NAME

DBIx::DataModel::Doc::Quickstart - Get quickly started with DBIx::DataModel

DOCUMENTATION CONTEXT

This chapter is part of the DBIx::DataModel manual.

This chapter is a tutorial that shows the main steps to get started with DBIx::DataModel. The goal here is conciseness, not completeness; a full reference is given in the REFERENCE chapter.

The tutorial is a gentle expansion of the examples given in the SYNOPSIS, namely a small human resources management system.

BASIC ASSUMPTIONS

Before starting with DBIx::DataModel, you should have installed CPAN modules DBI and SQL::Abstract::More. You also need a database management system with a DBD driver.

Use your database modeling tool to create some tables for employees, departments, activities (an employee working in a department from a start date to an end date), and employee skills. If you have no modeling tool, you can also feed something like the following SQL code to the database

  CREATE TABLE t_employee (
    emp_id     INTEGER AUTO_INCREMENT PRIMARY KEY,
    lastname   TEXT    NOT NULL,
    firstname  TEXT,
    d_birth    DATE 
  ); 
  CREATE TABLE t_department (
    dpt_code   VARCHAR(5) PRIMARY KEY,
    dpt_name   TEXT    NOT NULL 
  );
  CREATE TABLE t_activity (
    act_id     INTEGER AUTO_INCREMENT PRIMARY KEY,
    emp_id     INTEGER NOT NULL REFERENCES t_employee(emp_id),
    dpt_code   VARCHAR(5) NOT NULL REFERENCES t_department(dpt_code),
    d_begin    DATE    NOT NULL,
    d_end      DATE
  );
  CREATE TABLE t_skill (
    skill_code VARCHAR(2) PRIMARY KEY,
    skill_name TEXT    NOT NULL 
  );
  CREATE TABLE t_employee_skill (
    emp_id         INTEGER NOT NULL REFERENCES t_employee(emp_id),
    skill_code     VARCHAR(2)  NOT NULL REFERENCES t_skill(skill_code),
    CONSTRAINT PRIMARY KEY (emp_id, skill_code)
  );

As can be seen from this SQL, we assume that the primary keys for t_employee and t_activity are generated automatically by the RDBMS. Primary keys for other tables are character codes and therefore should be supplied by the client program. We decided to use the suffixes _id for auto-generated keys, and _code for user-supplied codes.

All examples in this document use single-schema mode, which is the simplest way to work with DBIx::DataModel. If your application needs to simultaneously work with several databases that share the same schema structure (like for example when transferring data between various sources), then you need to work in multi-schema mode; explanations are provided "SCHEMA METHODS" in DBIx::DataModel::Doc::Reference.

DECLARE SCHEMA AND TABLES

DBIx::DataModel needs to acquire some knowledge about the datamodel. The rest of this chapter will go through the steps to manually write the necessary declarations, which are quite concise; however, you may gain some time by using DBIx::DataModel::Schema::Generator to automatically create a skeleton of these declarations.

First load DBIx::DataModel :

  use DBIx::DataModel;

Now define a schema :

  DBIx::DataModel->Schema('HR');

Here we have chosen a simple acronym HR as the schema name, but it could as well have been something like Human::Resources.

The schema now is a Perl class, so we can invoke its Table method to declare the first table within the schema :

  HR->Table(qw/Employee      t_employee        emp_id/);

This creates a new Perl class named HR::Employee (the schema name HR has been automatically prepended before the table name). The second argument t_employee is the database table, and the third argument emp_id is the primary key. So far nothing is declared about other columns in the table.

Other tables are declared in a similar fashion :

  HR->Table(qw/Department    t_department      dpt_code/)
    ->Table(qw/Activity      t_activity        act_id/)
    ->Table(qw/Skill         t_skill           skill_code/)
    ->Table(qw/EmployeeSkill t_employee_skill  emp_id  skill_code/);

This last declaration has 4 arguments because the primary key ranges over 2 columns.

DECLARE COLUMN TYPES

RDBMS usually require that dates be in ISO format of shape yyyy-mm-dd. Let's assume our users are European and want to see and enter dates of shape dd.mm.yyyy. Insert of converting back and forth within the client code, it's easier to do it at the ORM level. So we define conversion routines within a "Date" column type

  HR->Type(Date => 
     fromDB => sub {$_[0] =~ s/(\d\d\d\d)-(\d\d)-(\d\d)/$3.$2.$1/   if $_[0]},
     toDB   => sub {$_[0] =~ s/(\d\d)\.(\d\d)\.(\d\d\d\d)/$3-$2-$1/ if $_[0]},
     validate => sub {$_[0] =~ m/\d\d\.\d\d\.\d\d\d\d/},
   );

and then apply this type to the appropriate columns, by calling the define_column_type() method on the meta-table objects associated with our tables.

  HR::Employee->metadm->define_column_type(Date => qw/d_birth/);
  HR::Activity->metadm->define_column_type(Date => qw/d_begin d_end/);

Here we just perform scalar conversions; another design choice could be to "inflate" the data to some kind of Perl objects.

DECLARE ASSOCIATIONS

Basic associations

Now we will declare a binary association between departements and activities:

  HR->Association([qw/Department department  1 /],
                  [qw/Activity   activities  * /]);

The Association method takes two references to lists of arguments; in each of them, we find : class name, role name, multiplicity, and optionally the names of columns participating in the join. Here column names are not specified, so the method assumes that the join is on dpt_code (from the primary key of the class with multiplicity 1 in the association). This declaration corresponds to the following UML diagram :

  +----------------+                            +--------------+
  |                | 1                        * |              |
  | HR::Department +----------------------------+ HR::Activity |
  |                | department      activities |              |
  +----------------+                            +--------------+

Like when reading the diagram, the declaration should be read crosswise : here we are stating that a department may be associated with several activities; therefore the HR::Department class will contain an activities method which returns an arrayref. Conversely, an activity is associated with exactly one department, so the HR::Activity class will contain a department method which returns a single instance of HR::Department.

Since associations are symmetric, the two arrayrefs in the Association declaration could as well be given in the reverse order, yielding exactly the same effect.

Choosing role names

Technically, a role name can be any valid Perl identifier, so it can be chosen arbitrarily; however, in most cases it is a good idea to take the name of the associated table : this will make it easier to follow method calls and joins that navigate between tables. In addition, it is also a good idea to use role names in singular when the multiplicity is 1, and in plural when the multiplicity is greater than 1, again for readability reasons.

One exception to this recommendation is when there are several associations between the same tables, in which case role names are precisely useful to make the distinction. For example, suppose that each department has offices in one or several buildings, and has its address in one building: this could be modeled with one pair of roles office_buildings / departments_using, and one other pair of roles address_building / departments_addressed_at.

Compositions

The second association could be defined in a similar way; but here we will introduce the new concept of composition.

  HR->Composition([qw/Employee   employee    1 /],
                  [qw/Activity   activities  * /]);

This looks exactly like an association declaration; but it states that an activity somehow "belongs" to an employee (cannot exist without being attached to an employee, and is often created and deleted together with the employee). In a UML class diagram, this would be pictured with a black diamond on the Employee side. Using a composition instead of an association in this particular example would perhaps be debated by some data modelers; but at least it allows us to illustrate the concept.

A composition declaration behaves in all respects like an association. The main difference is in insert and delete methods, which will be able to perform more complex operations on data trees : for example it will be possible in one method call to insert an employee together with its activities. Compositions also support auto-expansion of data trees through the auto_expand() method.

Many-to-many associations

Now comes the association between employees and skills, which is a many-to-many association. This happens in two steps: first we declare as usual the associations with the linking table :

  HR->Association([qw/Employee      employee   1 /],
                  [qw/EmployeeSkill emp_skills * /]);

  HR->Association([qw/Skill         skill      1 /],
                  [qw/EmployeeSkill emp_skills * /]);

Then we declare the many-to-many association:

  HR->Association([qw/Employee  employees  *  emp_skills employee/],
                  [qw/Skill     skills     *  emp_skills skill   /]);

This looks almost exactly like the previous declarations, except that the last arguments are no longer column names, but rather role names: these are the sequences of roles to follow in order to implement the association. This example is just an appetizer; more explanations are provided in the reference section.

USE THE SCHEMA

To use the schema, we first need to give it a database connection :

  my $dbh = DBI->connect(...); # parameters according to your RDBMS
  HR->dbh($dbh);               # give $dbh handle to the schema

Now we can start populating the database:

  my ($bach_id, $berlioz_id, $monteverdi_id)
    = HR->table('Employee')->insert(
        [qw/ firstname    lastname   /],
        [qw/ Johann       Bach       /],
        [qw/ Hector       Berlioz    /],
        [qw/ Claudio      Monteverdi /],
    );

This form of insert(), supplying a list of arrayrefs with column names in the first arrayref, is convenient for inserting a bunch of rows at once. The other form is to supply one or several hashrefs, where each hashref corresponds to a record to create, and yields the same result :

    HR->table('Employee')->insert(
      {firstname => "Johann",  lastname => "Bach"      },
      {firstname => "Hector",  lastname => "Berlioz"   },
      {firstname => "Claudio", lastname => "Monteverdi"},
    );

According to our earlier assumptions, keys are generated automatically within the database, so they need not be supplied here. The return value of the method is the list of generated ids (provided that your database driver supports DBI's last_insert_id method).

Similarly, we create some departments and skills (here with explicit primary keys, and using both insertion syntaxes) :

  HR->table('Department')->insert(
    {dpt_code => "CPT",  dpt_name => "Counterpoint" },
    {dpt_code => "ORCH", dpt_name => "Orchestration"},
  );

  HR->table('Skill')->insert(
    [qw/ skill_code  skill_name /],
    [qw/ VL          Violin     /],
    [qw/ KB          Keyboard   /],
    [qw/ GT          Guitar     /],
   );

To perform updates, there is either a class method or an object method. Here is an example with the class method :

  HR->table('Employee')->update($bach_id => {firstname => "Johann Sebastian"});

Associations have their own insert methods, named insert_into_* :

  my $bach = HR->table('Employee')->fetch($bach_id); 
  
  $bach->insert_into_activities({d_begin => '01.01.1695',
                                 d_end   => '18.07.1750',
                                 dpt_code => 'CPT'});
  
  $bach->insert_into_emp_skills({skill_code => 'VL'},
                                {skill_code => 'KB'});

Compositions implement cascaded inserts from a given data tree :

  HR->table('Employee')->insert(
    {firstname  => "Richard",  
     lastname   => "Strauss",
     activities => [ {d_begin  => '01.01.1874',
                      d_end    => '08.09.1949',
                      dpt_code => 'ORCH'      } ]}
  );

and if we need the keys of records generated by those insertions, we can use the -returning => {} option :

  my $data = {firstname  => "Richard",  
              lastname   => "Strauss",
              activities => [ {d_begin  => '01.01.1874',
                               d_end    => '08.09.1949',
                               dpt_code => 'ORCH'      } ]};
  my $ids = HR->table('Employee')->insert($data, -returning => {});
  # ids now contains : { emp_id     => ..., 
  #                      activities => [{act_id => ...}]};

The select() method retrieves several records from a class :

  my $all_employees = HR->table('Employee')->select; 
  foreach my $emp (@$all_employees) {
    do_something_with($emp);
  }

or maybe we want something more specific :

  my @columns  = qw/firstname lastname/;
  my %criteria = (lastname => {-like => 'B%'});
  my $some_employees = HR->table('Employee')->select(
    -columns  => \@columns,
    -where    => \%criteria,
    -order_by => 'd_birth',
   );

From a given object, role methods allow us to get associated objects :

  foreach my $emp (@$all_employees) {
    print "$emp->{firstname} $emp->{lastname} ";
    my @skill_names = map {$_->{skill_name}  }} @{$emp->skills};
    print " has skills ", join(", ", @skill_names) if @skill_names;
  }

Passing arguments to role methods, we can restrict to specific columns or specific rows, exactly like the select() method :

  my @columns = qw/d_begin d_end/;
  my %criteria = (d_end => undef);
  my $current_activities = $some_emp->activities(-columns => \@columns,
                                                 -where   => \%criteria);

And it is possible to join on several roles at once:

  my $result = $emp->join(qw/activities department/)
                   ->select(-columns => \@columns,
                            -where   => \%criteria);

This concludes our short tutorial. More examples are given in the Reference chapter.