8.7 KiB
Fluent PostgreSQL
Fluent PostgreSQL (vapor/fluent-postgresql) is a type-safe, fast, and easy-to-use ORM for PostgreSQL built on top of Fluent.
!!! seealso The Fluent PostgreSQL package is built on top of Fluent and the pure Swift, NIO-based PostgreSQL core. You should refer to their guides for more information about subjects not covered here.
Getting Started
This section will show you how to add Fluent PostgreSQL to your project and create your first PostgreSQLModel.
Package
The first step to using Fluent PostgreSQL is adding it as a dependency to your project in your SPM package manifest file.
// swift-tools-version:4.0
import PackageDescription
let package = Package(
name: "MyApp",
dependencies: [
/// Any other dependencies ...
// 🖋🐘 Swift ORM (queries, models, relations, etc) built on PostgreSQL.
.package(url: "https://github.com/vapor/fluent-postgresql.git", from: "1.0.0"),
],
targets: [
.target(name: "App", dependencies: ["FluentPostgreSQL", ...]),
.target(name: "Run", dependencies: ["App"]),
.testTarget(name: "AppTests", dependencies: ["App"]),
]
)
Don't forget to add the module as a dependency in the targets array. Once you have added the dependency, regenerate your Xcode project with the following command:
vapor xcode
Model
Now let's create your first PostgreSQLModel. Models represent tables in your PostgreSQL database and they are the primary method of interacting with your data.
import FluentPostgreSQL
import Vapor
/// A simple user.
final class User: PostgreSQLModel {
/// The unique identifier for this user.
var id: Int?
/// The user's full name.
var name: String
/// The user's current age in years.
var age: Int
/// Creates a new user.
init(id: Int? = nil, name: String, age: Int) {
self.id = id
self.name = name
self.age = age
}
}
The example above shows a PostgreSQLModel for a simple model representing a user. You can make both structs and classes a model. You can even conform types that come from external modules. The only requirement is that these types conform to Codable, which must be declared on the base type for synthesized (automatic) conformance.
Standard practice with PostgreSQL databases is using an auto-generated BIGINT for creating and storing unique identifiers in the id column. It's also possible to use UUIDs or even Strings for your identifiers. There are convenience protocol for that.
| protocol | type | key |
|---|---|---|
PostgreSQLModel |
Int | id |
PostgreSQLUUIDModel |
UUID | id |
PostgreSQLStringModel |
String | id |
!!! seealso Take a look at Fluent → Model for more information on creating models with custom ID types and keys.
Migration
Most of your models will have a corresponding table—or schema—in your database. You can use Fluent → Migration to setup your schemas in a testable, maintainable way.
If you are creating models to represent an existing table in your database, you don't need a migration. Just set the defaultDatabase property on your model so that Fluent knows which database to use if none is specified explicitly.
User.defaultDatabase = .psql
Automatic
Fluent makes it easy to automatically generate a migration for your model
/// Allows `User` to be used as a migration.
extension User: PostgreSQLMigration { }
That's all it takes. Fluent uses Codable to analyze your model and will attempt to create an appropriate schema for it.
Custom
You can also implement custom migrations for more fine-grain control over the schemas generated. For example, you may want to store a User's name using a VARCHAR(64) instead of TEXT. Just like PostgreSQLModel, any struct or class can conform to PostgreSQLMigration.
/// Creates a table for `User`s.
struct CreateUser: PostgreSQLMigration {
static func prepare(on conn: PostgreSQLConnection) -> Future<Void> {
return PostgreSQLDatabase.create(User.self, on: conn) { builder in
builder.field(for: \.id)
builder.field(for: \.name, type: .varchar(64))
}
}
static func revert(on conn: PostgreSQLConnection) -> Future<Void> {
return PostgreSQLDatabase.delete(User.self, on: conn)
}
}
Migrations consist of two methods: prepare(...) and revert(...). The prepare method runs once and should prepare the database for storing and fetching your model. The revert method runs only if you need to undo changes to your database and should undo anything you do in the prepare method.
Custom migrations are also useful for situations where you may need to alter an existing table, like to add a new column.
/// Adds a new field to `User`'s table.
struct AddUsernameToUser: PostgreSQLMigration {
static func prepare(on conn: PostgreSQLConnection) -> Future<Void> {
return PostgreSQLDatabase.update(User.self, on: conn) { builder in
builder.field(for: \.username)
}
}
static func revert(on conn: PostgreSQLConnection) -> Future<Void> {
return PostgreSQLDatabase.update(User.self) { builder in
builder.deleteField(for: \.username, on: conn)
}
}
}
Constraints
You can also add foreign key and unique constraints to your models during a migration.
// creates a foreign key constraint ensuring Post.userID is a valid User.id
builder.foreignKey(from: \Post.userID, to: \User.id)
// creates a unique constraint ensuring no other posts have the same slug
builder.unique(on: \Post.slug)
Take a look at Fluent → Migration if you are interested in learning more about migrations.
Configure
The final step is to configure your database. At a minimum, this requires adding two things to your configure.swift file.
FluentPostgreSQLProviderMigrationConfig
Let's take a look.
import FluentPostgreSQL
/// ...
/// Register providers first
try services.register(FluentPostgreSQLProvider())
/// Configure migrations
var migrations = MigrationConfig()
migrations.add(model: User.self, database: .psql)
services.register(migrations)
/// Other services....
!!! tip
If this migration you are adding is also a model, you can use the add(model:on:) convenience to automatically set the model's defaultDatabase property. Otherwise, use the add(migration:on) method.
Registering the provider will add all of the services required for Fluent PostgreSQL to work properly. It also includes a default database config struct that uses typical development environment credentials.
You can of course override this config struct if you have non-standard credentials.
/// Register custom PostgreSQL Config
let psqlConfig = PostgreSQLDatabaseConfig(hostname: "localhost", port: 5432, username: "vapor")
services.register(psqlConfig)
Once you have the MigrationConfig added, you should be able to run your application and see the following:
Migrating psql DB
Migrations complete
Server starting on http://localhost:8080
Query
Now that you have created a model and a corresponding schema in your database, let's make your first query.
router.get("users") { req in
return User.query(on: req).all()
}
If you run your app, and query that route, you should see an empty array returned. Now you just need to add some users! Congratulations on getting your first Fluent PostgreSQL model and migration working.
Connection
With Fluent, you always have access to the underlying database driver. Using this underlying driver to perform a query is sometimes called a "raw query".
Let's take a look at a raw PostgreSQL query.
router.get("psql-version") { req -> Future<String> in
struct Version: Decodable {
var version: String
}
return req.withPooledConnection(to: .psql) { conn in
return try conn.query("SELECT version() as version;", decoding: Version.self).map { rows in
return try rows[0].version
}
}
}
In the above example, withPooledConnection(to:) is used to create a connection to the database identified by .psql. This is the default database identifier. See Fluent → Database to learn more.
Once you have the PostgreSQLConnection, we can perform a query on it. You can learn more about the methods available in PostgreSQL → Core.