database, all read-type queries (SELECTs) go to the slave database.
Basically, any method request that L<DBIx::Class::Storage::DBI> would normally
-handle gets delegated to one of the two attributes: L</master_storage> or to
-L</current_replicant_storage>. Additionally, some methods need to be distributed
+handle gets delegated to one of the two attributes: L</read_handler> or to
+L</write_handler>. Additionally, some methods need to be distributed
to all existing storages. This way our storage class is a drop in replacement
for L<DBIx::Class::Storage::DBI>.
Read traffic is spread across the replicants (slaves) occuring to a user
selected algorithm. The default algorithm is random weighted.
-TODO more details about the algorithm.
+=head1 NOTES
+
+The consistancy betweeen master and replicants is database specific. The Pool
+gives you a method to validate it's replicants, removing and replacing them
+when they fail/pass predefined criteria. It is recommened that your application
+define two schemas, one using the replicated storage and another that just
+connects to the master.
=head1 ATTRIBUTES
},
);
+=head2 pool_args
+
+Contains a hashref of initialized information to pass to the Balancer object.
+See L<DBIx::Class::Storage::Replicated::Pool> for available arguments.
+
+=cut
+
+has 'pool_args' => (
+ is=>'ro',
+ isa=>'HashRef',
+ lazy=>1,
+ required=>1,
+ default=>sub { {} },
+);
+
+
=head2 balancer_type
The replication pool requires a balance class to provider the methods for
=head2 balancer_args
Contains a hashref of initialized information to pass to the Balancer object.
-See L<DBIx::Class::Storage::Replicated::Pool> for available arguments.
+See L<DBIx::Class::Storage::Replicated::Balancer> for available arguments.
=cut
has 'balancer_args' => (
is=>'ro',
isa=>'HashRef',
+ lazy=>1,
+ required=>1,
+ default=>sub { {} },
);
=head2 pool
update
delete
dbh
- txn_do
txn_commit
txn_rollback
sth
deploy
schema
+ reload_row
/],
);
sub _build_pool {
my $self = shift @_;
- $self->create_pool;
+ $self->create_pool(%{$self->pool_args});
}
=head2 _build_balancer_type
);
}
+=head2 execute_reliably ($coderef, ?@args)
+
+Given a coderef, saves the current state of the L</read_handler>, forces it to
+use reliable storage (ie sets it to the master), executes a coderef and then
+restores the original state.
+
+Example:
+
+ my $reliably = sub {
+ my $name = shift @_;
+ $schema->resultset('User')->create({name=>$name});
+ my $user_rs = $schema->resultset('User')->find({name=>$name});
+ return $user_rs;
+ };
+
+ my $user_rs = $schema->storage->execute_reliably($reliably, 'John');
+
+Use this when you must be certain of your database state, such as when you just
+inserted something and need to get a resultset including it, etc.
+
+=cut
+
+sub execute_reliably {
+ my ($self, $coderef, @args) = @_;
+
+ unless( ref $coderef eq 'CODE') {
+ $self->throw_exception('Second argument must be a coderef');
+ }
+
+ ##Get copy of master storage
+ my $master = $self->master;
+
+ ##Get whatever the current read hander is
+ my $current = $self->read_handler;
+
+ ##Set the read handler to master
+ $self->read_handler($master);
+
+ ## do whatever the caller needs
+ my @result;
+ my $want_array = wantarray;
+
+ eval {
+ if($want_array) {
+ @result = $coderef->(@args);
+ }
+ elsif(defined $want_array) {
+ ($result[0]) = ($coderef->(@args));
+ } else {
+ $coderef->(@args);
+ }
+ };
+
+ ##Reset to the original state
+ $self->schema->storage->read_handler($current);
+
+ ##Exception testing has to come last, otherwise you might leave the
+ ##read_handler set to master.
+
+ if($@) {
+ $self->throw_exception("coderef returned an error: $@");
+ } else {
+ return $want_array ? @result : $result[0];
+ }
+}
+
=head2 set_reliable_storage
Sets the current $schema to be 'reliable', that is all queries, both read and
$schema->storage->read_handler($write_handler);
}
+=head2 txn_do ($coderef)
+
+Overload to the txn_do method, which is delegated to whatever the
+L<write_handler> is set to. We overload this in order to wrap in inside a
+L</execute_reliably> method.
+
+=cut
+
+sub txn_do {
+ my($self, $coderef, @args) = @_;
+ $self->execute_reliably($coderef, @args);
+}
+
+=head2 reload_row ($row)
+
+Overload to the reload_row method so that the reloading is always directed to
+the master storage.
+
+=cut
+
+around 'reload_row' => sub {
+ my ($reload_row, $self, $row) = @_;
+ $self->execute_reliably(sub {
+ $self->$reload_row(shift);
+ }, $row);
+};
+
=head2 connected
Check that the master and at least one of the replicants is connected.
=head1 AUTHOR
-Norbert Csongrádi <bert@cpan.org>
+ John Napiorkowski <john.napiorkowski@takkle.com>
-Peter Siklósi <einon@einon.hu>
+Based on code originated by:
-John Napiorkowski <john.napiorkowski@takkle.com>
+ Norbert Csongrádi <bert@cpan.org>
+ Peter Siklósi <einon@einon.hu>
=head1 LICENSE