POCO ActiveRecord User Guide POCO ActiveRecord Framework !!!Introduction POCO ActiveRecord is a simple and lightweight object-relational mapping (ORM) framework built on top of the POCO Data library. The main goal of POCO ActiveRecord is to relieve developers from having to write lots of boilerplate database query code for common operations like finding an object by ID, updating an object, deleting an object or running paged queries. As its name implies, the framework follows the well-known [[https://en.wikipedia.org/wiki/Active_record_pattern Active Record]] architectural pattern. It's based on a code generator (named <*ActiveRecord Compiler*>, or <[arc]>) and uses a convention-over-configuration approach. !!!Getting Started The starting point for using the ActiveRecord framework is an XML file. The XML file describes the classes that correspond to database tables, and their relationships. From that XML file, the ActiveRecord Compiler generates corresponding header and source files defining and implementing the respective C++ classes, as well as type handlers for the POCO Data library. Following is an example for such an XML file. The file defines two classes, an `Employee` class (mapped to a table named `employees`), and a `Role` class (mapped to a table named `roles`). ---- There is a n:1 relationship between `Employee` and `Role` (each employee has exactly one role). Furthermore, each employee can optionally have a manager, which is again an `Employee`. Properties named `id` are considered to be primary keys, unless a different property has been designated the primary key (with the `key` attribute in the `class` element). It's also possible to have objects without a primary key or ID column (keyless active records). The generated C++ classes will be in the `Sample` namespace, as specified in the <[project]> element. The definitions in the XML file correspond to the database schema built by the following <[CREATE TABLE]> statements: CREATE TABLE employees ( id CHAR(36) PRIMARY KEY, name VARCHAR(64), ssn VARCHAR(32), role INTEGER, manager CHAR(36) ); CREATE TABLE roles ( id INTEGER PRIMARY KEY AUTOINCREMENT, name VARCHAR(64), description VARCHAR(256) ); ---- If the database engine supports it, the `id` column of the `employees` table can be an UUID as well. Running the ActiveRecord Compiler with the above XML file (sample.xml) with the following statement: $ arc sample.xml ---- will create the following files in the current working directory: include/ Sample/ Employee.h Role.h src/ Employee.cpp Role.cpp ---- The generated classes are derived from the Poco::ActiveRecord::ActiveRecord class template and have accessor methods for all properties defined in the XML file, as well as methods for creating, updating and deleting instances in the database. ActiveRecord objects are reference counted, and every generated class contains a `Ptr` type alias for an appropriate Poco::AutoPtr<>. !!The Context ActiveRecord uses a Context (Poco::ActiveRecord::Context) class to bind objects to a database session (Poco::Data::Session). In addition to the database session, the Context also holds a connector-specific Poco::ActiveRecord::StatementPlaceholderProvider. This class makes sure generated SQL statements have the correct placeholders for the respective database backend. For most database backends, the `?` placeholders will be fine, but PostgreSQL has a different placeholder format (`$1`, `$2`, etc). The Context's StatementPlaceholderProvider takes care of that. Every ActiveRecord object must be associated with a Context, before any database operations can take place. Context objects are relatively lightweight, so they can be created whenever needed. Context objects are reference-counted, so a Context object will be kept alive as long as at least one ActiveRecord object still references it. !!Creating an Object The following code snippet shows how to create a new `Role` object and insert it into the `roles` table. Poco::Data::Session session("SQLite", "data.sqlite"); Context::Ptr pContext = new Context(session); Role::Ptr pDeveloper = new Role; pDeveloper->name("Developer") .description("Developer role"); pDeveloper->create(pContext); ---- As can be seen, setters (`name()`, `description()` in this case) can be chained. The `create()` method will bind the object to a Context and then execute an `INSERT` statement to insert the object into the `roles` table. !!Finding an Object The following code snippet shows how to find a `Role` object by its ID (1). Poco::Data::Session session("SQLite", "data.sqlite"); Context::Ptr pContext = new Context(session); Role::Ptr pRole = Role::find(pContext, 1); std::cout << "name: " << pRole->name() << "\n" << "description: " << pRole->description() << std::endl; ---- !!Updating an Object Updating an object involves first updating the respective properties using the setter functions, then calling the `update()` method. To update an ActiveRecord object, the object must already be bound to a Context. Objects returned from `find()`, or from a query will already be bound to a Context. Note that the following snippets will omit the session and context setup code. Role::Ptr pRole = Role::find(pContext, 1); pRole->description("New developer role"); pRole->update(); ---- !!Deleting an Object An object bound to a Context can be deleted by calling the `remove()` method. Role::Ptr pRole = Role::find(pContext, 1); pRole->remove(); ---- !!Queries Finding objects by their IDs alone is fine if the respective IDs are already known. However, in most cases, ActiveRecord objects will be obtained by executing a query. To do that, the ActiveRecord framework provides the Poco::ActiveRecord::Query class template. The Query template must be instantiated with the class of the resulting objects. The Query class will generate a `SELECT` statement. Query parameters can be specified via data binding. The `?` placeholder can be used regardless of the underlying database backend. The Query class will replace it with the appropriate placeholder for the backend. Actual query parameters are bound with the `bind()` method. The query is then executed by calling the `execute()` method. The result of a Query is a `std::vector` containing pointers (Poco::AutoPtr) to returned objects. Poco::ActiveRecord::Query query(pContext); const auto result = query .where("name = ?") .bind("Developer"s) .execute(); for (const auto& pRole: result) { std::cout << pRole->description() << std::endl; } ---- The argument to the `where()` method can be any SQL WHERE clause. Please note that you must use column names from the actual database tables in the WHERE clause, not property names. !Ordering The results of a Query can be ordered, by calling the `orderBy()` method. Note that the argument to `orderBy` must be the actual column name in the table, not the property name of the object. The column name can be followed by `ASC` or `DESC` to specify the direction. Poco::ActiveRecord::Query query(pContext); const auto result = query .where("name = ?") .bind("Developer"s) .orderBy("name ASC") .execute(); for (const auto& pRole: result) { std::cout << pRole->description() << std::endl; } ---- !Paging The result of a query can be paged, by specifying an offset and a limit. The offset specifies the index of the first result to be returned, the limit specifies the maximum number of objects returned. To retrieve all roles, split up into pages of 10 roles, the following code could be used: std::size_t offset = 0; const std::size_t pageSize = 10; Poco::ActiveRecord::Query query(pContext); bool done = false; while (!done) { const auto result = query .orderBy("name") .offset(offset) .limit(pageSize) .execute(); offset += result.size(); done = result.empty(); for (const auto& pRole: result) { // ... } query.reset(); } ---- In order to re-execute a Query, the `reset()` method must be called first, as is shown above at the end of the `while` loop. !Filtering Results In addition to filtering results with a `WHERE` clause, it's also possible to filter results with a lambda expression. While `WHERE` is evaluated in the database engine, and therefore much more efficient, the `filter()` method allows some additional flexibility. Poco::ActiveRecord::Query query(pContext); query.filter( [](const Role& role) { return role.name() == "Senior Developer"; } ); const auto result = query.execute(); ---- The lambda expression is passed a const reference to an ActiveRecord object and must return a `bool`. If `true` is returned, the object is included in the result, otherwise not. !Relations Relations (defined in the XML file as properties with a `references` attribute) can be accessed via two kinds accessor methods. The first accepts an ActiveObject::Ptr as parameter or returns it, the second kind takes a key as parameter or returns it. Accessors that take a key/ID value instead of an ActiveRecord have their method name suffixed with `ID`. In the following sample, the `role` property is set with the key value, whereas the `manager` property is set via the ActiveRecord object. Employee::Ptr pManager = new Employee; pManager->name("Bill Lumbergh").ssn("23452343").roleID(3); pManager->create(pContext); Employee::Ptr pEmployee = new Employee; pEmployee->name("Michael Bolton").ssn("123987123").roleID(2).manager(pManager); pEmployee->create(pContext); ---- !Auto-Increment Keys and Auto-Generated UUIDs on Insert ActiveRecord supports auto-incrementing keys when inserting an ActiveRecord. T o enable this feature, the `autoIncrementID` attribute in the `class` element needs to be set to `true`. When inserting such an ActiveRecord object, after executing the `INSERT` statement, the actual value of the key will be obtained from the database. This is currently implemented for SQLite, MySQL/MariaDB and PostgreSQL, using appropriate database-specific mechanisms. When inserting an ActiveRecord with an all-null UUID, a random UUID will be generated before executing the `INSERT` statement. !Keyless Active Records It is possible to define classes without an ID or primary key property. For these objects, no `find()` method will be generated, and updating these objects is also not possible (`update()` will throw a Poco::NotImplementedException). Keyless ActiveRecord objects can be retrieved by executing a Poco::ActiveRecord::Query. !!!Compiler XML Reference !!Supported Data Types The following data types can be specified for properties in the `type` attribute and are mapped to the indicated C++ types. Type in XML C++ Type ---------------------------- bool bool char char int8 Poco::Int8 uint8 Poco::UInt8 int16 Poco::Int16 uint16 Poco::UInt16 int32 Poco::Int32 uint32 Poco::UInt32 int64 Poco::Int64 uint64 Poco::UInt64 float float double double dateTime Poco::DateTime timestamp Poco::Timestamp time Poco::Data::Time date Poco::Data::Date uuid Poco::UUID string std::string ---- Note: When creating the underlying database schema, it's the developer's responsibility to use a database-specific column type compatible with the data type specified in the XML. !!Elements and Attributes !The project Element The `project` element must be the root element in the XML file. The `project` element accepts the following attributes: - `namespace`: Specifies the C++ namespace for the generated classes. A multi-level namespace can be specified, e.g. "MyProject::Data". - `convertCamelCase`: If set to `true`, property and class names specified in camel case (e.g., `firstName`) will be converted to snake case (`first_name`) to identify the respective column or table. Defaults to `false`. !The class Element The `class` element must be inside of a `project` element and accepts the following attributes: - `name`: Specifies the name of the class. Must be a valid C++ class name. Required. - `table`: Specifies the name of the related database table. If not specified, the table name will be derived from the class name (see the `convertCamelCase` attribute in the `project` element). - `key`: Specifies the name of the primary key column. If not specified, defaults to `id`. - `autoIncrementID`: If set to `true`, the primary key is considered to be auto-incremented. A new ActiveObject is inserted with a NULL primary key, which causes the database to assign a new key value. The actual key value is then obtained from the database after executing the `INSERT` statement. !The property Element The `property` element must be inside of a `class` element and accepts the following attributes: - `name`: Specifies the name of the variable, which is also used for the getter and setter methods. Must be a valid C++ variable or method name. Required. - `column`: Specifies the name of the related database column. If not specified, the column name will be derived from the property name (see the `convertCamelCase` attribute in the `project` element). - `type`: Specifies the data type of the property. See <*Supported Data Types*> for a list of supported values. Required. - `references`: Specifies the name of the target class for a relation. Must be the name of another class defined in the same XML document. - `cardinality`: Specifies the cardinality of the relation. The following values can be specified: `?` means zero or one, `1` means exactly one (default). Additionally, `*` means zero or more and `+` means one or more, but no accessor is currently generated for the latter two cardinalities. - `nullable`: If set to `true`, marks the property or column as nullable. In this case, the accessor methods will accept or return a Poco::Nullable<> value.