NAME Class::PObject - Simple framework for programming persistent objects SYNOPSIS After loading the Class::PObject with "use", we can declare a class like so pobject Person => { columns => ['id', 'name', 'email'], datasource => './data' }; We can also declare the class in its own .pm file: package Person; use Class::PObject; pobject { columns => ['id', 'name', 'email'' datasource => './data' }; We can now create an instance of above Person, and fill it in with data, and store it into disk: $person = new Person(); $person->name('Sherzod'); $person->email('sherzodr@cpan.org'); $new_id = $person->save() We can access the saved Person later, make necessary changes and save back: $person = Person->load($new_id); $person->name('Sherzod Ruzmetov (The Geek)'); $person->save() We can load multiple objects as well: @people = Person->load(); for $person ( @people ) { printf("[%02d] %s <%s>\n", $person->id, $person->name, $person->email) } or we can load all the objects based on some criteria and sort the list by column name in descending order, and limit the results to only the first 3 objects: @people = Person->load( {name => "Sherzod"}, {sort => "name", direction => "desc", limit=>3}); We can also seek into a specific point of the result set: @people = Person->load(undef, {offset=>10, limit=>10}); DESCRIPTION Class::PObject is a simple class framework for programming persistent objects in Perl. Such objects can store themselves into disk, and recreate themselves from disk. OVERVIEW Idea behind Object Persistence is to represent data as a software object. Another way of looking at it is, to make objects persist across processes instead of simply being destroyed exiting the scope. DATA vs OBJECT Let's discuss what in common an object can have with raw data. In a plain text database, for instance, each line could represent a single record. Different pieces of the record could be separated by some commonly agreed delimiter, such as a comma (,), pipe sign (|) etc. Unique identifier for individual records can be the line number that particular record resides on. For example: # in person.txt Sherzod Ruzmetov, sherzodr[AT]cpan.org Leyla Ivanitskaya, leyla[AT]handalak.com In a BerkeleyDB (or DBM) each key/value pair of the hash can be considered a single record. A unique identifier for individual records can be the key of the hash. Pieces of records could be delimited by a commonly agreed delimiter, just like in a plain text database. For example: # in person.db 217 => "Sherzod Ruzmetov|sherzodr[AT]cpan.org" 218 => "Leyla Ivanitskaya|leyla[AT]handalak.com" In a Relational Database System, each row of a database table is considered a single record, and each piece of the record has its own column in the table. A unique identifier for individual records can be a single column marked as primary key, or multiple columns marked so: # in person +-----+----------------+------------------------+ | id | name | email | +-----+----------------+------------------------+ | 217 | Sherzod | sherzodr[AT]cpan.org | +-----+----------------+------------------------+ As you noticed, they all have something in common - they all have the same logical structure, a record identifier, several pieces of different records, and a container (single line, key/value pair or a single row). All these representations are low-level. Why couldn't we try to represent them all as a software object instead and forget what they really look like in the low-level. For example, we could treat a single record from either of the above databases as an object, say a Person object. According to above databases, this object may have three attributes, *id*, "name" and "email". Sounds so natural, doesn't it? Your programs, instead of dealing with low-level disk access each time a record should be accessed (for either writing or reading purposes), could just play with objects. And those objects could deal with low-level disk access behind the scenes. WHAT ARE THE ADVANTAGES First off, data, regardless of the storage mechanism, is always accessed through the same programming API. So your programs can work with any database system without any change at all. Will help make a cleaner code base, because your application will never be making use of any low-level procedures to access the data such as running any SQL queries. Everything happens through objects and their supported methods. Your applications will be more modular and code base will be more compact. As a developer you will have less code to maintain. Your programming API will be easily accessible by 3rd parties, thus making your applications easily integrative as well as extensible without having to undergo time consuming, costly training. All they will need to read is about a page of POD manual of your related class in order to be able to make use of it. WHAT ARE THE DISADVANTAGES Object API may not be able to provide all the flexibility and optimization of the underlying database engine. To remedy this some tools provide sort of backdoors for the programmers to be able to interact with the underlying database engine more directly. PROGRAMMING STYLE The style of Class::PObject is very similar to that of Class::Struct. Instead of exporting 'struct()', however, Class::PObject exports "pobject()" function. Another visual difference is the way you declare the class. In Class::PObject, each property of the class is represented as a *column*. Suppose, you have a database called "person" with the following records: # person +-----+----------------+------------------------+ | id | name | email | +-----+----------------+------------------------+ | 217 | Sherzod | sherzodr[AT]cpan.org | +-----+----------------+------------------------+ CLASS DECLARATIONS Let's declare a class first to represent the above data as a Persistent Object (pobject for short). To do this, we first load the Class::PObject with "use", and declare a class with "pobject()" function, like so: use Class::PObject; pobject Person => { columns => ["id", "name", "email"] }; Above construct is declaring a Class representing a Person object. Person object has 3 attributes that are called *columns* in the *pobject()* declaration. These are *id*, *name* and *email*. Above is called in-line declaration, because you are creating an inline object - the one that doesn't need to be in its own class file. You could declare it almost anywhere inside your Perl code. In-line declarations are not very useful, because you cannot access them separately from within another application without having to re-declare identical class several times in each of your programs. Another, more recommended way of declaring classes is in their own .pm files. For example, inside a Person.pm file we may put: # lib/Person.pm package Person; use Class::PObject; pobject Person => { columns => ["id", "name", "email"] }; __END__; That can be the whole content of your Perl module. Now, from any other application all we need to do is to load Person.pm, and access all the nifty things it has to offer: # inside our app.cgi, for example: use Person; .... OBJECT STORAGE From the above class declaration you may be wondering, how does it now how and where the object data are stored? The fact is, it doesn't. That's why by default it stores your objects in your system's temporary folder, wherever it may be, using default file driver. To control this behavior you can define *driver* and *datasource* attributes in addition to the above *columns* attribute: pobject Person => { columns => ["id", "name", "email"], datasource => './data' }; Now, it's still using the default file driver, but storing the objects in your custom, ./data folder. You could've also chosen to store your objects in a DBM file, or in mysql tables. That's where you will need to define your *driver* attribute. To store them in BerkelyDB, using DB_File pobject Person => { columns => ["id", "name", "email"], driver => 'db_file', datasource => './data' }; To store them in Comma Separated text files using DBD::CSV: pobject Person => { columns => ["id", "name", "email"], driver => 'csv', datasource { Dir => './data' } }; Or, to store them in a mysql database using DBD::mysql: pobject Person => { columns => ["id", "name", "email"], driver => 'mysql', datasource => { DSN => "dbi:mysql:people", User => "sherzodr", Password => "secret" } }; So forth. For more options you should refer to respective object driver. CREATEING NEW PERSON After having the above Person class declared, we can now create an instance of a new Person with the following syntax: $person = new Person(); Now what we need is to fill in the "$person"'s attributes, and save it into disk $person->name("Sherzod Ruzmetov"); $person->email("sherzodr[AT]cpan.org"); $person->save(); As soon as you call "save()" method of the "$person", all the records will be saved into the disk. Notice, we didn't give any value for the *id* column. Underlying object drivers will automatically generate a new ID for your newly created object, and "save()" method will return this ID for you. If you assign a value for *id*, you better make sure that ID doesn't already exist. If it does, the old object with that ID will be replaced with this new ID. So to be safe, just don't bother defining any values for your ID columns. Sometimes, if you have objects with few attributes that do not require too much data, you may choose to both create your Person and assign its values at the same time. You can do so by passing your column values while creating the new person: $person = new Person(name=>"Sherzod Ruzmetov", email=>"sherzodr[AT]cpan.org"); $person->save(); LOADING OBJECTS PObjects support "load()" class method, which allows you to retrieve your objects from the disk. You can retrieve objects in many ways. The easiest, and the most efficient way of loading an object from the disk is by its id: $person = Person->load(217); Now, assuming the "$person" could be retrieved successfully, we can access the attributes of the object like so: printf( "Hello %s!\n", $person->name ) Notice, we are using the same method names to access them as the ones we used to assign values with, but this time with no arguments. Above, instead of displaying the "$person"'s name, we could also edit the name and save it back: $person->name("Sherzod The Geek"); $person->save(); Sometimes you may choose to load multiple objects at a time. Using the same "load()" method, we could assign all the result set into an array: @people = Person->load(); Each element of the "@people" is a "$person" object, and you could list all of them with the following syntax: for my $person ( @people ) { printf("[%d] - %s <%s>\n", $person->id, $person->name, $person->email) } Notice two different contexts "load()" was used in. If you call "load()" in scalar context, regardless of the number of matching objects, you will always retrieve the first object in the data set. For added efficiency, Class::PObject will add *limit=>1* argument even if it's missing, or exists with a different value. If you called "load()" in array context, you will always receive an array of objects, even if result set consist of single object. Sometimes you just want to load objects matching a specific criteria, say, you want all the people whose name are *John*. You can achieve this by passing a hashref as the first argument to "load()": @johns = Person->load({name=>"John"}); Sets of key/value pairs passed to "load()" as the first argument are called *terms*. You can also apply post-result filtering to your list, such as sorting by a specific column in a specific order, and limit the list to *n* number of objects and start the listing at object *n* of the result set. All these attributes can be passed as the second argument to "load()" in the form of a hashref and are called *arguments* : @people = Person->load(undef, {sort=>'name', direction=>'desc', limit=>100}); Above "@people" holds 100 "$person" objects, all sorted by name in descending order. We could use both terms and arguments at the same time and in any combination. SUPPORTED ARGUMENTS OF load() Arguments are the second set of key/value pairs passed to "load()". Some drivers may look at this set as post-result-filtering. "sort" Defines which column the list should be sorted in. "direction" Denotes direction of the sort. Possible values are *asc* meaning ascending sort, and *desc*, meaning descending sort. If "sort" is defined, but no "direction" is available, *asc* is implied. "limit" Denotes the number of objects to be returned. "offset" Denotes the offset of the result set to be returned. It can be combined with "limit" to retrieve a sub-set of the result set. INCREMENTAL LOAD "load()" may be all you need most of the time. If your objects are of larger size, or if you need to operate on thousands of objects, your program may not have enough memory to hold them all, because "load()" tends to literally load all the matching objects to the memory. If this is your concern, you are better off using "fetch()" method instead. Syntax of "fetch()" is almost identical to "load()", with an exception that it doesn't except object id as the first argument, for it wouldn't make sense. You can either use it without any arguments, or with any combination of "\%terms" and "\%args" as needed, just like with "load()". Another important difference is, it does not return any objects. It's return value is an instance of Class::PObject::Iterator, which helps you to iterate through large data sets by loading them one at a time inside a "while"-loop: $result = Person->fetch(); while ( my $person = $result->next ) { ... } # or $result = Person->fetch({name=>"John"}, {limit=>100}); while ( my $person = $result->next ) { ... } For the list of methods available for "$result" - iterator object refer to its manual. COUNTING OBJECTS Counting objects is very frequent task in many projects. You want to be able to display how many people are in your database in total, or how many "John"s are there. You can of course do it with a syntax similar to: @all = People->load(); $count = scalar( @all ); This however, also means you will be loading all the objects to memory at the same time. Even if we could've done it using an iterator class, as discussed earlier, some database engines may provide a more optimized way of retrieving this information without having to "load()" any objects, by consulting available meta information. That's where "count()" class method comes in: $count = Person->count(); "count()" can accept \%terms, just like above "load()" does as the first argument. Using \%terms you can define conditions: $njohns = Person->count({name=>"John"}); REMOVING OBJECTS PObjects support "remove()" and "remove_all()" methods. "remove()" is an object method. It is used only to remove one object at a time. "remove_all()" is a class method, which removes all the objects of the same type, thus a little more scarier. To remove a person with id 217, we first need to create an object of that Person, and only then call "remove()" method: $person = Person->load(217); $person->remove(); "remove_all()" is a static class method, and is used for removing all the objects from the database: Person->remove_all(); "remove_all()" can also be used for removing objects selectively without having to load them first. To do this, you can pass "\%terms" as the first argument to "remove_all()". These "\%terms" are the same as the ones we used for "load()": Person->remove_all({rating=>1}); Notice, if we wanted to, we still could've used a code similar to the following to remove all the objects: $result = Person->fetch(); while ( $person = $result->next ) { $person->remove } However, this will require first loading the object to the memory one at a time, and then removing one at a time. Most of the object drivers may offer a better, efficient way of removing objects from the disk without having to "load()" them. That's why you should rely on "remove_all()". DEFINING METHODS OTHER THAN ACCESSORS In some cases accessor methods are not all the methods your class may ever need. It may need some other behaviors. In cases like these, you can extend your class with your own, custom methods. For example, assume you have a "User" object, which needs to be authenticated before they can access certain parts of the web site. It may be a good idea to add "authenticate()" method into your "User" class, which either returns a User object if he/she is logged in properly, or returns undef, meaning the user isn't logged in yet. To do this we can simply define additional method, "authenticate()" inside our .pm file. Consider the following example: package User; pobject { columns => ['id', 'login', 'psswd', 'email'], datasource => './data' }; sub authenticate { my $class = shift; my ($cgi, $session) = @_; # if the user is already logged in, return the object: if ( my $user_id = $session->param('_logged_in') ) { return $class->load( $user_id ) } # if we come this far, the user is not logged in yet, but still # might've submitted our login form: my $login = $cgi->param('login') or return 0; my $password = $cgi->param('password') or return 0; # if we come this far, both 'login' and 'password' fields were submitted # in the form. So we try to load() the matching object: my $user = $class->load({login=>$login, psswd=>$password}) or return undef; # we store the user's Id in our session parameter, and return the user # object $session->param('_logged_in', $user->id); return $user } __END__; Now, we can check if the user is logged into our web site with the following code: use User; my $user = User->authenticate($cgi, $session); unless ( defined $user ) { die "You need to login to the web site before you can access this page!" } printf "