NAME
DBIx::DataModel - Classes and UML-style Associations on top of DBI
SYNOPSIS
in file "MySchema.pm"
Schema
Declare the schema, which automatically creates a Perl package.
# do NOT declare here "package MySchema;"
use DBIx::DataModel;
DBIx::DataModel->Schema('MySchema'); # 'MySchema' is now a Perl package
Tables
Declare the tables with (Perl name, DB name, primary key column(s))
. Each table then becomes a Perl package (prefixed with the Schema name).
MySchema->Table(qw/Employee Employee emp_id/)
->Table(qw/Department Department dpt_id/)
->Table(qw/Activity Activity act_id/);
Associations
Declare associations or compositions in UML style ( [table1 role1 multiplicity1 join1], [table2...]
).
MySchema->Composition([qw/Employee employee 1 /],
[qw/Activity activities * /])
->Association([qw/Department department 1 /],
[qw/Activity activities * /]);
Declare a n-to-n association, on top of the linking table
MySchema->Association([qw/Department departments * activities department/]);
[qw/Employee employees * activities employee/]);
Columns
Declare "column types" with some handlers ..
# date conversion between database (yyyy-mm-dd) and user (dd.mm.yyyy)
MySchema->ColumnType(Date =>
fromDB => sub {$_[0] =~ s/(\d\d\d\d)-(\d\d)-(\d\d)/$3.$2.$1/},
toDB => sub {$_[0] =~ s/(\d\d)\.(\d\d)\.(\d\d\d\d)/$3-$2-$1/},
validate => sub {$_[0] =~ m/(\d\d)\.(\d\d)\.(\d\d\d\d)/});
# 'percent' conversion between database (0.8) and user (80)
MySchema->ColumnType(Percent =>
fromDB => sub {$_[0] *= 100 if $_[0]},
toDB => sub {$_[0] /= 100 if $_[0]},
validate => sub {$_[0] =~ /1?\d?\d/});
MySchema->ColumnType(Multivalue =>
fromDB => sub {$_[0] = [split /;/, $_[0] || ""] },
toDB => sub {$_[0] = join ";", @$_[0] if ref $_[0]});
.. and apply these "column types" to some of our columns
MySchema::Employee->ColumnType(Date => qw/d_birth/);
MySchema::Activity->ColumnType(Date => qw/d_begin d_end/)
->ColumnType(Percent => qw/activity_rate/);
Declare a column that will be filled automatically at each update
MySchema->AutoUpdateColumns(last_modif =>
sub{$ENV{REMOTE_USER}.", ".scalar(localtime)});
Declare a column that will be not be sent when updating records (for example if that column is filled automatically by the database)
MySchema->NoUpdateColumns(qw/date_modif time_modif/);
Additional methods
For details that could not be expressed in a declarative way, just add a new method into the table class (but in that case, Schema and Table declarations should be in a BEGIN block, so that the table class is defined before you start adding methods to it).
package MySchema::Activity;
sub activePeriod {
my $self = shift;
$self->{d_end} ? "from $self->{d_begin} to $self->{d_end}"
: "since $self->{d_begin}";
}
Data tree expansion
Declare how to automatically expand objects into data trees
MySchema::Activity->AutoExpand(qw/employee department/);
Automatic schema generation
perl -MDBIx::DataModel::Schema::Generator \
-e "fromDBI('dbi:connection:string')" -- \
-schema My::New::Schema > My/New/Schema.pm
See DBIx::DataModel::Schema::Generator.
in file "myClient.pl"
Database connection
use MySchema;
use DBI;
my $dbh = DBI->connect($dsn, ...);
MySchema->dbh($dbh);
Simple data retrieval
Search employees whose name starts with 'D' (select API is taken from SQL::Abstract)
my $empl_D
= MySchema::Employee->select(-where => {lastname => {-like => 'D%'}});
idem, but we just want a subset of the columns, and order by age.
my $empl_F
= MySchema::Employee->select(
-columns => [qw/firstname lastname d_birth/],
-where => {lastname => {-like => 'F%'}},
-orderBy => 'd_birth');
Print some info from employees. Because of the 'fromDB' handler associated with column type 'date', column 'd_birth' has been automatically converted to display format.
foreach my $emp (@$empl_D) {
print "$emp->{firstname} $emp->{lastname}, born $emp->{d_birth}\n";
}
Same thing, but using method calls instead of direct access to the hashref (must enable AUTOLOAD in the table or the whole schema)
MySchema::Employee->Autoload(1); # or MySchema->Autoload(1)
foreach my $emp (@$empl_D) {
printf "%s %s, born %s\n", $emp->firstname, $emp->lastname, $emp->d_birth;
}
Methods to follow joins
Follow the joins through role methods
foreach my $act (@{$emp->activities}) {
printf "working for %s from $act->{d_begin} to $act->{d_end}",
$act->department->name;
}
Role methods can take arguments too, like select()
my $recentAct
= $dpt->activities(-where => {d_begin => {'>=' => '2005-01-01'}});
my @recentEmpl
= map {$_->employee(-columns => [qw/firstname lastname/])} @$recentAct;
Data export : just regular hashrefs
Export the data : get related records and insert them into a data tree in memory; then remove all class information and export that tree.
$_->expand('activities') foreach @$empl_D;
my $export = MySchema->unbless({employees => $empl_D});
use Data::Dumper; print Dumper ($export); # export as PerlDump
use XML::Simple; print XMLout ($export); # export as XML
use JSON; print to_json($export); # export as Javascript
use YAML; print Dump ($export); # export as YAML
Note: the unbless
step is optional; it is proposed here because some exporter modules will not work if they encounter a blessed reference.
Database join
Select associated tables directly from a database join, in one single SQL statement (instead of iterating through role methods).
my $lst = MySchema->join(qw/Employee activities department/)
->select(-columns => [qw/lastname dept_name d_begin/],
-where => {d_begin => {'>=' => '2000-01-01'}});
Same thing, but forcing INNER joins
my $lst = MySchema->join(qw/Employee <=> activities <=> department/)
->select(...);
Statements and pagination
Instead of retrieving directly a list or records, get a statement :
my $statement
= MySchema->join(qw/Employee activities department/)
->select(-columns => [qw/lastname dept_name d_begin/],
-where => {d_begin => {'>=' => '2000-01-01'}},
-resultAs => 'statement');
Retrieve a single row from the statement
my $single_row = $statement->next or die "no more records";
Retrieve several rows at once
my $rows = $statement->next(10); # arrayref
Go to a specific page and retrieve the corresponding rows
my $statement
= MySchema->join(qw/Employee activities department/)
->select(-columns => [qw/lastname dept_name d_begin/],
-resultAs => 'statement',
-pageSize => 10);
$statement->gotoPage(3); # absolute page positioning
$statement->shiftPages(-2); # relative page positioning
my ($first, $last) = $statement->pageBoundaries;
print "displaying rows $first to $last:";
some_print_row_method($_) foreach @{$statement->pageRows};
Efficient use of statements
For fetching related rows : prepare a statement before the loop, execute it at each iteration.
my $statement = My::Table->join(qw/role1 role2/)
->prepare(-columns => ...,
-where => ...);
my $list = My::Table->select(...);
foreach my $obj (@$list) {
my $related_rows = $statement->execute($obj)->all;
...
}
Fast statement : each data row is retrieved into the same memory location (avoids the overhead of allocating a hashref for each row). Faster, but such rows cannot be accumulated into an array (they must be used immediately) :
my $fast_stmt = ..->select(..., -resultAs => "fast_statement");
while (my $row = $fast_stmt->next) {
do_something_immediately_with($row);
}
DESCRIPTION
Introduction
DBIx::DataModel
is a framework for building Perl abstractions (classes, objects and methods) that interact with relational database management systems (RDBMS). Of course the ubiquitous DBI module is used as a basic layer for communicating with databases; on top of that, DBIx::DataModel
provides facilities for generating SQL queries, joining tables automatically, navigating through the results, converting values, and building complex datastructures so that other modules can conveniently exploit the data.
Perl ORMs
There are many other CPAN modules offering somewhat similar features, like Class::DBI, DBIx::Class, Tangram, Rose::DB::Object, Jifty::DBI, Fey::ORM, just to name a few well-known alternatives. Frameworks in this family are called object-relational mappings (ORMs) -- see http://en.wikipedia.org/wiki/Object-relational_mapping. The mere fact that Perl ORMs are so numerous demonstrates that there is more than one way to do it!
For various reasons, none of these did fit nicely in my context, so I decided to write DBIx:DataModel
. Of course there might be also some reasons why DBIx:DataModel
will not fit in your context, so just do your own shopping. Comparing various ORMs is complex and time-consuming, because of the many issues and design dimensions involved; as far as I know, there is no thorough comparison summary, but here are some pointers :
general discussion on RDBMS - Perl mappings at http://poop.sourceforge.net (good but outdated).
http://osdir.com/ml/lang.perl.modules.dbi.rose-db-object/2006-06/msg00021.html, a detailed comparison between Rose::DB and DBIx::Class.
Strengths of DBIx::DataModel
The DESIGN chapter of this documentation will help you understand the philosophy of DBIx::DataModel
. Just as a summary, here are some of its strong points :
UML-style declaration of relationships (instead of 'has_many', 'belongs_to', etc.)
efficiency through fine control of collaboration with the DBI layer (prepare/execute, fetch into reusable memory location, etc.)
improved API for SQL::Abstract (named parameters, simplified 'orderBy')
clear conceptual distinction between
data sources (tables and views),
database statements (stateful objects representing stepwise building of an SQL query and stepwise retrieval of results),
data rows (lightweight hashrefs containing nothing but column names and values)
joins with simple syntax and possible override of default INNER JOIN/LEFT JOIN properties; instances of joins multiply inherit from their member tables.
named placeholders
nested, cross-database transactions
DBIx::DataModel
is used in production within a mission-critical application with several hundred users, for managing Geneva courts of law.
Limitations
Here are some current limitations of DBIx::DataModel
:
- no schema versioning
-
DBIx::DataModel
knows very little about the database schema (only tables, primary and foreign keys); therefore it provides no support for schema changes (and seldom needs to know about them). - no object caching nor 'dirty columns'
-
DBIx::DataModel
does not keep track of data mutations in memory, and therefore provides no support for automatically propagating changes into the database; the client code has explicitly manageinsert
andupdate
operations. - no 'cascaded update' nor 'insert or create'
-
Cascaded inserts and deletes are supported, but not cascaded updates. This would need 'insert or create', which at the moment is not supported either.
INDEX TO THE DOCUMENTATION
Although the basic principles are quite simple, there are many details to discuss, so the documentation is quite long. In an attempt to accomodate for different needs of readers, it has been structured as follows :
The DESIGN chapter covers the architecture of
DBIx::DataModel
, its main distinctive features and the motivation for such features; it is of interest if you are comparing various ORMs, or if you want to globally understand howDBIx::DataModel
works, and what it can or cannot do. This chapter also details the concept of statements, which underlies all SELECT requests to the database.The QUICKSTART chapter is a guided tour that summarizes the main steps to get started with the framework.
The REFERENCE chapter is a complete reference to all methods, structured along usage steps: creating a schema, populating it with table and associations, parameterizing the framework, and finally data retrieval and manipulation methods.
The MISC chapter discusses how this framework interacts with its context (Perl namespaces, DBI layer, etc.), and how to work with self-referential associations.
The INTERNALS chapter documents the internal structure of the framework, for programmers who might be interested in extending it.
The GLOSSARY defines terms used in this documentation, and points to the software constructs that implement these terms.
The DELTA_1.0 chapter summarizes the differences with previous version 0.35.
The DBIx::DataModel::Schema::Generator documentation explains how to automatically generate a schema from a
DBI
connection, from a SQL::Translator description or from an existingDBIx::Class|DBIx::Class
schema.The DBIx::DataModel::Statement documentation documents the methods of statements (not included in the general REFERENCE chapter).
SIDE-EFFECTS
Upon loading, DBIx::DataModel::View adds a coderef into global @INC
(see "require" in perlfunc), so that it can take control and generate a class on the fly when retrieving frozen objects from "thaw" in Storable. Should be totally harmless unless you do some very special things with @INC
.
AUTHOR
Laurent Dami, <laurent.dami AT etat geneve ch>
ACKNOWLEDGEMENTS
Thanks to Cedric Bouvier for some bug fixes and improvements.
COPYRIGHT AND LICENSE
Copyright 2006, 2008 by Laurent Dami.
This library is free software; you can redistribute it and/or modify it under the same terms as Perl itself.