = $rs->next ) {
1348 print $dual->{now}."\n";
1351 Here are some example C<select> conditions to illustrate the different syntax
1352 you could use for doing stuff like
1353 C<oracles.heavily(nested(functions_can('take', 'lots'), OF), 'args')>
1355 # get a sequence value
1356 select => [ 'A_SEQ.nextval' ],
1358 # get create table sql
1359 select => [ { 'dbms_metadata.get_ddl' => [ "'TABLE'", "'ARTIST'" ]} ],
1361 # get a random num between 0 and 100
1362 select => [ { "trunc" => [ { "dbms_random.value" => [0,100] } ]} ],
1365 select => [ { 'extract' => [ \'year from sysdate' ] } ],
1368 select => [ {'round' => [{'cos' => [ \'180 * 3.14159265359/180' ]}]}],
1370 # which day of the week were you born on?
1371 select => [{'to_char' => [{'to_date' => [ "'25-DEC-1980'", "'dd-mon-yyyy'" ]}, "'day'"]}],
1373 # select 16 rows from dual
1374 select => [ "'hello'" ],
1376 group_by => [ 'cube( 1, 2, 3, 4 )' ],
1380 =head2 Adding Indexes And Functions To Your SQL
1382 Often you will want indexes on columns on your table to speed up searching. To
1383 do this, create a method called C<sqlt_deploy_hook> in the relevant source
1384 class (refer to the advanced
1385 L<callback system|DBIx::Class::ResultSource/sqlt_deploy_callback> if you wish
1386 to share a hook between multiple sources):
1388 package My::Schema::Result::Artist;
1390 __PACKAGE__->table('artist');
1391 __PACKAGE__->add_columns(id => { ... }, name => { ... })
1393 sub sqlt_deploy_hook {
1394 my ($self, $sqlt_table) = @_;
1396 $sqlt_table->add_index(name => 'idx_name', fields => ['name']);
1401 Sometimes you might want to change the index depending on the type of the
1402 database for which SQL is being generated:
1404 my ($db_type = $sqlt_table->schema->translator->producer_type)
1405 =~ s/^SQL::Translator::Producer:://;
1407 You can also add hooks to the schema level to stop certain tables being
1414 sub sqlt_deploy_hook {
1415 my ($self, $sqlt_schema) = @_;
1417 $sqlt_schema->drop_table('table_name');
1420 You could also add views, procedures or triggers to the output using
1421 L<SQL::Translator::Schema/add_view>,
1422 L<SQL::Translator::Schema/add_procedure> or
1423 L<SQL::Translator::Schema/add_trigger>.
1426 =head2 Schema versioning
1428 The following example shows simplistically how you might use DBIx::Class to
1429 deploy versioned schemas to your customers. The basic process is as follows:
1435 Create a DBIx::Class schema
1447 Modify schema to change functionality
1451 Deploy update to customers
1455 B<Create a DBIx::Class schema>
1457 This can either be done manually, or generated from an existing database as
1458 described under L</Creating Schemas From An Existing Database>
1462 Call L<DBIx::Class::Schema/create_ddl_dir> as above under L</Creating DDL SQL>.
1464 B<Deploy to customers>
1466 There are several ways you could deploy your schema. These are probably
1467 beyond the scope of this recipe, but might include:
1473 Require customer to apply manually using their RDBMS.
1477 Package along with your app, making database dump/schema update/tests
1478 all part of your install.
1482 B<Modify the schema to change functionality>
1484 As your application evolves, it may be necessary to modify your schema
1485 to change functionality. Once the changes are made to your schema in
1486 DBIx::Class, export the modified schema and the conversion scripts as
1487 in L</Creating DDL SQL>.
1489 B<Deploy update to customers>
1491 Add the L<DBIx::Class::Schema::Versioned> schema component to your
1492 Schema class. This will add a new table to your database called
1493 C<dbix_class_schema_vesion> which will keep track of which version is installed
1494 and warn if the user trys to run a newer schema version than the
1495 database thinks it has.
1497 Alternatively, you can send the conversion sql scripts to your
1500 =head2 Setting quoting for the generated SQL.
1502 If the database contains column names with spaces and/or reserved words, they
1503 need to be quoted in the SQL queries. This is done using:
1505 __PACKAGE__->storage->sql_maker->quote_char([ qw/[ ]/] );
1506 __PACKAGE__->storage->sql_maker->name_sep('.');
1508 The first sets the quote characters. Either a pair of matching
1509 brackets, or a C<"> or C<'>:
1511 __PACKAGE__->storage->sql_maker->quote_char('"');
1513 Check the documentation of your database for the correct quote
1514 characters to use. C<name_sep> needs to be set to allow the SQL
1515 generator to put the quotes the correct place.
1517 In most cases you should set these as part of the arguments passed to
1518 L<DBIx::Class::Schema/connect>:
1520 my $schema = My::Schema->connect(
1530 =head2 Setting limit dialect for SQL::Abstract::Limit
1532 In some cases, SQL::Abstract::Limit cannot determine the dialect of
1533 the remote SQL server by looking at the database handle. This is a
1534 common problem when using the DBD::JDBC, since the DBD-driver only
1535 know that in has a Java-driver available, not which JDBC driver the
1536 Java component has loaded. This specifically sets the limit_dialect
1537 to Microsoft SQL-server (See more names in SQL::Abstract::Limit
1540 __PACKAGE__->storage->sql_maker->limit_dialect('mssql');
1542 The JDBC bridge is one way of getting access to a MSSQL server from a platform
1543 that Microsoft doesn't deliver native client libraries for. (e.g. Linux)
1545 The limit dialect can also be set at connect time by specifying a
1546 C<limit_dialect> key in the final hash as shown above.
1548 =head2 Working with PostgreSQL array types
1550 You can also assign values to PostgreSQL array columns by passing array
1551 references in the C<\%columns> (C<\%vals>) hashref of the
1552 L<DBIx::Class::ResultSet/create> and L<DBIx::Class::Row/update> family of
1555 $resultset->create({
1556 numbers => [1, 2, 3]
1561 numbers => [1, 2, 3]
1568 In conditions (eg. C<\%cond> in the L<DBIx::Class::ResultSet/search> family of
1569 methods) you cannot directly use array references (since this is interpreted as
1570 a list of values to be C<OR>ed), but you can use the following syntax to force
1571 passing them as bind values:
1575 numbers => \[ '= ?', [numbers => [1, 2, 3]] ]
1579 See L<SQL::Abstract/array_datatypes> and L<SQL::Abstract/Literal SQL with
1580 placeholders and bind values (subqueries)> for more explanation. Note that
1581 L<DBIx::Class> sets L<SQL::Abstract/bindtype> to C<columns>, so you must pass
1582 the bind values (the C<[1, 2, 3]> arrayref in the above example) wrapped in
1583 arrayrefs together with the column name, like this: C<< [column_name => value]
1586 =head1 BOOTSTRAPPING/MIGRATING
1588 =head2 Easy migration from class-based to schema-based setup
1590 You want to start using the schema-based approach to L<DBIx::Class>
1591 (see L<SchemaIntro.pod>), but have an established class-based setup with lots
1592 of existing classes that you don't want to move by hand. Try this nifty script
1596 use SQL::Translator;
1598 my $schema = MyDB->schema_instance;
1600 my $translator = SQL::Translator->new(
1601 debug => $debug || 0,
1602 trace => $trace || 0,
1603 no_comments => $no_comments || 0,
1604 show_warnings => $show_warnings || 0,
1605 add_drop_table => $add_drop_table || 0,
1606 validate => $validate || 0,
1608 'DBIx::Schema' => $schema,
1611 'prefix' => 'My::Schema',
1615 $translator->parser('SQL::Translator::Parser::DBIx::Class');
1616 $translator->producer('SQL::Translator::Producer::DBIx::Class::File');
1618 my $output = $translator->translate(@args) or die
1619 "Error: " . $translator->error;
1623 You could use L<Module::Find> to search for all subclasses in the MyDB::*
1624 namespace, which is currently left as an exercise for the reader.
1626 =head1 OVERLOADING METHODS
1628 L<DBIx::Class> uses the L<Class::C3> package, which provides for redispatch of
1629 method calls, useful for things like default values and triggers. You have to
1630 use calls to C<next::method> to overload methods. More information on using
1631 L<Class::C3> with L<DBIx::Class> can be found in
1632 L<DBIx::Class::Manual::Component>.
1634 =head2 Setting default values for a row
1636 It's as simple as overriding the C<new> method. Note the use of
1640 my ( $class, $attrs ) = @_;
1642 $attrs->{foo} = 'bar' unless defined $attrs->{foo};
1644 my $new = $class->next::method($attrs);
1649 For more information about C<next::method>, look in the L<Class::C3>
1650 documentation. See also L<DBIx::Class::Manual::Component> for more
1651 ways to write your own base classes to do this.
1653 People looking for ways to do "triggers" with DBIx::Class are probably
1654 just looking for this.
1656 =head2 Changing one field whenever another changes
1658 For example, say that you have three columns, C<id>, C<number>, and
1659 C<squared>. You would like to make changes to C<number> and have
1660 C<squared> be automagically set to the value of C<number> squared.
1661 You can accomplish this by overriding C<store_column>:
1664 my ( $self, $name, $value ) = @_;
1665 if ($name eq 'number') {
1666 $self->squared($value * $value);
1668 $self->next::method($name, $value);
1671 Note that the hard work is done by the call to C<next::method>, which
1672 redispatches your call to store_column in the superclass(es).
1674 =head2 Automatically creating related objects
1676 You might have a class C<Artist> which has many C<CD>s. Further, if you
1677 want to create a C<CD> object every time you insert an C<Artist> object.
1678 You can accomplish this by overriding C<insert> on your objects:
1681 my ( $self, @args ) = @_;
1682 $self->next::method(@args);
1683 $self->cds->new({})->fill_from_artist($self)->insert;
1687 where C<fill_from_artist> is a method you specify in C<CD> which sets
1688 values in C<CD> based on the data in the C<Artist> object you pass in.
1690 =head2 Wrapping/overloading a column accessor
1694 Say you have a table "Camera" and want to associate a description
1695 with each camera. For most cameras, you'll be able to generate the description from
1696 the other columns. However, in a few special cases you may want to associate a
1697 custom description with a camera.
1701 In your database schema, define a description field in the "Camera" table that
1702 can contain text and null values.
1704 In DBIC, we'll overload the column accessor to provide a sane default if no
1705 custom description is defined. The accessor will either return or generate the
1706 description, depending on whether the field is null or not.
1708 First, in your "Camera" schema class, define the description field as follows:
1710 __PACKAGE__->add_columns(description => { accessor => '_description' });
1712 Next, we'll define the accessor-wrapper subroutine:
1717 # If there is an update to the column, we'll let the original accessor
1719 return $self->_description(@_) if @_;
1721 # Fetch the column value.
1722 my $description = $self->_description;
1724 # If there's something in the description field, then just return that.
1725 return $description if defined $description && length $descripton;
1727 # Otherwise, generate a description.
1728 return $self->generate_description;
1731 =head1 DEBUGGING AND PROFILING
1733 =head2 DBIx::Class objects with Data::Dumper
1735 L<Data::Dumper> can be a very useful tool for debugging, but sometimes it can
1736 be hard to find the pertinent data in all the data it can generate.
1737 Specifically, if one naively tries to use it like so,
1741 my $cd = $schema->resultset('CD')->find(1);
1744 several pages worth of data from the CD object's schema and result source will
1745 be dumped to the screen. Since usually one is only interested in a few column
1746 values of the object, this is not very helpful.
1748 Luckily, it is possible to modify the data before L<Data::Dumper> outputs
1749 it. Simply define a hook that L<Data::Dumper> will call on the object before
1750 dumping it. For example,
1757 result_source => undef,
1765 local $Data::Dumper::Freezer = '_dumper_hook';
1767 my $cd = $schema->resultset('CD')->find(1);
1769 # dumps $cd without its ResultSource
1771 If the structure of your schema is such that there is a common base class for
1772 all your table classes, simply put a method similar to C<_dumper_hook> in the
1773 base class and set C<$Data::Dumper::Freezer> to its name and L<Data::Dumper>
1774 will automagically clean up your data before printing it. See
1775 L<Data::Dumper/EXAMPLES> for more information.
1779 When you enable L<DBIx::Class::Storage>'s debugging it prints the SQL
1780 executed as well as notifications of query completion and transaction
1781 begin/commit. If you'd like to profile the SQL you can subclass the
1782 L<DBIx::Class::Storage::Statistics> class and write your own profiling
1785 package My::Profiler;
1788 use base 'DBIx::Class::Storage::Statistics';
1790 use Time::HiRes qw(time);
1799 $self->print("Executing $sql: ".join(', ', @params)."\n");
1808 my $elapsed = sprintf("%0.4f", time() - $start);
1809 $self->print("Execution took $elapsed seconds.\n");
1815 You can then install that class as the debugging object:
1817 __PACKAGE__->storage->debugobj(new My::Profiler());
1818 __PACKAGE__->storage->debug(1);
1820 A more complicated example might involve storing each execution of SQL in an
1828 my $elapsed = time() - $start;
1829 push(@{ $calls{$sql} }, {
1835 You could then create average, high and low execution times for an SQL
1836 statement and dig down to see if certain parameters cause aberrant behavior.
1837 You might want to check out L<DBIx::Class::QueryLog> as well.
1839 =head1 STARTUP SPEED
1841 L<DBIx::Class|DBIx::Class> programs can have a significant startup delay
1842 as the ORM loads all the relevant classes. This section examines
1843 techniques for reducing the startup delay.
1845 These tips are are listed in order of decreasing effectiveness - so the
1846 first tip, if applicable, should have the greatest effect on your
1849 =head2 Statically Define Your Schema
1852 L<DBIx::Class::Schema::Loader|DBIx::Class::Schema::Loader> to build the
1853 classes dynamically based on the database schema then there will be a
1854 significant startup delay.
1856 For production use a statically defined schema (which can be generated
1857 using L<DBIx::Class::Schema::Loader|DBIx::Class::Schema::Loader> to dump
1858 the database schema once - see
1859 L<make_schema_at|DBIx::Class::Schema::Loader/make_schema_at> and
1860 L<dump_directory|DBIx::Class::Schema::Loader/dump_directory> for more
1861 details on creating static schemas from a database).
1863 =head2 Move Common Startup into a Base Class
1865 Typically L<DBIx::Class> result classes start off with
1867 use base qw/DBIx::Class/;
1868 __PACKAGE__->load_components(qw/InflateColumn::DateTime Core/);
1870 If this preamble is moved into a common base class:-
1874 use base qw/DBIx::Class/;
1875 __PACKAGE__->load_components(qw/InflateColumn::DateTime Core/);
1878 and each result class then uses this as a base:-
1880 use base qw/MyDBICbase/;
1882 then the load_components is only performed once, which can result in a
1883 considerable startup speedup for schemas with many classes.
1885 =head2 Explicitly List Schema Result Classes
1887 The schema class will normally contain
1889 __PACKAGE__->load_classes();
1891 to load the result classes. This will use L<Module::Find|Module::Find>
1892 to find and load the appropriate modules. Explicitly defining the
1893 classes you wish to load will remove the overhead of
1894 L<Module::Find|Module::Find> and the related directory operations:-
1896 __PACKAGE__->load_classes(qw/ CD Artist Track /);
1898 If you are instead using the L<load_namespaces|DBIx::Class::Schema/load_namespaces>
1899 syntax to load the appropriate classes there is not a direct alternative
1900 avoiding L<Module::Find|Module::Find>.
1904 =head2 Cached statements
1906 L<DBIx::Class> normally caches all statements with L<< prepare_cached()|DBI/prepare_cached >>.
1907 This is normally a good idea, but if too many statements are cached, the database may use too much
1908 memory and may eventually run out and fail entirely. If you suspect this may be the case, you may want
1909 to examine DBI's L<< CachedKids|DBI/CachedKidsCachedKids_(hash_ref) >> hash:
1911 # print all currently cached prepared statements
1912 print for keys %{$schema->storage->dbh->{CachedKids}};
1913 # get a count of currently cached prepared statements
1914 my $count = scalar keys %{$schema->storage->dbh->{CachedKids}};
1916 If it's appropriate, you can simply clear these statements, automatically deallocating them in the
1919 my $kids = $schema->storage->dbh->{CachedKids};
1920 delete @{$kids}{keys %$kids} if scalar keys %$kids > 100;
1922 But what you probably want is to expire unused statements and not those that are used frequently.
1923 You can accomplish this with L<Tie::Cache> or L<Tie::Cache::LRU>:
1927 my $schema = DB::Main->connect($dbi_dsn, $user, $pass, {
1928 on_connect_do => sub { tie %{shift->_dbh->{CachedKids}}, 'Tie::Cache', 100 },