Classes
Overview
The QodlyScript language supports the concept of classes. In a programming language, using a class allows you to define an object behaviour with associated properties and functions.
Once a user class is defined, you can instantiate objects of this class anywhere in your code. Each object is an instance of its class. A class can extend
another class, and then inherits from its functions and properties (declared and computed).
The class model in QodlyScript is similar to classes in JavaScript, and based on a chain of prototypes.
For example, you could create a Person
class with the following definition:
//Class: Person
constructor(firstname : string, lastname : string)
this.firstName = firstname
this.lastName = lastname
function get fullName() -> fullName : string
fullName = this.firstName+" "+this.lastName
function sayHello() -> welcome : string
welcome = "Hello "+this.fullName
In a method, creating a "Person":
var person : cs.Person //object of Person class
var hello : string
person = cs.Person.new("John","Doe")
//person:{firstName: "John", lastName: "Doe", fullName: "John Doe"}
hello = person.sayHello() //"Hello John Doe"
Creating classes
User classes
To create a new user class in Qodly Studio, click on the + button of the Explorer and give a name to the class:
You can also select New > Class from the menu bar, enter a name and click Create:
Data Model classes
Data Model classes are automatically created when you click on the <...>
button in the model editor, when a dataclass is selected. For more information, please refer to this section.
Class definition
When naming classes, you should keep in mind the following rules:
- A class name must be compliant with property naming rules.
- Class names are case sensitive.
- Giving the same name to a user class and a datastore's dataclass is not recommended, in order to prevent any conflict.
A user class in Qodly is defined by a specific method file (.4qs), stored in the /Project/Sources/Classes/
folder. The name of the file is the class name. For example, a class named "Polygon" will be based upon the following file:
Project folder
Project
Sources
Classes
Polygon.4qs
Class stores
Available classes are accessible from their class stores. Two class stores are available:
cs
for user class store4D
for built-in class store
cs
cs* : object
Parameter | Type | Description | |
---|---|---|---|
Result | object | ← | Class Store containing all user classes of the current project |
The cs
command returns a Class Store object containing all user classes defined in the current project. This command is necessary to instantiate an object from a user class.
It returns all user classes defined in the opened project, as well as Data Model classes.
Example
You want to create a new instance of an object of myClass
:
instance = cs.myClass.new()
4D
4D* : object
Parameter | Type | Description | |
---|---|---|---|
Result | object | ← | Class Store containing all built-in 4D classes |
The 4D
command returns a Class Store object containing all available built-in classes in the Qodly application. It provides access to specific classes such as CryptoKey.
Example
You want to create a new key in the CryptoKey
class:
key = 4D.CryptoKey.new(newObject("type","ECDSA","curve","prime256v1"))
Class object
When a class is defined in the project, it is loaded in the QodlyScript language environment. A class is an object itself, of "Class" class. A class object has the following properties and function:
name
stringsuperclass
object (null if none)new()
function, allowing to instantiate class objectsisShared
property, true if the class is sharedisSingleton
property, true if the class defines a singletonme
property, allowing to instantiate and access singletons.
In addition, a class object can reference a constructor
object (optional).
A class object is a shared object and can therefore be accessed from different processes simultaneously.
Inheritance
If a class inherits from another class (i.e. the extends keyword is used in its definition), the parent class is its superclass
.
When QodlyScript does not find a function or a property in a class, it searches it in its superclass
; if not found, QodlyScript continues searching in the superclass of the superclass, and so on until there is no more superclass (all objects inherit from the "4D.Object" superclass).
objectClass
objectClass ( object ) -> object | null
objectClass
returns the class of the object passed in parameter.
instanceOf
instanceOf ( object , class ) -> boolean
instanceOf
returns true
if object
belongs to class
or to one of its inherited classes, and false
otherwise.
Class keywords
Specific QodlyScript keywords can be used in class definitions:
function <Name>
to define class functions of the objectsfunction get <Name>
andfunction set <Name>
to define computed properties of the objectsconstructor
to define static properties of the objectsproperty
to define static properties of the objects with a typeextends <ClassName>
to define inheritancesuper
to call the superclassthis
to reference the object being processed
ORDA data model classes support additional keywords:
exposed
to allow external access to the function,function query <attributeName>
andfunction orderBy <attributeName>
to define additional database functions for calculated attributes.
function
Syntax
{shared} function <name>({parameterName : type, ...}){->parameterName : type}
// code
There is no ending keyword for function code. The QodlyScript language automatically detects the end of a function's code by the next function
keyword or the end of the class file.
Class functions are specific properties of the class. They are objects of the 4D.Function class.
In the class definition file, function declarations use the function
keyword, and the name of the function. If the function is declared in a shared class, you can use the shared
keyword so that the function could be called without use...end
structure. For more information, refer to the Shared functions paragraph below.
The function name must be compliant with property naming rules.
Since properties and functions share the same namespace, using the same name for a property and a function is not allowed (an error is thrown in this case).
Starting a function name with an underscore character ("_") will exclude the function from the autocompletion features in the code editor. For example, if you declare function _myPrivateFunction
in MyClass
, it will not be proposed in the code editor when you type in "cs.MyClass. "
.
Immediately following the function name, parameters for the function can be declared with an assigned name and data type, including the return parameter (optional). For example:
function computeArea(width : integer , height : integer)-> area : integer
Within a class function, the this
command is used as the object instance. For example:
function setFullname(firstname : string, lastname : string)
this.firstName = firstname
this.lastName = lastname
function getFullname()->fullname : string
fullname = this.firstName+" "+uppercase(this.lastName)
For a class function, the currentMethodName
command returns <ClassName>.<FunctionName>
, for example "MyClass.myFunction".
In the application code, class functions are called as member methods of the object instance and can receive parameters if any. The following syntaxes are supported:
- use of the
()
operator. For example,myObject.methodName("hello")
- use of a "4D.Function" class member method:
Parameters
Function parameters are declared using the parameter name and the parameter type, separated by a colon (:). The parameter name must be compliant with property naming rules. Multiple parameters (and types) are separated by commas (,).
function add(x, y : variant, z : integer, xy : object)
If the type is not stated, the parameter will be defined as variant
.
For more information on parameters, please refer to this page.
Return value
You declare the return parameter (optional) by adding an arrow (->
) and the return parameter definition after the input parameter(s) list, or a colon (:
) and the return parameter type only. For example:
function add(x : variant, y : integer)->result : integer
result = x+y
You can also declare the return parameter by adding only : type
and use the return expression
(it will also end the function execution). For example:
function add(x : variant, y : integer): integer
// some code
return x+y
Example 1
// Class: Rectangle
constructor(width : integer, height : integer)
this.name = "Rectangle"
this.height = height
this.width = width
// Function definition
function getArea()->result : integer
result = (this.height)*(this.width)
// In a project method
var rect : cs.Rectangle
var area : number
rect = cs.Rectangle.new(50,100)
area = rect.getArea() //5000
Example 2
This example uses the return expression
:
function getRectArea(width : integer, height : integer) : integer
if (width > 0 && height > 0)
return width * height
else
return 0
end
function get
and function set
Syntax
{shared} function get <name>()->result : type
// code
{shared} function set <name>(parameterName : type)
// code
function get
and function set
are accessors defining computed properties in the class. A computed property is a named property with a data type that masks a calculation. When a computed property value is accessed, QodlyScript substitutes the corresponding accessor's code:
- when the property is read, the
function get
is executed, - when the property is written, the
function set
is executed.
If the property is not accessed, the code never executes.
Computed properties are designed to handle data that do not necessary need to be kept in memory. They are usually based upon persistent properties. For example, if a class object contains as persistent property the gross price and the VAT rate, the net price could be handled by a computed property.
In the class definition file, computed property declarations use the function get
(the getter) and function set
(the setter) keywords, followed by the name of the property. The name must be compliant with property naming rules.
function get
returns a value of the property type and function set
takes a parameter of the property type. Both arguments must comply with standard function parameters.
When both functions are defined, the computed property is read-write. If only a function get
is defined, the computed property is read-only. In this case, an error is returned if the code tries to modify the property. If only a function set
is defined, QodlyScript returns undefined when the property is read.
If the functions are declared in a shared class, you can use the shared
keyword with them so that they could be called without use...end
structure. For more information, refer to the Shared functions paragraph below.
The type of the computed property is defined by the return
type declaration of the getter. It can be of any valid property type.
Assigning undefined to an object property clears its value while preserving its type. In order to do that, the function get
is first called to retrieve the value type, then the function set
is called with an empty value of that type.
In addition to function get
and function set
, ORDA classes also support the function query
and function orderBy
computed properties (named calculated attributes).
Example 1
//Class: Person
property firstName, lastName : string
constructor(firstname : string, lastname : string)
this.firstName = firstname
this.lastName = lastname
function get fullName() -> fullName : string
fullName = this.firstName+" "+this.lastName
function set fullName( fullName : string )
p = position(" ", fullName)
this.firstName = substring(fullName, 1; p-1)
this.lastName = substring(fullName, p+1)
//in a method
fullName = person.fullName // Function get fullName() is called
person.fullName = "John Smith" // Function set fullName() is called
Example 2
function get fullAddress()->result : object
result = newObject
result.fullName = this.fullName
result.address = this.address
result.zipCode = this.zipCode
result.city = this.city
result.state = this.state
result.country = this.country
constructor
Syntax
// Class: MyClass
{shared} {singleton} constructor({parameterName : type, ...})
// code
There is no ending keyword for class constructor function code. The QodlyScript language automatically detects the end of a function's code by the next function
keyword or the end of the class file.
A class constructor function, which accepts optional parameters, can be used to create and initialize objects of the user class.
When you call the new()
function, the class constructor is called with the parameters optionally passed to the new()
function.
There can only be one constructor function in a class (otherwise an error is returned). A constructor can use the super
keyword to call the constructor of the super class.
You can create and type instance properties inside the constructor (see example). Alternatively, if your instance properties' values do not depend on parameters passed to the constructor, you can define them using the property
keyword.
Using the shared
keyword creates a shared class, used to only instantiate shared objects. For more information, refer to the Shared classes paragraph.
Using the singleton
keyword creates a singleton, used to create a single instance. For more information, refer to the Singleton classes paragraph.
Example
// Class: MyClass
// Class constructor of MyClass
constructor (name : string)
this.name = name
// in a method
// you can instantiate an object
var o : cs.MyClass
o = cs.MyClass.new("HelloWorld")
// o == {"name":"HelloWorld"}
property
Syntax
property <propertyName>{, <propertyName2>,...}{ : <propertyType>}
The property
keyword can be used to declare a property inside a user class. A class property has a name and a type.
Declaring class properties enhances code editor suggestions, type-ahead features and error detection.
Properties are declared for new objects when you call the new()
function, however they are not automatically added to objects (they are only added when they are assigned a value).
A property is automatically added to the object when it is inititalized in the declaration line.
Property names must be compliant with property naming rules.
Since properties and functions share the same namespace, using the same name for a property and a function is not allowed (an error is thrown in this case).
The property type can be one of the following supported types:
propertyType | Contents |
---|---|
text | Text value |
date | Date value |
time | Time value |
boolean | Boolean value |
integer | Long integer value |
number | number value |
picture | Picture value |
blob | Scalar Blob value |
collection | Collection value |
variant | Variant value |
object | Object with default class |
4D.<className> | Object of the 4D class name |
cs.<className> | Object of the user class name |
The property
keyword can only be used in class methods and outside any function
or constructor
block.
Initializing the property in the declaration line
When declaring a property, you have the flexibility to specify its data type and provide its value in one statement. The supported syntax is:
property <propertyName> { : <propertyType>} := <propertyvalue>
When using this syntax, you cannot declare several properties in the declaration line.
You can omit the type in the declaration line, in which case the type will be inferred when possible. For example:
// Class: MyClass
property name : string := "Smith"
property age : integer := 42
property birthDate := !1988-09-29! //date is inferred
property fuzzy //variant
When you initialize a property in its declaration line, it is added to the class object after its instantiation with the new()
function but before the constructor is called.
If a class extends another class, the properties of the parent class are instantiated before the properties of the child class.
If you initialize a property in its declaration line with an object or a collection in a shared class, the value is automatically transformed into a shared value:
// in a shared class
property myCollection = ["something"]
// myCollection will be a shared collection
// equivalent to:
myCollection = newSharedCollection("something")
Example
// Class: MyClass
property name : string
property age : integer
property color : string := "Blue"
In a method:
var o : cs.MyClass
o = cs.MyClass.new() //o:{"color" : "Blue"}
o.name = "John" //o:{"color" : "Blue", "name":"John"}
o.age = "Smith" //error with check syntax
extends <ClassName>
Syntax
// Class: ChildClass
extends <ParentClass>
The extends
keyword is used in class declaration to create a user class which is a child of another user class. The child class inherits all functions of the parent class.
Class extension must respect the following rules:
- A user class cannot extend a built-in class (except 4D.Object and ORDA classes which are extended by default for user classes).
- A user class cannot extend a user class from another project.
- A user class cannot extend itself.
- It is not possible to extend classes in a circular way (i.e. "a" extends "b" that extends "a").
- It is not possible to define a shared user class extended from a non-shared user class.
Breaking such a rule is not detected by the code editor or the interpreter, only the check syntax
will throw an error in this case.
An extended class can call the constructor of its parent class using the super
command.
Example
This example creates a class called Square
from a class called Polygon
.
//Class: Square
//path: Classes/Square.4dm
extends Polygon
constructor (side : integer)
// It calls the parent class's constructor with lengths
// provided for the Polygon's width and height
super(side,side)
// In derived classes, super must be called
// before you can use 'this'
this.name = "Square"
function getArea() -> result : integer
result = this.height*this.width
super
super* : object
super( param...paramN : any )
Parameter | Type | Description | |
---|---|---|---|
param | any | → | Parameter(s) to pass to the parent constructor |
Result | object | ← | Object's parent |
Description
The super
command makes calls to the superclass.
super
serves two different purposes:
- Inside a constructor code,
super
allows to call the constructor of the superclass. When used in a constructor, thesuper
command appears alone and must be used before thethis
keyword is used.- If all class constructors in the inheritance tree are not properly called, error -10748 is generated. It's up to the developer to make sure calls are valid.
- If the
this
command is called on an object whose superclasses have not been constructed, error -10743 is generated. - If
super
is called out of an object scope, or on an object whose superclass constructor has already been called, error-10746 is generated.
constructor(t1 : string, t2 : string)
super(t1) //calls superclass constructor with a string param
this.param = t2 // use second param
- Inside a class function,
super
designates the prototype of the superclass and allows to call a function of the superclass hierarchy.
super.doSomething(42) //calls "doSomething" function declared in superclasses
Example 1
This example illustrates the use of super
in a class constructor. The command is called to avoid duplicating the constructor parts that are common between Rectangle
and Square
classes.
//Class: Rectangle
constructor(height : integer, width : integer)
this.name = "Rectangle"
this.height = height
this.width = width
function sayName()
return("Hi, I am a "+this.name+".")
function getArea()-> area : integer
area = this.height*this.width
//Class: Square
extends Rectangle
constructor(side : integer)
// It calls the parent class's constructor with lengths
// provided for the Rectangle's width and height
super(side, side)
// In derived classes, super must be called before you
// can use 'This'
this.name = "Square"
Example 2
This example illustrates the use of super
in a class member function.
You created a Rectangle class with a function:
//Class: Rectangle
function nbSides() -> sides : text
sides = "I have 4 sides"
You also created the Square class with a function calling the superclass function:
//Class: Square
extends Rectangle
function description() -> desc : text
desc = super.nbSides()+" which are all equal"
Then you can write in a method:
var square : object
var info : text
square = cs.Square.new()
info = square.description() //I have 4 sides which are all equal
this
this* : object
Parameter | Type | Description | |
---|---|---|---|
Result | object | ← | Current element or object |
Description
The this
command returns a reference to the currently processed object.
In most cases, the value of this
is determined by how a function is called. It can't be set by assignment during execution, and it may be different each time the function is called.
When executing a formula object created by the formula
or formulaFromString
commands, this
returns a reference to the object currently processed by the formula. For example:
o = newObject("prop",42,"f",formula(this.prop))
val = o.f() //42
When a constructor function is used (with the new()
function), its this
is bound to the new object being constructed.
//Class: ob
constructor
// Create properties on this as
// desired by assigning to them
this.a = 42
// in a method
o = cs.ob.new()
val = o.a //42
When calling the superclass constructor in a constructor using the super keyword, keep in mind that
this
must not be called before the superclass constructor, otherwise an error is generated.
In any cases, this
refers to the object the method was called on, as if the method were on the object.
//Class: ob
function f()
return this.a+this.b
Then you can write in a project method:
o = cs.ob.new()
o.a = 5
o.b = 3
val = o.f() //8
In this example, the object assigned to the variable o doesn't have its own f property, it inherits it from its class. Since f is called as a method of o, its this
refers to o.
Example
You want to use a project method as a formula encapsulated in an object:
var person : object
var g : string
person = newObject()
person.firstName = "John"
person.lastName = "Smith"
person.greeting = formula(Greeting)
g = person.greeting("hello") // returns "hello John Smith"
g = person.greeting("hi") // returns "hi John Smith"
With the Greeting
method:
declare(param : string) -> vMessage : text
vMessage = param+" "+this.firstName+" "+this.lastName
Shared classes
You can create shared classes. A shared class is a user class that instantiates a shared object when the new()
function is called on the class. A shared class can only create shared objects.
Shared classes also support shared functions that can be called without use...end
structures.
The .isShared
property of Class objects allows to know if the class is shared.
- A class inheriting from a non-shared class cannot be defined as shared.
- Shared classes are not supported by ORDA-based classes.
Creating a shared class
To create a shared class, add the shared
keyword before the Class Constructor. For example:
//shared class: Person
shared constructor ( firstname : string , lastname : string )
this.firstname:=firstname
this.lastname:=lastname
//myMethod
var person = cs.Person.new("John" , "Smith")
objectIsShared (person) // true
cs.Person.isShared //true
Shared functions
If a function defined inside a shared class modifies objects of the class, it should call use...end
structure to protect access to the shared objects. However, to simplify the code, you can define the function as shared so that it automatically triggers internal use...end
when executed.
To create a shared function, add the shared
keyword before the function keyword in a shared class. For example:
//shared class Foo
shared constructor ()
this.variable = 1
shared function bar (value : integer)
this.variable = value //no need to call use/end
If the shared
function keyword is used in a non-shared user class, it is ignored.
Singleton classes
A singleton class is a user class that only produces a single instance. For more information on singletons, please see the Wikipedia page about singletons.
Singletons types
QodlyScript supports three types of singletons:
- a process singleton has a unique instance for the process in which it is instantiated,
- a shared singleton has a unique instance for all processes.
- a session singleton is a shared singleton but with a unique instance for all processes in the session. Session singletons are shared within an entire session but vary between sessions. In Qodly, session singletons make it possible to create and use a different instance for each session, and therefore for each user.
Singletons are useful to define values that need to be available from anywhere in an application, a session, or a process.
Singleton classes are not supported by ORDA-based classes.
Creating and using singletons
You declare singleton classes by adding appropriate keyword(s) before the Class constructor
:
- To declare a (process) singleton class, write
singleton Class Constructor()
. - To declare a shared singleton class, write
shared singleton Class constructor()
. - To declare a session singleton class, write
session singleton Class constructor()
.
- Session singletons are automatically shared singletons (there's no need to use the
shared
keyword in the class constructor). - Singleton shared functions support
onHttpGet
keyword.
The class singleton is instantiated at the first call of the cs.<class>.me
property. The instantiated class singleton is then always returned when the me
property is used.
If you need to instantiate a singleton with parameters, you can also call the new()
function. In this case, it is recommended to instantiate the singleton in some code executed at application startup.
Once instantiated, a singleton class (and its singleton) exists as long as a reference to it exists somewhere in the application.
The .isSingleton
property of Class objects allows to know if the class is a singleton.
The .isSessionSingleton
property of Class objects allows to know if the class is a session singleton.
Singleton classes are only supported in User classes. They are NOT supported in Data Model classes such as Dataclass.
Examples
Process singleton
//class: ProcessTag
singleton constructor()
this.tag = random
To use the process singleton:
//in a process
var mySingleton = cs.ProcessTag.me //First instantiation
//mySingleton.tag == 5425 for example
...
var myOtherSingleton = cs.ProcessTag.me
//myOtherSingleton.tag == 5425
//in another process
var mySingleton = cs.ProcessTag.me //First instantiation
//mySingleton.tag == 14856 for example
...
var myOtherSingleton = cs.ProcessTag.me
//myOtherSingleton.tag == 14856
Shared singleton
//Class VehicleFactory
property vehicleBuilt : integer
shared singleton constructor()
this.vehicleBuilt = 0 //Number of vehicles built by the factory
shared function buildVehicle (type : string) -> vehicle : cs.Vehicle
switch
: type == "car"
vehicle = cs.Car.new()
: type == "truck"
vehicle = cs.Truck.new()
: type == "sport car"
vehicle = cs.SportCar.new()
: type == "motorbike"
vehicle = cs.Motorbike.new()
else
vehicle = cs.Car.new()
end
this.vehicleBuilt+=1
You can the call the cs.VehicleFactory singleton to get a new vehicle from everywhere in your application with a single line:
vehicle = cs.VehicleFactory.me.buildVehicle("truck")
Since the buildVehicle() function modifies the cs.VehicleFactory (by incrementing this.vehicleBuilt
) you need to add the shared
keyword to it.
Session singleton
In an inventory application, you want to implement an item inventory using session singletons.
//class ItemInventory
property itemList : collection = []
session singleton constructor()
shared function addItem (item : object)
this.itemList.push (item)
By defining the ItemInventory class as a session singleton, you make sure that every session and therefore every user has their own inventory. Accessing the user's inventory is as simple as:
//in a user session
myList = cs.ItemInventory.me.itemList
//current user's item list